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L1CaloJetProducer Class Reference

#include <L1CaloJetProducer.cc>

Inheritance diagram for L1CaloJetProducer:
edm::stream::EDProducer<>

Classes

class  l1CaloJetObj
 
class  SimpleCaloHit
 
class  simpleL1obj
 

Public Member Functions

 L1CaloJetProducer (const edm::ParameterSet &)
 
- Public Member Functions inherited from edm::stream::EDProducer<>
 EDProducer ()=default
 
 EDProducer (const EDProducer &)=delete
 
bool hasAbilityToProduceInBeginLumis () const final
 
bool hasAbilityToProduceInBeginProcessBlocks () const final
 
bool hasAbilityToProduceInBeginRuns () const final
 
bool hasAbilityToProduceInEndLumis () const final
 
bool hasAbilityToProduceInEndProcessBlocks () const final
 
bool hasAbilityToProduceInEndRuns () const final
 
const EDProduceroperator= (const EDProducer &)=delete
 

Private Member Functions

float get_deltaR (reco::Candidate::PolarLorentzVector &p4_1, reco::Candidate::PolarLorentzVector &p4_2) const
 
float get_hcal_calibration (float &jet_pt, float &ecal_pt, float &ecal_L1EG_jet_pt, float &jet_eta) const
 
float get_tau_pt_calibration (float &tau_pt, float &ecal_pt, float &l1EG_pt, float &n_L1EGs, float &tau_eta) const
 
int loose_iso_tau_wp (float &tau_pt, float &tau_iso_et, float &tau_eta) const
 
void produce (edm::Event &, const edm::EventSetup &) override
 
int tower_diEta (int &iEta_1, int &iEta_2) const
 
int tower_diPhi (int &iPhi_1, int &iPhi_2) const
 

Private Attributes

std::vector< double > absEtaBinsBarrel
 
std::vector< double > absEtaBinsHF
 
std::vector< double > absEtaBinsHGCal
 
std::vector< std::vector< std::vector< double > > > calibrationsBarrel
 
std::vector< std::vector< std::vector< double > > > calibrationsHF
 
std::vector< std::vector< std::vector< double > > > calibrationsHGCal
 
bool debug
 
double EcalTpEtMin
 
std::vector< double > emFractionBinsBarrel
 
std::vector< double > emFractionBinsHF
 
std::vector< double > emFractionBinsHGCal
 
double EtMinForCollection
 
double EtMinForSeedHit
 
double EtMinForTauCollection
 
double HcalTpEtMin
 
double HFTpEtMin
 
double HGCalEmTpEtMin
 
double HGCalHadTpEtMin
 
TF1 isoTauBarrel = TF1("isoTauBarrelFunction", "([0] + [1]*TMath::Exp(-[2]*x))")
 
TF1 isoTauHGCal = TF1("isoTauHGCalFunction", "([0] + [1]*TMath::Exp(-[2]*x))")
 
std::vector< double > jetCalibrationsBarrel
 
std::vector< double > jetCalibrationsHF
 
std::vector< double > jetCalibrationsHGCal
 
std::vector< double > jetPtBins
 
edm::Handle< l1tp2::CaloTowerCollectionl1CaloTowerHandle
 
edm::EDGetTokenT< l1tp2::CaloTowerCollectionl1TowerToken_
 
std::vector< double > tauAbsEtaBinsBarrel
 
std::vector< double > tauAbsEtaBinsHGCal
 
std::vector< double > tauCalibrationsBarrel
 
std::vector< double > tauCalibrationsHGCal
 
std::vector< edm::ParameterSettauL1egInfoBarrel
 
std::vector< edm::ParameterSettauL1egInfoHGCal
 
std::map< double, std::vector< double > > tauL1egInfoMapBarrel
 
std::map< double, std::vector< double > > tauL1egInfoMapHGCal
 
std::vector< double > tauL1egValuesBarrel
 
std::vector< double > tauL1egValuesHGCal
 
std::vector< double > tauPtBins
 
std::vector< std::vector< std::vector< std::vector< double > > > > tauPtCalibrationsBarrel
 
std::vector< std::vector< std::vector< std::vector< double > > > > tauPtCalibrationsHGCal
 

Additional Inherited Members

- Public Types inherited from edm::stream::EDProducer<>
using CacheTypes = CacheContexts< T... >
 
using GlobalCache = typename CacheTypes::GlobalCache
 
using HasAbility = AbilityChecker< T... >
 
using InputProcessBlockCache = typename CacheTypes::InputProcessBlockCache
 
using LuminosityBlockCache = typename CacheTypes::LuminosityBlockCache
 
using LuminosityBlockContext = LuminosityBlockContextT< LuminosityBlockCache, RunCache, GlobalCache >
 
using LuminosityBlockSummaryCache = typename CacheTypes::LuminosityBlockSummaryCache
 
using RunCache = typename CacheTypes::RunCache
 
using RunContext = RunContextT< RunCache, GlobalCache >
 
using RunSummaryCache = typename CacheTypes::RunSummaryCache
 

Detailed Description

Description: Beginning with HCAL TPs, create HCAL jet, then take L1EG crystal clusters from L1EGammaCrystalsProducer.cc and clusters them within fixed number of trigger towers

Implementation: [Notes on implementation]

Definition at line 55 of file L1CaloJetProducer.cc.

Constructor & Destructor Documentation

◆ L1CaloJetProducer()

L1CaloJetProducer::L1CaloJetProducer ( const edm::ParameterSet iConfig)
explicit

Definition at line 308 of file L1CaloJetProducer.cc.

References absEtaBinsBarrel, absEtaBinsHF, absEtaBinsHGCal, calibrationsBarrel, calibrationsHF, calibrationsHGCal, debug, EcalTpEtMin, emFractionBinsBarrel, emFractionBinsHF, emFractionBinsHGCal, first, HcalTpEtMin, createfilelist::int, isoTauBarrel, isoTauHGCal, jetCalibrationsBarrel, jetCalibrationsHF, jetCalibrationsHGCal, jetPtBins, L1CaloJetProducer_cfi::l1egCount, L1CaloJetProducer_cfi::l1egEmFractions, LogDebug, DiDispStaMuonMonitor_cfi::pt, jetUpdater_cfi::sort, tauAbsEtaBinsBarrel, tauAbsEtaBinsHGCal, tauCalibrationsBarrel, tauCalibrationsHGCal, tauL1egInfoBarrel, tauL1egInfoHGCal, tauL1egInfoMapBarrel, tauL1egInfoMapHGCal, tauL1egValuesBarrel, tauL1egValuesHGCal, tauPtBins, tauPtCalibrationsBarrel, and tauPtCalibrationsHGCal.

309  : HcalTpEtMin(iConfig.getParameter<double>("HcalTpEtMin")), // Should default to 0 MeV
310  EcalTpEtMin(iConfig.getParameter<double>("EcalTpEtMin")), // Should default to 0 MeV
311  HGCalHadTpEtMin(iConfig.getParameter<double>("HGCalHadTpEtMin")), // Should default to 0 MeV
312  HGCalEmTpEtMin(iConfig.getParameter<double>("HGCalEmTpEtMin")), // Should default to 0 MeV
313  HFTpEtMin(iConfig.getParameter<double>("HFTpEtMin")), // Should default to 0 MeV
314  EtMinForSeedHit(iConfig.getParameter<double>("EtMinForSeedHit")), // Should default to 2.5 GeV
315  EtMinForCollection(iConfig.getParameter<double>("EtMinForCollection")), // Testing 10 GeV
316  EtMinForTauCollection(iConfig.getParameter<double>("EtMinForTauCollection")), // Testing 10 GeV
317  jetPtBins(iConfig.getParameter<std::vector<double>>("jetPtBins")),
318  emFractionBinsBarrel(iConfig.getParameter<std::vector<double>>("emFractionBinsBarrel")),
319  absEtaBinsBarrel(iConfig.getParameter<std::vector<double>>("absEtaBinsBarrel")),
320  jetCalibrationsBarrel(iConfig.getParameter<std::vector<double>>("jetCalibrationsBarrel")),
321  emFractionBinsHGCal(iConfig.getParameter<std::vector<double>>("emFractionBinsHGCal")),
322  absEtaBinsHGCal(iConfig.getParameter<std::vector<double>>("absEtaBinsHGCal")),
323  jetCalibrationsHGCal(iConfig.getParameter<std::vector<double>>("jetCalibrationsHGCal")),
324  emFractionBinsHF(iConfig.getParameter<std::vector<double>>("emFractionBinsHF")),
325  absEtaBinsHF(iConfig.getParameter<std::vector<double>>("absEtaBinsHF")),
326  jetCalibrationsHF(iConfig.getParameter<std::vector<double>>("jetCalibrationsHF")),
327  tauPtBins(iConfig.getParameter<std::vector<double>>("tauPtBins")),
328  tauAbsEtaBinsBarrel(iConfig.getParameter<std::vector<double>>("tauAbsEtaBinsBarrel")),
329  tauCalibrationsBarrel(iConfig.getParameter<std::vector<double>>("tauCalibrationsBarrel")),
330  tauL1egInfoBarrel(iConfig.getParameter<std::vector<edm::ParameterSet>>("tauL1egInfoBarrel")),
331  tauAbsEtaBinsHGCal(iConfig.getParameter<std::vector<double>>("tauAbsEtaBinsHGCal")),
332  tauCalibrationsHGCal(iConfig.getParameter<std::vector<double>>("tauCalibrationsHGCal")),
333  tauL1egInfoHGCal(iConfig.getParameter<std::vector<edm::ParameterSet>>("tauL1egInfoHGCal")),
334  debug(iConfig.getParameter<bool>("debug")),
335  l1TowerToken_(consumes<l1tp2::CaloTowerCollection>(iConfig.getParameter<edm::InputTag>("l1CaloTowers")))
336 
337 {
338  produces<l1tp2::CaloJetsCollection>("L1CaloJetsNoCuts");
339  //produces<l1tp2::CaloJetsCollection>("L1CaloJetsWithCuts");
340  //produces<l1extra::L1JetParticleCollection>("L1CaloClusterCollectionWithCuts");
341  produces<BXVector<l1t::Jet>>("L1CaloJetCollectionBXV");
342  produces<BXVector<l1t::Tau>>("L1CaloTauCollectionBXV");
343 
344  if (debug) {
345  LogDebug("L1CaloJetProducer") << " HcalTpEtMin = " << HcalTpEtMin << " EcalTpEtMin = " << EcalTpEtMin << "\n";
346  }
347 
348  // Fill the calibration 3D vector
349  // Dimension 1 is AbsEta bin
350  // Dimension 2 is EM Fraction bin
351  // Dimension 3 is jet pT bin which is filled with the actual callibration value
352  // size()-1 b/c the inputs have lower and upper bounds
353  // Do Barrel, then HGCal, then HF
354  int index = 0;
355  //calibrations[em_frac][abs_eta].push_back( jetCalibrationsBarrel.at(index) );
356  for (unsigned int abs_eta = 0; abs_eta < absEtaBinsBarrel.size() - 1; abs_eta++) {
357  std::vector<std::vector<double>> em_bins;
358  for (unsigned int em_frac = 0; em_frac < emFractionBinsBarrel.size() - 1; em_frac++) {
359  std::vector<double> pt_bin_calibs;
360  for (unsigned int pt = 0; pt < jetPtBins.size() - 1; pt++) {
361  pt_bin_calibs.push_back(jetCalibrationsBarrel.at(index));
362  index++;
363  }
364  em_bins.push_back(pt_bin_calibs);
365  }
366  calibrationsBarrel.push_back(em_bins);
367  }
368  if (debug) {
369  LogDebug("L1CaloJetProducer") << " Loading Barrel calibrations: Loaded " << index
370  << " values vs. size() of input calibration file: "
371  << int(jetCalibrationsBarrel.size()) << "\n";
372  }
373 
374  index = 0;
375  //calibrations[em_frac][abs_eta].push_back( jetCalibrationsHGCal.at(index) );
376  for (unsigned int abs_eta = 0; abs_eta < absEtaBinsHGCal.size() - 1; abs_eta++) {
377  std::vector<std::vector<double>> em_bins;
378  for (unsigned int em_frac = 0; em_frac < emFractionBinsHGCal.size() - 1; em_frac++) {
379  std::vector<double> pt_bin_calibs;
380  for (unsigned int pt = 0; pt < jetPtBins.size() - 1; pt++) {
381  pt_bin_calibs.push_back(jetCalibrationsHGCal.at(index));
382  index++;
383  }
384  em_bins.push_back(pt_bin_calibs);
385  }
386  calibrationsHGCal.push_back(em_bins);
387  }
388  if (debug) {
389  LogDebug("L1CaloJetProducer") << " Loading HGCal calibrations: Loaded " << index
390  << " values vs. size() of input calibration file: "
391  << int(jetCalibrationsHGCal.size()) << "\n";
392  }
393 
394  index = 0;
395  //calibrations[em_frac][abs_eta].push_back( jetCalibrationsHF.at(index) );
396  for (unsigned int abs_eta = 0; abs_eta < absEtaBinsHF.size() - 1; abs_eta++) {
397  std::vector<std::vector<double>> em_bins;
398  for (unsigned int em_frac = 0; em_frac < emFractionBinsHF.size() - 1; em_frac++) {
399  std::vector<double> pt_bin_calibs;
400  for (unsigned int pt = 0; pt < jetPtBins.size() - 1; pt++) {
401  pt_bin_calibs.push_back(jetCalibrationsHF.at(index));
402  index++;
403  }
404  em_bins.push_back(pt_bin_calibs);
405  }
406  calibrationsHF.push_back(em_bins);
407  }
408  if (debug) {
409  LogDebug("L1CaloJetProducer") << " Loading HF calibrations: Loaded " << index
410  << " values vs. size() of input calibration file: " << int(jetCalibrationsHF.size())
411  << "\n";
412  }
413 
414  // Load Tau L1EG-base calibration info into maps
415  for (auto &first : tauL1egInfoBarrel) {
416  if (debug) {
417  LogDebug("L1CaloJetProducer") << " barrel l1egCount = " << first.getParameter<double>("l1egCount") << "\n";
418  for (auto &em_frac : first.getParameter<std::vector<double>>("l1egEmFractions")) {
419  LogDebug("L1CaloJetProducer") << " - EM = " << em_frac << "\n";
420  }
421  }
422  double l1egCount = first.getParameter<double>("l1egCount");
423  std::vector<double> l1egEmFractions = first.getParameter<std::vector<double>>("l1egEmFractions");
425  tauL1egValuesBarrel.push_back(l1egCount);
426  }
428  for (auto &first : tauL1egInfoHGCal) {
429  if (debug) {
430  LogDebug("L1CaloJetProducer") << " hgcal l1egCount = " << first.getParameter<double>("l1egCount") << "\n";
431  for (auto &em_frac : first.getParameter<std::vector<double>>("l1egEmFractions")) {
432  LogDebug("L1CaloJetProducer") << " - EM = " << em_frac << "\n";
433  }
434  }
435  double l1egCount = first.getParameter<double>("l1egCount");
436  std::vector<double> l1egEmFractions = first.getParameter<std::vector<double>>("l1egEmFractions");
438  tauL1egValuesHGCal.push_back(l1egCount);
439  }
441  // Fill the calibration 4D vector
442  // Dimension 1 is AbsEta bin
443  // Dimension 2 is L1EG count
444  // Dimension 3 is EM Fraction bin
445  // Dimension 4 is tau pT bin which is filled with the actual callibration value
446  // size()-1 b/c the inputs have lower and upper bounds (except L1EG b/c that is a cound)
447  // Do Barrel, then HGCal
448  //
449  // Note to future developers: be very concious of the order in which the calibrations are printed
450  // out in tool which makse the cfg files. You need to match that exactly when loading them and
451  // using the calibrations below.
452  index = 0;
453  for (unsigned int abs_eta = 0; abs_eta < tauAbsEtaBinsBarrel.size() - 1; abs_eta++) {
454  std::vector<std::vector<std::vector<double>>> l1eg_bins;
455  for (auto &l1eg_info : tauL1egInfoMapBarrel) {
456  std::vector<std::vector<double>> em_bins;
457  for (unsigned int em_frac = 0; em_frac < l1eg_info.second.size() - 1; em_frac++) {
458  std::vector<double> pt_bin_calibs;
459  for (unsigned int pt = 0; pt < tauPtBins.size() - 1; pt++) {
460  pt_bin_calibs.push_back(tauCalibrationsBarrel.at(index));
461  index++;
462  }
463  em_bins.push_back(pt_bin_calibs);
464  }
465  l1eg_bins.push_back(em_bins);
466  }
467  tauPtCalibrationsBarrel.push_back(l1eg_bins);
468  }
469  if (debug) {
470  LogDebug("L1CaloJetProducer") << " Loading Barrel calibrations: Loaded " << index
471  << " values vs. size() of input calibration file: "
472  << int(tauCalibrationsBarrel.size()) << "\n";
473  }
474 
475  index = 0;
476  for (unsigned int abs_eta = 0; abs_eta < tauAbsEtaBinsHGCal.size() - 1; abs_eta++) {
477  std::vector<std::vector<std::vector<double>>> l1eg_bins;
478  for (const auto &l1eg_info : tauL1egInfoMapHGCal) {
479  std::vector<std::vector<double>> em_bins;
480  for (unsigned int em_frac = 0; em_frac < l1eg_info.second.size() - 1; em_frac++) {
481  std::vector<double> pt_bin_calibs;
482  for (unsigned int pt = 0; pt < tauPtBins.size() - 1; pt++) {
483  pt_bin_calibs.push_back(tauCalibrationsHGCal.at(index));
484  index++;
485  }
486  em_bins.push_back(pt_bin_calibs);
487  }
488  l1eg_bins.push_back(em_bins);
489  }
490  tauPtCalibrationsHGCal.push_back(l1eg_bins);
491  }
492  if (debug) {
493  LogDebug("L1CaloJetProducer") << " Loading HGCal calibrations: Loaded " << index
494  << " values vs. size() of input calibration file: "
495  << int(tauCalibrationsHGCal.size()) << "\n";
496  }
497 
498  isoTauBarrel.SetParameter(0, 0.30);
499  isoTauBarrel.SetParameter(1, 0.31);
500  isoTauBarrel.SetParameter(2, 0.040);
501  isoTauHGCal.SetParameter(0, 0.34);
502  isoTauHGCal.SetParameter(1, 0.35);
503  isoTauHGCal.SetParameter(2, 0.051);
504 }
std::vector< double > tauAbsEtaBinsBarrel
T getParameter(std::string const &) const
Definition: ParameterSet.h:307
std::map< double, std::vector< double > > tauL1egInfoMapBarrel
std::vector< double > absEtaBinsHF
std::vector< double > jetCalibrationsHF
std::vector< double > jetCalibrationsBarrel
edm::EDGetTokenT< l1tp2::CaloTowerCollection > l1TowerToken_
std::vector< double > emFractionBinsHGCal
std::vector< std::vector< std::vector< double > > > calibrationsBarrel
std::vector< double > tauAbsEtaBinsHGCal
std::vector< double > emFractionBinsHF
std::vector< double > emFractionBinsBarrel
std::vector< double > tauCalibrationsBarrel
std::vector< std::vector< std::vector< double > > > calibrationsHF
std::vector< std::vector< std::vector< std::vector< double > > > > tauPtCalibrationsHGCal
std::vector< double > jetPtBins
std::vector< double > tauL1egValuesBarrel
std::vector< std::vector< std::vector< std::vector< double > > > > tauPtCalibrationsBarrel
std::vector< edm::ParameterSet > tauL1egInfoHGCal
std::vector< double > tauPtBins
std::vector< double > absEtaBinsBarrel
std::vector< edm::ParameterSet > tauL1egInfoBarrel
std::vector< double > absEtaBinsHGCal
std::vector< std::vector< std::vector< double > > > calibrationsHGCal
std::vector< double > jetCalibrationsHGCal
std::map< double, std::vector< double > > tauL1egInfoMapHGCal
std::vector< double > tauCalibrationsHGCal
std::vector< double > tauL1egValuesHGCal
#define LogDebug(id)

Member Function Documentation

◆ get_deltaR()

float L1CaloJetProducer::get_deltaR ( reco::Candidate::PolarLorentzVector p4_1,
reco::Candidate::PolarLorentzVector p4_2 
) const
private

Definition at line 1132 of file L1CaloJetProducer.cc.

References reco::deltaR().

1133  {
1134  // Check that pt is > 0 for both or else reco::deltaR returns bogus values
1135  if (p4_1.pt() > 0 && p4_2.pt() > 0) {
1136  return reco::deltaR(p4_1, p4_2);
1137  } else
1138  return -1;
1139 }
constexpr auto deltaR(const T1 &t1, const T2 &t2) -> decltype(t1.eta())
Definition: deltaR.h:30

◆ get_hcal_calibration()

float L1CaloJetProducer::get_hcal_calibration ( float &  jet_pt,
float &  ecal_pt,
float &  ecal_L1EG_jet_pt,
float &  jet_eta 
) const
private

Definition at line 1142 of file L1CaloJetProducer.cc.

References funct::abs(), absEtaBinsBarrel, absEtaBinsHF, absEtaBinsHGCal, L1EGammaClusterEmuProducer_cfi::calib, calibrationsBarrel, calibrationsHF, calibrationsHGCal, emFractionBinsBarrel, emFractionBinsHF, emFractionBinsHGCal, mps_fire::i, and jetPtBins.

Referenced by produce().

1145  {
1146  float em_frac = (ecal_L1EG_jet_pt + ecal_pt) / jet_pt;
1147  float abs_eta = std::abs(jet_eta);
1148  float tmp_jet_pt = jet_pt;
1149  if (tmp_jet_pt > 499)
1150  tmp_jet_pt = 499;
1151 
1152  // Different indices sizes in different calo regions.
1153  // Barrel...
1154  size_t em_index = 0;
1155  size_t eta_index = 0;
1156  size_t pt_index = 0;
1157  float calib = 1.0;
1158  if (abs_eta <= 1.5) {
1159  // Start loop checking 2nd value
1160  for (unsigned int i = 1; i < emFractionBinsBarrel.size(); i++) {
1161  if (em_frac <= emFractionBinsBarrel.at(i))
1162  break;
1163  em_index++;
1164  }
1165 
1166  // Start loop checking 2nd value
1167  for (unsigned int i = 1; i < absEtaBinsBarrel.size(); i++) {
1168  if (abs_eta <= absEtaBinsBarrel.at(i))
1169  break;
1170  eta_index++;
1171  }
1172 
1173  // Start loop checking 2nd value
1174  for (unsigned int i = 1; i < jetPtBins.size(); i++) {
1175  if (tmp_jet_pt <= jetPtBins.at(i))
1176  break;
1177  pt_index++;
1178  }
1179  calib = calibrationsBarrel[eta_index][em_index][pt_index];
1180  } // end Barrel
1181  else if (abs_eta <= 3.0) // HGCal
1182  {
1183  // Start loop checking 2nd value
1184  for (unsigned int i = 1; i < emFractionBinsHGCal.size(); i++) {
1185  if (em_frac <= emFractionBinsHGCal.at(i))
1186  break;
1187  em_index++;
1188  }
1189 
1190  // Start loop checking 2nd value
1191  for (unsigned int i = 1; i < absEtaBinsHGCal.size(); i++) {
1192  if (abs_eta <= absEtaBinsHGCal.at(i))
1193  break;
1194  eta_index++;
1195  }
1196 
1197  // Start loop checking 2nd value
1198  for (unsigned int i = 1; i < jetPtBins.size(); i++) {
1199  if (tmp_jet_pt <= jetPtBins.at(i))
1200  break;
1201  pt_index++;
1202  }
1203  calib = calibrationsHGCal[eta_index][em_index][pt_index];
1204  } // end HGCal
1205  else // HF
1206  {
1207  // Start loop checking 2nd value
1208  for (unsigned int i = 1; i < emFractionBinsHF.size(); i++) {
1209  if (em_frac <= emFractionBinsHF.at(i))
1210  break;
1211  em_index++;
1212  }
1213 
1214  // Start loop checking 2nd value
1215  for (unsigned int i = 1; i < absEtaBinsHF.size(); i++) {
1216  if (abs_eta <= absEtaBinsHF.at(i))
1217  break;
1218  eta_index++;
1219  }
1220 
1221  // Start loop checking 2nd value
1222  for (unsigned int i = 1; i < jetPtBins.size(); i++) {
1223  if (tmp_jet_pt <= jetPtBins.at(i))
1224  break;
1225  pt_index++;
1226  }
1227  calib = calibrationsHF[eta_index][em_index][pt_index];
1228  } // end HF
1229 
1230  return calib;
1231 }
std::vector< double > absEtaBinsHF
std::vector< double > emFractionBinsHGCal
std::vector< std::vector< std::vector< double > > > calibrationsBarrel
std::vector< double > emFractionBinsHF
std::vector< double > emFractionBinsBarrel
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
std::vector< std::vector< std::vector< double > > > calibrationsHF
std::vector< double > jetPtBins
std::vector< double > absEtaBinsBarrel
std::vector< double > absEtaBinsHGCal
std::vector< std::vector< std::vector< double > > > calibrationsHGCal

◆ get_tau_pt_calibration()

float L1CaloJetProducer::get_tau_pt_calibration ( float &  tau_pt,
float &  ecal_pt,
float &  l1EG_pt,
float &  n_L1EGs,
float &  tau_eta 
) const
private

Definition at line 1234 of file L1CaloJetProducer.cc.

References funct::abs(), L1EGammaClusterEmuProducer_cfi::calib, mps_fire::i, runTauDisplay::tau_eta, runTauDisplay::tau_pt, tauAbsEtaBinsBarrel, tauAbsEtaBinsHGCal, tauL1egInfoMapBarrel, tauL1egInfoMapHGCal, tauL1egValuesBarrel, tauL1egValuesHGCal, tauPtBins, tauPtCalibrationsBarrel, and tauPtCalibrationsHGCal.

Referenced by produce().

1235  {
1236  float em_frac = (l1EG_pt + ecal_pt) / tau_pt;
1237  float abs_eta = std::abs(tau_eta);
1238  float tmp_tau_pt = tau_pt;
1239  if (tmp_tau_pt > 199)
1240  tmp_tau_pt = 199;
1241 
1242  // Different indices sizes in different calo regions.
1243  // Barrel...
1244  size_t em_index = 0;
1245  size_t eta_index = 0;
1246  size_t n_L1EG_index = 0;
1247  size_t pt_index = 0;
1248  float calib = 1.0;
1249  // HERE
1250  if (abs_eta <= 1.5) {
1251  // Start loop checking 1st value
1252  for (unsigned int i = 0; i < tauL1egValuesBarrel.size(); i++) {
1253  if (n_L1EGs == tauL1egValuesBarrel.at(i))
1254  break;
1255  if (tauL1egValuesBarrel.at(i) == tauL1egValuesBarrel.back())
1256  break; // to preven incrementing on last one
1257  n_L1EG_index++;
1258  }
1259 
1260  // Find key value pair matching n L1EGs
1261  for (auto &l1eg_info : tauL1egInfoMapBarrel) {
1262  if (l1eg_info.first != double(n_L1EG_index))
1263  continue;
1264  // Start loop checking 2nd value
1265  for (unsigned int i = 1; i < l1eg_info.second.size(); i++) {
1266  if (em_frac <= l1eg_info.second.at(i))
1267  break;
1268  em_index++;
1269  }
1270  }
1271 
1272  // Start loop checking 2nd value
1273  for (unsigned int i = 1; i < tauAbsEtaBinsBarrel.size(); i++) {
1274  if (abs_eta <= tauAbsEtaBinsBarrel.at(i))
1275  break;
1276  eta_index++;
1277  }
1278 
1279  // Start loop checking 2nd value
1280  for (unsigned int i = 1; i < tauPtBins.size(); i++) {
1281  if (tmp_tau_pt <= tauPtBins.at(i))
1282  break;
1283  pt_index++;
1284  }
1285  calib = tauPtCalibrationsBarrel[eta_index][n_L1EG_index][em_index][pt_index];
1286  } // end Barrel
1287  else if (abs_eta <= 3.0) // HGCal
1288  {
1289  // Start loop checking 1st value
1290  for (unsigned int i = 0; i < tauL1egValuesHGCal.size(); i++) {
1291  if (n_L1EGs == tauL1egValuesHGCal.at(i))
1292  break;
1293  if (tauL1egValuesHGCal.at(i) == tauL1egValuesHGCal.back())
1294  break; // to preven incrementing on last one
1295  n_L1EG_index++;
1296  }
1297 
1298  // Find key value pair matching n L1EGs
1299  for (auto &l1eg_info : tauL1egInfoMapHGCal) {
1300  if (l1eg_info.first != double(n_L1EG_index))
1301  continue;
1302  // Start loop checking 2nd value
1303  for (unsigned int i = 1; i < l1eg_info.second.size(); i++) {
1304  if (em_frac <= l1eg_info.second.at(i))
1305  break;
1306  em_index++;
1307  }
1308  }
1309 
1310  // Start loop checking 2nd value
1311  for (unsigned int i = 1; i < tauAbsEtaBinsHGCal.size(); i++) {
1312  if (abs_eta <= tauAbsEtaBinsHGCal.at(i))
1313  break;
1314  eta_index++;
1315  }
1316 
1317  // Start loop checking 2nd value
1318  for (unsigned int i = 1; i < tauPtBins.size(); i++) {
1319  if (tmp_tau_pt <= tauPtBins.at(i))
1320  break;
1321  pt_index++;
1322  }
1323  calib = tauPtCalibrationsHGCal[eta_index][n_L1EG_index][em_index][pt_index];
1324  } // end HGCal
1325  else
1326  return calib;
1327 
1328  return calib;
1329 }
std::vector< double > tauAbsEtaBinsBarrel
std::map< double, std::vector< double > > tauL1egInfoMapBarrel
std::vector< double > tauAbsEtaBinsHGCal
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
std::vector< std::vector< std::vector< std::vector< double > > > > tauPtCalibrationsHGCal
std::vector< double > tauL1egValuesBarrel
std::vector< std::vector< std::vector< std::vector< double > > > > tauPtCalibrationsBarrel
std::vector< double > tauPtBins
std::map< double, std::vector< double > > tauL1egInfoMapHGCal
std::vector< double > tauL1egValuesHGCal

◆ loose_iso_tau_wp()

int L1CaloJetProducer::loose_iso_tau_wp ( float &  tau_pt,
float &  tau_iso_et,
float &  tau_eta 
) const
private

Definition at line 1332 of file L1CaloJetProducer.cc.

References funct::abs(), isoTauBarrel, isoTauHGCal, runTauDisplay::tau_eta, and runTauDisplay::tau_pt.

Referenced by produce().

1332  {
1333  // Fully relaxed above 100 GeV pT
1334  if (tau_pt > 100) {
1335  return 1;
1336  }
1337  // Split by barrel and HGCal
1338  // with Barrel first
1339  if (std::abs(tau_eta) < 1.5) {
1340  if (isoTauBarrel.Eval(tau_pt) >= (tau_iso_et / tau_pt)) {
1341  return 1;
1342  } else {
1343  return 0;
1344  }
1345  }
1346  // HGCal
1347  if (std::abs(tau_eta) < 3.0) {
1348  if (isoTauHGCal.Eval(tau_pt) >= (tau_iso_et / tau_pt)) {
1349  return 1;
1350  } else {
1351  return 0;
1352  }
1353  }
1354  // Beyond HGCal
1355  return 0;
1356 }
Abs< T >::type abs(const T &t)
Definition: Abs.h:22

◆ produce()

void L1CaloJetProducer::produce ( edm::Event iEvent,
const edm::EventSetup iSetup 
)
overrideprivate

Definition at line 506 of file L1CaloJetProducer.cc.

References a, funct::abs(), L1CaloJetProducer::l1CaloJetObj::associated_l1EGs_, b, L1CaloJetProducer::l1CaloJetObj::barrelSeeded, debug, reco::deltaPhi(), L1CaloJetProducer::l1CaloJetObj::ecal_3x5, L1CaloJetProducer::l1CaloJetObj::ecal_7x7, L1CaloJetProducer::l1CaloJetObj::ecal_nHits, L1CaloJetProducer::l1CaloJetObj::ecal_seed, L1CaloJetProducer::l1CaloJetObj::ecalJetCluster, L1CaloJetProducer::l1CaloJetObj::ecalJetClusterET, L1CaloJetProducer::SimpleCaloHit::ecalTowerEt, EcalTpEtMin, mps_fire::end, EtMinForCollection, EtMinForSeedHit, EtMinForTauCollection, dqmMemoryStats::float, get_hcal_calibration(), get_tau_pt_calibration(), L1CaloJetProducer::l1CaloJetObj::hcal_3x5, L1CaloJetProducer::l1CaloJetObj::hcal_7x7, L1CaloJetProducer::l1CaloJetObj::hcal_nHits, L1CaloJetProducer::l1CaloJetObj::hcal_seed, L1CaloJetProducer::l1CaloJetObj::hcalJetCluster, L1CaloJetProducer::l1CaloJetObj::hcalJetClusterET, L1CaloJetProducer::SimpleCaloHit::hcalTowerEt, HcalTpEtMin, iEvent, L1CaloJetProducer::l1CaloJetObj::Init(), createfilelist::int, L1CaloJetProducer::SimpleCaloHit::isBarrel, L1CaloJetProducer::l1CaloJetObj::jetCluster, L1CaloJetProducer::l1CaloJetObj::jetClusterET, l1CaloTowerHandle, L1CaloJetProducer_cfi::l1CaloTowers, L1CaloJetProducer::l1CaloJetObj::l1eg_3x5, L1CaloJetProducer::l1CaloJetObj::l1eg_7x7, L1CaloJetProducer::l1CaloJetObj::l1eg_nHits, L1CaloJetProducer::l1CaloJetObj::l1eg_nL1EGs, L1CaloJetProducer::l1CaloJetObj::l1eg_nL1EGs_standaloneIso, L1CaloJetProducer::l1CaloJetObj::l1eg_nL1EGs_standaloneSS, L1CaloJetProducer::l1CaloJetObj::l1eg_nL1EGs_trkMatchIso, L1CaloJetProducer::l1CaloJetObj::l1eg_nL1EGs_trkMatchSS, L1CaloJetProducer::l1CaloJetObj::l1eg_seed, L1CaloJetProducer::l1CaloJetObj::l1egJetCluster, L1CaloJetProducer::l1CaloJetObj::l1egJetClusterET, L1CaloJetProducer::SimpleCaloHit::l1egStandaloneIso, L1CaloJetProducer::SimpleCaloHit::l1egStandaloneSS, L1CaloJetProducer::SimpleCaloHit::l1egTowerEt, L1CaloJetProducer::SimpleCaloHit::l1egTrkIso, L1CaloJetProducer::SimpleCaloHit::l1egTrkSS, triggerObjects_cff::l1Tau, l1TowerToken_, LogDebug, loose_iso_tau_wp(), eostools::move(), L1CaloJetProducer::l1CaloJetObj::n_l1eg_HoverE_LessThreshold, L1CaloJetProducer::SimpleCaloHit::nL1eg, reco::LeafCandidate::p4(), submitPVValidationJobs::params, edm::Handle< T >::product(), L1CaloJetProducer::l1CaloJetObj::seed_iEta, L1CaloJetProducer::l1CaloJetObj::seed_iPhi, L1CaloJetProducer::l1CaloJetObj::seedTower, L1CaloJetProducer::l1CaloJetObj::seedTowerET, l1tp2::CaloJet::setAssociated_l1EGs(), l1tp2::CaloJet::setExperimentalParams(), jetUpdater_cfi::sort, L1TRate_Offline_cfi::Tau, L1CaloJetProducer::l1CaloJetObj::total_3x5, L1CaloJetProducer::l1CaloJetObj::total_7x7, L1CaloJetProducer::l1CaloJetObj::total_nHits, L1CaloJetProducer::l1CaloJetObj::total_seed, L1CaloJetProducer::SimpleCaloHit::total_tower_et, tower_diEta(), tower_diPhi(), L1CaloJetProducer::SimpleCaloHit::towerEta, L1CaloJetProducer::SimpleCaloHit::towerIEta, L1CaloJetProducer::SimpleCaloHit::towerIPhi, and L1CaloJetProducer::SimpleCaloHit::towerPhi.

506  {
507  // Output collections
508  std::unique_ptr<l1tp2::CaloJetsCollection> L1CaloJetsNoCuts(new l1tp2::CaloJetsCollection);
509  //std::unique_ptr<l1tp2::CaloJetsCollection> L1CaloJetsWithCuts( new l1tp2::CaloJetsCollection );
510  //std::unique_ptr<l1extra::L1JetParticleCollection> L1CaloClusterCollectionWithCuts( new l1extra::L1JetParticleCollection );
511  std::unique_ptr<BXVector<l1t::Jet>> L1CaloJetCollectionBXV(new l1t::JetBxCollection);
512  std::unique_ptr<BXVector<l1t::Tau>> L1CaloTauCollectionBXV(new l1t::TauBxCollection);
513 
514  // Load the ECAL+HCAL tower sums coming from L1EGammaCrystalsEmulatorProducer.cc
515  std::vector<SimpleCaloHit> l1CaloTowers;
516 
518  for (auto &hit : *l1CaloTowerHandle.product()) {
519  SimpleCaloHit l1Hit;
520  l1Hit.ecalTowerEt = hit.ecalTowerEt();
521  l1Hit.hcalTowerEt = hit.hcalTowerEt();
522  l1Hit.l1egTowerEt = hit.l1egTowerEt();
523  // Add min ET thresholds for tower ET
524  if (l1Hit.ecalTowerEt < EcalTpEtMin)
525  l1Hit.ecalTowerEt = 0.0;
526  if (l1Hit.hcalTowerEt < HcalTpEtMin)
527  l1Hit.hcalTowerEt = 0.0;
528  l1Hit.total_tower_et = l1Hit.ecalTowerEt + l1Hit.hcalTowerEt + l1Hit.l1egTowerEt;
529  l1Hit.towerIEta = hit.towerIEta();
530  l1Hit.towerIPhi = hit.towerIPhi();
531  l1Hit.nL1eg = hit.nL1eg();
532  l1Hit.l1egTrkSS = hit.l1egTrkSS();
533  l1Hit.l1egTrkIso = hit.l1egTrkIso();
534  l1Hit.l1egStandaloneSS = hit.l1egStandaloneSS();
535  l1Hit.l1egStandaloneIso = hit.l1egStandaloneIso();
536  l1Hit.isBarrel = hit.isBarrel();
537 
538  // FIXME There is an error in the L1EGammaCrystalsEmulatorProducer.cc which is
539  // returning towers with minimal ECAL energy, and no HCAL energy with these
540  // iEta/iPhi coordinates and eta = -88.653152 and phi = -99.000000.
541  // Skip these for the time being until the upstream code has been debugged
542  if ((int)l1Hit.towerIEta == -1016 && (int)l1Hit.towerIPhi == -962)
543  continue;
544 
545  l1Hit.towerEta = hit.towerEta();
546  l1Hit.towerPhi = hit.towerPhi();
547  l1CaloTowers.push_back(l1Hit);
548  if (debug) {
549  LogDebug("L1CaloJetProducer") << " Tower iEta " << (int)l1Hit.towerIEta << " iPhi " << (int)l1Hit.towerIPhi
550  << " eta " << l1Hit.towerEta << " phi " << l1Hit.towerPhi << " ecal_et "
551  << l1Hit.ecalTowerEt << " hacl_et " << l1Hit.hcalTowerEt << " total_et "
552  << l1Hit.total_tower_et << "\n";
553  }
554  }
555 
556  // Sort the ECAL+HCAL+L1EGs tower sums based on total ET
557  std::sort(begin(l1CaloTowers), end(l1CaloTowers), [](const SimpleCaloHit &a, SimpleCaloHit &b) {
558  return a.total_tower_et > b.total_tower_et;
559  });
560 
561  /**************************************************************************
562  * Begin with making CaloJets in 9x9 grid based on all energy not included in L1EG Objs.
563  * For reference, Run-I used 12x12 grid and Stage-2/Phase-I used 9x9 grid.
564  * We plan to further study this choice and possibly move towards a more circular shape
565  * Create jetCluster within 9x9 of highest ET seed tower.
566  * 9 trigger towers contains all of an ak-0.4 jets, but overshoots on the corners.
567  ******************************************************************************/
568 
569  // Experimental parameters, don't want to bother with hardcoding them in data format
570  std::map<std::string, float> params;
571 
572  std::vector<l1CaloJetObj> l1CaloJetObjs;
573 
574  // Count the number of unused HCAL TPs so we can stop while loop after done.
575  // Clustering can also stop once there are no seed hits >= EtMinForSeedHit
576  int n_towers = l1CaloTowers.size();
577  int n_stale = 0;
578  bool caloJetClusteringFinished = false;
579  while (!caloJetClusteringFinished && n_towers != n_stale) {
580  l1CaloJetObj caloJetObj;
581  caloJetObj.Init();
582 
583  // First find highest ET ECAL+HCAL+L1EGs tower and use to seed the 9x9 Jet
584  int cnt = 0;
585  for (auto &l1CaloTower : l1CaloTowers) {
586  cnt++;
587  if (l1CaloTower.stale)
588  continue; // skip l1CaloTowers which are already used
589 
590  if (caloJetObj.jetClusterET == 0.0) // this is the first l1CaloTower to seed the jet
591  {
592  // Check if the leading unused tower has ET < min for seeding a jet.
593  // If so, stop jet clustering
594  if (l1CaloTower.total_tower_et < EtMinForSeedHit) {
595  caloJetClusteringFinished = true;
596  continue;
597  }
598  l1CaloTower.stale = true;
599  n_stale++;
600 
601  // Set seed location needed for delta iEta/iPhi, eta/phi comparisons later
602  if (l1CaloTower.isBarrel)
603  caloJetObj.barrelSeeded = true;
604  else
605  caloJetObj.barrelSeeded = false;
606 
607  // 3 4-vectors for ECAL, HCAL, ECAL+HCAL for adding together
609  l1CaloTower.hcalTowerEt, l1CaloTower.towerEta, l1CaloTower.towerPhi, 0.);
611  l1CaloTower.ecalTowerEt, l1CaloTower.towerEta, l1CaloTower.towerPhi, 0.);
613  l1CaloTower.l1egTowerEt, l1CaloTower.towerEta, l1CaloTower.towerPhi, 0.);
615  l1CaloTower.total_tower_et, l1CaloTower.towerEta, l1CaloTower.towerPhi, 0.);
616 
617  if (hcalP4.pt() > 0) {
618  caloJetObj.hcal_nHits++;
619  caloJetObj.hcalJetCluster += hcalP4;
620  caloJetObj.hcalJetClusterET += l1CaloTower.hcalTowerEt;
621  }
622  if (ecalP4.pt() > 0) {
623  caloJetObj.ecal_nHits++;
624  caloJetObj.ecalJetCluster += ecalP4;
625  caloJetObj.ecalJetClusterET += l1CaloTower.ecalTowerEt;
626  }
627  if (l1egP4.pt() > 0) {
628  caloJetObj.l1eg_nHits++;
629  caloJetObj.l1egJetCluster += l1egP4;
630  caloJetObj.l1egJetClusterET += l1CaloTower.l1egTowerEt;
631  caloJetObj.l1eg_nL1EGs += l1CaloTower.nL1eg;
632 
633  caloJetObj.l1eg_nL1EGs_standaloneSS += l1CaloTower.l1egStandaloneSS;
634  caloJetObj.l1eg_nL1EGs_standaloneIso += l1CaloTower.l1egStandaloneIso;
635  caloJetObj.l1eg_nL1EGs_trkMatchSS += l1CaloTower.l1egTrkSS;
636  caloJetObj.l1eg_nL1EGs_trkMatchIso += l1CaloTower.l1egTrkIso;
637 
638  if (l1CaloTower.isBarrel) {
639  // For decay mode related checks with CaloTaus
640  // only applicable in the barrel at the moment:
641  // l1eg pt, HCAL ET, ECAL ET, dEta, dPhi, trkSS, trkIso, standaloneSS, standaloneIso
642  std::vector<float> l1EG_info = {float(l1egP4.pt()),
643  float(hcalP4.pt()),
644  float(ecalP4.pt()),
645  0.,
646  0.,
647  float(l1CaloTower.l1egTrkSS),
648  float(l1CaloTower.l1egTrkIso),
649  float(l1CaloTower.l1egStandaloneSS),
650  float(l1CaloTower.l1egStandaloneIso)};
651  if (l1EG_info[1] / (l1EG_info[0] + l1EG_info[2]) < 0.25) {
652  caloJetObj.n_l1eg_HoverE_LessThreshold++;
653  }
654  caloJetObj.associated_l1EGs_.push_back(l1EG_info);
655  }
656  }
657  if (totalP4.pt() > 0) {
658  caloJetObj.total_nHits++;
659  caloJetObj.jetCluster += totalP4;
660  caloJetObj.jetClusterET += l1CaloTower.total_tower_et;
661  caloJetObj.seedTower += totalP4;
662  caloJetObj.seedTowerET += l1CaloTower.total_tower_et;
663  }
664 
665  caloJetObj.seed_iEta = l1CaloTower.towerIEta;
666  caloJetObj.seed_iPhi = l1CaloTower.towerIPhi;
667 
668  if (debug) {
669  LogDebug("L1CaloJetProducer") << " -- hit " << cnt << " , seeding input p4 pt "
670  << l1CaloTower.total_tower_et << " eta " << l1CaloTower.towerEta << " phi "
671  << l1CaloTower.towerPhi << "\n";
672  LogDebug("L1CaloJetProducer") << " -- hit " << cnt << " , seeding input2 p4 pt " << totalP4.pt() << " eta "
673  << totalP4.eta() << " phi " << totalP4.phi() << "\n";
674  LogDebug("L1CaloJetProducer") << " -- hit " << cnt << " seeding reslt tot p4 pt " << caloJetObj.jetClusterET
675  << " eta " << caloJetObj.jetCluster.eta() << " phi "
676  << caloJetObj.jetCluster.phi() << "\n";
677  }
678 
679  // Need to add the seed energy to the dR rings
680  caloJetObj.hcal_seed += hcalP4.pt();
681  //caloJetObj.hcal_3x3 += hcalP4.pt();
682  caloJetObj.hcal_3x5 += hcalP4.pt();
683  //caloJetObj.hcal_5x5 += hcalP4.pt();
684  //caloJetObj.hcal_5x7 += hcalP4.pt();
685  caloJetObj.hcal_7x7 += hcalP4.pt();
686  caloJetObj.ecal_seed += ecalP4.pt();
687  //caloJetObj.ecal_3x3 += ecalP4.pt();
688  caloJetObj.ecal_3x5 += ecalP4.pt();
689  //caloJetObj.ecal_5x5 += ecalP4.pt();
690  //caloJetObj.ecal_5x7 += ecalP4.pt();
691  caloJetObj.ecal_7x7 += ecalP4.pt();
692  caloJetObj.l1eg_seed += l1egP4.pt();
693  //caloJetObj.l1eg_3x3 += l1egP4.pt();
694  caloJetObj.l1eg_3x5 += l1egP4.pt();
695  //caloJetObj.l1eg_5x5 += l1egP4.pt();
696  //caloJetObj.l1eg_5x7 += l1egP4.pt();
697  caloJetObj.l1eg_7x7 += l1egP4.pt();
698  caloJetObj.total_seed += totalP4.pt();
699  //caloJetObj.total_3x3 += totalP4.pt();
700  caloJetObj.total_3x5 += totalP4.pt();
701  //caloJetObj.total_5x5 += totalP4.pt();
702  //caloJetObj.total_5x7 += totalP4.pt();
703  caloJetObj.total_7x7 += totalP4.pt();
704 
705  // Some discrimination vars, 2x2s and 2x3 including central seed
706  //caloJetObj.hcal_2x3 += hcalP4.pt();
707  //caloJetObj.hcal_2x3_1 += hcalP4.pt();
708  //caloJetObj.hcal_2x3_2 += hcalP4.pt();
709  //caloJetObj.ecal_2x3 += ecalP4.pt();
710  //caloJetObj.ecal_2x3_1 += ecalP4.pt();
711  //caloJetObj.ecal_2x3_2 += ecalP4.pt();
712  //caloJetObj.l1eg_2x3 += l1egP4.pt();
713  //caloJetObj.l1eg_2x3_1 += l1egP4.pt();
714  //caloJetObj.l1eg_2x3_2 += l1egP4.pt();
715  //caloJetObj.total_2x3 += totalP4.pt();
716  //caloJetObj.total_2x3_1 += totalP4.pt();
717  //caloJetObj.total_2x3_2 += totalP4.pt();
718 
719  //caloJetObj.hcal_2x2 += hcalP4.pt();
720  //caloJetObj.hcal_2x2_1 += hcalP4.pt();
721  //caloJetObj.hcal_2x2_2 += hcalP4.pt();
722  //caloJetObj.hcal_2x2_3 += hcalP4.pt();
723  //caloJetObj.hcal_2x2_4 += hcalP4.pt();
724  //caloJetObj.ecal_2x2 += ecalP4.pt();
725  //caloJetObj.ecal_2x2_1 += ecalP4.pt();
726  //caloJetObj.ecal_2x2_2 += ecalP4.pt();
727  //caloJetObj.ecal_2x2_3 += ecalP4.pt();
728  //caloJetObj.ecal_2x2_4 += ecalP4.pt();
729  //caloJetObj.l1eg_2x2 += l1egP4.pt();
730  //caloJetObj.l1eg_2x2_1 += l1egP4.pt();
731  //caloJetObj.l1eg_2x2_2 += l1egP4.pt();
732  //caloJetObj.l1eg_2x2_3 += l1egP4.pt();
733  //caloJetObj.l1eg_2x2_4 += l1egP4.pt();
734  //caloJetObj.total_2x2 += totalP4.pt();
735  //caloJetObj.total_2x2_1 += totalP4.pt();
736  //caloJetObj.total_2x2_2 += totalP4.pt();
737  //caloJetObj.total_2x2_3 += totalP4.pt();
738  //caloJetObj.total_2x2_4 += totalP4.pt();
739  continue;
740  }
741 
742  // Unused l1CaloTowers which are not the initial seed
743  // Depending on seed and tower locations calculate iEta/iPhi or eta/phi comparisons.
744  // The defaults of 99 will automatically fail comparisons for the incorrect regions.
745  int hit_iPhi = 99;
746  int d_iEta = 99;
747  int d_iPhi = 99;
748  float d_eta = 99;
749  float d_phi = 99;
750  if (caloJetObj.barrelSeeded && l1CaloTower.isBarrel) // use iEta/iPhi comparisons
751  {
752  hit_iPhi = l1CaloTower.towerIPhi;
753  d_iEta = tower_diEta(caloJetObj.seed_iEta, l1CaloTower.towerIEta);
754  d_iPhi = tower_diPhi(caloJetObj.seed_iPhi, hit_iPhi);
755  } else // either seed or tower are in HGCal or HF, use eta/phi
756  {
757  d_eta = caloJetObj.seedTower.eta() - l1CaloTower.towerEta;
758  d_phi = reco::deltaPhi(caloJetObj.seedTower.phi(), l1CaloTower.towerPhi);
759  }
760 
761  // 7x7 HCAL Trigger Towers
762  // If seeded in barrel and hit is barrel then we can compare iEta/iPhi, else need to use eta/phi
763  // in HGCal / transition region
764  if ((abs(d_iEta) <= 3 && abs(d_iPhi) <= 3) || (std::abs(d_eta) < 0.3 && std::abs(d_phi) < 0.3)) {
765  l1CaloTower.stale = true;
766  n_stale++;
767 
768  // 3 4-vectors for ECAL, HCAL, ECAL+HCAL for adding together
770  l1CaloTower.hcalTowerEt, l1CaloTower.towerEta, l1CaloTower.towerPhi, 0.);
772  l1CaloTower.ecalTowerEt, l1CaloTower.towerEta, l1CaloTower.towerPhi, 0.);
774  l1CaloTower.l1egTowerEt, l1CaloTower.towerEta, l1CaloTower.towerPhi, 0.);
776  l1CaloTower.total_tower_et, l1CaloTower.towerEta, l1CaloTower.towerPhi, 0.);
777 
778  if (hcalP4.pt() > 0) {
779  caloJetObj.hcal_nHits++;
780  caloJetObj.hcalJetCluster += hcalP4;
781  caloJetObj.hcalJetClusterET += l1CaloTower.hcalTowerEt;
782  }
783  if (ecalP4.pt() > 0) {
784  caloJetObj.ecal_nHits++;
785  caloJetObj.ecalJetCluster += ecalP4;
786  caloJetObj.ecalJetClusterET += l1CaloTower.ecalTowerEt;
787  }
788  if (l1egP4.pt() > 0) {
789  caloJetObj.l1eg_nHits++;
790  caloJetObj.l1egJetCluster += l1egP4;
791  caloJetObj.l1egJetClusterET += l1CaloTower.l1egTowerEt;
792  caloJetObj.l1eg_nL1EGs += l1CaloTower.nL1eg;
793  }
794  if (totalP4.pt() > 0) {
795  caloJetObj.total_nHits++;
796  caloJetObj.jetCluster += totalP4;
797  caloJetObj.jetClusterET += l1CaloTower.total_tower_et;
798  }
799 
800  if (debug) {
801  LogDebug("L1CaloJetProducer") << " ---- hit " << cnt << " input p4 pt " << totalP4.pt() << " eta "
802  << totalP4.eta() << " phi " << totalP4.phi() << "\n";
803  LogDebug("L1CaloJetProducer") << " ---- hit " << cnt << " resulting p4 pt " << caloJetObj.jetClusterET
804  << " eta " << caloJetObj.jetCluster.eta() << " phi "
805  << caloJetObj.jetCluster.phi() << "\n";
806  }
807 
808  if ((abs(d_iEta) == 0 && abs(d_iPhi) == 0) || (std::abs(d_eta) < 0.043 && std::abs(d_phi) < 0.043)) {
809  caloJetObj.hcal_seed += hcalP4.pt();
810  caloJetObj.ecal_seed += ecalP4.pt();
811  caloJetObj.l1eg_seed += l1egP4.pt();
812  caloJetObj.total_seed += totalP4.pt();
813  }
814  //if ( (abs( d_iEta ) <= 1 && abs( d_iPhi ) <= 1) ||
815  // ( std::abs( d_eta ) < 0.13 && std::abs( d_phi ) < 0.13 ) )
816  //{
817  // caloJetObj.hcal_3x3 += hcalP4.pt();
818  // caloJetObj.ecal_3x3 += ecalP4.pt();
819  // caloJetObj.l1eg_3x3 += l1egP4.pt();
820  // caloJetObj.total_3x3 += totalP4.pt();
821  //}
822  if ((abs(d_iEta) <= 1 && abs(d_iPhi) <= 2) || (std::abs(d_eta) < 0.13 && std::abs(d_phi) < 0.22)) {
823  caloJetObj.hcal_3x5 += hcalP4.pt();
824  caloJetObj.ecal_3x5 += ecalP4.pt();
825  caloJetObj.l1eg_3x5 += l1egP4.pt();
826  caloJetObj.total_3x5 += totalP4.pt();
827 
828  // Do this for 3x5 only
829  if (l1egP4.pt() > 0) {
830  caloJetObj.l1eg_nL1EGs_standaloneSS += l1CaloTower.l1egStandaloneSS;
831  caloJetObj.l1eg_nL1EGs_standaloneIso += l1CaloTower.l1egStandaloneIso;
832  caloJetObj.l1eg_nL1EGs_trkMatchSS += l1CaloTower.l1egTrkSS;
833  caloJetObj.l1eg_nL1EGs_trkMatchIso += l1CaloTower.l1egTrkIso;
834 
835  // For decay mode related checks with CaloTaus
836  // only applicable in the barrel at the moment:
837  // l1eg pt, HCAL ET, ECAL ET, d_iEta, d_iPhi, trkSS, trkIso, standaloneSS, standaloneIso
838  std::vector<float> l1EG_info = {float(l1egP4.pt()),
839  float(hcalP4.pt()),
840  float(ecalP4.pt()),
841  float(d_iEta),
842  float(d_iPhi),
843  float(l1CaloTower.l1egTrkSS),
844  float(l1CaloTower.l1egTrkIso),
845  float(l1CaloTower.l1egStandaloneSS),
846  float(l1CaloTower.l1egStandaloneIso)};
847  if (l1EG_info[1] / (l1EG_info[0] + l1EG_info[2]) < 0.25) {
848  caloJetObj.n_l1eg_HoverE_LessThreshold++;
849  }
850  caloJetObj.associated_l1EGs_.push_back(l1EG_info);
851  }
852  }
853  //if ( ( abs( d_iEta ) <= 2 && abs( d_iPhi ) <= 2) ||
854  // ( std::abs( d_eta ) < 0.22 && std::abs( d_phi ) < 0.22 ) )
855  //{
856  // caloJetObj.hcal_5x5 += hcalP4.pt();
857  // caloJetObj.ecal_5x5 += ecalP4.pt();
858  // caloJetObj.l1eg_5x5 += l1egP4.pt();
859  // caloJetObj.total_5x5 += totalP4.pt();
860  //}
861  //if ( ( abs( d_iEta ) <= 2 && abs( d_iPhi ) <= 3) ||
862  // ( std::abs( d_eta ) < 0.22 && std::abs( d_phi ) < 0.3 ) )
863  //{
864  // caloJetObj.hcal_5x7 += hcalP4.pt();
865  // caloJetObj.ecal_5x7 += ecalP4.pt();
866  // caloJetObj.l1eg_5x7 += l1egP4.pt();
867  // caloJetObj.total_5x7 += totalP4.pt();
868  //}
869  if ((abs(d_iEta) <= 3 && abs(d_iPhi) <= 3) || (std::abs(d_eta) < 0.3 && std::abs(d_phi) < 0.3)) {
870  caloJetObj.hcal_7x7 += hcalP4.pt();
871  caloJetObj.ecal_7x7 += ecalP4.pt();
872  caloJetObj.l1eg_7x7 += l1egP4.pt();
873  caloJetObj.total_7x7 += totalP4.pt();
874  }
875 
878  //if ( ( d_iEta == 0 || d_iEta == 1 ) && abs(d_iPhi) <= 1 )
879  //{
880  // caloJetObj.hcal_2x3_1 += hcalP4.pt();
881  // caloJetObj.ecal_2x3_1 += ecalP4.pt();
882  // caloJetObj.l1eg_2x3_1 += l1egP4.pt();
883  // caloJetObj.total_2x3_1 += totalP4.pt();
884  //}
885  //if ( ( d_iEta == 0 || d_iEta == -1 ) && abs(d_iPhi) <= 1 )
886  //{
887  // caloJetObj.hcal_2x3_2 += hcalP4.pt();
888  // caloJetObj.ecal_2x3_2 += ecalP4.pt();
889  // caloJetObj.l1eg_2x3_2 += l1egP4.pt();
890  // caloJetObj.total_2x3_2 += totalP4.pt();
891  //}
893  //if ( std::abs( d_eta ) < 0.087 && std::abs( d_phi ) < 0.13 )
894  //{
895  // caloJetObj.hcal_2x3 += hcalP4.pt();
896  // caloJetObj.ecal_2x3 += ecalP4.pt();
897  // caloJetObj.l1eg_2x3 += l1egP4.pt();
898  // caloJetObj.total_2x3 += totalP4.pt();
899  //}
900 
902  //if ( ( d_iEta == 0 || d_iEta == 1 ) && ( d_iPhi == 0 || d_iPhi == 1 ) )
903  //{
904  // caloJetObj.hcal_2x2_1 += hcalP4.pt();
905  // caloJetObj.ecal_2x2_1 += ecalP4.pt();
906  // caloJetObj.l1eg_2x2_1 += l1egP4.pt();
907  // caloJetObj.total_2x2_1 += totalP4.pt();
908  //}
909  //if ( ( d_iEta == 0 || d_iEta == 1 ) && ( d_iPhi == 0 || d_iPhi == -1 ) )
910  //{
911  // caloJetObj.hcal_2x2_2 += hcalP4.pt();
912  // caloJetObj.ecal_2x2_2 += ecalP4.pt();
913  // caloJetObj.l1eg_2x2_2 += l1egP4.pt();
914  // caloJetObj.total_2x2_2 += totalP4.pt();
915  //}
916  //if ( ( d_iEta == 0 || d_iEta == -1 ) && ( d_iPhi == 0 || d_iPhi == 1 ) )
917  //{
918  // caloJetObj.hcal_2x2_3 += hcalP4.pt();
919  // caloJetObj.ecal_2x2_3 += ecalP4.pt();
920  // caloJetObj.l1eg_2x2_3 += l1egP4.pt();
921  // caloJetObj.total_2x2_3 += totalP4.pt();
922  //}
923  //if ( ( d_iEta == 0 || d_iEta == -1 ) && ( d_iPhi == 0 || d_iPhi == -1 ) )
924  //{
925  // caloJetObj.hcal_2x2_4 += hcalP4.pt();
926  // caloJetObj.ecal_2x2_4 += ecalP4.pt();
927  // caloJetObj.l1eg_2x2_4 += l1egP4.pt();
928  // caloJetObj.total_2x2_4 += totalP4.pt();
929  //}
931  //if ( std::abs( d_eta ) < 0.087 && std::abs( d_phi ) < 0.087 )
932  //{
933  // caloJetObj.hcal_2x2 += hcalP4.pt();
934  // caloJetObj.ecal_2x2 += ecalP4.pt();
935  // caloJetObj.l1eg_2x2 += l1egP4.pt();
936  // caloJetObj.total_2x2 += totalP4.pt();
937  //}
938  }
939  }
940 
941  if (caloJetObj.jetClusterET > 0.0) {
942  l1CaloJetObjs.push_back(caloJetObj);
943  }
944 
945  } // end while loop of HCAL TP clustering
946 
947  // Sort JetClusters so we can begin with the highest pt for next step of jet clustering
948  std::sort(begin(l1CaloJetObjs), end(l1CaloJetObjs), [](const l1CaloJetObj &a, const l1CaloJetObj &b) {
949  return a.jetClusterET > b.jetClusterET;
950  });
951 
952  /**************************************************************************
953  * Progress to adding L1EGs built from ECAL TPs 9x9 grid.
954  * Recall, for 9x9 trigger towers gives diameter 0.78
955  ******************************************************************************/
956 
957  // Cluster together the L1EGs around existing HCAL Jet
958  // Cluster within dEta/dPhi 0.4 which is very close to 0.39 = 9x9/2
959  //std::cout << " - Input L1EGs: " << crystalClustersVect.size() << std::endl;
960  for (auto &caloJetObj : l1CaloJetObjs) {
961  params["seed_pt"] = caloJetObj.seedTowerET;
962  params["seed_eta"] = caloJetObj.seedTower.eta();
963  params["seed_phi"] = caloJetObj.seedTower.phi();
964  params["seed_iEta"] = caloJetObj.seed_iEta;
965  params["seed_iPhi"] = caloJetObj.seed_iPhi;
966  params["seed_energy"] = caloJetObj.seedTower.energy();
967 
968  params["hcal_pt"] = caloJetObj.hcalJetClusterET;
969  params["hcal_seed"] = caloJetObj.hcal_seed;
970  //params["hcal_3x3"] = caloJetObj.hcal_3x3;
971  params["hcal_3x5"] = caloJetObj.hcal_3x5;
972  //params["hcal_5x5"] = caloJetObj.hcal_5x5;
973  //params["hcal_5x7"] = caloJetObj.hcal_5x7;
974  params["hcal_7x7"] = caloJetObj.hcal_7x7;
975  //params["hcal_2x3"] = std::max( caloJetObj.hcal_2x3, std::max( caloJetObj.hcal_2x3_1, caloJetObj.hcal_2x3_2 ));
976  //params["hcal_2x2"] = std::max( caloJetObj.hcal_2x2, std::max( caloJetObj.hcal_2x2_1, std::max( caloJetObj.hcal_2x2_2, std::max( caloJetObj.hcal_2x2_3, caloJetObj.hcal_2x2_4 ))));
977  params["hcal_nHits"] = caloJetObj.hcal_nHits;
978 
979  params["ecal_pt"] = caloJetObj.ecalJetClusterET;
980  params["ecal_seed"] = caloJetObj.ecal_seed;
981  //params["ecal_3x3"] = caloJetObj.ecal_3x3;
982  params["ecal_3x5"] = caloJetObj.ecal_3x5;
983  //params["ecal_5x5"] = caloJetObj.ecal_5x5;
984  //params["ecal_5x7"] = caloJetObj.ecal_5x7;
985  params["ecal_7x7"] = caloJetObj.ecal_7x7;
986  //params["ecal_2x3"] = std::max( caloJetObj.ecal_2x3, std::max( caloJetObj.ecal_2x3_1, caloJetObj.ecal_2x3_2 ));
987  //params["ecal_2x2"] = std::max( caloJetObj.ecal_2x2, std::max( caloJetObj.ecal_2x2_1, std::max( caloJetObj.ecal_2x2_2, std::max( caloJetObj.ecal_2x2_3, caloJetObj.ecal_2x2_4 ))));
988  params["ecal_nHits"] = caloJetObj.ecal_nHits;
989 
990  params["l1eg_pt"] = caloJetObj.l1egJetClusterET;
991  params["l1eg_seed"] = caloJetObj.l1eg_seed;
992  //params["l1eg_3x3"] = caloJetObj.l1eg_3x3;
993  params["l1eg_3x5"] = caloJetObj.l1eg_3x5;
994  //params["l1eg_5x5"] = caloJetObj.l1eg_5x5;
995  //params["l1eg_5x7"] = caloJetObj.l1eg_5x7;
996  params["l1eg_7x7"] = caloJetObj.l1eg_7x7;
997  //params["l1eg_2x3"] = std::max( caloJetObj.l1eg_2x3, std::max( caloJetObj.l1eg_2x3_1, caloJetObj.l1eg_2x3_2 ));
998  //params["l1eg_2x2"] = std::max( caloJetObj.l1eg_2x2, std::max( caloJetObj.l1eg_2x2_1, std::max( caloJetObj.l1eg_2x2_2, std::max( caloJetObj.l1eg_2x2_3, caloJetObj.l1eg_2x2_4 ))));
999  params["l1eg_nHits"] = caloJetObj.l1eg_nHits;
1000  params["l1eg_nL1EGs"] = caloJetObj.l1eg_nL1EGs;
1001  params["l1eg_nL1EGs_standaloneSS"] = caloJetObj.l1eg_nL1EGs_standaloneSS;
1002  params["l1eg_nL1EGs_standaloneIso"] = caloJetObj.l1eg_nL1EGs_standaloneIso;
1003  params["l1eg_nL1EGs_trkMatchSS"] = caloJetObj.l1eg_nL1EGs_trkMatchSS;
1004  params["l1eg_nL1EGs_trkMatchIso"] = caloJetObj.l1eg_nL1EGs_trkMatchIso;
1005 
1006  params["total_et"] = caloJetObj.jetClusterET;
1007  params["total_seed"] = caloJetObj.total_seed;
1008  //params["total_3x3"] = caloJetObj.total_3x3;
1009  params["total_3x5"] = caloJetObj.total_3x5;
1010  //params["total_5x5"] = caloJetObj.total_5x5;
1011  //params["total_5x7"] = caloJetObj.total_5x7;
1012  params["total_7x7"] = caloJetObj.total_7x7;
1013  //params["total_2x3"] = std::max( caloJetObj.total_2x3, std::max( caloJetObj.total_2x3_1, caloJetObj.total_2x3_2 ));
1014  //params["total_2x2"] = std::max( caloJetObj.total_2x2, std::max( caloJetObj.total_2x2_1, std::max( caloJetObj.total_2x2_2, std::max( caloJetObj.total_2x2_3, caloJetObj.total_2x2_4 ))));
1015  params["total_nHits"] = caloJetObj.total_nHits;
1016  //params["total_nTowers"] = total_nTowers;
1017 
1019  float hovere = -9;
1020  if (caloJetObj.ecalJetClusterET > 0.0) {
1021  hovere = caloJetObj.hcalJetClusterET / (caloJetObj.ecalJetClusterET + caloJetObj.l1egJetClusterET);
1022  }
1023 
1024  params["jet_pt"] = caloJetObj.jetClusterET;
1025  params["jet_eta"] = caloJetObj.jetCluster.eta();
1026  params["jet_phi"] = caloJetObj.jetCluster.phi();
1027  params["jet_mass"] = caloJetObj.jetCluster.mass();
1028  params["jet_energy"] = caloJetObj.jetCluster.energy();
1029 
1030  // Calibrations
1031  params["hcal_calibration"] =
1032  get_hcal_calibration(params["jet_pt"], params["ecal_pt"], params["l1eg_pt"], params["jet_eta"]);
1033  params["hcal_pt_calibration"] = params["hcal_pt"] * params["hcal_calibration"];
1034  params["jet_pt_calibration"] = params["hcal_pt_calibration"] + params["ecal_pt"] + params["l1eg_pt"];
1035 
1036  // Tau Vars
1037  // The tau pT calibration is applied as a SF to the total raw pT
1038  // in contrast to the jet calibration above
1039  params["tau_pt_calibration_value"] = get_tau_pt_calibration(params["total_3x5"],
1040  params["ecal_3x5"],
1041  params["l1eg_3x5"],
1042  caloJetObj.n_l1eg_HoverE_LessThreshold,
1043  params["jet_eta"]);
1044  params["tau_pt"] = params["total_3x5"] * params["tau_pt_calibration_value"];
1045  params["n_l1eg_HoverE_LessThreshold"] = caloJetObj.n_l1eg_HoverE_LessThreshold;
1046  // Currently, applying the tau_pt calibration to the isolation region as well...
1047  // One could switch to using the calibrated jet_pt instead for the iso region...
1048  // This should be revisited - FIXME?
1049  params["tau_total_iso_et"] = params["jet_pt"] * params["tau_pt_calibration_value"];
1050  params["tau_iso_et"] = (params["jet_pt"] * params["tau_pt_calibration_value"]) - params["tau_pt"];
1051  params["loose_iso_tau_wp"] = float(loose_iso_tau_wp(params["tau_pt"], params["tau_iso_et"], params["jet_eta"]));
1052 
1053  float calibratedPt = -1;
1054  float ECalIsolation = -1; // Need to loop over 7x7 crystals of unclustered energy
1055  float totalPtPUcorr = -1;
1056  l1tp2::CaloJet caloJet(caloJetObj.jetCluster, calibratedPt, hovere, ECalIsolation, totalPtPUcorr);
1057  caloJet.setExperimentalParams(params);
1058  caloJet.setAssociated_l1EGs(caloJetObj.associated_l1EGs_);
1059 
1060  // Only store jets passing ET threshold
1061  if (params["jet_pt_calibration"] >= EtMinForCollection) {
1062  L1CaloJetsNoCuts->push_back(caloJet);
1063  //L1CaloJetsWithCuts->push_back( caloJet );
1065  params["jet_pt_calibration"], caloJet.p4().eta(), caloJet.p4().phi(), caloJet.p4().M());
1066  L1CaloJetCollectionBXV->push_back(0, l1t::Jet(jet_p4));
1067 
1068  if (debug)
1069  LogDebug("L1CaloJetProducer") << " Made a Jet, eta " << caloJetObj.jetCluster.eta() << " phi "
1070  << caloJetObj.jetCluster.phi() << " pt " << caloJetObj.jetClusterET
1071  << " calibrated pt " << params["jet_pt_calibration"] << "\n";
1072  }
1073 
1074  // Only store taus passing ET threshold
1075  if (params["tau_pt"] >= EtMinForTauCollection) {
1076  short int tau_ieta = caloJetObj.seed_iEta;
1077  short int tau_iphi = caloJetObj.seed_iPhi;
1078  short int raw_et = params["total_3x5"];
1079  short int iso_et = params["tau_iso_et"];
1080  bool hasEM = false;
1081  if (params["l1eg_3x5"] > 0. || params["ecal_3x5"] > 0.) {
1082  hasEM = true;
1083  }
1084  int tau_qual = int(params["loose_iso_tau_wp"]);
1085 
1087  params["tau_pt"], caloJet.p4().eta(), caloJet.p4().phi(), caloJet.p4().M());
1088  l1t::Tau l1Tau = l1t::Tau(tau_p4, params["tau_pt"], caloJet.p4().eta(), caloJet.p4().phi(), tau_qual, iso_et);
1089  l1Tau.setTowerIEta(tau_ieta);
1090  l1Tau.setTowerIPhi(tau_iphi);
1091  l1Tau.setRawEt(raw_et);
1092  l1Tau.setIsoEt(iso_et);
1093  l1Tau.setHasEM(hasEM);
1094  l1Tau.setIsMerged(false);
1095  L1CaloTauCollectionBXV->push_back(0, l1Tau);
1096 
1097  if (debug) {
1098  LogDebug("L1CaloJetProducer") << " Made a Jet, eta " << l1Tau.eta() << " phi " << l1Tau.phi() << " pt "
1099  << l1Tau.rawEt() << " calibrated pt " << l1Tau.pt() << "\n";
1100  }
1101  }
1102 
1103  } // end jetClusters loop
1104 
1105  iEvent.put(std::move(L1CaloJetsNoCuts), "L1CaloJetsNoCuts");
1106  //iEvent.put(std::move(L1CaloJetsWithCuts), "L1CaloJetsWithCuts" );
1107  //iEvent.put(std::move(L1CaloClusterCollectionWithCuts), "L1CaloClusterCollectionWithCuts" );
1108  iEvent.put(std::move(L1CaloJetCollectionBXV), "L1CaloJetCollectionBXV");
1109  iEvent.put(std::move(L1CaloTauCollectionBXV), "L1CaloTauCollectionBXV");
1110 }
constexpr double deltaPhi(double phi1, double phi2)
Definition: deltaPhi.h:26
int loose_iso_tau_wp(float &tau_pt, float &tau_iso_et, float &tau_eta) const
Definition: Tau.h:20
T const * product() const
Definition: Handle.h:70
int tower_diPhi(int &iPhi_1, int &iPhi_2) const
edm::EDGetTokenT< l1tp2::CaloTowerCollection > l1TowerToken_
float get_hcal_calibration(float &jet_pt, float &ecal_pt, float &ecal_L1EG_jet_pt, float &jet_eta) const
float get_tau_pt_calibration(float &tau_pt, float &ecal_pt, float &l1EG_pt, float &n_L1EGs, float &tau_eta) const
Definition: Jet.h:20
int iEvent
Definition: GenABIO.cc:224
std::vector< l1tp2::CaloJet > CaloJetsCollection
Definition: CaloJet.h:57
int tower_diEta(int &iEta_1, int &iEta_2) const
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
double b
Definition: hdecay.h:118
double a
Definition: hdecay.h:119
edm::Handle< l1tp2::CaloTowerCollection > l1CaloTowerHandle
def move(src, dest)
Definition: eostools.py:511
#define LogDebug(id)
math::PtEtaPhiMLorentzVector PolarLorentzVector
Lorentz vector.
Definition: Candidate.h:38

◆ tower_diEta()

int L1CaloJetProducer::tower_diEta ( int &  iEta_1,
int &  iEta_2 
) const
private

Definition at line 1124 of file L1CaloJetProducer.cc.

Referenced by produce().

1124  {
1125  // On same side of barrel
1126  if (iEta_1 * iEta_2 > 0)
1127  return iEta_1 - iEta_2;
1128  else
1129  return iEta_1 - iEta_2 - 1;
1130 }

◆ tower_diPhi()

int L1CaloJetProducer::tower_diPhi ( int &  iPhi_1,
int &  iPhi_2 
) const
private

Definition at line 1112 of file L1CaloJetProducer.cc.

References PI, and mps_fire::result.

Referenced by produce().

1112  {
1113  // 360 Crystals in full, 72 towers, half way is 36
1114  int PI = 36;
1115  int result = iPhi_1 - iPhi_2;
1116  while (result > PI)
1117  result -= 2 * PI;
1118  while (result <= -PI)
1119  result += 2 * PI;
1120  return result;
1121 }
#define PI
Definition: QcdUeDQM.h:37

Member Data Documentation

◆ absEtaBinsBarrel

std::vector<double> L1CaloJetProducer::absEtaBinsBarrel
private

Definition at line 81 of file L1CaloJetProducer.cc.

Referenced by get_hcal_calibration(), and L1CaloJetProducer().

◆ absEtaBinsHF

std::vector<double> L1CaloJetProducer::absEtaBinsHF
private

Definition at line 87 of file L1CaloJetProducer.cc.

Referenced by get_hcal_calibration(), and L1CaloJetProducer().

◆ absEtaBinsHGCal

std::vector<double> L1CaloJetProducer::absEtaBinsHGCal
private

Definition at line 84 of file L1CaloJetProducer.cc.

Referenced by get_hcal_calibration(), and L1CaloJetProducer().

◆ calibrationsBarrel

std::vector<std::vector<std::vector<double> > > L1CaloJetProducer::calibrationsBarrel
private

Definition at line 100 of file L1CaloJetProducer.cc.

Referenced by get_hcal_calibration(), and L1CaloJetProducer().

◆ calibrationsHF

std::vector<std::vector<std::vector<double> > > L1CaloJetProducer::calibrationsHF
private

Definition at line 102 of file L1CaloJetProducer.cc.

Referenced by get_hcal_calibration(), and L1CaloJetProducer().

◆ calibrationsHGCal

std::vector<std::vector<std::vector<double> > > L1CaloJetProducer::calibrationsHGCal
private

Definition at line 101 of file L1CaloJetProducer.cc.

Referenced by get_hcal_calibration(), and L1CaloJetProducer().

◆ debug

bool L1CaloJetProducer::debug
private

◆ EcalTpEtMin

double L1CaloJetProducer::EcalTpEtMin
private

Definition at line 70 of file L1CaloJetProducer.cc.

Referenced by L1CaloJetProducer(), and produce().

◆ emFractionBinsBarrel

std::vector<double> L1CaloJetProducer::emFractionBinsBarrel
private

Definition at line 80 of file L1CaloJetProducer.cc.

Referenced by get_hcal_calibration(), and L1CaloJetProducer().

◆ emFractionBinsHF

std::vector<double> L1CaloJetProducer::emFractionBinsHF
private

Definition at line 86 of file L1CaloJetProducer.cc.

Referenced by get_hcal_calibration(), and L1CaloJetProducer().

◆ emFractionBinsHGCal

std::vector<double> L1CaloJetProducer::emFractionBinsHGCal
private

Definition at line 83 of file L1CaloJetProducer.cc.

Referenced by get_hcal_calibration(), and L1CaloJetProducer().

◆ EtMinForCollection

double L1CaloJetProducer::EtMinForCollection
private

Definition at line 75 of file L1CaloJetProducer.cc.

Referenced by produce().

◆ EtMinForSeedHit

double L1CaloJetProducer::EtMinForSeedHit
private

Definition at line 74 of file L1CaloJetProducer.cc.

Referenced by produce().

◆ EtMinForTauCollection

double L1CaloJetProducer::EtMinForTauCollection
private

Definition at line 76 of file L1CaloJetProducer.cc.

Referenced by produce().

◆ HcalTpEtMin

double L1CaloJetProducer::HcalTpEtMin
private

Definition at line 69 of file L1CaloJetProducer.cc.

Referenced by L1CaloJetProducer(), and produce().

◆ HFTpEtMin

double L1CaloJetProducer::HFTpEtMin
private

Definition at line 73 of file L1CaloJetProducer.cc.

◆ HGCalEmTpEtMin

double L1CaloJetProducer::HGCalEmTpEtMin
private

Definition at line 72 of file L1CaloJetProducer.cc.

◆ HGCalHadTpEtMin

double L1CaloJetProducer::HGCalHadTpEtMin
private

Definition at line 71 of file L1CaloJetProducer.cc.

◆ isoTauBarrel

TF1 L1CaloJetProducer::isoTauBarrel = TF1("isoTauBarrelFunction", "([0] + [1]*TMath::Exp(-[2]*x))")
private

Definition at line 117 of file L1CaloJetProducer.cc.

Referenced by L1CaloJetProducer(), and loose_iso_tau_wp().

◆ isoTauHGCal

TF1 L1CaloJetProducer::isoTauHGCal = TF1("isoTauHGCalFunction", "([0] + [1]*TMath::Exp(-[2]*x))")
private

Definition at line 118 of file L1CaloJetProducer.cc.

Referenced by L1CaloJetProducer(), and loose_iso_tau_wp().

◆ jetCalibrationsBarrel

std::vector<double> L1CaloJetProducer::jetCalibrationsBarrel
private

Definition at line 82 of file L1CaloJetProducer.cc.

Referenced by L1CaloJetProducer().

◆ jetCalibrationsHF

std::vector<double> L1CaloJetProducer::jetCalibrationsHF
private

Definition at line 88 of file L1CaloJetProducer.cc.

Referenced by L1CaloJetProducer().

◆ jetCalibrationsHGCal

std::vector<double> L1CaloJetProducer::jetCalibrationsHGCal
private

Definition at line 85 of file L1CaloJetProducer.cc.

Referenced by L1CaloJetProducer().

◆ jetPtBins

std::vector<double> L1CaloJetProducer::jetPtBins
private

Definition at line 79 of file L1CaloJetProducer.cc.

Referenced by get_hcal_calibration(), and L1CaloJetProducer().

◆ l1CaloTowerHandle

edm::Handle<l1tp2::CaloTowerCollection> L1CaloJetProducer::l1CaloTowerHandle
private

Definition at line 114 of file L1CaloJetProducer.cc.

Referenced by produce().

◆ l1TowerToken_

edm::EDGetTokenT<l1tp2::CaloTowerCollection> L1CaloJetProducer::l1TowerToken_
private

Definition at line 113 of file L1CaloJetProducer.cc.

Referenced by produce().

◆ tauAbsEtaBinsBarrel

std::vector<double> L1CaloJetProducer::tauAbsEtaBinsBarrel
private

Definition at line 92 of file L1CaloJetProducer.cc.

Referenced by get_tau_pt_calibration(), and L1CaloJetProducer().

◆ tauAbsEtaBinsHGCal

std::vector<double> L1CaloJetProducer::tauAbsEtaBinsHGCal
private

Definition at line 95 of file L1CaloJetProducer.cc.

Referenced by get_tau_pt_calibration(), and L1CaloJetProducer().

◆ tauCalibrationsBarrel

std::vector<double> L1CaloJetProducer::tauCalibrationsBarrel
private

Definition at line 93 of file L1CaloJetProducer.cc.

Referenced by L1CaloJetProducer().

◆ tauCalibrationsHGCal

std::vector<double> L1CaloJetProducer::tauCalibrationsHGCal
private

Definition at line 96 of file L1CaloJetProducer.cc.

Referenced by L1CaloJetProducer().

◆ tauL1egInfoBarrel

std::vector<edm::ParameterSet> L1CaloJetProducer::tauL1egInfoBarrel
private

Definition at line 94 of file L1CaloJetProducer.cc.

Referenced by L1CaloJetProducer().

◆ tauL1egInfoHGCal

std::vector<edm::ParameterSet> L1CaloJetProducer::tauL1egInfoHGCal
private

Definition at line 97 of file L1CaloJetProducer.cc.

Referenced by L1CaloJetProducer().

◆ tauL1egInfoMapBarrel

std::map<double, std::vector<double> > L1CaloJetProducer::tauL1egInfoMapBarrel
private

Definition at line 105 of file L1CaloJetProducer.cc.

Referenced by get_tau_pt_calibration(), and L1CaloJetProducer().

◆ tauL1egInfoMapHGCal

std::map<double, std::vector<double> > L1CaloJetProducer::tauL1egInfoMapHGCal
private

Definition at line 106 of file L1CaloJetProducer.cc.

Referenced by get_tau_pt_calibration(), and L1CaloJetProducer().

◆ tauL1egValuesBarrel

std::vector<double> L1CaloJetProducer::tauL1egValuesBarrel
private

Definition at line 107 of file L1CaloJetProducer.cc.

Referenced by get_tau_pt_calibration(), and L1CaloJetProducer().

◆ tauL1egValuesHGCal

std::vector<double> L1CaloJetProducer::tauL1egValuesHGCal
private

Definition at line 108 of file L1CaloJetProducer.cc.

Referenced by get_tau_pt_calibration(), and L1CaloJetProducer().

◆ tauPtBins

std::vector<double> L1CaloJetProducer::tauPtBins
private

Definition at line 91 of file L1CaloJetProducer.cc.

Referenced by get_tau_pt_calibration(), and L1CaloJetProducer().

◆ tauPtCalibrationsBarrel

std::vector<std::vector<std::vector<std::vector<double> > > > L1CaloJetProducer::tauPtCalibrationsBarrel
private

Definition at line 109 of file L1CaloJetProducer.cc.

Referenced by get_tau_pt_calibration(), and L1CaloJetProducer().

◆ tauPtCalibrationsHGCal

std::vector<std::vector<std::vector<std::vector<double> > > > L1CaloJetProducer::tauPtCalibrationsHGCal
private

Definition at line 110 of file L1CaloJetProducer.cc.

Referenced by get_tau_pt_calibration(), and L1CaloJetProducer().