FastL1GlobalAlgo Class Reference

#include <FastL1GlobalAlgo.h>

Public Member Functions
void	CaloTowersDump (edm::Event const &e)
	FastL1GlobalAlgo (const edm::ParameterSet &)
void	FillBitInfos ()
void	FillEgammas (edm::Event const &)
void	FillEgammasTP (edm::Event const &)
void	FillJets (const edm::EventSetup &e)
void	FillL1Regions (edm::Event const &e, const edm::EventSetup &c)
void	FillL1RegionsTP (edm::Event const &e, const edm::EventSetup &c)
void	FillMET ()
void	FillMET (edm::Event const &e)
FastL1BitInfoCollection	getBitInfos ()
std::vector< FastL1Region >	GetCaloRegions ()
l1extra::L1JetParticleCollection	getCenJets () const
l1extra::L1EmParticleCollection	getEgammas () const
l1extra::L1JetParticleCollection	getForJets () const
l1extra::L1EmParticleCollection	getisoEgammas () const
l1extra::L1EtMissParticleCollection	getMET () const
l1extra::L1JetParticleCollection	getTauJets () const
void	InitL1Regions ()
	~FastL1GlobalAlgo ()

Private Member Functions
void	addJet (int rgnId, bool taubit)
void	checkMapping ()
void	findJets ()
bool	greaterEt (const reco::Candidate &a, const reco::Candidate &b)
double	hcaletValue (const int ieta, const int compET)
int	isEMCand (CaloTowerDetId cid, l1extra::L1EmParticle *p, const edm::Event &e)
bool	isMaxEtRgn_Window33 (int rgnid)
bool	isTauJet (int rgnid)
bool	TauIsolation (int rgnid)

Private Attributes
FastL1BitInfoCollection	m_BitInfos
l1extra::L1JetParticleCollection	m_CenJets
bool	m_DoBitInfo
l1extra::L1EmParticleCollection	m_Egammas
l1extra::L1JetParticleCollection	m_ForJets
bool	m_GctIso
double	m_hcaluncomp [33][256]
l1extra::L1EmParticleCollection	m_isoEgammas
double	m_IsolationEt
L1Config	m_L1Config
l1extra::L1EtMissParticleCollection	m_METs
std::vector< FastL1Region >	m_Regions
FastL1RegionMap *	m_RMap
l1extra::L1JetParticleCollection	m_TauJets

Detailed Description

Description: Global algorithm.

Implementation: <Notes on="" implementation>="">

Definition at line 70 of file FastL1GlobalAlgo.h.

Constructor & Destructor Documentation

FastL1GlobalAlgo::FastL1GlobalAlgo ( const edm::ParameterSet &  iConfig )

explicit

Definition at line 28 of file FastL1GlobalAlgo.cc.

References L1Config::CrystalEBThreshold, L1Config::CrystalEEThreshold, L1Config::DoEMCorr, L1Config::DoJetCorr, L1Config::EcalTPInput, L1Config::EMActiveLevel, L1Config::EmInputs, L1Config::EMLSB, L1Config::EMNoiseLevel, L1Config::EMSeedEnThreshold, L1Config::FGEBThreshold, L1Config::FGEEThreshold, edm::FileInPath::fullPath(), FastL1RegionMap::getFastL1RegionMap(), edm::ParameterSet::getParameter(), L1Config::HadActiveLevel, L1Config::HadNoiseLevel, L1Config::HcalLUT, L1Config::HcalTPInput, L1Config::hOeThreshold, i, j, L1Config::JetLSB, L1Config::JetSeedEtThreshold, m_DoBitInfo, m_GctIso, m_hcaluncomp, m_IsolationEt, m_L1Config, m_Regions, m_RMap, L1Config::MuonNoiseLevel, L1Config::noFGThreshold, L1Config::noTauVetoLevel, L1Config::QuietRegionThreshold, AlCaHLTBitMon_QueryRunRegistry::string, L1Config::TowerEBScale, L1Config::TowerEBThreshold, L1Config::TowerEEScale, L1Config::TowerEEThreshold, L1Config::TowerEMLSB, L1Config::TowerHadLSB, L1Config::TowerHBScale, L1Config::TowerHBThreshold, L1Config::TowerHEScale, L1Config::TowerHEThreshold, and L1Config::TowerInput.

{  
  m_RMap = FastL1RegionMap::getFastL1RegionMap();

  // Get L1 config
  m_L1Config.DoEMCorr = iConfig.getParameter<bool>("DoEMCorr");
  m_L1Config.DoJetCorr = iConfig.getParameter<bool>("DoJetCorr");
  m_DoBitInfo = iConfig.getParameter<bool>("DoBitInfo");
  m_GctIso = iConfig.getParameter<bool>("GctIso");
  m_IsolationEt = iConfig.getParameter<double>("IsolationEt");

  // get uncompressed hcal et
  m_L1Config.HcalLUT = iConfig.getParameter<edm::FileInPath>("HcalLUT");

  m_L1Config.EMSeedEnThreshold = iConfig.getParameter<double>("EMSeedEnThreshold");
  m_L1Config.EMActiveLevel = iConfig.getParameter<double>("EMActiveLevel");
  m_L1Config.HadActiveLevel = iConfig.getParameter<double>("HadActiveLevel");
  m_L1Config.noTauVetoLevel = iConfig.getParameter<double>("noTauVetoLevel");   
  m_L1Config.hOeThreshold = iConfig.getParameter<double>("hOeThreshold");
  m_L1Config.FGEBThreshold = iConfig.getParameter<double>("FGEBThreshold");
  m_L1Config.FGEEThreshold = iConfig.getParameter<double>("FGEEThreshold");

  m_L1Config.MuonNoiseLevel = iConfig.getParameter<double>("MuonNoiseLevel");
  m_L1Config.EMNoiseLevel = iConfig.getParameter<double>("EMNoiseLevel");
  m_L1Config.HadNoiseLevel = iConfig.getParameter<double>("HadNoiseLevel");
  m_L1Config.QuietRegionThreshold = iConfig.getParameter<double>("QuietRegionThreshold");
  m_L1Config.JetSeedEtThreshold = iConfig.getParameter<double>("JetSeedEtThreshold");

  m_L1Config.TowerEMLSB = iConfig.getParameter<double>("TowerEMLSB");
  m_L1Config.TowerHadLSB = iConfig.getParameter<double>("TowerHadLSB");
  m_L1Config.EMLSB = iConfig.getParameter<double>("EMLSB");
  m_L1Config.JetLSB = iConfig.getParameter<double>("JetLSB");

  m_L1Config.CrystalEBThreshold = iConfig.getParameter<double>("CrystalEBThreshold");
  m_L1Config.CrystalEEThreshold = iConfig.getParameter<double>("CrystalEEThreshold");

  m_L1Config.TowerEBThreshold = iConfig.getParameter<double>("TowerEBThreshold");
  m_L1Config.TowerEEThreshold = iConfig.getParameter<double>("TowerEEThreshold");
  m_L1Config.TowerHBThreshold = iConfig.getParameter<double>("TowerHBThreshold");
  m_L1Config.TowerHEThreshold = iConfig.getParameter<double>("TowerHEThreshold");

  m_L1Config.TowerEBScale = iConfig.getParameter<double>("TowerEBScale");
  m_L1Config.TowerEEScale = iConfig.getParameter<double>("TowerEEScale");
  m_L1Config.TowerHBScale = iConfig.getParameter<double>("TowerHBScale");
  m_L1Config.TowerHEScale = iConfig.getParameter<double>("TowerHEScale");

  m_L1Config.noFGThreshold = iConfig.getParameter<double>("noFGThreshold"); 
  
  m_L1Config.EmInputs = iConfig.getParameter <std::vector<edm::InputTag> >("EmInputs");
  m_L1Config.TowerInput = iConfig.getParameter<edm::InputTag>("TowerInput");

  m_L1Config.EcalTPInput = iConfig.getParameter<edm::InputTag>("EcalTPInput");
  m_L1Config.HcalTPInput = iConfig.getParameter<edm::InputTag>("HcalTPInput");


  //Load Hcal LUT file
  std::ifstream userfile;
  const std::string userfileName = m_L1Config.HcalLUT.fullPath();
  userfile.open(userfileName.c_str());
  static const int etabound = 32;
  static const int tpgmax = 256;
  for (int i=0; i<tpgmax; i++) { 
    for(int j = 1; j <=etabound; j++) {
      userfile >> m_hcaluncomp[j][i];
    }
  }
  userfile.close();  
  

  FastL1Region tr;
  for (int i=0;i<396;i++)
    m_Regions.push_back(tr);

}

FastL1GlobalAlgo::~FastL1GlobalAlgo

(

)

Definition at line 103 of file FastL1GlobalAlgo.cc.

{
}

Member Function Documentation

void FastL1GlobalAlgo::addJet ( int  rgnId, bool  taubit  )

private

Definition at line 208 of file FastL1GlobalAlgo.cc.

References funct::abs(), corrJetEt(), funct::cos(), L1Config::DoJetCorr, alignCSCRings::e, eta(), create_public_lumi_plots::exp, GCTEnergyTrunc(), FastL1RegionMap::getRegionCenterEtaPhi(), myspace::greaterEt(), L1Config::JetLSB, m_CenJets, m_DoBitInfo, m_ForJets, m_L1Config, m_Regions, m_RMap, m_TauJets, L1Config::noTauVetoLevel, AlCaHLTBitMon_ParallelJobs::p, phi, funct::sin(), python.multivaluedict::sort(), and theta().

Referenced by findJets().

                                              {
  std::pair<double, double> p = m_RMap->getRegionCenterEtaPhi(iRgn);

  //double e     = m_Regions.at(iRgn).GetJetE();
  //double et = GCTEnergyTrunc(m_Regions.at(iRgn).GetJetEt(), m_L1Config.JetLSB, false);
  double et = m_Regions.at(iRgn).GetJetEt();

  double eta   = p.first;
  double phi   = p.second;

  if (m_L1Config.DoJetCorr) {
    et = GCTEnergyTrunc(corrJetEt(et,eta), m_L1Config.JetLSB, false);
  } else {
    et = GCTEnergyTrunc(et, m_L1Config.JetLSB, false);
  }

  double theta = 2.*atan(exp(-eta));
  double ex = et*cos(phi);
  double ey = et*sin(phi);
  //double ex = e*sin(theta)*cos(phi);
  //double ey = e*sin(theta)*sin(phi);
  double e = ex/sin(theta)/cos(phi);
  double ez = e*cos(theta);

  if (m_DoBitInfo){
    m_Regions[iRgn].BitInfo.setEt(et);
    m_Regions[iRgn].BitInfo.setEnergy(e);
  }

  reco::Particle::LorentzVector rp4(ex,ey,ez,e); 
  l1extra::L1JetParticle tjet(rp4);
  
  if (et>=5.) { 
    if (m_DoBitInfo) m_Regions[iRgn].BitInfo.setHard(true);
    if (m_DoBitInfo) m_Regions[iRgn].BitInfo.setSoft(false);
    if ((taubit || et>m_L1Config.noTauVetoLevel) && (std::abs(eta)<3.0) ) {
      m_TauJets.push_back(tjet);
      // sort by et 
      std::sort(m_TauJets.begin(),m_TauJets.end(), myspace::greaterEt);
    } else {
      if (std::abs(eta)<3.0) {
    m_CenJets.push_back(tjet);
    std::sort(m_CenJets.begin(),m_CenJets.end(), myspace::greaterEt);
      } else {
    m_ForJets.push_back(tjet);
    std::sort(m_ForJets.begin(),m_ForJets.end(), myspace::greaterEt);
      }
    }
  }
  else{  
    if (m_DoBitInfo) m_Regions[iRgn].BitInfo.setSoft(true);
    if (m_DoBitInfo) m_Regions[iRgn].BitInfo.setHard(false);
  } 
}

void FastL1GlobalAlgo::CaloTowersDump

(

edm::Event const &

e

)

Definition at line 111 of file FastL1GlobalAlgo.cc.

References edm::Event::getByLabel(), input, j, m_L1Config, and L1Config::TowerInput.

                                                  {
  /*
    std::vector<edm::Handle<CaloTowerCollection> > prods;
    
    edm::LogInfo("FastL1GlobalAlgo::CaloTowersDump") << "Start!";
    e.getManyByType(prods);
    
    std::vector<edm::Handle<CaloTowerCollection> >::iterator i;

    for (i=prods.begin(); i!=prods.end(); i++) {
    const CaloTowerCollection& c=*(*i);
      
    for (CaloTowerCollection::const_iterator j=c.begin(); j!=c.end(); j++) {
    edm::LogInfo("FastL1GlobalAlgo::CaloTowersDump") << *j;
    }
    }
    edm::LogInfo("FastL1GlobalAlgo::CaloTowersDump") << "End!";
  */


  edm::Handle<CaloTowerCollection> input;
    
  edm::LogInfo("FastL1GlobalAlgo::CaloTowersDump") << "Start!";
  e.getByLabel(m_L1Config.TowerInput,input);

  for (CaloTowerCollection::const_iterator j=input->begin(); j!=input->end(); j++) {
    edm::LogInfo("FastL1GlobalAlgo::CaloTowersDump") << *j;
  }

  edm::LogInfo("FastL1GlobalAlgo::CaloTowersDump") << "End!";
}

void FastL1GlobalAlgo::checkMapping ( )

private

Definition at line 1339 of file FastL1GlobalAlgo.cc.

References FastL1RegionMap::convertFromECal_to_HCal_iphi(), gather_cfg::cout, FastL1RegionMap::getRegionCenterEtaPhi(), FastL1RegionMap::getRegionEtaPhiIndex(), FastL1RegionMap::getRegionIndex(), FastL1RegionMap::getRegionTowerIndex(), i, j, and m_RMap.

                               {

  // loop over towers ieta,iphi
  for (int j=1;j<=72;j++) {
    for (int i=-28; i<=28; i++) {
      if (i==0) continue;
      int iRgn =  m_RMap->getRegionIndex(i,j);
      std::pair<double, double> RgnEtaPhi = m_RMap->getRegionCenterEtaPhi(iRgn);
      //int iTwr = m_RMap->getRegionTowerIndex(i,j);
      std::pair<int, int> iRgnEtaPhi = m_RMap->getRegionEtaPhiIndex(iRgn);
      std::pair<int, int> iRgnEtaPhi2 = m_RMap->getRegionEtaPhiIndex(std::pair<int, int>(i,j));

      std::cout<<"---------------------------------------------------------------------------"<<std::endl;
      std::cout<<"Region:   "<<iRgn<<" | "<<RgnEtaPhi.first<<", "<<RgnEtaPhi.second*180./3.141<<std::endl;
      std::cout<<"   -      "<<iRgnEtaPhi.first<<", "<<iRgnEtaPhi.second<<std::endl;
      std::cout<<"   -      "<<iRgnEtaPhi2.first<<", "<<iRgnEtaPhi2.second<<std::endl;
      std::cout<<" Tower:   "<<i<<", "<<m_RMap->convertFromECal_to_HCal_iphi(j)<<std::endl;
      std::cout<<" TowerId: "<<m_RMap->getRegionTowerIndex(i,j)<<std::endl;

    }
  }

}

void FastL1GlobalAlgo::FillBitInfos

(

)

Definition at line 832 of file FastL1GlobalAlgo.cc.

References i, m_BitInfos, m_DoBitInfo, and m_Regions.

Referenced by FastL1CaloSim::produce().

                               {
  if (m_DoBitInfo){
    m_BitInfos.clear();
    for (int i=0; i<396; i++) {
      m_BitInfos.push_back(m_Regions[i].getBitInfo());
    }
  }
}

void FastL1GlobalAlgo::FillEgammas

(

edm::Event const &

e

)

Definition at line 304 of file FastL1GlobalAlgo.cc.

References edm::Event::getByLabel(), myspace::greaterEt(), input, isEMCand(), m_Egammas, m_isoEgammas, m_L1Config, python.multivaluedict::sort(), and L1Config::TowerInput.

Referenced by FastL1CaloSim::produce().

                                               {
  m_Egammas.clear();
  m_isoEgammas.clear();

  //std::vector< edm::Handle<CaloTowerCollection> > input;
  //e.getManyByType(input);
  edm::Handle<CaloTowerCollection> input;
  e.getByLabel(m_L1Config.TowerInput,input);

  //std::vector< edm::Handle<CaloTowerCollection> >::iterator j;
  //for (j=input.begin(); j!=input.end(); j++) {
  //  const CaloTowerCollection& c=*(*j);
  
  l1extra::L1EmParticle* ph = new l1extra::L1EmParticle();  
  //l1extra::L1EmParticle ph;
  //for (CaloTowerCollection::const_iterator cnd=c.begin(); cnd!=c.end(); cnd++) {
  for (CaloTowerCollection::const_iterator cnd=input->begin(); cnd!=input->end(); cnd++) {
    reco::Particle::LorentzVector rp4(0.,0.,0.,0.);
    //l1extra::L1EmParticle* ph = new l1extra::L1EmParticle(rp4);
    *ph = l1extra::L1EmParticle(rp4);

    CaloTowerDetId cid   = cnd->id();

    int emTag = isEMCand(cid,ph,e);
      
    // 1 = non-iso EM, 2 = iso EM
    if (emTag==1) {
      m_Egammas.push_back(*ph);
    } else if (emTag==2) {
      m_isoEgammas.push_back(*ph);
    }

  }
  //}

  std::sort(m_Egammas.begin(),m_Egammas.end(), myspace::greaterEt);
  std::sort(m_isoEgammas.begin(),m_isoEgammas.end(), myspace::greaterEt);

  delete ph;
}

void FastL1GlobalAlgo::FillEgammasTP

(

edm::Event const &

e

)

Definition at line 266 of file FastL1GlobalAlgo.cc.

References edm::SortedCollection< T, SORT >::begin(), edm::SortedCollection< T, SORT >::end(), myspace::greaterEt(), i, isEMCand(), m_Egammas, m_isoEgammas, m_Regions, and python.multivaluedict::sort().

Referenced by FastL1CaloSim::produce().

                                                 {
  m_Egammas.clear();
  m_isoEgammas.clear();

  l1extra::L1EmParticle* ph = new l1extra::L1EmParticle();
  //l1extra::L1EmParticle ph;
  for (int i=0; i<396; i++) { 
    CaloTowerCollection towers = m_Regions[i].GetCaloTowers();

    for (CaloTowerCollection::const_iterator cnd=towers.begin(); cnd!=towers.end(); cnd++) {
      if (cnd->emEt()<0.01 && cnd->hadEt()<0.01) continue;
      //if (cnd->emEt()<0.01) continue;

      reco::Particle::LorentzVector rp4(0.,0.,0.,0.);
      // l1extra::L1EmParticle* ph = new l1extra::L1EmParticle(rp4);
      *ph = l1extra::L1EmParticle(rp4);

      CaloTowerDetId cid   = cnd->id();
      
      int emTag = isEMCand(cid,ph,e);
      
      // 1 = non-iso EM, 2 = iso EM
      if (emTag==1) {
    m_Egammas.push_back(*ph);
      } else if (emTag==2) {
    m_isoEgammas.push_back(*ph);
      }
      
    }
    std::sort(m_Egammas.begin(),m_Egammas.end(), myspace::greaterEt);
    std::sort(m_isoEgammas.begin(),m_isoEgammas.end(), myspace::greaterEt);
  }
  delete ph;
}

void FastL1GlobalAlgo::FillJets ( const edm::EventSetup &  e )

inline

Definition at line 93 of file FastL1GlobalAlgo.h.

References findJets().

Referenced by FastL1CaloSim::produce().

{ findJets(); };

void FastL1GlobalAlgo::FillL1Regions	(	edm::Event const &	e,
		const edm::EventSetup &	c
	)

Definition at line 750 of file FastL1GlobalAlgo.cc.

References funct::abs(), L1Config::EmInputs, edm::EventSetup::get(), edm::Event::getByLabel(), FastL1RegionMap::getRegionEtaPhiIndex(), FastL1RegionMap::getRegionTowerIndex(), i, InitL1Regions(), input, m_L1Config, m_Regions, m_RMap, edm::ESHandle< class >::product(), and L1Config::TowerInput.

Referenced by FastL1CaloSim::produce().

{
  InitL1Regions();
  
  edm::Handle<CaloTowerCollection> input;
  e.getByLabel(m_L1Config.TowerInput,input);
  
  edm::ESHandle<CaloTowerConstituentsMap> cttopo;
  c.get<IdealGeometryRecord>().get(cttopo);
  const CaloTowerConstituentsMap* theTowerConstituentsMap = cttopo.product();
  
  edm::ESHandle<CaloTopology> calotopo;
  c.get<CaloTopologyRecord>().get(calotopo);
  
  edm::ESHandle<CaloGeometry> cGeom;
  //c.get<IdealGeometryRecord>().get(cGeom);
  c.get<CaloGeometryRecord>().get(cGeom);    

  edm::Handle<EcalRecHitCollection> ec1;
  e.getByLabel(m_L1Config.EmInputs.at(1),ec1);
  
  edm::Handle<EcalRecHitCollection> ec0;
  e.getByLabel(m_L1Config.EmInputs.at(0),ec0);
  
  // ascii visualisation of mapping
  //m_RMap->display();
  
 
  // works for barrel/endcap region only right now!
  //std::vector< edm::Handle<CaloTowerCollection> > input;
  //e.getManyByType(input);
  //edm::Handle<CaloTowerCollection> input;
  //e.getByLabel(m_L1Config.TowerInput,input);

  //std::vector< edm::Handle<CaloTowerCollection> >::iterator j;
  //for (j=input.begin(); j!=input.end(); j++) {
  //  const CaloTowerCollection& c=*(*j);
    
  //  for (CaloTowerCollection::const_iterator cnd=c.begin(); cnd!=c.end(); cnd++) {
  for (CaloTowerCollection::const_iterator cnd=input->begin(); cnd!=input->end(); cnd++) {

    CaloTowerDetId cid   = cnd->id();
    std::pair<int, int> pep = m_RMap->getRegionEtaPhiIndex(cid);
 
    int rgnid = 999;
    int twrid = 999;
      
    if (std::abs(pep.first)<=22) {
      rgnid = pep.second*22 + pep.first;
      twrid = m_RMap->getRegionTowerIndex(cid);
      //std::cout << rgnid << " " << twrid << std::endl;
      //std::cout << cnd->emEt() << " " << cnd->hadEt() << std::endl;
    } 

    if (rgnid<396 && twrid<16) {
      m_Regions[rgnid].FillTower_Scaled(*cnd,twrid,true,cGeom);
      m_Regions[rgnid].SetRegionBits(e);
    }

  }

  //}
  
  // Fill EM Crystals
  for (int i=0; i<396; i++) {

    //m_Regions[i].FillEMCrystals(e,iConfig,m_RMap);
    m_Regions[i].FillEMCrystals(theTowerConstituentsMap,
                &(*calotopo),
                &(*cGeom),
                &(*ec0), &(*ec1),
                m_RMap);
    
  }

  //checkMapping();
  
}

void FastL1GlobalAlgo::FillL1RegionsTP	(	edm::Event const &	e,
		const edm::EventSetup &	c
	)

Definition at line 531 of file FastL1GlobalAlgo.cc.

References funct::abs(), corrEmEt(), L1Config::DoEMCorr, L1Config::EcalTPInput, L1Config::EMLSB, eta(), fastmath::etaphi(), edm::EventSetup::get(), edm::Event::getByLabel(), FastL1RegionMap::getRegionCenterEtaPhi(), FastL1RegionMap::getRegionIndex(), FastL1RegionMap::getRegionTowerIndex(), hcaletValue(), L1Config::HcalTPInput, L1Config::hOeThreshold, i, InitL1Regions(), j, m_L1Config, m_Regions, m_RMap, L1Config::noFGThreshold, phi, and edmStreamStallGrapher::t.

Referenced by FastL1CaloSim::produce().

{
  //edm::ESHandle<CaloTowerConstituentsMap> cttopo;
  //s.get<IdealGeometryRecord>().get(cttopo);
  //const CaloTowerConstituentsMap* theTowerConstituentsMap = cttopo.product();

  InitL1Regions();

  edm::ESHandle<CaloGeometry> cGeom;
  //c.get<IdealGeometryRecord>().get(cGeom);
  s.get<CaloGeometryRecord>().get(cGeom);    

  edm::Handle<EcalTrigPrimDigiCollection> ETPinput;
  e.getByLabel(m_L1Config.EcalTPInput,ETPinput);

  edm::Handle<HcalTrigPrimDigiCollection> HTPinput;
  e.getByLabel(m_L1Config.HcalTPInput,HTPinput);

  //CaloTowerCollection towers;
  int hEtV  [396][16] = {{0}}; 
  //  int hFGV  [396][16] = {{0}};
  int hiEtaV[396][16] = {{0}};
  int hiPhiV[396][16] = {{0}};
  for (HcalTrigPrimDigiCollection::const_iterator hTP=HTPinput->begin(); 
       hTP!=HTPinput->end(); hTP++) {
    
    int rgnid = 999;
    int twrid = 999;

    int hiphi = hTP->id().iphi();
    int hieta = hTP->id().ieta();

    /*
      if(abs(hieta) > 20 && hiphi%2 == 0) hiphi--;
      std::pair<int, int> prim_tower_feed; // prim tower indeces iEta +/- 1~32, iPhi (+) 1~72
      prim_tower_feed.first = hieta;
      prim_tower_feed.second = hiphi;
      std::pair<int, int> rct_index = m_RMap-> getRegionEtaPhiIndex(prim_tower_feed); // convert prim tower indeces into RCT indeces ieta 0~21, iphi 0~17
      rgnid = rct_index.second*22 + rct_index.first; // converting fastL1 obsolete RCT numbering
    */

    rgnid  = m_RMap->getRegionIndex(hieta,hiphi);
    twrid = m_RMap->getRegionTowerIndex(hieta,hiphi);

    /*
      if (std::abs(htwrid.ieta())>28) {
      std::cout<<htwrid.ieta()<<" "<<htwrid.iphi()<<" "<<rgnid<<" "<<twrid<<" "<<std::endl;
      }
    */

    /*
    if (hTP->SOI_compressedEt()>0) {
      std::cout<<"hcalTP >>> "<<hTP->SOI_compressedEt()<<" "<<hTP->SOI_fineGrain()<<" "
           <<rgnid<<" "<<twrid<<std::endl;
    }
    */
    if(rgnid < 396 && twrid < 16){
      hEtV[rgnid][twrid] = (int)hTP->SOI_compressedEt();
      //      hFGV[rgnid][twrid] = (int)hTP->SOI_fineGrain();
      hiEtaV[rgnid][twrid] = hieta;
      hiPhiV[rgnid][twrid] = hiphi;
    }
  }
  

  int emEtV  [396][16] = {{0}};
  int emFGV  [396][16] = {{0}};
  int emiEtaV[396][16] = {{0}};
  int emiPhiV[396][16] = {{0}};
  //double emEtaV[396][16] = {0.};
  for (EcalTrigPrimDigiCollection::const_iterator eTP=ETPinput->begin(); 
       eTP!=ETPinput->end(); eTP++) {
   
    int eieta = eTP->id().ieta();

    if(abs(eieta)> 28) continue; // no crystal in HF
    else{
      int eiphi = eTP->id().iphi();
      //int teiphi = eiphi;
      
      int rgnid = 999;
      int twrid = 999;
      
      //if(abs(eieta) > 20 && eiphi%2 == 0) teiphi=eiphi-1;
      
      /*
    if(abs(eieta) > 20 && eiphi%2 == 0) eiphi--;
    std::pair<int, int> prim_tower_feed; // prim tower indeces iEta +/- 1~28, iPhi (+) 1~72
    prim_tower_feed.first = eieta;
    prim_tower_feed.second = eiphi;
    std::pair<int, int> rct_index = m_RMap-> getRegionEtaPhiIndex(prim_tower_feed); // convert prim tower indeces into RCT indeces ieta 0~21, iphi 0~17
    rgnid = rct_index.second*22 + rct_index.first; // converting fastL1 obsolete RCT numbering
      */
      
      /*  
      rgnid  = m_RMap->getRegionIndex(eieta,eiphi);
      twrid = m_RMap->getRegionTowerIndex(eieta,eiphi);
      
      if (eTP->compressedEt()>0) {
    std::cout<<"ecalTP *** "<<eTP->compressedEt()<<" "<<eTP->fineGrain()<<" "
         <<rgnid<<" "<<twrid<<std::endl;
      }
      */
      if(rgnid < 396 && twrid < 16){
    emEtV[rgnid][twrid] = (int)eTP->compressedEt();
    emFGV[rgnid][twrid] = (int)eTP->fineGrain();
    emiEtaV[rgnid][twrid] = eieta;
    emiPhiV[rgnid][twrid] = eiphi;
    
    //edm::ESHandle<CaloGeometry> cGeom; 
    //s.get<IdealGeometryRecord>().get(cGeom);    
      
    //CaloTowerDetId  towerDetId = CaloTowerDetId( eieta, teiphi); 
    //CaloTowerDetId  towerDetId2 = CaloTowerDetId( eieta, eiphi); 
    //const GlobalPoint gP1 = cGeom->getPosition(towerDetId);
    //const GlobalPoint gP12 = cGeom->getPosition(towerDetId2);
    //double eta = gP1.eta();  

    //if(abs(eieta) > 20) 
    //std::cout<<eiphi<<" "<<gP1.phi()<<" "<<eieta<<" "<<gP1.eta()<<" "<<std::endl;

    //double phi = gP1.phi();    
    //emEtaV[rgnid][twrid] = eta;
      }
    } // else
  } // ecalTP
  
  
  for (int i=0; i<396; i++) {
    for (int j=0; j<16; j++) {
      if (emEtV[i][j]>0 || hEtV[i][j]>0) {
    

    std::pair<double, double> etaphi 
      = m_RMap->getRegionCenterEtaPhi(i);
    double eta = etaphi.first;
    double phi = etaphi.second;
   

    double emEt = ((double) emEtV[i][j]) * m_L1Config.EMLSB;
    //double hadEt = ((double )hEtV[i][j]) * m_L1Config.JetLSB * cos(2.*atan(exp(-hiEtaV[i][j])));
    int iAbsTwrEta = std::abs(hiEtaV[i][j]);
    //double hadEt = ((double )hcaletValue(iAbsTwrEta, hEtV[i][j])) * m_L1Config.JetLSB;
    double hadEt = ((double )hcaletValue(iAbsTwrEta, hEtV[i][j]));
    //double hadEt = hEtV[i][j] * m_L1Config.JetLSB;
   
    if (m_L1Config.DoEMCorr) {
      //emEt = corrEmEt(emEt,emEtaV[i][j]);
      emEt = corrEmEt(emEt,std::abs(emiEtaV[i][j]));
    }

    double et = emEt + hadEt;
    edm::ESHandle<CaloGeometry> cGeom; 
    //s.get<IdealGeometryRecord>().get(cGeom);    
    s.get<CaloGeometryRecord>().get(cGeom);    


    //math::RhoEtaPhiVector lvec(et,eta,phi);
    math::XYZTLorentzVector lvec(et,eta,phi,0.);
    //math::PtEtaPhiMLorentzVector lvec(et,eta,phi,0.);
    
    CaloTowerDetId towerDetId;  
    if (emEtV[i][j]>0) 
      towerDetId = CaloTowerDetId(emiEtaV[i][j],emiPhiV[i][j]); 
    else
      towerDetId = CaloTowerDetId(hiEtaV[i][j],hiPhiV[i][j]); 
    
    GlobalPoint gP = cGeom->getPosition(towerDetId);
    CaloTower t = CaloTower(towerDetId,  
                emEt, hadEt, 0.,
                0, 0, lvec,
                gP, gP);
    
    //m_Regions[i].FillTower_Scaled(t,j,false);
    m_Regions[i].FillTower_Scaled(t,j,true,cGeom);
    
      /*
        if (et>0) {
        std::cout<<"+++ "<<emEt<<" "<<hadEt<<" "
        <<i<<" "<<j<<" "
        <<std::endl<<"-- "
        <<t.emEt()<<" "<<t.hadEt()<<" "
        <<t.eta()<<" "<<t.phi()<<" "
        <<std::endl;
        }
      */


      // Explicitely take care of integer boolean conversion
      if (emEt > 3.0 && emEt < m_L1Config.noFGThreshold && (int)emFGV[i][j]!=0) 
        m_Regions[i].SetFGBit(j,true);
      else 
        m_Regions[i].SetFGBit(j,false);
    
      if (emEt > 3.0){
        if (emEt < 60. && hadEt/emEt >  m_L1Config.hOeThreshold)  
          m_Regions[i].SetHOEBit(j,true);
        else
          m_Regions[i].SetHOEBit(j,false);
      }
      else
        m_Regions[i].SetHOEBit(j,false);

      m_Regions[i].SetRegionBits(e);
      }
      

    }
  }




  

}

void FastL1GlobalAlgo::FillMET

(

)

Definition at line 463 of file FastL1GlobalAlgo.cc.

References funct::cos(), fastmath::etaphi(), FastL1RegionMap::getRegionCenterEtaPhi(), i, l1extra::L1EtMissParticle::kMET, m_METs, m_Regions, m_RMap, phi, funct::sin(), and mathSSE::sqrt().

Referenced by FastL1CaloSim::produce().

                          {
  m_METs.clear();

  //double sum_e = 0.0;
  double sum_et = 0.0;
  double sum_ex = 0.0;
  double sum_ey = 0.0;
  //double sum_ez = 0.0;

  for (int i=0; i<396; i++) { 
    std::pair<double, double> etaphi = m_RMap->getRegionCenterEtaPhi(i);
    double phi   = etaphi.second;
    //double eta = etaphi.first;
    //double theta = 2.*atan(exp(-eta));
    
    double et = m_Regions[i].SumEt();
    //double e = m_Regions[i].SumE();

    //sum_et += et;
    //sum_et += RCTEnergyTrunc(et,0.5,2048);
    //sum_et += et;
    //sum_ex += RCTEnergyTrunc(et*cos(phi),0.5,2048);
    //sum_ey += RCTEnergyTrunc(et*sin(phi),0.5,2048); 
    sum_ex += et*cos(phi);
    sum_ey += et*sin(phi); 
    //sum_ex += e*sin(theta)*cos(phi);
    //sum_ey += e*sin(theta)*sin(phi); 
    //sum_e += e;
    //sum_e += RCTEnergyTrunc(et/sin(theta),0.5,2048);
    //sum_ez += RCTEnergyTrunc(et*cos(theta)/sin(theta),0.5,2048);
    //sum_e += et/sin(theta);
    //sum_ez += et*cos(theta)/sin(theta);
    //sum_ez += e*cos(theta);
    //sum_et += e*sin(theta);
  }
  
  //sum_et = RCTEnergyTrunc(std::sqrt(sum_ex*sum_ex + sum_ey*sum_ey),0.5,2048);
  sum_et = std::sqrt(sum_ex*sum_ex + sum_ey*sum_ey);
    
  //reco::Particle::LorentzVector rp4(-sum_ex,-sum_ey,-sum_ez,sum_e);
  reco::Particle::LorentzVector rp4(-sum_ex,-sum_ey,0.,std::sqrt(sum_ex*sum_ex + sum_ey*sum_ey));
  //edm::LogInfo("********** FastL1GlobalAlgo::FillMET()")<<rp4.mass()<<std::endl; 
  //m_MET = l1extra::L1EtMissParticle(rp4,sum_et,0.);  
  m_METs.push_back(l1extra::L1EtMissParticle(rp4,l1extra::L1EtMissParticle::kMET,sum_et));  

}

void FastL1GlobalAlgo::FillMET

(

edm::Event const &

e

)

Definition at line 347 of file FastL1GlobalAlgo.cc.

References funct::abs(), funct::cos(), eta(), create_public_lumi_plots::exp, edm::Event::getByLabel(), input, l1extra::L1EtMissParticle::kMET, m_L1Config, m_METs, phi, RCTEnergyTrunc(), funct::sin(), mathSSE::sqrt(), theta(), L1Config::TowerEBScale, L1Config::TowerEBThreshold, L1Config::TowerEEScale, L1Config::TowerEEThreshold, L1Config::TowerHBScale, L1Config::TowerHBThreshold, L1Config::TowerHEScale, and L1Config::TowerInput.

                                           {
  m_METs.clear();

  //std::vector< edm::Handle<CaloTowerCollection> > input;
  //e.getManyByType(input);
  edm::Handle<CaloTowerCollection> input;
  e.getByLabel(m_L1Config.TowerInput,input);

  double sum_hade = 0.0;
  double sum_hadet = 0.0;
  double sum_hadex = 0.0;
  double sum_hadey = 0.0;
  double sum_hadez = 0.0;
  double sum_e = 0.0;
  double sum_et = 0.0;
  double sum_ex = 0.0;
  double sum_ey = 0.0;
  double sum_ez = 0.0;

  //std::vector< edm::Handle<CaloTowerCollection> >::iterator i;

  //for (i=input.begin(); i!=input.end(); i++) {
  //  const CaloTowerCollection& c=*(*i);

  //  for (CaloTowerCollection::const_iterator candidate=c.begin(); candidate!=c.end(); candidate++) {
  for (CaloTowerCollection::const_iterator candidate=input->begin(); candidate!=input->end(); candidate++) {
    //double eme    = candidate->emEnergy();
    //double hade    = candidate->hadEnergy();
    double eme    = candidate->emEt();
    double hade    = candidate->hadEt();
      
    double EThres = 0.;
    double HThres = 0.;
    double EBthres = m_L1Config.TowerEBThreshold;
    double HBthres = m_L1Config.TowerHBThreshold;
    double EEthres = m_L1Config.TowerEBThreshold;
    double HEthres = m_L1Config.TowerEEThreshold;

    //if(std::abs(candidate->eta())<1.479) {
    if(std::abs(candidate->eta())<2.322) {
      EThres = EBthres;
    } else {
      EThres = EEthres;
    }
    //if(std::abs(candidate->eta())<1.305) {
    if(std::abs(candidate->eta())<2.322) {
      HThres = HBthres;
    } else {
      HThres = HEthres;
    }

    // rescale energies
    double emScale = 1.0;
    double hadScale = 1.0;
    if (std::abs(candidate->eta()>1.3050) && std::abs(candidate->eta())<3.0) {
      hadScale = m_L1Config.TowerHEScale;
      emScale = m_L1Config.TowerEEScale;
    }
    if (std::abs(candidate->eta()<1.3050)) {
      hadScale = m_L1Config.TowerHBScale;
      emScale = m_L1Config.TowerEBScale;
    }
    eme    *= emScale;
    hade   *= hadScale;
      
    if (eme>=EThres || hade>=HThres) {
      double phi   = candidate->phi();
      double eta = candidate->eta();
      //double et    = candidate->et();
      //double e     = candidate->energy();
      double theta = 2.*atan(exp(-eta));
      double et    = 0.;
      double e     = 0.;
      double had_et    = 0.;
      double had_e     = 0.;

      if (eme>=EThres) {
    et    += candidate->emEt();
    e    += candidate->emEnergy();
      }
      if (hade>=HThres) {
    et    += candidate->hadEt();
    e    += candidate->hadEnergy();
    had_et  += candidate->hadEt();
    had_e   += candidate->hadEnergy();
      }

      //sum_et += et;
      sum_et += RCTEnergyTrunc(et,1.0,1024);
      sum_ex += et*cos(phi);
      sum_ey += et*sin(phi); 
      //sum_ex += e*sin(theta)*cos(phi);
      //sum_ey += e*sin(theta)*sin(phi); 
      //sum_e += e;
      sum_e += et/sin(theta);
      sum_ez += et*cos(theta)/sin(theta);

      sum_hadet += had_et;
      sum_hadex += had_et*cos(phi);
      sum_hadey += had_et*sin(phi); 
      //sum_hadex += had_e*sin(theta)*cos(phi);
      //sum_hadey += had_e*sin(theta)*sin(phi); 
      //sum_hade += had_e;
      sum_hade += had_et/sin(theta);
      sum_hadez += had_et*cos(theta)/sin(theta);
    }
  }
  //}

  reco::Particle::LorentzVector rp4(-sum_ex,-sum_ey,0.,std::sqrt(sum_ex*sum_ex + sum_ey*sum_ey));
  //m_MET = l1extra::L1EtMissParticle(rp4,sum_et,0.);  
  m_METs.push_back(l1extra::L1EtMissParticle(rp4,l1extra::L1EtMissParticle::kMET,sum_et));  
}

void FastL1GlobalAlgo::findJets ( )

private

Definition at line 155 of file FastL1GlobalAlgo.cc.

References addJet(), eta(), FastL1RegionMap::getRegionCenterEtaPhi(), i, isMaxEtRgn_Window33(), isTauJet(), L1Config::JetSeedEtThreshold, m_CenJets, m_DoBitInfo, m_ForJets, m_GctIso, m_L1Config, m_Regions, m_RMap, m_TauJets, AlCaHLTBitMon_ParallelJobs::p, phi, and TauIsolation().

Referenced by FillJets().

                           {

  m_TauJets.clear();
  m_CenJets.clear();
  m_ForJets.clear();
  
  for (int i=0; i<396; i++) {
    // barrel/endcap part only:
    //if ((i%22)>3 && (i%22)<18) {
    std::pair<double, double> p = m_RMap->getRegionCenterEtaPhi(i);
    
    //if (m_Regions.at(i).SumEt()>0.)
    //  std::cout<<"******** TEST "<<i<<": "<<m_Regions.at(i).SumEt()<<std::endl;

    double eta   = p.first;
    double phi   = p.second;
    if (m_DoBitInfo){
      m_Regions[i].BitInfo.setEta(eta);
      m_Regions[i].BitInfo.setPhi(phi);
    }

    if (m_Regions.at(i).SumEt()>m_L1Config.JetSeedEtThreshold) {
      if (isMaxEtRgn_Window33(i)) {
    if (m_GctIso == true) { 
      if (TauIsolation(i) && (i%22)>3 && (i%22)<18 ) {
        addJet(i,true);    
      } else {
        addJet(i,false);    
      }
    } else {
      if (isTauJet(i) && (i%22)>3 && (i%22)<18 ) {
        addJet(i,true);    
      } else {
        addJet(i,false);    
      }
    }
    if (m_DoBitInfo) m_Regions[i].BitInfo.setMaxEt(true);
      }
      else {  
    if (m_DoBitInfo) m_Regions[i].BitInfo.setMaxEt(false);
      }
      if (m_DoBitInfo) m_Regions[i].BitInfo.setSumEtBelowThres (false);
    } else {
      if (m_DoBitInfo) m_Regions[i].BitInfo.setSumEtBelowThres (true);
    }
    //}
  }
  
}

FastL1BitInfoCollection FastL1GlobalAlgo::getBitInfos ( )

inline

Definition at line 84 of file FastL1GlobalAlgo.h.

References m_BitInfos.

Referenced by FastL1CaloSim::produce().

{ return m_BitInfos; }

std::vector<FastL1Region> FastL1GlobalAlgo::GetCaloRegions ( )

inline

Definition at line 100 of file FastL1GlobalAlgo.h.

References m_Regions.

{return m_Regions;}//KP

l1extra::L1JetParticleCollection FastL1GlobalAlgo::getCenJets ( ) const

inline

Definition at line 80 of file FastL1GlobalAlgo.h.

References m_CenJets.

Referenced by FastL1CaloSim::produce().

{ return m_CenJets; }

l1extra::L1EmParticleCollection FastL1GlobalAlgo::getEgammas ( ) const

inline

Definition at line 82 of file FastL1GlobalAlgo.h.

References m_Egammas.

Referenced by FastL1CaloSim::produce().

{ return m_Egammas; }

l1extra::L1JetParticleCollection FastL1GlobalAlgo::getForJets ( ) const

inline

Definition at line 81 of file FastL1GlobalAlgo.h.

References m_ForJets.

Referenced by FastL1CaloSim::produce().

{ return m_ForJets; }

l1extra::L1EmParticleCollection FastL1GlobalAlgo::getisoEgammas ( ) const

inline

Definition at line 83 of file FastL1GlobalAlgo.h.

References m_isoEgammas.

Referenced by FastL1CaloSim::produce().

{ return m_isoEgammas; }

l1extra::L1EtMissParticleCollection FastL1GlobalAlgo::getMET ( ) const

inline

Definition at line 78 of file FastL1GlobalAlgo.h.

References m_METs.

Referenced by FastL1CaloSim::produce().

{ return m_METs; }

l1extra::L1JetParticleCollection FastL1GlobalAlgo::getTauJets ( ) const

inline

Definition at line 79 of file FastL1GlobalAlgo.h.

References m_TauJets.

Referenced by FastL1CaloSim::produce().

{ return m_TauJets; }

bool FastL1GlobalAlgo::greaterEt ( const reco::Candidate &  a, const reco::Candidate &  b  )

private

double FastL1GlobalAlgo::hcaletValue ( const int  ieta, const int  compET  )

private

Definition at line 1364 of file FastL1GlobalAlgo.cc.

References m_hcaluncomp.

Referenced by FillL1RegionsTP().

                                                             {
  double etvalue = m_hcaluncomp[ieta][compET];//*cos(eta_ave);
  return etvalue;
}

void FastL1GlobalAlgo::InitL1Regions

(

)

Definition at line 511 of file FastL1GlobalAlgo.cc.

References trackerHits::c, FastL1RegionMap::getRegionEtaPhiIndex(), i, m_DoBitInfo, m_L1Config, m_Regions, m_RMap, and AlCaHLTBitMon_ParallelJobs::p.

Referenced by FillL1Regions(), and FillL1RegionsTP().

{
  m_Regions.clear();
  m_Regions = std::vector<FastL1Region>(396); // ieta: 1-22, iphi: 1-18

  // init regions
  for (int i=0; i<396; i++) {
    m_Regions[i].SetParameters(m_L1Config);
    m_Regions[i].SetDoBitInfo(m_DoBitInfo);
    std::pair<int, int> p = m_RMap->getRegionEtaPhiIndex(i);
    m_Regions[i].SetEtaPhiIndex(p.first,p.second,i);
    CaloTower c;
    for (int twrid=0; twrid<16; twrid++) {
      m_Regions[i].FillTowerZero(c,twrid);
    }
  }  
}

int FastL1GlobalAlgo::isEMCand ( CaloTowerDetId  cid, l1extra::L1EmParticle *  p, const edm::Event &  e  )

private

Definition at line 932 of file FastL1GlobalAlgo.cc.

References trackerHits::c, funct::cos(), L1Config::EMLSB, L1Config::EMSeedEnThreshold, create_public_lumi_plots::exp, GCTEnergyTrunc(), FastL1RegionMap::getRegionCenterEtaPhi(), FastL1RegionMap::getRegionIndex(), FastL1RegionMap::getRegionTowerIndex(), FastL1RegionMap::GetTowerEastEtaPhi(), FastL1RegionMap::GetTowerNEEtaPhi(), FastL1RegionMap::GetTowerNorthEtaPhi(), FastL1RegionMap::GetTowerNWEtaPhi(), FastL1RegionMap::GetTowerSEEtaPhi(), FastL1RegionMap::GetTowerSouthEtaPhi(), FastL1RegionMap::GetTowerSWEtaPhi(), FastL1RegionMap::GetTowerWestEtaPhi(), CaloTowerDetId::ieta(), CaloTowerDetId::iphi(), m_L1Config, m_Regions, m_RMap, bookConverter::max, Vispa.Plugins.EdmBrowser.EdmDataAccessor::ne(), L1Config::QuietRegionThreshold, funct::sin(), and L1Config::TowerEBThreshold.

Referenced by FillEgammas(), and FillEgammasTP().

                                                                                             {

  // center tower
  int crgn = m_RMap->getRegionIndex(cid);
  int ctwr = m_RMap->getRegionTowerIndex(cid);

  // crystals only in barrel/endcap part
  if ((crgn%22)<4 || (crgn%22)>17) return 0;
  if (crgn>395 || crgn < 0 || ctwr > 15 || ctwr < 0) return 0;

  CaloTowerCollection c = m_Regions.at(crgn).GetCaloTowers();
  double cenEt = c[ctwr].et();
  //double cenEt = RCTEnergyTrunc(c[ctwr].et(),0.5,64);
  //double cenE = c[ctwr].emEnergy();
  
  // Using region position rather than tower position
  std::pair<double, double> crpos = m_RMap->getRegionCenterEtaPhi(crgn);
  //double cenEta = c[ctwr].eta();
  //double cenPhi = c[ctwr].phi();
  double cenEta = crpos.first;
  double cenPhi = crpos.second;

  double cenFGbit = m_Regions.at(crgn).GetFGBit(ctwr);
  double cenHOEbit = m_Regions.at(crgn).GetHOEBit(ctwr);

  if (cenEt<m_L1Config.TowerEBThreshold) return 0;

  // check fine grain bit
  if (cenFGbit) return 0;

  // check H/E bit
  if (cenHOEbit) return 0;

  // check neighbours
  std::pair<int, int> no = m_RMap->GetTowerNorthEtaPhi(cid.ieta(),cid.iphi()); 
  std::pair<int, int> so = m_RMap->GetTowerSouthEtaPhi(cid.ieta(),cid.iphi()); 
  std::pair<int, int> we = m_RMap->GetTowerWestEtaPhi(cid.ieta(),cid.iphi()); 
  std::pair<int, int> ea = m_RMap->GetTowerEastEtaPhi(cid.ieta(),cid.iphi()); 
  std::pair<int, int> nw = m_RMap->GetTowerNWEtaPhi(cid.ieta(),cid.iphi()); 
  std::pair<int, int> ne = m_RMap->GetTowerNEEtaPhi(cid.ieta(),cid.iphi()); 
  std::pair<int, int> sw = m_RMap->GetTowerSWEtaPhi(cid.ieta(),cid.iphi()); 
  std::pair<int, int> se = m_RMap->GetTowerSEEtaPhi(cid.ieta(),cid.iphi()); 
  if (no.first>29 || no.first<-29 || no.second>72 || no.second<0) return 0;
  if (so.first>29 || so.first<-29 || so.second>72 || so.second<0) return 0;
  if (we.first>29 || we.first<-29 || we.second>72 || we.second<0) return 0;
  if (ea.first>29 || ea.first<-29 || ea.second>72 || ea.second<0) return 0;
  if (nw.first>29 || nw.first<-29 || nw.second>72 || nw.second<0) return 0;
  if (ne.first>29 || ne.first<-29 || ne.second>72 || ne.second<0) return 0;
  if (sw.first>29 || sw.first<-29 || sw.second>72 || sw.second<0) return 0;
  if (se.first>29 || se.first<-29 || se.second>72 || se.second<0) return 0;

  int notwr = m_RMap->getRegionTowerIndex(no);
  int norgn = m_RMap->getRegionIndex(no.first,no.second);
  int sotwr = m_RMap->getRegionTowerIndex(so);
  int sorgn = m_RMap->getRegionIndex(so.first,so.second);
  int wetwr = m_RMap->getRegionTowerIndex(we);
  int wergn = m_RMap->getRegionIndex(we.first,we.second);
  int eatwr = m_RMap->getRegionTowerIndex(ea);
  int eargn = m_RMap->getRegionIndex(ea.first,ea.second);
  int setwr = m_RMap->getRegionTowerIndex(se);
  int sergn = m_RMap->getRegionIndex(se.first,sw.second);
  int swtwr = m_RMap->getRegionTowerIndex(sw);
  int swrgn = m_RMap->getRegionIndex(sw.first,sw.second);
  int netwr = m_RMap->getRegionTowerIndex(ne);
  int nergn = m_RMap->getRegionIndex(ne.first,ne.second);
  int nwtwr = m_RMap->getRegionTowerIndex(nw);
  int nwrgn = m_RMap->getRegionIndex(nw.first,nw.second);
  
  //
  if (norgn>395 || norgn < 0 || notwr > 15 || notwr < 0) return 0;
  c = m_Regions[norgn].GetCaloTowers();
  double noEt = c[notwr].et();
  //double noEt = RCTEnergyTrunc(c[notwr].et(),0.5,64);
  //double noE = c[notwr].emEnergy();
  // check fine grain bit
  bool noFGbit = m_Regions[norgn].GetFGBit(notwr);
  // check H/E bit
  bool noHOEbit = m_Regions[norgn].GetHOEBit(notwr);

  //
  if (sorgn>395 || sorgn < 0 || sotwr > 15 || sotwr < 0) return 0;
  c = m_Regions[sorgn].GetCaloTowers();
  double soEt = c[sotwr].et();
  //double soEt = RCTEnergyTrunc(c[sotwr].et(),0.5,64);
  //double soE = c[sotwr].emEnergy();
  // check fine grain bit
  bool soFGbit = m_Regions[sorgn].GetFGBit(sotwr);
  // check H/E bit
  bool soHOEbit = m_Regions[sorgn].GetHOEBit(sotwr);

  //
  if (wergn>395 || wergn < 0 || wetwr > 15 || wetwr < 0) return 0;
  c = m_Regions[wergn].GetCaloTowers();
  double weEt = c[wetwr].et();
  //double weEt = RCTEnergyTrunc(c[wetwr].et(),0.5,64);
  //double weE = c[wetwr].emEnergy();
  // check fine grain bit
  bool weFGbit = m_Regions[wergn].GetFGBit(wetwr);
  // check H/E bit
  bool weHOEbit = m_Regions[wergn].GetHOEBit(wetwr);

  //
  if (eargn>395 || eargn < 0 || eatwr > 15 || eatwr < 0) return 0;
  c = m_Regions[eargn].GetCaloTowers();
  double eaEt = c[eatwr].et();
  //double eaEt = RCTEnergyTrunc(c[eatwr].et(),0.5,64);
  //double eaE = c[eatwr].emEnergy();
  // check fine grain bit
  bool eaFGbit = m_Regions[eargn].GetFGBit(eatwr);
  // check H/E bit
  bool eaHOEbit = m_Regions[eargn].GetHOEBit(eatwr);

  //
  if (nwrgn>395 || nwrgn < 0 || nwtwr > 15 || nwtwr < 0) return 0;
  c = m_Regions[nwrgn].GetCaloTowers();
  double nwEt = c[nwtwr].et();
  //double nwEt = RCTEnergyTrunc(c[nwtwr].et(),0.5,64);
  //double nwE = c[nwtwr].emEnergy();
  // check fine grain bit
  bool nwFGbit = m_Regions[nwrgn].GetFGBit(nwtwr);
  // check H/E bit
  bool nwHOEbit = m_Regions[nwrgn].GetHOEBit(nwtwr);

  //
  if (nergn>395 || nergn < 0 || netwr > 15 || netwr < 0) return 0;
  c = m_Regions[nergn].GetCaloTowers();
  double neEt = c[netwr].et();
  //double neEt = RCTEnergyTrunc(c[netwr].et(),0.5,64);
  //double neE = c[netwr].emEnergy();
  // check fine grain bit
  bool neFGbit = m_Regions[nergn].GetFGBit(netwr);
  // check H/E bit
  bool neHOEbit = m_Regions[nergn].GetHOEBit(netwr);

  //
  if (swrgn>395 || swrgn < 0 || swtwr > 15 || swtwr < 0) return 0;
  c = m_Regions[swrgn].GetCaloTowers();
  double swEt = c[swtwr].et();
  //double swEt = RCTEnergyTrunc(c[swtwr].et(),0.5,64);
  //double swE = c[swtwr].emEnergy();
  // check fine grain bit
  bool swFGbit = m_Regions[swrgn].GetFGBit(swtwr);
  // check H/E bit
  bool swHOEbit = m_Regions[swrgn].GetHOEBit(swtwr);

  //
  if (sergn>395 || sergn < 0 || setwr > 15 || setwr < 0) return 0;
  c = m_Regions[sergn].GetCaloTowers();
  double seEt = c[setwr].et();
  //double seEt = RCTEnergyTrunc(c[setwr].et(),0.5,64);
  //double seE = c[setwr].emEnergy();
  // check fine grain bit
  bool seFGbit = m_Regions[sergn].GetFGBit(setwr);
  // check H/E bit
  bool seHOEbit = m_Regions[sergn].GetHOEBit(setwr);

  
  // check if highest et tower
  bool isHit = ( cenEt > noEt && cenEt >= soEt && cenEt > weEt &&
         cenEt >= eaEt && cenEt > nwEt && cenEt > neEt &&
         cenEt >= swEt && cenEt >= seEt );
  if (!isHit) return 0;

  // find highest neighbour
  double hitEt = cenEt;
  //double hitE = cenE;
  double maxEt = std::max(noEt,std::max(soEt,std::max(weEt,eaEt)));
  //double maxE = std::max(noE,std::max(soE,std::max(weE,eaE)));

  // check 2 tower Et
  float emEtThres = m_L1Config.EMSeedEnThreshold;
  
  // at this point candidate is at least non-iso Egamma
  //double eme = (hitE+maxE);
  //double eme = (hitE+maxE);
  double emet = (hitEt+maxEt);

  /*
    if (m_L1Config.DoEMCorr) {
    emet = GCTEnergyTrunc(corrEmEt(emet,cenEta),m_L1Config.EMLSB, true);
    //emet = GCTEnergyTrunc(emet,m_L1Config.EMLSB, true);
    } else {
    emet = GCTEnergyTrunc(emet,m_L1Config.EMLSB, true);
    }
  */
  emet = GCTEnergyTrunc(emet,m_L1Config.EMLSB, true);

  if ((emet)<emEtThres) return 0;

  double emtheta = 2.*atan(exp(-cenEta));
  //double emet = eme*sin(emtheta);
  double emex = emet*cos(cenPhi);
  double emey = emet*sin(cenPhi);
  //double emex = eme*sin(emtheta)*cos(cenPhi);
  //double emey = eme*sin(emtheta)*sin(cenPhi);
  double eme = emex/sin(emtheta)/cos(cenPhi);
  double emez = eme*cos(emtheta);


  reco::Particle::LorentzVector rp4(emex,emey,emez,eme);
  //reco::Particle::Point rp3(0.,0.,0.);
  //reco::Particle::Charge q(0);
  //*ph = reco::Photon(q,rp4,rp3);
  *ph = l1extra::L1EmParticle(rp4);
  //ph = l1extra::L1EmParticle(rp4);

  //std::cout<<"EM eme     : "<<eme<<std::endl;
  //std::cout<<"EM rp4.et(): "<<rp4.Et()<<std::endl;
  //std::cout<<"EM ph->et() : "<<ph->et()<<std::endl;
 
  //if (emet>0.) {
  //  std::cout << "em region et, eta, phi: "<< emet<<" "<< cenEta<<" "<< cenPhi<<" " << std::endl;
  //  std::cout << "em lv et, eta, phi: "<< ph->et()<<" "<< ph->eta()<<" "<< ph->phi()<<" " << std::endl;
  //}

  // check isolation FG bits
  if (noFGbit || soFGbit || weFGbit || eaFGbit || 
      nwFGbit || neFGbit || swFGbit || seFGbit ||
      noHOEbit || soHOEbit || weHOEbit || eaHOEbit || 
      nwHOEbit || neHOEbit || swHOEbit || seHOEbit)
    return 1;
  
  // check isolation corners
  //double corThres = 0.4;
  //double quietThres = m_L1Config.EMNoiseLevel;
  double quietThres = m_L1Config.QuietRegionThreshold;
  bool isoVeto1 = false,isoVeto2 = false,isoVeto3 = false,isoVeto4 = false;
  if (swEt>quietThres || weEt>quietThres || nwEt>quietThres || noEt>quietThres || neEt>quietThres ) {
    //if ((swEt + weEt + nwEt + noEt + neEt)/cenEt > corThres) 
    isoVeto1 = true;
  }
  if (neEt>quietThres || eaEt>quietThres || seEt>quietThres || soEt>quietThres || swEt>quietThres ) {
    //if ((neEt + eaEt + seEt + soEt + swEt)/cenEt > corThres) 
    isoVeto2 = true;
  }
  if (nwEt>quietThres || noEt>quietThres || neEt>quietThres || eaEt>quietThres || seEt>quietThres ) {
    //if ((nwEt + noEt + neEt + eaEt + seEt)/cenEt > corThres) 
    isoVeto3 = true;
  }
  if (seEt>quietThres || soEt>quietThres || swEt>quietThres || weEt>quietThres || nwEt>quietThres ) {
    //if ((seEt + soEt + swEt + weEt + nwEt)/cenEt > corThres) 
    isoVeto4 = true;
  }
  if (isoVeto1 && isoVeto2 && isoVeto3 && isoVeto4)
    return 1;
  
  return 2;    
}

bool FastL1GlobalAlgo::isMaxEtRgn_Window33 ( int  rgnid )

private

Definition at line 1184 of file FastL1GlobalAlgo.cc.

References m_Regions.

Referenced by findJets().

                                              {

  int nwid = m_Regions.at(crgn).GetNWId();
  int nid = m_Regions.at(crgn).GetNorthId();
  int neid = m_Regions.at(crgn).GetNEId();
  int wid = m_Regions.at(crgn).GetWestId();
  int eid = m_Regions.at(crgn).GetEastId();
  int swid = m_Regions.at(crgn).GetSWId();
  int sid = m_Regions.at(crgn).GetSouthId();
  int seid = m_Regions.at(crgn).GetSEId();


  //Use 3x2 window at eta borders!
  // east border:
  if ((crgn%22)==21) { 
    
    if (nwid==999 || nid==999 || swid==999 || sid==999 || wid==999 ) { 
      return false;
    }

    double cenet = m_Regions.at(crgn).SumEt();
    double nwet =  m_Regions[nwid].SumEt();
    double noet = m_Regions[nid].SumEt();
    double weet = m_Regions[wid].SumEt();
    double swet = m_Regions[swid].SumEt();
    double soet = m_Regions[sid].SumEt();
    
    if ( cenet > nwet &&  cenet > noet &&
     cenet >= weet &&  cenet >= soet &&
     cenet >= swet ) 
      {

    double cene = m_Regions.at(crgn).SumE();
    double nwe =  m_Regions[nwid].SumE();
    double noe = m_Regions[nid].SumE();
    double wee = m_Regions[wid].SumE();
    double swe = m_Regions[swid].SumE();
    double soe = m_Regions[sid].SumE();
    
    // if region is central: jet energy is sum of 3x3 region
    // surrounding the central region
    double jE = cene + nwe + noe + wee + swe + soe;
    double jEt = cenet + nwet + noet + weet + swet + soet;
    

    m_Regions.at(crgn).SetJetE(jE);
    m_Regions.at(crgn).SetJetEt(jEt);
    
    m_Regions.at(crgn).SetJetE3x3(cene);
    m_Regions.at(crgn).SetJetEt3x3(cenet);
    
    return true;
      } else { return false; }
    
  }


  // west border:
  if ((crgn%22)==0) { 
    
    if (neid==999 || nid==999 || seid==999 || sid==999 || eid==999 ) { 
      return false;
    }

    double cenet = m_Regions.at(crgn).SumEt();
    double neet =  m_Regions[neid].SumEt();
    double noet = m_Regions[nid].SumEt();
    double eaet = m_Regions[eid].SumEt();
    double seet = m_Regions[seid].SumEt();
    double soet = m_Regions[sid].SumEt();
    
    if ( cenet > neet &&  cenet > noet &&
     cenet >= eaet &&  cenet >= soet &&
     cenet >= seet ) 
      {

    double cene = m_Regions.at(crgn).SumE();
    double nee =  m_Regions[neid].SumE();
    double noe = m_Regions[nid].SumE();
    double eae = m_Regions[eid].SumE();
    double see = m_Regions[seid].SumE();
    double soe = m_Regions[sid].SumE();
    
    // if region is central: jet energy is sum of 3x3 region
    // surrounding the central region
    double jE = cene + nee + noe + eae + see + soe;
    double jEt = cenet + neet + noet + eaet + seet + soet;
    
    m_Regions.at(crgn).SetJetE(jE);
    m_Regions.at(crgn).SetJetEt(jEt);
    
    m_Regions.at(crgn).SetJetE3x3(cene);
    m_Regions.at(crgn).SetJetEt3x3(cenet);
    
    return true;
      } else { return false; }
    
  }


  if (nwid==999 || neid==999 || nid==999 || swid==999 || seid==999 || sid==999 || wid==999 || 
      eid==999 ) { 
    //std::cerr << "FastL1GlobalAlgo::isMaxEtRgn_Window33(): RegionId out of bounds: " << std::endl
    //      << nwid << " " << nid << " "  << neid << " " << std::endl
    //      << wid << " " << crgn << " "  << eid << " " << std::endl
    //      << swid << " " << sid << " "  << seid << " " << std::endl;    
    return false;
  }


  double cenet = m_Regions.at(crgn).SumEt();
  double nwet =  m_Regions[nwid].SumEt();
  double noet = m_Regions[nid].SumEt();
  double neet = m_Regions[neid].SumEt();
  double weet = m_Regions[wid].SumEt();
  double eaet = m_Regions[eid].SumEt();
  double swet = m_Regions[swid].SumEt();
  double soet = m_Regions[sid].SumEt();
  double seet = m_Regions[seid].SumEt();

  if ( cenet > nwet &&  cenet > noet &&
       cenet > neet &&  cenet >= eaet &&
       cenet > weet &&  cenet >= soet &&
       cenet >= swet &&  cenet >= seet ) 
    {

      double cene = m_Regions.at(crgn).SumE();
      double nwe =  m_Regions[nwid].SumE();
      double noe = m_Regions[nid].SumE();
      double nee = m_Regions[neid].SumE();
      double wee = m_Regions[wid].SumE();
      double eae = m_Regions[eid].SumE();
      double swe = m_Regions[swid].SumE();
      double soe = m_Regions[sid].SumE();
      double see = m_Regions[seid].SumE();

      // if region is central: jet energy is sum of 3x3 region
      // surrounding the central region
      double jE = cene + nwe + noe + nee + wee + eae + swe + soe + see;
      double jEt = cenet + nwet + noet + neet + weet + eaet + swet + soet + seet;


      m_Regions.at(crgn).SetJetE(jE);
      m_Regions.at(crgn).SetJetEt(jEt);

      m_Regions.at(crgn).SetJetE3x3(cene);
      m_Regions.at(crgn).SetJetEt3x3(cenet);
      
      return true;
    } else { return false; }

}

bool FastL1GlobalAlgo::isTauJet ( int  rgnid )

private

Definition at line 843 of file FastL1GlobalAlgo.cc.

References m_DoBitInfo, and m_Regions.

Referenced by findJets().

                                   {

  // Barrel and Endcap only
  if ((cRgn%22)<4 || (cRgn%22)>17)  
    return false;

  int shower_shape = 0; 
  int et_isolation = 0;

  if (m_Regions[cRgn].GetTauBit()) {
    shower_shape = 1;
    //if (m_DoBitInfo) m_Regions[cRgn].BitInfo.setTauVeto(true);     
  } else {
    shower_shape = 0;
    //if (m_DoBitInfo) m_Regions[cRgn].BitInfo.setTauVeto(false);    
  }

  int nwid = m_Regions[cRgn].GetNWId();
  int nid = m_Regions[cRgn].GetNorthId();
  int neid = m_Regions[cRgn].GetNEId();
  int wid = m_Regions[cRgn].GetWestId();
  int eid = m_Regions[cRgn].GetEastId();
  int swid = m_Regions[cRgn].GetSWId();
  int sid = m_Regions[cRgn].GetSouthId();
  int seid = m_Regions[cRgn].GetSEId();

  //Use 3x2 window at eta borders!
  // west border:
  if ((cRgn%22)==4) { 
    if (m_Regions[nid].GetTauBit()  ||
    m_Regions[neid].GetTauBit() ||
    m_Regions[eid].GetTauBit()  ||
    m_Regions[seid].GetTauBit() ||
    m_Regions[sid].GetTauBit() ) {
      et_isolation = 1;
    }    
  }
  
  // east border:
  if ((cRgn%22)==17) { 
    if (m_Regions[nid].GetTauBit()  ||
    m_Regions[nwid].GetTauBit() ||
    m_Regions[wid].GetTauBit()  ||
    m_Regions[swid].GetTauBit() ||
    m_Regions[sid].GetTauBit() ) {
      et_isolation = 1;
    }    
  }

  if ( (cRgn%22)>4 && (cRgn%22)<17){ // non-border
    if (nwid==999 || neid==999 || nid==999 || swid==999 || seid==999 || sid==999 || wid==999 || 
    eid==999 ) { 
      return false;
    }
    
    if (m_Regions[nwid].GetTauBit() ||
    m_Regions[nid].GetTauBit()  ||
    m_Regions[neid].GetTauBit() ||
    m_Regions[wid].GetTauBit()  ||
    m_Regions[eid].GetTauBit()  ||
    m_Regions[swid].GetTauBit() ||
    m_Regions[seid].GetTauBit() ||
    m_Regions[sid].GetTauBit()  ) {
      et_isolation = 1; 
    }    
  } // non-border

  if (m_DoBitInfo) {
    if (et_isolation == 1) {
      //std::cout<<"*********************************"<<std::endl;
      //std::cout<<"Rgn iso veto: "<<et_isolation<<std::endl;
      m_Regions[cRgn].BitInfo.setIsolationVeto(true);   
    } else {
      m_Regions[cRgn].BitInfo.setIsolationVeto(false);  
    }
    //    if (shower_shape == 1) {
    //std::cout<<"###############################"<<std::endl;
    //std::cout<<"Rgn shower veto: "<<shower_shape<<std::endl;
    //}
  }
  
  if (et_isolation == 1 || shower_shape == 1) return false;
  else return true;

}

bool FastL1GlobalAlgo::TauIsolation ( int  rgnid )

private

Definition at line 1371 of file FastL1GlobalAlgo.cc.

References m_DoBitInfo, m_IsolationEt, and m_Regions.

Referenced by findJets().

                                       {     
         
  if ((cRgn%22)<4 || (cRgn%22)>17) return false;     
         
  double iso_threshold =  m_IsolationEt; // arbitrarily set      
  int shower_shape = 0;      
  int et_isolation = 0;      
  unsigned int iso_count = 0;    
         
  int nwid = m_Regions[cRgn].GetNWId();      
  int nid = m_Regions[cRgn].GetNorthId();    
  int neid = m_Regions[cRgn].GetNEId();      
  int wid = m_Regions[cRgn].GetWestId();     
  int eid = m_Regions[cRgn].GetEastId();     
  int swid = m_Regions[cRgn].GetSWId();      
  int sid = m_Regions[cRgn].GetSouthId();    
  int seid = m_Regions[cRgn].GetSEId();      
         
  if (m_Regions[cRgn].GetTauBit()) {  // check center 
    shower_shape = 1;    
    //if (m_DoBitInfo) m_Regions[cRgn].BitInfo.setTauVeto(true);     
  } 

  if((cRgn%22)==4  || (cRgn%22)==17 ) {      
    // west border   
    if ((cRgn%22)==4) {      
      if( m_Regions[neid].SumEt() > iso_threshold){      
    iso_count ++;    
    if (m_Regions[neid].GetTauBit()) iso_count++;    
      }      
      if( m_Regions[nid].SumEt() > iso_threshold){   
    iso_count ++;    
    if (m_Regions[nid].GetTauBit()) iso_count++;     
      }      
      if( m_Regions[eid].SumEt() > iso_threshold){   
    iso_count ++;    
    if (m_Regions[eid].GetTauBit()) iso_count++;     
      }      
      if( m_Regions[seid].SumEt() > iso_threshold){      
    iso_count ++;    
    if (m_Regions[seid].GetTauBit()) iso_count++;    
      }      
      if( m_Regions[sid].SumEt() > iso_threshold){   
    iso_count ++;    
    if (m_Regions[sid].GetTauBit()) iso_count++;     
      }      
    } // west bd     
         
    // east border:      
    if ((cRgn%22)==17) {     
      if( m_Regions[nwid].SumEt() > iso_threshold){      
    iso_count ++;    
    if (m_Regions[nwid].GetTauBit()) iso_count++;    
      }      
      if( m_Regions[nid].SumEt() > iso_threshold){   
    iso_count ++;    
    if (m_Regions[nid].GetTauBit()) iso_count++;     
      }      
      if( m_Regions[wid].SumEt() > iso_threshold){   
    iso_count ++;    
    if (m_Regions[wid].GetTauBit()) iso_count++;     
      }      
      if( m_Regions[swid].SumEt() > iso_threshold){      
    iso_count ++;    
    if (m_Regions[swid].GetTauBit()) iso_count++;    
      }      
      if( m_Regions[sid].SumEt() > iso_threshold){   
    iso_count ++;    
    if (m_Regions[sid].GetTauBit()) iso_count++;     
      }      
    } // east bd     
         
  }      
         
  if ( (cRgn%22)>4 && (cRgn%22)<17){ // non-border   
    if (nwid==999 || neid==999 || nid==999 || swid==999 || seid==999 || sid==999 || wid==999 ||      
    eid==999 ) {     
      return false;      
    }    
         
    if( m_Regions[neid].SumEt() > iso_threshold){    
      iso_count ++;      
      if (m_Regions[neid].GetTauBit()) iso_count++;      
    }    
    if( m_Regions[nid].SumEt() > iso_threshold){     
      iso_count ++;      
      if (m_Regions[nid].GetTauBit()) iso_count++;   
    }    
    if( m_Regions[eid].SumEt() > iso_threshold){     
      iso_count ++;      
      if (m_Regions[eid].GetTauBit()) iso_count++;   
    }    
    if( m_Regions[seid].SumEt() > iso_threshold){    
      iso_count ++;      
      if (m_Regions[seid].GetTauBit()) iso_count++;      
    }    
    if( m_Regions[sid].SumEt() > iso_threshold){     
      iso_count ++;      
      if (m_Regions[sid].GetTauBit()) iso_count++;   
    }    
    if( m_Regions[nwid].SumEt() > iso_threshold){    
      iso_count ++;      
      if (m_Regions[nwid].GetTauBit()) iso_count++;      
    }    
    if( m_Regions[wid].SumEt() > iso_threshold){     
      iso_count ++;      
      if (m_Regions[wid].GetTauBit()) iso_count++;   
    }    
    if( m_Regions[swid].SumEt() > iso_threshold){    
      iso_count ++;      
      if (m_Regions[swid].GetTauBit()) iso_count++;      
    }    
  }// non-border     
         
         
  if (iso_count >= 2 ){      
    et_isolation = 1;    
  }      
  else {
    et_isolation = 0;
  }      
         
  if (m_DoBitInfo){      
    if (et_isolation == 1) 
      m_Regions[cRgn].BitInfo.setIsolationVeto (true);   
    else
      m_Regions[cRgn].BitInfo.setIsolationVeto (false);      
  }      

  if (et_isolation == 1 || shower_shape == 1) return false; 
  else return true;
  
}//

Member Data Documentation

FastL1BitInfoCollection FastL1GlobalAlgo::m_BitInfos

private

Definition at line 125 of file FastL1GlobalAlgo.h.

Referenced by FillBitInfos(), and getBitInfos().

l1extra::L1JetParticleCollection FastL1GlobalAlgo::m_CenJets

private

Definition at line 121 of file FastL1GlobalAlgo.h.

Referenced by addJet(), findJets(), and getCenJets().

bool FastL1GlobalAlgo::m_DoBitInfo

private

Definition at line 129 of file FastL1GlobalAlgo.h.

Referenced by addJet(), FastL1GlobalAlgo(), FillBitInfos(), findJets(), InitL1Regions(), isTauJet(), and TauIsolation().

l1extra::L1EmParticleCollection FastL1GlobalAlgo::m_Egammas

private

Definition at line 123 of file FastL1GlobalAlgo.h.

Referenced by FillEgammas(), FillEgammasTP(), and getEgammas().

l1extra::L1JetParticleCollection FastL1GlobalAlgo::m_ForJets

private

Definition at line 122 of file FastL1GlobalAlgo.h.

Referenced by addJet(), findJets(), and getForJets().

bool FastL1GlobalAlgo::m_GctIso

private

Definition at line 131 of file FastL1GlobalAlgo.h.

Referenced by FastL1GlobalAlgo(), and findJets().

double FastL1GlobalAlgo::m_hcaluncomp[33][256]

private

Definition at line 135 of file FastL1GlobalAlgo.h.

Referenced by FastL1GlobalAlgo(), and hcaletValue().

l1extra::L1EmParticleCollection FastL1GlobalAlgo::m_isoEgammas

private

Definition at line 124 of file FastL1GlobalAlgo.h.

Referenced by FillEgammas(), FillEgammasTP(), and getisoEgammas().

double FastL1GlobalAlgo::m_IsolationEt

private

Definition at line 132 of file FastL1GlobalAlgo.h.

Referenced by FastL1GlobalAlgo(), and TauIsolation().

L1Config FastL1GlobalAlgo::m_L1Config

private

Definition at line 134 of file FastL1GlobalAlgo.h.

Referenced by addJet(), CaloTowersDump(), FastL1GlobalAlgo(), FillEgammas(), FillL1Regions(), FillL1RegionsTP(), FillMET(), findJets(), InitL1Regions(), and isEMCand().

l1extra::L1EtMissParticleCollection FastL1GlobalAlgo::m_METs

private

Definition at line 119 of file FastL1GlobalAlgo.h.

Referenced by FillMET(), and getMET().

std::vector<FastL1Region> FastL1GlobalAlgo::m_Regions

private

Definition at line 127 of file FastL1GlobalAlgo.h.

Referenced by addJet(), FastL1GlobalAlgo(), FillBitInfos(), FillEgammasTP(), FillL1Regions(), FillL1RegionsTP(), FillMET(), findJets(), GetCaloRegions(), InitL1Regions(), isEMCand(), isMaxEtRgn_Window33(), isTauJet(), and TauIsolation().

FastL1RegionMap* FastL1GlobalAlgo::m_RMap

private

Definition at line 128 of file FastL1GlobalAlgo.h.

Referenced by addJet(), checkMapping(), FastL1GlobalAlgo(), FillL1Regions(), FillL1RegionsTP(), FillMET(), findJets(), InitL1Regions(), and isEMCand().

l1extra::L1JetParticleCollection FastL1GlobalAlgo::m_TauJets

private

Definition at line 120 of file FastL1GlobalAlgo.h.

Referenced by addJet(), findJets(), and getTauJets().