L1RCTLutWriter Class Reference

#include <L1RCTLutWriter.h>

Inheritance diagram for L1RCTLutWriter:

Public Member Functions
	L1RCTLutWriter (const edm::ParameterSet &)
	~L1RCTLutWriter ()
Public Member Functions inherited from edm::EDAnalyzer
void	callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)
	EDAnalyzer ()
ModuleDescription const &	moduleDescription () const
std::string	workerType () const
virtual	~EDAnalyzer ()
Public Member Functions inherited from edm::EDConsumerBase
	EDConsumerBase ()
ProductHolderIndexAndSkipBit	indexFrom (EDGetToken, BranchType, TypeID const &) const
void	itemsMayGet (BranchType, std::vector< ProductHolderIndexAndSkipBit > &) const
void	itemsToGet (BranchType, std::vector< ProductHolderIndexAndSkipBit > &) const
std::vector < ProductHolderIndexAndSkipBit > const &	itemsToGetFromEvent () const
void	labelsForToken (EDGetToken iToken, Labels &oLabels) const
bool	registeredToConsume (ProductHolderIndex, bool, BranchType) const
bool	registeredToConsumeMany (TypeID const &, BranchType) const
void	updateLookup (BranchType iBranchType, ProductHolderIndexHelper const &)
virtual	~EDConsumerBase ()

Private Member Functions
virtual void	analyze (const edm::Event &, const edm::EventSetup &)
virtual void	endJob ()
void	writeEicLutFile (unsigned short card)
void	writeJscLutFile ()
void	writeRcLutFile (unsigned short card)
void	writeThresholdsFile (unsigned int eicThreshold, unsigned int jscThresholdBarrel, unsigned int jscThresholdEndcap)

Private Attributes
std::string	keyName_
L1RCTLookupTables *	lookupTable_
std::ofstream	lutFile_
const L1RCTParameters *	rctParameters_
bool	useDebugTpgScales_

Additional Inherited Members
Public Types inherited from edm::EDAnalyzer
typedef EDAnalyzer	ModuleType
Static Public Member Functions inherited from edm::EDAnalyzer
static const std::string &	baseType ()
static void	fillDescriptions (ConfigurationDescriptions &descriptions)
static void	prevalidate (ConfigurationDescriptions &)
Protected Member Functions inherited from edm::EDConsumerBase
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	consumes (edm::InputTag const &tag)
EDGetToken	consumes (const TypeToGet &id, edm::InputTag const &tag)
template<BranchType B>
EDGetToken	consumes (TypeToGet const &id, edm::InputTag const &tag)
ConsumesCollector	consumesCollector ()
	Use a ConsumesCollector to gather consumes information from helper functions. More...
template<typename ProductType , BranchType B = InEvent>
void	consumesMany ()
void	consumesMany (const TypeToGet &id)
template<BranchType B>
void	consumesMany (const TypeToGet &id)
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	mayConsume (edm::InputTag const &tag)
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)
template<BranchType B>
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)

Detailed Description

L1Trigger/L1RCTLutWriter/src/L1RCTLutWriter.cc

Description: <one line="" class="" summary>="">

Implementation: <Notes on="" implementation>="">

Definition at line 48 of file L1RCTLutWriter.h.

Constructor & Destructor Documentation

L1RCTLutWriter::L1RCTLutWriter ( const edm::ParameterSet &  iConfig )

explicit

Definition at line 37 of file L1RCTLutWriter.cc.

                                                             :
  lookupTable_(new L1RCTLookupTables),
  keyName_(iConfig.getParameter<std::string>("key")),
  useDebugTpgScales_(iConfig.getParameter<bool>("useDebugTpgScales"))
{
   //now do what ever initialization is needed
 
}

L1RCTLutWriter::~L1RCTLutWriter

(

)

Definition at line 47 of file L1RCTLutWriter.cc.

References lookupTable_.

{
 
   // do anything here that needs to be done at destruction time
   // (e.g. close files, deallocate resources etc.)
  
  if (lookupTable_ != 0) delete lookupTable_;
}

Member Function Documentation

void L1RCTLutWriter::analyze ( const edm::Event &  iEvent, const edm::EventSetup &  iSetup  )

privatevirtual

Implements edm::EDAnalyzer.

Definition at line 63 of file L1RCTLutWriter.cc.

References gather_cfg::cout, alignCSCRings::e, EcalBarrel, EcalEndcap, L1RCTChannelMask::ecalMask, L1RCTNoisyChannelMask::ecalMask, L1RCTNoisyChannelMask::ecalThreshold, L1RCTParameters::eicIsolationThreshold(), edm::EventSetup::get(), EcalTPGScale::getTPGInGeV(), h, CaloTPGTranscoder::hcaletValue(), L1RCTChannelMask::hcalMask, L1RCTNoisyChannelMask::hcalMask, L1RCTNoisyChannelMask::hcalThreshold, L1RCTChannelMask::hfMask, L1RCTNoisyChannelMask::hfMask, L1RCTNoisyChannelMask::hfThreshold, i, j, L1RCTParameters::jscQuietThresholdBarrel(), L1RCTParameters::jscQuietThresholdEndcap(), gen::k, lookupTable_, m, L1CaloEcalScale::nBinEta, L1CaloHcalScale::nBinEta, L1CaloEcalScale::nBinRank, L1CaloHcalScale::nBinRank, edm::ESHandle< class >::product(), rctParameters_, alignCSCRings::s, L1CaloHcalScale::setBin(), L1CaloEcalScale::setBin(), L1RCTLookupTables::setChannelMask(), L1RCTLookupTables::setEcalScale(), EcalTPGScale::setEventSetup(), L1RCTLookupTables::setHcalScale(), L1RCTLookupTables::setL1CaloEtScale(), L1RCTLookupTables::setNoisyChannelMask(), L1RCTLookupTables::setRCTParameters(), useDebugTpgScales_, writeEicLutFile(), writeJscLutFile(), writeRcLutFile(), and writeThresholdsFile().

{
   
   // get all the configuration information from the event, set it
   // in the lookuptable
   edm::ESHandle<L1RCTParameters> rctParameters;
   iSetup.get<L1RCTParametersRcd>().get(rctParameters);
   rctParameters_ = rctParameters.product();
   edm::ESHandle<L1CaloEtScale> emScale;
   iSetup.get<L1EmEtScaleRcd>().get(emScale);
   const L1CaloEtScale* s = emScale.product();

   // make dummy channel mask -- we don't want to mask
   // any channels when writing LUTs, that comes afterwards
   L1RCTChannelMask* m = new L1RCTChannelMask;
   for (int i = 0; i < 18; i++)
     {
       for (int j = 0; j < 2; j++)
     {
       for (int k = 0; k < 28; k++)
         {
           m->ecalMask[i][j][k] = false;
           m->hcalMask[i][j][k] = false;
         }
       for (int k = 0; k < 4; k++)
         {
           m->hfMask[i][j][k] = false;
         }
     }
     }


   //Same for Noisy mask
   // make dummy channel mask -- we don't want to mask
   // any channels when writing LUTs, that comes afterwards
   L1RCTNoisyChannelMask* m2 = new L1RCTNoisyChannelMask;
   for (int i = 0; i < 18; i++)
     {
       for (int j = 0; j < 2; j++)
     {
       for (int k = 0; k < 28; k++)
         {
           m2->ecalMask[i][j][k] = false;
           m2->hcalMask[i][j][k] = false;
         }
       for (int k = 0; k < 4; k++)
         {
           m2->hfMask[i][j][k] = false;
         }
     }
     }
   m2->ecalThreshold = 0.0;
   m2->hcalThreshold = 0.0;
   m2->hfThreshold = 0.0;


   
  // use these dummies to get the delete right when using old-style
  // scales to create set of L1CaloXcalScales
  L1CaloEcalScale* dummyE(0);
  L1CaloHcalScale* dummyH(0);

  if (useDebugTpgScales_) // generate new-style scales from tpg scales
    {

      std::cout << "Using old-style TPG scales!" << std::endl;

      // old version of hcal energy scale to convert input
      edm::ESHandle<CaloTPGTranscoder> transcoder;
      iSetup.get<CaloTPGRecord>().get(transcoder);
      const CaloTPGTranscoder* h_tpg = transcoder.product();

      // old version of ecal energy scale to convert input
      EcalTPGScale* e_tpg = new EcalTPGScale();
      e_tpg->setEventSetup(iSetup);

      L1CaloEcalScale* ecalScale = new L1CaloEcalScale();
      L1CaloHcalScale* hcalScale = new L1CaloHcalScale();

      // generate L1CaloXcalScales from old-style scales (thanks, werner!)

      // ECAL
      for( unsigned short ieta = 1 ; ieta <= L1CaloEcalScale::nBinEta; ++ieta )
    {
      for( unsigned short irank = 0 ; irank < L1CaloEcalScale::nBinRank; ++irank )
        {
          EcalSubdetector subdet = ( ieta <= 17 ) ? EcalBarrel : EcalEndcap ;
          double etGeVPos =
        e_tpg->getTPGInGeV
        ( irank, EcalTrigTowerDetId(1, // +ve eta
                        subdet,
                        ieta,
                        1 )); // dummy phi value
          ecalScale->setBin( irank, ieta, 1, etGeVPos ) ;
        }
    }
      
      for( unsigned short ieta = 1 ; ieta <= L1CaloEcalScale::nBinEta; ++ieta )
    {
      for( unsigned short irank = 0 ; irank < L1CaloEcalScale::nBinRank; ++irank )
        {
          EcalSubdetector subdet = ( ieta <= 17 ) ? EcalBarrel : EcalEndcap ;
          
          double etGeVNeg =
        e_tpg->getTPGInGeV
        ( irank,
          EcalTrigTowerDetId(-1, // -ve eta
                     subdet,
                     ieta,
                     2 )); // dummy phi value
          ecalScale->setBin( irank, ieta, -1, etGeVNeg ) ;
        }
    }

      // HCAL
      for( unsigned short ieta = 1 ; ieta <= L1CaloHcalScale::nBinEta; ++ieta )
    {
      for( unsigned short irank = 0 ; irank < L1CaloHcalScale::nBinRank; ++irank )
        {
          double etGeV = h_tpg->hcaletValue( ieta, irank ) ;

          hcalScale->setBin( irank, ieta, 1, etGeV ) ;
          hcalScale->setBin( irank, ieta, -1, etGeV ) ;
        }
    }

      // set the input scales
      lookupTable_->setEcalScale(ecalScale);
      lookupTable_->setHcalScale(hcalScale);

      dummyE = ecalScale;
      dummyH = hcalScale;

      delete e_tpg;

    }
  else
    {

      // get energy scale to convert input from ECAL
      edm::ESHandle<L1CaloEcalScale> ecalScale;
      iSetup.get<L1CaloEcalScaleRcd>().get(ecalScale);
      const L1CaloEcalScale* e = ecalScale.product();
      
      // get energy scale to convert input from HCAL
      edm::ESHandle<L1CaloHcalScale> hcalScale;
      iSetup.get<L1CaloHcalScaleRcd>().get(hcalScale);
      const L1CaloHcalScale* h = hcalScale.product();

      // set scales
      lookupTable_->setEcalScale(e);
      lookupTable_->setHcalScale(h);

    }

   lookupTable_->setRCTParameters(rctParameters_);
   lookupTable_->setChannelMask(m);
   lookupTable_->setNoisyChannelMask(m2);
   //lookupTable_->setHcalScale(h);
   //lookupTable_->setEcalScale(e);
   lookupTable_->setL1CaloEtScale(s);

   for (unsigned short nCard = 0; nCard <= 6; nCard = nCard + 2)
     {
       writeRcLutFile(nCard);
       writeEicLutFile(nCard);
     }
   writeJscLutFile();

   unsigned int eicThreshold = rctParameters_->eicIsolationThreshold();
   unsigned int jscThresholdBarrel = rctParameters_->jscQuietThresholdBarrel();
   unsigned int jscThresholdEndcap = rctParameters_->jscQuietThresholdEndcap();
   writeThresholdsFile(eicThreshold, jscThresholdBarrel, jscThresholdEndcap);

  if (dummyE != 0) delete dummyE;
  if (dummyH != 0) delete dummyH;

}

void L1RCTLutWriter::endJob ( void  )

privatevirtual

Reimplemented from edm::EDAnalyzer.

Definition at line 247 of file L1RCTLutWriter.cc.

                       {
}

void L1RCTLutWriter::writeEicLutFile ( unsigned short  card )

private

Definition at line 366 of file L1RCTLutWriter.cc.

References edmPickEvents::command, data, L1RCTLookupTables::emRank(), lut2db_cfg::filename, keyName_, lookupTable_, lutFile_, and estimatePileup_makeJSON::trunc.

Referenced by analyze().

{
  // try timestamp
  char filename[256];
  char command[64];
  if (card != 6)
    {
      int card2 = card + 1;
      sprintf(filename,"EIC%i%i-%s.dat", card, card2, keyName_.c_str() );
    }
  else
    {
      sprintf(filename,"EIC6-%s.dat", keyName_.c_str() );
    }
  // open file for writing, delete any existing content
  lutFile_.open(filename, std::ios::trunc);
  lutFile_ << "Emulator-parameter generated EIC lut file, card " 
       << card << " key " << keyName_ << "   ";
  // close to append timestamp info
  lutFile_.close();
  sprintf(command, "date >> %s", filename);
  system(command);

  // reopen file for writing values
  lutFile_.open(filename, std::ios::app);

  unsigned long data = 0;

  // write all memory addresses in increasing order
  // address = (1<<22) + (etIn7Bits<<1)

  // 2^7 = 0x7f = 128
  for (int etIn7Bits = 0; etIn7Bits < 128; etIn7Bits++)
    {
      data = lookupTable_->emRank(etIn7Bits);
      if (data > 0x3f)
    {
      data = 0x3f;
    }
      lutFile_ << std::hex << data << std::dec << std::endl;
    }
  lutFile_.close();
  return;
}

void L1RCTLutWriter::writeJscLutFile ( )

private

Definition at line 413 of file L1RCTLutWriter.cc.

References edmPickEvents::command, data, lut2db_cfg::filename, keyName_, L1RCTLookupTables::lookup(), lookupTable_, lutFile_, and estimatePileup_makeJSON::trunc.

Referenced by analyze().

{
  char filename[256];
  char command[64];
  sprintf(filename, "JSC-%s.dat", keyName_.c_str() );

  // open file; if it already existed, delete existing content
  lutFile_.open(filename, std::ios::trunc);
  lutFile_ << "Emulator parameter-generated lut file, key " << keyName_ 
       << "   ";
  // close to append time-stamp
  lutFile_.close();
  sprintf(command, "date >> %s", filename);
  system(command);
  // reopen file for writing
  lutFile_.open(filename, std::ios::app);

  unsigned long data = 0;
  unsigned long data0 = 0;
  unsigned long data1 = 0;

  // write all memory addresses in increasing order
  // address = (1<<22) + (lutbits<<17) + (phi1et<<9) + (phi0et<<1);

  // ecl and U93/U225 lut id bits, identify eta segment of hf
  for (int lutbits = 0; lutbits < 4; lutbits++)
    {
      // 8-bit phi_1 et for each eta partition
      for (unsigned int phi1et = 0; phi1et < 256; phi1et++)
    {
      // 8-bit phi_0 et for each eta
      for (unsigned int phi0et = 0; phi0et < 256; phi0et++)
        {
          // lookup takes "(hf_et, crate, card, tower)"
          // "card" convention for hf is 999, tower is 0-7
          // but equivalent to 0-3 == lutbits
          // crate doesn't matter, take 0
          // only |ieta| matters
          data0 = lookupTable_->lookup(phi0et, 0, 999, lutbits);
          if (data0 > 0xff)
        {
          data0 = 0xff;   // 8-bit output energy for each phi region
        }
          data1 = lookupTable_->lookup(phi1et, 0, 999, lutbits);
          if (data1 > 0xff)
        {
          data1 = 0xff;   // 8-bit output energy for each phi region
        }
          data = (data1<<8) + (data0);
          lutFile_ << std::hex << data << std::dec << std::endl;
          /*
          if (phi0et < 10 && phi1et < 10)
        {
          std::cout << "Writer: jsc. lutbits=" << lutbits 
                << " phi0et=" << phi0et << " data0=" << data0
                << " phi1et=" << phi1et << " data1=" << data1
                << std::endl;
        }
          */
        }
    }
    }
  
  lutFile_.close();
  return;
}

void L1RCTLutWriter::writeRcLutFile ( unsigned short  card )

private

Definition at line 253 of file L1RCTLutWriter.cc.

References L1RCTParameters::calcCrate(), L1RCTParameters::calcTower(), edmPickEvents::command, data, lut2db_cfg::filename, keyName_, lookupTable_, lutFile_, convertSQLitetoXML_cfg::output, rctParameters_, and estimatePileup_makeJSON::trunc.

Referenced by analyze().

{

  // don't mess yet with name
  char filename[256];
  char command[64];
  if (card != 6)
    {
      int card2 = card + 1;
      sprintf(filename,"RC%i%i-%s.dat",card,card2,keyName_.c_str() );
      //sprintf(filename, "RC%i%i.dat", card, card2);
    }
  else
    {
      sprintf(filename,"RC6-%s.dat",keyName_.c_str() );
      //sprintf(filename, "RC6.dat");
    }
  // open file for writing, delete any existing content
  lutFile_.open(filename, std::ios::trunc);
  lutFile_ << "Emulator-parameter generated lut file, card " 
       << card << " key " << keyName_ << "   ";

  // close to append timestamp info
  lutFile_.close();
  sprintf(command, "date >> %s", filename);
  system(command);

  // reopen file for writing values
  lutFile_.open(filename, std::ios::app);

  unsigned long data = 0;

  // write all memory addresses in increasing order
  // address = (1<<22)+(nLUT<<19)+(eG?<18)+(hcalEt<<10)+(ecalfg<<9)+(ecalEt<<1)

  // loop through the physical LUTs on the card, 0-7
  for (unsigned short nLUT = 0; nLUT < 8; nLUT++)
    {
      // determine ieta, iphi, etc. everything
      unsigned short iAbsEta = 0;
      if (card != 6)
    {
      iAbsEta = (card/2)*8 + nLUT + 1;
    }
      else
    {
      if (nLUT < 4)
        {
          iAbsEta = (card/2)*8 + nLUT + 1;
        }
      else
        {
          iAbsEta = (card/2)*8 + (3 - (nLUT%4) ) + 1;         
        }
      //std::cout << "LUT is " << nLUT << " iAbsEta is " << iAbsEta << std::endl;
    }


      // All RCT stuff uniform in phi, symmetric wrt eta = 0

      // below line always gives crate in +eta; makes no difference to us
      unsigned short crate = rctParameters_->calcCrate(1, iAbsEta); 
      unsigned short tower = rctParameters_->calcTower(1, iAbsEta);

      // first do region sums half of LUTs, bit 18 of address is 0
      // loop through 8 bits of hcal energy, 2^8 is 256
      for (unsigned int hcalEt = 0; hcalEt < 256; hcalEt++)
    {
      // loop through 1 bit of ecal fine grain
      for (unsigned short ecalfg = 0; ecalfg < 2; ecalfg++)
        {
          // loop through 8 bits of ecal energy
          for (unsigned int ecalEt = 0; ecalEt < 256; ecalEt++)
        {
          // assign 10-bit (9et,1mip) sums data here!
          unsigned long output = lookupTable_->
            lookup(ecalEt, hcalEt, ecalfg, crate, card, tower);
          unsigned short etIn9Bits = (output>>8)&511;
          unsigned short tauActivityBit = (output>>17)&1;
          data = (tauActivityBit<<9)+etIn9Bits;
          lutFile_ << std::hex << data << std::dec << std::endl;
        }
        }
    }
      // second do egamma half of LUTs, bit 18 of address is 1
      // loop through 8 bits of hcal energy
      for (unsigned int hcalEt = 0; hcalEt < 256; hcalEt++)
        {
          // loop through 1 bit of ecal fine grain
          for (unsigned short ecalfg = 0; ecalfg < 2; ecalfg++)
            {
              // loop through 8 bits of ecal energy
              for (unsigned int ecalEt = 0; ecalEt < 256; ecalEt++)
                {
                  // assign 8-bit (7et,1veto) egamma data here!
          unsigned long output = lookupTable_->
            lookup(ecalEt, hcalEt, ecalfg, crate, card, tower);
          unsigned short etIn7Bits = output&127;
          unsigned short heFgVetoBit = (output>>7)&1;
          data = (heFgVetoBit<<7)+etIn7Bits;
          lutFile_ << std::hex << data << std::dec << std::endl;
                }
            }
        }
    }

  lutFile_.close();
  return;

}

void L1RCTLutWriter::writeThresholdsFile ( unsigned int  eicThreshold, unsigned int  jscThresholdBarrel, unsigned int  jscThresholdEndcap  )

private

Definition at line 482 of file L1RCTLutWriter.cc.

References lut2db_cfg::filename, keyName_, and estimatePileup_makeJSON::trunc.

Referenced by analyze().

{
  //
  std::ofstream thresholdsFile;
  char filename[256];
  sprintf(filename, "Thresholds-%s.dat", keyName_.c_str() );
  thresholdsFile.open(filename, std::ios::trunc);

  thresholdsFile << "key is " << keyName_ << std::endl << std::endl;
  thresholdsFile << "eicIsolationThreshold " << eicThreshold << std::endl;
  thresholdsFile << "jscQuietThresholdBarrel " << jscThresholdBarrel << std::endl;
  thresholdsFile << "jscQuietThresholdEndcap " << jscThresholdEndcap << std::endl;

  thresholdsFile.close();
}

Member Data Documentation

std::string L1RCTLutWriter::keyName_

private

Definition at line 70 of file L1RCTLutWriter.h.

Referenced by writeEicLutFile(), writeJscLutFile(), writeRcLutFile(), and writeThresholdsFile().

L1RCTLookupTables* L1RCTLutWriter::lookupTable_

private

Definition at line 66 of file L1RCTLutWriter.h.

Referenced by analyze(), writeEicLutFile(), writeJscLutFile(), writeRcLutFile(), and ~L1RCTLutWriter().

std::ofstream L1RCTLutWriter::lutFile_

private

Definition at line 69 of file L1RCTLutWriter.h.

Referenced by writeEicLutFile(), writeJscLutFile(), and writeRcLutFile().

const L1RCTParameters* L1RCTLutWriter::rctParameters_

private

Definition at line 67 of file L1RCTLutWriter.h.

Referenced by analyze(), and writeRcLutFile().

bool L1RCTLutWriter::useDebugTpgScales_

private

Definition at line 71 of file L1RCTLutWriter.h.

Referenced by analyze().