/************************************************************************** * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. * * * * Author: The ALICE Off-line Project. * * Contributors are mentioned in the code where appropriate. * * * * Permission to use, copy, modify and distribute this software and its * * documentation strictly for non-commercial purposes is hereby granted * * without fee, provided that the above copyright notice appears in all * * copies and that both the copyright notice and this permission notice * * appear in the supporting documentation. The authors make no claims * * about the suitability of this software for any purpose. It is * * provided "as is" without express or implied warranty. * **************************************************************************/ /* $Id: AliPHOSGeometry.cxx 25590 2008-05-06 07:09:11Z prsnko $ */ //_________________________________________________________________________ // Geometry class for PHOS // PHOS consists of the electromagnetic calorimeter (EMCA) // and a charged particle veto (CPV) // The EMCA/CPV modules are parametrized so that any configuration // can be easily implemented // The title is used to identify the version of CPV used. // // -- Author: Yves Schutz (SUBATECH) & Dmitri Peressounko (RRC "KI" & SUBATECH) // --- ROOT system --- #include "TClonesArray.h" #include "TVector3.h" #include "TParticle.h" #include #include // --- Standard library --- // --- AliRoot header files --- #include "AliLog.h" #include "AliPHOSEMCAGeometry.h" #include "AliPHOSCPVGeometry.h" #include "AliPHOSSupportGeometry.h" #include "AliPHOSGeoUtils.h" ClassImp(AliPHOSGeoUtils) //____________________________________________________________________________ AliPHOSGeoUtils::AliPHOSGeoUtils(): fGeometryEMCA(0x0),fGeometryCPV(0x0),fGeometrySUPP(0x0), fNModules(0),fNCristalsInModule(0),fNPhi(0),fNZ(0), fNumberOfCPVPadsPhi(0),fNumberOfCPVPadsZ(0), fNCellsXInStrip(0),fNCellsZInStrip(0),fNStripZ(0), fCrystalShift(0.),fCryCellShift(0.),fCryStripShift(0.),fCellStep(0.), fPadSizePhi(0.),fPadSizeZ(0.),fCPVBoxSizeY(0.),fMisalArray(0x0) { // default ctor // must be kept public for root persistency purposes, but should never be called by the outside world fXtlArrSize[0]=0.; fXtlArrSize[1]=0.; fXtlArrSize[2]=0.; for(Int_t mod=0; mod<5; mod++){ fEMCMatrix[mod]=0 ; for(Int_t istrip=0; istrip<224; istrip++) fStripMatrix[mod][istrip]=0 ; fCPVMatrix[mod]=0; fPHOSMatrix[mod]=0 ; } } //____________________________________________________________________________ AliPHOSGeoUtils::AliPHOSGeoUtils(const AliPHOSGeoUtils & rhs) : TNamed(rhs), fGeometryEMCA(0x0),fGeometryCPV(0x0),fGeometrySUPP(0x0), fNModules(0),fNCristalsInModule(0),fNPhi(0),fNZ(0), fNumberOfCPVPadsPhi(0),fNumberOfCPVPadsZ(0), fNCellsXInStrip(0),fNCellsZInStrip(0),fNStripZ(0), fCrystalShift(0.),fCryCellShift(0.),fCryStripShift(0.),fCellStep(0.), fPadSizePhi(0.),fPadSizeZ(0.),fCPVBoxSizeY(0.),fMisalArray(0x0) { Fatal("cpy ctor", "not implemented") ; for(Int_t mod=0; mod<5; mod++){ fEMCMatrix[mod]=0 ; for(Int_t istrip=0; istrip<224; istrip++) fStripMatrix[mod][istrip]=0 ; fCPVMatrix[mod]=0; fPHOSMatrix[mod]=0 ; } } //____________________________________________________________________________ AliPHOSGeoUtils::AliPHOSGeoUtils(const Text_t* name, const Text_t* title) : TNamed(name, title), fGeometryEMCA(0x0),fGeometryCPV(0x0),fGeometrySUPP(0x0), fNModules(0),fNCristalsInModule(0),fNPhi(0),fNZ(0), fNumberOfCPVPadsPhi(0),fNumberOfCPVPadsZ(0), fNCellsXInStrip(0),fNCellsZInStrip(0),fNStripZ(0), fCrystalShift(0.),fCryCellShift(0.),fCryStripShift(0.),fCellStep(0.), fPadSizePhi(0.),fPadSizeZ(0.),fCPVBoxSizeY(0.),fMisalArray(0x0) { // ctor only for normal usage fGeometryEMCA = new AliPHOSEMCAGeometry() ; fGeometryCPV = new AliPHOSCPVGeometry() ; fGeometrySUPP = new AliPHOSSupportGeometry() ; fNModules = 5; fNPhi = fGeometryEMCA->GetNPhi() ; fNZ = fGeometryEMCA->GetNZ() ; fNCristalsInModule = fNPhi*fNZ ; fNCellsXInStrip= fGeometryEMCA->GetNCellsXInStrip() ; fNCellsZInStrip= fGeometryEMCA->GetNCellsZInStrip() ; fNStripZ = fGeometryEMCA->GetNStripZ() ; fXtlArrSize[0]=fGeometryEMCA->GetInnerThermoHalfSize()[0] ; //Wery close to the zise of the Xtl set fXtlArrSize[1]=fGeometryEMCA->GetInnerThermoHalfSize()[1] ; //Wery close to the zise of the Xtl set fXtlArrSize[2]=fGeometryEMCA->GetInnerThermoHalfSize()[2] ; //Wery close to the zise of the Xtl set //calculate offset to crystal surface const Float_t * inthermo = fGeometryEMCA->GetInnerThermoHalfSize() ; const Float_t * strip = fGeometryEMCA->GetStripHalfSize() ; const Float_t * splate = fGeometryEMCA->GetSupportPlateHalfSize(); const Float_t * crystal = fGeometryEMCA->GetCrystalHalfSize() ; const Float_t * pin = fGeometryEMCA->GetAPDHalfSize() ; const Float_t * preamp = fGeometryEMCA->GetPreampHalfSize() ; fCrystalShift=-inthermo[1]+strip[1]+splate[1]+crystal[1]-fGeometryEMCA->GetAirGapLed()/2.+pin[1]+preamp[1] ; fCryCellShift=crystal[1]-(fGeometryEMCA->GetAirGapLed()-2*pin[1]-2*preamp[1])/2; fCryStripShift=fCryCellShift+splate[1] ; fCellStep = 2.*fGeometryEMCA->GetAirCellHalfSize()[0] ; fNumberOfCPVPadsPhi = fGeometryCPV->GetNumberOfCPVPadsPhi() ; fNumberOfCPVPadsZ = fGeometryCPV->GetNumberOfCPVPadsZ() ; fPadSizePhi = fGeometryCPV->GetCPVPadSizePhi() ; fPadSizeZ = fGeometryCPV->GetCPVPadSizeZ() ; fCPVBoxSizeY= fGeometryCPV->GetCPVBoxSize(1) ; for(Int_t mod=0; mod<5; mod++){ fEMCMatrix[mod]=0 ; for(Int_t istrip=0; istrip<224; istrip++) fStripMatrix[mod][istrip]=0 ; fCPVMatrix[mod]=0; fPHOSMatrix[mod]=0 ; } } //____________________________________________________________________________ AliPHOSGeoUtils & AliPHOSGeoUtils::operator = (const AliPHOSGeoUtils & /*rvalue*/) { Fatal("assignment operator", "not implemented") ; return *this ; } //____________________________________________________________________________ AliPHOSGeoUtils::~AliPHOSGeoUtils(void) { // dtor if(fGeometryEMCA){ delete fGeometryEMCA; fGeometryEMCA = 0 ; } if(fGeometryCPV){ delete fGeometryCPV; fGeometryCPV=0 ; } if(fGeometrySUPP){ delete fGeometrySUPP ; fGeometrySUPP=0 ; } if(fMisalArray){ delete fMisalArray; fMisalArray=0 ; } for(Int_t mod=0; mod<5; mod++){ delete fEMCMatrix[mod] ; for(Int_t istrip=0; istrip<224; istrip++) delete fStripMatrix[mod][istrip]; delete fCPVMatrix[mod]; delete fPHOSMatrix[mod]; } } //____________________________________________________________________________ Bool_t AliPHOSGeoUtils::AbsToRelNumbering(Int_t absId, Int_t * relid) const { // Converts the absolute numbering into the following array // relid[0] = PHOS Module number 1:fNModules // relid[1] = 0 if PbW04 // = -1 if CPV // relid[2] = Row number inside a PHOS module // relid[3] = Column number inside a PHOS module Float_t id = absId ; Int_t phosmodulenumber = (Int_t)TMath:: Ceil( id / fNCristalsInModule ) ; if ( phosmodulenumber > fNModules ) { // it is a CPV pad id -= fNPhi * fNZ * fNModules ; Float_t nCPV = fNumberOfCPVPadsPhi * fNumberOfCPVPadsZ ; relid[0] = (Int_t) TMath::Ceil( id / nCPV ) ; relid[1] = -1 ; id -= ( relid[0] - 1 ) * nCPV ; relid[2] = (Int_t) TMath::Ceil( id / fNumberOfCPVPadsZ ) ; relid[3] = (Int_t) ( id - ( relid[2] - 1 ) * fNumberOfCPVPadsZ ) ; } else { // it is a PW04 crystal relid[0] = phosmodulenumber ; relid[1] = 0 ; id -= ( phosmodulenumber - 1 ) * fNPhi * fNZ ; relid[2] = (Int_t)TMath::Ceil( id / fNZ ) ; relid[3] = (Int_t)( id - ( relid[2] - 1 ) * fNZ ) ; } return kTRUE ; } //____________________________________________________________________________ Bool_t AliPHOSGeoUtils::RelToAbsNumbering(const Int_t * relid, Int_t & absId) const { // Converts the relative numbering into the absolute numbering // EMCA crystals: // absId = from 1 to fNModules * fNPhi * fNZ // CPV pad: // absId = from N(total PHOS crystals) + 1 // to NCPVModules * fNumberOfCPVPadsPhi * fNumberOfCPVPadsZ if ( relid[1] == 0 ) { // it is a Phos crystal absId = ( relid[0] - 1 ) * fNPhi * fNZ // the offset of PHOS modules + ( relid[2] - 1 ) * fNZ // the offset along phi + relid[3] ; // the offset along z } else { // it is a CPV pad absId = fNPhi * fNZ * fNModules // the offset to separate EMCA crystals from CPV pads + ( relid[0] - 1 ) * fNumberOfCPVPadsPhi * fNumberOfCPVPadsZ // the pads offset of PHOS modules + ( relid[2] - 1 ) * fNumberOfCPVPadsZ // the pads offset of a CPV row + relid[3] ; // the column number } return kTRUE ; } //____________________________________________________________________________ void AliPHOSGeoUtils::RelPosInModule(const Int_t * relid, Float_t & x, Float_t & z) const { // Converts the relative numbering into the local PHOS-module (x, z) coordinates if(relid[1]==0){ //this is PHOS Double_t pos[3]= {0.0,-fCryCellShift,0.}; //Position incide the crystal Double_t posC[3]={0.0,0.0,0.}; //Global position //Shift and possibly apply misalignment corrections Int_t strip=1+((Int_t) TMath::Ceil((Double_t)relid[2]/fNCellsXInStrip))*fNStripZ- (Int_t) TMath::Ceil((Double_t)relid[3]/fNCellsZInStrip) ; pos[0]=((relid[2]-1)%fNCellsXInStrip-fNCellsXInStrip/2+0.5)*fCellStep ; pos[2]=(-(relid[3]-1)%fNCellsZInStrip+fNCellsZInStrip/2-0.5)*fCellStep ; Int_t mod = relid[0] ; const TGeoHMatrix * m2 = GetMatrixForStrip(mod, strip) ; m2->LocalToMaster(pos,posC); //Return to PHOS local system Double_t posL2[3]={posC[0],posC[1],posC[2]}; const TGeoHMatrix *mPHOS2 = GetMatrixForModule(mod) ; mPHOS2->MasterToLocal(posC,posL2); x=posL2[0] ; z=-posL2[2]; return ; } else{//CPV //first calculate position with respect to CPV plain Int_t row = relid[2] ; //offset along x axis Int_t column = relid[3] ; //offset along z axis Double_t pos[3]= {0.0,0.0,0.}; //Position incide the CPV printed circuit Double_t posC[3]={0.0,0.0,0.}; //Global position pos[0] = - ( fNumberOfCPVPadsPhi/2. - row - 0.5 ) * fPadSizePhi ; // position of pad with respect pos[2] = - ( fNumberOfCPVPadsZ /2. - column - 0.5 ) * fPadSizeZ ; // of center of PHOS module //now apply possible shifts and rotations const TGeoHMatrix *m = GetMatrixForCPV(relid[0]) ; m->LocalToMaster(pos,posC); //Return to PHOS local system Double_t posL[3]={0.,0.,0.,} ; const TGeoHMatrix *mPHOS = GetMatrixForPHOS(relid[0]) ; mPHOS->MasterToLocal(posC,posL); x=posL[0] ; z=posL[1]; return ; } } //____________________________________________________________________________ void AliPHOSGeoUtils::RelPosToAbsId(Int_t module, Double_t x, Double_t z, Int_t & absId) const { // converts local PHOS-module (x, z) coordinates to absId //Calculate AbsId using ideal geometry. Should be sufficient for primary particles calculation //(the only place where this method used currently) Int_t relid[4]={module,0,1,1} ; relid[2] = static_cast(TMath::Ceil( x/ fCellStep + fNPhi / 2.) ); relid[3] = fNZ+1-static_cast(TMath::Ceil(-z/ fCellStep + fNZ / 2.) ) ; if(relid[2]<1)relid[2]=1 ; if(relid[3]<1)relid[3]=1 ; if(relid[2]>fNPhi)relid[2]=fNPhi ; if(relid[3]>fNZ)relid[3]=fNZ ; RelToAbsNumbering(relid,absId) ; /* //find Global position if (!gGeoManager){ printf("Geo manager not initialized\n"); abort() ; } Double_t posL[3]={x,-fCrystalShift,-z} ; //Only for EMC!!! Double_t posG[3] ; char path[100] ; sprintf(path,"/ALIC_1/PHOS_%d/PEMC_1/PCOL_1/PTIO_1/PCOR_1/PAGA_1/PTII_1",module) ; if (!gGeoManager->cd(path)){ printf("Geo manager can not find path \n"); abort() ; } TGeoHMatrix *mPHOS = gGeoManager->GetCurrentMatrix(); if (mPHOS){ mPHOS->LocalToMaster(posL,posG); } else{ printf("Geo matrixes are not loaded \n") ; abort() ; } Int_t relid[4] ; gGeoManager->FindNode(posG[0],posG[1],posG[2]) ; //Check that path contains PSTR and extract strip number TString cpath(gGeoManager->GetPath()) ; Int_t indx = cpath.Index("PCEL") ; if(indx==-1){ //for the few events when particle hits between srips use ideal geometry relid[0] = module ; relid[1] = 0 ; relid[2] = static_cast(TMath::Ceil( x/ fCellStep + fNPhi / 2.) ); relid[3] = static_cast(TMath::Ceil(-z/ fCellStep + fNZ / 2.) ) ; if(relid[2]<1)relid[2]=1 ; if(relid[3]<1)relid[3]=1 ; if(relid[2]>fNPhi)relid[2]=fNPhi ; if(relid[3]>fNZ)relid[3]=fNZ ; RelToAbsNumbering(relid,absId) ; } else{ Int_t indx2 = cpath.Index("/",indx) ; if(indx2==-1) indx2=cpath.Length() ; TString cell=cpath(indx+5,indx2-indx-5) ; Int_t icell=cell.Atoi() ; indx = cpath.Index("PSTR") ; indx2 = cpath.Index("/",indx) ; TString strip=cpath(indx+5,indx2-indx-5) ; Int_t iStrip = strip.Atoi() ; Int_t row = fNStripZ - (iStrip - 1) % (fNStripZ) ; Int_t col = (Int_t) TMath::Ceil((Double_t) iStrip/(fNStripZ)) -1 ; // Absid for 8x2-strips. Looks nice :) absId = (module-1)*fNCristalsInModule + row * 2 + (col*fNCellsXInStrip + (icell - 1) / 2)*fNZ - (icell & 1 ? 1 : 0); } */ } //____________________________________________________________________________ void AliPHOSGeoUtils::RelPosToRelId(Int_t module, Double_t x, Double_t z, Int_t * relId) const { //Evaluates RelId of the crystall with given coordinates Int_t absId ; RelPosToAbsId(module, x,z,absId) ; AbsToRelNumbering(absId,relId) ; } //____________________________________________________________________________ void AliPHOSGeoUtils::RelPosInAlice(Int_t id, TVector3 & pos ) const { // Converts the absolute numbering into the global ALICE coordinate system if (!gGeoManager){ AliFatal("Geo manager not initialized\n"); } Int_t relid[4] ; AbsToRelNumbering(id , relid) ; //construct module name if(relid[1]==0){ //this is EMC Double_t ps[3]= {0.0,-fCryStripShift,0.}; //Position incide the crystal Double_t psC[3]={0.0,0.0,0.}; //Global position //Shift and possibly apply misalignment corrections Int_t strip=1+((Int_t) TMath::Ceil((Double_t)relid[2]/fNCellsXInStrip))*fNStripZ- (Int_t) TMath::Ceil((Double_t)relid[3]/fNCellsZInStrip) ; ps[0]=((relid[2]-1)%fNCellsXInStrip-fNCellsXInStrip/2+0.5)*fCellStep ; ps[2]=(-(relid[3]-1)%fNCellsZInStrip+fNCellsZInStrip/2-0.5)*fCellStep ; Int_t mod = relid[0] ; const TGeoHMatrix * m2 = GetMatrixForStrip(mod, strip) ; m2->LocalToMaster(ps,psC); pos.SetXYZ(psC[0],psC[1],psC[2]) ; } else{ //first calculate position with respect to CPV plain Int_t row = relid[2] ; //offset along x axis Int_t column = relid[3] ; //offset along z axis Double_t ps[3]= {0.0,fCPVBoxSizeY/2.,0.}; //Position on top of CPV Double_t psC[3]={0.0,0.0,0.}; //Global position pos[0] = - ( fNumberOfCPVPadsPhi/2. - row - 0.5 ) * fPadSizePhi ; // position of pad with respect pos[2] = - ( fNumberOfCPVPadsZ /2. - column - 0.5 ) * fPadSizeZ ; // of center of PHOS module //now apply possible shifts and rotations const TGeoHMatrix *m = GetMatrixForCPV(relid[0]) ; m->LocalToMaster(ps,psC); pos.SetXYZ(psC[0],psC[1],-psC[2]) ; } } //____________________________________________________________________________ void AliPHOSGeoUtils::Local2Global(Int_t mod, Float_t x, Float_t z, TVector3& globalPosition) const { Double_t posL[3]={x,-fCrystalShift,-z} ; //Only for EMC!!! Double_t posG[3] ; const TGeoHMatrix *mPHOS = GetMatrixForModule(mod) ; mPHOS->LocalToMaster(posL,posG); globalPosition.SetXYZ(posG[0],posG[1],posG[2]) ; } //____________________________________________________________________________ void AliPHOSGeoUtils::Global2Local(TVector3& localPosition, const TVector3& globalPosition, Int_t module) const { // Transforms a global position to the local coordinate system // of the module //Return to PHOS local system Double_t posG[3]={globalPosition.X(),globalPosition.Y(),globalPosition.Z()} ; Double_t posL[3]={0.,0.,0.} ; const TGeoHMatrix *mPHOS = GetMatrixForModule(module) ; if(mPHOS){ mPHOS->MasterToLocal(posG,posL); localPosition.SetXYZ(posL[0],posL[1]+fCrystalShift,-posL[2]) ; } else{ localPosition.SetXYZ(999.,999.,999.) ; //module does not exist in given configuration } } //____________________________________________________________________________ Bool_t AliPHOSGeoUtils::GlobalPos2RelId(TVector3 & global, Int_t * relId){ //Converts position in global ALICE coordinates to relId //returns false if x,z coordinates are beyond PHOS //distande to PHOS surface is NOT calculated TVector3 loc ; for(Int_t mod=1; mod<=fNModules; mod++){ Global2Local(loc,global,mod) ; //If in Acceptance if((TMath::Abs(loc.Z())Vx(),particle->Vy(),particle->Vz()} ; return ImpactOnEmc(vtx,particle->Theta(),particle->Phi(),moduleNumber,z,x); } //____________________________________________________________________________ Bool_t AliPHOSGeoUtils::ImpactOnEmc(const Double_t * vtx, Double_t theta, Double_t phi, Int_t & moduleNumber, Double_t & z, Double_t & x) const { // calculates the impact coordinates on PHOS of a neutral particle // emitted in the vertex vtx[3] with direction vec(p) in the ALICE global coordinate system TVector3 p(TMath::Sin(theta)*TMath::Cos(phi),TMath::Sin(theta)*TMath::Sin(phi),TMath::Cos(theta)) ; return ImpactOnEmc(vtx,p,moduleNumber,z,x) ; } //____________________________________________________________________________ Bool_t AliPHOSGeoUtils::ImpactOnEmc(const Double_t * vtx, const TVector3 &p, Int_t & moduleNumber, Double_t & z, Double_t & x) const { // calculates the impact coordinates on PHOS of a neutral particle // emitted in the vertex vtx[3] with direction theta and phi in the ALICE global coordinate system TVector3 v(vtx[0],vtx[1],vtx[2]) ; for(Int_t imod=1; imod<=fNModules ; imod++){ //create vector from (0,0,0) to center of crystal surface of imod module Double_t tmp[3]={0.,-fCrystalShift,0.} ; const TGeoHMatrix *m = GetMatrixForModule(imod) ; if(!m) //module does not exist in given configuration continue ; Double_t posG[3]={0.,0.,0.} ; m->LocalToMaster(tmp,posG); TVector3 n(posG[0],posG[1],posG[2]) ; Double_t direction=n.Dot(p) ; if(direction<=0.) continue ; //momentum directed FROM module Double_t fr = (n.Mag2()-n.Dot(v))/direction ; //Calculate direction in module plain n-=v+fr*p ; n*=-1. ; if(TMath::Abs(TMath::Abs(n.Z())cd(path)){ AliWarning(Form("Geo manager can not find path %s \n",path)); return 0; } return gGeoManager->GetCurrentMatrix(); } if(fEMCMatrix[mod-1]){ return fEMCMatrix[mod-1] ; } else{ // AliWarning("Can not find PHOS misalignment matrixes\n") ; // AliWarning("Either import TGeoManager from geometry.root or \n"); // AliWarning("read stored matrixes from AliESD Header: \n") ; // AliWarning("AliPHOSGeoUtils::SetMisalMatrixes(header->GetPHOSMisalMatrix()) \n") ; return 0 ; } return 0 ; } //____________________________________________________________________________ const TGeoHMatrix * AliPHOSGeoUtils::GetMatrixForStrip(Int_t mod, Int_t strip)const { //Provides shift-rotation matrix for strip unit of the module mod //If GeoManager exists, take matrixes from it if(gGeoManager){ char path[255] ; snprintf(path,255,"/ALIC_1/PHOS_%d/PEMC_1/PCOL_1/PTIO_1/PCOR_1/PAGA_1/PTII_1/PSTR_%d",mod,strip) ; if (!gGeoManager->cd(path)){ AliWarning(Form("Geo manager can not find path %s \n",path)); return 0 ; } return gGeoManager->GetCurrentMatrix(); } if(fStripMatrix[mod-1][strip-1]){ return fStripMatrix[mod-1][strip-1] ; } else{ AliWarning("Can not find PHOS misalignment matrixes\n") ; AliWarning("Either import TGeoManager from geometry.root or \n"); AliWarning("read stored matrixes from AliESD Header: \n") ; AliWarning("AliPHOSGeoUtils::SetMisalMatrixes(header->GetPHOSMisalMatrix()) \n") ; return 0 ; } return 0 ; } //____________________________________________________________________________ const TGeoHMatrix * AliPHOSGeoUtils::GetMatrixForCPV(Int_t mod)const { //Provides shift-rotation matrix for CPV of the module mod //If GeoManager exists, take matrixes from it if(gGeoManager){ char path[255] ; //now apply possible shifts and rotations snprintf(path,255,"/ALIC_1/PHOS_%d/PCPV_1",mod) ; if (!gGeoManager->cd(path)){ AliWarning(Form("Geo manager can not find path %s \n",path)); return 0 ; } return gGeoManager->GetCurrentMatrix(); } if(fCPVMatrix[mod-1]){ return fCPVMatrix[mod-1] ; } else{ AliWarning("Can not find PHOS misalignment matrixes\n") ; AliWarning("Either import TGeoManager from geometry.root or \n"); AliWarning("read stored matrixes from AliESD Header: \n") ; AliWarning("AliPHOSGeoUtils::SetMisalMatrixes(header->GetPHOSMisalMatrix()) \n") ; return 0 ; } return 0 ; } //____________________________________________________________________________ const TGeoHMatrix * AliPHOSGeoUtils::GetMatrixForPHOS(Int_t mod)const { //Provides shift-rotation matrix for PHOS (EMC+CPV) //If GeoManager exists, take matrixes from it if(gGeoManager){ char path[255] ; snprintf(path,255,"/ALIC_1/PHOS_%d",mod) ; if (!gGeoManager->cd(path)){ AliWarning(Form("Geo manager can not find path %s \n",path)); return 0 ; } return gGeoManager->GetCurrentMatrix(); } if(fPHOSMatrix[mod-1]){ return fPHOSMatrix[mod-1] ; } else{ AliWarning("Can not find PHOS misalignment matrixes\n") ; AliWarning("Either import TGeoManager from geometry.root or \n"); AliWarning("read stored matrixes from AliESD Header: \n") ; AliWarning("AliPHOSGeoUtils::SetMisalMatrixes(header->GetPHOSMisalMatrix()) \n") ; return 0 ; } return 0 ; } //____________________________________________________________________________ void AliPHOSGeoUtils::SetMisalMatrix(const TGeoHMatrix * m, Int_t mod){ //Fills pointers to geo matrixes if(fPHOSMatrix[mod]){ //have been set already. Can not be changed any more return ; } if(m==NULL) //Matrix for non-existing modules? Remain zero, no need to re-set return ; fPHOSMatrix[mod]= new TGeoHMatrix(*m) ; //Calculate maxtrices for PTII if(!fMisalArray) fMisalArray = new TClonesArray("TGeoHMatrix",1120+10) ; Int_t nr = fMisalArray->GetEntriesFast() ; Double_t rotEMC[9]={1.,0.,0.,0.,0.,-1.,0.,1.,0.} ; const Float_t * inthermo = fGeometryEMCA->GetInnerThermoHalfSize() ; const Float_t * strip = fGeometryEMCA->GetStripHalfSize() ; const Float_t * covparams = fGeometryEMCA->GetAlCoverParams() ; const Float_t * warmcov = fGeometryEMCA->GetWarmAlCoverHalfSize() ; Float_t z = fGeometryCPV->GetCPVBoxSize(1) / 2. - warmcov[2] + covparams[3]-inthermo[1] ; Double_t locTII[3]={0.,0.,z} ; Double_t globTII[3] ; if (fEMCMatrix[mod] == NULL) fEMCMatrix[mod] = new((*fMisalArray)[nr])TGeoHMatrix() ; nr++ ; fEMCMatrix[mod]->SetRotation(rotEMC) ; fEMCMatrix[mod]->MultiplyLeft(fPHOSMatrix[mod]) ; fPHOSMatrix[mod]->LocalToMaster(locTII,globTII) ; fEMCMatrix[mod]->SetTranslation(globTII) ; //Now calculate ideal matrixes for strip misalignment. //For the moment we can not store them in ESDHeader Double_t loc[3]={0.,inthermo[1] - strip[1],0.} ; Double_t glob[3] ; Int_t istrip=0 ; for(Int_t irow = 0; irow < fGeometryEMCA->GetNStripX(); irow ++){ loc[0] = (2*irow + 1 - fGeometryEMCA->GetNStripX())* strip[0] ; for(Int_t icol = 0; icol < fGeometryEMCA->GetNStripZ(); icol ++){ loc[2] = (2*icol + 1 - fGeometryEMCA->GetNStripZ()) * strip[2] ; fEMCMatrix[mod]->LocalToMaster(loc,glob) ; if (fStripMatrix[mod][istrip] == NULL) fStripMatrix[mod][istrip] = new((*fMisalArray)[nr])TGeoHMatrix(*(fEMCMatrix[mod])) ; //Use same rotation as PHOS module nr++ ; fStripMatrix[mod][istrip]->SetTranslation(glob) ; istrip++; } } //Now calculate CPV matrixes const Float_t * emcParams = fGeometryEMCA->GetEMCParams() ; Double_t globCPV[3] ; Double_t locCPV[3]={0.,0.,- emcParams[3]} ; Double_t rot[9]={1.,0.,0.,0.,0.,1.,0.,-1.,0.} ; if (fCPVMatrix[mod] == NULL) fCPVMatrix[mod] = new((*fMisalArray)[nr])TGeoHMatrix() ; nr++ ; fCPVMatrix[mod]->SetRotation(rot) ; fCPVMatrix[mod]->MultiplyLeft(fPHOSMatrix[mod]) ; fCPVMatrix[mod]->ReflectY(kFALSE) ; fPHOSMatrix[mod]->LocalToMaster(locCPV,globCPV) ; fCPVMatrix[mod]->SetTranslation(globCPV) ; }