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RunManagerMTWorker.cc
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1 #include "SimG4Core/Application/interface/RunManagerMTWorker.h"
2 #include "SimG4Core/Application/interface/RunManagerMT.h"
3 #include "SimG4Core/Application/interface/SimRunInterface.h"
4 #include "SimG4Core/Application/interface/RunAction.h"
5 #include "SimG4Core/Application/interface/EventAction.h"
6 #include "SimG4Core/Application/interface/StackingAction.h"
7 #include "SimG4Core/Application/interface/TrackingAction.h"
8 #include "SimG4Core/Application/interface/SteppingAction.h"
9 #include "SimG4Core/Application/interface/CustomUIsessionThreadPrefix.h"
10 #include "SimG4Core/Application/interface/CustomUIsessionToFile.h"
11 #include "SimG4Core/Application/interface/ExceptionHandler.h"
12 
13 #include "SimG4Core/Geometry/interface/CustomUIsession.h"
14 
15 #include "FWCore/ParameterSet/interface/ParameterSet.h"
16 #include "FWCore/MessageLogger/interface/MessageLogger.h"
17 #include "FWCore/Framework/interface/Event.h"
18 #include "FWCore/Framework/interface/EventSetup.h"
19 #include "FWCore/Framework/interface/ConsumesCollector.h"
20 #include "FWCore/ServiceRegistry/interface/Service.h"
21 #include "FWCore/Utilities/interface/Exception.h"
22 #include "FWCore/Utilities/interface/thread_safety_macros.h"
23 
24 #include "SimG4Core/Notification/interface/G4SimEvent.h"
25 #include "SimG4Core/Notification/interface/SimActivityRegistry.h"
26 #include "SimG4Core/Notification/interface/BeginOfJob.h"
27 #include "SimG4Core/Notification/interface/CMSSteppingVerbose.h"
28 #include "SimG4Core/Watcher/interface/SimWatcherFactory.h"
29 
30 #include "SimG4Core/Geometry/interface/DDDWorld.h"
31 #include "SimG4Core/MagneticField/interface/FieldBuilder.h"
32 #include "SimG4Core/MagneticField/interface/CMSFieldManager.h"
33 
34 #include "SimDataFormats/GeneratorProducts/interface/HepMCProduct.h"
35 #include "DataFormats/GeometryVector/interface/GlobalPoint.h"
36 
37 #include "SimG4Core/Physics/interface/PhysicsList.h"
38 
39 #include "SimG4Core/SensitiveDetector/interface/AttachSD.h"
40 #include "SimG4Core/SensitiveDetector/interface/SensitiveTkDetector.h"
41 #include "SimG4Core/SensitiveDetector/interface/SensitiveCaloDetector.h"
42 #include "SimG4Core/SensitiveDetector/interface/SensitiveDetectorMakerBase.h"
43 #include "SimG4Core/SensitiveDetector/interface/sensitiveDetectorMakers.h"
44 
45 #include "G4Timer.hh"
46 #include "G4Event.hh"
47 #include "G4Run.hh"
48 #include "G4SystemOfUnits.hh"
49 #include "G4Threading.hh"
50 #include "G4UImanager.hh"
51 #include "G4WorkerThread.hh"
52 #include "G4WorkerRunManagerKernel.hh"
53 #include "G4StateManager.hh"
54 #include "G4TransportationManager.hh"
55 #include "G4Field.hh"
56 #include "G4FieldManager.hh"
57 
58 #include <atomic>
59 #include <memory>
60 
61 #include <thread>
62 #include <sstream>
63 #include <vector>
64 
65 static std::once_flag applyOnce;
66 
67 // from https://hypernews.cern.ch/HyperNews/CMS/get/edmFramework/3302/2.html
68 namespace {
69  std::atomic<int> thread_counter{0};
70 
71  int get_new_thread_index() { return thread_counter++; }
72 
73  bool createWatchers(const edm::ParameterSet& iP,
74  SimActivityRegistry* iReg,
75  std::vector<std::shared_ptr<SimWatcher>>& oWatchers,
76  std::vector<std::shared_ptr<SimProducer>>& oProds,
77  int threadID) {
78  std::vector<edm::ParameterSet> ws = iP.getParameter<std::vector<edm::ParameterSet>>("Watchers");
79  if (ws.empty()) {
80  return false;
81  }
82 
83  for (auto& watcher : ws) {
84  std::unique_ptr<SimWatcherMakerBase> maker(
85  SimWatcherFactory::get()->create(watcher.getParameter<std::string>("type")));
86  if (maker == nullptr) {
87  throw cms::Exception("Configuration")
88  << "RunManagerMTWorker::createWatchers: "
89  << "Unable to find the requested Watcher " << watcher.getParameter<std::string>("type");
90  } else {
91  std::shared_ptr<SimWatcher> watcherTemp;
92  std::shared_ptr<SimProducer> producerTemp;
93  maker->make(watcher, *(iReg), watcherTemp, producerTemp);
94  if (nullptr != watcherTemp) {
95  if (!watcherTemp->isMT() && 0 < threadID) {
96  throw cms::Exception("Configuration")
97  << "RunManagerMTWorker::createWatchers: "
98  << "Unable to use Watcher " << watcher.getParameter<std::string>("type") << " if number of threads > 1";
99  } else {
100  oWatchers.push_back(watcherTemp);
101  if (nullptr != producerTemp) {
102  oProds.push_back(producerTemp);
103  }
104  }
105  }
106  }
107  }
108  return (!oWatchers.empty());
109  }
110 } // namespace
111 
112 struct RunManagerMTWorker::TLSData {
113  std::unique_ptr<G4RunManagerKernel> kernel; //must be deleted last
114  std::unique_ptr<RunAction> userRunAction;
115  std::unique_ptr<SimRunInterface> runInterface;
116  std::unique_ptr<SimActivityRegistry> registry;
117  std::unique_ptr<SimTrackManager> trackManager;
118  std::vector<SensitiveTkDetector*> sensTkDets;
119  std::vector<SensitiveCaloDetector*> sensCaloDets;
120  std::vector<std::shared_ptr<SimWatcher>> watchers;
121  std::vector<std::shared_ptr<SimProducer>> producers;
122  //G4Run can only be deleted if there is a G4RunManager
123  // on the thread where the G4Run is being deleted,
124  // else it causes a segmentation fault
125  G4Run* currentRun = nullptr;
126  std::unique_ptr<G4Event> currentEvent;
127  edm::RunNumber_t currentRunNumber = 0;
128  bool threadInitialized = false;
129  bool runTerminated = false;
130 
131  TLSData() {}
132 
133  ~TLSData() {}
134 };
135 
136 //This can not be a smart pointer since we must delete some of the members
137 // before leaving main() else we get a segmentation fault caused by accessing
138 // other 'singletons' after those singletons have been deleted. Instead we
139 // atempt to delete all TLS at RunManagerMTWorker destructor. If that fails for
140 // some reason, it is better to leak than cause a crash.
141 //thread_local RunManagerMTWorker::TLSData* RunManagerMTWorker::m_tls{nullptr};
142 
143 RunManagerMTWorker::RunManagerMTWorker(const edm::ParameterSet& iConfig, edm::ConsumesCollector&& iC)
144  : m_generator(iConfig.getParameter<edm::ParameterSet>("Generator")),
145  m_InToken(iC.consumes<edm::HepMCProduct>(
146  iConfig.getParameter<edm::ParameterSet>("Generator").getParameter<edm::InputTag>("HepMCProductLabel"))),
147  m_theLHCTlinkToken(
148  iC.consumes<edm::LHCTransportLinkContainer>(iConfig.getParameter<edm::InputTag>("theLHCTlinkTag"))),
149  m_nonBeam(iConfig.getParameter<bool>("NonBeamEvent")),
150  m_pUseMagneticField(iConfig.getParameter<bool>("UseMagneticField")),
151  m_LHCTransport(iConfig.getParameter<bool>("LHCTransport")),
152  m_thread_index{get_new_thread_index()},
153  m_EvtMgrVerbosity(iConfig.getUntrackedParameter<int>("G4EventManagerVerbosity", 0)),
154  m_pField(iConfig.getParameter<edm::ParameterSet>("MagneticField")),
155  m_pRunAction(iConfig.getParameter<edm::ParameterSet>("RunAction")),
156  m_pEventAction(iConfig.getParameter<edm::ParameterSet>("EventAction")),
157  m_pStackingAction(iConfig.getParameter<edm::ParameterSet>("StackingAction")),
158  m_pTrackingAction(iConfig.getParameter<edm::ParameterSet>("TrackingAction")),
159  m_pSteppingAction(iConfig.getParameter<edm::ParameterSet>("SteppingAction")),
160  m_pCustomUIsession(iConfig.getUntrackedParameter<edm::ParameterSet>("CustomUIsession")),
161  m_p(iConfig) {
162  int thisID = getThreadIndex();
163  edm::LogVerbatim("SimG4CoreApplication") << "RunManagerMTWorker for the thread " << thisID;
164 
165  // sensitive detectors
166  std::vector<std::string> onlySDs = iConfig.getParameter<std::vector<std::string>>("OnlySDs");
167  m_sdMakers = sim::sensitiveDetectorMakers(m_p, iC, onlySDs);
168 
169  // TLS and watchers
170  initializeTLS();
171  if (m_hasWatchers) {
172  for (auto& watcher : m_tls->watchers) {
173  watcher->registerConsumes(iC);
174  }
175  }
176 
177  if (m_LHCTransport) {
178  m_LHCToken = iC.consumes<edm::HepMCProduct>(edm::InputTag("LHCTransport"));
179  }
180  if (m_pUseMagneticField) {
181  m_MagField = iC.esConsumes<MagneticField, IdealMagneticFieldRecord, edm::Transition::BeginRun>();
182  }
183  edm::LogVerbatim("SimG4CoreApplication") << "RunManagerMTWorker is constructed for the thread " << thisID;
184  unsigned int k = 0;
185  for (std::unordered_map<std::string, std::unique_ptr<SensitiveDetectorMakerBase>>::const_iterator itr =
186  m_sdMakers.begin();
187  itr != m_sdMakers.end();
188  ++itr, ++k)
189  edm::LogVerbatim("SimG4CoreApplication") << "SD[" << k << "] " << itr->first;
190 }
191 
192 RunManagerMTWorker::~RunManagerMTWorker() {
193  m_tls = nullptr;
194  delete m_UIsession;
195 }
196 
197 void RunManagerMTWorker::beginRun(edm::EventSetup const& es) {
198  for (auto& maker : m_sdMakers) {
199  maker.second->beginRun(es);
200  }
201  if (m_pUseMagneticField) {
202  m_pMagField = &es.getData(m_MagField);
203  }
204  if (m_hasWatchers) {
205  for (auto& watcher : m_tls->watchers) {
206  watcher->beginRun(es);
207  }
208  }
209 }
210 
211 void RunManagerMTWorker::endRun() {
212  int thisID = getThreadIndex();
213  edm::LogVerbatim("SimG4CoreApplication") << "RunManagerMTWorker::endRun for the thread " << thisID;
214  terminateRun();
215 }
216 
217 void RunManagerMTWorker::initializeTLS() {
218  if (nullptr != m_tls) {
219  return;
220  }
221 
222  m_tls = new TLSData();
223  m_tls->registry = std::make_unique<SimActivityRegistry>();
224 
225  edm::Service<SimActivityRegistry> otherRegistry;
226  //Look for an outside SimActivityRegistry
227  // this is used by the visualization code
228  int thisID = getThreadIndex();
229  if (otherRegistry) {
230  m_tls->registry->connect(*otherRegistry);
231  if (thisID > 0) {
232  throw cms::Exception("Configuration")
233  << "RunManagerMTWorker::initializeTLS : "
234  << "SimActivityRegistry service (i.e. visualization) is not supported for more than 1 thread. "
235  << " \n If this use case is needed, RunManagerMTWorker has to be updated.";
236  }
237  }
238  m_hasWatchers = createWatchers(m_p, m_tls->registry.get(), m_tls->watchers, m_tls->producers, thisID);
239 }
240 
241 void RunManagerMTWorker::initializeG4(RunManagerMT* runManagerMaster, const edm::EventSetup& es) {
242  if (m_tls->threadInitialized)
243  return;
244 
245  G4Timer timer;
246  timer.Start();
247 
248  // I guess everything initialized here should be in thread_local storage
249  initializeTLS();
250 
251  int thisID = getThreadIndex();
252  edm::LogVerbatim("SimG4CoreApplication") << "RunManagerMTWorker::initializeG4 in thread " << thisID << " is started";
253 
254  // Initialize per-thread output
255  G4Threading::G4SetThreadId(thisID);
256  G4UImanager::GetUIpointer()->SetUpForAThread(thisID);
257  const std::string& uitype = m_pCustomUIsession.getUntrackedParameter<std::string>("Type", "MessageLogger");
258  if (uitype == "MessageLogger") {
259  m_UIsession = new CustomUIsession();
260  } else if (uitype == "MessageLoggerThreadPrefix") {
261  m_UIsession = new CustomUIsessionThreadPrefix(
262  m_pCustomUIsession.getUntrackedParameter<std::string>("ThreadPrefix", ""), thisID);
263  } else if (uitype == "FilePerThread") {
264  m_UIsession =
265  new CustomUIsessionToFile(m_pCustomUIsession.getUntrackedParameter<std::string>("ThreadFile", ""), thisID);
266  } else {
267  throw cms::Exception("Configuration")
268  << "RunManagerMTWorker::initializeG4: Invalid value of CustomUIsession.Type '" << uitype
269  << "', valid are MessageLogger, MessageLoggerThreadPrefix, FilePerThread";
270  }
271  G4UImanager::GetUIpointer()->SetCoutDestination(m_UIsession);
272 
273  // Initialize worker part of shared resources (geometry, physics)
274  G4WorkerThread::BuildGeometryAndPhysicsVector();
275 
276  // Create worker run manager
277  m_tls->kernel.reset(G4WorkerRunManagerKernel::GetRunManagerKernel());
278  if (nullptr == m_tls->kernel) {
279  m_tls->kernel = std::make_unique<G4WorkerRunManagerKernel>();
280  }
281 
282  // Define G4 exception handler
283  double th = m_p.getParameter<double>("ThresholdForGeometryExceptions") * CLHEP::GeV;
284  bool tr = m_p.getParameter<bool>("TraceExceptions");
285  G4StateManager::GetStateManager()->SetExceptionHandler(new ExceptionHandler(th, tr));
286 
287  // Set the geometry for the worker, share from master
288  auto worldPV = runManagerMaster->world().GetWorldVolume();
289  m_tls->kernel->WorkerDefineWorldVolume(worldPV);
290  G4TransportationManager* tM = G4TransportationManager::GetTransportationManager();
291  tM->SetWorldForTracking(worldPV);
292 
293  // we need the track manager now
294  m_tls->trackManager = std::make_unique<SimTrackManager>();
295 
296  // setup the magnetic field
297  if (m_pUseMagneticField) {
298  const GlobalPoint g(0.f, 0.f, 0.f);
299 
300  sim::FieldBuilder fieldBuilder(m_pMagField, m_pField);
301 
302  CMSFieldManager* fieldManager = new CMSFieldManager();
303  tM->SetFieldManager(fieldManager);
304  fieldBuilder.build(fieldManager, tM->GetPropagatorInField());
305 
306  std::string fieldFile = m_p.getUntrackedParameter<std::string>("FileNameField", "");
307  if (!fieldFile.empty()) {
308  std::call_once(applyOnce, [this]() { m_dumpMF = true; });
309  if (m_dumpMF) {
310  edm::LogVerbatim("SimG4CoreApplication")
311  << "RunManagerMTWorker::InitializeG4: Dump magnetic field to file " << fieldFile;
312  DumpMagneticField(tM->GetFieldManager()->GetDetectorField(), fieldFile);
313  }
314  }
315  }
316 
317  // attach sensitive detector
318  auto sensDets = sim::attachSD(
319  m_sdMakers, es, runManagerMaster->catalog(), m_p, m_tls->trackManager.get(), *(m_tls->registry.get()));
320 
321  m_tls->sensTkDets.swap(sensDets.first);
322  m_tls->sensCaloDets.swap(sensDets.second);
323 
324  edm::LogVerbatim("SimG4CoreApplication")
325  << "RunManagerMTWorker::InitializeG4: Sensitive Detectors are built in thread " << thisID << " found "
326  << m_tls->sensTkDets.size() << " Tk type SD, and " << m_tls->sensCaloDets.size() << " Calo type SD";
327 
328  // Set the physics list for the worker, share from master
329  PhysicsList* physicsList = runManagerMaster->physicsListForWorker();
330 
331  edm::LogVerbatim("SimG4CoreApplication")
332  << "RunManagerMTWorker::InitializeG4: start initialisation of PhysicsList for the thread " << thisID;
333 
334  // Geant4 UI commands in PreInit state
335  if (!runManagerMaster->G4Commands().empty()) {
336  G4cout << "RunManagerMTWorker::InitializeG4: Requested UI commands: " << G4endl;
337  for (const std::string& command : runManagerMaster->G4Commands()) {
338  G4cout << " " << command << G4endl;
339  G4UImanager::GetUIpointer()->ApplyCommand(command);
340  }
341  }
342  G4StateManager::GetStateManager()->SetNewState(G4State_Init);
343 
344  physicsList->InitializeWorker();
345  m_tls->kernel->SetPhysics(physicsList);
346  m_tls->kernel->InitializePhysics();
347 
348  if (!m_tls->kernel->RunInitialization()) {
349  throw cms::Exception("Configuration")
350  << "RunManagerMTWorker::InitializeG4: Geant4 kernel initialization failed in thread " << thisID;
351  }
352  //tell all interesting parties that we are beginning the job
353  BeginOfJob aBeginOfJob(&es);
354  m_tls->registry->beginOfJobSignal_(&aBeginOfJob);
355 
356  G4int sv = m_p.getUntrackedParameter<int>("SteppingVerbosity", 0);
357  G4double elim = m_p.getUntrackedParameter<double>("StepVerboseThreshold", 0.1) * CLHEP::GeV;
358  std::vector<int> ve = m_p.getUntrackedParameter<std::vector<int>>("VerboseEvents");
359  std::vector<int> vn = m_p.getUntrackedParameter<std::vector<int>>("VertexNumber");
360  std::vector<int> vt = m_p.getUntrackedParameter<std::vector<int>>("VerboseTracks");
361 
362  if (sv > 0) {
363  m_sVerbose = std::make_unique<CMSSteppingVerbose>(sv, elim, ve, vn, vt);
364  }
365  initializeUserActions();
366 
367  G4StateManager::GetStateManager()->SetNewState(G4State_Idle);
368 
369  timer.Stop();
370  edm::LogVerbatim("SimG4CoreApplication")
371  << "RunManagerMTWorker::initializeG4 done for the thread " << thisID << " " << timer;
372  m_tls->threadInitialized = true;
373 }
374 
375 void RunManagerMTWorker::initializeUserActions() {
376  m_tls->runInterface = std::make_unique<SimRunInterface>(this, false);
377  m_tls->userRunAction = std::make_unique<RunAction>(m_pRunAction, m_tls->runInterface.get(), false);
378  m_tls->userRunAction->SetMaster(false);
379  Connect(m_tls->userRunAction.get());
380 
381  G4EventManager* eventManager = m_tls->kernel->GetEventManager();
382  eventManager->SetVerboseLevel(m_EvtMgrVerbosity);
383 
384  EventAction* userEventAction =
385  new EventAction(m_pEventAction, m_tls->runInterface.get(), m_tls->trackManager.get(), m_sVerbose.get());
386  Connect(userEventAction);
387  eventManager->SetUserAction(userEventAction);
388 
389  TrackingAction* userTrackingAction = new TrackingAction(userEventAction, m_pTrackingAction, m_sVerbose.get());
390  Connect(userTrackingAction);
391  eventManager->SetUserAction(userTrackingAction);
392 
393  SteppingAction* userSteppingAction =
394  new SteppingAction(userEventAction, m_pSteppingAction, m_sVerbose.get(), m_hasWatchers);
395  Connect(userSteppingAction);
396  eventManager->SetUserAction(userSteppingAction);
397 
398  eventManager->SetUserAction(new StackingAction(userTrackingAction, m_pStackingAction, m_sVerbose.get()));
399 }
400 
401 void RunManagerMTWorker::Connect(RunAction* runAction) {
402  runAction->m_beginOfRunSignal.connect(m_tls->registry->beginOfRunSignal_);
403  runAction->m_endOfRunSignal.connect(m_tls->registry->endOfRunSignal_);
404 }
405 
406 void RunManagerMTWorker::Connect(EventAction* eventAction) {
407  eventAction->m_beginOfEventSignal.connect(m_tls->registry->beginOfEventSignal_);
408  eventAction->m_endOfEventSignal.connect(m_tls->registry->endOfEventSignal_);
409 }
410 
411 void RunManagerMTWorker::Connect(TrackingAction* trackingAction) {
412  trackingAction->m_beginOfTrackSignal.connect(m_tls->registry->beginOfTrackSignal_);
413  trackingAction->m_endOfTrackSignal.connect(m_tls->registry->endOfTrackSignal_);
414 }
415 
416 void RunManagerMTWorker::Connect(SteppingAction* steppingAction) {
417  steppingAction->m_g4StepSignal.connect(m_tls->registry->g4StepSignal_);
418 }
419 
420 SimTrackManager* RunManagerMTWorker::GetSimTrackManager() {
421  initializeTLS();
422  return m_tls->trackManager.get();
423 }
424 std::vector<SensitiveTkDetector*>& RunManagerMTWorker::sensTkDetectors() {
425  initializeTLS();
426  return m_tls->sensTkDets;
427 }
428 std::vector<SensitiveCaloDetector*>& RunManagerMTWorker::sensCaloDetectors() {
429  initializeTLS();
430  return m_tls->sensCaloDets;
431 }
432 std::vector<std::shared_ptr<SimProducer>>& RunManagerMTWorker::producers() {
433  initializeTLS();
434  return m_tls->producers;
435 }
436 
437 void RunManagerMTWorker::initializeRun() {
438  int thisID = getThreadIndex();
439  edm::LogVerbatim("SimG4CoreApplication") << "RunManagerMTWorker::initializeRun " << thisID << " is started";
440  m_tls->currentRun = new G4Run();
441  G4StateManager::GetStateManager()->SetNewState(G4State_GeomClosed);
442  if (nullptr != m_tls->userRunAction) {
443  m_tls->userRunAction->BeginOfRunAction(m_tls->currentRun);
444  }
445 }
446 
447 void RunManagerMTWorker::terminateRun() {
448  edm::LogVerbatim("SimG4CoreApplication") << "RunManagerMTWorker::terminateRun ";
449  if (nullptr == m_tls || m_tls->runTerminated) {
450  return;
451  }
452  int thisID = getThreadIndex();
453  edm::LogVerbatim("SimG4CoreApplication") << "RunManagerMTWorker::terminateRun " << thisID << " is started";
454  if (m_tls->userRunAction) {
455  m_tls->userRunAction->EndOfRunAction(m_tls->currentRun);
456  m_tls->userRunAction.reset();
457  }
458  m_tls->currentEvent.reset();
459  m_simEvent = nullptr;
460 
461  if (m_tls->kernel) {
462  m_tls->kernel->RunTermination();
463  }
464 
465  m_tls->runTerminated = true;
466 }
467 
468 std::unique_ptr<G4SimEvent> RunManagerMTWorker::produce(const edm::Event& inpevt,
469  const edm::EventSetup& es,
470  RunManagerMT& runManagerMaster) {
471  // The initialization and begin/end run is a bit convoluted due to
472  // - Geant4 deals per-thread
473  // - OscarMTProducer deals per-stream
474  // and framework/TBB is free to schedule work in streams to the
475  // threads as it likes.
476  //
477  // We have to do the per-thread initialization, and per-thread
478  // per-run initialization here by ourselves.
479 
480  assert(m_tls != nullptr and m_tls->threadInitialized);
481  // Initialize run
482  if (inpevt.id().run() != m_tls->currentRunNumber) {
483  edm::LogVerbatim("SimG4CoreApplication")
484  << "RunManagerMTWorker::produce: RunID= " << inpevt.id().run() << " TLS RunID= " << m_tls->currentRunNumber;
485  if (m_tls->currentRunNumber != 0 && !m_tls->runTerminated) {
486  // If previous run in this thread was not terminated via endRun() call,
487  // terminate it now
488  terminateRun();
489  }
490  initializeRun();
491  m_tls->currentRunNumber = inpevt.id().run();
492  }
493  m_tls->runInterface->setRunManagerMTWorker(this); // For UserActions
494 
495  m_tls->currentEvent.reset(generateEvent(inpevt));
496 
497  auto simEvent = std::make_unique<G4SimEvent>();
498  m_simEvent = simEvent.get();
499  m_simEvent->hepEvent(m_generator.genEvent());
500  m_simEvent->weight(m_generator.eventWeight());
501  if (m_generator.genVertex() != nullptr) {
502  auto genVertex = m_generator.genVertex();
503  m_simEvent->collisionPoint(math::XYZTLorentzVectorD(genVertex->x() / CLHEP::cm,
504  genVertex->y() / CLHEP::cm,
505  genVertex->z() / CLHEP::cm,
506  genVertex->t() / CLHEP::second));
507  }
508  if (m_tls->currentEvent->GetNumberOfPrimaryVertex() == 0) {
509  throw cms::Exception("EventCorruption")
510  << "RunManagerMTWorker::produce: event " << inpevt.id().event() << " with no G4PrimaryVertices"
511  << " StreamID=" << inpevt.streamID() << " threadIndex=" << getThreadIndex();
512 
513  } else {
514  edm::LogVerbatim("SimG4CoreApplication")
515  << "RunManagerMTWorker::produce: start EventID=" << inpevt.id().event() << " StreamID=" << inpevt.streamID()
516  << " threadIndex=" << getThreadIndex() << " weight=" << m_simEvent->weight() << "; "
517  << m_tls->currentEvent->GetNumberOfPrimaryVertex() << " vertices for Geant4; generator produced "
518  << m_simEvent->nGenParts() << " particles.";
519 
520  m_tls->kernel->GetEventManager()->ProcessOneEvent(m_tls->currentEvent.get());
521  }
522 
523  //remove memory only needed during event processing
524  m_tls->currentEvent.reset();
525 
526  for (auto& sd : m_tls->sensCaloDets) {
527  sd->reset();
528  }
529  edm::LogVerbatim("SimG4CoreApplication") << "RunManagerMTWorker::produce: ended Event " << inpevt.id().event();
530  m_simEvent = nullptr;
531  return simEvent;
532 }
533 
534 void RunManagerMTWorker::abortEvent() {
535  if (m_tls->runTerminated) {
536  return;
537  }
538  G4Track* t = m_tls->kernel->GetEventManager()->GetTrackingManager()->GetTrack();
539  t->SetTrackStatus(fStopAndKill);
540 
541  // CMS-specific act
542  //
543  TrackingAction* uta = static_cast<TrackingAction*>(m_tls->kernel->GetEventManager()->GetUserTrackingAction());
544  uta->PostUserTrackingAction(t);
545 
546  m_tls->currentEvent->SetEventAborted();
547  m_tls->kernel->GetEventManager()->GetStackManager()->clear();
548  m_tls->kernel->GetEventManager()->GetTrackingManager()->EventAborted();
549 }
550 
551 void RunManagerMTWorker::abortRun(bool softAbort) {
552  if (!softAbort) {
553  abortEvent();
554  }
555  m_tls->currentRun = nullptr;
556  terminateRun();
557 }
558 
559 G4Event* RunManagerMTWorker::generateEvent(const edm::Event& inpevt) {
560  m_tls->currentEvent.reset();
561  m_simEvent = nullptr;
562 
563  // 64 bits event ID in CMSSW converted into Geant4 event ID
564  G4int evtid = (G4int)inpevt.id().event();
565  G4Event* evt = new G4Event(evtid);
566 
567  edm::Handle<edm::HepMCProduct> HepMCEvt;
568  inpevt.getByToken(m_InToken, HepMCEvt);
569 
570  m_generator.setGenEvent(HepMCEvt->GetEvent());
571 
572  // required to reset the GenParticle Id for particles transported
573  // along the beam pipe
574  // to their original value for SimTrack creation
575  resetGenParticleId(inpevt);
576 
577  if (!m_nonBeam) {
578  m_generator.HepMC2G4(HepMCEvt->GetEvent(), evt);
579  if (m_LHCTransport) {
580  edm::Handle<edm::HepMCProduct> LHCMCEvt;
581  inpevt.getByToken(m_LHCToken, LHCMCEvt);
582  m_generator.nonCentralEvent2G4(LHCMCEvt->GetEvent(), evt);
583  }
584  } else {
585  m_generator.nonCentralEvent2G4(HepMCEvt->GetEvent(), evt);
586  }
587 
588  return evt;
589 }
590 
591 void RunManagerMTWorker::resetGenParticleId(const edm::Event& inpevt) {
592  edm::Handle<edm::LHCTransportLinkContainer> theLHCTlink;
593  inpevt.getByToken(m_theLHCTlinkToken, theLHCTlink);
594  if (theLHCTlink.isValid()) {
595  m_tls->trackManager->setLHCTransportLink(theLHCTlink.product());
596  }
597 }
598 
599 void RunManagerMTWorker::DumpMagneticField(const G4Field* field, const std::string& file) const {
600  std::ofstream fout(file.c_str(), std::ios::out);
601  if (fout.fail()) {
602  edm::LogWarning("SimG4CoreApplication")
603  << "MTWorker::DumpMagneticField: error opening file <" << file << "> for magnetic field";
604  } else {
605  // CMS magnetic field volume
606  double rmax = 9000 * mm;
607  double zmax = 24000 * mm;
608 
609  double dr = 1 * cm;
610  double dz = 5 * cm;
611 
612  int nr = (int)(rmax / dr);
613  int nz = 2 * (int)(zmax / dz);
614 
615  double r = 0.0;
616  double z0 = -zmax;
617  double z;
618 
619  double phi = 0.0;
620  double cosf = cos(phi);
621  double sinf = sin(phi);
622 
623  double point[4] = {0.0, 0.0, 0.0, 0.0};
624  double bfield[3] = {0.0, 0.0, 0.0};
625 
626  fout << std::setprecision(6);
627  for (int i = 0; i <= nr; ++i) {
628  z = z0;
629  for (int j = 0; j <= nz; ++j) {
630  point[0] = r * cosf;
631  point[1] = r * sinf;
632  point[2] = z;
633  field->GetFieldValue(point, bfield);
634  fout << "R(mm)= " << r / mm << " phi(deg)= " << phi / degree << " Z(mm)= " << z / mm
635  << " Bz(tesla)= " << bfield[2] / tesla << " Br(tesla)= " << (bfield[0] * cosf + bfield[1] * sinf) / tesla
636  << " Bphi(tesla)= " << (bfield[0] * sinf - bfield[1] * cosf) / tesla << G4endl;
637  z += dz;
638  }
639  r += dr;
640  }
641 
642  fout.close();
643  }
644 }
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