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SiStripPsuDetIdMap.cc
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7 
11 #include <cstdlib>
12 #include <iostream>
13 #include <iomanip>
14 #include <sstream>
15 #include <string>
16 
17 using namespace sistrip;
18 
19 // only one constructor
21  LogTrace("SiStripPsuDetIdMap") << "[SiStripPsuDetIdMap::" << __func__ << "] Constructing ...";
22 }
23 // destructor
25  LogTrace("SiStripPsuDetIdMap") << "[SiStripPsuDetIdMap::" << __func__ << "] Destructing ...";
26 }
27 
28 // Build PSU-DETID map
29 void SiStripPsuDetIdMap::BuildMap(const std::string& mapFile, const bool debug) {
30  BuildMap(mapFile, debug, LVMap, HVMap, HVUnmapped_Map, HVCrosstalking_Map);
31 }
32 
33 void SiStripPsuDetIdMap::BuildMap(const std::string& mapFile, std::vector<std::pair<uint32_t, std::string> >& rawmap) {
34  //This method is a remnant of the old method, that provided a vector type of map, based on the
35  //raw reading of a file, with no processing.
36  //FIXME:
37  //This is not currently used, but I think we could slim this down to just a vector with
38  //the detIDs since the PSUChannel part of the excludedlist (if it ever is in a file) is never used!
39  edm::FileInPath file(mapFile.c_str());
40  std::ifstream ifs(file.fullPath().c_str());
41  string line;
42  while (getline(ifs, line)) {
43  if (!line.empty()) {
44  // split the line and insert in the map
45  stringstream ss(line);
46  string PSUChannel;
47  uint32_t detId;
48  ss >> detId;
49  ss >> PSUChannel;
50  rawmap.push_back(std::make_pair(detId, PSUChannel));
51  }
52  }
53 }
54 
55 //The following is the currently used method (called from SiStripDetVOffBuilder::buildPSUdetIdMap)
57  const std::string& mapFile,
58  const bool debug,
59  PsuDetIdMap& LVmap,
60  PsuDetIdMap& HVmap,
61  PsuDetIdMap& HVUnmappedmap,
62  PsuDetIdMap& HVCrosstalkingmap) //Maybe it would be nicer to return the map instead of using a reference...
63 {
64  //This method reads the map from the mapfile indicated in the cfg
65  //It populates the 4 maps (private data members of the SiStripPSUDetIdMap in question) (all maps are std::map<std::string,uint32_t > ):
66  //LVMap
67  //HVMap
68  //HVUnmapped_Map
69  //HVCrosstalking_Map
70  //These maps are accessed, based on the LV/HV case, to extract the detIDs connected to a given PSUChannel...
71  //see the getDetIDs method...
72  edm::FileInPath file(mapFile.c_str());
73  std::ifstream ifs(file.fullPath().c_str());
74  string line;
75  while (getline(ifs, line)) {
76  if (!line.empty()) {
77  // split the line and insert in the map
78  stringstream ss(line);
79  string PSUChannel;
80  uint32_t detId;
81  ss >> detId;
82  ss >> PSUChannel;
83  //Old "vector of pairs" map!
84  //map.push_back( std::make_pair(detId, dpName) );//This "map" is normally the pgMap of the map of which we are executing BuildMap()...
85  //Using a map to make the look-up easy and avoid lots of lookup loops.
86  std::string PSU = PSUChannel.substr(0, PSUChannel.size() - 10);
87  std::string Channel = PSUChannel.substr(PSUChannel.size() - 10);
88  LVmap[PSU].push_back(detId); // LVmap uses simply the PSU since there is no channel distinction necessary
89  if (Channel == "channel000") {
90  HVUnmappedmap[PSU].push_back(
91  detId); //Populate HV Unmapped map, by PSU listing all detids unmapped in that PSU (not necessarily all will be unmapped)
92  } else if (Channel == "channel999") {
93  HVCrosstalkingmap[PSU].push_back(
94  detId); //Populate HV Crosstalking map, by PSU listing all detids crosstalking in that PSU (usually all will be unmapped)
95  } else {
96  HVmap[PSUChannel].push_back(detId); //HV map for HV mapped channels, populated by PSU channel!
97  }
98  }
99  }
100 
101  //Remove duplicates for all 4 maps
102  for (PsuDetIdMap::iterator psu = LVMap.begin(); psu != LVMap.end(); psu++) {
103  RemoveDuplicateDetIDs(psu->second);
104  }
105  for (PsuDetIdMap::iterator psuchan = HVMap.begin(); psuchan != HVMap.end(); psuchan++) {
106  RemoveDuplicateDetIDs(psuchan->second);
107  }
108  for (PsuDetIdMap::iterator psu = HVUnmapped_Map.begin(); psu != HVUnmapped_Map.end(); psu++) {
109  RemoveDuplicateDetIDs(psu->second);
110  }
111  for (PsuDetIdMap::iterator psu = HVCrosstalking_Map.begin(); psu != HVCrosstalking_Map.end(); psu++) {
112  RemoveDuplicateDetIDs(psu->second);
113  }
114  if (debug) {
115  //Print out all the 4 maps:
116  std::cout << "Dumping the LV map" << std::endl;
117  std::cout << "PSU->detids" << std::endl;
118  for (PsuDetIdMap::iterator psu = LVMap.begin(); psu != LVMap.end(); psu++) {
119  std::cout << psu->first << " corresponds to following detids" << endl;
120  for (unsigned int i = 0; i < psu->second.size(); i++) {
121  std::cout << "\t\t" << psu->second[i] << std::endl;
122  }
123  }
124  std::cout << "Dumping the HV map for HV mapped channels" << std::endl;
125  std::cout << "PSUChannel->detids" << std::endl;
126  for (PsuDetIdMap::iterator psuchan = HVMap.begin(); psuchan != HVMap.end(); psuchan++) {
127  std::cout << psuchan->first << " corresponds to following detids" << endl;
128  for (unsigned int i = 0; i < psuchan->second.size(); i++) {
129  std::cout << "\t\t" << psuchan->second[i] << std::endl;
130  }
131  }
132  std::cout << "Dumping the HV map for HV UNmapped channels" << std::endl;
133  std::cout << "PSU->detids" << std::endl;
134  for (PsuDetIdMap::iterator psu = HVUnmapped_Map.begin(); psu != HVUnmapped_Map.end(); psu++) {
135  std::cout << psu->first << " corresponds to following detids" << endl;
136  for (unsigned int i = 0; i < psu->second.size(); i++) {
137  std::cout << "\t\t" << psu->second[i] << std::endl;
138  }
139  }
140  std::cout << "Dumping the HV map for HV Crosstalking channels" << std::endl;
141  std::cout << "PSU->detids" << std::endl;
142  for (PsuDetIdMap::iterator psu = HVCrosstalking_Map.begin(); psu != HVCrosstalking_Map.end(); psu++) {
143  std::cout << psu->first << " corresponds to following detids" << endl;
144  for (unsigned int i = 0; i < psu->second.size(); i++) {
145  std::cout << "\t\t" << psu->second[i] << std::endl;
146  }
147  }
148  //Could add here consistency checks against the list of detIDs for Strip or Pixels
149  //Number of total detIDs LVMapped, HV Mapped, HVunmapped, HV crosstalking...
150  }
151 }
152 
153 void SiStripPsuDetIdMap::RemoveDuplicateDetIDs(std::vector<uint32_t>& detids) {
154  //Function to remove duplicates from a vector of detids
155  if (!detids.empty()) { //Leave empty vector alone ;)
156  std::sort(detids.begin(), detids.end());
157  std::vector<uint32_t>::iterator it = std::unique(detids.begin(), detids.end());
158  detids.resize(it - detids.begin());
159  }
160 }
161 
162 std::vector<uint32_t> SiStripPsuDetIdMap::getLvDetID(std::string PSU) {
163  //Function that returns a vector with all detids associated with a PSU
164  //(no channel information is saved in the map since it is not relevant for LV!)
165  if (LVMap.find(PSU) != LVMap.end()) {
166  return LVMap[PSU];
167  } else {
168  std::vector<uint32_t> detids;
169  return detids;
170  }
171 }
172 
174  std::vector<uint32_t>& ids,
175  std::vector<uint32_t>& unmapped_ids,
176  std::vector<uint32_t>& crosstalking_ids) {
177  //Function that (via reference parameters) populates ids, unmapped_ids, crosstalking_ids vectors of detids associated with a given PSU *HV* channel.
178  if (HVMap.find(PSUChannel) != HVMap.end()) {
179  ids = HVMap[PSUChannel];
180  }
181  //Extract the PSU to check the unmapped and crosstalking maps too corresponding to this channel
182  std::string PSU = PSUChannel.substr(0, PSUChannel.size() - 10);
183  if (HVUnmapped_Map.find(PSU) != HVUnmapped_Map.end()) {
184  unmapped_ids = HVUnmapped_Map[PSU];
185  }
186  if (HVCrosstalking_Map.find(PSU) != HVCrosstalking_Map.end()) {
187  crosstalking_ids = HVCrosstalking_Map[PSU];
188  }
189 }
190 
191 // This method needs to be updated once HV channel mapping is known
192 // Currently, channel number is ignored for mapping purposes
193 // check both PG and CG as the channels should be unique
194 
196  const bool debug,
197  std::vector<uint32_t>& detids,
198  std::vector<uint32_t>& unmapped_detids,
199  std::vector<uint32_t>& crosstalking_detids) {
200  //This function takes as argument the PSUChannel (i.e. the dpname as it comes from the PVSS query, e.g. cms_trk_dcs_02:CAEN/CMS_TRACKER_SY1527_2/branchController05/easyCrate0/easyBoard12/channel001)
201  //And it returns 3 vectors:
202  //1-detids->all the detids positively matching the PSUChannel in question
203  //2-unmapped_detids->the detids that are matching the PSU in question but that are not HV mapped
204  //3-crosstalking_detids->the detids that are matching the PSU in question but exhibit the HV channel cross-talking behavior (they are ON as long as ANY of the 2 HV channels of the supply is ON, so they only go OFF when both channels are OFF)
205  //The second and third vectors are only relevant for the HV case, when unmapped and cross-talking channels need further processing before being turned ON and OFF.
206 
207  const std::string& PSUChannelFromQuery = PSUChannel;
208 
209  //Get the channel to see if it is LV or HV, they will be treated differently
210  std::string ChannelFromQuery = PSUChannelFromQuery.substr(PSUChannelFromQuery.size() - 10);
211  //Get the PSU from Query, to be used for LVMap and for the HVUnmapped and HVCrosstalking maps:
212  std::string PSUFromQuery = PSUChannelFromQuery.substr(0, PSUChannelFromQuery.size() - 10);
213  if (debug) {
214  //FIXME:
215  //Should handle all the couts with MessageLogger!
216  std::cout << "DPNAME from QUERY: " << PSUChannelFromQuery << ", Channel: " << ChannelFromQuery
217  << "PSU: " << PSUFromQuery << std::endl;
218  }
219 
220  //First prepare the strings needed to do the matching of the PSUChannel from the query to the ones in the map
221 
222  //Handle the LV case first:
223  if (ChannelFromQuery == "channel000" or ChannelFromQuery == "channel001") {
224  //For LV channels we need to look for any detID that is reported either as channel000 (not HV mapped)
225  //but also as channel002 and channel003 (if they are HV mapped), or as channel999 (if they are in a crosstalking PSU)
226  //Get the PSU to do a PSU-only matching to get all detIDs connected to the LV channel:
227  //Now loop over the map!
228  //for (PsuDetIdMap::iterator iter = pgMap.begin(); iter != pgMap.end(); iter++) {
229  // std::string PSUFromMap = iter->second.substr(0,iter->second.size()-10);
230  // //Careful if you uncomment this cout: it prints 15148 lines when checking for 1 psu name match! (meant for debugging of course)
231  // //std::cout<<"Truncated DPNAME from MAP: "<<PSUFromMap<<std::endl;
232  // if (PSUFromQuery == PSUFromMap) {
233  // detids.push_back(iter->first); //And fill the detids vector with the all detids matching the PSU from the query!
234  // }
235  //}
236  //No need to loop over if we use an actual map!
237 
238  if (LVMap.find(PSUFromQuery) != LVMap.end()) {
239  detids = LVMap[PSUFromQuery];
240  }
241  }
242  //Handle the HV case too:
243  else if (ChannelFromQuery == "channel002" or ChannelFromQuery == "channel003") {
244  //For the HV channel we need to look at the actual positive matching detIDs,
245  //but also to the unmapped one (channel000) and the crosstalking ones (channel999).
246  //Assemble the corresponding channel000 (unmapped channels) replacing the last character in PSUChannelFromQuery:
247  // std::string ZeroedPSUChannelFromQuery= PSUChannelFromQuery;
248  // ZeroedPSUChannelFromQuery.replace(ZeroedPSUChannelFromQuery.size()-1,1,"0");
249  // //Same for channel999 for the crosstalking channels:
250  // //std::string NineNineNine='999';
251  // std::string NinedPSUChannelFromQuery= PSUChannelFromQuery;
252  // NinedPSUChannelFromQuery.replace(NinedPSUChannelFromQuery.size()-3,3,"999");
253  // //std::string NinedPSUChannelFromQuery= PSUChannelFromQuery.substr(0,PSUChannelFromQuery.size()-3);// + '999';
254  // //Now loop over the map!
255  // for (PsuDetIdMap::iterator iter = pgMap.begin(); iter != pgMap.end(); iter++) {
256  // std::string PSUChannelFromMap = iter->second;
257  // //Careful if you uncomment this cout: it prints 15148 lines when checking for 1 psu name match! (meant for debugging of course)
258  // //std::cout<<"Truncated DPNAME from MAP: "<<PSUFromMap<<std::endl;
259  // if (PSUChannelFromMap==PSUChannelFromQuery) {
260  // detids.push_back(iter->first); //Fill the detids vector with the all detids matching the PSUChannel from the query!
261  // }
262  // if (PSUChannelFromMap==ZeroedPSUChannelFromQuery) {
263  // unmapped_detids.push_back(iter->first); //Fill the unmapped_detids vector with the all detids matching the channel000 for the PSU from the query!
264  // if (debug) { //BEWARE: this debug printouts can become very heavy! 1 print out per detID matched!
265  // std::cout<<"Matched one of the HV-UNMAPPED channels: "<<ZeroedPSUChannelFromQuery<<std::endl;
266  // std::cout<<"Corresponding to detID: "<<iter->first<<std::endl;
267  // //for (unsigned int i_nohvmap_detid=0;i_nohvmap_detid < iter->first.size();i_nohvmap_detid++) {
268  // // cout<< iter->first[i_nohvmap_detid] << std::endl;
269  // }
270  // }
271  // if (PSUChannelFromMap==NinedPSUChannelFromQuery) {
272  // crosstalking_detids.push_back(iter->first); //Fill the crosstalking_detids vector with the all detids matching the channel999 for the PSU from the query!
273  // }
274  // }
275  if (HVMap.find(PSUChannelFromQuery) != HVMap.end()) {
276  detids = HVMap[PSUChannelFromQuery];
277  } else if (HVUnmapped_Map.find(PSUFromQuery) != HVUnmapped_Map.end()) {
278  unmapped_detids = HVUnmapped_Map[PSUFromQuery];
279  } else if (HVCrosstalking_Map.find(PSUFromQuery) != HVCrosstalking_Map.end()) {
280  crosstalking_detids = HVCrosstalking_Map[PSUFromQuery];
281  }
282  }
283  //
284  //
285  // //With the new code above that makes use of the channel00X information in the map
286  // //we should no more need to remove duplicates by construction.
287  // //The following code was used when there was no channel information in the map,
288  // //to elegantly eliminate duplicates.
289  // //We can now use it as a cross-check (still removing duplicates in case they happen, but writing a message out)
290  //
291  // // remove duplicates
292  //
293  // //First sort detIDs vector, so that duplicates will be consecutive
294  // if (!detids.empty()) {
295  // std::sort(detids.begin(),detids.end());
296  // //Then use the forward iterator unique from STD that basically removes all consecutive duplicates from the vector
297  // //and reports a forward iterator pointing to the new end of the sequence
298  // std::vector<uint32_t>::iterator it = std::unique(detids.begin(),detids.end());
299  // if (it!=detids.end()) {
300  // std::cout<<"ARGH! It seems we found duplicate detIDs in the map corresponding to this PSUChannel: "<<PSUChannelFromQuery<<std::endl;
301  // detids.resize( it - detids.begin() );
302  // }
303  // if (debug) {
304  // std::cout<<"Matched the following detIDs to PSU channel from query "<<PSUChannelFromQuery <<":"<<std::endl;
305  // for (std::vector<uint32_t>::iterator i_detid=detids.begin();i_detid!=detids.end(); i_detid++) {
306  // std::cout<<*i_detid<<std::endl;;
307  // }
308  // }
309  // }
310  // //Same for unmapped detIDs:
311  // if (!unmapped_detids.empty()) {
312  // std::sort(unmapped_detids.begin(),unmapped_detids.end());
313  // //Then use the forward iterator unique from STD that basically removes all consecutive duplicates from the vector
314  // //and reports a forward iterator pointing to the new end of the sequence
315  // std::vector<uint32_t>::iterator it = std::unique(unmapped_detids.begin(),unmapped_detids.end());
316  // if (it!=unmapped_detids.end()) {
317  // std::cout<<"ARGH! It seems we found duplicate unmapped_detids in the map corresponding to this PSUChannel: "<<PSUChannelFromQuery<<std::endl;
318  // unmapped_detids.resize( it - unmapped_detids.begin() );
319  // }
320  // if (debug) {
321  // std::cout<<"Matched the following unmapped_detids to PSU channel from query "<<PSUChannelFromQuery <<":"<<std::endl;
322  // for (std::vector<uint32_t>::iterator i_detid=unmapped_detids.begin();i_detid!=unmapped_detids.end(); i_detid++) {
323  // std::cout<<*i_detid<<std::endl;;
324  // }
325  // }
326  // }
327  // //Finally, same for crosstalking detIDs:
328  // if (!crosstalking_detids.empty()) {
329  // std::sort(crosstalking_detids.begin(),crosstalking_detids.end());
330  // //Then use the forward iterator unique from STD that basically removes all consecutive duplicates from the vector
331  // //and reports a forward iterator pointing to the new end of the sequence
332  // std::vector<uint32_t>::iterator it = std::unique(crosstalking_detids.begin(),crosstalking_detids.end());
333  // if (it!=crosstalking_detids.end()) {
334  // std::cout<<"ARGH! It seems we found duplicate crosstalking_detids in the map corresponding to this PSUChannel: "<<PSUChannelFromQuery<<std::endl;
335  // crosstalking_detids.resize( it - crosstalking_detids.begin() );
336  // }
337  // if (debug) {
338  // std::cout<<"Matched the following crosstalking_detids to PSU channel from query "<<PSUChannelFromQuery <<":"<<std::endl;
339  // for (std::vector<uint32_t>::iterator i_detid=crosstalking_detids.begin();i_detid!=crosstalking_detids.end(); i_detid++) {
340  // std::cout<<*i_detid<<std::endl;;
341  // }
342  // }
343  // }
344  //
345  // //Using reference parameters since we are returning multiple objects.
346  // //return detids;
347 }
348 
349 // returns PSU channel name for a given DETID
351  std::vector<std::pair<uint32_t, std::string> >::iterator iter;
352  for (iter = pgMap.begin(); iter != pgMap.end(); iter++) {
353  if (iter->first && iter->first == detid) {
354  return iter->second;
355  }
356  }
357  // if we reach here, then we didn't find the detid in the map
358  return "UNKNOWN";
359 }
360 
362  std::vector<std::pair<uint32_t, std::string> >::iterator iter;
363  if (group == "PG") {
364  for (iter = pgMap.begin(); iter != pgMap.end(); iter++) {
365  if (iter->first && iter->first == detid) {
366  return iter->second;
367  }
368  }
369  }
370  if (group == "CG") {
371  for (iter = cgMap.begin(); iter != cgMap.end(); iter++) {
372  if (iter->first && iter->first == detid) {
373  return iter->second;
374  }
375  }
376  }
377  // if we reach here, then we didn't find the detid in the map
378  return "UNKNOWN";
379 }
380 
381 // returns the PVSS name for a given DETID
383  for (unsigned int i = 0; i < pgMap.size(); i++) {
384  if (pgMap[i].first == detid) {
385  return detectorLocations[i];
386  }
387  }
388  return "UNKNOWN";
389 }
390 
391 // returns the PVSS name for a given DETID, depending on specified map
393  if (group == "PG") {
394  for (unsigned int i = 0; i < pgMap.size(); i++) {
395  if (pgMap[i].first == detid) {
396  return detectorLocations[i];
397  }
398  }
399  }
400  if (group == "CG") {
401  for (unsigned int i = 0; i < cgMap.size(); i++) {
402  if (cgMap[i].first == detid) {
403  return controlLocations[i];
404  }
405  }
406  }
407  return "UNKNOWN";
408 }
409 
410 // returns the PVSS name for a given PSU channel
412  for (unsigned int i = 0; i < pgMap.size(); i++) {
413  if (pgMap[i].second == PSUChannel) {
414  return detectorLocations[i];
415  }
416  }
417  for (unsigned int i = 0; i < cgMap.size(); i++) {
418  if (cgMap[i].second == PSUChannel) {
419  return controlLocations[i];
420  }
421  }
422  return "UNKNOWN";
423 }
424 
425 // returns the DCU ID for a given PSU channel
427  for (unsigned int i = 0; i < pgMap.size(); i++) {
428  if (pgMap[i].second == PSUChannel) {
429  return dcuIds[i];
430  }
431  }
432  for (unsigned int i = 0; i < cgMap.size(); i++) {
433  if (cgMap[i].second == PSUChannel) {
434  return cgDcuIds[i];
435  }
436  }
437  return 0;
438 }
439 
440 uint32_t SiStripPsuDetIdMap::getDcuId(uint32_t detid) {
441  for (unsigned int i = 0; i < pgMap.size(); i++) {
442  if (pgMap[i].first == detid) {
443  return dcuIds[i];
444  }
445  }
446  return 0;
447 }
448 
449 // determine if a given PSU channel is HV or not
451  // isHV = 0 means LV, = 1 means HV, = -1 means error
452  int isHV = 0;
453  std::string::size_type loc = PSUChannel.find("channel", 0);
454  if (loc != std::string::npos) {
455  std::string chNumber = PSUChannel.substr(loc + 7, 3);
456  if (chNumber == "002" || chNumber == "003") {
457  isHV = 1;
458  } else if (chNumber == "000" || chNumber == "001") {
459  isHV = 0;
460  } else {
461  edm::LogWarning("SiStripPsuDetIdMap")
462  << "[SiStripPsuDetIdMap::" << __func__ << "] channel number of unexpected format, setting error flag!";
463  isHV = -1;
464  }
465  } else {
466  edm::LogWarning("SiStripPsuDetIdMap") << "[SiStripPsuDetIdMap::" << __func__
467  << "] channel number not located in PSU channel name, setting error flag!";
468  isHV = -1;
469  }
470  return isHV;
471 }
472 
474  output.clear();
475  for (unsigned int i = 0; i < input.size(); i++) {
476  output.push_back(new TkDcuPsuMap(*(input[i])));
477  }
478 }
479 
481  stringstream pg;
482  pg << "Map of power supplies to DET IDs: " << std::endl << "-- PSU name -- -- Det Id --" << std::endl;
483  for (unsigned int p = 0; p < pgMap.size(); p++) {
484  pg << pgMap[p].first << " " << pgMap[p].second << std::endl;
485  }
486  edm::LogInfo("SiStripPsuDetIdMap") << "[SiStripPsuDetIdMap::" << __func__ << "] " << pg.str();
487 }
488 
490  stringstream cg;
491  cg << "Map of control power supplies to DET IDs: " << std::endl
492  << "-- PSU name -- -- Det Id --" << std::endl;
493  for (unsigned int p = 0; p < cgMap.size(); p++) {
494  cg << cgMap[p].first << " " << cgMap[p].second << std::endl;
495  }
496  edm::LogInfo("SiStripPsuDetIdMap") << "[SiStripPsuDetIdMap::" << __func__ << "] " << cg.str();
497 }
498 
499 std::vector<std::pair<uint32_t, std::string> > SiStripPsuDetIdMap::getDcuPsuMap() {
500  if (!pgMap.empty()) {
501  return pgMap;
502  }
503  std::vector<std::pair<uint32_t, std::string> > emptyVec;
504  return emptyVec;
505 }
506 
508  const DcuPsuVector& dcuPsus_) {
509  std::cout << "Number of entries in DCU-PSU map: " << dcuPsus_.size() << std::endl;
510  std::cout << "Number of entries in DCU-DETID map: " << dcuDetIds_.size() << std::endl;
511  std::cout << std::endl;
512 
513  std::vector<bool> ddUsed(dcuDetIds_.size(), false);
514  std::vector<bool> dpUsed(dcuPsus_.size(), false);
515 
516  for (unsigned int dp = 0; dp < dcuPsus_.size(); dp++) {
517  for (unsigned int dd = 0; dd < dcuDetIds_.size(); dd++) {
518  if (dcuPsus_[dp]->getDcuHardId() == dcuDetIds_[dd].second->getDcuHardId()) {
519  dpUsed[dp] = true;
520  ddUsed[dd] = true;
521  }
522  }
523  }
524  unsigned int numDpUsed = 0, numDpNotUsed = 0;
525  for (unsigned int dp = 0; dp < dpUsed.size(); dp++) {
526  if (dpUsed[dp]) {
527  numDpUsed++;
528  } else {
529  numDpNotUsed++;
530  }
531  }
532 
533  std::cout << "Number of used DCU-PSU entries: " << numDpUsed << std::endl;
534  std::cout << "Number of unused DCU-PSU entries: " << numDpNotUsed << std::endl;
535 
536  unsigned int numDdUsed = 0, numDdNotUsed = 0;
537  for (unsigned int dd = 0; dd < ddUsed.size(); dd++) {
538  if (ddUsed[dd]) {
539  numDdUsed++;
540  } else {
541  numDdNotUsed++;
542  }
543  }
544 
545  std::cout << "Number of used DCU-DETID entries: " << numDdUsed << std::endl;
546  std::cout << "Number of unused DCU-DETID entries: " << numDdNotUsed << std::endl;
547  std::cout << std::endl;
548  std::cout << "Size of PSU-DETID map: " << pgMap.size() << std::endl;
549  std::cout << "Size of detectorLocations: " << detectorLocations.size() << std::endl;
550 }
551 
552 //std::vector< std::pair<uint32_t, SiStripConfigDb::DeviceAddress> > SiStripPsuDetIdMap::retrieveDcuDeviceAddresses(std::string partition) {
553 std::vector<std::pair<std::vector<uint16_t>, std::vector<uint32_t> > > SiStripPsuDetIdMap::retrieveDcuDeviceAddresses(
554  std::string partition) {
555  // get the DB parameters
556  SiStripDbParams dbParams_ = db_->dbParams();
557  SiStripDbParams::SiStripPartitions::const_iterator iter;
558 
559  std::vector<std::pair<uint32_t, SiStripConfigDb::DeviceAddress> > resultVec;
560 
562  SiStripConfigDb::DeviceType device_ = DCU;
563 
564  for (iter = dbParams_.partitions().begin(); iter != dbParams_.partitions().end(); ++iter) {
565  if (partition.empty() || partition == iter->second.partitionName()) {
566  if (iter->second.partitionName() == SiStripPartition::defaultPartitionName_) {
567  continue;
568  }
569  if (iter->second.dcuVersion().first > 0 && iter->second.fecVersion().first > 0) {
571  db_->getDeviceDescriptions(device_, iter->second.partitionName());
572  if (!range.empty()) {
573  SiStripConfigDb::DeviceDescriptionsV nextVec(range.begin(), range.end());
574  for (unsigned int i = 0; i < nextVec.size(); i++) {
575  dcuDescription* desc = dynamic_cast<dcuDescription*>(nextVec[i]);
576  resultVec.push_back(std::make_pair(desc->getDcuHardId(), db_->deviceAddress(*(nextVec[i]))));
577  }
578  }
579  }
580  }
581  }
582 
583  std::vector<std::pair<std::vector<uint16_t>, std::vector<uint32_t> > > testVec;
584  std::vector<std::pair<uint32_t, SiStripConfigDb::DeviceAddress> >::iterator reorg_iter = resultVec.begin();
585 
586  for (; reorg_iter != resultVec.end(); reorg_iter++) {
587  std::vector<uint16_t> fecInfo(4, 0);
588  fecInfo[0] = reorg_iter->second.fecCrate_;
589  fecInfo[1] = reorg_iter->second.fecSlot_;
590  fecInfo[2] = reorg_iter->second.fecRing_;
591  fecInfo[3] = reorg_iter->second.ccuAddr_;
592  std::vector<uint32_t> dcuids;
593  std::vector<std::pair<uint32_t, SiStripConfigDb::DeviceAddress> >::iterator jter = reorg_iter;
594  for (; jter != resultVec.end(); jter++) {
595  if (reorg_iter->second.fecCrate_ == jter->second.fecCrate_ &&
596  reorg_iter->second.fecSlot_ == jter->second.fecSlot_ &&
597  reorg_iter->second.fecRing_ == jter->second.fecRing_ &&
598  reorg_iter->second.ccuAddr_ == jter->second.ccuAddr_) {
599  dcuids.push_back(jter->first);
600  }
601  }
602  // handle duplicates
603  bool isDup = false;
604  for (unsigned int i = 0; i < testVec.size(); i++) {
605  if (fecInfo == testVec[i].first) {
606  isDup = true;
607  dcuids.insert(dcuids.end(), (testVec[i].second).begin(), (testVec[i].second).end());
608  std::sort(dcuids.begin(), dcuids.end());
609  std::vector<uint32_t>::iterator it = std::unique(dcuids.begin(), dcuids.end());
610  dcuids.resize(it - dcuids.begin());
611  testVec[i].second = dcuids;
612  }
613  }
614  if (!isDup) {
615  std::sort(dcuids.begin(), dcuids.end());
616  std::vector<uint32_t>::iterator it = std::unique(dcuids.begin(), dcuids.end());
617  dcuids.resize(it - dcuids.begin());
618  testVec.push_back(std::make_pair(fecInfo, dcuids));
619  }
620  }
621  // return resultVec;
622  return testVec;
623 }
624 
625 std::vector<uint32_t> SiStripPsuDetIdMap::findDcuIdFromDeviceAddress(uint32_t dcuid_) {
626  std::vector<std::pair<std::vector<uint16_t>, std::vector<uint32_t> > >::iterator iter =
627  dcu_device_addr_vector.begin();
628  std::vector<std::pair<std::vector<uint16_t>, std::vector<uint32_t> > >::iterator res_iter =
629  dcu_device_addr_vector.end();
630  std::vector<uint32_t> pgDcu;
631 
632  for (; iter != dcu_device_addr_vector.end(); iter++) {
633  std::vector<uint32_t> dcuids = iter->second;
634  std::vector<uint32_t>::iterator dcu_iter = std::find(dcuids.begin(), dcuids.end(), dcuid_);
635  bool alreadyFound = false;
636  if (res_iter != dcu_device_addr_vector.end()) {
637  alreadyFound = true;
638  }
639  if (dcu_iter != dcuids.end()) {
640  res_iter = iter;
641  if (!alreadyFound) {
642  for (unsigned int i = 0; i < dcuids.size(); i++) {
643  if (dcuids[i] != dcuid_) {
644  pgDcu.push_back(dcuids[i]);
645  }
646  }
647  } else {
648  std::cout << "Oh oh ... we have a duplicate :-(" << std::endl;
649  }
650  }
651  }
652  return pgDcu;
653 }
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