plugins/monitoring/CDC_expert/JEventProcessor_CDC

Bug Summary

File:	plugins/monitoring/CDC_expert/JEventProcessor_CDC_expert.cc
Location:	line 452, column 5
Description:	Value stored to 'total_ped' is never read

Annotated Source Code

1	// $Id$
2	//
3	// File: JEventProcessor_CDC_expert.cc
4	// Created: Wed Oct 22
5	// Creator: Naomi Jarvis
6
7
8	#include <stdint.h>
9	#include <vector>
10
11	#include <TMath.h>
12
13
14	#include "JEventProcessor_CDC_expert.h"
15	#include <JANA/JApplication.h>
16
17
18	using namespace std;
19	using namespace jana;
20
21
22	#include "CDC/DCDCHit.h"
23	#include "CDC/DCDCDigiHit.h"
24	#include "DAQ/Df125PulseIntegral.h"
25	#include "DAQ/Df125PulsePedestal.h"
26	#include "DAQ/Df125WindowRawData.h"
27	#include "DAQ/Df125CDCPulse.h"
28
29	#include <TDirectory.h>
30	#include <TH2.h>
31	#include <TH1.h>
32
33
34	// root hist pointers
35
36
37
38	static TH1D *cdc_e = NULL__null;
39	static TH2D *cdc_e_vs_n = NULL__null;
40
41	static TH1D *cdc_t = NULL__null;
42	static TH2D *cdc_t_vs_n = NULL__null;
43
44
45	static TH2D *cdc_e_ring[29];
46	static TH2D *cdc_t_ring[29];
47
48
49	static TH2D *cdc_e_vs_t;
50	static TH2D *cdc_e_vs_t_ring[29];
51
52	static TH2I *cdc_raw_int_vs_t;
53	static TH2I *cdc_raw_int_vs_t_ring[29];
54
55
56	static TH2I *cdc_o_badt;
57	static TH2I *cdc_o_overflow;
58
59	static TH2I *cdc_ped_ring[29];
60	static TH1I *cdc_ped_badt;
61	static TH1I *cdc_ped_overflow;
62
63	static TH2I *cdc_windata_ped_ring[29];
64
65	static TH2I *cdc_windata_ped_roc25;
66	static TH2I *cdc_windata_ped_roc26;
67	static TH2I *cdc_windata_ped_roc27;
68	static TH2I *cdc_windata_ped_roc28;
69
70	static TH2I *cdc_raw_t_ring[29];
71	static TH1I *cdc_raw_t_badt;
72	static TH1I *cdc_raw_t_overflow;
73
74	static TH2I *cdc_raw_amp_ring[29];
75	static TH1I *cdc_raw_amp_badt;
76	static TH1I *cdc_raw_amp_overflow;
77
78
79
80	static TH2I *cdc_raw_intpp_ring[29];
81	static TH1I *cdc_raw_intpp_badt;
82	static TH1I *cdc_raw_intpp_overflow;
83
84
85
86	static TH2I *cdc_raw_int_ring[29];
87	static TH1I *cdc_raw_int_badt;
88	static TH1I *cdc_raw_int_overflow;
89
90
91
92
93	//----------------------------------------------------------------------------------
94
95
96	// Routine used to create our JEventProcessor
97	extern "C"{
98	void InitPlugin(JApplication *app){
99	InitJANAPlugin(app);
100	app->AddProcessor(new JEventProcessor_CDC_expert());
101	}
102	}
103
104
105	//----------------------------------------------------------------------------------
106
107
108	JEventProcessor_CDC_expert::JEventProcessor_CDC_expert() {
109	}
110
111
112	//----------------------------------------------------------------------------------
113
114
115	JEventProcessor_CDC_expert::~JEventProcessor_CDC_expert() {
116	}
117
118
119	//----------------------------------------------------------------------------------
120
121	jerror_t JEventProcessor_CDC_expert::init(void) {
122
123	// I moved all the histogram setup into the brun so that I can use different
124	// scales for the later runs using the new firmware. NSJ.
125
126	// japp->RootWriteLock(); //ACQUIRE ROOT LOCK!!
127	// japp->RootUnLock(); //RELEASE ROOT LOCK!!
128
129
130	return NOERROR;
131	}
132
133
134	//----------------------------------------------------------------------------------
135
136
137	jerror_t JEventProcessor_CDC_expert::brun(JEventLoop *eventLoop, int32_t runnumber) {
138	// This is called whenever the run number changes
139
140
141
142	japp->RootWriteLock(); //ACQUIRE ROOT LOCK!!
143
144	// max values for histogram scales, modified fa250-format readout
145
146	// Int_t IMAX = 524288; //max for raw integral, fa250-format, 19 bits
147	Int_t IMAX = 400000; //max for raw integral
148	Int_t PMAX = 512; //max for pedestal, fa250-format max is 512
149	Int_t AMAX = 4096; //max for amplitude, fa250-format, 12 bits
150	Int_t RTMAX = 12000;
151	Int_t RTVSNMAX = 8192; //raw time vs straw histogram range ends at this value
152
153	Char_t rtunits[8] = "0.125ns"; //raw time is in units of sample/64 = ns/8
154
155	if (runnumber > 3675) { //new fa125 format firmware, from 11 Sept 2015
156
157	// raw quantities for read out (125 format) are
158	// time field max 2047 scaled x 1, units 0.8ns
159	// time qf field max 1
160	// overflow count field max 7
161	// pedestal field max 255 scaled x 1/4 initially
162	// max amplitude 9 bits, field max 511 scaled x 1/8
163	// integral field max 16383 scaled x 1/14
164
165
166	// max values for histogram scales, fa125-format readout
167
168	IMAX = 16384; //max for raw integral, fa125-format, 14 bits
169	PMAX = 256; //max for pedestal, fa125-format, 8 bits
170	AMAX = 512; //max for amplitude, fa125-format, 9 bits
171	RTMAX = 2048; //max for raw time, fa125-format, 11 bits
172	RTVSNMAX = 1024; //raw time vs straw histogram range ends at this value
173
174	sprintf(rtunits,"0.8ns"); //raw time is in units of sample/10 = 0.8ns
175
176	}
177
178
179	const Int_t EMAX = 21000; //max for E histograms, fC
180	// const Int_t EMAX = 21000000; //max for E histograms, fC
181	// E histograms filled with a_scalegains(integration-pedestal)
182
183	const Int_t TMAX = 2000; //max for t histograms, ns
184	// t histograms filled with t_scale*(raw-t - offset) + tmin
185
186
187	const Int_t NSTRAWS = 3522;
188	const Float_t HALF = 0.5;
189	const Float_t NSTRAWSPH = 3522.5;
190
191
192	// create root folder for cdc and cd to it, store main dir
193	TDirectory *main = gDirectory(TDirectory::CurrentDirectory());
194	gDirectory(TDirectory::CurrentDirectory())->mkdir("CDC_expert")->cd();
195
196
197
198	// book histograms
199
200	//number of straws in each ring, starts with 0 so that straws[1] is the number of straws in ring 1
201	const Int_t straws[29] = {0,42,42,54,54,66,66,80,80,93,93,106,106,123,123,135,135,146,146,158,158,170,170,182,182,197,197,209,209};
202
203
204	cdc_e = new TH1D("cdc_e","CDC charge (fC);charge (fC)",200,0,EMAX);
205	cdc_e_vs_n = new TH2D("cdc_e_vs_n","CDC charge (fC) vs straw number;straw;charge (fC)",NSTRAWS,HALF,NSTRAWSPH,100,0,EMAX);
206
207	cdc_e_vs_t = new TH2D("cdc_e_vs_t","CDC charge (fC) vs time (ns);time (ns);charge (fC)",150,-250,TMAX,100,0,EMAX);
208
209
210	cdc_t = new TH1D("cdc_t","CDC time (ns);time (ns)",300,-250,TMAX);
211	cdc_t_vs_n = new TH2D("cdc_t_vs_n","CDC time (ns) vs straw number;straw;time (ns)",NSTRAWS,HALF,NSTRAWSPH,150,-250,TMAX);
212
213
214
215
216	cdc_raw_int_vs_t = new TH2I("cdc_raw_int_vs_t",Form("CDC integral (ADC units), pedestal subtracted, vs raw time (units of %s);time (%s);integral, pedestal subtracted (ADC units)",rtunits,rtunits),(Int_t)256,0,RTVSNMAX,100,0,IMAX);
217
218
219
220	cdc_windata_ped_roc25 = new TH2I("cdc_windata_ped_roc25","CDC pedestal (ADC units) from raw window data vs slot100+channel, ROC 25;slot100 + channel;pedestal",1600,200+HALF,1800+HALF,(Int_t)PMAX/4,0,PMAX);
221	cdc_windata_ped_roc26 = new TH2I("cdc_windata_ped_roc26","CDC pedestal (ADC units) from raw window data vs slot100+channel, ROC 26;slot100 + channel;pedestal",1600,200+HALF,1800+HALF,(Int_t)PMAX/4,0,PMAX);
222	cdc_windata_ped_roc27 = new TH2I("cdc_windata_ped_roc27","CDC pedestal (ADC units) from raw window data vs slot100+channel, ROC 27;slot100 + channel;pedestal",1600,200+HALF,1800+HALF,(Int_t)PMAX/4,0,PMAX);
223	cdc_windata_ped_roc28 = new TH2I("cdc_windata_ped_roc28","CDC pedestal (ADC units) from raw window data vs slot100+channel, ROC 28;slot100 + channel;pedestal",1600,200+HALF,1800+HALF,(Int_t)PMAX/4,0,PMAX);
224
225
226
227	if (runnumber > 3675) { //new fa125 format firmware, from 11 Sept 2015
228
229	gDirectory(TDirectory::CurrentDirectory())->mkdir("bad_t","CDC Bad time flagged")->cd();
230
231	cdc_o_badt = new TH2I("cdc_o_badt","CDC occupancy by straw,ring, events with bad time flagged;straw;ring",209,0.5,209.5,28,0.5,28.5);
232	cdc_ped_badt = new TH1I("cdc_ped_badt","CDC pedestal, events with bad time flagged;straw;pedestal",256,0,PMAX);
233	cdc_raw_t_badt = new TH1I("cdc_raw_t_badt",Form("CDC raw time (units of %s), events with bad time flagged;straw;raw time (%s)",rtunits,rtunits),256,0,RTMAX);
234	cdc_raw_amp_badt = new TH1I("cdc_raw_amp_badt","CDC amplitude (ADC units), events with bad time flagged;ADC units",256,0,AMAX);
235	cdc_raw_int_badt = new TH1I("cdc_raw_intpp_badt","CDC integral (ADC units), pedestal subtracted, events with bad time flagged;ADC units",100,0,IMAX);
236	cdc_raw_intpp_badt = new TH1I("cdc_raw_intpp_badt","CDC integral (ADC units), including pedestal, events with bad time flagged;ADC units",100,0,IMAX);
237
238	gDirectory(TDirectory::CurrentDirectory())->cd("../");
239	gDirectory(TDirectory::CurrentDirectory())->mkdir("overflows","CDC overflow flagged")->cd();
240
241	cdc_o_overflow = new TH2I("cdc_o_overflow","CDC overflow occupancy by straw,ring;straw;ring",209,0.5,209.5,28,0.5,28.5);
242	cdc_ped_overflow = new TH1I("cdc_ped_overflow","CDC pedestal, events with ADC overflow;pedestal",256,0,PMAX);
243	cdc_raw_t_overflow = new TH1I("cdc_raw_t_overflow",Form("CDC raw time (units of %s), events with ADC overflow;raw time (%s)",rtunits,rtunits),256,0,RTMAX);
244	cdc_raw_amp_overflow = new TH1I("cdc_raw_amp_overflow","CDC amplitude (ADC units), events with ADC overflow;ADC units",256,0,AMAX);
245	cdc_raw_int_overflow = new TH1I("cdc_raw_intpp_overflow","CDC integral (ADC units), pedestal subtracted, events with ADC overflow;ADC units",100,0,IMAX);
246	cdc_raw_intpp_overflow = new TH1I("cdc_raw_intpp_overflow","CDC integral (ADC units), including pedestal, events with ADC overflow;ADC units",100,0,IMAX);
247
248	gDirectory(TDirectory::CurrentDirectory())->cd("../");
249
250	}
251
252	Int_t i;
253
254
255	gDirectory(TDirectory::CurrentDirectory())->mkdir("rings_e_vs_t","CDC rings: charge vs time")->cd();
256
257	for (i=1; i<29; i++) {
258	cdc_e_vs_t_ring[i] = new TH2D(Form("cdc_e_vs_t_ring[%i]",i),"CDC charge (fC) vs time (ns);time (ns);charge (fC)",150,0,TMAX,100,0,EMAX);
259	}
260
261	gDirectory(TDirectory::CurrentDirectory())->cd("../");
262
263
264	gDirectory(TDirectory::CurrentDirectory())->mkdir("rings_int_vs_raw_t","CDC rings: integral vs raw time (pedestal subtracted)")->cd();
265
266	for (i=1; i<29; i++) {
267	cdc_raw_int_vs_t_ring[i] = new TH2I(Form("cdc_raw_int_vs_t_ring[%i]",i),Form("CDC integral (ADC units), pedestal subtracted, vs raw time (%s);raw time (%s);integral, pedestal subtracted (ADC units)",rtunits,rtunits),256,0,RTVSNMAX,100,0,IMAX);
268
269	}
270
271	gDirectory(TDirectory::CurrentDirectory())->cd("../");
272
273
274
275	gDirectory(TDirectory::CurrentDirectory())->mkdir("rings_e","CDC rings: charge vs straw")->cd();
276
277	for (i=1; i<29; i++) {
278	cdc_e_ring[i] = new TH2D(Form("cdc_e_ring[%i]",i),Form("CDC charge (fC), ring %i;straw;charge (fC)",i),straws[i],HALF,straws[i]+HALF,100,0,EMAX);
279	}
280
281	gDirectory(TDirectory::CurrentDirectory())->cd("../");
282	gDirectory(TDirectory::CurrentDirectory())->mkdir("rings__t","CDC rings: time vs straw")->cd();
283
284	for (i=1; i<29; i++) {
285	cdc_t_ring[i] = new TH2D(Form("cdc_t_ring[%i]",i),Form("CDC time (ns), ring %i;straw;time (ns)",i),straws[i],HALF,straws[i]+HALF,150,0,TMAX);
286	}
287
288
289	gDirectory(TDirectory::CurrentDirectory())->cd("../");
290	gDirectory(TDirectory::CurrentDirectory())->mkdir("rings_pedestal","CDC rings: pedestal vs straw")->cd();
291
292	for (i=1; i<29; i++) {
293	cdc_ped_ring[i] = new TH2I(Form("cdc_ped_ring[%i]",i),Form("CDC pedestal (ADC units), ring %i;straw;pedestal",i),straws[i],HALF,straws[i]+HALF,(Int_t)PMAX/2,0,PMAX);
294	}
295
296	gDirectory(TDirectory::CurrentDirectory())->cd("../");
297	gDirectory(TDirectory::CurrentDirectory())->mkdir("rings_windata_pedestal","CDC rings: pedestal from raw window data vs straw")->cd();
298
299	for (i=1; i<29; i++) {
300	cdc_windata_ped_ring[i] = new TH2I(Form("cdc_windata_ped_ring[%i]",i),Form("CDC pedestal (ADC units) from raw window data, ring %i;straw;pedestal",i),straws[i],HALF,straws[i]+HALF,(Int_t)PMAX/2,0,PMAX);
301	}
302
303
304
305
306
307	gDirectory(TDirectory::CurrentDirectory())->cd("../");
308	gDirectory(TDirectory::CurrentDirectory())->mkdir("rings_raw_t","CDC rings: raw time vs straw")->cd();
309
310	for (i=1; i<29; i++) {
311	cdc_raw_t_ring[i] = new TH2I(Form("cdc_raw_t_ring[%i]",i),Form("CDC raw time (units of %s), ring %i;straw;raw time (%s)",rtunits,i,rtunits),straws[i],HALF,straws[i]+HALF,256,0,RTVSNMAX);
312	}
313
314
315	gDirectory(TDirectory::CurrentDirectory())->cd("../");
316	gDirectory(TDirectory::CurrentDirectory())->mkdir("rings_raw_amp","CDC rings: amplitude")->cd();
317
318	for (i=1; i<29; i++) {
319	cdc_raw_amp_ring[i] = new TH2I(Form("cdc_raw_amp_ring[%i]",i),Form("CDC amplitude (ADC units), ring %i",i),straws[i],HALF,straws[i]+HALF,256,0,AMAX);
320	}
321
322
323
324	gDirectory(TDirectory::CurrentDirectory())->cd("../");
325	gDirectory(TDirectory::CurrentDirectory())->mkdir("rings_raw_integral","CDC rings: integral vs straw (pedestal subtracted)")->cd();
326
327	for (i=1; i<29; i++) {
328	cdc_raw_int_ring[i] = new TH2I(Form("cdc_raw_int_ring[%i]",i),Form("CDC integral (ADC units), pedestal subtracted, ring %i",i),straws[i],HALF,straws[i]+HALF,100,0,IMAX);
329	}
330
331
332	gDirectory(TDirectory::CurrentDirectory())->cd("../");
333	gDirectory(TDirectory::CurrentDirectory())->mkdir("rings_raw_integral_incl_ped","CDC rings: integral vs straw (including pedestal)")->cd();
334
335	for (i=1; i<29; i++) {
336	cdc_raw_intpp_ring[i] = new TH2I(Form("cdc_raw_intpp_ring[%i]",i),Form("CDC integral (ADC units), including pedestal, ring %i",i),straws[i],HALF,straws[i]+HALF,100,0,IMAX);
337	}
338
339
340
341	// back to main dir
342	main->cd();
343
344	japp->RootUnLock(); //RELEASE ROOT LOCK!!
345
346	return NOERROR;
347	}
348
349
350	//----------------------------------------------------------------------------------
351
352
353	jerror_t JEventProcessor_CDC_expert::evnt(JEventLoop *eventLoop, uint64_t eventnumber) {
354	// This is called for every event. Use of common resources like writing
355	// to a file or filling a histogram should be mutex protected. Using
356	// loop-Get(...) to get reconstructed objects (and thereby activating the
357	// reconstruction algorithm) should be done outside of any mutex lock
358	// since multiple threads may call this method at the same time.
359
360	float q,t; // dcdchits quantities charge, time
361
362	uint32_t qf,ocount; // time quality factor and overflow count from new firmware
363	uint32_t tr,p,a; // dcdcdigihits raw quantities: time, pedestal, amplitude, quality factor, overflow count
364	uint32_t integral; // dcdcdigihits integral, includes pedestal
365	uint32_t integ; // dcdcdigihits integral minus pedestal
366
367	uint16_t ring,straw; // ring and straw numbers from either dcdchits or dcdcdigihits
368	uint16_t n; // straw number, 1 to 3522
369
370	Bool_t PED_SUB; // if this is false, integration window info is missing, so don't plot integrals
371
372	uint32_t total_ped; //total pedestal during integration period
373	uint32_t nsamples_integral; ///< number of samples used in integral
374	uint32_t nsamples_pedestal; ///< number of samples used in pedestal
375
376	uint32_t rocid;
377	uint32_t slot;
378	uint32_t channel;
379
380
381	const uint16_t NPEDSAMPLES=16;
382
383	//add extra 0 at front to use offset[1] for ring 1
384	int straw_offset[29] = {0,0,42,84,138,192,258,324,404,484,577,670,776,882,1005,1128,1263,1398,1544,1690,1848,2006,2176,2346,2528,2710,2907,3104,3313};
385
386
387	//first set of histograms is for dcdchits, these are t and q after calibration
388	//second set is for dcdcdigihits, these are the raw quantities
389
390	// get hit data for cdc
391	vector<const DCDCHit*> hits;
392	eventLoop->Get(hits);
393
394	// get raw data for cdc
395	vector<const DCDCDigiHit*> digihits;
396	eventLoop->Get(digihits);
397
398	//get WRD data for new format (until it is linked to CDCPulse)
399	vector<const Df125WindowRawData*> wrdvector;
400	eventLoop->Get(wrdvector);
401
402	japp->RootWriteLock(); //ACQUIRE ROOT LOCK!!
403
404
405	for(uint32_t i=0; i<hits.size(); i++) {
406
407	const DCDCHit *hit = hits[i]; // avoids having to use the uglier “cdcdigihits[0]->” syntax
408
409	if(hit->q>0.0) {
410
411	q = hit->q; // in fC
412	t = hit->t; // in nanoseconds
413	ring = hit->ring;
414	straw = hit->straw;
415
416	n = straw_offset[ring] + straw;
417
418	if (q > 0.0) {
419	cdc_e->Fill(q);
420	cdc_e_vs_n->Fill(n,q);
421	}
422
423	//if (t > 0.0) {
424	cdc_t->Fill(t);
425	cdc_t_vs_n->Fill(n,t);
426	//}
427
428	cdc_e_vs_t->Fill(t,q);
429	cdc_e_vs_t_ring[ring]->Fill(t,q);
430
431	cdc_e_ring[ring]->Fill(straw,q);
432	cdc_t_ring[ring]->Fill(straw,t);
433	}
434	}
435
436
437	for(uint32_t i=0; i<digihits.size(); i++) {
438
439	const DCDCDigiHit *digihit = digihits[i]; // avoids having to use the uglier “cdcdigihits[0]->” syntax
440
441	// Get pointers to the underlying objects of interest
442	const Df125PulseIntegral *pi = NULL__null;
443	const Df125PulsePedestal *pp = NULL__null;
444	const Df125WindowRawData *windat = NULL__null;
445	const Df125CDCPulse *cp = NULL__null;
446
447
448	vector<uint16_t> samples;
449	uint32_t winped=0;
450
451	PED_SUB = kFALSE; //set this to true when we find the config params
452	total_ped = 0;
	Value stored to 'total_ped' is never read
453
454	rocid = 0;
455	slot = 0;
456	channel = 0;
457	qf = 0;
458	ocount = 0;
459	a = 0;
460
461	//old firmware uses Df125PulseIntegral and Df125PulsePedestal
462	digihit->GetSingle(pi);
463	if (pi) {
464	rocid = pi->rocid;
465	slot = pi->slot;
466	channel = pi->channel;
467	pi->GetSingle(windat);
468	} else if (i < (uint32_t)wrdvector.size()) {
469	windat = wrdvector[i];
470	}
471
472	nsamples_integral = pi ? pi->nsamples_integral : 0;
473	nsamples_pedestal = pi ? pi->nsamples_pedestal : 0;
474
475	if ((nsamples_integral > 0) && (nsamples_pedestal > 0)) PED_SUB = kTRUE;
476
477	digihit->GetSingle(pp);
478	if(pp) a = pp->pulse_peak;
479
480	//new firmware uses Df125CDCPulseData
481	digihit->GetSingle(cp);
482	if (cp) {
483	rocid = cp->rocid;
484	slot = cp->slot;
485	channel = cp->channel;
486	a = cp->first_max_amp;
487	qf = cp->time_quality_bit;
488	ocount = cp->overflow_count;
489	}
490
491
492
493	if (windat) {
494
495	if (windat->samples.size()>=NPEDSAMPLES) {
496
497	winped = 0;
498
499	for (uint16_t j=0; j<NPEDSAMPLES; j++) winped += (uint32_t)windat->samples[j];
500
501	winped = (uint32_t)winped/16.0;
502
503	if (winped > 0) {
504
505	if (rocid == 25) cdc_windata_ped_roc25->Fill(100*slot + channel,winped);
506	if (rocid == 26) cdc_windata_ped_roc26->Fill(100*slot + channel,winped);
507	if (rocid == 27) cdc_windata_ped_roc27->Fill(100*slot + channel,winped);
508	if (rocid == 28) cdc_windata_ped_roc28->Fill(100*slot + channel,winped);
509
510	}
511
512	}//sample size
513	} //windat
514
515
516
517
518	if((digihit->pulse_integral>0)\|\|(digihit->pulse_time>0)) {
519
520	ring = digihit->ring;
521	straw = digihit->straw;
522
523	p = digihit->pedestal;
524	tr = digihit->pulse_time; // raw time in 0.8 ns units
525	integral = digihit->pulse_integral; // pulse integral in fadc units, pedestal not subtracted
526
527	integ = 0;
528
529	//ok to use p for pedestal subtraction here because if fa250 algo fails with p=0, integral=0 and amplitude=0 also
530
531	if (PED_SUB) {
532	total_ped = p*nsamples_integral/nsamples_pedestal;
533	integ = integral - total_ped;
534	}
535
536	// straw_offset[ring] + straw;
537
538	if (PED_SUB) cdc_raw_int_vs_t->Fill(tr,integ);
539	if (PED_SUB) cdc_raw_int_vs_t_ring[ring]->Fill(tr,integ);
540
541	cdc_ped_ring[ring]->Fill(straw,p);
542	cdc_raw_t_ring[ring]->Fill(straw,tr);
543	cdc_raw_amp_ring[ring]->Fill(straw,a); //no ped subtraction in case scaling factors differ
544	if (PED_SUB) cdc_raw_int_ring[ring]->Fill(straw,integ);
545	cdc_raw_intpp_ring[ring]->Fill(straw,integral);
546	if (winped) cdc_windata_ped_ring[ring]->Fill(straw,winped);
547
548
549	if (cp) {
550	if (qf==1) { // rough time flag is set
551	cdc_o_badt->Fill(straw,ring);
552	cdc_ped_badt->Fill(p);
553	cdc_raw_t_badt->Fill(tr);
554	cdc_raw_amp_badt->Fill(a);
555	if (PED_SUB) cdc_raw_int_badt->Fill(integ);
556	cdc_raw_intpp_badt->Fill(integral);
557	}
558
559
560	if (ocount>0) { // overflow samples present
561	cdc_o_overflow->Fill(straw,ring);
562	cdc_ped_overflow->Fill(p);
563	cdc_raw_t_overflow->Fill(tr);
564	cdc_raw_amp_overflow->Fill(a);
565	if (PED_SUB) cdc_raw_int_overflow->Fill(integ);
566	cdc_raw_intpp_overflow->Fill(integral);
567	}
568	}
569
570
571	}
572
573	}
574
575
576	japp->RootUnLock(); //RELEASE ROOT LOCK!!
577
578
579	return NOERROR;
580	}
581
582
583	//----------------------------------------------------------------------------------
584
585
586	jerror_t JEventProcessor_CDC_expert::erun(void) {
587	// This is called whenever the run number changes, before it is
588	// changed to give you a chance to clean up before processing
589	// events from the next run number.
590	return NOERROR;
591	}
592
593
594	//----------------------------------------------------------------------------------
595
596
597	jerror_t JEventProcessor_CDC_expert::fini(void) {
598	// Called before program exit after event processing is finished.
599	return NOERROR;
600	}
601
602
603	//----------------------------------------------------------------------------------
604	//----------------------------------------------------------------------------------