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Geant4/processes/hadronic/models/parton_string/diffraction/src/G4DiffractiveExcitation.cc

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Diff markup

Differences between /processes/hadronic/models/parton_string/diffraction/src/G4DiffractiveExcitation.cc (Version 11.3.0) and /processes/hadronic/models/parton_string/diffraction/src/G4DiffractiveExcitation.cc (Version 9.0)


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 25 //                                                 25 //
 26 //                                                 26 //
 27 //                                             <<  27 // $Id: G4DiffractiveExcitation.cc,v 1.1 2007/05/25 06:56:53 vuzhinsk Exp $
 28                                                << 
 29 // -------------------------------------------     28 // ------------------------------------------------------------
 30 //      GEANT 4 class implemetation file           29 //      GEANT 4 class implemetation file
 31 //                                                 30 //
 32 //      ---------------- G4DiffractiveExcitati     31 //      ---------------- G4DiffractiveExcitation --------------
 33 //             by Gunter Folger, October 1998.     32 //             by Gunter Folger, October 1998.
 34 //        diffractive Excitation used by strin <<  33 //         diffractive Excitation used by strings models
 35 //             Take a projectile and a target  <<  34 //     Take a projectile and a target
 36 //             excite the projectile and targe <<  35 //     excite the projectile and target
 37 //  Essential changed by V. Uzhinsky in Novemb     36 //  Essential changed by V. Uzhinsky in November - December 2006
 38 //  in order to put it in a correspondence wit     37 //  in order to put it in a correspondence with original FRITIOF
 39 //  model. Variant of FRITIOF with nucleon de-     38 //  model. Variant of FRITIOF with nucleon de-excitation is implemented.
 40 //  Other changes by V.Uzhinsky in May 2007 we     39 //  Other changes by V.Uzhinsky in May 2007 were introduced to fit
 41 //  meson-nucleon interactions. Additional cha <<  40 //  meson-nucleon interactions  
 42 //  were introduced in December 2006. They tre << 
 43 //  processes more exactly.                    << 
 44 //  Correct treatment of the diffraction disso << 
 45 //  Mass distributions for resonances and uu-d << 
 46 //  and dd-diquarks suppression in neutrons we << 
 47 // -------------------------------------------     41 // ---------------------------------------------------------------------
 48                                                    42 
                                                   >>  43 
 49 #include "globals.hh"                              44 #include "globals.hh"
 50 #include "Randomize.hh"                            45 #include "Randomize.hh"
 51 #include "G4PhysicalConstants.hh"              << 
 52 #include "G4SystemOfUnits.hh"                  << 
 53                                                    46 
 54 #include "G4DiffractiveExcitation.hh"              47 #include "G4DiffractiveExcitation.hh"
 55 #include "G4FTFParameters.hh"                  <<  48 #include "G4LorentzRotation.hh"
 56 #include "G4ElasticHNScattering.hh"            <<  49 #include "G4ThreeVector.hh"
 57                                                <<  50 #include "G4ParticleDefinition.hh"
 58 #include "G4RotationMatrix.hh"                 << 
 59 #include "G4ParticleDefinition.hh"             << 
 60 #include "G4ParticleTable.hh"                  << 
 61 #include "G4SampleResonance.hh"                << 
 62 #include "G4VSplitableHadron.hh"                   51 #include "G4VSplitableHadron.hh"
 63 #include "G4ExcitedString.hh"                      52 #include "G4ExcitedString.hh"
 64 #include "G4Neutron.hh"                        << 
 65                                                << 
 66 #include "G4Exp.hh"                            << 
 67 #include "G4Log.hh"                            << 
 68 #include "G4Pow.hh"                            << 
 69                                                << 
 70 //#include "G4ios.hh"                              53 //#include "G4ios.hh"
 71                                                    54 
 72 //============================================ <<  55 G4DiffractiveExcitation::G4DiffractiveExcitation()                         // Uzhi
 73                                                <<  56 {
 74 //#define debugFTFexcitation                   << 
 75 //#define debug_heavyHadrons                   << 
 76                                                << 
 77 //============================================ << 
 78                                                << 
 79 G4DiffractiveExcitation::G4DiffractiveExcitati << 
 80                                                << 
 81                                                << 
 82 //============================================ << 
 83                                                << 
 84 G4DiffractiveExcitation::~G4DiffractiveExcitat << 
 85                                                << 
 86                                                << 
 87 //============================================ << 
 88                                                << 
 89 G4bool G4DiffractiveExcitation::ExciteParticip << 
 90                                                << 
 91                                                << 
 92                                                << 
 93                                                << 
 94   #ifdef debugFTFexcitation                    << 
 95   G4cout << G4endl << "FTF ExciteParticipants  << 
 96   #endif                                       << 
 97                                                << 
 98   CommonVariables common;                      << 
 99                                                << 
100   // Projectile parameters                     << 
101   common.Pprojectile = projectile->Get4Momentu << 
102   if ( common.Pprojectile.z() < 0.0 ) return f << 
103   common.ProjectilePDGcode = projectile->GetDe << 
104   common.absProjectilePDGcode = std::abs( comm << 
105   common.M0projectile = projectile->GetDefinit << 
106   G4double ProjectileRapidity = common.Pprojec << 
107                                                << 
108   // Target parameters                         << 
109   common.Ptarget = target->Get4Momentum();     << 
110   common.TargetPDGcode = target->GetDefinition << 
111   common.absTargetPDGcode = std::abs( common.T << 
112   common.M0target = target->GetDefinition()->G << 
113   G4double TargetRapidity = common.Ptarget.rap << 
114                                                << 
115   // Kinematical properties of the interaction << 
116   G4LorentzVector Psum = common.Pprojectile +  << 
117   common.S = Psum.mag2();                      << 
118   common.SqrtS = std::sqrt( common.S );        << 
119                                                << 
120   // Check off-shellness of the participants   << 
121   G4bool toBePutOnMassShell = true;  //Uzhi Au << 
122   common.MminProjectile = common.BrW.GetMinimu << 
123   /* Uzhi Aug.2019                             << 
124   if ( common.M0projectile < common.MminProjec << 
125     toBePutOnMassShell = true;                 << 
126     common.M0projectile = common.BrW.SampleMas << 
127                                                << 
128                                                << 
129   }                                            << 
130   */                                           << 
131   common.M0projectile2 = common.M0projectile * << 
132   common.ProjectileDiffStateMinMass    = thePa << 
133   common.ProjectileNonDiffStateMinMass = thePa << 
134   if ( common.M0projectile > common.Projectile << 
135     common.ProjectileDiffStateMinMass    = com << 
136     common.ProjectileNonDiffStateMinMass = com << 
137     if ( common.absProjectilePDGcode > 3000 )  << 
138       common.ProjectileDiffStateMinMass    +=  << 
139       common.ProjectileNonDiffStateMinMass +=  << 
140     }                                          << 
141   }                                            << 
142   common.MminTarget = common.BrW.GetMinimumMas << 
143   /* Uzhi Aug.2019                             << 
144   if ( common.M0target < common.MminTarget ) { << 
145     toBePutOnMassShell = true;                 << 
146     common.M0target = common.BrW.SampleMass( t << 
147                                              t << 
148                                              + << 
149   }                                            << 
150   */                                           << 
151   common.M0target2 = common.M0target * common. << 
152   common.TargetDiffStateMinMass    = theParame << 
153   common.TargetNonDiffStateMinMass = theParame << 
154   if ( common.M0target > common.TargetDiffStat << 
155     common.TargetDiffStateMinMass    = common. << 
156     common.TargetNonDiffStateMinMass = common. << 
157     if ( common.absTargetPDGcode > 3000 ) {  / << 
158       common.TargetDiffStateMinMass    += 140. << 
159       common.TargetNonDiffStateMinMass += 140. << 
160     }                                          << 
161   };                                           << 
162   #ifdef debugFTFexcitation                    << 
163   G4cout << "Proj Targ PDGcodes " << common.Pr << 
164          << "Mprojectile  Y " << common.Pproje << 
165          << "M0projectile Y " << common.M0proj << 
166   G4cout << "Mtarget      Y " << common.Ptarge << 
167          << "M0target     Y " << common.M0targ << 
168   G4cout << "Pproj " << common.Pprojectile <<  << 
169   #endif                                       << 
170                                                << 
171   // Transform momenta to cms and then rotate  << 
172   common.toCms = G4LorentzRotation( -1 * Psum. << 
173   G4LorentzVector Ptmp = common.toCms * common << 
174   if ( Ptmp.pz() <= 0.0 ) return false;  // "S << 
175   common.toCms.rotateZ( -1*Ptmp.phi() );       << 
176   common.toCms.rotateY( -1*Ptmp.theta() );     << 
177   common.toLab = common.toCms.inverse();       << 
178   common.Pprojectile.transform( common.toCms ) << 
179   common.Ptarget.transform( common.toCms );    << 
180                                                << 
181   G4double SumMasses = common.M0projectile + c << 
182   #ifdef debugFTFexcitation                    << 
183   G4cout << "SqrtS     " << common.SqrtS << G4 << 
184          << " " << common.M0target << " " << S << 
185   #endif                                       << 
186   if ( common.SqrtS < SumMasses ) return false << 
187                                                << 
188   common.PZcms2 = ( sqr( common.S ) + sqr( com << 
189                     - 2.0 * ( common.S * ( com << 
190                               + common.M0proje << 
191   #ifdef debugFTFexcitation                    << 
192   G4cout << "PZcms2 after toBePutOnMassShell " << 
193   #endif                                       << 
194   if ( common.PZcms2 < 0.0 ) return false;  // << 
195                                                << 
196   common.PZcms = std::sqrt( common.PZcms2 );   << 
197   if ( toBePutOnMassShell ) {                  << 
198     if ( common.Pprojectile.z() > 0.0 ) {      << 
199       common.Pprojectile.setPz(  common.PZcms  << 
200       common.Ptarget.setPz(     -common.PZcms  << 
201     } else {                                   << 
202       common.Pprojectile.setPz( -common.PZcms  << 
203       common.Ptarget.setPz(      common.PZcms  << 
204     }                                          << 
205     common.Pprojectile.setE( std::sqrt( common << 
206                                         + comm << 
207                                         + comm << 
208                                         + comm << 
209     common.Ptarget.setE( std::sqrt( common.M0t << 
210                                     + common.P << 
211                                     + common.P << 
212                                     + common.P << 
213   }                                            << 
214   #ifdef debugFTFexcitation                    << 
215   G4cout << "Start --------------------" << G4 << 
216          << " " << common.ProjectileDiffStateM << 
217          << G4endl                             << 
218          << "Targ M0 Mdif Mndif " << common.M0 << 
219          << " " << common.TargetNonDiffStateMi << 
220          << "Proj CMS " << common.Pprojectile  << 
221   #endif                                       << 
222                                                << 
223   // Check for possible quark exchange         << 
224   ProjectileRapidity = common.Pprojectile.rapi << 
225   TargetRapidity = common.Ptarget.rapidity();  << 
226   G4double QeNoExc = theParameters->GetProcPro << 
227   G4double QeExc   = theParameters->GetProcPro << 
228                      theParameters->GetProcPro << 
229   common.ProbProjectileDiffraction =           << 
230     theParameters->GetProcProb( 2, ProjectileR << 
231   common.ProbTargetDiffraction =               << 
232     theParameters->GetProcProb( 3, ProjectileR << 
233   common.ProbOfDiffraction = common.ProbProjec << 
234   #ifdef debugFTFexcitation                    << 
235   G4cout << "Proc Probs " << QeNoExc << " " << << 
236          << common.ProbProjectileDiffraction < << 
237          << "ProjectileRapidity " << Projectil << 
238   #endif                                       << 
239                                                << 
240   if ( QeNoExc + QeExc + common.ProbProjectile << 
241     QeNoExc = 1.0 - QeExc - common.ProbProject << 
242   }                                            << 
243   if ( QeExc + QeNoExc != 0.0 ) {              << 
244     common.ProbExc = QeExc / ( QeExc + QeNoExc << 
245   }                                            << 
246   if ( 1.0 - QeExc - QeNoExc > 0.0 ) {         << 
247     common.ProbProjectileDiffraction /= ( 1.0  << 
248     common.ProbTargetDiffraction     /= ( 1.0  << 
249   }                                            << 
250   #ifdef debugFTFexcitation                    << 
251   G4cout << "Proc Probs " << QeNoExc << " " << << 
252          << common.ProbProjectileDiffraction < << 
253          << "ProjectileRapidity " << Projectil << 
254   #endif                                       << 
255                                                << 
256   // Try out charge exchange                   << 
257   G4int returnCode = 1;                        << 
258   if ( G4UniformRand() < QeExc + QeNoExc ) {   << 
259     returnCode = ExciteParticipants_doChargeEx << 
260                                                << 
261   }                                            << 
262                                                << 
263   G4bool returnResult = false;                 << 
264   if ( returnCode == 0 ) {                     << 
265     returnResult = true;  // Successfully ende << 
266   } else if ( returnCode == 1 ) {              << 
267                                                << 
268     common.ProbOfDiffraction = common.ProbProj << 
269     #ifdef debugFTFexcitation                  << 
270     G4cout << "Excitation -------------------- << 
271            << "Proj M0 MdMin MndMin " << commo << 
272            << common.ProjectileDiffStateMinMas << 
273            << G4endl                           << 
274            << "Targ M0 MdMin MndMin " << commo << 
275            << " " << common.TargetNonDiffState << 
276            << G4endl                           << 
277            << "Prob: ProjDiff TargDiff + Sum " << 
278            << common.ProbTargetDiffraction <<  << 
279     #endif                                     << 
280     if ( common.ProbOfDiffraction != 0.0 ) {   << 
281       common.ProbProjectileDiffraction /= comm << 
282     } else {                                   << 
283       common.ProbProjectileDiffraction = 0.0;  << 
284     }                                          << 
285     #ifdef debugFTFexcitation                  << 
286     G4cout << "Prob: ProjDiff TargDiff + Sum " << 
287            << common.ProbTargetDiffraction <<  << 
288     #endif                                     << 
289     common.ProjectileDiffStateMinMass2    = sq << 
290     common.ProjectileNonDiffStateMinMass2 = sq << 
291     common.TargetDiffStateMinMass2        = sq << 
292     common.TargetNonDiffStateMinMass2     = sq << 
293     // Choose between diffraction and non-diff << 
294     if ( G4UniformRand() < common.ProbOfDiffra << 
295                                                << 
296       returnResult = ExciteParticipants_doDiff << 
297                                                << 
298     } else {                                   << 
299                                                << 
300       returnResult = ExciteParticipants_doNonD << 
301                                                << 
302     }                                          << 
303     if ( returnResult ) {                      << 
304       common.Pprojectile += common.Qmomentum;  << 
305       common.Ptarget     -= common.Qmomentum;  << 
306       // Transform back and update SplitableHa << 
307       common.Pprojectile.transform( common.toL << 
308       common.Ptarget.transform( common.toLab ) << 
309       #ifdef debugFTFexcitation                << 
310       G4cout << "Mproj " << common.Pprojectile << 
311              << G4endl;                        << 
312       #endif                                   << 
313       projectile->Set4Momentum( common.Pprojec << 
314       target->Set4Momentum( common.Ptarget );  << 
315       projectile->IncrementCollisionCount( 1 ) << 
316       target->IncrementCollisionCount( 1 );    << 
317     }                                          << 
318   }                                            << 
319                                                << 
320   return returnResult;                         << 
321 }                                              << 
322                                                << 
323 //-------------------------------------------- << 
324                                                << 
325 G4int G4DiffractiveExcitation::                << 
326 ExciteParticipants_doChargeExchange( G4VSplita << 
327                                      G4VSplita << 
328                                      G4FTFPara << 
329                                      G4Elastic << 
330                                      G4Diffrac << 
331   // First of the three utility methods used o << 
332   // it does the sampling for the charge-excha << 
333   // This method returns an integer code - ins << 
334   //   "0" : successfully ended and nothing el << 
335   //   "1" : successfully completed, but the w << 
336   //  "99" : unsuccessfully ended, nothing els << 
337   G4int returnCode = 99;                       << 
338                                                << 
339   G4double DeltaProbAtQuarkExchange = theParam << 
340   G4ParticleDefinition* TestParticle = 0;      << 
341   G4double MtestPr = 0.0, MtestTr = 0.0;       << 
342                                                << 
343   #ifdef debugFTFexcitation                    << 
344   G4cout << "Q exchange ---------------------- << 
345   #endif                                       << 
346                                                << 
347   // The target hadron is always a nucleon (i. << 
348   // never an antinucleon), therefore only a q << 
349   // exchanged between the projectile hadron a << 
350   // we could get a quark-quark-antiquark syst << 
351   // This implies that any projectile meson or << 
352   // a constituent quark in all cases - can ha << 
353   // hadron. Instead, any projectile anti-bary << 
354   // with a target hadron (because it has only << 
355   // projectile baryons, instead can have char << 
356                                                << 
357   G4int NewProjCode = 0, NewTargCode = 0, Proj << 
358   //  Projectile unpacking                     << 
359   if ( common.absProjectilePDGcode < 1000 ) {  << 
360     UnpackMeson(  common.ProjectilePDGcode, Pr << 
361   } else {                                     << 
362     UnpackBaryon( common.ProjectilePDGcode, Pr << 
363   }                                            << 
364   //  Target unpacking                         << 
365   G4int TargQ1 = 0, TargQ2 = 0, TargQ3 = 0;    << 
366   UnpackBaryon( common.TargetPDGcode, TargQ1,  << 
367   #ifdef debugFTFexcitation                    << 
368   G4cout << "Proj Quarks " << ProjQ1 << " " << << 
369          << "Targ Quarks " << TargQ1 << " " << << 
370   #endif                                       << 
371                                                << 
372   // Sampling of exchanged quarks              << 
373   G4int ProjExchangeQ = 0, TargExchangeQ = 0;  << 
374   if ( common.absProjectilePDGcode < 1000 ) {  << 
375                                                << 
376     G4bool isProjQ1Quark = false;              << 
377     ProjExchangeQ = ProjQ2;                    << 
378     if ( ProjQ1 > 0 ) {  // ProjQ1 is a quark  << 
379       isProjQ1Quark = true;                    << 
380       ProjExchangeQ = ProjQ1;                  << 
381     }                                          << 
382     // Exchange of non-identical quarks is all << 
383     G4int NpossibleStates = 0;                 << 
384     if ( ProjExchangeQ != TargQ1 ) NpossibleSt << 
385     if ( ProjExchangeQ != TargQ2 ) NpossibleSt << 
386     if ( ProjExchangeQ != TargQ3 ) NpossibleSt << 
387     G4int Nsampled = (G4int)G4RandFlat::shootI << 
388     NpossibleStates = 0;                       << 
389     if ( ProjExchangeQ != TargQ1 ) {           << 
390       if ( ++NpossibleStates == Nsampled ) {   << 
391         TargExchangeQ = TargQ1; TargQ1 = ProjE << 
392         isProjQ1Quark ? ProjQ1 = TargExchangeQ << 
393       }                                        << 
394     }                                          << 
395     if ( ProjExchangeQ != TargQ2 ) {           << 
396       if ( ++NpossibleStates == Nsampled ) {   << 
397         TargExchangeQ = TargQ2; TargQ2 = ProjE << 
398         isProjQ1Quark ? ProjQ1 = TargExchangeQ << 
399       }                                        << 
400     }                                          << 
401     if ( ProjExchangeQ != TargQ3 ) {           << 
402       if ( ++NpossibleStates == Nsampled ) {   << 
403         TargExchangeQ = TargQ3; TargQ3 = ProjE << 
404         isProjQ1Quark ? ProjQ1 = TargExchangeQ << 
405       }                                        << 
406     }                                          << 
407     #ifdef debugFTFexcitation                  << 
408     G4cout << "Exchanged Qs in Pr Tr " << Proj << 
409     #endif                                     << 
410                                                << 
411     G4int aProjQ1 = std::abs( ProjQ1 ), aProjQ << 
412     G4bool ProjExcited = false;                << 
413     const G4int maxNumberOfAttempts = 50;      << 
414     G4int attempts = 0;                        << 
415     while ( attempts++ < maxNumberOfAttempts ) << 
416                                                << 
417       // Determination of a new projectile ID  << 
418       G4double ProbSpin0 = 0.5;                << 
419       G4double Ksi = G4UniformRand();          << 
420       if ( aProjQ1 == aProjQ2 ) {              << 
421         if ( G4UniformRand() < ProbSpin0 ) {   << 
422           if ( aProjQ1 < 3 ) {                 << 
423             NewProjCode = 111;                 << 
424             if ( Ksi < 0.5 ) {                 << 
425               NewProjCode = 221;               << 
426               if ( Ksi < 0.25 ) {              << 
427                 NewProjCode = 331;             << 
428               }                                << 
429             }                                  << 
430           } else if ( aProjQ1 == 3 ) {         << 
431               NewProjCode = 221;               << 
432               if ( Ksi < 0.5 ) {               << 
433                 NewProjCode = 331;             << 
434               }                                << 
435           } else if ( aProjQ1 == 4 ) {         << 
436       NewProjCode = 441;                // eta << 
437     } else if ( aProjQ1 == 5 ) {               << 
438       NewProjCode = 551;                // eta << 
439     }                                          << 
440         } else {                               << 
441           if ( aProjQ1 < 3 ) {                 << 
442             NewProjCode = 113;                 << 
443             if ( Ksi < 0.5 ) {                 << 
444               NewProjCode = 223;               << 
445             }                                  << 
446           } else if ( aProjQ1 == 3 ) {         << 
447             NewProjCode = 333;                 << 
448           } else if ( aProjQ1 == 4 ) {         << 
449       NewProjCode = 443;                // J/p << 
450     } else if ( aProjQ1 == 5 ) {               << 
451       NewProjCode = 553;                // Ups << 
452     }                                          << 
453         }                                      << 
454       } else {                                 << 
455         if ( aProjQ1 > aProjQ2 ) {             << 
456           NewProjCode = aProjQ1*100 + aProjQ2* << 
457         } else {                               << 
458           NewProjCode = aProjQ2*100 + aProjQ1* << 
459         }                                      << 
460       }                                        << 
461       #ifdef debugFTFexcitation                << 
462       G4cout << "NewProjCode " << NewProjCode  << 
463       #endif                                   << 
464       // Decide (with 50% probability) whether << 
465       // but not in the case of charmed and bo << 
466       // there are no excited charmed and bott << 
467       ProjExcited = false;                     << 
468       if ( aProjQ1 <= 3  &&  aProjQ2 <= 3  &&  << 
469         NewProjCode += 2;  // Excited meson (J << 
470         ProjExcited = true;                    << 
471       }                                        << 
472                                                << 
473       // So far we have used the absolute valu << 
474       // now look at their signed values to se << 
475       G4int value = ProjQ1, absValue = aProjQ1 << 
476       for ( G4int iQ = 0; iQ < 2; ++iQ ) {  // << 
477         if ( iQ == 1 ) {                       << 
478           value = ProjQ2; absValue = aProjQ2;  << 
479         }                                      << 
480         if ( absValue == 2  ||  absValue == 4  << 
481           Qquarks += 2*value/absValue;  // u,  << 
482         } else {                               << 
483           Qquarks -= value/absValue;    // d,  << 
484         }                                      << 
485       }                                        << 
486       // If Qquarks is positive, the sign of N << 
487       // If Qquarks is negative, then the sign << 
488       // If Qquarks is zero, then we need to d << 
489       // 1. If aProjQ1 and aProjQ2 are the sam << 
490       //    (because the antiparticle is the s << 
491       // 2. If aProjQ1 and aProjQ2 are not the << 
492       //    we have only two possibilities:    << 
493       //    a. aProjQ1 and aProjQ2 are two dif << 
494       //       (s,d) or (b,d), or (b,s). In th << 
495       //       is fine (because the heaviest o << 
496       //       to be anti-quark belonging to t << 
497       //       implies a meson with positive P << 
498       //    b. aProjQ1 and aProjQ2 are two dif << 
499       //       The heaviest of the two (c) has << 
500       //       in the projectile, therefore th << 
501       //       reverse: 421 -> -421 anti_D0 (c << 
502       if ( Qquarks < 0  || ( Qquarks == 0  &&  << 
503   NewProjCode *= -1;                           << 
504       }                                        << 
505       #ifdef debugFTFexcitation                << 
506       G4cout << "NewProjCode +2 or 0 " << NewP << 
507       G4cout<<"+++++++++++++++++++++++++++++++ << 
508       G4cout<<ProjQ1<<" "<<ProjQ2<<" "<<Qquark << 
509       G4cout<<"+++++++++++++++++++++++++++++++ << 
510       #endif                                   << 
511                                                << 
512       // Proj                                  << 
513       TestParticle = G4ParticleTable::GetParti << 
514       if ( ! TestParticle ) continue;          << 
515       common.MminProjectile = common.BrW.GetMi << 
516       if ( common.SqrtS - common.M0target < co << 
517       MtestPr = common.BrW.SampleMass( TestPar << 
518                                                << 
519       #ifdef debugFTFexcitation                << 
520       G4cout << "TestParticle Name " << NewPro << 
521              << G4endl                         << 
522              << "MtestPart MtestPart0 "<<Mtest << 
523              << "M0projectile projectile PDGMa << 
524              << projectile->GetDefinition()->G << 
525       #endif                                   << 
526                                                << 
527       // Targ                                  << 
528       NewTargCode = NewNucleonId( TargQ1, Targ << 
529       #ifdef debugFTFexcitation                << 
530       G4cout << "New TrQ " << TargQ1 << " " << << 
531              << "NewTargCode " << NewTargCode  << 
532       #endif                                   << 
533                                                << 
534       // If the target has not heavy (charm or << 
535       // see whether a Delta isobar can be cre << 
536       if ( TargQ1 <= 3  &&  TargQ2 <= 3  &&  T << 
537         if ( TargQ1 != TargQ2  &&  TargQ1 != T << 
538           if ( G4UniformRand() < 0.5 ) {       << 
539             NewTargCode += 2;                  << 
540           } else if ( G4UniformRand() < 0.75 ) << 
541             NewTargCode = 3122;  // Lambda     << 
542           }                                    << 
543         } else if ( TargQ1 == TargQ2  &&  Targ << 
544           NewTargCode += 2; ProjExcited = true << 
545         } else if ( target->GetDefinition()->G << 
546           if ( G4UniformRand() > DeltaProbAtQu << 
547             NewTargCode += 2; ProjExcited = tr << 
548           }                                    << 
549         } else if ( ! ProjExcited  &&          << 
550                     G4UniformRand() < DeltaPro << 
551                     common.SqrtS > common.M0pr << 
552                          G4ParticleTable::GetP << 
553           NewTargCode += 2;  // Create Delta i << 
554         }                                      << 
555       }                                        << 
556                                                << 
557       // Protection against:                   << 
558       // - Lambda* (i.e. excited Lambda state) << 
559       // - Sigma*  (i.e. excited Sigma hyperon << 
560       // - Xi*     (i.e. excited Xi hyperon st << 
561       if ( NewTargCode == 3124  ||   // Lambda << 
562      NewTargCode == 3224  ||   // Sigma*+ NOT  << 
563      NewTargCode == 3214  ||   // Sigma*0 NOT  << 
564      NewTargCode == 3114  ||   // Sigma*- NOT  << 
565      NewTargCode == 3324  ||   // Xi*0    NOT  << 
566      NewTargCode == 3314  ) {  // Xi*-    NOT  << 
567   //G4cout << "G4DiffractiveExcitation::Excite << 
568   //       << NewTargCode << G4endl;           << 
569   NewTargCode -= 2;  // Corresponding ground-s << 
570       }                                        << 
571                                                << 
572       // Special treatment for charmed and bot << 
573       // so we need to transform them by hand  << 
574       #ifdef debug_heavyHadrons                << 
575       G4int initialNewTargCode = NewTargCode;  << 
576       #endif                                   << 
577       if      ( NewTargCode == 4322 ) NewTargC << 
578       else if ( NewTargCode == 4312 ) NewTargC << 
579       else if ( NewTargCode == 5312 ) NewTargC << 
580       else if ( NewTargCode == 5322 ) NewTargC << 
581       #ifdef debug_heavyHadrons                << 
582       if ( NewTargCode != initialNewTargCode ) << 
583   G4cout << "G4DiffractiveExcitation::ExcitePa << 
584          << "\t target heavy baryon with pdgCo << 
585          << " into pdgCode=" << NewTargCode << << 
586       }                                        << 
587       #endif                                   << 
588                                                << 
589       TestParticle = G4ParticleTable::GetParti << 
590       if ( ! TestParticle ) continue;          << 
591       #ifdef debugFTFexcitation                << 
592       G4cout << "New targ " << NewTargCode <<  << 
593       #endif                                   << 
594       common.MminTarget = common.BrW.GetMinimu << 
595       if ( common.SqrtS - MtestPr < common.Mmi << 
596       MtestTr = common.BrW.SampleMass( TestPar << 
597                                                << 
598       if ( common.SqrtS > MtestPr + MtestTr )  << 
599                                                << 
600     }  // End of while loop                    << 
601     if ( attempts >= maxNumberOfAttempts ) ret << 
602                                                << 
603     if ( MtestPr >= common.Pprojectile.mag()   << 
604       common.M0projectile = MtestPr;           << 
605     }                                          << 
606     #ifdef debugFTFexcitation                  << 
607     G4cout << "M0projectile After check " << c << 
608     #endif                                     << 
609     common.M0projectile2 = common.M0projectile << 
610     common.ProjectileDiffStateMinMass    = com << 
611     common.ProjectileNonDiffStateMinMass = com << 
612     if ( MtestTr >= common.Ptarget.mag()  ||   << 
613       common.M0target = MtestTr;               << 
614     }                                          << 
615     common.M0target2 = common.M0target * commo << 
616     #ifdef debugFTFexcitation                  << 
617     G4cout << "New targ M0 M0^2 " << common.M0 << 
618     #endif                                     << 
619     common.TargetDiffStateMinMass    = common. << 
620     common.TargetNonDiffStateMinMass = common. << 
621                                                << 
622   } else {  // of the if ( common.absProjectil << 
623                                                << 
624     // If it is a projectile anti-baryon, no q << 
625     // therefore returns immediately 1 (which  << 
626     // needs to be continued").                << 
627     if ( common.ProjectilePDGcode < 0 ) return << 
628                                                << 
629     // Choose randomly, with equal probability << 
630     // projectile or target hadron for selecti << 
631     G4bool isProjectileExchangedQ = false;     << 
632     G4int firstQ      = TargQ1, secondQ      = << 
633     G4int otherFirstQ = ProjQ1, otherSecondQ = << 
634     if ( G4UniformRand() < 0.5 ) {             << 
635       isProjectileExchangedQ = true;           << 
636       firstQ      = ProjQ1; secondQ      = Pro << 
637       otherFirstQ = TargQ1; otherSecondQ = Tar << 
638     }                                          << 
639     // Choose randomly, with equal probability << 
640     // selected (projectile or target) hadron  << 
641     G4int exchangedQ = 0;                      << 
642     G4double Ksi = G4UniformRand();            << 
643     if ( Ksi < 0.333333 ) {                    << 
644       exchangedQ = firstQ;                     << 
645     } else if ( 0.333333 <= Ksi  &&  Ksi < 0.6 << 
646       exchangedQ = secondQ;                    << 
647     } else {                                   << 
648       exchangedQ = thirdQ;                     << 
649     }                                          << 
650     #ifdef debugFTFexcitation                  << 
651     G4cout << "Exchange Qs isProjectile Q " << << 
652     #endif                                     << 
653     // The exchanged quarks (one of the projec << 
654     // are always accepted if they have differ << 
655     // same flavour) they are accepted only wi << 
656     G4double probSame = theParameters->GetProb << 
657     const G4int MaxCount = 100;                << 
658     G4int count = 0, otherExchangedQ = 0;      << 
659     do {                                       << 
660       if ( exchangedQ != otherFirstQ  ||  G4Un << 
661         otherExchangedQ = otherFirstQ; otherFi << 
662       } else {                                 << 
663         if ( exchangedQ != otherSecondQ  ||  G << 
664           otherExchangedQ = otherSecondQ; othe << 
665         } else {                               << 
666           if ( exchangedQ != otherThirdQ  ||   << 
667             otherExchangedQ = otherThirdQ; oth << 
668           }                                    << 
669         }                                      << 
670       }                                        << 
671     } while ( otherExchangedQ == 0  &&  ++coun << 
672     if ( count >= MaxCount ) return returnCode << 
673     // Swap (between projectile and target had << 
674     // as "exchanged" quarks.                  << 
675     if ( Ksi < 0.333333 ) {                    << 
676       firstQ = exchangedQ;                     << 
677     } else if ( 0.333333 <= Ksi  &&  Ksi < 0.6 << 
678       secondQ = exchangedQ;                    << 
679     } else {                                   << 
680       thirdQ = exchangedQ;                     << 
681     }                                          << 
682     if ( isProjectileExchangedQ ) {            << 
683       ProjQ1 = firstQ;      ProjQ2 = secondQ;  << 
684       TargQ1 = otherFirstQ; TargQ2 = otherSeco << 
685     } else {                                   << 
686       TargQ1 = firstQ;      TargQ2 = secondQ;  << 
687       ProjQ1 = otherFirstQ; ProjQ2 = otherSeco << 
688     }                                          << 
689     #ifdef debugFTFexcitation                  << 
690     G4cout << "Exchange Qs Pr  Tr " << ( isPro << 
691            << " " << ( isProjectileExchangedQ  << 
692     #endif                                     << 
693                                                << 
694     NewProjCode = NewNucleonId( ProjQ1, ProjQ2 << 
695     NewTargCode = NewNucleonId( TargQ1, TargQ2 << 
696     // Decide whether the new projectile hadro << 
697     // then decide whether the new target hadr << 
698     // Notice that a Delta particle has the la << 
699     // whereas a nucleon has "2" (because its  << 
700     // If the new projectile hadron or the new << 
701     // constituent quark, then skip this part  << 
702     // excited charm and bottom hadrons).      << 
703     for ( G4int iHadron = 0; iHadron < 2; iHad << 
704       // First projectile hadron, then target  << 
705       G4int codeQ1 = ProjQ1, codeQ2 = ProjQ2,  << 
706       G4double massConstraint = common.M0targe << 
707       G4bool isHadronADelta = ( projectile->Ge << 
708       if ( iHadron == 1 ) {  // Target hadron  << 
709         codeQ1 = TargQ1, codeQ2 = TargQ2, code << 
710         massConstraint = common.M0projectile;  << 
711         isHadronADelta = ( target->GetDefiniti << 
712       }                                        << 
713       if ( codeQ1 > 3  ||  codeQ2 > 3  ||  cod << 
714       if ( codeQ1 == codeQ2  &&  codeQ1 == cod << 
715         newHadCode += 2;  // Delta++ (uuu) or  << 
716       } else if ( isHadronADelta ) {  // Hadro << 
717         if ( G4UniformRand() > DeltaProbAtQuar << 
718           newHadCode += 2;  // Delta+ (uud) or << 
719         } else {                               << 
720           newHadCode += 0;  // No delta (so th << 
721         }                                      << 
722       } else {  // Hadron (projectile or targe << 
723         if ( G4UniformRand() < DeltaProbAtQuar << 
724              common.SqrtS > G4ParticleTable::G << 
725                             + massConstraint ) << 
726           newHadCode += 2;  // Delta+ (uud) or << 
727         } else {                               << 
728           newHadCode += 0;  // No delta (so th << 
729         }                                      << 
730       }                                        << 
731       if ( iHadron == 0 ) {  // Projectile had << 
732         NewProjCode = newHadCode;              << 
733       } else {               // Target hadron  << 
734         NewTargCode = newHadCode;              << 
735       }                                        << 
736     }                                          << 
737     #ifdef debugFTFexcitation                  << 
738     G4cout << "NewProjCode NewTargCode " << Ne << 
739     #endif                                     << 
740                                                << 
741     // Protection against:                     << 
742     // - Lambda* (i.e. excited Lambda state)   << 
743     // - Sigma*  (i.e. excited Sigma hyperon s << 
744     // - Xi*     (i.e. excited Xi hyperon stat << 
745     if ( NewProjCode == 3124  ||   // Lambda*  << 
746    NewProjCode == 3224  ||   // Sigma*+ NOT ex << 
747    NewProjCode == 3214  ||   // Sigma*0 NOT ex << 
748    NewProjCode == 3114  ||   // Sigma*- NOT ex << 
749    NewProjCode == 3324  ||   // Xi*0    NOT ex << 
750    NewProjCode == 3314  ) {  // Xi*-    NOT ex << 
751       //G4cout << "G4DiffractiveExcitation::Ex << 
752       //       << NewProjCode << G4endl;       << 
753       NewProjCode -= 2;  // Corresponding grou << 
754     }                                          << 
755     if ( NewTargCode == 3124  ||   // Lambda*  << 
756    NewTargCode == 3224  ||   // Sigma*+ NOT ex << 
757    NewTargCode == 3214  ||   // Sigma*0 NOT ex << 
758    NewTargCode == 3114  ||   // Sigma*- NOT ex << 
759    NewTargCode == 3324  ||   // Xi*0    NOT ex << 
760    NewTargCode == 3314  ) {  // Xi*-    NOT ex << 
761       //G4cout << "G4DiffractiveExcitation::Ex << 
762       //       << NewTargCode << G4endl;       << 
763       NewTargCode -= 2;  // Corresponding grou << 
764     }                                          << 
765                                                << 
766     // Special treatment for charmed and botto << 
767     // so we need to transform them by hand to << 
768     #ifdef debug_heavyHadrons                  << 
769     G4int initialNewProjCode = NewProjCode, in << 
770     #endif                                     << 
771     if      ( NewProjCode == 4322 ) NewProjCod << 
772     else if ( NewProjCode == 4312 ) NewProjCod << 
773     else if ( NewProjCode == 5312 ) NewProjCod << 
774     else if ( NewProjCode == 5322 ) NewProjCod << 
775     if      ( NewTargCode == 4322 ) NewTargCod << 
776     else if ( NewTargCode == 4312 ) NewTargCod << 
777     else if ( NewTargCode == 5312 ) NewTargCod << 
778     else if ( NewTargCode == 5322 ) NewTargCod << 
779     #ifdef debug_heavyHadrons                  << 
780     if ( NewProjCode != initialNewProjCode  || << 
781       G4cout << "G4DiffractiveExcitation::Exci << 
782              << "\t heavy baryon into an exist << 
783       if ( NewProjCode != initialNewProjCode ) << 
784   G4cout << "\t \t projectile baryon with pdgC << 
785          << " into pdgCode=" << NewProjCode << << 
786       }                                        << 
787       if ( NewTargCode != initialNewTargCode ) << 
788         G4cout << "\t \t target baryon with pd << 
789          << " into pdgCode=" << NewTargCode << << 
790       }                                        << 
791     }                                          << 
792     #endif                                     << 
793                                                << 
794     // Sampling of the masses of the projectil << 
795     // Because of energy conservation, the ord << 
796     // randomly, half of the time we sample fi << 
797     // then the projectile nucleon mass, and t << 
798     // sample first the projectile nucleon mas << 
799     G4VSplitableHadron* firstHadron  = target; << 
800     G4VSplitableHadron* secondHadron = project << 
801     G4int firstHadronCode = NewTargCode, secon << 
802     G4double massConstraint = common.M0project << 
803     G4bool isFirstTarget = true;               << 
804     if ( G4UniformRand() < 0.5 ) {             << 
805       // Sample first the projectile nucleon m << 
806       firstHadron  = projectile;      secondHa << 
807       firstHadronCode = NewProjCode;  secondHa << 
808       massConstraint = common.M0target;        << 
809       isFirstTarget = false;                   << 
810     }                                          << 
811     G4double Mtest1st = 0.0, Mtest2nd = 0.0, M << 
812     for ( int iSamplingCase = 0; iSamplingCase << 
813       G4VSplitableHadron* aHadron = firstHadro << 
814       G4int aHadronCode = firstHadronCode;     << 
815       if ( iSamplingCase == 1 ) {  // Second n << 
816         aHadron = secondHadron; aHadronCode =  << 
817       }                                        << 
818       G4double MtestHadron = 0.0, MminHadron = << 
819       if ( aHadron->GetStatus() == 1  ||  aHad << 
820         TestParticle = G4ParticleTable::GetPar << 
821         if ( ! TestParticle ) return returnCod << 
822         MminHadron = common.BrW.GetMinimumMass << 
823         if ( common.SqrtS - massConstraint < M << 
824         if ( TestParticle->GetPDGWidth() == 0. << 
825           MtestHadron = common.BrW.SampleMass( << 
826         } else {                               << 
827           const G4int maxNumberOfAttempts = 50 << 
828           G4int attempts = 0;                  << 
829           while ( attempts < maxNumberOfAttemp << 
830             attempts++;                        << 
831             MtestHadron = common.BrW.SampleMas << 
832                                                << 
833             if ( common.SqrtS < MtestHadron +  << 
834               continue;  // Kinematically unac << 
835             } else {                           << 
836               break;     // Kinematically acce << 
837             }                                  << 
838           }                                    << 
839           if ( attempts >= maxNumberOfAttempts << 
840         }                                      << 
841       }                                        << 
842       if ( iSamplingCase == 0 ) {              << 
843         Mtest1st = MtestHadron;  Mmin1st = Mmi << 
844       } else {                                 << 
845         Mtest2nd = MtestHadron;  Mmin2nd = Mmi << 
846       }                                        << 
847     }  // End for loop on the two sampling cas << 
848     if ( isFirstTarget ) {                     << 
849       MtestTr = Mtest1st;    MtestPr = Mtest2n << 
850       common.MminTarget = Mmin1st;  common.Mmi << 
851     } else {                                   << 
852       MtestTr = Mtest2nd;    MtestPr = Mtest1s << 
853       common.MminTarget = Mmin2nd;  common.Mmi << 
854     }                                          << 
855                                                << 
856     if ( MtestPr != 0.0 ) {                    << 
857       common.M0projectile = MtestPr;           << 
858       common.M0projectile2 = common.M0projecti << 
859       common.ProjectileDiffStateMinMass =    c << 
860       common.ProjectileNonDiffStateMinMass = c << 
861     }                                          << 
862     if ( MtestTr != 0.0 ) {                    << 
863       common.M0target = MtestTr;               << 
864       common.M0target2 = common.M0target * com << 
865       common.TargetDiffStateMinMass    = commo << 
866       common.TargetNonDiffStateMinMass = commo << 
867     }                                          << 
868                                                << 
869   }  // End of if ( common.absProjectilePDGcod << 
870                                                << 
871   // If we assume that final state hadrons aft << 
872   // in the ground states, we have to put      << 
873   if ( common.SqrtS < common.M0projectile + co << 
874                                                << 
875   common.PZcms2 = ( sqr( common.S ) + sqr( com << 
876                     - 2.0 * ( common.S * ( com << 
877                               + common.M0proje << 
878   #ifdef debugFTFexcitation                    << 
879   G4cout << "At the end// NewProjCode " << New << 
880          << "At the end// NewTargCode " << New << 
881          << "M0pr  M0tr  SqS " << common.M0pro << 
882          << common.SqrtS << G4endl             << 
883          << "M0pr2 M0tr2 SqS " << common.M0pro << 
884          << common.SqrtS << G4endl             << 
885          << "PZcms2 after the change " << comm << 
886   #endif                                       << 
887   if ( common.PZcms2 < 0.0 ) return returnCode << 
888                                                << 
889   projectile->SetDefinition( G4ParticleTable:: << 
890   target->SetDefinition( G4ParticleTable::GetP << 
891   common.PZcms = std::sqrt( common.PZcms2 );   << 
892   common.Pprojectile.setPz( common.PZcms );    << 
893   common.Pprojectile.setE( std::sqrt( common.M << 
894   common.Ptarget.setPz(    -common.PZcms );    << 
895   common.Ptarget.setE( std::sqrt( common.M0tar << 
896   #ifdef debugFTFexcitation                    << 
897   G4cout << "Proj Targ and Proj+Targ in CMS" < << 
898          << common.Ptarget << G4endl << common << 
899   #endif                                       << 
900                                                << 
901   if ( projectile->GetStatus() != 0 ) projecti << 
902   if ( target->GetStatus()     != 0 ) target-> << 
903                                                << 
904   // Check for possible excitation of the part << 
905   if ( common.SqrtS < common.M0projectile + co << 
906        common.SqrtS < common.ProjectileDiffSta << 
907        common.ProbOfDiffraction == 0.0 ) commo << 
908                                                << 
909   if ( G4UniformRand() > common.ProbExc ) {  / << 
910     #ifdef debugFTFexcitation                  << 
911     G4cout << "Make elastic scattering of new  << 
912     #endif                                     << 
913     common.Pprojectile.transform( common.toLab << 
914     common.Ptarget.transform( common.toLab );  << 
915     projectile->Set4Momentum( common.Pprojecti << 
916     target->Set4Momentum( common.Ptarget );    << 
917     G4bool Result = theElastic->ElasticScatter << 
918     #ifdef debugFTFexcitation                  << 
919     G4cout << "Result of el. scatt " << Result << 
920            << G4endl << projectile->Get4Moment << 
921            << projectile->Get4Momentum() + tar << 
922            << (projectile->Get4Momentum() + ta << 
923     #endif                                     << 
924     if ( Result ) returnCode = 0;  // successf << 
925     return returnCode;                         << 
926   }                                            << 
927                                                << 
928   #ifdef debugFTFexcitation                    << 
929   G4cout << "Make excitation of new hadrons" < << 
930   #endif                                       << 
931                                                << 
932   // Redefinition of ProbOfDiffraction because << 
933   common.ProbOfDiffraction = common.ProbProjec << 
934   if ( common.ProbOfDiffraction != 0.0 ) {     << 
935     common.ProbProjectileDiffraction /= common << 
936     common.ProbTargetDiffraction     /= common << 
937   }                                            << 
938                                                << 
939   return returnCode = 1;  // successfully comp << 
940 }                                                  57 }
941                                                    58 
942 //-------------------------------------------- << 
943                                                << 
944 G4bool G4DiffractiveExcitation::               << 
945 ExciteParticipants_doDiffraction( G4VSplitable << 
946                                   G4FTFParamet << 
947                                   G4Diffractiv << 
948   // Second of the three utility methods used  << 
949   // it does the sampling for the diffraction  << 
950                                                << 
951   G4bool isProjectileDiffraction = false;      << 
952   if ( G4UniformRand() < common.ProbProjectile << 
953     isProjectileDiffraction = true;            << 
954     #ifdef debugFTFexcitation                  << 
955     G4cout << "projectile diffraction" << G4en << 
956     #endif                                     << 
957     common.ProjMassT2 = common.ProjectileDiffS << 
958     common.ProjMassT  = common.ProjectileDiffS << 
959     common.TargMassT2 = common.M0target2;      << 
960     common.TargMassT  = common.M0target;       << 
961   } else {                                     << 
962     #ifdef debugFTFexcitation                  << 
963     G4cout << "Target diffraction" << G4endl;  << 
964     #endif                                     << 
965     common.ProjMassT2 = common.M0projectile2;  << 
966     common.ProjMassT  = common.M0projectile;   << 
967     common.TargMassT2 = common.TargetDiffState << 
968     common.TargMassT  = common.TargetDiffState << 
969   }                                            << 
970                                                << 
971   // Check whether the interaction is possible << 
972   if ( common.SqrtS < common.ProjMassT + commo << 
973                                                << 
974   common.PZcms2 = ( sqr( common.S ) + sqr( com << 
975                     - 2.0 * ( common.S * ( com << 
976                           + common.ProjMassT2  << 
977   if ( common.PZcms2 < 0.0 ) return false;     << 
978   common.maxPtSquare = common.PZcms2;          << 
979                                                << 
980   G4double DiffrAveragePt2 = theParameters->Ge << 
981   G4bool loopCondition = true;                 << 
982   G4int whilecount = 0;                        << 
983   do {  // Generate pt and mass of projectile  << 
984                                                << 
985     whilecount++;                              << 
986     if ( whilecount > 1000 ) {                 << 
987       common.Qmomentum = G4LorentzVector( 0.0, << 
988       return false;  //  Ignore this interacti << 
989     };                                         << 
990                                                << 
991     common.Qmomentum = G4LorentzVector( Gaussi << 
992     common.Pt2 = G4ThreeVector( common.Qmoment << 
993     if ( isProjectileDiffraction ) {  // proje << 
994       common.ProjMassT2 = common.ProjectileDif << 
995       common.TargMassT2 = common.M0target2 + c << 
996     } else {                          // targe << 
997       common.ProjMassT2 = common.M0projectile2 << 
998       common.TargMassT2 = common.TargetDiffSta << 
999     }                                          << 
1000     common.ProjMassT = std::sqrt( common.Proj << 
1001     common.TargMassT = std::sqrt( common.Targ << 
1002     if ( common.SqrtS < common.ProjMassT + co << 
1003                                               << 
1004     common.PZcms2 = ( sqr( common.S ) + sqr(  << 
1005                       - 2.0 * ( common.S * (  << 
1006                                 + common.Proj << 
1007     if ( common.PZcms2 < 0.0 ) continue;      << 
1008                                               << 
1009     common.PZcms = std::sqrt( common.PZcms2 ) << 
1010     if ( isProjectileDiffraction ) {  // proj << 
1011       common.PMinusMin = std::sqrt( common.Pr << 
1012       common.PMinusMax = common.SqrtS - commo << 
1013       common.PMinusNew = ChooseP( common.PMin << 
1014       common.TMinusNew = common.SqrtS - commo << 
1015       common.Qminus = common.Ptarget.minus()  << 
1016       common.TPlusNew = common.TargMassT2 / c << 
1017       common.Qplus = common.Ptarget.plus() -  << 
1018       common.Qmomentum.setPz( (common.Qplus - << 
1019       common.Qmomentum.setE(  (common.Qplus + << 
1020       loopCondition = ( ( common.Pprojectile  << 
1021                         common.ProjectileDiff << 
1022     } else {                          // targ << 
1023       common.TPlusMin = std::sqrt( common.Tar << 
1024       common.TPlusMax = common.SqrtS - common << 
1025       common.TPlusNew = ChooseP( common.TPlus << 
1026       common.PPlusNew = common.SqrtS - common << 
1027       common.Qplus = common.PPlusNew - common << 
1028       common.PMinusNew = common.ProjMassT2 /  << 
1029       common.Qminus = common.PMinusNew - comm << 
1030       common.Qmomentum.setPz( (common.Qplus - << 
1031       common.Qmomentum.setE(  (common.Qplus + << 
1032       loopCondition =  ( ( common.Ptarget - c << 
1033                          common.TargetDiffSta << 
1034     }                                         << 
1035                                               << 
1036   } while ( loopCondition );  /* Loop checkin << 
1037           // Repeat the sampling because ther << 
1038                                               << 
1039   if ( isProjectileDiffraction ) {  // projec << 
1040     projectile->SetStatus( 0 );               << 
1041     if ( projectile->GetStatus() == 2 ) proje << 
1042     if ( target->GetStatus() == 1  &&  target << 
1043   } else {                          // target << 
1044     target->SetStatus( 0 );                   << 
1045   }                                           << 
1046                                               << 
1047   return true;                                << 
1048 }                                             << 
1049                                               << 
1050 //------------------------------------------- << 
1051                                               << 
1052 G4bool G4DiffractiveExcitation::                  59 G4bool G4DiffractiveExcitation::
1053 ExciteParticipants_doNonDiffraction( G4VSplit <<  60   ExciteParticipants(G4VSplitableHadron *projectile, G4VSplitableHadron *target) const
1054                                      G4VSplit <<  61 {
1055                                      G4FTFPar << 
1056                                      G4Diffra << 
1057   // Third of the three utility methods used  << 
1058   // it does the sampling for the non-diffrac << 
1059                                               << 
1060   #ifdef debugFTFexcitation                   << 
1061   G4cout << "Non-diffraction process" << G4en << 
1062   #endif                                      << 
1063                                               << 
1064   // Check whether the interaction is possibl << 
1065   common.ProjMassT2 = common.ProjectileNonDif << 
1066   common.ProjMassT  = common.ProjectileNonDif << 
1067   common.TargMassT2 = common.TargetNonDiffSta << 
1068   common.TargMassT  = common.TargetNonDiffSta << 
1069   if ( common.SqrtS < common.ProjMassT + comm << 
1070                                               << 
1071   common.PZcms2 = ( sqr( common.S ) + sqr( co << 
1072                   - 2.0 * ( common.S * ( comm << 
1073                         + common.ProjMassT2 * << 
1074   common.maxPtSquare = common.PZcms2;         << 
1075                                               << 
1076   G4int whilecount = 0;                       << 
1077   do {  // Generate pt and masses             << 
1078                                               << 
1079     whilecount++;                             << 
1080     if ( whilecount > 1000 ) {                << 
1081       common.Qmomentum = G4LorentzVector( 0.0 << 
1082       return false;  // Ignore this interacti << 
1083     };                                        << 
1084                                               << 
1085     common.Qmomentum = G4LorentzVector( Gauss << 
1086                                               << 
1087     common.Pt2 = G4ThreeVector( common.Qmomen << 
1088     common.ProjMassT2 = common.ProjectileNonD << 
1089     common.ProjMassT  = std::sqrt( common.Pro << 
1090     common.TargMassT2 = common.TargetNonDiffS << 
1091     common.TargMassT  = std::sqrt( common.Tar << 
1092     if ( common.SqrtS < common.ProjMassT + co << 
1093                                               << 
1094     common.PZcms2 =( sqr( common.S ) + sqr( c << 
1095                      - 2.0 * ( common.S * ( c << 
1096                                + common.ProjM << 
1097     if ( common.PZcms2 < 0.0 ) continue;      << 
1098                                               << 
1099     common.PZcms = std::sqrt( common.PZcms2 ) << 
1100     common.PMinusMin = std::sqrt( common.Proj << 
1101     common.PMinusMax = common.SqrtS - common. << 
1102     common.TPlusMin = std::sqrt( common.TargM << 
1103     common.TPlusMax = common.SqrtS - common.P << 
1104                                               << 
1105     if ( G4UniformRand() <= 0.5 ) {  // Rando << 
1106       if ( G4UniformRand() < theParameters->G << 
1107         common.PMinusNew = ChooseP( common.PM << 
1108       } else {                                << 
1109         common.PMinusNew = ( common.PMinusMax << 
1110       }                                       << 
1111       if ( G4UniformRand() < theParameters->G << 
1112         common.TPlusNew = ChooseP( common.TPl << 
1113       } else {                                << 
1114         common.TPlusNew = ( common.TPlusMax - << 
1115       }                                       << 
1116     } else {                                  << 
1117       if ( G4UniformRand() < theParameters->G << 
1118         common.TPlusNew = ChooseP( common.TPl << 
1119       } else {                                << 
1120         common.TPlusNew = ( common.TPlusMax - << 
1121       }                                       << 
1122       if ( G4UniformRand() < theParameters->G << 
1123         common.PMinusNew = ChooseP( common.PM << 
1124       } else {                                << 
1125         common.PMinusNew = ( common.PMinusMax << 
1126       }                                       << 
1127     }                                         << 
1128                                               << 
1129     common.Qminus = common.PMinusNew - common << 
1130     common.Qplus = -( common.TPlusNew - commo << 
1131     common.Qmomentum.setPz( (common.Qplus - c << 
1132     common.Qmomentum.setE(  (common.Qplus + c << 
1133     #ifdef debugFTFexcitation                 << 
1134     G4cout <<"Sampled: Mpr, MdifPr, Mtr, Mdif << 
1135            << ( common.Pprojectile + common.Q << 
1136            << common.ProjectileNonDiffStateMi << 
1137            << ( common.Ptarget - common.Qmome << 
1138            << common.TargetNonDiffStateMinMas << 
1139     #endif                                    << 
1140                                               << 
1141   } while ( ( common.Pprojectile + common.Qmo << 
1142             common.ProjectileNonDiffStateMinM << 
1143             ( common.Ptarget - common.Qmoment << 
1144             common.TargetNonDiffStateMinMass2 << 
1145                                               << 
1146   projectile->SetStatus( 0 );                 << 
1147   target->SetStatus( 0 );                     << 
1148   return true;                                << 
1149 }                                             << 
1150                                               << 
1151                                               << 
1152 //=========================================== << 
1153                                               << 
1154 void G4DiffractiveExcitation::CreateStrings(  << 
1155                                               << 
1156                                               << 
1157                                               << 
1158                                               << 
1159                                               << 
1160   //G4cout << "Create Strings SplitUp " << ha << 
1161   //       << "Defin " << hadron->GetDefiniti << 
1162   //       << "Defin " << hadron->GetDefiniti << 
1163                                               << 
1164   G4bool HadronIsString = hadron->IsSplit();  << 
1165   if( ! HadronIsString ) hadron->SplitUp();   << 
1166                                               << 
1167   G4Parton* start = hadron->GetNextParton();  << 
1168   if ( start == nullptr ) {                   << 
1169     G4cout << " G4FTFModel::String() Error: N << 
1170     FirstString = 0; SecondString = 0;        << 
1171     return;                                   << 
1172   }                                           << 
1173                                               << 
1174   G4Parton* end = hadron->GetNextParton();    << 
1175   if ( end == nullptr ) {                     << 
1176     G4cout << " G4FTFModel::String() Error: N << 
1177     FirstString = 0; SecondString = 0;        << 
1178     return;                                   << 
1179   }                                           << 
1180                                               << 
1181   //G4cout << start << " " << start->GetPDGco << 
1182   //       << G4endl                          << 
1183   //       << "Create string " << start->GetP << 
1184                                               << 
1185   if ( HadronIsString ) {                     << 
1186     if ( isProjectile ) {                     << 
1187       FirstString = new G4ExcitedString( end, << 
1188     } else {                                  << 
1189       FirstString = new G4ExcitedString( end, << 
1190     }                                         << 
1191     FirstString->SetTimeOfCreation( hadron->G << 
1192     FirstString->SetPosition( hadron->GetPosi << 
1193     SecondString = 0;                         << 
1194     return;                                   << 
1195   }                                           << 
1196                                               << 
1197   G4LorentzVector Phadron = hadron->Get4Momen << 
1198   //G4cout << "String mom " << Phadron << G4e << 
1199   G4LorentzVector Pstart( 0.0, 0.0, 0.0, 0.0  << 
1200   G4LorentzVector Pend( 0.0, 0.0, 0.0, 0.0 ); << 
1201   G4LorentzVector Pkink( 0.0, 0.0, 0.0, 0.0 ) << 
1202   G4LorentzVector PkinkQ1( 0.0, 0.0, 0.0, 0.0 << 
1203   G4LorentzVector PkinkQ2( 0.0, 0.0, 0.0, 0.0 << 
1204                                               << 
1205   G4int PDGcode_startQ = std::abs( start->Get << 
1206   G4int PDGcode_endQ   = std::abs(   end->Get << 
1207   //G4cout << "PDGcode_startQ " << PDGcode_st << 
1208                                               << 
1209   G4double Wmin( 0.0 );                       << 
1210   if ( isProjectile ) {                       << 
1211     Wmin = theParameters->GetProjMinDiffMass( << 
1212   } else {                                    << 
1213     Wmin = theParameters->GetTarMinDiffMass() << 
1214   }                                           << 
1215                                               << 
1216   G4double W = hadron->Get4Momentum().mag();  << 
1217   G4double W2 = W*W;                          << 
1218   G4double Pt( 0.0 ), x1( 0.0 ), x3( 0.0 );   << 
1219   G4bool Kink = false;                        << 
1220                                               << 
1221   if ( ! ( ( start->GetDefinition()->GetParti << 
1222                end->GetDefinition()->GetParti << 
1223            ( start->GetDefinition()->GetParti << 
1224                end->GetDefinition()->GetParti << 
1225     // Kinky strings are allowed only for qq- << 
1226     // Kinky strings are impossible for other << 
1227     // according to the analysis of Pbar P in << 
1228                                               << 
1229     if ( W > Wmin ) {  // Kink is possible    << 
1230       if ( hadron->GetStatus() == 0 ) {       << 
1231         G4double Pt2kink = theParameters->Get << 
1232         if ( Pt2kink ) {                      << 
1233           Pt = std::sqrt( Pt2kink * ( G4Pow:: << 
1234         } else {                              << 
1235           Pt = 0.0;                           << 
1236         }                                     << 
1237       } else {                                << 
1238         Pt = 0.0;                             << 
1239       }                                       << 
1240                                               << 
1241       if ( Pt > 500.0*MeV ) {                 << 
1242         G4double Ymax = G4Log( W/2.0/Pt + std << 
1243         G4double Y = Ymax*( 1.0 - 2.0*G4Unifo << 
1244         x1 = 1.0 - Pt/W * G4Exp( Y );         << 
1245         x3 = 1.0 - Pt/W * G4Exp(-Y );         << 
1246         //x2 = 2.0 - x1 - x3;                 << 
1247                                               << 
1248         G4double Mass_startQ = 650.0*MeV;     << 
1249         if ( PDGcode_startQ <  3 ) Mass_start << 
1250         if ( PDGcode_startQ == 3 ) Mass_start << 
1251         if ( PDGcode_startQ == 4 ) Mass_start << 
1252         if ( PDGcode_startQ == 5 ) Mass_start << 
1253         G4double Mass_endQ = 650.0*MeV;       << 
1254         if ( PDGcode_endQ <  3 ) Mass_endQ =  << 
1255         if ( PDGcode_endQ == 3 ) Mass_endQ =  << 
1256         if ( PDGcode_endQ == 4 ) Mass_endQ =  << 
1257         if ( PDGcode_endQ == 5 ) Mass_endQ =  << 
1258                                               << 
1259         G4double P2_1 = W2*x1*x1/4.0 - Mass_e << 
1260         G4double P2_3 = W2*x3*x3/4.0 - Mass_s << 
1261         G4double P2_2 = sqr( (2.0 - x1 - x3)* << 
1262         if ( P2_1 <= 0.0  ||  P2_3 <= 0.0 ) { << 
1263           Kink = false;                       << 
1264         } else {                              << 
1265           G4double P_1 = std::sqrt( P2_1 );   << 
1266           G4double P_2 = std::sqrt( P2_2 );   << 
1267           G4double P_3 = std::sqrt( P2_3 );   << 
1268           G4double CosT12 = ( P2_3 - P2_1 - P << 
1269           G4double CosT13 = ( P2_2 - P2_1 - P << 
1270                                               << 
1271           if ( std::abs( CosT12 ) > 1.0  ||   << 
1272             Kink = false;                     << 
1273           } else {                            << 
1274             Kink = true;                      << 
1275             Pt = P_2 * std::sqrt( 1.0 - CosT1 << 
1276             Pstart.setPx( -Pt ); Pstart.setPy << 
1277             Pend.setPx(   0.0 ); Pend.setPy(  << 
1278             Pkink.setPx(   Pt ); Pkink.setPy( << 
1279             Pstart.setE( x3*W/2.0 );          << 
1280             Pkink.setE( Pkink.vect().mag() ); << 
1281             Pend.setE( x1*W/2.0 );            << 
1282                                               << 
1283             G4double XkQ = GetQuarkFractionOf << 
1284             if ( Pkink.getZ() > 0.0 ) {       << 
1285               if ( XkQ > 0.5 ) {              << 
1286                 PkinkQ1 = XkQ*Pkink;          << 
1287               } else {                        << 
1288                 PkinkQ1 = (1.0 - XkQ)*Pkink;  << 
1289               }                               << 
1290             } else {                          << 
1291               if ( XkQ > 0.5 ) {              << 
1292                 PkinkQ1 = (1.0 - XkQ)*Pkink;  << 
1293               } else {                        << 
1294                 PkinkQ1 = XkQ*Pkink;          << 
1295               }                               << 
1296             }                                 << 
1297                                               << 
1298             PkinkQ2 = Pkink - PkinkQ1;        << 
1299             // Minimizing Pt1^2+Pt3^2         << 
1300             G4double Cos2Psi = ( sqr(x1) - sq << 
1301                                std::sqrt( sqr << 
1302             G4double Psi = std::acos( Cos2Psi << 
1303                                               << 
1304             G4LorentzRotation Rotate;         << 
1305             if ( isProjectile ) {             << 
1306               Rotate.rotateY( Psi );          << 
1307             } else {                          << 
1308               Rotate.rotateY( pi + Psi );     << 
1309             }                                 << 
1310             Rotate.rotateZ( twopi * G4Uniform << 
1311             Pstart *= Rotate;                 << 
1312             Pkink *= Rotate;                  << 
1313             PkinkQ1 *= Rotate;                << 
1314             PkinkQ2 *= Rotate;                << 
1315             Pend *= Rotate;                   << 
1316           }                                   << 
1317         }  // End of if ( P2_1 <= 0.0  ||  P2 << 
1318       }  // End of if ( Pt > 500.0*MeV )      << 
1319     } // End of if ( W > Wmin ) : check for a << 
1320   }  // end of qq-q string selection          << 
1321                                               << 
1322   if ( Kink ) {  // Kink is possible          << 
1323                                               << 
1324     //G4cout << "Kink is sampled!" << G4endl; << 
1325     std::vector< G4double > QuarkProbabilitie << 
1326         theParameters->GetQuarkProbabilitiesA << 
1327                                               << 
1328     G4int QuarkInGluon( 1 ); G4double Ksi = G << 
1329     for ( unsigned int Iq = 0; Iq < 3; Iq++ ) << 
1330       //G4cout << "Iq " << Iq << G4endl;      << 
1331       if ( Ksi > QuarkProbabilitiesAtGluonSpl << 
1332     }                                         << 
1333     //G4cout << "Last Iq " << QuarkInGluon << << 
1334     G4Parton* Gquark = new G4Parton( QuarkInG << 
1335     G4Parton* Ganti_quark = new G4Parton( -Qu << 
1336     //G4cout << "Lorentz " << G4endl;         << 
1337                                               << 
1338     G4LorentzRotation toCMS( -1 * Phadron.boo << 
1339     G4LorentzRotation toLab( toCMS.inverse()  << 
1340     //G4cout << "Pstart " << Pstart << G4endl << 
1341     //G4cout << "Pend   " << Pend << G4endl;  << 
1342     //G4cout << "Kink1  " <<PkinkQ1<<G4endl;  << 
1343     //G4cout << "Kink2  " <<PkinkQ2<<G4endl;  << 
1344     //G4cout << "Pstart " << Pstart << G4endl << 
1345                                               << 
1346     Pstart.transform( toLab );  start->Set4Mo << 
1347     PkinkQ1.transform( toLab );               << 
1348     PkinkQ2.transform( toLab );               << 
1349     Pend.transform( toLab );    end->Set4Mome << 
1350     //G4cout << "Pstart " << Pstart << G4endl << 
1351     //G4cout << "Pend   " << Pend << G4endl;  << 
1352     //G4cout << "Defin " << hadron->GetDefini << 
1353     //G4cout << "Defin " << hadron->GetDefini << 
1354                                               << 
1355     //G4int absPDGcode = std::abs( hadron->Ge << 
1356     G4int absPDGcode = 1500;                  << 
1357     if ( start->GetDefinition()->GetParticleS << 
1358          end->GetDefinition()->GetParticleSub << 
1359       absPDGcode = 110;                       << 
1360     }                                         << 
1361     //G4cout << "absPDGcode " << absPDGcode < << 
1362                                               << 
1363     if ( absPDGcode < 1000 ) {  // meson      << 
1364       if ( isProjectile ) { // Projectile     << 
1365         if ( end->GetDefinition()->GetPDGEnco << 
1366           FirstString  = new G4ExcitedString( << 
1367           SecondString = new G4ExcitedString( << 
1368           Ganti_quark->Set4Momentum( PkinkQ1  << 
1369           Gquark->Set4Momentum( PkinkQ2 );    << 
1370         } else {  // Anti_Quark on the end    << 
1371           FirstString  = new G4ExcitedString( << 
1372           SecondString = new G4ExcitedString( << 
1373           Gquark->Set4Momentum( PkinkQ1 );    << 
1374           Ganti_quark->Set4Momentum( PkinkQ2  << 
1375         }                                     << 
1376       } else {  // Target                     << 
1377         if ( end->GetDefinition()->GetPDGEnco << 
1378           FirstString  = new G4ExcitedString( << 
1379           SecondString = new G4ExcitedString( << 
1380           Ganti_quark->Set4Momentum( PkinkQ2  << 
1381           Gquark->Set4Momentum( PkinkQ1 );    << 
1382         } else {  // Anti_Quark on the end    << 
1383           FirstString  = new G4ExcitedString( << 
1384           SecondString = new G4ExcitedString( << 
1385           Gquark->Set4Momentum( PkinkQ2 );    << 
1386           Ganti_quark->Set4Momentum( PkinkQ1  << 
1387         }                                     << 
1388       }                                       << 
1389     } else {  // Baryon/AntiBaryon            << 
1390       if ( isProjectile ) {  // Projectile    << 
1391         if ( end->GetDefinition()->GetParticl << 
1392              end->GetDefinition()->GetPDGEnco << 
1393           FirstString  = new G4ExcitedString( << 
1394           SecondString = new G4ExcitedString( << 
1395           Gquark->Set4Momentum( PkinkQ1 );    << 
1396           Ganti_quark->Set4Momentum( PkinkQ2  << 
1397         } else {                            / << 
1398           FirstString  = new G4ExcitedString( << 
1399           SecondString = new G4ExcitedString( << 
1400           Ganti_quark->Set4Momentum( PkinkQ1  << 
1401           Gquark->Set4Momentum( PkinkQ2 );    << 
1402         }                                     << 
1403       } else {  // Target                     << 
1404         if ( end->GetDefinition()->GetParticl << 
1405              end->GetDefinition()->GetPDGEnco << 
1406           Gquark->Set4Momentum( PkinkQ1 );    << 
1407           Ganti_quark->Set4Momentum( PkinkQ2  << 
1408           FirstString  = new G4ExcitedString( << 
1409           SecondString = new G4ExcitedString( << 
1410         } else {  // Anti_DiQuark on the end  << 
1411           FirstString  = new G4ExcitedString( << 
1412           SecondString = new G4ExcitedString( << 
1413           Gquark->Set4Momentum( PkinkQ2 );    << 
1414           Ganti_quark->Set4Momentum( PkinkQ1  << 
1415         }                                     << 
1416       }                                       << 
1417     }                                         << 
1418                                               << 
1419     FirstString->SetTimeOfCreation( hadron->G << 
1420     FirstString->SetPosition( hadron->GetPosi << 
1421     SecondString->SetTimeOfCreation( hadron-> << 
1422     SecondString->SetPosition( hadron->GetPos << 
1423                                               << 
1424   } else {  // Kink is impossible             << 
1425                                               << 
1426     if ( isProjectile ) {                     << 
1427       FirstString = new G4ExcitedString( end, << 
1428     } else {                                  << 
1429       FirstString = new G4ExcitedString( end, << 
1430     }                                         << 
1431     FirstString->SetTimeOfCreation( hadron->G << 
1432     FirstString->SetPosition( hadron->GetPosi << 
1433     SecondString = 0;                         << 
1434     // momenta of string ends                 << 
1435     G4LorentzVector HadronMom = hadron->Get4M << 
1436     G4LorentzVector Pstart1 = G4LorentzVector << 
1437     G4LorentzVector   Pend1 = G4LorentzVector << 
1438     G4double Pz  = HadronMom.pz();            << 
1439     G4double Eh  = HadronMom.e();             << 
1440     G4double Pt2 = sqr( HadronMom.px() ) + sq << 
1441     G4double Mt2 = HadronMom.mt2();           << 
1442     G4double Exp = std::sqrt( sqr(Pz) + ( sqr << 
1443     G4double Pzq  = Pz/2.0 - Exp;             << 
1444     G4double Eq   = std::sqrt( sqr(Pzq) + Pt2 << 
1445     G4double Pzqq = Pz/2.0 + Exp;             << 
1446     G4double Eqq  = std::sqrt( sqr(Pzqq) + Pt << 
1447     start->Set4Momentum( Pstart1 );           << 
1448     end->Set4Momentum( Pend1 );               << 
1449     Pstart = Pstart1;  Pend = Pend1;          << 
1450                                               << 
1451   }  // End of "if (Kink)"                    << 
1452                                               << 
1453   //G4cout << "Quarks in the string at creati << 
1454   //       << " " << FirstString->GetLeftPart << 
1455   //       << FirstString << " " << SecondStr << 
1456                                               << 
1457   #ifdef G4_FTFDEBUG                          << 
1458   G4cout << " generated string flavors        << 
1459          << end->GetPDGcode() << G4endl << "  << 
1460          << start->Get4Momentum() << "mass :  << 
1461          << " generated string momenta: Diqua << 
1462          << end->Get4Momentum().mag() << G4en << 
1463          << Pstart + Pend << G4endl << " Orig << 
1464          << hadron->Get4Momentum() << " "<<ha << 
1465   #endif                                      << 
1466                                               << 
1467   return;                                     << 
1468 }                                             << 
1469                                               << 
1470                                               << 
1471 //=========================================== << 
1472                                               << 
1473 G4double G4DiffractiveExcitation::ChooseP( G4 << 
1474   // Choose an x between Xmin and Xmax with P << 
1475   // To be improved...                        << 
1476   G4double range = Pmax - Pmin;               << 
1477   if ( Pmin <= 0.0 || range <= 0.0 ) {        << 
1478     G4cout << " Pmin, range : " << Pmin << "  << 
1479     throw G4HadronicException( __FILE__, __LI << 
1480                                "G4Diffractive << 
1481   }                                           << 
1482   G4double P = Pmin * G4Pow::GetInstance()->p << 
1483   //G4double P = (Pmax - Pmin) * G4UniformRan << 
1484   return P;                                   << 
1485 }                                             << 
1486                                               << 
1487                                                   62 
1488 //=========================================== <<  63      G4LorentzVector Pprojectile=projectile->Get4Momentum();
1489                                               << 
1490 G4ThreeVector G4DiffractiveExcitation::Gaussi << 
1491   //  @@ this method is used in FTFModel as w << 
1492   G4double Pt2( 0.0 );                        << 
1493   if ( AveragePt2 <= 0.0 ) {                  << 
1494     Pt2 = 0.0;                                << 
1495   } else {                                    << 
1496     Pt2 = -AveragePt2 * G4Log( 1.0 + G4Unifor << 
1497                                        ( G4Ex << 
1498   }                                           << 
1499   G4double Pt = std::sqrt( Pt2 );             << 
1500   G4double phi = G4UniformRand() * twopi;     << 
1501   return G4ThreeVector( Pt * std::cos( phi ), << 
1502 }                                             << 
1503                                               << 
1504                                               << 
1505 //=========================================== << 
1506                                               << 
1507 G4double G4DiffractiveExcitation::GetQuarkFra << 
1508   G4double z, yf;                             << 
1509   const G4int maxNumberOfLoops = 10000;       << 
1510   G4int loopCounter = 0;                      << 
1511   do {                                        << 
1512     z = zmin + G4UniformRand() * (zmax - zmin << 
1513     yf = z*z + sqr(1.0 - z);                  << 
1514   } while ( ( G4UniformRand() > yf ) &&       << 
1515             ++loopCounter < maxNumberOfLoops  << 
1516   if ( loopCounter >= maxNumberOfLoops ) {    << 
1517     z = 0.5*(zmin + zmax);  // Just something << 
1518   }                                           << 
1519   return z;                                   << 
1520 }                                             << 
1521                                               << 
1522                                               << 
1523 //=========================================== << 
1524                                               << 
1525 void G4DiffractiveExcitation::UnpackMeson( co << 
1526   G4int absIdPDG = std::abs( IdPDG );         << 
1527   if ( ! ( absIdPDG == 111 || absIdPDG == 221 << 
1528            absIdPDG == 441 || absIdPDG == 443 << 
1529     // All other projectile mesons (including << 
1530     Q1 =  absIdPDG / 100;                     << 
1531     Q2 = (absIdPDG % 100) / 10;               << 
1532     G4int anti = 1 - 2 * ( std::max( Q1, Q2 ) << 
1533     if ( IdPDG < 0 ) anti *= -1;              << 
1534     Q1 *= anti;                               << 
1535     Q2 *= -1 * anti;                          << 
1536   } else {                                    << 
1537     if ( absIdPDG == 441 || absIdPDG == 443 ) << 
1538       Q1 =  4; Q2 = -4;                       << 
1539     } else if ( absIdPDG == 553 ) {           << 
1540       Q1 =  5; Q2 = -5;                       << 
1541     } else {                                  << 
1542       if ( G4UniformRand() < 0.5 ) {          << 
1543   Q1 = 1; Q2 = -1;                            << 
1544       } else {                                << 
1545   Q1 = 2; Q2 = -2;                            << 
1546       }                                       << 
1547     }                                         << 
1548   }                                           << 
1549   return;                                     << 
1550 }                                             << 
1551                                               << 
1552                                               << 
1553 //=========================================== << 
1554                                               << 
1555 void G4DiffractiveExcitation::UnpackBaryon( G << 
1556                                             G << 
1557   Q1 = IdPDG          / 1000;                 << 
1558   Q2 = (IdPDG % 1000) / 100;                  << 
1559   Q3 = (IdPDG % 100)  / 10;                   << 
1560   return;                                     << 
1561 }                                             << 
1562                                               << 
1563                                               << 
1564 //=========================================== << 
1565                                               << 
1566 G4int G4DiffractiveExcitation::NewNucleonId(  << 
1567   // Order the three integers in such a way t << 
1568   G4int TmpQ( 0 );                            << 
1569   if ( Q3 > Q2 ) {                            << 
1570     TmpQ = Q2;                                << 
1571     Q2 = Q3;                                  << 
1572     Q3 = TmpQ;                                << 
1573   } else if ( Q3 > Q1 ) {                     << 
1574     TmpQ = Q1;                                << 
1575     Q1 = Q3;                                  << 
1576     Q3 = TmpQ;                                << 
1577   }                                           << 
1578   if ( Q2 > Q1 ) {                            << 
1579     TmpQ = Q1;                                << 
1580     Q1 = Q2;                                  << 
1581     Q2 = TmpQ;                                << 
1582   }                                           << 
1583   // By now Q1 >= Q2 >= Q3                    << 
1584   G4int NewCode = Q1*1000 + Q2*100 + Q3*10 +  << 
1585   return NewCode;                             << 
1586 }                                             << 
1587                                               << 
1588                                               << 
1589 //=========================================== << 
1590                                               << 
1591 G4DiffractiveExcitation::G4DiffractiveExcitat << 
1592   throw G4HadronicException( __FILE__, __LINE << 
1593                              "G4DiffractiveEx << 
1594 }                                             << 
1595                                               << 
1596                                               << 
1597 //=========================================== << 
1598                                               << 
1599 const G4DiffractiveExcitation & G4Diffractive << 
1600   throw G4HadronicException( __FILE__, __LINE << 
1601                              "G4DiffractiveEx << 
1602   return *this;                               << 
1603 }                                             << 
1604                                               << 
1605                                               << 
1606 //=========================================== << 
1607                                               << 
1608 G4bool G4DiffractiveExcitation::operator==( c << 
1609   throw G4HadronicException( __FILE__, __LINE << 
1610                              "G4DiffractiveEx << 
1611 }                                             << 
1612                                                   64 
                                                   >>  65 // -------------------- Projectile parameters -----------------------------------
                                                   >>  66            G4bool PutOnMassShell=0;
1613                                                   67 
1614 //=========================================== <<  68 // With de-excitation
1615                                               <<  69 //     G4double M0projectile=projectile->GetDefinition()->GetPDGMass();  
1616 G4bool G4DiffractiveExcitation::operator!= (  <<  70 // Without de-excitation
1617   throw G4HadronicException( __FILE__, __LINE <<  71      G4double M0projectile = Pprojectile.mag();                        
1618                              "G4DiffractiveEx <<  72 
                                                   >>  73            if(M0projectile < projectile->GetDefinition()->GetPDGMass()) 
                                                   >>  74              {
                                                   >>  75               PutOnMassShell=1;
                                                   >>  76               M0projectile=projectile->GetDefinition()->GetPDGMass();
                                                   >>  77              }
                                                   >>  78 
                                                   >>  79      G4double Mprojectile2 = M0projectile * M0projectile;
                                                   >>  80 
                                                   >>  81            G4int    PDGcode=projectile->GetDefinition()->GetPDGEncoding();
                                                   >>  82            G4int    absPDGcode=std::abs(PDGcode);
                                                   >>  83            G4double ProjectileDiffCut;
                                                   >>  84            G4double ProjectileBackgroundWeight;           // Uzhi May 2007
                                                   >>  85 
                                                   >>  86            G4double TargetBackgroundWeight;               // Uzhi May 2007
                                                   >>  87 
                                                   >>  88            G4double AveragePt2;
                                                   >>  89 
                                                   >>  90            if( absPDGcode > 1000 )                        //------Projectile is baryon --------
                                                   >>  91              {
                                                   >>  92               ProjectileDiffCut = 1.1;                    // GeV
                                                   >>  93               ProjectileBackgroundWeight=0.;              // Uzhi May 2007
                                                   >>  94               AveragePt2 = 0.3;                           // GeV^2
                                                   >>  95              }
                                                   >>  96            else if( absPDGcode == 211 || PDGcode ==  111) //------Projectile is Pion -----------
                                                   >>  97              {
                                                   >>  98               ProjectileDiffCut = 0.6;                   // GeV Uzhi May 2007 1.0->0.6
                                                   >>  99               ProjectileBackgroundWeight=0.9;            // Uzhi May 2007
                                                   >> 100               AveragePt2 = 0.3;                          // GeV^2
                                                   >> 101              }
                                                   >> 102            else if( absPDGcode == 321 || PDGcode == -311) //------Projectile is Kaon -----------
                                                   >> 103              {
                                                   >> 104               ProjectileDiffCut = 0.7;                    // GeV 1.1
                                                   >> 105               ProjectileBackgroundWeight=0.5;             // Uzhi May 2007   ???
                                                   >> 106               AveragePt2 = 0.3;                           // GeV^2
                                                   >> 107              }
                                                   >> 108            else                                           //------Projectile is undefined,
                                                   >> 109                                                           //------Nucleon assumed
                                                   >> 110              {
                                                   >> 111               ProjectileDiffCut = 1.1;                    // GeV
                                                   >> 112               ProjectileBackgroundWeight=0.;              // Uzhi May 2007
                                                   >> 113               AveragePt2 = 0.3;                           // GeV^2
                                                   >> 114              };
                                                   >> 115 
                                                   >> 116            ProjectileDiffCut = ProjectileDiffCut * GeV;
                                                   >> 117            AveragePt2 = AveragePt2 * GeV*GeV;
                                                   >> 118 
                                                   >> 119 // -------------------- Target parameters ----------------------------------------------
                                                   >> 120        G4LorentzVector Ptarget=target->Get4Momentum();
                                                   >> 121 
                                                   >> 122      G4double M0target = Ptarget.mag();
                                                   >> 123 
                                                   >> 124            if(M0target < target->GetDefinition()->GetPDGMass()) 
                                                   >> 125              {
                                                   >> 126               PutOnMassShell=1;
                                                   >> 127               M0target=target->GetDefinition()->GetPDGMass();
                                                   >> 128              }
                                                   >> 129      
                                                   >> 130        G4double Mtarget2 = M0target * M0target;                      //Ptarget.mag2(); 
                                                   >> 131                                                                          // for AA-inter.
                                                   >> 132 
                                                   >> 133            G4double NuclearNucleonDiffCut = 1.1*GeV;        
                                                   >> 134            TargetBackgroundWeight=0.;                           // Uzhi May 2007
                                                   >> 135 
                                                   >> 136            G4double ProjectileDiffCut2 = ProjectileDiffCut * ProjectileDiffCut;
                                                   >> 137            G4double NuclearNucleonDiffCut2 = NuclearNucleonDiffCut * NuclearNucleonDiffCut;
                                                   >> 138 
                                                   >> 139 // Transform momenta to cms and then rotate parallel to z axis;
                                                   >> 140 
                                                   >> 141      G4LorentzVector Psum;
                                                   >> 142      Psum=Pprojectile+Ptarget;
                                                   >> 143 
                                                   >> 144      G4LorentzRotation toCms(-1*Psum.boostVector());
                                                   >> 145 
                                                   >> 146      G4LorentzVector Ptmp=toCms*Pprojectile;
                                                   >> 147 
                                                   >> 148      if ( Ptmp.pz() <= 0. )
                                                   >> 149      {
                                                   >> 150      // "String" moving backwards in  CMS, abort collision !!
                                                   >> 151            //G4cout << " abort Collision!! " << G4endl;
                                                   >> 152        return false; 
                                                   >> 153      }
                                                   >> 154            
                                                   >> 155      toCms.rotateZ(-1*Ptmp.phi());
                                                   >> 156      toCms.rotateY(-1*Ptmp.theta());
                                                   >> 157   
                                                   >> 158      G4LorentzRotation toLab(toCms.inverse());
                                                   >> 159 
                                                   >> 160      Pprojectile.transform(toCms);
                                                   >> 161      Ptarget.transform(toCms);
                                                   >> 162 
                                                   >> 163      G4double Pt2;                                                    
                                                   >> 164            G4double ProjMassT2, ProjMassT;                                  
                                                   >> 165            G4double TargMassT2, TargMassT;                                  
                                                   >> 166            G4double PZcms2, PZcms;                                          
                                                   >> 167            G4double PMinusNew, TPlusNew;                                    
                                                   >> 168 
                                                   >> 169            G4double S=Psum.mag2();                                          
                                                   >> 170            G4double SqrtS=std::sqrt(S);                                     
                                                   >> 171 
                                                   >> 172            if(absPDGcode > 1000 && SqrtS < 2200*MeV) 
                                                   >> 173              {return false;}                         // The model cannot work for 
                                                   >> 174                                                      // p+p-interactions
                                                   >> 175                                                      // at Plab < 1.3 GeV/c.
                                                   >> 176 
                                                   >> 177            if(( absPDGcode == 211 || PDGcode ==  111) && SqrtS < 1600*MeV) 
                                                   >> 178              {return false;}                         // The model cannot work for 
                                                   >> 179                                                      // Pi+p-interactions
                                                   >> 180                                                      // at Plab < 1. GeV/c.  
                                                   >> 181 
                                                   >> 182            if(( absPDGcode == 321 || PDGcode == -311) && SqrtS < 1600*MeV) 
                                                   >> 183              {return false;}                         // The model cannot work for 
                                                   >> 184                                                      // K+p-interactions
                                                   >> 185                                                      // at Plab < ??? GeV/c.  ???
                                                   >> 186 
                                                   >> 187      PZcms2=(S*S+Mprojectile2*Mprojectile2+Mtarget2*Mtarget2-
                                                   >> 188                                  2*S*Mprojectile2-2*S*Mtarget2-2*Mprojectile2*Mtarget2)/4./S;
                                                   >> 189            if(PZcms2 < 0) 
                                                   >> 190              {return false;}   // It can be in an interaction with off-shell nuclear nucleon
                                                   >> 191 
                                                   >> 192            PZcms = std::sqrt(PZcms2);
                                                   >> 193 
                                                   >> 194            if(PutOnMassShell)
                                                   >> 195              {
                                                   >> 196               if(Pprojectile.z() > 0.)
                                                   >> 197                 {
                                                   >> 198                  Pprojectile.setPz( PZcms);
                                                   >> 199                  Ptarget.setPz(    -PZcms);
                                                   >> 200                 }
                                                   >> 201               else
                                                   >> 202                  {
                                                   >> 203                  Pprojectile.setPz(-PZcms);
                                                   >> 204                  Ptarget.setPz(     PZcms);
                                                   >> 205                 };
                                                   >> 206 
                                                   >> 207                Pprojectile.setE(std::sqrt(Mprojectile2+
                                                   >> 208                                                        Pprojectile.x()*Pprojectile.x()+
                                                   >> 209                                                        Pprojectile.y()*Pprojectile.y()+
                                                   >> 210                                                        PZcms2));
                                                   >> 211                Ptarget.setE(std::sqrt(    Mtarget2    +
                                                   >> 212                                                        Ptarget.x()*Ptarget.x()+
                                                   >> 213                                                        Ptarget.y()*Ptarget.y()+
                                                   >> 214                                                        PZcms2));
                                                   >> 215              }
                                                   >> 216 
                                                   >> 217            G4double maxPtSquare = PZcms2;
                                                   >> 218 
                                                   >> 219 //G4cout << "Pprojectile aft boost : " << Pprojectile << G4endl;
                                                   >> 220 //G4cout << "Ptarget aft boost : " << Ptarget << G4endl;
                                                   >> 221 //     G4cout << "cms aft boost : " << (Pprojectile+ Ptarget) << G4endl;
                                                   >> 222 
                                                   >> 223 //     G4cout << " Projectile Xplus / Xminus : " << 
                                                   >> 224 //      Pprojectile.plus() << " / " << Pprojectile.minus() << G4endl;
                                                   >> 225 //     G4cout << " Target Xplus / Xminus : " << 
                                                   >> 226 //      Ptarget.plus() << " / " << Ptarget.minus() << G4endl;
                                                   >> 227 
                                                   >> 228      G4LorentzVector Qmomentum;
                                                   >> 229            G4double Qminus, Qplus;                                          
                                                   >> 230 
                                                   >> 231      G4int whilecount=0;
                                                   >> 232      do {
                                                   >> 233 //  Generate pt   
                                                   >> 234 
                                                   >> 235          if (whilecount++ >= 500 && (whilecount%100)==0) 
                                                   >> 236 //       G4cout << "G4DiffractiveExcitation::ExciteParticipants possibly looping"
                                                   >> 237 //       << ", loop count/ maxPtSquare : " 
                                                   >> 238 //             << whilecount << " / " << maxPtSquare << G4endl;
                                                   >> 239                if (whilecount > 1000 ) 
                                                   >> 240                {
                                                   >> 241              Qmomentum=G4LorentzVector(0.,0.,0.,0.);
                                                   >> 242        return false;    //  Ignore this interaction 
                                                   >> 243                }
                                                   >> 244 
                                                   >> 245          Qmomentum=G4LorentzVector(GaussianPt(AveragePt2,maxPtSquare),0);
                                                   >> 246 
                                                   >> 247 //G4cout << "generated Pt " << Qmomentum << G4endl;
                                                   >> 248 //G4cout << "Pprojectile with pt : " << Pprojectile+Qmomentum << G4endl;
                                                   >> 249 //G4cout << "Ptarget with pt : " << Ptarget-Qmomentum << G4endl;
                                                   >> 250 
                                                   >> 251 //  Momentum transfer
                                                   >> 252 /*                                                                          // Uzhi
                                                   >> 253          G4double Xmin = minmass / ( Pprojectile.e() + Ptarget.e() );
                                                   >> 254          G4double Xmax=1.;
                                                   >> 255          G4double Xplus =ChooseX(Xmin,Xmax);
                                                   >> 256          G4double Xminus=ChooseX(Xmin,Xmax);
                                                   >> 257 
                                                   >> 258 //         G4cout << " X-plus  " << Xplus << G4endl;
                                                   >> 259 //         G4cout << " X-minus " << Xminus << G4endl;
                                                   >> 260          
                                                   >> 261          G4double pt2=G4ThreeVector(Qmomentum.vect()).mag2();
                                                   >> 262          G4double Qplus =-1 * pt2 / Xminus/Ptarget.minus();
                                                   >> 263          G4double Qminus=     pt2 / Xplus /Pprojectile.plus();
                                                   >> 264 */                                                                          // Uzhi    *
                                                   >> 265 
                                                   >> 266          Pt2=G4ThreeVector(Qmomentum.vect()).mag2();                  
                                                   >> 267                ProjMassT2=Mprojectile2+Pt2;                           
                                                   >> 268                ProjMassT =std::sqrt(ProjMassT2);                            
                                                   >> 269 
                                                   >> 270                TargMassT2=Mtarget2+Pt2;                               
                                                   >> 271                TargMassT =std::sqrt(TargMassT2);                            
                                                   >> 272 
                                                   >> 273                PZcms2=(S*S+ProjMassT2*ProjMassT2+                           
                                                   >> 274                            TargMassT2*TargMassT2-                           
                                                   >> 275                            2.*S*ProjMassT2-2.*S*TargMassT2-                 
                                                   >> 276                            2.*ProjMassT2*TargMassT2)/4./S;                  
                                                   >> 277                if(PZcms2 < 0 ) {PZcms2=0;};                                 
                                                   >> 278                PZcms =std::sqrt(PZcms2);                                    
                                                   >> 279 
                                                   >> 280                G4double PMinusMin=std::sqrt(ProjMassT2+PZcms2)-PZcms;       
                                                   >> 281                G4double PMinusMax=SqrtS-TargMassT;                          
                                                   >> 282 
                                                   >> 283                if(G4UniformRand() < ProjectileBackgroundWeight)              // Uzhi May 2007
                                                   >> 284                  {
                                                   >> 285                   PMinusNew=PMinusMax-(PMinusMax-PMinusMin)*G4UniformRand(); // Uzhi May 2007
                                                   >> 286                  }                                                           // Uzhi May 2007
                                                   >> 287                else                                                          // Uzhi May 2007
                                                   >> 288                  {                                                           // Uzhi May 2007
                                                   >> 289                   PMinusNew=ChooseP(PMinusMin, PMinusMax);                   // Uzhi May 2007
                                                   >> 290                  };                                                          // Uzhi May 2007
                                                   >> 291 //               PMinusNew=ChooseP(PMinusMin, PMinusMax);                    // Uzhi May 2007
                                                   >> 292                Qminus=PMinusNew-Pprojectile.minus();                        
                                                   >> 293 
                                                   >> 294                G4double TPlusMin=std::sqrt(TargMassT2+PZcms2)-PZcms;        
                                                   >> 295                G4double TPlusMax=SqrtS-PMinusNew;                            // Uzhi May 2007
                                                   >> 296 //               G4double TPlusMax=SqrtS-ProjMassT;                          // Uzhi May 2007 
                                                   >> 297 
                                                   >> 298                if(G4UniformRand() < TargetBackgroundWeight)                  // Uzhi May 2007
                                                   >> 299                  {
                                                   >> 300                   TPlusNew=TPlusMax-(TPlusMax-TPlusMin)*G4UniformRand();     // Uzhi May 2007
                                                   >> 301                  }                                                           // Uzhi May 2007
                                                   >> 302                else                                                          // Uzhi May 2007
                                                   >> 303                  {                                                           // Uzhi May 2007
                                                   >> 304                   TPlusNew=ChooseP(TPlusMin, TPlusMax);                      // Uzhi May 2007
                                                   >> 305                  };                                                          // Uzhi May 2007
                                                   >> 306 
                                                   >> 307 //               TPlusNew=ChooseP(TPlusMin, TPlusMax);                       // Uzhi May 2007 
                                                   >> 308                Qplus=-(TPlusNew-Ptarget.plus());                            
                                                   >> 309 
                                                   >> 310          Qmomentum.setPz( (Qplus-Qminus)/2 );
                                                   >> 311          Qmomentum.setE(  (Qplus+Qminus)/2 );
                                                   >> 312 
                                                   >> 313 //G4cout << "Qplus / Qminus " << Qplus << " / " << Qminus<<G4endl;
                                                   >> 314 //       G4cout << "pt2" << pt2 << G4endl;
                                                   >> 315 //       G4cout << "Qmomentum " << Qmomentum << G4endl;
                                                   >> 316 //       G4cout << " Masses (P/T) : " << (Pprojectile+Qmomentum).mag() <<
                                                   >> 317 //               " / " << (Ptarget-Qmomentum).mag() << G4endl;
                                                   >> 318 
                                                   >> 319      } while (
                                                   >> 320 ( (Pprojectile+Qmomentum).mag2() <  Mprojectile2       ||      // Uzhi No without excitation
                                                   >> 321   (Ptarget    -Qmomentum).mag2() <  Mtarget2             ) ||  // Uzhi   
                                                   >> 322 ( (Pprojectile+Qmomentum).mag2() <  ProjectileDiffCut2 &&      // Uzhi No double Diffraction
                                                   >> 323   (Ptarget    -Qmomentum).mag2()  <  NuclearNucleonDiffCut2) );// Uzhi
                                                   >> 324 
                                                   >> 325            if((Ptarget-Qmomentum).mag2() < NuclearNucleonDiffCut2)           // Uzhi 
                                                   >> 326 //Projectile diffraction
                                                   >> 327              {
                                                   >> 328               G4double TMinusNew=SqrtS-PMinusNew;
                                                   >> 329               Qminus=Ptarget.minus()-TMinusNew;
                                                   >> 330               TPlusNew=TargMassT2/TMinusNew;
                                                   >> 331               Qplus=Ptarget.plus()-TPlusNew;
                                                   >> 332 
                                                   >> 333         Qmomentum.setPz( (Qplus-Qminus)/2 );                          
                                                   >> 334         Qmomentum.setE(  (Qplus+Qminus)/2 );                          
                                                   >> 335              }
                                                   >> 336            else if((Pprojectile+Qmomentum).mag2() <  ProjectileDiffCut2)    // Uzhi 
                                                   >> 337 //Target diffraction
                                                   >> 338              {
                                                   >> 339               G4double PPlusNew=SqrtS-TPlusNew;
                                                   >> 340               Qplus=PPlusNew-Pprojectile.plus();
                                                   >> 341               PMinusNew=ProjMassT2/PPlusNew;
                                                   >> 342               Qminus=PMinusNew-Pprojectile.minus();
                                                   >> 343 
                                                   >> 344         Qmomentum.setPz( (Qplus-Qminus)/2 );                          
                                                   >> 345         Qmomentum.setE(  (Qplus+Qminus)/2 );                          
                                                   >> 346              };
                                                   >> 347 
                                                   >> 348      Pprojectile += Qmomentum;
                                                   >> 349      Ptarget     -= Qmomentum;
                                                   >> 350 
                                                   >> 351 /*
                                                   >> 352 Pprojectile.setPz(0.);
                                                   >> 353 Pprojectile.setE(SqrtS-M0target);
                                                   >> 354 
                                                   >> 355 Ptarget.setPz(0.);
                                                   >> 356 Ptarget.setE(M0target);
                                                   >> 357 */
                                                   >> 358 
                                                   >> 359 //G4cout << "Pprojectile with Q : " << Pprojectile << G4endl;
                                                   >> 360 //G4cout << "Ptarget with Q : " << Ptarget << G4endl;
                                                   >> 361   
                                                   >> 362 //     G4cout << "Projectile back: " << toLab * Pprojectile << G4endl;
                                                   >> 363 //     G4cout << "Target back: " << toLab * Ptarget << G4endl;
                                                   >> 364 
                                                   >> 365 // Transform back and update SplitableHadron Participant.
                                                   >> 366      Pprojectile.transform(toLab);
                                                   >> 367      Ptarget.transform(toLab);
                                                   >> 368 
                                                   >> 369 //G4cout << "Pprojectile with Q M: " << Pprojectile<<" "<<  Pprojectile.mag() << G4endl;
                                                   >> 370 //G4cout << "Ptarget     with Q M: " << Ptarget    <<" "<<  Ptarget.mag()     << G4endl;
                                                   >> 371 
                                                   >> 372 //G4cout << "Target  mass  " <<  Ptarget.mag() << G4endl;     
                                                   >> 373            
                                                   >> 374      target->Set4Momentum(Ptarget);
                                                   >> 375 
                                                   >> 376 //G4cout << "Projectile mass  " <<  Pprojectile.mag() << G4endl; 
                                                   >> 377 
                                                   >> 378      projectile->Set4Momentum(Pprojectile);
                                                   >> 379 
                                                   >> 380      return true;
                                                   >> 381 }
                                                   >> 382 
                                                   >> 383 
                                                   >> 384 G4ExcitedString * G4DiffractiveExcitation::
                                                   >> 385            String(G4VSplitableHadron * hadron, G4bool isProjectile) const
                                                   >> 386 {
                                                   >> 387   hadron->SplitUp();
                                                   >> 388   G4Parton *start= hadron->GetNextParton();
                                                   >> 389   if ( start==NULL) 
                                                   >> 390   { G4cout << " G4FTFModel::String() Error:No start parton found"<< G4endl;
                                                   >> 391     return NULL;
                                                   >> 392   }
                                                   >> 393   G4Parton *end  = hadron->GetNextParton();
                                                   >> 394   if ( end==NULL) 
                                                   >> 395   { G4cout << " G4FTFModel::String() Error:No end parton found"<< G4endl;
                                                   >> 396     return NULL;
                                                   >> 397   }
                                                   >> 398   
                                                   >> 399   G4ExcitedString * string;
                                                   >> 400   if ( isProjectile ) 
                                                   >> 401   {
                                                   >> 402     string= new G4ExcitedString(end,start, +1);
                                                   >> 403   } else {
                                                   >> 404     string= new G4ExcitedString(start,end, -1);
                                                   >> 405   }
                                                   >> 406   
                                                   >> 407   string->SetPosition(hadron->GetPosition());
                                                   >> 408 
                                                   >> 409 // momenta of string ends
                                                   >> 410   G4double ptSquared= hadron->Get4Momentum().perp2();
                                                   >> 411   G4double transverseMassSquared= hadron->Get4Momentum().plus()
                                                   >> 412             * hadron->Get4Momentum().minus();
                                                   >> 413 
                                                   >> 414 
                                                   >> 415   G4double maxAvailMomentumSquared=
                                                   >> 416      sqr( std::sqrt(transverseMassSquared) - std::sqrt(ptSquared) );
                                                   >> 417 
                                                   >> 418         G4double widthOfPtSquare = 0.25;          // Uzhi <Pt^2>=0.25 ??????????????????
                                                   >> 419   G4ThreeVector pt=GaussianPt(widthOfPtSquare,maxAvailMomentumSquared);
                                                   >> 420 
                                                   >> 421   G4LorentzVector Pstart(G4LorentzVector(pt,0.));
                                                   >> 422   G4LorentzVector Pend;
                                                   >> 423   Pend.setPx(hadron->Get4Momentum().px() - pt.x());
                                                   >> 424   Pend.setPy(hadron->Get4Momentum().py() - pt.y());
                                                   >> 425 
                                                   >> 426   G4double tm1=hadron->Get4Momentum().minus() +
                                                   >> 427     ( Pend.perp2()-Pstart.perp2() ) / hadron->Get4Momentum().plus();
                                                   >> 428 
                                                   >> 429   G4double tm2= std::sqrt( std::max(0., sqr(tm1) -
                                                   >> 430        4. * Pend.perp2() * hadron->Get4Momentum().minus()
                                                   >> 431         /  hadron->Get4Momentum().plus() ));
                                                   >> 432 
                                                   >> 433   G4int Sign= isProjectile ? -1 : 1;
                                                   >> 434   
                                                   >> 435   G4double endMinus  = 0.5 * (tm1 + Sign*tm2);
                                                   >> 436   G4double startMinus= hadron->Get4Momentum().minus() - endMinus;
                                                   >> 437 
                                                   >> 438   G4double startPlus= Pstart.perp2() /  startMinus;
                                                   >> 439   G4double endPlus  = hadron->Get4Momentum().plus() - startPlus;
                                                   >> 440 
                                                   >> 441   Pstart.setPz(0.5*(startPlus - startMinus));
                                                   >> 442   Pstart.setE(0.5*(startPlus + startMinus));
                                                   >> 443 
                                                   >> 444   Pend.setPz(0.5*(endPlus - endMinus));
                                                   >> 445   Pend.setE(0.5*(endPlus + endMinus));
                                                   >> 446 
                                                   >> 447   start->Set4Momentum(Pstart);
                                                   >> 448   end->Set4Momentum(Pend);
                                                   >> 449   
                                                   >> 450 #ifdef G4_FTFDEBUG
                                                   >> 451   G4cout << " generated string flavors          " << start->GetPDGcode() << " / " << end->GetPDGcode() << G4endl;
                                                   >> 452   G4cout << " generated string momenta:   quark " << start->Get4Momentum() << "mass : " <<start->Get4Momentum().mag()<< G4endl;
                                                   >> 453   G4cout << " generated string momenta: Diquark " << end ->Get4Momentum() << "mass : " <<end->Get4Momentum().mag()<< G4endl;
                                                   >> 454   G4cout << " sum of ends                       " << Pstart+Pend << G4endl;
                                                   >> 455   G4cout << " Original                          " << hadron->Get4Momentum() << G4endl;
                                                   >> 456 #endif
                                                   >> 457   
                                                   >> 458   return string;  
                                                   >> 459 }
                                                   >> 460 
                                                   >> 461 
                                                   >> 462 // --------- private methods ----------------------
                                                   >> 463 
                                                   >> 464 G4double G4DiffractiveExcitation::ChooseP(G4double Pmin, G4double Pmax) const // Uzhi
                                                   >> 465 {
                                                   >> 466 // choose an x between Xmin and Xmax with P(x) ~ 1/x
                                                   >> 467 
                                                   >> 468 //  to be improved...
                                                   >> 469 
                                                   >> 470   G4double range=Pmax-Pmin;                                         // Uzhi
                                                   >> 471   
                                                   >> 472   if ( Pmin <= 0. || range <=0. ) 
                                                   >> 473   {
                                                   >> 474     G4cout << " Pmin, range : " << Pmin << " , " << range << G4endl;
                                                   >> 475     throw G4HadronicException(__FILE__, __LINE__, "G4DiffractiveExcitation::ChooseP : Invalid arguments ");
                                                   >> 476   }
                                                   >> 477 
                                                   >> 478   G4double P;
                                                   >> 479 /*                                                                          // Uzhi
                                                   >> 480   do {
                                                   >> 481       x=Xmin + G4UniformRand() * range;
                                                   >> 482   }  while ( Xmin/x < G4UniformRand() );
                                                   >> 483 */                                                                          // Uzhi
                                                   >> 484 
                                                   >> 485         P=Pmin * std::pow(Pmax/Pmin,G4UniformRand());                       // Uzhi
                                                   >> 486 
                                                   >> 487 //debug-hpw cout << "DiffractiveX "<<x<<G4endl;
                                                   >> 488   return P;
                                                   >> 489 }
                                                   >> 490 
                                                   >> 491 G4ThreeVector G4DiffractiveExcitation::GaussianPt(G4double AveragePt2, G4double maxPtSquare) const // Uzhi
                                                   >> 492 {            //  @@ this method is used in FTFModel as well. Should go somewhere common!
                                                   >> 493   
                                                   >> 494   G4double Pt2;
                                                   >> 495 /*                                                                          // Uzhi
                                                   >> 496   do {
                                                   >> 497       pt2=widthSquare * std::log( G4UniformRand() );
                                                   >> 498   } while ( pt2 > maxPtSquare);
                                                   >> 499 */                                                                          // Uzhi
                                                   >> 500 
                                                   >> 501         Pt2 = -AveragePt2 * std::log(1. + G4UniformRand() * (std::exp(-maxPtSquare/AveragePt2)-1.));// Uzhi 
                                                   >> 502   
                                                   >> 503   G4double Pt=std::sqrt(Pt2);
                                                   >> 504 
                                                   >> 505   G4double phi=G4UniformRand() * twopi;
                                                   >> 506   
                                                   >> 507   return G4ThreeVector (Pt*std::cos(phi), Pt*std::sin(phi), 0.);    
                                                   >> 508 }
                                                   >> 509 
                                                   >> 510 G4DiffractiveExcitation::G4DiffractiveExcitation(const G4DiffractiveExcitation &)
                                                   >> 511 {
                                                   >> 512   throw G4HadronicException(__FILE__, __LINE__, "G4DiffractiveExcitation copy contructor not meant to be called");
                                                   >> 513 }
                                                   >> 514 
                                                   >> 515 
                                                   >> 516 G4DiffractiveExcitation::~G4DiffractiveExcitation()
                                                   >> 517 {
                                                   >> 518 }
                                                   >> 519 
                                                   >> 520 
                                                   >> 521 const G4DiffractiveExcitation & G4DiffractiveExcitation::operator=(const G4DiffractiveExcitation &)
                                                   >> 522 {
                                                   >> 523   throw G4HadronicException(__FILE__, __LINE__, "G4DiffractiveExcitation = operator meant to be called");
                                                   >> 524   return *this;
                                                   >> 525 }
                                                   >> 526 
                                                   >> 527 
                                                   >> 528 int G4DiffractiveExcitation::operator==(const G4DiffractiveExcitation &) const
                                                   >> 529 {
                                                   >> 530   throw G4HadronicException(__FILE__, __LINE__, "G4DiffractiveExcitation == operator meant to be called");
                                                   >> 531   return false;
                                                   >> 532 }
                                                   >> 533 
                                                   >> 534 int G4DiffractiveExcitation::operator!=(const G4DiffractiveExcitation &) const
                                                   >> 535 {
                                                   >> 536   throw G4HadronicException(__FILE__, __LINE__, "G4DiffractiveExcitation != operator meant to be called");
                                                   >> 537   return true;
1619 }                                                538 }
1620                                               << 
1621                                                  539