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HGCalShowerSeparation Class Reference
Inheritance diagram for HGCalShowerSeparation:
one::DQMEDAnalyzer< T > one::dqmimplementation::DQMBaseClass< T... >

Public Member Functions

 HGCalShowerSeparation (const edm::ParameterSet &)
 
 ~HGCalShowerSeparation () override
 
- Public Member Functions inherited from one::DQMEDAnalyzer< T >
 DQMEDAnalyzer ()=default
 
 DQMEDAnalyzer (DQMEDAnalyzer< T... > const &)=delete
 
 DQMEDAnalyzer (DQMEDAnalyzer< T... > &&)=delete
 
 ~DQMEDAnalyzer () override=default
 

Static Public Member Functions

static void fillDescriptions (edm::ConfigurationDescriptions &descriptions)
 

Private Member Functions

void analyze (const edm::Event &, const edm::EventSetup &) override
 
void bookHistograms (DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override
 
void fillWithRecHits (std::map< DetId, const HGCRecHit * > &, DetId, unsigned int, float, int &, float &)
 

Private Attributes

edm::EDGetTokenT< std::vector< CaloParticle > > caloParticles_
 
std::vector< MonitorElement * > centers_
 
int debug_
 
MonitorElementdeltaEtaPhi_
 
std::vector< MonitorElement * > distanceOnLayer_
 
MonitorElementenergy1_
 
MonitorElementenergy2_
 
MonitorElementenergytot_
 
MonitorElementeta1_
 
MonitorElementeta2_
 
MonitorElementetaPhi_
 
bool filterOnEnergyAndCaloP_
 
std::vector< MonitorElement * > globalProfileOnLayer_
 
std::vector< MonitorElement * > idealDeltaXY_
 
std::vector< MonitorElement * > idealDistanceOnLayer_
 
MonitorElementlayerDistance_
 
MonitorElementlayerEnergy_
 
std::vector< MonitorElement * > profileOnLayer_
 
edm::EDGetTokenT< HGCRecHitCollectionrecHitsBH_
 
edm::EDGetTokenT< HGCRecHitCollectionrecHitsEE_
 
edm::EDGetTokenT< HGCRecHitCollectionrecHitsFH_
 
hgcal::RecHitTools recHitTools_
 
MonitorElementscEnergy_
 
MonitorElementshowerProfile_
 

Static Private Attributes

static int layers_ = 52
 

Detailed Description

Definition at line 43 of file HGCalShowerSeparation.cc.

Constructor & Destructor Documentation

HGCalShowerSeparation::HGCalShowerSeparation ( const edm::ParameterSet iConfig)
explicit

Definition at line 88 of file HGCalShowerSeparation.cc.

References caloTruthProducer_cfi::caloParticles, caloParticles_, edm::ParameterSet::getParameter(), recHitsBH_, EcalDeadCellBoundaryEnergyFilter_cfi::recHitsEE, recHitsEE_, and recHitsFH_.

89  : debug_(iConfig.getParameter<int>("debug")),
90  filterOnEnergyAndCaloP_(iConfig.getParameter<bool>("filterOnEnergyAndCaloP")){
91  auto recHitsEE = iConfig.getParameter<edm::InputTag>("recHitsEE");
92  auto recHitsFH = iConfig.getParameter<edm::InputTag>("recHitsFH");
93  auto recHitsBH = iConfig.getParameter<edm::InputTag>("recHitsBH");
94  auto caloParticles = iConfig.getParameter<edm::InputTag>("caloParticles");
95  recHitsEE_ = consumes<HGCRecHitCollection>(recHitsEE);
96  recHitsFH_ = consumes<HGCRecHitCollection>(recHitsFH);
97  recHitsBH_ = consumes<HGCRecHitCollection>(recHitsBH);
98  caloParticles_ = consumes<std::vector<CaloParticle> >(caloParticles);
99 }
edm::EDGetTokenT< HGCRecHitCollection > recHitsEE_
T getParameter(std::string const &) const
edm::EDGetTokenT< HGCRecHitCollection > recHitsFH_
edm::EDGetTokenT< HGCRecHitCollection > recHitsBH_
edm::EDGetTokenT< std::vector< CaloParticle > > caloParticles_
HGCalShowerSeparation::~HGCalShowerSeparation ( )
override

Definition at line 101 of file HGCalShowerSeparation.cc.

101  {
102  // do anything here that needs to be done at desctruction time
103  // (e.g. close files, deallocate resources etc.)
104 }

Member Function Documentation

void HGCalShowerSeparation::analyze ( const edm::Event iEvent,
const edm::EventSetup iSetup 
)
overrideprivate

Definition at line 164 of file HGCalShowerSeparation.cc.

References funct::abs(), caloTruthProducer_cfi::caloParticles, caloParticles_, centers_, funct::cos(), KineDebug3::count(), debug_, deltaEtaPhi_, SoftLeptonByDistance_cfi::distance, distanceOnLayer_, randomXiThetaGunProducer_cfi::energy, SimCluster::energy(), energy1_, energy2_, energytot_, eta1_, eta2_, etaPhi_, JetChargeProducer_cfi::exp, MonitorElement::Fill(), filterOnEnergyAndCaloP_, edm::Event::getByToken(), hgcal::RecHitTools::getEventSetup(), hgcal::RecHitTools::getLayerWithOffset(), hgcal::RecHitTools::getPosition(), globalProfileOnLayer_, SimCluster::hits_and_fractions(), mps_fire::i, idealDeltaXY_, idealDistanceOnLayer_, IfLogTrace, layerDistance_, layerEnergy_, or, profileOnLayer_, recHitsBH_, recHitsEE_, recHitsFH_, recHitTools_, scEnergy_, showerProfile_, SimCluster::simEnergy(), funct::sin(), edm::RefVector< C, T, F >::size(), findQualityFiles::size, mathSSE::sqrt(), funct::tan(), PV3DBase< T, PVType, FrameType >::x(), globals_cff::x1, and globals_cff::x2.

165  {
166  using namespace edm;
167 
168  recHitTools_.getEventSetup(iSetup);
169 
170  Handle<HGCRecHitCollection> recHitHandleEE;
171  Handle<HGCRecHitCollection> recHitHandleFH;
172  Handle<HGCRecHitCollection> recHitHandleBH;
173 
174  Handle<std::vector<CaloParticle> > caloParticleHandle;
175  iEvent.getByToken(caloParticles_, caloParticleHandle);
176  const std::vector<CaloParticle>& caloParticles = *caloParticleHandle;
177 
178 
179  iEvent.getByToken(recHitsEE_, recHitHandleEE);
180  iEvent.getByToken(recHitsFH_, recHitHandleFH);
181  iEvent.getByToken(recHitsBH_, recHitHandleBH);
182  const auto& rechitsEE = *recHitHandleEE;
183  const auto& rechitsFH = *recHitHandleFH;
184  const auto& rechitsBH = *recHitHandleBH;
185 
186  std::map<DetId, const HGCRecHit*> hitmap;
187  for (unsigned int i = 0; i < rechitsEE.size(); ++i) {
188  hitmap[rechitsEE[i].detid()] = &rechitsEE[i];
189  }
190  for (unsigned int i = 0; i < rechitsFH.size(); ++i) {
191  hitmap[rechitsFH[i].detid()] = &rechitsFH[i];
192  }
193  for (unsigned int i = 0; i < rechitsBH.size(); ++i) {
194  hitmap[rechitsBH[i].detid()] = &rechitsBH[i];
195  }
196 
197  // loop over caloParticles
198  IfLogTrace(debug_ > 0, "HGCalShowerSeparation")
199  << "Number of caloParticles: " << caloParticles.size() << std::endl;
200  if (caloParticles.size() == 2) {
201  auto eta1 = caloParticles[0].eta();
202  auto phi1 = caloParticles[0].phi();
203  auto theta1 = 2.*atan(exp(-eta1));
204  auto eta2 = caloParticles[1].eta();
205  auto phi2 = caloParticles[1].phi();
206  auto theta2 = 2.*atan(exp(-eta2));
207  eta1_->Fill(eta1);
208  eta2_->Fill(eta2);
209 
210 
211  // Select event only if the sum of the energy of its recHits
212  // is close enough to the gen energy
213  int count = 0;
214  int size = 0;
215  float energy = 0.;
216  float energy_tmp = 0.;
217  for (const auto& it_caloPart : caloParticles) {
218  count++;
219  const SimClusterRefVector& simClusterRefVector = it_caloPart.simClusters();
220  size += simClusterRefVector.size();
221  for (const auto& it_sc : simClusterRefVector) {
222  const SimCluster& simCluster = (*(it_sc));
223  const std::vector<std::pair<uint32_t, float> >& hits_and_fractions =
224  simCluster.hits_and_fractions();
225  for (const auto& it_haf : hits_and_fractions) {
226  if (hitmap.count(it_haf.first))
227  energy += hitmap[it_haf.first]->energy()*it_haf.second;
228  } //hits and fractions
229  } // simcluster
230  if (count == 1) {
231  energy1_->Fill(energy);
232  energy_tmp = energy;
233  } else {
234  energy2_->Fill(energy-energy_tmp);
235  }
236  } // caloParticle
237  energytot_->Fill(energy);
238  if (filterOnEnergyAndCaloP_ && (energy < 2.*0.8*80 or size !=2))
239  return;
240 
241  deltaEtaPhi_->Fill(eta1-eta2, phi1-phi2);
242 
243  for (const auto& it_caloPart : caloParticles) {
244  const SimClusterRefVector& simClusterRefVector = it_caloPart.simClusters();
245  IfLogTrace(debug_ > 0, "HGCalShowerSeparation")
246  << ">>> " << simClusterRefVector.size() << std::endl;
247  for (const auto& it_sc : simClusterRefVector) {
248  const SimCluster& simCluster = (*(it_sc));
249  if (simCluster.energy() < 80*0.8)
250  continue;
251  scEnergy_->Fill(simCluster.energy());
252  IfLogTrace(debug_ > 1, "HGCalShowerSeparation")
253  << ">>> SC.energy(): " << simCluster.energy()
254  << " SC.simEnergy(): " << simCluster.simEnergy()
255  << std::endl;
256  const std::vector<std::pair<uint32_t, float> >& hits_and_fractions =
257  simCluster.hits_and_fractions();
258 
259  for (const auto& it_haf : hits_and_fractions) {
260  if (!hitmap.count(it_haf.first))
261  continue;
262  unsigned int hitlayer = recHitTools_.getLayerWithOffset(it_haf.first);
263  auto global = recHitTools_.getPosition(it_haf.first);
264  float globalx = global.x();
265  float globaly = global.y();
266  float globalz = global.z();
267  if (globalz == 0)
268  continue;
269  auto rho1 = globalz*tan(theta1);
270  auto rho2 = globalz*tan(theta2);
271  auto x1 = rho1*cos(phi1);
272  auto y1 = rho1*sin(phi1);
273  auto x2 = rho2*cos(phi2);
274  auto y2 = rho2*sin(phi2);
275  auto half_point_x = (x1+x2)/2.;
276  auto half_point_y = (y1+y2)/2.;
277  auto half_point = sqrt((x1-half_point_x)*(x1-half_point_x)+(y1-half_point_y)*(y1-half_point_y));
278  auto d_len = sqrt((x2-x1)*(x2-x1)+(y2-y1)*(y2-y1));
279  auto dn_x = (x2-x1)/d_len;
280  auto dn_y = (y2-y1)/d_len;
281  auto distance = (globalx-x1)*dn_x + (globaly - y1)*dn_y;
282  distance -= half_point;
283  auto idealDistance = sqrt((x1-x2)*(x1-x2) + (y1-y2)*(y1-y2));
284  if (hitmap.count(it_haf.first)) {
285  profileOnLayer_[hitlayer]->Fill(10.*(globalx-half_point_x),
286  10.*(globaly-half_point_y),
287  hitmap[it_haf.first]->energy()*it_haf.second);
288  profileOnLayer_[55]->Fill(10.*(globalx-half_point_x),
289  10.*(globaly-half_point_y),
290  hitmap[it_haf.first]->energy()*it_haf.second);
291  globalProfileOnLayer_[hitlayer]->Fill(globalx,
292  globaly,
293  hitmap[it_haf.first]->energy()*it_haf.second);
294  globalProfileOnLayer_[55]->Fill(globalx,
295  globaly,
296  hitmap[it_haf.first]->energy()*it_haf.second);
297  layerEnergy_->Fill(hitlayer, hitmap[it_haf.first]->energy());
298  layerDistance_->Fill(hitlayer, std::abs(10.*distance), hitmap[it_haf.first]->energy()*it_haf.second);
299  etaPhi_->Fill(global.eta(), global.phi());
300  distanceOnLayer_[hitlayer]->Fill(10.*distance);//,
301  idealDistanceOnLayer_[hitlayer]->Fill(10.*idealDistance);//,
302  idealDeltaXY_[hitlayer]->Fill(10.*(x1-x2), 10.*(y1-y2));//,
303  centers_[hitlayer]->Fill(10.*half_point_x, 10.*half_point_y);//,
304  IfLogTrace(debug_ > 0, "HGCalShowerSeparation")
305  << ">>> " << distance
306  << " " << hitlayer
307  << " " << hitmap[it_haf.first]->energy()*it_haf.second
308  << std::endl;
310  hitlayer,
311  hitmap[it_haf.first]->energy()*it_haf.second);
312  }
313  } // end simHit
314  } // end simCluster
315  } // end caloparticle
316  }
317 }
size
Write out results.
edm::EDGetTokenT< HGCRecHitCollection > recHitsEE_
edm::EDGetTokenT< HGCRecHitCollection > recHitsFH_
bool getByToken(EDGetToken token, Handle< PROD > &result) const
Definition: Event.h:517
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
std::vector< MonitorElement * > globalProfileOnLayer_
#define IfLogTrace(cond, cat)
std::vector< MonitorElement * > idealDeltaXY_
std::vector< MonitorElement * > profileOnLayer_
void getEventSetup(const edm::EventSetup &)
Definition: RecHitTools.cc:73
void Fill(long long x)
edm::EDGetTokenT< HGCRecHitCollection > recHitsBH_
Monte Carlo truth information used for tracking validation.
Definition: SimCluster.h:29
T sqrt(T t)
Definition: SSEVec.h:18
edm::EDGetTokenT< std::vector< CaloParticle > > caloParticles_
The Signals That Services Can Subscribe To This is based on ActivityRegistry and is current per Services can connect to the signals distributed by the ActivityRegistry in order to monitor the activity of the application Each possible callback has some defined which we here list in angle e< void, edm::EventID const &, edm::Timestamp const & > We also list in braces which AR_WATCH_USING_METHOD_ is used for those or
Definition: Activities.doc:12
std::vector< MonitorElement * > distanceOnLayer_
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
Tan< T >::type tan(const T &t)
Definition: Tan.h:22
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
float energy() const
Energy. Note this is taken from the first SimTrack only.
Definition: SimCluster.h:104
float simEnergy() const
returns the accumulated sim energy in the cluster
Definition: SimCluster.h:196
hgcal::RecHitTools recHitTools_
unsigned int getLayerWithOffset(const DetId &) const
Definition: RecHitTools.cc:283
MonitorElement * layerDistance_
GlobalPoint getPosition(const DetId &id) const
Definition: RecHitTools.cc:112
HLT enums.
std::vector< MonitorElement * > centers_
size_type size() const
Size of the RefVector.
Definition: RefVector.h:107
std::vector< MonitorElement * > idealDistanceOnLayer_
T x() const
Definition: PV3DBase.h:62
MonitorElement * showerProfile_
std::vector< std::pair< uint32_t, float > > hits_and_fractions() const
Returns list of rechit IDs and fractions for this SimCluster.
Definition: SimCluster.h:181
void HGCalShowerSeparation::bookHistograms ( DQMStore::IBooker ibooker,
edm::Run const &  iRun,
edm::EventSetup const &   
)
overrideprivate

Definition at line 106 of file HGCalShowerSeparation.cc.

References DQMStore::IBooker::book1D(), DQMStore::IBooker::book2D(), DQMStore::IBooker::cd(), centers_, deltaEtaPhi_, distanceOnLayer_, energy1_, energy2_, energytot_, eta1_, eta2_, etaPhi_, globalProfileOnLayer_, mps_fire::i, idealDeltaXY_, idealDistanceOnLayer_, layerDistance_, layerEnergy_, layers_, profileOnLayer_, scEnergy_, DQMStore::IBooker::setCurrentFolder(), showerProfile_, and AlCaHLTBitMon_QueryRunRegistry::string.

108  {
109  ibooker.cd();
110  ibooker.setCurrentFolder("HGCalShowerSeparation");
111  scEnergy_ = ibooker.book1D("SCEnergy", "SCEnergy", 240, 0., 120.);
112  eta1_ = ibooker.book1D("eta1", "eta1", 80, 0., 4.);
113  eta2_ = ibooker.book1D("eta2", "eta2", 80, 0., 4.);
114  energy1_ = ibooker.book1D("energy1", "energy1", 240, 0., 120.);
115  energy2_ = ibooker.book1D("energy2", "energy2", 240, 0., 120.);
116  energytot_ = ibooker.book1D("energytot", "energytot", 200, 100., 200.);
117  showerProfile_ = ibooker.book2D("ShowerProfile", "ShowerProfile",
118  800, -400., 400.,
119  layers_, 0., (float)layers_);
120  layerEnergy_ = ibooker.book2D("LayerEnergy", "LayerEnergy",
121  60, 0., 60.,
122  50, 0., 0.1);
123  layerDistance_ = ibooker.book2D("LayerDistance", "LayerDistance",
124  60, 0., 60.,
125  400, -400., 400.);
126  etaPhi_ = ibooker.book2D("EtaPhi", "EtaPhi",
127  800, -4., 4.,
128  800, -4., 4.);
129  deltaEtaPhi_ = ibooker.book2D("DeltaEtaPhi", "DeltaEtaPhi",
130  100, -0.5, 0.5,
131  100, -0.5, 0.5);
132  for (int i = 0; i < layers_; ++i) {
133  profileOnLayer_.push_back(ibooker.book2D(std::string("ProfileOnLayer_") + std::to_string(i),
134  std::string("ProfileOnLayer_") + std::to_string(i),
135  120, -600., 600.,
136  120, -600., 600.)
137  );
138  globalProfileOnLayer_.push_back(ibooker.book2D(std::string("GlobalProfileOnLayer_") + std::to_string(i),
139  std::string("GlobalProfileOnLayer_") + std::to_string(i),
140  320, -160., 160.,
141  320, -160., 160.)
142  );
143  distanceOnLayer_.push_back(ibooker.book1D(std::string("DistanceOnLayer_") + std::to_string(i),
144  std::string("DistanceOnLayer_") + std::to_string(i),
145  120, -600., 600.)
146  );
147  idealDistanceOnLayer_.push_back(ibooker.book1D(std::string("IdealDistanceOnLayer_") + std::to_string(i),
148  std::string("IdealDistanceOnLayer_") + std::to_string(i),
149  120, -600., 600.)
150  );
151  idealDeltaXY_.push_back(ibooker.book2D(std::string("IdealDeltaXY_") + std::to_string(i),
152  std::string("IdealDeltaXY_") + std::to_string(i),
153  800, -400., 400.,
154  800, -400., 400.)
155  );
156  centers_.push_back(ibooker.book2D(std::string("Centers_") + std::to_string(i),
157  std::string("Centers_") + std::to_string(i),
158  320, -1600., 1600.,
159  320, -1600., 1600.)
160  );
161  }
162 }
std::vector< MonitorElement * > globalProfileOnLayer_
std::vector< MonitorElement * > idealDeltaXY_
std::vector< MonitorElement * > profileOnLayer_
void setCurrentFolder(std::string const &fullpath)
Definition: DQMStore.cc:268
std::vector< MonitorElement * > distanceOnLayer_
MonitorElement * book1D(Args &&...args)
Definition: DQMStore.h:106
MonitorElement * book2D(Args &&...args)
Definition: DQMStore.h:109
MonitorElement * layerDistance_
std::vector< MonitorElement * > centers_
std::vector< MonitorElement * > idealDistanceOnLayer_
MonitorElement * showerProfile_
void HGCalShowerSeparation::fillDescriptions ( edm::ConfigurationDescriptions descriptions)
static

Definition at line 321 of file HGCalShowerSeparation.cc.

References edm::ConfigurationDescriptions::add(), edm::ParameterSetDescription::add(), and DEFINE_FWK_MODULE.

322  {
324  desc.add<int>("debug", 1);
325  desc.add<bool>("filterOnEnergyAndCaloP", false);
326  desc.add<edm::InputTag>("caloParticles", edm::InputTag("mix", "MergedCaloTruth"));
327  desc.add<edm::InputTag>("recHitsEE", edm::InputTag("HGCalRecHit", "HGCEERecHits"));
328  desc.add<edm::InputTag>("recHitsFH", edm::InputTag("HGCalRecHit", "HGCHEFRecHits"));
329  desc.add<edm::InputTag>("recHitsBH", edm::InputTag("HGCalRecHit", "HGCHEBRecHits"));
330  descriptions.add("hgcalShowerSeparationDefault", desc);
331 }
ParameterDescriptionBase * add(U const &iLabel, T const &value)
void add(std::string const &label, ParameterSetDescription const &psetDescription)
void HGCalShowerSeparation::fillWithRecHits ( std::map< DetId, const HGCRecHit * > &  ,
DetId  ,
unsigned  int,
float  ,
int &  ,
float &   
)
private

Member Data Documentation

edm::EDGetTokenT<std::vector<CaloParticle> > HGCalShowerSeparation::caloParticles_
private

Definition at line 61 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and HGCalShowerSeparation().

std::vector<MonitorElement*> HGCalShowerSeparation::centers_
private

Definition at line 83 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

int HGCalShowerSeparation::debug_
private

Definition at line 63 of file HGCalShowerSeparation.cc.

Referenced by analyze().

MonitorElement* HGCalShowerSeparation::deltaEtaPhi_
private

Definition at line 77 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

std::vector<MonitorElement*> HGCalShowerSeparation::distanceOnLayer_
private

Definition at line 80 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

MonitorElement* HGCalShowerSeparation::energy1_
private

Definition at line 69 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

MonitorElement* HGCalShowerSeparation::energy2_
private

Definition at line 70 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

MonitorElement* HGCalShowerSeparation::energytot_
private

Definition at line 71 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

MonitorElement* HGCalShowerSeparation::eta1_
private

Definition at line 67 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

MonitorElement* HGCalShowerSeparation::eta2_
private

Definition at line 68 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

MonitorElement* HGCalShowerSeparation::etaPhi_
private

Definition at line 76 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

bool HGCalShowerSeparation::filterOnEnergyAndCaloP_
private

Definition at line 64 of file HGCalShowerSeparation.cc.

Referenced by analyze().

std::vector<MonitorElement*> HGCalShowerSeparation::globalProfileOnLayer_
private

Definition at line 79 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

std::vector<MonitorElement*> HGCalShowerSeparation::idealDeltaXY_
private

Definition at line 82 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

std::vector<MonitorElement*> HGCalShowerSeparation::idealDistanceOnLayer_
private

Definition at line 81 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

MonitorElement* HGCalShowerSeparation::layerDistance_
private

Definition at line 75 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

MonitorElement* HGCalShowerSeparation::layerEnergy_
private

Definition at line 74 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

int HGCalShowerSeparation::layers_ = 52
staticprivate

Definition at line 85 of file HGCalShowerSeparation.cc.

Referenced by bookHistograms().

std::vector<MonitorElement*> HGCalShowerSeparation::profileOnLayer_
private

Definition at line 78 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

edm::EDGetTokenT<HGCRecHitCollection> HGCalShowerSeparation::recHitsBH_
private

Definition at line 60 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and HGCalShowerSeparation().

edm::EDGetTokenT<HGCRecHitCollection> HGCalShowerSeparation::recHitsEE_
private

Definition at line 58 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and HGCalShowerSeparation().

edm::EDGetTokenT<HGCRecHitCollection> HGCalShowerSeparation::recHitsFH_
private

Definition at line 59 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and HGCalShowerSeparation().

hgcal::RecHitTools HGCalShowerSeparation::recHitTools_
private

Definition at line 65 of file HGCalShowerSeparation.cc.

Referenced by analyze().

MonitorElement* HGCalShowerSeparation::scEnergy_
private

Definition at line 72 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().

MonitorElement* HGCalShowerSeparation::showerProfile_
private

Definition at line 73 of file HGCalShowerSeparation.cc.

Referenced by analyze(), and bookHistograms().