ZntupleToTreeConverter.cc File Reference

#include <memory>
#include <string>
#include <vector>
#include <sstream>
#include <fstream>
#include <iostream>
#include <TH1F.h>
#include <TROOT.h>
#include <TFile.h>
#include <TSystem.h>
#include "DataFormats/Common/interface/Handle.h"
#include "DataFormats/FWLite/interface/Event.h"
#include "DataFormats/PatCandidates/interface/Muon.h"
#include "FWCore/FWLite/interface/FWLiteEnabler.h"
#include "DataFormats/FWLite/interface/Handle.h"
#include "PhysicsTools/FWLite/interface/TFileService.h"
#include "MuonAnalysis/MomentumScaleCalibration/interface/RootTreeHandler.h"

Go to the source code of this file.

Functions
lorentzVector	fromPtEtaPhiToPxPyPz (const double *ptEtaPhiE)
int	main (int argc, char *argv[])

Function Documentation

fromPtEtaPhiToPxPyPz()

lorentzVector fromPtEtaPhiToPxPyPz

(

const double *

ptEtaPhiE

)

Definition at line 24 of file ZntupleToTreeConverter.cc.

References funct::cos(), JetChargeProducer_cfi::exp, fastsim::Constants::muMass, multPhiCorr_741_25nsDY_cfi::px, multPhiCorr_741_25nsDY_cfi::py, funct::sin(), mathSSE::sqrt(), and createJobs::tmp.

Referenced by main().

                                                            {
  double muMass = 0.105658;
  double px = ptEtaPhiE[0] * cos(ptEtaPhiE[2]);
  double py = ptEtaPhiE[0] * sin(ptEtaPhiE[2]);
  double tmp = 2 * atan(exp(-ptEtaPhiE[1]));
  double pz = ptEtaPhiE[0] * cos(tmp) / sin(tmp);
  double E = sqrt(px * px + py * py + pz * pz + muMass * muMass);

  // lorentzVector corrMu(px,py,pz,E);
  // To fix memory leaks, this is to be substituted with
  // std::unique_ptr<lorentzVector> corrMu(new lorentzVector(px, py, pz, E));

  return lorentzVector(px, py, pz, E);
}

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

errA with average Amplitudes

errA with average Amplitudes

errA with average Amplitudes

Summed Amplitude Plots:





Summed Amplitude Plots:

Summed Amplitude Plots:

Summed Amplitude Plots:

Summed Amplitude Plots:

Summed Amplitude Plots:

RBX:

errA with average Amplitudes

errA with average Amplitudes

errA with average Amplitudes

errA with average Amplitudes

Summed Amplitude Plots:





Summed Amplitude Plots:

Summed Amplitude Plots:

Summed Amplitude Plots:

Summed Amplitude Plots:

Summed Amplitude Plots:

RBX:

errA with average Amplitudes

errA with average Amplitudes

errA with average Amplitudes

errA with average Amplitudes

Summed Amplitude Plots:





Summed Amplitude Plots:

Summed Amplitude Plots:

Summed Amplitude Plots:

Summed Amplitude Plots:

Summed Amplitude Plots:

RBX:

Prepare maps of good/bad channels:

Prepare maps of good/bad channels:

Prepare maps of good/bad channels:

Prepare maps of good/bad channels:

Definition at line 39 of file ZntupleToTreeConverter.cc.

References dir2webdir::argc, GCPpyPlots::argv, gather_cfg::cout, FWLiteEnabler::enable(), makeMEIFBenchmarkPlots::ev, beamvalidation::exit(), MillePedeFileConverter_cfg::fileName, fromPtEtaPhiToPxPyPz(), compareTotals::fs, fwlite::Handle< T >::getByLabel(), mps_fire::i, iEvent, testHGCalDigi_cfg::inFile, fwlite::Handle< T >::isValid(), TFileDirectory::make(), AlCaHLTBitMon_QueryRunRegistry::string, and align_cfg::TFileService.

                                 {
  if (argc != 2) {
    std::cout << "Please provide the name of the file with file: or rfio: as needed" << std::endl;
    exit(1);
  }
  std::string fileName(argv[1]);
  if (fileName.find("file:") != 0 && fileName.find("rfio:") != 0) {
    std::cout << "Please provide the name of the file with file: or rfio: as needed" << std::endl;
    exit(1);
  }

  // ----------------------------------------------------------------------
  // First Part:
  //
  //  * enable FWLite
  //  * book the histograms of interest
  //  * open the input file
  // ----------------------------------------------------------------------

  // load framework libraries
  gSystem->Load("libFWCoreFWLite");
  FWLiteEnabler::enable();

  // book a set of histograms
  fwlite::TFileService fs = fwlite::TFileService("analyzeBasics.root");
  TFileDirectory theDir = fs.mkdir("analyzeBasic");
  TH1F* muonPt_ = theDir.make<TH1F>("muonPt", "pt", 100, 0., 300.);
  TH1F* muonEta_ = theDir.make<TH1F>("muonEta", "eta", 100, -3., 3.);
  TH1F* muonPhi_ = theDir.make<TH1F>("muonPhi", "phi", 100, -5., 5.);

  // open input file (can be located on castor)
  TFile* inFile = TFile::Open(fileName.c_str());

  //   TFile* inFile = TFile::Open("rfio:/castor/cern.ch/user/f/fabozzi/36XSkimData/run_139791-140159/NtupleLoose_139791-140159_v2.root");
  //   TFile* inFile = TFile::Open("rfio:/castor/cern.ch/user/f/fabozzi/36XSkimData/run_140160-140182/NtupleLoose_140160-140182.root");
  //   TFile* inFile = TFile::Open("rfio:/castor/cern.ch/user/f/fabozzi/36XSkimData/run_140183-140399/NtupleLoose_140183-140399.root");
  //   TFile* inFile = TFile::Open("rfio:/castor/cern.ch/user/d/degrutto/36XSkimData/run_140440-141961/NtupleLoose_140440-141961.root");
  //   TFile* inFile = TFile::Open("rfio:/castor/cern.ch/user/d/degrutto/36XSkimData/run_142035-142664/NtupleLoose_142035-142664.root");

  // ----------------------------------------------------------------------
  // Second Part:
  //
  //  * loop the events in the input file
  //  * receive the collections of interest via fwlite::Handle
  //  * fill the histograms
  //  * after the loop close the input file
  // ----------------------------------------------------------------------

  // Create the RootTreeHandler to save the events in the root tree
  RootTreeHandler treeHandler;
  // MuonPairVector pairVector;
  std::vector<MuonPair> pairVector;

  // loop the events
  unsigned int iEvent = 0;
  fwlite::Event ev(inFile);
  for (ev.toBegin(); !ev.atEnd(); ++ev, ++iEvent) {
    // simple event counter
    if (iEvent > 0 && iEvent % 100 == 0) {
      std::cout << "  processing event: " << iEvent << std::endl;
    }

    // Handle to the muon collection
    fwlite::Handle<std::vector<float> > muon1pt;
    fwlite::Handle<std::vector<float> > muon1eta;
    fwlite::Handle<std::vector<float> > muon1phi;
    fwlite::Handle<std::vector<float> > muon2pt;
    fwlite::Handle<std::vector<float> > muon2eta;
    fwlite::Handle<std::vector<float> > muon2phi;
    muon1pt.getByLabel(ev, "goodZToMuMuEdmNtupleLoose", "zGoldenDau1Pt");
    muon1eta.getByLabel(ev, "goodZToMuMuEdmNtupleLoose", "zGoldenDau1Eta");
    muon1phi.getByLabel(ev, "goodZToMuMuEdmNtupleLoose", "zGoldenDau1Phi");
    muon2pt.getByLabel(ev, "goodZToMuMuEdmNtupleLoose", "zGoldenDau2Pt");
    muon2eta.getByLabel(ev, "goodZToMuMuEdmNtupleLoose", "zGoldenDau2Eta");
    muon2phi.getByLabel(ev, "goodZToMuMuEdmNtupleLoose", "zGoldenDau2Phi");

    if (!muon1pt.isValid())
      continue;
    if (!muon1eta.isValid())
      continue;
    if (!muon1phi.isValid())
      continue;
    if (!muon2pt.isValid())
      continue;
    if (!muon2eta.isValid())
      continue;
    if (!muon2phi.isValid())
      continue;
    // std::cout << "muon1pt = " << muon1pt->size() << std::endl;

    // loop muon collection and fill histograms
    if (muon1pt->size() != muon2pt->size()) {
      std::cout << "Error: size of muon1 and muon2 is different. Skipping event" << std::endl;
      continue;
    }
    for (unsigned i = 0; i < muon1pt->size(); ++i) {
      muonPt_->Fill((*muon1pt)[i]);
      muonEta_->Fill((*muon1eta)[i]);
      muonPhi_->Fill((*muon1phi)[i]);
      muonPt_->Fill((*muon2pt)[i]);
      muonEta_->Fill((*muon2eta)[i]);
      muonPhi_->Fill((*muon2phi)[i]);

      double muon1[3] = {(*muon1pt)[i], (*muon1eta)[i], (*muon1phi)[i]};
      double muon2[3] = {(*muon2pt)[i], (*muon2eta)[i], (*muon2phi)[i]};

      // pairVector.push_back( std::make_pair( fromPtEtaPhiToPxPyPz(muon1), fromPtEtaPhiToPxPyPz(muon2) ) );
      pairVector.push_back(
          MuonPair(fromPtEtaPhiToPxPyPz(muon1), fromPtEtaPhiToPxPyPz(muon2), MuScleFitEvent(0, 0, 0, 0, 0, 0)));
    }
  }
  size_t namePos = fileName.find_last_of('/');
  treeHandler.writeTree(("tree_" + fileName.substr(namePos + 1, fileName.size())).c_str(), &pairVector);

  // close input file
  inFile->Close();

  // ----------------------------------------------------------------------
  // Third Part:
  //
  //  * never forget to free the memory of objects you created
  // ----------------------------------------------------------------------

  // in this example there is nothing to do

  // that's it!
  return 0;
}