#include <Calibration/AlCaHOCalibProducer/src/AlCaHOCalibProducer.cc>

Inheritance diagram for AlCaHOCalibProducer:

Public Types
typedef Basic3DVector< float >	DirectionType

typedef Basic3DVector< float >	PositionType

typedef Basic3DVector< float >	RotationType

Public Types inherited from edm::EDProducer
typedef EDProducer	ModuleType

Public Types inherited from edm::ProducerBase
using	ModuleToResolverIndicies = std::unordered_multimap< std::string, std::tuple< edm::TypeID const , const char , edm::ProductResolverIndex >>

typedef ProductRegistryHelper::TypeLabelList	TypeLabelList

Public Types inherited from edm::EDConsumerBase
typedef ProductLabels	Labels

Public Member Functions
	AlCaHOCalibProducer (const edm::ParameterSet &)

	~AlCaHOCalibProducer () override

Public Member Functions inherited from edm::EDProducer
	EDProducer ()

SerialTaskQueue *	globalLuminosityBlocksQueue ()

SerialTaskQueue *	globalRunsQueue ()

ModuleDescription const &	moduleDescription () const

	~EDProducer () override

Public Member Functions inherited from edm::ProducerBase
void	callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)

std::vector< edm::ProductResolverIndex > const &	indiciesForPutProducts (BranchType iBranchType) const

	ProducerBase ()

std::vector< edm::ProductResolverIndex > const &	putTokenIndexToProductResolverIndex () const

void	registerProducts (ProducerBase , ProductRegistry , ModuleDescription const &)

std::function< void(BranchDescription const &)>	registrationCallback () const
	used by the fwk to register list of products More...

void	resolvePutIndicies (BranchType iBranchType, ModuleToResolverIndicies const &iIndicies, std::string const &moduleLabel)

	~ProducerBase () noexcept(false) override

Public Member Functions inherited from edm::EDConsumerBase
std::vector< ConsumesInfo >	consumesInfo () const

void	convertCurrentProcessAlias (std::string const &processName)
	Convert "@currentProcess" in InputTag process names to the actual current process name. More...

	EDConsumerBase ()

	EDConsumerBase (EDConsumerBase const &)=delete

	EDConsumerBase (EDConsumerBase &&)=default

ProductResolverIndexAndSkipBit	indexFrom (EDGetToken, BranchType, TypeID const &) const

void	itemsMayGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const

void	itemsToGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const

std::vector< ProductResolverIndexAndSkipBit > const &	itemsToGetFrom (BranchType iType) const

void	labelsForToken (EDGetToken iToken, Labels &oLabels) const

void	modulesWhoseProductsAreConsumed (std::vector< ModuleDescription const * > &modules, ProductRegistry const &preg, std::map< std::string, ModuleDescription const * > const &labelsToDesc, std::string const &processName) const

EDConsumerBase const &	operator= (EDConsumerBase const &)=delete

EDConsumerBase &	operator= (EDConsumerBase &&)=default

bool	registeredToConsume (ProductResolverIndex, bool, BranchType) const

bool	registeredToConsumeMany (TypeID const &, BranchType) const

ProductResolverIndexAndSkipBit	uncheckedIndexFrom (EDGetToken) const

void	updateLookup (BranchType iBranchType, ProductResolverIndexHelper const &, bool iPrefetchMayGet)

virtual	~EDConsumerBase () noexcept(false)

Private Types
typedef math::Error< 5 >::type	CovarianceMatrix

Private Member Functions
void	beginJob () override

void	beginRun (edm::Run const &, edm::EventSetup const &) override

void	endJob () override

void	fillHOStore (const reco::TrackRef &ncosm, HOCalibVariables &tmpHOCalib, std::unique_ptr< HOCalibVariableCollection > &hostore, int Noccu_old, int indx, edm::Handle< reco::TrackCollection > cosmicmuon, edm::View< reco::Muon >::const_iterator muon1, const edm::Event &iEvent, const edm::EventSetup &iSetup)

void	findHOEtaPhi (int iphsect, int &ietaho, int &iphiho)

FreeTrajectoryState	getFreeTrajectoryState (const reco::Track &tk, const MagneticField *field, int itag, bool dir)

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

Private Attributes
std::map< std::string, bool >	fired

edm::ESHandle< HcalSeverityLevelComputer >	hcalSevLvlComputerHndl

TH2F *	ho_occupency [5]

int	iring

float	localxhor0

float	localxhor1

float	localyhor0

float	localyhor1

bool	m_cosmic

int	m_endTS

bool	m_hbinfo

bool	m_occupancy

double	m_sigma

int	m_startTS

edm::InputTag	muonTags_

const int	ncidmx = 5

const int	netabin = 16

const int	netamx = 32

int	Nevents

int	Noccu

const int	nphimx = 72

int	nRuns

unsigned int	Ntp

const double	rHOL0 = 382.0

const double	rHOL1 = 407.0

const HcalChannelQuality *	theHcalChStatus

edm::EDGetTokenT< HBHERecHitCollection >	tok_hbhe_

edm::EDGetTokenT< HORecHitCollection >	tok_ho_

edm::EDGetTokenT< LumiScalersCollection >	tok_lumi_

edm::EDGetTokenT< edm::View< reco::Muon > >	tok_muons_

edm::EDGetTokenT< reco::TrackCollection >	tok_muonsCosmic_

edm::EDGetTokenT< CaloTowerCollection >	tok_tower_

edm::EDGetTokenT< reco::VertexCollection >	tok_vertex_

float	xhor0

float	xhor1

float	yhor0

float	yhor1

Additional Inherited Members
Static Public Member Functions inherited from edm::EDProducer
static const std::string &	baseType ()

static void	fillDescriptions (ConfigurationDescriptions &descriptions)

static void	prevalidate (ConfigurationDescriptions &descriptions)

static bool	wantsGlobalLuminosityBlocks ()

static bool	wantsGlobalRuns ()

static bool	wantsStreamLuminosityBlocks ()

static bool	wantsStreamRuns ()

Protected Member Functions inherited from edm::EDConsumerBase
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	consumes (edm::InputTag const &tag)

EDGetToken	consumes (const TypeToGet &id, edm::InputTag const &tag)

template<BranchType B>
EDGetToken	consumes (TypeToGet const &id, edm::InputTag const &tag)

ConsumesCollector	consumesCollector ()
	Use a ConsumesCollector to gather consumes information from helper functions. More...

template<typename ProductType , BranchType B = InEvent>
void	consumesMany ()

void	consumesMany (const TypeToGet &id)

template<BranchType B>
void	consumesMany (const TypeToGet &id)

template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	mayConsume (edm::InputTag const &tag)

EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)

template<BranchType B>
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)

Detailed Description

change magnetic field inside ../data/HOCosmicCalib_RecoLocalMuon.cff ../data/HOCosmicCalib_RecoLocalTracker.cff

Description: <one line="" class="" summary>="">

Implementation: <Notes on="" implementation>=""> Missing towers : eta=5, phi=18-19 : eta = -5, phi =11-14

HO tile sizes Ring +-2 : width Tray 6:404.6, 5&4:347.6, 3:352.6, 2:364.6, 1:315.6 (phi ordering is opposite) lenght Tile 1:420.1, 2:545.1, 3:583.3, 4:626.0, 5:335.5

    (five tiles, 1 is close to Ring 1 and 5 is towardslc endcap)

Ring +-1 : width Tray 6:404.6, 5&4:347.6, 3:352.6, 2:364.6, 1:315.6 (same as Ring+-2) lenght Tile 1:391.5, 2:394.2, 3:411.0, 4:430.9, 5:454.0, 6:426.0 (1: near R0 and 6 near R2)

Ring 0 L1 : Width Tray (6:290.6, 5&4:345.6, 3:350.6, 2:362.6, 1:298.6 lenght 1:351.2, 2:353.8, 3:359.2, 4:189.1 (4 is towards Ring1)

Ring 0 L0 : Width Tray 6:266.6, 5&4:325.6, 3:330.6, 2:341.6, 1:272.6 length 1:331.5, 2:334.0, 3:339.0, 4:248.8 (4 is towards Ring1)

Definition at line 154 of file AlCaHOCalibProducer.cc.

Member Typedef Documentation

typedef math::Error<5>::type AlCaHOCalibProducer::CovarianceMatrix

private

Definition at line 219 of file AlCaHOCalibProducer.cc.

typedef Basic3DVector<float> AlCaHOCalibProducer::DirectionType

Definition at line 160 of file AlCaHOCalibProducer.cc.

typedef Basic3DVector<float> AlCaHOCalibProducer::PositionType

Definition at line 159 of file AlCaHOCalibProducer.cc.

typedef Basic3DVector<float> AlCaHOCalibProducer::RotationType

Definition at line 161 of file AlCaHOCalibProducer.cc.

Constructor & Destructor Documentation

AlCaHOCalibProducer::AlCaHOCalibProducer ( const edm::ParameterSet & iConfig )

explicit

Definition at line 247 of file AlCaHOCalibProducer.cc.

References edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), ho_occupency, m_cosmic, m_hbinfo, m_occupancy, m_sigma, TFileService::make(), muonTags_, netamx, nphimx, fftjetcommon_cfi::title, tok_hbhe_, tok_ho_, tok_lumi_, tok_muons_, tok_muonsCosmic_, tok_tower_, and tok_vertex_.

                                                                        {
   //register your products
 
   m_hbinfo = iConfig.getUntrackedParameter<bool>("hbinfo", false);
   m_sigma = iConfig.getUntrackedParameter<double>("sigma", 0.05);
   m_occupancy = iConfig.getUntrackedParameter<bool>("plotOccupancy", false);
   m_cosmic    =  iConfig.getUntrackedParameter<bool>("CosmicData", false);
 
   // keep InputTag muonTags_ since it is used below. - cowden
   muonTags_ =   iConfig.getUntrackedParameter<edm::InputTag>("muons");
   tok_muonsCosmic_ = consumes<reco::TrackCollection>(muonTags_);
   tok_muons_  = consumes<edm::View<reco::Muon> >(muonTags_);
   tok_vertex_ = consumes<reco::VertexCollection >(iConfig.getParameter<edm::InputTag>("vertexTags"));
   //  tok_lumi_ = consumes<LumiDetails ,edm::InLumi>(iConfig.getParameter<edm::InputTag>("lumiTags"));
   tok_lumi_ = consumes<LumiScalersCollection>(iConfig.getParameter<edm::InputTag>("lumiTags"));
   tok_ho_ = consumes<HORecHitCollection>(iConfig.getParameter<edm::InputTag>("hoInput"));
   tok_hbhe_ = consumes<HBHERecHitCollection>(iConfig.getParameter<edm::InputTag>("hbheInput"));
   tok_tower_ = consumes<CaloTowerCollection>(iConfig.getParameter<edm::InputTag>("towerInput"));  
 
   produces<HOCalibVariableCollection>("HOCalibVariableCollection").setBranchAlias("HOCalibVariableCollection");
   
   if (m_occupancy) {
     edm::Service<TFileService> fs;
     
     char title[200];
 
     for (int ij=0; ij<5; ij++) {
       sprintf(title, "ho_occupency (>%i #sigma)", ij+2); 
       ho_occupency[ij] = fs->make<TH2F>(title, title, netamx+1, -netamx-0.5, netamx/2+0.5, nphimx, 0.5, nphimx+0.5); 
     }
   }  
 }

AlCaHOCalibProducer::~AlCaHOCalibProducer ( )

override

Definition at line 281 of file AlCaHOCalibProducer.cc.

 {
  
   // do anything here that needs to be done at desctruction time
   // (e.g. close files, deallocate resources etc.)
 }

Member Function Documentation

void AlCaHOCalibProducer::beginJob ( void )

overrideprivatevirtual

Reimplemented from edm::EDProducer.

Definition at line 372 of file AlCaHOCalibProducer.cc.

References Nevents, Noccu, and nRuns.

 {
   Nevents = 0;
   nRuns = 0;
   Noccu = 0;
 }

void AlCaHOCalibProducer::beginRun	(	edm::Run const &	,
		edm::EventSetup const &
	)

overrideprivatevirtual

Reimplemented from edm::EDProducer.

Definition at line 394 of file AlCaHOCalibProducer.cc.

References edm::EventSetup::get(), edm::ESHandle< T >::product(), and theHcalChStatus.

                                             {
   
   // HCAL channel status map ****************************************
   edm::ESHandle<HcalChannelQuality> hcalChStatus;    
   es.get<HcalChannelQualityRcd>().get("withTopo", hcalChStatus );
   theHcalChStatus = hcalChStatus.product();
 }

void AlCaHOCalibProducer::endJob ( void )

overrideprivatevirtual

Reimplemented from edm::EDProducer.

Definition at line 380 of file AlCaHOCalibProducer.cc.

References ho_occupency, m_occupancy, SiStripPI::max, Nevents, and Noccu.

Referenced by o2olib.O2ORunMgr::executeJob().

                                  {
   if (m_occupancy) { 
     for (int ij=0; ij<5; ij++) {
       ho_occupency[ij]->Scale(1./std::max(1,Noccu));
     }
   }
   edm::LogInfo("HOCalib") <<" AlCaHOCalibProducer processed event "<< Nevents;
 }

void AlCaHOCalibProducer::fillHOStore	(	const reco::TrackRef &	ncosm,
		HOCalibVariables &	tmpHOCalib,
		std::unique_ptr< HOCalibVariableCollection > &	hostore,
		int	Noccu_old,
		int	indx,
		edm::Handle< reco::TrackCollection >	cosmicmuon,
		edm::View< reco::Muon >::const_iterator	muon1,
		const edm::Event &	iEvent,
		const edm::EventSetup &	iSetup
	)

private

Definition at line 404 of file AlCaHOCalibProducer.cc.

Referenced by produce().

                                                    {
 
   edm::ESHandle<CaloGeometry> pG;
   iSetup.get<CaloGeometryRecord>().get(pG);
   const CaloGeometry* geo = pG.product();
   const CaloSubdetectorGeometry* gHO = 
     geo->getSubdetectorGeometry(DetId::Hcal,HcalOuter);
  
   // Get Hcal Severity Level Computer, so that the severity of each rechit flag/status may be determined
   //  edm::ESHandle<HcalSeverityLevelComputer> hcalSevLvlComputerHndl;
   iSetup.get<HcalSeverityLevelComputerRcd>().get(hcalSevLvlComputerHndl);
   const HcalSeverityLevelComputer* hcalSevLvlComputer = hcalSevLvlComputerHndl.product();
 
   int charge = ncosm->charge();  
       
   double innerr = (*ncosm).innerPosition().Perp2();
   double outerr = (*ncosm).outerPosition().Perp2();
   int iiner = (innerr <outerr) ? 1 : 0;
       
   //---------------------------------------------------
   //             in_to_out  Dir         in_to_out  Dir
   //   StandAlone ^         ^     Cosmic    ^    |
   //              |         |               |    v
   //---------------------------------------------------Y=0
   //   StandAlone |         |     Cosmic    ^    |
   //              v         v               |    v
   //----------------------------------------------------
       
   double posx, posy, posz;
   double momx, momy, momz;
       
   if (iiner==1) {
     posx = (*ncosm).innerPosition().X();
     posy = (*ncosm).innerPosition().Y();
     posz = (*ncosm).innerPosition().Z();
     
     momx = (*ncosm).innerMomentum().X();
     momy = (*ncosm).innerMomentum().Y();
     momz = (*ncosm).innerMomentum().Z();
     
   } else {
     posx = (*ncosm).outerPosition().X();
     posy = (*ncosm).outerPosition().Y();
     posz = (*ncosm).outerPosition().Z();
     
     momx = (*ncosm).outerMomentum().X();
     momy = (*ncosm).outerMomentum().Y();
     momz = (*ncosm).outerMomentum().Z();
   }
       
       
   PositionType trkpos(posx, posy, posz);
       
   CLHEP::Hep3Vector tmpmuon3v(posx, posy, posz);
   CLHEP::Hep3Vector tmpmuondir(momx, momy, momz);
       
   bool samedir = (tmpmuon3v.dot(tmpmuondir) >0) ? true : false;
   for (int ij=0; ij<3; ij++) {tmpHOCalib.caloen[ij] = 0.0;}
   int inearbymuon = 0;
   localxhor0 = localyhor0 = 20000;  //GM for 22OCT07 data
 
   if (m_cosmic) {
     int ind(0);
     for(reco::TrackCollection::const_iterator ncosmcor=cosmicmuon->begin();
     ncosmcor != cosmicmuon->end();  ++ncosmcor,++ind) {
       if (indx==ind) continue;
       CLHEP::Hep3Vector tmpmuon3vcor;
       CLHEP::Hep3Vector tmpmom3v;
       if (iiner==1) {
     tmpmuon3vcor = CLHEP::Hep3Vector((*ncosmcor).innerPosition().X(),(*ncosmcor).innerPosition().Y(),(*ncosmcor).innerPosition().Z());
     tmpmom3v = CLHEP::Hep3Vector((*ncosmcor).innerMomentum().X(),(*ncosmcor).innerMomentum().Y(),(*ncosmcor).innerMomentum().Z());
       } else {
     tmpmuon3vcor = CLHEP::Hep3Vector((*ncosmcor).outerPosition().X(),(*ncosmcor).outerPosition().Y(),(*ncosmcor).outerPosition().Z());
     tmpmom3v = CLHEP::Hep3Vector((*ncosmcor).outerMomentum().X(),(*ncosmcor).outerMomentum().Y(),(*ncosmcor).outerMomentum().Z());  
         
       }
 
       if (tmpmom3v.mag()<0.2 || (*ncosmcor).ndof()<5) continue;
       
       double angle = tmpmuon3v.angle(tmpmuon3vcor);
       if (angle < 7.5*CLHEP::deg) {inearbymuon=1;} //  break;}
     
       //    if (muonTagsi_.label() =="cosmicMuons") {
       if (angle <7.5*CLHEP::deg) { tmpHOCalib.caloen[0] +=1.;}
       if (angle <15.0*CLHEP::deg) { tmpHOCalib.caloen[1] +=1.;}
       if (angle <35.0*CLHEP::deg) { tmpHOCalib.caloen[2] +=1.;}
     }
   } else {
     //            if (muonTags_.label() =="muons") {
     edm::Handle<CaloTowerCollection> calotower;
     iEvent.getByToken(tok_tower_, calotower);
     
     for (CaloTowerCollection::const_iterator calt = calotower->begin();
      calt !=calotower->end(); calt++) {
       //CMSSW_2_1_x const math::XYZVector towermom = (*calt).momentum();
       double ith = (*calt).momentum().theta();
       double iph = (*calt).momentum().phi();
       
       CLHEP::Hep3Vector calo3v(sin(ith)*cos(iph), sin(ith)*sin(iph), cos(ith));
     
       double angle = tmpmuon3v.angle(calo3v);
     
       if (angle < 7.5*CLHEP::deg) {tmpHOCalib.caloen[0] += calt->emEnergy()+calt->hadEnergy();}
       if (angle < 15*CLHEP::deg) {tmpHOCalib.caloen[1] += calt->emEnergy()+calt->hadEnergy();}
       if (angle < 35*CLHEP::deg) {tmpHOCalib.caloen[2] += calt->emEnergy()+calt->hadEnergy();}
     }
   }
   if ((m_cosmic) || (tmpHOCalib.caloen[0] <=10.0)) {
 
     GlobalPoint glbpt(posx, posy, posz);
       
     double mom = sqrt(momx*momx + momy*momy +momz*momz);
       
     momx /= mom;
     momy /= mom;
     momz /= mom;
       
     DirectionType trkdir(momx, momy, momz);
       
     tmpHOCalib.trkdr = (*ncosm).d0();
     tmpHOCalib.trkdz = (*ncosm).dz();
     tmpHOCalib.nmuon = (m_cosmic) ? cosmicmuon->size() : 1;
     tmpHOCalib.trkvx = glbpt.x();
     tmpHOCalib.trkvy = glbpt.y();
     tmpHOCalib.trkvz = glbpt.z();
     tmpHOCalib.trkmm = mom*charge;
     tmpHOCalib.trkth = trkdir.theta();
     tmpHOCalib.trkph = trkdir.phi();
     tmpHOCalib.isect2 = -2;
     tmpHOCalib.isect = -2;
     tmpHOCalib.hodx = -100;
     tmpHOCalib.hody = -100;
     tmpHOCalib.hoang = -2.0;
     tmpHOCalib.momatho = -2;
     tmpHOCalib.ndof  = (inearbymuon ==0) ? (int)(*ncosm).ndof() : -(int)(*ncosm).ndof();
     tmpHOCalib.chisq = (*ncosm).normalizedChi2(); // max(1.,tmpHOCalib.ndof);
     if (!m_cosmic) {      
       reco::MuonEnergy muonenr = muon1->calEnergy();
       reco::MuonIsolation iso03 = muon1->isolationR03();    
       reco::MuonIsolation iso05 = muon1->isolationR05(); 
 
       tmpHOCalib.tkpt03 = iso03.sumPt;
       tmpHOCalib.ecal03 = iso05.sumPt; // iso03.emEt+muonenr.em;
       tmpHOCalib.hcal03 = iso03.hadEt+muonenr.had;
     }
     tmpHOCalib.therr = 0.;
     tmpHOCalib.pherr = 0.;
     if (iiner==1) {
       reco::TrackBase::CovarianceMatrix innercov = (*ncosm).innerStateCovariance();
       tmpHOCalib.therr = innercov(1,1); //thetaError();
       tmpHOCalib.pherr = innercov(2,2); //phi0Error();
     } else {
       reco::TrackBase::CovarianceMatrix outercov = (*ncosm).outerStateCovariance();
       tmpHOCalib.therr = outercov(1,1); //thetaError();
       tmpHOCalib.pherr = outercov(2,2); //phi0Error();
     }
     edm::ESHandle<MagneticField> theMagField;
     iSetup.get<IdealMagneticFieldRecord>().get(theMagField );     
 
     SteppingHelixPropagator myHelix(&*theMagField,anyDirection);
     myHelix.setMaterialMode(false);
     myHelix.applyRadX0Correction(true);
     double phiho = trkpos.phi();
     if (phiho<0) phiho +=CLHEP::twopi;
       
     int iphisect_dt=int(6*(phiho+10.0*CLHEP::deg)/CLHEP::pi); //for u 18/12/06
     if (iphisect_dt>=12) iphisect_dt=0;
 
     int iphisect = -1;
     bool ipath = false;
     for (int kl = 0; kl<=2; kl++) {
 
       int iphisecttmp = (kl<2) ? iphisect_dt + kl : iphisect_dt - 1;
       if (iphisecttmp <0) iphisecttmp = 11;
       if (iphisecttmp >=12) iphisecttmp = 0;
     
       double phipos = iphisecttmp*CLHEP::pi/6.;
       double phirot = phipos;
     
       GlobalVector xLocal(-sin(phirot), cos(phirot), 0.);
       GlobalVector yLocal(0., 0., 1.);
       GlobalVector zLocal = xLocal.cross(yLocal).unit();
       //    GlobalVector zLocal(cos(phirot), sin(phirot), 0.0); 
     
 
       FreeTrajectoryState freetrajectorystate_ = getFreeTrajectoryState(*ncosm,&(*theMagField), iiner, samedir);
     
       Surface::RotationType rot(xLocal, yLocal, zLocal);
     
       for (int ik=1; ik>=0; ik--) { //propagate track in two HO layers
 
     double     radial = rHOL1;
     if (ik==0) radial = rHOL0;
 
     Surface::PositionType pos(radial*cos(phipos), radial*sin(phipos), 0.);
     PlaneBuilder::ReturnType aPlane = PlaneBuilder().plane(pos,rot);
 
     auto aPlane2 = new Plane(pos,rot);
 
     SteppingHelixStateInfo steppingHelixstateinfo_;
     myHelix.propagate(SteppingHelixStateInfo(freetrajectorystate_), (*aPlane2), steppingHelixstateinfo_);
 
     if (steppingHelixstateinfo_.isValid()) {
         
       GlobalPoint hotrkpos2xx(steppingHelixstateinfo_.position().x(), steppingHelixstateinfo_.position().y(), steppingHelixstateinfo_.position().z());
         
       if (ik==1) {
         HcalDetId ClosestCell = (HcalDetId) gHO->getClosestCell(hotrkpos2xx);
         int ixeta = ClosestCell.ieta();
         int ixphi = ClosestCell.iphi();
         tmpHOCalib.isect2 = 100*std::abs(ixeta+50)+std::abs(ixphi);
       }
         
 
       GlobalVector hotrkpos2(steppingHelixstateinfo_.position().x(), steppingHelixstateinfo_.position().y(), steppingHelixstateinfo_.position().z());
       CLHEP::Hep3Vector hotrkdir2(steppingHelixstateinfo_.momentum().x(), steppingHelixstateinfo_.momentum().y(),steppingHelixstateinfo_.momentum().z());
 
       LocalVector lclvt0 = (*aPlane).toLocal(hotrkpos2);
         
       double xx = lclvt0.x();
       double yy = lclvt0.y();
         
       if (ik ==1) {
         if ((std::abs(yy) < 130 && xx >-64.7 && xx <138.2) //Ring-0
         ||(std::abs(yy) > 130 && std::abs(yy) <700 && xx >-76.3 && xx <140.5)) { //Ring +-1,2
           ipath = true;  //Only look for tracks which as hits in layer 1
           iphisect = iphisecttmp;
         }
       }
         
       if (iphisect != iphisecttmp) continue; //Look for ring-0 only when ring1 is accepted for that sector
         
       switch (ik) 
         {
         case 0 : 
           xhor0 = xx; //lclvt0.x();
           yhor0 = yy; //lclvt0.y();
           break;
         case 1 :
           xhor1 = xx; //lclvt0.x();
           yhor1 = yy; //lclvt0.y();
           tmpHOCalib.momatho = hotrkdir2.mag();
           tmpHOCalib.hoang = CLHEP::Hep3Vector(zLocal.x(),zLocal.y(),zLocal.z()).dot(hotrkdir2.unit());
           break;
         default : break;
         }
     } else {
       break;
     }
       }
       if (ipath) break;
     }
     if (ipath) { //If muon crossed HO laeyrs
     
       int ietaho = 50;
       int iphiho = -1;
     
       for (int ij=0; ij<9; ij++) {tmpHOCalib.hosig[ij]=-100.0;}
       for (int ij=0; ij<18; ij++) {tmpHOCalib.hocorsig[ij]=-100.0;}
       for (int ij=0; ij<9; ij++) {tmpHOCalib.hbhesig[ij]=-100.0;}
       tmpHOCalib.hocro = -100;
       tmpHOCalib.htime = -1000;
     
       int isect = 0;
 
       findHOEtaPhi(iphisect, ietaho, iphiho);
     
       if (ietaho !=0 && iphiho !=0 && std::abs(iring)<=2) { //Muon passed through a tower
     isect = 100*std::abs(ietaho+50)+std::abs(iphiho);
     if (std::abs(ietaho) >=netabin || iphiho<0) isect *=-1; //Not extrapolated to any tower
     if (std::abs(ietaho) >=netabin) isect -=1000000;  //not matched with eta
     if (iphiho<0)        isect -=2000000; //not matched with phi
     tmpHOCalib.isect = isect;
       
     tmpHOCalib.hodx = localxhor1;
     tmpHOCalib.hody = localyhor1;      
       
     if (iring==0) {
       tmpHOCalib.hocorsig[8] = localxhor0;
       tmpHOCalib.hocorsig[9] = localyhor0;
     }
       
     int etamn=-4;
     int etamx=4;
     if (iring==1) {etamn=5; etamx = 10;}
     if (iring==2) {etamn=11; etamx = 16;}
     if (iring==-1){etamn=-10; etamx = -5;}
     if (iring==-2){etamn=-16; etamx = -11;}
       
     int phimn = 1;
     int phimx = 2;
     if (iring ==0) {
       phimx =2*int((iphiho+1)/2.);
       phimn = phimx - 1;
     } else {
       phimn = 3*int((iphiho+1)/3.) - 1; 
       phimx = phimn + 2;
     }
       
     if (phimn <1) phimn += nphimx;
     if (phimx >72) phimx -= nphimx;
       
     if (m_hbinfo) {
       for (int ij=0; ij<9; ij++) {tmpHOCalib.hbhesig[ij]=-100.0;}
         
       edm::Handle<HBHERecHitCollection> hbheht;// iEvent.getByType(hbheht);
       iEvent.getByToken(tok_hbhe_,hbheht);
         
       if (!(*hbheht).empty()) {
         if((*hbheht).empty()) throw (int)(*hbheht).size();
           
         for (HBHERecHitCollection::const_iterator jk=(*hbheht).begin(); jk!=(*hbheht).end(); jk++){
           HcalDetId id =(*jk).id();
           int tmpeta= id.ieta();
           int tmpphi= id.iphi();
         
           int deta = tmpeta-ietaho;
           if (tmpeta<0 && ietaho>0) deta += 1;
           if (tmpeta>0 && ietaho<0) deta -= 1;
 
           //        if (tmpeta==-1 && ietaho== 1) deta = -1;
           //        if (tmpeta== 1 && ietaho==-1) deta =  1;
 
           int dphi = tmpphi-iphiho;
           if (dphi>nphimx/2) { dphi -=nphimx;}
           if (dphi<-nphimx/2) { dphi +=nphimx;}
 
           //        if (phimn >phimx) {
           //          if (dphi==71) dphi=-1;
           //          if (dphi==-71) dphi=1;
           //        }
 
           if (m_occupancy) {
         float signal = (*jk).energy();
         //      int tmpeta1 = (tmpeta>0) ? tmpeta -1 : -tmpeta +14; 
         if (signal >-100 && Noccu == Noccu_old) {
           for (int ij=0; ij<5; ij++) {
             if (signal >(ij+2)*m_sigma) {
               ho_occupency[ij]->Fill(tmpeta, tmpphi);
             }
           }
         }
           }
         
           int ipass2 = (std::abs(deta) <=1 && std::abs(dphi)<=1) ? 1 : 0; //NEED correction in full CMS detector
           if ( ipass2 ==0 ) continue;
         
           float signal = (*jk).energy();
           
           if (3*(deta+1)+dphi+1<9)  tmpHOCalib.hbhesig[3*(deta+1)+dphi+1] = signal;
         }
       }
     } //m_hbinfo #endif
       
     edm::Handle<HORecHitCollection> hoht;
     iEvent.getByToken(tok_ho_,hoht);
       
     if (!(*hoht).empty()) {
       for (HORecHitCollection::const_iterator jk=(*hoht).begin(); jk!=(*hoht).end(); jk++){
         HcalDetId id =(*jk).id();
         int tmpeta= id.ieta();
         int tmpphi= id.iphi();
 
         int ipass1 =0;
         if (tmpeta >=etamn && tmpeta <=etamx) {
           if (phimn < phimx) {
         ipass1 = (tmpphi >=phimn && tmpphi <=phimx ) ? 1 : 0;
           } else {
         ipass1 = (tmpphi==71 || tmpphi ==72 || tmpphi==1) ? 1 : 0;
           }
         }
           
         int deta = tmpeta-ietaho;
         int dphi = tmpphi -iphiho;
 
         if (tmpeta<0 && ietaho>0) deta += 1;
         if (tmpeta>0 && ietaho<0) deta -= 1;
         //        if (tmpeta==-1 && ietaho== 1) deta = -1;
         //        if (tmpeta== 1 && ietaho==-1) deta =  1;
           
         if (dphi>nphimx/2) { dphi -=nphimx;}
         if (dphi<-nphimx/2) { dphi +=nphimx;}
         //        if (phimn>phimx) {
         //      if (dphi==71) dphi=-1;
         //      if (dphi==-71) dphi=1;
         //        }
 
         float signal = (*jk).energy();
           
         int ipass2 = (std::abs(deta) <=1 && std::abs(dphi)<=1) ? 1 : 0;
           
         if (ipass1 ==0 && ipass2 ==0 ) continue;
 
         if (ipass1 ==1) {
           int tmpdph = tmpphi-phimn;
           if (tmpdph<0) tmpdph = 2;  //only case of iphi==1, where phimn=71
           
           int ilog = 2*(tmpeta-etamn)+tmpdph;
           if (iring !=0) { 
         if (iring >0) {
           ilog = 3*(tmpeta-etamn)+tmpdph; //Again CMS correction
         } else {
           ilog = 3*(etamx-tmpeta)+tmpdph; //Again CMS correction
         }
           }
           if (ilog>-1 && ilog<18) {
         tmpHOCalib.hocorsig[ilog] = signal;
           }
         }         
           
         if (ipass2 ==1) {
         
           if (3*(deta+1)+dphi+1<9) {
         tmpHOCalib.hosig[3*(deta+1)+dphi+1] = signal; //Again CMS azimuthal near phi 1&72
           }
         }
           
         if (deta==0 && dphi ==0) {
           tmpHOCalib.htime = (*jk).time();
           tmpHOCalib.hoflag = (*jk).flags();
 
           // Get Channel Quality information for the given detID
           unsigned theStatusValue = theHcalChStatus->getValues(id)->getValue();
           // Now get severity of problems for the given detID, based on the rechit flag word and the channel quality status value
           int hitSeverity=hcalSevLvlComputer->getSeverityLevel(id, (*jk).flags(),theStatusValue);
           tmpHOCalib.hoflag = hitSeverity;
           int crphi = tmpphi + 6;
           if (crphi >72) crphi -=72;
         
           for (HORecHitCollection::const_iterator jcr=(*hoht).begin(); jcr!=(*hoht).end(); jcr++){
         const HORecHit reccr = (const HORecHit)(*jcr);
         HcalDetId idcr =reccr.id();
         int etacr= idcr.ieta();
         int phicr= idcr.iphi();
         if (tmpeta==etacr && crphi ==phicr) {
             
           tmpHOCalib.hocro = reccr.energy();
             
         }
           }
         }
       }
     } 
       }
     
       //GMA   Npass++;
       if (Noccu == Noccu_old) Noccu++;
       hostore->push_back(tmpHOCalib);   
     } // if (ipath)
   } // Cut on calo energy
 }

void AlCaHOCalibProducer::findHOEtaPhi	(	int	iphsect,
		int &	ietaho,
		int &	iphiho
	)

private

Definition at line 863 of file AlCaHOCalibProducer.cc.

References funct::abs(), iring, localxhor0, localxhor1, localyhor0, localyhor1, netabin, nphimx, xhor0, xhor1, yhor0, and yhor1.

Referenced by fillHOStore().

                                                                              {
   
   //18/12/06 : use only position, not angle phi
 
  const double etalow[16]={   0.025,  35.195,  70.625, 106.595, 141.565, 180.765, 220.235, 261.385, 304.525, 349.975, 410.025, 452.085, 506.645, 565.025, 627.725, 660.25};
  const double etahgh[16]={  35.145,  70.575, 106.545, 125.505, 180.715, 220.185, 261.335, 304.475, 349.925, 392.575, 452.035, 506.595, 564.975, 627.675, 661.075, 700.25};
 
   const double philow[6]={-76.27, -35.11, 0.35, 35.81, 71.77, 108.93};  //Ring+/-1 & 2
   const double phihgh[6]={-35.81, -0.35, 35.11, 71.07, 108.23, 140.49};
 
   const double philow00[6]={-60.27, -32.91, 0.35, 33.61, 67.37, 102.23}; //Ring0 L0
   const double phihgh00[6]={-33.61, -0.35, 32.91, 66.67, 101.53, 129.49};
 
   const double philow01[6]={-64.67, -34.91, 0.35, 35.61, 71.37, 108.33}; //Ring0 L1
   const double phihgh01[6]={-35.61, -0.35, 34.91, 70.67, 107.63, 138.19};
 
   iring = -10;
 
   double tmpdy =  std::abs(yhor1);
   for (int ij=0; ij<netabin; ij++) {
     if (tmpdy >etalow[ij] && tmpdy <etahgh[ij]) {
       ietaho = ij+1; 
       float tmp1 = fabs(tmpdy-etalow[ij]);
       float tmp2 = fabs(tmpdy-etahgh[ij]);
  
       localyhor1 = (tmp1 < tmp2) ? -tmp1 : tmp2;
       if (yhor1 <0) localyhor1 *=-1.;
 
       if (ij<4) iring =0;
       if (ij>=4 && ij<10) iring=1;
       if (ij>=10 && ij<netabin) iring=2;
       break;
     }
   }
 
   int tmpphi = 0;
   int tmpphi0 = 0;
 
   if (ietaho >4) { //Ring 1 and 2
     for (int ij=0; ij<6; ij++) {
       if (xhor1 >philow[ij] && xhor1 <phihgh[ij]) { 
     tmpphi=ij+1; 
     float tmp1 = fabs(xhor1-philow[ij]);
     float tmp2 = fabs(xhor1-phihgh[ij]);
     localxhor1 = (tmp1 < tmp2) ? -tmp1 : tmp2;
     break;
       }
     }
   } else {  //Ring 0
     for (int ij=0; ij<6; ij++) {
       if (xhor1 >philow01[ij] && xhor1 <phihgh01[ij]) { 
     tmpphi=ij+1; 
     float tmp1 = fabs(xhor1-philow01[ij]);
     float tmp2 = fabs(xhor1-phihgh01[ij]);
     localxhor1 = (tmp1 < tmp2) ? -tmp1 : tmp2;
     break;
       }
     }
 
     for (int ij=0; ij<6; ij++) {
       if (xhor0 >philow00[ij] && xhor0 <phihgh00[ij]) { 
     tmpphi0=ij+1; 
     float tmp1 = fabs(xhor0-philow00[ij]);
     float tmp2 = fabs(xhor0-phihgh00[ij]);
     localxhor0 = (tmp1 < tmp2) ? -tmp1 : tmp2;
     if (tmpphi !=tmpphi0) localxhor0 +=10000.;
     break;
       }
     }
 
     double tmpdy =  std::abs(yhor0);
     for (int ij=0; ij<4; ij++) {
       if (tmpdy >etalow[ij] && tmpdy <etahgh[ij]) {
     float tmp1 = fabs(tmpdy-etalow[ij]);
     float tmp2 = fabs(tmpdy-etahgh[ij]);
     localyhor0 = (tmp1 < tmp2) ? -tmp1 : tmp2;
     if (yhor0 <0) localyhor0 *=-1.;
     if (ij+1 != ietaho)  localyhor0 +=10000.;
     break;
       }
     }
   }
 
   if (tmpphi!=0) { 
     iphiho = 6*iphisect -2 + tmpphi;
     if (iphiho <=0) iphiho +=nphimx;
     if (iphiho >nphimx) iphiho -=nphimx;
   }
 
   //  isect2 = 15*iring+iphisect+1;
 
   if (yhor1 <0) { 
     if (std::abs(ietaho) >netabin) { //Initialised with 50
       ietaho +=1; 
     } else {
       ietaho *=-1; 
     }
     //    isect2 *=-1; 
     iring *=-1;
   } 
 }

FreeTrajectoryState AlCaHOCalibProducer::getFreeTrajectoryState	(	const reco::Track &	tk,
		const MagneticField *	field,
		int	itag,
		bool	dir
	)

private

Definition at line 965 of file AlCaHOCalibProducer.cc.

References reco::TrackBase::charge(), DEFINE_FWK_MODULE, reco::Track::extra(), reco::Track::innerMomentum(), reco::Track::innerPosition(), reco::Track::outerPx(), reco::Track::outerPy(), reco::Track::outerPz(), reco::Track::outerX(), reco::Track::outerY(), and reco::Track::outerZ().

Referenced by fillHOStore().

 {
 
   if (iiner ==0) {
     GlobalPoint gpos( tk.outerX(), tk.outerY(), tk.outerZ());
     GlobalVector gmom( tk.outerPx(), tk.outerPy(), tk.outerPz());
     if (dir) gmom *=-1.;
     GlobalTrajectoryParameters par( gpos, gmom, tk.charge(), field);
     CurvilinearTrajectoryError err( tk.extra()->outerStateCovariance());
     return FreeTrajectoryState( par, err);
   } else {
     GlobalPoint gpos( tk.innerPosition().X(), tk.innerPosition().Y(), tk.innerPosition().Z());
     GlobalVector gmom( tk.innerMomentum().X(), tk.innerMomentum().Y(), tk.innerMomentum().Z());
     if (dir) gmom *=-1.;
     GlobalTrajectoryParameters par( gpos, -gmom, tk.charge(), field);
     CurvilinearTrajectoryError err( tk.extra()->innerStateCovariance());
     return FreeTrajectoryState( par, err);
   }
 
 }

void AlCaHOCalibProducer::produce	(	edm::Event &	iEvent,
		const edm::EventSetup &	iSetup
	)

overrideprivate

Definition at line 295 of file AlCaHOCalibProducer.cc.

References edm::EventID::event(), fillHOStore(), edm::Event::getByToken(), edm::EventBase::id(), HOCalibVariables::inslumi, edm::EventBase::isRealData(), edm::HandleBase::isValid(), m_cosmic, eostools::move(), Nevents, Noccu, HOCalibVariables::nprim, jets_cff::primaryVertices, edm::Event::put(), edm::EventID::run(), tok_lumi_, tok_muons_, tok_muonsCosmic_, and tok_vertex_.

Referenced by JSONExport.JsonExport::export(), HTMLExport.HTMLExport::export(), and HTMLExport.HTMLExportStatic::export().

 {
 
   int irun = iEvent.id().run();
   //  int ilumi = iEvent.luminosityBlock();
 
   Nevents++;
 
   if (Nevents%5000==1)  edm::LogInfo("HOCalib") <<"AlCaHOCalibProducer Processing event # "<<Nevents<<" "<<Noccu<<" "<<irun<<" "<<iEvent.id().event();
 
   auto hostore = std::make_unique<HOCalibVariableCollection>();
 
   edm::Handle<reco::TrackCollection> cosmicmuon;
   edm::Handle<edm::View<reco::Muon> > collisionmuon;
 
   bool muonOK(true);
   HOCalibVariables tmpHOCalib;
   tmpHOCalib.nprim = -1;
   tmpHOCalib.inslumi=-1.;
 
   if (m_cosmic) {
     iEvent.getByToken(tok_muonsCosmic_, cosmicmuon);
     muonOK = (cosmicmuon.isValid() && !cosmicmuon->empty());
   } else {
     iEvent.getByToken(tok_muons_,collisionmuon);
     muonOK = (collisionmuon.isValid() && !collisionmuon->empty());
 
     if (iEvent.isRealData()) {
       edm::Handle<reco::VertexCollection> primaryVertices;
       iEvent.getByToken(tok_vertex_, primaryVertices);
       if (primaryVertices.isValid()) { tmpHOCalib.nprim = primaryVertices->size();}
 
       tmpHOCalib.inslumi=0.;
     
       edm::Handle<LumiScalersCollection> lumiScale;
       iEvent.getByToken(tok_lumi_, lumiScale);
 
       if (lumiScale.isValid()) {
         if ( lumiScale->empty() ) {
           edm::LogError("HOCalib") << "lumiScale collection is empty";
         } else {
           tmpHOCalib.inslumi=lumiScale->begin()->pileup();
         }
       }
     }
   }
 
   if (muonOK) { 
     
     int Noccu_old = Noccu;
     edm::View<reco::Muon>::const_iterator muon1;
     if (m_cosmic) {
       int indx(0);
       for(reco::TrackCollection::const_iterator ncosm = cosmicmuon->begin();
       ncosm != cosmicmuon->end();  ++ncosm,++indx) {
     if ((*ncosm).ndof() < 15) continue;
     if ((*ncosm).normalizedChi2() >30.0) continue;
     reco::TrackRef tRef = reco::TrackRef(cosmicmuon,indx);
     fillHOStore(tRef,tmpHOCalib,hostore,Noccu_old,indx,cosmicmuon,muon1,
             iEvent, iSetup);
       }
     } else {
       for( muon1 = collisionmuon->begin(); muon1 < collisionmuon->end(); muon1++ ) {
     if ((!muon1->isGlobalMuon()) || (!muon1->isTrackerMuon())) continue;
     reco::TrackRef ncosm =  muon1->innerTrack();
     fillHOStore(ncosm,tmpHOCalib,hostore,Noccu_old,0,cosmicmuon,muon1,
             iEvent, iSetup);
       }
     }
   }
 
   iEvent.put(std::move(hostore), "HOCalibVariableCollection");
   
 }