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EventWithHistory.cc
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1 #include <map>
7 
9 
11 
12 EventWithHistory::EventWithHistory(const edm::EventNumber_t event, const int orbit, const int bx):
13  TinyEvent(event,orbit,bx), _prevse() { }
14 
15 EventWithHistory::EventWithHistory(const edm::EventNumber_t event, const unsigned int orbit, const int bx):
16  TinyEvent(event,orbit,bx), _prevse() { }
17 
19  TinyEvent(event), _prevse() { }
20 
21 EventWithHistory::EventWithHistory(const std::vector<edm::EventAuxiliary>& veaux):
22  TinyEvent((veaux.size()>0) ? veaux[veaux.size()-1]: TinyEvent()), _prevse()
23 {
24  for(std::vector<edm::EventAuxiliary>::const_reverse_iterator eaux=veaux.rbegin();eaux!=veaux.rend();eaux++) {
25  if(eaux!=veaux.rbegin()) {
26  _prevse.push_back(*eaux);
27  }
28  }
29 }
30 
32  const long long orbitoffset, const int bxoffset):
33  TinyEvent(), _prevse()
34 {
35 
36  std::map<int,TinyEvent> tmpmap;
37 
38  for(L1AcceptBunchCrossingCollection::const_iterator l1abc=l1abcc.begin();l1abc!=l1abcc.end();++l1abc) {
39  if(event.id().event() > (edm::EventNumber_t)(-1*l1abc->l1AcceptOffset()) ) {
40  edm::EventNumber_t evnumb = event.id().event()+l1abc->l1AcceptOffset();
41  if(orbitoffset < (long long)l1abc->orbitNumber()) {
42  unsigned int neworbit = l1abc->orbitNumber() - orbitoffset;
43  int newbx = l1abc->bunchCrossing() - bxoffset;
44 
45  /*
46  the lines below assumes that the BX number is between 0 and 3563. If this is not the case it will jump to 0 and to the next orbit in case of
47  evets with BX=3564
48  */
49  while(newbx > 3563) {
50  ++neworbit;
51  newbx -= 3564;
52  }
53  while(newbx < 0) {
54  --neworbit;
55  newbx += 3564;
56  }
57 
58  if(l1abc->eventType()!=0) {
59  TinyEvent tmpse(evnumb,neworbit,newbx);
60  tmpmap[l1abc->l1AcceptOffset()]=tmpse;
61  }
62  else {
63  edm::LogWarning("L1AcceptBunchCrossingNoType") << "L1AcceptBunchCrossing with no type found: ";
64  for(L1AcceptBunchCrossingCollection::const_iterator debu=l1abcc.begin();debu!=l1abcc.end();++debu) {
65  edm::LogPrint("L1AcceptBunchCrossingNoType") << *debu;
66  }
67  }
68  }
69  else {
70  edm::LogError("L1AcceptBunchCrossingOffsetTooLarge") << " Too large orbit offset "
71  << orbitoffset << " "
72  << l1abc->orbitNumber();
73  }
74  }
75  else {
76  edm::LogInfo("L1AcceptBunchCrossingNegativeEvent") << "L1AcceptBunchCrossing with negative event: ";
77  for(L1AcceptBunchCrossingCollection::const_iterator debu=l1abcc.begin();debu!=l1abcc.end();++debu) {
78  edm::LogVerbatim("L1AcceptBunchCrossingNegativeEvent") << *debu;
79  }
80  }
81  }
82  // look for the event itself
83  if(tmpmap.find(0)!=tmpmap.end()) {
84 
85  TinyEvent::operator=(tmpmap[0]);
86 
87  // loop on the rest of the map and stop when it is missing
88  // check that the events are in the right order and break if not
89 
90  int counter=-1;
91  while(tmpmap.find(counter)!=tmpmap.end()) {
92 
93  if(tmpmap[counter+1].deltaBX(tmpmap[counter]) > 0) {
94  _prevse.push_back(tmpmap[counter]);
95  --counter;
96  }
97  else {
98  edm::LogWarning("L1AcceptBunchCrossingNotInOrder") << "L1AcceptBunchCrossing not in order: orbit "
99  << event.orbitNumber() << " BX " << event.bunchCrossing()
100  << " orbit offset " << orbitoffset << " bx offset " << bxoffset << " :";
101  for(L1AcceptBunchCrossingCollection::const_iterator debu=l1abcc.begin();debu!=l1abcc.end();++debu) {
102  edm::LogPrint("L1AcceptBunchCrossingNotInOrder") << *debu;
103  }
104  break;
105  }
106  }
107  }
108  else {
109  TinyEvent::operator=(event);
110  edm::LogWarning("L1AcceptBunchCrossingNoCollection") << " L1AcceptBunchCrossing with offset=0 not found "
111  << " likely L1ABCCollection is empty ";
112  }
113 
114 }
115 
116 EventWithHistory::EventWithHistory(const EventWithHistory& he): TinyEvent(he), _prevse(he._prevse) { }
117 
119 
120  if(this != &he) {
122  _prevse = he._prevse;
123  }
124  return *this;
125 }
126 
127 // int EventWithHistory::operator<(const EventWithHistory& other) const { return TinyEvent::operator<(other); }
128 
130 
131  int equal = TinyEvent::operator==(other);
132 
133  // depth is not checked anymore
134 
135  // equal = equal && (depth() == other.depth());
136 
137  if(equal) {
138  for(unsigned int i=0;i<((depth()<other.depth())?depth():other.depth());i++) {
139  equal = equal && (_prevse[i] == other._prevse[i]);
140  }
141  }
142 
143  return equal;
144 }
145 
146 int EventWithHistory::add(const EventWithHistory& he, const int idepth) {
147 
148  if(!add((const TinyEvent&) he,idepth)) return 0;
149 
150  for(std::vector<TinyEvent>::const_iterator ev=he._prevse.begin();ev!=he._prevse.end();ev++) {
151  if(!add(*ev,idepth)) return 0;
152  }
153  return 1;
154 }
155 
156 int EventWithHistory::add(const TinyEvent& se, const int idepth) {
157 
158  bool isfuture = (idepth <0);
159  const unsigned int adepth = abs(idepth);
160 
161  // protect against the possibility of filling with past and future history
162 
163  if( depth()>0 && ((isfuture && !isFutureHistory()) || (!isfuture && isFutureHistory()))) return 0;
164 
165  if(adepth==0) return 0;
166  if(_prevse.size()>= adepth) return 0;
167 
168  if(_prevse.size()==0) {
169  if((!isfuture && isNextOf(se)) || (isfuture && se.isNextOf(*this))) {
170  _prevse.push_back(se);
171  return 1;
172  }
173  else {
174  return 0;
175  }
176  }
177  else {
178  if((!isfuture && _prevse[_prevse.size()-1].isNextOf(se)) || (isfuture && se.isNextOf(_prevse[_prevse.size()-1]))) {
179  _prevse.push_back(se);
180  return 1;
181  }
182  else {
183  return 0;
184  }
185  }
186  return 0;
187 }
188 
190 const unsigned int EventWithHistory::orbit() const { return TinyEvent::_orbit; }
191 const int EventWithHistory::bx() const { return TinyEvent::_bx; }
192 
193 const TinyEvent* EventWithHistory::get(const unsigned int ev) const {
194 
195  if(ev==0) return this;
196  if(ev<=_prevse.size()) return &_prevse[ev-1];
197  return 0;
198 
199 }
200 
201 unsigned int EventWithHistory::depth() const { return _prevse.size(); }
202 
204 
205  return (depth()>0 && _prevse[0].isNextOf(*this));
206 
207 }
208 
209 long long EventWithHistory::deltaBX(const unsigned int ev2, const unsigned int ev1) const {
210 
211  if(ev2==ev1) return 0;
212 
213  if(ev2<ev1 && ev1<=_prevse.size()) {
214  if(ev2==0) return TinyEvent::deltaBX(_prevse[ev1-1]);
215  return _prevse[ev2-1].deltaBX(_prevse[ev1-1]);
216  }
217 
218  return -1;
219 }
220 
221 long long EventWithHistory::deltaBX(const unsigned int ev1) const { return deltaBX(0,ev1); }
222 
223 long long EventWithHistory::deltaBX() const { return deltaBX(0,1); }
224 
225 long long EventWithHistory::deltaBX(const TinyEvent& se) const {
226 
227  return TinyEvent::deltaBX(se);
228 
229 }
230 
231 long long EventWithHistory::absoluteBX(const unsigned int ev1) const {
232 
233  if(ev1==0) return TinyEvent::absoluteBX();
234  if(ev1<=_prevse.size()) return _prevse[ev1-1].absoluteBX();
235 
236  return -1;
237 
238 }
239 
240 long long EventWithHistory::absoluteBX() const {
241 
242  return TinyEvent::absoluteBX();
243 
244 }
245 
246 long long EventWithHistory::absoluteBXinCycle(const unsigned int ev1, const int bx0) const {
247 
248  if(ev1==0) return TinyEvent::absoluteBXinCycle(bx0);
249  if(ev1<=_prevse.size()) return _prevse[ev1-1].absoluteBXinCycle(bx0);
250 
251  return -1;
252 
253 }
254 
255 long long EventWithHistory::absoluteBXinCycle(const int bx0) const {
256 
257  return TinyEvent::absoluteBXinCycle(bx0);
258 
259 }
260 
261 long long EventWithHistory::deltaBXinCycle(const unsigned int ev2, const unsigned int ev1, const int bx0) const {
262 
263  if(ev2==ev1 && ev1<=_prevse.size()) {
264  if(ev2==0) return TinyEvent::deltaBXinCycle(*this,bx0);
265  return _prevse[ev2-1].deltaBXinCycle(_prevse[ev1-1],bx0);
266  }
267 
268  if(ev2<ev1 && ev1<=_prevse.size()) {
269  if(ev2==0) return TinyEvent::deltaBXinCycle(_prevse[ev1-1],bx0);
270  return _prevse[ev2-1].deltaBXinCycle(_prevse[ev1-1],bx0);
271  }
272 
273  return -1;
274 }
275 
276 long long EventWithHistory::deltaBXinCycle(const unsigned int ev1, const int bx0) const {
277  return deltaBXinCycle(0,ev1,bx0);
278 }
279 
280 long long EventWithHistory::deltaBXinCycle(const int bx0) const {
281  return deltaBXinCycle(0,1,bx0);
282 }
283 
284 long long EventWithHistory::deltaBXinCycle(const TinyEvent& se, const int bx0) const {
285 
286  return TinyEvent::deltaBXinCycle(se,bx0);
287 
288 }
unsigned int depth() const
long long absoluteBXinCycle(const int bx0) const
Definition: TinyEvent.h:63
EventNumber_t event() const
Definition: EventID.h:41
int i
Definition: DBlmapReader.cc:9
long long deltaBX() const
const unsigned int orbit() const
const TinyEvent * get(const unsigned int ev) const
unsigned int _bx
Definition: TinyEvent.h:89
unsigned long long EventNumber_t
long long absoluteBXinCycle(const unsigned int ev1, const int bx0) const
bool ev
bool equal(const T &first, const T &second)
Definition: Equal.h:34
std::vector< TinyEvent > _prevse
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
std::vector< L1AcceptBunchCrossing > L1AcceptBunchCrossingCollection
How EventSelector::AcceptEvent() decides whether to accept an event for output otherwise it is excluding the probing of A single or multiple positive and the trigger will pass if any such matching triggers are PASS or EXCEPTION[A criterion thatmatches no triggers at all is detected and causes a throw.] A single negative with an expectation of appropriate bit checking in the decision and the trigger will pass if any such matching triggers are FAIL or EXCEPTION A wildcarded negative criterion that matches more than one trigger in the trigger but the state exists so we define the behavior If all triggers are the negative crieriion will lead to accepting the event(this again matches the behavior of"!*"before the partial wildcard feature was incorporated).The per-event"cost"of each negative criterion with multiple relevant triggers is about the same as!*was in the past
int add(const EventWithHistory &he, const int idepth)
TinyEvent & operator=(const TinyEvent &se)
Definition: TinyEvent.h:29
long long absoluteBX() const
Definition: TinyEvent.h:57
long long deltaBX(const TinyEvent &se) const
Definition: TinyEvent.h:69
const int bx() const
const edm::EventNumber_t event() const
int isNextOf(const TinyEvent &se) const
Definition: TinyEvent.h:51
long long deltaBXinCycle(const unsigned int ev2, const unsigned int ev1, const int bx0) const
bool isFutureHistory() const
edm::EventID id() const
Definition: EventBase.h:59
long long absoluteBX() const
static std::atomic< unsigned int > counter
edm::EventNumber_t _event
Definition: TinyEvent.h:87
EventWithHistory & operator=(const EventWithHistory &he)
unsigned int _orbit
Definition: TinyEvent.h:88
int operator==(const TinyEvent &other) const
Definition: TinyEvent.h:45
int operator==(const EventWithHistory &other) const
tuple size
Write out results.
long long deltaBXinCycle(const TinyEvent &se, const int bx0) const
Definition: TinyEvent.h:79