void SvtxEvaluator::printInputInfo(PHCompositeNode *topNode) { if (verbosity > 1) cout << "SvtxEvaluator::printInputInfo() entered" << endl; if (verbosity > 3) { // event information cout << endl; cout << PHWHERE << " INPUT FOR EVENT " << _ievent << endl; cout << endl; cout << "---PHG4HITS-------------" << endl; _svtxevalstack->get_truth_eval()->set_strict(_strict); std::set<PHG4Hit*> g4hits = _svtxevalstack->get_truth_eval()->all_truth_hits(); unsigned int ig4hit = 0; for(std::set<PHG4Hit*>::iterator iter = g4hits.begin(); iter != g4hits.end(); ++iter) { PHG4Hit *g4hit = *iter; cout << ig4hit << " of " << g4hits.size(); cout << ": PHG4Hit: " << endl; g4hit->identify(); ++ig4hit; } cout << "---SVTXCLUSTERS-------------" << endl; SvtxClusterMap* clustermap = findNode::getClass<SvtxClusterMap>(topNode,"SvtxClusterMap"); if (clustermap) { unsigned int icluster = 0; for (SvtxClusterMap::Iter iter = clustermap->begin(); iter != clustermap->end(); ++iter) { SvtxCluster* cluster = iter->second; cout << icluster << " of " << clustermap->size(); cout << ": SvtxCluster: " << endl; cluster->identify(); ++icluster; } } cout << "---SVXTRACKS-------------" << endl; SvtxTrackMap* trackmap = findNode::getClass<SvtxTrackMap>(topNode,"SvtxTrackMap"); if (trackmap) { unsigned int itrack = 0; for (SvtxTrackMap::Iter iter = trackmap->begin(); iter != trackmap->end(); ++iter) { cout << itrack << " of " << trackmap->size(); SvtxTrack *track = iter->second; cout << " : SvtxTrack:" << endl; track->identify(); cout << endl; } } cout << "---SVXVERTEXES-------------" << endl; SvtxVertexMap* vertexmap = findNode::getClass<SvtxVertexMap>(topNode,"SvtxVertexMap"); if (vertexmap) { unsigned int ivertex = 0; for (SvtxVertexMap::Iter iter = vertexmap->begin(); iter != vertexmap->end(); ++iter) { cout << ivertex << " of " << vertexmap->size(); SvtxVertex *vertex = iter->second; cout << " : SvtxVertex:" << endl; vertex->identify(); cout << endl; } } } return; }
int PHG4HoughTransformTPC::process_event(PHCompositeNode *topNode) { _timer.get()->restart(); if(_write_reco_tree==true){ _recoevent->tracks.clear();} if(verbosity > 0) cout << "PHG4HoughTransformTPC::process_event -- entered" << endl; // moving clearing to the beginning of event or we will have // return bugs from early exits! _clusters_init.clear(); _clusters.clear(); _tracks.clear(); //--------------------------------- // Get Objects off of the Node Tree //--------------------------------- GetNodes(topNode); // Translate into Helix_Hough objects //----------------------------------- //wrap_clusters_timer.get()->restart(); for (SvtxClusterMap::Iter iter = _g4clusters->begin(); iter != _g4clusters->end(); ++iter) { SvtxCluster* cluster = iter->second; //cluster->identify(); float phi = atan2(cluster->get_position(1),cluster->get_position(0)); unsigned int ilayer = _layer_ilayer_map[cluster->get_layer()]; float xy_error=0.;float z_error=0.; if (_use_cell_size) { xy_error = _smear_xy_layer[ilayer] * _vote_error_scale[ilayer]; z_error = _smear_z_layer[ilayer] * _vote_error_scale[ilayer]; } else { if( cluster->get_phi_size() <= _max_cluster_error*_smear_xy_layer[ilayer] ){xy_error = cluster->get_phi_size() * _vote_error_scale[ilayer];} else{xy_error = _max_cluster_error*_smear_xy_layer[ilayer] * _vote_error_scale[ilayer];} if(cluster->get_z_size() <= _max_cluster_error*_smear_z_layer[ilayer]){z_error = cluster->get_z_size() * _vote_error_scale[ilayer];} else{z_error = _max_cluster_error*_smear_z_layer[ilayer] * _vote_error_scale[ilayer];} } vector<SimpleHit3D>* which_vec = &_clusters; if (ilayer<_seed_layers) {which_vec=&_clusters_init;} //SimpleHit3D(float xx, float dxx, float yy, float dyy, float zz, float dzz, unsigned int ind, int lyr=-1) SimpleHit3D hit3d(cluster->get_x(),fabs(xy_error*sin(phi)), cluster->get_y(),fabs(xy_error*cos(phi)), cluster->get_z(),z_error, cluster->get_id(),ilayer); // copy covariance over for (int i=0; i<3; ++i) { for (int j=i; j<3; ++j) { hit3d.set_error(i,j,cluster->get_error(i,j)); } } which_vec->push_back(hit3d); } if (verbosity > 20) { cout << "-------------------------------------------------------------------" << endl; cout << "PHG4HoughTransformTPC::process_event has the following input clusters:" << endl; if (!_clusters_init.empty()) { for (unsigned int i = 0; i < _clusters_init.size(); ++i) { cout << "n init clusters = "<<_clusters_init.size() << endl; _clusters_init[i].print(); } } else { for (unsigned int i = 0; i < _clusters.size(); ++i) { cout << "n clusters = "<<_clusters.size() << endl; _clusters[i].print(); } } cout << "-------------------------------------------------------------------" << endl; } cout<<"_clusters_init.size() = "<<_clusters_init.size()<<endl; //------------------------------------ // Perform the initial zvertex finding //------------------------------------ if(verbosity > 0) cout << "PHG4HoughTransformTPC::process_event -- initial vertex finding..." << endl; // Grab some initial tracks for initial z-vertex finding _tracks.clear(); _vertex.clear(); _vertex.push_back(0.0); // x guess _vertex.push_back(0.0); // y guess _vertex.push_back(0.0); // z guess if(_use_vertex) { // find maxtracks tracks unsigned int maxtracks = 100; // _tracker->setRemoveHits(false); _tracker->findHelices(_clusters_init, _req_seed, _max_hits_init, _tracks, maxtracks); // _tracker->setRemoveHits(_remove_hits); cout<<"found "<<_tracks.size()<<" tracks"<<endl; if(_tracks.size() == 0){return Fun4AllReturnCodes::EVENT_OK;} else if(_tracks.size() == 1) { _vertex[0] = cos(_tracks[0].phi) * _tracks[0].d; _vertex[1] = sin(_tracks[0].phi) * _tracks[0].d; _vertex[2] = _tracks[0].z0; } else { vector<vector<double> > pTmap; for(unsigned int i=0;i<_tracks.size();++i) { if(_tracks[i].kappa == 0.0){continue;} double pT = kappaToPt(_tracks[i].kappa); pTmap.push_back(vector<double>()); pTmap.back().push_back(pT); pTmap.back().push_back((double)i); } sort(pTmap.begin(), pTmap.end()); vector<SimpleTrack3D> vtxtracks; unsigned int maxvtxtracks=100; if(_tracks.size() < maxvtxtracks) { vtxtracks = _tracks; } else { for(unsigned int i=0;i<maxvtxtracks;++i) { vtxtracks.push_back(_tracks[ (int)(pTmap[pTmap.size()-1-i][1]) ]); } } vector<double> zvertices(3,0.); vector<float> temp_vertex(3,0.); vector<unsigned int> vtracks(3,0); for(unsigned int iter = 0;iter < 3; ++iter) { temp_vertex[2] = 0.; TH1D z0_hist("z0_hist","z0_hist", 20, -10., 10.); for(unsigned int i=0;i<vtxtracks.size();++i) { z0_hist.Fill(vtxtracks[i].z0); } temp_vertex[2] = z0_hist.GetBinCenter( z0_hist.GetMaximumBin() ); _vertexFinder.findVertex(vtxtracks, temp_vertex, 3., true); _vertexFinder.findVertex(vtxtracks, temp_vertex, 0.1, true); _vertexFinder.findVertex(vtxtracks, temp_vertex, 0.02, false); vector<SimpleTrack3D> ttracks; for(unsigned int t=0;t<vtxtracks.size();++t) { if( fabs(vtxtracks[t].z0 - temp_vertex[2]) < 0.1 ){vtracks[iter] += 1;} else{ttracks.push_back(vtxtracks[t]);} } vtxtracks = ttracks; zvertices[iter] = temp_vertex[2]; } _vertex[2] = zvertices[0]; unsigned int zbest = 0; for(unsigned int iter = 1;iter < 3; ++iter) { if(vtracks[iter] > vtracks[zbest]) { _vertex[2] = zvertices[iter]; zbest = iter; } } } if(verbosity > 0) cout << "PHG4HoughTransformTPC::process_event -- found initial vertex : " << _vertex[0] << " " << _vertex[1] << " " << _vertex[2] << endl; _tracks.clear(); // shift the vertex to the origin for(unsigned int ht=0;ht<_clusters_init.size();++ht) { _clusters_init[ht].x -= _vertex[0]; _clusters_init[ht].y -= _vertex[1]; _clusters_init[ht].z -= _vertex[2]; } for(unsigned int ht=0;ht<_clusters.size();++ht) { _clusters[ht].x -= _vertex[0]; _clusters[ht].y -= _vertex[1]; _clusters[ht].z -= _vertex[2]; } } // if(_use_vertex) //---------------------------------- // Preform the track finding //---------------------------------- _tracker->clear(); _tracks.clear(); _timer_initial_hough.get()->restart(); _tracker->findHelices(_clusters_init, _min_hits_init, _max_hits_init, _tracks); _timer_initial_hough.get()->stop(); if(verbosity > 0) { cout << "PHG4HoughTransformTPC::process_event -- full track finding pass found: " << _tracks.size() << " tracks" << endl; } //---------------------------- // Re-center event on detector //---------------------------- if(verbosity > 0) cout << "PHG4HoughTransformTPC::process_event -- recentering event on detector..." << endl; vector<double> chi_squareds; for(unsigned int tt=0;tt<_tracks.size();tt++) { // move the hits in the track back to their original position for(unsigned int hh=0;hh<_tracks[tt].hits.size();hh++) { _tracks[tt].hits[hh].x = _tracks[tt].hits[hh].x + _vertex[0]; _tracks[tt].hits[hh].y = _tracks[tt].hits[hh].y + _vertex[1]; _tracks[tt].hits[hh].z = _tracks[tt].hits[hh].z + _vertex[2]; // _tracks[tt].z0 += _vertex[2]; } chi_squareds.push_back(_tracker->getKalmanStates()[tt].chi2);} if(verbosity > 0) { cout << "PHG4HoughTransformTPC::process_event -- final track count: " << _tracks.size() << endl; } //--------------------------- // Final vertex determination //--------------------------- // final best guess of the primary vertex position here... if(verbosity > 0) { cout<< "PHG4HoughTransformTPC::process_event -- calculating final vertex" << endl; } // sort the tracks by pT vector<vector<double> > pTmap; for(unsigned int i=0;i<_tracks.size();++i) { double pT = kappaToPt(_tracks[i].kappa); pTmap.push_back(vector<double>()); pTmap.back().push_back(pT); pTmap.back().push_back((double)i); } sort(pTmap.begin(), pTmap.end()); vector<SimpleTrack3D> vtxtracks; vector<Matrix<float,5,5> > vtxcovariances; unsigned int maxvtxtracks=100; if(_tracks.size() < maxvtxtracks){vtxtracks = _tracks;} else { for(unsigned int i=0;i<maxvtxtracks;++i) { vtxtracks.push_back(_tracks[ (int)(pTmap[pTmap.size()-1-i][1]) ]); vtxcovariances.push_back( (_tracker->getKalmanStates())[ (int)(pTmap[pTmap.size()-1-i][1]) ].C ); } } double vx = _vertex[0]; double vy = _vertex[1]; double vz = _vertex[2]; _vertex[0] = 0.; _vertex[1] = 0.; _vertex[2] = 0.; _vertexFinder.findVertex(vtxtracks, vtxcovariances, _vertex, 0.3, false); _vertexFinder.findVertex(vtxtracks, vtxcovariances, _vertex, 0.1, false); _vertexFinder.findVertex(vtxtracks, vtxcovariances, _vertex, 0.02, false); _vertexFinder.findVertex(vtxtracks, vtxcovariances, _vertex, 0.005, false); _vertex[0] += vx; _vertex[1] += vy; _vertex[2] += vz; if(verbosity > 0) { cout << "PHG4HoughTransformTPC::process_event -- final vertex: " << _vertex[0] << " " << _vertex[1] << " " << _vertex[2] << endl; } //-------------------------------- // Translate back into PHG4 objects //-------------------------------- if(verbosity > 0) { cout << "PHG4HoughTransformTPC::process_event -- producing PHG4Track objects..." << endl; } SvtxVertex_v1 vertex; vertex.set_t0(0.0); for (int i=0;i<3;++i) vertex.set_position(i,_vertex[i]); vertex.set_chisq(0.0); vertex.set_ndof(0); vertex.set_error(0,0,0.0); vertex.set_error(0,1,0.0); vertex.set_error(0,2,0.0); vertex.set_error(1,0,0.0); vertex.set_error(1,1,0.0); vertex.set_error(1,2,0.0); vertex.set_error(2,0,0.0); vertex.set_error(2,1,0.0); vertex.set_error(2,2,0.0); // copy out the reconstructed vertex position //_g4tracks->setVertex(_vertex[0],_vertex[1],_vertex[2]); //_g4tracks->setVertexError(0.0,0.0,0.0); // at this point we should already have an initial pt and pz guess... // need to translate this into the PHG4Track object... vector<SimpleHit3D> track_hits; int clusterID; int clusterLayer; float cluster_x; float cluster_y; float cluster_z; // float dEdx1; // float dEdx2; for(unsigned int itrack=0; itrack<_tracks.size();itrack++) { SvtxTrack_v1 track; track.set_id(itrack); track_hits.clear(); track_hits = _tracks.at(itrack).hits; for(unsigned int ihit = 0; ihit<track_hits.size();ihit++) { // dEdx1=0; // dEdx2=0; if( (track_hits.at(ihit).index) >= _g4clusters->size()){continue;} SvtxCluster *cluster = _g4clusters->get(track_hits.at(ihit).index); clusterID = cluster->get_id(); clusterLayer = cluster->get_layer(); cluster_x = cluster->get_x(); cluster_y = cluster->get_y(); cluster_z = cluster->get_z(); if( (clusterLayer < (int)_seed_layers) && (clusterLayer >= 0) ) { track.insert_cluster(clusterID); } } float kappa = _tracks.at(itrack).kappa; float d = _tracks.at(itrack).d; float phi = _tracks.at(itrack).phi; float dzdl = _tracks.at(itrack).dzdl; float z0 = _tracks.at(itrack).z0; // track.set_helix_phi(phi); // track.set_helix_kappa(kappa); // track.set_helix_d(d); // track.set_helix_z0(z0); // track.set_helix_dzdl(dzdl); float pT = kappaToPt(kappa); float x_center = cos(phi)*(d+1/kappa); // x coordinate of circle center float y_center = sin(phi)*(d+1/kappa); // y " " " " // find helicity from cross product sign short int helicity; if((track_hits[0].x-x_center)*(track_hits[track_hits.size()-1].y-y_center) - (track_hits[0].y-y_center)*(track_hits[track_hits.size()-1].x-x_center) > 0) { helicity = 1; } else { helicity = -1; } float pZ = 0; if(dzdl != 1) { pZ = pT * dzdl / sqrt(1.0 - dzdl*dzdl); } int ndf = 2*_tracks.at(itrack).hits.size() - 5; track.set_chisq(chi_squareds[itrack]); track.set_ndf(ndf); track.set_px( pT*cos(phi-helicity*M_PI/2) ); track.set_py( pT*sin(phi-helicity*M_PI/2) ); track.set_pz( pZ ); track.set_dca2d( d ); track.set_dca2d_error(sqrt(_tracker->getKalmanStates()[itrack].C(1,1))); if(_write_reco_tree==true) { _recoevent->tracks.push_back( SimpleRecoTrack() ); _recoevent->tracks.back().px = pT*cos(phi-helicity*M_PI/2); _recoevent->tracks.back().py = pT*sin(phi-helicity*M_PI/2); _recoevent->tracks.back().pz = pZ; _recoevent->tracks.back().d = d; _recoevent->tracks.back().z0 = z0; _recoevent->tracks.back().quality = chi_squareds[itrack]/((float)ndf); _recoevent->tracks.back().charge = (-1*helicity); } if(_magField > 0) { track.set_charge( helicity ); } else { track.set_charge( -1.0*helicity ); } Matrix<float,6,6> euclidean_cov = Matrix<float,6,6>::Zero(6,6); convertHelixCovarianceToEuclideanCovariance( _magField, phi, d, kappa, z0, dzdl, _tracker->getKalmanStates()[itrack].C, euclidean_cov ); for(unsigned int row=0;row<6;++row) { for(unsigned int col=0;col<6;++col) { track.set_error(row,col,euclidean_cov(row,col)); } } track.set_x( vertex.get_x() + d*cos(phi) ); track.set_y( vertex.get_y() + d*sin(phi) ); track.set_z( vertex.get_z() + z0 ); _g4tracks->insert(&track); vertex.insert_track(track.get_id()); if (verbosity > 5) { cout << "track " << itrack << " quality = " << track.get_quality() << endl; cout << "px = " << track.get_px() << " py = " << track.get_py() << " pz = " << track.get_pz() << endl; } } // track loop SvtxVertex *vtxptr = _g4vertexes->insert(&vertex); if (verbosity > 5) vtxptr->identify(); if(verbosity > 0) { cout << "PHG4HoughTransformTPC::process_event -- leaving process_event" << endl; } if(_write_reco_tree==true){ _reco_tree->Fill(); } _timer.get()->stop(); return Fun4AllReturnCodes::EVENT_OK; }
int PHG4HoughTransform::export_output() { if (_tracks.empty()) return Fun4AllReturnCodes::EVENT_OK; SvtxVertex_v1 vertex; vertex.set_t0(0.0); for (int i=0;i<3;++i) vertex.set_position(i,_vertex[i]); vertex.set_chisq(0.0); vertex.set_ndof(0); vertex.set_error(0,0,0.0); vertex.set_error(0,1,0.0); vertex.set_error(0,2,0.0); vertex.set_error(1,0,0.0); vertex.set_error(1,1,0.0); vertex.set_error(1,2,0.0); vertex.set_error(2,0,0.0); vertex.set_error(2,1,0.0); vertex.set_error(2,2,0.0); // at this point we should already have an initial pt and pz guess... // need to translate this into the PHG4Track object... vector<SimpleHit3D> track_hits; int clusterID; int clusterLayer; for (unsigned int itrack = 0; itrack < _tracks.size(); itrack++) { SvtxTrack_v1 track; track.set_id(itrack); track_hits.clear(); track_hits = _tracks.at(itrack).hits; for (unsigned int ihit = 0; ihit < track_hits.size(); ihit++) { if ((track_hits.at(ihit).get_id()) >= _g4clusters->size()) { continue; } SvtxCluster* cluster = _g4clusters->get(track_hits.at(ihit).get_id()); clusterID = cluster->get_id(); clusterLayer = cluster->get_layer(); if ((clusterLayer < (int)_nlayers) && (clusterLayer >= 0)) { track.insert_cluster(clusterID); } } float kappa = _tracks.at(itrack).kappa; float d = _tracks.at(itrack).d; float phi = _tracks.at(itrack).phi; float dzdl = _tracks.at(itrack).dzdl; float z0 = _tracks.at(itrack).z0; // track.set_helix_phi(phi); // track.set_helix_kappa(kappa); // track.set_helix_d(d); // track.set_helix_z0(z0); // track.set_helix_dzdl(dzdl); float pT = kappaToPt(kappa); float x_center = cos(phi) * (d + 1 / kappa); // x coordinate of circle center float y_center = sin(phi) * (d + 1 / kappa); // y " " " " // find helicity from cross product sign short int helicity; if ((track_hits[0].get_x() - x_center) * (track_hits[track_hits.size() - 1].get_y() - y_center) - (track_hits[0].get_y() - y_center) * (track_hits[track_hits.size() - 1].get_x() - x_center) > 0) { helicity = 1; } else { helicity = -1; } float pZ = 0; if (dzdl != 1) { pZ = pT * dzdl / sqrt(1.0 - dzdl * dzdl); } int ndf = 2 * _tracks.at(itrack).hits.size() - 5; track.set_chisq(_track_errors[itrack]); track.set_ndf(ndf); track.set_px(pT * cos(phi - helicity * M_PI / 2)); track.set_py(pT * sin(phi - helicity * M_PI / 2)); track.set_pz(pZ); track.set_dca2d(d); track.set_dca2d_error(sqrt(_track_covars[itrack](1, 1))); if (_magField > 0) { track.set_charge(helicity); } else { track.set_charge(-1.0 * helicity); } Eigen::Matrix<float, 6, 6> euclidean_cov = Eigen::Matrix<float, 6, 6>::Zero(6, 6); convertHelixCovarianceToEuclideanCovariance( _magField, phi, d, kappa, z0, dzdl, _track_covars[itrack], euclidean_cov); for (unsigned int row = 0; row < 6; ++row) { for (unsigned int col = 0; col < 6; ++col) { track.set_error(row, col, euclidean_cov(row, col)); } } track.set_x(vertex.get_x() + d * cos(phi)); track.set_y(vertex.get_y() + d * sin(phi)); track.set_z(vertex.get_z() + z0); _g4tracks->insert(&track); vertex.insert_track(track.get_id()); if (verbosity > 5) { cout << "track " << itrack << " quality = " << track.get_quality() << endl; cout << "px = " << track.get_px() << " py = " << track.get_py() << " pz = " << track.get_pz() << endl; } } // track loop SvtxVertex *vtxptr = _g4vertexes->insert(&vertex); if (verbosity > 5) vtxptr->identify(); if (verbosity > 0) { cout << "PHG4HoughTransform::process_event -- leaving process_event" << endl; } // we are done with these now... _clusters.clear(); _tracks.clear(); _track_errors.clear(); _track_covars.clear(); _vertex.clear(); _vertex.assign(3,0.0); return Fun4AllReturnCodes::EVENT_OK; }