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Even Odd two flavour ratio added and dH == small
This commit is contained in:
Peter Boyle
112
lib/qcd/action/pseudofermion/EvenOddSchurDifferentiable.h
Normal file
112
lib/qcd/action/pseudofermion/EvenOddSchurDifferentiable.h
Normal file
@ -0,0 +1,112 @@
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#ifndef QCD_EVEN_ODD_SCHUR_DIFFERENTIABLE_H
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#define QCD_EVEN_ODD_SCHUR_DIFFERENTIABLE_H
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namespace Grid{
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namespace QCD{
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// Base even odd HMC on the normal Mee based schur decomposition.
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//
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// M = (Mee Meo) = (1 0 ) (Mee 0 ) (1 Mee^{-1} Meo)
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// (Moe Moo) (Moe Mee^-1 1 ) (0 Moo-Moe Mee^-1 Meo) (0 1 )
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//
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// Determinant is det of middle factor
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// This assumes Mee is indept of U.
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//
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template<class Impl>
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class SchurDifferentiableOperator : public SchurDiagMooeeOperator<FermionOperator<Impl>,typename Impl::FermionField>
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{
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public:
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INHERIT_IMPL_TYPES(Impl);
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typedef FermionOperator<Impl> Matrix;
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SchurDifferentiableOperator (Matrix &Mat) : SchurDiagMooeeOperator<Matrix,FermionField>(Mat) {};
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void MpcDeriv(GaugeField &Force,const FermionField &U,const FermionField &V) {
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GridBase *fgrid = this->_Mat.FermionGrid();
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GridBase *fcbgrid = this->_Mat.FermionRedBlackGrid();
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GridBase *ugrid = this->_Mat.GaugeGrid();
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GridBase *ucbgrid = this->_Mat.GaugeRedBlackGrid();
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Real coeff = 1.0;
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FermionField tmp1(fcbgrid);
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FermionField tmp2(fcbgrid);
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conformable(fcbgrid,U._grid);
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conformable(fcbgrid,V._grid);
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// Assert the checkerboard?? or code for either
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assert(U.checkerboard==Odd);
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assert(V.checkerboard==U.checkerboard);
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GaugeField ForceO(ucbgrid);
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GaugeField ForceE(ucbgrid);
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// X^dag Der_oe MeeInv Meo Y
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// Use Mooee as nontrivial but gauge field indept
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this->_Mat.Meooe (V,tmp1); // odd->even -- implicit -0.5 factor to be applied
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this->_Mat.MooeeInv(tmp1,tmp2); // even->even
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this->_Mat.MoeDeriv(ForceO,U,tmp2,DaggerNo);
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// Accumulate X^dag M_oe MeeInv Der_eo Y
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this->_Mat.MeooeDag (U,tmp1); // even->odd -- implicit -0.5 factor to be applied
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this->_Mat.MooeeInvDag(tmp1,tmp2); // even->even
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this->_Mat.MeoDeriv(ForceE,tmp2,V,DaggerNo);
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assert(ForceE.checkerboard==Even);
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assert(ForceO.checkerboard==Odd);
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setCheckerboard(Force,ForceE);
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setCheckerboard(Force,ForceO);
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Force=-Force;
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}
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void MpcDagDeriv(GaugeField &Force,const FermionField &U,const FermionField &V) {
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GridBase *fgrid = this->_Mat.FermionGrid();
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GridBase *fcbgrid = this->_Mat.FermionRedBlackGrid();
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GridBase *ugrid = this->_Mat.GaugeGrid();
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GridBase *ucbgrid = this->_Mat.GaugeRedBlackGrid();
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Real coeff = 1.0;
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FermionField tmp1(fcbgrid);
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FermionField tmp2(fcbgrid);
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conformable(fcbgrid,U._grid);
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conformable(fcbgrid,V._grid);
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// Assert the checkerboard?? or code for either
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assert(V.checkerboard==Odd);
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assert(V.checkerboard==V.checkerboard);
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GaugeField ForceO(ucbgrid);
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GaugeField ForceE(ucbgrid);
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// X^dag Der_oe MeeInv Meo Y
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// Use Mooee as nontrivial but gauge field indept
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this->_Mat.MeooeDag (V,tmp1); // odd->even -- implicit -0.5 factor to be applied
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this->_Mat.MooeeInvDag(tmp1,tmp2); // even->even
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this->_Mat.MoeDeriv(ForceO,U,tmp2,DaggerYes);
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// Accumulate X^dag M_oe MeeInv Der_eo Y
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this->_Mat.Meooe (U,tmp1); // even->odd -- implicit -0.5 factor to be applied
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this->_Mat.MooeeInv(tmp1,tmp2); // even->even
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this->_Mat.MeoDeriv(ForceE,tmp2,V,DaggerYes);
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assert(ForceE.checkerboard==Even);
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assert(ForceO.checkerboard==Odd);
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setCheckerboard(Force,ForceE);
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setCheckerboard(Force,ForceO);
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Force=-Force;
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}
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};
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}
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}
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#endif
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@ -4,108 +4,6 @@
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namespace Grid{
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namespace QCD{
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// Base even odd HMC on the normal Mee based schur decomposition.
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//
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// M = (Mee Meo) = (1 0 ) (Mee 0 ) (1 Mee^{-1} Meo)
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// (Moe Moo) (Moe Mee^-1 1 ) (0 Moo-Moe Mee^-1 Meo) (0 1 )
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//
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// Determinant is det of middle factor
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// This assumes Mee is indept of U.
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//
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template<class Impl>
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class SchurDifferentiableOperator : public SchurDiagMooeeOperator<FermionOperator<Impl>,typename Impl::FermionField>
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{
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public:
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INHERIT_IMPL_TYPES(Impl);
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typedef FermionOperator<Impl> Matrix;
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SchurDifferentiableOperator (Matrix &Mat) : SchurDiagMooeeOperator<Matrix,FermionField>(Mat) {};
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void MpcDeriv(GaugeField &Force,const FermionField &U,const FermionField &V) {
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GridBase *fgrid = this->_Mat.FermionGrid();
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GridBase *fcbgrid = this->_Mat.FermionRedBlackGrid();
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GridBase *ugrid = this->_Mat.GaugeGrid();
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GridBase *ucbgrid = this->_Mat.GaugeRedBlackGrid();
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Real coeff = 1.0;
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FermionField tmp1(fcbgrid);
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FermionField tmp2(fcbgrid);
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conformable(fcbgrid,U._grid);
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conformable(fcbgrid,V._grid);
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// Assert the checkerboard?? or code for either
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assert(U.checkerboard==Odd);
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assert(V.checkerboard==U.checkerboard);
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GaugeField ForceO(ucbgrid);
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GaugeField ForceE(ucbgrid);
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// X^dag Der_oe MeeInv Meo Y
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// Use Mooee as nontrivial but gauge field indept
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this->_Mat.Meooe (V,tmp1); // odd->even -- implicit -0.5 factor to be applied
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this->_Mat.MooeeInv(tmp1,tmp2); // even->even
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this->_Mat.MoeDeriv(ForceO,U,tmp2,DaggerNo);
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// Accumulate X^dag M_oe MeeInv Der_eo Y
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this->_Mat.MeooeDag (U,tmp1); // even->odd -- implicit -0.5 factor to be applied
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this->_Mat.MooeeInvDag(tmp1,tmp2); // even->even
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this->_Mat.MeoDeriv(ForceE,tmp2,V,DaggerNo);
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assert(ForceE.checkerboard==Even);
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assert(ForceO.checkerboard==Odd);
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setCheckerboard(Force,ForceE);
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setCheckerboard(Force,ForceO);
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Force=-Force;
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}
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void MpcDagDeriv(GaugeField &Force,const FermionField &U,const FermionField &V) {
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GridBase *fgrid = this->_Mat.FermionGrid();
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GridBase *fcbgrid = this->_Mat.FermionRedBlackGrid();
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GridBase *ugrid = this->_Mat.GaugeGrid();
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GridBase *ucbgrid = this->_Mat.GaugeRedBlackGrid();
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Real coeff = 1.0;
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FermionField tmp1(fcbgrid);
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FermionField tmp2(fcbgrid);
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conformable(fcbgrid,U._grid);
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conformable(fcbgrid,V._grid);
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// Assert the checkerboard?? or code for either
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assert(V.checkerboard==Odd);
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assert(V.checkerboard==V.checkerboard);
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GaugeField ForceO(ucbgrid);
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GaugeField ForceE(ucbgrid);
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// X^dag Der_oe MeeInv Meo Y
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// Use Mooee as nontrivial but gauge field indept
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this->_Mat.MeooeDag (V,tmp1); // odd->even -- implicit -0.5 factor to be applied
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this->_Mat.MooeeInvDag(tmp1,tmp2); // even->even
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this->_Mat.MoeDeriv(ForceO,U,tmp2,DaggerYes);
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// Accumulate X^dag M_oe MeeInv Der_eo Y
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this->_Mat.Meooe (U,tmp1); // even->odd -- implicit -0.5 factor to be applied
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this->_Mat.MooeeInv(tmp1,tmp2); // even->even
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this->_Mat.MeoDeriv(ForceE,tmp2,V,DaggerYes);
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assert(ForceE.checkerboard==Even);
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assert(ForceO.checkerboard==Odd);
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setCheckerboard(Force,ForceE);
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setCheckerboard(Force,ForceO);
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Force=-Force;
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}
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};
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////////////////////////////////////////////////////////////////////////
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@ -123,7 +21,6 @@ namespace Grid{
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FermionOperator<Impl> & FermOp;// the basic operator
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OperatorFunction<FermionField> &DerivativeSolver;
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OperatorFunction<FermionField> &ActionSolver;
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FermionField PhiOdd; // the pseudo fermion field for this trajectory
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@ -154,6 +51,7 @@ namespace Grid{
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// P(eta) = e^{- eta^dag eta}
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//
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// e^{x^2/2 sig^2} => sig^2 = 0.5.
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RealD scale = std::sqrt(0.5);
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FermionField eta (FermOp.FermionGrid());
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@ -169,6 +67,7 @@ namespace Grid{
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FermOp.ImportGauge(U);
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PCop.MpcDag(etaOdd,PhiOdd);
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FermOp.MooeeDag(etaEven,PhiEven);
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PhiOdd =PhiOdd*scale;
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@ -219,17 +118,16 @@ namespace Grid{
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FermionField Y(FermOp.FermionRedBlackGrid());
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GaugeField tmp(FermOp.GaugeGrid());
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SchurDifferentiableOperator<Impl> PCop(FermOp);
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X=zero;
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DerivativeSolver(PCop,PhiOdd,X);
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PCop.Op(X,Y);
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SchurDifferentiableOperator<Impl> Mpc(FermOp);
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// Our conventions really make this UdSdU; We do not differentiate wrt Udag here.
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// So must take dSdU - adj(dSdU) and left multiply by mom to get dS/dt.
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PCop.MpcDeriv(tmp , Y, X ); dSdU=tmp;
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PCop.MpcDagDeriv(tmp , X, Y); dSdU=dSdU+tmp;
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X=zero;
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DerivativeSolver(Mpc,PhiOdd,X);
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Mpc.Mpc(X,Y);
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Mpc.MpcDeriv(tmp , Y, X ); dSdU=tmp;
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Mpc.MpcDagDeriv(tmp , X, Y); dSdU=dSdU+tmp;
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// Treat the EE case. (MdagM)^-1 = Minv Minvdag
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// Deriv defaults to zero.
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163
lib/qcd/action/pseudofermion/TwoFlavourEvenOddRatio.h
Normal file
163
lib/qcd/action/pseudofermion/TwoFlavourEvenOddRatio.h
Normal file
@ -0,0 +1,163 @@
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#ifndef QCD_PSEUDOFERMION_TWO_FLAVOUR_EVEN_ODD_RATIO_H
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#define QCD_PSEUDOFERMION_TWO_FLAVOUR_EVEN_ODD_RATIO_H
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namespace Grid{
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namespace QCD{
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///////////////////////////////////////
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// Two flavour ratio
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///////////////////////////////////////
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template<class Impl>
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class TwoFlavourEvenOddRatioPseudoFermionAction : public Action<typename Impl::GaugeField> {
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public:
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INHERIT_IMPL_TYPES(Impl);
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private:
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FermionOperator<Impl> & NumOp;// the basic operator
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FermionOperator<Impl> & DenOp;// the basic operator
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OperatorFunction<FermionField> &DerivativeSolver;
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OperatorFunction<FermionField> &ActionSolver;
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FermionField PhiOdd; // the pseudo fermion field for this trajectory
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FermionField PhiEven; // the pseudo fermion field for this trajectory
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public:
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TwoFlavourEvenOddRatioPseudoFermionAction(FermionOperator<Impl> &_NumOp,
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FermionOperator<Impl> &_DenOp,
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OperatorFunction<FermionField> & DS,
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OperatorFunction<FermionField> & AS) :
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NumOp(_NumOp),
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DenOp(_DenOp),
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DerivativeSolver(DS),
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ActionSolver(AS),
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PhiEven(_NumOp.FermionRedBlackGrid()),
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PhiOdd(_NumOp.FermionRedBlackGrid())
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{
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conformable(_NumOp.FermionGrid(), _DenOp.FermionGrid());
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conformable(_NumOp.FermionRedBlackGrid(), _DenOp.FermionRedBlackGrid());
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conformable(_NumOp.GaugeGrid(), _DenOp.GaugeGrid());
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conformable(_NumOp.GaugeRedBlackGrid(), _DenOp.GaugeRedBlackGrid());
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};
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virtual void init(const GaugeField &U, GridParallelRNG& pRNG) {
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// P(phi) = e^{- phi^dag Vpc (MpcdagMpc)^-1 Vpcdag phi}
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//
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// NumOp == V
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// DenOp == M
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//
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// Take phi_o = Vpcdag^{-1} Mpcdag eta_o ; eta_o = Mpcdag^{-1} Vpcdag Phi
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//
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// P(eta_o) = e^{- eta_o^dag eta_o}
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//
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// e^{x^2/2 sig^2} => sig^2 = 0.5.
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//
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RealD scale = std::sqrt(0.5);
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FermionField eta (NumOp.FermionGrid());
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FermionField etaOdd (NumOp.FermionRedBlackGrid());
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FermionField etaEven(NumOp.FermionRedBlackGrid());
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FermionField tmp (NumOp.FermionRedBlackGrid());
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gaussian(pRNG,eta);
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pickCheckerboard(Even,etaEven,eta);
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pickCheckerboard(Odd,etaOdd,eta);
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NumOp.ImportGauge(U);
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DenOp.ImportGauge(U);
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SchurDifferentiableOperator<Impl> Mpc(DenOp);
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SchurDifferentiableOperator<Impl> Vpc(NumOp);
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// Odd det factors
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Mpc.MpcDag(etaOdd,PhiOdd);
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ActionSolver(Vpc,PhiOdd,tmp);
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Vpc.Mpc(tmp,PhiOdd);
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// Even det factors
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DenOp.MooeeDag(etaEven,tmp);
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NumOp.MooeeInvDag(tmp,PhiEven);
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PhiOdd =PhiOdd*scale;
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PhiEven=PhiEven*scale;
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};
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//////////////////////////////////////////////////////
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// S = phi^dag V (Mdag M)^-1 Vdag phi
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//////////////////////////////////////////////////////
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virtual RealD S(const GaugeField &U) {
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NumOp.ImportGauge(U);
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DenOp.ImportGauge(U);
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SchurDifferentiableOperator<Impl> Mpc(DenOp);
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SchurDifferentiableOperator<Impl> Vpc(NumOp);
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||||
FermionField X(NumOp.FermionRedBlackGrid());
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FermionField Y(NumOp.FermionRedBlackGrid());
|
||||
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||||
X=zero;
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||||
Vpc.MpcDag(PhiOdd,Y); // Y= Vdag phi
|
||||
ActionSolver(Mpc,Y,X); // X= (MdagM)^-1 Vdag phi
|
||||
Mpc.Mpc(X,Y); // Y= Mdag^-1 Vdag phi
|
||||
|
||||
RealD action = norm2(Y);
|
||||
|
||||
// The EE factorised block; normally can replace with zero if det is constant (gauge field indept)
|
||||
// Only really clover term that creates this. Leave the EE portion as a future to do to make most
|
||||
// rapid progresss on DWF for now.
|
||||
//
|
||||
// Vpc.MooeeDag(PhiEven,X);
|
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// Mpc.MooeeInvDag(X,Y);
|
||||
// action = action + norm2(Y);
|
||||
|
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return action;
|
||||
};
|
||||
|
||||
//////////////////////////////////////////////////////
|
||||
// dS/du = phi^dag dV (Mdag M)^-1 V^dag phi
|
||||
// - phi^dag V (Mdag M)^-1 [ Mdag dM + dMdag M ] (Mdag M)^-1 V^dag phi
|
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// + phi^dag V (Mdag M)^-1 dV^dag phi
|
||||
//////////////////////////////////////////////////////
|
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virtual void deriv(const GaugeField &U,GaugeField & dSdU) {
|
||||
|
||||
NumOp.ImportGauge(U);
|
||||
DenOp.ImportGauge(U);
|
||||
|
||||
SchurDifferentiableOperator<Impl> Mpc(DenOp);
|
||||
SchurDifferentiableOperator<Impl> Vpc(NumOp);
|
||||
|
||||
FermionField X(NumOp.FermionRedBlackGrid());
|
||||
FermionField Y(NumOp.FermionRedBlackGrid());
|
||||
|
||||
GaugeField force(NumOp.GaugeGrid());
|
||||
|
||||
X=zero;
|
||||
|
||||
//Y=Vdag phi
|
||||
//X = (Mdag M)^-1 V^dag phi
|
||||
//Y = (Mdag)^-1 V^dag phi
|
||||
Vpc.MpcDag(PhiOdd,Y); // Y= Vdag phi
|
||||
DerivativeSolver(Mpc,Y,X); // X= (MdagM)^-1 Vdag phi
|
||||
Mpc.Mpc(X,Y); // Y= Mdag^-1 Vdag phi
|
||||
|
||||
// phi^dag V (Mdag M)^-1 dV^dag phi
|
||||
Vpc.MpcDagDeriv(force , X, PhiOdd ); dSdU=force;
|
||||
|
||||
// phi^dag dV (Mdag M)^-1 V^dag phi
|
||||
Vpc.MpcDeriv(force , PhiOdd, X ); dSdU=dSdU+force;
|
||||
|
||||
// - phi^dag V (Mdag M)^-1 Mdag dM (Mdag M)^-1 V^dag phi
|
||||
// - phi^dag V (Mdag M)^-1 dMdag M (Mdag M)^-1 V^dag phi
|
||||
Mpc.MpcDeriv(force,Y,X); dSdU=dSdU-force;
|
||||
Mpc.MpcDagDeriv(force,X,Y); dSdU=dSdU-force;
|
||||
|
||||
dSdU = -Ta(dSdU);
|
||||
|
||||
};
|
||||
};
|
||||
}
|
||||
}
|
||||
#endif
|
||||
@ -1,10 +1,5 @@
|
||||
<<<<<<< HEAD
|
||||
#ifndef QCD_PSEUDOFERMION_TWO_FLAVOUR_RATIO_H
|
||||
#define QCD_PSEUDOFERMION_TWO_FLAVOUR_RATIO_H
|
||||
=======
|
||||
#ifndef QCD_PSEUDOFERMION_TWO_FLAVOUR_H
|
||||
#define QCD_PSEUDOFERMION_TWO_FLAVOUR_H
|
||||
>>>>>>> ef6a9e6b07b80aea909c0a62f223fa3e66f53b3a
|
||||
|
||||
namespace Grid{
|
||||
namespace QCD{
|
||||
@ -107,7 +102,6 @@ namespace Grid{
|
||||
|
||||
FermionField X(NumOp.FermionGrid());
|
||||
FermionField Y(NumOp.FermionGrid());
|
||||
FermionField f1(NumOp.FermionGrid());
|
||||
|
||||
GaugeField force(NumOp.GaugeGrid());
|
||||
|
||||
@ -130,8 +124,8 @@ namespace Grid{
|
||||
// - phi^dag V (Mdag M)^-1 dMdag M (Mdag M)^-1 V^dag phi
|
||||
DenOp.MDeriv(force,Y,X,DaggerNo); dSdU=dSdU-force;
|
||||
DenOp.MDeriv(force,X,Y,DaggerYes); dSdU=dSdU-force;
|
||||
dSdU = - dSdU;
|
||||
dSdU = Ta(dSdU);
|
||||
|
||||
dSdU = - Ta(dSdU);
|
||||
|
||||
};
|
||||
};
|
||||
|
||||
Reference in New Issue
Block a user