89 :
simTracks_(iConfig.getParameter<
edm::InputTag>(
"simTracks")),
131 std::vector<int> sorted_tracks_idx(
tracks.size());
132 iota(
begin(sorted_tracks_idx),
end(sorted_tracks_idx), 0);
133 sort(
begin(sorted_tracks_idx),
end(sorted_tracks_idx), [&
tracks](
int i,
int j) {
134 return tracks[
i].momentum().eta() <
tracks[j].momentum().eta();
139 std::vector<int> sorted_genParticles_idx(
genParticles.size());
140 iota(
begin(sorted_genParticles_idx),
end(sorted_genParticles_idx), 0);
141 sort(
begin(sorted_genParticles_idx),
end(sorted_genParticles_idx), [&
genParticles](
int i,
int j) {
147 std::vector<int> sorted_vertices_idx(
vertices.size());
148 iota(
begin(sorted_vertices_idx),
end(sorted_vertices_idx), 0);
149 sort(
begin(sorted_vertices_idx),
end(sorted_vertices_idx), [&
vertices](
int i,
int j) {
154 auto const& trackingpart = *trackingParticlesH.
product();
155 std::vector<int> sorted_tp_idx(trackingpart.size());
156 iota(
begin(sorted_tp_idx),
end(sorted_tp_idx), 0);
157 sort(
begin(sorted_tp_idx),
end(sorted_tp_idx), [&trackingpart](
int i,
int j) {
158 return trackingpart[
i].eta() < trackingpart[j].eta();
162 auto const& calopart = *caloParticlesH.
product();
163 std::vector<int> sorted_cp_idx(calopart.size());
164 iota(
begin(sorted_cp_idx),
end(sorted_cp_idx), 0);
165 sort(
begin(sorted_cp_idx),
end(sorted_cp_idx), [&calopart](
int i,
int j) {
166 return calopart[
i].eta() < calopart[j].eta();
170 auto const& simclusters = *simClustersH.
product();
171 std::vector<int> sorted_simcl_idx(simclusters.size());
172 iota(
begin(sorted_simcl_idx),
end(sorted_simcl_idx), 0);
173 sort(
begin(sorted_simcl_idx),
end(sorted_simcl_idx), [&simclusters](
int i,
int j) {
174 return simclusters[
i].eta() < simclusters[j].eta();
178 std::map<int, float> detIdToTotalSimEnergy;
179 fillSimHits(detIdToTotalSimEnergy, iEvent, iSetup);
183 std::map<int, int> trackid_to_track_index;
184 std::cout <<
"Printing SimTracks information" << std::endl;
185 std::cout <<
"IDX\tTrackId\tPDGID\tMOMENTUM(x,y,z,E)\tVertexIdx\tGenPartIdx" << std::endl;
186 for (
auto i : sorted_tracks_idx) {
188 std::cout << idx <<
"\t" <<
t.trackId() <<
"\t" <<
t << std::endl;
189 trackid_to_track_index[
t.trackId()] =
idx;
193 std::cout <<
"Printing GenParticles information" << std::endl;
194 std::cout <<
"IDX\tPDGID\tMOMENTUM(x,y,z)\tVertex(x,y,z)" << std::endl;
195 for (
auto i : sorted_genParticles_idx) {
197 std::cout << i <<
"\t" <<
gp.pdgId() <<
"\t" <<
gp.momentum() <<
"\t" <<
gp.vertex() << std::endl;
200 std::cout <<
"Printing SimVertex information" << std::endl;
201 std::cout <<
"IDX\tPOSITION(x,y,z)\tPARENT_INDEX\tVERTEX_ID" << std::endl;
202 for (
auto i : sorted_vertices_idx) {
206 std::cout <<
"Printing TrackingParticles information" << std::endl;
207 for (
auto i : sorted_tp_idx) {
208 auto const& tp = trackingpart[
i];
209 std::cout << i <<
"\t" << tp << std::endl;
212 std::cout <<
"Printing CaloParticles information" << std::endl;
214 for (
auto i : sorted_cp_idx) {
215 auto const&
cp = calopart[
i];
220 double total_sim_energy = 0.;
221 double total_cp_energy = 0.;
225 std::vector<int> sorted_sc_idx(simcs.size());
226 iota(
begin(sorted_sc_idx),
end(sorted_sc_idx), 0);
227 sort(
begin(sorted_sc_idx),
end(sorted_sc_idx), [&simcs](
int i,
int j) {
228 return simcs[
i]->momentum().eta() < simcs[j]->momentum().eta();
230 for (
auto i : sorted_sc_idx) {
236 total_sim_energy += detIdToTotalSimEnergy[
cl.first] *
cl.second;
240 std::cout <<
"--> Overall SC energy (sum using sim energies): " << total_sim_energy << std::endl;
241 std::cout <<
"--> Overall SC energy (sum using CaloP energies): " << total_cp_energy << std::endl;
245 std::cout <<
"Printing SimClusters information" << std::endl;
246 for (
auto i : sorted_simcl_idx) {
247 auto const& simcl = simclusters[
i];
249 << idx++ <<
" |Eta|: " <<
std::abs(simcl.momentum().eta()) <<
"\tType: " << simcl.pdgId()
250 <<
"\tEnergy: " << simcl.energy() <<
"\tKey: " << i << std::endl;
251 double total_sim_energy = 0.;
252 std::cout <<
"--> Overall simclusters's size: " << simcl.numberOfRecHits() << std::endl;
253 for (
auto const&
cl : simcl.hits_and_fractions()) {
254 total_sim_energy += detIdToTotalSimEnergy[
cl.first] *
cl.second;
257 std::cout <<
"--> Overall SimCluster energy (sum using sim energies): " << total_sim_energy << std::endl;
273 const HGCalGeometry *eegeom =
nullptr, *fhgeom =
nullptr, *bhgeomnew =
nullptr;
294 hgtopo[1] = &(fhgeom->topology());
296 hgtopo[2] = &(bhgeomnew->topology());
298 for (
unsigned i = 0;
i < 3; ++
i) {
310 const bool isHcal = (collectionTag.instance().find(
"HcalHits") != std::string::npos);
312 for (
auto const&
simHit : *hSimHits) {
314 const uint32_t simId =
simHit.id();
324 int subdet, layer, cell, sec, subsec, zp;
327 std::pair<int, int> recoLayerCell = ddd->
simToReco(cell, layer, sec, hgtopo[subdet - 3]->detectorType());
328 cell = recoLayerCell.first;
329 layer = recoLayerCell.second;
331 if (layer == -1 ||
simHit.geantTrackId() == 0)
339 detIdToTotalSimEnergy[
id.rawId()] +=
simHit.energy();
353 desc.
add<std::vector<edm::InputTag>>(
"collectionTags",
357 descriptions.
add(
"caloParticleDebugger", desc);
EDGetTokenT< ProductType > consumes(edm::InputTag const &tag)
const CaloSubdetectorGeometry * getSubdetectorGeometry(const DetId &id) const
access the subdetector geometry for the given subdetector directly
const HcalDDDRecConstants * dddConstants() const
HcalSubdetector subdet() const
get the subdetector
bool getByToken(EDGetToken token, Handle< PROD > &result) const
edm::EDGetTokenT< std::vector< TrackingParticle > > trackingParticlesToken_
const std::vector< SimTrack > & g4Tracks() const
edm::InputTag simClusters_
edm::EDGetTokenT< std::vector< SimCluster > > simClustersToken_
const HcalTopology & topology() const
CaloParticleDebugger(const edm::ParameterSet &)
std::pair< int, int > simToReco(int cell, int layer, int mod, bool half) const
std::vector< edm::EDGetTokenT< std::vector< PCaloHit > > > collectionTagsToken_
#define DEFINE_FWK_MODULE(type)
edm::InputTag genParticles_
const SimClusterRefVector & simClusters() const
ConsumesCollector consumesCollector()
Use a ConsumesCollector to gather consumes information from helper functions.
const HGCalTopology & topology() const
float energy() const
Energy. Note this is taken from the first SimTrack only.
Abs< T >::type abs(const T &t)
edm::EDGetTokenT< std::vector< SimTrack > > simTracksToken_
ParameterDescriptionBase * add(U const &iLabel, T const &value)
edm::EDGetTokenT< std::vector< CaloParticle > > caloParticlesToken_
static void fillDescriptions(edm::ConfigurationDescriptions &descriptions)
math::XYZVectorF momentum() const
spatial momentum vector
T const * product() const
const HGCalDDDConstants & dddConstants() const
void fillSimHits(std::map< int, float > &, const edm::Event &, const edm::EventSetup &)
void add(std::string const &label, ParameterSetDescription const &psetDescription)
int pdgId() const
PDG ID.
edm::EDGetTokenT< std::vector< reco::GenParticle > > genParticlesToken_
void analyze(const edm::Event &, const edm::EventSetup &) override
size_type size() const
Size of the RefVector.
DetId relabel(const uint32_t testId) const
edm::InputTag trackingParticles_
edm::InputTag caloParticles_
edm::InputTag simVertices_
static void unpackHexagonIndex(const uint32_t &idx, int &subdet, int &z, int &lay, int &wafer, int &celltyp, int &cell)
std::vector< std::pair< uint32_t, float > > hits_and_fractions() const
Returns list of rechit IDs and fractions for this SimCluster.
std::vector< edm::InputTag > collectionTags_
~CaloParticleDebugger() override
edm::EDGetTokenT< std::vector< SimVertex > > simVerticesToken_