CMS 3D CMS Logo

/data/refman/pasoursint/CMSSW_5_3_4/src/RecoEgamma/EgammaHLTProducers/src/EgammaHLTHybridClusterProducer.cc

Go to the documentation of this file.
00001 // C/C++ headers
00002 #include <iostream>
00003 #include <vector>
00004 #include <memory>
00005 
00006 // Framework
00007 #include "FWCore/Framework/interface/Event.h"
00008 #include "FWCore/Framework/interface/EventSetup.h"
00009 #include "DataFormats/Common/interface/Handle.h"
00010 #include "FWCore/MessageLogger/interface/MessageLogger.h"
00011 #include "FWCore/Framework/interface/ESHandle.h"
00012 #include "CommonTools/Utils/interface/StringToEnumValue.h"
00013 
00014 // Reconstruction Classes
00015 #include "DataFormats/EcalRecHit/interface/EcalRecHit.h"
00016 #include "DataFormats/EcalRecHit/interface/EcalRecHitCollections.h"
00017 #include "DataFormats/EcalDetId/interface/EBDetId.h"
00018 #include "DataFormats/EgammaReco/interface/BasicCluster.h"
00019 #include "DataFormats/EgammaReco/interface/SuperCluster.h"
00020 #include "DataFormats/EgammaReco/interface/BasicClusterFwd.h"
00021 #include "CondFormats/DataRecord/interface/EcalChannelStatusRcd.h"
00022 #include "CondFormats/EcalObjects/interface/EcalChannelStatus.h"
00023 #include "RecoLocalCalo/EcalRecAlgos/interface/EcalSeverityLevelAlgo.h"
00024 #include "RecoLocalCalo/EcalRecAlgos/interface/EcalSeverityLevelAlgoRcd.h"
00025 
00026 // Geometry
00027 #include "Geometry/Records/interface/CaloGeometryRecord.h"
00028 #include "Geometry/CaloGeometry/interface/CaloSubdetectorGeometry.h"
00029 #include "Geometry/CaloGeometry/interface/CaloCellGeometry.h"
00030 #include "Geometry/CaloGeometry/interface/CaloGeometry.h"
00031 #include "Geometry/CaloTopology/interface/EcalBarrelTopology.h"
00032 #include "Geometry/CaloTopology/interface/EcalEndcapTopology.h"
00033 #include "Geometry/CaloTopology/interface/EcalPreshowerTopology.h"
00034 
00035 
00036 // Level 1 Trigger
00037 #include "DataFormats/L1Trigger/interface/L1EmParticle.h"
00038 #include "DataFormats/L1Trigger/interface/L1EmParticleFwd.h"
00039 #include "CondFormats/L1TObjects/interface/L1CaloGeometry.h"
00040 #include "CondFormats/DataRecord/interface/L1CaloGeometryRecord.h"
00041 
00042 // EgammaCoreTools
00043 #include "RecoEcal/EgammaCoreTools/interface/PositionCalc.h"
00044 #include "RecoEcal/EgammaCoreTools/interface/EcalEtaPhiRegion.h"
00045 
00046 // Class header file
00047 #include "RecoEgamma/EgammaHLTProducers/interface/EgammaHLTHybridClusterProducer.h"
00048 
00049 
00050 EgammaHLTHybridClusterProducer::EgammaHLTHybridClusterProducer(const edm::ParameterSet& ps)
00051 {
00052 
00053 
00054   basicclusterCollection_ = ps.getParameter<std::string>("basicclusterCollection");
00055   superclusterCollection_ = ps.getParameter<std::string>("superclusterCollection");
00056   hitproducer_ = ps.getParameter<edm::InputTag>("ecalhitproducer");
00057   hitcollection_ =ps.getParameter<std::string>("ecalhitcollection");
00058 
00059 
00060 
00061   // L1 matching parameters
00062   l1TagIsolated_ = ps.getParameter< edm::InputTag > ("l1TagIsolated");
00063   l1TagNonIsolated_ = ps.getParameter< edm::InputTag > ("l1TagNonIsolated");
00064 
00065   doIsolated_   = ps.getParameter<bool>("doIsolated");
00066 
00067   l1LowerThr_ = ps.getParameter<double> ("l1LowerThr");
00068   l1UpperThr_ = ps.getParameter<double> ("l1UpperThr");
00069   l1LowerThrIgnoreIsolation_ = ps.getParameter<double> ("l1LowerThrIgnoreIsolation");
00070 
00071   regionEtaMargin_   = ps.getParameter<double>("regionEtaMargin");
00072   regionPhiMargin_   = ps.getParameter<double>("regionPhiMargin");
00073 
00074   // Parameters for the position calculation:
00075   posCalculator_ = PositionCalc( ps.getParameter<edm::ParameterSet>("posCalcParameters") );
00076   
00077   const std::vector<std::string> flagnames = 
00078     ps.getParameter<std::vector<std::string> >("RecHitFlagToBeExcluded");
00079 
00080   const std::vector<int> flagsexcl= 
00081     StringToEnumValue<EcalRecHit::Flags>(flagnames);
00082 
00083   const std::vector<std::string> severitynames = 
00084     ps.getParameter<std::vector<std::string> >("RecHitSeverityToBeExcluded");
00085    
00086   const std::vector<int> severitiesexcl= 
00087     StringToEnumValue<EcalSeverityLevel::SeverityLevel>(severitynames);
00088 
00089 
00090   hybrid_p = new HybridClusterAlgo(ps.getParameter<double>("HybridBarrelSeedThr"), 
00091                                    ps.getParameter<int>("step"),
00092                                    ps.getParameter<double>("ethresh"),
00093                                    ps.getParameter<double>("eseed"),
00094                                    ps.getParameter<double>("xi"),
00095                                    ps.getParameter<bool>("useEtForXi"),
00096                                    ps.getParameter<double>("ewing"),
00097                                    flagsexcl,
00098                                    posCalculator_,
00099                                    ps.getParameter<bool>("dynamicEThresh"),
00100                                    ps.getParameter<double>("eThreshA"),
00101                                    ps.getParameter<double>("eThreshB"),
00102                                    severitiesexcl,
00103                                    ps.getParameter<bool>("excludeFlagged")
00104                                    );
00105 
00106   bool dynamicPhiRoad = ps.getParameter<bool>("dynamicPhiRoad");
00107     if (dynamicPhiRoad) {
00108      edm::ParameterSet bremRecoveryPset = ps.getParameter<edm::ParameterSet>("bremRecoveryPset");
00109      hybrid_p->setDynamicPhiRoad(bremRecoveryPset);
00110   }
00111 
00112 
00113   produces< reco::BasicClusterCollection >(basicclusterCollection_);
00114   produces< reco::SuperClusterCollection >(superclusterCollection_);
00115   nEvt_ = 0;
00116 }
00117 
00118 
00119 EgammaHLTHybridClusterProducer::~EgammaHLTHybridClusterProducer()
00120 {
00121   delete hybrid_p;
00122 }
00123 
00124 
00125 void EgammaHLTHybridClusterProducer::produce(edm::Event& evt, const edm::EventSetup& es)
00126 {
00127   // get the hit collection from the event:
00128   edm::Handle<EcalRecHitCollection> rhcHandle;
00129   //  evt.getByType(rhcHandle);
00130   evt.getByLabel(hitproducer_.label(), hitcollection_, rhcHandle);
00131   if (!(rhcHandle.isValid())) 
00132     {
00133       edm::LogError("ProductNotFound")<< "could not get a handle on the EcalRecHitCollection!" << std::endl;
00134       return;
00135     }
00136   const EcalRecHitCollection *hit_collection = rhcHandle.product();
00137 
00138   // get the collection geometry:
00139   edm::ESHandle<CaloGeometry> geoHandle;
00140   es.get<CaloGeometryRecord>().get(geoHandle);
00141   const CaloGeometry& geometry = *geoHandle;
00142   const CaloSubdetectorGeometry *geometry_p;
00143   std::auto_ptr<const CaloSubdetectorTopology> topology;
00144 
00145   //edm::ESHandle<EcalChannelStatus> chStatus;
00146   //es.get<EcalChannelStatusRcd>().get(chStatus);
00147   //const EcalChannelStatus* theEcalChStatus = chStatus.product();
00148   
00149   edm::ESHandle<EcalSeverityLevelAlgo> sevlv;
00150   es.get<EcalSeverityLevelAlgoRcd>().get(sevlv);
00151   const EcalSeverityLevelAlgo* sevLevel = sevlv.product();
00152  
00153   if(hitcollection_ == "EcalRecHitsEB") {
00154     geometry_p = geometry.getSubdetectorGeometry(DetId::Ecal, EcalBarrel);
00155     topology.reset(new EcalBarrelTopology(geoHandle));
00156   } else if(hitcollection_ == "EcalRecHitsEE") {
00157     geometry_p = geometry.getSubdetectorGeometry(DetId::Ecal, EcalEndcap);
00158     topology.reset(new EcalEndcapTopology(geoHandle));
00159   } else if(hitcollection_ == "EcalRecHitsPS") {
00160     geometry_p = geometry.getSubdetectorGeometry(DetId::Ecal, EcalPreshower);
00161     topology.reset(new EcalPreshowerTopology (geoHandle));
00162   } else throw(std::runtime_error("\n\nHybrid Cluster Producer encountered invalied ecalhitcollection type.\n\n"));
00163     
00164   //Get the L1 EM Particle Collection
00165   //Get the L1 EM Particle Collection
00166   edm::Handle< l1extra::L1EmParticleCollection > emIsolColl ;
00167   if(doIsolated_)
00168     evt.getByLabel(l1TagIsolated_, emIsolColl);
00169   //Get the L1 EM Particle Collection
00170   edm::Handle< l1extra::L1EmParticleCollection > emNonIsolColl ;
00171   evt.getByLabel(l1TagNonIsolated_, emNonIsolColl);
00172 
00173   // Get the CaloGeometry
00174   edm::ESHandle<L1CaloGeometry> l1CaloGeom ;
00175   es.get<L1CaloGeometryRecord>().get(l1CaloGeom) ;
00176 
00177   std::vector<EcalEtaPhiRegion> regions;
00178 
00179   if(doIsolated_) {
00180     for( l1extra::L1EmParticleCollection::const_iterator emItr = emIsolColl->begin(); emItr != emIsolColl->end() ;++emItr ){
00181 
00182     if (emItr->et() > l1LowerThr_ && emItr->et() < l1UpperThr_
00183         //&&
00185 ) {
00186 
00187       //bool isolated = emItr->gctEmCand()->isolated();
00188       //if ((l1Isolated_ &&isolated) || (!l1Isolated_ &&!isolated)) {
00189 
00190       // Access the GCT hardware object corresponding to the L1Extra EM object.
00191       int etaIndex = emItr->gctEmCand()->etaIndex() ;
00192       int phiIndex = emItr->gctEmCand()->phiIndex() ;
00193       // Use the L1CaloGeometry to find the eta, phi bin boundaries.
00194       double etaLow  = l1CaloGeom->etaBinLowEdge( etaIndex ) ;
00195       double etaHigh = l1CaloGeom->etaBinHighEdge( etaIndex ) ;
00196       double phiLow  = l1CaloGeom->emJetPhiBinLowEdge( phiIndex ) ;
00197       double phiHigh = l1CaloGeom->emJetPhiBinHighEdge( phiIndex ) ;
00198 
00199        int isbarl=0;
00200        //Part of the region is in the barel if either the upper or lower
00201        //edge of the region is within the barrel
00202        if(((float)(etaLow)>-1.479 && (float)(etaLow)<1.479) || 
00203           ((float)(etaHigh)>-1.479 && (float)(etaHigh)<1.479)) isbarl=1;
00204 
00205 
00206       etaLow -= regionEtaMargin_;
00207       etaHigh += regionEtaMargin_;
00208       phiLow -= regionPhiMargin_;
00209       phiHigh += regionPhiMargin_;
00210 
00211       if (etaHigh>1.479) etaHigh=1.479;
00212       if (etaLow<-1.479) etaLow=-1.479;
00213 
00214       if(isbarl) regions.push_back(EcalEtaPhiRegion(etaLow,etaHigh,phiLow,phiHigh));
00215 
00216     }
00217   }
00218   }
00219 
00220   if(!doIsolated_||l1LowerThrIgnoreIsolation_<64) {
00221     for( l1extra::L1EmParticleCollection::const_iterator emItr = emNonIsolColl->begin(); emItr != emNonIsolColl->end() ;++emItr ){
00222 
00223       if(doIsolated_&&emItr->et()<l1LowerThrIgnoreIsolation_) continue;
00224 
00225     if (emItr->et() > l1LowerThr_ && emItr->et() < l1UpperThr_
00226         //&&
00228 ) {
00229 
00230       //bool isolated = emItr->gctEmCand()->isolated();
00231       //if ((l1Isolated_ &&isolated) || (!l1Isolated_ &&!isolated)) {
00232 
00233       // Access the GCT hardware object corresponding to the L1Extra EM object.
00234       int etaIndex = emItr->gctEmCand()->etaIndex() ;
00235       int phiIndex = emItr->gctEmCand()->phiIndex() ;
00236       // Use the L1CaloGeometry to find the eta, phi bin boundaries.
00237       double etaLow  = l1CaloGeom->etaBinLowEdge( etaIndex ) ;
00238       double etaHigh = l1CaloGeom->etaBinHighEdge( etaIndex ) ;
00239       double phiLow  = l1CaloGeom->emJetPhiBinLowEdge( phiIndex ) ;
00240       double phiHigh = l1CaloGeom->emJetPhiBinHighEdge( phiIndex ) ;
00241 
00242        int isbarl=0;
00243        //Part of the region is in the barel if either the upper or lower
00244        //edge of the region is within the barrel
00245        if(((float)(etaLow)>-1.479 && (float)(etaLow)<1.479) || 
00246           ((float)(etaHigh)>-1.479 && (float)(etaHigh)<1.479)) isbarl=1;
00247        
00248        
00249        etaLow -= regionEtaMargin_;
00250        etaHigh += regionEtaMargin_;
00251        phiLow -= regionPhiMargin_;
00252        phiHigh += regionPhiMargin_;
00253        
00254        if (etaHigh>1.479) etaHigh=1.479;
00255        if (etaLow<-1.479) etaLow=-1.479;
00256        
00257        if(isbarl) regions.push_back(EcalEtaPhiRegion(etaLow,etaHigh,phiLow,phiHigh));
00258        
00259     }
00260     }
00261   }
00262   
00263   // make the Basic clusters!
00264   reco::BasicClusterCollection basicClusters;
00265   hybrid_p->makeClusters(hit_collection, geometry_p, basicClusters, sevLevel, true, regions);
00266   
00267   // create an auto_ptr to a BasicClusterCollection, copy the clusters into it and put in the Event:
00268   std::auto_ptr< reco::BasicClusterCollection > basicclusters_p(new reco::BasicClusterCollection);
00269   basicclusters_p->assign(basicClusters.begin(), basicClusters.end());
00270   edm::OrphanHandle<reco::BasicClusterCollection> bccHandle =  evt.put(basicclusters_p, 
00271                                                                        basicclusterCollection_);
00272   //Basic clusters now in the event.
00273   
00274   //Weird though it is, get the BasicClusters back out of the event.  We need the
00275   //edm::Ref to these guys to make our superclusters for Hybrid.
00276 //  edm::Handle<reco::BasicClusterCollection> bccHandle;
00277  // evt.getByLabel("clusterproducer",basicclusterCollection_, bccHandle);
00278   if (!(bccHandle.isValid())) {
00279     return;
00280   }
00281   reco::BasicClusterCollection clusterCollection = *bccHandle;
00282 
00283   reco::CaloClusterPtrVector clusterRefVector;
00284   for (unsigned int i = 0; i < clusterCollection.size(); i++){
00285     clusterRefVector.push_back(reco::CaloClusterPtr(bccHandle, i));
00286   }
00287 
00288   reco::SuperClusterCollection superClusters = hybrid_p->makeSuperClusters(clusterRefVector);
00289 
00290   std::auto_ptr< reco::SuperClusterCollection > superclusters_p(new reco::SuperClusterCollection);
00291   superclusters_p->assign(superClusters.begin(), superClusters.end());
00292   evt.put(superclusters_p, superclusterCollection_);
00293 
00294 
00295   nEvt_++;
00296 }
00297