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L1TCSCTF.cc
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1 /*
2  * \file L1TCSCTF.cc
3  *
4  * \author J. Berryhill
5  *
6  */
7 
10 
11 // includes to fetch all reguired data products from the edm::Event
17 
20 
21 
22 using namespace std;
23 using namespace edm;
24 
26 // if some piece of data is absent - configure corresponding source with 'null:'
27 // : csctfSource_( ps.getParameter< InputTag >("csctfSource") )
28  : gmtProducer( ps.getParameter< InputTag >("gmtProducer") ),
29  lctProducer( ps.getParameter< InputTag >("lctProducer") ),
30  trackProducer( ps.getParameter< InputTag >("trackProducer") ),
31  statusProducer( ps.getParameter< InputTag >("statusProducer") ),
32  mbProducer( ps.getParameter< InputTag >("mbProducer") )
33 {
34 
35  // verbosity switch
36  verbose_ = ps.getUntrackedParameter<bool>("verbose", false);
37 
38  if(verbose_) edm::LogInfo("DataNotFound") << "L1TCSCTF: constructor...." << endl;
39 
40  outputFile_ = ps.getUntrackedParameter<string>("outputFile", "");
41  if ( outputFile_.size() != 0 )
42  {
43  edm::LogInfo("DataNotFound") << "L1T Monitoring histograms will be saved to " << outputFile_.c_str() << endl;
44  }
45 
46  bool disable = ps.getUntrackedParameter<bool>("disableROOToutput", false);
47  if(disable){
48  outputFile_="";
49  }
50 
51  gangedME11a_ = ps.getUntrackedParameter<bool>("gangedME11a", false);
52 
53  // instantiate standard on-fly SR LUTs from CSC TF emulator package
54  bzero(srLUTs_ , sizeof(srLUTs_));
55  //int sector=1; // assume SR LUTs are all same for every sector
56  bool TMB07=true; // specific TMB firmware
57  // Create a pset for SR/PT LUTs: if you do not change the value in the
58  // configuration file, it will load the default minitLUTs
59  edm::ParameterSet srLUTset;
60  srLUTset.addUntrackedParameter<bool>("ReadLUTs", false);
61  srLUTset.addUntrackedParameter<bool>("Binary", false);
62  srLUTset.addUntrackedParameter<std::string>("LUTPath", "./");
63 
64  // positive endcap
65  int endcap = 1;
66  for(int sector=0; sector<6; sector++) {
67  for(int station=1,fpga=0; station<=4 && fpga<5; station++) {
68  if(station==1)
69  for(int subSector=0; subSector<2 && fpga<5; subSector++)
70  srLUTs_[fpga++][1][sector] = new CSCSectorReceiverLUT(endcap,sector+1,subSector+1,
71  station, srLUTset, TMB07);
72  else
73  srLUTs_[fpga++][1][sector] = new CSCSectorReceiverLUT(endcap, sector+1, 0,
74  station, srLUTset, TMB07);
75  }
76  }
77 
78  // negative endcap
79  endcap = 2;
80  for(int sector=0; sector<6; sector++) {
81  for(int station=1,fpga=0; station<=4 && fpga<5; station++) {
82  if(station==1)
83  for(int subSector=0; subSector<2 && fpga<5; subSector++)
84  srLUTs_[fpga++][0][sector] = new CSCSectorReceiverLUT(endcap,sector+1,subSector+1,
85  station, srLUTset, TMB07);
86  else
87  srLUTs_[fpga++][0][sector] = new CSCSectorReceiverLUT(endcap, sector+1, 0,
88  station, srLUTset, TMB07);
89  }
90  }
91 
92 
93  //set Token(-s)
99 
100  gmtProducerToken_ = consumes<L1MuGMTReadoutCollection>(ps.getParameter< InputTag >("gmtProducer"));
101  statusToken_ = consumes<L1CSCStatusDigiCollection>(statusTag_);
102  corrlctsToken_ = consumes<CSCCorrelatedLCTDigiCollection>(corrlctsTag_);
103  tracksToken_ = consumes<L1CSCTrackCollection>(tracksTag_);
104  dtStubsToken_ = consumes<CSCTriggerContainer<csctf::TrackStub> >(dtStubsTag_);
105  mbtracksToken_ = consumes<L1CSCTrackCollection>(mbtracksTag_);
106 }
107 
109 {
110 
111  for(unsigned int j=0; j<2; j++)
112  for(unsigned int i=0; i<5; i++)
113  for(unsigned int s=0; s<6; s++)
114  delete srLUTs_[i][j][s]; //free the array of pointers
115 
116 }
117 
119 }
120 
122 {
123  m_scalesCacheID = -999;
124  m_ptScaleCacheID = -999;
125 
126  nev_ = 0;
127  ibooker.setCurrentFolder("L1T/L1TCSCTF");
128 
129  // Error counting histogram:
130  // 1) checks TF data integrity (error rate - first bin),
131  // 2) monitors sychronization on input links (4 errors types: SE/SM/BX/AF; ORed for all time bins, links, and SPs),
132  // 3) reports FMM status (if in any SP FMM status != "Ready" - fill the last bin)
133  csctferrors = ibooker.book1D("CSCTF_errors","CSCTF Errors",6,0,6);
134  csctferrors->setAxisTitle("Error type",1);
135  csctferrors->setAxisTitle("Number of Errors",2);
136  csctferrors->setBinLabel(1,"Corruptions",1);
137  csctferrors->setBinLabel(2,"Synch. Err.",1);
138  csctferrors->setBinLabel(3,"Synch. Mod.",1);
139  csctferrors->setBinLabel(4,"BX mismatch",1);
140  csctferrors->setBinLabel(5,"Time misalign.",1);
141  csctferrors->setBinLabel(6,"FMM != Ready",1);
142 
143  // Occupancy histogram Eta x Y, where Y:
144  // 1) Phi_packed of input LCTs from 1st, 2nd, 3rd, and 4th stations
145  // 2) Phi_packed of output tracks
146  // (all 12 SPs - 360 degree coveradge)
147  csctfoccupancies = ibooker.book2D("CSCTF_occupancies", "CSCTF Occupancies", 64,-32,31,32,0,6.2);
148  csctfoccupancies->setAxisTitle("#eta",1);
149  csctfoccupancies->setAxisTitle("#phi",2);
150  csctfoccupancies->setBinLabel( 1,"-2.5", 1);
151  csctfoccupancies->setBinLabel( 8,"-2.1", 1);
152  csctfoccupancies->setBinLabel(18,"-1.6", 1);
153  csctfoccupancies->setBinLabel(26,"-1.2", 1);
154  csctfoccupancies->setBinLabel(32,"-0.9", 1);
155  csctfoccupancies->setBinLabel(33, "0.9", 1);
156  csctfoccupancies->setBinLabel(39, "1.2", 1);
157  csctfoccupancies->setBinLabel(47, "1.6", 1);
158  csctfoccupancies->setBinLabel(57, "2.1", 1);
159  csctfoccupancies->setBinLabel(64, "2.5", 1);
160 
161  // ... and for halo muons only
162  csctfoccupancies_H = ibooker.book2D("CSCTF_occupancies_H", "CSCTF Halo Occupancies", 64,-32,31,32,0,6.2);
163  csctfoccupancies_H->setAxisTitle("#eta",1);
164  csctfoccupancies_H->setAxisTitle("#phi",2);
165  csctfoccupancies_H->setBinLabel( 1,"-2.5", 1);
166  csctfoccupancies_H->setBinLabel( 8,"-2.1", 1);
167  csctfoccupancies_H->setBinLabel(18,"-1.6", 1);
168  csctfoccupancies_H->setBinLabel(26,"-1.2", 1);
169  csctfoccupancies_H->setBinLabel(32,"-0.9", 1);
170  csctfoccupancies_H->setBinLabel(33, "0.9", 1);
171  csctfoccupancies_H->setBinLabel(39, "1.2", 1);
172  csctfoccupancies_H->setBinLabel(47, "1.6", 1);
173  csctfoccupancies_H->setBinLabel(57, "2.1", 1);
174  csctfoccupancies_H->setBinLabel(64, "2.5", 1);
175 
176  //haloDelEta12 = ibooker.book1D("CSCTF_Halo_Eta12", "#Delta #eta_{12} for Halo Muons", 40, -0.20,0.30);
177  //haloDelEta112 = ibooker.book1D("CSCTF_Halo_Eta112","#Delta #eta_{112} for Halo Muons", 40, -0.20,0.30);
178  //haloDelEta13 = ibooker.book1D("CSCTF_Halo_Eta13", "#Delta #eta_{13} for Halo Muons", 40, -0.20,0.30);
179  //haloDelEta113 = ibooker.book1D("CSCTF_Halo_Eta113","#Delta #eta_{113} for Halo Muons", 40, -0.20,0.30);
180 
181  // Quality VS Mode
182  trackModeVsQ = ibooker.book2D("CSCTF_Track_ModeVsQual","CSC Track Mode Vs Quality", 19, -0.5, 18.5, 4, 0, 4);
183  trackModeVsQ->setAxisTitle("Track Type", 1);
184  trackModeVsQ->setBinLabel(1,"No Track",1);
185  trackModeVsQ->setBinLabel(2,"Bad Phi/Single",1);
186  trackModeVsQ->setBinLabel(3,"ME1-2-3",1);
187  trackModeVsQ->setBinLabel(4,"ME1-2-4",1);
188  trackModeVsQ->setBinLabel(5,"ME1-3-4",1);
189  trackModeVsQ->setBinLabel(6,"ME2-3-4",1);
190  trackModeVsQ->setBinLabel(7,"ME1-2",1);
191  trackModeVsQ->setBinLabel(8,"ME1-3",1);
192  trackModeVsQ->setBinLabel(9,"ME2-3",1);
193  trackModeVsQ->setBinLabel(10,"ME2-4",1);
194  trackModeVsQ->setBinLabel(11,"ME3-4",1);
195  trackModeVsQ->setBinLabel(12,"MB1-ME3",1);
196  trackModeVsQ->setBinLabel(13,"MB1-ME2",1);
197  trackModeVsQ->setBinLabel(14,"ME1-4",1);
198  trackModeVsQ->setBinLabel(15,"MB1-ME1",1);
199  trackModeVsQ->setBinLabel(16,"Halo Trigger",1);
200  trackModeVsQ->setBinLabel(17,"MB1-ME1-2",1);
201  trackModeVsQ->setBinLabel(18,"MB1-ME1-3",1);
202  trackModeVsQ->setBinLabel(19,"MB1-ME2-3",1);
203 
204  trackModeVsQ->setAxisTitle("Quality",2);
205  trackModeVsQ->setBinLabel(1,"0",2);
206  trackModeVsQ->setBinLabel(2,"1",2);
207  trackModeVsQ->setBinLabel(3,"2",2);
208  trackModeVsQ->setBinLabel(4,"3",2);
209 
210  // Mode
211  csctfTrackM = ibooker.book1D("CSCTF_Track_Mode","CSC Track Mode", 19, -0.5, 18.5);
212  csctfTrackM->setAxisTitle("Track Type", 1);
213  csctfTrackM->setBinLabel(1,"No Track",1);
214  csctfTrackM->setBinLabel(2,"Bad Phi/Single",1);
215  csctfTrackM->setBinLabel(3,"ME1-2-3",1);
216  csctfTrackM->setBinLabel(4,"ME1-2-4",1);
217  csctfTrackM->setBinLabel(5,"ME1-3-4",1);
218  csctfTrackM->setBinLabel(6,"ME2-3-4",1);
219  csctfTrackM->setBinLabel(7,"ME1-2",1);
220  csctfTrackM->setBinLabel(8,"ME1-3",1);
221  csctfTrackM->setBinLabel(9,"ME2-3",1);
222  csctfTrackM->setBinLabel(10,"ME2-4",1);
223  csctfTrackM->setBinLabel(11,"ME3-4",1);
224  csctfTrackM->setBinLabel(12,"MB1-ME3",1);
225  csctfTrackM->setBinLabel(13,"MB1-ME2",1);
226  csctfTrackM->setBinLabel(14,"ME1-4",1);
227  csctfTrackM->setBinLabel(15,"MB1-ME1",1);
228  csctfTrackM->setBinLabel(16,"Halo Trigger",1);
229  csctfTrackM->setBinLabel(17,"MB1-ME1-2",1);
230  csctfTrackM->setBinLabel(18,"MB1-ME1-3",1);
231  csctfTrackM->setBinLabel(19,"MB1-ME2-3",1);
232 
233  // Chamber Occupancy
234  csctfChamberOccupancies = ibooker.book2D("CSCTF_Chamber_Occupancies","CSCTF Chamber Occupancies", 54, -0.05, 5.35, 10, -5.5, 4.5);
235  csctfChamberOccupancies->setAxisTitle("Sector, (chambers 1-9 not labeled)",1);
239  csctfChamberOccupancies->setBinLabel(4,"ME-1b",2);
240  csctfChamberOccupancies->setBinLabel(5,"ME-1a",2);
241  csctfChamberOccupancies->setBinLabel(6,"ME+1a",2);
242  csctfChamberOccupancies->setBinLabel(7,"ME+1b",2);
245  csctfChamberOccupancies->setBinLabel(10,"ME+4",2);
252 
253  // Track Phi
254  csctfTrackPhi = ibooker.book1D("CSCTF_Track_Phi", "CSCTF Track #phi",144,0,2*M_PI);
255  csctfTrackPhi->setAxisTitle("Track #phi", 1);
256 
257  // Track Eta
258  csctfTrackEta = ibooker.book1D("CSCTF_Track_Eta", "CSCTF Track #eta",64,-32,32);
259  csctfTrackEta->setAxisTitle("Track #eta", 1);
260  csctfTrackEta->setBinLabel( 1,"-2.5", 1);
261  csctfTrackEta->setBinLabel( 8,"-2.1", 1);
262  csctfTrackEta->setBinLabel(18,"-1.6", 1);
263  csctfTrackEta->setBinLabel(26,"-1.2", 1);
264  csctfTrackEta->setBinLabel(32,"-0.9", 1);
265  csctfTrackEta->setBinLabel(33, "0.9", 1);
266  csctfTrackEta->setBinLabel(39, "1.2", 1);
267  csctfTrackEta->setBinLabel(47, "1.6", 1);
268  csctfTrackEta->setBinLabel(57, "2.1", 1);
269  csctfTrackEta->setBinLabel(64, "2.5", 1);
270 
271  // Track Eta Low Quality
272  csctfTrackEtaLowQ = ibooker.book1D("CSCTF_Track_Eta_LowQ", "CSCTF Track #eta LQ",64,-32,32);
273  csctfTrackEtaLowQ->setAxisTitle("Track #eta", 1);
274  csctfTrackEtaLowQ->setBinLabel( 1,"-2.5", 1);
275  csctfTrackEtaLowQ->setBinLabel( 8,"-2.1", 1);
276  csctfTrackEtaLowQ->setBinLabel(18,"-1.6", 1);
277  csctfTrackEtaLowQ->setBinLabel(26,"-1.2", 1);
278  csctfTrackEtaLowQ->setBinLabel(32,"-0.9", 1);
279  csctfTrackEtaLowQ->setBinLabel(33, "0.9", 1);
280  csctfTrackEtaLowQ->setBinLabel(39, "1.2", 1);
281  csctfTrackEtaLowQ->setBinLabel(47, "1.6", 1);
282  csctfTrackEtaLowQ->setBinLabel(57, "2.1", 1);
283  csctfTrackEtaLowQ->setBinLabel(64, "2.5", 1);
284 
285 
286  // Track Eta High Quality
287  csctfTrackEtaHighQ = ibooker.book1D("CSCTF_Track_Eta_HighQ", "CSCTF Track #eta HQ",64,-32,32);
288  csctfTrackEtaHighQ->setAxisTitle("Track #eta", 1);
289  csctfTrackEtaHighQ->setBinLabel( 1,"-2.5", 1);
290  csctfTrackEtaHighQ->setBinLabel( 8,"-2.1", 1);
291  csctfTrackEtaHighQ->setBinLabel(18,"-1.6", 1);
292  csctfTrackEtaHighQ->setBinLabel(26,"-1.2", 1);
293  csctfTrackEtaHighQ->setBinLabel(32,"-0.9", 1);
294  csctfTrackEtaHighQ->setBinLabel(33, "0.9", 1);
295  csctfTrackEtaHighQ->setBinLabel(39, "1.2", 1);
296  csctfTrackEtaHighQ->setBinLabel(47, "1.6", 1);
297  csctfTrackEtaHighQ->setBinLabel(57, "2.1", 1);
298  csctfTrackEtaHighQ->setBinLabel(64, "2.5", 1);
299 
300 
301  // Halo Phi
302  csctfTrackPhi_H = ibooker.book1D("CSCTF_Track_Phi_H", "CSCTF Halo #phi",144,0,2*M_PI);
303  csctfTrackPhi_H->setAxisTitle("Track #phi", 1);
304 
305  // Halo Eta
306  csctfTrackEta_H = ibooker.book1D("CSCTF_Track_Eta_H", "CSCTF Halo #eta",64,-32,32);
307  csctfTrackEta_H->setAxisTitle("Track #eta", 1);
308  csctfTrackEta_H->setBinLabel( 1,"-2.5", 1);
309  csctfTrackEta_H->setBinLabel( 8,"-2.1", 1);
310  csctfTrackEta_H->setBinLabel(18,"-1.6", 1);
311  csctfTrackEta_H->setBinLabel(26,"-1.2", 1);
312  csctfTrackEta_H->setBinLabel(32,"-0.9", 1);
313  csctfTrackEta_H->setBinLabel(33, "0.9", 1);
314  csctfTrackEta_H->setBinLabel(39, "1.2", 1);
315  csctfTrackEta_H->setBinLabel(47, "1.6", 1);
316  csctfTrackEta_H->setBinLabel(57, "2.1", 1);
317  csctfTrackEta_H->setBinLabel(64, "2.5", 1);
318 
319  // Track Timing
320  csctfbx = ibooker.book2D("CSCTF_bx","CSCTF BX", 12,1,13, 7,-3,3) ;
321  csctfbx->setAxisTitle("Sector (Endcap)", 1);
322  csctfbx->setBinLabel( 1," 1 (+)",1);
323  csctfbx->setBinLabel( 2," 2 (+)",1);
324  csctfbx->setBinLabel( 3," 3 (+)",1);
325  csctfbx->setBinLabel( 4," 4 (+)",1);
326  csctfbx->setBinLabel( 5," 5 (+)",1);
327  csctfbx->setBinLabel( 6," 6 (+)",1);
328  csctfbx->setBinLabel( 7," 7 (-)",1);
329  csctfbx->setBinLabel( 8," 8 (-)",1);
330  csctfbx->setBinLabel( 9," 9 (-)",1);
331  csctfbx->setBinLabel(10,"10 (-)",1);
332  csctfbx->setBinLabel(11,"11 (-)",1);
333  csctfbx->setBinLabel(12,"12 (-)",1);
334 
335  csctfbx->setAxisTitle("CSCTF BX", 2);
336  csctfbx->setBinLabel( 1, "-3", 2);
337  csctfbx->setBinLabel( 2, "-2", 2);
338  csctfbx->setBinLabel( 3, "-1", 2);
339  csctfbx->setBinLabel( 4, "-0", 2);
340  csctfbx->setBinLabel( 5, " 1", 2);
341  csctfbx->setBinLabel( 6, " 2", 2);
342  csctfbx->setBinLabel( 7, " 3", 2);
343 
344  // Halo Timing
345  csctfbx_H = ibooker.book2D("CSCTF_bx_H","CSCTF HALO BX", 12,1,13, 7,-3,3) ;
346  csctfbx_H->setAxisTitle("Sector (Endcap)", 1);
347  csctfbx_H->setBinLabel( 1," 1 (+)",1);
348  csctfbx_H->setBinLabel( 2," 2 (+)",1);
349  csctfbx_H->setBinLabel( 3," 3 (+)",1);
350  csctfbx_H->setBinLabel( 4," 4 (+)",1);
351  csctfbx_H->setBinLabel( 5," 5 (+)",1);
352  csctfbx_H->setBinLabel( 6," 6 (+)",1);
353  csctfbx_H->setBinLabel( 7," 7 (-)",1);
354  csctfbx_H->setBinLabel( 8," 8 (-)",1);
355  csctfbx_H->setBinLabel( 9," 9 (-)",1);
356  csctfbx_H->setBinLabel(10,"10 (-)",1);
357  csctfbx_H->setBinLabel(11,"11 (-)",1);
358  csctfbx_H->setBinLabel(12,"12 (-)",1);
359 
360  csctfbx_H->setAxisTitle("CSCTF BX", 2);
361  csctfbx_H->setBinLabel( 1, "-3", 2);
362  csctfbx_H->setBinLabel( 2, "-2", 2);
363  csctfbx_H->setBinLabel( 3, "-1", 2);
364  csctfbx_H->setBinLabel( 4, "-0", 2);
365  csctfbx_H->setBinLabel( 5, " 1", 2);
366  csctfbx_H->setBinLabel( 6, " 2", 2);
367  csctfbx_H->setBinLabel( 7, " 3", 2);
368 
369  // Number of Tracks Stubs
370  cscTrackStubNumbers = ibooker.book1D("CSCTF_TrackStubs", "Number of Stubs in CSCTF Tracks", 5, 0, 5);
371  cscTrackStubNumbers->setBinLabel( 1, "0", 1);
372  cscTrackStubNumbers->setBinLabel( 2, "1", 1);
373  cscTrackStubNumbers->setBinLabel( 3, "2", 1);
374  cscTrackStubNumbers->setBinLabel( 4, "3", 1);
375  cscTrackStubNumbers->setBinLabel( 5, "4", 1);
376 
377  // Number of Tracks
378  csctfntrack = ibooker.book1D("CSCTF_ntrack","Number of CSCTracks found per event", 5, 0, 5 ) ;
379  csctfntrack->setBinLabel( 1, "0", 1);
380  csctfntrack->setBinLabel( 2, "1", 1);
381  csctfntrack->setBinLabel( 3, "2", 1);
382  csctfntrack->setBinLabel( 4, "3", 1);
383  csctfntrack->setBinLabel( 5, "4", 1);
384  //}
385 
386  char hname [200];
387  char htitle[200];
388 
389  for(int i=0; i<12; i++) {
390 
391  sprintf(hname ,"DTstubsTimeTrackMenTimeArrival_%d",i+1);
392  sprintf(htitle,"T_{track} - T_{DT stub} sector %d",i+1);
393 
394  DTstubsTimeTrackMenTimeArrival[i] = ibooker.book2D(hname,htitle, 7,-3,3, 2,1,3);
395  DTstubsTimeTrackMenTimeArrival[i]->getTH2F()->SetMinimum(0);
396 
397  // axis makeup
398  DTstubsTimeTrackMenTimeArrival[i]->setAxisTitle("bx_{CSC track} - bx_{DT stub}",1);
400 
408 
411 
412  }
413 
414 
415  // NEW: CSC EVENT LCT PLOTS
416  csctflcts = ibooker.book2D("CSCTF_LCT", "CSCTF LCTs", 12,1,13, 18,0,18);
417  csctflcts->setAxisTitle("CSCTF LCT BX",1);
418  csctflcts->setBinLabel(1,"1",1);
419  csctflcts->setBinLabel(2,"2",1);
420  csctflcts->setBinLabel(3,"3",1);
421  csctflcts->setBinLabel(4,"4",1);
422  csctflcts->setBinLabel(5,"5",1);
423  csctflcts->setBinLabel(6,"6",1);
424  csctflcts->setBinLabel(7,"7",1);
425  csctflcts->setBinLabel(8,"8",1);
426  csctflcts->setBinLabel(9,"9",1);
427  csctflcts->setBinLabel(10,"10",1);
428  csctflcts->setBinLabel(11,"11",1);
429  csctflcts->setBinLabel(12,"12",1);
430 
431  int ihist = 0;
432  for (int iEndcap = 0; iEndcap < 2; iEndcap++) {
433  for (int iStation = 1; iStation < 5; iStation++) {
434  for (int iRing = 1; iRing < 4; iRing++) {
435  if (iStation != 1 && iRing > 2) continue;
436  TString signEndcap="+";
437  if(iEndcap==0) signEndcap="-";
438 
439  char lcttitle[200];
440  snprintf(lcttitle,200,"ME%s%d/%d", signEndcap.Data(), iStation, iRing);
441  if(ihist<=8){
442  csctflcts -> setBinLabel(9-ihist,lcttitle,2);
443  }
444  else csctflcts -> setBinLabel(ihist+1,lcttitle,2);
445 
446  ihist++;
447  }
448  }
449  }
450 
451 
452  // plots for ME1/1 chambers
453  me11_lctStrip = ibooker.book1D("CSC_ME11_LCT_Strip", "CSC_ME11_LCT_Strip", 223, 0, 223);
454  me11_lctStrip->setAxisTitle("Cathode HalfStrip, ME1/1", 1);
455 
456  me11_lctWire = ibooker.book1D("CSC_ME11_LCT_Wire", "CSC_ME11_LCT_Wire", 112, 0, 112);
457  me11_lctWire->setAxisTitle("Anode Wiregroup, ME1/1", 1);
458 
459  me11_lctLocalPhi = ibooker.book1D("CSC_ME11_LCT_LocalPhi", "CSC_ME11_LCT_LocalPhi", 200,0,1024);
460  me11_lctLocalPhi ->setAxisTitle("LCT Local #it{#phi}, ME1/1", 1);
461 
462  me11_lctPackedPhi = ibooker.book1D("CSC_ME11_LCT_PackedPhi", "CSC_ME11_LCT_PackedPhi", 200,0,4096);
463  me11_lctPackedPhi ->setAxisTitle("LCT Packed #it{#phi}, ME1/1",1);
464 
465  me11_lctGblPhi = ibooker.book1D("CSC_ME11_LCT_GblPhi", "CSC_ME11_LCT_GblPhi", 200, 0, 2*M_PI);
466  me11_lctGblPhi ->setAxisTitle("LCT Global #it{#phi}, ME1/1", 1);
467 
468  me11_lctGblEta = ibooker.book1D("CSC_ME11_LCT_GblEta", "CSC_ME11_LCT_GblEta", 50, 0.9, 2.5);
469  me11_lctGblEta ->setAxisTitle("LCT Global #eta, ME1/1", 1);
470 
471 
472  // plots for ME4/2 chambers
473  me42_lctGblPhi = ibooker.book1D("CSC_ME42_LCT_GblPhi", "CSC_ME42_LCT_GblPhi", 200, 0, 2*M_PI);
474  me42_lctGblPhi ->setAxisTitle("LCT Global #it{#phi}, ME4/2", 1);
475 
476  me42_lctGblEta = ibooker.book1D("CSC_ME42_LCT_GblEta", "CSC_ME42_LCT_GblEta", 50, 0.9, 2.5);
477  me42_lctGblEta ->setAxisTitle("LCT Global #eta, ME4/2", 1);
478 
479  //
480  csc_strip_MEplus11= ibooker.book2D("csc_strip_MEplus11", "csc_strip_MEplus11", 36,1,37, 240,0,240);
481  csc_strip_MEplus11->setAxisTitle("Cathode HalfStrip", 2);
482  csc_strip_MEplus11->setAxisTitle("ME+1/1", 1);
483  csc_strip_MEplus12= ibooker.book2D("csc_strip_MEplus12", "csc_strip_MEplus12", 36,1,37, 240,0,240);
484  csc_strip_MEplus12->setAxisTitle("Cathode HalfStrip", 2);
485  csc_strip_MEplus12->setAxisTitle("ME+1/2", 1);
486  csc_strip_MEplus13= ibooker.book2D("csc_strip_MEplus13", "csc_strip_MEplus13", 36,1,37, 240,0,240);
487  csc_strip_MEplus13->setAxisTitle("Cathode HalfStrip", 2);
488  csc_strip_MEplus13->setAxisTitle("ME+1/3", 1);
489  csc_strip_MEplus21= ibooker.book2D("csc_strip_MEplus21", "csc_strip_MEplus21", 18,1,19, 240,0,240);
490  csc_strip_MEplus21->setAxisTitle("Cathode HalfStrip", 2);
491  csc_strip_MEplus21->setAxisTitle("ME+2/1", 1);
492  csc_strip_MEplus22= ibooker.book2D("csc_strip_MEplus22", "csc_strip_MEplus22", 36,1,37, 240,0,240);
493  csc_strip_MEplus22->setAxisTitle("Cathode HalfStrip", 2);
494  csc_strip_MEplus22->setAxisTitle("ME+2/2", 1);
495  csc_strip_MEplus31= ibooker.book2D("csc_strip_MEplus31", "csc_strip_MEplus31", 18,1,19, 240,0,240);
496  csc_strip_MEplus31->setAxisTitle("Cathode HalfStrip", 2);
497  csc_strip_MEplus31->setAxisTitle("ME+3/1", 1);
498  csc_strip_MEplus32= ibooker.book2D("csc_strip_MEplus32", "csc_strip_MEplus32", 36,1,37, 240,0,240);
499  csc_strip_MEplus32->setAxisTitle("Cathode HalfStrip", 2);
500  csc_strip_MEplus32->setAxisTitle("ME+3/2", 1);
501  csc_strip_MEplus41= ibooker.book2D("csc_strip_MEplus41", "csc_strip_MEplus41", 18,1,19, 240,0,240);
502  csc_strip_MEplus41->setAxisTitle("Cathode HalfStrip", 2);
503  csc_strip_MEplus41->setAxisTitle("ME+4/1", 1);
504  csc_strip_MEplus42= ibooker.book2D("csc_strip_MEplus42", "csc_strip_MEplus42", 36,1,37, 240,0,240);
505  csc_strip_MEplus42->setAxisTitle("Cathode HalfStrip", 2);
506  csc_strip_MEplus42->setAxisTitle("ME+4/2", 1);
507 
508  csc_strip_MEminus11= ibooker.book2D("csc_strip_MEminus11", "csc_strip_MEminus11", 36,1,37, 240,0,240);
509  csc_strip_MEminus11->setAxisTitle("Cathode HalfStrip", 2);
510  csc_strip_MEminus11->setAxisTitle("ME-1/1", 1);
511  csc_strip_MEminus12= ibooker.book2D("csc_strip_MEminus12", "csc_strip_MEminus12", 36,1,37, 240,0,240);
512  csc_strip_MEminus12->setAxisTitle("Cathode HalfStrip", 2);
513  csc_strip_MEminus12->setAxisTitle("ME-1/2", 1);
514  csc_strip_MEminus13= ibooker.book2D("csc_strip_MEminus13", "csc_strip_MEminus13", 36,1,37, 240,0,240);
515  csc_strip_MEminus13->setAxisTitle("Cathode HalfStrip", 2);
516  csc_strip_MEminus13->setAxisTitle("ME-1/3", 1);
517  csc_strip_MEminus21= ibooker.book2D("csc_strip_MEminus21", "csc_strip_MEminus21", 18,1,19, 240,0,240);
518  csc_strip_MEminus21->setAxisTitle("Cathode HalfStrip", 2);
519  csc_strip_MEminus21->setAxisTitle("ME-2/1", 1);
520  csc_strip_MEminus22= ibooker.book2D("csc_strip_MEminus22", "csc_strip_MEminus22", 36,1,37, 240,0,240);
521  csc_strip_MEminus22->setAxisTitle("Cathode HalfStrip", 2);
522  csc_strip_MEminus22->setAxisTitle("ME-2/2", 1);
523  csc_strip_MEminus31= ibooker.book2D("csc_strip_MEminus31", "csc_strip_MEminus31", 18,1,19, 240,0,240);
524  csc_strip_MEminus31->setAxisTitle("Cathode HalfStrip", 2);
525  csc_strip_MEminus31->setAxisTitle("ME-3/1", 1);
526  csc_strip_MEminus32= ibooker.book2D("csc_strip_MEminus32", "csc_strip_MEminus32", 36,1,37, 240,0,240);
527  csc_strip_MEminus32->setAxisTitle("Cathode HalfStrip", 2);
528  csc_strip_MEminus32->setAxisTitle("ME-3/2", 1);
529  csc_strip_MEminus41= ibooker.book2D("csc_strip_MEminus41", "csc_strip_MEminus41", 18,1,19, 240,0,240);
530  csc_strip_MEminus41->setAxisTitle("Cathode HalfStrip", 2);
531  csc_strip_MEminus41->setAxisTitle("ME-4/1", 1);
532  csc_strip_MEminus42= ibooker.book2D("csc_strip_MEminus42", "csc_strip_MEminus42", 36,1,37, 240,0,240);
533  csc_strip_MEminus42->setAxisTitle("Cathode HalfStrip", 2);
534  csc_strip_MEminus42->setAxisTitle("ME-4/2", 1);
535 
536  csc_wire_MEplus11= ibooker.book2D("csc_wire_MEplus11", "csc_wire_MEplus11", 36,1,37, 120,0,120);
537  csc_wire_MEplus11->setAxisTitle("Anode Wiregroup", 2);
538  csc_wire_MEplus11->setAxisTitle("ME+1/1", 1);
539  csc_wire_MEplus12= ibooker.book2D("csc_wire_MEplus12", "csc_wire_MEplus12", 36,1,37, 120,0,120);
540  csc_wire_MEplus12->setAxisTitle("Anode Wiregroup", 2);
541  csc_wire_MEplus12->setAxisTitle("ME+1/2", 1);
542  csc_wire_MEplus13= ibooker.book2D("csc_wire_MEplus13", "csc_wire_MEplus13", 36,1,37, 120,0,120);
543  csc_wire_MEplus13->setAxisTitle("Anode Wiregroup", 2);
544  csc_wire_MEplus13->setAxisTitle("ME+1/3", 1);
545  csc_wire_MEplus21= ibooker.book2D("csc_wire_MEplus21", "csc_wire_MEplus21", 18,1,19, 120,0,120);
546  csc_wire_MEplus21->setAxisTitle("Anode Wiregroup", 2);
547  csc_wire_MEplus21->setAxisTitle("ME+2/1", 1);
548  csc_wire_MEplus22= ibooker.book2D("csc_wire_MEplus22", "csc_wire_MEplus22", 36,1,37, 120,0,120);
549  csc_wire_MEplus22->setAxisTitle("Anode Wiregroup", 2);
550  csc_wire_MEplus22->setAxisTitle("ME+2/2", 1);
551  csc_wire_MEplus31= ibooker.book2D("csc_wire_MEplus31", "csc_wire_MEplus31", 18,1,19, 120,0,120);
552  csc_wire_MEplus31->setAxisTitle("Anode Wiregroup", 2);
553  csc_wire_MEplus31->setAxisTitle("ME+3/1", 1);
554  csc_wire_MEplus32= ibooker.book2D("csc_wire_MEplus32", "csc_wire_MEplus32", 36,1,37, 120,0,120);
555  csc_wire_MEplus32->setAxisTitle("Anode Wiregroup", 2);
556  csc_wire_MEplus32->setAxisTitle("ME+3/2", 1);
557  csc_wire_MEplus41= ibooker.book2D("csc_wire_MEplus41", "csc_wire_MEplus41", 18,1,19, 120,0,120);
558  csc_wire_MEplus41->setAxisTitle("Anode Wiregroup", 2);
559  csc_wire_MEplus41->setAxisTitle("ME+4/1", 1);
560  csc_wire_MEplus42= ibooker.book2D("csc_wire_MEplus42", "csc_wire_MEplus42", 36,1,37, 120,0,120);
561  csc_wire_MEplus42->setAxisTitle("Anode Wiregroup", 2);
562  csc_wire_MEplus42->setAxisTitle("ME+4/2", 1);
563 
564  csc_wire_MEminus11= ibooker.book2D("csc_wire_MEminus11", "csc_wire_MEminus11", 36,1,37, 120,0,120);
565  csc_wire_MEminus11->setAxisTitle("Anode Wiregroup", 2);
566  csc_wire_MEminus11->setAxisTitle("ME-1/1", 1);
567  csc_wire_MEminus12= ibooker.book2D("csc_wire_MEminus12", "csc_wire_MEminus12", 36,1,37, 120,0,120);
568  csc_wire_MEminus12->setAxisTitle("Anode Wiregroup", 2);
569  csc_wire_MEminus12->setAxisTitle("ME-1/2", 1);
570  csc_wire_MEminus13= ibooker.book2D("csc_wire_MEminus13", "csc_wire_MEminus13", 36,1,37, 120,0,120);
571  csc_wire_MEminus13->setAxisTitle("Anode Wiregroup", 2);
572  csc_wire_MEminus13->setAxisTitle("ME-1/3", 1);
573  csc_wire_MEminus21= ibooker.book2D("csc_wire_MEminus21", "csc_wire_MEminus21", 18,1,19, 120,0,120);
574  csc_wire_MEminus21->setAxisTitle("Anode Wiregroup", 2);
575  csc_wire_MEminus21->setAxisTitle("ME-2/1", 1);
576  csc_wire_MEminus22= ibooker.book2D("csc_wire_MEminus22", "csc_wire_MEminus22", 36,1,37, 120,0,120);
577  csc_wire_MEminus22->setAxisTitle("Anode Wiregroup", 2);
578  csc_wire_MEminus22->setAxisTitle("ME-2/2", 1);
579  csc_wire_MEminus31= ibooker.book2D("csc_wire_MEminus31", "csc_wire_MEminus31", 18,1,19, 120,0,120);
580  csc_wire_MEminus31->setAxisTitle("Anode Wiregroup", 2);
581  csc_wire_MEminus31->setAxisTitle("ME-3/1", 1);
582  csc_wire_MEminus32= ibooker.book2D("csc_wire_MEminus32", "csc_wire_MEminus32", 36,1,37, 120,0,120);
583  csc_wire_MEminus32->setAxisTitle("Anode Wiregroup", 2);
584  csc_wire_MEminus32->setAxisTitle("ME-3/2", 1);
585  csc_wire_MEminus41= ibooker.book2D("csc_wire_MEminus41", "csc_wire_MEminus41", 18,1,19, 120,0,120);
586  csc_wire_MEminus41->setAxisTitle("Anode Wiregroup", 2);
587  csc_wire_MEminus41->setAxisTitle("ME-4/1", 1);
588  csc_wire_MEminus42= ibooker.book2D("csc_wire_MEminus42", "csc_wire_MEminus42", 36,1,37, 120,0,120);
589  csc_wire_MEminus42->setAxisTitle("Anode Wiregroup", 2);
590  csc_wire_MEminus42->setAxisTitle("ME-4/2", 1);
591 
592 
593 
594  for(int cscid = 1; cscid < 37; cscid++){
595  char bxtitle[100];
596  sprintf(bxtitle,"%d", cscid);
597 
598  csc_strip_MEplus11 ->setBinLabel(cscid,bxtitle,1);
599  csc_strip_MEplus12 ->setBinLabel(cscid,bxtitle,1);
600  csc_strip_MEplus13 ->setBinLabel(cscid,bxtitle,1);
601  csc_strip_MEplus22 ->setBinLabel(cscid,bxtitle,1);
602  csc_strip_MEplus32 ->setBinLabel(cscid,bxtitle,1);
603  csc_strip_MEplus42 ->setBinLabel(cscid,bxtitle,1);
604 
605  csc_strip_MEminus11 ->setBinLabel(cscid,bxtitle,1);
606  csc_strip_MEminus12 ->setBinLabel(cscid,bxtitle,1);
607  csc_strip_MEminus13 ->setBinLabel(cscid,bxtitle,1);
608  csc_strip_MEminus22 ->setBinLabel(cscid,bxtitle,1);
609  csc_strip_MEminus32 ->setBinLabel(cscid,bxtitle,1);
610  csc_strip_MEminus42 ->setBinLabel(cscid,bxtitle,1);
611 
612  csc_wire_MEplus11 ->setBinLabel(cscid,bxtitle,1);
613  csc_wire_MEplus12 ->setBinLabel(cscid,bxtitle,1);
614  csc_wire_MEplus13 ->setBinLabel(cscid,bxtitle,1);
615  csc_wire_MEplus22 ->setBinLabel(cscid,bxtitle,1);
616  csc_wire_MEplus32 ->setBinLabel(cscid,bxtitle,1);
617  csc_wire_MEplus42 ->setBinLabel(cscid,bxtitle,1);
618 
619  csc_wire_MEminus11 ->setBinLabel(cscid,bxtitle,1);
620  csc_wire_MEminus12 ->setBinLabel(cscid,bxtitle,1);
621  csc_wire_MEminus13 ->setBinLabel(cscid,bxtitle,1);
622  csc_wire_MEminus22 ->setBinLabel(cscid,bxtitle,1);
623  csc_wire_MEminus32 ->setBinLabel(cscid,bxtitle,1);
624  csc_wire_MEminus42 ->setBinLabel(cscid,bxtitle,1);
625  }
626 
627 
628  for(int cscid = 1; cscid < 19; cscid++){
629  char bxtitle[100];
630  sprintf(bxtitle,"%d", cscid);
631 
632  csc_strip_MEplus21 ->setBinLabel(cscid,bxtitle,1);
633  csc_strip_MEplus31 ->setBinLabel(cscid,bxtitle,1);
634  csc_strip_MEplus41 ->setBinLabel(cscid,bxtitle,1);
635 
636  csc_strip_MEminus21 ->setBinLabel(cscid,bxtitle,1);
637  csc_strip_MEminus31 ->setBinLabel(cscid,bxtitle,1);
638  csc_strip_MEminus41 ->setBinLabel(cscid,bxtitle,1);
639 
640  csc_wire_MEplus21 ->setBinLabel(cscid,bxtitle,1);
641  csc_wire_MEplus31 ->setBinLabel(cscid,bxtitle,1);
642  csc_wire_MEplus41 ->setBinLabel(cscid,bxtitle,1);
643 
644  csc_wire_MEminus21 ->setBinLabel(cscid,bxtitle,1);
645  csc_wire_MEminus31 ->setBinLabel(cscid,bxtitle,1);
646  csc_wire_MEminus41 ->setBinLabel(cscid,bxtitle,1);
647 
648  }
649 
650 }
651 
652 void L1TCSCTF::analyze(const Event& e, const EventSetup& c)
653 {
654 
656  c.get< L1MuTriggerPtScaleRcd >().cacheIdentifier() != m_ptScaleCacheID ){
657 
659  c.get< L1MuTriggerScalesRcd >().get(scales);
660  ts = scales.product();
662  c.get< L1MuTriggerPtScaleRcd >().get(ptscales);
663  tpts = ptscales.product();
664  m_scalesCacheID = c.get< L1MuTriggerScalesRcd >().cacheIdentifier();
665  m_ptScaleCacheID = c.get< L1MuTriggerPtScaleRcd >().cacheIdentifier();
666 
667  edm::LogInfo("L1TCSCTF") << "Changing triggerscales and triggerptscales...";
668  }
669 
670  int NumCSCTfTracksRep = 0;
671  nev_++;
672  if(verbose_) edm::LogInfo("DataNotFound") << "L1TCSCTF: analyze...." << endl;
673 
675  if( gmtProducer.label() != "null" )
676  { // GMT block
677  e.getByToken(gmtProducerToken_, pCollection);
678  if (!pCollection.isValid())
679  {
680  edm::LogInfo("DataNotFound") << "can't find L1MuGMTReadoutCollection with label "; // << csctfSource_.label() ;
681  return;
682  }
683 
684  L1MuGMTReadoutCollection const* gmtrc = pCollection.product();
685  vector<L1MuGMTReadoutRecord> gmt_records = gmtrc->getRecords();
686  vector<L1MuGMTReadoutRecord>::const_iterator RRItr;
687 
688  // Look if the readout window contains one (and only one CSC cands)
689  // to make it simpler I reject events with more than a CSC cand in the
690  // same readout window
691 
692  // count non-empty candidates in this bx
693  int bxWindow = 0;
694  int nCands = 0;
695 
696  for( RRItr = gmt_records.begin(); RRItr != gmt_records.end(); RRItr++ ) {
697  bxWindow++;
698 
699  // get the csc candidates
700  vector<L1MuRegionalCand> INPCands = RRItr->getCSCCands();
701  vector<L1MuRegionalCand>::const_iterator INPItr;
702 
703  BxInEvent_ = 0;
704  isCSCcand_ = false;
705  int nCandsBx = 0;
706 
707  for( INPItr = INPCands.begin(); INPItr != INPCands.end(); ++INPItr ) {
708  if(!INPItr->empty())
709  {
710  nCandsBx++;
711  nCands++;
712  BxInEvent_ = RRItr->getBxInEvent();
713  if (verbose_) edm::LogInfo("DataNotFound") << "cand " << nCandsBx << " -> assigned CSCTF bx: " << INPItr->bx() << endl;
714  }
715  }
716  if (verbose_)
717  if(nCandsBx) edm::LogInfo("DataNotFound") << nCandsBx << " cands in bx: " << BxInEvent_ << endl;
718  }
719 
720  if (nCands != 1) return;
721  else isCSCcand_ = true;
722  if (verbose_) edm::LogInfo("DataNotFound") << "bxWindow: " << bxWindow << endl;
723 
724  int ncsctftrack = 0;
725  if (verbose_)
726  {
727  edm::LogInfo("DataNotFound") << "\tCSCTFCand ntrack " << ncsctftrack << endl;
728  }
729  } // end of GMT block
730 
731  L1ABXN = -999;
732  if( statusProducer.label() != "null" )
733  {
735  e.getByToken(statusToken_, status);
736  bool integrity=status->first, se=false, sm=false, bx=false, af=false, fmm=false;
737  int nStat = 0;
738 
739  for(std::vector<L1CSCSPStatusDigi>::const_iterator stat=status->second.begin(); stat!=status->second.end(); stat++)
740  {
741  se |= stat->SEs()&0xFFF;
742  sm |= stat->SMs()&0xFFF;
743  bx |= stat->BXs()&0xFFF;
744  af |= stat->AFs()&0xFFF;
745  fmm|= stat->FMM()!=8;
746 
747  if(stat->VPs() != 0)
748  {
749  L1ABXN += stat->BXN();
750  nStat++;
751  }
752  }
753  // compute the average
754  if(nStat!=0) L1ABXN /= nStat;
755  if(integrity) csctferrors->Fill(0.5);
756  if(se) csctferrors->Fill(1.5);
757  if(sm) csctferrors->Fill(2.5);
758  if(bx) csctferrors->Fill(3.5);
759  if(af) csctferrors->Fill(4.5);
760  if(fmm) csctferrors->Fill(5.5);
761  }
762 
763  if( lctProducer.label() != "null" )
764  {
766  c.get<MuonGeometryRecord>().get( pDD );
768 
770  e.getByToken(corrlctsToken_, corrlcts);
771 
772  for(CSCCorrelatedLCTDigiCollection::DigiRangeIterator csc=corrlcts.product()->begin(); csc!=corrlcts.product()->end(); csc++)
773  {
774  CSCCorrelatedLCTDigiCollection::Range range1 = corrlcts.product()->get((*csc).first);
775  for(CSCCorrelatedLCTDigiCollection::const_iterator lct=range1.first; lct!=range1.second; lct++)
776  {
777  int endcap = (*csc).first.endcap()-1;
778  int station = (*csc).first.station()-1;
779  int sector = (*csc).first.triggerSector()-1;
780  int subSector = CSCTriggerNumbering::triggerSubSectorFromLabels((*csc).first);
781  int ring = (*csc).first.ring();
782  int cscId = (*csc).first.triggerCscId()-1;
783  int fpga = ( subSector ? subSector-1 : station+1 );
784  int strip = lct -> getStrip();
785  int keyWire = lct -> getKeyWG();
786  int bx = lct -> getBX();
787 
788 
789  int endcapAssignment = 1;
790  int shift = 1;
791  float sectorArg = sector;
792  //float sectorArg = j;
793 
794  if( endcap == 1 ){
795  endcapAssignment = -1;
796  shift = 2;
797  //sectorArg = sector - 6;
798  }
799 
800  int signedStation = (station + shift)* endcapAssignment;
801  if( (station == 0) && (endcap == 0)) signedStation = subSector - 1;
802  if( (station == 0) && (endcap == 1)) signedStation = (-1)*subSector;
803 
804  float chamberArg1 = cscId * 0.1 + sectorArg;
805  //float chamberArg1 = i*0.1 + sectorArg;
806  //std::cout << "First" << i << " " << sectorArg << " " << chamberArg1 << std::endl;
807 
808  float chamberArg11 = chamberArg1;
809  if(sectorArg == 1) chamberArg1 = chamberArg11 - 0.1;
810  if(sectorArg == 2) chamberArg1 = chamberArg11 - 0.2;
811  if(sectorArg == 3) chamberArg1 = chamberArg11 - 0.3;
812  if(sectorArg == 4) chamberArg1 = chamberArg11 - 0.4;
813  if(sectorArg == 5) chamberArg1 = chamberArg11 - 0.5;
814 
815  //std::cout << "cscId, station, sector, endcap, sectorArg, chamber Arg: " << cscId << ", " << station << ", " <<sector << ", " << endcap << ", " << chamberArg1 << ", " << signedStation << std::endl;
816 
817  csctfChamberOccupancies->Fill(chamberArg1, signedStation);
818  //int bunchX = ( (lct->getBX()) - 6 );
819 
820  //int timingSectorArg = 3*(sector) + (lct->getMPCLink());
821  //if( endcap == 1) timingSectorArg = 3*(sector + 6) + (lct->getMPCLink());
822  //std::cout << "Sector, MPCLink, TSA, endcap: " << sector << ", " << lct->getMPCLink() << ", " << timingSectorArg << ", " << endcap << std::endl;
823 
824  //csctfbx->Fill(timingSectorArg, bunchX );
825  //std::cout << "LCT'S, encap: " << endcap << ", station: " << station << ", sector: " << sector << ", subSector: " << subSector << ", cscId: " << cscId << std:: endl;
826  //End JAG
827 
828  // Check if Det Id is within pysical range:
829  if( endcap<0||endcap>1 || sector<0||sector>6 || station<0||station>3 || cscId<0||cscId>8 || fpga<0||fpga>4)
830  {
831  edm::LogError("L1CSCTF: CSC TP are out of range: ")<<" endcap: "<<(endcap+1)<<" station: "<<(station+1) <<" sector: "<<(sector+1)<<" subSector: "<<subSector<<" fpga: "<<fpga<<" cscId: "<<(cscId+1);
832  continue;
833  }
834 
835  int EndCapLUT=1;
836  //if(endcap==0) EndCapLUT=1; // ME+
837  if(endcap==1) EndCapLUT=0; // ME-
838 
839  lclphidat lclPhi;
840  try {
841  lclPhi = srLUTs_[fpga][EndCapLUT][sector]->localPhi(lct->getStrip(), lct->getPattern(), lct->getQuality(), lct->getBend(), gangedME11a_);
842  } catch(cms::Exception &) {
843  bzero(&lclPhi,sizeof(lclPhi));
844  }
845 
846  gblphidat gblPhi;
847  try {
848  gblPhi = srLUTs_[fpga][EndCapLUT][sector]->globalPhiME(lclPhi.phi_local, lct->getKeyWG(), cscId+1, gangedME11a_);
849  } catch(cms::Exception &) {
850  bzero(&gblPhi,sizeof(gblPhi));
851  }
852 
853  gbletadat gblEta;
854  try {
855  gblEta = srLUTs_[fpga][EndCapLUT][sector]->globalEtaME(lclPhi.phi_bend_local, lclPhi.phi_local, lct->getKeyWG(), cscId+1, gangedME11a_);
856  } catch(cms::Exception &) {
857  bzero(&gblEta,sizeof(gblEta));
858  }
859 
860 
861  //TrackStub
862  csctf::TrackStub theStub((*lct), (*csc).first);
863  theStub.setPhiPacked(gblPhi.global_phi);
864  theStub.setEtaPacked(gblEta.global_eta);
865 
866  float etaG = theStub.etaValue();
867  float phiG = fmod( theStub.phiValue()+15.0*M_PI/180+(sector)*60.0*M_PI/180, 2.*M_PI );
868 
869 
870  //BX plots
871  // endcap==1: minus side; endcap==0: plus side
872  // station=0,1,2,3; ring=1,2,3;
873  if(endcap==1) {
874  if(station==0) {
875  if(ring==1) csctflcts -> Fill(bx, 8.5);
876  else if(ring==2) csctflcts -> Fill(bx, 7.5);
877  else csctflcts -> Fill(bx, 6.5);
878  } else if(station==1) {
879  if(ring==1) csctflcts -> Fill(bx, 5.5);
880  else csctflcts -> Fill(bx, 4.5);
881  } else if(station==2) {
882  if(ring==1) csctflcts -> Fill(bx, 3.5);
883  else csctflcts -> Fill(bx, 2.5);
884  } else if(station==3) {
885  if(ring==1) csctflcts -> Fill(bx, 1.5);
886  else csctflcts -> Fill(bx, 0.5);
887  }
888 
889  } else {
890  if(station==0) {
891  if(ring==1) csctflcts -> Fill(bx, 9.5);
892  else if(ring==2) csctflcts -> Fill(bx, 10.5);
893  else csctflcts -> Fill(bx, 11.5);
894  } else if(station==1) {
895  if(ring==1) csctflcts -> Fill(bx, 12.5);
896  else csctflcts -> Fill(bx, 13.5);
897  } else if(station==2) {
898  if(ring==1) csctflcts -> Fill(bx, 14.5);
899  else csctflcts -> Fill(bx, 15.5);
900  } else if(station==3) {
901  if(ring==1) csctflcts -> Fill(bx, 16.5);
902  else csctflcts -> Fill(bx, 17.5);
903  }
904  }
905 
906 
907 
908  // only for ME1/1
909  if(station == 0 && ring == 1){
910  me11_lctStrip -> Fill(strip);
911  me11_lctWire -> Fill(keyWire);
912  me11_lctLocalPhi -> Fill(lclPhi.phi_local);
913  me11_lctPackedPhi-> Fill(theStub.phiPacked());
914  me11_lctGblPhi -> Fill(phiG);
915  me11_lctGblEta -> Fill(etaG);
916  }
917 
918  // only for ME4/2
919  if(station == 3 && ring == 2){
920  me42_lctGblPhi -> Fill(phiG);
921  me42_lctGblEta -> Fill(etaG);
922  }
923 
924 
925  //ME1/1
926  if (station == 0 && ring == 1){
927  int realID = cscId+6*sector+3*subSector;
928  if(realID>36) realID -= 36;
929  if(endcap == 0) { csc_strip_MEplus11 -> Fill(realID,strip); csc_wire_MEplus11 -> Fill(realID,keyWire); }
930  if(endcap == 1) { csc_strip_MEminus11 -> Fill(realID,strip); csc_wire_MEminus11 -> Fill(realID,keyWire); }
931  }
932  //ME1/2
933  if (station == 0 && ring == 2){
934  int realID = (cscId-3)+6*sector+3*subSector;
935  if(realID>36) realID -= 36;
936  if(endcap == 0) { csc_strip_MEplus12 -> Fill(realID,strip); csc_wire_MEplus12 -> Fill(realID,keyWire); }
937  if(endcap == 1) { csc_strip_MEminus12 -> Fill(realID,strip); csc_wire_MEminus12 -> Fill(realID,keyWire); }
938  }
939  //ME1/3
940  if (station == 0 && ring == 3){
941  int realID = (cscId-6)+6*sector+3*subSector;
942  if(realID>36) realID -= 36;
943  if(endcap == 0) { csc_strip_MEplus13 -> Fill(realID,strip); csc_wire_MEplus13 -> Fill(realID,keyWire); }
944  if(endcap == 1) { csc_strip_MEminus13 -> Fill(realID,strip); csc_wire_MEminus13 -> Fill(realID,keyWire); }
945  }
946  //ME2/1
947  if (station == 1 && ring == 1){
948  int realID = cscId+3*sector+2;
949  if(realID>18) realID -= 18;
950  if(endcap == 0) { csc_strip_MEplus21 -> Fill(realID,strip); csc_wire_MEplus21 -> Fill(realID,keyWire); }
951  if(endcap == 1) { csc_strip_MEminus21 -> Fill(realID,strip); csc_wire_MEminus21 -> Fill(realID,keyWire); }
952  }
953  //ME2/2
954  if (station == 1 && ring == 2){
955  int realID = (cscId-3)+6*sector+3;
956  if(realID>36) realID -= 36;
957  if(endcap == 0) { csc_strip_MEplus22 -> Fill(realID,strip); csc_wire_MEplus22 -> Fill(realID,keyWire); }
958  if(endcap == 1) { csc_strip_MEminus22 -> Fill(realID,strip); csc_wire_MEminus22 -> Fill(realID,keyWire); }
959  }
960 
961  //ME3/1
962  if (station == 2 && ring == 1){
963  int realID = cscId+3*sector+2;
964  if(realID>18) realID -= 18;
965  if(endcap == 0) { csc_strip_MEplus31 -> Fill(realID,strip); csc_wire_MEplus31 -> Fill(realID,keyWire); }
966  if(endcap == 1) { csc_strip_MEminus31 -> Fill(realID,strip); csc_wire_MEminus31 -> Fill(realID,keyWire); }
967  }
968 
969  //ME3/2
970  if (station == 2 && ring == 2){
971  int realID = (cscId-3)+6*sector+3;
972  if(realID>36) realID -= 36;
973  if(endcap == 0) { csc_strip_MEplus32 -> Fill(realID,strip); csc_wire_MEplus32 -> Fill(realID,keyWire); }
974  if(endcap == 1) { csc_strip_MEminus32 -> Fill(realID,strip); csc_wire_MEminus32 -> Fill(realID,keyWire); }
975  }
976  //ME4/1
977  if (station == 3 && ring == 1){
978  int realID = cscId+3*sector+2;
979  if(realID>18) realID -= 18;
980  if(endcap == 0) { csc_strip_MEplus41 -> Fill(realID,strip); csc_wire_MEplus41 -> Fill(realID,keyWire);}
981  if(endcap == 1) { csc_strip_MEminus41 -> Fill(realID,strip); csc_wire_MEminus41 -> Fill(realID,keyWire);}
982  }
983  //ME4/2
984  if (station == 3 && ring == 2){
985  int realID = (cscId-3)+6*sector+3;
986  if(realID>36) realID -= 36;
987  if(endcap == 0) { csc_strip_MEplus42 -> Fill(realID,strip); csc_wire_MEplus42 -> Fill(realID,keyWire); }
988  if(endcap == 1) { csc_strip_MEminus42 -> Fill(realID,strip); csc_wire_MEminus42 -> Fill(realID,keyWire); }
989  }
990 
991 
992 
993 
994 
995 
996  // SR LUT gives packed eta and phi values -> normilize them to 1 by scale them to 'max' and shift by 'min'
997  //float etaP = gblEta.global_eta/127*1.5 + 0.9;
998  //float phiP = (gblPhi.global_phi);// + ( sector )*4096 + station*4096*12) * 1./(4*4096*12);
999  //std::cout << "LCT Eta & Phi Coordinates: " << etaP << ", " << phiP << "." << std::endl;
1000  //csctfoccupancies->Fill( gblEta.global_eta/127. * 1.5 + 0.9, (gblPhi.global_phi + ( sector + (endcap?0:6) )*4096 + station*4096*12) * 1./(4*4096*12) );
1001  }//lct != range1.scond
1002  }//csc!=corrlcts.product()->end()
1003  }// lctProducer.label() != "null"
1004 
1005 
1006 
1007  if( trackProducer.label() != "null" )
1008  {
1010  e.getByToken(tracksToken_, tracks);
1011  for(L1CSCTrackCollection::const_iterator trk=tracks->begin(); trk<tracks->end(); trk++)
1012  {
1013 
1014  NumCSCTfTracksRep++;
1015  long LUTAdd = trk->first.ptLUTAddress();
1016  int trigMode = ( (LUTAdd)&0xf0000 ) >> 16;
1017  int trEta = (trk->first.eta_packed() );
1018 
1019 
1020  // trk->first.endcap() = 2 for - endcap
1021  // = 1 for + endcap
1022  //int trEndcap = (trk->first.endcap()==2 ? trk->first.endcap()-3 : trk->first.endcap());
1023  if( trk->first.endcap() != 1)
1024  {
1025  int holder = trEta;
1026  trEta = -1*holder;
1027  trEta -= 1;
1028  }
1029 
1030  int trSector = 6*(trk->first.endcap()-1)+trk->first.sector();
1031  int trBX = trk->first.BX();
1032 
1033  //Here is what is done with output phi value:
1034  //output_phi = (phi / 32) * 3 /16
1035  //where:
1036  //phi is 12-bit phi, 4096 bins covering 62 degrees
1037  //output_phi is 5-bit value
1038 
1039  //Easy to see that output_phi can have values from 0 to 23, or 24 total combinations.
1040  //This gives per-bin phi value of 62/24 = 2.583333 degrees.
1041 
1042  // Sector 1 nominally starts at 15 degrees but there 1 degree overlap between sectors so 14 degrees effectively
1043  //double trPhi = trk->first.localPhi() * 62. / 24.;
1044  double trPhi = ts->getPhiScale()->getLowEdge(trk->first.localPhi());
1045  double trPhi02PI = fmod(trPhi +
1046  ((trSector-1)*M_PI/3) +
1047  (M_PI*14/180.), 2*M_PI);
1048 
1049  if (trigMode == 15) {
1050  csctfTrackPhi_H -> Fill( trPhi02PI );
1051  csctfTrackEta_H -> Fill( trEta );
1052  csctfoccupancies_H -> Fill( trEta, trPhi02PI );
1053  csctfbx_H -> Fill( trSector, trBX );
1054  }
1055  else{
1056  csctfTrackPhi -> Fill( trPhi02PI );
1057  csctfTrackEta -> Fill( trEta );
1058  csctfoccupancies -> Fill( trEta, trPhi02PI );
1059  csctfbx -> Fill( trSector, trBX );
1060 
1061  // Low Quality / High Quality Eta Distributions
1062  //|eta| < 2.1
1063  if (abs(trEta) < 24) {
1064  if (trigMode == 2 ||
1065  trigMode == 3 ||
1066  trigMode == 4 ||
1067  trigMode == 5 ||
1068  trigMode == 6 ||
1069  trigMode == 7 ||
1070  trigMode == 11 ||
1071  trigMode == 12 ||
1072  trigMode == 13 ||
1073  trigMode == 14 ) csctfTrackEtaHighQ -> Fill (trEta);
1074 
1075  if (trigMode == 8 ||
1076  trigMode == 9 ||
1077  trigMode == 10 ) csctfTrackEtaLowQ -> Fill (trEta);
1078  }
1079  else {//|eta| > 2.1
1080  if (trigMode == 2 ||
1081  trigMode == 3 ||
1082  trigMode == 4 ||
1083  trigMode == 5 ) csctfTrackEtaHighQ -> Fill (trEta);
1084  else
1085  csctfTrackEtaLowQ -> Fill (trEta);
1086  }
1087  }
1088 
1089  csctfTrackM->Fill( trk->first.modeExtended() );
1090 
1091  // we monitor the track quality only on the first link
1092  // so let's make sure to fill the plot if there is something that
1093  // is read from the hardware
1094  int trRank = trk->first.rank();
1095  if (trRank) {
1096  int trQuality = ((trRank>>5)&0x3);
1097  trackModeVsQ->Fill( trk->first.modeExtended(), trQuality );
1098  }
1099 
1100  /*
1101  OLD METHOD FOR FILLING HALO PLOTS, IMPROVED METHOD USING ASSOCIATED TRACK STUBS
1102  BELOW ~LINE 605
1103  if( trigMode == 15 )
1104  {
1105 
1106  double haloVals[4][4];
1107  for( int i = 0; i < 4; i++)
1108  {
1109  haloVals[i][0] = 0;
1110  }
1111 
1112  edm::Handle<CSCCorrelatedLCTDigiCollection> corrlcts;
1113  for(CSCCorrelatedLCTDigiCollection::DigiRangeIterator csc=corrlcts.product()->begin(); csc!=corrlcts.product()->end(); csc++)
1114  {
1115  CSCCorrelatedLCTDigiCollection::Range range1 = corrlcts.product()->get((*csc).first);
1116  for(CSCCorrelatedLCTDigiCollection::const_iterator lct=range1.first; lct!=range1.second; lct++)
1117  {
1118  int endcap = (*csc).first.endcap()-1;
1119  int station = (*csc).first.station()-1;
1120  int sector = (*csc).first.triggerSector()-1;
1121  int cscId = (*csc).first.triggerCscId()-1;
1122  int subSector = CSCTriggerNumbering::triggerSubSectorFromLabels((*csc).first);
1123  int fpga = ( subSector ? subSector-1 : station+1 );
1124 
1125  if(station != 4)
1126  {
1127  int modEnd = 1;
1128  if( endcap == 0 ) modEnd = -1;
1129  int indexHalo = modEnd + station;
1130  if(haloVals[indexHalo][0] == 1.0) haloVals[indexHalo][3] = 1.0;
1131  if(haloVals[indexHalo][0] == 0) haloVals[indexHalo][0] = 1.0;
1132  haloVals[indexHalo][1] = sector*1.0;
1133 
1134  lclphidat lclPhi;
1135  lclPhi = srLUTs_[fpga]->localPhi(lct->getStrip(), lct->getPattern(), lct->getQuality(), lct->getBend());
1136  gblphidat gblPhi;
1137  gblPhi = srLUTs_[fpga]->globalPhiME(lclPhi.phi_local, lct->getKeyWG(), cscId+1);
1138  gbletadat gblEta;
1139  gblEta = srLUTs_[fpga]->globalEtaME(lclPhi.phi_bend_local, lclPhi.phi_local, lct->getKeyWG(), cscId+1);
1140 
1141  haloVals[indexHalo][2] = gblEta.global_eta/127. * 1.5 + 0.9;
1142  } //station1 or 2
1143  } //lct first to second
1144  } //corrlcts
1145 
1146  if( (haloVals[0][0] == 1.) && (haloVals[1][0] == 1.) && (haloVals[0][3] != 1.) && (haloVals[1][3] != 1.) )
1147  {
1148  if( haloVals[0][1] == haloVals[1][1] ){
1149  double delEta23 = haloVals[1][2] - haloVals[0][2];
1150  haloDelEta23->Fill( delEta23 );
1151  }
1152  }
1153 
1154  if( (haloVals[2][0] == 1.) && (haloVals[3][0] == 1.) && (haloVals[2][3] != 1.) && (haloVals[3][3] != 1.) )
1155  {
1156  if( haloVals[2][1] == haloVals[3][1] ){
1157  double delEta23 = haloVals[3][2] - haloVals[2][2];
1158  haloDelEta23->Fill( delEta23 );
1159  }
1160  }
1161  } //halo trigger
1162  */
1163 
1164  int cscTrackStub = 0;
1165  //float haloEta[3];
1166  //for(int i=0; i<3; i++) haloEta[i]=-1.0;
1167  //bool haloME11 = false;
1168  CSCCorrelatedLCTDigiCollection lctsOfTracks=trk->second;
1169  for(CSCCorrelatedLCTDigiCollection::DigiRangeIterator trackStub=lctsOfTracks.begin(); trackStub!=lctsOfTracks.end(); trackStub++)
1170  {
1171  CSCCorrelatedLCTDigiCollection::Range range2 = lctsOfTracks.get((*trackStub).first);
1172  for(CSCCorrelatedLCTDigiCollection::const_iterator lct=range2.first; lct!=range2.second; lct++)
1173  {
1174 // int station = (*trackStub).first.station()-1;
1175 // if(station != 4)
1176 // {
1177 // // int endcap = (*trackStub).first.endcap()-1;
1178 // // int sector = (*trackStub).first.triggerSector()-1;
1179 // int cscId = (*trackStub).first.triggerCscId()-1;
1180 // int subSector = CSCTriggerNumbering::triggerSubSectorFromLabels((*trackStub).first);
1181 // int fpga = ( subSector ? subSector-1 : station+1 );
1182 
1183 // lclphidat lclPhi;
1184 // lclPhi = srLUTs_[fpga]->localPhi(lct->getStrip(), lct->getPattern(), lct->getQuality(), lct->getBend());
1185 // gblphidat gblPhi;
1186 // gblPhi = srLUTs_[fpga]->globalPhiME(lclPhi.phi_local, lct->getKeyWG(), cscId+1);
1187 // gbletadat gblEta;
1188 // gblEta = srLUTs_[fpga]->globalEtaME(lclPhi.phi_bend_local, lclPhi.phi_local, lct->getKeyWG(), cscId+1);
1189 // haloEta[station-1] = gblEta.global_eta/127. * 1.5 + 0.9;
1190 // if(station==1 && cscId<2) haloME11 = true;
1191 // }
1192  cscTrackStub++;
1193  }
1194  }
1195  cscTrackStubNumbers->Fill(cscTrackStub);
1196 
1197 // if(trigMode == 15)
1198 // {
1199 // float dEta13 = haloEta[2]-haloEta[0];
1200 // float dEta12 = haloEta[1]-haloEta[0];
1201 // if(haloME11)
1202 // {
1203 // if(haloEta[1]!=-1.0) haloDelEta112->Fill(dEta12);
1204 // if(haloEta[2]!=-1.0) haloDelEta113->Fill(dEta13);
1205 // } else {
1206 // if(haloEta[1]!=-1.0) haloDelEta12->Fill(dEta12);
1207 // if(haloEta[2]!=-1.0) haloDelEta13->Fill(dEta13);
1208 // }
1209 // }
1210  //
1211 
1212 
1213 
1214  }
1215  }
1216  csctfntrack->Fill(NumCSCTfTracksRep);
1217 
1218 
1219  if( mbProducer.label() != "null" )
1220  {
1221  // handle to needed collections
1223  e.getByToken(dtStubsToken_, dtStubs);
1225  e.getByToken(mbtracksToken_, tracks);
1226 
1227  // loop on the DT stubs
1228  std::vector<csctf::TrackStub> vstubs = dtStubs->get();
1229  for(std::vector<csctf::TrackStub>::const_iterator stub=vstubs.begin();
1230  stub!=vstubs.end(); stub++)
1231  {
1232  if (verbose_)
1233  {
1234  edm::LogInfo("DataNotFound") << "\n mbEndcap: " << stub->endcap();
1235  edm::LogInfo("DataNotFound") << "\n stub->getStrip()[FLAG]: " << stub->getStrip();
1236  edm::LogInfo("DataNotFound") << "\n stub->getKeyWG()[CAL]: " << stub->getKeyWG();
1237  edm::LogInfo("DataNotFound") << "\n stub->BX(): " << stub->BX();
1238  edm::LogInfo("DataNotFound") << "\n stub->sector(): " << stub->sector();
1239  edm::LogInfo("DataNotFound") << "\n stub->subsector(): " << stub->subsector();
1240  edm::LogInfo("DataNotFound") << "\n stub->station(): " << stub->station();
1241  edm::LogInfo("DataNotFound") << "\n stub->phiPacked(): " << stub->phiPacked();
1242  edm::LogInfo("DataNotFound") << "\n stub->getBend(): " << stub->getBend();
1243  edm::LogInfo("DataNotFound") << "\n stub->getQuality(): " << stub->getQuality();
1244  edm::LogInfo("DataNotFound") << "\n stub->cscid(): " << stub->cscid() << endl;
1245  }
1246  // define the sector ID
1247  int mbId = (stub->endcap()==2) ? 6 : 0;
1248  mbId += stub->sector();
1249  // *** do not fill if CalMB variable is set ***
1250  // horrible! They used the same class to write up the LCT and MB info,
1251  // but given the MB does not have strip and WG they replaced this two
1252  // with the flag and cal bits... :S
1253  if (stub->getKeyWG() == 0)
1254  {
1255  // if FLAG =1, muon belong to previous BX
1256  int bxDT = stub->BX()-stub->getStrip(); // correct by the FLAG
1257  int subDT = stub->subsector();
1258 
1259  // Fill the event only if CSC had or would have triggered
1260  if (isCSCcand_)
1261  {
1262  //look for tracks in the event and compare the matching DT stubs
1263  int trkBX = 0;
1264  for(L1CSCTrackCollection::const_iterator trk=tracks->begin(); trk<tracks->end(); trk++)
1265  {
1266  trkBX = trk->first.BX();
1267  int trkId = (trk->first.endcap()==2) ? 6 : 0;
1268  trkId += trk->first.sector();
1269  if (verbose_){
1270  edm::LogInfo("DataNotFound") << "\n trk BX: " << trkBX
1271  << " Sector: " << trkId
1272  << " SubSector: " << trk->first.subsector()
1273  << " Endcap: " << trk->first.endcap();
1274 
1275  edm::LogInfo("DataNotFound") << "\n DT BX: " << stub->BX()
1276  << " Sector: " << mbId
1277  << " SubSector: " << stub->subsector()
1278  << " Endcap: " << stub->endcap() << endl;
1279  }
1280 
1281  if (mbId == trkId)
1282  {
1283  if (verbose_) {
1284  edm::LogInfo("DataNotFound") << " --> MATCH" << endl;
1285  edm::LogInfo("DataNotFound") << "Fill :" << trkBX+6-bxDT << " -- " << subDT << " -- cands" << endl;
1286  }
1287  // DT bx ranges from 3 to 9
1288  // trk bx ranges from -3 to 3
1289  DTstubsTimeTrackMenTimeArrival[mbId-1]->Fill(bxDT-trkBX-6,subDT);//subsec
1290  }
1291  }// loop on the tracks
1292  }//if (isCSCcand_){
1293  }//if (stub->getKeyWG() == 0) {
1294  }
1295  }
1296 }
MonitorElement * DTstubsTimeTrackMenTimeArrival[12]
Definition: L1TCSCTF.h:166
MonitorElement * csctfoccupancies
Definition: L1TCSCTF.h:83
T getParameter(std::string const &) const
unsigned long long cacheIdentifier() const
MonitorElement * csctfTrackEtaHighQ
Definition: L1TCSCTF.h:99
T getUntrackedParameter(std::string const &, T const &) const
int i
Definition: DBlmapReader.cc:9
MonitorElement * csctflcts
Definition: L1TCSCTF.h:108
lclphidat localPhi(int strip, int pattern, int quality, int lr, const bool gangedME1a=false) const
Geometry Lookup Tables.
MonitorElement * csctfTrackPhi
Definition: L1TCSCTF.h:96
MonitorElement * csc_strip_MEminus22
Definition: L1TCSCTF.h:137
bool verbose_
Definition: L1TCSCTF.h:174
unsigned long long m_scalesCacheID
Definition: L1TCSCTF.h:184
MonitorElement * csctfTrackPhi_H
Definition: L1TCSCTF.h:100
MonitorElement * csc_wire_MEplus31
Definition: L1TCSCTF.h:148
bool getByToken(EDGetToken token, Handle< PROD > &result) const
Definition: Event.h:464
MonitorElement * csc_strip_MEplus21
Definition: L1TCSCTF.h:126
MonitorElement * csc_strip_MEplus11
Definition: L1TCSCTF.h:123
virtual float getLowEdge(unsigned packed) const =0
get the low edge of bin represented by packed
MonitorElement * csc_wire_MEminus13
Definition: L1TCSCTF.h:155
MonitorElement * csc_wire_MEminus22
Definition: L1TCSCTF.h:157
MonitorElement * me11_lctGblPhi
Definition: L1TCSCTF.h:115
void setBinLabel(int bin, const std::string &label, int axis=1)
set bin label for x, y or z axis (axis=1, 2, 3 respectively)
MonitorElement * csc_wire_MEplus12
Definition: L1TCSCTF.h:144
MonitorElement * csc_wire_MEminus31
Definition: L1TCSCTF.h:158
MonitorElement * csctfbx
Definition: L1TCSCTF.h:79
MonitorElement * csc_wire_MEminus32
Definition: L1TCSCTF.h:159
MonitorElement * csctfTrackEtaLowQ
Definition: L1TCSCTF.h:98
edm::InputTag mbProducer
Definition: L1TCSCTF.h:177
MonitorElement * csc_strip_MEminus12
Definition: L1TCSCTF.h:134
static void setGeometry(const edm::ESHandle< CSCGeometry > &thegeom)
MonitorElement * csctfTrackEta
Definition: L1TCSCTF.h:97
void analyze(const edm::Event &e, const edm::EventSetup &c)
Definition: L1TCSCTF.cc:652
MonitorElement * me11_lctWire
Definition: L1TCSCTF.h:112
MonitorElement * csc_strip_MEminus31
Definition: L1TCSCTF.h:138
std::string outputFile_
Definition: L1TCSCTF.h:173
unsigned phiPacked() const
Return the binned phi for this stub.
Definition: TrackStub.h:44
MonitorElement * csc_wire_MEminus21
Definition: L1TCSCTF.h:156
void Fill(long long x)
edm::InputTag statusProducer
Definition: L1TCSCTF.h:177
edm::EDGetTokenT< L1CSCStatusDigiCollection > statusToken_
Definition: L1TCSCTF.h:189
MonitorElement * csctfTrackEta_H
Definition: L1TCSCTF.h:101
MonitorElement * me42_lctGblPhi
Definition: L1TCSCTF.h:119
const L1MuTriggerScales * ts
Definition: L1TCSCTF.h:182
bool gangedME11a_
Definition: L1TCSCTF.h:178
gblphidat globalPhiME(int phi_local, int wire_group, int cscid, const bool gangedME1a=false) const
MonitorElement * cscTrackStubNumbers
Definition: L1TCSCTF.h:102
MonitorElement * csc_strip_MEminus32
Definition: L1TCSCTF.h:139
int L1ABXN
Definition: L1TCSCTF.h:170
MonitorElement * me11_lctStrip
Definition: L1TCSCTF.h:111
void Fill(HcalDetId &id, double val, std::vector< TH2F > &depth)
int BxInEvent_
Definition: L1TCSCTF.h:167
MonitorElement * csc_strip_MEminus42
Definition: L1TCSCTF.h:141
MonitorElement * csc_wire_MEplus41
Definition: L1TCSCTF.h:150
virtual ~L1TCSCTF()
Definition: L1TCSCTF.cc:108
double etaValue() const
return the Eta Value of this stub&#39;s position.
Definition: TrackStub.h:36
const L1MuScale * getPhiScale() const
get the phi scale
MonitorElement * book1D(Args &&...args)
Definition: DQMStore.h:115
MonitorElement * csc_strip_MEplus13
Definition: L1TCSCTF.h:125
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
int j
Definition: DBlmapReader.cc:9
MonitorElement * csc_strip_MEplus22
Definition: L1TCSCTF.h:127
int nev_
Definition: L1TCSCTF.h:172
MonitorElement * csc_wire_MEminus41
Definition: L1TCSCTF.h:160
L1TCSCTF(const edm::ParameterSet &ps)
Definition: L1TCSCTF.cc:25
MonitorElement * csctfChamberOccupancies
Definition: L1TCSCTF.h:95
bool isValid() const
Definition: HandleBase.h:75
MonitorElement * csc_wire_MEplus13
Definition: L1TCSCTF.h:145
edm::InputTag lctProducer
Definition: L1TCSCTF.h:177
#define M_PI
MonitorElement * csc_wire_MEplus21
Definition: L1TCSCTF.h:146
virtual void bookHistograms(DQMStore::IBooker &ibooker, edm::Run const &, edm::EventSetup const &) override
Definition: L1TCSCTF.cc:121
edm::EDGetTokenT< L1CSCTrackCollection > tracksToken_
Definition: L1TCSCTF.h:191
MonitorElement * csc_strip_MEminus41
Definition: L1TCSCTF.h:140
MonitorElement * me42_lctGblEta
Definition: L1TCSCTF.h:120
MonitorElement * csc_strip_MEplus31
Definition: L1TCSCTF.h:128
MonitorElement * csc_wire_MEplus32
Definition: L1TCSCTF.h:149
edm::EDGetTokenT< CSCCorrelatedLCTDigiCollection > corrlctsToken_
Definition: L1TCSCTF.h:190
double phiValue() const
return the Phi Value of this stub&#39;s position in local coordinates.
Definition: TrackStub.h:38
void setCurrentFolder(const std::string &fullpath)
Definition: DQMStore.cc:274
MonitorElement * csctferrors
Definition: L1TCSCTF.h:82
T const * product() const
Definition: Handle.h:81
MonitorElement * book2D(Args &&...args)
Definition: DQMStore.h:133
tuple tracks
Definition: testEve_cfg.py:39
void addUntrackedParameter(std::string const &name, T const &value)
Definition: ParameterSet.h:208
MonitorElement * csc_wire_MEminus42
Definition: L1TCSCTF.h:161
bool isCSCcand_
Definition: L1TCSCTF.h:168
class global_phi_data gblphidat
MonitorElement * csc_strip_MEplus41
Definition: L1TCSCTF.h:130
const T & get() const
Definition: EventSetup.h:56
MonitorElement * csctfTrackM
Definition: L1TCSCTF.h:103
edm::EDGetTokenT< L1CSCTrackCollection > mbtracksToken_
Definition: L1TCSCTF.h:193
T const * product() const
Definition: ESHandle.h:86
MonitorElement * csctfbx_H
Definition: L1TCSCTF.h:80
std::vector< CSCCorrelatedLCTDigi >::const_iterator const_iterator
class local_phi_data lclphidat
Data Types.
virtual void dqmBeginRun(const edm::Run &, const edm::EventSetup &)
Definition: L1TCSCTF.cc:118
static int triggerSubSectorFromLabels(int station, int chamber)
MonitorElement * csctfntrack
Definition: L1TCSCTF.h:78
edm::InputTag trackProducer
Definition: L1TCSCTF.h:177
edm::EDGetTokenT< L1MuGMTReadoutCollection > gmtProducerToken_
Definition: L1TCSCTF.h:188
std::string const & label() const
Definition: InputTag.h:43
MonitorElement * csc_wire_MEplus42
Definition: L1TCSCTF.h:151
MonitorElement * trackModeVsQ
Definition: L1TCSCTF.h:104
MonitorElement * me11_lctGblEta
Definition: L1TCSCTF.h:116
gbletadat globalEtaME(int phi_bend, int phi_local, int wire_group, int cscid, const bool gangedME1a=false) const
std::vector< L1MuGMTReadoutRecord > const & getRecords() const
MonitorElement * csc_strip_MEminus21
Definition: L1TCSCTF.h:136
MonitorElement * csctfoccupancies_H
Definition: L1TCSCTF.h:84
MonitorElement * csc_strip_MEplus32
Definition: L1TCSCTF.h:129
MonitorElement * csc_strip_MEplus12
Definition: L1TCSCTF.h:124
static unsigned int const shift
void setPhiPacked(const unsigned &phi_)
Definition: TrackStub.h:33
CSCSectorReceiverLUT * srLUTs_[5][2][6]
Definition: L1TCSCTF.h:180
std::pair< const_iterator, const_iterator > Range
const L1MuTriggerPtScale * tpts
Definition: L1TCSCTF.h:183
MonitorElement * me11_lctLocalPhi
Definition: L1TCSCTF.h:113
MonitorElement * csc_strip_MEminus11
Definition: L1TCSCTF.h:133
MonitorElement * csc_strip_MEminus13
Definition: L1TCSCTF.h:135
unsigned long long m_ptScaleCacheID
Definition: L1TCSCTF.h:185
MonitorElement * csc_wire_MEplus11
Definition: L1TCSCTF.h:143
tuple status
Definition: ntuplemaker.py:245
TH2F * getTH2F(void) const
MonitorElement * csc_wire_MEminus12
Definition: L1TCSCTF.h:154
class global_eta_data gbletadat
void setAxisTitle(const std::string &title, int axis=1)
set x-, y- or z-axis title (axis=1, 2, 3 respectively)
MonitorElement * csc_strip_MEplus42
Definition: L1TCSCTF.h:131
std::string const & instance() const
Definition: InputTag.h:44
edm::EDGetTokenT< CSCTriggerContainer< csctf::TrackStub > > dtStubsToken_
Definition: L1TCSCTF.h:192
edm::InputTag gmtProducer
Definition: L1TCSCTF.h:177
void setEtaPacked(const unsigned &eta_)
set Eta and Phi from integer values.
Definition: TrackStub.h:32
MonitorElement * me11_lctPackedPhi
Definition: L1TCSCTF.h:114
MonitorElement * csc_wire_MEplus22
Definition: L1TCSCTF.h:147
MonitorElement * csc_wire_MEminus11
Definition: L1TCSCTF.h:153
Definition: Run.h:43