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OccupancyClient.cc
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10 
11 namespace ecaldqm {
12  OccupancyClient::OccupancyClient() : DQWorkerClient(), minHits_(0), deviationThreshold_(0.) {
13  qualitySummaries_.insert("QualitySummary");
14  }
15 
17  minHits_ = _params.getUntrackedParameter<int>("minHits");
18  deviationThreshold_ = _params.getUntrackedParameter<double>("deviationThreshold");
19  }
20 
22  using namespace std;
23 
24  // number of allowed ieta indices
25  // EE-: -28 to -1 with -27, -25 empty
26  // EE+: 1 to 28 with 26, 28 empty
27  unsigned const nPhiRings(56);
28 
29  MESet& meQualitySummary(MEs_.at("QualitySummary"));
30  // MESet& meHotDigi(MEs_.at("HotDigi"));
31  // MESet& meHotRecHitThr(MEs_.at("HotRecHitThr"));
32  // MESet& meHotTPDigiThr(MEs_.at("HotTPDigiThr"));
33 
34  MESet const& sDigi(sources_.at("DigiAll"));
35  MESet const& sRecHitThr(sources_.at("RecHitThrAll"));
36  MESet const& sTPDigiThr(sources_.at("TPDigiThrAll"));
37 
41 
42  double digiPhiRingMean[nPhiRings];
43  std::fill_n(digiPhiRingMean, nPhiRings, 0.);
44  double rechitPhiRingMean[nPhiRings];
45  std::fill_n(rechitPhiRingMean, nPhiRings, 0.);
46  int numCrystals[nPhiRings]; // this is static, but is easier to count now
47  std::fill_n(numCrystals, nPhiRings, 0);
48 
49  MESet::const_iterator dEnd(sDigi.end(GetElectronicsMap()));
50  MESet::const_iterator rItr(GetElectronicsMap(), sRecHitThr);
51  for (MESet::const_iterator dItr(sDigi.beginChannel(GetElectronicsMap())); dItr != dEnd;
53  rItr = dItr;
54 
55  float entries(dItr->getBinContent());
56  float rhentries(rItr->getBinContent());
57 
58  DetId id(dItr->getId());
59  int ieta(0);
60  if (id.subdetId() == EcalTriggerTower) // barrel
62  else {
63  std::vector<DetId> ids(scConstituents(EcalScDetId(id)));
64  if (ids.empty())
65  continue;
66  ieta = GetTrigTowerMap()->towerOf(ids[0]).ieta();
67  }
68 
69  unsigned index(ieta < 0 ? ieta + 28 : ieta + 27);
70 
71  digiPhiRingMean[index] += entries;
72  rechitPhiRingMean[index] += rhentries;
73  numCrystals[index] += 1;
74  }
75 
76  for (unsigned ie(0); ie < nPhiRings; ie++) {
77  digiPhiRingMean[ie] /= numCrystals[ie];
78  rechitPhiRingMean[ie] /= numCrystals[ie];
79  }
80 
81  // Store # of entries for Occupancy analysis
82  std::vector<float> Nentries(nDCC, 0.); // digis
83  std::vector<float> Nrhentries(nDCC, 0.); // (filtered) rechits
84 
85  // second round to find hot towers
86  for (MESet::const_iterator dItr(sDigi.beginChannel(GetElectronicsMap())); dItr != dEnd;
88  DetId id(dItr->getId());
89 
90  bool doMask(meQualitySummary.maskMatches(id, mask, statusManager_, GetTrigTowerMap()));
91 
92  rItr = dItr;
93 
94  float entries(dItr->getBinContent());
95  float rhentries(rItr->getBinContent());
96 
97  int ieta(0);
98  if (id.subdetId() == EcalTriggerTower) // barrel
100  else {
101  std::vector<DetId> ids(scConstituents(EcalScDetId(id)));
102  if (ids.empty())
103  continue;
104  ieta = GetTrigTowerMap()->towerOf(ids[0]).ieta();
105  }
106 
107  unsigned index(ieta < 0 ? ieta + 28 : ieta + 27);
108 
109  int quality(doMask ? kMGood : kGood);
110 
111  if (entries > minHits_ && entries > digiPhiRingMean[index] * deviationThreshold_) {
112  // meHotDigi->fill(id);
113  quality = doMask ? kMBad : kBad;
114  }
115  if (rhentries > minHits_ && rhentries > rechitPhiRingMean[index] * deviationThreshold_) {
116  // meHotRecHitThr->fill(id);
117  quality = doMask ? kMBad : kBad;
118  }
119 
120  meQualitySummary.setBinContent(getEcalDQMSetupObjects(), id, double(quality));
121 
122  // Keep count of digis & rechits for Occupancy analysis
123  unsigned iDCC(dccId(id, GetElectronicsMap()) - 1);
124  if (entries > minHits_)
125  Nentries[iDCC] += entries;
126  if (rhentries > minHits_)
127  Nrhentries[iDCC] += rhentries;
128  }
129 
130  double tpdigiPhiRingMean[nPhiRings];
131  std::fill_n(tpdigiPhiRingMean, nPhiRings, 0.);
132 
133  for (unsigned iTT(0); iTT < EcalTrigTowerDetId::kSizeForDenseIndexing; ++iTT) {
135  float entries(sTPDigiThr.getBinContent(getEcalDQMSetupObjects(), ttid));
136 
137  unsigned index(ttid.ieta() < 0 ? ttid.ieta() + 28 : ttid.ieta() + 27);
138 
139  tpdigiPhiRingMean[index] += entries;
140  }
141 
142  for (int ie(0); ie < 28; ie++) {
143  float denom(-1.);
144  if (ie < 27)
145  denom = 72.;
146  else
147  denom = 36.;
148  tpdigiPhiRingMean[ie] /= denom;
149  tpdigiPhiRingMean[55 - ie] /= denom;
150  }
151 
152  for (unsigned iTT(0); iTT < EcalTrigTowerDetId::kSizeForDenseIndexing; ++iTT) {
154 
155  float entries(sTPDigiThr.getBinContent(getEcalDQMSetupObjects(), ttid));
156 
157  unsigned index(ttid.ieta() < 0 ? ttid.ieta() + 28 : ttid.ieta() + 27);
158 
159  int quality(kGood);
160 
161  if (entries > minHits_ && entries > tpdigiPhiRingMean[index] * deviationThreshold_) {
162  // meHotTPDigiThr.fill(ttid);
163  quality = kBad;
164  }
165 
166  if (quality != kBad)
167  continue;
168 
169  std::vector<DetId> ids(GetTrigTowerMap()->constituentsOf(ttid));
170  for (unsigned iD(0); iD < ids.size(); ++iD) {
171  DetId& id(ids[iD]);
172 
173  int quality(meQualitySummary.getBinContent(getEcalDQMSetupObjects(), id));
174  if (quality == kMBad || quality == kBad)
175  continue;
176 
177  meQualitySummary.setBinContent(
179  id,
180  meQualitySummary.maskMatches(id, mask, statusManager_, GetTrigTowerMap()) ? kMBad : kBad);
181  }
182  }
183 
184  // Quality check: set entire FED to BAD if its occupancy begins to vanish
185  // Fill FED statistics from (filtered) RecHit Occupancy
186  float meanFEDEB(0), meanFEDEE(0), rmsFEDEB(0), rmsFEDEE(0);
187  unsigned int nFEDEB(0), nFEDEE(0);
188  for (unsigned iDCC(0); iDCC < nDCC; iDCC++) {
189  if (iDCC >= kEBmLow && iDCC <= kEBpHigh) {
190  meanFEDEB += Nrhentries[iDCC];
191  rmsFEDEB += Nrhentries[iDCC] * Nrhentries[iDCC];
192  nFEDEB++;
193  } else {
194  meanFEDEE += Nrhentries[iDCC];
195  rmsFEDEE += Nrhentries[iDCC] * Nrhentries[iDCC];
196  nFEDEE++;
197  }
198  }
199  meanFEDEB /= float(nFEDEB);
200  rmsFEDEB /= float(nFEDEB);
201  meanFEDEE /= float(nFEDEE);
202  rmsFEDEE /= float(nFEDEE);
203  rmsFEDEB = sqrt(abs(rmsFEDEB - meanFEDEB * meanFEDEB));
204  rmsFEDEE = sqrt(abs(rmsFEDEE - meanFEDEE * meanFEDEE));
205  // Analyze FED statistics
206  float meanFED(0.), rmsFED(0.), nRMS(5.);
207  for (MESet::iterator qsItr(meQualitySummary.beginChannel(GetElectronicsMap()));
208  qsItr != meQualitySummary.end(GetElectronicsMap());
209  qsItr.toNextChannel(GetElectronicsMap())) {
210  DetId id(qsItr->getId());
211  unsigned iDCC(dccId(id, GetElectronicsMap()) - 1);
212  if (iDCC >= kEBmLow && iDCC <= kEBpHigh) {
213  meanFED = meanFEDEB;
214  rmsFED = rmsFEDEB;
215  } else {
216  meanFED = meanFEDEE;
217  rmsFED = rmsFEDEE;
218  }
219  float threshold(meanFED < nRMS * rmsFED ? minHits_ : meanFED - nRMS * rmsFED);
220  if (meanFED > 1000. && Nrhentries[iDCC] < threshold)
221  meQualitySummary.setBinContent(
223  id,
224  meQualitySummary.maskMatches(id, mask, statusManager_, GetTrigTowerMap()) ? kMBad : kBad);
225  }
226 
227  } // producePlots()
228 
230 } // namespace ecaldqm
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