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source: git/classes/DelphesClasses.h@ 0ccf6fd

ImprovedOutputFile Timing dual_readout llp
Last change on this file since 0ccf6fd was a98c7ef, checked in by Michele Selvaggi <michele.selvaggi@…>, 9 years ago

fixed eflow at high pt

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File size: 16.3 KB
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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
[986d9d5]86class LHEFWeight: public TObject
87{
88public:
89 Int_t ID; // weight ID
90 Float_t Weight; // weight value
91
92 ClassDef(LHEFWeight, 1)
93};
94
95//---------------------------------------------------------------------------
96
[d7d2da3]97class HepMCEvent: public Event
98{
99public:
100
101 Int_t ProcessID; // unique signal process id | signal_process_id()
[3b465ca]102 Int_t MPI; // number of multi parton interactions | mpi ()
[d7d2da3]103
[59abd43]104 Float_t Weight; // weight for the event
105
[d7d2da3]106 Float_t Scale; // energy scale, see hep-ph/0109068 | event_scale()
107 Float_t AlphaQED; // QED coupling, see hep-ph/0109068 | alphaQED()
108 Float_t AlphaQCD; // QCD coupling, see hep-ph/0109068 | alphaQCD()
109
110 Int_t ID1; // flavour code of first parton | pdf_info()->id1()
[3b465ca]111 Int_t ID2; // flavour code of second parton | pdf_info()->id2()
[d7d2da3]112
113 Float_t X1; // fraction of beam momentum carried by first parton ("beam side") | pdf_info()->x1()
114 Float_t X2; // fraction of beam momentum carried by second parton ("target side") | pdf_info()->x2()
115
116 Float_t ScalePDF; // Q-scale used in evaluation of PDF's (in GeV) | pdf_info()->scalePDF()
117
118 Float_t PDF1; // PDF (id1, x1, Q) | pdf_info()->pdf1()
119 Float_t PDF2; // PDF (id2, x2, Q) | pdf_info()->pdf2()
120
121 ClassDef(HepMCEvent, 2)
122};
123
124//---------------------------------------------------------------------------
125
126class GenParticle: public SortableObject
127{
128public:
129 Int_t PID; // particle HEP ID number | hepevt.idhep[number]
130
131 Int_t Status; // particle status | hepevt.isthep[number]
132 Int_t IsPU; // 0 or 1 for particles from pile-up interactions
[3b465ca]133
[d7d2da3]134 Int_t M1; // particle 1st mother | hepevt.jmohep[number][0] - 1
135 Int_t M2; // particle 2nd mother | hepevt.jmohep[number][1] - 1
136
137 Int_t D1; // particle 1st daughter | hepevt.jdahep[number][0] - 1
138 Int_t D2; // particle last daughter | hepevt.jdahep[number][1] - 1
139
140 Int_t Charge; // particle charge
141
142 Float_t Mass; // particle mass
143
144 Float_t E; // particle energy | hepevt.phep[number][3]
145 Float_t Px; // particle momentum vector (x component) | hepevt.phep[number][0]
146 Float_t Py; // particle momentum vector (y component) | hepevt.phep[number][1]
147 Float_t Pz; // particle momentum vector (z component) | hepevt.phep[number][2]
148
149 Float_t PT; // particle transverse momentum
150 Float_t Eta; // particle pseudorapidity
151 Float_t Phi; // particle azimuthal angle
152
153 Float_t Rapidity; // particle rapidity
154
155 Float_t T; // particle vertex position (t component) | hepevt.vhep[number][3]
156 Float_t X; // particle vertex position (x component) | hepevt.vhep[number][0]
157 Float_t Y; // particle vertex position (y component) | hepevt.vhep[number][1]
158 Float_t Z; // particle vertex position (z component) | hepevt.vhep[number][2]
159
160 static CompBase *fgCompare; //!
161 const CompBase *GetCompare() const { return fgCompare; }
[3b465ca]162
[2b3ef28]163 TLorentzVector P4() const;
[d7d2da3]164
165 ClassDef(GenParticle, 1)
166};
167
168//---------------------------------------------------------------------------
169
[d07e957]170class Vertex: public TObject
171{
172public:
173 Float_t T; // vertex position (t component)
174 Float_t X; // vertex position (x component)
175 Float_t Y; // vertex position (y component)
176 Float_t Z; // vertex position (z component)
177
178 ClassDef(Vertex, 1)
179};
180
181//---------------------------------------------------------------------------
182
[d7d2da3]183class MissingET: public TObject
184{
185public:
186 Float_t MET; // mising transverse energy
[4ad7b96]187 Float_t Eta; // mising energy pseudorapidity
[d7d2da3]188 Float_t Phi; // mising energy azimuthal angle
189
[2b3ef28]190 TLorentzVector P4() const;
[4ad7b96]191
[d7d2da3]192 ClassDef(MissingET, 1)
193};
194
195//---------------------------------------------------------------------------
196
197class ScalarHT: public TObject
198{
199public:
200 Float_t HT; // scalar sum of transverse momenta
201
202 ClassDef(ScalarHT, 1)
203};
204
205//---------------------------------------------------------------------------
206
[71648c2]207class Rho: public TObject
208{
209public:
210 Float_t Rho; // rho energy density
[3b465ca]211 Float_t Edges[2]; // pseudorapidity range edges
[71648c2]212
213 ClassDef(Rho, 1)
214};
215
216//---------------------------------------------------------------------------
217
[2e229c9]218class Weight: public TObject
219{
220public:
221 Float_t Weight; // weight for the event
222
223 ClassDef(Weight, 1)
224};
225
226//---------------------------------------------------------------------------
227
[d7d2da3]228class Photon: public SortableObject
229{
230public:
231
232 Float_t PT; // photon transverse momentum
233 Float_t Eta; // photon pseudorapidity
234 Float_t Phi; // photon azimuthal angle
235
236 Float_t E; // photon energy
[da00c35]237
238 Float_t T; //particle arrival time of flight
239
[d7d2da3]240 Float_t EhadOverEem; // ratio of the hadronic versus electromagnetic energy deposited in the calorimeter
241
242 TRefArray Particles; // references to generated particles
243
[b62c2da]244 // Isolation variables
[edf10ba]245
[b62c2da]246 Float_t IsolationVar;
247 Float_t IsolationVarRhoCorr;
248 Float_t SumPtCharged;
249 Float_t SumPtNeutral;
250 Float_t SumPtChargedPU;
251 Float_t SumPt;
252
[d7d2da3]253 static CompBase *fgCompare; //!
254 const CompBase *GetCompare() const { return fgCompare; }
255
[2b3ef28]256 TLorentzVector P4() const;
[d7d2da3]257
[eb52a5d]258 ClassDef(Photon, 3)
[d7d2da3]259};
260
261//---------------------------------------------------------------------------
262
263class Electron: public SortableObject
264{
265public:
266
267 Float_t PT; // electron transverse momentum
268 Float_t Eta; // electron pseudorapidity
269 Float_t Phi; // electron azimuthal angle
[da00c35]270
271 Float_t T; //particle arrival time of flight
272
[d7d2da3]273 Int_t Charge; // electron charge
274
275 Float_t EhadOverEem; // ratio of the hadronic versus electromagnetic energy deposited in the calorimeter
276
277 TRef Particle; // reference to generated particle
278
[b62c2da]279 // Isolation variables
[edf10ba]280
[b62c2da]281 Float_t IsolationVar;
282 Float_t IsolationVarRhoCorr;
283 Float_t SumPtCharged;
284 Float_t SumPtNeutral;
285 Float_t SumPtChargedPU;
286 Float_t SumPt;
287
[d7d2da3]288 static CompBase *fgCompare; //!
289 const CompBase *GetCompare() const { return fgCompare; }
290
[2b3ef28]291 TLorentzVector P4() const;
[d7d2da3]292
[eb52a5d]293 ClassDef(Electron, 3)
[d7d2da3]294};
295
296//---------------------------------------------------------------------------
297
298class Muon: public SortableObject
299{
300public:
301
302 Float_t PT; // muon transverse momentum
303 Float_t Eta; // muon pseudorapidity
304 Float_t Phi; // muon azimuthal angle
305
[da00c35]306 Float_t T; //particle arrival time of flight
307
[d7d2da3]308 Int_t Charge; // muon charge
309
310 TRef Particle; // reference to generated particle
311
[b62c2da]312 // Isolation variables
[edf10ba]313
[b62c2da]314 Float_t IsolationVar;
315 Float_t IsolationVarRhoCorr;
316 Float_t SumPtCharged;
317 Float_t SumPtNeutral;
318 Float_t SumPtChargedPU;
319 Float_t SumPt;
320
[d7d2da3]321 static CompBase *fgCompare; //!
322 const CompBase *GetCompare() const { return fgCompare; }
323
[2b3ef28]324 TLorentzVector P4() const;
[d7d2da3]325
[eb52a5d]326 ClassDef(Muon, 3)
[d7d2da3]327};
328
329//---------------------------------------------------------------------------
330
331class Jet: public SortableObject
332{
333public:
334
335 Float_t PT; // jet transverse momentum
336 Float_t Eta; // jet pseudorapidity
337 Float_t Phi; // jet azimuthal angle
338
[da00c35]339 Float_t T; //particle arrival time of flight
340
[d7d2da3]341 Float_t Mass; // jet invariant mass
342
343 Float_t DeltaEta; // jet radius in pseudorapidity
344 Float_t DeltaPhi; // jet radius in azimuthal angle
345
[fe0273c]346 UInt_t Flavor;
347 UInt_t FlavorAlgo;
348 UInt_t FlavorPhys;
[edf10ba]349
[fe0273c]350 UInt_t BTag; // 0 or 1 for a jet that has been tagged as containing a heavy quark
[edf10ba]351 UInt_t BTagAlgo;
[fe0273c]352 UInt_t BTagPhys;
[edf10ba]353
[264bf40]354 UInt_t TauTag; // 0 or 1 for a jet that has been tagged as a tau
[d7d2da3]355
356 Int_t Charge; // tau charge
357
358 Float_t EhadOverEem; // ratio of the hadronic versus electromagnetic energy deposited in the calorimeter
359
[edf10ba]360 Int_t NCharged; // number of charged constituents
361 Int_t NNeutrals; // number of neutral constituents
362 Float_t Beta; // (sum pt of charged pile-up constituents)/(sum pt of charged constituents)
363 Float_t BetaStar; // (sum pt of charged constituents coming from hard interaction)/(sum pt of charged constituents)
364 Float_t MeanSqDeltaR; // average distance (squared) between constituent and jet weighted by pt (squared) of constituent
365 Float_t PTD; // average pt between constituent and jet weighted by pt of constituent
366 Float_t FracPt[5]; // (sum pt of constituents within a ring 0.1*i < DeltaR < 0.1*(i+1))/(sum pt of constituents)
[63178fb]367
[666d795]368 Float_t Tau[5]; // N-subjettiness
[edf10ba]369
370 TLorentzVector TrimmedP4[5]; // first entry (i = 0) is the total Trimmed Jet 4-momenta and from i = 1 to 4 are the trimmed subjets 4-momenta
371 TLorentzVector PrunedP4[5]; // first entry (i = 0) is the total Pruned Jet 4-momenta and from i = 1 to 4 are the pruned subjets 4-momenta
372 TLorentzVector SoftDroppedP4[5]; // first entry (i = 0) is the total SoftDropped Jet 4-momenta and from i = 1 to 4 are the pruned subjets 4-momenta
373
374 Int_t NSubJetsTrimmed; // number of subjets trimmed
375 Int_t NSubJetsPruned; // number of subjets pruned
376 Int_t NSubJetsSoftDropped; // number of subjets soft-dropped
377
[e4c3fef]378 TRefArray Constituents; // references to constituents
379 TRefArray Particles; // references to generated particles
380
381 static CompBase *fgCompare; //!
382 const CompBase *GetCompare() const { return fgCompare; }
383
[8707eeb]384 TLorentzVector P4() const;
[ba1f1ee]385 TLorentzVector Area;
[24d005f]386
[666d795]387 ClassDef(Jet, 3)
[d7d2da3]388};
389
390//---------------------------------------------------------------------------
391
[3b465ca]392class Track: public SortableObject
[d7d2da3]393{
[3b465ca]394public:
[d7d2da3]395 Int_t PID; // HEP ID number
396
397 Int_t Charge; // track charge
398
399 Float_t PT; // track transverse momentum
400
401 Float_t Eta; // track pseudorapidity
402 Float_t Phi; // track azimuthal angle
403
404 Float_t EtaOuter; // track pseudorapidity at the tracker edge
405 Float_t PhiOuter; // track azimuthal angle at the tracker edge
406
407 Float_t X; // track vertex position (x component)
408 Float_t Y; // track vertex position (y component)
409 Float_t Z; // track vertex position (z component)
[22dc7fd]410 Float_t T; // track vertex position (z component)
[d7d2da3]411
412 Float_t XOuter; // track position (x component) at the tracker edge
413 Float_t YOuter; // track position (y component) at the tracker edge
414 Float_t ZOuter; // track position (z component) at the tracker edge
[22dc7fd]415 Float_t TOuter; // track position (z component) at the tracker edge
[e4c3fef]416
[a0431dc]417 Float_t Dxy; // track signed transverse impact parameter
418 Float_t SDxy; // signed error on the track signed transverse impact parameter
419 Float_t Xd; // X coordinate of point of closest approach to vertex
420 Float_t Yd; // Y coordinate of point of closest approach to vertex
421 Float_t Zd; // Z coordinate of point of closest approach to vertex
[d7d2da3]422
423 TRef Particle; // reference to generated particle
424
425 static CompBase *fgCompare; //!
426 const CompBase *GetCompare() const { return fgCompare; }
427
[2b3ef28]428 TLorentzVector P4() const;
[d7d2da3]429
[e4c3fef]430 ClassDef(Track, 2)
[d7d2da3]431};
432
433//---------------------------------------------------------------------------
434
[3b465ca]435class Tower: public SortableObject
[d7d2da3]436{
437public:
438 Float_t ET; // calorimeter tower transverse energy
439 Float_t Eta; // calorimeter tower pseudorapidity
440 Float_t Phi; // calorimeter tower azimuthal angle
441
442 Float_t E; // calorimeter tower energy
443
[3db5282]444 Float_t T; // ecal deposit time, averaged by sqrt(EM energy) over all particles, not smeared
[839deb7]445 Int_t NTimeHits; // number of hits contributing to time measurement
[edf10ba]446
[d7d2da3]447 Float_t Eem; // calorimeter tower electromagnetic energy
448 Float_t Ehad; // calorimeter tower hadronic energy
449
450 Float_t Edges[4]; // calorimeter tower edges
451
452 TRefArray Particles; // references to generated particles
453
454 static CompBase *fgCompare; //!
455 const CompBase *GetCompare() const { return fgCompare; }
456
[2b3ef28]457 TLorentzVector P4() const;
[d7d2da3]458
[eb52a5d]459 ClassDef(Tower, 2)
[d7d2da3]460};
461
462//---------------------------------------------------------------------------
463
[8f7db23]464class HectorHit: public SortableObject
465{
466public:
467 Float_t E; // reconstructed energy [GeV]
468
469 Float_t Tx; // angle of the momentum in the horizontal (x,z) plane [urad]
470 Float_t Ty; // angle of the momentum in the verical (y,z) plane [urad]
471
472 Float_t T; // time of flight to the detector [s]
473
474 Float_t X; // horizontal distance to the beam [um]
475 Float_t Y; // vertical distance to the beam [um]
476 Float_t S; // distance to the interaction point [m]
477
[64a4950]478 TRef Particle; // reference to generated particle
479
[8f7db23]480 static CompBase *fgCompare; //!
481 const CompBase *GetCompare() const { return fgCompare; }
482
483 ClassDef(HectorHit, 1)
484};
485
486//---------------------------------------------------------------------------
487
[3b465ca]488class Candidate: public SortableObject
[d7d2da3]489{
490 friend class DelphesFactory;
491
492public:
493 Candidate();
494
495 Int_t PID;
496
497 Int_t Status;
498 Int_t M1, M2, D1, D2;
499
500 Int_t Charge;
501
502 Float_t Mass;
[3b465ca]503
[d7d2da3]504 Int_t IsPU;
[b62c2da]505 Int_t IsRecoPU;
[edf10ba]506
[d7d2da3]507 Int_t IsConstituent;
[839deb7]508
[5d2481f]509 Int_t IsFromConversion;
[839deb7]510
[fe0273c]511 UInt_t Flavor;
512 UInt_t FlavorAlgo;
513 UInt_t FlavorPhys;
[edf10ba]514
[fe0273c]515 UInt_t BTag;
[edf10ba]516 UInt_t BTagAlgo;
[fe0273c]517 UInt_t BTagPhys;
[edf10ba]518
[264bf40]519 UInt_t TauTag;
[d7d2da3]520
521 Float_t Eem;
522 Float_t Ehad;
523
524 Float_t Edges[4];
525 Float_t DeltaEta;
526 Float_t DeltaPhi;
527
528 TLorentzVector Momentum, Position, Area;
[e4c3fef]529
[839deb7]530 Float_t Dxy;
531 Float_t SDxy;
532 Float_t Xd;
533 Float_t Yd;
534 Float_t Zd;
[d7d2da3]535
[a98c7ef]536 // tracking resolution
537
538 Float_t TrackResolution;
539
[da00c35]540 // PileUpJetID variables
541
[839deb7]542 Int_t NCharged;
543 Int_t NNeutrals;
544 Float_t Beta;
545 Float_t BetaStar;
546 Float_t MeanSqDeltaR;
547 Float_t PTD;
548 Float_t FracPt[5];
[edf10ba]549
[839deb7]550 // Timing information
[edf10ba]551
[839deb7]552 Int_t NTimeHits;
553 std::vector< std::pair< Float_t, Float_t > > ECalEnergyTimePairs;
[e4c3fef]554
[b62c2da]555 // Isolation variables
[edf10ba]556
[b62c2da]557 Float_t IsolationVar;
558 Float_t IsolationVarRhoCorr;
559 Float_t SumPtCharged;
560 Float_t SumPtNeutral;
561 Float_t SumPtChargedPU;
562 Float_t SumPt;
563
[63178fb]564 // N-subjettiness variables
[e4c3fef]565
566 Float_t Tau[5];
[edf10ba]567
[de6d698]568 // Other Substructure variables
[edf10ba]569
570 TLorentzVector TrimmedP4[5]; // first entry (i = 0) is the total Trimmed Jet 4-momenta and from i = 1 to 4 are the trimmed subjets 4-momenta
571 TLorentzVector PrunedP4[5]; // first entry (i = 0) is the total Pruned Jet 4-momenta and from i = 1 to 4 are the pruned subjets 4-momenta
572 TLorentzVector SoftDroppedP4[5]; // first entry (i = 0) is the total SoftDropped Jet 4-momenta and from i = 1 to 4 are the pruned subjets 4-momenta
573
574 Int_t NSubJetsTrimmed; // number of subjets trimmed
575 Int_t NSubJetsPruned; // number of subjets pruned
576 Int_t NSubJetsSoftDropped; // number of subjets soft-dropped
[de6d698]577
[e4c3fef]578
[d7d2da3]579 static CompBase *fgCompare; //!
580 const CompBase *GetCompare() const { return fgCompare; }
581
582 void AddCandidate(Candidate *object);
583 TObjArray *GetCandidates();
584
585 Bool_t Overlaps(const Candidate *object) const;
586
587 virtual void Copy(TObject &object) const;
588 virtual TObject *Clone(const char *newname = "") const;
[3b465ca]589 virtual void Clear(Option_t* option = "");
[d7d2da3]590
591private:
592 DelphesFactory *fFactory; //!
593 TObjArray *fArray; //!
[3b465ca]594
[d7d2da3]595 void SetFactory(DelphesFactory *factory) { fFactory = factory; }
596
[a98c7ef]597 ClassDef(Candidate, 4)
[d7d2da3]598};
599
600#endif // DelphesClasses_h
601
602
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