L1TRate.cc

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/*
 * \file L1TRate.cc
 *
 * \author J. Pela, P. Musella
 *
 */
 
// L1TMonitor includes
#include "DQM/L1TMonitor/interface/L1TRate.h"
#include "DQM/L1TMonitor/interface/L1TOMDSHelper.h"
 
#include "DQMServices/Core/interface/DQMStore.h"
 
#include "DataFormats/Common/interface/ConditionsInEdm.h"  // Parameters associated to Run, LS and Event
#include "DataFormats/Luminosity/interface/LumiDetails.h"  // Luminosity Information
#include "DataFormats/Luminosity/interface/LumiSummary.h"  // Luminosity Information
 
#include "CondFormats/L1TObjects/interface/L1GtTriggerMenu.h"
#include "CondFormats/L1TObjects/interface/L1GtTriggerMenuFwd.h"
#include "CondFormats/L1TObjects/interface/L1GtPrescaleFactors.h"
#include "CondFormats/L1TObjects/interface/L1GtTriggerMask.h"             // L1Gt - Masks
#include "CondFormats/DataRecord/interface/L1GtTriggerMaskAlgoTrigRcd.h"  // L1Gt - Masks
#include "CondFormats/DataRecord/interface/L1GtTriggerMenuRcd.h"
#include "CondFormats/DataRecord/interface/L1GtPrescaleFactorsAlgoTrigRcd.h"
 
#include "TList.h"
 
using namespace edm;
using namespace std;
 
//_____________________________________________________________________
L1TRate::L1TRate(const ParameterSet& ps)
    : m_menuToken(esConsumes<edm::Transition::BeginRun>()),
      m_l1GtPfAlgoToken(esConsumes<edm::Transition::BeginRun>()),
      m_helperTokens(L1TMenuHelper::consumes<edm::Transition::BeginRun>(consumesCollector())),
      m_l1GtUtils(ps, consumesCollector(), false, *this) {
  m_maxNbins = 2500;  // Maximum LS for each run (for binning purposes)
  m_parameters = ps;
 
  // Mapping parameter input variables
  m_scalersSource_colLScal =
      consumes<LumiScalersCollection>(m_parameters.getParameter<InputTag>("inputTagScalersResults"));
  m_scalersSource_triggerScalers =
      consumes<Level1TriggerScalersCollection>(m_parameters.getParameter<InputTag>("inputTagScalersResults"));
  m_l1GtDataDaqInputTag =
      consumes<L1GlobalTriggerReadoutRecord>(m_parameters.getParameter<InputTag>("inputTagL1GtDataDaq"));
  m_verbose = m_parameters.getUntrackedParameter<bool>("verbose", false);
  m_refPrescaleSet = m_parameters.getParameter<int>("refPrescaleSet");
  m_lsShiftGTRates = m_parameters.getUntrackedParameter<int>("lsShiftGTRates", 0);
 
  // Getting which categories to monitor
  ParameterSet Categories = ps.getParameter<ParameterSet>("categories");
  m_inputCategories["Mu"] = Categories.getUntrackedParameter<bool>("Mu");
  m_inputCategories["EG"] = Categories.getUntrackedParameter<bool>("EG");
  m_inputCategories["IsoEG"] = Categories.getUntrackedParameter<bool>("IsoEG");
  m_inputCategories["Jet"] = Categories.getUntrackedParameter<bool>("Jet");
  m_inputCategories["CenJet"] = Categories.getUntrackedParameter<bool>("CenJet");
  m_inputCategories["ForJet"] = Categories.getUntrackedParameter<bool>("ForJet");
  m_inputCategories["TauJet"] = Categories.getUntrackedParameter<bool>("TauJet");
  m_inputCategories["ETM"] = Categories.getUntrackedParameter<bool>("ETM");
  m_inputCategories["ETT"] = Categories.getUntrackedParameter<bool>("ETT");
  m_inputCategories["HTT"] = Categories.getUntrackedParameter<bool>("HTT");
  m_inputCategories["HTM"] = Categories.getUntrackedParameter<bool>("HTM");
 
  // What to do if we want our output to be saved to a external file
  m_outputFile = ps.getUntrackedParameter<string>("outputFile", "");
 
  if (!m_outputFile.empty()) {
    cout << "L1T Monitoring histograms will be saved to " << m_outputFile.c_str() << endl;
  }
 
  bool disable = ps.getUntrackedParameter<bool>("disableROOToutput", false);
  if (disable) {
    m_outputFile = "";
  }
}
 
//_____________________________________________________________________
L1TRate::~L1TRate() {}
 
//_____________________________________________________________________
// BeginRun
//_____________________________________________________________________
void L1TRate::bookHistograms(DQMStore::IBooker& ibooker, const edm::Run&, const edm::EventSetup& iSetup) {
  const L1GtTriggerMenu& menu = iSetup.getData(m_menuToken);
  const L1GtPrescaleFactors& l1GtPfAlgo = iSetup.getData(m_l1GtPfAlgoToken);
 
  // Initializing DQM Monitor Elements
  ibooker.setCurrentFolder("L1T/L1TRate");
  m_ErrorMonitor = ibooker.book1D("ErrorMonitor", "ErrorMonitor", 5, 0, 5);
  m_ErrorMonitor->setBinLabel(1, "WARNING_DB_CONN_FAILED");         // Errors from L1TOMDSHelper
  m_ErrorMonitor->setBinLabel(2, "WARNING_DB_QUERY_FAILED");        // Errors from L1TOMDSHelper
  m_ErrorMonitor->setBinLabel(3, "WARNING_DB_INCORRECT_NBUNCHES");  // Errors from L1TOMDSHelper
  m_ErrorMonitor->setBinLabel(4, "WARNING_PY_MISSING_FIT");
  m_ErrorMonitor->setBinLabel(5, "UNKNOWN");
 
  // Retriving the list of prescale sets
  m_listsPrescaleFactors = &(l1GtPfAlgo.gtPrescaleFactors());
 
  // Getting Lowest Prescale Single Object Triggers from the menu
  L1TMenuHelper myMenuHelper = L1TMenuHelper(iSetup, m_helperTokens);
  m_l1GtUtils.retrieveL1EventSetup(iSetup);
  m_selectedTriggers = myMenuHelper.getLUSOTrigger(m_inputCategories, m_refPrescaleSet, m_l1GtUtils);
 
  //-> Getting template fits for the algLo cross sections
  int srcAlgoXSecFit = m_parameters.getParameter<int>("srcAlgoXSecFit");
  if (srcAlgoXSecFit == 0) {
    getXSexFitsOMDS(m_parameters);
  } else if (srcAlgoXSecFit == 1) {
    getXSexFitsPython(m_parameters);
  }
 
  for (const auto& algo : menu.gtAlgorithmMap()) {
    m_algoBit[algo.second.algoAlias()] = algo.second.algoBitNumber();
  }
 
  double minInstantLuminosity = m_parameters.getParameter<double>("minInstantLuminosity");
  double maxInstantLuminosity = m_parameters.getParameter<double>("maxInstantLuminosity");
 
  // Initializing DQM Monitor Elements
  for (map<string, string>::const_iterator i = m_selectedTriggers.begin(); i != m_selectedTriggers.end(); i++) {
    TString tCategory = (*i).first;
    TString tTrigger = (*i).second;
 
    TString tErrorMessage = "";
    TF1* tTestFunction;
 
    if (tTrigger != "Undefined" && m_templateFunctions.find(tTrigger) != m_templateFunctions.end()) {
      tTestFunction = m_templateFunctions[tTrigger];
    } else if (tTrigger == "Undefined") {
      TString tFunc = "-1";
      tTestFunction = new TF1("FitParametrization_" + tTrigger, tFunc, 0, double(m_maxNbins) - 0.5);
    } else if (m_templateFunctions.find(tTrigger) == m_templateFunctions.end()) {
      TString tFunc = "-1";
      tTestFunction = new TF1("FitParametrization_" + tTrigger, tFunc, 0, double(m_maxNbins) - 0.5);
      tErrorMessage = " (Undefined Test Function)";
    } else {
      TString tFunc = "-1";
      tTestFunction = new TF1("FitParametrization_" + tTrigger, tFunc, 0, double(m_maxNbins) - 0.5);
    }
 
    if (tTrigger != "Undefined") {
      if (myMenuHelper.getPrescaleByAlias(tCategory, tTrigger) != 1) {
        tErrorMessage += " WARNING: Default Prescale = ";
        tErrorMessage += myMenuHelper.getPrescaleByAlias(tCategory, tTrigger);
      }
 
      if (tCategory == "Mu" && myMenuHelper.getEtaRangeByAlias(tCategory, tTrigger) != 4294967295) {
        tErrorMessage += " WARNING: Eta Range = ";
        tErrorMessage += myMenuHelper.getEtaRangeByAlias(tCategory, tTrigger);
      } else if (tCategory == "EG" && myMenuHelper.getEtaRangeByAlias(tCategory, tTrigger) != 32639) {
        tErrorMessage += " WARNING: Eta Range = ";
        tErrorMessage += myMenuHelper.getEtaRangeByAlias(tCategory, tTrigger);
      } else if (tCategory == "IsoEG" && myMenuHelper.getEtaRangeByAlias(tCategory, tTrigger) != 32639) {
        tErrorMessage += " WARNING: Eta Range = ";
        tErrorMessage += myMenuHelper.getEtaRangeByAlias(tCategory, tTrigger);
      }
 
      if (tCategory == "Mu" && myMenuHelper.getQualityAlias(tCategory, tTrigger) != 240) {
        tErrorMessage += " WARNING: Quality = ";
        tErrorMessage += myMenuHelper.getQualityAlias(tCategory, tTrigger);
      }
    }
 
    ibooker.setCurrentFolder("L1T/L1TRate/TriggerCrossSections");
    m_xSecVsInstLumi[tTrigger] = ibooker.bookProfile(tCategory,
                                                     "Cross Sec. vs Inst. Lumi Algo: " + tTrigger + tErrorMessage,
                                                     m_maxNbins,
                                                     minInstantLuminosity,
                                                     maxInstantLuminosity,
                                                     0,
                                                     500);
    m_xSecVsInstLumi[tTrigger]->setAxisTitle("Instantaneous Luminosity [10^{30}cm^{-2}s^{-1}]", 1);
    m_xSecVsInstLumi[tTrigger]->setAxisTitle("Algorithm #sigma [#mu b]", 2);
    m_xSecVsInstLumi[tTrigger]->getTProfile()->GetListOfFunctions()->Add(tTestFunction);
    m_xSecVsInstLumi[tTrigger]->getTProfile()->SetMarkerStyle(23);
 
    ibooker.setCurrentFolder("L1T/L1TRate/Certification");
    m_xSecObservedToExpected[tTrigger] =
        ibooker.book1D(tCategory, "Algo: " + tTrigger + tErrorMessage, m_maxNbins, -0.5, double(m_maxNbins) - 0.5);
    m_xSecObservedToExpected[tTrigger]->setAxisTitle("Lumi Section", 1);
    m_xSecObservedToExpected[tTrigger]->setAxisTitle("#sigma_{obs} / #sigma_{exp}", 2);
  }
}
 
void L1TRate::dqmBeginRun(edm::Run const&, edm::EventSetup const&) {
  //
  if (m_verbose) {
    cout << "[L1TRate:] Called beginRun." << endl;
  }
}
//_____________________________________________________________________
void L1TRate::beginLuminosityBlock(LuminosityBlock const& lumiBlock, EventSetup const& c) {
  if (m_verbose) {
    cout << "[L1TRate:] Called beginLuminosityBlock at LS=" << lumiBlock.id().luminosityBlock() << endl;
  }
}
 
//_____________________________________________________________________
void L1TRate::endLuminosityBlock(LuminosityBlock const& lumiBlock, EventSetup const& c) {
  int eventLS = lumiBlock.id().luminosityBlock();
  if (m_verbose) {
    cout << "[L1TRate:] Called endLuminosityBlock at LS=" << eventLS << endl;
  }
 
  // We can certify LS -1 since we should have available:
  // gt rates: (current LS)-1
  // prescale: current LS
  // lumi    : current LS
  //eventLS--;
 
  // Checking if all necessary quantities are defined for our calculations
  bool isDefRate, isDefLumi, isDefPrescaleIndex;
  map<TString, double>* rates = nullptr;
  double lumi = 0;
  int prescalesIndex = 0;
 
  // Reseting MonitorElements so we can refill them
  for (map<string, string>::const_iterator i = m_selectedTriggers.begin(); i != m_selectedTriggers.end(); i++) {
    string tTrigger = (*i).second;
    m_xSecObservedToExpected[tTrigger]->getTH1()->Reset("ICE");
    m_xSecVsInstLumi[tTrigger]->getTH1()->Reset("ICE");
  }
 
  for (map<int, map<TString, double> >::iterator i = m_lsRates.begin(); i != m_lsRates.end(); i++) {
    unsigned int ls = (*i).first;
    rates = &(*i).second;
    isDefRate = true;
 
    if (m_lsLuminosity.find(ls) == m_lsLuminosity.end()) {
      isDefLumi = false;
    } else {
      isDefLumi = true;
      lumi = m_lsLuminosity[ls];
    }
 
    if (m_lsPrescaleIndex.find(ls) == m_lsPrescaleIndex.end()) {
      isDefPrescaleIndex = false;
    } else {
      isDefPrescaleIndex = true;
      prescalesIndex = m_lsPrescaleIndex[ls];
    }
 
    if (isDefRate && isDefLumi && isDefPrescaleIndex) {
      const vector<int>& currentPrescaleFactors = (*m_listsPrescaleFactors).at(prescalesIndex);
 
      for (map<string, string>::const_iterator i = m_selectedTriggers.begin(); i != m_selectedTriggers.end(); i++) {
        string tTrigger = (*i).second;
        TF1* tTestFunction = (TF1*)m_xSecVsInstLumi[tTrigger]->getTProfile()->GetListOfFunctions()->First();
 
        // If trigger name is defined we get the rate fit parameters
        if (tTrigger != "Undefined") {
          unsigned int trigBit = m_algoBit[tTrigger];
          double trigPrescale = currentPrescaleFactors[trigBit];
          double trigRate = (*rates)[tTrigger];
 
          if (lumi != 0 && trigPrescale != 0 && trigRate != 0) {
            double AlgoXSec = (trigPrescale * trigRate) / lumi;
            double TemplateFunctionValue = tTestFunction->Eval(lumi);
 
            // Checking against Template function
            int ibin = m_xSecObservedToExpected[tTrigger]->getTH1()->FindBin(ls);
            m_xSecObservedToExpected[tTrigger]->setBinContent(ibin, AlgoXSec / TemplateFunctionValue);
            m_xSecVsInstLumi[tTrigger]->Fill(lumi, AlgoXSec);
 
            if (m_verbose) {
              cout << "[L1TRate:] ls=" << ls << " Algo=" << tTrigger << " XSec=" << AlgoXSec
                   << " Test=" << AlgoXSec / TemplateFunctionValue << endl;
            }
 
          } else {
            int ibin = m_xSecObservedToExpected[tTrigger]->getTH1()->FindBin(ls);
            m_xSecObservedToExpected[tTrigger]->setBinContent(ibin, 0.000001);
            if (m_verbose) {
              cout << "[L1TRate:] Algo=" << tTrigger << " XSec=Failed" << endl;
            }
          }
        }
      }
    }
  }
}
 
//_____________________________________________________________________
void L1TRate::analyze(const Event& iEvent, const EventSetup& eventSetup) {
  edm::Handle<L1GlobalTriggerReadoutRecord> gtReadoutRecordData;
  edm::Handle<Level1TriggerScalersCollection> triggerScalers;
  edm::Handle<LumiScalersCollection> colLScal;
 
  iEvent.getByToken(m_l1GtDataDaqInputTag, gtReadoutRecordData);
  iEvent.getByToken(m_scalersSource_colLScal, colLScal);
  iEvent.getByToken(m_scalersSource_triggerScalers, triggerScalers);
 
  // Integers
  int EventRun = iEvent.id().run();
  unsigned int eventLS = iEvent.id().luminosityBlock();
 
  // Getting the trigger trigger rates from GT and buffering it
  if (triggerScalers.isValid()) {
    Level1TriggerScalersCollection::const_iterator itL1TScalers = triggerScalers->begin();
    Level1TriggerRates trigRates(*itL1TScalers, EventRun);
 
    int gtLS = (*itL1TScalers).lumiSegmentNr() + m_lsShiftGTRates;
 
    // If we haven't got the data from this LS yet get it
    if (m_lsRates.find(gtLS) == m_lsRates.end()) {
      if (m_verbose) {
        cout << "[L1TRate:] Buffering GT Rates for LS=" << gtLS << endl;
      }
      map<TString, double> bufferRate;
 
      // Buffer the rate informations for all selected bits
      for (map<string, string>::const_iterator i = m_selectedTriggers.begin(); i != m_selectedTriggers.end(); i++) {
        string tTrigger = (*i).second;
 
        // If trigger name is defined we store the rate
        if (tTrigger != "Undefined") {
          unsigned int trigBit = m_algoBit[tTrigger];
          double trigRate = trigRates.gtAlgoCountsRate()[trigBit];
 
          bufferRate[tTrigger] = trigRate;
        }
      }
      m_lsRates[gtLS] = bufferRate;
    }
  }
 
  // Getting from the SCAL the luminosity information and buffering it
  if (colLScal.isValid() && !colLScal->empty()) {
    LumiScalersCollection::const_iterator itLScal = colLScal->begin();
    unsigned int scalLS = itLScal->sectionNumber();
 
    // If we haven't got the data from this SCAL LS yet get it
    if (m_lsLuminosity.find(scalLS) == m_lsLuminosity.end()) {
      if (m_verbose) {
        cout << "[L1TRate:] Buffering SCAL-HF Lumi for LS=" << scalLS << endl;
      }
      double instLumi = itLScal->instantLumi();                  // Getting Instant Lumi from HF (via SCAL)
      double deadTimeNormHF = itLScal->deadTimeNormalization();  // Getting Dead Time Normalization from HF (via SCAL)
 
      // If HF Dead Time Corrections is requested we apply it
      // NOTE: By default this is assumed false since for now WbM fits do NOT assume this correction
      if (m_parameters.getUntrackedParameter<bool>("useHFDeadTimeNormalization", false)) {
        // Protecting for deadtime = 0
        if (deadTimeNormHF == 0) {
          instLumi = 0;
        } else {
          instLumi = instLumi / deadTimeNormHF;
        }
      }
      // Buffering the luminosity information
      m_lsLuminosity[scalLS] = instLumi;
    }
  }
 
  // Getting the prescale index used when this event was triggered
  if (gtReadoutRecordData.isValid()) {
    // If we haven't got the data from this LS yet get it
    if (m_lsPrescaleIndex.find(eventLS) == m_lsPrescaleIndex.end()) {
      if (m_verbose) {
        cout << "[L1TRate:] Buffering Prescale Index for LS=" << eventLS << endl;
      }
 
      // Getting Final Decision Logic (FDL) Data from GT
      const vector<L1GtFdlWord>& gtFdlVectorData = gtReadoutRecordData->gtFdlVector();
 
      // Getting the index for the fdl data for this event
      int indexFDL = 0;
      for (unsigned int i = 0; i < gtFdlVectorData.size(); i++) {
        if (gtFdlVectorData[i].bxInEvent() == 0) {
          indexFDL = i;
          break;
        }
      }
 
      int CurrentPrescalesIndex = gtFdlVectorData[indexFDL].gtPrescaleFactorIndexAlgo();
      m_lsPrescaleIndex[eventLS] = CurrentPrescalesIndex;
    }
  }
}
 
//_____________________________________________________________________
// function: getXSexFitsOMDS
// Imputs:
//   * const edm::ParameterSet& ps = ParameterSet contaning necessary
//     information for the OMDS data extraction
// Outputs:
//   * int error = Number of algos where you did not find a
//     corresponding fit
//_____________________________________________________________________
bool L1TRate::getXSexFitsOMDS(const edm::ParameterSet& ps) {
  bool noError = true;
 
  string oracleDB = ps.getParameter<string>("oracleDB");
  string pathCondDB = ps.getParameter<string>("pathCondDB");
 
  L1TOMDSHelper myOMDSHelper;
  int conError;
  myOMDSHelper.connect(oracleDB, pathCondDB, conError);
 
  map<string, WbMTriggerXSecFit> wbmFits;
 
  if (conError == L1TOMDSHelper::NO_ERROR) {
    int errorRetrive;
    wbmFits = myOMDSHelper.getWbMAlgoXsecFits(errorRetrive);
 
    // Filling errors if they exist
    if (errorRetrive != L1TOMDSHelper::NO_ERROR) {
      noError = false;
      string eName = myOMDSHelper.enumToStringError(errorRetrive);
      m_ErrorMonitor->Fill(eName);
    }
  } else {
    noError = false;
    string eName = myOMDSHelper.enumToStringError(conError);
    m_ErrorMonitor->Fill(eName);
  }
 
  double minInstantLuminosity = m_parameters.getParameter<double>("minInstantLuminosity");
  double maxInstantLuminosity = m_parameters.getParameter<double>("maxInstantLuminosity");
 
  // Getting rate fit parameters for all input triggers
  for (map<string, string>::const_iterator a = m_selectedTriggers.begin(); a != m_selectedTriggers.end(); a++) {
    string tTrigger = (*a).second;
 
    // If trigger name is defined we get the rate fit parameters
    if (tTrigger != "Undefined") {
      if (wbmFits.find(tTrigger) != wbmFits.end()) {
        WbMTriggerXSecFit tWbMParameters = wbmFits[tTrigger];
 
        vector<double> tParameters;
        tParameters.push_back(tWbMParameters.pm1);
        tParameters.push_back(tWbMParameters.p0);
        tParameters.push_back(tWbMParameters.p1);
        tParameters.push_back(tWbMParameters.p2);
 
        // Retriving and populating the m_templateFunctions array
        m_templateFunctions[tTrigger] = new TF1("FitParametrization_" + tWbMParameters.bitName,
                                                tWbMParameters.fitFunction,
                                                minInstantLuminosity,
                                                maxInstantLuminosity);
        m_templateFunctions[tTrigger]->SetParameters(&tParameters[0]);
        m_templateFunctions[tTrigger]->SetLineWidth(1);
        m_templateFunctions[tTrigger]->SetLineColor(kRed);
 
      } else {
        noError = false;
      }
    }
  }
 
  return noError;
}
 
//_____________________________________________________________________
// function: getXSexFitsPython
// Imputs:
//   * const edm::ParameterSet& ps = ParameterSet contaning the fit
//     functions and parameters for the selected triggers
// Outputs:
//   * int error = Number of algos where you did not find a
//     corresponding fit
//_____________________________________________________________________
bool L1TRate::getXSexFitsPython(const edm::ParameterSet& ps) {
  // error meaning
  bool noError = true;
 
  // Getting fit parameters
  std::vector<edm::ParameterSet> m_fitParameters = ps.getParameter<vector<ParameterSet> >("fitParameters");
 
  double minInstantLuminosity = m_parameters.getParameter<double>("minInstantLuminosity");
  double maxInstantLuminosity = m_parameters.getParameter<double>("maxInstantLuminosity");
 
  // Getting rate fit parameters for all input triggers
  for (map<string, string>::const_iterator a = m_selectedTriggers.begin(); a != m_selectedTriggers.end(); a++) {
    string tTrigger = (*a).second;
 
    // If trigger name is defined we get the rate fit parameters
    if (tTrigger != "Undefined") {
      bool foundFit = false;
 
      for (unsigned int b = 0; b < m_fitParameters.size(); b++) {
        if (tTrigger == m_fitParameters[b].getParameter<string>("AlgoName")) {
          TString tAlgoName = m_fitParameters[b].getParameter<string>("AlgoName");
          TString tTemplateFunction = m_fitParameters[b].getParameter<string>("TemplateFunction");
          vector<double> tParameters = m_fitParameters[b].getParameter<vector<double> >("Parameters");
 
          // Retriving and populating the m_templateFunctions array
          m_templateFunctions[tTrigger] =
              new TF1("FitParametrization_" + tAlgoName, tTemplateFunction, minInstantLuminosity, maxInstantLuminosity);
          m_templateFunctions[tTrigger]->SetParameters(&tParameters[0]);
          m_templateFunctions[tTrigger]->SetLineWidth(1);
          m_templateFunctions[tTrigger]->SetLineColor(kRed);
 
          foundFit = true;
          break;
        }
 
        if (!foundFit) {
          noError = false;
          string eName = "WARNING_PY_MISSING_FIT";
          m_ErrorMonitor->Fill(eName);
        }
      }
    }
  }
 
  return noError;
}