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Public Member Functions | Private Member Functions | Private Attributes

MuonAlignmentFromReference Class Reference

#include <Alignment/MuonAlignmentFromReference/interface/MuonAlignmentFromReference.h>

Inheritance diagram for MuonAlignmentFromReference:
AlignmentAlgorithmBase

List of all members.

Public Member Functions

void initialize (const edm::EventSetup &iSetup, AlignableTracker *alignableTracker, AlignableMuon *alignableMuon, AlignableExtras *extras, AlignmentParameterStore *alignmentParameterStore)
 Call at beginning of job (must be implemented in derived class)
 MuonAlignmentFromReference (const edm::ParameterSet &cfg)
void processMuonResidualsFromTrack (MuonResidualsFromTrack &mrft)
void run (const edm::EventSetup &iSetup, const EventInfo &eventInfo)
 Run the algorithm (must be implemented in derived class)
void startNewLoop ()
void terminate ()
 Call at end of each loop (must be implemented in derived class)
virtual ~MuonAlignmentFromReference ()

Private Member Functions

void bookNtuple ()
std::string chamberPrettyNameFromId (unsigned int idx)
void correctBField ()
void eraseNotSelectedResiduals ()
void fillNtuple ()
void fitAndAlign ()
int number (std::string s)
bool numeric (std::string s)
void parseReference (std::vector< Alignable * > &reference, std::vector< Alignable * > &all_DT_chambers, std::vector< Alignable * > &all_CSC_chambers)
void readTmpFiles ()
void selectResidualsPeaks ()
void writeTmpFiles ()

Private Attributes

AlignableNavigatorm_alignableNavigator
std::vector< Alignable * > m_alignables
AlignmentParameterStorem_alignmentParameterStore
bool m_allowTIDTEC
int m_BFieldCorrection
bool m_combineME11
long m_counter_csc
long m_counter_cscaligning
long m_counter_cschits
long m_counter_cscvalid
long m_counter_events
long m_counter_minchambers
long m_counter_resslopey
long m_counter_station123
long m_counter_station123aligning
long m_counter_station123dt13hits
long m_counter_station123dt2hits
long m_counter_station123valid
long m_counter_station4
long m_counter_station4aligning
long m_counter_station4hits
long m_counter_station4valid
long m_counter_totchambers
long m_counter_trackdxy
long m_counter_trackerchi2
long m_counter_trackerhits
long m_counter_trackertidtec
long m_counter_trackmomentum
long m_counter_tracks
bool m_createNtuple
bool m_doAlignment
bool m_doCSC
bool m_doDT
std::map< unsigned int,
MuonResidualsTwoBin * > 
m_fitterOrder
std::map< Alignable
*, MuonResidualsTwoBin * > 
m_fitters
std::vector< unsigned int > m_indexes
double m_maxDxy
double m_maxResSlopeY
double m_maxTrackerRedChi2
double m_maxTrackP
double m_maxTrackPt
std::map< Alignable
*, Alignable * > 
m_me11map
int m_minAlignmentHits
int m_minCSCHits
int m_minDT13Hits
int m_minDT2Hits
int m_minNCrossedChambers
int m_minTrackerHits
double m_minTrackP
double m_minTrackPt
edm::InputTag m_muonCollectionTag
double m_peakNSigma
std::vector< std::string > m_readTemporaryFiles
std::vector< std::string > m_reference
std::string m_reportFileName
std::string m_residualsModel
int m_strategy
MuonResidualsFitter::MuonAlignmentTreeRow m_tree_row
TTree * m_ttree
bool m_twoBin
std::string m_useResiduals
bool m_weightAlignment
std::string m_writeTemporaryFile

Detailed Description

Description: <one line="" class="" summary>="">

Implementation: <Notes on="" implementation>="">

Definition at line 69 of file MuonAlignmentFromReference.cc.


Constructor & Destructor Documentation

MuonAlignmentFromReference::MuonAlignmentFromReference ( const edm::ParameterSet cfg)

Definition at line 183 of file MuonAlignmentFromReference.cc.

References bookNtuple(), m_counter_csc, m_counter_cscaligning, m_counter_cschits, m_counter_cscvalid, m_counter_events, m_counter_minchambers, m_counter_resslopey, m_counter_station123, m_counter_station123aligning, m_counter_station123dt13hits, m_counter_station123dt2hits, m_counter_station123valid, m_counter_station4, m_counter_station4aligning, m_counter_station4hits, m_counter_station4valid, m_counter_totchambers, m_counter_trackdxy, m_counter_trackerchi2, m_counter_trackerhits, m_counter_trackertidtec, m_counter_trackmomentum, m_counter_tracks, m_createNtuple, m_doAlignment, m_ttree, and NULL.

  : AlignmentAlgorithmBase(cfg)
  , m_muonCollectionTag(cfg.getParameter<edm::InputTag>("muonCollectionTag"))
  , m_reference(cfg.getParameter<std::vector<std::string> >("reference"))
  , m_minTrackPt(cfg.getParameter<double>("minTrackPt"))
  , m_maxTrackPt(cfg.getParameter<double>("maxTrackPt"))
  , m_minTrackP(cfg.getParameter<double>("minTrackP"))
  , m_maxTrackP(cfg.getParameter<double>("maxTrackP"))
  , m_maxDxy(cfg.getParameter<double>("maxDxy"))
  , m_minTrackerHits(cfg.getParameter<int>("minTrackerHits"))
  , m_maxTrackerRedChi2(cfg.getParameter<double>("maxTrackerRedChi2"))
  , m_allowTIDTEC(cfg.getParameter<bool>("allowTIDTEC"))
  , m_minNCrossedChambers(cfg.getParameter<int>("minNCrossedChambers"))
  , m_minDT13Hits(cfg.getParameter<int>("minDT13Hits"))
  , m_minDT2Hits(cfg.getParameter<int>("minDT2Hits"))
  , m_minCSCHits(cfg.getParameter<int>("minCSCHits"))
  , m_writeTemporaryFile(cfg.getParameter<std::string>("writeTemporaryFile"))
  , m_readTemporaryFiles(cfg.getParameter<std::vector<std::string> >("readTemporaryFiles"))
  , m_doAlignment(cfg.getParameter<bool>("doAlignment"))
  , m_strategy(cfg.getParameter<int>("strategy"))
  , m_residualsModel(cfg.getParameter<std::string>("residualsModel"))
  , m_minAlignmentHits(cfg.getParameter<int>("minAlignmentHits"))
  , m_twoBin(cfg.getParameter<bool>("twoBin"))
  , m_combineME11(cfg.getParameter<bool>("combineME11"))
  , m_weightAlignment(cfg.getParameter<bool>("weightAlignment"))
  , m_reportFileName(cfg.getParameter<std::string>("reportFileName"))
  , m_maxResSlopeY(cfg.getParameter<double>("maxResSlopeY"))
  , m_createNtuple(cfg.getParameter<bool>("createNtuple"))
  , m_peakNSigma(cfg.getParameter<double>("peakNSigma"))
  , m_BFieldCorrection(cfg.getParameter<int>("bFieldCorrection"))
  , m_doDT(cfg.getParameter<bool>("doDT"))
  , m_doCSC(cfg.getParameter<bool>("doCSC"))
  , m_useResiduals(cfg.getParameter<std::string>("useResiduals"))
{
  // alignment requires a TFile to provide plots to check the fit output
  // just filling the residuals lists does not
  // but we don't want to wait until the end of the job to find out that the TFile is missing
  if (m_doAlignment || m_createNtuple) {
    edm::Service<TFileService> fs;
    TFile &tfile = fs->file();
    tfile.ls();
  }

  m_ttree = NULL;
  if (m_createNtuple) bookNtuple();

  m_counter_events = 0;
  m_counter_tracks = 0;
  m_counter_trackmomentum = 0;
  m_counter_trackdxy = 0;
  m_counter_trackerhits = 0;
  m_counter_trackerchi2 = 0;
  m_counter_trackertidtec = 0;
  m_counter_minchambers = 0;
  m_counter_totchambers = 0;
  m_counter_station123 = 0;
  m_counter_station123valid = 0;
  m_counter_station123dt13hits = 0;
  m_counter_station123dt2hits = 0;
  m_counter_station123aligning = 0;
  m_counter_station4 = 0;
  m_counter_station4valid = 0;
  m_counter_station4hits = 0;
  m_counter_station4aligning = 0;
  m_counter_csc = 0;
  m_counter_cscvalid = 0;
  m_counter_cschits = 0;
  m_counter_cscaligning = 0;
  m_counter_resslopey = 0;
}
MuonAlignmentFromReference::~MuonAlignmentFromReference ( ) [virtual]

Definition at line 255 of file MuonAlignmentFromReference.cc.

References m_alignableNavigator.


Member Function Documentation

void MuonAlignmentFromReference::bookNtuple ( ) [private]

Definition at line 261 of file MuonAlignmentFromReference.cc.

References MuonResidualsFitter::MuonAlignmentTreeRow::angle_x, MuonResidualsFitter::MuonAlignmentTreeRow::angle_y, MuonResidualsFitter::MuonAlignmentTreeRow::is_dt, MuonResidualsFitter::MuonAlignmentTreeRow::is_plus, m_tree_row, m_ttree, MuonResidualsFitter::MuonAlignmentTreeRow::pos_x, MuonResidualsFitter::MuonAlignmentTreeRow::pos_y, MuonResidualsFitter::MuonAlignmentTreeRow::pt, MuonResidualsFitter::MuonAlignmentTreeRow::pz, MuonResidualsFitter::MuonAlignmentTreeRow::q, MuonResidualsFitter::MuonAlignmentTreeRow::res_slope_x, MuonResidualsFitter::MuonAlignmentTreeRow::res_slope_y, MuonResidualsFitter::MuonAlignmentTreeRow::res_x, MuonResidualsFitter::MuonAlignmentTreeRow::res_y, MuonResidualsFitter::MuonAlignmentTreeRow::ring_wheel, MuonResidualsFitter::MuonAlignmentTreeRow::sector, MuonResidualsFitter::MuonAlignmentTreeRow::select, and MuonResidualsFitter::MuonAlignmentTreeRow::station.

Referenced by MuonAlignmentFromReference().

{
  edm::Service<TFileService> fs;
  m_ttree = fs->make<TTree>("mual_ttree", "mual_ttree");
  m_ttree->Branch("is_plus", &m_tree_row.is_plus, "is_plus/O");
  m_ttree->Branch("is_dt", &m_tree_row.is_dt, "is_dt/O");
  m_ttree->Branch("station", &m_tree_row.station, "station/b");
  m_ttree->Branch("ring_wheel", &m_tree_row.ring_wheel, "ring_wheel/B");
  m_ttree->Branch("sector", &m_tree_row.sector, "sector/b");
  m_ttree->Branch("res_x", &m_tree_row.res_x, "res_x/F");
  m_ttree->Branch("res_y", &m_tree_row.res_y, "res_y/F");
  m_ttree->Branch("res_slope_x", &m_tree_row.res_slope_x, "res_slope_x/F");
  m_ttree->Branch("res_slope_y", &m_tree_row.res_slope_y, "res_slope_y/F");
  m_ttree->Branch("pos_x",&m_tree_row.pos_x, "pos_x/F");
  m_ttree->Branch("pos_y",&m_tree_row.pos_y, "pos_y/F");
  m_ttree->Branch("angle_x",&m_tree_row.angle_x, "angle_x/F");
  m_ttree->Branch("angle_y",&m_tree_row.angle_y,"angle_y/F");
  m_ttree->Branch("pz",&m_tree_row.pz,"pz/F");
  m_ttree->Branch("pt",&m_tree_row.pt,"pt/F");
  m_ttree->Branch("q",&m_tree_row.q,"q/B");
  m_ttree->Branch("select", &m_tree_row.select, "select/O");
  //m_ttree->Branch("",&m_tree_row.,"/");

}
std::string MuonAlignmentFromReference::chamberPrettyNameFromId ( unsigned int  idx) [private]

Definition at line 1678 of file MuonAlignmentFromReference.cc.

References CSCDetId::chamber(), CSC(), MuonSubdetId::DT, CSCDetId::endcap(), CSCDetId::ring(), DTChamberId::sector(), CSCDetId::station(), DTChamberId::station(), AlCaHLTBitMon_QueryRunRegistry::string, and DTChamberId::wheel().

Referenced by correctBField(), eraseNotSelectedResiduals(), and selectResidualsPeaks().

{
   DetId id(idx); 
   char cname[40];
   if (id.subdetId() == MuonSubdetId::DT)
   {
     DTChamberId chamberId(id.rawId());
     sprintf(cname, "MB%+d/%d/%02d", chamberId.wheel(), chamberId.station(), chamberId.sector());
   }
   else if (id.subdetId() == MuonSubdetId::CSC)
   {
     CSCDetId chamberId(id.rawId());
     sprintf(cname, "ME%s%d/%d/%02d", (chamberId.endcap() == 1 ? "+" : "-"), chamberId.station(), chamberId.ring(), chamberId.chamber());
   }
   return std::string(cname);
}
void MuonAlignmentFromReference::correctBField ( ) [private]

Definition at line 1574 of file MuonAlignmentFromReference.cc.

References chamberPrettyNameFromId(), MuonResidualsTwoBin::correctBField(), gather_cfg::cout, getHLTprescales::index, m_fitterOrder, and m_indexes.

Referenced by terminate().

{
  for (std::vector<unsigned int>::const_iterator index = m_indexes.begin();  index != m_indexes.end();  ++index)
  {
    std::cout<<"correcting B in "<<chamberPrettyNameFromId(*index)<<std::endl;
    MuonResidualsTwoBin *fitter = m_fitterOrder[*index];
    fitter->correctBField();
  }
}
void MuonAlignmentFromReference::eraseNotSelectedResiduals ( ) [private]

Definition at line 1585 of file MuonAlignmentFromReference.cc.

References chamberPrettyNameFromId(), gather_cfg::cout, MuonResidualsTwoBin::eraseNotSelectedResiduals(), getHLTprescales::index, m_fitterOrder, and m_indexes.

Referenced by terminate().

{
  for (std::vector<unsigned int>::const_iterator index = m_indexes.begin();  index != m_indexes.end();  ++index)
  {
    std::cout<<"erasing in "<<chamberPrettyNameFromId(*index)<<std::endl;
    MuonResidualsTwoBin *fitter = m_fitterOrder[*index];
    fitter->eraseNotSelectedResiduals();
  }
}
void MuonAlignmentFromReference::fillNtuple ( ) [private]

Definition at line 1696 of file MuonAlignmentFromReference.cc.

References MuonResidualsFitter::MuonAlignmentTreeRow::angle_x, MuonResidualsFitter::MuonAlignmentTreeRow::angle_y, CSC(), DetId::det(), cond::rpcobgas::detid, GeomDetEnumerators::DT, MuonSubdetId::DT, Reference_intrackfit_cff::endcap, getHLTprescales::index, MuonResidualsFitter::MuonAlignmentTreeRow::is_dt, MuonResidualsFitter::MuonAlignmentTreeRow::is_plus, MuonResidualsFitter::k5DOF, MuonResidualsFitter::k6DOF, MuonResidualsFitter::k6DOFrphi, MuonResiduals6DOFFitter::kAngleX, MuonResiduals5DOFFitter::kAngleX, MuonResiduals5DOFFitter::kAngleY, MuonResiduals6DOFFitter::kAngleY, MuonResiduals5DOFFitter::kCharge, MuonResiduals6DOFFitter::kCharge, MuonResiduals6DOFFitter::kPositionX, MuonResiduals5DOFFitter::kPositionX, MuonResiduals6DOFFitter::kPositionY, MuonResiduals5DOFFitter::kPositionY, kPt, MuonResiduals6DOFFitter::kPz, MuonResiduals5DOFFitter::kPz, MuonResiduals5DOFFitter::kResid, MuonResiduals6DOFFitter::kResidX, MuonResiduals6DOFFitter::kResidY, MuonResiduals5DOFFitter::kResSlope, MuonResiduals6DOFFitter::kResSlopeX, MuonResiduals6DOFFitter::kResSlopeY, m_fitterOrder, m_indexes, m_tree_row, m_ttree, DetId::Muon, MuonResidualsFitter::MuonAlignmentTreeRow::pos_x, MuonResidualsFitter::MuonAlignmentTreeRow::pos_y, MuonResidualsFitter::MuonAlignmentTreeRow::pt, MuonResidualsFitter::MuonAlignmentTreeRow::pz, MuonResidualsFitter::MuonAlignmentTreeRow::q, MuonResidualsFitter::MuonAlignmentTreeRow::res_slope_x, MuonResidualsFitter::MuonAlignmentTreeRow::res_slope_y, MuonResidualsFitter::MuonAlignmentTreeRow::res_x, MuonResidualsFitter::MuonAlignmentTreeRow::res_y, MuonResidualsTwoBin::residualsPos_begin(), MuonResidualsTwoBin::residualsPos_end(), MuonResidualsTwoBin::residualsPos_ok_begin(), relativeConstraints::ring, MuonResidualsFitter::MuonAlignmentTreeRow::ring_wheel, MuonResidualsFitter::MuonAlignmentTreeRow::sector, MuonResidualsFitter::MuonAlignmentTreeRow::select, relativeConstraints::station, MuonResidualsFitter::MuonAlignmentTreeRow::station, DetId::subdetId(), and MuonResidualsTwoBin::type().

Referenced by terminate().

{
  // WARNING: does not support two bin option!!!

  for (std::vector<unsigned int>::const_iterator index = m_indexes.begin();  index != m_indexes.end();  ++index)
  {
    DetId detid(*index);
    if (detid.det() != DetId::Muon || !( detid.subdetId() == MuonSubdetId::DT || detid.subdetId() == MuonSubdetId::CSC) ) assert(false);

    if(detid.subdetId() == MuonSubdetId::DT)
    {
      m_tree_row.is_dt = (Bool_t) true;
      DTChamberId id(*index);
      m_tree_row.is_plus = (Bool_t) true;
      m_tree_row.station = (UChar_t) id.station();
      m_tree_row.ring_wheel = (Char_t) id.wheel();
      m_tree_row.sector = (UChar_t) id.sector();
    }
    else
    {
      m_tree_row.is_dt = (Bool_t) false;
      CSCDetId id(*index);
      m_tree_row.is_plus = (Bool_t) (id.endcap() == 1);
      m_tree_row.station = (UChar_t) id.station();
      m_tree_row.ring_wheel = (Char_t) id.ring();
      m_tree_row.sector = (UChar_t) id.chamber();
    }

    MuonResidualsTwoBin *fitter = m_fitterOrder[*index];

    std::vector<double*>::const_iterator residual = fitter->residualsPos_begin();
    std::vector<bool>::const_iterator residual_ok = fitter->residualsPos_ok_begin();
    for (;  residual != fitter->residualsPos_end();  ++residual, ++residual_ok)
    {
      if (fitter->type() == MuonResidualsFitter::k5DOF || fitter->type() == MuonResidualsFitter::k6DOFrphi)
      {
        m_tree_row.res_x       = (Float_t) (*residual)[MuonResiduals5DOFFitter::kResid];
        m_tree_row.res_y       = (Float_t) 0.;
        m_tree_row.res_slope_x = (Float_t) (*residual)[MuonResiduals5DOFFitter::kResSlope];
        m_tree_row.res_slope_y = (Float_t) 0.;
        m_tree_row.pos_x       = (Float_t) (*residual)[MuonResiduals5DOFFitter::kPositionX];
        m_tree_row.pos_y       = (Float_t) (*residual)[MuonResiduals5DOFFitter::kPositionY];
        m_tree_row.angle_x     = (Float_t) (*residual)[MuonResiduals5DOFFitter::kAngleX];
        m_tree_row.angle_y     = (Float_t) (*residual)[MuonResiduals5DOFFitter::kAngleY];
        m_tree_row.pz          = (Float_t) (*residual)[MuonResiduals5DOFFitter::kPz];
        m_tree_row.pt          = (Float_t) (*residual)[MuonResiduals5DOFFitter::kPt];
        m_tree_row.q           = (Char_t) (*residual)[MuonResiduals5DOFFitter::kCharge];
        m_tree_row.select      = (Bool_t) *residual_ok;
      }
      else if (fitter->type() == MuonResidualsFitter::k6DOF)
      {
        m_tree_row.res_x       = (Float_t) (*residual)[MuonResiduals6DOFFitter::kResidX];
        m_tree_row.res_y       = (Float_t) (*residual)[MuonResiduals6DOFFitter::kResidY];
        m_tree_row.res_slope_x = (Float_t) (*residual)[MuonResiduals6DOFFitter::kResSlopeX];
        m_tree_row.res_slope_y = (Float_t) (*residual)[MuonResiduals6DOFFitter::kResSlopeY];
        m_tree_row.pos_x       = (Float_t) (*residual)[MuonResiduals6DOFFitter::kPositionX];
        m_tree_row.pos_y       = (Float_t) (*residual)[MuonResiduals6DOFFitter::kPositionY];
        m_tree_row.angle_x     = (Float_t) (*residual)[MuonResiduals6DOFFitter::kAngleX];
        m_tree_row.angle_y     = (Float_t) (*residual)[MuonResiduals6DOFFitter::kAngleY];
        m_tree_row.pz          = (Float_t) (*residual)[MuonResiduals6DOFFitter::kPz];
        m_tree_row.pt          = (Float_t) (*residual)[MuonResiduals6DOFFitter::kPt];
        m_tree_row.q           = (Char_t) (*residual)[MuonResiduals6DOFFitter::kCharge];
        m_tree_row.select      = (Bool_t) *residual_ok;
      }
      else assert(false);

      m_ttree->Fill();
    }
  }
}
void MuonAlignmentFromReference::fitAndAlign ( ) [private]

Definition at line 933 of file MuonAlignmentFromReference.cc.

References AlignmentParameterStore::applyParameters(), CSCDetId::chamber(), AlignmentParameters::cloneFromSelected(), gather_cfg::cout, MuonSubdetId::CSC, GeomDetEnumerators::DT, CSCDetId::endcap(), i, MuonResidualsFitter::k5DOF, MuonResidualsFitter::k6DOF, MuonResidualsFitter::k6DOFrphi, MuonResiduals5DOFFitter::kAlignPhiX, MuonResiduals6DOFFitter::kAlignPhiX, MuonResiduals6DOFrphiFitter::kAlignPhiX, MuonResiduals5DOFFitter::kAlignPhiY, MuonResiduals6DOFFitter::kAlignPhiY, MuonResiduals6DOFrphiFitter::kAlignPhiY, MuonResiduals5DOFFitter::kAlignPhiZ, MuonResiduals6DOFFitter::kAlignPhiZ, MuonResiduals6DOFrphiFitter::kAlignPhiZ, MuonResiduals6DOFrphiFitter::kAlignX, MuonResiduals5DOFFitter::kAlignX, MuonResiduals6DOFFitter::kAlignX, MuonResiduals6DOFrphiFitter::kAlignY, MuonResiduals6DOFFitter::kAlignY, MuonResiduals5DOFFitter::kAlignZ, MuonResiduals6DOFFitter::kAlignZ, MuonResiduals6DOFrphiFitter::kAlignZ, MuonResidualsFitter::kGaussPowerTails, MuonResidualsFitter::kPureGaussian, MuonResidualsFitter::kPureGaussian2D, MuonResiduals5DOFFitter::kRedChi2, MuonResiduals6DOFFitter::kRedChi2, MuonResiduals6DOFrphiFitter::kRedChi2, MuonResiduals5DOFFitter::kResid, MuonResiduals6DOFrphiFitter::kResid, MuonResiduals5DOFFitter::kResidGamma, MuonResiduals6DOFrphiFitter::kResidGamma, MuonResiduals6DOFrphiFitter::kResidSigma, MuonResiduals5DOFFitter::kResidSigma, MuonResiduals6DOFFitter::kResidX, MuonResiduals6DOFFitter::kResidXGamma, MuonResiduals6DOFFitter::kResidXSigma, MuonResiduals6DOFFitter::kResidY, MuonResiduals6DOFFitter::kResidYGamma, MuonResiduals6DOFFitter::kResidYSigma, MuonResiduals5DOFFitter::kResSlope, MuonResiduals6DOFrphiFitter::kResSlope, MuonResiduals5DOFFitter::kResSlopeGamma, MuonResiduals6DOFrphiFitter::kResSlopeGamma, MuonResiduals6DOFrphiFitter::kResSlopeSigma, MuonResiduals5DOFFitter::kResSlopeSigma, MuonResiduals6DOFFitter::kResSlopeX, MuonResiduals6DOFFitter::kResSlopeXGamma, MuonResiduals6DOFFitter::kResSlopeXSigma, MuonResiduals6DOFFitter::kResSlopeY, MuonResiduals6DOFFitter::kResSlopeYGamma, MuonResiduals6DOFFitter::kResSlopeYSigma, m_alignables, m_alignmentParameterStore, m_combineME11, m_fitters, m_me11map, m_minAlignmentHits, m_reportFileName, zeeHLT_cff::report, CSCDetId::ring(), DTChamberId::sector(), AlignmentParameterStore::setAlignmentPositionError(), CSCDetId::station(), DTChamberId::station(), AlCaHLTBitMon_QueryRunRegistry::string, and DTChamberId::wheel().

Referenced by terminate().

{
  edm::Service<TFileService> tfileService;
  TFileDirectory rootDirectory(tfileService->mkdir("MuonAlignmentFromReference"));

  std::ofstream report;
  bool writeReport = (m_reportFileName != std::string(""));
  if (writeReport)
  {
    report.open(m_reportFileName.c_str());
    report << "nan = None;  NAN = None" << std::endl;
    report << "reports = []" << std::endl;
    report << "class ValErr:" << std::endl
           << "    def __init__(self, value, error, antisym):" << std::endl
           << "        self.value, self.error, self.antisym = value, error, antisym" << std::endl
           << "" << std::endl
           << "    def __repr__(self):" << std::endl
           << "        if self.antisym == 0.:" << std::endl
           << "            return \"%g +- %g\" % (self.value, self.error)" << std::endl
           << "        else:" << std::endl
           << "            return \"%g +- %g ~ %g\" % (self.value, self.error, self.antisym)" << std::endl
           << "" << std::endl
           << "class Report:" << std::endl
           << "    def __init__(self, chamberId, postal_address, name):" << std::endl
           << "        self.chamberId, self.postal_address, self.name = chamberId, postal_address, name" << std::endl
           << "        self.status = \"NOFIT\"" << std::endl
           << "        self.fittype = None" << std::endl
           << "" << std::endl
           << "    def add_parameters(self, deltax, deltay, deltaz, deltaphix, deltaphiy, deltaphiz, loglikelihood, numsegments, sumofweights, redchi2):" << std::endl
           << "        self.status = \"PASS\"" << std::endl
           << "        self.deltax, self.deltay, self.deltaz, self.deltaphix, self.deltaphiy, self.deltaphiz = deltax, deltay, deltaz, deltaphix, deltaphiy, deltaphiz" << std::endl
           << "        self.loglikelihood, self.numsegments, self.sumofweights, self.redchi2 = loglikelihood, numsegments, sumofweights, redchi2" << std::endl
           << "" << std::endl
           << "    def add_stats(self, median_x, median_y, median_dxdz, median_dydz, mean30_x, mean30_y, mean20_dxdz, mean50_dydz, mean15_x, mean15_y, mean10_dxdz, mean25_dydz, wmean30_x, wmean30_y, wmean20_dxdz, wmean50_dydz, wmean15_x, wmean15_y, wmean10_dxdz, wmean25_dydz, stdev30_x, stdev30_y, stdev20_dxdz, stdev50_dydz, stdev15_x, stdev15_y, stdev10_dxdz, stdev25_dydz):" << std::endl
           << "        self.median_x, self.median_y, self.median_dxdz, self.median_dydz, self.mean30_x, self.mean30_y, self.mean20_dxdz, self.mean50_dydz, self.mean15_x, self.mean15_y, self.mean10_dxdz, self.mean25_dydz, self.wmean30_x, self.wmean30_y, self.wmean20_dxdz, self.wmean50_dydz, self.wmean15_x, self.wmean15_y, self.wmean10_dxdz, self.wmean25_dydz, self.stdev30_x, self.stdev30_y, self.stdev20_dxdz, self.stdev50_dydz, self.stdev15_x, self.stdev15_y, self.stdev10_dxdz, self.stdev25_dydz = median_x, median_y, median_dxdz, median_dydz, mean30_x, mean30_y, mean20_dxdz, mean50_dydz, mean15_x, mean15_y, mean10_dxdz, mean25_dydz, wmean30_x, wmean30_y, wmean20_dxdz, wmean50_dydz, wmean15_x, wmean15_y, wmean10_dxdz, wmean25_dydz, stdev30_x, stdev30_y, stdev20_dxdz, stdev50_dydz, stdev15_x, stdev15_y, stdev10_dxdz, stdev25_dydz" << std::endl
           << "" << std::endl
           << "    def __repr__(self):" << std::endl
           << "        return \"<Report %s %s %s>\" % (self.postal_address[0], \" \".join(map(str, self.postal_address[1:])), self.status)"<< std::endl
           << std::endl;
  }

  for (std::vector<Alignable*>::const_iterator ali = m_alignables.begin(); ali != m_alignables.end(); ++ali)
  {
    std::vector<bool> selector = (*ali)->alignmentParameters()->selector();
    bool align_x = selector[0];
    bool align_y = selector[1];
    bool align_z = selector[2];
    bool align_phix = selector[3];
    bool align_phiy = selector[4];
    bool align_phiz = selector[5];
    int numParams = ((align_x ? 1 : 0) + (align_y ? 1 : 0) + (align_z ? 1 : 0) + (align_phix ? 1 : 0) + (align_phiy ? 1 : 0) + (align_phiz ? 1 : 0));

    // map from 0-5 to the index of params, above
    std::vector<int> paramIndex;
    int paramIndex_counter = -1;
    if (align_x) paramIndex_counter++;
    paramIndex.push_back(paramIndex_counter);
    if (align_y) paramIndex_counter++;
    paramIndex.push_back(paramIndex_counter);
    if (align_z) paramIndex_counter++;
    paramIndex.push_back(paramIndex_counter);
    if (align_phix) paramIndex_counter++;
    paramIndex.push_back(paramIndex_counter);
    if (align_phiy) paramIndex_counter++;
    paramIndex.push_back(paramIndex_counter);
    if (align_phiz) paramIndex_counter++;
    paramIndex.push_back(paramIndex_counter);

    DetId id = (*ali)->geomDetId();

    Alignable *thisali = *ali;
    if (m_combineME11 && id.subdetId() == MuonSubdetId::CSC)
    {
      CSCDetId cscid(id.rawId());
      if (cscid.station() == 1 && cscid.ring() == 4)   thisali = m_me11map[*ali];
    }

    char cname[40];
    char wheel_label[][2]={"A","B","C","D","E"};
    
    if (id.subdetId() == MuonSubdetId::DT)
    {
      DTChamberId chamberId(id.rawId());

      //if ( ! ( (chamberId.station()==1&&chamberId.wheel()==0) || (chamberId.station()==4&&chamberId.wheel()==2) ) ) continue;
      
      sprintf(cname, "MBwh%sst%dsec%02d", wheel_label[chamberId.wheel()+2], chamberId.station(), chamberId.sector());
      if (writeReport)
      {
        report << "reports.append(Report(" << id.rawId() << ", (\"DT\", "
            << chamberId.wheel() << ", " << chamberId.station() << ", " << chamberId.sector() << "), \"" << cname << "\"))" << std::endl;
      }
    }
    else if (id.subdetId() == MuonSubdetId::CSC)
    {
      CSCDetId chamberId(id.rawId());
      sprintf(cname, "ME%s%d%d_%02d", (chamberId.endcap() == 1 ? "p" : "m"), chamberId.station(), chamberId.ring(), chamberId.chamber());

      //if ( chamberId.chamber()>6 || chamberId.endcap()==2 || ! ( (chamberId.station()==2&&chamberId.ring()==1) || (chamberId.station()==3&&chamberId.ring()==2) ) ) continue;

      if (writeReport)
      {
        report << "reports.append(Report(" << id.rawId() << ", (\"CSC\", "
            << chamberId.endcap() << ", " << chamberId.station() << ", " << chamberId.ring() << ", " << chamberId.chamber()
            << "), \"" << cname << "\"))" << std::endl;
      }
    }

    //if(! ( strcmp(cname,"MBwhCst3sec12")==0 || strcmp(cname,"MBwhCst3sec06")==0)) continue;

    std::map<Alignable*, MuonResidualsTwoBin*>::const_iterator fitter = m_fitters.find(thisali);

    if (fitter != m_fitters.end())
    {
      //if (fitter->second->type() != MuonResidualsFitter::k6DOFrphi) continue;
      
      TStopwatch stop_watch;
      stop_watch.Start();

      // MINUIT is verbose in std::cout anyway
      std::cout << "=============================================================================================" << std::endl;
      std::cout << "Fitting " << cname << std::endl;

      if (writeReport)
      {
        report << "reports[-1].posNum = " << fitter->second->numResidualsPos() << std::endl;
        report << "reports[-1].negNum = " << fitter->second->numResidualsNeg() << std::endl;
      }

      if (fitter->second->type() == MuonResidualsFitter::k5DOF)
      {
        if (!align_x) fitter->second->fix(MuonResiduals5DOFFitter::kAlignX);
        if (!align_z) fitter->second->fix(MuonResiduals5DOFFitter::kAlignZ);
        if (!align_phix) fitter->second->fix(MuonResiduals5DOFFitter::kAlignPhiX);
        if (!align_phiy) fitter->second->fix(MuonResiduals5DOFFitter::kAlignPhiY);
        if (!align_phiz) fitter->second->fix(MuonResiduals5DOFFitter::kAlignPhiZ);
      }
      else if (fitter->second->type() == MuonResidualsFitter::k6DOF)
      {
        if (!align_x) fitter->second->fix(MuonResiduals6DOFFitter::kAlignX);
        if (!align_y) fitter->second->fix(MuonResiduals6DOFFitter::kAlignY);
        if (!align_z) fitter->second->fix(MuonResiduals6DOFFitter::kAlignZ);
        if (!align_phix) fitter->second->fix(MuonResiduals6DOFFitter::kAlignPhiX);
        if (!align_phiy) fitter->second->fix(MuonResiduals6DOFFitter::kAlignPhiY);
        if (!align_phiz) fitter->second->fix(MuonResiduals6DOFFitter::kAlignPhiZ);
      }
      else if (fitter->second->type() == MuonResidualsFitter::k6DOFrphi)
      {
        if (!align_x) fitter->second->fix(MuonResiduals6DOFrphiFitter::kAlignX);
        if (!align_y) fitter->second->fix(MuonResiduals6DOFrphiFitter::kAlignY);
        if (!align_z) fitter->second->fix(MuonResiduals6DOFrphiFitter::kAlignZ);
        if (!align_phix) fitter->second->fix(MuonResiduals6DOFrphiFitter::kAlignPhiX);
        if (!align_phiy) fitter->second->fix(MuonResiduals6DOFrphiFitter::kAlignPhiY);
        if (!align_phiz) fitter->second->fix(MuonResiduals6DOFrphiFitter::kAlignPhiZ);
      }
      else  assert(false);

      AlgebraicVector params(numParams);
      AlgebraicSymMatrix cov(numParams);

      if (fitter->second->numsegments() >= m_minAlignmentHits)
      {
        bool successful_fit = fitter->second->fit(thisali);

        double loglikelihood = fitter->second->loglikelihood();
        double numsegments = fitter->second->numsegments();
        double sumofweights = fitter->second->sumofweights();
        double redchi2 = fitter->second->plot(cname, &rootDirectory, thisali);

        if (fitter->second->type() == MuonResidualsFitter::k5DOF)
        {
          double deltax_value = fitter->second->value(MuonResiduals5DOFFitter::kAlignX);
          double deltax_error = fitter->second->errorerror(MuonResiduals5DOFFitter::kAlignX);
          double deltax_antisym = fitter->second->antisym(MuonResiduals5DOFFitter::kAlignX);

          double deltaz_value = fitter->second->value(MuonResiduals5DOFFitter::kAlignZ);
          double deltaz_error = fitter->second->errorerror(MuonResiduals5DOFFitter::kAlignZ);
          double deltaz_antisym = fitter->second->antisym(MuonResiduals5DOFFitter::kAlignZ);

          double deltaphix_value = fitter->second->value(MuonResiduals5DOFFitter::kAlignPhiX);
          double deltaphix_error = fitter->second->errorerror(MuonResiduals5DOFFitter::kAlignPhiX);
          double deltaphix_antisym = fitter->second->antisym(MuonResiduals5DOFFitter::kAlignPhiX);

          double deltaphiy_value = fitter->second->value(MuonResiduals5DOFFitter::kAlignPhiY);
          double deltaphiy_error = fitter->second->errorerror(MuonResiduals5DOFFitter::kAlignPhiY);
          double deltaphiy_antisym = fitter->second->antisym(MuonResiduals5DOFFitter::kAlignPhiY);

          double deltaphiz_value = fitter->second->value(MuonResiduals5DOFFitter::kAlignPhiZ);
          double deltaphiz_error = fitter->second->errorerror(MuonResiduals5DOFFitter::kAlignPhiZ);
          double deltaphiz_antisym = fitter->second->antisym(MuonResiduals5DOFFitter::kAlignPhiZ);

          double sigmaresid_value = fitter->second->value(MuonResiduals5DOFFitter::kResidSigma);
          double sigmaresid_error = fitter->second->errorerror(MuonResiduals5DOFFitter::kResidSigma);
          double sigmaresid_antisym = fitter->second->antisym(MuonResiduals5DOFFitter::kResidSigma);

          double sigmaresslope_value = fitter->second->value(MuonResiduals5DOFFitter::kResSlopeSigma);
          double sigmaresslope_error = fitter->second->errorerror(MuonResiduals5DOFFitter::kResSlopeSigma);
          double sigmaresslope_antisym = fitter->second->antisym(MuonResiduals5DOFFitter::kResSlopeSigma);

          double gammaresid_value, gammaresid_error, gammaresid_antisym, gammaresslope_value, gammaresslope_error, gammaresslope_antisym;
          gammaresid_value = gammaresid_error = gammaresid_antisym = gammaresslope_value = gammaresslope_error = gammaresslope_antisym = 0.;

          if (fitter->second->residualsModel() != MuonResidualsFitter::kPureGaussian &&
              fitter->second->residualsModel() != MuonResidualsFitter::kPureGaussian2D &&
              fitter->second->residualsModel() != MuonResidualsFitter::kGaussPowerTails)
          {
            gammaresid_value = fitter->second->value(MuonResiduals5DOFFitter::kResidGamma);
            gammaresid_error = fitter->second->errorerror(MuonResiduals5DOFFitter::kResidGamma);
            gammaresid_antisym = fitter->second->antisym(MuonResiduals5DOFFitter::kResidGamma);

            gammaresslope_value = fitter->second->value(MuonResiduals5DOFFitter::kResSlopeGamma);
            gammaresslope_error = fitter->second->errorerror(MuonResiduals5DOFFitter::kResSlopeGamma);
            gammaresslope_antisym = fitter->second->antisym(MuonResiduals5DOFFitter::kResSlopeGamma);
          }

          if (writeReport)
          {
            report << "reports[-1].fittype = \"5DOF\"" << std::endl;
            report << "reports[-1].add_parameters(ValErr(" << deltax_value << ", " << deltax_error << ", "  << deltax_antisym << "), \\" << std::endl
                   << "                           None, \\" << std::endl
                   << "                           ValErr(" << deltaz_value << ", " << deltaz_error << ", " << deltaz_antisym << "), \\" << std::endl
                   << "                           ValErr(" << deltaphix_value << ", " << deltaphix_error << ", " << deltaphix_antisym << "), \\" << std::endl
                   << "                           ValErr(" << deltaphiy_value << ", " << deltaphiy_error << ", " << deltaphiy_antisym << "), \\" << std::endl
                   << "                           ValErr(" << deltaphiz_value << ", " << deltaphiz_error << ", " << deltaphiz_antisym << "), \\" << std::endl
                   << "                           " << loglikelihood << ", " << numsegments << ", " << sumofweights << ", " << redchi2 << ")" << std::endl;
            report << "reports[-1].sigmaresid = ValErr(" << sigmaresid_value << ", " << sigmaresid_error << ", "  << sigmaresid_antisym << ")" << std::endl;
            report << "reports[-1].sigmaresslope = ValErr(" << sigmaresslope_value << ", " << sigmaresslope_error << ", " << sigmaresslope_antisym << ")" << std::endl;
            if (fitter->second->residualsModel() != MuonResidualsFitter::kPureGaussian &&
                fitter->second->residualsModel() != MuonResidualsFitter::kPureGaussian2D &&
                fitter->second->residualsModel() != MuonResidualsFitter::kGaussPowerTails)
            {
              report << "reports[-1].gammaresid = ValErr(" << gammaresid_value << ", " << gammaresid_error << ", " << gammaresid_antisym << ")" << std::endl;
              report << "reports[-1].gammaresslope = ValErr(" << gammaresslope_value << ", " << gammaresslope_error << ", " << gammaresslope_antisym << ")" << std::endl;
            }

            report << "reports[-1].add_stats(" << fitter->second->median(MuonResiduals5DOFFitter::kResid) << ", " << "None, "
                << fitter->second->median(MuonResiduals5DOFFitter::kResSlope) << ", " << "None, "
                << fitter->second->mean(MuonResiduals5DOFFitter::kResid, 30.) << ", " << "None, "
                << fitter->second->mean(MuonResiduals5DOFFitter::kResSlope, 20.) << ", " << "None, "
                << fitter->second->mean(MuonResiduals5DOFFitter::kResid, 15.) << ", " << "None, "
                << fitter->second->mean(MuonResiduals5DOFFitter::kResSlope, 10.) << ", " << "None, "
                << fitter->second->wmean(MuonResiduals5DOFFitter::kResid, MuonResiduals5DOFFitter::kRedChi2, 30.) << ", " << "None, "
                << fitter->second->wmean(MuonResiduals5DOFFitter::kResSlope, MuonResiduals5DOFFitter::kRedChi2, 20.) << ", " << "None, "
                << fitter->second->wmean(MuonResiduals5DOFFitter::kResid, MuonResiduals5DOFFitter::kRedChi2, 15.) << ", " << "None, "
                << fitter->second->wmean(MuonResiduals5DOFFitter::kResSlope, MuonResiduals5DOFFitter::kRedChi2, 10.) << ", " << "None, "
                << fitter->second->stdev(MuonResiduals5DOFFitter::kResid, 30.) << ", " << "None, "
                << fitter->second->stdev(MuonResiduals5DOFFitter::kResSlope, 20.) << ", " << "None, "
                << fitter->second->stdev(MuonResiduals5DOFFitter::kResid, 15.) << ", " << "None, "
                << fitter->second->stdev(MuonResiduals5DOFFitter::kResSlope, 10.) << ", " << "None)" << std::endl;

            std::stringstream namesimple_x, namesimple_dxdz, nameweighted_x, nameweighted_dxdz;
            namesimple_x << cname << "_simple_x";
            namesimple_dxdz << cname << "_simple_dxdz";
            nameweighted_x << cname << "_weighted_x";
            nameweighted_dxdz << cname << "_weighted_dxdz";

            fitter->second->plotsimple(namesimple_x.str(), &rootDirectory, MuonResiduals5DOFFitter::kResid, 10.);
            fitter->second->plotsimple(namesimple_dxdz.str(), &rootDirectory, MuonResiduals5DOFFitter::kResSlope, 1000.);

            fitter->second->plotweighted(nameweighted_x.str(), &rootDirectory, MuonResiduals5DOFFitter::kResid, MuonResiduals5DOFFitter::kRedChi2, 10.);
            fitter->second->plotweighted(nameweighted_dxdz.str(), &rootDirectory, MuonResiduals5DOFFitter::kResSlope, MuonResiduals5DOFFitter::kRedChi2, 1000.);
          }

          if (successful_fit)
          {
            if (align_x) params[paramIndex[0]] = deltax_value;
            if (align_z) params[paramIndex[2]] = deltaz_value;
            if (align_phix) params[paramIndex[3]] = deltaphix_value;
            if (align_phiy) params[paramIndex[4]] = deltaphiy_value;
            if (align_phiz) params[paramIndex[5]] = deltaphiz_value;
          }
        } // end if 5DOF

        else if (fitter->second->type() == MuonResidualsFitter::k6DOF)
        {
          double deltax_value = fitter->second->value(MuonResiduals6DOFFitter::kAlignX);
          double deltax_error = fitter->second->errorerror(MuonResiduals6DOFFitter::kAlignX);
          double deltax_antisym = fitter->second->antisym(MuonResiduals6DOFFitter::kAlignX);

          double deltay_value = fitter->second->value(MuonResiduals6DOFFitter::kAlignY);
          double deltay_error = fitter->second->errorerror(MuonResiduals6DOFFitter::kAlignY);
          double deltay_antisym = fitter->second->antisym(MuonResiduals6DOFFitter::kAlignY);

          double deltaz_value = fitter->second->value(MuonResiduals6DOFFitter::kAlignZ);
          double deltaz_error = fitter->second->errorerror(MuonResiduals6DOFFitter::kAlignZ);
          double deltaz_antisym = fitter->second->antisym(MuonResiduals6DOFFitter::kAlignZ);

          double deltaphix_value = fitter->second->value(MuonResiduals6DOFFitter::kAlignPhiX);
          double deltaphix_error = fitter->second->errorerror(MuonResiduals6DOFFitter::kAlignPhiX);
          double deltaphix_antisym = fitter->second->antisym(MuonResiduals6DOFFitter::kAlignPhiX);

          double deltaphiy_value = fitter->second->value(MuonResiduals6DOFFitter::kAlignPhiY);
          double deltaphiy_error = fitter->second->errorerror(MuonResiduals6DOFFitter::kAlignPhiY);
          double deltaphiy_antisym = fitter->second->antisym(MuonResiduals6DOFFitter::kAlignPhiY);

          double deltaphiz_value = fitter->second->value(MuonResiduals6DOFFitter::kAlignPhiZ);
          double deltaphiz_error = fitter->second->errorerror(MuonResiduals6DOFFitter::kAlignPhiZ);
          double deltaphiz_antisym = fitter->second->antisym(MuonResiduals6DOFFitter::kAlignPhiZ);

          double sigmax_value = fitter->second->value(MuonResiduals6DOFFitter::kResidXSigma);
          double sigmax_error = fitter->second->errorerror(MuonResiduals6DOFFitter::kResidXSigma);
          double sigmax_antisym = fitter->second->antisym(MuonResiduals6DOFFitter::kResidXSigma);

          double sigmay_value = fitter->second->value(MuonResiduals6DOFFitter::kResidYSigma);
          double sigmay_error = fitter->second->errorerror(MuonResiduals6DOFFitter::kResidYSigma);
          double sigmay_antisym = fitter->second->antisym(MuonResiduals6DOFFitter::kResidYSigma);

          double sigmadxdz_value = fitter->second->value(MuonResiduals6DOFFitter::kResSlopeXSigma);
          double sigmadxdz_error = fitter->second->errorerror(MuonResiduals6DOFFitter::kResSlopeXSigma);
          double sigmadxdz_antisym = fitter->second->antisym(MuonResiduals6DOFFitter::kResSlopeXSigma);

          double sigmadydz_value = fitter->second->value(MuonResiduals6DOFFitter::kResSlopeYSigma);
          double sigmadydz_error = fitter->second->errorerror(MuonResiduals6DOFFitter::kResSlopeYSigma);
          double sigmadydz_antisym = fitter->second->antisym(MuonResiduals6DOFFitter::kResSlopeYSigma);

          double gammax_value, gammax_error, gammax_antisym, gammay_value, gammay_error, gammay_antisym,
              gammadxdz_value, gammadxdz_error, gammadxdz_antisym, gammadydz_value, gammadydz_error, gammadydz_antisym;
          gammax_value = gammax_error = gammax_antisym = gammay_value = gammay_error = gammay_antisym = gammadxdz_value
              = gammadxdz_error = gammadxdz_antisym = gammadydz_value = gammadydz_error = gammadydz_antisym = 0.;
          if (fitter->second->residualsModel() != MuonResidualsFitter::kPureGaussian &&
              fitter->second->residualsModel() != MuonResidualsFitter::kPureGaussian2D &&
              fitter->second->residualsModel() != MuonResidualsFitter::kGaussPowerTails)
          {
            gammax_value = fitter->second->value(MuonResiduals6DOFFitter::kResidXGamma);
            gammax_error = fitter->second->errorerror(MuonResiduals6DOFFitter::kResidXGamma);
            gammax_antisym = fitter->second->antisym(MuonResiduals6DOFFitter::kResidXGamma);

            gammay_value = fitter->second->value(MuonResiduals6DOFFitter::kResidYGamma);
            gammay_error = fitter->second->errorerror(MuonResiduals6DOFFitter::kResidYGamma);
            gammay_antisym = fitter->second->antisym(MuonResiduals6DOFFitter::kResidYGamma);

            gammadxdz_value = fitter->second->value(MuonResiduals6DOFFitter::kResSlopeXGamma);
            gammadxdz_error = fitter->second->errorerror(MuonResiduals6DOFFitter::kResSlopeXGamma);
            gammadxdz_antisym = fitter->second->antisym(MuonResiduals6DOFFitter::kResSlopeXGamma);

            gammadydz_value = fitter->second->value(MuonResiduals6DOFFitter::kResSlopeYGamma);
            gammadydz_error = fitter->second->errorerror(MuonResiduals6DOFFitter::kResSlopeYGamma);
            gammadydz_antisym = fitter->second->antisym(MuonResiduals6DOFFitter::kResSlopeYGamma);
          }

          if (writeReport)
          {
            report << "reports[-1].fittype = \"6DOF\"" << std::endl;
            report << "reports[-1].add_parameters(ValErr(" << deltax_value << ", " << deltax_error << ", " << deltax_antisym << "), \\" << std::endl
                << "                           ValErr(" << deltay_value << ", " << deltay_error << ", " << deltay_antisym << "), \\" << std::endl
                << "                           ValErr(" << deltaz_value << ", " << deltaz_error << ", " << deltaz_antisym << "), \\" << std::endl
                << "                           ValErr(" << deltaphix_value << ", " << deltaphix_error << ", " << deltaphix_antisym << "), \\" << std::endl
                << "                           ValErr(" << deltaphiy_value << ", " << deltaphiy_error << ", " << deltaphiy_antisym << "), \\" << std::endl
                << "                           ValErr(" << deltaphiz_value << ", " << deltaphiz_error << ", " << deltaphiz_antisym << "), \\" << std::endl
                << "                           " << loglikelihood << ", " << numsegments << ", " << sumofweights << ", " << redchi2 << ")" << std::endl;
            report << "reports[-1].sigmax = ValErr(" << sigmax_value << ", " << sigmax_error << ", " << sigmax_antisym<< ")" << std::endl;
            report << "reports[-1].sigmay = ValErr(" << sigmay_value << ", " << sigmay_error << ", " << sigmay_antisym<< ")" << std::endl;
            report << "reports[-1].sigmadxdz = ValErr(" << sigmadxdz_value << ", " << sigmadxdz_error << ", "<< sigmadxdz_antisym << ")" << std::endl;
            report << "reports[-1].sigmadydz = ValErr(" << sigmadydz_value << ", " << sigmadydz_error << ", "<< sigmadydz_antisym << ")" << std::endl;
            if (fitter->second->residualsModel() != MuonResidualsFitter::kPureGaussian &&
                fitter->second->residualsModel() != MuonResidualsFitter::kPureGaussian2D &&
                fitter->second->residualsModel() != MuonResidualsFitter::kGaussPowerTails)
            {
              report << "reports[-1].gammax = ValErr(" << gammax_value << ", " << gammax_error << ", " << gammax_antisym << ")" << std::endl;
              report << "reports[-1].gammay = ValErr(" << gammay_value << ", " << gammay_error << ", " << gammay_antisym << ")" << std::endl;
              report << "reports[-1].gammadxdz = ValErr(" << gammadxdz_value << ", " << gammadxdz_error << ", " << gammadxdz_antisym << ")" << std::endl;
              report << "reports[-1].gammadydz = ValErr(" << gammadydz_value << ", " << gammadydz_error << ", " << gammadydz_antisym << ")" << std::endl;
            }

            report << "reports[-1].add_stats("
                << fitter->second->median(MuonResiduals6DOFFitter::kResidX) << ", "
                << fitter->second->median(MuonResiduals6DOFFitter::kResidY) << ", "
                << fitter->second->median(MuonResiduals6DOFFitter::kResSlopeX) << ", "
                << fitter->second->median(MuonResiduals6DOFFitter::kResSlopeY) << ", "
                << fitter->second->mean(MuonResiduals6DOFFitter::kResidX, 30.) << ", "
                << fitter->second->mean(MuonResiduals6DOFFitter::kResidY, 30.) << ", "
                << fitter->second->mean(MuonResiduals6DOFFitter::kResSlopeX, 20.) << ", "
                << fitter->second->mean(MuonResiduals6DOFFitter::kResSlopeY, 50.) << ", "
                << fitter->second->mean(MuonResiduals6DOFFitter::kResidX, 15.) << ", "
                << fitter->second->mean(MuonResiduals6DOFFitter::kResidY, 15.) << ", "
                << fitter->second->mean(MuonResiduals6DOFFitter::kResSlopeX, 10.) << ", "
                << fitter->second->mean(MuonResiduals6DOFFitter::kResSlopeY, 25.) << ", "
                << fitter->second->wmean(MuonResiduals6DOFFitter::kResidX, MuonResiduals6DOFFitter::kRedChi2, 30.) << ", "
                << fitter->second->wmean(MuonResiduals6DOFFitter::kResidY, MuonResiduals6DOFFitter::kRedChi2, 30.) << ", "
                << fitter->second->wmean(MuonResiduals6DOFFitter::kResSlopeX,MuonResiduals6DOFFitter::kRedChi2, 20.) << ", "
                << fitter->second->wmean(MuonResiduals6DOFFitter::kResSlopeY, MuonResiduals6DOFFitter::kRedChi2, 50.) << ", "
                << fitter->second->wmean(MuonResiduals6DOFFitter::kResidX, MuonResiduals6DOFFitter::kRedChi2, 15.) << ", "
                << fitter->second->wmean(MuonResiduals6DOFFitter::kResidY, MuonResiduals6DOFFitter::kRedChi2, 15.) << ", "
                << fitter->second->wmean(MuonResiduals6DOFFitter::kResSlopeX, MuonResiduals6DOFFitter::kRedChi2, 10.) << ", "
                << fitter->second->wmean(MuonResiduals6DOFFitter::kResSlopeY, MuonResiduals6DOFFitter::kRedChi2, 25.) << ", "
                << fitter->second->stdev(MuonResiduals6DOFFitter::kResidX, 30.) << ", "
                << fitter->second->stdev(MuonResiduals6DOFFitter::kResidY, 30.) << ", "
                << fitter->second->stdev(MuonResiduals6DOFFitter::kResSlopeX, 20.) << ", "
                << fitter->second->stdev(MuonResiduals6DOFFitter::kResSlopeY, 50.) << ", "
                << fitter->second->stdev(MuonResiduals6DOFFitter::kResidX, 15.) << ", "
                << fitter->second->stdev(MuonResiduals6DOFFitter::kResidY, 15.) << ", "
                << fitter->second->stdev(MuonResiduals6DOFFitter::kResSlopeX, 10.) << ", "
                << fitter->second->stdev(MuonResiduals6DOFFitter::kResSlopeY, 25.) << ")" << std::endl;

            std::stringstream namesimple_x, namesimple_y, namesimple_dxdz, namesimple_dydz, nameweighted_x,
                nameweighted_y, nameweighted_dxdz, nameweighted_dydz;
            namesimple_x << cname << "_simple_x";
            namesimple_y << cname << "_simple_y";
            namesimple_dxdz << cname << "_simple_dxdz";
            namesimple_dydz << cname << "_simple_dydz";
            nameweighted_x << cname << "_weighted_x";
            nameweighted_y << cname << "_weighted_y";
            nameweighted_dxdz << cname << "_weighted_dxdz";
            nameweighted_dydz << cname << "_weighted_dydz";

            fitter->second->plotsimple(namesimple_x.str(), &rootDirectory, MuonResiduals6DOFFitter::kResidX, 10.);
            fitter->second->plotsimple(namesimple_y.str(), &rootDirectory, MuonResiduals6DOFFitter::kResidY, 10.);
            fitter->second->plotsimple(namesimple_dxdz.str(), &rootDirectory, MuonResiduals6DOFFitter::kResSlopeX, 1000.);
            fitter->second->plotsimple(namesimple_dydz.str(), &rootDirectory, MuonResiduals6DOFFitter::kResSlopeY,1000.);

            fitter->second->plotweighted(nameweighted_x.str(), &rootDirectory, MuonResiduals6DOFFitter::kResidX, MuonResiduals6DOFFitter::kRedChi2, 10.);
            fitter->second->plotweighted(nameweighted_y.str(), &rootDirectory, MuonResiduals6DOFFitter::kResidY, MuonResiduals6DOFFitter::kRedChi2, 10.);
            fitter->second->plotweighted(nameweighted_dxdz.str(), &rootDirectory, MuonResiduals6DOFFitter::kResSlopeX, MuonResiduals6DOFFitter::kRedChi2, 1000.);
            fitter->second->plotweighted(nameweighted_dydz.str(), &rootDirectory, MuonResiduals6DOFFitter::kResSlopeY, MuonResiduals6DOFFitter::kRedChi2, 1000.);
          }

          if (successful_fit)
          {
            if (align_x) params[paramIndex[0]] = deltax_value;
            if (align_y) params[paramIndex[1]] = deltay_value;
            if (align_z) params[paramIndex[2]] = deltaz_value;
            if (align_phix) params[paramIndex[3]] = deltaphix_value;
            if (align_phiy) params[paramIndex[4]] = deltaphiy_value;
            if (align_phiz) params[paramIndex[5]] = deltaphiz_value;
          }
        } // end if 6DOF

        else if (fitter->second->type() == MuonResidualsFitter::k6DOFrphi)
        {
          double deltax_value = fitter->second->value(MuonResiduals6DOFrphiFitter::kAlignX);
          double deltax_error = fitter->second->errorerror(MuonResiduals6DOFrphiFitter::kAlignX);
          double deltax_antisym = fitter->second->antisym(MuonResiduals6DOFrphiFitter::kAlignX);

          double deltay_value = fitter->second->value(MuonResiduals6DOFrphiFitter::kAlignY);
          double deltay_error = fitter->second->errorerror(MuonResiduals6DOFrphiFitter::kAlignY);
          double deltay_antisym = fitter->second->antisym(MuonResiduals6DOFrphiFitter::kAlignY);

          double deltaz_value = fitter->second->value(MuonResiduals6DOFrphiFitter::kAlignZ);
          double deltaz_error = fitter->second->errorerror(MuonResiduals6DOFrphiFitter::kAlignZ);
          double deltaz_antisym = fitter->second->antisym(MuonResiduals6DOFrphiFitter::kAlignZ);

          double deltaphix_value = fitter->second->value(MuonResiduals6DOFrphiFitter::kAlignPhiX);
          double deltaphix_error = fitter->second->errorerror(MuonResiduals6DOFrphiFitter::kAlignPhiX);
          double deltaphix_antisym = fitter->second->antisym(MuonResiduals6DOFrphiFitter::kAlignPhiX);

          double deltaphiy_value = fitter->second->value(MuonResiduals6DOFrphiFitter::kAlignPhiY);
          double deltaphiy_error = fitter->second->errorerror(MuonResiduals6DOFrphiFitter::kAlignPhiY);
          double deltaphiy_antisym = fitter->second->antisym(MuonResiduals6DOFrphiFitter::kAlignPhiY);

          double deltaphiz_value = fitter->second->value(MuonResiduals6DOFrphiFitter::kAlignPhiZ);
          double deltaphiz_error = fitter->second->errorerror(MuonResiduals6DOFrphiFitter::kAlignPhiZ);
          double deltaphiz_antisym = fitter->second->antisym(MuonResiduals6DOFrphiFitter::kAlignPhiZ);

          double sigmaresid_value = fitter->second->value(MuonResiduals6DOFrphiFitter::kResidSigma);
          double sigmaresid_error = fitter->second->errorerror(MuonResiduals6DOFrphiFitter::kResidSigma);
          double sigmaresid_antisym = fitter->second->antisym(MuonResiduals6DOFrphiFitter::kResidSigma);

          double sigmaresslope_value = fitter->second->value(MuonResiduals6DOFrphiFitter::kResSlopeSigma);
          double sigmaresslope_error = fitter->second->errorerror(MuonResiduals6DOFrphiFitter::kResSlopeSigma);
          double sigmaresslope_antisym = fitter->second->antisym(MuonResiduals6DOFrphiFitter::kResSlopeSigma);

          double gammaresid_value, gammaresid_error, gammaresid_antisym, gammaresslope_value, gammaresslope_error, gammaresslope_antisym;
          gammaresid_value = gammaresid_error = gammaresid_antisym = gammaresslope_value = gammaresslope_error = gammaresslope_antisym = 0.;
          if (fitter->second->residualsModel() != MuonResidualsFitter::kPureGaussian &&
              fitter->second->residualsModel() != MuonResidualsFitter::kPureGaussian2D &&
              fitter->second->residualsModel() != MuonResidualsFitter::kGaussPowerTails)
          {
            gammaresid_value = fitter->second->value(MuonResiduals6DOFrphiFitter::kResidGamma);
            gammaresid_error = fitter->second->errorerror(MuonResiduals6DOFrphiFitter::kResidGamma);
            gammaresid_antisym = fitter->second->antisym(MuonResiduals6DOFrphiFitter::kResidGamma);

            gammaresslope_value = fitter->second->value(MuonResiduals6DOFrphiFitter::kResSlopeGamma);
            gammaresslope_error = fitter->second->errorerror(MuonResiduals6DOFrphiFitter::kResSlopeGamma);
            gammaresslope_antisym = fitter->second->antisym(MuonResiduals6DOFrphiFitter::kResSlopeGamma);
          }

          if (writeReport)
          {
            report << "reports[-1].fittype = \"6DOFrphi\"" << std::endl;
            report << "reports[-1].add_parameters(ValErr(" << deltax_value << ", " << deltax_error << ", " << deltax_antisym << "), \\" << std::endl
                << "                           ValErr(" << deltay_value << ", " << deltay_error << ", " << deltay_antisym << "), \\" << std::endl
                << "                           ValErr(" << deltaz_value << ", " << deltaz_error << ", " << deltaz_antisym << "), \\" << std::endl
                << "                           ValErr(" << deltaphix_value << ", " << deltaphix_error << ", " << deltaphix_antisym << "), \\" << std::endl
                << "                           ValErr(" << deltaphiy_value << ", " << deltaphiy_error << ", " << deltaphiy_antisym << "), \\" << std::endl
                << "                           ValErr(" << deltaphiz_value << ", " << deltaphiz_error << ", " << deltaphiz_antisym << "), \\" << std::endl
                << "                           " << loglikelihood << ", " << numsegments << ", " << sumofweights << ", " << redchi2 << ")" << std::endl;
            report << "reports[-1].sigmaresid = ValErr(" << sigmaresid_value << ", " << sigmaresid_error << ", " << sigmaresid_antisym << ")" << std::endl;
            report << "reports[-1].sigmaresslope = ValErr(" << sigmaresslope_value << ", " << sigmaresslope_error << ", " << sigmaresslope_antisym << ")" << std::endl;
            if (fitter->second->residualsModel() != MuonResidualsFitter::kPureGaussian &&
                fitter->second->residualsModel() != MuonResidualsFitter::kPureGaussian2D &&
                fitter->second->residualsModel() != MuonResidualsFitter::kGaussPowerTails)
            {
              report << "reports[-1].gammaresid = ValErr(" << gammaresid_value << ", " << gammaresid_error << ", " << gammaresid_antisym << ")" << std::endl;
              report << "reports[-1].gammaresslope = ValErr(" << gammaresslope_value << ", " << gammaresslope_error << ", " << gammaresslope_antisym << ")" << std::endl;
            }

            report << "reports[-1].add_stats(" << fitter->second->median(MuonResiduals6DOFrphiFitter::kResid) << ", " << "None, "
                << fitter->second->median(MuonResiduals6DOFrphiFitter::kResSlope) << ", " << "None, "
                << fitter->second->mean(MuonResiduals6DOFrphiFitter::kResid, 30.) << ", " << "None, "
                << fitter->second->mean(MuonResiduals6DOFrphiFitter::kResSlope, 20.) << ", " << "None, "
                << fitter->second->mean(MuonResiduals6DOFrphiFitter::kResid, 15.) << ", " << "None, "
                << fitter->second->mean(MuonResiduals6DOFrphiFitter::kResSlope, 10.) << ", " << "None, "
                << fitter->second->wmean(MuonResiduals6DOFrphiFitter::kResid, MuonResiduals6DOFrphiFitter::kRedChi2, 30.) << ", " << "None, "
                << fitter->second->wmean(MuonResiduals6DOFrphiFitter::kResSlope, MuonResiduals6DOFrphiFitter::kRedChi2, 20.) << ", " << "None, "
                << fitter->second->wmean(MuonResiduals6DOFrphiFitter::kResid, MuonResiduals6DOFrphiFitter::kRedChi2, 15.) << ", " << "None, "
                << fitter->second->wmean(MuonResiduals6DOFrphiFitter::kResSlope, MuonResiduals6DOFrphiFitter::kRedChi2, 10.) << ", " << "None, "
                << fitter->second->stdev(MuonResiduals6DOFrphiFitter::kResid, 30.) << ", " << "None, "
                << fitter->second->stdev(MuonResiduals6DOFrphiFitter::kResSlope, 20.) << ", " << "None, "
                << fitter->second->stdev(MuonResiduals6DOFrphiFitter::kResid, 15.) << ", " << "None, "
                << fitter->second->stdev(MuonResiduals6DOFrphiFitter::kResSlope, 10.) << ", " << "None)" << std::endl;

            std::stringstream namesimple_x, namesimple_dxdz, nameweighted_x, nameweighted_dxdz;
            namesimple_x << cname << "_simple_x";
            namesimple_dxdz << cname << "_simple_dxdz";
            nameweighted_x << cname << "_weighted_x";
            nameweighted_dxdz << cname << "_weighted_dxdz";

            fitter->second->plotsimple(namesimple_x.str(), &rootDirectory, MuonResiduals6DOFrphiFitter::kResid, 10.);
            fitter->second->plotsimple(namesimple_dxdz.str(), &rootDirectory, MuonResiduals6DOFrphiFitter::kResSlope, 1000.);

            fitter->second->plotweighted(nameweighted_x.str(), &rootDirectory, MuonResiduals6DOFrphiFitter::kResid, MuonResiduals6DOFrphiFitter::kRedChi2, 10.);
            fitter->second->plotweighted(nameweighted_dxdz.str(), &rootDirectory, MuonResiduals6DOFrphiFitter::kResSlope, MuonResiduals6DOFrphiFitter::kRedChi2, 1000.);
          }

          if (successful_fit)
          {
            if (align_x) params[paramIndex[0]] = deltax_value;
            if (align_y) params[paramIndex[1]] = deltay_value;
            if (align_z) params[paramIndex[2]] = deltaz_value;
            if (align_phix) params[paramIndex[3]] = deltaphix_value;
            if (align_phiy) params[paramIndex[4]] = deltaphiy_value;
            if (align_phiz) params[paramIndex[5]] = deltaphiz_value;
          }
        } // end if 6DOFrphi

        if (successful_fit)
        {
          std::vector<Alignable*> oneortwo;
          oneortwo.push_back(*ali);
          if (thisali != *ali) oneortwo.push_back(thisali);
          m_alignmentParameterStore->setAlignmentPositionError(oneortwo, 0., 0.);
        }
        else
        {
          std::cout << "MINUIT fit failed!" << std::endl;
          if (writeReport)
          {
            report << "reports[-1].status = \"MINUITFAIL\"" << std::endl;
          }

          for (int i = 0; i < numParams; i++)  cov[i][i] = 1000.;

          std::vector<Alignable*> oneortwo;
          oneortwo.push_back(*ali);
          if (thisali != *ali) oneortwo.push_back(thisali);
          m_alignmentParameterStore->setAlignmentPositionError(oneortwo, 1000., 0.);
        }
      }
      else
      { // too few hits
        std::cout << "Too few hits!" << std::endl;
        if (writeReport)
        {
          report << "reports[-1].status = \"TOOFEWHITS\"" << std::endl;
        }

        for (int i = 0; i < numParams; i++)  cov[i][i] = 1000.;

        std::vector<Alignable*> oneortwo;
        oneortwo.push_back(*ali);
        if (thisali != *ali) oneortwo.push_back(thisali);
        m_alignmentParameterStore->setAlignmentPositionError(oneortwo, 1000., 0.);
      }

      AlignmentParameters *parnew = (*ali)->alignmentParameters()->cloneFromSelected(params, cov);
      (*ali)->setAlignmentParameters(parnew);
      m_alignmentParameterStore->applyParameters(*ali);
      (*ali)->alignmentParameters()->setValid(true);

      std::cout << cname<<" fittime= "<< stop_watch.CpuTime() << " sec" << std::endl;
    } // end we have a fitter for this alignable

    if (writeReport) report << std::endl;

  } // end loop over alignables

  if (writeReport) report.close();
}
void MuonAlignmentFromReference::initialize ( const edm::EventSetup setup,
AlignableTracker tracker,
AlignableMuon muon,
AlignableExtras extras,
AlignmentParameterStore store 
) [virtual]

Call at beginning of job (must be implemented in derived class)

Implements AlignmentAlgorithmBase.

Definition at line 300 of file MuonAlignmentFromReference.cc.

References align::AlignableCSCChamber, align::AlignableDTChamber, AlignmentParameterStore::alignables(), AlignableMuon::CSCChambers(), AlignableMuon::DTChambers(), Reference_intrackfit_cff::endcap, Exception, edm::EventSetup::get(), getHLTprescales::index, MuonResidualsFitter::k0010, MuonResidualsFitter::k1010, MuonResidualsFitter::k1100, MuonResidualsFitter::k1110, MuonResidualsFitter::k1111, MuonResidualsFitter::kGaussPowerTails, MuonResidualsFitter::kPowerLawTails, MuonResidualsFitter::kPureGaussian, MuonResidualsFitter::kPureGaussian2D, MuonResidualsFitter::kROOTVoigt, m_alignableNavigator, m_alignables, m_alignmentParameterStore, m_combineME11, m_fitterOrder, m_fitters, m_indexes, m_me11map, m_minAlignmentHits, m_reference, m_residualsModel, m_strategy, m_twoBin, m_useResiduals, m_weightAlignment, NULL, parseReference(), DetId::rawId(), RecoTauValidation_cfi::reference, align_cfg::residualsModel, AlignmentParameterStore::setAlignmentPositionError(), python::multivaluedict::sort(), relativeConstraints::station, AlCaHLTBitMon_QueryRunRegistry::string, and align_cfg::useResiduals.

{
   if (alignableMuon == NULL)
     throw cms::Exception("MuonAlignmentFromReference") << "doMuon must be set to True" << std::endl;

   m_alignableNavigator = new AlignableNavigator(alignableMuon);
   m_alignmentParameterStore = alignmentParameterStore;
   m_alignables = m_alignmentParameterStore->alignables();

   int residualsModel;
   if      (m_residualsModel == std::string("pureGaussian"))    residualsModel = MuonResidualsFitter::kPureGaussian;
   else if (m_residualsModel == std::string("pureGaussian2D"))  residualsModel = MuonResidualsFitter::kPureGaussian2D;
   else if (m_residualsModel == std::string("powerLawTails"))   residualsModel = MuonResidualsFitter::kPowerLawTails;
   else if (m_residualsModel == std::string("ROOTVoigt"))       residualsModel = MuonResidualsFitter::kROOTVoigt;
   else if (m_residualsModel == std::string("GaussPowerTails")) residualsModel = MuonResidualsFitter::kGaussPowerTails;
   else throw cms::Exception("MuonAlignmentFromReference") << "unrecognized residualsModel: \"" << m_residualsModel << "\"" << std::endl;

   int useResiduals;
   if      (m_useResiduals == std::string("1111")) useResiduals = MuonResidualsFitter::k1111;
   else if (m_useResiduals == std::string("1110")) useResiduals = MuonResidualsFitter::k1110;
   else if (m_useResiduals == std::string("1100")) useResiduals = MuonResidualsFitter::k1100;
   else if (m_useResiduals == std::string("1010")) useResiduals = MuonResidualsFitter::k1010;
   else if (m_useResiduals == std::string("0010")) useResiduals = MuonResidualsFitter::k0010;
   else throw cms::Exception("MuonAlignmentFromReference") << "unrecognized useResiduals: \"" << m_useResiduals << "\"" << std::endl;

   edm::ESHandle<CSCGeometry> cscGeometry;
   iSetup.get<MuonGeometryRecord>().get(cscGeometry);

   // set up the MuonResidualsFitters (which also collect residuals for fitting)
   m_me11map.clear();
   m_fitters.clear();
   m_indexes.clear();
   m_fitterOrder.clear();

   for (std::vector<Alignable*>::const_iterator ali = m_alignables.begin();  ali != m_alignables.end();  ++ali)
   {
     bool made_fitter = false;

     // fitters for DT
     if ((*ali)->alignableObjectId() == align::AlignableDTChamber)
     {
       DTChamberId id( (*ali)->geomDetId().rawId() );
       
       if (id.station() == 4)
       {
         m_fitters[*ali] =
             new MuonResidualsTwoBin(m_twoBin, new MuonResiduals5DOFFitter(residualsModel, m_minAlignmentHits, useResiduals, m_weightAlignment),
                                               new MuonResiduals5DOFFitter(residualsModel, m_minAlignmentHits, useResiduals, m_weightAlignment));
         made_fitter = true;
       }
       else
       {
         m_fitters[*ali] =
             new MuonResidualsTwoBin(m_twoBin, new MuonResiduals6DOFFitter(residualsModel, m_minAlignmentHits, useResiduals, m_weightAlignment),
                                               new MuonResiduals6DOFFitter(residualsModel, m_minAlignmentHits, useResiduals, m_weightAlignment));
         made_fitter = true;
       }
     }

     // fitters for CSC
     else if ((*ali)->alignableObjectId() == align::AlignableCSCChamber)
     {
       Alignable *thisali = *ali;
       CSCDetId id( (*ali)->geomDetId().rawId() );

       // take care of ME1/1a
       if (m_combineME11  &&  id.station() == 1  &&  id.ring() == 4)
       {
         CSCDetId pairid(id.endcap(), 1, 1, id.chamber());

         for (std::vector<Alignable*>::const_iterator ali2 = m_alignables.begin();  ali2 != m_alignables.end();  ++ali2)
         {
           if ((*ali2)->alignableObjectId() == align::AlignableCSCChamber  &&  (*ali2)->geomDetId().rawId() == pairid.rawId())
           {
             thisali = *ali2;
             break;
           }
         }
         m_me11map[*ali] = thisali;  // points from each ME1/4 chamber to the corresponding ME1/1 chamber
       }

       if (thisali == *ali)   // don't make fitters for ME1/4; they get taken care of in ME1/1
       {
         m_fitters[*ali] =
             new MuonResidualsTwoBin(m_twoBin, new MuonResiduals6DOFrphiFitter(residualsModel, m_minAlignmentHits, useResiduals, &(*cscGeometry), m_weightAlignment),
                                               new MuonResiduals6DOFrphiFitter(residualsModel, m_minAlignmentHits, useResiduals, &(*cscGeometry), m_weightAlignment));
         made_fitter = true;
       }
     }

     else {
       throw cms::Exception("MuonAlignmentFromReference") << "only DTChambers and CSCChambers can be aligned with this module" << std::endl;
     }

     if (made_fitter) {
       m_fitters[*ali]->setStrategy(m_strategy);

       int index = (*ali)->geomDetId().rawId();
       m_indexes.push_back(index);
       m_fitterOrder[index] = m_fitters[*ali];
     }
   } // end loop over chambers chosen for alignment

   // cannonical order of fitters in the file
   std::sort(m_indexes.begin(), m_indexes.end());

   // de-weight all chambers but the reference
   std::vector<Alignable*> all_DT_chambers = alignableMuon->DTChambers();
   std::vector<Alignable*> all_CSC_chambers = alignableMuon->CSCChambers();
   std::vector<Alignable*> reference;
   if (m_reference.size()) parseReference(reference, all_DT_chambers, all_CSC_chambers);
   
   alignmentParameterStore->setAlignmentPositionError(all_DT_chambers, 100000000., 0.);
   alignmentParameterStore->setAlignmentPositionError(all_CSC_chambers, 100000000., 0.);
   alignmentParameterStore->setAlignmentPositionError(reference, 0., 0.);
}
int MuonAlignmentFromReference::number ( std::string  s) [private]

Definition at line 293 of file MuonAlignmentFromReference.cc.

References numeric().

Referenced by parseReference().

{
  if (!numeric(s)) assert(false);
  return atoi(s.c_str());
}
bool MuonAlignmentFromReference::numeric ( std::string  s) [private]

Definition at line 287 of file MuonAlignmentFromReference.cc.

Referenced by number(), and parseReference().

{
  return s.length()==1 && std::isdigit(s[0]);
}
void MuonAlignmentFromReference::parseReference ( std::vector< Alignable * > &  reference,
std::vector< Alignable * > &  all_DT_chambers,
std::vector< Alignable * > &  all_CSC_chambers 
) [private]

Definition at line 422 of file MuonAlignmentFromReference.cc.

References abs, Reference_intrackfit_cff::barrel, Reference_intrackfit_cff::endcap, Exception, getHLTprescales::index, m_reference, mergeVDriftHistosByStation::name, number(), numeric(), reco::HaloData::plus, relativeConstraints::ring, relativeConstraints::station, and AlCaHLTBitMon_QueryRunRegistry::string.

Referenced by initialize().

{
  std::map<Alignable*,bool> already_seen;

  for (std::vector<std::string>::const_iterator name = m_reference.begin();  name != m_reference.end();  ++name)
  {
    bool parsing_error = false;

    bool barrel = (name->substr(0, 2) == std::string("MB"));
    bool endcap = (name->substr(0, 2) == std::string("ME"));
    if (!barrel  &&  !endcap) parsing_error = true;

    if (!parsing_error  &&  barrel)
    {
      int index = 2;
      if (name->substr(index, 1) == std::string(" "))  index++;

      bool plus = true;
      if (name->substr(index, 1) == std::string("+"))
      {
        plus = true;
        index++;
      }
      else if (name->substr(index, 1) == std::string("-"))
      {
        plus = false;
        index++;
      }
      else if (numeric(name->substr(index, 1))) {}
      else parsing_error = true;

      int wheel = 0;
      bool wheel_digit = false;
      while (!parsing_error  &&  numeric(name->substr(index, 1)))
      {
        wheel *= 10;
        wheel += number(name->substr(index, 1));
        wheel_digit = true;
        index++;
      }
      if (!plus) wheel *= -1;
      if (!wheel_digit) parsing_error = true;
      
      if (name->substr(index, 1) != std::string(" ")) parsing_error = true;
      index++;

      int station = 0;
      bool station_digit = false;
      while (!parsing_error  &&  numeric(name->substr(index, 1)))
      {
        station *= 10;
        station += number(name->substr(index, 1));
        station_digit = true;
        index++;
      }
      if (!station_digit) parsing_error = true;

      if (name->substr(index, 1) != std::string(" ")) parsing_error = true;
      index++;

      int sector = 0;
      bool sector_digit = false;
      while (!parsing_error  &&  numeric(name->substr(index, 1)))
      {
        sector *= 10;
        sector += number(name->substr(index, 1));
        sector_digit = true;
        index++;
      }
      if (!sector_digit) parsing_error = true;

      if (!parsing_error)
      {
        bool no_such_chamber = false;

        if (wheel < -2  ||  wheel > 2) no_such_chamber = true;
        if (station < 1  ||  station > 4) no_such_chamber = true;
        if (station == 4  &&  (sector < 1  ||  sector > 14)) no_such_chamber = true;
        if (station < 4  &&  (sector < 1  ||  sector > 12)) no_such_chamber = true;

        if (no_such_chamber)
          throw cms::Exception("MuonAlignmentFromReference") << "reference chamber doesn't exist: " << (*name) << std::endl;

        DTChamberId id(wheel, station, sector);
        for (std::vector<Alignable*>::const_iterator ali = all_DT_chambers.begin();  ali != all_DT_chambers.end();  ++ali)
        {
          if ((*ali)->geomDetId().rawId() == id.rawId())
          {
            std::map<Alignable*,bool>::const_iterator trial = already_seen.find(*ali);
            if (trial == already_seen.end())
            {
              reference.push_back(*ali);
              already_seen[*ali] = true;
            }
          }
        }
      } // if (!parsing_error)
    }
    
    if (!parsing_error  &&  endcap)
    {
      int index = 2;
      if (name->substr(index, 1) == std::string(" "))  index++;

      bool plus = true;
      if (name->substr(index, 1) == std::string("+"))
      {
        plus = true;
        index++;
      }
      else if (name->substr(index, 1) == std::string("-"))
      {
        plus = false;
        index++;
      }
      else if (numeric(name->substr(index, 1))) {}
      else parsing_error = true;

      int station = 0;
      bool station_digit = false;
      while (!parsing_error  &&  numeric(name->substr(index, 1)))
      {
        station *= 10;
        station += number(name->substr(index, 1));
        station_digit = true;
        index++;
      }
      if (!plus) station *= -1;
      if (!station_digit) parsing_error = true;

      if (name->substr(index, 1) != std::string("/")) parsing_error = true;
      index++;

      int ring = 0;
      bool ring_digit = false;
      while (!parsing_error  &&  numeric(name->substr(index, 1)))
      {
        ring *= 10;
        ring += number(name->substr(index, 1));
        ring_digit = true;
        index++;
      }
      if (!ring_digit) parsing_error = true;

      if (name->substr(index, 1) != std::string(" ")) parsing_error = true;
      index++;

      int chamber = 0;
      bool chamber_digit = false;
      while (!parsing_error  &&  numeric(name->substr(index, 1)))
      {
        chamber *= 10;
        chamber += number(name->substr(index, 1));
        chamber_digit = true;
        index++;
      }
      if (!chamber_digit) parsing_error = true;

      if (!parsing_error)
      {
        bool no_such_chamber = false;

        int endcap = (station > 0 ? 1 : 2);
        station = abs(station);
        if (station < 1  ||  station > 4) no_such_chamber = true;
        if (station == 1  &&  (ring < 1  ||  ring > 4)) no_such_chamber = true;
        if (station > 1  &&  (ring < 1  ||  ring > 2)) no_such_chamber = true;
        if (station == 1  &&  (chamber < 1  ||  chamber > 36)) no_such_chamber = true;
        if (station > 1  &&  ring == 1  &&  (chamber < 1  ||  chamber > 18)) no_such_chamber = true;
        if (station > 1  &&  ring == 2  &&  (chamber < 1  ||  chamber > 36)) no_such_chamber = true;

        if (no_such_chamber)
          throw cms::Exception("MuonAlignmentFromReference") << "reference chamber doesn't exist: " << (*name) << std::endl;

        CSCDetId id(endcap, station, ring, chamber);
        for (std::vector<Alignable*>::const_iterator ali = all_CSC_chambers.begin();  ali != all_CSC_chambers.end();  ++ali)
        {
          if ((*ali)->geomDetId().rawId() == id.rawId())
          {
            std::map<Alignable*,bool>::const_iterator trial = already_seen.find(*ali);
            if (trial == already_seen.end()) 
            {
              reference.push_back(*ali);
              already_seen[*ali] = true;
            }
          }
        }
      } // if (!parsing_error)
    }// endcap

    if (parsing_error)
      throw cms::Exception("MuonAlignmentFromReference") << "reference chamber name is malformed: " << (*name) << std::endl;
  }
}
void MuonAlignmentFromReference::processMuonResidualsFromTrack ( MuonResidualsFromTrack mrft)

Definition at line 686 of file MuonAlignmentFromReference.cc.

References MuonChamberResidual::chamberAlignable(), MuonResidualsFromTrack::chamberIds(), MuonResidualsFromTrack::chamberResidual(), reco::TrackBase::charge(), DeDxDiscriminatorTools::charge(), MuonChamberResidual::chi2(), MuonResidualsFromTrack::contains_TIDTEC(), CSC(), MuonSubdetId::DT, DTChamberId, Alignable::geomDetId(), MuonResidualsFromTrack::getTrack(), MuonResiduals6DOFFitter::kAngleX, MuonResiduals6DOFrphiFitter::kAngleX, MuonResiduals5DOFFitter::kAngleX, MuonResiduals6DOFrphiFitter::kAngleY, MuonResiduals5DOFFitter::kAngleY, MuonResiduals6DOFFitter::kAngleY, MuonResiduals5DOFFitter::kCharge, MuonResiduals6DOFFitter::kCharge, MuonResiduals6DOFrphiFitter::kCharge, MuonChamberResidual::kCSC, MuonChamberResidual::kDT13, MuonChamberResidual::kDT2, MuonResiduals6DOFrphiFitter::kNData, MuonResiduals6DOFFitter::kNData, MuonResiduals5DOFFitter::kNData, MuonResiduals6DOFrphiFitter::kPositionX, MuonResiduals6DOFFitter::kPositionX, MuonResiduals5DOFFitter::kPositionX, MuonResiduals6DOFrphiFitter::kPositionY, MuonResiduals6DOFFitter::kPositionY, MuonResiduals5DOFFitter::kPositionY, kPt, MuonResiduals6DOFrphiFitter::kPz, MuonResiduals6DOFFitter::kPz, MuonResiduals5DOFFitter::kPz, MuonResiduals5DOFFitter::kRedChi2, MuonResiduals6DOFFitter::kRedChi2, MuonResiduals6DOFrphiFitter::kRedChi2, MuonResiduals5DOFFitter::kResid, MuonResiduals6DOFrphiFitter::kResid, MuonResiduals6DOFFitter::kResidX, MuonResiduals6DOFFitter::kResidY, MuonResiduals5DOFFitter::kResSlope, MuonResiduals6DOFrphiFitter::kResSlope, MuonResiduals6DOFFitter::kResSlopeX, MuonResiduals6DOFFitter::kResSlopeY, m_allowTIDTEC, m_combineME11, m_counter_csc, m_counter_cscaligning, m_counter_cschits, m_counter_cscvalid, m_counter_minchambers, m_counter_resslopey, m_counter_station123, m_counter_station123aligning, m_counter_station123dt13hits, m_counter_station123dt2hits, m_counter_station123valid, m_counter_station4, m_counter_station4aligning, m_counter_station4hits, m_counter_station4valid, m_counter_totchambers, m_counter_trackerchi2, m_counter_trackerhits, m_counter_trackertidtec, m_doCSC, m_doDT, m_fitters, m_maxResSlopeY, m_maxTrackerRedChi2, m_me11map, m_minCSCHits, m_minDT13Hits, m_minDT2Hits, m_minNCrossedChambers, m_minTrackerHits, DetId::Muon, MuonChamberResidual::ndof(), MuonResidualsFromTrack::normalizedChi2(), NULL, MuonChamberResidual::numHits(), reco::TrackBase::pt(), reco::TrackBase::pz(), DetId::rawId(), MuonChamberResidual::residual(), MuonChamberResidual::resslope(), relativeConstraints::station, MuonChamberResidual::trackdxdz(), MuonChamberResidual::trackdydz(), MuonResidualsFromTrack::trackerNumHits(), MuonChamberResidual::trackx(), and MuonChamberResidual::tracky().

Referenced by run().

{
  if (mrft.trackerNumHits() >= m_minTrackerHits)
  {
    m_counter_trackerhits++;
    if (mrft.normalizedChi2() < m_maxTrackerRedChi2)
    {
      m_counter_trackerchi2++;
      if (m_allowTIDTEC  ||  !mrft.contains_TIDTEC())
      {
        m_counter_trackertidtec++;

        std::vector<DetId> chamberIds = mrft.chamberIds();

        if ((int)chamberIds.size() >= m_minNCrossedChambers)
        {
          m_counter_minchambers++;

          char charge = (mrft.getTrack()->charge() > 0 ? 1 : -1);

          for (std::vector<DetId>::const_iterator chamberId = chamberIds.begin();  chamberId != chamberIds.end();  ++chamberId)
          {
            if (chamberId->det() != DetId::Muon) continue;
            m_counter_totchambers++;

            // DT station 1,2,3
            if (m_doDT &&
                chamberId->subdetId() == MuonSubdetId::DT  &&
                DTChamberId(chamberId->rawId()).station() != 4)
            {
              MuonChamberResidual *dt13 = mrft.chamberResidual(*chamberId, MuonChamberResidual::kDT13);
              MuonChamberResidual *dt2 = mrft.chamberResidual(*chamberId, MuonChamberResidual::kDT2);

              m_counter_station123++;
              if (dt13 != NULL  &&  dt2 != NULL)
              {
                m_counter_station123valid++;
                if (dt13->numHits() >= m_minDT13Hits)
                {
                  m_counter_station123dt13hits++;
                  if (dt2->numHits() >= m_minDT2Hits)
                  {
                    m_counter_station123dt2hits++;
                    std::map<Alignable*,MuonResidualsTwoBin*>::const_iterator fitter = m_fitters.find(dt13->chamberAlignable());
                    if (fitter != m_fitters.end())
                    {
                      m_counter_station123aligning++;
                      if (fabs(dt2->resslope()) < m_maxResSlopeY)
                      {
                        m_counter_resslopey++;
                        double *residdata = new double[MuonResiduals6DOFFitter::kNData];
                        residdata[MuonResiduals6DOFFitter::kResidX] = dt13->residual();
                        residdata[MuonResiduals6DOFFitter::kResidY] = dt2->residual();
                        residdata[MuonResiduals6DOFFitter::kResSlopeX] = dt13->resslope();
                        residdata[MuonResiduals6DOFFitter::kResSlopeY] = dt2->resslope();
                        residdata[MuonResiduals6DOFFitter::kPositionX] = dt13->trackx();
                        residdata[MuonResiduals6DOFFitter::kPositionY] = dt13->tracky();
                        residdata[MuonResiduals6DOFFitter::kAngleX] = dt13->trackdxdz();
                        residdata[MuonResiduals6DOFFitter::kAngleY] = dt13->trackdydz();
                        residdata[MuonResiduals6DOFFitter::kRedChi2] = (dt13->chi2() + dt2->chi2()) / double(dt13->ndof() + dt2->ndof());
                        residdata[MuonResiduals6DOFFitter::kPz] = mrft.getTrack()->pz();
                        residdata[MuonResiduals6DOFFitter::kPt] = mrft.getTrack()->pt();
                        residdata[MuonResiduals6DOFFitter::kCharge] = mrft.getTrack()->charge();
                        fitter->second->fill(charge, residdata);
                        // the MuonResidualsFitter will delete the array when it is destroyed
                      }
                    }
                  }
                }
              }
            }

            // DT 4th station
            else if (m_doDT &&
                     chamberId->subdetId() == MuonSubdetId::DT  &&
                     DTChamberId(chamberId->rawId()).station() == 4)
            {
              MuonChamberResidual *dt13 = mrft.chamberResidual(*chamberId, MuonChamberResidual::kDT13);

              m_counter_station4++;
              if (dt13 != NULL)
              {
                m_counter_station4valid++;
                if (dt13->numHits() >= m_minDT13Hits)
                {
                  m_counter_station4hits++;

                  std::map<Alignable*,MuonResidualsTwoBin*>::const_iterator fitter = m_fitters.find(dt13->chamberAlignable());
                  if (fitter != m_fitters.end())
                  {
                    m_counter_station4aligning++;

                    double *residdata = new double[MuonResiduals5DOFFitter::kNData];
                    residdata[MuonResiduals5DOFFitter::kResid] = dt13->residual();
                    residdata[MuonResiduals5DOFFitter::kResSlope] = dt13->resslope();
                    residdata[MuonResiduals5DOFFitter::kPositionX] = dt13->trackx();
                    residdata[MuonResiduals5DOFFitter::kPositionY] = dt13->tracky();
                    residdata[MuonResiduals5DOFFitter::kAngleX] = dt13->trackdxdz();
                    residdata[MuonResiduals5DOFFitter::kAngleY] = dt13->trackdydz();
                    residdata[MuonResiduals5DOFFitter::kRedChi2] = dt13->chi2() / double(dt13->ndof());
                    residdata[MuonResiduals5DOFFitter::kPz] = mrft.getTrack()->pz();
                    residdata[MuonResiduals5DOFFitter::kPt] = mrft.getTrack()->pt();
                    residdata[MuonResiduals5DOFFitter::kCharge] = mrft.getTrack()->charge();            
                    fitter->second->fill(charge, residdata);
                    // the MuonResidualsFitter will delete the array when it is destroyed
                  }
                }
              }
            } // end DT 4th station

            // CSC
            else if (m_doCSC  &&
                     chamberId->subdetId() == MuonSubdetId::CSC)
            {
              MuonChamberResidual *csc = mrft.chamberResidual(*chamberId, MuonChamberResidual::kCSC);
              m_counter_csc++;
              if (csc != NULL)
              {
                m_counter_cscvalid++;
                if (csc->numHits() >= m_minCSCHits)
                {
                  m_counter_cschits++;
                  Alignable *ali = csc->chamberAlignable();

                  CSCDetId id(ali->geomDetId().rawId());
                  if (m_combineME11  &&  id.station() == 1  &&  id.ring() == 4)  ali = m_me11map[ali];

                  std::map<Alignable*,MuonResidualsTwoBin*>::const_iterator fitter = m_fitters.find(ali);
                  if (fitter != m_fitters.end())
                  {
                    m_counter_cscaligning++;
                    double *residdata = new double[MuonResiduals6DOFrphiFitter::kNData];
                    residdata[MuonResiduals6DOFrphiFitter::kResid] = csc->residual();
                    residdata[MuonResiduals6DOFrphiFitter::kResSlope] = csc->resslope();
                    residdata[MuonResiduals6DOFrphiFitter::kPositionX] = csc->trackx();
                    residdata[MuonResiduals6DOFrphiFitter::kPositionY] = csc->tracky();
                    residdata[MuonResiduals6DOFrphiFitter::kAngleX] = csc->trackdxdz();
                    residdata[MuonResiduals6DOFrphiFitter::kAngleY] = csc->trackdydz();
                    residdata[MuonResiduals6DOFrphiFitter::kRedChi2] = csc->chi2() / double(csc->ndof());
                    residdata[MuonResiduals6DOFrphiFitter::kPz] = mrft.getTrack()->pz();
                    residdata[MuonResiduals6DOFrphiFitter::kPt] = mrft.getTrack()->pt();
                    residdata[MuonResiduals6DOFrphiFitter::kCharge] = mrft.getTrack()->charge();
                    fitter->second->fill(charge, residdata);
                    // the MuonResidualsFitter will delete the array when it is destroyed
                  }
                }
              }
            } // end CSC

            else if (m_doDT && m_doCSC) assert(false);

          } // end loop over chamberIds
        } // # crossed muon chambers ok
      } // endcap tracker ok
    } // chi2 ok
  } // trackerNumHits ok
}
void MuonAlignmentFromReference::readTmpFiles ( ) [private]

Definition at line 1523 of file MuonAlignmentFromReference.cc.

References Exception, mergeVDriftHistosByStation::file, convertXMLtoSQLite_cfg::fileName, i, getHLTprescales::index, m_fitterOrder, m_indexes, m_readTemporaryFiles, NULL, MuonResidualsTwoBin::read(), and findQualityFiles::size.

Referenced by terminate().

{
  for (std::vector<std::string>::const_iterator fileName = m_readTemporaryFiles.begin();  fileName != m_readTemporaryFiles.end();  ++fileName)
  {
    FILE *file;
    int size;
    file = fopen(fileName->c_str(), "r");
    if (file == NULL)
      throw cms::Exception("MuonAlignmentFromReference") << "file \"" << *fileName << " can't be opened (doesn't exist?)" << std::endl;

    fread(&size, sizeof(int), 1, file);
    if (int(m_indexes.size()) != size)
      throw cms::Exception("MuonAlignmentFromReference") << "file \"" << *fileName << "\" has " << size
        << " fitters, but this job has " << m_indexes.size() << " fitters (probably corresponds to the wrong alignment job)" << std::endl;

    int i = 0;
    for (std::vector<unsigned int>::const_iterator index = m_indexes.begin();  index != m_indexes.end();  ++index, ++i)
    {
      MuonResidualsTwoBin *fitter = m_fitterOrder[*index];
      unsigned int index_toread;
      fread(&index_toread, sizeof(unsigned int), 1, file);
      if (*index != index_toread)
        throw cms::Exception("MuonAlignmentFromReference") << "file \"" << *fileName << "\" has index " << index_toread
          << " at position " << i << ", but this job is expecting " << *index << " (probably corresponds to the wrong alignment job)" << std::endl;
      fitter->read(file, i);
    }

    fclose(file);
  }
}
void MuonAlignmentFromReference::run ( const edm::EventSetup setup,
const EventInfo eventInfo 
) [virtual]

Run the algorithm (must be implemented in derived class)

Implements AlignmentAlgorithmBase.

Definition at line 621 of file MuonAlignmentFromReference.cc.

References AlignmentAlgorithmBase::EventInfo::beamSpot_, reco::TrackBase::dxy(), edm::EventSetup::get(), edm::InputTag::label(), m_alignableNavigator, m_counter_events, m_counter_trackdxy, m_counter_trackmomentum, m_counter_tracks, m_maxDxy, m_maxTrackP, m_maxTrackPt, m_minTrackP, m_muonCollectionTag, reco::TrackBase::p(), reco::BeamSpot::position(), processMuonResidualsFromTrack(), reco::TrackBase::pt(), and AlignmentAlgorithmBase::EventInfo::trajTrackPairs_.

{
  m_counter_events++;

  edm::ESHandle<GlobalTrackingGeometry> globalGeometry;
  iSetup.get<GlobalTrackingGeometryRecord>().get(globalGeometry);

  if (m_muonCollectionTag.label().empty()) // use trajectories
  {
    const ConstTrajTrackPairCollection &trajtracks = eventInfo.trajTrackPairs_;
    for (ConstTrajTrackPairCollection::const_iterator trajtrack = trajtracks.begin();  trajtrack != trajtracks.end();  ++trajtrack)
    {
      m_counter_tracks++;

      const Trajectory* traj = (*trajtrack).first;
      const reco::Track* track = (*trajtrack).second;

      if (m_minTrackPt < track->pt()  &&  track->pt() < m_maxTrackPt && m_minTrackP < track->p()  &&  track->p() < m_maxTrackP)
      {
        m_counter_trackmomentum++;

        if ( fabs(track->dxy(eventInfo.beamSpot_.position())) < m_maxDxy )
        {
          m_counter_trackdxy++;

          MuonResidualsFromTrack muonResidualsFromTrack(globalGeometry, traj, track, m_alignableNavigator, 1000.);

          processMuonResidualsFromTrack(muonResidualsFromTrack);
        }
      } // end if track p is within range
    } // end if track pT is within range
  }
  else // use muons
  {
    /*
    for (reco::MuonCollection::const_iterator muon = eventInfo.muonCollection_->begin();  muon != eventInfo.muonCollection_->end();  ++muon)
    {
      if ( !(muon->isTrackerMuon() && muon->innerTrack().isNonnull() ) ) continue;

      m_counter_tracks++;

      if (m_minTrackPt < muon->pt()  &&  muon->pt() < m_maxTrackPt && m_minTrackP < muon->p()  &&  muon->p() < m_maxTrackP)
      {
        m_counter_trackmomentum++;

        if (fabs(muon->innerTrack()->dxy(eventInfo.beamSpot_.position())) < m_maxDxy)
        {
          m_counter_trackdxy++;

          //std::cout<<"    *** will make MuonResidualsFromTrack ***"<<std::endl;
          MuonResidualsFromTrack muonResidualsFromTrack(globalGeometry, &(*muon), m_alignableNavigator, 100.);
          //std::cout<<"    *** have made MuonResidualsFromTrack ***"<<std::endl;

          //std::cout<<" trk eta="<<muon->eta()<<" ndof="<<muon->innerTrack()->ndof()<<" nchi2="<<muon->innerTrack()->normalizedChi2()
          //         <<" muresnchi2="<<muonResidualsFromTrack.normalizedChi2()<<" muresnhits="<<muonResidualsFromTrack.trackerNumHits()<<std::endl;

          processMuonResidualsFromTrack(muonResidualsFromTrack);
        } // end if track p is within range
      } // end if track pT is within range
    } // end loop over tracks
    */
  }
}
void MuonAlignmentFromReference::selectResidualsPeaks ( ) [private]

Definition at line 1596 of file MuonAlignmentFromReference.cc.

References chamberPrettyNameFromId(), gather_cfg::cout, getHLTprescales::index, MuonResidualsFitter::k0010, MuonResidualsFitter::k1010, MuonResidualsFitter::k1100, MuonResidualsFitter::k1110, MuonResidualsFitter::k1111, MuonResidualsFitter::k5DOF, MuonResidualsFitter::k6DOF, MuonResidualsFitter::k6DOFrphi, MuonResiduals5DOFFitter::kResid, MuonResiduals6DOFrphiFitter::kResid, MuonResiduals6DOFFitter::kResidX, MuonResiduals6DOFFitter::kResidY, MuonResiduals5DOFFitter::kResSlope, MuonResiduals6DOFrphiFitter::kResSlope, MuonResiduals6DOFFitter::kResSlopeX, MuonResiduals6DOFFitter::kResSlopeY, m_fitterOrder, m_indexes, m_peakNSigma, MuonResidualsTwoBin::selectPeakResiduals(), MuonResidualsTwoBin::type(), and MuonResidualsTwoBin::useRes().

Referenced by terminate().

{
  // should not be called with negative peakNSigma
  assert(m_peakNSigma>0.);
  
  for (std::vector<unsigned int>::const_iterator index = m_indexes.begin();  index != m_indexes.end();  ++index)
  {
    MuonResidualsTwoBin *fitter = m_fitterOrder[*index];

    int nvar = 2;
    int vars_index[10] = {0,1};
    if (fitter->type() == MuonResidualsFitter::k5DOF)
    {
      if (fitter->useRes() == MuonResidualsFitter::k1111 || fitter->useRes() == MuonResidualsFitter::k1110 || fitter->useRes() == MuonResidualsFitter::k1010) {
        nvar = 2;
        vars_index[0] = MuonResiduals5DOFFitter::kResid;
        vars_index[1] = MuonResiduals5DOFFitter::kResSlope;
      }
      else if (fitter->useRes() == MuonResidualsFitter::k1100) {
        nvar = 1;
        vars_index[0] = MuonResiduals5DOFFitter::kResid;
      }
      else if (fitter->useRes() == MuonResidualsFitter::k0010) {
        nvar = 1;
        vars_index[0] = MuonResiduals5DOFFitter::kResSlope;
      }
    }
    else if (fitter->type() == MuonResidualsFitter::k6DOF)
    {
      if (fitter->useRes() == MuonResidualsFitter::k1111) {
        nvar = 4;
        vars_index[0] = MuonResiduals6DOFFitter::kResidX;
        vars_index[1] = MuonResiduals6DOFFitter::kResidY;
        vars_index[2] = MuonResiduals6DOFFitter::kResSlopeX;
        vars_index[3] = MuonResiduals6DOFFitter::kResSlopeY;
      }
      else if (fitter->useRes() == MuonResidualsFitter::k1110) {
        nvar = 3;
        vars_index[0] = MuonResiduals6DOFFitter::kResidX;
        vars_index[1] = MuonResiduals6DOFFitter::kResidY;
        vars_index[2] = MuonResiduals6DOFFitter::kResSlopeX;
      }
      else if (fitter->useRes() == MuonResidualsFitter::k1010) {
        nvar = 2;
        vars_index[0] = MuonResiduals6DOFFitter::kResidX;
        vars_index[2] = MuonResiduals6DOFFitter::kResSlopeX;
      }
      else if (fitter->useRes() == MuonResidualsFitter::k1100) {
        nvar = 2;
        vars_index[0] = MuonResiduals6DOFFitter::kResidX;
        vars_index[1] = MuonResiduals6DOFFitter::kResidY;
      }
      else if (fitter->useRes() == MuonResidualsFitter::k0010) {
        nvar = 1;
        vars_index[0] = MuonResiduals6DOFFitter::kResSlopeX;
      }
    }
    else if (fitter->type() == MuonResidualsFitter::k6DOFrphi)
    {
      if (fitter->useRes() == MuonResidualsFitter::k1111 || fitter->useRes() == MuonResidualsFitter::k1110 || fitter->useRes() == MuonResidualsFitter::k1010) {
        nvar = 2;
        vars_index[0] = MuonResiduals6DOFrphiFitter::kResid;
        vars_index[1] = MuonResiduals6DOFrphiFitter::kResSlope;
      }
      else if (fitter->useRes() == MuonResidualsFitter::k1100) {
        nvar = 1;
        vars_index[0] = MuonResiduals6DOFrphiFitter::kResid;
      }
      else if (fitter->useRes() == MuonResidualsFitter::k0010) {
        nvar = 1;
        vars_index[0] = MuonResiduals6DOFrphiFitter::kResSlope;
      }
    }
    else assert(false);

    std::cout<<"selecting in "<<chamberPrettyNameFromId(*index)<<std::endl;
    
    fitter->selectPeakResiduals(m_peakNSigma, nvar, vars_index);
  }
}
void MuonAlignmentFromReference::startNewLoop ( void  ) [inline, virtual]

Call at start of loop Default implementation is dummy for non-iterative algorithms

Reimplemented from AlignmentAlgorithmBase.

Definition at line 82 of file MuonAlignmentFromReference.cc.

{};
void MuonAlignmentFromReference::terminate ( ) [virtual]

Call at end of each loop (must be implemented in derived class)

Implements AlignmentAlgorithmBase.

Definition at line 845 of file MuonAlignmentFromReference.cc.

References correctBField(), gather_cfg::cout, eraseNotSelectedResiduals(), fillNtuple(), fitAndAlign(), m_BFieldCorrection, m_counter_csc, m_counter_cscaligning, m_counter_cschits, m_counter_cscvalid, m_counter_events, m_counter_minchambers, m_counter_resslopey, m_counter_station123, m_counter_station123aligning, m_counter_station123dt13hits, m_counter_station123dt2hits, m_counter_station123valid, m_counter_station4, m_counter_station4aligning, m_counter_station4hits, m_counter_station4valid, m_counter_totchambers, m_counter_trackdxy, m_counter_trackerchi2, m_counter_trackerhits, m_counter_trackertidtec, m_counter_trackmomentum, m_counter_tracks, m_createNtuple, m_doAlignment, m_peakNSigma, m_readTemporaryFiles, m_writeTemporaryFile, readTmpFiles(), selectResidualsPeaks(), AlCaHLTBitMon_QueryRunRegistry::string, and writeTmpFiles().

{
  // one-time print-out
  std::cout << "Counters:" << std::endl
            << "COUNT{ events: " << m_counter_events << " }" << std::endl
            << "COUNT{  tracks: " << m_counter_tracks << " }" << std::endl
            << "COUNT{   trackppt: " << m_counter_trackmomentum << " }" << std::endl
            << "COUNT{    trackdxy: " << m_counter_trackdxy << " }" << std::endl
            << "COUNT{     trackerhits: " << m_counter_trackerhits << " }" << std::endl
            << "COUNT{      trackerchi2: " << m_counter_trackerchi2 << " }" << std::endl
            << "COUNT{       trackertidtec: " << m_counter_trackertidtec << " }" << std::endl
            << "COUNT{        minnchambers: " << m_counter_minchambers << " }" << std::endl
            << "COUNT{          totchambers: " << m_counter_totchambers << " }" << std::endl
            << "COUNT{            station123:             " << m_counter_station123 << " }" << std::endl
            << "COUNT{             station123valid:       " << m_counter_station123valid << " }" << std::endl
            << "COUNT{              station123dt13hits:   " << m_counter_station123dt13hits << " }" << std::endl
            << "COUNT{               station123dt2hits:   " << m_counter_station123dt2hits << " }" << std::endl
            << "COUNT{                station123aligning: " << m_counter_station123aligning << " }" << std::endl
            << "COUNT{                 resslopey: " << m_counter_resslopey << " }" << std::endl
            << "COUNT{            station4:            " << m_counter_station4 << " }" << std::endl
            << "COUNT{             station4valid:      " << m_counter_station4valid << " }" << std::endl
            << "COUNT{              station4hits:      " << m_counter_station4hits << " }" << std::endl
            << "COUNT{               station4aligning: " << m_counter_station4aligning << " }" << std::endl
            << "COUNT{            csc:            " << m_counter_csc << " }" << std::endl
            << "COUNT{             cscvalid:      " << m_counter_cscvalid << " }" << std::endl
            << "COUNT{              cschits:      " << m_counter_cschits << " }" << std::endl
            << "COUNT{               cscaligning: " << m_counter_cscaligning << " }" << std::endl
            << "That's all!" << std::endl;

  TStopwatch stop_watch;

  // collect temporary files
  if (m_readTemporaryFiles.size() != 0) 
  {
    stop_watch.Start();
    readTmpFiles();
    std::cout <<"readTmpFiles took "<< stop_watch.CpuTime() << " sec" << std::endl;
    stop_watch.Stop();
  }
  
  // select residuals peaks and discard tails if peakNSigma>0 (only while doing alignment)
  if (m_peakNSigma > 0. && m_doAlignment) 
  {
    stop_watch.Start();
    selectResidualsPeaks();
    std::cout <<"selectResidualsPeaks took "<< stop_watch.CpuTime() << " sec" << std::endl;
    stop_watch.Stop();
  }

  if (m_BFieldCorrection > 0 && m_doAlignment)
  {
    stop_watch.Start();
    correctBField();
    std::cout <<"correctBField took "<< stop_watch.CpuTime() << " sec" << std::endl;
    stop_watch.Stop();
  }

  // optionally, create an nutuple for easy debugging
  if (m_createNtuple)
  {
    stop_watch.Start();
    fillNtuple();
    std::cout <<"fillNtuple took "<< stop_watch.CpuTime() << " sec" << std::endl;
    stop_watch.Stop();
  }

  if (m_doAlignment)
  {
    stop_watch.Start();
    eraseNotSelectedResiduals();
    std::cout <<"eraseNotSelectedResiduals took "<< stop_watch.CpuTime() << " sec" << std::endl;
    stop_watch.Stop();
  }

  // fit and align (time-consuming, so the user can turn it off if in a residuals-gathering job)
  if (m_doAlignment) 
  {
    stop_watch.Start();
    fitAndAlign();
    std::cout <<"fitAndAlign took "<< stop_watch.CpuTime() << " sec" << std::endl;
    stop_watch.Stop();
  }

  // write out the pseudontuples for a later job to collect
  if (m_writeTemporaryFile != std::string("")) writeTmpFiles();
}
void MuonAlignmentFromReference::writeTmpFiles ( ) [private]

Definition at line 1555 of file MuonAlignmentFromReference.cc.

References mergeVDriftHistosByStation::file, i, getHLTprescales::index, m_fitterOrder, m_indexes, m_writeTemporaryFile, findQualityFiles::size, and MuonResidualsTwoBin::write().

Referenced by terminate().

{
  FILE *file;
  file = fopen(m_writeTemporaryFile.c_str(), "w");
  int size = m_indexes.size();
  fwrite(&size, sizeof(int), 1, file);

  int i = 0;
  for (std::vector<unsigned int>::const_iterator index = m_indexes.begin();  index != m_indexes.end();  ++index, ++i)
  {
    MuonResidualsTwoBin *fitter = m_fitterOrder[*index];
    unsigned int index_towrite = *index;
    fwrite(&index_towrite, sizeof(unsigned int), 1, file);
    fitter->write(file, i);
  }

  fclose(file);
}

Member Data Documentation

Definition at line 143 of file MuonAlignmentFromReference.cc.

Referenced by initialize(), run(), and ~MuonAlignmentFromReference().

Definition at line 145 of file MuonAlignmentFromReference.cc.

Referenced by fitAndAlign(), and initialize().

Definition at line 144 of file MuonAlignmentFromReference.cc.

Referenced by fitAndAlign(), and initialize().

Definition at line 119 of file MuonAlignmentFromReference.cc.

Referenced by processMuonResidualsFromTrack().

Definition at line 137 of file MuonAlignmentFromReference.cc.

Referenced by terminate().

Definition at line 152 of file MuonAlignmentFromReference.cc.

Referenced by MuonAlignmentFromReference(), run(), and terminate().

Definition at line 155 of file MuonAlignmentFromReference.cc.

Referenced by MuonAlignmentFromReference(), run(), and terminate().

Definition at line 154 of file MuonAlignmentFromReference.cc.

Referenced by MuonAlignmentFromReference(), run(), and terminate().

Definition at line 153 of file MuonAlignmentFromReference.cc.

Referenced by MuonAlignmentFromReference(), run(), and terminate().

Definition at line 135 of file MuonAlignmentFromReference.cc.

Referenced by MuonAlignmentFromReference(), and terminate().

Definition at line 126 of file MuonAlignmentFromReference.cc.

Referenced by MuonAlignmentFromReference(), and terminate().

Definition at line 139 of file MuonAlignmentFromReference.cc.

Referenced by processMuonResidualsFromTrack().

Definition at line 138 of file MuonAlignmentFromReference.cc.

Referenced by processMuonResidualsFromTrack().

std::vector<unsigned int> MuonAlignmentFromReference::m_indexes [private]

Definition at line 116 of file MuonAlignmentFromReference.cc.

Referenced by run().

Definition at line 134 of file MuonAlignmentFromReference.cc.

Referenced by processMuonResidualsFromTrack().

Definition at line 118 of file MuonAlignmentFromReference.cc.

Referenced by processMuonResidualsFromTrack().

Definition at line 115 of file MuonAlignmentFromReference.cc.

Referenced by run().

Definition at line 113 of file MuonAlignmentFromReference.cc.

Referenced by run().

Definition at line 129 of file MuonAlignmentFromReference.cc.

Referenced by fitAndAlign(), and initialize().

Definition at line 123 of file MuonAlignmentFromReference.cc.

Referenced by processMuonResidualsFromTrack().

Definition at line 121 of file MuonAlignmentFromReference.cc.

Referenced by processMuonResidualsFromTrack().

Definition at line 122 of file MuonAlignmentFromReference.cc.

Referenced by processMuonResidualsFromTrack().

Definition at line 120 of file MuonAlignmentFromReference.cc.

Referenced by processMuonResidualsFromTrack().

Definition at line 117 of file MuonAlignmentFromReference.cc.

Referenced by processMuonResidualsFromTrack().

Definition at line 114 of file MuonAlignmentFromReference.cc.

Referenced by run().

Definition at line 112 of file MuonAlignmentFromReference.cc.

Definition at line 110 of file MuonAlignmentFromReference.cc.

Referenced by run().

Definition at line 136 of file MuonAlignmentFromReference.cc.

Referenced by selectResidualsPeaks(), and terminate().

std::vector<std::string> MuonAlignmentFromReference::m_readTemporaryFiles [private]

Definition at line 125 of file MuonAlignmentFromReference.cc.

Referenced by readTmpFiles(), and terminate().

std::vector<std::string> MuonAlignmentFromReference::m_reference [private]

Definition at line 111 of file MuonAlignmentFromReference.cc.

Referenced by initialize(), and parseReference().

Definition at line 133 of file MuonAlignmentFromReference.cc.

Referenced by fitAndAlign().

Definition at line 128 of file MuonAlignmentFromReference.cc.

Referenced by initialize().

Definition at line 127 of file MuonAlignmentFromReference.cc.

Referenced by initialize().

Definition at line 179 of file MuonAlignmentFromReference.cc.

Referenced by bookNtuple(), and fillNtuple().

Definition at line 130 of file MuonAlignmentFromReference.cc.

Referenced by initialize().

Definition at line 140 of file MuonAlignmentFromReference.cc.

Referenced by initialize().

Definition at line 132 of file MuonAlignmentFromReference.cc.

Referenced by initialize().

Definition at line 124 of file MuonAlignmentFromReference.cc.

Referenced by terminate(), and writeTmpFiles().