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[d7d2da3]1//STARTHEADER
[d69dfe4]2// $Id: ClusterSequence.hh 3114 2013-05-04 08:46:00Z salam $
[d7d2da3]3//
4// Copyright (c) 2005-2011, Matteo Cacciari, Gavin P. Salam and Gregory Soyez
5//
6//----------------------------------------------------------------------
7// This file is part of FastJet.
8//
9// FastJet is free software; you can redistribute it and/or modify
10// it under the terms of the GNU General Public License as published by
11// the Free Software Foundation; either version 2 of the License, or
12// (at your option) any later version.
13//
14// The algorithms that underlie FastJet have required considerable
15// development and are described in hep-ph/0512210. If you use
16// FastJet as part of work towards a scientific publication, please
17// include a citation to the FastJet paper.
18//
19// FastJet is distributed in the hope that it will be useful,
20// but WITHOUT ANY WARRANTY; without even the implied warranty of
21// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
22// GNU General Public License for more details.
23//
24// You should have received a copy of the GNU General Public License
25// along with FastJet. If not, see <http://www.gnu.org/licenses/>.
26//----------------------------------------------------------------------
27//ENDHEADER
28
29
30#ifndef __FASTJET_CLUSTERSEQUENCE_HH__
31#define __FASTJET_CLUSTERSEQUENCE_HH__
32
33#include<vector>
34#include<map>
35#include "fastjet/PseudoJet.hh"
36#include<memory>
37#include<cassert>
38#include<iostream>
39#include<string>
40#include<set>
41#include<cmath> // needed to get double std::abs(double)
42#include "fastjet/Error.hh"
43#include "fastjet/JetDefinition.hh"
44#include "fastjet/SharedPtr.hh"
45#include "fastjet/LimitedWarning.hh"
46#include "fastjet/FunctionOfPseudoJet.hh"
47#include "fastjet/ClusterSequenceStructure.hh"
48
49FASTJET_BEGIN_NAMESPACE // defined in fastjet/internal/base.hh
50
51
[d69dfe4]52// forward declarations
[d7d2da3]53class ClusterSequenceStructure;
[d69dfe4]54class DynamicNearestNeighbours;
[d7d2da3]55
56/// @ingroup basic_classes
57/// \class ClusterSequence
58/// deals with clustering
59class ClusterSequence {
60
61
62 public:
63
64 /// default constructor
65 ClusterSequence () : _deletes_self_when_unused(false) {}
66
67// /// create a clustersequence starting from the supplied set
68// /// of pseudojets and clustering them with the long-invariant
69// /// kt algorithm (E-scheme recombination) with the supplied
70// /// value for R.
71// ///
72// /// If strategy=DumbN3 a very stupid N^3 algorithm is used for the
73// /// clustering; otherwise strategy = NlnN* uses cylinders algorithms
74// /// with some number of pi coverage. If writeout_combinations=true a
75// /// summary of the recombination sequence is written out
76// template<class L> ClusterSequence (const std::vector<L> & pseudojets,
77// const double & R = 1.0,
78// const Strategy & strategy = Best,
79// const bool & writeout_combinations = false);
80
81
82 /// create a clustersequence starting from the supplied set
83 /// of pseudojets and clustering them with jet definition specified
84 /// by jet_def (which also specifies the clustering strategy)
85 template<class L> ClusterSequence (
86 const std::vector<L> & pseudojets,
87 const JetDefinition & jet_def,
88 const bool & writeout_combinations = false);
89
90 /// copy constructor for a ClusterSequence
91 ClusterSequence (const ClusterSequence & cs) : _deletes_self_when_unused(false) {
92 transfer_from_sequence(cs);
93 }
94
95 // virtual ClusterSequence destructor, in case any derived class
96 // thinks of needing a destructor at some point
97 virtual ~ClusterSequence (); //{}
98
99 // NB: in the routines that follow, for extracting lists of jets, a
100 // list structure might be more efficient, if sometimes a little
101 // more awkward to use (at least for old fortran hands).
102
103 /// return a vector of all jets (in the sense of the inclusive
104 /// algorithm) with pt >= ptmin. Time taken should be of the order
105 /// of the number of jets returned.
106 std::vector<PseudoJet> inclusive_jets (const double & ptmin = 0.0) const;
107
108 /// return the number of jets (in the sense of the exclusive
109 /// algorithm) that would be obtained when running the algorithm
110 /// with the given dcut.
111 int n_exclusive_jets (const double & dcut) const;
112
113 /// return a vector of all jets (in the sense of the exclusive
114 /// algorithm) that would be obtained when running the algorithm
115 /// with the given dcut.
116 std::vector<PseudoJet> exclusive_jets (const double & dcut) const;
117
118 /// return a vector of all jets when the event is clustered (in the
119 /// exclusive sense) to exactly njets.
120 ///
121 /// If there are fewer than njets particles in the ClusterSequence
122 /// an error is thrown
123 std::vector<PseudoJet> exclusive_jets (const int & njets) const;
124
125 /// return a vector of all jets when the event is clustered (in the
126 /// exclusive sense) to exactly njets.
127 ///
128 /// If there are fewer than njets particles in the ClusterSequence
129 /// the function just returns however many particles there were.
130 std::vector<PseudoJet> exclusive_jets_up_to (const int & njets) const;
131
132 /// return the dmin corresponding to the recombination that went
133 /// from n+1 to n jets (sometimes known as d_{n n+1}). If the number
134 /// of particles in the event is <= njets, the function returns 0.
135 double exclusive_dmerge (const int & njets) const;
136
137 /// return the maximum of the dmin encountered during all recombinations
138 /// up to the one that led to an n-jet final state; identical to
139 /// exclusive_dmerge, except in cases where the dmin do not increase
140 /// monotonically.
141 double exclusive_dmerge_max (const int & njets) const;
142
143 /// return the ymin corresponding to the recombination that went from
144 /// n+1 to n jets (sometimes known as y_{n n+1}).
145 double exclusive_ymerge (int njets) const {return exclusive_dmerge(njets) / Q2();}
146
147 /// same as exclusive_dmerge_max, but normalised to squared total energy
148 double exclusive_ymerge_max (int njets) const {return exclusive_dmerge_max(njets)/Q2();}
149
150 /// the number of exclusive jets at the given ycut
151 int n_exclusive_jets_ycut (double ycut) const {return n_exclusive_jets(ycut*Q2());}
152
153 /// the exclusive jets obtained at the given ycut
154 std::vector<PseudoJet> exclusive_jets_ycut (double ycut) const {
155 int njets = n_exclusive_jets_ycut(ycut);
156 return exclusive_jets(njets);
157 }
158
159
160 //int n_exclusive_jets (const PseudoJet & jet, const double & dcut) const;
161
162 /// return a vector of all subjets of the current jet (in the sense
163 /// of the exclusive algorithm) that would be obtained when running
164 /// the algorithm with the given dcut.
165 ///
166 /// Time taken is O(m ln m), where m is the number of subjets that
167 /// are found. If m gets to be of order of the total number of
168 /// constituents in the jet, this could be substantially slower than
169 /// just getting that list of constituents.
170 std::vector<PseudoJet> exclusive_subjets (const PseudoJet & jet,
171 const double & dcut) const;
172
173 /// return the size of exclusive_subjets(...); still n ln n with same
174 /// coefficient, but marginally more efficient than manually taking
175 /// exclusive_subjets.size()
176 int n_exclusive_subjets(const PseudoJet & jet,
177 const double & dcut) const;
178
179 /// return the list of subjets obtained by unclustering the supplied
180 /// jet down to nsub subjets. Throws an error if there are fewer than
181 /// nsub particles in the jet.
182 ///
183 /// This requires nsub ln nsub time
184 std::vector<PseudoJet> exclusive_subjets (const PseudoJet & jet,
185 int nsub) const;
186
187 /// return the list of subjets obtained by unclustering the supplied
188 /// jet down to nsub subjets (or all constituents if there are fewer
189 /// than nsub).
190 ///
191 /// This requires nsub ln nsub time
192 std::vector<PseudoJet> exclusive_subjets_up_to (const PseudoJet & jet,
193 int nsub) const;
194
195 /// return the dij that was present in the merging nsub+1 -> nsub
196 /// subjets inside this jet.
197 ///
198 /// Returns 0 if there were nsub or fewer constituents in the jet.
199 double exclusive_subdmerge(const PseudoJet & jet, int nsub) const;
200
201 /// return the maximum dij that occurred in the whole event at the
202 /// stage that the nsub+1 -> nsub merge of subjets occurred inside
203 /// this jet.
204 ///
205 /// Returns 0 if there were nsub or fewer constituents in the jet.
206 double exclusive_subdmerge_max(const PseudoJet & jet, int nsub) const;
207
208 //std::vector<PseudoJet> exclusive_jets (const PseudoJet & jet,
209 // const int & njets) const;
210 //double exclusive_dmerge (const PseudoJet & jet, const int & njets) const;
211
212 /// returns the sum of all energies in the event (relevant mainly for e+e-)
213 double Q() const {return _Qtot;}
214 /// return Q()^2
215 double Q2() const {return _Qtot*_Qtot;}
216
217 /// returns true iff the object is included in the jet.
218 ///
219 /// NB: this is only sensible if the object is already registered
220 /// within the cluster sequence, so you cannot use it with an input
221 /// particle to the CS (since the particle won't have the history
222 /// index set properly).
223 ///
224 /// For nice clustering structures it should run in O(ln(N)) time
225 /// but in worst cases (certain cone plugins) it can take O(n) time,
226 /// where n is the number of particles in the jet.
227 bool object_in_jet(const PseudoJet & object, const PseudoJet & jet) const;
228
229 /// if the jet has parents in the clustering, it returns true
230 /// and sets parent1 and parent2 equal to them.
231 ///
232 /// if it has no parents it returns false and sets parent1 and
233 /// parent2 to zero
234 bool has_parents(const PseudoJet & jet, PseudoJet & parent1,
235 PseudoJet & parent2) const;
236
237 /// if the jet has a child then return true and give the child jet
238 /// otherwise return false and set the child to zero
239 bool has_child(const PseudoJet & jet, PseudoJet & child) const;
240
241 /// Version of has_child that sets a pointer to the child if the child
242 /// exists;
243 bool has_child(const PseudoJet & jet, const PseudoJet * & childp) const;
244
245 /// if this jet has a child (and so a partner) return true
246 /// and give the partner, otherwise return false and set the
247 /// partner to zero
248 bool has_partner(const PseudoJet & jet, PseudoJet & partner) const;
249
250
251 /// return a vector of the particles that make up jet
252 std::vector<PseudoJet> constituents (const PseudoJet & jet) const;
253
254
255 /// output the supplied vector of jets in a format that can be read
256 /// by an appropriate root script; the format is:
257 /// jet-n jet-px jet-py jet-pz jet-E
258 /// particle-n particle-rap particle-phi particle-pt
259 /// particle-n particle-rap particle-phi particle-pt
260 /// ...
261 /// #END
262 /// ... [i.e. above repeated]
263 void print_jets_for_root(const std::vector<PseudoJet> & jets,
264 std::ostream & ostr = std::cout) const;
265
266 /// print jets for root to the file labelled filename, with an
267 /// optional comment at the beginning
268 void print_jets_for_root(const std::vector<PseudoJet> & jets,
269 const std::string & filename,
270 const std::string & comment = "") const;
271
272// Not yet. Perhaps in a future release.
273// /// print out all inclusive jets with pt > ptmin
274// virtual void print_jets (const double & ptmin=0.0) const;
275
276 /// add on to subjet_vector the constituents of jet (for internal use mainly)
277 void add_constituents (const PseudoJet & jet,
278 std::vector<PseudoJet> & subjet_vector) const;
279
280 /// return the enum value of the strategy used to cluster the event
281 inline Strategy strategy_used () const {return _strategy;}
282
283 /// return the name of the strategy used to cluster the event
284 std::string strategy_string () const {return strategy_string(_strategy);}
285
286 /// return the name of the strategy associated with the enum strategy_in
287 std::string strategy_string (Strategy strategy_in) const;
288
289
290 /// return a reference to the jet definition
291 const JetDefinition & jet_def() const {return _jet_def;}
292
293 /// by calling this routine you tell the ClusterSequence to delete
294 /// itself when all the Pseudojets associated with it have gone out
295 /// of scope.
296 ///
297 /// At the time you call this, there must be at least one jet or
298 /// other object outside the CS that is associated with the CS
299 /// (e.g. the result of inclusive_jets()).
300 ///
301 /// NB: after having made this call, the user is still allowed to
302 /// delete the CS or let it go out of scope. Jets associated with it
303 /// will then simply not be able to access their substructure after
304 /// that point.
305 void delete_self_when_unused();
306
307 /// return true if the object has been told to delete itself
308 /// when unused
309 bool will_delete_self_when_unused() const {return _deletes_self_when_unused;}
310
311 /// tell the ClusterSequence it's about to be self deleted (internal use only)
312 void signal_imminent_self_deletion() const;
313
314 /// returns the scale associated with a jet as required for this
315 /// clustering algorithm (kt^2 for the kt-algorithm, 1 for the
316 /// Cambridge algorithm). [May become virtual at some point]
317 double jet_scale_for_algorithm(const PseudoJet & jet) const;
318
319 ///
320
321 //----- next follow functions designed specifically for plugins, which
322 // may only be called when plugin_activated() returns true
323
324 /// record the fact that there has been a recombination between
325 /// jets()[jet_i] and jets()[jet_k], with the specified dij, and
326 /// return the index (newjet_k) allocated to the new jet, whose
327 /// momentum is assumed to be the 4-vector sum of that of jet_i and
328 /// jet_j
329 void plugin_record_ij_recombination(int jet_i, int jet_j, double dij,
330 int & newjet_k) {
331 assert(plugin_activated());
332 _do_ij_recombination_step(jet_i, jet_j, dij, newjet_k);
333 }
334
335 /// as for the simpler variant of plugin_record_ij_recombination,
336 /// except that the new jet is attributed the momentum and
337 /// user_index of newjet
338 void plugin_record_ij_recombination(int jet_i, int jet_j, double dij,
339 const PseudoJet & newjet,
340 int & newjet_k);
341
342 /// record the fact that there has been a recombination between
343 /// jets()[jet_i] and the beam, with the specified diB; when looking
344 /// for inclusive jets, any iB recombination will returned to the user
345 /// as a jet.
346 void plugin_record_iB_recombination(int jet_i, double diB) {
347 assert(plugin_activated());
348 _do_iB_recombination_step(jet_i, diB);
349 }
350
351 /// @ingroup extra_info
352 /// \class Extras
353 /// base class to store extra information that plugins may provide
354 ///
355 /// a class intended to serve as a base in case a plugin needs to
356 /// associate extra information with a ClusterSequence (see
357 /// SISConePlugin.* for an example).
358 class Extras {
359 public:
360 virtual ~Extras() {}
361 virtual std::string description() const {return "This is a dummy extras class that contains no extra information! Derive from it if you want to use it to provide extra information from a plugin jet finder";}
362 };
363
364 /// the plugin can associate some extra information with the
365 /// ClusterSequence object by calling this function
366 inline void plugin_associate_extras(std::auto_ptr<Extras> extras_in) {
367 //_extras = extras_in;
368 _extras.reset(extras_in.release());
369 }
370
371 /// returns true when the plugin is allowed to run the show.
372 inline bool plugin_activated() const {return _plugin_activated;}
373
374 /// returns a pointer to the extras object (may be null)
375 const Extras * extras() const {return _extras.get();}
376
377 /// allows a plugin to run a templated clustering (nearest-neighbour heuristic)
378 ///
379 /// This has N^2 behaviour on "good" distance, but a worst case behaviour
380 /// of N^3 (and many algs trigger the worst case behaviour)
381 ///
382 ///
383 /// For more details on how this works, see GenBriefJet below
384 template<class GBJ> void plugin_simple_N2_cluster () {
385 assert(plugin_activated());
386 _simple_N2_cluster<GBJ>();
387 }
388
389
390public:
391//DEP /// set the default (static) jet finder across all current and future
392//DEP /// ClusterSequence objects -- deprecated and obsolescent (i.e. may be
393//DEP /// suppressed in a future release).
394//DEP static void set_jet_algorithm (JetAlgorithm jet_algorithm) {_default_jet_algorithm = jet_algorithm;}
395//DEP /// same as above for backward compatibility
396//DEP static void set_jet_finder (JetAlgorithm jet_algorithm) {_default_jet_algorithm = jet_algorithm;}
397
398
399 /// \ingroup extra_info
400 /// \struct history_element
401 /// a single element in the clustering history
402 ///
403 /// (see vector _history below).
404 struct history_element{
405 int parent1; /// index in _history where first parent of this jet
406 /// was created (InexistentParent if this jet is an
407 /// original particle)
408
409 int parent2; /// index in _history where second parent of this jet
410 /// was created (InexistentParent if this jet is an
411 /// original particle); BeamJet if this history entry
412 /// just labels the fact that the jet has recombined
413 /// with the beam)
414
415 int child; /// index in _history where the current jet is
416 /// recombined with another jet to form its child. It
417 /// is Invalid if this jet does not further
418 /// recombine.
419
420 int jetp_index; /// index in the _jets vector where we will find the
421 /// PseudoJet object corresponding to this jet
422 /// (i.e. the jet created at this entry of the
423 /// history). NB: if this element of the history
424 /// corresponds to a beam recombination, then
425 /// jetp_index=Invalid.
426
427 double dij; /// the distance corresponding to the recombination
428 /// at this stage of the clustering.
429
430 double max_dij_so_far; /// the largest recombination distance seen
431 /// so far in the clustering history.
432 };
433
434 enum JetType {Invalid=-3, InexistentParent = -2, BeamJet = -1};
435
436 /// allow the user to access the internally stored _jets() array,
437 /// which contains both the initial particles and the various
438 /// intermediate and final stages of recombination.
439 ///
440 /// The first n_particles() entries are the original particles,
441 /// in the order in which they were supplied to the ClusterSequence
442 /// constructor. It can be useful to access them for example when
443 /// examining whether a given input object is part of a specific
444 /// jet, via the objects_in_jet(...) member function (which only takes
445 /// PseudoJets that are registered in the ClusterSequence).
446 ///
447 /// One of the other (internal uses) is related to the fact
448 /// because we don't seem to be able to access protected elements of
449 /// the class for an object that is not "this" (at least in case where
450 /// "this" is of a slightly different kind from the object, both
451 /// derived from ClusterSequence).
452 const std::vector<PseudoJet> & jets() const;
453
454 /// allow the user to access the raw internal history.
455 ///
456 /// This is present (as for jets()) in part so that protected
457 /// derived classes can access this information about other
458 /// ClusterSequences.
459 ///
460 /// A user who wishes to follow the details of the ClusterSequence
461 /// can also make use of this information (and should consult the
462 /// history_element documentation for more information), but should
463 /// be aware that these internal structures may evolve in future
464 /// FastJet versions.
465 const std::vector<history_element> & history() const;
466
467 /// returns the number of particles that were provided to the
468 /// clustering algorithm (helps the user find their way around the
469 /// history and jets objects if they weren't paying attention
470 /// beforehand).
471 unsigned int n_particles() const;
472
473 /// returns a vector of size n_particles() which indicates, for
474 /// each of the initial particles (in the order in which they were
475 /// supplied), which of the supplied jets it belongs to; if it does
476 /// not belong to any of the supplied jets, the index is set to -1;
477 std::vector<int> particle_jet_indices(const std::vector<PseudoJet> &) const;
478
479 /// routine that returns an order in which to read the history
480 /// such that clusterings that lead to identical jet compositions
481 /// but different histories (because of degeneracies in the
482 /// clustering order) will have matching constituents for each
483 /// matching entry in the unique_history_order.
484 ///
485 /// The order has the property that an entry's parents will always
486 /// appear prior to that entry itself.
487 ///
488 /// Roughly speaking the order is such that we first provide all
489 /// steps that lead to the final jet containing particle 1; then we
490 /// have the steps that lead to reconstruction of the jet containing
491 /// the next-lowest-numbered unclustered particle, etc...
492 /// [see GPS CCN28-12 for more info -- of course a full explanation
493 /// here would be better...]
494 std::vector<int> unique_history_order() const;
495
496 /// return the set of particles that have not been clustered. For
497 /// kt and cam/aachen algorithms this should always be null, but for
498 /// cone type algorithms it can be non-null;
499 std::vector<PseudoJet> unclustered_particles() const;
500
501 /// Return the list of pseudojets in the ClusterSequence that do not
502 /// have children (and are not among the inclusive jets). They may
503 /// result from a clustering step or may be one of the pseudojets
504 /// returned by unclustered_particles().
505 std::vector<PseudoJet> childless_pseudojets() const;
506
507 /// returns true if the object (jet or particle) is contained by (ie
508 /// belongs to) this cluster sequence.
509 ///
510 /// Tests performed: if thejet's interface is this cluster sequence
511 /// and its cluster history index is in a consistent range.
512 bool contains(const PseudoJet & object) const;
513
514 /// transfer the sequence contained in other_seq into our own;
515 /// any plugin "extras" contained in the from_seq will be lost
516 /// from there.
517 ///
518 /// It also sets the ClusterSequence pointers of the PseudoJets in
519 /// the history to point to this ClusterSequence
520 ///
521 /// When specified, the second argument is an action that will be
522 /// applied on every jets in the resulting ClusterSequence
523 void transfer_from_sequence(const ClusterSequence & from_seq,
524 const FunctionOfPseudoJet<PseudoJet> * action_on_jets = 0);
525
526 /// retrieve a shared pointer to the wrapper to this ClusterSequence
527 ///
528 /// this may turn useful if you want to track when this
529 /// ClusterSequence goes out of scope
530 const SharedPtr<PseudoJetStructureBase> & structure_shared_ptr() const{
531 return _structure_shared_ptr;
532 }
533
534 /// the structure type associated with a jet belonging to a ClusterSequence
535 typedef ClusterSequenceStructure StructureType;
536
537 /// This is the function that is automatically called during
538 /// clustering to print the FastJet banner. Only the first call to
539 /// this function will result in the printout of the banner. Users
540 /// may wish to call this function themselves, during the
541 /// initialization phase of their program, in order to ensure that
542 /// the banner appears before other output. This call will not
543 /// affect 3rd-party banners, e.g. those from plugins.
544 static void print_banner();
545
546 /// \cond internal_doc
547 // [this line must be left as is to hide the doxygen comment]
548 /// A call to this function modifies the stream used to print
549 /// banners (by default cout). If a null pointer is passed, banner
550 /// printout is suppressed. This affects all banners, including
551 /// those from plugins.
552 ///
553 /// Please note that if you distribute 3rd party code
554 /// that links with FastJet, that 3rd party code must not
555 /// use this call turn off the printing of FastJet banners
556 /// by default. This requirement reflects the spirit of
557 /// clause 2c of the GNU Public License (v2), under which
558 /// FastJet and its plugins are distributed.
559 static void set_fastjet_banner_stream(std::ostream * ostr) {_fastjet_banner_ostr = ostr;}
560 // [this line must be left as is to hide the doxygen comment]
561 /// \endcond
562
563 /// returns a pointer to the stream to be used to print banners
564 /// (cout by default). This function is used by plugins to determine
565 /// where to direct their banners. Plugins should properly handle
566 /// the case where the pointer is null.
567 static std::ostream * fastjet_banner_stream() {return _fastjet_banner_ostr;}
568
569private:
570 /// \cond internal_doc
571
572 /// contains the actual stream to use for banners
573 static std::ostream * _fastjet_banner_ostr;
574
575 /// \endcond
576
577protected:
578//DEP static JetAlgorithm _default_jet_algorithm;
579 JetDefinition _jet_def;
580
581 /// transfer the vector<L> of input jets into our own vector<PseudoJet>
582 /// _jets (with some reserved space for future growth).
583 template<class L> void _transfer_input_jets(
584 const std::vector<L> & pseudojets);
585
586 /// This is what is called to do all the initialisation and
587 /// then run the clustering (may be called by various constructors).
588 /// It assumes _jets contains the momenta to be clustered.
589 void _initialise_and_run (const JetDefinition & jet_def,
590 const bool & writeout_combinations);
591
592 //// this performs the initialisation, minus the option-decanting
593 //// stage; for low multiplicity, initialising a few things in the
594 //// constructor, calling the decant_options_partial() and then this
595 //// is faster than going through _initialise_and_run.
596 void _initialise_and_run_no_decant();
597
598//DEP /// This is an alternative routine for initialising and running the
599//DEP /// clustering, provided for legacy purposes. The jet finder is that
600//DEP /// specified in the static member _default_jet_algorithm.
601//DEP void _initialise_and_run (const double & R,
602//DEP const Strategy & strategy,
603//DEP const bool & writeout_combinations);
604
605 /// fills in the various member variables with "decanted" options from
606 /// the jet_definition and writeout_combinations variables
607 void _decant_options(const JetDefinition & jet_def,
608 const bool & writeout_combinations);
609
610 /// assuming that the jet definition, writeout_combinations and
611 /// _structure_shared_ptr have been set (e.g. in an initialiser list
612 /// in the constructor), it handles the remaining decanting of
613 /// options.
614 void _decant_options_partial();
615
616 /// fill out the history (and jet cross refs) related to the initial
617 /// set of jets (assumed already to have been "transferred"),
618 /// without any clustering
619 void _fill_initial_history();
620
621 /// carry out the recombination between the jets numbered jet_i and
622 /// jet_j, at distance scale dij; return the index newjet_k of the
623 /// result of the recombination of i and j.
624 void _do_ij_recombination_step(const int & jet_i, const int & jet_j,
625 const double & dij, int & newjet_k);
626
627 /// carry out an recombination step in which _jets[jet_i] merges with
628 /// the beam,
629 void _do_iB_recombination_step(const int & jet_i, const double & diB);
630
631 /// every time a jet is added internally during clustering, this
632 /// should be called to set the jet's structure shared ptr to point
633 /// to the CS (and the count of internally associated objects is
634 /// also updated). This should not be called outside construction of
635 /// a CS object.
636 void _set_structure_shared_ptr(PseudoJet & j);
637
638 /// make sure that the CS's internal tally of the use count matches
639 /// that of the _structure_shared_ptr
640 void _update_structure_use_count();
641
642
643 /// This contains the physical PseudoJets; for each PseudoJet one
644 /// can find the corresponding position in the _history by looking
645 /// at _jets[i].cluster_hist_index().
646 std::vector<PseudoJet> _jets;
647
648
649 /// this vector will contain the branching history; for each stage,
650 /// _history[i].jetp_index indicates where to look in the _jets
651 /// vector to get the physical PseudoJet.
652 std::vector<history_element> _history;
653
654 /// set subhist to be a set pointers to history entries corresponding to the
655 /// subjets of this jet; one stops going working down through the
656 /// subjets either when
657 /// - there is no further to go
658 /// - one has found maxjet entries
659 /// - max_dij_so_far <= dcut
660 /// By setting maxjet=0 one can use just dcut; by setting dcut<0
661 /// one can use jet maxjet
662 void get_subhist_set(std::set<const history_element*> & subhist,
663 const PseudoJet & jet, double dcut, int maxjet) const;
664
665 bool _writeout_combinations;
666 int _initial_n;
667 double _Rparam, _R2, _invR2;
668 double _Qtot;
669 Strategy _strategy;
670 JetAlgorithm _jet_algorithm;
671
672 SharedPtr<PseudoJetStructureBase> _structure_shared_ptr; //< will actually be of type ClusterSequenceStructure
673 int _structure_use_count_after_construction; //< info of use when CS handles its own memory
674 /// if true then the CS will delete itself when the last external
675 /// object referring to it disappears. It is mutable so as to ensure
676 /// that signal_imminent_self_deletion() [const] can make relevant
677 /// changes.
678 mutable bool _deletes_self_when_unused;
679
680 private:
681
682 bool _plugin_activated;
683 //std::auto_ptr<Extras> _extras; // things the plugin might want to add
684 SharedPtr<Extras> _extras; // things the plugin might want to add
685
686 void _really_dumb_cluster ();
687 void _delaunay_cluster ();
688 //void _simple_N2_cluster ();
689 template<class BJ> void _simple_N2_cluster ();
690 void _tiled_N2_cluster ();
691 void _faster_tiled_N2_cluster ();
692
693 //
694 void _minheap_faster_tiled_N2_cluster();
695
696 // things needed specifically for Cambridge with Chan's 2D closest
697 // pairs method
698 void _CP2DChan_cluster();
699 void _CP2DChan_cluster_2pi2R ();
700 void _CP2DChan_cluster_2piMultD ();
701 void _CP2DChan_limited_cluster(double D);
702 void _do_Cambridge_inclusive_jets();
703
704 // NSqrtN method for C/A
705 void _fast_NsqrtN_cluster();
706
707 void _add_step_to_history(const int & step_number, const int & parent1,
708 const int & parent2, const int & jetp_index,
709 const double & dij);
710
711 /// internal routine associated with the construction of the unique
712 /// history order (following children in the tree)
713 void _extract_tree_children(int pos, std::valarray<bool> &,
714 const std::valarray<int> &, std::vector<int> &) const;
715
716 /// internal routine associated with the construction of the unique
717 /// history order (following parents in the tree)
718 void _extract_tree_parents (int pos, std::valarray<bool> &,
719 const std::valarray<int> &, std::vector<int> &) const;
720
721
722 // these will be useful shorthands in the Voronoi-based code
723 typedef std::pair<int,int> TwoVertices;
724 typedef std::pair<double,TwoVertices> DijEntry;
725 typedef std::multimap<double,TwoVertices> DistMap;
726
727 /// currently used only in the Voronoi based code
728 void _add_ktdistance_to_map(const int & ii,
729 DistMap & DijMap,
730 const DynamicNearestNeighbours * DNN);
731
732
733 /// will be set by default to be true for the first run
734 static bool _first_time;
735
736 /// record the number of warnings provided about the exclusive
737 /// algorithm -- so that we don't print it out more than a few
738 /// times.
739 static int _n_exclusive_warnings;
740
741 /// the limited warning member for notification of user that
742 /// their requested strategy has been overridden (usually because
743 /// they have R>2pi and not all strategies work then)
744 static LimitedWarning _changed_strategy_warning;
745
746 //----------------------------------------------------------------------
747 /// the fundamental structure which contains the minimal info about
748 /// a jet, as needed for our plain N^2 algorithm -- the idea is to
749 /// put all info that will be accessed N^2 times into an array of
750 /// BriefJets...
751 struct BriefJet {
752 double eta, phi, kt2, NN_dist;
753 BriefJet * NN;
754 int _jets_index;
755 };
756
757
758 /// structure analogous to BriefJet, but with the extra information
759 /// needed for dealing with tiles
760 class TiledJet {
761 public:
762 double eta, phi, kt2, NN_dist;
763 TiledJet * NN, *previous, * next;
764 int _jets_index, tile_index, diJ_posn;
765 // routines that are useful in the minheap version of tiled
766 // clustering ("misuse" the otherwise unused diJ_posn, so as
767 // to indicate whether jets need to have their minheap entries
768 // updated).
769 inline void label_minheap_update_needed() {diJ_posn = 1;}
770 inline void label_minheap_update_done() {diJ_posn = 0;}
771 inline bool minheap_update_needed() const {return diJ_posn==1;}
772 };
773
774 //-- some of the functions that follow are templates and will work
775 //as well for briefjet and tiled jets
776
777 /// set the kinematic and labelling info for jeta so that it corresponds
778 /// to _jets[_jets_index]
779 template <class J> void _bj_set_jetinfo( J * const jet,
780 const int _jets_index) const;
781
782 /// "remove" this jet, which implies updating links of neighbours and
783 /// perhaps modifying the tile structure
784 void _bj_remove_from_tiles( TiledJet * const jet) const;
785
786 /// return the distance between two BriefJet objects
787 template <class J> double _bj_dist(const J * const jeta,
788 const J * const jetb) const;
789
790 // return the diJ (multiplied by _R2) for this jet assuming its NN
791 // info is correct
792 template <class J> double _bj_diJ(const J * const jeta) const;
793
794 /// for testing purposes only: if in the range head--tail-1 there is a
795 /// a jet which corresponds to hist_index in the history, then
796 /// return a pointer to that jet; otherwise return tail.
797 template <class J> inline J * _bj_of_hindex(
798 const int hist_index,
799 J * const head, J * const tail)
800 const {
801 J * res;
802 for(res = head; res<tail; res++) {
803 if (_jets[res->_jets_index].cluster_hist_index() == hist_index) {break;}
804 }
805 return res;
806 }
807
808
809 //-- remaining functions are different in various cases, so we
810 // will use templates but are not sure if they're useful...
811
812 /// updates (only towards smaller distances) the NN for jeta without checking
813 /// whether in the process jeta itself might be a new NN of one of
814 /// the jets being scanned -- span the range head to tail-1 with
815 /// assumption that jeta is not contained in that range
816 template <class J> void _bj_set_NN_nocross(J * const jeta,
817 J * const head, const J * const tail) const;
818
819 /// reset the NN for jeta and DO check whether in the process jeta
820 /// itself might be a new NN of one of the jets being scanned --
821 /// span the range head to tail-1 with assumption that jeta is not
822 /// contained in that range
823 template <class J> void _bj_set_NN_crosscheck(J * const jeta,
824 J * const head, const J * const tail) const;
825
826
827
828 /// number of neighbours that a tile will have (rectangular geometry
829 /// gives 9 neighbours).
830 static const int n_tile_neighbours = 9;
831 //----------------------------------------------------------------------
832 /// The fundamental structures to be used for the tiled N^2 algorithm
833 /// (see CCN27-44 for some discussion of pattern of tiling)
834 struct Tile {
835 /// pointers to neighbouring tiles, including self
836 Tile * begin_tiles[n_tile_neighbours];
837 /// neighbouring tiles, excluding self
838 Tile ** surrounding_tiles;
839 /// half of neighbouring tiles, no self
840 Tile ** RH_tiles;
841 /// just beyond end of tiles
842 Tile ** end_tiles;
843 /// start of list of BriefJets contained in this tile
844 TiledJet * head;
845 /// sometimes useful to be able to tag a tile
846 bool tagged;
847 };
848 std::vector<Tile> _tiles;
849 double _tiles_eta_min, _tiles_eta_max;
850 double _tile_size_eta, _tile_size_phi;
851 int _n_tiles_phi,_tiles_ieta_min,_tiles_ieta_max;
852
853 // reasonably robust return of tile index given ieta and iphi, in particular
854 // it works even if iphi is negative
855 inline int _tile_index (int ieta, int iphi) const {
856 // note that (-1)%n = -1 so that we have to add _n_tiles_phi
857 // before performing modulo operation
858 return (ieta-_tiles_ieta_min)*_n_tiles_phi
859 + (iphi+_n_tiles_phi) % _n_tiles_phi;
860 }
861
862 // routines for tiled case, including some overloads of the plain
863 // BriefJet cases
864 int _tile_index(const double & eta, const double & phi) const;
865 void _tj_set_jetinfo ( TiledJet * const jet, const int _jets_index);
866 void _bj_remove_from_tiles(TiledJet * const jet);
867 void _initialise_tiles();
868 void _print_tiles(TiledJet * briefjets ) const;
869 void _add_neighbours_to_tile_union(const int tile_index,
870 std::vector<int> & tile_union, int & n_near_tiles) const;
871 void _add_untagged_neighbours_to_tile_union(const int tile_index,
872 std::vector<int> & tile_union, int & n_near_tiles);
873
874
875 //----------------------------------------------------------------------
876 /// fundamental structure for e+e- clustering
877 struct EEBriefJet {
878 double NN_dist; // obligatorily present
879 double kt2; // obligatorily present == E^2 in general
880 EEBriefJet * NN; // must be present too
881 int _jets_index; // must also be present!
882 //...........................................................
883 double nx, ny, nz; // our internal storage for fast distance calcs
884 };
885
886 /// to help instantiation (fj 2.4.0; did not quite work on gcc 33 and os x 10.3?)
887 //void _dummy_N2_cluster_instantiation();
888
889
890 /// to avoid issues with template instantiation (OS X 10.3, gcc 3.3)
891 void _simple_N2_cluster_BriefJet();
892 /// to avoid issues with template instantiation (OS X 10.3, gcc 3.3)
893 void _simple_N2_cluster_EEBriefJet();
894};
895
896
897//**********************************************************************
898//************** START OF INLINE MATERIAL ******************
899//**********************************************************************
900
901
902//----------------------------------------------------------------------
903// Transfer the initial jets into our internal structure
904template<class L> void ClusterSequence::_transfer_input_jets(
905 const std::vector<L> & pseudojets) {
906
907 // this will ensure that we can point to jets without difficulties
908 // arising.
909 _jets.reserve(pseudojets.size()*2);
910
911 // insert initial jets this way so that any type L that can be
912 // converted to a pseudojet will work fine (basically PseudoJet
913 // and any type that has [] subscript access to the momentum
914 // components, such as CLHEP HepLorentzVector).
915 for (unsigned int i = 0; i < pseudojets.size(); i++) {
916 _jets.push_back(pseudojets[i]);}
917
918}
919
920// //----------------------------------------------------------------------
921// // initialise from some generic type... Has to be made available
922// // here in order for it the template aspect of it to work...
923// template<class L> ClusterSequence::ClusterSequence (
924// const std::vector<L> & pseudojets,
925// const double & R,
926// const Strategy & strategy,
927// const bool & writeout_combinations) {
928//
929// // transfer the initial jets (type L) into our own array
930// _transfer_input_jets(pseudojets);
931//
932// // run the clustering
933// _initialise_and_run(R,strategy,writeout_combinations);
934// }
935
936
937//----------------------------------------------------------------------
938/// constructor of a jet-clustering sequence from a vector of
939/// four-momenta, with the jet definition specified by jet_def
940template<class L> ClusterSequence::ClusterSequence (
941 const std::vector<L> & pseudojets,
942 const JetDefinition & jet_def_in,
943 const bool & writeout_combinations) :
944 _jet_def(jet_def_in), _writeout_combinations(writeout_combinations),
945 _structure_shared_ptr(new ClusterSequenceStructure(this))
946{
947
948 // transfer the initial jets (type L) into our own array
949 _transfer_input_jets(pseudojets);
950
951 // transfer the remaining options
952 _decant_options_partial();
953
954 // run the clustering
955 _initialise_and_run_no_decant();
956}
957
958
959inline const std::vector<PseudoJet> & ClusterSequence::jets () const {
960 return _jets;
961}
962
963inline const std::vector<ClusterSequence::history_element> & ClusterSequence::history () const {
964 return _history;
965}
966
967inline unsigned int ClusterSequence::n_particles() const {return _initial_n;}
968
969
970
971//----------------------------------------------------------------------
972template <class J> inline void ClusterSequence::_bj_set_jetinfo(
973 J * const jetA, const int _jets_index) const {
974 jetA->eta = _jets[_jets_index].rap();
975 jetA->phi = _jets[_jets_index].phi_02pi();
976 jetA->kt2 = jet_scale_for_algorithm(_jets[_jets_index]);
977 jetA->_jets_index = _jets_index;
978 // initialise NN info as well
979 jetA->NN_dist = _R2;
980 jetA->NN = NULL;
981}
982
983
984
985
986//----------------------------------------------------------------------
987template <class J> inline double ClusterSequence::_bj_dist(
988 const J * const jetA, const J * const jetB) const {
989 double dphi = std::abs(jetA->phi - jetB->phi);
990 double deta = (jetA->eta - jetB->eta);
991 if (dphi > pi) {dphi = twopi - dphi;}
992 return dphi*dphi + deta*deta;
993}
994
995//----------------------------------------------------------------------
996template <class J> inline double ClusterSequence::_bj_diJ(const J * const jet) const {
997 double kt2 = jet->kt2;
998 if (jet->NN != NULL) {if (jet->NN->kt2 < kt2) {kt2 = jet->NN->kt2;}}
999 return jet->NN_dist * kt2;
1000}
1001
1002
1003//----------------------------------------------------------------------
1004// set the NN for jet without checking whether in the process you might
1005// have discovered a new nearest neighbour for another jet
1006template <class J> inline void ClusterSequence::_bj_set_NN_nocross(
1007 J * const jet, J * const head, const J * const tail) const {
1008 double NN_dist = _R2;
1009 J * NN = NULL;
1010 if (head < jet) {
1011 for (J * jetB = head; jetB != jet; jetB++) {
1012 double dist = _bj_dist(jet,jetB);
1013 if (dist < NN_dist) {
1014 NN_dist = dist;
1015 NN = jetB;
1016 }
1017 }
1018 }
1019 if (tail > jet) {
1020 for (J * jetB = jet+1; jetB != tail; jetB++) {
1021 double dist = _bj_dist(jet,jetB);
1022 if (dist < NN_dist) {
1023 NN_dist = dist;
1024 NN = jetB;
1025 }
1026 }
1027 }
1028 jet->NN = NN;
1029 jet->NN_dist = NN_dist;
1030}
1031
1032
1033//----------------------------------------------------------------------
1034template <class J> inline void ClusterSequence::_bj_set_NN_crosscheck(J * const jet,
1035 J * const head, const J * const tail) const {
1036 double NN_dist = _R2;
1037 J * NN = NULL;
1038 for (J * jetB = head; jetB != tail; jetB++) {
1039 double dist = _bj_dist(jet,jetB);
1040 if (dist < NN_dist) {
1041 NN_dist = dist;
1042 NN = jetB;
1043 }
1044 if (dist < jetB->NN_dist) {
1045 jetB->NN_dist = dist;
1046 jetB->NN = jet;
1047 }
1048 }
1049 jet->NN = NN;
1050 jet->NN_dist = NN_dist;
1051}
1052
1053FASTJET_END_NAMESPACE
1054
1055#endif // __FASTJET_CLUSTERSEQUENCE_HH__
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