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TPythia6Decayer.cxx
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1// @(#)root/pythia6:$Id$
2// Author: Christian Holm Christensen 22/04/06
3// Much of this code has been lifted from AliROOT.
4
5/*************************************************************************
6 * Copyright (C) 1995-2006, Rene Brun and Fons Rademakers. *
7 * All rights reserved. *
8 * *
9 * For the licensing terms see $ROOTSYS/LICENSE. *
10 * For the list of contributors see $ROOTSYS/README/CREDITS. *
11 *************************************************************************/
12
13/** \class TPythia6Decayer
14 \ingroup pythia6
15
16This class implements the TVirtualMCDecayer interface.
17
18The TPythia6 singleton object is used to decay particles. Note, that since
19this class modifies common blocks (global variables) it is defined as a
20singleton.
21*/
22
23#include "TPythia6.h"
24#include "TPythia6Decayer.h"
25#include "TPDGCode.h"
26#include "TLorentzVector.h"
27#include "TClonesArray.h"
28
30
32
33////////////////////////////////////////////////////////////////////////////////
34/// Get the singleton object.
35
37{
39 return fgInstance;
40}
41
42////////////////////////////////////////////////////////////////////////////////
43/// Constructor
44
46 : fDecay(kMaxDecay),
47 fBraPart(501)
48{
49 fBraPart.Reset(1);
50}
51
52////////////////////////////////////////////////////////////////////////////////
53/// Initialize the decayer
54
56{
57 static Bool_t init = kFALSE;
58 if (init) return;
59 init = kTRUE;
60 ForceDecay();
61}
62
63////////////////////////////////////////////////////////////////////////////////
64/// Decay a particle of type IDPART (PDG code) and momentum P.
65
67{
68 if (!p) return;
69 TPythia6::Instance()->Py1ent(0, idpart, p->Energy(), p->Theta(), p->Phi());
71}
72
73////////////////////////////////////////////////////////////////////////////////
74/// Get the decay products into the passed PARTICLES TClonesArray of
75/// TParticles
76
78{
79 return TPythia6::Instance()->ImportParticles(particles,"All");
80}
81
82////////////////////////////////////////////////////////////////////////////////
83/// Force a particular decay type
84
86{
87 if (type > kMaxDecay) {
88 Warning("SetForceDecay", "Invalid decay mode: %d", type);
89 return;
90 }
92}
93
94////////////////////////////////////////////////////////////////////////////////
95/// Force a particle decay mode
96
98{
99 EDecayType decay=fDecay;
101 if (decay == kNoDecayHeavy) return;
102
103 //
104 // select mode
105 Int_t products[3];
106 Int_t mult[3];
107
108 switch (decay) {
109 case kHardMuons:
110 products[0] = 13;
111 products[1] = 443;
112 products[2] = 100443;
113 mult[0] = 1;
114 mult[1] = 1;
115 mult[2] = 1;
116 ForceParticleDecay( 511, products, mult, 3);
117 ForceParticleDecay( 521, products, mult, 3);
118 ForceParticleDecay( 531, products, mult, 3);
119 ForceParticleDecay( 5122, products, mult, 3);
120 ForceParticleDecay( 5132, products, mult, 3);
121 ForceParticleDecay( 5232, products, mult, 3);
122 ForceParticleDecay( 5332, products, mult, 3);
123 ForceParticleDecay( 100443, 443, 1); // Psi' -> J/Psi X
124 ForceParticleDecay( 443, 13, 2); // J/Psi -> mu+ mu-
125
126 ForceParticleDecay( 411,13,1); // D+/-
127 ForceParticleDecay( 421,13,1); // D0
128 ForceParticleDecay( 431,13,1); // D_s
129 ForceParticleDecay( 4122,13,1); // Lambda_c
130 ForceParticleDecay( 4132,13,1); // Xsi_c
131 ForceParticleDecay( 4232,13,1); // Sigma_c
132 ForceParticleDecay( 4332,13,1); // Omega_c
133 break;
134 case kSemiMuonic:
135 ForceParticleDecay( 411,13,1); // D+/-
136 ForceParticleDecay( 421,13,1); // D0
137 ForceParticleDecay( 431,13,1); // D_s
138 ForceParticleDecay( 4122,13,1); // Lambda_c
139 ForceParticleDecay( 4132,13,1); // Xsi_c
140 ForceParticleDecay( 4232,13,1); // Sigma_c
141 ForceParticleDecay( 4332,13,1); // Omega_c
142 ForceParticleDecay( 511,13,1); // B0
143 ForceParticleDecay( 521,13,1); // B+/-
144 ForceParticleDecay( 531,13,1); // B_s
145 ForceParticleDecay( 5122,13,1); // Lambda_b
146 ForceParticleDecay( 5132,13,1); // Xsi_b
147 ForceParticleDecay( 5232,13,1); // Sigma_b
148 ForceParticleDecay( 5332,13,1); // Omega_b
149 break;
150 case kDiMuon:
151 ForceParticleDecay( 113,13,2); // rho
152 ForceParticleDecay( 221,13,2); // eta
153 ForceParticleDecay( 223,13,2); // omega
154 ForceParticleDecay( 333,13,2); // phi
155 ForceParticleDecay( 443,13,2); // J/Psi
156 ForceParticleDecay(100443,13,2);// Psi'
157 ForceParticleDecay( 553,13,2); // Upsilon
158 ForceParticleDecay(100553,13,2);// Upsilon'
159 ForceParticleDecay(200553,13,2);// Upsilon''
160 break;
161 case kSemiElectronic:
162 ForceParticleDecay( 411,11,1); // D+/-
163 ForceParticleDecay( 421,11,1); // D0
164 ForceParticleDecay( 431,11,1); // D_s
165 ForceParticleDecay( 4122,11,1); // Lambda_c
166 ForceParticleDecay( 4132,11,1); // Xsi_c
167 ForceParticleDecay( 4232,11,1); // Sigma_c
168 ForceParticleDecay( 4332,11,1); // Omega_c
169 ForceParticleDecay( 511,11,1); // B0
170 ForceParticleDecay( 521,11,1); // B+/-
171 ForceParticleDecay( 531,11,1); // B_s
172 ForceParticleDecay( 5122,11,1); // Lambda_b
173 ForceParticleDecay( 5132,11,1); // Xsi_b
174 ForceParticleDecay( 5232,11,1); // Sigma_b
175 ForceParticleDecay( 5332,11,1); // Omega_b
176 break;
177 case kDiElectron:
178 ForceParticleDecay( 113,11,2); // rho
179 ForceParticleDecay( 333,11,2); // phi
180 ForceParticleDecay( 221,11,2); // eta
181 ForceParticleDecay( 223,11,2); // omega
182 ForceParticleDecay( 443,11,2); // J/Psi
183 ForceParticleDecay(100443,11,2);// Psi'
184 ForceParticleDecay( 553,11,2); // Upsilon
185 ForceParticleDecay(100553,11,2);// Upsilon'
186 ForceParticleDecay(200553,11,2);// Upsilon''
187 break;
188 case kBJpsiDiMuon:
189
190 products[0] = 443;
191 products[1] = 100443;
192 mult[0] = 1;
193 mult[1] = 1;
194
195 ForceParticleDecay( 511, products, mult, 2); // B0 -> J/Psi (Psi') X
196 ForceParticleDecay( 521, products, mult, 2); // B+/- -> J/Psi (Psi') X
197 ForceParticleDecay( 531, products, mult, 2); // B_s -> J/Psi (Psi') X
198 ForceParticleDecay( 5122, products, mult, 2); // Lambda_b -> J/Psi (Psi') X
199 ForceParticleDecay( 100443, 443, 1); // Psi' -> J/Psi X
200 ForceParticleDecay( 443,13,2); // J/Psi -> mu+ mu-
201 break;
202 case kBPsiPrimeDiMuon:
203 ForceParticleDecay( 511,100443,1); // B0
204 ForceParticleDecay( 521,100443,1); // B+/-
205 ForceParticleDecay( 531,100443,1); // B_s
206 ForceParticleDecay( 5122,100443,1); // Lambda_b
207 ForceParticleDecay(100443,13,2); // Psi'
208 break;
209 case kBJpsiDiElectron:
210 ForceParticleDecay( 511,443,1); // B0
211 ForceParticleDecay( 521,443,1); // B+/-
212 ForceParticleDecay( 531,443,1); // B_s
213 ForceParticleDecay( 5122,443,1); // Lambda_b
214 ForceParticleDecay( 443,11,2); // J/Psi
215 break;
216 case kBJpsi:
217 ForceParticleDecay( 511,443,1); // B0
218 ForceParticleDecay( 521,443,1); // B+/-
219 ForceParticleDecay( 531,443,1); // B_s
220 ForceParticleDecay( 5122,443,1); // Lambda_b
221 break;
223 ForceParticleDecay( 511,100443,1); // B0
224 ForceParticleDecay( 521,100443,1); // B+/-
225 ForceParticleDecay( 531,100443,1); // B_s
226 ForceParticleDecay( 5122,100443,1); // Lambda_b
227 ForceParticleDecay(100443,11,2); // Psi'
228 break;
229 case kPiToMu:
230 ForceParticleDecay(211,13,1); // pi->mu
231 break;
232 case kKaToMu:
233 ForceParticleDecay(321,13,1); // K->mu
234 break;
235 case kWToMuon:
236 ForceParticleDecay( 24, 13,1); // W -> mu
237 break;
238 case kWToCharm:
239 ForceParticleDecay( 24, 4,1); // W -> c
240 break;
241 case kWToCharmToMuon:
242 ForceParticleDecay( 24, 4,1); // W -> c
243 ForceParticleDecay( 411,13,1); // D+/- -> mu
244 ForceParticleDecay( 421,13,1); // D0 -> mu
245 ForceParticleDecay( 431,13,1); // D_s -> mu
246 ForceParticleDecay( 4122,13,1); // Lambda_c
247 ForceParticleDecay( 4132,13,1); // Xsi_c
248 ForceParticleDecay( 4232,13,1); // Sigma_c
249 ForceParticleDecay( 4332,13,1); // Omega_c
250 break;
251 case kZDiMuon:
252 ForceParticleDecay( 23, 13,2); // Z -> mu+ mu-
253 break;
254 case kHadronicD:
256 break;
257 case kPhiKK:
258 ForceParticleDecay(333,321,2); // Phi->K+K-
259 break;
260 case kOmega:
261 ForceOmega();
262 case kAll:
263 break;
264 case kNoDecay:
266 break;
267 case kNoDecayHeavy: break; // cannot get here: early return above
268 case kMaxDecay: break;
269 }
270}
271
272////////////////////////////////////////////////////////////////////////////////
273/// Get the partial branching ratio for a particle of type IPART (a
274/// PDG code).
275
277{
279 // return TPythia6::Instance()->GetBRAT(kc);
280 return fBraPart[kc];
281}
282
283////////////////////////////////////////////////////////////////////////////////
284/// Get the life-time of a particle of type KF (a PDG code).
285
287{
289 return TPythia6::Instance()->GetPMAS(kc,4) * 3.3333e-12;
290}
291
292////////////////////////////////////////////////////////////////////////////////
293/// Read in particle data from an ASCII file. The file name must
294/// previously have been set using the member function
295/// SetDecayTableFile.
296
298{
299 if (fDecayTableFile.IsNull()) {
300 Warning("ReadDecayTable", "No file set");
301 return;
302 }
303 Int_t lun = 15;
305 const_cast<char*>(fDecayTableFile.Data()));
306 TPythia6::Instance()->Pyupda(3,lun);
308}
309
310// ===================================================================
311// BEGIN COMMENT
312//
313// It would be better if the particle and decay information could be
314// read from the current TDatabasePDG instance.
315//
316// However, it seems to me that some information is missing. In
317// particular
318//
319// - The broadning cut-off,
320// - Resonance width
321// - Color charge
322// - MWID (?)
323//
324// Further more, it's not clear to me at least, what all the
325// parameters Pythia needs are.
326//
327// Code like the below could be used to make a temporary file that
328// Pythia could then read in. Ofcourse, one could also manipulate
329// the data structures directly, but that's propably more dangerous.
330//
331#if 0
332void PrintPDG(TParticlePDG* pdg)
333{
334 TParticlePDG* anti = pdg->AntiParticle();
335 const char* antiName = (anti ? anti->GetName() : "");
336 Int_t color = 0;
337 switch (TMath::Abs(pdg->PdgCode())) {
338 case 1: case 2: case 3: case 4: case 5: case 6: case 7: case 8: // Quarks
339 color = 1; break;
340 case 21: // Gluon
341 color = 2; break;
342 case 1103:
343 case 2101: case 2103: case 2203:
344 case 3101: case 3103: case 3201: case 3203: case 3303:
345 case 4101: case 4103: case 4201: case 4203: case 4301: case 4303: case 4403:
346 case 5101: case 5103: case 5201: case 5203: case 5301: case 5303: case 5401:
347 case 5403: case 5503:
348 // Quark combinations
349 color = -1; break;
350 case 1000001: case 1000002: case 1000003: case 1000004: case 1000005:
351 case 1000006: // super symmetric partners to quars
352 color = 1; break;
353 case 1000021: // ~g
354 color = 2; break;
355 case 2000001: case 2000002: case 2000003: case 2000004: case 2000005:
356 case 2000006: // R hadrons
357 color = 1; break;
358 case 3000331: case 3100021: case 3200111: case 3100113: case 3200113:
359 case 3300113: case 3400113:
360 // Technicolor
361 color = 2; break;
362 case 4000001: case 4000002:
363 color = 1; break;
364 case 9900443: case 9900441: case 9910441: case 9900553: case 9900551:
365 case 9910551:
366 color = 2; break;
367 }
368 std::cout << std::right
369 << " " << std::setw(9) << pdg->PdgCode()
370 << " " << std::left << std::setw(16) << pdg->GetName()
371 << " " << std::setw(16) << antiName
372 << std::right
373 << std::setw(3) << Int_t(pdg->Charge())
374 << std::setw(3) << color
375 << std::setw(3) << (anti ? 1 : 0)
376 << std::fixed << std::setprecision(5)
377 << std::setw(12) << pdg->Mass()
378 << std::setw(12) << pdg->Width()
379 << std::setw(12) << 0 // Broad
380 << std::scientific
381 << " " << std::setw(13) << pdg->Lifetime()
382 << std::setw(3) << 0 // MWID
383 << std::setw(3) << pdg->Stable()
384 << std::endl;
385}
386
387void MakeDecayList()
388{
390 pdgDB->ReadPDGTable();
391 const THashList* pdgs = pdgDB->ParticleList();
392 TParticlePDG* pdg = 0;
393 TIter nextPDG(pdgs);
394 while ((pdg = static_cast<TParticlePDG*>(nextPDG()))) {
395 // std::cout << "Processing " << pdg->GetName() << std::endl;
396 PrintPDG(pdg);
397
398 TObjArray* decays = pdg->DecayList();
399 TDecayChannel* decay = 0;
400 TIter nextDecay(decays);
401 while ((decay = static_cast<TDecayChannel*>(nextDecay()))) {
402 // std::cout << "Processing decay number " << decay->Number() << std::endl;
403 }
404 }
405}
406#endif
407// END COMMENT
408// ===================================================================
409
410////////////////////////////////////////////////////////////////////////////////
411/// write particle data to an ASCII file. The file name must
412/// previously have been set using the member function
413/// SetDecayTableFile.
414///
415/// Users can use this function to make an initial decay list file,
416/// which then can be edited by hand, and re-loaded into the decayer
417/// using ReadDecayTable.
418///
419/// The file syntax is
420///
421/// particle_list : partcle_data
422/// | particle_list particle_data
423/// ;
424/// particle_data : particle_info
425/// | particle_info '\n' decay_list
426/// ;
427/// particle_info : See below
428/// ;
429/// decay_list : decay_entry
430/// | decay_list decay_entry
431/// ;
432/// decay_entry : See below
433///
434/// The particle_info consists of 13 fields:
435///
436/// PDG code int
437/// Name string
438/// Anti-particle name string if there's no anti-particle,
439/// then this field must be the
440/// empty string
441/// Electic charge int in units of |e|/3
442/// Color charge int in units of quark color charges
443/// Have anti-particle int 1 of there's an anti-particle
444/// to this particle, or 0
445/// otherwise
446/// Mass float in units of GeV
447/// Resonance width float
448/// Max broadning float
449/// Lifetime float
450/// MWID int ??? (some sort of flag)
451/// Decay int 1 if it decays. 0 otherwise
452///
453/// The format to write these entries in are
454///
455/// " %9 %-16s %-16s%3d%3d%3d%12.5f%12.5f%12.5f%13.gf%3d%d\n"
456///
457/// The decay_entry consists of 8 fields:
458///
459/// On/Off int 1 for on, -1 for off
460/// Matrix element type int
461/// Branching ratio float
462/// Product 1 int PDG code of decay product 1
463/// Product 2 int PDG code of decay product 2
464/// Product 3 int PDG code of decay product 3
465/// Product 4 int PDG code of decay product 4
466/// Product 5 int PDG code of decay product 5
467///
468/// The format for these lines are
469///
470/// " %5d%5d%12.5f%10d%10d%10d%10d%10d\n"
471///
472
474{
475 if (fDecayTableFile.IsNull()) {
476 Warning("ReadDecayTable", "No file set");
477 return;
478 }
479 Int_t lun = 15;
481 const_cast<char*>(fDecayTableFile.Data()));
482 TPythia6::Instance()->Pyupda(1,lun);
484}
485
486////////////////////////////////////////////////////////////////////////////////
487/// Count number of decay products
488
490{
491 Int_t np = 0;
492 for (Int_t i = 1; i <= 5; i++)
493 if (TMath::Abs(TPythia6::Instance()->GetKFDP(channel,i)) == particle) np++;
494 return np;
495}
496
497////////////////////////////////////////////////////////////////////////////////
498/// Force golden D decay modes
499
501{
502 const Int_t kNHadrons = 4;
503 Int_t channel;
504 Int_t hadron[kNHadrons] = {411, 421, 431, 4112};
505
506 // for D+ -> K0* (-> K- pi+) pi+
507 Int_t iKstar0 = 313;
508 Int_t iKstarbar0 = -313;
509 Int_t products[2] = {kKPlus, kPiMinus}, mult[2] = {1, 1};
510 ForceParticleDecay(iKstar0, products, mult, 2);
511
512 // for Ds -> Phi pi+
513 Int_t iPhi = 333;
514 ForceParticleDecay(iPhi,kKPlus,2); // Phi->K+K-
515
516 Int_t decayP1[kNHadrons][3] = {
518 {kKMinus, kPiPlus, 0 },
519 {kKPlus , iKstarbar0, 0 },
520 {-1 , -1 , -1 }
521 };
522 Int_t decayP2[kNHadrons][3] = {
523 {iKstarbar0, kPiPlus, 0 },
524 {-1 , -1 , -1 },
525 {iPhi , kPiPlus, 0 },
526 {-1 , -1 , -1 }
527 };
528
530 for (Int_t ihadron = 0; ihadron < kNHadrons; ihadron++) {
531 Int_t kc = pyth->Pycomp(hadron[ihadron]);
532 pyth->SetMDCY(kc,1,1);
533 Int_t ifirst = pyth->GetMDCY(kc,2);
534 Int_t ilast = ifirst + pyth->GetMDCY(kc,3)-1;
535
536 for (channel = ifirst; channel <= ilast; channel++) {
537 if ((pyth->GetKFDP(channel,1) == decayP1[ihadron][0] &&
538 pyth->GetKFDP(channel,2) == decayP1[ihadron][1] &&
539 pyth->GetKFDP(channel,3) == decayP1[ihadron][2] &&
540 pyth->GetKFDP(channel,4) == 0) ||
541 (pyth->GetKFDP(channel,1) == decayP2[ihadron][0] &&
542 pyth->GetKFDP(channel,2) == decayP2[ihadron][1] &&
543 pyth->GetKFDP(channel,3) == decayP2[ihadron][2] &&
544 pyth->GetKFDP(channel,4) == 0)) {
545 pyth->SetMDME(channel,1,1);
546 } else {
547 pyth->SetMDME(channel,1,0);
548 fBraPart[kc] -= pyth->GetBRAT(channel);
549 } // selected channel ?
550 } // decay channels
551 } // hadrons
552}
553
554////////////////////////////////////////////////////////////////////////////////
555///
556/// Force decay of particle into products with multiplicity mult
557
559{
561
562 Int_t kc = pyth->Pycomp(particle);
563 pyth->SetMDCY(kc,1,1);
564
565 Int_t ifirst = pyth->GetMDCY(kc,2);
566 Int_t ilast = ifirst + pyth->GetMDCY(kc,3)-1;
567 fBraPart[kc] = 1;
568
569 //
570 // Loop over decay channels
571 for (Int_t channel= ifirst; channel <= ilast; channel++) {
572 if (CountProducts(channel,product) >= mult) {
573 pyth->SetMDME(channel,1,1);
574 } else {
575 pyth->SetMDME(channel,1,0);
576 fBraPart[kc]-=pyth->GetBRAT(channel);
577 }
578 }
579}
580
581////////////////////////////////////////////////////////////////////////////////
582///
583/// Force decay of particle into products with multiplicity mult
584
586 Int_t* mult, Int_t npart)
587{
589
590 Int_t kc = pyth->Pycomp(particle);
591 pyth->SetMDCY(kc,1,1);
592 Int_t ifirst = pyth->GetMDCY(kc,2);
593 Int_t ilast = ifirst+pyth->GetMDCY(kc,3)-1;
594 fBraPart[kc] = 1;
595 //
596 // Loop over decay channels
597 for (Int_t channel = ifirst; channel <= ilast; channel++) {
598 Int_t nprod = 0;
599 for (Int_t i = 0; i < npart; i++)
600 nprod += (CountProducts(channel, products[i]) >= mult[i]);
601 if (nprod)
602 pyth->SetMDME(channel,1,1);
603 else {
604 pyth->SetMDME(channel,1,0);
605 fBraPart[kc] -= pyth->GetBRAT(channel);
606 }
607 }
608}
609
610////////////////////////////////////////////////////////////////////////////////
611/// Force Omega -> Lambda K- Decay
612
614{
616
617 Int_t kc = pyth->Pycomp(3334);
618 pyth->SetMDCY(kc,1,1);
619 Int_t ifirst = pyth->GetMDCY(kc,2);
620 Int_t ilast = ifirst + pyth->GetMDCY(kc,3)-1;
621 for (Int_t channel = ifirst; channel <= ilast; channel++) {
622 if (pyth->GetKFDP(channel,1) == kLambda0 &&
623 pyth->GetKFDP(channel,2) == kKMinus &&
624 pyth->GetKFDP(channel,3) == 0)
625 pyth->SetMDME(channel,1,1);
626 else
627 pyth->SetMDME(channel,1,0);
628 // selected channel ?
629 } // decay channels
630}
int Int_t
Definition RtypesCore.h:45
float Float_t
Definition RtypesCore.h:57
constexpr Bool_t kFALSE
Definition RtypesCore.h:101
constexpr Bool_t kTRUE
Definition RtypesCore.h:100
#define ClassImp(name)
Definition Rtypes.h:377
winID h TVirtualViewer3D TVirtualGLPainter p
Option_t Option_t TPoint TPoint const char GetTextMagnitude GetFillStyle GetLineColor GetLineWidth GetMarkerStyle GetTextAlign GetTextColor GetTextSize void char Point_t Rectangle_t WindowAttributes_t Float_t Float_t Float_t Int_t Int_t UInt_t UInt_t Rectangle_t Int_t Int_t Window_t TString Int_t GCValues_t GetPrimarySelectionOwner GetDisplay GetScreen GetColormap GetNativeEvent const char const char dpyName wid window const char font_name cursor keysym reg const char only_if_exist regb h Point_t np
Option_t Option_t TPoint TPoint const char GetTextMagnitude GetFillStyle GetLineColor GetLineWidth GetMarkerStyle GetTextAlign GetTextColor GetTextSize void char Point_t Rectangle_t WindowAttributes_t Float_t Float_t Float_t Int_t Int_t UInt_t UInt_t Rectangle_t Int_t Int_t Window_t TString Int_t GCValues_t GetPrimarySelectionOwner GetDisplay GetScreen GetColormap GetNativeEvent const char const char dpyName wid window const char font_name cursor keysym reg const char only_if_exist regb h Point_t winding char text const char depth char const char Int_t count const char ColorStruct_t color const char Pixmap_t Pixmap_t PictureAttributes_t attr const char char ret_data h unsigned char height h Atom_t Int_t ULong_t ULong_t unsigned char prop_list Atom_t Atom_t Atom_t Time_t type
@ kKPlus
Definition TPDGCode.h:33
@ kPiMinus
Definition TPDGCode.h:30
@ kLambda0
Definition TPDGCode.h:33
@ kPiPlus
Definition TPDGCode.h:29
@ kKMinus
Definition TPDGCode.h:33
void Reset()
Definition TArrayF.h:47
An array of clone (identical) objects.
Particle database manager class.
static TDatabasePDG * Instance()
static function
const THashList * ParticleList() const
virtual void ReadPDGTable(const char *filename="")
read list of particles from a file if the particle list does not exist, it is created,...
Description of the decay channel.
virtual TObjArray * GetPrimaries(Option_t *option="")
Definition TGenerator.h:177
THashList implements a hybrid collection class consisting of a hash table and a list to store TObject...
Definition THashList.h:34
const char * GetName() const override
Returns name of object.
Definition TNamed.h:47
An array of TObjects.
Definition TObjArray.h:31
virtual void Warning(const char *method, const char *msgfmt,...) const
Issue warning message.
Definition TObject.cxx:956
Description of the static properties of a particle.
Double_t Lifetime() const
Int_t Stable() const
Int_t PdgCode() const
Double_t Width() const
Double_t Charge() const
TParticlePDG * AntiParticle()
Double_t Mass() const
TObjArray * DecayList()
This class implements the TVirtualMCDecayer interface.
virtual void Decay(Int_t idpart, TLorentzVector *p)
Decay a particle of type IDPART (PDG code) and momentum P.
Int_t CountProducts(Int_t channel, Int_t particle)
Count number of decay products.
virtual void ForceDecay()
Force a particle decay mode.
void ForceParticleDecay(Int_t particle, Int_t *products, Int_t *mult, Int_t npart)
Force decay of particle into products with multiplicity mult.
virtual void SetForceDecay(Int_t type)
Force a particular decay type.
virtual Float_t GetLifetime(Int_t kf)
Get the life-time of a particle of type KF (a PDG code).
static TPythia6Decayer * fgInstance
Branching ratios.
virtual void ReadDecayTable()
Read in particle data from an ASCII file.
virtual void Init()
Initialize the decayer.
virtual Float_t GetPartialBranchingRatio(Int_t ipart)
Get the partial branching ratio for a particle of type IPART (a PDG code).
void ForceOmega()
Force Omega -> Lambda K- Decay.
virtual void WriteDecayTable()
write particle data to an ASCII file.
TPythia6Decayer()
Constructor.
void ForceHadronicD()
Force golden D decay modes.
static TPythia6Decayer * Instance()
Get the singleton object.
virtual Int_t ImportParticles(TClonesArray *particles)
Get the decay products into the passed PARTICLES TClonesArray of TParticles.
TPythia is an interface class to F77 version of Pythia 6.2
Definition TPythia6.h:84
Int_t ImportParticles(TClonesArray *particles, Option_t *option="")
Default primary creation method.
Definition TPythia6.cxx:364
static TPythia6 * Instance()
model of automatic memory cleanup suggested by Jim Kowalkovski: destructor for local static variable ...
Definition TPythia6.cxx:287
void SetMSTJ(int i, int m)
Definition TPythia6.h:159
int Pycomp(int kf)
Definition TPythia6.cxx:547
int GetMDCY(int i, int j)
Definition TPythia6.h:178
void CloseFortranFile(int lun)
interface with fortran i/o
Definition TPythia6.cxx:314
int GetKFDP(int i, int j)
Definition TPythia6.h:181
void SetMDME(int i, int j, int m)
Definition TPythia6.h:184
void OpenFortranFile(int lun, char *name)
interface with fortran i/o
Definition TPythia6.cxx:307
void SetMDCY(int i, int j, int m)
Definition TPythia6.h:183
void Py1ent(Int_t line, Int_t kf, Double_t pe, Double_t theta, Double_t phi)
Add one entry to the event record, i.e.
Definition TPythia6.cxx:664
void Pyupda(int mupda, int lun)
Definition TPythia6.cxx:631
double GetBRAT(int i)
Definition TPythia6.h:180
double GetPMAS(int ip, int i)
Definition TPythia6.h:166
const char * Data() const
Definition TString.h:380
Bool_t IsNull() const
Definition TString.h:418
Short_t Abs(Short_t d)
Returns the absolute value of parameter Short_t d.
Definition TMathBase.h:123