Int_t THaScaler::LoadData(const THaEvData& evdata) {
// Load data from THaEvData object. Return of 0 is ok.
// Note: GetEvBuffer is no faster than evdata.Get...
static int ldebug = 0;
static Int_t data[2*SCAL_NUMBANK*SCAL_NUMCHAN+100];
new_load = kFALSE;
Int_t nlen = 0;
if (evstr_type == 1) { // data in the event stream (physics triggers)
if (!evdata.IsPhysicsTrigger()) return 0;
nlen = evdata.GetRocLength(crate);
if (nlen == 0) return 0;
} else { // traditional scaler event type 140
if (evdata.GetEvType() != 140) return 0;
nlen = evdata.GetEvLength();
}
if (ldebug) cout << "Loading evdata, bank = "<<bankgroup<<" "<<evstr_type<<" "<<crate<<" "<<evdata.GetEvType()<<" "<<nlen<<endl;
Int_t maxlen = sizeof(data)/sizeof(Int_t);
if (nlen > maxlen) nlen = maxlen;
for (Int_t i = 0; i < nlen; i++) {
if (evstr_type == 1) {
data[i] = evdata.GetRawData(crate, i);
} else {
data[i] = evdata.GetRawData(i);
}
if (ldebug) {
cout << " data["<<i<<"] = "<<data[i]<<" =0x"<<hex<<data[i]<<dec<<endl;
}
}
ExtractRaw(data,nlen);
return 0;
};
int main(int argc, char* argv[])
{
int debug=0;
if (argc > 1) debug=1;
// CODA file "snippet.dat" is a disk file of CODA data.
THaCodaFile datafile; // We could also open the data using a
// different constructor:
// THaCodaFile datafile("snippet.dat");
TString filename("snippet.dat");
if (datafile.codaOpen(filename) != S_SUCCESS) {
cout << "ERROR: Cannot open CODA data" << endl;
exit(0);
}
THaEvData *evdata = new THaCodaDecoder();
// Loop over events
int NUMEVT=100;
int ievent;
for (ievent=0; ievent<NUMEVT; ievent++) {
int status = datafile.codaRead();
if ( status != S_SUCCESS ) {
if ( status == EOF) {
cout << "This is normal end of file. Goodbye !" << endl;
} else {
cout << hex << "ERROR: codaRread status = " << status << endl;
}
goto Finish;
}
// load_evbuffer() must be called each event before you access evdata contents.
// If you use the version of load_evbuffer() shown here,
// evdata uses its private crate map (recommended).
// Alternatively you could use load_evbuffer(int* evbuffer, haCrateMap& map)
evdata->LoadEvent( datafile.getEvBuffer() );
cout << "\nEvent type " << dec << evdata->GetEvType() << endl;
cout << "Event number " << evdata->GetEvNum() << endl;
cout << "Event length " << evdata->GetEvLength() << endl;
if (evdata->IsPhysicsTrigger() ) { // triggers 1-14
cout << "Physics trigger " << endl;
}
if(evdata->IsScalerEvent()) cout << "Scaler `event' " << endl;
// Now we want data from a particular crate and slot.
// E.g. crates are 1,2,3,13,14,15 (roc numbers), Slots are 1,2,3...
// This is like what one might do in a detector decode() routine.
int crate = 1; // for example
int slot = 24;
// Here are raw 32-bit CODA words for this crate and slot
cout << "Raw Data Dump for crate "<<dec<<crate<<" slot "<<slot<<endl;
int hit;
for(hit=0; hit<evdata->GetNumRaw(crate,slot); hit++) {
cout<<dec<<"raw["<<hit<<"] = ";
cout<<hex<<evdata->GetRawData(crate,slot,hit)<<endl;
}
// You can alternatively let evdata print out the contents of a crate and slot:
evdata->PrintSlotData(crate,slot);
if (evdata->IsPhysicsTrigger()) {
// Below are interpreted data, device types are ADC, TDC, or scaler.
// One needs to know the channel number within the device
int channel = 7; // for example
cout << "Device type = ";
cout << evdata->DevType(crate,slot) << endl;
for (hit=0; hit<evdata->GetNumHits(crate,slot,channel); hit++) {
cout << "Channel " <<dec<<channel<<" hit # "<<hit<<" ";
cout << "data = " << evdata->GetData(crate,slot,channel,hit)<<endl;
}
// Helicity data
cout << "Helicity on left spectrometer "<<evdata->GetHelicity("left")<<endl;
cout << "Helicity on right spectrometer "<<evdata->GetHelicity("right")<<endl;
cout << "Helicity "<<evdata->GetHelicity()<<endl;
}
// Scalers: Although the getData methods works if you happen
// to know what crate & slot contain scaler data, here is
// another way to get scalers directly from evdata
for (slot=0; slot<5; slot++) {
cout << "\n scaler slot -> " << dec << slot << endl;;
for (int chan=0; chan<16; chan++) {
cout << "Scaler chan " << chan << " ";
cout << evdata->GetScaler("left",slot,chan);
cout << " " << evdata->GetScaler(7,slot,chan) << endl;
}
}
} // end of event loop
Finish:
cout<<"\nAll done; processed "<<dec<<ievent<<" events"<<endl;
}
//_____________________________________________________________________________
Int_t THaScintillator::Decode( const THaEvData& evdata )
{
// Decode scintillator data, correct TDC times and ADC amplitudes, and copy
// the data to the local data members.
// This implementation makes the following assumptions about the detector map:
// - The first half of the map entries corresponds to ADCs,
// the second half, to TDCs.
// - The first fNelem detector channels correspond to the PMTs on the
// right hand side, the next fNelem channels, to the left hand side.
// (Thus channel numbering for each module must be consecutive.)
// Loop over all modules defined for this detector
for( Int_t i = 0; i < fDetMap->GetSize(); i++ ) {
THaDetMap::Module* d = fDetMap->GetModule( i );
bool adc = ( d->model ? fDetMap->IsADC(d) : (i < fDetMap->GetSize()/2) );
// Loop over all channels that have a hit.
for( Int_t j = 0; j < evdata.GetNumChan( d->crate, d->slot ); j++) {
Int_t chan = evdata.GetNextChan( d->crate, d->slot, j );
if( chan < d->lo || chan > d->hi ) continue; // Not one of my channels
#ifdef WITH_DEBUG
Int_t nhit = evdata.GetNumHits(d->crate, d->slot, chan);
if( nhit > 1 )
if (d->model != 250)
Warning( Here("Decode"), "%d hits on %s channel %d/%d/%d",
nhit, adc ? "ADC" : "TDC", d->crate, d->slot, chan );
#endif
// Get the data. Scintillators are assumed to have only single hit (hit=0)
Int_t data = evdata.GetData( d->crate, d->slot, chan, 0 );
// Get the detector channel number, starting at 0
Int_t k = d->first + chan - d->lo - 1;
#ifdef WITH_DEBUG
if( k<0 || k>NDEST*fNelem ) {
// Indicates bad database
Warning( Here("Decode()"), "Illegal detector channel: %d", k );
continue;
}
// cout << "adc,j,k = " <<adc<<","<<j<< ","<<k<< endl;
#endif
// Copy the data to the local variables.
DataDest* dest = fDataDest + k/fNelem;
k = k % fNelem;
if( adc ) {
dest->adc[k] = static_cast<Double_t>( data );
dest->adc_p[k] = data - dest->ped[k];
dest->adc_c[k] = dest->adc_p[k] * dest->gain[k];
(*dest->nahit)++;
} else {
dest->tdc[k] = static_cast<Double_t>( data );
dest->tdc_c[k] = (data - dest->offset[k])*fTdc2T;
(*dest->nthit)++;
}
}
}
if ( fDebug > 3 ) {
printf("\n\nEvent %d Trigger %d Scintillator %s\n:",
evdata.GetEvNum(), evdata.GetEvType(), GetPrefix() );
printf(" paddle Left(TDC ADC ADC_p) Right(TDC ADC ADC_p)\n");
for ( int i=0; i<fNelem; i++ ) {
printf(" %2d %5.0f %5.0f %5.0f %5.0f %5.0f %5.0f\n",
i+1,fLT[i],fLA[i],fLA_p[i],fRT[i],fRA[i],fRA_p[i]);
}
}
return fLTNhit+fRTNhit;
}
int main(int argc, char* argv[]) {
int myroc, iev, nevents;
int trig, clkp, clkm, lastclkp, lastclkm;
Float_t time, sum, asy;
int found,index;
int len, data, status, nscaler, header;
int numread0, numread1, badread, i, jstat;
int ring_clock, ring_qrt, ring_helicity;
int ring_t3, ring_bcm, ring_l1a, ring_t1;
int prev_clock, prev_trig, prev_bcm, prev_l1a, prev_hel2;
int sum_clock, sum_t3, sum_bcm, sum_l1a;
int latest_clock, latest_trig, latest_bcm, latest_l1a;
int inquad, nrread, q1_helicity, helicity_now;
int ring_data[MAXRING], rloc;
string filename, bank, mybank;
if (argc < 2) {
cout << "Usage: " << argv[0]<<" file [nevents]" << endl;
cout << "where file = CODA file to analyze " << endl;
cout << "and nevents is the number of events you want (optional)"<<endl;
cout << "(default nevents = all of them)"<<endl;
return 1;
}
filename = argv[1];
mybank = "evgen";
myroc = 23;
nevents = 0;
if (argc >= 3) nevents = atoi(argv[3]);
cout << "bank "<<mybank<<" num events "<<nevents<<endl;
// Pedestals. Left, Right Arms. u1,u3,u10,d1,d3,d10
Float_t bcmpedL[NBCM] = { 188.2, 146.2, 271.6, 37.8, 94.2, 260.2 };
Float_t bcmpedR[NBCM] = { 53.0, 41.8, 104.1, 0., 101.6, 254.6 };
Float_t bcmped[NBCM];
// Pedestals for Ring buffer analysis
// L-arm tuned from run e01012_20288, R-arm from e01012_1288
Float_t ringpedL[2] = { 112.2, 112.2 };
Float_t ringpedR[2] = { 112.2, 112.2 };
Float_t ringped[2];
if (myroc == 23) {
cout << "Using Left Arm BCM pedestals (for now) "<<endl;
for (i = 0; i < NBCM; i++) {
bcmped[i] = bcmpedL[i];
}
for (i = 0; i < 2; i++) ringped[i] = ringpedL[i];
} else {
cout << "Using Right Arm BCM pedestals"<<endl;
for (i = 0; i < NBCM; i++) {
bcmped[i] = bcmpedR[i];
}
for (i = 0; i < 2; i++) ringped[i] = ringpedR[i];
}
// Scaler object to extract data using scaler.map.
// WARNING: bank = "Left" goes with event type 140 data,
// while "EvLeft" goes with ROC11 data. Similarly "Right", "EvRight".
THaScaler *scaler = new THaScaler(mybank.c_str());
if (scaler->Init("3-1-2006") == -1) {
cout << "Error initializing scaler object. "<<endl;
return 1;
}
// Initialize root and output.
TROOT scalana("scalroot","Hall A scaler analysis");
TFile hfile("scaler.root","RECREATE","Scaler data in Hall A");
// Define the ntuple here. Part of the ntuple is filled from scaler
// object (scal_obj) and part is from event data (evdata).
// If you add a variable, I suggest you keep track of the indices the same way.
// 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14
char scal_obj_rawrates[]="time:u1:u3:u10:d1:d3:d10:t1:t2:t3:t4:t5:clkp:clkm:tacc:";
// 15 16 17 18 19 20 21 22 23 24 25 26
char scal_obj_asymmetries[]="au1:au3:au10:ad1:ad3:ad10:at1:at2:at3:at4:at5:aclk:";
// 27 28 29 30 31 32 33
char evdata_rawrates[]="evt:evclk:evtrig:evbcm:evl1a:evmhel:evphel:";
// Asymmetries delayed various amounts, using RING BUFFER. The correct
// one is presumably the one delayed by NDELAY quads, but we need to check.
// 34 35 36 37 38 39 40 41 42 43
char asydelay[]="a3d1:a3d2:a3d3:a3d4:a3d5:a3d6:a3d7:a3d8:a3d9:a3d10";
int nlen = strlen(scal_obj_rawrates) + strlen(scal_obj_asymmetries) + strlen(evdata_rawrates) + strlen(asydelay);
char *string_ntup = new char[nlen+1];
strcpy(string_ntup, scal_obj_rawrates);
strcat(string_ntup, scal_obj_asymmetries);
strcat(string_ntup, evdata_rawrates);
strcat(string_ntup,asydelay);
TNtuple *ntup = new TNtuple("ascal","Scaler Rates",string_ntup);
Float_t* farray_ntup = new Float_t[nlen+1];
// 2nd ntuple for 1-sec averaged ring buffer
// 0 1 2 3 4 5 6 7 8 9 10 11
char ring_rates[]="evt:clkp:clkm:clk:bcmp:bcmm:bcm:trig:l1a:nump:numm:num:aclk:abcm:atrig:al1a";
//12 13 14 15
TNtuple *rnt = new TNtuple("aring","Ring values", ring_rates);
Float_t *farray2 = new Float_t[16];
THaCodaFile *coda = new THaCodaFile(TString(filename.c_str()));
THaEvData *evdata = new THaCodaDecoder();
inquad = 0;
q1_helicity = 0;
rloc = 0;
status = 0;
sum_clock = 0; sum_t3 = 0; sum_bcm = 0; sum_l1a = 0;
prev_clock = 0; prev_trig = 0; prev_bcm = 0; prev_l1a = 0; prev_hel2 = 0;
lastclkp = 0; lastclkm = 0;
nrread = 0;
iev = 0;
resetSums();
while (status == 0) {
status = coda->codaRead();
if (status != 0) break;
evdata->LoadEvent(coda->getEvBuffer());
len = evdata->GetRocLength(myroc);
if (nevents > 0 && iev++ > nevents) goto finish;
if (len <= 4) continue;
if (evdata->GetEvType() == 140) continue;
scaler->LoadData(*evdata);
if ( !scaler->IsRenewed() ) continue;
memset(farray_ntup, 0, (nlen+1)*sizeof(Float_t));
// Having loaded the scaler object, we pull out what we can from it.
// Note, we must average the two helicities to get non-helicity rates because ROC23
// data only have helicity scalers. (In contrast, event type 140 has all scalers.)
time = (scaler->GetPulser(1,"clock") + scaler->GetPulser(-1,"clock"))/1024;
latest_clock = (scaler->GetPulser(1,"clock") + scaler->GetPulser(-1,"clock"));
latest_trig = (scaler->GetTrig(1,3) + scaler->GetTrig(-1,3));
latest_bcm = (scaler->GetBcm(1,"bcm_u3") + scaler->GetBcm(-1,"bcm_u3"));
latest_l1a = (scaler->GetNormData(1,"TS-accept") + scaler->GetNormData(-1,"TS-accept"));
if (PRINTOUT) cout << dec << "latest data "<<latest_clock<<" "<<latest_trig<<" "<<latest_bcm<<" "<<latest_l1a<<endl;
farray_ntup[0] = time;
farray_ntup[1] = 0.5*(scaler->GetBcmRate(1,"bcm_u1") + scaler->GetBcmRate(-1,"bcm_u1"));
farray_ntup[2] = 0.5*(scaler->GetBcmRate(1,"bcm_u3") + scaler->GetBcmRate(-1,"bcm_u3"));
farray_ntup[3] = 0.5*(scaler->GetBcmRate(1,"bcm_u10") + scaler->GetBcmRate(-1,"bcm_u10"));
farray_ntup[4] = 0.5*(scaler->GetBcmRate(1,"bcm_d1") + scaler->GetBcmRate(-1,"bcm_d1"));
farray_ntup[5] = 0.5*(scaler->GetBcmRate(1,"bcm_d3") + scaler->GetBcmRate(-1,"bcm_d3"));
farray_ntup[6] = 0.5*(scaler->GetBcmRate(1,"bcm_d10") + scaler->GetBcmRate(-1,"bcm_d10"));
for (trig = 1; trig <= 5; trig++) {
farray_ntup[6+trig] = 0.5*(scaler->GetTrigRate(1,trig) + scaler->GetTrigRate(-1,trig));
}
if (PRINTOUT == 1 && len >= 16) {
scaler->Print();
for (i = 0; i < 6; i++) cout << " bcm -> "<<farray_ntup[i];
cout << endl << endl;
for (i = 0; i < 5; i++) cout << " trig -> "<<farray_ntup[i+7];
cout << endl << endl;
}
clkp = scaler->GetNormData(1,"clock");
clkm = scaler->GetNormData(-1,"clock");
farray_ntup[12] = clkp - lastclkp;
farray_ntup[13] = clkm - lastclkm;
lastclkp = clkp;
lastclkm = clkm;
farray_ntup[14] = 0.5*(scaler->GetNormRate(1,"TS-accept") +
scaler->GetNormRate(-1,"TS-accept"));
string bcms[] = {"bcm_u1", "bcm_u3", "bcm_u10", "bcm_d1", "bcm_d3", "bcm_d10"};
//
// Next we construct the helicity correlated asymmetries.
//
for (int ibcm = 0; ibcm < 6; ibcm++ ) {
sum = scaler->GetBcmRate(1,bcms[ibcm].c_str()) - bcmped[ibcm]
+ scaler->GetBcmRate(-1,bcms[ibcm].c_str()) - bcmped[ibcm];
asy = -999;
if (sum != 0) {
asy = (scaler->GetBcmRate(1,bcms[ibcm].c_str()) -
scaler->GetBcmRate(-1,bcms[ibcm].c_str())) / sum;
}
farray_ntup[15+ibcm] = asy;
}
for (trig = 1; trig <= 5; trig++) {
asy = -999;
if (scaler->GetBcmRate(1,"bcm_u3") > BCM_CUT3 &&
scaler->GetBcmRate(-1,"bcm_u3") > BCM_CUT3) {
sum = scaler->GetTrigRate(1,trig)/scaler->GetBcmRate(1,"bcm_u3")
+ scaler->GetTrigRate(-1,trig)/scaler->GetBcmRate(-1,"bcm_u3");
if (sum != 0) {
asy = (scaler->GetTrigRate(1,trig)/scaler->GetBcmRate(1,"bcm_u3")
- scaler->GetTrigRate(-1,trig)/scaler->GetBcmRate(-1,"bcm_u3")) / sum;
}
}
farray_ntup[20+trig] = asy;
}
sum = scaler->GetPulser(1,"clock") + scaler->GetPulser(-1,"clock");
asy = -999;
if (sum != 0) {
asy = (scaler->GetPulser(1,"clock") -
scaler->GetPulser(-1,"clock")) / sum;
}
farray_ntup[26] = asy;
//
// Next we ignore the scaler object and obtain data directly from the event.
//
found = 0;
index = 0;
while ( !found ) {
data = evdata->GetRawData(myroc,index++);
if ( (data & 0xffff0000) == 0xfb0b0000) found = 1;
if (PRINTOUT) cout << "evbuffer["<<index-1<<"] = 0x"<<hex<<data<<" = (dec) "<<dec<<data<<endl;
if (index >= len) break;
}
if (!found) continue;
nscaler = data & 0x7;
// if (evdata->GetEvType() == 9) cout << "Ev 9 qrt "<<qrt<<" helicity "<<helicity<<" gate "<<gate<<" timestamp "<<timestamp<<endl;
if (PRINTOUT) {
cout << "nscaler in this event " << nscaler << endl;
}
if (nscaler <= 0) continue;
if (nscaler > 2) nscaler = 2; // shouldn't be necessary
// 32 channels of scaler data for two helicities.
if (PRINTOUT) cout << "Scaler data in event ----> " << endl;
for (int ihel = 0; ihel < nscaler; ihel++) {
header = evdata->GetRawData(myroc,index++);
if (PRINTOUT) {
cout << "Scaler for helicity = " << dec << ihel;
cout << " unique header = " << hex << header << endl;
}
for (int ichan = 0; ichan < 32; ichan++) {
data = evdata->GetRawData(myroc,index++);
if (PRINTOUT) {
cout << "channel # " << dec << ichan+1;
cout << " data = 0x" << hex << data;
cout << " = (dec) "<< dec << data << endl;
}
}
}
numread0 = evdata->GetRawData(myroc,index++);
numread1 = evdata->GetRawData(myroc,index++);
badread = evdata->GetRawData(myroc,index++);
if (PRINTOUT)
cout << "FIFO num of last good read " << dec << numread0 << numread1 << endl;
if (badread != 0) {
cout << "DISASTER: There are bad readings " << endl;
cout << "FIFO num of last bad read " << endl;
}
// Ring buffer analysis: analyze subset of scaler channels in 30 Hz ring buffer.
int nring = 0;
while (index < len && nring == 0) {
header = evdata->GetRawData(myroc,index++);
if ((header & 0xffff0000) == 0xfb1b0000) {
nring = header & 0x3ff;
}
}
if (PRINTOUT) cout << "Num in ring buffer = " << dec << nring << endl;
// The following assumes three are (now 6) pieces of data per 'iring'
for (int iring = 0; iring < nring; iring++) {
ring_clock = evdata->GetRawData(myroc,index++);
data = evdata->GetRawData(myroc,index++);
ring_qrt = (data & 0x10) >> 4;
ring_helicity = (data & 0x1);
present_reading = ring_helicity;
if (ring_qrt) {
inquad = 1;
if (loadHelicity()) {
// cout << "CHECK HEL "<<present_reading<<" "
// << predicted_reading << endl;
if (present_reading != predicted_reading) {
cout << "DISASTER: The helicity is wrong !!"<<endl;
recovery_flag = 1; // ask for recovery
}
q1_helicity = present_helicity;
}
} else {
inquad++;
}
if (inquad == 1 || inquad == 4) {
helicity_now = q1_helicity;
} else {
helicity_now = 1 - q1_helicity;
}
ring_t3 = evdata->GetRawData(myroc,index++);
ring_bcm = evdata->GetRawData(myroc,index++);
ring_l1a = evdata->GetRawData(myroc,index++);
#ifdef READ6
ring_t1 = evdata->GetRawData(myroc,index++);
#else
ring_t1 = -99;
#endif
sum_clock = sum_clock + ring_clock;
sum_t3 = sum_t3 + ring_t3;
sum_bcm = sum_bcm + ring_bcm;
sum_l1a = sum_l1a + ring_l1a;
// We know the helicity bits come one window later, so we adjust
// for that here.
jstat = incrementSums(helicity_now, prev_clock, prev_trig,
prev_bcm, prev_l1a);
if (jstat == 1) {
farray2[0] = (Float_t) evdata->GetEvNum();
farray2[1] = rsum_clk[0];
farray2[2] = rsum_clk[1];
farray2[3] = rsum_clk[0] + rsum_clk[1];
corr_bcm0 = rsum_bcm[0] - ringped[0]; // the 2 peds had better
corr_bcm1 = rsum_bcm[1] - ringped[1]; // be the same (but we check)
farray2[4] = rsum_bcm[0];
farray2[5] = rsum_bcm[1];
farray2[6] = corr_bcm0 + corr_bcm1;
farray2[7] = rsum_t3[0] + rsum_t3[1];
farray2[8] = rsum_l1a[0] + rsum_l1a[1];
farray2[9] = rsum_num[0];
farray2[10] = rsum_num[1];
farray2[11] = rsum_num[0] + rsum_num[1];
sum = rsum_clk[0] + rsum_clk[1];
asy = -999;
if (sum != 0) asy = (rsum_clk[0] - rsum_clk[1])/sum;
farray2[12] = asy;
// Charge asymmetry. Don't forget to normalize to clock.
asy = -999;
sum = corr_bcm0 + corr_bcm1;
if (sum != 0) asy = (corr_bcm0 - corr_bcm1)/sum;
farray2[13] = asy;
asy = -999;
if (corr_bcm0 != 0 && corr_bcm1 != 0) {
Float_t trig0 = rsum_t3[0] / corr_bcm0;
Float_t trig1 = rsum_t3[1] / corr_bcm1;
sum = trig0 + trig1;
if (sum != 0) {
asy = (trig0 - trig1) / sum;
}
}
farray2[14] = asy;
asy = -999;
if (corr_bcm0 != 0 && corr_bcm1 != 0) {
Float_t l1a0 = rsum_l1a[0] / corr_bcm0;
Float_t l1a1 = rsum_l1a[1] / corr_bcm1;
sum = l1a0 + l1a1;
if (sum != 0) {
asy = (l1a0 - l1a1) / sum;
}
}
farray2[15] = asy;
rnt->Fill(farray2);
resetSums();
}
prev_clock = ring_clock;
prev_trig = ring_t3;
prev_bcm = ring_bcm;
prev_l1a = ring_l1a;
// Empirical check of delayed helicity scheme.
ring_data[rloc%MAXRING] = ring_bcm;
if (inquad == 1 && nrread++ > 12) {
farray_ntup[27] = (float)nrread; // need to cut that this is >0 in analysis
farray_ntup[28] = ring_clock;
farray_ntup[29] = ring_t3;
farray_ntup[30] = ring_bcm;
farray_ntup[31] = ring_l1a;
farray_ntup[32] = (float)present_reading;
farray_ntup[33] = (float)present_helicity;
for (int ishift = 3; ishift <= 12; ishift++) {
Float_t pdat = ring_data[(rloc-ishift)%MAXRING];
Float_t mdat = ring_data[(rloc-ishift+1)%MAXRING];
Float_t sum = pdat + mdat;
Float_t asy = 99999;
if (sum != 0) {
if (present_reading == 1) {
asy = (pdat - mdat)/sum;
} else {
asy = (mdat - pdat)/sum;
}
}
// ishift = 9 is the correct one. (should be 8, but the helicity
// bits are one cycle out of phase w.r.t. data)
farray_ntup[31+ishift] = asy;
if (PRINTOUT) cout << "shift "<<ishift<<" "<<asy<<endl;
}
}
ntup->Fill(farray_ntup);
rloc++;
if (PRINTOUT) {
cout << "buff [" << dec << iring << "] ";
cout << " clock " << ring_clock << " qrt " << ring_qrt;
cout << " helicity " << ring_helicity<<" T1 "<<ring_t1<<endl;
cout << " T3 " << ring_t3 << " bcm " << ring_bcm;
cout << " L1a "<<ring_l1a<<endl;
cout << " inquad "<<inquad<<endl;
cout << " sums: "<<endl;
cout << " clock "<<sum_clock<<" trig "<<sum_t3;
cout << " bcm "<<sum_bcm<<" l1a "<<sum_l1a<<endl;
cout << " update from online sums: "<<endl;
cout << " clock "<<latest_clock<<" trig "<<latest_trig;
cout << " bcm "<<latest_bcm<<" l1a "<<latest_l1a<<endl;
}
}
}
finish:
cout << "All done"<<endl<<flush;
cout << "Sums from ring buffer: "<<dec<<endl;
cout << " Clock "<<sum_clock<<" trigger "<<sum_t3;
cout << " BCM "<<sum_bcm<<" L1a "<<sum_l1a<<endl;
cout << "Latest data from online sums: "<<endl;
cout << " Clock "<<latest_clock<<" trigger "<<latest_trig;
cout << " BCM "<<latest_bcm<<" L1a "<<latest_l1a<<endl;
hfile.Write();
hfile.Close();
exit(0);
}
int main(int argc, char* argv[])
{
TString filename("snippet.dat");
ofstream *debugfile = 0;
#ifdef DEBUG
debugfile = new ofstream;
debugfile->open ("oodecoder1.txt");
*debugfile << "Debug of OO decoder\n\n";
#endif
THaCodaFile datafile(filename);
THaEvData *evdata = new CodaDecoder();
evdata->SetDebug(1);
evdata->SetDebugFile(debugfile);
// Initialize root and output
TROOT fadcana("fadcroot","Hall A FADC analysis, 1st version");
TFile hfile("fadc.root","RECREATE","FADC data");
h1 = new TH1F("h1","snapshot 1",1020,-5,505);
h2 = new TH1F("h2","snapshot 2",1020,-5,505);
h3 = new TH1F("h3","snapshot 3",1020,-5,505);
h4 = new TH1F("h4","snapshot 4",1020,-5,505);
h5 = new TH1F("h5","snapshot 5",1020,-5,505);
hinteg = new TH1F("hinteg","Integral of ADC",1000,50000,120000);
// Loop over events
int NUMEVT=22;
Int_t jnum=1;
for (int iev=0; iev<NUMEVT; iev++) {
int status = datafile.codaRead();
if (status != S_SUCCESS) {
if ( status == EOF) {
if (debugfile) *debugfile << "Normal end of file. Bye bye." << endl;
} else {
if (debugfile) *debugfile << hex << "ERROR: codaRread status = " << status << endl;
}
exit(1);
} else {
UInt_t *data = datafile.getEvBuffer();
dump(data, debugfile);
if (debugfile) *debugfile << "\nAbout to Load Event "<<endl;
evdata->LoadEvent( data );
if (debugfile) *debugfile << "\nFinished with Load Event "<<endl;
if (evdata->GetEvType() == MYTYPE) {
process (jnum, evdata, debugfile);
jnum++;
}
}
}
hfile.Write();
hfile.Close();
}
int main(int argc, char* argv[]) {
int i,iev,evnum,trig,iskip,status;
Int_t clkp, clkm, lastclkp, lastclkm;
Float_t sum,asy;
TString filename = "run.dat";
char bank[100] = "EvLeft"; // Event stream, Left HRS
cout << "Analyzing CODA file "<<filename<<endl;
cout << "Bank = "<<bank<<endl<<flush;
evnum = 10000000;
if (argc > 1) evnum = atoi(argv[1]);
THaScaler *scaler = new THaScaler(bank);
if (scaler->Init("1-10-2004") == -1) {
cout << "Error initializing scaler "<<endl;
return 1;
}
THaCodaData *coda = new THaCodaFile(filename);
THaEvData *evdata = new THaCodaDecoder();
// Pedestals. Left, Right Arms. u1,u3,u10,d1,d3,d10
Float_t bcmpedL[NBCM] = { 188.2, 146.2, 271.6, 37.8, 94.2, 260.2 };
Float_t bcmpedR[NBCM] = { 53.0, 41.8, 104.1, 0., 101.6, 254.6 };
Float_t bcmped[NBCM];
if (strcmp(bank,"EvLeft") == 0) {
cout << "Using Left Arm BCM pedestals"<<endl;
for (i = 0; i < NBCM; i++) {
bcmped[i] = bcmpedL[i];
}
} else {
cout << "Using Right Arm BCM pedestals"<<endl;
for (i = 0; i < NBCM; i++) {
bcmped[i] = bcmpedR[i];
}
}
// Initialize root and output
TROOT scalana("scalroot","Hall A scaler analysis");
TFile hfile("scaler.root","RECREATE","Scaler data in Hall A");
// Define the ntuple here
// 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14
char rawrates[]="time:u1:u3:u10:d1:d3:d10:t1:t2:t3:t4:t5:clkp:clkm:tacc:";
// 15 16 17 18 19 20 21 22 23 24 25 26
char asymmetries[]="au1:au3:au10:ad1:ad3:ad10:at1:at2:at3:at4:at5:aclk";
int nlen = strlen(rawrates) + strlen(asymmetries);
char *string_ntup = new char[nlen+1];
strcpy(string_ntup,rawrates);
strcat(string_ntup,asymmetries);
TNtuple *ntup = new TNtuple("ascal","Scaler Rates",string_ntup);
Float_t farray_ntup[27]; // Note, dimension is same as size of string_ntup (i.e. nlen+1)
status = 0;
iev = 0;
iskip = 0;
lastclkp = 0;
lastclkm = 0;
while (status == 0) {
if(coda) status = coda->codaRead();
if (status != 0) {
cout << "coda status nonzero. assume EOF"<<endl;
goto quit;
}
evdata->LoadEvent(coda->getEvBuffer());
// Dirty trick to average over larger time intervals (depending on
// SKIPEVENT) to reduce the fluctuations due to clock.
if (evdata->GetRocLength(MYROC) > 16) iskip++;
if (SKIPEVENT != 0 && iskip < SKIPEVENT) continue;
iskip = 0;
scaler->LoadData(*evdata);
// Not every trigger has new scaler data, so skip if not new.
if ( !scaler->IsRenewed() ) {
cout << "not renewed "<<endl<<flush;
continue;
}
if (iev++ > evnum) goto quit;
// Fill the ntuple here
// Note, we must average the two helicities here to get non-helicity rates
Double_t time = (scaler->GetPulser(1,"clock") + scaler->GetPulser(-1,"clock"))/1024;
farray_ntup[0] = time;
farray_ntup[1] = 0.5*(scaler->GetBcmRate(1,"bcm_u1") + scaler->GetBcmRate(-1,"bcm_u1"));
farray_ntup[2] = 0.5*(scaler->GetBcmRate(1,"bcm_u3") + scaler->GetBcmRate(-1,"bcm_u3"));
farray_ntup[3] = 0.5*(scaler->GetBcmRate(1,"bcm_u10") + scaler->GetBcmRate(-1,"bcm_u10"));
farray_ntup[4] = 0.5*(scaler->GetBcmRate(1,"bcm_d1") + scaler->GetBcmRate(-1,"bcm_d1"));
farray_ntup[5] = 0.5*(scaler->GetBcmRate(1,"bcm_d3") + scaler->GetBcmRate(-1,"bcm_d3"));
farray_ntup[6] = 0.5*(scaler->GetBcmRate(1,"bcm_d10") + scaler->GetBcmRate(-1,"bcm_d10"));
for (trig = 1; trig <= 5; trig++) {
farray_ntup[6+trig] = 0.5*(scaler->GetTrigRate(1,trig) + scaler->GetTrigRate(-1,trig));
}
clkp = scaler->GetNormData(1,"clock");
clkm = scaler->GetNormData(-1,"clock");
farray_ntup[12] = clkp - lastclkp;
farray_ntup[13] = clkm - lastclkm;
lastclkp = clkp;
lastclkm = clkm;
farray_ntup[14] = 0.5*(scaler->GetNormRate(1,"TS-accept") +
scaler->GetNormRate(-1,"TS-accept"));
string bcms[] = {"bcm_u1", "bcm_u3", "bcm_u10", "bcm_d1", "bcm_d3", "bcm_d10"};
for (int ibcm = 0; ibcm < 6; ibcm++ ) {
sum = scaler->GetBcmRate(1,bcms[ibcm].c_str()) - bcmped[ibcm]
+ scaler->GetBcmRate(-1,bcms[ibcm].c_str()) - bcmped[ibcm];
asy = -999;
if (sum != 0) {
asy = (scaler->GetBcmRate(1,bcms[ibcm].c_str()) -
scaler->GetBcmRate(-1,bcms[ibcm].c_str())) / sum;
}
farray_ntup[15+ibcm] = asy;
}
for (trig = 1; trig <= 5; trig++) {
asy = -999;
if (scaler->GetBcmRate(1,"bcm_u3") > BCM_CUT3 &&
scaler->GetBcmRate(-1,"bcm_u3") > BCM_CUT3) {
sum = scaler->GetTrigRate(1,trig)/scaler->GetBcmRate(1,"bcm_u3")
+ scaler->GetTrigRate(-1,trig)/scaler->GetBcmRate(-1,"bcm_u3");
if (sum != 0) {
asy = (scaler->GetTrigRate(1,trig)/scaler->GetBcmRate(1,"bcm_u3")
- scaler->GetTrigRate(-1,trig)/scaler->GetBcmRate(-1,"bcm_u3")) / sum;
}
}
farray_ntup[20+trig] = asy;
}
sum = scaler->GetPulser(1,"clock") + scaler->GetPulser(-1,"clock");
asy = -999;
if (sum != 0) {
asy = (scaler->GetPulser(1,"clock") -
scaler->GetPulser(-1,"clock")) / sum;
}
farray_ntup[26] = asy;
if (DEBUG) {
cout << "event type "<<evdata->GetEvType()<< " event number "<<evdata->GetEvNum()<<endl;
scaler->Print();
if (farray_ntup[12] < 1000) cout << "Low clock"<<endl;
cout << " clock(+) "<<scaler->GetNormRate(1,"clock");
cout << " clock(-) "<<scaler->GetNormRate(-1,"clock")<<endl;
if (farray_ntup[16]>0.005||farray_ntup[16]<-0.005) cout << "Big asy"<<endl;
}
ntup->Fill(farray_ntup);
}
quit:
hfile.Write();
hfile.Close();
exit(0);
}
