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EmissionVetoHook1 Class Reference

#include <EmissionVetoHook1.h>

Inheritance diagram for EmissionVetoHook1:

Public Member Functions

bool canVetoFSREmission ()
 
bool canVetoISREmission ()
 
bool canVetoMPIEmission ()
 
bool canVetoMPIStep ()
 
bool doVetoFSREmission (int, const Pythia8::Event &e, int iSys, bool)
 
bool doVetoISREmission (int, const Pythia8::Event &e, int iSys)
 
bool doVetoMPIEmission (int, const Pythia8::Event &e)
 
bool doVetoMPIStep (int nMPI, const Pythia8::Event &e)
 
 EmissionVetoHook1 (int nFinalIn, bool vetoOnIn, int vetoCountIn, int pThardModeIn, int pTemtModeIn, int emittedModeIn, int pTdefModeIn, bool MPIvetoOnIn, int VerbosityIn)
 
void fatalEmissionVeto (string message)
 
int numberVetoMPIStep ()
 
double pTcalc (const Pythia8::Event &e, int i, int j, int k, int r, int xSRin)
 
double pTpowheg (const Pythia8::Event &e, int i, int j, bool FSR)
 
double pTpythia (const Pythia8::Event &e, int RadAfterBranch, int EmtAfterBranch, int RecAfterBranch, bool FSR)
 
 ~EmissionVetoHook1 ()
 

Private Attributes

bool accepted
 
int emittedMode
 
int MPIvetoOn
 
int nAcceptSeq
 
int nFinal
 
int nFinalExt
 
unsigned long int nFSRveto
 
unsigned long int nISRveto
 
int pTdefMode
 
int pTemtMode
 
double pThard
 
int pThardMode
 
double pTMPI
 
int Verbosity
 
int vetoCount
 
int vetoOn
 

Detailed Description

Definition at line 3 of file EmissionVetoHook1.h.

Constructor & Destructor Documentation

EmissionVetoHook1::EmissionVetoHook1 ( int  nFinalIn,
bool  vetoOnIn,
int  vetoCountIn,
int  pThardModeIn,
int  pTemtModeIn,
int  emittedModeIn,
int  pTdefModeIn,
bool  MPIvetoOnIn,
int  VerbosityIn 
)
inline

Definition at line 8 of file EmissionVetoHook1.h.

10  :
11  nFinalExt(nFinalIn),
12  vetoOn(vetoOnIn), vetoCount(vetoCountIn),
13  pThardMode(pThardModeIn), pTemtMode(pTemtModeIn),
14  emittedMode(emittedModeIn), pTdefMode(pTdefModeIn),
15  MPIvetoOn(MPIvetoOnIn), nISRveto(0), nFSRveto(0),
16  Verbosity(VerbosityIn) {}
unsigned long int nISRveto
unsigned long int nFSRveto
EmissionVetoHook1::~EmissionVetoHook1 ( )
inline

Definition at line 17 of file EmissionVetoHook1.h.

References gather_cfg::cout, nFSRveto, and nISRveto.

17  {
18  cout << "Number of ISR vetoed = " << nISRveto << endl;
19  cout << "Number of FSR vetoed = " << nFSRveto << endl;
20  }
unsigned long int nISRveto
unsigned long int nFSRveto
tuple cout
Definition: gather_cfg.py:121

Member Function Documentation

bool EmissionVetoHook1::canVetoFSREmission ( )
inline

Definition at line 31 of file EmissionVetoHook1.h.

References vetoOn.

31 { return vetoOn; }
bool EmissionVetoHook1::canVetoISREmission ( )
inline

Definition at line 28 of file EmissionVetoHook1.h.

References vetoOn.

28 { return vetoOn; }
bool EmissionVetoHook1::canVetoMPIEmission ( )
inline

Definition at line 34 of file EmissionVetoHook1.h.

References MPIvetoOn.

34 { return MPIvetoOn; }
bool EmissionVetoHook1::canVetoMPIStep ( )
inline

Definition at line 24 of file EmissionVetoHook1.h.

24 { return true; }
bool EmissionVetoHook1::doVetoFSREmission ( int  ,
const Pythia8::Event &  e,
int  iSys,
bool   
)

Definition at line 384 of file EmissionVetoHook1.cc.

References accepted, gather_cfg::cout, emittedMode, fatalEmissionVeto(), i, j, relval_steps::k, min(), nAcceptSeq, nFSRveto, pTcalc(), pTemtMode, pThard, alignCSCRings::r, ntuplemaker::status, swap(), vetoCount, and vetoOn.

384  {
385  // Must be radiation from the hard system
386  if (iSys != 0) return false;
387 
388  // If we already have accepted 'vetoCount' emissions in a row, do nothing
389  if (vetoOn && nAcceptSeq >= vetoCount) return false;
390 
391  // Pythia radiator (before and after), emitted and recoiler (after)
392  int iRecAft = e.size() - 1;
393  int iEmt = e.size() - 2;
394  int iRadAft = e.size() - 3;
395  int iRadBef = e[iEmt].mother1();
396  if ( (e[iRecAft].status() != 52 && e[iRecAft].status() != -53) ||
397  e[iEmt].status() != 51 || e[iRadAft].status() != 51) {
398  e.list();
399  fatalEmissionVeto(string("Couldn't find Pythia FSR emission"));
400  }
401 
402  // Behaviour based on pTemtMode:
403  // 0 - pT of emitted w.r.t. radiator before
404  // 1 - min(pT of emitted w.r.t. all incoming/outgoing)
405  // 2 - min(pT of all outgoing w.r.t. all incoming/outgoing)
406  int xSR = (pTemtMode == 0) ? 1 : -1;
407  int i = (pTemtMode == 0) ? iRadBef : -1;
408  int k = (pTemtMode == 0) ? iRadAft : -1;
409  int r = (pTemtMode == 0) ? iRecAft : -1;
410 
411  // When pTemtMode is 0 or 1, iEmt has been selected
412  double pTemt = -1.;
413  if (pTemtMode == 0 || pTemtMode == 1) {
414  // Which parton is emitted, based on emittedMode:
415  // 0 - Pythia definition of emitted
416  // 1 - Pythia definition of radiated after emission
417  // 2 - Random selection of emitted or radiated after emission
418  // 3 - Try both emitted and radiated after emission
419  int j = iRadAft;
420  if (emittedMode == 0 || (emittedMode == 2 && rndmPtr->flat() < 0.5)) j++;
421 
422  for (int jLoop = 0; jLoop < 2; jLoop++) {
423  if (jLoop == 0) pTemt = pTcalc(e, i, j, k, r, xSR);
424  else if (jLoop == 1) pTemt = min(pTemt, pTcalc(e, i, j, k, r, xSR));
425 
426  // For emittedMode == 3, have tried iRadAft, now try iEmt
427  if (emittedMode != 3) break;
428  if (k != -1) swap(j, k); else j = iEmt;
429  }
430 
431  // If pTemtMode is 2, then try all final-state partons as emitted
432  } else if (pTemtMode == 2) {
433  pTemt = pTcalc(e, i, -1, k, r, xSR);
434 
435  }
436 
437 #ifdef DBGOUTPUT
438  cout << "doVetoFSREmission: pTemt = " << pTemt << endl << endl;
439 #endif
440 
441  // Veto if pTemt > pThard
442  if (pTemt > pThard) {
443  nAcceptSeq = 0;
444  nFSRveto++;
445  return true;
446  }
447 
448  // Else mark that an emission has been accepted and continue
449  nAcceptSeq++;
450  accepted = true;
451  return false;
452 }
void swap(ora::Record &rh, ora::Record &lh)
Definition: Record.h:70
int i
Definition: DBlmapReader.cc:9
void fatalEmissionVeto(string message)
int j
Definition: DBlmapReader.cc:9
T min(T a, T b)
Definition: MathUtil.h:58
unsigned long int nFSRveto
double pTcalc(const Pythia8::Event &e, int i, int j, int k, int r, int xSRin)
tuple cout
Definition: gather_cfg.py:121
tuple status
Definition: ntuplemaker.py:245
bool EmissionVetoHook1::doVetoISREmission ( int  ,
const Pythia8::Event &  e,
int  iSys 
)

Definition at line 333 of file EmissionVetoHook1.cc.

References accepted, gather_cfg::cout, fatalEmissionVeto(), i, j, relval_steps::k, nAcceptSeq, nISRveto, pTcalc(), pTemtMode, pThard, alignCSCRings::r, ntuplemaker::status, vetoCount, and vetoOn.

333  {
334  // Must be radiation from the hard system
335  if (iSys != 0) return false;
336 
337  // If we already have accepted 'vetoCount' emissions in a row, do nothing
338  if (vetoOn && nAcceptSeq >= vetoCount) return false;
339 
340  // Pythia radiator after, emitted and recoiler after.
341  int iRadAft = -1, iEmt = -1, iRecAft = -1;
342  for (int i = e.size() - 1; i > 0; i--) {
343  if (iRadAft == -1 && e[i].status() == -41) iRadAft = i;
344  else if (iEmt == -1 && e[i].status() == 43) iEmt = i;
345  else if (iRecAft == -1 && e[i].status() == -42) iRecAft = i;
346  if (iRadAft != -1 && iEmt != -1 && iRecAft != -1) break;
347  }
348  if (iRadAft == -1 || iEmt == -1 || iRecAft == -1) {
349  e.list();
350  fatalEmissionVeto(string("Couldn't find Pythia ISR emission"));
351  }
352 
353  // pTemtMode == 0: pT of emitted w.r.t. radiator
354  // pTemtMode == 1: min(pT of emitted w.r.t. all incoming/outgoing)
355  // pTemtMode == 2: min(pT of all outgoing w.r.t. all incoming/outgoing)
356  int xSR = (pTemtMode == 0) ? 0 : -1;
357  int i = (pTemtMode == 0) ? iRadAft : -1;
358  int j = (pTemtMode != 2) ? iEmt : -1;
359  int k = -1;
360  int r = (pTemtMode == 0) ? iRecAft : -1;
361  double pTemt = pTcalc(e, i, j, k, r, xSR);
362 
363 #ifdef DBGOUTPUT
364  cout << "doVetoISREmission: pTemt = " << pTemt << endl << endl;
365 #endif
366 
367  // Veto if pTemt > pThard
368  if (pTemt > pThard) {
369  nAcceptSeq = 0;
370  nISRveto++;
371  return true;
372  }
373 
374  // Else mark that an emission has been accepted and continue
375  nAcceptSeq++;
376  accepted = true;
377  return false;
378 }
int i
Definition: DBlmapReader.cc:9
void fatalEmissionVeto(string message)
unsigned long int nISRveto
int j
Definition: DBlmapReader.cc:9
double pTcalc(const Pythia8::Event &e, int i, int j, int k, int r, int xSRin)
tuple cout
Definition: gather_cfg.py:121
tuple status
Definition: ntuplemaker.py:245
bool EmissionVetoHook1::doVetoMPIEmission ( int  ,
const Pythia8::Event &  e 
)

Definition at line 458 of file EmissionVetoHook1.cc.

References gather_cfg::cout, MPIvetoOn, and pTMPI.

458  {
459  if (MPIvetoOn) {
460  if (e[e.size() - 1].pT() > pTMPI) {
461 #ifdef DBGOUTPUT
462  cout << "doVetoMPIEmission: pTnow = " << e[e.size() - 1].pT()
463  << ", pTMPI = " << pTMPI << endl << endl;
464 #endif
465  return true;
466  }
467  }
468  return false;
469 }
tuple cout
Definition: gather_cfg.py:121
bool EmissionVetoHook1::doVetoMPIStep ( int  nMPI,
const Pythia8::Event &  e 
)

Definition at line 248 of file EmissionVetoHook1.cc.

References funct::abs(), accepted, prof2calltree::count, gather_cfg::cout, fatalEmissionVeto(), plotBeamSpotDB::first, i, prof2calltree::last, MPIvetoOn, nAcceptSeq, nFinal, nFinalExt, pTcalc(), pThard, pThardMode, pTMPI, and Verbosity.

248  {
249  // Extra check on nMPI
250  if (nMPI > 1) return false;
251 
252  // Find if there is a POWHEG emission. Go backwards through the
253  // event record until there is a non-final particle. Also sum pT and
254  // find pT_1 for possible MPI vetoing
255  int count = 0, inonfinal = 0;
256  double pT1 = 0., pTsum = 0.;
257  for (int i = e.size() - 1; i > 0; i--) {
258  inonfinal = i;
259  if (e[i].isFinal()) {
260  count++;
261  pT1 = e[i].pT();
262  pTsum += e[i].pT();
263  } else break;
264  }
265 
266  nFinal = nFinalExt;
267 
268  if (nFinal < 0) { // nFinal is not specified from external, try to find out
269  int first = -1, myid;
270  int last = -1;
271  for(int ip = 2; ip < e.size(); ip++) {
272  myid = e[ip].id();
273  if(abs(myid) < 6 || abs(myid) == 21) continue;
274  first = ip;
275  break;
276  }
277  if(first < 0) fatalEmissionVeto(string("signal particles not found"));
278  for(int ip = first; ip < e.size(); ip++) {
279  myid = e[ip].id();
280  if(abs(myid) < 6 || abs(myid) == 21) continue;
281  last = ip;
282  }
283  nFinal = last - inonfinal;
284  }
285 
286  // Extra check that we have the correct final state
287  if (count != nFinal && count != nFinal + 1)
288  fatalEmissionVeto(string("Wrong number of final state particles in event"));
289 
290  // Flag if POWHEG radiation present and index
291  bool isEmt = (count == nFinal) ? false : true;
292  int iEmt = (isEmt) ? e.size() - 1 : -1;
293 
294  // If there is no radiation or if pThardMode is 0 then set pThard to QRen.
295  if (!isEmt || pThardMode == 0) {
296  pThard = infoPtr->QRen();
297 
298  // If pThardMode is 1 then the pT of the POWHEG emission is checked against
299  // all other incoming and outgoing partons, with the minimal value taken
300  } else if (pThardMode == 1) {
301  pThard = pTcalc(e, -1, iEmt, -1, -1, -1);
302 
303  // If pThardMode is 2, then the pT of all final-state partons is checked
304  // against all other incoming and outgoing partons, with the minimal value
305  // taken
306  } else if (pThardMode == 2) {
307  pThard = pTcalc(e, -1, -1, -1, -1, -1);
308 
309  }
310 
311  // Find MPI veto pT if necessary
312  if (MPIvetoOn) {
313  pTMPI = (isEmt) ? pTsum / 2. : pT1;
314  }
315 
316  if(Verbosity)
317  cout << "doVetoMPIStep: QFac = " << infoPtr->QFac()
318  << ", QRen = " << infoPtr->QRen()
319  << ", pThard = " << pThard << endl << endl;
320 
321  // Initialise other variables
322  accepted = false;
323  nAcceptSeq = 0;
324 
325  // Do not veto the event
326  return false;
327 }
int i
Definition: DBlmapReader.cc:9
void fatalEmissionVeto(string message)
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
double pTcalc(const Pythia8::Event &e, int i, int j, int k, int r, int xSRin)
tuple cout
Definition: gather_cfg.py:121
void EmissionVetoHook1::fatalEmissionVeto ( string  message)

Definition at line 4 of file EmissionVetoHook1.cc.

References edm::errors::Configuration, and edm::hlt::Exception.

Referenced by doVetoFSREmission(), doVetoISREmission(), and doVetoMPIStep().

4  {
5  throw edm::Exception(edm::errors::Configuration,"Pythia8Interface")
6  << "EmissionVeto: " << message << endl;
7 }
int EmissionVetoHook1::numberVetoMPIStep ( )
inline

Definition at line 25 of file EmissionVetoHook1.h.

25 { return 1; }
double EmissionVetoHook1::pTcalc ( const Pythia8::Event &  e,
int  i,
int  j,
int  k,
int  r,
int  xSRin 
)

Definition at line 117 of file EmissionVetoHook1.cc.

References gather_cfg::cout, min(), pTdefMode, pTpowheg(), and pTpythia().

Referenced by doVetoFSREmission(), doVetoISREmission(), and doVetoMPIStep().

117  {
118 
119  // Loop over ISR and FSR if necessary
120  double pTemt = -1., pTnow;
121  int xSR1 = (xSRin == -1) ? 0 : xSRin;
122  int xSR2 = (xSRin == -1) ? 2 : xSRin + 1;
123  for (int xSR = xSR1; xSR < xSR2; xSR++) {
124  // FSR flag
125  bool FSR = (xSR == 0) ? false : true;
126 
127  // If all necessary arguments have been given, then directly calculate.
128  // POWHEG ISR and FSR, need i and j.
129  if ((pTdefMode == 0 || pTdefMode == 1) && i > 0 && j > 0) {
130  pTemt = pTpowheg(e, i, j, (pTdefMode == 0) ? false : FSR);
131 
132  // Pythia ISR, need i, j and r.
133  } else if (!FSR && pTdefMode == 2 && i > 0 && j > 0 && r > 0) {
134  pTemt = pTpythia(e, i, j, r, FSR);
135 
136  // Pythia FSR, need k, j and r.
137  } else if (FSR && pTdefMode == 2 && j > 0 && k > 0 && r > 0) {
138  pTemt = pTpythia(e, k, j, r, FSR);
139 
140  // Otherwise need to try all possible combintations.
141  } else {
142  // Start by finding incoming legs to the hard system after
143  // branching (radiator after branching, i for ISR).
144  // Use partonSystemsPtr to find incoming just prior to the
145  // branching and track mothers.
146  int iInA = partonSystemsPtr->getInA(0);
147  int iInB = partonSystemsPtr->getInB(0);
148  while (e[iInA].mother1() != 1) { iInA = e[iInA].mother1(); }
149  while (e[iInB].mother1() != 2) { iInB = e[iInB].mother1(); }
150 
151  // If we do not have j, then try all final-state partons
152  int jNow = (j > 0) ? j : 0;
153  int jMax = (j > 0) ? j + 1 : e.size();
154  for (; jNow < jMax; jNow++) {
155 
156  // Final-state and coloured jNow or photon only
157  if (!e[jNow].isFinal()) continue;
158  if (e[jNow].colType() == 0 && e[jNow].id() != 22) continue;
159 
160  // POWHEG
161  if (pTdefMode == 0 || pTdefMode == 1) {
162 
163  // ISR - only done once as just kinematical pT
164  if (!FSR) {
165  pTnow = pTpowheg(e, iInA, jNow, (pTdefMode == 0) ? false : FSR);
166  if (pTnow > 0.) pTemt = (pTemt < 0) ? pTnow : min(pTemt, pTnow);
167 
168  // FSR - try all outgoing partons from system before branching
169  // as i. Note that for the hard system, there is no
170  // "before branching" information.
171  } else {
172 
173  int outSize = partonSystemsPtr->sizeOut(0);
174  for (int iMem = 0; iMem < outSize; iMem++) {
175  int iNow = partonSystemsPtr->getOut(0, iMem);
176 
177  // Coloured only, i != jNow and no carbon copies
178  if (iNow == jNow || e[iNow].colType() == 0) continue;
179  if (jNow == e[iNow].daughter1()
180  && jNow == e[iNow].daughter2()) continue;
181 
182  pTnow = pTpowheg(e, iNow, jNow, (pTdefMode == 0)
183  ? false : FSR);
184  if (pTnow > 0.) pTemt = (pTemt < 0)
185  ? pTnow : min(pTemt, pTnow);
186  } // for (iMem)
187 
188  } // if (!FSR)
189 
190  // Pythia
191  } else if (pTdefMode == 2) {
192 
193  // ISR - other incoming as recoiler
194  if (!FSR) {
195  pTnow = pTpythia(e, iInA, jNow, iInB, FSR);
196  if (pTnow > 0.) pTemt = (pTemt < 0) ? pTnow : min(pTemt, pTnow);
197  pTnow = pTpythia(e, iInB, jNow, iInA, FSR);
198  if (pTnow > 0.) pTemt = (pTemt < 0) ? pTnow : min(pTemt, pTnow);
199 
200  // FSR - try all final-state coloured partons as radiator
201  // after emission (k).
202  } else {
203  for (int kNow = 0; kNow < e.size(); kNow++) {
204  if (kNow == jNow || !e[kNow].isFinal() ||
205  e[kNow].colType() == 0) continue;
206 
207  // For this kNow, need to have a recoiler.
208  // Try two incoming.
209  pTnow = pTpythia(e, kNow, jNow, iInA, FSR);
210  if (pTnow > 0.) pTemt = (pTemt < 0)
211  ? pTnow : min(pTemt, pTnow);
212  pTnow = pTpythia(e, kNow, jNow, iInB, FSR);
213  if (pTnow > 0.) pTemt = (pTemt < 0)
214  ? pTnow : min(pTemt, pTnow);
215 
216  // Try all other outgoing.
217  for (int rNow = 0; rNow < e.size(); rNow++) {
218  if (rNow == kNow || rNow == jNow ||
219  !e[rNow].isFinal() || e[rNow].colType() == 0) continue;
220  pTnow = pTpythia(e, kNow, jNow, rNow, FSR);
221  if (pTnow > 0.) pTemt = (pTemt < 0)
222  ? pTnow : min(pTemt, pTnow);
223  } // for (rNow)
224 
225  } // for (kNow)
226  } // if (!FSR)
227  } // if (pTdefMode)
228  } // for (j)
229  }
230  } // for (xSR)
231 
232 #ifdef DBGOUTPUT
233  cout << "pTcalc: i = " << i << ", j = " << j << ", k = " << k
234  << ", r = " << r << ", xSR = " << xSRin
235  << ", pTemt = " << pTemt << endl;
236 #endif
237 
238  return pTemt;
239 }
int i
Definition: DBlmapReader.cc:9
int j
Definition: DBlmapReader.cc:9
T min(T a, T b)
Definition: MathUtil.h:58
double pTpowheg(const Pythia8::Event &e, int i, int j, bool FSR)
double pTpythia(const Pythia8::Event &e, int RadAfterBranch, int EmtAfterBranch, int RecAfterBranch, bool FSR)
tuple cout
Definition: gather_cfg.py:121
double EmissionVetoHook1::pTpowheg ( const Pythia8::Event &  e,
int  i,
int  j,
bool  FSR 
)

Definition at line 74 of file EmissionVetoHook1.cc.

References gather_cfg::cout, alignCSCRings::e, j, AlCaHLTBitMon_ParallelJobs::p, and mathSSE::sqrt().

Referenced by pTcalc().

74  {
75 
76  // pT value for FSR and ISR
77  double pTnow = 0.;
78  if (FSR) {
79  // POWHEG d_ij (in CM frame). Note that the incoming beams have not
80  // been updated in the parton systems pointer yet (i.e. prior to any
81  // potential recoil).
82  int iInA = partonSystemsPtr->getInA(0);
83  int iInB = partonSystemsPtr->getInB(0);
84  double betaZ = - ( e[iInA].pz() + e[iInB].pz() ) /
85  ( e[iInA].e() + e[iInB].e() );
86  Pythia8::Vec4 iVecBst(e[i].p()), jVecBst(e[j].p());
87  iVecBst.bst(0., 0., betaZ);
88  jVecBst.bst(0., 0., betaZ);
89  pTnow = sqrt( (iVecBst + jVecBst).m2Calc() *
90  iVecBst.e() * jVecBst.e() /
91  Pythia8::pow2(iVecBst.e() + jVecBst.e()) );
92 
93  } else {
94  // POWHEG pT_ISR is just kinematic pT
95  pTnow = e[j].pT();
96  }
97 
98  // Check result
99  if (pTnow < 0.) {
100  cout << "Warning: pTpowheg was negative" << endl;
101  return -1.;
102  }
103 
104 #ifdef DBGOUTPUT
105  cout << "pTpowheg: i = " << i << ", j = " << j
106  << ", pTnow = " << pTnow << endl;
107 #endif
108 
109  return pTnow;
110 }
int i
Definition: DBlmapReader.cc:9
ExtVec< T, 4 > Vec4
Definition: ExtVec.h:49
T sqrt(T t)
Definition: SSEVec.h:48
int j
Definition: DBlmapReader.cc:9
tuple cout
Definition: gather_cfg.py:121
double EmissionVetoHook1::pTpythia ( const Pythia8::Event &  e,
int  RadAfterBranch,
int  EmtAfterBranch,
int  RecAfterBranch,
bool  FSR 
)

Definition at line 17 of file EmissionVetoHook1.cc.

References funct::abs(), gather_cfg::cout, class-composition::Q, jetcorrextractor::sign(), mathSSE::sqrt(), and detailsBasic3DVector::z.

Referenced by pTcalc().

18  {
19 
20  // Convenient shorthands for later
21  Pythia8::Vec4 radVec = e[RadAfterBranch].p();
22  Pythia8::Vec4 emtVec = e[EmtAfterBranch].p();
23  Pythia8::Vec4 recVec = e[RecAfterBranch].p();
24  int radID = e[RadAfterBranch].id();
25 
26  // Calculate virtuality of splitting
27  double sign = (FSR) ? 1. : -1.;
28  Pythia8::Vec4 Q(radVec + sign * emtVec);
29  double Qsq = sign * Q.m2Calc();
30 
31  // Mass term of radiator
32  double m2Rad = (abs(radID) >= 4 && abs(radID) < 7) ?
33  Pythia8::pow2(particleDataPtr->m0(radID)) : 0.;
34 
35  // z values for FSR and ISR
36  double z, pTnow;
37  if (FSR) {
38  // Construct 2 -> 3 variables
39  Pythia8::Vec4 sum = radVec + recVec + emtVec;
40  double m2Dip = sum.m2Calc();
41  double x1 = 2. * (sum * radVec) / m2Dip;
42  double x3 = 2. * (sum * emtVec) / m2Dip;
43  z = x1 / (x1 + x3);
44  pTnow = z * (1. - z);
45 
46  } else {
47  // Construct dipoles before/after splitting
48  Pythia8::Vec4 qBR(radVec - emtVec + recVec);
49  Pythia8::Vec4 qAR(radVec + recVec);
50  z = qBR.m2Calc() / qAR.m2Calc();
51  pTnow = (1. - z);
52  }
53 
54  // Virtuality with correct sign
55  pTnow *= (Qsq - sign * m2Rad);
56 
57  // Can get negative pT for massive splittings
58  if (pTnow < 0.) {
59  cout << "Warning: pTpythia was negative" << endl;
60  return -1.;
61  }
62 
63 #ifdef DBGOUTPUT
64  cout << "pTpythia: rad = " << RadAfterBranch << ", emt = "
65  << EmtAfterBranch << ", rec = " << RecAfterBranch
66  << ", pTnow = " << sqrt(pTnow) << endl;
67 #endif
68 
69  // Return pT
70  return sqrt(pTnow);
71 }
ExtVec< T, 4 > Vec4
Definition: ExtVec.h:49
double sign(double x)
float float float z
T sqrt(T t)
Definition: SSEVec.h:48
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
tuple cout
Definition: gather_cfg.py:121

Member Data Documentation

bool EmissionVetoHook1::accepted
private

Definition at line 53 of file EmissionVetoHook1.h.

Referenced by doVetoFSREmission(), doVetoISREmission(), and doVetoMPIStep().

int EmissionVetoHook1::emittedMode
private

Definition at line 49 of file EmissionVetoHook1.h.

Referenced by doVetoFSREmission().

int EmissionVetoHook1::MPIvetoOn
private

Definition at line 49 of file EmissionVetoHook1.h.

Referenced by canVetoMPIEmission(), doVetoMPIEmission(), and doVetoMPIStep().

int EmissionVetoHook1::nAcceptSeq
private

Definition at line 55 of file EmissionVetoHook1.h.

Referenced by doVetoFSREmission(), doVetoISREmission(), and doVetoMPIStep().

int EmissionVetoHook1::nFinal
private

Definition at line 51 of file EmissionVetoHook1.h.

Referenced by doVetoMPIStep().

int EmissionVetoHook1::nFinalExt
private

Definition at line 49 of file EmissionVetoHook1.h.

Referenced by doVetoMPIStep().

unsigned long int EmissionVetoHook1::nFSRveto
private

Definition at line 57 of file EmissionVetoHook1.h.

Referenced by doVetoFSREmission(), and ~EmissionVetoHook1().

unsigned long int EmissionVetoHook1::nISRveto
private

Definition at line 57 of file EmissionVetoHook1.h.

Referenced by doVetoISREmission(), and ~EmissionVetoHook1().

int EmissionVetoHook1::pTdefMode
private

Definition at line 49 of file EmissionVetoHook1.h.

Referenced by pTcalc().

int EmissionVetoHook1::pTemtMode
private

Definition at line 49 of file EmissionVetoHook1.h.

Referenced by doVetoFSREmission(), and doVetoISREmission().

double EmissionVetoHook1::pThard
private

Definition at line 52 of file EmissionVetoHook1.h.

Referenced by doVetoFSREmission(), doVetoISREmission(), and doVetoMPIStep().

int EmissionVetoHook1::pThardMode
private

Definition at line 49 of file EmissionVetoHook1.h.

Referenced by doVetoMPIStep().

double EmissionVetoHook1::pTMPI
private

Definition at line 52 of file EmissionVetoHook1.h.

Referenced by doVetoMPIEmission(), and doVetoMPIStep().

int EmissionVetoHook1::Verbosity
private

Definition at line 58 of file EmissionVetoHook1.h.

Referenced by doVetoMPIStep().

int EmissionVetoHook1::vetoCount
private

Definition at line 49 of file EmissionVetoHook1.h.

Referenced by doVetoFSREmission(), and doVetoISREmission().

int EmissionVetoHook1::vetoOn
private