adding eta:phi tracks and clusters histograms

[u/mrichter/AliRoot.git] / MUON / AliMUONVTrackReconstructor.cxx

/**************************************************************************
 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
 *                                                                        *
 * Author: The ALICE Off-line Project.                                    *
 * Contributors are mentioned in the code where appropriate.              *
 *                                                                        *
 * Permission to use, copy, modify and distribute this software and its   *
 * documentation strictly for non-commercial purposes is hereby granted   *
 * without fee, provided that the above copyright notice appears in all   *
 * copies and that both the copyright notice and this permission notice   *
 * appear in the supporting documentation. The authors make no claims     *
 * about the suitability of this software for any purpose. It is          *
 * provided "as is" without express or implied warranty.                  *
 **************************************************************************/

/* $Id$ */

//-----------------------------------------------------------------------------
/// \class AliMUONVTrackReconstructor
/// Virtual MUON track reconstructor in ALICE (class renamed from AliMUONEventReconstructor)
///
/// This class contains as data a pointer to the array of reconstructed tracks
///
/// It contains as methods, among others:
/// * EventReconstruct to build the muon tracks
/// * EventReconstructTrigger to build the trigger tracks
/// * ValidateTracksWithTrigger to match tracker/trigger tracks
///
/// Several options and adjustable parameters are available for both KALMAN and ORIGINAL
/// tracking algorithms. They can be changed through the AliMUONRecoParam object
/// set in the reconstruction macro or read from the CDB
/// (see methods in AliMUONRecoParam.h file for details)
///
/// Main parameters and options are:
/// - *fgkSigmaToCutForTracking* : quality cut used to select new clusters to be
///   attached to the track candidate and to select good tracks.
/// - *fgkMakeTrackCandidatesFast* : if this flag is set to 'true', the track candidates
///   are made assuming linear propagation between stations 4 and 5.
/// - *fgkTrackAllTracks* : according to the value of this flag, in case that several
///   new clusters pass the quality cut, either we consider all the possibilities
///   (duplicating tracks) or we attach only the best cluster.
/// - *fgkRecoverTracks* : if this flag is set to 'true', we try to recover the tracks
///   lost during the tracking by removing the worst of the 2 clusters attached in the
///   previous station.
/// - *fgkImproveTracks* : if this flag is set to 'true', we try to improve the quality
///   of the tracks at the end of the tracking by removing clusters that do not pass
///   new quality cut (the track is removed is it does not contain enough cluster anymore).
/// - *fgkComplementTracks* : if this flag is set to 'true', we try to improve the quality
///   of the tracks at the end of the tracking by adding potentially missing clusters
///   (we may have 2 clusters in the same chamber because of the overlapping of detection
///   elements, which is not handle by the tracking algorithm).
/// - *fgkSigmaToCutForImprovement* : quality cut used when we try to improve the
///   quality of the tracks.
///
///  \author Philippe Pillot
//-----------------------------------------------------------------------------

#include "AliMUONVTrackReconstructor.h"

#include "AliMUONConstants.h"
#include "AliMUONObjectPair.h"
#include "AliMUONTriggerTrack.h"
#include "AliMUONTriggerCircuit.h"
#include "AliMUONLocalTrigger.h"
#include "AliMUONGlobalTrigger.h"
#include "AliMUONTrack.h"
#include "AliMUONTrackParam.h"
#include "AliMUONTrackExtrap.h"
#include "AliMUONTrackHitPattern.h"
#include "AliMUONVTrackStore.h"
#include "AliMUONVClusterStore.h"
#include "AliMUONVCluster.h"
#include "AliMUONVClusterServer.h"
#include "AliMUONVTriggerStore.h"
#include "AliMUONVTriggerTrackStore.h"
#include "AliMUONRecoParam.h"
#include "AliMUONGeometryTransformer.h"
#include "AliMUONVDigit.h"

#include "AliMpDEManager.h"
#include "AliMpArea.h"

#include "AliMpDDLStore.h"
#include "AliMpVSegmentation.h"
#include "AliMpSegmentation.h"
#include "AliMpPad.h"
#include "AliMpDetElement.h"
#include "AliMpCathodType.h"

#include "AliLog.h"
#include "AliCodeTimer.h"
#include "AliTracker.h"

#include <TClonesArray.h>
#include <TMath.h>
#include <TMatrixD.h>
#include <TVector2.h>

#include <Riostream.h>

using std::cout;
using std::endl;
/// \cond CLASSIMP
ClassImp(AliMUONVTrackReconstructor) // Class implementation in ROOT context
/// \endcond

  //__________________________________________________________________________
AliMUONVTrackReconstructor::AliMUONVTrackReconstructor(const AliMUONRecoParam* recoParam,
                                                       AliMUONVClusterServer* clusterServer,
                                                       const AliMUONGeometryTransformer* transformer)
: TObject(),
fRecTracksPtr(0x0),
fNRecTracks(0),
fClusterServer(clusterServer),
fkRecoParam(recoParam),
fkTransformer(transformer),
fMaxMCSAngle2(0x0)
{
  /// Constructor for class AliMUONVTrackReconstructor
  /// WARNING: if clusterServer=0x0, no clusterization will be possible at this level
  
  // Memory allocation for the TClonesArray of reconstructed tracks
  fRecTracksPtr = new TClonesArray("AliMUONTrack", 100);
  
  // set the magnetic field for track extrapolations
  AliMUONTrackExtrap::SetField();
  
  // set the maximum MCS angle in chamber from the minimum acceptable momentum
  AliMUONTrackParam param;
  Double_t inverseBendingP = (GetRecoParam()->GetMinBendingMomentum() > 0.) ? 1./GetRecoParam()->GetMinBendingMomentum() : 1.;
  param.SetInverseBendingMomentum(inverseBendingP);
  fMaxMCSAngle2 = new Double_t [AliMUONConstants::NTrackingCh()];
  for (Int_t iCh=0; iCh<AliMUONConstants::NTrackingCh(); iCh++)
    fMaxMCSAngle2[iCh] = AliMUONTrackExtrap::GetMCSAngle2(param, AliMUONConstants::ChamberThicknessInX0(iCh), 1.);
  
}

  //__________________________________________________________________________
AliMUONVTrackReconstructor::~AliMUONVTrackReconstructor()
{
  /// Destructor for class AliMUONVTrackReconstructor
  delete fRecTracksPtr;
  delete[] fMaxMCSAngle2;
}

  //__________________________________________________________________________
void AliMUONVTrackReconstructor::ResetTracks()
{
  /// To reset the TClonesArray of reconstructed tracks
  if (fRecTracksPtr) fRecTracksPtr->Clear("C");
  fNRecTracks = 0;
  return;
}

  //__________________________________________________________________________
void AliMUONVTrackReconstructor::EventReconstruct(AliMUONVClusterStore& clusterStore, AliMUONVTrackStore& trackStore)
{
  /// To reconstruct one event
  AliDebug(1,"");
  AliCodeTimerAuto("",0);
  
  // Reset array of tracks
  ResetTracks();
  
  // Look for candidates from clusters in stations(1..) 4 and 5 (abort in case of failure)
  if (!MakeTrackCandidates(clusterStore)) return;
  
  // Look for extra candidates from clusters in stations(1..) 4 and 5 (abort in case of failure)
  if (GetRecoParam()->MakeMoreTrackCandidates()) {
    if (!MakeMoreTrackCandidates(clusterStore)) return;
  }
  
  // Stop tracking if no candidate found
  if (fRecTracksPtr->GetEntriesFast() == 0) return;
  
  // Follow tracks in stations(1..) 3, 2 and 1 (abort in case of failure)
  if (!FollowTracks(clusterStore)) return;
  
  // Complement the reconstructed tracks
  if (GetRecoParam()->ComplementTracks()) {
    if (ComplementTracks(clusterStore)) RemoveIdenticalTracks();
  }
  
  // Improve the reconstructed tracks
  if (GetRecoParam()->ImproveTracks()) ImproveTracks();
  
  // Remove connected tracks
  RemoveConnectedTracks(3, 4, kFALSE);
  RemoveConnectedTracks(2, 2, kFALSE);
  if (GetRecoParam()->RemoveConnectedTracksInSt12()) RemoveConnectedTracks(0, 1, kFALSE);
  
  // Fill AliMUONTrack data members
  Finalize();
  if (!GetRecoParam()->RemoveConnectedTracksInSt12()) TagConnectedTracks(0, 1, kTRUE);
  
  // Make sure there is no bad track left
  RemoveBadTracks();
  
  // Refit the reconstructed tracks with a different resolution for mono-cathod clusters
  if (GetRecoParam()->DiscardMonoCathodClusters()) DiscardMonoCathodClusters();
  
  // Add tracks to MUON data container 
  for (Int_t i=0; i<fNRecTracks; ++i)
  {
    AliMUONTrack * track = (AliMUONTrack*) fRecTracksPtr->At(i);
    track->SetUniqueID(i+1);
    trackStore.Add(*track);
  }
  
}

//__________________________________________________________________________
Bool_t AliMUONVTrackReconstructor::IsAcceptable(AliMUONTrackParam &trackParam)
{
  /// Return kTRUE if the track is within given limits on momentum/angle/origin
  
  const TMatrixD& kParamCov = trackParam.GetCovariances();
  Int_t chamber = trackParam.GetClusterPtr()->GetChamberId();
  Double_t z = trackParam.GetZ();
  Double_t sigmaCut = GetRecoParam()->GetSigmaCutForTracking();
  
  // MCS dipersion
  Double_t angleMCS2 = 0.;
  Double_t impactMCS2 = 0.;
  if (AliMUONTrackExtrap::IsFieldON() && chamber < 6) {
    
    // track momentum is known
    for (Int_t iCh=0; iCh<=chamber; iCh++) {
      Double_t localMCS2 = AliMUONTrackExtrap::GetMCSAngle2(trackParam, AliMUONConstants::ChamberThicknessInX0(iCh), 1.);
      angleMCS2 += localMCS2;
      impactMCS2 += AliMUONConstants::DefaultChamberZ(chamber) * AliMUONConstants::DefaultChamberZ(chamber) * localMCS2;
    }
    
  } else {
    
    // track momentum is unknown
    for (Int_t iCh=0; iCh<=chamber; iCh++) {
      angleMCS2 += fMaxMCSAngle2[iCh];
      impactMCS2 += AliMUONConstants::DefaultChamberZ(chamber) * AliMUONConstants::DefaultChamberZ(chamber) * fMaxMCSAngle2[iCh];
    }
    
  }
  
  // ------ track selection in non bending direction ------
  if (GetRecoParam()->SelectOnTrackSlope()) {
    
    // check if non bending slope is within tolerances
    Double_t nonBendingSlopeErr = TMath::Sqrt(kParamCov(1,1) + angleMCS2);
    if ((TMath::Abs(trackParam.GetNonBendingSlope()) - sigmaCut * nonBendingSlopeErr) > GetRecoParam()->GetMaxNonBendingSlope()) return kFALSE;
    
  } else {
    
    // or check if non bending impact parameter is within tolerances
    Double_t nonBendingImpactParam = TMath::Abs(trackParam.GetNonBendingCoor() - z * trackParam.GetNonBendingSlope());
    Double_t nonBendingImpactParamErr = TMath::Sqrt(kParamCov(0,0) + z * z * kParamCov(1,1) - 2. * z * kParamCov(0,1) + impactMCS2);
    if ((nonBendingImpactParam - sigmaCut * nonBendingImpactParamErr) > (3. * GetRecoParam()->GetNonBendingVertexDispersion())) return kFALSE;
    
  }
  
  // ------ track selection in bending direction ------
  if (AliMUONTrackExtrap::IsFieldON()) { // depending whether the field is ON or OFF
    
    // check if bending momentum is within tolerances
    Double_t bendingMomentum = TMath::Abs(1. / trackParam.GetInverseBendingMomentum());
    Double_t bendingMomentumErr = TMath::Sqrt(kParamCov(4,4)) * bendingMomentum * bendingMomentum;
    if (chamber < 6 && (bendingMomentum + sigmaCut * bendingMomentumErr) < GetRecoParam()->GetMinBendingMomentum()) return kFALSE;
    else if ((bendingMomentum + 3. * bendingMomentumErr) < GetRecoParam()->GetMinBendingMomentum()) return kFALSE;
    
  } else {
    
    if (GetRecoParam()->SelectOnTrackSlope()) {
      
      // check if bending slope is within tolerances
      Double_t bendingSlopeErr = TMath::Sqrt(kParamCov(3,3) + angleMCS2);
      if ((TMath::Abs(trackParam.GetBendingSlope()) - sigmaCut * bendingSlopeErr) > GetRecoParam()->GetMaxBendingSlope()) return kFALSE;
      
    } else {
      
      // or check if bending impact parameter is within tolerances
      Double_t bendingImpactParam = TMath::Abs(trackParam.GetBendingCoor() - z * trackParam.GetBendingSlope());
      Double_t bendingImpactParamErr = TMath::Sqrt(kParamCov(2,2) + z * z * kParamCov(3,3) - 2. * z * kParamCov(2,3) + impactMCS2);
      if ((bendingImpactParam - sigmaCut * bendingImpactParamErr) > (3. * GetRecoParam()->GetBendingVertexDispersion())) return kFALSE;
      
    }
    
  }
  
  return kTRUE;
  
}

//__________________________________________________________________________
TClonesArray* AliMUONVTrackReconstructor::MakeSegmentsBetweenChambers(const AliMUONVClusterStore& clusterStore, Int_t ch1, Int_t ch2)
{
  /// To make the list of segments from the list of clusters in the 2 given chambers.
  /// Return a TClonesArray of new segments (segments made in a previous call of this function are removed).
  AliDebug(1,Form("Enter MakeSegmentsBetweenChambers (1..) %d-%d", ch1+1, ch2+1));
  AliCodeTimerAuto("",0);
  
  AliMUONVCluster *cluster1, *cluster2;
  AliMUONObjectPair *segment;
  Double_t z1 = 0., z2 = 0., dZ = 0.;
  Double_t nonBendingSlope = 0., nonBendingSlopeErr = 0., nonBendingImpactParam = 0., nonBendingImpactParamErr = 0.;
  Double_t bendingSlope = 0., bendingSlopeErr = 0., bendingImpactParam = 0., bendingImpactParamErr = 0., bendingImpactParamErr2 = 0.;
  Double_t bendingMomentum = 0., bendingMomentumErr = 0.;
  Double_t bendingVertexDispersion2 = GetRecoParam()->GetBendingVertexDispersion() * GetRecoParam()->GetBendingVertexDispersion();
  Double_t angleMCS2 = 0.; // maximum angular dispersion**2 due to MCS in chamber
  Double_t impactMCS2 = 0.; // maximum impact parameter dispersion**2 due to MCS in chamber
  for (Int_t iCh=0; iCh<=ch1; iCh++) {
    angleMCS2 += fMaxMCSAngle2[iCh];
    impactMCS2 += AliMUONConstants::DefaultChamberZ(iCh) * AliMUONConstants::DefaultChamberZ(iCh) * fMaxMCSAngle2[iCh];
  }
  Double_t sigmaCut = GetRecoParam()->GetSigmaCutForTracking();
  
  // Create iterators to loop over clusters in both chambers
  TIter nextInCh1(clusterStore.CreateChamberIterator(ch1,ch1));
  TIter nextInCh2(clusterStore.CreateChamberIterator(ch2,ch2));
  
  // list of segments
  static TClonesArray *segments = new TClonesArray("AliMUONObjectPair", 100);
  segments->Clear("C");
  
  // Loop over clusters in the first chamber of the station
  while ( ( cluster1 = static_cast<AliMUONVCluster*>(nextInCh1()) ) ) {
    z1 = cluster1->GetZ();
    
    // reset cluster iterator of chamber 2
    nextInCh2.Reset();
    
    // Loop over clusters in the second chamber of the station
    while ( ( cluster2 = static_cast<AliMUONVCluster*>(nextInCh2()) ) ) {
      z2 = cluster2->GetZ();
      dZ = z1 - z2;
      
      // ------ track selection in non bending direction ------
      nonBendingSlope = (cluster1->GetX() - cluster2->GetX()) / dZ;
      if (GetRecoParam()->SelectOnTrackSlope()) {
        
        // check if non bending slope is within tolerances
        nonBendingSlopeErr = TMath::Sqrt((cluster1->GetErrX2() + cluster2->GetErrX2()) / dZ / dZ + angleMCS2);
        if ((TMath::Abs(nonBendingSlope) - sigmaCut * nonBendingSlopeErr) > GetRecoParam()->GetMaxNonBendingSlope()) continue;
        
      } else {
        
        // or check if non bending impact parameter is within tolerances
        nonBendingImpactParam = TMath::Abs(cluster1->GetX() - cluster1->GetZ() * nonBendingSlope);
        nonBendingImpactParamErr = TMath::Sqrt((z1 * z1 * cluster2->GetErrX2() + z2 * z2 * cluster1->GetErrX2()) / dZ / dZ + impactMCS2);
        if ((nonBendingImpactParam - sigmaCut * nonBendingImpactParamErr) > (3. * GetRecoParam()->GetNonBendingVertexDispersion())) continue;
        
      }
      
      // ------ track selection in bending direction ------
      bendingSlope = (cluster1->GetY() - cluster2->GetY()) / dZ;
      if (AliMUONTrackExtrap::IsFieldON()) { // depending whether the field is ON or OFF
        
        // check if bending momentum is within tolerances
        bendingImpactParam = cluster1->GetY() - cluster1->GetZ() * bendingSlope;
        bendingImpactParamErr2 = (z1 * z1 * cluster2->GetErrY2() + z2 * z2 * cluster1->GetErrY2()) / dZ / dZ + impactMCS2;
        bendingMomentum = TMath::Abs(AliMUONTrackExtrap::GetBendingMomentumFromImpactParam(bendingImpactParam));
        bendingMomentumErr = TMath::Sqrt((bendingVertexDispersion2 + bendingImpactParamErr2) /
                                         bendingImpactParam / bendingImpactParam + 0.01) * bendingMomentum;
        if ((bendingMomentum + 3. * bendingMomentumErr) < GetRecoParam()->GetMinBendingMomentum()) continue;
        
      } else {
        
        if (GetRecoParam()->SelectOnTrackSlope()) {
          
          // check if bending slope is within tolerances
          bendingSlopeErr = TMath::Sqrt((cluster1->GetErrY2() + cluster2->GetErrY2()) / dZ / dZ + angleMCS2);
          if ((TMath::Abs(bendingSlope) - sigmaCut * bendingSlopeErr) > GetRecoParam()->GetMaxBendingSlope()) continue;
          
        } else {
          
          // or check if bending impact parameter is within tolerances
          bendingImpactParam = TMath::Abs(cluster1->GetY() - cluster1->GetZ() * bendingSlope);
          bendingImpactParamErr = TMath::Sqrt((z1 * z1 * cluster2->GetErrY2() + z2 * z2 * cluster1->GetErrY2()) / dZ / dZ + impactMCS2);
          if ((bendingImpactParam - sigmaCut * bendingImpactParamErr) > (3. * GetRecoParam()->GetBendingVertexDispersion())) continue;
          
        }
        
      }
      
      // make new segment
      segment = new ((*segments)[segments->GetLast()+1]) AliMUONObjectPair(cluster1, cluster2, kFALSE, kFALSE);
      
      // Printout for debug
      if (AliLog::GetGlobalDebugLevel() > 1) {
        cout << "segmentIndex(0...): " << segments->GetLast() << endl;
        segment->Dump();
        cout << "Cluster in first chamber" << endl;
        cluster1->Print();
        cout << "Cluster in second chamber" << endl;
        cluster2->Print();
      }
      
    }
    
  }
  
  // Printout for debug
  AliDebug(1,Form("chambers%d-%d: NSegments =  %d ", ch1+1, ch2+1, segments->GetEntriesFast()));
  
  return segments;
}

  //__________________________________________________________________________
void AliMUONVTrackReconstructor::RemoveUsedSegments(TClonesArray& segments)
{
  /// To remove pairs of clusters already attached to a track
  AliDebug(1,"Enter RemoveUsedSegments");
  Int_t nSegments = segments.GetEntriesFast();
  Int_t nTracks = fRecTracksPtr->GetEntriesFast();
  AliMUONObjectPair *segment;
  AliMUONTrack *track;
  AliMUONVCluster *cluster, *cluster1, *cluster2;
  Bool_t foundCluster1, foundCluster2, removeSegment;
  
  // Loop over segments
  for (Int_t iSegment=0; iSegment<nSegments; iSegment++) {
    segment = (AliMUONObjectPair*) segments.UncheckedAt(iSegment);
    
    cluster1 = (AliMUONVCluster*) segment->First();
    cluster2 = (AliMUONVCluster*) segment->Second();
    removeSegment = kFALSE;
    
    // Loop over tracks
    for (Int_t iTrack = 0; iTrack < nTracks; iTrack++) {
      track = (AliMUONTrack*) fRecTracksPtr->UncheckedAt(iTrack);
      
      // skip empty slot
      if (!track) continue;
      
      foundCluster1 = kFALSE;
      foundCluster2 = kFALSE;
      
      // Loop over clusters
      Int_t nClusters = track->GetNClusters();
      for (Int_t iCluster = 0; iCluster < nClusters; iCluster++) {
        cluster = ((AliMUONTrackParam*) track->GetTrackParamAtCluster()->UncheckedAt(iCluster))->GetClusterPtr();
        
        // check if both clusters are in that track
        if (cluster == cluster1) foundCluster1 = kTRUE;
        else if (cluster == cluster2) foundCluster2 = kTRUE;
        
        if (foundCluster1 && foundCluster2) {
          removeSegment = kTRUE;
          break;
        }
        
      }
      
      if (removeSegment) break;
      
    }
    
    if (removeSegment) segments.RemoveAt(iSegment);
      
  }
  
  segments.Compress();
  
  // Printout for debug
  AliDebug(1,Form("NSegments =  %d ", segments.GetEntriesFast()));
}

  //__________________________________________________________________________
void AliMUONVTrackReconstructor::RemoveIdenticalTracks()
{
  /// To remove identical tracks:
  /// Tracks are considered identical if they have all their clusters in common.
  /// One keeps the track with the larger number of clusters if need be
  AliMUONTrack *track1, *track2;
  Int_t nTracks = fRecTracksPtr->GetEntriesFast();
  Int_t clustersInCommon, nClusters1, nClusters2;
  // Loop over first track of the pair
  for (Int_t iTrack1 = 0; iTrack1 < nTracks; iTrack1++) {
    track1 = (AliMUONTrack*) fRecTracksPtr->UncheckedAt(iTrack1);
    // skip empty slot
    if (!track1) continue;
    nClusters1 = track1->GetNClusters();
    // Loop over second track of the pair
    for (Int_t iTrack2 = iTrack1+1; iTrack2 < nTracks; iTrack2++) {
      track2 = (AliMUONTrack*) fRecTracksPtr->UncheckedAt(iTrack2);
      // skip empty slot
      if (!track2) continue;
      nClusters2 = track2->GetNClusters();
      // number of clusters in common between two tracks
      clustersInCommon = track1->ClustersInCommon(track2);
      // check for identical tracks
      if ((clustersInCommon == nClusters1) || (clustersInCommon == nClusters2)) {
        // decide which track to remove
        if (nClusters2 > nClusters1) {
          // remove track1 and continue the first loop with the track next to track1
          fRecTracksPtr->RemoveAt(iTrack1);
          fNRecTracks--;
          break;
        } else {
          // remove track2 and continue the second loop with the track next to track2
          fRecTracksPtr->RemoveAt(iTrack2);
          fNRecTracks--;
        }
      }
    } // track2
  } // track1
  fRecTracksPtr->Compress(); // this is essential to retrieve the TClonesArray afterwards
}

  //__________________________________________________________________________
void AliMUONVTrackReconstructor::RemoveDoubleTracks()
{
  /// To remove double tracks:
  /// Tracks are considered identical if more than half of the clusters of the track
  /// which has the smaller number of clusters are in common with the other track.
  /// Among two identical tracks, one keeps the track with the larger number of clusters
  /// or, if these numbers are equal, the track with the minimum chi2.
  AliMUONTrack *track1, *track2;
  Int_t nTracks = fRecTracksPtr->GetEntriesFast();
  Int_t clustersInCommon2, nClusters1, nClusters2;
  // Loop over first track of the pair
  for (Int_t iTrack1 = 0; iTrack1 < nTracks; iTrack1++) {
    track1 = (AliMUONTrack*) fRecTracksPtr->UncheckedAt(iTrack1);
    // skip empty slot
    if (!track1) continue;
    nClusters1 = track1->GetNClusters();
    // Loop over second track of the pair
    for (Int_t iTrack2 = iTrack1+1; iTrack2 < nTracks; iTrack2++) {
      track2 = (AliMUONTrack*) fRecTracksPtr->UncheckedAt(iTrack2);
      // skip empty slot
      if (!track2) continue;
      nClusters2 = track2->GetNClusters();
      // number of clusters in common between two tracks
      clustersInCommon2 = 2 * track1->ClustersInCommon(track2);
      // check for identical tracks
      if (clustersInCommon2 > nClusters1 || clustersInCommon2 > nClusters2) {
        // decide which track to remove
        if ((nClusters1 > nClusters2) || ((nClusters1 == nClusters2) && (track1->GetGlobalChi2() <= track2->GetGlobalChi2()))) {
          // remove track2 and continue the second loop with the track next to track2
          fRecTracksPtr->RemoveAt(iTrack2);
          fNRecTracks--;
        } else {
          // else remove track1 and continue the first loop with the track next to track1
          fRecTracksPtr->RemoveAt(iTrack1);
          fNRecTracks--;
          break;
        }
      }
    } // track2
  } // track1
  fRecTracksPtr->Compress(); // this is essential to retrieve the TClonesArray afterwards
}

  //__________________________________________________________________________
void AliMUONVTrackReconstructor::RemoveBadTracks()
{
  /// Remove tracks for which a problem occured somewhere during the tracking
  
  AliMUONTrack *track, *nextTrack;
  Bool_t trackRemoved = kFALSE;
  
  track = (AliMUONTrack*) fRecTracksPtr->First();
  while (track) {
    
    nextTrack = (AliMUONTrack*) fRecTracksPtr->After(track);
    
    if (track->GetGlobalChi2() >= AliMUONTrack::MaxChi2()) {
      AliWarning("problem occured somewhere during the tracking --> discard track");
      fRecTracksPtr->Remove(track);
      fNRecTracks--;
      trackRemoved = kTRUE;
    }
    
    track = nextTrack;
    
  }
  
  // compress array of tracks if needed
  if (trackRemoved) fRecTracksPtr->Compress();
  
}

  //__________________________________________________________________________
void AliMUONVTrackReconstructor::RemoveConnectedTracks(Int_t stMin, Int_t stMax, Bool_t all)
{
  /// Find and remove tracks sharing 1 cluster or more in station(s) [stMin, stMax].
  /// For each couple of connected tracks, one removes the one with the smallest
  /// number of clusters or with the highest chi2 value in case of equality.
  /// If all=kTRUE: both tracks are removed.
  
  // tag the tracks to be removed
  TagConnectedTracks(stMin, stMax, all);
  
  // remove them
  Int_t nTracks = fRecTracksPtr->GetEntriesFast();
  for (Int_t i = 0; i < nTracks; i++) {
    if (((AliMUONTrack*) fRecTracksPtr->UncheckedAt(i))->IsConnected()) {
      fRecTracksPtr->RemoveAt(i);
      fNRecTracks--;
    }
  }
  
  // remove holes in the array if any
  fRecTracksPtr->Compress();
}

  //__________________________________________________________________________
void AliMUONVTrackReconstructor::TagConnectedTracks(Int_t stMin, Int_t stMax, Bool_t all)
{
  /// Find and tag tracks sharing 1 cluster or more in station(s) [stMin, stMax].
  /// For each couple of connected tracks, one tags the one with the smallest
  /// number of clusters or with the highest chi2 value in case of equality.
  /// If all=kTRUE: both tracks are tagged.
  
  AliMUONTrack *track1, *track2;
  Int_t nClusters1, nClusters2;
  Int_t nTracks = fRecTracksPtr->GetEntriesFast();
  
  // reset the tags
  for (Int_t i = 0; i < nTracks; i++) ((AliMUONTrack*) fRecTracksPtr->UncheckedAt(i))->Connected(kFALSE);
    
  // Loop over first track of the pair
  for (Int_t iTrack1 = 0; iTrack1 < nTracks; iTrack1++) {
    track1 = (AliMUONTrack*) fRecTracksPtr->UncheckedAt(iTrack1);
    
    // Loop over second track of the pair
    for (Int_t iTrack2 = iTrack1+1; iTrack2 < nTracks; iTrack2++) {
      track2 = (AliMUONTrack*) fRecTracksPtr->UncheckedAt(iTrack2);
      
      // check for connected tracks and tag them
      if (track1->ClustersInCommon(track2, stMin, stMax) > 0) {
        
        if (all) {
          
          // tag both tracks
          track1->Connected();
          track2->Connected();
          
        } else {
          
          // tag only the worst track
          nClusters1 = track1->GetNClusters();
          nClusters2 = track2->GetNClusters();
          if ((nClusters1 > nClusters2) || ((nClusters1 == nClusters2) && (track1->GetGlobalChi2() <= track2->GetGlobalChi2()))) {
            track2->Connected();
          } else {
            track1->Connected();
          }
          
        }
        
      }
      
    }
    
  }
  
}

  //__________________________________________________________________________
void AliMUONVTrackReconstructor::AskForNewClustersInChamber(const AliMUONTrackParam &trackParam,
                                                            AliMUONVClusterStore& clusterStore, Int_t chamber)
{
  /// Ask the clustering to reconstruct new clusters around the track candidate position
  
  // check if the current chamber is useable
  if (!fClusterServer || !GetRecoParam()->UseChamber(chamber)) return;
  
  // maximum distance between the center of the chamber and a detection element
  // (accounting for the inclination of the chamber)
  static const Double_t kMaxDZ = 15.; // 15 cm
  
  // extrapolate track parameters to the chamber
  AliMUONTrackParam extrapTrackParam(trackParam);
  if (!AliMUONTrackExtrap::ExtrapToZCov(&extrapTrackParam, AliMUONConstants::DefaultChamberZ(chamber))) return;
  
  // build the searching area using the track and chamber resolutions and the maximum-distance-to-track value
  const TMatrixD& kParamCov = extrapTrackParam.GetCovariances();
  Double_t errX2 = kParamCov(0,0) + kMaxDZ * kMaxDZ * kParamCov(1,1) + 2. * kMaxDZ * TMath::Abs(kParamCov(0,1)) +
                   GetRecoParam()->GetDefaultNonBendingReso(chamber) * GetRecoParam()->GetDefaultNonBendingReso(chamber);
  Double_t errY2 = kParamCov(2,2) + kMaxDZ * kMaxDZ * kParamCov(3,3) + 2. * kMaxDZ * TMath::Abs(kParamCov(2,3)) +
                   GetRecoParam()->GetDefaultBendingReso(chamber) * GetRecoParam()->GetDefaultBendingReso(chamber);
  Double_t dX = TMath::Abs(trackParam.GetNonBendingSlope()) * kMaxDZ +
                GetRecoParam()->GetMaxNonBendingDistanceToTrack() +
                GetRecoParam()->GetSigmaCutForTracking() * TMath::Sqrt(2. * errX2);
  Double_t dY = TMath::Abs(trackParam.GetBendingSlope()) * kMaxDZ +
                GetRecoParam()->GetMaxBendingDistanceToTrack() +
                GetRecoParam()->GetSigmaCutForTracking() * TMath::Sqrt(2. * errY2);
  AliMpArea area(extrapTrackParam.GetNonBendingCoor(), 
                 extrapTrackParam.GetBendingCoor(),
                 dX, dY);
  
  // ask to cluterize in the given area of the given chamber
  fClusterServer->Clusterize(chamber, clusterStore, area, GetRecoParam());
  
}

  //__________________________________________________________________________
void AliMUONVTrackReconstructor::AskForNewClustersInStation(const AliMUONTrackParam &trackParam,
                                                            AliMUONVClusterStore& clusterStore, Int_t station)
{
  /// Ask the clustering to reconstruct new clusters around the track candidate position
  /// in the 2 chambers of the given station
  AskForNewClustersInChamber(trackParam, clusterStore, 2*station+1);
  AskForNewClustersInChamber(trackParam, clusterStore, 2*station);
}

  //__________________________________________________________________________
Double_t AliMUONVTrackReconstructor::TryOneCluster(const AliMUONTrackParam &trackParam, AliMUONVCluster* cluster,
                                                   AliMUONTrackParam &trackParamAtCluster, Bool_t updatePropagator)
{
/// Test the compatibility between the track and the cluster (using trackParam's covariance matrix):
/// return the corresponding Chi2
/// return trackParamAtCluster
  
  // extrapolate track parameters and covariances at the z position of the tested cluster
  // and set pointer to cluster into trackParamAtCluster
  trackParamAtCluster = trackParam;
  trackParamAtCluster.SetClusterPtr(cluster);
  if (!AliMUONTrackExtrap::ExtrapToZCov(&trackParamAtCluster, cluster->GetZ(), updatePropagator))
    return 2.*AliMUONTrack::MaxChi2();
  
  // Set differences between trackParam and cluster in the bending and non bending directions
  Double_t dX = cluster->GetX() - trackParamAtCluster.GetNonBendingCoor();
  Double_t dY = cluster->GetY() - trackParamAtCluster.GetBendingCoor();
  
  // Calculate errors and covariances
  const TMatrixD& kParamCov = trackParamAtCluster.GetCovariances();
  Double_t sigmaX2 = kParamCov(0,0) + cluster->GetErrX2();
  Double_t sigmaY2 = kParamCov(2,2) + cluster->GetErrY2();
  Double_t covXY   = kParamCov(0,2);
  Double_t det     = sigmaX2 * sigmaY2 - covXY * covXY;
  
  // Compute chi2
  if (det == 0.) return 2.*AliMUONTrack::MaxChi2();
  return (dX * dX * sigmaY2 + dY * dY * sigmaX2 - 2. * dX * dY * covXY) / det;
  
}

  //__________________________________________________________________________
Bool_t AliMUONVTrackReconstructor::TryOneClusterFast(const AliMUONTrackParam &trackParam, const AliMUONVCluster* cluster)
{
/// Test the compatibility between the track and the cluster
/// given the track and cluster resolutions + the maximum-distance-to-track value
/// and assuming linear propagation of the track:
/// return kTRUE if they are compatibles
  
  Double_t dZ = cluster->GetZ() - trackParam.GetZ();
  Double_t dX = cluster->GetX() - (trackParam.GetNonBendingCoor() + trackParam.GetNonBendingSlope() * dZ);
  Double_t dY = cluster->GetY() - (trackParam.GetBendingCoor() + trackParam.GetBendingSlope() * dZ);
  const TMatrixD& kParamCov = trackParam.GetCovariances();
  Double_t errX2 = kParamCov(0,0) + dZ * dZ * kParamCov(1,1) + 2. * dZ * kParamCov(0,1) + cluster->GetErrX2();
  Double_t errY2 = kParamCov(2,2) + dZ * dZ * kParamCov(3,3) + 2. * dZ * kParamCov(2,3) + cluster->GetErrY2();

  Double_t dXmax = GetRecoParam()->GetSigmaCutForTracking() * TMath::Sqrt(2. * errX2) +
                   GetRecoParam()->GetMaxNonBendingDistanceToTrack();
  Double_t dYmax = GetRecoParam()->GetSigmaCutForTracking() * TMath::Sqrt(2. * errY2) +
                   GetRecoParam()->GetMaxBendingDistanceToTrack();
  
  if (TMath::Abs(dX) > dXmax || TMath::Abs(dY) > dYmax) return kFALSE;
  
  return kTRUE;
  
}

  //__________________________________________________________________________
Double_t AliMUONVTrackReconstructor::TryTwoClustersFast(const AliMUONTrackParam &trackParamAtCluster1, AliMUONVCluster* cluster2,
                                                        AliMUONTrackParam &trackParamAtCluster2)
{
/// Test the compatibility between the track and the 2 clusters together (using trackParam's covariance matrix)
/// assuming linear propagation between the two clusters:
/// return the corresponding Chi2 accounting for covariances between the 2 clusters
/// return trackParamAtCluster2
  
  // extrapolate linearly track parameters and covariances at the z position of the second cluster
  trackParamAtCluster2 = trackParamAtCluster1;
  AliMUONTrackExtrap::LinearExtrapToZCov(&trackParamAtCluster2, cluster2->GetZ());
  
  // set pointer to cluster2 into trackParamAtCluster2
  trackParamAtCluster2.SetClusterPtr(cluster2);
  
  // Set differences between track and clusters in the bending and non bending directions
  AliMUONVCluster* cluster1 = trackParamAtCluster1.GetClusterPtr();
  Double_t dX1 = cluster1->GetX() - trackParamAtCluster1.GetNonBendingCoor();
  Double_t dX2 = cluster2->GetX() - trackParamAtCluster2.GetNonBendingCoor();
  Double_t dY1 = cluster1->GetY() - trackParamAtCluster1.GetBendingCoor();
  Double_t dY2 = cluster2->GetY() - trackParamAtCluster2.GetBendingCoor();
  
  // Calculate errors and covariances
  const TMatrixD& kParamCov1 = trackParamAtCluster1.GetCovariances();
  const TMatrixD& kParamCov2 = trackParamAtCluster2.GetCovariances();
  Double_t dZ = trackParamAtCluster2.GetZ() - trackParamAtCluster1.GetZ();
  Double_t sigma2X1 = kParamCov1(0,0) + cluster1->GetErrX2();
  Double_t sigma2X2 = kParamCov2(0,0) + cluster2->GetErrX2();
  Double_t covX1X2  = kParamCov1(0,0) + dZ * kParamCov1(0,1);
  Double_t sigma2Y1 = kParamCov1(2,2) + cluster1->GetErrY2();
  Double_t sigma2Y2 = kParamCov2(2,2) + cluster2->GetErrY2();
  Double_t covY1Y2  = kParamCov1(2,2) + dZ * kParamCov1(2,3);
  
  // Compute chi2
  Double_t detX = sigma2X1 * sigma2X2 - covX1X2 * covX1X2;
  Double_t detY = sigma2Y1 * sigma2Y2 - covY1Y2 * covY1Y2;
  if (detX == 0. || detY == 0.) return 2.*AliMUONTrack::MaxChi2();
  return   (dX1 * dX1 * sigma2X2 + dX2 * dX2 * sigma2X1 - 2. * dX1 * dX2 * covX1X2) / detX
         + (dY1 * dY1 * sigma2Y2 + dY2 * dY2 * sigma2Y1 - 2. * dY1 * dY2 * covY1Y2) / detY;
  
}

  //__________________________________________________________________________
Bool_t AliMUONVTrackReconstructor::FollowLinearTrackInChamber(AliMUONTrack &trackCandidate, const AliMUONVClusterStore& clusterStore,
                                                              Int_t nextChamber)
{
  /// Follow trackCandidate in chamber(0..) nextChamber assuming linear propagation, and search for compatible cluster(s)
  /// Keep all possibilities or only the best one(s) according to the flag fgkTrackAllTracks:
  /// kTRUE:  duplicate "trackCandidate" if there are several possibilities and add the new tracks at the end of
  ///         fRecTracksPtr to avoid conficts with other track candidates at this current stage of the tracking procedure.
  ///         Remove the obsolete "trackCandidate" at the end.
  /// kFALSE: add only the best cluster(s) to the "trackCandidate". Try to add a couple of clusters in priority.
  /// return kTRUE if new cluster(s) have been found (otherwise return kFALSE)
  AliDebug(1,Form("Enter FollowLinearTrackInChamber(1..) %d", nextChamber+1));
  
  Double_t chi2WithOneCluster = AliMUONTrack::MaxChi2();
  Double_t maxChi2WithOneCluster = 2. * GetRecoParam()->GetSigmaCutForTracking() *
                                        GetRecoParam()->GetSigmaCutForTracking(); // 2 because 2 quantities in chi2
  Double_t bestChi2WithOneCluster = maxChi2WithOneCluster;
  Bool_t foundOneCluster = kFALSE;
  AliMUONTrack *newTrack = 0x0;
  AliMUONVCluster *cluster;
  AliMUONTrackParam trackParam;
  AliMUONTrackParam extrapTrackParamAtCluster;
  AliMUONTrackParam bestTrackParamAtCluster;
  
  // Get track parameters according to the propagation direction
  if (nextChamber > 7) trackParam = *(AliMUONTrackParam*)trackCandidate.GetTrackParamAtCluster()->Last();
  else trackParam = *(AliMUONTrackParam*)trackCandidate.GetTrackParamAtCluster()->First();
  
  // Printout for debuging
  if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 2) || (AliLog::GetGlobalDebugLevel() >= 2)) {
    cout<<endl<<"Track parameters and covariances at first cluster:"<<endl;
    trackParam.GetParameters().Print();
    trackParam.GetCovariances().Print();
  }
  
  // Add MCS effect
  AliMUONTrackExtrap::AddMCSEffect(&trackParam,AliMUONConstants::ChamberThicknessInX0(trackParam.GetClusterPtr()->GetChamberId()),-1.);
  
  // Printout for debuging
  if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 1) || (AliLog::GetGlobalDebugLevel() >= 1)) {
    cout << "FollowLinearTrackInChamber: look for cluster in chamber(1..): " << nextChamber+1 << endl;
  }
  
  // Create iterators to loop over clusters in chamber
  TIter next(clusterStore.CreateChamberIterator(nextChamber,nextChamber));
  
  // look for candidates in chamber
  while ( ( cluster = static_cast<AliMUONVCluster*>(next()) ) ) {
    
    // try to add the current cluster fast
    if (!TryOneClusterFast(trackParam, cluster)) continue;
    
    // try to add the current cluster accuratly
    extrapTrackParamAtCluster = trackParam;
    AliMUONTrackExtrap::LinearExtrapToZCov(&extrapTrackParamAtCluster, cluster->GetZ());
    chi2WithOneCluster = TryOneCluster(extrapTrackParamAtCluster, cluster, extrapTrackParamAtCluster);
    
    // if good chi2 then consider to add cluster
    if (chi2WithOneCluster < maxChi2WithOneCluster) {
      foundOneCluster = kTRUE;
      
      // Printout for debuging
      if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 1) || (AliLog::GetGlobalDebugLevel() >= 1)) {
        cout << "FollowLinearTrackInChamber: found one cluster in chamber(1..): " << nextChamber+1
        << " (Chi2 = " << chi2WithOneCluster << ")" << endl;
        cluster->Print();
      }
      
      if (GetRecoParam()->TrackAllTracks()) {
        // copy trackCandidate into a new track put at the end of fRecTracksPtr and add the new cluster
        newTrack = new ((*fRecTracksPtr)[fRecTracksPtr->GetLast()+1]) AliMUONTrack(trackCandidate);
        if (GetRecoParam()->RequestStation(nextChamber/2))
          extrapTrackParamAtCluster.SetRemovable(kFALSE);
        else extrapTrackParamAtCluster.SetRemovable(kTRUE);
        newTrack->AddTrackParamAtCluster(extrapTrackParamAtCluster,*cluster);
        newTrack->SetGlobalChi2(trackCandidate.GetGlobalChi2()+chi2WithOneCluster);
        fNRecTracks++;
        
        // Printout for debuging
        if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 1) || (AliLog::GetGlobalDebugLevel() >= 1)) {
          cout << "FollowLinearTrackInChamber: added one cluster in chamber(1..): " << nextChamber+1 << endl;
          if (AliLog::GetGlobalDebugLevel() >= 3) newTrack->RecursiveDump();
        }
        
      } else if (chi2WithOneCluster < bestChi2WithOneCluster) {
        // keep track of the best cluster
        bestChi2WithOneCluster = chi2WithOneCluster;
        bestTrackParamAtCluster = extrapTrackParamAtCluster;
      }
      
    }
    
  }
  
  // fill out the best track if required else clean up the fRecTracksPtr array
  if (!GetRecoParam()->TrackAllTracks()) {
    if (foundOneCluster) {
      if (GetRecoParam()->RequestStation(nextChamber/2))
        bestTrackParamAtCluster.SetRemovable(kFALSE);
      else bestTrackParamAtCluster.SetRemovable(kTRUE);
      trackCandidate.AddTrackParamAtCluster(bestTrackParamAtCluster,*(bestTrackParamAtCluster.GetClusterPtr()));
      trackCandidate.SetGlobalChi2(trackCandidate.GetGlobalChi2()+bestChi2WithOneCluster);
      
      // Printout for debuging
      if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 1) || (AliLog::GetGlobalDebugLevel() >= 1)) {
        cout << "FollowLinearTrackInChamber: added the best cluster in chamber(1..): " << bestTrackParamAtCluster.GetClusterPtr()->GetChamberId()+1 << endl;
        if (AliLog::GetGlobalDebugLevel() >= 3) newTrack->RecursiveDump();
      }
      
    } else return kFALSE;
    
  } else if (foundOneCluster) {
    
    // remove obsolete track
    fRecTracksPtr->Remove(&trackCandidate);
    fNRecTracks--;
    
  } else return kFALSE;
  
  return kTRUE;
  
}

//__________________________________________________________________________
Bool_t AliMUONVTrackReconstructor::FollowLinearTrackInStation(AliMUONTrack &trackCandidate, const AliMUONVClusterStore& clusterStore,
                                                              Int_t nextStation)
{
  /// Follow trackCandidate in station(0..) nextStation assuming linear propagation, and search for compatible cluster(s)
  /// Keep all possibilities or only the best one(s) according to the flag fgkTrackAllTracks:
  /// kTRUE:  duplicate "trackCandidate" if there are several possibilities and add the new tracks at the end of
  ///         fRecTracksPtr to avoid conficts with other track candidates at this current stage of the tracking procedure.
  ///         Remove the obsolete "trackCandidate" at the end.
  /// kFALSE: add only the best cluster(s) to the "trackCandidate". Try to add a couple of clusters in priority.
  /// return kTRUE if new cluster(s) have been found (otherwise return kFALSE)
  AliDebug(1,Form("Enter FollowLinearTrackInStation(1..) %d", nextStation+1));
  
  // Order the chamber according to the propagation direction (tracking starts with chamber 2):
  // - nextStation == station(1...) 5 => forward propagation
  // - nextStation < station(1...) 5 => backward propagation
  Int_t ch1, ch2;
  if (nextStation==4) {
    ch1 = 2*nextStation+1;
    ch2 = 2*nextStation;
  } else {
    ch1 = 2*nextStation;
    ch2 = 2*nextStation+1;
  }
  
  Double_t chi2WithOneCluster = AliMUONTrack::MaxChi2();
  Double_t chi2WithTwoClusters = AliMUONTrack::MaxChi2();
  Double_t maxChi2WithOneCluster = 2. * GetRecoParam()->GetSigmaCutForTracking() *
                                        GetRecoParam()->GetSigmaCutForTracking(); // 2 because 2 quantities in chi2
  Double_t maxChi2WithTwoClusters = 4. * GetRecoParam()->GetSigmaCutForTracking() *
                                         GetRecoParam()->GetSigmaCutForTracking(); // 4 because 4 quantities in chi2
  Double_t bestChi2WithOneCluster = maxChi2WithOneCluster;
  Double_t bestChi2WithTwoClusters = maxChi2WithTwoClusters;
  Bool_t foundOneCluster = kFALSE;
  Bool_t foundTwoClusters = kFALSE;
  AliMUONTrack *newTrack = 0x0;
  AliMUONVCluster *clusterCh1, *clusterCh2;
  AliMUONTrackParam trackParam;
  AliMUONTrackParam extrapTrackParamAtCluster1;
  AliMUONTrackParam extrapTrackParamAtCluster2;
  AliMUONTrackParam bestTrackParamAtCluster1;
  AliMUONTrackParam bestTrackParamAtCluster2;
  
  Int_t nClusters = clusterStore.GetSize();
  Bool_t *clusterCh1Used = new Bool_t[nClusters];
  for (Int_t i = 0; i < nClusters; i++) clusterCh1Used[i] = kFALSE;
  Int_t iCluster1;
  
  // Get track parameters according to the propagation direction
  if (nextStation==4) trackParam = *(AliMUONTrackParam*)trackCandidate.GetTrackParamAtCluster()->Last();
  else trackParam = *(AliMUONTrackParam*)trackCandidate.GetTrackParamAtCluster()->First();
  
  // Printout for debuging
  if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 2) || (AliLog::GetGlobalDebugLevel() >= 2)) {
    cout<<endl<<"Track parameters and covariances at first cluster:"<<endl;
    trackParam.GetParameters().Print();
    trackParam.GetCovariances().Print();
  }
  
  // Add MCS effect
  AliMUONTrackExtrap::AddMCSEffect(&trackParam,AliMUONConstants::ChamberThicknessInX0(trackParam.GetClusterPtr()->GetChamberId()),-1.);
  
  // Printout for debuging
  if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 1) || (AliLog::GetGlobalDebugLevel() >= 1)) {
    cout << "FollowLinearTrackInStation: look for clusters in chamber(1..): " << ch2+1 << endl;
  }
  
  // Create iterators to loop over clusters in both chambers
  TIter nextInCh1(clusterStore.CreateChamberIterator(ch1,ch1));
  TIter nextInCh2(clusterStore.CreateChamberIterator(ch2,ch2));
  
  // look for candidates in chamber 2
  while ( ( clusterCh2 = static_cast<AliMUONVCluster*>(nextInCh2()) ) ) {
    
    // try to add the current cluster fast
    if (!TryOneClusterFast(trackParam, clusterCh2)) continue;
    
    // try to add the current cluster accuratly
    extrapTrackParamAtCluster2 = trackParam;
    AliMUONTrackExtrap::LinearExtrapToZCov(&extrapTrackParamAtCluster2, clusterCh2->GetZ());
    chi2WithOneCluster = TryOneCluster(extrapTrackParamAtCluster2, clusterCh2, extrapTrackParamAtCluster2);
    
    // if good chi2 then try to attach a cluster in the other chamber too
    if (chi2WithOneCluster < maxChi2WithOneCluster) {
      Bool_t foundSecondCluster = kFALSE;
      
      // Printout for debuging
      if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 1) || (AliLog::GetGlobalDebugLevel() >= 1)) {
        cout << "FollowLinearTrackInStation: found one cluster in chamber(1..): " << ch2+1
             << " (Chi2 = " << chi2WithOneCluster << ")" << endl;
        clusterCh2->Print();
        cout << "                      look for second clusters in chamber(1..): " << ch1+1 << " ..." << endl;
      }
      
      // add MCS effect
      AliMUONTrackExtrap::AddMCSEffect(&extrapTrackParamAtCluster2,AliMUONConstants::ChamberThicknessInX0(ch2),-1.);
      
      // reset cluster iterator of chamber 1
      nextInCh1.Reset();
      iCluster1 = -1;
      
      // look for second candidates in chamber 1
      while ( ( clusterCh1 = static_cast<AliMUONVCluster*>(nextInCh1()) ) ) {
        iCluster1++;
        
        // try to add the current cluster fast
        if (!TryOneClusterFast(extrapTrackParamAtCluster2, clusterCh1)) continue;
        
        // try to add the current cluster in addition to the one found in the previous chamber
        chi2WithTwoClusters = TryTwoClustersFast(extrapTrackParamAtCluster2, clusterCh1, extrapTrackParamAtCluster1);
        
        // if good chi2 then consider to add the 2 clusters to the "trackCandidate"
        if (chi2WithTwoClusters < maxChi2WithTwoClusters) {
          foundSecondCluster = kTRUE;
          foundTwoClusters = kTRUE;
          
          // Printout for debuging
          if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 1) || (AliLog::GetGlobalDebugLevel() >= 1)) {
            cout << "FollowLinearTrackInStation: found one cluster in chamber(1..): " << ch1+1
                 << " (Chi2 = " << chi2WithTwoClusters << ")" << endl;
            clusterCh1->Print();
          }
          
          if (GetRecoParam()->TrackAllTracks()) {
            // copy trackCandidate into a new track put at the end of fRecTracksPtr and add the new clusters
            newTrack = new ((*fRecTracksPtr)[fRecTracksPtr->GetLast()+1]) AliMUONTrack(trackCandidate);
            extrapTrackParamAtCluster1.SetRemovable(kTRUE);
            newTrack->AddTrackParamAtCluster(extrapTrackParamAtCluster1,*clusterCh1);
            extrapTrackParamAtCluster2.SetRemovable(kTRUE);
            newTrack->AddTrackParamAtCluster(extrapTrackParamAtCluster2,*clusterCh2);
            newTrack->SetGlobalChi2(newTrack->GetGlobalChi2()+chi2WithTwoClusters);
            fNRecTracks++;
            
            // Tag clusterCh1 as used
            clusterCh1Used[iCluster1] = kTRUE;
            
            // Printout for debuging
            if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 1) || (AliLog::GetGlobalDebugLevel() >= 1)) {
              cout << "FollowLinearTrackInStation: added two clusters in station(1..): " << nextStation+1 << endl;
              if (AliLog::GetGlobalDebugLevel() >= 3) newTrack->RecursiveDump();
            }
            
          } else if (chi2WithTwoClusters < bestChi2WithTwoClusters) {
            // keep track of the best couple of clusters
            bestChi2WithTwoClusters = chi2WithTwoClusters;
            bestTrackParamAtCluster1 = extrapTrackParamAtCluster1;
            bestTrackParamAtCluster2 = extrapTrackParamAtCluster2;
          }
          
        }
        
      }
      
      // if no cluster found in chamber1 then consider to add clusterCh2 only
      if (!foundSecondCluster) {
        foundOneCluster = kTRUE;
        
        if (GetRecoParam()->TrackAllTracks()) {
          // copy trackCandidate into a new track put at the end of fRecTracksPtr and add the new cluster
          newTrack = new ((*fRecTracksPtr)[fRecTracksPtr->GetLast()+1]) AliMUONTrack(trackCandidate);
          if (GetRecoParam()->RequestStation(nextStation))
            extrapTrackParamAtCluster2.SetRemovable(kFALSE);
          else extrapTrackParamAtCluster2.SetRemovable(kTRUE);
          newTrack->AddTrackParamAtCluster(extrapTrackParamAtCluster2,*clusterCh2);
          newTrack->SetGlobalChi2(newTrack->GetGlobalChi2()+chi2WithOneCluster);
          fNRecTracks++;
          
          // Printout for debuging
          if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 1) || (AliLog::GetGlobalDebugLevel() >= 1)) {
            cout << "FollowLinearTrackInStation: added one cluster in chamber(1..): " << ch2+1 << endl;
            if (AliLog::GetGlobalDebugLevel() >= 3) newTrack->RecursiveDump();
          }
          
        } else if (!foundTwoClusters && chi2WithOneCluster < bestChi2WithOneCluster) {
          // keep track of the best cluster except if a couple of clusters has already been found
          bestChi2WithOneCluster = chi2WithOneCluster;
          bestTrackParamAtCluster1 = extrapTrackParamAtCluster2;
        }
        
      }
      
    }
    
  }
  
  // look for candidates in chamber 1 not already attached to a track
  // if we want to keep all possible tracks or if no good couple of clusters has been found
  if (GetRecoParam()->TrackAllTracks() || !foundTwoClusters) {
    
    // Printout for debuging
    if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 1) || (AliLog::GetGlobalDebugLevel() >= 1)) {
      cout << "FollowLinearTrackInStation: look for single cluster in chamber(1..): " << ch1+1 << endl;
    }
    
    //Extrapolate trackCandidate to chamber "ch2"
    AliMUONTrackExtrap::LinearExtrapToZCov(&trackParam, AliMUONConstants::DefaultChamberZ(ch2));
    
    // add MCS effect for next step
    AliMUONTrackExtrap::AddMCSEffect(&trackParam,AliMUONConstants::ChamberThicknessInX0(ch2),-1.);
    
    // reset cluster iterator of chamber 1
    nextInCh1.Reset();
    iCluster1 = -1;
    
    // look for second candidates in chamber 1
    while ( ( clusterCh1 = static_cast<AliMUONVCluster*>(nextInCh1()) ) ) {
      iCluster1++;
      
      if (clusterCh1Used[iCluster1]) continue; // Skip clusters already used
      
      // try to add the current cluster fast
      if (!TryOneClusterFast(trackParam, clusterCh1)) continue;
      
      // try to add the current cluster accuratly
      extrapTrackParamAtCluster1 = trackParam;
      AliMUONTrackExtrap::LinearExtrapToZCov(&extrapTrackParamAtCluster1, clusterCh1->GetZ());
      chi2WithOneCluster = TryOneCluster(extrapTrackParamAtCluster1, clusterCh1, extrapTrackParamAtCluster1);
      
      // if good chi2 then consider to add clusterCh1
      // We do not try to attach a cluster in the other chamber too since it has already been done above
      if (chi2WithOneCluster < maxChi2WithOneCluster) {
        foundOneCluster = kTRUE;
        
        // Printout for debuging
        if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 1) || (AliLog::GetGlobalDebugLevel() >= 1)) {
          cout << "FollowLinearTrackInStation: found one cluster in chamber(1..): " << ch1+1
               << " (Chi2 = " << chi2WithOneCluster << ")" << endl;
          clusterCh1->Print();
        }
        
        if (GetRecoParam()->TrackAllTracks()) {
          // copy trackCandidate into a new track put at the end of fRecTracksPtr and add the new cluster
          newTrack = new ((*fRecTracksPtr)[fRecTracksPtr->GetLast()+1]) AliMUONTrack(trackCandidate);
          if (GetRecoParam()->RequestStation(nextStation))
            extrapTrackParamAtCluster1.SetRemovable(kFALSE);
          else extrapTrackParamAtCluster1.SetRemovable(kTRUE);
          newTrack->AddTrackParamAtCluster(extrapTrackParamAtCluster1,*clusterCh1);
          newTrack->SetGlobalChi2(newTrack->GetGlobalChi2()+chi2WithOneCluster);
          fNRecTracks++;
          
          // Printout for debuging
          if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 1) || (AliLog::GetGlobalDebugLevel() >= 1)) {
            cout << "FollowLinearTrackInStation: added one cluster in chamber(1..): " << ch1+1 << endl;
            if (AliLog::GetGlobalDebugLevel() >= 3) newTrack->RecursiveDump();
          }
          
        } else if (chi2WithOneCluster < bestChi2WithOneCluster) {
          // keep track of the best cluster except if a couple of clusters has already been found
          bestChi2WithOneCluster = chi2WithOneCluster;
          bestTrackParamAtCluster1 = extrapTrackParamAtCluster1;
        }
        
      }
      
    }
    
  }
  
  // fill out the best track if required else clean up the fRecTracksPtr array
  if (!GetRecoParam()->TrackAllTracks()) {
    if (foundTwoClusters) {
      bestTrackParamAtCluster1.SetRemovable(kTRUE);
      trackCandidate.AddTrackParamAtCluster(bestTrackParamAtCluster1,*(bestTrackParamAtCluster1.GetClusterPtr()));
      bestTrackParamAtCluster2.SetRemovable(kTRUE);
      trackCandidate.AddTrackParamAtCluster(bestTrackParamAtCluster2,*(bestTrackParamAtCluster2.GetClusterPtr()));
      trackCandidate.SetGlobalChi2(trackCandidate.GetGlobalChi2()+bestChi2WithTwoClusters);
      
      // Printout for debuging
      if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 1) || (AliLog::GetGlobalDebugLevel() >= 1)) {
        cout << "FollowLinearTrackInStation: added the two best clusters in station(1..): " << nextStation+1 << endl;
        if (AliLog::GetGlobalDebugLevel() >= 3) newTrack->RecursiveDump();
      }
      
    } else if (foundOneCluster) {
      if (GetRecoParam()->RequestStation(nextStation))
        bestTrackParamAtCluster1.SetRemovable(kFALSE);
      else bestTrackParamAtCluster1.SetRemovable(kTRUE);
      trackCandidate.AddTrackParamAtCluster(bestTrackParamAtCluster1,*(bestTrackParamAtCluster1.GetClusterPtr()));
      trackCandidate.SetGlobalChi2(trackCandidate.GetGlobalChi2()+bestChi2WithOneCluster);
      
      // Printout for debuging
      if ((AliLog::GetDebugLevel("MUON","AliMUONVTrackReconstructor") >= 1) || (AliLog::GetGlobalDebugLevel() >= 1)) {
        cout << "FollowLinearTrackInStation: added the best cluster in chamber(1..): " << bestTrackParamAtCluster1.GetClusterPtr()->GetChamberId()+1 << endl;
        if (AliLog::GetGlobalDebugLevel() >= 3) newTrack->RecursiveDump();
      }
      
    } else {
      delete [] clusterCh1Used;
      return kFALSE;
    }
    
  } else if (foundOneCluster || foundTwoClusters) {
    
    // remove obsolete track
    fRecTracksPtr->Remove(&trackCandidate);
    fNRecTracks--;
    
  } else {
    delete [] clusterCh1Used;  
    return kFALSE;
  }
  
  delete [] clusterCh1Used;
  return kTRUE;
  
}

//__________________________________________________________________________
void AliMUONVTrackReconstructor::ImproveTracks()
{
  /// Improve tracks by removing clusters with local chi2 highter than the defined cut
  /// Recompute track parameters and covariances at the remaining clusters
  AliDebug(1,"Enter ImproveTracks");
  
  AliMUONTrack *track, *nextTrack;
  
  track = (AliMUONTrack*) fRecTracksPtr->First();
  while (track) {
    
    // prepare next track in case the actual track is suppressed
    nextTrack = (AliMUONTrack*) fRecTracksPtr->After(track);
    
    ImproveTrack(*track);
    
    // remove track if improvement failed
    if (!track->IsImproved()) {
      fRecTracksPtr->Remove(track);
      fNRecTracks--;
    }
    
    track = nextTrack;
  }
  
  // compress the array in case of some tracks have been removed
  fRecTracksPtr->Compress();
  
}

//__________________________________________________________________________
void AliMUONVTrackReconstructor::Finalize()
{
  /// Recompute track parameters and covariances at each attached cluster
  /// Set the label pointing to the corresponding MC track
  /// Remove the track if finalization failed
  
  AliMUONTrack *track, *nextTrack;
  Bool_t trackRemoved = kFALSE;
  
  track = (AliMUONTrack*) fRecTracksPtr->First();
  while (track) {
    
    nextTrack = (AliMUONTrack*) fRecTracksPtr->After(track);
    
    if (FinalizeTrack(*track)) track->FindMCLabel();
    else {
      fRecTracksPtr->Remove(track);
      fNRecTracks--;
      trackRemoved = kTRUE;
    }
    
    track = nextTrack;
    
  }
  
  // compress array of tracks if needed
  if (trackRemoved) fRecTracksPtr->Compress();
  
}

//__________________________________________________________________________
void AliMUONVTrackReconstructor::DiscardMonoCathodClusters()
{
  /// Assign a different resolution to the mono-cathod clusters
  /// in the direction of the missing plane and refit the track
  /// Remove the track in case of failure
  
  if (!fkTransformer) AliFatal("missing geometry transformer");
  
  AliMUONTrack *track, *nextTrack;
  Bool_t trackRemoved = kFALSE;
  
  track = (AliMUONTrack*) fRecTracksPtr->First();
  while (track) {
    
    nextTrack = (AliMUONTrack*) fRecTracksPtr->After(track);
    
    ChangeMonoCathodClusterRes(*track);
    
    if (!RefitTrack(*track) || (GetRecoParam()->ImproveTracks() && !track->IsImproved())) {
      fRecTracksPtr->Remove(track);
      fNRecTracks--;
      trackRemoved = kTRUE;
    }
    
    track = nextTrack;
    
  }
  
  // compress array of tracks if needed
  if (trackRemoved) fRecTracksPtr->Compress();
  
}

//__________________________________________________________________________
void AliMUONVTrackReconstructor::ChangeMonoCathodClusterRes(AliMUONTrack &track)
{
  /// Assign a different resolution to the mono-cathod clusters
  /// in the direction of the missing plane and refit the track
  
  // Loop over clusters
  AliMUONVCluster *cluster;
  Int_t nClusters = track.GetNClusters();
  for (Int_t iCluster = 0; iCluster < nClusters; iCluster++) {
    cluster = ((AliMUONTrackParam*) track.GetTrackParamAtCluster()->UncheckedAt(iCluster))->GetClusterPtr();
    
    // do it only for stations 3, 4 & 5
    if (cluster->GetChamberId() < 4) continue;
    
    // get the cathod corresponding to the bending/non-bending plane
    Int_t deId = cluster->GetDetElemId();
    AliMpDetElement* de = AliMpDDLStore::Instance()->GetDetElement(deId, kFALSE);
    if (!de) continue;
    AliMp::CathodType cath1 = de->GetCathodType(AliMp::kBendingPlane); 
    AliMp::CathodType cath2 = de->GetCathodType(AliMp::kNonBendingPlane); 
    
    // get the corresponding segmentation
    const AliMpVSegmentation* seg1 = AliMpSegmentation::Instance()->GetMpSegmentation(deId, cath1);
    const AliMpVSegmentation* seg2 = AliMpSegmentation::Instance()->GetMpSegmentation(deId, cath2);
    if (!seg1 || !seg2) continue;
    
    // get local coordinate of the cluster
    Double_t lX,lY,lZ;
    Double_t gX = cluster->GetX();
    Double_t gY = cluster->GetY();
    Double_t gZ = cluster->GetZ();
    fkTransformer->Global2Local(deId,gX,gY,gZ,lX,lY,lZ);
    
    // find pads below the cluster
    AliMpPad pad1 = seg1->PadByPosition(lX, lY, kFALSE);
    AliMpPad pad2 = seg2->PadByPosition(lX, lY, kFALSE);
    
    // build their ID if pads are valid
    UInt_t padId1 = (pad1.IsValid()) ? AliMUONVDigit::BuildUniqueID(deId, pad1.GetManuId(), pad1.GetManuChannel(), cath1) : 0;
    UInt_t padId2 = (pad2.IsValid()) ? AliMUONVDigit::BuildUniqueID(deId, pad2.GetManuId(), pad2.GetManuChannel(), cath2) : 0;
    
    // check if the cluster contains these pads 
    Bool_t hasNonBending = kFALSE;
    Bool_t hasBending = kFALSE;
    for (Int_t iDigit = 0; iDigit < cluster->GetNDigits(); iDigit++) {
      
      UInt_t digitId = cluster->GetDigitId(iDigit);
      
      if (digitId == padId1) {
        
        hasBending = kTRUE;
        if (hasNonBending) break;
        
      } else if (digitId == padId2) {
        
        hasNonBending = kTRUE;
        if (hasBending) break;
        
      }
      
    }
    
    // modify the cluster resolution if needed
    if (!hasNonBending) cluster->SetErrXY(GetRecoParam()->GetMonoCathodClNonBendingRes(), cluster->GetErrY());
    if (!hasBending) cluster->SetErrXY(cluster->GetErrX(), GetRecoParam()->GetMonoCathodClBendingRes());
    
  }
  
}

//__________________________________________________________________________
void AliMUONVTrackReconstructor::ValidateTracksWithTrigger(AliMUONVTrackStore& trackStore,
                                                           const AliMUONVTriggerTrackStore& triggerTrackStore,
                                                           const AliMUONVTriggerStore& triggerStore,
                                                           const AliMUONTrackHitPattern& trackHitPattern)
{
  /// Try to match track from tracking system with trigger track
  AliCodeTimerAuto("",0);

  trackHitPattern.ExecuteValidation(trackStore, triggerTrackStore, triggerStore);
}


//__________________________________________________________________________
void AliMUONVTrackReconstructor::EventReconstructTrigger(const AliMUONTriggerCircuit& circuit,
                                                         const AliMUONVTriggerStore& triggerStore,
                                                         AliMUONVTriggerTrackStore& triggerTrackStore)
{
  /// Fill trigger track store from local trigger
  AliDebug(1, "");
  AliCodeTimerAuto("",0);

  AliMUONGlobalTrigger* globalTrigger = triggerStore.Global();
  
  UChar_t gloTrigPat = 0;

  if (globalTrigger)
  {
    gloTrigPat = globalTrigger->GetGlobalResponse();
  }
  
  AliMUONTriggerTrack triggerTrack;
  
  TIter next(triggerStore.CreateIterator());
  AliMUONLocalTrigger* locTrg(0x0);
  
  while ( ( locTrg = static_cast<AliMUONLocalTrigger*>(next()) ) )
  {
    if ( locTrg->IsTrigX() && locTrg->IsTrigY() ) 
    { // make Trigger Track if trigger in X and Y
      
      if (TriggerToTrack(circuit, *locTrg, triggerTrack, gloTrigPat))
        triggerTrackStore.Add(triggerTrack);

    } // board is fired 
  } // end of loop on Local Trigger
}

//__________________________________________________________________________
Bool_t AliMUONVTrackReconstructor::TriggerToTrack(const AliMUONTriggerCircuit& circuit,
                                                const AliMUONLocalTrigger& locTrg,
                                                AliMUONTriggerTrack& triggerTrack,
                                                UChar_t globalTriggerPattern)
{
  /// To make the trigger tracks from Local Trigger
  const Double_t kTrigNonBendReso = AliMUONConstants::TriggerNonBendingReso();
  const Double_t kTrigBendReso = AliMUONConstants::TriggerBendingReso();
  const Double_t kSqrt12 = TMath::Sqrt(12.);
  
  TMatrixD trigCov(3,3);

  Int_t localBoardId = locTrg.LoCircuit();
      
  Float_t y11 = circuit.GetY11Pos(localBoardId, locTrg.LoStripX()); 
  Float_t z11 = circuit.GetZ11Pos(localBoardId, locTrg.LoStripX());
  // need first to convert deviation to [0-30] 
  // (see AliMUONLocalTriggerBoard::LocalTrigger)
  Int_t deviation = locTrg.GetDeviation(); 
  Int_t stripX21 = locTrg.LoStripX()+deviation+1;
  Float_t y21 = circuit.GetY21Pos(localBoardId, stripX21);       
  Float_t z21 = circuit.GetZ21Pos(localBoardId, stripX21);
  Float_t x11 = circuit.GetX11Pos(localBoardId, locTrg.LoStripY());
      
  AliDebug(1, Form(" MakeTriggerTrack %3d %2d %2d %2d (%f %f %f) (%f %f)\n",locTrg.LoCircuit(),
                   locTrg.LoStripX(),locTrg.LoStripX()+deviation+1,locTrg.LoStripY(),x11, y11, z11, y21, z21));
      
  if (TMath::Abs(z11) < 0.00001) return kFALSE;

  Double_t deltaZ = z11 - z21;
      
  Float_t slopeX = x11/z11;
  Float_t slopeY = (y11-y21) / deltaZ;
      
  Float_t sigmaX = circuit.GetX11Width(localBoardId, locTrg.LoStripY()) / kSqrt12;
  Float_t sigmaY = circuit.GetY11Width(localBoardId, locTrg.LoStripX()) / kSqrt12;
  Float_t sigmaY21 = circuit.GetY21Width(localBoardId, locTrg.LoStripX()) / kSqrt12;
      
  trigCov.Zero();
  trigCov(0,0) = kTrigNonBendReso * kTrigNonBendReso + sigmaX * sigmaX;
  trigCov(1,1) = kTrigBendReso * kTrigBendReso + sigmaY * sigmaY;
  trigCov(2,2) = 
    (2. * kTrigBendReso * kTrigBendReso + sigmaY * sigmaY + sigmaY21 * sigmaY21 ) / deltaZ / deltaZ;
    trigCov(1,2) = trigCov(2,1) = trigCov(1,1) / deltaZ;
      
  triggerTrack.SetX11(x11);
  triggerTrack.SetY11(y11);
  triggerTrack.SetZ11(z11);
  triggerTrack.SetZ21(z21);
  triggerTrack.SetSlopeX(slopeX);
  triggerTrack.SetSlopeY(slopeY);
  triggerTrack.SetGTPattern(globalTriggerPattern);
  triggerTrack.SetLoTrgNum(localBoardId);
  triggerTrack.SetCovariances(trigCov);
  triggerTrack.SetUniqueID(locTrg.GetUniqueID());

  return kTRUE;

}