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HGCalShowerSeparation.cc
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1 // user include files
2 
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29 
35 
37 
38 #include <map>
39 #include <array>
40 #include <string>
41 #include <numeric>
42 
44 public:
46  ~HGCalShowerSeparation() override;
47 
48  static void fillDescriptions(edm::ConfigurationDescriptions& descriptions);
49 
50 private:
51  void bookHistograms(DQMStore::IBooker&, edm::Run const&, edm::EventSetup const&) override;
52  void analyze(const edm::Event&, const edm::EventSetup&) override;
53 
54  void fillWithRecHits(std::unordered_map<DetId, const HGCRecHit*>&, DetId, unsigned int, float, int&, float&);
55 
58 
59  int debug_;
62 
74  std::vector<MonitorElement*> profileOnLayer_;
75  std::vector<MonitorElement*> globalProfileOnLayer_;
76  std::vector<MonitorElement*> distanceOnLayer_;
77  std::vector<MonitorElement*> idealDistanceOnLayer_;
78  std::vector<MonitorElement*> idealDeltaXY_;
79  std::vector<MonitorElement*> centers_;
80 
81  static constexpr int layers_ = 52;
82 };
83 
85  : debug_(iConfig.getParameter<int>("debug")),
86  filterOnEnergyAndCaloP_(iConfig.getParameter<bool>("filterOnEnergyAndCaloP")) {
87  auto hitMapInputTag = iConfig.getParameter<edm::InputTag>("hitMapTag");
88  auto caloParticles = iConfig.getParameter<edm::InputTag>("caloParticles");
89  hitMap_ = consumes<std::unordered_map<DetId, const HGCRecHit*>>(hitMapInputTag);
90  caloParticles_ = consumes<std::vector<CaloParticle>>(caloParticles);
91 }
92 
94  // do anything here that needs to be done at desctruction time
95  // (e.g. close files, deallocate resources etc.)
96 }
97 
99  edm::Run const& iRun,
100  edm::EventSetup const& /* iSetup */) {
101  ibooker.cd();
102  ibooker.setCurrentFolder("HGCalShowerSeparation");
103  scEnergy_ = ibooker.book1D("SCEnergy", "SCEnergy", 240, 0., 120.);
104  eta1_ = ibooker.book1D("eta1", "eta1", 80, 0., 4.);
105  eta2_ = ibooker.book1D("eta2", "eta2", 80, 0., 4.);
106  energy1_ = ibooker.book1D("energy1", "energy1", 240, 0., 120.);
107  energy2_ = ibooker.book1D("energy2", "energy2", 240, 0., 120.);
108  energytot_ = ibooker.book1D("energytot", "energytot", 200, 100., 200.);
109  showerProfile_ = ibooker.book2D("ShowerProfile", "ShowerProfile", 800, -400., 400., layers_, 0., (float)layers_);
110  layerEnergy_ = ibooker.book2D("LayerEnergy", "LayerEnergy", 60, 0., 60., 50, 0., 0.1);
111  layerDistance_ = ibooker.book2D("LayerDistance", "LayerDistance", 60, 0., 60., 400, -400., 400.);
112  etaPhi_ = ibooker.book2D("EtaPhi", "EtaPhi", 800, -4., 4., 800, -4., 4.);
113  deltaEtaPhi_ = ibooker.book2D("DeltaEtaPhi", "DeltaEtaPhi", 100, -0.5, 0.5, 100, -0.5, 0.5);
114  for (int i = 0; i < layers_; ++i) {
115  profileOnLayer_.push_back(ibooker.book2D(std::string("ProfileOnLayer_") + std::to_string(i),
116  std::string("ProfileOnLayer_") + std::to_string(i),
117  120,
118  -600.,
119  600.,
120  120,
121  -600.,
122  600.));
123  globalProfileOnLayer_.push_back(ibooker.book2D(std::string("GlobalProfileOnLayer_") + std::to_string(i),
124  std::string("GlobalProfileOnLayer_") + std::to_string(i),
125  320,
126  -160.,
127  160.,
128  320,
129  -160.,
130  160.));
131  distanceOnLayer_.push_back(ibooker.book1D(std::string("DistanceOnLayer_") + std::to_string(i),
132  std::string("DistanceOnLayer_") + std::to_string(i),
133  120,
134  -600.,
135  600.));
136  idealDistanceOnLayer_.push_back(ibooker.book1D(std::string("IdealDistanceOnLayer_") + std::to_string(i),
137  std::string("IdealDistanceOnLayer_") + std::to_string(i),
138  120,
139  -600.,
140  600.));
141  idealDeltaXY_.push_back(ibooker.book2D(std::string("IdealDeltaXY_") + std::to_string(i),
142  std::string("IdealDeltaXY_") + std::to_string(i),
143  800,
144  -400.,
145  400.,
146  800,
147  -400.,
148  400.));
149  centers_.push_back(ibooker.book2D(std::string("Centers_") + std::to_string(i),
150  std::string("Centers_") + std::to_string(i),
151  320,
152  -1600.,
153  1600.,
154  320,
155  -1600.,
156  1600.));
157  }
158 }
159 
161  using namespace edm;
162 
164  iSetup.get<CaloGeometryRecord>().get(geom);
166 
167  Handle<std::vector<CaloParticle>> caloParticleHandle;
168  iEvent.getByToken(caloParticles_, caloParticleHandle);
169  const std::vector<CaloParticle>& caloParticles = *caloParticleHandle;
170 
172  iEvent.getByToken(hitMap_, hitMapHandle);
173  const auto hitmap = *hitMapHandle;
174 
175  // loop over caloParticles
176  IfLogTrace(debug_ > 0, "HGCalShowerSeparation") << "Number of caloParticles: " << caloParticles.size() << std::endl;
177  if (caloParticles.size() == 2) {
178  auto eta1 = caloParticles[0].eta();
179  auto phi1 = caloParticles[0].phi();
180  auto theta1 = 2. * atan(exp(-eta1));
181  auto eta2 = caloParticles[1].eta();
182  auto phi2 = caloParticles[1].phi();
183  auto theta2 = 2. * atan(exp(-eta2));
184  eta1_->Fill(eta1);
185  eta2_->Fill(eta2);
186 
187  // Select event only if the sum of the energy of its recHits
188  // is close enough to the gen energy
189  int count = 0;
190  int size = 0;
191  float energy = 0.;
192  float energy_tmp = 0.;
193  for (const auto& it_caloPart : caloParticles) {
194  count++;
195  const SimClusterRefVector& simClusterRefVector = it_caloPart.simClusters();
196  size += simClusterRefVector.size();
197  for (const auto& it_sc : simClusterRefVector) {
198  const SimCluster& simCluster = (*(it_sc));
199  const std::vector<std::pair<uint32_t, float>>& hits_and_fractions = simCluster.hits_and_fractions();
200  for (const auto& it_haf : hits_and_fractions) {
201  if (hitmap.count(it_haf.first))
202  energy += hitmap.at(it_haf.first)->energy() * it_haf.second;
203  } //hits and fractions
204  } // simcluster
205  if (count == 1) {
206  energy1_->Fill(energy);
207  energy_tmp = energy;
208  } else {
209  energy2_->Fill(energy - energy_tmp);
210  }
211  } // caloParticle
213  if (filterOnEnergyAndCaloP_ && (energy < 2. * 0.8 * 80 or size != 2))
214  return;
215 
216  deltaEtaPhi_->Fill(eta1 - eta2, phi1 - phi2);
217 
218  for (const auto& it_caloPart : caloParticles) {
219  const SimClusterRefVector& simClusterRefVector = it_caloPart.simClusters();
220  IfLogTrace(debug_ > 0, "HGCalShowerSeparation") << ">>> " << simClusterRefVector.size() << std::endl;
221  for (const auto& it_sc : simClusterRefVector) {
222  const SimCluster& simCluster = (*(it_sc));
223  if (simCluster.energy() < 80 * 0.8)
224  continue;
225  scEnergy_->Fill(simCluster.energy());
226  IfLogTrace(debug_ > 1, "HGCalShowerSeparation")
227  << ">>> SC.energy(): " << simCluster.energy() << " SC.simEnergy(): " << simCluster.simEnergy() << std::endl;
228  const std::vector<std::pair<uint32_t, float>>& hits_and_fractions = simCluster.hits_and_fractions();
229 
230  for (const auto& it_haf : hits_and_fractions) {
231  if (!hitmap.count(it_haf.first))
232  continue;
233  unsigned int hitlayer = recHitTools_.getLayerWithOffset(it_haf.first);
234  auto global = recHitTools_.getPosition(it_haf.first);
235  float globalx = global.x();
236  float globaly = global.y();
237  float globalz = global.z();
238  if (globalz == 0)
239  continue;
240  auto rho1 = globalz * tan(theta1);
241  auto rho2 = globalz * tan(theta2);
242  auto x1 = rho1 * cos(phi1);
243  auto y1 = rho1 * sin(phi1);
244  auto x2 = rho2 * cos(phi2);
245  auto y2 = rho2 * sin(phi2);
246  auto half_point_x = (x1 + x2) / 2.;
247  auto half_point_y = (y1 + y2) / 2.;
248  auto half_point = sqrt((x1 - half_point_x) * (x1 - half_point_x) + (y1 - half_point_y) * (y1 - half_point_y));
249  auto d_len = sqrt((x2 - x1) * (x2 - x1) + (y2 - y1) * (y2 - y1));
250  auto dn_x = (x2 - x1) / d_len;
251  auto dn_y = (y2 - y1) / d_len;
252  auto distance = (globalx - x1) * dn_x + (globaly - y1) * dn_y;
253  distance -= half_point;
254  auto idealDistance = sqrt((x1 - x2) * (x1 - x2) + (y1 - y2) * (y1 - y2));
255  if (hitmap.count(it_haf.first)) {
256  profileOnLayer_[hitlayer]->Fill(10. * (globalx - half_point_x),
257  10. * (globaly - half_point_y),
258  hitmap.at(it_haf.first)->energy() * it_haf.second);
259  profileOnLayer_[55]->Fill(10. * (globalx - half_point_x),
260  10. * (globaly - half_point_y),
261  hitmap.at(it_haf.first)->energy() * it_haf.second);
262  globalProfileOnLayer_[hitlayer]->Fill(globalx, globaly, hitmap.at(it_haf.first)->energy() * it_haf.second);
263  globalProfileOnLayer_[55]->Fill(globalx, globaly, hitmap.at(it_haf.first)->energy() * it_haf.second);
264  layerEnergy_->Fill(hitlayer, hitmap.at(it_haf.first)->energy());
265  layerDistance_->Fill(hitlayer, std::abs(10. * distance), hitmap.at(it_haf.first)->energy() * it_haf.second);
266  etaPhi_->Fill(global.eta(), global.phi());
267  distanceOnLayer_[hitlayer]->Fill(10. * distance); //,
268  idealDistanceOnLayer_[hitlayer]->Fill(10. * idealDistance); //,
269  idealDeltaXY_[hitlayer]->Fill(10. * (x1 - x2), 10. * (y1 - y2)); //,
270  centers_[hitlayer]->Fill(10. * half_point_x, 10. * half_point_y); //,
271  IfLogTrace(debug_ > 0, "HGCalShowerSeparation")
272  << ">>> " << distance << " " << hitlayer << " " << hitmap.at(it_haf.first)->energy() * it_haf.second
273  << std::endl;
274  showerProfile_->Fill(10. * distance, hitlayer, hitmap.at(it_haf.first)->energy() * it_haf.second);
275  }
276  } // end simHit
277  } // end simCluster
278  } // end caloparticle
279  }
280 }
281 
282 // ------------ method fills 'descriptions' with the allowed parameters for the
283 // module ------------
286  desc.add<int>("debug", 1);
287  desc.add<bool>("filterOnEnergyAndCaloP", false);
288  desc.add<edm::InputTag>("caloParticles", edm::InputTag("mix", "MergedCaloTruth"));
289  desc.add<edm::InputTag>("hitMapTag", edm::InputTag("hgcalRecHitMapProducer"));
290  descriptions.add("hgcalShowerSeparationDefault", desc);
291 }
292 
293 // define this as a plug-in
HGCalShowerSeparation::energy1_
MonitorElement * energy1_
Definition: HGCalShowerSeparation.cc:65
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Definition: MonitorElement.h:98
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Definition: RecHitTools.h:23
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Definition: HGCalShowerSeparation.cc:69
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Definition: CaloGeometryRecord.h:30
HGCalShowerSeparation::idealDeltaXY_
std::vector< MonitorElement * > idealDeltaXY_
Definition: HGCalShowerSeparation.cc:78
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HGCalShowerSeparation::distanceOnLayer_
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Definition: HGCalShowerSeparation.cc:76
HGCalShowerSeparation::centers_
std::vector< MonitorElement * > centers_
Definition: HGCalShowerSeparation.cc:79
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float energy() const
Energy. Note this is taken from the first SimTrack only.
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Definition: SimCluster.h:29
HGCalShowerSeparation::hitMap_
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Definition: HGCalShowerSeparation.cc:56
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Definition: HGCalShowerSeparation.cc:60
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static void fillDescriptions(edm::ConfigurationDescriptions &descriptions)
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T getParameter(std::string const &) const
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Definition: HGCalShowerSeparation.cc:75
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int debug_
Definition: HGCalShowerSeparation.cc:59
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Definition: findQualityFiles.py:443