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[b443089]1/*
2 * Delphes: a framework for fast simulation of a generic collider experiment
3 * Copyright (C) 2012-2014 Universite catholique de Louvain (UCL), Belgium
[1fa50c2]4 *
[b443089]5 * This program is free software: you can redistribute it and/or modify
6 * it under the terms of the GNU General Public License as published by
7 * the Free Software Foundation, either version 3 of the License, or
8 * (at your option) any later version.
[1fa50c2]9 *
[b443089]10 * This program is distributed in the hope that it will be useful,
11 * but WITHOUT ANY WARRANTY; without even the implied warranty of
12 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
13 * GNU General Public License for more details.
[1fa50c2]14 *
[b443089]15 * You should have received a copy of the GNU General Public License
16 * along with this program. If not, see <http://www.gnu.org/licenses/>.
17 */
18
[d7d2da3]19#ifndef DelphesClasses_h
20#define DelphesClasses_h
21
22/**
23 *
24 * Definition of classes to be stored in the root tree.
25 * Function CompareXYZ sorts objects by the variable XYZ that MUST be
26 * present in the data members of the root tree class of the branch.
27 *
28 * \author P. Demin - UCL, Louvain-la-Neuve
29 *
30 */
31
32// Dependencies (#includes)
33
34#include "TRef.h"
35#include "TObject.h"
36#include "TRefArray.h"
37#include "TLorentzVector.h"
38
39#include "classes/SortableObject.h"
40
41class DelphesFactory;
42
43//---------------------------------------------------------------------------
44
45class Event: public TObject
46{
47public:
48
49 Long64_t Number; // event number
50
51 Float_t ReadTime;
[3b465ca]52 Float_t ProcTime;
[d7d2da3]53
54 ClassDef(Event, 1)
55};
56
57//---------------------------------------------------------------------------
58
59class LHCOEvent: public Event
60{
61public:
62
63 Int_t Trigger; // trigger word
64
65 ClassDef(LHCOEvent, 1)
66};
67
68//---------------------------------------------------------------------------
69
70class LHEFEvent: public Event
71{
72public:
73
74 Int_t ProcessID; // subprocess code for the event | hepup.IDPRUP
75
76 Float_t Weight; // weight for the event | hepup.XWGTUP
77 Float_t ScalePDF; // scale in GeV used in the calculation of the PDFs in the event | hepup.SCALUP
78 Float_t AlphaQED; // value of the QED coupling used in the event | hepup.AQEDUP
79 Float_t AlphaQCD; // value of the QCD coupling used in the event | hepup.AQCDUP
80
81 ClassDef(LHEFEvent, 2)
82};
83
84//---------------------------------------------------------------------------
85
86class HepMCEvent: public Event
87{
88public:
89
90 Int_t ProcessID; // unique signal process id | signal_process_id()
[3b465ca]91 Int_t MPI; // number of multi parton interactions | mpi ()
[d7d2da3]92
[59abd43]93 Float_t Weight; // weight for the event
94
[d7d2da3]95 Float_t Scale; // energy scale, see hep-ph/0109068 | event_scale()
96 Float_t AlphaQED; // QED coupling, see hep-ph/0109068 | alphaQED()
97 Float_t AlphaQCD; // QCD coupling, see hep-ph/0109068 | alphaQCD()
98
99 Int_t ID1; // flavour code of first parton | pdf_info()->id1()
[3b465ca]100 Int_t ID2; // flavour code of second parton | pdf_info()->id2()
[d7d2da3]101
102 Float_t X1; // fraction of beam momentum carried by first parton ("beam side") | pdf_info()->x1()
103 Float_t X2; // fraction of beam momentum carried by second parton ("target side") | pdf_info()->x2()
104
105 Float_t ScalePDF; // Q-scale used in evaluation of PDF's (in GeV) | pdf_info()->scalePDF()
106
107 Float_t PDF1; // PDF (id1, x1, Q) | pdf_info()->pdf1()
108 Float_t PDF2; // PDF (id2, x2, Q) | pdf_info()->pdf2()
109
110 ClassDef(HepMCEvent, 2)
111};
112
113//---------------------------------------------------------------------------
114
115class GenParticle: public SortableObject
116{
117public:
118 Int_t PID; // particle HEP ID number | hepevt.idhep[number]
119
120 Int_t Status; // particle status | hepevt.isthep[number]
121 Int_t IsPU; // 0 or 1 for particles from pile-up interactions
[3b465ca]122
[d7d2da3]123 Int_t M1; // particle 1st mother | hepevt.jmohep[number][0] - 1
124 Int_t M2; // particle 2nd mother | hepevt.jmohep[number][1] - 1
125
126 Int_t D1; // particle 1st daughter | hepevt.jdahep[number][0] - 1
127 Int_t D2; // particle last daughter | hepevt.jdahep[number][1] - 1
128
129 Int_t Charge; // particle charge
130
131 Float_t Mass; // particle mass
132
133 Float_t E; // particle energy | hepevt.phep[number][3]
134 Float_t Px; // particle momentum vector (x component) | hepevt.phep[number][0]
135 Float_t Py; // particle momentum vector (y component) | hepevt.phep[number][1]
136 Float_t Pz; // particle momentum vector (z component) | hepevt.phep[number][2]
137
138 Float_t PT; // particle transverse momentum
139 Float_t Eta; // particle pseudorapidity
140 Float_t Phi; // particle azimuthal angle
141
142 Float_t Rapidity; // particle rapidity
143
144 Float_t T; // particle vertex position (t component) | hepevt.vhep[number][3]
145 Float_t X; // particle vertex position (x component) | hepevt.vhep[number][0]
146 Float_t Y; // particle vertex position (y component) | hepevt.vhep[number][1]
147 Float_t Z; // particle vertex position (z component) | hepevt.vhep[number][2]
148
149 static CompBase *fgCompare; //!
150 const CompBase *GetCompare() const { return fgCompare; }
[3b465ca]151
[d7d2da3]152 TLorentzVector P4();
153
154 ClassDef(GenParticle, 1)
155};
156
157//---------------------------------------------------------------------------
158
[d07e957]159class Vertex: public TObject
160{
161public:
162 Float_t T; // vertex position (t component)
163 Float_t X; // vertex position (x component)
164 Float_t Y; // vertex position (y component)
165 Float_t Z; // vertex position (z component)
166
167 ClassDef(Vertex, 1)
168};
169
170//---------------------------------------------------------------------------
171
[d7d2da3]172class MissingET: public TObject
173{
174public:
175 Float_t MET; // mising transverse energy
[4ad7b96]176 Float_t Eta; // mising energy pseudorapidity
[d7d2da3]177 Float_t Phi; // mising energy azimuthal angle
178
[4ad7b96]179 TLorentzVector P4();
180
[d7d2da3]181 ClassDef(MissingET, 1)
182};
183
184//---------------------------------------------------------------------------
185
186class ScalarHT: public TObject
187{
188public:
189 Float_t HT; // scalar sum of transverse momenta
190
191 ClassDef(ScalarHT, 1)
192};
193
194//---------------------------------------------------------------------------
195
[71648c2]196class Rho: public TObject
197{
198public:
199 Float_t Rho; // rho energy density
[3b465ca]200 Float_t Edges[2]; // pseudorapidity range edges
[71648c2]201
202 ClassDef(Rho, 1)
203};
204
205//---------------------------------------------------------------------------
206
[2e229c9]207class Weight: public TObject
208{
209public:
210 Float_t Weight; // weight for the event
211
212 ClassDef(Weight, 1)
213};
214
215//---------------------------------------------------------------------------
216
[d7d2da3]217class Photon: public SortableObject
218{
219public:
220
221 Float_t PT; // photon transverse momentum
222 Float_t Eta; // photon pseudorapidity
223 Float_t Phi; // photon azimuthal angle
224
225 Float_t E; // photon energy
[da00c35]226
227 Float_t T; //particle arrival time of flight
228
[d7d2da3]229 Float_t EhadOverEem; // ratio of the hadronic versus electromagnetic energy deposited in the calorimeter
230
231 TRefArray Particles; // references to generated particles
232
233 static CompBase *fgCompare; //!
234 const CompBase *GetCompare() const { return fgCompare; }
235
236 TLorentzVector P4();
237
238 ClassDef(Photon, 2)
239};
240
241//---------------------------------------------------------------------------
242
243class Electron: public SortableObject
244{
245public:
246
247 Float_t PT; // electron transverse momentum
248 Float_t Eta; // electron pseudorapidity
249 Float_t Phi; // electron azimuthal angle
[da00c35]250
251 Float_t T; //particle arrival time of flight
252
[d7d2da3]253 Int_t Charge; // electron charge
254
255 Float_t EhadOverEem; // ratio of the hadronic versus electromagnetic energy deposited in the calorimeter
256
257 TRef Particle; // reference to generated particle
258
259 static CompBase *fgCompare; //!
260 const CompBase *GetCompare() const { return fgCompare; }
261
262 TLorentzVector P4();
263
264 ClassDef(Electron, 2)
265};
266
267//---------------------------------------------------------------------------
268
269class Muon: public SortableObject
270{
271public:
272
273 Float_t PT; // muon transverse momentum
274 Float_t Eta; // muon pseudorapidity
275 Float_t Phi; // muon azimuthal angle
276
[da00c35]277 Float_t T; //particle arrival time of flight
278
[d7d2da3]279 Int_t Charge; // muon charge
280
281 TRef Particle; // reference to generated particle
282
283 static CompBase *fgCompare; //!
284 const CompBase *GetCompare() const { return fgCompare; }
285
286 TLorentzVector P4();
287
288 ClassDef(Muon, 2)
289};
290
291//---------------------------------------------------------------------------
292
293class Jet: public SortableObject
294{
295public:
296
297 Float_t PT; // jet transverse momentum
298 Float_t Eta; // jet pseudorapidity
299 Float_t Phi; // jet azimuthal angle
300
[da00c35]301 Float_t T; //particle arrival time of flight
302
[d7d2da3]303 Float_t Mass; // jet invariant mass
304
305 Float_t DeltaEta; // jet radius in pseudorapidity
306 Float_t DeltaPhi; // jet radius in azimuthal angle
307
[264bf40]308 UInt_t BTag; // 0 or 1 for a jet that has been tagged as containing a heavy quark
309 UInt_t TauTag; // 0 or 1 for a jet that has been tagged as a tau
[d7d2da3]310
311 Int_t Charge; // tau charge
312
313 Float_t EhadOverEem; // ratio of the hadronic versus electromagnetic energy deposited in the calorimeter
314
[63178fb]315 Int_t NCharged; // number of charged constituents
316 Int_t NNeutrals; // number of neutral constituents
317 Float_t Beta; // (sum pt of charged pile-up constituents)/(sum pt of charged constituents)
318 Float_t BetaStar; // (sum pt of charged constituents coming from hard interaction)/(sum pt of charged constituents)
319 Float_t MeanSqDeltaR; // average distance (squared) between constituent and jet weighted by pt (squared) of constituent
320 Float_t PTD; // average pt between constituent and jet weighted by pt of constituent
321 Float_t FracPt[5]; // (sum pt of constituents within a ring 0.1*i < DeltaR < 0.1*(i+1))/(sum pt of constituents)
322
323 Float_t Tau1; // 1-subjettiness
324 Float_t Tau2; // 2-subjettiness
325 Float_t Tau3; // 3-subjettiness
326 Float_t Tau4; // 4-subjettiness
327 Float_t Tau5; // 5-subjettiness
[e4c3fef]328
329 TRefArray Constituents; // references to constituents
330 TRefArray Particles; // references to generated particles
331
332 static CompBase *fgCompare; //!
333 const CompBase *GetCompare() const { return fgCompare; }
334
335 TLorentzVector P4();
[24d005f]336
[d7d2da3]337 ClassDef(Jet, 2)
338};
339
340//---------------------------------------------------------------------------
341
[3b465ca]342class Track: public SortableObject
[d7d2da3]343{
[3b465ca]344public:
[d7d2da3]345 Int_t PID; // HEP ID number
346
347 Int_t Charge; // track charge
348
349 Float_t PT; // track transverse momentum
350
351 Float_t Eta; // track pseudorapidity
352 Float_t Phi; // track azimuthal angle
353
354 Float_t EtaOuter; // track pseudorapidity at the tracker edge
355 Float_t PhiOuter; // track azimuthal angle at the tracker edge
356
357 Float_t X; // track vertex position (x component)
358 Float_t Y; // track vertex position (y component)
359 Float_t Z; // track vertex position (z component)
[22dc7fd]360 Float_t T; // track vertex position (z component)
[d7d2da3]361
362 Float_t XOuter; // track position (x component) at the tracker edge
363 Float_t YOuter; // track position (y component) at the tracker edge
364 Float_t ZOuter; // track position (z component) at the tracker edge
[22dc7fd]365 Float_t TOuter; // track position (z component) at the tracker edge
[e4c3fef]366
[a0431dc]367 Float_t Dxy; // track signed transverse impact parameter
368 Float_t SDxy; // signed error on the track signed transverse impact parameter
369 Float_t Xd; // X coordinate of point of closest approach to vertex
370 Float_t Yd; // Y coordinate of point of closest approach to vertex
371 Float_t Zd; // Z coordinate of point of closest approach to vertex
[d7d2da3]372
373 TRef Particle; // reference to generated particle
374
375 static CompBase *fgCompare; //!
376 const CompBase *GetCompare() const { return fgCompare; }
377
378 TLorentzVector P4();
379
[e4c3fef]380 ClassDef(Track, 2)
[d7d2da3]381};
382
383//---------------------------------------------------------------------------
384
[3b465ca]385class Tower: public SortableObject
[d7d2da3]386{
387public:
388 Float_t ET; // calorimeter tower transverse energy
389 Float_t Eta; // calorimeter tower pseudorapidity
390 Float_t Phi; // calorimeter tower azimuthal angle
391
392 Float_t E; // calorimeter tower energy
393
[da00c35]394 Float_t T; //particle arrival time of flight
395
[d7d2da3]396 Float_t Eem; // calorimeter tower electromagnetic energy
397 Float_t Ehad; // calorimeter tower hadronic energy
398
399 Float_t Edges[4]; // calorimeter tower edges
400
401 TRefArray Particles; // references to generated particles
402
403 static CompBase *fgCompare; //!
404 const CompBase *GetCompare() const { return fgCompare; }
405
406 TLorentzVector P4();
407
408 ClassDef(Tower, 1)
409};
410
411//---------------------------------------------------------------------------
412
[8f7db23]413class HectorHit: public SortableObject
414{
415public:
416 Float_t E; // reconstructed energy [GeV]
417
418 Float_t Tx; // angle of the momentum in the horizontal (x,z) plane [urad]
419 Float_t Ty; // angle of the momentum in the verical (y,z) plane [urad]
420
421 Float_t T; // time of flight to the detector [s]
422
423 Float_t X; // horizontal distance to the beam [um]
424 Float_t Y; // vertical distance to the beam [um]
425 Float_t S; // distance to the interaction point [m]
426
[64a4950]427 TRef Particle; // reference to generated particle
428
[8f7db23]429 static CompBase *fgCompare; //!
430 const CompBase *GetCompare() const { return fgCompare; }
431
432 ClassDef(HectorHit, 1)
433};
434
435//---------------------------------------------------------------------------
436
[3b465ca]437class Candidate: public SortableObject
[d7d2da3]438{
439 friend class DelphesFactory;
440
441public:
442 Candidate();
443
444 Int_t PID;
445
446 Int_t Status;
447 Int_t M1, M2, D1, D2;
448
449 Int_t Charge;
450
451 Float_t Mass;
[3b465ca]452
[d7d2da3]453 Int_t IsPU;
454 Int_t IsConstituent;
[3b465ca]455
[264bf40]456 UInt_t BTag;
457 UInt_t TauTag;
[d7d2da3]458
459 Float_t Eem;
460 Float_t Ehad;
461
462 Float_t Edges[4];
463 Float_t DeltaEta;
464 Float_t DeltaPhi;
465
466 TLorentzVector Momentum, Position, Area;
[e4c3fef]467
468 Float_t Dxy;
469 Float_t SDxy;
470 Float_t Xd;
471 Float_t Yd;
472 Float_t Zd;
[d7d2da3]473
[da00c35]474 // PileUpJetID variables
475
476 Int_t NCharged;
477 Int_t NNeutrals;
478 Float_t Beta;
479 Float_t BetaStar;
480 Float_t MeanSqDeltaR;
481 Float_t PTD;
482 Float_t FracPt[5];
[e4c3fef]483
[63178fb]484 // N-subjettiness variables
[e4c3fef]485
486 Float_t Tau[5];
487
[d7d2da3]488 static CompBase *fgCompare; //!
489 const CompBase *GetCompare() const { return fgCompare; }
490
491 void AddCandidate(Candidate *object);
492 TObjArray *GetCandidates();
493
494 Bool_t Overlaps(const Candidate *object) const;
495
496 virtual void Copy(TObject &object) const;
497 virtual TObject *Clone(const char *newname = "") const;
[3b465ca]498 virtual void Clear(Option_t* option = "");
[d7d2da3]499
500private:
501 DelphesFactory *fFactory; //!
502 TObjArray *fArray; //!
[3b465ca]503
[d7d2da3]504 void SetFactory(DelphesFactory *factory) { fFactory = factory; }
505
[e4c3fef]506 ClassDef(Candidate, 2)
[d7d2da3]507};
508
509#endif // DelphesClasses_h
510
511
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