Geant4 Cross Reference

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Geant4/processes/hadronic/models/inclxx/incl_physics/src/G4INCLCascade.cc

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Diff markup

Differences between /processes/hadronic/models/inclxx/incl_physics/src/G4INCLCascade.cc (Version 11.3.0) and /processes/hadronic/models/inclxx/incl_physics/src/G4INCLCascade.cc (Version 4.0)


  1 //                                                  1 
  2 // *******************************************    
  3 // * License and Disclaimer                       
  4 // *                                              
  5 // * The  Geant4 software  is  copyright of th    
  6 // * the Geant4 Collaboration.  It is provided    
  7 // * conditions of the Geant4 Software License    
  8 // * LICENSE and available at  http://cern.ch/    
  9 // * include a list of copyright holders.         
 10 // *                                              
 11 // * Neither the authors of this software syst    
 12 // * institutes,nor the agencies providing fin    
 13 // * work  make  any representation or  warran    
 14 // * regarding  this  software system or assum    
 15 // * use.  Please see the license in the file     
 16 // * for the full disclaimer and the limitatio    
 17 // *                                              
 18 // * This  code  implementation is the result     
 19 // * technical work of the GEANT4 collaboratio    
 20 // * By using,  copying,  modifying or  distri    
 21 // * any work based  on the software)  you  ag    
 22 // * use  in  resulting  scientific  publicati    
 23 // * acceptance of all terms of the Geant4 Sof    
 24 // *******************************************    
 25 //                                                
 26 // INCL++ intra-nuclear cascade model             
 27 // Alain Boudard, CEA-Saclay, France              
 28 // Joseph Cugnon, University of Liege, Belgium    
 29 // Jean-Christophe David, CEA-Saclay, France      
 30 // Pekka Kaitaniemi, CEA-Saclay, France, and H    
 31 // Sylvie Leray, CEA-Saclay, France               
 32 // Davide Mancusi, CEA-Saclay, France             
 33 //                                                
 34 #define INCLXX_IN_GEANT4_MODE 1                   
 35                                                   
 36 #include "globals.hh"                             
 37                                                   
 38 /** \file G4INCLCascade.cc                        
 39  *                                                
 40  * INCL Cascade                                   
 41  */                                               
 42 #include "G4INCLCascade.hh"                       
 43 #include "G4INCLRandom.hh"                        
 44 #include "G4INCLStandardPropagationModel.hh"      
 45 #include "G4INCLParticleTable.hh"                 
 46 #include "G4INCLParticle.hh"                      
 47 #include "G4INCLNuclearMassTable.hh"              
 48 #include "G4INCLGlobalInfo.hh"                    
 49 #include "G4INCLNucleus.hh"                       
 50                                                   
 51 #include "G4INCLPauliBlocking.hh"                 
 52                                                   
 53 #include "G4INCLCrossSections.hh"                 
 54                                                   
 55 #include "G4INCLPhaseSpaceGenerator.hh"           
 56                                                   
 57 #include "G4INCLLogger.hh"                        
 58 #include "G4INCLGlobals.hh"                       
 59 #include "G4INCLNuclearDensityFactory.hh"         
 60                                                   
 61 #include "G4INCLINuclearPotential.hh"             
 62                                                   
 63 #include "G4INCLCoulombDistortion.hh"             
 64                                                   
 65 #include "G4INCLClustering.hh"                    
 66                                                   
 67 #include "G4INCLIntersection.hh"                  
 68                                                   
 69 #include "G4INCLBinaryCollisionAvatar.hh"         
 70                                                   
 71 #include "G4INCLCascadeAction.hh"                 
 72 #include "G4INCLAvatarDumpAction.hh"              
 73                                                   
 74 #include <cstring>                                
 75 #include <cstdlib>                                
 76 #include <numeric>                                
 77                                                   
 78 #include "G4INCLPbarAtrestEntryChannel.hh"        
 79                                                   
 80 namespace G4INCL {                                
 81                                                   
 82   INCL::INCL(Config const * const config)         
 83     :propagationModel(0), theA(208), theZ(82),    
 84     targetInitSuccess(false),                     
 85     maxImpactParameter(0.),                       
 86     maxUniverseRadius(0.),                        
 87     maxInteractionDistance(0.),                   
 88     fixedImpactParameter(0.),                     
 89     theConfig(config),                            
 90     nucleus(NULL),                                
 91     forceTransparent(false),                      
 92     minRemnantSize(4)                             
 93   {                                               
 94     // Set the logger object.                     
 95 #ifdef INCLXX_IN_GEANT4_MODE                      
 96     Logger::initVerbosityLevelFromEnvvar();       
 97 #else // INCLXX_IN_GEANT4_MODE                    
 98     Logger::initialize(theConfig);                
 99 #endif // INCLXX_IN_GEANT4_MODE                   
100                                                   
101     // Set the random number generator algorit    
102     // multiple different generator algorithms    
103     // transparent way.                           
104     Random::initialize(theConfig);                
105                                                   
106     // Select the Pauli and CDPP blocking algo    
107     Pauli::initialize(theConfig);                 
108                                                   
109     // Set the cross-section set                  
110     CrossSections::initialize(theConfig);         
111                                                   
112     // Set the phase-space generator              
113     PhaseSpaceGenerator::initialize(theConfig)    
114                                                   
115     // Select the Coulomb-distortion algorithm    
116     CoulombDistortion::initialize(theConfig);     
117                                                   
118     // Select the clustering algorithm:           
119     Clustering::initialize(theConfig);            
120                                                   
121     // Initialize the INCL particle table:        
122     ParticleTable::initialize(theConfig);         
123                                                   
124     // Initialize the value of cutNN in Binary    
125     BinaryCollisionAvatar::setCutNN(theConfig-    
126                                                   
127     // Initialize the value of strange cross s    
128     BinaryCollisionAvatar::setBias(theConfig->    
129                                                   
130     // Propagation model is responsible for fi    
131     // transporting the particles. In principl    
132     // behind an abstract interface and the re    
133     // care how the transportation and avatar     
134     // should allow us to "easily" experiment     
135     // finding schemes and even to support thi    
136     // trajectories in the future.                
137     propagationModel = new StandardPropagation    
138     if(theConfig->getCascadeActionType() == Av    
139       cascadeAction = new AvatarDumpAction();     
140     else                                          
141       cascadeAction = new CascadeAction();        
142     cascadeAction->beforeRunAction(theConfig);    
143                                                   
144     theGlobalInfo.cascadeModel = theConfig->ge    
145     theGlobalInfo.deexcitationModel = theConfi    
146 #ifdef INCL_ROOT_USE                              
147     theGlobalInfo.rootSelection = theConfig->g    
148 #endif                                            
149                                                   
150 #ifndef INCLXX_IN_GEANT4_MODE                     
151     // Fill in the global information             
152     theGlobalInfo.At = theConfig->getTargetA()    
153     theGlobalInfo.Zt = theConfig->getTargetZ()    
154     theGlobalInfo.St = theConfig->getTargetS()    
155     const ParticleSpecies theSpecies = theConf    
156     theGlobalInfo.Ap = theSpecies.theA;           
157     theGlobalInfo.Zp = theSpecies.theZ;           
158     theGlobalInfo.Sp = theSpecies.theS;           
159     theGlobalInfo.Ep = theConfig->getProjectil    
160     theGlobalInfo.biasFactor = theConfig->getB    
161 #endif                                            
162                                                   
163     fixedImpactParameter = theConfig->getImpac    
164   }                                               
165                                                   
166   INCL::~INCL() {                                 
167     InteractionAvatar::deleteBackupParticles()    
168 #ifndef INCLXX_IN_GEANT4_MODE                     
169     NuclearMassTable::deleteTable();              
170 #endif                                            
171     PhaseSpaceGenerator::deletePhaseSpaceGener    
172     CrossSections::deleteCrossSections();         
173     Pauli::deleteBlockers();                      
174     CoulombDistortion::deleteCoulomb();           
175     Random::deleteGenerator();                    
176     Clustering::deleteClusteringModel();          
177 #ifndef INCLXX_IN_GEANT4_MODE                     
178     Logger::deleteLoggerSlave();                  
179 #endif                                            
180     NuclearDensityFactory::clearCache();          
181     NuclearPotential::clearCache();               
182     cascadeAction->afterRunAction();              
183     delete cascadeAction;                         
184     delete propagationModel;                      
185     delete theConfig;                             
186   }                                               
187                                                   
188   G4bool INCL::prepareReaction(const ParticleS    
189     if(A < 0 || A > 300 || Z < 1 || Z > 200) {    
190       INCL_ERROR("Unsupported target: A = " <<    
191                  << "Target configuration reje    
192       return false;                               
193     }                                             
194     if(projectileSpecies.theType==Composite &&    
195        (projectileSpecies.theZ==projectileSpec    
196       INCL_ERROR("Unsupported projectile: A =     
197                  << "Projectile configuration     
198       return false;                               
199     }                                             
200                                                   
201     // Reset the forced-transparent flag          
202     forceTransparent = false;                     
203                                                   
204     // Initialise the maximum universe radius     
205     initUniverseRadius(projectileSpecies, kine    
206     // Initialise the nucleus                     
207                                                   
208 //D                                               
209     //reset                                       
210     G4bool ProtonIsTheVictim = false;             
211     G4bool NeutronIsTheVictim = false;            
212     theEventInfo.annihilationP = false;           
213     theEventInfo.annihilationN = false;           
214                                                   
215     //G4double AnnihilationBarrier = kineticEn    
216     if(projectileSpecies.theType == antiProton    
217       G4double SpOverSn = 1.331;//from experim    
218       //INCL_WARN("theA number set to A-1 from    
219                                                   
220       G4double neutronprob;                       
221       if(theConfig->isNaturalTarget()){ // A =    
222         theA = ParticleTable::drawRandomNatura    
223         neutronprob = (theA + 1 - Z)/(theA + 1    
224       }                                           
225       else{                                       
226         theA = A - 1;                             
227         neutronprob = (A - Z)/(A - Z + SpOverS    
228       }                                           
229                                                   
230       theS = S;                                   
231                                                   
232       G4double rndm = Random::shoot();            
233       if(rndm >= neutronprob){     //proton is    
234         theEventInfo.annihilationP = true;        
235         theZ = Z - 1;                             
236         ProtonIsTheVictim = true;                 
237         //INCL_WARN("theZ number set to Z-1 fr    
238       }                                           
239       else{        //neutron is annihilated       
240         theEventInfo.annihilationN = true;        
241         theZ = Z;                                 
242         NeutronIsTheVictim = true;                
243       }                                           
244     }                                             
245     else{ // not annihilation of pbar             
246       theZ = Z;                                   
247       theS = S;                                   
248       if(theConfig->isNaturalTarget())            
249         theA = ParticleTable::drawRandomNatura    
250       else                                        
251         theA = A;                                 
252     }                                             
253                                                   
254     AnnihilationType theAType = Def;              
255     if(ProtonIsTheVictim == true && NeutronIsT    
256     theAType = PType;                             
257     if(NeutronIsTheVictim == true && ProtonIsT    
258     theAType = NType;                             
259                                                   
260 //D                                               
261                                                   
262     initializeTarget(theA, theZ, theS, theATyp    
263                                                   
264     // Set the maximum impact parameter           
265     maxImpactParameter = CoulombDistortion::ma    
266     INCL_DEBUG("Maximum impact parameter initi    
267                                                   
268     // For forced CN events                       
269     initMaxInteractionDistance(projectileSpeci    
270 // Set the geometric cross sectiony section       
271     if(projectileSpecies.theType == antiProton    
272       G4int currentA = A;                         
273       if(theConfig->isNaturalTarget()){           
274         currentA = ParticleTable::drawRandomNa    
275       }                                           
276       G4double kineticEnergy2=kineticEnergy;      
277       if (kineticEnergy2 <= 0.) kineticEnergy2    
278       theGlobalInfo.geometricCrossSection = 9.    
279         Math::pi*std::pow((1.840 + 1.120*std::    
280         (1. + (Z*G4INCL::PhysicalConstants::eS    
281          //xsection formula was borrowed from     
282     }                                             
283     else{                                         
284       theGlobalInfo.geometricCrossSection =       
285         Math::tenPi*std::pow(maxImpactParamete    
286     }                                             
287                                                   
288     // Set the minimum remnant size               
289     if(projectileSpecies.theA > 0)                
290       minRemnantSize = std::min(theA, 4);         
291     else                                          
292       minRemnantSize = std::min(theA-1, 4);       
293     return true;                                  
294   }                                               
295                                                   
296   G4bool INCL::initializeTarget(const G4int A,    
297     delete nucleus;                               
298                                                   
299     if (theAType==PType || theAType==NType) {     
300       G4double newmaxUniverseRadius=0.;           
301       if (theAType==PType) newmaxUniverseRadiu    
302       else newmaxUniverseRadius=initUniverseRa    
303       nucleus = new Nucleus(A, Z, S, theConfig    
304     }                                             
305     else{                                         
306       nucleus = new Nucleus(A, Z, S, theConfig    
307     }                                             
308     nucleus->getStore()->getBook().reset();       
309     nucleus->initializeParticles();               
310     propagationModel->setNucleus(nucleus);        
311     return true;                                  
312   }                                               
313                                                   
314   const EventInfo &INCL::processEvent(            
315       ParticleSpecies const &projectileSpecies    
316       const G4double kineticEnergy,               
317       const G4int targetA,                        
318       const G4int targetZ,                        
319       const G4int targetS                         
320       ) {                                         
321                                                   
322     ParticleList starlistH2;                      
323                                                   
324     if (projectileSpecies.theType==antiProton     
325                                                   
326       if (targetA==1) {                           
327         preCascade_pbarH1(projectileSpecies, k    
328       } else {                                    
329         preCascade_pbarH2(projectileSpecies, k    
330         theEventInfo.annihilationP = false;       
331         theEventInfo.annihilationN = false;       
332                                                   
333         G4double SpOverSn = 1.331;  //from exp    
334                                                   
335         ThreeVector dummy(0.,0.,0.);              
336         G4double rndm = Random::shoot()*(SpOve    
337         if (rndm <= SpOverSn) {  //proton is a    
338           theEventInfo.annihilationP = true;      
339           Particle *p2 = new Particle(Neutron,    
340           starlistH2.push_back(p2);               
341           //delete p2;                            
342         } else {                 //neutron is     
343           theEventInfo.annihilationN = true;      
344           Particle *p2 = new Particle(Proton,     
345           starlistH2.push_back(p2);               
346           //delete p2;                            
347         }                                         
348       }                                           
349                                                   
350       // File names                               
351 #ifdef INCLXX_IN_GEANT4_MODE                      
352       if (!G4FindDataDir("G4INCLDATA") ) {        
353         G4ExceptionDescription ed;                
354         ed << " Data missing: set environment     
355            << " to point to the directory cont    
356            << " by the INCL++ model" << G4endl    
357         G4Exception("G4INCLDataFile::readData(    
358       }                                           
359       const G4String& dataPath0(G4FindDataDir(    
360       const G4String& dataPathppbar(dataPath0     
361 //      const G4String& dataPathnpbar(dataPath    
362       const G4String& dataPathppbark(dataPath0    
363 //      const G4String& dataPathnpbark(dataPat    
364 #else                                             
365       std::string path;                           
366       if (theConfig) path = theConfig->getINCL    
367       const std::string& dataPathppbar(path +     
368       INCL_DEBUG("Reading https://doi.org/10.1    
369       const std::string& dataPathnpbar(path +     
370       INCL_DEBUG("Reading https://doi.org/10.1    
371       const std::string& dataPathppbark(path +    
372       INCL_DEBUG("Reading https://doi.org/10.1    
373       const std::string& dataPathnpbark(path +    
374       INCL_DEBUG("Reading https://doi.org/10.1    
375 #endif                                            
376                                                   
377       //read probabilities and particle types     
378       std::vector<G4double> probabilities;  //    
379       std::vector<std::vector<G4String>> parti    
380       G4double sum = 0.0;  //will contain a su    
381       G4double kaonicFSprob=0.05;  //probabili    
382                                                   
383       ParticleList starlist;                      
384       ThreeVector mommy;  //momentum to be ass    
385                                                   
386       G4double rdm = Random::shoot();             
387       ThreeVector annihilationPosition(0.,0.,0    
388       if (rdm < (1.-kaonicFSprob)) {  // pioni    
389         INCL_DEBUG("pionic pp final state chos    
390         sum = read_file(dataPathppbar, probabi    
391         rdm = (rdm/(1.-kaonicFSprob))*sum;  //    
392         //now get the line number in the file     
393         G4int n = findStringNumber(rdm, std::m    
394         if ( n < 0 ) return theEventInfo;         
395         for (G4int j = 0; j < static_cast<G4in    
396           if (particle_types[n][j] == "pi0") {    
397             Particle *p = new Particle(PiZero,    
398             starlist.push_back(p);                
399           } else if (particle_types[n][j] == "    
400             Particle *p = new Particle(PiMinus    
401             starlist.push_back(p);                
402           } else if (particle_types[n][j] == "    
403             Particle *p = new Particle(PiPlus,    
404             starlist.push_back(p);                
405           } else if (particle_types[n][j] == "    
406             Particle *p = new Particle(Omega,     
407             starlist.push_back(p);                
408           } else if (particle_types[n][j] == "    
409             Particle *p = new Particle(Eta, mo    
410             starlist.push_back(p);                
411           } else if (particle_types[n][j] == "    
412             Particle *p = new Particle(PiMinus    
413             starlist.push_back(p);                
414             Particle *pp = new Particle(PiZero    
415             starlist.push_back(pp);               
416           } else if (particle_types[n][j] == "    
417             Particle *p = new Particle(PiPlus,    
418             starlist.push_back(p);                
419             Particle *pp = new Particle(PiZero    
420             starlist.push_back(pp);               
421           } else if (particle_types[n][j] == "    
422             Particle *p = new Particle(PiMinus    
423             starlist.push_back(p);                
424             Particle *pp = new Particle(PiPlus    
425             starlist.push_back(pp);               
426           } else {                                
427             INCL_ERROR("Some non-existing FS p    
428             for (G4int jj = 0; jj < static_cas    
429 #ifdef INCLXX_IN_GEANT4_MODE                      
430               G4cout << "gotcha! " << particle    
431 #else                                             
432               std::cout << "gotcha! " << parti    
433 #endif                                            
434             }                                     
435 #ifdef INCLXX_IN_GEANT4_MODE                      
436             G4cout << "Some non-existing FS pa    
437 #else                                             
438             std::cout << "Some non-existing FS    
439 #endif                                            
440           }                                       
441         }                                         
442       } else {                                    
443         INCL_DEBUG("kaonic pp final state chos    
444         sum = read_file(dataPathppbark, probab    
445         rdm = ((1.-rdm)/kaonicFSprob)*sum;  //    
446         //now get the line number in the file     
447         G4int n = findStringNumber(rdm, probab    
448         if ( n < 0 ) return theEventInfo;         
449         for (G4int j = 0; j < static_cast<G4in    
450           if (particle_types[n][j] == "pi0") {    
451             Particle *p = new Particle(PiZero,    
452             starlist.push_back(p);                
453           } else if (particle_types[n][j] == "    
454             Particle *p = new Particle(PiMinus    
455             starlist.push_back(p);                
456           } else if (particle_types[n][j] == "    
457             Particle *p = new Particle(PiPlus,    
458             starlist.push_back(p);                
459           } else if (particle_types[n][j] == "    
460             Particle *p = new Particle(Omega,     
461             starlist.push_back(p);                
462           } else if (particle_types[n][j] == "    
463             Particle *p = new Particle(Eta, mo    
464             starlist.push_back(p);                
465           } else if (particle_types[n][j] == "    
466             Particle *p = new Particle(KMinus,    
467             starlist.push_back(p);                
468           } else if (particle_types[n][j] == "    
469             Particle *p = new Particle(KPlus,     
470             starlist.push_back(p);                
471           } else if (particle_types[n][j] == "    
472             Particle *p = new Particle(KZero,     
473             starlist.push_back(p);                
474           } else if (particle_types[n][j] == "    
475             Particle *p = new Particle(KZeroBa    
476             starlist.push_back(p);                
477           } else {                                
478             INCL_ERROR("Some non-existing FS p    
479             for (G4int jj = 0; jj < static_cas    
480 #ifdef INCLXX_IN_GEANT4_MODE                      
481               G4cout << "gotcha! " << particle    
482 #else                                             
483               std::cout << "gotcha! " << parti    
484 #endif                                            
485             }                                     
486 #ifdef INCLXX_IN_GEANT4_MODE                      
487             G4cout << "Some non-existing FS pa    
488 #else                                             
489             std::cout << "Some non-existing FS    
490 #endif                                            
491           }                                       
492         }                                         
493       }                                           
494                                                   
495       //compute energies of mesons with a phas    
496       G4double energyOfMesonStar=ParticleTable    
497       if (starlist.size() < 2) {                  
498         INCL_ERROR("should never happen, at le    
499       } else if (starlist.size() == 2) {          
500         ParticleIter first = starlist.begin();    
501         ParticleIter last = std::next(first, 1    
502         G4double m1 = (*first)->getMass();        
503         G4double m2 = (*last)->getMass();         
504         G4double s = energyOfMesonStar*energyO    
505         G4double mom1 = std::sqrt(s/4. - (std:    
506         ThreeVector momentello = Random::normV    
507         (*first)->setMomentum(momentello);        
508         (*first)->adjustEnergyFromMomentum();     
509         (*last)->setMomentum(-momentello);        
510         (*last)->adjustEnergyFromMomentum();      
511       } else {                                    
512         PhaseSpaceGenerator::generate(energyOf    
513       }                                           
514                                                   
515       if (targetA==1) postCascade_pbarH1(starl    
516       else            postCascade_pbarH2(starl    
517                                                   
518       theGlobalInfo.nShots++;                     
519       return theEventInfo;                        
520     }  // pbar on H1                              
521                                                   
522     // ReInitialize the bias vector               
523     Particle::INCLBiasVector.clear();             
524     //Particle::INCLBiasVector.Clear();           
525     Particle::nextBiasedCollisionID = 0;          
526                                                   
527     // Set the target and the projectile          
528     targetInitSuccess = prepareReaction(projec    
529                                                   
530     if(!targetInitSuccess) {                      
531       INCL_WARN("Target initialisation failed     
532       theEventInfo.transparent=true;              
533       return theEventInfo;                        
534     }                                             
535                                                   
536     cascadeAction->beforeCascadeAction(propaga    
537                                                   
538     const G4bool canRunCascade = preCascade(pr    
539     if(canRunCascade) {                           
540       cascade();                                  
541       postCascade(projectileSpecies, kineticEn    
542       cascadeAction->afterCascadeAction(nucleu    
543     }                                             
544     updateGlobalInfo();                           
545     return theEventInfo;                          
546   }                                               
547                                                   
548   G4bool INCL::preCascade(ParticleSpecies cons    
549     // Reset theEventInfo                         
550     theEventInfo.reset();                         
551                                                   
552     EventInfo::eventNumber++;                     
553                                                   
554     // Fill in the event information              
555     theEventInfo.projectileType = projectileSp    
556     theEventInfo.Ap = (Short_t)projectileSpeci    
557     theEventInfo.Zp = (Short_t)projectileSpeci    
558     theEventInfo.Sp = (Short_t)projectileSpeci    
559     theEventInfo.Ep = kineticEnergy;              
560     theEventInfo.St = (Short_t)nucleus->getS()    
561                                                   
562     if(nucleus->getAnnihilationType()==PType){    
563       theEventInfo.annihilationP = true;          
564       theEventInfo.At = (Short_t)nucleus->getA    
565       theEventInfo.Zt = (Short_t)nucleus->getZ    
566     }                                             
567     else if(nucleus->getAnnihilationType()==NT    
568       theEventInfo.annihilationN = true;          
569       theEventInfo.At = (Short_t)nucleus->getA    
570       theEventInfo.Zt = (Short_t)nucleus->getZ    
571     }                                             
572     else {                                        
573       theEventInfo.At = (Short_t)nucleus->getA    
574       theEventInfo.Zt = (Short_t)nucleus->getZ    
575     }                                             
576     // Do nothing below the Coulomb barrier       
577     if(maxImpactParameter<=0.) {                  
578       // Fill in the event information            
579     //Particle *pbar = new Particle;              
580     //PbarAtrestEntryChannel *obj = new PbarAt    
581       if(projectileSpecies.theType == antiProt    
582         INCL_DEBUG("at rest annihilation" << '    
583         //theEventInfo.transparent = false;       
584       } else {                                    
585         theEventInfo.transparent = true;          
586         return false;                             
587       }                                           
588     }                                             
589                                                   
590                                                   
591     // Randomly draw an impact parameter or us    
592     // Config option                              
593     G4double impactParameter, phi;                
594     if(fixedImpactParameter<0.) {                 
595       impactParameter = maxImpactParameter * s    
596       phi = Random::shoot() * Math::twoPi;        
597     } else {                                      
598       impactParameter = fixedImpactParameter;     
599       phi = 0.;                                   
600     }                                             
601     INCL_DEBUG("Selected impact parameter: " <    
602                                                   
603     // Fill in the event information              
604     theEventInfo.impactParameter = impactParam    
605                                                   
606     const G4double effectiveImpactParameter =     
607     if(effectiveImpactParameter < 0.) {           
608       // Fill in the event information            
609       theEventInfo.transparent = true;            
610       return false;                               
611     }                                             
612                                                   
613     // Fill in the event information              
614     theEventInfo.transparent = false;             
615     theEventInfo.effectiveImpactParameter = ef    
616                                                   
617     return true;                                  
618   }                                               
619                                                   
620   void INCL::cascade() {                          
621     FinalState *finalState = new FinalState;      
622                                                   
623     unsigned long loopCounter = 0;                
624     const unsigned long maxLoopCounter = 10000    
625     do {                                          
626       // Run book keeping actions that should     
627       cascadeAction->beforePropagationAction(p    
628                                                   
629       // Get the avatar with the smallest time    
630       // to that point in time.                   
631       IAvatar *avatar = propagationModel->prop    
632                                                   
633       finalState->reset();                        
634                                                   
635       // Run book keeping actions that should     
636       cascadeAction->afterPropagationAction(pr    
637                                                   
638       if(avatar == 0) break; // No more avatar    
639                                                   
640       // Run book keeping actions that should     
641       cascadeAction->beforeAvatarAction(avatar    
642                                                   
643       // Channel is responsible for calculatin    
644       // selected avatar. There are different     
645       // class IChannel is, again, an abstract    
646       // the externally observable behavior of    
647       // channels.                                
648       // The handling of the channel is transp    
649       // Final state tells what changed...        
650       avatar->fillFinalState(finalState);         
651       // Run book keeping actions that should     
652       cascadeAction->afterAvatarAction(avatar,    
653                                                   
654       // So now we must give this information     
655       nucleus->applyFinalState(finalState);       
656       // and now we are ready to process the n    
657                                                   
658       delete avatar;                              
659                                                   
660       ++loopCounter;                              
661     } while(continueCascade() && loopCounter<m    
662                                                   
663     delete finalState;                            
664   }                                               
665                                                   
666   void INCL::postCascade(const ParticleSpecies    
667     // Fill in the event information              
668     theEventInfo.stoppingTime = propagationMod    
669                                                   
670     // The event bias                             
671     theEventInfo.eventBias = (Double_t) Partic    
672                                                   
673     // Forced CN?                                 
674     if(!(projectileSpecies.theType==antiProton    
675       if(nucleus->getTryCompoundNucleus()) {      
676         INCL_DEBUG("Trying compound nucleus" <    
677         makeCompoundNucleus();                    
678         theEventInfo.transparent = forceTransp    
679       // Global checks of conservation laws       
680 #ifndef INCLXX_IN_GEANT4_MODE                     
681       if(!theEventInfo.transparent) globalCons    
682 #endif                                            
683       return;                                     
684       }                                           
685     }                                             
686                                                   
687     if(!(projectileSpecies.theType==antiProton    
688       theEventInfo.transparent = forceTranspar    
689     }                                             
690                                                   
691     if(theEventInfo.transparent) {                
692       ProjectileRemnant * const projectileRemn    
693       if(projectileRemnant) {                     
694         // Clear the incoming list (particles     
695         nucleus->getStore()->clearIncoming();     
696       } else {                                    
697         // Delete particles in the incoming li    
698         nucleus->getStore()->deleteIncoming();    
699       }                                           
700     } else {                                      
701                                                   
702       // Check if the nucleus contains strange    
703       theEventInfo.sigmasInside = nucleus->con    
704       theEventInfo.antikaonsInside = nucleus->    
705       theEventInfo.lambdasInside = nucleus->co    
706       theEventInfo.kaonsInside = nucleus->cont    
707                                                   
708       // Capture antiKaons and Sigmas and prod    
709       theEventInfo.absorbedStrangeParticle = n    
710                                                   
711       // Emit strange particles still inside t    
712       nucleus->emitInsideStrangeParticles();      
713       theEventInfo.emitKaon = nucleus->emitIns    
714                                                   
715 #ifdef INCLXX_IN_GEANT4_MODE                      
716       theEventInfo.emitLambda = nucleus->emitI    
717 #endif // INCLXX_IN_GEANT4_MODE                   
718                                                   
719       // Check if the nucleus contains deltas     
720       theEventInfo.deltasInside = nucleus->con    
721                                                   
722       // Take care of any remaining deltas        
723       theEventInfo.forcedDeltasOutside = nucle    
724       theEventInfo.forcedDeltasInside = nucleu    
725                                                   
726       // Take care of any remaining etas, omeg    
727       G4double timeThreshold=theConfig->getDec    
728       theEventInfo.forcedPionResonancesOutside    
729       nucleus->decayOutgoingSigmaZero(timeThre    
730       nucleus->decayOutgoingNeutralKaon();        
731                                                   
732       // Apply Coulomb distortion, if appropri    
733       // Note that this will apply Coulomb dis    
734       // unphysical remnants (see decayInsideD    
735       // what INCL4.6 does, but these events a    
736       // whatever we do doesn't (shouldn't!) m    
737       CoulombDistortion::distortOut(nucleus->g    
738                                                   
739       // If the normal cascade predicted compl    
740       // masses to compute the excitation ener    
741       if(nucleus->getStore()->getOutgoingParti    
742          && (!nucleus->getProjectileRemnant()     
743              || nucleus->getProjectileRemnant(    
744                                                   
745         INCL_DEBUG("Cascade resulted in comple    
746                                                   
747         nucleus->useFusionKinematics();           
748                                                   
749         if(nucleus->getExcitationEnergy()<0.)     
750           // Complete fusion is energetically     
751           INCL_WARN("Complete-fusion kinematic    
752           theEventInfo.transparent = true;        
753           return;                                 
754         }                                         
755                                                   
756       } else { // Normal cascade here             
757                                                   
758         // Set the excitation energy              
759         nucleus->setExcitationEnergy(nucleus->    
760                                                   
761         // Make a projectile pre-fragment out     
762         // spectators                             
763         theEventInfo.nUnmergedSpectators = mak    
764                                                   
765         // Compute recoil momentum, energy and    
766         if(nucleus->getA()==1 && minRemnantSiz    
767           INCL_ERROR("Computing one-nucleon re    
768         }                                         
769         nucleus->computeRecoilKinematics();       
770                                                   
771 #ifndef INCLXX_IN_GEANT4_MODE                     
772         // Global checks of conservation laws     
773         globalConservationChecks(false);          
774 #endif                                            
775                                                   
776         // Make room for the remnant recoil by    
777         // outgoing particles.                    
778         if(nucleus->hasRemnant()) rescaleOutgo    
779                                                   
780       }                                           
781                                                   
782       // Cluster decay                            
783       theEventInfo.clusterDecay = nucleus->dec    
784                                                   
785 #ifndef INCLXX_IN_GEANT4_MODE                     
786       // Global checks of conservation laws       
787       globalConservationChecks(true);             
788 #endif                                            
789                                                   
790       // Fill the EventInfo structure             
791       nucleus->fillEventInfo(&theEventInfo);      
792                                                   
793     }                                             
794   }                                               
795                                                   
796   void INCL::makeCompoundNucleus() {              
797     // If this is not a nucleus-nucleus collis    
798     // compound nucleus.                          
799     //                                            
800     // Yes, even nucleon-nucleus collisions ca    
801     // below the Fermi level. Take e.g. 1-MeV     
802     if(!nucleus->isNucleusNucleusCollision())     
803       forceTransparent = true;                    
804       return;                                     
805     }                                             
806                                                   
807     // Reset the internal Nucleus variables       
808     nucleus->getStore()->clearIncoming();         
809     nucleus->getStore()->clearOutgoing();         
810     nucleus->getProjectileRemnant()->reset();     
811     nucleus->setA(theEventInfo.At);               
812     nucleus->setZ(theEventInfo.Zt);               
813                                                   
814     // CN kinematical variables                   
815     // Note: the CN orbital angular momentum i    
816     // should actually take it into account!      
817     ThreeVector theCNMomentum = nucleus->getIn    
818     ThreeVector theCNSpin = nucleus->getIncomi    
819     const G4double theTargetMass = ParticleTab    
820     G4int theCNA=theEventInfo.At, theCNZ=theEv    
821     Cluster * const theProjectileRemnant = nuc    
822     G4double theCNEnergy = theTargetMass + the    
823                                                   
824     // Loop over the potential participants       
825     ParticleList const &initialProjectileCompo    
826     std::vector<Particle *> shuffledComponents    
827     // Shuffle the list of potential participa    
828     std::shuffle(shuffledComponents.begin(), s    
829                                                   
830     G4bool success = true;                        
831     G4bool atLeastOneNucleonEntering = false;     
832     for(std::vector<Particle*>::const_iterator    
833       // Skip particles that miss the interact    
834       Intersection intersectionInteractionDist    
835             (*p)->getPosition(),                  
836             (*p)->getPropagationVelocity(),       
837             maxInteractionDistance));             
838       if(!intersectionInteractionDistance.exis    
839         continue;                                 
840                                                   
841       // Build an entry avatar for this nucleo    
842       atLeastOneNucleonEntering = true;           
843       ParticleEntryAvatar *theAvatar = new Par    
844       nucleus->getStore()->addParticleEntryAva    
845       FinalState *fs = theAvatar->getFinalStat    
846       nucleus->applyFinalState(fs);               
847       FinalStateValidity validity = fs->getVal    
848       delete fs;                                  
849       switch(validity) {                          
850         case ValidFS:                             
851         case ParticleBelowFermiFS:                
852         case ParticleBelowZeroFS:                 
853           // Add the particle to the CN           
854           theCNA++;                               
855           theCNZ += (*p)->getZ();                 
856           theCNS += (*p)->getS();                 
857           break;                                  
858         case PauliBlockedFS:                      
859         case NoEnergyConservationFS:              
860         default:                                  
861           success = false;                        
862           break;                                  
863       }                                           
864     }                                             
865                                                   
866     if(!success || !atLeastOneNucleonEntering)    
867       INCL_DEBUG("No nucleon entering in force    
868       forceTransparent = true;                    
869       return;                                     
870     }                                             
871                                                   
872 // assert(theCNA==nucleus->getA());               
873 // assert(theCNA<=theEventInfo.At+theEventInfo    
874 // assert(theCNZ<=theEventInfo.Zt+theEventInfo    
875 // assert(theCNS>=theEventInfo.St+theEventInfo    
876                                                   
877     // Update the kinematics of the CN            
878     theCNEnergy -= theProjectileRemnant->getEn    
879     theCNMomentum -= theProjectileRemnant->get    
880                                                   
881     // Deal with the projectile remnant           
882     nucleus->finalizeProjectileRemnant(propaga    
883                                                   
884     // Subtract the angular momentum of the pr    
885 // assert(nucleus->getStore()->getOutgoingPart    
886     theCNSpin -= theProjectileRemnant->getAngu    
887                                                   
888     // Compute the excitation energy of the CN    
889     const G4double theCNMass = ParticleTable::    
890     const G4double theCNInvariantMassSquared =    
891     if(theCNInvariantMassSquared<0.) {            
892       // Negative invariant mass squared, retu    
893       forceTransparent = true;                    
894       return;                                     
895     }                                             
896     const G4double theCNExcitationEnergy = std    
897     if(theCNExcitationEnergy<0.) {                
898       // Negative excitation energy, return a     
899       INCL_DEBUG("CN excitation energy is nega    
900             << "  theCNA = " << theCNA << '\n'    
901             << "  theCNZ = " << theCNZ << '\n'    
902             << "  theCNS = " << theCNS << '\n'    
903             << "  theCNEnergy = " << theCNEner    
904             << "  theCNMomentum = (" << theCNM    
905             << "  theCNExcitationEnergy = " <<    
906             << "  theCNSpin = (" << theCNSpin.    
907             );                                    
908       forceTransparent = true;                    
909       return;                                     
910     } else {                                      
911       // Positive excitation energy, can make     
912       INCL_DEBUG("CN excitation energy is posi    
913             << "  theCNA = " << theCNA << '\n'    
914             << "  theCNZ = " << theCNZ << '\n'    
915             << "  theCNS = " << theCNS << '\n'    
916             << "  theCNEnergy = " << theCNEner    
917             << "  theCNMomentum = (" << theCNM    
918             << "  theCNExcitationEnergy = " <<    
919             << "  theCNSpin = (" << theCNSpin.    
920             );                                    
921       nucleus->setA(theCNA);                      
922       nucleus->setZ(theCNZ);                      
923       nucleus->setS(theCNS);                      
924       nucleus->setMomentum(theCNMomentum);        
925       nucleus->setEnergy(theCNEnergy);            
926       nucleus->setExcitationEnergy(theCNExcita    
927       nucleus->setMass(theCNMass+theCNExcitati    
928       nucleus->setSpin(theCNSpin); // neglects    
929                                                   
930       // Take care of any remaining deltas        
931       theEventInfo.forcedDeltasOutside = nucle    
932                                                   
933       // Take care of any remaining etas and/o    
934       G4double timeThreshold=theConfig->getDec    
935       theEventInfo.forcedPionResonancesOutside    
936                                                   
937       // Take care of any remaining Kaons         
938       theEventInfo.emitKaon = nucleus->emitIns    
939                                                   
940       // Cluster decay                            
941       theEventInfo.clusterDecay = nucleus->dec    
942                                                   
943       // Fill the EventInfo structure             
944       nucleus->fillEventInfo(&theEventInfo);      
945     }                                             
946   }                                               
947                                                   
948   void INCL::rescaleOutgoingForRecoil() {         
949     RecoilCMFunctor theRecoilFunctor(nucleus,     
950                                                   
951     // Apply the root-finding algorithm           
952     const RootFinder::Solution theSolution = R    
953     if(theSolution.success) {                     
954       theRecoilFunctor(theSolution.x); // Appl    
955     } else {                                      
956       INCL_WARN("Couldn't accommodate remnant     
957     }                                             
958   }                                               
959                                                   
960 #ifndef INCLXX_IN_GEANT4_MODE                     
961   void INCL::globalConservationChecks(G4bool a    
962     Nucleus::ConservationBalance theBalance =     
963                                                   
964     // Global conservation checks                 
965     const G4double pLongBalance = theBalance.m    
966     const G4double pTransBalance = theBalance.    
967     if(theBalance.Z != 0) {                       
968       INCL_ERROR("Violation of charge conserva    
969     }                                             
970     if(theBalance.A != 0) {                       
971       INCL_ERROR("Violation of baryon-number c    
972     }                                             
973     if(theBalance.S != 0) {                       
974       INCL_ERROR("Violation of strange-number     
975     }                                             
976     G4double EThreshold, pLongThreshold, pTran    
977     if(afterRecoil) {                             
978       // Less stringent checks after accommoda    
979       EThreshold = 10.; // MeV                    
980       pLongThreshold = 1.; // MeV/c               
981       pTransThreshold = 1.; // MeV/c              
982     } else {                                      
983       // More stringent checks before accommod    
984       EThreshold = 0.1; // MeV                    
985       pLongThreshold = 0.1; // MeV/c              
986       pTransThreshold = 0.1; // MeV/c             
987     }                                             
988     if(std::abs(theBalance.energy)>EThreshold)    
989       INCL_WARN("Violation of energy conservat    
990     }                                             
991     if(std::abs(pLongBalance)>pLongThreshold)     
992       INCL_WARN("Violation of longitudinal mom    
993     }                                             
994     if(std::abs(pTransBalance)>pTransThreshold    
995       INCL_WARN("Violation of transverse momen    
996     }                                             
997                                                   
998     // Feed the EventInfo variables               
999     theEventInfo.EBalance = theBalance.energy;    
1000     theEventInfo.pLongBalance = pLongBalance;    
1001     theEventInfo.pTransBalance = pTransBalanc    
1002   }                                              
1003 #endif                                           
1004                                                  
1005   G4bool INCL::continueCascade() {               
1006     // Stop if we have passed the stopping ti    
1007     if(propagationModel->getCurrentTime() > p    
1008       INCL_DEBUG("Cascade time (" << propagat    
1009           << ") exceeded stopping time (" <<     
1010           << "), stopping cascade" << '\n');     
1011       return false;                              
1012     }                                            
1013     // Stop if there are no participants and     
1014     if(nucleus->getStore()->getBook().getCasc    
1015         nucleus->getStore()->getIncomingParti    
1016       INCL_DEBUG("No participants in the nucl    
1017       return false;                              
1018     }                                            
1019     // Stop if the remnant is smaller than mi    
1020     if(nucleus->getA() <= minRemnantSize) {      
1021       INCL_DEBUG("Remnant size (" << nucleus-    
1022           << ") smaller than or equal to mini    
1023           << "), stopping cascade" << '\n');     
1024       return false;                              
1025     }                                            
1026     // Stop if we have to try and make a comp    
1027     // force a transparent                       
1028     if(nucleus->getTryCompoundNucleus()) {       
1029       INCL_DEBUG("Trying to make a compound n    
1030       return false;                              
1031     }                                            
1032                                                  
1033     return true;                                 
1034   }                                              
1035                                                  
1036   void INCL::finalizeGlobalInfo(Random::SeedV    
1037     const G4double normalisationFactor = theG    
1038       ((G4double) theGlobalInfo.nShots);         
1039     theGlobalInfo.nucleonAbsorptionCrossSecti    
1040       ((G4double) theGlobalInfo.nNucleonAbsor    
1041     theGlobalInfo.pionAbsorptionCrossSection     
1042       ((G4double) theGlobalInfo.nPionAbsorpti    
1043     theGlobalInfo.reactionCrossSection = norm    
1044       ((G4double) (theGlobalInfo.nShots - the    
1045     theGlobalInfo.errorReactionCrossSection =    
1046       std::sqrt((G4double) (theGlobalInfo.nSh    
1047     theGlobalInfo.forcedCNCrossSection = norm    
1048       ((G4double) theGlobalInfo.nForcedCompou    
1049     theGlobalInfo.errorForcedCNCrossSection =    
1050       std::sqrt((G4double) (theGlobalInfo.nFo    
1051     theGlobalInfo.completeFusionCrossSection     
1052       ((G4double) theGlobalInfo.nCompleteFusi    
1053     theGlobalInfo.errorCompleteFusionCrossSec    
1054       std::sqrt((G4double) (theGlobalInfo.nCo    
1055     theGlobalInfo.energyViolationInteractionC    
1056       ((G4double) theGlobalInfo.nEnergyViolat    
1057                                                  
1058     theGlobalInfo.initialRandomSeeds.assign(i    
1059                                                  
1060     Random::SeedVector theSeeds = Random::get    
1061     theGlobalInfo.finalRandomSeeds.assign(the    
1062   }                                              
1063                                                  
1064   G4int INCL::makeProjectileRemnant() {          
1065     // Do nothing if this is not a nucleus-nu    
1066     if(!nucleus->getProjectileRemnant())         
1067       return 0;                                  
1068                                                  
1069     // Get the spectators (geometrical+dynami    
1070     ParticleList geomSpectators(nucleus->getP    
1071     ParticleList dynSpectators(nucleus->getSt    
1072                                                  
1073     G4int nUnmergedSpectators = 0;               
1074                                                  
1075     // If there are no spectators, do nothing    
1076     if(dynSpectators.empty() && geomSpectator    
1077       return 0;                                  
1078     } else if(dynSpectators.size()==1 && geom    
1079       // No geometrical spectators, one dynam    
1080       // Just put it back in the outgoing lis    
1081       nucleus->getStore()->addToOutgoing(dynS    
1082     } else {                                     
1083       // Make a cluster out of the geometrica    
1084       ProjectileRemnant *theProjectileRemnant    
1085                                                  
1086       // Add the dynamical spectators to the     
1087       ParticleList rejected = theProjectileRe    
1088       // Put back the rejected spectators int    
1089       nUnmergedSpectators = (G4int)rejected.s    
1090       nucleus->getStore()->addToOutgoing(reje    
1091                                                  
1092       // Deal with the projectile remnant        
1093       nucleus->finalizeProjectileRemnant(prop    
1094                                                  
1095     }                                            
1096                                                  
1097     return nUnmergedSpectators;                  
1098   }                                              
1099                                                  
1100   void INCL::initMaxInteractionDistance(Parti    
1101     if(projectileSpecies.theType != Composite    
1102       maxInteractionDistance = 0.;               
1103       return;                                    
1104     }                                            
1105                                                  
1106     const G4double r0 = std::max(ParticleTabl    
1107                                ParticleTable:    
1108                                                  
1109     const G4double theNNDistance = CrossSecti    
1110     maxInteractionDistance = r0 + theNNDistan    
1111     INCL_DEBUG("Initialised interaction dista    
1112           << "    theNNDistance = " << theNND    
1113           << "    maxInteractionDistance = "     
1114   }                                              
1115                                                  
1116   void INCL::initUniverseRadius(ParticleSpeci    
1117     G4double rMax = 0.0;                         
1118     if(A==0) {                                   
1119       IsotopicDistribution const &anIsotopicD    
1120         ParticleTable::getNaturalIsotopicDist    
1121       IsotopeVector theIsotopes = anIsotopicD    
1122       for(IsotopeIter i=theIsotopes.begin(),     
1123         const G4double pMaximumRadius = Parti    
1124         const G4double nMaximumRadius = Parti    
1125         const G4double maximumRadius = std::m    
1126         rMax = std::max(maximumRadius, rMax);    
1127       }                                          
1128     } else {                                     
1129       const G4double pMaximumRadius = Particl    
1130       const G4double nMaximumRadius = Particl    
1131       const G4double maximumRadius = std::max    
1132       rMax = std::max(maximumRadius, rMax);      
1133     }                                            
1134     if(p.theType==Composite || p.theType==Pro    
1135       const G4double interactionDistanceNN =     
1136       maxUniverseRadius = rMax + interactionD    
1137     } else if(p.theType==PiPlus                  
1138         || p.theType==PiZero                     
1139         || p.theType==PiMinus) {                 
1140       const G4double interactionDistancePiN =    
1141       maxUniverseRadius = rMax + interactionD    
1142     } else if(p.theType==KPlus                   
1143         || p.theType==KZero) {                   
1144       const G4double interactionDistanceKN =     
1145       maxUniverseRadius = rMax + interactionD    
1146     } else if(p.theType==KZeroBar                
1147         || p.theType==KMinus) {                  
1148       const G4double interactionDistanceKbarN    
1149       maxUniverseRadius = rMax + interactionD    
1150     } else if(p.theType==Lambda                  
1151         ||p.theType==SigmaPlus                   
1152         || p.theType==SigmaZero                  
1153         || p.theType==SigmaMinus) {              
1154       const G4double interactionDistanceYN =     
1155       maxUniverseRadius = rMax + interactionD    
1156     }                                            
1157       else if(p.theType==antiProton) {           
1158       maxUniverseRadius = rMax;                  
1159     }                                            
1160     INCL_DEBUG("Initialised universe radius:     
1161   }                                              
1162                                                  
1163                                                  
1164   G4double INCL::initUniverseRadiusForAntipro    
1165     G4double rMax = 0.0;                         
1166     if(A==0) {                                   
1167       IsotopicDistribution const &anIsotopicD    
1168         ParticleTable::getNaturalIsotopicDist    
1169       IsotopeVector theIsotopes = anIsotopicD    
1170       for(IsotopeIter i=theIsotopes.begin(),     
1171         const G4double pMaximumRadius = Parti    
1172         const G4double nMaximumRadius = Parti    
1173         const G4double maximumRadius = std::m    
1174         rMax = std::max(maximumRadius, rMax);    
1175       }                                          
1176     } else {                                     
1177       const G4double pMaximumRadius = Particl    
1178       const G4double nMaximumRadius = Particl    
1179       const G4double maximumRadius = std::max    
1180       rMax = std::max(maximumRadius, rMax);      
1181     }                                            
1182     return rMax;                                 
1183     }                                            
1184                                                  
1185                                                  
1186   void INCL::updateGlobalInfo() {                
1187     // Increment the global counter for the n    
1188     theGlobalInfo.nShots++;                      
1189                                                  
1190     if(theEventInfo.transparent) {               
1191       // Increment the global counter for the    
1192       theGlobalInfo.nTransparents++;             
1193       // Increment the global counter for the    
1194       if(forceTransparent)                       
1195         theGlobalInfo.nForcedTransparents++;     
1196       return;                                    
1197     }                                            
1198                                                  
1199     // Check if we have an absorption:           
1200     if(theEventInfo.nucleonAbsorption) theGlo    
1201     if(theEventInfo.pionAbsorption) theGlobal    
1202                                                  
1203     // Count complete-fusion events              
1204     if(theEventInfo.nCascadeParticles==0) the    
1205                                                  
1206     if(nucleus->getTryCompoundNucleus())         
1207       theGlobalInfo.nForcedCompoundNucleus++;    
1208                                                  
1209     // Counters for the number of violations     
1210     // collisions                                
1211     theGlobalInfo.nEnergyViolationInteraction    
1212   }                                              
1213                                                  
1214   G4double INCL::read_file(std::string filena    
1215                            std::vector<std::v    
1216     std::ifstream file(filename);                
1217     G4double sum_probs = 0.0;                    
1218     if (file.is_open()) {                        
1219       G4String line;                             
1220       while (getline(file, line)) {              
1221         std::istringstream iss(line);            
1222         G4double prob;                           
1223         iss >> prob;                             
1224         sum_probs += prob;                       
1225         probabilities.push_back(prob);           
1226         std::vector<G4String> types;             
1227         G4String type;                           
1228         while (iss >> type) {                    
1229           types.push_back(type);                 
1230         }                                        
1231         particle_types.push_back(std::move(ty    
1232       }                                          
1233     } else {                                     
1234 #ifdef INCLXX_IN_GEANT4_MODE                     
1235       G4cout << "ERROR no fread_file " << fil    
1236 #else                                            
1237       std::cout << "ERROR no fread_file " <<     
1238 #endif                                           
1239     }                                            
1240     return sum_probs;                            
1241   }                                              
1242                                                  
1243                                                  
1244   G4int INCL::findStringNumber(G4double rdm,     
1245     G4int stringNumber = -1;                     
1246     G4double smallestsum = 0.0;                  
1247     G4double biggestsum = yields[0];             
1248     //G4cout << "initial input " << rdm << G4    
1249     for (G4int i = 0; i < static_cast<G4int>(    
1250       if (rdm >= smallestsum && rdm <= bigges    
1251         //G4cout << smallestsum << " and " <<    
1252         stringNumber = i+1;                      
1253       }                                          
1254       smallestsum += yields[i];                  
1255       biggestsum += yields[i+1];                 
1256     }                                            
1257     if(stringNumber==-1) stringNumber = stati    
1258     if(stringNumber==-1){                        
1259       INCL_ERROR("ERROR in findStringNumber (    
1260 #ifdef INCLXX_IN_GEANT4_MODE                     
1261       G4cout << "ERROR in findStringNumber" <    
1262 #else                                            
1263       std::cout << "ERROR in findStringNumber    
1264 #endif                                           
1265     }                                            
1266     return stringNumber;                         
1267   }                                              
1268                                                  
1269                                                  
1270   void INCL::preCascade_pbarH1(ParticleSpecie    
1271     // Reset theEventInfo                        
1272     theEventInfo.reset();                        
1273                                                  
1274     EventInfo::eventNumber++;                    
1275                                                  
1276     // Fill in the event information             
1277     theEventInfo.projectileType = projectileS    
1278     theEventInfo.Ap = -1;                        
1279     theEventInfo.Zp = -1;                        
1280     theEventInfo.Sp = 0;                         
1281     theEventInfo.Ep = kineticEnergy;             
1282     theEventInfo.St = 0;                         
1283     theEventInfo.At = 1;                         
1284     theEventInfo.Zt = 1;                         
1285   }                                              
1286                                                  
1287                                                  
1288   void INCL::postCascade_pbarH1(ParticleList     
1289     theEventInfo.nParticles = 0;                 
1290                                                  
1291     // Reset the remnant counter                 
1292     theEventInfo.nRemnants = 0;                  
1293     theEventInfo.history.clear();                
1294                                                  
1295     for(ParticleIter i=outgoingParticles.begi    
1296       theEventInfo.A[theEventInfo.nParticles]    
1297       theEventInfo.Z[theEventInfo.nParticles]    
1298       theEventInfo.S[theEventInfo.nParticles]    
1299       theEventInfo.EKin[theEventInfo.nParticl    
1300       ThreeVector mom = (*i)->getMomentum();     
1301       theEventInfo.px[theEventInfo.nParticles    
1302       theEventInfo.py[theEventInfo.nParticles    
1303       theEventInfo.pz[theEventInfo.nParticles    
1304       theEventInfo.theta[theEventInfo.nPartic    
1305       theEventInfo.phi[theEventInfo.nParticle    
1306       theEventInfo.origin[theEventInfo.nParti    
1307 #ifdef INCLXX_IN_GEANT4_MODE                     
1308       theEventInfo.parentResonancePDGCode[the    
1309       theEventInfo.parentResonanceID[theEvent    
1310 #endif                                           
1311       theEventInfo.history.push_back("");        
1312       ParticleSpecies pt((*i)->getType());       
1313       theEventInfo.PDGCode[theEventInfo.nPart    
1314       theEventInfo.nParticles++;                 
1315     }                                            
1316     theEventInfo.nCascadeParticles = theEvent    
1317   }                                              
1318                                                  
1319                                                  
1320   void INCL::preCascade_pbarH2(ParticleSpecie    
1321     // Reset theEventInfo                        
1322     theEventInfo.reset();                        
1323                                                  
1324     EventInfo::eventNumber++;                    
1325                                                  
1326     // Fill in the event information             
1327     theEventInfo.projectileType = projectileS    
1328     theEventInfo.Ap = -1;                        
1329     theEventInfo.Zp = -1;                        
1330     theEventInfo.Sp = 0;                         
1331     theEventInfo.Ep = kineticEnergy;             
1332     theEventInfo.St = 0;                         
1333     theEventInfo.At = 2;                         
1334     theEventInfo.Zt = 1;                         
1335   }                                              
1336                                                  
1337                                                  
1338   void INCL::postCascade_pbarH2(ParticleList     
1339     theEventInfo.nParticles = 0;                 
1340                                                  
1341     // Reset the remnant counter                 
1342     theEventInfo.nRemnants = 0;                  
1343     theEventInfo.history.clear();                
1344                                                  
1345     for(ParticleIter i=outgoingParticles.begi    
1346       theEventInfo.A[theEventInfo.nParticles]    
1347       theEventInfo.Z[theEventInfo.nParticles]    
1348       theEventInfo.S[theEventInfo.nParticles]    
1349       theEventInfo.EKin[theEventInfo.nParticl    
1350       ThreeVector mom = (*i)->getMomentum();     
1351       theEventInfo.px[theEventInfo.nParticles    
1352       theEventInfo.py[theEventInfo.nParticles    
1353       theEventInfo.pz[theEventInfo.nParticles    
1354       theEventInfo.theta[theEventInfo.nPartic    
1355       theEventInfo.phi[theEventInfo.nParticle    
1356       theEventInfo.origin[theEventInfo.nParti    
1357 #ifdef INCLXX_IN_GEANT4_MODE                     
1358       theEventInfo.parentResonancePDGCode[the    
1359       theEventInfo.parentResonanceID[theEvent    
1360 #endif                                           
1361       theEventInfo.history.push_back("");        
1362       ParticleSpecies pt((*i)->getType());       
1363       theEventInfo.PDGCode[theEventInfo.nPart    
1364       theEventInfo.nParticles++;                 
1365     }                                            
1366                                                  
1367     for(ParticleIter i=H2Particles.begin(), e    
1368       theEventInfo.A[theEventInfo.nParticles]    
1369       theEventInfo.Z[theEventInfo.nParticles]    
1370       theEventInfo.S[theEventInfo.nParticles]    
1371       theEventInfo.EKin[theEventInfo.nParticl    
1372       ThreeVector mom = (*i)->getMomentum();     
1373       theEventInfo.px[theEventInfo.nParticles    
1374       theEventInfo.py[theEventInfo.nParticles    
1375       theEventInfo.pz[theEventInfo.nParticles    
1376       theEventInfo.theta[theEventInfo.nPartic    
1377       theEventInfo.phi[theEventInfo.nParticle    
1378       theEventInfo.origin[theEventInfo.nParti    
1379 #ifdef INCLXX_IN_GEANT4_MODE                     
1380       theEventInfo.parentResonancePDGCode[the    
1381       theEventInfo.parentResonanceID[theEvent    
1382 #endif                                           
1383       theEventInfo.history.push_back("");        
1384       ParticleSpecies pt((*i)->getType());       
1385       theEventInfo.PDGCode[theEventInfo.nPart    
1386       theEventInfo.nParticles++;                 
1387     }                                            
1388     theEventInfo.nCascadeParticles = theEvent    
1389   }                                              
1390                                                  
1391 }                                                
1392