#include "TFile.h"
#include "TTree.h"
#include <iostream>
#include <list>
#include <unordered_map>
#include "RecoTracker/MkFitCore/standalone/Event.h"
#include "RecoTracker/MkFitCore/interface/Config.h"
#include "RecoTracker/MkFitCore/interface/TrackerInfo.h"
#include "RecoTracker/MkFitCMS/interface/LayerNumberConverter.h"

Typedefs
typedef lStr_t::iterator	lStr_i

typedef std::list< std::string >	lStr_t

using	TrackAlgorithm = TrackBase::TrackAlgorithm

Enumerations
enum	HitType { HitType::Pixel = 0, HitType::Strip = 1, HitType::Glued = 2, HitType::Invalid = 3, HitType::Phase2OT = 4, HitType::Unknown = 99 }

Functions
int	main (int argc, char *argv[])

bool	next_arg_option (lStr_t &args, lStr_i &i)

void	next_arg_or_die (lStr_t &args, lStr_i &i)

void	printHelp (const char *av0)

Variables
constexpr int	cleanSimTrack_minRecHits = 2

constexpr int	cleanSimTrack_minSimHits = 3

constexpr bool	useMatched = false

Typedef Documentation

◆ lStr_i

typedef lStr_t::iterator lStr_i

Definition at line 25 of file WriteMemoryFile.cc.

◆ lStr_t

typedef std::list<std::string> lStr_t

Definition at line 24 of file WriteMemoryFile.cc.

◆ TrackAlgorithm

using TrackAlgorithm = TrackBase::TrackAlgorithm

Definition at line 14 of file WriteMemoryFile.cc.

Enumeration Type Documentation

◆ HitType

enum HitType

strong

Enumerator
Pixel
Strip
Glued
Invalid
Phase2OT
Unknown

Definition at line 22 of file WriteMemoryFile.cc.

22 { Pixel = 0, Strip = 1, Glued = 2, Invalid = 3, Phase2OT = 4, Unknown = 99 };

reco::Unknown

Definition: MuonSimInfo.h:32

align::Pixel

Definition: StructureType.h:68

HitType::Phase2OT

DetStateFilter::Invalid

Definition: DetectorStateFilter.cc:46

align::Strip

Definition: StructureType.h:69

HitType::Glued

Function Documentation

◆ main()

int main	(	int	argc,
		char *	argv[]
	)

===============================================================================================================================================================================================

variant2: for each run define phi-averaged A for normalization channel (Dref,16) and then, divide Rijk on it, i.e. get RRijk

eta=27

eta=25

eta=23

eta=22

eta=21

eta=26

eta=24

eta=19

eta=17

eta=25

eta=23

eta=22

eta=21

eta=26

eta=24

eta=20

eta=19

eta=18

eta=27 L1=1

eta=25 L1=1

eta=23 L1=1

eta=22 L1=1

eta=21 L1=1

eta=29 L1=1

eta=26 L1=1

eta=24 L1=1

eta=20 L1=1

eta=19 L1=1

eta=18 L1=1

eta=17 L1=1

eta=28 L7=1

eta=27 L7=1

eta=25 L7=1

eta=23 L7=1

eta=22 L7=1

eta=21 L7=1

eta=26 L7=1

eta=24 L7=1

eta=20 L7=1

eta=19 L7=1

eta=18 L7=1

eta=17 L7=1

eta=27

eta=25

eta=23

eta=22

eta=21

eta=26

eta=24

eta=19

eta=17

eta=25

eta=23

eta=22

eta=21

eta=26

eta=24

eta=20

eta=19

eta=18

eta=27 L1=1

eta=25 L1=1

eta=23 L1=1

eta=22 L1=1

eta=21 L1=1

eta=26 L1=1

eta=24 L1=1

eta=20 L1=1

eta=19 L1=1

eta=18 L1=1

eta=17 L1=1

eta=28 L7=1

eta=27 L7=1

eta=25 L7=1

eta=23 L7=1

eta=22 L7=1

eta=21 L7=1

eta=26 L7=1

eta=24 L7=1

eta=20 L7=1

eta=19 L7=1

eta=18 L7=1

eta=17 L7=1

eta=27

eta=28

errA with average Amplitudes

Summed Amplitude Plots:

Summed Amplitude Plots:

Summed Amplitude Plots:

RBX:

errA with average Amplitudes

Summed Amplitude Plots:

Summed Amplitude Plots:

Summed Amplitude Plots:

RBX:

errA with average Amplitudes

Summed Amplitude Plots:

Summed Amplitude Plots:

Summed Amplitude Plots:

RBX:

Prepare maps of good/bad channels:

CALO JETS

PF JETS

Definition at line 61 of file WriteMemoryFile.cc.

References qcdUeDQM_cfi::algorithm, dir2webdir::argc, cmsBatch::argv, cms::cuda::assert(), cms::cuda::bs, ALCARECOTkAlJpsiMuMu_cff::charge, hltPixelTracks_cff::chi2, cleanSimTrack_minRecHits, cleanSimTrack_minSimHits, mkfit::DataFile::CloseWrite(), mkfit::LayerNumberConverter::convertLayerNumber(), funct::cos(), submitPVResolutionJobs::count, gather_cfg::cout, EE, submitPVResolutionJobs::err, mkfit::DataFile::ES_BeamSpot, mkfit::DataFile::ES_CmsswTracks, mkfit::DataFile::ES_HitIterMasks, mkfit::DataFile::ES_Seeds, edmPickEvents::event, beamvalidation::exit(), f, dqmMemoryStats::float, Glued, hfClusterShapes_cfi::hits, ntupleEnum::hltIter0, trackingPlots::hp, mps_fire::i, cuy::ii, InitialStep_cff::initialStep, InefficientDoubleROC::inputFileName, createfilelist::int, mkfit::TrackBase::InTimePU, Invalid, dqmiolumiharvest::j, label, M_PI_2, SiStripPI::min, mkfit::TrackerInfo::n_layers(), next_arg_option(), next_arg_or_die(), cms::cuda::nh, nHits, mkfit::LayerNumberConverter::nLayers(), EgHLTOffHistBins_cfi::nr, nt, mkfit::DataFile::openWrite(), or, mkfit::TrackBase::OutOfTimePU, reco_skim_cfg_mod::outputFileName, SiStripOfflineCRack_cfg::p2, mkfit::phase1, Pixel, funct::pow(), printHelp(), DiDispStaMuonMonitor_cfi::pt, PVValHelper::pT, multPhiCorr_741_25nsDY_cfi::px, multPhiCorr_741_25nsDY_cfi::py, mkfit::TrackerInfo::read_bin_file(), mkfit::TrackBase::Signal, funct::sin(), findQualityFiles::size, mathSSE::sqrt(), submitPVResolutionJobs::stderr, AlCaHLTBitMon_QueryRunRegistry::string, Strip, submitPVValidationJobs::t, cmsswSequenceInfo::tp, HLT_2022v12_cff::track, mitigatedMETSequence_cff::U, useMatched, ctppsCommonDQMSource_cfi::verbosity, and x.

                                  {
   bool haveInput = false;
   std::string inputFileName;
   bool haveOutput = false;
   std::string outputFileName;
   std::string geoFileName("CMS-2017.bin");
 
   bool cleanSimTracks = false;
   bool writeAllEvents = false;
   bool writeRecTracks = false;
   bool writeHitIterMasks = false;
   bool applyCCC = false;
   bool allSeeds = false;
 
   int verbosity = 0;
   long long maxevt = -1;
 
   int cutValueCCC = 1620;  //Nominal value (from first iteration of CMSSW) is 1620
 
   lStr_t mArgs;
   for (int i = 1; i < argc; ++i) {
     mArgs.push_back(argv[i]);
   }
 
   lStr_i i = mArgs.begin();
   while (i != mArgs.end()) {
     lStr_i start = i;
 
     if (*i == "-h" || *i == "-help" || *i == "--help") {
       printHelp(argv[0]);
     } else if (*i == "--input") {
       next_arg_or_die(mArgs, i);
       inputFileName = *i;
       haveInput = true;
     } else if (*i == "--output") {
       next_arg_or_die(mArgs, i);
       outputFileName = *i;
       haveOutput = true;
     } else if (*i == "--geo") {
       next_arg_or_die(mArgs, i);
       geoFileName = *i;
     } else if (*i == "--verbosity") {
       next_arg_or_die(mArgs, i);
       verbosity = std::atoi(i->c_str());
     } else if (*i == "--maxevt") {
       next_arg_or_die(mArgs, i);
       maxevt = std::atoi(i->c_str());
     } else if (*i == "--clean-sim-tracks") {
       cleanSimTracks = true;
     } else if (*i == "--write-all-events") {
       writeAllEvents = true;
     } else if (*i == "--write-rec-tracks") {
       writeRecTracks = true;
     } else if (*i == "--write-hit-iter-masks") {
       writeHitIterMasks = true;
     } else if (*i == "--apply-ccc") {
       applyCCC = true;
       if (next_arg_option(mArgs, i)) {
         cutValueCCC = std::atoi(i->c_str());
       }
     } else if (*i == "--all-seeds") {
       allSeeds = true;
     } else {
       fprintf(stderr, "Error: Unknown option/argument '%s'.\n", i->c_str());
       printHelp(argv[0]);
       exit(1);
     }
     mArgs.erase(start, ++i);
   }  //while arguments
 
   if (not haveOutput or not haveInput) {
     fprintf(stderr, "Error: both input and output are required\n");
     printHelp(argv[0]);
     exit(1);
   }
 
   using namespace std;
 
   TrackerInfo tkinfo;
   tkinfo.read_bin_file(geoFileName);
   LayerNumberConverter lnc(TkLayout::phase1);
   const unsigned int nTotalLayers = lnc.nLayers();
   assert(nTotalLayers == (unsigned int)tkinfo.n_layers());
 
   int nstot = 0;
   std::vector<int> nhitstot(nTotalLayers, 0);
 
   TFile* f = TFile::Open(inputFileName.c_str());
   if (f == 0) {
     fprintf(stderr, "Failed opening input root file '%s'\n", inputFileName.c_str());
     exit(1);
   }
 
   TTree* t = (TTree*)f->Get("trackingNtuple/tree");
 
   unsigned long long event;
   t->SetBranchAddress("event", &event);
 
   //sim tracks
   std::vector<float>* sim_eta = 0;
   std::vector<float>* sim_px = 0;
   std::vector<float>* sim_py = 0;
   std::vector<float>* sim_pz = 0;
   std::vector<int>* sim_parentVtxIdx = 0;
   std::vector<int>* sim_q = 0;
   std::vector<int>* sim_event = 0;
   std::vector<int>* sim_bunchCrossing = 0;
   std::vector<int>* sim_nValid = 0;  //simHit count, actually
   t->SetBranchAddress("sim_eta", &sim_eta);
   t->SetBranchAddress("sim_px", &sim_px);
   t->SetBranchAddress("sim_py", &sim_py);
   t->SetBranchAddress("sim_pz", &sim_pz);
   t->SetBranchAddress("sim_parentVtxIdx", &sim_parentVtxIdx);
   t->SetBranchAddress("sim_q", &sim_q);
   t->SetBranchAddress("sim_event", &sim_event);
   t->SetBranchAddress("sim_bunchCrossing", &sim_bunchCrossing);
   t->SetBranchAddress("sim_nValid", &sim_nValid);
 
   std::vector<vector<int>>* sim_trkIdx = 0;
   t->SetBranchAddress("sim_trkIdx", &sim_trkIdx);
 
   //simvtx
   std::vector<float>* simvtx_x = 0;
   std::vector<float>* simvtx_y = 0;
   std::vector<float>* simvtx_z = 0;
   t->SetBranchAddress("simvtx_x", &simvtx_x);
   t->SetBranchAddress("simvtx_y", &simvtx_y);
   t->SetBranchAddress("simvtx_z", &simvtx_z);
 
   //simhit
   std::vector<short>* simhit_process = 0;
   std::vector<int>* simhit_particle = 0;
   std::vector<int>* simhit_simTrkIdx = 0;
   std::vector<float>* simhit_x = 0;
   std::vector<float>* simhit_y = 0;
   std::vector<float>* simhit_z = 0;
   std::vector<float>* simhit_px = 0;
   std::vector<float>* simhit_py = 0;
   std::vector<float>* simhit_pz = 0;
   t->SetBranchAddress("simhit_process", &simhit_process);
   t->SetBranchAddress("simhit_particle", &simhit_particle);
   t->SetBranchAddress("simhit_simTrkIdx", &simhit_simTrkIdx);
   t->SetBranchAddress("simhit_x", &simhit_x);
   t->SetBranchAddress("simhit_y", &simhit_y);
   t->SetBranchAddress("simhit_z", &simhit_z);
   t->SetBranchAddress("simhit_px", &simhit_px);
   t->SetBranchAddress("simhit_py", &simhit_py);
   t->SetBranchAddress("simhit_pz", &simhit_pz);
 
   std::vector<std::vector<int>>* simhit_hitIdx = 0;
   t->SetBranchAddress("simhit_hitIdx", &simhit_hitIdx);
   std::vector<std::vector<int>>* simhit_hitType = 0;
   t->SetBranchAddress("simhit_hitType", &simhit_hitType);
 
   //rec tracks
   std::vector<int>* trk_q = 0;
   std::vector<unsigned int>* trk_nValid = 0;
   std::vector<int>* trk_seedIdx = 0;
   std::vector<unsigned long long>* trk_algoMask = 0;
   std::vector<unsigned int>* trk_algo = 0;
   std::vector<unsigned int>* trk_originalAlgo = 0;
   std::vector<float>* trk_nChi2 = 0;
   std::vector<float>* trk_px = 0;
   std::vector<float>* trk_py = 0;
   std::vector<float>* trk_pz = 0;
   std::vector<float>* trk_pt = 0;
   std::vector<float>* trk_phi = 0;
   std::vector<float>* trk_lambda = 0;
   std::vector<float>* trk_refpoint_x = 0;
   std::vector<float>* trk_refpoint_y = 0;
   std::vector<float>* trk_refpoint_z = 0;
   std::vector<float>* trk_dxyErr = 0;
   std::vector<float>* trk_dzErr = 0;
   std::vector<float>* trk_ptErr = 0;
   std::vector<float>* trk_phiErr = 0;
   std::vector<float>* trk_lambdaErr = 0;
   t->SetBranchAddress("trk_q", &trk_q);
   t->SetBranchAddress("trk_nValid", &trk_nValid);
   t->SetBranchAddress("trk_seedIdx", &trk_seedIdx);
   t->SetBranchAddress("trk_algoMask", &trk_algoMask);
   t->SetBranchAddress("trk_algo", &trk_algo);
   t->SetBranchAddress("trk_originalAlgo", &trk_originalAlgo);
   t->SetBranchAddress("trk_nChi2", &trk_nChi2);
   t->SetBranchAddress("trk_px", &trk_px);
   t->SetBranchAddress("trk_py", &trk_py);
   t->SetBranchAddress("trk_pz", &trk_pz);
   t->SetBranchAddress("trk_pt", &trk_pt);
   t->SetBranchAddress("trk_phi", &trk_phi);
   t->SetBranchAddress("trk_lambda", &trk_lambda);
   t->SetBranchAddress("trk_refpoint_x", &trk_refpoint_x);
   t->SetBranchAddress("trk_refpoint_y", &trk_refpoint_y);
   t->SetBranchAddress("trk_refpoint_z", &trk_refpoint_z);
   t->SetBranchAddress("trk_dxyErr", &trk_dxyErr);
   t->SetBranchAddress("trk_dzErr", &trk_dzErr);
   t->SetBranchAddress("trk_ptErr", &trk_ptErr);
   t->SetBranchAddress("trk_phiErr", &trk_phiErr);
   t->SetBranchAddress("trk_lambdaErr", &trk_lambdaErr);
 
   std::vector<std::vector<int>>* trk_hitIdx = 0;
   t->SetBranchAddress("trk_hitIdx", &trk_hitIdx);
   std::vector<std::vector<int>>* trk_hitType = 0;
   t->SetBranchAddress("trk_hitType", &trk_hitType);
 
   //seeds
   std::vector<float>* see_stateTrajGlbX = 0;
   std::vector<float>* see_stateTrajGlbY = 0;
   std::vector<float>* see_stateTrajGlbZ = 0;
   std::vector<float>* see_stateTrajGlbPx = 0;
   std::vector<float>* see_stateTrajGlbPy = 0;
   std::vector<float>* see_stateTrajGlbPz = 0;
   std::vector<float>* see_eta = 0;  //PCA parameters
   std::vector<float>* see_pt = 0;   //PCA parameters
   std::vector<float>* see_stateCcov00 = 0;
   std::vector<float>* see_stateCcov01 = 0;
   std::vector<float>* see_stateCcov02 = 0;
   std::vector<float>* see_stateCcov03 = 0;
   std::vector<float>* see_stateCcov04 = 0;
   std::vector<float>* see_stateCcov05 = 0;
   std::vector<float>* see_stateCcov11 = 0;
   std::vector<float>* see_stateCcov12 = 0;
   std::vector<float>* see_stateCcov13 = 0;
   std::vector<float>* see_stateCcov14 = 0;
   std::vector<float>* see_stateCcov15 = 0;
   std::vector<float>* see_stateCcov22 = 0;
   std::vector<float>* see_stateCcov23 = 0;
   std::vector<float>* see_stateCcov24 = 0;
   std::vector<float>* see_stateCcov25 = 0;
   std::vector<float>* see_stateCcov33 = 0;
   std::vector<float>* see_stateCcov34 = 0;
   std::vector<float>* see_stateCcov35 = 0;
   std::vector<float>* see_stateCcov44 = 0;
   std::vector<float>* see_stateCcov45 = 0;
   std::vector<float>* see_stateCcov55 = 0;
   std::vector<std::vector<float>>* see_stateCurvCov = 0;
   std::vector<int>* see_q = 0;
   std::vector<unsigned int>* see_algo = 0;
   t->SetBranchAddress("see_stateTrajGlbX", &see_stateTrajGlbX);
   t->SetBranchAddress("see_stateTrajGlbY", &see_stateTrajGlbY);
   t->SetBranchAddress("see_stateTrajGlbZ", &see_stateTrajGlbZ);
   t->SetBranchAddress("see_stateTrajGlbPx", &see_stateTrajGlbPx);
   t->SetBranchAddress("see_stateTrajGlbPy", &see_stateTrajGlbPy);
   t->SetBranchAddress("see_stateTrajGlbPz", &see_stateTrajGlbPz);
   t->SetBranchAddress("see_eta", &see_eta);
   t->SetBranchAddress("see_pt", &see_pt);
 
   bool hasCartCov = t->GetBranch("see_stateCcov00") != nullptr;
   if (hasCartCov) {
     t->SetBranchAddress("see_stateCcov00", &see_stateCcov00);
     t->SetBranchAddress("see_stateCcov01", &see_stateCcov01);
     t->SetBranchAddress("see_stateCcov02", &see_stateCcov02);
     t->SetBranchAddress("see_stateCcov03", &see_stateCcov03);
     t->SetBranchAddress("see_stateCcov04", &see_stateCcov04);
     t->SetBranchAddress("see_stateCcov05", &see_stateCcov05);
     t->SetBranchAddress("see_stateCcov11", &see_stateCcov11);
     t->SetBranchAddress("see_stateCcov12", &see_stateCcov12);
     t->SetBranchAddress("see_stateCcov13", &see_stateCcov13);
     t->SetBranchAddress("see_stateCcov14", &see_stateCcov14);
     t->SetBranchAddress("see_stateCcov15", &see_stateCcov15);
     t->SetBranchAddress("see_stateCcov22", &see_stateCcov22);
     t->SetBranchAddress("see_stateCcov23", &see_stateCcov23);
     t->SetBranchAddress("see_stateCcov24", &see_stateCcov24);
     t->SetBranchAddress("see_stateCcov25", &see_stateCcov25);
     t->SetBranchAddress("see_stateCcov33", &see_stateCcov33);
     t->SetBranchAddress("see_stateCcov34", &see_stateCcov34);
     t->SetBranchAddress("see_stateCcov35", &see_stateCcov35);
     t->SetBranchAddress("see_stateCcov44", &see_stateCcov44);
     t->SetBranchAddress("see_stateCcov45", &see_stateCcov45);
     t->SetBranchAddress("see_stateCcov55", &see_stateCcov55);
   } else {
     t->SetBranchAddress("see_stateCurvCov", &see_stateCurvCov);
   }
   t->SetBranchAddress("see_q", &see_q);
   t->SetBranchAddress("see_algo", &see_algo);
 
   std::vector<std::vector<int>>* see_hitIdx = 0;
   t->SetBranchAddress("see_hitIdx", &see_hitIdx);
   std::vector<std::vector<int>>* see_hitType = 0;
   t->SetBranchAddress("see_hitType", &see_hitType);
 
   //pixel hits
   vector<unsigned short>* pix_det = 0;
   vector<unsigned short>* pix_lay = 0;
   vector<unsigned int>* pix_detId = 0;
   vector<float>* pix_x = 0;
   vector<float>* pix_y = 0;
   vector<float>* pix_z = 0;
   vector<float>* pix_xx = 0;
   vector<float>* pix_xy = 0;
   vector<float>* pix_yy = 0;
   vector<float>* pix_yz = 0;
   vector<float>* pix_zz = 0;
   vector<float>* pix_zx = 0;
   vector<int>* pix_csize_col = 0;
   vector<int>* pix_csize_row = 0;
   vector<uint64_t>* pix_usedMask = 0;
   //these were renamed in CMSSW_9_1_0: auto-detect
   bool has910_det_lay = t->GetBranch("pix_det") == nullptr;
   if (has910_det_lay) {
     t->SetBranchAddress("pix_subdet", &pix_det);
     t->SetBranchAddress("pix_layer", &pix_lay);
   } else {
     t->SetBranchAddress("pix_det", &pix_det);
     t->SetBranchAddress("pix_lay", &pix_lay);
   }
   t->SetBranchAddress("pix_detId", &pix_detId);
   t->SetBranchAddress("pix_x", &pix_x);
   t->SetBranchAddress("pix_y", &pix_y);
   t->SetBranchAddress("pix_z", &pix_z);
   t->SetBranchAddress("pix_xx", &pix_xx);
   t->SetBranchAddress("pix_xy", &pix_xy);
   t->SetBranchAddress("pix_yy", &pix_yy);
   t->SetBranchAddress("pix_yz", &pix_yz);
   t->SetBranchAddress("pix_zz", &pix_zz);
   t->SetBranchAddress("pix_zx", &pix_zx);
   t->SetBranchAddress("pix_clustSizeCol", &pix_csize_col);
   t->SetBranchAddress("pix_clustSizeRow", &pix_csize_row);
   if (writeHitIterMasks) {
     t->SetBranchAddress("pix_usedMask", &pix_usedMask);
   }
 
   vector<vector<int>>* pix_simHitIdx = 0;
   t->SetBranchAddress("pix_simHitIdx", &pix_simHitIdx);
   vector<vector<float>>* pix_chargeFraction = 0;
   t->SetBranchAddress("pix_chargeFraction", &pix_chargeFraction);
 
   //strip hits
   vector<short>* glu_isBarrel = 0;
   vector<unsigned int>* glu_det = 0;
   vector<unsigned int>* glu_lay = 0;
   vector<unsigned int>* glu_detId = 0;
   vector<int>* glu_monoIdx = 0;
   vector<int>* glu_stereoIdx = 0;
   vector<float>* glu_x = 0;
   vector<float>* glu_y = 0;
   vector<float>* glu_z = 0;
   vector<float>* glu_xx = 0;
   vector<float>* glu_xy = 0;
   vector<float>* glu_yy = 0;
   vector<float>* glu_yz = 0;
   vector<float>* glu_zz = 0;
   vector<float>* glu_zx = 0;
   t->SetBranchAddress("glu_isBarrel", &glu_isBarrel);
   if (has910_det_lay) {
     t->SetBranchAddress("glu_subdet", &glu_det);
     t->SetBranchAddress("glu_layer", &glu_lay);
   } else {
     t->SetBranchAddress("glu_det", &glu_det);
     t->SetBranchAddress("glu_lay", &glu_lay);
   }
   t->SetBranchAddress("glu_detId", &glu_detId);
   t->SetBranchAddress("glu_monoIdx", &glu_monoIdx);
   t->SetBranchAddress("glu_stereoIdx", &glu_stereoIdx);
   t->SetBranchAddress("glu_x", &glu_x);
   t->SetBranchAddress("glu_y", &glu_y);
   t->SetBranchAddress("glu_z", &glu_z);
   t->SetBranchAddress("glu_xx", &glu_xx);
   t->SetBranchAddress("glu_xy", &glu_xy);
   t->SetBranchAddress("glu_yy", &glu_yy);
   t->SetBranchAddress("glu_yz", &glu_yz);
   t->SetBranchAddress("glu_zz", &glu_zz);
   t->SetBranchAddress("glu_zx", &glu_zx);
 
   vector<short>* str_isBarrel = 0;
   vector<short>* str_isStereo = 0;
   vector<unsigned int>* str_det = 0;
   vector<unsigned int>* str_lay = 0;
   vector<unsigned int>* str_detId = 0;
   vector<unsigned int>* str_simType = 0;
   vector<float>* str_x = 0;
   vector<float>* str_y = 0;
   vector<float>* str_z = 0;
   vector<float>* str_xx = 0;
   vector<float>* str_xy = 0;
   vector<float>* str_yy = 0;
   vector<float>* str_yz = 0;
   vector<float>* str_zz = 0;
   vector<float>* str_zx = 0;
   vector<float>* str_chargePerCM = 0;
   vector<int>* str_csize = 0;
   vector<uint64_t>* str_usedMask = 0;
   t->SetBranchAddress("str_isBarrel", &str_isBarrel);
   t->SetBranchAddress("str_isStereo", &str_isStereo);
   if (has910_det_lay) {
     t->SetBranchAddress("str_subdet", &str_det);
     t->SetBranchAddress("str_layer", &str_lay);
   } else {
     t->SetBranchAddress("str_det", &str_det);
     t->SetBranchAddress("str_lay", &str_lay);
   }
   t->SetBranchAddress("str_detId", &str_detId);
   t->SetBranchAddress("str_simType", &str_simType);
   t->SetBranchAddress("str_x", &str_x);
   t->SetBranchAddress("str_y", &str_y);
   t->SetBranchAddress("str_z", &str_z);
   t->SetBranchAddress("str_xx", &str_xx);
   t->SetBranchAddress("str_xy", &str_xy);
   t->SetBranchAddress("str_yy", &str_yy);
   t->SetBranchAddress("str_yz", &str_yz);
   t->SetBranchAddress("str_zz", &str_zz);
   t->SetBranchAddress("str_zx", &str_zx);
   t->SetBranchAddress("str_chargePerCM", &str_chargePerCM);
   t->SetBranchAddress("str_clustSize", &str_csize);
   if (writeHitIterMasks) {
     t->SetBranchAddress("str_usedMask", &str_usedMask);
   }
 
   vector<vector<int>>* str_simHitIdx = 0;
   t->SetBranchAddress("str_simHitIdx", &str_simHitIdx);
   vector<vector<float>>* str_chargeFraction = 0;
   t->SetBranchAddress("str_chargeFraction", &str_chargeFraction);
 
   // beam spot
   float bsp_x;
   float bsp_y;
   float bsp_z;
   float bsp_sigmax;
   float bsp_sigmay;
   float bsp_sigmaz;
   t->SetBranchAddress("bsp_x", &bsp_x);
   t->SetBranchAddress("bsp_y", &bsp_y);
   t->SetBranchAddress("bsp_z", &bsp_z);
   t->SetBranchAddress("bsp_sigmax", &bsp_sigmax);
   t->SetBranchAddress("bsp_sigmay", &bsp_sigmay);
   t->SetBranchAddress("bsp_sigmaz", &bsp_sigmaz);
 
   long long totentries = t->GetEntries();
   long long savedEvents = 0;
 
   DataFile data_file;
   int outOptions = DataFile::ES_Seeds;
   if (writeRecTracks)
     outOptions |= DataFile::ES_CmsswTracks;
   if (writeHitIterMasks)
     outOptions |= DataFile::ES_HitIterMasks;
   outOptions |= DataFile::ES_BeamSpot;
 
   if (maxevt < 0)
     maxevt = totentries;
   data_file.openWrite(outputFileName, static_cast<int>(nTotalLayers), std::min(maxevt, totentries), outOptions);
 
   Event EE(0, static_cast<int>(nTotalLayers));
 
   int numFailCCC = 0;
   int numTotalStr = 0;
   // gDebug = 8;
 
   for (long long i = 0; savedEvents < maxevt && i < totentries && i < maxevt; ++i) {
     EE.reset(i);
 
     cout << "process entry i=" << i << " out of " << totentries << ", saved so far " << savedEvents
          << ", with max=" << maxevt << endl;
 
     t->GetEntry(i);
 
     cout << "edm event=" << event << endl;
 
     auto& bs = EE.beamSpot_;
     bs.x = bsp_x;
     bs.y = bsp_y;
     bs.z = bsp_z;
     bs.sigmaZ = bsp_sigmaz;
     bs.beamWidthX = bsp_sigmax;
     bs.beamWidthY = bsp_sigmay;
     //dxdz and dydz are not in the trackingNtuple at the moment
 
     for (unsigned int istr = 0; istr < str_lay->size(); ++istr) {
       if (str_chargePerCM->at(istr) < cutValueCCC)
         numFailCCC++;
       numTotalStr++;
     }
 
     auto nSims = sim_q->size();
     if (nSims == 0) {
       cout << "branches not loaded" << endl;
       exit(1);
     }
     if (verbosity > 0)
       std::cout << __FILE__ << " " << __LINE__ << " nSims " << nSims << " nSeeds " << see_q->size() << " nRecT "
                 << trk_q->size() << std::endl;
 
     //find best matching tkIdx from a list of simhits indices
     auto bestTkIdx = [&](std::vector<int> const& shs, std::vector<float> const& shfs, int rhIdx, HitType rhType) {
       //assume that all simhits are associated
       int ibest = -1;
       int shbest = -1;
       float hpbest = -1;
       float tpbest = -1;
       float hfbest = -1;
 
       float maxfrac = -1;
       int ish = -1;
       int nshs = shs.size();
       for (auto const sh : shs) {
         ish++;
         auto tkidx = simhit_simTrkIdx->at(sh);
         //use only sh with available TP
         if (tkidx < 0)
           continue;
 
         auto hpx = simhit_px->at(sh);
         auto hpy = simhit_py->at(sh);
         auto hpz = simhit_pz->at(sh);
         auto hp = sqrt(hpx * hpx + hpy * hpy + hpz * hpz);
 
         //look only at hits with p> 50 MeV
         if (hp < 0.05f)
           continue;
 
         auto tpx = sim_px->at(tkidx);
         auto tpy = sim_py->at(tkidx);
         auto tpz = sim_pz->at(tkidx);
         auto tp = sqrt(tpx * tpx + tpy * tpy + tpz * tpz);
 
         //take only hits with hp> 0.5*tp
         if (hp < 0.5 * tp)
           continue;
 
         //pick tkidx corresponding to max hp/tp; .. this is probably redundant
         if (maxfrac < hp / tp) {
           maxfrac = hp / tp;
           ibest = tkidx;
           shbest = sh;
           hpbest = hp;
           tpbest = tp;
           hfbest = shfs[ish];
         }
       }
 
       //arbitration: a rechit with one matching sim is matched to sim if it's the first
       //FIXME: SOME BETTER SELECTION CAN BE DONE (it will require some more correlated knowledge)
       if (nshs == 1 && ibest >= 0) {
         auto const& srhIdxV = simhit_hitIdx->at(shbest);
         auto const& srhTypeV = simhit_hitType->at(shbest);
         int ih = -1;
         for (auto itype : srhTypeV) {
           ih++;
           if (HitType(itype) == rhType && srhIdxV[ih] != rhIdx) {
             ibest = -1;
             break;
           }
         }
       }
 
       if (ibest >= 0 && false) {
         std::cout << " best tkIdx " << ibest << " rh " << rhIdx << " for sh " << shbest << " out of " << shs.size()
                   << " hp " << hpbest << " chF " << hfbest << " tp " << tpbest << " process "
                   << simhit_process->at(shbest) << " particle " << simhit_particle->at(shbest) << std::endl;
         if (rhType == HitType::Strip) {
           std::cout << "    sh " << simhit_x->at(shbest) << ", " << simhit_y->at(shbest) << ", " << simhit_z->at(shbest)
                     << "  rh " << str_x->at(rhIdx) << ", " << str_y->at(rhIdx) << ", " << str_z->at(rhIdx) << std::endl;
         }
       }
       return ibest;
     };
 
     vector<Track>& simTracks_ = EE.simTracks_;
     vector<int> simTrackIdx_(sim_q->size(), -1);  //keep track of original index in ntuple
     vector<int> seedSimIdx(see_q->size(), -1);
     for (unsigned int isim = 0; isim < sim_q->size(); ++isim) {
       //load sim production vertex data
       auto iVtx = sim_parentVtxIdx->at(isim);
       constexpr float largeValF = 9999.f;
       float sim_prodx = iVtx >= 0 ? simvtx_x->at(iVtx) : largeValF;
       float sim_prody = iVtx >= 0 ? simvtx_y->at(iVtx) : largeValF;
       float sim_prodz = iVtx >= 0 ? simvtx_z->at(iVtx) : largeValF;
       //if (fabs(sim_eta->at(isim))>0.8) continue;
 
       vector<int> const& trkIdxV = sim_trkIdx->at(isim);
 
       //if (trkIdx<0) continue;
       //FIXME: CHECK IF THE LOOP AND BEST SELECTION IS NEEDED.
       //Pick the first
       const int trkIdx = trkIdxV.empty() ? -1 : trkIdxV[0];
 
       int nlay = 0;
       if (trkIdx >= 0) {
         std::vector<int> hitlay(nTotalLayers, 0);
         auto const& hits = trk_hitIdx->at(trkIdx);
         auto const& hitTypes = trk_hitType->at(trkIdx);
         auto nHits = hits.size();
         for (auto ihit = 0U; ihit < nHits; ++ihit) {
           auto ihIdx = hits[ihit];
           auto const ihType = HitType(hitTypes[ihit]);
 
           switch (ihType) {
             case HitType::Pixel: {
               int ipix = ihIdx;
               if (ipix < 0)
                 continue;
               int cmsswlay =
                   lnc.convertLayerNumber(pix_det->at(ipix), pix_lay->at(ipix), useMatched, -1, pix_z->at(ipix) > 0);
               if (cmsswlay >= 0 && cmsswlay < static_cast<int>(nTotalLayers))
                 hitlay[cmsswlay]++;
               break;
             }
             case HitType::Strip: {
               int istr = ihIdx;
               if (istr < 0)
                 continue;
               int cmsswlay = lnc.convertLayerNumber(
                   str_det->at(istr), str_lay->at(istr), useMatched, str_isStereo->at(istr), str_z->at(istr) > 0);
               if (cmsswlay >= 0 && cmsswlay < static_cast<int>(nTotalLayers))
                 hitlay[cmsswlay]++;
               break;
             }
             case HitType::Glued: {
               if (useMatched) {
                 int iglu = ihIdx;
                 if (iglu < 0)
                   continue;
                 int cmsswlay =
                     lnc.convertLayerNumber(glu_det->at(iglu), glu_lay->at(iglu), useMatched, -1, glu_z->at(iglu) > 0);
                 if (cmsswlay >= 0 && cmsswlay < static_cast<int>(nTotalLayers))
                   hitlay[cmsswlay]++;
               }
               break;
             }
             case HitType::Invalid:
               break;  //FIXME. Skip, really?
             default:
               throw std::logic_error("Track type can not be handled");
           }  //hit type
         }    //hits on track
         for (unsigned int i = 0; i < nTotalLayers; i++)
           if (hitlay[i] > 0)
             nlay++;
       }  //count nlay layers on matching reco track
 
       //cout << Form("track q=%2i p=(%6.3f, %6.3f, %6.3f) x=(%6.3f, %6.3f, %6.3f) nlay=%i",sim_q->at(isim),sim_px->at(isim),sim_py->at(isim),sim_pz->at(isim),sim_prodx,sim_prody,sim_prodz,nlay) << endl;
 
       SVector3 pos(sim_prodx, sim_prody, sim_prodz);
       SVector3 mom(sim_px->at(isim), sim_py->at(isim), sim_pz->at(isim));
       SMatrixSym66 err;
       err.At(0, 0) = sim_prodx * sim_prodx;
       err.At(1, 1) = sim_prody * sim_prody;
       err.At(2, 2) = sim_prodz * sim_prodz;
       err.At(3, 3) = sim_px->at(isim) * sim_px->at(isim);
       err.At(4, 4) = sim_py->at(isim) * sim_py->at(isim);
       err.At(5, 5) = sim_pz->at(isim) * sim_pz->at(isim);
       TrackState state(sim_q->at(isim), pos, mom, err);
       state.convertFromCartesianToCCS();
       //create track: store number of reco hits in place of track chi2; fill hits later
       //              set label to be its own index in the output file
       Track track(state, float(nlay), simTracks_.size(), 0, nullptr);
       if (sim_bunchCrossing->at(isim) == 0) {  //in time
         if (sim_event->at(isim) == 0)
           track.setProdType(Track::ProdType::Signal);
         else
           track.setProdType(Track::ProdType::InTimePU);
       } else {
         track.setProdType(Track::ProdType::OutOfTimePU);
       }
       if (trkIdx >= 0) {
         int seedIdx = trk_seedIdx->at(trkIdx);
         // Unused: auto const& shTypes = see_hitType->at(seedIdx);
         seedSimIdx[seedIdx] = simTracks_.size();
       }
       if (cleanSimTracks) {
         if (sim_nValid->at(isim) < cleanSimTrack_minSimHits)
           continue;
         if (cleanSimTrack_minRecHits > 0) {
           int nRecToSimHit = 0;
           for (unsigned int ipix = 0; ipix < pix_lay->size() && nRecToSimHit < cleanSimTrack_minRecHits; ++ipix) {
             int ilay = -1;
             ilay = lnc.convertLayerNumber(pix_det->at(ipix), pix_lay->at(ipix), useMatched, -1, pix_z->at(ipix) > 0);
             if (ilay < 0)
               continue;
             int simTkIdxNt = bestTkIdx(pix_simHitIdx->at(ipix), pix_chargeFraction->at(ipix), ipix, HitType::Pixel);
             if (simTkIdxNt >= 0)
               nRecToSimHit++;
           }
           if (useMatched) {
             for (unsigned int iglu = 0; iglu < glu_lay->size() && nRecToSimHit < cleanSimTrack_minRecHits; ++iglu) {
               if (glu_isBarrel->at(iglu) == 0)
                 continue;
               int igluMono = glu_monoIdx->at(iglu);
               int simTkIdxNt =
                   bestTkIdx(str_simHitIdx->at(igluMono), str_chargeFraction->at(igluMono), igluMono, HitType::Strip);
               if (simTkIdxNt >= 0)
                 nRecToSimHit++;
             }
           }
           for (unsigned int istr = 0; istr < str_lay->size() && nRecToSimHit < cleanSimTrack_minRecHits; ++istr) {
             int ilay = -1;
             ilay = lnc.convertLayerNumber(
                 str_det->at(istr), str_lay->at(istr), useMatched, str_isStereo->at(istr), str_z->at(istr) > 0);
             if (useMatched && str_isBarrel->at(istr) == 1 && str_isStereo->at(istr))
               continue;
             if (ilay == -1)
               continue;
             int simTkIdxNt = bestTkIdx(str_simHitIdx->at(istr), str_chargeFraction->at(istr), istr, HitType::Strip);
             if (simTkIdxNt >= 0)
               nRecToSimHit++;
           }
           if (nRecToSimHit < cleanSimTrack_minRecHits)
             continue;
         }  //count rec-to-sim hits
       }    //cleanSimTracks
 
       simTrackIdx_[isim] = simTracks_.size();
       simTracks_.push_back(track);
     }
 
     if (simTracks_.empty() and not writeAllEvents)
       continue;
 
     vector<Track>& seedTracks_ = EE.seedTracks_;
     vector<vector<int>> pixHitSeedIdx(pix_lay->size());
     vector<vector<int>> strHitSeedIdx(str_lay->size());
     vector<vector<int>> gluHitSeedIdx(glu_lay->size());
     for (unsigned int is = 0; is < see_q->size(); ++is) {
       auto isAlgo = TrackAlgorithm(see_algo->at(is));
       if (not allSeeds)
         if (isAlgo != TrackAlgorithm::initialStep && isAlgo != TrackAlgorithm::hltIter0)
           continue;  //select seed in acceptance
       //if (see_pt->at(is)<0.5 || fabs(see_eta->at(is))>0.8) continue;//select seed in acceptance
       SVector3 pos = SVector3(see_stateTrajGlbX->at(is), see_stateTrajGlbY->at(is), see_stateTrajGlbZ->at(is));
       SVector3 mom = SVector3(see_stateTrajGlbPx->at(is), see_stateTrajGlbPy->at(is), see_stateTrajGlbPz->at(is));
       SMatrixSym66 err;
       if (hasCartCov) {
         err.At(0, 0) = see_stateCcov00->at(is);
         err.At(0, 1) = see_stateCcov01->at(is);
         err.At(0, 2) = see_stateCcov02->at(is);
         err.At(0, 3) = see_stateCcov03->at(is);
         err.At(0, 4) = see_stateCcov04->at(is);
         err.At(0, 5) = see_stateCcov05->at(is);
         err.At(1, 1) = see_stateCcov11->at(is);
         err.At(1, 2) = see_stateCcov12->at(is);
         err.At(1, 3) = see_stateCcov13->at(is);
         err.At(1, 4) = see_stateCcov14->at(is);
         err.At(1, 5) = see_stateCcov15->at(is);
         err.At(2, 2) = see_stateCcov22->at(is);
         err.At(2, 3) = see_stateCcov23->at(is);
         err.At(2, 4) = see_stateCcov24->at(is);
         err.At(2, 5) = see_stateCcov25->at(is);
         err.At(3, 3) = see_stateCcov33->at(is);
         err.At(3, 4) = see_stateCcov34->at(is);
         err.At(3, 5) = see_stateCcov35->at(is);
         err.At(4, 4) = see_stateCcov44->at(is);
         err.At(4, 5) = see_stateCcov45->at(is);
         err.At(5, 5) = see_stateCcov55->at(is);
       } else {
         auto const& vCov = see_stateCurvCov->at(is);
         assert(vCov.size() == 15);
         auto vCovP = vCov.begin();
         for (int i = 0; i < 5; ++i)
           for (int j = 0; j <= i; ++j)
             err.At(i, j) = *(vCovP++);
       }
       TrackState state(see_q->at(is), pos, mom, err);
       if (hasCartCov)
         state.convertFromCartesianToCCS();
       else
         state.convertFromGlbCurvilinearToCCS();
       Track track(state, 0, seedSimIdx[is], 0, nullptr);
       track.setAlgorithm(isAlgo);
       auto const& shTypes = see_hitType->at(is);
       auto const& shIdxs = see_hitIdx->at(is);
       if (not allSeeds)
         if (!((isAlgo == TrackAlgorithm::initialStep || isAlgo == TrackAlgorithm::hltIter0) &&
               std::count(shTypes.begin(), shTypes.end(), int(HitType::Pixel)) >= 3))
           continue;  //check algo and nhits
       for (unsigned int ip = 0; ip < shTypes.size(); ip++) {
         unsigned int hidx = shIdxs[ip];
         switch (HitType(shTypes[ip])) {
           case HitType::Pixel: {
             pixHitSeedIdx[hidx].push_back(seedTracks_.size());
             break;
           }
           case HitType::Strip: {
             strHitSeedIdx[hidx].push_back(seedTracks_.size());
             break;
           }
           case HitType::Glued: {
             if (not useMatched) {
               //decompose
               int uidx = glu_monoIdx->at(hidx);
               strHitSeedIdx[uidx].push_back(seedTracks_.size());
               uidx = glu_stereoIdx->at(hidx);
               strHitSeedIdx[uidx].push_back(seedTracks_.size());
             } else {
               gluHitSeedIdx[hidx].push_back(seedTracks_.size());
             }
             break;
           }
           case HitType::Invalid:
             break;  //FIXME. Skip, really?
           default:
             throw std::logic_error("Track hit type can not be handled");
         }  //switch( HitType
       }
       seedTracks_.push_back(track);
     }
 
     if (seedTracks_.empty() and not writeAllEvents)
       continue;
 
     vector<Track>& cmsswTracks_ = EE.cmsswTracks_;
     vector<vector<int>> pixHitRecIdx(pix_lay->size());
     vector<vector<int>> strHitRecIdx(str_lay->size());
     vector<vector<int>> gluHitRecIdx(glu_lay->size());
     for (unsigned int ir = 0; ir < trk_q->size(); ++ir) {
       //check the origin; redundant for initialStep ntuples
       if (not allSeeds)
         if ((trk_algoMask->at(ir) & ((1 << int(TrackAlgorithm::initialStep)) | (1 << int(TrackAlgorithm::hltIter0)))) ==
             0) {
           if (verbosity > 1) {
             std::cout << "track " << ir << " failed algo selection for " << int(TrackAlgorithm::initialStep)
                       << ": mask " << trk_algoMask->at(ir) << " origAlgo " << trk_originalAlgo->at(ir) << " algo "
                       << trk_algo->at(ir) << std::endl;
           }
           continue;
         }
       //fill the state in CCS upfront
       SMatrixSym66 err;
       /*    
     vx = -dxy*sin(phi) - pt*cos(phi)/p*pz/p*dz;
     vy =  dxy*cos(phi) - pt*sin(phi)/p*pz/p*dz;
     vz = dz*pt*pt/p/p;
     //partial: ignores cross-terms
     c(vx,vx) = c(dxy,dxy)*sin(phi)*sin(phi) + c(dz,dz)*pow(pt*cos(phi)/p*pz/p ,2);
     c(vx,vy) = -c(dxy,dxy)*cos(phi)*sin(phi) + c(dz,dz)*cos(phi)*sin(phi)*pow(pt/p*pz/p, 2);
     c(vy,vy) = c(dxy,dxy)*cos(phi)*cos(phi) + c(dz,dz)*pow(pt*sin(phi)/p*pz/p ,2);
     c(vx,vz) = -c(dz,dz)*pt*pt/p/p*pt/p*pz/p*cos(phi);
     c(vy,vz) = -c(dz,dz)*pt*pt/p/p*pt/p*pz/p*sin(phi);
     c(vz,vz) = c(dz,dz)*pow(pt*pt/p/p, 2);
       */
       float pt = trk_pt->at(ir);
       float pz = trk_pz->at(ir);
       float p2 = pt * pt + pz * pz;
       float phi = trk_phi->at(ir);
       float sP = sin(phi);
       float cP = cos(phi);
       float dxyErr2 = trk_dxyErr->at(ir);
       dxyErr2 *= dxyErr2;
       float dzErr2 = trk_dzErr->at(ir);
       dzErr2 *= dzErr2;
       float dzErrF2 = trk_dzErr->at(ir) * (pt * pz / p2);
       dzErr2 *= dzErr2;
       err.At(0, 0) = dxyErr2 * sP * sP + dzErrF2 * cP * cP;
       err.At(0, 1) = -dxyErr2 * cP * sP + dzErrF2 * cP * sP;
       err.At(1, 1) = dxyErr2 * cP * cP + dzErrF2 * sP * sP;
       err.At(0, 2) = -dzErrF2 * cP * pt / pz;
       err.At(1, 2) = -dzErrF2 * sP * pt / pz;
       err.At(2, 2) = dzErr2 * std::pow((pt * pt / p2), 2);
       err.At(3, 3) = std::pow(trk_ptErr->at(ir) / pt / pt, 2);
       err.At(4, 4) = std::pow(trk_phiErr->at(ir), 2);
       err.At(5, 5) = std::pow(trk_lambdaErr->at(ir), 2);
       SVector3 pos = SVector3(trk_refpoint_x->at(ir), trk_refpoint_y->at(ir), trk_refpoint_z->at(ir));
       SVector3 mom = SVector3(1.f / pt, phi, M_PI_2 - trk_lambda->at(ir));
       TrackState state(trk_q->at(ir), pos, mom, err);
       Track track(state, trk_nChi2->at(ir), trk_seedIdx->at(ir), 0, nullptr);  //hits are filled later
       track.setAlgorithm(TrackAlgorithm(trk_originalAlgo->at(ir)));
       auto const& hTypes = trk_hitType->at(ir);
       auto const& hIdxs = trk_hitIdx->at(ir);
       for (unsigned int ip = 0; ip < hTypes.size(); ip++) {
         unsigned int hidx = hIdxs[ip];
         switch (HitType(hTypes[ip])) {
           case HitType::Pixel: {
             //cout << "pix=" << hidx << " track=" << cmsswTracks_.size() << endl;
             pixHitRecIdx[hidx].push_back(cmsswTracks_.size());
             break;
           }
           case HitType::Strip: {
             //cout << "pix=" << hidx << " track=" << cmsswTracks_.size() << endl;
             strHitRecIdx[hidx].push_back(cmsswTracks_.size());
             break;
           }
           case HitType::Glued: {
             if (not useMatched)
               throw std::logic_error("Tracks have glued hits, but matchedHit load is not configured");
             //cout << "pix=" << hidx << " track=" << cmsswTracks_.size() << endl;
             gluHitRecIdx[hidx].push_back(cmsswTracks_.size());
             break;
           }
           case HitType::Invalid:
             break;  //FIXME. Skip, really?
           default:
             throw std::logic_error("Track hit type can not be handled");
         }  //switch( HitType
       }
       cmsswTracks_.push_back(track);
     }
 
     vector<vector<Hit>>& layerHits_ = EE.layerHits_;
     vector<vector<uint64_t>>& layerHitMasks_ = EE.layerHitMasks_;
     vector<MCHitInfo>& simHitsInfo_ = EE.simHitsInfo_;
     int totHits = 0;
     layerHits_.resize(nTotalLayers);
     layerHitMasks_.resize(nTotalLayers);
     for (unsigned int ipix = 0; ipix < pix_lay->size(); ++ipix) {
       int ilay = -1;
       ilay = lnc.convertLayerNumber(pix_det->at(ipix), pix_lay->at(ipix), useMatched, -1, pix_z->at(ipix) > 0);
       if (ilay < 0)
         continue;
 
       unsigned int imoduleid = tkinfo[ilay].short_id(pix_detId->at(ipix));
 
       int simTkIdxNt = bestTkIdx(pix_simHitIdx->at(ipix), pix_chargeFraction->at(ipix), ipix, HitType::Pixel);
       int simTkIdx = simTkIdxNt >= 0 ? simTrackIdx_[simTkIdxNt] : -1;  //switch to index in simTracks_
 
       //cout << Form("pix lay=%i det=%i x=(%6.3f, %6.3f, %6.3f)",ilay+1,pix_det->at(ipix),pix_x->at(ipix),pix_y->at(ipix),pix_z->at(ipix)) << endl;
       SVector3 pos(pix_x->at(ipix), pix_y->at(ipix), pix_z->at(ipix));
       SMatrixSym33 err;
       err.At(0, 0) = pix_xx->at(ipix);
       err.At(1, 1) = pix_yy->at(ipix);
       err.At(2, 2) = pix_zz->at(ipix);
       err.At(0, 1) = pix_xy->at(ipix);
       err.At(0, 2) = pix_zx->at(ipix);
       err.At(1, 2) = pix_yz->at(ipix);
       if (simTkIdx >= 0) {
         simTracks_[simTkIdx].addHitIdx(layerHits_[ilay].size(), ilay, 0);
       }
       for (unsigned int is = 0; is < pixHitSeedIdx[ipix].size(); is++) {
         //cout << "xxx ipix=" << ipix << " seed=" << pixHitSeedIdx[ipix][is] << endl;
         seedTracks_[pixHitSeedIdx[ipix][is]].addHitIdx(layerHits_[ilay].size(), ilay, 0);  //per-hit chi2 is not known
       }
       for (unsigned int ir = 0; ir < pixHitRecIdx[ipix].size(); ir++) {
         //cout << "xxx ipix=" << ipix << " recTrack=" << pixHitRecIdx[ipix][ir] << endl;
         cmsswTracks_[pixHitRecIdx[ipix][ir]].addHitIdx(layerHits_[ilay].size(), ilay, 0);  //per-hit chi2 is not known
       }
       Hit hit(pos, err, totHits);
       hit.setupAsPixel(imoduleid, pix_csize_row->at(ipix), pix_csize_col->at(ipix));
       layerHits_[ilay].push_back(hit);
       if (writeHitIterMasks)
         layerHitMasks_[ilay].push_back(pix_usedMask->at(ipix));
       MCHitInfo hitInfo(simTkIdx, ilay, layerHits_[ilay].size() - 1, totHits);
       simHitsInfo_.push_back(hitInfo);
       totHits++;
     }
 
     if (useMatched) {
       for (unsigned int iglu = 0; iglu < glu_lay->size(); ++iglu) {
         if (glu_isBarrel->at(iglu) == 0)
           continue;
         int igluMono = glu_monoIdx->at(iglu);
         int simTkIdxNt =
             bestTkIdx(str_simHitIdx->at(igluMono), str_chargeFraction->at(igluMono), igluMono, HitType::Strip);
         int simTkIdx = simTkIdxNt >= 0 ? simTrackIdx_[simTkIdxNt] : -1;  //switch to index in simTracks_
 
         int ilay = lnc.convertLayerNumber(glu_det->at(iglu), glu_lay->at(iglu), useMatched, -1, glu_z->at(iglu) > 0);
         // cout << Form("glu lay=%i det=%i bar=%i x=(%6.3f, %6.3f, %6.3f)",ilay+1,glu_det->at(iglu),glu_isBarrel->at(iglu),glu_x->at(iglu),glu_y->at(iglu),glu_z->at(iglu)) << endl;
         SVector3 pos(glu_x->at(iglu), glu_y->at(iglu), glu_z->at(iglu));
         SMatrixSym33 err;
         err.At(0, 0) = glu_xx->at(iglu);
         err.At(1, 1) = glu_yy->at(iglu);
         err.At(2, 2) = glu_zz->at(iglu);
         err.At(0, 1) = glu_xy->at(iglu);
         err.At(0, 2) = glu_zx->at(iglu);
         err.At(1, 2) = glu_yz->at(iglu);
         if (simTkIdx >= 0) {
           simTracks_[simTkIdx].addHitIdx(layerHits_[ilay].size(), ilay, 0);
         }
         for (unsigned int ir = 0; ir < gluHitSeedIdx[iglu].size(); ir++) {
           //cout << "xxx iglu=" << iglu << " seed=" << gluHitSeedIdx[iglu][ir] << endl;
           seedTracks_[gluHitSeedIdx[iglu][ir]].addHitIdx(layerHits_[ilay].size(), ilay, 0);  //per-hit chi2 is not known
         }
         for (unsigned int ir = 0; ir < gluHitRecIdx[iglu].size(); ir++) {
           //cout << "xxx iglu=" << iglu << " recTrack=" << gluHitRecIdx[iglu][ir] << endl;
           cmsswTracks_[gluHitRecIdx[iglu][ir]].addHitIdx(layerHits_[ilay].size(), ilay, 0);  //per-hit chi2 is not known
         }
 
         // QQQQ module-id-in-layer, adc and phi/theta spans are not done for matched hits.
         // Will we ever use / need this?
         assert(false && "Implement module-ids, cluster adc and spans for matched hits!");
 
         Hit hit(pos, err, totHits);
         layerHits_[ilay].push_back(hit);
         MCHitInfo hitInfo(simTkIdx, ilay, layerHits_[ilay].size() - 1, totHits);
         simHitsInfo_.push_back(hitInfo);
         totHits++;
       }
     }
 
     vector<int> strIdx;
     strIdx.resize(str_lay->size());
     for (unsigned int istr = 0; istr < str_lay->size(); ++istr) {
       int ilay = -1;
       ilay = lnc.convertLayerNumber(
           str_det->at(istr), str_lay->at(istr), useMatched, str_isStereo->at(istr), str_z->at(istr) > 0);
       if (useMatched && str_isBarrel->at(istr) == 1 && str_isStereo->at(istr))
         continue;
       if (ilay == -1)
         continue;
 
       unsigned int imoduleid = tkinfo[ilay].short_id(str_detId->at(istr));
 
       int simTkIdxNt = bestTkIdx(str_simHitIdx->at(istr), str_chargeFraction->at(istr), istr, HitType::Strip);
       int simTkIdx = simTkIdxNt >= 0 ? simTrackIdx_[simTkIdxNt] : -1;  //switch to index in simTracks_
 
       bool passCCC = applyCCC ? (str_chargePerCM->at(istr) > cutValueCCC) : true;
 
       //if (str_onTrack->at(istr)==0) continue;//do not consider hits that are not on track!
       SVector3 pos(str_x->at(istr), str_y->at(istr), str_z->at(istr));
       SMatrixSym33 err;
       err.At(0, 0) = str_xx->at(istr);
       err.At(1, 1) = str_yy->at(istr);
       err.At(2, 2) = str_zz->at(istr);
       err.At(0, 1) = str_xy->at(istr);
       err.At(0, 2) = str_zx->at(istr);
       err.At(1, 2) = str_yz->at(istr);
       if (simTkIdx >= 0) {
         if (passCCC)
           simTracks_[simTkIdx].addHitIdx(layerHits_[ilay].size(), ilay, 0);
         else
           simTracks_[simTkIdx].addHitIdx(-9, ilay, 0);
       }
       for (unsigned int ir = 0; ir < strHitSeedIdx[istr].size(); ir++) {
         //cout << "xxx istr=" << istr << " seed=" << strHitSeedIdx[istr][ir] << endl;
         if (passCCC)
           seedTracks_[strHitSeedIdx[istr][ir]].addHitIdx(layerHits_[ilay].size(), ilay, 0);  //per-hit chi2 is not known
         else
           seedTracks_[strHitSeedIdx[istr][ir]].addHitIdx(-9, ilay, 0);
       }
       for (unsigned int ir = 0; ir < strHitRecIdx[istr].size(); ir++) {
         //cout << "xxx istr=" << istr << " recTrack=" << strHitRecIdx[istr][ir] << endl;
         if (passCCC)
           cmsswTracks_[strHitRecIdx[istr][ir]].addHitIdx(layerHits_[ilay].size(), ilay, 0);  //per-hit chi2 is not known
         else
           cmsswTracks_[strHitRecIdx[istr][ir]].addHitIdx(-9, ilay, 0);
       }
       if (passCCC) {
         Hit hit(pos, err, totHits);
         hit.setupAsStrip(imoduleid, str_chargePerCM->at(istr), str_csize->at(istr));
         layerHits_[ilay].push_back(hit);
         if (writeHitIterMasks)
           layerHitMasks_[ilay].push_back(str_usedMask->at(istr));
         MCHitInfo hitInfo(simTkIdx, ilay, layerHits_[ilay].size() - 1, totHits);
         simHitsInfo_.push_back(hitInfo);
         totHits++;
       }
     }
 
     // Seed % hit statistics
     nstot += seedTracks_.size();
     for (unsigned int il = 0; il < layerHits_.size(); ++il) {
       int nh = layerHits_[il].size();
       nhitstot[il] += nh;
     }
 
     if (verbosity > 0) {
       int nt = simTracks_.size();
 
       int nl = layerHits_.size();
 
       int nm = simHitsInfo_.size();
 
       int ns = seedTracks_.size();
 
       int nr = cmsswTracks_.size();
 
       printf("number of simTracks %i\n", nt);
       printf("number of layerHits %i\n", nl);
       printf("number of simHitsInfo %i\n", nm);
       printf("number of seedTracks %i\n", ns);
       printf("number of recTracks %i\n", nr);
 
       if (verbosity > 1) {
         printf("\n");
         for (int il = 0; il < nl; ++il) {
           int nh = layerHits_[il].size();
           for (int ih = 0; ih < nh; ++ih) {
             printf("lay=%i idx=%i mcid=%i x=(%6.3f, %6.3f, %6.3f) r=%6.3f mask=0x%lx\n",
                    il + 1,
                    ih,
                    layerHits_[il][ih].mcHitID(),
                    layerHits_[il][ih].x(),
                    layerHits_[il][ih].y(),
                    layerHits_[il][ih].z(),
                    sqrt(pow(layerHits_[il][ih].x(), 2) + pow(layerHits_[il][ih].y(), 2)),
                    writeHitIterMasks ? layerHitMasks_[il][ih] : 0);
           }
         }
 
         for (int i = 0; i < nt; ++i) {
           float spt = sqrt(pow(simTracks_[i].px(), 2) + pow(simTracks_[i].py(), 2));
           printf(
               "sim track id=%i q=%2i p=(%6.3f, %6.3f, %6.3f) x=(%6.3f, %6.3f, %6.3f) pT=%7.4f nTotal=%i nFound=%i \n",
               i,
               simTracks_[i].charge(),
               simTracks_[i].px(),
               simTracks_[i].py(),
               simTracks_[i].pz(),
               simTracks_[i].x(),
               simTracks_[i].y(),
               simTracks_[i].z(),
               spt,
               simTracks_[i].nTotalHits(),
               simTracks_[i].nFoundHits());
           int nh = simTracks_[i].nTotalHits();
           for (int ih = 0; ih < nh; ++ih) {
             int hidx = simTracks_[i].getHitIdx(ih);
             int hlay = simTracks_[i].getHitLyr(ih);
             float hx = layerHits_[hlay][hidx].x();
             float hy = layerHits_[hlay][hidx].y();
             float hz = layerHits_[hlay][hidx].z();
             printf("track #%4i hit #%2i idx=%4i lay=%2i x=(% 8.3f, % 8.3f, % 8.3f) r=%8.3f\n",
                    i,
                    ih,
                    hidx,
                    hlay,
                    hx,
                    hy,
                    hz,
                    sqrt(hx * hx + hy * hy));
           }
         }
 
         for (int i = 0; i < ns; ++i) {
           printf("seed id=%i label=%i algo=%i q=%2i pT=%6.3f p=(%6.3f, %6.3f, %6.3f) x=(%6.3f, %6.3f, %6.3f)\n",
                  i,
                  seedTracks_[i].label(),
                  (int)seedTracks_[i].algorithm(),
                  seedTracks_[i].charge(),
                  seedTracks_[i].pT(),
                  seedTracks_[i].px(),
                  seedTracks_[i].py(),
                  seedTracks_[i].pz(),
                  seedTracks_[i].x(),
                  seedTracks_[i].y(),
                  seedTracks_[i].z());
           int nh = seedTracks_[i].nTotalHits();
           for (int ih = 0; ih < nh; ++ih)
             printf("seed #%i hit #%i idx=%i\n", i, ih, seedTracks_[i].getHitIdx(ih));
         }
 
         if (writeRecTracks) {
           for (int i = 0; i < nr; ++i) {
             float spt = sqrt(pow(cmsswTracks_[i].px(), 2) + pow(cmsswTracks_[i].py(), 2));
             printf(
                 "rec track id=%i label=%i algo=%i chi2=%6.3f q=%2i p=(%6.3f, %6.3f, %6.3f) x=(%6.3f, %6.3f, %6.3f) "
                 "pT=%7.4f nTotal=%i nFound=%i \n",
                 i,
                 cmsswTracks_[i].label(),
                 (int)cmsswTracks_[i].algorithm(),
                 cmsswTracks_[i].chi2(),
                 cmsswTracks_[i].charge(),
                 cmsswTracks_[i].px(),
                 cmsswTracks_[i].py(),
                 cmsswTracks_[i].pz(),
                 cmsswTracks_[i].x(),
                 cmsswTracks_[i].y(),
                 cmsswTracks_[i].z(),
                 spt,
                 cmsswTracks_[i].nTotalHits(),
                 cmsswTracks_[i].nFoundHits());
             int nh = cmsswTracks_[i].nTotalHits();
             for (int ih = 0; ih < nh; ++ih) {
               int hidx = cmsswTracks_[i].getHitIdx(ih);
               int hlay = cmsswTracks_[i].getHitLyr(ih);
               float hx = layerHits_[hlay][hidx].x();
               float hy = layerHits_[hlay][hidx].y();
               float hz = layerHits_[hlay][hidx].z();
               printf("track #%4i hit #%2i idx=%4i lay=%2i x=(% 8.3f, % 8.3f, % 8.3f) r=%8.3f\n",
                      i,
                      ih,
                      hidx,
                      hlay,
                      hx,
                      hy,
                      hz,
                      sqrt(hx * hx + hy * hy));
             }
           }
         }  //if (writeRecTracks){
 
       }  //verbosity>1
     }    //verbosity>0
     EE.write_out(data_file);
 
     savedEvents++;
     printf("end of event %lli\n", savedEvents);
   }
 
   data_file.CloseWrite(savedEvents);
   printf("\nSaved %lli events\n\n", savedEvents);
 
   printf("Average number of seeds per event %f\n", float(nstot) / float(savedEvents));
   for (unsigned int il = 0; il < nhitstot.size(); ++il)
     printf("Average number of hits in layer %3i = %7.2f\n",
            il,
            float(nhitstot[il]) / float(savedEvents));  //Includes those that failed the cluster charge cut
 
   printf("Out of %i hits, %i failed the cut", numTotalStr, numFailCCC);
 
   //========================================================================
 
   printf("\n\n================================================================\n");
   printf("=== Max module id for %u layers\n", nTotalLayers);
   printf("================================================================\n");
   for (unsigned int ii = 0; ii < nTotalLayers; ++ii) {
     printf("Layer%2d : %d\n", ii, tkinfo[ii].n_modules());
   }
 }

◆ next_arg_option()

bool next_arg_option	(	lStr_t &	args,
		lStr_i &	i
	)

Definition at line 35 of file WriteMemoryFile.cc.

References writedatasetfile::args, mps_fire::i, and dqmiolumiharvest::j.

Referenced by main().

                                               {
   lStr_i j = i;
   if (++j == args.end() || ((*j)[0] == '-')) {
     return false;
   }
   i = j;
   return true;
 }

◆ next_arg_or_die()

void next_arg_or_die	(	lStr_t &	args,
		lStr_i &	i
	)

Definition at line 26 of file WriteMemoryFile.cc.

References writedatasetfile::args, EcnaPython_AdcPeg12_S1_10_R170298_1_0_150_Dee0::cerr, beamvalidation::exit(), mps_fire::i, and dqmiolumiharvest::j.

Referenced by main().

                                               {
   lStr_i j = i;
   if (++j == args.end() || ((*j)[0] == '-')) {
     std::cerr << "Error: option " << *i << " requires an argument.\n";
     exit(1);
   }
   i = j;
 }

◆ printHelp()

void printHelp ( const char * av0 )

Definition at line 44 of file WriteMemoryFile.cc.

Referenced by main().

                                 {
   printf(
       "Usage: %s [options]\n"
       "Options:\n"
       "  --input          <str>    input file\n"
       "  --output         <str>    output file\n"
       "  --geo            <file>   binary TrackerInfo geometry (def: CMS-2017.bin)\n"
       "  --verbosity      <num>    print details (0 quiet, 1 print counts, 2 print all; def: 0)\n"
       "  --maxevt         <num>    maxevt events to write (-1 for everything in the file def: -1)\n"
       "  --clean-sim-tracks        apply sim track cleaning (def: no cleaning)\n"
       "  --write-all-events        write all events (def: skip events with 0 simtracks or seeds)\n"
       "  --write-rec-tracks        write rec tracks (def: not written)\n"
       "  --apply-ccc               apply cluster charge cut to strip hits (def: false)\n"
       "  --all-seeds               merge all seeds from the input file (def: false)\n",
       av0);
 }

Variable Documentation

◆ cleanSimTrack_minRecHits

constexpr int cleanSimTrack_minRecHits = 2

Definition at line 19 of file WriteMemoryFile.cc.

Referenced by main().

◆ cleanSimTrack_minSimHits

constexpr int cleanSimTrack_minSimHits = 3

Definition at line 18 of file WriteMemoryFile.cc.

Referenced by main().

◆ useMatched

constexpr bool useMatched = false

Definition at line 16 of file WriteMemoryFile.cc.

Referenced by mkfit::LayerNumberConverter::convertBarrelLayerNumber(), mkfit::LayerNumberConverter::convertDiskNumber(), mkfit::LayerNumberConverter::convertLayerNumber(), MkFitGeometryESProducer::fillShapeAndPlacement(), and main().

Typedefs

Enumerations

Functions

Variables

Typedef Documentation

◆ lStr_i

◆ lStr_t

◆ TrackAlgorithm

Enumeration Type Documentation

◆ HitType

Function Documentation

◆ main()

CALO JETS

PF JETS

◆ next_arg_option()

◆ next_arg_or_die()

◆ printHelp()

Variable Documentation

◆ cleanSimTrack_minRecHits

◆ cleanSimTrack_minSimHits

◆ useMatched