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Public Member Functions | Private Attributes

Pi0FixedMassWindowCalibration Class Reference

#include <Pi0FixedMassWindowCalibration.h>

Inheritance diagram for Pi0FixedMassWindowCalibration:
edm::ESProducerLooper edm::ESProducer edm::EventSetupRecordIntervalFinder edm::EDLooper edm::ESProxyFactoryProducer edm::EDLooperBase edm::eventsetup::DataProxyProvider

List of all members.

Public Member Functions

virtual void beginOfJob ()
 Called at beginning of job.
virtual Status duringLoop (const edm::Event &, const edm::EventSetup &)
 Called at each event.
virtual void endOfJob ()
 Called at end of job.
virtual Status endOfLoop (const edm::EventSetup &, unsigned int iLoop)
 Called at end of loop.
 Pi0FixedMassWindowCalibration (const edm::ParameterSet &iConfig)
 Constructor.
virtual void produce (edm::Event &, const edm::EventSetup &)
 Dummy implementation (job done in duringLoop)
virtual void startingNewLoop (unsigned int iLoop)
 Called at beginning of loop.
 ~Pi0FixedMassWindowCalibration ()
 Destructor.

Private Attributes

std::vector< DetIdbarrelCells
std::string barrelClusterCollection_
std::string barrelClusterShapeAssociation_
std::string barrelHitCollection_
std::string barrelHitProducer_
std::string barrelHits_
std::string clustershapecollectionEB_
std::string ecalHitsProducer_
const EcalRecHitCollectionecalRecHitBarrelCollection
bool isfirstcall_
IslandClusterAlgoisland_p
double mwxtals [85][360][2]
int nevent
double newCalibs_barl [85][360][2]
double oldCalibs_barl [85][360][2]
PositionCalc posCalculator_
const EcalRecHitCollectionrecalibEcalRecHitCollection
std::map< DetId, EcalRecHit > * recHitsEB_map
double selePi0DetaBelt_
double selePi0DRBelt_
double selePi0EtBeltIsoRatioMax_
double selePi0MinvMeanFixed_
double selePi0MinvSigmaFixed_
double selePi0PtGammaOneMin_
double selePi0PtGammaTwoMin_
double selePi0PtPi0Min_
double selePi0S4S9GammaOneMin_
double selePi0S4S9GammaTwoMin_
double selePi0S9S25GammaOneMin_
double selePi0S9S25GammaTwoMin_
ClusterShapeAlgo shapeAlgo_
TFile * theFile
unsigned int theMaxLoops
edm::ParameterSet theParameterSet
IslandClusterAlgo::VerbosityLevel verbosity
double wxtals [85][360][2]

Detailed Description

Definition at line 58 of file Pi0FixedMassWindowCalibration.h.


Constructor & Destructor Documentation

Pi0FixedMassWindowCalibration::Pi0FixedMassWindowCalibration ( const edm::ParameterSet iConfig)

Constructor.

Definition at line 34 of file Pi0FixedMassWindowCalibration.cc.

References barrelClusterCollection_, barrelClusterShapeAssociation_, clustershapecollectionEB_, gather_cfg::cout, edm::ParameterSet::getParameter(), island_p, IslandClusterAlgo::pDEBUG, IslandClusterAlgo::pERROR, IslandClusterAlgo::pINFO, posCalculator_, IslandClusterAlgo::pWARNING, selePi0DetaBelt_, selePi0DRBelt_, selePi0EtBeltIsoRatioMax_, selePi0MinvMeanFixed_, selePi0MinvSigmaFixed_, selePi0PtGammaOneMin_, selePi0PtGammaTwoMin_, selePi0PtPi0Min_, selePi0S4S9GammaOneMin_, selePi0S4S9GammaTwoMin_, selePi0S9S25GammaOneMin_, selePi0S9S25GammaTwoMin_, shapeAlgo_, AlCaHLTBitMon_QueryRunRegistry::string, theParameterSet, and verbosity.

                                                                                           :
  theMaxLoops( iConfig.getUntrackedParameter<unsigned int>("maxLoops",0) ),
  ecalHitsProducer_( iConfig.getParameter< std::string > ("ecalRecHitsProducer") ),
  barrelHits_( iConfig.getParameter< std::string > ("barrelHitCollection") )
{

  std::cout << "[Pi0FixedMassWindowCalibration] Constructor "<<std::endl;
  // The verbosity level
  std::string verbosityString = iConfig.getParameter<std::string>("VerbosityLevel");
  if      (verbosityString == "DEBUG")   verbosity = IslandClusterAlgo::pDEBUG;
  else if (verbosityString == "WARNING") verbosity = IslandClusterAlgo::pWARNING;
  else if (verbosityString == "INFO")    verbosity = IslandClusterAlgo::pINFO;
  else                                   verbosity = IslandClusterAlgo::pERROR;

  // The names of the produced cluster collections
  barrelClusterCollection_  = iConfig.getParameter<std::string>("barrelClusterCollection");

  // Island algorithm parameters
  double barrelSeedThreshold = iConfig.getParameter<double>("IslandBarrelSeedThr");
  double endcapSeedThreshold = iConfig.getParameter<double>("IslandEndcapSeedThr");


  // Selection algorithm parameters
  selePi0PtGammaOneMin_ = iConfig.getParameter<double>("selePi0PtGammaOneMin");
  selePi0PtGammaTwoMin_ = iConfig.getParameter<double>("selePi0PtGammaTwoMin");

  selePi0DRBelt_ = iConfig.getParameter<double>("selePi0DRBelt");
  selePi0DetaBelt_ = iConfig.getParameter<double>("selePi0DetaBelt");

  selePi0PtPi0Min_ = iConfig.getParameter<double>("selePi0PtPi0Min");

  selePi0S4S9GammaOneMin_ = iConfig.getParameter<double>("selePi0S4S9GammaOneMin");
  selePi0S4S9GammaTwoMin_ = iConfig.getParameter<double>("selePi0S4S9GammaTwoMin");
  selePi0S9S25GammaOneMin_ = iConfig.getParameter<double>("selePi0S9S25GammaOneMin");
  selePi0S9S25GammaTwoMin_ = iConfig.getParameter<double>("selePi0S9S25GammaTwoMin");
 
  selePi0EtBeltIsoRatioMax_ = iConfig.getParameter<double>("selePi0EtBeltIsoRatioMax");

  selePi0MinvMeanFixed_ = iConfig.getParameter<double>("selePi0MinvMeanFixed");
  selePi0MinvSigmaFixed_ = iConfig.getParameter<double>("selePi0MinvSigmaFixed");




  // Parameters for the position calculation:
  edm::ParameterSet posCalcParameters = 
    iConfig.getParameter<edm::ParameterSet>("posCalcParameters");
  posCalculator_ = PositionCalc(posCalcParameters); 
  shapeAlgo_ = ClusterShapeAlgo(posCalcParameters);
  clustershapecollectionEB_ = iConfig.getParameter<std::string>("clustershapecollectionEB");

  //AssociationMap
  barrelClusterShapeAssociation_ = iConfig.getParameter<std::string>("barrelShapeAssociation");

  island_p = new IslandClusterAlgo(barrelSeedThreshold, endcapSeedThreshold, posCalculator_,verbosity);

  theParameterSet=iConfig;


}
Pi0FixedMassWindowCalibration::~Pi0FixedMassWindowCalibration ( )

Destructor.

Definition at line 99 of file Pi0FixedMassWindowCalibration.cc.

{

}

Member Function Documentation

void Pi0FixedMassWindowCalibration::beginOfJob ( ) [virtual]

Called at beginning of job.

Reimplemented from edm::EDLooperBase.

Definition at line 107 of file Pi0FixedMassWindowCalibration.cc.

References isfirstcall_.

{

  //std::cout << "[Pi0FixedMassWindowCalibration] beginOfJob "<<std::endl;

  isfirstcall_=true;
  
 

}
edm::EDLooper::Status Pi0FixedMassWindowCalibration::duringLoop ( const edm::Event event,
const edm::EventSetup setup 
) [virtual]

Called at each event.

Implements edm::EDLooper.

Definition at line 218 of file Pi0FixedMassWindowCalibration.cc.

References abs, IslandClusterAlgo::barrel, barrelCells, barrelHits_, edm::SortedCollection< T, SORT >::begin(), ClusterShapeAlgo::Calculate(), calib, dtNoiseDBValidation_cfg::cerr, funct::cos(), gather_cfg::cout, DetId::Ecal, EcalBarrel, ecalHitsProducer_, EcalPreshower, ecalRecHitBarrelCollection, EcalCondObjectContainer< T >::end(), edm::SortedCollection< T, SORT >::end(), exception, create_public_lumi_plots::exp, EcalCondObjectContainer< T >::find(), geometry, edm::EventSetup::get(), CaloGeometry::getValidDetIds(), i, EBDetId::ieta(), EBDetId::iphi(), isfirstcall_, island_p, j, gen::k, edm::EDLooperBase::kContinue, create_public_lumi_plots::log, IslandClusterAlgo::makeClusters(), mwxtals, nevent, newCalibs_barl, oldCalibs_barl, edm::ESHandle< T >::product(), DetId::rawId(), recalibEcalRecHitCollection, recHitsEB_map, selePi0DetaBelt_, selePi0DRBelt_, selePi0EtBeltIsoRatioMax_, selePi0MinvMeanFixed_, selePi0MinvSigmaFixed_, selePi0PtGammaOneMin_, selePi0PtPi0Min_, selePi0S4S9GammaOneMin_, selePi0S4S9GammaTwoMin_, selePi0S9S25GammaOneMin_, selePi0S9S25GammaTwoMin_, shapeAlgo_, funct::sin(), EcalCondObjectContainer< T >::size(), edm::SortedCollection< T, SORT >::size(), mathSSE::sqrt(), AlCaHLTBitMon_QueryRunRegistry::string, funct::tan(), wxtals, and EBDetId::zside().

{
  using namespace edm;
  using namespace std;

  // this chunk used to belong to beginJob(isetup). Moved here
  // with the beginJob without arguments migration
  
  if (isfirstcall_){
   // initialize arrays

    for (int sign=0; sign<2; sign++) {
      for (int ieta=0; ieta<85; ieta++) {
        for (int iphi=0; iphi<360; iphi++) {
          oldCalibs_barl[ieta][iphi][sign]=0.;
          newCalibs_barl[ieta][iphi][sign]=0.;
          wxtals[ieta][iphi][sign]=0.;
          mwxtals[ieta][iphi][sign]=0.;
        }
      }
    }
    
    // get initial constants out of DB
    
    edm::ESHandle<EcalIntercalibConstants> pIcal;
    EcalIntercalibConstantMap imap;
    
    try {
      setup.get<EcalIntercalibConstantsRcd>().get(pIcal);
      std::cout << "Taken EcalIntercalibConstants" << std::endl;
      imap = pIcal.product()->getMap();
      std::cout << "imap.size() = " << imap.size() << std::endl;
    } catch ( std::exception& ex ) {     
      std::cerr << "Error! can't get EcalIntercalibConstants " << std::endl;
    } 
    
    // get the ecal geometry:
    edm::ESHandle<CaloGeometry> geoHandle;
    setup.get<CaloGeometryRecord>().get(geoHandle);
    const CaloGeometry& geometry = *geoHandle;
    //const CaloSubdetectorGeometry *barrelGeometry = geometry.getSubdetectorGeometry(DetId::Ecal, EcalBarrel);
    
    // loop over all barrel crystals
    barrelCells = geometry.getValidDetIds(DetId::Ecal, EcalBarrel);
    std::vector<DetId>::const_iterator barrelIt;
    for (barrelIt=barrelCells.begin(); barrelIt!=barrelCells.end(); barrelIt++) {
      EBDetId eb(*barrelIt);
      
      // get the initial calibration constants
      EcalIntercalibConstantMap::const_iterator itcalib = imap.find(eb.rawId());
      if ( itcalib == imap.end() ) {
        // FIXME -- throw error
      }
      EcalIntercalibConstant calib = (*itcalib);
      int sign = eb.zside()>0 ? 1 : 0;
      oldCalibs_barl[abs(eb.ieta())-1][eb.iphi()-1][sign] = calib;
      if (eb.iphi()==1) std::cout << "Read old constant for crystal "
                                  << " (" << eb.ieta() << "," << eb.iphi()
                                  << ") : " << calib << std::endl;
      
      
      
    }
    isfirstcall_=false;
  }
  


  nevent++;

  if ((nevent<100 && nevent%10==0) 
      ||(nevent<1000 && nevent%100==0) 
      ||(nevent<10000 && nevent%100==0) 
      ||(nevent<100000 && nevent%1000==0) 
      ||(nevent<10000000 && nevent%1000==0))
    std::cout << "[Pi0FixedMassWindowCalibration] Events processed: "<<nevent<<std::endl;

  recHitsEB_map = new std::map<DetId, EcalRecHit>();

  EcalRecHitCollection* recalibEcalRecHitCollection( new EcalRecHitCollection );

  int nRecHitsEB=0;
  Handle<EcalRecHitCollection> pEcalRecHitBarrelCollection;
  event.getByLabel(ecalHitsProducer_, barrelHits_, pEcalRecHitBarrelCollection);
  const EcalRecHitCollection* ecalRecHitBarrelCollection = pEcalRecHitBarrelCollection.product();
  cout << " ECAL Barrel RecHits # "<< ecalRecHitBarrelCollection->size() <<endl;
  for(EcalRecHitCollection::const_iterator aRecHitEB = ecalRecHitBarrelCollection->begin(); aRecHitEB != ecalRecHitBarrelCollection->end(); aRecHitEB++) {
    //cout << " ECAL Barrel RecHit #,E,time,det,subdetid: "<<nRecHitsEB<<" "<<aRecHitEB->energy()<<" "<<aRecHitEB->time()<<" "<<aRecHitEB->detid().det()<<" "<<aRecHitEB->detid().subdetId()<<endl;


    EBDetId ebrhdetid = aRecHitEB->detid();
    //cout << " EBDETID: z,ieta,iphi "<<ebrhdetid.zside()<<" "<<ebrhdetid.ieta()<<" "<<ebrhdetid.iphi()<<endl;
    //cout << " EBDETID: tower_ieta,tower_iphi "<<ebrhdetid.tower_ieta()<<" "<<ebrhdetid.tower_iphi()<<endl;
    //cout << " EBDETID: iSM, ic "<<ebrhdetid.ism()<<" "<<ebrhdetid.ic()<<endl;

    int sign = ebrhdetid.zside()>0 ? 1 : 0;
    EcalRecHit aHit(aRecHitEB->id(),aRecHitEB->energy()*oldCalibs_barl[abs(ebrhdetid.ieta())-1][ebrhdetid.iphi()-1][sign],aRecHitEB->time());
    recalibEcalRecHitCollection->push_back(aHit);

    nRecHitsEB++;

  }

  //  cout<<" Recalib size: "<<recalibEcalRecHitCollection->size()<<endl;
  int irecalib=0;
  for(EcalRecHitCollection::const_iterator aRecHitEB = recalibEcalRecHitCollection->begin(); aRecHitEB != recalibEcalRecHitCollection->end(); aRecHitEB++) {
    //cout << " [recalibrated] ECAL Barrel RecHit #,E,time,det,subdetid: "<<irecalib<<" "<<aRecHitEB->energy()<<" "<<aRecHitEB->time()<<" "<<aRecHitEB->detid().det()<<" "<<aRecHitEB->detid().subdetId()<<endl;

    //    EBDetId ebrhdetid = aRecHitEB->detid();
    //cout << " [recalibrated] EBDETID: z,ieta,iphi "<<ebrhdetid.zside()<<" "<<ebrhdetid.ieta()<<" "<<ebrhdetid.iphi()<<endl;
    //cout << " [recalibrated] EBDETID: tower_ieta,tower_iphi "<<ebrhdetid.tower_ieta()<<" "<<ebrhdetid.tower_iphi()<<endl;
    //cout << " [recalibrated] EBDETID: iSM, ic "<<ebrhdetid.ism()<<" "<<ebrhdetid.ic()<<endl;

    std::pair<DetId, EcalRecHit> map_entry(aRecHitEB->id(), *aRecHitEB);
    recHitsEB_map->insert(map_entry);


    irecalib++;

  }

  
  // get the geometry and topology from the event setup:
  edm::ESHandle<CaloGeometry> geoHandle;
  setup.get<CaloGeometryRecord>().get(geoHandle);

  const CaloSubdetectorGeometry *geometry_p;
  CaloSubdetectorTopology *topology_p;

  std::string clustershapetag;
  geometry_p = geoHandle->getSubdetectorGeometry(DetId::Ecal, EcalBarrel);
  topology_p = new EcalBarrelTopology(geoHandle);

  const CaloSubdetectorGeometry *geometryES_p;
  geometryES_p = geoHandle->getSubdetectorGeometry(DetId::Ecal, EcalPreshower);

  /*
  reco::BasicClusterCollection clusters;
  clusters = island_p->makeClusters(ecalRecHitBarrelCollection,geometry_p,topology_p,geometryES_p,IslandClusterAlgo::barrel);
  
  //Create associated ClusterShape objects.
  std::vector <reco::ClusterShape> ClusVec;
  for (int erg=0;erg<int(clusters.size());++erg){
    reco::ClusterShape TestShape = shapeAlgo_.Calculate(clusters[erg],ecalRecHitBarrelCollection,geometry_p,topology_p);
    ClusVec.push_back(TestShape);
  }

  //Put clustershapes in event, but retain a Handle on them.
  std::auto_ptr<reco::ClusterShapeCollection> clustersshapes_p(new reco::ClusterShapeCollection);
  clustersshapes_p->assign(ClusVec.begin(), ClusVec.end());

  cout<<"[Pi0Calibration] Basic Cluster collection size: "<<clusters.size()<<endl;
  cout<<"[Pi0Calibration] Basic Cluster Shape Collection size: "<<clustersshapes_p->size()<<endl;

  int iClus=0;
  for(reco::BasicClusterCollection::const_iterator aClus = clusters.begin(); aClus != clusters.end(); aClus++) {
    cout<<" CLUSTER : #,NHits,e,et,eta,phi,e2x2,e3x3,e5x5: "<<iClus<<" "<<aClus->getHitsByDetId().size()<<" "<<aClus->energy()<<" "<<aClus->energy()*sin(aClus->position().theta())<<" "<<aClus->position().eta()<<" "<<aClus->position().phi()<<" "<<(*clustersshapes_p)[iClus].e2x2()<<" "<<(*clustersshapes_p)[iClus].e3x3()<<" "<<(*clustersshapes_p)[iClus].e5x5()<<endl; 
    iClus++;
  }
  */

  // recalibrated clusters
  reco::BasicClusterCollection clusters_recalib;
  clusters_recalib = island_p->makeClusters(recalibEcalRecHitCollection,geometry_p,topology_p,geometryES_p,IslandClusterAlgo::barrel);
  
  //Create associated ClusterShape objects.
  std::vector <reco::ClusterShape> ClusVec_recalib;
  for (int erg=0;erg<int(clusters_recalib.size());++erg){
    reco::ClusterShape TestShape_recalib = shapeAlgo_.Calculate(clusters_recalib[erg],recalibEcalRecHitCollection,geometry_p,topology_p);
    ClusVec_recalib.push_back(TestShape_recalib);
  }

  //Put clustershapes in event, but retain a Handle on them.
  std::auto_ptr<reco::ClusterShapeCollection> clustersshapes_p_recalib(new reco::ClusterShapeCollection);
  clustersshapes_p_recalib->assign(ClusVec_recalib.begin(), ClusVec_recalib.end());

  cout<<"[Pi0FixedMassWindowCalibration][recalibration] Basic Cluster collection size: "<<clusters_recalib.size()<<endl;
  cout<<"[Pi0FixedMassWindowCalibration][recalibration] Basic Cluster Shape Collection size: "<<clustersshapes_p_recalib->size()<<endl;


  // pizero selection

  // Get ECAL Barrel Island Basic Clusters collection
  // ECAL Barrel Island Basic Clusters 
  static const int MAXBCEB = 200;
  static const int MAXBCEBRH = 200;
  int nIslandBCEB;
  float eIslandBCEB[MAXBCEB];
  float etIslandBCEB[MAXBCEB];
  float etaIslandBCEB[MAXBCEB];
  float phiIslandBCEB[MAXBCEB];
  float e2x2IslandBCEB[MAXBCEB];
  float e3x3IslandBCEB[MAXBCEB];
  float e5x5IslandBCEB[MAXBCEB];
  // indexes to the RecHits assiciated with 
  // ECAL Barrel Island Basic Clusters
  int nIslandBCEBRecHits[MAXBCEB];
  //  int indexIslandBCEBRecHits[MAXBCEB][MAXBCEBRH];
  int ietaIslandBCEBRecHits[MAXBCEB][MAXBCEBRH];
  int iphiIslandBCEBRecHits[MAXBCEB][MAXBCEBRH];
  int zsideIslandBCEBRecHits[MAXBCEB][MAXBCEBRH];
  float eIslandBCEBRecHits[MAXBCEB][MAXBCEBRH];

  nIslandBCEB=0;
  for(int i=0; i<MAXBCEB; i++){
    eIslandBCEB[i] = 0;
    etIslandBCEB[i] = 0;
    etaIslandBCEB[i] = 0;
    phiIslandBCEB[i] = 0;
    e2x2IslandBCEB[i] = 0;
    e3x3IslandBCEB[i] = 0;
    e5x5IslandBCEB[i] = 0;
     nIslandBCEBRecHits[i] = 0;
     for(int j=0;j<MAXBCEBRH;j++){
       //       indexIslandBCEBRecHits[i][j] = 0;
       ietaIslandBCEBRecHits[i][j] = 0;
       iphiIslandBCEBRecHits[i][j] = 0;
       zsideIslandBCEBRecHits[i][j] = 0;
       eIslandBCEBRecHits[i][j] = 0;
     }
  }


  int iClus_recalib=0;
  for(reco::BasicClusterCollection::const_iterator aClus = clusters_recalib.begin(); aClus != clusters_recalib.end(); aClus++) {
    cout<<" CLUSTER [recalibration] : #,NHits,e,et,eta,phi,e2x2,e3x3,e5x5: "<<iClus_recalib<<" "<<aClus->size()<<" "<<aClus->energy()<<" "<<aClus->energy()*sin(aClus->position().theta())<<" "<<aClus->position().eta()<<" "<<aClus->position().phi()<<" "<<(*clustersshapes_p_recalib)[iClus_recalib].e2x2()<<" "<<(*clustersshapes_p_recalib)[iClus_recalib].e3x3()<<" "<<(*clustersshapes_p_recalib)[iClus_recalib].e5x5()<<endl; 

    eIslandBCEB[nIslandBCEB] = aClus->energy();
    etIslandBCEB[nIslandBCEB] = aClus->energy()*sin(aClus->position().theta());
    etaIslandBCEB[nIslandBCEB] = aClus->position().eta();
    phiIslandBCEB[nIslandBCEB] = aClus->position().phi();
    
    e2x2IslandBCEB[nIslandBCEB] = (*clustersshapes_p_recalib)[nIslandBCEB].e2x2();    
    e3x3IslandBCEB[nIslandBCEB] = (*clustersshapes_p_recalib)[nIslandBCEB].e3x3();    
    e5x5IslandBCEB[nIslandBCEB] = (*clustersshapes_p_recalib)[nIslandBCEB].e5x5();    

    nIslandBCEBRecHits[nIslandBCEB] = aClus->size();

    std::vector<std::pair< DetId,float> > hits = aClus->hitsAndFractions();
    std::vector<std::pair< DetId,float> >::iterator hit;
    std::map<DetId, EcalRecHit>::iterator aHit;

    int irhcount=0;
    for(hit = hits.begin(); hit != hits.end(); hit++)
      {
        // need to get hit by DetID in order to get energy
        aHit = recHitsEB_map->find((*hit).first);
        //cout << "       RecHit #: "<<irhcount<<" from Basic Cluster with Energy: "<<aHit->second.energy()<<endl; 

        EBDetId sel_rh = aHit->second.detid();
        //cout << "       RecHit: z,ieta,iphi "<<sel_rh.zside()<<" "<<sel_rh.ieta()<<" "<<sel_rh.iphi()<<endl;
        //cout << "       RecHit: tower_ieta,tower_iphi "<<sel_rh.tower_ieta()<<" "<<sel_rh.tower_iphi()<<endl;
        //cout << "       RecHit: iSM, ic "<<sel_rh.ism()<<" "<<sel_rh.ic()<<endl;

        ietaIslandBCEBRecHits[nIslandBCEB][irhcount] = sel_rh.ieta();
        iphiIslandBCEBRecHits[nIslandBCEB][irhcount] = sel_rh.iphi();
        zsideIslandBCEBRecHits[nIslandBCEB][irhcount] = sel_rh.zside();
        eIslandBCEBRecHits[nIslandBCEB][irhcount] = aHit->second.energy();

        irhcount++;
      }
    nIslandBCEB++;
    iClus_recalib++;


  }

  // Selection, based on ECAL Barrel Basic Clusters

  if (nIslandBCEB > 1) 
    {
      for(int i=0 ; i<nIslandBCEB ; i++)
        {
          for(int j=i+1 ; j<nIslandBCEB ; j++)
            {

              if( etIslandBCEB[i]>selePi0PtGammaOneMin_ && etIslandBCEB[j]>selePi0PtGammaOneMin_) 
                {
                
                  float theta_0 = 2. * atan(exp(-etaIslandBCEB[i]));
                  float theta_1 = 2. * atan(exp(-etaIslandBCEB[j]));
                
                  float p0x = eIslandBCEB[i] * sin(theta_0) * cos(phiIslandBCEB[i]);
                  float p1x = eIslandBCEB[j] * sin(theta_1) * cos(phiIslandBCEB[j]);
                
                  float p0y = eIslandBCEB[i] * sin(theta_0) * sin(phiIslandBCEB[i]);
                  float p1y = eIslandBCEB[j] * sin(theta_1) * sin(phiIslandBCEB[j]);
                
                  float p0z = eIslandBCEB[i] * cos(theta_0);
                  float p1z = eIslandBCEB[j] * cos(theta_1);

                  float pi0_px = p0x + p1x;
                  float pi0_py = p0y + p1y;
                  float pi0_pz = p0z + p1z;
                
                  float pi0_ptot = sqrt (pi0_px*pi0_px + pi0_py*pi0_py + pi0_pz*pi0_pz); 

                  float pi0_theta = acos(pi0_pz/pi0_ptot);
                  float pi0_eta = -log(tan(pi0_theta/2));
                  float pi0_phi = atan(pi0_py/pi0_px);
                  //cout << " pi0_theta, pi0_eta, pi0_phi "<<pi0_theta<<" "<<pi0_eta<<" "<<pi0_phi<<endl;

                  // belt isolation
                
                  float et_belt=0;
                  for(Int_t k=0 ; k<nIslandBCEB ; k++)
                    {
                      if( (k != i) && (k != j) ) 
                        {
                          float dr_pi0_k = sqrt( (etaIslandBCEB[k]-pi0_eta)*(etaIslandBCEB[k]-pi0_eta) + (phiIslandBCEB[k]-pi0_phi)*(phiIslandBCEB[k]-pi0_phi) );
                          float deta_pi0_k = fabs(etaIslandBCEB[k]-pi0_eta);
                          if ( (dr_pi0_k<selePi0DRBelt_) && (deta_pi0_k<selePi0DetaBelt_) ) et_belt = et_belt + etIslandBCEB[k];
                        }
                    }

                
                  float pt_pi0 = sqrt( (p0x+p1x)*(p0x+p1x) + (p0y+p1y)*(p0y+p1y));
                  //float dr_pi0 = sqrt ( (etaIslandBCEB[i]-etaIslandBCEB[j])*(etaIslandBCEB[i]-etaIslandBCEB[j]) + (phiIslandBCEB[i]-phiIslandBCEB[j])*(phiIslandBCEB[i]-phiIslandBCEB[j]) );

                  //cout <<" pi0 pt,dr:  "<<pt_pi0<<" "<<dr_pi0<<endl; 
                  if (pt_pi0 > selePi0PtPi0Min_) 
                    {
                      float m_inv = sqrt ( (eIslandBCEB[i] + eIslandBCEB[j])*(eIslandBCEB[i] + eIslandBCEB[j]) - (p0x+p1x)*(p0x+p1x) - (p0y+p1y)*(p0y+p1y) - (p0z+p1z)*(p0z+p1z) );  
                      cout <<" pi0 (pt>2.5 GeV) m_inv = "<<m_inv<<endl;  

                      float s4s9_1 = e2x2IslandBCEB[i]/e3x3IslandBCEB[i];
                      float s4s9_2 = e2x2IslandBCEB[j]/e3x3IslandBCEB[j];

                      float s9s25_1 = e3x3IslandBCEB[i]/e5x5IslandBCEB[i];
                      float s9s25_2 = e3x3IslandBCEB[j]/e5x5IslandBCEB[j];

                      //float s9Esc_1 = e3x3IslandBCEB[i]/eIslandBCEB[i];
                      //float s9Esc_2 = e3x3IslandBCEB[j]/eIslandBCEB[j];

                      if (s4s9_1>selePi0S4S9GammaOneMin_ && s4s9_2>selePi0S4S9GammaTwoMin_ && s9s25_1>selePi0S9S25GammaOneMin_ && s9s25_2>selePi0S9S25GammaTwoMin_ && (et_belt/pt_pi0 < selePi0EtBeltIsoRatioMax_) ) 
                        {
                          //good pizero candidate
                          if ( m_inv>(selePi0MinvMeanFixed_ - 2*selePi0MinvSigmaFixed_) && m_inv<(selePi0MinvMeanFixed_ + 2*selePi0MinvSigmaFixed_) ) 
                            {
                              //fill wxtals and mwxtals weights
                              cout<<" Pi0 Good candidate : minv = "<<m_inv<<endl;
                              for(int kk=0 ; kk<nIslandBCEBRecHits[i] ; kk++)
                                {
                                  int ieta_xtal = ietaIslandBCEBRecHits[i][kk];
                                  int iphi_xtal = iphiIslandBCEBRecHits[i][kk];
                                  int sign = zsideIslandBCEBRecHits[i][kk]>0 ? 1 : 0;
                                  wxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] = wxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] + eIslandBCEBRecHits[i][kk]/e3x3IslandBCEB[i];
                                  mwxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] = mwxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] + (selePi0MinvMeanFixed_/m_inv)*(selePi0MinvMeanFixed_/m_inv)*(eIslandBCEBRecHits[i][kk]/e3x3IslandBCEB[i]);
                                  cout<< "[Pi0FixedMassWindowCalibration] eta, phi, sign, e, e3x3, wxtals and mwxtals: "<<ieta_xtal<<" "<<iphi_xtal<<" "<<sign<<" "<<eIslandBCEBRecHits[i][kk]<<" "<<e3x3IslandBCEB[i]<<" "<<wxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign]<<" "<<mwxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign]<<endl;
                                }

                              for(int kk=0 ; kk<nIslandBCEBRecHits[j] ; kk++)
                                {
                                  int ieta_xtal = ietaIslandBCEBRecHits[j][kk];
                                  int iphi_xtal = iphiIslandBCEBRecHits[j][kk];
                                  int sign = zsideIslandBCEBRecHits[j][kk]>0 ? 1 : 0;
                                  wxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] = wxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] + eIslandBCEBRecHits[j][kk]/e3x3IslandBCEB[j];
                                  mwxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] = mwxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign] + (selePi0MinvMeanFixed_/m_inv)*(selePi0MinvMeanFixed_/m_inv)*(eIslandBCEBRecHits[j][kk]/e3x3IslandBCEB[j]);
                                  cout<< "[Pi0FixedMassWindowCalibration] eta, phi, sign, e, e3x3, wxtals and mwxtals: "<<ieta_xtal<<" "<<iphi_xtal<<" "<<sign<<" "<<eIslandBCEBRecHits[j][kk]<<" "<<e3x3IslandBCEB[j]<<" "<<wxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign]<<" "<<mwxtals[abs(ieta_xtal)-1][iphi_xtal-1][sign]<<endl;
                                }

                            }
                        }
                    }
                }
                
              
            } // End of the "j" loop over BCEB
        } // End of the "i" loop over BCEB


    } else {
      cout<< " Not enough ECAL Barrel Basic Clusters: "<<nIslandBCEB<<endl;
    }






  return kContinue;
}
void Pi0FixedMassWindowCalibration::endOfJob ( ) [virtual]

Called at end of job.

Reimplemented from edm::EDLooperBase.

Definition at line 119 of file Pi0FixedMassWindowCalibration.cc.

References abs, barrelCells, gather_cfg::cout, EcalBarrel, EBDetId::ieta(), EBDetId::iphi(), newCalibs_barl, Pi0CalibXMLwriter::writeLine(), and EBDetId::zside().

{
  
  std::cout << "[Pi0FixedMassWindowCalibration] endOfJob"<<endl;

  // Write new calibration constants

  Pi0CalibXMLwriter barrelWriter(EcalBarrel,99);

  std::vector<DetId>::const_iterator barrelIt=barrelCells.begin();
  for (; barrelIt!=barrelCells.end(); barrelIt++) {
    EBDetId eb(*barrelIt);
    int ieta = eb.ieta();
    int iphi = eb.iphi();
    int sign = eb.zside()>0 ? 1 : 0;
    barrelWriter.writeLine(eb,newCalibs_barl[abs(ieta)-1][iphi-1][sign]);
  }

}
edm::EDLooper::Status Pi0FixedMassWindowCalibration::endOfLoop ( const edm::EventSetup iSetup,
unsigned int  iLoop 
) [virtual]

Called at end of loop.

Implements edm::EDLooperBase.

Definition at line 161 of file Pi0FixedMassWindowCalibration.cc.

References abs, barrelCells, gather_cfg::cout, EcalBarrel, EBDetId::ieta(), EBDetId::iphi(), edm::EDLooperBase::kContinue, edm::EDLooperBase::kStop, mwxtals, newCalibs_barl, oldCalibs_barl, theMaxLoops, Pi0CalibXMLwriter::writeLine(), wxtals, and EBDetId::zside().

{
  std::cout << "[Pi0FixedMassWindowCalibration] Ending loop " << iLoop<<std::endl;

  for (int sign=0; sign<2; sign++) {
    for (int ieta=0; ieta<85; ieta++) {
      for (int iphi=0; iphi<360; iphi++) {

        if (wxtals[ieta][iphi][sign] == 0 ) 
          {
            newCalibs_barl[ieta][iphi][sign]=oldCalibs_barl[ieta][iphi][sign];
          } else {
            newCalibs_barl[ieta][iphi][sign]=oldCalibs_barl[ieta][iphi][sign]*(mwxtals[ieta][iphi][sign]/wxtals[ieta][iphi][sign]);
          }
        cout<< " New calibration constant: ieta iphi sign - old,mwxtals,wxtals,new: "<<ieta<<" "<<iphi<<" "<<sign<<" - "<<oldCalibs_barl[ieta][iphi][sign]<<" "<<mwxtals[ieta][iphi][sign]<<" "<<wxtals[ieta][iphi][sign]<<" "<<newCalibs_barl[ieta][iphi][sign]<<endl;

      }
    }
  }
    
  Pi0CalibXMLwriter barrelWriter(EcalBarrel,iLoop+1);

  std::vector<DetId>::const_iterator barrelIt=barrelCells.begin();
  for (; barrelIt!=barrelCells.end(); barrelIt++) {
    EBDetId eb(*barrelIt);
    int ieta = eb.ieta();
    int iphi = eb.iphi();
    int sign = eb.zside()>0 ? 1 : 0;
    barrelWriter.writeLine(eb,newCalibs_barl[abs(ieta)-1][iphi-1][sign]);
    if (iphi==1) {
      std::cout << "Calib constant for barrel crystal "
                << " (" << ieta << "," << iphi << ") changed from "
                << oldCalibs_barl[abs(ieta)-1][iphi-1][sign] << " to "
                << newCalibs_barl[abs(ieta)-1][iphi-1][sign] << std::endl;
    }
  }

  // replace old calibration constants with new one

  for (int sign=0; sign<2; sign++) {
    for (int ieta=0; ieta<85; ieta++) {
      for (int iphi=0; iphi<360; iphi++) {
        oldCalibs_barl[ieta][iphi][sign]=newCalibs_barl[ieta][iphi][sign];
        newCalibs_barl[ieta][iphi][sign]=0;
      }
    }
  }


  if ( iLoop == theMaxLoops-1 || iLoop >= theMaxLoops ) return kStop;
  else return kContinue;
}
virtual void Pi0FixedMassWindowCalibration::produce ( edm::Event ,
const edm::EventSetup  
) [inline, virtual]

Dummy implementation (job done in duringLoop)

Definition at line 70 of file Pi0FixedMassWindowCalibration.h.

{};
void Pi0FixedMassWindowCalibration::startingNewLoop ( unsigned int  iLoop) [virtual]

Called at beginning of loop.

Implements edm::EDLooperBase.

Definition at line 141 of file Pi0FixedMassWindowCalibration.cc.

References gather_cfg::cout, mwxtals, and wxtals.

{

  for (int sign=0; sign<2; sign++) {
    for (int ieta=0; ieta<85; ieta++) {
      for (int iphi=0; iphi<360; iphi++) {
        wxtals[ieta][iphi][sign]=0.;
        mwxtals[ieta][iphi][sign]=0.;
      }
    }
  }
  std::cout << "[Pi0FixedMassWindowCalibration] Starting loop number " << iLoop<<std::endl;

}

Member Data Documentation

Definition at line 131 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), endOfJob(), and endOfLoop().

Definition at line 102 of file Pi0FixedMassWindowCalibration.h.

Referenced by Pi0FixedMassWindowCalibration().

Definition at line 104 of file Pi0FixedMassWindowCalibration.h.

Referenced by Pi0FixedMassWindowCalibration().

Definition at line 101 of file Pi0FixedMassWindowCalibration.h.

Definition at line 100 of file Pi0FixedMassWindowCalibration.h.

Definition at line 95 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop().

Definition at line 103 of file Pi0FixedMassWindowCalibration.h.

Referenced by Pi0FixedMassWindowCalibration().

Definition at line 94 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop().

Definition at line 149 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop().

Definition at line 156 of file Pi0FixedMassWindowCalibration.h.

Referenced by beginOfJob(), and duringLoop().

Definition at line 108 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), and Pi0FixedMassWindowCalibration().

double Pi0FixedMassWindowCalibration::mwxtals[85][360][2] [private]

Definition at line 137 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), endOfLoop(), and startingNewLoop().

Definition at line 91 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop().

double Pi0FixedMassWindowCalibration::newCalibs_barl[85][360][2] [private]

Definition at line 135 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), endOfJob(), and endOfLoop().

double Pi0FixedMassWindowCalibration::oldCalibs_barl[85][360][2] [private]

Definition at line 134 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), and endOfLoop().

Definition at line 106 of file Pi0FixedMassWindowCalibration.h.

Referenced by Pi0FixedMassWindowCalibration().

Definition at line 150 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop().

Definition at line 147 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop().

Definition at line 115 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), and Pi0FixedMassWindowCalibration().

Definition at line 114 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), and Pi0FixedMassWindowCalibration().

Definition at line 124 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), and Pi0FixedMassWindowCalibration().

Definition at line 126 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), and Pi0FixedMassWindowCalibration().

Definition at line 127 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), and Pi0FixedMassWindowCalibration().

Definition at line 111 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), and Pi0FixedMassWindowCalibration().

Definition at line 112 of file Pi0FixedMassWindowCalibration.h.

Referenced by Pi0FixedMassWindowCalibration().

Definition at line 117 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), and Pi0FixedMassWindowCalibration().

Definition at line 119 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), and Pi0FixedMassWindowCalibration().

Definition at line 120 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), and Pi0FixedMassWindowCalibration().

Definition at line 121 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), and Pi0FixedMassWindowCalibration().

Definition at line 122 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), and Pi0FixedMassWindowCalibration().

Definition at line 107 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), and Pi0FixedMassWindowCalibration().

Definition at line 154 of file Pi0FixedMassWindowCalibration.h.

Definition at line 93 of file Pi0FixedMassWindowCalibration.h.

Referenced by endOfLoop().

Definition at line 141 of file Pi0FixedMassWindowCalibration.h.

Referenced by Pi0FixedMassWindowCalibration().

Definition at line 98 of file Pi0FixedMassWindowCalibration.h.

Referenced by Pi0FixedMassWindowCalibration().

double Pi0FixedMassWindowCalibration::wxtals[85][360][2] [private]

Definition at line 136 of file Pi0FixedMassWindowCalibration.h.

Referenced by duringLoop(), endOfLoop(), and startingNewLoop().