// // ******************************************************************** // * License and Disclaimer * // * * // * The Geant4 software is copyright of the Copyright Holders of * // * the Geant4 Collaboration. It is provided under the terms and * // * conditions of the Geant4 Software License, included in the file * // * LICENSE and available at http://cern.ch/geant4/license . These * // * include a list of copyright holders. * // * * // * Neither the authors of this software system, nor their employing * // * institutes,nor the agencies providing financial support for this * // * work make any representation or warranty, express or implied, * // * regarding this software system or assume any liability for its * // * use. Please see the license in the file LICENSE and URL above * // * for the full disclaimer and the limitation of liability. * // * * // * This code implementation is the result of the scientific and * // * technical work of the GEANT4 collaboration. * // * By using, copying, modifying or distributing the software (or * // * any work based on the software) you agree to acknowledge its * // * use in resulting scientific publications, and indicate your * // * acceptance of all terms of the Geant4 Software license. * // ******************************************************************** // // INCL++ intra-nuclear cascade model // Pekka Kaitaniemi, CEA and Helsinki Institute of Physics // Davide Mancusi, CEA // Alain Boudard, CEA // Sylvie Leray, CEA // Joseph Cugnon, University of Liege // // INCL++ revision: v5.0_rc3 // #define INCLXX_IN_GEANT4_MODE 1 #include "globals.hh" #ifndef G4INCLConfig_hh #define G4INCLConfig_hh 1 #include "G4INCLParticleType.hh" #include "G4INCLConfigEnums.hh" #include "G4INCLIRandomGenerator.hh" #include #include #include namespace G4INCL { /** * The INCL configuration object * * The Config object keeps track of various INCL physics options * (e.g. which Pauli blocking scheme to use, whether to use local * energy option or not, etc. */ class Config { public: /// \brief Default constructor Config(); /** * Constructor for INCL++ with specified target A, Z, projectile * type and energy. All other options are the default ones. */ Config(G4int, G4int, ParticleType, G4double); /** \brief Constructor based on command-line and config-file options. * * \param argc command-line parameters * \param argv command-line parameters * \param isFullRun is this a real calculation: true = yes; false = no, it's just a unit test */ Config(G4int argc, char *argv[], G4bool isFullRun); /// \brief Default destructor ~Config(); /// \brief Return a summary of the run configuration. std::string summary(); /// \brief Get the verbosity. G4int getVerbosity() const { return verbosity; } /// \brief Get the run title. std::string const &getCalculationTitle() const { return title; } /// \brief Get the output file root. std::string const &getOutputFileRoot() const { return outputFileRoot; } /// \brief Get the number of shots. G4int getNumberOfShots() const { return nShots; } /// \brief Natural targets. G4bool isNaturalTarget() const { return naturalTarget; } /** \brief Get the target mass number. * * Note that A==0 means natural target. You should first check the * isNaturalTarget() method. */ G4int getTargetA() const { return targetA; } /// \brief Get the target charge number. G4int getTargetZ() const { return targetZ; } /// \brief Set target mass number void setTargetA(G4int A) { targetA = A; } /// \brief Set target charge number void setTargetZ(G4int Z) { targetZ = Z; } /// \brief Get the projectile type. ParticleType getProjectileType() const { return projectileType; } /// \brief Get the projectile kinetic energy. G4float getProjectileKineticEnergy() const { return projectileKineticEnergy; } /// \brief Get the number of the verbose event. G4int getVerboseEvent() const { return verboseEvent; } /// \brief Get the INCL version ID. static std::string const getVersionID(); /// \brief Get the seeds for the random-number generator. SeedVector const getRandomSeeds() const { SeedVector s; s.push_back(randomSeed1); s.push_back(randomSeed2); return s; } /// \brief Get the Pauli-blocking algorithm. PauliType getPauliType() const { return pauliType; } /// \brief Do we want CDPP? G4bool getCDPP() const { return CDPP; } /// \brief Do we want the pion potential? G4bool getPionPotential() const { return pionPotential; } /// \brief Get the Coulomb-distortion algorithm. CoulombType getCoulombType() const { return coulombType; } /// \brief Get the type of the potential for nucleons. PotentialType getPotentialType() const { return potentialType; } /// \brief Set the type of the potential for nucleons. void setPotentialType(PotentialType type) { potentialType = type; } /// \brief Set the type of the potential for nucleons. void setPionPotential(const G4bool pionPot) { pionPotential = pionPot; } /// \brief Get the type of local energy for N-N avatars. LocalEnergyType getLocalEnergyBBType() const { return localEnergyBBType; } /// \brief Get the type of local energy for pi-N and decay avatars. LocalEnergyType getLocalEnergyPiType() const { return localEnergyPiType; } /// \brief Get the log file name. std::string const &getLogFileName() const { return logFileName; } /// \brief Get the de-excitation model. DeExcitationType getDeExcitationType() const { return deExcitationType; } /// \brief Get the clustering algorithm. ClusterAlgorithmType getClusterAlgorithm() const { return clusterAlgorithmType; } /// \brief Get the maximum mass for production of clusters. G4int getClusterMaxMass() const { return clusterMaxMass; } /// \brief Get back-to-spectator G4bool getBackToSpectator() const { return backToSpectator; } /// \brief Get back-to-spectator G4float getBackToSpectatorThreshold() const { return backToSpectatorThreshold; } /// \brief Echo the input options. std::string const echo() const; std::string const &getABLAv3pCxxDataFilePath() const { return ablav3pCxxDataFilePath; } std::string const &getABLA07DataFilePath() const { return abla07DataFilePath; } private: G4int verbosity; std::string inputFileName; std::string title; std::string outputFileRoot; std::string logFileName; G4int nShots; G4int targetA, targetZ; G4bool naturalTarget; std::string projectileString; ParticleType projectileType; G4float projectileKineticEnergy; G4int verboseEvent; G4int randomSeed1, randomSeed2; std::string pauliString; PauliType pauliType; G4bool CDPP; std::string coulombString; CoulombType coulombType; std::string potentialString; PotentialType potentialType; G4bool pionPotential; std::string localEnergyBBString; LocalEnergyType localEnergyBBType; std::string localEnergyPiString; LocalEnergyType localEnergyPiType; std::string deExcitationString; DeExcitationType deExcitationType; std::string ablav3pCxxDataFilePath; std::string abla07DataFilePath; std::string clusterAlgorithmString; ClusterAlgorithmType clusterAlgorithmType; G4int clusterMaxMass; G4bool backToSpectator; G4float backToSpectatorThreshold; }; } #endif