libraries/DAQ/DEVIOWorkerThread.cc

Bug Summary

File:	libraries/DAQ/DEVIOWorkerThread.cc
Location:	line 919, column 17
Description:	Called C++ object pointer is null

Annotated Source Code

/// $Id$

// File: DEVIOWorkerThread.cc

// Created: Mon Mar 28 07:40:07 EDT 2016

// Creator: davidl (on Darwin harriet.jlab.org 13.4.0 i386)

#include <unistd.h>

#include "DEVIOWorkerThread.h"

#include "JEventSource_EVIOpp.h"

#include "LinkAssociations.h"

#include <swap_bank.h>

using namespace std;

using namespace std::chrono;

//---------------------------------

// DEVIOWorkerThread (Constructor)

//---------------------------------

DEVIOWorkerThread::DEVIOWorkerThread(

JEventSource_EVIOpp *event_source

,list<DParsedEvent*> &parsed_events

,uint32_t &MAX_PARSED_EVENTS

,mutex &PARSED_EVENTS_MUTEX

,condition_variable &PARSED_EVENTS_CV

event_source(event_source)

,parsed_events(parsed_events)

,MAX_PARSED_EVENTS(MAX_PARSED_EVENTS)

,PARSED_EVENTS_MUTEX(PARSED_EVENTS_MUTEX)

,PARSED_EVENTS_CV(PARSED_EVENTS_CV)

,done(false)

,thd(&DEVIOWorkerThread::Run,this)

{

// n.b. in principal, the worker thread is started when the

// above constructor is hit and so may already be in Run()

// before executing anything below. The "done" variable is

// therefore initialized first to guarantee that if that

// happens, it gets to the cv.wait() call where it will wait

// for someone to notify it. That won't happen before this

// constructor completes so we do the remaining initializations

// below.

VERBOSE = 1;

Nrecycled = 0; // Incremented in JEventSource_EVIOpp::Dispatcher()

MAX_EVENT_RECYCLES = 1000; // In EVIO events (not L1 trigger events!) overwritten in JEventSource_EVIOpp constructor

MAX_OBJECT_RECYCLES = 1000; // overwritten in JEventSource_EVIOpp constructor

run_number_seed = 0; // Set in JEventSource_EVIOpp constructor

in_use = false;

jobtype = JOB_NONE;

buff_len = 100; // this will grow as needed

buff = new uint32_t[buff_len];

PARSE_F250 = true;

PARSE_F125 = true;

PARSE_F1TDC = true;

PARSE_CAEN1290TDC = true;

PARSE_CONFIG = true;

PARSE_BOR = true;

PARSE_EPICS = true;

PARSE_EVENTTAG = true;

PARSE_TRIGGER = true;

LINK_TRIGGERTIME = true;

}

//---------------------------------

// ~DEVIOWorkerThread (Destructor)

//---------------------------------

DEVIOWorkerThread::~DEVIOWorkerThread()

{

if(buff) delete[] buff;

for(auto pe : parsed_event_pool) delete pe;

}

//---------------------------------

// Run

//---------------------------------

void DEVIOWorkerThread::Run(void)

{

unique_lock<std::mutex> lck(mtx);

// Loop waiting for jobs or until told to quit

while(!done){

cv.wait_for(lck, std::chrono::milliseconds(1));

// In principle, in_use should never be false with a jobtype!=JOB_NONE

// In practice, this has happened, possibly due to compiler optimization

// reordering things in JEventSource_EVIOpp::Dispatcher. That led to

// attempting to process a buffer that was being written to. Avoid that

// condition by checking the in_use flag is really set.

if( !in_use ) continue;

100

101

try {

102

103

if( jobtype & JOB_SWAP ) swap_bank(buff, buff, swap32(buff[0])( (((buff[0]) >> 24) & 0x000000FF) | (((buff[0]) >>
8) & 0x0000FF00) | (((buff[0]) << 8) & 0x00FF0000
) | (((buff[0]) << 24) & 0xFF000000) )+1 );

104

105

if( jobtype & JOB_FULL_PARSE ) MakeEvents();

106

107

if( jobtype & JOB_ASSOCIATE ) LinkAllAssociations();

108

109

if( !current_parsed_events.empty() ) PublishEvents();

110

111

} catch (exception &e) {

112

jerr << e.what() << endl;

113

for(auto pe : parsed_event_pool) delete pe; // delete all parsed events any any objects they hold

114

parsed_event_pool.clear();

115

current_parsed_events.clear(); // (these are also in parsed_event_pool so were already deleted)

116

//exit(-1);

117

}

118

119

// Reset and mark us as available for use

120

jobtype = JOB_NONE;

121

in_use = false;

122

123

if( jobtype & JOB_QUIT ) break;

124

}

125

126

in_use = false;

127

}

128

129

//---------------------------------

130

// Finish

131

//---------------------------------

132

void DEVIOWorkerThread::Finish(bool wait_to_complete)

133

{

134

/// Set the done flag so that the worker thread

135

/// will exit once it is done processing its current

136

/// job. The thread is notified to wake up in case

137

/// it is currently idle. If the wait_to_complete

138

/// flag is set (default), then the worker thread is

139

/// joined to guarantee the current job's processing

140

/// is completed before returning.

141

done = true;

142

cv.notify_all();

143

if(wait_to_complete) {

144

thd.join();

145

} else {

146

thd.detach();

147

}

148

}

149

150

//---------------------------------

151

// Prune

152

//---------------------------------

153

void DEVIOWorkerThread::Prune(void)

154

{

155

/// Delete any DParsedEvent objects not currently in use.

156

/// If the DParsedEvent object pool and their internal

157

/// hit object pools are allowed to continuously grow, it

158

/// will appear as a though there is a memory leak. Occasional

159

/// pruning will reduce the average memory footprint.

160

/// This is called from MakeEvents() every MAX_EVENT_RECYCLES

161

/// EVIO events processed by this worker thread.

162

/// Note that this is in EVIO events (i.e. possibly a block

163

/// of events) not in L1 trigger events.

164

///

165

/// NOTE: We currently do NOT reduce the size of buff

166

/// here if it is too big. We may wish to do that at some point!

167

168

// Delete extra parsed events

169

vector<DParsedEvent*> tmp_events = parsed_event_pool;

170

parsed_event_pool.clear();

171

for(auto pe : tmp_events) {

172

if(pe->in_use)

173

parsed_event_pool.push_back(pe);

174

else

175

delete pe;

176

177

}

178

}

179

180

//---------------------------------

181

// MakeEvents

182

//---------------------------------

183

void DEVIOWorkerThread::MakeEvents(void)

184

{

185

186

/// Make DParsedEvent objects from data currently in buff.

187

/// This will look at the begining of the EVIO event to see

188

/// how many L1 events are in it. It will then grab that many

189

/// DParsedEvent objects from this threads pool , or create

190

/// new ones and add them all to the current_parsed_events

191

/// vector. These are then filled out later as the data is

192

/// parsed.

193

194

if(!current_parsed_events.empty()) throw JException("Attempting call to DEVIOWorkerThread::MakeEvents when current_parsed_events not empty!!", __FILE__"libraries/DAQ/DEVIOWorkerThread.cc", __LINE__194);

195

196

uint32_t *iptr = buff;

197

198

uint32_t M = 1;

199

uint64_t event_num = 0;

200

201

iptr++;

202

uint32_t mask = 0xFF001000;

203

if( ((*iptr)&mask) == mask ){

204

// Physics event

205

M = *(iptr)&0xFF;

206

uint64_t eventnum_lo = iptr[4];

207

uint64_t eventnum_hi = iptr[5];

208

event_num = (eventnum_hi<<32) + (eventnum_lo);

209

}

210

211

// Try and get M DParsedEvent objects from this thread's pool.

212

for(auto pe : parsed_event_pool){

213

if(pe->in_use) continue;

214

current_parsed_events.push_back(pe);

215

if( current_parsed_events.size() >= M ) break;

216

}

217

218

// Create new DParsedEvent objects if needed

219

while( current_parsed_events.size() < M ){

220

DParsedEvent *pe = new DParsedEvent(MAX_OBJECT_RECYCLES);

221

current_parsed_events.push_back(pe);

222

parsed_event_pool.push_back(pe);

223

}

224

225

// Set indexes for the parsed event objects

226

// and flag them as being in use.

227

for(auto pe : current_parsed_events){

228

229

pe->Clear(); // return previous event's objects to pools and clear vectors

230

pe->istreamorder = istreamorder;

231

pe->run_number = run_number_seed;

232

pe->event_number = event_num++;

233

pe->sync_flag = false;

234

pe->in_use = true;

235

pe->copied_to_factories = false;

236

pe->event_status_bits = 0;

237

pe->borptrs = NULL__null; // may be set by either ParseBORbank or JEventSource_EVIOpp::GetEvent

238

}

239

240

// Parse data in buffer to create data objects

241

ParseBank();

242

243

// Occasionally prune extra DParsedEvent objects as well as objects

244

// from the existing pools to reduce average memory usage. We do

245

// this after parsing so that not everything is deleted (objects

246

// being used this event will be returned to the pools later.)

247

if(++Nrecycled%MAX_EVENT_RECYCLES == 0) Prune();

248

for(auto pe : current_parsed_events){

249

if( ++pe->Nrecycled%pe->MAX_RECYCLES == 0) pe->Prune();

250

}

251

}

252

253

//---------------------------------

254

// PublishEvents

255

//---------------------------------

256

void DEVIOWorkerThread::PublishEvents(void)

257

{

258

/// Copy our "current_parsed_events" pointers into the global "parsed_events"

259

/// list making them available for consumption.

260

261

// Lock mutex so other threads can't modify parsed_events

262

unique_lock<mutex> lck(PARSED_EVENTS_MUTEX);

263

264

// Make sure we don't exceed the maximum number of simultaneous

265

// parsed events. If the done flag is set, go ahead and add

266

// this regardless

267

while( ((current_parsed_events.size()+parsed_events.size())>=MAX_PARSED_EVENTS) && !done ){

268

event_source->NPARSER_STALLED++;

269

PARSED_EVENTS_CV.wait_for(lck, std::chrono::milliseconds(1));

270

}

271

272

// Loop over all elements of parsed_events and insert

273

// these based on istreamorder so that the front element

274

// is the most recent.

275

bool inserted = false;

276

for(auto it = parsed_events.begin(); it!=parsed_events.end(); it++){

277

if( istreamorder < (*it)->istreamorder ){

278

parsed_events.insert(it, current_parsed_events.begin(), current_parsed_events.end());

279

inserted = true;

280

break;

281

}

282

}

283

284

// In case this should go at end of list

285

if(!inserted) parsed_events.insert(parsed_events.end(), current_parsed_events.begin(), current_parsed_events.end());

286

287

lck.unlock();

288

PARSED_EVENTS_CV.notify_all();

289

290

// Any events should now be published

291

current_parsed_events.clear();

292

}

293

294

//---------------------------------

295

// ParseBank

296

//---------------------------------

297

void DEVIOWorkerThread::ParseBank(void)

298

{

299

300

uint32_t *iptr = buff;

301

uint32_t *iend = &buff[buff[0]+1];

302

303

while(iptr < iend){

304

uint32_t event_len = iptr[0];

305

uint32_t event_head = iptr[1];

306

uint32_t tag = (event_head >> 16) & 0xFFFF;

307

308

//_DBG_ << "tag=" << hex << tag << dec << endl;

309

310

switch(tag){

311

case 0x0060: ParseEPICSbank(iptr, iend); break;

312

case 0x0070: ParseBORbank(iptr, iend); break;

313

314

case 0xFFD0:

315

case 0xFFD1:

316

case 0xFFD2:

317

case 0xFFD3: ParseControlEvent(iptr, iend); break;

318

319

case 0xFF58:

320

case 0xFF78: current_parsed_events.back()->sync_flag = true;

321

case 0xFF50:

322

case 0xFF70: ParsePhysicsBank(iptr, iend); break;

323

324

default:

325

_DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<325<<" " << "Unknown outer EVIO bank tag: " << hex << tag << dec << endl;

326

iptr = &iptr[event_len+1];

327

if(event_len<1) iptr = iend;

328

}

329

}

330

}

331

332

//---------------------------------

333

// ParseEventTagBank

334

//---------------------------------

335

void DEVIOWorkerThread::ParseEventTagBank(uint32_t* &iptr, uint32_t *iend)

336

{

337

iptr = &iptr[(*iptr) + 1];

338

}

339

340

//---------------------------------

341

// ParseEPICSbank

342

//---------------------------------

343

void DEVIOWorkerThread::ParseEPICSbank(uint32_t* &iptr, uint32_t *iend)

344

{

345

if(!PARSE_EPICS){ iptr = iend; return; }

346

347

time_t timestamp=0;

348

349

// Outer bank

350

uint32_t *istart = iptr;

351

uint32_t epics_bank_len = *iptr++;

352

if(epics_bank_len < 1){

353

_DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<353<<" " << "bank_len<1 in EPICS event!" << endl;

354

iptr = iend;

355

return;

356

}

357

358

uint32_t *iend_epics = &iptr[epics_bank_len];

359

if( iend_epics < iend ) iend = iend_epics;

360

361

// Advance to first daughter bank

362

iptr++;

363

364

// Get pointer to first DParsedEvent

365

DParsedEvent *pe = current_parsed_events.front();

366

pe->event_status_bits |= (1<<kSTATUS_EPICS_EVENT);

367

368

// Loop over daughter banks

369

while( iptr < iend_epics ){

370

371

uint32_t bank_len = (*iptr)&0xFFFF;

372

uint32_t tag = ((*iptr)>>24)&0xFF;

373

iptr++;

374

375

if(tag == 0x61){

376

// timestamp bank

377

timestamp = *iptr;

378

}else if(tag == 0x62){

379

// EPICS data value

380

string nameval = (const char*)iptr;

381

pe->NEW_DEPICSvalue(timestamp, nameval);

382

}else{

383

// Unknown tag. Bail

384

_DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<384<<" " << "Unknown tag 0x" << hex << tag << dec << " in EPICS event!" <<endl;

385

DumpBinary(istart, iend_epics, 32, &iptr[-1]);

386

}

387

388

iptr = &iptr[bank_len];

389

}

390

391

iptr = iend_epics;

392

}

393

394

//---------------------------------

395

// ParseBORbank

396

//---------------------------------

397

void DEVIOWorkerThread::ParseBORbank(uint32_t* &iptr, uint32_t *iend)

398

{

399

/// Create BOR config objects from the EVIO bank and store them in

400

/// the event (should only be one since BOR events are not entangled).

401

/// These objects will eventually be inherited by the JEventSource_EVIOpp

402

/// object and passed to all subsequent events.

403

404

// Upon entry, iptr should point to length word of a bank of banks with tag=0x70

405

// indicating BOR event. Each bank contained within will represent one crate and

406

// will be a bank with tag=0x71 and num the rocid, containing tagsegments. Each tagsegment

407

// represents a single module with the tag containing the module type (bits 0-4) and

408

// slot (bits 5-10). The data in the tagsegments is uint32_t and maps to a data

409

// structure in bor_roc.h depending on the module type. Below is a summary of

410

// how this looks in memory:

411

412

// BOR event length

413

// BOR header

414

// crate bank length

415

// crate header

416

// module bank len/header

417

// module data ...

418

// module bank len/header

419

// module data ...

420

// ...

421

// crate bank length

422

// crate header

423

// ...

424

425

if(!PARSE_BOR){ iptr = &iptr[(*iptr) + 1]; return; }

426

427

// Make sure there is exactly 1 event in current_parsed_events

428

if(current_parsed_events.size() != 1){

429

stringstream ss;

430

ss << "DEVIOWorkerThread::ParseBORbank called for EVIO event with " << current_parsed_events.size() << " events in it. (Should be exactly 1!)";

431

throw JException(ss.str(), __FILE__"libraries/DAQ/DEVIOWorkerThread.cc", __LINE__431);

432

}

433

434

// Create new DBORptrs object and set pointer to it in DParsedEvent

435

// (see JEventSource_EVIOpp::GetEvent)

436

DParsedEvent *pe = current_parsed_events.front();

437

pe->event_status_bits |= (1<<kSTATUS_BOR_EVENT);

438

pe->borptrs = new DBORptrs();

439

DBORptrs* &borptrs = pe->borptrs;

440

441

// Make sure we have full event

442

uint32_t borevent_len = *iptr++;

443

uint32_t bank_len = (uint32_t)((uint64_t)iend - (uint64_t)iptr)/sizeof(uint32_t);

444

if(borevent_len > bank_len){

445

stringstream ss;

446

ss << "BOR: Size of bank doesn't match amount of data given (" << borevent_len << " > " << bank_len << ")";

447

throw JException(ss.str(), __FILE__"libraries/DAQ/DEVIOWorkerThread.cc", __LINE__447);

448

}

449

iend = &iptr[borevent_len]; // in case they give us too much data!

450

451

// Make sure BOR header word is right

452

uint32_t bor_header = *iptr++;

453

if(bor_header != 0x700e01){

454

stringstream ss;

455

ss << "Bad BOR header: 0x" << hex << bor_header;

456

throw JException(ss.str(), __FILE__"libraries/DAQ/DEVIOWorkerThread.cc", __LINE__456);

457

}

458

459

// Loop over crates

460

while(iptr<iend){

461

uint32_t crate_len = *iptr++;

462

uint32_t *iend_crate = &iptr[crate_len]; // points to first word after this crate

463

uint32_t crate_header = *iptr++;

464

// uint32_t rocid = crate_header&0xFF;

465

466

// Make sure crate tag is right

467

if( (crate_header>>16) != 0x71 ){

468

stringstream ss;

469

ss << "Bad BOR crate header: 0x" << hex << (crate_header>>16);

470

throw JException(ss.str(), __FILE__"libraries/DAQ/DEVIOWorkerThread.cc", __LINE__470);

471

}

472

473

// Loop over modules

474

while(iptr<iend_crate){

475

uint32_t module_header = *iptr++;

476

uint32_t module_len = module_header&0xFFFF;

477

uint32_t modType = (module_header>>20)&0x1f;

478

// uint32_t slot = (module_header>>25);

479

// uint32_t *iend_module = &iptr[module_len]; // points to first word after this module

480

481

uint32_t *src = iptr;

482

uint32_t *dest = NULL__null;

483

uint32_t sizeof_dest = 0;

484

485

Df250BORConfig *f250conf = NULL__null;

486

Df125BORConfig *f125conf = NULL__null;

487

DF1TDCBORConfig *F1TDCconf = NULL__null;

488

DCAEN1290TDCBORConfig *caen1190conf = NULL__null;

489

490

switch(modType){

491

case DModuleType::FADC250: // f250

492

f250conf = new Df250BORConfig;

493

dest = (uint32_t*)&f250conf->rocid;

494

sizeof_dest = sizeof(f250config);

495

break;

496

case DModuleType::FADC125: // f125

497

f125conf = new Df125BORConfig;

498

dest = (uint32_t*)&f125conf->rocid;

499

sizeof_dest = sizeof(f125config);

500

break;

501

502

case DModuleType::F1TDC32: // F1TDCv2

503

case DModuleType::F1TDC48: // F1TDCv3

504

F1TDCconf = new DF1TDCBORConfig;

505

dest = (uint32_t*)&F1TDCconf->rocid;

506

sizeof_dest = sizeof(F1TDCconfig);

507

break;

508

509

case DModuleType::CAEN1190: // CAEN 1190 TDC

510

case DModuleType::CAEN1290: // CAEN 1290 TDC

511

caen1190conf = new DCAEN1290TDCBORConfig;

512

dest = (uint32_t*)&caen1190conf->rocid;

513

sizeof_dest = sizeof(caen1190config);

514

break;

515

516

default:

517

{

518

stringstream ss;

519

ss << "Unknown BOR module type: " << modType << " (module_header=0x"<<hex<<module_header<<")";

520

jerr << ss.str() << endl;

521

throw JException(ss.str(), __FILE__"libraries/DAQ/DEVIOWorkerThread.cc", __LINE__521);

522

}

523

}

524

525

// Check that the bank size and data structure size match.

526

if( module_len != (sizeof_dest/sizeof(uint32_t)) ){

527

stringstream ss;

528

ss << "BOR module bank size does not match structure! " << module_len << " != " << (sizeof_dest/sizeof(uint32_t)) << " for modType " << modType;

529

throw JException(ss.str(), __FILE__"libraries/DAQ/DEVIOWorkerThread.cc", __LINE__529);

530

}

531

532

// Copy bank data, assuming format is the same

533

for(uint32_t i=0; i<module_len; i++) *dest++ = *src++;

534

535

// Store object for use in this and subsequent events

536

if(f250conf ) borptrs->vDf250BORConfig.push_back(f250conf);

537

if(f125conf ) borptrs->vDf125BORConfig.push_back(f125conf);

538

if(F1TDCconf ) borptrs->vDF1TDCBORConfig.push_back(F1TDCconf);

539

if(caen1190conf) borptrs->vDCAEN1290TDCBORConfig.push_back(caen1190conf);

540

541

iptr = &iptr[module_len];

542

}

543

544

iptr = iend_crate; // ensure we're pointing past this crate

545

}

546

547

// Sort the BOR config events now so we don't have to do it for every event

548

borptrs->Sort();

549

550

}

551

552

//---------------------------------

553

// ParseTSscalerBank

554

//---------------------------------

555

void DEVIOWorkerThread::ParseTSscalerBank(uint32_t* &iptr, uint32_t *iend)

556

{

557

uint32_t Nwords = ((uint64_t)iend - (uint64_t)iptr)/sizeof(uint32_t);

558

uint32_t Nwords_expected = (6+32+16+32+16);

559

if(Nwords != Nwords_expected){

560

_DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<560<<" " << "TS bank size does not match expected!!" << endl;

561

_DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<561<<" " << "Found " << Nwords << " words. Expected " << Nwords_expected << endl;

562

563

}else{

564

// n.b. Get the last event here since if this is a block

565

// of events, the last should be the actual sync event.

566

DParsedEvent *pe = current_parsed_events.back();

567

DL1Info *s = pe->NEW_DL1Info();

568

s->nsync = *iptr++;

569

s->trig_number = *iptr++;

570

s->live_time = *iptr++;

571

s->busy_time = *iptr++;

572

s->live_inst = *iptr++;

573

s->unix_time = *iptr++;

574

for(uint32_t i=0; i<32; i++) s->gtp_sc.push_back ( *iptr++ );

575

for(uint32_t i=0; i<16; i++) s->fp_sc.push_back ( *iptr++ );

576

for(uint32_t i=0; i<32; i++) s->gtp_rate.push_back( *iptr++ );

577

for(uint32_t i=0; i<16; i++) s->fp_rate.push_back ( *iptr++ );

578

}

579

580

iptr = iend;

581

}

582

583

//---------------------------------

584

// Parsef250scalerBank

585

//---------------------------------

586

void DEVIOWorkerThread::Parsef250scalerBank(uint32_t* &iptr, uint32_t *iend)

587

{

588

iptr = &iptr[(*iptr) + 1];

589

}

590

591

//---------------------------------

592

// ParseControlEvent

593

//---------------------------------

594

void DEVIOWorkerThread::ParseControlEvent(uint32_t* &iptr, uint32_t *iend)

595

{

596

for(auto pe : current_parsed_events) pe->event_status_bits |= (1<<kSTATUS_CONTROL_EVENT);

597

598

iptr = &iptr[(*iptr) + 1];

599

}

600

601

//---------------------------------

602

// ParsePhysicsBank

603

//---------------------------------

604

void DEVIOWorkerThread::ParsePhysicsBank(uint32_t* &iptr, uint32_t *iend)

605

{

606

607

for(auto pe : current_parsed_events) pe->event_status_bits |= (1<<kSTATUS_PHYSICS_EVENT);

608

609

uint32_t physics_event_len = *iptr++;

610

uint32_t *iend_physics_event = &iptr[physics_event_len];

611

iptr++;

612

613

// Built Trigger Bank

614

uint32_t built_trigger_bank_len = *iptr;

615

uint32_t *iend_built_trigger_bank = &iptr[built_trigger_bank_len+1];

616

ParseBuiltTriggerBank(iptr, iend_built_trigger_bank);

617

iptr = iend_built_trigger_bank;

618

619

// Loop over Data banks

620

while( iptr < iend_physics_event ) {

621

622

uint32_t data_bank_len = *iptr;

623

uint32_t *iend_data_bank = &iptr[data_bank_len+1];

624

625

ParseDataBank(iptr, iend_data_bank);

626

627

iptr = iend_data_bank;

628

}

629

630

iptr = iend_physics_event;

631

}

632

633

//---------------------------------

634

// ParseBuiltTriggerBank

635

//---------------------------------

636

void DEVIOWorkerThread::ParseBuiltTriggerBank(uint32_t* &iptr, uint32_t *iend)

637

{

638

if(!PARSE_TRIGGER) return;

639

640

iptr++; // advance past length word

641

uint32_t mask = 0xFF202000;

642

if( ((*iptr) & mask) != mask ){

643

stringstream ss;

644

ss << "Bad header word in Built Trigger Bank: " << hex << *iptr;

645

throw JException(ss.str(), __FILE__"libraries/DAQ/DEVIOWorkerThread.cc", __LINE__645);

646

}

647

648

uint32_t tag = (*iptr)>>16; // 0xFF2X

649

uint32_t Nrocs = (*iptr++) & 0xFF;

650

uint32_t Mevents = current_parsed_events.size();

651

652

//-------- Common data (64bit)

653

uint32_t common_header64 = *iptr++;

654

uint32_t common_header64_len = common_header64 & 0xFFFF;

655

uint64_t *iptr64 = (uint64_t*)iptr;

656

iptr = &iptr[common_header64_len];

657

658

// First event number

659

uint64_t first_event_num = *iptr64++;

660

661

// Hi and lo 32bit words in 64bit numbers seem to be

662

// switched for events read from ET, but not read from

663

// file. Not sure if this is in the swapping routine

664

// if(source_type==kETSource) first_event_num = (first_event_num>>32) | (first_event_num<<32);

665

666

// Average timestamps

667

uint32_t Ntimestamps = (common_header64_len/2)-1;

668

if(tag & 0x2) Ntimestamps--; // subtract 1 for run number/type word if present

669

vector<uint64_t> avg_timestamps;

670

for(uint32_t i=0; i<Ntimestamps; i++) avg_timestamps.push_back(*iptr64++);

671

672

// run number and run type

673

uint32_t run_number = 0;

674

uint32_t run_type = 0;

675

if(tag & 0x02){

676

run_number = (*iptr64) >> 32;

677

run_type = (*iptr64) & 0xFFFFFFFF;

678

iptr64++;

679

}

680

681

//-------- Common data (16bit)

682

uint32_t common_header16 = *iptr++;

683

uint32_t common_header16_len = common_header16 & 0xFFFF;

684

uint16_t *iptr16 = (uint16_t*)iptr;

685

iptr = &iptr[common_header16_len];

686

687

vector<uint16_t> event_types;

688

for(uint32_t i=0; i<Mevents; i++) event_types.push_back(*iptr16++);

689

690

//-------- ROC data (32bit)

691

for(uint32_t iroc=0; iroc<Nrocs; iroc++){

692

uint32_t common_header32 = *iptr++;

693

uint32_t common_header32_len = common_header32 & 0xFFFF;

694

uint32_t rocid = common_header32 >> 24;

695

696

uint32_t Nwords_per_event = common_header32_len/Mevents;

697

for(auto pe : current_parsed_events){

698

699

DCODAROCInfo *codarocinfo = pe->NEW_DCODAROCInfo();

700

codarocinfo->rocid = rocid;

701

702

uint64_t ts_low = *iptr++;

703

uint64_t ts_high = *iptr++;

704

codarocinfo->timestamp = (ts_high<<32) + ts_low;

705

codarocinfo->misc.clear(); // could be recycled from previous event

706

for(uint32_t i=2; i<Nwords_per_event; i++) codarocinfo->misc.push_back(*iptr++);

707

708

if(iptr > iend){

709

throw JException("Bad data format in ParseBuiltTriggerBank!", __FILE__"libraries/DAQ/DEVIOWorkerThread.cc", __LINE__709);

710

}

711

}

712

}

713

714

//-------- Make DCODAEventInfo objects

715

uint64_t ievent = 0;

716

for(auto pe : current_parsed_events){

717

718

pe->run_number = run_number; // may be overwritten in JEventSource_EVIOpp::GetEvent()

719

720

DCODAEventInfo *codaeventinfo = pe->NEW_DCODAEventInfo();

721

codaeventinfo->run_number = run_number;

722

codaeventinfo->run_type = run_type;

723

codaeventinfo->event_number = first_event_num + ievent;

724

codaeventinfo->event_type = event_types.empty() ? 0:event_types[ievent];

725

codaeventinfo->avg_timestamp = avg_timestamps.empty() ? 0:avg_timestamps[ievent];

726

ievent++;

727

}

728

}

729

730

//---------------------------------

731

// ParseDataBank

732

//---------------------------------

733

void DEVIOWorkerThread::ParseDataBank(uint32_t* &iptr, uint32_t *iend)

734

{

735

// Physics Event's Data Bank header

736

iptr++; // advance past data bank length word

737

uint32_t rocid = ((*iptr)>>16) & 0xFFF;

738

iptr++;

739

740

// Loop over Data Block Banks

741

while(iptr < iend){

742

743

uint32_t data_block_bank_len = *iptr++;

744

uint32_t *iend_data_block_bank = &iptr[data_block_bank_len];

745

uint32_t data_block_bank_header = *iptr++;

746

747

// Not sure where this comes from, but it needs to be skipped if present

748

while( (*iptr==0xF800FAFA) && (iptr<iend) ) iptr++;

749

750

uint32_t det_id = (data_block_bank_header>>16) & 0xFFF;

751

switch(det_id){

752

753

case 20:

754

ParseCAEN1190(rocid, iptr, iend_data_block_bank);

755

break;

756

757

case 0x55:

758

ParseModuleConfiguration(rocid, iptr, iend_data_block_bank);

759

break;

760

761

case 0x56:

762

ParseEventTagBank(iptr, iend_data_block_bank);

763

break;

764

765

case 0:

766

case 1:

767

case 3:

768

case 6: // flash 250 module, MMD 2014/2/4

769

case 16: // flash 125 module (CDC), DL 2014/6/19

770

case 26: // F1 TDC module (BCAL), MMD 2014-07-31

771

ParseJLabModuleData(rocid, iptr, iend_data_block_bank);

772

break;

773

774

// These were implemented in the ROL for sync events

775

// as 0xEE02 and 0xEE05. However, that violates the

776

// spec. which reserves the top 4 bits as status bits

777

// (the first "E" should really be a "1". We just check

778

// other 12 bits here.

779

case 0xE02:

780

ParseTSscalerBank(iptr, iend);

781

break;

782

case 0xE05:

783

Parsef250scalerBank(iptr, iend);

784

break;

785

case 0xE10: // really wish Sascha would share when he does this stuff!

786

Parsef250scalerBank(iptr, iend);

787

break;

788

789

// When we write out single events in the offline, we also can save some

790

// higher level data objects to save disk space and speed up

791

// specialized processing (e.g. pi0 calibration)

792

case 0xD01:

793

ParseDVertexBank(iptr, iend);

794

break;

795

796

case 5:

797

// old ROL Beni used had this but I don't think its

798

// been used for years. Run 10390 seems to have

799

// this though (???)

800

break;

801

802

803

default:

804

jerr<<"Unknown module type ("<<det_id<<" = " << hex << det_id << dec << " ) encountered" << endl;

805

// if(VERBOSE>5){

806

cout << "----- First few words to help with debugging -----" << endl;

807

cout.flush(); cerr.flush();

808

DumpBinary(&iptr[-2], iend, 32, &iptr[-1]);

809

// }

810

}

811

812

iptr = iend_data_block_bank;

813

}

814

815

}

816

817

//----------------

818

// ParseTIBank

819

//----------------

820

void DEVIOWorkerThread::ParseTIBank(uint32_t rocid, uint32_t* &iptr, uint32_t* iend)

821

{

822

while(iptr<iend && ((*iptr) & 0xF8000000) != 0x88000000) iptr++; // Skip to JLab block trailer

823

iptr++; // advance past JLab block trailer

824

while(iptr<iend && *iptr == 0xF8000000) iptr++; // skip filler words after block trailer

825

//iptr = iend;

826

}

827

828

//----------------

829

// ParseCAEN1190

830

//----------------

831

void DEVIOWorkerThread::ParseCAEN1190(uint32_t rocid, uint32_t* &iptr, uint32_t *iend)

832

{

833

if(!PARSE_CAEN1290TDC){ iptr = &iptr[(*iptr) + 1]; return; }

Taking false branch

→

834

835

/// Parse data from a CAEN 1190 or 1290 module

836

/// (See ppg. 72-74 of V1290_REV15.pdf manual)

837

838

uint32_t slot = 0;

839

uint32_t event_count = 0;

840

uint32_t word_count = 0;

841

uint32_t trigger_time_tag = 0;

842

uint32_t tdc_num = 0;

843

uint32_t event_id = 0;

844

uint32_t bunch_id = 0;

845

846

// We need to accomodate multi-event blocks where

847

// events are entangled (i.e. hits from event 1

848

// are mixed in between those of event 2,3,4,

849

// etc... With CAEN modules, we only know which

850

// event a hit came from by looking at the event_id

851

// in the TDC header. This value is only 12 bits

852

// and could roll over within an event block. This

853

// means we need to keep track of the order we

854

// encounter them in so it is maintained in the

855

// "events" container. The event_id order is kept

856

// in the "event_id_order" vector.

857

map<uint32_t, DParsedEvent*> events_by_event_id;

858

859

auto pe_iter = current_parsed_events.begin();

860

DParsedEvent *pe = NULL__null;

←

'pe' initialized to a null pointer value

→

861

862

while(iptr<iend){

←

Assuming 'iptr' is < 'iend'

→

←

Loop condition is true. Entering loop body

→

←

Loop condition is true. Entering loop body

→

←

Loop condition is true. Entering loop body

→

←

Loop condition is true. Entering loop body

→

863

864

// This word appears to be appended to the data.

865

// Probably in the ROL. Ignore it if found.

866

if(*iptr == 0xd00dd00d) {

Taking false branch

Taking false branch

Taking false branch

Taking false branch

867

if(VERBOSE>7) cout << " CAEN skipping 0xd00dd00d word" << endl;

868

iptr++;

869

continue;

870

}

871

872

uint32_t type = (*iptr) >> 27;

873

uint32_t edge = 0; // 1=trailing, 0=leading

874

uint32_t channel = 0;

875

uint32_t tdc = 0;

876

uint32_t error_flags = 0;

877

switch(type){

←

Control jumps to the 'default' case at line 935

→

←

Control jumps to the 'default' case at line 935

→

←

Control jumps to 'case 24:' at line 932

→

←

Control jumps to 'case 0:' at line 912

→

878

case 0b01000: // Global Header

879

slot = (*iptr) & 0x1f;

880

event_count = ((*iptr)>>5) & 0xffffff;

881

if(VERBOSE>7) cout << " CAEN TDC Global Header (slot=" << slot << " , event count=" << event_count << ")" << endl;

882

break;

883

case 0b10000: // Global Trailer

884

slot = (*iptr) & 0x1f;

885

word_count = ((*iptr)>>5) & 0x7ffff;

886

if(VERBOSE>7) cout << " CAEN TDC Global Trailer (slot=" << slot << " , word count=" << word_count << ")" << endl;

887

slot = event_count = word_count = trigger_time_tag = tdc_num = event_id = bunch_id = 0;

888

break;

889

case 0b10001: // Global Trigger Time Tag

890

trigger_time_tag = ((*iptr)>>5) & 0x7ffffff;

891

if(VERBOSE>7) cout << " CAEN TDC Global Trigger Time Tag (tag=" << trigger_time_tag << ")" << endl;

892

break;

893

case 0b00001: // TDC Header

894

tdc_num = ((*iptr)>>24) & 0x03;

895

event_id = ((*iptr)>>12) & 0x0fff;

896

bunch_id = (*iptr) & 0x0fff;

897

if(events_by_event_id.find(event_id) == events_by_event_id.end()){

898

if(pe_iter == current_parsed_events.end()){

899

_DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<899<<" " << "CAEN1290TDC parser sees more events than CODA header! (>" << current_parsed_events.size() << ")" << endl;

900

for( auto p : events_by_event_id) cout << "id=" << p.first << endl;

901

iptr = iend;

902

exit(-1); // should we exit, or try and continue??

903

return;

904

}

905

pe = *pe_iter++;

906

events_by_event_id[event_id] = pe;

907

}else{

908

pe = events_by_event_id[event_id];

909

}

910

if(VERBOSE>7) cout << " CAEN TDC TDC Header (tdc=" << tdc_num <<" , event id=" << event_id <<" , bunch id=" << bunch_id << ")" << endl;

911

break;

912

case 0b00000: // TDC Measurement

913

edge = ((*iptr)>>26) & 0x01;

914

channel = ((*iptr)>>21) & 0x1f;

915

tdc = ((*iptr)>>0) & 0x1fffff;

916

if(VERBOSE>7) cout << " CAEN TDC TDC Measurement (" << (edge ? "trailing":"leading") << " , channel=" << channel << " , tdc=" << tdc << ")" << endl;

←

Taking false branch

→

917

918

// Create DCAEN1290TDCHit object

919

pe->NEW_DCAEN1290TDCHit(rocid, slot, channel, 0, edge, tdc_num, event_id, bunch_id, tdc);

←

Called C++ object pointer is null

920

break;

921

case 0b00100: // TDC Error

922

error_flags = (*iptr) & 0x7fff;

923

if(VERBOSE>7) cout << " CAEN TDC TDC Error (err flags=0x" << hex << error_flags << dec << ")" << endl;

924

break;

925

case 0b00011: // TDC Trailer

926

tdc_num = ((*iptr)>>24) & 0x03;

927

event_id = ((*iptr)>>12) & 0x0fff;

928

word_count = ((*iptr)>>0) & 0x0fff;

929

if(VERBOSE>7) cout << " CAEN TDC TDC Trailer (tdc=" << tdc_num <<" , event id=" << event_id <<" , word count=" << word_count << ")" << endl;

930

tdc_num = event_id = bunch_id = 0;

931

break;

932

case 0b11000: // Filler Word

933

if(VERBOSE>7) cout << " CAEN TDC Filler Word" << endl;

←

Taking false branch

→

934

break;

←

Execution continues on line 939

→

935

default:

936

cout << "Unknown datatype: 0x" << hex << type << " full word: "<< *iptr << dec << endl;

937

}

938

939

iptr++;

940

}

941

942

}

943

944

//----------------

945

// ParseModuleConfiguration

946

//----------------

947

void DEVIOWorkerThread::ParseModuleConfiguration(uint32_t rocid, uint32_t* &iptr, uint32_t *iend)

948

{

949

if(!PARSE_CONFIG){ iptr = &iptr[(*iptr) + 1]; return; }

950

951

/// Parse a bank of module configuration data. These are configuration values

952

/// programmed into the module at the beginning of the run that may be needed

953

/// in the offline. For example, the number of samples to sum in a FADC pulse

954

/// integral.

955

///

956

/// The bank has one or more sections, each describing parameters applicable

957

/// to a number of modules as indicated by a 24bit slot mask.

958

///

959

/// This bank should appear only once per DAQ event which, if in multi-event

960

/// block mode, may have multiple L1 events. The parameters here will apply

961

/// to all L1 events in the block. This method will put the config objects

962

/// into each event in current_parsed_events. The config objects are duplicated

963

/// as needed so each event has its own, indepenent set of config object.

964

965

while(iptr < iend){

966

uint32_t slot_mask = (*iptr) & 0xFFFFFF;

967

uint32_t Nvals = ((*iptr) >> 24) & 0xFF;

968

iptr++;

969

970

// Events will be created in the first event (i.e. using its pool)

971

// but pointers are saved so we can use them to construct identical

972

// objects in all other event later

973

DParsedEvent *pe = current_parsed_events.front();

974

975

Df250Config *f250config = NULL__null;

976

Df125Config *f125config = NULL__null;

977

DF1TDCConfig *f1tdcconfig = NULL__null;

978

DCAEN1290TDCConfig *caen1290tdcconfig = NULL__null;

979

980

// Loop over all parameters in this section

981

for(uint32_t i=0; i< Nvals; i++){

982

if( iptr >= iend){

983

_DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<983<<" " << "DAQ Configuration bank corrupt! slot_mask=0x" << hex << slot_mask << dec << " Nvals="<< Nvals << endl;

984

exit(-1);

985

}

986

987

daq_param_type ptype = (daq_param_type)((*iptr)>>16);

988

uint16_t val = (*iptr) & 0xFFFF;

989

990

if(VERBOSE>6) cout << " DAQ parameter of type: 0x" << hex << ptype << dec << " found with value: " << val << endl;

991

992

// Create config object of correct type if needed and copy

993

// parameter value into it.

994

switch(ptype>>8){

995

996

// f250

997

case 0x05:

998

if( !f250config ) f250config = pe->NEW_Df250Config(rocid, slot_mask);

999

switch(ptype){

1000

case kPARAM250_NSA : f250config->NSA = val; break;

1001

case kPARAM250_NSB : f250config->NSB = val; break;

1002

case kPARAM250_NSA_NSB : f250config->NSA_NSB = val; break;

1003

case kPARAM250_NPED : f250config->NPED = val; break;

1004

default: _DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<1004<<" " << "UNKNOWN DAQ Config Parameter type: 0x" << hex << ptype << dec << endl;

1005

}

1006

break;

1007

1008

// f125

1009

case 0x0F:

1010

if( !f125config ) f125config = pe->NEW_Df125Config(rocid, slot_mask);

1011

switch(ptype){

1012

case kPARAM125_NSA : f125config->NSA = val; break;

1013

case kPARAM125_NSB : f125config->NSB = val; break;

1014

case kPARAM125_NSA_NSB : f125config->NSA_NSB = val; break;

1015

case kPARAM125_NPED : f125config->NPED = val; break;

1016

case kPARAM125_WINWIDTH : f125config->WINWIDTH = val; break;

1017

case kPARAM125_PL : f125config->PL = val; break;

1018

case kPARAM125_NW : f125config->NW = val; break;

1019

case kPARAM125_NPK : f125config->NPK = val; break;

1020

case kPARAM125_P1 : f125config->P1 = val; break;

1021

case kPARAM125_P2 : f125config->P2 = val; break;

1022

case kPARAM125_PG : f125config->PG = val; break;

1023

case kPARAM125_IE : f125config->IE = val; break;

1024

case kPARAM125_H : f125config->H = val; break;

1025

case kPARAM125_TH : f125config->TH = val; break;

1026

case kPARAM125_TL : f125config->TL = val; break;

1027

case kPARAM125_IBIT : f125config->IBIT = val; break;

1028

case kPARAM125_ABIT : f125config->ABIT = val; break;

1029

case kPARAM125_PBIT : f125config->PBIT = val; break;

1030

default: _DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<1030<<" " << "UNKNOWN DAQ Config Parameter type: 0x" << hex << ptype << dec << endl;

1031

}

1032

break;

1033

1034

// F1TDC

1035

case 0x06:

1036

if( !f1tdcconfig ) f1tdcconfig = pe->NEW_DF1TDCConfig(rocid, slot_mask);

1037

switch(ptype){

1038

case kPARAMF1_REFCNT : f1tdcconfig->REFCNT = val; break;

1039

case kPARAMF1_TRIGWIN : f1tdcconfig->TRIGWIN = val; break;

1040

case kPARAMF1_TRIGLAT : f1tdcconfig->TRIGLAT = val; break;

1041

case kPARAMF1_HSDIV : f1tdcconfig->HSDIV = val; break;

1042

case kPARAMF1_BINSIZE : f1tdcconfig->BINSIZE = val; break;

1043

case kPARAMF1_REFCLKDIV : f1tdcconfig->REFCLKDIV = val; break;

1044

default: _DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<1044<<" " << "UNKNOWN DAQ Config Parameter type: 0x" << hex << ptype << dec << endl;

1045

}

1046

break;

1047

1048

// caen1290

1049

case 0x10:

1050

if( !caen1290tdcconfig ) caen1290tdcconfig = pe->NEW_DCAEN1290TDCConfig(rocid, slot_mask);

1051

switch(ptype){

1052

case kPARAMCAEN1290_WINWIDTH : caen1290tdcconfig->WINWIDTH = val; break;

1053

case kPARAMCAEN1290_WINOFFSET : caen1290tdcconfig->WINOFFSET = val; break;

1054

default: _DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<1054<<" " << "UNKNOWN DAQ Config Parameter type: 0x" << hex << ptype << dec << endl;

1055

}

1056

break;

1057

1058

default:

1059

_DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<1059<<" " << "Unknown module type: 0x" << hex << (ptype>>8) << endl;

1060

exit(-1);

1061

}

1062

1063

1064

iptr++;

1065

}

1066

1067

// Make copies of all config objects for all other events

1068

for(auto tpe : current_parsed_events){

1069

1070

if(tpe == pe) continue; // first event already owns objects so skip it

1071

1072

if(f250config ) tpe->NEW_Df250Config(f250config);

1073

if(f125config ) tpe->NEW_Df125Config(f125config);

1074

if(f1tdcconfig ) tpe->NEW_DF1TDCConfig(f1tdcconfig);

1075

if(caen1290tdcconfig) tpe->NEW_DCAEN1290TDCConfig(caen1290tdcconfig);

1076

}

1077

}

1078

}

1079

1080

//----------------

1081

// ParseJLabModuleData

1082

//----------------

1083

void DEVIOWorkerThread::ParseJLabModuleData(uint32_t rocid, uint32_t* &iptr, uint32_t *iend)

1084

{

1085

1086

while(iptr<iend){

1087

1088

// Get module type from next word (bits 18-21)

1089

uint32_t mod_id = ((*iptr) >> 18) & 0x000F;

1090

MODULE_TYPE type = (MODULE_TYPE)mod_id;

1091

//cout << " rocid=" << rocid << " Encountered module type: " << type << " (=" << DModuleType::GetModule(type).GetName() << ") word=" << hex << (*iptr) << dec << endl;

1092

1093

switch(type){

1094

case DModuleType::FADC250:

1095

Parsef250Bank(rocid, iptr, iend);

1096

break;

1097

1098

case DModuleType::FADC125:

1099

Parsef125Bank(rocid, iptr, iend);

1100

break;

1101

1102

case DModuleType::F1TDC32:

1103

ParseF1TDCBank(rocid, iptr, iend);

1104

break;

1105

1106

case DModuleType::F1TDC48:

1107

ParseF1TDCBank(rocid, iptr, iend);

1108

break;

1109

1110

case DModuleType::TID:

1111

ParseTIBank(rocid, iptr, iend);

1112

1113

// Ignore this data and skip over it

1114

while(iptr<iend && ((*iptr) & 0xF8000000) != 0x88000000) iptr++; // Skip to JLab block trailer

1115

iptr++; // advance past JLab block trailer

1116

while(iptr<iend && *iptr == 0xF8000000) iptr++; // skip filler words after block trailer

1117

break;

1118

1119

break;

1120

1121

case DModuleType::UNKNOWN:

1122

default:

1123

jerr<<"Unknown module type ("<<mod_id<<") iptr=0x" << hex << iptr << dec << endl;

1124

1125

while(iptr<iend && ((*iptr) & 0xF8000000) != 0x88000000) iptr++; // Skip to JLab block trailer

1126

iptr++; // advance past JLab block trailer

1127

while(iptr<iend && *iptr == 0xF8000000) iptr++; // skip filler words after block trailer

1128

break;

1129

}

1130

}

1131

1132

}

1133

1134

//----------------

1135

// Parsef250Bank

1136

//----------------

1137

void DEVIOWorkerThread::Parsef250Bank(uint32_t rocid, uint32_t* &iptr, uint32_t *iend)

1138

{

1139

if(!PARSE_F250){ iptr = &iptr[(*iptr) + 1]; return; }

1140

1141

auto pe_iter = current_parsed_events.begin();

1142

DParsedEvent *pe = NULL__null;

1143

1144

uint32_t slot = 0;

1145

uint32_t itrigger = -1;

1146

1147

// Loop over data words

1148

for(; iptr<iend; iptr++){

1149

1150

// Skip all non-data-type-defining words at this

1151

// level. When we do encounter one, the appropriate

1152

// case block below should handle parsing all of

1153

// the data continuation words and advance the iptr.

1154

if(((*iptr>>31) & 0x1) == 0)continue;

1155

1156

uint32_t data_type = (*iptr>>27) & 0x0F;

1157

switch(data_type){

1158

case 0: // Block Header

1159

slot = (*iptr>>22) & 0x1F;

1160

if(VERBOSE>7) cout << " FADC250 Block Header: slot="<<slot<<" ("<<hex<<*iptr<<dec<<")"<<endl;

1161

break;

1162

case 1: // Block Trailer

1163

pe_iter = current_parsed_events.begin();

1164

pe = NULL__null;

1165

if(VERBOSE>7) cout << " FADC250 Block Trailer"<<" ("<<hex<<*iptr<<dec<<")"<<endl;

1166

break;

1167

case 2: // Event Header

1168

itrigger = (*iptr>>0) & 0x3FFFFF;

1169

pe = *pe_iter++;

1170

if(VERBOSE>7) cout << " FADC250 Event Header: itrigger="<<itrigger<<", rocid="<<rocid<<", slot="<<slot<<")" <<" ("<<hex<<*iptr<<dec<<")" <<endl;

1171

break;

1172

case 3: // Trigger Time

1173

{

1174

uint64_t t = ((*iptr)&0xFFFFFF)<<0;

1175

iptr++;

1176

if(((*iptr>>31) & 0x1) == 0){

1177

t += ((*iptr)&0xFFFFFF)<<24; // from word on the street: second trigger time word is optional!!??

1178

if(VERBOSE>7) cout << " Trigger time high word="<<(((*iptr)&0xFFFFFF))<<" ("<<hex<<*iptr<<dec<<")"<<endl;

1179

}else{

1180

iptr--;

1181

}

1182

if(VERBOSE>7) cout << " FADC250 Trigger Time: t="<<t<<" ("<<hex<<*iptr<<dec<<")"<<endl;

1183

if(pe) pe->NEW_Df250TriggerTime(rocid, slot, itrigger, t);

1184

}

1185

break;

1186

case 4: // Window Raw Data

1187

// iptr passed by reference and so will be updated automatically

1188

if(VERBOSE>7) cout << " FADC250 Window Raw Data"<<" ("<<hex<<*iptr<<dec<<")"<<endl;

1189

MakeDf250WindowRawData(pe, rocid, slot, itrigger, iptr);

1190

break;

1191

case 5: // Window Sum

1192

{

1193

uint32_t channel = (*iptr>>23) & 0x0F;

1194

uint32_t sum = (*iptr>>0) & 0x3FFFFF;

1195

uint32_t overflow = (*iptr>>22) & 0x1;

1196

if(VERBOSE>7) cout << " FADC250 Window Sum"<<" ("<<hex<<*iptr<<dec<<")"<<endl;

1197

if(pe) pe->NEW_Df250WindowSum(rocid, slot, channel, itrigger, sum, overflow);

1198

}

1199

break;

1200

case 6: // Pulse Raw Data

1201

// MakeDf250PulseRawData(objs, rocid, slot, itrigger, iptr);

1202

if(VERBOSE>7) cout << " FADC250 Pulse Raw Data"<<" ("<<hex<<*iptr<<dec<<")"<<endl;

1203

break;

1204

case 7: // Pulse Integral

1205

{

1206

uint32_t channel = (*iptr>>23) & 0x0F;

1207

uint32_t pulse_number = (*iptr>>21) & 0x03;

1208

uint32_t quality_factor = (*iptr>>19) & 0x03;

1209

uint32_t sum = (*iptr>>0) & 0x7FFFF;

1210

uint32_t nsamples_integral = 0; // must be overwritten later in GetObjects with value from Df125Config value

1211

uint32_t nsamples_pedestal = 1; // The firmware returns an already divided pedestal

1212

uint32_t pedestal = 0; // This will be replaced by the one from Df250PulsePedestal in GetObjects

1213

if(VERBOSE>7) cout << " FADC250 Pulse Integral: chan="<<channel<<" pulse_number="<<pulse_number<<" sum="<<sum<<" ("<<hex<<*iptr<<dec<<")"<<endl;

1214

if(pe) pe->NEW_Df250PulseIntegral(rocid, slot, channel, itrigger, pulse_number, quality_factor, sum, pedestal, nsamples_integral, nsamples_pedestal);

1215

}

1216

break;

1217

case 8: // Pulse Time

1218

{

1219

uint32_t channel = (*iptr>>23) & 0x0F;

1220

uint32_t pulse_number = (*iptr>>21) & 0x03;

1221

uint32_t quality_factor = (*iptr>>19) & 0x03;

1222

uint32_t pulse_time = (*iptr>>0) & 0x7FFFF;

1223

if(VERBOSE>7) cout << " FADC250 Pulse Time: chan="<<channel<<" pulse_number="<<pulse_number<<" pulse_time="<<pulse_time<<" ("<<hex<<*iptr<<dec<<")"<<endl;

1224

if(pe) pe->NEW_Df250PulseTime(rocid, slot, channel, itrigger, pulse_number, quality_factor, pulse_time);

1225

}

1226

break;

1227

case 9: // Pulse Data (firmware instroduce in Fall 2016)

1228

{

1229

// from word 1

1230

uint32_t event_number_within_block = (*iptr>>19) & 0xFF;

1231

uint32_t channel = (*iptr>>15) & 0x0F;

1232

bool QF_pedestal = (*iptr>>14) & 0x01;

1233

uint32_t pedestal = (*iptr>>0 ) & 0x3FFF;

1234

1235

// Event headers may be supressed so determine event from hit data

1236

if( (event_number_within_block > current_parsed_events.size()) || (event_number_within_block==0) ) throw JException("Bad f250 event number", __FILE__"libraries/DAQ/DEVIOWorkerThread.cc", __LINE__1236);

1237

pe_iter = current_parsed_events.begin();

1238

advance( pe_iter, (event_number_within_block-1) );

1239

pe = *pe_iter++;

1240

1241

itrigger = event_number_within_block; // is this right?

1242

uint32_t pulse_number = 0;

1243

1244

while( (*++iptr>>31) == 0 ){

1245

1246

if( (*iptr>>30) != 0x01) throw JException("Bad f250 Pulse Data!", __FILE__"libraries/DAQ/DEVIOWorkerThread.cc", __LINE__1246);

1247

1248

// from word 2

1249

uint32_t integral = (*iptr>>12) & 0x3FFFF;

1250

bool QF_NSA_beyond_PTW = (*iptr>>11) & 0x01;

1251

bool QF_overflow = (*iptr>>10) & 0x01;

1252

bool QF_underflow = (*iptr>>9 ) & 0x01;

1253

uint32_t nsamples_over_threshold = (*iptr>>0 ) & 0x1FF;

1254

1255

iptr++;

1256

if( (*iptr>>30) != 0x00) throw JException("Bad f250 Pulse Data!", __FILE__"libraries/DAQ/DEVIOWorkerThread.cc", __LINE__1256);

1257

1258

// from word 3

1259

uint32_t course_time = (*iptr>>21) & 0x1FF;//< 4 ns/count

1260

uint32_t fine_time = (*iptr>>15) & 0x3F;//< 0.0625 ns/count

1261

uint32_t pulse_peak = (*iptr>>3 ) & 0xFFF;

1262

bool QF_vpeak_beyond_NSA = (*iptr>>2 ) & 0x01;

1263

bool QF_vpeak_not_found = (*iptr>>1 ) & 0x01;

1264

bool QF_bad_pedestal = (*iptr>>0 ) & 0x01;

1265

1266

if( pe ) {

1267

pe->NEW_Df250PulseData(rocid, slot, channel, itrigger

1268

, event_number_within_block

1269

, QF_pedestal

1270

, pedestal

1271

, integral

1272

, QF_NSA_beyond_PTW

1273

, QF_overflow

1274

, QF_underflow

1275

, nsamples_over_threshold

1276

, course_time

1277

, fine_time

1278

, pulse_peak

1279

, QF_vpeak_beyond_NSA

1280

, QF_vpeak_not_found

1281

, QF_bad_pedestal

1282

, pulse_number++);

1283

}

1284

}

1285

iptr--; // backup so when outer loop advances, it points to next data defining word

1286

1287

}

1288

break;

1289

case 10: // Pulse Pedestal

1290

{

1291

uint32_t channel = (*iptr>>23) & 0x0F;

1292

uint32_t pulse_number = (*iptr>>21) & 0x03;

1293

uint32_t pedestal = (*iptr>>12) & 0x1FF;

1294

uint32_t pulse_peak = (*iptr>>0) & 0xFFF;

1295

if(VERBOSE>7) cout << " FADC250 Pulse Pedestal chan="<<channel<<" pulse_number="<<pulse_number<<" pedestal="<<pedestal<<" pulse_peak="<<pulse_peak<<" ("<<hex<<*iptr<<dec<<")"<<endl;

1296

if(pe) pe->NEW_Df250PulsePedestal(rocid, slot, channel, itrigger, pulse_number, pedestal, pulse_peak);

1297

}

1298

break;

1299

case 13: // Event Trailer

1300

// This is marked "suppressed for normal readout – debug mode only" in the

1301

// current manual (v2). It does not contain any data so the most we could do here

1302

// is return early. I'm hesitant to do that though since it would mean

1303

// different behavior for debug mode data as regular data.

1304

case 14: // Data not valid (empty module)

1305

case 15: // Filler (non-data) word

1306

if(VERBOSE>7) cout << " FADC250 Event Trailer, Data not Valid, or Filler word ("<<data_type<<")"<<" ("<<hex<<*iptr<<dec<<")"<<endl;

1307

break;

1308

}

1309

}

1310

1311

// Chop off filler words

1312

for(; iptr<iend; iptr++){

1313

if(((*iptr)&0xf8000000) != 0xf8000000) break;

1314

}

1315

}

1316

1317

//----------------

1318

// MakeDf250WindowRawData

1319

//----------------

1320

void DEVIOWorkerThread::MakeDf250WindowRawData(DParsedEvent *pe, uint32_t rocid, uint32_t slot, uint32_t itrigger, uint32_t* &iptr)

1321

{

1322

uint32_t channel = (*iptr>>23) & 0x0F;

1323

uint32_t window_width = (*iptr>>0) & 0x0FFF;

1324

1325

Df250WindowRawData *wrd = pe->NEW_Df250WindowRawData(rocid, slot, channel, itrigger);

1326

1327

for(uint32_t isample=0; isample<window_width; isample +=2){

1328

1329

// Advance to next word

1330

iptr++;

1331

1332

// Make sure this is a data continuation word, if not, stop here

1333

if(((*iptr>>31) & 0x1) != 0x0){

1334

iptr--; // calling method expects us to point to last word in block

1335

break;

1336

}

1337

1338

bool invalid_1 = (*iptr>>29) & 0x1;

1339

bool invalid_2 = (*iptr>>13) & 0x1;

1340

uint16_t sample_1 = 0;

1341

uint16_t sample_2 = 0;

1342

if(!invalid_1)sample_1 = (*iptr>>16) & 0x1FFF;

1343

if(!invalid_2)sample_2 = (*iptr>>0) & 0x1FFF;

1344

1345

// Sample 1

1346

wrd->samples.push_back(sample_1);

1347

wrd->invalid_samples |= invalid_1;

1348

wrd->overflow |= (sample_1>>12) & 0x1;

1349

1350

if(((isample+2) == window_width) && invalid_2)break; // skip last sample if flagged as invalid

1351

1352

// Sample 2

1353

wrd->samples.push_back(sample_2);

1354

wrd->invalid_samples |= invalid_2;

1355

wrd->overflow |= (sample_2>>12) & 0x1;

1356

}

1357

}

1358

1359

//----------------

1360

// Parsef125Bank

1361

//----------------

1362

void DEVIOWorkerThread::Parsef125Bank(uint32_t rocid, uint32_t* &iptr, uint32_t *iend)

1363

{

1364

if(!PARSE_F125){ iptr = &iptr[(*iptr) + 1]; return; }

1365

1366

auto pe_iter = current_parsed_events.begin();

1367

DParsedEvent *pe = NULL__null;

1368

1369

uint32_t slot=0;

1370

uint32_t itrigger = -1;

1371

uint32_t last_itrigger = -2;

1372

uint32_t last_pulse_time_channel=0;

1373

uint32_t last_slot = -1;

1374

uint32_t last_channel = -1;

1375

1376

// Loop over data words

1377

for(; iptr<iend; iptr++){

1378

1379

// Skip all non-data-type-defining words at this

1380

// level. When we do encounter one, the appropriate

1381

// case block below should handle parsing all of

1382

// the data continuation words and advance the iptr.

1383

if(((*iptr>>31) & 0x1) == 0)continue;

1384

1385

uint32_t data_type = (*iptr>>27) & 0x0F;

1386

switch(data_type){

1387

case 0: // Block Header

1388

slot = (*iptr>>22) & 0x1F;

1389

if(VERBOSE>7) cout << " FADC125 Block Header: slot="<<slot<<endl;

1390

break;

1391

case 1: // Block Trailer

1392

pe_iter = current_parsed_events.begin();

1393

pe = NULL__null;

1394

break;

1395

case 2: // Event Header

1396

//slot_event_header = (*iptr>>22) & 0x1F;

1397

itrigger = (*iptr>>0) & 0x3FFFFFF;

1398

pe = *pe_iter++;

1399

if(VERBOSE>7) cout << " FADC125 Event Header: itrigger="<<itrigger<<" last_itrigger="<<last_itrigger<<", rocid="<<rocid<<", slot="<<slot <<endl;

1400

break;

1401

case 3: // Trigger Time

1402

{

1403

uint64_t t = ((*iptr)&0xFFFFFF)<<0;

1404

iptr++;

1405

if(((*iptr>>31) & 0x1) == 0){

1406

t += ((*iptr)&0xFFFFFF)<<24; // from word on the street: second trigger time word is optional!!??

1407

}else{

1408

iptr--;

1409

}

1410

if(VERBOSE>7) cout << " FADC125 Trigger Time (t="<<t<<")"<<endl;

1411

if(pe) pe->NEW_Df125TriggerTime(rocid, slot, itrigger, t);

1412

}

1413

break;

1414

case 4: // Window Raw Data

1415

// iptr passed by reference and so will be updated automatically

1416

if(VERBOSE>7) cout << " FADC125 Window Raw Data"<<endl;

1417

MakeDf125WindowRawData(pe, rocid, slot, itrigger, iptr);

1418

break;

1419

1420

case 5: // CDC pulse data (new) (GlueX-doc-2274-v8)

1421

{

1422

// Word 1:

1423

uint32_t word1 = *iptr;

1424

uint32_t channel = (*iptr>>20) & 0x7F;

1425

uint32_t pulse_number = (*iptr>>15) & 0x1F;

1426

uint32_t pulse_time = (*iptr>>4 ) & 0x7FF;

1427

uint32_t quality_factor = (*iptr>>3 ) & 0x1; //time QF bit

1428

uint32_t overflow_count = (*iptr>>0 ) & 0x7;

1429

if(VERBOSE>7){

1430

cout << " FADC125 CDC Pulse Data word1: " << hex << (*iptr) << dec << endl;

1431

cout << " FADC125 CDC Pulse Data (chan="<<channel<<" pulse="<<pulse_number<<" time="<<pulse_time<<" QF="<<quality_factor<<" OC="<<overflow_count<<")"<<endl;

1432

}

1433

1434

// Word 2:

1435

++iptr;

1436

if(iptr>=iend){

1437

jerr << " Truncated f125 CDC hit (block ends before continuation word!)" << endl;

1438

continue;

1439

}

1440

if( ((*iptr>>31) & 0x1) != 0 ){

1441

jerr << " Truncated f125 CDC hit (missing continuation word!)" << endl;

1442

continue;

1443

}

1444

uint32_t word2 = *iptr;

1445

uint32_t pedestal = (*iptr>>23) & 0xFF;

1446

uint32_t sum = (*iptr>>9 ) & 0x3FFF;

1447

uint32_t pulse_peak = (*iptr>>0 ) & 0x1FF;

1448

if(VERBOSE>7){

1449

cout << " FADC125 CDC Pulse Data word2: " << hex << (*iptr) << dec << endl;

1450

cout << " FADC125 CDC Pulse Data (pedestal="<<pedestal<<" sum="<<sum<<" peak="<<pulse_peak<<")"<<endl;

1451

}

1452

1453

// Create hit objects

1454

uint32_t nsamples_integral = 0; // must be overwritten later in GetObjects with value from Df125Config value

1455

uint32_t nsamples_pedestal = 1; // The firmware pedestal divided by 2^PBIT where PBIT is a config. parameter

1456

1457

if( pe ) {

1458

pe->NEW_Df125CDCPulse(rocid, slot, channel, itrigger

1459

, pulse_number // NPK

1460

, pulse_time // le_time

1461

, quality_factor // time_quality_bit

1462

, overflow_count // overflow_count

1463

, pedestal // pedestal

1464

, sum // integral

1465

, pulse_peak // first_max_amp

1466

, word1 // word1

1467

, word2 // word2

1468

, nsamples_pedestal // nsamples_pedestal

1469

, nsamples_integral // nsamples_integral

1470

, false); // emulated

1471

}

1472

}

1473

break;

1474

1475

case 6: // FDC pulse data-integral (new) (GlueX-doc-2274-v8)

1476

{

1477

// Word 1:

1478

uint32_t word1 = *iptr;

1479

uint32_t channel = (*iptr>>20) & 0x7F;

1480

uint32_t pulse_number = (*iptr>>15) & 0x1F;

1481

uint32_t pulse_time = (*iptr>>4 ) & 0x7FF;

1482

uint32_t quality_factor = (*iptr>>3 ) & 0x1; //time QF bit

1483

uint32_t overflow_count = (*iptr>>0 ) & 0x7;

1484

if(VERBOSE>7){

1485

cout << " FADC125 FDC Pulse Data(integral) word1: " << hex << (*iptr) << dec << endl;

1486

cout << " FADC125 FDC Pulse Data (chan="<<channel<<" pulse="<<pulse_number<<" time="<<pulse_time<<" QF="<<quality_factor<<" OC="<<overflow_count<<")"<<endl;

1487

}

1488

1489

// Word 2:

1490

++iptr;

1491

if(iptr>=iend){

1492

jerr << " Truncated f125 FDC hit (block ends before continuation word!)" << endl;

1493

continue;

1494

}

1495

if( ((*iptr>>31) & 0x1) != 0 ){

1496

jerr << " Truncated f125 FDC hit (missing continuation word!)" << endl;

1497

continue;

1498

}

1499

uint32_t word2 = *iptr;

1500

uint32_t pulse_peak = 0;

1501

uint32_t sum = (*iptr>>19) & 0xFFF;

1502

uint32_t peak_time = (*iptr>>11) & 0xFF;

1503

uint32_t pedestal = (*iptr>>0 ) & 0x7FF;

1504

if(VERBOSE>7){

1505

cout << " FADC125 FDC Pulse Data(integral) word2: " << hex << (*iptr) << dec << endl;

1506

cout << " FADC125 FDC Pulse Data (integral="<<sum<<" time="<<peak_time<<" pedestal="<<pedestal<<")"<<endl;

1507

}

1508

1509

// Create hit objects

1510

uint32_t nsamples_integral = 0; // must be overwritten later in GetObjects with value from Df125Config value

1511

uint32_t nsamples_pedestal = 1; // The firmware pedestal divided by 2^PBIT where PBIT is a config. parameter

1512

1513

if( pe ) {

1514

pe->NEW_Df125FDCPulse(rocid, slot, channel, itrigger

1515

, pulse_number // NPK

1516

, pulse_time // le_time

1517

, quality_factor // time_quality_bit

1518

, overflow_count // overflow_count

1519

, pedestal // pedestal

1520

, sum // integral

1521

, pulse_peak // peak_amp

1522

, peak_time // peak_time

1523

, word1 // word1

1524

, word2 // word2

1525

, nsamples_pedestal // nsamples_pedestal

1526

, nsamples_integral // nsamples_integral

1527

, false); // emulated

1528

}

1529

}

1530

break;

1531

1532

case 7: // Pulse Integral

1533

{

1534

if(VERBOSE>7) cout << " FADC125 Pulse Integral"<<endl;

1535

uint32_t channel = (*iptr>>20) & 0x7F;

1536

uint32_t sum = (*iptr>>0) & 0xFFFFF;

1537

uint32_t quality_factor = 0;

1538

uint32_t nsamples_integral = 0; // must be overwritten later in GetObjects with value from Df125Config value

1539

uint32_t nsamples_pedestal = 1; // The firmware returns an already divided pedestal

1540

uint32_t pedestal = 0; // This will be replaced by the one from Df250PulsePedestal in GetObjects

1541

uint32_t pulse_number = 0;

1542

if (last_slot == slot && last_channel == channel) pulse_number = 1;

1543

last_slot = slot;

1544

last_channel = channel;

1545

if( pe ) pe->NEW_Df125PulseIntegral(rocid, slot, channel, itrigger, pulse_number, quality_factor, sum, pedestal, nsamples_integral, nsamples_pedestal);

1546

}

1547

break;

1548

case 8: // Pulse Time

1549

{

1550

if(VERBOSE>7) cout << " FADC125 Pulse Time"<<endl;

1551

uint32_t channel = (*iptr>>20) & 0x7F;

1552

uint32_t pulse_number = (*iptr>>18) & 0x03;

1553

uint32_t pulse_time = (*iptr>>0) & 0xFFFF;

1554

uint32_t quality_factor = 0;

1555

if( pe ) pe->NEW_Df125PulseTime(rocid, slot, channel, itrigger, pulse_number, quality_factor, pulse_time);

1556

last_pulse_time_channel = channel;

1557

}

1558

break;

1559

1560

case 9: // FDC pulse data-peak (new) (GlueX-doc-2274-v8)

1561

{

1562

// Word 1:

1563

uint32_t word1 = *iptr;

1564

uint32_t channel = (*iptr>>20) & 0x7F;

1565

uint32_t pulse_number = (*iptr>>15) & 0x1F;

1566

uint32_t pulse_time = (*iptr>>4 ) & 0x7FF;

1567

uint32_t quality_factor = (*iptr>>3 ) & 0x1; //time QF bit

1568

uint32_t overflow_count = (*iptr>>0 ) & 0x7;

1569

if(VERBOSE>7){

1570

cout << " FADC125 FDC Pulse Data(peak) word1: " << hex << (*iptr) << dec << endl;

1571

cout << " FADC125 FDC Pulse Data (chan="<<channel<<" pulse="<<pulse_number<<" time="<<pulse_time<<" QF="<<quality_factor<<" OC="<<overflow_count<<")"<<endl;

1572

}

1573

1574

// Word 2:

1575

++iptr;

1576

if(iptr>=iend){

1577

jerr << " Truncated f125 FDC hit (block ends before continuation word!)" << endl;

1578

continue;

1579

}

1580

if( ((*iptr>>31) & 0x1) != 0 ){

1581

jerr << " Truncated f125 FDC hit (missing continuation word!)" << endl;

1582

continue;

1583

}

1584

uint32_t word2 = *iptr;

1585

uint32_t pulse_peak = (*iptr>>19) & 0xFFF;

1586

uint32_t sum = 0;

1587

uint32_t peak_time = (*iptr>>11) & 0xFF;

1588

uint32_t pedestal = (*iptr>>0 ) & 0x7FF;

1589

if(VERBOSE>7){

1590

cout << " FADC125 FDC Pulse Data(peak) word2: " << hex << (*iptr) << dec << endl;

1591

cout << " FADC125 FDC Pulse Data (integral="<<sum<<" time="<<peak_time<<" pedestal="<<pedestal<<")"<<endl;

1592

}

1593

1594

// Create hit objects

1595

uint32_t nsamples_integral = 0; // must be overwritten later in GetObjects with value from Df125Config value

1596

uint32_t nsamples_pedestal = 1; // The firmware pedestal divided by 2^PBIT where PBIT is a config. parameter

1597

1598

if( pe ) {

1599

pe->NEW_Df125FDCPulse(rocid, slot, channel, itrigger

1600

, pulse_number // NPK

1601

, pulse_time // le_time

1602

, quality_factor // time_quality_bit

1603

, overflow_count // overflow_count

1604

, pedestal // pedestal

1605

, sum // integral

1606

, pulse_peak // peak_amp

1607

, peak_time // peak_time

1608

, word1 // word1

1609

, word2 // word2

1610

, nsamples_pedestal // nsamples_pedestal

1611

, nsamples_integral // nsamples_integral

1612

, false); // emulated

1613

}

1614

}

1615

break;

1616

1617

case 10: // Pulse Pedestal (consistent with Beni's hand-edited version of Cody's document)

1618

{

1619

if(VERBOSE>7) cout << " FADC125 Pulse Pedestal"<<endl;

1620

//channel = (*iptr>>20) & 0x7F;

1621

uint32_t channel = last_pulse_time_channel; // not enough bits to hold channel number so rely on proximity to Pulse Time in data stream (see "FADC125 dataformat 250 modes.docx")

1622

uint32_t pulse_number = (*iptr>>21) & 0x03;

1623

uint32_t pedestal = (*iptr>>12) & 0x1FF;

1624

uint32_t pulse_peak = (*iptr>>0) & 0xFFF;

1625

uint32_t nsamples_pedestal = 1; // The firmware returns an already divided pedestal

1626

if( pe ) pe->NEW_Df125PulsePedestal(rocid, slot, channel, itrigger, pulse_number, pedestal, pulse_peak, nsamples_pedestal);

1627

}

1628

break;

1629

1630

case 13: // Event Trailer

1631

case 14: // Data not valid (empty module)

1632

case 15: // Filler (non-data) word

1633

if(VERBOSE>7) cout << " FADC125 ignored data type: " << data_type <<endl;

1634

break;

1635

}

1636

}

1637

1638

// Chop off filler words

1639

for(; iptr<iend; iptr++){

1640

if(((*iptr)&0xf8000000) != 0xf8000000) break;

1641

}

1642

}

1643

1644

//----------------

1645

// MakeDf125WindowRawData

1646

//----------------

1647

void DEVIOWorkerThread::MakeDf125WindowRawData(DParsedEvent *pe, uint32_t rocid, uint32_t slot, uint32_t itrigger, uint32_t* &iptr)

1648

{

1649

uint32_t channel = (*iptr>>20) & 0x7F;

1650

uint32_t window_width = (*iptr>>0) & 0x0FFF;

1651

1652

Df125WindowRawData *wrd = pe->NEW_Df125WindowRawData(rocid, slot, channel, itrigger);

1653

1654

for(uint32_t isample=0; isample<window_width; isample +=2){

1655

1656

// Advance to next word

1657

iptr++;

1658

1659

// Make sure this is a data continuation word, if not, stop here

1660

if(((*iptr>>31) & 0x1) != 0x0)break;

1661

1662

bool invalid_1 = (*iptr>>29) & 0x1;

1663

bool invalid_2 = (*iptr>>13) & 0x1;

1664

uint16_t sample_1 = 0;

1665

uint16_t sample_2 = 0;

1666

if(!invalid_1)sample_1 = (*iptr>>16) & 0x1FFF;

1667

if(!invalid_2)sample_2 = (*iptr>>0) & 0x1FFF;

1668

1669

// Sample 1

1670

wrd->samples.push_back(sample_1);

1671

wrd->invalid_samples |= invalid_1;

1672

wrd->overflow |= (sample_1>>12) & 0x1;

1673

1674

if((isample+2) == window_width && invalid_2)break; // skip last sample if flagged as invalid

1675

1676

// Sample 2

1677

wrd->samples.push_back(sample_2);

1678

wrd->invalid_samples |= invalid_2;

1679

wrd->overflow |= (sample_2>>12) & 0x1;

1680

}

1681

}

1682

1683

//----------------

1684

// ParseF1TDCBank

1685

//----------------

1686

void DEVIOWorkerThread::ParseF1TDCBank(uint32_t rocid, uint32_t* &iptr, uint32_t *iend)

1687

{

1688

if(!PARSE_F1TDC){ iptr = &iptr[(*iptr) + 1]; return; }

1689

1690

uint32_t *istart = iptr;

1691

1692

auto pe_iter = current_parsed_events.begin();

1693

DParsedEvent *pe = NULL__null;

1694

1695

uint32_t slot = 0;

1696

uint32_t modtype = 0;

1697

uint32_t itrigger = -1;

1698

uint32_t trig_time_f1header = 0;

1699

1700

// Some early data had a marker word at just before the actual F1 data

1701

if(*iptr == 0xf1daffff) iptr++;

1702

1703

// Loop over data words

1704

for(; iptr<iend; iptr++){

1705

1706

// Skip all non-data-type-defining words at this

1707

// level. When we do encounter one, the appropriate

1708

// case block below should handle parsing all of

1709

// the data continuation words and advance the iptr.

1710

if(((*iptr>>31) & 0x1) == 0)continue;

1711

1712

uint32_t data_type = (*iptr>>27) & 0x0F;

1713

switch(data_type){

1714

case 0: // Block Header

1715

slot = (*iptr)>>22 & 0x001F;

1716

modtype = (*iptr)>>18 & 0x000F; // should match a DModuleType::type_id_t

1717

if(VERBOSE>7) cout << " F1 Block Header: slot=" << slot << " modtype=" << modtype << endl;

1718

break;

1719

1720

case 1: // Block Trailer

1721

pe_iter = current_parsed_events.begin();

1722

pe = NULL__null;

1723

if(VERBOSE>7) cout << " F1 Block Trailer" << endl;

1724

break;

1725

1726

case 2: // Event Header

1727

{

1728

pe = *pe_iter++;

1729

itrigger = (*iptr)>>0 & 0x0003FFFFF;

1730

if(VERBOSE>7) {

1731

uint32_t slot_event_header = (*iptr)>>22 & 0x00000001F;

1732

cout << " F1 Event Header: slot=" << slot_event_header << " itrigger=" << itrigger << endl;

1733

}

1734

}

1735

break;

1736

1737

case 3: // Trigger time

1738

{

1739

uint64_t t = ((*iptr)&0xFFFFFF)<<0;

1740

iptr++;

1741

if(((*iptr>>31) & 0x1) == 0){

1742

t += ((*iptr)&0xFFFFFF)<<24; // from word on the street: second trigger time word is optional!!??

1743

}else{

1744

iptr--;

1745

}

1746

if(VERBOSE>7) cout << " F1TDC Trigger Time (t="<<t<<")"<<endl;

1747

if(pe) pe->NEW_DF1TDCTriggerTime(rocid, slot, itrigger, t);

1748

}

1749

break;

1750

1751

case 8: // F1 Chip Header

1752

trig_time_f1header = ((*iptr)>> 7) & 0x1FF;

1753

if(VERBOSE>7) {

1754

uint32_t chip_f1header = ((*iptr)>> 3) & 0x07;

1755

uint32_t chan_on_chip_f1header = ((*iptr)>> 0) & 0x07; // this is always 7 in real data!

1756

uint32_t itrigger_f1header = ((*iptr)>>16) & 0x3F;

1757

cout << " Found F1 header: chip=" << chip_f1header << " chan=" << chan_on_chip_f1header << " itrig=" << itrigger_f1header << " trig_time=" << trig_time_f1header << endl;

1758

}

1759

break;

1760

1761

case 7: // F1 Data

1762

{

1763

uint32_t chip = (*iptr>>19) & 0x07;

1764

uint32_t chan_on_chip = (*iptr>>16) & 0x07;

1765

uint32_t time = (*iptr>> 0) & 0xFFFF;

1766

uint32_t channel = F1TDC_channel(chip, chan_on_chip, modtype);

1767

if(VERBOSE>7) cout << " Found F1 data : chip=" << chip << " chan=" << chan_on_chip << " time=" << time << endl;

1768

if(pe) pe->NEW_DF1TDCHit(rocid, slot, channel, itrigger, trig_time_f1header, time, *iptr, MODULE_TYPE(modtype));

1769

}

1770

break;

1771

1772

case 15: // Filler word

1773

if(VERBOSE>7) cout << " F1 filler word" << endl;

1774

case 14: // Data not valid (how to handle this?)

1775

break;

1776

1777

default:

1778

cerr<<endl;

1779

cout.flush(); cerr.flush();

1780

_DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<1780<<" "<<"Unknown data word in F1TDC block. Dumping for debugging:" << endl;

1781

for(const uint32_t *iiptr = istart; iiptr<iend; iiptr++){

1782

_DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<1782<<" "<<"0x"<<hex<<*iiptr<<dec;

1783

if(iiptr == iptr)cerr<<" <----";

1784

switch( (*iiptr) & 0xF8000000 ){

1785

case 0x80000000: cerr << " F1 Block Header"; break;

1786

case 0x90000000: cerr << " F1 Event Header"; break;

1787

case 0x98000000: cerr << " F1 Trigger time"; break;

1788

case 0xC0000000: cerr << " F1 Header"; break;

1789

case 0xB8000000: cerr << " F1 Data"; break;

1790

case 0x88000000: cerr << " F1 Block Trailer"; break;

1791

case 0xF8000000: cerr << " Filler word"; break;

1792

case 0xF0000000: cerr << " <module has no valid data>"; break;

1793

default: break;

1794

}

1795

cerr<<endl;

1796

if(iiptr > (iptr+4)) break;

1797

}

1798

throw JException("Unexpected word type in F1TDC block!", __FILE__"libraries/DAQ/DEVIOWorkerThread.cc", __LINE__1798);

1799

break;

1800

}

1801

}

1802

1803

// Skip filler words

1804

while(iptr<iend && (*iptr&0xF8000000)==0xF8000000)iptr++;

1805

}

1806

1807

//----------------

1808

// ParseDVertexBank

1809

//----------------

1810

void DEVIOWorkerThread::ParseDVertexBank(uint32_t* &iptr, uint32_t *iend)

1811

{

1812

uint32_t Nwords = ((uint64_t)iend - (uint64_t)iptr)/sizeof(uint32_t);

1813

uint32_t Nwords_expected = 11; // ?

1814

if(Nwords != Nwords_expected){

1815

_DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<1815<<" " << "DVertex size does not match expected!!" << endl;

1816

_DBG_std::cerr<<"libraries/DAQ/DEVIOWorkerThread.cc"<<
":"<<1816<<" " << "Found " << Nwords << " words. Expected " << Nwords_expected << endl;

1817

}else{

1818

DParsedEvent *pe = current_parsed_events.back();

1819

DVertex *the_vertex = pe->NEW_DVertex();

1820

1821

uint64_t in_word = *iptr++; // 1st word, lo word; 2nd word, hi word

1822

uint64_t in_word_hi = *iptr++;

1823

in_word |= in_word_hi<<32;

1824

//uint64_t hi_word = *iptr++;

1825

double vertex_x_pos;

1826

memcpy(&vertex_x_pos, &in_word, sizeof(double));

1827

in_word = *iptr++; in_word_hi = *iptr++;

1828

in_word |= in_word_hi<<32;

1829

double vertex_y_pos;

1830

memcpy(&vertex_y_pos, &in_word, sizeof(double));

1831

in_word = *iptr++; in_word_hi = *iptr++;

1832

in_word |= in_word_hi<<32;

1833

double vertex_z_pos;

1834

memcpy(&vertex_z_pos, &in_word, sizeof(double));

1835

in_word = *iptr++; in_word_hi = *iptr++;

1836

in_word |= in_word_hi<<32;

1837

double vertex_t;

1838

memcpy(&vertex_t, &in_word, sizeof(double));

1839

1840

DVector3 vertex_position(vertex_x_pos, vertex_y_pos, vertex_z_pos);

1841

the_vertex->dSpacetimeVertex = DLorentzVector(vertex_position, vertex_t);

1842

the_vertex->dKinFitNDF = *iptr++;

1843

1844

in_word = *iptr++; in_word_hi = *iptr++;

1845

in_word |= in_word_hi<<32;

1846

memcpy(&(the_vertex->dKinFitChiSq), &in_word, sizeof(double));

1847

}

1848

}

1849

1850

1851

//----------------

1852

// LinkAllAssociations

1853

//----------------

1854

void DEVIOWorkerThread::LinkAllAssociations(void)

1855

{

1856

1857

/// Find objects that should be linked as "associated objects"

1858

/// of one another and add to each other's list.

1859

for( auto pe : current_parsed_events){

1860

1861

//----------------- Sort hit objects

1862

1863

// fADC250

1864

if(pe->vDf250PulseIntegral.size()>1) sort(pe->vDf250PulseIntegral.begin(), pe->vDf250PulseIntegral.end(), SortByPulseNumber<Df250PulseIntegral> );

1865

if(pe->vDf250PulseTime.size()>1 ) sort(pe->vDf250PulseTime.begin(), pe->vDf250PulseTime.end(), SortByPulseNumber<Df250PulseTime> );

1866

if(pe->vDf250PulsePedestal.size()>1) sort(pe->vDf250PulsePedestal.begin(), pe->vDf250PulsePedestal.end(), SortByPulseNumber<Df250PulsePedestal> );

1867

1868

// fADC125

1869

if(pe->vDf125PulseIntegral.size()>1) sort(pe->vDf125PulseIntegral.begin(), pe->vDf125PulseIntegral.end(), SortByPulseNumber<Df125PulseIntegral> );

1870

if(pe->vDf125CDCPulse.size()>1 ) sort(pe->vDf125CDCPulse.begin(), pe->vDf125CDCPulse.end(), SortByChannel<Df125CDCPulse> );

1871

if(pe->vDf125FDCPulse.size()>1 ) sort(pe->vDf125FDCPulse.begin(), pe->vDf125FDCPulse.end(), SortByChannel<Df125FDCPulse> );

1872

if(pe->vDf125PulseTime.size()>1 ) sort(pe->vDf125PulseTime.begin(), pe->vDf125PulseTime.end(), SortByPulseNumber<Df125PulseTime> );

1873

if(pe->vDf125PulsePedestal.size()>1) sort(pe->vDf125PulsePedestal.begin(), pe->vDf125PulsePedestal.end(), SortByPulseNumber<Df125PulsePedestal> );

1874

1875

// F1TDC

1876

if(pe->vDF1TDCHit.size()>1 ) sort(pe->vDF1TDCHit.begin(), pe->vDF1TDCHit.end(), SortByModule<DF1TDCHit> );

1877

1878

// CAEN1290TDC

1879

if(pe->vDCAEN1290TDCHit.size()>1 ) sort(pe->vDCAEN1290TDCHit.begin(), pe->vDCAEN1290TDCHit.end(), SortByModule<DCAEN1290TDCHit> );

1880

1881

1882

//----------------- Link hit objects

1883

1884

// Connect Df250 pulse objects

1885

LinkPulse(pe->vDf250PulseTime, pe->vDf250PulseIntegral);

1886

LinkPulsePedCopy(pe->vDf250PulsePedestal, pe->vDf250PulseIntegral);

1887

1888

// Connect Df125 pulse objects

1889

LinkPulse(pe->vDf125PulseTime, pe->vDf125PulseIntegral);

1890

LinkPulsePedCopy(pe->vDf125PulsePedestal, pe->vDf125PulseIntegral);

1891

1892

// Connect Df250 window raw data objects

1893

if(!pe->vDf250WindowRawData.empty()){

1894

LinkConfig(pe->vDf250Config, pe->vDf250WindowRawData);

1895

LinkModule(pe->vDf250TriggerTime, pe->vDf250WindowRawData);

1896

LinkChannel(pe->vDf250WindowRawData, pe->vDf250PulseIntegral);

1897

LinkChannel(pe->vDf250WindowRawData, pe->vDf250PulseTime);

1898

LinkChannel(pe->vDf250WindowRawData, pe->vDf250PulsePedestal);

1899

}

1900

1901

// Connect Df125 window raw data objects

1902

if(!pe->vDf125WindowRawData.empty()){

1903

LinkConfig(pe->vDf125Config, pe->vDf125WindowRawData);

1904

LinkModule(pe->vDf125TriggerTime, pe->vDf125WindowRawData);

1905

LinkChannel(pe->vDf125WindowRawData, pe->vDf125PulseIntegral);

1906

LinkChannel(pe->vDf125WindowRawData, pe->vDf125PulseTime);

1907

LinkChannel(pe->vDf125WindowRawData, pe->vDf125PulsePedestal);

1908

LinkChannel(pe->vDf125WindowRawData, pe->vDf125CDCPulse);

1909

LinkChannel(pe->vDf125WindowRawData, pe->vDf125FDCPulse);

1910

}

1911

1912

//----------------- Optionally link config objects (on by default)

1913

if(LINK_CONFIG){

1914

if(pe->vDf250Config.size()>1 ) sort(pe->vDf250Config.begin(), pe->vDf250Config.end(), SortByROCID<Df250Config> );

1915

if(pe->vDf125Config.size()>1 ) sort(pe->vDf125Config.begin(), pe->vDf125Config.end(), SortByROCID<Df125Config> );

1916

if(pe->vDF1TDCConfig.size()>1 ) sort(pe->vDF1TDCConfig.begin(), pe->vDF1TDCConfig.end(), SortByROCID<DF1TDCConfig> );

1917

if(pe->vDCAEN1290TDCConfig.size()>1) sort(pe->vDCAEN1290TDCConfig.begin(), pe->vDCAEN1290TDCConfig.end(), SortByROCID<DCAEN1290TDCConfig> );

1918

1919

LinkConfigSamplesCopy(pe->vDf250Config, pe->vDf250PulseIntegral);

1920

LinkConfigSamplesCopy(pe->vDf250Config, pe->vDf250PulseData);

1921

LinkConfigSamplesCopy(pe->vDf125Config, pe->vDf125PulseIntegral);

1922

LinkConfigSamplesCopy(pe->vDf125Config, pe->vDf125CDCPulse);

1923

LinkConfigSamplesCopy(pe->vDf125Config, pe->vDf125FDCPulse);

1924

LinkConfig(pe->vDF1TDCConfig, pe->vDF1TDCHit);

1925

LinkConfig(pe->vDCAEN1290TDCConfig, pe->vDCAEN1290TDCHit);

1926

}

1927

1928

//----------------- Optionally link trigger time objects (off by default)

1929

if(LINK_TRIGGERTIME){

1930

if(pe->vDf250TriggerTime.size()>1 ) sort(pe->vDf250TriggerTime.begin(), pe->vDf250TriggerTime.end(), SortByModule<Df250TriggerTime> );

1931

if(pe->vDf125TriggerTime.size()>1 ) sort(pe->vDf125TriggerTime.begin(), pe->vDf125TriggerTime.end(), SortByModule<Df125TriggerTime> );

1932

if(pe->vDF1TDCTriggerTime.size()>1 ) sort(pe->vDF1TDCTriggerTime.begin(), pe->vDF1TDCTriggerTime.end(), SortByModule<DF1TDCTriggerTime> );

1933

1934

LinkModule(pe->vDf250TriggerTime, pe->vDf250PulseIntegral);

1935

LinkModule(pe->vDf125TriggerTime, pe->vDf125PulseIntegral);

1936

LinkModule(pe->vDf125TriggerTime, pe->vDf125CDCPulse);

1937

LinkModule(pe->vDf125TriggerTime, pe->vDf125FDCPulse);

1938

LinkModule(pe->vDF1TDCTriggerTime, pe->vDF1TDCHit);

1939

}

1940

}

1941

1942

}

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1944

//----------------

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// DumpBinary

1946

//----------------

1947

void DEVIOWorkerThread::DumpBinary(const uint32_t *iptr, const uint32_t *iend, uint32_t MaxWords, const uint32_t *imark)

1948

{

1949

/// This is used for debugging. It will print to the screen the words

1950

/// starting at the address given by iptr and ending just before iend

1951

/// or for MaxWords words, whichever comes first. If iend is NULL,

1952

/// then MaxWords will be printed. If MaxWords is zero then it is ignored

1953

/// and only iend is checked. If both iend==NULL and MaxWords==0, then

1954

/// only the word at iptr is printed.

1955

1956

cout << "Dumping binary: istart=" << hex << iptr << " iend=" << iend << " MaxWords=" << dec << MaxWords << endl;

1957

1958

if(iend==NULL__null && MaxWords==0) MaxWords=1;

1959

if(MaxWords==0) MaxWords = (uint32_t)0xffffffff;

1960

1961

uint32_t Nwords=0;

1962

while(iptr!=iend && Nwords<MaxWords){

1963

1964

// line1 is hex and line2 is decimal

1965

stringstream line1, line2;

1966

1967

// print words in columns 8 words wide. First part is

1968

// reserved for word number

1969

uint32_t Ncols = 8;

1970

line1 << setw(5) << Nwords;

1971

line2 << string(5, ' ');

1972

1973

// Loop over columns

1974

for(uint32_t i=0; i<Ncols; i++, iptr++, Nwords++){

1975

1976

if(iptr == iend) break;

1977

if(Nwords>=MaxWords) break;

1978

1979

stringstream iptr_hex;

1980

iptr_hex << hex << "0x" << *iptr;

1981

1982

string mark = (iptr==imark ? "*":" ");

1983

1984

line1 << setw(12) << iptr_hex.str() << mark;

1985

line2 << setw(12) << *iptr << mark;

1986

}

1987

1988

cout << line1.str() << endl;

1989

cout << line2.str() << endl;

1990

cout << endl;

1991

}

1992

}

1993

1994