MuonRPCDetLayerGeometryBuilder Class Reference

#include <MuonRPCDetLayerGeometryBuilder.h>

Public Member Functions
	MuonRPCDetLayerGeometryBuilder ()
	Constructor (disabled, only static access is allowed) More...
virtual	~MuonRPCDetLayerGeometryBuilder ()
	Destructor. More...

Static Public Member Functions
static std::vector< DetLayer * >	buildBarrelLayers (const RPCGeometry &geo)
	Builds the barrel layers. Result vector is sorted inside-out. More...
static std::pair< std::vector< DetLayer * >, std::vector< DetLayer * > >	buildEndcapLayers (const RPCGeometry &geo)

Static Private Member Functions
static MuRingForwardDoubleLayer *	buildLayer (int endcap, const std::vector< int > &rings, int station, int layer, std::vector< int > &rolls, const RPCGeometry &geo)
static bool	isFront (const RPCDetId &rpcId)
static void	makeBarrelLayers (std::vector< const GeomDet * > &geomDets, std::vector< MuRodBarrelLayer * > &result)
static void	makeBarrelRods (std::vector< const GeomDet * > &geomDets, std::vector< const DetRod * > &result)

Detailed Description

Build the RPC DetLayers.

Author

N. Amapane - CERN

Definition at line 19 of file MuonRPCDetLayerGeometryBuilder.h.

Constructor & Destructor Documentation

MuonRPCDetLayerGeometryBuilder()

MuonRPCDetLayerGeometryBuilder::MuonRPCDetLayerGeometryBuilder ( )

inline

Constructor (disabled, only static access is allowed)

Definition at line 22 of file MuonRPCDetLayerGeometryBuilder.h.

{}

~MuonRPCDetLayerGeometryBuilder()

MuonRPCDetLayerGeometryBuilder::~MuonRPCDetLayerGeometryBuilder ( )

virtual

Destructor.

Definition at line 29 of file MuonRPCDetLayerGeometryBuilder.cc.

{}

Member Function Documentation

buildBarrelLayers()

vector< DetLayer * > MuonRPCDetLayerGeometryBuilder::buildBarrelLayers ( const RPCGeometry &  geo )

static

Builds the barrel layers. Result vector is sorted inside-out.

Definition at line 150 of file MuonRPCDetLayerGeometryBuilder.cc.

                                                                                          {
  const std::string metname = "Muon|RPC|RecoMuon|RecoMuonDetLayers|MuonRPCDetLayerGeometryBuilder";
 
  vector<DetLayer*> detlayers;
  vector<MuRodBarrelLayer*> result;
  int region = 0;
 
  for (int station = RPCDetId::minStationId; station <= RPCDetId::maxStationId; station++) {
    vector<const GeomDet*> geomDets;
 
    for (int layer = RPCDetId::minLayerId; layer <= RPCDetId::maxLayerId; ++layer) {
      for (int sector = RPCDetId::minSectorId; sector <= RPCDetId::maxSectorId; sector++) {
        for (int subsector = RPCDetId::minSubSectorId; subsector <= RPCDetId::maxSubSectorId; subsector++) {
          for (int wheel = RPCDetId::minRingBarrelId; wheel <= RPCDetId::maxRingBarrelId; wheel++) {
            for (int roll = RPCDetId::minRollId + 1; roll <= RPCDetId::maxRollId; roll++) {
              const GeomDet* geomDet = geo.idToDet(RPCDetId(region, wheel, station, sector, layer, subsector, roll));
              if (geomDet) {
                geomDets.push_back(geomDet);
                LogTrace(metname) << "get RPC Barrel roll "
                                  << RPCDetId(region, wheel, station, sector, layer, subsector, roll)
                                  << " at R=" << geomDet->position().perp() << ", phi=" << geomDet->position().phi();
              }
            }
          }
        }
      }
    }
    makeBarrelLayers(geomDets, result);
  }
 
  for (vector<MuRodBarrelLayer*>::const_iterator it = result.begin(); it != result.end(); it++)
    detlayers.push_back((DetLayer*)(*it));
 
  return detlayers;
}

References RPCGeometry::idToDet(), LogTrace, RPCDetId::maxLayerId, RPCDetId::maxRingBarrelId, RPCDetId::maxRollId, RPCDetId::maxSectorId, RPCDetId::maxStationId, RPCDetId::maxSubSectorId, metname, RPCDetId::minLayerId, RPCDetId::minRingBarrelId, RPCDetId::minRollId, RPCDetId::minSectorId, RPCDetId::minStationId, RPCDetId::minSubSectorId, PV3DBase< T, PVType, FrameType >::perp(), PV3DBase< T, PVType, FrameType >::phi(), GeomDet::position(), HLT_FULL_cff::region, mps_fire::result, relativeConstraints::station, AlCaHLTBitMon_QueryRunRegistry::string, and makeMuonMisalignmentScenario::wheel.

Referenced by MuonDetLayerGeometryESProducer::produce().

buildEndcapLayers()

pair< vector< DetLayer * >, vector< DetLayer * > > MuonRPCDetLayerGeometryBuilder::buildEndcapLayers ( const RPCGeometry &  geo )

static

Builds the forward (+Z, return.first) and backward (-Z, return.second) layers. Both vectors are sorted inside-out

Definition at line 32 of file MuonRPCDetLayerGeometryBuilder.cc.

                                                                                                                    {
  vector<DetLayer*> result[2];
 
  for (int endcap = -1; endcap <= 1; endcap += 2) {
    int iendcap = (endcap == 1) ? 0 : 1;  // +1: forward, -1: backward
 
    // ME 1
    int firstStation = 1;
 
    // ME 1/1
    for (int layer = RPCDetId::minLayerId; layer <= RPCDetId::maxLayerId; ++layer) {
      vector<int> rolls;
      std::vector<int> rings;
      int FirstStationRing = 1;
      rings.push_back(FirstStationRing);
      for (int roll = RPCDetId::minRollId + 1; roll <= RPCDetId::maxRollId; ++roll) {
        rolls.push_back(roll);
      }
 
      MuRingForwardDoubleLayer* ringLayer = buildLayer(endcap, rings, firstStation, layer, rolls, geo);
      if (ringLayer)
        result[iendcap].push_back(ringLayer);
    }
 
    // ME 1/2 and ME1/3
    for (int layer = RPCDetId::minLayerId; layer <= RPCDetId::maxLayerId; ++layer) {
      vector<int> rolls;
      std::vector<int> rings;
      for (int ring = 2; ring <= 3; ++ring) {
        rings.push_back(ring);
      }
      for (int roll = RPCDetId::minRollId + 1; roll <= RPCDetId::maxRollId; ++roll) {
        rolls.push_back(roll);
      }
 
      MuRingForwardDoubleLayer* ringLayer = buildLayer(endcap, rings, firstStation, layer, rolls, geo);
      if (ringLayer)
        result[iendcap].push_back(ringLayer);
    }
 
    // ME 2 and ME 3
    for (int station = 2; station <= RPCDetId::maxStationId; ++station) {
      for (int layer = RPCDetId::minLayerId; layer <= RPCDetId::maxLayerId; ++layer) {
        vector<int> rolls;
        std::vector<int> rings;
        for (int ring = RPCDetId::minRingForwardId; ring <= RPCDetId::maxRingForwardId; ++ring) {
          rings.push_back(ring);
        }
        for (int roll = RPCDetId::minRollId + 1; roll <= RPCDetId::maxRollId; ++roll) {
          rolls.push_back(roll);
        }
 
        MuRingForwardDoubleLayer* ringLayer = buildLayer(endcap, rings, station, layer, rolls, geo);
        if (ringLayer)
          result[iendcap].push_back(ringLayer);
      }
    }
  }
  pair<vector<DetLayer*>, vector<DetLayer*> > res_pair(result[0], result[1]);
  return res_pair;
}

References makeMuonMisalignmentScenario::endcap, RPCDetId::maxLayerId, RPCDetId::maxRingForwardId, RPCDetId::maxRollId, RPCDetId::maxStationId, RPCDetId::minLayerId, RPCDetId::minRingForwardId, RPCDetId::minRollId, mps_fire::result, relativeConstraints::ring, and relativeConstraints::station.

Referenced by MuonDetLayerGeometryESProducer::produce().

buildLayer()

MuRingForwardDoubleLayer * MuonRPCDetLayerGeometryBuilder::buildLayer ( int  endcap, const std::vector< int > &  rings, int  station, int  layer, std::vector< int > &  rolls, const RPCGeometry &  geo  )

staticprivate

Definition at line 94 of file MuonRPCDetLayerGeometryBuilder.cc.

                                                                                                                 {
  const std::string metname = "Muon|RPC|RecoMuon|RecoMuonDetLayers|MuonRPCDetLayerGeometryBuilder";
 
  vector<const ForwardDetRing*> frontRings, backRings;
 
  for (std::vector<int>::const_iterator ring = rings.begin(); ring < rings.end(); ++ring) {
    for (vector<int>::iterator roll = rolls.begin(); roll != rolls.end(); ++roll) {
      vector<const GeomDet*> frontDets, backDets;
      for (int sector = RPCDetId::minSectorForwardId; sector <= RPCDetId::maxSectorForwardId; ++sector) {
        for (int subsector = RPCDetId::minSubSectorForwardId; subsector <= RPCDetId::maxSectorForwardId; ++subsector) {
          RPCDetId rpcId(endcap, *ring, station, sector, layer, subsector, (*roll));
          bool isInFront = isFront(rpcId);
          const GeomDet* geomDet = geo.idToDet(rpcId);
          if (geomDet) {
            if (isInFront) {
              frontDets.push_back(geomDet);
            } else {
              backDets.push_back(geomDet);
            }
            LogTrace(metname) << "get RPC Endcap roll " << rpcId << (isInFront ? "front" : "back ")
                              << " at R=" << geomDet->position().perp() << ", phi=" << geomDet->position().phi()
                              << ", Z=" << geomDet->position().z();
          }
        }
      }
      if (!frontDets.empty()) {
        precomputed_value_sort(frontDets.begin(), frontDets.end(), geomsort::DetPhi());
        frontRings.push_back(new MuDetRing(frontDets));
        LogTrace(metname) << "New front ring with " << frontDets.size()
                          << " chambers at z=" << frontRings.back()->position().z();
      }
      if (!backDets.empty()) {
        precomputed_value_sort(backDets.begin(), backDets.end(), geomsort::DetPhi());
        backRings.push_back(new MuDetRing(backDets));
        LogTrace(metname) << "New back ring with " << backDets.size()
                          << " chambers at z=" << backRings.back()->position().z();
      }
    }
  }
 
  MuRingForwardDoubleLayer* result = nullptr;
 
  if (!backRings.empty() || !frontRings.empty()) {
    typedef rpcdetlayergeomsort::ExtractInnerRadius<ForwardDetRing, float> SortRingByInnerR;
    precomputed_value_sort(frontRings.begin(), frontRings.end(), SortRingByInnerR());
    precomputed_value_sort(backRings.begin(), backRings.end(), SortRingByInnerR());
 
    result = new MuRingForwardDoubleLayer(frontRings, backRings);
    LogTrace(metname) << "New layer with " << frontRings.size() << " front rings and " << backRings.size()
                      << " back rings, at Z " << result->position().z();
  }
 
  return result;
}

References makeMuonMisalignmentScenario::endcap, RPCGeometry::idToDet(), LogTrace, RPCDetId::maxSectorForwardId, metname, RPCDetId::minSectorForwardId, RPCDetId::minSubSectorForwardId, PV3DBase< T, PVType, FrameType >::perp(), PV3DBase< T, PVType, FrameType >::phi(), GeomDet::position(), precomputed_value_sort(), mps_fire::result, relativeConstraints::ring, relativeConstraints::station, AlCaHLTBitMon_QueryRunRegistry::string, and PV3DBase< T, PVType, FrameType >::z().

isFront()

bool MuonRPCDetLayerGeometryBuilder::isFront ( const RPCDetId &  rpcId )

staticprivate

Definition at line 299 of file MuonRPCDetLayerGeometryBuilder.cc.

                                                                  {
  // ME1/2 is always in back
  //  if(rpcId.station() == 1 && rpcId.ring() == 2)  return false;
 
  bool result = false;
  int ring = rpcId.ring();
  int station = rpcId.station();
  // 20 degree rings are a little weird! not anymore from 17x
  if (ring == 1 && station > 1) {
    // RE2/1 RE3/1  Upscope Geometry
    /* goes (sector) (subsector)            1/3
    1 1 back   // front 
    1 2 front  // back  
    1 3 front  // front 
    2 1 front  // back  
    2 2 back   // from  
    2 3 back   // back  
                        
    */
    result = (rpcId.subsector() != 2);
    if (rpcId.sector() % 2 == 0)
      result = !result;
    return result;
  } else {
    // 10 degree rings have odd subsectors in front
    result = (rpcId.subsector() % 2 == 0);
  }
  return result;
}

References mps_fire::result, RPCDetId::ring(), relativeConstraints::ring, RPCDetId::sector(), relativeConstraints::station, RPCDetId::station(), and RPCDetId::subsector().

makeBarrelLayers()

void MuonRPCDetLayerGeometryBuilder::makeBarrelLayers ( std::vector< const GeomDet * > &  geomDets, std::vector< MuRodBarrelLayer * > &  result  )

staticprivate

Definition at line 186 of file MuonRPCDetLayerGeometryBuilder.cc.

                                                                                         {
  const std::string metname = "Muon|RPC|RecoMuon|RecoMuonDetLayers|MuonRPCDetLayerGeometryBuilder";
 
  //Sort in R
  precomputed_value_sort(geomDets.begin(), geomDets.end(), geomsort::DetR());
 
  // Clusterize in phi - phi0
  float resolution(25);  // cm
  float r0 = float(geomDets.front()->position().perp());
  float rMin = -float(resolution);
  float rMax = float(geomDets.back()->position().perp()) - r0 + resolution;
 
  ClusterizingHistogram hisR(int((rMax - rMin) / resolution) + 1, rMin, rMax);
 
  vector<const GeomDet*>::iterator first = geomDets.begin();
  vector<const GeomDet*>::iterator last = geomDets.end();
 
  for (vector<const GeomDet*>::iterator i = first; i != last; i++) {
    hisR.fill(float((*i)->position().perp()) - r0);
    LogTrace(metname) << "R " << float((*i)->position().perp()) - r0;
  }
  vector<float> rClust = hisR.clusterize(resolution);
 
  // LogTrace(metname) << "     Found " << phiClust.size() << " clusters in Phi, ";
 
  vector<const GeomDet*>::iterator layerStart = first;
  vector<const GeomDet*>::iterator separ = first;
 
  for (unsigned int i = 0; i < rClust.size(); i++) {
    float rSepar;
    if (i < rClust.size() - 1) {
      rSepar = (rClust[i] + rClust[i + 1]) / 2.f;
    } else {
      rSepar = rMax;
    }
 
    // LogTrace(metname) << "       cluster " << i
    // << " phisepar " << phiSepar <<endl;
    while (separ < last && float((*separ)->position().perp()) - r0 < rSepar) {
      // LogTrace(metname) << "         roll at dphi:  " << float((*separ)->position().phi())-phi0;
      separ++;
    }
 
    if (int(separ - layerStart) > 0) {
      // we have a layer in R.  Now separate it into rods
      vector<const DetRod*> rods;
      vector<const GeomDet*> layerDets(layerStart, separ);
      makeBarrelRods(layerDets, rods);
 
      if (!rods.empty()) {
        result.push_back(new MuRodBarrelLayer(rods));
        LogTrace(metname) << "    New MuRodBarrelLayer with " << rods.size() << " rods, at R "
                          << result.back()->specificSurface().radius();
      }
    }
    layerStart = separ;
  }
}

References f, dqmdumpme::first, dqmMemoryStats::float, mps_fire::i, dqmdumpme::last, LogTrace, metname, precomputed_value_sort(), L1TObjectsTimingClient_cff::resolution, mps_fire::result, photonAnalyzer_cfi::rMax, photonAnalyzer_cfi::rMin, and AlCaHLTBitMon_QueryRunRegistry::string.

makeBarrelRods()

void MuonRPCDetLayerGeometryBuilder::makeBarrelRods ( std::vector< const GeomDet * > &  geomDets, std::vector< const DetRod * > &  result  )

staticprivate

Definition at line 246 of file MuonRPCDetLayerGeometryBuilder.cc.

                                                                                                                   {
  const std::string metname = "Muon|RPC|RecoMuon|RecoMuonDetLayers|MuonRPCDetLayerGeometryBuilder";
 
  //Sort in phi
  precomputed_value_sort(geomDets.begin(), geomDets.end(), geomsort::DetPhi());
 
  // Clusterize in phi - phi0
  float resolution(0.01);  // rad
  float phi0 = float(geomDets.front()->position().phi());
  float phiMin = -float(resolution);
  float phiMax = float(geomDets.back()->position().phi()) - phi0 + resolution;
 
  ClusterizingHistogram hisPhi(int((phiMax - phiMin) / resolution) + 1, phiMin, phiMax);
 
  vector<const GeomDet*>::iterator first = geomDets.begin();
  vector<const GeomDet*>::iterator last = geomDets.end();
 
  for (vector<const GeomDet*>::iterator i = first; i != last; i++) {
    hisPhi.fill(float((*i)->position().phi()) - phi0);
    LogTrace(metname) << "C " << float((*i)->position().phi()) - phi0;
  }
  vector<float> phiClust = hisPhi.clusterize(resolution);
 
  // LogTrace(metname) << "     Found " << phiClust.size() << " clusters in Phi, ";
 
  vector<const GeomDet*>::iterator rodStart = first;
  vector<const GeomDet*>::iterator separ = first;
 
  for (unsigned int i = 0; i < phiClust.size(); i++) {
    float phiSepar;
    if (i < phiClust.size() - 1) {
      phiSepar = (phiClust[i] + phiClust[i + 1]) / 2.f;
    } else {
      phiSepar = phiMax;
    }
 
    // LogTrace(metname) << "       cluster " << i
    // << " phisepar " << phiSepar <<endl;
    while (separ < last && float((*separ)->position().phi()) - phi0 < phiSepar) {
      // LogTrace(metname) << "         roll at dphi:  " << float((*separ)->position().phi())-phi0;
      separ++;
    }
 
    if (int(separ - rodStart) > 0) {
      result.push_back(new MuDetRod(rodStart, separ));
      LogTrace(metname) << "  New MuDetRod with " << int(separ - rodStart)
                        << " rolls at R=" << (*rodStart)->position().perp()
                        << ", phi=" << float((*rodStart)->position().phi());
    }
    rodStart = separ;
  }
}

References f, dqmdumpme::first, dqmMemoryStats::float, mps_fire::i, createfilelist::int, dqmdumpme::last, LogTrace, metname, AlignmentTrackSelector_cfi::phiMax, AlignmentTrackSelector_cfi::phiMin, precomputed_value_sort(), L1TObjectsTimingClient_cff::resolution, mps_fire::result, and AlCaHLTBitMon_QueryRunRegistry::string.