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[u/mrichter/AliRoot.git] / FMD / AliFMDBaseDigitizer.cxx
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02a27b50 1/**************************************************************************
2 * Copyright(c) 2004, ALICE Experiment at CERN, All rights reserved. *
3 * *
4 * Author: The ALICE Off-line Project. *
5 * Contributors are mentioned in the code where appropriate. *
6 * *
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 **************************************************************************/
15/* $Id$ */
16/** @file AliFMDBaseDigitizer.cxx
17 @author Christian Holm Christensen <cholm@nbi.dk>
18 @date Mon Mar 27 12:38:26 2006
19 @brief FMD Digitizers implementation
20 @ingroup FMD_sim
21*/
22//////////////////////////////////////////////////////////////////////////////
23//
24// This class contains the procedures simulation ADC signal for the
25// Forward Multiplicity detector : Hits->Digits and Hits->SDigits
26//
27// Digits consists of
28// - Detector #
29// - Ring ID
30// - Sector #
31// - Strip #
32// - ADC count in this channel
33//
34// Digits consists of
35// - Detector #
36// - Ring ID
37// - Sector #
38// - Strip #
39// - Total energy deposited in the strip
40// - ADC count in this channel
41//
42// As the Digits and SDigits have so much in common, the classes
43// AliFMDDigitizer and AliFMDSDigitizer are implemented via a base
44// class AliFMDBaseDigitizer.
45//
46// +---------------------+
47// | AliFMDBaseDigitizer |
48// +---------------------+
49// ^
50// |
51// +----------+---------+
52// | |
53// +-----------------+ +------------------+
54// | AliFMDDigitizer | | AliFMDSDigitizer |
55// +-----------------+ +------------------+
56//
57// These classes has several paramters:
58//
59// fPedestal
60// fPedestalWidth
61// (Only AliFMDDigitizer)
62// Mean and width of the pedestal. The pedestal is simulated
63// by a Guassian, but derived classes my override MakePedestal
64// to simulate it differently (or pick it up from a database).
65//
66// fVA1MipRange
67// The dymamic MIP range of the VA1_ALICE pre-amplifier chip
68//
69// fAltroChannelSize
70// The largest number plus one that can be stored in one
71// channel in one time step in the ALTRO ADC chip.
72//
73// fSampleRate
74// How many times the ALTRO ADC chip samples the VA1_ALICE
75// pre-amplifier signal. The VA1_ALICE chip is read-out at
76// 10MHz, while it's possible to drive the ALTRO chip at
77// 25MHz. That means, that the ALTRO chip can have time to
78// sample each VA1_ALICE signal up to 2 times. Although it's
79// not certain this feature will be used in the production,
80// we'd like have the option, and so it should be reflected in
81// the code.
82//
83//
84// The shaping function of the VA1_ALICE is generally given by
85//
86// f(x) = A(1 - exp(-Bx))
87//
88// where A is the total charge collected in the pre-amp., and B is a
89// paramter that depends on the shaping time of the VA1_ALICE circut.
90//
91// When simulating the shaping function of the VA1_ALICe
92// pre-amp. chip, we have to take into account, that the shaping
93// function depends on the previous value of read from the pre-amp.
94//
95// That results in the following algorithm:
96//
97// last = 0;
98// FOR charge IN pre-amp. charge train DO
99// IF last < charge THEN
100// f(t) = (charge - last) * (1 - exp(-B * t)) + last
101// ELSE
102// f(t) = (last - charge) * exp(-B * t) + charge)
103// ENDIF
104// FOR i IN # samples DO
105// adc_i = f(i / (# samples))
106// DONE
107// last = charge
108// DONE
109//
110// Here,
111//
112// pre-amp. charge train
113// is a series of 128 charges read from the VA1_ALICE chip
114//
115// # samples
116// is the number of times the ALTRO ADC samples each of the 128
117// charges from the pre-amp.
118//
119// Where Q is the total charge collected by the VA1_ALICE
120// pre-amplifier. Q is then given by
121//
122// E S
123// Q = - -
124// e R
125//
126// where E is the total energy deposited in a silicon strip, R is the
127// dynamic range of the VA1_ALICE pre-amp (fVA1MipRange), e is the
128// energy deposited by a single MIP, and S ALTRO channel size in each
129// time step (fAltroChannelSize).
130//
131// The energy deposited per MIP is given by
132//
133// e = M * rho * w
134//
135// where M is the universal number 1.664, rho is the density of
136// silicon, and w is the depth of the silicon sensor.
137//
138// The final ADC count is given by
139//
140// C' = C + P
141//
142// where P is the (randomized) pedestal (see MakePedestal)
143//
144// This class uses the class template AliFMDMap<Type> to make an
145// internal cache of the energy deposted of the hits. The class
146// template is instantasized as
147//
148// typedef AliFMDMap<std::pair<Float_t, UShort_t> > AliFMDEdepMap;
149//
150// The first member of the values is the summed energy deposition in a
151// given strip, while the second member of the values is the number of
152// hits in a given strip. Using the second member, it's possible to
153// do some checks on just how many times a strip got hit, and what
154// kind of error we get in our reconstructed hits. Note, that this
155// information is currently not written to the digits tree. I think a
156// QA (Quality Assurance) digit tree is better suited for that task.
157// However, the information is there to be used in the future.
158//
159//
160// Latest changes by Christian Holm Christensen
161//
162//////////////////////////////////////////////////////////////////////////////
163
164// /1
165// | A(-1 + B + exp(-B))
166// | f(x) dx = ------------------- = 1
167// | B
168// / 0
169//
170// and B is the a parameter defined by the shaping time (fShapingTime).
171//
172// Solving the above equation, for A gives
173//
174// B
175// A = ----------------
176// -1 + B + exp(-B)
177//
178// So, if we define the function g: [0,1] -> [0:1] by
179//
180// / v
181// | Bu + exp(-Bu) - Bv - exp(-Bv)
182// g(u,v) = | f(x) dx = -A -----------------------------
183// | B
184// / u
185//
186// we can evaluate the ALTRO sample of the VA1_ALICE pre-amp between
187// any two times (u, v), by
188//
189//
190// B Bu + exp(-Bu) - Bv - exp(-Bv)
191// C = Q g(u,v) = - Q ---------------- -----------------------------
192// -1 + B + exp(-B) B
193//
194// Bu + exp(-Bu) - Bv - exp(-Bv)
195// = - Q -----------------------------
196// -1 + B + exp(-B)
197//
198
090026bf 199#include <TMath.h>
02a27b50 200#include <TTree.h> // ROOT_TTree
201//#include <TRandom.h> // ROOT_TRandom
f95a63c4 202// #include <AliLog.h> // ALILOG_H
203#include "AliFMDDebug.h" // Better debug macros
02a27b50 204#include "AliFMDBaseDigitizer.h" // ALIFMDDIGITIZER_H
205#include "AliFMD.h" // ALIFMD_H
206#include "AliFMDGeometry.h" // ALIFMDGEOMETRY_H
207#include "AliFMDDetector.h" // ALIFMDDETECTOR_H
208#include "AliFMDRing.h" // ALIFMDRING_H
209#include "AliFMDHit.h" // ALIFMDHIT_H
6169f936 210// #include "AliFMDDigit.h" // ALIFMDDIGIT_H
02a27b50 211#include "AliFMDParameters.h" // ALIFMDPARAMETERS_H
6169f936 212// #include <AliRunDigitizer.h> // ALIRUNDIGITIZER_H
02a27b50 213//#include <AliRun.h> // ALIRUN_H
214#include <AliLoader.h> // ALILOADER_H
42f1b2f5 215#include <AliRun.h> // ALILOADER_H
02a27b50 216#include <AliRunLoader.h> // ALIRUNLOADER_H
ef8e8623 217#include <TRandom.h>
02a27b50 218
219//====================================================================
220ClassImp(AliFMDBaseDigitizer)
221#if 0
222 ; // This is here to keep Emacs for indenting the next line
223#endif
224
225//____________________________________________________________________
226AliFMDBaseDigitizer::AliFMDBaseDigitizer()
ef8e8623 227 : fFMD(0),
228 fRunLoader(0),
b5ee4425 229 fEdep(AliFMDMap::kMaxDetectors,
230 AliFMDMap::kMaxRings,
231 AliFMDMap::kMaxSectors,
232 AliFMDMap::kMaxStrips),
b2e6f0b0 233 fShapingTime(6),
faf80567 234 fStoreTrackRefs(kTRUE)
02a27b50 235{
42f1b2f5 236 AliFMDDebug(1, ("Constructed"));
02a27b50 237 // Default ctor - don't use it
238}
239
240//____________________________________________________________________
241AliFMDBaseDigitizer::AliFMDBaseDigitizer(AliRunDigitizer* manager)
242 : AliDigitizer(manager, "AliFMDBaseDigitizer", "FMD Digitizer base class"),
ef8e8623 243 fFMD(0),
02a27b50 244 fRunLoader(0),
245 fEdep(AliFMDMap::kMaxDetectors,
246 AliFMDMap::kMaxRings,
247 AliFMDMap::kMaxSectors,
b5ee4425 248 AliFMDMap::kMaxStrips),
b2e6f0b0 249 fShapingTime(6),
faf80567 250 fStoreTrackRefs(kTRUE)
02a27b50 251{
252 // Normal CTOR
42f1b2f5 253 AliFMDDebug(1, ("Constructed"));
02a27b50 254 SetShapingTime();
255}
256
257//____________________________________________________________________
258AliFMDBaseDigitizer::AliFMDBaseDigitizer(const Char_t* name,
259 const Char_t* title)
260 : AliDigitizer(name, title),
ef8e8623 261 fFMD(0),
02a27b50 262 fRunLoader(0),
263 fEdep(AliFMDMap::kMaxDetectors,
264 AliFMDMap::kMaxRings,
265 AliFMDMap::kMaxSectors,
322be683 266 AliFMDMap::kMaxStrips),
b2e6f0b0 267 fShapingTime(6),
faf80567 268 fStoreTrackRefs(kTRUE)
02a27b50 269{
270 // Normal CTOR
42f1b2f5 271 AliFMDDebug(1, (" Constructed"));
02a27b50 272 SetShapingTime();
273}
274
275//____________________________________________________________________
276AliFMDBaseDigitizer::~AliFMDBaseDigitizer()
277{
278 // Destructor
279}
280
281//____________________________________________________________________
282Bool_t
283AliFMDBaseDigitizer::Init()
284{
ef8e8623 285 // Initialization. Get a pointer to the parameter manager, and
286 // initialize it.
02a27b50 287 AliFMDParameters::Instance()->Init();
ef8e8623 288 if (AliLog::GetDebugLevel("FMD","") >= 15)
289 AliFMDParameters::Instance()->Print("");
42f1b2f5 290 return kTRUE;
291}
292
02a27b50 293//____________________________________________________________________
294UShort_t
ef8e8623 295AliFMDBaseDigitizer::MakePedestal(UShort_t detector,
296 Char_t ring,
297 UShort_t sector,
298 UShort_t strip) const
02a27b50 299{
ef8e8623 300 // Make a pedestal. The pedestal value is drawn from a Gaussian
301 // distribution. The mean of the distribution is the measured
302 // pedestal, and the width is the measured noise.
303 AliFMDParameters* param =AliFMDParameters::Instance();
304 Float_t mean =param->GetPedestal(detector,ring,sector,strip);
305 Float_t width =param->GetPedestalWidth(detector,ring,sector,strip);
306 return UShort_t(TMath::Max(gRandom->Gaus(mean, width), 0.));
02a27b50 307}
308
309//____________________________________________________________________
310void
ef8e8623 311AliFMDBaseDigitizer::AddContribution(UShort_t detector,
312 Char_t ring,
313 UShort_t sector,
314 UShort_t strip,
83ad576a 315 Float_t edep,
b2e6f0b0 316 Bool_t isPrimary,
faf80567 317 Int_t nTrack,
318 Int_t* tracknos)
02a27b50 319{
ef8e8623 320 // Add edep contribution from (detector,ring,sector,strip) to cache
321 AliFMDParameters* param = AliFMDParameters::Instance();
8d00dfa3 322 AliFMDDebug(10, ("Adding contribution %7.5f for FMD%d%c[%2d,%3d] "
323 " from %d tracks (%s)",
324 edep,
325 detector,
326 ring,
327 sector,
328 strip,
329 nTrack,
330 (isPrimary ? "primary" : "secondary")));
ef8e8623 331 // Check if strip is `dead'
332 if (param->IsDead(detector, ring, sector, strip)) {
333 AliFMDDebug(5, ("FMD%d%c[%2d,%3d] is marked as dead",
334 detector, ring, sector, strip));
335 return;
02a27b50 336 }
ef8e8623 337 // Check if strip is out-side read-out range
338 // if (strip < minstrip || strip > maxstrip) {
339 // AliFMDDebug(5, ("FMD%d%c[%2d,%3d] is outside range [%3d,%3d]",
340 // detector,ring,sector,strip,minstrip,maxstrip));
341 // continue;
342 // }
02a27b50 343
b2e6f0b0 344 AliFMDEdepHitPair& entry = fEdep(detector, ring, sector, strip);
345
ef8e8623 346 // Give warning in case of double sdigit
b2e6f0b0 347 if (entry.fEdep != 0)
348 AliFMDDebug(5, ("Double digit in FMD%d%c[%2d,%3d]",
ef8e8623 349 detector, ring, sector, strip));
02a27b50 350
ef8e8623 351 // Sum energy deposition
8d00dfa3 352 Int_t oldN = entry.fN;
b2e6f0b0 353 entry.fEdep += edep;
faf80567 354 entry.fN += nTrack;
355 if (isPrimary) entry.fNPrim += nTrack;
b2e6f0b0 356 if (fStoreTrackRefs) {
8d00dfa3 357 if (entry.fLabels.fN < entry.fN) {
358 AliFMDDebug(15, ("== New label array size %d, was %d, added %d",
359 entry.fN, entry.fLabels.fN, nTrack));
360 entry.fLabels.Set(entry.fN);
361 }
362 for (Int_t i = 0; i < nTrack; i++) {
363 AliFMDDebug(15, ("=> Setting track label # %d", oldN+i));
faf80567 364 entry.fLabels[oldN + i] = tracknos[i];
8d00dfa3 365 AliFMDDebug(15, ("<= Setting track label # %d", oldN+i));
366 }
b2e6f0b0 367 }
8d00dfa3 368 AliFMDDebug(15,("Adding contribution %f to FMD%d%c[%2d,%3d] (%f) track %d",
369 edep, detector, ring, sector, strip,
370 entry.fEdep, (nTrack > 0 ? tracknos[0] : -1)));
83ad576a 371
02a27b50 372}
373
374//____________________________________________________________________
375void
ef8e8623 376AliFMDBaseDigitizer::DigitizeHits() const
02a27b50 377{
378 // For the stored energy contributions in the cache (fEdep), convert
379 // the energy signal to ADC counts, and store the created digit in
380 // the digits array (AliFMD::fDigits)
381 //
42f1b2f5 382 AliFMDDebug(5, ("Will now digitize all the summed signals"));
02a27b50 383 AliFMDGeometry* geometry = AliFMDGeometry::Instance();
384
2aeec17d 385 TArrayI counts(4);
02a27b50 386 for (UShort_t detector=1; detector <= 3; detector++) {
ef8e8623 387 AliFMDDebug(10, ("Processing hits in FMD%d", detector));
02a27b50 388 // Get pointer to subdetector
389 AliFMDDetector* det = geometry->GetDetector(detector);
390 if (!det) continue;
391 for (UShort_t ringi = 0; ringi <= 1; ringi++) {
392 Char_t ring = ringi == 0 ? 'I' : 'O';
ef8e8623 393 AliFMDDebug(10, (" Processing hits in FMD%d%c", detector,ring));
02a27b50 394 // Get pointer to Ring
395 AliFMDRing* r = det->GetRing(ring);
396 if (!r) continue;
397
398 // Get number of sectors
399 UShort_t nSectors = UShort_t(360. / r->GetTheta());
400 // Loop over the number of sectors
401 for (UShort_t sector = 0; sector < nSectors; sector++) {
ef8e8623 402 AliFMDDebug(10, (" Processing hits in FMD%d%c[%2d]",
f95a63c4 403 detector,ring,sector));
02a27b50 404 // Get number of strips
405 UShort_t nStrips = r->GetNStrips();
406 // Loop over the stips
407 Float_t last = 0;
408 for (UShort_t strip = 0; strip < nStrips; strip++) {
409 // Reset the counter array to the invalid value -1
410 counts.Reset(-1);
411 // Reset the last `ADC' value when we've get to the end of a
412 // VA1_ALICE channel.
413 if (strip % 128 == 0) last = 0;
414
b2e6f0b0 415 const AliFMDEdepHitPair& entry = fEdep(detector,ring,sector,strip);
416 Float_t edep = entry.fEdep;
417 UShort_t ntot = entry.fN;
418 UShort_t nprim = entry.fNPrim;
419 const TArrayI& labels = entry.fLabels;
83ad576a 420 if (edep > 0)
421 AliFMDDebug(15, ("Edep = %f for FMD%d%c[%2d,%3d]",
422 edep, detector, ring, sector, strip));
02a27b50 423 ConvertToCount(edep, last, detector, ring, sector, strip, counts);
424 last = edep;
8b26caab 425
83ad576a 426
8b26caab 427 // The following line was introduced - wrongly - by Peter
428 // Hristov. It _will_ break the digitisation and the
429 // following reconstruction. The behviour of the
430 // digitisation models exactly the front-end as it should
431 // (no matter what memory concuption it may entail). The
432 // check should be on zero suppression, since that's what
433 // models the front-end - if zero suppression is turned on
434 // in the front-end, then we can suppress empty digits -
435 // otherwise we shoud never do that. Note, that the line
436 // affects _both_ normal digitisation and digitisation for
437 // summable digits, since the condition is on the energy
438 // deposition and not on the actual number of counts. If
439 // this line should go anywhere, it should be in the
440 // possible overloaded AliFMDSDigitizer::AddDigit - not
441 // here.
442 //
443 // if (edep<=0) continue;
ef8e8623 444 AddDigit(detector, ring, sector, strip, edep,
02a27b50 445 UShort_t(counts[0]), Short_t(counts[1]),
83ad576a 446 Short_t(counts[2]), Short_t(counts[3]),
b2e6f0b0 447 ntot, nprim, labels);
ef8e8623 448 AliFMDDebug(15, (" Adding digit in FMD%d%c[%2d,%3d]=%d",
faf80567 449 detector,ring,sector,strip,counts[0]));
02a27b50 450#if 0
451 // This checks if the digit created will give the `right'
452 // number of particles when reconstructed, using a naiive
453 // approach. It's here only as a quality check - nothing
454 // else.
455 CheckDigit(digit, fEdep(detector, ring, sector, strip).fN,
456 counts);
457#endif
458 } // Strip
459 } // Sector
460 } // Ring
461 } // Detector
462}
463
464//____________________________________________________________________
465void
466AliFMDBaseDigitizer::ConvertToCount(Float_t edep,
467 Float_t last,
468 UShort_t detector,
469 Char_t ring,
470 UShort_t sector,
471 UShort_t strip,
472 TArrayI& counts) const
473{
474 // Convert the total energy deposited to a (set of) ADC count(s).
475 //
476 // This is done by
477 //
478 // Energy_Deposited ALTRO_Channel_Size
479 // ADC = -------------------------- ------------------- + pedestal
480 // Energy_Deposition_Of_1_MIP VA1_ALICE_MIP_Range
481 //
482 // Energy_Deposited fAltroChannelSize
483 // = --------------------------------- ----------------- + pedestal
484 // 1.664 * Si_Thickness * Si_Density fVA1MipRange
485 //
486 //
487 // = Energy_Deposited * ConversionFactor + pedestal
488 //
489 // However, this is modified by the response function of the
490 // VA1_ALICE pre-amp. chip in case we are doing oversampling of the
491 // VA1_ALICE output.
492 //
493 // In that case, we get N=fSampleRate values of the ADC, and the
494 // `EnergyDeposited' is a function of which sample where are
495 // calculating the ADC for
496 //
497 // ADC_i = f(EnergyDeposited, i/N, Last) * ConversionFactor + pedestal
498 //
499 // where Last is the Energy deposited in the previous strip.
500 //
501 // Here, f is the shaping function of the VA1_ALICE. This is given
502 // by
503 //
504 // | (E - l) * (1 - exp(-B * t) + l if E > l
505 // f(E, t, l) = <
506 // | (l - E) * exp(-B * t) + E otherwise
507 //
508 //
509 // = E + (l - E) * ext(-B * t)
510 //
511 AliFMDParameters* param = AliFMDParameters::Instance();
83ad576a 512 Float_t convF = (param->GetDACPerMIP() / param->GetEdepMip() *
513 param->GetPulseGain(detector,ring,sector,strip));
a9579262 514 Int_t ped = MakePedestal(detector,ring,sector,strip);
515 Int_t maxAdc = param->GetAltroChannelSize()-1;
516 if (maxAdc < 0) {
517 AliWarning(Form("Maximum ADC is %d < 0, forcing it to 1023", maxAdc));
518 maxAdc = 1023;
519 }
02a27b50 520 UShort_t rate = param->GetSampleRate(detector,ring,sector,strip);
ef8e8623 521 AliFMDDebug(15, ("Sample rate for FMD%d%c[%2d,%3d] = %d",
83ad576a 522 detector, ring, sector, strip, rate));
ef8e8623 523 if (rate < 1 || rate > 4) {
524 AliWarning(Form("Invalid sample rate for for FMD%d%c[%2d,%3d] = %d",
525 detector, ring, sector, strip, rate));
526 rate = 1;
527 }
528
02a27b50 529 // In case we don't oversample, just return the end value.
530 if (rate == 1) {
a9579262 531 Float_t a = edep * convF + ped;
532 if (a < 0) a = 0;
533 counts[0] = UShort_t(TMath::Min(a, Float_t(maxAdc)));
ef8e8623 534 AliFMDDebug(15, ("FMD%d%c[%2d,%3d]: converting ELoss %f to "
a9579262 535 "ADC %4d (%f,%d)",
536 detector,ring,sector,strip,edep,counts[0],convF,ped));
02a27b50 537 return;
538 }
83ad576a 539
02a27b50 540
541 // Create a pedestal
542 Float_t b = fShapingTime;
543 for (Ssiz_t i = 0; i < rate; i++) {
2aeec17d 544 Float_t t = Float_t(i) / rate + 1./rate;
a9579262 545 Float_t s = edep + (last - edep) * TMath::Exp(-b * t);
546 Float_t a = Int_t(s * convF + ped);
547 if (a < 0) a = 0;
548 counts[i] = UShort_t(TMath::Min(a, Float_t(maxAdc)));
02a27b50 549 }
83ad576a 550 AliFMDDebug(15, ("Converted edep = %f to ADC (%x,%x,%x,%x) "
551 "[gain: %f=(%f/%f*%f), pedestal: %d, rate: %d]",
552 edep, counts[0], counts[1], counts[2], counts[3],
553 convF, param->GetDACPerMIP(),param->GetEdepMip(),
554 param->GetPulseGain(detector,ring,sector,strip),
555 ped, rate));
02a27b50 556}
557
ef8e8623 558//____________________________________________________________________
559void
b2e6f0b0 560AliFMDBaseDigitizer::AddDigit(UShort_t detector,
561 Char_t ring,
562 UShort_t sector,
563 UShort_t strip,
564 Float_t /* edep */,
565 UShort_t count1,
566 Short_t count2,
567 Short_t count3,
568 Short_t count4,
8d00dfa3 569 UShort_t ntot,
b2e6f0b0 570 UShort_t /* nprim */,
faf80567 571 const TArrayI& refs) const
ef8e8623 572{
573 // Add a digit or summable digit
ef8e8623 574 fFMD->AddDigitByFields(detector, ring, sector, strip,
8d00dfa3 575 count1, count2, count3, count4,
576 ntot, fStoreTrackRefs ? refs.fArray : 0);
ef8e8623 577}
02a27b50 578
ef8e8623 579//____________________________________________________________________
580TTree*
581AliFMDBaseDigitizer::MakeOutputTree(AliLoader* loader)
582{
583 // Create output tree using loader. If the passed loader differs
584 // from the currently set loader in the FMD object, reset the FMD
585 // loader to be the passed loader. This is for the cases wher the
586 // output is different from the output.
587 AliFMDDebug(5, ("Making digits tree"));
588 loader->LoadDigits("UPDATE"); // "RECREATE");
589 TTree* out = loader->TreeD();
590 if (!out) loader->MakeTree("D");
591 out = loader->TreeD();
592 if (out) {
593 out->Reset();
594 if (loader != fFMD->GetLoader())
595 fFMD->SetLoader(loader);
596 fFMD->MakeBranch("D");
597 }
598 return out;
599}
600
601//____________________________________________________________________
602void
603AliFMDBaseDigitizer::StoreDigits(AliLoader* loader)
604{
605 // Write the digits to disk
606 AliFMDDebug(5, ("Storing %d digits", fFMD->Digits()->GetEntries()));
607 loader->WriteDigits("OVERWRITE");
608 loader->UnloadDigits();
609 // Reset the digits in the AliFMD object
610 fFMD->ResetDigits();
611}
02a27b50 612
613//____________________________________________________________________
614//
615// EOF
616//
617
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619
620