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/data/refman/pasoursint/CMSSW_5_3_10/src/L1Trigger/GlobalCaloTrigger/src/L1GctTdrJetFinder.cc

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00001 #include "L1Trigger/GlobalCaloTrigger/interface/L1GctTdrJetFinder.h"
00002 
00003 using namespace std;
00004 
00005 //DEFINE STATICS
00006 // *** Note the following definition in terms of COL_OFFSET appears not to work ***
00007 // ***          for some deep C++ reason that I don't understand - GPH          ***
00008 // const unsigned int L1GctTdrJetFinder::MAX_REGIONS_IN = L1GctJetFinderBase::COL_OFFSET*L1GctTdrJetFinder::N_COLS;
00009 // ***                        So - use the following instead                    ***
00010 const unsigned int L1GctTdrJetFinder::MAX_REGIONS_IN = (((L1CaloRegionDetId::N_ETA)/2)+1)*L1GctTdrJetFinder::N_COLS;
00011 
00012 const unsigned int L1GctTdrJetFinder::N_COLS = 4;
00013 const unsigned int L1GctTdrJetFinder::CENTRAL_COL0 = 1;
00014 
00015 L1GctTdrJetFinder::L1GctTdrJetFinder(int id):
00016   L1GctJetFinderBase(id)
00017 {
00018   this->reset();
00019   // Initialise parameters for Region input calculations in the 
00020   // derived class so we get the right values of constants.
00021   static const unsigned NPHI = L1CaloRegionDetId::N_PHI;
00022   m_minColThisJf = (NPHI + m_id*2 - CENTRAL_COL0) % NPHI;
00023 }
00024 
00025 L1GctTdrJetFinder::~L1GctTdrJetFinder()
00026 {
00027 }
00028 
00029 ostream& operator << (ostream& os, const L1GctTdrJetFinder& algo)
00030 {
00031   os << "===L1GctTdrJetFinder===" << endl;
00032   const L1GctJetFinderBase* temp = &algo;
00033   os << *temp;
00034   return os;
00035 }
00036 
00037 void L1GctTdrJetFinder::fetchInput()
00038 {
00039 }
00040 
00041 void L1GctTdrJetFinder::process() 
00042 {
00043   if (setupOk()) {
00044     findJets();
00045     sortJets();
00046     doEnergySums();
00047   }
00048 }
00049 
00051 
00052 void L1GctTdrJetFinder::findJets() 
00053 {
00054   UShort jetNum = 0; //holds the number of jets currently found
00055   UShort centreIndex = COL_OFFSET*this->centralCol0();
00056   for(UShort column = 0; column <2; ++column)  //Find jets in the central search region
00057   {
00058     //don't include row zero as it is not in the search region
00059     ++centreIndex;
00060     for (UShort row = 1; row < COL_OFFSET; ++row)  
00061     {
00062       //Determine if we are at end of the HF or not (so need 3*2 window)
00063       bool hfBoundary = (row == COL_OFFSET-1);
00064       //Determine if we are at the end of the endcap HCAL regions, so need boundary condition tauveto
00065       bool heBoundary = (row == COL_OFFSET-5);
00066 
00067       //debug checks for improper input indices
00068       if ((centreIndex % COL_OFFSET != 0)  //Don't want the 4 regions from other half of detector
00069           && (centreIndex >= COL_OFFSET)  //Don't want the shared column to left of jet finding area
00070           && (centreIndex < (MAX_REGIONS_IN - COL_OFFSET))) { //Don't want column to the right either
00071                         
00072         if(detectJet(centreIndex, hfBoundary))
00073           {
00074             if (jetNum < MAX_JETS_OUT) {
00075             
00076               m_outputJets.at(jetNum).setRawsum(calcJetEnergy(centreIndex, hfBoundary));
00077               m_outputJets.at(jetNum).setDetId(calcJetPosition(centreIndex));
00078               m_outputJets.at(jetNum).setBx(m_inputRegions.at(centreIndex).bx());
00079               if(row < COL_OFFSET-4)  //if we are not in the HF, perform tauVeto analysis
00080                 {
00081                   m_outputJets.at(jetNum).setForward(false);
00082                   m_outputJets.at(jetNum).setTauVeto(calcJetTauVeto(centreIndex,heBoundary));
00083                 }
00084               else //can't be a tau jet because we are in the HF
00085                 {
00086                   m_outputJets.at(jetNum).setForward(true);
00087                   m_outputJets.at(jetNum).setTauVeto(true);
00088                 }
00089               ++jetNum;
00090             }
00091           }
00092         ++centreIndex;
00093       }
00094     }
00095   }
00096 }
00097 
00098 // Returns true if region index is the centre of a jet. Set boundary = true if at edge of HCAL.
00099 bool L1GctTdrJetFinder::detectJet(const UShort centreIndex, const bool boundary) const
00100 {
00101   if(!boundary)  //Not at boundary, so use 3*3 window of regions to determine if a jet
00102   {
00103     // Get the energy of the central region
00104     ULong testEt = m_inputRegions.at(centreIndex).et();
00105         
00106     //Test if our region qualifies as a jet by comparing its energy with the energies of the
00107     //surrounding eight regions.  In the event of neighbouring regions with identical energy,
00108     //this will locate the jet in the lower-most (furthest away from eta=0), left-most (least phi) region.
00109     if(testEt >  m_inputRegions.at(centreIndex-1-COL_OFFSET).et() &&
00110        testEt >  m_inputRegions.at(centreIndex - COL_OFFSET).et() &&
00111        testEt >  m_inputRegions.at(centreIndex+1-COL_OFFSET).et() &&
00112            
00113        testEt >= m_inputRegions.at(centreIndex - 1).et() &&
00114        testEt >  m_inputRegions.at(centreIndex + 1).et() &&
00115            
00116        testEt >= m_inputRegions.at(centreIndex-1+COL_OFFSET).et() &&
00117        testEt >= m_inputRegions.at(centreIndex + COL_OFFSET).et() &&
00118        testEt >= m_inputRegions.at(centreIndex+1+COL_OFFSET).et())
00119     {
00120       return true;
00121     }
00122 //USE THIS BLOCK INSTEAD IF YOU WANT OVERFLOW BIT FUNCTIONALITY        
00123 //*** BUT IT WILL NEED MODIFICATION SINCE L1GctRegion IS OBSOLETE ***
00124 /*    // Get the energy of the central region & OR the overflow bit to become the MSB
00125     ULong testEt = (m_inputRegions.at(centreIndex).et() | (m_inputRegions.at(centreIndex).getOverFlow() << L1GctRegion::ET_BITWIDTH));
00126         
00127     //Test if our region qualifies as a jet by comparing its energy with the energies of the
00128     //surrounding eight regions.  In the event of neighbouring regions with identical energy,
00129     //this will locate the jet in the lower-most (furthest away from eta=0), left-most (least phi) region.
00130     if(testEt >  (m_inputRegions.at(centreIndex-1-COL_OFFSET).et() | (m_inputRegions.at(centreIndex-1-COL_OFFSET).getOverFlow() << L1GctRegion::ET_BITWIDTH)) &&
00131        testEt >  (m_inputRegions.at(centreIndex - COL_OFFSET).et() | (m_inputRegions.at(centreIndex - COL_OFFSET).getOverFlow() << L1GctRegion::ET_BITWIDTH)) &&
00132        testEt >  (m_inputRegions.at(centreIndex+1-COL_OFFSET).et() | (m_inputRegions.at(centreIndex+1-COL_OFFSET).getOverFlow() << L1GctRegion::ET_BITWIDTH)) &&
00133            
00134        testEt >= (m_inputRegions.at(centreIndex - 1).et() | (m_inputRegions.at(centreIndex - 1).getOverFlow() << L1GctRegion::ET_BITWIDTH)) &&
00135        testEt >  (m_inputRegions.at(centreIndex + 1).et() | (m_inputRegions.at(centreIndex + 1).getOverFlow() << L1GctRegion::ET_BITWIDTH)) &&
00136            
00137        testEt >= (m_inputRegions.at(centreIndex-1+COL_OFFSET).et() | (m_inputRegions.at(centreIndex-1+COL_OFFSET).getOverFlow() << L1GctRegion::ET_BITWIDTH)) &&
00138        testEt >= (m_inputRegions.at(centreIndex + COL_OFFSET).et() | (m_inputRegions.at(centreIndex + COL_OFFSET).getOverFlow() << L1GctRegion::ET_BITWIDTH)) &&
00139        testEt >= (m_inputRegions.at(centreIndex+1+COL_OFFSET).et() | (m_inputRegions.at(centreIndex+1+COL_OFFSET).getOverFlow() << L1GctRegion::ET_BITWIDTH)))
00140     {
00141       return true;
00142     }
00143 */  //END OVERFLOW FUNCTIONALITY       
00144   }
00145   else    //...so only test surround 5 regions in our jet testing.
00146   {    
00147     // Get the energy of the central region
00148     // Don't need all the overflow bit adjustments as above, since we are in the HF here
00149     ULong testEt = m_inputRegions.at(centreIndex).et();        
00150         
00151     if(testEt >  m_inputRegions.at(centreIndex-1-COL_OFFSET).et() &&
00152        testEt >  m_inputRegions.at(centreIndex - COL_OFFSET).et() &&
00153        
00154        testEt >= m_inputRegions.at(centreIndex - 1).et() &&
00155            
00156        testEt >= m_inputRegions.at(centreIndex-1+COL_OFFSET).et() &&
00157        testEt >= m_inputRegions.at(centreIndex + COL_OFFSET).et())
00158     {
00159       return true;
00160     }
00161   }
00162   return false;           
00163 }
00164 
00165 //returns the energy sum of the nine regions centred (physically) about centreIndex
00166 L1GctJetFinderBase::ULong L1GctTdrJetFinder::calcJetEnergy(const UShort centreIndex, const bool boundary) const
00167 {
00168   ULong energy = 0;
00169     
00170   if(!boundary)
00171   {
00172     for(int column = -1; column <= +1; ++column)
00173     {
00174       energy += m_inputRegions.at(centreIndex-1 + (column*COL_OFFSET)).et() +
00175                 m_inputRegions.at( centreIndex  + (column*COL_OFFSET)).et() +
00176                 m_inputRegions.at(centreIndex+1 + (column*COL_OFFSET)).et();
00177     }
00178   }
00179   else
00180   {
00181     for(int column = -1; column <= +1; ++column)
00182     {
00183       energy += m_inputRegions.at(centreIndex-1 + (column*COL_OFFSET)).et() +
00184                 m_inputRegions.at( centreIndex  + (column*COL_OFFSET)).et();
00185     }
00186   }
00187 
00188   return energy;                                   
00189 }
00190 
00191 // returns the encoded (eta, phi) position of the centre region
00192 L1CaloRegionDetId L1GctTdrJetFinder::calcJetPosition(const UShort centreIndex) const
00193 {
00194   return m_inputRegions.at(centreIndex).id();
00195 }
00196 
00197 // returns the combined tauveto of the nine regions centred (physically) about centreIndex. Set boundary = true if at edge of Endcap.
00198 bool L1GctTdrJetFinder::calcJetTauVeto(const UShort centreIndex, const bool boundary) const
00199 {
00200   bool partial[3] = {false, false, false};
00201     
00202   if(!boundary)
00203   {
00204     for(int column = -1; column <= +1; ++column)
00205     {
00206       partial[column+1] = m_inputRegions.at(centreIndex-1 + (column*COL_OFFSET)).tauVeto() ||
00207                           m_inputRegions.at( centreIndex  + (column*COL_OFFSET)).tauVeto() ||
00208                           m_inputRegions.at(centreIndex+1 + (column*COL_OFFSET)).tauVeto();
00209     }
00210   }
00211   else
00212   {
00213     for(int column = -1; column <= +1; ++column)
00214     {
00215       partial[column+1] = m_inputRegions.at(centreIndex-1 + (column*COL_OFFSET)).tauVeto() ||
00216                           m_inputRegions.at( centreIndex  + (column*COL_OFFSET)).tauVeto();
00217     }
00218   }
00219   return partial[0] || partial[1] || partial[2];
00220 }
00221