* about the suitability of this software for any purpose. It is *
* provided "as is" without express or implied warranty. *
**************************************************************************/
-
/* $Id$ */
-
+/** @file AliFMD.cxx
+ @author Christian Holm Christensen <cholm@nbi.dk>
+ @date Sun Mar 26 17:59:18 2006
+ @brief Implementation of AliFMD base class
+*/
//____________________________________________________________________
//
// Forward Multiplicity Detector based on Silicon wafers. This class
-// contains the base procedures for the Forward Multiplicity detector
-// Detector consists of 5 Si volumes covered pseudorapidity interval
-// from 1.7 to 5.1.
+// is the driver for especially simulation.
+//
+// The Forward Multiplicity Detector consists of 3 sub-detectors FMD1,
+// FMD2, and FMD3, each of which has 1 or 2 rings of silicon sensors.
//
// This is the base class for all FMD manager classes.
//
// The actual code is done by various separate classes. Below is
// diagram showing the relationship between the various FMD classes
-// that handles the geometry
+// that handles the simulation
//
//
// +----------+ +----------+
-// | AliFMDv1 | | AliFMDv1 |
+// | AliFMDv1 | | AliFMDv0 |
// +----------+ +----------+
-// | |
-// +----+--------------+
-// |
-// | +------------+ 1 +---------------+
-// | +- | AliFMDRing |<>--| AliFMDPolygon |
-// V 2 | +------------+ +---------------+
-// +--------+<>--+ |
-// | AliFMD | ^
-// +--------+<>--+ V 1..2
-// 3 | +-------------------+
-// +-| AliFMDSubDetector |
-// +-------------------+
-// ^
-// |
-// +-------------+-------------+
-// | | |
-// +---------+ +---------+ +---------+
-// | AliFMD1 | | AliFMD2 | | AliFMD3 |
-// +---------+ +---------+ +---------+
-//
+// | | +-----------------+
+// +----+--------------+ +--| AliFMDDigitizer |
+// | | +-----------------+
+// | +---------------------+ |
+// | +--| AliFMDBaseDigitizer |<--+
+// V 1 | +---------------------+ |
+// +--------+<>--+ | +------------------+
+// | AliFMD | +--| AliFMDSDigitizer |
+// +--------+<>--+ +------------------+
+// 1 | +---------------------+
+// +--| AliFMDReconstructor |
+// +---------------------+
//
// * AliFMD
// This defines the interface for the various parts of AliROOT that
-// uses the FMD, like AliFMDDigitizer, AliFMDReconstructor, and so
-// on.
+// uses the FMD, like AliFMDSimulator, AliFMDDigitizer,
+// AliFMDReconstructor, and so on.
+//
+// * AliFMDv0
+// This is a concrete implementation of the AliFMD interface.
+// It is the responsibility of this class to create the FMD
+// geometry.
//
// * AliFMDv1
// This is a concrete implementation of the AliFMD interface.
// geometry, process hits in the FMD, and serve hits and digits to
// the various clients.
//
-// It uses the objects of class AliFMDSubDetector to do the various
-// stuff for FMD1, 2, and 3
-//
-// * AliFMDRing
-// This class contains all stuff needed to do with a ring. It's
-// used by the AliFMDSubDetector objects to instantise inner and
-// outer rings. The AliFMDRing objects are shared by the
-// AliFMDSubDetector objects, and owned by the AliFMDv1 object.
-//
-// * AliFMDPolygon
-// The code I lifted from TGeoPolygon to help with the geometry of
-// the modules, as well as to decide wether a hit is actually with
-// in the real module shape. The point is, that the shape of the
-// various ring modules are really polygons (much like the lid of a
-// coffin), but it's segmented at constant radius. That is very
-// hard to implement using GEANT 3.21 shapes, so instead the
-// modules are implemented as TUBS (tube sections), and in the step
-// procedure we do the test whether the track was inside the real
-// shape of the module.
-//
-// * AliFMD1, AliFMD2, and AliFMD3
-// These are specialisation of AliFMDSubDetector, that contains the
-// particularities of each of the sub-detector system. It is
-// envisioned that the classes should also define the support
-// volumes and material for each of the detectors.
+// * AliFMDSimulator
+// This is the base class for the FMD simulation tasks. The
+// simulator tasks are responsible to implment the geoemtry, and
+// process hits.
//
-// The responsible person for this module is Alla Maevskaia
-// <Alla.Maevskaia@cern.ch>.
+// * AliFMDReconstructor
+// This is a concrete implementation of the AliReconstructor that
+// reconstructs pseudo-inclusive-multiplicities from digits (raw or
+// from simulation)
//
-// Many modifications by Christian Holm Christensen <cholm@nbi.dk>
+// Calibration and geometry parameters are managed by separate
+// singleton managers. These are AliFMDGeometry and
+// AliFMDParameters. Please refer to these classes for more
+// information on these.
//
-#include "TClonesArray.h" // ROOT_TClonesArray
-#include "TGeometry.h" // ROOT_TGeomtry
-#include "TNode.h" // ROOT_TNode
-#include "TTUBE.h" // ROOT_TTUBE
-#include "TTree.h" // ROOT_TTree
-#include "TVirtualMC.h" // ROOT_TVirtualMC
-#include "TBrowser.h" // ROOT_TBrowser
-#include "TMath.h" // ROOT_TMath
-
-#include "AliRunDigitizer.h" // ALIRUNDIGITIZER_H
-#include "AliLoader.h" // ALILOADER_H
-#include "AliRun.h" // ALIRUN_H
-#include "AliMC.h" // ALIMC_H
-#include "AliLog.h" // ALILOG_H
-#include "AliMagF.h" // ALIMAGF_H
+// These files are not in the same directory, so there's no reason to
+// ask the preprocessor to search in the current directory for these
+// files by including them with `#include "..."'
+#include <cmath> // __CMATH__
+#include <TClonesArray.h> // ROOT_TClonesArray
+#include <TGeometry.h> // ROOT_TGeomtry
+#include <TNode.h> // ROOT_TNode
+#include <TXTRU.h> // ROOT_TXTRU
+#include <TRotMatrix.h> // ROOT_TRotMatrix
+#include <TTUBE.h> // ROOT_TTUBE
+#include <TTree.h> // ROOT_TTree
+#include <TBrowser.h> // ROOT_TBrowser
+// #include <TVirtualMC.h> // ROOT_TVirtualMC
+#include <TVector2.h> // ROOT_TVector2
+#include <TGeoManager.h> // ROOT_TGeoManager
+
+#include <AliRunDigitizer.h> // ALIRUNDIGITIZER_H
+#include <AliLoader.h> // ALILOADER_H
+#include <AliRun.h> // ALIRUN_H
+#include <AliMC.h> // ALIMC_H
+#include <AliMagF.h> // ALIMAGF_H
+#include <AliLog.h> // ALILOG_H
#include "AliFMD.h" // ALIFMD_H
-#include "AliFMDDigit.h" // ALIFMDDIGIG_H
+#include "AliFMDDigit.h" // ALIFMDDIGIT_H
+#include "AliFMDSDigit.h" // ALIFMDSDIGIT_H
#include "AliFMDHit.h" // ALIFMDHIT_H
+#include "AliFMDGeometry.h" // ALIFMDGEOMETRY_H
+#include "AliFMDDetector.h" // ALIFMDDETECTOR_H
+#include "AliFMDRing.h" // ALIFMDRING_H
#include "AliFMDDigitizer.h" // ALIFMDDIGITIZER_H
-#include "AliFMD1.h" // ALIFMD1_H
-#include "AliFMD2.h" // ALIFMD2_H
-#include "AliFMD3.h" // ALIFMD3_H
+#include "AliFMDSDigitizer.h" // ALIFMDSDIGITIZER_H
+// #include "AliFMDGeometryBuilder.h"
#include "AliFMDRawWriter.h" // ALIFMDRAWWRITER_H
+#include "AliFMDPoints.h" // ALIFMDPOINTS_H
//____________________________________________________________________
-ClassImp(AliFMD);
+ClassImp(AliFMD)
+#if 0
+ ; // This is to keep Emacs from indenting the next line
+#endif
//____________________________________________________________________
AliFMD::AliFMD()
- : fInner(0),
- fOuter(0),
- fFMD1(0),
- fFMD2(0),
- fFMD3(0),
+ : AliDetector(),
fSDigits(0),
fNsdigits(0),
- fSiDensity(0),
- fPrintboardRotationId(0),
- fIdentityRotationId(0),
- fShortLegId(0),
- fLongLegId(0),
- fLegLength(0),
- fLegRadius(0),
- fModuleSpacing(0)
+ fDetailed(kTRUE),
+ fUseOld(kFALSE),
+ fUseAssembly(kTRUE),
+ fBad(0)
{
//
// Default constructor for class AliFMD
//
- AliDebug(0, "Default CTOR");
- fHits = 0;
- fDigits = 0;
- fIshunt = 0;
+ AliDebug(10, "\tDefault CTOR");
+ fHits = 0;
+ fDigits = 0;
+ fIshunt = 0;
+ fBad = new TClonesArray("AliFMDHit");
}
//____________________________________________________________________
-AliFMD::AliFMD(const char *name, const char *title, bool detailed)
+AliFMD::AliFMD(const char *name, const char *title)
: AliDetector (name, title),
- fInner(0),
- fOuter(0),
- fFMD1(0),
- fFMD2(0),
- fFMD3(0),
fSDigits(0),
fNsdigits(0),
- fSiDensity(0),
- fPrintboardRotationId(0),
- fIdentityRotationId(0),
- fShortLegId(0),
- fLongLegId(0),
- fLegLength(0),
- fLegRadius(0),
- fModuleSpacing(0)
+ fDetailed(kTRUE),
+ fUseOld(kFALSE),
+ fUseAssembly(kFALSE),
+ fBad(0)
{
//
// Standard constructor for Forward Multiplicity Detector
//
- AliDebug(0, "Standard CTOR");
-
+ AliDebug(10, "\tStandard CTOR");
+ fBad = new TClonesArray("AliFMDHit");
+
// Initialise Hit array
HitsArray();
gAlice->GetMCApp()->AddHitList(fHits);
// CHC: What is this?
fIshunt = 0;
- SetMarkerColor(kRed);
- SetLineColor(kYellow);
- SetSiDensity();
-
- // Create sub-volume managers
- fInner = new AliFMDRing('I', detailed);
- fOuter = new AliFMDRing('O', detailed);
- fFMD1 = new AliFMD1();
- fFMD2 = new AliFMD2();
- fFMD3 = new AliFMD3();
-
- // Specify parameters of sub-volume managers
- fFMD1->SetInner(fInner);
- fFMD1->SetOuter(0);
-
- fFMD2->SetInner(fInner);
- fFMD2->SetOuter(fOuter);
-
- fFMD3->SetInner(fInner);
- fFMD3->SetOuter(fOuter);
-
- SetLegLength();
- SetLegRadius();
- SetLegOffset();
- SetModuleSpacing();
-
- fInner->SetLowR(4.3);
- fInner->SetHighR(17.2);
- fInner->SetWaferRadius(13.4/2);
- fInner->SetTheta(36/2);
- fInner->SetNStrips(512);
- fInner->SetSiThickness(.03);
- fInner->SetPrintboardThickness(.11);
- fInner->SetBondingWidth(.5);
-
- fOuter->SetLowR(15.6);
- fOuter->SetHighR(28.0);
- fOuter->SetWaferRadius(13.4/2);
- fOuter->SetTheta(18/2);
- fOuter->SetNStrips( 256);
- fOuter->SetSiThickness(.03);
- fOuter->SetPrintboardThickness(.1);
- fOuter->SetBondingWidth(.5);
-
-
- fFMD1->SetHoneycombThickness(1);
- fFMD1->SetInnerZ(340.0);
-
- fFMD2->SetHoneycombThickness(1);
- fFMD2->SetInnerZ(83.4);
- fFMD2->SetOuterZ(75.2);
-
- fFMD3->SetHoneycombThickness(1);
- fFMD3->SetInnerZ(-62.8);
- fFMD3->SetOuterZ(-75.2);
+ //PH SetMarkerColor(kRed);
+ //PH SetLineColor(kYellow);
}
//____________________________________________________________________
delete fSDigits;
fSDigits = 0;
}
+ if (fBad) {
+ fBad->Delete();
+ delete fBad;
+ fBad = 0;
+ }
}
+
//====================================================================
//
// GEometry ANd Traking
{
//
// Create the geometry of Forward Multiplicity Detector. The actual
- // construction of the geometry is delegated to the class AliFMDRing
- // and AliFMDSubDetector and the relevant derived classes.
- //
- // The flow of this member function is:
+ // construction of the geometry is delegated to the class
+ // AliFMDGeometryBuilder, invoked by the singleton manager
+ // AliFMDGeometry.
//
- // FOR rings fInner and fOuter DO
- // AliFMDRing::Init();
- // END FOR
- //
- // Set up hybrud card support (leg) volume shapes
- //
- // FOR rings fInner and fOuter DO
- // AliFMDRing::SetupGeometry();
- // END FOR
- //
- // FOR subdetectors fFMD1, fFMD2, and fFMD3 DO
- // AliFMDSubDetector::SetupGeomtry();
- // END FOR
- //
- // FOR subdetectors fFMD1, fFMD2, and fFMD3 DO
- // AliFMDSubDetector::Geomtry();
- // END FOR
- //
-
- // DebugGuard guard("AliFMD::CreateGeometry");
- AliDebug(10, "Creating geometry");
-
- fInner->Init();
- fOuter->Init();
-
- TString name;
- Double_t par[3];
-
- par[0] = fLegRadius - .1;
- par[1] = fLegRadius;
- par[2] = fLegLength / 2;
- name = "FSL";
- fShortLegId = gMC->Gsvolu(name.Data(),"TUBE",(*fIdtmed)[kPlasticId],par,3);
-
- par[2] += fModuleSpacing / 2;
- name = "FLL";
- fLongLegId = gMC->Gsvolu(name.Data(),"TUBE",(*fIdtmed)[kPlasticId],par,3);
-
- fInner->SetupGeometry((*fIdtmed)[kAirId],
- (*fIdtmed)[kSiId],
- (*fIdtmed)[kPcbId],
- fPrintboardRotationId,
- fIdentityRotationId);
- fOuter->SetupGeometry((*fIdtmed)[kAirId],
- (*fIdtmed)[kSiId],
- (*fIdtmed)[kPcbId],
- fPrintboardRotationId,
- fIdentityRotationId);
-
- fFMD1->SetupGeometry((*fIdtmed)[kAirId], (*fIdtmed)[kKaptionId]);
- fFMD2->SetupGeometry((*fIdtmed)[kAirId], (*fIdtmed)[kKaptionId]);
- fFMD3->SetupGeometry((*fIdtmed)[kAirId], (*fIdtmed)[kKaptionId]);
-
- fFMD1->Geometry("ALIC", fPrintboardRotationId, fIdentityRotationId);
- fFMD2->Geometry("ALIC", fPrintboardRotationId, fIdentityRotationId);
- fFMD3->Geometry("ALIC", fPrintboardRotationId, fIdentityRotationId);
+ AliFMDGeometry* fmd = AliFMDGeometry::Instance();
+ fmd->SetDetailed(fDetailed);
+ fmd->UseAssembly(fUseAssembly);
+ fmd->Build();
}
//____________________________________________________________________
void AliFMD::CreateMaterials()
{
- // Register various materials and tracking mediums with the
- // backend.
+ // Define the materials and tracking mediums needed by the FMD
+ // simulation. These mediums are made by sending the messages
+ // AliMaterial, AliMixture, and AliMedium to the passed AliModule
+ // object module. The defined mediums are
//
- // Currently defined materials and mediums are
- //
- // FMD Air Normal air
- // FMD Si Active silicon of sensors
- // FMD Carbon Normal carbon used in support, etc.
- // FMD Kapton Carbon used in Honeycomb
- // FMD PCB Printed circuit board material
- // FMD Plastic Material for support legs
- //
- // Also defined are two rotation matricies.
+ // FMD Si$ Silicon (active medium in sensors)
+ // FMD C$ Carbon fibre (support cone for FMD3 and vacuum pipe)
+ // FMD Al$ Aluminium (honeycomb support plates)
+ // FMD PCB$ Printed Circuit Board (FEE board with VA1_3)
+ // FMD Chip$ Electronics chips (currently not used)
+ // FMD Air$ Air (Air in the FMD)
+ // FMD Plastic$ Plastic (Support legs for the hybrid cards)
+ //
+ // The geometry builder should really be the one that creates the
+ // materials, but the architecture of AliROOT makes that design
+ // akward. What should happen, was that the AliFMDGeometryBuilder
+ // made the mediums, and that this class retrives pointers from the
+ // TGeoManager, and registers the mediums here. Alas, it's not
+ // really that easy.
//
- // DebugGuard guard("AliFMD::CreateMaterials");
- AliDebug(10, "Creating materials");
+ AliDebug(10, "\tCreating materials");
+ // Get pointer to geometry singleton object.
+ AliFMDGeometry* geometry = AliFMDGeometry::Instance();
+ geometry->Init();
+#if 0
+ if (gGeoManager && gGeoManager->GetMedium("FMD Si$")) {
+ // We need to figure out the some stuff about the geometry
+ fmd->ExtractGeomInfo();
+ return;
+ }
+#endif
Int_t id;
Double_t a = 0;
Double_t z = 0;
// Silicon
a = 28.0855;
z = 14.;
- density = fSiDensity;
+ density = geometry->GetSiDensity();
radiationLength = 9.36;
maxBending = 1;
maxStepSize = .001;
precision = .001;
minStepSize = .001;
id = kSiId;
- AliMaterial(id, "FMD Si$", a, z, density, radiationLength, absorbtionLength);
- AliMedium(kSiId, "FMD Si$",id,1,fieldType,maxField,maxBending,
+ AliMaterial(id, "Si$", a, z, density, radiationLength, absorbtionLength);
+ AliMedium(kSiId, "Si$", id,1,fieldType,maxField,maxBending,
maxStepSize,maxEnergyLoss,precision,minStepSize);
-
+
// Carbon
a = 12.011;
precision = .003;
minStepSize = .003;
id = kCarbonId;
- AliMaterial(id, "FMD Carbon$", a, z, density, radiationLength,
- absorbtionLength);
- AliMedium(kCarbonId, "FMD Carbon$",id,0,fieldType,maxField,maxBending,
- maxStepSize,maxEnergyLoss,precision,minStepSize);
+ AliMaterial(id, "Carbon$", a, z, density, radiationLength, absorbtionLength);
+ AliMedium(kCarbonId, "Carbon$", id,0,fieldType,maxField,maxBending,
+ maxStepSize,maxEnergyLoss,precision,minStepSize);
+
+ // Aluminum
+ a = 26.981539;
+ z = 13.;
+ density = 2.7;
+ radiationLength = 8.9;
+ id = kAlId;
+ AliMaterial(id, "Aluminum$",a,z, density, radiationLength, absorbtionLength);
+ AliMedium(kAlId, "Aluminum$", id, 0, fieldType, maxField, maxBending,
+ maxStepSize, maxEnergyLoss, precision, minStepSize);
+
+
+ // Copper
+ a = 63.546;
+ z = 29;
+ density = 8.96;
+ radiationLength = 1.43;
+ id = kCopperId;
+ AliMaterial(id, "Copper$",
+ a, z, density, radiationLength, absorbtionLength);
+ AliMedium(kCopperId, "Copper$", id, 0, fieldType, maxField, maxBending,
+ maxStepSize, maxEnergyLoss, precision, minStepSize);
+
// Silicon chip
{
Float_t as[] = { 12.0107, 14.0067, 15.9994,
- 1.00794, 28.0855, 107.8682 };
+ 1.00794, 28.0855, 107.8682 };
Float_t zs[] = { 6., 7., 8.,
1., 14., 47. };
Float_t ws[] = { 0.039730642, 0.001396798, 0.01169634,
0.004367771, 0.844665, 0.09814344903 };
- density = 2.36436;
+ density = 2.36436;
maxBending = 10;
maxStepSize = .01;
precision = .003;
minStepSize = .003;
- id = kSiChipId;
- AliMixture(id, "FMD Si Chip$", as, zs, density, 6, ws);
- AliMedium(kSiChipId, "FMD Si Chip$", id, 0, fieldType, maxField,
- maxBending, maxStepSize, maxEnergyLoss, precision, minStepSize);
+ id = kSiChipId;
+ AliMixture(id, "Si Chip$", as, zs, density, 6, ws);
+ AliMedium(kSiChipId, "Si Chip$", id, 0, fieldType, maxField, maxBending,
+ maxStepSize, maxEnergyLoss, precision, minStepSize);
}
-
- // Kaption
+ // Kaption
{
Float_t as[] = { 1.00794, 12.0107, 14.010, 15.9994};
Float_t zs[] = { 1., 6., 7., 8.};
maxStepSize = .001;
precision = .001;
minStepSize = .001;
- id = kKaptionId;
- AliMixture(id, "FMD Kaption$", as, zs, density, 4, ws);
- AliMedium(kKaptionId, "FMD Kaption$",id,0,fieldType,maxField,maxBending,
+ id = kKaptonId;
+ AliMixture(id, "Kaption$", as, zs, density, 4, ws);
+ AliMedium(kKaptonId, "Kaption$", id,0,fieldType,maxField,maxBending,
maxStepSize,maxEnergyLoss,precision,minStepSize);
}
-
+
// Air
{
Float_t as[] = { 12.0107, 14.0067, 15.9994, 39.948 };
precision = .001;
minStepSize = .001;
id = kAirId;
- AliMixture(id, "FMD Air$", as, zs, density, 4, ws);
- AliMedium(kAirId, "FMD Air$", id,0,fieldType,maxField,maxBending,
+ AliMixture(id, "Air$", as, zs, density, 4, ws);
+ AliMedium(kAirId, "Air$", id,0,fieldType,maxField,maxBending,
maxStepSize,maxEnergyLoss,precision,minStepSize);
}
precision = .001;
minStepSize = .001;
id = kPcbId;
- AliMixture(id, "FMD PCB$", as, zs, density, 14, ws);
- AliMedium(kPcbId, "FMD PCB$", id,1,fieldType,maxField,maxBending,
+ AliMixture(id, "PCB$", as, zs, density, 14, ws);
+ AliMedium(kPcbId, "PCB$", id,0,fieldType,maxField,maxBending,
maxStepSize,maxEnergyLoss,precision,minStepSize);
}
precision = .003;
minStepSize = .003;
id = kPlasticId;
- AliMixture(id, "FMD Plastic$", as, zs, density, -2, ws);
- AliMedium(kPlasticId, "FMD Plastic$", id,0,fieldType,maxField,maxBending,
- maxStepSize,maxEnergyLoss,precision,minStepSize);
+ AliMixture(id, "Plastic$", as, zs, density, -2, ws);
+ AliMedium(kPlasticId, "Plastic$", id,0,fieldType,maxField,maxBending,
+ maxStepSize,maxEnergyLoss,precision,minStepSize);
}
- AliMatrix(fPrintboardRotationId, 90, 90, 0, 90, 90, 0);
- AliMatrix(fIdentityRotationId, 90, 0, 90, 90, 0, 0);
}
//____________________________________________________________________
void
AliFMD::Init()
{
- //
- // Initialis the FMD after it has been built
- Int_t i;
- //
- if (fDebug) {
- cout << "\n" << ClassName() << ": " << flush;
- for (i = 0; i < 35; i++) cout << "*";
- cout << " FMD_INIT ";
- for (i = 0; i < 35; i++) cout << "*";
- cout << "\n" << ClassName() << ": " << flush;
- //
- // Here the FMD initialisation code (if any!)
- for (i = 0; i < 80; i++) cout << "*";
- cout << endl;
+ // Initialize the detector
+ //
+ AliDebug(1, "Initialising FMD detector object");
+ // AliFMDGeometry* fmd = AliFMDGeometry::Instance();
+ // fmd->InitTransformations();
+}
+
+//____________________________________________________________________
+void
+AliFMD::FinishEvent()
+{
+ // Called at the end of the an event in simulations. If the debug
+ // level is high enough, then the `bad' hits are printed.
+ //
+ if (AliLog::GetDebugLevel("FMD", "AliFMD") < 10) return;
+ if (fBad && fBad->GetEntries() > 0) {
+ AliWarning((Form("EndEvent", "got %d 'bad' hits", fBad->GetEntries())));
+ TIter next(fBad);
+ AliFMDHit* hit;
+ while ((hit = static_cast<AliFMDHit*>(next()))) hit->Print("D");
+ fBad->Clear();
}
- //
- //
}
+
//====================================================================
//
// Graphics and event display
AliFMD::BuildGeometry()
{
//
- // Build simple ROOT TNode geometry for event display
- //
- // Build a simplified geometry of the FMD used for event display
- //
- // The actual building of the TNodes is done by
- // AliFMDSubDetector::SimpleGeometry.
- AliDebug(10, "Creating a simplified geometry");
+ // Build simple ROOT TNode geometry for event display. With the new
+ // geometry modeller, TGeoManager, this seems rather redundant.
+ AliDebug(10, "\tCreating a simplified geometry");
+ AliFMDGeometry* fmd = AliFMDGeometry::Instance();
+
+ static TXTRU* innerShape = 0;
+ static TXTRU* outerShape = 0;
+ static TObjArray* innerRot = 0;
+ static TObjArray* outerRot = 0;
+
+ if (!innerShape || !outerShape) {
+ // Make the shapes for the modules
+ for (Int_t i = 0; i < 2; i++) {
+ AliFMDRing* r = 0;
+ switch (i) {
+ case 0: r = fmd->GetRing('I'); break;
+ case 1: r = fmd->GetRing('O'); break;
+ }
+ if (!r) {
+ AliError(Form("no ring found for i=%d", i));
+ return;
+ }
+ Double_t siThick = r->GetSiThickness();
+ const Int_t knv = r->GetNVerticies();
+ Double_t theta = r->GetTheta();
+ Int_t nmod = r->GetNModules();
+
+ TXTRU* shape = new TXTRU(r->GetName(), r->GetTitle(), "void", knv, 2);
+ for (Int_t j = 0; j < knv; j++) {
+ TVector2* vv = r->GetVertex(knv - 1 - j);
+ shape->DefineVertex(j, vv->X(), vv->Y());
+ }
+ shape->DefineSection(0, -siThick / 2, 1, 0, 0);
+ shape->DefineSection(1, +siThick / 2, 1, 0, 0);
+ shape->SetLineColor(kYellow); //PH kYellow is the default line color in FMD
+
+ TObjArray* rots = new TObjArray(nmod);
+ for (Int_t j = 0; j < nmod; j++) {
+ Double_t th = (j + .5) * theta * 2;
+ TString name(Form("FMD_ring_%c_rot_%02d", r->GetId(), j));
+ TString title(Form("FMD Ring %c Rotation # %d", r->GetId(), j));
+ TRotMatrix* rot = new TRotMatrix(name.Data(), title.Data(),
+ 90, th, 90, fmod(90+th,360), 0, 0);
+ rots->AddAt(rot, j);
+ }
+
+ switch (r->GetId()) {
+ case 'i':
+ case 'I': innerShape = shape; innerRot = rots; break;
+ case 'o':
+ case 'O': outerShape = shape; outerRot = rots; break;
+ }
+ }
+ }
+
TNode* top = gAlice->GetGeometry()->GetNode("alice");
- fFMD1->SimpleGeometry(fNodes, top, GetLineColor(), 0);
- fFMD2->SimpleGeometry(fNodes, top, GetLineColor(), 0);
- fFMD3->SimpleGeometry(fNodes, top, GetLineColor(), 0);
+ for (Int_t i = 1; i <= 3; i++) {
+ AliFMDDetector* det = fmd->GetDetector(i);
+ if (!det) {
+ Warning("BuildGeometry", "FMD%d seems to be disabled", i);
+ continue;
+ }
+ Double_t w = 0;
+ Double_t rh = det->GetRing('I')->GetHighR();
+ Char_t id = 'I';
+ if (det->GetRing('O')) {
+ w = TMath::Abs(det->GetRingZ('O') - det->GetRingZ('I'));
+ id = (TMath::Abs(det->GetRingZ('O'))
+ > TMath::Abs(det->GetRingZ('I')) ? 'O' : 'I');
+ rh = det->GetRing('O')->GetHighR();
+ }
+ w += (det->GetRing(id)->GetModuleSpacing() +
+ det->GetRing(id)->GetSiThickness());
+ TShape* shape = new TTUBE(det->GetName(), det->GetTitle(), "void",
+ det->GetRing('I')->GetLowR(), rh, w / 2);
+ Double_t z = (det->GetRingZ('I') - w / 2);
+ if (z > 0) z += det->GetRing(id)->GetModuleSpacing();
+ top->cd();
+ TNode* node = new TNode(det->GetName(), det->GetTitle(), shape,
+ 0, 0, z, 0);
+ fNodes->Add(node);
+
+ for (Int_t j = 0; j < 2; j++) {
+ AliFMDRing* r = 0;
+ TShape* rshape = 0;
+ TObjArray* rots = 0;
+ switch (j) {
+ case 0:
+ r = det->GetRing('I'); rshape = innerShape; rots = innerRot; break;
+ case 1:
+ r = det->GetRing('O'); rshape = outerShape; rots = outerRot; break;
+ }
+ if (!r) continue;
+
+ Double_t siThick = r->GetSiThickness();
+ Int_t nmod = r->GetNModules();
+ Double_t modspace = r->GetModuleSpacing();
+ Double_t rz = - (z - det->GetRingZ(r->GetId()));
+
+ for (Int_t k = 0; k < nmod; k++) {
+ node->cd();
+ Double_t offz = (k % 2 == 1 ? modspace : 0);
+ TRotMatrix* rot = static_cast<TRotMatrix*>(rots->At(k));
+ TString name(Form("%s%c_module_%02d", det->GetName(), r->GetId(),k));
+ TString title(Form("%s%c Module %d", det->GetName(), r->GetId(),k));
+ TNode* mnod = new TNode(name.Data(), title.Data(), rshape,
+ 0, 0, rz - siThick / 2
+ + TMath::Sign(offz,z), rot);
+ mnod->SetLineColor(kYellow); //PH kYellow is the default line color in FMD
+ fNodes->Add(mnod);
+ } // for (Int_t k = 0 ; ...)
+ } // for (Int_t j = 0 ; ...)
+ } // for (Int_t i = 1 ; ...)
}
//____________________________________________________________________
void
-AliFMD::DrawDetector()
+AliFMD::LoadPoints(Int_t /* track */)
{
+ // Store x, y, z of all hits in memory for display.
+ //
+ // Normally, the hits are drawn using TPolyMarker3D - however, that
+ // is not very useful for the FMD. Therefor, this member function
+ // is overloaded to make TMarker3D, via the class AliFMDPoints.
+ // AliFMDPoints is a local class.
//
- // Draw a shaded view of the Forward multiplicity detector
- //
- // DebugGuard guard("AliFMD::DrawDetector");
- AliDebug(10, "Draw detector");
-
- //Set ALIC mother transparent
- gMC->Gsatt("ALIC","SEEN",0);
-
- //Set volumes visible
- fFMD1->Gsatt();
- fFMD2->Gsatt();
- fFMD3->Gsatt();
- fInner->Gsatt();
- fOuter->Gsatt();
+ if (!fHits) {
+ AliError(Form("fHits == 0. Name is %s",GetName()));
+ return;
+ }
+ Int_t nHits = fHits->GetEntriesFast();
+ if (nHits == 0) {
+ return;
+ }
+ Int_t tracks = gAlice->GetMCApp()->GetNtrack();
+ if (fPoints == 0) fPoints = new TObjArray(2 * tracks);
+
+ // Get geometry
+ AliFMDGeometry* geom = AliFMDGeometry::Instance();
+ geom->Init();
+ geom->InitTransformations();
+
+ // Now make markers for each hit
+ // AliInfo(Form("Drawing %d hits (have %d points) for track %d",
+ // nHits, fPoints->GetEntriesFast(), track));
+ for (Int_t ihit = 0; ihit < nHits; ihit++) {
+ AliFMDHit* hit = static_cast<AliFMDHit*>(fHits->At(ihit));
+ if (!hit) continue;
+ Double_t edep = hit->Edep();
+ Double_t m = hit->M();
+ Double_t poverm = (m == 0 ? 0 : hit->P());
+ Double_t absQ = TMath::Abs(hit->Q());
+ Bool_t bad = kFALSE;
+ // This `if' is to debug abnormal energy depositions. We trigger on
+ // p/m approx larger than or equal to a MIP, and a large edep - more
+ // than 1 keV - a MIP is 100 eV.
+ if (edep > absQ * absQ && poverm > 1) bad = kTRUE;
+
+ AliFMDPoints* p1 = new AliFMDPoints(hit, kRed); //PH kRed is the default marker color in FMD
+ // AliPoints* p1 = new AliPoints();
+ // p1->SetMarkerColor(GetMarkerColor());
+ // p1->SetMarkerSize(GetMarkerSize());
+ // p1->SetPoint(0, hit->X(), hit->Y(), hit->Z());
+ p1->SetDetector(this);
+ p1->SetParticle(hit->GetTrack());
+ fPoints->AddAt(p1, hit->GetTrack());
+ if (bad) {
+ p1->SetMarkerColor(4);
+ // p1->SetMarkerSize(2 * GetMarkerSize());
+ }
+
+ Double_t x, y, z;
+ geom->Detector2XYZ(hit->Detector(), hit->Ring(), hit->Sector(),
+ hit->Strip(), x, y, z);
+ AliFMDPoints* p = new AliFMDPoints(hit, 3);
+ // AliPoints* p = new AliPoints();
+ // p->SetMarkerColor(3);
+ // p->SetMarkerSize(GetMarkerSize());
+ // p->SetPoint(0, x, y, z);
+ p->SetDetector(this);
+ p->SetParticle(hit->GetTrack());
+ p->SetXYZ(x, y, z);
+ p->SetMarkerColor(3);
+ fPoints->AddAt(p, tracks+hit->GetTrack());
+ if (bad) {
+ p->SetMarkerColor(5);
+ // p->SetMarkerSize(2 * GetMarkerSize());
+ }
+ // AliInfo(Form("Adding point at %d", tracks+hit->GetTrack()));
+ }
+}
- //
- gMC->Gdopt("hide", "on");
- gMC->Gdopt("shad", "on");
- gMC->Gsatt("*", "fill", 7);
- gMC->SetClipBox(".");
- gMC->SetClipBox("*", 0, 1000, -1000, 1000, -1000, 1000);
- gMC->DefaultRange();
- gMC->Gdraw("alic", 40, 30, 0, 12, 12, .055, .055);
- gMC->Gdhead(1111, "Forward Multiplicity Detector");
- gMC->Gdman(16, 10, "MAN");
- gMC->Gdopt("hide", "off");
+//____________________________________________________________________
+void
+AliFMD::DrawDetector()
+{
+ // Draw a shaded view of the Forward multiplicity detector. This
+ // isn't really useful anymore.
+ AliDebug(10, "\tDraw detector");
}
//____________________________________________________________________
-const Int_t
-AliFMD::DistanceToPrimitive(Int_t, Int_t)
+Int_t
+AliFMD::DistancetoPrimitive(Int_t, Int_t)
{
- //
// Calculate the distance from the mouse to the FMD on the screen
- // Dummy routine
+ // Dummy routine.
//
return 9999;
}
}
}
-
-
//____________________________________________________________________
void
AliFMD::SetHitsAddressBranch(TBranch *b)
// hits[9] [Float_t ] Time when the track hit
//
//
- AddHit(track,
- UShort_t(vol[0]), // Detector #
- Char_t(vol[1]), // Ring ID
- UShort_t(vol[2]), // Sector #
- UShort_t(vol[3]), // Strip #
- hits[0], // X
- hits[1], // Y
- hits[2], // Z
- hits[3], // Px
- hits[4], // Py
- hits[5], // Pz
- hits[6], // Energy loss
- Int_t(hits[7]), // PDG
- hits[8]); // Time
+ AddHitByFields(track,
+ UShort_t(vol[0]), // Detector #
+ Char_t(vol[1]), // Ring ID
+ UShort_t(vol[2]), // Sector #
+ UShort_t(vol[3]), // Strip #
+ hits[0], // X
+ hits[1], // Y
+ hits[2], // Z
+ hits[3], // Px
+ hits[4], // Py
+ hits[5], // Pz
+ hits[6], // Energy loss
+ Int_t(hits[7]), // PDG
+ hits[8]); // Time
}
//____________________________________________________________________
-void
-AliFMD::AddHit(Int_t track,
- UShort_t detector,
- Char_t ring,
- UShort_t sector,
- UShort_t strip,
- Float_t x,
- Float_t y,
- Float_t z,
- Float_t px,
- Float_t py,
- Float_t pz,
- Float_t edep,
- Int_t pdg,
- Float_t t)
+AliFMDHit*
+AliFMD::AddHitByFields(Int_t track,
+ UShort_t detector,
+ Char_t ring,
+ UShort_t sector,
+ UShort_t strip,
+ Float_t x,
+ Float_t y,
+ Float_t z,
+ Float_t px,
+ Float_t py,
+ Float_t pz,
+ Float_t edep,
+ Int_t pdg,
+ Float_t t,
+ Float_t l,
+ Bool_t stop)
{
- //
// Add a hit to the list
//
// Parameters:
// edep Energy deposited by track
// pdg Track's particle Id #
// t Time when the track hit
+ // l Track length through the material.
+ // stop Whether track was stopped or disappeared
//
TClonesArray& a = *(HitsArray());
// Search through the list of already registered hits, and see if we
// a new hit, but rather update the energy deposited in the hit.
// This is done, so that a FLUKA based simulation will get the
// number of hits right, not just the enerrgy deposition.
+ AliFMDHit* hit = 0;
for (Int_t i = 0; i < fNhits; i++) {
if (!a.At(i)) continue;
- AliFMDHit* hit = static_cast<AliFMDHit*>(a.At(i));
+ hit = static_cast<AliFMDHit*>(a.At(i));
if (hit->Detector() == detector
&& hit->Ring() == ring
&& hit->Sector() == sector
&& hit->Strip() == strip
&& hit->Track() == track) {
- Warning("AddHit", "already had a hit in FMD%d%c[%2d,%3d] for track # %d,"
- " adding energy (%f) to that hit (%f) -> %f",
- detector, ring, sector, strip, track, edep, hit->Edep(),
- hit->Edep() + edep);
+ AliDebug(1, Form("already had a hit in FMD%d%c[%2d,%3d] for track # %d,"
+ " adding energy (%f) to that hit (%f) -> %f",
+ detector, ring, sector, strip, track, edep, hit->Edep(),
+ hit->Edep() + edep));
hit->SetEdep(hit->Edep() + edep);
- return;
+ return hit;
}
}
// If hit wasn't already registered, do so know.
- new (a[fNhits]) AliFMDHit(fIshunt, track, detector, ring, sector, strip,
- x, y, z, px, py, pz, edep, pdg, t);
+ hit = new (a[fNhits]) AliFMDHit(fIshunt, track, detector, ring, sector,
+ strip, x, y, z, px, py, pz, edep, pdg, t,
+ l, stop);
fNhits++;
+ return hit;
}
//____________________________________________________________________
void
-AliFMD::AddDigit(Int_t* digits)
+AliFMD::AddDigit(Int_t* digits, Int_t*)
{
// Add a digit to the Digit tree
//
// digits[5] [Short_t] ADC Count, -1 if not used
// digits[6] [Short_t] ADC Count, -1 if not used
//
- AddDigit(UShort_t(digits[0]), // Detector #
- Char_t(digits[1]), // Ring ID
- UShort_t(digits[2]), // Sector #
- UShort_t(digits[3]), // Strip #
- UShort_t(digits[4]), // ADC Count1
- Short_t(digits[5]), // ADC Count2
- Short_t(digits[6])); // ADC Count3
+ AddDigitByFields(UShort_t(digits[0]), // Detector #
+ Char_t(digits[1]), // Ring ID
+ UShort_t(digits[2]), // Sector #
+ UShort_t(digits[3]), // Strip #
+ UShort_t(digits[4]), // ADC Count1
+ Short_t(digits[5]), // ADC Count2
+ Short_t(digits[6])); // ADC Count3
}
//____________________________________________________________________
void
-AliFMD::AddDigit(UShort_t detector,
- Char_t ring,
- UShort_t sector,
- UShort_t strip,
- UShort_t count1,
- Short_t count2,
- Short_t count3)
+AliFMD::AddDigitByFields(UShort_t detector,
+ Char_t ring,
+ UShort_t sector,
+ UShort_t strip,
+ UShort_t count1,
+ Short_t count2,
+ Short_t count3)
{
// add a real digit - as coming from data
//
// digits[6] [Short_t] ADC Count, -1 if not used
// digits[7] [Short_t] ADC Count, -1 if not used
//
- AddSDigit(UShort_t(digits[0]), // Detector #
- Char_t(digits[1]), // Ring ID
- UShort_t(digits[2]), // Sector #
- UShort_t(digits[3]), // Strip #
- Float_t(digits[4]), // Edep
- UShort_t(digits[5]), // ADC Count1
- Short_t(digits[6]), // ADC Count2
- Short_t(digits[7])); // ADC Count3
+ AddSDigitByFields(UShort_t(digits[0]), // Detector #
+ Char_t(digits[1]), // Ring ID
+ UShort_t(digits[2]), // Sector #
+ UShort_t(digits[3]), // Strip #
+ Float_t(digits[4]), // Edep
+ UShort_t(digits[5]), // ADC Count1
+ Short_t(digits[6]), // ADC Count2
+ Short_t(digits[7])); // ADC Count3
}
//____________________________________________________________________
void
-AliFMD::AddSDigit(UShort_t detector,
- Char_t ring,
- UShort_t sector,
- UShort_t strip,
- Float_t edep,
- UShort_t count1,
- Short_t count2,
- Short_t count3)
+AliFMD::AddSDigitByFields(UShort_t detector,
+ Char_t ring,
+ UShort_t sector,
+ UShort_t strip,
+ Float_t edep,
+ UShort_t count1,
+ Short_t count2,
+ Short_t count3)
{
// add a summable digit
//
void
AliFMD::ResetSDigits()
{
- //
- // Reset number of digits and the digits array for this detector
+ // Reset number of digits and the digits array for this detector.
//
fNsdigits = 0;
if (fSDigits) fSDigits->Clear();
// Create AliFMDDigit's from AliFMDHit's. This is done by making a
// AliFMDDigitizer, and executing that code.
//
+ Warning("Hits2Digits", "Try not to use this method.\n"
+ "Instead, use AliSimulator");
AliRunDigitizer* manager = new AliRunDigitizer(1, 1);
manager->SetInputStream(0, "galice.root");
manager->SetOutputFile("H2Dfile");
/* AliDigitizer* dig =*/ CreateDigitizer(manager);
manager->Exec("");
+ delete manager;
}
//____________________________________________________________________
// Create AliFMDSDigit's from AliFMDHit's. This is done by creating
// an AliFMDSDigitizer object, and executing it.
//
- AliDigitizer* sdig = new AliFMDSDigitizer("galice.root");
- sdig->Exec("");
+ AliFMDSDigitizer* digitizer = new AliFMDSDigitizer("galice.root");
+ digitizer->Exec("");
+ delete digitizer;
}
AliFMD::CreateDigitizer(AliRunDigitizer* manager) const
{
// Create a digitizer object
- return new AliFMDDigitizer(manager);
+ AliFMDDigitizer* digitizer = new AliFMDDigitizer(manager);
+ return digitizer;
}
//====================================================================
// to that class for more information.
AliFMDRawWriter writer(this);
writer.Exec();
-
-#if 0
- // Digits are read from the Digit branch, and processed to make
- // three DDL files, one for each of the sub-detectors FMD1, FMD2,
- // and FMD3.
- //
- // The raw data files consists of a header, followed by ALTRO
- // formatted blocks.
- //
- // +-------------+
- // | Header |
- // +-------------+
- // | ALTRO Block |
- // | ... |
- // +-------------+
- // DDL file
- //
- // An ALTRO formatted block, in the FMD context, consists of a
- // number of counts followed by a trailer.
- //
- // +------------------+
- // | Count |
- // | ... |
- // | possible fillers |
- // +------------------+
- // | Trailer |
- // +------------------+
- // ALTRO block
- //
- // The counts are listed backwards, that is, starting with the
- // latest count, and ending in the first.
- //
- // Each count consist of 1 or more ADC samples of the VA1_ALICE
- // pre-amp. signal. Just how many samples are used depends on
- // whether the ALTRO over samples the pre-amp. Each sample is a
- // 10-bit word, and the samples are grouped into 40-bit blocks
- //
- // +------------------------------------+
- // | S(n) | S(n-1) | S(n-2) | S(n-3) |
- // | ... | ... | ... | ... |
- // | S(2) | S(1) | AA | AA |
- // +------------------------------------+
- // Counts + possible filler
- //
- // The trailer of the number of words of signales, the starting
- // strip number, the sector number, and the ring ID; each 10-bit
- // words, packed into 40-bits.
- //
- // +------------------------------------+
- // | # words | start | sector | ring |
- // +------------------------------------+
- // Trailer
- //
- // Note, that this method assumes that the digits are ordered.
- //
- AliFMD* fmd = static_cast<AliFMD*>(gAlice->GetDetector(GetName()));
- fLoader->LoadDigits();
- TTree* digitTree = fLoader->TreeD();
- if (!digitTree) {
- Error("Digits2Raw", "no digit tree");
- return;
- }
-
- TClonesArray* digits = new TClonesArray("AliFMDDigit", 1000);
- fmd->SetTreeAddress();
- TBranch* digitBranch = digitTree->GetBranch(GetName());
- if (!digitBranch) {
- Error("Digits2Raw", "no branch for %s", GetName());
- return;
- }
- digitBranch->SetAddress(&digits);
-
- Int_t nEvents = Int_t(digitTree->GetEntries());
- for (Int_t event = 0; event < nEvents; event++) {
- fmd->ResetDigits();
- digitTree->GetEvent(event);
-
- Int_t nDigits = digits->GetEntries();
- if (nDigits < 1) continue;
-
-
- UShort_t prevDetector = 0;
- Char_t prevRing = '\0';
- UShort_t prevSector = 0;
- // UShort_t prevStrip = 0;
-
- // The first seen strip number for a channel
- UShort_t startStrip = 0;
-
- // Which channel number in the ALTRO channel we're at
- UShort_t offset = 0;
-
- // How many times the ALTRO Samples one VA1_ALICE channel
- Int_t sampleRate = 1;
-
- // A buffer to hold 1 ALTRO channel - Normally, one ALTRO channel
- // holds 128 VA1_ALICE channels, sampled at a rate of `sampleRate'
- TArrayI channel(128 * sampleRate);
-
- // The Altro buffer
- AliAltroBuffer* altro = 0;
-
- // Loop over the digits in the event. Note, that we assume the
- // the digits are in order in the branch. If they were not, we'd
- // have to cache all channels before we could write the data to
- // the ALTRO buffer, or we'd have to set up a map of the digits.
- for (Int_t i = 0; i < nDigits; i++) {
- // Get the digit
- AliFMDDigit* digit = static_cast<AliFMDDigit*>(digits->At(i));
-
- UShort_t det = digit->Detector();
- Char_t ring = digit->Ring();
- UShort_t sector = digit->Sector();
- UShort_t strip = digit->Strip();
- if (det != prevDetector) {
- AliDebug(10, Form("FMD: New DDL, was %d, now %d",
- kBaseDDL + prevDetector - 1,
- kBaseDDL + det - 1));
- // If an altro exists, delete the object, flushing the data to
- // disk, and closing the file.
- if (altro) {
- // When the first argument is false, we write the real
- // header.
- AliDebug(10, Form("New altro: Write channel at %d Strip: %d "
- "Sector: %d Ring: %d",
- i, startStrip, prevSector, prevRing));
- // TPC to FMD translations
- //
- // TPC FMD
- // ----------+-----------
- // pad | strip
- // row | sector
- // sector | ring
- //
- altro->WriteChannel(Int_t(startStrip),
- Int_t(prevSector),
- Int_t((prevRing == 'I' ? 0 : 1)),
- channel.fN, channel.fArray, 0);
- altro->Flush();
- altro->WriteDataHeader(kFALSE, kFALSE);
- delete altro;
- altro = 0;
- }
-
- prevDetector = det;
- // Need to open a new DDL!
- Int_t ddlId = kBaseDDL + det - 1;
- TString filename(Form("%s_%d.ddl", GetName(), ddlId));
-
- AliDebug(10, Form("New altro buffer with DDL file %s",
- filename.Data()));
- AliDebug(10, Form("New altro at %d", i));
- // Create a new altro buffer - a `1' as the second argument
- // means `write mode'
- altro = new AliAltroBuffer(filename.Data(), 1);
-
- // Write a dummy (first argument is true) header to the DDL
- // file - later on, when we close the file, we write the real
- // header
- altro->WriteDataHeader(kTRUE, kFALSE);
-
- // Figure out the sample rate
- if (digit->Count2() > 0) sampleRate = 2;
- if (digit->Count3() > 0) sampleRate = 3;
-
- channel.Set(128 * sampleRate);
- offset = 0;
- prevRing = ring;
- prevSector = sector;
- startStrip = strip;
- }
- else if (offset == 128
- || digit->Ring() != prevRing
- || digit->Sector() != prevSector) {
- // Force a new Altro channel
- AliDebug(10, Form("Flushing channel to disk because %s",
- (offset == 128 ? "channel is full" :
- (ring != prevRing ? "new ring up" :
- "new sector up"))));
- AliDebug(10, Form("New Channel: Write channel at %d Strip: %d "
- "Sector: %d Ring: %d",
- i, startStrip, prevSector, prevRing));
- altro->WriteChannel(Int_t(startStrip),
- Int_t(prevSector),
- Int_t((prevRing == 'I' ? 0 : 1)),
- channel.fN, channel.fArray, 0);
- // Reset and update channel variables
- channel.Reset(0);
- offset = 0;
- startStrip = strip;
- prevRing = ring;
- prevSector = sector;
- }
-
- // Store the counts of the ADC in the channel buffer
- channel[offset * sampleRate] = digit->Count1();
- if (sampleRate > 1)
- channel[offset * sampleRate + 1] = digit->Count2();
- if (sampleRate > 2)
- channel[offset * sampleRate + 2] = digit->Count3();
- offset++;
- }
- // Finally, we need to close the final ALTRO buffer if it wasn't
- // already
- if (altro) {
- altro->Flush();
- altro->WriteDataHeader(kFALSE, kFALSE);
- delete altro;
- }
- }
- fLoader->UnloadDigits();
-#endif
-}
-
-//==================================================================
-//
-// Various setter functions for the common paramters
-//
-
-//__________________________________________________________________
-void
-AliFMD::SetLegLength(Double_t length)
-{
- // Set lenght of plastic legs that hold the hybrid (print board and
- // silicon sensor) onto the honeycomp support
- //
- // DebugGuard guard("AliFMD::SetLegLength");
- AliDebug(10, "AliFMD::SetLegLength");
- fLegLength = length;
- fInner->SetLegLength(fLegLength);
- fOuter->SetLegLength(fLegLength);
-}
-
-//__________________________________________________________________
-void
-AliFMD::SetLegOffset(Double_t offset)
-{
- // Set offset from edge of hybrid to plastic legs that hold the
- // hybrid (print board and silicon sensor) onto the honeycomp
- // support
- //
- // DebugGuard guard("AliFMD::SetLegOffset");
- AliDebug(10, "AliFMD::SetLegOffset");
- fInner->SetLegOffset(offset);
- fOuter->SetLegOffset(offset);
-}
-
-//__________________________________________________________________
-void
-AliFMD::SetLegRadius(Double_t radius)
-{
- // Set the diameter of the plastic legs that hold the hybrid (print
- // board and silicon sensor) onto the honeycomp support
- //
- // DebugGuard guard("AliFMD::SetLegRadius");
- AliDebug(10, "AliFMD::SetLegRadius");
- fLegRadius = radius;
- fInner->SetLegRadius(fLegRadius);
- fOuter->SetLegRadius(fLegRadius);
}
-//__________________________________________________________________
-void
-AliFMD::SetModuleSpacing(Double_t spacing)
-{
- // Set the distance between the front and back sensor modules
- // (module staggering).
- //
- // DebugGuard guard("AliFMD::SetModuleSpacing");
- AliDebug(10, "AliFMD::SetModuleSpacing");
- fModuleSpacing = spacing;
- fInner->SetModuleSpacing(fModuleSpacing);
- fOuter->SetModuleSpacing(fModuleSpacing);
-}
//====================================================================
//
{
// Browse this object.
//
- AliDebug(10, "AliFMD::Browse");
+ AliDebug(30, "\tBrowsing the FMD");
AliDetector::Browse(b);
- if (fInner) b->Add(fInner, "Inner Ring");
- if (fOuter) b->Add(fOuter, "Outer Ring");
- if (fFMD1) b->Add(fFMD1, "FMD1 SubDetector");
- if (fFMD2) b->Add(fFMD2, "FMD2 SubDetector");
- if (fFMD3) b->Add(fFMD3, "FMD3 SubDetector");
+ b->Add(AliFMDGeometry::Instance());
}
-
+//____________________________________________________________________
+void
+AliFMD::AddAlignableVolumes() const
+{
+ //
+ // Create entries for alignable volumes associating the symbolic volume
+ // name with the corresponding volume path. Needs to be syncronized with
+ // eventual changes in the geometry.
+ //
+ // This code was made by Raffaele Grosso <rgrosso@mail.cern.ch>. I
+ // (cholm) will probably want to change it. For one, I think it
+ // should be the job of the geometry manager to deal with this.
+ AliFMDGeometry::Instance()->SetAlignableVolumes();
+#if 0
+ for(size_t f = 1; f <= 3; f++){ // Detector 1,2,3
+ for(size_t tb = 0; tb <2 ; tb++){ // Top/Bottom
+ char stb = tb == 0 ? 'T' : 'B';
+ unsigned min = tb == 0 ? 0 : 5;
+
+ TString halfVol(Form("/ALIC_1/F%dM%c_%d", f, stb, f));
+ TString halfSym(halfVol);
+ if(!gGeoManager->SetAlignableEntry(halfSym.Data(),halfVol.Data()))
+ AliFatal(Form("Alignable entry %s not created. "
+ "Volume path %s not valid",
+ halfSym.Data(),halfVol.Data()));
+ for(size_t io = 0; io < 2; io++){ // inner, outer
+ if (f==1 && io==1) continue; // Only one ring in FMD1
+ if(tb == 1 && io==1) min=10;
+ char sio = (io == 0 ? 'I' : 'O');
+ unsigned nio = (io == 0 ? 3 : 9);
+ unsigned max = (io == 0 ? 5 : 10) + min;
+
+ for(size_t i = min; i < max; i++) { // Modules
+ TString modVol(Form("%s/F%c%cV_7%d/F%cSE_%d", halfVol.Data(),
+ sio, stb, nio, sio, i));
+ TString modSym(modVol);
+ if(!gGeoManager->SetAlignableEntry(modSym.Data(),modVol.Data()))
+ AliFatal(Form("Alignable entry %s not created. "
+ "Volume path %s not valid",
+ modSym.Data(), modVol.Data()));
+ }
+ }
+ }
+ }
+#endif
+}
//___________________________________________________________________
//
// EOF