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422 lines
15 KiB
C++
422 lines
15 KiB
C++
/*************************************************************************************
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Grid physics library, www.github.com/paboyle/Grid
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Source file: ./tests/Test_hmc_EODWFRatio.cc
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Copyright (C) 2015-2016
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Author: Peter Boyle <pabobyle@ph.ed.ac.uk>
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Author: Guido Cossu <guido.cossu@ed.ac.uk>
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This program is free software; you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation; either version 2 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License along
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with this program; if not, write to the Free Software Foundation, Inc.,
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51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
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See the full license in the file "LICENSE" in the top level distribution
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directory
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*************************************************************************************/
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/* END LEGAL */
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#include <Grid/Grid.h>
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int main(int argc, char **argv) {
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using namespace Grid;
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Grid_init(&argc, &argv);
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int threads = GridThread::GetThreads();
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// Typedefs to simplify notation
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typedef WilsonImplR FermionImplPolicy;
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typedef MobiusFermionD FermionAction;
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typedef typename FermionAction::FermionField FermionField;
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typedef Grid::XmlReader Serialiser;
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//::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::
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IntegratorParameters MD;
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// typedef GenericHMCRunner<LeapFrog> HMCWrapper;
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// MD.name = std::string("Leap Frog");
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// typedef GenericHMCRunner<ForceGradient> HMCWrapper;
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// MD.name = std::string("Force Gradient");
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typedef GenericHMCRunner<MinimumNorm2> HMCWrapper;
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MD.name = std::string("MinimumNorm2");
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MD.MDsteps = 6;
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MD.trajL = 1.0;
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HMCparameters HMCparams;
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HMCparams.StartTrajectory = 1077;
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HMCparams.Trajectories = 1;
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HMCparams.NoMetropolisUntil= 0;
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// "[HotStart, ColdStart, TepidStart, CheckpointStart]\n";
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// HMCparams.StartingType =std::string("ColdStart");
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HMCparams.StartingType =std::string("CheckpointStart");
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HMCparams.MD = MD;
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HMCWrapper TheHMC(HMCparams);
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// Grid from the command line arguments --grid and --mpi
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TheHMC.Resources.AddFourDimGrid("gauge"); // use default simd lanes decomposition
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CheckpointerParameters CPparams;
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CPparams.config_prefix = "ckpoint_DDHMC_lat";
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CPparams.rng_prefix = "ckpoint_DDHMC_rng";
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CPparams.saveInterval = 1;
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CPparams.format = "IEEE64BIG";
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TheHMC.Resources.LoadNerscCheckpointer(CPparams);
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RNGModuleParameters RNGpar;
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RNGpar.serial_seeds = "1 2 3 4 5";
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RNGpar.parallel_seeds = "6 7 8 9 10";
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TheHMC.Resources.SetRNGSeeds(RNGpar);
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// Construct observables
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// here there is too much indirection
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typedef PlaquetteMod<HMCWrapper::ImplPolicy> PlaqObs;
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TheHMC.Resources.AddObservable<PlaqObs>();
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//////////////////////////////////////////////
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const int Ls = 12;
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RealD M5 = 1.8;
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RealD b = 1.5;
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RealD c = 0.5;
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// Real beta = 2.31;
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// Real light_mass = 5.4e-4;
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Real beta = 2.13;
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Real light_mass = 7.8e-4;
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Real strange_mass = 0.02132;
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Real pv_mass = 1.0;
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// std::vector<Real> hasenbusch({ light_mass, 3.8e-3, 0.0145, 0.045, 0.108, 0.25, 0.51 , pv_mass });
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std::vector<Real> hasenbusch({ light_mass, 0.0145, 0.045, 0.108, 0.25, 0.51 , pv_mass });
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// FIXME:
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// Same in MC and MD
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// Need to mix precision too
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OneFlavourRationalParams SFRp; // Strange
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SFRp.lo = 4.0e-3;
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SFRp.hi = 90.0;
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SFRp.MaxIter = 60000;
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SFRp.tolerance= 1.0e-8;
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SFRp.mdtolerance= 1.0e-4;
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SFRp.degree = 12;
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SFRp.precision= 50;
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SFRp.BoundsCheckFreq=0;
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OneFlavourRationalParams OFRp; // Up/down
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OFRp.lo = 2.0e-5;
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OFRp.hi = 90.0;
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OFRp.MaxIter = 60000;
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OFRp.tolerance= 1.0e-7;
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OFRp.mdtolerance= 1.0e-4;
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// OFRp.degree = 20; converges
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// OFRp.degree = 16;
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OFRp.degree = 12;
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OFRp.precision= 80;
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OFRp.BoundsCheckFreq=0;
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auto GridPtr = TheHMC.Resources.GetCartesian();
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auto GridRBPtr = TheHMC.Resources.GetRBCartesian();
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////////////////////////////////////////////////////////////////
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// Domain decomposed
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////////////////////////////////////////////////////////////////
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Coordinate latt4 = GridPtr->GlobalDimensions();
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Coordinate mpi = GridPtr->ProcessorGrid();
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Coordinate shm;
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GlobalSharedMemory::GetShmDims(mpi,shm);
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Coordinate CommDim(Nd);
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for(int d=0;d<Nd;d++) CommDim[d]= (mpi[d]/shm[d])>1 ? 1 : 0;
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Coordinate NonDirichlet(Nd+1,0);
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Coordinate Dirichlet(Nd+1,0);
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Dirichlet[1] = CommDim[0]*latt4[0]/mpi[0] * shm[0];
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Dirichlet[2] = CommDim[1]*latt4[1]/mpi[1] * shm[1];
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Dirichlet[3] = CommDim[2]*latt4[2]/mpi[2] * shm[2];
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Dirichlet[4] = CommDim[3]*latt4[3]/mpi[3] * shm[3];
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Coordinate Block4(Nd);
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// Block4[0] = Dirichlet[1];
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// Block4[1] = Dirichlet[2];
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// Block4[2] = Dirichlet[3];
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Block4[0] = 0;
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Block4[1] = 0;
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Block4[2] = 0;
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Block4[3] = Dirichlet[4];
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int Width=3;
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TheHMC.Resources.SetMomentumFilter(new DDHMCFilter<WilsonImplR::Field>(Block4,Width));
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//////////////////////////
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// Fermion Grid
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//////////////////////////
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auto FGrid = SpaceTimeGrid::makeFiveDimGrid(Ls,GridPtr);
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auto FrbGrid = SpaceTimeGrid::makeFiveDimRedBlackGrid(Ls,GridPtr);
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IwasakiGaugeActionR GaugeAction(beta);
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// temporarily need a gauge field
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LatticeGaugeField U(GridPtr);
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std::cout << GridLogMessage << " Running the HMC "<< std::endl;
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TheHMC.ReadCommandLine(argc,argv); // params on CML or from param file
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TheHMC.initializeGaugeFieldAndRNGs(U);
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// These lines are unecessary if BC are all periodic
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std::vector<Complex> boundary = {1,1,1,-1};
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FermionAction::ImplParams Params(boundary);
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Params.dirichlet=NonDirichlet;
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FermionAction::ImplParams ParamsDir(boundary);
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ParamsDir.dirichlet=Dirichlet;
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// double StoppingCondition = 1e-14;
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// double MDStoppingCondition = 1e-9;
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double StoppingCondition = 1e-8;
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double MDStoppingCondition = 1e-6;
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double MaxCGIterations = 300000;
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ConjugateGradient<FermionField> CG(StoppingCondition,MaxCGIterations);
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ConjugateGradient<FermionField> MDCG(MDStoppingCondition,MaxCGIterations);
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////////////////////////////////////
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// Collect actions
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////////////////////////////////////
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ActionLevel<HMCWrapper::Field> Level1(1);
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ActionLevel<HMCWrapper::Field> Level2(4);
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ActionLevel<HMCWrapper::Field> Level3(8);
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////////////////////////////////////
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// Strange action
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////////////////////////////////////
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FermionAction StrangeOp (U,*FGrid,*FrbGrid,*GridPtr,*GridRBPtr,strange_mass,M5,b,c, Params);
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FermionAction StrangePauliVillarsOp(U,*FGrid,*FrbGrid,*GridPtr,*GridRBPtr,pv_mass, M5,b,c, Params);
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FermionAction StrangeOpDir (U,*FGrid,*FrbGrid,*GridPtr,*GridRBPtr,strange_mass,M5,b,c, ParamsDir);
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FermionAction StrangePauliVillarsOpDir(U,*FGrid,*FrbGrid,*GridPtr,*GridRBPtr,pv_mass, M5,b,c, ParamsDir);
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OneFlavourEvenOddRatioRationalPseudoFermionAction<FermionImplPolicy> StrangePseudoFermionBdy(StrangeOpDir,StrangeOp,SFRp);
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OneFlavourEvenOddRatioRationalPseudoFermionAction<FermionImplPolicy> StrangePseudoFermionLocal(StrangePauliVillarsOpDir,StrangeOpDir,SFRp);
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OneFlavourEvenOddRatioRationalPseudoFermionAction<FermionImplPolicy> StrangePseudoFermionPVBdy(StrangePauliVillarsOp,StrangePauliVillarsOpDir,SFRp);
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Level1.push_back(&StrangePseudoFermionBdy);
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Level2.push_back(&StrangePseudoFermionLocal);
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Level1.push_back(&StrangePseudoFermionPVBdy);
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////////////////////////////////////
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// up down action
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////////////////////////////////////
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std::vector<Real> light_den;
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std::vector<Real> light_num;
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std::vector<int> dirichlet_den;
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std::vector<int> dirichlet_num;
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int n_hasenbusch = hasenbusch.size();
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light_den.push_back(light_mass); dirichlet_den.push_back(0);
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for(int h=0;h<n_hasenbusch;h++){
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light_den.push_back(hasenbusch[h]); dirichlet_den.push_back(1);
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}
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for(int h=0;h<n_hasenbusch;h++){
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light_num.push_back(hasenbusch[h]); dirichlet_num.push_back(1);
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}
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light_num.push_back(pv_mass); dirichlet_num.push_back(0);
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std::vector<FermionAction *> Numerators;
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std::vector<FermionAction *> Denominators;
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std::vector<TwoFlavourEvenOddRatioPseudoFermionAction<FermionImplPolicy> *> Quotients;
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std::vector<OneFlavourEvenOddRatioRationalPseudoFermionAction<FermionImplPolicy> *> Bdys;
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for(int h=0;h<n_hasenbusch+1;h++){
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std::cout << GridLogMessage
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<< " 2f quotient Action ";
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std::cout << "det D("<<light_den[h]<<")";
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if ( dirichlet_den[h] ) std::cout << "^dirichlet ";
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std::cout << "/ det D("<<light_num[h]<<")";
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if ( dirichlet_num[h] ) std::cout << "^dirichlet ";
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std::cout << std::endl;
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FermionAction::ImplParams ParamsNum(boundary);
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FermionAction::ImplParams ParamsDen(boundary);
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if ( dirichlet_num[h]==1) ParamsNum.dirichlet = Dirichlet;
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else ParamsNum.dirichlet = NonDirichlet;
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Numerators.push_back (new FermionAction(U,*FGrid,*FrbGrid,*GridPtr,*GridRBPtr,light_num[h],M5,b,c, ParamsNum));
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if ( dirichlet_den[h]==1) ParamsDen.dirichlet = Dirichlet;
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else ParamsDen.dirichlet = NonDirichlet;
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Denominators.push_back(new FermionAction(U,*FGrid,*FrbGrid,*GridPtr,*GridRBPtr,light_den[h],M5,b,c, ParamsDen));
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if(h!=0) {
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Quotients.push_back (new TwoFlavourEvenOddRatioPseudoFermionAction<FermionImplPolicy>(*Numerators[h],*Denominators[h],MDCG,CG));
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} else {
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Bdys.push_back( new OneFlavourEvenOddRatioRationalPseudoFermionAction<FermionImplPolicy>(*Numerators[h],*Denominators[h],OFRp));
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Bdys.push_back( new OneFlavourEvenOddRatioRationalPseudoFermionAction<FermionImplPolicy>(*Numerators[h],*Denominators[h],OFRp));
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}
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}
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int nquo=Quotients.size();
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Level1.push_back(Bdys[0]);
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Level1.push_back(Bdys[1]);
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for(int h=0;h<nquo-1;h++){
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Level2.push_back(Quotients[h]);
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}
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Level2.push_back(Quotients[nquo-1]);
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/////////////////////////////////////////////////////////////
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// Gauge action
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/////////////////////////////////////////////////////////////
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Level3.push_back(&GaugeAction);
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TheHMC.TheAction.push_back(Level1);
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TheHMC.TheAction.push_back(Level2);
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TheHMC.TheAction.push_back(Level3);
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std::cout << GridLogMessage << " Action complete "<< std::endl;
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/////////////////////////////////////////////////////////////
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if(1){
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// TODO:
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// i) Break high bound, how rapidly does it break? Tune this test.
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// ii) Break low bound, how rapidly?
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// iii) Run lanczos
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// iv) Have CG return spectral range estimate
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FermionField vec(StrangeOp.FermionRedBlackGrid());
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FermionField res(StrangeOp.FermionRedBlackGrid());
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vec = 1; // Fill with any old junk
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std::cout << "Bounds check on strange operator mass "<< StrangeOp.Mass()<<std::endl;
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SchurDifferentiableOperator<FermionImplPolicy> SdagS(StrangeOp);
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HighBoundCheck(SdagS,vec,SFRp.hi);
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ChebyBoundsCheck(SdagS,vec,SFRp.lo,SFRp.hi);
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std::cout << "Strange inversion"<<std::endl;
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res=Zero();
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// MDCG(SdagS,vec,res);
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vec = 1; // Fill with any old junk
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std::cout << "Bounds check on light quark operator mass "<< Denominators[0]->Mass() <<std::endl;
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SchurDifferentiableOperator<FermionImplPolicy> UdagU(*Denominators[0]);
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HighBoundCheck(UdagU,vec,OFRp.hi);
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ChebyBoundsCheck(UdagU,vec,OFRp.lo,OFRp.hi);
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std::cout << "light inversion"<<std::endl;
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res=Zero();
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// MDCG(UdagU,vec,res);
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vec = 1; // Fill with any old junk
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std::cout << "Bounds check on strange dirichlet operator mass "<< StrangeOpDir.Mass()<<std::endl;
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SchurDifferentiableOperator<FermionImplPolicy> SddagSd(StrangeOpDir);
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HighBoundCheck(SddagSd,vec,SFRp.hi);
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ChebyBoundsCheck(SddagSd,vec,SFRp.lo,SFRp.hi);
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std::cout << "strange dirichlet inversion"<<std::endl;
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res=Zero();
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// MDCG(SddagSd,vec,res);
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vec = 1; // Fill with any old junk
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std::cout << "Bounds check on light dirichlet operator mass "<< Numerators[0]->Mass()<<std::endl;
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SchurDifferentiableOperator<FermionImplPolicy> UddagUd(*Numerators[0]);
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HighBoundCheck(UddagUd,vec,OFRp.hi);
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ChebyBoundsCheck(UddagUd,vec,OFRp.lo,OFRp.hi);
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std::cout << "light dirichlet inversion"<<std::endl;
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res=Zero();
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//MDCG(UddagUd,vec,res);
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auto grid4= GridPtr;
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auto rbgrid = StrangeOp.FermionRedBlackGrid();
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auto grid = StrangeOp.FermionGrid();
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if(1){
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const int Nstop = 5;
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const int Nk = 20;
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const int Np = 20;
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const int Nm = Nk+Np;
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const int MaxIt= 10000;
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int Nconv;
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RealD resid = 1.0e-5;
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if(1)
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{
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int order = 501;
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RealD bound = 5.0e-4;
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std::cout << GridLogMessage << " Lanczos for dirichlet bound " << bound<<" order "<< order<<std::endl;
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Chebyshev<FermionField> Cheby(bound,90.,order);
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FunctionHermOp<FermionField> OpCheby(Cheby,UddagUd);
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PlainHermOp<FermionField> Op (UddagUd);
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ImplicitlyRestartedLanczos<FermionField> IRL(OpCheby,Op,Nstop,Nk,Nm,resid,MaxIt);
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std::vector<RealD> eval(Nm);
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std::vector<FermionField> evec(Nm,rbgrid);
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FermionField src(rbgrid);src = 1.0;
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IRL.calc(eval,evec,src,Nconv);
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FermionField tmp(rbgrid);
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FermionField ftmp(grid);
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FermionField ftmp4(grid4);
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for(int ev=0;ev<evec.size();ev++){
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Gamma GT(Gamma::Algebra::GammaT);
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std::cout << " evec " << ev << std::endl;
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tmp = evec[ev] + GT*evec[ev];
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DumpSliceNorm(" 1+gammaT ",tmp,Nd);
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tmp = evec[ev] - GT*evec[ev];
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DumpSliceNorm(" 1-gammaT ",tmp,Nd);
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}
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for(int e=0;e<10;e++){
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std::cout << " Dirichlet evec "<<e<<std::endl;
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tmp = evec[e];
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for(int s=0;s<Ls;s++){
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ftmp=Zero();
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setCheckerboard(ftmp,tmp);
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ExtractSlice(ftmp4,ftmp,s,0);
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std::cout << "s-slice "<<s<< " evec[0] " << std::endl;
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DumpSliceNorm(" s-slice ",ftmp4,Nd-1);
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}
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}
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}
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if(1)
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{
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int order = 2001;
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RealD bound = 6.0e-5;
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std::cout << GridLogMessage << " Lanczos for full operator bound " << bound<<" order "<< order<<std::endl;
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Chebyshev<FermionField> Cheby(bound,90.,order);
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FunctionHermOp<FermionField> OpCheby(Cheby,UdagU);
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PlainHermOp<FermionField> Op (UdagU);
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ImplicitlyRestartedLanczos<FermionField> IRL(OpCheby,Op,Nstop,Nk,Nm,resid,MaxIt);
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std::vector<RealD> eval(Nm);
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std::vector<FermionField> evec(Nm,rbgrid);
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FermionField src(rbgrid); src = 1.0;
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IRL.calc(eval,evec,src,Nconv);
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FermionField tmp(rbgrid);
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FermionField ftmp(grid);
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FermionField ftmp4(grid4);
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for(int e=0;e<evec.size();e++){
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std::cout << " Full evec "<<e<<std::endl;
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tmp = evec[e];
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for(int s=0;s<Ls;s++){
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ftmp=Zero();
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setCheckerboard(ftmp,tmp);
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ExtractSlice(ftmp4,ftmp,s,0);
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std::cout << "s-slice "<<s<< " evec[0] " << std::endl;
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DumpSliceNorm(" s-slice ",ftmp4,Nd-1);
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}
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}
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}
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Grid_finalize();
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std::cout << " All done "<<std::endl;
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exit(EXIT_SUCCESS);
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}
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}
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TheHMC.Run(); // no smearing
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Grid_finalize();
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} // main
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