43 inputPFlowLabel_tok_ = consumes<reco::PFCandidateCollection> (iConfig.
getParameter<
std::string>(
"InputPFlowLabel") );
46 if (outputFile_.size() > 0)
47 edm::LogInfo(
"OutputInfo") <<
" ParticleFLow Task histograms will be saved to '" << outputFile_.c_str() <<
"'";
48 else edm::LogInfo(
"OutputInfo") <<
" ParticleFlow Task histograms will NOT be saved";
63 dbe_->setCurrentFolder(
"PFTask/PFCandidates");
65 me[
"CandidateEt"] =
dbe_->book1D(
"CandidateEt",
"CandidateEt",1000,0,1000);
66 me[
"CandidateEta"] =
dbe_->book1D(
"CandidateEta",
"CandidateEta",200,-5,5);
67 me[
"CandidatePhi"] =
dbe_->book1D(
"CandidatePhi",
"CandidatePhi",200,-
M_PI,
M_PI);
68 me[
"CandidateCharge"] =
dbe_->book1D(
"CandidateCharge",
"CandidateCharge",5,-2,2);
69 me[
"PFCandidateType"] =
dbe_->book1D(
"PFCandidateType",
"PFCandidateType",10,0,10);
71 dbe_->setCurrentFolder(
"PFTask/PFBlocks");
73 me[
"NumElements"] =
dbe_->book1D(
"NumElements",
"NumElements",25,0,25);
74 me[
"NumTrackElements"] =
dbe_->book1D(
"NumTrackElements",
"NumTrackElements",5,0,5);
75 me[
"NumPS1Elements"] =
dbe_->book1D(
"NumPS1Elements",
"NumPS1Elements",5,0,5);
76 me[
"NumPS2Elements"] =
dbe_->book1D(
"NumPS2Elements",
"NumPS2Elements",5,0,5);
77 me[
"NumECALElements"] =
dbe_->book1D(
"NumECALElements",
"NumECALElements",5,0,5);
78 me[
"NumHCALElements"] =
dbe_->book1D(
"NumHCALElements",
"NumHCALElements",5,0,5);
79 me[
"NumMuonElements"] =
dbe_->book1D(
"NumMuonElements",
"NumMuonElements",5,0,5);
81 dbe_->setCurrentFolder(
"PFTask/PFTracks");
83 me[
"TrackCharge"] =
dbe_->book1D(
"TrackCharge",
"TrackCharge",5,-2,2);
84 me[
"TrackNumPoints"] =
dbe_->book1D(
"TrackNumPoints",
"TrackNumPoints",100,0,100);
85 me[
"TrackNumMeasurements"] =
dbe_->book1D(
"TrackNumMeasurements",
"TrackNumMeasurements",100,0,100);
86 me[
"TrackImpactParameter"] =
dbe_->book1D(
"TrackImpactParameter",
"TrackImpactParameter",1000,0,1);
88 dbe_->setCurrentFolder(
"PFTask/PFClusters");
110 iEvent.
getByToken(inputPFlowLabel_tok_, pflow_hnd);
111 pflow_candidates = pflow_hnd.
product();
115 if (!pflow_candidates) {
117 edm::LogInfo(
"OutputInfo") <<
" failed to retrieve data required by ParticleFlow Task";
118 edm::LogInfo(
"OutputInfo") <<
" ParticleFlow Task cannot continue...!";
128 PFCandidateCollection::const_iterator pf;
129 for (pf = pflow_candidates->begin(); pf != pflow_candidates->end(); pf++) {
134 me[
"CandidateEt"]->Fill(particle->
et());
135 me[
"CandidateEta"]->Fill(particle->
eta());
136 me[
"CandidatePhi"]->Fill(particle->
phi());
137 me[
"CandidateCharge"]->Fill(particle->
charge());
138 me[
"CandidatePdgId"]->Fill(particle->
pdgId());
218 if (outputFile_.size() > 0 &&
dbe_)
219 dbe_->save(outputFile_);
T getParameter(std::string const &) const
T getUntrackedParameter(std::string const &, T const &) const
bool getByToken(EDGetToken token, Handle< PROD > &result) const
virtual double phi() const final
momentum azimuthal angle
virtual void analyze(const edm::Event &, const edm::EventSetup &)
virtual int charge() const final
electric charge
std::vector< reco::PFCandidate > PFCandidateCollection
collection of PFCandidates
T const * product() const
virtual int pdgId() const final
PDG identifier.
Particle reconstructed by the particle flow algorithm.
virtual double et() const final
transverse energy
virtual double eta() const final
momentum pseudorapidity
virtual ParticleType particleId() const
PFTester(const edm::ParameterSet &)