df/dec/G4INCLConfig_8cc_source.html

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//

// INCL++ intra-nuclear cascade model

// Alain Boudard, CEA-Saclay, France

// Joseph Cugnon, University of Liege, Belgium

// Jean-Christophe David, CEA-Saclay, France

// Pekka Kaitaniemi, CEA-Saclay, France, and Helsinki Institute of Physics, Finland

// Sylvie Leray, CEA-Saclay, France

// Davide Mancusi, CEA-Saclay, France

//

#define INCLXX_IN_GEANT4_MODE 1


#include "globals.hh"


#include "G4INCLParticleType.hh"

#include "G4INCLConfig.hh"

#include "G4INCLParticleSpecies.hh"

#include "G4INCLParticleTable.hh"


namespace G4INCL {


  Config::Config() {

    init();

  }


  Config::~Config() {}


  void Config::init() {

    verbosity = 1;

    logFileName = "-";

    inputFileName = "";

    title = "INCL default run title";

    nShots = 1000;

    naturalTarget = false;

    projectileString = "proton";

    projectileSpecies = G4INCL::Proton;

    projectileKineticEnergy = 1000.0;

    verboseEvent = -1;

    randomSeeds = "";

    randomSeedVector.push_back(666);

    randomSeedVector.push_back(777);

    randomSeedVector.push_back(1234);

    pauliString = "strict-statistical";

    pauliType = StrictStatisticalPauli;

    CDPP = true;

    coulombString = "non-relativistic";

    coulombType = NonRelativisticCoulomb;

    potentialString = "isospin-energy";

    potentialType = IsospinEnergyPotential;

    pionPotential = true;

    localEnergyBBString = "first-collision";

    localEnergyBBType = FirstCollisionLocalEnergy;

    localEnergyPiString = "first-collision";

    localEnergyPiType = FirstCollisionLocalEnergy;

    deExcitationString = "none";

    deExcitationType = DeExcitationNone;

    clusterAlgorithmString = "intercomparison";

    clusterAlgorithmType = IntercomparisonClusterAlgorithm;

    clusterMaxMass = 8;

    backToSpectator = true;

    useRealMasses = true;

    impactParameter = -1.;

    separationEnergyString = "INCL";

    separationEnergyType = INCLSeparationEnergy;

    fermiMomentumString = "constant";

    fermiMomentumType = ConstantFermiMomentum;

    fermiMomentum = -1.;

    cutNN = 1910.;

#ifdef INCL_DEEXCITATION_FERMI_BREAKUP

    maxMassFermiBreakUp = 16;

    maxChargeFermiBreakUp = 8;

#endif

    rpCorrelationCoefficient = 0.98;

    rpCorrelationCoefficientProton = 0.5;

    rpCorrelationCoefficientNeutron = 0.73;

    neutronSkin = 0.;

    neutronHalo = 0.;

    refraction=false;

    phaseSpaceGenerator = "Raubold-Lynch";

    phaseSpaceGeneratorType = RauboldLynchType;

    cascadeAction = "default";

    cascadeActionType = DefaultActionType;

    randomNumberGenerator = "Ranecu";

    rngType = RanecuType;

    autosaveFrequency = 10000;

    maxNumberMultipions = -1;

    crossSectionsString = "strangeness";

    crossSectionsType = StrangenessCrossSections;

    hadronizationTime = 0.;

#ifdef INCL_ROOT_USE

    conciseROOTTree = false;

#endif

    inverseKinematics = false;

    decayTimeThreshold = 1.e-20;

    bias = 1.;

  }


  std::string Config::summary() {

    std::stringstream message;

    message << "INCL++ version " << getVersionString() << '\n';

    if(projectileSpecies.theType != Composite)

      message << "Projectile: " << ParticleTable::getName(projectileSpecies) << '\n';

    else

      message << "Projectile: composite, A=" << projectileSpecies.theA << ", Z=" << projectileSpecies.theZ << ", S=" << projectileSpecies.theS << '\n';

    message << "  energy = " << projectileKineticEnergy << '\n';

    if(targetSpecies.theA>0)

      message << "Target: A = " << targetSpecies.theA << " Z = " << targetSpecies.theZ << " S = " << targetSpecies.theS << '\n';

    else

      message << "Target: natural isotopic composition, Z = " << targetSpecies.theZ << '\n';

    message << "Number of requested shots = " << nShots << '\n';

    return message.str();

  }


}