int PHG4SvtxThresholds::process_event(PHCompositeNode *topNode) { _timer.get()->restart(); std::vector<unsigned int> remove_hits; for (SvtxHitMap::Iter iter = _hits->begin(); iter != _hits->end(); ++iter) { SvtxHit* hit = iter->second; if (hit->get_e() < get_threshold_by_layer(hit->get_layer())) { if(verbosity > 2) cout << "Removing hit with energy " << hit->get_e() << " in layer " << hit->get_layer() << " threshold = " << get_threshold_by_layer(hit->get_layer()) << endl; remove_hits.push_back(hit->get_id()); } } for (unsigned int i = 0; i < remove_hits.size(); ++i) { _hits->erase(remove_hits[i]); } _timer.get()->stop(); return Fun4AllReturnCodes::EVENT_OK; }
std::set<SvtxHit*> SvtxHitEval::all_hits_from(PHG4Hit* g4hit) { if (!has_node_pointers()) {++_errors; return std::set<SvtxHit*>();} if (_strict) {assert(g4hit);} else if (!g4hit) {++_errors; return std::set<SvtxHit*>();} if (_do_cache) { std::map<PHG4Hit*,std::set<SvtxHit*> >::iterator iter = _cache_all_hits_from_g4hit.find(g4hit); if (iter != _cache_all_hits_from_g4hit.end()) { return iter->second; } } std::set<SvtxHit*> hits; unsigned int hit_layer = g4hit->get_layer(); // loop over all the hits for (SvtxHitMap::Iter iter = _hitmap->begin(); iter != _hitmap->end(); ++iter) { SvtxHit* hit = iter->second; if (hit->get_layer() != hit_layer) continue; // loop over all truth hits connected to this hit std::set<PHG4Hit*> g4hits = all_truth_hits(hit); for (std::set<PHG4Hit*>::iterator jter = g4hits.begin(); jter != g4hits.end(); ++jter) { PHG4Hit* candidate = *jter; if (candidate->get_hit_id() == g4hit->get_hit_id()) { hits.insert(hit); } } } if (_do_cache) _cache_all_hits_from_g4hit.insert(make_pair(g4hit,hits)); return hits; }
int PHG4SvtxDeadArea::process_event(PHCompositeNode *topNode) { _timer.get()->restart(); std::vector<unsigned int> remove_hits; for (SvtxHitMap::Iter iter = _hits->begin(); iter != _hits->end(); ++iter) { SvtxHit* hit = &iter->second; if (_rand->Rndm() > get_hit_efficiency(hit->get_layer())) { remove_hits.push_back(hit->get_id()); } } for (unsigned int i = 0; i < remove_hits.size(); ++i) { _hits->erase(remove_hits[i]); } _timer.get()->stop(); return Fun4AllReturnCodes::EVENT_OK; }
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; }
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; }
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; }
void PHG4SvtxClusterizer::ClusterLadderCells(PHCompositeNode *topNode) { //---------- // Get Nodes //---------- // get the SVX geometry object PHG4CylinderGeomContainer* geom_container = findNode::getClass<PHG4CylinderGeomContainer>(topNode,"CYLINDERGEOM_SILICON_TRACKER"); if (!geom_container) return; PHG4HitContainer* g4hits = findNode::getClass<PHG4HitContainer>(topNode,"G4HIT_SILICON_TRACKER"); if (!g4hits) return; PHG4CylinderCellContainer* cells = findNode::getClass<PHG4CylinderCellContainer>(topNode,"G4CELL_SILICON_TRACKER"); if (!cells) return; //----------- // Clustering //----------- // sort hits layer by layer std::multimap<int,SvtxHit*> layer_hits_mmap; for (SvtxHitMap::Iter iter = _hits->begin(); iter != _hits->end(); ++iter) { SvtxHit* hit = &iter->second; layer_hits_mmap.insert(make_pair(hit->get_layer(),hit)); } PHG4CylinderGeomContainer::ConstRange layerrange = geom_container->get_begin_end(); for(PHG4CylinderGeomContainer::ConstIterator layeriter = layerrange.first; layeriter != layerrange.second; ++layeriter) { int layer = layeriter->second->get_layer(); std::map<PHG4CylinderCell*,SvtxHit*> cell_hit_map; vector<PHG4CylinderCell*> cell_list; for (std::multimap<int,SvtxHit*>::iterator hiter = layer_hits_mmap.lower_bound(layer); hiter != layer_hits_mmap.upper_bound(layer); ++hiter) { SvtxHit* hit = hiter->second; PHG4CylinderCell* cell = cells->findCylinderCell(hit->get_cellid()); cell_list.push_back(cell); cell_hit_map.insert(make_pair(cell,hit)); } if (cell_list.size() == 0) continue; // if no cells, go to the next layer // i'm not sure this sorting is ever really used sort(cell_list.begin(), cell_list.end(), PHG4SvtxClusterizer::ladder_lessthan); typedef adjacency_list <vecS, vecS, undirectedS> Graph; typedef graph_traits<Graph>::vertex_descriptor Vertex; Graph G; for(unsigned int i=0; i<cell_list.size(); i++) { for(unsigned int j=i+1; j<cell_list.size(); j++) { if(ladder_are_adjacent(cell_list[i], cell_list[j]) ) add_edge(i,j,G); } add_edge(i,i,G); } // Find the connections between the vertices of the graph (vertices are the rawhits, // connections are made when they are adjacent to one another) vector<int> component(num_vertices(G)); // this is the actual clustering, performed by boost connected_components(G, &component[0]); // Loop over the components(hit cells) compiling a list of the // unique connected groups (ie. clusters). set<int> cluster_ids; // unique components multimap<int, PHG4CylinderCell*> clusters; for (unsigned int i=0; i<component.size(); i++) { cluster_ids.insert( component[i] ); clusters.insert( make_pair(component[i], cell_list[i]) ); } // for (set<int>::iterator clusiter = cluster_ids.begin(); clusiter != cluster_ids.end(); clusiter++ ) { int clusid = *clusiter; pair<multimap<int, PHG4CylinderCell*>::iterator, multimap<int, PHG4CylinderCell*>::iterator> clusrange = clusters.equal_range(clusid); multimap<int, PHG4CylinderCell*>::iterator mapiter = clusrange.first; int layer = mapiter->second->get_layer(); PHG4CylinderGeom* geom = geom_container->GetLayerGeom(layer); SvtxCluster clus; clus.set_layer( layer ); float clus_energy = 0.0; unsigned int clus_adc = 0; // determine the size of the cluster in phi and z // useful for track fitting the cluster set<int> phibins; set<int> zbins; for (mapiter = clusrange.first; mapiter != clusrange.second; mapiter++ ) { PHG4CylinderCell* cell = mapiter->second; phibins.insert(cell->get_binphi()); zbins.insert(cell->get_binz()); } float thickness = geom->get_thickness(); float pitch = geom->get_strip_y_spacing(); float length = geom->get_strip_z_spacing(); float phisize = phibins.size()*pitch; float zsize = zbins.size()*length; float tilt = geom->get_strip_tilt(); // determine the cluster position... double xsum = 0.0; double ysum = 0.0; double zsum = 0.0; unsigned nhits = 0; int ladder_z_index = -1; int ladder_phi_index = -1; for(mapiter = clusrange.first; mapiter != clusrange.second; mapiter++ ) { PHG4CylinderCell* cell = mapiter->second; SvtxHit* hit = cell_hit_map[cell]; clus.insert_hit(hit->get_id()); clus_energy += hit->get_e(); clus_adc += hit->get_adc(); double hit_location[3] = {0.0,0.0,0.0}; geom->find_strip_center(cell->get_ladder_z_index(), cell->get_ladder_phi_index(), cell->get_binz(), cell->get_binphi(), hit_location); ladder_z_index = cell->get_ladder_z_index(); ladder_phi_index = cell->get_ladder_phi_index(); if (_make_e_weights[layer]) { xsum += hit_location[0] * hit->get_adc(); ysum += hit_location[1] * hit->get_adc(); zsum += hit_location[2] * hit->get_adc(); } else { xsum += hit_location[0]; ysum += hit_location[1]; zsum += hit_location[2]; } ++nhits; } double clusx = NAN; double clusy = NAN; double clusz = NAN; if (_make_e_weights[layer]) { clusx = xsum / clus_adc; clusy = ysum / clus_adc; clusz = zsum / clus_adc; } else { clusx = xsum / nhits; clusy = ysum / nhits; clusz = zsum / nhits; } double ladder_location[3] = {0.0,0.0,0.0}; geom->find_segment_center(ladder_z_index, ladder_phi_index, ladder_location); double ladderphi = atan2( ladder_location[1], ladder_location[0] ); clus.set_position(0, clusx); clus.set_position(1, clusy); clus.set_position(2, clusz); clus.set_e(clus_energy); clus.set_adc(clus_adc); float invsqrt12 = 1.0/sqrt(12.0); TMatrixF DIM(3,3); DIM[0][0] = pow(0.5*thickness,2); DIM[0][1] = 0.0; DIM[0][2] = 0.0; DIM[1][0] = 0.0; DIM[1][1] = pow(0.5*phisize,2); DIM[1][2] = 0.0; DIM[2][0] = 0.0; DIM[2][1] = 0.0; DIM[2][2] = pow(0.5*zsize,2); TMatrixF ERR(3,3); ERR[0][0] = pow(0.5*thickness*invsqrt12,2); ERR[0][1] = 0.0; ERR[0][2] = 0.0; ERR[1][0] = 0.0; ERR[1][1] = pow(0.5*phisize*invsqrt12,2); ERR[1][2] = 0.0; ERR[2][0] = 0.0; ERR[2][1] = 0.0; ERR[2][2] = pow(0.5*zsize*invsqrt12,2); TMatrixF ROT(3,3); ROT[0][0] = cos(ladderphi); ROT[0][1] = -1.0*sin(ladderphi); ROT[0][2] = 0.0; ROT[1][0] = sin(ladderphi); ROT[1][1] = cos(ladderphi); ROT[1][2] = 0.0; ROT[2][0] = 0.0; ROT[2][1] = 0.0; ROT[2][2] = 1.0; TMatrixF TILT(3,3); TILT[0][0] = 1.0; TILT[0][1] = 0.0; TILT[0][2] = 0.0; TILT[1][0] = 0.0; TILT[1][1] = cos(tilt); TILT[1][2] = -1.0*sin(tilt); TILT[2][0] = 0.0; TILT[2][1] = sin(tilt); TILT[2][2] = cos(tilt); TMatrixF R(3,3); R = ROT * TILT; TMatrixF R_T(3,3); R_T.Transpose(R); TMatrixF COVAR_DIM(3,3); COVAR_DIM = R * DIM * R_T; clus.set_size( 0 , 0 , COVAR_DIM[0][0] ); clus.set_size( 0 , 1 , COVAR_DIM[0][1] ); clus.set_size( 0 , 2 , COVAR_DIM[0][2] ); clus.set_size( 1 , 0 , COVAR_DIM[1][0] ); clus.set_size( 1 , 1 , COVAR_DIM[1][1] ); clus.set_size( 1 , 2 , COVAR_DIM[1][2] ); clus.set_size( 2 , 0 , COVAR_DIM[2][0] ); clus.set_size( 2 , 1 , COVAR_DIM[2][1] ); clus.set_size( 2 , 2 , COVAR_DIM[2][2] ); TMatrixF COVAR_ERR(3,3); COVAR_ERR = R * ERR * R_T; clus.set_error( 0 , 0 , COVAR_ERR[0][0] ); clus.set_error( 0 , 1 , COVAR_ERR[0][1] ); clus.set_error( 0 , 2 , COVAR_ERR[0][2] ); clus.set_error( 1 , 0 , COVAR_ERR[1][0] ); clus.set_error( 1 , 1 , COVAR_ERR[1][1] ); clus.set_error( 1 , 2 , COVAR_ERR[1][2] ); clus.set_error( 2 , 0 , COVAR_ERR[2][0] ); clus.set_error( 2 , 1 , COVAR_ERR[2][1] ); clus.set_error( 2 , 2 , COVAR_ERR[2][2] ); if (clus_energy > get_threshold_by_layer(layer)) { SvtxCluster* ptr = _clusterlist->insert(clus); if (!ptr->IsValid()) { static bool first = true; if (first) { cout << PHWHERE << "ERROR: Invalid SvtxClusters are being produced" << endl; ptr->identify(); first = false; } } if (verbosity>1) { double radius = sqrt(clusx*clusx+clusy*clusy); double clusphi = atan2(clusy,clusx); cout << "r=" << radius << " phi=" << clusphi << " z=" << clusz << endl; cout << "pos=(" << clus.get_position(0) << ", " << clus.get_position(1) << ", " << clus.get_position(2) << ")" << endl; cout << endl; } } else if (verbosity>1) { double radius = sqrt(clusx*clusx+clusy*clusy); double clusphi = atan2(clusy,clusx); cout << "removed r=" << radius << " phi=" << clusphi << " z=" << clusz << endl; cout << "pos=(" << clus.get_position(0) << ", " << clus.get_position(1) << ", " << clus.get_position(2) << ")" << endl; cout << endl; } } } return; }
int PHG4TPCClusterizer::process_event(PHCompositeNode* topNode) { PHNodeIterator iter(topNode); PHCompositeNode* dstNode = static_cast<PHCompositeNode*>(iter.findFirst("PHCompositeNode", "DST")); if (!dstNode) { cout << PHWHERE << "DST Node missing, doing nothing." << endl; return Fun4AllReturnCodes::ABORTRUN; } PHNodeIterator iter_dst(dstNode); SvtxHitMap* hits = findNode::getClass<SvtxHitMap>(dstNode, "SvtxHitMap"); if (!hits) { cout << PHWHERE << "ERROR: Can't find node SvtxHitMap" << endl; return Fun4AllReturnCodes::ABORTRUN; } PHCompositeNode* svxNode = dynamic_cast<PHCompositeNode*>(iter_dst.findFirst("PHCompositeNode", "SVTX")); if (!svxNode) { svxNode = new PHCompositeNode("SVTX"); dstNode->addNode(svxNode); } SvtxClusterMap* svxclusters = findNode::getClass<SvtxClusterMap>(dstNode, "SvtxClusterMap"); if (!svxclusters) { svxclusters = new SvtxClusterMap_v1(); PHIODataNode<PHObject>* SvtxClusterMapNode = new PHIODataNode<PHObject>(svxclusters, "SvtxClusterMap", "PHObject"); svxNode->addNode(SvtxClusterMapNode); } PHG4CylinderCellGeomContainer* geom_container = findNode::getClass<PHG4CylinderCellGeomContainer>(topNode,"CYLINDERCELLGEOM_SVTX"); if (!geom_container) return Fun4AllReturnCodes::ABORTRUN; PHG4CylinderCellContainer* cells = findNode::getClass<PHG4CylinderCellContainer>(dstNode,"G4CELL_SVTX"); if (!cells) return Fun4AllReturnCodes::ABORTRUN; std::vector<std::vector<const SvtxHit*> > layer_sorted; PHG4CylinderCellGeomContainer::ConstRange layerrange = geom_container->get_begin_end(); for (PHG4CylinderCellGeomContainer::ConstIterator layeriter = layerrange.first; layeriter != layerrange.second; ++layeriter) { // We only need TPC layers here, so skip the layers below _min_layer // This if statement is needed because although the maps ladder layers are not included in the cylinder cell geom container, // the cylinder Svx layers are, so they have to be dropped here if they are present if( (unsigned int) layeriter->second->get_layer() < _min_layer) continue; layer_sorted.push_back(std::vector<const SvtxHit*>()); } for (SvtxHitMap::Iter iter = hits->begin(); iter != hits->end(); ++iter) { SvtxHit* hit = iter->second; if( (unsigned int) hit->get_layer() < _min_layer) continue; layer_sorted[hit->get_layer() - _min_layer].push_back(hit); } for (PHG4CylinderCellGeomContainer::ConstIterator layeriter = layerrange.first; layeriter != layerrange.second; ++layeriter) { unsigned int layer = (unsigned int)layeriter->second->get_layer(); // exit on the MAPS layers... // needed in case cylinder svtx layers are present if (layer < _min_layer) continue; if (layer > _max_layer) continue; PHG4CylinderCellGeom* geo = geom_container->GetLayerCellGeom(layer); const int nphibins = layeriter->second->get_phibins(); const int nzbins = layeriter->second->get_zbins(); nhits.clear(); nhits.assign(nzbins, 0); amps.clear(); amps.assign(nphibins * nzbins, 0.); cellids.clear(); cellids.assign(nphibins * nzbins, 0); for (unsigned int i = 0; i < layer_sorted[layer - _min_layer].size(); ++i) { const SvtxHit* hit = layer_sorted[layer - _min_layer][i]; if (hit->get_e() <= 0.) continue; PHG4CylinderCell* cell = cells->findCylinderCell(hit->get_cellid()); int phibin = cell->get_binphi(); int zbin = cell->get_binz(); nhits[zbin] += 1; amps[zbin * nphibins + phibin] += hit->get_e(); cellids[zbin * nphibins + phibin] = hit->get_id(); } int nhits_tot = 0; for (int zbin = 0; zbin < nzbins; ++zbin) { nhits_tot += nhits[zbin]; } while (nhits_tot > 0) { for (int zbin = 0; zbin < nzbins; ++zbin) { if (nhits[zbin] <= 0) continue; for (int phibin = 0; phibin < nphibins; ++phibin) { if (is_local_maximum(amps, nphibins, nzbins, phibin, zbin) == false) { continue; } float phi = 0.; float z = 0.; float e = 0.; fit_cluster(amps, nphibins, nzbins, nhits_tot, nhits, phibin, zbin, geo, phi, z, e); if ((layer > 2) && (e < energy_cut)) { continue; } SvtxCluster_v1 clus; clus.set_layer(layer); clus.set_e(e); double radius = geo->get_radius() + 0.5*geo->get_thickness(); clus.set_position(0, radius * cos(phi)); clus.set_position(1, radius * sin(phi)); clus.set_position(2, z); clus.insert_hit(cellids[zbin * nphibins + phibin]); float invsqrt12 = 1.0/sqrt(12.); TMatrixF DIM(3,3); DIM[0][0] = 0.0;//pow(0.0*0.5*thickness,2); DIM[0][1] = 0.0; DIM[0][2] = 0.0; DIM[1][0] = 0.0; DIM[1][1] = pow(0.5*0.011,2); DIM[1][2] = 0.0; DIM[2][0] = 0.0; DIM[2][1] = 0.0; DIM[2][2] = pow(0.5*0.03,2); TMatrixF ERR(3,3); ERR[0][0] = 0.0;//pow(0.0*0.5*thickness*invsqrt12,2); ERR[0][1] = 0.0; ERR[0][2] = 0.0; ERR[1][0] = 0.0; ERR[1][1] = pow(0.5*0.011*invsqrt12,2); ERR[1][2] = 0.0; ERR[2][0] = 0.0; ERR[2][1] = 0.0; ERR[2][2] = pow(0.5*0.03*invsqrt12,2); TMatrixF ROT(3,3); ROT[0][0] = cos(phi); ROT[0][1] = -sin(phi); ROT[0][2] = 0.0; ROT[1][0] = sin(phi); ROT[1][1] = cos(phi); ROT[1][2] = 0.0; ROT[2][0] = 0.0; ROT[2][1] = 0.0; ROT[2][2] = 1.0; TMatrixF ROT_T(3,3); ROT_T.Transpose(ROT); TMatrixF COVAR_DIM(3,3); COVAR_DIM = ROT * DIM * ROT_T; clus.set_size( 0 , 0 , COVAR_DIM[0][0] ); clus.set_size( 0 , 1 , COVAR_DIM[0][1] ); clus.set_size( 0 , 2 , COVAR_DIM[0][2] ); clus.set_size( 1 , 0 , COVAR_DIM[1][0] ); clus.set_size( 1 , 1 , COVAR_DIM[1][1] ); clus.set_size( 1 , 2 , COVAR_DIM[1][2] ); clus.set_size( 2 , 0 , COVAR_DIM[2][0] ); clus.set_size( 2 , 1 , COVAR_DIM[2][1] ); clus.set_size( 2 , 2 , COVAR_DIM[2][2] ); TMatrixF COVAR_ERR(3,3); COVAR_ERR = ROT * ERR * ROT_T; clus.set_error( 0 , 0 , COVAR_ERR[0][0] ); clus.set_error( 0 , 1 , COVAR_ERR[0][1] ); clus.set_error( 0 , 2 , COVAR_ERR[0][2] ); clus.set_error( 1 , 0 , COVAR_ERR[1][0] ); clus.set_error( 1 , 1 , COVAR_ERR[1][1] ); clus.set_error( 1 , 2 , COVAR_ERR[1][2] ); clus.set_error( 2 , 0 , COVAR_ERR[2][0] ); clus.set_error( 2 , 1 , COVAR_ERR[2][1] ); clus.set_error( 2 , 2 , COVAR_ERR[2][2] ); svxclusters->insert(&clus); } } } } reset(); return Fun4AllReturnCodes::EVENT_OK; }