CMS 3D CMS Logo

Classes | Public Member Functions | Private Member Functions | Private Attributes

RPCTechnicalTrigger Class Reference

#include <L1Trigger/RPCTechnicalTrigger/interface/RPCTechnicalTrigger.cc>

Inheritance diagram for RPCTechnicalTrigger:
edm::EDProducer edm::ProducerBase edm::ProductRegistryHelper

List of all members.

Classes

struct  sortByBx
class  TTUResults

Public Member Functions

 RPCTechnicalTrigger (const edm::ParameterSet &)
 ~RPCTechnicalTrigger ()

Private Member Functions

virtual void beginRun (edm::Run &, const edm::EventSetup &)
int convertToMap (const std::vector< TTUResults * > &)
virtual void endJob ()
void printinfo ()
virtual void produce (edm::Event &, const edm::EventSetup &)
bool Reset ()
bool searchCoincidence (int, int)

Private Attributes

int m_boardIndex [3]
int m_cand
std::string m_configFile
std::vector< int >::iterator m_firstSector
bool m_hasConfig
int m_ievt
RPCInputSignalm_input
int m_maxBits
int m_maxTtuBoards
int m_nWheels [3]
std::vector< int > m_quadrants
const RBCBoardSpecsm_rbcspecs
TTUConfiguratorm_readConfig
edm::InputTag m_rpcDigiLabel
edm::ESHandle< RPCGeometrym_rpcGeometry
edm::InputTag m_rpcSimLinkInstance
std::vector< TTUResults * > m_serializedInfoLine1
std::vector< TTUResults * > m_serializedInfoLine2
ProcessInputSignalm_signal
std::bitset< 5 > m_triggerbits
std::vector< unsigned > m_ttBits
std::vector< std::string > m_ttNames
TTUEmulatorm_ttu [3]
TTUEmulatorm_ttuRbcLine [3]
std::map< int, TTUResults * > m_ttuResultsByQuadrant
const TTUBoardSpecsm_ttuspecs
int m_useEventSetup
int m_useRPCSimLink
int m_verbosity
std::map< int, int > m_WheelTtu

Detailed Description

Description: Implementation of the RPC Technical Trigger Emulator

Implementation:

Definition at line 68 of file RPCTechnicalTrigger.h.


Constructor & Destructor Documentation

RPCTechnicalTrigger::RPCTechnicalTrigger ( const edm::ParameterSet iConfig) [explicit]

Definition at line 28 of file RPCTechnicalTrigger.cc.

References HDQMDatabaseProducer::configFile, python::connectstrParser::f1, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), LogTrace, m_boardIndex, m_cand, m_configFile, m_hasConfig, m_ievt, m_maxBits, m_maxTtuBoards, m_nWheels, m_quadrants, m_readConfig, m_rpcDigiLabel, m_rpcSimLinkInstance, m_ttBits, m_ttNames, m_ttu, m_ttuRbcLine, m_useEventSetup, m_useRPCSimLink, m_verbosity, m_WheelTtu, and NULL.

                                                                       {
  
  //...........................................................................
  
  std::string configFile  = iConfig.getParameter<std::string>("ConfigFile");
  m_verbosity             = iConfig.getUntrackedParameter<int>("Verbosity", 0);
  m_rpcDigiLabel          = iConfig.getParameter<edm::InputTag>("RPCDigiLabel");
  m_ttBits                = iConfig.getParameter< std::vector<unsigned> >("BitNumbers");
  m_ttNames               = iConfig.getParameter< std::vector<std::string> >("BitNames");
  m_useEventSetup         = iConfig.getUntrackedParameter<int>("UseEventSetup", 0);
  m_useRPCSimLink         = iConfig.getUntrackedParameter<int>("UseRPCSimLink", 0);
  m_rpcSimLinkInstance    = iConfig.getParameter<edm::InputTag>("RPCSimLinkInstance");

  edm::FileInPath f1("L1Trigger/RPCTechnicalTrigger/data/" + configFile);
  m_configFile = f1.fullPath();

  if ( m_verbosity ) {
    LogTrace("RPCTechnicalTrigger")
      << m_rpcDigiLabel << '\n'
      << std::endl;

    LogTrace("RPCTechnicalTrigger")
      << "\nConfiguration file used for UseEventSetup = 0 \n" << m_configFile << '\n'
      << std::endl;
  }
  
  //...........................................................................
  //... There are three Technical Trigger Units Boards: 1 can handle 2 Wheels
  //... n_Wheels sets the number of wheels attached to board with index boardIndex
  
  m_boardIndex[0] = 1;
  m_boardIndex[1] = 2;
  m_boardIndex[2] = 3;
  
  m_nWheels[0]    = 2;
  m_nWheels[1]    = 1;
  m_nWheels[2]    = 2;
  
  m_ttu[0] = new TTUEmulator( m_boardIndex[0] , m_nWheels[0] );
  m_ttu[1] = new TTUEmulator( m_boardIndex[1] , m_nWheels[1] );
  m_ttu[2] = new TTUEmulator( m_boardIndex[2] , m_nWheels[2] );

  //... This is second line that delivers in parallel a second trigger
  m_ttuRbcLine[0] = new TTUEmulator( m_boardIndex[0] , m_nWheels[0] );
  m_ttuRbcLine[1] = new TTUEmulator( m_boardIndex[1] , m_nWheels[1] );
  m_ttuRbcLine[2] = new TTUEmulator( m_boardIndex[2] , m_nWheels[2] );
  
  m_WheelTtu[-2] = 3;
  m_WheelTtu[-1] = 3;
  m_WheelTtu[0 ] = 2;
  m_WheelTtu[1 ] = 1;
  m_WheelTtu[2 ] = 1;
  
  //...........................................................................
  //For the pointing Logic: declare here the first sector of each quadrant
  //
  m_quadrants.push_back(2);
  m_quadrants.push_back(3);
  m_quadrants.push_back(4);
  m_quadrants.push_back(5);
  m_quadrants.push_back(6);
  m_quadrants.push_back(7);
  m_quadrants.push_back(8);
  m_quadrants.push_back(9);
  m_quadrants.push_back(10);
  m_quadrants.push_back(11);

  //...........................................................................
  
  m_ievt = 0;
  m_cand = 0;
  m_maxTtuBoards = 3;
  m_maxBits = 5;
  m_hasConfig = false;
  m_readConfig = NULL;
  produces<L1GtTechnicalTriggerRecord>();
  
}
RPCTechnicalTrigger::~RPCTechnicalTrigger ( )

Definition at line 108 of file RPCTechnicalTrigger.cc.

References LogDebug, m_hasConfig, m_readConfig, m_ttu, m_ttuRbcLine, and m_WheelTtu.

{
  
  LogDebug("RPCTechnicalTrigger") << "RPCTechnicalTrigger: object starts deletion" << std::endl;

  if ( m_hasConfig ) {
    
    delete m_ttu[0];
    delete m_ttu[1];
    delete m_ttu[2];
    
    delete m_ttuRbcLine[0];
    delete m_ttuRbcLine[1];
    delete m_ttuRbcLine[2];
    
    if ( m_readConfig )
      delete m_readConfig;
    
  }
  
  m_WheelTtu.clear();
    
  LogDebug("RPCTechnicalTrigger") << "RPCTechnicalTrigger: object deleted" << '\n';
  
}

Member Function Documentation

void RPCTechnicalTrigger::beginRun ( edm::Run iRun,
const edm::EventSetup evtSetup 
) [private, virtual]

Reimplemented from edm::EDProducer.

Definition at line 378 of file RPCTechnicalTrigger.cc.

References edm::EventSetup::get(), TTUConfigurator::getRbcSpecs(), TTUConfigurator::getTtuSpecs(), TTUEmulator::initialise(), edm::ESHandleBase::isValid(), gen::k, LogDebug, m_configFile, m_hasConfig, TTUConfigurator::m_hasConfig, m_maxTtuBoards, m_rbcspecs, m_readConfig, m_rpcGeometry, m_ttu, m_ttuRbcLine, m_ttuspecs, m_useEventSetup, TTUConfigurator::process(), edm::ESHandle< T >::product(), TTUEmulator::SetLineId(), and TTUEmulator::setSpecifications().

{
  LogDebug("RPCTechnicalTrigger") << "RPCTechnicalTrigger::beginRun> starts" << std::endl;
  
  //.   Set up RPC geometry
  
  evtSetup.get<MuonGeometryRecord>().get( m_rpcGeometry );
  
  //..  Get Board Specifications (hardware configuration)
  
  if ( m_useEventSetup >= 1 ) {
    
    edm::ESHandle<RBCBoardSpecs> pRBCSpecs;
    evtSetup.get<RBCBoardSpecsRcd>().get(pRBCSpecs);

    edm::ESHandle<TTUBoardSpecs> pTTUSpecs;
    evtSetup.get<TTUBoardSpecsRcd>().get(pTTUSpecs);
    
    if ( !pRBCSpecs.isValid() ||  !pTTUSpecs.isValid() ) {
      edm::LogError("RPCTechnicalTrigger") << "can't find RBC/TTU BoardSpecsRcd" << '\n';
      m_hasConfig = false;
    }
    else  {
      m_rbcspecs = pRBCSpecs.product();
      m_ttuspecs = pTTUSpecs.product();
      m_hasConfig = true;
    }
    
  } else {
    
    // read hardware configuration from file
    m_readConfig = new TTUConfigurator( m_configFile );
    
    if ( m_readConfig->m_hasConfig ) {
      m_readConfig->process();
      m_rbcspecs = m_readConfig->getRbcSpecs();
      m_ttuspecs = m_readConfig->getTtuSpecs();
      m_hasConfig = true;
    }
    
    else m_hasConfig = false;
    
  }
  
  if ( m_hasConfig ) {
    
    //... Initialize all
    
    for (int k=0; k < m_maxTtuBoards; ++k ) {

      m_ttu[k]->SetLineId ( 1 );
      m_ttuRbcLine[k]->SetLineId( 2 );
      
      m_ttu[k]->setSpecifications( m_ttuspecs, m_rbcspecs );
      m_ttuRbcLine[k]->setSpecifications( m_ttuspecs, m_rbcspecs );
      
      m_ttu[k]->initialise();
      m_ttuRbcLine[k]->initialise();
    }
  
  }
    
}
int RPCTechnicalTrigger::convertToMap ( const std::vector< TTUResults * > &  ttuResults) [private]

Definition at line 443 of file RPCTechnicalTrigger.cc.

References combine::key, and m_ttuResultsByQuadrant.

Referenced by produce().

{
  
  std::vector<TTUResults*>::const_iterator itr = ttuResults.begin();
  
  while ( itr != ttuResults.end() ) {
    
    if ( (*itr)->m_bx != 0 ) {
      ++itr;
      continue;
    }
    
    int key(0);
    key = 1000 * ( (*itr)->m_ttuidx + 1 ) + 1*(*itr)->m_wedge;
    m_ttuResultsByQuadrant[ key ] = (*itr);
    ++itr;
    
  }
  
  return m_ttuResultsByQuadrant.size();
    
}
void RPCTechnicalTrigger::endJob ( void  ) [private, virtual]

Reimplemented from edm::EDProducer.

Definition at line 550 of file RPCTechnicalTrigger.cc.

References LogDebug.

{
  
  LogDebug("RPCTechnicalTrigger") << "RPCTechnicalTrigger::endJob>" << std::endl;
  
}
void RPCTechnicalTrigger::printinfo ( ) [private]

Definition at line 557 of file RPCTechnicalTrigger.cc.

References gen::k, LogDebug, m_maxTtuBoards, m_ttu, m_ttuRbcLine, and TTUEmulator::printinfo().

{
  
  LogDebug("RPCTechnicalTrigger") << "RPCTechnicalTrigger::Printing TTU emulators info>" << std::endl;
  
  for (int k=0; k < m_maxTtuBoards; ++k ) {
    m_ttu[k]->printinfo();
    m_ttuRbcLine[k]->printinfo();
  }
  
    
}
void RPCTechnicalTrigger::produce ( edm::Event iEvent,
const edm::EventSetup iSetup 
) [private, virtual]

Implements edm::EDProducer.

Definition at line 135 of file RPCTechnicalTrigger.cc.

References abs, TTUEmulator::clearTriggerResponse(), convertToMap(), gather_cfg::cout, edm::Event::getByLabel(), edm::HandleBase::isValid(), gen::k, LogDebug, m_firstSector, m_hasConfig, m_ievt, m_input, m_maxTtuBoards, m_quadrants, m_rpcDigiLabel, m_rpcGeometry, m_serializedInfoLine1, m_serializedInfoLine2, m_signal, m_triggerbits, TTUEmulator::m_triggerBxVec, m_ttBits, m_ttNames, m_ttu, m_ttuRbcLine, m_useRPCSimLink, m_verbosity, ProcessInputSignal::next(), convertSQLitetoXML_cfg::output, TTUEmulator::processTtu(), edm::Event::put(), Reset(), query::result, ProcessInputSignal::retrievedata(), searchCoincidence(), python::multivaluedict::sort(), and ntuplemaker::status.

                                                                               {


  bool status(false);
  
  edm::Handle<RPCDigiCollection> pIn;
  
  edm::Handle<edm::DetSetVector<RPCDigiSimLink> > simIn;
  
  std::auto_ptr<L1GtTechnicalTriggerRecord> output(new L1GtTechnicalTriggerRecord());
  
  if ( m_useRPCSimLink == 0 ) {

    iEvent.getByLabel(m_rpcDigiLabel, pIn);
    if ( ! pIn.isValid() ) {
      edm::LogError("RPCTechnicalTrigger") << "can't find RPCDigiCollection with label: " 
                                           << m_rpcDigiLabel << '\n';
      iEvent.put(output);
      return;
    }
    m_signal  = dynamic_cast<ProcessInputSignal*>(new RBCProcessRPCDigis( m_rpcGeometry, pIn ));
    
  } else {
    
    iEvent.getByLabel("simMuonRPCDigis", "RPCDigiSimLink", simIn);
    
    if ( ! simIn.isValid() ) {
      edm::LogError("RPCTechnicalTrigger") << "can't find RPCDigiCollection with label: " 
                                           << m_rpcDigiLabel << '\n';
      iEvent.put(output);
      return;
    }
    m_signal  = dynamic_cast<ProcessInputSignal*>(new RBCProcessRPCSimDigis( m_rpcGeometry, simIn ));
  }
  
  LogDebug("RPCTechnicalTrigger") << "signal object created" << '\n';
  
  if ( ! m_hasConfig ) {
    edm::LogError("RPCTechnicalTrigger") << "cannot read hardware configuration \n";
    iEvent.put(output);
    return;
  }
  
  status = m_signal->next();
  
  if ( !status)  { 
    delete m_signal;
    iEvent.put(output);
    return;
  }
  
  m_input = m_signal->retrievedata();
  
  std::vector<L1GtTechnicalTrigger> ttVec( m_ttBits.size() );
  
  //. distribute data to different TTU emulator instances and process it
  
  m_triggerbits.reset();
  
  std::vector<TTUEmulator::TriggerResponse*>::const_iterator outItr;
  
  for(int k=0; k < m_maxTtuBoards; ++k) {
    
    m_ttu[k]->processTtu( m_input );
    
    //work out Pointing Logic to Tracker
    for( m_firstSector = m_quadrants.begin(); m_firstSector != m_quadrants.end(); ++m_firstSector)
      m_ttuRbcLine[k]->processTtu( m_input , (*m_firstSector) );
    
    //...for trigger 1
    for( outItr  = m_ttu[k]->m_triggerBxVec.begin(); outItr != m_ttu[k]->m_triggerBxVec.end(); ++outItr )
      m_serializedInfoLine1.push_back( new TTUResults( k, (*outItr)->m_bx, (*outItr)->m_trigger[0], (*outItr)->m_trigger[1] ) );
    m_ttu[k]->clearTriggerResponse();
    
    //...for trigger 2
    for( outItr  = m_ttuRbcLine[k]->m_triggerBxVec.begin(); outItr != m_ttuRbcLine[k]->m_triggerBxVec.end(); ++outItr )
      m_serializedInfoLine2.push_back( new TTUResults( k, 
                                                       (*outItr)->m_bx, 
                                                       (*outItr)->m_trigger[0], 
                                                       (*outItr)->m_trigger[1], 
                                                       (*outItr)->m_wedge ) );
    
    m_ttuRbcLine[k]->clearTriggerResponse();
    
  }
  
  //.. write results to technical trigger bits
  int bx(0);
  int infoSize(0);
  
  infoSize = m_serializedInfoLine1.size();

  std::vector<RPCTechnicalTrigger::TTUResults*>::const_iterator ttuItr;
  
  std::sort( m_serializedInfoLine1.begin(), m_serializedInfoLine1.end(), sortByBx() );
  
  for( ttuItr = m_serializedInfoLine1.begin(); ttuItr != m_serializedInfoLine1.end(); ++ttuItr ) {
    if ( m_verbosity && abs( (*ttuItr)->m_bx ) <= 1 ) 
      std::cout << "RPCTechnicalTrigger> " 
                << (*ttuItr)->m_ttuidx << '\t'
                << (*ttuItr)->m_bx << '\t'
                << (*ttuItr)->m_trigWheel1 << '\t'
                << (*ttuItr)->m_trigWheel2 << '\n';
  }
  
  bool has_bx0 = false;
  
  for(int k = 0; k < infoSize; k+=m_maxTtuBoards) {
    
    bx = m_serializedInfoLine1[k]->m_bx;
    
    if ( bx == 0 ) {
      
      m_triggerbits.set(0, m_serializedInfoLine1[k]->m_trigWheel2);
      m_triggerbits.set(1, m_serializedInfoLine1[k]->m_trigWheel1);
      m_triggerbits.set(2, m_serializedInfoLine1[k+1]->m_trigWheel1);
      m_triggerbits.set(3, m_serializedInfoLine1[k+2]->m_trigWheel1);
      m_triggerbits.set(4, m_serializedInfoLine1[k+2]->m_trigWheel2);
      
      bool five_wheels_OR = m_triggerbits.any();
      
      ttVec.at(0)=L1GtTechnicalTrigger(m_ttNames.at(0), m_ttBits.at(0), bx, five_wheels_OR ) ;   // bit 24 = Or 5 wheels in TTU mode
      ttVec.at(2)=L1GtTechnicalTrigger(m_ttNames.at(2), m_ttBits.at(2), bx, m_triggerbits[0] ) ; // bit 26 
      ttVec.at(3)=L1GtTechnicalTrigger(m_ttNames.at(3), m_ttBits.at(3), bx, m_triggerbits[1] ) ; // bit 27 
      ttVec.at(4)=L1GtTechnicalTrigger(m_ttNames.at(4), m_ttBits.at(4), bx, m_triggerbits[2] ) ; // bit 28 
      ttVec.at(5)=L1GtTechnicalTrigger(m_ttNames.at(5), m_ttBits.at(5), bx, m_triggerbits[3] ) ; // bit 29
      ttVec.at(6)=L1GtTechnicalTrigger(m_ttNames.at(6), m_ttBits.at(6), bx, m_triggerbits[4] ) ; // bit 30
      
      m_triggerbits.reset();
      
      has_bx0 = true;
      
      break;
      
    } else continue;
    
  }
  
  infoSize = m_serializedInfoLine2.size();
  
  std::sort( m_serializedInfoLine2.begin(), m_serializedInfoLine2.end(), sortByBx() );
  
  for( ttuItr = m_serializedInfoLine2.begin(); ttuItr != m_serializedInfoLine2.end(); ++ttuItr ) {
    if ( m_verbosity && abs ( (*ttuItr)->m_bx ) <= 1 )
      std::cout << "RPCTechnicalTrigger> " 
                << (*ttuItr)->m_ttuidx << '\t'
                << (*ttuItr)->m_bx << '\t'
                << (*ttuItr)->m_trigWheel1 << '\t'
                << (*ttuItr)->m_trigWheel2 << '\t'
                << (*ttuItr)->m_wedge << '\n';
  }
  
  infoSize = convertToMap( m_serializedInfoLine2 );
  
  std::bitset<8> triggerCoincidence;
  triggerCoincidence.reset();
  
  // searchCoincidence( W-2 , W0 )
  bool result = searchCoincidence( -2, 0 );
  triggerCoincidence.set(0, result );
  
  // searchCoincidence( W-2 , W+1 )
  result = searchCoincidence( -2, 1 );
  triggerCoincidence.set(1, result );
  
  // searchCoincidence( W-1 , W0  )
  result = searchCoincidence( -1, 0 );
  triggerCoincidence.set(2, result );
  
  // searchCoincidence( W-1 , W+1 )
  result = searchCoincidence( -1, 1 );
  triggerCoincidence.set(3, result );
  
  // searchCoincidence( W-1 , W+2 )
  result = searchCoincidence( -1, 2 );
  triggerCoincidence.set(4, result );
  
  // searchCoincidence( W0  , W0  )
  result = searchCoincidence( 0 , 0 );
  triggerCoincidence.set(5, result );
  
  // searchCoincidence( W+1 , W0  )
  result = searchCoincidence( 1, 0 );
  triggerCoincidence.set(6, result );
  
  // searchCoincidence( W+2 , W0  ) 
  result = searchCoincidence( 2, 0 );
  triggerCoincidence.set(7, result );
  
  bool five_wheels_OR = triggerCoincidence.any();

  if ( m_verbosity ) std::cout << "RPCTechnicalTrigger> pointing trigger: " << five_wheels_OR << '\n';
  
  ttVec.at(1)=L1GtTechnicalTrigger(m_ttNames.at(1), m_ttBits.at(1), bx, five_wheels_OR ) ; // bit 25 = Or 5 wheels in RBC mode
  
  triggerCoincidence.reset();
  
  //...check that data appeared at bx=0
  
  if ( ! has_bx0 ) {
    iEvent.put(output);
    status = Reset();
    ++m_ievt;
    LogDebug("RPCTechnicalTrigger") << "RPCTechnicalTrigger> end of event loop" << std::endl;
    return;
    
  }
  
  output->setGtTechnicalTrigger(ttVec);    
  iEvent.put(output);
  
  //.... all done
  
  status = Reset();
  ++m_ievt;
  LogDebug("RPCTechnicalTrigger") << "RPCTechnicalTrigger> end of event loop" << std::endl;
  
}
bool RPCTechnicalTrigger::Reset ( void  ) [private]

Definition at line 354 of file RPCTechnicalTrigger.cc.

References RPCInputSignal::clear(), m_input, m_serializedInfoLine1, m_serializedInfoLine2, m_signal, m_triggerbits, and m_ttuResultsByQuadrant.

Referenced by produce().

{
  
  m_input->clear();
  m_triggerbits.reset();
  std::vector<TTUResults*>::iterator itrRes;
  
  for( itrRes=m_serializedInfoLine1.begin(); itrRes!=m_serializedInfoLine1.end(); ++itrRes)
    delete (*itrRes);
  
  for( itrRes=m_serializedInfoLine2.begin(); itrRes!=m_serializedInfoLine2.end(); ++itrRes)
    delete (*itrRes);
  
  m_serializedInfoLine1.clear();
  m_serializedInfoLine2.clear();
  m_ttuResultsByQuadrant.clear();
  
  delete m_signal; 
  
  return true;
  
}
bool RPCTechnicalTrigger::searchCoincidence ( int  wheel1,
int  wheel2 
) [private]

Definition at line 467 of file RPCTechnicalTrigger.cc.

References gen::k, combine::key, m_firstSector, m_quadrants, m_ttuResultsByQuadrant, and m_WheelTtu.

Referenced by produce().

{
  
  std::map<int, TTUResults*>::iterator itr;
  bool topRight(false);
  bool botLeft(false);
  
  int indxW1 = m_WheelTtu[wheel1];
  int indxW2 = m_WheelTtu[wheel2];
  
  int k(0);
  int key(0);
  bool finalTrigger(false);
  int maxTopQuadrants = 4;
  
  //work out Pointing Logic to Tracker
  
  for( m_firstSector = m_quadrants.begin(); m_firstSector != m_quadrants.end(); ++m_firstSector) {
    
    key = 1000 * ( indxW1 ) + (*m_firstSector);
    
    itr = m_ttuResultsByQuadrant.find( key );
    if ( itr != m_ttuResultsByQuadrant.end() )
      topRight  =  (*itr).second->getTriggerForWheel(wheel1);

    //std::cout << "W1: " << wheel1 << " " << "sec: " << (*m_firstSector) << " dec: " << topRight << '\n';
    
    key = 1000 * ( indxW2 ) + (*m_firstSector) + 5;
    
    itr = m_ttuResultsByQuadrant.find( key );
    
    if ( itr != m_ttuResultsByQuadrant.end() )
      botLeft   = (*itr).second->getTriggerForWheel(wheel2);
    
    //std::cout << "W2: " << wheel2 << " " << "sec: " << (*m_firstSector) + 5 << " dec: " << botLeft << '\n';
    
    finalTrigger |= ( topRight && botLeft );
    
    ++k;
    
    if ( k > maxTopQuadrants)
      break;
        
  }
  
  //Try the opposite now

  k=0;
  
  for( m_firstSector = m_quadrants.begin(); m_firstSector != m_quadrants.end(); ++m_firstSector) {
    
    key = 1000 * ( indxW2 ) + (*m_firstSector);
    
    itr = m_ttuResultsByQuadrant.find( key );
    if ( itr != m_ttuResultsByQuadrant.end() )
      topRight  =  (*itr).second->getTriggerForWheel(wheel1);

    //std::cout << "W1: " << wheel1 << " " << "sec: " << (*m_firstSector) << " dec: " << topRight << '\n';
    
    key = 1000 * ( indxW1 ) + (*m_firstSector) + 5;
    
    itr = m_ttuResultsByQuadrant.find( key );
    
    if ( itr != m_ttuResultsByQuadrant.end() )
      botLeft   = (*itr).second->getTriggerForWheel(wheel2);
    
    //std::cout << "W2: " << wheel2 << " " << "sec: " << (*m_firstSector) + 5 << " dec: " << botLeft << '\n';
    
    finalTrigger |= ( topRight && botLeft );
    
    ++k;
    
    if ( k > maxTopQuadrants)
      break;
        
  }
  
  return finalTrigger;
  
}

Member Data Documentation

Definition at line 115 of file RPCTechnicalTrigger.h.

Referenced by RPCTechnicalTrigger().

Definition at line 114 of file RPCTechnicalTrigger.h.

Referenced by RPCTechnicalTrigger().

std::string RPCTechnicalTrigger::m_configFile [private]

Definition at line 101 of file RPCTechnicalTrigger.h.

Referenced by beginRun(), and RPCTechnicalTrigger().

std::vector<int>::iterator RPCTechnicalTrigger::m_firstSector [private]

Definition at line 182 of file RPCTechnicalTrigger.h.

Referenced by produce(), and searchCoincidence().

Definition at line 113 of file RPCTechnicalTrigger.h.

Referenced by produce(), and RPCTechnicalTrigger().

Definition at line 91 of file RPCTechnicalTrigger.h.

Referenced by produce(), and Reset().

Definition at line 118 of file RPCTechnicalTrigger.h.

Referenced by RPCTechnicalTrigger().

Definition at line 117 of file RPCTechnicalTrigger.h.

Referenced by beginRun(), printinfo(), produce(), and RPCTechnicalTrigger().

Definition at line 116 of file RPCTechnicalTrigger.h.

Referenced by RPCTechnicalTrigger().

std::vector<int> RPCTechnicalTrigger::m_quadrants [private]

Definition at line 180 of file RPCTechnicalTrigger.h.

Referenced by produce(), RPCTechnicalTrigger(), and searchCoincidence().

Definition at line 111 of file RPCTechnicalTrigger.h.

Referenced by beginRun().

Definition at line 109 of file RPCTechnicalTrigger.h.

Referenced by beginRun(), RPCTechnicalTrigger(), and ~RPCTechnicalTrigger().

Definition at line 104 of file RPCTechnicalTrigger.h.

Referenced by produce(), and RPCTechnicalTrigger().

Definition at line 97 of file RPCTechnicalTrigger.h.

Referenced by beginRun(), and produce().

Definition at line 105 of file RPCTechnicalTrigger.h.

Referenced by RPCTechnicalTrigger().

Definition at line 169 of file RPCTechnicalTrigger.h.

Referenced by produce(), and Reset().

Definition at line 170 of file RPCTechnicalTrigger.h.

Referenced by produce(), and Reset().

Definition at line 93 of file RPCTechnicalTrigger.h.

Referenced by produce(), and Reset().

std::bitset<5> RPCTechnicalTrigger::m_triggerbits [private]

Definition at line 95 of file RPCTechnicalTrigger.h.

Referenced by produce(), and Reset().

std::vector<unsigned> RPCTechnicalTrigger::m_ttBits [private]

Definition at line 102 of file RPCTechnicalTrigger.h.

Referenced by produce(), and RPCTechnicalTrigger().

std::vector<std::string> RPCTechnicalTrigger::m_ttNames [private]

Definition at line 103 of file RPCTechnicalTrigger.h.

Referenced by produce(), and RPCTechnicalTrigger().

Definition at line 178 of file RPCTechnicalTrigger.h.

Referenced by convertToMap(), Reset(), and searchCoincidence().

Definition at line 110 of file RPCTechnicalTrigger.h.

Referenced by beginRun().

Definition at line 100 of file RPCTechnicalTrigger.h.

Referenced by beginRun(), and RPCTechnicalTrigger().

Definition at line 107 of file RPCTechnicalTrigger.h.

Referenced by produce(), and RPCTechnicalTrigger().

Definition at line 99 of file RPCTechnicalTrigger.h.

Referenced by produce(), and RPCTechnicalTrigger().

std::map<int,int> RPCTechnicalTrigger::m_WheelTtu [private]