#ifndef A2A_Vectors_hpp_ #define A2A_Vectors_hpp_ #include #include #include BEGIN_HADRONS_NAMESPACE //////////////////////////////// // A2A Modes //////////////////////////////// template class A2AModesSchurDiagTwo { private: const std::vector *evec; const std::vector *eval; Matrix &action; Solver &solver; const int Nl, Nh; const bool return_5d; std::vector w_high_5d, v_high_5d, w_high_4d, v_high_4d; public: A2AModesSchurDiagTwo(const std::vector *_evec, const std::vector *_eval, Matrix &_action, Solver &_solver, const int _Nl, const int _Nh, const bool _return_5d) : evec(_evec), eval(_eval), action(_action), solver(_solver), Nl(_Nl), Nh(_Nh), return_5d(_return_5d) { init_resize(1, Nh); if (return_5d) init_resize(Nh, Nh); }; void init_resize(const size_t size_5d, const size_t size_4d) { GridBase *grid_5d = action.Grid(); GridBase *grid_4d = action.GaugeGrid(); w_high_5d.resize(size_5d, grid_5d); v_high_5d.resize(size_5d, grid_5d); w_high_4d.resize(size_4d, grid_4d); v_high_4d.resize(size_4d, grid_4d); } void high_modes(Field &source_5d, Field &w_source_5d, Field &source_4d, int i) { int i5d; LOG(Message) << "A2A high modes for i = " << i << std::endl; i5d = 0; if (return_5d) i5d = i; this->high_mode_v(action, solver, source_5d, v_high_5d[i5d], v_high_4d[i]); this->high_mode_w(w_source_5d, source_4d, w_high_5d[i5d], w_high_4d[i]); } void return_v(int i, Field &vout_5d, Field &vout_4d) { if (i < Nl) { this->low_mode_v(action, evec->at(i), eval->at(i), vout_5d, vout_4d); } else { vout_4d = v_high_4d[i - Nl]; if (!(return_5d)) i = Nl; vout_5d = v_high_5d[i - Nl]; } } void return_w(int i, Field &wout_5d, Field &wout_4d) { if (i < Nl) { this->low_mode_w(action, evec->at(i), eval->at(i), wout_5d, wout_4d); } else { wout_4d = w_high_4d[i - Nl]; if (!(return_5d)) i = Nl; wout_5d = w_high_5d[i - Nl]; } } void low_mode_v(Matrix &action, const Field &evec, const RealD &eval, Field &vout_5d, Field &vout_4d) { GridBase *grid = action.RedBlackGrid(); Field src_o(grid); Field sol_e(grid); Field sol_o(grid); Field tmp(grid); src_o = evec; src_o.checkerboard = Odd; pickCheckerboard(Even, sol_e, vout_5d); pickCheckerboard(Odd, sol_o, vout_5d); ///////////////////////////////////////////////////// // v_ie = -(1/eval_i) * MeeInv Meo MooInv evec_i ///////////////////////////////////////////////////// action.MooeeInv(src_o, tmp); assert(tmp.checkerboard == Odd); action.Meooe(tmp, sol_e); assert(sol_e.checkerboard == Even); action.MooeeInv(sol_e, tmp); assert(tmp.checkerboard == Even); sol_e = (-1.0 / eval) * tmp; assert(sol_e.checkerboard == Even); ///////////////////////////////////////////////////// // v_io = (1/eval_i) * MooInv evec_i ///////////////////////////////////////////////////// action.MooeeInv(src_o, tmp); assert(tmp.checkerboard == Odd); sol_o = (1.0 / eval) * tmp; assert(sol_o.checkerboard == Odd); setCheckerboard(vout_5d, sol_e); assert(sol_e.checkerboard == Even); setCheckerboard(vout_5d, sol_o); assert(sol_o.checkerboard == Odd); action.ExportPhysicalFermionSolution(vout_5d, vout_4d); } void low_mode_w(Matrix &action, const Field &evec, const RealD &eval, Field &wout_5d, Field &wout_4d) { GridBase *grid = action.RedBlackGrid(); SchurDiagTwoOperator _HermOpEO(action); Field src_o(grid); Field sol_e(grid); Field sol_o(grid); Field tmp(grid); GridBase *fgrid = action.Grid(); Field tmp_wout(fgrid); src_o = evec; src_o.checkerboard = Odd; pickCheckerboard(Even, sol_e, tmp_wout); pickCheckerboard(Odd, sol_o, tmp_wout); ///////////////////////////////////////////////////// // w_ie = - MeeInvDag MoeDag Doo evec_i ///////////////////////////////////////////////////// _HermOpEO.Mpc(src_o, tmp); assert(tmp.checkerboard == Odd); action.MeooeDag(tmp, sol_e); assert(sol_e.checkerboard == Even); action.MooeeInvDag(sol_e, tmp); assert(tmp.checkerboard == Even); sol_e = (-1.0) * tmp; ///////////////////////////////////////////////////// // w_io = Doo evec_i ///////////////////////////////////////////////////// _HermOpEO.Mpc(src_o, sol_o); assert(sol_o.checkerboard == Odd); setCheckerboard(tmp_wout, sol_e); assert(sol_e.checkerboard == Even); setCheckerboard(tmp_wout, sol_o); assert(sol_o.checkerboard == Odd); action.DminusDag(tmp_wout, wout_5d); action.ExportPhysicalFermionSource(wout_5d, wout_4d); } void high_mode_v(Matrix &action, Solver &solver, const Field &source, Field &vout_5d, Field &vout_4d) { GridBase *fgrid = action.Grid(); solver(vout_5d, source); // Note: solver is solver(out, in) action.ExportPhysicalFermionSolution(vout_5d, vout_4d); } void high_mode_w(const Field &w_source_5d, const Field &source_4d, Field &wout_5d, Field &wout_4d) { wout_5d = w_source_5d; wout_4d = source_4d; } }; // TODO: A2A for coarse eigenvectors // template // class A2ALMSchurDiagTwoCoarse : public A2AModesSchurDiagTwo // { // private: // const std::vector &subspace; // const std::vector &evec_coarse; // const std::vector &eval_coarse; // Matrix &action; // public: // A2ALMSchurDiagTwoCoarse(const std::vector &_subspace, const std::vector &_evec_coarse, const std::vector &_eval_coarse, Matrix &_action) // : subspace(_subspace), evec_coarse(_evec_coarse), eval_coarse(_eval_coarse), action(_action){}; // void operator()(int i, FineField &vout, FineField &wout) // { // FineField prom_evec(subspace[0]._grid); // blockPromote(evec_coarse[i], prom_evec, subspace); // this->low_mode_v(action, prom_evec, eval_coarse[i], vout); // this->low_mode_w(action, prom_evec, eval_coarse[i], wout); // } // }; END_HADRONS_NAMESPACE #endif // A2A_Vectors_hpp_