#include "AliConst.h"
#include "AliMC.h"
#include "AliPHOSGeometry.h"
+#include "AliPHOSQAIntCheckable.h"
+#include "AliPHOSQAFloatCheckable.h"
+#include "AliPHOSQAMeanChecker.h"
ClassImp(AliPHOSv1)
//____________________________________________________________________________
AliPHOSv1::AliPHOSv1(const char *name, const char *title):
-AliPHOSv0(name,title)
+ AliPHOSv0(name,title)
{
// ctor : title is used to identify the layout
// GPS2 = 5 modules (EMC + PPSD)
// We do not want to save in TreeH the raw hits
// But save the cumulated hits instead (need to create the branch myself)
// It is put in the Digit Tree because the TreeH is filled after each primary
- // and the TreeD at the end of the event (branch is set in FinishEvent() ).
+ // and the TreeD at the end of the event (branch is set in FinishEvent() ).
fHits= new TClonesArray("AliPHOSHit",1000) ;
fNhits = 0 ;
fIshunt = 1 ; // All hits are associated with primary particles
+
+ Int_t nb = GetGeometry()->GetNModules() ;
+ // create checkables
+ fQAHitsMul = new AliPHOSQAIntCheckable("HitsM") ;
+ fQATotEner = new AliPHOSQAFloatCheckable("TotEn") ;
+ fQAHitsMulB = new TClonesArray("AliPHOSQAIntCheckable",nb) ;
+ fQATotEnerB = new TClonesArray("AliPHOSQAFloatCheckable", nb);
+ char tempo[20] ;
+ Int_t i ;
+ for ( i = 0 ; i < nb ; i++ ) {
+ sprintf(tempo, "HitsMB%d", i+1) ;
+ new( (*fQAHitsMulB)[i]) AliPHOSQAIntCheckable(tempo) ;
+ sprintf(tempo, "TotEnB%d", i+1) ;
+ new( (*fQATotEnerB)[i] ) AliPHOSQAFloatCheckable(tempo) ;
+ }
+
+ AliPHOSQAMeanChecker * hmc = new AliPHOSQAMeanChecker("HitsMul", 100. ,25.) ;
+ AliPHOSQAMeanChecker * emc = new AliPHOSQAMeanChecker("TotEner", 10. ,5.) ;
+ AliPHOSQAMeanChecker * bhmc = new AliPHOSQAMeanChecker("HitsMulB", 100. ,5.) ;
+ AliPHOSQAMeanChecker * bemc = new AliPHOSQAMeanChecker("TotEnerB", 2. ,.5) ;
+
+ // associate checkables and checkers
+ fQAHitsMul->AddChecker(hmc) ;
+ fQATotEner->AddChecker(emc) ;
+ for ( i = 0 ; i < nb ; i++ ) {
+ ((AliPHOSQAIntCheckable*)(*fQAHitsMulB)[i])->AddChecker(bhmc) ;
+ ((AliPHOSQAFloatCheckable*)(*fQATotEnerB)[i])->AddChecker(bemc) ;
+ }
}
//____________________________________________________________________________
AliPHOSHit *newHit ;
AliPHOSHit *curHit ;
Bool_t deja = kFALSE ;
+ AliPHOSGeometry * geom = GetGeometry() ;
newHit = new AliPHOSHit(shunt, primary, tracknumber, Id, hits) ;
for ( hitCounter = fNhits-1 ; hitCounter >= 0 && !deja ; hitCounter-- ) {
curHit = (AliPHOSHit*) (*fHits)[hitCounter] ;
- if(curHit->GetPrimary() != primary) break ; // We add hits with the same primary, while GEANT treats primaries consequently
+ if(curHit->GetPrimary() != primary) break ; // We add hits with the same primary, while GEANT treats primaries succesively
if( *curHit == *newHit ) {
*curHit = *curHit + *newHit ;
deja = kTRUE ;
if ( !deja ) {
new((*fHits)[fNhits]) AliPHOSHit(*newHit) ;
+ // get the block Id number
+ Int_t * relid = new Int_t[geom->GetNModules()] ;
+ geom->AbsToRelNumbering(Id, relid) ;
+ // and fill the relevant QA checkable (only if in PbW04)
+ if ( relid[1] == 0 ) {
+ fQAHitsMul->Update(1) ;
+ ((AliPHOSQAIntCheckable*)(*fQAHitsMulB)[relid[0]-1])->Update(1) ;
+ }
+ delete relid ;
fNhits++ ;
}
delete newHit;
}
+//____________________________________________________________________________
+void AliPHOSv1::FinishPrimary()
+{
+ // called at the end of each track (primary) by AliRun
+ // hits are reset for each new track
+ // accumulate the total hit-multiplicity
+// if ( fQAHitsMul )
+// fQAHitsMul->Update( fHits->GetEntriesFast() ) ;
+
+}
+
+//____________________________________________________________________________
+void AliPHOSv1::FinishEvent()
+{
+ // called at the end of each event by AliRun
+ // accumulate the hit-multiplicity and total energy per block
+ // if the values have been updated check it
+
+ if ( fQATotEner ) {
+ if ( fQATotEner->HasChanged() ) {
+ fQATotEner->CheckMe() ;
+ fQATotEner->Reset() ;
+ }
+ }
+
+ Int_t i ;
+ if ( fQAHitsMulB && fQATotEnerB ) {
+ for (i = 0 ; i < GetGeometry()->GetNModules() ; i++) {
+ AliPHOSQAIntCheckable * ci = (AliPHOSQAIntCheckable*)(*fQAHitsMulB)[i] ;
+ AliPHOSQAFloatCheckable* cf = (AliPHOSQAFloatCheckable*)(*fQATotEnerB)[i] ;
+ if ( ci->HasChanged() ) {
+ ci->CheckMe() ;
+ ci->Reset() ;
+ }
+ if ( cf->HasChanged() ) {
+ cf->CheckMe() ;
+ cf->Reset() ;
+ }
+ }
+ }
+
+ // check the total multiplicity
+
+ if ( fQAHitsMul ) {
+ if ( fQAHitsMul->HasChanged() ) {
+ fQAHitsMul->CheckMe() ;
+ fQAHitsMul->Reset() ;
+ }
+ }
+}
+
//____________________________________________________________________________
void AliPHOSv1::StepManager(void)
{
Int_t tracknumber = gAlice->CurrentTrack() ;
Int_t primary = gAlice->GetPrimary( gAlice->CurrentTrack() );
- TString name = fGeom->GetName() ;
+ TString name = GetGeometry()->GetName() ;
if ( name == "GPS2" || name == "MIXT" ) { // ======> CPV is a GPS' PPSD
- if( gMC->CurrentVolID(copy) == gMC->VolId("PCEL") ) // We are inside a gas cell
+ if( gMC->CurrentVolID(copy) == gMC->VolId("PPCE") ) // We are inside a gas cell
{
gMC->TrackPosition(pos) ;
xyze[0] = pos[0] ;
if ( xyze[3] != 0 ) { // there is deposited energy
gMC->CurrentVolOffID(5, relid[0]) ; // get the PHOS Module number
if ( name == "MIXT" && strcmp(gMC->CurrentVolOffName(5),"PHO1") == 0 ){
- relid[0] += fGeom->GetNModules() - fGeom->GetNPPSDModules();
+ relid[0] += GetGeometry()->GetNModules() - GetGeometry()->GetNPPSDModules();
}
gMC->CurrentVolOffID(3, relid[1]) ; // get the Micromegas Module number
- // 1-> fGeom->GetNumberOfModulesPhi() * fGeom->GetNumberOfModulesZ() upper
- // > fGeom->GetNumberOfModulesPhi() * fGeom->GetNumberOfModulesZ() lower
+ // 1-> GetGeometry()->GetNumberOfModulesPhi() * GetGeometry()->GetNumberOfModulesZ() upper
+ // > GetGeometry()->GetNumberOfModulesPhi() * GetGeometry()->GetNumberOfModulesZ() lower
gMC->CurrentVolOffID(1, relid[2]) ; // get the row number of the cell
gMC->CurrentVolID(relid[3]) ; // get the column number
// get the absolute Id number
- fGeom->RelToAbsNumbering(relid, absid) ;
+ GetGeometry()->RelToAbsNumbering(relid, absid) ;
// add current hit to the hit list
AddHit(fIshunt, primary, tracknumber, absid, xyze);
relid[3] = cpvDigit->GetYpad() ; // row number of a pad
// get the absolute Id number
- fGeom->RelToAbsNumbering(relid, absid) ;
+ GetGeometry()->RelToAbsNumbering(relid, absid) ;
// add current digit to the temporary hit list
xyze[0] = 0. ;
if ( xyze[3] != 0 ) { // Track is inside the crystal and deposits some energy
gMC->CurrentVolOffID(10, relid[0]) ; // get the PHOS module number ;
+
+ // fill the relevant QA Checkables
+ fQATotEner->Update( xyze[3] ) ; // total energy in PHOS
+ ((AliPHOSQAFloatCheckable*)(*fQATotEnerB)[relid[0]-1])->Update( xyze[3] ) ; // energy in this block
if ( name == "MIXT" && strcmp(gMC->CurrentVolOffName(10),"PHO1") == 0 )
- relid[0] += fGeom->GetNModules() - fGeom->GetNPPSDModules();
+ relid[0] += GetGeometry()->GetNModules() - GetGeometry()->GetNPPSDModules();
relid[1] = 0 ; // means PBW04
gMC->CurrentVolOffID(4, relid[2]) ; // get the row number inside the module
gMC->CurrentVolOffID(3, relid[3]) ; // get the cell number inside the module
// get the absolute Id number
- fGeom->RelToAbsNumbering(relid, absid) ;
+ GetGeometry()->RelToAbsNumbering(relid, absid) ;
// add current hit to the hit list
AddHit(fIshunt, primary,tracknumber, absid, xyze);
// 2 October 2000
// ------------------------------------------------------------------------
- const Float_t kCelWr = fGeom->GetPadSizePhi()/2; // Distance between wires (2 wires above 1 pad)
+ const Float_t kCelWr = GetGeometry()->GetPadSizePhi()/2; // Distance between wires (2 wires above 1 pad)
const Float_t kDetR = 0.1; // Relative energy fluctuation in track for 100 e-
const Float_t kdEdx = 4.0; // Average energy loss in CPV;
const Int_t kNgamz = 5; // Ionization size in Z
// cout << "CPVDigitize: YVK : "<<hitX<<" "<<hitZ<<" | "<<pX<<" "<<pZ<<" "<<pNorm<<endl;
- Float_t dZY = pZ/pNorm * fGeom->GetCPVGasThickness();
- Float_t dXY = pX/pNorm * fGeom->GetCPVGasThickness();
+ Float_t dZY = pZ/pNorm * GetGeometry()->GetCPVGasThickness();
+ Float_t dXY = pX/pNorm * GetGeometry()->GetCPVGasThickness();
gRandom->Rannor(rnor1,rnor2);
eloss *= (1 + kDetR*rnor1) *
- TMath::Sqrt((1 + ( pow(dZY,2) + pow(dXY,2) ) / pow(fGeom->GetCPVGasThickness(),2)));
- Float_t zhit1 = hitZ + fGeom->GetCPVActiveSize(1)/2 - dZY/2;
- Float_t xhit1 = hitX + fGeom->GetCPVActiveSize(0)/2 - dXY/2;
+ TMath::Sqrt((1 + ( pow(dZY,2) + pow(dXY,2) ) / pow(GetGeometry()->GetCPVGasThickness(),2)));
+ Float_t zhit1 = hitZ + GetGeometry()->GetCPVActiveSize(1)/2 - dZY/2;
+ Float_t xhit1 = hitX + GetGeometry()->GetCPVActiveSize(0)/2 - dXY/2;
Float_t zhit2 = zhit1 + dZY;
Float_t xhit2 = xhit1 + dXY;
// Finite size of ionization region
- Int_t nCellZ = fGeom->GetNumberOfCPVPadsZ();
- Int_t nCellX = fGeom->GetNumberOfCPVPadsPhi();
+ Int_t nCellZ = GetGeometry()->GetNumberOfCPVPadsZ();
+ Int_t nCellX = GetGeometry()->GetNumberOfCPVPadsPhi();
Int_t nz3 = (kNgamz+1)/2;
Int_t nx3 = (kNgamx+1)/2;
cpvDigits->Expand(nIter*kNgamx*kNgamz);
Float_t zhit = zxe[0][iter];
Float_t xhit = zxe[1][iter];
Float_t qhit = zxe[2][iter];
- Float_t zcell = zhit / fGeom->GetPadSizeZ();
- Float_t xcell = xhit / fGeom->GetPadSizePhi();
+ Float_t zcell = zhit / GetGeometry()->GetPadSizeZ();
+ Float_t xcell = xhit / GetGeometry()->GetPadSizePhi();
if ( zcell<=0 || xcell<=0 ||
zcell>=nCellZ || xcell>=nCellX) return;
Int_t izcell = (Int_t) zcell;
// 3 October 2000
// ------------------------------------------------------------------------
- Double_t dz = fGeom->GetPadSizeZ() / 2;
- Double_t dx = fGeom->GetPadSizePhi() / 2;
- Double_t z = zhit * fGeom->GetPadSizeZ();
- Double_t x = xhit * fGeom->GetPadSizePhi();
+ Double_t dz = GetGeometry()->GetPadSizeZ() / 2;
+ Double_t dx = GetGeometry()->GetPadSizePhi() / 2;
+ Double_t z = zhit * GetGeometry()->GetPadSizeZ();
+ Double_t x = xhit * GetGeometry()->GetPadSizePhi();
Double_t amplitude = qhit *
(CPVCumulPadResponse(z+dz,x+dx) - CPVCumulPadResponse(z+dz,x-dx) -
CPVCumulPadResponse(z-dz,x+dx) + CPVCumulPadResponse(z-dz,x-dx));