예제 #1
0
int PHG4TrackGhostRejection::process_event(PHCompositeNode *topNode)
{
  if(verbosity > 0) cout << "PHG4TrackGhostRejection::process_event -- entered" << endl;

  //---------------------------------
  // Get Objects off of the Node Tree
  //---------------------------------

  // Pull the reconstructed track information off the node tree...
  _g4tracks = findNode::getClass<SvtxTrackMap>(topNode, "SvtxTrackMap");
  if(!_g4tracks) 
    {
      cerr << PHWHERE << " ERROR: Can't find SvtxTrackMap." << endl;
      return Fun4AllReturnCodes::ABORTEVENT;
    }

  if (verbosity > 1) {
    _g4tracks->identify();
    for (SvtxTrackMap::Iter iter = _g4tracks->begin();
	 iter != _g4tracks->end();
	 ++iter) {
      SvtxTrack *track = iter->second;
      track->identify();
    }
  }

  //----------------------------
  // Sort the hits on each track
  //----------------------------

  _candidates.clear();
  
  for (SvtxTrackMap::Iter iter = _g4tracks->begin();
       iter != _g4tracks->end();
       ++iter) {

    SvtxTrack* track = iter->second;
  
    PHG4TrackCandidate combo;

    combo.trackid = track->get_id();
    combo.nhits = track->size_clusters();

    for (SvtxTrack::ConstClusterIter iter = track->begin_clusters();
	 iter != track->end_clusters();
	 ++iter) {
      unsigned int cluster_id = *iter;
      combo.hitids.push_back(cluster_id);
    }
      
    if (track->get_ndf() != 0) {
      combo.chisq = track->get_chisq()/track->get_ndf();
    }

    combo.keep = true;

    // sort the hits by index
    stable_sort(combo.hitids.begin(),combo.hitids.end(),hit_sort);

    _candidates.push_back(combo);
  }

  //---------------------
  // Fill the overlap map
  //---------------------

  _overlapping.clear();
  for(unsigned int i = 0; i < _candidates.size(); i++)
    {
      for(unsigned int j = i+1; j < _candidates.size(); j++)
  	{ 
	  // determine the maximum length of the anticipated storage
	  unsigned maxhits = _candidates[i].hitids.size();
	  if(_candidates[j].hitids.size() > maxhits)
	    {
	      maxhits = _candidates[j].hitids.size();
	    }

	  // create the difference storage
	  std::vector<unsigned int> diff;
	  diff.assign(maxhits,0);

	  // run the difference algorithm
	  std::vector<unsigned int>::iterator it = diff.begin();
	  it = std::set_difference(_candidates[i].hitids.begin(),_candidates[i].hitids.end(),
				   _candidates[j].hitids.begin(),_candidates[j].hitids.end(),
				   diff.begin());

	  // calculate the overlap
	  unsigned int overlap = maxhits - int(it - diff.begin());

	  // insert an overlapping pair into the map
	  if(overlap > _max_shared_hits) _overlapping.insert(std::make_pair(i,j));	  
   	}
    }

  //----------------------
  // Flag the ghost tracks
  //----------------------

  std::multimap<unsigned,unsigned int>::iterator iter;
  for (iter = _overlapping.begin(); iter != _overlapping.end(); iter++) {

    unsigned int key = iter->first;
    unsigned int value = iter->second;

    if (_candidates[key].nhits > _candidates[value].nhits) {
      // prefer longer track
      _candidates[value].keep = false;
    } else if (_candidates[key].nhits < _candidates[value].nhits) {
      // prefer longer track
      _candidates[key].nhits = false;
    } else {
      // choose between equal length tracks by chisq/dof
      if (_candidates[key].chisq < _candidates[value].chisq) {
	_candidates[value].keep = false;
      } else {
	_candidates[key].keep = false;
      }
    }
  }

  //------------------------
  // Remove the ghost tracks
  //------------------------

  SvtxVertexMap* vertexmap = findNode::getClass<SvtxVertexMap>(topNode, "SvtxVertexMap");
  
  int initial_size = _g4tracks->size();

  // loop over container and delete!
  for (unsigned int i = 0; i < _candidates.size(); i++) {
    if (!_candidates[i].keep) {
      // look for the track to delete
      if (_g4tracks->find(_candidates[i].trackid) != _g4tracks->end()) {
	_g4tracks->erase(_candidates[i].trackid);

	// also remove the track id from any vertex that contains this track
	if (!vertexmap) continue;
	for (SvtxVertexMap::Iter iter = vertexmap->begin();
	     iter != vertexmap->end();
	     ++iter) {
	  SvtxVertex* vertex = iter->second;
	  vertex->erase_track(_candidates[i].trackid);
	}
      }
    }
  }

  if (verbosity > 1) {
    _g4tracks->identify();
    for (SvtxTrackMap::Iter iter = _g4tracks->begin();
	 iter != _g4tracks->end();
	 ++iter) {
      SvtxTrack *track = iter->second;
      track->identify();
    }
  }

  if(verbosity > 0)
    cout << "PHG4TrackGhostRejection - rejected and removed " 
         << initial_size - _g4tracks->size()
         << " tracks" << endl;;
  
  if(verbosity > 0) cout << "PHG4TrackGhostRejection::process_event -- exited" << endl;

  return Fun4AllReturnCodes::EVENT_OK;
}
예제 #2
0
int PHG4SvtxTrackProjection::process_event(PHCompositeNode *topNode)
{
  if(verbosity > 1) cout << "PHG4SvtxTrackProjection::process_event -- entered" << endl;

  //---------------------------------
  // Get Objects off of the Node Tree
  //---------------------------------

  // Pull the reconstructed track information off the node tree...
  SvtxTrackMap* _g4tracks = findNode::getClass<SvtxTrackMap>(topNode, "SvtxTrackMap");
  if (!_g4tracks) {
    cerr << PHWHERE << " ERROR: Can't find SvtxTrackMap." << endl;
    return Fun4AllReturnCodes::ABORTRUN;
  }

  for (int i=0;i<_num_cal_layers;++i) {

    if (isnan(_cal_radii[i])) continue;

    if (verbosity > 1) cout << "Projecting tracks into: " << _cal_names[i] << endl;

    // pull the tower geometry
    string towergeonodename = "TOWERGEOM_" + _cal_names[i];
    RawTowerGeom *towergeo = findNode::getClass<RawTowerGeom>(topNode,towergeonodename.c_str());
    if (!towergeo) {
      cerr << PHWHERE << " ERROR: Can't find node " << towergeonodename << endl;
      return Fun4AllReturnCodes::ABORTRUN;
    }

    // pull the towers
    string towernodename = "TOWER_CALIB_" + _cal_names[i];
    RawTowerContainer *towerList = findNode::getClass<RawTowerContainer>(topNode,towernodename.c_str());
    if (!towerList) {
      cerr << PHWHERE << " ERROR: Can't find node " << towernodename << endl;
      return Fun4AllReturnCodes::ABORTRUN;
    }

    // pull the clusters
    string clusternodename = "CLUSTER_" + _cal_names[i];
    RawClusterContainer *clusterList = findNode::getClass<RawClusterContainer>(topNode,clusternodename.c_str());
    if (!clusterList) {
      cerr << PHWHERE << " ERROR: Can't find node " << clusternodename << endl;
      return Fun4AllReturnCodes::ABORTRUN;
    }    
    
    // loop over all tracks
    for (SvtxTrackMap::Iter iter = _g4tracks->begin();
	 iter != _g4tracks->end();
	 ++iter) {
      SvtxTrack *track = iter->second;

      if (verbosity > 1) cout << "projecting track id " << track->get_id() << endl;

      if (verbosity > 1) {
	cout << " track pt = " << track->get_pt() << endl;
      }

      // curved tracks inside mag field
      // straight projections thereafter
      std::vector<double> point;
      point.assign(3,-9999.);
      //if (_cal_radii[i] < _mag_extent) {
      // curved projections inside field

      _hough.projectToRadius(track,_magfield,_cal_radii[i],point);

      if (isnan(point[0])) continue;
      if (isnan(point[1])) continue;
      if (isnan(point[2])) continue;
      // } else {
      // 	// straight line projections after mag field exit
      // 	_hough.projectToRadius(track,_mag_extent-0.05,point);
      // 	if (isnan(point[0])) continue;
      // 	if (isnan(point[1])) continue;
      // 	if (isnan(point[2])) continue;

      // 	std::vector<double> point2;
      // 	point2.assign(3,-9999.);
      // 	_hough.projectToRadius(track,_mag_extent+0.05,point2);
      // 	if (isnan(point2[0])) continue;
      // 	if (isnan(point2[1])) continue;
      // 	if (isnan(point2[2])) continue;

      // 	// find intersection of r and z


      // find x,y of intersection
      //}
      double x = point[0];
      double y = point[1];
      double z = point[2];

      double phi = atan2(y,x);
      double eta = asinh(z/sqrt(x*x+y*y));

      if (verbosity > 1) {
	cout << " initial track phi = " << track->get_phi();
	cout << ", eta = " << track->get_eta() << endl;
	cout << " calorimeter phi = " << phi << ", eta = " << eta << endl;
      }

      // projection is outside the detector extent
      // \todo towergeo doesn't make this easy to extract, but this should be
      // fetched from the node tree instead of hardcoded
      if (fabs(eta) >= 1.0) continue;

      // calculate 3x3 tower energy
      int binphi = towergeo->get_phibin(phi);
      int bineta = towergeo->get_etabin(eta);

      double energy_3x3 = 0.0;
      for (int iphi = binphi-1; iphi < binphi+2; ++iphi) { 
      	for (int ieta = bineta-1; ieta < bineta+2; ++ieta) { 

	  // wrap around
	  int wrapphi = iphi;
	  if (wrapphi < 0) {
	    wrapphi = towergeo->get_phibins() + wrapphi;
	  }
	  if (wrapphi >= towergeo->get_phibins()) {
	    wrapphi = wrapphi - towergeo->get_phibins();
	  }

	  // edges
	  if (ieta < 0) continue;
	  if (ieta >= towergeo->get_etabins()) continue;

	  RawTower* tower = towerList->getTower(ieta,wrapphi);
	  if (tower) {
	    energy_3x3 += tower->get_energy();

	    if (verbosity > 1) cout << " tower " << ieta << " " << wrapphi << " energy = " << tower->get_energy() << endl;
	  }
      	}
      }

      track->set_cal_energy_3x3(_cal_types[i],energy_3x3);

      // loop over all clusters and find nearest
      double min_r = DBL_MAX;
      double min_index = -9999;
      double min_dphi = NAN;
      double min_deta = NAN;
      double min_e = NAN;
      for (unsigned int k = 0; k < clusterList->size(); ++k) {

	RawCluster *cluster = clusterList->getCluster(k);

	double dphi = atan2(sin(phi-cluster->get_phi()),cos(phi-cluster->get_phi()));
	double deta = eta-cluster->get_eta();
	double r = sqrt(pow(dphi,2)+pow(deta,2));

	if (r < min_r) {
	  min_index = k;
	  min_r = r;
	  min_dphi = dphi;
	  min_deta = deta;
	  min_e = cluster->get_energy();
	}
      }

      if (min_index != -9999) {
	track->set_cal_dphi(_cal_types[i],min_dphi);
	track->set_cal_deta(_cal_types[i],min_deta);
	track->set_cal_cluster_id(_cal_types[i],min_index);
	track->set_cal_cluster_e(_cal_types[i],min_e);

	if (verbosity > 1) {
	  cout << " nearest cluster dphi = " << min_dphi << " deta = " << min_deta << " e = " << min_e << endl;
	}
      }

    } // end track loop
  } // end calorimeter layer loop

 
  if(verbosity > 1) cout << "PHG4SvtxTrackProjection::process_event -- exited" << endl;

  return Fun4AllReturnCodes::EVENT_OK;
}
예제 #3
0
void SvtxEvaluator::fillOutputNtuples(PHCompositeNode *topNode) {

  if (verbosity > 1) cout << "SvtxEvaluator::fillOutputNtuples() entered" << endl;

  SvtxVertexEval*   vertexeval = _svtxevalstack->get_vertex_eval();
  SvtxTrackEval*     trackeval = _svtxevalstack->get_track_eval();
  SvtxClusterEval* clustereval = _svtxevalstack->get_cluster_eval();
  SvtxHitEval*         hiteval = _svtxevalstack->get_hit_eval();
  SvtxTruthEval*     trutheval = _svtxevalstack->get_truth_eval();
  
  //-----------------------
  // fill the Vertex NTuple
  //-----------------------

  if (_ntp_vertex) {
    //cout << "Filling ntp_vertex " << endl;
    SvtxVertexMap* vertexmap = findNode::getClass<SvtxVertexMap>(topNode,"SvtxVertexMap");
    PHG4TruthInfoContainer* truthinfo = findNode::getClass<PHG4TruthInfoContainer>(topNode,"G4TruthInfo");
    if (vertexmap && truthinfo) {
      for (SvtxVertexMap::Iter iter = vertexmap->begin();
	   iter != vertexmap->end();
	   ++iter) {
	SvtxVertex* vertex = iter->second;
	PHG4VtxPoint* point = vertexeval->max_truth_point_by_ntracks(vertex);

	float vx         = vertex->get_x();
	float vy         = vertex->get_y();
	float vz         = vertex->get_z();
	float ntracks    = vertex->size_tracks();

	float gvx        = NAN;
	float gvy        = NAN;
	float gvz        = NAN;
	float gvt        = NAN;
	float gntracks   = truthinfo->GetNumPrimaryVertexParticles();
	float nfromtruth = NAN;
	
	if (point) {
	  gvx        = point->get_x();
	  gvy        = point->get_y();
	  gvz        = point->get_z();
	  gvt        = point->get_t();
	  gntracks   = truthinfo->GetNumPrimaryVertexParticles();
	  nfromtruth = vertexeval->get_ntracks_contribution(vertex,point);
	}
	  
	float vertex_data[11] = {(float) _ievent,
				 vx,
				 vy,
				 vz,
				 ntracks,
				 gvx,
				 gvy,
				 gvz,
				 gvt,
				 gntracks,
				 nfromtruth
	};

	/*
	cout << "vertex: " 
	     << " ievent " << vertex_data[0]
	     << " vx " << vertex_data[1]
	     << " vy " << vertex_data[2]
	     << " vz " << vertex_data[3]
	     << endl;
	*/

	_ntp_vertex->Fill(vertex_data);      
      }
    }
  }
  
  //-----------------------
  // fill the gpoint NTuple
  //-----------------------
  
  if (_ntp_gpoint) {
    //cout << "Filling ntp_gpoint " << endl;    
    SvtxVertexMap* vertexmap = findNode::getClass<SvtxVertexMap>(topNode,"SvtxVertexMap");
    PHG4TruthInfoContainer* truthinfo = findNode::getClass<PHG4TruthInfoContainer>(topNode,"G4TruthInfo");

    if (vertexmap && truthinfo) {

      PHG4VtxPoint* point =  truthinfo->GetPrimaryVtx(truthinfo->GetPrimaryVertexIndex());

      if (point) {
      
	SvtxVertex* vertex = vertexeval->best_vertex_from(point);
    
	float gvx        = point->get_x();
	float gvy        = point->get_y();
	float gvz        = point->get_z();
	float gvt        = point->get_t();
	float gntracks   = truthinfo->GetNumPrimaryVertexParticles();
	float vx         = NAN;
	float vy         = NAN;
	float vz         = NAN;
	float ntracks    = NAN;
	float nfromtruth = NAN;

	if (vertex) {
	  vx         = vertex->get_x();
	  vy         = vertex->get_y();
	  vz         = vertex->get_z();
	  ntracks    = vertex->size_tracks();
	  nfromtruth = vertexeval->get_ntracks_contribution(vertex,point);
	}
	
	float gpoint_data[11] = {(float) _ievent,
				 gvx,
				 gvy,
				 gvz,
				 gvt,
				 gntracks,
				 vx,
				 vy,
				 vz,
				 ntracks,
				 nfromtruth
	};

	_ntp_gpoint->Fill(gpoint_data);      
      }
    }
  }
  
  //---------------------
  // fill the G4hit NTuple
  //---------------------

  if (_ntp_g4hit) {
    //cout << "Filling ntp_g4hit " << endl;
    std::set<PHG4Hit*> g4hits = trutheval->all_truth_hits();
    for (std::set<PHG4Hit*>::iterator iter = g4hits.begin();
	 iter != g4hits.end();
	 ++iter) {
            
      PHG4Hit *g4hit = *iter;
      PHG4Particle *g4particle = trutheval->get_particle(g4hit);
      
      float g4hitID   = g4hit->get_hit_id();
      float gx        = g4hit->get_avg_x();
      float gy        = g4hit->get_avg_y();
      float gz        = g4hit->get_avg_z();
      float gt        = g4hit->get_avg_t();
      float gedep     = g4hit->get_edep();
      float glayer    = g4hit->get_layer();
  
      float gtrackID  = g4hit->get_trkid();

      float gflavor   = NAN;
      float gpx       = NAN;
      float gpy       = NAN;
      float gpz       = NAN;

      float gvx       = NAN;
      float gvy       = NAN;
      float gvz       = NAN;

      float gembed  = NAN;
      float gprimary = NAN;

      float gfpx      = 0.;
      float gfpy      = 0.;
      float gfpz      = 0.;
      float gfx       = 0.;
      float gfy       = 0.;
      float gfz       = 0.;

      if (g4particle) {

	if (_scan_for_embedded) {
	  if (trutheval->get_embed(g4particle) == 0) continue;
	}
	
	gflavor   = g4particle->get_pid();
	gpx       = g4particle->get_px();
	gpy       = g4particle->get_py();
	gpz       = g4particle->get_pz();

	PHG4VtxPoint* vtx = trutheval->get_vertex(g4particle);	

	if (vtx) {
	  gvx       = vtx->get_x();
	  gvy       = vtx->get_y();
	  gvz       = vtx->get_z();
	}
    
	PHG4Hit* outerhit = trutheval->get_outermost_truth_hit(g4particle);	
	if (outerhit) {
	  gfpx      = outerhit->get_px(1);
	  gfpy      = outerhit->get_py(1);
	  gfpz      = outerhit->get_pz(1);
	  gfx       = outerhit->get_x(1);
	  gfy       = outerhit->get_y(1);
	  gfz       = outerhit->get_z(1);
	}
	
	gembed    = trutheval->get_embed(g4particle);
	gprimary  = trutheval->is_primary(g4particle);
      } //       if (g4particle)
      
      std::set<SvtxCluster*> clusters = clustereval->all_clusters_from(g4hit);  
      float nclusters = clusters.size();

      // best cluster reco'd
      SvtxCluster* cluster = clustereval->best_cluster_from(g4hit);

      float clusID     = NAN;
      float x          = NAN;
      float y          = NAN;
      float z          = NAN;
      float e          = NAN;
      float adc        = NAN;
      float layer      = NAN;
      float size       = NAN;
      float phisize    = NAN;
      float zsize      = NAN;
      float efromtruth = NAN;

      if (cluster) {
	clusID     = cluster->get_id();
	x          = cluster->get_x();
	y          = cluster->get_y();
	z          = cluster->get_z();
	e          = cluster->get_e();
	adc        = cluster->get_adc();
	layer      = cluster->get_layer();
	size       = cluster->size_hits();
	phisize    = cluster->get_phi_size();
	zsize      = cluster->get_z_size();
	if (g4particle) {
	  efromtruth = clustereval->get_energy_contribution(cluster,g4particle);
	}
      }

      float g4hit_data[36] = {(float) _ievent,
			      g4hitID,
			      gx,
			      gy,
			      gz,
			      gt,
			      gedep,
			      glayer,
			      gtrackID,
			      gflavor,
			      gpx,
			      gpy,
			      gpz,
			      gvx,
			      gvy,
			      gvz,
			      gfpx,
			      gfpy,
			      gfpz,
			      gfx,
			      gfy,
			      gfz,
			      gembed,
			      gprimary,
			      nclusters,
			      clusID,  
			      x,      
			      y,      
			      z,      
			      e,      
			      adc,    
			      layer,  
			      size,   
			      phisize,
			      zsize,  
			      efromtruth
      };

      _ntp_g4hit->Fill(g4hit_data);
    }
  }
  
  //--------------------
  // fill the Hit NTuple
  //--------------------

  if (_ntp_hit) {
    //cout << "Filling ntp_hit " << endl;
    // need things off of the DST...
    SvtxHitMap* hitmap = findNode::getClass<SvtxHitMap>(topNode,"SvtxHitMap");
    if (hitmap) {

      for (SvtxHitMap::Iter iter = hitmap->begin();
	   iter != hitmap->end();
	   ++iter) {

	SvtxHit* hit             = iter->second;
	PHG4Hit* g4hit           = hiteval->max_truth_hit_by_energy(hit);
	PHG4CylinderCell* g4cell = hiteval->get_cell(hit);
	PHG4Particle* g4particle = trutheval->get_particle(g4hit);

	float event  = _ievent;
	float hitID  = hit->get_id();
	float e      = hit->get_e();
	float adc    = hit->get_adc();
	float layer  = hit->get_layer();
	float cellID = hit->get_cellid();
	float ecell  = g4cell->get_edep();

	float g4hitID  = NAN;
	float gedep    = NAN;
	float gx       = NAN;
	float gy       = NAN;
	float gz       = NAN;
	float gt       = NAN;
	float gtrackID = NAN;
	float gflavor  = NAN;
	float gpx      = NAN;
	float gpy      = NAN;
	float gpz      = NAN;
	float gvx      = NAN;
	float gvy      = NAN;
	float gvz      = NAN;
	float gfpx     = NAN;
	float gfpy     = NAN;
	float gfpz     = NAN;
	float gfx      = NAN;
	float gfy      = NAN;
	float gfz      = NAN;
	float gembed   = NAN;
	float gprimary = NAN;
      
	float efromtruth = NAN;
      
	if (g4hit) {
	  g4hitID  = g4hit->get_hit_id();
	  gedep    = g4hit->get_edep();
	  gx       = g4hit->get_avg_x();
	  gy       = g4hit->get_avg_y();
	  gz       = g4hit->get_avg_z();
	  gt       = g4hit->get_avg_t();

	  if (g4particle) {

	    if (_scan_for_embedded) {
	      if (trutheval->get_embed(g4particle) == 0) continue;
	    }
	    
	    gtrackID = g4particle->get_track_id();
	    gflavor  = g4particle->get_pid();
	    gpx      = g4particle->get_px();
	    gpy      = g4particle->get_py();
	    gpz      = g4particle->get_pz();

	    PHG4VtxPoint* vtx = trutheval->get_vertex(g4particle);

	    if (vtx) {
	      gvx      = vtx->get_x();
	      gvy      = vtx->get_y();
	      gvz      = vtx->get_z();
	    }

	    PHG4Hit* outerhit = trutheval->get_outermost_truth_hit(g4particle);	
	    if (outerhit) {
	      gfpx     = outerhit->get_px(1);
	      gfpy     = outerhit->get_py(1);
	      gfpz     = outerhit->get_pz(1);
	      gfx      = outerhit->get_x(1);
	      gfy      = outerhit->get_y(1);
	      gfz      = outerhit->get_z(1);
	    }
	    gembed   = trutheval->get_embed(g4particle);
	    gprimary = trutheval->is_primary(g4particle);
	  } //   if (g4particle){
	}      

	if (g4particle) {
	  efromtruth = hiteval->get_energy_contribution(hit,g4particle);
	}

	float hit_data[33] = {
	  event,
	  hitID,
	  e,
	  adc,
	  layer,
	  cellID,
	  ecell,
	  g4hitID,
	  gedep,
	  gx,
	  gy,
	  gz,
	  gt,
	  gtrackID,
	  gflavor,
	  gpx,
	  gpy,
	  gpz,
	  gvx,
	  gvy,
	  gvz,
	  gfpx,
	  gfpy,
	  gfpz,
	  gfx,
	  gfy,
	  gfz,
	  gembed,
	  gprimary,
	  efromtruth
	};
	  
	_ntp_hit->Fill(hit_data);     
      }
    }
  }
  
  //------------------------
  // fill the Cluster NTuple
  //------------------------

  //cout << "check for ntp_cluster" << endl;

  if (_ntp_cluster && !_scan_for_embedded) {
    //cout << "Filling ntp_cluster 1 " << endl;
    // need things off of the DST...
    SvtxClusterMap* clustermap = findNode::getClass<SvtxClusterMap>(topNode,"SvtxClusterMap");
    if (clustermap) {

      for (SvtxClusterMap::Iter iter = clustermap->begin();
	   iter != clustermap->end();
	   ++iter) {
    
	SvtxCluster* cluster     = iter->second;   
	SvtxTrack* track = trackeval->best_track_from(cluster);
	
	PHG4Hit *g4hit           = clustereval->max_truth_hit_by_energy(cluster); 
	PHG4Particle *g4particle = trutheval->get_particle(g4hit);
    
	float hitID    = cluster->get_id();
	float x        = cluster->get_x();
	float y        = cluster->get_y();
	float z        = cluster->get_z();

	float ex       = sqrt(cluster->get_error(0,0));
	float ey       = sqrt(cluster->get_error(1,1));
	float ez       = cluster->get_z_error();

	float ephi     = cluster->get_phi_error();
	
	float e        = cluster->get_e();
	float adc      = cluster->get_adc();
	float layer    = cluster->get_layer();
	float size     = cluster->size_hits();
	float phisize  = cluster->get_phi_size();
	float zsize    = cluster->get_z_size();

	float trackID  = NAN;
	if (track) trackID = track->get_id();

	float g4hitID  = NAN;
	float gx       = NAN;
	float gy       = NAN;
	float gz       = NAN;
	float gt       = NAN;
	float gtrackID = NAN;
	float gflavor  = NAN;
	float gpx      = NAN;
	float gpy      = NAN;
	float gpz      = NAN;
	float gvx      = NAN;
	float gvy      = NAN;
	float gvz      = NAN;
	float gfpx     = NAN;
	float gfpy     = NAN;
	float gfpz     = NAN;
	float gfx      = NAN;
	float gfy      = NAN;
	float gfz      = NAN;
	float gembed   = NAN;
	float gprimary = NAN;
    
	float efromtruth = NAN;
      
	if (g4hit) {
	  g4hitID  = g4hit->get_hit_id();
	  gx       = g4hit->get_avg_x();
	  gy       = g4hit->get_avg_y();
	  gz       = g4hit->get_avg_z();
	  gt       = g4hit->get_avg_t();

	  if (g4particle) {

	    gtrackID = g4particle->get_track_id();
	    gflavor  = g4particle->get_pid();
	    gpx      = g4particle->get_px();
	    gpy      = g4particle->get_py();
	    gpz      = g4particle->get_pz();

	    PHG4VtxPoint* vtx = trutheval->get_vertex(g4particle);
	    if (vtx) {
	      gvx      = vtx->get_x();
	      gvy      = vtx->get_y();
	      gvz      = vtx->get_z();
	    }

	    PHG4Hit* outerhit = trutheval->get_outermost_truth_hit(g4particle);	
	    if (outerhit) {
	      gfpx     = outerhit->get_px(1);
	      gfpy     = outerhit->get_py(1);
	      gfpz     = outerhit->get_pz(1);
	      gfx      = outerhit->get_x(1);
	      gfy      = outerhit->get_y(1);
	      gfz      = outerhit->get_z(1);
	    }
	    
	    gembed   = trutheval->get_embed(g4particle);
	    gprimary = trutheval->is_primary(g4particle);
	  }      //   if (g4particle){
	} //  if (g4hit) {

	if (g4particle){
	  efromtruth = clustereval->get_energy_contribution(cluster,g4particle);
	}

	float cluster_data[38] = {(float) _ievent,
				  hitID,
				  x,
				  y,
				  z,
				  ex,
				  ey,
				  ez,
				  ephi,
				  e,
				  adc,
				  layer,
				  size,
				  phisize,
				  zsize,
				  trackID,
				  g4hitID,
				  gx,
				  gy,
				  gz,
				  gt,
				  gtrackID,
				  gflavor,
				  gpx,
				  gpy,
				  gpz,
				  gvx,
				  gvy,
				  gvz,
				  gfpx,
				  gfpy,
				  gfpz,
				  gfx,
				  gfy,
				  gfz,
				  gembed,
				  gprimary,
				  efromtruth};

	_ntp_cluster->Fill(cluster_data);
      }		  
    }
    
  } else if (_ntp_cluster && _scan_for_embedded) {

    //cout << "Filling ntp_cluster 2 " << endl;

    // if only scanning embedded signals, loop over all the tracks from
    // embedded particles and report all of their clusters, including those
    // from other sources (noise hits on the embedded track)
    
    // need things off of the DST...
    SvtxTrackMap* trackmap = findNode::getClass<SvtxTrackMap>(topNode,"SvtxTrackMap");
    SvtxClusterMap* clustermap = findNode::getClass<SvtxClusterMap>(topNode,"SvtxClusterMap");
    if (trackmap) {
      
      for (SvtxTrackMap::Iter iter = trackmap->begin();
	   iter != trackmap->end();
	   ++iter) {
	
	SvtxTrack* track = iter->second;
	PHG4Particle* truth = trackeval->max_truth_particle_by_nclusters(track);
	if (truth) {	  
	  if (trutheval->get_embed(truth) == 0) continue;
	}
	
	for (SvtxTrack::ConstClusterIter iter = track->begin_clusters();
	     iter != track->end_clusters();
	     ++iter) {

	  unsigned int cluster_id = *iter;
	  SvtxCluster* cluster = clustermap->get(cluster_id);

	  PHG4Hit *g4hit           = clustereval->max_truth_hit_by_energy(cluster); 
	  PHG4Particle *g4particle = trutheval->get_particle(g4hit);
    
	  float hitID    = cluster->get_id();
	  float x        = cluster->get_x();
	  float y        = cluster->get_y();
	  float z        = cluster->get_z();

	  float ex       = sqrt(cluster->get_error(0,0));
	  float ey       = sqrt(cluster->get_error(1,1));
	  float ez       = cluster->get_z_error();

	  float ephi     = cluster->get_phi_error();
	  
	  float e        = cluster->get_e();
	  float adc      = cluster->get_adc();
	  float layer    = cluster->get_layer();
	  float size     = cluster->size_hits();
	  float phisize  = cluster->get_phi_size();
	  float zsize    = cluster->get_z_size();

	  float trackID  = NAN;
	  if (track) trackID = track->get_id();

	  float g4hitID  = NAN;
	  float gx       = NAN;
	  float gy       = NAN;
	  float gz       = NAN;
	  float gt       = NAN;
	  float gtrackID = NAN;
	  float gflavor  = NAN;
	  float gpx      = NAN;
	  float gpy      = NAN;
	  float gpz      = NAN;
	  float gvx      = NAN;
	  float gvy      = NAN;
	  float gvz      = NAN;
	  float gfpx     = NAN;
	  float gfpy     = NAN;
	  float gfpz     = NAN;
	  float gfx      = NAN;
	  float gfy      = NAN;
	  float gfz      = NAN;
	  float gembed   = NAN;
	  float gprimary = NAN;
    
	  float efromtruth = NAN;
      
	  if (g4hit) {
	    g4hitID  = g4hit->get_hit_id();
	    gx       = g4hit->get_avg_x();
	    gy       = g4hit->get_avg_y();
      gz       = g4hit->get_avg_z();
      gt       = g4hit->get_avg_t();

	    if (g4particle) {
	    
	      gtrackID = g4particle->get_track_id();
	      gflavor  = g4particle->get_pid();
	      gpx      = g4particle->get_px();
	      gpy      = g4particle->get_py();
	      gpz      = g4particle->get_pz();

	      PHG4VtxPoint* vtx = trutheval->get_vertex(g4particle);
	      if (vtx) {
		gvx      = vtx->get_x();
		gvy      = vtx->get_y();
		gvz      = vtx->get_z();
	      }

	      PHG4Hit* outerhit = trutheval->get_outermost_truth_hit(g4particle);	
	      if (outerhit) {
		gfpx     = outerhit->get_px(1);
		gfpy     = outerhit->get_py(1);
		gfpz     = outerhit->get_pz(1);
		gfx      = outerhit->get_x(1);
		gfy      = outerhit->get_y(1);
		gfz      = outerhit->get_z(1);
	      }
	    
	      gembed   = trutheval->get_embed(g4particle);
	      gprimary = trutheval->is_primary(g4particle);
	    }      //   if (g4particle){
	  } //  if (g4hit) {

	  if (g4particle){
	    efromtruth = clustereval->get_energy_contribution(cluster,g4particle);
	  }

	  float cluster_data[38] = {(float) _ievent,
				    hitID,
				    x,
				    y,
				    z,
				    ex,
				    ey,
				    ez,
				    ephi,
				    e,
				    adc,
				    layer,
				    size,
				    phisize,
				    zsize,
				    trackID,
				    g4hitID,
				    gx,
				    gy,
				    gz,
				    gt,
				    gtrackID,
				    gflavor,
				    gpx,
				    gpy,
				    gpz,
				    gvx,
				    gvy,
				    gvz,
				    gfpx,
				    gfpy,
				    gfpz,
				    gfx,
				    gfy,
				    gfz,
				    gembed,
				    gprimary,
				    efromtruth};

	  _ntp_cluster->Fill(cluster_data);
	}		  
      }
    }
  }
    
  //------------------------
  // fill the Gtrack NTuple
  //------------------------

  // need things off of the DST...

  //cout << "check for ntp_gtrack" << endl;

  if (_ntp_gtrack) {
    //cout << "Filling ntp_gtrack " << endl;

    PHG4TruthInfoContainer* truthinfo = findNode::getClass<PHG4TruthInfoContainer>(topNode,"G4TruthInfo");   
    SvtxClusterMap* clustermap = findNode::getClass<SvtxClusterMap>(topNode,"SvtxClusterMap");
    if (truthinfo) {

      PHG4TruthInfoContainer::ConstRange range = truthinfo->GetPrimaryParticleRange();
      for (PHG4TruthInfoContainer::ConstIterator iter = range.first;
	   iter != range.second; 
	 ++iter) {
	
	PHG4Particle* g4particle = iter->second;

	if (_scan_for_embedded) {
	  if (trutheval->get_embed(g4particle) == 0) continue;
	}
	
	float gtrackID = g4particle->get_track_id();
	float gflavor  = g4particle->get_pid();
      
	std::set<PHG4Hit*> g4hits = trutheval->all_truth_hits(g4particle);     
	float ng4hits = g4hits.size();  
	float gpx      = g4particle->get_px();
	float gpy      = g4particle->get_py();
	float gpz      = g4particle->get_pz();

	PHG4VtxPoint* vtx = trutheval->get_vertex(g4particle);	
	float gvx      = vtx->get_x();
	float gvy      = vtx->get_y();
	float gvz      = vtx->get_z();
	float gvt      = vtx->get_t();

	float gfpx      = 0.;
	float gfpy      = 0.;
	float gfpz      = 0.;
	float gfx       = 0.;
	float gfy       = 0.;
	float gfz       = 0.;
    
	PHG4Hit* outerhit = trutheval->get_outermost_truth_hit(g4particle);	
	if (outerhit) {
	  gfpx      = outerhit->get_px(1);
	  gfpy      = outerhit->get_py(1);
	  gfpz      = outerhit->get_pz(1);
	  gfx       = outerhit->get_x(1);
	  gfy       = outerhit->get_y(1);
	  gfz       = outerhit->get_z(1);
	}
      
	float gembed   = trutheval->get_embed(g4particle);
	float gprimary = trutheval->is_primary(g4particle);

	SvtxTrack* track = trackeval->best_track_from(g4particle);

	float trackID       = NAN;
	float charge        = NAN;
	float quality       = NAN;
	float chisq         = NAN;
	float ndf           = NAN;
	float nhits         = NAN;
	unsigned int layers = 0x0;
	float dca2d         = NAN;
	float dca2dsigma    = NAN;
	float px            = NAN;
	float py            = NAN;
	float pz            = NAN;
	float pcax          = NAN;
	float pcay          = NAN;
	float pcaz          = NAN;

	float nfromtruth    = NAN;
	float layersfromtruth = NAN;

	if (track) {
	  trackID   = track->get_id();     
	  charge    = track->get_charge();
	  quality   = track->get_quality();
	  chisq     = track->get_chisq();
	  ndf       = track->get_ndf();
	  nhits     = track->size_clusters();
	  
	  for (SvtxTrack::ConstClusterIter iter = track->begin_clusters();
	       iter != track->end_clusters();
	       ++iter) {
	    unsigned int cluster_id = *iter;
	    SvtxCluster* cluster = clustermap->get(cluster_id);
	    unsigned int layer = cluster->get_layer();
	    if (layer < 32) layers |= (0x1 << layer);
	  }

	  dca2d     = track->get_dca2d();
	  dca2dsigma = track->get_dca2d_error();
	  px        = track->get_px();
	  py        = track->get_py();
	  pz        = track->get_pz();
	  pcax      = track->get_x();
	  pcay      = track->get_y();
	  pcaz      = track->get_z();

	  nfromtruth = trackeval->get_nclusters_contribution(track,g4particle);
	  layersfromtruth = trackeval->get_nclusters_contribution_by_layer(track,g4particle);
	}
      
	float gtrack_data[36] = {(float) _ievent,
				 gtrackID,
				 gflavor,
				 ng4hits,
				 gpx,
				 gpy,
				 gpz,
				 gvx,
				 gvy,
				 gvz,
				 gvt,
				 gfpx,
				 gfpy,
				 gfpz,
				 gfx,
				 gfy,
				 gfz,
				 gembed,
				 gprimary,
				 trackID,
				 px,         
				 py,         
				 pz,  
				 charge,     
				 quality,    
				 chisq,      
				 ndf,        
				 nhits,      
				 (float) layers,     
				 dca2d,      
				 dca2dsigma, 			       
				 pcax,       
				 pcay,       
				 pcaz,
				 nfromtruth,
				 layersfromtruth
	};

	/*
	cout << " ievent " << _ievent
	     << " gtrackID " << gtrackID
	     << " gflavor " << gflavor
	     << " ng4hits " << ng4hits
	     << endl;
	*/

	_ntp_gtrack->Fill(gtrack_data);

      }	     
    }
  }
  
  //------------------------
  // fill the Track NTuple
  //------------------------



  if (_ntp_track) {
    //cout << "Filling ntp_track " << endl;

    // need things off of the DST...
    SvtxTrackMap* trackmap = findNode::getClass<SvtxTrackMap>(topNode,"SvtxTrackMap");
    SvtxClusterMap* clustermap = findNode::getClass<SvtxClusterMap>(topNode,"SvtxClusterMap");
    if (trackmap) {

      for (SvtxTrackMap::Iter iter = trackmap->begin();
	   iter != trackmap->end();
	   ++iter) {
    
	SvtxTrack* track = iter->second;

	float trackID   = track->get_id();     
	float charge    = track->get_charge();
	float quality   = track->get_quality();
	float chisq     = track->get_chisq();
	float ndf       = track->get_ndf();
	float nhits     = track->size_clusters();

	unsigned int layers = 0x0;
	for (SvtxTrack::ConstClusterIter iter = track->begin_clusters();
	     iter != track->end_clusters();
	     ++iter) {
	  unsigned int cluster_id = *iter;
	  SvtxCluster* cluster = clustermap->get(cluster_id);
	  unsigned int layer = cluster->get_layer();
	  if (layer < 31) layers |= (0x1 << layer);
	}
      
	float dca2d     = track->get_dca2d();
	float dca2dsigma = track->get_dca2d_error();
	float px        = track->get_px();
	float py        = track->get_py();
	float pz        = track->get_pz();
	float pcax      = track->get_x();
	float pcay      = track->get_y();
	float pcaz      = track->get_z();

	float presdphi = track->get_cal_dphi(SvtxTrack::PRES);
	float presdeta = track->get_cal_deta(SvtxTrack::PRES);
	float prese3x3 = track->get_cal_energy_3x3(SvtxTrack::PRES);
	float prese    = track->get_cal_cluster_e(SvtxTrack::PRES);

	float cemcdphi = track->get_cal_dphi(SvtxTrack::CEMC);
	float cemcdeta = track->get_cal_deta(SvtxTrack::CEMC);
	float cemce3x3 = track->get_cal_energy_3x3(SvtxTrack::CEMC);
	float cemce    = track->get_cal_cluster_e(SvtxTrack::CEMC);

	float hcalindphi = track->get_cal_dphi(SvtxTrack::HCALIN);
	float hcalindeta = track->get_cal_deta(SvtxTrack::HCALIN);
	float hcaline3x3 = track->get_cal_energy_3x3(SvtxTrack::HCALIN);
	float hcaline    = track->get_cal_cluster_e(SvtxTrack::HCALIN);

	float hcaloutdphi = track->get_cal_dphi(SvtxTrack::HCALOUT);
	float hcaloutdeta = track->get_cal_deta(SvtxTrack::HCALOUT);
	float hcaloute3x3 = track->get_cal_energy_3x3(SvtxTrack::HCALOUT);
	float hcaloute    = track->get_cal_cluster_e(SvtxTrack::HCALOUT);

	float gtrackID = NAN;
	float gflavor  = NAN;     
	float ng4hits  = NAN;
	float gpx      = NAN;
	float gpy      = NAN;
	float gpz      = NAN;
	float gvx      = NAN;
	float gvy      = NAN;
	float gvz      = NAN;
	float gvt      = NAN;
	float gfpx     = NAN;
	float gfpy     = NAN;
	float gfpz     = NAN;
	float gfx      = NAN;
	float gfy      = NAN;
	float gfz      = NAN;
	float gembed   = NAN;
	float gprimary = NAN;

	float nfromtruth = NAN;
	float layersfromtruth = NAN;
      
	PHG4Particle* g4particle = trackeval->max_truth_particle_by_nclusters(track);	
	
	if (g4particle) {

	  if (_scan_for_embedded) {
	    if (trutheval->get_embed(g4particle) == 0) continue;
	  }
	  
	  gtrackID = g4particle->get_track_id();
	  gflavor  = g4particle->get_pid();
      
	  std::set<PHG4Hit*> g4hits = trutheval->all_truth_hits(g4particle);     
	  ng4hits = g4hits.size();  
	  gpx      = g4particle->get_px();
	  gpy      = g4particle->get_py();
	  gpz      = g4particle->get_pz();
	
	  PHG4VtxPoint* vtx = trutheval->get_vertex(g4particle);	
	  gvx      = vtx->get_x();
	  gvy      = vtx->get_y();
	  gvz      = vtx->get_z();
	  gvt      = vtx->get_t();

	  PHG4Hit* outerhit = trutheval->get_outermost_truth_hit(g4particle);	      
	  if (outerhit) {
	    gfpx     = outerhit->get_px(1);
	    gfpy     = outerhit->get_py(1);
	    gfpz     = outerhit->get_pz(1);
	    gfx      = outerhit->get_x(1);
	    gfy      = outerhit->get_y(1);
	    gfz      = outerhit->get_z(1);
	  }
	  gembed   = trutheval->get_embed(g4particle);
	  gprimary = trutheval->is_primary(g4particle);

	  nfromtruth = trackeval->get_nclusters_contribution(track,g4particle);
	  layersfromtruth = trackeval->get_nclusters_contribution_by_layer(track,g4particle);
	}
      
	float track_data[52] = {(float) _ievent,
				trackID, 
				px,        
				py,        
				pz,      
				charge,  
				quality, 
				chisq,   
				ndf,     
				nhits,   
				(float) layers,
				dca2d,     
				dca2dsigma,      
				pcax,      
				pcay,      
				pcaz,      
				presdphi,
				presdeta,
				prese3x3,
				prese,   
				cemcdphi,
				cemcdeta,
				cemce3x3,
				cemce,   
				hcalindphi,
				hcalindeta,
				hcaline3x3,
				hcaline,   
				hcaloutdphi,
				hcaloutdeta,
				hcaloute3x3,
				hcaloute,
				gtrackID,
				gflavor,
				ng4hits,
				gpx,
				gpy,
				gpz,
				gvx,
				gvy,
				gvz,
				gvt,
				gfpx,
				gfpy,
				gfpz,
				gfx,
				gfy,
				gfz,
				gembed,
				gprimary,
				nfromtruth,
				layersfromtruth
	};

	/*
	cout << "ievent " << _ievent
	     << " trackID " << trackID
	     << " nhits " << nhits
	     << " px " << px
	     << " py " << py
	     << " pz " << pz
	     << " gembed " << gembed
	     << " gprimary " << gprimary 
	     << endl;
	*/
	_ntp_track->Fill(track_data);
      }
    }
  }
  
  return;
}
예제 #4
0
void SvtxEvaluator::printOutputInfo(PHCompositeNode *topNode) {
  
  if (verbosity > 1) cout << "SvtxEvaluator::printOutputInfo() entered" << endl;

  //==========================================
  // print out some useful stuff for debugging
  //==========================================

  if (verbosity > 0) {
    
    SvtxTrackEval*     trackeval = _svtxevalstack->get_track_eval();
    SvtxClusterEval* clustereval = _svtxevalstack->get_cluster_eval();
    SvtxTruthEval*     trutheval = _svtxevalstack->get_truth_eval();
  
    // event information
    cout << endl;
    cout << PHWHERE << "   NEW OUTPUT FOR EVENT " << _ievent << endl;
    cout << endl;

    PHG4TruthInfoContainer* truthinfo = findNode::getClass<PHG4TruthInfoContainer>(topNode,"G4TruthInfo");
    
    PHG4VtxPoint *gvertex = truthinfo->GetPrimaryVtx( truthinfo->GetPrimaryVertexIndex() );
    float gvx = gvertex->get_x();
    float gvy = gvertex->get_y();
    float gvz = gvertex->get_z();

    float vx = NAN;
    float vy = NAN;
    float vz = NAN;

    SvtxVertexMap* vertexmap = findNode::getClass<SvtxVertexMap>(topNode,"SvtxVertexMap");    
    if (vertexmap) {
      if (!vertexmap->empty()) {
	SvtxVertex* vertex = (vertexmap->begin()->second);
	
	vx = vertex->get_x();
	vy = vertex->get_y();
	vz = vertex->get_z();
      }
    }

    cout << "===Vertex Reconstruction=======================" << endl;
    cout << "vtrue = (" << gvx << "," << gvy << "," << gvz << ") => vreco = (" << vx << "," << vy << "," << vz << ")" << endl;
    cout << endl;

    cout << "===Tracking Summary============================" << endl;
    unsigned int ng4hits[100] = {0};
    std::set<PHG4Hit*> g4hits = trutheval->all_truth_hits();
    for (std::set<PHG4Hit*>::iterator iter = g4hits.begin();
	 iter != g4hits.end();
	 ++iter) {
      PHG4Hit *g4hit = *iter;
      ++ng4hits[g4hit->get_layer()];
    }

    SvtxHitMap* hitmap = findNode::getClass<SvtxHitMap>(topNode,"SvtxHitMap");
    unsigned int nhits[100] = {0};
    if (hitmap) {
      for (SvtxHitMap::Iter iter = hitmap->begin();
	   iter != hitmap->end();
	   ++iter) {
	SvtxHit* hit = iter->second;
	++nhits[hit->get_layer()];
      }
    }
    
    SvtxClusterMap* clustermap = findNode::getClass<SvtxClusterMap>(topNode,"SvtxClusterMap");
    unsigned int nclusters[100] = {0};
    if (clustermap) {
      for (SvtxClusterMap::Iter iter = clustermap->begin();
	   iter != clustermap->end();
	   ++iter) {
	SvtxCluster* cluster = iter->second;
	++nclusters[cluster->get_layer()];
      }
    }

    for (unsigned int ilayer = 0; ilayer < 100; ++ilayer) {
      cout << "layer " << ilayer << ": nG4hits = " << ng4hits[ilayer]
	   << " => nHits = " << nhits[ilayer]
	   << " => nClusters = " << nclusters[ilayer] << endl;
    }

    SvtxTrackMap* trackmap = findNode::getClass<SvtxTrackMap>(topNode,"SvtxTrackMap");
    
    cout << "nGtracks = " << std::distance(truthinfo->GetPrimaryParticleRange().first,
					  truthinfo->GetPrimaryParticleRange().second);
    cout << " => nTracks = ";
    if (trackmap) cout << trackmap->size() << endl;
    else cout << 0 << endl;

    // cluster wise information
    if (verbosity > 1) {
 
      for(std::set<PHG4Hit*>::iterator iter = g4hits.begin();
	  iter != g4hits.end();
	  ++iter) {
	PHG4Hit *g4hit = *iter;

	cout << endl;
        cout << "===PHG4Hit===================================" << endl;
	cout << " PHG4Hit: "; g4hit->identify();

	std::set<SvtxCluster*> clusters = clustereval->all_clusters_from(g4hit);

	for (std::set<SvtxCluster*>::iterator jter = clusters.begin();
	     jter != clusters.end();
	     ++jter) {
	  SvtxCluster *cluster = *jter;
	  cout << "===Created-SvtxCluster================" << endl;      
	  cout << "SvtxCluster: "; cluster->identify();
	}
      }

      PHG4TruthInfoContainer::ConstRange range = truthinfo->GetPrimaryParticleRange();
      for (PHG4TruthInfoContainer::ConstIterator iter = range.first;
	   iter != range.second; 
	   ++iter) {
	
	PHG4Particle *particle = iter->second;

	// track-wise information
	cout << endl;

	cout << "=== Gtrack ===================================================" << endl;
	cout << " PHG4Particle id = " << particle->get_track_id() << endl;
	particle->identify();
	cout << " ptrue = (";
	cout.width(5); cout << particle->get_px();
	cout << ",";
	cout.width(5); cout << particle->get_py();
	cout << ",";
	cout.width(5); cout << particle->get_pz();
	cout << ")" << endl;

	cout << " vtrue = (";
	cout.width(5); cout << truthinfo->GetVtx(particle->get_vtx_id())->get_x();
	cout << ",";
	cout.width(5); cout << truthinfo->GetVtx(particle->get_vtx_id())->get_y();
	cout << ",";
	cout.width(5); cout << truthinfo->GetVtx(particle->get_vtx_id())->get_z();
	cout << ")" << endl;
	  
	cout << " pt = " << sqrt(pow(particle->get_px(),2)+pow(particle->get_py(),2)) << endl;
	cout << " phi = " << atan2(particle->get_py(),particle->get_px()) << endl;
	cout << " eta = " << asinh(particle->get_pz()/sqrt(pow(particle->get_px(),2)+pow(particle->get_py(),2))) << endl;
	  
	cout << " embed flag = " << truthinfo->isEmbeded(particle->get_track_id()) << endl;

	cout << " ---Associated-PHG4Hits-----------------------------------------" << endl;
	std::set<PHG4Hit*> g4hits = trutheval->all_truth_hits(particle);
	for(std::set<PHG4Hit*>::iterator jter = g4hits.begin();
	    jter != g4hits.end();
	    ++jter) {
	  PHG4Hit *g4hit = *jter;

	  float x = 0.5*(g4hit->get_x(0)+g4hit->get_x(1));
	  float y = 0.5*(g4hit->get_y(0)+g4hit->get_y(1));
	  float z = 0.5*(g4hit->get_z(0)+g4hit->get_z(1));
	      
	  cout << " #" << g4hit->get_hit_id() << " xtrue = (";
	  cout.width(5); cout << x;
	  cout << ",";
	  cout.width(5); cout << y;
	  cout << ",";
	  cout.width(5); cout << z;
	  cout << ")";

	  std::set<SvtxCluster*> clusters = clustereval->all_clusters_from(g4hit);
	  for (std::set<SvtxCluster*>::iterator kter = clusters.begin();
	       kter != clusters.end();
	       ++kter) {
	  
	    SvtxCluster *cluster = *kter;

	    float x = cluster->get_x();
	    float y = cluster->get_y();
	    float z = cluster->get_z();
		 
	    cout << " => #" << cluster->get_id(); 
	    cout << " xreco = (";
	    cout.width(5); cout << x;
	    cout << ",";
	    cout.width(5); cout << y;
	    cout << ",";
	    cout.width(5); cout << z;
	    cout << ")";
	  }

	  cout << endl;
	}

	if (trackmap&&clustermap) {

	  std::set<SvtxTrack*> tracks = trackeval->all_tracks_from(particle);
	  for (std::set<SvtxTrack*>::iterator jter = tracks.begin();
	       jter != tracks.end();
	       ++jter) {
	  
	    SvtxTrack *track = *jter;

	    float px = track->get_px();
	    float py = track->get_py();
	    float pz = track->get_pz();

	    cout << "===Created-SvtxTrack==========================================" << endl;
	    cout << " SvtxTrack id = " << track->get_id() << endl;
	    cout << " preco = (";
	    cout.width(5); cout << px;
	    cout << ",";
	    cout.width(5); cout << py;
	    cout << ",";
	    cout.width(5); cout << pz;
	    cout << ")" << endl;
	    cout << " quality = " << track->get_quality() << endl;
	    cout << " nfromtruth = " << trackeval->get_nclusters_contribution(track,particle) << endl;

	    cout << " ---Associated-SvtxClusters-to-PHG4Hits-------------------------" << endl;    

	    for (SvtxTrack::ConstClusterIter iter = track->begin_clusters();
		 iter != track->end_clusters();
		 ++iter) {
	      unsigned int cluster_id = *iter;
	      SvtxCluster* cluster = clustermap->get(cluster_id);
	      		  
	      float x = cluster->get_x();
	      float y = cluster->get_y();
	      float z = cluster->get_z();
			  
	      cout << " #" << cluster->get_id() << " xreco = (";
	      cout.width(5); cout << x;
	      cout << ",";
	      cout.width(5); cout << y;
	      cout << ",";
	      cout.width(5); cout << z;
	      cout << ") =>";

	      PHG4Hit* g4hit = clustereval->max_truth_hit_by_energy(cluster);
	      if ((g4hit) && (g4hit->get_trkid() == particle->get_track_id())) {
			  
		x = 0.5*(g4hit->get_x(0)+g4hit->get_x(1));
		y = 0.5*(g4hit->get_y(0)+g4hit->get_y(1));
		z = 0.5*(g4hit->get_z(0)+g4hit->get_z(1));
			    
		cout << " #" << g4hit->get_hit_id()
		     << " xtrue = (";
		cout.width(5); cout << x;
		cout << ",";
		cout.width(5); cout << y;
		cout << ",";
		cout.width(5); cout << z;
		cout << ") => Gtrack id = " << g4hit->get_trkid();
	      } else {
		cout << " noise hit";
	      }
	    }
  
	    cout << endl;
	  }
	}
      }
    }
      
    cout << endl;

  } // if verbosity

  return;
}
예제 #5
0
void SvtxEvaluator::fillOutputNtuples(PHCompositeNode *topNode) {

  if (verbosity > 1) cout << "SvtxEvaluator::fillOutputNtuples() entered" << endl;

  SvtxVertexEval*   vertexeval = _svtxevalstack->get_vertex_eval();
  SvtxTrackEval*     trackeval = _svtxevalstack->get_track_eval();
  SvtxClusterEval* clustereval = _svtxevalstack->get_cluster_eval();
  SvtxHitEval*         hiteval = _svtxevalstack->get_hit_eval();
  SvtxTruthEval*     trutheval = _svtxevalstack->get_truth_eval();
  
  //-----------------------
  // fill the Vertex NTuple
  //-----------------------

  if (_ntp_vertex) {
    SvtxVertexMap* vertexmap = findNode::getClass<SvtxVertexMap>(topNode,"SvtxVertexMap");
    PHG4TruthInfoContainer* truthinfo = findNode::getClass<PHG4TruthInfoContainer>(topNode,"G4TruthInfo");
    if (vertexmap && truthinfo) {
      for (SvtxVertexMap::Iter iter = vertexmap->begin();
	   iter != vertexmap->end();
	   ++iter) {
	SvtxVertex* vertex = iter->second;
	PHG4VtxPoint* point = vertexeval->max_truth_point_by_ntracks(vertex);

	float vx         = vertex->get_x();
	float vy         = vertex->get_y();
	float vz         = vertex->get_z();
	float ntracks    = vertex->size_tracks();

	float gvx        = NAN;
	float gvy        = NAN;
	float gvz        = NAN;
	float gntracks   = truthinfo->GetNumPrimaryVertexParticles();
	float nfromtruth = NAN;
	
	if (point) {
	  gvx        = point->get_x();
	  gvy        = point->get_y();
	  gvz        = point->get_z();
	  gntracks   = truthinfo->GetNumPrimaryVertexParticles();
	  nfromtruth = vertexeval->get_ntracks_contribution(vertex,point);
	}
	  
	float vertex_data[10] = {_ievent,
				 vx,
				 vy,
				 vz,
				 ntracks,
				 gvx,
				 gvy,
				 gvz,
				 gntracks,
				 nfromtruth
	};

	_ntp_vertex->Fill(vertex_data);      
      }
    }
  }
  
  //-----------------------
  // fill the gpoint NTuple
  //-----------------------

  if (_ntp_gpoint) {
    SvtxVertexMap* vertexmap = findNode::getClass<SvtxVertexMap>(topNode,"SvtxVertexMap");
    PHG4TruthInfoContainer* truthinfo = findNode::getClass<PHG4TruthInfoContainer>(topNode,"G4TruthInfo");
    if (vertexmap && truthinfo) {

      PHG4VtxPoint* point =  truthinfo->GetPrimaryVtx(truthinfo->GetPrimaryVertexIndex());
      SvtxVertex* vertex = vertexeval->best_vertex_from(point);
    
      float gvx        = point->get_x();
      float gvy        = point->get_y();
      float gvz        = point->get_z();
      float gntracks   = truthinfo->GetNumPrimaryVertexParticles();
      float vx         = NAN;
      float vy         = NAN;
      float vz         = NAN;
      float ntracks    = NAN;
      float nfromtruth = NAN;

      if (vertex) {
	vx         = vertex->get_x();
	vy         = vertex->get_y();
	vz         = vertex->get_z();
	ntracks    = vertex->size_tracks();
	nfromtruth = vertexeval->get_ntracks_contribution(vertex,point);
      }
	
      float gpoint_data[10] = {_ievent,
			       gvx,
			       gvy,
			       gvz,
			       gntracks,
			       vx,
			       vy,
			       vz,
			       ntracks,
			       nfromtruth
      };

      _ntp_gpoint->Fill(gpoint_data);      
    }
  }
  
  //---------------------
  // fill the G4hit NTuple
  //---------------------

  if (_ntp_g4hit) {
    std::set<PHG4Hit*> g4hits = trutheval->all_truth_hits();
    for (std::set<PHG4Hit*>::iterator iter = g4hits.begin();
	 iter != g4hits.end();
	 ++iter) {
            
      PHG4Hit *g4hit = *iter;
      PHG4Particle *g4particle = trutheval->get_particle(g4hit);
      
      float g4hitID   = g4hit->get_hit_id();
      float gx        = 0.5*(g4hit->get_x(0)+g4hit->get_x(1));
      float gy        = 0.5*(g4hit->get_y(0)+g4hit->get_y(1));
      float gz        = 0.5*(g4hit->get_z(0)+g4hit->get_z(1));
      float gedep     = g4hit->get_edep();
      float glayer    = g4hit->get_layer();
  
      float gtrackID  = g4hit->get_trkid();


      float gflavor   = NAN;
      float gpx       = NAN;
      float gpy       = NAN;
      float gpz       = NAN;

      float gvx       = NAN;
      float gvy       = NAN;
      float gvz       = NAN;

      float gembed  = NAN;
      float gprimary = NAN;

      float gfpx      = NULL;
      float gfpy      = NULL;
      float gfpz      = NULL;
      float gfx       = NULL;
      float gfy       = NULL;
      float gfz       = NULL;

      if (g4particle) {

	gflavor   = g4particle->get_pid();
	gpx       = g4particle->get_px();
	gpy       = g4particle->get_py();
	gpz       = g4particle->get_pz();

	PHG4VtxPoint* vtx = trutheval->get_vertex(g4particle);	

	if (vtx) {
	  gvx       = vtx->get_x();
	  gvy       = vtx->get_y();
	  gvz       = vtx->get_z();
	}
    
	PHG4Hit* outerhit = trutheval->get_outermost_truth_hit(g4particle);	
	if (outerhit) {
	  gfpx      = outerhit->get_px(1);
	  gfpy      = outerhit->get_py(1);
	  gfpz      = outerhit->get_pz(1);
	  gfx       = outerhit->get_x(1);
	  gfy       = outerhit->get_y(1);
	  gfz       = outerhit->get_z(1);
	}
	
	gembed    = trutheval->get_embed(g4particle);
	gprimary  = trutheval->is_primary(g4particle);
      } //       if (g4particle)
      
      std::set<SvtxCluster*> clusters = clustereval->all_clusters_from(g4hit);  
      float nclusters = clusters.size();

      // best cluster reco'd
      SvtxCluster* cluster = clustereval->best_cluster_from(g4hit);

      float clusID     = NAN;
      float x          = NAN;
      float y          = NAN;
      float z          = NAN;
      float e          = NAN;
      float adc        = NAN;
      float layer      = NAN;
      float size       = NAN;
      float phisize    = NAN;
      float zsize      = NAN;
      float efromtruth = NAN;

      if (cluster) {
	clusID     = cluster->get_id();
	x          = cluster->get_x();
	y          = cluster->get_y();
	z          = cluster->get_z();
	e          = cluster->get_e();
	adc        = cluster->get_adc();
	layer      = cluster->get_layer();
	size       = cluster->size_hits();
	phisize    = cluster->get_phi_size();
	zsize      = cluster->get_z_size();
	if (g4particle) {
	  efromtruth = clustereval->get_energy_contribution(cluster,g4particle);
	}
      }

      float g4hit_data[35] = {_ievent,
			      g4hitID,
			      gx,
			      gy,
			      gz,
			      gedep,
			      glayer,
			      gtrackID,
			      gflavor,
			      gpx,
			      gpy,
			      gpz,
			      gvx,
			      gvy,
			      gvz,
			      gfpx,
			      gfpy,
			      gfpz,
			      gfx,
			      gfy,
			      gfz,
			      gembed,
			      gprimary,
			      nclusters,
			      clusID,  
			      x,      
			      y,      
			      z,      
			      e,      
			      adc,    
			      layer,  
			      size,   
			      phisize,
			      zsize,  
			      efromtruth
      };

      _ntp_g4hit->Fill(g4hit_data);
    }
  }
  
  //--------------------
  // fill the Hit NTuple
  //--------------------

  if (_ntp_hit) {
    // need things off of the DST...
    SvtxHitMap* hitmap = findNode::getClass<SvtxHitMap>(topNode,"SvtxHitMap");
    if (hitmap) {

      for (SvtxHitMap::Iter iter = hitmap->begin();
	   iter != hitmap->end();
	   ++iter) {

	SvtxHit* hit             = iter->second;
	PHG4Hit* g4hit           = hiteval->max_truth_hit_by_energy(hit);
	PHG4CylinderCell* g4cell = hiteval->get_cell(hit);
	PHG4Particle* g4particle = trutheval->get_particle(g4hit);

	float event  = _ievent;
	float hitID  = hit->get_id();
	float e      = hit->get_e();
	float adc    = hit->get_adc();
	float layer  = hit->get_layer();
	float cellID = hit->get_cellid();
	float ecell  = g4cell->get_edep();

	float g4hitID  = NAN;
	float gedep    = NAN;
	float gx       = NAN;
	float gy       = NAN;
	float gz       = NAN;
	float gtrackID = NAN;
	float gflavor  = NAN;
	float gpx      = NAN;
	float gpy      = NAN;
	float gpz      = NAN;
	float gvx      = NAN;
	float gvy      = NAN;
	float gvz      = NAN;
	float gfpx     = NAN;
	float gfpy     = NAN;
	float gfpz     = NAN;
	float gfx      = NAN;
	float gfy      = NAN;
	float gfz      = NAN;
	float glast    = NAN;
	float gembed   = NAN;
	float gprimary = NAN;
      
	float efromtruth = NAN;
      
	if (g4hit) {
	  g4hitID  = g4hit->get_hit_id();
	  gedep    = g4hit->get_edep();
	  gx       = 0.5*(g4hit->get_x(0)+g4hit->get_x(1));
	  gy       = 0.5*(g4hit->get_y(0)+g4hit->get_y(1));
	  gz       = 0.5*(g4hit->get_z(0)+g4hit->get_z(1));
	  gx       = g4hit->get_x(0);
	  gy       = g4hit->get_y(0);
	  gz       = g4hit->get_z(0);

	  if (g4particle) {

	    gtrackID = g4particle->get_track_id();
	    gflavor  = g4particle->get_pid();
	    gpx      = g4particle->get_px();
	    gpy      = g4particle->get_py();
	    gpz      = g4particle->get_pz();

	    PHG4VtxPoint* vtx = trutheval->get_vertex(g4particle);

	    if (vtx) {
	      gvx      = vtx->get_x();
	      gvy      = vtx->get_y();
	      gvz      = vtx->get_z();
	    }

	    PHG4Hit* outerhit = trutheval->get_outermost_truth_hit(g4particle);	
	    if (outerhit) {
	      gfpx     = outerhit->get_px(1);
	      gfpy     = outerhit->get_py(1);
	      gfpz     = outerhit->get_pz(1);
	      gfx      = outerhit->get_x(1);
	      gfy      = outerhit->get_y(1);
	      gfz      = outerhit->get_z(1);
	    }
	    glast    = NAN;
	    gembed   = trutheval->get_embed(g4particle);
	    gprimary = trutheval->is_primary(g4particle);
	  } //   if (g4particle){
	}      

	if (g4particle) {
	  efromtruth = hiteval->get_energy_contribution(hit,g4particle);
	}

	float hit_data[32] = {
	  event,
	  hitID,
	  e,
	  adc,
	  layer,
	  cellID,
	  ecell,
	  g4hitID,
	  gedep,
	  gx,
	  gy,
	  gz,
	  gtrackID,
	  gflavor,
	  gpx,
	  gpy,
	  gpz,
	  gvx,
	  gvy,
	  gvz,
	  gfpx,
	  gfpy,
	  gfpz,
	  gfx,
	  gfy,
	  gfz,
	  gembed,
	  gprimary,
	  efromtruth
	};
	  
	_ntp_hit->Fill(hit_data);     
      }
    }
  }
  
  //------------------------
  // fill the Cluster NTuple
  //------------------------

  if (_ntp_cluster) {
    // need things off of the DST...
    SvtxClusterMap* clustermap = findNode::getClass<SvtxClusterMap>(topNode,"SvtxClusterMap");
    if (clustermap) {

      for (SvtxClusterMap::Iter iter = clustermap->begin();
	   iter != clustermap->end();
	   ++iter) {
    
	SvtxCluster* cluster     = iter->second;   
	PHG4Hit *g4hit           = clustereval->max_truth_hit_by_energy(cluster); 
	PHG4Particle *g4particle = trutheval->get_particle(g4hit);
    
	float hitID    = cluster->get_id();
	float x        = cluster->get_x();
	float y        = cluster->get_y();
	float z        = cluster->get_z();
	float e        = cluster->get_e();
	float adc      = cluster->get_adc();
	float layer    = cluster->get_layer();
	float size     = cluster->size_hits();
	float phisize  = cluster->get_phi_size();
	float zsize    = cluster->get_z_size();

	float g4hitID  = NAN;
	float gx       = NAN;
	float gy       = NAN;
	float gz       = NAN;
	float gtrackID = NAN;
	float gflavor  = NAN;
	float gpx      = NAN;
	float gpy      = NAN;
	float gpz      = NAN;
	float gvx      = NAN;
	float gvy      = NAN;
	float gvz      = NAN;
	float gfpx     = NAN;
	float gfpy     = NAN;
	float gfpz     = NAN;
	float gfx      = NAN;
	float gfy      = NAN;
	float gfz      = NAN;
	float glast    = NAN;
	float gembed   = NAN;
	float gprimary = NAN;
    
	float nhits      = NAN;
	float efromtruth = NAN;
      
	if (g4hit) {
	  g4hitID  = g4hit->get_hit_id();
	  gx       = 0.5*(g4hit->get_x(0)+g4hit->get_x(1));
	  gy       = 0.5*(g4hit->get_y(0)+g4hit->get_y(1));
	  gz       = 0.5*(g4hit->get_z(0)+g4hit->get_z(1));
	  gx       = g4hit->get_x(0);
	  gy       = g4hit->get_y(0);
	  gz       = g4hit->get_z(0);

	  if (g4particle) {

	    gtrackID = g4particle->get_track_id();
	    gflavor  = g4particle->get_pid();
	    gpx      = g4particle->get_px();
	    gpy      = g4particle->get_py();
	    gpz      = g4particle->get_pz();

	    PHG4VtxPoint* vtx = trutheval->get_vertex(g4particle);
	    if (vtx) {
	      gvx      = vtx->get_x();
	      gvy      = vtx->get_y();
	      gvz      = vtx->get_z();
	    }

	    PHG4Hit* outerhit = trutheval->get_outermost_truth_hit(g4particle);	
	    if (outerhit) {
	      gfpx     = outerhit->get_px(1);
	      gfpy     = outerhit->get_py(1);
	      gfpz     = outerhit->get_pz(1);
	      gfx      = outerhit->get_x(1);
	      gfy      = outerhit->get_y(1);
	      gfz      = outerhit->get_z(1);
	    }
	    
	    glast    = NAN;
	    gembed   = trutheval->get_embed(g4particle);
	    gprimary = trutheval->is_primary(g4particle);
	  }      //   if (g4particle){
	} //  if (g4hit) {

	if (g4particle){
	  efromtruth = clustereval->get_energy_contribution(cluster,g4particle);
	}

	float cluster_data[33] = {_ievent,
				  hitID,
				  x,
				  y,
				  z,
				  e,
				  adc,
				  layer,
				  size,
				  phisize,
				  zsize,
				  g4hitID,
				  gx,
				  gy,
				  gz,
				  gtrackID,
				  gflavor,
				  gpx,
				  gpy,
				  gpz,
				  gvx,
				  gvy,
				  gvz,
				  gfpx,
				  gfpy,
				  gfpz,
				  gfx,
				  gfy,
				  gfz,
				  gembed,
				  gprimary,
				  nhits,
				  efromtruth};

	_ntp_cluster->Fill(cluster_data);
      }		  
    }
  }
  
  //------------------------
  // fill the Gtrack NTuple
  //------------------------

  // need things off of the DST...

  if (_ntp_gtrack) {
    PHG4TruthInfoContainer* truthinfo = findNode::getClass<PHG4TruthInfoContainer>(topNode,"G4TruthInfo");   
    SvtxClusterMap* clustermap = findNode::getClass<SvtxClusterMap>(topNode,"SvtxClusterMap");
    if (truthinfo) {

      PHG4TruthInfoContainer::ConstRange range = truthinfo->GetPrimaryParticleRange();
      for (PHG4TruthInfoContainer::ConstIterator iter = range.first;
	   iter != range.second; 
	 ++iter) {
	
	PHG4Particle* g4particle = iter->second;
    
	float gtrackID = g4particle->get_track_id();
	float gflavor  = g4particle->get_pid();
      
	std::set<PHG4Hit*> g4hits = trutheval->all_truth_hits(g4particle);     
	float ng4hits = g4hits.size();  
	float gpx      = g4particle->get_px();
	float gpy      = g4particle->get_py();
	float gpz      = g4particle->get_pz();

	PHG4VtxPoint* vtx = trutheval->get_vertex(g4particle);	
	float gvx      = vtx->get_x();
	float gvy      = vtx->get_y();
	float gvz      = vtx->get_z();

	float gfpx      = NULL;
	float gfpy      = NULL;
	float gfpz      = NULL;
	float gfx       = NULL;
	float gfy       = NULL;
	float gfz       = NULL;
    
	PHG4Hit* outerhit = trutheval->get_outermost_truth_hit(g4particle);	
	if (outerhit) {
	  gfpx      = outerhit->get_px(1);
	  gfpy      = outerhit->get_py(1);
	  gfpz      = outerhit->get_pz(1);
	  gfx       = outerhit->get_x(1);
	  gfy       = outerhit->get_y(1);
	  gfz       = outerhit->get_z(1);
	}
      
	float gembed   = trutheval->get_embed(g4particle);
	float gprimary = trutheval->is_primary(g4particle);

	SvtxTrack* track = trackeval->best_track_from(g4particle);

	float trackID       = NAN;
	float charge        = NAN;
	float quality       = NAN;
	float chisq         = NAN;
	float ndf           = NAN;
	float nhits         = NAN;
	unsigned int layers = 0x0;
	float dca           = NAN;
	float dca2d         = NAN;
	float dca2dsigma    = NAN;
	float px            = NAN;
	float py            = NAN;
	float pz            = NAN;
	float pcax          = NAN;
	float pcay          = NAN;
	float pcaz          = NAN;

	float nfromtruth    = NAN;

	if (track) {
	  trackID   = track->get_id();     
	  charge    = track->get_charge();
	  quality   = track->get_quality();
	  chisq     = track->get_chisq();
	  ndf       = track->get_ndf();
	  nhits     = track->size_clusters();
	  
	  for (SvtxTrack::ConstClusterIter iter = track->begin_clusters();
	       iter != track->end_clusters();
	       ++iter) {
	    unsigned int cluster_id = *iter;
	    SvtxCluster* cluster = clustermap->get(cluster_id);
	    unsigned int layer = cluster->get_layer();
	    if (layer < 32) layers |= (0x1 << layer);
	  }

	  dca       = track->get_dca();
	  dca2d     = track->get_dca2d();
	  dca2dsigma = track->get_dca2d_error();
	  px        = track->get_px();
	  py        = track->get_py();
	  pz        = track->get_pz();
	  pcax      = track->get_x();
	  pcay      = track->get_y();
	  pcaz      = track->get_z();

	  nfromtruth = trackeval->get_nclusters_contribution(track,g4particle);
	}
      
	float gtrack_data[34] = {_ievent,
				 gtrackID,
				 gflavor,
				 ng4hits,
				 gpx,
				 gpy,
				 gpz,
				 gvx,
				 gvy,
				 gvz,
				 gfpx,
				 gfpy,
				 gfpz,
				 gfx,
				 gfy,
				 gfz,
				 gembed,
				 gprimary,
				 trackID,
				 px,         
				 py,         
				 pz,  
				 charge,     
				 quality,    
				 chisq,      
				 ndf,        
				 nhits,      
				 layers,     
				 dca2d,      
				 dca2dsigma, 			       
				 pcax,       
				 pcay,       
				 pcaz,
				 nfromtruth
	};

	_ntp_gtrack->Fill(gtrack_data);
      }	     
    }
  }
  
  //------------------------
  // fill the Track NTuple
  //------------------------

  if (_ntp_track) {
    // need things off of the DST...
    SvtxTrackMap* trackmap = findNode::getClass<SvtxTrackMap>(topNode,"SvtxTrackMap");
    SvtxClusterMap* clustermap = findNode::getClass<SvtxClusterMap>(topNode,"SvtxClusterMap");
    if (trackmap) {

      for (SvtxTrackMap::Iter iter = trackmap->begin();
	   iter != trackmap->end();
	   ++iter) {
    
	SvtxTrack* track = iter->second;

	float trackID   = track->get_id();     
	float charge    = track->get_charge();
	float quality   = track->get_quality();
	float chisq     = track->get_chisq();
	float ndf       = track->get_ndf();
	float nhits     = track->size_clusters();

	unsigned int layers = 0x0;
	for (SvtxTrack::ConstClusterIter iter = track->begin_clusters();
	     iter != track->end_clusters();
	     ++iter) {
	  unsigned int cluster_id = *iter;
	  SvtxCluster* cluster = clustermap->get(cluster_id);
	  unsigned int layer = cluster->get_layer();
	  if (layer < 32) layers |= (0x1 << layer);
	}
      
	float dca2d     = track->get_dca2d();
	float dca2dsigma = track->get_dca2d_error();
	float px        = track->get_px();
	float py        = track->get_py();
	float pz        = track->get_pz();
	float pcax      = track->get_x();
	float pcay      = track->get_y();
	float pcaz      = track->get_z();

	float presdphi = track->get_cal_dphi(SvtxTrack::PRES);
	float presdeta = track->get_cal_deta(SvtxTrack::PRES);
	float prese3x3 = track->get_cal_energy_3x3(SvtxTrack::PRES);
	float prese    = track->get_cal_cluster_e(SvtxTrack::PRES);

	float cemcdphi = track->get_cal_dphi(SvtxTrack::CEMC);
	float cemcdeta = track->get_cal_deta(SvtxTrack::CEMC);
	float cemce3x3 = track->get_cal_energy_3x3(SvtxTrack::CEMC);
	float cemce    = track->get_cal_cluster_e(SvtxTrack::CEMC);

	float hcalindphi = track->get_cal_dphi(SvtxTrack::HCALIN);
	float hcalindeta = track->get_cal_deta(SvtxTrack::HCALIN);
	float hcaline3x3 = track->get_cal_energy_3x3(SvtxTrack::HCALIN);
	float hcaline    = track->get_cal_cluster_e(SvtxTrack::HCALIN);

	float hcaloutdphi = track->get_cal_dphi(SvtxTrack::HCALOUT);
	float hcaloutdeta = track->get_cal_deta(SvtxTrack::HCALOUT);
	float hcaloute3x3 = track->get_cal_energy_3x3(SvtxTrack::HCALOUT);
	float hcaloute    = track->get_cal_cluster_e(SvtxTrack::HCALOUT);

	float gtrackID = NAN;
	float gflavor  = NAN;     
	float ng4hits  = NAN;
	float gpx      = NAN;
	float gpy      = NAN;
	float gpz      = NAN;
	float gvx      = NAN;
	float gvy      = NAN;
	float gvz      = NAN;
	float gfpx     = NAN;
	float gfpy     = NAN;
	float gfpz     = NAN;
	float gfx      = NAN;
	float gfy      = NAN;
	float gfz      = NAN;
	float gembed   = NAN;
	float gprimary = NAN;

	float nfromtruth = NAN;
      
	PHG4Particle* g4particle = trackeval->max_truth_particle_by_nclusters(track);
      
	if (g4particle) {
	  gtrackID = g4particle->get_track_id();
	  gflavor  = g4particle->get_pid();
      
	  std::set<PHG4Hit*> g4hits = trutheval->all_truth_hits(g4particle);     
	  ng4hits = g4hits.size();  
	  gpx      = g4particle->get_px();
	  gpy      = g4particle->get_py();
	  gpz      = g4particle->get_pz();
	
	  PHG4VtxPoint* vtx = trutheval->get_vertex(g4particle);	
	  gvx      = vtx->get_x();
	  gvy      = vtx->get_y();
	  gvz      = vtx->get_z();

	  PHG4Hit* outerhit = trutheval->get_outermost_truth_hit(g4particle);	      
	  if (outerhit) {
	    gfpx     = outerhit->get_px(1);
	    gfpy     = outerhit->get_py(1);
	    gfpz     = outerhit->get_pz(1);
	    gfx      = outerhit->get_x(1);
	    gfy      = outerhit->get_y(1);
	    gfz      = outerhit->get_z(1);
	  }
	  gembed   = trutheval->get_embed(g4particle);
	  gprimary = trutheval->is_primary(g4particle);

	  nfromtruth = trackeval->get_nclusters_contribution(track,g4particle);
	}
      
	float track_data[50] = {_ievent,
				trackID, 
				px,        
				py,        
				pz,      
				charge,  
				quality, 
				chisq,   
				ndf,     
				nhits,   
				layers,
				dca2d,     
				dca2dsigma,      
				pcax,      
				pcay,      
				pcaz,      
				presdphi,
				presdeta,
				prese3x3,
				prese,   
				cemcdphi,
				cemcdeta,
				cemce3x3,
				cemce,   
				hcalindphi,
				hcalindeta,
				hcaline3x3,
				hcaline,   
				hcaloutdphi,
				hcaloutdeta,
				hcaloute3x3,
				hcaloute,
				gtrackID,
				gflavor,
				ng4hits,
				gpx,
				gpy,
				gpz,
				gvx,
				gvy,
				gvz,
				gfpx,
				gfpy,
				gfpz,
				gfx,
				gfy,
				gfz,
				gembed,
				gprimary,
				nfromtruth
	};
      
	_ntp_track->Fill(track_data);
      }
    }
  }
  
  return;
}
int PHG4GenFitTrackProjection::process_event(PHCompositeNode *topNode) {
	if (verbosity > 1)
		cout << "PHG4GenFitTrackProjection::process_event -- entered" << endl;

	//---------------------------------
	// Get Objects off of the Node Tree
	//---------------------------------

	// Pull the reconstructed track information off the node tree...
	SvtxTrackMap* _g4tracks = findNode::getClass<SvtxTrackMap>(topNode,
			"SvtxTrackMap");
	if (!_g4tracks) {
		cerr << PHWHERE << " ERROR: Can't find SvtxTrackMap." << endl;
		return Fun4AllReturnCodes::ABORTRUN;
	}

	for (int i = 0; i < _num_cal_layers; ++i) {

		if (std::isnan(_cal_radii[i]))
			continue;

		if (verbosity > 1)
			cout << "Projecting tracks into: " << _cal_names[i] << endl;

		// pull the tower geometry
		string towergeonodename = "TOWERGEOM_" + _cal_names[i];
		RawTowerGeomContainer *towergeo = findNode::getClass<
				RawTowerGeomContainer>(topNode, towergeonodename.c_str());
		if (!towergeo) {
			cerr << PHWHERE << " ERROR: Can't find node " << towergeonodename
					<< endl;
			return Fun4AllReturnCodes::ABORTRUN;
		}

		// pull the towers
		string towernodename = "TOWER_CALIB_" + _cal_names[i];
		RawTowerContainer *towerList = findNode::getClass<RawTowerContainer>(
				topNode, towernodename.c_str());
		if (!towerList) {
			cerr << PHWHERE << " ERROR: Can't find node " << towernodename
					<< endl;
			return Fun4AllReturnCodes::ABORTRUN;
		}

		// pull the clusters
		string clusternodename = "CLUSTER_" + _cal_names[i];
		RawClusterContainer *clusterList = findNode::getClass<
				RawClusterContainer>(topNode, clusternodename.c_str());
		if (!clusterList) {
			cerr << PHWHERE << " ERROR: Can't find node " << clusternodename
					<< endl;
			return Fun4AllReturnCodes::ABORTRUN;
		}

		// loop over all tracks
		for (SvtxTrackMap::Iter iter = _g4tracks->begin();
				iter != _g4tracks->end(); ++iter) {
			SvtxTrack *track = iter->second;
#ifdef DEBUG
			cout
			<<__LINE__
			<<": track->get_charge(): "<<track->get_charge()
			<<endl;
#endif
			if(!track) {
				if(verbosity >= 2) LogWarning("!track");
				continue;
			}

			if (verbosity > 1)
				cout << "projecting track id " << track->get_id() << endl;

			if (verbosity > 1) {
				cout << " track pt = " << track->get_pt() << endl;
			}

			std::vector<double> point;
			point.assign(3, -9999.);

			auto last_state_iter = --track->end_states();

			SvtxTrackState * trackstate = last_state_iter->second;

			if(!trackstate) {
				if(verbosity >= 2) LogWarning("!trackstate");
				continue;
			}

			auto pdg = unique_ptr<TDatabasePDG> (TDatabasePDG::Instance());
			int reco_charge = track->get_charge();
			int gues_charge = pdg->GetParticle(_pid_guess)->Charge();
			if(reco_charge*gues_charge<0) _pid_guess *= -1;
#ifdef DEBUG
			cout
			<<__LINE__
			<<": guess charge: " << gues_charge
			<<": reco charge: " << reco_charge
			<<": pid: " << _pid_guess
			<<": pT: " << sqrt(trackstate->get_px()*trackstate->get_px() + trackstate->get_py()*trackstate->get_py())
			<<endl;
#endif

			auto rep = unique_ptr<genfit::AbsTrackRep> (new genfit::RKTrackRep(_pid_guess));

			unique_ptr<genfit::MeasuredStateOnPlane> msop80 = nullptr;

			{
				TVector3 pos(trackstate->get_x(), trackstate->get_y(), trackstate->get_z());
				//pos.SetXYZ(0.01,0,0);

				TVector3 mom(trackstate->get_px(), trackstate->get_py(), trackstate->get_pz());
				//mom.SetXYZ(1,0,0);

				TMatrixDSym cov(6);
				for (int i = 0; i < 6; ++i) {
					for (int j = 0; j < 6; ++j) {
						cov[i][j] = trackstate->get_error(i, j);
					}
				}

				msop80 = unique_ptr<genfit::MeasuredStateOnPlane> (new genfit::MeasuredStateOnPlane(rep.get()));

				msop80->setPosMomCov(pos, mom, cov);
			}

#ifdef DEBUG
			{
				double x = msop80->getPos().X();
				double y = msop80->getPos().Y();
				double z = msop80->getPos().Z();
//				double px = msop80->getMom().X();
//				double py = msop80->getMom().Y();
				double pz = msop80->getMom().Z();
				genfit::FieldManager *field_mgr = genfit::FieldManager::getInstance();
				double Bx=0, By=0, Bz=0;
				field_mgr->getFieldVal(x,y,z,Bx,By,Bz);
				cout
				<< __LINE__
				<< ": { " << msop80->getPos().Perp() << ", " << msop80->getPos().Phi() << ", " << msop80->getPos().Eta() << "} @ "
				//<< "{ " << Bx << ", " << By << ", " << Bz << "}"
				<< "{ " << msop80->getMom().Perp() << ", " << msop80->getMom().Phi() << ", " << pz << "} "
				<<endl;
				//msop80->Print();
			}
#endif
			try {
				rep->extrapolateToCylinder(*msop80, _cal_radii[i], TVector3(0,0,0),  TVector3(0,0,1));
				//rep->extrapolateToCylinder(*msop80, 5., TVector3(0,0,0),  TVector3(0,0,1));
			} catch (...) {
				if(verbosity >= 2) LogWarning("extrapolateToCylinder failed");
				continue;
			}

#ifdef DEBUG
			{
				cout<<__LINE__<<endl;
				//msop80->Print();
				double x = msop80->getPos().X();
				double y = msop80->getPos().Y();
				double z = msop80->getPos().Z();
//				double px = msop80->getMom().X();
//				double py = msop80->getMom().Y();
				double pz = msop80->getMom().Z();
				genfit::FieldManager *field_mgr = genfit::FieldManager::getInstance();
				double Bx=0, By=0, Bz=0;
				field_mgr->getFieldVal(x,y,z,Bx,By,Bz);
				cout
				<< __LINE__
				<< ": { " << msop80->getPos().Perp() << ", " << msop80->getPos().Phi() << ", " << msop80->getPos().Eta() << "} @ "
				//<< "{ " << Bx << ", " << By << ", " << Bz << "}"
				<< "{ " << msop80->getMom().Perp() << ", " << msop80->getMom().Phi() << ", " << pz << "} "
				<<endl;
			}
#endif

			point[0] = msop80->getPos().X();
			point[1] = msop80->getPos().Y();
			point[2] = msop80->getPos().Z();

#ifdef DEBUG
			cout
			<<__LINE__
			<<": GenFit: {"
			<< point[0] <<", "
			<< point[1] <<", "
			<< point[2] <<" }"
			<<endl;
#endif

			if (std::isnan(point[0]))
				continue;
			if (std::isnan(point[1]))
				continue;
			if (std::isnan(point[2]))
				continue;

			double x = point[0];
			double y = point[1];
			double z = point[2];

			double phi = atan2(y, x);
			double eta = asinh(z / sqrt(x * x + y * y));

			if (verbosity > 1) {
				cout << " initial track phi = " << track->get_phi();
				cout << ", eta = " << track->get_eta() << endl;
				cout << " calorimeter phi = " << phi << ", eta = " << eta
						<< endl;
			}

			// projection is outside the detector extent
			// TODO towergeo doesn't make this easy to extract, but this should be
			// fetched from the node tree instead of hardcoded
			if (fabs(eta) >= 1.0)
				continue;

			// calculate 3x3 tower energy
			int binphi = towergeo->get_phibin(phi);
			int bineta = towergeo->get_etabin(eta);

			double energy_3x3 = 0.0;
			double energy_5x5 = 0.0;
			for (int iphi = binphi - 2; iphi <= binphi + 2; ++iphi) {
				for (int ieta = bineta - 2; ieta <= bineta + 2; ++ieta) {

					// wrap around
					int wrapphi = iphi;
					if (wrapphi < 0) {
						wrapphi = towergeo->get_phibins() + wrapphi;
					}
					if (wrapphi >= towergeo->get_phibins()) {
						wrapphi = wrapphi - towergeo->get_phibins();
					}

					// edges
					if (ieta < 0)
						continue;
					if (ieta >= towergeo->get_etabins())
						continue;

					RawTower* tower = towerList->getTower(ieta, wrapphi);
					if (tower) {

						energy_5x5 += tower->get_energy();
						if (abs(iphi - binphi) <= 1 and abs(ieta - bineta) <= 1)
							energy_3x3 += tower->get_energy();

						if (verbosity > 1)
							cout << " tower " << ieta << " " << wrapphi
									<< " energy = " << tower->get_energy()
									<< endl;
					}
				}
			}

			track->set_cal_energy_3x3(_cal_types[i], energy_3x3);
			track->set_cal_energy_5x5(_cal_types[i], energy_5x5);

			// loop over all clusters and find nearest
			double min_r = DBL_MAX;
			double min_index = -9999;
			double min_dphi = NAN;
			double min_deta = NAN;
			double min_e = NAN;
#ifdef DEBUG
			double min_cluster_phi = NAN;
#endif
			for (unsigned int k = 0; k < clusterList->size(); ++k) {

				RawCluster *cluster = clusterList->getCluster(k);

				double dphi = atan2(sin(phi - cluster->get_phi()),
						cos(phi - cluster->get_phi()));
				double deta = eta - cluster->get_eta();
				double r = sqrt(pow(dphi, 2) + pow(deta, 2));

				if (r < min_r) {
					min_index = k;
					min_r = r;
					min_dphi = dphi;
					min_deta = deta;
					min_e = cluster->get_energy();
#ifdef DEBUG
					min_cluster_phi = cluster->get_phi();
#endif
				}
			}

			if (min_index != -9999) {
				track->set_cal_dphi(_cal_types[i], min_dphi);
				track->set_cal_deta(_cal_types[i], min_deta);
				track->set_cal_cluster_id(_cal_types[i], min_index);
				track->set_cal_cluster_e(_cal_types[i], min_e);

#ifdef DEBUG
			cout
			<<__LINE__
			<<": min_cluster_phi: "<<min_cluster_phi
			<<endl;
#endif

				if (verbosity > 1) {
					cout << " nearest cluster dphi = " << min_dphi << " deta = "
							<< min_deta << " e = " << min_e << endl;
				}
			}

		} // end track loop
	} // end calorimeter layer loop

	if (verbosity > 1)
		cout << "PHG4GenFitTrackProjection::process_event -- exited" << endl;

	return Fun4AllReturnCodes::EVENT_OK;
}