KKMC Class Reference

#include <KKMC.h>

Inheritance diagram for KKMC:

Public Member Functions
	KKMC (const std::string &name, ISvcLocator *pSvcLocator)
StatusCode	initialize ()
StatusCode	execute ()
StatusCode	finalize ()

Detailed Description

Definition at line 18 of file KKMC.h.

Constructor & Destructor Documentation

KKMC()

KKMC::KKMC	(	const std::string &	name,
		ISvcLocator *	pSvcLocator )

Definition at line 106 of file KKMC.cxx.

                                                          : Algorithm(name, pSvcLocator)
{
  m_numberEvent = 0;
 
  m_kkseed.clear();
  m_kkseed.push_back(123456);
  m_kkseed.push_back(1);
  m_kkseed.push_back(0);
 
 
  declareProperty("NumberOfEventPrinted", m_numberEventPrint=100);
  declareProperty("InitializedSeed", m_kkseed);
  declareProperty("CMSEnergy", m_cmsEnergy = 3.773);
  declareProperty("ReadEcmsFromDB", m_ReadEcmsFromDB = false);
  declareProperty("BeamEnergySpread", m_cmsEnergySpread = 0.0013); //it should be beam energy spread,pingrg-2009-09-24
  declareProperty("GenerateResonance", m_generateResonance = true);
  declareProperty("GenerateContinuum", m_generateContinuum = true);
  declareProperty("GenerateDownQuark", m_generateDownQuark = true);
  declareProperty("GenerateUpQuark", m_generateUpQuark = true);
  declareProperty("GenerateStrangeQuark", m_generateStrangeQuark = true);
  declareProperty("GenerateCharmQuark", m_generateCharmQuark = true);
  declareProperty("GenerateBottomQuark", m_generateBottomQuark = false);
  declareProperty("GenerateMuonPair", m_generateMuonPair = true);
  declareProperty("GenerateTauPair", m_generateTauPair = true);
  declareProperty("GenerateRho", m_generateRho = true);
  declareProperty("GenerateOmega", m_generateOmega = true);
  declareProperty("GeneratePhi", m_generatePhi = true);
  declareProperty("GenerateJPsi", m_generateJPsi = true);
  declareProperty("GeneratePsiPrime", m_generatePsiPrime = true);
  declareProperty("GeneratePsi3770", m_generatePsi3770 = true);
  declareProperty("GeneratePsi4030", m_generatePsi4030 = true);
  declareProperty("GeneratePsi4160", m_generatePsi4160 = true);
  declareProperty("GeneratePsi4415", m_generatePsi4415 = true);
  declareProperty("GeneratePsi4260", m_generatePsi4260 = true);
  declareProperty("ThresholdCut", m_DdbarCutPsi3770 = -3.0); //generate DDbar decay, pingrg-2009-10-14
  declareProperty("TagISR", m_isrtag = false);               //Tag ISR photon, false: ID=22, true: ID=-22, pingrg-2010-6-30
  declareProperty("TagFSR", m_fsrtag = false);               //Tag FSR photon, false: ID=22, true: ID=-22, pingrg-2010-6-30
  declareProperty("ModeIndexExpXS", m_ich = -10);  //mode index using the measured cross section  
 
  m_paramRho.clear(); m_paramRho.push_back(0.77457e0); m_paramRho.push_back(147.65e-3); m_paramRho.push_back(6.89e-6);
  m_paramRh2.clear(); m_paramRh2.push_back(1.465e0); m_paramRh2.push_back(310e-3); m_paramRh2.push_back(0.0e-6);
  m_paramRh3.clear(); m_paramRh3.push_back(1.700e0); m_paramRh3.push_back(240e-3); m_paramRh3.push_back(0.0e-6);
  m_paramOme.clear(); m_paramOme.push_back(0.78194e0);m_paramOme.push_back(8.41e-3);m_paramOme.push_back(0.60e-6);
  m_paramOm2.clear(); m_paramOm2.push_back(1.419e0);m_paramOm2.push_back(174e-3);m_paramOm2.push_back(0.00e-6);
  m_paramOm3.clear(); m_paramOm3.push_back(1.649e0);m_paramOm3.push_back(220e-3);m_paramOm3.push_back(0.00e-6);
  m_paramPhi.clear(); m_paramPhi.push_back(1.01942e0);m_paramPhi.push_back(4.46e-3);m_paramPhi.push_back(1.33e-6);
  m_paramPh2.clear(); m_paramPh2.push_back(1.680e0);m_paramPh2.push_back(150e-3);m_paramPh2.push_back(0.00e-6);
  m_paramPsi.clear(); m_paramPsi.push_back(3.096916e0);m_paramPsi.push_back(0.0929e-3);m_paramPsi.push_back(5.40e-6);
  m_paramPs2.clear(); m_paramPs2.push_back(3.686109e0);m_paramPs2.push_back(0.304e-3);m_paramPs2.push_back(2.12e-6);
  m_paramPs3.clear(); m_paramPs3.push_back(3.77315e0);m_paramPs3.push_back(27.2e-3);m_paramPs3.push_back(0.26e-6);
  m_paramPs4.clear(); m_paramPs4.push_back(4.039e0);m_paramPs4.push_back(80e-3);m_paramPs4.push_back(0.86e-6);
  m_paramPs5.clear(); m_paramPs5.push_back(4.153e0);m_paramPs5.push_back(103e-3);m_paramPs5.push_back(0.83e-6);
  m_paramPs6.clear(); m_paramPs6.push_back(4.421e0);m_paramPs6.push_back(62e-3);m_paramPs6.push_back(0.58e-6);
  m_paramPs7.clear(); m_paramPs7.push_back(4.263e0);m_paramPs7.push_back(95e-3);m_paramPs7.push_back(0.47e-6); 
  m_paramPs8.clear(); m_paramPs8.push_back(3.872e0);m_paramPs8.push_back(100e-3);m_paramPs8.push_back(0.00e-6);
  m_paramUps.clear(); m_paramUps.push_back(9.46030e0); m_paramUps.push_back(0.0525e-3); m_paramUps.push_back(1.32e-6);
  m_paramUp2.clear(); m_paramUp2.push_back(10.02326e0); m_paramUp2.push_back(0.044e-3); m_paramUp2.push_back(0.52e-6);
  m_paramUp3.clear(); m_paramUp3.push_back(10.3552e0); m_paramUp3.push_back(0.026e-3); m_paramUp3.push_back(0.00e-6);
  m_paramUp4.clear(); m_paramUp4.push_back(10.580e0); m_paramUp4.push_back(14e-3); m_paramUp4.push_back(0.248e-6);
  m_paramUp5.clear(); m_paramUp5.push_back(10.865e0); m_paramUp5.push_back(110e-3); m_paramUp5.push_back(0.31e-6);
  m_paramUp6.clear(); m_paramUp6.push_back(11.019); m_paramUp6.push_back(79e-3); m_paramUp6.push_back(0.13e-6);
  m_paramZeta.clear(); m_paramZeta.push_back(91.1876e0); m_paramZeta.push_back(2.4952e0); m_paramZeta.push_back(0.08391e0);
  m_paramW.clear(); m_paramW.push_back(80.43); m_paramW.push_back(2.11e0);
 
  declareProperty("ResParameterRho", m_paramRho);
  declareProperty("ResParameterRh2", m_paramRh2);
  declareProperty("ResParameterRh3", m_paramRh3);
  declareProperty("ResParameterOme", m_paramOme);
  declareProperty("ResParameterOm2", m_paramOm2);
  declareProperty("ResParameterOm3", m_paramOm3);
  declareProperty("ResParameterPhi", m_paramPhi); 
  declareProperty("ResParameterPh2", m_paramPh2);
  declareProperty("ResParameterPsi", m_paramPsi);
  declareProperty("ResParameterPs2", m_paramPs2);
  declareProperty("ResParameterPs3", m_paramPs3);
  declareProperty("ResParameterPs4", m_paramPs4);
  declareProperty("ResParameterPs5", m_paramPs5);
  declareProperty("ResParameterPs6", m_paramPs6);
  declareProperty("ResParameterPs7", m_paramPs7);  
  declareProperty("ResParameterPs8", m_paramPs8);
  declareProperty("ResParameterUps", m_paramUps);
  declareProperty("ResParameterUp2", m_paramUp2);
  declareProperty("ResParameterUp3", m_paramUp3);
  declareProperty("ResParameterUp4", m_paramUp4);
  declareProperty("ResParameterUp5", m_paramUp5);
  declareProperty("ResParameterUp6", m_paramUp6);
  declareProperty("ResParameterZeta", m_paramZeta);
  declareProperty("ResParameterW", m_paramW);
 
  // psi(3770) decay
  declareProperty("Psi3770toNonDDb", m_ps3toNonDDb = 0.0);
  declareProperty("Psi3770RatioOfD0toDp", m_ps3D0toDp = 0.563);
  // psi(4030) decay
  declareProperty("Psi4030toD0D0b", m_ps4toD0D0b = 0.0227);
  declareProperty("Psi4030toDpDm", m_ps4toDpDm = 0.0167);
  declareProperty("Psi4030toDsDs", m_ps4toDsDs = 0.0383);
  declareProperty("Psi4030toD0D0Star", m_ps4toD0D0Star = 0.2952);
  declareProperty("Psi4030toDpDmStar", m_ps4toDpDmStar = 0.2764);
  declareProperty("Psi4030toD0StarD0Star", m_ps4toD0StarD0Star=0.2476);
  declareProperty("Psi4030toDpStarDmStar", m_ps4toDpStarDmStar=0.1041);
  // psi(4160) decay
  declareProperty("Psi4160toD0D0b", m_ps5toD0D0b = 0.0190);
  declareProperty("Psi4160toDpDm", m_ps5toDpDm = 0.0180);
  declareProperty("Psi4160toDsDs", m_ps5toDsDs = 0.0488);
  declareProperty("Psi4160toD0D0Star", m_ps5toD0D0Star = 0.1248);
  declareProperty("Psi4160toDpDmStar", m_ps5toDpDmStar = 0.1240);
  declareProperty("Psi4160toDsDsStar", m_ps5toDsDsStar = 0.0820);
  declareProperty("Psi4160toD0StarD0Star", m_ps5toD0StarD0Star=0.3036);
  declareProperty("Psi4160toDpStarDmStar", m_ps5toDpStarDmStar=0.2838);
  // interface to EvtGen
  declareProperty("ParticleDecayThroughEvtGen", m_evtGenDecay = true);
  declareProperty("RadiationCorrection", m_radiationCorrection = true);
  //interface set pythia pars
  m_pypars.clear();
  declareProperty("setPythiaPars", m_pypars);
}

Member Function Documentation

execute()

StatusCode KKMC::execute

(

)

Definition at line 432 of file KKMC.cxx.

                         {
  SmartDataPtr<Event::EventHeader> eventHeader(eventSvc(),"/Event/EventHeader");
   int runNo=eventHeader->runNumber();
   int event=eventHeader->eventNumber();
   bool newRunFlag=0;
   if(runNo != 0 && runNo != m_runNo){m_runNo=runNo;newRunFlag = true;}else{newRunFlag=false;}
 
   //std::cout<<"runNo= "<<runNo<<" m_runNo "<<m_runNo<<" newRunFlag= "<<newRunFlag<<std::endl;
 
   if(m_ReadEcmsFromDB && newRunFlag){// using cms energy of beam read from database
    runNo = std::abs(runNo);
    ReadEb theEb(runNo);
    double dbEcms = theEb.getEcms();
    double dbXangle = theEb.getXangle();
    m_cmsEnergy = dbEcms; //*cos(dbXangle); //here the dbEcms is the enegy in the center-mass system of psi"
    std::cout<<"The beam energy is "<<dbEcms<<", set for RunNo "<<runNo<<std::endl;
    xwpar[0] = m_cmsEnergy; 
    KK2F_INITIALIZE(xwpar);
   }
  MsgStream log(msgSvc(), name());
  
  log << MSG::INFO << "KKMC in execute()" << endreq;
 
 
  HepMC::IO_HEPEVT HepEvtIO;
 
 
  int KeySkip,iflag;
  do {
    HEPEVT_CLEAN();
    KK2F_MAKE();
    KK2F_GETKEYSKIP(KeySkip);
    PSIPP_DDBARCUT(iflag);
  } while (KeySkip != 0 || iflag ==0);
 
  int KeyInter;
  KK2F_GETEVTGENINTERFACE(KeyInter);
 
  //  PSIPP_DDBARCUT(iflag);
  //  if(iflag == 0)  {return StatusCode::SUCCESS;}
 
  if(KeyInter == 0) {  // make photos correction
    int Pos1, Pos2, KFfin, Nhep;
    HEPEVT_NUMHEP(Nhep);
    HEPEVT_GETF(Pos1);
    HEPEVT_GETFBAR(Pos2);
    HEPEVT_GETKFFIN(KFfin);
    int Posn = Pos1;
    if(Pos2 > Posn) Posn = Pos2;
    Posn = Posn + 1;
    if(KFfin < 10) Posn = Posn + 1;
    for(int ip = Posn; ip <= Nhep; ip++) HEPEVT_SETPHOTOSFLAGTRUE(ip);
    for(int ip = Posn; ip <= Nhep; ip++) PHOTOS(ip);
    PYHEPC(2);
  }
 
  //sleep(5);
 
  m_numberEvent += 1;
 
  if(m_numberEvent <= m_numberEventPrint) PYLIST(1);
  log << MSG::INFO <<"  " <<m_numberEvent<<"th event was generated !!" <<endreq;
  
  PYHEPC(1);
 
  HepMC::GenEvent* evt = HepEvtIO.read_next_event();
  evt->set_event_number(m_numberEvent);
  evt->set_signal_process_id(1);
  //  evt->print();
 
  // Check if the McCollection already exists
  SmartDataPtr<McGenEventCol> anMcCol(eventSvc(), "/Event/Gen");
  if (anMcCol!=0) {
    // Add event to existing collection
    MsgStream log(messageService(), name());
    log << MSG::INFO << "Add McGenEvent to existing collection" << endreq;
    McGenEvent* mcEvent = new McGenEvent(evt);
    anMcCol->push_back(mcEvent);
  }  else {
    // Create Collection and add  to the transient store
    McGenEventCol *mcColl = new McGenEventCol;
    McGenEvent* mcEvent = new McGenEvent(evt);
    mcColl->push_back(mcEvent);
    StatusCode sc = eventSvc()->registerObject("/Event/Gen",mcColl);
    if (sc != StatusCode::SUCCESS) {
      log << MSG::ERROR << "Could not register McGenEvent" << endreq;
      delete mcColl;
      delete evt;
      delete mcEvent;
      return StatusCode::FAILURE;
    }  else {
      //      log << MSG::INFO << "McGenEventCol created and " << npart <<" particles stored in McGenEvent" << endreq;
    }
  }
  
 
 
 
 return StatusCode::SUCCESS;
 
}

finalize()

StatusCode KKMC::finalize

(

)

Definition at line 534 of file KKMC.cxx.

                          {
 
  MsgStream log(msgSvc(), name());
  
  log << MSG::INFO << "KKMC in finalize()" << endreq;
 
  KK2F_FINALIZE();
  double xSecPb, xErrPb;
  KK2F_GETXSECMC(xSecPb, xErrPb);
 
  log << MSG::INFO << "Total MC Xsec = " << xSecPb << " +/- " << xErrPb << endreq;
  return StatusCode::SUCCESS;
}

initialize()

StatusCode KKMC::initialize

(

)

Definition at line 223 of file KKMC.cxx.

                            {
 
  MsgStream log(msgSvc(), name());
  
  log << MSG::INFO << "KKMC in initialize()" << endreq;
 
  //set Bes unified random engine
  static const bool CREATEIFNOTTHERE(true);
  StatusCode RndmStatus = service("BesRndmGenSvc", p_BesRndmGenSvc, CREATEIFNOTTHERE);
  if (!RndmStatus.isSuccess() || 0 == p_BesRndmGenSvc)
  {
    log << MSG::ERROR << " Could not initialize Random Number Service" << endreq;
    return RndmStatus;
  }
  CLHEP::HepRandomEngine* engine  = p_BesRndmGenSvc->GetEngine("KKMC");
  KKMCRandom::setRandomEngine(engine);
  //--- 
  if(m_ich == -2 || m_ich>=50 ) {// ISR exclusive default set particle as Psi(4260)
    m_generatePsi4260 = true;
    m_generateJPsi = 0;
    m_generatePsiPrime = 0;
    m_generatePsi3770 = 0;
    m_generatePsi4030 = 0;
    m_generatePsi4160 = 0;
    m_generatePsi4415 = 0;
  }
 
  WHYM_SETDEF(xwpar);
  xwpar[0] = m_cmsEnergy;        // c.m.s energy
  xwpar[1] = m_cmsEnergySpread;  // energy spread of c.m.s.
  xwpar[3] = 6.0;                // fortran output unit
 
  if(m_generateResonance)   // flag indicate to generate Resonance data
    xwpar[12] = 1.0;
  else
    xwpar[12] = 0.0;
 
  if(m_generateContinuum )   // generate continuum
    xwpar[3000] = 1.0;
  else
    xwpar[3000] = 0.0;
  
  if(m_generateDownQuark)         // d quark production
    xwpar[400] = 1.0;
  else
    xwpar[400] = 0.0;
 
  if(m_generateUpQuark)         // u quark production
    xwpar[401] = 1.0;
  else
    xwpar[401] = 0.0;
 
  if(m_generateStrangeQuark)         // s quark production
    xwpar[402] = 1.0;
  else
    xwpar[402] = 0.0;
 
  if(m_generateCharmQuark)         // c quark production
    xwpar[403] = 1.0;
  else
    xwpar[403] = 0.0;
 
  if(m_generateBottomQuark)         // b quark production
    xwpar[404] = 1.0;
  else
    xwpar[404] = 0.0;
 
 
  if(m_generateMuonPair)     // e+ e- --> mu+ mu- 
    xwpar[412] = 1.0;
  else
    xwpar[412] = 0.0; 
 
  if(m_generateTauPair)      // e+ e- --> tau+ tau-
    xwpar[414] = 1.0;
  else
    xwpar[414] = 0.0;
  int keyuds = 0;
  if(m_generateRho)     keyuds |= 1;
  if(m_generateOmega)   keyuds |= 2;
  if(m_generatePhi)     keyuds |= 4;
  
  int keycharm = 0;
  if(m_generateJPsi)     keycharm |=  1;
  if(m_generatePsiPrime) keycharm |=  2;
  if(m_generatePsi3770)  keycharm |=  4;
  if(m_generatePsi4030)  keycharm |=  8;
  if(m_generatePsi4160)  keycharm |= 16;
  if(m_generatePsi4415)  keycharm |= 32;
  if(m_generatePsi4260)  keycharm |= 64;
 
  // resonant parameters 
  int offset = 3100;
  for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramRho[i];
  offset = offset + 3;
  for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramRh2[i];
  offset = offset + 3;
  for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramRh3[i];
  offset = offset + 3;
  for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramOme[i];
  offset = offset + 3;
  for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramOm2[i];
  offset = offset + 3;
  for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramOm3[i];
  offset = offset + 3;
  for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramPhi[i];
  offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramPh2[i];
 offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramPsi[i];
 offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramPs2[i];
 offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramPs3[i];
 offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramPs4[i];
 offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramPs5[i];
 offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramPs6[i];
 offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramPs7[i];
 offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramPs8[i];
 offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramUps[i];
 offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramUp2[i];
 offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramUp3[i];
 offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramUp4[i];
 offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramUp5[i];
 offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramUp6[i];
 offset = offset + 3;
 for(int i = 0; i < 3; i++) xwpar[offset+i] = m_paramZeta[i];
 offset = offset + 3;
 for(int i = 0; i < 2; i++) xwpar[offset+i] = m_paramW[i];
 // offset = offset + 2;
 
  xwpar[3001] = keyuds + 0.0;
  xwpar[3002] = keycharm + 0.0;
  
  // psi(3770) decay
  offset = 3200;
  xwpar[offset + 0] = m_ps3toNonDDb;
  xwpar[offset + 1] = m_ps3D0toDp;
  DDBARMASS.ddbarmassCUT= m_DdbarCutPsi3770;
  MODEXS.ich = m_ich;
  //tag ISR or FSR photon
  if(m_isrtag){PHOTONTAG.isrtag=1;} else {PHOTONTAG.isrtag=0;}
  if(m_fsrtag){PHOTONTAG.fsrtag=1;} else {PHOTONTAG.fsrtag=0;}
 
  // psi(4030) decay
  offset = 3210;
  xwpar[offset + 0] = m_ps4toD0D0b;
  xwpar[offset + 1] = m_ps4toDpDm;
  xwpar[offset + 2] = m_ps4toDsDs;
  xwpar[offset + 3] = m_ps4toD0D0Star;
  xwpar[offset + 4] = m_ps4toDpDmStar;
  xwpar[offset + 5] = m_ps4toD0StarD0Star;
  xwpar[offset + 6] = m_ps4toDpStarDmStar;
  // psi(4160) decay
  offset = 3220;
  xwpar[offset + 0] = m_ps5toD0D0b;
  xwpar[offset + 1] = m_ps5toDpDm;
  xwpar[offset + 2] = m_ps5toDsDs;
  xwpar[offset + 3] = m_ps5toD0D0Star;
  xwpar[offset + 4] = m_ps5toDpDmStar;
  xwpar[offset + 5] = m_ps5toDsDsStar;
  xwpar[offset + 6] = m_ps5toD0StarD0Star;
  xwpar[offset + 7] = m_ps5toDpStarDmStar;
 
  if(!m_radiationCorrection) {
    xwpar[19] = 0;
    xwpar[20] = 0;
    xwpar[26] = 0;
  }
 
 
  KK2F_INITIALIZE(xwpar);
  MY_PYUPD();
  PYUPDA(1, 22);
  //for pythia parameter tunning,pingrg-2013-6-9
  for(int i=0;i<m_pypars.size();i++){
    pygive_(m_pypars[i].c_str(),strlen(m_pypars[i].c_str()));
  }
 
  if(m_evtGenDecay) {
    KK2F_SETEVTGENINTERFACE(1);
    TURNOFFTAUDECAY();
  } else {
    KK2F_SETEVTGENINTERFACE(0);
    PHOINI();
  }
 
  HepMC::HEPEVT_Wrapper::set_sizeof_real(8);
  HepMC::HEPEVT_Wrapper::set_sizeof_int(4);
  HepMC::HEPEVT_Wrapper::set_max_number_entries(4000);
  //  std::cout << "max entries = " << HepMC::HEPEVT_Wrapper::max_number_entries() <<std::endl;
  //  std::cout << "size of real = " << HepMC::HEPEVT_Wrapper::sizeof_real() <<std::endl;
              
 
  log <<MSG::INFO<< "Finish KKMC initialize()" <<endreq;
  return StatusCode::SUCCESS;
}

---

The documentation for this class was generated from the following files:

• KKMC.h
• KKMC.cxx