#include <HcalRecHitsValidation.h>

Inheritance diagram for HcalRecHitsValidation:

Public Member Functions
void	analyze (edm::Event const &ev, edm::EventSetup const &c) override

void	bookHistograms (DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override

	HcalRecHitsValidation (edm::ParameterSet const &conf)

	~HcalRecHitsValidation () override

Public Member Functions inherited from DQMEDAnalyzer
void	accumulate (edm::Event const &event, edm::EventSetup const &setup) final

void	beginLuminosityBlock (edm::LuminosityBlock const &lumi, edm::EventSetup const &setup) final

void	beginRun (edm::Run const &run, edm::EventSetup const &setup) final

void	beginStream (edm::StreamID id) final

virtual void	dqmBeginRun (edm::Run const &, edm::EventSetup const &)

	DQMEDAnalyzer ()

void	endLuminosityBlock (edm::LuminosityBlock const &lumi, edm::EventSetup const &setup) final

void	endRun (edm::Run const &run, edm::EventSetup const &setup) final

virtual bool	getCanSaveByLumi ()

Public Member Functions inherited from edm::stream::EDProducer< edm::GlobalCache< DQMEDAnalyzerGlobalCache >, edm::EndRunProducer, edm::EndLuminosityBlockProducer, edm::Accumulator >
	EDProducer ()=default

bool	hasAbilityToProduceInBeginLumis () const final

bool	hasAbilityToProduceInBeginProcessBlocks () const final

bool	hasAbilityToProduceInBeginRuns () const final

bool	hasAbilityToProduceInEndLumis () const final

bool	hasAbilityToProduceInEndProcessBlocks () const final

bool	hasAbilityToProduceInEndRuns () const final

Private Member Functions
double	dPhiWsign (double phi1, double phi2)

double	dR (double eta1, double phi1, double eta2, double phi2)

virtual void	fillRecHitsTmp (int subdet_, edm::Event const &ev)

double	phi12 (double phi1, double en1, double phi2, double en2)

Private Attributes
std::vector< uint32_t >	cauxstwd

std::vector< double >	cchi2

std::vector< int >	cdepth

std::vector< double >	cen

std::vector< double >	ceta

std::vector< int >	cieta

std::vector< int >	ciphi

std::vector< double >	cphi

std::vector< uint32_t >	cstwd

std::vector< int >	csub

std::vector< double >	ctime

std::vector< double >	cz

std::string	ecalselector_

edm::ESHandle< CaloGeometry >	geometry

std::string	hcalselector_

int	imc

int	iz

std::string	mc_

MonitorElement *	meEnConeEtaProfile

MonitorElement *	meEnConeEtaProfile_E

MonitorElement *	meEnConeEtaProfile_EH

MonitorElement *	meEnergyHcalVsEcalHB

MonitorElement *	meEnergyHcalVsEcalHE

MonitorElement *	meLog10Chi2profileHB

MonitorElement *	meLog10Chi2profileHE

MonitorElement *	meRecHitsEnergyHB

MonitorElement *	meRecHitsEnergyHE

MonitorElement *	meRecHitsEnergyHF

MonitorElement *	meRecHitsEnergyHO

MonitorElement *	meRecHitSimHitHB

MonitorElement *	meRecHitSimHitHE

MonitorElement *	meRecHitSimHitHF

MonitorElement *	meRecHitSimHitHFL

MonitorElement *	meRecHitSimHitHFS

MonitorElement *	meRecHitSimHitHO

MonitorElement *	meRecHitSimHitProfileHB

MonitorElement *	meRecHitSimHitProfileHE

MonitorElement *	meRecHitSimHitProfileHF

MonitorElement *	meRecHitSimHitProfileHFL

MonitorElement *	meRecHitSimHitProfileHFS

MonitorElement *	meRecHitSimHitProfileHO

MonitorElement *	meRecHitsM2Chi2HB

MonitorElement *	meRecHitsM2Chi2HE

MonitorElement *	meTEprofileHB

MonitorElement *	meTEprofileHB_High

MonitorElement *	meTEprofileHB_Low

MonitorElement *	meTEprofileHE

MonitorElement *	meTEprofileHE_Low

MonitorElement *	meTEprofileHF

MonitorElement *	meTEprofileHF_Low

MonitorElement *	meTEprofileHO

MonitorElement *	meTEprofileHO_High

int	nevtot

std::string	outputFile_

std::string	sign_

int	subdet_

bool	testNumber_

edm::EDGetTokenT< EBRecHitCollection >	tok_EB_

edm::EDGetTokenT< EERecHitCollection >	tok_EE_

edm::EDGetTokenT< edm::HepMCProduct >	tok_evt_

edm::EDGetTokenT< HBHERecHitCollection >	tok_hbhe_

edm::EDGetTokenT< HFRecHitCollection >	tok_hf_

edm::EDGetTokenT< edm::PCaloHitContainer >	tok_hh_

edm::EDGetTokenT< HORecHitCollection >	tok_ho_

std::string	topFolderName_

Additional Inherited Members
Public Types inherited from DQMEDAnalyzer
typedef dqm::reco::DQMStore	DQMStore

typedef dqm::reco::MonitorElement	MonitorElement

Public Types inherited from edm::stream::EDProducer< edm::GlobalCache< DQMEDAnalyzerGlobalCache >, edm::EndRunProducer, edm::EndLuminosityBlockProducer, edm::Accumulator >
typedef CacheContexts< T... >	CacheTypes

typedef CacheTypes::GlobalCache	GlobalCache

typedef AbilityChecker< T... >	HasAbility

typedef CacheTypes::LuminosityBlockCache	LuminosityBlockCache

typedef LuminosityBlockContextT< LuminosityBlockCache, RunCache, GlobalCache >	LuminosityBlockContext

typedef CacheTypes::LuminosityBlockSummaryCache	LuminosityBlockSummaryCache

typedef CacheTypes::RunCache	RunCache

typedef RunContextT< RunCache, GlobalCache >	RunContext

typedef CacheTypes::RunSummaryCache	RunSummaryCache

Static Public Member Functions inherited from DQMEDAnalyzer
static void	globalEndJob (DQMEDAnalyzerGlobalCache const *)

static void	globalEndLuminosityBlockProduce (edm::LuminosityBlock &lumi, edm::EventSetup const &setup, LuminosityBlockContext const *context)

static void	globalEndRunProduce (edm::Run &run, edm::EventSetup const &setup, RunContext const *context)

static std::unique_ptr< DQMEDAnalyzerGlobalCache >	initializeGlobalCache (edm::ParameterSet const &)

Protected Member Functions inherited from DQMEDAnalyzer
uint64_t	meId () const

Protected Attributes inherited from DQMEDAnalyzer
edm::EDPutTokenT< DQMToken >	lumiToken_

edm::EDPutTokenT< DQMToken >	runToken_

unsigned int	streamId_

Detailed Description

Definition at line 55 of file HcalRecHitsValidation.h.

Constructor & Destructor Documentation

◆ HcalRecHitsValidation()

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

Definition at line 8 of file HcalRecHitsValidation.cc.

     : topFolderName_(conf.getParameter<std::string>("TopFolderName")) {
   // DQM ROOT output
   outputFile_ = conf.getUntrackedParameter<std::string>("outputFile", "myfile.root");
  
   if (!outputFile_.empty()) {
     edm::LogInfo("OutputInfo") << " Hcal RecHit Task histograms will be saved to '" << outputFile_.c_str() << "'";
   } else {
     edm::LogInfo("OutputInfo") << " Hcal RecHit Task histograms will NOT be saved";
   }
  
   nevtot = 0;
  
   hcalselector_ = conf.getUntrackedParameter<std::string>("hcalselector", "all");
   ecalselector_ = conf.getUntrackedParameter<std::string>("ecalselector", "yes");
   sign_ = conf.getUntrackedParameter<std::string>("sign", "*");
   mc_ = conf.getUntrackedParameter<std::string>("mc", "yes");
   testNumber_ = conf.getParameter<bool>("TestNumber");
  
   // Collections
   tok_hbhe_ = consumes<HBHERecHitCollection>(conf.getUntrackedParameter<edm::InputTag>("HBHERecHitCollectionLabel"));
   tok_hf_ = consumes<HFRecHitCollection>(conf.getUntrackedParameter<edm::InputTag>("HFRecHitCollectionLabel"));
   tok_ho_ = consumes<HORecHitCollection>(conf.getUntrackedParameter<edm::InputTag>("HORecHitCollectionLabel"));
  
   // register for data access
   tok_evt_ = consumes<edm::HepMCProduct>(edm::InputTag("generatorSmeared"));
   edm::InputTag EBRecHitCollectionLabel = conf.getParameter<edm::InputTag>("EBRecHitCollectionLabel");
   tok_EB_ = consumes<EBRecHitCollection>(EBRecHitCollectionLabel);
   edm::InputTag EERecHitCollectionLabel = conf.getParameter<edm::InputTag>("EERecHitCollectionLabel");
   tok_EE_ = consumes<EERecHitCollection>(EERecHitCollectionLabel);
  
   tok_hh_ = consumes<edm::PCaloHitContainer>(conf.getUntrackedParameter<edm::InputTag>("SimHitCollectionLabel"));
  
   subdet_ = 5;
   if (hcalselector_ == "noise")
     subdet_ = 0;
   if (hcalselector_ == "HB")
     subdet_ = 1;
   if (hcalselector_ == "HE")
     subdet_ = 2;
   if (hcalselector_ == "HO")
     subdet_ = 3;
   if (hcalselector_ == "HF")
     subdet_ = 4;
   if (hcalselector_ == "all")
     subdet_ = 5;
   if (hcalselector_ == "ZS")
     subdet_ = 6;
  
   iz = 1;
   if (sign_ == "-")
     iz = -1;
   if (sign_ == "*")
     iz = 0;
  
   imc = 1;
   if (mc_ == "no")
     imc = 0;
 }

References PDWG_EXOHSCP_cff::EBRecHitCollectionLabel, ecalselector_, PDWG_EXOHSCP_cff::EERecHitCollectionLabel, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), hcalselector_, imc, iz, mc_, nevtot, outputFile_, sign_, AlCaHLTBitMon_QueryRunRegistry::string, subdet_, testNumber_, tok_EB_, tok_EE_, tok_evt_, tok_hbhe_, tok_hf_, tok_hh_, and tok_ho_.

◆ ~HcalRecHitsValidation()

HcalRecHitsValidation::~HcalRecHitsValidation ( )

override

Definition at line 68 of file HcalRecHitsValidation.cc.

68 {}

Member Function Documentation

◆ analyze()

void HcalRecHitsValidation::analyze	(	edm::Event const &	ev,
		edm::EventSetup const &	c
	)

overridevirtual

Reimplemented from DQMEDAnalyzer.

Definition at line 189 of file HcalRecHitsValidation.cc.

                                                                               {
   using namespace edm;
  
   edm::ESHandle<HcalDDDRecConstants> pHRNDC;
   c.get<HcalRecNumberingRecord>().get(pHRNDC);
   const HcalDDDRecConstants *hcons = &(*pHRNDC);
  
   // cuts for each subdet_ector mimiking  "Scheme B"
   //  double cutHB = 0.9, cutHE = 1.4, cutHO = 1.1, cutHFL = 1.2, cutHFS = 1.8;
  
   // energy in HCAL
   double eHcal = 0.;
   double eHcalCone = 0.;
   double eHcalConeHB = 0.;
   double eHcalConeHE = 0.;
   double eHcalConeHO = 0.;
   double eHcalConeHF = 0.;
   double eHcalConeHFL = 0.;
   double eHcalConeHFS = 0.;
  
   // Total numbet of RecHits in HCAL, in the cone, above 1 GeV theshold
   int nrechits = 0;
   int nrechitsCone = 0;
   int nrechitsThresh = 0;
  
   // energy in ECAL
   double eEcal = 0.;
   double eEcalB = 0.;
   double eEcalE = 0.;
   double eEcalCone = 0.;
   int numrechitsEcal = 0;
  
   // MC info
   double phi_MC = -999999.;  // phi of initial particle from HepMC
   double eta_MC = -999999.;  // eta of initial particle from HepMC
  
   // HCAL energy around MC eta-phi at all depths;
   double partR = 0.3;
  
   if (imc != 0) {
     edm::Handle<edm::HepMCProduct> evtMC;
     ev.getByToken(tok_evt_, evtMC);  // generator in late 310_preX
     if (!evtMC.isValid()) {
       edm::LogInfo("HcalRecHitsValidation") << "no HepMCProduct found";
     } else {
       //    std::cout << "*** source HepMCProduct found"<< std::endl;
     }
  
     // MC particle with highest pt is taken as a direction reference
     double maxPt = -99999.;
     int npart = 0;
     const HepMC::GenEvent *myGenEvent = evtMC->GetEvent();
     for (HepMC::GenEvent::particle_const_iterator p = myGenEvent->particles_begin(); p != myGenEvent->particles_end();
          ++p) {
       double phip = (*p)->momentum().phi();
       double etap = (*p)->momentum().eta();
       //    phi_MC = phip;
       //    eta_MC = etap;
       double pt = (*p)->momentum().perp();
       if (pt > maxPt) {
         npart++;
         maxPt = pt;
         phi_MC = phip;
         eta_MC = etap;
       }
     }
     //  std::cout << "*** Max pT = " << maxPt <<  std::endl;
   }
  
   //   std::cout << "*** 2" << std::endl;
  
   c.get<CaloGeometryRecord>().get(geometry);
  
   // Fill working vectors of HCAL RecHits quantities (all of these are drawn)
   fillRecHitsTmp(subdet_, ev);
  
   //  std::cout << "*** 3" << std::endl;
  
   //===========================================================================
   // IN ALL other CASES : ieta-iphi maps
   //===========================================================================
  
   // ECAL
   if (ecalselector_ == "yes" && (subdet_ == 1 || subdet_ == 2 || subdet_ == 5)) {
     Handle<EBRecHitCollection> rhitEB;
  
     EcalRecHitCollection::const_iterator RecHit;
     EcalRecHitCollection::const_iterator RecHitEnd;
  
     if (ev.getByToken(tok_EB_, rhitEB)) {
       RecHit = rhitEB.product()->begin();
       RecHitEnd = rhitEB.product()->end();
  
       for (; RecHit != RecHitEnd; ++RecHit) {
         EBDetId EBid = EBDetId(RecHit->id());
  
         auto cellGeometry = geometry->getSubdetectorGeometry(EBid)->getGeometry(EBid);
         double eta = cellGeometry->getPosition().eta();
         double phi = cellGeometry->getPosition().phi();
         double en = RecHit->energy();
         eEcal += en;
         eEcalB += en;
  
         double r = dR(eta_MC, phi_MC, eta, phi);
         if (r < partR) {
           eEcalCone += en;
           numrechitsEcal++;
         }
       }
     }
  
     Handle<EERecHitCollection> rhitEE;
  
     if (ev.getByToken(tok_EE_, rhitEE)) {
       RecHit = rhitEE.product()->begin();
       RecHitEnd = rhitEE.product()->end();
  
       for (; RecHit != RecHitEnd; ++RecHit) {
         EEDetId EEid = EEDetId(RecHit->id());
  
         auto cellGeometry = geometry->getSubdetectorGeometry(EEid)->getGeometry(EEid);
         double eta = cellGeometry->getPosition().eta();
         double phi = cellGeometry->getPosition().phi();
         double en = RecHit->energy();
         eEcal += en;
         eEcalE += en;
  
         double r = dR(eta_MC, phi_MC, eta, phi);
         if (r < partR) {
           eEcalCone += en;
           numrechitsEcal++;
         }
       }
     }
   }  // end of ECAL selection
  
   //     std::cout << "*** 4" << std::endl;
  
   //===========================================================================
   // SUBSYSTEMS,
   //===========================================================================
  
   if ((subdet_ != 6) && (subdet_ != 0)) {
     //       std::cout << "*** 6" << std::endl;
  
     double HcalCone = 0.;
  
     int ietaMax = 9999;
     double etaMax = 9999.;
  
     //   CYCLE over cells ====================================================
  
     for (unsigned int i = 0; i < cen.size(); i++) {
       int sub = csub[i];
       int depth = cdepth[i];
       double eta = ceta[i];
       double phi = cphi[i];
       double en = cen[i];
       double t = ctime[i];
       int ieta = cieta[i];
       double chi2 = cchi2[i];
  
       double chi2_log10 = 9.99;  // initial value above histos limits , keep it if chi2 <= 0.
       if (chi2 > 0.)
         chi2_log10 = log10(chi2);
  
       nrechits++;
       eHcal += en;
       if (en > 1.)
         nrechitsThresh++;
  
       double r = dR(eta_MC, phi_MC, eta, phi);
       if (r < partR) {
         if (sub == 1)
           eHcalConeHB += en;
         if (sub == 2)
           eHcalConeHE += en;
         if (sub == 3)
           eHcalConeHO += en;
         if (sub == 4) {
           eHcalConeHF += en;
           if (depth == 1)
             eHcalConeHFL += en;
           else
             eHcalConeHFS += en;
         }
         eHcalCone += en;
         nrechitsCone++;
  
         HcalCone += en;
  
         // alternative: ietamax -> closest to MC eta  !!!
         float eta_diff = fabs(eta_MC - eta);
         if (eta_diff < etaMax) {
           etaMax = eta_diff;
           ietaMax = ieta;
         }
       }
  
       // The energy and overall timing histos are drawn while
       // the ones split by depth are not
       if (sub == 1 && (subdet_ == 1 || subdet_ == 5)) {
         meRecHitsM2Chi2HB->Fill(chi2_log10);
         meLog10Chi2profileHB->Fill(en, chi2_log10);
  
         meRecHitsEnergyHB->Fill(en);
  
         meTEprofileHB_Low->Fill(en, t);
         meTEprofileHB->Fill(en, t);
         meTEprofileHB_High->Fill(en, t);
       }
       if (sub == 2 && (subdet_ == 2 || subdet_ == 5)) {
         meRecHitsM2Chi2HE->Fill(chi2_log10);
         meLog10Chi2profileHE->Fill(en, chi2_log10);
  
         meRecHitsEnergyHE->Fill(en);
  
         meTEprofileHE_Low->Fill(en, t);
         meTEprofileHE->Fill(en, t);
       }
       if (sub == 4 && (subdet_ == 4 || subdet_ == 5)) {
         meRecHitsEnergyHF->Fill(en);
  
         meTEprofileHF_Low->Fill(en, t);
         meTEprofileHF->Fill(en, t);
       }
       if (sub == 3 && (subdet_ == 3 || subdet_ == 5)) {
         meRecHitsEnergyHO->Fill(en);
  
         meTEprofileHO->Fill(en, t);
         meTEprofileHO_High->Fill(en, t);
       }
     }
  
     if (imc != 0) {
       meEnConeEtaProfile->Fill(double(ietaMax), HcalCone);  //
       meEnConeEtaProfile_E->Fill(double(ietaMax), eEcalCone);
       meEnConeEtaProfile_EH->Fill(double(ietaMax), HcalCone + eEcalCone);
     }
  
     //     std::cout << "*** 7" << std::endl;
   }
  
   // SimHits vs. RecHits
   const CaloGeometry *geo = geometry.product();
   if (subdet_ > 0 && subdet_ < 6 && imc != 0) {  // not noise
  
     edm::Handle<PCaloHitContainer> hcalHits;
     if (ev.getByToken(tok_hh_, hcalHits)) {
       const PCaloHitContainer *SimHitResult = hcalHits.product();
  
       double enSimHits = 0.;
       double enSimHitsHB = 0.;
       double enSimHitsHE = 0.;
       double enSimHitsHO = 0.;
       double enSimHitsHF = 0.;
       double enSimHitsHFL = 0.;
       double enSimHitsHFS = 0.;
       // sum of SimHits in the cone
  
       for (std::vector<PCaloHit>::const_iterator SimHits = SimHitResult->begin(); SimHits != SimHitResult->end();
            ++SimHits) {
         int sub, depth;
         HcalDetId cell;
  
         if (testNumber_)
           cell = HcalHitRelabeller::relabel(SimHits->id(), hcons);
         else
           cell = HcalDetId(SimHits->id());
  
         sub = cell.subdet();
         depth = cell.depth();
  
         if (sub != subdet_ && subdet_ != 5)
           continue;  // If we are not looking at all of the subdetectors and the
                      // simhit doesn't come from the specific subdetector of
                      // interest, then we won't do any thing with it
  
         const HcalGeometry *cellGeometry =
             dynamic_cast<const HcalGeometry *>(geo->getSubdetectorGeometry(DetId::Hcal, cell.subdet()));
         double etaS = cellGeometry->getPosition(cell).eta();
         double phiS = cellGeometry->getPosition(cell).phi();
         double en = SimHits->energy();
  
         double r = dR(eta_MC, phi_MC, etaS, phiS);
  
         if (r < partR) {  // just energy in the small cone
  
           enSimHits += en;
           if (sub == static_cast<int>(HcalBarrel))
             enSimHitsHB += en;
           if (sub == static_cast<int>(HcalEndcap))
             enSimHitsHE += en;
           if (sub == static_cast<int>(HcalOuter))
             enSimHitsHO += en;
           if (sub == static_cast<int>(HcalForward)) {
             enSimHitsHF += en;
             if (depth == 1)
               enSimHitsHFL += en;
             else
               enSimHitsHFS += en;
           }
         }
       }
  
       // Now some histos with SimHits
  
       if (subdet_ == 4 || subdet_ == 5) {
         meRecHitSimHitHF->Fill(enSimHitsHF, eHcalConeHF);
         meRecHitSimHitProfileHF->Fill(enSimHitsHF, eHcalConeHF);
  
         meRecHitSimHitHFL->Fill(enSimHitsHFL, eHcalConeHFL);
         meRecHitSimHitProfileHFL->Fill(enSimHitsHFL, eHcalConeHFL);
         meRecHitSimHitHFS->Fill(enSimHitsHFS, eHcalConeHFS);
         meRecHitSimHitProfileHFS->Fill(enSimHitsHFS, eHcalConeHFS);
       }
       if (subdet_ == 1 || subdet_ == 5) {
         meRecHitSimHitHB->Fill(enSimHitsHB, eHcalConeHB);
         meRecHitSimHitProfileHB->Fill(enSimHitsHB, eHcalConeHB);
       }
       if (subdet_ == 2 || subdet_ == 5) {
         meRecHitSimHitHE->Fill(enSimHitsHE, eHcalConeHE);
         meRecHitSimHitProfileHE->Fill(enSimHitsHE, eHcalConeHE);
       }
       if (subdet_ == 3 || subdet_ == 5) {
         meRecHitSimHitHO->Fill(enSimHitsHO, eHcalConeHO);
         meRecHitSimHitProfileHO->Fill(enSimHitsHO, eHcalConeHO);
       }
     }
   }
  
   nevtot++;
 }

References edm::SortedCollection< T, SORT >::begin(), HltBtagPostValidation_cff::c, cchi2, cdepth, cen, ceta, hltPixelTracks_cff::chi2, cieta, cphi, csub, ctime, LEDCalibrationChannels::depth, dR(), ecalselector_, edm::SortedCollection< T, SORT >::end(), PVValHelper::eta, PV3DBase< T, PVType, FrameType >::eta(), ALCARECOTkAlBeamHalo_cff::etaMax, ev, dqm::impl::MonitorElement::Fill(), fillRecHitsTmp(), get, edm::HepMCProduct::GetEvent(), HcalGeometry::getPosition(), CaloGeometry::getSubdetectorGeometry(), DetId::Hcal, HcalBarrel, HcalEndcap, HcalForward, HcalOuter, mps_fire::i, LEDCalibrationChannels::ieta, imc, edm::HandleBase::isValid(), MuonErrorMatrixAnalyzer_cfi::maxPt, meEnConeEtaProfile, meEnConeEtaProfile_E, meEnConeEtaProfile_EH, meLog10Chi2profileHB, meLog10Chi2profileHE, meRecHitsEnergyHB, meRecHitsEnergyHE, meRecHitsEnergyHF, meRecHitsEnergyHO, meRecHitSimHitHB, meRecHitSimHitHE, meRecHitSimHitHF, meRecHitSimHitHFL, meRecHitSimHitHFS, meRecHitSimHitHO, meRecHitSimHitProfileHB, meRecHitSimHitProfileHE, meRecHitSimHitProfileHF, meRecHitSimHitProfileHFL, meRecHitSimHitProfileHFS, meRecHitSimHitProfileHO, meRecHitsM2Chi2HB, meRecHitsM2Chi2HE, meTEprofileHB, meTEprofileHB_High, meTEprofileHB_Low, meTEprofileHE, meTEprofileHE_Low, meTEprofileHF, meTEprofileHF_Low, meTEprofileHO, meTEprofileHO_High, nevtot, npart, AlCaHLTBitMon_ParallelJobs::p, phi, PV3DBase< T, PVType, FrameType >::phi(), edm::Handle< T >::product(), DiDispStaMuonMonitor_cfi::pt, alignCSCRings::r, HcalHitRelabeller::relabel(), HcalDetId::subdet(), subdet_, submitPVValidationJobs::t, testNumber_, tok_EB_, tok_EE_, tok_evt_, and tok_hh_.

◆ bookHistograms()

void HcalRecHitsValidation::bookHistograms	(	DQMStore::IBooker &	ib,
		edm::Run const &	run,
		edm::EventSetup const &	es
	)

overridevirtual

Implements DQMEDAnalyzer.

Definition at line 70 of file HcalRecHitsValidation.cc.

                                                                                                           {
   Char_t histo[200];
  
   ib.setCurrentFolder(topFolderName_);
  
   //======================= Now various cases one by one ===================
  
   // Histograms drawn for single pion scan
   if (subdet_ != 0 && imc != 0) {  // just not for noise
     sprintf(histo, "HcalRecHitTask_En_rechits_cone_profile_vs_ieta_all_depths");
     meEnConeEtaProfile = ib.bookProfile(histo, histo, 83, -41.5, 41.5, -100., 2000., " ");
  
     sprintf(histo, "HcalRecHitTask_En_rechits_cone_profile_vs_ieta_all_depths_E");
     meEnConeEtaProfile_E = ib.bookProfile(histo, histo, 83, -41.5, 41.5, -100., 2000., " ");
  
     sprintf(histo, "HcalRecHitTask_En_rechits_cone_profile_vs_ieta_all_depths_EH");
     meEnConeEtaProfile_EH = ib.bookProfile(histo, histo, 83, -41.5, 41.5, -100., 2000., " ");
   }
  
   // ************** HB **********************************
   if (subdet_ == 1 || subdet_ == 5) {
     sprintf(histo, "HcalRecHitTask_M2Log10Chi2_of_rechits_HB");  //   Chi2
     meRecHitsM2Chi2HB = ib.book1D(histo, histo, 120, -2., 10.);
  
     sprintf(histo, "HcalRecHitTask_Log10Chi2_vs_energy_profile_HB");
     meLog10Chi2profileHB = ib.bookProfile(histo, histo, 300, -5., 295., -2., 9.9, " ");
  
     sprintf(histo, "HcalRecHitTask_energy_of_rechits_HB");
     meRecHitsEnergyHB = ib.book1D(histo, histo, 2010, -10., 2000.);
  
     sprintf(histo, "HcalRecHitTask_timing_vs_energy_profile_HB");
     meTEprofileHB = ib.bookProfile(histo, histo, 150, -5., 295., -48., 92., " ");
  
     sprintf(histo, "HcalRecHitTask_timing_vs_energy_profile_Low_HB");
     meTEprofileHB_Low = ib.bookProfile(histo, histo, 150, -5., 295., -48., 92., " ");
  
     sprintf(histo, "HcalRecHitTask_timing_vs_energy_profile_High_HB");
     meTEprofileHB_High = ib.bookProfile(histo, histo, 150, -5., 295., 48., 92., " ");
  
     if (imc != 0) {
       sprintf(histo, "HcalRecHitTask_energy_rechits_vs_simhits_HB");
       meRecHitSimHitHB = ib.book2D(histo, histo, 120, 0., 1.2, 300, 0., 150.);
       sprintf(histo, "HcalRecHitTask_energy_rechits_vs_simhits_profile_HB");
       meRecHitSimHitProfileHB = ib.bookProfile(histo, histo, 120, 0., 1.2, 0., 500., " ");
     }
   }
  
   // ********************** HE ************************************
   if (subdet_ == 2 || subdet_ == 5) {
     sprintf(histo, "HcalRecHitTask_M2Log10Chi2_of_rechits_HE");  //   Chi2
     meRecHitsM2Chi2HE = ib.book1D(histo, histo, 120, -2., 10.);
  
     sprintf(histo, "HcalRecHitTask_Log10Chi2_vs_energy_profile_HE");
     meLog10Chi2profileHE = ib.bookProfile(histo, histo, 1000, -5., 995., -2., 9.9, " ");
  
     sprintf(histo, "HcalRecHitTask_energy_of_rechits_HE");
     meRecHitsEnergyHE = ib.book1D(histo, histo, 2010, -10., 2000.);
  
     sprintf(histo, "HcalRecHitTask_timing_vs_energy_profile_Low_HE");
     meTEprofileHE_Low = ib.bookProfile(histo, histo, 80, -5., 75., -48., 92., " ");
  
     sprintf(histo, "HcalRecHitTask_timing_vs_energy_profile_HE");
     meTEprofileHE = ib.bookProfile(histo, histo, 200, -5., 2995., -48., 92., " ");
  
     if (imc != 0) {
       sprintf(histo, "HcalRecHitTask_energy_rechits_vs_simhits_HE");
       meRecHitSimHitHE = ib.book2D(histo, histo, 120, 0., 0.6, 300, 0., 150.);
       sprintf(histo, "HcalRecHitTask_energy_rechits_vs_simhits_profile_HE");
       meRecHitSimHitProfileHE = ib.bookProfile(histo, histo, 120, 0., 0.6, 0., 500., " ");
     }
   }
  
   // ************** HO ****************************************
   if (subdet_ == 3 || subdet_ == 5) {
     sprintf(histo, "HcalRecHitTask_energy_of_rechits_HO");
     meRecHitsEnergyHO = ib.book1D(histo, histo, 2010, -10., 2000.);
  
     sprintf(histo, "HcalRecHitTask_timing_vs_energy_profile_HO");
     meTEprofileHO = ib.bookProfile(histo, histo, 60, -5., 55., -48., 92., " ");
  
     sprintf(histo, "HcalRecHitTask_timing_vs_energy_profile_High_HO");
     meTEprofileHO_High = ib.bookProfile(histo, histo, 100, -5., 995., -48., 92., " ");
  
     if (imc != 0) {
       sprintf(histo, "HcalRecHitTask_energy_rechits_vs_simhits_HO");
       meRecHitSimHitHO = ib.book2D(histo, histo, 150, 0., 1.5, 350, 0., 350.);
       sprintf(histo, "HcalRecHitTask_energy_rechits_vs_simhits_profile_HO");
       meRecHitSimHitProfileHO = ib.bookProfile(histo, histo, 150, 0., 1.5, 0., 500., " ");
     }
   }
  
   // ********************** HF ************************************
   if (subdet_ == 4 || subdet_ == 5) {
     sprintf(histo, "HcalRecHitTask_energy_of_rechits_HF");
     meRecHitsEnergyHF = ib.book1D(histo, histo, 2010, -10., 2000.);
  
     sprintf(histo, "HcalRecHitTask_timing_vs_energy_profile_Low_HF");
     meTEprofileHF_Low = ib.bookProfile(histo, histo, 100, -5., 195., -48., 92., " ");
  
     sprintf(histo, "HcalRecHitTask_timing_vs_energy_profile_HF");
     meTEprofileHF = ib.bookProfile(histo, histo, 200, -5., 995., -48., 92., " ");
  
     if (imc != 0) {
       sprintf(histo, "HcalRecHitTask_energy_rechits_vs_simhits_HF");
       meRecHitSimHitHF = ib.book2D(histo, histo, 50, 0., 50., 150, 0., 150.);
       sprintf(histo, "HcalRecHitTask_energy_rechits_vs_simhits_HFL");
       meRecHitSimHitHFL = ib.book2D(histo, histo, 50, 0., 50., 150, 0., 150.);
       sprintf(histo, "HcalRecHitTask_energy_rechits_vs_simhits_HFS");
       meRecHitSimHitHFS = ib.book2D(histo, histo, 50, 0., 50., 150, 0., 150.);
       sprintf(histo, "HcalRecHitTask_energy_rechits_vs_simhits_profile_HF");
       meRecHitSimHitProfileHF = ib.bookProfile(histo, histo, 50, 0., 50., 0., 500., " ");
       sprintf(histo, "HcalRecHitTask_energy_rechits_vs_simhits_profile_HFL");
       meRecHitSimHitProfileHFL = ib.bookProfile(histo, histo, 50, 0., 50., 0., 500., " ");
       sprintf(histo, "HcalRecHitTask_energy_rechits_vs_simhits_profile_HFS");
       meRecHitSimHitProfileHFS = ib.bookProfile(histo, histo, 50, 0., 50., 0., 500., " ");
     }
   }
 }

References timingPdfMaker::histo, cuy::ib, imc, meEnConeEtaProfile, meEnConeEtaProfile_E, meEnConeEtaProfile_EH, meLog10Chi2profileHB, meLog10Chi2profileHE, meRecHitsEnergyHB, meRecHitsEnergyHE, meRecHitsEnergyHF, meRecHitsEnergyHO, meRecHitSimHitHB, meRecHitSimHitHE, meRecHitSimHitHF, meRecHitSimHitHFL, meRecHitSimHitHFS, meRecHitSimHitHO, meRecHitSimHitProfileHB, meRecHitSimHitProfileHE, meRecHitSimHitProfileHF, meRecHitSimHitProfileHFL, meRecHitSimHitProfileHFS, meRecHitSimHitProfileHO, meRecHitsM2Chi2HB, meRecHitsM2Chi2HE, meTEprofileHB, meTEprofileHB_High, meTEprofileHB_Low, meTEprofileHE, meTEprofileHE_Low, meTEprofileHF, meTEprofileHF_Low, meTEprofileHO, meTEprofileHO_High, subdet_, and topFolderName_.

◆ dPhiWsign()

double HcalRecHitsValidation::dPhiWsign	(	double	phi1,
		double	phi2
	)

private

Definition at line 678 of file HcalRecHitsValidation.cc.

                                                                 {
   // clockwise      phi2 w.r.t phi1 means "+" phi distance
   // anti-clockwise phi2 w.r.t phi1 means "-" phi distance
  
   double PI = 3.1415926535898;
   double a1 = phi1;
   double a2 = phi2;
   double tmp = a2 - a1;
   if (a1 * a2 < 0.) {
     if (a1 > 0.5 * PI)
       tmp += 2. * PI;
     if (a2 > 0.5 * PI)
       tmp -= 2. * PI;
   }
   return tmp;
 }

References testProducerWithPsetDescEmpty_cfi::a2, PI, and createJobs::tmp.

◆ dR()

double HcalRecHitsValidation::dR	(	double	eta1,
		double	phi1,
		double	eta2,
		double	phi2
	)

private

Definition at line 645 of file HcalRecHitsValidation.cc.

                                                                                    {
   double PI = 3.1415926535898;
   double deltaphi = phi1 - phi2;
   if (phi2 > phi1) {
     deltaphi = phi2 - phi1;
   }
   if (deltaphi > PI) {
     deltaphi = 2. * PI - deltaphi;
   }
   double deltaeta = eta2 - eta1;
   double tmp = sqrt(deltaeta * deltaeta + deltaphi * deltaphi);
   return tmp;
 }

References HLT_FULL_cff::eta1, HLT_FULL_cff::eta2, mathSSE::sqrt(), and createJobs::tmp.

Referenced by analyze().

◆ fillRecHitsTmp()

void HcalRecHitsValidation::fillRecHitsTmp	(	int	subdet_,
		edm::Event const &	ev
	)

privatevirtual

Definition at line 524 of file HcalRecHitsValidation.cc.

                                                                           {
   using namespace edm;
  
   // initialize data vectors
   csub.clear();
   cen.clear();
   ceta.clear();
   cphi.clear();
   ctime.clear();
   cieta.clear();
   ciphi.clear();
   cdepth.clear();
   cz.clear();
   cchi2.clear();
  
   if (subdet_ == 1 || subdet_ == 2 || subdet_ == 5 || subdet_ == 6 || subdet_ == 0) {
     // HBHE
     edm::Handle<HBHERecHitCollection> hbhecoll;
     if (ev.getByToken(tok_hbhe_, hbhecoll)) {
       const CaloGeometry *geo = geometry.product();
  
       for (HBHERecHitCollection::const_iterator j = hbhecoll->begin(); j != hbhecoll->end(); j++) {
         HcalDetId cell(j->id());
         const HcalGeometry *cellGeometry =
             dynamic_cast<const HcalGeometry *>(geo->getSubdetectorGeometry(DetId::Hcal, cell.subdet()));
         double eta = cellGeometry->getPosition(cell).eta();
         double phi = cellGeometry->getPosition(cell).phi();
         double zc = cellGeometry->getPosition(cell).z();
         int sub = cell.subdet();
         int depth = cell.depth();
         int inteta = cell.ieta();
         int intphi = cell.iphi() - 1;
         double en = j->energy();
         double t = j->time();
         double chi2 = j->chi2();
  
         if ((iz > 0 && eta > 0.) || (iz < 0 && eta < 0.) || iz == 0) {
           csub.push_back(sub);
           cen.push_back(en);
           ceta.push_back(eta);
           cphi.push_back(phi);
           ctime.push_back(t);
           cieta.push_back(inteta);
           ciphi.push_back(intphi);
           cdepth.push_back(depth);
           cz.push_back(zc);
           cchi2.push_back(chi2);
         }
       }
     }
   }
  
   if (subdet_ == 4 || subdet_ == 5 || subdet_ == 6 || subdet_ == 0) {
     // HF
     edm::Handle<HFRecHitCollection> hfcoll;
     if (ev.getByToken(tok_hf_, hfcoll)) {
       for (HFRecHitCollection::const_iterator j = hfcoll->begin(); j != hfcoll->end(); j++) {
         HcalDetId cell(j->id());
         auto cellGeometry = geometry->getSubdetectorGeometry(cell)->getGeometry(cell);
  
         double eta = cellGeometry->getPosition().eta();
         double phi = cellGeometry->getPosition().phi();
         double zc = cellGeometry->getPosition().z();
         int sub = cell.subdet();
         int depth = cell.depth();
         int inteta = cell.ieta();
         int intphi = cell.iphi() - 1;
         double en = j->energy();
         double t = j->time();
  
         if ((iz > 0 && eta > 0.) || (iz < 0 && eta < 0.) || iz == 0) {
           csub.push_back(sub);
           cen.push_back(en);
           ceta.push_back(eta);
           cphi.push_back(phi);
           ctime.push_back(t);
           cieta.push_back(inteta);
           ciphi.push_back(intphi);
           cdepth.push_back(depth);
           cz.push_back(zc);
           cchi2.push_back(0.);
         }
       }
     }
   }
  
   // HO
   if (subdet_ == 3 || subdet_ == 5 || subdet_ == 6 || subdet_ == 0) {
     edm::Handle<HORecHitCollection> hocoll;
     if (ev.getByToken(tok_ho_, hocoll)) {
       for (HORecHitCollection::const_iterator j = hocoll->begin(); j != hocoll->end(); j++) {
         HcalDetId cell(j->id());
         auto cellGeometry = geometry->getSubdetectorGeometry(cell)->getGeometry(cell);
  
         double eta = cellGeometry->getPosition().eta();
         double phi = cellGeometry->getPosition().phi();
         double zc = cellGeometry->getPosition().z();
         int sub = cell.subdet();
         int depth = cell.depth();
         int inteta = cell.ieta();
         int intphi = cell.iphi() - 1;
         double t = j->time();
         double en = j->energy();
  
         if ((iz > 0 && eta > 0.) || (iz < 0 && eta < 0.) || iz == 0) {
           csub.push_back(sub);
           cen.push_back(en);
           ceta.push_back(eta);
           cphi.push_back(phi);
           ctime.push_back(t);
           cieta.push_back(inteta);
           ciphi.push_back(intphi);
           cdepth.push_back(depth);
           cz.push_back(zc);
           cchi2.push_back(0.);
         }
       }
     }
   }
 }

References edm::SortedCollection< T, SORT >::begin(), cchi2, cdepth, cen, ceta, hltPixelTracks_cff::chi2, cieta, ciphi, cphi, csub, ctime, cz, LEDCalibrationChannels::depth, edm::SortedCollection< T, SORT >::end(), PVValHelper::eta, ev, CaloGeometry::getSubdetectorGeometry(), DetId::Hcal, iz, dqmiolumiharvest::j, phi, subdet_, submitPVValidationJobs::t, tok_hbhe_, tok_hf_, and tok_ho_.

Referenced by analyze().

◆ phi12()

double HcalRecHitsValidation::phi12	(	double	phi1,
		double	en1,
		double	phi2,
		double	en2
	)

private

Definition at line 659 of file HcalRecHitsValidation.cc.

                                                                                     {
   // weighted mean value of phi1 and phi2
  
   double tmp;
   double PI = 3.1415926535898;
   double a1 = phi1;
   double a2 = phi2;
  
   if (a1 > 0.5 * PI && a2 < 0.)
     a2 += 2 * PI;
   if (a2 > 0.5 * PI && a1 < 0.)
     a1 += 2 * PI;
   tmp = (a1 * en1 + a2 * en2) / (en1 + en2);
   if (tmp > PI)
     tmp -= 2. * PI;
  
   return tmp;
 }