fastjet_timing.cc File Reference
#include "fastjet/PseudoJet.hh"#include "fastjet/ClusterSequence.hh"#include <iostream>#include <sstream>#include <valarray>#include <vector>#include <cstdio>#include <cstdlib>#include <cstddef>#include "CmdLine.hh"
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Functions | |
| double | pow2 (const double x) |
| int | main (int argc, char **argv) |
| a program to test and time the kt algorithm as implemented in fastjet | |
Function Documentation
| int main | ( | int | argc, | |
| char ** | argv | |||
| ) |
a program to test and time the kt algorithm as implemented in fastjet
Definition at line 99 of file fastjet_timing.cc.
References CmdLine::all_options_used(), Best, cambridge_algorithm, CmdLine::double_val(), CmdLine::int_val(), kt_algorithm, fastjet::d0::inline_maths::phi(), pow2(), CmdLine::present(), sorted_by_E(), sorted_by_pt(), and twopi.
00099 { 00100 00101 CmdLine cmdline(argc,argv); 00102 // allow the use to specify the fj::Strategy either through the 00103 // -clever or the -strategy options (both will take numerical 00104 // values); the latter will override the former. 00105 fj::Strategy strategy = fj::Strategy(cmdline.int_val("-strategy", 00106 cmdline.int_val("-clever", fj::Best))); 00107 int repeat = cmdline.int_val("-repeat",1); 00108 int combine = cmdline.int_val("-combine",1); 00109 bool write = cmdline.present("-write"); 00110 bool unique_write = cmdline.present("-unique_write"); 00111 bool hydjet = cmdline.present("-hydjet"); 00112 double ktR = cmdline.double_val("-r",1.0); 00113 double inclkt = cmdline.double_val("-incl",-1.0); 00114 int excln = cmdline.int_val ("-excln",-1); 00115 double excld = cmdline.double_val("-excld",-1.0); 00116 double etamax = cmdline.double_val("-etamax",1.0e305); 00117 bool show_constituents = cmdline.present("-const"); 00118 bool massless = cmdline.present("-massless"); 00119 int nev = cmdline.int_val("-nev",1); 00120 bool add_dense_coverage = cmdline.present("-dense"); 00121 00122 // The following option causes the Cambridge algo to be used. 00123 // Note that currently the only output that works sensibly here is 00124 // "-incl 0" 00125 fj::JetAlgorithm jet_algorithm; 00126 if (cmdline.present("-cam")) { 00127 jet_algorithm = fj::cambridge_algorithm; 00128 } else { 00129 jet_algorithm = fj::kt_algorithm; 00130 } 00131 00132 if (!cmdline.all_options_used()) {cerr << 00133 "Error: some options were not recognized"<<endl; 00134 exit(-1);} 00135 00136 00137 for (int iev = 0; iev < nev; iev++) { 00138 vector<fj::PseudoJet> jets; 00139 string line; 00140 int ndone = 0; 00141 while (getline(cin, line)) { 00142 //cout << line<<endl; 00143 istringstream linestream(line); 00144 if (line == "#END") { 00145 ndone += 1; 00146 if (ndone == combine) {break;} 00147 } 00148 if (line.substr(0,1) == "#") {continue;} 00149 valarray<double> fourvec(4); 00150 if (hydjet) { 00151 // special reading from hydjet.txt event record (though actually 00152 // this is supposed to be a standard pythia event record, so 00153 // being able to read from it is perhaps not so bad an idea...) 00154 int ii, istat,id,m1,m2,d1,d2; 00155 double mass; 00156 linestream >> ii>> istat >> id >> m1 >> m2 >> d1 >> d2 00157 >> fourvec[0] >> fourvec[1] >> fourvec[2] >> mass; 00158 // current file contains mass of particle as 4th entry 00159 if (istat == 1) { 00160 fourvec[3] = sqrt(+pow2(fourvec[0])+pow2(fourvec[1]) 00161 +pow2(fourvec[2])+pow2(mass)); 00162 } 00163 } else { 00164 if (massless) { 00165 linestream >> fourvec[0] >> fourvec[1] >> fourvec[2]; 00166 fourvec[3] = sqrt(pow2(fourvec[0])+pow2(fourvec[1])+pow2(fourvec[2]));} 00167 else { 00168 linestream >> fourvec[0] >> fourvec[1] >> fourvec[2] >> fourvec[3]; 00169 } 00170 } 00171 fj::PseudoJet psjet(fourvec); 00172 if (abs(psjet.rap() < etamax)) {jets.push_back(psjet);} 00173 } 00174 00175 // add a fake underlying event which is very soft, uniformly distributed 00176 // in eta,phi so as to allow one to reconstruct the area that is associated 00177 // with each jet. 00178 if (add_dense_coverage) { 00179 srand(2); 00180 int nphi = 60; 00181 int neta = 100; 00182 double kt = 1e-1; 00183 for (int iphi = 0; iphi<nphi; iphi++) { 00184 for (int ieta = -neta; ieta<neta+1; ieta++) { 00185 double phi = (iphi+0.5) * (fj::twopi/nphi) + rand()*0.001/RAND_MAX; 00186 double eta = ieta * (10.0/neta) + rand()*0.001/RAND_MAX; 00187 kt = 0.0000001*(1+rand()*0.1/RAND_MAX); 00188 double pminus = kt*exp(-eta); 00189 double pplus = kt*exp(+eta); 00190 double px = kt*sin(phi); 00191 double py = kt*cos(phi); 00192 //cout << kt<<" "<<eta<<" "<<phi<<"\n"; 00193 fj::PseudoJet mom(px,py,0.5*(pplus-pminus),0.5*(pplus+pminus)); 00194 jets.push_back(mom); 00195 } 00196 } 00197 } 00198 00199 fj::JetDefinition jet_def(jet_algorithm, ktR, strategy); 00200 00201 for (int irepeat = 0; irepeat < repeat ; irepeat++) { 00202 fj::ClusterSequence clust_seq(jets,jet_def,write); 00203 if (irepeat != 0) {continue;} 00204 cout << "iev "<<iev<< ": number of particles = "<< jets.size() << endl; 00205 cout << "strategy used = "<< clust_seq.strategy_string()<< endl; 00206 00207 // now provide some nice output... 00208 if (inclkt >= 0.0) { 00209 vector<fj::PseudoJet> jets = sorted_by_pt(clust_seq.inclusive_jets(inclkt)); 00210 for (size_t j = 0; j < jets.size(); j++) { 00211 printf("%5u %15.8f %15.8f %15.8f\n",j,jets[j].rap(),jets[j].phi(),sqrt(jets[j].kt2())); 00212 if (show_constituents) { 00213 vector<fj::PseudoJet> const_jets = clust_seq.constituents(jets[j]); 00214 for (size_t k = 0; k < const_jets.size(); k++) { 00215 printf(" jet%03u %15.8f %15.8f %15.8f\n",j,const_jets[k].rap(), 00216 const_jets[k].phi(),sqrt(const_jets[k].kt2())); 00217 } 00218 cout << "\n\n"; 00219 } 00220 } 00221 } 00222 00223 if (excln > 0) { 00224 vector<fj::PseudoJet> jets = sorted_by_E(clust_seq.exclusive_jets(excln)); 00225 00226 cout << "Printing "<<excln<<" exclusive jets\n"; 00227 for (size_t j = 0; j < jets.size(); j++) { 00228 printf("%5u %15.8f %15.8f %15.8f\n", 00229 //j,jets[j].rap(),jets[j].phi(),sqrt(jets[j].kt2())); 00230 j,jets[j].rap(),jets[j].phi(),jets[j].kt2()); 00231 } 00232 } 00233 00234 if (excld > 0.0) { 00235 vector<fj::PseudoJet> jets = sorted_by_pt(clust_seq.exclusive_jets(excld)); 00236 cout << "Printing exclusive jets for d = "<<excld<<"\n"; 00237 for (size_t j = 0; j < jets.size(); j++) { 00238 printf("%5u %15.8f %15.8f %15.8f\n", 00239 j,jets[j].rap(),jets[j].phi(),sqrt(jets[j].kt2())); 00240 } 00241 } 00242 00243 // useful for testing that recombination sequences are unique 00244 if (unique_write) { 00245 vector<int> unique_history = clust_seq.unique_history_order(); 00246 // construct the inverse of the above mapping 00247 vector<int> inv_unique_history(clust_seq.history().size()); 00248 for (unsigned int i = 0; i < unique_history.size(); i++) { 00249 inv_unique_history[unique_history[i]] = i;} 00250 00251 for (unsigned int i = 0; i < unique_history.size(); i++) { 00252 fj::ClusterSequence::history_element el = 00253 clust_seq.history()[unique_history[i]]; 00254 int uhp1 = el.parent1>=0 ? inv_unique_history[el.parent1] : el.parent1; 00255 int uhp2 = el.parent2>=0 ? inv_unique_history[el.parent2] : el.parent2; 00256 printf("%7d u %15.8e %7d u %7d u\n",i,el.dij,uhp1, uhp2); 00257 } 00258 } 00259 00260 } // irepeat 00261 00262 } // iev 00263 }
| double pow2 | ( | const double | x | ) | [inline] |
