OverlapValidation Class Reference

Inheritance diagram for OverlapValidation:

Public Member Functions
	OverlapValidation (const edm::ParameterSet &)
	~OverlapValidation () override
Public Member Functions inherited from edm::one::EDAnalyzer< edm::one::SharedResources >
	EDAnalyzer ()=default
	EDAnalyzer (const EDAnalyzer &)=delete
SerialTaskQueue *	globalLuminosityBlocksQueue () final
SerialTaskQueue *	globalRunsQueue () final
const EDAnalyzer &	operator= (const EDAnalyzer &)=delete
bool	wantsGlobalLuminosityBlocks () const noexcept final
bool	wantsGlobalRuns () const noexcept final
bool	wantsInputProcessBlocks () const noexcept final
bool	wantsProcessBlocks () const noexcept final
Public Member Functions inherited from edm::one::EDAnalyzerBase
void	callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)
	EDAnalyzerBase ()
ModuleDescription const &	moduleDescription () const
bool	wantsStreamLuminosityBlocks () const noexcept
bool	wantsStreamRuns () const noexcept
	~EDAnalyzerBase () override
Public Member Functions inherited from edm::EDConsumerBase
std::vector< ConsumesInfo >	consumesInfo () const
void	convertCurrentProcessAlias (std::string const &processName)
	Convert "@currentProcess" in InputTag process names to the actual current process name. More...
	EDConsumerBase ()
	EDConsumerBase (EDConsumerBase const &)=delete
	EDConsumerBase (EDConsumerBase &&)=default
ESResolverIndex const *	esGetTokenIndices (edm::Transition iTrans) const
std::vector< ESResolverIndex > const &	esGetTokenIndicesVector (edm::Transition iTrans) const
std::vector< ESRecordIndex > const &	esGetTokenRecordIndicesVector (edm::Transition iTrans) const
ProductResolverIndexAndSkipBit	indexFrom (EDGetToken, BranchType, TypeID const &) const
void	itemsMayGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const
void	itemsToGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const
std::vector< ProductResolverIndexAndSkipBit > const &	itemsToGetFrom (BranchType iType) const
void	labelsForToken (EDGetToken iToken, Labels &oLabels) const
void	modulesWhoseProductsAreConsumed (std::array< std::vector< ModuleDescription const *> *, NumBranchTypes > &modulesAll, std::vector< ModuleProcessName > &modulesInPreviousProcesses, ProductRegistry const &preg, std::map< std::string, ModuleDescription const *> const &labelsToDesc, std::string const &processName) const
EDConsumerBase const &	operator= (EDConsumerBase const &)=delete
EDConsumerBase &	operator= (EDConsumerBase &&)=default
bool	registeredToConsume (ProductResolverIndex, bool, BranchType) const
void	selectInputProcessBlocks (ProductRegistry const &productRegistry, ProcessBlockHelperBase const &processBlockHelperBase)
ProductResolverIndexAndSkipBit	uncheckedIndexFrom (EDGetToken) const
void	updateLookup (BranchType iBranchType, ProductResolverIndexHelper const &, bool iPrefetchMayGet)
void	updateLookup (eventsetup::ESRecordsToProductResolverIndices const &)
virtual	~EDConsumerBase () noexcept(false)

Static Public Member Functions
static void	fillDescriptions (edm::ConfigurationDescriptions &descriptions)
Static Public Member Functions inherited from edm::one::EDAnalyzerBase
static const std::string &	baseType ()
static void	fillDescriptions (ConfigurationDescriptions &descriptions)
static void	prevalidate (ConfigurationDescriptions &descriptions)

Private Types
typedef TransientTrackingRecHit::ConstRecHitPointer	ConstRecHitPointer
typedef vector< Trajectory >	TrajectoryCollection

Private Member Functions
void	analyze (const edm::Event &, const edm::EventSetup &) override
virtual void	analyzeTrajectory (const Trajectory &, const Propagator &, TrackerHitAssociator &, const TrackerTopology *const tTopo)
void	endJob () override
int	layerFromId (const DetId &, const TrackerTopology *const tTopo) const

Private Attributes
vector< bool >	acceptLayer
const bool	addExtraBranches_
bool	barrelOnly_
float	chi2_ [2]
const float	chi2ProbCut_
uint	clusterCharge_ [2]
float	clusterSize_ [2]
float	clusterWidthX_ [2]
float	clusterWidthY_ [2]
TrajectoryStateCombiner	combiner_
const int	compressionSettings_
edm::ParameterSet	config_
SiStripDetInfo	detInfo_
bool	doSimHit_
int	edge_ [2]
uint	event_
edm::FileInPath	FileInPath_
const edm::ESGetToken< TrackerGeometry, TrackerDigiGeometryRecord >	geomToken_
unsigned short	hitCounts_ [2]
float	hitErrors_ [2]
float	hitErrorsY_ [2]
float	hitPositions_ [2]
float	hitPositionsY_ [2]
uint	layer_
float	localxdotglobalphi_ [2]
float	localxdotglobalr_ [2]
float	localxdotglobalx_ [2]
float	localxdotglobaly_ [2]
float	localxdotglobalz_ [2]
float	localydotglobalphi_ [2]
float	localydotglobalr_ [2]
float	localydotglobalx_ [2]
float	localydotglobaly_ [2]
float	localydotglobalz_ [2]
const MagneticField *	magField_
const edm::ESGetToken< MagneticField, IdealMagneticFieldRecord >	magFieldToken_
const int	minHitsCut_
float	moduleX_ [2]
float	moduleY_ [2]
float	moduleZ_ [2]
float	momentum_
const Point2DBase< float, LocalTag >	onezero = Point2DBase<float, LocalTag>(1, 0)
int	overlapCounts_ [3]
unsigned int	overlapIds_ [2]
float	overlapPath_
float	predictedDeltaXError_
float	predictedDeltaYError_
float	predictedLocalErrors_ [5][2]
float	predictedLocalParameters_ [5][2]
float	predictedPositions_ [3][2]
char	relativeXSign_
char	relativeYSign_
TTree *	rootTree_
uint	run_
float	simHitPositions_ [2]
float	simHitPositionsY_ [2]
int	subdetID
const edm::ESGetToken< TrackerTopology, TrackerTopologyRcd >	topoToken_
const TrackerGeometry *	trackerGeometry_
edm::InputTag	trajectoryTag_
edm::EDGetTokenT< TrajectoryCollection >	trajectoryToken_
const Point2DBase< float, LocalTag >	zeroone = Point2DBase<float, LocalTag>(0, 1)
const Point2DBase< float, LocalTag >	zerozero = Point2DBase<float, LocalTag>(0, 0)

Additional Inherited Members
Public Types inherited from edm::one::EDAnalyzerBase
typedef EDAnalyzerBase	ModuleType
Public Types inherited from edm::EDConsumerBase
typedef ProductLabels	Labels
Protected Member Functions inherited from edm::EDConsumerBase
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	consumes (edm::InputTag const &tag)
template<BranchType B = InEvent>
EDConsumerBaseAdaptor< B >	consumes (edm::InputTag tag) noexcept
EDGetToken	consumes (const TypeToGet &id, edm::InputTag const &tag)
template<BranchType B>
EDGetToken	consumes (TypeToGet const &id, edm::InputTag const &tag)
ConsumesCollector	consumesCollector ()
	Use a ConsumesCollector to gather consumes information from helper functions. More...
template<typename ESProduct , typename ESRecord , Transition Tr = Transition::Event>
auto	esConsumes ()
template<typename ESProduct , typename ESRecord , Transition Tr = Transition::Event>
auto	esConsumes (ESInputTag const &tag)
template<Transition Tr = Transition::Event>
constexpr auto	esConsumes ()
template<Transition Tr = Transition::Event>
auto	esConsumes (ESInputTag tag)
template<Transition Tr = Transition::Event>
ESGetTokenGeneric	esConsumes (eventsetup::EventSetupRecordKey const &iRecord, eventsetup::DataKey const &iKey)
	Used with EventSetupRecord::doGet. More...
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	mayConsume (edm::InputTag const &tag)
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)
template<BranchType B>
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)
void	resetItemsToGetFrom (BranchType iType)

Detailed Description

Definition at line 81 of file OverlapValidation.cc.

Member Typedef Documentation

ConstRecHitPointer

typedef TransientTrackingRecHit::ConstRecHitPointer OverlapValidation::ConstRecHitPointer

private

Definition at line 91 of file OverlapValidation.cc.

TrajectoryCollection

typedef vector<Trajectory> OverlapValidation::TrajectoryCollection

private

Definition at line 88 of file OverlapValidation.cc.

Constructor & Destructor Documentation

OverlapValidation()

OverlapValidation::OverlapValidation ( const edm::ParameterSet &  iConfig )

explicit

Definition at line 186 of file OverlapValidation.cc.

References acceptLayer, addExtraBranches_, barrelOnly_, chi2_, clusterCharge_, clusterSize_, clusterWidthX_, clusterWidthY_, compressionSettings_, edm::ConsumesCollector::consumes(), edm::EDConsumerBase::consumesCollector(), detInfo_, doSimHit_, edge_, event_, FileInPath_, compareTotals::fs, edm::FileInPath::fullPath(), edm::ParameterSet::getParameter(), hitCounts_, hitErrors_, hitErrorsY_, hitPositions_, hitPositionsY_, TFileService::kSharedResource, layer_, localxdotglobalphi_, localxdotglobalr_, localxdotglobalx_, localxdotglobaly_, localxdotglobalz_, localydotglobalphi_, localydotglobalr_, localydotglobalx_, localydotglobaly_, localydotglobalz_, moduleX_, moduleY_, moduleZ_, momentum_, overlapCounts_, overlapIds_, overlapPath_, PixelSubdetector::PixelBarrel, PixelSubdetector::PixelEndcap, predictedDeltaXError_, predictedDeltaYError_, predictedLocalErrors_, predictedLocalParameters_, predictedPositions_, SiStripDetInfoFileReader::read(), relativeXSign_, relativeYSign_, rootTree_, run_, simHitPositions_, simHitPositionsY_, subdetID, StripSubdetector::TEC, StripSubdetector::TIB, StripSubdetector::TID, StripSubdetector::TOB, trajectoryTag_, and trajectoryToken_.

    : geomToken_(esConsumes()),
      magFieldToken_(esConsumes()),
      topoToken_(esConsumes()),
      config_(iConfig),
      rootTree_(nullptr),
      FileInPath_(SiStripDetInfoFileReader::kDefaultFile),
      compressionSettings_(iConfig.getUntrackedParameter<int>("compressionSettings", -1)),
      addExtraBranches_(false),
      minHitsCut_(6),
      chi2ProbCut_(0.001) {
  usesResource(TFileService::kSharedResource);
  edm::ConsumesCollector&& iC = consumesCollector();
  //now do what ever initialization is needed
  trajectoryTag_ = iConfig.getParameter<edm::InputTag>("trajectories");
  trajectoryToken_ = iC.consumes<TrajectoryCollection>(trajectoryTag_);
  doSimHit_ = iConfig.getParameter<bool>("associateStrip");
  detInfo_ = SiStripDetInfoFileReader::read(FileInPath_.fullPath());

  overlapCounts_[0] = 0;  // #trajectories
  overlapCounts_[1] = 0;  // #hits
  overlapCounts_[2] = 0;  // #overlap hits
  acceptLayer.resize(7, false);
  acceptLayer[PixelSubdetector::PixelBarrel] = iConfig.getParameter<bool>("usePXB");
  acceptLayer[PixelSubdetector::PixelEndcap] = iConfig.getParameter<bool>("usePXF");
  acceptLayer[StripSubdetector::TIB] = iConfig.getParameter<bool>("useTIB");
  acceptLayer[StripSubdetector::TOB] = iConfig.getParameter<bool>("useTOB");
  acceptLayer[StripSubdetector::TID] = iConfig.getParameter<bool>("useTID");
  acceptLayer[StripSubdetector::TEC] = iConfig.getParameter<bool>("useTEC");
  barrelOnly_ = iConfig.getParameter<bool>("barrelOnly");

  edm::Service<TFileService> fs;
  //
  // root output
  //
  if (compressionSettings_ > 0) {
    fs->file().SetCompressionSettings(compressionSettings_);
  }

  rootTree_ = fs->make<TTree>("Overlaps", "Overlaps");
  if (addExtraBranches_) {
    rootTree_->Branch("hitCounts", hitCounts_, "found/s:lost/s");
    rootTree_->Branch("chi2", chi2_, "chi2/F:ndf/F");
    rootTree_->Branch("path", &overlapPath_, "path/F");
  }
  rootTree_->Branch("layer", &layer_, "layer/i");
  rootTree_->Branch("detids", overlapIds_, "id[2]/i");
  rootTree_->Branch("predPos", predictedPositions_, "gX[2]/F:gY[2]/F:gZ[2]/F");
  rootTree_->Branch("predPar", predictedLocalParameters_, "predQP[2]/F:predDX[2]/F:predDY[2]/F:predX[2]/F:predY[2]/F");
  rootTree_->Branch("predErr", predictedLocalErrors_, "predEQP[2]/F:predEDX[2]/F:predEDY[2]/F:predEX[2]/F:predEY[2]/F");
  rootTree_->Branch("predEDeltaX", &predictedDeltaXError_, "sigDeltaX/F");
  rootTree_->Branch("predEDeltaY", &predictedDeltaYError_, "sigDeltaY/F");
  rootTree_->Branch("relSignX", &relativeXSign_, "relSignX/B");
  rootTree_->Branch("relSignY", &relativeYSign_, "relSignY/B");
  rootTree_->Branch("hitX", hitPositions_, "hitX[2]/F");
  rootTree_->Branch("hitEX", hitErrors_, "hitEX[2]/F");
  rootTree_->Branch("hitY", hitPositionsY_, "hitY[2]/F");
  rootTree_->Branch("hitEY", hitErrorsY_, "hitEY[2]/F");
  if (addExtraBranches_) {
    rootTree_->Branch("simX", simHitPositions_, "simX[2]/F");
    rootTree_->Branch("simY", simHitPositionsY_, "simY[2]/F");
    rootTree_->Branch("clusterSize", clusterSize_, "clusterSize[2]/F");
    rootTree_->Branch("clusterWidthX", clusterWidthX_, "clusterWidthX[2]/F");
    rootTree_->Branch("clusterWidthY", clusterWidthY_, "clusterWidthY[2]/F");
    rootTree_->Branch("clusterCharge", clusterCharge_, "clusterCharge[2]/i");
    rootTree_->Branch("edge", edge_, "edge[2]/I");
  }
  rootTree_->Branch("momentum", &momentum_, "momentum/F");
  rootTree_->Branch("run", &run_, "run/i");
  rootTree_->Branch("event", &event_, "event/i");
  rootTree_->Branch("subdetID", &subdetID, "subdetID/I");
  rootTree_->Branch("moduleX", moduleX_, "moduleX[2]/F");
  rootTree_->Branch("moduleY", moduleY_, "moduleY[2]/F");
  rootTree_->Branch("moduleZ", moduleZ_, "moduleZ[2]/F");
  rootTree_->Branch("localxdotglobalphi", localxdotglobalphi_, "localxdotglobalphi[2]/F");
  rootTree_->Branch("localxdotglobalr", localxdotglobalr_, "localxdotglobalr[2]/F");
  rootTree_->Branch("localxdotglobalz", localxdotglobalz_, "localxdotglobalz[2]/F");
  rootTree_->Branch("localxdotglobalx", localxdotglobalx_, "localxdotglobalx[2]/F");
  rootTree_->Branch("localxdotglobaly", localxdotglobaly_, "localxdotglobaly[2]/F");
  rootTree_->Branch("localydotglobalphi", localydotglobalphi_, "localydotglobalphi[2]/F");
  rootTree_->Branch("localydotglobalr", localydotglobalr_, "localydotglobalr[2]/F");
  rootTree_->Branch("localydotglobalz", localydotglobalz_, "localydotglobalz[2]/F");
  rootTree_->Branch("localydotglobalx", localydotglobalx_, "localydotglobalx[2]/F");
  rootTree_->Branch("localydotglobaly", localydotglobaly_, "localydotglobaly[2]/F");
}

~OverlapValidation()

OverlapValidation::~OverlapValidation ( )

override

Definition at line 290 of file OverlapValidation.cc.

References overlapCounts_, and w().

                                      {
  edm::LogWarning w("Overlaps");
  // do anything here that needs to be done at desctruction time
  // (e.g. close files, deallocate resources etc.)
  w << "Counters =";
  w << " Number of tracks: " << overlapCounts_[0];
  w << " Number of valid hits: " << overlapCounts_[1];
  w << " Number of overlaps: " << overlapCounts_[2];
}

Member Function Documentation

analyze()

void OverlapValidation::analyze ( const edm::Event &  iEvent, const edm::EventSetup &  iSetup  )

overrideprivatevirtual

Implements edm::one::EDAnalyzerBase.

Definition at line 305 of file OverlapValidation.cc.

References AnalyticalPropagator_cfi::AnalyticalPropagator, analyzeTrajectory(), anyDirection, LCToCPAssociation_cfi::associator, config_, edm::EDConsumerBase::consumesCollector(), doSimHit_, event_, geomToken_, edm::EventSetup::getData(), iEvent, magField_, magFieldToken_, edm::Handle< T >::product(), TrackCandidateProducer_cfi::propagator, run_, topoToken_, trackerGeometry_, and trajectoryToken_.

                                                                                   {
  using namespace edm;
  //
  // mag field & search tracker
  //
  magField_ = &iSetup.getData(magFieldToken_);
  //
  // propagator
  //
  AnalyticalPropagator propagator(magField_, anyDirection);
  //
  // geometry
  //
  trackerGeometry_ = &iSetup.getData(geomToken_);
  //
  // make associator for SimHits
  //
  TrackerHitAssociator* associator;
  if (doSimHit_) {
    TrackerHitAssociator::Config hitassociatorconfig(config_, consumesCollector());
    associator = new TrackerHitAssociator(iEvent, hitassociatorconfig);
  } else {
    associator = nullptr;
  }

  //if(doSimHit_) associator = new TrackerHitAssociator(iEvent, config_); else associator = 0;

  //
  // trajectories (from refit)
  //
  //typedef vector<Trajectory> TrajectoryCollection;
  edm::Handle<TrajectoryCollection> trajectoryCollectionHandle;
  iEvent.getByToken(trajectoryToken_, trajectoryCollectionHandle);
  const TrajectoryCollection* const trajectoryCollection = trajectoryCollectionHandle.product();

  //
  // loop over trajectories from refit
  const TrackerTopology* const tTopo = &iSetup.getData(topoToken_);
  for (const auto& trajectory : *trajectoryCollection)
    analyzeTrajectory(trajectory, propagator, *associator, tTopo);

  run_ = iEvent.id().run();
  event_ = iEvent.id().event();
}

analyzeTrajectory()

void OverlapValidation::analyzeTrajectory ( const Trajectory &  trajectory, const Propagator &  propagator, TrackerHitAssociator &  associator, const TrackerTopology *const  tTopo  )

privatevirtual

Definition at line 350 of file OverlapValidation.cc.

References funct::abs(), acceptLayer, LCToCPAssociation_cfi::associator, barrelOnly_, ALCARECOTkAlJpsiMuMu_cff::charge, chi2_, chi2ProbCut_, Trajectory::chiSquared(), ChiSquaredProbability(), SiStripRecHit1D::cluster(), SiPixelRecHit::cluster(), clusterCharge_, clusterSize_, clusterWidthX_, clusterWidthY_, TrajectoryStateCombiner::combine(), combiner_, detInfo_, change_name::diff, doSimHit_, edge_, Trajectory::foundHits(), SiStripDetInfo::getNumberOfApvsAndStripLength(), TrajectoryStateOnSurface::globalMomentum(), TrajectoryStateOnSurface::globalParameters(), TrajectoryStateOnSurface::globalPosition(), SiStripDetId::glued(), runTauDisplay::gp, hitCounts_, hitErrors_, hitErrorsY_, hitPositions_, hitPositionsY_, mps_fire::i, globals_cff::id1, globals_cff::id2, PixelTopology::isItEdgePixelInX(), PixelTopology::isItEdgePixelInY(), TrajectoryStateOnSurface::isValid(), dqmiolumiharvest::j, JacobianCurvilinearToLocal::jacobian(), nano_mu_digi_cff::layer, layer_, layerFromId(), TrajectoryStateOnSurface::localError(), TrajectoryStateOnSurface::localParameters(), localxdotglobalphi_, localxdotglobalr_, localxdotglobalx_, localxdotglobaly_, localxdotglobalz_, localydotglobalphi_, localydotglobalr_, localydotglobalx_, localydotglobaly_, localydotglobalz_, Trajectory::lostHits(), visualization-live-secondInstance_cfg::m, PV3DBase< T, PVType, FrameType >::mag(), magField_, LocalTrajectoryError::matrix(), Trajectory::measurements(), minHitsCut_, moduleX_, moduleY_, moduleZ_, momentum_, GluedGeomDet::monoDet(), Trajectory::ndof(), onezero, HLT_2024v14_cff::Overlap, overlapCounts_, overlapIds_, overlapPath_, PixelSubdetector::PixelBarrel, PixelSubdetector::PixelEndcap, position, predictedDeltaXError_, predictedDeltaYError_, predictedLocalErrors_, predictedLocalParameters_, predictedPositions_, TrackCandidateProducer_cfi::propagator, DetId::rawId(), nano_mu_digi_cff::rawId, relativeXSign_, relativeYSign_, rootTree_, l1tEGammaCrystalsEmulatorProducer_cfi::scale, simHitPositions_, simHitPositionsY_, findQualityFiles::size, PixelGeomDetUnit::specificTopology(), mathSSE::sqrt(), SiStripDetId::stereo(), DetId::subdetId(), subdetID, GeomDet::surface(), TrajectoryStateOnSurface::surface(), StripSubdetector::TEC, StripSubdetector::TIB, StripSubdetector::TID, StripSubdetector::TOB, Surface::toGlobal(), GloballyPositioned< T >::toLocal(), parallelization::uint, LocalTrajectoryParameters::vector(), PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), PV3DBase< T, PVType, FrameType >::z(), zeroone, and zerozero.

Referenced by analyze().

                                                                              {
  typedef std::pair<const TrajectoryMeasurement*, const TrajectoryMeasurement*> Overlap;
  typedef vector<Overlap> OverlapContainer;
  ++overlapCounts_[0];

  OverlapContainer overlapHits;

  // quality cuts on trajectory
  // min. # hits / matched hits

  if (trajectory.foundHits() < minHitsCut_)
    return;
  if (ChiSquaredProbability((double)(trajectory.chiSquared()), (double)(trajectory.ndof(false))) < chi2ProbCut_)
    return;
  //
  // loop over measurements in the trajectory and calculate residuals
  //

  vector<TrajectoryMeasurement> measurements(trajectory.measurements());
  for (vector<TrajectoryMeasurement>::const_iterator itm = measurements.begin(); itm != measurements.end(); ++itm) {
    //
    // skip "invalid" (i.e. missing) hits
    //
    ConstRecHitPointer hit = itm->recHit();
    DetId id = hit->geographicalId();
    int layer(layerFromId(id, tTopo));
    int subDet = id.subdetId();

    if (!hit->isValid()) {
      edm::LogVerbatim("OverlapValidation") << "Invalid";
      continue;
    }
    if (barrelOnly_ && (subDet == StripSubdetector::TID || subDet == StripSubdetector::TEC))
      return;

    //edm::LogVerbatim("OverlapValidation")  << "Check " <<subDet << ", layer = " << layer<<" stereo: "<< ((subDet > 2)?(SiStripDetId(id).stereo()):2);
    //cout << "Check SubID " <<subDet << ", layer = " << layer<<" stereo: "<< ((subDet > 2)?(SiStripDetId(id).stereo()):2) << endl;

    //
    // check for overlap: same subdet-id && layer number for
    // two consecutive hits
    //
    ++overlapCounts_[1];
    if ((layer != -1) && (acceptLayer[subDet])) {
      for (vector<TrajectoryMeasurement>::const_iterator itmCompare = itm - 1;
           itmCompare >= measurements.begin() && itmCompare > itm - 4;
           --itmCompare) {
        DetId compareId = itmCompare->recHit()->geographicalId();

        if (subDet != compareId.subdetId() || layer != layerFromId(compareId, tTopo))
          break;
        if (!itmCompare->recHit()->isValid())
          continue;
        if ((subDet == PixelSubdetector::PixelBarrel || subDet == PixelSubdetector::PixelEndcap) ||
            (SiStripDetId(id).stereo() == SiStripDetId(compareId).stereo())) {
          overlapHits.push_back(std::make_pair(&(*itmCompare), &(*itm)));
          //edm::LogVerbatim("OverlapValidation") << "adding pair "<< ((subDet > 2)?(SiStripDetId(id).stereo()) : 2)
          //                 << " from layer = " << layer;
          //cout << "adding pair "<< ((subDet > 2)?(SiStripDetId(id).stereo()) : 2) << " from subDet = " << subDet << " and layer = " << layer;
          //cout << " \t"<<run_<< "\t"<<event_<<"\t";
          //cout << min(id.rawId(),compareId.rawId())<<"\t"<<max(id.rawId(),compareId.rawId())<<endl;
          if (SiStripDetId(id).glued() == id.rawId())
            edm::LogInfo("Overlaps") << "BAD GLUED: Have glued layer with id = " << id.rawId()
                                     << " and glued id = " << SiStripDetId(id).glued()
                                     << "  and stereo = " << SiStripDetId(id).stereo() << endl;
          if (SiStripDetId(compareId).glued() == compareId.rawId())
            edm::LogInfo("Overlaps") << "BAD GLUED: Have glued layer with id = " << compareId.rawId()
                                     << " and glued id = " << SiStripDetId(compareId).glued()
                                     << "  and stereo = " << SiStripDetId(compareId).stereo() << endl;
          break;
        }
      }
    }
  }

  //
  // Loop over all overlap pairs.
  //
  hitCounts_[0] = trajectory.foundHits();
  hitCounts_[1] = trajectory.lostHits();
  chi2_[0] = trajectory.chiSquared();
  chi2_[1] = trajectory.ndof(false);

  for (const auto& overlapHit : overlapHits) {
    //
    // create reference state @ module 1 (no info from overlap hits)
    //
    ++overlapCounts_[2];
    // backward predicted state at module 1
    TrajectoryStateOnSurface bwdPred1 = overlapHit.first->backwardPredictedState();
    if (!bwdPred1.isValid())
      continue;
    //cout << "momentum from backward predicted state = " << bwdPred1.globalMomentum().mag() << endl;
    // forward predicted state at module 2
    TrajectoryStateOnSurface fwdPred2 = overlapHit.second->forwardPredictedState();
    //cout << "momentum from forward predicted state = " << fwdPred2.globalMomentum().mag() << endl;
    if (!fwdPred2.isValid())
      continue;
    // extrapolate fwdPred2 to module 1
    TrajectoryStateOnSurface fwdPred2At1 = propagator.propagate(fwdPred2, bwdPred1.surface());
    if (!fwdPred2At1.isValid())
      continue;
    // combine fwdPred2At1 with bwdPred1 (ref. state, best estimate without hits 1 and 2)
    TrajectoryStateOnSurface comb1 = combiner_.combine(bwdPred1, fwdPred2At1);
    if (!comb1.isValid())
      continue;
    //
    // propagation of reference parameters to module 2
    //
    std::pair<TrajectoryStateOnSurface, double> tsosWithS = propagator.propagateWithPath(comb1, fwdPred2.surface());
    TrajectoryStateOnSurface comb1At2 = tsosWithS.first;
    if (!comb1At2.isValid())
      continue;
    //distance of propagation from one surface to the next==could cut here
    overlapPath_ = tsosWithS.second;
    if (abs(overlapPath_) > 15)
      continue;  //cut to remove hit pairs > 15 cm apart
    // global position on module 1
    GlobalPoint position = comb1.globalPosition();
    predictedPositions_[0][0] = position.x();
    predictedPositions_[1][0] = position.y();
    predictedPositions_[2][0] = position.z();
    momentum_ = comb1.globalMomentum().mag();
    //cout << "momentum from combination = " << momentum_ << endl;
    //cout << "magnetic field from TSOS = " << comb1.magneticField()->inTesla(position).mag() << endl;
    // local parameters and errors on module 1
    AlgebraicVector5 pars = comb1.localParameters().vector();
    AlgebraicSymMatrix55 errs = comb1.localError().matrix();
    for (int i = 0; i < 5; ++i) {
      predictedLocalParameters_[i][0] = pars[i];
      predictedLocalErrors_[i][0] = sqrt(errs(i, i));
    }
    // global position on module 2
    position = comb1At2.globalPosition();
    predictedPositions_[0][1] = position.x();
    predictedPositions_[1][1] = position.y();
    predictedPositions_[2][1] = position.z();
    // local parameters and errors on module 2
    pars = comb1At2.localParameters().vector();
    errs = comb1At2.localError().matrix();
    for (int i = 0; i < 5; ++i) {
      predictedLocalParameters_[i][1] = pars[i];
      predictedLocalErrors_[i][1] = sqrt(errs(i, i));
    }

    //print out local errors in X to check
    //cout << "Predicted local error in X at 1 = " << predictedLocalErrors_[3][0] << "   and predicted local error in X at 2 is = " <<  predictedLocalErrors_[3][1] << endl;
    //cout << "Predicted local error in Y at 1 = " << predictedLocalErrors_[4][0] << "   and predicted local error in Y at 2 is = " <<  predictedLocalErrors_[4][1] << endl;

    //
    // jacobians (local-to-global@1,global 1-2,global-to-local@2)
    //
    JacobianLocalToCurvilinear jacLocToCurv(comb1.surface(), comb1.localParameters(), *magField_);
    AnalyticalCurvilinearJacobian jacCurvToCurv(
        comb1.globalParameters(), comb1At2.globalPosition(), comb1At2.globalMomentum(), tsosWithS.second);
    JacobianCurvilinearToLocal jacCurvToLoc(comb1At2.surface(), comb1At2.localParameters(), *magField_);
    // combined jacobian local-1-to-local-2
    AlgebraicMatrix55 jacobian = jacLocToCurv.jacobian() * jacCurvToCurv.jacobian() * jacCurvToLoc.jacobian();
    // covariance on module 1
    AlgebraicSymMatrix55 covComb1 = comb1.localError().matrix();
    // variance and correlations for predicted local_x on modules 1 and 2
    double c00 = covComb1(3, 3);
    double c10(0.);
    double c11(0.);
    for (int i = 1; i < 5; ++i) {
      c10 += jacobian(3, i) * covComb1(i, 3);
      for (int j = 1; j < 5; ++j)
        c11 += jacobian(3, i) * covComb1(i, j) * jacobian(3, j);
    }
    // choose relative sign in order to minimize error on difference
    double diff = c00 - 2 * fabs(c10) + c11;
    diff = diff > 0 ? sqrt(diff) : -sqrt(-diff);
    predictedDeltaXError_ = diff;
    relativeXSign_ = c10 > 0 ? -1 : 1;
    //
    // now find variance and correlations for predicted local_y
    double c00Y = covComb1(4, 4);
    double c10Y(0.);
    double c11Y(0.);
    for (int i = 1; i < 5; ++i) {
      c10Y += jacobian(4, i) * covComb1(i, 4);
      for (int j = 1; j < 5; ++j)
        c11Y += jacobian(4, i) * covComb1(i, j) * jacobian(4, j);
    }
    double diffY = c00Y - 2 * fabs(c10Y) + c11Y;
    diffY = diffY > 0 ? sqrt(diffY) : -sqrt(-diffY);
    predictedDeltaYError_ = diffY;
    relativeYSign_ = c10Y > 0 ? -1 : 1;

    // information on modules and hits
    overlapIds_[0] = overlapHit.first->recHit()->geographicalId().rawId();
    overlapIds_[1] = overlapHit.second->recHit()->geographicalId().rawId();

    //added by Heshy and Jared
    moduleX_[0] = overlapHit.first->recHit()->det()->surface().position().x();
    moduleX_[1] = overlapHit.second->recHit()->det()->surface().position().x();
    moduleY_[0] = overlapHit.first->recHit()->det()->surface().position().y();
    moduleY_[1] = overlapHit.second->recHit()->det()->surface().position().y();
    moduleZ_[0] = overlapHit.first->recHit()->det()->surface().position().z();
    moduleZ_[1] = overlapHit.second->recHit()->det()->surface().position().z();
    subdetID = overlapHit.first->recHit()->geographicalId().subdetId();
    localxdotglobalphi_[0] = overlapHit.first->recHit()->det()->surface().toGlobal(onezero).phi() -
                             overlapHit.first->recHit()->det()->surface().toGlobal(zerozero).phi();
    localxdotglobalphi_[1] = overlapHit.second->recHit()->det()->surface().toGlobal(onezero).phi() -
                             overlapHit.second->recHit()->det()->surface().toGlobal(zerozero).phi();
    //added by Jason
    localxdotglobalr_[0] = overlapHit.first->recHit()->det()->surface().toGlobal(onezero).perp() -
                           overlapHit.first->recHit()->det()->surface().toGlobal(zerozero).perp();
    localxdotglobalr_[1] = overlapHit.second->recHit()->det()->surface().toGlobal(onezero).perp() -
                           overlapHit.second->recHit()->det()->surface().toGlobal(zerozero).perp();
    localxdotglobalz_[0] = overlapHit.first->recHit()->det()->surface().toGlobal(onezero).z() -
                           overlapHit.first->recHit()->det()->surface().toGlobal(zerozero).z();
    localxdotglobalz_[1] = overlapHit.second->recHit()->det()->surface().toGlobal(onezero).z() -
                           overlapHit.second->recHit()->det()->surface().toGlobal(zerozero).z();
    localxdotglobalx_[0] = overlapHit.first->recHit()->det()->surface().toGlobal(onezero).x() -
                           overlapHit.first->recHit()->det()->surface().toGlobal(zerozero).x();
    localxdotglobalx_[1] = overlapHit.second->recHit()->det()->surface().toGlobal(onezero).x() -
                           overlapHit.second->recHit()->det()->surface().toGlobal(zerozero).x();
    localxdotglobaly_[0] = overlapHit.first->recHit()->det()->surface().toGlobal(onezero).y() -
                           overlapHit.first->recHit()->det()->surface().toGlobal(zerozero).y();
    localxdotglobaly_[1] = overlapHit.second->recHit()->det()->surface().toGlobal(onezero).y() -
                           overlapHit.second->recHit()->det()->surface().toGlobal(zerozero).y();
    localydotglobalr_[0] = overlapHit.first->recHit()->det()->surface().toGlobal(zeroone).perp() -
                           overlapHit.first->recHit()->det()->surface().toGlobal(zerozero).perp();
    localydotglobalr_[1] = overlapHit.second->recHit()->det()->surface().toGlobal(zeroone).perp() -
                           overlapHit.second->recHit()->det()->surface().toGlobal(zerozero).perp();
    localydotglobalz_[0] = overlapHit.first->recHit()->det()->surface().toGlobal(zeroone).z() -
                           overlapHit.first->recHit()->det()->surface().toGlobal(zerozero).z();
    localydotglobalz_[1] = overlapHit.second->recHit()->det()->surface().toGlobal(zeroone).z() -
                           overlapHit.second->recHit()->det()->surface().toGlobal(zerozero).z();
    localydotglobalx_[0] = overlapHit.first->recHit()->det()->surface().toGlobal(zeroone).x() -
                           overlapHit.first->recHit()->det()->surface().toGlobal(zerozero).x();
    localydotglobalx_[1] = overlapHit.second->recHit()->det()->surface().toGlobal(zeroone).x() -
                           overlapHit.second->recHit()->det()->surface().toGlobal(zerozero).x();
    localydotglobaly_[0] = overlapHit.first->recHit()->det()->surface().toGlobal(zeroone).y() -
                           overlapHit.first->recHit()->det()->surface().toGlobal(zerozero).y();
    localydotglobaly_[1] = overlapHit.second->recHit()->det()->surface().toGlobal(zeroone).y() -
                           overlapHit.second->recHit()->det()->surface().toGlobal(zerozero).y();
    localydotglobalphi_[0] = overlapHit.first->recHit()->det()->surface().toGlobal(zeroone).phi() -
                             overlapHit.first->recHit()->det()->surface().toGlobal(zerozero).phi();
    localydotglobalphi_[1] = overlapHit.second->recHit()->det()->surface().toGlobal(zeroone).phi() -
                             overlapHit.second->recHit()->det()->surface().toGlobal(zerozero).phi();

    if (overlapHit.first->recHit()->geographicalId().subdetId() == StripSubdetector::TIB)
      layer_ = layerFromId(overlapHit.first->recHit()->geographicalId().rawId(), tTopo);
    else if (overlapHit.first->recHit()->geographicalId().subdetId() == StripSubdetector::TOB)
      layer_ = layerFromId(overlapHit.first->recHit()->geographicalId().rawId(), tTopo) + 4;
    else if (overlapHit.first->recHit()->geographicalId().subdetId() == StripSubdetector::TID)
      layer_ = layerFromId(overlapHit.first->recHit()->geographicalId().rawId(), tTopo) + 10;
    else if (overlapHit.first->recHit()->geographicalId().subdetId() == StripSubdetector::TEC)
      layer_ = layerFromId(overlapHit.first->recHit()->geographicalId().rawId(), tTopo) + 13;
    else if (overlapHit.first->recHit()->geographicalId().subdetId() == PixelSubdetector::PixelBarrel)
      layer_ = layerFromId(overlapHit.first->recHit()->geographicalId().rawId(), tTopo) + 20;
    else if (overlapHit.first->recHit()->geographicalId().subdetId() == PixelSubdetector::PixelEndcap)
      layer_ = layerFromId(overlapHit.first->recHit()->geographicalId().rawId(), tTopo) + 30;
    else
      layer_ = 99;

    if (overlapIds_[0] == SiStripDetId(overlapHit.first->recHit()->geographicalId()).glued())
      edm::LogWarning("Overlaps") << "BAD GLUED: First Id = " << overlapIds_[0] << " has glued = "
                                  << SiStripDetId(overlapHit.first->recHit()->geographicalId()).glued()
                                  << "  and stereo = "
                                  << SiStripDetId(overlapHit.first->recHit()->geographicalId()).stereo() << endl;
    if (overlapIds_[1] == SiStripDetId(overlapHit.second->recHit()->geographicalId()).glued())
      edm::LogWarning("Overlaps") << "BAD GLUED: Second Id = " << overlapIds_[1] << " has glued = "
                                  << SiStripDetId(overlapHit.second->recHit()->geographicalId()).glued()
                                  << "  and stereo = "
                                  << SiStripDetId(overlapHit.second->recHit()->geographicalId()).stereo() << endl;

    const TransientTrackingRecHit::ConstRecHitPointer firstRecHit = overlapHit.first->recHit();
    const TransientTrackingRecHit::ConstRecHitPointer secondRecHit = overlapHit.second->recHit();
    hitPositions_[0] = firstRecHit->localPosition().x();
    hitErrors_[0] = sqrt(firstRecHit->localPositionError().xx());
    hitPositions_[1] = secondRecHit->localPosition().x();
    hitErrors_[1] = sqrt(secondRecHit->localPositionError().xx());

    hitPositionsY_[0] = firstRecHit->localPosition().y();
    hitErrorsY_[0] = sqrt(firstRecHit->localPositionError().yy());
    hitPositionsY_[1] = secondRecHit->localPosition().y();
    hitErrorsY_[1] = sqrt(secondRecHit->localPositionError().yy());

    //cout << "printing local X hit position and error for the overlap hits. Hit 1 = " << hitPositions_[0] << "+-" << hitErrors_[0] << "  and hit 2 is "  << hitPositions_[1] << "+-" << hitErrors_[1] << endl;

    DetId id1 = overlapHit.first->recHit()->geographicalId();
    DetId id2 = overlapHit.second->recHit()->geographicalId();
    int layer1 = layerFromId(id1, tTopo);
    int subDet1 = id1.subdetId();
    int layer2 = layerFromId(id2, tTopo);
    int subDet2 = id2.subdetId();
    if (abs(hitPositions_[0]) > 5)
      edm::LogInfo("Overlaps") << "BAD: Bad hit position: Id = " << id1.rawId()
                               << " stereo = " << SiStripDetId(id1).stereo()
                               << "  glued = " << SiStripDetId(id1).glued() << " from subdet = " << subDet1
                               << " and layer = " << layer1 << endl;
    if (abs(hitPositions_[1]) > 5)
      edm::LogInfo("Overlaps") << "BAD: Bad hit position: Id = " << id2.rawId()
                               << " stereo = " << SiStripDetId(id2).stereo()
                               << "  glued = " << SiStripDetId(id2).glued() << " from subdet = " << subDet2
                               << " and layer = " << layer2 << endl;

    // get track momentum
    momentum_ = comb1.globalMomentum().mag();

    // get cluster size
    if (!(subDet1 == PixelSubdetector::PixelBarrel || subDet1 == PixelSubdetector::PixelEndcap)) {  //strip
      const TransientTrackingRecHit::ConstRecHitPointer thit1 = overlapHit.first->recHit();
      const SiStripRecHit1D* hit1 = dynamic_cast<const SiStripRecHit1D*>((*thit1).hit());
      if (hit1) {
        //check cluster width
        const SiStripRecHit1D::ClusterRef& cluster1 = hit1->cluster();
        clusterSize_[0] = (cluster1->amplitudes()).size();
        clusterWidthX_[0] = (cluster1->amplitudes()).size();
        clusterWidthY_[0] = -1;

        //check if cluster at edge of sensor
        uint16_t firstStrip = cluster1->firstStrip();
        uint16_t lastStrip = firstStrip + (cluster1->amplitudes()).size() - 1;
        unsigned short Nstrips;
        Nstrips = detInfo_.getNumberOfApvsAndStripLength(id1).first * 128;
        bool atEdge = false;
        if (firstStrip == 0 || lastStrip == (Nstrips - 1))
          atEdge = true;
        if (atEdge)
          edge_[0] = 1;
        else
          edge_[0] = -1;

        // get cluster total charge
        const auto& stripCharges = cluster1->amplitudes();
        uint16_t charge = 0;
        for (uint i = 0; i < stripCharges.size(); i++) {
          charge += stripCharges[i];
        }
        clusterCharge_[0] = charge;
      }

      const TransientTrackingRecHit::ConstRecHitPointer thit2 = overlapHit.second->recHit();
      const SiStripRecHit1D* hit2 = dynamic_cast<const SiStripRecHit1D*>((*thit2).hit());
      if (hit2) {
        const SiStripRecHit1D::ClusterRef& cluster2 = hit2->cluster();
        clusterSize_[1] = (cluster2->amplitudes()).size();
        clusterWidthX_[1] = (cluster2->amplitudes()).size();
        clusterWidthY_[1] = -1;

        uint16_t firstStrip = cluster2->firstStrip();
        uint16_t lastStrip = firstStrip + (cluster2->amplitudes()).size() - 1;
        unsigned short Nstrips;
        Nstrips = detInfo_.getNumberOfApvsAndStripLength(id2).first * 128;
        bool atEdge = false;
        if (firstStrip == 0 || lastStrip == (Nstrips - 1))
          atEdge = true;
        if (atEdge)
          edge_[1] = 1;
        else
          edge_[1] = -1;

        // get cluster total charge
        const auto& stripCharges = cluster2->amplitudes();
        uint16_t charge = 0;
        for (uint i = 0; i < stripCharges.size(); i++) {
          charge += stripCharges[i];
        }
        clusterCharge_[1] = charge;
      }
      //cout << "strip cluster size2 = " << clusterWidthX_[0] << "  and size 2 = " << clusterWidthX_[1] << endl;
    }

    if (subDet2 == PixelSubdetector::PixelBarrel || subDet2 == PixelSubdetector::PixelEndcap) {  //pixel

      const TransientTrackingRecHit::ConstRecHitPointer thit1 = overlapHit.first->recHit();
      const SiPixelRecHit* recHitPix1 = dynamic_cast<const SiPixelRecHit*>((*thit1).hit());
      if (recHitPix1) {
        // check for cluster size and width
        SiPixelRecHit::ClusterRef const& cluster1 = recHitPix1->cluster();

        clusterSize_[0] = cluster1->size();
        clusterWidthX_[0] = cluster1->sizeX();
        clusterWidthY_[0] = cluster1->sizeY();

        // check for cluster at edge
        const PixelGeomDetUnit* theGeomDet = dynamic_cast<const PixelGeomDetUnit*>((*trackerGeometry_).idToDet(id1));
        const PixelTopology* topol = (&(theGeomDet->specificTopology()));

        int minPixelRow = cluster1->minPixelRow();  //x
        int maxPixelRow = cluster1->maxPixelRow();
        int minPixelCol = cluster1->minPixelCol();  //y
        int maxPixelCol = cluster1->maxPixelCol();

        bool edgeHitX = (topol->isItEdgePixelInX(minPixelRow)) || (topol->isItEdgePixelInX(maxPixelRow));
        bool edgeHitY = (topol->isItEdgePixelInY(minPixelCol)) || (topol->isItEdgePixelInY(maxPixelCol));
        if (edgeHitX || edgeHitY)
          edge_[0] = 1;
        else
          edge_[0] = -1;

        clusterCharge_[0] = (uint)cluster1->charge();

      } else {
        edm::LogWarning("Overlaps") << "didn't find pixel cluster" << endl;
        continue;
      }

      const TransientTrackingRecHit::ConstRecHitPointer thit2 = overlapHit.second->recHit();
      const SiPixelRecHit* recHitPix2 = dynamic_cast<const SiPixelRecHit*>((*thit2).hit());
      if (recHitPix2) {
        SiPixelRecHit::ClusterRef const& cluster2 = recHitPix2->cluster();

        clusterSize_[1] = cluster2->size();
        clusterWidthX_[1] = cluster2->sizeX();
        clusterWidthY_[1] = cluster2->sizeY();
        //cout << "second pixel cluster is " << clusterSize_[1] << " pixels with x width = " << clusterWidthX_[1] << " and y width = " << clusterWidthY_[1] << endl;

        const PixelGeomDetUnit* theGeomDet = dynamic_cast<const PixelGeomDetUnit*>((*trackerGeometry_).idToDet(id2));
        const PixelTopology* topol = (&(theGeomDet->specificTopology()));

        int minPixelRow = cluster2->minPixelRow();  //x
        int maxPixelRow = cluster2->maxPixelRow();
        int minPixelCol = cluster2->minPixelCol();  //y
        int maxPixelCol = cluster2->maxPixelCol();

        bool edgeHitX = (topol->isItEdgePixelInX(minPixelRow)) || (topol->isItEdgePixelInX(maxPixelRow));
        bool edgeHitY = (topol->isItEdgePixelInY(minPixelCol)) || (topol->isItEdgePixelInY(maxPixelCol));
        if (edgeHitX || edgeHitY)
          edge_[1] = 1;
        else
          edge_[1] = -1;

        clusterCharge_[1] = (uint)cluster2->charge();

      } else {
        edm::LogWarning("Overlaps") << "didn't find pixel cluster" << endl;
        continue;
      }
    }

    //also check for edge pixels

    //try writing out the SimHit info (for MC only)
    if (doSimHit_) {
      std::vector<PSimHit> psimHits1;
      std::vector<PSimHit> psimHits2;
      //calculate layer
      DetId id = overlapHit.first->recHit()->geographicalId();
      int layer(-1);
      layer = layerFromId(id, tTopo);
      int subDet = id.subdetId();
      edm::LogVerbatim("OverlapValidation") << "Subdet = " << subDet << " ; layer = " << layer;

      psimHits1 = associator.associateHit(*(firstRecHit->hit()));
      edm::LogVerbatim("OverlapValidation") << "single hit ";
      edm::LogVerbatim("OverlapValidation") << "length of psimHits1: " << psimHits1.size();
      if (!psimHits1.empty()) {
        float closest_dist = 99999.9;
        std::vector<PSimHit>::const_iterator closest_simhit = psimHits1.begin();
        for (std::vector<PSimHit>::const_iterator m = psimHits1.begin(); m < psimHits1.end(); m++) {
          //find closest simHit to the recHit
          float simX = (*m).localPosition().x();
          float dist = fabs(simX - (overlapHit.first->recHit()->localPosition().x()));
          edm::LogVerbatim("OverlapValidation")
              << "simHit1 simX = " << simX << "   hitX = " << overlapHit.first->recHit()->localPosition().x()
              << "   distX = " << dist << "   layer = " << layer;
          if (dist < closest_dist) {
            //cout << "found newest closest dist for simhit1" << endl;
            closest_dist = dist;
            closest_simhit = m;
          }
        }
        //if glued layer, convert sim hit position to matchedhit surface
        //layer index from 1-4 for TIB, 1-6 for TOB
        // Are the sim hits on the glued layers or are they split???
        if (subDet > 2 && !SiStripDetId(id).glued()) {
          const GluedGeomDet* gluedDet =
              (const GluedGeomDet*)(*trackerGeometry_).idToDet((*firstRecHit).hit()->geographicalId());
          const StripGeomDetUnit* stripDet = (StripGeomDetUnit*)gluedDet->monoDet();
          GlobalPoint gp = stripDet->surface().toGlobal((*closest_simhit).localPosition());
          LocalPoint lp = gluedDet->surface().toLocal(gp);
          LocalVector localdirection = (*closest_simhit).localDirection();
          GlobalVector globaldirection = stripDet->surface().toGlobal(localdirection);
          LocalVector direction = gluedDet->surface().toLocal(globaldirection);
          float scale = -lp.z() / direction.z();
          LocalPoint projectedPos = lp + scale * direction;
          simHitPositions_[0] = projectedPos.x();
          edm::LogVerbatim("OverlapValidation") << "simhit position from matched layer = " << simHitPositions_[0];
          simHitPositionsY_[0] = projectedPos.y();
        } else {
          simHitPositions_[0] = (*closest_simhit).localPosition().x();
          simHitPositionsY_[0] = (*closest_simhit).localPosition().y();
          edm::LogVerbatim("OverlapValidation") << "simhit position from non-matched layer = " << simHitPositions_[0];
        }
        edm::LogVerbatim("OverlapValidation") << "hit position = " << hitPositions_[0];
      } else {
        simHitPositions_[0] = -99.;
        simHitPositionsY_[0] = -99.;
        //cout << " filling simHitX: " << -99 << endl;
      }

      psimHits2 = associator.associateHit(*(secondRecHit->hit()));
      if (!psimHits2.empty()) {
        float closest_dist = 99999.9;
        std::vector<PSimHit>::const_iterator closest_simhit = psimHits2.begin();
        for (std::vector<PSimHit>::const_iterator m = psimHits2.begin(); m < psimHits2.end(); m++) {
          float simX = (*m).localPosition().x();
          float dist = fabs(simX - (overlapHit.second->recHit()->localPosition().x()));
          if (dist < closest_dist) {
            closest_dist = dist;
            closest_simhit = m;
          }
        }
        //if glued layer, convert sim hit position to matchedhit surface
        // if no sim hits on matched layers then this section can be removed
        if (subDet > 2 && !SiStripDetId(id).glued()) {
          const GluedGeomDet* gluedDet =
              (const GluedGeomDet*)(*trackerGeometry_).idToDet((*secondRecHit).hit()->geographicalId());
          const StripGeomDetUnit* stripDet = (StripGeomDetUnit*)gluedDet->monoDet();
          GlobalPoint gp = stripDet->surface().toGlobal((*closest_simhit).localPosition());
          LocalPoint lp = gluedDet->surface().toLocal(gp);
          LocalVector localdirection = (*closest_simhit).localDirection();
          GlobalVector globaldirection = stripDet->surface().toGlobal(localdirection);
          LocalVector direction = gluedDet->surface().toLocal(globaldirection);
          float scale = -lp.z() / direction.z();
          LocalPoint projectedPos = lp + scale * direction;
          simHitPositions_[1] = projectedPos.x();
          simHitPositionsY_[1] = projectedPos.y();
        } else {
          simHitPositions_[1] = (*closest_simhit).localPosition().x();
          simHitPositionsY_[1] = (*closest_simhit).localPosition().y();
        }
      } else {
        simHitPositions_[1] = -99.;
        simHitPositionsY_[1] = -99.;
      }
    }
    rootTree_->Fill();
  }
}

endJob()

void OverlapValidation::endJob ( void  )

overrideprivatevirtual

Reimplemented from edm::one::EDAnalyzerBase.

Definition at line 897 of file OverlapValidation.cc.

References rootTree_.

Referenced by o2olib.O2ORunMgr::executeJob().

                               {
  if (rootTree_) {
    rootTree_->GetDirectory()->cd();
    rootTree_->Write();
    delete rootTree_;
  }
}

fillDescriptions()

void OverlapValidation::fillDescriptions ( edm::ConfigurationDescriptions &  descriptions )

static

Definition at line 273 of file OverlapValidation.cc.

References edm::ConfigurationDescriptions::addWithDefaultLabel(), submitPVResolutionJobs::desc, TrackerHitAssociator::fillPSetDescription(), and ProducerED_cfi::InputTag.

                                                                                   {
  edm::ParameterSetDescription desc;
  desc.setComment("Overlap Validation analyzer plugin.");
  TrackerHitAssociator::fillPSetDescription(desc);
  //desc.add<bool>("associateStrip",false);  // NB this comes from the fillPSetDescription
  desc.addUntracked<int>("compressionSettings", -1);
  desc.add<edm::InputTag>("trajectories", edm::InputTag("FinalTrackRefitter"));
  desc.add<bool>("barrelOnly", false);
  desc.add<bool>("usePXB", true);
  desc.add<bool>("usePXF", true);
  desc.add<bool>("useTIB", true);
  desc.add<bool>("useTOB", true);
  desc.add<bool>("useTID", true);
  desc.add<bool>("useTEC", true);
  descriptions.addWithDefaultLabel(desc);
}

layerFromId()

int OverlapValidation::layerFromId ( const DetId &  id, const TrackerTopology *const  tTopo  ) const

private

Definition at line 889 of file OverlapValidation.cc.

References nano_mu_digi_cff::layer, and TrackerAlignableId::typeAndLayerFromDetId().

Referenced by analyzeTrajectory().

                                                                                            {
  TrackerAlignableId aliid;
  std::pair<int, int> subdetandlayer = aliid.typeAndLayerFromDetId(id, tTopo);
  int layer = subdetandlayer.second;

  return layer;
}

Member Data Documentation

acceptLayer

vector<bool> OverlapValidation::acceptLayer

private

Definition at line 148 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

addExtraBranches_

const bool OverlapValidation::addExtraBranches_

private

Definition at line 120 of file OverlapValidation.cc.

Referenced by OverlapValidation().

barrelOnly_

bool OverlapValidation::barrelOnly_

private

Definition at line 151 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

chi2_

float OverlapValidation::chi2_[2]

private

Definition at line 127 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

chi2ProbCut_

const float OverlapValidation::chi2ProbCut_

private

Definition at line 122 of file OverlapValidation.cc.

Referenced by analyzeTrajectory().

clusterCharge_

uint OverlapValidation::clusterCharge_[2]

private

Definition at line 145 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

clusterSize_

float OverlapValidation::clusterSize_[2]

private

Definition at line 144 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

clusterWidthX_

float OverlapValidation::clusterWidthX_[2]

private

Definition at line 142 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

clusterWidthY_

float OverlapValidation::clusterWidthY_[2]

private

Definition at line 143 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

combiner_

TrajectoryStateCombiner OverlapValidation::combiner_

private

Definition at line 114 of file OverlapValidation.cc.

Referenced by analyzeTrajectory().

compressionSettings_

const int OverlapValidation::compressionSettings_

private

Definition at line 119 of file OverlapValidation.cc.

Referenced by OverlapValidation().

config_

edm::ParameterSet OverlapValidation::config_

private

Definition at line 107 of file OverlapValidation.cc.

Referenced by analyze().

detInfo_

SiStripDetInfo OverlapValidation::detInfo_

private

Definition at line 109 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

doSimHit_

bool OverlapValidation::doSimHit_

private

Definition at line 110 of file OverlapValidation.cc.

Referenced by analyze(), analyzeTrajectory(), and OverlapValidation().

edge_

int OverlapValidation::edge_[2]

private

Definition at line 146 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

event_

uint OverlapValidation::event_

private

Definition at line 150 of file OverlapValidation.cc.

Referenced by analyze(), and OverlapValidation().

FileInPath_

edm::FileInPath OverlapValidation::FileInPath_

private

Definition at line 118 of file OverlapValidation.cc.

Referenced by OverlapValidation().

geomToken_

const edm::ESGetToken<TrackerGeometry, TrackerDigiGeometryRecord> OverlapValidation::geomToken_

private

Definition at line 103 of file OverlapValidation.cc.

Referenced by analyze().

hitCounts_

unsigned short OverlapValidation::hitCounts_[2]

private

Definition at line 126 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

hitErrors_

float OverlapValidation::hitErrors_[2]

private

Definition at line 137 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

hitErrorsY_

float OverlapValidation::hitErrorsY_[2]

private

Definition at line 139 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

hitPositions_

float OverlapValidation::hitPositions_[2]

private

Definition at line 136 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

hitPositionsY_

float OverlapValidation::hitPositionsY_[2]

private

Definition at line 138 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

layer_

uint OverlapValidation::layer_

private

Definition at line 125 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

localxdotglobalphi_

float OverlapValidation::localxdotglobalphi_[2]

private

Definition at line 162 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

localxdotglobalr_

float OverlapValidation::localxdotglobalr_[2]

private

Definition at line 163 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

localxdotglobalx_

float OverlapValidation::localxdotglobalx_[2]

private

Definition at line 165 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

localxdotglobaly_

float OverlapValidation::localxdotglobaly_[2]

private

Definition at line 166 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

localxdotglobalz_

float OverlapValidation::localxdotglobalz_[2]

private

Definition at line 164 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

localydotglobalphi_

float OverlapValidation::localydotglobalphi_[2]

private

Definition at line 167 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

localydotglobalr_

float OverlapValidation::localydotglobalr_[2]

private

Definition at line 168 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

localydotglobalx_

float OverlapValidation::localydotglobalx_[2]

private

Definition at line 170 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

localydotglobaly_

float OverlapValidation::localydotglobaly_[2]

private

Definition at line 171 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

localydotglobalz_

float OverlapValidation::localydotglobalz_[2]

private

Definition at line 169 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

magField_

const MagneticField* OverlapValidation::magField_

private

Definition at line 112 of file OverlapValidation.cc.

Referenced by analyze(), and analyzeTrajectory().

magFieldToken_

const edm::ESGetToken<MagneticField, IdealMagneticFieldRecord> OverlapValidation::magFieldToken_

private

Definition at line 104 of file OverlapValidation.cc.

Referenced by analyze().

minHitsCut_

const int OverlapValidation::minHitsCut_

private

Definition at line 121 of file OverlapValidation.cc.

Referenced by analyzeTrajectory().

moduleX_

float OverlapValidation::moduleX_[2]

private

Definition at line 154 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

moduleY_

float OverlapValidation::moduleY_[2]

private

Definition at line 155 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

moduleZ_

float OverlapValidation::moduleZ_[2]

private

Definition at line 156 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

momentum_

float OverlapValidation::momentum_

private

Definition at line 149 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

onezero

const Point2DBase<float, LocalTag> OverlapValidation::onezero = Point2DBase<float, LocalTag>(1, 0)

private

Definition at line 159 of file OverlapValidation.cc.

Referenced by analyzeTrajectory().

overlapCounts_

int OverlapValidation::overlapCounts_[3]

private

Definition at line 115 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), OverlapValidation(), and ~OverlapValidation().

overlapIds_

unsigned int OverlapValidation::overlapIds_[2]

private

Definition at line 128 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

overlapPath_

float OverlapValidation::overlapPath_

private

Definition at line 124 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

predictedDeltaXError_

float OverlapValidation::predictedDeltaXError_

private

Definition at line 132 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

predictedDeltaYError_

float OverlapValidation::predictedDeltaYError_

private

Definition at line 133 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

predictedLocalErrors_

float OverlapValidation::predictedLocalErrors_[5][2]

private

Definition at line 131 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

predictedLocalParameters_

float OverlapValidation::predictedLocalParameters_[5][2]

private

Definition at line 130 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

predictedPositions_

float OverlapValidation::predictedPositions_[3][2]

private

Definition at line 129 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

relativeXSign_

char OverlapValidation::relativeXSign_

private

Definition at line 134 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

relativeYSign_

char OverlapValidation::relativeYSign_

private

Definition at line 135 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

rootTree_

TTree* OverlapValidation::rootTree_

private

Definition at line 117 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), endJob(), and OverlapValidation().

run_

uint OverlapValidation::run_

private

Definition at line 150 of file OverlapValidation.cc.

Referenced by analyze(), and OverlapValidation().

simHitPositions_

float OverlapValidation::simHitPositions_[2]

private

Definition at line 140 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

simHitPositionsY_

float OverlapValidation::simHitPositionsY_[2]

private

Definition at line 141 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

subdetID

int OverlapValidation::subdetID

private

Definition at line 157 of file OverlapValidation.cc.

Referenced by analyzeTrajectory(), and OverlapValidation().

topoToken_

const edm::ESGetToken<TrackerTopology, TrackerTopologyRcd> OverlapValidation::topoToken_

private

Definition at line 105 of file OverlapValidation.cc.

Referenced by analyze().

trackerGeometry_

const TrackerGeometry* OverlapValidation::trackerGeometry_

private

Definition at line 111 of file OverlapValidation.cc.

Referenced by analyze().

trajectoryTag_

edm::InputTag OverlapValidation::trajectoryTag_

private

Definition at line 108 of file OverlapValidation.cc.

Referenced by OverlapValidation().

trajectoryToken_

edm::EDGetTokenT<TrajectoryCollection> OverlapValidation::trajectoryToken_

private

Definition at line 90 of file OverlapValidation.cc.

Referenced by analyze(), and OverlapValidation().

zeroone

const Point2DBase<float, LocalTag> OverlapValidation::zeroone = Point2DBase<float, LocalTag>(0, 1)

private

Definition at line 160 of file OverlapValidation.cc.

Referenced by analyzeTrajectory().

zerozero

const Point2DBase<float, LocalTag> OverlapValidation::zerozero = Point2DBase<float, LocalTag>(0, 0)

private

Definition at line 158 of file OverlapValidation.cc.

Referenced by analyzeTrajectory().