1 /**************************************************************************
2 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
4 * Author: The ALICE Off-line Project. *
5 * Contributors are mentioned in the code where appropriate. *
7 * Permission to use, copy, modify and distribute this software and its *
8 * documentation strictly for non-commercial purposes is hereby granted *
9 * without fee, provided that the above copyright notice appears in all *
10 * copies and that both the copyright notice and this permission notice *
11 * appear in the supporting documentation. The authors make no claims *
12 * about the suitability of this software for any purpose. It is *
13 * provided "as is" without express or implied warranty. *
14 **************************************************************************/
16 /* $Id: AliTRDchamberTimeBin.cxx 23313 2008-01-11 14:56:43Z cblume $ */
18 ///////////////////////////////////////////////////////////////////////////////
20 // Organization of clusters at the level of 1 TRD chamber. //
21 // The data structure is used for tracking at the stack level. //
23 // Functionalities: //
24 // 1. cluster organization and sorting //
25 // 2. fast data navigation //
28 // Alex Bercuci <A.Bercuci@gsi.de> //
29 // Markus Fasel <M.Fasel@gsi.de> //
31 ///////////////////////////////////////////////////////////////////////////////
35 #include <TTreeStream.h>
38 #include "AliTRDcluster.h"
39 #include "AliTRDgeometry.h"
40 #include "AliTRDpadPlane.h"
41 #include "AliTRDchamberTimeBin.h"
42 #include "AliTRDrecoParam.h"
43 #include "AliTRDReconstructor.h"
45 ClassImp(AliTRDchamberTimeBin)
47 //_____________________________________________________________________________
48 AliTRDchamberTimeBin::AliTRDchamberTimeBin(Int_t plane, Int_t stack, Int_t sector, Double_t z0, Double_t zLength)
50 ,fkReconstructor(NULL)
61 // Default constructor (Only provided to use AliTRDchamberTimeBin with arrays)
64 SetBit(kOwner, kFALSE);
65 memset(fPositions, 1, kMaxRows*sizeof(UChar_t));
66 memset(fClusters, 0, kMaxClustersLayer*sizeof(AliTRDcluster*));
67 memset(fIndex, 1, kMaxClustersLayer*sizeof(UInt_t));
71 //_____________________________________________________________________________
72 AliTRDchamberTimeBin::AliTRDchamberTimeBin(const AliTRDchamberTimeBin &layer):
74 ,fkReconstructor(layer.fkReconstructor)
77 ,fSector(layer.fSector)
82 ,fZLength(layer.fZLength)
86 SetBit(kT0, layer.IsT0());
87 SetBit(kOwner, kFALSE);
88 for(int i=0; i<kMaxRows; i++) fPositions[i] = layer.fPositions[i];
89 memcpy(&fClusters[0], &layer.fClusters[0], kMaxClustersLayer*sizeof(AliTRDcluster*));
90 memcpy(&fIndex[0], &layer.fIndex[0], kMaxClustersLayer*sizeof(UInt_t));
96 //_____________________________________________________________________________
97 AliTRDchamberTimeBin &AliTRDchamberTimeBin::operator=(const AliTRDchamberTimeBin &layer)
99 // Assignment operator
101 if (this != &layer) layer.Copy(*this);
105 //_____________________________________________________________________________
106 void AliTRDchamberTimeBin::Clear(const Option_t *)
108 // Reset the Chamber Timebin
110 for(Int_t it = 0; it<kMaxClustersLayer; it++)
111 delete fClusters[it];
112 memset(fClusters,0,kMaxClustersLayer*sizeof(fClusters[0]));
116 //_____________________________________________________________________________
117 void AliTRDchamberTimeBin::Copy(TObject &o) const
119 // Copy method. Performs a deep copy of all data from this object to object o.
121 AliTRDchamberTimeBin &layer = (AliTRDchamberTimeBin &)o;
122 layer.fkReconstructor = fkReconstructor;
123 layer.fPlane = fPlane;
124 layer.fStack = fStack;
125 layer.fSector = fSector;
126 layer.fNRows = fNRows;
130 layer.fZLength = fZLength;
132 layer.SetBit(kOwner, kFALSE);
134 for(int i=0; i<kMaxRows; i++) layer.fPositions[i] = fPositions[i];
135 memcpy(&layer.fClusters[0], &fClusters[0], kMaxClustersLayer*sizeof(AliTRDcluster*));
136 memcpy(&layer.fIndex[0], &fIndex[0], kMaxClustersLayer*sizeof(UInt_t));
138 TObject::Copy(layer); // copies everything into layer
140 // layer.BuildIndices();
143 //_____________________________________________________________________________
144 AliTRDchamberTimeBin::~AliTRDchamberTimeBin()
148 for(AliTRDcluster **cit = &fClusters[0]; (*cit); cit++) delete (*cit);
152 //_____________________________________________________________________________
153 void AliTRDchamberTimeBin::SetOwner(Bool_t copy)
155 // Sets the ownership of the clusters to this
156 // If option "copy" is kTRUE [default] the clusters
157 // are also copied otherwise only the ownership bit
160 SetBit(kOwner, kTRUE);
162 for(AliTRDcluster **cit = &fClusters[0]; (*cit); ++cit){
163 (*cit) = new AliTRDcluster(*(*cit));
167 //_____________________________________________________________________________
168 void AliTRDchamberTimeBin::SetRange(Float_t z0, Float_t zLength)
170 // Sets the range in z-direction
173 // z0 : starting position of layer in the z direction
174 // zLength : length of layer in the z direction
176 fZ0 = (z0 <= z0 + zLength) ? z0 : z0 + zLength;
177 fZLength = TMath::Abs(zLength);
180 //_____________________________________________________________________________
181 void AliTRDchamberTimeBin::InsertCluster(AliTRDcluster *c, UInt_t index)
184 // Insert cluster in cluster array.
185 // Clusters are sorted according to Y coordinate.
188 //if (fTimeBinIndex < 0) {
189 //AliWarning("Attempt to insert cluster into non-sensitive time bin!\n");
193 if (fN == (Int_t) kMaxClustersLayer) {
194 //AliWarning("Too many clusters !\n");
204 Int_t i = Find(c->GetY());
205 memmove(fClusters+i+1,fClusters+i,(fN-i)*sizeof(AliTRDcluster*));
206 memmove(fIndex +i+1,fIndex +i,(fN-i)*sizeof(UInt_t));
212 //___________________________________________________
213 void AliTRDchamberTimeBin::Bootstrap(const AliTRDReconstructor *rec, Int_t det)
215 // Reinitialize all data members from the clusters array
216 // It has to be used after reading from disk
218 fkReconstructor = rec;
219 fPlane = AliTRDgeometry::GetLayer(det);
220 fStack = AliTRDgeometry::GetStack(det);
221 fSector = AliTRDgeometry::GetSector(det);
223 fNRows = g.GetPadPlane(fPlane, fStack)->GetNrows();
225 for(AliTRDcluster **cit = &fClusters[0]; (*cit); cit++) fN++;
229 //_____________________________________________________________________________
230 void AliTRDchamberTimeBin::BuildIndices(Int_t iter)
232 // Rearrangement of the clusters belonging to the propagation layer for the stack.
234 // Detailed description
236 // The array indices of all clusters in one PropagationLayer are stored in
237 // array. The array is divided into several bins.
238 // The clusters are sorted in increasing order of their y coordinate.
240 // Sorting algorithm: TreeSearch
245 // Select clusters that belong to the Stack
246 Int_t nClStack = 0; // Internal counter
247 for(Int_t i = 0; i < fN; i++){
248 if(fClusters[i]->IsUsed() || fClusters[i]->IsShared()){
253 if(nClStack > kMaxClustersLayer) AliInfo(Form("Number of clusters in stack %d exceed buffer size %d. Truncating.", nClStack, kMaxClustersLayer));
255 // Nothing in this time bin. Reset indexes
258 memset(&fPositions[0], 0, sizeof(UChar_t) * kMaxRows);
259 memset(&fClusters[0], 0, sizeof(AliTRDcluster*) * kMaxClustersLayer);
260 memset(&fIndex[0], 0, sizeof(UInt_t) * kMaxClustersLayer);
265 AliTRDcluster *helpCL[kMaxClustersLayer];
266 UInt_t helpInd[kMaxClustersLayer];
268 // Defining iterators
269 AliTRDcluster **fcliter = &fClusters[0], **hcliter = &helpCL[0]; UInt_t *finditer = &fIndex[0], *hinditer = &helpInd[0];
270 AliTRDcluster *tmpcl = NULL;
271 for(Int_t i = 0; i < TMath::Min(fN, kMaxClustersLayer); i++){
272 if(!(tmpcl = *(fcliter++))){
276 *(hcliter++) = tmpcl;
277 *(hinditer++) = *finditer;
279 *(finditer++) = 0xffff;
283 // do clusters arrangement
287 // Reset Positions array
288 memset(fPositions, 0, sizeof(UChar_t)*kMaxRows);
289 AliTRDcluster **cliter = &helpCL[0]; // Declare iterator running over the whole array
290 const AliTRDrecoParam* const recoParam = fkReconstructor->GetRecoParam(); //the dynamic cast in GetRecoParam is slow, so caching the pointer to it
292 for(Int_t i = 0; i < fN; i++){
294 AliTRDcluster *cl = *(cliter++);
295 UChar_t rowIndex = cl->GetPadRow();
296 if(tb<0) tb=cl->GetLocalTimeBin();
298 Int_t pos = FindYPosition(cl->GetY(), rowIndex, nClStack);
299 if(pos == -2) continue; // zbin error;
300 else if(pos == -1) { // zbin is empty;
301 Int_t upper = (rowIndex == fNRows - 1) ? nClStack : fPositions[rowIndex + 1];
302 memmove(fClusters + upper + 1, fClusters + upper, (sizeof(AliTRDcluster *))*(nClStack-upper));
303 memmove(fIndex + upper + 1, fIndex + upper, (sizeof(UInt_t))*(nClStack-upper));
304 fClusters[upper] = cl;
305 fIndex[upper] = helpInd[i];
306 // Move All pointer one position back
307 for(UChar_t j = rowIndex + 1; j < fNRows; j++) fPositions[j]++;
309 } else { // zbin not empty
310 memmove(fClusters + pos + 2, fClusters + pos+1, (sizeof(AliTRDcluster *))*(nClStack-(pos+1)));
311 memmove(fIndex + pos + 2, fIndex + pos+1, (sizeof(UInt_t))*(nClStack-(pos+1)));
312 fClusters[pos + 1] = cl; //fIndex[i];
313 fIndex[pos + 1] = helpInd[i];
314 // Move All pointer one position back
315 for(UChar_t j = rowIndex + 1; j < fNRows; j++) fPositions[j]++;
323 if(recoParam->GetStreamLevel(AliTRDrecoParam::kTracker) >= 3){
324 AliTRDcluster dcl(*cl);
325 TTreeSRedirector &cstream = *fkReconstructor->GetDebugStream(AliTRDrecoParam::kTracker);
326 cstream << "BuildIndices"
327 << "Plane=" << fPlane
328 << "Stack=" << fStack
329 << "Sector=" << fSector
332 << "rowIndex=" << rowIndex
337 // AliInfo("Positions");
338 // for(int ir=0; ir<fNRows; ir++) printf("pos[%d] %d\n", ir, fPositions[ir]);
340 AliWarning(Form("Found %d out of %d clusters outside in ChamberTimeBin[%02d_%d_%d|%2d]", fN-nClStack, fN, fSector, fStack, fPlane, tb));
342 if(!fN){ // Nothing left in this time bin. Reset indexes
343 memset(&fPositions[0], 0, sizeof(UChar_t) * kMaxRows);
344 memset(&fClusters[0], 0, sizeof(AliTRDcluster*) * kMaxClustersLayer);
345 memset(&fIndex[0], 0, sizeof(UInt_t) * kMaxClustersLayer);
352 //_____________________________________________________________________________
353 Int_t AliTRDchamberTimeBin::Find(Float_t y) const
356 // Returns index of the cluster nearest in Y
359 if (fN <= 0) return 0;
361 if (y <= fClusters[0]->GetY()) return 0;
363 if (y > fClusters[fN-1]->GetY()) return fN;
368 Int_t m = (b + e) / 2;
370 for ( ; b < e; m = (b + e) / 2) {
371 if (y > fClusters[m]->GetY()) b = m + 1;
378 //_____________________________________________________________________________
379 Int_t AliTRDchamberTimeBin::FindYPosition(Double_t y, UChar_t z, Int_t nClusters) const
382 // Tree search Algorithm to find the nearest left cluster for a given
383 // y-position in a certain z-bin (in fact AVL-tree).
384 // Making use of the fact that clusters are sorted in y-direction.
387 // y : y position of the reference point in tracking coordinates
388 // z : z reference bin.
392 // Index of the nearest left cluster in the StackLayer indexing (-1 if no clusters are found)
395 if(z>=fNRows){ // check pad row of cluster
396 AliDebug(1, Form("Row[%2d] outside range [0 %2d] in %02d_%d_%d.", z, fNRows, fSector, fStack, fPlane));
399 Int_t start = fPositions[z]; // starting Position of the bin
400 Int_t upper = (Int_t)((z != fNRows - 1) ? fPositions[z+1] : nClusters); // ending Position of the bin
401 Int_t end = upper - 1; // ending Position of the bin
402 if(end < start) return -1; // Bin is empty
403 Int_t middle = static_cast<Int_t>((start + end)/2);
404 // 1st Part: climb down the tree: get the next cluster BEFORE ypos
405 while(start + 1 < end){
406 if(y >= fClusters[middle]->GetY()) start = middle;
408 middle = static_cast<Int_t>((start + end)/2);
410 if(y > fClusters[end]->GetY()) return end;
414 //_____________________________________________________________________________
415 Int_t AliTRDchamberTimeBin::FindNearestYCluster(Double_t y, UChar_t z) const
418 // Tree search Algorithm to find the nearest cluster for a given
419 // y-position in a certain z-bin (in fact AVL-tree).
420 // Making use of the fact that clusters are sorted in y-direction.
423 // y : y position of the reference point in tracking coordinates
424 // z : z reference bin.
427 // Index of the nearest cluster in the StackLayer indexing (-1 if no clusters are found)
430 Int_t position = FindYPosition(y, z, fN);
431 if(position == -2 || position == -1) return position; // bin empty
432 // FindYPosition always returns the left Neighbor. We don't know if the left or the right Neighbor is nearest
433 // to the Reference y-position, so test both
434 Int_t upper = (Int_t)((z < fNRows-1) ? fPositions[z+1] : fN); // ending Position of the bin
435 if((position + 1) < (upper)){
436 if(TMath::Abs(y - fClusters[position + 1]->GetY()) < TMath::Abs(y - fClusters[position]->GetY())) return position + 1;
437 else return position;
442 //_____________________________________________________________________________
443 Int_t AliTRDchamberTimeBin::SearchNearestCluster(Double_t y, Double_t z, Double_t maxroady, Double_t maxroadz) const
446 // Finds the nearest cluster from a given point in a defined range.
447 // Distance is determined in a 2D space by the 2-Norm.
450 // y : y position of the reference point in tracking coordinates
451 // z : z reference bin.
452 // maxroady : maximum searching distance in y direction
453 // maxroadz : maximum searching distance in z direction
456 // Index of the nearest cluster in the StackLayer indexing (-1 if no cluster is found).
457 // Cluster can be accessed with the operator[] or GetCluster(Int_t index)
459 // Detail description
461 // The following steps are perfomed:
462 // 1. Get the expected z bins inside maxroadz.
463 // 2. For each z bin find nearest y cluster.
464 // 3. Select best candidate
467 // initial minimal distance will be represented as ellipse: semi-major = z-direction
468 // later 2-Norm will be used
469 // Float_t nExcentricity = TMath::Sqrt(maxroadz*maxroadz - maxroad*maxroad)/maxroadz;
470 Float_t mindist = maxroadz;
472 // not very nice but unfortunately neccessarry: we have ho check the neighbors in both directions (+ and -) too. How
473 // much neighbors depends on the Quotient maxroadz/fZLength
475 UChar_t zpos[kMaxRows];
476 // Float_t mindist = TMath::Sqrt(maxroad*maxroad + maxroadz*maxroadz);
477 // UChar_t myZbin = FindTreePosition(z, fZ0 + fZLength/2, fZLength/4, 8, 8, kFALSE);
478 UChar_t myZbin = fNRows - 1 - (UChar_t)(TMath::Abs(fZ0 - z)/fZLength * fNRows);
479 if(z < fZ0) myZbin = fNRows - 1;
480 if(z > fZ0 + fZLength) myZbin = 0;
481 //printf("\n%f < %f < %f [%d]\n", fZ0, z, fZ0 + fZLength, myZbin);
482 //for(int ic=0; ic<fN; ic++) printf("%d z = %f row %d\n", ic, fClusters[ic]->GetZ(), fClusters[ic]->GetPadRow());
484 UChar_t nNeighbors = 0;
485 for(UChar_t i = 0; i < maxRows; i++){
486 if((myZbin - 1 + i) < 0) continue;
487 if((myZbin - 1 + i) > fNRows - 1) break;
488 zpos[nNeighbors] = myZbin - 1 + i;
491 Float_t ycl = 0, zcl = 0;
492 for(UChar_t neighbor = 0; neighbor < nNeighbors; neighbor++){ // Always test the neighbors too
493 Int_t pos = FindNearestYCluster(y, zpos[neighbor]);
494 if(pos == -1) continue; // No cluster in bin
495 AliTRDcluster *c = (AliTRDcluster *) (fClusters[pos]);
496 if(c->IsUsed()) continue; // we are only interested in unused clusters
498 // Too far away in y-direction (Prearrangement)
499 if (TMath::Abs(ycl - y) > maxroady){
500 //printf("y[%f] ycl[%f] roady[%f]\n", y, ycl, maxroady);
504 // Too far away in z-Direction
505 // (Prearrangement since we have not so many bins to test)
506 if (TMath::Abs(zcl - z) > maxroadz) continue;
508 Float_t dist; // distance defined as 2-Norm
509 // if we havent found a Particle that is in the ellipse around (y,z) with maxroad as semi-minor and
510 // maxroadz as semi-major, we take the radius of the ellipse concerning the cluster as mindist, later we
511 // take the 2-Norm when we found a cluster inside the ellipse (The value 10000 is taken because it is surely
512 // large enough to be usable as an indicator whether we have found a nearer cluster or not)
513 // if(mindist > 10000.){
514 // Float_t phi = ((zcl - z) == 0) ? TMath::Pi()/2 : TMath::ATan((ycl - y)/(zcl - z));
515 // mindist = maxroad/TMath::Sqrt(1 - nExcentricity*nExcentricity * (TMath::Cos(phi))*(TMath::Cos(phi)));
517 dist = TMath::Max(TMath::Abs(y-ycl),TMath::Abs(z-zcl)); // infinity Norm
518 // dist = TMath::Sqrt((ycl - y)*(ycl - y) + (zcl - z)*(zcl - z));
519 if((Int_t)(dist * 100000) < (Int_t)(mindist * 100000)){
520 //if((dist = TMath::Sqrt((ycl - y)*(ycl - y) + (zcl - z)*(zcl - z))) < mindist){
525 // This is the Array Position in fIndex2D of the Nearest cluster: if a
526 // cluster is called, then the function has to retrieve the Information
527 // which is Stored in the Array called, the function
531 //_____________________________________________________________________________
532 void AliTRDchamberTimeBin::BuildCond(AliTRDcluster * const cl, Double_t *cond, UChar_t Layer, Double_t theta, Double_t phi)
534 // Helper function to calculate the area where to expect a cluster in THIS
544 // Detail description
546 // Helper function to calculate the area where to expect a cluster in THIS
547 // layer. by using the information of a former cluster in another layer
548 // and the angle in theta- and phi-direction between layer 0 and layer 3.
549 // If the layer is zero, initial conditions are calculated. Otherwise a
550 // linear interpolation is performed.
552 //<img src="gif/build_cond.gif">
556 if(!fkReconstructor){
557 AliError("Reconstructor not set.");
562 cond[0] = cl->GetY(); // center: y-Direction
563 cond[1] = cl->GetZ(); // center: z-Direction
564 cond[2] = fkReconstructor->GetRecoParam()->GetMaxPhi() * (cl->GetX() - GetX()) + 1.0; // deviation: y-Direction
565 cond[3] = fkReconstructor->GetRecoParam()->GetMaxTheta() * (cl->GetX() - GetX()) + 1.0; // deviation: z-Direction
567 cond[0] = cl->GetY() + phi * (GetX() - cl->GetX());
568 cond[1] = cl->GetZ() + theta * (GetX() - cl->GetX());
569 cond[2] = fkReconstructor->GetRecoParam()->GetRoad0y() + phi;
570 cond[3] = fkReconstructor->GetRecoParam()->GetRoad0z();
574 //_____________________________________________________________________________
575 void AliTRDchamberTimeBin::GetClusters(const Double_t * const cond, Int_t *index, Int_t& ncl, Int_t BufferSize)
577 // Finds all clusters situated in this layer inside a rectangle given by the center an ranges.
587 // Detail description
589 // Function returs an array containing the indices in the stacklayer of
590 // the clusters found an the number of found clusters in the stacklayer
593 memset(index, 0, BufferSize*sizeof(Int_t));
598 if(((cond[1] - cond[3]) >= (fZ0 + fZLength)) || (cond[1] + cond[3]) <= fZ0) return; // We are outside of the chamvber
599 zvals[0] = ((cond[1] - cond[3]) < fZ0) ? fZ0 : (cond[1] - cond[3]);
600 zvals[1] = ((cond[1] + cond[3]) < fZ0 + fZLength) ? (cond[1] + cond[3]) : fZ0 + fZLength - 1.E-3;
602 UChar_t zhi = fNRows - 1 - (UChar_t)(TMath::Abs(fZ0 - zvals[0])/fZLength * fNRows);
603 UChar_t zlo = fNRows - 1 - (UChar_t)(TMath::Abs(fZ0 - zvals[1])/fZLength * fNRows);
605 /* AliInfo(Form("yc[%f] zc[%f] dy[%f] dz[%f]", cond[0], cond[1], cond[2], cond[3]));
607 AliInfo(Form("zlo[%f] zhi[%f]", zvals[0], zvals[1]));
608 AliInfo(Form("zlo[%d] zhi[%d]", zlo, zhi));*/
610 Double_t ylo = cond[0] - cond[2],
611 yhi = cond[0] + cond[2];
612 //printf("CTB : ylo[%f] yhi[%f]\n", ylo, yhi);
613 //Preordering in Direction z saves a lot of loops (boundary checked)
614 for(UChar_t z = zlo; z <= zhi; z++){
615 UInt_t upper = (z < fNRows-1) ? fPositions[z+1] : fN;
616 //AliInfo(Form("z[%d] y [%d %d]", z, fPositions[z], upper));
617 for(Int_t y = fPositions[z]; y < (Int_t)upper; y++){
618 if(ncl == BufferSize){
619 AliDebug(1, Form("Buffer size [%d] riched. Some clusters may be lost.", BufferSize));
620 return; //Buffer filled
623 if(fClusters[y]->GetY() > yhi) break; // Abbortion conditions!!!
624 if(fClusters[y]->GetY() < ylo) continue; // Too small
625 if(((Int_t)((fClusters[y]->GetZ())*1000) < (Int_t)(zvals[0]*1000)) || ((Int_t)((fClusters[y]->GetZ())*1000) > (Int_t)(zvals[1]*1000))){/*printf("exit z\n"); TODO*/ continue;}
630 if(ncl>fN) AliError(Form("Clusters found %d > %d (clusters in layer)", ncl, fN));
633 //_____________________________________________________________________________
634 AliTRDcluster *AliTRDchamberTimeBin::GetNearestCluster(Double_t *cond)
636 // Function returning a pointer to the nearest cluster (nullpointer if not successfull).
642 // pointer to the nearest cluster (nullpointer if not successfull).
644 // Detail description
646 // returns a pointer to the nearest cluster (nullpointer if not
647 // successfull) by the help of the method FindNearestCluster
650 Double_t maxroad = fkReconstructor->GetRecoParam()->GetRoad2y();
651 Double_t maxroadz = fkReconstructor->GetRecoParam()->GetRoad2z();
653 Int_t index = SearchNearestCluster(cond[0],cond[1],maxroad,maxroadz);
654 AliTRDcluster *returnCluster = NULL;
655 if(index != -1) returnCluster = (AliTRDcluster *) fClusters[index];
656 return returnCluster;
659 //_____________________________________________________________________________
660 void AliTRDchamberTimeBin::Print(Option_t *) const
662 // Prints the position of each cluster in the stacklayer on the stdout
665 AliInfo(Form("Layer[%d] Stack[%d] Sector[%2d] nRows[%2d]", fPlane, fStack, fSector, fNRows));
666 AliInfo(Form("Z0[%7.3f] Z1[%7.3f]", fZ0, fZ0+fZLength));
667 AliTRDcluster* const* icl = &fClusters[0];
668 for(Int_t jcl = 0; jcl < fN; jcl++, icl++){
669 AliInfo(Form("%2d X[%7.3f] Y[%7.3f] Z[%7.3f] tb[%2d] col[%3d] row[%2d] used[%s]", jcl, (*icl)->GetX(), (*icl)->GetY(), (*icl)->GetZ(), (*icl)->GetLocalTimeBin(), (*icl)->GetPadCol(), (*icl)->GetPadRow(),
670 (*icl)->IsUsed() ? "y" : "n"));
673 for(UChar_t const* pos = &fPositions[0]; irow<fNRows; pos++, irow++){
674 if((*pos) != 0xff) AliInfo(Form("r[%2d] pos[%d]", irow, (*pos)));