CaloParamsHelperO2O.h

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#include <iostream>

#include "CondFormats/L1TObjects/interface/CaloParams.h"

#include "CondFormats/L1TObjects/interface/L1CaloEtScale.h"
#include "CondFormats/DataRecord/interface/L1EmEtScaleRcd.h"
#include "CondFormats/DataRecord/interface/L1JetEtScaleRcd.h"
#include "CondFormats/DataRecord/interface/L1HtMissScaleRcd.h"
#include "CondFormats/DataRecord/interface/L1HfRingEtScaleRcd.h"

#ifndef CaloParamsHelperO2O_h
#define CaloParamsHelperO2O_h

namespace l1t {

  class CaloParamsHelperO2O : public CaloParams {
  public:
    // DO NOT ADD ENTRIES ANYWHERE BUT DIRECTLY BEFORE "NUM_CALOPARAMNODES"
    // DO NOT CHANGE NUMERICAL VALUES OF ANY ALREADY EXISTING FIELDS, YOU CAN ONLY EXTEND, AT THE END.
    enum {
      regionPUS = 0,
      egTrimming = 1,
      egMaxHOverE = 2,
      egCompressShapes = 3,
      egShapeId = 4,
      egCalibration = 5,
      egPUS = 6,
      egIsolation = 7,
      tauCalibration = 8,
      tauPUS = 9,
      tauIsolation = 10,
      jetPUS = 11,
      jetCalibration = 12,
      hiCentrality = 13,
      hiQ2 = 14,
      tauEtToHFRingEt = 15,
      tauCompress = 16,
      layer1ECal = 17,
      layer1HCal = 18,
      layer1HF = 19,
      jetCompressEta = 20,
      jetCompressPt = 21,
      metCalibration = 22,
      metHFCalibration = 23,
      etSumEttCalibration = 24,
      etSumEcalSumCalibration = 25,
      tauIsolation2 = 26,
      egBypassEGVetosFlag = 27,
      jetBypassPUSFlag = 28,
      egHOverEBarrel = 29,
      egHOverEEndcap = 30,
      etSumMetPUS = 31,
      etSumBypassMetPUSFlag = 32,
      egBypassExtHoE = 33,
      egIsolation2 = 34,
      etSumEttPUS = 35,
      etSumBypassEttPUSFlag = 36,
      etSumEcalSumPUS = 37,
      etSumBypassEcalSumPUSFlag = 38,
      layer1HOverE = 39,
      PUTowerThreshold = 40,
      tauTrimmingShapeVeto = 41,
      egBypassShapeFlag = 42,
      egBypassECALFGFlag = 43,
      egBypassHoEFlag = 44,
      etSumCentralityLower = 45,
      etSumCentralityUpper = 46,
      jetPUSUsePhiRingFlag = 47,
      metPhiCalibration = 48,
      metHFPhiCalibration = 49,
      NUM_CALOPARAMNODES = 50
    };

    CaloParamsHelperO2O() { pnode_.resize(NUM_CALOPARAMNODES); }
    CaloParamsHelperO2O(const CaloParams& p) : CaloParams(p) {
      if (pnode_.size() < NUM_CALOPARAMNODES) {
        pnode_.resize(NUM_CALOPARAMNODES);
        // at version 2, tauCompress was added, we can add a default version here if necessary...
      }
    };
    ~CaloParamsHelperO2O() {}

    bool isValidForStage1() { return true; }
    bool isValidForStage2() { return (version_ >= 2); }

    L1CaloEtScale emScale() { return emScale_; }
    void setEmScale(L1CaloEtScale emScale) { emScale_ = emScale; }
    L1CaloEtScale jetScale() { return jetScale_; }
    void setJetScale(L1CaloEtScale jetScale) { jetScale_ = jetScale; }
    L1CaloEtScale HtMissScale() { return HtMissScale_; }
    L1CaloEtScale HfRingScale() { return HfRingScale_; }
    void setHtMissScale(L1CaloEtScale HtMissScale) { HtMissScale_ = HtMissScale; }
    void setHfRingScale(L1CaloEtScale HfRingScale) { HfRingScale_ = HfRingScale; }

    // towers
    double towerLsbH() const { return towerp_.lsbH_; }
    double towerLsbE() const { return towerp_.lsbE_; }
    double towerLsbSum() const { return towerp_.lsbSum_; }
    int towerNBitsH() const { return towerp_.nBitsH_; }
    int towerNBitsE() const { return towerp_.nBitsE_; }
    int towerNBitsSum() const { return towerp_.nBitsSum_; }
    int towerNBitsRatio() const { return towerp_.nBitsRatio_; }
    int towerMaskE() const { return towerp_.maskE_; }
    int towerMaskH() const { return towerp_.maskH_; }
    int towerMaskSum() const { return towerp_.maskSum_; }
    int towerMaskRatio() const { return towerp_.maskRatio_; }
    bool doTowerEncoding() const { return towerp_.doEncoding_; }

    void setTowerLsbH(double lsb) { towerp_.lsbH_ = lsb; }
    void setTowerLsbE(double lsb) { towerp_.lsbE_ = lsb; }
    void setTowerLsbSum(double lsb) { towerp_.lsbSum_ = lsb; }
    void setTowerNBitsH(int n) {
      towerp_.nBitsH_ = n;
      towerp_.maskH_ = std::pow(2, n) - 1;
    }
    void setTowerNBitsE(int n) {
      towerp_.nBitsE_ = n;
      towerp_.maskE_ = std::pow(2, n) - 1;
    }
    void setTowerNBitsSum(int n) {
      towerp_.nBitsSum_ = n;
      towerp_.maskSum_ = std::pow(2, n) - 1;
    }
    void setTowerNBitsRatio(int n) {
      towerp_.nBitsRatio_ = n;
      towerp_.maskRatio_ = std::pow(2, n) - 1;
    }
    void setTowerEncoding(bool doit) { towerp_.doEncoding_ = doit; }

    // regions
    double regionLsb() const { return regionLsb_; }
    std::string regionPUSType() const { return pnode_[regionPUS].type_; }
    std::vector<double> regionPUSParams() { return pnode_[regionPUS].dparams_; }
    l1t::LUT* regionPUSLUT() { return &pnode_[regionPUS].LUT_; }

    int regionPUSValue(int PUM0, int eta) {
      int puSub = ceil(regionPUSParams()[18 * eta + PUM0] * 2);
      return puSub;
    }

    void setRegionLsb(double lsb) { regionLsb_ = lsb; }
    void setRegionPUSType(std::string type) { pnode_[regionPUS].type_ = type; }
    void setRegionPUSParams(const std::vector<double>& params) { pnode_[regionPUS].dparams_ = params; }
    void setRegionPUSLUT(const l1t::LUT& lut) { pnode_[regionPUS].LUT_ = lut; }

    int pileUpTowerThreshold() const { return pnode_[PUTowerThreshold].iparams_[0]; }
    void setPileUpTowerThreshold(int thresh) {
      pnode_[PUTowerThreshold].iparams_.resize(1);
      pnode_[PUTowerThreshold].iparams_[0] = thresh;
    }

    // EG
    int egEtaCut() const {
      if (pnode_[egPUS].version_ == 1)
        return pnode_[egPUS].iparams_[0];
      else
        return 0;
    }
    double egLsb() const { return egp_.lsb_; }
    double egSeedThreshold() const { return egp_.seedThreshold_; }
    double egNeighbourThreshold() const { return egp_.neighbourThreshold_; }
    double egHcalThreshold() const { return egp_.hcalThreshold_; }
    l1t::LUT* egTrimmingLUT() { return &pnode_[egTrimming].LUT_; }
    double egMaxHcalEt() const { return egp_.maxHcalEt_; }
    double egMaxPtHOverE() const { return egp_.maxPtHOverE_; }
    l1t::LUT* egMaxHOverELUT() { return &pnode_[egMaxHOverE].LUT_; }
    l1t::LUT* egCompressShapesLUT() { return &pnode_[egCompressShapes].LUT_; }
    l1t::LUT* egShapeIdLUT() { return &pnode_[egShapeId].LUT_; }
    int egMinPtJetIsolation() const { return egp_.minPtJetIsolation_; }
    int egMaxPtJetIsolation() const { return egp_.maxPtJetIsolation_; }
    int egMinPtHOverEIsolation() const { return egp_.minPtHOverEIsolation_; }
    int egMaxPtHOverEIsolation() const { return egp_.maxPtHOverEIsolation_; }
    unsigned egBypassEGVetos() { return pnode_[egBypassEGVetosFlag].uparams_[0]; }
    unsigned egBypassExtHOverE() { return pnode_[egBypassExtHoE].uparams_[0]; }
    unsigned egBypassShape() const {
      if (pnode_[egBypassShapeFlag].uparams_.empty())
        return 0;
      else
        return pnode_[egBypassShapeFlag].uparams_[0];
    }
    unsigned egBypassECALFG() const {
      if (pnode_[egBypassECALFGFlag].uparams_.empty())
        return 0;
      else
        return pnode_[egBypassECALFGFlag].uparams_[0];
    }
    unsigned egBypassHoE() const {
      if (pnode_[egBypassHoEFlag].uparams_.empty())
        return 0;
      else
        return pnode_[egBypassHoEFlag].uparams_[0];
    }

    int egHOverEcutBarrel() const { return pnode_[egHOverEBarrel].iparams_[0]; }
    int egHOverEcutEndcap() const { return pnode_[egHOverEEndcap].iparams_[0]; }

    unsigned egIsoAreaNrTowersEta() const { return egp_.isoAreaNrTowersEta_; }
    unsigned egIsoAreaNrTowersPhi() const { return egp_.isoAreaNrTowersPhi_; }
    unsigned egIsoVetoNrTowersPhi() const { return egp_.isoVetoNrTowersPhi_; }
    const std::string& egPUSType() const { return pnode_[egPUS].type_; }
    const std::vector<double>& egPUSParams() const { return pnode_[egPUS].dparams_; }
    double egPUSParam(int ipar) const { return pnode_[egPUS].dparams_.at(ipar); }

    std::string egIsolationType() const { return pnode_[egIsolation].type_; }
    l1t::LUT* egIsolationLUT() { return &pnode_[egIsolation].LUT_; }
    l1t::LUT* egIsolationLUT2() { return &pnode_[egIsolation2].LUT_; }
    std::string egCalibrationType() const { return pnode_[egCalibration].type_; }
    std::vector<double> egCalibrationParams() { return pnode_[egCalibration].dparams_; }
    l1t::LUT* egCalibrationLUT() { return &pnode_[egCalibration].LUT_; }

    void setEgEtaCut(int mask) {
      pnode_[egPUS].iparams_.resize(1);
      pnode_[egPUS].iparams_[0] = mask;
    }
    void setEgLsb(double lsb) { egp_.lsb_ = lsb; }
    void setEgSeedThreshold(double thresh) { egp_.seedThreshold_ = thresh; }
    void setEgNeighbourThreshold(double thresh) { egp_.neighbourThreshold_ = thresh; }
    void setEgHcalThreshold(double thresh) { egp_.hcalThreshold_ = thresh; }
    void setEgTrimmingLUT(const l1t::LUT& lut) { pnode_[egTrimming].LUT_ = lut; }
    void setEgMaxHcalEt(double cut) { egp_.maxHcalEt_ = cut; }
    void setEgMaxPtHOverE(double thresh) { egp_.maxPtHOverE_ = thresh; }
    void setEgMaxHOverELUT(const l1t::LUT& lut) { pnode_[egMaxHOverE].LUT_ = lut; }
    void setEgCompressShapesLUT(const l1t::LUT& lut) { pnode_[egCompressShapes].LUT_ = lut; }
    void setEgShapeIdLUT(const l1t::LUT& lut) { pnode_[egShapeId].LUT_ = lut; }
    void setEgMinPtJetIsolation(int cutValue) { egp_.minPtJetIsolation_ = cutValue; }
    void setEgMaxPtJetIsolation(int cutValue) { egp_.maxPtJetIsolation_ = cutValue; }
    void setEgMinPtHOverEIsolation(int cutValue) { egp_.minPtHOverEIsolation_ = cutValue; }
    void setEgMaxPtHOverEIsolation(int cutValue) { egp_.maxPtHOverEIsolation_ = cutValue; }
    void setEgBypassEGVetos(unsigned flag) {
      pnode_[egBypassEGVetosFlag].uparams_.resize(1);
      pnode_[egBypassEGVetosFlag].uparams_[0] = flag;
    }
    void setEgBypassShape(unsigned flag) {
      pnode_[egBypassShapeFlag].uparams_.resize(1);
      pnode_[egBypassShapeFlag].uparams_[0] = flag;
    }
    void setEgBypassECALFG(unsigned flag) {
      pnode_[egBypassECALFGFlag].uparams_.resize(1);
      pnode_[egBypassECALFGFlag].uparams_[0] = flag;
    }
    void setEgBypassExtHOverE(unsigned flag) {
      pnode_[egBypassExtHoE].uparams_.resize(1);
      pnode_[egBypassExtHoE].uparams_[0] = flag;
    }
    void setEgHOverEcutBarrel(int cut) {
      pnode_[egHOverEBarrel].iparams_.resize(1);
      pnode_[egHOverEBarrel].iparams_[0] = cut;
    }
    void setEgHOverEcutEndcap(int cut) {
      pnode_[egHOverEEndcap].iparams_.resize(1);
      pnode_[egHOverEEndcap].iparams_[0] = cut;
    }

    void setEgIsoAreaNrTowersEta(unsigned iEgIsoAreaNrTowersEta) { egp_.isoAreaNrTowersEta_ = iEgIsoAreaNrTowersEta; }
    void setEgIsoAreaNrTowersPhi(unsigned iEgIsoAreaNrTowersPhi) { egp_.isoAreaNrTowersPhi_ = iEgIsoAreaNrTowersPhi; }
    void setEgIsoVetoNrTowersPhi(unsigned iEgIsoVetoNrTowersPhi) { egp_.isoVetoNrTowersPhi_ = iEgIsoVetoNrTowersPhi; }
    void setEgPUSType(std::string type) { pnode_[egPUS].type_ = type; }
    void setEgPUSParams(const std::vector<double>& params) { pnode_[egPUS].dparams_ = params; }
    void setEgIsolationType(std::string type) { pnode_[egIsolation].type_ = type; }
    void setEgIsolationLUT(const l1t::LUT& lut) { pnode_[egIsolation].LUT_ = lut; }
    void setEgIsolationLUT2(const l1t::LUT& lut) { pnode_[egIsolation2].LUT_ = lut; }
    void setEgCalibrationType(std::string type) { pnode_[egCalibration].type_ = type; }
    void setEgCalibrationParams(std::vector<double> params) { pnode_[egCalibration].dparams_ = params; }
    void setEgCalibrationLUT(const l1t::LUT& lut) { pnode_[egCalibration].LUT_ = lut; }

    // - recently imported:
    std::string egShapeIdType() const { return pnode_[egShapeId].type_; }
    void setEgShapeIdType(std::string type) { pnode_[egShapeId].type_ = type; }
    unsigned egShapeIdVersion() const { return pnode_[egShapeId].version_; }
    void setEgShapeIdVersion(unsigned version) { pnode_[egShapeId].version_ = version; }
    unsigned egCalibrationVersion() const { return pnode_[egCalibration].version_; }
    void setEgCalibrationVersion(unsigned version) { pnode_[egCalibration].version_ = version; }

    // tau
    int tauRegionMask() const {
      if (pnode_[tauPUS].version_ == 1)
        return pnode_[tauPUS].iparams_[0];
      else
        return 0;
    }
    double tauLsb() const { return taup_.lsb_; }
    double tauSeedThreshold() const { return taup_.seedThreshold_; }
    double tauNeighbourThreshold() const { return taup_.neighbourThreshold_; }
    double tauMaxPtTauVeto() const { return taup_.maxPtTauVeto_; }
    double tauMinPtJetIsolationB() const { return taup_.minPtJetIsolationB_; }
    double tauMaxJetIsolationB() const { return taup_.maxJetIsolationB_; }
    double tauMaxJetIsolationA() const { return taup_.maxJetIsolationA_; }
    int isoTauEtaMin() const { return taup_.isoEtaMin_; }
    int isoTauEtaMax() const { return taup_.isoEtaMax_; }
    std::string tauPUSType() const { return pnode_[tauPUS].type_; }
    const std::vector<double>& tauPUSParams() const { return pnode_[tauPUS].dparams_; }
    double tauPUSParam(int ipar) const { return pnode_[tauPUS].dparams_.at(ipar); }

    l1t::LUT* tauIsolationLUT() { return &pnode_[tauIsolation].LUT_; }
    l1t::LUT* tauIsolationLUT2() { return &pnode_[tauIsolation2].LUT_; }
    l1t::LUT* tauTrimmingShapeVetoLUT() { return &pnode_[tauTrimmingShapeVeto].LUT_; }

    std::string tauCalibrationType() const { return pnode_[tauCalibration].type_; }
    std::vector<double> tauCalibrationParams() { return pnode_[tauCalibration].dparams_; }
    l1t::LUT* tauCalibrationLUT() { return &pnode_[tauCalibration].LUT_; }
    l1t::LUT* tauCompressLUT() { return &pnode_[tauCompress].LUT_; }

    l1t::LUT* tauEtToHFRingEtLUT() { return &pnode_[tauEtToHFRingEt].LUT_; }

    unsigned tauIsoAreaNrTowersEta() const { return taup_.isoAreaNrTowersEta_; }
    unsigned tauIsoAreaNrTowersPhi() const { return taup_.isoAreaNrTowersPhi_; }
    unsigned tauIsoVetoNrTowersPhi() const { return taup_.isoVetoNrTowersPhi_; }

    void setTauRegionMask(int mask) {
      pnode_[tauPUS].iparams_.resize(1);
      pnode_[tauPUS].iparams_[0] = mask;
    }
    void setTauLsb(double lsb) { taup_.lsb_ = lsb; }
    void setTauSeedThreshold(double thresh) { taup_.seedThreshold_ = thresh; }
    void setTauNeighbourThreshold(double thresh) { taup_.neighbourThreshold_ = thresh; }
    void setTauMaxPtTauVeto(double limit) { taup_.maxPtTauVeto_ = limit; }
    void setTauMinPtJetIsolationB(double limit) { taup_.minPtJetIsolationB_ = limit; }
    void setTauMaxJetIsolationB(double limit) { taup_.maxJetIsolationB_ = limit; }
    void setTauMaxJetIsolationA(double cutValue) { taup_.maxJetIsolationA_ = cutValue; }
    void setIsoTauEtaMin(int value) { taup_.isoEtaMin_ = value; }
    void setIsoTauEtaMax(int value) { taup_.isoEtaMax_ = value; }
    void setTauPUSType(std::string type) { pnode_[tauPUS].type_ = type; }
    void setTauIsolationLUT(const l1t::LUT& lut) { pnode_[tauIsolation].LUT_ = lut; }
    void setTauIsolationLUT2(const l1t::LUT& lut) { pnode_[tauIsolation2].LUT_ = lut; }
    void setTauTrimmingShapeVetoLUT(const l1t::LUT& lut) { pnode_[tauTrimmingShapeVeto].LUT_ = lut; }

    void setTauCalibrationType(std::string type) { pnode_[tauCalibration].type_ = type; }
    void setTauIsoAreaNrTowersEta(unsigned iTauIsoAreaNrTowersEta) {
      taup_.isoAreaNrTowersEta_ = iTauIsoAreaNrTowersEta;
    }
    void setTauIsoAreaNrTowersPhi(unsigned iTauIsoAreaNrTowersPhi) {
      taup_.isoAreaNrTowersPhi_ = iTauIsoAreaNrTowersPhi;
    }
    void setTauIsoVetoNrTowersPhi(unsigned iTauIsoVetoNrTowersPhi) {
      taup_.isoVetoNrTowersPhi_ = iTauIsoVetoNrTowersPhi;
    }

    void setTauCalibrationParams(std::vector<double> params) { pnode_[tauCalibration].dparams_ = params; }
    void setTauCalibrationLUT(const l1t::LUT& lut) { pnode_[tauCalibration].LUT_ = lut; }
    void setTauCompressLUT(const l1t::LUT& lut) { pnode_[tauCompress].LUT_ = lut; }
    void setTauPUSParams(const std::vector<double>& params) { pnode_[tauPUS].dparams_ = params; }

    void setTauEtToHFRingEtLUT(const l1t::LUT& lut) { pnode_[tauEtToHFRingEt].LUT_ = lut; }

    // jets
    double jetLsb() const { return jetp_.lsb_; }
    double jetSeedThreshold() const { return jetp_.seedThreshold_; }
    double jetNeighbourThreshold() const { return jetp_.neighbourThreshold_; }
    int jetRegionMask() const {
      if (pnode_[jetPUS].version_ == 1)
        return pnode_[jetPUS].iparams_[0];
      else
        return 0;
    }

    unsigned jetBypassPUS() const { return pnode_[jetBypassPUSFlag].uparams_[0]; }
    unsigned jetPUSUsePhiRing() const {
      if (pnode_[jetPUSUsePhiRingFlag].uparams_.empty())
        return 0;
      else
        return pnode_[jetPUSUsePhiRingFlag].uparams_[0];
    }

    std::string jetPUSType() const { return pnode_[jetPUS].type_; }
    std::vector<double> jetPUSParams() { return pnode_[jetPUS].dparams_; }
    std::string jetCalibrationType() const { return pnode_[jetCalibration].type_; }
    std::vector<double> jetCalibrationParams() { return pnode_[jetCalibration].dparams_; }

    l1t::LUT* jetCalibrationLUT() { return &pnode_[jetCalibration].LUT_; }
    l1t::LUT* jetCompressPtLUT() { return &pnode_[jetCompressPt].LUT_; }
    l1t::LUT* jetCompressEtaLUT() { return &pnode_[jetCompressEta].LUT_; }

    void setJetLsb(double lsb) { jetp_.lsb_ = lsb; }
    void setJetSeedThreshold(double thresh) { jetp_.seedThreshold_ = thresh; }
    void setJetNeighbourThreshold(double thresh) { jetp_.neighbourThreshold_ = thresh; }
    void setJetRegionMask(int mask) {
      pnode_[jetPUS].iparams_.resize(1);
      pnode_[jetPUS].iparams_[0] = mask;
    }
    void setJetPUSType(std::string type) { pnode_[jetPUS].type_ = type; }
    void setJetPUSParams(std::vector<double> params) { pnode_[jetPUS].dparams_ = params; }
    void setJetCalibrationType(std::string type) { pnode_[jetCalibration].type_ = type; }
    void setJetCalibrationParams(std::vector<double> params) { pnode_[jetCalibration].dparams_ = params; }
    void setJetCalibrationLUT(const l1t::LUT& lut) { pnode_[jetCalibration].LUT_ = lut; }
    void setJetCompressEtaLUT(const l1t::LUT& lut) { pnode_[jetCompressEta].LUT_ = lut; }
    void setJetCompressPtLUT(const l1t::LUT& lut) { pnode_[jetCompressPt].LUT_ = lut; }
    void setJetBypassPUS(unsigned flag) {
      pnode_[jetBypassPUSFlag].uparams_.resize(1);
      pnode_[jetBypassPUSFlag].uparams_[0] = flag;
    }
    void setJetPUSUsePhiRing(unsigned flag) {
      pnode_[jetPUSUsePhiRingFlag].uparams_.resize(1);
      pnode_[jetPUSUsePhiRingFlag].uparams_[0] = flag;
    }
    // sums

    double etSumLsb() const { return etSumLsb_; }
    int etSumEtaMin(unsigned isum) const {
      if (etSumEtaMin_.size() > isum)
        return etSumEtaMin_.at(isum);
      else
        return 0;
    }
    int etSumEtaMax(unsigned isum) const {
      if (etSumEtaMax_.size() > isum)
        return etSumEtaMax_.at(isum);
      else
        return 0;
    }
    double etSumEtThreshold(unsigned isum) const {
      if (etSumEtThreshold_.size() > isum)
        return etSumEtThreshold_.at(isum);
      else
        return 0.;
    }
    unsigned etSumBypassMetPUS() const { return pnode_[etSumBypassMetPUSFlag].uparams_[0]; }
    unsigned etSumBypassEttPUS() const { return pnode_[etSumBypassEttPUSFlag].uparams_[0]; }
    unsigned etSumBypassEcalSumPUS() const { return pnode_[etSumBypassEcalSumPUSFlag].uparams_[0]; }
    std::string etSumMetPUSType() const { return pnode_[etSumMetPUS].type_; }
    std::string etSumEttPUSType() const { return pnode_[etSumEttPUS].type_; }
    std::string etSumEcalSumPUSType() const { return pnode_[etSumEcalSumPUS].type_; }
    std::string metCalibrationType() const { return pnode_[metCalibration].type_; }
    std::string metHFCalibrationType() const { return pnode_[metHFCalibration].type_; }
    std::string etSumEttCalibrationType() const { return pnode_[etSumEttCalibration].type_; }
    std::string etSumEcalSumCalibrationType() const { return pnode_[etSumEcalSumCalibration].type_; }

    l1t::LUT* etSumMetPUSLUT() { return &pnode_[etSumMetPUS].LUT_; }
    l1t::LUT* etSumEttPUSLUT() { return &pnode_[etSumEttPUS].LUT_; }
    l1t::LUT* etSumEcalSumPUSLUT() { return &pnode_[etSumEcalSumPUS].LUT_; }
    l1t::LUT* metCalibrationLUT() { return &pnode_[metCalibration].LUT_; }
    l1t::LUT* metHFCalibrationLUT() { return &pnode_[metHFCalibration].LUT_; }
    l1t::LUT* etSumEttCalibrationLUT() { return &pnode_[etSumEttCalibration].LUT_; }
    l1t::LUT* etSumEcalSumCalibrationLUT() { return &pnode_[etSumEcalSumCalibration].LUT_; }
    l1t::LUT* metPhiCalibrationLUT() { return &pnode_[metPhiCalibration].LUT_; }
    l1t::LUT* metHFPhiCalibrationLUT() { return &pnode_[metHFPhiCalibration].LUT_; }

    void setEtSumLsb(double lsb) { etSumLsb_ = lsb; }
    void setEtSumEtaMin(unsigned isum, int eta) {
      if (etSumEtaMin_.size() <= isum)
        etSumEtaMin_.resize(isum + 1);
      etSumEtaMin_.at(isum) = eta;
    }
    void setEtSumEtaMax(unsigned isum, int eta) {
      if (etSumEtaMax_.size() <= isum)
        etSumEtaMax_.resize(isum + 1);
      etSumEtaMax_.at(isum) = eta;
    }
    void setEtSumEtThreshold(unsigned isum, double thresh) {
      if (etSumEtThreshold_.size() <= isum)
        etSumEtThreshold_.resize(isum + 1);
      etSumEtThreshold_.at(isum) = thresh;
    }
    void setEtSumMetPUSType(std::string type) { pnode_[etSumMetPUS].type_ = type; }
    void setEtSumEttPUSType(std::string type) { pnode_[etSumEttPUS].type_ = type; }
    void setEtSumEcalSumPUSType(std::string type) { pnode_[etSumEcalSumPUS].type_ = type; }
    void setMetCalibrationType(std::string type) { pnode_[metCalibration].type_ = type; }
    void setMetHFCalibrationType(std::string type) { pnode_[metHFCalibration].type_ = type; }
    void setEtSumEttCalibrationType(std::string type) { pnode_[etSumEttCalibration].type_ = type; }
    void setEtSumEcalSumCalibrationType(std::string type) { pnode_[etSumEcalSumCalibration].type_ = type; }
    void setEtSumBypassMetPUS(unsigned flag) {
      pnode_[etSumBypassMetPUSFlag].uparams_.resize(1);
      pnode_[etSumBypassMetPUSFlag].uparams_[0] = flag;
    }
    void setEtSumBypassEttPUS(unsigned flag) {
      pnode_[etSumBypassEttPUSFlag].uparams_.resize(1);
      pnode_[etSumBypassEttPUSFlag].uparams_[0] = flag;
    }
    void setEtSumBypassEcalSumPUS(unsigned flag) {
      pnode_[etSumBypassEcalSumPUSFlag].uparams_.resize(1);
      pnode_[etSumBypassEcalSumPUSFlag].uparams_[0] = flag;
    }

    void setEtSumMetPUSLUT(const l1t::LUT& lut) { pnode_[etSumMetPUS].LUT_ = lut; }
    void setEtSumEttPUSLUT(const l1t::LUT& lut) { pnode_[etSumEttPUS].LUT_ = lut; }
    void setEtSumEcalSumPUSLUT(const l1t::LUT& lut) { pnode_[etSumEcalSumPUS].LUT_ = lut; }
    void setMetCalibrationLUT(const l1t::LUT& lut) { pnode_[metCalibration].LUT_ = lut; }
    void setMetHFCalibrationLUT(const l1t::LUT& lut) { pnode_[metHFCalibration].LUT_ = lut; }
    void setEtSumEttCalibrationLUT(const l1t::LUT& lut) { pnode_[etSumEttCalibration].LUT_ = lut; }
    void setEtSumEcalSumCalibrationLUT(const l1t::LUT& lut) { pnode_[etSumEcalSumCalibration].LUT_ = lut; }
    void setMetPhiCalibrationLUT(const l1t::LUT& lut) { pnode_[metPhiCalibration].LUT_ = lut; }
    void setMetHFPhiCalibrationLUT(const l1t::LUT& lut) { pnode_[metHFPhiCalibration].LUT_ = lut; }

    double etSumCentLower(unsigned centClass) const {
      if (pnode_[etSumCentralityLower].dparams_.size() > centClass)
        return pnode_[etSumCentralityLower].dparams_.at(centClass);
      else
        return 0.;
    }

    double etSumCentUpper(unsigned centClass) const {
      if (pnode_[etSumCentralityUpper].dparams_.size() > centClass)
        return pnode_[etSumCentralityUpper].dparams_.at(centClass);
      else
        return 0.;
    }

    void setEtSumCentLower(unsigned centClass, double loBound) {
      if (pnode_[etSumCentralityLower].dparams_.size() <= centClass)
        pnode_[etSumCentralityLower].dparams_.resize(centClass + 1);
      pnode_[etSumCentralityLower].dparams_.at(centClass) = loBound;
    }

    void setEtSumCentUpper(unsigned centClass, double upBound) {
      if (pnode_[etSumCentralityUpper].dparams_.size() <= centClass)
        pnode_[etSumCentralityUpper].dparams_.resize(centClass + 1);
      pnode_[etSumCentralityUpper].dparams_.at(centClass) = upBound;
    }

    // HI centrality
    int centralityRegionMask() const {
      if (pnode_[hiCentrality].version_ == 1)
        return pnode_[hiCentrality].iparams_[0];
      else
        return 0;
    }
    std::vector<int> minimumBiasThresholds() const {
      if (pnode_[hiCentrality].version_ == 1 && pnode_[hiCentrality].iparams_.size() == 5) {
        std::vector<int> newVec;
        newVec.reserve(4);
        for (int i = 0; i < 4; i++) {
          newVec.push_back(pnode_[hiCentrality].iparams_.at(i + 1));
        }
        return newVec;
      } else {
        std::vector<int> newVec;
        return newVec;
      }
    }
    l1t::LUT* centralityLUT() { return &pnode_[hiCentrality].LUT_; }
    void setCentralityRegionMask(int mask) {
      pnode_[hiCentrality].iparams_.resize(5);
      pnode_[hiCentrality].iparams_[0] = mask;
    }
    void setMinimumBiasThresholds(std::vector<int> thresholds) {
      pnode_[hiCentrality].iparams_.resize(5);
      for (int i = 0; i < 4; i++) {
        pnode_[hiCentrality].iparams_[i + 1] = thresholds.at(i);
      }
    }
    void setCentralityLUT(const l1t::LUT& lut) { pnode_[hiCentrality].LUT_ = lut; }

    // HI Q2
    l1t::LUT* q2LUT() { return &pnode_[hiQ2].LUT_; }
    void setQ2LUT(const l1t::LUT& lut) { pnode_[hiQ2].LUT_ = lut; }

    // HI parameters

    // Layer 1 LUT specification
    std::vector<double> layer1ECalScaleFactors() { return pnode_[layer1ECal].dparams_; }
    std::vector<double> layer1HCalScaleFactors() { return pnode_[layer1HCal].dparams_; }
    std::vector<double> layer1HFScaleFactors() { return pnode_[layer1HF].dparams_; }
    std::vector<int> layer1ECalScaleETBins() { return pnode_[layer1ECal].iparams_; }
    std::vector<int> layer1HCalScaleETBins() { return pnode_[layer1HCal].iparams_; }
    std::vector<int> layer1HFScaleETBins() { return pnode_[layer1HF].iparams_; }
    std::vector<unsigned> layer1ECalScalePhiBins() { return pnode_[layer1ECal].uparams_; }
    std::vector<unsigned> layer1HCalScalePhiBins() { return pnode_[layer1HCal].uparams_; }
    std::vector<unsigned> layer1HFScalePhiBins() { return pnode_[layer1HF].uparams_; }
    void setLayer1ECalScaleFactors(const std::vector<double> params) { pnode_[layer1ECal].dparams_ = params; }
    void setLayer1HCalScaleFactors(const std::vector<double> params) { pnode_[layer1HCal].dparams_ = params; }
    void setLayer1HFScaleFactors(const std::vector<double> params) { pnode_[layer1HF].dparams_ = params; }
    void setLayer1ECalScaleETBins(const std::vector<int> params) { pnode_[layer1ECal].iparams_ = params; }
    void setLayer1HCalScaleETBins(const std::vector<int> params) { pnode_[layer1HCal].iparams_ = params; }
    void setLayer1HFScaleETBins(const std::vector<int> params) { pnode_[layer1HF].iparams_ = params; }
    void setLayer1ECalScalePhiBins(const std::vector<unsigned> params) { pnode_[layer1ECal].uparams_ = params; }
    void setLayer1HCalScalePhiBins(const std::vector<unsigned> params) { pnode_[layer1HCal].uparams_ = params; }
    void setLayer1HFScalePhiBins(const std::vector<unsigned> params) { pnode_[layer1HF].uparams_ = params; }

    std::vector<unsigned> layer1SecondStageLUT() { return pnode_[layer1HOverE].uparams_; }
    void setLayer1SecondStageLUT(const std::vector<unsigned>& lut) { pnode_[layer1HOverE].uparams_ = lut; }

  private:
    L1CaloEtScale emScale_;
    L1CaloEtScale jetScale_;
    L1CaloEtScale HtMissScale_;
    L1CaloEtScale HfRingScale_;
  };

}  // namespace l1t

#endif