L1CaloInputScalesGenerator.cc

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#include "L1TriggerConfig/L1ScalesProducers/interface/L1CaloInputScalesGenerator.h"

// system include files
#include <memory>
#include <iostream>
using std::cout;
using std::endl;
#include <iomanip>
using std::setprecision;
#include <fstream>
using std::ofstream;


// user include files
#include "FWCore/Framework/interface/Frameworkfwd.h"

#include "FWCore/Framework/interface/MakerMacros.h"
#include "FWCore/Framework/interface/EventSetup.h"
#include "FWCore/Framework/interface/ESHandle.h"

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

#include "CalibFormats/CaloTPG/interface/CaloTPGTranscoder.h"
#include "CalibFormats/CaloTPG/interface/CaloTPGRecord.h"
#include "CalibCalorimetry/EcalTPGTools/interface/EcalTPGScale.h"
#include "DataFormats/EcalDetId/interface/EcalTrigTowerDetId.h"


//
// constants, enums and typedefs
//

//
// static data member definitions
//

//
// constructors and destructor
//
L1CaloInputScalesGenerator::L1CaloInputScalesGenerator(const edm::ParameterSet& iConfig)

{
   //now do what ever initialization is needed

}


L1CaloInputScalesGenerator::~L1CaloInputScalesGenerator()
{
 
   // do anything here that needs to be done at desctruction time
   // (e.g. close files, deallocate resources etc.)

}


//
// member functions
//

// ------------ method called to for each event  ------------
void
L1CaloInputScalesGenerator::analyze(const edm::Event& iEvent, const edm::EventSetup& iSetup)
{
   using namespace edm;


   ESHandle<CaloTPGTranscoder> caloTPGTranscoder;
   iSetup.get<CaloTPGRecord>().get(caloTPGTranscoder);
   
   EcalTPGScale* ecalTPGScale = new EcalTPGScale();
   ecalTPGScale->setEventSetup(iSetup);

   double output; 
   ofstream scalesFile("L1CaloInputScales_cfi.py");


   // Write the ecal scales, positive eta

   scalesFile << "import FWCore.ParameterSet.Config as cms\n" <<endl;

   scalesFile << "L1CaloInputScalesProducer =cms.ESProducer(\"L1CaloInputScalesProducer\"," << endl;
   scalesFile << "L1EcalEtThresholdsPositiveEta = cms.vdouble(" << endl; 


   //Python does not support arrays over 255 entries so we neeed ton accomodate it by creating new array after 255 entries
   int nEntries = 0;



   // loop over ietas, barrel
   for (unsigned short absIeta = 1; absIeta <= 28; absIeta++)
     {
       EcalSubdetector subdet = ( absIeta <= 17 ) ? EcalBarrel : EcalEndcap ;
       // 8 bits of input energy
       for (unsigned short input = 0; input <= 0xFF; input++)
     {
       output = ecalTPGScale->getTPGInGeV( (unsigned int) input, 
                          EcalTrigTowerDetId(1, subdet,
                                 absIeta, 1));
       scalesFile << setprecision (8) << output;
       nEntries++;

       if (absIeta == 28 && input == 0xFF)
         {
           scalesFile << "),";
         }
       else if(nEntries>254)
         {
           scalesFile <<")+cms.vdouble(";
           nEntries=0;
         }
       else
         {
           scalesFile << ", ";
         }
     }
       scalesFile << endl;
     }

   // Write the ecal scales, negative eta

   scalesFile << endl << "\tL1EcalEtThresholdsNegativeEta = cms.vdouble(" << endl;

   nEntries=0;
   // loop over ietas, barrel first
   for (unsigned short absIeta = 1; absIeta <= 28; absIeta++)
     {
       EcalSubdetector subdet = ( absIeta <= 17 ) ? EcalBarrel : EcalEndcap ;
       // 8 bits of input energy
       for (unsigned short input = 0; input <= 0xFF; input++)
     {
       // negative eta
       output = ecalTPGScale->
         getTPGInGeV( (unsigned int) input, EcalTrigTowerDetId(-1, subdet,
                               absIeta, 2));
       scalesFile << setprecision (8) << output;
       nEntries++;



       if (absIeta == 28 && input == 0xFF)
         {
           scalesFile << "),";
         }
       else if(nEntries>254)
         {
           scalesFile <<")+cms.vdouble(";
           nEntries=0;
         }
       else
         {
           scalesFile << ", ";
         }
     }
       scalesFile << endl;
     }

   // Write the hcal scales (Positive Eta)

     scalesFile << endl << "\tL1HcalEtThresholdsPositiveEta = cms.vdouble(" << endl;

   // loop over ietas

     nEntries=0;
   for (unsigned short absIeta = 1; absIeta <= 32; absIeta++)
     {
       for (unsigned short input = 0; input <= 0xFF; input++)
     {
       output = caloTPGTranscoder->hcaletValue(absIeta, input); 
       scalesFile << setprecision (8) << output ;
       nEntries++;


       if (absIeta == 32 && input == 0xFF)
         {
           scalesFile << "),";
         }
       else if(nEntries>254)
         {
           scalesFile <<")+cms.vdouble(";
           nEntries=0;
         }
       else
         {
           scalesFile << ", ";
         }
     }
       scalesFile << endl;
     }

   // Write the hcal scales (Negative Eta)

     scalesFile << endl << "\tL1HcalEtThresholdsNegativeEta = cms.vdouble(" << endl;

     nEntries=0;  
   // loop over ietas
   for (unsigned short absIeta = 1; absIeta <= 32; absIeta++)
     {
       for (unsigned short input = 0; input <= 0xFF; input++)
     {
       output = caloTPGTranscoder->hcaletValue(-absIeta, input); 
       scalesFile << setprecision (8) << output ;
       nEntries++;


       if (absIeta == 32 && input == 0xFF)
         {
           scalesFile << ")";
         }
       else if(nEntries>254)
         {
           scalesFile <<")+cms.vdouble(";
           nEntries=0;
         }
       else 
         {
           scalesFile << ", ";
         }
     }
       scalesFile << endl;
     }


   scalesFile << ")" << endl;

   scalesFile.close();
}


// ------------ method called once each job just before starting event loop  ------------
void 
L1CaloInputScalesGenerator::beginJob()
{
}

// ------------ method called once each job just after ending the event loop  ------------
void 
L1CaloInputScalesGenerator::endJob() {
}