57 electronToken_(consumes<
edm::
View<
reco::GsfElectron> >(iConfig.getParameter<
edm::InputTag>(
"electronSource" ))),
59 embedGsfElectronCore_(iConfig.getParameter<bool>(
"embedGsfElectronCore" )),
60 embedGsfTrack_(iConfig.getParameter<bool>(
"embedGsfTrack" )),
61 embedSuperCluster_(iConfig.getParameter<bool> (
"embedSuperCluster" )),
62 embedPflowSuperCluster_(iConfig.getParameter<bool> (
"embedPflowSuperCluster" )),
63 embedSeedCluster_(iConfig.getParameter<bool>(
"embedSeedCluster" )),
64 embedBasicClusters_(iConfig.getParameter<bool>(
"embedBasicClusters" )),
65 embedPreshowerClusters_(iConfig.getParameter<bool>(
"embedPreshowerClusters" )),
66 embedPflowBasicClusters_(iConfig.getParameter<bool>(
"embedPflowBasicClusters" )),
67 embedPflowPreshowerClusters_(iConfig.getParameter<bool>(
"embedPflowPreshowerClusters" )),
68 embedTrack_(iConfig.getParameter<bool>(
"embedTrack" )),
69 addGenMatch_(iConfig.getParameter<bool>(
"addGenMatch" )),
70 embedGenMatch_(addGenMatch_ ? iConfig.getParameter<bool>(
"embedGenMatch" ) :
false),
71 embedRecHits_(iConfig.getParameter<bool>(
"embedRecHits" )),
73 useParticleFlow_(iConfig.getParameter<bool>(
"useParticleFlow" )),
74 usePfCandidateMultiMap_(iConfig.getParameter<bool>(
"usePfCandidateMultiMap" )),
78 embedPFCandidate_(iConfig.getParameter<bool>(
"embedPFCandidate" )),
80 reducedBarrelRecHitCollection_(iConfig.getParameter<
edm::InputTag>(
"reducedBarrelRecHitCollection")),
81 reducedBarrelRecHitCollectionToken_(mayConsume<
EcalRecHitCollection>(reducedBarrelRecHitCollection_)),
82 reducedEndcapRecHitCollection_(iConfig.getParameter<
edm::InputTag>(
"reducedEndcapRecHitCollection")),
83 reducedEndcapRecHitCollectionToken_(mayConsume<
EcalRecHitCollection>(reducedEndcapRecHitCollection_)),
85 addPFClusterIso_(iConfig.getParameter<bool>(
"addPFClusterIso")),
86 addPuppiIsolation_(iConfig.getParameter<bool>(
"addPuppiIsolation")),
87 ecalPFClusterIsoT_(consumes<
edm::ValueMap<
float> >(iConfig.getParameter<
edm::InputTag>(
"ecalPFClusterIsoMap"))),
88 hcalPFClusterIsoT_(consumes<
edm::ValueMap<
float> >(iConfig.getParameter<
edm::InputTag>(
"hcalPFClusterIsoMap"))),
90 embedHighLevelSelection_(iConfig.getParameter<bool>(
"embedHighLevelSelection")),
91 beamLineToken_(consumes<
reco::
BeamSpot>(iConfig.getParameter<
edm::InputTag>(
"beamLineSrc"))),
92 pvToken_(mayConsume<
std::vector<
reco::Vertex> >(iConfig.getParameter<
edm::InputTag>(
"pvSrc"))),
93 addElecID_(iConfig.getParameter<bool>(
"addElectronID" )),
96 addEfficiencies_(iConfig.getParameter<bool>(
"addEfficiencies")),
97 addResolutions_(iConfig.getParameter<bool>(
"addResolutions" )),
98 useUserData_(iConfig.exists(
"userData"))
135 throw cms::Exception(
"Configuration") <<
"PATElectronProducer: you can't specify both 'electronIDSource' and 'electronIDSources'\n";
140 for (std::vector<std::string>::const_iterator it = names.begin(), ed = names.end(); it != ed; ++it) {
147 "PATElectronProducer: id addElectronID is true, you must specify either:\n" <<
148 "\tInputTag electronIDSource = <someTag>\n" <<
"or\n" <<
149 "\tPSet electronIDSources = { \n" <<
150 "\t\tInputTag <someName> = <someTag> // as many as you want \n " <<
180 if(computeMiniIso_ && (miniIsoParamsE_.size() != 9 || miniIsoParamsB_.size() != 9)){
181 throw cms::Exception(
"ParameterError") <<
"miniIsoParams must have exactly 9 elements.\n";
205 produces<std::vector<Electron> >();
235 edm::InputTag reducedEBRecHitCollection(
string(
"reducedEcalRecHitsEB"));
236 edm::InputTag reducedEERecHitCollection(
string(
"reducedEcalRecHitsEE"));
277 std::vector<edm::Handle<edm::ValueMap<float> > > idhandles;
278 std::vector<pat::Electron::IdPair> ids;
294 bool beamSpotIsValid =
false;
295 bool primaryVertexIsValid =
false;
309 if ( pvHandle.
isValid() && !pvHandle->empty() ) {
310 primaryVertex = pvHandle->at(0);
311 primaryVertexIsValid =
true;
314 <<
"No primary vertex available from EventSetup, not adding high level selection \n";
337 std::vector<Electron> *
patElectrons =
new std::vector<Electron>();
345 i != pfElectrons->end(); ++
i, ++
index) {
354 bool MatchedToAmbiguousGsfTrack=
false;
356 unsigned int idx = itElectron - electrons->begin();
357 auto elePtr = electrons -> ptrAt(idx);
358 if (Matched || MatchedToAmbiguousGsfTrack)
continue;
362 if (itElectron->gsfTrack()==
i->gsfTrackRef()){
367 it!=itElectron->ambiguousGsfTracksEnd(); it++ ){
368 MatchedToAmbiguousGsfTrack |= (bool)(
i->gsfTrackRef()==(*it));
372 if (Matched || MatchedToAmbiguousGsfTrack){
382 anElectron.
setIsolationPUPPI((*PUPPIIsolation_charged_hadrons)[elePtr], (*PUPPIIsolation_neutral_hadrons)[elePtr], (*PUPPIIsolation_photons)[elePtr]);
383 anElectron.
setIsolationPUPPINoLeptons((*PUPPINoLeptonsIsolation_charged_hadrons)[elePtr], (*PUPPINoLeptonsIsolation_neutral_hadrons)[elePtr], (*PUPPINoLeptonsIsolation_photons)[elePtr]);
414 primaryVertexIsValid,
419 ip3d = ip3dpv.second.value();
428 ids[
i].second = (*idhandles[
i])[elecsRef];
431 ids.push_back(std::make_pair(
"pf_evspi",pfRef->mva_e_pi()));
432 ids.push_back(std::make_pair(
"pf_evsmu",pfRef->mva_e_mu()));
437 std::vector<float> vCov = lazyTools.localCovariances(*( itElectron->superCluster()->seed()));
454 std::vector<DetId> selectedCells;
455 bool barrel = itElectron->isEB();
458 for (
reco::CaloCluster_iterator clusIt = itElectron->superCluster()->clustersBegin(); clusIt!=itElectron->superCluster()->clustersEnd(); ++clusIt) {
460 DetId seed = lazyTools.getMaximum(**clusIt).first;
464 selectedCells.insert(selectedCells.end(), dets5x5.begin(), dets5x5.end());
467 for (
const std::pair<DetId, float> &
hit : (*clusIt)->hitsAndFractions()) {
468 selectedCells.push_back(
hit.first);
474 for (
reco::CaloCluster_iterator clusIt = itElectron->parentSuperCluster()->clustersBegin(); clusIt!=itElectron->parentSuperCluster()->clustersEnd(); ++clusIt) {
476 DetId seed = lazyTools.getMaximum(**clusIt).first;
480 selectedCells.insert(selectedCells.end(), dets5x5.begin(), dets5x5.end());
483 for (
const std::pair<DetId, float> &
hit : (*clusIt)->hitsAndFractions()) {
484 selectedCells.push_back(
hit.first);
490 std::sort(selectedCells.begin(),selectedCells.end());
491 std::unique(selectedCells.begin(),selectedCells.end());
505 unsigned nSelectedCells = selectedCells.
size();
506 for (
unsigned icell = 0 ; icell < nSelectedCells ; ++icell) {
508 if ( it != recHits->
end() ) {
512 selectedRecHits.
sort();
516 bool passconversionveto =
false;
550 patElectrons->push_back(anElectron);
561 bool pfCandsPresent =
false, valMapPresent =
false;
572 unsigned int idx = itElectron - electrons->begin();
576 auto elePtr = electrons -> ptrAt(idx);
589 }
else if ( pfCandsPresent ) {
594 ie != pfElectrons->end(); ++ie, ++
index) {
597 if( trkRef == pfTrkRef ) {
605 else if( valMapPresent ) {
627 for (
size_t j = 0, nd =
deposits.size(); j < nd; ++j) {
634 ids[
i].second = (*idhandles[
i])[elecsRef];
660 primaryVertexIsValid,
665 ip3d = ip3dpv.second.value();
671 std::vector<float> vCov = lazyTools.localCovariances(*( itElectron->superCluster()->seed()));
688 anElectron.
setIsolationPUPPI((*PUPPIIsolation_charged_hadrons)[elePtr], (*PUPPIIsolation_neutral_hadrons)[elePtr], (*PUPPIIsolation_photons)[elePtr]);
689 anElectron.
setIsolationPUPPINoLeptons((*PUPPINoLeptonsIsolation_charged_hadrons)[elePtr], (*PUPPINoLeptonsIsolation_neutral_hadrons)[elePtr], (*PUPPINoLeptonsIsolation_photons)[elePtr]);
696 std::vector<DetId> selectedCells;
697 bool barrel = itElectron->isEB();
700 for (
reco::CaloCluster_iterator clusIt = itElectron->superCluster()->clustersBegin(); clusIt!=itElectron->superCluster()->clustersEnd(); ++clusIt) {
702 DetId seed = lazyTools.getMaximum(**clusIt).first;
706 selectedCells.insert(selectedCells.end(), dets5x5.begin(), dets5x5.end());
709 for (
const std::pair<DetId, float> &
hit : (*clusIt)->hitsAndFractions()) {
710 selectedCells.push_back(
hit.first);
716 for (
reco::CaloCluster_iterator clusIt = itElectron->parentSuperCluster()->clustersBegin(); clusIt!=itElectron->parentSuperCluster()->clustersEnd(); ++clusIt) {
718 DetId seed = lazyTools.getMaximum(**clusIt).first;
722 selectedCells.insert(selectedCells.end(), dets5x5.begin(), dets5x5.end());
725 for (
const std::pair<DetId, float> &
hit : (*clusIt)->hitsAndFractions()) {
726 selectedCells.push_back(
hit.first);
732 std::sort(selectedCells.begin(),selectedCells.end());
733 std::unique(selectedCells.begin(),selectedCells.end());
746 unsigned nSelectedCells = selectedCells.
size();
747 for (
unsigned icell = 0 ; icell < nSelectedCells ; ++icell) {
749 if ( it != recHits->
end() ) {
753 selectedRecHits.
sort();
757 bool passconversionveto =
false;
774 patElectrons->push_back(anElectron);
779 std::sort(patElectrons->begin(), patElectrons->end(),
pTComparator_);
782 std::unique_ptr<std::vector<Electron> > ptr(patElectrons);
830 for(
size_t i = 0,
n = genMatches.size();
i <
n; ++
i) {
851 for (
size_t j = 0, nd = deposits.size(); j < nd; ++j) {
855 assert(!pfcandref.
isNull());
858 (*deposits[j])[source]);
862 (*deposits[j])[elecRef]);
865 for (
size_t j = 0; j<isolationValues.size(); ++j) {
869 (*isolationValues[j])[source]);
878 for (
size_t j = 0; j<isolationValuesNoPFId.size(); ++j) {
916 for(
size_t i = 0,
n = genMatches.size();
i <
n; ++
i) {
932 for (
size_t j = 0, nd = deposits.size(); j < nd; ++j) {
936 deposits[j]->
contains(candPtrForGenMatch.
id())) {
938 (*deposits[j])[candPtrForGenMatch]);
940 else if (deposits[j]->
contains(candPtrForIsolation.
id())) {
942 (*deposits[j])[candPtrForIsolation]);
946 (*deposits[j])[candPtrForIsolation->sourceCandidatePtr(0)]);
950 for (
size_t j = 0; j<isolationValues.size(); ++j) {
954 isolationValues[j]->
contains(candPtrForGenMatch.
id())) {
956 (*isolationValues[j])[candPtrForGenMatch]);
958 else if (isolationValues[j]->
contains(candPtrForIsolation.
id())) {
960 (*isolationValues[j])[candPtrForIsolation]);
964 (*isolationValues[j])[candPtrForIsolation->sourceCandidatePtr(0)]);
972 if(anElectron.
isEE())
975 miniIsoParamsE_[3], miniIsoParamsE_[4], miniIsoParamsE_[5],
976 miniIsoParamsE_[6], miniIsoParamsE_[7], miniIsoParamsE_[8]);
980 miniIsoParamsB_[3], miniIsoParamsB_[4], miniIsoParamsB_[5],
981 miniIsoParamsB_[6], miniIsoParamsB_[7], miniIsoParamsB_[8]);
990 iDesc.
setComment(
"PAT electron producer module");
1013 iDesc.
add<
bool>(
"embedGsfElectronCore",
true)->setComment(
"embed external gsf electron core");
1014 iDesc.
add<
bool>(
"embedGsfTrack",
true)->setComment(
"embed external gsf track");
1015 iDesc.
add<
bool>(
"embedSuperCluster",
true)->setComment(
"embed external super cluster");
1016 iDesc.
add<
bool>(
"embedPflowSuperCluster",
true)->setComment(
"embed external super cluster");
1017 iDesc.
add<
bool>(
"embedSeedCluster",
true)->setComment(
"embed external seed cluster");
1018 iDesc.
add<
bool>(
"embedBasicClusters",
true)->setComment(
"embed external basic clusters");
1019 iDesc.
add<
bool>(
"embedPreshowerClusters",
true)->setComment(
"embed external preshower clusters");
1020 iDesc.
add<
bool>(
"embedPflowBasicClusters",
true)->setComment(
"embed external pflow basic clusters");
1021 iDesc.
add<
bool>(
"embedPflowPreshowerClusters",
true)->setComment(
"embed external pflow preshower clusters");
1022 iDesc.
add<
bool>(
"embedTrack",
false)->setComment(
"embed external track");
1023 iDesc.
add<
bool>(
"embedRecHits",
true)->setComment(
"embed external RecHits");
1028 usePfCandidateMultiMap.setComment(
"take ParticleFlow candidates from pfCandidateMultiMap instead of matching to pfElectrons by Gsf track reference");
1032 iDesc.
add<
bool>(
"useParticleFlow",
false)->setComment(
"whether to use particle flow or not");
1033 iDesc.
add<
bool>(
"embedPFCandidate",
false)->setComment(
"embed external particle flow object");
1036 iDesc.
add<
bool>(
"addGenMatch",
true)->setComment(
"add MC matching");
1037 iDesc.
add<
bool>(
"embedGenMatch",
false)->setComment(
"embed MC matched MC information");
1038 std::vector<edm::InputTag> emptySourceVector;
1041 )->
setComment(
"input with MC match information");
1044 iDesc.
add<
bool>(
"addElectronID",
true)->setComment(
"add electron ID variables");
1049 )->
setComment(
"input with electron ID variables");
1053 iDesc.
add<
bool>(
"computeMiniIso",
false)->setComment(
"whether or not to compute and store electron mini-isolation");
1055 iDesc.
add<std::vector<double> >(
"miniIsoParamsE", std::vector<double>())->
setComment(
"mini-iso parameters to use for endcap electrons");
1056 iDesc.
add<std::vector<double> >(
"miniIsoParamsB", std::vector<double>())->
setComment(
"mini-iso parameters to use for barrel electrons");
1069 isoDepositsPSet.
addOptional<std::vector<edm::InputTag> >(
"user");
1070 iDesc.
addOptional(
"isoDeposits", isoDepositsPSet);
1083 isolationValuesPSet.
addOptional<std::vector<edm::InputTag> >(
"user");
1084 iDesc.
addOptional(
"isolationValues", isolationValuesPSet);
1097 isolationValuesNoPFIdPSet.
addOptional<std::vector<edm::InputTag> >(
"user");
1098 iDesc.
addOptional(
"isolationValuesNoPFId", isolationValuesNoPFIdPSet);
1103 iDesc.
add(
"efficiencies", efficienciesPSet);
1104 iDesc.
add<
bool>(
"addEfficiencies",
false);
1113 iDesc.
add<
bool>(
"addElectronShapes",
true);
1119 iDesc.
add(
"userIsolation", isolationPSet);
1124 iDesc.
add<
bool>(
"embedHighLevelSelection",
true)->setComment(
"embed high level selection");
1128 )->
setComment(
"input with high level selection");
1130 )->
setComment(
"input with high level selection");
1132 descriptions.
add(
"PATElectronProducer", iDesc);
1143 bool primaryVertexIsValid,
1145 bool beamspotIsValid
1151 std::pair<bool,Measurement1D>
result =
1157 double d0_corr = result.second.value();
1158 double d0_err = primaryVertexIsValid ? result.second.error() : -1.0;
1169 d0_corr = result.second.value();
1170 d0_err = primaryVertexIsValid ? result.second.error() : -1.0;
1185 d0_corr = result.second.value();
1186 d0_err = beamspotIsValid ? result.second.error() : -1.0;
1196 d0_corr = result.second.value();
1197 d0_err = beamspotIsValid ? result.second.error() : -1.0;
void readIsolationLabels(const edm::ParameterSet &iConfig, const char *psetName, IsolationLabels &labels, std::vector< edm::EDGetTokenT< edm::ValueMap< T > > > &tokens)
void setMvaVariables(double sigmaIetaIphi, double ip3d)
set missing mva input variables
bool enabled() const
'true' if this there is at least one efficiency configured
T getParameter(std::string const &) const
void setComment(std::string const &value)
Assists in assimilating all pat::UserData into pat objects.
void embedRecHits(const EcalRecHitCollection *rechits)
method to store the RecHits internally - can be called from the PATElectronProducer ...
void newEvent(const edm::Event &event)
To be called for each new event, reads in the ValueMaps for efficiencies.
void setP4(P4Kind kind, const LorentzVector &p4, float p4Error, bool setCandidate)
OrphanHandle< PROD > put(std::unique_ptr< PROD > product)
Put a new product.
ParameterDescriptionBase * addOptional(U const &iLabel, T const &value)
const edm::EDGetTokenT< reco::ConversionCollection > hConversionsToken_
bool isNonnull() const
Checks for non-null.
edm::EDGetTokenT< edm::ValueMap< float > > PUPPINoLeptonsIsolation_charged_hadrons_
void setIsolation(IsolationKeys key, float value)
const GreaterByPt< Electron > pTComparator_
bool existsAs(std::string const ¶meterName, bool trackiness=true) const
checks if a parameter exists as a given type
bool contains(EventRange const &lh, EventID const &rh)
edm::EDGetTokenT< edm::ValueMap< float > > PUPPIIsolation_charged_hadrons_
const bool useParticleFlow_
pflow specific
~PATElectronProducer() override
void setElectronIDs(const std::vector< IdPair > &ids)
Store multiple electron ID values, discarding existing ones. The first one in the list becomes the 'd...
static const HistoName names[]
Covariance3DMatrix covariance3D() const
return only 3D position covariance matrix
const LorentzVector & p4(P4Kind kind) const
const edm::EDGetTokenT< reco::PFCandidateCollection > pfElecToken_
std::vector< double > miniIsoParamsE_
bool getByToken(EDGetToken token, Handle< PROD > &result) const
void setAllowAnything()
allow any parameter label/value pairs
#define DEFINE_FWK_MODULE(type)
edm::EDGetTokenT< edm::ValueMap< float > > PUPPIIsolation_neutral_hadrons_
const edm::EDGetTokenT< edm::ValueMap< float > > ecalPFClusterIsoT_
IsolationLabels isoDepositLabels_
const bool embedPFCandidate_
void embedSuperCluster()
method to store the electron's SuperCluster internally
std::vector< pat::PackedCandidate > PackedCandidateCollection
void embedHighLevel(pat::Electron &anElectron, reco::GsfTrackRef track, reco::TransientTrack &tt, reco::Vertex &primaryVertex, bool primaryVertexIsValid, reco::BeamSpot &beamspot, bool beamspotIsValid)
std::vector< EcalRecHit >::const_iterator const_iterator
reco::TransientTrack build(const reco::Track *p) const
void setPFCandidateRef(const reco::PFCandidateRef &ref)
add a reference to the source IsolatedPFCandidate
void fillElectron(Electron &aElectron, const ElectronBaseRef &electronRef, const reco::CandidateBaseRef &baseRef, const GenAssociations &genMatches, const IsoDepositMaps &deposits, const bool pfId, const IsolationValueMaps &isolationValues, const IsolationValueMaps &isolationValuesNoPFId) const
common electron filling, for both the standard and PF2PAT case
void push_back(T const &t)
ParameterDescriptionNode * addNode(ParameterDescriptionNode const &node)
void embedGsfElectronCore()
method to store the electron's core internally
void setPassConversionVeto(bool flag)
const edm::EDGetTokenT< edm::ValueMap< float > > hcalPFClusterIsoT_
void setHcalPFClusterIso(float hcalPFClus)
const bool embedBasicClusters_
auto vector_transform(std::vector< InputType > const &input, Function predicate) -> std::vector< typename std::remove_cv< typename std::remove_reference< decltype(predicate(input.front()))>::type >::type >
PFCandidateCollection::const_iterator PFCandidateConstIterator
iterator
void setEcalDrivenMomentum(const Candidate::LorentzVector &mom)
void setResolutions(pat::PATObject< T > &obj) const
Sets the efficiencies for this object, using the reference to the original objects.
std::vector< edm::EDGetTokenT< edm::ValueMap< float > > > elecIDTokens_
const edm::EDGetTokenT< edm::View< reco::GsfElectron > > electronToken_
std::vector< double > miniIsoParamsB_
void embedPflowSuperCluster()
method to store the electron's PflowSuperCluster internally
bool enabled() const
'true' if this there is at least one efficiency configured
EDGetTokenT< ProductType > consumes(edm::InputTag const &tag)
void setIsoDeposit(IsolationKeys key, const IsoDeposit &dep)
Sets the IsoDeposit associated with some key; if it is already existent, it is overwritten.
static void fillDescription(edm::ParameterSetDescription &iDesc)
std::vector< std::string > getParameterNamesForType(bool trackiness=true) const
const bool addEfficiencies_
const edm::EDGetTokenT< std::vector< reco::Vertex > > pvToken_
bool enabled() const
True if it has a non null configuration.
const edm::EDGetTokenT< edm::ValueMap< reco::PFCandidatePtr > > pfCandidateMapToken_
const bool usePfCandidateMultiMap_
void setComment(std::string const &value)
pat::helper::MultiIsolator isolator_
std::vector< edm::Handle< edm::Association< reco::GenParticleCollection > > > GenAssociations
void setDB(double dB, double edB, IPTYPE type)
Set impact parameter of a certain type and its uncertainty.
edm::EDGetTokenT< edm::ValueMap< float > > PUPPIIsolation_photons_
void beginEvent(const edm::Event &event, const edm::EventSetup &eventSetup)
Produces pat::Electron's.
const bool addPuppiIsolation_
void embedSeedCluster()
method to store the electron's seedcluster internally
PATElectronProducer(const edm::ParameterSet &iConfig)
const bool embedHighLevelSelection_
embed high level selection variables?
reco::PFCandidateRef pfCandidateRef() const
reference to the source PFCandidates; null if this has been built from a standard electron ...
const bool addResolutions_
void newEvent(const edm::Event &event, const edm::EventSetup &setup)
To be called for each new event, reads in the EventSetup object.
ConsumesCollector consumesCollector()
Use a ConsumesCollector to gather consumes information from helper functions.
std::vector< edm::EDGetTokenT< edm::Association< reco::GenParticleCollection > > > genMatchTokens_
The Signals That Services Can Subscribe To This is based on ActivityRegistry and is current per Services can connect to the signals distributed by the ActivityRegistry in order to monitor the activity of the application Each possible callback has some defined which we here list in angle e< void, edm::EventID const &, edm::Timestamp const & > We also list in braces which AR_WATCH_USING_METHOD_ is used for those or
def unique(seq, keepstr=True)
void setIsolationPUPPINoLeptons(float chargedhadrons_, float neutralhadrons_, float photons_)
sets PUPPINoLeptons isolations
ParameterDescriptionNode * ifValue(ParameterDescription< T > const &switchParameter, std::unique_ptr< ParameterDescriptionCases< T > > cases)
std::vector< edm::EDGetTokenT< edm::ValueMap< IsoDeposit > > > isoDepositTokens_
edm::EDGetTokenT< edm::ValueMap< float > > PUPPINoLeptonsIsolation_neutral_hadrons_
const bool embedSeedCluster_
const edm::EDGetTokenT< EcalRecHitCollection > reducedEndcapRecHitCollectionToken_
const bool addPFClusterIso_
math::XYZPoint Point
point in the space
std::vector< edm::Handle< edm::ValueMap< double > > > IsolationValueMaps
void embedPflowBasicClusters()
method to store the electron's pflow basic clusters
edm::Ref< PFCandidateCollection > PFCandidateRef
persistent reference to a PFCandidate
ParameterDescriptionBase * add(U const &iLabel, T const &value)
void embedBasicClusters()
method to store the electron's basic clusters
std::pair< std::string, edm::InputTag > NameTag
edm::EDGetTokenT< edm::ValueMap< float > > PUPPINoLeptonsIsolation_photons_
bool isNull() const
Checks for null.
void embedGsfTrack()
method to store the electron's GsfTrack internally
static void fillDescriptions(edm::ConfigurationDescriptions &descriptions)
void produce(edm::Event &iEvent, const edm::EventSetup &iSetup) override
bool isNonnull() const
Checks for non-null.
std::vector< Conversion > ConversionCollection
const bool embedGsfTrack_
const_iterator end() const
std::vector< reco::PFCandidate > PFCandidateCollection
collection of PFCandidates
const edm::EDGetTokenT< reco::BeamSpot > beamLineToken_
void fillElectron2(Electron &anElectron, const reco::CandidatePtr &candPtrForIsolation, const reco::CandidatePtr &candPtrForGenMatch, const reco::CandidatePtr &candPtrForLoader, const GenAssociations &genMatches, const IsoDepositMaps &deposits, const IsolationValueMaps &isolationValues) const
void addGenParticleRef(const reco::GenParticleRef &ref)
std::vector< edm::EDGetTokenT< edm::ValueMap< double > > > isolationValueNoPFIdTokens_
virtual std::vector< DetId > getWindow(const DetId &id, const int &northSouthSize, const int &eastWestSize) const
T const * product() const
static void fillDescription(edm::ParameterSetDescription &iDesc)
Method for documentation and validation of PSet.
void setEcalPFClusterIso(float ecalPFClus)
pat::helper::EfficiencyLoader efficiencyLoader_
const edm::EDGetTokenT< EcalRecHitCollection > reducedBarrelRecHitCollectionToken_
void setIsPF(bool hasPFCandidate)
const bool embedGsfElectronCore_
const edm::EDGetTokenT< edm::ValueMap< std::vector< reco::PFCandidateRef > > > pfCandidateMultiMapToken_
pat::PATUserDataHelper< pat::Electron > userDataHelper_
void setEfficiencies(pat::PATObject< T > &obj, const R &originalRef) const
Sets the efficiencies for this object, using the reference to the original objects.
Analysis-level electron class.
const CaloTopology * ecalTopology_
void add(std::string const &label, ParameterSetDescription const &psetDescription)
const CaloSubdetectorTopology * getSubdetectorTopology(const DetId &id) const
access the subdetector Topology for the given subdetector directly
void setMiniPFIsolation(PFIsolation const &iso)
ProductID id() const
Accessor for product ID.
IsolationLabels isolationValueLabelsNoPFId_
void setElectronMiniIso(pat::Electron &anElectron, const pat::PackedCandidateCollection *pc)
void embedPreshowerClusters()
method to store the electron's preshower clusters
std::vector< std::pair< pat::IsolationKeys, float > > IsolationValuePairs
iterator find(key_type k)
boost::indirect_iterator< typename seq_t::const_iterator > const_iterator
IsolationLabels isolationValueLabels_
PFIsolation getMiniPFIsolation(const pat::PackedCandidateCollection *pfcands, const math::XYZTLorentzVector &p4, float mindr=0.05, float maxdr=0.2, float kt_scale=10.0, float ptthresh=0.5, float deadcone_ch=0.0001, float deadcone_pu=0.01, float deadcone_ph=0.01, float deadcone_nh=0.01, float dZ_cut=0.0)
const bool embedPflowSuperCluster_
const bool embedPflowPreshowerClusters_
pat::helper::KinResolutionsLoader resolutionLoader_
const Point & position() const
position
const bool embedPflowBasicClusters_
void embedPflowPreshowerClusters()
method to store the electron's pflow preshower clusters
std::vector< edm::EDGetTokenT< edm::ValueMap< double > > > isolationValueTokens_
void embedTrack()
method to store the electron's Track internally
pat::helper::MultiIsolator::IsolationValuePairs isolatorTmpStorage_
edm::Ptr< PFCandidate > PFCandidatePtr
persistent Ptr to a PFCandidate
const bool embedPreshowerClusters_
void setIsolationPUPPI(float chargedhadrons_, float neutralhadrons_, float photons_)
sets PUPPI isolations
static std::string const source
edm::EDGetTokenT< pat::PackedCandidateCollection > pcToken_
void embedPFCandidate()
embed the PFCandidate pointed to by pfCandidateRef_
Global3DVector GlobalVector
std::vector< NameTag > elecIDSrcs_
void fill(const edm::View< T > &coll, int idx, IsolationValuePairs &isolations) const
const bool embedSuperCluster_
std::vector< edm::Handle< edm::ValueMap< IsoDeposit > > > IsoDepositMaps