#include "TNode.h"
#include "TRandom.h"
#include "TTree.h"
-
+#include "TParticle.h"
// --- Standard library ---
-#include <stdio.h>
#include <string.h>
#include <stdlib.h>
-#include <strstream.h>
// --- AliRoot header files ---
#include "AliPHOSCPVDigit.h"
#include "AliRun.h"
#include "AliConst.h"
-#include "AliMC.h"
#include "AliPHOSGeometry.h"
#include "AliPHOSQAIntCheckable.h"
#include "AliPHOSQAFloatCheckable.h"
fLightYieldAttenuation = 0. ;
fRecalibrationFactor = 0. ;
fElectronsPerGeV = 0. ;
- fAPDGain = 0. ;
+ fAPDGain = 0. ;
+ fLightFactor = 0. ;
+ fAPDFactor = 0. ;
}
// and the TreeD at the end of the event (branch is set in FinishEvent() ).
fHits= new TClonesArray("AliPHOSHit",1000) ;
+ gAlice->AddHitList(fHits) ;
fNhits = 0 ;
- fIshunt = 1 ; // All hits are associated with primary particles
+ fIshunt = 2 ; // All hits are associated with primary particles
//Photoelectron statistics:
// The light yield is a poissonian distribution of the number of
// The APD Gain is 300
fLightYieldMean = 47000;
fIntrinsicPINEfficiency = 0.02655 ; //APD= 0.1875/0.1271 * 0.018 (PIN)
- fLightYieldAttenuation = 0.0045 ;
- fRecalibrationFactor = 13.418/ fLightYieldMean ;
- fElectronsPerGeV = 2.77e+8 ;
- fAPDGain= 300. ;
+ fLightYieldAttenuation = 0.0045 ;
+ fRecalibrationFactor = 13.418/ fLightYieldMean ;
+ fElectronsPerGeV = 2.77e+8 ;
+ fAPDGain = 300. ;
+ fLightFactor = fLightYieldMean * fIntrinsicPINEfficiency ;
+ fAPDFactor = (fRecalibrationFactor/100.) * fAPDGain ;
+
Int_t nb = GetGeometry()->GetNModules() ;
// create checkables
fQAHitsMul = new AliPHOSQAIntCheckable("HitsM") ;
fQATotEner = new AliPHOSQAFloatCheckable("TotEn") ;
- fQAHitsMulB = new TClonesArray("AliPHOSQAIntCheckable",nb) ;
+ fQAHitsMulB = new TClonesArray("AliPHOSQAIntCheckable",nb) ;
+ fQAHitsMulB->SetOwner() ;
fQATotEnerB = new TClonesArray("AliPHOSQAFloatCheckable", nb);
+ fQATotEnerB->SetOwner() ;
char tempo[20] ;
Int_t i ;
for ( i = 0 ; i < nb ; i++ ) {
fQAHitsMul->AddChecker(hmc) ;
fQATotEner->AddChecker(emc) ;
for ( i = 0 ; i < nb ; i++ ) {
- ((AliPHOSQAIntCheckable*)(*fQAHitsMulB)[i])->AddChecker(bhmc) ;
- ((AliPHOSQAFloatCheckable*)(*fQATotEnerB)[i])->AddChecker(bemc) ;
+ (static_cast<AliPHOSQAIntCheckable*>((*fQAHitsMulB)[i]))->AddChecker(bhmc) ;
+ (static_cast<AliPHOSQAFloatCheckable*>((*fQATotEnerB)[i]))->AddChecker(bemc) ;
}
}
delete fHits ;
fHits = 0 ;
}
- if (fTreeQA)
- delete fTreeQA ;
+
+ if ( fQAHitsMulB ) {
+ fQAHitsMulB->Delete() ;
+ delete fQAHitsMulB ;
+ }
+
+ if ( fQATotEnerB ) {
+ fQATotEnerB->Delete() ;
+ delete fQATotEnerB ;
+ }
+
}
//____________________________________________________________________________
void AliPHOSv1::AddHit(Int_t shunt, Int_t primary, Int_t tracknumber, Int_t Id, Float_t * hits)
{
// Add a hit to the hit list.
- // A PHOS hit is the sum of all hits in a single crystal from one primary and within soem taime gate
+ // A PHOS hit is the sum of all hits in a single crystal from one primary and within some time gate
Int_t hitCounter ;
AliPHOSHit *newHit ;
newHit = new AliPHOSHit(shunt, primary, tracknumber, Id, hits) ;
for ( hitCounter = fNhits-1 ; hitCounter >= 0 && !deja ; hitCounter-- ) {
- curHit = (AliPHOSHit*) (*fHits)[hitCounter] ;
+ curHit = dynamic_cast<AliPHOSHit*>((*fHits)[hitCounter]) ;
if(curHit->GetPrimary() != primary) break ;
// We add hits with the same primary, while GEANT treats primaries succesively
if( *curHit == *newHit ) {
// and fill the relevant QA checkable (only if in PbW04)
if ( relid[1] == 0 ) {
fQAHitsMul->Update(1) ;
- ((AliPHOSQAIntCheckable*)(*fQAHitsMulB)[relid[0]-1])->Update(1) ;
+ (static_cast<AliPHOSQAIntCheckable*>((*fQAHitsMulB)[relid[0]-1]))->Update(1) ;
}
fNhits++ ;
}
Int_t i ;
if ( fQAHitsMulB && fQATotEnerB ) {
for (i = 0 ; i < GetGeometry()->GetNModules() ; i++) {
- AliPHOSQAIntCheckable * ci = (AliPHOSQAIntCheckable*)(*fQAHitsMulB)[i] ;
- AliPHOSQAFloatCheckable* cf = (AliPHOSQAFloatCheckable*)(*fQATotEnerB)[i] ;
+ AliPHOSQAIntCheckable * ci = static_cast<AliPHOSQAIntCheckable*>((*fQAHitsMulB)[i]) ;
+ AliPHOSQAFloatCheckable* cf = static_cast<AliPHOSQAFloatCheckable*>((*fQATotEnerB)[i]) ;
if ( ci->HasChanged() ) {
ci->CheckMe() ;
ci->Reset() ;
Int_t relid[4] ; // (box, layer, row, column) indices
Int_t absid ; // absolute cell ID number
- Float_t xyze[5]={-1000,-1000,-1000,0,0} ; // position wrt MRS, time and energy deposited
+ Float_t xyzte[5]={-1000.,-1000.,-1000.,0.,0.} ; // position wrt MRS, time and energy deposited
TLorentzVector pos ; // Lorentz vector of the track current position
Int_t copy ;
if( gMC->CurrentVolID(copy) == gMC->VolId("PCPQ") &&
(gMC->IsTrackEntering() ) &&
gMC->TrackCharge() != 0) {
-
+
gMC -> TrackPosition(pos);
-
+
Float_t xyzm[3], xyzd[3] ;
Int_t i;
for (i=0; i<3; i++) xyzm[i] = pos[i];
gMC -> Gmtod (xyzm, xyzd, 1); // transform coordinate from master to daughter system
- Float_t xyd[3]={0,0,0} ; //local posiiton of the entering
+ Float_t xyd[3]={0,0,0} ; //local position of the entering
xyd[0] = xyzd[0];
xyd[1] =-xyzd[2];
xyd[2] =-xyzd[1];
-
+
// Current momentum of the hit's track in the local ref. system
TLorentzVector pmom ; //momentum of the particle initiated hit
gMC -> TrackMomentum(pmom);
Float_t pm[3], pd[3];
for (i=0; i<3; i++)
pm[i] = pmom[i];
-
+
gMC -> Gmtod (pm, pd, 2); // transform 3-momentum from master to daughter system
pmom[0] = pd[0];
- pmom[1] =-pd[2];
- pmom[2] =-pd[1];
-
+ pmom[1] =-pd[1];
+ pmom[2] =-pd[2];
+
// Digitize the current CPV hit:
// 1. find pad response and
ndigits = cpvDigits->GetEntriesFast();
for (idigit=0; idigit<ndigits-1; idigit++) {
- AliPHOSCPVDigit *cpvDigit1 = (AliPHOSCPVDigit*) cpvDigits->UncheckedAt(idigit);
+ AliPHOSCPVDigit *cpvDigit1 = dynamic_cast<AliPHOSCPVDigit*>(cpvDigits->UncheckedAt(idigit));
Float_t x1 = cpvDigit1->GetXpad() ;
Float_t z1 = cpvDigit1->GetYpad() ;
for (Int_t jdigit=idigit+1; jdigit<ndigits; jdigit++) {
- AliPHOSCPVDigit *cpvDigit2 = (AliPHOSCPVDigit*) cpvDigits->UncheckedAt(jdigit);
+ AliPHOSCPVDigit *cpvDigit2 = dynamic_cast<AliPHOSCPVDigit*>(cpvDigits->UncheckedAt(jdigit));
Float_t x2 = cpvDigit2->GetXpad() ;
Float_t z2 = cpvDigit2->GetYpad() ;
if (x1==x2 && z1==z2) {
ndigits = cpvDigits->GetEntriesFast();
for (idigit=0; idigit<ndigits; idigit++) {
- AliPHOSCPVDigit *cpvDigit = (AliPHOSCPVDigit*) cpvDigits->UncheckedAt(idigit);
+ AliPHOSCPVDigit *cpvDigit = dynamic_cast<AliPHOSCPVDigit*>(cpvDigits->UncheckedAt(idigit));
relid[0] = moduleNumber + 1 ; // CPV (or PHOS) module number
relid[1] =-1 ; // means CPV
relid[2] = cpvDigit->GetXpad() ; // column number of a pad
// add current digit to the temporary hit list
- xyze[3] = gMC->TrackTime() ;
- xyze[4] = cpvDigit->GetQpad() ; // amplitude in a pad
+ xyzte[3] = gMC->TrackTime() ;
+ xyzte[4] = cpvDigit->GetQpad() ; // amplitude in a pad
primary = -1; // No need in primary for CPV
- AddHit(fIshunt, primary, tracknumber, absid, xyze);
+ AddHit(fIshunt, primary, tracknumber, absid, xyzte);
if (cpvDigit->GetQpad() > 0.02) {
xmean += cpvDigit->GetQpad() * (cpvDigit->GetXpad() + 0.5);
qsum += cpvDigit->GetQpad();
}
}
- delete cpvDigits;
+ if (cpvDigits) {
+ cpvDigits->Delete();
+ delete cpvDigits;
+ cpvDigits=0;
+ }
}
if(gMC->CurrentVolID(copy) == gMC->VolId("PXTL") ) { // We are inside a PBWO crystal
gMC->TrackPosition(pos) ;
- xyze[0] = pos[0] ;
- xyze[1] = pos[1] ;
- xyze[2] = pos[2] ;
+ xyzte[0] = pos[0] ;
+ xyzte[1] = pos[1] ;
+ xyzte[2] = pos[2] ;
+
Float_t global[3], local[3] ;
global[0] = pos[0] ;
global[1] = pos[1] ;
global[2] = pos[2] ;
Float_t lostenergy = gMC->Edep();
-
+
+ //Put in the TreeK particle entering PHOS and all its parents
+ if ( gMC->IsTrackEntering() ){
+ Float_t xyzd[3] ;
+ gMC -> Gmtod (xyzte, xyzd, 1); // transform coordinate from master to daughter system
+ if (xyzd[1] > GetGeometry()->GetCrystalSize(1)/2-0.002 ||
+ xyzd[1] < -GetGeometry()->GetCrystalSize(1)/2+0.002) {
+ TParticle * part = 0 ;
+ Int_t parent = gAlice->CurrentTrack() ;
+ while ( parent != -1 ) {
+ part = gAlice->Particle(parent) ;
+ part->SetBit(kKeepBit);
+ parent = part->GetFirstMother() ;
+ }
+ }
+ }
if ( lostenergy != 0 ) { // Track is inside the crystal and deposits some energy
+ xyzte[3] = gMC->TrackTime() ;
- xyze[3] = gMC->TrackTime() ;
-
gMC->CurrentVolOffID(10, moduleNumber) ; // get the PHOS module number ;
- // fill the relevant QA Checkables
- fQATotEner->Update( xyze[4] ) ; // total energy in PHOS
- ((AliPHOSQAFloatCheckable*)(*fQATotEnerB)[moduleNumber-1])->Update( xyze[4] ) ; // energy in this block
-
Int_t strip ;
gMC->CurrentVolOffID(3, strip);
Int_t cell ;
gMC->CurrentVolOffID(2, cell);
-
+
Int_t row = 1 + GetGeometry()->GetNZ() - strip % GetGeometry()->GetNZ() ;
Int_t col = (Int_t) TMath::Ceil((Double_t) strip/GetGeometry()->GetNZ()) -1 ;
-
+
absid = (moduleNumber-1)*GetGeometry()->GetNCristalsInModule() +
row + (col*GetGeometry()->GetEMCAGeometry()->GetNCellsInStrip() + cell-1)*GetGeometry()->GetNZ() ;
-
+
gMC->Gmtod(global, local, 1) ;
- //Calculates the light yield, the number of photns produced in the
+ //Calculates the light yield, the number of photons produced in the
//crystal
- Float_t lightYield = gRandom->Poisson(fLightYieldMean * lostenergy *
- fIntrinsicPINEfficiency *
+ Float_t lightYield = gRandom->Poisson(fLightFactor * lostenergy *
exp(-fLightYieldAttenuation *
(local[1]+GetGeometry()->GetCrystalSize(1)/2.0 ))
) ;
+
//Calculates de energy deposited in the crystal
- xyze[4] = (fRecalibrationFactor/100.) * fAPDGain * lightYield ;
+ xyzte[4] = fAPDFactor * lightYield ;
// add current hit to the hit list
- AddHit(fIshunt, primary,tracknumber, absid, xyze);
+ // Info("StepManager","%d %d", primary, tracknumber) ;
+ AddHit(fIshunt, primary,tracknumber, absid, xyzte);
+ // fill the relevant QA Checkables
+ fQATotEner->Update( xyzte[4] ) ; // total energy in PHOS
+ (static_cast<AliPHOSQAFloatCheckable*>((*fQATotEnerB)[moduleNumber-1]))->Update( xyzte[4] ) ; // energy in this block
} // there is deposited energy
} // we are inside a PHOS Xtal
-
+
}
//____________________________________________________________________________
Float_t pNorm = p.Py();
Float_t eloss = kdEdx;
-// cout << "CPVDigitize: YVK : "<<hitX<<" "<<hitZ<<" | "<<pX<<" "<<pZ<<" "<<pNorm<<endl;
+//Info("CPVDigitize", "YVK : %f %f | %f %f %d", hitX, hitZ, pX, pZ, pNorm) ;
Float_t dZY = pZ/pNorm * GetGeometry()->GetCPVGasThickness();
Float_t dXY = pX/pNorm * GetGeometry()->GetCPVGasThickness();
Int_t nz3 = (kNgamz+1)/2;
Int_t nx3 = (kNgamx+1)/2;
cpvDigits->Expand(nIter*kNgamx*kNgamz);
- TClonesArray &ldigits = *(TClonesArray *)cpvDigits;
+ TClonesArray &ldigits = *(static_cast<TClonesArray *>(cpvDigits));
for (Int_t iter=0; iter<nIter; iter++) {
git://git.uio.no / u / mrichter / AliRoot.git / blobdiff