Inheritance diagram for ATLAS_2012_CONF_2012_153:

Collaboration diagram for ATLAS_2012_CONF_2012_153:

Public Member Functions
void	finalize ()
AnalysisHandler &	handler () const
	Access the controlling AnalysisHandler object.
void	normalize (Histo1DPtr histo, double norm=1.0, bool includeoverflows=true)
void	scale (Histo1DPtr histo, double scale)
Analysis &	setCrossSection (double xs)
	Set the cross section from the generator.
void	divide (Histo1DPtr h1, Histo1DPtr h2, Scatter2DPtr s) const
void	divide (Profile1DPtr p1, Profile1DPtr p2, Scatter2DPtr s) const
void	divide (const YODA::Histo1D &h1, const YODA::Histo1D &h2, Scatter2DPtr s) const
void	divide (const YODA::Profile1D &p1, const YODA::Profile1D &p2, Scatter2DPtr s) const
const vector< AnalysisObjectPtr > &	plots () const
	List of registered plot objects.
Constructors etc.
	ATLAS_2012_CONF_2012_153 ()
	Constructor.
Analysis methods
void	init ()
	Book histograms and initialise projections before the run.
void	analyze (const Event &event)
	Perform the per-event analysis.
Metadata
Metadata is used for querying from the command line and also for building web pages and the analysis pages in the Rivet manual.
const AnalysisInfo &	info () const
	Get the actual AnalysisInfo object in which all this metadata is stored.
virtual std::string	name () const
	Get the name of the analysis.
virtual std::string	inspireId () const
	Get the Inspire ID code for this analysis.
virtual std::string	spiresId () const
	Get the SPIRES ID code for this analysis (~deprecated).
virtual std::vector< std::string >	authors () const
	Names & emails of paper/analysis authors.
virtual std::string	summary () const
	Get a short description of the analysis.
virtual std::string	description () const
	Get a full description of the analysis.
virtual std::string	runInfo () const
	Information about the events needed as input for this analysis.
virtual std::string	experiment () const
	Experiment which performed and published this analysis.
virtual std::string	collider () const
	Collider on which the experiment ran.
virtual std::string	year () const
	When the original experimental analysis was published.
virtual std::vector< std::string >	references () const
	Journal, and preprint references.
virtual std::string	bibKey () const
	BibTeX citation key for this article.
virtual std::string	bibTeX () const
	BibTeX citation entry for this article.
virtual std::string	status () const
	Whether this analysis is trusted (in any way!)
virtual std::vector< std::string >	todos () const
	Any work to be done on this analysis.
virtual const std::vector < PdgIdPair > &	requiredBeams () const
	Return the allowed pairs of incoming beams required by this analysis.
virtual Analysis &	setRequiredBeams (const std::vector< PdgIdPair > &requiredBeams)
	Declare the allowed pairs of incoming beams required by this analysis.
virtual const std::vector < std::pair< double, double > > &	requiredEnergies () const
	Sets of valid beam energy pairs, in GeV.
virtual Analysis &	setRequiredEnergies (const std::vector< std::pair< double, double > > &requiredEnergies)
	Declare the list of valid beam energy pairs, in GeV.
bool	needsCrossSection () const
Analysis &	setNeedsCrossSection (bool needed=true)
Internal metadata modifying methods
AnalysisInfo &	info ()
	Get the actual AnalysisInfo object in which all this metadata is stored (non-const).
Run conditions
const ParticlePair &	beams () const
	Incoming beams for this run.
const PdgIdPair	beamIds () const
	Incoming beam IDs for this run.
double	sqrtS () const
	Centre of mass energy for this run.
Analysis / beam compatibility testing
bool	isCompatible (const ParticlePair &beams) const
	Check if analysis is compatible with the provided beam particle IDs and energies.
bool	isCompatible (PdgId beam1, PdgId beam2, double e1, double e2) const
	Check if analysis is compatible with the provided beam particle IDs and energies.
bool	isCompatible (const PdgIdPair &beams, const std::pair< double, double > &energies) const
	Check if analysis is compatible with the provided beam particle IDs and energies.
Projection "getting" functions
std::set< ConstProjectionPtr >	getProjections () const
	Get the contained projections, including recursion.
template<typename PROJ >
const PROJ &	getProjection (const std::string &name) const
	Get the named projection, specifying return type via a template argument.
const Projection &	getProjection (const std::string &name) const
Projection applying functions
template<typename PROJ >
const PROJ &	applyProjection (const Event &evt, const PROJ &proj) const
	Apply the supplied projection on event.
template<typename PROJ >
const PROJ &	applyProjection (const Event &evt, const Projection &proj) const
	Apply the supplied projection on event.
template<typename PROJ >
const PROJ &	applyProjection (const Event &evt, const std::string &name) const
	Apply the named projection on event.
Protected Member Functions
Log &	getLog () const
	Get a Log object based on the name() property of the calling analysis object.
double	crossSection () const
	Get the process cross-section in pb. Throws if this hasn't been set.
double	crossSectionPerEvent () const
size_t	numEvents () const
double	sumOfWeights () const
void	addPlot (AnalysisObjectPtr)
	Add a plot object to the final output list.
ProjectionHandler &	getProjHandler () const
	Get a reference to the ProjectionHandler for this thread.
AIDA analysis infrastructure.
const std::string	histoDir () const
	Get the canonical histogram "directory" path for this analysis.
const std::string	histoPath (const std::string &hname) const
	Get the canonical histogram path for the named histogram in this analysis.
const std::string	histoPath (size_t datasetId, size_t xAxisId, size_t yAxisId) const
	Get the canonical histogram path for the numbered histogram in this analysis.
const std::string	makeAxisCode (size_t datasetId, size_t xAxisId, size_t yAxisId) const
	Get the internal histogram name for given d, x and y (cf. HepData)
Internal histogram booking (for use by Analysis sub-classes).
const YODA::Scatter2D &	referenceData (const string &hname) const
	Get reference data for a named histo.
const YODA::Scatter2D &	referenceData (size_t datasetId, size_t xAxisId, size_t yAxisId) const
	Get reference data for a numbered histo.
Histo1DPtr	bookHisto1D (const std::string &name, size_t nbins, double lower, double upper, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
Histo1DPtr	bookHisto1D (const std::string &name, const std::vector< double > &binedges, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
Histo1DPtr	bookHisto1D (const std::string &name, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
Histo1DPtr	bookHisto1D (size_t datasetId, size_t xAxisId, size_t yAxisId, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
Internal profile histogram booking (for use by Analysis sub-classes).
Profile1DPtr	bookProfile1D (const std::string &name, size_t nbins, double lower, double upper, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
Profile1DPtr	bookProfile1D (const std::string &name, const std::vector< double > &binedges, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
Profile1DPtr	bookProfile1D (const std::string &name, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
Profile1DPtr	bookProfile1D (size_t datasetId, size_t xAxisId, size_t yAxisId, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
Internal data point set booking (for use by Analysis sub-classes).
Scatter2DPtr	bookScatter2D (const std::string &name, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
Scatter2DPtr	bookScatter2D (const std::string &name, size_t npts, double lower, double upper, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
Scatter2DPtr	bookScatter2D (const std::string &name, const std::string &title)
Scatter2DPtr	bookScatter2D (size_t datasetId, size_t xAxisId, size_t yAxisId, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
Projection registration functions
template<typename PROJ >
const PROJ &	addProjection (const PROJ &proj, const std::string &name)
const Projection &	_addProjection (const Projection &proj, const std::string &name)
	Untemplated function to do the work...
Protected Attributes
string	_defaultname
	Name passed to constructor (used to find .info analysis data file, and as a fallback)
shared_ptr< AnalysisInfo >	_info
	Pointer to analysis metadata object.
bool	_allowProjReg
	Flag to forbid projection registration in analyses until the init phase.
Private Attributes
Histograms
Histo1DPtr	_hist_electrons
Histo1DPtr	_hist_muons
Histo1DPtr	_hist_leptons
Histo1DPtr	_hist_4leptons
Histo1DPtr	_hist_veto
Histo1DPtr	_hist_etmiss
Histo1DPtr	_hist_meff
Histo1DPtr	_count_SR1
Histo1DPtr	_count_SR2

Detailed Description

Definition at line 17 of file ATLAS_2012_CONF_2012_153.cc.

Constructor & Destructor Documentation

ATLAS_2012_CONF_2012_153 ( ) [inline]

Constructor.

Definition at line 24 of file ATLAS_2012_CONF_2012_153.cc.

      : Analysis("ATLAS_2012_CONF_2012_153")
    {    }

Member Function Documentation

const Projection & _addProjection	(	const Projection &	proj,
		const std::string &	name
	)		`[protected, inherited]`

Untemplated function to do the work...

Definition at line 33 of file ProjectionApplier.cc.

References ProjectionApplier::_allowProjReg, ProjectionApplier::getProjHandler(), ProjectionApplier::name(), Projection::name(), and ProjectionHandler::registerProjection().

Referenced by ProjectionApplier::addProjection().

                                                                             {
    if (!_allowProjReg) {
      cerr << "Trying to register projection '"
           << proj.name() << "' before init phase in '" << this->name() << "'." << endl;
      exit(2);
    }
    const Projection& reg = getProjHandler().registerProjection(*this, proj, name);
    return reg;
  }

void addPlot ( AnalysisObjectPtr ao ) [protected, inherited]

Add a plot object to the final output list.

Todo:: 2D versions of scale and normalize... or ditch these completely?

Definition at line 475 of file Analysis.cc.

References Analysis::_plotobjects.

Referenced by Analysis::bookHisto1D(), Analysis::bookProfile1D(), and Analysis::bookScatter2D().

                                             {
    _plotobjects.push_back(ao);
  }

const PROJ& addProjection	(	const PROJ &	proj,
		const std::string &	name
	)		`[inline, protected, inherited]`

Register a contained projection. The type of the argument is used to instantiate a new projection internally: this new object is applied to events rather than the argument object. Hence you are advised to only use locally-scoped Projection objects in your Projection and Analysis constructors, and to avoid polymorphism (e.g. handling ConcreteProjection via a pointer or reference to type Projection) since this will screw up the internal type management.

Definition at line 113 of file ProjectionApplier.hh.

References ProjectionApplier::_addProjection().

                                                                       {
      const Projection& reg = _addProjection(proj, name);
      const PROJ& rtn = dynamic_cast<const PROJ&>(reg);
      return rtn;
    }

void analyze ( const Event & event ) [inline, virtual]

Perform the per-event analysis.

Implements Analysis.

Definition at line 100 of file ATLAS_2012_CONF_2012_153.cc.

                                     {
      const double weight = event.weight();
      // get the jet candidates
      Jets cand_jets;
      foreach (const Jet& jet,
               applyProjection<FastJets>(event, "AntiKtJets04").jetsByPt(20.0*GeV) ) {
        if ( fabs( jet.momentum().eta() ) < 2.5 ) {
          cand_jets.push_back(jet);
        }
      }

      // candidate muons
      ParticleVector cand_mu = applyProjection<IdentifiedFinalState>(event, "muons").particlesByPt();

      // candidate electrons
      // Discard if two electrons are within R=0.1
      ParticleVector temp = applyProjection<IdentifiedFinalState>(event, "elecs").particlesByE();
      vector<bool> vetoed(temp.size(),false);
      ParticleVector cand_e;
      for (unsigned int ix=0; ix<temp.size(); ++ix) {
        if(vetoed[ix]) continue;
        for (unsigned int iy=ix+1; iy<temp.size(); ++iy) {
          if( deltaR(temp[ix].momentum(),temp[iy].momentum()) < 0.1 ) {
            vetoed[iy] = true;
          }
        }
        if(!vetoed[ix]) cand_e.push_back(temp[ix]);
      }

      // Sort by transverse momentum
      std::sort(cand_e.begin(), cand_e.end(), cmpParticleByPt);

      // resolve jet/lepton ambiguity
      Jets recon_jets;
      foreach ( const Jet& jet, cand_jets ) {
        bool away_from_e = true;
        foreach ( const Particle & e, cand_e ) {
          if ( deltaR(e.momentum(),jet.momentum()) <= 0.2 ) {
            away_from_e = false;
            break;
          }
        }
        if ( away_from_e )
          recon_jets.push_back( jet );
      }

      // only keep electrons more than R=0.4 from jets
      ParticleVector cand2_e;
      foreach (const Particle & e, cand_e) {
        // at least 0.4 from any jets
        bool away = true;
        foreach ( const Jet& jet, recon_jets ) {
          if ( deltaR(e.momentum(),jet.momentum()) < 0.4 ) {
            away = false;
            break;
          }
        }
        // if isolated keep it
        if ( away )
          cand2_e.push_back( e );
      }

      // only keep muons more than R=0.4 from jets
      ParticleVector cand2_mu;
      foreach(const Particle & mu, cand_mu ) {
        bool away = true;
        // at least 0.4 from any jets
        foreach ( const Jet& jet, recon_jets ) {
          if ( deltaR(mu.momentum(),jet.momentum()) < 0.4 ) {
            away = false;
            break;
          }
        }
        if ( away )
          cand2_mu.push_back( mu );
      }

      // electron and muon more than 0.1 apart
      ParticleVector cand3_e;
      foreach ( const Particle & e, cand2_e ) {
        bool away = true;
        foreach( const Particle & mu, cand2_mu ) {
          if( deltaR(e.momentum(),mu.momentum()) < 0.1) {
            away = false;
            break;
          }
        }
        if(away) cand3_e.push_back(e);
      }
      ParticleVector cand3_mu;
      foreach( const Particle & mu, cand2_mu ) {
        bool away = true;
        foreach ( const Particle & e, cand2_e ) {
          if( deltaR(e.momentum(),mu.momentum()) < 0.1) {
            away = false;
            break;
          }
        }
        if(away) cand3_mu.push_back(mu);
      }

      // pTmiss
      ParticleVector vfs_particles =
        applyProjection<VisibleFinalState>(event, "vfs").particles();
      FourMomentum pTmiss;
      foreach ( const Particle & p, vfs_particles ) {
        pTmiss -= p.momentum();
      }
      double eTmiss = pTmiss.pT();

      // apply electron isolation
      ParticleVector chg_tracks =
        applyProjection<ChargedFinalState>(event, "cfs").particles();
      ParticleVector cand4_e;
      foreach ( const Particle & e, cand3_e ) {
        // charge isolation
        double pTinCone = -e.momentum().perp();
        foreach ( const Particle & track, chg_tracks ) {
          if(track.momentum().perp()>0.4 &&
             deltaR(e.momentum(),track.momentum()) <= 0.3 )
            pTinCone += track.momentum().pT();
        }
        if (pTinCone/e.momentum().perp()>0.16) continue;
        // all particles isolation
        pTinCone = -e.momentum().perp();
        foreach ( const Particle & p, vfs_particles ) {
          if(abs(p.pdgId())!=MUON &&
             deltaR(e.momentum(),p.momentum()) <= 0.3 )
            pTinCone += p.momentum().pT();
        }
        if (pTinCone/e.momentum().perp()<0.18) {
          cand4_e.push_back(e);
        }
      }

      // apply muon isolation
      ParticleVector cand4_mu;
      foreach ( const Particle & mu, cand3_mu ) {
        double pTinCone = -mu.momentum().perp();
        foreach ( const Particle & track, chg_tracks ) {
          if(track.momentum().perp()>1.0 &&
             deltaR(mu.momentum(),track.momentum()) <= 0.3 )
            pTinCone += track.momentum().pT();
        }
        if (pTinCone/mu.momentum().perp()<0.12) {
          cand4_mu.push_back(mu);
        }
      }

      // same SOSF pairs m>12.
      ParticleVector recon_e;
      foreach(const Particle & e, cand4_e) {
        bool veto=false;
        foreach(const Particle & e2, cand4_e) {
          if(e.pdgId()*e2.pdgId()<0&&(e.momentum()+e2.momentum()).mass()<12.) {
            veto=true;
            break;
          }
        }
        if(!veto) recon_e.push_back(e);
      }
      ParticleVector recon_mu;
      foreach(const Particle & mu, cand4_mu) {
        bool veto=false;
        foreach(const Particle & mu2, cand4_mu) {
          if(mu.pdgId()*mu2.pdgId()<0&&(mu.momentum()+mu2.momentum()).mass()<12.) {
            veto=true;
            break;
          }
        }
        if(!veto) recon_mu.push_back(mu);
      }

      // now only use recon_jets, recon_mu, recon_e
      _hist_electrons->fill(recon_e.size(), weight);
      _hist_muons->fill(recon_mu.size(), weight);
      _hist_leptons->fill(recon_mu.size() + recon_e.size(), weight);
      if( recon_mu.size() + recon_e.size() > 3) {
        _hist_4leptons->fill(0.5, weight);
      }

      // reject events with less than 4 electrons and muons
      if ( recon_mu.size() + recon_e.size() < 4 ) {
        MSG_DEBUG("To few charged leptons left after selection");
        vetoEvent;
      }


      // or two lepton trigger
      bool passDouble =
        (recon_mu.size()>=2 && ( (recon_mu[1].momentum().perp()>14.) ||
                                 (recon_mu[0].momentum().perp()>18. && recon_mu[1].momentum().perp()>10.) )) ||
        (recon_e.size() >=2 && ( (recon_e [1].momentum().perp()>14.) ||
                                 (recon_e [0].momentum().perp()>25. && recon_e [1].momentum().perp()>10.) )) ||
        (!recon_e.empty() && !recon_mu.empty() &&
         ( (recon_e[0].momentum().perp()>14. && recon_mu[0].momentum().perp()>10.)||
           (recon_e[0].momentum().perp()>10. && recon_mu[0].momentum().perp()>18.) ));

      // must pass a trigger
       if(!passDouble ) {
         MSG_DEBUG("Hardest lepton fails trigger");
         _hist_veto->fill(0.5, weight);
         vetoEvent;
       }

      // calculate meff
      double meff = eTmiss;
      foreach ( const Particle & e , recon_e  )
        meff += e.momentum().perp();
      foreach ( const Particle & mu, recon_mu )
        meff += mu.momentum().perp();
      foreach ( const Jet & jet, recon_jets ) {
        double pT = jet.momentum().perp();
        if(pT>40.) meff += pT;
      }

      // 2/3 leptons --> find 1 SFOS pair in range and veto event
      // 4+  leptons --> find 2 SFOS pairs and in range veto event
      for(unsigned int ix=0;ix<recon_e.size();++ix) {
        for(unsigned int iy=ix+1;iy<recon_e.size();++iy) {
          if(recon_e[ix].pdgId()*recon_e[iy].pdgId()>0) continue;
          FourMomentum ppair = recon_e[ix].momentum()+recon_e[iy].momentum();
          double mtest = ppair.mass();
          if(mtest>81.2 && mtest<101.2) vetoEvent;

          // check triplets with electron
          for(unsigned int iz=0;iz<recon_e.size();++iz) {
            if(iz==ix||iz==iy) continue;
            mtest = (ppair+recon_e[iz].momentum()).mass();
            if(mtest>81.2 && mtest<101.2) vetoEvent;
          }

          // check triplets with muon
          for(unsigned int iz=0;iz<recon_mu.size();++iz) {
            mtest = (ppair+recon_mu[iz].momentum()).mass();
            if(mtest>81.2 && mtest<101.2) vetoEvent;
          }

          // check quadruplets with electrons
          for(unsigned int iz=0;iz<recon_e.size();++iz) {
            for(unsigned int iw=iz+1;iw<recon_e.size();++iw) {
              if(iz==ix||iz==iy||iw==ix||iw==iy) continue;
              if(recon_e[iz].pdgId()*recon_e[iw].pdgId()>0) continue;
              mtest = (ppair+recon_e[iz].momentum()+recon_e[iw].momentum()).mass();
              if(mtest>81.2 && mtest<101.2) vetoEvent;
            }
          }
          // check quadruplets with muons
          for(unsigned int iz=0;iz<recon_mu.size();++iz) {
            for(unsigned int iw=iz+1;iw<recon_mu.size();++iw) {
              if(recon_mu[iz].pdgId()*recon_mu[iw].pdgId()>0) continue;
              mtest = (ppair+recon_mu[iz].momentum()+recon_mu[iw].momentum()).mass();
              if(mtest>81.2 && mtest<101.2) vetoEvent;
            }
          }
        }
      }

      // Muon pairs
      for(unsigned int ix=0;ix<recon_mu.size();++ix) {
        for(unsigned int iy=ix+1;iy<recon_mu.size();++iy) {
          if(recon_mu[ix].pdgId()*recon_mu[iy].pdgId()>0) continue;
          FourMomentum ppair = recon_mu[ix].momentum()+recon_mu[iy].momentum();
          double mtest = ppair.mass();
          if(mtest>81.2 && mtest<101.2) vetoEvent;

         // check triplets with muon
          for(unsigned int iz=0;iz<recon_mu.size();++iz) {
            if(iz==ix||iz==iy) continue;
            mtest = (ppair+recon_mu[iz].momentum()).mass();
            if(mtest>81.2 && mtest<101.2) vetoEvent;
          }

         // check triplets with electron
          for(unsigned int iz=0;iz<recon_e.size();++iz) {
            mtest = (ppair+recon_e[iz].momentum()).mass();
            if(mtest>81.2 && mtest<101.2) vetoEvent;
          }

        // check muon quadruplets
          for(unsigned int iz=0;iz<recon_mu.size();++iz) {
            for(unsigned int iw=iz+1;iy<recon_mu.size();++iy) {
              if(iz==ix||iz==iy||iw==ix||iw==iy) continue;
              if(recon_mu[iz].pdgId()*recon_mu[iw].pdgId()>0) continue;
              mtest = (ppair+recon_mu[iz].momentum()+recon_mu[iw].momentum()).mass();
              if(mtest>81.2 && mtest<101.2) vetoEvent;
            }
          }
        }
      }

      //make the control plots
      _hist_etmiss ->fill(eTmiss,weight);
      _hist_meff   ->fill(meff  ,weight);
      // finally the counts
      if(eTmiss>50.) _count_SR1->fill(0.5,weight);
      if(meff  >0. ) _count_SR2->fill(0.5,weight);

    }

const PROJ& applyProjection	(	const Event &	evt,
		const PROJ &	proj
	)		const `[inline, inherited]`

Apply the supplied projection on event.

Definition at line 67 of file ProjectionApplier.hh.

References ProjectionApplier::_applyProjection().

Referenced by DISFinalState::project().

                                                                          {
      return pcast<PROJ>(_applyProjection(evt, proj));
    }

const PROJ& applyProjection	(	const Event &	evt,
		const Projection &	proj
	)		const `[inline, inherited]`

Apply the supplied projection on event.

Definition at line 74 of file ProjectionApplier.hh.

References ProjectionApplier::_applyProjection().

                                                                                {
      return pcast<PROJ>(_applyProjection(evt, proj));
    }

const PROJ& applyProjection	(	const Event &	evt,
		const std::string &	name
	)		const `[inline, inherited]`

Apply the named projection on event.

Definition at line 81 of file ProjectionApplier.hh.

References ProjectionApplier::_applyProjection().

                                                                               {
      return pcast<PROJ>(_applyProjection(evt, name));
    }

virtual std::vector<std::string> authors ( ) const [inline, virtual, inherited]

Names & emails of paper/analysis authors.

Names and email of authors in 'NAME <EMAIL>' format. The first name in the list should be the primary contact person.

Definition at line 136 of file Analysis.hh.

References AnalysisInfo::authors(), and Analysis::info().

                                                 {
      return info().authors();
    }

const PdgIdPair beamIds ( ) const [inherited]

Incoming beam IDs for this run.

Definition at line 32 of file Analysis.cc.

References AnalysisHandler::beamIds(), and Analysis::handler().

Referenced by UA5_1982_S875503::finalize(), and UA5_1982_S875503::init().

                                          {
    return handler().beamIds();
  }

const ParticlePair & beams ( ) const [inherited]

Incoming beams for this run.

Definition at line 28 of file Analysis.cc.

References AnalysisHandler::beams(), and Analysis::handler().

Referenced by BABAR_2005_S6181155::analyze(), BABAR_2007_S6895344::analyze(), CLEO_2004_S5809304::analyze(), BELLE_2006_S6265367::analyze(), OPAL_1994_S2927284::analyze(), SLD_2004_S5693039::analyze(), OPAL_1998_S3780481::analyze(), SLD_1999_S3743934::analyze(), OPAL_1995_S3198391::analyze(), OPAL_1997_S3608263::analyze(), OPAL_2000_S4418603::analyze(), ALEPH_2002_S4823664::analyze(), DELPHI_1999_S3960137::analyze(), OPAL_1996_S3257789::analyze(), OPAL_1998_S3702294::analyze(), DELPHI_1995_S3137023::analyze(), SLD_2002_S4869273::analyze(), ALEPH_2001_S4656318::analyze(), DELPHI_2002_069_CONF_603::analyze(), OPAL_1998_S3749908::analyze(), OPAL_1997_S3396100::analyze(), ALEPH_1999_S4193598::analyze(), MC_WPOL::analyze(), ALEPH_1996_S3486095::analyze(), ALEPH_2004_S5765862::analyze(), DELPHI_1996_S3430090::analyze(), MC_WPOL::init(), and Analysis::isCompatible().

                                            {
    return handler().beams();
  }

virtual std::string bibKey ( ) const [inline, virtual, inherited]

BibTeX citation key for this article.

Definition at line 189 of file Analysis.hh.

References AnalysisInfo::bibKey(), and Analysis::info().

                                     {
      return info().bibKey();
    }

virtual std::string bibTeX ( ) const [inline, virtual, inherited]

BibTeX citation entry for this article.

Definition at line 194 of file Analysis.hh.

References AnalysisInfo::bibTeX(), and Analysis::info().

                                     {
      return info().bibTeX();
    }

Histo1DPtr bookHisto1D	(	const std::string &	name,
		size_t	nbins,
		double	lower,
		double	upper,
		const std::string &	title = `""`,
		const std::string &	xtitle = `""`,
		const std::string &	ytitle = `""`
	)		`[protected, inherited]`

Book a 1D histogram with nbins uniformly distributed across the range lower - upper . (NB. this returns a pointer rather than a reference since it will have to be stored in the analysis class - there's no point in forcing users to explicitly get the pointer from a reference before they can use it!)

Definition at line 213 of file Analysis.cc.

References Analysis::addPlot(), Analysis::histoPath(), MSG_TRACE, and Analysis::name().

                                                                               {
    const string path = histoPath(hname);
    Histo1DPtr hist( new Histo1D(nbins, lower, upper, path, title) );
    addPlot(hist);
    MSG_TRACE("Made histogram " << hname <<  " for " << name());
    hist->setAnnotation("XLabel", xtitle);
    hist->setAnnotation("YLabel", ytitle);
    return hist;
  }

Histo1DPtr bookHisto1D	(	const std::string &	name,
		const std::vector< double > &	binedges,
		const std::string &	title = `""`,
		const std::string &	xtitle = `""`,
		const std::string &	ytitle = `""`
	)		`[protected, inherited]`

Book a 1D histogram with non-uniform bins defined by the vector of bin edges binedges . (NB. this returns a pointer rather than a reference since it will have to be stored in the analysis class - there's no point in forcing users to explicitly get the pointer from a reference before they can use it!)

Definition at line 227 of file Analysis.cc.

References Analysis::addPlot(), Analysis::histoPath(), MSG_TRACE, and Analysis::name().

                                                         {
    const string path = histoPath(hname);
    Histo1DPtr hist( new Histo1D(binedges, path, title) );
    addPlot(hist);
    MSG_TRACE("Made histogram " << hname <<  " for " << name());
    hist->setAnnotation("XLabel", xtitle);
    hist->setAnnotation("YLabel", ytitle);
    return hist;
  }

Histo1DPtr bookHisto1D	(	const std::string &	name,
		const std::string &	title = `""`,
		const std::string &	xtitle = `""`,
		const std::string &	ytitle = `""`
	)		`[protected, inherited]`

Book a 1D histogram based on the name in the corresponding AIDA file. The binnings will be obtained by reading the bundled AIDA data record file with the same filename as the analysis' name() property.

Definition at line 198 of file Analysis.cc.

References Analysis::addPlot(), Analysis::histoPath(), MSG_TRACE, Analysis::name(), and Analysis::referenceData().

  {
    const Scatter2D & refdata = referenceData(hname);
    const string path = histoPath(hname);
    Histo1DPtr hist( new Histo1D(refdata, path) );
    addPlot(hist);
    MSG_TRACE("Made histogram " << hname <<  " for " << name());
    hist->setTitle(title);
    hist->setAnnotation("XLabel", xtitle);
    hist->setAnnotation("YLabel", ytitle);
    return hist;
  }

Histo1DPtr bookHisto1D	(	size_t	datasetId,
		size_t	xAxisId,
		size_t	yAxisId,
		const std::string &	title = `""`,
		const std::string &	xtitle = `""`,
		const std::string &	ytitle = `""`
	)		`[protected, inherited]`

Book a 1D histogram based on the paper, dataset and x/y-axis IDs in the corresponding HepData record. The binnings will be obtained by reading the bundled AIDA data record file of the same filename as the analysis' name() property.

Definition at line 189 of file Analysis.cc.

References Analysis::bookHisto1D(), and Analysis::makeAxisCode().

  {
    const string axisCode = makeAxisCode(datasetId, xAxisId, yAxisId);
    return bookHisto1D(axisCode, title, xtitle, ytitle);
  }

Profile1DPtr bookProfile1D	(	const std::string &	name,
		size_t	nbins,
		double	lower,
		double	upper,
		const std::string &	title = `""`,
		const std::string &	xtitle = `""`,
		const std::string &	ytitle = `""`
	)		`[protected, inherited]`

Book a 1D profile histogram with nbins uniformly distributed across the range lower - upper . (NB. this returns a pointer rather than a reference since it will have to be stored in the analysis class - there's no point in forcing users to explicitly get the pointer from a reference before they can use it!)

Definition at line 304 of file Analysis.cc.

References Analysis::addPlot(), Analysis::histoPath(), MSG_TRACE, and Analysis::name().

Referenced by Analysis::bookProfile1D(), ATLAS_2010_S8894728::init(), ATLAS_2011_S8994773::init(), ALICE_2011_S8945144::init(), CMS_2012_I1107658::init(), ATLAS_2010_S8591806::init(), CDF_2012_NOTE10874::init(), STAR_2008_S7993412::init(), CDF_2008_S7782535::init(), D0_1996_S3324664::init(), MC_LEADJETUE::init(), MC_PHOTONJETUE::init(), ATLAS_2011_S8924791::init(), CDF_2005_S6217184::init(), MC_GENERIC::init(), UA1_1990_S2044935::init(), STAR_2006_S6860818::init(), STAR_2009_UE_HELEN::init(), MC_PHOTONS::init(), ALICE_2010_S8706239::init(), ALEPH_2001_S4656318::init(), DELPHI_2002_069_CONF_603::init(), MC_WPOL::init(), CDF_2009_S8233977::init(), CDF_2010_S8591881_DY::init(), CDF_2008_NOTE_9351::init(), CDF_2010_S8591881_QCD::init(), CDF_2008_LEADINGJETS::init(), CDF_2001_S4751469::init(), ATLAS_2010_S8918562::init(), DELPHI_1996_S3430090::init(), CDF_2004_S5839831::init(), H1_1994_S2919893::init(), H1_2000_S4129130::init(), and ATLAS_2011_S9126244::initializePlots().

                                                                                   {
    const string path = histoPath(hname);
    Profile1DPtr prof( new Profile1D(nbins, lower, upper, path, title) );
    addPlot(prof);
    MSG_TRACE("Made profile histogram " << hname <<  " for " << name());
    prof->setAnnotation("XLabel", xtitle);
    prof->setAnnotation("YLabel", ytitle);
    return prof;
  }

Profile1DPtr bookProfile1D	(	const std::string &	name,
		const std::vector< double > &	binedges,
		const std::string &	title = `""`,
		const std::string &	xtitle = `""`,
		const std::string &	ytitle = `""`
	)		`[protected, inherited]`

Book a 1D profile histogram with non-uniform bins defined by the vector of bin edges binedges . (NB. this returns a pointer rather than a reference since it will have to be stored in the analysis class - there's no point in forcing users to explicitly get the pointer from a reference before they can use it!)

Definition at line 318 of file Analysis.cc.

References Analysis::addPlot(), Analysis::histoPath(), MSG_TRACE, and Analysis::name().

                                                                                   {
    const string path = histoPath(hname);
    Profile1DPtr prof( new Profile1D(binedges, path, title) );
    addPlot(prof);
    MSG_TRACE("Made profile histogram " << hname <<  " for " << name());
    prof->setAnnotation("XLabel", xtitle);
    prof->setAnnotation("YLabel", ytitle);
    return prof;
  }

Profile1DPtr bookProfile1D	(	const std::string &	name,
		const std::string &	title = `""`,
		const std::string &	xtitle = `""`,
		const std::string &	ytitle = `""`
	)		`[protected, inherited]`

Book a 1D profile histogram based on the name in the corresponding AIDA file. The binnings will be obtained by reading the bundled AIDA data record file with the same filename as the analysis' name() property.

Definition at line 289 of file Analysis.cc.

References Analysis::addPlot(), Analysis::histoPath(), MSG_TRACE, Analysis::name(), and Analysis::referenceData().

  {
    const Scatter2D & refdata = referenceData(hname);
    const string path = histoPath(hname);
    Profile1DPtr prof( new Profile1D(refdata, path) );
    addPlot(prof);
    MSG_TRACE("Made profile histogram " << hname <<  " for " << name());
    prof->setTitle(title);
    prof->setAnnotation("XLabel", xtitle);
    prof->setAnnotation("YLabel", ytitle);
    return prof;
  }

Profile1DPtr bookProfile1D	(	size_t	datasetId,
		size_t	xAxisId,
		size_t	yAxisId,
		const std::string &	title = `""`,
		const std::string &	xtitle = `""`,
		const std::string &	ytitle = `""`
	)		`[protected, inherited]`

Book a 1D profile histogram based on the paper, dataset and x/y-axis IDs in the corresponding HepData record. The binnings will be obtained by reading the bundled AIDA data record file of the same filename as the analysis' name() property.

Definition at line 281 of file Analysis.cc.

References Analysis::bookProfile1D(), and Analysis::makeAxisCode().

                                                                                   {
    const string axisCode = makeAxisCode(datasetId, xAxisId, yAxisId);
    return bookProfile1D(axisCode, title, xtitle, ytitle);
  }

Scatter2DPtr bookScatter2D	(	const std::string &	name,
		const std::string &	title = `""`,
		const std::string &	xtitle = `""`,
		const std::string &	ytitle = `""`
	)		`[protected, inherited]`

Book a 2-dimensional data point set. (NB. this returns a pointer rather than a reference since it will have to be stored in the analysis class - there's no point in forcing users to explicitly get the pointer from a reference before they can use it!)

Definition at line 343 of file Analysis.cc.

References Analysis::addPlot(), Analysis::histoPath(), MSG_TRACE, and Analysis::name().

Referenced by Analysis::bookScatter2D(), ALEPH_2004_S5765862::finalize(), ATLAS_2010_S8894728::init(), ALICE_2011_S8909580::init(), CMS_2011_S8978280::init(), CMS_2011_S9088458::init(), STAR_2006_S6500200::init(), ATLAS_2011_S9002537::init(), MC_JetAnalysis::init(), CDF_2008_S7782535::init(), CMS_2012_I1102908::init(), MC_WJETS::init(), MC_GENERIC::init(), CDF_1994_S2952106::init(), CDF_2005_S6217184::init(), D0_2001_S4674421::init(), STAR_2006_S6860818::init(), ATLAS_2011_S9128077::init(), MC_XS::init(), D0_2008_S7837160::init(), CDF_1996_S3418421::init(), UA5_1988_S1867512::init(), ATLAS_2012_I1083318::init(), ATLAS_2011_I944826::init(), CDF_2008_S7541902::init(), D0_2008_S7719523::init(), ATLAS_2011_I945498::init(), SLD_2004_S5693039::init(), SLD_1999_S3743934::init(), ATLAS_2011_S9126244::initializePlots(), and ATLAS_2012_I1094568::InitializePlots().

                                                                                   {
    const string path = histoPath(hname);
    Scatter2DPtr dps( new Scatter2D(path, title) );
    addPlot(dps);
    MSG_TRACE("Made data point set " << hname <<  " for " << name());
    dps->setAnnotation("XLabel", xtitle);
    dps->setAnnotation("YLabel", ytitle);
    return dps;
  }

Scatter2DPtr bookScatter2D	(	const std::string &	name,
		size_t	npts,
		double	lower,
		double	upper,
		const std::string &	title = `""`,
		const std::string &	xtitle = `""`,
		const std::string &	ytitle = `""`
	)		`[protected, inherited]`

Book a 2-dimensional data point set with equally spaced points in a range. (NB. this returns a pointer rather than a reference since it will have to be stored in the analysis class - there's no point in forcing users to explicitly get the pointer from a reference before they can use it!)

Definition at line 355 of file Analysis.cc.

References Analysis::bookScatter2D().

                                                                                   {
    Scatter2DPtr dps = bookScatter2D(hname, title, xtitle, ytitle);
    const double binwidth = (upper-lower)/npts;
    for (size_t pt = 0; pt < npts; ++pt) {
      const double bincentre = lower + (pt + 0.5) * binwidth;
      // @todo YODA check
      dps->addPoint(bincentre, 0, binwidth/2.0, 0);
      // IMeasurement* meas = dps->point(pt)->coordinate(0);
      // meas->setValue(bincentre);
      // meas->setErrorPlus(binwidth/2.0);
      // meas->setErrorMinus(binwidth/2.0);
    }
    return dps;
  }

Scatter2DPtr bookScatter2D	(	const std::string &	name,
		const std::string &	title
	)		`[protected, inherited]`

Book a 2-dimensional data point set based on the corresponding AIDA data file. The binnings (x-errors) will be obtained by reading the bundled AIDA data record file of the same filename as the analysis' name() property.

Scatter2DPtr bookScatter2D	(	size_t	datasetId,
		size_t	xAxisId,
		size_t	yAxisId,
		const std::string &	title = `""`,
		const std::string &	xtitle = `""`,
		const std::string &	ytitle = `""`
	)		`[protected, inherited]`

Book a 2-dimensional data point set based on the paper, dataset and x/y-axis IDs in the corresponding HepData record. The binnings (x-errors) will be obtained by reading the bundled AIDA data record file of the same filename as the analysis' name() property.

Definition at line 335 of file Analysis.cc.

References Analysis::bookScatter2D(), and Analysis::makeAxisCode().

                                                                                   {
    const string axisCode = makeAxisCode(datasetId, xAxisId, yAxisId);
    return bookScatter2D(axisCode, title, xtitle, ytitle);
  }

virtual std::string collider ( ) const [inline, virtual, inherited]

Collider on which the experiment ran.

Definition at line 174 of file Analysis.hh.

References AnalysisInfo::collider(), and Analysis::info().

                                       {
      return info().collider();
    }

double crossSection ( ) const [protected, inherited]

Get the process cross-section in pb. Throws if this hasn't been set.

Definition at line 145 of file Analysis.cc.

References Analysis::_crossSection, Analysis::_gotCrossSection, and Analysis::name().

                                      {
    if (!_gotCrossSection || std::isnan(_crossSection)) {
      string errMsg = "You did not set the cross section for the analysis " + name();
      throw Error(errMsg);
    }
    return _crossSection;
  }

double crossSectionPerEvent ( ) const [protected, inherited]

Get the process cross-section per generated event in pb. Throws if this hasn't been set.

Definition at line 153 of file Analysis.cc.

References Analysis::_crossSection, and Analysis::sumOfWeights().

Referenced by D0_2010_S8671338::finalize(), CDF_2007_S7057202::finalize(), CDF_1988_S1865951::finalize(), LHCB_2011_I919315::finalize(), ATLAS_2010_S8817804::finalize(), MC_PHOTONJETS::finalize(), ATLAS_2012_I1082936::finalize(), D0_2009_S8349509::finalize(), UA1_1990_S2044935::finalize(), D0_2001_S4674421::finalize(), MC_WPOL::finalize(), ATLAS_2011_S9128077::finalize(), and ATLAS_2011_I945498::finalize().

                                              {
    const double sumW = sumOfWeights();
    assert(sumW != 0.0);
    return _crossSection / sumW;
  }

virtual std::string description ( ) const [inline, virtual, inherited]

Get a full description of the analysis.

Full textual description of this analysis, what it is useful for, what experimental techniques are applied, etc. Should be treated as a chunk of restructuredText (http://docutils.sourceforge.net/rst.html), with equations to be rendered as LaTeX with amsmath operators.

Definition at line 155 of file Analysis.hh.

References AnalysisInfo::description(), and Analysis::info().

                                          {
      return info().description();
    }

void divide	(	Histo1DPtr	h1,
		Histo1DPtr	h2,
		Scatter2DPtr	s
	)		const `[inherited]`

Helper for histogram division. Preserves the path information of the target.

Definition at line 399 of file Analysis.cc.

Referenced by CMS_2011_S8978280::finalize(), ALICE_2011_S8909580::finalize(), STAR_2006_S6500200::finalize(), D0_2008_S7837160::finalize(), MC_WJETS::finalize(), D0_2008_S7719523::finalize(), STAR_2006_S6860818::finalize(), ATLAS_2011_S9128077::finalize(), SLD_2004_S5693039::finalize(), and SLD_1999_S3743934::finalize().

                                                                          {
    // preserve the path info
    std::string path = s->path();
    *s = *h1 / *h2;
    s->setPath( path );
  }

void divide	(	Profile1DPtr	p1,
		Profile1DPtr	p2,
		Scatter2DPtr	s
	)		const `[inherited]`

Helper for profile histogram division. Preserves the path information of the target.

Definition at line 406 of file Analysis.cc.

                                                                              {
    // preserve the path info
    std::string path = s->path();
    *s = *p1 / *p2;
    s->setPath( path );
  }

void divide	(	const YODA::Histo1D &	h1,
		const YODA::Histo1D &	h2,
		Scatter2DPtr	s
	)		const `[inherited]`

Helper for histogram division. Preserves the path information of the target.

Definition at line 413 of file Analysis.cc.

                                              {
    // preserve the path info
    std::string path = s->path();
    *s = h1 / h2;
    s->setPath( path );
  }

void divide	(	const YODA::Profile1D &	p1,
		const YODA::Profile1D &	p2,
		Scatter2DPtr	s
	)		const `[inherited]`

Helper for profile histogram division. Preserves the path information of the target.

Definition at line 422 of file Analysis.cc.

                                              {
    // preserve the path info
    std::string path = s->path();
    *s = p1 / p2;
    s->setPath( path );
  }

virtual std::string experiment ( ) const [inline, virtual, inherited]

Experiment which performed and published this analysis.

Definition at line 169 of file Analysis.hh.

References AnalysisInfo::experiment(), and Analysis::info().

                                         {
      return info().experiment();
    }

void finalize ( ) [inline, virtual]

Finalize this analysis object. A concrete class should here make all necessary operations on the histograms. Writing the histograms to a file is, however, done by the Rivet class. An overridden function must make sure it first calls the base class function.

Reimplemented from Analysis.

Definition at line 402 of file ATLAS_2012_CONF_2012_153.cc.

References ATLAS_2012_CONF_2012_153::_count_SR1, ATLAS_2012_CONF_2012_153::_count_SR2, ATLAS_2012_CONF_2012_153::_hist_etmiss, ATLAS_2012_CONF_2012_153::_hist_meff, Analysis::crossSection(), Rivet::femtobarn, Analysis::scale(), and Analysis::sumOfWeights().

                    {
      double norm = crossSection()/femtobarn*13./sumOfWeights();
      scale(_hist_etmiss,norm*20.);
      scale(_hist_meff  ,norm*20.);
      scale(_count_SR1,norm);
      scale(_count_SR2,norm);
    }

Log & getLog ( ) const [protected, inherited]

Get a Log object based on the name() property of the calling analysis object.

Reimplemented from ProjectionApplier.

Definition at line 76 of file Analysis.cc.

References Analysis::name().

                              {
    string logname = "Rivet.Analysis." + name();
    return Log::getLog(logname);
  }

const PROJ& getProjection ( const std::string & name ) const [inline, inherited]

Get the named projection, specifying return type via a template argument.

Definition at line 49 of file ProjectionApplier.hh.

References ProjectionHandler::getProjection(), and ProjectionApplier::getProjHandler().

Referenced by ProjectionApplier::_applyProjection(), Rivet::pcmp(), and Hemispheres::project().

                                                           {
      const Projection& p = getProjHandler().getProjection(*this, name);
      return pcast<PROJ>(p);
    }

const Projection& getProjection ( const std::string & name ) const [inline, inherited]

Get the named projection (non-templated, so returns as a reference to a Projection base class).

Definition at line 57 of file ProjectionApplier.hh.

References ProjectionHandler::getProjection(), and ProjectionApplier::getProjHandler().

                                                                 {
      return getProjHandler().getProjection(*this, name);
    }

std::set<ConstProjectionPtr> getProjections ( ) const [inline, inherited]

Get the contained projections, including recursion.

Definition at line 42 of file ProjectionApplier.hh.

References ProjectionHandler::DEEP, ProjectionHandler::getChildProjections(), and ProjectionApplier::getProjHandler().

Referenced by Projection::beamPairs().

                                                      {
      return getProjHandler().getChildProjections(*this, ProjectionHandler::DEEP);
    }

ProjectionHandler& getProjHandler ( ) const [inline, protected, inherited]

Get a reference to the ProjectionHandler for this thread.

Definition at line 94 of file ProjectionApplier.hh.

References ProjectionApplier::_projhandler.

Referenced by ProjectionApplier::_addProjection(), ProjectionApplier::getProjection(), ProjectionApplier::getProjections(), and ProjectionApplier::~ProjectionApplier().

                                              {
      return _projhandler;
    }

AnalysisHandler& handler ( ) const [inline, inherited]

Access the controlling AnalysisHandler object.

Definition at line 291 of file Analysis.hh.

References Analysis::_analysishandler.

Referenced by Analysis::beamIds(), Analysis::beams(), Analysis::histoDir(), Analysis::numEvents(), Analysis::sqrtS(), and Analysis::sumOfWeights().

{ return *_analysishandler; }

const string histoDir ( ) const [protected, inherited]

Get the canonical histogram "directory" path for this analysis.

Todo:: This doesn't change: calc and cache at first use!

Definition at line 37 of file Analysis.cc.

References Analysis::handler(), Analysis::name(), and AnalysisHandler::runName().

Referenced by Analysis::histoPath().

                                        {
    /// @todo This doesn't change: calc and cache at first use!
    string path = "/" + name();
    if (handler().runName().length() > 0) {
      path = "/" + handler().runName() + path;
    }
    while (find_first(path, "//")) {
      replace_all(path, "//", "/");
    }
    return path;
  }

const string histoPath ( const std::string & hname ) const [protected, inherited]

Get the canonical histogram path for the named histogram in this analysis.

Definition at line 50 of file Analysis.cc.

References Analysis::histoDir().

Referenced by Analysis::bookHisto1D(), Analysis::bookProfile1D(), and Analysis::bookScatter2D().

                                                            {
    const string path = histoDir() + "/" + hname;
    return path;
  }

const string histoPath	(	size_t	datasetId,
		size_t	xAxisId,
		size_t	yAxisId
	)		const `[protected, inherited]`

Get the canonical histogram path for the numbered histogram in this analysis.

Definition at line 56 of file Analysis.cc.

References Analysis::histoDir(), and Analysis::makeAxisCode().

                                                                                         {
    return histoDir() + "/" + makeAxisCode(datasetId, xAxisId, yAxisId);
  }

const AnalysisInfo& info ( ) const [inline, inherited]

Get the actual AnalysisInfo object in which all this metadata is stored.

Definition at line 108 of file Analysis.hh.

References Analysis::_info.

Referenced by Analysis::authors(), Analysis::bibKey(), Analysis::bibTeX(), Analysis::collider(), Analysis::description(), Analysis::experiment(), Analysis::inspireId(), Analysis::name(), Analysis::needsCrossSection(), Analysis::references(), Analysis::requiredBeams(), Analysis::requiredEnergies(), Analysis::runInfo(), Analysis::setNeedsCrossSection(), Analysis::setRequiredBeams(), Analysis::setRequiredEnergies(), Analysis::spiresId(), Analysis::status(), Analysis::summary(), Analysis::todos(), and Analysis::year().

                                     {
      assert(_info.get() != 0 && "No AnalysisInfo object :O");
      return *_info;
    }

AnalysisInfo& info ( ) [inline, inherited]

Get the actual AnalysisInfo object in which all this metadata is stored (non-const).

Definition at line 250 of file Analysis.hh.

References Analysis::_info.

                         {
      assert(_info.get() != 0 && "No AnalysisInfo object :O");
      return *_info;
    }

void init ( ) [inline, virtual]

Book histograms and initialise projections before the run.

Jet finder

Reimplemented from Analysis.

Definition at line 40 of file ATLAS_2012_CONF_2012_153.cc.

                {

      // projection to find the electrons
      std::vector<std::pair<double, double> > eta_e;
      eta_e.push_back(make_pair(-2.47,2.47));
      IdentifiedFinalState elecs(eta_e, 10.0*GeV);
      elecs.acceptIdPair(ELECTRON);
      addProjection(elecs, "elecs");


      // projection to find the muons
      std::vector<std::pair<double, double> > eta_m;
      eta_m.push_back(make_pair(-2.4,2.4));
      IdentifiedFinalState muons(eta_m, 10.0*GeV);
      muons.acceptIdPair(MUON);
      addProjection(muons, "muons");

      // for pTmiss
      addProjection(VisibleFinalState(-4.9,4.9),"vfs");

      VetoedFinalState vfs;
      vfs.addVetoPairId(MUON);

      /// Jet finder
      addProjection(FastJets(vfs, FastJets::ANTIKT, 0.4),
                    "AntiKtJets04");

      // all tracks (to do deltaR with leptons)
      addProjection(ChargedFinalState(-3.0,3.0),"cfs");

      vector<double> edges_meff;
      edges_meff.push_back(   0);
      edges_meff.push_back( 150);
      edges_meff.push_back( 300);
      edges_meff.push_back( 500);
      edges_meff.push_back(1000);
      edges_meff.push_back(1500);

      vector<double> edges_eT;
      edges_eT.push_back(0);
      edges_eT.push_back(50);
      edges_eT.push_back(150);
      edges_eT.push_back(300);
      edges_eT.push_back(500);

      // Book histograms
      _hist_electrons = bookHisto1D("hist_electrons_before", 11, -0.5,10.5);
      _hist_muons     = bookHisto1D("hist_muons_before"    , 11, -0.5,10.5);
      _hist_leptons   = bookHisto1D("hist_leptons_before"  , 11, -0.5,10.5);
      _hist_4leptons  = bookHisto1D("hist_4leptons", 1, 0.,1.);
      _hist_veto      = bookHisto1D("hist_veto", 1, 0., 1.);
      _hist_etmiss    = bookHisto1D("hist_etmiss",edges_eT);
      _hist_meff      = bookHisto1D("hist_m_eff",edges_meff);
      _count_SR1      = bookHisto1D("count_SR1", 1, 0., 1.);
      _count_SR2      = bookHisto1D("count_SR2", 1, 0., 1.);

    }

virtual std::string inspireId ( ) const [inline, virtual, inherited]

Get the Inspire ID code for this analysis.

Definition at line 123 of file Analysis.hh.

References Analysis::info(), and AnalysisInfo::inspireId().

                                        {
      return info().inspireId();
    }

bool isCompatible ( const ParticlePair & beams ) const [inherited]

Check if analysis is compatible with the provided beam particle IDs and energies.

Definition at line 95 of file Analysis.cc.

Referenced by Analysis::isCompatible().

                                                             {
    return isCompatible(beams.first.pdgId(),  beams.second.pdgId(),
                        beams.first.energy(), beams.second.energy());
  }

bool isCompatible	(	PdgId	beam1,
		PdgId	beam2,
		double	e1,
		double	e2
	)		const `[inherited]`

Check if analysis is compatible with the provided beam particle IDs and energies.

Definition at line 101 of file Analysis.cc.

References Analysis::beams(), and Analysis::isCompatible().

                                                                                  {
    PdgIdPair beams(beam1, beam2);
    pair<double,double> energies(e1, e2);
    return isCompatible(beams, energies);
  }

bool isCompatible	(	const PdgIdPair &	beams,
		const std::pair< double, double > &	energies
	)		const `[inherited]`

Check if analysis is compatible with the provided beam particle IDs and energies.

const string makeAxisCode	(	size_t	datasetId,
		size_t	xAxisId,
		size_t	yAxisId
	)		const `[protected, inherited]`

Get the internal histogram name for given d, x and y (cf. HepData)

Definition at line 61 of file Analysis.cc.

Referenced by Analysis::bookHisto1D(), Analysis::bookProfile1D(), Analysis::bookScatter2D(), Analysis::histoPath(), and Analysis::referenceData().

                                                                                            {
    stringstream axisCode;
    axisCode << "d";
    if (datasetId < 10) axisCode << 0;
    axisCode << datasetId;
    axisCode << "-x";
    if (xAxisId < 10) axisCode << 0;
    axisCode << xAxisId;
    axisCode << "-y";
    if (yAxisId < 10) axisCode << 0;
    axisCode << yAxisId;
    return axisCode.str();
  }

virtual std::string name ( ) const [inline, virtual, inherited]

Get the name of the analysis.

By default this is computed by combining the results of the experiment, year and Spires ID metadata methods and you should only override it if there's a good reason why those won't work.

Implements ProjectionApplier.

Definition at line 118 of file Analysis.hh.

References Analysis::_defaultname, Analysis::info(), and AnalysisInfo::name().

Referenced by Analysis::_cacheRefData(), Analysis::Analysis(), Analysis::bookHisto1D(), Analysis::bookProfile1D(), Analysis::bookScatter2D(), Analysis::crossSection(), Analysis::getLog(), Analysis::histoDir(), Analysis::normalize(), Analysis::referenceData(), HistoHandler::registerAnalysisObject(), and Analysis::scale().

                                   {
      return (info().name().empty()) ? _defaultname : info().name();
    }

bool needsCrossSection ( ) const [inline, inherited]

Return true if this analysis needs to know the process cross-section.

Todo:: Remove this and require HepMC >= 2.06

Definition at line 233 of file Analysis.hh.

References Analysis::info(), and AnalysisInfo::needsCrossSection().

                                   {
      return info().needsCrossSection();
    }

void normalize	(	Histo1DPtr	histo,
		double	norm = `1.0`,
		bool	includeoverflows = `true`
	)		`[inherited]`

Normalize the given histogram, histo, to area = norm.

NB. The histogram is no longer invalidated by this procedure.

Definition at line 431 of file Analysis.cc.

References MSG_ERROR, MSG_TRACE, MSG_WARNING, and Analysis::name().

Referenced by CMS_2011_S8950903::finalize(), CMS_2011_S8968497::finalize(), D0_2010_S8671338::finalize(), CDF_2009_NOTE_9936::finalize(), D0_2007_S7075677::finalize(), BABAR_2005_S6181155::finalize(), D0_2008_S7554427::finalize(), ALICE_2010_S8624100::finalize(), ATLAS_2011_S8971293::finalize(), ALICE_2010_S8625980::finalize(), D0_2009_S8320160::finalize(), CMS_2011_S8957746::finalize(), DELPHI_1995_S3137023::finalize(), CDF_1993_S2742446::finalize(), D0_1996_S3324664::finalize(), SLD_2002_S4869273::finalize(), CDF_1996_S3418421::finalize(), D0_2008_S6879055::finalize(), D0_2010_S8821313::finalize(), EXAMPLE::finalize(), CDF_1996_S3108457::finalize(), CDF_1994_S2952106::finalize(), JADE_1998_S3612880::finalize(), ALEPH_2001_S4656318::finalize(), D0_1996_S3214044::finalize(), ATLAS_2011_I925932::finalize(), DELPHI_2002_069_CONF_603::finalize(), D0_2004_S5992206::finalize(), OPAL_1997_S3396100::finalize(), MC_PHOTONS::finalize(), CMS_2012_I1107658::finalize(), D0_2001_S4674421::finalize(), OPAL_2001_S4553896::finalize(), TASSO_1990_S2148048::finalize(), STAR_2008_S7869363::finalize(), OPAL_1998_S3780481::finalize(), CDF_1997_S3541940::finalize(), DELPHI_2003_WUD_03_11::finalize(), H1_1994_S2919893::finalize(), BELLE_2006_S6265367::finalize(), CDF_2001_S4751469::finalize(), MC_TTBAR::finalize(), ALEPH_2004_S5765862::finalize(), CDF_2004_S5839831::finalize(), CDF_1996_S3349578::finalize(), ALEPH_1996_S3486095::finalize(), DELPHI_1996_S3430090::finalize(), and ATLAS_2011_I919017::safeinvscale().

                                                                               {
    if (!histo) {
      MSG_ERROR("Failed to normalize histo=NULL in analysis " << name() << " (norm=" << norm << ")");
      return;
    }
    MSG_TRACE("Normalizing histo " << histo->path() << " to " << norm);
    try {
      histo->normalize(norm, includeoverflows);
    } catch (YODA::WeightError& we) {
      MSG_WARNING("Could not normalize histo " << histo->path());
      return;
    }
  }

size_t numEvents ( ) const [protected, inherited]

Get the number of events seen (via the analysis handler). Use in the finalize phase only.

Definition at line 82 of file Analysis.cc.

References Analysis::handler(), and AnalysisHandler::numEvents().

                                   {
    return handler().numEvents();
  }

const vector<AnalysisObjectPtr>& plots ( ) const [inline, inherited]

List of registered plot objects.

Definition at line 521 of file Analysis.hh.

References Analysis::_plotobjects.

                                                    {
      return _plotobjects;
    }

const Scatter2D & referenceData ( const string & hname ) const [protected, inherited]

Get reference data for a named histo.

Definition at line 173 of file Analysis.cc.

References Analysis::_cacheRefData(), Analysis::_refdata, MSG_ERROR, MSG_TRACE, and Analysis::name().

Referenced by ATLAS_2011_S8994773::analyze(), ATLAS_2010_S8894728::analyze(), Analysis::bookHisto1D(), Analysis::bookProfile1D(), ATLAS_2010_S8894728::init(), CMS_2012_I1102908::init(), CDF_1994_S2952106::init(), and Analysis::referenceData().

                                                                     {
    _cacheRefData();
    MSG_TRACE("Using histo bin edges for " << name() << ":" << hname);
    if (!_refdata[hname]) {
      MSG_ERROR("Can't find reference histogram " << hname);
    }
    return *_refdata[hname];
  }

const Scatter2D & referenceData	(	size_t	datasetId,
		size_t	xAxisId,
		size_t	yAxisId
	)		const `[protected, inherited]`

Get reference data for a numbered histo.

Definition at line 183 of file Analysis.cc.

References Analysis::makeAxisCode(), and Analysis::referenceData().

                                                                                                  {
    const string hname = makeAxisCode(datasetId, xAxisId, yAxisId);
    return referenceData(hname);
  }

virtual std::vector<std::string> references ( ) const [inline, virtual, inherited]

Journal, and preprint references.

Definition at line 184 of file Analysis.hh.

References Analysis::info(), and AnalysisInfo::references().

                                                    {
      return info().references();
    }

virtual const std::vector<PdgIdPair>& requiredBeams ( ) const [inline, virtual, inherited]

Return the allowed pairs of incoming beams required by this analysis.

Definition at line 210 of file Analysis.hh.

References AnalysisInfo::beams(), and Analysis::info().

                                                              {
      return info().beams();
    }

virtual const std::vector<std::pair<double, double> >& requiredEnergies ( ) const [inline, virtual, inherited]

Sets of valid beam energy pairs, in GeV.

Definition at line 221 of file Analysis.hh.

References AnalysisInfo::energies(), and Analysis::info().

Referenced by Analysis::setRequiredEnergies().

                                                                                {
      return info().energies();
    }

virtual std::string runInfo ( ) const [inline, virtual, inherited]

Information about the events needed as input for this analysis.

Event types, energies, kinematic cuts, particles to be considered stable, etc. etc. Should be treated as a restructuredText bullet list (http://docutils.sourceforge.net/rst.html)

Definition at line 164 of file Analysis.hh.

References Analysis::info(), and AnalysisInfo::runInfo().

                                      {
      return info().runInfo();
    }

void scale	(	Histo1DPtr	histo,
		double	scale
	)		`[inherited]`

Multiplicatively scale the given histogram, histo, by factor scale.

NB. The histogram is no longer invalidated by this procedure.

Definition at line 446 of file Analysis.cc.

References MSG_ERROR, MSG_TRACE, MSG_WARNING, and Analysis::name().

                                                     {
    if (!histo) {
      MSG_ERROR("Failed to scale histo=NULL in analysis " << name() << " (scale=" << scale << ")");
      return;
    }
    MSG_TRACE("Scaling histo " << histo->path() << "by factor " << scale);
    try {
      histo->scaleW(scale);
    } catch (YODA::WeightError& we) {
      MSG_WARNING("Could not normalize histo " << histo->path());
      return;
    }
    // // Transforming the histo into a scatter after scaling
    // vector<double> x, y, ex, ey;
    // for (size_t i = 0, N = histo->numBins(); i < N; ++i) {
    //   x.push_back( histo->bin(i).midpoint() );
    //   ex.push_back(histo->bin(i).width()*0.5);
    //   y.push_back(histo->bin(i).height()*scale);
    //   ey.push_back(histo->bin(i).heightErr()*scale);
    // }
    // string title = histo->title();
    // Scatter2DPtr dps( new Scatter2D(x, y, ex, ey, hpath, title) );
    // addPlot(dps);
  }

Analysis & setCrossSection ( double xs ) [inherited]

Set the cross section from the generator.

Normalize the given histogram, histo, to area = norm.

NB. The histogram is no longer invalidated by this procedure. Multiplicatively scale the given histogram, histo, by factor scale.

NB. The histogram is no longer invalidated by this procedure.

Definition at line 139 of file Analysis.cc.

References Analysis::_crossSection, and Analysis::_gotCrossSection.

                                               {
    _crossSection = xs;
    _gotCrossSection = true;
    return *this;
  }

Analysis& setNeedsCrossSection ( bool needed = true ) [inline, inherited]

Declare whether this analysis needs to know the process cross-section from the generator.

Todo:: Remove this and require HepMC >= 2.06

Definition at line 238 of file Analysis.hh.

References Analysis::info(), and AnalysisInfo::setNeedsCrossSection().

Referenced by ATLAS_2011_I945498::ATLAS_2011_I945498(), ATLAS_2011_I954993::ATLAS_2011_I954993(), and MC_JetAnalysis::MC_JetAnalysis().

                                                     {
      info().setNeedsCrossSection(needed);
      return *this;
    }

virtual Analysis& setRequiredBeams ( const std::vector< PdgIdPair > & requiredBeams ) [inline, virtual, inherited]

Declare the allowed pairs of incoming beams required by this analysis.

Definition at line 214 of file Analysis.hh.

References Analysis::info(), and AnalysisInfo::setBeams().

                                                                                  {
      info().setBeams(requiredBeams);
      return *this;
    }

virtual Analysis& setRequiredEnergies ( const std::vector< std::pair< double, double > > & requiredEnergies ) [inline, virtual, inherited]

Declare the list of valid beam energy pairs, in GeV.

Definition at line 225 of file Analysis.hh.

References Analysis::info(), Analysis::requiredEnergies(), and AnalysisInfo::setEnergies().

                                                                                                       {
      info().setEnergies(requiredEnergies);
      return *this;
    }

virtual std::string spiresId ( ) const [inline, virtual, inherited]

Get the SPIRES ID code for this analysis (~deprecated).

Definition at line 128 of file Analysis.hh.

References Analysis::info(), and AnalysisInfo::spiresId().

                                       {
      return info().spiresId();
    }

double sqrtS ( ) const [inherited]

Centre of mass energy for this run.

Definition at line 24 of file Analysis.cc.

References Analysis::handler(), and AnalysisHandler::sqrtS().

Referenced by PDG_HADRON_MULTIPLICITIES::analyze(), PDG_HADRON_MULTIPLICITIES_RATIOS::analyze(), SLD_2004_S5693039::analyze(), CMS_2011_S9215166::analyze(), SFM_1984_S1178091::analyze(), ALICE_2010_S8625980::analyze(), UA1_1990_S2044935::analyze(), JADE_1998_S3612880::analyze(), TASSO_1990_S2148048::analyze(), MC_TTBAR::analyze(), ATLAS_2010_S8894728::analyze(), ATLAS_2010_S8918562::analyze(), ALEPH_2004_S5765862::analyze(), CDF_2004_S5839831::analyze(), ALICE_2010_S8625980::finalize(), JADE_1998_S3612880::finalize(), UA1_1990_S2044935::finalize(), ATLAS_2010_S8918562::finalize(), ALEPH_2004_S5765862::finalize(), CDF_2004_S5839831::finalize(), PDG_HADRON_MULTIPLICITIES_RATIOS::finalize(), PDG_HADRON_MULTIPLICITIES::finalize(), ATLAS_2010_S8894728::init(), CMS_2010_S8547297::init(), ATLAS_2011_S8994773::init(), CMS_2011_S9215166::init(), CDF_2012_NOTE10874::init(), CMS_QCD_10_024::init(), MC_JetAnalysis::init(), SFM_1984_S1178091::init(), MC_DIPHOTON::init(), MC_HJETS::init(), MC_ZJETS::init(), UA5_1989_S1926373::init(), CDF_1988_S1865951::init(), MC_PHOTONJETS::init(), MC_ZZJETS::init(), ATLAS_2012_I1091481::init(), CDF_1990_S2089246::init(), MC_WJETS::init(), MC_WWJETS::init(), UA5_1986_S1583476::init(), JADE_OPAL_2000_S4300807::init(), UA1_1990_S2044935::init(), ALICE_2010_S8624100::init(), MC_PHOTONS::init(), JADE_1998_S3612880::init(), ALEPH_2004_S5765862::init(), ALICE_2010_S8625980::init(), MC_WPOL::init(), ATLAS_2011_I944826::init(), UA5_1988_S1867512::init(), TASSO_1990_S2148048::init(), ATLAS_2010_S8918562::init(), LHCB_2011_I917009::init(), OPAL_2004_S6132243::init(), CDF_2004_S5839831::init(), PDG_HADRON_MULTIPLICITIES::init(), and PDG_HADRON_MULTIPLICITIES_RATIOS::init().

                               {
    return handler().sqrtS();
  }

virtual std::string status ( ) const [inline, virtual, inherited]

Whether this analysis is trusted (in any way!)

Definition at line 199 of file Analysis.hh.

References Analysis::info(), and AnalysisInfo::status().

                                     {
      return (info().status().empty()) ? "UNVALIDATED" : info().status();
    }

virtual std::string summary ( ) const [inline, virtual, inherited]

Get a short description of the analysis.

Short (one sentence) description used as an index entry. Use description() to provide full descriptive paragraphs of analysis details.

Definition at line 145 of file Analysis.hh.

References Analysis::info(), and AnalysisInfo::summary().

                                      {
      return info().summary();
    }

double sumOfWeights ( ) const [protected, inherited]

Get the sum of event weights seen (via the analysis handler). Use in the finalize phase only.

Definition at line 87 of file Analysis.cc.

References Analysis::handler(), and AnalysisHandler::sumOfWeights().

                                      {
    return handler().sumOfWeights();
  }

virtual std::vector<std::string> todos ( ) const [inline, virtual, inherited]

Any work to be done on this analysis.

Definition at line 204 of file Analysis.hh.

References Analysis::info(), and AnalysisInfo::todos().

                                               {
      return info().todos();
    }

virtual std::string year ( ) const [inline, virtual, inherited]

When the original experimental analysis was published.

Definition at line 179 of file Analysis.hh.

References Analysis::info(), and AnalysisInfo::year().

                                   {
      return info().year();
    }

Member Data Documentation

bool _allowProjReg [protected, inherited]

Flag to forbid projection registration in analyses until the init phase.

Definition at line 140 of file ProjectionApplier.hh.

Referenced by ProjectionApplier::_addProjection(), and Analysis::Analysis().

Histo1DPtr _count_SR1 [private]

Definition at line 421 of file ATLAS_2012_CONF_2012_153.cc.

Referenced by ATLAS_2012_CONF_2012_153::analyze(), ATLAS_2012_CONF_2012_153::finalize(), and ATLAS_2012_CONF_2012_153::init().

Histo1DPtr _count_SR2 [private]

Definition at line 422 of file ATLAS_2012_CONF_2012_153.cc.

Referenced by ATLAS_2012_CONF_2012_153::analyze(), ATLAS_2012_CONF_2012_153::finalize(), and ATLAS_2012_CONF_2012_153::init().

string _defaultname [protected, inherited]

Name passed to constructor (used to find .info analysis data file, and as a fallback)

Definition at line 542 of file Analysis.hh.

Referenced by Analysis::Analysis(), and Analysis::name().

Histo1DPtr _hist_4leptons [private]

Definition at line 417 of file ATLAS_2012_CONF_2012_153.cc.

Referenced by ATLAS_2012_CONF_2012_153::analyze(), and ATLAS_2012_CONF_2012_153::init().

Histo1DPtr _hist_electrons [private]

Definition at line 414 of file ATLAS_2012_CONF_2012_153.cc.

Referenced by ATLAS_2012_CONF_2012_153::analyze(), and ATLAS_2012_CONF_2012_153::init().

Histo1DPtr _hist_etmiss [private]

Definition at line 419 of file ATLAS_2012_CONF_2012_153.cc.

Referenced by ATLAS_2012_CONF_2012_153::analyze(), ATLAS_2012_CONF_2012_153::finalize(), and ATLAS_2012_CONF_2012_153::init().

Histo1DPtr _hist_leptons [private]

Definition at line 416 of file ATLAS_2012_CONF_2012_153.cc.

Referenced by ATLAS_2012_CONF_2012_153::analyze(), and ATLAS_2012_CONF_2012_153::init().

Histo1DPtr _hist_meff [private]

Definition at line 420 of file ATLAS_2012_CONF_2012_153.cc.

Referenced by ATLAS_2012_CONF_2012_153::analyze(), ATLAS_2012_CONF_2012_153::finalize(), and ATLAS_2012_CONF_2012_153::init().

Histo1DPtr _hist_muons [private]

Definition at line 415 of file ATLAS_2012_CONF_2012_153.cc.

Referenced by ATLAS_2012_CONF_2012_153::analyze(), and ATLAS_2012_CONF_2012_153::init().

Histo1DPtr _hist_veto [private]

Definition at line 418 of file ATLAS_2012_CONF_2012_153.cc.

Referenced by ATLAS_2012_CONF_2012_153::analyze(), and ATLAS_2012_CONF_2012_153::init().

shared_ptr<AnalysisInfo> _info [protected, inherited]

Pointer to analysis metadata object.

Definition at line 545 of file Analysis.hh.

Referenced by Analysis::Analysis(), and Analysis::info().

The documentation for this class was generated from the following file:

ATLAS_2012_CONF_2012_153.cc

Public Member Functions

Protected Member Functions

Protected Attributes

Private Attributes

Detailed Description

Constructor & Destructor Documentation

Member Function Documentation

Member Data Documentation