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Public Member Functions | Private Member Functions | Private Attributes | Static Private Attributes

CSCSectorReceiverLUT Class Reference

#include <CSCSectorReceiverLUT.h>

List of all members.

Public Member Functions

 CSCSectorReceiverLUT (int endcap, int sector, int subsector, int station, const edm::ParameterSet &pset, bool TMB07)
 CSCSectorReceiverLUT (const CSCSectorReceiverLUT &)
std::string encodeFileIndex () const
 Helpers.
gbletadat globalEtaME (gbletaadd address) const
gbletadat globalEtaME (int phi_bend, int phi_local, int wire_group, int cscid) const
gbletadat globalEtaME (unsigned address) const
gblphidat globalPhiMB (unsigned address) const
gblphidat globalPhiMB (int phi_local, int wire_group, int cscid) const
gblphidat globalPhiMB (gblphiadd address) const
gblphidat globalPhiME (int phi_local, int wire_group, int cscid) const
gblphidat globalPhiME (unsigned address) const
gblphidat globalPhiME (gblphiadd address) const
lclphidat localPhi (unsigned address) const
lclphidat localPhi (lclphiadd address) const
lclphidat localPhi (int strip, int pattern, int quality, int lr) const
 Geometry Lookup Tables.
CSCSectorReceiverLUToperator= (const CSCSectorReceiverLUT &)
 ~CSCSectorReceiverLUT ()

Private Member Functions

gbletadat calcGlobalEtaME (const gbletaadd &address) const
 Global Eta LUT.
gblphidat calcGlobalPhiMB (const gblphidat &me_gphi_data) const
gblphidat calcGlobalPhiME (const gblphiadd &address) const
 Global Phi LUT.
lclphidat calcLocalPhi (const lclphiadd &address) const
 Local Phi LUT.
void fillLocalPhiLUT ()
double getGlobalEtaValue (const unsigned &cscid, const unsigned &wire_group, const unsigned &phi_local) const
double getGlobalPhiValue (const CSCLayer *thelayer, const unsigned &strip, const unsigned &wire_group) const
void readLUTsFromFile ()

Private Attributes

int _endcap
int _sector
int _station
int _subsector
bool isBinary
bool isTMB07
bool LUTsFromFile
edm::FileInPath mb_gbl_phi_file
gblphidatmb_global_phi
edm::FileInPath me_gbl_eta_file
edm::FileInPath me_gbl_phi_file
gbletadatme_global_eta
gblphidatme_global_phi
edm::FileInPath me_lcl_phi_file
bool useMiniLUTs

Static Private Attributes

static lclphidatme_lcl_phi = NULL
static bool me_lcl_phi_loaded = false

Detailed Description

Author:
Lindsey Gray, Slava Valuev, Jason Mumford

Provides Look Up Table information for use in the SP Core. Partial port from ORCA.

Definition at line 18 of file CSCSectorReceiverLUT.h.


Constructor & Destructor Documentation

CSCSectorReceiverLUT::CSCSectorReceiverLUT ( int  endcap,
int  sector,
int  subsector,
int  station,
const edm::ParameterSet pset,
bool  TMB07 
)

Definition at line 26 of file CSCSectorReceiverLUT.cc.

References encodeFileIndex(), edm::ParameterSet::getUntrackedParameter(), isBinary, LUTsFromFile, mb_gbl_phi_file, mb_global_phi, me_gbl_eta_file, me_gbl_phi_file, me_global_eta, me_global_phi, me_lcl_phi_file, NULL, readLUTsFromFile(), and useMiniLUTs.

                                                                                    :_endcap(endcap),_sector(sector),
                                                                           _subsector(subsector),
                                                                           _station(station),isTMB07(TMB07)
{
  LUTsFromFile = pset.getUntrackedParameter<bool>("ReadLUTs",false);
  useMiniLUTs = pset.getUntrackedParameter<bool>("UseMiniLUTs", true);
  isBinary = pset.getUntrackedParameter<bool>("Binary",false);

  me_global_eta = NULL;
  me_global_phi = NULL;
  mb_global_phi = NULL;
  if(LUTsFromFile && !useMiniLUTs)
    {
      me_lcl_phi_file = pset.getUntrackedParameter<edm::FileInPath>("LocalPhiLUT", edm::FileInPath(std::string("L1Trigger/CSCTrackFinder/LUTs/LocalPhiLUT"
                                                                                                               + (isBinary ? std::string(".bin") : std::string(".dat")))));
      me_gbl_phi_file = pset.getUntrackedParameter<edm::FileInPath>("GlobalPhiLUTME", edm::FileInPath((std::string("L1Trigger/CSCTrackFinder/LUTs/GlobalPhiME")
                                                                                                       + encodeFileIndex()
                                                                                                       + (isBinary ? std::string(".bin") : std::string(".dat")))));
      if(station == 1)
        mb_gbl_phi_file = pset.getUntrackedParameter<edm::FileInPath>("GlobalPhiLUTMB", edm::FileInPath((std::string("L1Trigger/CSCTrackFinder/LUTs/GlobalPhiMB")
                                                                                                         + encodeFileIndex()
                                                                                                         + (isBinary ? std::string(".bin") : std::string(".dat")))));
      me_gbl_eta_file = pset.getUntrackedParameter<edm::FileInPath>("GlobalEtaLUTME", edm::FileInPath((std::string("L1Trigger/CSCTrackFinder/LUTs/GlobalEtaME")
                                                                                                       + encodeFileIndex()
                                                                                                       + (isBinary ? std::string(".bin") : std::string(".dat")))));
      readLUTsFromFile();
    }

}
CSCSectorReceiverLUT::CSCSectorReceiverLUT ( const CSCSectorReceiverLUT lut)
CSCSectorReceiverLUT::~CSCSectorReceiverLUT ( )

Member Function Documentation

gbletadat CSCSectorReceiverLUT::calcGlobalEtaME ( const gbletaadd address) const [private]

Global Eta LUT.

Definition at line 717 of file CSCSectorReceiverLUT.cc.

References _sector, _station, CSCTFConstants::etaBins, Exception, getGlobalEtaValue(), maxEta, CSCTFConstants::maxEta, CSCTriggerNumbering::maxTriggerCscId(), benchmark_cfg::minEta, CSCTFConstants::minEta, CSCTriggerNumbering::minTriggerCscId(), query::result, relativeConstraints::ring, and CSCTriggerNumbering::ringFromTriggerLabels().

Referenced by globalEtaME().

{
  gbletadat result;
  double float_eta = getGlobalEtaValue(address.cscid, address.wire_group, address.phi_local);
  unsigned int_eta = 0;
  unsigned bend_global = 0; // not filled yet... will change when it is.
  const double etaPerBin = (CSCTFConstants::maxEta - CSCTFConstants::minEta)/CSCTFConstants::etaBins;
  const unsigned me12EtaCut = 56;

  if ((float_eta < CSCTFConstants::minEta) || (float_eta >= CSCTFConstants::maxEta))
    {
      edm::LogWarning("CSCSectorReceiverLUT:OutOfBounds")
        << "CSCSectorReceiverLUT warning: float_eta = " << float_eta
        << " minEta = " << CSCTFConstants::minEta << " maxEta = " << CSCTFConstants::maxEta
        << "   station " << _station << " sector " << _sector
        << " chamber "   << address.cscid << " wire group " << address.wire_group;

      throw cms::Exception("CSCSectorReceiverLUT")
        << "+++ Value of CSC ID, " << float_eta
        << ", is out of bounds [" << CSCTFConstants::minEta << "-"
        << CSCTFConstants::maxEta << ") +++\n";

      //if (float_eta < CSCTFConstants::minEta)
      //result.global_eta = 0;
      //else if (float_eta >= CSCTFConstants::maxEta)
      //result.global_eta = CSCTFConstants::etaBins - 1;
    }
  else
    {
      float_eta -= CSCTFConstants::minEta;
      float_eta = float_eta/etaPerBin;
      int_eta = static_cast<unsigned>(float_eta);
      /* Commented until I find out its use.
      // Fine-tune eta boundary between DT and CSC.
      if ((intEta == L1MuCSCSetup::CscEtaStart() && (L1MuCSCSetup::CscEtaStartCorr() > 0.) ) ||
          (intEta == L1MuCSCSetup::CscEtaStart() - 1 && (L1MuCSCSetup::CscEtaStartCorr() < 0.) ) ) {
        bitEta = (thisEta-minEta-L1MuCSCSetup::CscEtaStartCorr())/EtaPerBin;
        intEta = static_cast<int>(bitEta);
      }
      */
      if (_station == 1 && address.cscid >= static_cast<unsigned>(CSCTriggerNumbering::minTriggerCscId())
          && address.cscid <= static_cast<unsigned>(CSCTriggerNumbering::maxTriggerCscId()) )
        {
          unsigned ring = CSCTriggerNumbering::ringFromTriggerLabels(_station, address.cscid);

          if      (ring == 1 && int_eta <  me12EtaCut) {int_eta = me12EtaCut;}
          else if (ring == 2 && int_eta >= me12EtaCut) {int_eta = me12EtaCut-1;}
        }
      result.global_eta = int_eta;
    }
  result.global_bend = bend_global;

  return result;
}
gblphidat CSCSectorReceiverLUT::calcGlobalPhiMB ( const gblphidat me_gphi_data) const [private]

Definition at line 539 of file CSCSectorReceiverLUT.cc.

References _subsector.

Referenced by globalPhiMB().

{
  gblphidat dtlut;

  // The following method was ripped from D. Holmes' LUT conversion program
  // modifications from Darin and GP
  int GlobalPhiMin = (_subsector == 1) ? 0x42 : 0x800;  // (0.999023 : 31 in degrees)
  int GlobalPhiMax = (_subsector == 1) ? 0x7ff : 0xfbd; // (30.985 : 60.986 in degrees)
  double GlobalPhiShift = (1.0*GlobalPhiMin + (GlobalPhiMax - GlobalPhiMin)/2.0);

  double dt_out = static_cast<double>(csclut.global_phi) - GlobalPhiShift;

  // these numbers are 62 deg / 1 rad (CSC phi scale vs. DT phi scale)
  dt_out = (dt_out/1982)*2145; //CSC phi 62 degrees; DT phi 57.3 degrees

  if(dt_out >= 0) // msb != 1
    {
      dtlut.global_phi = 0x7ff&static_cast<unsigned>(dt_out);
    }
  else
    {
      dtlut.global_phi = static_cast<unsigned>(-dt_out);
      dtlut.global_phi = ~dtlut.global_phi;
      dtlut.global_phi |= 0x800;
    }

  return dtlut;
}
gblphidat CSCSectorReceiverLUT::calcGlobalPhiME ( const gblphiadd address) const [private]

Global Phi LUT.

Definition at line 273 of file CSCSectorReceiverLUT.cc.

References _endcap, _sector, _station, _subsector, CSCTriggerGeomManager::chamber(), kinem::delta_phi(), Exception, CSCLayer::geometry(), reco::get(), getGlobalPhiValue(), isTMB07, CSCConstants::KEY_CLCT_LAYER, CSCConstants::KEY_CLCT_LAYER_PRE_TMB07, CSCBitWidths::kGlobalPhiDataBitWidth, CSCBitWidths::kLocalPhiDataBitWidth, CSCChamber::layer(), LogDebug, M_PI, CSCConstants::MAX_NUM_STRIPS, CSCTriggerNumbering::maxTriggerCscId(), CSCTriggerNumbering::minTriggerCscId(), NULL, CSCLayerGeometry::numberOfStrips(), query::result, CSCTFConstants::SECTOR1_CENT_RAD, CSCTFConstants::SECTOR_DEG, CSCTFConstants::SECTOR_RAD, strip(), and cms::Exception::what().

Referenced by globalPhiME().

{
  gblphidat result(0);
  CSCTriggerGeomManager* thegeom = CSCTriggerGeometry::get();
  CSCChamber* thechamber = NULL;
  CSCLayer* thelayer = NULL;
  CSCLayerGeometry* layergeom = NULL;
  int cscid = address.cscid;
  unsigned wire_group = address.wire_group;
  unsigned local_phi = address.phi_local;
  const double sectorOffset = (CSCTFConstants::SECTOR1_CENT_RAD-CSCTFConstants::SECTOR_RAD/2.) + (_sector-1)*M_PI/3.;

  //Number of global phi units per radian.
  static int maxPhiG = 1<<CSCBitWidths::kGlobalPhiDataBitWidth;
  double binPhiG = static_cast<double>(maxPhiG)/CSCTFConstants::SECTOR_RAD;

  // We will use these to convert the local phi into radians.
  static unsigned int maxPhiL = 1<<CSCBitWidths::kLocalPhiDataBitWidth;
  const double binPhiL = static_cast<double>(maxPhiL)/(2.*CSCConstants::MAX_NUM_STRIPS);

  if(cscid < CSCTriggerNumbering::minTriggerCscId())
    {
      edm::LogWarning("CSCSectorReceiverLUT|getGlobalPhiValue")
        << " warning: cscId " << cscid << " is out of bounds ["
        << CSCTriggerNumbering::maxTriggerCscId() << "-"
        << CSCTriggerNumbering::maxTriggerCscId() << "]\n";
      throw cms::Exception("CSCSectorReceiverLUT")
        << "+++ Value of CSC ID, " << cscid
        << ", is out of bounds [" << CSCTriggerNumbering::minTriggerCscId() << "-"
        << CSCTriggerNumbering::maxTriggerCscId() << "] +++\n";
    }

  if(cscid > CSCTriggerNumbering::maxTriggerCscId())
    {
      edm::LogWarning("CSCSectorReceiverLUT|getGlobalPhiValue")
        << " warning: cscId " << cscid << " is out of bounds ["
        << CSCTriggerNumbering::maxTriggerCscId() << "-"
        << CSCTriggerNumbering::maxTriggerCscId() << "]\n";
      throw cms::Exception("CSCSectorReceiverLUT")
        << "+++ Value of CSC ID, " << cscid
        << ", is out of bounds [" << CSCTriggerNumbering::minTriggerCscId() << "-"
        << CSCTriggerNumbering::maxTriggerCscId() << "] +++\n";
    }

  if(wire_group >= 1<<5)
    {
      edm::LogWarning("CSCSectorReceiverLUT|getGlobalPhiValue")
        << "warning: wire_group" << wire_group
        << " is out of bounds (1-" << ((1<<5)-1) << "]\n";
      throw cms::Exception("CSCSectorReceiverLUT")
        << "+++ Value of wire_group, " << wire_group
        << ", is out of bounds (1-" << ((1<<5)-1) << "] +++\n";
    }

  if(local_phi >= maxPhiL)
    {
      edm::LogWarning("CSCSectorReceiverLUT|getGlobalPhiValue")
        << "warning: local_phi" << local_phi
        << " is out of bounds [0-" << maxPhiL << ")\n";
      throw cms::Exception("CSCSectorReceiverLUT")
        << "+++ Value of local_phi, " << local_phi
        << ", is out of bounds [0-, " << maxPhiL << ") +++\n";
    }

  try
    {
      thechamber = thegeom->chamber(_endcap,_station,_sector,_subsector,cscid);
      if(thechamber)
        {
          if(isTMB07)
            {
              layergeom = const_cast<CSCLayerGeometry*>(thechamber->layer(CSCConstants::KEY_CLCT_LAYER)->geometry());
              thelayer = const_cast<CSCLayer*>(thechamber->layer(CSCConstants::KEY_CLCT_LAYER));
            }
          else
            {
              layergeom = const_cast<CSCLayerGeometry*>(thechamber->layer(CSCConstants::KEY_CLCT_LAYER_PRE_TMB07)->geometry());
              thelayer = const_cast<CSCLayer*>(thechamber->layer(CSCConstants::KEY_CLCT_LAYER_PRE_TMB07));
            }
          const int nStrips = layergeom->numberOfStrips();
          // PhiL is the strip number converted into some units between 0 and
          // 1023.  When we did the conversion in fillLocalPhiTable(), we did
          // not know for which chamber we do it (and, therefore, how many strips
          // it has), and always used the maximum possible number of strips
          // per chamber, MAX_NUM_STRIPS=80.  Now, since we know the chamber id
          // and how many strips the chamber has, we can re-adjust the scale.
          //const double scale = static_cast<double>(CSCConstants::MAX_NUM_STRIPS)/nStrips;

          int strip = 0, halfstrip = 0;

          halfstrip = static_cast<int>(local_phi/binPhiL);
          strip     = halfstrip/2;

          // Find the phi width of the chamber and the position of its "left"
          // (lower phi) edge (both in radians).
          // Phi positions of the centers of the first and of the last strips
          // in the chamber.
          const double phi_f = getGlobalPhiValue(thelayer, 1, wire_group);
          const double phi_l = getGlobalPhiValue(thelayer, nStrips, wire_group);
          // Phi widths of the half-strips at both ends of the chamber;
          // surprisingly, they are not the same.
          const double hsWidth_f = fabs(getGlobalPhiValue(thelayer, 2, wire_group) - phi_f)/2.;
          const double hsWidth_l = fabs(phi_l - getGlobalPhiValue(thelayer, nStrips - 1, wire_group))/2.;

          // The "natural" match between the strips and phi values -- when
          // a larger strip number corresponds to a larger phi value, i.e. strips
          // are counted clockwise if we look at them from the inside of the
          // detector -- is reversed for some stations.  At the moment, these
          // are stations 3 and 4 of the 1st endcap, and stations 1 and 2 of
          // the 2nd endcap.  Instead of using
          // if ((theEndcap == 1 && theStation <= 2) ||
          // (theEndcap == 2 && theStation >= 3)),
          // we get the order from the phi values of the first and the last strip
          // in a chamber, just in case the counting scheme changes in the future.
          // Once we know how the strips are counted, we can go from the middle
          // of the strips to their outer edges.
          bool   clockwiseOrder;
          double leftEdge, rightEdge;
          if (fabs(phi_f - phi_l) < M_PI)
            {
              if (phi_f < phi_l) clockwiseOrder = true;
              else clockwiseOrder = false;
            }
          else
            { // the chamber crosses the phi = pi boundary
              if (phi_f < phi_l) clockwiseOrder = false;
              else clockwiseOrder = true;
            }
          if (clockwiseOrder)
            {
              leftEdge  = phi_f - hsWidth_f;
              rightEdge = phi_l + hsWidth_l;
            }
          else
            {
              leftEdge  = phi_l - hsWidth_l;
              rightEdge = phi_f + hsWidth_f;
            }
          if (fabs(phi_f - phi_l) >= M_PI) {rightEdge += 2.*M_PI;}
          //double chamberWidth = (rightEdge - leftEdge);

          // Chamber offset, relative to the edge of the sector.
          //double chamberOffset = leftEdge - sectorOffset;
          //if (chamberOffset < -M_PI) chamberOffset += 2*M_PI;

          double temp_phi = 0.0, strip_phi = 0.0, delta_phi = 0.0;
          double distFromHalfStripCenter = 0.0, halfstripWidth = 0.0;

          if (strip < nStrips)
            {
              // Approximate distance from the center of the half-strip to the center
              // of this phil bin, in units of half-strip width.
              distFromHalfStripCenter = (local_phi+0.5)/binPhiL - halfstrip - 0.5;
              // Half-strip width (in rad), calculated as the half-distance between
              // the adjacent strips.  Since in the current ORCA implementation
              // the half-strip width changes from strip to strip, base the choice
              // of the adjacent strip on the half-strip number.
              if ((halfstrip%2 == 0 && halfstrip != 0) || halfstrip == 2*nStrips-1) {
                halfstripWidth =
                  fabs(getGlobalPhiValue(thelayer, strip+1, wire_group) - getGlobalPhiValue(thelayer, strip, wire_group)) / 2.;
              }
              else
                {
                  halfstripWidth =
                    fabs(getGlobalPhiValue(thelayer, strip+1, wire_group) - getGlobalPhiValue(thelayer, strip+2, wire_group)) / 2.;
                }
              // Correction for the strips crossing the 180 degree boundary.
              if (halfstripWidth > M_PI/2.) halfstripWidth = M_PI - halfstripWidth;
              // Phi at the center of the strip.
              strip_phi = getGlobalPhiValue(thelayer, strip+1, wire_group);
              // Distance between the center of the strip and the phil position.
              delta_phi = halfstripWidth*(((halfstrip%2)-0.5)+distFromHalfStripCenter);
              if (clockwiseOrder)
                temp_phi = strip_phi+ delta_phi;
              else
                temp_phi = strip_phi- delta_phi;
            }
          else
            {
              // PhiL values that do not have corresponding strips (the chamber
              // has less than 80 strips assumed in fillLocalPhi).  It does not
              // really matter what we do with these values; at the moment, just
              // set them to the phis of the edges of the chamber.
              if (clockwiseOrder) temp_phi = rightEdge;
              else temp_phi = leftEdge;
            }

          // Finally, subtract the sector offset and convert to the scale of
          // the global phi.

          temp_phi -= sectorOffset;

          if (temp_phi < 0.) temp_phi += 2.*M_PI;

          temp_phi *= binPhiG;

          if (temp_phi < 0.)
            {
              result.global_phi = 0;
            }
          else if (temp_phi >= maxPhiG)
            {
              result.global_phi = maxPhiG - 1;
            }
          else
            {
             result.global_phi = static_cast<unsigned short>(temp_phi);
            }

          LogDebug("CSCSectorReceiverLUT")
            << "local_phi = " << local_phi
            << " halfstrip = " << halfstrip << " strip = " << strip
            << " distFromHalfStripCenter = " << distFromHalfStripCenter
            << " halfstripWidth = " << halfstripWidth
            << " strip phi = " << strip_phi/(M_PI/180.)
            << " temp_phi = " << temp_phi*CSCTFConstants::SECTOR_DEG/maxPhiG
            << " global_phi = "    << result.global_phi
            << " " << result.global_phi*CSCTFConstants::SECTOR_DEG/maxPhiG;

        }
    }
  catch(edm::Exception& e)
    {
      edm::LogError("CSCSectorReceiverLUT|getGlobalPhiValue") << e.what();
    }

  return result;
}
lclphidat CSCSectorReceiverLUT::calcLocalPhi ( const lclphiadd address) const [private]

Local Phi LUT.

Local Phi Bend is always zero. Until we start using it.

Definition at line 152 of file CSCSectorReceiverLUT.cc.

References _endcap, _station, AlCaHLTBitMon_QueryRunRegistry::data, Exception, CSCPatternLUT::get2007Position(), CSCPatternLUT::getPosition(), isTMB07, CSCBitWidths::kLocalPhiDataBitWidth, LogDebug, and CSCConstants::MAX_NUM_STRIPS.

Referenced by localPhi().

{
  lclphidat data;

  static int maxPhiL = 1<<CSCBitWidths::kLocalPhiDataBitWidth;
  double binPhiL = static_cast<double>(maxPhiL)/(2.*CSCConstants::MAX_NUM_STRIPS);

  memset(&data,0,sizeof(lclphidat));

  double patternOffset;

  if(isTMB07) patternOffset = CSCPatternLUT::get2007Position((theadd.pattern_type<<3) + theadd.clct_pattern);
  else patternOffset = CSCPatternLUT::getPosition(theadd.clct_pattern);

  // The phiL value stored is for the center of the half-/di-strip.
  if(theadd.strip < 2*CSCConstants::MAX_NUM_STRIPS)
    if(theadd.pattern_type == 1 || isTMB07) // if halfstrip (Note: no distrips in TMB 2007 patterns)
      data.phi_local = static_cast<unsigned>((0.5 + theadd.strip + patternOffset)*binPhiL);
    else // if distrip
      data.phi_local = static_cast<unsigned>((2 + theadd.strip + 4.*patternOffset)*binPhiL);
  else {
    throw cms::Exception("CSCSectorReceiverLUT")
      << "+++ Value of strip, " << theadd.strip
      << ", exceeds max allowed, " << 2*CSCConstants::MAX_NUM_STRIPS-1
      << " +++\n";
  }

  if (data.phi_local >= maxPhiL) {
    throw cms::Exception("CSCSectorReceiverLUT")
      << "+++ Value of phi_local, " << data.phi_local
      << ", exceeds max allowed, " << maxPhiL-1 << " +++\n";
  }

  LogDebug("CSCSectorReceiver")
    << "endcap = " << _endcap << " station = " << _station
    << " maxPhiL = " << maxPhiL << " binPhiL = " << binPhiL;
  LogDebug("CSCSectorReceiver")
    << "strip # " << theadd.strip << " hs/ds = " << theadd.pattern_type
    << " pattern = " << theadd.clct_pattern << " offset = " << patternOffset
    << " phi_local = " << data.phi_local;

  data.phi_bend_local = 0;

  return data; //return LUT result
}
std::string CSCSectorReceiverLUT::encodeFileIndex ( ) const

Helpers.

Definition at line 810 of file CSCSectorReceiverLUT.cc.

References _endcap, _sector, _station, _subsector, and convertXMLtoSQLite_cfg::fileName.

Referenced by CSCSectorReceiverLUT().

                                                      {
  std::string fileName = "";
  if (_station == 1) {
    if (_subsector == 1) fileName += "1a";
    if (_subsector == 2) fileName += "1b";
  }
  else if (_station == 2) fileName += "2";
  else if (_station == 3) fileName += "3";
  else if (_station == 4) fileName += "4";
  fileName += "End";
  if (_endcap == 1) fileName += "1";
  else                fileName += "2";
  fileName += "Sec";
  if      (_sector == 1) fileName += "1";
  else if (_sector == 2) fileName += "2";
  else if (_sector == 3) fileName += "3";
  else if (_sector == 4) fileName += "4";
  else if (_sector == 5) fileName += "5";
  else if (_sector == 6) fileName += "6";
  fileName += "LUT";
  return fileName;
}
void CSCSectorReceiverLUT::fillLocalPhiLUT ( ) [private]

Definition at line 200 of file CSCSectorReceiverLUT.cc.

{
  // read data in from a file... Add this later.
}
double CSCSectorReceiverLUT::getGlobalEtaValue ( const unsigned &  cscid,
const unsigned &  wire_group,
const unsigned &  phi_local 
) const [private]

Calculate Eta correction

Definition at line 611 of file CSCSectorReceiverLUT.cc.

References _endcap, _sector, _station, _subsector, CSCLayer::centerOfWireGroup(), CSCTriggerGeomManager::chamber(), PV3DBase< T, PVType, FrameType >::eta(), CSCLayer::geometry(), reco::get(), CSCConstants::KEY_ALCT_LAYER, CSCChamber::layer(), LogDebug, CSCConstants::MAX_NUM_STRIPS, CSCTriggerNumbering::maxTriggerCscId(), CSCTriggerNumbering::minTriggerCscId(), NULL, CSCLayerGeometry::numberOfStrips(), CSCLayerGeometry::numberOfWireGroups(), query::result, CSCTriggerNumbering::ringFromTriggerLabels(), CSCLayerGeometry::stripWireGroupIntersection(), GeomDet::surface(), Surface::toGlobal(), and cms::Exception::what().

Referenced by calcGlobalEtaME().

{
  double result = 0.0;
  unsigned wire_group = thewire_group;
  int cscid = thecscid;
  unsigned phi_local = thephi_local;

  // Flag to be set if one wants to apply phi corrections ONLY in ME1/1.
  // Turn it into a parameter?
  bool me1ir_only = false;

  if(cscid < CSCTriggerNumbering::minTriggerCscId() ||
     cscid > CSCTriggerNumbering::maxTriggerCscId()) {
       edm::LogWarning("CSCSectorReceiverLUT|getEtaValue")
         << " warning: cscId " << cscid
         << " is out of bounds [1-" << CSCTriggerNumbering::maxTriggerCscId()
         << "]\n";
      cscid = CSCTriggerNumbering::maxTriggerCscId();
    }

  CSCTriggerGeomManager* thegeom = CSCTriggerGeometry::get();
  CSCLayerGeometry* layerGeom = NULL;
  const unsigned numBins = 1 << 2; // 4 local phi bins

  if(phi_local > numBins - 1) {
      edm::LogWarning("CSCSectorReceiverLUT|getEtaValue")
        << "warning: phiL " << phi_local
        << " is out of bounds [0-" << numBins - 1 << "]\n";
      phi_local = numBins - 1;
  }
  try
    {
      const CSCChamber* thechamber = thegeom->chamber(_endcap,_station,_sector,_subsector,cscid);
      if(thechamber) {
        layerGeom = const_cast<CSCLayerGeometry*>(thechamber->layer(CSCConstants::KEY_ALCT_LAYER)->geometry());
        const unsigned nWireGroups = layerGeom->numberOfWireGroups();

        // Check wire group numbers; expect them to be counted from 0, as in
        // CorrelatedLCTDigi class.
        if (wire_group >= nWireGroups) {
           edm::LogWarning("CSCSectorReceiverLUT|getEtaValue")
             << "warning: wireGroup " << wire_group
            << " is out of bounds [0-" << nWireGroups << ")\n";
          wire_group = nWireGroups - 1;
        }
        // Convert to [1; nWireGroups] range used in geometry methods.
        wire_group += 1;

        // If me1ir_only is set, apply phi corrections only in ME1/1.
        if (me1ir_only &&
            (_station != 1 ||
             CSCTriggerNumbering::ringFromTriggerLabels(_station, cscid) != 1))
          {
            result = thechamber->layer(CSCConstants::KEY_ALCT_LAYER)->centerOfWireGroup(wire_group).eta();
          }
        else {
          const unsigned nStrips = layerGeom->numberOfStrips();
          const unsigned nStripsPerBin = CSCConstants::MAX_NUM_STRIPS/numBins;
          // Check that no strips will be left out.
          if (nStrips%numBins != 0 || CSCConstants::MAX_NUM_STRIPS%numBins != 0)
            edm::LogWarning("CSCSectorReceiverLUT")
              << "getGlobalEtaValue warning: number of strips "
              << nStrips << " (" << CSCConstants::MAX_NUM_STRIPS
              << ") is not divisible by numBins " << numBins
              << " Station " << _station << " sector " << _sector
              << " subsector " << _subsector << " cscid " << cscid << "\n";

          unsigned    maxStripPrevBin = 0, maxStripThisBin = 0;
          unsigned    correctionStrip;
          LocalPoint  lPoint;
          GlobalPoint gPoint;
          // Bins phi_local and find the the middle strip for each bin.
          maxStripThisBin = nStripsPerBin * (phi_local+1);
          if (maxStripThisBin <= nStrips) {
            correctionStrip = nStripsPerBin/2 * (2*phi_local+1);
          }
          else {
            // If the actual number of strips in the chamber is smaller than
            // the number of strips corresponding to the right edge of this phi
            // local bin, we take the middle strip between number of strips
            // at the left edge of the bin and the actual number of strips.
            maxStripPrevBin = nStripsPerBin * phi_local;
            correctionStrip = (nStrips+maxStripPrevBin)/2;
          }

          lPoint = layerGeom->stripWireGroupIntersection(correctionStrip, wire_group);
          gPoint = thechamber->layer(CSCConstants::KEY_ALCT_LAYER)->surface().toGlobal(lPoint);

          // end calc of eta correction.
          result = gPoint.eta();
        }
      }
    }
  catch (cms::Exception &e)
    {
      LogDebug("CSCSectorReceiver|OutofBoundInput") << e.what();
    }

  return std::fabs(result);
}
double CSCSectorReceiverLUT::getGlobalPhiValue ( const CSCLayer thelayer,
const unsigned &  strip,
const unsigned &  wire_group 
) const [private]

Definition at line 249 of file CSCSectorReceiverLUT.cc.

References CSCLayer::centerOfStrip(), LogDebug, M_PI, PV3DBase< T, PVType, FrameType >::phi(), query::result, and cms::Exception::what().

Referenced by calcGlobalPhiME().

{
  double result = 0.0;
  //CSCLayerGeometry* thegeom;
  //LocalPoint lp;
  //GlobalPoint gp;

  try
    {
      //thegeom = const_cast<CSCLayerGeometry*>(thelayer->geometry());
      //lp = thegeom->stripWireGroupIntersection(strip, wire_group);
      //gp = thelayer->surface().toGlobal(lp);
      result = thelayer->centerOfStrip(strip).phi();//gp.phi();

      if (result < 0.) result += 2.*M_PI;
    }
  catch(edm::Exception& e)
    {
      LogDebug("CSCSectorReceiverLUT|getGlobalPhiValue") << e.what();
    }

  return result;
}
gbletadat CSCSectorReceiverLUT::globalEtaME ( unsigned  address) const
gbletadat CSCSectorReceiverLUT::globalEtaME ( gbletaadd  address) const
gbletadat CSCSectorReceiverLUT::globalEtaME ( int  phi_bend,
int  phi_local,
int  wire_group,
int  cscid 
) const

Definition at line 772 of file CSCSectorReceiverLUT.cc.

References _endcap, _sector, _station, _subsector, calcGlobalEtaME(), CSCSectorReceiverMiniLUT::calcGlobalEtaMEMini(), isTMB07, CSCBitWidths::kLocalPhiDataBitWidth, LUTsFromFile, me_global_eta, query::result, and useMiniLUTs.

Referenced by L1TdeCSCTF::analyze(), and L1TCSCTF::analyze().

{
  gbletadat result;
  gbletaadd theadd;

  theadd.phi_bend = tphi_bend;
  theadd.phi_local = (tphi_local>>(CSCBitWidths::kLocalPhiDataBitWidth - 2)) & 0x3; // want 2 msb of local phi
  theadd.wire_group = twire_group;
  theadd.cscid = tcscid;

  if(useMiniLUTs && isTMB07) result = CSCSectorReceiverMiniLUT::calcGlobalEtaMEMini(_endcap, _sector, _station, _subsector, theadd.toint());
  else if(LUTsFromFile) result = me_global_eta[theadd.toint()];
  else result = calcGlobalEtaME(theadd);

  return result;
}
gblphidat CSCSectorReceiverLUT::globalPhiMB ( int  phi_local,
int  wire_group,
int  cscid 
) const

Definition at line 568 of file CSCSectorReceiverLUT.cc.

References calcGlobalPhiMB(), globalPhiME(), LUTsFromFile, mb_global_phi, and query::result.

{
  gblphiadd address;
  gblphidat result;

  address.cscid = cscid;
  address.wire_group = ((1<<5)-1)&(wire_group>>2);
  address.phi_local = phi_local;

  // comment for now
  //  if(useMiniLUTs && isTMB07) result = CSCSectorReceiverMiniLUT::calcGlobalPhiMBMini(_endcap, _sector, _subsector, address.toint());
  //else 
  if(LUTsFromFile) result = mb_global_phi[address.toint()];
  else result = calcGlobalPhiMB(globalPhiME(address));

  return result;
}
gblphidat CSCSectorReceiverLUT::globalPhiMB ( unsigned  address) const

Definition at line 586 of file CSCSectorReceiverLUT.cc.

References calcGlobalPhiMB(), globalPhiME(), LUTsFromFile, mb_global_phi, and query::result.

{
  gblphidat result;
  gblphiadd theadd(address);

  //if(useMiniLUTs && isTMB07) result = CSCSectorReceiverMiniLUT::calcGlobalPhiMBMini(_endcap, _sector, _subsector, address);
  //else 
  if(LUTsFromFile) result = mb_global_phi[theadd.toint()];
  else result = calcGlobalPhiMB(globalPhiME(address));

  return result;
}
gblphidat CSCSectorReceiverLUT::globalPhiMB ( gblphiadd  address) const

Definition at line 599 of file CSCSectorReceiverLUT.cc.

References calcGlobalPhiMB(), globalPhiME(), LUTsFromFile, mb_global_phi, and query::result.

{
  gblphidat result;

  //if(useMiniLUTs && isTMB07) result = CSCSectorReceiverMiniLUT::calcGlobalPhiMBMini(_endcap, _sector, _subsector, address.toint());
  //else 
  if(LUTsFromFile) result = mb_global_phi[address.toint()];
  else result = calcGlobalPhiMB(globalPhiME(address));

  return result;
}
gblphidat CSCSectorReceiverLUT::globalPhiME ( int  phi_local,
int  wire_group,
int  cscid 
) const

Definition at line 502 of file CSCSectorReceiverLUT.cc.

References _endcap, _sector, _station, _subsector, calcGlobalPhiME(), CSCSectorReceiverMiniLUT::calcGlobalPhiMEMini(), isTMB07, LUTsFromFile, me_global_phi, query::result, and useMiniLUTs.

Referenced by L1TdeCSCTF::analyze(), L1TCSCTF::analyze(), and globalPhiMB().

{
  gblphidat result;
  gblphiadd theadd;
  theadd.phi_local = phi_local;
  theadd.wire_group = ((1<<5)-1)&(wire_group >> 2); // want 2-7 of wg
  theadd.cscid = cscid;

  if(useMiniLUTs && isTMB07) result = CSCSectorReceiverMiniLUT::calcGlobalPhiMEMini(_endcap, _sector, _station, _subsector, theadd.toint());
  else if(LUTsFromFile) result = me_global_phi[theadd.toint()];
  else result = calcGlobalPhiME(theadd);

  return result;
}
gblphidat CSCSectorReceiverLUT::globalPhiME ( unsigned  address) const
gblphidat CSCSectorReceiverLUT::globalPhiME ( gblphiadd  address) const
lclphidat CSCSectorReceiverLUT::localPhi ( lclphiadd  address) const
lclphidat CSCSectorReceiverLUT::localPhi ( int  strip,
int  pattern,
int  quality,
int  lr 
) const

Geometry Lookup Tables.

Please note, the pattern used below is the 4 bit pattern. ex) digi->getPattern(), NOT digi->getCLCTPattern()

Definition at line 205 of file CSCSectorReceiverLUT.cc.

References strip().

Referenced by L1TdeCSCTF::analyze(), and L1TCSCTF::analyze().

{
  lclphiadd theadd;

  theadd.strip = strip;
  theadd.clct_pattern = pattern & 0x7;
  theadd.pattern_type = (pattern & 0x8) >> 3;
  theadd.quality = quality;
  theadd.lr = lr;
  theadd.spare = 0;

  return localPhi(theadd);
}
lclphidat CSCSectorReceiverLUT::localPhi ( unsigned  address) const
CSCSectorReceiverLUT & CSCSectorReceiverLUT::operator= ( const CSCSectorReceiverLUT lut)
void CSCSectorReceiverLUT::readLUTsFromFile ( ) [private]

Arrays for holding read in LUT information. MB LUT arrays only initialized in ME1

Definition at line 833 of file CSCSectorReceiverLUT.cc.

References _station, end, edm::FileInPath::fullPath(), i, isBinary, CSCBitWidths::kGlobalEtaAddressWidth, CSCBitWidths::kGlobalPhiAddressWidth, CSCBitWidths::kLocalPhiAddressWidth, mb_gbl_phi_file, mb_global_phi, me_gbl_eta_file, me_gbl_phi_file, me_global_eta, me_global_phi, me_lcl_phi, me_lcl_phi_file, me_lcl_phi_loaded, and cond::rpcobtemp::temp.

Referenced by CSCSectorReceiverLUT().

{
  if(!me_lcl_phi_loaded)
    {
      me_lcl_phi = new lclphidat[1<<CSCBitWidths::kLocalPhiAddressWidth];
      memset(me_lcl_phi, 0, (1<<CSCBitWidths::kLocalPhiAddressWidth)*sizeof(short));
      std::string fName(me_lcl_phi_file.fullPath());
      std::ifstream LocalPhiLUT;

      edm::LogInfo("CSCSectorReceiverLUT") << "Loading SR LUT: " << fName;

      if(isBinary)
        {
          LocalPhiLUT.open(fName.c_str(),std::ios::binary);
          LocalPhiLUT.seekg(0,std::ios::end);
          int length = LocalPhiLUT.tellg();
          if(length == (1<<CSCBitWidths::kLocalPhiAddressWidth)*sizeof(short))
            {
              LocalPhiLUT.seekg(0,std::ios::beg);
              LocalPhiLUT.read(reinterpret_cast<char*>(me_lcl_phi),length);
              LocalPhiLUT.close();
            }
          else
            edm::LogError("CSCSectorReceiverLUT") << "File "<< fName << " is incorrect size!";
          LocalPhiLUT.close();
        }
      else
        {
          LocalPhiLUT.open(fName.c_str());
          unsigned i = 0;
          unsigned short temp = 0;
          while(!LocalPhiLUT.eof() && i < 1<<CSCBitWidths::kLocalPhiAddressWidth)
            {
              LocalPhiLUT >> temp;
              me_lcl_phi[i++] = (*reinterpret_cast<lclphidat*>(&temp));
            }
          LocalPhiLUT.close();
        }
    }
  if(!me_global_phi)
    {
      me_global_phi = new gblphidat[1<<CSCBitWidths::kGlobalPhiAddressWidth];
      memset(me_global_phi, 0, (1<<CSCBitWidths::kGlobalPhiAddressWidth)*sizeof(short));
      std::string fName = me_gbl_phi_file.fullPath();
      std::ifstream GlobalPhiLUT;

      edm::LogInfo("CSCSectorReceiverLUT") << "Loading SR LUT: " << fName;

      if(isBinary)
        {
          GlobalPhiLUT.open(fName.c_str(),std::ios::binary);
          GlobalPhiLUT.seekg(0,std::ios::end);
          int length = GlobalPhiLUT.tellg();
          if(length == (1<<CSCBitWidths::kGlobalPhiAddressWidth)*sizeof(short))
            {
              GlobalPhiLUT.seekg(0,std::ios::beg);
              GlobalPhiLUT.read(reinterpret_cast<char*>(me_global_phi),length);
            }
          else
            edm::LogError("CSCSectorReceiverLUT") << "File "<< fName << " is incorrect size!";
          GlobalPhiLUT.close();
        }
      else
        {
          GlobalPhiLUT.open( fName.c_str());
          unsigned short temp = 0;
          unsigned i = 0;
          while(!GlobalPhiLUT.eof() && i < 1<<CSCBitWidths::kGlobalPhiAddressWidth)
            {
              GlobalPhiLUT >> temp;
              me_global_phi[i++] = (*reinterpret_cast<gblphidat*>(&temp));
            }
          GlobalPhiLUT.close();
        }
    }
  if(!mb_global_phi && _station == 1) // MB lut only in station one.
    {
      mb_global_phi = new gblphidat[1<<CSCBitWidths::kGlobalPhiAddressWidth];
      memset(mb_global_phi, 0, (1<<CSCBitWidths::kGlobalPhiAddressWidth)*sizeof(short));
      std::string fName = mb_gbl_phi_file.fullPath();
      std::ifstream GlobalPhiLUT;

      edm::LogInfo("CSCSectorReceiverLUT") << "Loading SR LUT: " << fName;

      if(isBinary)
        {
          GlobalPhiLUT.open( fName.c_str(),std::ios::binary);
          GlobalPhiLUT.seekg(0,std::ios::end);
          int length = GlobalPhiLUT.tellg();
          if(length == (1<<CSCBitWidths::kGlobalPhiAddressWidth)*sizeof(short))
            {
              GlobalPhiLUT.seekg(0,std::ios::beg);
              GlobalPhiLUT.read(reinterpret_cast<char*>(mb_global_phi),length);
            }
          else
            edm::LogError("CSCSectorReceiverLUT") << "File "<< fName << " is incorrect size!";
          GlobalPhiLUT.close();
        }
      else
        {
          GlobalPhiLUT.open(fName.c_str());
          unsigned short temp = 0;
          unsigned i = 0;
          while(!GlobalPhiLUT.eof() && i < 1<<CSCBitWidths::kGlobalPhiAddressWidth)
            {
              GlobalPhiLUT >> temp;
              mb_global_phi[i++] = (*reinterpret_cast<gblphidat*>(&temp));
            }
          GlobalPhiLUT.close();
        }
    }
  if(!me_global_eta)
    {
      me_global_eta = new gbletadat[1<<CSCBitWidths::kGlobalEtaAddressWidth];
      memset(me_global_eta, 0, (1<<CSCBitWidths::kGlobalEtaAddressWidth)*sizeof(short));
      std::string fName = me_gbl_eta_file.fullPath();
      std::ifstream GlobalEtaLUT;

      edm::LogInfo("CSCSectorReceiverLUT") << "Loading SR LUT: " << fName;

      if(isBinary)
        {
          GlobalEtaLUT.open(fName.c_str(),std::ios::binary);
          GlobalEtaLUT.seekg(0,std::ios::end);
          int length = GlobalEtaLUT.tellg();
          if(length == (1<<CSCBitWidths::kGlobalEtaAddressWidth)*sizeof(short))
            {
              GlobalEtaLUT.seekg(0,std::ios::beg);
              GlobalEtaLUT.read(reinterpret_cast<char*>(me_global_eta),length);
            }
          else
            edm::LogError("CSCSectorReceiverLUT") << "File "<< fName << " is incorrect size!";
          GlobalEtaLUT.close();
        }
      else
        {
          GlobalEtaLUT.open(fName.c_str());
          unsigned short temp = 0;
          unsigned i = 0;
          while(!GlobalEtaLUT.eof() && i < 1<<CSCBitWidths::kGlobalEtaAddressWidth)
          {
            GlobalEtaLUT >> temp;
            me_global_eta[i++] = (*reinterpret_cast<gbletadat*>(&temp));
          }
          GlobalEtaLUT.close();
        }
    }
}

Member Data Documentation

Definition at line 74 of file CSCSectorReceiverLUT.h.

Referenced by CSCSectorReceiverLUT(), operator=(), and readLUTsFromFile().

Definition at line 70 of file CSCSectorReceiverLUT.h.

Referenced by CSCSectorReceiverLUT(), operator=(), and readLUTsFromFile().

Definition at line 71 of file CSCSectorReceiverLUT.h.

Referenced by CSCSectorReceiverLUT(), operator=(), and readLUTsFromFile().

Definition at line 69 of file CSCSectorReceiverLUT.h.

Referenced by CSCSectorReceiverLUT(), operator=(), and readLUTsFromFile().

lclphidat * CSCSectorReceiverLUT::me_lcl_phi = NULL [static, private]

Definition at line 83 of file CSCSectorReceiverLUT.h.

Referenced by localPhi(), readLUTsFromFile(), and ~CSCSectorReceiverLUT().

Definition at line 68 of file CSCSectorReceiverLUT.h.

Referenced by CSCSectorReceiverLUT(), operator=(), and readLUTsFromFile().

bool CSCSectorReceiverLUT::me_lcl_phi_loaded = false [static, private]

Definition at line 82 of file CSCSectorReceiverLUT.h.

Referenced by readLUTsFromFile(), and ~CSCSectorReceiverLUT().

Definition at line 73 of file CSCSectorReceiverLUT.h.

Referenced by CSCSectorReceiverLUT(), globalEtaME(), globalPhiME(), and localPhi().