#include <EcalRecHitProducer.h>

Inheritance diagram for EcalRecHitProducer:

Public Member Functions
	EcalRecHitProducer (const edm::ParameterSet &ps)

void	produce (edm::Event &evt, const edm::EventSetup &es) override

	~EcalRecHitProducer () 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

Static Public Member Functions
static void	fillDescriptions (edm::ConfigurationDescriptions &descriptions)

Private Attributes
std::unique_ptr< EcalCleaningAlgo >	cleaningAlgo_

const bool	doEB_

const bool	doEE_

edm::EDGetTokenT< std::set< EBDetId > >	ebDetIdToBeRecoveredToken_

edm::EDGetTokenT< std::set< EcalTrigTowerDetId > >	ebFEToBeRecoveredToken_

const edm::EDPutTokenT< EBRecHitCollection >	ebRecHitToken_

edm::EDGetTokenT< EBUncalibratedRecHitCollection >	ebUncalibRecHitToken_

edm::ESGetToken< EcalChannelStatus, EcalChannelStatusRcd >	ecalChannelStatusToken_

edm::EDGetTokenT< std::set< EEDetId > >	eeDetIdToBeRecoveredToken_

edm::EDGetTokenT< std::set< EcalScDetId > >	eeFEToBeRecoveredToken_

const edm::EDPutTokenT< EERecHitCollection >	eeRecHitToken_

edm::EDGetTokenT< EEUncalibratedRecHitCollection >	eeUncalibRecHitToken_

const bool	killDeadChannels_

const bool	recoverEBFE_

const bool	recoverEBIsolatedChannels_

const bool	recoverEBVFE_

const bool	recoverEEFE_

const bool	recoverEEIsolatedChannels_

const bool	recoverEEVFE_

std::unique_ptr< EcalRecHitWorkerBaseClass >	worker_

std::unique_ptr< EcalRecHitWorkerBaseClass >	workerRecover_

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

produce ECAL rechits from uncalibrated rechits

Author: Shahram Rahatlou, University of Rome & INFN, March 2006

Definition at line 27 of file EcalRecHitProducer.h.

Constructor & Destructor Documentation

◆ EcalRecHitProducer()

EcalRecHitProducer::EcalRecHitProducer ( const edm::ParameterSet & ps )

explicit

Definition at line 24 of file EcalRecHitProducer.cc.

References c, cleaningAlgo_, doEB_, doEE_, ebDetIdToBeRecoveredToken_, ebFEToBeRecoveredToken_, ebUncalibRecHitToken_, ecalChannelStatusToken_, eeDetIdToBeRecoveredToken_, eeFEToBeRecoveredToken_, eeUncalibRecHitToken_, get, edm::ParameterSet::getParameter(), killDeadChannels_, recoverEBFE_, recoverEBIsolatedChannels_, recoverEEFE_, recoverEEIsolatedChannels_, AlCaHLTBitMon_QueryRunRegistry::string, worker_, and workerRecover_.

     : doEB_(!ps.getParameter<edm::InputTag>("EBuncalibRecHitCollection").label().empty()),
       doEE_(!ps.getParameter<edm::InputTag>("EEuncalibRecHitCollection").label().empty()),
       recoverEBIsolatedChannels_(ps.getParameter<bool>("recoverEBIsolatedChannels")),
       recoverEEIsolatedChannels_(ps.getParameter<bool>("recoverEEIsolatedChannels")),
       recoverEBVFE_(ps.getParameter<bool>("recoverEBVFE")),
       recoverEEVFE_(ps.getParameter<bool>("recoverEEVFE")),
       recoverEBFE_(ps.getParameter<bool>("recoverEBFE")),
       recoverEEFE_(ps.getParameter<bool>("recoverEEFE")),
       killDeadChannels_(ps.getParameter<bool>("killDeadChannels")),
       ebRecHitToken_(produces<EBRecHitCollection>(ps.getParameter<std::string>("EBrechitCollection"))),
       eeRecHitToken_(produces<EERecHitCollection>(ps.getParameter<std::string>("EErechitCollection"))) {
   if (doEB_) {
     ebUncalibRecHitToken_ =
         consumes<EBUncalibratedRecHitCollection>(ps.getParameter<edm::InputTag>("EBuncalibRecHitCollection"));
 
     if (recoverEBIsolatedChannels_ || recoverEBFE_ || killDeadChannels_) {
       ebDetIdToBeRecoveredToken_ = consumes<std::set<EBDetId>>(ps.getParameter<edm::InputTag>("ebDetIdToBeRecovered"));
     }
 
     if (recoverEBFE_ || killDeadChannels_) {
       ebFEToBeRecoveredToken_ =
           consumes<std::set<EcalTrigTowerDetId>>(ps.getParameter<edm::InputTag>("ebFEToBeRecovered"));
     }
   }
 
   if (doEE_) {
     eeUncalibRecHitToken_ =
         consumes<EEUncalibratedRecHitCollection>(ps.getParameter<edm::InputTag>("EEuncalibRecHitCollection"));
 
     if (recoverEEIsolatedChannels_ || recoverEEFE_ || killDeadChannels_) {
       eeDetIdToBeRecoveredToken_ = consumes<std::set<EEDetId>>(ps.getParameter<edm::InputTag>("eeDetIdToBeRecovered"));
     }
 
     if (recoverEEFE_ || killDeadChannels_) {
       eeFEToBeRecoveredToken_ = consumes<std::set<EcalScDetId>>(ps.getParameter<edm::InputTag>("eeFEToBeRecovered"));
     }
   }
 
   if (recoverEBIsolatedChannels_ || recoverEBFE_ || recoverEEIsolatedChannels_ || recoverEEFE_ || killDeadChannels_) {
     ecalChannelStatusToken_ = esConsumes<EcalChannelStatus, EcalChannelStatusRcd>();
   }
 
   std::string componentType = ps.getParameter<std::string>("algo");
   edm::ConsumesCollector c{consumesCollector()};
   worker_ = EcalRecHitWorkerFactory::get()->create(componentType, ps, c);
 
   // to recover problematic channels
   componentType = ps.getParameter<std::string>("algoRecover");
   workerRecover_ = EcalRecHitWorkerFactory::get()->create(componentType, ps, c);
 
   edm::ParameterSet cleaningPs = ps.getParameter<edm::ParameterSet>("cleaningConfig");
   cleaningAlgo_ = std::make_unique<EcalCleaningAlgo>(cleaningPs);
 }

◆ ~EcalRecHitProducer()

EcalRecHitProducer::~EcalRecHitProducer ( )

overridedefault

Member Function Documentation

◆ fillDescriptions()

void EcalRecHitProducer::fillDescriptions ( edm::ConfigurationDescriptions & descriptions )

static

Definition at line 230 of file EcalRecHitProducer.cc.

References edm::ConfigurationDescriptions::add(), edm::ParameterSetDescription::add(), submitPVResolutionJobs::desc, HLT_2022v12_cff::InputTag, edm::ParameterSetDescription::reserve(), and AlCaHLTBitMon_QueryRunRegistry::string.

                                                                                     {
   edm::ParameterSetDescription desc;
   desc.add<bool>("recoverEEVFE", false);
   desc.add<std::string>("EErechitCollection", "EcalRecHitsEE");
   desc.add<bool>("recoverEBIsolatedChannels", false);
   desc.add<bool>("recoverEBVFE", false);
   desc.add<bool>("laserCorrection", true);
   desc.add<double>("EBLaserMIN", 0.5);
   desc.add<bool>("killDeadChannels", true);
   {
     std::vector<int> temp1;
     temp1.reserve(3);
     temp1.push_back(14);
     temp1.push_back(78);
     temp1.push_back(142);
     desc.add<std::vector<int>>("dbStatusToBeExcludedEB", temp1);
   }
   desc.add<edm::InputTag>("EEuncalibRecHitCollection",
                           edm::InputTag("ecalMultiFitUncalibRecHit", "EcalUncalibRecHitsEE"));
   {
     std::vector<int> temp1;
     temp1.reserve(3);
     temp1.push_back(14);
     temp1.push_back(78);
     temp1.push_back(142);
     desc.add<std::vector<int>>("dbStatusToBeExcludedEE", temp1);
   }
   desc.add<double>("EELaserMIN", 0.5);
   desc.add<edm::InputTag>("ebFEToBeRecovered", edm::InputTag("ecalDetIdToBeRecovered", "ebFE"));
   {
     edm::ParameterSetDescription psd0;
     psd0.add<double>("e6e2thresh", 0.04);
     psd0.add<double>("tightenCrack_e6e2_double", 3);
     psd0.add<double>("e4e1Threshold_endcap", 0.3);
     psd0.add<double>("tightenCrack_e4e1_single", 3);
     psd0.add<double>("tightenCrack_e1_double", 2);
     psd0.add<double>("cThreshold_barrel", 4);
     psd0.add<double>("e4e1Threshold_barrel", 0.08);
     psd0.add<double>("tightenCrack_e1_single", 2);
     psd0.add<double>("e4e1_b_barrel", -0.024);
     psd0.add<double>("e4e1_a_barrel", 0.04);
     psd0.add<double>("ignoreOutOfTimeThresh", 1000000000.0);
     psd0.add<double>("cThreshold_endcap", 15);
     psd0.add<double>("e4e1_b_endcap", -0.0125);
     psd0.add<double>("e4e1_a_endcap", 0.02);
     psd0.add<double>("cThreshold_double", 10);
     desc.add<edm::ParameterSetDescription>("cleaningConfig", psd0);
   }
   desc.add<double>("logWarningEtThreshold_EE_FE", 50);
   desc.add<edm::InputTag>("eeDetIdToBeRecovered", edm::InputTag("ecalDetIdToBeRecovered", "eeDetId"));
   desc.add<bool>("recoverEBFE", true);
   desc.add<edm::InputTag>("eeFEToBeRecovered", edm::InputTag("ecalDetIdToBeRecovered", "eeFE"));
   desc.add<edm::InputTag>("ebDetIdToBeRecovered", edm::InputTag("ecalDetIdToBeRecovered", "ebDetId"));
   desc.add<double>("singleChannelRecoveryThreshold", 8);
   desc.add<double>("sum8ChannelRecoveryThreshold", 0.);
   desc.add<edm::FileInPath>("bdtWeightFileNoCracks",
                             edm::FileInPath("RecoLocalCalo/EcalDeadChannelRecoveryAlgos/data/BDTWeights/"
                                             "bdtgAllRH_8GT700MeV_noCracks_ZskimData2017_v1.xml"));
   desc.add<edm::FileInPath>("bdtWeightFileCracks",
                             edm::FileInPath("RecoLocalCalo/EcalDeadChannelRecoveryAlgos/data/BDTWeights/"
                                             "bdtgAllRH_8GT700MeV_onlyCracks_ZskimData2017_v1.xml"));
   {
     std::vector<std::string> temp1;
     temp1.reserve(9);
     temp1.push_back("kNoisy");
     temp1.push_back("kNNoisy");
     temp1.push_back("kFixedG6");
     temp1.push_back("kFixedG1");
     temp1.push_back("kFixedG0");
     temp1.push_back("kNonRespondingIsolated");
     temp1.push_back("kDeadVFE");
     temp1.push_back("kDeadFE");
     temp1.push_back("kNoDataNoTP");
     desc.add<std::vector<std::string>>("ChannelStatusToBeExcluded", temp1);
   }
   desc.add<std::string>("EBrechitCollection", "EcalRecHitsEB");
   desc.add<edm::InputTag>("triggerPrimitiveDigiCollection", edm::InputTag("ecalDigis", "EcalTriggerPrimitives"));
   desc.add<bool>("recoverEEFE", true);
   desc.add<std::string>("singleChannelRecoveryMethod", "NeuralNetworks");
   desc.add<double>("EBLaserMAX", 3.0);
   {
     edm::ParameterSetDescription psd0;
     {
       std::vector<std::string> temp2;
       temp2.reserve(4);
       temp2.push_back("kOk");
       temp2.push_back("kDAC");
       temp2.push_back("kNoLaser");
       temp2.push_back("kNoisy");
       psd0.add<std::vector<std::string>>("kGood", temp2);
     }
     {
       std::vector<std::string> temp2;
       temp2.reserve(3);
       temp2.push_back("kFixedG0");
       temp2.push_back("kNonRespondingIsolated");
       temp2.push_back("kDeadVFE");
       psd0.add<std::vector<std::string>>("kNeighboursRecovered", temp2);
     }
     {
       std::vector<std::string> temp2;
       temp2.reserve(1);
       temp2.push_back("kNoDataNoTP");
       psd0.add<std::vector<std::string>>("kDead", temp2);
     }
     {
       std::vector<std::string> temp2;
       temp2.reserve(3);
       temp2.push_back("kNNoisy");
       temp2.push_back("kFixedG6");
       temp2.push_back("kFixedG1");
       psd0.add<std::vector<std::string>>("kNoisy", temp2);
     }
     {
       std::vector<std::string> temp2;
       temp2.reserve(1);
       temp2.push_back("kDeadFE");
       psd0.add<std::vector<std::string>>("kTowerRecovered", temp2);
     }
     desc.add<edm::ParameterSetDescription>("flagsMapDBReco", psd0);
   }
   desc.add<edm::InputTag>("EBuncalibRecHitCollection",
                           edm::InputTag("ecalMultiFitUncalibRecHit", "EcalUncalibRecHitsEB"));
   desc.add<std::string>("algoRecover", "EcalRecHitWorkerRecover");
   desc.add<std::string>("algo", "EcalRecHitWorkerSimple");
   desc.add<double>("EELaserMAX", 8.0);
   desc.add<double>("logWarningEtThreshold_EB_FE", 50);
   desc.add<bool>("recoverEEIsolatedChannels", false);
   desc.add<bool>("skipTimeCalib", false);
   descriptions.add("ecalRecHit", desc);
 }

◆ produce()

void EcalRecHitProducer::produce	(	edm::Event &	evt,
		const edm::EventSetup &	es
	)

override

Definition at line 81 of file EcalRecHitProducer.cc.

References cleaningAlgo_, doEB_, doEE_, EcalRecHitWorkerBaseClass::EB_FE, EcalRecHitWorkerBaseClass::EB_single, EcalRecHitWorkerBaseClass::EB_VFE, ebDetIdToBeRecoveredToken_, ebFEToBeRecoveredToken_, ebRecHitToken_, ebUncalibRecHitToken_, ecalChannelStatusToken_, EcalRecHitWorkerBaseClass::EE_FE, EcalRecHitWorkerBaseClass::EE_single, EcalRecHitWorkerBaseClass::EE_VFE, eeDetIdToBeRecoveredToken_, eeFEToBeRecoveredToken_, eeRecHitToken_, eeUncalibRecHitToken_, EBDetId::ETAPHIMODE, edm::Event::get(), edm::EventSetup::getData(), EcalChannelStatusCode::getStatusCode(), LEDCalibrationChannels::ieta, LEDCalibrationChannels::iphi, EcalChannelStatusCode::kDeadVFE, killDeadChannels_, LogDebug, eostools::move(), edm::Event::put(), recoverEBFE_, recoverEBIsolatedChannels_, recoverEBVFE_, recoverEEFE_, recoverEEIsolatedChannels_, recoverEEVFE_, ecaldqm::ttId(), EEDetId::validDetId(), worker_, and workerRecover_.

                                                                        {
   using namespace edm;
 
   // collection of rechits to put in the event
   auto ebRecHits = std::make_unique<EBRecHitCollection>();
   auto eeRecHits = std::make_unique<EERecHitCollection>();
 
   worker_->set(es);
 
   if (recoverEBIsolatedChannels_ || recoverEEIsolatedChannels_ || recoverEBFE_ || recoverEEFE_ || recoverEBVFE_ ||
       recoverEEVFE_ || killDeadChannels_) {
     workerRecover_->set(es);
   }
 
   // Make EB rechits
   if (doEB_) {
     const auto& ebUncalibRecHits = evt.get(ebUncalibRecHitToken_);
     LogDebug("EcalRecHitDebug") << "total # EB uncalibrated rechits: " << ebUncalibRecHits.size();
 
     // loop over uncalibrated rechits to make calibrated ones
     for (const auto& uncalibRecHit : ebUncalibRecHits) {
       worker_->run(evt, uncalibRecHit, *ebRecHits);
     }
   }
 
   // Make EE rechits
   if (doEE_) {
     const auto& eeUncalibRecHits = evt.get(eeUncalibRecHitToken_);
     LogDebug("EcalRecHitDebug") << "total # EE uncalibrated rechits: " << eeUncalibRecHits.size();
 
     // loop over uncalibrated rechits to make calibrated ones
     for (const auto& uncalibRecHit : eeUncalibRecHits) {
       worker_->run(evt, uncalibRecHit, *eeRecHits);
     }
   }
 
   // sort collections before attempting recovery, to avoid insertion of double recHits
   ebRecHits->sort();
   eeRecHits->sort();
 
   if (recoverEBIsolatedChannels_ || recoverEBFE_ || killDeadChannels_) {
     const auto& detIds = evt.get(ebDetIdToBeRecoveredToken_);
     const auto& chStatus = es.getData(ecalChannelStatusToken_);
 
     for (const auto& detId : detIds) {
       // get channel status map to treat dead VFE separately
       EcalChannelStatusMap::const_iterator chit = chStatus.find(detId);
       EcalChannelStatusCode chStatusCode;
       if (chit != chStatus.end()) {
         chStatusCode = *chit;
       } else {
         edm::LogError("EcalRecHitProducerError") << "No channel status found for xtal " << detId.rawId()
                                                  << "! something wrong with EcalChannelStatus in your DB? ";
       }
       EcalUncalibratedRecHit urh;
       if (chStatusCode.getStatusCode() == EcalChannelStatusCode::kDeadVFE) {  // dead VFE (from DB info)
         // uses the EcalUncalibratedRecHit to pass the DetId info
         urh = EcalUncalibratedRecHit(detId, 0, 0, 0, 0, EcalRecHitWorkerBaseClass::EB_VFE);
         if (recoverEBVFE_ || killDeadChannels_)
           workerRecover_->run(evt, urh, *ebRecHits);
       } else {
         // uses the EcalUncalibratedRecHit to pass the DetId info
         urh = EcalUncalibratedRecHit(detId, 0, 0, 0, 0, EcalRecHitWorkerBaseClass::EB_single);
         if (recoverEBIsolatedChannels_ || killDeadChannels_)
           workerRecover_->run(evt, urh, *ebRecHits);
       }
     }
   }
 
   if (recoverEEIsolatedChannels_ || recoverEEVFE_ || killDeadChannels_) {
     const auto& detIds = evt.get(eeDetIdToBeRecoveredToken_);
     const auto& chStatus = es.getData(ecalChannelStatusToken_);
 
     for (const auto& detId : detIds) {
       // get channel status map to treat dead VFE separately
       EcalChannelStatusMap::const_iterator chit = chStatus.find(detId);
       EcalChannelStatusCode chStatusCode;
       if (chit != chStatus.end()) {
         chStatusCode = *chit;
       } else {
         edm::LogError("EcalRecHitProducerError") << "No channel status found for xtal " << detId.rawId()
                                                  << "! something wrong with EcalChannelStatus in your DB? ";
       }
       EcalUncalibratedRecHit urh;
       if (chStatusCode.getStatusCode() == EcalChannelStatusCode::kDeadVFE) {  // dead VFE (from DB info)
         // uses the EcalUncalibratedRecHit to pass the DetId info
         urh = EcalUncalibratedRecHit(detId, 0, 0, 0, 0, EcalRecHitWorkerBaseClass::EE_VFE);
         if (recoverEEVFE_ || killDeadChannels_)
           workerRecover_->run(evt, urh, *eeRecHits);
       } else {
         // uses the EcalUncalibratedRecHit to pass the DetId info
         urh = EcalUncalibratedRecHit(detId, 0, 0, 0, 0, EcalRecHitWorkerBaseClass::EE_single);
         if (recoverEEIsolatedChannels_ || killDeadChannels_)
           workerRecover_->run(evt, urh, *eeRecHits);
       }
     }
   }
 
   if (recoverEBFE_ || killDeadChannels_) {
     const auto& ttIds = evt.get(ebFEToBeRecoveredToken_);
 
     for (const auto& ttId : ttIds) {
       // uses the EcalUncalibratedRecHit to pass the DetId info
       int ieta = ((ttId.ietaAbs() - 1) * 5 + 1) * ttId.zside();  // from EcalTrigTowerConstituentsMap
       int iphi = ((ttId.iphi() - 1) * 5 + 11) % 360;             // from EcalTrigTowerConstituentsMap
       if (iphi <= 0)
         iphi += 360;  // from EcalTrigTowerConstituentsMap
       EcalUncalibratedRecHit urh(
           EBDetId(ieta, iphi, EBDetId::ETAPHIMODE), 0, 0, 0, 0, EcalRecHitWorkerBaseClass::EB_FE);
       workerRecover_->run(evt, urh, *ebRecHits);
     }
   }
 
   if (recoverEEFE_ || killDeadChannels_) {
     const auto& scIds = evt.get(eeFEToBeRecoveredToken_);
 
     for (const auto& scId : scIds) {
       // uses the EcalUncalibratedRecHit to pass the DetId info
       if (EEDetId::validDetId((scId.ix() - 1) * 5 + 1, (scId.iy() - 1) * 5 + 1, scId.zside())) {
         EcalUncalibratedRecHit urh(EEDetId((scId.ix() - 1) * 5 + 1, (scId.iy() - 1) * 5 + 1, scId.zside()),
                                    0,
                                    0,
                                    0,
                                    0,
                                    EcalRecHitWorkerBaseClass::EE_FE);
         workerRecover_->run(evt, urh, *eeRecHits);
       }
     }
   }
 
   // without re-sorting, find (used below in cleaning) will lead
   // to undefined results
   ebRecHits->sort();
   eeRecHits->sort();
 
   // apply spike cleaning
   if (cleaningAlgo_) {
     cleaningAlgo_->setFlags(*ebRecHits);
     cleaningAlgo_->setFlags(*eeRecHits);
   }
 
   // put the collection of reconstructed hits in the event
   LogInfo("EcalRecHitInfo") << "total # EB calibrated rechits: " << ebRecHits->size();
   LogInfo("EcalRecHitInfo") << "total # EE calibrated rechits: " << eeRecHits->size();
 
   evt.put(ebRecHitToken_, std::move(ebRecHits));
   evt.put(eeRecHitToken_, std::move(eeRecHits));
 }