Inheritance diagram for ConversionTrackMerger:

Public Member Functions
	ConversionTrackMerger (const edm::ParameterSet &conf)

void	produce (edm::Event &e, const edm::EventSetup &c) override

	~ConversionTrackMerger () override

Public Member Functions inherited from edm::stream::EDProducer<>
	EDProducer ()=default

	EDProducer (const EDProducer &)=delete

bool	hasAbilityToProduceInBeginLumis () const final

bool	hasAbilityToProduceInBeginProcessBlocks () const final

bool	hasAbilityToProduceInBeginRuns () const final

bool	hasAbilityToProduceInEndLumis () const final

bool	hasAbilityToProduceInEndProcessBlocks () const final

bool	hasAbilityToProduceInEndRuns () const final

const EDProducer &	operator= (const EDProducer &)=delete

Private Attributes
edm::ParameterSet	conf_

std::unique_ptr< reco::ConversionTrackCollection >	outputTrks

edm::EDGetTokenT< reco::ConversionTrackCollection >	trackProducer1

edm::EDGetTokenT< reco::ConversionTrackCollection >	trackProducer2

Additional Inherited Members
Public Types inherited from edm::stream::EDProducer<>
using	CacheTypes = CacheContexts< T... >

using	GlobalCache = typename CacheTypes::GlobalCache

using	HasAbility = AbilityChecker< T... >

using	InputProcessBlockCache = typename CacheTypes::InputProcessBlockCache

using	LuminosityBlockCache = typename CacheTypes::LuminosityBlockCache

using	LuminosityBlockContext = LuminosityBlockContextT< LuminosityBlockCache, RunCache, GlobalCache >

using	LuminosityBlockSummaryCache = typename CacheTypes::LuminosityBlockSummaryCache

using	RunCache = typename CacheTypes::RunCache

using	RunContext = RunContextT< RunCache, GlobalCache >

using	RunSummaryCache = typename CacheTypes::RunSummaryCache

Detailed Description

Definition at line 32 of file ConversionTrackMerger.cc.

Constructor & Destructor Documentation

◆ ConversionTrackMerger()

ConversionTrackMerger::ConversionTrackMerger ( const edm::ParameterSet & conf )

explicit

Definition at line 52 of file ConversionTrackMerger.cc.

References conf_, edm::ParameterSet::getParameter(), trackProducer1, and trackProducer2.

                                                                         : conf_(conf) {
   // retrieve producer name of input TrackCollection(s)
   trackProducer1 = consumes<reco::ConversionTrackCollection>(conf_.getParameter<edm::InputTag>("TrackProducer1"));
   trackProducer2 = consumes<reco::ConversionTrackCollection>(conf_.getParameter<edm::InputTag>("TrackProducer2"));
 
   produces<reco::ConversionTrackCollection>();
 }

◆ ~ConversionTrackMerger()

ConversionTrackMerger::~ConversionTrackMerger ( )

override

Definition at line 61 of file ConversionTrackMerger.cc.

61 {}

Member Function Documentation

◆ produce()

void ConversionTrackMerger::produce	(	edm::Event &	e,
		const edm::EventSetup &	c
	)

override

Definition at line 64 of file ConversionTrackMerger.cc.

References HLT_2022v15_cff::allowFirstHitShare, conversionTrackMerger_cfi::arbitratedEcalSeededPreferCollection, conversionTrackMerger_cfi::arbitratedMergedEcalGeneralPreferCollection, conversionTrackMerger_cfi::arbitratedMergedPreferCollection, PA_ZEESkim_cff::checkCharge, ChiSquaredProbability(), conf_, MillePedeFileConverter_cfg::e, edm::ParameterSet::getParameter(), mps_fire::i, edm::HandleBase::isValid(), TrackingRecHit::isValid(), dqmiolumiharvest::j, findQualityFiles::jj, SiStripPI::min, conversionTrackMerger_cfi::minProb, eostools::move(), conversionTrackMerger_cfi::outputPreferCollection, outputTrks, edm::Handle< T >::product(), HLT_FULL_cff::shareFrac, TrackingRecHit::sharesInput(), TrackingRecHit::some, HLT_2022v15_cff::track, conversionTrackMerger_cfi::trackerOnlyPreferCollection, trackProducer1, and trackProducer2.

                                                                         {
   double shareFrac = conf_.getParameter<double>("ShareFrac");
   bool allowFirstHitShare = conf_.getParameter<bool>("allowFirstHitShare");
   bool checkCharge = conf_.getParameter<bool>("checkCharge");
   double minProb = conf_.getParameter<double>("minProb");
 
   int outputPreferCollection = conf_.getParameter<int>("outputPreferCollection");
   int trackerOnlyPreferCollection = conf_.getParameter<int>("trackerOnlyPreferCollection");
   int arbitratedEcalSeededPreferCollection = conf_.getParameter<int>("arbitratedEcalSeededPreferCollection");
   int arbitratedMergedPreferCollection = conf_.getParameter<int>("arbitratedMergedPreferCollection");
   int arbitratedMergedEcalGeneralPreferCollection =
       conf_.getParameter<int>("arbitratedMergedEcalGeneralPreferCollection");
 
   // get Inputs
   // if 1 input list doesn't exist, make an empty list, issue a warning, and continue
   // this allows ConversionTrackMerger to be used as a cleaner only if handed just one list
   // if both input lists don't exist, will issue 2 warnings and generate an empty output collection
   //
   const reco::ConversionTrackCollection* TC1 = nullptr;
   static const reco::ConversionTrackCollection s_empty1, s_empty2;
   edm::Handle<reco::ConversionTrackCollection> trackCollection1;
   e.getByToken(trackProducer1, trackCollection1);
   if (trackCollection1.isValid()) {
     TC1 = trackCollection1.product();
     //std::cout << "1st collection " << trackProducer1 << " has "<< TC1->size() << " tracks" << std::endl ;
   } else {
     TC1 = &s_empty1;
     edm::LogWarning("ConversionTrackMerger") << "1st TrackCollection not found;"
                                              << " will only clean 2nd TrackCollection ";
   }
   reco::ConversionTrackCollection tC1 = *TC1;
 
   const reco::ConversionTrackCollection* TC2 = nullptr;
   edm::Handle<reco::ConversionTrackCollection> trackCollection2;
   e.getByToken(trackProducer2, trackCollection2);
   if (trackCollection2.isValid()) {
     TC2 = trackCollection2.product();
     //std::cout << "2nd collection " << trackProducer2 << " has "<< TC2->size() << " tracks" << std::endl ;
   } else {
     TC2 = &s_empty2;
     edm::LogWarning("ConversionTrackMerger") << "2nd TrackCollection not found;"
                                              << " will only clean 1st TrackCollection ";
   }
   reco::ConversionTrackCollection tC2 = *TC2;
 
   // Step B: create empty output collection
   outputTrks = std::make_unique<reco::ConversionTrackCollection>();
   int i;
 
   std::vector<int> selected1;
   for (unsigned int i = 0; i < tC1.size(); ++i) {
     selected1.push_back(1);
   }
   std::vector<int> selected2;
   for (unsigned int i = 0; i < tC2.size(); ++i) {
     selected2.push_back(1);
   }
 
   std::map<reco::ConversionTrackCollection::const_iterator, std::vector<const TrackingRecHit*> > rh1;
   std::map<reco::ConversionTrackCollection::const_iterator, std::vector<const TrackingRecHit*> > rh2;
   for (reco::ConversionTrackCollection::const_iterator track = tC1.begin(); track != tC1.end(); ++track) {
     trackingRecHit_iterator itB = track->track()->recHitsBegin();
     trackingRecHit_iterator itE = track->track()->recHitsEnd();
     for (trackingRecHit_iterator it = itB; it != itE; ++it) {
       const TrackingRecHit* hit = &(**it);
       rh1[track].push_back(hit);
     }
   }
   for (reco::ConversionTrackCollection::const_iterator track = tC2.begin(); track != tC2.end(); ++track) {
     trackingRecHit_iterator jtB = track->track()->recHitsBegin();
     trackingRecHit_iterator jtE = track->track()->recHitsEnd();
     for (trackingRecHit_iterator jt = jtB; jt != jtE; ++jt) {
       const TrackingRecHit* hit = &(**jt);
       rh2[track].push_back(hit);
     }
   }
 
   if ((!tC1.empty()) && (!tC2.empty())) {
     i = -1;
     for (reco::ConversionTrackCollection::iterator track = tC1.begin(); track != tC1.end(); ++track) {
       i++;
 
       //clear flags if preferCollection was set to 0
       selected1[i] = selected1[i] && outputPreferCollection != 0;
       track->setIsTrackerOnly(track->isTrackerOnly() && trackerOnlyPreferCollection != 0);
       track->setIsArbitratedEcalSeeded(track->isArbitratedEcalSeeded() && arbitratedEcalSeededPreferCollection != 0);
       track->setIsArbitratedMerged(track->isArbitratedMerged() && arbitratedMergedPreferCollection != 0);
       track->setIsArbitratedMergedEcalGeneral(track->isArbitratedMergedEcalGeneral() &&
                                               arbitratedMergedEcalGeneralPreferCollection != 0);
 
       std::vector<const TrackingRecHit*>& iHits = rh1[track];
       unsigned nh1 = iHits.size();
       int j = -1;
       for (reco::ConversionTrackCollection::iterator track2 = tC2.begin(); track2 != tC2.end(); ++track2) {
         j++;
 
         //clear flags if preferCollection was set to 0
         selected2[j] = selected2[j] && outputPreferCollection != 0;
         track2->setIsTrackerOnly(track2->isTrackerOnly() && trackerOnlyPreferCollection != 0);
         track2->setIsArbitratedEcalSeeded(track2->isArbitratedEcalSeeded() &&
                                           arbitratedEcalSeededPreferCollection != 0);
         track2->setIsArbitratedMerged(track2->isArbitratedMerged() && arbitratedMergedPreferCollection != 0);
         track2->setIsArbitratedMergedEcalGeneral(track2->isArbitratedMergedEcalGeneral() &&
                                                  arbitratedMergedEcalGeneralPreferCollection != 0);
 
         std::vector<const TrackingRecHit*>& jHits = rh2[track2];
         unsigned nh2 = jHits.size();
         int noverlap = 0;
         int firstoverlap = 0;
         for (unsigned ih = 0; ih < nh1; ++ih) {
           const TrackingRecHit* it = iHits[ih];
           if (it->isValid()) {
             int jj = -1;
             for (unsigned jh = 0; jh < nh2; ++jh) {
               const TrackingRecHit* jt = jHits[jh];
               jj++;
               if (jt->isValid()) {
                 if (it->sharesInput(jt, TrackingRecHit::some)) {
                   noverlap++;
                   if (allowFirstHitShare && (ih == 0) && (jh == 0))
                     firstoverlap = 1;
                 }
               }
             }
           }
         }
         int nhit1 = track->track()->numberOfValidHits();
         int nhit2 = track2->track()->numberOfValidHits();
         //if (noverlap>0) printf("noverlap = %i, firstoverlap = %i, nhit1 = %i, nhit2 = %i, algo1 = %i, algo2 = %i, q1 = %i, q2 = %i\n",noverlap,firstoverlap,nhit1,nhit2,track->track()->algo(),track2->track()->algo(),track->track()->charge(),track2->track()->charge());
         //std::cout << " trk1 trk2 nhits1 nhits2 nover " << i << " " << j << " " << track->numberOfValidHits() << " "  << track2->numberOfValidHits() << " " << noverlap << " " << fi << " " << fj  <<std::endl;
         if ((noverlap - firstoverlap) > (std::min(nhit1, nhit2) - firstoverlap) * shareFrac &&
             (!checkCharge || track->track()->charge() * track2->track()->charge() > 0)) {
           //printf("overlapping tracks\n");
           //printf ("ndof1 = %5f, chisq1 = %5f, ndof2 = %5f, chisq2 = %5f\n",track->track()->ndof(),track->track()->chi2(),track2->track()->ndof(),track2->track()->chi2());
 
           double probFirst = ChiSquaredProbability(track->track()->chi2(), track->track()->ndof());
           double probSecond = ChiSquaredProbability(track2->track()->chi2(), track2->track()->ndof());
 
           //arbitrate by number of hits and reduced chisq
           bool keepFirst = (nhit1 > nhit2 ||
                             (nhit1 == nhit2 && track->track()->normalizedChi2() < track2->track()->normalizedChi2()));
 
           //override decision in case one track is radically worse quality than the other
           keepFirst |= (probFirst > minProb && probSecond <= minProb);
           keepFirst &= !(probFirst <= minProb && probSecond > minProb);
 
           bool keepSecond = !keepFirst;
 
           //set flags based on arbitration decision and precedence settings
 
           selected1[i] = selected1[i] && ((keepFirst && outputPreferCollection == 3) || outputPreferCollection == -1 ||
                                           outputPreferCollection == 1);
           track->setIsTrackerOnly(track->isTrackerOnly() &&
                                   ((keepFirst && trackerOnlyPreferCollection == 3) ||
                                    trackerOnlyPreferCollection == -1 || trackerOnlyPreferCollection == 1));
           track->setIsArbitratedEcalSeeded(track->isArbitratedEcalSeeded() &&
                                            ((keepFirst && arbitratedEcalSeededPreferCollection == 3) ||
                                             arbitratedEcalSeededPreferCollection == -1 ||
                                             arbitratedEcalSeededPreferCollection == 1));
           track->setIsArbitratedMerged(track->isArbitratedMerged() &&
                                        ((keepFirst && arbitratedMergedPreferCollection == 3) ||
                                         arbitratedMergedPreferCollection == -1 ||
                                         arbitratedMergedPreferCollection == 1));
           track->setIsArbitratedMergedEcalGeneral(track->isArbitratedMergedEcalGeneral() &&
                                                   ((keepFirst && arbitratedMergedEcalGeneralPreferCollection == 3) ||
                                                    arbitratedMergedEcalGeneralPreferCollection == -1 ||
                                                    arbitratedMergedEcalGeneralPreferCollection == 1));
 
           selected2[j] = selected2[j] && ((keepSecond && outputPreferCollection == 3) || outputPreferCollection == -1 ||
                                           outputPreferCollection == 2);
           track2->setIsTrackerOnly(track2->isTrackerOnly() &&
                                    ((keepSecond && trackerOnlyPreferCollection == 3) ||
                                     trackerOnlyPreferCollection == -1 || trackerOnlyPreferCollection == 2));
           track2->setIsArbitratedEcalSeeded(track2->isArbitratedEcalSeeded() &&
                                             ((keepSecond && arbitratedEcalSeededPreferCollection == 3) ||
                                              arbitratedEcalSeededPreferCollection == -1 ||
                                              arbitratedEcalSeededPreferCollection == 2));
           track2->setIsArbitratedMerged(track2->isArbitratedMerged() &&
                                         ((keepSecond && arbitratedMergedPreferCollection == 3) ||
                                          arbitratedMergedPreferCollection == -1 ||
                                          arbitratedMergedPreferCollection == 2));
           track2->setIsArbitratedMergedEcalGeneral(track2->isArbitratedMergedEcalGeneral() &&
                                                    ((keepSecond && arbitratedMergedEcalGeneralPreferCollection == 3) ||
                                                     arbitratedMergedEcalGeneralPreferCollection == -1 ||
                                                     arbitratedMergedEcalGeneralPreferCollection == 2));
 
         }  //end got a duplicate
       }    //end track2 loop
     }      //end track loop
   }        //end more than 1 track
 
   //
   //  output selected tracks - if any
   //
 
   if (!tC1.empty()) {
     i = 0;
     for (reco::ConversionTrackCollection::const_iterator track = tC1.begin(); track != tC1.end(); ++track, ++i) {
       //don't store tracks rejected as duplicates
       if (!selected1[i]) {
         continue;
       }
       //fill the TrackCollection
       outputTrks->push_back(*track);
     }  //end faux loop over tracks
   }    //end more than 0 track
 
   //Fill the trajectories, etc. for 1st collection
 
   if (!tC2.empty()) {
     i = 0;
     for (reco::ConversionTrackCollection::const_iterator track = tC2.begin(); track != tC2.end(); ++track, ++i) {
       //don't store tracks rejected as duplicates
       if (!selected2[i]) {
         continue;
       }
       //fill the TrackCollection
       outputTrks->push_back(*track);
     }  //end faux loop over tracks
   }    //end more than 0 track
 
   e.put(std::move(outputTrks));
   return;
 
 }  //end produce