#ifndef __FASTJET_SELECTOR_HH__
#define __FASTJET_SELECTOR_HH__
//FJSTARTHEADER
// $Id: Selector.hh 3504 2014-08-01 06:07:54Z soyez $
//
// Copyright (c) 2009-2014, Matteo Cacciari, Gavin P. Salam and Gregory Soyez
//
//----------------------------------------------------------------------
// This file is part of FastJet.
//
// FastJet is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// The algorithms that underlie FastJet have required considerable
// development. They are described in the original FastJet paper,
// hep-ph/0512210 and in the manual, arXiv:1111.6097. If you use
// FastJet as part of work towards a scientific publication, please
// quote the version you use and include a citation to the manual and
// optionally also to hep-ph/0512210.
//
// FastJet is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with FastJet. If not, see .
//----------------------------------------------------------------------
//FJENDHEADER
#include "fastjet/PseudoJet.hh"
#ifndef __FJCORE__
#include "fastjet/RangeDefinition.hh" // for initialisation from a RangeDefinition
#endif // __FJCORE__
#include
#include
FASTJET_BEGIN_NAMESPACE // defined in fastjet/internal/base.hh
//----------------------------------------------------------------------
/// @ingroup selectors
/// \class Selector
/// Class that encodes information about cuts and other selection
/// criteria that can be applied to PseudoJet(s).
///
class Selector;
//----------------------------------------------------------------------
/// @ingroup selectors
/// \class SelectorWorker
/// default selector worker is an abstract virtual base class
///
/// The Selector class is only an interface, it is the SelectorWorker
/// that really does the work. To implement various selectors, one
/// thus has to overload this class.
class SelectorWorker {
public:
//----------------------------------------------------------
// fundamental info
//----------------------------------------------------------
/// default dtor
virtual ~SelectorWorker() {}
//----------------------------------------------------------
// basic operations for checking what gets selected
//----------------------------------------------------------
/// returns true if a given object passes the selection criterion,
/// and is the main function that needs to be overloaded by derived
/// workers.
///
/// NB: this function is used only if applies_jet_by_jet() returns
/// true. If it does not, then derived classes are expected to
/// (re)implement the terminator function()
virtual bool pass(const PseudoJet & jet) const = 0;
/// For each jet that does not pass the cuts, this routine sets the
/// pointer to 0.
///
/// It does not assume that the PseudoJet* passed as argument are not NULL
virtual void terminator(std::vector & jets) const {
for (unsigned i = 0; i < jets.size(); i++) {
if (jets[i] && !pass(*jets[i])) jets[i] = NULL;
}
}
/// returns true if this can be applied jet by jet
virtual bool applies_jet_by_jet() const {return true;}
/// returns a description of the worker
virtual std::string description() const {return "missing description";}
//----------------------------------------------------------
// operations for dealing with reference jets
//----------------------------------------------------------
/// returns true if the worker is defined with respect to a reference jet
virtual bool takes_reference() const { return false;}
/// sets the reference jet for the selector
/// NB: "reference" is commented to avoid unused-variable compiler warnings
virtual void set_reference(const PseudoJet & /*reference*/){
throw Error("set_reference(...) cannot be used for a selector worker that does not take a reference");
}
/// return a copy of the current object.
///
/// This function is only called for objects that take a reference and need
/// not be reimplemented otherwise.
virtual SelectorWorker* copy(){
throw Error("this SelectorWorker has nothing to copy");
}
//----------------------------------------------------------
// operations for area and extent
//----------------------------------------------------------
/// returns the rapidity range for which it may return "true"
virtual void get_rapidity_extent(double & rapmin, double & rapmax) const {
rapmax = std::numeric_limits::infinity();
rapmin = -rapmax;
}
/// check if it is a geometric selector (i.e. only puts constraints
/// on rapidity and azimuthal angle)
virtual bool is_geometric() const { return false;}
/// check if it has a finite area
virtual bool has_finite_area() const;
/// check if it has an analytically computable area
virtual bool has_known_area() const { return false;}
/// if it has a computable area, return it
virtual double known_area() const{
throw Error("this selector has no computable area");
}
};
//----------------------------------------------------------------------
// class Selector
//
// Class that encodes information about cuts that
class Selector{
public:
/// default constructor produces a Selector whose action is undefined
/// (any attempt to use it will lead to an error)
Selector() {}
/// constructor that causes the Selector to use the supplied worker
///
/// Note that the Selector takes ownership of the pointer to the
/// worker (and so will delete automatically when appropriate).
Selector(SelectorWorker * worker_in) {_worker.reset(worker_in);}
#ifndef __FJCORE__
/// ctor from a RangeDefinition
///
/// This is provided for backward compatibility and will be removed in
/// a future major release of FastJet
///
/// Watch out that the Selector will only hold a pointer to the
/// range so the selector will crash if one tries to use it after
/// the range has gone out of scope. We thus strongly advise against
/// the direct use of this constructor.
Selector(const RangeDefinition &range);
#endif // __FJCORE__
/// dummy virtual dtor
virtual ~Selector(){}
/// return true if the jet passes the selection
bool pass(const PseudoJet & jet) const {
if (!validated_worker()->applies_jet_by_jet()) {
throw Error("Cannot apply this selector to an individual jet");
}
return _worker->pass(jet);
}
/// an operator way of knowing whether a given jet passes the selection or not
bool operator()(const PseudoJet & jet) const {
return pass(jet);
}
/// Return a count of the objects that pass the selection.
///
/// This will often be more efficient that getting the vector of objects that
/// passes and then evaluating the size of the vector
unsigned int count(const std::vector & jets) const;
/// Return the 4-vector sum of the objects that pass the selection.
///
/// This will often be more efficient that getting the vector of objects that
/// passes and then evaluating the size of the vector
PseudoJet sum(const std::vector & jets) const;
/// Return the scalar pt sum of the objects that pass the selection.
///
/// This will often be more efficient that getting the vector of objects that
/// passes and then evaluating the size of the vector
double scalar_pt_sum(const std::vector & jets) const;
/// sift the input jets into two vectors -- those that pass the selector
/// and those that do not
void sift(const std::vector & jets,
std::vector & jets_that_pass,
std::vector & jets_that_fail) const;
/// returns true if this can be applied jet by jet
bool applies_jet_by_jet() const {
return validated_worker()->applies_jet_by_jet();
}
/// returns a vector with the jets that pass the selection
std::vector operator()(const std::vector & jets) const;
/// For each jet that does not pass the cuts, this routine sets the
/// pointer to 0.
///
/// It is legitimate for some (or all) of the pointers that are
/// passed to already be NULL.
virtual void nullify_non_selected(std::vector & jets) const {
validated_worker()->terminator(jets);
}
/// returns the rapidity range for which it may return "true"
void get_rapidity_extent(double &rapmin, double &rapmax) const {
return validated_worker()->get_rapidity_extent(rapmin, rapmax);
}
/// returns a textual description of the selector
std::string description() const {
return validated_worker()->description();
}
/// returns true if it is a geometric selector (i.e. one that only puts
/// constraints on rapidities and azimuthal angles)
bool is_geometric() const{
return validated_worker()->is_geometric();
}
/// returns true if it has a meaningful and finite area (i.e. the
/// Selector has the property that is_geometric() returns true and
/// the rapidity extent is finite).
bool has_finite_area() const{
return validated_worker()->has_finite_area();
}
#ifndef __FJCORE__
/// returns the rapidity-phi area associated with the Selector
/// (throws InvalidArea if the area does not make sense).
///
/// If the result is not known analytically, the area will be
/// estimated using a pseudo Monte Carlo method (as for jet areas),
/// using the default ghost area from the GhostedAreaSpec class
/// (0.01). The Monte Carlo estimate involves a time penalty
/// proportional to the ratio of the rapidity extent of the Selector
/// divided by the ghost area.
double area() const;
/// returns the rapidity-phi area associated with the Selector
/// (throws InvalidArea if the area does not make sense).
///
/// The behaviour is the as with the area() call, but with the
/// ability to additionally specify the ghost area to be used in the
/// case of a Monte Carlo area evaluation.
///
double area(double ghost_area) const;
#endif // __FJCORE__
/// returns a (reference to) the underlying worker's shared pointer
const SharedPtr & worker() const {return _worker;}
/// returns a worker if there is a valid one, otherwise throws an InvalidWorker error
const SelectorWorker* validated_worker() const {
const SelectorWorker* worker_ptr = _worker.get();
if (worker_ptr == 0) throw InvalidWorker();
return worker_ptr;
}
/// returns true if this can be applied jet by jet
bool takes_reference() const {
return validated_worker()->takes_reference();
}
/// set the reference jet for this Selector
const Selector & set_reference(const PseudoJet &reference){
// if the worker does not take a reference jet, do nothing
if (! validated_worker()->takes_reference()){
return *this;
}
// since this is a non-const operation, make sure we have a
// correct behaviour with respect to shared workers
_copy_worker_if_needed();
_worker->set_reference(reference);
return *this;
}
/// class that gets throw when a Selector is applied despite it not
/// having a valid underlying worker.
class InvalidWorker : public Error {
public:
InvalidWorker() : Error("Attempt to use Selector with no valid underlying worker") {}
};
/// class that gets throw when a Selector is applied despite it not
/// having a valid underlying worker.
class InvalidArea : public Error {
public:
InvalidArea() : Error("Attempt to obtain area from Selector for which this is not meaningful") {}
};
// some operators (applying directly on a Selector)
//----------------------------------------------------------------------
/// For 2 Selectors a and b, a &= b is eauivalent to a = a && b;
Selector & operator &=(const Selector & b);
/// For 2 Selectors a and b, a |= b is eauivalent to a = a || b;
Selector & operator |=(const Selector & b);
protected:
/// Helper for copying selector workers if needed
///
/// The following is needed if we want to modify a selectors that
/// shares a worker with another selector. In that case, we need to
/// get another copy of the worker to avoid interferences
///
/// Note that any non-const operation has to call this to behave
/// correctly w.r.t shared workers!
void _copy_worker_if_needed(){
// do nothing if there's a sinlge user of the worker
if (_worker.unique()) return;
// call the worker's copy
//std::cout << "will make a copy of " << description() << std::endl;
_worker.reset(_worker->copy());
}
private:
SharedPtr _worker; ///< the underlying worker
};
//----------------------------------------------------------------------
// a list of specific selectors
//----------------------------------------------------------------------
/// \addtogroup selectors
/// @{
// fundamental selectors
//----------------------------------------------------------------------
// "identity" selector that lets everything pass
Selector SelectorIdentity();
// logical operations
//----------------------------------------------------------------------
/// logical not applied on a selector
///
/// This will keep objects that do not pass the 's' selector
Selector operator!(const Selector & s);
/// logical or between two selectors
///
/// this will keep the objects that are selected by s1 or s2
Selector operator ||(const Selector & s1, const Selector & s2);
/// logical and between two selectors
///
/// this will keep the objects that are selected by both s1 and s2
///
/// watch out: for both s1 and s2, the selection is applied on the
/// original list of objects. For successive applications of two
/// selectors (convolution/multiplication) see the operator *
Selector operator&&(const Selector & s1, const Selector & s2);
/// successive application of 2 selectors
///
/// Apply the selector s2, then the selector s1.
///
/// watch out: the operator * acts like an operator product i.e. does
/// not commute. The order of its arguments is therefore important.
/// Whenever they commute (in particluar, when they apply jet by
/// jet), this would have the same effect as the logical &&.
Selector operator*(const Selector & s1, const Selector & s2);
// selection with kinematic cuts
//----------------------------------------------------------------------
Selector SelectorPtMin(double ptmin); ///< select objects with pt >= ptmin
Selector SelectorPtMax(double ptmax); ///< select objects with pt <= ptmax
Selector SelectorPtRange(double ptmin, double ptmax); ///< select objects with ptmin <= pt <= ptmax
Selector SelectorEtMin(double Etmin); ///< select objects with Et >= Etmin
Selector SelectorEtMax(double Etmax); ///< select objects with Et <= Etmax
Selector SelectorEtRange(double Etmin, double Etmax); ///< select objects with Etmin <= Et <= Etmax
Selector SelectorEMin(double Emin); ///< select objects with E >= Emin
Selector SelectorEMax(double Emax); ///< select objects with E <= Emax
Selector SelectorERange(double Emin, double Emax); ///< select objects with Emin <= E <= Emax
Selector SelectorMassMin(double Mmin); ///< select objects with Mass >= Mmin
Selector SelectorMassMax(double Mmax); ///< select objects with Mass <= Mmax
Selector SelectorMassRange(double Mmin, double Mmax); ///< select objects with Mmin <= Mass <= Mmax
Selector SelectorRapMin(double rapmin); ///< select objects with rap >= rapmin
Selector SelectorRapMax(double rapmax); ///< select objects with rap <= rapmax
Selector SelectorRapRange(double rapmin, double rapmax); ///< select objects with rapmin <= rap <= rapmax
Selector SelectorAbsRapMin(double absrapmin); ///< select objects with |rap| >= absrapmin
Selector SelectorAbsRapMax(double absrapmax); ///< select objects with |rap| <= absrapmax
Selector SelectorAbsRapRange(double absrapmin, double absrapmax); ///< select objects with absrapmin <= |rap| <= absrapmax
Selector SelectorEtaMin(double etamin); ///< select objects with eta >= etamin
Selector SelectorEtaMax(double etamax); ///< select objects with eta <= etamax
Selector SelectorEtaRange(double etamin, double etamax); ///< select objects with etamin <= eta <= etamax
Selector SelectorAbsEtaMin(double absetamin); ///< select objects with |eta| >= absetamin
Selector SelectorAbsEtaMax(double absetamax); ///< select objects with |eta| <= absetamax
Selector SelectorAbsEtaRange(double absetamin, double absetamax); ///< select objects with absetamin <= |eta| <= absetamax
Selector SelectorPhiRange(double phimin, double phimax); ///< select objects with phimin <= phi <= phimax
/// select objects with rapmin <= rap <= rapmax && phimin <= phi <= phimax
///
/// Note that this is essentially a combination of SelectorRapRange
/// and SelectorPhiRange. We provide it as a Selector on its own in
/// order to use the known area (which would otherwise be lost by the &&
/// operator)
Selector SelectorRapPhiRange(double rapmin, double rapmax, double phimin, double phimax);
/// select the n hardest objects
Selector SelectorNHardest(unsigned int n);
// Selectors that take (require) a reference jet.
//----------------------------------------------------------------------
/// select objets within a distance 'radius' from the location of the
/// reference jet, set by Selector::set_reference(...)
Selector SelectorCircle(const double radius);
/// select objets with distance from the reference jet is between 'radius_in'
/// and 'radius_out'; the reference jet is set by Selector::set_reference(...)
Selector SelectorDoughnut(const double radius_in, const double radius_out);
/// select objets within a rapidity distance 'half_width' from the
/// location of the reference jet, set by Selector::set_reference(...)
Selector SelectorStrip(const double half_width);
/// select objets within rapidity distance 'half_rap_width' from the
/// reference jet and azimuthal-angle distance within 'half_phi_width'; the
/// reference jet is set by Selector::set_reference(...)
Selector SelectorRectangle(const double half_rap_width, const double half_phi_width);
/// select objects that carry at least a fraction "fraction" of the
/// reference jet. The reference jet must have been set with
/// Selector::set_reference(...)
Selector SelectorPtFractionMin(double fraction);
// additional (mostly helper) selectors
//----------------------------------------------------------------------
/// select PseudoJet with 0 momentum
Selector SelectorIsZero();
#ifndef __FJCORE__
/// select objects that are (or are only made of) ghosts.
/// PseudoJets for which has_area() are considered non-pure-ghost.
Selector SelectorIsPureGhost();
#endif // __FJCORE__
/// @}
FASTJET_END_NAMESPACE // defined in fastjet/internal/base.hh
#endif // __FASTJET_SELECTOR_HH__