//------------------------------------------------------------
- //Begin_Html
- /*
+//Begin_Html
+/*
<img src="picts/AliGenParam.gif">
- */
- //End_Html
+*/
+//End_Html
//____________________________________________________________
- AliGenParam::AliGenParam():
- fPtParaFunc(0),
+AliGenParam::AliGenParam()
+: fPtParaFunc(0),
fYParaFunc(0),
fIpParaFunc(0),
+ fV2ParaFunc(0),
fPtPara(0),
fYPara(0),
+ fV2Para(0),
+ fdNdPhi(0),
fParam(0),
fdNdy0(0.),
fYWgt(0.),
fTrials(0),
fDeltaPt(0.01),
fSelectAll(kFALSE),
- fDecayer(0)
+ fDecayer(0),
+ fForceConv(kFALSE)
{
-// Default constructor
+ // Default constructor
}
//____________________________________________________________
AliGenParam::AliGenParam(Int_t npart, const AliGenLib * Library, Int_t param, const char* tname)
fPtParaFunc(Library->GetPt(param, tname)),
fYParaFunc (Library->GetY (param, tname)),
fIpParaFunc(Library->GetIp(param, tname)),
+ fV2ParaFunc(Library->GetV2(param, tname)),
fPtPara(0),
fYPara(0),
+ fV2Para(0),
+ fdNdPhi(0),
fParam(param),
fdNdy0(0.),
fYWgt(0.),
fTrials(0),
fDeltaPt(0.01),
fSelectAll(kFALSE),
- fDecayer(0)
+ fDecayer(0),
+ fForceConv(kFALSE)
{
-// Constructor using number of particles parameterisation id and library
+ // Constructor using number of particles parameterisation id and library
fName = "Param";
fTitle= "Particle Generator using pT and y parameterisation";
fAnalog = kAnalog;
fPtParaFunc(0),
fYParaFunc (0),
fIpParaFunc(0),
+ fV2ParaFunc(0),
fPtPara(0),
fYPara(0),
+ fV2Para(0),
+ fdNdPhi(0),
fParam(param),
fdNdy0(0.),
fYWgt(0.),
fTrials(0),
fDeltaPt(0.01),
fSelectAll(kFALSE),
- fDecayer(0)
+ fDecayer(0),
+ fForceConv(kFALSE)
{
-// Constructor using parameterisation id and number of particles
-//
+ // Constructor using parameterisation id and number of particles
+ //
fName = name;
fTitle= "Particle Generator using pT and y parameterisation";
fPtParaFunc = pLibrary->GetPt(param, tname);
fYParaFunc = pLibrary->GetY (param, tname);
fIpParaFunc = pLibrary->GetIp(param, tname);
+ fV2ParaFunc = pLibrary->GetV2(param, tname);
fAnalog = kAnalog;
fChildSelect.Set(5);
AliGenParam::AliGenParam(Int_t npart, Int_t param,
Double_t (*PtPara) (const Double_t*, const Double_t*),
Double_t (*YPara ) (const Double_t* ,const Double_t*),
+ Double_t (*V2Para) (const Double_t* ,const Double_t*),
Int_t (*IpPara) (TRandom *))
:AliGenMC(npart),
fPtParaFunc(PtPara),
fYParaFunc(YPara),
fIpParaFunc(IpPara),
+ fV2ParaFunc(V2Para),
fPtPara(0),
fYPara(0),
+ fV2Para(0),
+ fdNdPhi(0),
fParam(param),
fdNdy0(0.),
fYWgt(0.),
fTrials(0),
fDeltaPt(0.01),
fSelectAll(kFALSE),
- fDecayer(0)
+ fDecayer(0),
+ fForceConv(kFALSE)
{
-// Constructor
-// Gines Martinez 1/10/99
+ // Constructor
+ // Gines Martinez 1/10/99
fName = "Param";
fTitle= "Particle Generator using pT and y parameterisation";
//____________________________________________________________
AliGenParam::~AliGenParam()
{
-// Destructor
+ // Destructor
delete fPtPara;
delete fYPara;
+ delete fV2Para;
+ delete fdNdPhi;
+}
+
+//-------------------------------------------------------------------
+TVector3 AliGenParam::OrthogonalVector(TVector3 &inVec){
+ double abc[]={inVec.x(), inVec.y(), inVec.z()};
+ double xyz[]={1,1,1};
+ int solvDim=0;
+ double tmp=abc[0];
+ for(int i=0; i<3; i++)
+ if(abs(abc[i])>tmp){
+ solvDim=i;
+ tmp=abs(abc[i]);
+ }
+ xyz[solvDim]=(-abc[(1+solvDim)%3]-abc[(2+solvDim)%3])/abc[(0+solvDim)%3];
+
+ TVector3 res(xyz[0],xyz[1],xyz[2]);
+ return res;
+}
+
+void AliGenParam::RotateVector(Double_t *pin, Double_t *pout, Double_t costheta, Double_t sintheta,
+ Double_t cosphi, Double_t sinphi)
+{
+ // Perform rotation
+ pout[0] = pin[0]*costheta*cosphi-pin[1]*sinphi+pin[2]*sintheta*cosphi;
+ pout[1] = pin[0]*costheta*sinphi+pin[1]*cosphi+pin[2]*sintheta*sinphi;
+ pout[2] = -1.0 * pin[0] * sintheta + pin[2] * costheta;
+ return;
+}
+
+Double_t AliGenParam::IntegratedKrollWada(Double_t mh){
+ if(mh<0.003) return 0;
+ return 2*log(mh/0.000511/exp(7.0/4.0))/411.0/TMath::Pi();
+}
+
+double AliGenParam::ScreenFunction1(double screenVariable){
+ if(screenVariable>1)
+ return 42.24 - 8.368 * log(screenVariable + 0.952);
+ else
+ return 42.392 - screenVariable * (7.796 - 1.961 * screenVariable);
+}
+
+double AliGenParam::ScreenFunction2(double screenVariable){
+ if(screenVariable>1)
+ return 42.24 - 8.368 * log(screenVariable + 0.952);
+ else
+ return 41.405 - screenVariable * (5.828 - 0.8945 * screenVariable);
+}
+
+double AliGenParam::RandomEnergyFraction(double Z, double photonEnergy){
+ double aZ=Z/137.036;
+ double epsilon ;
+ double epsilon0Local = 0.000511 / photonEnergy ;
+
+ // Do it fast if photon energy < 2. MeV
+ if (photonEnergy < 0.002 )
+ {
+ epsilon = epsilon0Local + (0.5 - epsilon0Local) * fRandom->Rndm();
+ }
+ else
+ {
+ double fZ = 8*log(Z)/3;
+ double fcZ=(aZ*aZ)*(1/(1+aZ*aZ)+0.20206-0.0368*aZ*aZ+0.0083*aZ*aZ*aZ);
+ if (photonEnergy > 0.050) fZ += 8*fcZ;
+
+ // Limits of the screening variable
+ double screenFactor = 136. * epsilon0Local / pow (Z,1/3);
+ double screenMax = exp ((42.24 - fZ)/8.368) - 0.952 ;
+ double screenMin = std::min(4.*screenFactor,screenMax) ;
+
+ // Limits of the energy sampling
+ double epsilon1 = 0.5 - 0.5 * sqrt(1. - screenMin / screenMax) ;
+ double epsilonMin = std::max(epsilon0Local,epsilon1);
+ double epsilonRange = 0.5 - epsilonMin ;
+
+ // Sample the energy rate of the created electron (or positron)
+ double screen;
+ double gReject ;
+
+ double f10 = ScreenFunction1(screenMin) - fZ;
+ double f20 = ScreenFunction2(screenMin) - fZ;
+ double normF1 = std::max(f10 * epsilonRange * epsilonRange,0.);
+ double normF2 = std::max(1.5 * f20,0.);
+
+ do
+ {
+ if (normF1 / (normF1 + normF2) > fRandom->Rndm() )
+ {
+ epsilon = 0.5 - epsilonRange * pow(fRandom->Rndm(), 0.333333) ;
+ screen = screenFactor / (epsilon * (1. - epsilon));
+ gReject = (ScreenFunction1(screen) - fZ) / f10 ;
+ }
+ else
+ {
+ epsilon = epsilonMin + epsilonRange * fRandom->Rndm();
+ screen = screenFactor / (epsilon * (1 - epsilon));
+ gReject = (ScreenFunction2(screen) - fZ) / f20 ;
+ }
+ } while ( gReject < fRandom->Rndm() );
+
+ } // End of epsilon sampling
+ return epsilon;
+}
+
+double AliGenParam::RandomPolarAngle(){
+ double u;
+ const double a1 = 0.625;
+ double a2 = 3. * a1;
+ // double d = 27. ;
+
+ // if (9. / (9. + d) > fRandom->Rndm())
+ if (0.25 > fRandom->Rndm())
+ {
+ u = - log(fRandom->Rndm() * fRandom->Rndm()) / a1 ;
+ }
+ else
+ {
+ u = - log(fRandom->Rndm() * fRandom->Rndm()) / a2 ;
+ }
+ return u*0.000511;
+}
+
+Double_t AliGenParam::RandomMass(Double_t mh){
+ while(true){
+ double y=fRandom->Rndm();
+ double mee=2*0.000511*TMath::Power(2*0.000511/mh,-y); //inverse of the enveloping cumulative distribution
+ double apxkw=2.0/3.0/137.036/TMath::Pi()/mee;
+ double val=fRandom->Uniform(0,apxkw); //enveloping probability density0
+ double kw=apxkw*sqrt(1-4*0.000511*0.000511/mee/mee)*(1+2*0.000511*0.000511/mee/mee)*1*1*TMath::Power(1-mee*mee/mh/mh,3);
+ if(val<kw)
+ return mee;
+ }
+}
+
+Int_t AliGenParam::VirtualGammaPairProduction(TClonesArray *particles, Int_t nPart)
+{
+ Int_t nPartNew=nPart;
+ for(int iPart=0; iPart<nPart; iPart++){
+ TParticle *gamma = (TParticle *) particles->At(iPart);
+ if(gamma->GetPdgCode()!=223000 || gamma->GetPdgCode()!=224000) continue;
+ //if(gamma->Energy()<0.001022) continue; //can never be
+ double mass=RandomMass(gamma->Pt());
+
+ // lepton pair kinematics in virtual photon rest frame
+ double Ee=mass/2;
+ double Pe=TMath::Sqrt((Ee+0.000511)*(Ee-0.000511));
+
+ double costheta = (2.0 * gRandom->Rndm()) - 1.;
+ double sintheta = TMath::Sqrt((1. + costheta) * (1. - costheta));
+ double phi = 2.0 * TMath::ACos(-1.) * gRandom->Rndm();
+ double sinphi = TMath::Sin(phi);
+ double cosphi = TMath::Cos(phi);
+
+ // momentum vectors of leptons in virtual photon rest frame
+ Double_t pProd1[3] = {Pe * sintheta * cosphi,
+ Pe * sintheta * sinphi,
+ Pe * costheta};
+
+ Double_t pProd2[3] = {-1.0 * Pe * sintheta * cosphi,
+ -1.0 * Pe * sintheta * sinphi,
+ -1.0 * Pe * costheta};
+
+ // lepton 4-vectors in properly rotated virtual photon rest frame
+ Double_t pRot1[3] = {0.};
+ RotateVector(pProd1, pRot1, costheta, -sintheta, -cosphi, -sinphi);
+ Double_t pRot2[3] = {0.};
+ RotateVector(pProd2, pRot2, costheta, -sintheta, -cosphi, -sinphi);
+
+ TLorentzVector e1V4(pRot1[0],pRot1[1],pRot1[2],Ee);
+ TLorentzVector e2V4(pRot2[0],pRot2[1],pRot2[2],Ee);
+
+ TVector3 boost(gamma->Px(),gamma->Py(),gamma->Pz());
+ boost*=1/sqrt(gamma->P()*gamma->P()+mass*mass);
+ e1V4.Boost(boost);
+ e2V4.Boost(boost);
+
+ TLorentzVector vtx;
+ gamma->ProductionVertex(vtx);
+ new((*particles)[nPartNew]) TParticle(11, gamma->GetStatusCode(), iPart+1, -1, 0, 0, e1V4, vtx);
+ nPartNew++;
+ new((*particles)[nPartNew]) TParticle(-11, gamma->GetStatusCode(), iPart+1, -1, 0, 0, e2V4, vtx);
+ nPartNew++;
+ }
+}
+
+Int_t AliGenParam::ForceGammaConversion(TClonesArray *particles, Int_t nPart)
+{
+ //based on: http://geant4.cern.ch/G4UsersDocuments/UsersGuides/PhysicsReferenceManual/html/node27.html
+ // and: http://geant4.cern.ch/G4UsersDocuments/UsersGuides/PhysicsReferenceManual/html/node58.html
+ // and: G4LivermoreGammaConversionModel.cc
+ Int_t nPartNew=nPart;
+ for(int iPart=0; iPart<nPart; iPart++){
+ TParticle *gamma = (TParticle *) particles->At(iPart);
+ if(gamma->GetPdgCode()!=22) continue;
+ if(gamma->Energy()<0.001022) continue;
+
+ TVector3 gammaV3(gamma->Px(),gamma->Py(),gamma->Pz());
+ double frac=RandomEnergyFraction(1,gamma->Energy());
+ double Ee1=frac*gamma->Energy();
+ double Ee2=(1-frac)*gamma->Energy();
+ double Pe1=sqrt((Ee1+0.000511)*(Ee1-0.000511));
+ double Pe2=sqrt((Ee2+0.000511)*(Ee2-0.000511));
+
+ TVector3 rotAxis(OrthogonalVector(gammaV3));
+ Float_t az=fRandom->Uniform(TMath::Pi()*2);
+ rotAxis.Rotate(az,gammaV3);
+ TVector3 e1V3(gammaV3);
+ double u=RandomPolarAngle();
+ e1V3.Rotate(u/Ee1,rotAxis);
+ e1V3=e1V3.Unit();
+ e1V3*=Pe1;
+ TVector3 e2V3(gammaV3);
+ e2V3.Rotate(-u/Ee2,rotAxis);
+ e2V3=e2V3.Unit();
+ e2V3*=Pe2;
+ // gamma = new TParticle(*gamma);
+ // particles->RemoveAt(iPart);
+ gamma->SetFirstDaughter(nPartNew+1);
+ gamma->SetLastDaughter(nPartNew+2);
+ // new((*particles)[iPart]) TParticle(*gamma);
+ // delete gamma;
+
+ TLorentzVector vtx;
+ gamma->ProductionVertex(vtx);
+ new((*particles)[nPartNew]) TParticle(11, gamma->GetStatusCode(), iPart+1, -1, 0, 0, TLorentzVector(e1V3,Ee1), vtx);
+ nPartNew++;
+ new((*particles)[nPartNew]) TParticle(-11, gamma->GetStatusCode(), iPart+1, -1, 0, 0, TLorentzVector(e2V3,Ee2), vtx);
+ nPartNew++;
+ }
+ // particles->Compress();
+ return particles->GetEntriesFast();
}
//____________________________________________________________
void AliGenParam::Init()
{
-// Initialisation
+ // Initialisation
if (gMC) fDecayer = gMC->GetDecayer();
//Begin_Html
if (fPtPara) fPtPara->Delete();
fPtPara = new TF1(name, fPtParaFunc, fPtMin, fPtMax,0);
gROOT->GetListOfFunctions()->Remove(fPtPara);
-// Set representation precision to 10 MeV
+ // Set representation precision to 10 MeV
Int_t npx= Int_t((fPtMax - fPtMin) / fDeltaPt);
fPtPara->SetNpx(npx);
fYPara = new TF1(name, fYParaFunc, fYMin, fYMax, 0);
gROOT->GetListOfFunctions()->Remove(fYPara);
+ snprintf(name, 256, "v2-parameterisation for %s", GetName());
+ if (fV2Para) fV2Para->Delete();
+ fV2Para = new TF1(name, fV2ParaFunc, fPtMin, fPtMax, 0);
+ // fV2Para = new TF1(name, "2*[0]/(1+TMath::Exp([1]*([2]-x)))-[0]", fPtMin, fPtMax);
+ // fV2Para->SetParameter(0, 0.236910);
+ // fV2Para->SetParameter(1, 1.71122);
+ // fV2Para->SetParameter(2, 0.0827617);
+ //gROOT->GetListOfFunctions()->Remove(fV2Para); //TR: necessary?
+
+ snprintf(name, 256, "dNdPhi for %s", GetName());
+ if (fdNdPhi) fdNdPhi->Delete();
+ fdNdPhi = new TF1(name, "1+2*[0]*TMath::Cos(2*(x-[1]))", fPhiMin, fPhiMax);
+ //gROOT->GetListOfFunctions()->Remove(fdNdPhi); //TR: necessary?
snprintf(name, 256, "pt-for-%s", GetName());
TF1 ptPara(name ,fPtParaFunc, 0, 15, 0);
snprintf(name, 256, "y-for-%s", GetName());
TF1 yPara(name, fYParaFunc, -6, 6, 0);
-//
-// dN/dy| y=0
+ //
+ // dN/dy| y=0
Double_t y1=0;
Double_t y2=0;
fdNdy0=fYParaFunc(&y1,&y2);
-//
-// Integral over generation region
+ //
+ // Integral over generation region
+#if ROOT_VERSION_CODE < ROOT_VERSION(5,99,0)
Float_t intYS = yPara.Integral(fYMin, fYMax,(Double_t*) 0x0,1.e-6);
Float_t intPt0 = ptPara.Integral(0,15,(Double_t *) 0x0,1.e-6);
Float_t intPtS = ptPara.Integral(fPtMin,fPtMax,(Double_t*) 0x0,1.e-6);
- Float_t phiWgt=(fPhiMax-fPhiMin)/2./TMath::Pi();
+#else
+ Float_t intYS = yPara.Integral(fYMin, fYMax,1.e-6);
+ Float_t intPt0 = ptPara.Integral(0,15,1.e-6);
+ Float_t intPtS = ptPara.Integral(fPtMin,fPtMax,1.e-6);
+#endif
+ Float_t phiWgt=(fPhiMax-fPhiMin)/2./TMath::Pi(); //TR: should probably be done differently in case of anisotropic phi...
if (fAnalog == kAnalog) {
fYWgt = intYS/fdNdy0;
fPtWgt = intPtS/intPt0;
fPtWgt = (fPtMax-fPtMin)/intPt0;
fParentWeight = fYWgt*fPtWgt*phiWgt/fNpart;
}
-//
-// particle decay related initialization
+ //
+ // particle decay related initialization
fDecayer->SetForceDecay(fForceDecay);
fDecayer->Init();
-//
+ //
AliGenMC::Init();
}
//____________________________________________________________
void AliGenParam::Generate()
{
-//
-// Generate 'npart' of light and heavy mesons (J/Psi, upsilon or phi, Pion,
-// Kaons, Etas, Omegas) and Baryons (proton, antiprotons, neutrons and
-// antineutrons in the the desired theta, phi and momentum windows;
-// Gaussian smearing on the vertex is done if selected.
-// The decay of heavy mesons is done using lujet,
-// and the childern particle are tracked by GEANT
-// However, light mesons are directly tracked by GEANT
-// setting fForceDecay = nodecay (SetForceDecay(nodecay))
-//
-//
-// Reinitialize decayer
+ //
+ // Generate 1 event (see Generate(Int_t ntimes) for details
+ //
+ GenerateN(1);
+}
+//____________________________________________________________
+void AliGenParam::GenerateN(Int_t ntimes)
+{
+ //
+ // Generate ntimes*'npart' light and heavy mesons (J/Psi, upsilon or phi, Pion,
+ // Kaons, Etas, Omegas) and Baryons (proton, antiprotons, neutrons and
+ // antineutrons in the the desired theta, phi and momentum windows;
+ // Gaussian smearing on the vertex is done if selected.
+ // The decay of heavy mesons is done using lujet,
+ // and the childern particle are tracked by GEANT
+ // However, light mesons are directly tracked by GEANT
+ // setting fForceDecay = nodecay (SetForceDecay(nodecay))
+ //
+ //
+ // Reinitialize decayer
fDecayer->SetForceDecay(fForceDecay);
fDecayer->Init();
-//
+ //
Float_t polar[3]= {0,0,0}; // Polarisation of the parent particle (for GEANT tracking)
Float_t origin0[3]; // Origin of the generated parent particle (for GEANT tracking)
Float_t time0; // Time0 of the generated parent particle
//
Float_t random[6];
-// Calculating vertex position per event
+ // Calculating vertex position per event
for (j=0;j<3;j++) origin0[j]=fOrigin[j];
time0 = fTimeOrigin;
if(fVertexSmear==kPerEvent) {
Int_t ipa=0;
-// Generating fNpart particles
+ // Generating fNpart particles
fNprimaries = 0;
- while (ipa<fNpart) {
+ Int_t nGen = fNpart*ntimes;
+ while (ipa<nGen) {
while(1) {
-//
-// particle type
+ //
+ // particle type
Int_t iPart = fIpParaFunc(fRandom);
+ Int_t iTemp = iPart;
+
+ // custom pdg codes for to destinguish direct photons
+ if((iPart>=221000) && (iPart<=229000)) iPart=22;
+
fChildWeight=(fDecayer->GetPartialBranchingRatio(iPart))*fParentWeight;
TParticlePDG *particle = pDataBase->GetParticle(iPart);
Float_t am = particle->Mass();
Rndm(random,2);
-//
-// phi
- phi=fPhiMin+random[0]*(fPhiMax-fPhiMin);
-//
-// y
+ //
+ // y
ty = TMath::TanH(fYPara->GetRandom());
-//
-// pT
+
+ //
+ // pT
if (fAnalog == kAnalog) {
pt=fPtPara->GetRandom();
wgtp=fParentWeight;
Fatal("AliGenParam",
"Division by 0: Please check you rapidity range !");
}
+ //
+ // phi
+ // if(!ipa)
+ //phi=fEvPlane; //align first particle of each event with event plane
+ //else{
+ double v2 = fV2Para->Eval(pt);
+ fdNdPhi->SetParameter(0,v2);
+ fdNdPhi->SetParameter(1,fEvPlane);
+ phi=fdNdPhi->GetRandom();
+ // }
pl=xmt*ty/sqrt((1.-ty)*(1.+ty));
theta=TMath::ATan2(pt,pl);
-// Cut on theta
+ // Cut on theta
if(theta<fThetaMin || theta>fThetaMax) continue;
ptot=TMath::Sqrt(pt*pt+pl*pl);
-// Cut on momentum
+ // Cut on momentum
if(ptot<fPMin || ptot>fPMax) continue;
-//
+ //
p[0]=pt*TMath::Cos(phi);
p[1]=pt*TMath::Sin(phi);
p[2]=pl;
+
if(fVertexSmear==kPerTrack) {
Rndm(random,6);
for (j=0;j<3;j++) {
TMath::Sqrt(-2*TMath::Log(random[1]));
}
-// Looking at fForceDecay :
-// if fForceDecay != none Primary particle decays using
-// AliPythia and children are tracked by GEANT
-//
-// if fForceDecay == none Primary particle is tracked by GEANT
-// (In the latest, make sure that GEANT actually does all the decays you want)
-//
+ // Looking at fForceDecay :
+ // if fForceDecay != none Primary particle decays using
+ // AliPythia and children are tracked by GEANT
+ //
+ // if fForceDecay == none Primary particle is tracked by GEANT
+ // (In the latest, make sure that GEANT actually does all the decays you want)
+ //
Bool_t decayed = kFALSE;
if (fForceDecay != kNoDecay) {
-// Using lujet to decay particle
+ // Using lujet to decay particle
Float_t energy=TMath::Sqrt(ptot*ptot+am*am);
TLorentzVector pmom(p[0], p[1], p[2], energy);
fDecayer->Decay(iPart,&pmom);
-//
-// select decay particles
+ //
+ // select decay particles
Int_t np=fDecayer->ImportParticles(particles);
+ iPart=iTemp;
+ if(fForceConv) np=ForceGammaConversion(particles,np);
+ if(iPart==223000 || iPart==224000){
+ // wgtp*=IntegratedKrollWada(pt);
+ // wgtch*=IntegratedKrollWada(pt);
+ // np=VirtualGammaPairProduction(particles,np)
+ }
+
+
// Selecting GeometryAcceptance for particles fPdgCodeParticleforAcceptanceCut;
if (fGeometryAcceptance)
if (!CheckAcceptanceGeometry(np,particles)) continue;
iparticle = (TParticle *) particles->At(i);
Int_t kf = iparticle->GetPdgCode();
Int_t ks = iparticle->GetStatusCode();
-// flagged particle
+ // flagged particle
if (pFlag[i] == 1) {
ipF = iparticle->GetFirstDaughter();
continue;
}
-// flag decay products of particles with long life-time (c tau > .3 mum)
+ // flag decay products of particles with long life-time (c tau > .3 mum)
if (ks != 1) {
-// TParticlePDG *particle = pDataBase->GetParticle(kf);
+ // TParticlePDG *particle = pDataBase->GetParticle(kf);
Double_t lifeTime = fDecayer->GetLifetime(kf);
-// Double_t mass = particle->Mass();
-// Double_t width = particle->Width();
+ // Double_t mass = particle->Mass();
+ // Double_t width = particle->Width();
if (lifeTime > (Double_t) fMaxLifeTime) {
ipF = iparticle->GetFirstDaughter();
ipL = iparticle->GetLastDaughter();
pSelected[i] = 1;
}
} // ks==1 ?
-//
-// children
+ //
+ // children
if ((ChildSelected(TMath::Abs(kf)) || fForceDecay == kAll || fSelectAll) && trackIt[i])
{
Int_t iparent;
if ((fCutOnChild && ncsel >0) || !fCutOnChild){
ipa++;
-//
-// Parent
+ //
+ // Parent
PushTrack(0, -1, iPart, p, origin0, polar, time0, kPPrimary, nt, wgtp, ((decayed)? 11 : 1));
KeepTrack(nt);
fNprimaries++;
-//
-// Decay Products
-//
+ //
+ // Decay Products
+ //
for (i = 1; i < np; i++) {
if (pSelected[i]) {
TParticle* iparticle = (TParticle *) particles->At(i);
Int_t ksc = iparticle->GetStatusCode();
Int_t jpa = iparticle->GetFirstMother()-1;
- och[0] = origin0[0]+iparticle->Vx()/10;
- och[1] = origin0[1]+iparticle->Vy()/10;
- och[2] = origin0[2]+iparticle->Vz()/10;
+ och[0] = origin0[0]+iparticle->Vx();
+ och[1] = origin0[1]+iparticle->Vy();
+ och[2] = origin0[2]+iparticle->Vz();
pc[0] = iparticle->Px();
pc[1] = iparticle->Py();
pc[2] = iparticle->Pz();
//____________________________________________________________________________________
Float_t AliGenParam::GetRelativeArea(Float_t ptMin, Float_t ptMax, Float_t yMin, Float_t yMax, Float_t phiMin, Float_t phiMax)
{
-//
-// Normalisation for selected kinematic region
-//
+ //
+ // Normalisation for selected kinematic region
+ //
+#if ROOT_VERSION_CODE < ROOT_VERSION(5,99,0)
Float_t ratio =
fPtPara->Integral(ptMin,ptMax,(Double_t *)0,1.e-6) / fPtPara->Integral( fPtPara->GetXmin(), fPtPara->GetXmax(),(Double_t *)0,1.e-6) *
fYPara->Integral(yMin,yMax,(Double_t *)0,1.e-6)/fYPara->Integral(fYPara->GetXmin(),fYPara->GetXmax(),(Double_t *)0,1.e-6) *
(phiMax-phiMin)/360.;
+#else
+ Float_t ratio =
+ fPtPara->Integral(ptMin,ptMax,1.e-6) / fPtPara->Integral( fPtPara->GetXmin(), fPtPara->GetXmax(),1.e-6) *
+ fYPara->Integral(yMin,yMax,1.e-6)/fYPara->Integral(fYPara->GetXmin(),fYPara->GetXmax(),1.e-6) *
+ (phiMax-phiMin)/360.;
+#endif
return TMath::Abs(ratio);
}