source: fact/FADctrl/FADBoard.cc@ 13151

Last change on this file since 13151 was 12891, checked in by ogrimm, 13 years ago
Added code for automized measurement of dynamic range, not yet tested
File size: 25.2 KB
Line 
1/********************************************************************\
2
3 Class interfacing to FAD board
4
5\********************************************************************/
6
7#include "FADBoard.h"
8using namespace std;
9
10//
11// Constructor
12//
13FADBoard::FADBoard(string Server, unsigned short ServerPort, class FAD *Parent, unsigned int Num) {
14
15 int Ret;
16
17 // Initialization
18 m = Parent;
19 Active = false;
20 Continue = true;
21 CommOK = false;
22 ACalib.Time = -1;
23 Status.Update.tv_sec = -1;
24 Port = ServerPort;
25 Status.Frequency = 0;
26 Status.Rate = 0;
27 Status.BoardID = 0;
28
29 Name = new char [Server.size()+1]; // Name in permanent memory for DIM service
30 strcpy(Name, Server.c_str());
31
32 // Initialise mutex for synchronization
33 pthread_mutexattr_t Attr;
34
35 if ((Ret = pthread_mutexattr_init(&Attr)) != 0) {
36 m->Message(m->ERROR, "pthread_mutex_init() failed in FADBoard constructor (%s)", strerror(Ret));
37 }
38 if ((Ret = pthread_mutexattr_settype(&Attr, PTHREAD_MUTEX_ERRORCHECK)) != 0) {
39 m->Message(m->ERROR, "pthread_mutex_settype() failed in FADBoard constructor (%s)", strerror(Ret));
40 }
41 if ((Ret = pthread_mutex_init(&Mutex, &Attr)) != 0) {
42 m->Message(m->FATAL, "pthread_mutex_init() failed in FADBoard constructor (%s)", strerror(Ret));
43 }
44
45 // Initialise condition variable for synchronization
46 if ((Ret = pthread_cond_init(&CondVar, NULL)) != 0) {
47 m->Message(m->FATAL, "pthread_cond_init() failed in FADBoard constructor (%s)", strerror(Ret));
48 }
49
50 // Construct DIM service name prefix
51 stringstream ID;
52 ID << SERVER_NAME"/Board" << setfill('0') << setw(2) << Num << "/";
53
54 DIM_Name = new DimService((ID.str()+"Server").c_str(), Name);
55 DIM_Status = new DimService((ID.str()+"Status").c_str(), (char *) "");
56 DIM_ID = new DimService((ID.str()+"BoardID").c_str(), (char *) "S", NULL, 0);
57 DIM_Rate = new DimService((ID.str()+"RateHz").c_str(), Status.Rate);
58 DIM_Frequency = new DimService((ID.str()+"Frequency").c_str(), Status.Frequency);
59 DIM_BoardTime = new DimService((ID.str()+"BoardTime").c_str(), (char *) "I", &Status.BoardTime, sizeof(Status.BoardTime));
60 DIM_Lock = new DimService((ID.str()+"Lock").c_str(), (char *) "S", NULL, 0);
61 DIM_TriggerNum = new DimService((ID.str()+"TriggerNum").c_str(), (char *) "I", &Status.TriggerNum, sizeof(Status.TriggerNum));
62 DIM_Temp = new DimService((ID.str()+"Temperature").c_str(), (char *) "F", NULL, 0);
63 DIM_DAC = new DimService((ID.str()+"DAC").c_str(), (char *) "S", NULL, 0);
64 DIM_ROI = new DimService((ID.str()+"ROI").c_str(), (char *) "S", NULL, 0);
65 DIM_ACalData = new DimService((ID.str()+"ACalData").c_str(), (char *) "F", NULL, 0);
66
67 // Create thread that connects and receives data
68 SetStatus("Trying to connect...");
69
70 if ((Ret = pthread_create(&Thread, NULL, (void * (*)(void *)) LaunchThread, (void *) this)) != 0) {
71 m->Message(m->FATAL, "pthread_create() failed in FADBoard() (%s)", strerror(Ret));
72 }
73
74 // Start thread to connect to other sockets
75 DimThread::start();
76}
77
78//
79// Destructor
80//
81FADBoard::~FADBoard() {
82
83 int Ret;
84
85 // Cancel thread (if it did not quit already) and wait for it to quit
86 if ((Ret = pthread_cancel(Thread)) != 0 && Ret != ESRCH) {
87 m->Message(m->ERROR, "pthread_cancel() failed in ~FADBoard() (%s)", strerror(Ret));
88 }
89 if ((Ret = pthread_join(Thread, NULL)) != 0) {
90 m->Message(m->ERROR, "pthread_join() failed in ~FADBoard (%s)", strerror(Ret));
91 }
92
93 // Delete condition variable
94 if ((Ret = pthread_cond_destroy(&CondVar)) != 0) {
95 m->Message(m->ERROR, "pthread_cond_destroy() failed for %s in ~FADBoard (%s)", Name, strerror(Ret));
96 }
97
98 // Delete mutex
99 if ((Ret = pthread_mutex_destroy(&Mutex)) != 0) {
100 m->Message(m->ERROR, "pthread_mutex_destroy() failed for %s in ~FADBoard (%s)", Name, strerror(Ret));
101 }
102
103 delete DIM_Name; delete DIM_Status;
104 delete DIM_ID; delete DIM_Rate;
105 delete DIM_Frequency; delete DIM_Lock;
106 delete DIM_TriggerNum; delete DIM_Temp;
107 delete DIM_DAC; delete DIM_ROI;
108 delete DIM_ACalData; delete DIM_BoardTime;
109 delete[] Name;
110}
111
112
113//
114// Send data to board
115//
116void FADBoard::Send(const void *Data, size_t Bytes) {
117
118 // Do not send if not active or communication problem
119 if (!Active || !CommOK) return;
120
121 // Write data
122 ssize_t Result = write(Socket, Data, Bytes);
123
124 // Check result
125 if (Result == -1) m->PrintMessage("Error: Could not write to socket (%s)\n", strerror(errno));
126 else if ((size_t) Result < Bytes) m->PrintMessage("Error: Could only write %d bytes out of %d to socket\n", Result, Bytes);
127}
128
129void FADBoard::Send(unsigned short Data) {
130
131 unsigned short Buffer = htons(Data);
132
133 Send(&Buffer, sizeof(unsigned short));
134}
135
136
137//
138// Get board status (mutex protected to avoid concurrent access in ReadLoop)
139//
140struct FADBoard::BoardStatus FADBoard::GetStatus() {
141
142 int Ret;
143 struct BoardStatus S;
144
145 // Lock
146 if ((Ret = pthread_mutex_lock(&Mutex)) != 0) {
147 m->Message(m->FATAL, "pthread_mutex_lock() failed in ReadLoop() (%s)", strerror(Ret));
148 }
149
150 S = Status;
151
152 // Unlock
153 if ((Ret = pthread_mutex_unlock(&Mutex)) != 0) {
154 m->Message(m->FATAL, "pthread_mutex_unlock() failed in Unlock() (%s)", strerror(Ret));
155 }
156
157 return S;
158}
159
160
161//
162// Perform amplitude calibration in steps
163//
164// The steps are intended to assure that up to date data is available
165void FADBoard::AmplitudeCalibration() {
166
167 vector<unsigned short> ROICmd;
168 unsigned short DACCmd[] = {htons(CMD_Write | (BADDR_DAC + 1)), 0, htons(CMD_Write | (BADDR_DAC + 2)), 0, htons(CMD_Write | (BADDR_DAC + 3)), 0, htons(CMD_Execute) };
169 string Message = string("ACALIBDONE")+Name+"\n";
170
171 switch (State) {
172 // ====== Part A: Check if amplitude calibration should start and initialise =====
173 case standbye:
174 if (m->Mode != m->acalib) break;
175
176 // Invalidate current calibration
177 ACalib.Time = -1;
178 Count = 0;
179
180 // Save initial board status, set all ROIs to 1024 and set DAC values (no triggers while setting ROI)
181 InitialStatus = GetStatus();
182
183 for (unsigned int i=0; i<NChips*NChannels; i++) {
184 ROICmd.push_back(htons(CMD_Write | (BADDR_ROI + i)));
185 ROICmd.push_back(htons(NBins));
186 }
187 ROICmd.push_back(htons(CMD_Execute));
188 Send(&ROICmd[0], ROICmd.size()*sizeof(unsigned short));
189
190 DACCmd[1] = htons(0);
191 DACCmd[3] = htons(0);
192 DACCmd[5] = htons(0);
193 Send(DACCmd, sizeof(DACCmd));
194
195 // Clear sum vector and set state to accumulate
196 memset(Sum, 0, sizeof(Sum));
197 State = baseline;
198 SetStatus("Starting calilbration");
199 break;
200
201 // ====== Part B: Baseline calibration =====
202 case baseline:
203 // Check for stopping
204 if (m->Mode != m->acalib) {
205 State = cleanup;
206 break;
207 }
208
209 // Average
210 for (unsigned int Chip=0; Chip<NChips; Chip++) {
211 for (unsigned int Chan=0; Chan<NChannels; Chan++) {
212 for (int i=0; i<Status.ROI[Chip][Chan]; i++) {
213 Sum[Chip][Chan][(i+Status.TriggerCell[Chip]) % NBins] += Data[Chip][Chan][i];
214 }
215 }
216 }
217 Count++;
218
219 // Determine baseline if integration finished
220 if (Count < m->NumEventsRequested) break;
221
222 for (unsigned int i=0; i<NChips; i++) {
223 for (unsigned int j=0; j<NChannels; j++) {
224 for (unsigned int k=0; k<NBins; k++) {
225 ACalib.Baseline[i][j][k] = Sum[i][j][k] / m->NumEventsRequested;
226 }
227 }
228 }
229
230 // Set new DAC values and start accumulation
231 DACCmd[1] = htons(50000);
232 DACCmd[3] = htons(50000);
233 DACCmd[5] = htons(50000);
234 Send(DACCmd, sizeof(DACCmd));
235
236 // Clear sum vector and set state to accumulate
237 memset(Sum, 0, sizeof(Sum));
238 Count = 0;
239 State = gain;
240 break;
241
242 // ====== Part C: Gain calibration =====
243 case gain:
244 // Check for stopping
245 if (m->Mode != m->acalib) {
246 State = cleanup;
247 break;
248 }
249
250 // Average
251 for (unsigned int Chip=0; Chip<NChips; Chip++) {
252 for (unsigned int Chan=0; Chan<NChannels; Chan++) {
253 for (int i=0; i<Status.ROI[Chip][Chan]; i++) {
254 Sum[Chip][Chan][(i+Status.TriggerCell[Chip]) % NBins] += Data[Chip][Chan][i];
255 }
256 }
257 }
258 Count++;
259
260 // Determine gain if integration finished
261 if (Count < m->NumEventsRequested) break;
262
263 for (unsigned int i=0; i<NChips; i++) {
264 for (unsigned int j=0; j<NChannels; j++) {
265 for (unsigned int k=0; k<NBins; k++) {
266 ACalib.Gain[i][j][k] = (Sum[i][j][k] / m->NumEventsRequested) - ACalib.Baseline[i][j][k];
267 }
268 }
269 }
270
271 // Set new DAC values and start accumulation
272 DACCmd[1] = htons(0);
273 DACCmd[3] = htons(0);
274 DACCmd[5] = htons(0);
275 Send(DACCmd, sizeof(DACCmd));
276
277 // Clear sum vector and set state to accumulate
278 memset(Sum, 0, sizeof(Sum));
279 Count = 0;
280 State = secondary;
281 break;
282
283 // ====== Part D: Secondary calibration =====
284 case secondary:
285 // Check for stopping
286 if (m->Mode != m->acalib) {
287 State = cleanup;
288 break;
289 }
290
291 // Average
292 for (unsigned int Chip=0; Chip<NChips; Chip++) {
293 for (unsigned int Chan=0; Chan<NChannels; Chan++) {
294 for (int i=0; i<Status.ROI[Chip][Chan]; i++) {
295 Sum[Chip][Chan][i] = Data[Chip][Chan][i] - ACalib.Baseline[Chip][Chan][(i-Status.TriggerCell[Chip]) % NBins];
296 }
297 }
298 }
299 Count++;
300
301 // Determine secondary baseline if integration finished
302 if (Count < m->NumEventsRequested) break;
303
304 for (unsigned int i=0; i<NChips; i++) {
305 for (unsigned int j=0; j<NChannels; j++) {
306 for (unsigned int k=0; k<NBins; k++) {
307 ACalib.Secondary[i][j][k] = Sum[i][j][k] / (double) m->NumEventsRequested;
308 }
309 }
310 }
311
312 // Store calibration time and temperature
313 ACalib.DNA = Status.DNA;
314 ACalib.Frequency = Status.Frequency;
315 ACalib.Time = time(NULL);
316 ACalib.Temp = 0;
317 for (unsigned int i=0; i<NTemp; i++) ACalib.Temp += Status.Temp[i] / NTemp;
318
319 // Inform event thread that calibration is finished for this board
320 if (write(m->Pipe[1], Message.data(), Message.size()) == -1) {
321 m->Message(m->ERROR, "write() to Pipe[1] failed in class FADBoard::AmplitudeCalibration (%s)", strerror(errno));
322 }
323
324 SetStatus("Finished calibration");
325 State = cleanup;
326 break;
327
328 // ====== Part E: Write back original ROI and DAC settings =====
329 case cleanup:
330 // ROI values
331
332 ROICmd.clear();
333 for (unsigned int i=0; i<NChips*NChannels; i++) {
334 ROICmd.push_back(htons(CMD_Write | (BADDR_ROI + i)));
335 ROICmd.push_back(htons(InitialStatus.ROI[i/NChannels][i%NChannels]));
336 }
337 ROICmd.push_back(htons(CMD_Execute));
338 Send(&ROICmd[0], ROICmd.size()*sizeof(unsigned short));
339
340 // DAC values
341 DACCmd[1] = htons(InitialStatus.DAC[1]);
342 DACCmd[3] = htons(InitialStatus.DAC[2]);
343 DACCmd[5] = htons(InitialStatus.DAC[3]);
344 Send(DACCmd, sizeof(DACCmd));
345
346 // Update DIM service with calibration information
347 for (unsigned int i=0; i<NChips; i++) {
348 for (unsigned int j=0; j<NChannels; j++) {
349 for (unsigned int k=0; k<NBins; k++) {
350 ACalData[0][i][j][k] = ACalib.Baseline[i][j][k];
351 ACalData[1][i][j][k] = ACalib.Gain[i][j][k];
352 ACalData[2][i][j][k] = ACalib.Secondary[i][j][k];
353 }
354 }
355 }
356 DIM_ACalData->updateService(ACalData, 3*NChips*NChannels*NBins*sizeof(float));
357
358 State = wait;
359 break;
360
361 // ====== Wait for Mode not being idle =====
362 case wait:
363 if (m->Mode == m->idle) State = standbye;
364 break;
365 }
366}
367
368//
369// Connect to board and read data
370//
371void FADBoard::ReadLoop() {
372
373 char Buffer[READ_BUFFER_SIZE];
374 unsigned int Pos = 0, Count = 0;
375 const PEVNT_HEADER *Header = (PEVNT_HEADER *) Buffer;
376 ssize_t Result;
377 struct sockaddr_in SocketAddress;
378 struct BoardStatus PrevStatus;
379 int Ret;
380
381 // Resolve hostname
382 struct hostent *Host = gethostbyname(Name);
383 if (Host == 0) {
384 SetStatus("Could not resolve host name '%s'", Name);
385 return;
386 }
387
388 SocketAddress.sin_family = PF_INET;
389 SocketAddress.sin_port = htons(Port);
390 SocketAddress.sin_addr = *(struct in_addr*) Host->h_addr;
391
392 // Open socket descriptor
393 if ((Socket = socket(PF_INET, SOCK_STREAM, 0)) == -1) {
394 m->Message(m->ERROR, "Could not open socket for %s (%s)\n", Name, strerror(errno));
395 return;
396 }
397
398 // Connect to server
399 if (connect(Socket, (struct sockaddr *) &SocketAddress, sizeof(SocketAddress)) == -1) {
400 SetStatus("Could not connect to port %hu (%s)", Port, strerror(errno));
401 }
402 else {
403 CommOK = true;
404 Active = true;
405 SetStatus("Connected");
406 }
407
408 // Use not zero so that comparing Status and PrevStatus at first test will likely show differences
409 memset(&PrevStatus, 0xee, sizeof(PrevStatus));
410
411 // Leave loop if program termination requested or board communication not OK
412 while (!m->ExitRequest && CommOK) {
413 // Read data from socket
414 Result = read(Socket, Buffer + Pos, sizeof(Buffer)-Pos);
415
416 // Check result of read
417 if (Result == -1) {
418 m->Message(m->ERROR, "Could not read from socket for %s, exiting read loop (%s)\n", Name, strerror(errno));
419 CommOK = false;
420 break;
421 }
422 else if (Result == 0) {
423 SetStatus("Server not existing anymore, exiting read loop");
424 CommOK = false;
425 break;
426 }
427
428 // If not active, discard incoming data
429 if (!Active) continue;
430
431 // Advance write pointer
432 Pos += Result;
433
434 // Check if internal buffer full
435 if (Pos == sizeof(Buffer)) {
436 SetStatus("Internal buffer full, deleting all data in buffer");
437 Pos = 0;
438 continue;
439 }
440
441 // Check if buffer starts with start_package_flag, remove data if not
442 unsigned int Temp = 0;
443 while (ntohs(*((unsigned short *) (Buffer+Temp))) != 0xfb01 && Temp<Pos) Temp++;
444 if (Temp != 0) {
445 memmove(Buffer, Buffer+Temp, Pos-Temp);
446 Pos -= Temp;
447 SetStatus("Removed %d bytes because of start_package_flag not found", Temp);
448 continue;
449 }
450
451 // Wait until the buffer contains at least enough bytes to potentially hold a PEVNT_HEADER
452 if (Pos < sizeof(PEVNT_HEADER)) continue;
453
454 unsigned int Length = ntohs(Header->package_length)*2*sizeof(char);
455 if (Pos < Length) continue;
456
457 // Extract data if event end package flag correct
458 if (ntohs(*(unsigned short *) (Buffer+Length-sizeof(unsigned short))) == 0x04FE) {
459
460 // Prepare pointers to channel data (channels stored in order 0,9,18,27 - 1,10,19,28 - ... - 8,17,26,35)
461 PCHANNEL *Channel[NChips*NChannels], *Pnt=(PCHANNEL *) (Header+1);
462 for(unsigned int i=0; i<NChips*NChannels; i++) {
463 Channel[i] = Pnt;
464 Pnt = (PCHANNEL *) ((short *) (Channel[i] + 1) + ntohs(Channel[i]->roi));
465 }
466
467 // Wait until event thread processed the previous data and lock to avoid concurrent access in GetStatus()
468 Lock();
469 while (!Continue) {
470 struct timespec Wakeup;
471 Wakeup.tv_sec = time(NULL)+MAX_WAIT_FOR_CONDITION;
472 Wakeup.tv_nsec = 0;
473 if ((Ret = pthread_cond_timedwait(&CondVar, &Mutex, &Wakeup)) != 0) {
474 if (Ret == ETIMEDOUT) SetStatus("Board %s timed out (%d s) waiting for condition\n", Name, MAX_WAIT_FOR_CONDITION);
475 else m->Message(m->ERROR, "pthread_cond_wait() failed (%s)", strerror(Ret));
476 }
477 }
478 gettimeofday(&Status.Update, NULL);
479
480 // Extract board and trigger information
481 Status.BoardID = ntohs(Header->board_id);
482 Status.FirmwareRevision = ntohs(Header->version_no);
483 Status.BoardTime = ntohl(Header->time);
484 Status.EventCounter = ntohl(Header->fad_evt_counter);
485 Status.TriggerNum = ntohl(Header->trigger_id);
486 Status.Runnumber = ntohl(Header->runnumber);
487 Status.TriggerType = ntohs(Header->trigger_type);
488 Status.TriggerCRC = ntohs(Header->trigger_crc);
489 Status.DNA = Header->DNA;
490
491 // Extract frequency related information
492 Status.Frequency = ntohl(Header->REFCLK_frequency)/1.0e3*2.048;
493 Status.PhaseShift = Header->adc_clock_phase_shift;
494 for (unsigned int i=0; i<NChips; i++) {
495 if ((ntohs(Header->PLLLCK)>>12 & (1<<i)) != 0) Status.Lock[i] = 1;
496 else Status.Lock[i] = 0;
497 }
498
499 // Extract Firmware status info
500 Status.denable = (bool) ( ntohs(Header->PLLLCK) & (1<<11) );
501 Status.dwrite = (bool) ( ntohs(Header->PLLLCK) & (1<<10) );
502 Status.DCM_lock = (bool) ( ntohs(Header->PLLLCK) & (1<<7) );
503 Status.DCM_ready = (bool) ( ntohs(Header->PLLLCK) & (1<<6) );
504 Status.spi_clk = (bool) ( ntohs(Header->PLLLCK) & (1<<5) );
505 Status.RefClk_low = (bool) ( ntohs(Header->PLLLCK) & (1<<8) );
506
507 // Extract temperatures (MSB indicates if temperature is positive or negative)
508 for (unsigned int i=0; i<NTemp; i++) {
509 if ((ntohs(Header->drs_temperature[i]) & 0x8000) == 0) Status.Temp[i] = float(ntohs(Header->drs_temperature[i]) >> 3)/16;
510 else Status.Temp[i] = float(0xE000 | (ntohs(Header->drs_temperature[i])) >> 3)/16;
511 }
512
513 // Extract DAC channels
514 for (unsigned int i=0; i<NDAC; i++) Status.DAC[i] = ntohs(Header->dac[i]);
515
516 for (unsigned int Chip=0; Chip<NChips; Chip++) {
517 // Extract trigger cells
518 Status.TriggerCell[Chip] = (int) ntohs(Channel[Chip]->start_cell);
519
520 for (unsigned int Chan=0; Chan<NChannels; Chan++) {
521 // Extract ROI
522 Status.ROI[Chip][Chan] = ntohs(Channel[Chip+NChips*Chan]->roi);
523
524 // Extract ADC data (stored as signed short)
525 // FADs ADC is 12 bit (values -2048 .. 2047)
526 // negative/positive overflow is -2049 / +2048
527 for (int i=0; i<Status.ROI[Chip][Chan]; i++) {
528 Data[Chip][Chan][i] = Channel[Chip+NChips*Chan]->adc_data[i];
529 }
530 }
531 }
532
533 // Prepare predicate for condition variable
534 Continue = false;
535 Count++;
536 Unlock();
537
538 // Amplitude calibration (will check if Mode is acalib)
539 AmplitudeCalibration();
540
541 // Update DIM services if necessary
542 if (Status.Update.tv_sec - PrevStatus.Update.tv_sec > m->EventUpdateDelay) {
543
544 // Check if trigger cells resonable (to trace FAD 'double signal' bug)
545 int Diff = abs((*max_element(Status.TriggerCell,Status.TriggerCell+4) - *min_element(Status.TriggerCell,Status.TriggerCell+4)));
546 if (Diff > 20 && Diff < 1000) {
547 SetStatus("Warning: Trigger cell mismatch board %s, cells are %d %d %d %d", Name, Status.TriggerCell[0], Status.TriggerCell[1], Status.TriggerCell[2], Status.TriggerCell[3]);
548 m->Message(m->WARN, "Trigger cell mismatch board %s, cells are %d %d %d %d", Name, Status.TriggerCell[0], Status.TriggerCell[1], Status.TriggerCell[2], Status.TriggerCell[3]);
549 }
550
551 // Determine event rate
552 Status.Rate =
553 Count / (double(Status.Update.tv_sec-PrevStatus.Update.tv_sec) + (Status.Update.tv_usec-PrevStatus.Update.tv_usec)/1000000.0);
554 Count = 0;
555
556 if (PrevStatus.Frequency != Status.Frequency) DIM_Frequency->updateService();
557 if (PrevStatus.TriggerNum != Status.TriggerNum) DIM_TriggerNum->updateService();
558 if (PrevStatus.BoardTime != Status.BoardTime) DIM_BoardTime->updateService();
559 if (PrevStatus.Rate != Status.Rate) DIM_Rate->updateService();
560
561 if (memcmp(PrevStatus.Lock, Status.Lock, sizeof(Status.Lock)) != 0) {
562 DIM_Lock->updateService(Status.Lock, sizeof(Status.Lock));
563 }
564 if (memcmp(PrevStatus.Temp, Status.Temp, sizeof(Status.Temp)) != 0) {
565 DIM_Temp->updateService(Status.Temp, sizeof(Status.Temp));
566 }
567 if (memcmp(PrevStatus.DAC, Status.DAC, sizeof(Status.DAC)) != 0) {
568 DIM_DAC->updateService(Status.DAC, sizeof(Status.DAC));
569 }
570 if (memcmp(PrevStatus.ROI, Status.ROI, sizeof(Status.ROI)) != 0) {
571 DIM_ROI->updateService(Status.ROI, sizeof(Status.ROI));
572 }
573 if (PrevStatus.BoardID != Status.BoardID) {
574 DIM_ID->updateService(&Status.BoardID, sizeof(Status.BoardID));
575 }
576
577 PrevStatus = Status;
578 }
579
580 // Inform event thread of new data
581 string Message = string("EVENT")+Name+"\n";
582 if (write(m->Pipe[1], Message.data(), Message.size()) == -1) {
583 m->Message(m->ERROR, "write() to Pipe[1] failed in class FADBoard (%s)", strerror(errno));
584 break;
585 }
586 }
587 else SetStatus("End package flag incorrect, removing corrupt event");
588
589 // Remove event data from internal buffer
590 memmove(Buffer, Buffer+Length, Pos-Length);
591 Pos = Pos-Length;
592 } // while()
593
594 // Set inactive and close socket descriptor
595 Active = false;
596
597 if (close(Socket) == -1) {
598 m->Message(m->ERROR, "Could not close socket descriptor for board %s (%s)", Name, strerror(errno));
599 }
600
601}
602
603//
604// Install cleanup handler and launch read thread inside class
605//
606void FADBoard::LaunchThread(class FADBoard *m) {
607
608 pthread_cleanup_push((void (*)(void *)) FADBoard::ThreadCleanup, (void *) m);
609 m->ReadLoop();
610 pthread_cleanup_pop(0);
611}
612
613
614//
615// Set status message
616//
617void FADBoard::SetStatus(const char *Format, ...) {
618
619 int Ret;
620
621 // Assemble message
622 va_list ArgumentPointer;
623 va_start(ArgumentPointer, Format);
624 Lock();
625 Ret = vsnprintf(Status.Message, sizeof(Status.Message), Format, ArgumentPointer);
626 Unlock();
627 va_end(ArgumentPointer);
628
629 if (Ret == -1) m->Message(m->FATAL, "snprintf() in FADBoard::SetStatus() failed (%s)", strerror(errno));
630
631 // Update status service
632 DIM_Status->updateService(Status.Message);
633}
634
635
636//
637// Lock and unlock mutex
638//
639void FADBoard::Lock() {
640
641 int Ret;
642
643 if ((Ret = pthread_mutex_lock(&Mutex)) != 0) {
644 m->Message(m->FATAL, "pthread_mutex_lock() failed in class FADBoard (%s)", strerror(Ret));
645 }
646}
647
648void FADBoard::Unlock() {
649
650 int Ret;
651
652 if ((Ret = pthread_mutex_unlock(&Mutex)) != 0) {
653 m->Message(m->FATAL, "pthread_mutex_unlock() failed in class FADBoard (%s)", strerror(Ret));
654 }
655}
656
657// Ensure that mutex is unlocked when before cancelling thread
658void FADBoard::ThreadCleanup(class FADBoard *This) {
659
660 int Ret;
661
662 if ((Ret = pthread_mutex_trylock(&This->Mutex)) != 0) {
663 if (Ret != EBUSY) This->m->Message(This->m->FATAL, "pthread_mutex_trylock() failed in FADBoard::ThreadCleanup (%s)", strerror(Ret));
664 }
665 This->Unlock();
666}
667
668//
669// Open other sockets
670//
671// Error reporting is limited as this function is expected to be removed when firmware allows single socket
672//
673void FADBoard::threadHandler() {
674
675 int List[] = {31920, 31921, 31922, 31923, 31924, 31925, 31926};
676 int Socket[sizeof(List)/sizeof(int)], MaxSocketNum, Ret;
677 fd_set DescriptorList;
678 char Buffer[1000000];
679
680 // Resolve hostname
681 struct hostent *Host = gethostbyname(Name);
682 if (Host == 0) return;
683
684 // Connect to server
685 struct sockaddr_in SocketAddress;
686 SocketAddress.sin_family = PF_INET;
687 SocketAddress.sin_addr = *(struct in_addr*) Host->h_addr;
688
689 for (unsigned int i=0; i<sizeof(List)/sizeof(int); i++) {
690 // Open socket descriptor
691 if ((Socket[i] = socket(PF_INET, SOCK_STREAM, 0)) == -1) {
692 m->Message(m->ERROR, "OtherSockets: Could not open socket for port %d (%s)\n", List[i], strerror(errno));
693 return;
694 }
695 MaxSocketNum = *max_element(Socket, Socket+sizeof(List)/sizeof(int));
696
697 // Connect to server
698 SocketAddress.sin_port = htons((unsigned short) List[i]);
699 if (connect(Socket[i], (struct sockaddr *) &SocketAddress, sizeof(SocketAddress)) == -1) return;
700 }
701
702 while(true) {
703 // Wait for data from sockets
704 FD_ZERO(&DescriptorList);
705 for (unsigned int i=0; i<sizeof(List)/sizeof(int); i++) FD_SET(Socket[i], &DescriptorList);
706 if (select(MaxSocketNum+1, &DescriptorList, NULL, NULL, NULL) == -1) {
707 m->Message(m->ERROR, "OtherSockets: Error with select() (%s)\n", strerror(errno));
708 break;
709 }
710
711 // Data from socket
712 for (unsigned int i=0; i<sizeof(List)/sizeof(int); i++) if (FD_ISSET(Socket[i], &DescriptorList)) {
713 Ret = read(Socket[i], Buffer, sizeof(Buffer));
714 if (Ret == -1) m->Message(m->ERROR, "OtherSockets: Error reading from port %d (%s)\n", List[i], strerror(errno));
715 }
716 }
717
718 // Close all sockets
719 for (unsigned int i=0; i<sizeof(List)/sizeof(int); i++) {
720 if ((Socket[i] != -1) && (close(Socket[i]) == -1)) {
721 m->Message(m->ERROR, "OtherSockets: Could not close socket of port %d (%s)", List[i], strerror(errno));
722 }
723 }
724}
725
726
727
728//
729// Dynamic range determination
730//
731void FADBoard::DynamicRange() {
732
733 #if 0
734 vector<unsigned short> ROICmd;
735 unsigned short DACCmd[] = {htons(CMD_Write | (BADDR_DAC + 1)), 0, htons(CMD_Write | (BADDR_DAC + 2)), 0, htons(CMD_Write | (BADDR_DAC + 3)), 0, htons(CMD_Execute) };
736 string Message = string("ACALIBDONE")+Name+"\n";
737
738 switch (StateDR) {
739 // ====== Check if dynamic range measurement should start and initialise =====
740 case standbye:
741 if (m->Mode != m->dynrange) break;
742
743 // Save initial board status, and set all ROIs to 1024
744 InitialStatus = GetStatus();
745
746 for (unsigned int i=0; i<NChips*NChannels; i++) {
747 ROICmd.push_back(htons(CMD_Write | (BADDR_ROI + i)));
748 ROICmd.push_back(htons(NBins));
749 }
750 ROICmd.push_back(htons(CMD_Execute));
751 Send(&ROICmd[0], ROICmd.size()*sizeof(unsigned short));
752
753 // Start measurement
754 DAC_DR = 0;
755 StateDR = setdac;
756 SetStatus("Starting dynamic range measurement");
757 break;
758
759 // ====== Set calibration DAC =====
760 case setdac:
761 // Check for stopping
762 if (m->Mode != m->dynrange) {
763 StateDR = cleanup;
764 break;
765 }
766
767 if (DAC_DR > 66000) {
768 StateDR = cleanup;
769 break;
770 }
771
772 // Set new DAC values
773 DACCmd[1] = htons(DAC_DR);
774 DACCmd[3] = htons(DAC_DR);
775 DACCmd[5] = htons(DAC_DR);
776 Send(DACCmd, sizeof(DACCmd));
777
778 StateDR = measure;
779 break;
780
781 // ====== Determine mean and sigma =====
782 case measure:
783 // Check for stopping
784 if (m->Mode != m->dynrange) {
785 StateDR = cleanup;
786 break;
787 }
788
789 Mean = 0;
790 Sigma = 0;
791 for (unsigned int Chip=0; Chip<NChips; Chip++) {
792 for (unsigned int Chan=0; Chan<NChannels; Chan++) {
793 for (int i=0; i<Status.ROI[Chip][Chan]; i++) {
794 Mean += Data[Chip][Chan][i];
795 Sigma += Data[Chip][Chan][i]*Data[Chip][Chan][i];
796 }
797 Mean /= Status.ROI[Chip][Chan];
798 Sigma = sqrt(Status.ROI[Chip][Chan]/(Status.ROI[Chip][Chan]-1)*(Sigma/Status.ROI[Chip][Chan]-Mean*Mean));
799 }
800 }
801
802 DAC_DR += 1000;
803
804 StateDR = setdac;
805 break;
806
807 // ====== Write back original ROI and DAC settings =====
808 case cleanup:
809 // ROI values
810 ROICmd.clear();
811 for (unsigned int i=0; i<NChips*NChannels; i++) {
812 ROICmd.push_back(htons(CMD_Write | (BADDR_ROI + i)));
813 ROICmd.push_back(htons(InitialStatus.ROI[i/NChannels][i%NChannels]));
814 }
815 ROICmd.push_back(htons(CMD_Execute));
816 Send(&ROICmd[0], ROICmd.size()*sizeof(unsigned short));
817
818 // DAC values
819 DACCmd[1] = htons(InitialStatus.DAC[1]);
820 DACCmd[3] = htons(InitialStatus.DAC[2]);
821 DACCmd[5] = htons(InitialStatus.DAC[3]);
822 Send(DACCmd, sizeof(DACCmd));
823
824 StateDR = wait;
825 break;
826
827 // ====== Wait for Mode not being idle =====
828 case wait:
829 if (m->Mode == m->idle) StateDR = standbye;
830 break;
831 }
832 #endif
833}
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