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HcalRecHitsValidation.cc
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7 
9  : topFolderName_ (conf.getParameter<std::string>("TopFolderName"))
10 {
11  // DQM ROOT output
12  outputFile_ = conf.getUntrackedParameter<std::string>("outputFile", "myfile.root");
13 
14  if ( outputFile_.size() != 0 ) {
15  edm::LogInfo("OutputInfo") << " Hcal RecHit Task histograms will be saved to '" << outputFile_.c_str() << "'";
16  } else {
17  edm::LogInfo("OutputInfo") << " Hcal RecHit Task histograms will NOT be saved";
18  }
19 
20  nevtot = 0;
21 
22  hcalselector_ = conf.getUntrackedParameter<std::string>("hcalselector", "all");
23  ecalselector_ = conf.getUntrackedParameter<std::string>("ecalselector", "yes");
24  sign_ = conf.getUntrackedParameter<std::string>("sign", "*");
25  mc_ = conf.getUntrackedParameter<std::string>("mc", "yes");
26  testNumber_ = conf.getParameter<bool>("TestNumber");
27 
28  //Collections
29  tok_hbhe_ = consumes<HBHERecHitCollection>(conf.getUntrackedParameter<edm::InputTag>("HBHERecHitCollectionLabel"));
30  tok_hf_ = consumes<HFRecHitCollection>(conf.getUntrackedParameter<edm::InputTag>("HFRecHitCollectionLabel"));
31  tok_ho_ = consumes<HORecHitCollection>(conf.getUntrackedParameter<edm::InputTag>("HORecHitCollectionLabel"));
32 
33  // register for data access
34  tok_evt_ = consumes<edm::HepMCProduct>(edm::InputTag("generatorSmeared"));
35  edm::InputTag EBRecHitCollectionLabel = conf.getParameter<edm::InputTag>("EBRecHitCollectionLabel");
36  tok_EB_ = consumes<EBRecHitCollection>(EBRecHitCollectionLabel);
37  edm::InputTag EERecHitCollectionLabel = conf.getParameter<edm::InputTag>("EERecHitCollectionLabel");
38  tok_EE_ = consumes<EERecHitCollection>(EERecHitCollectionLabel);
39 
40  tok_hh_ = consumes<edm::PCaloHitContainer>(conf.getUntrackedParameter<edm::InputTag>("SimHitCollectionLabel"));
41 
42  subdet_ = 5;
43  if (hcalselector_ == "noise") subdet_ = 0;
44  if (hcalselector_ == "HB" ) subdet_ = 1;
45  if (hcalselector_ == "HE" ) subdet_ = 2;
46  if (hcalselector_ == "HO" ) subdet_ = 3;
47  if (hcalselector_ == "HF" ) subdet_ = 4;
48  if (hcalselector_ == "all" ) subdet_ = 5;
49  if (hcalselector_ == "ZS" ) subdet_ = 6;
50 
51  iz = 1;
52  if(sign_ == "-") iz = -1;
53  if(sign_ == "*") iz = 0;
54 
55  imc = 1;
56  if(mc_ == "no") imc = 0;
57 
58 }
59 
60 
62 
64 {
65 
66  Char_t histo[200];
67 
69 
70  //======================= Now various cases one by one ===================
71 
72  //Histograms drawn for single pion scan
73  if(subdet_ != 0 && imc != 0) { // just not for noise
74  sprintf (histo, "HcalRecHitTask_En_rechits_cone_profile_vs_ieta_all_depths");
75  meEnConeEtaProfile = ib.bookProfile(histo, histo, 82, -41., 41., -100., 2000., " ");
76 
77  sprintf (histo, "HcalRecHitTask_En_rechits_cone_profile_vs_ieta_all_depths_E");
78  meEnConeEtaProfile_E = ib.bookProfile(histo, histo, 82, -41., 41., -100., 2000., " ");
79 
80  sprintf (histo, "HcalRecHitTask_En_rechits_cone_profile_vs_ieta_all_depths_EH");
81  meEnConeEtaProfile_EH = ib.bookProfile(histo, histo, 82, -41., 41., -100., 2000., " ");
82  }
83 
84  // ************** HB **********************************
85  if (subdet_ == 1 || subdet_ == 5 ){
86 
87  sprintf (histo, "HcalRecHitTask_energy_of_rechits_HB" ) ;
88  meRecHitsEnergyHB = ib.book1D(histo, histo, 2010 , -10. , 2000.);
89 
90  sprintf (histo, "HcalRecHitTask_timing_vs_energy_profile_HB" ) ;
91  meTEprofileHB = ib.bookProfile(histo, histo, 150, -5., 295., -48., 92., " ");
92 
93  sprintf (histo, "HcalRecHitTask_timing_vs_energy_profile_Low_HB" ) ;
94  meTEprofileHB_Low = ib.bookProfile(histo, histo, 150, -5., 295., -48., 92., " ");
95 
96  sprintf (histo, "HcalRecHitTask_timing_vs_energy_profile_High_HB" ) ;
97  meTEprofileHB_High = ib.bookProfile(histo, histo, 150, -5., 295., 48., 92., " ");
98 
99  if(imc != 0) {
100  sprintf (histo, "HcalRecHitTask_energy_rechits_vs_simhits_HB");
101  meRecHitSimHitHB = ib.book2D(histo, histo, 120, 0., 1.2, 300, 0., 150.);
102  sprintf (histo, "HcalRecHitTask_energy_rechits_vs_simhits_profile_HB");
103  meRecHitSimHitProfileHB = ib.bookProfile(histo, histo, 120, 0., 1.2, 0., 500., " ");
104  }
105 
106  }
107 
108  // ********************** HE ************************************
109  if ( subdet_ == 2 || subdet_ == 5 ){
110 
111  sprintf (histo, "HcalRecHitTask_energy_of_rechits_HE" ) ;
112  meRecHitsEnergyHE = ib.book1D(histo, histo, 2010, -10., 2000.);
113 
114  sprintf (histo, "HcalRecHitTask_timing_vs_energy_profile_Low_HE" ) ;
115  meTEprofileHE_Low = ib.bookProfile(histo, histo, 80, -5., 75., -48., 92., " ");
116 
117  sprintf (histo, "HcalRecHitTask_timing_vs_energy_profile_HE" ) ;
118  meTEprofileHE = ib.bookProfile(histo, histo, 200, -5., 2995., -48., 92., " ");
119 
120  if(imc != 0) {
121  sprintf (histo, "HcalRecHitTask_energy_rechits_vs_simhits_HE");
122  meRecHitSimHitHE = ib.book2D(histo, histo, 120, 0., 0.6, 300, 0., 150.);
123  sprintf (histo, "HcalRecHitTask_energy_rechits_vs_simhits_profile_HE");
124  meRecHitSimHitProfileHE = ib.bookProfile(histo, histo, 120, 0., 0.6, 0., 500., " ");
125  }
126 
127  }
128 
129  // ************** HO ****************************************
130  if ( subdet_ == 3 || subdet_ == 5 ){
131 
132  sprintf (histo, "HcalRecHitTask_energy_of_rechits_HO" ) ;
133  meRecHitsEnergyHO = ib.book1D(histo, histo, 2010 , -10. , 2000.);
134 
135  sprintf (histo, "HcalRecHitTask_timing_vs_energy_profile_HO" ) ;
136  meTEprofileHO = ib.bookProfile(histo, histo, 60, -5., 55., -48., 92., " ");
137 
138  sprintf (histo, "HcalRecHitTask_timing_vs_energy_profile_High_HO" ) ;
139  meTEprofileHO_High = ib.bookProfile(histo, histo, 100, -5., 995., -48., 92., " ");
140 
141  if(imc != 0) {
142  sprintf (histo, "HcalRecHitTask_energy_rechits_vs_simhits_HO");
143  meRecHitSimHitHO = ib.book2D(histo, histo, 150, 0., 1.5, 350, 0., 350.);
144  sprintf (histo, "HcalRecHitTask_energy_rechits_vs_simhits_profile_HO");
145  meRecHitSimHitProfileHO = ib.bookProfile(histo, histo, 150, 0., 1.5, 0., 500., " ");
146  }
147 
148  }
149 
150  // ********************** HF ************************************
151  if ( subdet_ == 4 || subdet_ == 5 ){
152 
153  sprintf (histo, "HcalRecHitTask_energy_of_rechits_HF" ) ;
154  meRecHitsEnergyHF = ib.book1D(histo, histo, 2010 , -10. , 2000.);
155 
156  sprintf (histo, "HcalRecHitTask_timing_vs_energy_profile_Low_HF" ) ;
157  meTEprofileHF_Low = ib.bookProfile(histo, histo, 100, -5., 195., -48., 92., " ");
158 
159  sprintf (histo, "HcalRecHitTask_timing_vs_energy_profile_HF" ) ;
160  meTEprofileHF = ib.bookProfile(histo, histo, 200, -5., 995., -48., 92., " ");
161 
162  if(imc != 0) {
163  sprintf (histo, "HcalRecHitTask_energy_rechits_vs_simhits_HF");
164  meRecHitSimHitHF = ib.book2D(histo, histo, 50, 0., 50., 150, 0., 150.);
165  sprintf (histo, "HcalRecHitTask_energy_rechits_vs_simhits_HFL");
166  meRecHitSimHitHFL = ib.book2D(histo, histo, 50, 0., 50., 150, 0., 150.);
167  sprintf (histo, "HcalRecHitTask_energy_rechits_vs_simhits_HFS");
168  meRecHitSimHitHFS = ib.book2D(histo, histo, 50, 0., 50., 150, 0., 150.);
169  sprintf (histo, "HcalRecHitTask_energy_rechits_vs_simhits_profile_HF");
170  meRecHitSimHitProfileHF = ib.bookProfile(histo, histo, 50, 0., 50., 0., 500., " ");
171  sprintf (histo, "HcalRecHitTask_energy_rechits_vs_simhits_profile_HFL");
172  meRecHitSimHitProfileHFL = ib.bookProfile(histo, histo, 50, 0., 50., 0., 500., " ");
173  sprintf (histo, "HcalRecHitTask_energy_rechits_vs_simhits_profile_HFS");
174  meRecHitSimHitProfileHFS = ib.bookProfile(histo, histo, 50, 0., 50., 0., 500., " ");
175  }
176 
177  }
178 
179 }
180 
182 
183  using namespace edm;
184 
186  c.get<HcalRecNumberingRecord>().get( pHRNDC );
187  const HcalDDDRecConstants* hcons = &(*pHRNDC);
188 
189  // cuts for each subdet_ector mimiking "Scheme B"
190  // double cutHB = 0.9, cutHE = 1.4, cutHO = 1.1, cutHFL = 1.2, cutHFS = 1.8;
191 
192  // energy in HCAL
193  double eHcal = 0.;
194  double eHcalCone = 0.;
195  double eHcalConeHB = 0.;
196  double eHcalConeHE = 0.;
197  double eHcalConeHO = 0.;
198  double eHcalConeHF = 0.;
199  double eHcalConeHFL = 0.;
200  double eHcalConeHFS = 0.;
201 
202  // Total numbet of RecHits in HCAL, in the cone, above 1 GeV theshold
203  int nrechits = 0;
204  int nrechitsCone = 0;
205  int nrechitsThresh = 0;
206 
207  // energy in ECAL
208  double eEcal = 0.;
209  double eEcalB = 0.;
210  double eEcalE = 0.;
211  double eEcalCone = 0.;
212  int numrechitsEcal = 0;
213 
214  // MC info
215  double phi_MC = -999999.; // phi of initial particle from HepMC
216  double eta_MC = -999999.; // eta of initial particle from HepMC
217 
218  // HCAL energy around MC eta-phi at all depths;
219  double partR = 0.3;
220 
221  if(imc != 0) {
222 
224  ev.getByToken(tok_evt_,evtMC); // generator in late 310_preX
225  if (!evtMC.isValid()) {
226  edm::LogInfo("HcalRecHitsValidation") << "no HepMCProduct found";
227  } else {
228  // std::cout << "*** source HepMCProduct found"<< std::endl;
229  }
230 
231  // MC particle with highest pt is taken as a direction reference
232  double maxPt = -99999.;
233  int npart = 0;
234  const HepMC::GenEvent * myGenEvent = evtMC->GetEvent();
235  for ( HepMC::GenEvent::particle_const_iterator p = myGenEvent->particles_begin(); p != myGenEvent->particles_end(); ++p ) {
236  double phip = (*p)->momentum().phi();
237  double etap = (*p)->momentum().eta();
238  // phi_MC = phip;
239  // eta_MC = etap;
240  double pt = (*p)->momentum().perp();
241  if(pt > maxPt) { npart++; maxPt = pt; phi_MC = phip; eta_MC = etap; }
242  }
243  // std::cout << "*** Max pT = " << maxPt << std::endl;
244 
245  }
246 
247  // std::cout << "*** 2" << std::endl;
248 
249  c.get<CaloGeometryRecord>().get (geometry);
250 
251  // Fill working vectors of HCAL RecHits quantities (all of these are drawn)
252  fillRecHitsTmp(subdet_, ev);
253 
254  // std::cout << "*** 3" << std::endl;
255 
256  //===========================================================================
257  // IN ALL other CASES : ieta-iphi maps
258  //===========================================================================
259 
260  // ECAL
261  if(ecalselector_ == "yes" && (subdet_ == 1 || subdet_ == 2 || subdet_ == 5)) {
263 
266 
267 
268  if ( ev.getByToken(tok_EB_, rhitEB) ) {
269 
270  RecHit = rhitEB.product()->begin();
271  RecHitEnd = rhitEB.product()->end();
272 
273  for (; RecHit != RecHitEnd ; ++RecHit) {
274  EBDetId EBid = EBDetId(RecHit->id());
275 
276  const CaloCellGeometry* cellGeometry =
277  geometry->getSubdetectorGeometry (EBid)->getGeometry (EBid) ;
278  double eta = cellGeometry->getPosition ().eta () ;
279  double phi = cellGeometry->getPosition ().phi () ;
280  double en = RecHit->energy();
281  eEcal += en;
282  eEcalB += en;
283 
284  double r = dR(eta_MC, phi_MC, eta, phi);
285  if( r < partR) {
286  eEcalCone += en;
287  numrechitsEcal++;
288  }
289  }
290 
291  }
292 
294 
295  if ( ev.getByToken(tok_EE_, rhitEE) ) {
296 
297  RecHit = rhitEE.product()->begin();
298  RecHitEnd = rhitEE.product()->end();
299 
300  for (; RecHit != RecHitEnd ; ++RecHit) {
301  EEDetId EEid = EEDetId(RecHit->id());
302 
303  const CaloCellGeometry* cellGeometry =
304  geometry->getSubdetectorGeometry (EEid)->getGeometry (EEid) ;
305  double eta = cellGeometry->getPosition ().eta () ;
306  double phi = cellGeometry->getPosition ().phi () ;
307  double en = RecHit->energy();
308  eEcal += en;
309  eEcalE += en;
310 
311  double r = dR(eta_MC, phi_MC, eta, phi);
312  if( r < partR) {
313  eEcalCone += en;
314  numrechitsEcal++;
315  }
316  }
317  }
318  } // end of ECAL selection
319 
320 
321  // std::cout << "*** 4" << std::endl;
322 
323 
324  //===========================================================================
325  // SUBSYSTEMS,
326  //===========================================================================
327 
328  if ((subdet_ != 6) && (subdet_ != 0)) {
329 
330  // std::cout << "*** 6" << std::endl;
331 
332 
333  double HcalCone = 0.;
334 
335  int ietaMax = 9999;
336  double etaMax = 9999.;
337 
338 
339  // CYCLE over cells ====================================================
340 
341  for (unsigned int i = 0; i < cen.size(); i++) {
342  int sub = csub[i];
343  int depth = cdepth[i];
344  double eta = ceta[i];
345  double phi = cphi[i];
346  double en = cen[i];
347  double t = ctime[i];
348  int ieta = cieta[i];
349 
350  nrechits++;
351  eHcal += en;
352  if(en > 1. ) nrechitsThresh++;
353 
354  double r = dR(eta_MC, phi_MC, eta, phi);
355  if( r < partR ){
356  if(sub == 1) eHcalConeHB += en;
357  if(sub == 2) eHcalConeHE += en;
358  if(sub == 3) eHcalConeHO += en;
359  if(sub == 4) {
360  eHcalConeHF += en;
361  if (depth == 1) eHcalConeHFL += en;
362  else eHcalConeHFS += en;
363  }
364  eHcalCone += en;
365  nrechitsCone++;
366 
367  HcalCone += en;
368 
369  // alternative: ietamax -> closest to MC eta !!!
370  float eta_diff = fabs(eta_MC - eta);
371  if(eta_diff < etaMax) {
372  etaMax = eta_diff;
373  ietaMax = ieta;
374  }
375  }
376 
377  //The energy and overall timing histos are drawn while
378  //the ones split by depth are not
379  if(sub == 1 && (subdet_ == 1 || subdet_ == 5)) {
380  meRecHitsEnergyHB->Fill(en);
381 
382  meTEprofileHB_Low->Fill(en, t);
383  meTEprofileHB->Fill(en, t);
384  meTEprofileHB_High->Fill(en, t);
385 
386  }
387  if(sub == 2 && (subdet_ == 2 || subdet_ == 5)) {
388  meRecHitsEnergyHE->Fill(en);
389 
390  meTEprofileHE_Low->Fill(en, t);
391  meTEprofileHE->Fill(en, t);
392 
393  }
394  if(sub == 4 && (subdet_ == 4 || subdet_ == 5)) {
395  meRecHitsEnergyHF->Fill(en);
396 
397  meTEprofileHF_Low->Fill(en, t);
398  meTEprofileHF->Fill(en, t);
399 
400  }
401  if(sub == 3 && (subdet_ == 3 || subdet_ == 5)) {
402  meRecHitsEnergyHO->Fill(en);
403 
404  meTEprofileHO->Fill(en, t);
405  meTEprofileHO_High->Fill(en, t);
406  }
407  }
408 
409  if(imc != 0) {
410  meEnConeEtaProfile ->Fill(double(ietaMax), HcalCone); //
411  meEnConeEtaProfile_E ->Fill(double(ietaMax), eEcalCone);
412  meEnConeEtaProfile_EH ->Fill(double(ietaMax), HcalCone+eEcalCone);
413  }
414 
415  // std::cout << "*** 7" << std::endl;
416 
417 
418  }
419 
420  //SimHits vs. RecHits
421  const CaloGeometry* geo = geometry.product();
422  if(subdet_ > 0 && subdet_ < 6 && imc !=0) { // not noise
423 
425  if ( ev.getByToken(tok_hh_,hcalHits) ) {
426  const PCaloHitContainer * SimHitResult = hcalHits.product () ;
427 
428  double enSimHits = 0.;
429  double enSimHitsHB = 0.;
430  double enSimHitsHE = 0.;
431  double enSimHitsHO = 0.;
432  double enSimHitsHF = 0.;
433  double enSimHitsHFL = 0.;
434  double enSimHitsHFS = 0.;
435  // sum of SimHits in the cone
436 
437  for (std::vector<PCaloHit>::const_iterator SimHits = SimHitResult->begin () ; SimHits != SimHitResult->end(); ++SimHits) {
438 
439  int sub, depth;
440  HcalDetId cell;
441 
442  if (testNumber_) cell = HcalHitRelabeller::relabel(SimHits->id(),hcons);
443  else cell = HcalDetId(SimHits->id());
444 
445  sub = cell.subdet();
446  depth = cell.depth();
447 
448  if(sub != subdet_ && subdet_ != 5) continue; //If we are not looking at all of the subdetectors and the simhit doesn't come from the specific subdetector of interest, then we won't do any thing with it
449 
450  const HcalGeometry* cellGeometry =
451  (HcalGeometry*)(geo->getSubdetectorGeometry(DetId::Hcal,cell.subdet()));
452  //const CaloCellGeometry* cellGeometry =
453  //geometry->getSubdetectorGeometry (cell)->getGeometry (cell);
454  double etaS = cellGeometry->getPosition(cell).eta () ;
455  double phiS = cellGeometry->getPosition(cell).phi () ;
456  double en = SimHits->energy();
457 
458  double r = dR(eta_MC, phi_MC, etaS, phiS);
459 
460  if ( r < partR ){ // just energy in the small cone
461 
462  enSimHits += en;
463  if(sub == static_cast<int>(HcalBarrel)) enSimHitsHB += en;
464  if(sub == static_cast<int>(HcalEndcap)) enSimHitsHE += en;
465  if(sub == static_cast<int>(HcalOuter)) enSimHitsHO += en;
466  if(sub == static_cast<int>(HcalForward)) {
467  enSimHitsHF += en;
468  if(depth == 1) enSimHitsHFL += en;
469  else enSimHitsHFS += en;
470  }
471  }
472  }
473 
474  // Now some histos with SimHits
475 
476  if(subdet_ == 4 || subdet_ == 5) {
477  meRecHitSimHitHF->Fill( enSimHitsHF, eHcalConeHF );
478  meRecHitSimHitProfileHF->Fill( enSimHitsHF, eHcalConeHF);
479 
480  meRecHitSimHitHFL->Fill( enSimHitsHFL, eHcalConeHFL );
481  meRecHitSimHitProfileHFL->Fill( enSimHitsHFL, eHcalConeHFL);
482  meRecHitSimHitHFS->Fill( enSimHitsHFS, eHcalConeHFS );
483  meRecHitSimHitProfileHFS->Fill( enSimHitsHFS, eHcalConeHFS);
484  }
485  if(subdet_ == 1 || subdet_ == 5) {
486  meRecHitSimHitHB->Fill( enSimHitsHB,eHcalConeHB );
487  meRecHitSimHitProfileHB->Fill( enSimHitsHB,eHcalConeHB);
488  }
489  if(subdet_ == 2 || subdet_ == 5) {
490  meRecHitSimHitHE->Fill( enSimHitsHE,eHcalConeHE );
491  meRecHitSimHitProfileHE->Fill( enSimHitsHE,eHcalConeHE);
492  }
493  if(subdet_ == 3 || subdet_ == 5) {
494  meRecHitSimHitHO->Fill( enSimHitsHO,eHcalConeHO );
495  meRecHitSimHitProfileHO->Fill( enSimHitsHO,eHcalConeHO);
496  }
497 
498  }
499  }
500 
501  nevtot++;
502 }
503 
504 
507 
508  using namespace edm;
509 
510  // initialize data vectors
511  csub.clear();
512  cen.clear();
513  ceta.clear();
514  cphi.clear();
515  ctime.clear();
516  cieta.clear();
517  ciphi.clear();
518  cdepth.clear();
519  cz.clear();
520 
521  if( subdet_ == 1 || subdet_ == 2 || subdet_ == 5 || subdet_ == 6 || subdet_ == 0) {
522 
523  //HBHE
525  if ( ev.getByToken(tok_hbhe_, hbhecoll) ) {
526  const CaloGeometry* geo = geometry.product();
527 
528  for (HBHERecHitCollection::const_iterator j=hbhecoll->begin(); j != hbhecoll->end(); j++) {
529 
530  HcalDetId cell(j->id());
531  const HcalGeometry* cellGeometry =
532  (HcalGeometry*)(geo->getSubdetectorGeometry(DetId::Hcal,cell.subdet()));
533  // const CaloCellGeometry* cellGeometry =
534  // geometry->getSubdetectorGeometry (cell)->getGeometry (cell) ;
535  double eta = cellGeometry->getPosition(cell).eta () ;
536  double phi = cellGeometry->getPosition(cell).phi () ;
537  double zc = cellGeometry->getPosition(cell).z ();
538  int sub = cell.subdet();
539  int depth = cell.depth();
540  int inteta = cell.ieta();
541  if(inteta > 0) inteta -= 1;
542  int intphi = cell.iphi()-1;
543  double en = j->energy();
544  double t = j->time();
545 
546  if((iz > 0 && eta > 0.) || (iz < 0 && eta <0.) || iz == 0) {
547 
548  csub.push_back(sub);
549  cen.push_back(en);
550  ceta.push_back(eta);
551  cphi.push_back(phi);
552  ctime.push_back(t);
553  cieta.push_back(inteta);
554  ciphi.push_back(intphi);
555  cdepth.push_back(depth);
556  cz.push_back(zc);
557  }
558  }
559  }
560 
561  }
562 
563  if( subdet_ == 4 || subdet_ == 5 || subdet_ == 6 || subdet_ == 0) {
564 
565  //HF
567  if ( ev.getByToken(tok_hf_, hfcoll) ) {
568 
569  for (HFRecHitCollection::const_iterator j = hfcoll->begin(); j != hfcoll->end(); j++) {
570 
571  HcalDetId cell(j->id());
572  const CaloCellGeometry* cellGeometry =
573  geometry->getSubdetectorGeometry (cell)->getGeometry (cell) ;
574 
575  double eta = cellGeometry->getPosition().eta () ;
576  double phi = cellGeometry->getPosition().phi () ;
577  double zc = cellGeometry->getPosition().z ();
578  int sub = cell.subdet();
579  int depth = cell.depth();
580  int inteta = cell.ieta();
581  if(inteta > 0) inteta -= 1;
582  int intphi = cell.iphi()-1;
583  double en = j->energy();
584  double t = j->time();
585 
586  if((iz > 0 && eta > 0.) || (iz < 0 && eta <0.) || iz == 0) {
587 
588  csub.push_back(sub);
589  cen.push_back(en);
590  ceta.push_back(eta);
591  cphi.push_back(phi);
592  ctime.push_back(t);
593  cieta.push_back(inteta);
594  ciphi.push_back(intphi);
595  cdepth.push_back(depth);
596  cz.push_back(zc);
597  }
598  }
599  }
600  }
601 
602  //HO
603  if( subdet_ == 3 || subdet_ == 5 || subdet_ == 6 || subdet_ == 0) {
604 
606  if ( ev.getByToken(tok_ho_, hocoll) ) {
607 
608  for (HORecHitCollection::const_iterator j = hocoll->begin(); j != hocoll->end(); j++) {
609 
610  HcalDetId cell(j->id());
611  const CaloCellGeometry* cellGeometry =
612  geometry->getSubdetectorGeometry (cell)->getGeometry (cell) ;
613 
614  double eta = cellGeometry->getPosition().eta () ;
615  double phi = cellGeometry->getPosition().phi () ;
616  double zc = cellGeometry->getPosition().z ();
617  int sub = cell.subdet();
618  int depth = cell.depth();
619  int inteta = cell.ieta();
620  if(inteta > 0) inteta -= 1;
621  int intphi = cell.iphi()-1;
622  double t = j->time();
623  double en = j->energy();
624 
625  if((iz > 0 && eta > 0.) || (iz < 0 && eta <0.) || iz == 0) {
626  csub.push_back(sub);
627  cen.push_back(en);
628  ceta.push_back(eta);
629  cphi.push_back(phi);
630  ctime.push_back(t);
631  cieta.push_back(inteta);
632  ciphi.push_back(intphi);
633  cdepth.push_back(depth);
634  cz.push_back(zc);
635  }
636  }
637  }
638  }
639 }
640 
641 double HcalRecHitsValidation::dR(double eta1, double phi1, double eta2, double phi2) {
642  double PI = 3.1415926535898;
643  double deltaphi= phi1 - phi2;
644  if( phi2 > phi1 ) { deltaphi= phi2 - phi1;}
645  if(deltaphi > PI) { deltaphi = 2.*PI - deltaphi;}
646  double deltaeta = eta2 - eta1;
647  double tmp = sqrt(deltaeta* deltaeta + deltaphi*deltaphi);
648  return tmp;
649 }
650 
651 double HcalRecHitsValidation::phi12(double phi1, double en1, double phi2, double en2) {
652  // weighted mean value of phi1 and phi2
653 
654  double tmp;
655  double PI = 3.1415926535898;
656  double a1 = phi1; double a2 = phi2;
657 
658  if( a1 > 0.5*PI && a2 < 0.) a2 += 2*PI;
659  if( a2 > 0.5*PI && a1 < 0.) a1 += 2*PI;
660  tmp = (a1 * en1 + a2 * en2)/(en1 + en2);
661  if(tmp > PI) tmp -= 2.*PI;
662 
663  return tmp;
664 
665 }
666 
667 double HcalRecHitsValidation::dPhiWsign(double phi1, double phi2) {
668  // clockwise phi2 w.r.t phi1 means "+" phi distance
669  // anti-clockwise phi2 w.r.t phi1 means "-" phi distance
670 
671  double PI = 3.1415926535898;
672  double a1 = phi1; double a2 = phi2;
673  double tmp = a2 - a1;
674  if( a1*a2 < 0.) {
675  if(a1 > 0.5 * PI) tmp += 2.*PI;
676  if(a2 > 0.5 * PI) tmp -= 2.*PI;
677  }
678  return tmp;
679 
680 }
681 
682 
684 
T getParameter(std::string const &) const
const CaloSubdetectorGeometry * getSubdetectorGeometry(const DetId &id) const
access the subdetector geometry for the given subdetector directly
Definition: CaloGeometry.cc:45
T getUntrackedParameter(std::string const &, T const &) const
std::vector< PCaloHit > PCaloHitContainer
edm::EDGetTokenT< edm::PCaloHitContainer > tok_hh_
MonitorElement * meRecHitsEnergyHF
HcalSubdetector subdet() const
get the subdetector
Definition: HcalDetId.h:49
double phi12(double phi1, double en1, double phi2, double en2)
MonitorElement * bookProfile(Args &&...args)
Definition: DQMStore.h:157
bool getByToken(EDGetToken token, Handle< PROD > &result) const
Definition: Event.h:460
MonitorElement * meTEprofileHE_Low
#define DEFINE_FWK_MODULE(type)
Definition: MakerMacros.h:17
Geom::Phi< T > phi() const
Definition: PV3DBase.h:69
edm::EDGetTokenT< HFRecHitCollection > tok_hf_
std::vector< EcalRecHit >::const_iterator const_iterator
MonitorElement * meEnConeEtaProfile
double npart
Definition: HydjetWrapper.h:49
bool ev
double dPhiWsign(double phi1, double phi2)
MonitorElement * meRecHitSimHitProfileHF
MonitorElement * meRecHitSimHitProfileHFS
MonitorElement * meRecHitsEnergyHB
std::vector< double > ceta
MonitorElement * meRecHitSimHitHF
MonitorElement * meRecHitsEnergyHE
MonitorElement * meRecHitSimHitProfileHE
edm::EDGetTokenT< HORecHitCollection > tok_ho_
void Fill(long long x)
MonitorElement * meEnConeEtaProfile_E
MonitorElement * meRecHitSimHitHB
MonitorElement * meRecHitSimHitHFS
std::vector< double > cphi
T sqrt(T t)
Definition: SSEVec.h:18
MonitorElement * meTEprofileHB
MonitorElement * book1D(Args &&...args)
Definition: DQMStore.h:115
virtual void fillRecHitsTmp(int subdet_, edm::Event const &ev)
double dR(double eta1, double phi1, double eta2, double phi2)
edm::EDGetTokenT< HBHERecHitCollection > tok_hbhe_
bool isValid() const
Definition: HandleBase.h:74
#define PI
Definition: QcdUeDQM.h:36
MonitorElement * meRecHitSimHitHO
MonitorElement * meRecHitSimHitProfileHB
GlobalPoint getPosition(const DetId &id) const
virtual void analyze(edm::Event const &ev, edm::EventSetup const &c)
virtual void bookHistograms(DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &)
const_iterator end() const
MonitorElement * meTEprofileHF_Low
edm::EDGetTokenT< EBRecHitCollection > tok_EB_
MonitorElement * meTEprofileHO_High
MonitorElement * meTEprofileHE
void setCurrentFolder(const std::string &fullpath)
Definition: DQMStore.cc:277
const HepMC::GenEvent * GetEvent() const
Definition: HepMCProduct.h:38
T const * product() const
Definition: Handle.h:81
MonitorElement * book2D(Args &&...args)
Definition: DQMStore.h:133
MonitorElement * meTEprofileHF
MonitorElement * meRecHitSimHitProfileHO
edm::EDGetTokenT< EERecHitCollection > tok_EE_
const T & get() const
Definition: EventSetup.h:55
std::vector< double > ctime
MonitorElement * meEnConeEtaProfile_EH
MonitorElement * meRecHitSimHitProfileHFL
std::vector< double > cz
T eta() const
Definition: PV3DBase.h:76
std::vector< std::vector< double > > tmp
Definition: MVATrainer.cc:100
MonitorElement * meRecHitsEnergyHO
HLT enums.
MonitorElement * meRecHitSimHitHFL
MonitorElement * meTEprofileHO
edm::EDGetTokenT< edm::HepMCProduct > tok_evt_
DetId relabel(const uint32_t testId) const
MonitorElement * meTEprofileHB_Low
MonitorElement * meRecHitSimHitHE
HcalRecHitsValidation(edm::ParameterSet const &conf)
MonitorElement * meTEprofileHB_High
std::vector< double > cen
const_iterator begin() const
Definition: Run.h:42
ib
Definition: cuy.py:660