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;
}
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;
}
int
LeptoquarksReco::AddTrackInformation( type_map_tcan& tauCandidateMap, SvtxTrackMap* trackmap, SvtxVertexMap* vertexmap, SvtxEvalStack *svtxevalstack, double R_max )
{
  
  // Pointers for tracks //
  SvtxTrackEval* trackeval = svtxevalstack->get_track_eval();
  SvtxTruthEval* trutheval = svtxevalstack->get_truth_eval();

  /* Loop over tau candidates */
  for (type_map_tcan::iterator iter = tauCandidateMap.begin();
       iter != tauCandidateMap.end();
       ++iter)
    {
      uint tracks_count_r02 = 0;
      int tracks_chargesum_r02 = 0;
      float tracks_rmax_r02 = 0;

      uint tracks_count_r04 = 0;
      int tracks_chargesum_r04 = 0;
      float tracks_rmax_r04 = 0;

      uint tracks_count_R = 0;
      int tracks_chargesum_R = 0;
      float tracks_rmax_R = 0;

      vector<float> tracks_vertex;
      vector<float> temp_vertex;

      float jet_eta = (iter->second)->get_property_float( PidCandidate::jet_eta );
      float jet_phi = (iter->second)->get_property_float( PidCandidate::jet_phi );
      
      /* Loop over tracks
       * (float) track->get_eta(),     //eta of the track
       * (float) track->get_phi(),     //phi of the track
       * (float) track->get_pt(),      //transverse momentum of track
       * (float) track->get_p(),       //total momentum of track
       * (float) track->get_charge(),  //electric charge of track
       * (float) track->get_quality()  //track quality */
  
      //Loop over tracks in event //
    for (SvtxTrackMap::ConstIter track_itr = trackmap->begin();
           track_itr != trackmap->end(); track_itr++) {

        SvtxTrack* track = dynamic_cast<SvtxTrack*>(track_itr->second);

	// Get track variables //
        float track_eta = track->get_eta();
        float track_phi = track->get_phi();
        int track_charge = track->get_charge();
	double gvx,gvy,gvz;
	  
        float delta_R = CalculateDeltaR( track_eta, track_phi, jet_eta, jet_phi );

	PHG4Particle* g4particle = trackeval->max_truth_particle_by_nclusters(track);

	// Get true vertex distances //	  
	PHG4VtxPoint* vtx = trutheval->get_vertex(g4particle);
	gvx = vtx->get_x();
	gvy = vtx->get_y();
	gvz = vtx->get_z();
	

	
	// If charged track is within jet then use its vertex //
	if(delta_R < 0.5 && trutheval->is_primary(g4particle)) tracks_vertex.push_back(sqrt(pow(gvx,2)+pow(gvy,2)+pow(gvz,2)));
	
	/* if save_tracks set true: add track to tree */
        if ( _save_tracks )
          {
            float track_data[17] = {(float) _ievent,
                                    (float) (iter->second)->get_property_uint( PidCandidate::jet_id ),
                                    (float) (iter->second)->get_property_int( PidCandidate::evtgen_pid ),
                                    (float) (iter->second)->get_property_float( PidCandidate::evtgen_etotal ),
                                    (float) (iter->second)->get_property_float( PidCandidate::evtgen_eta ),
                                    (float) (iter->second)->get_property_float( PidCandidate::evtgen_phi ),
                                    (float) (iter->second)->get_property_uint( PidCandidate::evtgen_decay_prong ),
                                    (float) (iter->second)->get_property_uint( PidCandidate::evtgen_decay_hcharged ),
                                    (float) (iter->second)->get_property_uint( PidCandidate::evtgen_decay_lcharged ),
                                    (float) (iter->second)->get_property_float( PidCandidate::jet_eta ),
                                    (float) (iter->second)->get_property_float( PidCandidate::jet_phi ),
                                    (float) (iter->second)->get_property_float( PidCandidate::jet_etotal ),
                                    (float) track->get_quality(),
                                    (float) track_eta,
                                    (float) track_phi,
                                    (float) delta_R,
                                    (float) track->get_p()
            };

            _ntp_track->Fill(track_data);
          }

        /* If track within search cone, update track information for tau candidate */
        if ( delta_R < 0.2 )
          {
            tracks_count_r02++;
            tracks_chargesum_r02 += track_charge;

            if ( delta_R > tracks_rmax_r02 )
              tracks_rmax_r02 = delta_R;
          }

        if ( delta_R < 0.4 )
          {
            tracks_count_r04++;
            tracks_chargesum_r04 += track_charge;

            if ( delta_R > tracks_rmax_r04 )
              tracks_rmax_r04 = delta_R;
          }

	if ( delta_R < R_max )
          {
            tracks_count_R++;
            tracks_chargesum_R += track_charge;

            if ( delta_R > tracks_rmax_R )
              tracks_rmax_R = delta_R;
          }

    } // end loop over reco tracks //
    // sort vertex array in increasing order //
    std::sort(tracks_vertex.begin(),tracks_vertex.end());
    
    // Compute average vertex distance of tracks in jet //
    float avg = Average(tracks_vertex);

    /* Set track-based properties for tau candidate */
      (iter->second)->set_property( PidCandidate::tracks_count_r02, tracks_count_r02 );
      (iter->second)->set_property( PidCandidate::tracks_chargesum_r02, tracks_chargesum_r02 );
      (iter->second)->set_property( PidCandidate::tracks_rmax_r02, tracks_rmax_r02 );
      (iter->second)->set_property( PidCandidate::tracks_count_r04, tracks_count_r04 );
      (iter->second)->set_property( PidCandidate::tracks_chargesum_r04, tracks_chargesum_r04 );
      (iter->second)->set_property( PidCandidate::tracks_rmax_r04, tracks_rmax_r04 );
      (iter->second)->set_property( PidCandidate::tracks_count_R, tracks_count_R );
      (iter->second)->set_property( PidCandidate::tracks_chargesum_R, tracks_chargesum_R );
      (iter->second)->set_property( PidCandidate::tracks_rmax_R, tracks_rmax_R );
      if(avg == avg) (iter->second)->set_property( PidCandidate::tracks_vertex, avg);

    } // end loop over tau  candidates

  return 0;
}
Esempio n. 4
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int PhotonJet::process_event(PHCompositeNode *topnode)
{
 
  cout<<"at event number "<<nevents<<endl;


  //get the nodes from the NodeTree
  JetMap* truth_jets = findNode::getClass<JetMap>(topnode,"AntiKt_Truth_r04");
  JetMap *reco_jets = findNode::getClass<JetMap>(topnode,"AntiKt_Tower_r04");
  PHG4TruthInfoContainer* truthinfo = findNode::getClass<PHG4TruthInfoContainer>(topnode,"G4TruthInfo");
  RawClusterContainer *clusters = findNode::getClass<RawClusterContainer>(topnode,"CLUSTER_CEMC");
  SvtxTrackMap *trackmap = findNode::getClass<SvtxTrackMap>(topnode,"SvtxTrackMap");
  JetEvalStack* _jetevalstack = new JetEvalStack(topnode,"AntiKt_Tower_r04","AntiKt_Truth_r04");
  PHG4TruthInfoContainer::Range range = truthinfo->GetPrimaryParticleRange();

  if(!truth_jets){
      cout<<"no truth jets"<<endl;
      return 0;
    }
  if(!reco_jets){
      cout<<"no reco jets"<<endl;
      return 0;
    }
  if(!truthinfo){
      cout<<"no truth track info"<<endl;
      return 0;
    }
  if(!clusters){
    cout<<"no cluster info"<<endl;
    return 0;
  }
  if(!trackmap){
    cout<<"no track map"<<endl;
    return 0;
  }
  if(!_jetevalstack){
    cout<<"no good truth jets"<<endl;
    return 0;
  }


  JetRecoEval* recoeval = _jetevalstack->get_reco_eval();


 /***********************************************

  GET THE TRUTH PARTICLES

  ************************************************/



  for( PHG4TruthInfoContainer::ConstIterator iter = range.first; iter!=range.second; ++iter){

    PHG4Particle *truth = iter->second;
    
    truthpx = truth->get_px();
    truthpy = truth->get_py();
    truthpz = truth->get_pz();
    truthp = sqrt(truthpx*truthpx+truthpy*truthpy+truthpz*truthpz);
    truthenergy = truth->get_e();
    
    TLorentzVector vec;
    vec.SetPxPyPzE(truthpx,truthpy,truthpz,truthenergy);
    
    truthpt = sqrt(truthpx*truthpx+truthpy*truthpy);
    if(truthpt<0.5)
      continue;
    
    truthphi = vec.Phi();
    trutheta = vec.Eta();
    truthpid = truth->get_pid();
    
    truth_g4particles->Fill();

  }


  /***********************************************

  GET THE EMCAL CLUSTERS

  ************************************************/


  RawClusterContainer::ConstRange begin_end = clusters->getClusters();
  RawClusterContainer::ConstIterator clusiter;
  
  for(clusiter = begin_end.first; clusiter!=begin_end.second; ++clusiter){

    RawCluster *cluster = clusiter->second;

    clus_energy = cluster->get_energy();
    clus_eta = cluster->get_eta();
    clus_theta = 2.*TMath::ATan((TMath::Exp(-1.*clus_eta)));
    clus_pt = clus_energy*TMath::Sin(clus_theta);
    clus_phi = cluster->get_phi();
    
    if(clus_pt<0.5)
      continue;

   
    
    TLorentzVector *clus = new TLorentzVector();
    clus->SetPtEtaPhiE(clus_pt,clus_eta,clus_phi,clus_energy);
    
    float dumarray[4];
    clus->GetXYZT(dumarray);
    clus_x = dumarray[0];
    clus_y = dumarray[1];
    clus_z = dumarray[2];
    clus_t = dumarray[3];

    clus_px = clus_pt*TMath::Cos(clus_phi);
    clus_py = clus_pt*TMath::Sin(clus_phi);
    clus_pz = sqrt(clus_energy*clus_energy-clus_px*clus_px-clus_py*clus_py);

    cluster_tree->Fill();

    //only interested in high pt photons to be isolated
    if(clus_pt<mincluspt)
      continue;
    if(fabs(clus_eta)>(1.0-isoconeradius))
      continue;

    float energysum = ConeSum(cluster,clusters,trackmap,isoconeradius);
    bool conecut = energysum > 0.1*clus_energy;
    if(conecut)
      continue;
   
    isolated_clusters->Fill();
    
    GetRecoHadronsAndJets(cluster, trackmap, reco_jets,recoeval);

  }



  /***********************************************

  GET THE SVTX TRACKS

  ************************************************/
  
  SvtxEvalStack *svtxevalstack = new SvtxEvalStack(topnode);
  svtxevalstack->next_event(topnode);

  SvtxTrackEval *trackeval = svtxevalstack->get_track_eval();

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

    SvtxTrack *track = iter->second;

    //get reco info
    tr_px = track->get_px();
    tr_py = track->get_py();
    tr_pz = track->get_pz();
    tr_p = sqrt(tr_px*tr_px+tr_py*tr_py+tr_pz*tr_pz);
    
    tr_pt = sqrt(tr_px*tr_px+tr_py*tr_py);
    
    if(tr_pt<0.5)
      continue;
  
    tr_phi = track->get_phi();
    tr_eta = track->get_eta();

    if(fabs(tr_eta)>1)
      continue;

    charge = track->get_charge();
    chisq = track->get_chisq();
    ndf = track->get_ndf();
    dca = track->get_dca();
    tr_x = track->get_x();
    tr_y = track->get_y();
    tr_z = track->get_z();
    
   
    //get truth info
    PHG4Particle *truthtrack = trackeval->max_truth_particle_by_nclusters(track);
    truth_is_primary = truthinfo->is_primary(truthtrack);
    
    truthtrackpx = truthtrack->get_px();
    truthtrackpy = truthtrack->get_py();
    truthtrackpz = truthtrack->get_pz();
    truthtrackp = sqrt(truthtrackpx*truthtrackpx+truthtrackpy*truthtrackpy+truthtrackpz*truthtrackpz);
    
    truthtracke = truthtrack->get_e();
    TLorentzVector *Truthtrack = new TLorentzVector();
    Truthtrack->SetPxPyPzE(truthtrackpx,truthtrackpy,truthtrackpz,truthtracke);
    truthtrackpt = Truthtrack->Pt();
    truthtrackphi = Truthtrack->Phi();
    truthtracketa = Truthtrack->Eta();
    truthtrackpid = truthtrack->get_pid();


    tracktree->Fill();

  }







  /***************************************

   TRUTH JETS

   ***************************************/


  for(JetMap::Iter iter = truth_jets->begin(); iter!=truth_jets->end(); ++iter){
    Jet *jet = iter->second;
    
    truthjetpt = jet->get_pt();
    if(truthjetpt<10.)
      continue;
    
    truthjeteta = jet->get_eta();
    if(fabs(truthjeteta)>2.)
      continue;

    truthjetpx = jet->get_px();
    truthjetpy = jet->get_py();
    truthjetpz = jet->get_pz();
    truthjetphi = jet->get_phi();
    truthjetmass = jet->get_mass();
    truthjetp = jet->get_p();
    truthjetenergy = jet->get_e();
    
    truthjettree->Fill();
    


  }



/***************************************

   RECONSTRUCTED JETS

   ***************************************/



  for(JetMap::Iter iter = reco_jets->begin(); iter!=reco_jets->end(); ++iter){
    Jet *jet = iter->second;
    Jet *truthjet = recoeval->max_truth_jet_by_energy(jet);
    recojetpt = jet->get_pt();
    if(recojetpt<4.)
      continue;
    
    recojeteta = jet->get_eta();
    if(fabs(recojeteta)>2.)
      continue;
    recojetid = jet->get_id();
    recojetpx = jet->get_px();
    recojetpy = jet->get_py();
    recojetpz = jet->get_pz();
    recojetphi = jet->get_phi();
    recojetmass = jet->get_mass();
    recojetp = jet->get_p();
    recojetenergy = jet->get_e();

    if(truthjet){
      truthjetid = truthjet->get_id();
      truthjetp = truthjet->get_p();
      truthjetphi = truthjet->get_phi();
      truthjeteta = truthjet->get_eta();
      truthjetpt = truthjet->get_pt();
      truthjetenergy = truthjet->get_e();
      truthjetpx = truthjet->get_px();
      truthjetpy = truthjet->get_py();
      truthjetpz = truthjet->get_pz();
    }
    else{
      truthjetid = 0;
      truthjetp = 0;
      truthjetphi = 0;
      truthjeteta = 0;
      truthjetpt = 0;
      truthjetenergy = 0;
      truthjetpx = 0;
      truthjetpy = 0;
      truthjetpz = 0;
      
    }
    recojettree->Fill();

  }

  


  nevents++;
  tree->Fill();
  return 0;

}
Esempio n. 5
0
float PhotonJet::ConeSum(RawCluster *cluster, 
			 RawClusterContainer *cluster_container,
			 SvtxTrackMap *trackmap,
			 float coneradius)
{

  float energyptsum=0;
  
  RawClusterContainer::ConstRange begin_end = cluster_container->getClusters();
  RawClusterContainer::ConstIterator clusiter;
  
  for(clusiter = begin_end.first; clusiter!=begin_end.second; ++clusiter){
    RawCluster *conecluster = clusiter->second;
    
    //check to make sure that the candidate isolated photon isn't being counted in the energy sum
    if(conecluster->get_energy() == cluster->get_energy())
      if(conecluster->get_phi() == cluster->get_phi())
	if(conecluster->get_eta() == cluster->get_eta())
	  continue;

    float cone_pt = conecluster->get_energy()/TMath::CosH(conecluster->get_eta());
    if(cone_pt<0.2)
      continue;
    
    float cone_e = conecluster->get_energy();
    float cone_eta = conecluster->get_eta();
    float cone_phi = conecluster->get_phi();
    


    float dphi = cluster->get_phi()-cone_phi;
    if(dphi<-1*pi)
      dphi+=2.*pi;
    if(dphi>pi)
      dphi-=2.*pi;
    
    float deta = cluster->get_eta()-cone_eta;

   
    float radius = sqrt(dphi*dphi+deta*deta);
   
    if(radius<coneradius){
      energyptsum+=cone_e;
    
    }
  }
  

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

    float trackpx = track->get_px();
    float trackpy = track->get_py();
    float trackpt = sqrt(trackpx*trackpx+trackpy*trackpy);
    if(trackpt<0.2)
      continue;
    float trackphi = track->get_phi();
    float tracketa = track->get_eta();
    float dphi = cluster->get_phi()-trackphi;
    float deta = cluster->get_eta()-tracketa;
    float radius = sqrt(dphi*dphi+deta*deta);
  
    if(radius<coneradius){
      energyptsum+=trackpt;
    }
  }


  return energyptsum;

}
Esempio n. 6
0
void PhotonJet::GetRecoHadronsAndJets(RawCluster *trig,
				      SvtxTrackMap *tracks,
				      JetMap *jets,
				      JetRecoEval *recoeval)
{

  float trig_phi = trig->get_phi();
  float trig_eta = trig->get_eta();

 
  for(SvtxTrackMap::Iter iter = tracks->begin(); iter!=tracks->end(); ++iter){

    SvtxTrack *track = iter->second;

    _tr_px = track->get_px();
    _tr_py = track->get_py();
    _tr_pz = track->get_pz();
    _tr_pt = sqrt(_tr_px*_tr_px+_tr_py*_tr_py);
    if(_tr_pt<0.5)
      continue;

    _tr_p = sqrt(_tr_px*_tr_px+_tr_py*_tr_py+_tr_pz*_tr_pz);
    _tr_phi = track->get_phi();
    _tr_eta = track->get_eta();
    _charge = track->get_charge();
    _chisq = track->get_chisq();
    _ndf = track->get_ndf();
    _dca = track->get_dca();
    _tr_x = track->get_x();
    _tr_y = track->get_y();
    _tr_z = track->get_z();

    haddphi = trig_phi-_tr_phi;
    if(haddphi<pi2)
      haddphi+=2.*pi;
    if(haddphi>threepi2)
      haddphi-=2.*pi;


    haddeta = trig_eta-_tr_eta;

    hadpout = _tr_p*TMath::Sin(haddphi);

    isophot_had_tree->Fill();
    

  }
  for(JetMap::Iter iter = jets->begin(); iter!=jets->end(); ++iter){
    Jet* jet = iter->second;
    Jet *truthjet = recoeval->max_truth_jet_by_energy(jet);

    _recojetpt = jet->get_pt();
    if(_recojetpt<4.0) 
      continue;
      
    _recojeteta = jet->get_eta();
    if(fabs(_recojeteta)>1.)
      continue;

    _recojetpx = jet->get_px();
    _recojetpy = jet->get_py();
    _recojetpz = jet->get_pz();
    _recojetphi = jet->get_phi();
    _recojetmass = jet->get_mass();
    _recojetp = jet->get_p();
    _recojetenergy = jet->get_e();
    _recojetid = jet->get_id();

    if(truthjet){
      _truthjetid = truthjet->get_id();
      _truthjetp = truthjet->get_p();
      _truthjetphi = truthjet->get_phi();
      _truthjeteta = truthjet->get_eta();
      _truthjetpt = truthjet->get_pt();
      _truthjetenergy = truthjet->get_e();
      _truthjetpx = truthjet->get_px();
      _truthjetpy = truthjet->get_py();
      _truthjetpz = truthjet->get_pz();
    }
    else{
      _truthjetid = 0;
      _truthjetp = 0;
      _truthjetphi = 0;
      _truthjeteta = 0;
      _truthjetpt = 0;
      _truthjetenergy = 0;
      _truthjetpx = 0;
      _truthjetpy = 0;
      _truthjetpz = 0;

    }
    
    jetdphi = trig_phi-_recojetphi;
    if(jetdphi<pi2)
      jetdphi+=2.*pi;
    if(jetdphi>threepi2)
      jetdphi-=2.*pi;
    
    jetdeta = trig_eta-_recojeteta;
    jetpout = _recojetpt*TMath::Sin(jetdphi);

    isophot_jet_tree->Fill();
  }


}