Grid/tests/hadrons/Test_hadrons_wilsonFund.cc

/*******************************************************************************
 Grid physics library, www.github.com/paboyle/Grid
 
 Source file: tests/hadrons/Test_hadrons_spectrum.cc
 
 Copyright (C) 2015
 
 Author: Antonin Portelli <antonin.portelli@me.com>
 
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2 of the License, or
 (at your option) any later version.
 
 This program is distributed in the hope that it will be useful,
 but WITHOUT ANY WARRANTY; without even the implied warranty of
 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 GNU General Public License for more details.
 
 You should have received a copy of the GNU General Public License along
 with this program; if not, write to the Free Software Foundation, Inc.,
 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 
 See the full license in the file "LICENSE" in the top level distribution
 directory.
 *******************************************************************************/

#include <Grid/Hadrons/Application.hpp>

using namespace Grid;
using namespace Hadrons;

int main(int argc, char *argv[])
{
    // initialization //////////////////////////////////////////////////////////
    Grid_init(&argc, &argv);
    HadronsLogError.Active(GridLogError.isActive());
    HadronsLogWarning.Active(GridLogWarning.isActive());
    HadronsLogMessage.Active(GridLogMessage.isActive());
    HadronsLogIterative.Active(GridLogIterative.isActive());
    HadronsLogDebug.Active(GridLogDebug.isActive());
    LOG(Message) << "Grid initialized" << std::endl;
    
    // run setup ///////////////////////////////////////////////////////////////
    Application              application;
    std::vector<std::string> flavour = {"l"};
    std::vector<double>      mass    = {-0.1};
    double                   csw     = 0.0;
    
    // global parameters
    Application::GlobalPar globalPar;
  
    globalPar.trajCounter.start = 1;
    globalPar.trajCounter.end   = 2;
    globalPar.trajCounter.step  = 1;

    globalPar.trajCounter.start = 309;
    globalPar.trajCounter.end   = 310;
    globalPar.trajCounter.step  = 1;
    globalPar.seed              = "1 2 3 4";
    application.setPar(globalPar);
    // gauge field
    application.createModule<MGauge::Load>("gauge");
   //application.createModule<MGauge::Unit>("gauge");
   
    // sources
    //MSource::Z2::Par z2Par;
    //z2Par.tA = 0;
    //z2Par.tB = 0;
    //application.createModule<MSource::Z2>("z2", z2Par);
    MSource::Point::Par ptPar;
    ptPar.position = "0 0 0 0";
    application.createModule<MSource::Point>("pt", ptPar);
    // sink
    MSink::Point::Par sinkPar;
    sinkPar.mom = "0 0 0";
    application.createModule<MSink::ScalarPoint>("sink", sinkPar);
    
    // set fermion boundary conditions to be periodic space, antiperiodic time.
    std::string boundary = "1 1 1 -1";

    for (unsigned int i = 0; i < flavour.size(); ++i)
    {
        // actions
        MAction::WilsonClover::Par actionPar;
        actionPar.gauge = "gauge";
        actionPar.mass  = mass[i];
        actionPar.boundary = boundary;
        actionPar.csw_r = csw;
        actionPar.csw_t = csw;

        // !!!!! Check if Anisotropy works  !!!!!
        actionPar.clover_anisotropy.isAnisotropic= false;
        actionPar.clover_anisotropy.t_direction  = 3    ;   // Explicit for D=4
        actionPar.clover_anisotropy.xi_0         = 1.0  ;
        actionPar.clover_anisotropy.nu           = 1.0  ;

        application.createModule<MAction::WilsonClover>("WilsonClover_" + flavour[i], actionPar);
        
        // solvers
        MSolver::RBPrecCG::Par solverPar;
        solverPar.action   = "WilsonClover_" + flavour[i];
        solverPar.residual = 1.0e-8;
        application.createModule<MSolver::RBPrecCG>("CG_" + flavour[i],
                                                    solverPar);
        
        // propagators
        MFermion::GaugeProp::Par quarkPar;
        quarkPar.solver = "CG_" + flavour[i];
        quarkPar.source = "pt";
        application.createModule<MFermion::GaugeProp>("Qpt_" + flavour[i], quarkPar);
 //       quarkPar.source = "z2";
 //       application.createModule<MFermion::GaugeProp>("QZ2_" + flavour[i], quarkPar);
    }
    for (unsigned int i = 0; i < flavour.size(); ++i)
    for (unsigned int j = i; j < flavour.size(); ++j)
    {
        MContraction::Meson::Par mesPar;
        
        mesPar.output  = "Fund_mesons/pt_" + flavour[i] + flavour[j];
        mesPar.q1      = "Qpt_" + flavour[i];
        mesPar.q2      = "Qpt_" + flavour[j];
        mesPar.gammas  = "all";
        mesPar.sink    = "sink";
        application.createModule<MContraction::Meson>("meson_pt_"
                                                      + flavour[i] + flavour[j],
                                                      mesPar);
   //     mesPar.output  = "mesons/Z2_" + flavour[i] + flavour[j];
   //     mesPar.q1      = "QZ2_" + flavour[i];
   //     mesPar.q2      = "QZ2_" + flavour[j];
   //     mesPar.gammas  = "all";
   //     mesPar.sink    = "sink";
   //     application.createModule<MContraction::Meson>("meson_Z2_"
   //                                                   + flavour[i] + flavour[j],
   //                                                   mesPar);
    }
    for (unsigned int i = 0; i < flavour.size(); ++i)
    for (unsigned int j = i; j < flavour.size(); ++j)
    for (unsigned int k = j; k < flavour.size(); ++k)
    {
        MContraction::Baryon::Par barPar;
        
        barPar.output = "Fund_baryons/pt_" + flavour[i] + flavour[j] + flavour[k];
        barPar.q1     = "Qpt_" + flavour[i];
        barPar.q2     = "Qpt_" + flavour[j];
        barPar.q3     = "Qpt_" + flavour[k];
        application.createModule<MContraction::Baryon>(
            "baryon_pt_" + flavour[i] + flavour[j] + flavour[k], barPar);
    }
    
    // execution
    application.saveParameterFile("WilsonClover_spectrum.xml");
    application.run();
    
    // epilogue
    LOG(Message) << "Grid is finalizing now" << std::endl;
    Grid_finalize();
    
    return EXIT_SUCCESS;
}
Trying to fix a bug with SU4 mesons (still under investigation) 2018-01-06 14:57:38 +00:00			`/*******************************************************************************`
			`Grid physics library, www.github.com/paboyle/Grid`

			`Source file: tests/hadrons/Test_hadrons_spectrum.cc`

			`Copyright (C) 2015`

			`Author: Antonin Portelli <antonin.portelli@me.com>`

			`This program is free software; you can redistribute it and/or modify`
			`it under the terms of the GNU General Public License as published by`
			`the Free Software Foundation; either version 2 of the License, or`
			`(at your option) any later version.`

			`This program is distributed in the hope that it will be useful,`
			`but WITHOUT ANY WARRANTY; without even the implied warranty of`
			`MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the`
			`GNU General Public License for more details.`

			`You should have received a copy of the GNU General Public License along`
			`with this program; if not, write to the Free Software Foundation, Inc.,`
			`51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.`

			`See the full license in the file "LICENSE" in the top level distribution`
			`directory.`
			`*******************************************************************************/`

			`#include <Grid/Hadrons/Application.hpp>`

			`using namespace Grid;`
			`using namespace Hadrons;`

			`int main(int argc, char *argv[])`
			`{`
			`// initialization //////////////////////////////////////////////////////////`
			`Grid_init(&argc, &argv);`
			`HadronsLogError.Active(GridLogError.isActive());`
			`HadronsLogWarning.Active(GridLogWarning.isActive());`
			`HadronsLogMessage.Active(GridLogMessage.isActive());`
			`HadronsLogIterative.Active(GridLogIterative.isActive());`
			`HadronsLogDebug.Active(GridLogDebug.isActive());`
			`LOG(Message) << "Grid initialized" << std::endl;`

			`// run setup ///////////////////////////////////////////////////////////////`
			`Application application;`
			`std::vector<std::string> flavour = {"l"};`
			`std::vector<double> mass = {-0.1};`
			`double csw = 0.0;`

			`// global parameters`
			`Application::GlobalPar globalPar;`

			`globalPar.trajCounter.start = 1;`
			`globalPar.trajCounter.end = 2;`
			`globalPar.trajCounter.step = 1;`

			`globalPar.trajCounter.start = 309;`
			`globalPar.trajCounter.end = 310;`
			`globalPar.trajCounter.step = 1;`
			`globalPar.seed = "1 2 3 4";`
			`application.setPar(globalPar);`
			`// gauge field`
			`application.createModule<MGauge::Load>("gauge");`
			`//application.createModule<MGauge::Unit>("gauge");`

			`// sources`
			`//MSource::Z2::Par z2Par;`
			`//z2Par.tA = 0;`
			`//z2Par.tB = 0;`
			`//application.createModule<MSource::Z2>("z2", z2Par);`
			`MSource::Point::Par ptPar;`
			`ptPar.position = "0 0 0 0";`
			`application.createModule<MSource::Point>("pt", ptPar);`
			`// sink`
			`MSink::Point::Par sinkPar;`
			`sinkPar.mom = "0 0 0";`
			`application.createModule<MSink::ScalarPoint>("sink", sinkPar);`

			`// set fermion boundary conditions to be periodic space, antiperiodic time.`
			`std::string boundary = "1 1 1 -1";`

			`for (unsigned int i = 0; i < flavour.size(); ++i)`
			`{`
			`// actions`
			`MAction::WilsonClover::Par actionPar;`
			`actionPar.gauge = "gauge";`
			`actionPar.mass = mass[i];`
			`actionPar.boundary = boundary;`
			`actionPar.csw_r = csw;`
			`actionPar.csw_t = csw;`

			`// !!!!! Check if Anisotropy works !!!!!`
			`actionPar.clover_anisotropy.isAnisotropic= false;`
			`actionPar.clover_anisotropy.t_direction = 3 ; // Explicit for D=4`
			`actionPar.clover_anisotropy.xi_0 = 1.0 ;`
			`actionPar.clover_anisotropy.nu = 1.0 ;`

			`application.createModule<MAction::WilsonClover>("WilsonClover_" + flavour[i], actionPar);`

			`// solvers`
			`MSolver::RBPrecCG::Par solverPar;`
			`solverPar.action = "WilsonClover_" + flavour[i];`
			`solverPar.residual = 1.0e-8;`
			`application.createModule<MSolver::RBPrecCG>("CG_" + flavour[i],`
			`solverPar);`

			`// propagators`
			`MFermion::GaugeProp::Par quarkPar;`
			`quarkPar.solver = "CG_" + flavour[i];`
			`quarkPar.source = "pt";`
			`application.createModule<MFermion::GaugeProp>("Qpt_" + flavour[i], quarkPar);`
			`// quarkPar.source = "z2";`
			`// application.createModule<MFermion::GaugeProp>("QZ2_" + flavour[i], quarkPar);`
			`}`
			`for (unsigned int i = 0; i < flavour.size(); ++i)`
			`for (unsigned int j = i; j < flavour.size(); ++j)`
			`{`
			`MContraction::Meson::Par mesPar;`

			`mesPar.output = "Fund_mesons/pt_" + flavour[i] + flavour[j];`
			`mesPar.q1 = "Qpt_" + flavour[i];`
			`mesPar.q2 = "Qpt_" + flavour[j];`
			`mesPar.gammas = "all";`
			`mesPar.sink = "sink";`
			`application.createModule<MContraction::Meson>("meson_pt_"`
			`+ flavour[i] + flavour[j],`
			`mesPar);`
			`// mesPar.output = "mesons/Z2_" + flavour[i] + flavour[j];`
			`// mesPar.q1 = "QZ2_" + flavour[i];`
			`// mesPar.q2 = "QZ2_" + flavour[j];`
			`// mesPar.gammas = "all";`
			`// mesPar.sink = "sink";`
			`// application.createModule<MContraction::Meson>("meson_Z2_"`
			`// + flavour[i] + flavour[j],`
			`// mesPar);`
			`}`
			`for (unsigned int i = 0; i < flavour.size(); ++i)`
			`for (unsigned int j = i; j < flavour.size(); ++j)`
			`for (unsigned int k = j; k < flavour.size(); ++k)`
			`{`
			`MContraction::Baryon::Par barPar;`

			`barPar.output = "Fund_baryons/pt_" + flavour[i] + flavour[j] + flavour[k];`
			`barPar.q1 = "Qpt_" + flavour[i];`
			`barPar.q2 = "Qpt_" + flavour[j];`
			`barPar.q3 = "Qpt_" + flavour[k];`
			`application.createModule<MContraction::Baryon>(`
			`"baryon_pt_" + flavour[i] + flavour[j] + flavour[k], barPar);`
			`}`

			`// execution`
			`application.saveParameterFile("WilsonClover_spectrum.xml");`
			`application.run();`

			`// epilogue`
			`LOG(Message) << "Grid is finalizing now" << std::endl;`
			`Grid_finalize();`

			`return EXIT_SUCCESS;`
			`}`