#include <iostream>
#include <vector>
#include <cmath>
#include <numeric>
#include <TSystem.h>
#include <Math/VectorUtil.h>
#include "filval.hpp"
#include "root_filval.hpp"
#include "common.hpp"
#include "analysis/TrackingNtupleObjs.hpp"
typedef ROOT::Math::LorentzVector<ROOT::Math::PxPyPzE4D<float>> Vec4;
SeedCollection seeds;
GenCollection gens;
SimTrackCollection sim_tracks;
SimVertexCollection sim_vertices;
TrackCollection gsf_tracks;
SuperClusterCollection scls;
std::vector<SimTrack> sim_els;
void register_objects(TrackingDataSet& tds){
seeds.init(&tds);
gens.init(&tds);
sim_tracks.init(&tds);
sim_vertices.init(&tds);
gsf_tracks.init(&tds);
scls.init(&tds);
}
struct {
Value<float>* x;
Value<float>* y;
Value<float>* z;
Value<float>* sigma_x;
Value<float>* sigma_y;
Value<float>* sigma_z;
} bs;
template <typename T>
struct KinColl {
T* pt;
T* eta;
T* phi;
};
bool in_lum_region(const SimVertex& vertex) {
/* Here approximate the luminous region as a cylinder with length 5*\sigma_z and radius
* sqrt(\simga_x^2 + \sigma_y^2) centered as beamspot position.
*/
float dx = vertex.x() - bs.x->get();
float dy = vertex.y() - bs.y->get();
float dz = vertex.z() - bs.z->get();
auto radius = static_cast<float>(5 * sqrt(pow(bs.sigma_x->get(), 2) + pow(bs.sigma_y->get(), 2)));
float half_len = 5*bs.sigma_z->get();
return sqrt(dx*dx + dy*dy) < radius and abs(dz) < half_len;
};
bool is_good_sim(const SimTrack& sim_track) {
const auto& vertex = sim_vertices[sim_track.parentVtxIdx()];
return abs(sim_track.pdgId()) == 11 and // electrons
in_lum_region(vertex) and // from luminous region
abs(sim_track.eta())<3.0; // inside ECAL acceptance
};
bool is_good_sim(const std::vector<SimTrack> prompt_sims, const SimTrack& sim_track) {
return find(prompt_sims.begin(), prompt_sims.end(), sim_track) != prompt_sims.end();
};
bool is_good_seed(const Seed& seed, float hoe_cut) {
return seed.isECALDriven() and seed.hoe() < hoe_cut;
}
float reco_energy_rel_err(const SimTrack& sim_track, const Seed& seed) {
return (sim_track.pt() - seed.Et()) / sim_track.pt() ;
}
float reco_energy_rel_err(const SimTrack& sim_track, const Track& track) {
return (sim_track.pt() - track.pt()) / sim_track.pt() ;
}
template<typename TrackOrSeed>
bool reco_energy_consistent(const SimTrack& sim_track, const TrackOrSeed& track, float consistency_cut=0.1) {
return fabs(reco_energy_rel_err(sim_track, track)) < consistency_cut;
}
Vec4 scl_p4(const SuperCluster& scl) {
return Vec4(scl.px(), scl.py(), scl.pz(), scl.e());
}
double deltaR(double eta1, double phi1, double eta2, double phi2) {
return sqrt(pow(eta1 - eta2, 2.0) +
pow(phi1 - phi2, 2.0));
}
void update_sim_els() {
sim_els.clear();
for (const SimTrack sim_track: sim_tracks) {
if (is_good_sim(sim_track)) {
sim_els.push_back(sim_track);
}
}
}
std::tuple<std::vector<SimTrack>, std::vector<SimTrack>> get_prompt_sims() {
/*
* Returns sim tracks that pass is_good_sim as well as match well with a
* prompt gen electron
*/
std::vector<Gen> prompt_gen;
for (const auto& gen : gens) {
if (abs(gen.pdgId()) == 11 and gen.isPrompt()) {
prompt_gen.push_back(gen);
}
}
std::vector<SimTrack> prompt_sim;
for (const auto& gen : prompt_gen) {
float gen_phi = atan2(gen.py(), gen.px());
float gen_eta = pseudorapidityP(gen.px(), gen.py(), gen.pz());
int gen_id = gen.pdgId();
for (const auto& sim_el : sim_els) {
float sim_phi = sim_el.phi();
float sim_eta = sim_el.eta();
int sim_id = sim_el.pdgId();
if (gen_id == sim_id and deltaR(gen_eta, gen_phi, sim_eta, sim_phi) < 0.05) {
prompt_sim.push_back(sim_el);
break;
}
}
}
std::vector<SimTrack> nonprompt_sim;
for (const auto& sim_el : sim_els) {
if (find(prompt_sim.begin(), prompt_sim.end(), sim_el) == prompt_sim.end()) {
nonprompt_sim.push_back(sim_el);
}
}
return make_tuple(prompt_sim, nonprompt_sim);
}
auto get_match_stats(bool dRMatch) {
int nSimTrack = 0;
int nGSFTrack = 0;
int nMatched = 0; // 1-to-1
int nMerged = 0; // n-to-1
int nLost = 0; // 1-to-0
int nSplit = 0; // 1-to-n
int nFaked = 0; // 0-to-1
int nFlipped = 0;
vector<float> matched_dR;
vector<float> matched_dpT;
std::map<int, std::vector<int>> sim_matches;
std::map<int, std::vector<int>> gsf_matches;
for(const auto& sim_track : sim_els)
sim_matches[sim_track.idx] = {};
for(const auto& gsf_track : gsf_tracks)
gsf_matches[gsf_track.idx] = {};
nSimTrack = static_cast<int>(sim_matches.size());
nGSFTrack = static_cast<int>(gsf_matches.size());
for (const auto& sim_track : sim_els) {
if (dRMatch) {
for (const auto& gsf_track : gsf_tracks) {
double dR = deltaR(sim_track.eta(), sim_track.phi(), gsf_track.eta(), gsf_track.phi());
if (dR < 0.2) {
sim_matches[sim_track.idx].push_back(gsf_track.idx);
gsf_matches[gsf_track.idx].push_back(sim_track.idx);
matched_dR.push_back(dR);
matched_dpT.push_back((sim_track.pt() - gsf_track.pt())/sim_track.pt());
if (gsf_track.q() != sim_track.q()) {
nFlipped++;
}
}
}
} else {
for (const auto& gsfIdx : sim_track.trkIdx()) {
const Track& gsf_track = gsf_tracks[gsfIdx];
double dR = deltaR(sim_track.eta(), sim_track.phi(), gsf_track.eta(), gsf_track.phi());
sim_matches[sim_track.idx].push_back(gsf_track.idx);
gsf_matches[gsf_track.idx].push_back(sim_track.idx);
matched_dR.push_back(static_cast<float &&>(dR));
matched_dpT.push_back((sim_track.pt() - gsf_track.pt())/sim_track.pt());
if (gsf_track.q() != sim_track.q()) {
nFlipped++;
}
}
}
}
for (const auto& p : sim_matches) {
const auto& matches = p.second;
if (matches.size() == 0) nLost++;
if (matches.size() == 1 and gsf_matches[matches[0]].size() == 1) nMatched++;
if (matches.size() > 1) nSplit++;
}
for (const auto& p : gsf_matches) {
const auto& matches = p.second;
if (matches.size() == 0) nFaked++;
if (matches.size() > 1) nMerged++;
}
return std::make_tuple(nSimTrack, nGSFTrack, nMatched, nMerged, nLost, nSplit, nFaked, nFlipped, matched_dR, matched_dpT);
}
void run(){
using namespace std;
using namespace fv;
using namespace fv_root;
using namespace fv_util;
auto file_list = the_config->get_source_files();
string output_filename = the_config->get_output_filename();
TrackingDataSet tds(output_filename, file_list, "trackingNtuple/tree");
register_objects(tds);
auto hoe_cut = the_config->get("hoe_cut").as<float>(999);
bs = {
tds.track_branch<float>("bsp_x"),
tds.track_branch<float>("bsp_y"),
tds.track_branch<float>("bsp_z"),
tds.track_branch<float>("bsp_sigmax"),
tds.track_branch<float>("bsp_sigmay"),
tds.track_branch<float>("bsp_sigmaz")
};
enum TMType {
NoMatch = 0,
SeedMatched = 1,
TrackMatched = 2,
SeedAndTrackMatched = 3,
};
std::map<std::tuple<int, int>, ContainerTH2<float>*> residuals_dRz;
std::map<std::tuple<int, int>, ContainerTH2<float>*> residuals_dPhi;
std::map<std::tuple<int, int, int>, ContainerTH2<float>*> BPIX_residuals_dRz;
std::map<std::tuple<int, int, int>, ContainerTH2<float>*> BPIX_residuals_dPhi;
std::map<std::tuple<int, int, int>, ContainerTH2<float>*> FPIX_residuals_dRz;
std::map<std::tuple<int, int, int>, ContainerTH2<float>*> FPIX_residuals_dPhi;
stringstream name;
auto set_name = [&name](const std::string& var, const std::string& region,
const int& layer, const int& hit, const int& tm_type) {
name.str("");
name << var << "_" << region;
if (layer>0)
name << "_L" << layer;
name << "_H" << hit << "_v_Et";
switch (tm_type) {
case NoMatch:
name << "_NoMatch";
break;
case SeedMatched:
name << "_SeedMatched";
break;
case TrackMatched:
name << "_TrackMatched";
break;
case SeedAndTrackMatched:
name << "_SeedAndTrackMatched";
break;
default:
break;
}
};
THParams hist_params;
for (int hit=1; hit<=3; hit++) {
for (int tm_type = NoMatch; tm_type <= SeedAndTrackMatched; tm_type++) {
for (int layer=1; layer<=4; layer++) {
hist_params = (hit == 1) ? THParams::lookup("dRz_v_Et") : THParams::lookup("dRz_v_Et_outer_hits");
set_name("dRz", "BPIX", layer, hit, tm_type);
BPIX_residuals_dRz[make_tuple(layer, hit, tm_type)] = tds.register_container<ContainerTH2<float>>(name.str(), hist_params);
set_name("dRz", "FPIX", layer, hit, tm_type);
FPIX_residuals_dRz[make_tuple(layer, hit, tm_type)] = tds.register_container<ContainerTH2<float>>(name.str(), hist_params);
hist_params = (hit == 1) ? THParams::lookup("dPhi_v_Et") : THParams::lookup("dPhi_v_Et_outer_hits");
set_name("dPhi", "BPIX", layer, hit, tm_type);
BPIX_residuals_dPhi[make_tuple(layer, hit, tm_type)] = tds.register_container<ContainerTH2<float>>(name.str(), hist_params);
set_name("dPhi", "FPIX", layer, hit, tm_type);
FPIX_residuals_dPhi[make_tuple(layer, hit, tm_type)] = tds.register_container<ContainerTH2<float>>(name.str(), hist_params);
}
hist_params = (hit == 1) ? THParams::lookup("dRz_v_Et") : THParams::lookup("dRz_v_Et_outer_hits");
set_name("dRz", "ALL", 0, hit, tm_type);
residuals_dRz[std::make_tuple(hit, tm_type)] = tds.register_container<ContainerTH2<float>>(name.str(), hist_params);
hist_params = (hit == 1) ? THParams::lookup("dPhi_v_Et") : THParams::lookup("dPhi_v_Et_outer_hits");
set_name("dPhi", "ALL", 0, hit, tm_type);
residuals_dPhi[make_tuple(hit, tm_type)] = tds.register_container<ContainerTH2<float>>(name.str(), hist_params);
}
}
std::map<int,vector<float>> eta_regions = {{1, {0.0, 1.1, 1.8, 3.0}},
{2, {0.0, 1.4, 2.3, 3.0}},
{3, {0.0, 1.0, 2.0, 3.0}}};
auto get_region = [&eta_regions](int hit, float eta) {
auto regions = eta_regions[hit];
if (regions.size() <= 1) return 1;
float abseta = abs(eta);
for (int r_idx=1; r_idx < regions.size(); r_idx++) {
if (abseta > regions[r_idx-1] and abseta < regions[r_idx]) {
return r_idx;
}
}
return static_cast<int>(regions.size());
};
std::map<int, ContainerTH2<float>*> dPhi_residuals_v_eta;
std::map<int, ContainerTH2<float>*> dRz_residuals_v_eta;
std::map<std::pair<int, int>, ContainerTH2<float>*> dPhi_residuals_v_region;
std::map<std::pair<int, int>, ContainerTH2<float>*> dRz_residuals_v_region;
for (int hit=1; hit<=3; hit++) {
name.str("");
name << "dPhi_residuals_v_eta_H" << hit;
hist_params = (hit==1) ? THParams::lookup("dPhi_v_eta") : THParams::lookup("dPhi_v_eta_outer_hits");
dPhi_residuals_v_eta[hit] = tds.register_container<ContainerTH2<float>>(name.str(), hist_params);
name.str("");
name << "dRz_residuals_v_eta_H" << hit;
hist_params = (hit==1) ? THParams::lookup("dRz_v_eta") : THParams::lookup("dRz_v_eta_outer_hits");
dRz_residuals_v_eta[hit] = tds.register_container<ContainerTH2<float>>(name.str(), hist_params);
for (int region=1; region<=eta_regions[hit].size()-1; region++){
hist_params = (hit==1) ? THParams::lookup("dRz_v_Et") : THParams::lookup("dRz_v_Et_outer_hits");
name.str("");
name << "dRz_residuals_H" << hit << "_R" << region;
dRz_residuals_v_region[{hit, region}] = tds.register_container<ContainerTH2<float>>(name.str(), hist_params);
hist_params = (hit==1) ? THParams::lookup("dPhi_v_Et") : THParams::lookup("dPhi_v_Et_outer_hits");
name.str("");
name << "dPhi_residuals_H" << hit << "_R" << region;
dPhi_residuals_v_region[{hit, region}] = tds.register_container<ContainerTH2<float>>(name.str(), hist_params);
}
}
KinColl<ContainerTH1<float>> good_sim_kinems = {
tds.register_container<ContainerTH1<float>>("good_sim_v_pt", THParams::lookup("pt_fine")),
tds.register_container<ContainerTH1<float>>("good_sim_v_eta", THParams::lookup("eta_fine")),
tds.register_container<ContainerTH1<float>>("good_sim_v_phi", THParams::lookup("phi_fine"))};
KinColl<ContainerTH1<float>> gsf_kinems = {
tds.register_container<ContainerTH1<float>>("gsf_track_v_pt", THParams::lookup("pt_fine")),
tds.register_container<ContainerTH1<float>>("gsf_track_v_eta", THParams::lookup("eta_fine")),
tds.register_container<ContainerTH1<float>>("gsf_track_v_phi", THParams::lookup("phi_fine"))};
KinColl<ContainerTH1<float>> seed_kinems = {
tds.register_container<ContainerTH1<float>>("seed_v_pt", THParams::lookup("pt_fine")),
tds.register_container<ContainerTH1<float>>("seed_v_eta", THParams::lookup("eta_fine")),
tds.register_container<ContainerTH1<float>>("seed_v_phi", THParams::lookup("phi_fine"))};
KinColl<ContainerTH1<float>> scl_kinems = {
tds.register_container<ContainerTH1<float>>("scl_v_pt", THParams::lookup("pt_fine")),
tds.register_container<ContainerTH1<float>>("scl_v_eta", THParams::lookup("eta_fine")),
tds.register_container<ContainerTH1<float>>("scl_v_phi", THParams::lookup("phi_fine"))};
KinColl<ContainerTH1<float>> prompt_kinems = {
tds.register_container<ContainerTH1<float>>("prompt_v_pt", THParams::lookup("pt_fine")),
tds.register_container<ContainerTH1<float>>("prompt_v_eta", THParams::lookup("eta_fine")),
tds.register_container<ContainerTH1<float>>("prompt_v_phi", THParams::lookup("phi_fine"))};
KinColl<ContainerTH1<float>> nonprompt_kinems = {
tds.register_container<ContainerTH1<float>>("nonprompt_v_pt", THParams::lookup("pt_fine")),
tds.register_container<ContainerTH1<float>>("nonprompt_v_eta", THParams::lookup("eta_fine")),
tds.register_container<ContainerTH1<float>>("nonprompt_v_phi", THParams::lookup("phi_fine"))};
KinColl<EfficiencyContainer<float>> seed_eff = {
tds.register_container<EfficiencyContainer<float>>("seed_eff_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("seed_eff_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("seed_eff_v_phi", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> seed_pur = {
tds.register_container<EfficiencyContainer<float>>("seed_pur_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("seed_pur_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("seed_pur_v_phi", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> tracking_eff = {
tds.register_container<EfficiencyContainer<float>>("tracking_eff_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("tracking_eff_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("tracking_eff_v_phi", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> tracking_pur = {
tds.register_container<EfficiencyContainer<float>>("tracking_pur_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("tracking_pur_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("tracking_pur_v_phi", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> prompt_eff = {
tds.register_container<EfficiencyContainer<float>>("prompt_eff_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("prompt_eff_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("prompt_eff_v_phi", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> prompt_pur = {
tds.register_container<EfficiencyContainer<float>>("prompt_pur_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("prompt_pur_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("prompt_pur_v_phi", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> nonprompt_eff = {
tds.register_container<EfficiencyContainer<float>>("nonprompt_eff_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("nonprompt_eff_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("nonprompt_eff_v_phi", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> nonprompt_pur = {
tds.register_container<EfficiencyContainer<float>>("nonprompt_pur_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("nonprompt_pur_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("nonprompt_pur_v_phi", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> tracking_eff_dR = {
tds.register_container<EfficiencyContainer<float>>("tracking_eff_v_pt_dR", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("tracking_eff_v_eta_dR", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("tracking_eff_v_phi_dR", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> tracking_pur_dR = {
tds.register_container<EfficiencyContainer<float>>("tracking_pur_v_pt_dR", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("tracking_pur_v_eta_dR", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("tracking_pur_v_phi_dR", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> prompt_eff_dR = {
tds.register_container<EfficiencyContainer<float>>("prompt_eff_v_pt_dR", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("prompt_eff_v_eta_dR", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("prompt_eff_v_phi_dR", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> prompt_pur_dR = {
tds.register_container<EfficiencyContainer<float>>("prompt_pur_v_pt_dR", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("prompt_pur_v_eta_dR", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("prompt_pur_v_phi_dR", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> nonprompt_eff_dR = {
tds.register_container<EfficiencyContainer<float>>("nonprompt_eff_v_pt_dR", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("nonprompt_eff_v_eta_dR", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("nonprompt_eff_v_phi_dR", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> nonprompt_pur_dR = {
tds.register_container<EfficiencyContainer<float>>("nonprompt_pur_v_pt_dR", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("nonprompt_pur_v_eta_dR", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("nonprompt_pur_v_phi_dR", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> fake_rate = {
tds.register_container<EfficiencyContainer<float>>("fake_rate_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("fake_rate_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("fake_rate_v_phi", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> partial_fake_rate = {
tds.register_container<EfficiencyContainer<float>>("partial_fake_rate_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("partial_fake_rate_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("partial_fake_rate_v_phi", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> full_fake_rate = {
tds.register_container<EfficiencyContainer<float>>("full_fake_rate_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("full_fake_rate_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("full_fake_rate_v_phi", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> clean_fake_rate = {
tds.register_container<EfficiencyContainer<float>>("clean_fake_rate_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("clean_fake_rate_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("clean_fake_rate_v_phi", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> fake_rate_incl = {
tds.register_container<EfficiencyContainer<float>>("fake_rate_incl_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("fake_rate_incl_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("fake_rate_incl_v_phi", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> partial_fake_rate_incl = {
tds.register_container<EfficiencyContainer<float>>("partial_fake_rate_incl_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("partial_fake_rate_incl_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("partial_fake_rate_incl_v_phi", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> full_fake_rate_incl = {
tds.register_container<EfficiencyContainer<float>>("full_fake_rate_incl_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("full_fake_rate_incl_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("full_fake_rate_incl_v_phi", THParams::lookup("phi"))};
KinColl<EfficiencyContainer<float>> clean_fake_rate_incl = {
tds.register_container<EfficiencyContainer<float>>("clean_fake_rate_incl_v_pt", THParams::lookup("pt")),
tds.register_container<EfficiencyContainer<float>>("clean_fake_rate_incl_v_eta", THParams::lookup("eta")),
tds.register_container<EfficiencyContainer<float>>("clean_fake_rate_incl_v_phi", THParams::lookup("phi"))};
auto& hit_vs_layer_barrel = *tds.register_container<ContainerTH2<int>>("hit_vs_layer_barrel", THParams::lookup("hit_vs_layer"));
auto& hit_vs_layer_forward = *tds.register_container<ContainerTH2<int>>("hit_vs_layer_forward", THParams::lookup("hit_vs_layer"));
auto& gsf_tracks_nmatch_sim_tracks = *tds.register_container<ContainerTH1<size_t>>("gsf_tracks_nmatch_sim_tracks ", THParams::lookup("gsf_tracks_nmatch_sim_tracks"));
auto& ecal_energy_resolution = *tds.register_container<ContainerTH1<float>>("ecal_energy_resolution ", THParams::lookup("ecal_energy_resolution"));
auto& n_seeds = *tds.register_container<ContainerTH1<size_t>>("n_seeds", THParams::lookup("n_seeds"));
auto& n_good_seeds = *tds.register_container<ContainerTH1<size_t>>("n_good_seeds", THParams::lookup("n_seeds"));
auto& n_good_sim = *tds.register_container<ContainerTH1<size_t>>("n_good_sim", THParams::lookup("n_seeds"));
auto& n_prompt = *tds.register_container<ContainerTH1<size_t>>("n_prompt", THParams::lookup("n_seeds"));
auto& n_nonprompt = *tds.register_container<ContainerTH1<size_t>>("n_nonprompt", THParams::lookup("n_seeds"));
auto& n_gsf_tracks = *tds.register_container<ContainerTH1<size_t>>("n_gsf_track", THParams::lookup("n_seeds"));
auto& n_scl = *tds.register_container<ContainerTH1<size_t>>("n_scl", THParams::lookup("n_seeds"));
auto& n_good_scl = *tds.register_container<ContainerTH1<size_t>>("n_good_scl", THParams::lookup("n_seeds"));
auto& n_matched = *tds.register_container<ContainerTH1<int>>("n_matched", THParams::lookup("n_seeds"));
auto& n_merged = *tds.register_container<ContainerTH1<int>>("n_merged", THParams::lookup("n_seeds"));
auto& n_lost = *tds.register_container<ContainerTH1<int>>("n_lost", THParams::lookup("n_seeds"));
auto& n_split = *tds.register_container<ContainerTH1<int>>("n_split", THParams::lookup("n_seeds"));
auto& n_faked = *tds.register_container<ContainerTH1<int>>("n_faked", THParams::lookup("n_seeds"));
auto& n_flipped = *tds.register_container<ContainerTH1<int>>("n_flipped", THParams::lookup("n_seeds"));
auto& matched_dR = *tds.register_container<ContainerTH1<float>>("matched_dR", THParams::lookup("matched_dR"));
auto& matched_dpT = *tds.register_container<ContainerTH1<float>>("matched_dpT", THParams::lookup("matched_dpT"));
auto& n_matched_dR = *tds.register_container<ContainerTH1<int>>("n_matched_dR", THParams::lookup("n_seeds"));
auto& n_merged_dR = *tds.register_container<ContainerTH1<int>>("n_merged_dR", THParams::lookup("n_seeds"));
auto& n_lost_dR = *tds.register_container<ContainerTH1<int>>("n_lost_dR", THParams::lookup("n_seeds"));
auto& n_split_dR = *tds.register_container<ContainerTH1<int>>("n_split_dR", THParams::lookup("n_seeds"));
auto& n_faked_dR = *tds.register_container<ContainerTH1<int>>("n_faked_dR", THParams::lookup("n_seeds"));
auto& n_flipped_dR = *tds.register_container<ContainerTH1<int>>("n_flipped_dR", THParams::lookup("n_seeds"));
auto& matched_dR_dR = *tds.register_container<ContainerTH1<float>>("matched_dR_dR", THParams::lookup("matched_dR"));
auto& matched_dpT_dR = *tds.register_container<ContainerTH1<float>>("matched_dpT_dR", THParams::lookup("matched_dpT"));
auto& tm_corr = *tds.register_container<ContainerTH2<int>>("tm_corr", THParams(2, -0.5, 1.5, 2, -0.5, 1.5));
while (tds.next()) {
update_sim_els();
vector<SimTrack> prompt_sims, nonprompt_sims;
std::tie(prompt_sims, nonprompt_sims) = get_prompt_sims();
size_t _n_good_seeds = 0;
for (const auto& seed : seeds) {
if (is_good_seed(seed, hoe_cut)) {
_n_good_seeds++;
seed_kinems.pt->fill(seed.pt());
seed_kinems.eta->fill(seed.eta());
seed_kinems.phi->fill(seed.phi());
}
}
n_seeds.fill(seeds.size());
n_good_seeds.fill(_n_good_seeds);
for (const auto& sim_track : sim_els) {
good_sim_kinems.pt->fill(sim_track.pt());
good_sim_kinems.eta->fill(sim_track.eta());
good_sim_kinems.phi->fill(sim_track.phi());
}
n_prompt.fill(prompt_sims.size());
for (const auto& prompt : prompt_sims) {
prompt_kinems.pt->fill(prompt.pt());
prompt_kinems.eta->fill(prompt.eta());
prompt_kinems.phi->fill(prompt.phi());
}
n_nonprompt.fill(nonprompt_sims.size());
for (const auto& nonprompt : nonprompt_sims) {
nonprompt_kinems.pt->fill(nonprompt.pt());
nonprompt_kinems.eta->fill(nonprompt.eta());
nonprompt_kinems.phi->fill(nonprompt.phi());
}
for (const auto& gsf_track : gsf_tracks) {
gsf_kinems.pt->fill(gsf_track.pt());
gsf_kinems.eta->fill(gsf_track.eta());
gsf_kinems.phi->fill(gsf_track.phi());
}
size_t _n_good_scl = 0;
for (const auto& scl : scls) {
if (scl.hoe() < hoe_cut) {
_n_good_scl++;
scl_kinems.pt->fill(hypot(scl.px(), scl.py()));
scl_kinems.eta->fill(pseudorapidity(scl.x(), scl.y(), scl.z()));
scl_kinems.phi->fill(atan2(scl.y(), scl.x()));
}
}
n_scl.fill(scls.size());
n_good_scl.fill(_n_good_scl);
auto match_stats = get_match_stats(false);
n_good_sim.fill(std::get<0>(match_stats));
n_gsf_tracks.fill(std::get<1>(match_stats));
n_matched.fill(std::get<2>(match_stats));
n_merged.fill(std::get<3>(match_stats));
n_lost.fill(std::get<4>(match_stats));
n_split.fill(std::get<5>(match_stats));
n_faked.fill(std::get<6>(match_stats));
n_flipped.fill(std::get<7>(match_stats));
for(float dR : std::get<8>(match_stats)) matched_dR.fill(dR);
for(float dpT : std::get<9>(match_stats)) matched_dpT.fill(dpT);
match_stats = get_match_stats(true);
n_matched_dR.fill(std::get<2>(match_stats));
n_merged_dR.fill(std::get<3>(match_stats));
n_lost_dR.fill(std::get<4>(match_stats));
n_split_dR.fill(std::get<5>(match_stats));
n_faked_dR.fill(std::get<6>(match_stats));
n_flipped_dR.fill(std::get<7>(match_stats));
for(float dR : std::get<8>(match_stats)) matched_dR_dR.fill(dR);
for(float dpT : std::get<9>(match_stats)) matched_dpT_dR.fill(dpT);
for (const auto& sim_track : sim_els) {
if (seeds.size() == 0) continue;
for (const auto &seed_idx : sim_track.seedIdx()) {
const Seed& seed = seeds[seed_idx];
if (!is_good_seed(seed, hoe_cut)) continue;
ecal_energy_resolution.fill(reco_energy_rel_err(sim_track, seed));
}
}
// Seeding Efficiency
for (const auto& sim_track : sim_els) {
if (seeds.size() == 0) continue;
bool matched = false;
for (const auto& seed_idx : sim_track.seedIdx()) {
const Seed& seed = seeds[seed_idx];
if (is_good_seed(seed, hoe_cut)) {
matched=true;
break;
}
}
if (abs(sim_track.eta()) < 2.4)
seed_eff.pt->fill(sim_track.pt(), matched);
if (sim_track.pt() > 20.0)
seed_eff.eta->fill(sim_track.eta(), matched);
if (abs(sim_track.eta()) < 2.4 and sim_track.pt() > 20)
seed_eff.phi->fill(sim_track.phi(), matched);
}
// Tracking Efficiency
for (const auto& sim_track : sim_els) {
if (gsf_tracks.size() == 0) continue;
bool matched = false;
for (const auto& track_idx : sim_track.trkIdx()) {
const Seed& seed = seeds[gsf_tracks[track_idx].seedIdx()];
if (is_good_seed(seed, hoe_cut)) {
matched=true;
break;
}
}
if (abs(sim_track.eta()) < 2.4)
tracking_eff.pt->fill(sim_track.pt(), matched);
if (sim_track.pt() > 20.0)
tracking_eff.eta->fill(sim_track.eta(), matched);
if (abs(sim_track.eta()) < 2.4 and sim_track.pt() > 20)
tracking_eff.phi->fill(sim_track.phi(), matched);
if (std::find(prompt_sims.begin(), prompt_sims.end(), sim_track) != prompt_sims.end()) {
if (abs(sim_track.eta()) < 2.4)
prompt_eff.pt->fill(sim_track.pt(), matched);
if (sim_track.pt() > 20.0)
prompt_eff.eta->fill(sim_track.eta(), matched);
if (abs(sim_track.eta()) < 2.4 and sim_track.pt() > 20)
prompt_eff.phi->fill(sim_track.phi(), matched);
}
if (std::find(nonprompt_sims.begin(), nonprompt_sims.end(), sim_track) != nonprompt_sims.end()) {
if (abs(sim_track.eta()) < 2.4)
nonprompt_eff.pt->fill(sim_track.pt(), matched);
if (sim_track.pt() > 20.0)
nonprompt_eff.eta->fill(sim_track.eta(), matched);
if (abs(sim_track.eta()) < 2.4 and sim_track.pt() > 20)
nonprompt_eff.phi->fill(sim_track.phi(), matched);
}
// dR-matching
matched = false;
for (const auto& gsf_track : gsf_tracks) {
const Seed& seed = seeds[gsf_track.seedIdx()];
double dR = deltaR(sim_track.eta(), sim_track.phi(), gsf_track.eta(), gsf_track.phi());
if (is_good_seed(seed, hoe_cut) and dR < 0.2) {
matched = true;
break;
}
}
if (abs(sim_track.eta()) < 2.4)
tracking_eff_dR.pt->fill(sim_track.pt(), matched);
if (sim_track.pt() > 20.0)
tracking_eff_dR.eta->fill(sim_track.eta(), matched);
if (abs(sim_track.eta()) < 2.4 and sim_track.pt() > 20)
tracking_eff_dR.phi->fill(sim_track.phi(), matched);
if (find(prompt_sims.begin(), prompt_sims.end(), sim_track) != prompt_sims.end()) {
if (abs(sim_track.eta()) < 2.4)
prompt_eff_dR.pt->fill(sim_track.pt(), matched);
if (sim_track.pt() > 20.0)
prompt_eff_dR.eta->fill(sim_track.eta(), matched);
if (abs(sim_track.eta()) < 2.4 and sim_track.pt() > 20)
prompt_eff_dR.phi->fill(sim_track.phi(), matched);
}
if (find(nonprompt_sims.begin(), nonprompt_sims.end(), sim_track) != nonprompt_sims.end()) {
if (abs(sim_track.eta()) < 2.4)
nonprompt_eff_dR.pt->fill(sim_track.pt(), matched);
if (sim_track.pt() > 20.0)
nonprompt_eff_dR.eta->fill(sim_track.eta(), matched);
if (abs(sim_track.eta()) < 2.4 and sim_track.pt() > 20)
nonprompt_eff_dR.phi->fill(sim_track.phi(), matched);
}
}
// Seeding Purity
for (const auto& seed : seeds) {
if (!is_good_seed(seed, hoe_cut)) continue;
bool match = false;
for (const auto& sim_track_idx : seed.simTrkIdx()) {
if (is_good_sim(sim_els, sim_tracks[sim_track_idx])) {
match = true;
break;
}
}
if (abs(seed.eta()) < 2.4)
seed_pur.pt->fill(seed.pt(), match);
if (seed.pt() > 20)
seed_pur.eta->fill(seed.eta(), match);
if (abs(seed.eta()) < 2.4 and seed.pt() > 20)
seed_pur.phi->fill(seed.phi(), match);
}
// Tracking Purity
for (const auto& gsf_track : gsf_tracks) {
gsf_tracks_nmatch_sim_tracks.fill(gsf_track.simTrkIdx().size());
const Seed& seed = seeds[gsf_track.seedIdx()];
if (!is_good_seed(seed, hoe_cut)) continue;
bool matched = false;
bool prompt_matched = false;
bool nonprompt_matched = false;
for (const auto& sim_track_idx : gsf_track.simTrkIdx()) {
const auto& sim_track = sim_tracks[sim_track_idx];
if (!is_good_sim(sim_els, sim_track)) continue;
matched = true;
if (find(prompt_sims.begin(), prompt_sims.end(), sim_track) != prompt_sims.end()) {
prompt_matched = true;
}
if (find(nonprompt_sims.begin(), nonprompt_sims.end(), sim_track) != nonprompt_sims.end()) {
nonprompt_matched = true;
}
}
if (abs(gsf_track.eta()) < 2.4)
tracking_pur.pt->fill(gsf_track.pt(), matched);
if (gsf_track.pt() > 20)
tracking_pur.eta->fill(gsf_track.eta(), matched);
if (abs(gsf_track.eta()) < 2.4 and gsf_track.pt() > 20)
tracking_pur.phi->fill(gsf_track.phi(), matched);
if (abs(gsf_track.eta()) < 2.4)
prompt_pur.pt->fill(gsf_track.pt(), prompt_matched);
if (gsf_track.pt() > 20)
prompt_pur.eta->fill(gsf_track.eta(), prompt_matched);
if (abs(gsf_track.eta()) < 2.4 and gsf_track.pt() > 20)
prompt_pur.phi->fill(gsf_track.phi(), prompt_matched);
if (abs(gsf_track.eta()) < 2.4)
nonprompt_pur.pt->fill(gsf_track.pt(), nonprompt_matched);
if (gsf_track.pt() > 20)
nonprompt_pur.eta->fill(gsf_track.eta(), nonprompt_matched);
if (abs(gsf_track.eta()) < 2.4 and gsf_track.pt() > 20)
nonprompt_pur.phi->fill(gsf_track.phi(), nonprompt_matched);
// dR-matching
matched = false;
prompt_matched = false;
nonprompt_matched = false;
for (const auto& sim_track : sim_els) {
double dR = deltaR(sim_track.eta(), sim_track.phi(), gsf_track.eta(), gsf_track.phi());
if (dR < 0.2) {
matched = true;
if (find(prompt_sims.begin(), prompt_sims.end(), sim_track) != prompt_sims.end()) {
prompt_matched = true;
}
if (find(nonprompt_sims.begin(), nonprompt_sims.end(), sim_track) != nonprompt_sims.end()) {
nonprompt_matched = true;
}
}
}
if (abs(gsf_track.eta()) < 2.4)
tracking_pur_dR.pt->fill(gsf_track.pt(), matched);
if (gsf_track.pt() > 20.0)
tracking_pur_dR.eta->fill(gsf_track.eta(), matched);
if (abs(gsf_track.eta()) < 2.4 and gsf_track.pt() > 20)
tracking_pur_dR.phi->fill(gsf_track.phi(), matched);
if (abs(gsf_track.eta()) < 2.4)
prompt_pur_dR.pt->fill(gsf_track.pt(), prompt_matched);
if (gsf_track.pt() > 20)
prompt_pur_dR.eta->fill(gsf_track.eta(), prompt_matched);
if (abs(gsf_track.eta()) < 2.4 and gsf_track.pt() > 20)
prompt_pur_dR.phi->fill(gsf_track.phi(), prompt_matched);
if (abs(gsf_track.eta()) < 2.4)
nonprompt_pur_dR.pt->fill(gsf_track.pt(), nonprompt_matched);
if (gsf_track.pt() > 20)
nonprompt_pur_dR.eta->fill(gsf_track.eta(), nonprompt_matched);
if (abs(gsf_track.eta()) < 2.4 and gsf_track.pt() > 20)
nonprompt_pur_dR.phi->fill(gsf_track.phi(), nonprompt_matched);
}
// Fake-Rate
std::map<size_t, std::vector<int>> scl2trk; // Maps superclusters to tm-status of matched gsf-tracks
for (const auto &gsf_track : gsf_tracks) {
bool gsf_truth_matched = false;
for(const auto& sim_track_idx : gsf_track.simTrkIdx()) {
if (is_good_sim(sim_els, sim_tracks[sim_track_idx])) {
gsf_truth_matched = true;
break;
}
}
int scl_idx = seeds[gsf_track.seedIdx()].sclIdx();
scl2trk[scl_idx].push_back(gsf_truth_matched);
}
std::set<size_t> tm_scls; // Set of super-clusters with well matched sim-electrons
for (const auto &scl : scls) {
Vec4 p4 = scl_p4(scl);
for(const auto& sim_track : sim_els) {
if (deltaR(p4.eta(), p4.phi(), sim_track.eta(), sim_track.phi()) > 0.2) continue;
if (((p4.Et() - sim_track.pt()) / p4.Et()) > 0.1) continue;
tm_scls.insert(scl.idx);
break;
}
}
/* cout << "scls: "; */
/* for (const auto& scl: scls) cout << scl.idx << ", "; */
/* cout << endl << "tm_scls: "; */
/* for (const auto& idx: tm_scls) cout << idx << ", "; */
/* cout << endl; */
for (const auto &scl : scls) {
if (scl.hoe() > hoe_cut) continue;
float scl_pt = hypot(scl.px(), scl.py());
float scl_eta = pseudorapidity(scl.x(), scl.y(), scl.z());
float scl_phi = atan2(scl.py(), scl.px());
int ntracks = scl2trk[scl.idx].size();
int ntmtracks = std::accumulate(scl2trk[scl.idx].begin(), scl2trk[scl.idx].end(), 0);
bool partial_fake = ntmtracks > 0 and ntracks > ntmtracks;
bool full_fake = ntmtracks == 0 and ntracks > 0;
/* cout << "ntracks: " << ntracks << " "; */
/* cout << "count: " << tm_scls.count(scl.idx); */
if (ntracks > 0) {
partial_fake_rate_incl.pt->fill(scl_pt, partial_fake);
partial_fake_rate_incl.eta->fill(scl_eta, partial_fake);
partial_fake_rate_incl.phi->fill(scl_phi, partial_fake);
if (abs(scl_eta) < 2.4) partial_fake_rate.pt->fill(scl_pt, partial_fake);
if (scl_pt > 20.0) partial_fake_rate.eta->fill(scl_eta, partial_fake);
if (abs(scl_eta) < 2.4 and scl_pt > 20) partial_fake_rate.phi->fill(scl_phi, partial_fake);
full_fake_rate_incl.pt->fill(scl_pt, full_fake);
full_fake_rate_incl.eta->fill(scl_eta, full_fake);
full_fake_rate_incl.phi->fill(scl_phi, full_fake);
if (abs(scl_eta) < 2.4) full_fake_rate.pt->fill(scl_pt, full_fake);
if (scl_pt > 20.0) full_fake_rate.eta->fill(scl_eta, full_fake);
if (abs(scl_eta) < 2.4 and scl_pt > 20) full_fake_rate.phi->fill(scl_phi, full_fake);
if (tm_scls.count(scl.idx) == 0) {
clean_fake_rate_incl.pt->fill(scl_pt, full_fake);
clean_fake_rate_incl.eta->fill(scl_eta, full_fake);
clean_fake_rate_incl.phi->fill(scl_phi, full_fake);
if (abs(scl_eta) < 2.4) clean_fake_rate.pt->fill(scl_pt, full_fake);
if (scl_pt > 20.0) clean_fake_rate.eta->fill(scl_eta, full_fake);
if (abs(scl_eta) < 2.4 and scl_pt > 20) clean_fake_rate.phi->fill(scl_phi, full_fake);
}
}
if (tm_scls.count(scl.idx) == 0) {
fake_rate_incl.pt->fill(scl_pt, ntracks>0);
fake_rate_incl.eta->fill(scl_eta, ntracks>0);
fake_rate_incl.phi->fill(scl_phi, ntracks>0);
if (abs(scl_eta) < 2.4) fake_rate.pt->fill(scl_pt, ntracks>0);
if (scl_pt > 20.0) fake_rate.eta->fill(scl_eta, ntracks>0);
if (abs(scl_eta) < 2.4 and scl_pt > 20) fake_rate.phi->fill(scl_phi, ntracks>0);
}
/* cout << endl; */
}
// Hit Residuals
for (const auto& seed : seeds) {
if (seed.trkIdx() < 0) continue; // require that seed produced gsf-track
if (!is_good_seed(seed, hoe_cut)) continue;
bool is_seed_sim_matched = false;
for (const auto& sim_track_idx : seed.simTrkIdx()) {
const SimTrack& sim_track = sim_tracks[sim_track_idx];
if (is_good_sim(sim_els, sim_track) and reco_energy_consistent(sim_track, seed)) {
is_seed_sim_matched = true;
break;
}
}
bool is_track_sim_matched = false;
const auto the_track = gsf_tracks[seed.trkIdx()];
for (const auto& sim_track_idx : the_track.simTrkIdx()) {
const SimTrack& sim_track = sim_tracks[sim_track_idx];
if (is_good_sim(sim_els, sim_track) and reco_energy_consistent(sim_track, the_track)) {
is_track_sim_matched = true;
break;
}
}
std::vector<TMType> tm_types;
if (is_seed_sim_matched and is_track_sim_matched) {
tm_types = {SeedAndTrackMatched, SeedMatched, TrackMatched};
} else if (is_seed_sim_matched) {
tm_types = {SeedMatched};
} else if (is_track_sim_matched) {
tm_types = {TrackMatched};
} else {
tm_types = {NoMatch};
}
tm_corr.fill(is_seed_sim_matched, is_track_sim_matched);
vector<int> hits_valid;
vector<float> hits_dRz;
vector<float> hits_dPhi;
if (the_track.q() == 1) {
hits_valid = seed.isValidPos();
hits_dRz = seed.dRZPos();
hits_dPhi = seed.dPhiPos();
} else {
hits_valid = seed.isValidNeg();
hits_dRz = seed.dRZNeg();
hits_dPhi = seed.dPhiNeg();
}
const vector<int>& hits_isBarrel = seed.isBarrel();
const vector<int>& hits_layerOrDiskNr = seed.layerOrDiskNr();
for (const auto& tm_type : tm_types) {
size_t nHits = hits_valid.size();
for (size_t hit_idx = 0; hit_idx < nHits; hit_idx++) {
if (!hits_valid[hit_idx]) continue;
bool isBarrel = hits_isBarrel[hit_idx] == 1;
int layerOrDiskNr = hits_layerOrDiskNr[hit_idx];
float dRz = abs(hits_dRz[hit_idx]);
float dPhi = abs(hits_dPhi[hit_idx]);
int eta_region = get_region(static_cast<int>(hit_idx + 1), seed.eta());
if (is_seed_sim_matched) {
dRz_residuals_v_eta[hit_idx + 1]->fill(dRz, abs(seed.eta()));
dPhi_residuals_v_eta[hit_idx + 1]->fill(dPhi, abs(seed.eta()));
dRz_residuals_v_region[make_pair(hit_idx + 1, eta_region)]->fill(dRz, seed.Et());
dPhi_residuals_v_region[make_pair(hit_idx + 1, eta_region)]->fill(dPhi, seed.Et());
}
residuals_dRz[make_tuple(hit_idx + 1, tm_type)]->fill(dRz, seed.Et());
residuals_dPhi[make_tuple(hit_idx + 1, tm_type)]->fill(dPhi, seed.Et());
if (layerOrDiskNr == -1) continue; // subDet is not set w/ old seeding
if (isBarrel)
hit_vs_layer_barrel.fill(layerOrDiskNr, static_cast<const int &>(hit_idx + 1));
else
hit_vs_layer_forward.fill(layerOrDiskNr, static_cast<const int &>(hit_idx + 1));
if (isBarrel) {
BPIX_residuals_dRz[make_tuple(layerOrDiskNr, hit_idx + 1, tm_type)]->fill(dRz, seed.Et());
BPIX_residuals_dPhi[make_tuple(layerOrDiskNr, hit_idx + 1, tm_type)]->fill(dPhi, seed.Et());
} else {
FPIX_residuals_dRz[make_tuple(layerOrDiskNr, hit_idx + 1, tm_type)]->fill(dRz, seed.Et());
FPIX_residuals_dPhi[make_tuple(layerOrDiskNr, hit_idx + 1, tm_type)]->fill(dPhi, seed.Et());
}
}
}
}
}
tds.save_all();
}
int main(int argc, char * argv[]){
using namespace fv_util;
ArgParser args(argc, argv);
if(args.cmd_option_exists("-c")) {
init_config(args.get_cmd_option("-c"));
args.update_config();
if (args.cmd_option_exists("-s")) {
the_config->update_key("silent", true);
}
if (args.cmd_option_exists("-b")) {
the_config->update_key("batch", true);
}
init_log(LogPriority::kLogInfo);
// gSystem->Load("libfilval.so");
run();
} else {
cout << "Usage: ./" << argv[0] << " (-s) (-b) -c config_file.yaml" << endl;
}
return 0;
}