OPAL_2004_S6132243 Class Reference

Inheritance diagram for OPAL_2004_S6132243:

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Collaboration diagram for OPAL_2004_S6132243:

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List of all members.

Detailed Description

OPAL event shapes and moments at 91, 133, 177, and 197 GeV.

Author:: Andy Buckley

Definition at line 18 of file OPAL_2004_S6132243.cc.


Public Member Functions
	OPAL_2004_S6132243 ()
	Constructor.
virtual bool	isCompatible (PdgId beam1, PdgId beam2) const
	Is this analysis able to run on the supplied pair of beams?
virtual bool	isCompatible (const PdgIdPair &beams) const
	Is this analysis able to run on the PdgIdPair beams ?
AnalysisHandler &	handler () const
	Access the controlling AnalysisHandler object.
void	normalize (AIDA::IHistogram1D *&histo, double norm=1.0)
void	scale (AIDA::IHistogram1D *&histo, double scale)
Analysis &	setCrossSection (double xs)
	Set the cross section from the generator.
bool	needsCrossSection () const
	Return true if this analysis needs to know the process cross-section.
Analysis methods
int	getHistIndex (double sqrts)
	Energies: 91, 133, 177 (161-183), 197 (189-209) => index 0..4.
void	init ()
void	analyze (const Event &event)
void	finalize ()
Metadata
Metadata is used for querying from the command line and also for building web pages and the analysis pages in the Rivet manual.
virtual 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	spiresId () const
	Get a the SPIRES/Inspire ID code for this analysis.
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 const std::vector < PdgIdPair > &	requiredBeams () const
	Return the pair of incoming beams required by this analysis.
virtual const std::vector < std::pair< double, double > > &	energies () const
	Sets of valid beam energy pairs, in GeV.
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.
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.
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
Analysis &	setBeams (PdgId beam1, PdgId beam2)
Analysis &	setNeedsCrossSection (bool needed)
	Declare whether this analysis needs to know the process cross-section from the generator.
ProjectionHandler &	getProjHandler () const
	Get a reference to the ProjectionHandler for this thread.
AIDA analysis infrastructure.
AIDA::IAnalysisFactory &	analysisFactory ()
	Access the AIDA analysis factory of the controlling AnalysisHandler object.
AIDA::ITree &	tree ()
	Access the AIDA tree of the controlling AnalysisHandler object.
AIDA::IHistogramFactory &	histogramFactory ()
	Access the AIDA histogram factory of the controlling AnalysisHandler object.
AIDA::IDataPointSetFactory &	datapointsetFactory ()
	Access the AIDA histogram factory of the controlling AnalysisHandler object.
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.
Internal histogram booking (for use by Analysis sub-classes).
const BinEdges &	binEdges (const std::string &hname) const
	Get bin edges for a named histo (using ref AIDA caching).
const BinEdges &	binEdges (size_t datasetId, size_t xAxisId, size_t yAxisId) const
	Get bin edges for a numbered histo (using ref AIDA caching).
BinEdges	logBinEdges (size_t nbins, double lower, double upper)
	Get bin edges with logarithmic widths.
AIDA::IHistogram1D *	bookHistogram1D (const std::string &name, size_t nbins, double lower, double upper, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
AIDA::IHistogram1D *	bookHistogram1D (const std::string &name, const std::vector< double > &binedges, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
AIDA::IHistogram1D *	bookHistogram1D (const std::string &name, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
AIDA::IHistogram1D *	bookHistogram1D (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).
AIDA::IProfile1D *	bookProfile1D (const std::string &name, size_t nbins, double lower, double upper, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
AIDA::IProfile1D *	bookProfile1D (const std::string &name, const std::vector< double > &binedges, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
AIDA::IProfile1D *	bookProfile1D (const std::string &name, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
AIDA::IProfile1D *	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).
AIDA::IDataPointSet *	bookDataPointSet (const std::string &name, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
AIDA::IDataPointSet *	bookDataPointSet (const std::string &name, size_t npts, double lower, double upper, const std::string &title="", const std::string &xtitle="", const std::string &ytitle="")
AIDA::IDataPointSet *	bookDataPointSet (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
int	_isqrts
	Beam energy index for histograms.
Counters of event weights passing the cuts
double	_sumWTrack2
double	_sumWJet3
Event shape histos at 4 energies
AIDA::IHistogram1D *	_hist1MinusT [4]
AIDA::IHistogram1D *	_histHemiMassH [4]
AIDA::IHistogram1D *	_histCParam [4]
AIDA::IHistogram1D *	_histHemiBroadT [4]
AIDA::IHistogram1D *	_histHemiBroadW [4]
AIDA::IHistogram1D *	_histY23Durham [4]
AIDA::IHistogram1D *	_histTMajor [4]
AIDA::IHistogram1D *	_histTMinor [4]
AIDA::IHistogram1D *	_histAplanarity [4]
AIDA::IHistogram1D *	_histSphericity [4]
AIDA::IHistogram1D *	_histOblateness [4]
AIDA::IHistogram1D *	_histHemiMassL [4]
AIDA::IHistogram1D *	_histHemiBroadN [4]
AIDA::IHistogram1D *	_histDParam [4]
Event shape moment histos at 4 energies
AIDA::IHistogram1D *	_hist1MinusTMom [4]
AIDA::IHistogram1D *	_histHemiMassHMom [4]
AIDA::IHistogram1D *	_histCParamMom [4]
AIDA::IHistogram1D *	_histHemiBroadTMom [4]
AIDA::IHistogram1D *	_histHemiBroadWMom [4]
AIDA::IHistogram1D *	_histY23DurhamMom [4]
AIDA::IHistogram1D *	_histTMajorMom [4]
AIDA::IHistogram1D *	_histTMinorMom [4]
AIDA::IHistogram1D *	_histSphericityMom [4]
AIDA::IHistogram1D *	_histOblatenessMom [4]
AIDA::IHistogram1D *	_histHemiMassLMom [4]
AIDA::IHistogram1D *	_histHemiBroadNMom [4]
Friends
class	Projectionhandler

Constructor & Destructor Documentation

OPAL_2004_S6132243 ( ) [inline]

Constructor.

Definition at line 22 of file OPAL_2004_S6132243.cc.

00023       : Analysis("OPAL_2004_S6132243"),
00024         _isqrts(-1), _sumWTrack2(0.0), _sumWJet3(0.0)
00025     {
00026       //
00027     }

Member Function Documentation

int getHistIndex ( double sqrts ) [inline]

Energies: 91, 133, 177 (161-183), 197 (189-209) => index 0..4.

Definition at line 34 of file OPAL_2004_S6132243.cc.

References Rivet::fuzzyEquals(), Rivet::GeV, and Rivet::inRange().

Referenced by OPAL_2004_S6132243::init().

00034                                    {
00035       int ih = -1;
00036       if (inRange(sqrts/GeV, 89.9, 91.5)) {
00037         ih = 0;
00038       } else if (fuzzyEquals(sqrts/GeV, 133)) {
00039         ih = 1;
00040       } else if (fuzzyEquals(sqrts/GeV, 177)) { // (161-183)
00041         ih = 2;
00042       } else if (fuzzyEquals(sqrts/GeV, 197)) { // (189-209)
00043         ih = 3;
00044       } else {
00045         stringstream ss;
00046         ss << "Invalid energy for OPAL_2004 analysis: "
00047            << sqrts/GeV << " GeV != 91, 133, 177, or 197 GeV";
00048         throw Error(ss.str());
00049       }
00050       assert(ih >= 0);
00051       return ih;
00052     }

void init ( ) [inline, virtual]

Initialize this analysis object. A concrete class should here book all necessary histograms. An overridden function must make sure it first calls the base class function.

Implements Analysis.

Definition at line 55 of file OPAL_2004_S6132243.cc.

00055                 {
00056       // Projections
00057       addProjection(Beam(), "Beams");
00058       const ChargedFinalState cfs;
00059       addProjection(cfs, "FS");
00060       addProjection(FastJets(cfs, FastJets::DURHAM, 0.7), "DurhamJets");
00061       addProjection(Sphericity(cfs), "Sphericity");
00062       addProjection(ParisiTensor(cfs), "Parisi");
00063       const Thrust thrust(cfs);
00064       addProjection(thrust, "Thrust");
00065       addProjection(Hemispheres(thrust), "Hemispheres");
00066 
00067       // Get beam energy index
00068       _isqrts = getHistIndex(sqrtS());
00069 
00070       // Book histograms
00071       _hist1MinusT[_isqrts]    = bookHistogram1D(1, 1, _isqrts+1);
00072       _histHemiMassH[_isqrts]  = bookHistogram1D(2, 1, _isqrts+1);
00073       _histCParam[_isqrts]     = bookHistogram1D(3, 1, _isqrts+1);
00074       _histHemiBroadT[_isqrts] = bookHistogram1D(4, 1, _isqrts+1);
00075       _histHemiBroadW[_isqrts] = bookHistogram1D(5, 1, _isqrts+1);
00076       _histY23Durham[_isqrts]  = bookHistogram1D(6, 1, _isqrts+1);
00077       _histTMajor[_isqrts]     = bookHistogram1D(7, 1, _isqrts+1);
00078       _histTMinor[_isqrts]     = bookHistogram1D(8, 1, _isqrts+1);
00079       _histAplanarity[_isqrts] = bookHistogram1D(9, 1, _isqrts+1);
00080       _histSphericity[_isqrts] = bookHistogram1D(10, 1, _isqrts+1);
00081       _histOblateness[_isqrts] = bookHistogram1D(11, 1, _isqrts+1);
00082       _histHemiMassL[_isqrts]  = bookHistogram1D(12, 1, _isqrts+1);
00083       _histHemiBroadN[_isqrts] = bookHistogram1D(13, 1, _isqrts+1);
00084       _histDParam[_isqrts]     = bookHistogram1D(14, 1, _isqrts+1);
00085       //
00086       _hist1MinusTMom[_isqrts]    = bookHistogram1D(15, 1, _isqrts+1);
00087       _histHemiMassHMom[_isqrts]  = bookHistogram1D(16, 1, _isqrts+1);
00088       _histCParamMom[_isqrts]     = bookHistogram1D(17, 1, _isqrts+1);
00089       _histHemiBroadTMom[_isqrts] = bookHistogram1D(18, 1, _isqrts+1);
00090       _histHemiBroadWMom[_isqrts] = bookHistogram1D(19, 1, _isqrts+1);
00091       _histY23DurhamMom[_isqrts]  = bookHistogram1D(20, 1, _isqrts+1);
00092       _histTMajorMom[_isqrts]     = bookHistogram1D(21, 1, _isqrts+1);
00093       _histTMinorMom[_isqrts]     = bookHistogram1D(22, 1, _isqrts+1);
00094       _histSphericityMom[_isqrts] = bookHistogram1D(23, 1, _isqrts+1);
00095       _histOblatenessMom[_isqrts] = bookHistogram1D(24, 1, _isqrts+1);
00096       _histHemiMassLMom[_isqrts]  = bookHistogram1D(25, 1, _isqrts+1);
00097       _histHemiBroadNMom[_isqrts] = bookHistogram1D(26, 1, _isqrts+1);
00098     }

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

Analyze one event. A concrete class should here apply the necessary projections on the event and fill the relevant histograms. An overridden function must make sure it first calls the base class function.

Implements Analysis.

Definition at line 101 of file OPAL_2004_S6132243.cc.

00101                                      {
00102       // Even if we only generate hadronic events, we still need a cut on numCharged >= 2.
00103       const FinalState& cfs = applyProjection<FinalState>(event, "FS");
00104       if (cfs.size() < 2) vetoEvent;
00105 
00106       // Increment passed-cuts weight sum
00107       const double weight = event.weight();
00108       _sumWTrack2 += weight;
00109 
00110       // Thrusts
00111       const Thrust& thrust = applyProjection<Thrust>(event, "Thrust");
00112       _hist1MinusT[_isqrts]->fill(1-thrust.thrust(), weight);
00113       _histTMajor[_isqrts]->fill(thrust.thrustMajor(), weight);
00114       _histTMinor[_isqrts]->fill(thrust.thrustMinor(), weight);
00115       _histOblateness[_isqrts]->fill(thrust.oblateness(), weight);
00116       for (int n = 1; n <= 5; ++n) {
00117         _hist1MinusTMom[_isqrts]->fill(n, pow(1-thrust.thrust(), n)*weight);
00118         _histTMajorMom[_isqrts]->fill(n, pow(thrust.thrustMajor(), n)*weight);
00119         _histTMinorMom[_isqrts]->fill(n, pow(thrust.thrustMinor(), n)*weight);
00120         _histOblatenessMom[_isqrts]->fill(n, pow(thrust.oblateness(), n)*weight);
00121       }
00122 
00123       // Jets
00124       const FastJets& durjet = applyProjection<FastJets>(event, "DurhamJets");
00125       if (durjet.clusterSeq()) {
00126         _sumWJet3 += weight;
00127         const double y23 = durjet.clusterSeq()->exclusive_ymerge_max(2);
00128         _histY23Durham[_isqrts]->fill(y23, weight);
00129         for (int n = 1; n <= 5; ++n) {
00130           _histY23DurhamMom[_isqrts]->fill(n, pow(y23, n)*weight);
00131         }
00132       }
00133 
00134       // Sphericities
00135       const Sphericity& sphericity = applyProjection<Sphericity>(event, "Sphericity");
00136       const double sph = sphericity.sphericity();
00137       const double apl = sphericity.aplanarity();
00138       _histSphericity[_isqrts]->fill(sph, weight);
00139       _histAplanarity[_isqrts]->fill(apl, weight);
00140       for (int n = 1; n <= 5; ++n) {
00141         _histSphericityMom[_isqrts]->fill(n, pow(sph, n)*weight);
00142       }
00143 
00144       // C & D params
00145       const ParisiTensor& parisi = applyProjection<ParisiTensor>(event, "Parisi");
00146       const double cparam = parisi.C();
00147       const double dparam = parisi.D();
00148       _histCParam[_isqrts]->fill(cparam, weight);
00149       _histDParam[_isqrts]->fill(dparam, weight);
00150       for (int n = 1; n <= 5; ++n) {
00151         _histCParamMom[_isqrts]->fill(n, pow(cparam, n)*weight);
00152       }
00153 
00154       // Hemispheres
00155       const Hemispheres& hemi = applyProjection<Hemispheres>(event, "Hemispheres");
00156       // The paper says that M_H/L are scaled by sqrt(s), but scaling by E_vis is the way that fits the data...
00157       const double hemi_mh = hemi.scaledMhigh();
00158       const double hemi_ml = hemi.scaledMlow();
00159       //
00160       const double hemi_bmax = hemi.Bmax();
00161       const double hemi_bmin = hemi.Bmin();
00162       const double hemi_bsum = hemi.Bsum();
00163       _histHemiMassH[_isqrts]->fill(hemi_mh, weight);
00164       _histHemiMassL[_isqrts]->fill(hemi_ml, weight);
00165       _histHemiBroadW[_isqrts]->fill(hemi_bmax, weight);
00166       _histHemiBroadN[_isqrts]->fill(hemi_bmin, weight);
00167       _histHemiBroadT[_isqrts]->fill(hemi_bsum, weight);
00168       for (int n = 1; n <= 5; ++n) {
00169         _histHemiMassHMom[_isqrts]->fill(n, pow(hemi_mh, n)*weight);
00170         _histHemiMassLMom[_isqrts]->fill(n, pow(hemi_ml, n)*weight);
00171         _histHemiBroadWMom[_isqrts]->fill(n, pow(hemi_bmax, n)*weight);
00172         _histHemiBroadNMom[_isqrts]->fill(n, pow(hemi_bmin, n)*weight);
00173         _histHemiBroadTMom[_isqrts]->fill(n, pow(hemi_bsum, n)*weight);
00174       }
00175     }

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.

Implements Analysis.

Definition at line 178 of file OPAL_2004_S6132243.cc.

00178                     {
00179       scale(_hist1MinusT[_isqrts], 1.0/_sumWTrack2);
00180       scale(_histTMajor[_isqrts], 1.0/_sumWTrack2);
00181       scale(_histTMinor[_isqrts], 1.0/_sumWTrack2);
00182       scale(_histOblateness[_isqrts], 1.0/_sumWTrack2);
00183       scale(_histSphericity[_isqrts], 1.0/_sumWTrack2);
00184       scale(_histAplanarity[_isqrts], 1.0/_sumWTrack2);
00185       scale(_histHemiMassH[_isqrts], 1.0/_sumWTrack2);
00186       scale(_histHemiMassL[_isqrts], 1.0/_sumWTrack2);
00187       scale(_histHemiBroadW[_isqrts], 1.0/_sumWTrack2);
00188       scale(_histHemiBroadN[_isqrts], 1.0/_sumWTrack2);
00189       scale(_histHemiBroadT[_isqrts], 1.0/_sumWTrack2);
00190       scale(_histCParam[_isqrts], 1.0/_sumWTrack2);
00191       scale(_histDParam[_isqrts], 1.0/_sumWTrack2);
00192       scale(_histY23Durham[_isqrts], 1.0/_sumWJet3);
00193       //
00194       scale(_hist1MinusTMom[_isqrts], 1.0/_sumWTrack2);
00195       scale(_histTMajorMom[_isqrts], 1.0/_sumWTrack2);
00196       scale(_histTMinorMom[_isqrts], 1.0/_sumWTrack2);
00197       scale(_histOblatenessMom[_isqrts], 1.0/_sumWTrack2);
00198       scale(_histSphericityMom[_isqrts], 1.0/_sumWTrack2);
00199       scale(_histHemiMassHMom[_isqrts], 1.0/_sumWTrack2);
00200       scale(_histHemiMassLMom[_isqrts], 1.0/_sumWTrack2);
00201       scale(_histHemiBroadWMom[_isqrts], 1.0/_sumWTrack2);
00202       scale(_histHemiBroadNMom[_isqrts], 1.0/_sumWTrack2);
00203       scale(_histHemiBroadTMom[_isqrts], 1.0/_sumWTrack2);
00204       scale(_histCParamMom[_isqrts], 1.0/_sumWTrack2);
00205       scale(_histY23DurhamMom[_isqrts], 1.0/_sumWJet3);
00206     }

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

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

Definition at line 126 of file Analysis.cc.

References Analysis::_info.

Referenced by Analysis::energies(), and Analysis::requiredBeams().

00126                                            {
00127     assert(_info.get() != 0);
00128     return *_info;
00129   }

string name ( ) const [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 131 of file Analysis.cc.

References Analysis::_defaultname, and Analysis::_info.

Referenced by Analysis::_cacheBinEdges(), Analysis::_cacheXAxisData(), Analysis::_makeHistoDir(), Analysis::crossSection(), Analysis::getLog(), Analysis::histoDir(), Analysis::normalize(), HistoHandler::registerAnalysisObject(), and Analysis::scale().

00131                               {
00132     if (_info && !_info->name().empty()) return _info->name();
00133     return _defaultname;
00134   }

string spiresId ( ) const [virtual, inherited]

Get a the SPIRES/Inspire ID code for this analysis.

Definition at line 136 of file Analysis.cc.

References Analysis::_info.

00136                                   {
00137     if (!_info) return "NONE";
00138     return _info->spiresId();
00139   }

vector< string > authors ( ) const [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 141 of file Analysis.cc.

References Analysis::_info.

00141                                          {
00142     if (!_info) return std::vector<std::string>();
00143     return _info->authors();
00144   }

string summary ( ) const [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 146 of file Analysis.cc.

References Analysis::_info.

00146                                  {
00147     if (!_info) return "NONE";
00148     return _info->summary();
00149   }

string description ( ) const [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 151 of file Analysis.cc.

References Analysis::_info.

00151                                      {
00152     if (!_info) return "NONE";
00153     return _info->description();
00154   }

string runInfo ( ) const [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 156 of file Analysis.cc.

References Analysis::_info.

00156                                  {
00157     if (!_info) return "NONE";
00158     return _info->runInfo();
00159   }

string experiment ( ) const [virtual, inherited]

Experiment which performed and published this analysis.

Definition at line 165 of file Analysis.cc.

References Analysis::_info.

00165                                     {
00166     if (!_info) return "NONE";
00167     return _info->experiment();
00168   }

string collider ( ) const [virtual, inherited]

Collider on which the experiment ran.

Definition at line 170 of file Analysis.cc.

References Analysis::_info.

00170                                   {
00171     if (!_info) return "NONE";
00172     return _info->collider();
00173   }

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

Return the pair of incoming beams required by this analysis.

Definition at line 205 of file Analysis.cc.

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

Referenced by Analysis::isCompatible().

00205                                                          {
00206     return info().beams();
00207   }

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

Sets of valid beam energy pairs, in GeV.

Definition at line 161 of file Analysis.cc.

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

00161                                                                      {
00162     return info().energies();
00163   }

string year ( ) const [virtual, inherited]

When the original experimental analysis was published.

When the refereed paper on which this is based was published, according to SPIRES.

Definition at line 175 of file Analysis.cc.

References Analysis::_info.

00175                               {
00176     if (!_info) return "NONE";
00177     return _info->year();
00178   }

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

Journal, and preprint references.

Definition at line 180 of file Analysis.cc.

References Analysis::_info.

00180                                             {
00181     if (!_info) return vector<string>();
00182     return _info->references();
00183   }

string bibKey ( ) const [virtual, inherited]

BibTeX citation key for this article.

Definition at line 185 of file Analysis.cc.

References Analysis::_info.

00185                                 {
00186     if (!_info) return "";
00187     return _info->bibKey();
00188   }

string bibTeX ( ) const [virtual, inherited]

BibTeX citation entry for this article.

Definition at line 190 of file Analysis.cc.

References Analysis::_info.

00190                                 {
00191     if (!_info) return "";
00192     return _info->bibTeX();
00193   }

string status ( ) const [virtual, inherited]

Whether this analysis is trusted (in any way!).

Definition at line 195 of file Analysis.cc.

References Analysis::_info.

00195                                 {
00196     if (!_info) return "UNVALIDATED";
00197     return _info->status();
00198   }

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

Any work to be done on this analysis.

Definition at line 200 of file Analysis.cc.

References Analysis::_info.

00200                                        {
00201     if (!_info) return vector<string>();
00202     return _info->todos();
00203   }

const ParticlePair & beams ( ) const [inherited]

Incoming beams for this run.

Definition at line 79 of file Analysis.cc.

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

Referenced by OPAL_1998_S3780481::analyze(), DELPHI_2002_069_CONF_603::analyze(), DELPHI_1995_S3137023::analyze(), BELLE_2006_S6265367::analyze(), ALEPH_2004_S5765862::analyze(), ALEPH_1996_S3486095::analyze(), and Analysis::isCompatible().

00079                                             {
00080     return handler().beams();
00081   }

const PdgIdPair beamIds ( ) const [inherited]

Incoming beam IDs for this run.

Definition at line 83 of file Analysis.cc.

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

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

00083                                           {
00084     return handler().beamIds();
00085   }

double sqrtS ( ) const [inherited]

Centre of mass energy for this run.

Definition at line 75 of file Analysis.cc.

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

Referenced by UA1_1990_S2044935::analyze(), SFM_1984_S1178091::analyze(), PDG_HADRON_MULTIPLICITIES_RATIOS::analyze(), PDG_HADRON_MULTIPLICITIES::analyze(), CDF_2004_S5839831::analyze(), ALEPH_2004_S5765862::analyze(), UA1_1990_S2044935::finalize(), PDG_HADRON_MULTIPLICITIES_RATIOS::finalize(), PDG_HADRON_MULTIPLICITIES::finalize(), CDF_2004_S5839831::finalize(), CDF_2002_S4796047::finalize(), ALEPH_2004_S5765862::finalize(), UA5_1989_S1926373::init(), UA5_1988_S1867512::init(), UA5_1986_S1583476::init(), UA1_1990_S2044935::init(), SFM_1984_S1178091::init(), PDG_HADRON_MULTIPLICITIES_RATIOS::init(), PDG_HADRON_MULTIPLICITIES::init(), OPAL_2004_S6132243::init(), MC_ZZJETS::init(), MC_ZJETS::init(), MC_WWJETS::init(), MC_WJETS::init(), MC_PHOTONJETS::init(), MC_JetAnalysis::init(), MC_HJETS::init(), MC_DIPHOTON::init(), JADE_OPAL_2000_S4300807::init(), CDF_2004_S5839831::init(), CDF_2002_S4796047::init(), CDF_1990_S2089246::init(), CDF_1988_S1865951::init(), and ALEPH_2004_S5765862::init().

00075                                {
00076     return handler().sqrtS();
00077   }

bool isCompatible	(	PdgId	beam1,
		PdgId	beam2
	)			const `[virtual, inherited]`

Is this analysis able to run on the supplied pair of beams?

Todo:: Deprecate?

Definition at line 220 of file Analysis.cc.

References Analysis::beams().

00220                                                             {
00221     PdgIdPair beams(beam1, beam2);
00222     return isCompatible(beams);
00223   }

bool isCompatible ( const PdgIdPair & beams ) const [virtual, inherited]

Is this analysis able to run on the PdgIdPair beams ?

Todo:: Deprecate?

Todo:: Need to also check internal consistency of the analysis' beam requirements with those of the projections it uses.

Definition at line 227 of file Analysis.cc.

References Rivet::compatible(), and Analysis::requiredBeams().

00227                                                           {
00228     foreach (const PdgIdPair& bp, requiredBeams()) {
00229       if (compatible(beams, bp)) return true;
00230     }
00231     return false;
00232     /// @todo Need to also check internal consistency of the analysis'
00233     /// beam requirements with those of the projections it uses.
00234   }

AnalysisHandler & handler ( ) const [inherited]

Access the controlling AnalysisHandler object.

Definition at line 269 of file Analysis.cc.

References Analysis::_analysishandler.

Referenced by Analysis::analysisFactory(), Analysis::beamIds(), Analysis::beams(), Analysis::datapointsetFactory(), Analysis::histoDir(), Analysis::histogramFactory(), Analysis::numEvents(), Analysis::sqrtS(), Analysis::sumOfWeights(), and Analysis::tree().

00269                                            {
00270     return *_analysishandler;
00271   }

void normalize	(	AIDA::IHistogram1D *&	histo,
		double	norm = `1.0`
	)			`[inherited]`

Normalize the given histogram, histo. After this call the histogram will have been transformed to a DataPointSet with the same name and path. It has the same effect as scale(histo, norm/sumOfWeights).

Parameters:

	histo	The histogram to be normalised.
	norm	The new area of the histogram.

Warning:: The old histogram will be deleted, and its pointer set to zero.

Definition at line 512 of file Analysis.cc.

References Log::ERROR, Analysis::getLog(), Analysis::name(), Analysis::scale(), Log::TRACE, Analysis::tree(), and Log::WARN.

Referenced by STAR_2008_S7869363::finalize(), OPAL_2001_S4553896::finalize(), OPAL_1998_S3780481::finalize(), H1_1994_S2919893::finalize(), ExampleAnalysis::finalize(), DELPHI_2002_069_CONF_603::finalize(), DELPHI_1995_S3137023::finalize(), D0_2010_S8671338::finalize(), D0_2009_S8320160::finalize(), D0_2008_S7554427::finalize(), D0_2008_S6879055::finalize(), D0_2007_S7075677::finalize(), D0_2004_S5992206::finalize(), D0_2001_S4674421::finalize(), D0_1996_S3324664::finalize(), D0_1996_S3214044::finalize(), CDF_2009_NOTE_9936::finalize(), CDF_2004_S5839831::finalize(), CDF_2002_S4796047::finalize(), CDF_2001_S4751469::finalize(), CDF_1997_S3541940::finalize(), CDF_1996_S3418421::finalize(), CDF_1996_S3349578::finalize(), CDF_1996_S3108457::finalize(), CDF_1993_S2742446::finalize(), ALEPH_2004_S5765862::finalize(), and ALEPH_1996_S3486095::finalize().

00512                                                                 {
00513     if (!histo) {
00514       getLog() << Log::ERROR << "Failed to normalise histo=NULL in analysis "
00515                << name() << " (norm=" << norm << ")" << endl;
00516       return;
00517     }
00518     const string hpath = tree().findPath(dynamic_cast<const AIDA::IManagedObject&>(*histo));
00519     getLog() << Log::TRACE << "Normalizing histo " << hpath << " to " << norm << endl;
00520 
00521     double oldintg = 0.0;
00522     int nBins = histo->axis().bins();
00523     for (int iBin = 0; iBin != nBins; ++iBin) {
00524       // Leaving out factor of binWidth because AIDA's "height" already includes a width factor.
00525       oldintg += histo->binHeight(iBin); // * histo->axis().binWidth(iBin);
00526     }
00527     if (oldintg == 0.0) {
00528       getLog() << Log::WARN << "Histo " << hpath << " has null integral during normalisation" << endl;
00529       return;
00530     }
00531 
00532     // Scale by the normalisation factor.
00533     scale(histo, norm/oldintg);
00534   }

void scale	(	AIDA::IHistogram1D *&	histo,
		double	scale
	)			`[inherited]`

Multiplicatively scale the given histogram, histo. After this call the histogram will have been transformed to a DataPointSet with the same name and path.

Parameters:

	histo	The histogram to be scaled.
	scale	The factor used to multiply the histogram bin heights.

Warning:: The old histogram will be deleted, and its pointer set to zero.

Definition at line 537 of file Analysis.cc.

References Analysis::datapointsetFactory(), Log::ERROR, Analysis::getLog(), Analysis::name(), Log::TRACE, and Analysis::tree().

Referenced by UA5_1989_S1926373::finalize(), UA5_1987_S1640666::finalize(), UA5_1986_S1583476::finalize(), UA5_1982_S875503::finalize(), UA1_1990_S2044935::finalize(), STAR_2006_S6870392::finalize(), STAR_2006_S6860818::finalize(), STAR_2006_S6500200::finalize(), SFM_1984_S1178091::finalize(), PDG_HADRON_MULTIPLICITIES_RATIOS::finalize(), PDG_HADRON_MULTIPLICITIES::finalize(), OPAL_2004_S6132243::finalize(), OPAL_1998_S3780481::finalize(), MC_ZZJETS::finalize(), MC_ZJETS::finalize(), MC_WWJETS::finalize(), MC_WJETS::finalize(), MC_TTBAR::finalize(), MC_PHOTONJETS::finalize(), MC_JetAnalysis::finalize(), MC_HJETS::finalize(), MC_GENERIC::finalize(), MC_DIPHOTON::finalize(), JADE_OPAL_2000_S4300807::finalize(), H1_2000_S4129130::finalize(), H1_1994_S2919893::finalize(), E735_1998_S3905616::finalize(), D0_2010_S8570965::finalize(), D0_2009_S8349509::finalize(), D0_2009_S8202443::finalize(), D0_2008_S7863608::finalize(), D0_2008_S7719523::finalize(), D0_2008_S7662670::finalize(), D0_2006_S6438750::finalize(), D0_2000_S4480767::finalize(), CDF_2009_S8436959::finalize(), CDF_2009_S8383952::finalize(), CDF_2009_S8233977::finalize(), CDF_2008_S8093652::finalize(), CDF_2008_S7540469::finalize(), CDF_2007_S7057202::finalize(), CDF_2006_S6450792::finalize(), CDF_2005_S6080774::finalize(), CDF_2001_S4563131::finalize(), CDF_2000_S4266730::finalize(), CDF_2000_S4155203::finalize(), CDF_1998_S3618439::finalize(), CDF_1990_S2089246::finalize(), CDF_1988_S1865951::finalize(), ATLAS_2010_S8591806::finalize(), ALEPH_2004_S5765862::finalize(), ALEPH_1996_S3486095::finalize(), ALEPH_1996_S3196992::finalize(), ALEPH_1991_S2435284::finalize(), Analysis::normalize(), and BinnedHistogram::scale().

00537                                                              {
00538     if (!histo) {
00539       getLog() << Log::ERROR << "Failed to scale histo=NULL in analysis "
00540           << name() << " (scale=" << scale << ")" << endl;
00541       return;
00542     }
00543     const string hpath = tree().findPath(dynamic_cast<const AIDA::IManagedObject&>(*histo));
00544     getLog() << Log::TRACE << "Scaling histo " << hpath << endl;
00545 
00546     vector<double> x, y, ex, ey;
00547     for (size_t i = 0, N = histo->axis().bins(); i < N; ++i) {
00548       x.push_back(0.5 * (histo->axis().binLowerEdge(i) + histo->axis().binUpperEdge(i)));
00549       ex.push_back(histo->axis().binWidth(i)*0.5);
00550 
00551       // "Bin height" is a misnomer in the AIDA spec: width is neglected.
00552       // We'd like to do this: y.push_back(histo->binHeight(i) * scale);
00553       y.push_back(histo->binHeight(i)*scale/histo->axis().binWidth(i));
00554 
00555       // "Bin error" is a misnomer in the AIDA spec: width is neglected.
00556       // We'd like to do this: ey.push_back(histo->binError(i) * scale);
00557       ey.push_back(histo->binError(i)*scale/histo->axis().binWidth(i));
00558     }
00559 
00560     string title = histo->title();
00561     string xtitle = histo->xtitle();
00562     string ytitle = histo->ytitle();
00563 
00564     tree().mkdir("/tmpnormalize");
00565     tree().mv(hpath, "/tmpnormalize");
00566 
00567     AIDA::IDataPointSet* dps = datapointsetFactory().createXY(hpath, title, x, y, ex, ey);
00568     dps->setXTitle(xtitle);
00569     dps->setYTitle(ytitle);
00570 
00571     tree().rm(tree().findPath(dynamic_cast<AIDA::IManagedObject&>(*histo)));
00572     tree().rmdir("/tmpnormalize");
00573 
00574     // Set histo pointer to null - it can no longer be used.
00575     histo = 0;
00576   }

Analysis & setCrossSection ( double xs ) [inherited]

Set the cross section from the generator.

Definition at line 237 of file Analysis.cc.

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

00237                                                {
00238     _crossSection = xs;
00239     _gotCrossSection = true;
00240     return *this;
00241   }

bool needsCrossSection ( ) const [inherited]

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

Todo:: Deprecate, eventually

Definition at line 244 of file Analysis.cc.

References Analysis::_needsCrossSection.

00244                                          {
00245     return _needsCrossSection;
00246   }

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 107 of file Analysis.cc.

References Log::getLog(), and Analysis::name().

00107                               {
00108     string logname = "Rivet.Analysis." + name();
00109     return Log::getLog(logname);
00110   }

double crossSection ( ) const [protected, inherited]

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

Definition at line 254 of file Analysis.cc.

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

00254                                       {
00255     if (!_gotCrossSection || _crossSection < 0) {
00256       string errMsg = "You did not set the cross section for the analysis " + name();
00257       throw Error(errMsg);
00258     }
00259     return _crossSection;
00260   }

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 262 of file Analysis.cc.

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

Referenced by UA1_1990_S2044935::finalize(), MC_PHOTONJETS::finalize(), D0_2001_S4674421::finalize(), CDF_2007_S7057202::finalize(), and CDF_1988_S1865951::finalize().

00262                                               {
00263     const double sumW = sumOfWeights();
00264     assert(sumW > 0);
00265     return _crossSection / sumW;
00266   }

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 113 of file Analysis.cc.

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

00113                                    {
00114     return handler().numEvents();
00115   }

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 118 of file Analysis.cc.

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

Referenced by Analysis::crossSectionPerEvent(), STAR_2006_S6870392::finalize(), STAR_2006_S6860818::finalize(), STAR_2006_S6500200::finalize(), PDG_HADRON_MULTIPLICITIES::finalize(), OPAL_1998_S3780481::finalize(), OPAL_1993_S2692198::finalize(), MC_ZZJETS::finalize(), MC_ZJETS::finalize(), MC_WWJETS::finalize(), MC_WJETS::finalize(), MC_TTBAR::finalize(), MC_JetAnalysis::finalize(), MC_HJETS::finalize(), MC_GENERIC::finalize(), MC_DIPHOTON::finalize(), JADE_OPAL_2000_S4300807::finalize(), DELPHI_1995_S3137023::finalize(), D0_2010_S8570965::finalize(), D0_2010_S8566488::finalize(), D0_2008_S7863608::finalize(), D0_2008_S7719523::finalize(), D0_2008_S7662670::finalize(), D0_2006_S6438750::finalize(), D0_2000_S4480767::finalize(), CDF_2009_S8436959::finalize(), CDF_2009_S8383952::finalize(), CDF_2009_S8233977::finalize(), CDF_2008_S8093652::finalize(), CDF_2008_S7828950::finalize(), CDF_2008_S7541902::finalize(), CDF_2008_S7540469::finalize(), CDF_2006_S6653332::finalize(), CDF_2006_S6450792::finalize(), CDF_2005_S6080774::finalize(), CDF_2001_S4563131::finalize(), CDF_2001_S4517016::finalize(), CDF_2000_S4266730::finalize(), CDF_2000_S4155203::finalize(), CDF_1998_S3618439::finalize(), ALEPH_2004_S5765862::finalize(), ALEPH_1996_S3486095::finalize(), ALEPH_1996_S3196992::finalize(), and ALEPH_1991_S2435284::finalize().

00118                                       {
00119     return handler().sumOfWeights();
00120   }

IAnalysisFactory & analysisFactory ( ) [protected, inherited]

Access the AIDA analysis factory of the controlling AnalysisHandler object.

Definition at line 55 of file Analysis.cc.

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

00055                                               {
00056     return handler().analysisFactory();
00057   }

ITree & tree ( ) [protected, inherited]

Access the AIDA tree of the controlling AnalysisHandler object.

Definition at line 60 of file Analysis.cc.

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

Referenced by Analysis::_makeHistoDir(), Analysis::normalize(), and Analysis::scale().

00060                         {
00061     return handler().tree();
00062   }

IHistogramFactory & histogramFactory ( ) [protected, inherited]

Access the AIDA histogram factory of the controlling AnalysisHandler object.

Definition at line 65 of file Analysis.cc.

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

Referenced by STAR_2006_S6860818::finalize(), STAR_2006_S6500200::finalize(), MC_WJETS::finalize(), MC_JetAnalysis::finalize(), MC_GENERIC::finalize(), H1_1995_S3167097::finalize(), D0_2008_S7837160::finalize(), and D0_2008_S7719523::finalize().

00065                                                 {
00066     return handler().histogramFactory();
00067   }

IDataPointSetFactory & datapointsetFactory ( ) [protected, inherited]

Access the AIDA histogram factory of the controlling AnalysisHandler object.

Definition at line 70 of file Analysis.cc.

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

Referenced by Analysis::scale().

00070                                                       {
00071     return handler().datapointsetFactory();
00072   }

const string histoDir ( ) const [protected, inherited]

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

Todo:: This doesn't change: calc and cache at Analysis construction!

Definition at line 88 of file Analysis.cc.

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

Referenced by Analysis::_makeHistoDir(), STAR_2006_S6860818::finalize(), STAR_2006_S6500200::finalize(), MC_WJETS::finalize(), D0_2008_S7837160::finalize(), and D0_2008_S7719523::finalize().

00088                                         {
00089     /// @todo This doesn't change: calc and cache at Analysis construction!
00090     string path = "/" + name();
00091     if (handler().runName().length() > 0) {
00092       path = "/" + handler().runName() + path;
00093     }
00094     while (find_first(path, "//")) {
00095       replace_all(path, "//", "/");
00096     }
00097     return path;
00098   }

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

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

Referenced by MC_JetAnalysis::finalize(), and MC_GENERIC::finalize().

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

Get bin edges for a named histo (using ref AIDA caching).

Referenced by Analysis::binEdges(), and D0_2008_S7837160::init().

const BinEdges & binEdges	(	size_t	datasetId,
		size_t	xAxisId,
		size_t	yAxisId
	)			const `[protected, inherited]`

Get bin edges for a numbered histo (using ref AIDA caching).

Definition at line 311 of file Analysis.cc.

References Analysis::binEdges(), and Rivet::makeAxisCode().

00311                                                                                            {
00312     const string hname = makeAxisCode(datasetId, xAxisId, yAxisId);
00313     return binEdges(hname);
00314   }

BinEdges logBinEdges	(	size_t	nbins,
		double	lower,
		double	upper
	)			`[protected, inherited]`

Get bin edges with logarithmic widths.

Definition at line 317 of file Analysis.cc.

Referenced by MC_ZZJETS::init(), MC_ZJETS::init(), MC_WWJETS::init(), MC_WJETS::init(), MC_PHOTONJETS::init(), MC_JetAnalysis::init(), MC_HJETS::init(), and MC_DIPHOTON::init().

00317                                                                          {
00318     assert(lower>0.0);
00319     assert(upper>lower);
00320     double loglower=log10(lower);
00321     double logupper=log10(upper);
00322     vector<double> binedges;
00323     double stepwidth=(logupper-loglower)/double(nbins);
00324     for (size_t i=0; i<=nbins; ++i) {
00325       binedges.push_back(pow(10.0, loglower+double(i)*stepwidth));
00326     }
00327     return binedges;
00328   }

AIDA::IHistogram1D* bookHistogram1D	(	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!)

Referenced by ZEUS_2001_S4815815::init(), UA5_1989_S1926373::init(), UA5_1987_S1640666::init(), UA5_1986_S1583476::init(), UA5_1982_S875503::init(), UA1_1990_S2044935::init(), STAR_2008_S7869363::init(), STAR_2006_S6870392::init(), STAR_2006_S6860818::init(), STAR_2006_S6500200::init(), SFM_1984_S1178091::init(), PDG_HADRON_MULTIPLICITIES_RATIOS::init(), PDG_HADRON_MULTIPLICITIES::init(), OPAL_2004_S6132243::init(), OPAL_2001_S4553896::init(), OPAL_1998_S3780481::init(), MC_ZZJETS::init(), MC_ZJETS::init(), MC_WWJETS::init(), MC_WJETS::init(), MC_TTBAR::init(), MC_SUSY::init(), MC_PHOTONJETUE::init(), MC_PHOTONJETS::init(), MC_JetAnalysis::init(), MC_HJETS::init(), MC_GENERIC::init(), MC_DIPHOTON::init(), MC_DIJET::init(), JADE_OPAL_2000_S4300807::init(), H1_2000_S4129130::init(), H1_1995_S3167097::init(), H1_1994_S2919893::init(), ExampleAnalysis::init(), E735_1998_S3905616::init(), DELPHI_2002_069_CONF_603::init(), DELPHI_1995_S3137023::init(), D0_2010_S8671338::init(), D0_2010_S8570965::init(), D0_2010_S8566488::init(), D0_2009_S8349509::init(), D0_2009_S8320160::init(), D0_2009_S8202443::init(), D0_2008_S7863608::init(), D0_2008_S7837160::init(), D0_2008_S7719523::init(), D0_2008_S7662670::init(), D0_2008_S7554427::init(), D0_2008_S6879055::init(), D0_2007_S7075677::init(), D0_2006_S6438750::init(), D0_2004_S5992206::init(), D0_2001_S4674421::init(), D0_2000_S4480767::init(), D0_1998_S3711838::init(), D0_1996_S3324664::init(), D0_1996_S3214044::init(), CDF_2009_S8436959::init(), CDF_2009_S8383952::init(), CDF_2009_S8233977::init(), CDF_2009_NOTE_9936::init(), CDF_2008_S8095620::init(), CDF_2008_S8093652::init(), CDF_2008_S7828950::init(), CDF_2008_S7541902::init(), CDF_2008_S7540469::init(), CDF_2007_S7057202::init(), CDF_2006_S6653332::init(), CDF_2006_S6450792::init(), CDF_2005_S6080774::init(), CDF_2004_S5839831::init(), CDF_2002_S4796047::init(), CDF_2001_S4751469::init(), CDF_2001_S4563131::init(), CDF_2001_S4517016::init(), CDF_2000_S4266730::init(), CDF_2000_S4155203::init(), CDF_1998_S3618439::init(), CDF_1997_S3541940::init(), CDF_1996_S3418421::init(), CDF_1996_S3349578::init(), CDF_1996_S3108457::init(), CDF_1994_S2952106::init(), CDF_1993_S2742446::init(), CDF_1991_S2313472::init(), CDF_1990_S2089246::init(), CDF_1988_S1865951::init(), BELLE_2006_S6265367::init(), ATLAS_2010_S8591806::init(), ALEPH_2004_S5765862::init(), ALEPH_1996_S3486095::init(), ALEPH_1996_S3196992::init(), and ALEPH_1991_S2435284::init().

AIDA::IHistogram1D* bookHistogram1D	(	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!)

AIDA::IHistogram1D* bookHistogram1D	(	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.

AIDA::IHistogram1D* bookHistogram1D	(	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.

AIDA::IProfile1D* 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!)

Referenced by UA5_1988_S1867512::init(), UA1_1990_S2044935::init(), STAR_2009_UE_HELEN::init(), STAR_2008_S7993412::init(), STAR_2006_S6860818::init(), MC_PHOTONJETUE::init(), MC_LEADINGJETS::init(), H1_2000_S4129130::init(), H1_1994_S2919893::init(), DELPHI_2002_069_CONF_603::init(), D0_1996_S3324664::init(), CDF_2009_S8233977::init(), CDF_2008_S7782535::init(), CDF_2008_NOTE_9351::init(), CDF_2008_LEADINGJETS::init(), CDF_2005_S6217184::init(), CDF_2004_S5839831::init(), CDF_2002_S4796047::init(), CDF_2001_S4751469::init(), and ATLAS_2010_S8591806::init().

AIDA::IProfile1D* 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!)

AIDA::IProfile1D* 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.

AIDA::IProfile1D* 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.

AIDA::IDataPointSet* bookDataPointSet	(	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!)

Referenced by ALEPH_2004_S5765862::finalize(), STAR_2006_S6860818::init(), OPAL_1993_S2692198::init(), MC_JetAnalysis::init(), JADE_OPAL_2000_S4300807::init(), D0_2001_S4674421::init(), CDF_2008_S7782535::init(), CDF_2008_S7541902::init(), CDF_1996_S3418421::init(), CDF_1994_S2952106::init(), and ALEPH_2004_S5765862::init().

AIDA::IDataPointSet* bookDataPointSet	(	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!)

AIDA::IDataPointSet* bookDataPointSet	(	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 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. 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.

Analysis & setBeams	(	PdgId	beam1,
		PdgId	beam2
	)			`[protected, inherited]`

Set the colliding beam pair.

Deprecated:: Use .info file and AnalysisInfo class instead

Todo:: Deprecate?

Definition at line 211 of file Analysis.cc.

References Analysis::_info.

Referenced by ALEPH_1991_S2435284::ALEPH_1991_S2435284(), ALEPH_1996_S3196992::ALEPH_1996_S3196992(), ALEPH_1996_S3486095::ALEPH_1996_S3486095(), ALEPH_2004_S5765862::ALEPH_2004_S5765862(), BELLE_2006_S6265367::BELLE_2006_S6265367(), CDF_1988_S1865951::CDF_1988_S1865951(), CDF_1990_S2089246::CDF_1990_S2089246(), CDF_1991_S2313472::CDF_1991_S2313472(), CDF_1993_S2742446::CDF_1993_S2742446(), CDF_1994_S2952106::CDF_1994_S2952106(), CDF_1996_S3108457::CDF_1996_S3108457(), CDF_1996_S3349578::CDF_1996_S3349578(), CDF_1996_S3418421::CDF_1996_S3418421(), CDF_1997_S3541940::CDF_1997_S3541940(), CDF_1998_S3618439::CDF_1998_S3618439(), CDF_2000_S4155203::CDF_2000_S4155203(), CDF_2000_S4266730::CDF_2000_S4266730(), CDF_2001_S4517016::CDF_2001_S4517016(), CDF_2001_S4563131::CDF_2001_S4563131(), CDF_2001_S4751469::CDF_2001_S4751469(), CDF_2002_S4796047::CDF_2002_S4796047(), CDF_2004_S5839831::CDF_2004_S5839831(), CDF_2005_S6080774::CDF_2005_S6080774(), CDF_2005_S6217184::CDF_2005_S6217184(), CDF_2006_S6450792::CDF_2006_S6450792(), CDF_2006_S6653332::CDF_2006_S6653332(), CDF_2007_S7057202::CDF_2007_S7057202(), CDF_2008_LEADINGJETS::CDF_2008_LEADINGJETS(), CDF_2008_NOTE_9351::CDF_2008_NOTE_9351(), CDF_2008_S7540469::CDF_2008_S7540469(), CDF_2008_S7541902::CDF_2008_S7541902(), CDF_2008_S7782535::CDF_2008_S7782535(), CDF_2008_S7828950::CDF_2008_S7828950(), CDF_2008_S8093652::CDF_2008_S8093652(), CDF_2008_S8095620::CDF_2008_S8095620(), CDF_2009_NOTE_9936::CDF_2009_NOTE_9936(), CDF_2009_S8057893::CDF_2009_S8057893::CDF_2009_S8057893(), CDF_2009_S8233977::CDF_2009_S8233977(), CDF_2009_S8383952::CDF_2009_S8383952(), CDF_2009_S8436959::CDF_2009_S8436959(), D0_1996_S3214044::D0_1996_S3214044(), D0_1996_S3324664::D0_1996_S3324664(), D0_1998_S3711838::D0_1998_S3711838(), D0_2001_S4674421::D0_2001_S4674421(), D0_2004_S5992206::D0_2004_S5992206(), D0_2006_S6438750::D0_2006_S6438750(), D0_2007_S7075677::D0_2007_S7075677(), D0_2008_S6879055::D0_2008_S6879055(), D0_2008_S7554427::D0_2008_S7554427(), D0_2008_S7662670::D0_2008_S7662670(), D0_2008_S7719523::D0_2008_S7719523(), D0_2008_S7837160::D0_2008_S7837160(), D0_2008_S7863608::D0_2008_S7863608(), D0_2009_S8202443::D0_2009_S8202443(), D0_2009_S8320160::D0_2009_S8320160(), D0_2009_S8349509::D0_2009_S8349509(), D0_2010_S8566488::D0_2010_S8566488(), D0_2010_S8570965::D0_2010_S8570965(), D0_2010_S8671338::D0_2010_S8671338(), DELPHI_1995_S3137023::DELPHI_1995_S3137023(), DELPHI_2002_069_CONF_603::DELPHI_2002_069_CONF_603(), E735_1998_S3905616::E735_1998_S3905616(), H1_1994_S2919893::H1_1994_S2919893(), H1_1995_S3167097::H1_1995_S3167097(), H1_2000_S4129130::H1_2000_S4129130(), JADE_OPAL_2000_S4300807::JADE_OPAL_2000_S4300807(), OPAL_1993_S2692198::OPAL_1993_S2692198(), OPAL_1998_S3780481::OPAL_1998_S3780481(), OPAL_2001_S4553896::OPAL_2001_S4553896(), PDG_HADRON_MULTIPLICITIES::PDG_HADRON_MULTIPLICITIES(), PDG_HADRON_MULTIPLICITIES_RATIOS::PDG_HADRON_MULTIPLICITIES_RATIOS(), SFM_1984_S1178091::SFM_1984_S1178091(), STAR_2006_S6500200::STAR_2006_S6500200(), STAR_2006_S6860818::STAR_2006_S6860818(), STAR_2006_S6870392::STAR_2006_S6870392(), STAR_2008_S7869363::STAR_2008_S7869363(), STAR_2008_S7993412::STAR_2008_S7993412(), STAR_2009_UE_HELEN::STAR_2009_UE_HELEN(), UA1_1990_S2044935::UA1_1990_S2044935(), UA5_1986_S1583476::UA5_1986_S1583476(), UA5_1987_S1640666::UA5_1987_S1640666(), UA5_1988_S1867512::UA5_1988_S1867512(), UA5_1989_S1926373::UA5_1989_S1926373(), and ZEUS_2001_S4815815::ZEUS_2001_S4815815().

00211                                                        {
00212     assert(_info.get() != 0);
00213     _info->_beams.clear();
00214     _info->_beams += make_pair(beam1, beam2);
00215     return *this;
00216   }

Analysis & setNeedsCrossSection ( bool needed ) [protected, inherited]

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

Todo:: Deprecate, eventually

Definition at line 249 of file Analysis.cc.

References Analysis::_needsCrossSection.

Referenced by ATLAS_2010_S8591806::ATLAS_2010_S8591806(), CDF_1991_S2313472::CDF_1991_S2313472(), CDF_1993_S2742446::CDF_1993_S2742446(), CDF_1996_S3108457::CDF_1996_S3108457(), CDF_1998_S3618439::CDF_1998_S3618439(), CDF_2000_S4155203::CDF_2000_S4155203(), CDF_2000_S4266730::CDF_2000_S4266730(), CDF_2001_S4517016::CDF_2001_S4517016(), CDF_2001_S4563131::CDF_2001_S4563131(), CDF_2005_S6080774::CDF_2005_S6080774(), CDF_2006_S6450792::CDF_2006_S6450792(), CDF_2006_S6653332::CDF_2006_S6653332(), CDF_2007_S7057202::CDF_2007_S7057202(), CDF_2008_S7540469::CDF_2008_S7540469(), CDF_2008_S7541902::CDF_2008_S7541902(), CDF_2008_S7828950::CDF_2008_S7828950(), CDF_2008_S8093652::CDF_2008_S8093652(), CDF_2009_NOTE_9936::CDF_2009_NOTE_9936(), CDF_2009_S8233977::CDF_2009_S8233977(), CDF_2009_S8383952::CDF_2009_S8383952(), CDF_2009_S8436959::CDF_2009_S8436959(), D0_1996_S3214044::D0_1996_S3214044(), D0_1996_S3324664::D0_1996_S3324664(), D0_1998_S3711838::D0_1998_S3711838(), D0_2000_S4480767::D0_2000_S4480767(), D0_2001_S4674421::D0_2001_S4674421(), D0_2006_S6438750::D0_2006_S6438750(), D0_2008_S7662670::D0_2008_S7662670(), D0_2008_S7719523::D0_2008_S7719523(), D0_2008_S7863608::D0_2008_S7863608(), D0_2010_S8566488::D0_2010_S8566488(), D0_2010_S8570965::D0_2010_S8570965(), MC_DIPHOTON::MC_DIPHOTON(), MC_HJETS::MC_HJETS(), MC_JetAnalysis::MC_JetAnalysis(), MC_JETS::MC_JETS(), MC_PHOTONJETS::MC_PHOTONJETS(), MC_WJETS::MC_WJETS(), MC_WWJETS::MC_WWJETS(), MC_ZJETS::MC_ZJETS(), MC_ZZJETS::MC_ZZJETS(), OPAL_2001_S4553896::OPAL_2001_S4553896(), STAR_2006_S6870392::STAR_2006_S6870392(), STAR_2008_S7869363::STAR_2008_S7869363(), and UA1_1990_S2044935::UA1_1990_S2044935().

00249                                                       {
00250     _needsCrossSection = needed;
00251     return *this;
00252   }

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

Get the contained projections, including recursion.

Definition at line 58 of file ProjectionApplier.hh.

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

Referenced by Projection::beamPairs().

00058                                                       {
00059       return getProjHandler().getChildProjections(*this, ProjectionHandler::DEEP);
00060     }

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

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

Definition at line 65 of file ProjectionApplier.hh.

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

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

00065                                                            {
00066       const Projection& p = getProjHandler().getProjection(*this, name);
00067       return pcast<PROJ>(p);
00068     }

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 73 of file ProjectionApplier.hh.

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

00073                                                                  {
00074       return getProjHandler().getProjection(*this, name);
00075     }

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

Apply the supplied projection on event.

Definition at line 83 of file ProjectionApplier.hh.

References ProjectionApplier::_applyProjection().

Referenced by HadronicFinalState::project(), and FinalStateHCM::project().

00083                                                                           {
00084       return pcast<PROJ>(_applyProjection(evt, proj));
00085     }

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

Apply the supplied projection on event.

Definition at line 90 of file ProjectionApplier.hh.

References ProjectionApplier::_applyProjection().

00090                                                                                 {
00091       return pcast<PROJ>(_applyProjection(evt, proj));
00092     }

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

Apply the named projection on event.

Definition at line 97 of file ProjectionApplier.hh.

References ProjectionApplier::_applyProjection().

00097                                                                                {
00098       return pcast<PROJ>(_applyProjection(evt, name));
00099     }

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

Get a reference to the ProjectionHandler for this thread.

Definition at line 110 of file ProjectionApplier.hh.

References ProjectionApplier::_projhandler.

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

00110                                               {
00111       assert(_projhandler);
00112       return *_projhandler;
00113     }

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 130 of file ProjectionApplier.hh.

References ProjectionApplier::_addProjection().

Referenced by ZFinder::_init(), WFinder::_init(), VetoedFinalState::addVetoOnThisFinalState(), CDF_2009_S8057893::CDF_2009_S8057893::init(), CentralEtHCM::CentralEtHCM(), ChargedFinalState::ChargedFinalState(), ChargedLeptons::ChargedLeptons(), ClusteredPhotons::ClusteredPhotons(), DISKinematics::DISKinematics(), DISLepton::DISLepton(), FinalState::FinalState(), FinalStateHCM::FinalStateHCM(), FoxWolframMoments::FoxWolframMoments(), HadronicFinalState::HadronicFinalState(), Hemispheres::Hemispheres(), IdentifiedFinalState::IdentifiedFinalState(), ZEUS_2001_S4815815::init(), UA5_1989_S1926373::init(), UA5_1988_S1867512::init(), UA5_1987_S1640666::init(), UA5_1986_S1583476::init(), UA5_1982_S875503::init(), UA1_1990_S2044935::init(), STAR_2009_UE_HELEN::init(), STAR_2008_S7993412::init(), STAR_2008_S7869363::init(), STAR_2006_S6870392::init(), STAR_2006_S6860818::init(), STAR_2006_S6500200::init(), SFM_1984_S1178091::init(), PDG_HADRON_MULTIPLICITIES_RATIOS::init(), PDG_HADRON_MULTIPLICITIES::init(), OPAL_2004_S6132243::init(), OPAL_2001_S4553896::init(), OPAL_1998_S3780481::init(), OPAL_1993_S2692198::init(), MC_ZZJETS::init(), MC_ZJETS::init(), MC_WWJETS::init(), MC_WJETS::init(), MC_TTBAR::init(), MC_SUSY::init(), MC_PHOTONJETUE::init(), MC_PHOTONJETS::init(), MC_LEADINGJETS::init(), MC_JETS::init(), MC_HJETS::init(), MC_GENERIC::init(), MC_DIPHOTON::init(), MC_DIJET::init(), JADE_OPAL_2000_S4300807::init(), H1_2000_S4129130::init(), H1_1995_S3167097::init(), H1_1994_S2919893::init(), ExampleAnalysis::init(), E735_1998_S3905616::init(), DELPHI_2002_069_CONF_603::init(), DELPHI_1995_S3137023::init(), D0_2010_S8671338::init(), D0_2010_S8570965::init(), D0_2010_S8566488::init(), D0_2009_S8349509::init(), D0_2009_S8320160::init(), D0_2009_S8202443::init(), D0_2008_S7863608::init(), D0_2008_S7837160::init(), D0_2008_S7719523::init(), D0_2008_S7662670::init(), D0_2008_S7554427::init(), D0_2008_S6879055::init(), D0_2007_S7075677::init(), D0_2006_S6438750::init(), D0_2004_S5992206::init(), D0_2001_S4674421::init(), D0_2000_S4480767::init(), D0_1998_S3711838::init(), D0_1996_S3324664::init(), D0_1996_S3214044::init(), CDF_2009_S8436959::init(), CDF_2009_S8383952::init(), CDF_2009_S8233977::init(), CDF_2009_NOTE_9936::init(), CDF_2008_S8095620::init(), CDF_2008_S8093652::init(), CDF_2008_S7828950::init(), CDF_2008_S7782535::init(), CDF_2008_S7541902::init(), CDF_2008_S7540469::init(), CDF_2008_NOTE_9351::init(), CDF_2008_LEADINGJETS::init(), CDF_2007_S7057202::init(), CDF_2006_S6653332::init(), CDF_2006_S6450792::init(), CDF_2005_S6217184::init(), CDF_2005_S6080774::init(), CDF_2004_S5839831::init(), CDF_2002_S4796047::init(), CDF_2001_S4751469::init(), CDF_2001_S4563131::init(), CDF_2001_S4517016::init(), CDF_2000_S4266730::init(), CDF_2000_S4155203::init(), CDF_1998_S3618439::init(), CDF_1997_S3541940::init(), CDF_1996_S3418421::init(), CDF_1996_S3349578::init(), CDF_1996_S3108457::init(), CDF_1994_S2952106::init(), CDF_1993_S2742446::init(), CDF_1991_S2313472::init(), CDF_1990_S2089246::init(), CDF_1988_S1865951::init(), BELLE_2006_S6265367::init(), ATLAS_2010_S8591806::init(), ALEPH_2004_S5765862::init(), ALEPH_1996_S3486095::init(), ALEPH_1996_S3196992::init(), ALEPH_1991_S2435284::init(), IsolationProjection::IsolationProjection(), JetAlg::JetAlg(), JetShape::JetShape(), LeadingParticlesFinalState::LeadingParticlesFinalState(), LossyFinalState< Rivet::ConstRandomFilter >::LossyFinalState(), MergedFinalState::MergedFinalState(), Multiplicity::Multiplicity(), NeutralFinalState::NeutralFinalState(), ParisiTensor::ParisiTensor(), Sphericity::Sphericity(), SVertex::SVertex(), Thrust::Thrust(), TotalVisibleMomentum::TotalVisibleMomentum(), TriggerCDFRun0Run1::TriggerCDFRun0Run1(), TriggerCDFRun2::TriggerCDFRun2(), TriggerUA5::TriggerUA5(), and VetoedFinalState::VetoedFinalState().

00130                                                                        {
00131       const Projection& reg = _addProjection(proj, name);
00132       const PROJ& rtn = dynamic_cast<const PROJ&>(reg);
00133       return rtn;
00134     }

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, Log::ERROR, ProjectionApplier::getLog(), ProjectionApplier::getProjHandler(), ProjectionApplier::name(), Projection::name(), and ProjectionHandler::registerProjection().

Referenced by ProjectionApplier::addProjection().

00034                                                                              {
00035     if (!_allowProjReg) {
00036       getLog() << Log::ERROR << "Trying to register projection '"
00037                << proj.name() << "' before init phase in '" << this->name() << "'." << endl;
00038       exit(2);
00039     }
00040     const Projection& reg = getProjHandler().registerProjection(*this, proj, name);
00041     return reg;
00042   }