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Public Member Functions | Public Attributes | Private Attributes

CSCOverlapsAlignmentAlgorithm Class Reference

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

Inheritance diagram for CSCOverlapsAlignmentAlgorithm:
AlignmentAlgorithmBase

List of all members.

Public Member Functions

 CSCOverlapsAlignmentAlgorithm (const edm::ParameterSet &iConfig)
void initialize (const edm::EventSetup &iSetup, AlignableTracker *alignableTracker, AlignableMuon *alignableMuon, AlignableExtras *alignableExtras, AlignmentParameterStore *alignmentParameterStore)
 Call at beginning of job (must be implemented in derived class)
void run (const edm::EventSetup &iSetup, const EventInfo &eventInfo)
 Run the algorithm (must be implemented in derived class)
void terminate ()
 Call at end of job (must be implemented in derived class)
 ~CSCOverlapsAlignmentAlgorithm ()

Public Attributes

bool m_combineME11
TH1F * m_drdz
bool m_errorFromRMS
bool m_fiducial
TProfile * m_fiducial_ME11
TProfile * m_fiducial_ME12
TProfile * m_fiducial_MEx1
TProfile * m_fiducial_MEx2
TH1F * m_hitsPerChamber
bool m_makeHistograms
double m_maxdrdz
int m_minHitsPerChamber
int m_minStationsInTrackRefits
int m_minTracksPerOverlap
int m_mode
TH2F * m_occupancy
TH1F * m_offsetResiduals
TH1F * m_offsetResiduals_normalized
TH1F * m_offsetResiduals_weighted
TH2F * m_RPhipos_mem1
TH2F * m_RPhipos_mem2
TH2F * m_RPhipos_mem3
TH2F * m_RPhipos_mem4
TH2F * m_RPhipos_mep1
TH2F * m_RPhipos_mep2
TH2F * m_RPhipos_mep3
TH2F * m_RPhipos_mep4
TH1F * m_slope
TH1F * m_slope_MEm1
TH1F * m_slope_MEm2
TH1F * m_slope_MEm3
TH1F * m_slope_MEm4
TH1F * m_slope_MEp1
TH1F * m_slope_MEp2
TH1F * m_slope_MEp3
TH1F * m_slope_MEp4
bool m_slopeFromTrackRefit
TH1F * m_slopeResiduals
TH1F * m_slopeResiduals_normalized
TH1F * m_slopeResiduals_weighted
double m_truncateOffsetResid
double m_truncateSlopeResid
bool m_useHitWeights
bool m_useTrackWeights
TH2F * m_XYpos_mem1
TH2F * m_XYpos_mem2
TH2F * m_XYpos_mem3
TH2F * m_XYpos_mem4
TH2F * m_XYpos_mep1
TH2F * m_XYpos_mep2
TH2F * m_XYpos_mep3
TH2F * m_XYpos_mep4

Private Attributes

AlignableNavigatorm_alignableNavigator
std::vector< Alignable * > m_alignables
AlignmentParameterStorem_alignmentParameterStore
bool m_doAlignment
std::vector< CSCChamberFitterm_fitters
TH1F * m_histP10
TH1F * m_histP100
TH1F * m_histP1000
double m_maxRedChi2
double m_minP
std::string m_mode_string
std::string m_propagatorName
const Propagatorm_propagatorPointer
std::map< std::pair< CSCDetId,
CSCDetId >
, CSCPairResidualsConstraint * > 
m_quickChamberLookup
std::vector< std::string > m_readTemporaryFiles
std::string m_reportFileName
std::vector
< CSCPairResidualsConstraint * > 
m_residualsConstraints
TrackTransformerm_trackTransformer
std::string m_writeTemporaryFile

Detailed Description

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

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

Definition at line 61 of file CSCOverlapsAlignmentAlgorithm.h.


Constructor & Destructor Documentation

CSCOverlapsAlignmentAlgorithm::CSCOverlapsAlignmentAlgorithm ( const edm::ParameterSet iConfig)

Definition at line 3 of file CSCOverlapsAlignmentAlgorithm.cc.

References Exception, CSCOverlapsAlignmentAlgorithm_diskfitters_cff::fitters, edm::ParameterSet::getParameter(), i, CSCPairResidualsConstraint::kModePhiPos, CSCPairResidualsConstraint::kModePhiy, CSCPairResidualsConstraint::kModePhiz, CSCPairResidualsConstraint::kModeRadius, m_combineME11, m_drdz, m_fiducial_ME11, m_fiducial_ME12, m_fiducial_MEx1, m_fiducial_MEx2, m_fitters, m_histP10, m_histP100, m_histP1000, m_hitsPerChamber, m_makeHistograms, m_mode, m_mode_string, m_occupancy, m_offsetResiduals, m_offsetResiduals_normalized, m_offsetResiduals_weighted, M_PI, m_propagatorName, m_propagatorPointer, m_quickChamberLookup, m_residualsConstraints, m_RPhipos_mem1, m_RPhipos_mem2, m_RPhipos_mem3, m_RPhipos_mem4, m_RPhipos_mep1, m_RPhipos_mep2, m_RPhipos_mep3, m_RPhipos_mep4, m_slope, m_slope_MEm1, m_slope_MEm2, m_slope_MEm3, m_slope_MEm4, m_slope_MEp1, m_slope_MEp2, m_slope_MEp3, m_slope_MEp4, m_slopeFromTrackRefit, m_slopeResiduals, m_slopeResiduals_normalized, m_slopeResiduals_weighted, m_trackTransformer, m_XYpos_mem1, m_XYpos_mem2, m_XYpos_mem3, m_XYpos_mem4, m_XYpos_mep1, m_XYpos_mep2, m_XYpos_mep3, m_XYpos_mep4, and NULL.

   : AlignmentAlgorithmBase(iConfig)
   , m_minHitsPerChamber(iConfig.getParameter<int>("minHitsPerChamber"))
   , m_maxdrdz(iConfig.getParameter<double>("maxdrdz"))
   , m_fiducial(iConfig.getParameter<bool>("fiducial"))
   , m_useHitWeights(iConfig.getParameter<bool>("useHitWeights"))
   , m_slopeFromTrackRefit(iConfig.getParameter<bool>("slopeFromTrackRefit"))
   , m_minStationsInTrackRefits(iConfig.getParameter<int>("minStationsInTrackRefits"))
   , m_truncateSlopeResid(iConfig.getParameter<double>("truncateSlopeResid"))
   , m_truncateOffsetResid(iConfig.getParameter<double>("truncateOffsetResid"))
   , m_combineME11(iConfig.getParameter<bool>("combineME11"))
   , m_useTrackWeights(iConfig.getParameter<bool>("useTrackWeights"))
   , m_errorFromRMS(iConfig.getParameter<bool>("errorFromRMS"))
   , m_minTracksPerOverlap(iConfig.getParameter<int>("minTracksPerOverlap"))
   , m_makeHistograms(iConfig.getParameter<bool>("makeHistograms"))
   , m_mode_string(iConfig.getParameter<std::string>("mode"))
   , m_reportFileName(iConfig.getParameter<std::string>("reportFileName"))
   , m_minP(iConfig.getParameter<double>("minP"))
   , m_maxRedChi2(iConfig.getParameter<double>("maxRedChi2"))
   , m_writeTemporaryFile(iConfig.getParameter<std::string>("writeTemporaryFile"))
   , m_readTemporaryFiles(iConfig.getParameter<std::vector<std::string> >("readTemporaryFiles"))
   , m_doAlignment(iConfig.getParameter<bool>("doAlignment"))
{
  if (m_mode_string == std::string("phiy")) m_mode = CSCPairResidualsConstraint::kModePhiy;
  else if (m_mode_string == std::string("phipos")) m_mode = CSCPairResidualsConstraint::kModePhiPos;
  else if (m_mode_string == std::string("phiz")) m_mode = CSCPairResidualsConstraint::kModePhiz;
  else if (m_mode_string == std::string("radius")) m_mode = CSCPairResidualsConstraint::kModeRadius;
  else throw cms::Exception("BadConfig") << "mode must be one of \"phiy\", \"phipos\", \"phiz\", \"radius\"" << std::endl;

  std::vector<edm::ParameterSet> fitters = iConfig.getParameter<std::vector<edm::ParameterSet> >("fitters");
  for (std::vector<edm::ParameterSet>::const_iterator fitter = fitters.begin();  fitter != fitters.end();  ++fitter) {
    m_fitters.push_back(CSCChamberFitter(*fitter, m_residualsConstraints));
  }

  for (std::vector<CSCPairResidualsConstraint*>::const_iterator residualsConstraint = m_residualsConstraints.begin();  residualsConstraint != m_residualsConstraints.end();  ++residualsConstraint) {
    (*residualsConstraint)->configure(this);
    m_quickChamberLookup[std::pair<CSCDetId,CSCDetId>((*residualsConstraint)->id_i(), (*residualsConstraint)->id_j())] = *residualsConstraint;
  }

  if (m_slopeFromTrackRefit) {
    m_trackTransformer = new TrackTransformer(iConfig.getParameter<edm::ParameterSet>("TrackTransformer"));
    m_propagatorName = iConfig.getParameter<edm::ParameterSet>("TrackTransformer").getParameter<std::string>("Propagator");
  }
  else {
    m_trackTransformer = NULL;
    m_propagatorName = std::string("");
  }

  m_propagatorPointer = NULL;

  if (m_makeHistograms) {
    edm::Service<TFileService> tFileService;
    m_histP10 = tFileService->make<TH1F>("P10", "", 100, 0, 10);
    m_histP100 = tFileService->make<TH1F>("P100", "", 100, 0, 100);
    m_histP1000 = tFileService->make<TH1F>("P1000", "", 100, 0, 1000);

    m_hitsPerChamber = tFileService->make<TH1F>("hitsPerChamber", "", 10, -0.5, 9.5);

    m_fiducial_ME11 = tFileService->make<TProfile>("fiducial_ME11", "", 100, 0.075, 0.100);
    m_fiducial_ME12 = tFileService->make<TProfile>("fiducial_ME12", "", 100, 0.080, 0.105);
    m_fiducial_MEx1 = tFileService->make<TProfile>("fiducial_MEx1", "", 100, 0.160, 0.210);
    m_fiducial_MEx2 = tFileService->make<TProfile>("fiducial_MEx2", "", 100, 0.080, 0.105);

    m_slope = tFileService->make<TH1F>("slope", "", 100, -0.5, 0.5);
    m_slope_MEp4 = tFileService->make<TH1F>("slope_MEp4", "", 100, -0.5, 0.5);
    m_slope_MEp3 = tFileService->make<TH1F>("slope_MEp3", "", 100, -0.5, 0.5);
    m_slope_MEp2 = tFileService->make<TH1F>("slope_MEp2", "", 100, -0.5, 0.5);
    m_slope_MEp1 = tFileService->make<TH1F>("slope_MEp1", "", 100, -0.5, 0.5);
    m_slope_MEm1 = tFileService->make<TH1F>("slope_MEm1", "", 100, -0.5, 0.5);
    m_slope_MEm2 = tFileService->make<TH1F>("slope_MEm2", "", 100, -0.5, 0.5);
    m_slope_MEm3 = tFileService->make<TH1F>("slope_MEm3", "", 100, -0.5, 0.5);
    m_slope_MEm4 = tFileService->make<TH1F>("slope_MEm4", "", 100, -0.5, 0.5);

    m_slopeResiduals = tFileService->make<TH1F>("slopeResiduals", "mrad", 300, -30., 30.);
    m_slopeResiduals_weighted = tFileService->make<TH1F>("slopeResiduals_weighted", "mrad", 300, -30., 30.);
    m_slopeResiduals_normalized = tFileService->make<TH1F>("slopeResiduals_normalized", "", 200, -20., 20.);
    m_offsetResiduals = tFileService->make<TH1F>("offsetResiduals", "mm", 300, -30., 30.);
    m_offsetResiduals_weighted = tFileService->make<TH1F>("offsetResiduals_weighted", "mm", 300, -30., 30.);
    m_offsetResiduals_normalized = tFileService->make<TH1F>("offsetResiduals_normalized", "", 200, -20., 20.);

    m_drdz = tFileService->make<TH1F>("drdz", "", 100, -0.5, 0.5);

    m_occupancy = tFileService->make<TH2F>("occupancy", "", 36, 1, 37, 20, 1, 21);
    for (int i = 1;  i <= 36;  i++) {
      std::stringstream pairname;
      pairname << i << "-";
      if (i+1 == 37) pairname << 1;
      else pairname << (i+1);
      m_occupancy->GetXaxis()->SetBinLabel(i, pairname.str().c_str());
    }
    m_occupancy->GetYaxis()->SetBinLabel(1, "ME-4/2");
    m_occupancy->GetYaxis()->SetBinLabel(2, "ME-4/1");
    m_occupancy->GetYaxis()->SetBinLabel(3, "ME-3/2");
    m_occupancy->GetYaxis()->SetBinLabel(4, "ME-3/1");
    m_occupancy->GetYaxis()->SetBinLabel(5, "ME-2/2");
    m_occupancy->GetYaxis()->SetBinLabel(6, "ME-2/1");
    m_occupancy->GetYaxis()->SetBinLabel(7, "ME-1/3");
    m_occupancy->GetYaxis()->SetBinLabel(8, "ME-1/2");
    if (!m_combineME11) {
      m_occupancy->GetYaxis()->SetBinLabel(9, "ME-1/1b");
      m_occupancy->GetYaxis()->SetBinLabel(10, "ME-1/1a");
      m_occupancy->GetYaxis()->SetBinLabel(11, "ME+1/1a");
      m_occupancy->GetYaxis()->SetBinLabel(12, "ME+1/1b");
    }
    else {
      m_occupancy->GetYaxis()->SetBinLabel(9, "ME-1/1");
      m_occupancy->GetYaxis()->SetBinLabel(10, "");
      m_occupancy->GetYaxis()->SetBinLabel(11, "");
      m_occupancy->GetYaxis()->SetBinLabel(12, "ME+1/1");
    }
    m_occupancy->GetYaxis()->SetBinLabel(13, "ME+1/2");
    m_occupancy->GetYaxis()->SetBinLabel(14, "ME+1/3");
    m_occupancy->GetYaxis()->SetBinLabel(15, "ME+2/1");
    m_occupancy->GetYaxis()->SetBinLabel(16, "ME+2/2");
    m_occupancy->GetYaxis()->SetBinLabel(17, "ME+3/1");
    m_occupancy->GetYaxis()->SetBinLabel(18, "ME+3/2");
    m_occupancy->GetYaxis()->SetBinLabel(19, "ME+4/1");
    m_occupancy->GetYaxis()->SetBinLabel(20, "ME+4/2");

    m_XYpos_mep1 = tFileService->make<TH2F>("XYpos_mep1", "Positions: ME+1", 140, -700., 700., 140, -700., 700.);
    m_XYpos_mep2 = tFileService->make<TH2F>("XYpos_mep2", "Positions: ME+2", 140, -700., 700., 140, -700., 700.);
    m_XYpos_mep3 = tFileService->make<TH2F>("XYpos_mep3", "Positions: ME+3", 140, -700., 700., 140, -700., 700.);
    m_XYpos_mep4 = tFileService->make<TH2F>("XYpos_mep4", "Positions: ME+4", 140, -700., 700., 140, -700., 700.);
    m_XYpos_mem1 = tFileService->make<TH2F>("XYpos_mem1", "Positions: ME-1", 140, -700., 700., 140, -700., 700.);
    m_XYpos_mem2 = tFileService->make<TH2F>("XYpos_mem2", "Positions: ME-2", 140, -700., 700., 140, -700., 700.);
    m_XYpos_mem3 = tFileService->make<TH2F>("XYpos_mem3", "Positions: ME-3", 140, -700., 700., 140, -700., 700.);
    m_XYpos_mem4 = tFileService->make<TH2F>("XYpos_mem4", "Positions: ME-4", 140, -700., 700., 140, -700., 700.);
    m_RPhipos_mep1 = tFileService->make<TH2F>("RPhipos_mep1", "Positions: ME+1", 144, -M_PI, M_PI, 21, 0., 700.);
    m_RPhipos_mep2 = tFileService->make<TH2F>("RPhipos_mep2", "Positions: ME+2", 144, -M_PI, M_PI, 21, 0., 700.);
    m_RPhipos_mep3 = tFileService->make<TH2F>("RPhipos_mep3", "Positions: ME+3", 144, -M_PI, M_PI, 21, 0., 700.);
    m_RPhipos_mep4 = tFileService->make<TH2F>("RPhipos_mep4", "Positions: ME+4", 144, -M_PI, M_PI, 21, 0., 700.);
    m_RPhipos_mem1 = tFileService->make<TH2F>("RPhipos_mem1", "Positions: ME-1", 144, -M_PI, M_PI, 21, 0., 700.);
    m_RPhipos_mem2 = tFileService->make<TH2F>("RPhipos_mem2", "Positions: ME-2", 144, -M_PI, M_PI, 21, 0., 700.);
    m_RPhipos_mem3 = tFileService->make<TH2F>("RPhipos_mem3", "Positions: ME-3", 144, -M_PI, M_PI, 21, 0., 700.);
    m_RPhipos_mem4 = tFileService->make<TH2F>("RPhipos_mem4", "Positions: ME-4", 144, -M_PI, M_PI, 21, 0., 700.);
  }
  else {
    m_histP10 = NULL;
    m_histP100 = NULL;
    m_histP1000 = NULL;
    m_hitsPerChamber = NULL;
    m_fiducial_ME11 = NULL;
    m_fiducial_ME12 = NULL;
    m_fiducial_MEx1 = NULL;
    m_fiducial_MEx2 = NULL;
    m_slope = NULL;
    m_slope_MEp4 = NULL;
    m_slope_MEp3 = NULL;
    m_slope_MEp2 = NULL;
    m_slope_MEp1 = NULL;
    m_slope_MEm1 = NULL;
    m_slope_MEm2 = NULL;
    m_slope_MEm3 = NULL;
    m_slope_MEm4 = NULL;
    m_slopeResiduals = NULL;
    m_slopeResiduals_weighted = NULL;
    m_slopeResiduals_normalized = NULL;
    m_offsetResiduals = NULL;
    m_offsetResiduals_weighted = NULL;
    m_offsetResiduals_normalized = NULL;
    m_drdz = NULL;
    m_occupancy = NULL;
    m_XYpos_mep1 = NULL;
    m_XYpos_mep2 = NULL;
    m_XYpos_mep3 = NULL;
    m_XYpos_mep4 = NULL;
    m_XYpos_mem1 = NULL;
    m_XYpos_mem2 = NULL;
    m_XYpos_mem3 = NULL;
    m_XYpos_mem4 = NULL;
    m_RPhipos_mep1 = NULL;
    m_RPhipos_mep2 = NULL;
    m_RPhipos_mep3 = NULL;
    m_RPhipos_mep4 = NULL;
    m_RPhipos_mem1 = NULL;
    m_RPhipos_mem2 = NULL;
    m_RPhipos_mem3 = NULL;
    m_RPhipos_mem4 = NULL;
  }
}
CSCOverlapsAlignmentAlgorithm::~CSCOverlapsAlignmentAlgorithm ( )

Definition at line 184 of file CSCOverlapsAlignmentAlgorithm.cc.

{}

Member Function Documentation

void CSCOverlapsAlignmentAlgorithm::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 186 of file CSCOverlapsAlignmentAlgorithm.cc.

References AlignmentParameterStore::alignables(), MuonSubdetId::CSC, CSCDetId, Exception, mergeVDriftHistosByStation::file, convertXMLtoSQLite_cfg::fileName, edm::EventSetup::get(), i, collect_tpl::input, m_alignableNavigator, m_alignables, m_alignmentParameterStore, m_readTemporaryFiles, m_residualsConstraints, DetId::Muon, and NULL.

                                                                                                                                                                                                                                {
  m_alignmentParameterStore = alignmentParameterStore;
  m_alignables = m_alignmentParameterStore->alignables();

  if (alignableTracker == NULL) m_alignableNavigator = new AlignableNavigator(alignableMuon);
  else m_alignableNavigator = new AlignableNavigator(alignableTracker, alignableMuon);

  for (std::vector<Alignable*>::const_iterator alignable = m_alignables.begin();  alignable != m_alignables.end();  ++alignable) {
    DetId id = (*alignable)->geomDetId();
    if (id.det() != DetId::Muon  ||  id.subdetId() != MuonSubdetId::CSC  ||  CSCDetId(id.rawId()).layer() != 0) {
      throw cms::Exception("BadConfig") << "Only CSC chambers may be alignable" << std::endl;
    }

    std::vector<bool> selector = (*alignable)->alignmentParameters()->selector();
    for (std::vector<bool>::const_iterator i = selector.begin();  i != selector.end();  ++i) {
      if (!(*i)) throw cms::Exception("BadConfig") << "All selector strings should be \"111111\"" << std::endl;
    }
  }

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

  for (std::vector<CSCPairResidualsConstraint*>::const_iterator residualsConstraint = m_residualsConstraints.begin();  residualsConstraint != m_residualsConstraints.end();  ++residualsConstraint) {
    (*residualsConstraint)->setZplane(&*cscGeometry);
  }

  if (m_readTemporaryFiles.size() != 0) {
    std::vector<std::ifstream*> input;
    for (std::vector<std::string>::const_iterator fileName = m_readTemporaryFiles.begin();  fileName != m_readTemporaryFiles.end();  ++fileName) {
      input.push_back(new std::ifstream(fileName->c_str()));
    }

    for (std::vector<CSCPairResidualsConstraint*>::const_iterator residualsConstraint = m_residualsConstraints.begin();  residualsConstraint != m_residualsConstraints.end();  ++residualsConstraint) {
      (*residualsConstraint)->read(input, m_readTemporaryFiles);
    }

    for (std::vector<std::ifstream*>::const_iterator file = input.begin();  file != input.end();  ++file) {
      delete (*file);
    }
  }
}
void CSCOverlapsAlignmentAlgorithm::run ( const edm::EventSetup setup,
const EventInfo eventInfo 
) [virtual]

Run the algorithm (must be implemented in derived class)

Implements AlignmentAlgorithmBase.

Definition at line 228 of file CSCOverlapsAlignmentAlgorithm.cc.

References CSCDetId::chamber(), MuonSubdetId::CSC, CSCDetId, CSCDetId::endcap(), edm::EventSetup::get(), m_combineME11, m_histP10, m_histP100, m_histP1000, m_makeHistograms, m_minP, m_propagatorName, m_propagatorPointer, m_quickChamberLookup, m_residualsConstraints, m_RPhipos_mem1, m_RPhipos_mem2, m_RPhipos_mem3, m_RPhipos_mem4, m_RPhipos_mep1, m_RPhipos_mep2, m_RPhipos_mep3, m_RPhipos_mep4, m_slopeFromTrackRefit, m_trackTransformer, m_XYpos_mem1, m_XYpos_mem2, m_XYpos_mem3, m_XYpos_mem4, m_XYpos_mep1, m_XYpos_mep2, m_XYpos_mep3, m_XYpos_mep4, python::multivaluedict::map(), Trajectory::measurements(), DetId::Muon, NULL, reco::TrackBase::p(), PV3DBase< T, PVType, FrameType >::perp(), PV3DBase< T, PVType, FrameType >::phi(), pos, LargeD0_PixelPairStep_cff::propagator, CSCDetId::ring(), TrackTransformer::setServices(), relativeConstraints::station, CSCDetId::station(), AlignmentAlgorithmBase::EventInfo::trajTrackPairs_, PV3DBase< T, PVType, FrameType >::x(), and PV3DBase< T, PVType, FrameType >::y().

                                                                                               {
  edm::ESHandle<Propagator> propagator;
  if (m_slopeFromTrackRefit) {
    iSetup.get<TrackingComponentsRecord>().get(m_propagatorName, propagator);
    if (m_propagatorPointer != &*propagator) {
      m_propagatorPointer = &*propagator;

      for (std::vector<CSCPairResidualsConstraint*>::const_iterator residualsConstraint = m_residualsConstraints.begin();  residualsConstraint != m_residualsConstraints.end();  ++residualsConstraint) {
        (*residualsConstraint)->setPropagator(m_propagatorPointer);
      }
    }
  }

  edm::ESHandle<TransientTrackBuilder> transientTrackBuilder;
  iSetup.get<TransientTrackRecord>().get("TransientTrackBuilder", transientTrackBuilder);

  if (m_trackTransformer != NULL) m_trackTransformer->setServices(iSetup);

  const ConstTrajTrackPairCollection &trajtracks = eventInfo.trajTrackPairs_;
  for (ConstTrajTrackPairCollection::const_iterator trajtrack = trajtracks.begin();  trajtrack != trajtracks.end();  ++trajtrack) {
    const Trajectory* traj = (*trajtrack).first;
    const reco::Track* track = (*trajtrack).second;

    if (m_makeHistograms) {
      m_histP10->Fill(track->p());
      m_histP100->Fill(track->p());
      m_histP1000->Fill(track->p());
    }
    if (track->p() >= m_minP) {
      std::vector<TrajectoryMeasurement> measurements = traj->measurements();
      reco::TransientTrack transientTrack = transientTrackBuilder->build(track);

      std::map<int,std::map<CSCDetId,bool> > stationsToChambers;
      for (std::vector<TrajectoryMeasurement>::const_iterator measurement = measurements.begin();  measurement != measurements.end();  ++measurement) {
        DetId id = measurement->recHit()->geographicalId();
        if (id.det() == DetId::Muon  &&  id.subdetId() == MuonSubdetId::CSC) {
          CSCDetId cscid(id.rawId());
          CSCDetId chamberId(cscid.endcap(), cscid.station(), cscid.ring(), cscid.chamber(), 0);
          if (m_combineME11  &&  cscid.station() == 1  &&  cscid.ring() == 4) chamberId = CSCDetId(cscid.endcap(), 1, 1, cscid.chamber(), 0);
          int station = (cscid.endcap() == 1 ? 1 : -1)*cscid.station();

          if (stationsToChambers.find(station) == stationsToChambers.end()) stationsToChambers[station] = std::map<CSCDetId,bool>();
          stationsToChambers[station][chamberId] = true;

          if (m_makeHistograms) {
            GlobalPoint pos = measurement->recHit()->globalPosition();
            if (cscid.endcap() == 1  &&  cscid.station() == 1) { m_XYpos_mep1->Fill(pos.x(), pos.y()); m_RPhipos_mep1->Fill(pos.phi(), pos.perp()); }
            if (cscid.endcap() == 1  &&  cscid.station() == 2) { m_XYpos_mep2->Fill(pos.x(), pos.y()); m_RPhipos_mep2->Fill(pos.phi(), pos.perp()); }
            if (cscid.endcap() == 1  &&  cscid.station() == 3) { m_XYpos_mep3->Fill(pos.x(), pos.y()); m_RPhipos_mep3->Fill(pos.phi(), pos.perp()); }
            if (cscid.endcap() == 1  &&  cscid.station() == 4) { m_XYpos_mep4->Fill(pos.x(), pos.y()); m_RPhipos_mep4->Fill(pos.phi(), pos.perp()); }
            if (cscid.endcap() == 2  &&  cscid.station() == 1) { m_XYpos_mem1->Fill(pos.x(), pos.y()); m_RPhipos_mem1->Fill(pos.phi(), pos.perp()); }
            if (cscid.endcap() == 2  &&  cscid.station() == 2) { m_XYpos_mem2->Fill(pos.x(), pos.y()); m_RPhipos_mem2->Fill(pos.phi(), pos.perp()); }
            if (cscid.endcap() == 2  &&  cscid.station() == 3) { m_XYpos_mem3->Fill(pos.x(), pos.y()); m_RPhipos_mem3->Fill(pos.phi(), pos.perp()); }
            if (cscid.endcap() == 2  &&  cscid.station() == 4) { m_XYpos_mem4->Fill(pos.x(), pos.y()); m_RPhipos_mem4->Fill(pos.phi(), pos.perp()); }
          }
        }
      }
      
      std::map<CSCPairResidualsConstraint*,bool> residualsConstraints;
      for (std::map<int,std::map<CSCDetId,bool> >::const_iterator iter = stationsToChambers.begin();  iter != stationsToChambers.end();  ++iter) {
        for (std::map<CSCDetId,bool>::const_iterator one = iter->second.begin();  one != iter->second.end();  ++one) {
          for (std::map<CSCDetId,bool>::const_iterator two = one;  two != iter->second.end();  ++two) {
            if (one != two) {
              std::map<std::pair<CSCDetId,CSCDetId>,CSCPairResidualsConstraint*>::const_iterator quick;

              quick = m_quickChamberLookup.find(std::pair<CSCDetId,CSCDetId>(one->first, two->first));
              if (quick != m_quickChamberLookup.end()) residualsConstraints[quick->second] = true;

              quick = m_quickChamberLookup.find(std::pair<CSCDetId,CSCDetId>(two->first, one->first));
              if (quick != m_quickChamberLookup.end()) residualsConstraints[quick->second] = true;
            }
          }
        }
      }

      for (std::map<CSCPairResidualsConstraint*,bool>::const_iterator residualsConstraint = residualsConstraints.begin();  residualsConstraint != residualsConstraints.end();  ++residualsConstraint) {
        residualsConstraint->first->addTrack(measurements, transientTrack, m_trackTransformer);
      }
    }
  }
}
void CSCOverlapsAlignmentAlgorithm::terminate ( ) [virtual]

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

Implements AlignmentAlgorithmBase.

Definition at line 310 of file CSCOverlapsAlignmentAlgorithm.cc.

References CSCPairResidualsConstraint::kModeRadius, m_alignableNavigator, m_alignmentParameterStore, m_combineME11, m_doAlignment, m_fitters, m_makeHistograms, m_mode, m_reportFileName, m_residualsConstraints, m_writeTemporaryFile, convertSQLitetoXML_cfg::output, and zeeHLT_cff::report.

                                              {
  // write residuals partial fits to temporary files for collection
  if (m_writeTemporaryFile != std::string("")) {
    std::ofstream output(m_writeTemporaryFile.c_str());
    for (std::vector<CSCPairResidualsConstraint*>::const_iterator residualsConstraint = m_residualsConstraints.begin();  residualsConstraint != m_residualsConstraints.end();  ++residualsConstraint) {
      (*residualsConstraint)->write(output);
    }
  }

  // write report for alignment results
  if (m_doAlignment) {
    std::ofstream report;
    bool writeReport = (m_reportFileName != std::string(""));
    if (writeReport) {
      report.open(m_reportFileName.c_str());
      report << "cscReports = []" << std::endl << std::endl
             << "class CSCChamberCorrection:" << std::endl
             << "    def __init__(self, name, detid, value):" << std::endl
             << "        self.name, self.detid, self.value = name, detid, value" << std::endl << std::endl
             << "class CSCErrorMode:" << std::endl
             << "    def __init__(self, error):" << std::endl
             << "        self.error = error" << std::endl
             << "        self.terms = {}" << std::endl
             << "        self.detids = {}" << std::endl
             << "    def addTerm(self, name, detid, coefficient):" << std::endl
             << "        self.terms[name] = coefficient" << std::endl
             << "        self.detids[name] = detid" << std::endl << std::endl
             << "class CSCConstraintResidual:" << std::endl
             << "    def __init__(self, i, j, before, uncert, residual, pull):" << std::endl
             << "        self.i, self.j, self.before, self.error, self.residual, self.pull = i, j, before, uncert, residual, pull" << std::endl << std::endl
             << "class CSCFitterReport:" << std::endl
             << "    def __init__(self, name, oldchi2, newchi2):" << std::endl
             << "        self.name, self.oldchi2, self.newchi2 = name, oldchi2, newchi2" << std::endl
             << "        self.chamberCorrections = []" << std::endl
             << "        self.errorModes = []" << std::endl
             << "        self.constraintResiduals = []" << std::endl << std::endl
             << "    def addChamberCorrection(self, name, detid, value):" << std::endl
             << "        self.chamberCorrections.append(CSCChamberCorrection(name, detid, value))" << std::endl << std::endl
             << "    def addErrorMode(self, error):" << std::endl
             << "        self.errorModes.append(CSCErrorMode(error))" << std::endl << std::endl
             << "    def addErrorModeTerm(self, name, detid, coefficient):" << std::endl
             << "        self.errorModes[-1].addTerm(name, detid, coefficient)" << std::endl << std::endl
             << "    def addCSCConstraintResidual(self, i, j, before, uncert, residual, pull):" << std::endl
             << "        self.constraintResiduals.append(CSCConstraintResidual(i, j, before, uncert, residual, pull))" << std::endl << std::endl
             << "import re" << std::endl
             << "def nameToKey(name):" << std::endl
             << "    match = re.match(\"ME([\\+\\-])([1-4])/([1-4])/([0-9]{2})\", name)" << std::endl
             << "    if match is None: return None" << std::endl
             << "    endcap, station, ring, chamber = match.groups()" << std::endl
             << "    if endcap == \"+\": endcap = 1" << std::endl
             << "    else: endcap = 2" << std::endl
             << "    station = int(station)" << std::endl
             << "    ring = int(ring)" << std::endl
             << "    chamber = int(chamber)" << std::endl
             << "    return endcap, station, ring, chamber" << std::endl << std::endl;
    }

    for (std::vector<CSCChamberFitter>::const_iterator fitter = m_fitters.begin();  fitter != m_fitters.end();  ++fitter) {
      if (m_mode == CSCPairResidualsConstraint::kModeRadius) {
        fitter->radiusCorrection(m_alignableNavigator, m_alignmentParameterStore, m_combineME11);
        


      }
      else {
        std::vector<CSCAlignmentCorrections*> corrections;
        fitter->fit(corrections);
         
        // corrections only exist if the fit was successful
        for (std::vector<CSCAlignmentCorrections*>::iterator correction = corrections.begin();  correction != corrections.end();  ++correction) {
           
           (*correction)->applyAlignment(m_alignableNavigator, m_alignmentParameterStore, m_mode, m_combineME11);
           if (m_makeHistograms) (*correction)->plot();
           if (writeReport) (*correction)->report(report);
        }
      }
    }
  }
}

Member Data Documentation

Definition at line 143 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by initialize(), and terminate().

Definition at line 142 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by initialize().

Definition at line 141 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by initialize(), and terminate().

Definition at line 139 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by terminate().

Definition at line 128 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCPairResidualsConstraint::error().

Definition at line 144 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and terminate().

Definition at line 152 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 153 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 154 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 136 of file CSCOverlapsAlignmentAlgorithm.h.

Definition at line 135 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by run().

Definition at line 129 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCPairResidualsConstraint::valid().

Definition at line 133 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm().

Definition at line 149 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 150 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 146 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

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

Definition at line 138 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by initialize().

Definition at line 134 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by terminate().

Definition at line 112 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 113 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 114 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 115 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 108 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 109 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 110 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 111 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 148 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 137 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by terminate().

Definition at line 104 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 105 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 106 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 107 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 100 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 101 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 102 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().

Definition at line 103 of file CSCOverlapsAlignmentAlgorithm.h.

Referenced by CSCOverlapsAlignmentAlgorithm(), and run().