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Geant4/processes/hadronic/models/inclxx/utils/include/G4INCLParticleTable.hh

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Differences between /processes/hadronic/models/inclxx/utils/include/G4INCLParticleTable.hh (Version 11.3.0) and /processes/hadronic/models/inclxx/utils/include/G4INCLParticleTable.hh (Version 10.0.p2)

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  //                                                  //
  // INCL++ intra-nuclear cascade model               // INCL++ intra-nuclear cascade model
  // Alain Boudard, CEA-Saclay, France           <<   // Pekka Kaitaniemi, CEA and Helsinki Institute of Physics
  // Joseph Cugnon, University of Liege, Belgium <<   // Davide Mancusi, CEA
  // Jean-Christophe David, CEA-Saclay, France   <<   // Alain Boudard, CEA
  // Pekka Kaitaniemi, CEA-Saclay, France, and H <<   // Sylvie Leray, CEA
  // Sylvie Leray, CEA-Saclay, France            <<   // Joseph Cugnon, University of Liege
  // Davide Mancusi, CEA-Saclay, France          << 
  //                                                  //
  #define INCLXX_IN_GEANT4_MODE 1                     #define INCLXX_IN_GEANT4_MODE 1
                                                      
  #include "globals.hh"                               #include "globals.hh"
                                                      
  #ifndef G4INCLParticleTable_hh                      #ifndef G4INCLParticleTable_hh
  #define G4INCLParticleTable_hh 1                    #define G4INCLParticleTable_hh 1
                                                      
  #include <string>                                   #include <string>
  #include <vector>                                   #include <vector>
  // #include <cassert>                               // #include <cassert>
                                                      
  #include "G4INCLParticleType.hh"                    #include "G4INCLParticleType.hh"
  #include "G4INCLParticleSpecies.hh"                 #include "G4INCLParticleSpecies.hh"
  #include "G4INCLLogger.hh"                          #include "G4INCLLogger.hh"
  #include "G4INCLConfig.hh"                          #include "G4INCLConfig.hh"
  #include "G4INCLHFB.hh"                        << 
                                                      
  #ifdef INCLXX_IN_GEANT4_MODE                        #ifdef INCLXX_IN_GEANT4_MODE
  #include "G4IonTable.hh"                            #include "G4IonTable.hh"
  #include "G4ParticleTable.hh"                       #include "G4ParticleTable.hh"
  #endif                                              #endif
  #include "G4INCLGlobals.hh"                         #include "G4INCLGlobals.hh"
  #include "G4INCLNaturalIsotopicDistributions.h      #include "G4INCLNaturalIsotopicDistributions.hh"
                                                      
  namespace G4INCL {                                  namespace G4INCL {
                                                      
    namespace ParticleTable {                           namespace ParticleTable {
                                                      
      const G4int maxClusterMass = 12;                    const G4int maxClusterMass = 12;
      const G4int maxClusterCharge = 8;                   const G4int maxClusterCharge = 8;
                                                      
      const G4int clusterTableZSize = maxCluster          const G4int clusterTableZSize = maxClusterCharge+1;
      const G4int clusterTableASize = maxCluster          const G4int clusterTableASize = maxClusterMass+1;
      const G4int clusterTableSSize = 4;         << 
                                                      
      const G4double effectiveNucleonMass = 938.          const G4double effectiveNucleonMass = 938.2796;
      const G4double effectiveNucleonMass2 = 8.8          const G4double effectiveNucleonMass2 = 8.8036860777616e5;
      const G4double effectiveDeltaMass = 1232.0          const G4double effectiveDeltaMass = 1232.0;
      const G4double effectiveDeltaWidth = 130.0 << 
      const G4double effectivePionMass = 138.0;           const G4double effectivePionMass = 138.0;
      const G4double effectiveLambdaMass = 1115. <<       extern G4ThreadLocal G4double effectiveDeltaDecayThreshold;
      const G4double effectiveSigmaMass = 1197.4 << 
      const G4double effectiveXiMass = 1321.71;  << 
      const G4double effectiveKaonMass = 497.614 << 
      const G4double effectiveAntiKaonMass = 497 << 
      const G4double effectiveEtaMass = 547.862; << 
      const G4double effectiveOmegaMass = 782.65 << 
      const G4double effectiveEtaPrimeMass = 957 << 
      const G4double effectivePhotonMass = 0.0;  << 
      extern G4ThreadLocal G4double minDeltaMass << 
      extern G4ThreadLocal G4double minDeltaMass << 
      extern G4ThreadLocal G4double minDeltaMass << 
                                                      
      /// \brief Initialize the particle table            /// \brief Initialize the particle table
      void initialize(Config const * const theCo          void initialize(Config const * const theConfig = 0);
                                                      
      /// \brief Get the isospin of a particle            /// \brief Get the isospin of a particle
      G4int getIsospin(const ParticleType t);             G4int getIsospin(const ParticleType t);
                                                      
      /// \brief Get the native INCL name of the          /// \brief Get the native INCL name of the particle
      std::string getName(const ParticleType t);          std::string getName(const ParticleType t);
                                                      
      /// \brief Get the short INCL name of the           /// \brief Get the short INCL name of the particle
      std::string getShortName(const ParticleTyp          std::string getShortName(const ParticleType t);
                                                      
      /// \brief Get the native INCL name of the          /// \brief Get the native INCL name of the particle
     std::string getName(const ParticleSpecies           std::string getName(const ParticleSpecies &s);
                                                     
     /// \brief Get the short INCL name of the           /// \brief Get the short INCL name of the particle
     std::string getShortName(const ParticleSpe          std::string getShortName(const ParticleSpecies &s);
                                                     
     /// \brief Get the native INCL name of the          /// \brief Get the native INCL name of the ion
     std::string getName(const G4int A, const G          std::string getName(const G4int A, const G4int Z);
                                                     
     /// \brief Get the native INCL name of the << 
     std::string getName(const G4int A, const G << 
                                                << 
     /// \brief Get the short INCL name of the           /// \brief Get the short INCL name of the ion
     std::string getShortName(const G4int A, co          std::string getShortName(const G4int A, const G4int Z);
                                                     
     /// \brief Get INCL nuclear mass (in MeV/c          /// \brief Get INCL nuclear mass (in MeV/c^2)
     G4double getINCLMass(const G4int A, const  <<       G4double getINCLMass(const G4int A, const G4int Z);
                                                     
     /// \brief Get INCL particle mass (in MeV/          /// \brief Get INCL particle mass (in MeV/c^2)
     G4double getINCLMass(const ParticleType t)         G4double getINCLMass(const ParticleType t);
                                                    
 #ifndef INCLXX_IN_GEANT4_MODE                      #ifndef INCLXX_IN_GEANT4_MODE
     /// \brief Do we have this particle mass?          /// \brief Do we have this particle mass?
     G4double hasMassTable(const unsigned int A         G4double hasMassTable(const unsigned int A, const unsigned int Z);
                                                    
     /** \brief Weizsaecker mass formula                /** \brief Weizsaecker mass formula
      *                                                  *
      * Return the nuclear mass, as calculated           * Return the nuclear mass, as calculated from Weizsaecker's mass formula.
      * Adapted from the Geant4 source.                  * Adapted from the Geant4 source.
      *                                                  *
      * \param A the mass number                         * \param A the mass number
      * \param Z the charge number                       * \param Z the charge number
      * \return the nuclear mass [MeV/c^2]               * \return the nuclear mass [MeV/c^2]
      */                                                 */
     G4double getWeizsaeckerMass(const G4int A,         G4double getWeizsaeckerMass(const G4int A, const G4int Z);
 #endif                                             #endif
                                                    
     ///\brief Get particle mass (in MeV/c^2)           ///\brief Get particle mass (in MeV/c^2)
     G4double getRealMass(const G4INCL::Particl         G4double getRealMass(const G4INCL::ParticleType t);
     ///\brief Get nuclear mass (in MeV/c^2)            ///\brief Get nuclear mass (in MeV/c^2)
     G4double getRealMass(const G4int A, const  <<      G4double getRealMass(const G4int A, const G4int Z);
                                                    
     /**\brief Get Q-value (in MeV/c^2)                 /**\brief Get Q-value (in MeV/c^2)
      *                                                  *
      * Uses the getTableMass function to compu          * Uses the getTableMass function to compute the Q-value for the
      * following reaction:                              * following reaction:
      * \f[ (A_1,Z_1) + (A_2, Z_2) --> (A_1+A_2          * \f[ (A_1,Z_1) + (A_2, Z_2) --> (A_1+A_2,Z_1+Z_2) \f]
      */                                                 */
     G4double getTableQValue(const G4int A1, co <<      G4double getTableQValue(const G4int A1, const G4int Z1, const G4int A2, const G4int Z2);
                                                    
     /**\brief Get Q-value (in MeV/c^2)                 /**\brief Get Q-value (in MeV/c^2)
      *                                                  *
      * Uses the getTableMass function to compu          * Uses the getTableMass function to compute the Q-value for the
      * following reaction:                              * following reaction:
      * \f[ (A_1,Z_1) + (A_2, Z_2) --> (A_3,Z_3          * \f[ (A_1,Z_1) + (A_2, Z_2) --> (A_3,Z_3) + (A1+A2-A3,Z1+Z2-Z3) \f]
      */                                                 */
     G4double getTableQValue(const G4int A1, co <<      G4double getTableQValue(const G4int A1, const G4int Z1, const G4int A2, const G4int Z2, const G4int A3, const G4int Z3);
                                                    
     G4double getTableSpeciesMass(const Particl         G4double getTableSpeciesMass(const ParticleSpecies &p);
                                                    
     /// \brief Get mass number from particle t         /// \brief Get mass number from particle type
     G4int getMassNumber(const ParticleType t);         G4int getMassNumber(const ParticleType t);
                                                    
     /// \brief Get charge number from particle         /// \brief Get charge number from particle type
     G4int getChargeNumber(const ParticleType t         G4int getChargeNumber(const ParticleType t);
                                                << 
     /// \brief Get strangeness number from par << 
     G4int getStrangenessNumber(const ParticleT << 
                                                    
     G4double getNuclearRadius(const ParticleTy         G4double getNuclearRadius(const ParticleType t, const G4int A, const G4int Z);
     G4double getLargestNuclearRadius(const G4i         G4double getLargestNuclearRadius(const G4int A, const G4int Z);
     G4double getRadiusParameter(const Particle         G4double getRadiusParameter(const ParticleType t, const G4int A, const G4int Z);
     G4double getMaximumNuclearRadius(const Par         G4double getMaximumNuclearRadius(const ParticleType t, const G4int A, const G4int Z);
     G4double getSurfaceDiffuseness(const Parti         G4double getSurfaceDiffuseness(const ParticleType t, const G4int A, const G4int Z);
                                                    
     /// \brief Return the RMS of the momentum          /// \brief Return the RMS of the momentum distribution (light clusters)
     G4double getMomentumRMS(const G4int A, con         G4double getMomentumRMS(const G4int A, const G4int Z);
                                                    
     /// \brief Return INCL's default separatio         /// \brief Return INCL's default separation energy
     G4double getSeparationEnergyINCL(const Par         G4double getSeparationEnergyINCL(const ParticleType t, const G4int /*A*/, const G4int /*Z*/);
                                                    
     /// \brief Return the real separation ener         /// \brief Return the real separation energy
     G4double getSeparationEnergyReal(const Par         G4double getSeparationEnergyReal(const ParticleType t, const G4int A, const G4int Z);
                                                    
     /// \brief Return the real separation ener         /// \brief Return the real separation energy only for light nuclei
     G4double getSeparationEnergyRealForLight(c         G4double getSeparationEnergyRealForLight(const ParticleType t, const G4int A, const G4int Z);
                                                    
     /// \brief Getter for protonSeparationEner         /// \brief Getter for protonSeparationEnergy
     G4double getProtonSeparationEnergy();              G4double getProtonSeparationEnergy();
                                                    
     /// \brief Getter for neutronSeparationEne         /// \brief Getter for neutronSeparationEnergy
     G4double getNeutronSeparationEnergy();             G4double getNeutronSeparationEnergy();
                                                    
     /// \brief Setter for protonSeparationEner         /// \brief Setter for protonSeparationEnergy
     void setProtonSeparationEnergy(const G4dou         void setProtonSeparationEnergy(const G4double s);
                                                    
     /// \brief Setter for protonSeparationEner         /// \brief Setter for protonSeparationEnergy
     void setNeutronSeparationEnergy(const G4do         void setNeutronSeparationEnergy(const G4double s);
                                                    
     /// \brief Get the name of the element fro         /// \brief Get the name of the element from the atomic number
     std::string getElementName(const G4int Z);         std::string getElementName(const G4int Z);
                                                    
     /// \brief Get the name of an unnamed elem         /// \brief Get the name of an unnamed element from the IUPAC convention
     std::string getIUPACElementName(const G4in         std::string getIUPACElementName(const G4int Z);
                                                    
     /// \brief Get the name of the element fro         /// \brief Get the name of the element from the atomic number
     G4int parseElement(std::string pS);                G4int parseElement(std::string pS);
                                                    
     /** \brief Parse a IUPAC element name              /** \brief Parse a IUPAC element name
      *                                                  *
      * Note: this function is UGLY. Look at it          * Note: this function is UGLY. Look at it at your own peril.
      *                                                  *
      * \param pS a normalised string (lowercas          * \param pS a normalised string (lowercase)
      * \return the charge number of the nuclid          * \return the charge number of the nuclide, or zero on fail
      */                                                 */
     G4int parseIUPACElement(std::string const          G4int parseIUPACElement(std::string const &pS);
                                                    
     IsotopicDistribution const &getNaturalIsot         IsotopicDistribution const &getNaturalIsotopicDistribution(const G4int Z);
                                                    
     G4int drawRandomNaturalIsotope(const G4int         G4int drawRandomNaturalIsotope(const G4int Z);
                                                    
     // Typedefs and pointers for transparent h         // Typedefs and pointers for transparent handling of mass functions
     //typedef G4double (*NuclearMassFn)(const  <<      typedef G4double (*NuclearMassFn)(const G4int, const G4int);
     typedef G4double (*NuclearMassFn)(const G4 << 
     typedef G4double (*ParticleMassFn)(const P         typedef G4double (*ParticleMassFn)(const ParticleType);
     /// \brief Static pointer to the mass func         /// \brief Static pointer to the mass function for nuclei
     extern G4ThreadLocal NuclearMassFn getTabl         extern G4ThreadLocal NuclearMassFn getTableMass;
     /// \brief Static pointer to the mass func         /// \brief Static pointer to the mass function for particles
     extern G4ThreadLocal ParticleMassFn getTab         extern G4ThreadLocal ParticleMassFn getTableParticleMass;
                                                    
     // Typedefs and pointers for transparent h         // Typedefs and pointers for transparent handling of separation energies
     typedef G4double (*SeparationEnergyFn)(con         typedef G4double (*SeparationEnergyFn)(const ParticleType, const G4int, const G4int);
     /// \brief Static pointer to the separatio         /// \brief Static pointer to the separation-energy function
     extern G4ThreadLocal SeparationEnergyFn ge         extern G4ThreadLocal SeparationEnergyFn getSeparationEnergy;
                                                    
     // Typedefs and pointers for transparent h         // Typedefs and pointers for transparent handling of Fermi momentum
     typedef G4double (*FermiMomentumFn)(const          typedef G4double (*FermiMomentumFn)(const G4int, const G4int);
     extern G4ThreadLocal FermiMomentumFn getFe         extern G4ThreadLocal FermiMomentumFn getFermiMomentum;
                                                    
     /// \brief Return the constant value of th <<      /** \brief Return the constant value of the Fermi momentum
                                                   >>       *
                                                   >>       * This function should always return PhysicalConstants::Pf.
                                                   >>       */
     G4double getFermiMomentumConstant(const G4         G4double getFermiMomentumConstant(const G4int /*A*/, const G4int /*Z*/);
                                                    
     /** \brief Return the constant value of th         /** \brief Return the constant value of the Fermi momentum - special for light
      *                                                  *
      * This function should always return Phys          * This function should always return PhysicalConstants::Pf for heavy
      * nuclei, and values from the momentumRMS          * nuclei, and values from the momentumRMS table for light nuclei.
      *                                                  *
      * \param A mass number                             * \param A mass number
      * \param Z charge number                           * \param Z charge number
      */                                                 */
     G4double getFermiMomentumConstantLight(con         G4double getFermiMomentumConstantLight(const G4int A, const G4int Z);
                                                    
     /** \brief Return the value Fermi momentum         /** \brief Return the value Fermi momentum from a fit
      *                                                  *
      * This function returns a fitted Fermi mo          * This function returns a fitted Fermi momentum, based on data from Moniz
      * et al., Phys. Rev. Lett. 26 (1971) 445.          * et al., Phys. Rev. Lett. 26 (1971) 445. The fitted functional form is
      * \f[                                              * \f[
      * p_F(A)=\alpha-\beta\cdot e^{(-A\cdot\ga          * p_F(A)=\alpha-\beta\cdot e^{(-A\cdot\gamma)}
      * \f]                                              * \f]
      * with \f$\alpha=259.416\f$ MeV/\f$c\f$,           * with \f$\alpha=259.416\f$ MeV/\f$c\f$, \f$\beta=152.824\f$ MeV/\f$c\f$
      * and \f$\gamma=9.5157\cdot10^{-2}\f$.             * and \f$\gamma=9.5157\cdot10^{-2}\f$.
      *                                                  *
      * \param A mass number                             * \param A mass number
      */                                                 */
     G4double getFermiMomentumMassDependent(con         G4double getFermiMomentumMassDependent(const G4int A, const G4int /*Z*/);
                                                    
     /** \brief Get the value of the r-p correl         /** \brief Get the value of the r-p correlation coefficient
      *                                                  *
      * \param t the type of the particle (Prot          * \param t the type of the particle (Proton or Neutron)
      * \return the value of the r-p correlatio          * \return the value of the r-p correlation coefficient
      */                                                 */
     G4double getRPCorrelationCoefficient(const         G4double getRPCorrelationCoefficient(const ParticleType t);
                                                    
     /// \brief Get the thickness of the neutro <<      /// \brief Get the value of the neutron skin thickness
     G4double getNeutronSkin();                 <<      G4double getNeutronSkinThickness();
                                                << 
     /// \brief Get the size of the neutron hal << 
     G4double getNeutronHalo();                 << 
                                                << 
     /// \brief Get the type of pion            << 
     ParticleType getPionType(const G4int isosp << 
                                                << 
     /// \brief Get the type of nucleon         << 
     ParticleType getNucleonType(const G4int is << 
                                                << 
     /// \brief Get the type of delta           << 
     ParticleType getDeltaType(const G4int isos << 
                                                << 
     /// \brief Get the type of sigma           << 
     ParticleType getSigmaType(const G4int isos << 
                                                << 
     /// \brief Get the type of kaon            << 
     ParticleType getKaonType(const G4int isosp << 
                                                << 
     /// \brief Get the type of antikaon        << 
     ParticleType getAntiKaonType(const G4int i << 
                                                << 
     /// \brief Get the type of xi              << 
     ParticleType getXiType(const G4int isosp); << 
                                                << 
     /// \brief Get the type of antinucleon     << 
     ParticleType getAntiNucleonType(const G4in << 
                                                << 
     /// \brief Get the type of antidelta       << 
     ParticleType getAntiXiType(const G4int iso << 
                                                    
     /// \brief Get the type of antisigma       <<      /// \brief Get the value of the additional neutron skin diffuseness
     ParticleType getAntiSigmaType(const G4int  <<      G4double getNeutronSkinAdditionalDiffuseness();
                                                    
     /// \brief Get particle width (in s)       << 
     G4double getWidth(const ParticleType t);   << 
   }                                                  }
 }                                                  }
                                                    
 #endif                                             #endif