GsfEleHadronicOverEMEnergyScaledCut.cc

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#include "PhysicsTools/SelectorUtils/interface/CutApplicatorWithEventContentBase.h"
#include "DataFormats/EgammaCandidates/interface/GsfElectron.h"
 
class GsfEleHadronicOverEMEnergyScaledCut : public CutApplicatorWithEventContentBase {
public:
  GsfEleHadronicOverEMEnergyScaledCut(const edm::ParameterSet& c)
      : CutApplicatorWithEventContentBase(c),
        barrelC0_(c.getParameter<double>("barrelC0")),
        barrelCE_(c.getParameter<double>("barrelCE")),
        barrelCr_(c.getParameter<double>("barrelCr")),
        endcapC0_(c.getParameter<double>("endcapC0")),
        endcapCE_(c.getParameter<double>("endcapCE")),
        endcapCr_(c.getParameter<double>("endcapCr")),
        barrelCutOff_(c.getParameter<double>("barrelCutOff")) {
    edm::InputTag rhoTag = c.getParameter<edm::InputTag>("rho");
    contentTags_.emplace("rho", rhoTag);
  }
 
  result_type operator()(const reco::GsfElectronPtr&) const final;
 
  void setConsumes(edm::ConsumesCollector&) final;
  void getEventContent(const edm::EventBase&) final;
 
  double value(const reco::CandidatePtr& cand) const final;
 
  CandidateType candidateType() const final { return ELECTRON; }
 
private:
  const float barrelC0_, barrelCE_, barrelCr_, endcapC0_, endcapCE_, endcapCr_, barrelCutOff_;
  edm::Handle<double> rhoHandle_;
};
 
DEFINE_EDM_PLUGIN(CutApplicatorFactory, GsfEleHadronicOverEMEnergyScaledCut, "GsfEleHadronicOverEMEnergyScaledCut");
 
void GsfEleHadronicOverEMEnergyScaledCut::setConsumes(edm::ConsumesCollector& cc) {
  auto rho = cc.consumes<double>(contentTags_["rho"]);
  contentTokens_.emplace("rho", rho);
}
 
void GsfEleHadronicOverEMEnergyScaledCut::getEventContent(const edm::EventBase& ev) {
  ev.getByLabel(contentTags_["rho"], rhoHandle_);
}
 
CutApplicatorBase::result_type GsfEleHadronicOverEMEnergyScaledCut::operator()(const reco::GsfElectronPtr& cand) const {
  const double rho = rhoHandle_.isValid() ? (float)(*rhoHandle_) : 0;
  const float energy = cand->superCluster()->energy();
  const float c0 = (std::abs(cand->superCluster()->position().eta()) < barrelCutOff_ ? barrelC0_ : endcapC0_);
  const float cE = (std::abs(cand->superCluster()->position().eta()) < barrelCutOff_ ? barrelCE_ : endcapCE_);
  const float cR = (std::abs(cand->superCluster()->position().eta()) < barrelCutOff_ ? barrelCr_ : endcapCr_);
  return cand->hadronicOverEm() < c0 + cE / energy + cR * rho / energy;
}
 
double GsfEleHadronicOverEMEnergyScaledCut::value(const reco::CandidatePtr& cand) const {
  reco::GsfElectronPtr ele(cand);
  return ele->hadronicOverEm();
}