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Last change on this file since aa3c287 was b7b836a, checked in by Pavel Demin <pavel-demin@…>, 6 years ago

update FastJet library to 3.3.1 and FastJet Contrib library to 1.036

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[35cdc46]1#ifndef __FASTJET_JETDEFINITION_HH__
2#define __FASTJET_JETDEFINITION_HH__
3
4//FJSTARTHEADER
[b7b836a]5// $Id: JetDefinition.hh 4354 2018-04-22 07:12:37Z salam $
[d7d2da3]6//
[b7b836a]7// Copyright (c) 2005-2018, Matteo Cacciari, Gavin P. Salam and Gregory Soyez
[d7d2da3]8//
9//----------------------------------------------------------------------
10// This file is part of FastJet.
11//
12// FastJet is free software; you can redistribute it and/or modify
13// it under the terms of the GNU General Public License as published by
14// the Free Software Foundation; either version 2 of the License, or
15// (at your option) any later version.
16//
17// The algorithms that underlie FastJet have required considerable
[35cdc46]18// development. They are described in the original FastJet paper,
19// hep-ph/0512210 and in the manual, arXiv:1111.6097. If you use
[d7d2da3]20// FastJet as part of work towards a scientific publication, please
[35cdc46]21// quote the version you use and include a citation to the manual and
22// optionally also to hep-ph/0512210.
[d7d2da3]23//
24// FastJet is distributed in the hope that it will be useful,
25// but WITHOUT ANY WARRANTY; without even the implied warranty of
26// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
27// GNU General Public License for more details.
28//
29// You should have received a copy of the GNU General Public License
30// along with FastJet. If not, see <http://www.gnu.org/licenses/>.
31//----------------------------------------------------------------------
[35cdc46]32//FJENDHEADER
[d7d2da3]33
34#include<cassert>
35#include "fastjet/internal/numconsts.hh"
36#include "fastjet/PseudoJet.hh"
[1d208a2]37#include "fastjet/internal/deprecated.hh"
[d7d2da3]38#include<string>
39#include<memory>
40
41FASTJET_BEGIN_NAMESPACE // defined in fastjet/internal/base.hh
42
43/// return a string containing information about the release
44// NB: (implemented in ClusterSequence.cc but defined here because
45// this is a visible location)
46std::string fastjet_version_string();
47
48//======================================================================
49/// the various options for the algorithmic strategy to adopt in
50/// clustering events with kt and cambridge style algorithms.
51enum Strategy {
[35cdc46]52 /// Like N2MHTLazy9 in a number of respects, but does not calculate
53 /// ghost-ghost distances and so does not carry out ghost-ghost
54 /// recombination.
55 ///
56 /// If you want active ghosted areas, then this is only suitable for
57 /// use with the anti-kt algorithm (or genkt with negative p), and
58 /// does not produce any pure ghost jets. If used with active areas
59 /// with Kt or Cam algorithms it will actually produce a passive
60 /// area.
61 ///
62 /// Particles are deemed to be ghosts if their pt is below a
63 /// threshold (currently 1e-50, hard coded as ghost_limit in
64 /// LazyTiling9SeparateGhosts).
65 ///
66 /// Currently for events with a couple of thousand normal particles
67 /// and O(10k) ghosts, this can be quicker than N2MHTLazy9, which
68 /// would otherwise be the best strategy.
69 ///
70 /// New in FJ3.1
71 N2MHTLazy9AntiKtSeparateGhosts = -10,
72 /// only looks into a neighbouring tile for a particle's nearest
73 /// neighbour (NN) if that particle's in-tile NN is further than the
74 /// distance to the edge of the neighbouring tile. Uses tiles of
75 /// size R and a 3x3 tile grid around the particle.
76 /// New in FJ3.1
77 N2MHTLazy9 = -7,
78 /// Similar to N2MHTLazy9, but uses tiles of size R/2 and a 5x5 tile
79 /// grid around the particle.
80 /// New in FJ3.1
81 N2MHTLazy25 = -6,
82 /// Like to N2MHTLazy9 but uses slightly different optimizations,
83 /// e.g. for calculations of distance to nearest tile; as of
84 /// 2014-07-18 it is slightly slower and not recommended for
85 /// production use. To considered deprecated.
86 /// New in FJ3.1
87 N2MHTLazy9Alt = -5,
88 /// faster that N2Tiled above about 500 particles; differs from it
89 /// by retainig the di(closest j) distances in a MinHeap (sort of
90 /// priority queue) rather than a simple vector.
[d7d2da3]91 N2MinHeapTiled = -4,
92 /// fastest from about 50..500
93 N2Tiled = -3,
94 /// legacy
95 N2PoorTiled = -2,
96 /// fastest below 50
97 N2Plain = -1,
98 /// worse even than the usual N^3 algorithms
99 N3Dumb = 0,
[35cdc46]100 /// automatic selection of the best (based on N), including
101 /// the LazyTiled strategies that are new to FJ3.1
[d7d2da3]102 Best = 1,
103 /// best of the NlnN variants -- best overall for N>10^4.
104 /// (Does not work for R>=2pi)
105 NlnN = 2,
106 /// legacy N ln N using 3pi coverage of cylinder.
107 /// (Does not work for R>=2pi)
108 NlnN3pi = 3,
109 /// legacy N ln N using 4pi coverage of cylinder
110 NlnN4pi = 4,
111 /// Chan's closest pair method (in a variant with 4pi coverage),
112 /// for use exclusively with the Cambridge algorithm.
113 /// (Does not work for R>=2pi)
114 NlnNCam4pi = 14,
115 /// Chan's closest pair method (in a variant with 2pi+2R coverage),
116 /// for use exclusively with the Cambridge algorithm.
117 /// (Does not work for R>=2pi)
118 NlnNCam2pi2R = 13,
119 /// Chan's closest pair method (in a variant with 2pi+minimal extra
120 /// variant), for use exclusively with the Cambridge algorithm.
121 /// (Does not work for R>=2pi)
122 NlnNCam = 12, // 2piMultD
[35cdc46]123 /// the automatic strategy choice that was being made in FJ 3.0
124 /// (restricted to strategies that were present in FJ 3.0)
125 BestFJ30 = 21,
[d7d2da3]126 /// the plugin has been used...
127 plugin_strategy = 999
128};
129
130
131//======================================================================
132/// \enum JetAlgorithm
133/// the various families of jet-clustering algorithm
[35cdc46]134//
135// [Remember to update the "is_spherical()" routine if any further
136// spherical algorithms are added to the list below]
[d7d2da3]137enum JetAlgorithm {
138 /// the longitudinally invariant kt algorithm
139 kt_algorithm=0,
140 /// the longitudinally invariant variant of the cambridge algorithm
141 /// (aka Aachen algoithm).
142 cambridge_algorithm=1,
143 /// like the k_t but with distance measures
144 /// dij = min(1/kti^2,1/ktj^2) Delta R_{ij}^2 / R^2
145 /// diB = 1/kti^2
146 antikt_algorithm=2,
147 /// like the k_t but with distance measures
148 /// dij = min(kti^{2p},ktj^{2p}) Delta R_{ij}^2 / R^2
149 /// diB = 1/kti^{2p}
150 /// where p = extra_param()
151 genkt_algorithm=3,
[35cdc46]152 /// a version of cambridge with a special distance measure for
153 /// particles whose pt is < extra_param(); this is not usually
154 /// intended for end users, but is instead automatically selected
155 /// when requesting a passive Cambridge area.
[d7d2da3]156 cambridge_for_passive_algorithm=11,
157 /// a version of genkt with a special distance measure for particles
158 /// whose pt is < extra_param() [relevant for passive areas when p<=0]
[35cdc46]159 /// ***** NB: THERE IS CURRENTLY NO IMPLEMENTATION FOR THIS ALG *******
[d7d2da3]160 genkt_for_passive_algorithm=13,
161 //.................................................................
162 /// the e+e- kt algorithm
163 ee_kt_algorithm=50,
164 /// the e+e- genkt algorithm (R > 2 and p=1 gives ee_kt)
165 ee_genkt_algorithm=53,
166 //.................................................................
167 /// any plugin algorithm supplied by the user
168 plugin_algorithm = 99,
169 //.................................................................
170 /// the value for the jet algorithm in a JetDefinition for which
171 /// no algorithm has yet been defined
172 undefined_jet_algorithm = 999
173};
174
175/// make standard Les Houches nomenclature JetAlgorithm (algorithm is general
176/// recipe without the parameters) backward-compatible with old JetFinder
177typedef JetAlgorithm JetFinder;
178
179/// provide other possible names for the Cambridge/Aachen algorithm
180const JetAlgorithm aachen_algorithm = cambridge_algorithm;
181const JetAlgorithm cambridge_aachen_algorithm = cambridge_algorithm;
182
183//======================================================================
[273e668]184/// The various recombination schemes
185///
186/// Note that the schemes that recombine with non-linear weighting of
187/// the directions (e.g. pt2, winner-takes-all) are collinear safe
188/// only for algorithms with a suitable ordering of the
189/// recombinations: orderings in which, for particles of comparable
190/// energies, small-angle clusterings take place before large-angle
191/// clusterings. This property is satisfied by all gen-kt algorithms.
192///
[d7d2da3]193enum RecombinationScheme {
194 /// summing the 4-momenta
195 E_scheme=0,
196 /// pt weighted recombination of y,phi (and summing of pt's)
197 /// with preprocessing to make things massless by rescaling E=|\vec p|
198 pt_scheme=1,
199 /// pt^2 weighted recombination of y,phi (and summing of pt's)
200 /// with preprocessing to make things massless by rescaling E=|\vec p|
201 pt2_scheme=2,
202 /// pt weighted recombination of y,phi (and summing of pt's)
203 /// with preprocessing to make things massless by rescaling |\vec p|->=E
204 Et_scheme=3,
205 /// pt^2 weighted recombination of y,phi (and summing of pt's)
206 /// with preprocessing to make things massless by rescaling |\vec p|->=E
207 Et2_scheme=4,
208 /// pt weighted recombination of y,phi (and summing of pt's), with
209 /// no preprocessing
210 BIpt_scheme=5,
211 /// pt^2 weighted recombination of y,phi (and summing of pt's)
212 /// no preprocessing
213 BIpt2_scheme=6,
[273e668]214 /// pt-based Winner-Takes-All (WTA) recombination: the
215 /// result of the recombination has the rapidity, azimuth and mass
[b7b836a]216 /// of the PseudoJet with the larger pt, and a pt equal to the
[273e668]217 /// sum of the two pt's
218 WTA_pt_scheme=7,
219 /// mod-p-based Winner-Takes-All (WTA) recombination: the result of
220 /// the recombination gets the 3-vector direction and mass of the
221 /// PseudoJet with the larger |3-momentum| (modp), and a
222 /// |3-momentum| equal to the scalar sum of the two |3-momenta|.
223 WTA_modp_scheme=8,
224 // Energy-ordering can lead to dangerous situations with particles at
225 // rest. We instead implement the WTA_modp_scheme
226 //
227 // // energy-based Winner-Takes-All (WTA) recombination: the result of
228 // // the recombination gets the 3-vector direction and mass of the
229 // // PseudoJet with the larger energy, and an energy equal to the
230 // // to the sum of the two energies
231 // WTA_E_scheme=8,
[d7d2da3]232 /// for the user's external scheme
233 external_scheme = 99
234};
235
236
237
238// forward declaration, needed in order to specify interface for the
239// plugin.
240class ClusterSequence;
241
242
243
244
245//======================================================================
246/// @ingroup basic_classes
247/// \class JetDefinition
248/// class that is intended to hold a full definition of the jet
249/// clusterer
250class JetDefinition {
251
252public:
253
254 /// forward declaration of a class that allows the user to introduce
255 /// their own plugin
256 class Plugin;
257
258 // forward declaration of a class that will provide the
259 // recombination scheme facilities and/or allow a user to
260 // extend these facilities
261 class Recombiner;
262
263
264 /// constructor with alternative ordering or arguments -- note that
265 /// we have not provided a default jet finder, to avoid ambiguous
266 /// JetDefinition() constructor.
267 JetDefinition(JetAlgorithm jet_algorithm_in,
268 double R_in,
269 RecombinationScheme recomb_scheme_in = E_scheme,
270 Strategy strategy_in = Best) {
[1d208a2]271 *this = JetDefinition(jet_algorithm_in, R_in, recomb_scheme_in, strategy_in, 1);
[d7d2da3]272 }
273
274 /// constructor for algorithms that have no free parameters
275 /// (e.g. ee_kt_algorithm)
276 JetDefinition(JetAlgorithm jet_algorithm_in,
277 RecombinationScheme recomb_scheme_in = E_scheme,
278 Strategy strategy_in = Best) {
279 double dummyR = 0.0;
[1d208a2]280 *this = JetDefinition(jet_algorithm_in, dummyR, recomb_scheme_in, strategy_in, 0);
[d7d2da3]281 }
282
283 /// constructor for algorithms that require R + one extra parameter to be set
284 /// (the gen-kt series for example)
285 JetDefinition(JetAlgorithm jet_algorithm_in,
286 double R_in,
287 double xtra_param_in,
288 RecombinationScheme recomb_scheme_in = E_scheme,
289 Strategy strategy_in = Best) {
[1d208a2]290 *this = JetDefinition(jet_algorithm_in, R_in, recomb_scheme_in, strategy_in, 2);
[d7d2da3]291 set_extra_param(xtra_param_in);
292 }
293
294
295 /// constructor in a form that allows the user to provide a pointer
296 /// to an external recombiner class (which must remain valid for the
297 /// life of the JetDefinition object).
298 JetDefinition(JetAlgorithm jet_algorithm_in,
299 double R_in,
300 const Recombiner * recombiner_in,
301 Strategy strategy_in = Best) {
302 *this = JetDefinition(jet_algorithm_in, R_in, external_scheme, strategy_in);
303 _recombiner = recombiner_in;
304 }
305
306
307 /// constructor for case with 0 parameters (ee_kt_algorithm) and
308 /// and external recombiner
309 JetDefinition(JetAlgorithm jet_algorithm_in,
310 const Recombiner * recombiner_in,
311 Strategy strategy_in = Best) {
312 *this = JetDefinition(jet_algorithm_in, external_scheme, strategy_in);
313 _recombiner = recombiner_in;
314 }
315
316 /// constructor allowing the extra parameter to be set and a pointer to
317 /// a recombiner
318 JetDefinition(JetAlgorithm jet_algorithm_in,
319 double R_in,
320 double xtra_param_in,
321 const Recombiner * recombiner_in,
322 Strategy strategy_in = Best) {
[35cdc46]323 *this = JetDefinition(jet_algorithm_in, R_in, xtra_param_in, external_scheme, strategy_in);
[d7d2da3]324 _recombiner = recombiner_in;
325 }
326
327 /// a default constructor which creates a jet definition that is in
328 /// a well-defined internal state, but not actually usable for jet
329 /// clustering.
330 JetDefinition() {
331 *this = JetDefinition(undefined_jet_algorithm, 1.0);
332 }
333
334
335 // /// a default constructor
336 // JetDefinition() {
337 // *this = JetDefinition(kt_algorithm, 1.0);
338 // }
339
340 /// constructor based on a pointer to a user's plugin; the object
341 /// pointed to must remain valid for the whole duration of existence
342 /// of the JetDefinition and any related ClusterSequences
343 JetDefinition(const Plugin * plugin_in) {
344 _plugin = plugin_in;
345 _strategy = plugin_strategy;
346 _Rparam = _plugin->R();
[1d208a2]347 _extra_param = 0.0; // a dummy value to keep static code checkers happy
[d7d2da3]348 _jet_algorithm = plugin_algorithm;
349 set_recombination_scheme(E_scheme);
350 }
351
[1d208a2]352 /// constructor to fully specify a jet-definition (together with
353 /// information about how algorithically to run it).
354 JetDefinition(JetAlgorithm jet_algorithm_in,
355 double R_in,
356 RecombinationScheme recomb_scheme_in,
357 Strategy strategy_in,
358 int nparameters_in);
[d7d2da3]359
360 /// constructor to fully specify a jet-definition (together with
361 /// information about how algorithically to run it).
362 ///
363 /// the ordering of arguments here is old and deprecated (except
364 /// as the common constructor for internal use)
[1d208a2]365 FASTJET_DEPRECATED_MSG("This argument ordering is deprecated. Use JetDefinition(alg, R, strategy, scheme[, n_parameters]) instead")
[d7d2da3]366 JetDefinition(JetAlgorithm jet_algorithm_in,
367 double R_in,
368 Strategy strategy_in,
369 RecombinationScheme recomb_scheme_in = E_scheme,
[1d208a2]370 int nparameters_in = 1){
371 (*this) = JetDefinition(jet_algorithm_in,R_in,recomb_scheme_in,strategy_in,nparameters_in);
372 }
373
[35cdc46]374
375 /// cluster the supplied particles and returns a vector of resulting
376 /// jets, sorted by pt (or energy in the case of spherical,
377 /// i.e. e+e-, algorithms). This routine currently only makes
378 /// sense for "inclusive" type algorithms.
379 template <class L>
380 std::vector<PseudoJet> operator()(const std::vector<L> & particles) const;
[d7d2da3]381
382 /// R values larger than max_allowable_R are not allowed.
383 ///
384 /// We use a value of 1000, substantially smaller than
385 /// numeric_limits<double>::max(), to leave room for the convention
386 /// within PseudoJet of setting unphysical (infinite) rapidities to
387 /// +-(MaxRap + abs(pz())), where MaxRap is 10^5.
388 static const double max_allowable_R; //= 1000.0;
389
390 /// set the recombination scheme to the one provided
391 void set_recombination_scheme(RecombinationScheme);
392
393 /// set the recombiner class to the one provided
[35cdc46]394 ///
395 /// Note that in order to associate to a jet definition a recombiner
396 /// from another jet definition, it is strongly recommended to use
397 /// the set_recombiner(const JetDefinition &) method below. The
398 /// latter correctly handles the situations where the jet definition
399 /// owns the recombiner (i.e. where delete_recombiner_when_unused
400 /// has been called). In such cases, using set_recombiner(const
401 /// Recombiner *) may lead to memory corruption.
[d7d2da3]402 void set_recombiner(const Recombiner * recomb) {
[1d208a2]403 if (_shared_recombiner) _shared_recombiner.reset(recomb);
[d7d2da3]404 _recombiner = recomb;
405 _default_recombiner = DefaultRecombiner(external_scheme);
406 }
407
[35cdc46]408 /// set the recombiner to be the same as the one of 'other_jet_def'
409 ///
410 /// Note that this is the recommended method to associate to a jet
411 /// definition the recombiner from another jet definition. Compared
412 /// to the set_recombiner(const Recombiner *) above, it correctly
413 /// handles the case where the jet definition owns the recombiner
414 /// (i.e. where delete_recombiner_when_unused has been called)
415 void set_recombiner(const JetDefinition &other_jet_def);
416
[d7d2da3]417 /// calling this tells the JetDefinition to handle the deletion of
[35cdc46]418 /// the recombiner when it is no longer used. (Should not be called
419 /// if the recombiner was initialised from a JetDef whose recombiner
420 /// was already scheduled to delete itself - memory handling will
421 /// already be automatic across both JetDef's in that case).
[d7d2da3]422 void delete_recombiner_when_unused();
423
424 /// return a pointer to the plugin
425 const Plugin * plugin() const {return _plugin;};
426
[35cdc46]427 /// calling this causes the JetDefinition to handle the deletion of the
[d7d2da3]428 /// plugin when it is no longer used
429 void delete_plugin_when_unused();
430
431 /// return information about the definition...
432 JetAlgorithm jet_algorithm () const {return _jet_algorithm ;}
433 /// same as above for backward compatibility
434 JetAlgorithm jet_finder () const {return _jet_algorithm ;}
435 double R () const {return _Rparam ;}
436 // a general purpose extra parameter, whose meaning depends on
437 // the algorithm, and may often be unused.
438 double extra_param () const {return _extra_param ;}
439 Strategy strategy () const {return _strategy ;}
440 RecombinationScheme recombination_scheme() const {
441 return _default_recombiner.scheme();}
442
443 /// (re)set the jet finder
444 void set_jet_algorithm(JetAlgorithm njf) {_jet_algorithm = njf;}
445 /// same as above for backward compatibility
446 void set_jet_finder(JetAlgorithm njf) {_jet_algorithm = njf;}
447 /// (re)set the general purpose extra parameter
448 void set_extra_param(double xtra_param) {_extra_param = xtra_param;}
449
[35cdc46]450 /// returns a pointer to the currently defined recombiner.
[d7d2da3]451 ///
452 /// Warning: the pointer may be to an internal recombiner (for
453 /// default recombination schemes), in which case if the
454 /// JetDefinition becomes invalid (e.g. is deleted), the pointer
455 /// will then point to an object that no longer exists.
456 ///
457 /// Note also that if you copy a JetDefinition with a default
458 /// recombination scheme, then the two copies will have distinct
459 /// recombiners, and return different recombiner() pointers.
460 const Recombiner * recombiner() const {
461 return _recombiner == 0 ? & _default_recombiner : _recombiner;}
462
463 /// returns true if the current jet definitions shares the same
[35cdc46]464 /// recombiner as the one passed as an argument
[d7d2da3]465 bool has_same_recombiner(const JetDefinition &other_jd) const;
466
[35cdc46]467 /// returns true if the jet definition involves an algorithm
468 /// intended for use on a spherical geometry (e.g. e+e- algorithms,
469 /// as opposed to most pp algorithms, which use a cylindrical,
470 /// rapidity-phi geometry).
471 bool is_spherical() const;
472
[d7d2da3]473 /// return a textual description of the current jet definition
474 std::string description() const;
475
[35cdc46]476 /// returns a description not including the recombiner information
477 std::string description_no_recombiner() const;
478
479 /// a short textual description of the algorithm jet_alg
480 static std::string algorithm_description(const JetAlgorithm jet_alg);
481
482 /// the number of parameters associated to a given jet algorithm
483 static unsigned int n_parameters_for_algorithm(const JetAlgorithm jet_alg);
[d7d2da3]484
485public:
486 //======================================================================
487 /// @ingroup advanced_usage
488 /// \class Recombiner
489 /// An abstract base class that will provide the recombination scheme
490 /// facilities and/or allow a user to extend these facilities
491 class Recombiner {
492 public:
493 /// return a textual description of the recombination scheme
494 /// implemented here
495 virtual std::string description() const = 0;
496
497 /// recombine pa and pb and put result into pab
498 virtual void recombine(const PseudoJet & pa, const PseudoJet & pb,
499 PseudoJet & pab) const = 0;
500
501 /// routine called to preprocess each input jet (to make all input
502 /// jets compatible with the scheme requirements (e.g. massless).
503 virtual void preprocess(PseudoJet & ) const {};
504
505 /// a destructor to be replaced if necessary in derived classes...
506 virtual ~Recombiner() {};
507
508 /// pa += pb in the given recombination scheme. Not virtual -- the
509 /// user should have no reason to want to redefine this!
510 inline void plus_equal(PseudoJet & pa, const PseudoJet & pb) const {
511 // put result in a temporary location in case the recombiner
512 // does something funny (ours doesn't, but who knows about the
513 // user's)
514 PseudoJet pres;
515 recombine(pa,pb,pres);
516 pa = pres;
517 }
518
519 };
520
521
522 //======================================================================
523 /// @ingroup advanced_usage
524 /// \class DefaultRecombiner
525 /// A class that will provide the recombination scheme facilities and/or
526 /// allow a user to extend these facilities
527 ///
528 /// This class is derived from the (abstract) class Recombiner. It
529 /// simply "sums" PseudoJets using a specified recombination scheme
530 /// (E-scheme by default)
531 class DefaultRecombiner : public Recombiner {
532 public:
533 DefaultRecombiner(RecombinationScheme recomb_scheme = E_scheme) :
534 _recomb_scheme(recomb_scheme) {}
535
[1d208a2]536 virtual std::string description() const FASTJET_OVERRIDE;
[d7d2da3]537
538 /// recombine pa and pb and put result into pab
539 virtual void recombine(const PseudoJet & pa, const PseudoJet & pb,
[1d208a2]540 PseudoJet & pab) const FASTJET_OVERRIDE;
[d7d2da3]541
[1d208a2]542 virtual void preprocess(PseudoJet & p) const FASTJET_OVERRIDE;
[d7d2da3]543
544 /// return the index of the recombination scheme
545 RecombinationScheme scheme() const {return _recomb_scheme;}
546
547 private:
548 RecombinationScheme _recomb_scheme;
549 };
550
551
552 //======================================================================
553 /// @ingroup advanced_usage
554 /// \class Plugin
555 /// a class that allows a user to introduce their own "plugin" jet
556 /// finder
557 ///
558 /// Note that all the plugins provided with FastJet are derived from
559 /// this class
560 class Plugin{
561 public:
562 /// return a textual description of the jet-definition implemented
563 /// in this plugin
564 virtual std::string description() const = 0;
565
566 /// given a ClusterSequence that has been filled up with initial
567 /// particles, the following function should fill up the rest of the
568 /// ClusterSequence, using the following member functions of
569 /// ClusterSequence:
570 /// - plugin_do_ij_recombination(...)
571 /// - plugin_do_iB_recombination(...)
572 virtual void run_clustering(ClusterSequence &) const = 0;
573
574 virtual double R() const = 0;
575
576 /// return true if there is specific support for the measurement
577 /// of passive areas, in the sense that areas determined from all
578 /// particles below the ghost separation scale will be a passive
579 /// area. [If you don't understand this, ignore it!]
580 virtual bool supports_ghosted_passive_areas() const {return false;}
581
582 /// set the ghost separation scale for passive area determinations
583 /// in future runs (strictly speaking that makes the routine
584 /// a non const, so related internal info must be stored as a mutable)
585 virtual void set_ghost_separation_scale(double scale) const;
586 virtual double ghost_separation_scale() const {return 0.0;}
587
588 /// if this returns false then a warning will be given
589 /// whenever the user requests "exclusive" jets from the
590 /// cluster sequence
591 virtual bool exclusive_sequence_meaningful() const {return false;}
592
[35cdc46]593 /// returns true if the plugin implements an algorithm intended
594 /// for use on a spherical geometry (e.g. e+e- algorithms, as
595 /// opposed to most pp algorithms, which use a cylindrical,
596 /// rapidity-phi geometry).
597 virtual bool is_spherical() const {return false;}
598
[d7d2da3]599 /// a destructor to be replaced if necessary in derived classes...
600 virtual ~Plugin() {};
601 };
602
603private:
604
605
606 JetAlgorithm _jet_algorithm;
607 double _Rparam;
608 double _extra_param ; ///< parameter whose meaning varies according to context
609 Strategy _strategy ;
610
611 const Plugin * _plugin;
612 SharedPtr<const Plugin> _plugin_shared;
613
614 // when we use our own recombiner it's useful to point to it here
615 // so that we don't have to worry about deleting it etc...
616 DefaultRecombiner _default_recombiner;
617 const Recombiner * _recombiner;
[35cdc46]618 SharedPtr<const Recombiner> _shared_recombiner;
[d7d2da3]619
620};
621
622
623//-------------------------------------------------------------------------------
624// helper functions to build a jet made of pieces
625//
626// These functions include an options recombiner used to compute the
627// total composite jet momentum
628// -------------------------------------------------------------------------------
629
630/// build a "CompositeJet" from the vector of its pieces
631///
632/// In this case, E-scheme recombination is assumed to compute the
633/// total momentum
634PseudoJet join(const std::vector<PseudoJet> & pieces, const JetDefinition::Recombiner & recombiner);
635
636/// build a MergedJet from a single PseudoJet
637PseudoJet join(const PseudoJet & j1,
638 const JetDefinition::Recombiner & recombiner);
639
640/// build a MergedJet from 2 PseudoJet
641PseudoJet join(const PseudoJet & j1, const PseudoJet & j2,
642 const JetDefinition::Recombiner & recombiner);
643
644/// build a MergedJet from 3 PseudoJet
645PseudoJet join(const PseudoJet & j1, const PseudoJet & j2, const PseudoJet & j3,
646 const JetDefinition::Recombiner & recombiner);
647
648/// build a MergedJet from 4 PseudoJet
649PseudoJet join(const PseudoJet & j1, const PseudoJet & j2, const PseudoJet & j3, const PseudoJet & j4,
650 const JetDefinition::Recombiner & recombiner);
651
652
[35cdc46]653FASTJET_END_NAMESPACE
[d7d2da3]654
[35cdc46]655// include ClusterSequence which includes the implementation of the
656// templated JetDefinition::operator()(...) member
657#include "fastjet/ClusterSequence.hh"
[d7d2da3]658
659
660#endif // __FASTJET_JETDEFINITION_HH__
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