return 0;
} else {
printf("Current bin (lower) %13.3f %13.3f %13.3f %13.3f %13.3f \n", fValue[kMultiplicity], fValue[kZVertex], fValue[kEventPlane],fValue[kLeadingParticleEta],fValue[kLeadingParticlePhi]);
- printf("Current bin (upper) %13.3f %13.3f %13.3f %13.3f %13.3f \n", fValue[kMultiplicity] + fValueStep[kMultiplicity],
+ printf("Current bin (upper) %13.3f %13.3f %13.3f %13.3f %13.3f \n", fValue[kMultiplicity] + fValueStep[kMultiplicity] - 1,
fValue[kZVertex] + fValueStep[kZVertex],
fValue[kEventPlane] + fValueStep[kEventPlane],
fValue[kLeadingParticleEta] + fValueStep[kLeadingParticleEta],
);
- fEventCuts->SetMultiplicityRange(Int_t(fValue[kMultiplicity]) , Int_t(fValue[kMultiplicity] + fValueStep[kMultiplicity]));
+ fEventCuts->SetMultiplicityRange(Int_t(fValue[kMultiplicity]) , Int_t(fValue[kMultiplicity] + fValueStep[kMultiplicity] - 1));
fEventCuts->SetPrimaryVertexZRange(fValue[kZVertex] , fValue[kZVertex] + fValueStep[kZVertex]);
fEventCuts->SetEtaLeadingParticleRange(fValue[kLeadingParticleEta] , fValue[kLeadingParticleEta] + fValueStep[kLeadingParticleEta]);
fEventCuts->SetPhiLeadingParticleRange(fValue[kLeadingParticlePhi] , fValue[kLeadingParticlePhi] + fValueStep[kLeadingParticlePhi]);