L1GtTriggerMenuConfigOnlineProd.cc

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// this class header
#include "L1TriggerConfig/L1GtConfigProducers/interface/L1GtTriggerMenuConfigOnlineProd.h"

// system include files
#include <string>
#include <vector>
#include <map>
#include <list>
#include <utility>
#include <algorithm>

// user include files
#include "FWCore/MessageLogger/interface/MessageLogger.h"

#include "CondFormats/L1TObjects/interface/L1GtTriggerMenuFwd.h"
#include "CondFormats/L1TObjects/interface/L1GtFwd.h"

#include "CondFormats/L1TObjects/interface/L1GtTriggerMenu.h"

#include "CondFormats/L1TObjects/interface/L1GtCondition.h"
#include "CondFormats/L1TObjects/interface/L1GtAlgorithm.h"

// constructor
L1GtTriggerMenuConfigOnlineProd::L1GtTriggerMenuConfigOnlineProd(const edm::ParameterSet& parSet)
    : L1ConfigOnlineProdBase<L1GtTriggerMenuRcd, L1GtTriggerMenu>(parSet), m_isDebugEnabled(edm::isDebugEnabled()) {
  // empty
}

// destructor
L1GtTriggerMenuConfigOnlineProd::~L1GtTriggerMenuConfigOnlineProd() {
  // empty
}

// public methods

// initialize the class (mainly reserve/resize)
void L1GtTriggerMenuConfigOnlineProd::init(const int numberConditionChips) {
  // resize the vectors of condition maps
  // the number of condition chips should be correctly set

  m_vecMuonTemplate.resize(numberConditionChips);
  m_vecCaloTemplate.resize(numberConditionChips);
  m_vecEnergySumTemplate.resize(numberConditionChips);
  m_vecJetCountsTemplate.resize(numberConditionChips);
  m_vecCastorTemplate.resize(numberConditionChips);
  m_vecHfBitCountsTemplate.resize(numberConditionChips);
  m_vecHfRingEtSumsTemplate.resize(numberConditionChips);
  m_vecBptxTemplate.resize(numberConditionChips);
  m_vecExternalTemplate.resize(numberConditionChips);

  m_vecCorrelationTemplate.resize(numberConditionChips);
  m_corMuonTemplate.resize(numberConditionChips);
  m_corCaloTemplate.resize(numberConditionChips);
  m_corEnergySumTemplate.resize(numberConditionChips);
}

std::unique_ptr<L1GtTriggerMenu> L1GtTriggerMenuConfigOnlineProd::newObject(const std::string& objectKey) {
  // FIXME seems to not work anymore in constructor...
  m_isDebugEnabled = edm::isDebugEnabled();

  auto pL1GtTriggerMenuEmpty = std::make_unique<L1GtTriggerMenu>();

  // FIXME get it from L1GtStableParameters?
  //       initialize once, from outside
  const unsigned int numberConditionChips = 2;
  init(numberConditionChips);

  const std::string gtSchema = "CMS_GT";

  // l1GtTriggerMenu: parameters in table GTFE_SETUP_FK
  // the objectKey for the menu obtained from GT_SETUP is the L1T_MENU_IMPL key

  // SQL queries:

  // retrieve table with general menu parameters from DB, view L1T_MENU_GENERAL_VIEW
  if (!tableMenuGeneralFromDB(gtSchema, objectKey)) {
    return pL1GtTriggerMenuEmpty;
  }

  // build the menu name
  std::string menuName =
      m_tableMenuGeneral.menuInterface + "/" + m_tableMenuGeneral.scalesKey + "/" + m_tableMenuGeneral.algoImplTag;

  // retrieve table with physics algorithms from DB, view L1T_MENU_ALGO_VIEW
  if (!tableMenuAlgoFromDB(gtSchema, objectKey)) {
    return pL1GtTriggerMenuEmpty;
  }

  // retrieve table with conditions associated to physics algorithms from DB
  if (!tableMenuAlgoCondFromDB(gtSchema, objectKey)) {
    return pL1GtTriggerMenuEmpty;
  }

  // retrieve table with list of conditions in the menu
  if (!tableMenuCondFromDB(gtSchema, objectKey)) {
    return pL1GtTriggerMenuEmpty;
  }

  // retrieve table with object parameters from DB, view CMS_GT.L1T_MENU_OP_VIEW
  if (!tableMenuObjectParametersFromDB(gtSchema, objectKey)) {
    return pL1GtTriggerMenuEmpty;
  }

  // retrieve table with technical triggers from DB, view L1T_MENU_TECHTRIG_VIEW
  if (!tableMenuTechTrigFromDB(gtSchema, objectKey)) {
    return pL1GtTriggerMenuEmpty;
  }

  // build the algorithm map in the menu
  buildAlgorithmMap();

  // build the technical trigger map in the menu
  buildTechnicalTriggerMap();

  // add the conditions from a menu to the corresponding list
  addConditions();

  // fill the record
  auto pL1GtTriggerMenu = std::make_unique<L1GtTriggerMenu>(menuName,
                                                            numberConditionChips,
                                                            m_vecMuonTemplate,
                                                            m_vecCaloTemplate,
                                                            m_vecEnergySumTemplate,
                                                            m_vecJetCountsTemplate,
                                                            m_vecCastorTemplate,
                                                            m_vecHfBitCountsTemplate,
                                                            m_vecHfRingEtSumsTemplate,
                                                            m_vecBptxTemplate,
                                                            m_vecExternalTemplate,
                                                            m_vecCorrelationTemplate,
                                                            m_corMuonTemplate,
                                                            m_corCaloTemplate,
                                                            m_corEnergySumTemplate);

  pL1GtTriggerMenu->setGtTriggerMenuInterface(m_tableMenuGeneral.menuInterface);
  pL1GtTriggerMenu->setGtTriggerMenuImplementation(m_tableMenuGeneral.menuImplementation);
  pL1GtTriggerMenu->setGtScaleDbKey(m_tableMenuGeneral.scalesKey);

  pL1GtTriggerMenu->setGtAlgorithmMap(m_algorithmMap);
  pL1GtTriggerMenu->setGtAlgorithmAliasMap(m_algorithmAliasMap);
  pL1GtTriggerMenu->setGtTechnicalTriggerMap(m_technicalTriggerMap);

  if (m_isDebugEnabled) {
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\nThe following L1GtTriggerMenu record was read from OMDS: \n"
                                                << std::endl;

    std::ostringstream myCoutStream;
    int verbosity = 0;
    pL1GtTriggerMenu->print(myCoutStream, verbosity);
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\n" << std::endl;

    verbosity = 2;
    pL1GtTriggerMenu->print(myCoutStream, verbosity);
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << myCoutStream.str() << "\n" << std::endl;
  }

  return pL1GtTriggerMenu;
}

// retrieve table with general menu parameters from DB
bool L1GtTriggerMenuConfigOnlineProd::tableMenuGeneralFromDB(const std::string& gtSchema,
                                                             const std::string& objectKey) {
  // select * from CMS_GT.L1T_MENU_GENERAL_VIEW
  //     where L1T_MENU_GENERAL_VIEW.MENU_IMPLEMENTATION = objectKey

  const std::vector<std::string>& columns = m_omdsReader.columnNamesView(gtSchema, "L1T_MENU_GENERAL_VIEW");

  if (m_isDebugEnabled) {
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\n List of columns in L1T_MENU_GENERAL_VIEW:\n" << std::endl;
    for (std::vector<std::string>::const_iterator iter = columns.begin(); iter != columns.end(); iter++) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd") << (*iter) << std::endl;
    }
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\n\n" << std::endl;
  }

  l1t::OMDSReader::QueryResults results = m_omdsReader.basicQueryView(columns,
                                                                      gtSchema,
                                                                      "L1T_MENU_GENERAL_VIEW",
                                                                      "L1T_MENU_GENERAL_VIEW.MENU_IMPLEMENTATION",
                                                                      m_omdsReader.singleAttribute(objectKey));

  // check if query was successful
  if (results.queryFailed()) {
    edm::LogError("L1-O2O")
        << "Problem to get content of L1T_MENU_GENERAL_VIEW for L1GtTriggerMenu implementation key: " << objectKey;
    return false;
  }

  // retrieve menu interface name, scales key, algorithm implementation tag

  for (std::vector<std::string>::const_iterator constIt = columns.begin(); constIt != columns.end(); ++constIt) {
    if ((*constIt) == "MENU_IMPLEMENTATION") {
      results.fillVariable(*constIt, m_tableMenuGeneral.menuImplementation);

    } else if ((*constIt) == "INTERFACE") {
      results.fillVariable(*constIt, m_tableMenuGeneral.menuInterface);

    } else if ((*constIt) == "SCALES_KEY") {
      results.fillVariable(*constIt, m_tableMenuGeneral.scalesKey);

    } else if ((*constIt) == "ALGO_IMPL_TAG") {
      results.fillVariable(*constIt, m_tableMenuGeneral.algoImplTag);

    } else {
      // do nothing
    }
  }

  // cross checks
  if (m_tableMenuGeneral.menuImplementation != objectKey) {
    LogTrace("L1GtTriggerMenuConfigOnlineProd")
        << "\n L1 trigger menu implementation read from querying view not identical"
        << "\n with menu key:"
        << "\n   from view: " << m_tableMenuGeneral.menuImplementation << "\n   from key:  " << objectKey
        << "\n Menu implementation name set from key." << std::endl;
    m_tableMenuGeneral.menuImplementation = objectKey;
  }

  //
  return true;
}

// retrieve table with physics algorithms from DB
bool L1GtTriggerMenuConfigOnlineProd::tableMenuAlgoFromDB(const std::string& gtSchema, const std::string& objectKey) {
  // select * from CMS_GT.L1T_MENU_ALGO_VIEW
  //     where L1T_MENU_ALGO_VIEW.MENU_IMPLEMENTATION = objectKey

  const std::vector<std::string>& columnsMenuAlgo = m_omdsReader.columnNamesView(gtSchema, "L1T_MENU_ALGO_VIEW");

  if (m_isDebugEnabled) {
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\n List of columns in L1T_MENU_ALGO_VIEW:\n" << std::endl;
    for (std::vector<std::string>::const_iterator iter = columnsMenuAlgo.begin(); iter != columnsMenuAlgo.end();
         iter++) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd") << (*iter) << std::endl;
    }
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\n\n" << std::endl;
  }

  l1t::OMDSReader::QueryResults resultsMenuAlgo = m_omdsReader.basicQueryView(columnsMenuAlgo,
                                                                              gtSchema,
                                                                              "L1T_MENU_ALGO_VIEW",
                                                                              "L1T_MENU_ALGO_VIEW.MENU_IMPLEMENTATION",
                                                                              m_omdsReader.singleAttribute(objectKey));

  // check if query was successful is based on size of returned list
  // BUT one can have menus w/o physics algorithms - no error for empty list, but a warning!
  if (resultsMenuAlgo.queryFailed()) {
    edm::LogWarning("L1-O2O") << "Warning: Content of L1T_MENU_ALGO_VIEW for L1GtTriggerMenu implementation key: "
                              << "\n  " << objectKey << "\nis empty!"
                              << "\nNo physics algorithms are found for this menu.";
  }

  TableMenuAlgo menuAlgo;
  int resultsMenuAlgoRows = resultsMenuAlgo.numberRows();

  for (int iRow = 0; iRow < resultsMenuAlgoRows; ++iRow) {
    for (std::vector<std::string>::const_iterator constIt = columnsMenuAlgo.begin(); constIt != columnsMenuAlgo.end();
         ++constIt) {
      if ((*constIt) == "ALGO_INDEX") {
        resultsMenuAlgo.fillVariableFromRow(*constIt, iRow, menuAlgo.bitNumberSh);

      } else if ((*constIt) == "NAME") {
        resultsMenuAlgo.fillVariableFromRow(*constIt, iRow, menuAlgo.algName);

      } else if ((*constIt) == "ALIAS") {
        resultsMenuAlgo.fillVariableFromRow(*constIt, iRow, menuAlgo.algAlias);

      } else if ((*constIt) == "LOGICEXPR") {
        resultsMenuAlgo.fillVariableFromRow(*constIt, iRow, menuAlgo.logExpression);

      } else {
        // do nothing
      }
    }

    LogTrace("L1GtTriggerMenuConfigOnlineProd")
        << "Row  " << iRow << ": index = " << menuAlgo.bitNumberSh << " algName = " << menuAlgo.algName
        << " algAlias = " << menuAlgo.algAlias << " logExpression = '" << menuAlgo.logExpression << "'" << std::endl;

    m_tableMenuAlgo.push_back(menuAlgo);
  }

  if (m_isDebugEnabled) {
    LogTrace("L1GtTriggerMenuConfigOnlineProd")
        << "\n Number of rows read from L1T_MENU_ALGO_VIEW: " << resultsMenuAlgoRows << std::endl;
  }

  return true;
}

// retrieve table with conditions associated to physics algorithms from DB
bool L1GtTriggerMenuConfigOnlineProd::tableMenuAlgoCondFromDB(const std::string& gtSchema,
                                                              const std::string& objectKey) {
  // get list of conditions associated with the algorithms

  // select * from CMS_GT.L1T_MENU_ALGO_COND_VIEW
  //     where L1T_MENU_ALGO_COND_VIEW.MENU_IMPLEMENTATION = objectKey

  const std::vector<std::string>& columnsMenuAlgoCond =
      m_omdsReader.columnNamesView(gtSchema, "L1T_MENU_ALGO_COND_VIEW");

  if (m_isDebugEnabled) {
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\n List of columns in L1T_MENU_ALGO_COND_VIEW:\n" << std::endl;
    for (std::vector<std::string>::const_iterator iter = columnsMenuAlgoCond.begin(); iter != columnsMenuAlgoCond.end();
         iter++) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd") << (*iter) << std::endl;
    }
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\n\n" << std::endl;
  }

  l1t::OMDSReader::QueryResults resultsMenuAlgoCond =
      m_omdsReader.basicQueryView(columnsMenuAlgoCond,
                                  gtSchema,
                                  "L1T_MENU_ALGO_COND_VIEW",
                                  "L1T_MENU_ALGO_COND_VIEW.MENU_IMPLEMENTATION",
                                  m_omdsReader.singleAttribute(objectKey));

  // check if query was successful is based on size of returned list
  // BUT one can have menus w/o algorithms and conditions - no error for empty list, but a warning!
  if (resultsMenuAlgoCond.queryFailed()) {
    edm::LogWarning("L1-O2O") << "Warning: Content of L1T_MENU_ALGO_COND_VIEW for L1GtTriggerMenu implementation key: "
                              << "\n  " << objectKey << "\nis empty!"
                              << "\nNo list of condition associated to each algorithm are found for this menu.";
  }

  //
  TableMenuAlgoCond menuAlgoCond;
  int resultsMenuAlgoCondRows = resultsMenuAlgoCond.numberRows();

  for (int iRow = 0; iRow < resultsMenuAlgoCondRows; ++iRow) {
    for (std::vector<std::string>::const_iterator constIt = columnsMenuAlgoCond.begin();
         constIt != columnsMenuAlgoCond.end();
         ++constIt) {
      if ((*constIt) == "ALGO_INDEX") {
        resultsMenuAlgoCond.fillVariableFromRow(*constIt, iRow, menuAlgoCond.bitNumberSh);

      } else if ((*constIt) == "COND_INDEX") {
        resultsMenuAlgoCond.fillVariableFromRow(*constIt, iRow, menuAlgoCond.condIndexF);

      } else if ((*constIt) == "COND_FK") {
        resultsMenuAlgoCond.fillVariableFromRow(*constIt, iRow, menuAlgoCond.condFK);

      } else {
        // do nothing
      }
    }

    LogTrace("L1GtTriggerMenuConfigOnlineProd")
        << "Row  " << iRow << ": ALGO_INDEX = " << menuAlgoCond.bitNumberSh
        << " COND_INDEX = " << menuAlgoCond.condIndexF << " COND_FK = " << menuAlgoCond.condFK << std::endl;

    m_tableMenuAlgoCond.push_back(menuAlgoCond);
  }

  if (m_isDebugEnabled) {
    LogTrace("L1GtTriggerMenuConfigOnlineProd")
        << "\n Number of rows read from L1T_MENU_ALGO_COND_VIEW: " << resultsMenuAlgoCondRows << std::endl;
  }

  return true;
}

// retrieve table with list of conditions in the menu
bool L1GtTriggerMenuConfigOnlineProd::tableMenuCondFromDB(const std::string& gtSchema, const std::string& objectKey) {
  // select * from CMS_GT.L1T_MENU_COND_VIEW
  //     where L1T_MENU_COND_VIEW.MENU_IMPLEMENTATION = objectKey

  const std::vector<std::string>& columnsMenuCond = m_omdsReader.columnNamesView(gtSchema, "L1T_MENU_COND_VIEW");

  if (m_isDebugEnabled) {
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\n List of columns in L1T_MENU_COND_VIEW:\n" << std::endl;
    for (std::vector<std::string>::const_iterator iter = columnsMenuCond.begin(); iter != columnsMenuCond.end();
         iter++) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd") << (*iter) << std::endl;
    }
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\n\n" << std::endl;
  }

  l1t::OMDSReader::QueryResults resultsMenuCond = m_omdsReader.basicQueryView(columnsMenuCond,
                                                                              gtSchema,
                                                                              "L1T_MENU_COND_VIEW",
                                                                              "L1T_MENU_COND_VIEW.MENU_IMPLEMENTATION",
                                                                              m_omdsReader.singleAttribute(objectKey));

  // check if query was successful is based on size of returned list
  // BUT one can have menus w/o conditions - no error for empty list, but a warning!
  if (resultsMenuCond.queryFailed()) {
    edm::LogWarning("L1-O2O") << "Warning: Content of L1T_MENU_COND_VIEW for L1GtTriggerMenu implementation key: "
                              << "\n  " << objectKey << "\nis empty!"
                              << "\nNo conditions associated to menu are found for this menu.";
  }

  //
  TableMenuCond menuCond;
  int resultsMenuCondRows = resultsMenuCond.numberRows();

  for (int iRow = 0; iRow < resultsMenuCondRows; ++iRow) {
    for (std::vector<std::string>::const_iterator constIt = columnsMenuCond.begin(); constIt != columnsMenuCond.end();
         ++constIt) {
      if ((*constIt) == "COND") {
        resultsMenuCond.fillVariableFromRow(*constIt, iRow, menuCond.cond);

      } else if ((*constIt) == "COND_CATEGORY") {
        resultsMenuCond.fillVariableFromRow(*constIt, iRow, menuCond.condCategory);

      } else if ((*constIt) == "COND_TYPE") {
        resultsMenuCond.fillVariableFromRow(*constIt, iRow, menuCond.condType);

      } else if ((*constIt) == "GT_OBJECT_1") {
        resultsMenuCond.fillVariableFromRow(*constIt, iRow, menuCond.gtObject1);

      } else if ((*constIt) == "GT_OBJECT_2") {
        resultsMenuCond.fillVariableFromRow(*constIt, iRow, menuCond.gtObject2);

      } else if ((*constIt) == "COND_GEQ") {
        //float condGEqFloat = -1;
        //resultsMenuCond.fillVariableFromRow(*constIt, iRow, condGEqFloat);
        //menuCond.condGEq = (condGEqFloat > 0.5) ? true : false;
        resultsMenuCond.fillVariableFromRow(*constIt, iRow, menuCond.condGEq);

      } else if ((*constIt) == "COUNT_INDEX") {
        resultsMenuCond.fillVariableFromRow(*constIt, iRow, menuCond.countIndex);

      } else if ((*constIt) == "COUNT_THRESHOLD") {
        resultsMenuCond.fillVariableFromRow(*constIt, iRow, menuCond.countThreshold);

      } else if ((*constIt) == "CHARGE_CORRELATION") {
        resultsMenuCond.fillVariableFromRow(*constIt, iRow, menuCond.chargeCorrelation);

      } else if ((*constIt) == "OBJECT_PARAMETER_1_FK") {
        resultsMenuCond.fillVariableFromRow(*constIt, iRow, menuCond.objectParameter1FK);

      } else if ((*constIt) == "OBJECT_PARAMETER_2_FK") {
        resultsMenuCond.fillVariableFromRow(*constIt, iRow, menuCond.objectParameter2FK);

      } else if ((*constIt) == "OBJECT_PARAMETER_3_FK") {
        resultsMenuCond.fillVariableFromRow(*constIt, iRow, menuCond.objectParameter3FK);

      } else if ((*constIt) == "OBJECT_PARAMETER_4_FK") {
        resultsMenuCond.fillVariableFromRow(*constIt, iRow, menuCond.objectParameter4FK);

      } else if ((*constIt) == "DELTA_ETA_RANGE") {
        resultsMenuCond.fillVariableFromRow(*constIt, iRow, menuCond.deltaEtaRange);

      } else if ((*constIt) == "DELTA_PHI_RANGE") {
        resultsMenuCond.fillVariableFromRow(*constIt, iRow, menuCond.deltaPhiRange);

      } else {
        // do nothing
      }
    }

    LogTrace("L1GtTriggerMenuConfigOnlineProd")
        << " COND " << menuCond.cond << " COND_CATEGORY " << menuCond.condCategory << " COND_TYPE " << menuCond.condType
        << " GT_OBJECT_1 " << menuCond.gtObject1 << " GT_OBJECT_2 " << menuCond.gtObject2 << " COND_GEQ "
        << menuCond.condGEq << "\n"
        << " COUNT_INDEX " << menuCond.countIndex << " COUNT_THRESHOLD " << menuCond.countThreshold << "\n"
        << " CHARGE_CORRELATION " << menuCond.chargeCorrelation << "\n"
        << " OBJECT_PARAMETER_1_FK " << menuCond.objectParameter1FK << " OBJECT_PARAMETER_2_FK "
        << menuCond.objectParameter2FK << " OBJECT_PARAMETER_3_FK " << menuCond.objectParameter3FK
        << " OBJECT_PARAMETER_4_FK " << menuCond.objectParameter4FK << "\n"
        << " DELTA_ETA_RANGE " << menuCond.deltaEtaRange << " DELTA_PHI_RANGE " << menuCond.deltaPhiRange;

    m_tableMenuCond.push_back(menuCond);
  }

  if (m_isDebugEnabled) {
    LogTrace("L1GtTriggerMenuConfigOnlineProd")
        << "\n Number of rows read from L1T_MENU_COND_VIEW: " << resultsMenuCondRows << std::endl;
  }

  return true;
}

// retrieve table with object parameters from DB
bool L1GtTriggerMenuConfigOnlineProd::tableMenuObjectParametersFromDB(const std::string& gtSchema,
                                                                      const std::string& objectKey) {
  // get the list of object parameters in the menu

  // select * from CMS_GT.L1T_MENU_OP_VIEW
  //     where L1T_MENU_OP_VIEW.MENU_IMPLEMENTATION = objectKey

  const std::vector<std::string>& columnsMenuOp = m_omdsReader.columnNamesView(gtSchema, "L1T_MENU_OP_VIEW");

  if (m_isDebugEnabled) {
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\n List of columns in L1T_MENU_OP_VIEW:\n" << std::endl;
    for (std::vector<std::string>::const_iterator iter = columnsMenuOp.begin(); iter != columnsMenuOp.end(); iter++) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd") << (*iter) << std::endl;
    }
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\n\n" << std::endl;
  }

  l1t::OMDSReader::QueryResults resultsMenuOp = m_omdsReader.basicQueryView(columnsMenuOp,
                                                                            gtSchema,
                                                                            "L1T_MENU_OP_VIEW",
                                                                            "L1T_MENU_OP_VIEW.MENU_IMPLEMENTATION",
                                                                            m_omdsReader.singleAttribute(objectKey));

  // check if query was successful is based on size of returned list
  // BUT one can have menus w/o object parameters - no error for empty list, but a warning!
  if (resultsMenuOp.queryFailed()) {
    edm::LogWarning("L1-O2O") << "Warning: Content of L1T_MENU_OP_VIEW for L1GtTriggerMenu implementation key: "
                              << "\n  " << objectKey << "\nis empty!"
                              << "\nNo object parameters associated to menu are found for this menu.";
  }

  TableMenuObjectParameters menuObjectParameters;
  int resultsMenuOpRows = resultsMenuOp.numberRows();

  for (int iRow = 0; iRow < resultsMenuOpRows; ++iRow) {
    for (std::vector<std::string>::const_iterator constIt = columnsMenuOp.begin(); constIt != columnsMenuOp.end();
         ++constIt) {
      if ((*constIt) == "ID") {
        resultsMenuOp.fillVariableFromRow(*constIt, iRow, menuObjectParameters.opId);

      } else if ((*constIt) == "PT_HIGH_THRESHOLD") {
        resultsMenuOp.fillVariableFromRow(*constIt, iRow, menuObjectParameters.ptHighThreshold);

      } else if ((*constIt) == "PT_LOW_THRESHOLD") {
        resultsMenuOp.fillVariableFromRow(*constIt, iRow, menuObjectParameters.ptLowThreshold);

      } else if ((*constIt) == "ENABLE_MIP") {
        resultsMenuOp.fillVariableFromRow(*constIt, iRow, menuObjectParameters.enableMip);

      } else if ((*constIt) == "ENABLE_ISO") {
        resultsMenuOp.fillVariableFromRow(*constIt, iRow, menuObjectParameters.enableIso);

      } else if ((*constIt) == "REQUEST_ISO") {
        resultsMenuOp.fillVariableFromRow(*constIt, iRow, menuObjectParameters.requestIso);

      } else if ((*constIt) == "ENERGY_OVERFLOW") {
        resultsMenuOp.fillVariableFromRow(*constIt, iRow, menuObjectParameters.energyOverflow);

      } else if ((*constIt) == "ET_THRESHOLD") {
        resultsMenuOp.fillVariableFromRow(*constIt, iRow, menuObjectParameters.etThreshold);

      } else if ((*constIt) == "ETA_RANGE") {
        resultsMenuOp.fillVariableFromRow(*constIt, iRow, menuObjectParameters.etaRange);

      } else if ((*constIt) == "PHI_RANGE") {
        resultsMenuOp.fillVariableFromRow(*constIt, iRow, menuObjectParameters.phiRange);

      } else if ((*constIt) == "PHI_LOW") {
        resultsMenuOp.fillVariableFromRow(*constIt, iRow, menuObjectParameters.phiLow);

      } else if ((*constIt) == "PHI_HIGH") {
        resultsMenuOp.fillVariableFromRow(*constIt, iRow, menuObjectParameters.phiHigh);

      } else if ((*constIt) == "QUALITY_RANGE") {
        resultsMenuOp.fillVariableFromRow(*constIt, iRow, menuObjectParameters.qualityRange);

      } else if ((*constIt) == "CHARGE") {
        resultsMenuOp.fillVariableFromRow(*constIt, iRow, menuObjectParameters.charge);

      } else {
        // do nothing
      }
    }

    LogTrace("L1GtTriggerMenuConfigOnlineProd")
        << " ID " << menuObjectParameters.opId << " PT_HIGH_THRESHOLD " << menuObjectParameters.ptHighThreshold
        << " PT_LOW_THRESHOLD " << menuObjectParameters.ptLowThreshold << " ENABLE_MIP "
        << menuObjectParameters.enableMip << " ENABLE_ISO " << menuObjectParameters.enableIso << " REQUEST_ISO "
        << menuObjectParameters.requestIso << " ENERGY_OVERFLOW " << menuObjectParameters.energyOverflow
        << " ET_THRESHOLD " << menuObjectParameters.etThreshold << " ETA_RANGE " << menuObjectParameters.etaRange
        << " PHI_RANGE " << menuObjectParameters.phiRange << " PHI_LOW " << menuObjectParameters.phiLow << " PHI_HIGH "
        << menuObjectParameters.phiHigh << " QUALITY_RANGE " << menuObjectParameters.qualityRange << " CHARGE "
        << menuObjectParameters.charge << std::endl;

    m_tableMenuObjectParameters.push_back(menuObjectParameters);
  }

  if (m_isDebugEnabled) {
    LogTrace("L1GtTriggerMenuConfigOnlineProd")
        << "\n Number of rows read from L1T_MENU_OP_VIEW: " << resultsMenuOpRows << std::endl;
  }

  return true;
}

// retrieve table with technical triggers from DB
bool L1GtTriggerMenuConfigOnlineProd::tableMenuTechTrigFromDB(const std::string& gtSchema,
                                                              const std::string& objectKey) {
  // select * from CMS_GT.L1T_MENU_TECHTRIG_VIEW
  //     where L1T_MENU_TECHTRIG_VIEW.MENU_IMPLEMENTATION = objectKey

  const std::vector<std::string>& columnsMenuTechTrig =
      m_omdsReader.columnNamesView(gtSchema, "L1T_MENU_TECHTRIG_VIEW");

  if (m_isDebugEnabled) {
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\n List of columns in L1T_MENU_TECHTRIG_VIEW:\n" << std::endl;
    for (std::vector<std::string>::const_iterator iter = columnsMenuTechTrig.begin(); iter != columnsMenuTechTrig.end();
         iter++) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd") << (*iter) << std::endl;
    }
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\n\n" << std::endl;
  }

  l1t::OMDSReader::QueryResults resultsMenuTechTrig =
      m_omdsReader.basicQueryView(columnsMenuTechTrig,
                                  gtSchema,
                                  "L1T_MENU_TECHTRIG_VIEW",
                                  "L1T_MENU_TECHTRIG_VIEW.MENU_IMPLEMENTATION",
                                  m_omdsReader.singleAttribute(objectKey));

  // check if query was successful is based on size of returned list
  // BUT one can have menus w/o technical triggers - no error for empty list, but a warning!
  if (resultsMenuTechTrig.queryFailed()) {
    edm::LogWarning("L1-O2O") << "Warning: Content of L1T_MENU_TECHTRIG_VIEW for L1GtTriggerMenu implementation key: "
                              << "\n  " << objectKey << "\nis empty!"
                              << "\nNo technical triggers are found for this menu.";
  }

  TableMenuTechTrig menuTechTrig;
  int resultsMenuTechTrigRows = resultsMenuTechTrig.numberRows();

  for (int iRow = 0; iRow < resultsMenuTechTrigRows; ++iRow) {
    for (std::vector<std::string>::const_iterator constIt = columnsMenuTechTrig.begin();
         constIt != columnsMenuTechTrig.end();
         ++constIt) {
      if ((*constIt) == "TECHTRIG_INDEX") {
        resultsMenuTechTrig.fillVariableFromRow(*constIt, iRow, menuTechTrig.bitNumberSh);

      } else if ((*constIt) == "NAME") {
        resultsMenuTechTrig.fillVariableFromRow(*constIt, iRow, menuTechTrig.techName);

      } else {
        // do nothing
      }
    }

    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "Row  " << iRow << ": index = " << menuTechTrig.bitNumberSh
                                                << " techName = " << menuTechTrig.techName << std::endl;

    m_tableMenuTechTrig.push_back(menuTechTrig);
  }

  if (m_isDebugEnabled) {
    LogTrace("L1GtTriggerMenuConfigOnlineProd")
        << "\n Number of rows read from L1T_MENU_TECHTRIG_VIEW: " << resultsMenuTechTrigRows << std::endl;
  }

  return true;
}

// return for an algorithm with bitNr the mapping between the integer index in logical expression
// and the condition name (FK)
const std::map<int, std::string> L1GtTriggerMenuConfigOnlineProd::condIndexNameMap(const short bitNr) const {
  std::map<int, std::string> mapIndexName;

  for (std::vector<TableMenuAlgoCond>::const_iterator constIt = m_tableMenuAlgoCond.begin();
       constIt != m_tableMenuAlgoCond.end();
       ++constIt) {
    if (bitNr == (*constIt).bitNumberSh) {
      mapIndexName[static_cast<int>((*constIt).condIndexF)] = (*constIt).condFK;
    }
  }

  if (m_isDebugEnabled) {
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\n Bit number : " << bitNr << std::endl;

    for (std::map<int, std::string>::const_iterator constIt = mapIndexName.begin(); constIt != mapIndexName.end();
         ++constIt) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd")
          << "  Condition index -> name: " << ((*constIt).first) << " " << ((*constIt).second) << std::endl;
    }
  }

  return mapIndexName;
}

// convert a logical expression with indices to a logical expression with names
std::string L1GtTriggerMenuConfigOnlineProd::convertLogicalExpression(
    const std::string& expressionIndices, const std::map<int, std::string>& mapCondIndexName) const {
  std::string expressionNames;

  L1GtLogicParser parserIndices = L1GtLogicParser(expressionIndices);
  parserIndices.convertIntToNameLogicalExpression(mapCondIndexName);
  expressionNames = parserIndices.logicalExpression();

  return expressionNames;
}

// return the chip number for an algorithm with index bitNumberSh
int L1GtTriggerMenuConfigOnlineProd::chipNumber(short bitNumberSh) const {
  // FIXME get it from Event Setup
  const unsigned numberConditionChips = 2;
  const unsigned pinsOnConditionChip = 96;
  std::vector<int> orderConditionChip;
  orderConditionChip.push_back(2);
  orderConditionChip.push_back(1);

  int posChip = (static_cast<unsigned>(bitNumberSh) / pinsOnConditionChip) + 1;
  for (unsigned int iChip = 0; iChip < numberConditionChips; ++iChip) {
    if (posChip == orderConditionChip[iChip]) {
      return static_cast<int>(iChip);
    }
  }

  // chip number not found
  return -1;
}

// build the algorithm map in the menu
void L1GtTriggerMenuConfigOnlineProd::buildAlgorithmMap() {
  // temporary value
  int bitNumber = -1;
  std::string logicalExpression;

  // loop over m_tableMenuAlgo
  for (std::vector<TableMenuAlgo>::const_iterator constIt = m_tableMenuAlgo.begin(); constIt != m_tableMenuAlgo.end();
       constIt++) {
    bitNumber = static_cast<int>((*constIt).bitNumberSh);

    const std::map<int, std::string>& condIndexName = condIndexNameMap((*constIt).bitNumberSh);
    logicalExpression = convertLogicalExpression((*constIt).logExpression, condIndexName);

    // create a new algorithm and insert it into algorithm map
    L1GtAlgorithm alg((*constIt).algName, logicalExpression, bitNumber);
    alg.setAlgoAlias((*constIt).algAlias);

    // set algorithm chip number:
    int algChipNr = chipNumber((*constIt).bitNumberSh);
    alg.setAlgoChipNumber(algChipNr);

    // insert algorithm
    m_algorithmMap[(*constIt).algName] = alg;
    m_algorithmAliasMap[(*constIt).algAlias] = alg;
  }
}

// build the technical trigger map in the menu
void L1GtTriggerMenuConfigOnlineProd::buildTechnicalTriggerMap() {
  // temporary value
  int bitNumber = -1;
  std::string logicalExpression;

  // loop over m_tableMenuTechTrig
  for (std::vector<TableMenuTechTrig>::const_iterator constIt = m_tableMenuTechTrig.begin();
       constIt != m_tableMenuTechTrig.end();
       constIt++) {
    bitNumber = static_cast<int>((*constIt).bitNumberSh);

    // create a new technical trigger and insert it into technical trigger map
    // technical triggers have L1GtAlgorithm class
    L1GtAlgorithm techTrig((*constIt).techName, logicalExpression, bitNumber);

    // chip number set in constructor to -1 - no meaning for technical triggers

    // insert technical trigger
    m_technicalTriggerMap[(*constIt).techName] = techTrig;

    // no alias is defined for technical triggers
  }
}

L1GtConditionCategory L1GtTriggerMenuConfigOnlineProd::strToEnumCondCategory(const std::string& strCategory) {
  if (strCategory == "CondMuon") {
    return CondMuon;
  } else if (strCategory == "CondCalo") {
    return CondCalo;
  } else if (strCategory == "CondEnergySum") {
    return CondEnergySum;
  } else if (strCategory == "CondJetCounts") {
    return CondJetCounts;
  } else if (strCategory == "CondCorrelation") {
    return CondCorrelation;
  } else if (strCategory == "CondCastor") {
    return CondCastor;
  } else if (strCategory == "CondHfBitCounts") {
    return CondHfBitCounts;
  } else if (strCategory == "CondHfRingEtSums") {
    return CondHfRingEtSums;
  } else if (strCategory == "CondBptx") {
    return CondBptx;
  } else if (strCategory == "CondExternal") {
    return CondExternal;
  } else if (strCategory == "CondNull") {
    return CondNull;
  } else {
    edm::LogWarning("L1GtTriggerMenuConfigOnlineProd")
        << "\n Warning: string " << strCategory << " not defined. Returning CondNull.\n"
        << std::endl;
    return CondNull;
  }

  return CondNull;
}

// string to enum L1GtConditionType conversion
L1GtConditionType L1GtTriggerMenuConfigOnlineProd::strToEnumCondType(const std::string& strType) {
  if (strType == "1s") {
    return Type1s;
  } else if (strType == "2s") {
    return Type2s;
  } else if (strType == "2wsc") {
    return Type2wsc;
  } else if (strType == "2cor") {
    return Type2cor;
  } else if (strType == "3s") {
    return Type3s;
  } else if (strType == "4s") {
    return Type4s;
  } else if (strType == "ETM") {
    return TypeETM;
  } else if (strType == "ETT") {
    return TypeETT;
  } else if (strType == "HTT") {
    return TypeHTT;
  } else if (strType == "HTM") {
    return TypeHTM;
  } else if (strType == "JetCounts") {
    return TypeJetCounts;
  } else if (strType == "Castor") {
    return TypeCastor;
  } else if (strType == "HfBitCounts") {
    return TypeHfBitCounts;
  } else if (strType == "HfRingEtSums") {
    return TypeHfRingEtSums;
  } else if (strType == "Bptx") {
    return TypeBptx;
  } else if (strType == "TypeExternal") {
    return TypeExternal;
  } else {
    edm::LogWarning("L1GtTriggerMenuConfigOnlineProd")
        << "\n Warning: string " << strType << " not associated to any L1GtConditionType. Returning TypeNull.\n"
        << std::endl;
    return TypeNull;
  }

  return TypeNull;
}

// string to enum L1GtObject conversion
L1GtObject L1GtTriggerMenuConfigOnlineProd::strToEnumL1GtObject(const std::string& strObject) {
  if (strObject == "Mu") {
    return Mu;
  } else if (strObject == "NoIsoEG") {
    return NoIsoEG;
  } else if (strObject == "IsoEG") {
    return IsoEG;
  } else if (strObject == "CenJet") {
    return CenJet;
  } else if (strObject == "ForJet") {
    return ForJet;
  } else if (strObject == "TauJet") {
    return TauJet;
  } else if (strObject == "ETM") {
    return ETM;
  } else if (strObject == "ETT") {
    return ETT;
  } else if (strObject == "HTT") {
    return HTT;
  } else if (strObject == "HTM") {
    return HTM;
  } else if (strObject == "JetCounts") {
    return JetCounts;
  } else if (strObject == "HfBitCounts") {
    return HfBitCounts;
  } else if (strObject == "HfRingEtSums") {
    return HfRingEtSums;
  } else if (strObject == "TechTrig") {
    return TechTrig;
  } else if (strObject == "Castor") {
    return Castor;
  } else if (strObject == "BPTX") {
    return BPTX;
  } else if (strObject == "GtExternal") {
    return GtExternal;
  } else {
    edm::LogWarning("L1GtTriggerMenuConfigOnlineProd")
        << "\n Warning: string " << strObject << " not associated to any L1GtObject. Returning Mu (no Null type).\n"
        << std::endl;
    return Mu;
  }

  // no null type, so returning Mu - should never arrive here
  return Mu;
}

void L1GtTriggerMenuConfigOnlineProd::splitHexStringInTwo64bitWords(const std::string& hexStr,
                                                                    std::string& hex0WordStr,
                                                                    std::string& hex1WordStr) {
  unsigned int lenHexStr = hexStr.length();

  if (lenHexStr < 3) {
    LogTrace("L1GtTriggerMenuConfigOnlineProd") << "\n Warning: string " << hexStr << " has length less than 3."
                                                << "\n Not possible to split it in two 64-bit words."
                                                << "\n Return two zero strings." << std::endl;
    hex0WordStr = "0x0";
    hex1WordStr = "0x0";

    return;
  }

  unsigned int lenHex = lenHexStr - 2;
  unsigned int len0Word = lenHex > 16 ? 16 : lenHex;
  unsigned int len1Word = lenHex - len0Word;

  unsigned int pos0Word = lenHexStr - len0Word;
  hex0WordStr = "0x" + hexStr.substr(pos0Word, len0Word);

  if (len1Word > 0) {
    unsigned int pos1Word = pos0Word - len1Word;
    hex1WordStr = "0x" + hexStr.substr(pos1Word, len1Word);
  } else {
    hex1WordStr = "0x0";
  }
}

// get a list of chip numbers from the m_tableMenuAlgoCond table for a condition
std::list<int> L1GtTriggerMenuConfigOnlineProd::listChipNumber(const std::string& condFK) {
  std::list<int> chipList;

  // loop over m_tableMenuAlgoCond
  for (std::vector<TableMenuAlgoCond>::const_iterator constIt = m_tableMenuAlgoCond.begin();
       constIt != m_tableMenuAlgoCond.end();
       constIt++) {
    if (condFK == (*constIt).condFK) {
      int chipNr = chipNumber((*constIt).bitNumberSh);
      chipList.push_back(chipNr);
    }
  }

  return chipList;
}

void L1GtTriggerMenuConfigOnlineProd::fillMuonObjectParameter(const std::string& opFK,
                                                              L1GtMuonTemplate::ObjectParameter& objPar) {
  // loop over m_tableMenuCond
  for (std::vector<TableMenuObjectParameters>::const_iterator constIt = m_tableMenuObjectParameters.begin();
       constIt != m_tableMenuObjectParameters.end();
       constIt++) {
    if (opFK == (*constIt).opId) {
      objPar.ptHighThreshold = static_cast<unsigned int>((*constIt).ptHighThreshold);
      objPar.ptLowThreshold = static_cast<unsigned int>((*constIt).ptLowThreshold);
      objPar.enableMip = static_cast<bool>((*constIt).enableMip);
      objPar.enableIso = static_cast<bool>((*constIt).enableIso);
      objPar.requestIso = static_cast<bool>((*constIt).requestIso);
      objPar.etaRange = lexical_cast_from_hex<unsigned long long>((*constIt).etaRange);
      objPar.phiHigh = static_cast<unsigned int>((*constIt).phiHigh);
      objPar.phiLow = static_cast<unsigned int>((*constIt).phiLow);
      objPar.qualityRange = lexical_cast_from_hex<unsigned int>((*constIt).qualityRange);
      //objPar.charge = static_cast<unsigned int> ( ( *constIt ).charge);

      // can break after it is found - DB consistency
      break;
    }
  }
}

void L1GtTriggerMenuConfigOnlineProd::addMuonCondition(const TableMenuCond& condDB) {
  L1GtMuonTemplate muonCond(condDB.cond);
  muonCond.setCondType(strToEnumCondType(condDB.condType));

  // object types - all muons
  int nrObj = muonCond.nrObjects();
  std::vector<L1GtObject> objType(nrObj, Mu);
  muonCond.setObjectType(objType);

  muonCond.setCondGEq(condDB.condGEq);

  // temporary storage of the parameters
  std::vector<L1GtMuonTemplate::ObjectParameter> objParameter(nrObj);

  for (int iObj = 0; iObj < nrObj; ++iObj) {
    if (iObj == 0) {
      fillMuonObjectParameter(condDB.objectParameter1FK, objParameter[iObj]);
    } else if (iObj == 1) {
      fillMuonObjectParameter(condDB.objectParameter2FK, objParameter[iObj]);
    } else if (iObj == 2) {
      fillMuonObjectParameter(condDB.objectParameter3FK, objParameter[iObj]);
    } else if (iObj == 3) {
      fillMuonObjectParameter(condDB.objectParameter4FK, objParameter[iObj]);
    } else {
      LogTrace("L1GtTriggerMenuConfigOnlineProd")
          << "\n Warning: number of objects requested " << nrObj << " not available in DB."
          << "\n Maximum 4 object parameters implemented. \n"
          << std::endl;
    }
  }

  L1GtMuonTemplate::CorrelationParameter corrParameter;
  corrParameter.chargeCorrelation = static_cast<unsigned int>(condDB.chargeCorrelation);
  if (muonCond.wsc()) {
    corrParameter.deltaEtaRange = lexical_cast_from_hex<unsigned long long>(condDB.deltaEtaRange);

    std::string word0;
    std::string word1;
    splitHexStringInTwo64bitWords(condDB.deltaPhiRange, word0, word1);

    corrParameter.deltaPhiRange0Word = lexical_cast_from_hex<unsigned long long>(word0);
    corrParameter.deltaPhiRange1Word = lexical_cast_from_hex<unsigned long long>(word1);

    corrParameter.deltaPhiMaxbits = 0;  // not used anymore
  }

  muonCond.setConditionParameter(objParameter, corrParameter);

  // get chip number list
  std::list<int> chipList = listChipNumber(condDB.cond);

  // eliminate duplicates
  chipList.sort();
  chipList.unique();

  // add the same condition once to every chip where required
  for (std::list<int>::const_iterator itChip = chipList.begin(); itChip != chipList.end(); ++itChip) {
    muonCond.setCondChipNr(*itChip);

    // no check for uniqueness - done by DB
    (m_vecMuonTemplate[*itChip]).push_back(muonCond);

    if (m_isDebugEnabled) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd")
          << "\n Adding condition " << (condDB.cond) << " on chip " << (*itChip) << "\n " << std::endl;

      LogTrace("L1GtTriggerMenuConfigOnlineProd") << muonCond << "\n" << std::endl;
    }
  }
}

void L1GtTriggerMenuConfigOnlineProd::fillCaloObjectParameter(const std::string& opFK,
                                                              L1GtCaloTemplate::ObjectParameter& objPar) {
  // loop over m_tableMenuCond
  for (std::vector<TableMenuObjectParameters>::const_iterator constIt = m_tableMenuObjectParameters.begin();
       constIt != m_tableMenuObjectParameters.end();
       constIt++) {
    if (opFK == (*constIt).opId) {
      objPar.etThreshold = static_cast<unsigned int>((*constIt).etThreshold);
      objPar.etaRange = lexical_cast_from_hex<unsigned int>((*constIt).etaRange);
      objPar.phiRange = lexical_cast_from_hex<unsigned int>((*constIt).phiRange);

      // can break after it is found - DB consistency
      break;
    }
  }
}

void L1GtTriggerMenuConfigOnlineProd::addCaloCondition(const TableMenuCond& condDB) {
  L1GtCaloTemplate caloCond(condDB.cond);
  caloCond.setCondType(strToEnumCondType(condDB.condType));

  // object types - all have the same type, so reading it for first object is OK
  int nrObj = caloCond.nrObjects();

  L1GtObject obj = strToEnumL1GtObject(condDB.gtObject1);
  std::vector<L1GtObject> objType(nrObj, obj);
  caloCond.setObjectType(objType);

  caloCond.setCondGEq(condDB.condGEq);

  // temporary storage of the parameters
  std::vector<L1GtCaloTemplate::ObjectParameter> objParameter(nrObj);

  for (int iObj = 0; iObj < nrObj; ++iObj) {
    if (iObj == 0) {
      fillCaloObjectParameter(condDB.objectParameter1FK, objParameter[iObj]);
    } else if (iObj == 1) {
      fillCaloObjectParameter(condDB.objectParameter2FK, objParameter[iObj]);
    } else if (iObj == 2) {
      fillCaloObjectParameter(condDB.objectParameter3FK, objParameter[iObj]);
    } else if (iObj == 3) {
      fillCaloObjectParameter(condDB.objectParameter4FK, objParameter[iObj]);
    } else {
      LogTrace("L1GtTriggerMenuConfigOnlineProd")
          << "\n Warning: number of objects requested " << nrObj << " not available in DB."
          << "\n Maximum 4 object parameters implemented. \n"
          << std::endl;
    }
  }

  L1GtCaloTemplate::CorrelationParameter corrParameter;
  if (caloCond.wsc()) {
    corrParameter.deltaEtaRange = lexical_cast_from_hex<unsigned long long>(condDB.deltaEtaRange);

    corrParameter.deltaPhiRange = lexical_cast_from_hex<unsigned long long>(condDB.deltaPhiRange);
    corrParameter.deltaPhiMaxbits = 0;  // FIXME check correlations
  }

  caloCond.setConditionParameter(objParameter, corrParameter);

  // get chip number list
  std::list<int> chipList = listChipNumber(condDB.cond);

  // eliminate duplicates
  chipList.sort();
  chipList.unique();

  // add the same condition once to every chip where required
  for (std::list<int>::const_iterator itChip = chipList.begin(); itChip != chipList.end(); ++itChip) {
    caloCond.setCondChipNr(*itChip);

    // no check for uniqueness - done by DB
    (m_vecCaloTemplate[*itChip]).push_back(caloCond);

    if (m_isDebugEnabled) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd")
          << "\n Adding condition " << (condDB.cond) << " on chip " << (*itChip) << "\n " << std::endl;

      LogTrace("L1GtTriggerMenuConfigOnlineProd") << caloCond << "\n" << std::endl;
    }
  }
}

void L1GtTriggerMenuConfigOnlineProd::fillEnergySumObjectParameter(const std::string& opFK,
                                                                   L1GtEnergySumTemplate::ObjectParameter& objPar,
                                                                   const L1GtObject& obj) {
  // loop over m_tableMenuCond
  for (std::vector<TableMenuObjectParameters>::const_iterator constIt = m_tableMenuObjectParameters.begin();
       constIt != m_tableMenuObjectParameters.end();
       constIt++) {
    if (opFK == (*constIt).opId) {
      objPar.etThreshold = static_cast<unsigned int>((*constIt).etThreshold);
      objPar.energyOverflow = static_cast<bool>((*constIt).energyOverflow);  // not used

      std::string word0;
      std::string word1;
      splitHexStringInTwo64bitWords((*constIt).phiRange, word0, word1);

      if (obj == ETM) {
        objPar.phiRange0Word = lexical_cast_from_hex<unsigned long long>(word0);
        objPar.phiRange1Word = lexical_cast_from_hex<unsigned long long>(word1);

      } else if (obj == HTM) {
        objPar.phiRange0Word = lexical_cast_from_hex<unsigned long long>(word0);
      }

      // can break after it is found - DB consistency
      break;
    }
  }
}

void L1GtTriggerMenuConfigOnlineProd::addEnergySumCondition(const TableMenuCond& condDB) {
  L1GtEnergySumTemplate esumCond(condDB.cond);
  esumCond.setCondType(strToEnumCondType(condDB.condType));

  // object types - all energy sums are global - so 1 object
  int nrObj = 1;

  L1GtObject obj = strToEnumL1GtObject(condDB.gtObject1);
  std::vector<L1GtObject> objType(nrObj, obj);
  esumCond.setObjectType(objType);

  esumCond.setCondGEq(condDB.condGEq);

  // temporary storage of the parameters - no CorrelationParameter
  std::vector<L1GtEnergySumTemplate::ObjectParameter> objParameter(nrObj);
  fillEnergySumObjectParameter(condDB.objectParameter1FK, objParameter[0], objType[0]);

  esumCond.setConditionParameter(objParameter);

  // get chip number list
  std::list<int> chipList = listChipNumber(condDB.cond);

  // eliminate duplicates
  chipList.sort();
  chipList.unique();

  // add the same condition once to every chip where required
  for (std::list<int>::const_iterator itChip = chipList.begin(); itChip != chipList.end(); ++itChip) {
    esumCond.setCondChipNr(*itChip);

    // no check for uniqueness - done by DB
    (m_vecEnergySumTemplate[*itChip]).push_back(esumCond);

    if (m_isDebugEnabled) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd")
          << "\n Adding condition " << (condDB.cond) << " on chip " << (*itChip) << "\n " << std::endl;

      LogTrace("L1GtTriggerMenuConfigOnlineProd") << esumCond << "\n" << std::endl;
    }
  }
}

void L1GtTriggerMenuConfigOnlineProd::addJetCountsCondition(const TableMenuCond& condDB) {
  L1GtJetCountsTemplate jcCond(condDB.cond);
  jcCond.setCondType(strToEnumCondType(condDB.condType));

  // object types - jet counts are "global"
  int nrObj = 1;

  L1GtObject obj = strToEnumL1GtObject(condDB.gtObject1);
  std::vector<L1GtObject> objType(nrObj, obj);
  jcCond.setObjectType(objType);

  jcCond.setCondGEq(condDB.condGEq);

  // temporary storage of the parameters - no CorrelationParameter
  // for counts, the DB implementation is without OP, directly in TableMenuCond
  std::vector<L1GtJetCountsTemplate::ObjectParameter> objParameter(nrObj);
  objParameter.at(0).countIndex = static_cast<unsigned int>(condDB.countIndex);
  objParameter.at(0).countThreshold = static_cast<unsigned int>(condDB.countThreshold);
  objParameter.at(0).countOverflow = false;  // not used

  jcCond.setConditionParameter(objParameter);

  // get chip number list
  std::list<int> chipList = listChipNumber(condDB.cond);

  // eliminate duplicates
  chipList.sort();
  chipList.unique();

  // add the same condition once to every chip where required
  for (std::list<int>::const_iterator itChip = chipList.begin(); itChip != chipList.end(); ++itChip) {
    jcCond.setCondChipNr(*itChip);

    // no check for uniqueness - done by DB
    (m_vecJetCountsTemplate[*itChip]).push_back(jcCond);

    if (m_isDebugEnabled) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd")
          << "\n Adding condition " << (condDB.cond) << " on chip " << (*itChip) << "\n " << std::endl;

      LogTrace("L1GtTriggerMenuConfigOnlineProd") << jcCond << "\n" << std::endl;
    }
  }
}

void L1GtTriggerMenuConfigOnlineProd::addHfBitCountsCondition(const TableMenuCond& condDB) {
  L1GtHfBitCountsTemplate countsCond(condDB.cond);
  countsCond.setCondType(strToEnumCondType(condDB.condType));

  // object types - HF bit counts are "global"
  int nrObj = 1;

  L1GtObject obj = strToEnumL1GtObject(condDB.gtObject1);
  std::vector<L1GtObject> objType(nrObj, obj);
  countsCond.setObjectType(objType);

  countsCond.setCondGEq(condDB.condGEq);

  // temporary storage of the parameters - no CorrelationParameter
  // for counts, the DB implementation is without OP, directly in TableMenuCond
  std::vector<L1GtHfBitCountsTemplate::ObjectParameter> objParameter(nrObj);
  objParameter.at(0).countIndex = static_cast<unsigned int>(condDB.countIndex);
  objParameter.at(0).countThreshold = static_cast<unsigned int>(condDB.countThreshold);

  countsCond.setConditionParameter(objParameter);

  // get chip number list
  std::list<int> chipList = listChipNumber(condDB.cond);

  // eliminate duplicates
  chipList.sort();
  chipList.unique();

  // add the same condition once to every chip where required
  for (std::list<int>::const_iterator itChip = chipList.begin(); itChip != chipList.end(); ++itChip) {
    countsCond.setCondChipNr(*itChip);

    // no check for uniqueness - done by DB
    (m_vecHfBitCountsTemplate[*itChip]).push_back(countsCond);

    if (m_isDebugEnabled) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd")
          << "\n Adding condition " << (condDB.cond) << " on chip " << (*itChip) << "\n " << std::endl;

      LogTrace("L1GtTriggerMenuConfigOnlineProd") << countsCond << "\n" << std::endl;
    }
  }
}

void L1GtTriggerMenuConfigOnlineProd::addHfRingEtSumsCondition(const TableMenuCond& condDB) {
  L1GtHfRingEtSumsTemplate esumCond(condDB.cond);
  esumCond.setCondType(strToEnumCondType(condDB.condType));

  // object types - HF energy sums are "global"
  int nrObj = 1;

  L1GtObject obj = strToEnumL1GtObject(condDB.gtObject1);
  std::vector<L1GtObject> objType(nrObj, obj);
  esumCond.setObjectType(objType);

  esumCond.setCondGEq(condDB.condGEq);

  // temporary storage of the parameters - no CorrelationParameter
  // for HF energy sums, the DB implementation is without OP, directly in TableMenuCond
  std::vector<L1GtHfRingEtSumsTemplate::ObjectParameter> objParameter(nrObj);
  objParameter.at(0).etSumIndex = static_cast<unsigned int>(condDB.countIndex);
  objParameter.at(0).etSumThreshold = static_cast<unsigned int>(condDB.countThreshold);

  esumCond.setConditionParameter(objParameter);

  // get chip number list
  std::list<int> chipList = listChipNumber(condDB.cond);

  // eliminate duplicates
  chipList.sort();
  chipList.unique();

  // add the same condition once to every chip where required
  for (std::list<int>::const_iterator itChip = chipList.begin(); itChip != chipList.end(); ++itChip) {
    esumCond.setCondChipNr(*itChip);

    // no check for uniqueness - done by DB
    (m_vecHfRingEtSumsTemplate[*itChip]).push_back(esumCond);

    if (m_isDebugEnabled) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd")
          << "\n Adding condition " << (condDB.cond) << " on chip " << (*itChip) << "\n " << std::endl;

      LogTrace("L1GtTriggerMenuConfigOnlineProd") << esumCond << "\n" << std::endl;
    }
  }
}

void L1GtTriggerMenuConfigOnlineProd::addCastorCondition(const TableMenuCond& condDB) {
  L1GtCastorTemplate castorCond(condDB.cond);
  castorCond.setCondType(strToEnumCondType(condDB.condType));

  // object types - logical conditions have no objects associated in GT
  // one put however a "Castor" object type
  int nrObj = 1;

  L1GtObject obj = strToEnumL1GtObject(condDB.gtObject1);
  std::vector<L1GtObject> objType(nrObj, obj);
  castorCond.setObjectType(objType);

  // irrelevant, set to false for completeness
  castorCond.setCondGEq(false);

  // logical conditions have no ObjectParameter, no CorrelationParameter

  // get chip number list
  std::list<int> chipList = listChipNumber(condDB.cond);

  // eliminate duplicates
  chipList.sort();
  chipList.unique();

  // add the same condition once to every chip where required
  for (std::list<int>::const_iterator itChip = chipList.begin(); itChip != chipList.end(); ++itChip) {
    castorCond.setCondChipNr(*itChip);

    // no check for uniqueness - done by DB
    (m_vecCastorTemplate[*itChip]).push_back(castorCond);

    if (m_isDebugEnabled) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd")
          << "\n Adding condition " << (condDB.cond) << " on chip " << (*itChip) << "\n " << std::endl;

      LogTrace("L1GtTriggerMenuConfigOnlineProd") << castorCond << "\n" << std::endl;
    }
  }
}

void L1GtTriggerMenuConfigOnlineProd::addBptxCondition(const TableMenuCond& condDB) {
  L1GtBptxTemplate bptxCond(condDB.cond);
  bptxCond.setCondType(strToEnumCondType(condDB.condType));

  // object types - logical conditions have no objects associated in GT
  // one put however a "Bptx" object type
  int nrObj = 1;

  L1GtObject obj = strToEnumL1GtObject(condDB.gtObject1);
  std::vector<L1GtObject> objType(nrObj, obj);
  bptxCond.setObjectType(objType);

  // irrelevant, set to false for completeness
  bptxCond.setCondGEq(false);

  // logical conditions have no ObjectParameter, no CorrelationParameter

  // get chip number list
  std::list<int> chipList = listChipNumber(condDB.cond);

  // eliminate duplicates
  chipList.sort();
  chipList.unique();

  // add the same condition once to every chip where required
  for (std::list<int>::const_iterator itChip = chipList.begin(); itChip != chipList.end(); ++itChip) {
    bptxCond.setCondChipNr(*itChip);

    // no check for uniqueness - done by DB
    (m_vecBptxTemplate[*itChip]).push_back(bptxCond);

    if (m_isDebugEnabled) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd")
          << "\n Adding condition " << (condDB.cond) << " on chip " << (*itChip) << "\n " << std::endl;

      LogTrace("L1GtTriggerMenuConfigOnlineProd") << bptxCond << "\n" << std::endl;
    }
  }
}

void L1GtTriggerMenuConfigOnlineProd::addExternalCondition(const TableMenuCond& condDB) {
  L1GtExternalTemplate externalCond(condDB.cond);
  externalCond.setCondType(strToEnumCondType(condDB.condType));

  // object types - logical conditions have no objects associated in GT
  // one put however a "External" object type
  int nrObj = 1;

  L1GtObject obj = strToEnumL1GtObject(condDB.gtObject1);
  std::vector<L1GtObject> objType(nrObj, obj);
  externalCond.setObjectType(objType);

  // irrelevant, set to false for completeness
  externalCond.setCondGEq(false);

  // logical conditions have no ObjectParameter, no CorrelationParameter

  // get chip number list
  std::list<int> chipList = listChipNumber(condDB.cond);

  // eliminate duplicates
  chipList.sort();
  chipList.unique();

  // add the same condition once to every chip where required
  for (std::list<int>::const_iterator itChip = chipList.begin(); itChip != chipList.end(); ++itChip) {
    externalCond.setCondChipNr(*itChip);

    // no check for uniqueness - done by DB
    (m_vecExternalTemplate[*itChip]).push_back(externalCond);

    if (m_isDebugEnabled) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd")
          << "\n Adding condition " << (condDB.cond) << " on chip " << (*itChip) << "\n " << std::endl;

      LogTrace("L1GtTriggerMenuConfigOnlineProd") << externalCond << "\n" << std::endl;
    }
  }
}

void L1GtTriggerMenuConfigOnlineProd::addCorrelationCondition(const TableMenuCond& condDB) {
  // create a new correlation condition
  L1GtCorrelationTemplate correlationCond(condDB.cond);
  correlationCond.setCondType(strToEnumCondType(condDB.condType));

  // two objects (for sure) - type taken from DB
  const int nrObj = 2;

  std::vector<L1GtObject> objType(nrObj);
  L1GtObject obj = strToEnumL1GtObject(condDB.gtObject1);
  objType[0] = obj;

  obj = strToEnumL1GtObject(condDB.gtObject2);
  objType[1] = obj;

  correlationCond.setObjectType(objType);

  // irrelevant, it is set for each subcondition
  correlationCond.setCondGEq(condDB.condGEq);

  // get chip number list, eliminate duplicates
  std::list<int> chipList = listChipNumber(condDB.cond);
  chipList.sort();
  chipList.unique();

  // temporary vectors for sub-conditions
  std::vector<L1GtConditionCategory> subcondCategory(nrObj);
  std::vector<int> subcondIndex(nrObj);

  bool wrongSubcondition = false;

  for (int iObj = 0; iObj < nrObj; ++iObj) {
    L1GtObject gtObj = objType[iObj];

    // sub-conditions (all have the same condGEq as the correlation condition).
    switch (gtObj) {
      case Mu: {
        subcondCategory[iObj] = CondMuon;

        // temporary storage of the parameters
        std::vector<L1GtMuonTemplate::ObjectParameter> objParameter(1);

        std::string subcondName;
        if (iObj == 0) {
          fillMuonObjectParameter(condDB.objectParameter1FK, objParameter[0]);
          subcondName = condDB.objectParameter1FK;
        } else if (iObj == 1) {
          subcondName = condDB.objectParameter2FK;
          fillMuonObjectParameter(condDB.objectParameter2FK, objParameter[0]);
        }

        //  chargeCorrelation must be set for muons
        //  put it to ignore
        L1GtMuonTemplate::CorrelationParameter corrPar;
        corrPar.chargeCorrelation = 1;

        L1GtMuonTemplate subcond(subcondName, Type1s);
        subcond.setCondGEq(condDB.condGEq);
        subcond.setObjectType(std::vector<L1GtObject>(1, gtObj));
        subcond.setConditionParameter(objParameter, corrPar);

        // add the same sub-condition once to every chip where required
        for (std::list<int>::const_iterator itChip = chipList.begin(); itChip != chipList.end(); ++itChip) {
          subcond.setCondChipNr(*itChip);

          // no check for uniqueness - done by DB
          (m_corMuonTemplate[*itChip]).push_back(subcond);

          // index
          subcondIndex[iObj] = (m_corMuonTemplate[*itChip]).size() - 1;

          if (m_isDebugEnabled) {
            LogTrace("L1GtTriggerMenuConfigOnlineProd")
                << "\n Adding condition " << (condDB.cond) << " on chip " << (*itChip) << "\n " << std::endl;

            LogTrace("L1GtTriggerMenuConfigOnlineProd") << subcond << "\n" << std::endl;
          }
        }

      } break;

      case IsoEG:
      case NoIsoEG:
      case CenJet:
      case ForJet:
      case TauJet: {
        subcondCategory[iObj] = CondCalo;

        // temporary storage of the parameters
        std::vector<L1GtCaloTemplate::ObjectParameter> objParameter(1);

        std::string subcondName;
        if (iObj == 0) {
          fillCaloObjectParameter(condDB.objectParameter1FK, objParameter[0]);
          subcondName = condDB.objectParameter1FK;
        } else if (iObj == 1) {
          subcondName = condDB.objectParameter2FK;
          fillCaloObjectParameter(condDB.objectParameter2FK, objParameter[0]);
        }

        L1GtCaloTemplate::CorrelationParameter corrPar;  //  dummy

        L1GtCaloTemplate subcond(subcondName, Type1s);
        subcond.setCondGEq(condDB.condGEq);
        subcond.setObjectType(std::vector<L1GtObject>(1, gtObj));
        subcond.setConditionParameter(objParameter, corrPar);

        // add the same sub-condition once to every chip where required
        for (std::list<int>::const_iterator itChip = chipList.begin(); itChip != chipList.end(); ++itChip) {
          subcond.setCondChipNr(*itChip);

          // no check for uniqueness - done by DB
          (m_corCaloTemplate[*itChip]).push_back(subcond);

          // index
          subcondIndex[iObj] = (m_corCaloTemplate[*itChip]).size() - 1;

          if (m_isDebugEnabled) {
            LogTrace("L1GtTriggerMenuConfigOnlineProd")
                << "\n Adding condition " << (condDB.cond) << " on chip " << (*itChip) << "\n " << std::endl;

            LogTrace("L1GtTriggerMenuConfigOnlineProd") << subcond << "\n" << std::endl;
          }
        }
      } break;

      case ETM:
      case HTM: {
        subcondCategory[iObj] = CondEnergySum;

        // temporary storage of the parameters
        std::vector<L1GtEnergySumTemplate::ObjectParameter> objParameter(1);

        std::string subcondName;
        if (iObj == 0) {
          fillEnergySumObjectParameter(condDB.objectParameter1FK, objParameter[0], gtObj);
          subcondName = condDB.objectParameter1FK;
        } else if (iObj == 1) {
          subcondName = condDB.objectParameter2FK;
          fillEnergySumObjectParameter(condDB.objectParameter2FK, objParameter[0], gtObj);
        }

        L1GtConditionType condType;

        switch (gtObj) {
          case ETM: {
            condType = TypeETM;
          } break;
          case HTM: {
            condType = TypeHTM;
          } break;
          default: {
            edm::LogWarning("L1GtTriggerMenuConfigOnlineProd")
                << "\n Warning: wrong L1GtConditionType " << gtObj << std::endl;

          } break;
        }

        L1GtEnergySumTemplate subcond(subcondName, condType);
        subcond.setCondGEq(condDB.condGEq);
        subcond.setObjectType(std::vector<L1GtObject>(1, gtObj));
        subcond.setConditionParameter(objParameter);

        // add the same sub-condition once to every chip where required
        for (std::list<int>::const_iterator itChip = chipList.begin(); itChip != chipList.end(); ++itChip) {
          subcond.setCondChipNr(*itChip);

          // no check for uniqueness - done by DB
          (m_corEnergySumTemplate[*itChip]).push_back(subcond);

          // index
          subcondIndex[iObj] = (m_corEnergySumTemplate[*itChip]).size() - 1;

          if (m_isDebugEnabled) {
            LogTrace("L1GtTriggerMenuConfigOnlineProd")
                << "\n Adding condition " << (condDB.cond) << " on chip " << (*itChip) << "\n " << std::endl;

            LogTrace("L1GtTriggerMenuConfigOnlineProd") << subcond << "\n" << std::endl;
          }
        }
      } break;
      case ETT:
      case HTT:
      case JetCounts:
      case HfBitCounts:
      case HfRingEtSums:
      case Castor:
      case BPTX:
      case GtExternal:
      case TechTrig: {
        wrongSubcondition = true;
        edm::LogWarning("L1GtTriggerMenuConfigOnlineProd")
            << "\n Warning: correlation condition " << (condDB.cond) << " with invalid sub-condition object type "
            << gtObj << "\n Condition ignored!" << std::endl;
      }
        [[fallthrough]];
      default: {
        wrongSubcondition = true;
        edm::LogWarning("L1GtTriggerMenuConfigOnlineProd")
            << "\n Warning: correlation condition " << (condDB.cond) << " with invalid sub-condition object type "
            << gtObj << "\n Condition ignored!" << std::endl;

        //

      } break;
    }
  }

  if (wrongSubcondition) {
    edm::LogWarning("L1GtTriggerMenuConfigOnlineProd")
        << "\n Warning: wrong sub-condition for correlation condition " << (condDB.cond)
        << "\n Condition not inserted in menu. \n A sub-condition may be left in the menu" << std::endl;
    return;
  }

  // get the correlation parameters for the correlation condition (std::string)
  L1GtCorrelationTemplate::CorrelationParameter corrParameter;
  corrParameter.deltaEtaRange = condDB.deltaEtaRange;
  corrParameter.deltaPhiRange = condDB.deltaPhiRange;

  // set condition categories
  correlationCond.setCond0Category(subcondCategory[0]);
  correlationCond.setCond1Category(subcondCategory[1]);

  // set condition indices in correlation vector
  correlationCond.setCond0Index(subcondIndex[0]);
  correlationCond.setCond1Index(subcondIndex[1]);

  // set correlation parameter
  corrParameter.deltaPhiMaxbits = 0;  //  TODO
  correlationCond.setCorrelationParameter(corrParameter);

  // add the same condition once to every chip where required
  for (std::list<int>::const_iterator itChip = chipList.begin(); itChip != chipList.end(); ++itChip) {
    correlationCond.setCondChipNr(*itChip);

    // no check for uniqueness - done by DB
    (m_vecCorrelationTemplate[*itChip]).push_back(correlationCond);

    if (m_isDebugEnabled) {
      LogTrace("L1GtTriggerMenuConfigOnlineProd")
          << "\n Adding condition " << (condDB.cond) << " on chip " << (*itChip) << "\n " << std::endl;

      LogTrace("L1GtTriggerMenuConfigOnlineProd") << correlationCond << "\n" << std::endl;
    }
  }
}

// add the conditions from a menu to the corresponding list
void L1GtTriggerMenuConfigOnlineProd::addConditions() {
  // loop over m_tableMenuCond
  for (std::vector<TableMenuCond>::const_iterator constIt = m_tableMenuCond.begin(); constIt != m_tableMenuCond.end();
       constIt++) {
    L1GtConditionCategory conCategory = strToEnumCondCategory((*constIt).condCategory);

    switch (conCategory) {
      case CondMuon: {
        addMuonCondition(*constIt);

      } break;
      case CondCalo: {
        addCaloCondition(*constIt);

      } break;
      case CondEnergySum: {
        addEnergySumCondition(*constIt);

      } break;
      case CondJetCounts: {
        addJetCountsCondition(*constIt);

      } break;
      case CondHfBitCounts: {
        addHfBitCountsCondition(*constIt);

      } break;
      case CondHfRingEtSums: {
        addHfRingEtSumsCondition(*constIt);

      } break;
      case CondCastor: {
        addCastorCondition(*constIt);

      } break;
      case CondBptx: {
        addBptxCondition(*constIt);

      } break;
      case CondExternal: {
        addExternalCondition(*constIt);

      } break;
      case CondCorrelation: {
        addCorrelationCondition(*constIt);

      } break;
      case CondNull: {
        // do nothing

      } break;
      default: {
        // do nothing

      } break;
    }
  }
}

DEFINE_FWK_EVENTSETUP_MODULE(L1GtTriggerMenuConfigOnlineProd);