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L3MuonProducer.cc
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1 
11 // Framework
18 
20 
21 // TrackFinder and specific GLB Trajectory Builder
27 
28 
29 using namespace edm;
30 using namespace std;
31 
32 //
33 // constructor with config
34 //
36 
37  LogTrace("L3MuonProducer") << "constructor called" << endl;
38 
39  // Parameter set for the Builder
40  ParameterSet trajectoryBuilderParameters = parameterSet.getParameter<ParameterSet>("L3TrajBuilderParameters");
41 
42  // L2 Muon Collection Label
43  theL2CollectionLabel = parameterSet.getParameter<InputTag>("MuonCollectionLabel");
44  l2MuonToken_ = consumes<reco::TrackCollection>(theL2CollectionLabel);
45  l2MuonTrajToken_ = consumes<std::vector<Trajectory> >(theL2CollectionLabel.label());
46  l2AssoMapToken_ = consumes<TrajTrackAssociationCollection>(theL2CollectionLabel.label());
47  updatedL2AssoMapToken_ = consumes<reco::TrackToTrackMap>(theL2CollectionLabel.label());
48 
49  // service parameters
50  ParameterSet serviceParameters = parameterSet.getParameter<ParameterSet>("ServiceParameters");
51 
52  // TrackLoader parameters
53  ParameterSet trackLoaderParameters = parameterSet.getParameter<ParameterSet>("TrackLoaderParameters");
54 
55  // the services
56  theService = new MuonServiceProxy(serviceParameters);
57  ConsumesCollector iC = consumesCollector();
58 
59  // instantiate the concrete trajectory builder in the Track Finder
60  MuonTrackLoader* mtl = new MuonTrackLoader(trackLoaderParameters,iC,theService);
61  L3MuonTrajectoryBuilder* l3mtb = new L3MuonTrajectoryBuilder(trajectoryBuilderParameters, theService,iC);
62  theTrackFinder = new MuonTrackFinder(l3mtb, mtl);
63 
64  theL2SeededTkLabel = trackLoaderParameters.getUntrackedParameter<std::string>("MuonSeededTracksInstance",std::string());
65 
66  produces<reco::TrackCollection>(theL2SeededTkLabel);
67  produces<TrackingRecHitCollection>(theL2SeededTkLabel);
68  produces<reco::TrackExtraCollection>(theL2SeededTkLabel);
69  produces<vector<Trajectory> >(theL2SeededTkLabel) ;
70  produces<TrajTrackAssociationCollection>(theL2SeededTkLabel);
71 
72  produces<reco::TrackCollection>();
73  produces<TrackingRecHitCollection>();
74  produces<reco::TrackExtraCollection>();
75  produces<vector<Trajectory> >() ;
76  produces<TrajTrackAssociationCollection>();
77 
78  produces<reco::MuonTrackLinksCollection>();
79 
80 }
81 
82 
83 //
84 // destructor
85 //
87 
88  LogTrace("L3MuonProducer") << "destructor called" << endl;
89  if (theService) delete theService;
90  if (theTrackFinder) delete theTrackFinder;
91 
92 }
93 
94 
95 //
96 // reconstruct muons
97 //
98 void L3MuonProducer::produce(Event& event, const EventSetup& eventSetup) {
99  const string metname = "Muon|RecoMuon|L3MuonProducer";
100  LogTrace(metname)<<endl<<endl<<endl;
101  LogTrace(metname)<<"L3 Muon Reconstruction started"<<endl;
102 
103  typedef vector<Trajectory> TrajColl;
104 
105  // Update the services
106  theService->update(eventSetup);
107 
108  // Take the L2 muon container(s)
109  LogTrace(metname)<<"Taking the L2 Muons "<<theL2CollectionLabel<<endl;
110 
111 
113  event.getByToken(l2MuonToken_,L2Muons);
114 
115  Handle<vector<Trajectory> > L2MuonsTraj;
116  vector<MuonTrajectoryBuilder::TrackCand> L2TrackCands;
117 
118 
119  event.getByToken(l2MuonTrajToken_, L2MuonsTraj);
120 
122  event.getByToken(l2AssoMapToken_,L2AssoMap);
123 
124  edm::Handle<reco::TrackToTrackMap> updatedL2AssoMap;
125  event.getByToken(updatedL2AssoMapToken_,updatedL2AssoMap);
126 
127 
128 
129  for(TrajTrackAssociationCollection::const_iterator it = L2AssoMap->begin(); it != L2AssoMap->end(); ++it){
130  const Ref<vector<Trajectory> > traj = it->key;
131  const reco::TrackRef tkRegular = it->val;
132  reco::TrackRef tkUpdated;
135  if ( theL2CollectionLabel.instance() == "UpdatedAtVtx") {
136  iEnd = updatedL2AssoMap->end();
137  iii = updatedL2AssoMap->find(it->val);
138  if (iii != iEnd ) tkUpdated = (*updatedL2AssoMap)[it->val] ;
139  }
140 
141  const reco::TrackRef tk = ( tkUpdated.isNonnull() ) ? tkUpdated : tkRegular ;
142 
144  if( traj->isValid() ) L2Cand.first = &*traj ;
145  L2TrackCands.push_back(L2Cand);
146  }
147 
148  theTrackFinder->reconstruct(L2TrackCands, event, eventSetup);
149 
150  LogTrace(metname)<<"Event loaded"
151  <<"================================"
152  <<endl<<endl;
153 
154 }
155 
158  {
160  psd0.addUntracked<std::vector<std::string>>("Propagators", {
161  "hltESPSmartPropagatorAny",
162  "SteppingHelixPropagatorAny",
163  "hltESPSmartPropagator",
164  "hltESPSteppingHelixPropagatorOpposite",
165  });
166  psd0.add<bool>("RPCLayers", true);
167  psd0.addUntracked<bool>("UseMuonNavigation", true);
168  desc.add<edm::ParameterSetDescription>("ServiceParameters", psd0);
169  }
170  desc.add<edm::InputTag>("MuonCollectionLabel", edm::InputTag("hltL2Muons","UpdatedAtVtx"));
171  {
173  psd0.addUntracked<bool>("PutTkTrackIntoEvent", false);
174  psd0.add<std::string>("TTRHBuilder", "hltESPTTRHBWithTrackAngle");
175  psd0.add<edm::InputTag>("beamSpot", edm::InputTag("hltOnlineBeamSpot"));
176  psd0.addUntracked<bool>("SmoothTkTrack", false);
177  psd0.addUntracked<std::string>("MuonSeededTracksInstance", "L2Seeded");
178  psd0.add<std::string>("Smoother", "hltESPKFTrajectorySmootherForMuonTrackLoader");
179  {
181  psd1.add<double>("MaxChi2", 1000000.0);
182  psd1.add<std::string>("Propagator", "hltESPSteppingHelixPropagatorOpposite");
183  psd1.add<std::vector<double>>("BeamSpotPositionErrors", {
184  0.1,
185  0.1,
186  5.3,
187  });
188  psd0.add<edm::ParameterSetDescription>("MuonUpdatorAtVertexParameters", psd1);
189  }
190  psd0.add<bool>("VertexConstraint", false);
191  psd0.add<bool>("DoSmoothing", false);
192  desc.add<edm::ParameterSetDescription>("TrackLoaderParameters", psd0);
193  }
194  {
196  psd0.add<double>("ScaleTECyFactor", -1.0);
197  psd0.add<edm::InputTag>("tkTrajVertex", edm::InputTag("hltPixelVertices"));
198  psd0.add<bool>("tkTrajUseVertex", false);
199  {
201  psd1.add<int>("TrackerSkipSection", -1);
202  psd1.add<bool>("DoPredictionsOnly", false);
203  psd1.add<bool>("PropDirForCosmics", false);
204  psd1.add<int>("HitThreshold", 1);
205  psd1.add<int>("MuonHitsOption", 1);
206  psd1.add<bool>("RefitFlag", true);
207  psd1.add<std::string>("Fitter", "hltESPL3MuKFTrajectoryFitter");
208  psd1.add<int>("SkipStation", -1);
209  psd1.add<std::string>("TrackerRecHitBuilder", "hltESPTTRHBWithTrackAngle");
210  psd1.add<double>("Chi2CutRPC", 1.0);
211  psd1.add<std::string>("MuonRecHitBuilder", "hltESPMuonTransientTrackingRecHitBuilder");
212  psd1.add<std::string>("RefitDirection", "insideOut");
213  psd1.add<edm::InputTag>("CSCRecSegmentLabel", edm::InputTag("hltCscSegments"));
214  psd1.add<edm::InputTag>("GEMRecHitLabel", edm::InputTag("gemRecHits"));
215  psd1.add<edm::InputTag>("ME0RecHitLabel", edm::InputTag("me0Segments"));
216  psd1.add<std::vector<int>>("DYTthrs", {
217  30,
218  15,
219  });
220  psd1.add<double>("Chi2CutCSC", 150.0);
221  psd1.add<double>("Chi2CutDT", 10.0);
222  psd1.add<double>("Chi2CutGEM", 1.0);
223  psd1.add<double>("Chi2CutME0", 1.0);
224  psd1.add<bool>("RefitRPCHits", true);
225  psd1.add<edm::InputTag>("DTRecSegmentLabel", edm::InputTag("hltDt4DSegments"));
226  psd1.add<std::string>("Propagator", "hltESPSmartPropagatorAny");
227  psd1.add<int>("TrackerSkipSystem", -1);
228  psd0.add<edm::ParameterSetDescription>("GlbRefitterParameters", psd1);
229  }
230  psd0.add<double>("tkTrajMaxChi2", 9999.0);
231  psd0.add<double>("ScaleTECxFactor", -1.0);
232  psd0.add<std::string>("TrackerRecHitBuilder", "hltESPTTRHBWithTrackAngle");
233  psd0.add<edm::InputTag>("tkTrajBeamSpot", edm::InputTag("hltOnlineBeamSpot"));
234  psd0.add<std::string>("MuonRecHitBuilder", "hltESPMuonTransientTrackingRecHitBuilder");
235  psd0.add<double>("tkTrajMaxDXYBeamSpot", 9999.0);
236  psd0.add<std::string>("TrackerPropagator", "SteppingHelixPropagatorAny");
237  {
239  psd1.add<bool>("precise", true);
240  psd1.add<bool>("Eta_fixed", true);
241  psd1.add<double>("Eta_min", 0.1);
242  psd1.add<bool>("Z_fixed", false);
243  psd1.add<edm::InputTag>("MeasurementTrackerName", edm::InputTag("hltESPMeasurementTracker"));
244  psd1.add<int>("maxRegions", 2);
245  psd1.add<double>("Pt_min", 3.0);
246  psd1.add<double>("Rescale_Dz", 4.0);
247  psd1.add<double>("PhiR_UpperLimit_Par1", 0.6);
248  psd1.add<double>("PhiR_UpperLimit_Par2", 0.2);
249  psd1.add<edm::InputTag>("vertexCollection", edm::InputTag("pixelVertices"));
250  psd1.add<bool>("Phi_fixed", true);
251  psd1.add<edm::InputTag>("input", edm::InputTag("hltL2Muons","UpdatedAtVtx"));
252  psd1.add<double>("DeltaR", 0.025);
253  psd1.add<int>("OnDemand", -1);
254  psd1.add<double>("DeltaZ", 24.2);
255  psd1.add<double>("Rescale_phi", 3.0);
256  psd1.add<double>("Rescale_eta", 3.0);
257  psd1.add<double>("DeltaEta", 0.04);
258  psd1.add<double>("DeltaPhi", 0.15);
259  psd1.add<double>("Phi_min", 0.1);
260  psd1.add<bool>("UseVertex", false);
261  psd1.add<double>("EtaR_UpperLimit_Par1", 0.25);
262  psd1.add<double>("EtaR_UpperLimit_Par2", 0.15);
263  psd1.add<edm::InputTag>("beamSpot", edm::InputTag("hltOnlineBeamSpot"));
264  psd1.add<double>("EscapePt", 3.0);
265  psd1.add<bool>("Pt_fixed", false);
266  psd0.add<edm::ParameterSetDescription>("MuonTrackingRegionBuilder", psd1);
267  }
268  psd0.add<bool>("RefitRPCHits", true);
269  psd0.add<double>("PCut", 2.5);
270  {
272  psd1.add<bool>("DoPredictionsOnly", false);
273  psd1.add<std::string>("Fitter", "hltESPL3MuKFTrajectoryFitter");
274  psd1.add<std::string>("TrackerRecHitBuilder", "hltESPTTRHBWithTrackAngle");
275  psd1.add<std::string>("Smoother", "hltESPKFTrajectorySmootherForMuonTrackLoader");
276  psd1.add<std::string>("MuonRecHitBuilder", "hltESPMuonTransientTrackingRecHitBuilder");
277  psd1.add<std::string>("RefitDirection", "insideOut");
278  psd1.add<bool>("RefitRPCHits", true);
279  psd1.add<std::string>("Propagator", "hltESPSmartPropagatorAny");
280  psd0.add<edm::ParameterSetDescription>("TrackTransformer", psd1);
281  }
282  {
284  psd1.add<double>("Quality_3", 7.0);
285  psd1.add<double>("DeltaRCut_1", 0.1);
286  psd1.add<double>("MinP", 2.5);
287  psd1.add<double>("MinPt", 1.0);
288  psd1.add<double>("Quality_2", 15.0);
289  psd1.add<double>("Pt_threshold2", 999999999.0);
290  psd1.add<double>("LocChi2Cut", 0.001);
291  psd1.add<double>("Eta_threshold", 1.2);
292  psd1.add<double>("Pt_threshold1", 0.0);
293  psd1.add<double>("Chi2Cut_1", 50.0);
294  psd1.add<double>("Quality_1", 20.0);
295  psd1.add<double>("Chi2Cut_3", 200.0);
296  psd1.add<double>("DeltaRCut_3", 1.0);
297  psd1.add<double>("DeltaRCut_2", 0.2);
298  psd1.add<double>("DeltaDCut_1", 40.0);
299  psd1.add<double>("DeltaDCut_2", 10.0);
300  psd1.add<double>("DeltaDCut_3", 15.0);
301  psd1.add<double>("Chi2Cut_2", 50.0);
302  psd1.add<std::string>("Propagator", "hltESPSmartPropagator");
303  psd0.add<edm::ParameterSetDescription>("GlobalMuonTrackMatcher", psd1);
304  }
305  psd0.add<double>("PtCut", 1.0);
306  psd0.add<bool>("matchToSeeds", true);
307  psd0.add<edm::InputTag>("tkTrajLabel", edm::InputTag("hltBRSMuonSeededTracksOutIn"));
308  desc.add<edm::ParameterSetDescription>("L3TrajBuilderParameters", psd0);
309  }
310  descriptions.add("L3MuonProducer", desc);
311 }
T getParameter(std::string const &) const
bool isNonnull() const
Checks for non-null.
Definition: Ref.h:252
ParameterDescriptionBase * addUntracked(U const &iLabel, T const &value)
std::pair< const Trajectory *, reco::TrackRef > TrackCand
const std::string metname
key_type key() const
Accessor for product key.
Definition: Ref.h:264
tuple L2Muons
Definition: L2Muons_cfi.py:6
virtual ~L3MuonProducer()
destructor
ParameterDescriptionBase * add(U const &iLabel, T const &value)
How EventSelector::AcceptEvent() decides whether to accept an event for output otherwise it is excluding the probing of A single or multiple positive and the trigger will pass if any such matching triggers are PASS or EXCEPTION[A criterion thatmatches no triggers at all is detected and causes a throw.] A single negative with an expectation of appropriate bit checking in the decision and the trigger will pass if any such matching triggers are FAIL or EXCEPTION A wildcarded negative criterion that matches more than one trigger in the trigger but the state exists so we define the behavior If all triggers are the negative crieriion will lead to accepting the event(this again matches the behavior of"!*"before the partial wildcard feature was incorporated).The per-event"cost"of each negative criterion with multiple relevant triggers is about the same as!*was in the past
#define LogTrace(id)
L3MuonProducer(const edm::ParameterSet &)
constructor with config
void add(std::string const &label, ParameterSetDescription const &psetDescription)
static void fillDescriptions(edm::ConfigurationDescriptions &descriptions)
virtual void produce(edm::Event &, const edm::EventSetup &)
reconstruct muons
ParameterSet const & parameterSet(Provenance const &provenance)
Definition: Provenance.cc:11