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Geant4/processes/hadronic/models/inclxx/utils/include/G4INCLEventInfo.hh

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Diff markup

Differences between /processes/hadronic/models/inclxx/utils/include/G4INCLEventInfo.hh (Version 11.3.0) and /processes/hadronic/models/inclxx/utils/include/G4INCLEventInfo.hh (Version 10.2.p3)


  1 //                                                  1 //
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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 /** \file G4INCLEventInfo.hh                       38 /** \file G4INCLEventInfo.hh
 39  * \brief Simple container for output of event     39  * \brief Simple container for output of event results.
 40  *                                                 40  *
 41  * Contains the results of an INCL cascade.        41  * Contains the results of an INCL cascade.
 42  *                                                 42  *
 43  * \date 21 January 2011                           43  * \date 21 January 2011
 44  * \author Davide Mancusi                          44  * \author Davide Mancusi
 45  */                                                45  */
 46                                                    46 
 47 #ifndef G4INCLEVENTINFO_HH_HH                      47 #ifndef G4INCLEVENTINFO_HH_HH
 48 #define G4INCLEVENTINFO_HH_HH 1                    48 #define G4INCLEVENTINFO_HH_HH 1
 49                                                    49 
 50 #include "G4INCLParticleType.hh"                   50 #include "G4INCLParticleType.hh"
 51 #ifdef INCL_ROOT_USE                               51 #ifdef INCL_ROOT_USE
 52 #include <Rtypes.h>                                52 #include <Rtypes.h>
 53 #endif                                             53 #endif
 54 #include <string>                                  54 #include <string>
 55 #include <vector>                                  55 #include <vector>
 56 #include <algorithm>                               56 #include <algorithm>
 57                                                    57 
 58 namespace G4INCL {                                 58 namespace G4INCL {
 59 #ifndef INCL_ROOT_USE                              59 #ifndef INCL_ROOT_USE
 60     typedef G4int Int_t;                           60     typedef G4int Int_t;
 61     typedef short Short_t;                         61     typedef short Short_t;
 62     typedef G4float Float_t;                       62     typedef G4float Float_t;
 63     typedef G4double Double_t;                     63     typedef G4double Double_t;
 64     typedef G4bool Bool_t;                         64     typedef G4bool Bool_t;
 65 #endif                                             65 #endif
 66                                                    66 
 67     struct EventInfo {                             67     struct EventInfo {
 68       EventInfo() :                                68       EventInfo() :
 69         nParticles(0),                             69         nParticles(0),
 70         event(0),                              << 
 71         eventBias((Float_t)0.0),               << 
 72         nRemnants(0),                              70         nRemnants(0),
 73         projectileType(0),                         71         projectileType(0),
 74         At(0),                                     72         At(0),
 75         Zt(0),                                     73         Zt(0),
 76         St(0),                                 << 
 77         Ap(0),                                     74         Ap(0),
 78         Zp(0),                                     75         Zp(0),
 79         Sp(0),                                 << 
 80         Ep((Float_t)0.0),                          76         Ep((Float_t)0.0),
 81         impactParameter((Float_t)0.0),             77         impactParameter((Float_t)0.0),
 82         nCollisions(0),                            78         nCollisions(0),
 83         stoppingTime((Float_t)0.0),                79         stoppingTime((Float_t)0.0),
 84         EBalance((Float_t)0.0),                    80         EBalance((Float_t)0.0),
 85         firstEBalance((Float_t)0.0),           << 
 86         pLongBalance((Float_t)0.0),                81         pLongBalance((Float_t)0.0),
 87         pTransBalance((Float_t)0.0),               82         pTransBalance((Float_t)0.0),
 88         nCascadeParticles(0),                      83         nCascadeParticles(0),
 89         transparent(false),                        84         transparent(false),
 90         annihilationP(false),                  << 
 91         annihilationN(false),                  << 
 92         forcedCompoundNucleus(false),              85         forcedCompoundNucleus(false),
 93         nucleonAbsorption(false),                  86         nucleonAbsorption(false),
 94         pionAbsorption(false),                     87         pionAbsorption(false),
 95         nDecays(0),                                88         nDecays(0),
 96         nSrcCollisions(0),                     << 
 97         nSrcPairs(0),                          << 
 98         nBlockedCollisions(0),                     89         nBlockedCollisions(0),
 99         nBlockedDecays(0),                         90         nBlockedDecays(0),
100         effectiveImpactParameter((Float_t)0.0)     91         effectiveImpactParameter((Float_t)0.0),
101         deltasInside(false),                       92         deltasInside(false),
102         sigmasInside(false),                   << 
103         kaonsInside(false),                    << 
104         antikaonsInside(false),                << 
105         lambdasInside(false),                  << 
106         forcedDeltasInside(false),                 93         forcedDeltasInside(false),
107         forcedDeltasOutside(false),                94         forcedDeltasOutside(false),
108         forcedPionResonancesOutside(false),    << 
109         absorbedStrangeParticle(false),        << 
110         forcedSigmaOutside(false),             << 
111         forcedStrangeInside(false),            << 
112         emitLambda(0),                         << 
113         emitKaon(false),                       << 
114         clusterDecay(false),                       95         clusterDecay(false),
115         firstCollisionTime((Float_t)0.0),          96         firstCollisionTime((Float_t)0.0),
116         firstCollisionXSec((Float_t)0.0),          97         firstCollisionXSec((Float_t)0.0),
117         firstCollisionSpectatorPosition((Float     98         firstCollisionSpectatorPosition((Float_t)0.0),
118         firstCollisionSpectatorMomentum((Float     99         firstCollisionSpectatorMomentum((Float_t)0.0),
119         firstCollisionIsElastic(false),           100         firstCollisionIsElastic(false),
120         nReflectionAvatars(0),                    101         nReflectionAvatars(0),
121         nCollisionAvatars(0),                     102         nCollisionAvatars(0),
122         nDecayAvatars(0),                         103         nDecayAvatars(0),
123         nUnmergedSpectators(0),                   104         nUnmergedSpectators(0),
124         nEnergyViolationInteraction(0)         << 105         nEnergyViolationInteraction(0),
                                                   >> 106         event(0)
125                                                   107 
126       {                                           108       {
127         std::fill_n(A, maxSizeParticles, 0);      109         std::fill_n(A, maxSizeParticles, 0);
128         std::fill_n(Z, maxSizeParticles, 0);      110         std::fill_n(Z, maxSizeParticles, 0);
129         std::fill_n(S, maxSizeParticles, 0);   << 
130         std::fill_n(J, maxSizeParticles, 0);   << 
131         std::fill_n(PDGCode, maxSizeParticles, << 
132         std::fill_n(ParticleBias, maxSizeParti << 
133         std::fill_n(EKin, maxSizeParticles, (F    111         std::fill_n(EKin, maxSizeParticles, (Float_t)0.0);
134         std::fill_n(px, maxSizeParticles, (Flo    112         std::fill_n(px, maxSizeParticles, (Float_t)0.0);
135         std::fill_n(py, maxSizeParticles, (Flo    113         std::fill_n(py, maxSizeParticles, (Float_t)0.0);
136         std::fill_n(pz, maxSizeParticles, (Flo    114         std::fill_n(pz, maxSizeParticles, (Float_t)0.0);
137         std::fill_n(theta, maxSizeParticles, (    115         std::fill_n(theta, maxSizeParticles, (Float_t)0.0);
138         std::fill_n(phi, maxSizeParticles, (Fl    116         std::fill_n(phi, maxSizeParticles, (Float_t)0.0);
139         std::fill_n(origin, maxSizeParticles,     117         std::fill_n(origin, maxSizeParticles, 0);
140         std::fill_n(parentResonancePDGCode, ma << 
141         std::fill_n(parentResonanceID, maxSize << 
142         std::fill_n(emissionTime, maxSizeParti    118         std::fill_n(emissionTime, maxSizeParticles, (Float_t)0.0);
143         std::fill_n(ARem, maxSizeRemnants, 0);    119         std::fill_n(ARem, maxSizeRemnants, 0);
144         std::fill_n(ZRem, maxSizeRemnants, 0);    120         std::fill_n(ZRem, maxSizeRemnants, 0);
145         std::fill_n(SRem, maxSizeRemnants, 0); << 
146         std::fill_n(EStarRem, maxSizeRemnants,    121         std::fill_n(EStarRem, maxSizeRemnants, (Float_t)0.0);
147         std::fill_n(JRem, maxSizeRemnants, (Fl    122         std::fill_n(JRem, maxSizeRemnants, (Float_t)0.0);
148         std::fill_n(EKinRem, maxSizeRemnants,     123         std::fill_n(EKinRem, maxSizeRemnants, (Float_t)0.0);
149         std::fill_n(pxRem, maxSizeRemnants, (F    124         std::fill_n(pxRem, maxSizeRemnants, (Float_t)0.0);
150         std::fill_n(pyRem, maxSizeRemnants, (F    125         std::fill_n(pyRem, maxSizeRemnants, (Float_t)0.0);
151         std::fill_n(pzRem, maxSizeRemnants, (F    126         std::fill_n(pzRem, maxSizeRemnants, (Float_t)0.0);
152         std::fill_n(thetaRem, maxSizeRemnants,    127         std::fill_n(thetaRem, maxSizeRemnants, (Float_t)0.0);
153         std::fill_n(phiRem, maxSizeRemnants, (    128         std::fill_n(phiRem, maxSizeRemnants, (Float_t)0.0);
154         std::fill_n(jxRem, maxSizeRemnants, (F    129         std::fill_n(jxRem, maxSizeRemnants, (Float_t)0.0);
155         std::fill_n(jyRem, maxSizeRemnants, (F    130         std::fill_n(jyRem, maxSizeRemnants, (Float_t)0.0);
156         std::fill_n(jzRem, maxSizeRemnants, (F    131         std::fill_n(jzRem, maxSizeRemnants, (Float_t)0.0);
157         std::fill_n(EKinPrime, maxSizeParticle    132         std::fill_n(EKinPrime, maxSizeParticles, (Float_t)0.0);
158         std::fill_n(pzPrime, maxSizeParticles,    133         std::fill_n(pzPrime, maxSizeParticles, (Float_t)0.0);
159         std::fill_n(thetaPrime, maxSizeParticl    134         std::fill_n(thetaPrime, maxSizeParticles, (Float_t)0.0);
160       }                                           135       }
161                                                   136 
162       /** \brief Number of the event */           137       /** \brief Number of the event */
163       static G4ThreadLocal Int_t eventNumber;     138       static G4ThreadLocal Int_t eventNumber;
164                                                   139 
165       /** \brief Maximum array size for remnan    140       /** \brief Maximum array size for remnants */
166       static const Short_t maxSizeRemnants = 1    141       static const Short_t maxSizeRemnants = 10;
167                                                   142 
168       /** \brief Maximum array size for emitte    143       /** \brief Maximum array size for emitted particles */
169       static const Short_t maxSizeParticles =     144       static const Short_t maxSizeParticles = 1000;
170                                                   145 
171       /** \brief Number of particles in the fi    146       /** \brief Number of particles in the final state */
172       Short_t nParticles;                         147       Short_t nParticles;
173       /** \brief Sequential number of the even << 
174       Int_t event;                             << 
175       /** \brief Particle mass number */          148       /** \brief Particle mass number */
176       Short_t A[maxSizeParticles];                149       Short_t A[maxSizeParticles];
177       /** \brief Particle charge number */        150       /** \brief Particle charge number */
178       Short_t Z[maxSizeParticles];                151       Short_t Z[maxSizeParticles];
179       /** \brief Particle strangeness number * << 
180       Short_t S[maxSizeParticles];             << 
181       /** \brief Particle angular momemtum */  << 
182       Short_t J[maxSizeParticles];             << 
183       /** \brief PDG numbering of the particle << 
184       Int_t PDGCode[maxSizeParticles];         << 
185       /** \brief Event bias */                 << 
186       Float_t eventBias;                       << 
187       /** \brief Particle weight due to the bi << 
188       Float_t ParticleBias[maxSizeParticles];  << 
189       /** \brief Particle kinetic energy [MeV]    152       /** \brief Particle kinetic energy [MeV] */
190       Float_t EKin[maxSizeParticles];             153       Float_t EKin[maxSizeParticles];
191       /** \brief Particle momentum, x componen    154       /** \brief Particle momentum, x component [MeV/c] */
192       Float_t px[maxSizeParticles];               155       Float_t px[maxSizeParticles];
193       /** \brief Particle momentum, y componen    156       /** \brief Particle momentum, y component [MeV/c] */
194       Float_t py[maxSizeParticles];               157       Float_t py[maxSizeParticles];
195       /** \brief Particle momentum, z componen    158       /** \brief Particle momentum, z component [MeV/c] */
196       Float_t pz[maxSizeParticles];               159       Float_t pz[maxSizeParticles];
197       /** \brief Particle momentum polar angle    160       /** \brief Particle momentum polar angle [radians] */
198       Float_t theta[maxSizeParticles];            161       Float_t theta[maxSizeParticles];
199       /** \brief Particle momentum azimuthal a    162       /** \brief Particle momentum azimuthal angle [radians] */
200       Float_t phi[maxSizeParticles];              163       Float_t phi[maxSizeParticles];
201       /** \brief Origin of the particle           164       /** \brief Origin of the particle
202        *                                          165        *
203        * Should be -1 for cascade particles, o    166        * Should be -1 for cascade particles, or the number of the remnant for
204        * de-excitation particles. */              167        * de-excitation particles. */
205       Short_t origin[maxSizeParticles];           168       Short_t origin[maxSizeParticles];
206       /** \brief Particle's parent resonance P << 169       /** \brief Emission time [fm/c] */
207       Int_t parentResonancePDGCode[maxSizePart << 170       Float_t emissionTime[maxSizeParticles];
208       /** \brief Particle's parent resonance u << 
209       Int_t parentResonanceID[maxSizeParticles << 
210       /** \brief History of the particle          171       /** \brief History of the particle
211        *                                          172        *
212        * Condensed information about the de-ex    173        * Condensed information about the de-excitation chain of a particle. For
213        * cascade particles, it is just an empt    174        * cascade particles, it is just an empty string. For particles arising
214        * from the de-excitation of a cascade r    175        * from the de-excitation of a cascade remnant, it is a string of
215        * characters. Each character represents    176        * characters. Each character represents one or more identical steps in
216        * the de-excitation process. The curren    177        * the de-excitation process. The currently defined possible character
217        * values and their meanings are the fol    178        * values and their meanings are the following:
218        *                                          179        *
219        * e: evaporation product                   180        * e: evaporation product
220        * E: evaporation residue                   181        * E: evaporation residue
221        * m: multifragmentation                    182        * m: multifragmentation
222        * a: light partner in asymmetric fissio    183        * a: light partner in asymmetric fission or IMF emission
223        * A: heavy partner in asymmetric fissio    184        * A: heavy partner in asymmetric fission or IMF emission
224        * f: light partner in fission              185        * f: light partner in fission
225        * F: heavy partner in fission              186        * F: heavy partner in fission
226        * s: saddle-to-scission emission           187        * s: saddle-to-scission emission
227        * n: non-statistical emission (decay) *    188        * n: non-statistical emission (decay) */
228       std::vector<std::string> history;           189       std::vector<std::string> history;
229       /** \brief Number of remnants */            190       /** \brief Number of remnants */
230       Short_t nRemnants;                          191       Short_t nRemnants;
                                                   >> 192       /** \brief Remnant mass number */
                                                   >> 193       Short_t ARem[maxSizeRemnants];
                                                   >> 194       /** \brief Remnant charge number */
                                                   >> 195       Short_t ZRem[maxSizeRemnants];
                                                   >> 196       /** \brief Remnant excitation energy [MeV] */
                                                   >> 197       Float_t EStarRem[maxSizeRemnants];
                                                   >> 198       /** \brief Remnant spin [\f$\hbar\f$] */
                                                   >> 199       Float_t JRem[maxSizeRemnants];
                                                   >> 200       /** \brief Remnant kinetic energy [MeV] */
                                                   >> 201       Float_t EKinRem[maxSizeRemnants];
                                                   >> 202       /** \brief Remnant momentum, x component [MeV/c] */
                                                   >> 203       Float_t pxRem[maxSizeRemnants];
                                                   >> 204       /** \brief Remnant momentum, y component [MeV/c] */
                                                   >> 205       Float_t pyRem[maxSizeRemnants];
                                                   >> 206       /** \brief Remnant momentum, z component [MeV/c] */
                                                   >> 207       Float_t pzRem[maxSizeRemnants];
                                                   >> 208       /** \brief Remnant momentum polar angle [radians] */
                                                   >> 209       Float_t thetaRem[maxSizeRemnants];
                                                   >> 210       /** \brief Remnant momentum azimuthal angle [radians] */
                                                   >> 211       Float_t phiRem[maxSizeRemnants];
                                                   >> 212       /** \brief Remnant angular momentum, x component [\f$\hbar\f$] */
                                                   >> 213       Float_t jxRem[maxSizeRemnants];
                                                   >> 214       /** \brief Remnant angular momentum, y component [\f$\hbar\f$] */
                                                   >> 215       Float_t jyRem[maxSizeRemnants];
                                                   >> 216       /** \brief Remnant angular momentum, z component [\f$\hbar\f$] */
                                                   >> 217       Float_t jzRem[maxSizeRemnants];
231       /** \brief Projectile particle type */      218       /** \brief Projectile particle type */
232       Int_t projectileType;                       219       Int_t projectileType;
233       /** \brief Mass number of the target nuc    220       /** \brief Mass number of the target nucleus */
234       Short_t At;                                 221       Short_t At;
235       /** \brief Charge number of the target n    222       /** \brief Charge number of the target nucleus */
236       Short_t Zt;                                 223       Short_t Zt;
237       /** \brief Strangeness number of the tar << 
238       Short_t St;                              << 
239       /** \brief Mass number of the projectile    224       /** \brief Mass number of the projectile nucleus */
240       Short_t Ap;                                 225       Short_t Ap;
241       /** \brief Charge number of the projecti    226       /** \brief Charge number of the projectile nucleus */
242       Short_t Zp;                                 227       Short_t Zp;
243       /** \brief Strangeness number of the pro << 
244       Short_t Sp;                              << 
245       /** \brief Projectile kinetic energy giv    228       /** \brief Projectile kinetic energy given as input */
246       Float_t Ep;                                 229       Float_t Ep;
247       /** \brief Impact parameter [fm] */         230       /** \brief Impact parameter [fm] */
248       Float_t impactParameter;                    231       Float_t impactParameter;
249       /** \brief Number of accepted two-body c    232       /** \brief Number of accepted two-body collisions */
250       Int_t nCollisions;                          233       Int_t nCollisions;
251       /** \brief Cascade stopping time [fm/c]     234       /** \brief Cascade stopping time [fm/c] */
252       Float_t stoppingTime;                       235       Float_t stoppingTime;
253       /** \brief Energy-conservation balance [    236       /** \brief Energy-conservation balance [MeV] */
254       Float_t EBalance;                           237       Float_t EBalance;
255       /** \brief First value for the energy-co << 
256       Float_t firstEBalance;                   << 
257       /** \brief Longitudinal momentum-conserv    238       /** \brief Longitudinal momentum-conservation balance [MeV/c] */
258       Float_t pLongBalance;                       239       Float_t pLongBalance;
259       /** \brief Transverse momentum-conservat    240       /** \brief Transverse momentum-conservation balance [MeV/c] */
260       Float_t pTransBalance;                      241       Float_t pTransBalance;
261       /** \brief Number of cascade particles *    242       /** \brief Number of cascade particles */
262       Short_t nCascadeParticles;                  243       Short_t nCascadeParticles;
263       /** \brief True if the event is transpar    244       /** \brief True if the event is transparent */
264       Bool_t transparent;                         245       Bool_t transparent;
265       /** \brief True if annihilation at rest  << 
266       Bool_t annihilationP;                    << 
267       /** \brief True if annihilation at rest  << 
268       Bool_t annihilationN;                    << 
269       /** \brief True if the event is a forced    246       /** \brief True if the event is a forced CN */
270       Bool_t forcedCompoundNucleus;               247       Bool_t forcedCompoundNucleus;
271       /** \brief True if the event is a nucleo    248       /** \brief True if the event is a nucleon absorption */
272       Bool_t nucleonAbsorption;                   249       Bool_t nucleonAbsorption;
273       /** \brief True if the event is a pion a    250       /** \brief True if the event is a pion absorption */
274       Bool_t pionAbsorption;                      251       Bool_t pionAbsorption;
275       /** \brief Number of accepted Delta deca    252       /** \brief Number of accepted Delta decays */
276       Int_t nDecays;                              253       Int_t nDecays;
277       /** \brief Number of accepted SRC collis << 
278       Int_t nSrcCollisions;                    << 
279       /** \brief Number of src pairs */        << 
280       Int_t nSrcPairs;                         << 
281       /** \brief Number of two-body collisions    254       /** \brief Number of two-body collisions blocked by Pauli or CDPP */
282       Int_t nBlockedCollisions;                   255       Int_t nBlockedCollisions;
283       /** \brief Number of decays blocked by P    256       /** \brief Number of decays blocked by Pauli or CDPP */
284       Int_t nBlockedDecays;                       257       Int_t nBlockedDecays;
285       /** \brief Effective (Coulomb-distorted)    258       /** \brief Effective (Coulomb-distorted) impact parameter [fm] */
286       Float_t effectiveImpactParameter;           259       Float_t effectiveImpactParameter;
287       /** \brief Event involved deltas in the     260       /** \brief Event involved deltas in the nucleus at the end of the cascade */
288       Bool_t deltasInside;                        261       Bool_t deltasInside;
289       /** \brief Event involved sigmas in the  << 
290       Bool_t sigmasInside;                     << 
291       /** \brief Event involved kaons in the n << 
292       Bool_t kaonsInside;                      << 
293       /** \brief Event involved antikaons in t << 
294       Bool_t antikaonsInside;                  << 
295       /** \brief Event involved lambdas in the << 
296       Bool_t lambdasInside;                    << 
297       /** \brief Event involved forced delta d    262       /** \brief Event involved forced delta decays inside the nucleus */
298       Bool_t forcedDeltasInside;                  263       Bool_t forcedDeltasInside;
299       /** \brief Event involved forced delta d    264       /** \brief Event involved forced delta decays outside the nucleus */
300       Bool_t forcedDeltasOutside;                 265       Bool_t forcedDeltasOutside;
301       /** \brief Event involved forced eta/ome << 
302       Bool_t forcedPionResonancesOutside;      << 
303       /** \brief Event involved forced strange << 
304       Bool_t absorbedStrangeParticle;          << 
305       /** \brief Event involved forced Sigma Z << 
306       Bool_t forcedSigmaOutside;               << 
307       /** \brief Event involved forced antiKao << 
308       Bool_t forcedStrangeInside;              << 
309       /** \brief Number of forced Lambda emit  << 
310       Int_t emitLambda;                        << 
311       /** \brief Event involved forced Kaon em << 
312       Bool_t emitKaon;                         << 
313       /** \brief Event involved cluster decay     266       /** \brief Event involved cluster decay */
314       Bool_t clusterDecay;                        267       Bool_t clusterDecay;
315       /** \brief Time of the first collision [    268       /** \brief Time of the first collision [fm/c] */
316       Float_t firstCollisionTime;                 269       Float_t firstCollisionTime;
317       /** \brief Cross section of the first co    270       /** \brief Cross section of the first collision (mb) */
318       Float_t firstCollisionXSec;                 271       Float_t firstCollisionXSec;
319       /** \brief Position of the spectator on     272       /** \brief Position of the spectator on the first collision (fm) */
320       Float_t firstCollisionSpectatorPosition;    273       Float_t firstCollisionSpectatorPosition;
321       /** \brief Momentum of the spectator on     274       /** \brief Momentum of the spectator on the first collision (fm) */
322       Float_t firstCollisionSpectatorMomentum;    275       Float_t firstCollisionSpectatorMomentum;
323       /** \brief True if the first collision w    276       /** \brief True if the first collision was elastic */
324       Bool_t firstCollisionIsElastic;             277       Bool_t firstCollisionIsElastic;
325       /** \brief Number of reflection avatars     278       /** \brief Number of reflection avatars */
326       Int_t nReflectionAvatars;                   279       Int_t nReflectionAvatars;
327       /** \brief Number of collision avatars *    280       /** \brief Number of collision avatars */
328       Int_t nCollisionAvatars;                    281       Int_t nCollisionAvatars;
329       /** \brief Number of decay avatars */       282       /** \brief Number of decay avatars */
330       Int_t nDecayAvatars;                        283       Int_t nDecayAvatars;
331       /** \brief Number of dynamical spectator    284       /** \brief Number of dynamical spectators that were merged back into the projectile remnant */
332       Int_t nUnmergedSpectators;                  285       Int_t nUnmergedSpectators;
333       /** \brief Number of attempted collision    286       /** \brief Number of attempted collisions/decays for which the energy-conservation algorithm failed to find a solution. */
334       Int_t nEnergyViolationInteraction;          287       Int_t nEnergyViolationInteraction;
335       /** \brief Emission time [fm/c] */       << 288       /** \brief Sequential number of the event in the event loop */
336       Float_t emissionTime[maxSizeParticles];  << 289       Int_t event;
337       /** \brief Remnant mass number */        << 
338       Short_t ARem[maxSizeRemnants];           << 
339       /** \brief Remnant charge number */      << 
340       Short_t ZRem[maxSizeRemnants];           << 
341       /** \brief Remnant strangeness number */ << 
342       Short_t SRem[maxSizeRemnants];           << 
343       /** \brief Remnant excitation energy [Me << 
344       Float_t EStarRem[maxSizeRemnants];       << 
345       /** \brief Remnant spin [\f$\hbar\f$] */ << 
346       Float_t JRem[maxSizeRemnants];           << 
347       /** \brief Remnant kinetic energy [MeV]  << 
348       Float_t EKinRem[maxSizeRemnants];        << 
349       /** \brief Remnant momentum, x component << 
350       Float_t pxRem[maxSizeRemnants];          << 
351       /** \brief Remnant momentum, y component << 
352       Float_t pyRem[maxSizeRemnants];          << 
353       /** \brief Remnant momentum, z component << 
354       Float_t pzRem[maxSizeRemnants];          << 
355       /** \brief Remnant momentum polar angle  << 
356       Float_t thetaRem[maxSizeRemnants];       << 
357       /** \brief Remnant momentum azimuthal an << 
358       Float_t phiRem[maxSizeRemnants];         << 
359       /** \brief Remnant angular momentum, x c << 
360       Float_t jxRem[maxSizeRemnants];          << 
361       /** \brief Remnant angular momentum, y c << 
362       Float_t jyRem[maxSizeRemnants];          << 
363       /** \brief Remnant angular momentum, z c << 
364       Float_t jzRem[maxSizeRemnants];          << 
365       /** \brief Particle kinetic energy, in i    290       /** \brief Particle kinetic energy, in inverse kinematics [MeV] */
366       Float_t EKinPrime[maxSizeParticles];        291       Float_t EKinPrime[maxSizeParticles];
367       /** \brief Particle momentum, z componen    292       /** \brief Particle momentum, z component, in inverse kinematics [MeV/c] */
368       Float_t pzPrime[maxSizeParticles];          293       Float_t pzPrime[maxSizeParticles];
369       /** \brief Particle momentum polar angle    294       /** \brief Particle momentum polar angle, in inverse kinematics [radians] */
370       Float_t thetaPrime[maxSizeParticles];       295       Float_t thetaPrime[maxSizeParticles];
371                                                   296 
372       /** \brief Reset the EventInfo members *    297       /** \brief Reset the EventInfo members */
373       void reset() {                              298       void reset() {
374         nParticles = 0;                           299         nParticles = 0;
375         event = 0;                             << 
376         eventBias = (Float_t)0.0;              << 
377         history.clear();                          300         history.clear();
378         nRemnants = 0;                            301         nRemnants = 0;
379         projectileType = 0;                       302         projectileType = 0;
380         At = 0;                                   303         At = 0;
381         Zt = 0;                                   304         Zt = 0;
382         St = 0;                                << 
383         Ap = 0;                                   305         Ap = 0;
384         Zp = 0;                                   306         Zp = 0;
385         Sp = 0;                                << 
386         Ep = (Float_t)0.0;                        307         Ep = (Float_t)0.0;
387         impactParameter = (Float_t)0.0;           308         impactParameter = (Float_t)0.0;
388         nCollisions = 0;                          309         nCollisions = 0;
389         stoppingTime = (Float_t)0.0;              310         stoppingTime = (Float_t)0.0;
390         EBalance = (Float_t)0.0;                  311         EBalance = (Float_t)0.0;
391         firstEBalance = (Float_t)0.0;          << 
392         pLongBalance = (Float_t)0.0;              312         pLongBalance = (Float_t)0.0;
393         pTransBalance = (Float_t)0.0;             313         pTransBalance = (Float_t)0.0;
394         nCascadeParticles = 0;                    314         nCascadeParticles = 0;
395         transparent = false;                      315         transparent = false;
396         annihilationP = false;                 << 
397         annihilationN = false;                 << 
398         forcedCompoundNucleus = false;            316         forcedCompoundNucleus = false;
399         nucleonAbsorption = false;                317         nucleonAbsorption = false;
400         pionAbsorption = false;                   318         pionAbsorption = false;
401         nDecays = 0;                              319         nDecays = 0;
402         nSrcCollisions = 0;                    << 
403         nSrcPairs = 0;                         << 
404         nBlockedCollisions = 0;                   320         nBlockedCollisions = 0;
405         nBlockedDecays = 0;                       321         nBlockedDecays = 0;
406         effectiveImpactParameter = (Float_t)0.    322         effectiveImpactParameter = (Float_t)0.0;
407         deltasInside = false;                     323         deltasInside = false;
408         sigmasInside = false;                  << 
409         kaonsInside = false;                   << 
410         antikaonsInside = false;               << 
411         lambdasInside = false;                 << 
412         forcedDeltasInside = false;               324         forcedDeltasInside = false;
413         forcedDeltasOutside = false;              325         forcedDeltasOutside = false;
414         forcedPionResonancesOutside = false;   << 
415         absorbedStrangeParticle = false;       << 
416         forcedSigmaOutside = false;            << 
417         forcedStrangeInside = false;           << 
418         emitLambda = 0;                        << 
419         emitKaon = false;                      << 
420         clusterDecay = false;                     326         clusterDecay = false;
421         firstCollisionTime = (Float_t)0.0;        327         firstCollisionTime = (Float_t)0.0;
422         firstCollisionXSec = (Float_t)0.0;        328         firstCollisionXSec = (Float_t)0.0;
423         firstCollisionSpectatorPosition = (Flo    329         firstCollisionSpectatorPosition = (Float_t)0.0;
424         firstCollisionSpectatorMomentum = (Flo    330         firstCollisionSpectatorMomentum = (Float_t)0.0;
425         firstCollisionIsElastic = false;          331         firstCollisionIsElastic = false;
426         nReflectionAvatars = 0;                   332         nReflectionAvatars = 0;
427         nCollisionAvatars = 0;                    333         nCollisionAvatars = 0;
428         nDecayAvatars = 0;                        334         nDecayAvatars = 0;
429         nUnmergedSpectators = 0;                  335         nUnmergedSpectators = 0;
430         nEnergyViolationInteraction = 0;          336         nEnergyViolationInteraction = 0;
                                                   >> 337         event = 0;
431                                                   338 
432       }                                           339       }
433                                                   340 
434       /// \brief Move a remnant to the particl    341       /// \brief Move a remnant to the particle array
435       void remnantToParticle(const G4int remna    342       void remnantToParticle(const G4int remnantIndex);
436                                                   343 
437       /// \brief Fill the variables describing    344       /// \brief Fill the variables describing the reaction in inverse kinematics
438       void fillInverseKinematics(const Double_    345       void fillInverseKinematics(const Double_t gamma);
439     };                                            346     };
440 }                                                 347 }
441                                                   348 
442 #endif /* G4INCLEVENTINFO_HH_HH */                349 #endif /* G4INCLEVENTINFO_HH_HH */
443                                                   350