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Geant4/processes/hadronic/models/inclxx/incl_physics/src/G4INCLDecayAvatar.cc

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Differences between /processes/hadronic/models/inclxx/incl_physics/src/G4INCLDecayAvatar.cc (Version 11.3.0) and /processes/hadronic/models/inclxx/incl_physics/src/G4INCLDecayAvatar.cc (Version 10.6.p1)


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 25 //                                                 25 //
 26 // INCL++ intra-nuclear cascade model              26 // INCL++ intra-nuclear cascade model
 27 // Alain Boudard, CEA-Saclay, France               27 // Alain Boudard, CEA-Saclay, France
 28 // Joseph Cugnon, University of Liege, Belgium     28 // Joseph Cugnon, University of Liege, Belgium
 29 // Jean-Christophe David, CEA-Saclay, France       29 // Jean-Christophe David, CEA-Saclay, France
 30 // Pekka Kaitaniemi, CEA-Saclay, France, and H     30 // Pekka Kaitaniemi, CEA-Saclay, France, and Helsinki Institute of Physics, Finland
 31 // Sylvie Leray, CEA-Saclay, France                31 // Sylvie Leray, CEA-Saclay, France
 32 // Davide Mancusi, CEA-Saclay, France              32 // Davide Mancusi, CEA-Saclay, France
 33 //                                                 33 //
 34 #define INCLXX_IN_GEANT4_MODE 1                    34 #define INCLXX_IN_GEANT4_MODE 1
 35                                                    35 
 36 #include "globals.hh"                              36 #include "globals.hh"
 37                                                    37 
 38 #include "G4INCLDecayAvatar.hh"                    38 #include "G4INCLDecayAvatar.hh"
 39                                                    39 
 40 #include "G4INCLDeltaDecayChannel.hh"              40 #include "G4INCLDeltaDecayChannel.hh"
 41 #include "G4INCLPionResonanceDecayChannel.hh"      41 #include "G4INCLPionResonanceDecayChannel.hh"
 42 #include "G4INCLSigmaZeroDecayChannel.hh"          42 #include "G4INCLSigmaZeroDecayChannel.hh"
 43 #include "G4INCLNeutralKaonDecayChannel.hh"        43 #include "G4INCLNeutralKaonDecayChannel.hh"
 44 #include "G4INCLStrangeAbsorbtionChannel.hh"       44 #include "G4INCLStrangeAbsorbtionChannel.hh"
 45 #include "G4INCLPauliBlocking.hh"                  45 #include "G4INCLPauliBlocking.hh"
 46 #include <sstream>                                 46 #include <sstream>
 47 #include <string>                                  47 #include <string>
 48 // #include <cassert>                              48 // #include <cassert>
 49                                                    49 
 50 namespace G4INCL {                                 50 namespace G4INCL {
 51                                                    51 
 52   DecayAvatar::DecayAvatar(G4INCL::Particle *a     52   DecayAvatar::DecayAvatar(G4INCL::Particle *aParticle, G4double time, G4INCL::Nucleus *n, G4bool force)
 53     : InteractionAvatar(time, n, aParticle), f     53     : InteractionAvatar(time, n, aParticle), forced(force),
 54       incidentDirection(aParticle->getMomentum     54       incidentDirection(aParticle->getMomentum())
 55   {                                                55   {
 56     setType(DecayAvatarType);                      56     setType(DecayAvatarType);
 57   }                                                57   }
 58                                                    58   
 59   DecayAvatar::DecayAvatar(G4INCL::Particle *a     59   DecayAvatar::DecayAvatar(G4INCL::Particle *aParticle, G4INCL::Particle *bParticle, G4double time, G4INCL::Nucleus *n, G4bool force)
 60     : InteractionAvatar(time, n, aParticle, bP     60     : InteractionAvatar(time, n, aParticle, bParticle), forced(force),
 61       incidentDirection(aParticle->getMomentum     61       incidentDirection(aParticle->getMomentum())
 62   {                                                62   {
 63     setType(DecayAvatarType);                      63     setType(DecayAvatarType);
 64   }                                                64   }
 65                                                    65 
 66   DecayAvatar::~DecayAvatar() {                    66   DecayAvatar::~DecayAvatar() {
 67                                                    67 
 68   }                                                68   }
 69                                                    69 
 70   G4INCL::IChannel* DecayAvatar::getChannel()      70   G4INCL::IChannel* DecayAvatar::getChannel() {
 71     if(!particle2){                                71     if(!particle2){
 72        if(particle1->isDelta()) {                  72        if(particle1->isDelta()) {
 73          INCL_DEBUG("DeltaDecayChannel chosen.     73          INCL_DEBUG("DeltaDecayChannel chosen." << '\n');
 74          return new DeltaDecayChannel(particle     74          return new DeltaDecayChannel(particle1, incidentDirection);
 75        }                                           75        }
 76        else if(particle1->isEta() || particle1     76        else if(particle1->isEta() || particle1->isOmega()) {
 77          INCL_DEBUG("PionResonanceDecayChannel     77          INCL_DEBUG("PionResonanceDecayChannel chosen." << '\n');
 78          return new PionResonanceDecayChannel(     78          return new PionResonanceDecayChannel(particle1, incidentDirection);
 79        }                                           79        }
 80        else if(particle1->getType() == SigmaZe     80        else if(particle1->getType() == SigmaZero) {
 81          INCL_DEBUG("SigmaZeroDecayChannel cho     81          INCL_DEBUG("SigmaZeroDecayChannel chosen." << '\n');
 82          return new SigmaZeroDecayChannel(part     82          return new SigmaZeroDecayChannel(particle1, incidentDirection);
 83        }                                           83        }
 84        else if(particle1->getType() == KZero |     84        else if(particle1->getType() == KZero || particle1->getType() == KZeroBar) {
 85          INCL_DEBUG("NeutralKaonDecayChannel c     85          INCL_DEBUG("NeutralKaonDecayChannel chosen." << '\n');
 86          return new NeutralKaonDecayChannel(pa     86          return new NeutralKaonDecayChannel(particle1);
 87        }                                           87        }
 88     }                                              88     }
 89     else if(((particle1->isAntiKaon() || parti     89     else if(((particle1->isAntiKaon() || particle1->isSigma()) && particle2->isNucleon()) || ((particle2->isAntiKaon() || particle2->isSigma()) && particle1->isNucleon())){
 90       INCL_DEBUG("StrangeAbsorbtion." << '\n')     90       INCL_DEBUG("StrangeAbsorbtion." << '\n');
 91       return new StrangeAbsorbtionChannel(part     91       return new StrangeAbsorbtionChannel(particle1, particle2);
 92     }                                              92     }
 93     return NULL;                                   93     return NULL;
 94   }                                                94   }
 95                                                    95 
 96   void DecayAvatar::preInteraction() {             96   void DecayAvatar::preInteraction() {
 97     InteractionAvatar::preInteraction();           97     InteractionAvatar::preInteraction();
 98   }                                                98   }
 99                                                    99 
100   void DecayAvatar::postInteraction(FinalState    100   void DecayAvatar::postInteraction(FinalState *fs) {
101     // Make sure we have at least two particle    101     // Make sure we have at least two particles in the final state
102     // Removed because of neutral kaon decay      102     // Removed because of neutral kaon decay
103                                                   103     
104 // assert((fs->getModifiedParticles().size() +    104 // assert((fs->getModifiedParticles().size() + fs->getCreatedParticles().size() - fs->getDestroyedParticles().size() >= 2) || ((*fs->getModifiedParticles().begin())->getType() == KShort || (*fs->getModifiedParticles().begin())->getType() == KLong ));
105     //assert((fs->getModifiedParticles().size(    105     //assert((fs->getModifiedParticles().size() + fs->getCreatedParticles().size() - fs->getDestroyedParticles().size() >= 1));
106     if(!forced) { // Normal decay                 106     if(!forced) { // Normal decay
107       // Call the postInteraction method of th    107       // Call the postInteraction method of the parent class
108       // (provides Pauli blocking and enforces    108       // (provides Pauli blocking and enforces energy conservation)
109       InteractionAvatar::postInteraction(fs);     109       InteractionAvatar::postInteraction(fs);
110                                                   110 
111       if(fs->getValidity() == PauliBlockedFS)     111       if(fs->getValidity() == PauliBlockedFS)
112         /* If the decay was Pauli-blocked, mak    112         /* If the decay was Pauli-blocked, make sure the propagation model
113          * generates a new decay avatar on the    113          * generates a new decay avatar on the next call to propagate().
114          *                                        114          *
115          * \bug{Note that we don't generate ne    115          * \bug{Note that we don't generate new decay avatars for deltas that
116          * could not satisfy energy conservati    116          * could not satisfy energy conservation. This is in keeping with
117          * INCL4.6, but doesn't seem to make m    117          * INCL4.6, but doesn't seem to make much sense to me (DM), as energy
118          * conservation can be impossible to s    118          * conservation can be impossible to satisfy due to weird local-energy
119          * conditions, for example, that evolv    119          * conditions, for example, that evolve with time.}
120          */                                       120          */
121         fs->addModifiedParticle(particle1);       121         fs->addModifiedParticle(particle1);
122     } else { // Forced decay                      122     } else { // Forced decay
123       modified = fs->getModifiedParticles();      123       modified = fs->getModifiedParticles();
124       created = fs->getCreatedParticles();        124       created = fs->getCreatedParticles();
125       Destroyed = fs->getDestroyedParticles();    125       Destroyed = fs->getDestroyedParticles();
126       modifiedAndCreated = modified;              126       modifiedAndCreated = modified;
127       modifiedAndCreated.insert(modifiedAndCre    127       modifiedAndCreated.insert(modifiedAndCreated.end(), created.begin(), created.end());
128       ModifiedAndDestroyed = modified;            128       ModifiedAndDestroyed = modified;
129       ModifiedAndDestroyed.insert(ModifiedAndD    129       ModifiedAndDestroyed.insert(ModifiedAndDestroyed.end(), Destroyed.begin(), Destroyed.end());
130                                                   130       
131       std::vector<G4int> newBiasCollisionVecto    131       std::vector<G4int> newBiasCollisionVector;
132       newBiasCollisionVector = ModifiedAndDest    132       newBiasCollisionVector = ModifiedAndDestroyed.getParticleListBiasVector();
133       for(ParticleIter i=modifiedAndCreated.be    133       for(ParticleIter i=modifiedAndCreated.begin(), e=modifiedAndCreated.end(); i!=e; ++i ) {
134       (*i)->setBiasCollisionVector(newBiasColl    134       (*i)->setBiasCollisionVector(newBiasCollisionVector);
135       }                                           135       }
136       // Try to enforce energy conservation       136       // Try to enforce energy conservation
137       fs->setTotalEnergyBeforeInteraction(oldT    137       fs->setTotalEnergyBeforeInteraction(oldTotalEnergy);
138       const G4bool success = enforceEnergyCons    138       const G4bool success = enforceEnergyConservation(fs);
139       if(!success) {                              139       if(!success) {
140         INCL_DEBUG("Enforcing energy conservat    140         INCL_DEBUG("Enforcing energy conservation: failed!" << '\n');
141                                                   141 
142         if(theNucleus) {                          142         if(theNucleus) {
143           // Restore the state of the initial     143           // Restore the state of the initial particles
144           restoreParticles();                     144           restoreParticles();
145                                                   145 
146           // Delete newly created particles       146           // Delete newly created particles
147           for(ParticleIter i=created.begin(),     147           for(ParticleIter i=created.begin(), e=created.end(); i!=e; ++i )
148             delete *i;                            148             delete *i;
149                                                   149 
150           fs->reset();                            150           fs->reset();
151           fs->makeNoEnergyConservation();         151           fs->makeNoEnergyConservation();
152           fs->setTotalEnergyBeforeInteraction(    152           fs->setTotalEnergyBeforeInteraction(0.0);
153                                                   153 
154           return; // Interaction is blocked. R    154           return; // Interaction is blocked. Return an empty final state.
155         } else {                                  155         } else {
156           // If there is no nucleus we have to    156           // If there is no nucleus we have to continue anyway, even if energy
157           // conservation failed. We cannot af    157           // conservation failed. We cannot afford producing unphysical
158           // remnants.                            158           // remnants.
159           INCL_DEBUG("No nucleus, continuing a    159           INCL_DEBUG("No nucleus, continuing anyway." << '\n');
160         }                                         160         }
161       } else {                                    161       } else {
162         INCL_DEBUG("Enforcing energy conservat    162         INCL_DEBUG("Enforcing energy conservation: success!" << '\n');
163       }                                           163       }
164                                                   164 
165       if(theNucleus) {                            165       if(theNucleus) {
166         // Test CDPP blocking                     166         // Test CDPP blocking
167         G4bool isCDPPBlocked = Pauli::isCDPPBl    167         G4bool isCDPPBlocked = Pauli::isCDPPBlocked(created, theNucleus);
168                                                   168 
169         if(isCDPPBlocked) {                       169         if(isCDPPBlocked) {
170           INCL_DEBUG("CDPP: Blocked!" << '\n')    170           INCL_DEBUG("CDPP: Blocked!" << '\n');
171                                                   171 
172           // Restore the state of both particl    172           // Restore the state of both particles
173           restoreParticles();                     173           restoreParticles();
174                                                   174 
175           // Delete newly created particles       175           // Delete newly created particles
176           for(ParticleIter i=created.begin(),     176           for(ParticleIter i=created.begin(), e=created.end(); i!=e; ++i )
177             delete *i;                            177             delete *i;
178                                                   178 
179           fs->reset();                            179           fs->reset();
180           fs->makePauliBlocked();                 180           fs->makePauliBlocked();
181           fs->setTotalEnergyBeforeInteraction(    181           fs->setTotalEnergyBeforeInteraction(0.0);
182                                                   182 
183           return; // Interaction is blocked. R    183           return; // Interaction is blocked. Return an empty final state.
184         }                                         184         }
185         INCL_DEBUG("CDPP: Allowed!" << '\n');     185         INCL_DEBUG("CDPP: Allowed!" << '\n');
186                                                   186 
187       }                                           187       }
188     }                                             188     }
189     // If there is a nucleus, increment the co    189     // If there is a nucleus, increment the counters
190     if(theNucleus) {                              190     if(theNucleus) {
191       switch(fs->getValidity()) {                 191       switch(fs->getValidity()) {
192         case PauliBlockedFS:                      192         case PauliBlockedFS:
193           theNucleus->getStore()->getBook().in    193           theNucleus->getStore()->getBook().incrementBlockedDecays();
194           break;                                  194           break;
195         case NoEnergyConservationFS:              195         case NoEnergyConservationFS:
196         case ParticleBelowFermiFS:                196         case ParticleBelowFermiFS:
197         case ParticleBelowZeroFS:                 197         case ParticleBelowZeroFS:
198           break;                                  198           break;
199         case ValidFS:                             199         case ValidFS:
200           theNucleus->getStore()->getBook().in    200           theNucleus->getStore()->getBook().incrementAcceptedDecays();
201       }                                           201       }
202     }                                             202     }
203                                                   203     
204     return;                                       204     return;
205   }                                               205   }
206                                                   206 
207   std::string DecayAvatar::dump() const {         207   std::string DecayAvatar::dump() const {
208     std::stringstream ss;                         208     std::stringstream ss;
209     ss << "(avatar " << theTime << " 'decay" <    209     ss << "(avatar " << theTime << " 'decay" << '\n'
210       << "(list " << '\n'                         210       << "(list " << '\n'
211       << particle1->dump()                        211       << particle1->dump()
212       << "))" << '\n';                            212       << "))" << '\n';
213     return ss.str();                              213     return ss.str();
214   }                                               214   }
215 }                                                 215 }
216                                                   216