This program reads the DAQ data files passed as argument using the monitoring library.
-It computes the average event size and populates local "./result.txt" file with the
-result.
-
The program reports about its processing progress.
Messages on stdout are exported to DAQ log system.
Run Type: STANDALONE_LASER_RUN
DA Type: LDC
Number of events needed: no constraint (tipically ~10^3)
-Input Files:
+Input Files: ZDCPedestal.dat
Output Files: ZDCLaser.dat
Trigger Types Used: Standalone Trigger
*/
#define PEDDATA_FILE "ZDCPedestal.dat"
#define MAPDATA_FILE "ZDCChMapping.dat"
+#define LASHISTO_FILE "ZDCLaserHisto.root"
#define LASDATA_FILE "ZDCLaserCalib.dat"
#include <stdio.h>
#include <daqDA.h>
//ROOT
-#include <TRandom.h>
+#include <TROOT.h>
+#include <TPluginManager.h>
#include <TH1F.h>
#include <TF1.h>
#include <TFile.h>
#include <TFitter.h>
+#include "TMinuitMinimizer.h"
//AliRoot
#include <AliRawReaderDate.h>
*/
int main(int argc, char **argv) {
- TFitter *minuitFit = new TFitter(4);
- TVirtualFitter::SetFitter(minuitFit);
+ gROOT->GetPluginManager()->AddHandler("TVirtualStreamerInfo",
+ "*",
+ "TStreamerInfo",
+ "RIO",
+ "TStreamerInfo()");
+
+ TMinuitMinimizer m;
+ gROOT->GetPluginManager()->AddHandler("ROOT::Math::Minimizer", "Minuit","TMinuitMinimizer",
+ "Minuit", "TMinuitMinimizer(const char *)");
+ TVirtualFitter::SetDefaultFitter("Minuit");
+
int status = 0;
+ int const kNModules = 10;
+ int const kNChannels = 24;
+ int const kNScChannels = 32;
+ Int_t kFirstADCGeo=0, kLastADCGeo=1; // NO out-of-time signals!!!
+
+ Int_t iMod=-1;
+ Int_t modGeo[kNModules], modType[kNModules],modNCh[kNModules];
+ for(Int_t kl=0; kl<kNModules; kl++){
+ modGeo[kl]=modType[kl]=modNCh[kl]=0;
+ }
+
+ Int_t ich=0;
+ Int_t adcMod[2*kNChannels], adcCh[2*kNChannels], sigCode[2*kNChannels];
+ Int_t det[2*kNChannels], sec[2*kNChannels];
+ for(Int_t y=0; y<2*kNChannels; y++){
+ adcMod[y]=adcCh[y]=sigCode[y]=det[y]=sec[y]=0;
+ }
+
+ Int_t iScCh=0;
+ Int_t scMod[kNScChannels], scCh[kNScChannels], scSigCode[kNScChannels];
+ Int_t scDet[kNScChannels], scSec[kNScChannels];
+ for(Int_t y=0; y<kNScChannels; y++){
+ scMod[y]=scCh[y]=scSigCode[y]=scDet[y]=scSec[y]=0;
+ }
/* log start of process */
- printf("\nZDC LASER program started\n");
+ printf("\n ZDC LASER program started\n");
/* check that we got some arguments = list of files */
if (argc<2) {
// 20 signal channels + 2 reference PTMs
//
TH1F::AddDirectory(0);
- //
// --- Histos for reference PMTs (high gain chains)
- TH1F *hPMRefC = new TH1F("hPMRefC","hPMRefC", 100,0.,1400.);
- TH1F *hPMRefA = new TH1F("hPMRefA","hPMRefA", 100,0.,1400.);
+ TH1F *hPMRefChg = new TH1F("hPMRefChg","hPMRefChg", 100,-100.5,1100.5);
+ TH1F *hPMRefAhg = new TH1F("hPMRefAhg","hPMRefAhg", 100,-100.5,1100.5);
+ TH1F *hPMRefClg = new TH1F("hPMRefClg","hPMRefClg", 100,-100.5,4900.5);
+ TH1F *hPMRefAlg = new TH1F("hPMRefAlg","hPMRefAlg", 100,-100.5,4900.5);
//
- // --- Histos for detector PMTs (just high gain chain)
- TH1F *hZNC[5], *hZPC[5], *hZNA[5], *hZPA[5];
- char hnamZNC[20], hnamZPC[20], hnamZNA[20], hnamZPA[20];
+ // --- Histos for detector PMTs
+ TH1F *hZNChg[5], *hZPChg[5], *hZNAhg[5], *hZPAhg[5], *hZEMhg[2];
+ TH1F *hZNClg[5], *hZPClg[5], *hZNAlg[5], *hZPAlg[5], *hZEMlg[2];
+ char hnamZNChg[20], hnamZPChg[20], hnamZNAhg[20], hnamZPAhg[20];
+ char hnamZNClg[20], hnamZPClg[20], hnamZNAlg[20], hnamZPAlg[20];
+ char hnamZEMhg[20], hnamZEMlg[20];
for(Int_t j=0; j<5; j++){
- sprintf(hnamZNC,"ZNC-tow%d",j);
- sprintf(hnamZPC,"ZPC-tow%d",j);
- sprintf(hnamZNA,"ZNA-tow%d",j);
- sprintf(hnamZPA,"ZPA-tow%d",j);
+ sprintf(hnamZNChg,"ZNChg-tow%d",j);
+ sprintf(hnamZPChg,"ZPChg-tow%d",j);
+ sprintf(hnamZNAhg,"ZNAhg-tow%d",j);
+ sprintf(hnamZPAhg,"ZPAhg-tow%d",j);
+ //
+ hZNChg[j] = new TH1F(hnamZNChg, hnamZNChg, 100,-100.5,1100.5);
+ hZPChg[j] = new TH1F(hnamZPChg, hnamZPChg, 100,-100.5,1100.5);
+ hZNAhg[j] = new TH1F(hnamZNAhg, hnamZNAhg, 100,-100.5,1100.5);
+ hZPAhg[j] = new TH1F(hnamZPAhg, hnamZPAhg, 100,-100.5,1100.5);
//
- hZNC[j] = new TH1F(hnamZNC, hnamZNC, 100, 0., 1400.);
- hZPC[j] = new TH1F(hnamZPC, hnamZPC, 100, 0., 1400.);
- hZNA[j] = new TH1F(hnamZNA, hnamZNA, 100, 0., 1400.);
- hZPA[j] = new TH1F(hnamZPA, hnamZPA, 100, 0., 1400.);
+ sprintf(hnamZNClg,"ZNClg-tow%d",j);
+ sprintf(hnamZPClg,"ZPClg-tow%d",j);
+ sprintf(hnamZNAlg,"ZNAlg-tow%d",j);
+ sprintf(hnamZPAlg,"ZPAlg-tow%d",j);
+ //
+ hZNClg[j] = new TH1F(hnamZNClg, hnamZNClg, 100,-100.5,4900.5);
+ hZPClg[j] = new TH1F(hnamZPClg, hnamZPClg, 100,-100.5,4900.5);
+ hZNAlg[j] = new TH1F(hnamZNAlg, hnamZNAlg, 100,-100.5,4900.5);
+ hZPAlg[j] = new TH1F(hnamZPAlg, hnamZPAlg, 100,-100.5,4900.5);
+ //
+ if(j<2){
+ sprintf(hnamZEMhg,"ZEM%dhg",j);
+ sprintf(hnamZEMlg,"ZEM%dlg",j);
+ //
+ hZEMhg[j] = new TH1F(hnamZEMhg, hnamZEMhg, 100,-100.5,1100.5);
+ hZEMlg[j] = new TH1F(hnamZEMlg, hnamZEMlg, 100,-100.5,4900.5);
+ }
}
/* open result file */
printf("Failed to open file\n");
return -1;
}
-
- FILE *mapFile4Shuttle;
+ /* report progress */
+ daqDA_progressReport(10);
// *** To analyze LASER events you MUST have a pedestal data file!!!
- // *** -> check if a pedestal run has been analyzied
+ // *** -> check if a pedestal run has been analyzed
int read = 0;
- read = daqDA_DB_getFile(PEDDATA_FILE,PEDDATA_FILE);
+ read = daqDA_DB_getFile(PEDDATA_FILE, PEDDATA_FILE);
if(read){
printf("\t ERROR!!! ZDCPedestal.dat file NOT FOUND in DAQ db!!!\n");
return -1;
}
// 144 = 48 in-time + 48 out-of-time + 48 correlations
- Float_t readValues[2][144], MeanPed[44], MeanPedWidth[44],
- MeanPedOOT[44], MeanPedWidthOOT[44];
+ Float_t readValues[2][6*kNChannels];
+ Float_t MeanPedhg[kNChannels], MeanPedlg[kNChannels];
+ Float_t CorrCoeff0[2*kNChannels], CorrCoeff1[2*kNChannels];
// ***************************************************
// Unless we have a narrow correlation to fit we
// don't fit and store in-time vs. out-of-time
// histograms -> mean pedstal subtracted!!!!!!
// ***************************************************
- //Float_t CorrCoeff0[44], CorrCoeff1[44];
//
- for(int jj=0; jj<144; jj++){
+ for(int jj=0; jj<6*kNChannels; jj++){
for(int ii=0; ii<2; ii++){
fscanf(filePed,"%f",&readValues[ii][jj]);
}
- if(jj<48){
- MeanPed[jj] = readValues[0][jj];
- MeanPedWidth[jj] = readValues[1][jj];
- //printf("\t MeanPed[%d] = %1.1f\n",jj, MeanPed[jj]);
+ if(jj<kNChannels){
+ MeanPedhg[jj] = readValues[0][jj];
+ //printf("\t MeanPedhg[%d] = %1.1f\n",jj, MeanPedhg[jj]);
}
- else if(jj>48 && jj<96){
- MeanPedOOT[jj-48] = readValues[0][jj];
- MeanPedWidthOOT[jj-48] = readValues[1][jj];
+ else if(jj>=kNChannels && jj<2*kNChannels){
+ MeanPedlg[jj-kNChannels] = readValues[0][jj];
+ //printf("\t MeanPedlg[%d] = %1.1f\n",jj-kNChannels, MeanPedlg[jj-kNChannels]);
}
- /*else if(jj>144){
- CorrCoeff0[jj-96] = readValues[0][jj];
- CorrCoeff1[jj-96] = readValues[1][jj];;
+ else if(jj>4*kNChannels){
+ CorrCoeff0[jj-4*kNChannels] = readValues[0][jj];
+ CorrCoeff1[jj-4*kNChannels] = readValues[1][jj];;
}
- */
}
+
+ FILE *mapFile4Shuttle;
/* report progress */
- daqDA_progressReport(10);
+ daqDA_progressReport(20);
/* init some counters */
int nevents_physics=0;
int nevents_total=0;
+ struct eventHeaderStruct *event;
+ eventTypeType eventT;
+
/* read the data files */
int n;
- for (n=1;n<argc;n++) {
+ for(n=1;n<argc;n++) {
status=monitorSetDataSource( argv[n] );
if (status!=0) {
/* report progress */
/* in this example, indexed on the number of files */
- daqDA_progressReport(10+80*n/argc);
+ daqDA_progressReport(20+70*n/argc);
/* read the file */
for(;;) {
- struct eventHeaderStruct *event;
- eventTypeType eventT;
/* get next event */
status=monitorGetEventDynamic((void **)&event);
/* use event - here, just write event id to result file */
eventT=event->eventType;
- Int_t ich=0, adcMod[48], adcCh[48], sigCode[48], det[48], sec[48];
if(eventT==START_OF_DATA){
-
+
+ iMod=-1; ich=0; iScCh=0;
+
rawStreamZDC->SetSODReading(kTRUE);
-
+
+ // --------------------------------------------------------
+ // --- Writing ascii data file for the Shuttle preprocessor
+ mapFile4Shuttle = fopen(MAPDATA_FILE,"w");
if(!rawStreamZDC->Next()) printf(" \t No raw data found!! \n");
else{
- while(rawStreamZDC->Next()){
- if(rawStreamZDC->IsChMapping()){
- adcMod[ich] = rawStreamZDC->GetADCModFromMap(ich);
- adcCh[ich] = rawStreamZDC->GetADCChFromMap(ich);
- sigCode[ich] = rawStreamZDC->GetADCSignFromMap(ich);
- det[ich] = rawStreamZDC->GetDetectorFromMap(ich);
- sec[ich] = rawStreamZDC->GetTowerFromMap(ich);
- ich++;
+ while((rawStreamZDC->Next())){
+ if(rawStreamZDC->IsHeaderMapping()){ // mapping header
+ iMod++;
+ modGeo[iMod] = rawStreamZDC->GetADCModule();
+ modType[iMod] = rawStreamZDC->GetModType();
+ modNCh[iMod] = rawStreamZDC->GetADCNChannels();
}
+ if(rawStreamZDC->IsChMapping()){
+ if(modType[iMod]==1){ // ADC mapping ----------------------
+ adcMod[ich] = rawStreamZDC->GetADCModFromMap(ich);
+ adcCh[ich] = rawStreamZDC->GetADCChFromMap(ich);
+ sigCode[ich] = rawStreamZDC->GetADCSignFromMap(ich);
+ det[ich] = rawStreamZDC->GetDetectorFromMap(ich);
+ sec[ich] = rawStreamZDC->GetTowerFromMap(ich);
+ ich++;
+ }
+ else if(modType[iMod]==2){ //VME scaler mapping --------------------
+ scMod[iScCh] = rawStreamZDC->GetScalerModFromMap(iScCh);
+ scCh[iScCh] = rawStreamZDC->GetScalerChFromMap(iScCh);
+ scSigCode[iScCh] = rawStreamZDC->GetScalerSignFromMap(iScCh);
+ scDet[iScCh] = rawStreamZDC->GetScDetectorFromMap(iScCh);
+ scSec[iScCh] = rawStreamZDC->GetScTowerFromMap(iScCh);
+ iScCh++;
+ }
+ }
+ }
+ // Writing data on output FXS file
+ for(Int_t is=0; is<2*kNChannels; is++){
+ fprintf(mapFile4Shuttle,"\t%d\t%d\t%d\t%d\t%d\t%d\n",
+ is,adcMod[is],adcCh[is],sigCode[is],det[is],sec[is]);
+ //printf(" Laser DA -> %d ADC: mod %d ch %d, code %d det %d, sec %d\n",
+ // is,adcMod[is],adcCh[is],sigCode[is],det[is],sec[is]);
+ }
+ for(Int_t is=0; is<kNScChannels; is++){
+ fprintf(mapFile4Shuttle,"\t%d\t%d\t%d\t%d\t%d\t%d\n",
+ is,scMod[is],scCh[is],scSigCode[is],scDet[is],scSec[is]);
+ //printf(" Laser DA -> %d Scaler: mod %d ch %d, code %d det %d, sec %d\n",
+ // is,scMod[is],scCh[is],scSigCode[is],scDet[is],scSec[is]);
}
+ for(Int_t is=0; is<kNModules; is++){
+ fprintf(mapFile4Shuttle,"\t%d\t%d\t%d\n",
+ modGeo[is],modType[is],modNCh[is]);
+ //printf(" Laser DA -> Module mapping: geo %d type %d #ch %d\n",
+ // modGeo[is],modType[is],modNCh[is]);
+ }
+
}
- // --------------------------------------------------------
- // --- Writing ascii data file for the Shuttle preprocessor
- mapFile4Shuttle = fopen(MAPDATA_FILE,"w");
- for(Int_t i=0; i<ich; i++){
- fprintf(mapFile4Shuttle,"\t%d\t%d\t%d\t%d\t%d\t%d\n",i,
- adcMod[i],adcCh[i],sigCode[i],det[i],sec[i]);
- //
- //printf("ZDCLASERDA.cxx -> ch.%d mod %d, ch %d, code %d det %d, sec %d\n",
- // i,adcMod[i],adcCh[i],sigCode[i],det[i],sec[i]);
- }
fclose(mapFile4Shuttle);
- }
+ }// SOD event
- /* use event - here, just write event id to result file */
- eventT=event->eventType;
-
- if(eventT==PHYSICS_EVENT){
- //
- // --- Reading data header
+ else if(eventT==PHYSICS_EVENT){
+ // --- Reading data header
reader->ReadHeader();
const AliRawDataHeader* header = reader->GetDataHeader();
if(header) {
UChar_t message = header->GetAttributes();
- if(message & 0x20){ // DEDICATED LASER RUN
+ if((message & 0x30) == 0x30){ // DEDICATED LASER RUN
//printf("\t STANDALONE_LASER_RUN raw data found\n");
- continue;
}
else{
- printf("\t NO STANDALONE_LASER_RUN raw data found\n");
+ printf("ZDCLASERda.cxx -> NO STANDALONE_LASER_RUN raw data found\n");
return -1;
}
}
if (!rawStreamZDC->Next()) printf(" \t No raw data found!! \n");
//
// ----- Setting ch. mapping -----
- for(Int_t jk=0; jk<48; jk++){
+ for(Int_t jk=0; jk<2*kNChannels; jk++){
rawStreamZDC->SetMapADCMod(jk, adcMod[jk]);
rawStreamZDC->SetMapADCCh(jk, adcCh[jk]);
rawStreamZDC->SetMapADCSig(jk, sigCode[jk]);
while(rawStreamZDC->Next()){
Int_t index=-1;
Int_t detector = rawStreamZDC->GetSector(0);
+ Int_t sector = rawStreamZDC->GetSector(1);
- if(rawStreamZDC->IsADCDataWord() && !(rawStreamZDC->IsUnderflow())
- && !(rawStreamZDC->IsOverflow()) && detector!=-1){
+ if(rawStreamZDC->IsADCDataWord() && !(rawStreamZDC->IsUnderflow()) &&
+ !(rawStreamZDC->IsOverflow()) && detector!=-1 &&
+ rawStreamZDC->GetADCModule()>=kFirstADCGeo && rawStreamZDC->GetADCModule()<=kLastADCGeo){
- printf(" IsADCWord %d, IsUnderflow %d, IsOverflow %d\n",
- rawStreamZDC->IsADCDataWord(),rawStreamZDC->IsUnderflow(),rawStreamZDC->IsOverflow());
-
- if(rawStreamZDC->GetSector(1)!=5){ // Physics signals
- if(detector==1) index = rawStreamZDC->GetSector(1); // *** ZNC
- else if(detector==2) index = rawStreamZDC->GetSector(1)+5; // *** ZPC
- else if(detector==4) index = rawStreamZDC->GetSector(1)+12;// *** ZNA
- else if(detector==5) index = rawStreamZDC->GetSector(1)+17;// *** ZPA
+ if(sector!=5){ // Physics signals
+ if(detector==1) index = sector; // *** ZNC
+ else if(detector==2) index = sector+5; // *** ZPC
+ else if(detector==3) index = sector+9; // *** ZEM
+ else if(detector==4) index = sector+12;// *** ZNA
+ else if(detector==5) index = sector+17;// *** ZPA
}
else{ // Reference PMs
index = (detector-1)/3+22;
}
+ //
+ if(index==-1) printf("ERROR in ZDCLASERda.cxx -> det %d quad %d res %d index %d ADC %d\n",
+ detector, sector, rawStreamZDC->GetADCGain(), index, rawStreamZDC->GetADCValue());
- Float_t Pedestal = MeanPed[index];
+ Float_t Pedestal=0.;
+ if(rawStreamZDC->GetADCGain()==0) Pedestal = MeanPedhg[index];
+ else if(rawStreamZDC->GetADCGain()==1) Pedestal = MeanPedlg[index];
+ //
Float_t CorrADC = rawStreamZDC->GetADCValue() - Pedestal;
+ //
+ //printf("\tdet %d sec %d res %d index %d ped %1.0f ADCcorr %1.0f\n",
+ // detector, sector, rawStreamZDC->GetADCGain(), index, Pedestal,CorrADC);
// **** Detector PMs
- if(rawStreamZDC->GetSector(1)!=5 && rawStreamZDC->GetADCGain()==0){
- // ---- side C
- hZNC[rawStreamZDC->GetSector(1)]->Fill(CorrADC);
- hZPC[rawStreamZDC->GetSector(1)]->Fill(CorrADC);
- // ---- side A
- hZNA[rawStreamZDC->GetSector(1)]->Fill(CorrADC);
- hZPA[rawStreamZDC->GetSector(1)]->Fill(CorrADC);
+ if(sector!=5){
+ if(rawStreamZDC->GetADCGain()==0){ // --- High gain chain ---
+ // ---- side C
+ if(detector==1) hZNChg[sector]->Fill(CorrADC);
+ else if(detector==2) hZPChg[sector]->Fill(CorrADC);
+ // ---- side A
+ else if(detector==4) hZNAhg[sector]->Fill(CorrADC);
+ else if(detector==5) hZPAhg[sector]->Fill(CorrADC);
+ // ---- ZEM
+ else if(detector==3){
+ hZEMhg[sector-1]->Fill(CorrADC);
+ }
+ }
+ else if(rawStreamZDC->GetADCGain()==1){ // --- Low gain chain ---
+ // ---- side C
+ if(detector==1) hZNClg[sector]->Fill(CorrADC);
+ else if(detector==2) hZPClg[sector]->Fill(CorrADC);
+ // ---- side A
+ else if(detector==4) hZNAlg[sector]->Fill(CorrADC);
+ else if(detector==5) hZPAlg[sector]->Fill(CorrADC);
+ // ---- ZEM
+ else if(detector==3) hZEMlg[sector-1]->Fill(CorrADC);
+ }
}
// **** Reference PMs
- if(rawStreamZDC->GetSector(1)==5 && rawStreamZDC->GetADCGain()==0){
- // ---- PMRef chain side C
- if(detector==1) hPMRefC->Fill(CorrADC);
- // ---- PMRef side A
- else if(detector==4) hPMRefA->Fill(CorrADC);
- }
+ else if(sector==5){
+ if(rawStreamZDC->GetADCGain()==0){ // --- High gain chain ---
+ // ---- PMRef chain side C
+ if(detector==1) hPMRefChg->Fill(CorrADC);
+ // ---- PMRef side A
+ else if(detector==4) hPMRefAhg->Fill(CorrADC);
+ }
+ else if(rawStreamZDC->GetADCGain()==1){ // --- Low gain chain ---
+ // ---- PMRef chain side C
+ if(detector==1) hPMRefClg->Fill(CorrADC);
+ // ---- PMRef side A
+ else if(detector==4) hPMRefAlg->Fill(CorrADC);
+ }
+ }
}//IsADCDataWord()+NOunderflow+NOoverflow
//
}
delete rawStreamZDC;
}//(if PHYSICS_EVENT)
- nevents_total++;
- /* free resources */
- free(event);
+ /* exit when last event received, no need to wait for TERM signal */
+ else if(eventT==END_OF_RUN) {
+ printf(" -> EOR event detected\n");
+ break;
+ }
+
+
+ nevents_total++;
}
+
+ /* free resources */
+ free(event);
}
/* Analysis of the histograms */
//
- Int_t maxBin[22], nBin[22];
- Float_t xMax[22], maxXval[22], xlow[22];
- Float_t mean[22], sigma[22];
- TF1 *fun[4];
+ Int_t detector[2*kNChannels], quad[2*kNChannels];
+ Int_t maxBin[2*kNChannels], nBin[2*kNChannels];
+ Float_t xMax[2*kNChannels], maxXval[2*kNChannels], xlow[2*kNChannels];
+ Float_t mean[2*kNChannels], sigma[2*kNChannels];
+ for(Int_t t=0; t<2*kNChannels; t++){
+ detector[t] = quad[t] = 0;
+ maxBin[t] = nBin[t] = 0;
+ xMax[t] = maxXval[t] = xlow[t] = 0.;
+ mean[t] = sigma[t] = 0.;
+ }
+ TF1 *fun[2*kNChannels];
+ Int_t atLeastOneHisto=0;
+ // ******** High gain chain ********
for(Int_t k=0; k<5; k++){
// --- ZNC
- maxBin[k] = hZNC[k]->GetMaximumBin();
- nBin[k] = (hZNC[k]->GetXaxis())->GetNbins();
- xMax[k] = (hZNC[k]->GetXaxis())->GetXmax();
+ detector[k] = 1;
+ quad[k] = k;
+ maxBin[k] = hZNChg[k]->GetMaximumBin();
+ nBin[k] = (hZNChg[k]->GetXaxis())->GetNbins();
+ xMax[k] = (hZNChg[k]->GetXaxis())->GetXmax();
if(nBin[k]!=0) maxXval[k] = maxBin[k]*xMax[k]/nBin[k];
- //
if(maxXval[k]-150.<0.) xlow[k]=0.;
else xlow[k] = maxXval[k]-150.;
- hZNC[k]->Fit("gaus","Q","",xlow[k],maxXval[k]+150.);
- fun[k] = hZNC[k]->GetFunction("gaus");
- mean[k] = (Float_t) (fun[k]->GetParameter(1));
- sigma[k] = (Float_t) (fun[k]->GetParameter(2));
+ // checking if at least one histo is fitted
+ if(hZNChg[k]->GetEntries()!=0){
+ atLeastOneHisto=1;
+ //
+ hZNChg[k]->Fit("gaus","Q","",xlow[k],maxXval[k]+150.);
+ fun[k] = hZNChg[k]->GetFunction("gaus");
+ mean[k] = (Float_t) (fun[k]->GetParameter(1));
+ sigma[k] = (Float_t) (fun[k]->GetParameter(2));
+ }
// --- ZPC
- maxBin[k+5] = hZPC[k]->GetMaximumBin();
- nBin[k+5] = (hZPC[k]->GetXaxis())->GetNbins();
- xMax[k+5] = (hZPC[k]->GetXaxis())->GetXmax();
+ detector[k+5] = 2;
+ quad[k+5] = k;
+ maxBin[k+5] = hZPChg[k]->GetMaximumBin();
+ nBin[k+5] = (hZPChg[k]->GetXaxis())->GetNbins();
+ xMax[k+5] = (hZPChg[k]->GetXaxis())->GetXmax();
if(nBin[k+5]!=0) maxXval[k+5] = maxBin[k+5]*xMax[k+5]/nBin[k+5];
- //
if(maxXval[k+5]-150.<0.) xlow[k+5]=0.;
else xlow[k+5] = maxXval[k+5]-150.;
- hZPC[k]->Fit("gaus","Q","",xlow[k+5],maxXval[k+5]+150.);
- fun[k+5] = hZPC[k]->GetFunction("gaus");
- mean[k+5] = (Float_t) (fun[k+5]->GetParameter(1));
- sigma[k+5] = (Float_t) (fun[k+5]->GetParameter(2));
+ if(hZPChg[k]->GetEntries()!=0){
+ atLeastOneHisto=1;
+ //
+ hZPChg[k]->Fit("gaus","Q","",xlow[k+5],maxXval[k+5]+150.);
+ fun[k+5] = hZPChg[k]->GetFunction("gaus");
+ mean[k+5] = (Float_t) (fun[k+5]->GetParameter(1));
+ sigma[k+5] = (Float_t) (fun[k+5]->GetParameter(2));
+ }
+ // --- ZEM1
+ if(k<2){
+ detector[k+10] = 3;
+ quad[k+10] = k+1;
+ maxBin[k+10] = hZEMhg[k]->GetMaximumBin();
+ nBin[k+10] = (hZEMhg[k]->GetXaxis())->GetNbins();
+ xMax[k+10] = (hZEMhg[k]->GetXaxis())->GetXmax();
+ if(nBin[k+10]!=0) maxXval[k+10] = maxBin[k+10]*xMax[k+10]/nBin[k+10];
+ if(maxXval[k+10]-150.<0.) xlow[k+10]=0.;
+ else xlow[k+10] = maxXval[k+10]-150.;
+ if(hZEMhg[k]->GetEntries()!=0){
+ atLeastOneHisto=1;
+ //
+ hZEMhg[k]->Fit("gaus","Q","",xlow[k+10],maxXval[k+10]+150.);
+ fun[k+10] = hZEMhg[k]->GetFunction("gaus");
+ mean[k+10] = (Float_t) (fun[k+10]->GetParameter(1));
+ sigma[k+10] = (Float_t) (fun[k+10]->GetParameter(2));
+ }
+ }
// --- ZNA
- maxBin[k+10] = hZNA[k]->GetMaximumBin();
- nBin[k+10] = (hZNA[k]->GetXaxis())->GetNbins();
- xMax[k+10] = (hZNA[k]->GetXaxis())->GetXmax();
- if(nBin[k+10]!=0) maxXval[k+10] = maxBin[k+10]*xMax[k+10]/nBin[k+10];
- //
- if(maxXval[k+10]-150.<0.) xlow[k+10]=0.;
- else xlow[k+10] = maxXval[k+10]-150.;
- hZNA[k]->Fit("gaus","Q","",xlow[k+10],maxXval[k+10]+150.);
- fun[k+10] = hZNA[k]->GetFunction("gaus");
- mean[k+10] = (Float_t) (fun[k+10]->GetParameter(1));
- sigma[k+10] = (Float_t) (fun[k+10]->GetParameter(2));
+ detector[k+12] = 4;
+ quad[k+12] = k;
+ maxBin[k+12] = hZNAhg[k]->GetMaximumBin();
+ nBin[k+12] = (hZNAhg[k]->GetXaxis())->GetNbins();
+ xMax[k+12] = (hZNAhg[k]->GetXaxis())->GetXmax();
+ if(nBin[k+12]!=0) maxXval[k+12] = maxBin[k+12]*xMax[k+12]/nBin[k+12];
+ if(maxXval[k+12]-150.<0.) xlow[k+12]=0.;
+ else xlow[k+12] = maxXval[k+12]-150.;
+ if(hZNAhg[k]->GetEntries()!=0){
+ atLeastOneHisto=1;
+ //
+ hZNAhg[k]->Fit("gaus","Q","",xlow[k+12],maxXval[k+12]+150.);
+ fun[k+12] = hZNAhg[k]->GetFunction("gaus");
+ mean[k+12] = (Float_t) (fun[k+12]->GetParameter(1));
+ sigma[k+12] = (Float_t) (fun[k+12]->GetParameter(2));
+ }
// --- ZPA
- maxBin[k+15] = hZPA[k]->GetMaximumBin();
- nBin[k+15] = (hZPA[k]->GetXaxis())->GetNbins();
- xMax[k+15] = (hZPA[k]->GetXaxis())->GetXmax();
- if(nBin[k+15]!=0) maxXval[k+15] = maxBin[k+15]*xMax[k+15]/nBin[k+15];
+ detector[k+17] = 4;
+ quad[k+17] = 5;
+ maxBin[k+17] = hZPAhg[k]->GetMaximumBin();
+ nBin[k+17] = (hZPAhg[k]->GetXaxis())->GetNbins();
+ xMax[k+17] = (hZPAhg[k]->GetXaxis())->GetXmax();
+ if(nBin[k+17]!=0) maxXval[k+17] = maxBin[k+17]*xMax[k+17]/nBin[k+17];
+ if(maxXval[k+17]-150.<0.) xlow[k+17]=0.;
+ else xlow[k+17] = maxXval[k+17]-150.;
+ if(hZPAhg[k]->GetEntries()!=0){
+ atLeastOneHisto=1;
+ //
+ hZPAhg[k]->Fit("gaus","Q","",xlow[k+17],maxXval[k+17]+150.);
+ fun[k+17] = hZPAhg[k]->GetFunction("gaus");
+ mean[k+17] = (Float_t) (fun[k+17]->GetParameter(1));
+ sigma[k+17] = (Float_t) (fun[k+17]->GetParameter(2));
+ }
+ }
+ // ~~~~~~~~ PM Ref side C ~~~~~~~~
+ detector[22] = 1;
+ quad[22] = 5;
+ maxBin[22] = hPMRefChg->GetMaximumBin();
+ nBin[22] = (hPMRefChg->GetXaxis())->GetNbins();
+ xMax[22] = (hPMRefChg->GetXaxis())->GetXmax();
+ if(nBin[22]!=0) maxXval[22] = maxBin[22]*xMax[22]/nBin[22];
+ if(maxXval[22]-150.<0.) xlow[22]=0.;
+ else xlow[22] = maxXval[22]-150.;
+ if(hPMRefChg->GetEntries()!=0){
+ atLeastOneHisto=1;
//
- if(maxXval[k+15]-150.<0.) xlow[k+15]=0.;
- else xlow[k+15] = maxXval[k+15]-150.;
- hZPA[k]->Fit("gaus","Q","",xlow[k+15],maxXval[k+15]+150.);
- fun[k+15] = hZPA[k]->GetFunction("gaus");
- mean[k+15] = (Float_t) (fun[k+15]->GetParameter(1));
- sigma[k+15] = (Float_t) (fun[k+15]->GetParameter(2));
-
+ hPMRefChg->Fit("gaus","Q","",xlow[22],maxXval[22]+150.);
+ fun[22] = hPMRefChg->GetFunction("gaus");
+ mean[22] = (Float_t) (fun[22]->GetParameter(1));
+ sigma[22] = (Float_t) (fun[22]->GetParameter(2));
+ }
+ // ~~~~~~~~ PM Ref side A ~~~~~~~~
+ detector[23] = 4;
+ quad[23] = 5;
+ maxBin[23] = hPMRefAhg->GetMaximumBin();
+ nBin[23] = (hPMRefAhg->GetXaxis())->GetNbins();
+ xMax[23] = (hPMRefAhg->GetXaxis())->GetXmax();
+ if(nBin[23]!=0) maxXval[23] = maxBin[23]*xMax[23]/nBin[23];
+ if(maxXval[23]-100.<0.) xlow[23]=0.;
+ else xlow[23] = maxXval[23]-150.;
+ if(hPMRefAhg->GetEntries()!=0){
+ atLeastOneHisto=1;
+ //
+ hPMRefAhg->Fit("gaus","Q","",xlow[23],maxXval[23]+100.);
+ fun[23] = hPMRefAhg->GetFunction("gaus");
+ mean[23] = (Float_t) (fun[23]->GetParameter(1));
+ sigma[23] = (Float_t) (fun[23]->GetParameter(2));
}
+ // ******** Low gain chain ********
+/* Int_t kOffset = 24;
+ for(Int_t k=0; k<5; k++){
+ // --- ZNC
+ detector[k+kOffset] = 1;
+ quad[k+kOffset] = k;
+ maxBin[k+kOffset] = hZNClg[k]->GetMaximumBin();
+ nBin[k+kOffset] = (hZNClg[k]->GetXaxis())->GetNbins();
+ xMax[k+kOffset] = (hZNClg[k]->GetXaxis())->GetXmax();
+ if(nBin[k+kOffset]!=0) maxXval[k+kOffset] = maxBin[k+kOffset]*xMax[k+kOffset]/nBin[k+kOffset];
+ if(maxXval[k+kOffset]-150.<0.) xlow[k+kOffset]=0.;
+ else xlow[k+kOffset] = maxXval[k+kOffset]-150.;
+ if(hZNClg[k]->GetEntries()!=0){
+ atLeastOneHisto=1;
+ //
+ hZNClg[k]->Fit("gaus","Q","",xlow[k+kOffset],maxXval[k+kOffset]+150.);
+ fun[k+kOffset] = hZNClg[k]->GetFunction("gaus");
+ mean[k+kOffset] = (Float_t) (fun[k+kOffset]->GetParameter(1));
+ sigma[k+kOffset] = (Float_t) (fun[k+kOffset]->GetParameter(2));
+ }
+ // --- ZPC
+ detector[k+kOffset+5] = 2;
+ quad[k+kOffset+5] = k;
+ maxBin[k+kOffset+5] = hZPClg[k]->GetMaximumBin();
+ nBin[k+kOffset+5] = (hZPClg[k]->GetXaxis())->GetNbins();
+ xMax[k+kOffset+5] = (hZPClg[k]->GetXaxis())->GetXmax();
+ if(nBin[k+kOffset+5]!=0) maxXval[k+kOffset+5] = maxBin[k+kOffset+5]*xMax[k+kOffset+5]/nBin[k+kOffset+5];
+ if(maxXval[k+kOffset+5]-150.<0.) xlow[k+kOffset+5]=0.;
+ else xlow[k+kOffset+5] = maxXval[k+kOffset+5]-150.;
+ if(hZPClg[k]->GetEntries()!=0){
+ atLeastOneHisto=1;
+ //
+ hZPClg[k]->Fit("gaus","Q","",xlow[k+kOffset+5],maxXval[k+kOffset+5]+150.);
+ fun[k+kOffset+5] = hZPClg[k]->GetFunction("gaus");
+ mean[k+kOffset+5] = (Float_t) (fun[k+kOffset+5]->GetParameter(1));
+ sigma[k+kOffset+5] = (Float_t) (fun[k+kOffset+5]->GetParameter(2));
+ }
+ // --- ZEM1
+ if(k+kOffset<2){
+ detector[k+kOffset+10] = 3;
+ quad[k+kOffset+10] = k+1;
+ maxBin[k+kOffset+10] = hZEMlg[k]->GetMaximumBin();
+ nBin[k+kOffset+10] = (hZEMlg[k]->GetXaxis())->GetNbins();
+ xMax[k+kOffset+10] = (hZEMlg[k]->GetXaxis())->GetXmax();
+ if(nBin[k+kOffset+10]!=0) maxXval[k+kOffset+10] = maxBin[k+kOffset+10]*xMax[k+kOffset+10]/nBin[k+kOffset+10];
+ if(maxXval[k+kOffset+10]-150.<0.) xlow[k+kOffset+10]=0.;
+ else xlow[k+kOffset+10] = maxXval[k+kOffset+10]-150.;
+ if(hZEMlg[k]->GetEntries()!=0){
+ atLeastOneHisto=1;
+ //
+ hZEMlg[k]->Fit("gaus","Q","",xlow[k+kOffset+10],maxXval[k+kOffset+10]+150.);
+ fun[k+kOffset+10] = hZEMlg[k]->GetFunction("gaus");
+ mean[k+kOffset+10] = (Float_t) (fun[k+kOffset+10]->GetParameter(1));
+ sigma[k+kOffset+10] = (Float_t) (fun[k+kOffset+10]->GetParameter(2));
+ }
+ }
+ // --- ZNA
+ detector[k+kOffset+12] = 4;
+ quad[k+kOffset+12] = k;
+ maxBin[k+kOffset+12] = hZNAlg[k]->GetMaximumBin();
+ nBin[k+kOffset+12] = (hZNAlg[k]->GetXaxis())->GetNbins();
+ xMax[k+kOffset+12] = (hZNAlg[k]->GetXaxis())->GetXmax();
+ if(nBin[k+kOffset+12]!=0) maxXval[k+kOffset+12] = maxBin[k+kOffset+12]*xMax[k+kOffset+12]/nBin[k+kOffset+12];
+ if(maxXval[k+kOffset+12]-150.<0.) xlow[k+kOffset+12]=0.;
+ else xlow[k+kOffset+12] = maxXval[k+kOffset+12]-150.;
+ if(hZNAlg[k]->GetEntries()!=0){
+ atLeastOneHisto=1;
+ //
+ hZNAlg[k]->Fit("gaus","Q","",xlow[k+kOffset+12],maxXval[k+kOffset+12]+150.);
+ fun[k+kOffset+12] = hZNAlg[k]->GetFunction("gaus");
+ mean[k+kOffset+12] = (Float_t) (fun[k+kOffset+12]->GetParameter(1));
+ sigma[k+kOffset+12] = (Float_t) (fun[k+kOffset+12]->GetParameter(2));
+ }
+ // --- ZPA
+ detector[k+kOffset+17] = 5;
+ quad[k+kOffset+17] = k;
+ maxBin[k+kOffset+17] = hZPAlg[k]->GetMaximumBin();
+ nBin[k+kOffset+17] = (hZPAlg[k]->GetXaxis())->GetNbins();
+ xMax[k+kOffset+17] = (hZPAlg[k]->GetXaxis())->GetXmax();
+ if(nBin[k+kOffset+17]!=0) maxXval[k+kOffset+17] = maxBin[k+kOffset+17]*xMax[k+kOffset+17]/nBin[k+kOffset+17];
+ if(maxXval[k+kOffset+17]-150.<0.) xlow[k+kOffset+17]=0.;
+ else xlow[k+kOffset+17] = maxXval[k+kOffset+17]-150.;
+ if(hZPAlg[k]->GetEntries()!=0){
+ atLeastOneHisto=1;
+ //
+ hZPAlg[k]->Fit("gaus","Q","",xlow[k+kOffset+17],maxXval[k+kOffset+17]+150.);
+ fun[k+kOffset+17] = hZPAlg[k]->GetFunction("gaus");
+ mean[k+kOffset+17] = (Float_t) (fun[k+kOffset+17]->GetParameter(1));
+ sigma[k+kOffset+17] = (Float_t) (fun[k+kOffset+17]->GetParameter(2));
+ }
+ }
// ~~~~~~~~ PM Ref side C ~~~~~~~~
- maxBin[20] = hPMRefC->GetMaximumBin();
- nBin[20] = (hPMRefC->GetXaxis())->GetNbins();
- xMax[20] = (hPMRefC->GetXaxis())->GetXmax();
- if(nBin[20]!=0) maxXval[20] = maxBin[20]*xMax[20]/nBin[20];
- //
- if(maxXval[20]-150.<0.) xlow[20]=0.;
- else xlow[20] = maxXval[20];
- hPMRefC->Fit("gaus","Q","",xlow[20],maxXval[20]+150.);
- fun[20] = hPMRefC->GetFunction("gaus");
- mean[20] = (Float_t) (fun[20]->GetParameter(1));
- sigma[20] = (Float_t) (fun[20]->GetParameter(2));
-
+ detector[46] = 1;
+ quad[46] = 5;
+ maxBin[46] = hPMRefClg->GetMaximumBin();
+ nBin[46] = (hPMRefClg->GetXaxis())->GetNbins();
+ xMax[46] = (hPMRefClg->GetXaxis())->GetXmax();
+ if(nBin[46]!=0) maxXval[46] = maxBin[46]*xMax[46]/nBin[46];
+ if(maxXval[46]-150.<0.) xlow[46]=0.;
+ else xlow[46] = maxXval[46]-150.;
+ if(hPMRefClg->GetEntries()!=0){
+ atLeastOneHisto=1;
+ //
+ hPMRefClg->Fit("gaus","Q","",xlow[46],maxXval[46]+150.);
+ fun[46] = hPMRefClg->GetFunction("gaus");
+ mean[46] = (Float_t) (fun[46]->GetParameter(1));
+ sigma[46] = (Float_t) (fun[46]->GetParameter(2));
+ }
// ~~~~~~~~ PM Ref side A ~~~~~~~~
- maxBin[21] = hPMRefA->GetMaximumBin();
- nBin[21] = (hPMRefA->GetXaxis())->GetNbins();
- xMax[21] = (hPMRefA->GetXaxis())->GetXmax();
- if(nBin[21]!=0) maxXval[21] = maxBin[21]*xMax[21]/nBin[21];
- //
- if(maxXval[21]-100.<0.) xlow[21]=0.;
- else xlow[21] = maxXval[21];
- hPMRefA->Fit("gaus","Q","",xlow[21],maxXval[21]+100.);
- fun[21] = hPMRefA->GetFunction("gaus");
- mean[21] = (Float_t) (fun[21]->GetParameter(1));
- sigma[21] = (Float_t) (fun[21]->GetParameter(2));
-
+ detector[47] = 4;
+ quad[47] = 5;
+ maxBin[47] = hPMRefAlg->GetMaximumBin();
+ nBin[47] = (hPMRefAlg->GetXaxis())->GetNbins();
+ xMax[47] = (hPMRefAlg->GetXaxis())->GetXmax();
+ if(nBin[47]!=0) maxXval[47] = maxBin[47]*xMax[47]/nBin[47];
+ if(maxXval[47]-100.<0.) xlow[47]=0.;
+ else xlow[47] = maxXval[47]-150.;
+ if(hPMRefAlg->GetEntries()!=0){
+ atLeastOneHisto=1;
+ //
+ hPMRefAlg->Fit("gaus","Q","",xlow[47],maxXval[47]+100.);
+ fun[47] = hPMRefAlg->GetFunction("gaus");
+ mean[47] = (Float_t) (fun[47]->GetParameter(1));
+ sigma[47] = (Float_t) (fun[47]->GetParameter(2));
+ }
+*/
+ if(atLeastOneHisto==0){
+ printf("\n WARNING! Empty LASER histos -> ending DA WITHOUT writing output\n\n");
+ return -1;
+ }
FILE *fileShuttle;
fileShuttle = fopen(LASDATA_FILE,"w");
- for(Int_t i=0; i<22; i++){
- fprintf(fileShuttle,"\t%f\t%f\n",mean[i], sigma[i]);
+ for(Int_t i=0; i<2*kNChannels; i++){
+ fprintf(fileShuttle,"\t%d\t%d\t%f\t%f\n",detector[i],quad[i],mean[i], sigma[i]);
}
//
fclose(fileShuttle);
+
+ /* report progress */
+ daqDA_progressReport(80);
+ //
+ TFile *histofile = new TFile(LASHISTO_FILE,"RECREATE");
+ histofile->cd();
+ for(int j=0; j<5; j++){
+ hZNChg[j]->Write();
+ hZPChg[j]->Write();
+ hZNAhg[j]->Write();
+ hZPAhg[j]->Write();
+ hZNClg[j]->Write();
+ hZPClg[j]->Write();
+ hZNAlg[j]->Write();
+ hZPAlg[j]->Write();
+ if(j<2){
+ hZEMhg[j]->Write();
+ hZEMlg[j]->Write();
+ }
+ }
+ hPMRefChg->Write();
+ hPMRefAhg->Write();
+ hPMRefClg->Write();
+ hPMRefAlg->Write();
+ //
+ histofile->Close();
//
for(Int_t j=0; j<5; j++){
- delete hZNC[j];
- delete hZPC[j];
- delete hZNA[j];
- delete hZPA[j];
+ delete hZNChg[j];
+ delete hZPChg[j];
+ delete hZNAhg[j];
+ delete hZPAhg[j];
+ delete hZNClg[j];
+ delete hZPClg[j];
+ delete hZNAlg[j];
+ delete hZPAlg[j];
+ if(j<2){
+ delete hZEMhg[j];
+ delete hZEMlg[j];
+ }
}
- delete hPMRefC;
- delete hPMRefA;
-
- //delete minuitFit;
- TVirtualFitter::SetFitter(0);
+ delete hPMRefChg;
+ delete hPMRefAhg;
+ delete hPMRefClg;
+ delete hPMRefAlg;
/* write report */
fprintf(fp,"Run #%s, received %d physics events out of %d\n",getenv("DATE_RUN_NUMBER"),nevents_physics,nevents_total);
/* report progress */
daqDA_progressReport(90);
-
+
/* store the result file on FES */
- status = daqDA_FES_storeFile(MAPDATA_FILE,MAPDATA_FILE);
+ // [1] File with mapping
+ status = daqDA_FES_storeFile(MAPDATA_FILE, "MAPPING");
if(status){
printf("Failed to export file : %d\n",status);
return -1;
}
//
- status = daqDA_FES_storeFile(LASDATA_FILE,LASDATA_FILE);
+ // [2] File with laser data
+ status = daqDA_FES_storeFile(LASDATA_FILE, "LASERDATA");
if(status){
printf("Failed to export file : %d\n",status);
return -1;
}
+ // [3] File with laser histos
+ status = daqDA_FES_storeFile(LASHISTO_FILE, "LASERHISTOS");
+ if(status){
+ printf("Failed to export pedestal histos file to DAQ FES\n");
+ return -1;
+ }
/* report progress */
daqDA_progressReport(100);
-
return status;
}