const Double_t AliTRDgeometry::fgkXtrdEnd = 366.33; // mother volume inside space frame !!!
// The outer width of the chambers
- const Float_t AliTRDgeometry::fgkCwidth[kNlayer] = {90.4, 94.8, 99.3, 103.7, 108.1, 112.6};
+ const Float_t AliTRDgeometry::fgkCwidth[kNlayer] = { 90.4, 94.8, 99.3, 103.7, 108.1, 112.6 };
// The outer lengths of the chambers
// Includes the spacings between the chambers!
, { 145.0, 145.0, 110.0, 145.0, 145.0 }
, { 147.0, 147.0, 110.0, 147.0, 147.0 } };
+ Char_t AliTRDgeometry::fgSMstatus[kNsector] = { 1, 1, 1, 1, 1, 1, 1, 1, 1
+ , 1, 1, 1, 1, 1, 1, 1, 1, 1 };
+
TObjArray* AliTRDgeometry::fgClusterMatrixArray = NULL;
TObjArray* AliTRDgeometry::fgPadPlaneArray = NULL;
//_____________________________________________________________________________
AliTRDgeometry::AliTRDgeometry()
- :AliGeometry()
{
//
// AliTRDgeometry default constructor
//
- Init();
-
-}
-
-//_____________________________________________________________________________
-AliTRDgeometry::AliTRDgeometry(const AliTRDgeometry &g)
- :AliGeometry(g)
-{
- //
- // AliTRDgeometry copy constructor
- //
-
- Init();
-
}
//_____________________________________________________________________________
}
-//_____________________________________________________________________________
-AliTRDgeometry &AliTRDgeometry::operator=(const AliTRDgeometry &g)
-{
- //
- // Assignment operator
- //
-
- if (this != &g) {
- Init();
- }
-
- return *this;
-
-}
-
-//_____________________________________________________________________________
-void AliTRDgeometry::Init()
-{
- //
- // Initializes the geometry parameter
- //
-
- // The rotation matrix elements
- Float_t phi = 0.0;
- for (Int_t isector = 0; isector < fgkNsector; isector++) {
- phi = 2.0 * TMath::Pi() / (Float_t) fgkNsector * ((Float_t) isector + 0.5);
- fRotB11[isector] = TMath::Cos(phi);
- fRotB12[isector] = TMath::Sin(phi);
- fRotB21[isector] = TMath::Sin(phi);
- fRotB22[isector] = TMath::Cos(phi);
- }
-
- // SM status
- for (Int_t i = 0; i < kNsector; i++) {
- fSMstatus[i] = 1;
- }
-
-}
-
//_____________________________________________________________________________
void AliTRDgeometry::CreatePadPlaneArray()
{
Float_t parTrd[kNparTrd];
Float_t parCha[kNparCha];
- Char_t cTagV[100];
- Char_t cTagM[100];
+ const Int_t kTag = 100;
+ Char_t cTagV[kTag];
+ Char_t cTagM[kTag];
// There are three TRD volumes for the supermodules in order to accomodate
// the different arrangements in front of PHOS
// The lower part of the readout chambers (drift volume + radiator)
// The aluminum frames
- sprintf(cTagV,"UA%02d",iDet);
+ snprintf(cTagV,kTag,"UA%02d",iDet);
parCha[0] = fgkCwidth[ilayer]/2.0;
parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0;
parCha[2] = fgkCraH/2.0 + fgkCdrH/2.0;
// This part has not the correct shape but is just supposed to
// represent the missing material. The correct form of the L-shaped
// profile would not fit into the alignable volume.
- sprintf(cTagV,"UZ%02d",iDet);
+ snprintf(cTagV,kTag,"UZ%02d",iDet);
parCha[0] = fgkCalWmod/2.0;
parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0;
parCha[2] = fgkCalHmod/2.0;
gMC->Gsvolu(cTagV,"BOX ",idtmed[1301-1],parCha,kNparCha);
// The additional Wacosit on the frames
- sprintf(cTagV,"UP%02d",iDet);
+ snprintf(cTagV,kTag,"UP%02d",iDet);
parCha[0] = fgkCwsW/2.0;
parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0;
parCha[2] = fgkCwsH/2.0;
gMC->Gsvolu(cTagV,"BOX ",idtmed[1307-1],parCha,kNparCha);
// The Wacosit frames
- sprintf(cTagV,"UB%02d",iDet);
+ snprintf(cTagV,kTag,"UB%02d",iDet);
parCha[0] = fgkCwidth[ilayer]/2.0 - fgkCalT;
parCha[1] = -1.0;
parCha[2] = -1.0;
gMC->Gsvolu(cTagV,"BOX ",idtmed[1307-1],parCha,kNparCha);
// The glue around the radiator
- sprintf(cTagV,"UX%02d",iDet);
+ snprintf(cTagV,kTag,"UX%02d",iDet);
parCha[0] = fgkCwidth[ilayer]/2.0 - fgkCalT - fgkCclsT;
parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0 - fgkCclfT;
parCha[2] = fgkCraH/2.0;
gMC->Gsvolu(cTagV,"BOX ",idtmed[1311-1],parCha,kNparCha);
// The inner part of radiator (air)
- sprintf(cTagV,"UC%02d",iDet);
+ snprintf(cTagV,kTag,"UC%02d",iDet);
parCha[0] = fgkCwidth[ilayer]/2.0 - fgkCalT - fgkCclsT - fgkCglT;
parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0 - fgkCclfT - fgkCglT;
parCha[2] = -1.0;
// The upper part of the readout chambers (amplification volume)
// The Wacosit frames
- sprintf(cTagV,"UD%02d",iDet);
+ snprintf(cTagV,kTag,"UD%02d",iDet);
parCha[0] = fgkCwidth[ilayer]/2.0 + fgkCroW;
parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0;
parCha[2] = fgkCamH/2.0;
gMC->Gsvolu(cTagV,"BOX ",idtmed[1307-1],parCha,kNparCha);
// The inner part of the Wacosit frame (air)
- sprintf(cTagV,"UE%02d",iDet);
+ snprintf(cTagV,kTag,"UE%02d",iDet);
parCha[0] = fgkCwidth[ilayer]/2.0 + fgkCroW - fgkCcuTb;
parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0 - fgkCcuTa;
parCha[2] = -1.;
// The back panel, including pad plane and readout boards
// The aluminum frames
- sprintf(cTagV,"UF%02d",iDet);
+ snprintf(cTagV,kTag,"UF%02d",iDet);
parCha[0] = fgkCwidth[ilayer]/2.0 + fgkCroW;
parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0;
parCha[2] = fgkCroH/2.0;
gMC->Gsvolu(cTagV,"BOX ",idtmed[1301-1],parCha,kNparCha);
// The inner part of the aluminum frames
- sprintf(cTagV,"UG%02d",iDet);
+ snprintf(cTagV,kTag,"UG%02d",iDet);
parCha[0] = fgkCwidth[ilayer]/2.0 + fgkCroW - fgkCauT;
parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0 - fgkCauT;
parCha[2] = -1.0;
parCha[0] = -1.0;
parCha[1] = -1.0;
parCha[2] = fgkRMyThick/2.0;
- sprintf(cTagV,"URMY%02d",iDet);
+ snprintf(cTagV,kTag,"URMY%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1327-1],parCha,kNparCha);
// Carbon layer (radiator)
parCha[0] = -1.0;
parCha[1] = -1.0;
parCha[2] = fgkRCbThick/2.0;
- sprintf(cTagV,"URCB%02d",iDet);
+ snprintf(cTagV,kTag,"URCB%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1326-1],parCha,kNparCha);
// Araldite layer (radiator)
parCha[0] = -1.0;
parCha[1] = -1.0;
parCha[2] = fgkRGlThick/2.0;
- sprintf(cTagV,"URGL%02d",iDet);
+ snprintf(cTagV,kTag,"URGL%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1311-1],parCha,kNparCha);
// Rohacell layer (radiator)
parCha[0] = -1.0;
parCha[1] = -1.0;
parCha[2] = fgkRRhThick/2.0;
- sprintf(cTagV,"URRH%02d",iDet);
+ snprintf(cTagV,kTag,"URRH%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1315-1],parCha,kNparCha);
// Fiber layer (radiator)
parCha[0] = -1.0;
parCha[1] = -1.0;
parCha[2] = fgkRFbThick/2.0;
- sprintf(cTagV,"URFB%02d",iDet);
+ snprintf(cTagV,kTag,"URFB%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1328-1],parCha,kNparCha);
// Xe/Isobutane layer (drift volume)
parCha[0] = fgkCwidth[ilayer]/2.0 - fgkCalT - fgkCclsT;
parCha[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0 - fgkCclfT;
parCha[2] = fgkDrThick/2.0;
- sprintf(cTagV,"UJ%02d",iDet);
+ snprintf(cTagV,kTag,"UJ%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1309-1],parCha,kNparCha);
// Xe/Isobutane layer (amplification volume)
parCha[0] = -1.0;
parCha[1] = -1.0;
parCha[2] = fgkAmThick/2.0;
- sprintf(cTagV,"UK%02d",iDet);
+ snprintf(cTagV,kTag,"UK%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1309-1],parCha,kNparCha);
// Cu layer (wire plane)
parCha[0] = -1.0;
parCha[1] = -1.0;
parCha[2] = fgkWrThick/2.0;
- sprintf(cTagV,"UW%02d",iDet);
+ snprintf(cTagV,kTag,"UW%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1303-1],parCha,kNparCha);
// Cu layer (pad plane)
parCha[0] = -1.0;
parCha[1] = -1.0;
parCha[2] = fgkPPdThick/2.0;
- sprintf(cTagV,"UPPD%02d",iDet);
+ snprintf(cTagV,kTag,"UPPD%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1305-1],parCha,kNparCha);
// G10 layer (pad plane)
parCha[0] = -1.0;
parCha[1] = -1.0;
parCha[2] = fgkPPpThick/2.0;
- sprintf(cTagV,"UPPP%02d",iDet);
+ snprintf(cTagV,kTag,"UPPP%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1313-1],parCha,kNparCha);
// Araldite layer (glue)
parCha[0] = -1.0;
parCha[1] = -1.0;
parCha[2] = fgkPGlThick/2.0;
- sprintf(cTagV,"UPGL%02d",iDet);
+ snprintf(cTagV,kTag,"UPGL%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1311-1],parCha,kNparCha);
// Carbon layer (carbon fiber mats)
parCha[0] = -1.0;
parCha[1] = -1.0;
parCha[2] = fgkPCbThick/2.0;
- sprintf(cTagV,"UPCB%02d",iDet);
+ snprintf(cTagV,kTag,"UPCB%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1326-1],parCha,kNparCha);
// Aramide layer (honeycomb)
parCha[0] = -1.0;
parCha[1] = -1.0;
parCha[2] = fgkPHcThick/2.0;
- sprintf(cTagV,"UPHC%02d",iDet);
+ snprintf(cTagV,kTag,"UPHC%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1310-1],parCha,kNparCha);
// G10 layer (PCB readout board)
parCha[0] = -1.0;
parCha[1] = -1.0;
parCha[2] = fgkPPcThick/2;
- sprintf(cTagV,"UPPC%02d",iDet);
+ snprintf(cTagV,kTag,"UPPC%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1313-1],parCha,kNparCha);
// Cu layer (traces in readout board)
parCha[0] = -1.0;
parCha[1] = -1.0;
parCha[2] = fgkPRbThick/2.0;
- sprintf(cTagV,"UPRB%02d",iDet);
+ snprintf(cTagV,kTag,"UPRB%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1306-1],parCha,kNparCha);
// Cu layer (other material on in readout board, incl. screws)
parCha[0] = -1.0;
parCha[1] = -1.0;
parCha[2] = fgkPElThick/2.0;
- sprintf(cTagV,"UPEL%02d",iDet);
+ snprintf(cTagV,kTag,"UPEL%02d",iDet);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1304-1],parCha,kNparCha);
//
// Lower part
// Mylar layers (radiator)
zpos = fgkRMyThick/2.0 - fgkCraH/2.0;
- sprintf(cTagV,"URMY%02d",iDet);
- sprintf(cTagM,"UC%02d",iDet);
+ snprintf(cTagV,kTag,"URMY%02d",iDet);
+ snprintf(cTagM,kTag,"UC%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
zpos = -fgkRMyThick/2.0 + fgkCraH/2.0;
- sprintf(cTagV,"URMY%02d",iDet);
- sprintf(cTagM,"UC%02d",iDet);
+ snprintf(cTagV,kTag,"URMY%02d",iDet);
+ snprintf(cTagM,kTag,"UC%02d",iDet);
gMC->Gspos(cTagV,2,cTagM,xpos,ypos,zpos,0,"ONLY");
// Carbon layers (radiator)
zpos = fgkRCbThick/2.0 + fgkRMyThick - fgkCraH/2.0;
- sprintf(cTagV,"URCB%02d",iDet);
- sprintf(cTagM,"UC%02d",iDet);
+ snprintf(cTagV,kTag,"URCB%02d",iDet);
+ snprintf(cTagM,kTag,"UC%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
zpos = -fgkRCbThick/2.0 - fgkRMyThick + fgkCraH/2.0;
- sprintf(cTagV,"URCB%02d",iDet);
- sprintf(cTagM,"UC%02d",iDet);
+ snprintf(cTagV,kTag,"URCB%02d",iDet);
+ snprintf(cTagM,kTag,"UC%02d",iDet);
gMC->Gspos(cTagV,2,cTagM,xpos,ypos,zpos,0,"ONLY");
// Carbon layers (radiator)
zpos = fgkRGlThick/2.0 + fgkRCbThick + fgkRMyThick - fgkCraH/2.0;
- sprintf(cTagV,"URGL%02d",iDet);
- sprintf(cTagM,"UC%02d",iDet);
+ snprintf(cTagV,kTag,"URGL%02d",iDet);
+ snprintf(cTagM,kTag,"UC%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
zpos = -fgkRGlThick/2.0 - fgkRCbThick - fgkRMyThick + fgkCraH/2.0;
- sprintf(cTagV,"URGL%02d",iDet);
- sprintf(cTagM,"UC%02d",iDet);
+ snprintf(cTagV,kTag,"URGL%02d",iDet);
+ snprintf(cTagM,kTag,"UC%02d",iDet);
gMC->Gspos(cTagV,2,cTagM,xpos,ypos,zpos,0,"ONLY");
// Rohacell layers (radiator)
zpos = fgkRRhThick/2.0 + fgkRGlThick + fgkRCbThick + fgkRMyThick - fgkCraH/2.0;
- sprintf(cTagV,"URRH%02d",iDet);
- sprintf(cTagM,"UC%02d",iDet);
+ snprintf(cTagV,kTag,"URRH%02d",iDet);
+ snprintf(cTagM,kTag,"UC%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
zpos = -fgkRRhThick/2.0 - fgkRGlThick - fgkRCbThick - fgkRMyThick + fgkCraH/2.0;
- sprintf(cTagV,"URRH%02d",iDet);
- sprintf(cTagM,"UC%02d",iDet);
+ snprintf(cTagV,kTag,"URRH%02d",iDet);
+ snprintf(cTagM,kTag,"UC%02d",iDet);
gMC->Gspos(cTagV,2,cTagM,xpos,ypos,zpos,0,"ONLY");
// Fiber layers (radiator)
zpos = 0.0;
- sprintf(cTagV,"URFB%02d",iDet);
- sprintf(cTagM,"UC%02d",iDet);
+ snprintf(cTagV,kTag,"URFB%02d",iDet);
+ snprintf(cTagM,kTag,"UC%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
// Xe/Isobutane layer (drift volume)
zpos = fgkDrZpos;
- sprintf(cTagV,"UJ%02d",iDet);
- sprintf(cTagM,"UB%02d",iDet);
+ snprintf(cTagV,kTag,"UJ%02d",iDet);
+ snprintf(cTagM,kTag,"UB%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
// Upper part
// Xe/Isobutane layer (amplification volume)
zpos = fgkAmZpos;
- sprintf(cTagV,"UK%02d",iDet);
- sprintf(cTagM,"UE%02d",iDet);
+ snprintf(cTagV,kTag,"UK%02d",iDet);
+ snprintf(cTagM,kTag,"UE%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
// Cu layer (wire planes inside amplification volume)
zpos = fgkWrZposA;
- sprintf(cTagV,"UW%02d",iDet);
- sprintf(cTagM,"UK%02d",iDet);
+ snprintf(cTagV,kTag,"UW%02d",iDet);
+ snprintf(cTagM,kTag,"UK%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
zpos = fgkWrZposB;
- sprintf(cTagV,"UW%02d",iDet);
- sprintf(cTagM,"UK%02d",iDet);
+ snprintf(cTagV,kTag,"UW%02d",iDet);
+ snprintf(cTagM,kTag,"UK%02d",iDet);
gMC->Gspos(cTagV,2,cTagM,xpos,ypos,zpos,0,"ONLY");
// Back panel + pad plane + readout part
// Cu layer (pad plane)
zpos = fgkPPdThick/2.0 - fgkCroH/2.0;
- sprintf(cTagV,"UPPD%02d",iDet);
- sprintf(cTagM,"UG%02d",iDet);
+ snprintf(cTagV,kTag,"UPPD%02d",iDet);
+ snprintf(cTagM,kTag,"UG%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
// G10 layer (pad plane)
zpos = fgkPPpThick/2.0 + fgkPPdThick - fgkCroH/2.0;
- sprintf(cTagV,"UPPP%02d",iDet);
- sprintf(cTagM,"UG%02d",iDet);
+ snprintf(cTagV,kTag,"UPPP%02d",iDet);
+ snprintf(cTagM,kTag,"UG%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
// Araldite layer (glue)
zpos = fgkPGlThick/2.0 + fgkPPpThick + fgkPPdThick - fgkCroH/2.0;
- sprintf(cTagV,"UPGL%02d",iDet);
- sprintf(cTagM,"UG%02d",iDet);
+ snprintf(cTagV,kTag,"UPGL%02d",iDet);
+ snprintf(cTagM,kTag,"UG%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
// Carbon layers (carbon fiber mats)
zpos = fgkPCbThick/2.0 + fgkPGlThick + fgkPPpThick + fgkPPdThick - fgkCroH/2.0;
- sprintf(cTagV,"UPCB%02d",iDet);
- sprintf(cTagM,"UG%02d",iDet);
+ snprintf(cTagV,kTag,"UPCB%02d",iDet);
+ snprintf(cTagM,kTag,"UG%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
zpos = -fgkPCbThick/2.0 - fgkPPcThick - fgkPRbThick - fgkPElThick + fgkCroH/2.0;
- sprintf(cTagV,"UPCB%02d",iDet);
- sprintf(cTagM,"UG%02d",iDet);
+ snprintf(cTagV,kTag,"UPCB%02d",iDet);
+ snprintf(cTagM,kTag,"UG%02d",iDet);
gMC->Gspos(cTagV,2,cTagM,xpos,ypos,zpos,0,"ONLY");
// Aramide layer (honeycomb)
zpos = fgkPHcThick/2.0 + fgkPCbThick + fgkPGlThick + fgkPPpThick + fgkPPdThick - fgkCroH/2.0;
- sprintf(cTagV,"UPHC%02d",iDet);
- sprintf(cTagM,"UG%02d",iDet);
+ snprintf(cTagV,kTag,"UPHC%02d",iDet);
+ snprintf(cTagM,kTag,"UG%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
// G10 layer (PCB readout board)
zpos = -fgkPPcThick/2.0 - fgkPRbThick - fgkPElThick + fgkCroH/2.0;
- sprintf(cTagV,"UPPC%02d",iDet);
- sprintf(cTagM,"UG%02d",iDet);
+ snprintf(cTagV,kTag,"UPPC%02d",iDet);
+ snprintf(cTagM,kTag,"UG%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
// Cu layer (traces in readout board)
zpos = -fgkPRbThick/2.0 - fgkPElThick + fgkCroH/2.0;
- sprintf(cTagV,"UPRB%02d",iDet);
- sprintf(cTagM,"UG%02d",iDet);
+ snprintf(cTagV,kTag,"UPRB%02d",iDet);
+ snprintf(cTagM,kTag,"UG%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
// Cu layer (other materials on readout board, incl. screws)
zpos = -fgkPElThick/2.0 + fgkCroH/2.0;
- sprintf(cTagV,"UPEL%02d",iDet);
- sprintf(cTagM,"UG%02d",iDet);
+ snprintf(cTagV,kTag,"UPEL%02d",iDet);
+ snprintf(cTagM,kTag,"UG%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
// Position the inner volumes of the chambers in the frames
// The inner part of the radiator (air)
zpos = 0.0;
- sprintf(cTagV,"UC%02d",iDet);
- sprintf(cTagM,"UX%02d",iDet);
+ snprintf(cTagV,kTag,"UC%02d",iDet);
+ snprintf(cTagM,kTag,"UX%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
// The glue around the radiator
zpos = fgkCraH/2.0 - fgkCdrH/2.0 - fgkCraH/2.0;
- sprintf(cTagV,"UX%02d",iDet);
- sprintf(cTagM,"UB%02d",iDet);
+ snprintf(cTagV,kTag,"UX%02d",iDet);
+ snprintf(cTagM,kTag,"UB%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
// The lower Wacosit frame inside the aluminum frame
zpos = 0.0;
- sprintf(cTagV,"UB%02d",iDet);
- sprintf(cTagM,"UA%02d",iDet);
+ snprintf(cTagV,kTag,"UB%02d",iDet);
+ snprintf(cTagM,kTag,"UA%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
// The inside of the upper Wacosit frame
zpos = 0.0;
- sprintf(cTagV,"UE%02d",iDet);
- sprintf(cTagM,"UD%02d",iDet);
+ snprintf(cTagV,kTag,"UE%02d",iDet);
+ snprintf(cTagM,kTag,"UD%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
// The inside of the upper aluminum frame
zpos = 0.0;
- sprintf(cTagV,"UG%02d",iDet);
- sprintf(cTagM,"UF%02d",iDet);
+ snprintf(cTagV,kTag,"UG%02d",iDet);
+ snprintf(cTagM,kTag,"UF%02d",iDet);
gMC->Gspos(cTagV,1,cTagM,xpos,ypos,zpos,0,"ONLY");
}
zpos = 0.0;
for (Int_t isector = 0; isector < kNsector; isector++) {
if (GetSMstatus(isector)) {
- sprintf(cTagV,"BTRD%d",isector);
+ snprintf(cTagV,kTag,"BTRD%d",isector);
switch (isector) {
case 13:
case 14:
zpos = 0.0;
for (Int_t isector = 0; isector < kNsector; isector++) {
if (GetSMstatus(isector)) {
- sprintf(cTagV,"BTRD%d",isector);
+ snprintf(cTagV,kTag,"BTRD%d",isector);
gMC->Gspos("UTF1",1,cTagV,xpos, ypos,zpos,0,"ONLY");
gMC->Gspos("UTF2",1,cTagV,xpos,-ypos,zpos,0,"ONLY");
}
Float_t ypos = 0.0;
Float_t zpos = 0.0;
- Char_t cTagV[100];
- Char_t cTagM[100];
+ const Int_t kTag = 100;
+ Char_t cTagV[kTag];
+ Char_t cTagM[kTag];
const Int_t kNparTRD = 4;
Float_t parTRD[kNparTRD];
// The aluminum of the cross bars
parSCB[0] = fgkCwidth[ilayer]/2.0 + kSRLdst/2.0;
- sprintf(cTagV,"USF%01d",ilayer);
+ snprintf(cTagV,kTag,"USF%01d",ilayer);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1301-1],parSCB,kNparSCB);
// The empty regions in the cross bars
}
parSCI[2] = parSCB[2] - thkSCB;
parSCI[0] = parSCB[0]/4.0 - kSCBthk;
- sprintf(cTagV,"USI%01d",ilayer);
+ snprintf(cTagV,kTag,"USI%01d",ilayer);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1302-1],parSCI,kNparSCI);
- sprintf(cTagV,"USI%01d",ilayer);
- sprintf(cTagM,"USF%01d",ilayer);
+ snprintf(cTagV,kTag,"USI%01d",ilayer);
+ snprintf(cTagM,kTag,"USF%01d",ilayer);
ypos = 0.0;
zpos = 0.0;
xpos = parSCI[0] + thkSCB/2.0;
xpos = - 3.0 * parSCI[0] - 1.5 * thkSCB;
gMC->Gspos(cTagV,4,cTagM,xpos,ypos,zpos,0,"ONLY");
- sprintf(cTagV,"USF%01d",ilayer);
+ snprintf(cTagV,kTag,"USF%01d",ilayer);
xpos = 0.0;
zpos = fgkVrocsm + fgkSMpltT + parSCB[2] - fgkSheight/2.0
+ ilayer * (fgkCH + fgkVspace);
- fgkClength[ilayer ][2]/2.0 - fgkClength[ilayer ][1])/2.0;
parSCH[2] = kSCHhgt/2.0;
- sprintf(cTagV,"USH%01d",ilayer);
+ snprintf(cTagV,kTag,"USH%01d",ilayer);
gMC->Gsvolu(cTagV,"BOX ",idtmed[1301-1],parSCH,kNparSCH);
xpos = 0.0;
ypos = fgkClength[ilayer][2]/2.0 + fgkClength[ilayer][1] + parSCH[1];
Float_t ypos = 0.0;
Float_t zpos = 0.0;
- Char_t cTagV[100];
+ const Int_t kTag = 100;
+ Char_t cTagV[kTag];
const Int_t kNparBox = 3;
Float_t parBox[kNparBox];
Int_t iDet = GetDetectorSec(ilayer,istack);
- sprintf(cTagV,"UU%02d",iDet);
+ snprintf(cTagV,kTag,"UU%02d",iDet);
parServ[0] = fgkCwidth[ilayer] /2.0;
parServ[1] = fgkClength[ilayer][istack]/2.0 - fgkHspace/2.0;
parServ[2] = fgkCsvH /2.0;
Int_t nMCMrow = GetRowMax(ilayer,istack,0);
Float_t ySize = (GetChamberLength(ilayer,istack) - 2.0*fgkRpadW)
/ ((Float_t) nMCMrow);
- sprintf(cTagV,"UU%02d",iDet);
+ snprintf(cTagV,kTag,"UU%02d",iDet);
for (Int_t iMCMrow = 0; iMCMrow < nMCMrow; iMCMrow++) {
xpos = 0.0;
ypos = (0.5 + iMCMrow) * ySize
Int_t nMCMrow = GetRowMax(ilayer,istack,0);
Float_t ySize = (GetChamberLength(ilayer,istack) - 2.0*fgkRpadW)
/ ((Float_t) nMCMrow);
- sprintf(cTagV,"UU%02d",iDet);
+ snprintf(cTagV,kTag,"UU%02d",iDet);
for (Int_t iMCMrow = 0; iMCMrow < nMCMrow; iMCMrow++) {
xpos = 0.0;
ypos = (0.5 + iMCMrow) * ySize - 1.0
Float_t xSize = (GetChamberWidth(ilayer) - 2.0*fgkCpadW)
/ ((Float_t) nMCMcol + 6); // Introduce 6 gaps
Int_t iMCM[8] = { 1, 2, 3, 5, 8, 9, 10, 12 }; // 0..7 MCM + 6 gap structure
- sprintf(cTagV,"UU%02d",iDet);
+ snprintf(cTagV,kTag,"UU%02d",iDet);
for (Int_t iMCMrow = 0; iMCMrow < nMCMrow; iMCMrow++) {
for (Int_t iMCMcol = 0; iMCMcol < nMCMcol; iMCMcol++) {
xpos = (0.5 + iMCM[iMCMcol]) * xSize + 1.0
/ ((Float_t) GetRowMax(ilayer,istack,0));
ypos = 0.05 * fgkClength[ilayer][istack];
zpos = kDCSz/2.0 - fgkCsvH/2.0;
- sprintf(cTagV,"UU%02d",iDet);
+ snprintf(cTagV,kTag,"UU%02d",iDet);
gMC->Gspos("UDCS",iCopy,cTagV,xpos,ypos,zpos,0,"ONLY");
}
}
/ ((Float_t) GetRowMax(ilayer,istack,0));
ypos = -16.0;
zpos = kORIz/2.0 - fgkCsvH/2.0;
- sprintf(cTagV,"UU%02d",iDet);
+ snprintf(cTagV,kTag,"UU%02d",iDet);
gMC->Gspos("UORI",iCopy ,cTagV,xpos,ypos,zpos,0,"ONLY");
xpos = -fgkCwidth[ilayer]/2.0 + 3.8 * (GetChamberLength(ilayer,istack) - 2.0*fgkRpadW)
/ ((Float_t) GetRowMax(ilayer,istack,0));
ypos = -16.0;
zpos = kORIz/2.0 - fgkCsvH/2.0;
- sprintf(cTagV,"UU%02d",iDet);
+ snprintf(cTagV,kTag,"UU%02d",iDet);
gMC->Gspos("UORI",iCopy+kNdet,cTagV,xpos,ypos,zpos,0,"ONLY");
}
}
// alignable volume of a single readout chamber
//
- Char_t cTagM[100];
- Char_t cTagV[100];
+ const Int_t kTag = 100;
+ Char_t cTagV[kTag];
+ Char_t cTagM[kTag];
Double_t xpos = 0.0;
Double_t ypos = 0.0;
Int_t idet = GetDetectorSec(ilayer,istack);
// Create the assembly for a given ROC
- sprintf(cTagM,"UT%02d",idet);
+ snprintf(cTagM,kTag,"UT%02d",idet);
TGeoVolume *roc = new TGeoVolumeAssembly(cTagM);
// Add the lower part of the chamber (aluminum frame),
xpos = 0.0;
ypos = 0.0;
zpos = fgkCraH/2.0 + fgkCdrH/2.0 - fgkCHsv/2.0;
- sprintf(cTagV,"UA%02d",idet);
+ snprintf(cTagV,kTag,"UA%02d",idet);
TGeoVolume *rocA = gGeoManager->GetVolume(cTagV);
roc->AddNode(rocA,1,new TGeoTranslation(xpos,ypos,zpos));
xpos = fgkCwidth[ilayer]/2.0 + fgkCalWmod/2.0;
ypos = 0.0;
zpos = fgkCraH + fgkCdrH - fgkCalZpos - fgkCalHmod/2.0 - fgkCHsv/2.0;
- sprintf(cTagV,"UZ%02d",idet);
+ snprintf(cTagV,kTag,"UZ%02d",idet);
TGeoVolume *rocZ = gGeoManager->GetVolume(cTagV);
roc->AddNode(rocZ,1,new TGeoTranslation( xpos,ypos,zpos));
roc->AddNode(rocZ,2,new TGeoTranslation(-xpos,ypos,zpos));
xpos = fgkCwidth[ilayer]/2.0 + fgkCwsW/2.0;
ypos = 0.0;
zpos = fgkCraH + fgkCdrH - fgkCwsH/2.0 - fgkCHsv/2.0;
- sprintf(cTagV,"UP%02d",idet);
+ snprintf(cTagV,kTag,"UP%02d",idet);
TGeoVolume *rocP = gGeoManager->GetVolume(cTagV);
roc->AddNode(rocP,1,new TGeoTranslation( xpos,ypos,zpos));
roc->AddNode(rocP,2,new TGeoTranslation(-xpos,ypos,zpos));
xpos = 0.0;
ypos = 0.0;
zpos = fgkCamH/2.0 + fgkCraH + fgkCdrH - fgkCHsv/2.0;
- sprintf(cTagV,"UD%02d",idet);
+ snprintf(cTagV,kTag,"UD%02d",idet);
TGeoVolume *rocD = gGeoManager->GetVolume(cTagV);
roc->AddNode(rocD,1,new TGeoTranslation(xpos,ypos,zpos));
xpos = 0.0;
ypos = 0.0;
zpos = fgkCroH/2.0 + fgkCamH + fgkCraH + fgkCdrH - fgkCHsv/2.0;
- sprintf(cTagV,"UF%02d",idet);
+ snprintf(cTagV,kTag,"UF%02d",idet);
TGeoVolume *rocF = gGeoManager->GetVolume(cTagV);
roc->AddNode(rocF,1,new TGeoTranslation(xpos,ypos,zpos));
xpos = 0.0;
ypos = 0.0;
zpos = fgkCsvH/2.0 + fgkCroH + fgkCamH + fgkCraH + fgkCdrH - fgkCHsv/2.0;
- sprintf(cTagV,"UU%02d",idet);
+ snprintf(cTagV,kTag,"UU%02d",idet);
TGeoVolume *rocU = gGeoManager->GetVolume(cTagV);
roc->AddNode(rocU,1,new TGeoTranslation(xpos,ypos,zpos));
// coordinates <loc> into the coordinates of the ALICE restframe <glb>.
//
- Int_t sector = GetSector(det);
+ Int_t sector = GetSector(det);
+ Float_t phi = 2.0 * TMath::Pi() / (Float_t) fgkNsector * ((Float_t) sector + 0.5);
- glb[0] = loc[0] * fRotB11[sector] - loc[1] * fRotB12[sector];
- glb[1] = loc[0] * fRotB21[sector] + loc[1] * fRotB22[sector];
+ glb[0] = loc[0] * TMath::Cos(phi) - loc[1] * TMath::Sin(phi);
+ glb[1] = loc[0] * TMath::Sin(phi) + loc[1] * TMath::Cos(phi);
glb[2] = loc[2];
return kTRUE;
(layer >= fgkNlayer)) return -1;
Int_t istck = fgkNstack;
- Double_t zmin;
- Double_t zmax;
+ Double_t zmin = 0.0;
+ Double_t zmax = 0.0;
do {
istck--;
case 13:
case 14:
case 15:
+ // Check for holes in from of PHOS
if (istack == 2) {
continue;
}
continue;
}
- // Check for holes in from of PHOS
- if (((isector == 13) || (isector == 14) || (isector == 15)) &&
- (istack == 2)) {
- continue;
- }
-
UShort_t volid = AliGeomManager::LayerToVolUID(iLayer,iModule);
const char *symname = AliGeomManager::SymName(volid);
TGeoPNEntry *pne = gGeoManager->GetAlignableEntry(symname);