X-Git-Url: http://git.uio.no/git/?a=blobdiff_plain;f=FMD%2FAliFMD.cxx;h=2d699decb1660e66ac71b0ffddeada451ad46ee3;hb=ee8a5fe69a998eb0bd7394b1b7f936c07dc32f7e;hp=483afc9523cb08aaf0f89fee6a79342beefc07ad;hpb=c92eb8ad84d9fea19806972ade69abe6956f4e45;p=u%2Fmrichter%2FAliRoot.git
diff --git a/FMD/AliFMD.cxx b/FMD/AliFMD.cxx
index 483afc9523c..2d699decb16 100644
--- a/FMD/AliFMD.cxx
+++ b/FMD/AliFMD.cxx
@@ -12,338 +12,1138 @@
* about the suitability of this software for any purpose. It is *
* provided "as is" without express or implied warranty. *
**************************************************************************/
-
/* $Id$ */
-
- //////////////////////////////////////////////////////////////////////////////
-// //
-// Forward Multiplicity Detector based on Silicon plates //
-// 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. //
-// //
-//Begin_Html
-/*
- The responsible person for this module is
-Alla Maevskaia.
-
-
-
-
-
+/** @file AliFMD.cxx + @author Christian Holm Christensen+ @date Sun Mar 26 17:59:18 2006 + @brief Implementation of AliFMD base class */ -//End_Html -// // -// // -/////////////////////////////////////////////////////////////////////////////// - -#define DEBUG - -#include -#include - -#include -#include -#include -#include -#include -#include -#include -#include -#include - -#include "AliDetector.h" -#include "AliFMDReconstParticles.h" -#include "AliFMDReconstruction.h" -#include "AliFMDdigit.h" -#include "AliFMDhit.h" -#include "AliFMDv1.h" -#include "AliLoader.h" -#include "AliMagF.h" -#include "AliRun.h" -#include "AliMC.h" -#include "AliFMDDigitizer.h" - -ClassImp (AliFMD) - //_____________________________________________________________________________ -AliFMD::AliFMD ():AliDetector () +//____________________________________________________________________ +// +// Forward Multiplicity Detector based on Silicon wafers. This class +// 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 simulation +// +// +// +----------+ +----------+ +// | AliFMDv1 | | AliFMDv0 | +// +----------+ +----------+ +// | | +-----------------+ +// +----+--------------+ +--| AliFMDDigitizer | +// | | +-----------------+ +// | +---------------------+ | +// | +--| AliFMDBaseDigitizer |<--+ +// V 1 | +---------------------+ | +// +--------+<>--+ | +------------------+ +// | AliFMD | +--| AliFMDSDigitizer | +// +--------+<>--+ +------------------+ +// 1 | +---------------------+ +// +--| AliFMDReconstructor | +// +---------------------+ +// +// * AliFMD +// This defines the interface for the various parts of AliROOT that +// 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. +// It is the responsibility of this class to create the FMD +// geometry, process hits in the FMD, and serve hits and digits to +// the various clients. +// +// * AliFMDSimulator +// This is the base class for the FMD simulation tasks. The +// simulator tasks are responsible to implment the geoemtry, and +// process hits. +// +// * AliFMDReconstructor +// This is a concrete implementation of the AliReconstructor that +// reconstructs pseudo-inclusive-multiplicities from digits (raw or +// from simulation) +// +// 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. +// + +// 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__ +#include // ROOT_TClonesArray +#include // ROOT_TGeomtry +#include // ROOT_TNode +#include // ROOT_TXTRU +#include // ROOT_TRotMatrix +#include // ROOT_TTUBE +#include // ROOT_TTree +#include // ROOT_TBrowser +// #include // ROOT_TVirtualMC +#include // ROOT_TVector2 +#include // ROOT_TGeoManager + +#include // ALIRUNDIGITIZER_H +#include // ALILOADER_H +#include // ALIRUN_H +#include // ALIMC_H +#include // ALIMAGF_H +#include // ALILOG_H +#include "AliFMD.h" // ALIFMD_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 "AliFMDSDigitizer.h" // ALIFMDSDIGITIZER_H +// #include "AliFMDGeometryBuilder.h" +#include "AliFMDRawWriter.h" // ALIFMDRAWWRITER_H +#include "AliFMDPoints.h" // ALIFMDPOINTS_H + +//____________________________________________________________________ +ClassImp(AliFMD) +#if 0 + ; // This is to keep Emacs from indenting the next line +#endif + +//____________________________________________________________________ +AliFMD::AliFMD() + : AliDetector(), + fSDigits(0), + fNsdigits(0), + fDetailed(kTRUE), + fUseOld(kFALSE), + fUseAssembly(kTRUE), + fBad(0) { // // Default constructor for class AliFMD // - fIshunt = 0; - fHits = 0; - fDigits = 0; - fReconParticles=0; + AliDebug(10, "\tDefault CTOR"); + fHits = 0; + fDigits = 0; + fIshunt = 0; + fBad = new TClonesArray("AliFMDHit"); +} + +//____________________________________________________________________ +AliFMD::AliFMD(const AliFMD& other) + : AliDetector(other), + fSDigits(other.fSDigits), + fNsdigits(other.fNsdigits), + fDetailed(other.fDetailed), + fUseOld(other.fUseOld), + fUseAssembly(other.fUseAssembly), + fBad(other.fBad) +{ + // Copy constructor } -//_____________________________________________________________________________ -AliFMD::AliFMD (const char *name, const char *title): -AliDetector (name, title) +//____________________________________________________________________ +AliFMD::AliFMD(const char *name, const char *title) + : AliDetector (name, title), + fSDigits(0), + fNsdigits(0), + fDetailed(kTRUE), + fUseOld(kFALSE), + fUseAssembly(kFALSE), + fBad(0) { // // Standard constructor for Forward Multiplicity Detector // - - // + AliDebug(10, "\tStandard CTOR"); + fBad = new TClonesArray("AliFMDHit"); + // Initialise Hit array - fHits = new TClonesArray ("AliFMDhit", 1000); - // Digits for each Si disk - fDigits = new TClonesArray ("AliFMDdigit", 1000); - fReconParticles=new TClonesArray("AliFMDReconstParticles",1000); - gAlice->GetMCApp()->AddHitList (fHits); + HitsArray(); + gAlice->GetMCApp()->AddHitList(fHits); + // (S)Digits for the detectors disk + DigitsArray(); + SDigitsArray(); + + // CHC: What is this? fIshunt = 0; - // fMerger = 0; - SetMarkerColor (kRed); + SetMarkerColor(kRed); + SetLineColor(kYellow); } -//----------------------------------------------------------------------------- +//____________________________________________________________________ AliFMD::~AliFMD () { - if (fHits) - { - fHits->Delete (); - delete fHits; - fHits = 0; - } - if (fDigits) - { - fDigits->Delete (); - delete fDigits; - fDigits = 0; - } - if (fReconParticles) - { - fReconParticles->Delete (); - delete fReconParticles; - fReconParticles = 0; - } + // Destructor for base class AliFMD + if (fHits) { + fHits->Delete(); + delete fHits; + fHits = 0; + } + if (fDigits) { + fDigits->Delete(); + delete fDigits; + fDigits = 0; + } + if (fSDigits) { + fSDigits->Delete(); + delete fSDigits; + fSDigits = 0; + } + if (fBad) { + fBad->Delete(); + delete fBad; + fBad = 0; + } +} +//____________________________________________________________________ +AliFMD& +AliFMD::operator=(const AliFMD& other) +{ + // Assignment operator + AliDetector::operator=(other); + fSDigits = other.fSDigits; + fNsdigits = other.fNsdigits; + fDetailed = other.fDetailed; + fBad = other.fBad; + return *this; } -//_____________________________________________________________________________ -void AliFMD::AddHit (Int_t track, Int_t * vol, Float_t * hits) +//==================================================================== +// +// GEometry ANd Traking +// +//____________________________________________________________________ +void +AliFMD::CreateGeometry() { // - // Add a hit to the list + // Create the geometry of Forward Multiplicity Detector. The actual + // construction of the geometry is delegated to the class + // AliFMDGeometryBuilder, invoked by the singleton manager + // AliFMDGeometry. + // + AliFMDGeometry* fmd = AliFMDGeometry::Instance(); + fmd->SetDetailed(fDetailed); + fmd->UseAssembly(fUseAssembly); + fmd->Build(); +} + +//____________________________________________________________________ +void AliFMD::CreateMaterials() +{ + // 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 + // + // 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. // - TClonesArray & lhits = *fHits; - new (lhits[fNhits++]) AliFMDhit (fIshunt, track, vol, hits); + AliDebug(10, "\tCreating materials"); + // Get pointer to geometry singleton object. + AliFMDGeometry* geometry = AliFMDGeometry::Instance(); + geometry->Init(); +#if 0 + if (gGeoManager && gGeoManager->GetMedium("FMD Si$")) { + // We need to figure out the some stuff about the geometry + fmd->ExtractGeomInfo(); + return; + } +#endif + Int_t id; + Double_t a = 0; + Double_t z = 0; + Double_t density = 0; + Double_t radiationLength = 0; + Double_t absorbtionLength = 999; + Int_t fieldType = gAlice->Field()->Integ(); // Field type + Double_t maxField = gAlice->Field()->Max(); // Field max. + Double_t maxBending = 0; // Max Angle + Double_t maxStepSize = 0.001; // Max step size + Double_t maxEnergyLoss = 1; // Max Delta E + Double_t precision = 0.001; // Precision + Double_t minStepSize = 0.001; // Minimum step size + + // Silicon + a = 28.0855; + z = 14.; + density = geometry->GetSiDensity(); + radiationLength = 9.36; + maxBending = 1; + maxStepSize = .001; + precision = .001; + minStepSize = .001; + id = kSiId; + AliMaterial(id, "Si$", a, z, density, radiationLength, absorbtionLength); + AliMedium(kSiId, "Si$", id,1,fieldType,maxField,maxBending, + maxStepSize,maxEnergyLoss,precision,minStepSize); + + + // Carbon + a = 12.011; + z = 6.; + density = 2.265; + radiationLength = 18.8; + maxBending = 10; + maxStepSize = .01; + precision = .003; + minStepSize = .003; + id = kCarbonId; + AliMaterial(id, "Carbon$", 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$", id, 0, fieldType, maxField, maxBending, + maxStepSize, maxEnergyLoss, precision, minStepSize); + + + // Silicon chip + { + Float_t as[] = { 12.0107, 14.0067, 15.9994, + 1.00794, 28.0855, 107.8682 }; + Float_t zs[] = { 6., 7., 8., + 1., 14., 47. }; + Float_t ws[] = { 0.039730642, 0.001396798, 0.01169634, + 0.004367771, 0.844665, 0.09814344903 }; + density = 2.36436; + maxBending = 10; + maxStepSize = .01; + precision = .003; + minStepSize = .003; + id = kSiChipId; + AliMixture(id, "Si Chip$", as, zs, density, 6, ws); + AliMedium(kSiChipId, "Si Chip$", id, 0, fieldType, maxField, maxBending, + maxStepSize, maxEnergyLoss, precision, minStepSize); + } + + // Kaption + { + Float_t as[] = { 1.00794, 12.0107, 14.010, 15.9994}; + Float_t zs[] = { 1., 6., 7., 8.}; + Float_t ws[] = { 0.026362, 0.69113, 0.07327, 0.209235}; + density = 1.42; + maxBending = 1; + maxStepSize = .001; + precision = .001; + minStepSize = .001; + id = kKaptonId; + AliMixture(id, "Kaption$", as, zs, density, 4, ws); + AliMedium(kKaptonId, "Kaption$", id,0,fieldType,maxField,maxBending, + maxStepSize,maxEnergyLoss,precision,minStepSize); + } + + // Air + { + Float_t as[] = { 12.0107, 14.0067, 15.9994, 39.948 }; + Float_t zs[] = { 6., 7., 8., 18. }; + Float_t ws[] = { 0.000124, 0.755267, 0.231781, 0.012827 }; + density = .00120479; + maxBending = 1; + maxStepSize = .001; + precision = .001; + minStepSize = .001; + id = kAirId; + AliMixture(id, "Air$", as, zs, density, 4, ws); + AliMedium(kAirId, "Air$", id,0,fieldType,maxField,maxBending, + maxStepSize,maxEnergyLoss,precision,minStepSize); + } + + // PCB + { + Float_t zs[] = { 14., 20., 13., 12., + 5., 22., 11., 19., + 26., 9., 8., 6., + 7., 1.}; + Float_t as[] = { 28.0855, 40.078, 26.981538, 24.305, + 10.811, 47.867, 22.98977, 39.0983, + 55.845, 18.9984, 15.9994, 12.0107, + 14.0067, 1.00794}; + Float_t ws[] = { 0.15144894, 0.08147477, 0.04128158, 0.00904554, + 0.01397570, 0.00287685, 0.00445114, 0.00498089, + 0.00209828, 0.00420000, 0.36043788, 0.27529426, + 0.01415852, 0.03427566}; + density = 1.8; + maxBending = 1; + maxStepSize = .001; + precision = .001; + minStepSize = .001; + id = kPcbId; + AliMixture(id, "PCB$", as, zs, density, 14, ws); + AliMedium(kPcbId, "PCB$", id,0,fieldType,maxField,maxBending, + maxStepSize,maxEnergyLoss,precision,minStepSize); + } + + // Plastic + { + Float_t as[] = { 1.01, 12.01 }; + Float_t zs[] = { 1., 6. }; + Float_t ws[] = { 1., 1. }; + density = 1.03; + maxBending = 10; + maxStepSize = .01; + precision = .003; + minStepSize = .003; + id = kPlasticId; + AliMixture(id, "Plastic$", as, zs, density, -2, ws); + AliMedium(kPlasticId, "Plastic$", id,0,fieldType,maxField,maxBending, + maxStepSize,maxEnergyLoss,precision,minStepSize); + } } -//_____________________________________________________________________________ -void AliFMD::AddDigit (Int_t * digits) +//____________________________________________________________________ +void +AliFMD::Init() { - // add a real digit - as coming from data + // Initialize the detector + // + AliDebug(1, "Initialising FMD detector object"); + // AliFMDGeometry* fmd = AliFMDGeometry::Instance(); + // fmd->InitTransformations(); +} - if (fDigits == 0x0) fDigits = new TClonesArray ("AliFMDdigit", 1000); - TClonesArray & ldigits = *fDigits; - new (ldigits[fNdigits++]) AliFMDdigit (digits); +//____________________________________________________________________ +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 (next()))) hit->Print("D"); + fBad->Clear(); + } } -//_____________________________________________________________________________ -void AliFMD::BuildGeometry () + +//==================================================================== +// +// Graphics and event display +// +//____________________________________________________________________ +void +AliFMD::BuildGeometry() { // - // Build simple ROOT TNode geometry for event display - // - TNode *node, *top; - const int kColorFMD = 5; - // - top = gAlice->GetGeometry ()->GetNode ("alice"); - - // FMD define the different volumes - new TRotMatrix ("rot901", "rot901", 90, 0, 90, 90, 180, 0); - - new TTUBE ("S_FMD0", "FMD volume 0", "void", 4.2, 17.2, 1.5); - top->cd (); - node = new TNode ("FMD0", "FMD0", "S_FMD0", 0, 0, -62.8, ""); - node->SetLineColor (kColorFMD); - fNodes->Add (node); - - new TTUBE ("S_FMD1", "FMD volume 1", "void", 15.4, 28.4, 1.5); - top->cd (); - node = new TNode ("FMD1", "FMD1", "S_FMD1", 0, 0, -75.2, ""); - node->SetLineColor (kColorFMD); - fNodes->Add (node); - - new TTUBE ("S_FMD2", "FMD volume 2", "void", 4.2, 17.2, 1.5); - top->cd (); - node = new TNode ("FMD2", "FMD2", "S_FMD2", 0, 0, 83.2, ""); - node->SetLineColor (kColorFMD); - fNodes->Add (node); - - new TTUBE ("S_FMD3", "FMD volume 3", "void", 15.4, 28.4, 1.5); - top->cd (); - node = new TNode ("FMD3", "FMD3", "S_FMD3", 0, 0, 75.2, ""); - node->SetLineColor (kColorFMD); - fNodes->Add (node); - - new TTUBE ("S_FMD4", "FMD volume 4", "void", 4.2, 17.2, 1.5); - top->cd (); - node = new TNode ("FMD4", "FMD4", "S_FMD4", 0, 0, 340, ""); - node->SetLineColor (kColorFMD); - fNodes->Add (node); + // 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(GetLineColor()); + + 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"); + + 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 (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(GetLineColor()); + fNodes->Add(mnod); + } // for (Int_t k = 0 ; ...) + } // for (Int_t j = 0 ; ...) + } // for (Int_t i = 1 ; ...) } -//_____________________________________________________________________________ -Int_t AliFMD::DistanceToPrimitive (Int_t /*px*/, Int_t /*py*/) +//____________________________________________________________________ +void +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. // - // Calculate the distance from the mouse to the FMD on the screen - // Dummy routine - // - return 9999; + 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 (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, GetMarkerColor()); + // 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())); + } } -//___________________________________________ -void AliFMD::ResetHits () +//____________________________________________________________________ +void +AliFMD::DrawDetector() { - // Reset number of clusters and the cluster array for this detector - AliDetector::ResetHits (); + // Draw a shaded view of the Forward multiplicity detector. This + // isn't really useful anymore. + AliDebug(10, "\tDraw detector"); } -//____________________________________________ -void AliFMD::ResetDigits () +//____________________________________________________________________ +Int_t +AliFMD::DistancetoPrimitive(Int_t, Int_t) { + // Calculate the distance from the mouse to the FMD on the screen + // Dummy routine. // - // Reset number of digits and the digits array for this detector - AliDetector::ResetDigits (); - // + return 9999; } -//------------------------------------------------------------------------- -void AliFMD::Init () +//==================================================================== +// +// Hit and Digit managment +// +//____________________________________________________________________ +void +AliFMD::MakeBranch(Option_t * option) { + // Create Tree branches for the FMD. // - // Initialis the FMD after it has been built - Int_t i; - // - if (fDebug) - { - printf ("\n%s: ", ClassName ()); - for (i = 0; i < 35; i++) - printf ("*"); - printf (" FMD_INIT "); - for (i = 0; i < 35; i++) - printf ("*"); - printf ("\n%s: ", ClassName ()); - // - // Here the FMD initialisation code (if any!) - for (i = 0; i < 80; i++) - printf ("*"); - printf ("\n"); - } - // + // Options: // - -} -//--------------------------------------------------------------------- -void AliFMD::MakeBranch (Option_t * option) -{ - // Create Tree branches for the FMD. - char branchname[10]; + // H Make a branch of TClonesArray of AliFMDHit's + // D Make a branch of TClonesArray of AliFMDDigit's + // S Make a branch of TClonesArray of AliFMDSDigit's + // const Int_t kBufferSize = 16000; - sprintf (branchname, "%s", GetName ()); + TString branchname(GetName()); + TString opt(option); - const char *cH = strstr(option,"H"); - const char *cD = strstr(option,"D"); - const char *cR = strstr(option,"R"); - - if (cH && (fHits == 0x0)) fHits = new TClonesArray ("AliFMDhit", 1000); + if (opt.Contains("H", TString::kIgnoreCase)) { + HitsArray(); + AliDetector::MakeBranch(option); + } + if (opt.Contains("D", TString::kIgnoreCase)) { + DigitsArray(); + MakeBranchInTree(fLoader->TreeD(), branchname.Data(), + &fDigits, kBufferSize, 0); + } + if (opt.Contains("S", TString::kIgnoreCase)) { + SDigitsArray(); + MakeBranchInTree(fLoader->TreeS(), branchname.Data(), + &fSDigits, kBufferSize, 0); + } +} - AliDetector::MakeBranch (option); - - if (cD){ - if (fDigits == 0x0) fDigits = new TClonesArray ("AliFMDdigit", 1000); - MakeBranchInTree(fLoader->TreeD(), branchname,&fDigits, kBufferSize, 0); +//____________________________________________________________________ +void +AliFMD::SetTreeAddress() +{ + // Set branch address for the Hits, Digits, and SDigits Tree. + if (fLoader->TreeH()) HitsArray(); + AliDetector::SetTreeAddress(); + + TTree *treeD = fLoader->TreeD(); + if (treeD) { + DigitsArray(); + TBranch* branch = treeD->GetBranch ("FMD"); + if (branch) branch->SetAddress(&fDigits); } - if (cR){ - if (fReconParticles == 0x0) - fReconParticles=new TClonesArray("AliFMDReconstParticles",1000); - MakeBranchInTree(fLoader->TreeR(), branchname,&fReconParticles, kBufferSize, 0); + TTree *treeS = fLoader->TreeS(); + if (treeS) { + SDigitsArray(); + TBranch* branch = treeS->GetBranch ("FMD"); + if (branch) branch->SetAddress(&fSDigits); } - } -//_____________________________________________________________________________ -void AliFMD::SetTreeAddress () +//____________________________________________________________________ +void +AliFMD::SetHitsAddressBranch(TBranch *b) +{ + // Set the TClonesArray to read hits into. + b->SetAddress(&fHits); +} + +//____________________________________________________________________ +void +AliFMD::AddHit(Int_t track, Int_t *vol, Float_t *hits) { - // Set branch address for the Hits and Digits Tree. - char branchname[30]; + // Add a hit to the hits tree + // + // The information of the two arrays are decoded as + // + // Parameters + // track Track # + // ivol[0] [UShort_t ] Detector # + // ivol[1] [Char_t ] Ring ID + // ivol[2] [UShort_t ] Sector # + // ivol[3] [UShort_t ] Strip # + // hits[0] [Float_t ] Track's X-coordinate at hit + // hits[1] [Float_t ] Track's Y-coordinate at hit + // hits[3] [Float_t ] Track's Z-coordinate at hit + // hits[4] [Float_t ] X-component of track's momentum + // hits[5] [Float_t ] Y-component of track's momentum + // hits[6] [Float_t ] Z-component of track's momentum + // hits[7] [Float_t ] Energy deposited by track + // hits[8] [Int_t ] Track's particle Id # + // hits[9] [Float_t ] Time when the track hit + // + // + 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 +} - if (fLoader->TreeH() && (fHits == 0x0)) - fHits = new TClonesArray ("AliFMDhit", 1000); +//____________________________________________________________________ +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: + // + // track Track # + // detector Detector # (1, 2, or 3) + // ring Ring ID ('I' or 'O') + // sector Sector # (For inner/outer rings: 0-19/0-39) + // strip Strip # (For inner/outer rings: 0-511/0-255) + // x Track's X-coordinate at hit + // y Track's Y-coordinate at hit + // z Track's Z-coordinate at hit + // px X-component of track's momentum + // py Y-component of track's momentum + // pz Z-component of track's momentum + // 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 + // find a hit with the same parameters. If we do, then don't create + // 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; + hit = static_cast (a.At(i)); + if (hit->Detector() == detector + && hit->Ring() == ring + && hit->Sector() == sector + && hit->Strip() == strip + && hit->Track() == track) { + 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 hit; + } + } + // If hit wasn't already registered, do so know. + 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; +} - AliDetector::SetTreeAddress (); +//____________________________________________________________________ +void +AliFMD::AddDigit(Int_t* digits, Int_t*) +{ + // Add a digit to the Digit tree + // + // Paramters + // + // digits[0] [UShort_t] Detector # + // digits[1] [Char_t] Ring ID + // digits[2] [UShort_t] Sector # + // digits[3] [UShort_t] Strip # + // digits[4] [UShort_t] ADC Count + // digits[5] [Short_t] ADC Count, -1 if not used + // digits[6] [Short_t] ADC Count, -1 if not used + // + 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 +} - TBranch *branch; - TTree *treeD = fLoader->TreeD(); +//____________________________________________________________________ +void +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 + // + // Parameters + // + // detector Detector # (1, 2, or 3) + // ring Ring ID ('I' or 'O') + // sector Sector # (For inner/outer rings: 0-19/0-39) + // strip Strip # (For inner/outer rings: 0-511/0-255) + // count1 ADC count (a 10-bit word) + // count2 ADC count (a 10-bit word), or -1 if not used + // count3 ADC count (a 10-bit word), or -1 if not used + TClonesArray& a = *(DigitsArray()); + + new (a[fNdigits++]) + AliFMDDigit(detector, ring, sector, strip, count1, count2, count3); +} - if (treeD) - { - if (fDigits == 0x0) fDigits = new TClonesArray ("AliFMDdigit", 1000); - branch = treeD->GetBranch (branchname); - if (branch) - branch->SetAddress (&fDigits); - } +//____________________________________________________________________ +void +AliFMD::AddSDigit(Int_t* digits) +{ + // Add a digit to the SDigit tree + // + // Paramters + // + // digits[0] [UShort_t] Detector # + // digits[1] [Char_t] Ring ID + // digits[2] [UShort_t] Sector # + // digits[3] [UShort_t] Strip # + // digits[4] [Float_t] Total energy deposited + // digits[5] [UShort_t] ADC Count + // digits[6] [Short_t] ADC Count, -1 if not used + // digits[7] [Short_t] ADC Count, -1 if not used + // + 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::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 + // + // Parameters + // + // detector Detector # (1, 2, or 3) + // ring Ring ID ('I' or 'O') + // sector Sector # (For inner/outer rings: 0-19/0-39) + // strip Strip # (For inner/outer rings: 0-511/0-255) + // edep Total energy deposited + // count1 ADC count (a 10-bit word) + // count2 ADC count (a 10-bit word), or -1 if not used + // count3 ADC count (a 10-bit word), or -1 if not used + // + TClonesArray& a = *(SDigitsArray()); - if (fLoader->TreeR() && fReconParticles) - { - if (fReconParticles == 0x0) - fReconParticles=new TClonesArray("AliFMDReconstParticles",1000); - branch = fLoader->TreeR()->GetBranch("FMD"); - if (branch) branch->SetAddress(&fReconParticles) ; - } + new (a[fNsdigits++]) + AliFMDSDigit(detector, ring, sector, strip, edep, count1, count2, count3); } +//____________________________________________________________________ +void +AliFMD::ResetSDigits() +{ + // Reset number of digits and the digits array for this detector. + // + fNsdigits = 0; + if (fSDigits) fSDigits->Clear(); +} -void -AliFMD::Eta2Radius (Float_t eta, Float_t zDisk, Float_t * radius) +//____________________________________________________________________ +TClonesArray* +AliFMD::HitsArray() +{ + // Initialize hit array if not already, and return pointer to it. + if (!fHits) { + fHits = new TClonesArray("AliFMDHit", 1000); + fNhits = 0; + } + return fHits; +} + +//____________________________________________________________________ +TClonesArray* +AliFMD::DigitsArray() +{ + // Initialize digit array if not already, and return pointer to it. + if (!fDigits) { + fDigits = new TClonesArray("AliFMDDigit", 1000); + fNdigits = 0; + } + return fDigits; +} + +//____________________________________________________________________ +TClonesArray* +AliFMD::SDigitsArray() { - Float_t expEta = TMath::Exp (-eta); - Float_t theta = TMath::ATan (expEta); - theta = 2. * theta; - Float_t rad = zDisk * (TMath::Tan (theta)); - *radius = rad; + // Initialize digit array if not already, and return pointer to it. + if (!fSDigits) { + fSDigits = new TClonesArray("AliFMDSDigit", 1000); + fNsdigits = 0; + } + return fSDigits; +} - if (fDebug) - printf ("%s: eta %f radius %f\n", ClassName (), eta, rad); +//==================================================================== +// +// Digitization +// +//____________________________________________________________________ +void +AliFMD::Hits2Digits() +{ + // 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; } -//--------------------------------------------------------------------- +//____________________________________________________________________ +void +AliFMD::Hits2SDigits() +{ + // Create AliFMDSDigit's from AliFMDHit's. This is done by creating + // an AliFMDSDigitizer object, and executing it. + // + AliFMDSDigitizer* digitizer = new AliFMDSDigitizer("galice.root"); + digitizer->Exec(""); + delete digitizer; +} + +//____________________________________________________________________ +AliDigitizer* +AliFMD::CreateDigitizer(AliRunDigitizer* manager) const +{ + // Create a digitizer object + AliFMDDigitizer* digitizer = new AliFMDDigitizer(manager); + return digitizer; +} -void AliFMD::Digits2Reco() +//==================================================================== +// +// Raw data simulation +// +//__________________________________________________________________ +void +AliFMD::Digits2Raw() { - AliFMDReconstruction * reconstruction = new AliFMDReconstruction(fLoader->GetRunLoader()); - cout<<" AliFMD::Digits2Reco >> "< Exec(); - delete reconstruction; + // Turn digits into raw data. + // + // This uses the class AliFMDRawWriter to do the job. Please refer + // to that class for more information. + AliFMDRawWriter writer(this); + writer.Exec(); } -//----------------------------------------------------------------------- - -void AliFMD::MakeBranchInTreeD(TTree *treeD, const char *file) -{ - // - // Create TreeD branches for the FMD - // - const Int_t kBufferSize = 4000; - char branchname[20]; - sprintf(branchname,"%s",GetName()); - if(treeD) - { - MakeBranchInTree(treeD, branchname,&fDigits, kBufferSize, file); - } + + +//==================================================================== +// +// Utility +// +//__________________________________________________________________ +void +AliFMD::Browse(TBrowser* b) +{ + // Browse this object. + // + AliDebug(30, "\tBrowsing the FMD"); + AliDetector::Browse(b); + b->Add(AliFMDGeometry::Instance()); } -//____________________________________________________________________________ -AliDigitizer* AliFMD::CreateDigitizer(AliRunDigitizer* manager) const +//____________________________________________________________________ +void +AliFMD::AddAlignableVolumes() const { - return new AliFMDDigitizer(manager); + // + // 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 . 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. + 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/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 + min = (tb == 1 ? 10 : min); + char sio = (io == 0 ? 'I' : '0'); + 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())); + } + } + } + } + } +//___________________________________________________________________ +// +// EOF +//