FWMuonBuilder.cc

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// -*- C++ -*-
//
// Package:     Muons
// Class  :     FWMuonBuilder
//
 
#include "TEveVSDStructs.h"
#include "TEveTrack.h"
#include "TEveStraightLineSet.h"
#include "TEveGeoNode.h"
#include "TEveGeoShape.h"
#include "TGeoArb8.h"
 
#include "Fireworks/Core/interface/FWEventItem.h"
#include "Fireworks/Core/interface/FWMagField.h"
#include "Fireworks/Core/interface/FWProxyBuilderBase.h"
#include "Fireworks/Core/interface/FWGeometry.h"
#include "Fireworks/Core/interface/fwLog.h"
 
#include "Fireworks/Candidates/interface/CandidateUtils.h"
 
#include "Fireworks/Tracks/interface/TrackUtils.h"
#include "Fireworks/Tracks/interface/estimate_field.h"
 
#include "Fireworks/Muons/interface/FWMuonBuilder.h"
#include "Fireworks/Muons/interface/SegmentUtils.h"
 
#include "DataFormats/MuonReco/interface/Muon.h"
#include "DataFormats/TrackReco/interface/Track.h"
#include "DataFormats/MuonDetId/interface/MuonSubdetId.h"
 
namespace {
  std::vector<TEveVector> getRecoTrajectoryPoints(const reco::Muon* muon, const FWEventItem* iItem) {
    std::vector<TEveVector> points;
    const FWGeometry* geom = iItem->getGeom();
 
    float localTrajectoryPoint[3];
    float globalTrajectoryPoint[3];
 
    const std::vector<reco::MuonChamberMatch>& matches = muon->matches();
    for (std::vector<reco::MuonChamberMatch>::const_iterator chamber = matches.begin(), chamberEnd = matches.end();
         chamber != chamberEnd;
         ++chamber) {
      // expected track position
      localTrajectoryPoint[0] = chamber->x;
      localTrajectoryPoint[1] = chamber->y;
      localTrajectoryPoint[2] = 0;
 
      unsigned int rawid = chamber->id.rawId();
      if (geom->contains(rawid)) {
        geom->localToGlobal(rawid, localTrajectoryPoint, globalTrajectoryPoint);
        points.push_back(TEveVector(globalTrajectoryPoint[0], globalTrajectoryPoint[1], globalTrajectoryPoint[2]));
      }
    }
    return points;
  }
 
  //______________________________________________________________________________
 
  void addMatchInformation(const reco::Muon* muon, FWProxyBuilderBase* pb, TEveElement* parentList, bool showEndcap) {
    std::set<unsigned int> ids;
    const FWGeometry* geom = pb->context().getGeom();
 
    const std::vector<reco::MuonChamberMatch>& matches = muon->matches();
 
    //need to use auto_ptr since the segmentSet may not be passed to muonList
    std::unique_ptr<TEveStraightLineSet> segmentSet(new TEveStraightLineSet);
    // FIXME: This should be set elsewhere.
    segmentSet->SetLineWidth(4);
 
    for (std::vector<reco::MuonChamberMatch>::const_iterator chamber = matches.begin(), chambersEnd = matches.end();
         chamber != chambersEnd;
         ++chamber) {
      unsigned int rawid = chamber->id.rawId();
      float segmentLength = 0.0;
      float segmentLimit = 0.0;
 
      if (geom->contains(rawid)) {
        TEveGeoShape* shape = geom->getEveShape(rawid);
        shape->SetElementName("Chamber");
        shape->RefMainTrans().Scale(0.999, 0.999, 0.999);
 
        FWGeometry::IdToInfoItr det = geom->find(rawid);
        if (det->shape[0] == 1)  // TGeoTrap
        {
          segmentLength = det->shape[3];
          segmentLimit = det->shape[4];
        } else if (det->shape[0] == 2)  // TGeoBBox
        {
          segmentLength = det->shape[3];
        } else {
          const double segmentLength = 15;
          fwLog(fwlog::kWarning) << Form(
              "FWMuonBuilder: unknown shape type in muon chamber with detId=%d. Setting segment length to %.0f cm.\n",
              rawid,
              segmentLength);
        }
 
        if (ids.insert(rawid).second &&  // ensure that we add same chamber only once
            (chamber->detector() != MuonSubdetId::CSC || showEndcap)) {
          pb->setupAddElement(shape, parentList);
        }
 
        for (std::vector<reco::MuonSegmentMatch>::const_iterator segment = chamber->segmentMatches.begin(),
                                                                 segmentEnd = chamber->segmentMatches.end();
             segment != segmentEnd;
             ++segment) {
          float segmentPosition[3] = {segment->x, segment->y, 0.0};
          float segmentDirection[3] = {segment->dXdZ, segment->dYdZ, 0.0};
 
          float localSegmentInnerPoint[3];
          float localSegmentOuterPoint[3];
 
          fireworks::createSegment(chamber->detector(),
                                   true,
                                   segmentLength,
                                   segmentLimit,
                                   segmentPosition,
                                   segmentDirection,
                                   localSegmentInnerPoint,
                                   localSegmentOuterPoint);
 
          float globalSegmentInnerPoint[3];
          float globalSegmentOuterPoint[3];
 
          geom->localToGlobal(*det, localSegmentInnerPoint, globalSegmentInnerPoint);
          geom->localToGlobal(*det, localSegmentOuterPoint, globalSegmentOuterPoint);
 
          segmentSet->AddLine(globalSegmentInnerPoint[0],
                              globalSegmentInnerPoint[1],
                              globalSegmentInnerPoint[2],
                              globalSegmentOuterPoint[0],
                              globalSegmentOuterPoint[1],
                              globalSegmentOuterPoint[2]);
        }
      }
    }
 
    if (!matches.empty())
      pb->setupAddElement(segmentSet.release(), parentList);
  }
 
  //______________________________________________________________________________
 
  bool buggyMuon(const reco::Muon* muon, const FWGeometry* geom) {
    if (!muon->standAloneMuon().isAvailable() || !muon->standAloneMuon()->extra().isAvailable())
      return false;
 
    float localTrajectoryPoint[3];
    float globalTrajectoryPoint[3];
 
    const std::vector<reco::MuonChamberMatch>& matches = muon->matches();
    for (std::vector<reco::MuonChamberMatch>::const_iterator chamber = matches.begin(), chamberEnd = matches.end();
         chamber != chamberEnd;
         ++chamber) {
      // expected track position
      localTrajectoryPoint[0] = chamber->x;
      localTrajectoryPoint[1] = chamber->y;
      localTrajectoryPoint[2] = 0;
 
      unsigned int rawid = chamber->id.rawId();
      if (geom->contains(rawid)) {
        geom->localToGlobal(rawid, localTrajectoryPoint, globalTrajectoryPoint);
        double phi = atan2(globalTrajectoryPoint[1], globalTrajectoryPoint[0]);
        if (cos(phi - muon->standAloneMuon()->innerPosition().phi()) < 0)
          return true;
      }
    }
    return false;
  }
 
  TEveTrack* prepareMuonTrackWithExtraPoints(const reco::Track& track,
                                             TEveTrackPropagator* propagator,
                                             const std::vector<TEveVector>& extraPoints) {
    TEveRecTrack t;
    t.fBeta = 1.;
    t.fSign = track.charge();
    t.fV.Set(track.vx(), track.vy(), track.vz());
    t.fP.Set(track.px(), track.py(), track.pz());
    //  t.fSign = muon->charge();
    //  t.fV.Set(muon->vx(), muon->vy(), muon->vz());
    //  t.fP.Set(muon->px(), muon->py(), muon->pz());
    TEveTrack* trk = new TEveTrack(&t, propagator);
    size_t n = extraPoints.size();
 
    if (n > 1) {
      int lastDaughter = n - 2;
      for (int i = 0; i <= lastDaughter; ++i)
        trk->AddPathMark(TEvePathMark(TEvePathMark::kDaughter, extraPoints[i]));
    }
    trk->AddPathMark(TEvePathMark(TEvePathMark::kDecay, extraPoints.back()));
    return trk;
  }
 
}  // namespace
 
//
// constructors and destructor
//
FWMuonBuilder::FWMuonBuilder() : m_lineWidth(1) {}
 
FWMuonBuilder::~FWMuonBuilder() {}
 
//
// member functions
//
//______________________________________________________________________________
 
void FWMuonBuilder::calculateField(const reco::Muon& iData, FWMagField* field) {
  // if auto field estimation mode, do extra loop over muons.
  // use both inner and outer track if available
  if (field->getSource() == FWMagField::kNone) {
    if (fabs(iData.eta()) > 2.0 || iData.pt() < 3)
      return;
    if (iData.innerTrack().isAvailable()) {
      double estimate = fw::estimate_field(*(iData.innerTrack()), true);
      if (estimate >= 0)
        field->guessField(estimate);
    }
    if (iData.outerTrack().isAvailable()) {
      double estimate = fw::estimate_field(*(iData.outerTrack()));
      if (estimate >= 0)
        field->guessFieldIsOn(estimate > 0.5);
    }
  }
}
 
//______________________________________________________________________________
 
void FWMuonBuilder::buildMuon(
    FWProxyBuilderBase* pb, const reco::Muon* muon, TEveElement* tList, bool showEndcap, bool tracksOnly) {
  calculateField(*muon, pb->context().getField());
 
  TEveRecTrack recTrack;
  recTrack.fBeta = 1.;
 
  // If we deal with a tracker muon we use the inner track and guide it
  // through the trajectory points from the reconstruction. Segments
  // represent hits. Matching between hits and the trajectory shows
  // how well the inner track matches with the muon hypothesis.
  //
  // In other cases we use a global muon track with a few states from
  // the inner and outer tracks or just the outer track if it's the
  // only option
 
  if (muon->isTrackerMuon() && muon->innerTrack().isAvailable() && muon->isMatchesValid() &&
      !buggyMuon(&*muon, pb->context().getGeom())) {
    TEveTrack* trk = fireworks::prepareTrack(
        *(muon->innerTrack()), pb->context().getMuonTrackPropagator(), getRecoTrajectoryPoints(muon, pb->item()));
    trk->MakeTrack();
    trk->SetLineWidth(m_lineWidth);
    pb->setupAddElement(trk, tList);
    if (!tracksOnly)
      addMatchInformation(&(*muon), pb, tList, showEndcap);
    return;
  }
 
  if (muon->isGlobalMuon() && muon->globalTrack().isAvailable()) {
    std::vector<TEveVector> extraPoints;
    if (muon->innerTrack().isAvailable() && muon->innerTrack()->extra().isAvailable()) {
      extraPoints.push_back(TEveVector(muon->innerTrack()->innerPosition().x(),
                                       muon->innerTrack()->innerPosition().y(),
                                       muon->innerTrack()->innerPosition().z()));
      extraPoints.push_back(TEveVector(muon->innerTrack()->outerPosition().x(),
                                       muon->innerTrack()->outerPosition().y(),
                                       muon->innerTrack()->outerPosition().z()));
    }
    if (muon->outerTrack().isAvailable() && muon->outerTrack()->extra().isAvailable()) {
      extraPoints.push_back(TEveVector(muon->outerTrack()->innerPosition().x(),
                                       muon->outerTrack()->innerPosition().y(),
                                       muon->outerTrack()->innerPosition().z()));
      extraPoints.push_back(TEveVector(muon->outerTrack()->outerPosition().x(),
                                       muon->outerTrack()->outerPosition().y(),
                                       muon->outerTrack()->outerPosition().z()));
    }
    TEveTrack* trk = nullptr;
    if (extraPoints.empty())
      trk = fireworks::prepareTrack(*(muon->globalTrack()), pb->context().getMuonTrackPropagator());
    else
      trk =
          prepareMuonTrackWithExtraPoints(*(muon->globalTrack()), pb->context().getMuonTrackPropagator(), extraPoints);
 
    trk->MakeTrack();
    trk->SetLineWidth(m_lineWidth);
    pb->setupAddElement(trk, tList);
    return;
  }
 
  if (muon->innerTrack().isAvailable()) {
    TEveTrack* trk = fireworks::prepareTrack(*(muon->innerTrack()), pb->context().getMuonTrackPropagator());
    trk->MakeTrack();
    pb->setupAddElement(trk, tList);
    return;
  }
 
  if (muon->outerTrack().isAvailable()) {
    TEveTrack* trk = fireworks::prepareTrack(*(muon->outerTrack()), pb->context().getMuonTrackPropagator());
    trk->MakeTrack();
    trk->SetLineWidth(m_lineWidth);
    pb->setupAddElement(trk, tList);
    return;
  }
 
  // if got that far it means we have nothing but a candidate
  // show it anyway.
  TEveTrack* trk = fireworks::prepareCandidate(*muon, pb->context().getMuonTrackPropagator());
  trk->MakeTrack();
  trk->SetLineWidth(m_lineWidth);
  pb->setupAddElement(trk, tList);
}