#include <CaloTowersCreationAlgo.h>

Classes
struct	MetaTower

Public Member Functions
void	begin ()

	CaloTowersCreationAlgo ()

	CaloTowersCreationAlgo (double EBthreshold, double EEthreshold, bool useEtEBTreshold, bool useEtEETreshold, bool useSymEBTreshold, bool useSymEETreshold, double HcalThreshold, double HBthreshold, double HESthreshold, double HEDthreshold, double HOthreshold0, double HOthresholdPlus1, double HOthresholdMinus1, double HOthresholdPlus2, double HOthresholdMinus2, double HF1threshold, double HF2threshold, double EBweight, double EEweight, double HBweight, double HESweight, double HEDweight, double HOweight, double HF1weight, double HF2weight, double EcutTower, double EBSumThreshold, double EESumThreshold, bool useHO, int momConstrMethod, double momHBDepth, double momHEDepth, double momEBDepth, double momEEDepth, int hcalPhase=0)

	CaloTowersCreationAlgo (double EBthreshold, double EEthreshold, bool useEtEBTreshold, bool useEtEETreshold, bool useSymEBTreshold, bool useSymEETreshold, double HcalThreshold, double HBthreshold, double HESthreshold, double HEDthreshold, double HOthreshold0, double HOthresholdPlus1, double HOthresholdMinus1, double HOthresholdPlus2, double HOthresholdMinus2, double HF1threshold, double HF2threshold, const std::vector< double > &EBGrid, const std::vector< double > &EBWeights, const std::vector< double > &EEGrid, const std::vector< double > &EEWeights, const std::vector< double > &HBGrid, const std::vector< double > &HBWeights, const std::vector< double > &HESGrid, const std::vector< double > &HESWeights, const std::vector< double > &HEDGrid, const std::vector< double > &HEDWeights, const std::vector< double > &HOGrid, const std::vector< double > &HOWeights, const std::vector< double > &HF1Grid, const std::vector< double > &HF1Weights, const std::vector< double > &HF2Grid, const std::vector< double > &HF2Weights, double EBweight, double EEweight, double HBweight, double HESweight, double HEDweight, double HOweight, double HF1weight, double HF2weight, double EcutTower, double EBSumThreshold, double EESumThreshold, bool useHO, int momConstrMethod, double momHBDepth, double momHEDepth, double momEBDepth, double momEEDepth, int hcalPhase=0)

std::tuple< unsigned int, bool >	ecalChanStatusForCaloTower (const EcalRecHit *hit)

GlobalPoint	emCrystalShwrPos (DetId detId, float fracDepth)

GlobalPoint	emShwrLogWeightPos (const std::vector< std::pair< DetId, float > > &metaContains, float fracDepth, double totEmE)

GlobalPoint	emShwrPos (const std::vector< std::pair< DetId, float > > &metaContains, float fracDepth, double totEmE)

void	finish (CaloTowerCollection &destCollection)

GlobalPoint	hadSegmentShwrPos (DetId detId, float fracDepth)

GlobalPoint	hadShwPosFromCells (DetId frontCell, DetId backCell, float fracDepth)

GlobalPoint	hadShwrPos (const std::vector< std::pair< DetId, float > > &metaContains, float fracDepth, double hadE)

GlobalPoint	hadShwrPos (CaloTowerDetId id, float fracDepth)

unsigned int	hcalChanStatusForCaloTower (const CaloRecHit *hit)

void	makeEcalBadChs ()

void	makeHcalDropChMap ()

void	process (const HBHERecHitCollection &hbhe)

void	process (const HORecHitCollection &ho)

void	process (const HFRecHitCollection &hf)

void	process (const EcalRecHitCollection &ecal)

void	process (const CaloTowerCollection &ctc)

void	rescaleTowers (const CaloTowerCollection &ctInput, CaloTowerCollection &ctResult)

void	setEBEScale (double scale)

void	setEbHandle (const edm::Handle< EcalRecHitCollection > eb)

void	setEcalChStatusFromDB (const EcalChannelStatus *s)

void	setEcalSeveritiesToBeExcluded (const std::vector< int > &ecalSev)

void	SetEcalSeveritiesToBeUsedInBadTowers (const std::vector< int > &ecalSev)

void	setEcalSevLvlAlgo (const EcalSeverityLevelAlgo *a)

void	setEEEScale (double scale)

void	setEeHandle (const edm::Handle< EcalRecHitCollection > ee)

void	setGeometry (const CaloTowerTopology cttopo, const CaloTowerConstituentsMap ctmap, const HcalTopology htopo, const CaloGeometry geo)

void	setHBEScale (double scale)

void	setHcalAcceptSeverityLevel (unsigned int level)

void	setHcalAcceptSeverityLevelForRejectedHit (unsigned int level)

void	setHcalChStatusFromDB (const HcalChannelQuality *s)

void	setHcalSevLvlComputer (const HcalSeverityLevelComputer *c)

void	setHEDEScale (double scale)

void	setHESEScale (double scale)

void	setHF1EScale (double scale)

void	setHF2EScale (double scale)

void	setHOEScale (double scale)

void	setRecoveredEcalHitsAreUsed (bool flag)

void	setRecoveredHcalHitsAreUsed (bool flag)

void	setUseRejectedHitsOnly (bool flag)

void	setUseRejectedRecoveredEcalHits (bool flag)

void	setUseRejectedRecoveredHcalHits (bool flag)

Public Attributes
int	nalgo =-1

Private Types
enum	ctHitCategory { GoodChan = 0, BadChan = 1, RecoveredChan = 2, ProblematicChan = 3, IgnoredChan = 99 }

typedef std::map < CaloTowerDetId, int >	HcalDropChMap

typedef std::vector< MetaTower >	MetaTowerMap

Private Member Functions
void	assignHitEcal (const EcalRecHit *recHit)
	adds a single hit to the tower More...

void	assignHitHcal (const CaloRecHit *recHit)

int	compactTime (float time)

void	convert (const CaloTowerDetId &id, const MetaTower &mt, CaloTowerCollection &collection)

MetaTower &	find (const CaloTowerDetId &id)
	looks for a given tower in the internal cache. If it can't find it, it makes it. More...

void	getThresholdAndWeight (const DetId &detId, double &threshold, double &weight) const
	helper method to look up the appropriate threshold & weight More...

void	rescale (const CaloTower *ct)

Private Attributes
std::vector< unsigned short >	ecalBadChs

HcalDropChMap	hcalDropChMap

std::vector< int >	mergedDepths

double	theEBEScale

std::vector< double >	theEBGrid

edm::Handle< EcalRecHitCollection >	theEbHandle

double	theEBSumThreshold

double	theEBthreshold

double	theEBweight

std::vector< double >	theEBWeights

const EcalChannelStatus *	theEcalChStatus

std::vector< int >	theEcalSeveritiesToBeExcluded

std::vector< int >	theEcalSeveritiesToBeUsedInBadTowers

const EcalSeverityLevelAlgo *	theEcalSevLvlAlgo

double	theEcutTower

double	theEEEScale

std::vector< double >	theEEGrid

edm::Handle< EcalRecHitCollection >	theEeHandle

double	theEESumThreshold

double	theEEthreshold

double	theEEweight

std::vector< double >	theEEWeights

const CaloGeometry *	theGeometry

double	theHBEScale

std::vector< double >	theHBGrid

double	theHBthreshold

double	theHBweight

std::vector< double >	theHBWeights

unsigned int	theHcalAcceptSeverityLevel

unsigned int	theHcalAcceptSeverityLevelForRejectedHit

const HcalChannelQuality *	theHcalChStatus

int	theHcalPhase

const HcalSeverityLevelComputer *	theHcalSevLvlComputer

double	theHcalThreshold

const HcalTopology *	theHcalTopology

double	theHEDEScale

std::vector< double >	theHEDGrid

double	theHEDthreshold

double	theHEDweight

std::vector< double >	theHEDWeights

double	theHESEScale

std::vector< double >	theHESGrid

double	theHESthreshold

double	theHESweight

std::vector< double >	theHESWeights

double	theHF1EScale

std::vector< double >	theHF1Grid

double	theHF1threshold

double	theHF1weight

std::vector< double >	theHF1Weights

double	theHF2EScale

std::vector< double >	theHF2Grid

double	theHF2threshold

double	theHF2weight

std::vector< double >	theHF2Weights

double	theHOEScale

std::vector< double >	theHOGrid

bool	theHOIsUsed
	only affects energy and ET calculation. HO is still recorded in the tower More...

double	theHOthreshold0

double	theHOthresholdMinus1

double	theHOthresholdMinus2

double	theHOthresholdPlus1

double	theHOthresholdPlus2

double	theHOweight

std::vector< double >	theHOWeights

int	theMomConstrMethod

double	theMomEBDepth

double	theMomEEDepth

double	theMomHBDepth

double	theMomHEDepth

bool	theRecoveredEcalHitsAreUsed

bool	theRecoveredHcalHitsAreUsed

const CaloTowerConstituentsMap *	theTowerConstituentsMap

const CaloSubdetectorGeometry *	theTowerGeometry

MetaTowerMap	theTowerMap

unsigned int	theTowerMapSize =0

const CaloTowerTopology *	theTowerTopology

bool	theUseEtEBTresholdFlag

bool	theUseEtEETresholdFlag

bool	theUseSymEBTresholdFlag

bool	theUseSymEETresholdFlag

bool	useRejectedHitsOnly

unsigned int	useRejectedRecoveredEcalHits

unsigned int	useRejectedRecoveredHcalHits

Detailed Description

Author: R. Wilkinson - Caltech

Definition at line 49 of file CaloTowersCreationAlgo.h.

Member Typedef Documentation

typedef std::map<CaloTowerDetId, int> CaloTowersCreationAlgo::HcalDropChMap

private

Definition at line 337 of file CaloTowersCreationAlgo.h.

typedef std::vector<MetaTower> CaloTowersCreationAlgo::MetaTowerMap

private

Definition at line 331 of file CaloTowersCreationAlgo.h.

Member Enumeration Documentation

enum CaloTowersCreationAlgo::ctHitCategory

private

Enumerator
GoodChan
BadChan
RecoveredChan
ProblematicChan
IgnoredChan

Definition at line 347 of file CaloTowersCreationAlgo.h.

347 {GoodChan = 0, BadChan = 1, RecoveredChan = 2, ProblematicChan = 3, IgnoredChan = 99 };

CaloTowersCreationAlgo::IgnoredChan

Definition: CaloTowersCreationAlgo.h:347

CaloTowersCreationAlgo::GoodChan

Definition: CaloTowersCreationAlgo.h:347

CaloTowersCreationAlgo::BadChan

Definition: CaloTowersCreationAlgo.h:347

CaloTowersCreationAlgo::ProblematicChan

Definition: CaloTowersCreationAlgo.h:347

CaloTowersCreationAlgo::RecoveredChan

Definition: CaloTowersCreationAlgo.h:347

Constructor & Destructor Documentation

CaloTowersCreationAlgo::CaloTowersCreationAlgo ( )

Definition at line 12 of file CaloTowersCreationAlgo.cc.

  : theEBthreshold(-1000.),
    theEEthreshold(-1000.),
 
    theUseEtEBTresholdFlag(false),
    theUseEtEETresholdFlag(false),
    theUseSymEBTresholdFlag(false),
    theUseSymEETresholdFlag(false),
 
 
    theHcalThreshold(-1000.),
    theHBthreshold(-1000.),
    theHESthreshold(-1000.),
    theHEDthreshold(-1000.),
    theHOthreshold0(-1000.),  
    theHOthresholdPlus1(-1000.),   
    theHOthresholdMinus1(-1000.),  
    theHOthresholdPlus2(-1000.),
    theHOthresholdMinus2(-1000.),   
    theHF1threshold(-1000.),
    theHF2threshold(-1000.),
    theEBGrid(std::vector<double>(5,10.)),
    theEBWeights(std::vector<double>(5,1.)),
    theEEGrid(std::vector<double>(5,10.)),
    theEEWeights(std::vector<double>(5,1.)),
    theHBGrid(std::vector<double>(5,10.)),
    theHBWeights(std::vector<double>(5,1.)),
    theHESGrid(std::vector<double>(5,10.)),
    theHESWeights(std::vector<double>(5,1.)),
    theHEDGrid(std::vector<double>(5,10.)),
    theHEDWeights(std::vector<double>(5,1.)),
    theHOGrid(std::vector<double>(5,10.)),
    theHOWeights(std::vector<double>(5,1.)),
    theHF1Grid(std::vector<double>(5,10.)),
    theHF1Weights(std::vector<double>(5,1.)),
    theHF2Grid(std::vector<double>(5,10.)),
    theHF2Weights(std::vector<double>(5,1.)),
    theEBweight(1.),
    theEEweight(1.),
    theHBweight(1.),
    theHESweight(1.),
    theHEDweight(1.),
    theHOweight(1.),
    theHF1weight(1.),
    theHF2weight(1.),
    theEcutTower(-1000.),
    theEBSumThreshold(-1000.),
    theEESumThreshold(-1000.),
    theHcalTopology(0),
    theGeometry(0),
    theTowerConstituentsMap(0),
    theHOIsUsed(true),
    // (for momentum reconstruction algorithm)
    theMomConstrMethod(0),
    theMomHBDepth(0.),
    theMomHEDepth(0.),
    theMomEBDepth(0.),
    theMomEEDepth(0.),
    theHcalPhase(0)
 {
 }

CaloTowersCreationAlgo::CaloTowersCreationAlgo	(	double	EBthreshold,
		double	EEthreshold,
		bool	useEtEBTreshold,
		bool	useEtEETreshold,
		bool	useSymEBTreshold,
		bool	useSymEETreshold,
		double	HcalThreshold,
		double	HBthreshold,
		double	HESthreshold,
		double	HEDthreshold,
		double	HOthreshold0,
		double	HOthresholdPlus1,
		double	HOthresholdMinus1,
		double	HOthresholdPlus2,
		double	HOthresholdMinus2,
		double	HF1threshold,
		double	HF2threshold,
		double	EBweight,
		double	EEweight,
		double	HBweight,
		double	HESweight,
		double	HEDweight,
		double	HOweight,
		double	HF1weight,
		double	HF2weight,
		double	EcutTower,
		double	EBSumThreshold,
		double	EESumThreshold,
		bool	useHO,
		int	momConstrMethod,
		double	momHBDepth,
		double	momHEDepth,
		double	momEBDepth,
		double	momEEDepth,
		int	hcalPhase = `0`
	)

Definition at line 74 of file CaloTowersCreationAlgo.cc.

   : theEBthreshold(EBthreshold),
     theEEthreshold(EEthreshold),
 
     theUseEtEBTresholdFlag(useEtEBTreshold),
     theUseEtEETresholdFlag(useEtEETreshold),
     theUseSymEBTresholdFlag(useSymEBTreshold),
     theUseSymEETresholdFlag(useSymEETreshold),
 
     theHcalThreshold(HcalThreshold),
     theHBthreshold(HBthreshold),
     theHESthreshold(HESthreshold),
     theHEDthreshold(HEDthreshold),
     theHOthreshold0(HOthreshold0), 
     theHOthresholdPlus1(HOthresholdPlus1),
     theHOthresholdMinus1(HOthresholdMinus1),
     theHOthresholdPlus2(HOthresholdPlus2),
     theHOthresholdMinus2(HOthresholdMinus2),
     theHF1threshold(HF1threshold),
     theHF2threshold(HF2threshold),
     theEBGrid(std::vector<double>(5,10.)),
     theEBWeights(std::vector<double>(5,1.)),
     theEEGrid(std::vector<double>(5,10.)),
     theEEWeights(std::vector<double>(5,1.)),
     theHBGrid(std::vector<double>(5,10.)),
     theHBWeights(std::vector<double>(5,1.)),
     theHESGrid(std::vector<double>(5,10.)),
     theHESWeights(std::vector<double>(5,1.)),
     theHEDGrid(std::vector<double>(5,10.)),
     theHEDWeights(std::vector<double>(5,1.)),
     theHOGrid(std::vector<double>(5,10.)),
     theHOWeights(std::vector<double>(5,1.)),
     theHF1Grid(std::vector<double>(5,10.)),
     theHF1Weights(std::vector<double>(5,1.)),
     theHF2Grid(std::vector<double>(5,10.)),
     theHF2Weights(std::vector<double>(5,1.)),
     theEBweight(EBweight),
     theEEweight(EEweight),
     theHBweight(HBweight),
     theHESweight(HESweight),
     theHEDweight(HEDweight),
     theHOweight(HOweight),
     theHF1weight(HF1weight),
     theHF2weight(HF2weight),
     theEcutTower(EcutTower),
     theEBSumThreshold(EBSumThreshold),
     theEESumThreshold(EESumThreshold),
     theHOIsUsed(useHO),
     // (momentum reconstruction algorithm)
     theMomConstrMethod(momConstrMethod),
     theMomHBDepth(momHBDepth),
     theMomHEDepth(momHEDepth),
     theMomEBDepth(momEBDepth),
     theMomEEDepth(momEEDepth),
     theHcalPhase(hcalPhase)
 {
 }

CaloTowersCreationAlgo::CaloTowersCreationAlgo	(	double	EBthreshold,
		double	EEthreshold,
		bool	useEtEBTreshold,
		bool	useEtEETreshold,
		bool	useSymEBTreshold,
		bool	useSymEETreshold,
		double	HcalThreshold,
		double	HBthreshold,
		double	HESthreshold,
		double	HEDthreshold,
		double	HOthreshold0,
		double	HOthresholdPlus1,
		double	HOthresholdMinus1,
		double	HOthresholdPlus2,
		double	HOthresholdMinus2,
		double	HF1threshold,
		double	HF2threshold,
		const std::vector< double > &	EBGrid,
		const std::vector< double > &	EBWeights,
		const std::vector< double > &	EEGrid,
		const std::vector< double > &	EEWeights,
		const std::vector< double > &	HBGrid,
		const std::vector< double > &	HBWeights,
		const std::vector< double > &	HESGrid,
		const std::vector< double > &	HESWeights,
		const std::vector< double > &	HEDGrid,
		const std::vector< double > &	HEDWeights,
		const std::vector< double > &	HOGrid,
		const std::vector< double > &	HOWeights,
		const std::vector< double > &	HF1Grid,
		const std::vector< double > &	HF1Weights,
		const std::vector< double > &	HF2Grid,
		const std::vector< double > &	HF2Weights,
		double	EBweight,
		double	EEweight,
		double	HBweight,
		double	HESweight,
		double	HEDweight,
		double	HOweight,
		double	HF1weight,
		double	HF2weight,
		double	EcutTower,
		double	EBSumThreshold,
		double	EESumThreshold,
		bool	useHO,
		int	momConstrMethod,
		double	momHBDepth,
		double	momHEDepth,
		double	momEBDepth,
		double	momEEDepth,
		int	hcalPhase = `0`
	)

Definition at line 156 of file CaloTowersCreationAlgo.cc.

   : theEBthreshold(EBthreshold),
     theEEthreshold(EEthreshold),
 
     theUseEtEBTresholdFlag(useEtEBTreshold),
     theUseEtEETresholdFlag(useEtEETreshold),
     theUseSymEBTresholdFlag(useSymEBTreshold),
     theUseSymEETresholdFlag(useSymEETreshold),
 
     theHcalThreshold(HcalThreshold),
     theHBthreshold(HBthreshold),
     theHESthreshold(HESthreshold),
     theHEDthreshold(HEDthreshold),
     theHOthreshold0(HOthreshold0), 
     theHOthresholdPlus1(HOthresholdPlus1),
     theHOthresholdMinus1(HOthresholdMinus1),
     theHOthresholdPlus2(HOthresholdPlus2),
     theHOthresholdMinus2(HOthresholdMinus2),
     theHF1threshold(HF1threshold),
     theHF2threshold(HF2threshold),
     theEBGrid(EBGrid),
     theEBWeights(EBWeights),
     theEEGrid(EEGrid),
     theEEWeights(EEWeights),
     theHBGrid(HBGrid),
     theHBWeights(HBWeights),
     theHESGrid(HESGrid),
     theHESWeights(HESWeights),
     theHEDGrid(HEDGrid),
     theHEDWeights(HEDWeights),
     theHOGrid(HOGrid),
     theHOWeights(HOWeights),
     theHF1Grid(HF1Grid),
     theHF1Weights(HF1Weights),
     theHF2Grid(HF2Grid),
     theHF2Weights(HF2Weights),
     theEBweight(EBweight),
     theEEweight(EEweight),
     theHBweight(HBweight),
     theHESweight(HESweight),
     theHEDweight(HEDweight),
     theHOweight(HOweight),
     theHF1weight(HF1weight),
     theHF2weight(HF2weight),
     theEcutTower(EcutTower),
     theEBSumThreshold(EBSumThreshold),
     theEESumThreshold(EESumThreshold),
     theHOIsUsed(useHO),
     // (momentum reconstruction algorithm)
     theMomConstrMethod(momConstrMethod),
     theMomHBDepth(momHBDepth),
     theMomHEDepth(momHEDepth),
     theMomEBDepth(momEBDepth),
     theMomEEDepth(momEEDepth),
     theHcalPhase(hcalPhase)
 
 {
   // static int N = 0;
   // std::cout << "VI Algo " << ++N << std::endl; 
   // nalgo=N;
 }

Member Function Documentation

void CaloTowersCreationAlgo::assignHitEcal ( const EcalRecHit * recHit )

private

adds a single hit to the tower

Definition at line 676 of file CaloTowersCreationAlgo.cc.

Referenced by process().

                                                                     {
   DetId detId = recHit->detid();
 
   unsigned int chStatusForCT;
   bool ecalIsBad=false;
   std::tie(chStatusForCT,ecalIsBad) = ecalChanStatusForCaloTower(recHit);
 
   // this is for skipping channls: mostly needed for the creation of
   // bad towers from hits i the bad channel collections.
   if (chStatusForCT==CaloTowersCreationAlgo::IgnoredChan) return;
 
   double threshold, weight;
   getThresholdAndWeight(detId, threshold, weight);
 
   double energy = recHit->energy();  // original RecHit energy is used to apply thresholds  
   double e = energy * weight;        // energies scaled by user weight: used in energy assignments
         
   
   // For ECAL we count all bad channels after the metatower is complete 
 
   // Include options for symmetric thresholds and cut on Et
   // for ECAL RecHits
 
   bool passEmThreshold = false;
   
   if (detId.subdetId() == EcalBarrel) {
     if (theUseEtEBTresholdFlag) energy /= cosh( (theGeometry->getGeometry(detId)->getPosition()).eta() ) ;
     if (theUseSymEBTresholdFlag) passEmThreshold = (fabs(energy) >= threshold);
     else  passEmThreshold = (energy >= threshold);
 
   }
   else if (detId.subdetId() == EcalEndcap) {
     if (theUseEtEETresholdFlag) energy /= cosh( (theGeometry->getGeometry(detId)->getPosition()).eta() ) ;
     if (theUseSymEETresholdFlag) passEmThreshold = (fabs(energy) >= threshold);
     else  passEmThreshold = (energy >= threshold);
   }
 
   CaloTowerDetId towerDetId = theTowerConstituentsMap->towerOf(detId);
   if (towerDetId.null()) return;
   MetaTower & tower = find(towerDetId);
 
 
   // count bad cells and avoid double counting with those from DB (Recovered are counted bad)
 
   // somehow misses some
   // if ( (chStatusForCT == CaloTowersCreationAlgo::BadChan) & (!ecalIsBad) ) ++tower.numBadEcalCells; 
 
   // a bit slower...
   if ( chStatusForCT == CaloTowersCreationAlgo::BadChan ) {
     auto thisEcalSevLvl = theEcalSevLvlAlgo->severityLevel(detId);
     // check if the Ecal severity is ok to keep
     auto sevit = std::find(theEcalSeveritiesToBeExcluded.begin(),
                    theEcalSeveritiesToBeExcluded.end(),
                    thisEcalSevLvl);
     if (sevit==theEcalSeveritiesToBeExcluded.end()) ++tower.numBadEcalCells;  // notinDB
   }
   
 
   //      if (chStatusForCT != CaloTowersCreationAlgo::BadChan && energy >= threshold) {
   if (chStatusForCT != CaloTowersCreationAlgo::BadChan && passEmThreshold) {
 
     tower.E_em += e;
     tower.E += e;
     
     if (chStatusForCT == CaloTowersCreationAlgo::RecoveredChan)  {
       tower.numRecEcalCells += 1;  
     }
     else if (chStatusForCT == CaloTowersCreationAlgo::ProblematicChan) {
       tower.numProbEcalCells += 1;
     }
     
     // change when full status info is available
     // for now use only good channels
     
     // add e>0 check (new options allow e<0)
     if (chStatusForCT == CaloTowersCreationAlgo::GoodChan && e>0 ) {
       tower.emSumTimeTimesE += ( e * recHit->time() );
       tower.emSumEForTime   += e;  // see above
     }
 
     std::pair<DetId,float> mc(detId,e);
     tower.metaConstituents.push_back(mc);
   }
 }  // end of assignHitEcal method

void CaloTowersCreationAlgo::assignHitHcal ( const CaloRecHit * recHit )

private

Definition at line 457 of file CaloTowersCreationAlgo.cc.

Referenced by process().

                                                                     {
   DetId detId = recHit->detid();
 
   unsigned int chStatusForCT = hcalChanStatusForCaloTower(recHit);
 
   // this is for skipping channls: mostly needed for the creation of
   // bad towers from hits i the bad channel collections.
   if (chStatusForCT==CaloTowersCreationAlgo::IgnoredChan) return;
 
   double threshold, weight;
   getThresholdAndWeight(detId, threshold, weight);
 
   double energy = recHit->energy();  // original RecHit energy is used to apply thresholds  
   double e = energy * weight;        // energies scaled by user weight: used in energy assignments
         
   // SPECIAL handling of tower 28 merged depths --> half into tower 28 and half into tower 29
   if (detId.det()==DetId::Hcal && 
       HcalDetId(detId).subdet()==HcalEndcap &&
       (theHcalPhase==0 || theHcalPhase==1) &&
       std::find(mergedDepths.begin(), mergedDepths.end(), HcalDetId(detId).depth())!=mergedDepths.end() &&
       //HcalDetId(detId).depth()==3 &&
       HcalDetId(detId).ietaAbs()==theHcalTopology->lastHERing()-1) {
 
       
     // bad channels are counted regardless of energy threshold
 
     if (chStatusForCT == CaloTowersCreationAlgo::BadChan) {
       CaloTowerDetId towerDetId = theTowerConstituentsMap->towerOf(detId);
       if (towerDetId.null()) return;
       MetaTower & tower28 = find(towerDetId);
       CaloTowerDetId towerDetId29(towerDetId.ieta()+towerDetId.zside(),
                                   towerDetId.iphi());
       MetaTower & tower29 = find(towerDetId29);
       tower28.numBadHcalCells += 1;
       tower29.numBadHcalCells += 1;
     }
 
     else if (0.5*energy >= threshold) {  // not bad channel: use energy if above threshold
       
       CaloTowerDetId towerDetId = theTowerConstituentsMap->towerOf(detId);
       if (towerDetId.null()) return;
       MetaTower & tower28 = find(towerDetId);
       CaloTowerDetId towerDetId29(towerDetId.ieta()+towerDetId.zside(),
                                   towerDetId.iphi());
       MetaTower & tower29 = find(towerDetId29);
 
       if (chStatusForCT == CaloTowersCreationAlgo::RecoveredChan) {
         tower28.numRecHcalCells += 1;
         tower29.numRecHcalCells += 1;     
       }
       else if (chStatusForCT == CaloTowersCreationAlgo::ProblematicChan) {
         tower28.numProbHcalCells += 1;
         tower29.numProbHcalCells += 1;
       }
 
       // NOTE DIVIDE BY 2!!!
       double e28 = 0.5 * e;
       double e29 = 0.5 * e;
 
       tower28.E_had += e28;
       tower28.E += e28;
       std::pair<DetId,float> mc(detId,e28);
       tower28.metaConstituents.push_back(mc);
       
       tower29.E_had += e29;
       tower29.E += e29;
       tower29.metaConstituents.push_back(mc);
       
       // time info: do not use in averaging if timing error is found: need 
       // full set of status info to implement: use only "good" channels for now
 
       if (chStatusForCT == CaloTowersCreationAlgo::GoodChan) {
     tower28.hadSumTimeTimesE += ( e28 * recHit->time() );
     tower28.hadSumEForTime   += e28;
     tower29.hadSumTimeTimesE += ( e29 * recHit->time() );
     tower29.hadSumEForTime   += e29;
       }
 
       // store the energy in layer 3 also in E_outer
       tower28.E_outer += e28;
       tower29.E_outer += e29;
     } // not a "bad" hit
       
   }  // end of special case 
   
   else {
     HcalDetId hcalDetId(detId);
     
 
     if(hcalDetId.subdet() == HcalOuter) {
 
       CaloTowerDetId towerDetId = theTowerConstituentsMap->towerOf(detId);
       if (towerDetId.null()) return;
       MetaTower & tower = find(towerDetId);
 
       if (chStatusForCT == CaloTowersCreationAlgo::BadChan) {
           if (theHOIsUsed) tower.numBadHcalCells += 1;
       }
       
       else if (energy >= threshold) {
         tower.E_outer += e; // store HO energy even if HO is not used
         // add energy of the tower and/or flag if theHOIsUsed
         if(theHOIsUsed) {
           tower.E += e;
           
           if (chStatusForCT == CaloTowersCreationAlgo::RecoveredChan) {
             tower.numRecHcalCells += 1;
           }
           else if (chStatusForCT == CaloTowersCreationAlgo::ProblematicChan) {
             tower.numProbHcalCells += 1;
           }
         } // HO is used
       
         
         // add HO to constituents even if it is not used: JetMET wants to keep these towers
         std::pair<DetId,float> mc(detId,e);
         tower.metaConstituents.push_back(mc);   
 
       } // not a bad channel, energy above threshold
     
     }  // HO hit 
     
     // HF calculates EM fraction differently
     else if(hcalDetId.subdet() == HcalForward) {
 
       if (chStatusForCT == CaloTowersCreationAlgo::BadChan) {
         CaloTowerDetId towerDetId = theTowerConstituentsMap->towerOf(detId);
         if (towerDetId.null()) return;
         MetaTower & tower = find(towerDetId);
         tower.numBadHcalCells += 1;
       }
       
       else if (energy >= threshold)  {
         CaloTowerDetId towerDetId = theTowerConstituentsMap->towerOf(detId);
         if (towerDetId.null()) return;
         MetaTower & tower = find(towerDetId);
 
         if (hcalDetId.depth() == 1) {
           // long fiber, so E_EM = E(Long) - E(Short)
           tower.E_em += e;
         } 
         else {
           // short fiber, EHAD = 2 * E(Short)
           tower.E_em -= e;
           tower.E_had += 2. * e;
         }
         tower.E += e;
         if (chStatusForCT == CaloTowersCreationAlgo::RecoveredChan) {
           tower.numRecHcalCells += 1;
         }
         else if (chStatusForCT == CaloTowersCreationAlgo::ProblematicChan) {
           tower.numProbHcalCells += 1;
         }
         
         // put the timing in HCAL -> have to check timing errors when available
         // for now use only good channels
         if (chStatusForCT == CaloTowersCreationAlgo::GoodChan) {
           tower.hadSumTimeTimesE += ( e * recHit->time() );
           tower.hadSumEForTime   += e;
         }
 
         std::pair<DetId,float> mc(detId,e);
         tower.metaConstituents.push_back(mc);            
 
       } // not a bad HF channel, energy above threshold
     
     } // HF hit
     
     else {
       // HCAL situation normal in HB/HE
       if (chStatusForCT == CaloTowersCreationAlgo::BadChan) {
         CaloTowerDetId towerDetId = theTowerConstituentsMap->towerOf(detId);
         if (towerDetId.null()) return;
         MetaTower & tower = find(towerDetId);
         tower.numBadHcalCells += 1;
       }
       else if (energy >= threshold) {
         CaloTowerDetId towerDetId = theTowerConstituentsMap->towerOf(detId);
         if (towerDetId.null()) return;
         MetaTower & tower = find(towerDetId);
         tower.E_had += e;
         tower.E += e;
         if (chStatusForCT == CaloTowersCreationAlgo::RecoveredChan) {
           tower.numRecHcalCells += 1;
         }
         else if (chStatusForCT == CaloTowersCreationAlgo::ProblematicChan) {
           tower.numProbHcalCells += 1;
         }
         
         // Timing information: need specific accessors
         // for now use only good channels
         if (chStatusForCT == CaloTowersCreationAlgo::GoodChan) {
           tower.hadSumTimeTimesE += ( e * recHit->time() );
           tower.hadSumEForTime   += e;
         }
         // store energy in highest depth for towers 18-27 (for electron,photon ID in endcap)
         // also, store energy in HE part of tower 16 (for JetMET cleanup)
         HcalDetId hcalDetId(detId);
         if (hcalDetId.subdet()==HcalEndcap && theHcalPhase==0) {
           if ( (hcalDetId.depth()==2 && hcalDetId.ietaAbs()>=18 && hcalDetId.ietaAbs()<27) ||
                (hcalDetId.depth()==3 && hcalDetId.ietaAbs()==27) ||
                (hcalDetId.depth()==3 && hcalDetId.ietaAbs()==16) ) {
             tower.E_outer += e;
           }
         }
 
         std::pair<DetId,float> mc(detId,e);
         tower.metaConstituents.push_back(mc);   
      
       }   // not a "bad" channel, energy above threshold
     
     } // channel in HBHE (excluding twrs 28,29)
     
   }  // recHit normal case (not in HE towers 28,29)
 
 }  // end of assignHitHcal method

void CaloTowersCreationAlgo::begin ( void )

Definition at line 286 of file CaloTowersCreationAlgo.cc.

References theTowerMap, and theTowerMapSize.

Referenced by CaloTowersReCreator::produce(), and CaloTowersCreator::produce().

                                    {
   theTowerMap.clear();
   theTowerMapSize=0;
   //hcalDropChMap.clear();
 }

int CaloTowersCreationAlgo::compactTime ( float time )

private

Definition at line 1473 of file CaloTowersCreationAlgo.cc.

Referenced by convert().

                                                   {
 
   const float timeUnit = 0.01; // discretization (ns)
 
   if (time>  300.0) return  30000;
   if (time< -300.0) return -30000;
 
   return int(time/timeUnit + 0.5);
 
 }

void CaloTowersCreationAlgo::convert	(	const CaloTowerDetId &	id,
		const MetaTower &	mt,
		CaloTowerCollection &	collection
	)

private

if (E>0) towerP4 = CaloTower::PolarLorentzVector(E*sumPf, emPoint.eta(), emPoint.phi(), 0);

Definition at line 831 of file CaloTowersCreationAlgo.cc.

Referenced by finish().

 {
     assert(id.rawId()!=0);
 
     double ecalThres=(id.ietaAbs()<=17)?(theEBSumThreshold):(theEESumThreshold);
     double E=mt.E;
     double E_em=mt.E_em;
     double E_had=mt.E_had;
     double E_outer=mt.E_outer;
 
     // Note: E_outer is used to save HO energy OR energy in the outermost depths in endcap region
     // In the methods with separate treatment of EM and HAD components:
     //  - HO is not used to determine direction, however HO energy is added to get "total had energy"
     //  => Check if the tower is within HO coverage before adding E_outer to the "total had" energy
     //     else the energy will be double counted
     // When summing up the energy of the tower these checks are performed in the loops over RecHits
 
     std::vector<std::pair<DetId,float> > metaContains=mt.metaConstituents;
     if (id.ietaAbs()<theTowerTopology->firstHFRing() && E_em<ecalThres) { // ignore EM threshold in HF
       E-=E_em;
       E_em=0;
       std::vector<std::pair<DetId,float> > metaContains_noecal;
 
     for (std::vector<std::pair<DetId,float> >::iterator i=metaContains.begin(); i!=metaContains.end(); ++i) 
             if (i->first.det()!=DetId::Ecal) metaContains_noecal.push_back(*i);
       metaContains.swap(metaContains_noecal);
     }
     if (id.ietaAbs()<theTowerTopology->firstHFRing() && E_had<theHcalThreshold) {
       E-=E_had;
 
       if (theHOIsUsed && id.ietaAbs()<=theTowerTopology->lastHORing())  E-=E_outer; // not subtracted before, think it should be done
      
       E_had=0;
       E_outer=0;
       std::vector<std::pair<DetId,float> > metaContains_nohcal;
 
       for (std::vector<std::pair<DetId,float> >::iterator i=metaContains.begin(); i!=metaContains.end(); ++i) 
         if (i->first.det()!=DetId::Hcal) metaContains_nohcal.push_back(*i);
       metaContains.swap(metaContains_nohcal);
     }
 
     if(metaContains.empty()) return;
 
     double E_had_tot = (theHOIsUsed && id.ietaAbs()<=theTowerTopology->lastHORing())? E_had+E_outer : E_had;
 
 
     // create CaloTower using the selected algorithm
 
     GlobalPoint emPoint, hadPoint;
 
     // this is actually a 4D vector
     Basic3DVectorF towerP4;
     bool massless=true;
     // float mass1=0;
     float mass2=0;
 
     // conditional assignment of depths for barrel/endcap
     // Some additional tuning may be required in the transitional region
     // 14<|iEta|<19
     double momEmDepth = 0.;
     double momHadDepth = 0.;
     if (id.ietaAbs()<=17) {
       momHadDepth = theMomHBDepth;
       momEmDepth  = theMomEBDepth;
     }
     else {
       momHadDepth = theMomHEDepth;
       momEmDepth  = theMomEEDepth;
     }
 
 
 
     switch (theMomConstrMethod) {
       
       // FIXME  : move to simple cartesian algebra
     case 0 :
       {  // Simple 4-momentum assignment
     GlobalPoint p=theTowerGeometry->getGeometry(id)->getPosition();
     towerP4 = p.basicVector().unit();
     towerP4[3] = 1.f;  // energy
     towerP4 *=E;
     
     // double pf=1.0/cosh(p.eta());
     // if (E>0) towerP4 = CaloTower::PolarLorentzVector(E*pf, p.eta(), p.phi(), 0);
     
     emPoint  = p;   
     hadPoint = p;
       }  // end case 0
       break;
       
     case 1 :
       {   // separate 4-vectors for ECAL, HCAL, add to get the 4-vector of the tower (=>tower has mass!)
     if (id.ietaAbs()<theTowerTopology->firstHFRing()) {
           Basic3DVectorF emP4;
       if (E_em>0) {
         emPoint   = emShwrPos(metaContains, momEmDepth, E_em);
         emP4 = emPoint.basicVector().unit();
         emP4[3] = 1.f;  // energy
         towerP4 = emP4*E_em;
         
         // double emPf = 1.0/cosh(emPoint.eta());
         // towerP4 += CaloTower::PolarLorentzVector(E_em*emPf, emPoint.eta(), emPoint.phi(), 0); 
       }
       if ( (E_had + E_outer) >0) {
             massless = (E_em<=0);
         hadPoint  = hadShwrPos(id, momHadDepth);
         auto lP4 = hadPoint.basicVector().unit();
         lP4[3] = 1.f;  // energy
             if (!massless) {
               auto diff = lP4-emP4;  mass2 = std::sqrt(E_em*E_had_tot*diff.mag2()); 
             }
         lP4 *=E_had_tot;
         towerP4 +=lP4;
             /*
             if (!massless) {
                auto p = towerP4;
                double m2 = double(p[3]*p[3]) - double(p[0]*p[0])+double(p[1]*p[1])+double(p[2]*p[2]); mass1 = m2>0 ? std::sqrt(m2) : 0;
             }       
             */
         // double hadPf = 1.0/cosh(hadPoint.eta());   
         // if (E_had_tot>0) {
         //  towerP4 += CaloTower::PolarLorentzVector(E_had_tot*hadPf, hadPoint.eta(), hadPoint.phi(), 0); 
         // }
       }
     }
     else {  // forward detector: use the CaloTower position 
       GlobalPoint p=theTowerGeometry->getGeometry(id)->getPosition();
       towerP4 = p.basicVector().unit();
       towerP4[3] = 1.f;  // energy
       towerP4 *=E;
       // double pf=1.0/cosh(p.eta());
       // if (E>0) towerP4 = CaloTower::PolarLorentzVector(E*pf, p.eta(), p.phi(), 0);  // simple momentum assignment, same position
       emPoint  = p;   
       hadPoint = p;
     }
       }  // end case 1
       break;
       
     case 2:
       {   // use ECAL position for the tower (when E_cal>0), else default CaloTower position (massless tower)
     if (id.ietaAbs()<theTowerTopology->firstHFRing()) {
       if (E_em>0)  emPoint = emShwrLogWeightPos(metaContains, momEmDepth, E_em);
       else emPoint = theTowerGeometry->getGeometry(id)->getPosition();
       towerP4 = emPoint.basicVector().unit();
       towerP4[3] = 1.f;  // energy
       towerP4 *=E;
       
       // double sumPf = 1.0/cosh(emPoint.eta());
       
       hadPoint = emPoint;
     }
     else {  // forward detector: use the CaloTower position 
       GlobalPoint p=theTowerGeometry->getGeometry(id)->getPosition();
       towerP4 = p.basicVector().unit();
       towerP4[3] = 1.f;  // energy
       towerP4 *=E;
       
       // double pf=1.0/cosh(p.eta());
       // if (E>0) towerP4 = CaloTower::PolarLorentzVector(E*pf, p.eta(), p.phi(), 0);  // simple momentum assignment, same position
       emPoint  = p;   
       hadPoint = p;
     }
       }   // end case 2
       break;
       
     }  // end of decision on p4 reconstruction method
     
     
     // insert in collection (remove and return if below threshold)
     if unlikely ( (towerP4[3]==0) & (E_outer>0)  ) {
       collection.emplace_back(id, E_em, E_had, E_outer, -1, -1, CaloTower::PolarLorentzVector(0,hadPoint.eta(), hadPoint.phi(),0),  emPoint, hadPoint);
     } else {
       collection.emplace_back(id, E_em, E_had, E_outer, -1, -1, GlobalVector(towerP4), towerP4[3], mass2, emPoint, hadPoint);
     }
     auto & caloTower = collection.back();
 
     // if (!massless) std::cout << "massive " << id <<' ' << mass1 <<' ' << mass2 <<' ' <<  caloTower.mass() << std::endl;
     // std::cout << "CaloTowerVI " <<theMomConstrMethod <<' ' << id <<' '<< E_em <<' '<< E_had <<' '<< E_outer <<' '<< GlobalVector(towerP4) <<' '<< towerP4[3] <<' '<< emPoint <<' '<< hadPoint << std::endl;
     //if (towerP4[3]==0) std::cout << "CaloTowerVIzero " << theEcutTower << ' ' << collection.back().eta() <<' '<< collection.back().phi() << std::endl;
 
     if(caloTower.energy() < theEcutTower) { collection.pop_back(); return;}
     
     // set the timings
     float  ecalTime = (mt.emSumEForTime>0)?   mt.emSumTimeTimesE/mt.emSumEForTime  : -9999;
     float  hcalTime = (mt.hadSumEForTime>0)?  mt.hadSumTimeTimesE/mt.hadSumEForTime : -9999;
     caloTower.setEcalTime(compactTime(ecalTime));
     caloTower.setHcalTime(compactTime(hcalTime));
     //add topology info
     caloTower.setHcalSubdet(theTowerTopology->lastHBRing(),
                             theTowerTopology->lastHERing(),
                             theTowerTopology->lastHFRing(),
                             theTowerTopology->lastHORing() );
 
     // set the CaloTower status word =====================================
     // Channels must be counter exclusively in the defined cathegories
     // "Bad" channels (not used in energy assignment) can be flagged during
     // CaloTower creation only if specified in the configuration file
 
     unsigned int numBadHcalChan  = mt.numBadHcalCells;
     //    unsigned int numBadEcalChan  = mt.numBadEcalCells;
     unsigned int numBadEcalChan  = 0;   //
 
     unsigned int numRecHcalChan  = mt.numRecHcalCells;
     unsigned int numRecEcalChan  = mt.numRecEcalCells;
     unsigned int numProbHcalChan = mt.numProbHcalCells;
     unsigned int numProbEcalChan = mt.numProbEcalCells;
 
     // now add dead/off/... channels not used in RecHit reconstruction for HCAL 
     HcalDropChMap::iterator dropChItr = hcalDropChMap.find(id);
     if (dropChItr != hcalDropChMap.end()) numBadHcalChan += dropChItr->second;
     
 
     // for ECAL the number of all bad channels is obtained here -----------------------
 
     /*
     // old hyper slow algorithm    
     // get all possible constituents of the tower
     std::vector<DetId> allConstituents = theTowerConstituentsMap->constituentsOf(id);
 
     for (std::vector<DetId>::iterator ac_it=allConstituents.begin(); 
      ac_it!=allConstituents.end(); ++ac_it) {
 
       if (ac_it->det()!=DetId::Ecal) continue;
  
       int thisEcalSevLvl = -999;
      
       if (ac_it->subdetId() == EcalBarrel && theEbHandle.isValid()) {
     thisEcalSevLvl = theEcalSevLvlAlgo->severityLevel( *ac_it, *theEbHandle);//, *theEcalChStatus);
       }
       else if (ac_it->subdetId() == EcalEndcap && theEeHandle.isValid()) {
     thisEcalSevLvl = theEcalSevLvlAlgo->severityLevel( *ac_it, *theEeHandle);//, *theEcalChStatus);
       }
  
       // check if the Ecal severity is ok to keep
       std::vector<int>::const_iterator sevit = std::find(theEcalSeveritiesToBeExcluded.begin(),
                              theEcalSeveritiesToBeExcluded.end(),
                              thisEcalSevLvl);
       if (sevit!=theEcalSeveritiesToBeExcluded.end()) {
     ++numBadEcalChan;
       }
 
      }
      
      // compare with fast version
  
    //  hcal: 
     int inEcals[2] = {0,0};
     for (std::vector<std::pair<DetId,float> >::iterator i=metaContains.begin(); i!=metaContains.end(); ++i) {
       DetId detId = i->first;
       if(detId.det() == DetId::Ecal){
     if( detId.subdetId()==EcalBarrel ) inEcals[0] =1;
     else if( detId.subdetId()==EcalEndcap ) inEcals[1] =1;
       }
     }
 
      auto  numBadEcalChanNew = ecalBadChs[theTowerTopology->denseIndex(id)]+mt.numBadEcalCells; // - mt.numRecEcalCells
      if (int(numBadEcalChanNew)!=int(numBadEcalChan)) { 
        std::cout << "VI wrong " << ((inEcals[1]==1) ? "EE" : "" ) << id << " " << numBadEcalChanNew << " " << numBadEcalChan 
          << " " << mt.numBadEcalCells << " " << mt.numRecEcalCells << std::endl;
      }
      */
      
      numBadEcalChan =  ecalBadChs[theTowerTopology->denseIndex(id)]+mt.numBadEcalCells; // - mt.numRecEcalCells
 
     //--------------------------------------------------------------------------------------
 
     caloTower.setCaloTowerStatus(numBadHcalChan, numBadEcalChan,     
                   numRecHcalChan, numRecEcalChan,    
                   numProbHcalChan, numProbEcalChan);
   
     double maxCellE = -999.0; // for storing the hottest cell E in the calotower
 
     std::vector<DetId> contains;
     contains.reserve(metaContains.size());
     for (std::vector<std::pair<DetId,float> >::iterator i=metaContains.begin(); i!=metaContains.end(); ++i) {
 
       contains.push_back(i->first);
 
       if (maxCellE < i->second) {
     // need an extra check because of the funny towers that are empty except for the presence of an HO
     // hit in the constituents (JetMET wanted them saved)
     // This constituent is only used for storing the tower, but should not be concidered as a hot cell canditate for
     // configurations with useHO = false
 
 
     if (i->first.det()==DetId::Ecal) {  // ECAL
       maxCellE = i->second;
     }   
     else {  // HCAL
       if (HcalDetId(i->first).subdet() != HcalOuter) 
         maxCellE = i->second;
       else if (theHOIsUsed) maxCellE = i->second;
     }
 
       } // found higher E cell
 
     } // loop over matacontains
 
     caloTower.setConstituents(std::move(contains));
     caloTower.setHottestCellE(maxCellE);
 
     // std::cout << "CaloTowerVI " << nalgo << ' ' << caloTower.id() << ((inEcals[1]==1) ? "EE " : " " )  << caloTower.pt() << ' ' << caloTower.et() << ' ' << caloTower.mass() << ' '
     //           << caloTower.constituentsSize() <<' '<< caloTower.towerStatusWord() << std::endl;
 
 } 

std::tuple< unsigned int, bool > CaloTowersCreationAlgo::ecalChanStatusForCaloTower ( const EcalRecHit * hit )

Definition at line 1641 of file CaloTowersCreationAlgo.cc.

References BadChan, spr::find(), GoodChan, IgnoredChan, EcalSeverityLevel::kBad, EcalSeverityLevel::kGood, EcalSeverityLevel::kRecovered, ProblematicChan, RecoveredChan, EcalSeverityLevelAlgo::severityLevel(), theEcalSeveritiesToBeExcluded, theEcalSeveritiesToBeUsedInBadTowers, theEcalSevLvlAlgo, theRecoveredEcalHitsAreUsed, useRejectedHitsOnly, and useRejectedRecoveredEcalHits.

Referenced by assignHitEcal().

                                                                                                      {
 
   // const DetId id = hit->detid();
 
   //  uint16_t dbStatus = theEcalChStatus->find(id)->getStatusCode();
   //  uint32_t rhFlags  = hit->flags();
   //  int severityLevel = theEcalSevLvlAlgo->severityLevel(rhFlags, dbStatus);
   // The methods above will become private and cannot be usef for flagging ecal spikes.
   // Use the recommended interface - we leave the parameters for spilke removal to be specified by ECAL.
 
 
   //  int severityLevel = 999;
 
   EcalRecHit const & rh = *reinterpret_cast<EcalRecHit const *>(hit);
   int severityLevel = theEcalSevLvlAlgo->severityLevel(rh);
 
 //  if      (id.subdetId() == EcalBarrel) severityLevel = theEcalSevLvlAlgo->severityLevel( id, *theEbHandle);//, *theEcalChStatus);
 //  else if (id.subdetId() == EcalEndcap) severityLevel = theEcalSevLvlAlgo->severityLevel( id, *theEeHandle);//, *theEcalChStatus);
 
   // there should be no other ECAL types used in this reconstruction
 
   // The definition of ECAL severity levels uses categories that
   // are similar to the defined for CaloTower. (However, the categorization
   // for CaloTowers depends on the specified maximum acceptabel severity and therefore cannnot
   // be exact correspondence between the two. ECAL has additional categories describing modes of failure.)
   // This approach is different from the initial idea and from
   // the implementation for HCAL. Still make the logic similar to HCAL so that one has the ability to 
   // exclude problematic channels as defined by ECAL.
   // For definitions of ECAL severity levels see RecoLocalCalo/EcalRecAlgos/interface/EcalSeverityLevelAlgo.h
 
   bool isBad = (severityLevel == EcalSeverityLevel::kBad);
 
   bool isRecovered = (severityLevel == EcalSeverityLevel::kRecovered);
 
   // check if the severity is compatible with our configuration
   // This applies to the "default" tower cleaning
   std::vector<int>::const_iterator sevit = std::find(theEcalSeveritiesToBeExcluded.begin(),
                              theEcalSeveritiesToBeExcluded.end(),
                              severityLevel);
   bool accepted = (sevit==theEcalSeveritiesToBeExcluded.end()) ;
 
   // For use with hits that were rejected in the regular reconstruction:
   // This is for creating calotowers with lower level of cleaning by merging
   // the information from the default towers and a collection of towers created from
   // bad rechits 
  
 
   if (useRejectedHitsOnly) {
     
     if (!isRecovered) {
 
       if (accepted  ||
       std::find(theEcalSeveritiesToBeUsedInBadTowers.begin(), theEcalSeveritiesToBeUsedInBadTowers.end(), severityLevel)
       == theEcalSeveritiesToBeUsedInBadTowers.end())
     return std::make_tuple(CaloTowersCreationAlgo::IgnoredChan,isBad);
       // this hit was either already accepted, or is not eligible for inclusion
     }    
     else {
       
       if (theRecoveredEcalHitsAreUsed || !useRejectedRecoveredEcalHits) {
     // skip recovered hits either because they were already used or because there was an explicit instruction
     return std::make_tuple(CaloTowersCreationAlgo::IgnoredChan,isBad);;
       }
       else if (useRejectedRecoveredEcalHits) {
     return std::make_tuple(CaloTowersCreationAlgo::RecoveredChan,isBad);
       }  
   
     }  // recovered channels
 
     // clasify channels as problematic
     return std::make_tuple(CaloTowersCreationAlgo::ProblematicChan,isBad);
 
   }  // treatment of rejected hits
 
 
 
   // for normal reconstruction
   if (severityLevel == EcalSeverityLevel::kGood) return std::make_tuple(CaloTowersCreationAlgo::GoodChan,false);
 
   if (isRecovered) {
     return  std::make_tuple( (theRecoveredEcalHitsAreUsed) ? 
      CaloTowersCreationAlgo::RecoveredChan : CaloTowersCreationAlgo::BadChan, true);
   }  
   else {
     return  std::make_tuple(accepted ? CaloTowersCreationAlgo::ProblematicChan : CaloTowersCreationAlgo::BadChan,isBad);
 
   }
 
 
 }

GlobalPoint CaloTowersCreationAlgo::emCrystalShwrPos	(	DetId	detId,
		float	fracDepth
	)

Definition at line 1280 of file CaloTowersCreationAlgo.cc.

References CaloCellGeometry::getBackPoint(), CaloGeometry::getGeometry(), CaloCellGeometry::getPosition(), point, and theGeometry.

Referenced by emShwrLogWeightPos(), emShwrPos(), and hadSegmentShwrPos().

                                                                                  {
    const CaloCellGeometry* cellGeometry = theGeometry->getGeometry(detId);
    GlobalPoint point = cellGeometry->getPosition();  // face of the cell
 
    if (fracDepth<=0) return point;
    if (fracDepth>1) fracDepth=1;
 
      GlobalPoint backPoint = cellGeometry->getBackPoint();
      point += fracDepth * (backPoint-point);
 
    return point;
 }

GlobalPoint CaloTowersCreationAlgo::emShwrLogWeightPos	(	const std::vector< std::pair< DetId, float > > &	metaContains,
		float	fracDepth,
		double	totEmE
	)

Definition at line 1434 of file CaloTowersCreationAlgo.cc.

References DetId::Ecal, emCrystalShwrPos(), dqm-mbProfile::log, AlCaHLTBitMon_ParallelJobs::p, puppiForMET_cff::weight, PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().

Referenced by convert().

                                                             {
 
   double emX = 0.0;
   double emY = 0.0;
   double emZ = 0.0;
 
   double weight = 0;
   double sumWeights = 0;
   double sumEmE = 0;  // add crystals with E/E_EM > 1.5%
   double crystalThresh = 0.015 * emE;
 
   std::vector<std::pair<DetId,float> >::const_iterator mc_it = metaContains.begin();
   for (; mc_it!=metaContains.end(); ++mc_it) {
     if (mc_it->second < 0) continue;
     if (mc_it->first.det() == DetId::Ecal && mc_it->second > crystalThresh) sumEmE += mc_it->second;
   }
 
   for (mc_it = metaContains.begin(); mc_it!=metaContains.end(); ++mc_it) {
     
     if (mc_it->first.det() != DetId::Ecal || mc_it->second < crystalThresh) continue;
     
     GlobalPoint p = emCrystalShwrPos(mc_it->first, fracDepth);
 
     weight = 4.2 + log(mc_it->second/sumEmE);
     sumWeights += weight;
       
     emX += p.x() * weight;
     emY += p.y() * weight;
     emZ += p.z() * weight;
   }
 
    return GlobalPoint(emX/sumWeights, emY/sumWeights, emZ/sumWeights);
 }

GlobalPoint CaloTowersCreationAlgo::emShwrPos	(	const std::vector< std::pair< DetId, float > > &	metaContains,
		float	fracDepth,
		double	totEmE
	)

Definition at line 1404 of file CaloTowersCreationAlgo.cc.

References alignCSCRings::e, DetId::Ecal, emCrystalShwrPos(), AlCaHLTBitMon_ParallelJobs::p, PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().

Referenced by convert().

                                                                            {
 
   if (emE<=0) return GlobalPoint(0,0,0);
 
   double emX = 0.0;
   double emY = 0.0;
   double emZ = 0.0;
 
   double eSum = 0;
 
   std::vector<std::pair<DetId,float> >::const_iterator mc_it = metaContains.begin();
   for (; mc_it!=metaContains.end(); ++mc_it) {
     if (mc_it->first.det() != DetId::Ecal) continue;
     GlobalPoint p = emCrystalShwrPos(mc_it->first, fracDepth);
     double e = mc_it->second;
 
     if (e>0) {
       emX += p.x() * e;
       emY += p.y() * e;
       emZ += p.z() * e;
       eSum += e;
     }
 
   }
 
    return GlobalPoint(emX/eSum, emY/eSum, emZ/eSum);
 }

CaloTowersCreationAlgo::MetaTower & CaloTowersCreationAlgo::find ( const CaloTowerDetId & id )

private

looks for a given tower in the internal cache. If it can't find it, it makes it.

Definition at line 814 of file CaloTowersCreationAlgo.cc.

References CaloTowerTopology::denseIndex(), CaloTowerTopology::firstHFRing(), CaloTowerDetId::ietaAbs(), CaloTowerTopology::sizeForDenseIndexing(), theTowerMap, theTowerMapSize, and theTowerTopology.

Referenced by assignHitEcal(), assignHitHcal(), and rescale().

                                                                                            {
   if (theTowerMap.empty()) {
     theTowerMap.resize(theTowerTopology->sizeForDenseIndexing());
   }
   
   auto & mt = theTowerMap[theTowerTopology->denseIndex(detId)]; 
   
   if (mt.empty()) {
     mt.id=detId;
     mt.metaConstituents.reserve(detId.ietaAbs()<theTowerTopology->firstHFRing() ? 12 : 2);
     ++theTowerMapSize;
   }
   
   return mt;
 }

void CaloTowersCreationAlgo::finish ( CaloTowerCollection & destCollection )

Definition at line 329 of file CaloTowersCreationAlgo.cc.

References convert(), edm::SortedCollection< T, SORT >::reserve(), theTowerMap, and theTowerMapSize.

Referenced by progressbar.ProgressBar::__next__(), and CaloTowersCreator::produce().

                                                                {
   // now copy this map into the final collection
   result.reserve(theTowerMapSize);
   // auto k=0U;
   //  if (!theEbHandle.isValid()) std::cout << "VI ebHandle not valid" << std::endl;
   // if (!theEeHandle.isValid()) std::cout << "VI eeHandle not valid" << std::endl;
 
   for(auto const & mt : theTowerMap ) { 
     // Convert only if there is at least one constituent in the metatower. 
     // The check of constituents size in the coverted tower is still needed!
     if (!mt.empty() ) { convert(mt.id, mt, result); } // ++k;}  
   }
   
   // assert(k==theTowerMapSize);
   // std::cout << "VI TowerMap " << theTowerMapSize << " " << k << std::endl;
   
   theTowerMap.clear(); // save the memory
   theTowerMapSize=0;
 }

void CaloTowersCreationAlgo::getThresholdAndWeight	(	const DetId &	detId,
		double &	threshold,
		double &	weight
	)		const

private

helper method to look up the appropriate threshold & weight

Definition at line 1141 of file CaloTowersCreationAlgo.cc.

References HcalDetId::depth(), DetId::det(), DetId::Ecal, EcalBarrel, EcalEndcap, HcalTopology::firstHEDoublePhiRing(), DetId::Hcal, HcalBarrel, HcalEndcap, HcalForward, HcalOuter, HcalDetId::ieta(), HcalDetId::ietaAbs(), HcalDetId::subdet(), DetId::subdetId(), theEBEScale, theEBGrid, theEBthreshold, theEBweight, theEBWeights, theEEEScale, theEEGrid, theEEthreshold, theEEweight, theEEWeights, theHBEScale, theHBGrid, theHBthreshold, theHBweight, theHBWeights, theHcalTopology, theHEDEScale, theHEDGrid, theHEDthreshold, theHEDweight, theHEDWeights, theHESEScale, theHESGrid, theHESthreshold, theHESweight, theHESWeights, theHF1EScale, theHF1Grid, theHF1threshold, theHF1weight, theHF1Weights, theHF2EScale, theHF2Grid, theHF2threshold, theHF2weight, theHF2Weights, theHOEScale, theHOGrid, theHOthreshold0, theHOthresholdMinus1, theHOthresholdMinus2, theHOthresholdPlus1, theHOthresholdPlus2, theHOweight, and theHOWeights.

Referenced by assignHitEcal(), assignHitHcal(), rescale(), and rescaleTowers().

                                                                                                                  {
   DetId::Detector det = detId.det();
   weight=0; // in case the hit is not identified
 
   if(det == DetId::Ecal) {
     // may or may not be EB.  We'll find out.
 
     EcalSubdetector subdet = (EcalSubdetector)(detId.subdetId());
     if(subdet == EcalBarrel) {
       threshold = theEBthreshold;
       weight = theEBweight;
       if (weight <= 0.) {
         ROOT::Math::Interpolator my(theEBGrid,theEBWeights,ROOT::Math::Interpolation::kAKIMA);
         weight = my.Eval(theEBEScale);
       }
     }
     else if(subdet == EcalEndcap) {
       threshold = theEEthreshold;
       weight = theEEweight;
       if (weight <= 0.) {
         ROOT::Math::Interpolator my(theEEGrid,theEEWeights,ROOT::Math::Interpolation::kAKIMA);
         weight = my.Eval(theEEEScale);
       }
     }
   }
   else if(det == DetId::Hcal) {
     HcalDetId hcalDetId(detId);
     HcalSubdetector subdet = hcalDetId.subdet();
     
     if(subdet == HcalBarrel) {
       threshold = theHBthreshold;
       weight = theHBweight;
       if (weight <= 0.) {
         ROOT::Math::Interpolator my(theHBGrid,theHBWeights,ROOT::Math::Interpolation::kAKIMA);
         weight = my.Eval(theHBEScale);
       }
     }
     
     else if(subdet == HcalEndcap) {
       // check if it's single or double tower
       if(hcalDetId.ietaAbs() < theHcalTopology->firstHEDoublePhiRing()) {
         threshold = theHESthreshold;
         weight = theHESweight;
         if (weight <= 0.) {
           ROOT::Math::Interpolator my(theHESGrid,theHESWeights,ROOT::Math::Interpolation::kAKIMA);
           weight = my.Eval(theHESEScale);
         }
       }
       else {
         threshold = theHEDthreshold;
         weight = theHEDweight;
         if (weight <= 0.) {
           ROOT::Math::Interpolator my(theHEDGrid,theHEDWeights,ROOT::Math::Interpolation::kAKIMA);
           weight = my.Eval(theHEDEScale);
         }
       }
     }
     
     else if(subdet == HcalOuter) {
       //check if it's ring 0 or +1 or +2 or -1 or -2
       if(hcalDetId.ietaAbs() <= 4) threshold = theHOthreshold0;
       else if(hcalDetId.ieta() < 0) {
     // set threshold for ring -1 or -2
     threshold = (hcalDetId.ietaAbs() <= 10) ?  theHOthresholdMinus1 : theHOthresholdMinus2;
       } else {
     // set threshold for ring +1 or +2
     threshold = (hcalDetId.ietaAbs() <= 10) ?  theHOthresholdPlus1 : theHOthresholdPlus2;
       }
       weight = theHOweight;
       if (weight <= 0.) {
         ROOT::Math::Interpolator my(theHOGrid,theHOWeights,ROOT::Math::Interpolation::kAKIMA);
         weight = my.Eval(theHOEScale);
       }
     } 
 
     else if(subdet == HcalForward) {
       if(hcalDetId.depth() == 1) {
         threshold = theHF1threshold;
         weight = theHF1weight;
         if (weight <= 0.) {
           ROOT::Math::Interpolator my(theHF1Grid,theHF1Weights,ROOT::Math::Interpolation::kAKIMA);
           weight = my.Eval(theHF1EScale);
         }
       } else {
         threshold = theHF2threshold;
         weight = theHF2weight;
         if (weight <= 0.) {
           ROOT::Math::Interpolator my(theHF2Grid,theHF2Weights,ROOT::Math::Interpolation::kAKIMA);
           weight = my.Eval(theHF2EScale);
         }
       }
     }
   }
   else {
     edm::LogError("CaloTowersCreationAlgo") << "Bad cell: " << det << std::endl;
   }
 }

GlobalPoint CaloTowersCreationAlgo::hadSegmentShwrPos	(	DetId	detId,
		float	fracDepth
	)

Definition at line 1293 of file CaloTowersCreationAlgo.cc.

References emCrystalShwrPos().

Referenced by hadShwrPos().

                                                                                   {
   // same code as above
   return emCrystalShwrPos(detId, fracDepth);
 }

GlobalPoint CaloTowersCreationAlgo::hadShwPosFromCells	(	DetId	frontCell,
		DetId	backCell,
		float	fracDepth
	)

Definition at line 1387 of file CaloTowersCreationAlgo.cc.

References CaloCellGeometry::getBackPoint(), CaloGeometry::getGeometry(), CaloCellGeometry::getPosition(), point, and theGeometry.

Referenced by hadShwrPos().

                                                                                                            {
 
    // uses the "front" and "back" cells
    // to determine the axis. point set by the predefined depth.
 
     const CaloCellGeometry* frontCellGeometry = theGeometry->getGeometry(DetId(frontCellId));
     const CaloCellGeometry* backCellGeometry  = theGeometry->getGeometry(DetId(backCellId));
 
     GlobalPoint point = frontCellGeometry->getPosition();
     GlobalPoint backPoint = backCellGeometry->getBackPoint();
 
     point += fracDepth * (backPoint - point);
 
     return point;
 }

GlobalPoint CaloTowersCreationAlgo::hadShwrPos	(	const std::vector< std::pair< DetId, float > > &	metaContains,
		float	fracDepth,
		double	hadE
	)

Definition at line 1299 of file CaloTowersCreationAlgo.cc.

References hadSegmentShwrPos(), DetId::Hcal, HcalOuter, AlCaHLTBitMon_ParallelJobs::p, HcalDetId::subdet(), PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().

Referenced by convert().

                                                                              {
                                                   
   // this is based on available RecHits, can lead to different actual depths if
   // hits in multi-depth towers are not all there
   if (hadE<=0) return GlobalPoint(0,0,0);
 
   double hadX = 0.0;
   double hadY = 0.0;
   double hadZ = 0.0;
 
   int nConst = 0;
 
   std::vector<std::pair<DetId,float> >::const_iterator mc_it = metaContains.begin();
   for (; mc_it!=metaContains.end(); ++mc_it) {
     if (mc_it->first.det() != DetId::Hcal) continue;
     // do not use HO for deirection calculations for now
     if (HcalDetId(mc_it->first).subdet() == HcalOuter) continue;
     ++nConst;
 
     GlobalPoint p = hadSegmentShwrPos(mc_it->first, fracDepth);
 
     // longitudinal segmentation: do not weight by energy,
     // get the geometrical position
     hadX += p.x();
     hadY += p.y();
     hadZ += p.z();
   }
 
    return GlobalPoint(hadX/nConst, hadY/nConst, hadZ/nConst);
 }

GlobalPoint CaloTowersCreationAlgo::hadShwrPos	(	CaloTowerDetId	id,
		float	fracDepth
	)

Definition at line 1332 of file CaloTowersCreationAlgo.cc.

References funct::abs(), CaloTowerConstituentsMap::constituentsOf(), CaloTowerTopology::convertCTtoHcal(), HcalDetId::depth(), CaloTowerTopology::firstHFRing(), hadShwPosFromCells(), DetId::Hcal, HcalForward, HcalOuter, i, CaloTowerDetId::ieta(), CaloTowerDetId::ietaAbs(), CaloTowerDetId::iphi(), mps_monitormerge::items, CaloTowerTopology::lastHERing(), point, HcalDetId::subdet(), theHcalPhase, theTowerConstituentsMap, theTowerTopology, and CaloTowerDetId::zside().

                                                                                       {
 
   // set depth using geometry of cells that are associated with the
   // tower (regardless if they have non-zero energies)
 
 //  if (hadE <= 0) return GlobalPoint(0, 0, 0);
 
   if (fracDepth < 0) fracDepth = 0;
   else if (fracDepth > 1) fracDepth = 1;
 
   GlobalPoint point(0,0,0);
 
   int iEta = towerId.ieta();
   int iPhi = towerId.iphi();
 
   HcalDetId frontCellId, backCellId;
 
   if(towerId.ietaAbs() >= theTowerTopology->firstHFRing()){
     // forward, take the geometry for long fibers
     frontCellId = HcalDetId(HcalForward, towerId.zside()*theTowerTopology->convertCTtoHcal(abs(iEta)), iPhi, 1);
     backCellId  = HcalDetId(HcalForward, towerId.zside()*theTowerTopology->convertCTtoHcal(abs(iEta)), iPhi, 1);    
   }
   else {
     //use constituents map
     std::vector<DetId> items = theTowerConstituentsMap->constituentsOf(towerId);
     int frontDepth = 1000;
     int backDepth = -1000;
     for(unsigned i = 0; i < items.size(); i++){
       if(items[i].det()!=DetId::Hcal) continue;
       HcalDetId hid(items[i]);
       if(hid.subdet() == HcalOuter) continue;
       
       if(hid.depth()<frontDepth) { frontCellId = hid; frontDepth = hid.depth(); }
       if(hid.depth()>backDepth) { backCellId = hid; backDepth = hid.depth(); }
     }
     
     //fix for tower 28/29 - no tower 29 at highest depths
     if(towerId.ietaAbs()==theTowerTopology->lastHERing() && (theHcalPhase==0 || theHcalPhase==1)){
       CaloTowerDetId towerId28(towerId.ieta()-towerId.zside(),towerId.iphi());
       std::vector<DetId> items28 = theTowerConstituentsMap->constituentsOf(towerId28);
       for(unsigned i = 0; i < items28.size(); i++){
         if(items28[i].det()!=DetId::Hcal) continue;
         HcalDetId hid(items28[i]);
         if(hid.subdet() == HcalOuter) continue;
         
         if(hid.depth()>backDepth) { backCellId = hid; backDepth = hid.depth(); }
       }
     }
   }
 
   point = hadShwPosFromCells(DetId(frontCellId), DetId(backCellId), fracDepth);
 
   return point;
 }

unsigned int CaloTowersCreationAlgo::hcalChanStatusForCaloTower ( const CaloRecHit * hit )

Definition at line 1579 of file CaloTowersCreationAlgo.cc.

References BadChan, CaloRecHit::detid(), CaloRecHit::flags(), HcalSeverityLevelComputer::getSeverityLevel(), HcalChannelStatus::getValue(), HcalCondObjectContainer< Item >::getValues(), GoodChan, IgnoredChan, ProblematicChan, RecoveredChan, HcalSeverityLevelComputer::recoveredRecHit(), theHcalAcceptSeverityLevel, theHcalAcceptSeverityLevelForRejectedHit, theHcalChStatus, theHcalSevLvlComputer, theRecoveredHcalHitsAreUsed, useRejectedHitsOnly, and useRejectedRecoveredHcalHits.

Referenced by assignHitHcal().

                                                                                      {
 
   const DetId id = hit->detid();
 
   const uint32_t recHitFlag = hit->flags();
   const uint32_t dbStatusFlag = theHcalChStatus->getValues(id)->getValue();
   
   int severityLevel = theHcalSevLvlComputer->getSeverityLevel(id, recHitFlag, dbStatusFlag); 
   bool isRecovered  = theHcalSevLvlComputer->recoveredRecHit(id, recHitFlag);
 
 
   // For use with hits rejected in the default reconstruction
   if (useRejectedHitsOnly) {
     
     if (!isRecovered) {
 
       if (severityLevel <= int(theHcalAcceptSeverityLevel) ||
       severityLevel > int(theHcalAcceptSeverityLevelForRejectedHit)) return CaloTowersCreationAlgo::IgnoredChan;
       // this hit was either already accepted or is worse than 
     }    
     else {
       
       if (theRecoveredHcalHitsAreUsed || !useRejectedRecoveredHcalHits) {
     // skip recovered hits either because they were already used or because there was an explicit instruction
     return CaloTowersCreationAlgo::IgnoredChan;
       }
       else if (useRejectedRecoveredHcalHits) {
     return CaloTowersCreationAlgo::RecoveredChan;
       }  
   
     }  // recovered channels
 
     // clasify channels as problematic: no good hits are supposed to be present in the
     // extra rechit collections
     return CaloTowersCreationAlgo::ProblematicChan;
 
   }  // treatment of rejected hits
 
 
 
 
   // this is for the regular reconstruction sequence
 
   if (severityLevel == 0) return CaloTowersCreationAlgo::GoodChan;
 
   if (isRecovered) {
     return (theRecoveredHcalHitsAreUsed) ? 
       CaloTowersCreationAlgo::RecoveredChan : CaloTowersCreationAlgo::BadChan;
   }
   else {
     if (severityLevel > int(theHcalAcceptSeverityLevel)) {
       return CaloTowersCreationAlgo::BadChan;
     }
     else {
       return CaloTowersCreationAlgo::ProblematicChan;
     }
   }  
 
 }

void CaloTowersCreationAlgo::makeEcalBadChs ( )

Definition at line 1530 of file CaloTowersCreationAlgo.cc.

References CaloTowerConstituentsMap::constituentsOf(), CaloTowerTopology::detIdFromDenseIndex(), DetId::Ecal, ecalBadChs, spr::find(), EcalSeverityLevelAlgo::severityLevel(), CaloTowerTopology::sizeForDenseIndexing(), theEcalSeveritiesToBeExcluded, theEcalSevLvlAlgo, theTowerConstituentsMap, and theTowerTopology.

Referenced by CaloTowersCreator::produce().

                                             {
 
   // std::cout << "VI making EcalBadChs ";
 
   // for ECAL the number of all bad channels is obtained here -----------------------
   
   for (auto ind=0U; ind<theTowerTopology->sizeForDenseIndexing(); ++ind) {
     
     auto & numBadEcalChan = ecalBadChs[ind];
     numBadEcalChan=0;
     auto id = theTowerTopology->detIdFromDenseIndex(ind);
     
     // this is utterly slow... (can be optmized if really needed)
     
     // get all possible constituents of the tower
     std::vector<DetId> allConstituents = theTowerConstituentsMap->constituentsOf(id);
     
     for (std::vector<DetId>::iterator ac_it=allConstituents.begin(); 
      ac_it!=allConstituents.end(); ++ac_it) {
       
       if (ac_it->det()!=DetId::Ecal) continue;
             
       auto thisEcalSevLvl = theEcalSevLvlAlgo->severityLevel( *ac_it);
       
       // check if the Ecal severity is ok to keep
       std::vector<int>::const_iterator sevit = std::find(theEcalSeveritiesToBeExcluded.begin(),
                              theEcalSeveritiesToBeExcluded.end(),
                              thisEcalSevLvl);
       if (sevit!=theEcalSeveritiesToBeExcluded.end()) {
     ++numBadEcalChan;
       }
      }
 
     // if (0!=numBadEcalChan) std::cout << id << ":" << numBadEcalChan << ", ";
   }
 
   /*
   int tot=0;
   for (auto ind=0U; ind<theTowerTopology->sizeForDenseIndexing(); ++ind) {
     if (ecalBadChs[ind]!=0) ++tot; 
   }
   std::cout << " | " << tot << std::endl;
   */
 
 }

void CaloTowersCreationAlgo::makeHcalDropChMap ( )

Definition at line 1493 of file CaloTowersCreationAlgo.cc.

References HcalDetId::depth(), HcalSeverityLevelComputer::dropChannel(), spr::find(), HcalCondObjectContainer< Item >::getAllChannels(), HcalChannelStatus::getValue(), HcalCondObjectContainer< Item >::getValues(), hcalDropChMap, HcalEndcap, CaloTowerDetId::ieta(), HcalDetId::ietaAbs(), CaloTowerDetId::iphi(), HcalTopology::lastHERing(), mergedDepths, HcalDetId::subdet(), theHcalChStatus, theHcalPhase, theHcalSevLvlComputer, theHcalTopology, theTowerConstituentsMap, CaloTowerConstituentsMap::towerOf(), and CaloTowerDetId::zside().

Referenced by CaloTowersCreator::produce().

                                                {
 
   // This method fills the map of number of dead channels for the calotower,
   // The key of the map is CaloTowerDetId.
   // By definition these channels are not going to be in the RecHit collections.
   hcalDropChMap.clear();
   std::vector<DetId> allChanInStatusCont = theHcalChStatus->getAllChannels();
 
   for (std::vector<DetId>::iterator it = allChanInStatusCont.begin(); it!=allChanInStatusCont.end(); ++it) {
 
      const uint32_t dbStatusFlag = theHcalChStatus->getValues(*it)->getValue();
 
     if (theHcalSevLvlComputer->dropChannel(dbStatusFlag)) {
 
       CaloTowerDetId twrId = theTowerConstituentsMap->towerOf(*it);
       
       hcalDropChMap[twrId] +=1;
       
       HcalDetId hid(*it);
       
       // special case for tower 29: if HCAL hit is in depth 3 add to twr 29 as well
       if (hid.subdet()==HcalEndcap &&
           (theHcalPhase==0 || theHcalPhase==1) && 
           std::find(mergedDepths.begin(), mergedDepths.end(), hid.depth())!=mergedDepths.end() &&
           hid.ietaAbs()==theHcalTopology->lastHERing()-1) {
     
           CaloTowerDetId twrId29(twrId.ieta()+twrId.zside(), twrId.iphi());
           hcalDropChMap[twrId29] +=1;
       }
 
     }
 
   }
 
 }

void CaloTowersCreationAlgo::process ( const HBHERecHitCollection & hbhe )

Definition at line 292 of file CaloTowersCreationAlgo.cc.

References assignHitHcal(), edm::SortedCollection< T, SORT >::begin(), and edm::SortedCollection< T, SORT >::end().

                                                                      { 
   for(HBHERecHitCollection::const_iterator hbheItr = hbhe.begin();
       hbheItr != hbhe.end(); ++hbheItr)
     assignHitHcal(&(*hbheItr));
 }

void CaloTowersCreationAlgo::process ( const HORecHitCollection & ho )

Definition at line 298 of file CaloTowersCreationAlgo.cc.

References assignHitHcal(), edm::SortedCollection< T, SORT >::begin(), and edm::SortedCollection< T, SORT >::end().

                                                                  { 
   for(HORecHitCollection::const_iterator hoItr = ho.begin();
       hoItr != ho.end(); ++hoItr)
     assignHitHcal(&(*hoItr));
 }  

void CaloTowersCreationAlgo::process ( const HFRecHitCollection & hf )

Definition at line 304 of file CaloTowersCreationAlgo.cc.

References assignHitHcal(), edm::SortedCollection< T, SORT >::begin(), and edm::SortedCollection< T, SORT >::end().

                                                                  { 
   for(HFRecHitCollection::const_iterator hfItr = hf.begin();
       hfItr != hf.end(); ++hfItr)  
     assignHitHcal(&(*hfItr));
 }

void CaloTowersCreationAlgo::process ( const EcalRecHitCollection & ecal )

Definition at line 310 of file CaloTowersCreationAlgo.cc.

References assignHitEcal(), edm::SortedCollection< T, SORT >::begin(), and edm::SortedCollection< T, SORT >::end().

                                                                    { 
   for(EcalRecHitCollection::const_iterator ecItr = ec.begin();
       ecItr != ec.end(); ++ecItr)  
     assignHitEcal(&(*ecItr));
 }

void CaloTowersCreationAlgo::process ( const CaloTowerCollection & ctc )

Definition at line 320 of file CaloTowersCreationAlgo.cc.

References edm::SortedCollection< T, SORT >::begin(), edm::SortedCollection< T, SORT >::end(), and rescale().

                                                                    {
   for(CaloTowerCollection::const_iterator ctcItr = ctc.begin();
       ctcItr != ctc.end(); ++ctcItr) { 
     rescale(&(*ctcItr));
     }
 }

void CaloTowersCreationAlgo::rescale ( const CaloTower * ct )

private

Definition at line 769 of file CaloTowersCreationAlgo.cc.

Referenced by process().

                                                          {
   double threshold, weight;
   CaloTowerDetId towerDetId = theTowerConstituentsMap->towerOf(ct->id());
   if (towerDetId.null()) return;
   MetaTower & tower = find(towerDetId);
 
   tower.E_em = 0.;
   tower.E_had = 0.;
   tower.E_outer = 0.;
   for (unsigned int i=0; i<ct->constituentsSize(); i++) {
     DetId detId = ct->constituent(i);
     getThresholdAndWeight(detId, threshold, weight);
     DetId::Detector det = detId.det();
     if(det == DetId::Ecal) {
       tower.E_em = ct->emEnergy()*weight;
     }
     else {
       HcalDetId hcalDetId(detId);
       if(hcalDetId.subdet() == HcalForward) {
         if (hcalDetId.depth()==1) tower.E_em = ct->emEnergy()*weight;
         if (hcalDetId.depth()==2) tower.E_had = ct->hadEnergy()*weight;
       }
       else if(hcalDetId.subdet() == HcalOuter) {
         tower.E_outer = ct->outerEnergy()*weight;
       }
       else {
         tower.E_had = ct->hadEnergy()*weight;
       }
     }
     tower.E = tower.E_had+tower.E_em+tower.E_outer;
 
     // this is to be compliant with the new MetaTower setup
     // used only for the default simple vector assignment
     std::pair<DetId, float> mc(detId, 0);
     tower.metaConstituents.push_back(mc);
   }
 
   // preserve time inforamtion
   tower.emSumTimeTimesE  = ct->ecalTime();
   tower.hadSumTimeTimesE = ct->hcalTime();
   tower.emSumEForTime = 1.0;
   tower.hadSumEForTime = 1.0;
 }

void CaloTowersCreationAlgo::rescaleTowers	(	const CaloTowerCollection &	ctInput,
		CaloTowerCollection &	ctResult
	)

Definition at line 350 of file CaloTowersCreationAlgo.cc.

References CaloTower::addConstituents(), edm::SortedCollection< T, SORT >::begin(), edm::contains(), DetId::det(), DetId::Ecal, edm::SortedCollection< T, SORT >::end(), PV3DBase< T, PVType, FrameType >::eta(), CaloTowerTopology::firstHERing(), CaloTowerTopology::firstHFRing(), getThresholdAndWeight(), DetId::Hcal, HcalOuter, CaloTowerDetId::ietaAbs(), CaloTowerTopology::lastHBRing(), CaloTowerTopology::lastHERing(), CaloTowerTopology::lastHFRing(), CaloTowerTopology::lastHORing(), PV3DBase< T, PVType, FrameType >::phi(), edm::SortedCollection< T, SORT >::push_back(), CaloTower::setCaloTowerStatus(), CaloTower::setEcalTime(), CaloTower::setHcalSubdet(), CaloTower::setHcalTime(), HcalDetId::subdet(), theHF1weight, theHF2weight, theHOIsUsed, theTowerTopology, dtDQMClient_cfg::threshold, and puppiForMET_cff::weight.

Referenced by CaloTowersReCreator::produce().

                                                                                                          {
 
     for (CaloTowerCollection::const_iterator ctcItr = ctc.begin();
       ctcItr != ctc.end(); ++ctcItr) { 
       
       CaloTowerDetId  twrId = ctcItr->id(); 
       double newE_em    = ctcItr->emEnergy();
       double newE_had   = ctcItr->hadEnergy();
       double newE_outer = ctcItr->outerEnergy(); 
 
       double threshold = 0.0; // not used: we do not change thresholds
       double weight    = 1.0;
 
       // HF
       if (ctcItr->ietaAbs()>=theTowerTopology->firstHFRing()) {
         double E_short = 0.5 * newE_had;             // from the definitions for HF
         double E_long  = newE_em + 0.5 * newE_had;   //
         // scale
         E_long  *= theHF1weight;
         E_short *= theHF2weight;
         // convert
         newE_em  = E_long - E_short;
         newE_had = 2.0 * E_short;
       }
 
       else {   // barrel/endcap
 
         // find if its in EB, or EE; determine from first ecal constituent found
         for (unsigned int iConst = 0; iConst < ctcItr->constituentsSize(); ++iConst) {
           DetId constId = ctcItr->constituent(iConst);
           if (constId.det()!=DetId::Ecal) continue;
           getThresholdAndWeight(constId, threshold, weight);
           newE_em *= weight;
           break;
         }
         // HO
         for (unsigned int iConst = 0; iConst < ctcItr->constituentsSize(); ++iConst) {
           DetId constId = ctcItr->constituent(iConst);
           if (constId.det()!=DetId::Hcal) continue;
           if (HcalDetId(constId).subdet()!=HcalOuter) continue;
           getThresholdAndWeight(constId, threshold, weight);
           newE_outer *= weight;
           break;
         }
         // HB/HE
         for (unsigned int iConst = 0; iConst < ctcItr->constituentsSize(); ++iConst) {
           DetId constId = ctcItr->constituent(iConst);
           if (constId.det()!=DetId::Hcal) continue;
           if (HcalDetId(constId).subdet()==HcalOuter) continue;
           getThresholdAndWeight(constId, threshold, weight);
           newE_had *= weight;
           if (ctcItr->ietaAbs()>theTowerTopology->firstHERing()) newE_outer *= weight;
           break;
         }
         
     }   // barrel/endcap region
 
     // now make the new tower
 
     double newE_hadTot = (theHOIsUsed &&  twrId.ietaAbs()<=theTowerTopology->lastHORing())? newE_had+newE_outer : newE_had;
 
     GlobalPoint  emPoint = ctcItr->emPosition(); 
     GlobalPoint hadPoint = ctcItr->emPosition(); 
 
     double f_em  = 1.0/cosh(emPoint.eta());
     double f_had = 1.0/cosh(hadPoint.eta());
 
     CaloTower::PolarLorentzVector towerP4;
 
     if (ctcItr->ietaAbs()<theTowerTopology->firstHFRing()) {
       if (newE_em>0)     towerP4 += CaloTower::PolarLorentzVector(newE_em*f_em,   emPoint.eta(),  emPoint.phi(),  0); 
       if (newE_hadTot>0) towerP4 += CaloTower::PolarLorentzVector(newE_hadTot*f_had, hadPoint.eta(), hadPoint.phi(), 0); 
     }
     else {
       double newE_tot = newE_em + newE_had;
       // for HF we use common point for ecal, hcal shower positions regardless of the method
       if (newE_tot>0) towerP4 += CaloTower::PolarLorentzVector(newE_tot*f_had, hadPoint.eta(), hadPoint.phi(), 0);
     }
 
 
 
     CaloTower rescaledTower(twrId, newE_em, newE_had, newE_outer, -1, -1, towerP4, emPoint, hadPoint);
     // copy the timings, have to convert back to int, 1 unit = 0.01 ns
     rescaledTower.setEcalTime( int(ctcItr->ecalTime()*100.0 + 0.5) );
     rescaledTower.setHcalTime( int(ctcItr->hcalTime()*100.0 + 0.5) );
     //add topology info
     rescaledTower.setHcalSubdet(theTowerTopology->lastHBRing(),
                                 theTowerTopology->lastHERing(),
                                 theTowerTopology->lastHFRing(),
                                 theTowerTopology->lastHORing() );
 
     std::vector<DetId> contains;
     for (unsigned int iConst = 0; iConst < ctcItr->constituentsSize(); ++iConst) {
       contains.push_back(ctcItr->constituent(iConst));
     }
     rescaledTower.addConstituents(contains);
 
     rescaledTower.setCaloTowerStatus(ctcItr->towerStatusWord());
 
     ctcResult.push_back(rescaledTower);
 
     } // end of loop over towers
 
 
 }

void CaloTowersCreationAlgo::setEBEScale ( double scale )

Definition at line 1239 of file CaloTowersCreationAlgo.cc.

References pileupReCalc_HLTpaths::scale, and theEBEScale.

Referenced by CaloTowersReCreator::produce(), and CaloTowersCreator::produce().

                                                     {
   if (scale>0.00001) *&theEBEScale = scale;
   else *&theEBEScale = 50.;
 }

void CaloTowersCreationAlgo::setEbHandle ( const edm::Handle< EcalRecHitCollection > eb )

inline

Definition at line 192 of file CaloTowersCreationAlgo.h.

References theEbHandle.

Referenced by CaloTowersCreator::produce().

192 { theEbHandle = eb; }

CaloTowersCreationAlgo::theEbHandle

edm::Handle< EcalRecHitCollection > theEbHandle

Definition: CaloTowersCreationAlgo.h:352

void CaloTowersCreationAlgo::setEcalChStatusFromDB ( const EcalChannelStatus * s )

inline

Definition at line 115 of file CaloTowersCreationAlgo.h.

References alignCSCRings::s, and theEcalChStatus.

Referenced by CaloTowersCreator::produce().

115 { theEcalChStatus = s; }

CaloTowersCreationAlgo::theEcalChStatus

const EcalChannelStatus * theEcalChStatus

Definition: CaloTowersCreationAlgo.h:283

alignCSCRings.s

list s

Definition: alignCSCRings.py:91

void CaloTowersCreationAlgo::setEcalSeveritiesToBeExcluded ( const std::vector< int > & ecalSev )

inline

Definition at line 159 of file CaloTowersCreationAlgo.h.

References theEcalSeveritiesToBeExcluded.

Referenced by CaloTowersCreator::produce().

159 {theEcalSeveritiesToBeExcluded= ecalSev;}

CaloTowersCreationAlgo::theEcalSeveritiesToBeExcluded

std::vector< int > theEcalSeveritiesToBeExcluded

Definition: CaloTowersCreationAlgo.h:297

void CaloTowersCreationAlgo::SetEcalSeveritiesToBeUsedInBadTowers ( const std::vector< int > & ecalSev )

inline

Definition at line 180 of file CaloTowersCreationAlgo.h.

References theEcalSeveritiesToBeUsedInBadTowers.

Referenced by CaloTowersCreator::produce().

180 {theEcalSeveritiesToBeUsedInBadTowers= ecalSev;}

CaloTowersCreationAlgo::theEcalSeveritiesToBeUsedInBadTowers

std::vector< int > theEcalSeveritiesToBeUsedInBadTowers

Definition: CaloTowersCreationAlgo.h:306

void CaloTowersCreationAlgo::setEcalSevLvlAlgo ( const EcalSeverityLevelAlgo * a )

inline

Definition at line 169 of file CaloTowersCreationAlgo.h.

References a, and theEcalSevLvlAlgo.

Referenced by CaloTowersCreator::produce().

169 { theEcalSevLvlAlgo = a; }

CaloTowersCreationAlgo::theEcalSevLvlAlgo

const EcalSeverityLevelAlgo * theEcalSevLvlAlgo

Definition: CaloTowersCreationAlgo.h:290

a

double a

Definition: hdecay.h:121

void CaloTowersCreationAlgo::setEEEScale ( double scale )

Definition at line 1244 of file CaloTowersCreationAlgo.cc.

References pileupReCalc_HLTpaths::scale, and theEEEScale.

Referenced by CaloTowersReCreator::produce(), and CaloTowersCreator::produce().

                                                     {
   if (scale>0.00001) *&theEEEScale = scale;
   else *&theEEEScale = 50.;
 }

void CaloTowersCreationAlgo::setEeHandle ( const edm::Handle< EcalRecHitCollection > ee )

inline

Definition at line 193 of file CaloTowersCreationAlgo.h.

References theEeHandle.

Referenced by CaloTowersCreator::produce().

193 { theEeHandle = ee; }

CaloTowersCreationAlgo::theEeHandle

edm::Handle< EcalRecHitCollection > theEeHandle

Definition: CaloTowersCreationAlgo.h:353

void CaloTowersCreationAlgo::setGeometry	(	const CaloTowerTopology *	cttopo,
		const CaloTowerConstituentsMap *	ctmap,
		const HcalTopology *	htopo,
		const CaloGeometry *	geo
	)

Definition at line 250 of file CaloTowersCreationAlgo.cc.

References DetId::Calo, HcalTopology::depthBinInformation(), ecalBadChs, HcalTopology::getDepthSegmentation(), CaloGeometry::getSubdetectorGeometry(), HcalEndcap, i, HcalTopology::lastHERing(), mergedDepths, min(), CaloTowerTopology::sizeForDenseIndexing(), CaloTowerDetId::SubdetId, theGeometry, theHcalPhase, theHcalTopology, theTowerConstituentsMap, theTowerGeometry, and theTowerTopology.

Referenced by CaloTowersReCreator::produce(), and CaloTowersCreator::produce().

                                                                                                                                                                    {
   theTowerTopology = cttopo;
   theTowerConstituentsMap = ctmap;
   theHcalTopology = htopo;
   theGeometry = geo;
   theTowerGeometry=geo->getSubdetectorGeometry(DetId::Calo,CaloTowerDetId::SubdetId);
   
   //initialize ecal bad channel map
   ecalBadChs.resize(theTowerTopology->sizeForDenseIndexing(),0);
   
   //store some specific geom info
   
   //which depths of tower 28/29 are merged?
   //the merging starts at layer 5 in phase 0 or phase 1 configurations
   if(theHcalPhase==0 || theHcalPhase==1){
     std::vector<int> tower28depths;
     int ndepths, startdepth;
     theHcalTopology->getDepthSegmentation(theHcalTopology->lastHERing()-1,tower28depths);
     theHcalTopology->depthBinInformation(HcalEndcap,theHcalTopology->lastHERing()-1,ndepths,startdepth);
     
     //keep track of which depths are merged
     //layer 5 = index 6 (layers start at -1)
     std::vector<bool> isMergedDepth(ndepths,true);
     for(int i = 0; i < std::min(6,(int)(tower28depths.size())); i++){
       isMergedDepth[tower28depths[i]-startdepth] = false;
     }
     
     //store true merged depths
     for(int i = 0; i < ndepths; i++){
       if(isMergedDepth[i]) mergedDepths.push_back(i+startdepth);
     }
     
   }
   
 }

void CaloTowersCreationAlgo::setHBEScale ( double scale )

Definition at line 1249 of file CaloTowersCreationAlgo.cc.

References pileupReCalc_HLTpaths::scale, and theHBEScale.

Referenced by CaloTowersReCreator::produce(), and CaloTowersCreator::produce().

                                                     {
   if (scale>0.00001) *&theHBEScale = scale;
   else *&theHBEScale = 50.;
 }

void CaloTowersCreationAlgo::setHcalAcceptSeverityLevel ( unsigned int level )

inline

Definition at line 158 of file CaloTowersCreationAlgo.h.

References testEve_cfg::level, and theHcalAcceptSeverityLevel.

Referenced by CaloTowersCreator::produce().

158 {theHcalAcceptSeverityLevel = level;}

testEve_cfg.level

tuple level

Definition: testEve_cfg.py:34

CaloTowersCreationAlgo::theHcalAcceptSeverityLevel

unsigned int theHcalAcceptSeverityLevel

Definition: CaloTowersCreationAlgo.h:296

void CaloTowersCreationAlgo::setHcalAcceptSeverityLevelForRejectedHit ( unsigned int level )

inline

Definition at line 178 of file CaloTowersCreationAlgo.h.

References testEve_cfg::level, and theHcalAcceptSeverityLevelForRejectedHit.

Referenced by CaloTowersCreator::produce().

178 {theHcalAcceptSeverityLevelForRejectedHit = level;}

testEve_cfg.level

tuple level

Definition: testEve_cfg.py:34

CaloTowersCreationAlgo::theHcalAcceptSeverityLevelForRejectedHit

unsigned int theHcalAcceptSeverityLevelForRejectedHit

Definition: CaloTowersCreationAlgo.h:305

void CaloTowersCreationAlgo::setHcalChStatusFromDB ( const HcalChannelQuality * s )

inline

Definition at line 114 of file CaloTowersCreationAlgo.h.

References alignCSCRings::s, and theHcalChStatus.

Referenced by CaloTowersCreator::produce().

114 { theHcalChStatus = s; }

CaloTowersCreationAlgo::theHcalChStatus

const HcalChannelQuality * theHcalChStatus

Definition: CaloTowersCreationAlgo.h:284

alignCSCRings.s

list s

Definition: alignCSCRings.py:91

void CaloTowersCreationAlgo::setHcalSevLvlComputer ( const HcalSeverityLevelComputer * c )

inline

Definition at line 166 of file CaloTowersCreationAlgo.h.

References EnergyCorrector::c, and theHcalSevLvlComputer.

Referenced by CaloTowersCreator::produce().

166 {theHcalSevLvlComputer = c; };

EnergyCorrector.c

tuple c

Definition: EnergyCorrector.py:43

CaloTowersCreationAlgo::theHcalSevLvlComputer

const HcalSeverityLevelComputer * theHcalSevLvlComputer

Definition: CaloTowersCreationAlgo.h:287

void CaloTowersCreationAlgo::setHEDEScale ( double scale )

Definition at line 1259 of file CaloTowersCreationAlgo.cc.

References pileupReCalc_HLTpaths::scale, and theHEDEScale.

Referenced by CaloTowersReCreator::produce(), and CaloTowersCreator::produce().

                                                      {
   if (scale>0.00001) *&theHEDEScale = scale;
   else *&theHEDEScale = 50.;
 }

void CaloTowersCreationAlgo::setHESEScale ( double scale )

Definition at line 1254 of file CaloTowersCreationAlgo.cc.

References pileupReCalc_HLTpaths::scale, and theHESEScale.

Referenced by CaloTowersReCreator::produce(), and CaloTowersCreator::produce().

                                                      {
   if (scale>0.00001) *&theHESEScale = scale;
   else *&theHESEScale = 50.;
 }

void CaloTowersCreationAlgo::setHF1EScale ( double scale )

Definition at line 1269 of file CaloTowersCreationAlgo.cc.

References pileupReCalc_HLTpaths::scale, and theHF1EScale.

Referenced by CaloTowersReCreator::produce(), and CaloTowersCreator::produce().

                                                      {
   if (scale>0.00001) *&theHF1EScale = scale;
   else *&theHF1EScale = 50.;
 }

void CaloTowersCreationAlgo::setHF2EScale ( double scale )

Definition at line 1274 of file CaloTowersCreationAlgo.cc.

References pileupReCalc_HLTpaths::scale, and theHF2EScale.

Referenced by CaloTowersReCreator::produce(), and CaloTowersCreator::produce().

                                                      {
   if (scale>0.00001) *&theHF2EScale = scale;
   else *&theHF2EScale = 50.;
 }

void CaloTowersCreationAlgo::setHOEScale ( double scale )

Definition at line 1264 of file CaloTowersCreationAlgo.cc.

References pileupReCalc_HLTpaths::scale, and theHOEScale.

Referenced by CaloTowersReCreator::produce(), and CaloTowersCreator::produce().

                                                     {
   if (scale>0.00001) *&theHOEScale = scale;
   else *&theHOEScale = 50.;
 }

void CaloTowersCreationAlgo::setRecoveredEcalHitsAreUsed ( bool flag )

inline

Definition at line 163 of file CaloTowersCreationAlgo.h.

References theRecoveredEcalHitsAreUsed.

Referenced by CaloTowersCreator::produce().

163 {theRecoveredEcalHitsAreUsed = flag; };

CaloTowersCreationAlgo::theRecoveredEcalHitsAreUsed

bool theRecoveredEcalHitsAreUsed

Definition: CaloTowersCreationAlgo.h:300

void CaloTowersCreationAlgo::setRecoveredHcalHitsAreUsed ( bool flag )

inline

Definition at line 162 of file CaloTowersCreationAlgo.h.

References theRecoveredHcalHitsAreUsed.

Referenced by CaloTowersCreator::produce().

162 {theRecoveredHcalHitsAreUsed = flag; };

CaloTowersCreationAlgo::theRecoveredHcalHitsAreUsed

bool theRecoveredHcalHitsAreUsed

Definition: CaloTowersCreationAlgo.h:299

void CaloTowersCreationAlgo::setUseRejectedHitsOnly ( bool flag )

inline

Definition at line 176 of file CaloTowersCreationAlgo.h.

References useRejectedHitsOnly.

Referenced by CaloTowersCreator::produce().

176 { useRejectedHitsOnly = flag; }

CaloTowersCreationAlgo::useRejectedHitsOnly

bool useRejectedHitsOnly

Definition: CaloTowersCreationAlgo.h:304

void CaloTowersCreationAlgo::setUseRejectedRecoveredEcalHits ( bool flag )

inline

Definition at line 184 of file CaloTowersCreationAlgo.h.

References useRejectedRecoveredEcalHits.

Referenced by CaloTowersCreator::produce().

184 {useRejectedRecoveredEcalHits = flag; };

CaloTowersCreationAlgo::useRejectedRecoveredEcalHits

unsigned int useRejectedRecoveredEcalHits

Definition: CaloTowersCreationAlgo.h:310

void CaloTowersCreationAlgo::setUseRejectedRecoveredHcalHits ( bool flag )

inline

Definition at line 183 of file CaloTowersCreationAlgo.h.

References useRejectedRecoveredHcalHits.

Referenced by CaloTowersCreator::produce().

183 {useRejectedRecoveredHcalHits = flag; };

CaloTowersCreationAlgo::useRejectedRecoveredHcalHits

unsigned int useRejectedRecoveredHcalHits

Definition: CaloTowersCreationAlgo.h:309

Member Data Documentation

std::vector<unsigned short> CaloTowersCreationAlgo::ecalBadChs

private

Definition at line 342 of file CaloTowersCreationAlgo.h.

Referenced by convert(), makeEcalBadChs(), and setGeometry().

HcalDropChMap CaloTowersCreationAlgo::hcalDropChMap

private

Definition at line 338 of file CaloTowersCreationAlgo.h.

Referenced by convert(), and makeHcalDropChMap().

std::vector<int> CaloTowersCreationAlgo::mergedDepths

private

Definition at line 356 of file CaloTowersCreationAlgo.h.

Referenced by assignHitHcal(), makeHcalDropChMap(), and setGeometry().

int CaloTowersCreationAlgo::nalgo =-1

Definition at line 52 of file CaloTowersCreationAlgo.h.

double CaloTowersCreationAlgo::theEBEScale

private

Definition at line 268 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight(), and setEBEScale().

std::vector<double> CaloTowersCreationAlgo::theEBGrid

private

Definition at line 256 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

edm::Handle<EcalRecHitCollection> CaloTowersCreationAlgo::theEbHandle

private

Definition at line 352 of file CaloTowersCreationAlgo.h.

Referenced by setEbHandle().

double CaloTowersCreationAlgo::theEBSumThreshold

private

Definition at line 266 of file CaloTowersCreationAlgo.h.

Referenced by convert().

double CaloTowersCreationAlgo::theEBthreshold

private

Definition at line 246 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theEBweight

private

Definition at line 264 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

std::vector<double> CaloTowersCreationAlgo::theEBWeights

private

Definition at line 256 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

const EcalChannelStatus* CaloTowersCreationAlgo::theEcalChStatus

private

Definition at line 283 of file CaloTowersCreationAlgo.h.

Referenced by setEcalChStatusFromDB().

std::vector<int> CaloTowersCreationAlgo::theEcalSeveritiesToBeExcluded

private

Definition at line 297 of file CaloTowersCreationAlgo.h.

Referenced by assignHitEcal(), ecalChanStatusForCaloTower(), makeEcalBadChs(), and setEcalSeveritiesToBeExcluded().

std::vector<int> CaloTowersCreationAlgo::theEcalSeveritiesToBeUsedInBadTowers

private

Definition at line 306 of file CaloTowersCreationAlgo.h.

Referenced by ecalChanStatusForCaloTower(), and SetEcalSeveritiesToBeUsedInBadTowers().

const EcalSeverityLevelAlgo* CaloTowersCreationAlgo::theEcalSevLvlAlgo

private

Definition at line 290 of file CaloTowersCreationAlgo.h.

Referenced by assignHitEcal(), ecalChanStatusForCaloTower(), makeEcalBadChs(), and setEcalSevLvlAlgo().

double CaloTowersCreationAlgo::theEcutTower

private

Definition at line 266 of file CaloTowersCreationAlgo.h.

Referenced by convert().

double CaloTowersCreationAlgo::theEEEScale

private

Definition at line 269 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight(), and setEEEScale().

std::vector<double> CaloTowersCreationAlgo::theEEGrid

private

Definition at line 257 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

edm::Handle<EcalRecHitCollection> CaloTowersCreationAlgo::theEeHandle

private

Definition at line 353 of file CaloTowersCreationAlgo.h.

Referenced by setEeHandle().

double CaloTowersCreationAlgo::theEESumThreshold

private

Definition at line 266 of file CaloTowersCreationAlgo.h.

Referenced by convert().

double CaloTowersCreationAlgo::theEEthreshold

private

Definition at line 246 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theEEweight

private

Definition at line 264 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

std::vector<double> CaloTowersCreationAlgo::theEEWeights

private

Definition at line 257 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

const CaloGeometry* CaloTowersCreationAlgo::theGeometry

private

Definition at line 278 of file CaloTowersCreationAlgo.h.

Referenced by assignHitEcal(), emCrystalShwrPos(), hadShwPosFromCells(), and setGeometry().

double CaloTowersCreationAlgo::theHBEScale

private

Definition at line 270 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight(), and setHBEScale().

std::vector<double> CaloTowersCreationAlgo::theHBGrid

private

Definition at line 258 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHBthreshold

private

Definition at line 253 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHBweight

private

Definition at line 265 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

std::vector<double> CaloTowersCreationAlgo::theHBWeights

private

Definition at line 258 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

unsigned int CaloTowersCreationAlgo::theHcalAcceptSeverityLevel

private

Definition at line 296 of file CaloTowersCreationAlgo.h.

Referenced by hcalChanStatusForCaloTower(), and setHcalAcceptSeverityLevel().

unsigned int CaloTowersCreationAlgo::theHcalAcceptSeverityLevelForRejectedHit

private

Definition at line 305 of file CaloTowersCreationAlgo.h.

Referenced by hcalChanStatusForCaloTower(), and setHcalAcceptSeverityLevelForRejectedHit().

const HcalChannelQuality* CaloTowersCreationAlgo::theHcalChStatus

private

Definition at line 284 of file CaloTowersCreationAlgo.h.

Referenced by hcalChanStatusForCaloTower(), makeHcalDropChMap(), and setHcalChStatusFromDB().

int CaloTowersCreationAlgo::theHcalPhase

private

Definition at line 358 of file CaloTowersCreationAlgo.h.

Referenced by assignHitHcal(), hadShwrPos(), makeHcalDropChMap(), and setGeometry().

const HcalSeverityLevelComputer* CaloTowersCreationAlgo::theHcalSevLvlComputer

private

Definition at line 287 of file CaloTowersCreationAlgo.h.

Referenced by hcalChanStatusForCaloTower(), makeHcalDropChMap(), and setHcalSevLvlComputer().

double CaloTowersCreationAlgo::theHcalThreshold

private

Definition at line 251 of file CaloTowersCreationAlgo.h.

Referenced by convert().

const HcalTopology* CaloTowersCreationAlgo::theHcalTopology

private

Definition at line 277 of file CaloTowersCreationAlgo.h.

Referenced by assignHitHcal(), getThresholdAndWeight(), makeHcalDropChMap(), and setGeometry().

double CaloTowersCreationAlgo::theHEDEScale

private

Definition at line 272 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight(), and setHEDEScale().

std::vector<double> CaloTowersCreationAlgo::theHEDGrid

private

Definition at line 260 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHEDthreshold

private

Definition at line 253 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHEDweight

private

Definition at line 265 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

std::vector<double> CaloTowersCreationAlgo::theHEDWeights

private

Definition at line 260 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHESEScale

private

Definition at line 271 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight(), and setHESEScale().

std::vector<double> CaloTowersCreationAlgo::theHESGrid

private

Definition at line 259 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHESthreshold

private

Definition at line 253 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHESweight

private

Definition at line 265 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

std::vector<double> CaloTowersCreationAlgo::theHESWeights

private

Definition at line 259 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHF1EScale

private

Definition at line 274 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight(), and setHF1EScale().

std::vector<double> CaloTowersCreationAlgo::theHF1Grid

private

Definition at line 262 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHF1threshold

private

Definition at line 255 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHF1weight

private

Definition at line 265 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight(), and rescaleTowers().

std::vector<double> CaloTowersCreationAlgo::theHF1Weights

private

Definition at line 262 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHF2EScale

private

Definition at line 275 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight(), and setHF2EScale().

std::vector<double> CaloTowersCreationAlgo::theHF2Grid

private

Definition at line 263 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHF2threshold

private

Definition at line 255 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHF2weight

private

Definition at line 265 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight(), and rescaleTowers().

std::vector<double> CaloTowersCreationAlgo::theHF2Weights

private

Definition at line 263 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHOEScale

private

Definition at line 273 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight(), and setHOEScale().

std::vector<double> CaloTowersCreationAlgo::theHOGrid

private

Definition at line 261 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

bool CaloTowersCreationAlgo::theHOIsUsed

private

only affects energy and ET calculation. HO is still recorded in the tower

Definition at line 314 of file CaloTowersCreationAlgo.h.

Referenced by assignHitHcal(), convert(), and rescaleTowers().

double CaloTowersCreationAlgo::theHOthreshold0

private

Definition at line 254 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHOthresholdMinus1

private

Definition at line 254 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHOthresholdMinus2

private

Definition at line 255 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHOthresholdPlus1

private

Definition at line 254 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHOthresholdPlus2

private

Definition at line 255 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

double CaloTowersCreationAlgo::theHOweight

private

Definition at line 265 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

std::vector<double> CaloTowersCreationAlgo::theHOWeights

private

Definition at line 261 of file CaloTowersCreationAlgo.h.

Referenced by getThresholdAndWeight().

int CaloTowersCreationAlgo::theMomConstrMethod

private

Definition at line 318 of file CaloTowersCreationAlgo.h.

Referenced by convert().

double CaloTowersCreationAlgo::theMomEBDepth

private

Definition at line 321 of file CaloTowersCreationAlgo.h.

Referenced by convert().

double CaloTowersCreationAlgo::theMomEEDepth

private

Definition at line 322 of file CaloTowersCreationAlgo.h.

Referenced by convert().

double CaloTowersCreationAlgo::theMomHBDepth

private

Definition at line 319 of file CaloTowersCreationAlgo.h.

Referenced by convert().

double CaloTowersCreationAlgo::theMomHEDepth

private

Definition at line 320 of file CaloTowersCreationAlgo.h.

Referenced by convert().

bool CaloTowersCreationAlgo::theRecoveredEcalHitsAreUsed

private

Definition at line 300 of file CaloTowersCreationAlgo.h.

Referenced by ecalChanStatusForCaloTower(), and setRecoveredEcalHitsAreUsed().

bool CaloTowersCreationAlgo::theRecoveredHcalHitsAreUsed

private

Definition at line 299 of file CaloTowersCreationAlgo.h.

Referenced by hcalChanStatusForCaloTower(), and setRecoveredHcalHitsAreUsed().

const CaloTowerConstituentsMap* CaloTowersCreationAlgo::theTowerConstituentsMap

private

Definition at line 279 of file CaloTowersCreationAlgo.h.

Referenced by assignHitEcal(), assignHitHcal(), hadShwrPos(), makeEcalBadChs(), makeHcalDropChMap(), rescale(), and setGeometry().

const CaloSubdetectorGeometry* CaloTowersCreationAlgo::theTowerGeometry

private

Definition at line 280 of file CaloTowersCreationAlgo.h.

Referenced by convert(), and setGeometry().

MetaTowerMap CaloTowersCreationAlgo::theTowerMap

private

Definition at line 332 of file CaloTowersCreationAlgo.h.

Referenced by begin(), find(), and finish().

unsigned int CaloTowersCreationAlgo::theTowerMapSize =0

private

Definition at line 333 of file CaloTowersCreationAlgo.h.

Referenced by begin(), find(), and finish().

const CaloTowerTopology* CaloTowersCreationAlgo::theTowerTopology

private

Definition at line 276 of file CaloTowersCreationAlgo.h.

Referenced by convert(), find(), hadShwrPos(), makeEcalBadChs(), rescaleTowers(), and setGeometry().

bool CaloTowersCreationAlgo::theUseEtEBTresholdFlag

private

Definition at line 247 of file CaloTowersCreationAlgo.h.

Referenced by assignHitEcal().

bool CaloTowersCreationAlgo::theUseEtEETresholdFlag

private

Definition at line 247 of file CaloTowersCreationAlgo.h.

Referenced by assignHitEcal().

bool CaloTowersCreationAlgo::theUseSymEBTresholdFlag

private

Definition at line 248 of file CaloTowersCreationAlgo.h.

Referenced by assignHitEcal().

bool CaloTowersCreationAlgo::theUseSymEETresholdFlag

private

Definition at line 248 of file CaloTowersCreationAlgo.h.

Referenced by assignHitEcal().

bool CaloTowersCreationAlgo::useRejectedHitsOnly

private

Definition at line 304 of file CaloTowersCreationAlgo.h.

Referenced by ecalChanStatusForCaloTower(), hcalChanStatusForCaloTower(), and setUseRejectedHitsOnly().

unsigned int CaloTowersCreationAlgo::useRejectedRecoveredEcalHits

private

Definition at line 310 of file CaloTowersCreationAlgo.h.

Referenced by ecalChanStatusForCaloTower(), and setUseRejectedRecoveredEcalHits().

unsigned int CaloTowersCreationAlgo::useRejectedRecoveredHcalHits

private

Definition at line 309 of file CaloTowersCreationAlgo.h.

Referenced by hcalChanStatusForCaloTower(), and setUseRejectedRecoveredHcalHits().

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