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source: git/external/fastjet/ClusterSequenceAreaBase.cc@ b78adf8

ImprovedOutputFile Timing dual_readout llp
Last change on this file since b78adf8 was 35cdc46, checked in by Pavel Demin <demin@…>, 10 years ago

upgrade FastJet to version 3.1.0-beta.1, upgrade Nsubjettiness to version 2.1.0, add SoftKiller version 1.0.0

  • Property mode set to 100644
File size: 14.9 KB
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[d7d2da3]1
[35cdc46]2//FJSTARTHEADER
3// $Id: ClusterSequenceAreaBase.cc 3433 2014-07-23 08:17:03Z salam $
[d7d2da3]4//
[35cdc46]5// Copyright (c) 2005-2014, Matteo Cacciari, Gavin P. Salam and Gregory Soyez
[d7d2da3]6//
7//----------------------------------------------------------------------
8// This file is part of FastJet.
9//
10// FastJet is free software; you can redistribute it and/or modify
11// it under the terms of the GNU General Public License as published by
12// the Free Software Foundation; either version 2 of the License, or
13// (at your option) any later version.
14//
15// The algorithms that underlie FastJet have required considerable
[35cdc46]16// development. They are described in the original FastJet paper,
17// hep-ph/0512210 and in the manual, arXiv:1111.6097. If you use
[d7d2da3]18// FastJet as part of work towards a scientific publication, please
[35cdc46]19// quote the version you use and include a citation to the manual and
20// optionally also to hep-ph/0512210.
[d7d2da3]21//
22// FastJet is distributed in the hope that it will be useful,
23// but WITHOUT ANY WARRANTY; without even the implied warranty of
24// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
25// GNU General Public License for more details.
26//
27// You should have received a copy of the GNU General Public License
28// along with FastJet. If not, see <http://www.gnu.org/licenses/>.
29//----------------------------------------------------------------------
[35cdc46]30//FJENDHEADER
[d7d2da3]31
32
33
34
35#include "fastjet/ClusterSequenceAreaBase.hh"
36#include <algorithm>
37
38FASTJET_BEGIN_NAMESPACE
39
40using namespace std;
41
42
43/// allow for warnings
44LimitedWarning ClusterSequenceAreaBase::_warnings;
45LimitedWarning ClusterSequenceAreaBase::_warnings_zero_area;
46LimitedWarning ClusterSequenceAreaBase::_warnings_empty_area;
47
48//----------------------------------------------------------------------
49/// return the total area, within the selector's range, that is free
50/// of jets.
51///
52/// Calculate this as (range area) - \sum_{i in range} A_i
53///
54/// for ClusterSequences with explicit ghosts, assume that there will
55/// never be any empty area, i.e. it is always filled in by pure
56/// ghosts jets. This holds for seq.rec. algorithms
57double ClusterSequenceAreaBase::empty_area(const Selector & selector) const {
58
59 if (has_explicit_ghosts()) {return 0.0;}
60 else { return empty_area_from_jets(inclusive_jets(0.0), selector);}
61
62}
63
64//----------------------------------------------------------------------
65/// return the total area, within range, that is free of jets.
66///
67/// Calculate this as (range area) - \sum_{i in range} A_i
68///
69double ClusterSequenceAreaBase::empty_area_from_jets(
70 const std::vector<PseudoJet> & all_jets,
71 const Selector & selector) const {
72 _check_selector_good_for_median(selector);
73
74 double empty = selector.area();
75 for (unsigned i = 0; i < all_jets.size(); i++) {
76 if (selector.pass(all_jets[i])) empty -= area(all_jets[i]);
77 }
78 return empty;
79}
80
81double ClusterSequenceAreaBase::median_pt_per_unit_area(const Selector & selector) const {
82 return median_pt_per_unit_something(selector,false);
83}
84
85double ClusterSequenceAreaBase::median_pt_per_unit_area_4vector(const Selector & selector) const {
86 return median_pt_per_unit_something(selector,true);
87}
88
89
90//----------------------------------------------------------------------
91/// the median of (pt/area) for jets contained within range, counting
92/// the empty area as if it were made up of a collection of empty
93/// jets each of area (0.55 * pi R^2).
94double ClusterSequenceAreaBase::median_pt_per_unit_something(
95 const Selector & selector, bool use_area_4vector) const {
96
97 double median, sigma, mean_area;
98 get_median_rho_and_sigma(selector, use_area_4vector, median, sigma, mean_area);
99 return median;
100
101}
102
103
104//----------------------------------------------------------------------
105/// fits a form pt_per_unit_area(y) = a + b*y^2 for jets in range.
106/// exclude_above allows one to exclude large values of pt/area from fit.
107/// use_area_4vector = true uses the 4vector areas.
108void ClusterSequenceAreaBase::parabolic_pt_per_unit_area(
109 double & a, double & b, const Selector & selector,
110 double exclude_above, bool use_area_4vector) const {
111 // sanity check on the selector: we require a finite area and that
112 // it applies jet by jet (see BackgroundEstimator for more advanced
113 // usage)
114 _check_selector_good_for_median(selector);
115
116 int n=0;
117 int n_excluded = 0;
118 double mean_f=0, mean_x2=0, mean_x4=0, mean_fx2=0;
119
120 vector<PseudoJet> incl_jets = inclusive_jets();
121
122 for (unsigned i = 0; i < incl_jets.size(); i++) {
123 if (selector.pass(incl_jets[i])) {
124 double this_area;
125 if ( use_area_4vector ) {
126 this_area = area_4vector(incl_jets[i]).perp();
127 } else {
128 this_area = area(incl_jets[i]);
129 }
130 double f = incl_jets[i].perp()/this_area;
131 if (exclude_above <= 0.0 || f < exclude_above) {
132 double x = incl_jets[i].rap(); double x2 = x*x;
133 mean_f += f;
134 mean_x2 += x2;
135 mean_x4 += x2*x2;
136 mean_fx2 += f*x2;
137 n++;
138 } else {
139 n_excluded++;
140 }
141 }
142 }
143
144 if (n <= 1) {
145 // meaningful results require at least two jets inside the
146 // area -- mind you if there are empty jets we should be in
147 // any case doing something special...
148 a = 0.0;
149 b = 0.0;
150 } else {
151 mean_f /= n;
152 mean_x2 /= n;
153 mean_x4 /= n;
154 mean_fx2 /= n;
155
156 b = (mean_f*mean_x2 - mean_fx2)/(mean_x2*mean_x2 - mean_x4);
157 a = mean_f - b*mean_x2;
158 }
159 //cerr << "n_excluded = "<< n_excluded << endl;
160}
161
162
163
164void ClusterSequenceAreaBase::get_median_rho_and_sigma(
165 const Selector & selector, bool use_area_4vector,
166 double & median, double & sigma, double & mean_area) const {
167
168 vector<PseudoJet> incl_jets = inclusive_jets();
169 get_median_rho_and_sigma(incl_jets, selector, use_area_4vector,
170 median, sigma, mean_area, true);
171}
172
173
174void ClusterSequenceAreaBase::get_median_rho_and_sigma(
175 const vector<PseudoJet> & all_jets,
176 const Selector & selector, bool use_area_4vector,
177 double & median, double & sigma, double & mean_area,
178 bool all_are_incl) const {
179
180 _check_jet_alg_good_for_median();
181
182 // sanity check on the selector: we require a finite area and that
183 // it applies jet by jet (see BackgroundEstimator for more advanced
184 // usage)
185 _check_selector_good_for_median(selector);
186
187 vector<double> pt_over_areas;
188 double total_area = 0.0;
189 double total_njets = 0;
190
191 for (unsigned i = 0; i < all_jets.size(); i++) {
192 if (selector.pass(all_jets[i])) {
193 double this_area;
194 if (use_area_4vector) {
195 this_area = area_4vector(all_jets[i]).perp();
196 } else {
197 this_area = area(all_jets[i]);
198 }
199
200 if (this_area>0) {
201 pt_over_areas.push_back(all_jets[i].perp()/this_area);
202 } else {
203 _warnings_zero_area.warn("ClusterSequenceAreaBase::get_median_rho_and_sigma(...): discarded jet with zero area. Zero-area jets may be due to (i) too large a ghost area (ii) a jet being outside the ghost range (iii) the computation not being done using an appropriate algorithm (kt;C/A).");
204 }
205
206 total_area += this_area;
207 total_njets += 1.0;
208 }
209 }
210
211 // there is nothing inside our region, so answer will always be zero
212 if (pt_over_areas.size() == 0) {
213 median = 0.0;
214 sigma = 0.0;
215 mean_area = 0.0;
216 return;
217 }
218
219 // get median (pt/area) [this is the "old" median definition. It considers
220 // only the "real" jets in calculating the median, i.e. excluding the
221 // only-ghost ones; it will be supplemented with more info below]
222 sort(pt_over_areas.begin(), pt_over_areas.end());
223
224 // now get the median & error, accounting for empty jets
225 // define the fractions of distribution at median, median-1sigma
226 double posn[2] = {0.5, (1.0-0.6827)/2.0};
227 double res[2];
228
229 double n_empty, empty_a;
230 if (has_explicit_ghosts()) {
231 // NB: the following lines of code are potentially incorrect in cases
232 // where there are unclustered particles (empty_area would do a better job,
233 // at least for active areas). This is not an issue with kt or C/A, or other
234 // algorithms that cluster all particles (and the median estimation should in
235 // any case only be done with kt or C/A!)
236 empty_a = 0.0;
237 n_empty = 0;
238 } else if (all_are_incl) {
239 // the default case
240 empty_a = empty_area(selector);
241 n_empty = n_empty_jets(selector);
242 } else {
243 // this one is intended to be used when e.g. one runs C/A, then looks at its
244 // exclusive jets in order to get an effective smaller R value, and passes those
245 // to this routine.
246 empty_a = empty_area_from_jets(all_jets, selector);
247 mean_area = total_area / total_njets; // temporary value
248 n_empty = empty_a / mean_area;
249 }
250 //cout << "*** tot_area = " << total_area << ", empty_a = " << empty_a << endl;
251 //cout << "*** n_empty = " << n_empty << ", ntotal = " << total_njets << endl;
252 total_njets += n_empty;
253 total_area += empty_a;
254
255 // we need an int (rather than an unsigned int) with the size of the
256 // pt_over_areas array, because we'll often be doing subtraction of
257 // -1, negating it, etc. All of these operations go crazy with unsigned ints.
258 int pt_over_areas_size = pt_over_areas.size();
259 if (n_empty < -pt_over_areas_size/4.0)
260 _warnings_empty_area.warn("ClusterSequenceAreaBase::get_median_rho_and_sigma(...): the estimated empty area is suspiciously large and negative and may lead to an over-estimation of rho. This may be due to (i) a rare statistical fluctuation or (ii) too small a range used to estimate the background properties.");
261
262 for (int i = 0; i < 2; i++) {
263 double nj_median_pos =
264 (pt_over_areas_size-1.0 + n_empty)*posn[i] - n_empty;
265 double nj_median_ratio;
266 if (nj_median_pos >= 0 && pt_over_areas_size > 1) {
267 int int_nj_median = int(nj_median_pos);
268
269 // avoid potential overflow issues
270 if (int_nj_median+1 > pt_over_areas_size-1){
271 int_nj_median = pt_over_areas_size-2;
272 nj_median_pos = pt_over_areas_size-1;
273 }
274
275 nj_median_ratio =
276 pt_over_areas[int_nj_median] * (int_nj_median+1-nj_median_pos)
277 + pt_over_areas[int_nj_median+1] * (nj_median_pos - int_nj_median);
278 } else {
279 nj_median_ratio = 0.0;
280 }
281 res[i] = nj_median_ratio;
282 }
283 median = res[0];
284 double error = res[0] - res[1];
285 mean_area = total_area / total_njets;
286 sigma = error * sqrt(mean_area);
287}
288
289
290/// return a vector of all subtracted jets, using area_4vector, given rho.
291/// Only inclusive_jets above ptmin are subtracted and returned.
292/// the ordering is the same as that of sorted_by_pt(cs.inclusive_jets()),
293/// i.e. not necessarily ordered in pt once subtracted
294vector<PseudoJet> ClusterSequenceAreaBase::subtracted_jets(const double rho,
295 const double ptmin)
296 const {
297 vector<PseudoJet> sub_jets;
298 vector<PseudoJet> jets_local = sorted_by_pt(inclusive_jets(ptmin));
299 for (unsigned i=0; i<jets_local.size(); i++) {
300 PseudoJet sub_jet = subtracted_jet(jets_local[i],rho);
301 sub_jets.push_back(sub_jet);
302 }
303 return sub_jets;
304}
305
306/// return a vector of subtracted jets, using area_4vector.
307/// Only inclusive_jets above ptmin are subtracted and returned.
308/// the ordering is the same as that of sorted_by_pt(cs.inclusive_jets()),
309/// i.e. not necessarily ordered in pt once subtracted
310vector<PseudoJet> ClusterSequenceAreaBase::subtracted_jets(
311 const Selector & selector,
312 const double ptmin)
313 const {
314 double rho = median_pt_per_unit_area_4vector(selector);
315 return subtracted_jets(rho,ptmin);
316}
317
318
319/// return a subtracted jet, using area_4vector, given rho
320PseudoJet ClusterSequenceAreaBase::subtracted_jet(const PseudoJet & jet,
321 const double rho) const {
322 PseudoJet area4vect = area_4vector(jet);
323 PseudoJet sub_jet;
324 // sanity check
325 if (rho*area4vect.perp() < jet.perp() ) {
326 sub_jet = jet - rho*area4vect;
327 } else { sub_jet = PseudoJet(0.0,0.0,0.0,0.0); }
328
329 // make sure the subtracted jet has the same index (cluster, user, csw)
330 // (i.e. "looks like") the original jet
331 sub_jet.set_cluster_hist_index(jet.cluster_hist_index());
332 sub_jet.set_user_index(jet.user_index());
333 // do not use CS::_set_structure_shared_ptr here, which should
334 // only be called to maintain the tally during construction
335 sub_jet.set_structure_shared_ptr(jet.structure_shared_ptr());
336 return sub_jet;
337}
338
339
340/// return a subtracted jet, using area_4vector; note that this is
341/// potentially inefficient if repeatedly used for many different
342/// jets, because rho will be recalculated each time around.
343PseudoJet ClusterSequenceAreaBase::subtracted_jet(const PseudoJet & jet,
344 const Selector & selector) const {
345 double rho = median_pt_per_unit_area_4vector(selector);
346 PseudoJet sub_jet = subtracted_jet(jet, rho);
347 return sub_jet;
348}
349
350
351/// return the subtracted pt, given rho
352double ClusterSequenceAreaBase::subtracted_pt(const PseudoJet & jet,
353 const double rho,
354 bool use_area_4vector) const {
355 if ( use_area_4vector ) {
356 PseudoJet sub_jet = subtracted_jet(jet,rho);
357 return sub_jet.perp();
358 } else {
359 return jet.perp() - rho*area(jet);
360 }
361}
362
363
364/// return the subtracted pt; note that this is
365/// potentially inefficient if repeatedly used for many different
366/// jets, because rho will be recalculated each time around.
367double ClusterSequenceAreaBase::subtracted_pt(const PseudoJet & jet,
368 const Selector & selector,
369 bool use_area_4vector) const {
370 if ( use_area_4vector ) {
371 PseudoJet sub_jet = subtracted_jet(jet,selector);
372 return sub_jet.perp();
373 } else {
374 double rho = median_pt_per_unit_area(selector);
375 return subtracted_pt(jet,rho,false);
376 }
377}
378
379// check the selector is suited for the computations i.e. applies jet
380// by jet and has a finite area
381void ClusterSequenceAreaBase::_check_selector_good_for_median(const Selector &selector) const{
382 // make sure the selector has a finite area
383 if ((! has_explicit_ghosts()) && (! selector.has_finite_area())){
384 throw Error("ClusterSequenceAreaBase: empty area can only be computed from selectors with a finite area");
385 }
386
387 // make sure the selector applies jet by jet
388 if (! selector.applies_jet_by_jet()){
389 throw Error("ClusterSequenceAreaBase: empty area can only be computed from selectors that apply jet by jet");
390 }
391}
392
393
394/// check the jet algorithm is suitable (and if not issue a warning)
395void ClusterSequenceAreaBase::_check_jet_alg_good_for_median() const {
396 if (jet_def().jet_algorithm() != kt_algorithm
397 && jet_def().jet_algorithm() != cambridge_algorithm
398 && jet_def().jet_algorithm() != cambridge_for_passive_algorithm) {
399 _warnings.warn("ClusterSequenceAreaBase: jet_def being used may not be suitable for estimating diffuse backgrounds (good options are kt, cam)");
400 }
401}
402
403
404
405FASTJET_END_NAMESPACE
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