[u/mrichter/AliRoot.git] / ZDC / ZDCEMDda.cxx

/*

This program reads the DAQ data files passed as argument using the monitoring library.

The program reports about its processing progress.

Messages on stdout are exported to DAQ log system.

DA for ZDC standalone CALIBRATION_EMD runs

Contact: Chiara.Oppedisano@to.infn.it
Link: 
Run Type: CALIBRATION_EMD_RUN
DA Type: LDC
Number of events needed: at least ~5*10^3
Input Files: ZDCPedestal.dat
Output Files: ZDCEMDCalib.dat, ZDCChMapping.dat
Trigger Types Used: Standalone Trigger

*/
#define PEDDATA_FILE  "ZDCPedestal.dat"
#define MAPDATA_FILE  "ZDCChMapping.dat"
#define ENCALIBDATA_FILE   "ZDCEnergyCalib.dat"
#define TOWCALIBDATA_FILE  "ZDCTowerCalib.dat"

#include <stdio.h>
#include <stdlib.h>
#include <Riostream.h>
#include <Riostream.h>

// DATE
#include <daqDA.h>
#include <event.h>
#include <monitor.h>

//ROOT
#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>
#include <AliRawEventHeaderBase.h>
#include <AliZDCRawStream.h>


/* Main routine
      Arguments: 
      1- monitoring data source
*/
int main(int argc, char **argv) {
  
  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 = 9;
  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;
  }
      
  Int_t itdcCh=0;
  Int_t tdcMod[kNScChannels], tdcCh[kNScChannels], tdcSigCode[kNScChannels];
  Int_t tdcDet[kNScChannels], tdcSec[kNScChannels];
  for(Int_t y=0; y<kNScChannels; y++){
    tdcMod[y]=tdcCh[y]=tdcSigCode[y]=tdcDet[y]=tdcSec[y]=-1;
  }

  /* log start of process */
  printf("ZDC EMD program started\n");  

  /* check that we got some arguments = list of files */
  if (argc<2) {
    printf("Wrong number of arguments\n");
    return -1;
  }
  
  // --- Preparing histos for EM dissociation spectra
  //
  TH1F::AddDirectory(0);
  TH1F* histoEMDCorr[4];
  //
  //char namhistr[50];
  char namhistc[50];
  for(Int_t i=0; i<4; i++) {
     if(i==0) sprintf(namhistc,"ZN%d-EMDCorr",i+1);
     else if(i==1) sprintf(namhistc,"ZP%d-EMDCorr",i);
     else if(i==2) sprintf(namhistc,"ZN%d-EMDCorr",i);
     else if(i==3) sprintf(namhistc,"ZP%d-EMDCorr",i-1);
     histoEMDCorr[i] = new TH1F(namhistc,namhistc,200,0.,2000.);
  }

   // --- Preparing histos for tower inter-calibration
  //
/*  TH1F* histZNCtow[4]; TH1F* histZPCtow[4];
  TH1F* histZNAtow[4]; TH1F* histZPAtow[4];
  //
  char namhistznc[50], namhistzpc[50];
  char namhistzna[50], namhistzpa[50];
  for(Int_t i=0; i<4; i++) {
     sprintf(namhistznc,"ZNC-tow%d",i+1);
     sprintf(namhistzpc,"ZPC-tow%d",i+1);
     sprintf(namhistzna,"ZNA-tow%d",i+1);
     sprintf(namhistzpa,"ZPA-tow%d",i+1);
     //
     histZNCtow[i] = new TH1F(namhistznc,namhistznc,100,0.,4000.);
     histZPCtow[i] = new TH1F(namhistzpc,namhistzpc,100,0.,4000.);
     histZNAtow[i] = new TH1F(namhistzna,namhistzna,100,0.,4000.);
     histZPAtow[i] = new TH1F(namhistzpa,namhistzpa,100,0.,4000.);
  }
*/  
  /* open result file */
  FILE *fp=NULL;
  fp=fopen("./result.txt","a");
  if (fp==NULL) {
    printf("Failed to open file\n");
    return -1;
  }
  /* report progress */
  daqDA_progressReport(10);

  // *** To analyze EMD events you MUST have a pedestal data file!!!
  // *** -> check if a pedestal run has been analyzed
  int read = 0;
  read = daqDA_DB_getFile(PEDDATA_FILE,PEDDATA_FILE);
  if(read){
    printf("\t ERROR!!! ZDCPedestal.dat file NOT FOUND in DAQ db!!!\n");
    return -1;
  }
  else printf("\t ZDCPedestal.dat file retrieved from DAQ db\n");
  
  FILE *filePed = fopen(PEDDATA_FILE,"r");
  if (filePed==NULL) {
    printf("\t ERROR!!! Can't open ZDCPedestal.dat file!!!\n");
    return -1;
  }

  // 144 = 48 in-time + 48 out-of-time + 48 correlations
  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!!!!!!
  // ***************************************************
  //
  for(int jj=0; jj<6*kNChannels; jj++){
    for(int ii=0; ii<2; ii++){
       fscanf(filePed,"%f",&readValues[ii][jj]);
    }
    if(jj<kNChannels){
      MeanPedhg[jj] = readValues[0][jj];
      //printf("\t MeanPedhg[%d] = %1.1f\n",jj, MeanPedhg[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>4*kNChannels){
      CorrCoeff0[jj-4*kNChannels] = readValues[0][jj]; 
      CorrCoeff1[jj-4*kNChannels] = readValues[1][jj];;
    }
  }
  
  FILE *mapFile4Shuttle;

  /* report progress */
  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++){
   
    status=monitorSetDataSource( argv[n] );
    if (status!=0) {
      printf("monitorSetDataSource() failed : %s\n",monitorDecodeError(status));
      return -1;
    }

    /* report progress */
    /* in this example, indexed on the number of files */
    daqDA_progressReport(20+70*n/argc);

    /* read the file */
    for(;;){

      /* get next event */
      status=monitorGetEventDynamic((void **)&event);
      if(status==MON_ERR_EOF) break; /* end of monitoring file has been reached */
      if(status!=0) {
        printf("monitorGetEventDynamic() failed : %s\n",monitorDecodeError(status));
        return -1;
      }

      /* retry if got no event */
      if(event==NULL) {
        break;
      }
      
      // Initalize raw-data reading and decoding
      AliRawReader *reader = new AliRawReaderDate((void*)event);
      reader->Select("ZDC");
      // --- Reading event header
      //UInt_t evtype = reader->GetType();
      //printf("\n\t ZDCEMDda -> ev. type %d\n",evtype);
      //printf("\t ZDCEMDda -> run # %d\n",reader->GetRunNumber());
      //
      AliZDCRawStream *rawStreamZDC = new AliZDCRawStream(reader);
        

      /* use event - here, just write event id to result file */
      eventT=event->eventType;
      
      if(eventT==START_OF_DATA){

	iMod=-1; ich=0; iScCh=0; itdcCh=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->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++;
	      }
	      else if(modType[iMod]==6 && modGeo[iMod]==4){ // ZDC TDC mapping --------------------
	        tdcMod[itdcCh]     = rawStreamZDC->GetTDCModFromMap(itdcCh);
	        tdcCh[itdcCh]      = rawStreamZDC->GetTDCChFromMap(itdcCh);
	        tdcSigCode[itdcCh] = rawStreamZDC->GetTDCSignFromMap(itdcCh);
	        itdcCh++;
	      }
	    }
 	  }
	  // 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("  EMD 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("  EMD 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<kNScChannels; is++){
	     fprintf(mapFile4Shuttle,"\t%d\t%d\t%d\t%d\n",
	       is,tdcMod[is],tdcCh[is],tdcSigCode[is]);
 	     //if(tdcMod[is]!=-1) printf("  Mapping DA -> %d TDC: mod %d ch %d, code %d\n",
	     //  is,tdcMod[is],tdcCh[is],tdcSigCode[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("  EMD DA -> Module mapping: geo %d type %d #ch %d\n",
	     //  modGeo[is],modType[is],modNCh[is]);
	  }
	  
	}
        fclose(mapFile4Shuttle);
      }// SOD event
    
     else if(eventT==PHYSICS_EVENT){
      // --- Reading data header
      reader->ReadHeader();
      const AliRawDataHeader* header = reader->GetDataHeader();
      if(header){
         UChar_t message = header->GetAttributes();
	 if((message & 0x70) == 0x70){ // DEDICATED EMD RUN
	    //printf("\t CALIBRATION_EMD_RUN raw data found\n");
	 }
	 else{
	    // Temporary commented to validate DA with simulated data!!!
	    //printf("\t NO CALIBRATION_EMD_RUN raw data found\n");
	    //return -1;
	 }
      }
      else{
         printf("\t ATTENTION! No Raw Data Header found!!!\n");
         return -1;
      }
      
      rawStreamZDC->SetSODReading(kTRUE);

      if (!rawStreamZDC->Next()) printf(" \t No raw data found!! ");
      //
      // ----- Setting ch. mapping -----
      for(Int_t jk=0; jk<2*kNChannels; jk++){
        rawStreamZDC->SetMapADCMod(jk, adcMod[jk]);
        rawStreamZDC->SetMapADCCh(jk, adcCh[jk]);
        rawStreamZDC->SetMapADCSig(jk, sigCode[jk]);
        rawStreamZDC->SetMapDet(jk, det[jk]);
        rawStreamZDC->SetMapTow(jk, sec[jk]);
      }
      //
      Float_t ZDCCorrADC[4], ZDCCorrADCSum[4];
      for(Int_t g=0; g<4; g++){
           ZDCCorrADCSum[g] = 0.;
	   ZDCCorrADC[g] = 0.;
      }

      //
      while(rawStreamZDC->Next()){
	Int_t detID = rawStreamZDC->GetSector(0);
	Int_t quad = rawStreamZDC->GetSector(1);
	
	if((rawStreamZDC->IsADCDataWord()) && !(rawStreamZDC->IsUnderflow())
	   && !(rawStreamZDC->IsOverflow()) && (detID!=-1) && (detID!=3) 
	   && (rawStreamZDC->GetADCGain() == 1) && // Selecting LOW RES ch.s
           (rawStreamZDC->GetADCModule()>=kFirstADCGeo && rawStreamZDC->GetADCModule()<=kLastADCGeo)){
	  
	  // Taking LOW RES channels -> ch.+kNChannels !!!!
	  Int_t DetIndex=999, PedIndex=999;
	  // Not PMRef
	  if(quad!=5){ 
	    if(detID == 1){
	      DetIndex = detID-1;
	      PedIndex = quad; 
	    }
	    else if(detID == 2){
	      DetIndex = detID-1;
	      PedIndex = quad+5;
	    }
	    else if(detID == 4){
	      DetIndex = detID-2;
	      PedIndex = quad+12;
	    }
	    else if(detID == 5){
	      DetIndex = detID-2;
	      PedIndex = quad+17;
	    }
	    // Mean pedestal subtraction 
	    Float_t Pedestal = MeanPedlg[PedIndex];
	    // Pedestal subtraction from correlation with out-of-time signals
	    //Float_t Pedestal = CorrCoeff0[PedIndex]+CorrCoeff1[PedIndex]*MeanPedOOT[PedIndex];
	    
	    // Run 2010 -> we decide to fit only PMCs
/*	    if(DetIndex!=999 || PedIndex!=999){ 
	      if(quad==0){ 
	        Float_t corrADCval = (rawStreamZDC->GetADCValue()) - Pedestal;
		if(detID==1 || detID==2) histoEMDCorr[detID-1]->Fill(corrADCval);
		else if(detID==4 || detID==5) histoEMDCorr[detID-2]->Fill(corrADCval);
	      }
	    }
*/
	    if(DetIndex!=999 || PedIndex!=999){ 
	      //
	      ZDCCorrADC[DetIndex] = (rawStreamZDC->GetADCValue()) - Pedestal;
	      ZDCCorrADCSum[DetIndex] += ZDCCorrADC[DetIndex];
	      //
	      /*printf("\t det %d quad %d res %d pedInd %d "
	         "Pedestal %1.0f -> ADCCorr = %d ZDCCorrADCSum = %d\n", 
	         detID,quad,rawStreamZDC->GetADCGain(),PedIndex,Pedestal, 
	         (Int_t) ZDCCorrADC[DetIndex],(Int_t) ZDCCorrADCSum[DetIndex]);
	      */	 
	    }
	    // Not common PM 
	    /*if(quad!=0){
	      Float_t corrADCval = (rawStreamZDC->GetADCValue()) - Pedestal;
	      if(detID==1)      histZNCtow[quad-1]->Fill(corrADCval);
	      else if(detID==2) histZPCtow[quad-1]->Fill(corrADCval);
	      else if(detID==4) histZNAtow[quad-1]->Fill(corrADCval);
	      else if(detID==5) histZPAtow[quad-1]->Fill(corrADCval);
	      //
	      //printf("\t det %d tow %d fill histo w. value %1.0f\n", 
	      //  detID,quad,corrADCval);
	    }*/

	    if(DetIndex==999 || PedIndex==999) 
	       printf(" WARNING! Detector a/o pedestal index are WRONG!!!\n");
 
	  }//quad!=5
	}//IsADCDataWord()
	
       }
       //
       nevents_physics++;
       //
       delete reader;
       delete rawStreamZDC;
       //
       for(Int_t j=0; j<4; j++) histoEMDCorr[j]->Fill(ZDCCorrADCSum[j]);

    }//(if PHYSICS_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 */
  //
  FILE *fileShuttle1 = fopen(ENCALIBDATA_FILE,"w");
  //
  Int_t BinMax[4]={0,0,0,0};
  Float_t YMax[4]={0.,0.,0.,0.};
  Int_t NBinsx[4]={0,0,0,0};
  Float_t MeanFitVal[4]={1.,1.,1.,1.};
  TF1 *fitfun[4];
  for(Int_t k=0; k<4; k++){
     if(histoEMDCorr[k]->GetEntries()!=0 && histoEMDCorr[k]->GetMean()>0){
       BinMax[k] = histoEMDCorr[k]->GetMaximumBin();
       //printf("\n\t histoEMDCorr[%d]: BinMax = %d", k, BinMax[k]);
       if(BinMax[k]<=1){
         printf("\n WARNING! Something wrong with det %d histo -> calibration coeff. set to 1\n\n", k);
         continue;
       }
       // 
       YMax[k] = (histoEMDCorr[k]->GetXaxis())->GetXmax();
       NBinsx[k] = (histoEMDCorr[k]->GetXaxis())->GetNbins();
       //printf(" ChXMax = %f\n", BinMax[k]*YMax[k]/NBinsx[k]);
       histoEMDCorr[k]->Fit("gaus","Q","",BinMax[k]*YMax[k]/NBinsx[k]*0.7,BinMax[k]*YMax[k]/NBinsx[k]*1.25);
       fitfun[k] = histoEMDCorr[k]->GetFunction("gaus");
       MeanFitVal[k] = (Float_t) (fitfun[k]->GetParameter(1));
       //printf("\t Mean Value from gaussian fit = %f\n", MeanFitVal[k]);
     }
  }
  //
  Float_t CalibCoeff[6];     
  //
  for(Int_t j=0; j<6; j++){
     if(j<4){
       CalibCoeff[j] = MeanFitVal[j];
       fprintf(fileShuttle1,"\t%f\n",CalibCoeff[j]);
     }
     // ZEM energy calib. coeff. = 1
     else if(j==4 || j==5){
       CalibCoeff[j] = 1.; 
       fprintf(fileShuttle1,"\t%f\n",CalibCoeff[j]);
     }
  }
  fclose(fileShuttle1);
 
  FILE *fileShuttle2 = fopen(TOWCALIBDATA_FILE,"w");
  //Float_t meanvalznc[4], meanvalzpc[4], meanvalzna[4], meanvalzpa[4];
  for(Int_t j=0; j<4; j++){
     /*if(histZNCtow[j]->GetEntries() == 0){
       printf("\n WARNING! Empty histos -> ending DA WITHOUT writing output\n\n");
       return -1;
     } 
     meanvalznc[j] = histZNCtow[j]->GetMean();
     meanvalzpc[j] = histZPCtow[j]->GetMean();
     meanvalzna[j] = histZNAtow[j]->GetMean();
     meanvalzpa[j] = histZPAtow[j]->GetMean();*/
     
     // Note -> For the moment the inter-calibration coeff. are set to 1 
     for(Int_t k=0; k<5; k++){  
       Float_t icoeff = 1.;
       fprintf(fileShuttle2,"\t%f",icoeff);
       if(k==5) fprintf(fileShuttle2,"\n");
     }
  }
  //
  /*if(meanvalznc[1]!=0 && meanvalznc[2]!=0 && meanvalznc[3]!=0 && 
     meanvalzpc[1]!=0 && meanvalzpc[2]!=0 && meanvalzpc[3]!=0 &&
     meanvalzna[1]!=0 && meanvalzna[2]!=0 && meanvalzna[3]!=0 &&
     meanvalzpa[1]!=0 && meanvalzpa[2]!=0 && meanvalzpa[3]!=0){
    fprintf(fileShuttle2,"\t%f\t%f\t%f\t%f\n",
  	1.0,meanvalznc[0]/meanvalznc[1],meanvalznc[0]/meanvalznc[2],meanvalznc[0]/meanvalznc[3]);
    fprintf(fileShuttle2,"\t%f\t%f\t%f\t%f\n",
  	1.0,meanvalzpc[0]/meanvalzpc[1],meanvalzpc[0]/meanvalzpc[2],meanvalzpc[0]/meanvalzpc[3]);
    fprintf(fileShuttle2,"\t%f\t%f\t%f\t%f\n",
  	1.0,meanvalzna[0]/meanvalzna[1],meanvalzpc[0]/meanvalzna[2],meanvalzpc[0]/meanvalzna[3]);
    fprintf(fileShuttle2,"\t%f\t%f\t%f\t%f\n",
  	1.0,meanvalzpa[0]/meanvalzpa[1],meanvalzpc[0]/meanvalzpa[2],meanvalzpc[0]/meanvalzpa[3]);
  }
  else{
    printf("\n Tower intercalib. coeff. CAN'T be calculated (some mean values are ZERO)!!!\n\n");
    return -1;
  }*/
  fclose(fileShuttle2);
  
  for(Int_t ij=0; ij<4; ij++){
    delete histoEMDCorr[ij];
  }
  
  //delete minuitFit;
  TVirtualFitter::SetFitter(0);

  /* write report */
  fprintf(fp,"Run #%s, received %d physics events out of %d\n",getenv("DATE_RUN_NUMBER"),nevents_physics,nevents_total);

  /* close result file */
  fclose(fp);
  
  /* report progress */
  daqDA_progressReport(90);

  /* store the result file on FES */
  status = daqDA_FES_storeFile(MAPDATA_FILE, "MAPPING");
  if(status){
    printf("Failed to export file : %d\n",status);
    return -1;
  }
  //
  status = daqDA_FES_storeFile(ENCALIBDATA_FILE, "EMDENERGYCALIB");
  if(status){
    printf("Failed to export file : %d\n",status);
    return -1;
  }
  //
  status = daqDA_FES_storeFile(TOWCALIBDATA_FILE, "EMDTOWERCALIB");
  if(status){
    printf("Failed to export file : %d\n",status);
    return -1;
  }

  /* report progress */
  daqDA_progressReport(100);

  return status;
}
Commit	Line	Data
	1	/*
	2
	3	This program reads the DAQ data files passed as argument using the monitoring library.
	4
	5	The program reports about its processing progress.
	6
	7	Messages on stdout are exported to DAQ log system.
	8
	9	DA for ZDC standalone CALIBRATION_EMD runs
	10
	11	Contact: Chiara.Oppedisano@to.infn.it
	12	Link:
	13	Run Type: CALIBRATION_EMD_RUN
	14	DA Type: LDC
	15	Number of events needed: at least ~5*10^3
	16	Input Files: ZDCPedestal.dat
	17	Output Files: ZDCEMDCalib.dat, ZDCChMapping.dat
	18	Trigger Types Used: Standalone Trigger
	19
	20	*/
	21	#define PEDDATA_FILE "ZDCPedestal.dat"
	22	#define MAPDATA_FILE "ZDCChMapping.dat"
	23	#define ENCALIBDATA_FILE "ZDCEnergyCalib.dat"
	24	#define TOWCALIBDATA_FILE "ZDCTowerCalib.dat"
	25
	26	#include <stdio.h>
	27	#include <stdlib.h>
	28	#include <Riostream.h>
	29	#include <Riostream.h>
	30
	31	// DATE
	32	#include <daqDA.h>
	33	#include <event.h>
	34	#include <monitor.h>
	35
	36	//ROOT
	37	#include <TROOT.h>
	38	#include <TPluginManager.h>
	39	#include <TH1F.h>
	40	#include <TF1.h>
	41	#include <TFile.h>
	42	#include <TFitter.h>
	43	#include "TMinuitMinimizer.h"
	44
	45	//AliRoot
	46	#include <AliRawReaderDate.h>
	47	#include <AliRawEventHeaderBase.h>
	48	#include <AliZDCRawStream.h>
	49
	50
	51	/* Main routine
	52	Arguments:
	53	1- monitoring data source
	54	*/
	55	int main(int argc, char **argv) {
	56
	57	gROOT->GetPluginManager()->AddHandler("TVirtualStreamerInfo",
	58	"*",
	59	"TStreamerInfo",
	60	"RIO",
	61	"TStreamerInfo()");
	62
	63	TMinuitMinimizer m;
	64	gROOT->GetPluginManager()->AddHandler("ROOT::Math::Minimizer", "Minuit","TMinuitMinimizer",
	65	"Minuit", "TMinuitMinimizer(const char *)");
	66	TVirtualFitter::SetDefaultFitter("Minuit");
	67
	68	int status = 0;
	69	int const kNModules = 9;
	70	int const kNChannels = 24;
	71	int const kNScChannels = 32;
	72	Int_t kFirstADCGeo=0, kLastADCGeo=1; // NO out-of-time signals!!!
	73
	74	Int_t iMod=-1;
	75	Int_t modGeo[kNModules], modType[kNModules],modNCh[kNModules];
	76	for(Int_t kl=0; kl<kNModules; kl++){
	77	modGeo[kl]=modType[kl]=modNCh[kl]=0;
	78	}
	79
	80	Int_t ich=0;
	81	Int_t adcMod[2kNChannels], adcCh[2kNChannels], sigCode[2*kNChannels];
	82	Int_t det[2kNChannels], sec[2kNChannels];
	83	for(Int_t y=0; y<2*kNChannels; y++){
	84	adcMod[y]=adcCh[y]=sigCode[y]=det[y]=sec[y]=0;
	85	}
	86
	87	Int_t iScCh=0;
	88	Int_t scMod[kNScChannels], scCh[kNScChannels], scSigCode[kNScChannels];
	89	Int_t scDet[kNScChannels], scSec[kNScChannels];
	90	for(Int_t y=0; y<kNScChannels; y++){
	91	scMod[y]=scCh[y]=scSigCode[y]=scDet[y]=scSec[y]=0;
	92	}
	93
	94	Int_t itdcCh=0;
	95	Int_t tdcMod[kNScChannels], tdcCh[kNScChannels], tdcSigCode[kNScChannels];
	96	Int_t tdcDet[kNScChannels], tdcSec[kNScChannels];
	97	for(Int_t y=0; y<kNScChannels; y++){
	98	tdcMod[y]=tdcCh[y]=tdcSigCode[y]=tdcDet[y]=tdcSec[y]=-1;
	99	}
	100
	101	/* log start of process */
	102	printf("ZDC EMD program started\n");
	103
	104	/* check that we got some arguments = list of files */
	105	if (argc<2) {
	106	printf("Wrong number of arguments\n");
	107	return -1;
	108	}
	109
	110	// --- Preparing histos for EM dissociation spectra
	111	//
	112	TH1F::AddDirectory(0);
	113	TH1F* histoEMDCorr[4];
	114	//
	115	//char namhistr[50];
	116	char namhistc[50];
	117	for(Int_t i=0; i<4; i++) {
	118	if(i==0) sprintf(namhistc,"ZN%d-EMDCorr",i+1);
	119	else if(i==1) sprintf(namhistc,"ZP%d-EMDCorr",i);
	120	else if(i==2) sprintf(namhistc,"ZN%d-EMDCorr",i);
	121	else if(i==3) sprintf(namhistc,"ZP%d-EMDCorr",i-1);
	122	histoEMDCorr[i] = new TH1F(namhistc,namhistc,200,0.,2000.);
	123	}
	124
	125	// --- Preparing histos for tower inter-calibration
	126	//
	127	/* TH1F* histZNCtow[4]; TH1F* histZPCtow[4];
	128	TH1F* histZNAtow[4]; TH1F* histZPAtow[4];
	129	//
	130	char namhistznc[50], namhistzpc[50];
	131	char namhistzna[50], namhistzpa[50];
	132	for(Int_t i=0; i<4; i++) {
	133	sprintf(namhistznc,"ZNC-tow%d",i+1);
	134	sprintf(namhistzpc,"ZPC-tow%d",i+1);
	135	sprintf(namhistzna,"ZNA-tow%d",i+1);
	136	sprintf(namhistzpa,"ZPA-tow%d",i+1);
	137	//
	138	histZNCtow[i] = new TH1F(namhistznc,namhistznc,100,0.,4000.);
	139	histZPCtow[i] = new TH1F(namhistzpc,namhistzpc,100,0.,4000.);
	140	histZNAtow[i] = new TH1F(namhistzna,namhistzna,100,0.,4000.);
	141	histZPAtow[i] = new TH1F(namhistzpa,namhistzpa,100,0.,4000.);
	142	}
	143	*/
	144	/* open result file */
	145	FILE *fp=NULL;
	146	fp=fopen("./result.txt","a");
	147	if (fp==NULL) {
	148	printf("Failed to open file\n");
	149	return -1;
	150	}
	151	/* report progress */
	152	daqDA_progressReport(10);
	153
	154	// *** To analyze EMD events you MUST have a pedestal data file!!!
	155	// *** -> check if a pedestal run has been analyzed
	156	int read = 0;
	157	read = daqDA_DB_getFile(PEDDATA_FILE,PEDDATA_FILE);
	158	if(read){
	159	printf("\t ERROR!!! ZDCPedestal.dat file NOT FOUND in DAQ db!!!\n");
	160	return -1;
	161	}
	162	else printf("\t ZDCPedestal.dat file retrieved from DAQ db\n");
	163
	164	FILE *filePed = fopen(PEDDATA_FILE,"r");
	165	if (filePed==NULL) {
	166	printf("\t ERROR!!! Can't open ZDCPedestal.dat file!!!\n");
	167	return -1;
	168	}
	169
	170	// 144 = 48 in-time + 48 out-of-time + 48 correlations
	171	Float_t readValues[2][6*kNChannels];
	172	Float_t MeanPedhg[kNChannels], MeanPedlg[kNChannels];
	173	Float_t CorrCoeff0[2kNChannels], CorrCoeff1[2kNChannels];
	174	// ***************************************************
	175	// Unless we have a narrow correlation to fit we
	176	// don't fit and store in-time vs. out-of-time
	177	// histograms -> mean pedstal subtracted!!!!!!
	178	// ***************************************************
	179	//
	180	for(int jj=0; jj<6*kNChannels; jj++){
	181	for(int ii=0; ii<2; ii++){
	182	fscanf(filePed,"%f",&readValues[ii][jj]);
	183	}
	184	if(jj<kNChannels){
	185	MeanPedhg[jj] = readValues[0][jj];
	186	//printf("\t MeanPedhg[%d] = %1.1f\n",jj, MeanPedhg[jj]);
	187	}
	188	else if(jj>=kNChannels && jj<2*kNChannels){
	189	MeanPedlg[jj-kNChannels] = readValues[0][jj];
	190	//printf("\t MeanPedlg[%d] = %1.1f\n",jj-kNChannels, MeanPedlg[jj-kNChannels]);
	191	}
	192	else if(jj>4*kNChannels){
	193	CorrCoeff0[jj-4*kNChannels] = readValues[0][jj];
	194	CorrCoeff1[jj-4*kNChannels] = readValues[1][jj];;
	195	}
	196	}
	197
	198	FILE *mapFile4Shuttle;
	199
	200	/* report progress */
	201	daqDA_progressReport(20);
	202
	203
	204	/* init some counters */
	205	int nevents_physics=0;
	206	int nevents_total=0;
	207
	208	struct eventHeaderStruct *event;
	209	eventTypeType eventT;
	210
	211	/* read the data files */
	212	int n;
	213	for(n=1;n<argc;n++){
	214
	215	status=monitorSetDataSource( argv[n] );
	216	if (status!=0) {
	217	printf("monitorSetDataSource() failed : %s\n",monitorDecodeError(status));
	218	return -1;
	219	}
	220
	221	/* report progress */
	222	/* in this example, indexed on the number of files */
	223	daqDA_progressReport(20+70*n/argc);
	224
	225	/* read the file */
	226	for(;;){
	227
	228	/* get next event */
	229	status=monitorGetEventDynamic((void **)&event);
	230	if(status==MON_ERR_EOF) break; /* end of monitoring file has been reached */
	231	if(status!=0) {
	232	printf("monitorGetEventDynamic() failed : %s\n",monitorDecodeError(status));
	233	return -1;
	234	}
	235
	236	/* retry if got no event */
	237	if(event==NULL) {
	238	break;
	239	}
	240
	241	// Initalize raw-data reading and decoding
	242	AliRawReader reader = new AliRawReaderDate((void)event);
	243	reader->Select("ZDC");
	244	// --- Reading event header
	245	//UInt_t evtype = reader->GetType();
	246	//printf("\n\t ZDCEMDda -> ev. type %d\n",evtype);
	247	//printf("\t ZDCEMDda -> run # %d\n",reader->GetRunNumber());
	248	//
	249	AliZDCRawStream *rawStreamZDC = new AliZDCRawStream(reader);
	250
	251
	252	/* use event - here, just write event id to result file */
	253	eventT=event->eventType;
	254
	255	if(eventT==START_OF_DATA){
	256
	257	iMod=-1; ich=0; iScCh=0; itdcCh=0;
	258
	259	rawStreamZDC->SetSODReading(kTRUE);
	260
	261	// --------------------------------------------------------
	262	// --- Writing ascii data file for the Shuttle preprocessor
	263	mapFile4Shuttle = fopen(MAPDATA_FILE,"w");
	264	if(!rawStreamZDC->Next()) printf(" \t No raw data found!! \n");
	265	else{
	266	while((rawStreamZDC->Next())){
	267	if(rawStreamZDC->IsHeaderMapping()){ // mapping header
	268	iMod++;
	269	modGeo[iMod] = rawStreamZDC->GetADCModule();
	270	modType[iMod] = rawStreamZDC->GetModType();
	271	modNCh[iMod] = rawStreamZDC->GetADCNChannels();
	272	}
	273	if(rawStreamZDC->IsChMapping()){
	274	if(modType[iMod]==1){ // ADC mapping ----------------------
	275	adcMod[ich] = rawStreamZDC->GetADCModFromMap(ich);
	276	adcCh[ich] = rawStreamZDC->GetADCChFromMap(ich);
	277	sigCode[ich] = rawStreamZDC->GetADCSignFromMap(ich);
	278	det[ich] = rawStreamZDC->GetDetectorFromMap(ich);
	279	sec[ich] = rawStreamZDC->GetTowerFromMap(ich);
	280	ich++;
	281	}
	282	else if(modType[iMod]==2){ //VME scaler mapping --------------------
	283	scMod[iScCh] = rawStreamZDC->GetScalerModFromMap(iScCh);
	284	scCh[iScCh] = rawStreamZDC->GetScalerChFromMap(iScCh);
	285	scSigCode[iScCh] = rawStreamZDC->GetScalerSignFromMap(iScCh);
	286	scDet[iScCh] = rawStreamZDC->GetScDetectorFromMap(iScCh);
	287	scSec[iScCh] = rawStreamZDC->GetScTowerFromMap(iScCh);
	288	iScCh++;
	289	}
	290	else if(modType[iMod]==6 && modGeo[iMod]==4){ // ZDC TDC mapping --------------------
	291	tdcMod[itdcCh] = rawStreamZDC->GetTDCModFromMap(itdcCh);
	292	tdcCh[itdcCh] = rawStreamZDC->GetTDCChFromMap(itdcCh);
	293	tdcSigCode[itdcCh] = rawStreamZDC->GetTDCSignFromMap(itdcCh);
	294	itdcCh++;
	295	}
	296	}
	297	}
	298	// Writing data on output FXS file
	299	for(Int_t is=0; is<2*kNChannels; is++){
	300	fprintf(mapFile4Shuttle,"\t%d\t%d\t%d\t%d\t%d\t%d\n",
	301	is,adcMod[is],adcCh[is],sigCode[is],det[is],sec[is]);
	302	//printf(" EMD DA -> %d ADC: mod %d ch %d, code %d det %d, sec %d\n",
	303	// is,adcMod[is],adcCh[is],sigCode[is],det[is],sec[is]);
	304	}
	305	for(Int_t is=0; is<kNScChannels; is++){
	306	fprintf(mapFile4Shuttle,"\t%d\t%d\t%d\t%d\t%d\t%d\n",
	307	is,scMod[is],scCh[is],scSigCode[is],scDet[is],scSec[is]);
	308	//printf(" EMD DA -> %d Scaler: mod %d ch %d, code %d det %d, sec %d\n",
	309	// is,scMod[is],scCh[is],scSigCode[is],scDet[is],scSec[is]);
	310	}
	311	for(Int_t is=0; is<kNScChannels; is++){
	312	fprintf(mapFile4Shuttle,"\t%d\t%d\t%d\t%d\n",
	313	is,tdcMod[is],tdcCh[is],tdcSigCode[is]);
	314	//if(tdcMod[is]!=-1) printf(" Mapping DA -> %d TDC: mod %d ch %d, code %d\n",
	315	// is,tdcMod[is],tdcCh[is],tdcSigCode[is]);
	316	}
	317	for(Int_t is=0; is<kNModules; is++){
	318	fprintf(mapFile4Shuttle,"\t%d\t%d\t%d\n",
	319	modGeo[is],modType[is],modNCh[is]);
	320	//printf(" EMD DA -> Module mapping: geo %d type %d #ch %d\n",
	321	// modGeo[is],modType[is],modNCh[is]);
	322	}
	323
	324	}
	325	fclose(mapFile4Shuttle);
	326	}// SOD event
	327
	328	else if(eventT==PHYSICS_EVENT){
	329	// --- Reading data header
	330	reader->ReadHeader();
	331	const AliRawDataHeader* header = reader->GetDataHeader();
	332	if(header){
	333	UChar_t message = header->GetAttributes();
	334	if((message & 0x70) == 0x70){ // DEDICATED EMD RUN
	335	//printf("\t CALIBRATION_EMD_RUN raw data found\n");
	336	}
	337	else{
	338	// Temporary commented to validate DA with simulated data!!!
	339	//printf("\t NO CALIBRATION_EMD_RUN raw data found\n");
	340	//return -1;
	341	}
	342	}
	343	else{
	344	printf("\t ATTENTION! No Raw Data Header found!!!\n");
	345	return -1;
	346	}
	347
	348	rawStreamZDC->SetSODReading(kTRUE);
	349
	350	if (!rawStreamZDC->Next()) printf(" \t No raw data found!! ");
	351	//
	352	// ----- Setting ch. mapping -----
	353	for(Int_t jk=0; jk<2*kNChannels; jk++){
	354	rawStreamZDC->SetMapADCMod(jk, adcMod[jk]);
	355	rawStreamZDC->SetMapADCCh(jk, adcCh[jk]);
	356	rawStreamZDC->SetMapADCSig(jk, sigCode[jk]);
	357	rawStreamZDC->SetMapDet(jk, det[jk]);
	358	rawStreamZDC->SetMapTow(jk, sec[jk]);
	359	}
	360	//
	361	Float_t ZDCCorrADC[4], ZDCCorrADCSum[4];
	362	for(Int_t g=0; g<4; g++){
	363	ZDCCorrADCSum[g] = 0.;
	364	ZDCCorrADC[g] = 0.;
	365	}
	366
	367	//
	368	while(rawStreamZDC->Next()){
	369	Int_t detID = rawStreamZDC->GetSector(0);
	370	Int_t quad = rawStreamZDC->GetSector(1);
	371
	372	if((rawStreamZDC->IsADCDataWord()) && !(rawStreamZDC->IsUnderflow())
	373	&& !(rawStreamZDC->IsOverflow()) && (detID!=-1) && (detID!=3)
	374	&& (rawStreamZDC->GetADCGain() == 1) && // Selecting LOW RES ch.s
	375	(rawStreamZDC->GetADCModule()>=kFirstADCGeo && rawStreamZDC->GetADCModule()<=kLastADCGeo)){
	376
	377	// Taking LOW RES channels -> ch.+kNChannels !!!!
	378	Int_t DetIndex=999, PedIndex=999;
	379	// Not PMRef
	380	if(quad!=5){
	381	if(detID == 1){
	382	DetIndex = detID-1;
	383	PedIndex = quad;
	384	}
	385	else if(detID == 2){
	386	DetIndex = detID-1;
	387	PedIndex = quad+5;
	388	}
	389	else if(detID == 4){
	390	DetIndex = detID-2;
	391	PedIndex = quad+12;
	392	}
	393	else if(detID == 5){
	394	DetIndex = detID-2;
	395	PedIndex = quad+17;
	396	}
	397	// Mean pedestal subtraction
	398	Float_t Pedestal = MeanPedlg[PedIndex];
	399	// Pedestal subtraction from correlation with out-of-time signals
	400	//Float_t Pedestal = CorrCoeff0[PedIndex]+CorrCoeff1[PedIndex]*MeanPedOOT[PedIndex];
	401
	402	// Run 2010 -> we decide to fit only PMCs
	403	/* if(DetIndex!=999 \|\| PedIndex!=999){
	404	if(quad==0){
	405	Float_t corrADCval = (rawStreamZDC->GetADCValue()) - Pedestal;
	406	if(detID==1 \|\| detID==2) histoEMDCorr[detID-1]->Fill(corrADCval);
	407	else if(detID==4 \|\| detID==5) histoEMDCorr[detID-2]->Fill(corrADCval);
	408	}
	409	}
	410	*/
	411	if(DetIndex!=999 \|\| PedIndex!=999){
	412	//
	413	ZDCCorrADC[DetIndex] = (rawStreamZDC->GetADCValue()) - Pedestal;
	414	ZDCCorrADCSum[DetIndex] += ZDCCorrADC[DetIndex];
	415	//
	416	/*printf("\t det %d quad %d res %d pedInd %d "
	417	"Pedestal %1.0f -> ADCCorr = %d ZDCCorrADCSum = %d\n",
	418	detID,quad,rawStreamZDC->GetADCGain(),PedIndex,Pedestal,
	419	(Int_t) ZDCCorrADC[DetIndex],(Int_t) ZDCCorrADCSum[DetIndex]);
	420	*/
	421	}
	422	// Not common PM
	423	/*if(quad!=0){
	424	Float_t corrADCval = (rawStreamZDC->GetADCValue()) - Pedestal;
	425	if(detID==1) histZNCtow[quad-1]->Fill(corrADCval);
	426	else if(detID==2) histZPCtow[quad-1]->Fill(corrADCval);
	427	else if(detID==4) histZNAtow[quad-1]->Fill(corrADCval);
	428	else if(detID==5) histZPAtow[quad-1]->Fill(corrADCval);
	429	//
	430	//printf("\t det %d tow %d fill histo w. value %1.0f\n",
	431	// detID,quad,corrADCval);
	432	}*/
	433
	434	if(DetIndex==999 \|\| PedIndex==999)
	435	printf(" WARNING! Detector a/o pedestal index are WRONG!!!\n");
	436
	437	}//quad!=5
	438	}//IsADCDataWord()
	439
	440	}
	441	//
	442	nevents_physics++;
	443	//
	444	delete reader;
	445	delete rawStreamZDC;
	446	//
	447	for(Int_t j=0; j<4; j++) histoEMDCorr[j]->Fill(ZDCCorrADCSum[j]);
	448
	449	}//(if PHYSICS_EVENT)
	450
	451	/* exit when last event received, no need to wait for TERM signal */
	452	else if(eventT==END_OF_RUN) {
	453	printf(" -> EOR event detected\n");
	454	break;
	455	}
	456
	457	nevents_total++;
	458
	459	}
	460
	461	/* free resources */
	462	free(event);
	463	}
	464
	465	/* Analysis of the histograms */
	466	//
	467	FILE *fileShuttle1 = fopen(ENCALIBDATA_FILE,"w");
	468	//
	469	Int_t BinMax[4]={0,0,0,0};
	470	Float_t YMax[4]={0.,0.,0.,0.};
	471	Int_t NBinsx[4]={0,0,0,0};
	472	Float_t MeanFitVal[4]={1.,1.,1.,1.};
	473	TF1 *fitfun[4];
	474	for(Int_t k=0; k<4; k++){
	475	if(histoEMDCorr[k]->GetEntries()!=0 && histoEMDCorr[k]->GetMean()>0){
	476	BinMax[k] = histoEMDCorr[k]->GetMaximumBin();
	477	//printf("\n\t histoEMDCorr[%d]: BinMax = %d", k, BinMax[k]);
	478	if(BinMax[k]<=1){
	479	printf("\n WARNING! Something wrong with det %d histo -> calibration coeff. set to 1\n\n", k);
	480	continue;
	481	}
	482	//
	483	YMax[k] = (histoEMDCorr[k]->GetXaxis())->GetXmax();
	484	NBinsx[k] = (histoEMDCorr[k]->GetXaxis())->GetNbins();
	485	//printf(" ChXMax = %f\n", BinMax[k]*YMax[k]/NBinsx[k]);
	486	histoEMDCorr[k]->Fit("gaus","Q","",BinMax[k]YMax[k]/NBinsx[k]0.7,BinMax[k]YMax[k]/NBinsx[k]1.25);
	487	fitfun[k] = histoEMDCorr[k]->GetFunction("gaus");
	488	MeanFitVal[k] = (Float_t) (fitfun[k]->GetParameter(1));
	489	//printf("\t Mean Value from gaussian fit = %f\n", MeanFitVal[k]);
	490	}
	491	}
	492	//
	493	Float_t CalibCoeff[6];
	494	//
	495	for(Int_t j=0; j<6; j++){
	496	if(j<4){
	497	CalibCoeff[j] = MeanFitVal[j];
	498	fprintf(fileShuttle1,"\t%f\n",CalibCoeff[j]);
	499	}
	500	// ZEM energy calib. coeff. = 1
	501	else if(j==4 \|\| j==5){
	502	CalibCoeff[j] = 1.;
	503	fprintf(fileShuttle1,"\t%f\n",CalibCoeff[j]);
	504	}
	505	}
	506	fclose(fileShuttle1);
	507
	508	FILE *fileShuttle2 = fopen(TOWCALIBDATA_FILE,"w");
	509	//Float_t meanvalznc[4], meanvalzpc[4], meanvalzna[4], meanvalzpa[4];
	510	for(Int_t j=0; j<4; j++){
	511	/*if(histZNCtow[j]->GetEntries() == 0){
	512	printf("\n WARNING! Empty histos -> ending DA WITHOUT writing output\n\n");
	513	return -1;
	514	}
	515	meanvalznc[j] = histZNCtow[j]->GetMean();
	516	meanvalzpc[j] = histZPCtow[j]->GetMean();
	517	meanvalzna[j] = histZNAtow[j]->GetMean();
	518	meanvalzpa[j] = histZPAtow[j]->GetMean();*/
	519
	520	// Note -> For the moment the inter-calibration coeff. are set to 1
	521	for(Int_t k=0; k<5; k++){
	522	Float_t icoeff = 1.;
	523	fprintf(fileShuttle2,"\t%f",icoeff);
	524	if(k==5) fprintf(fileShuttle2,"\n");
	525	}
	526	}
	527	//
	528	/*if(meanvalznc[1]!=0 && meanvalznc[2]!=0 && meanvalznc[3]!=0 &&
	529	meanvalzpc[1]!=0 && meanvalzpc[2]!=0 && meanvalzpc[3]!=0 &&
	530	meanvalzna[1]!=0 && meanvalzna[2]!=0 && meanvalzna[3]!=0 &&
	531	meanvalzpa[1]!=0 && meanvalzpa[2]!=0 && meanvalzpa[3]!=0){
	532	fprintf(fileShuttle2,"\t%f\t%f\t%f\t%f\n",
	533	1.0,meanvalznc[0]/meanvalznc[1],meanvalznc[0]/meanvalznc[2],meanvalznc[0]/meanvalznc[3]);
	534	fprintf(fileShuttle2,"\t%f\t%f\t%f\t%f\n",
	535	1.0,meanvalzpc[0]/meanvalzpc[1],meanvalzpc[0]/meanvalzpc[2],meanvalzpc[0]/meanvalzpc[3]);
	536	fprintf(fileShuttle2,"\t%f\t%f\t%f\t%f\n",
	537	1.0,meanvalzna[0]/meanvalzna[1],meanvalzpc[0]/meanvalzna[2],meanvalzpc[0]/meanvalzna[3]);
	538	fprintf(fileShuttle2,"\t%f\t%f\t%f\t%f\n",
	539	1.0,meanvalzpa[0]/meanvalzpa[1],meanvalzpc[0]/meanvalzpa[2],meanvalzpc[0]/meanvalzpa[3]);
	540	}
	541	else{
	542	printf("\n Tower intercalib. coeff. CAN'T be calculated (some mean values are ZERO)!!!\n\n");
	543	return -1;
	544	}*/
	545	fclose(fileShuttle2);
	546
	547	for(Int_t ij=0; ij<4; ij++){
	548	delete histoEMDCorr[ij];
	549	}
	550
	551	//delete minuitFit;
	552	TVirtualFitter::SetFitter(0);
	553
	554	/* write report */
	555	fprintf(fp,"Run #%s, received %d physics events out of %d\n",getenv("DATE_RUN_NUMBER"),nevents_physics,nevents_total);
	556
	557	/* close result file */
	558	fclose(fp);
	559
	560	/* report progress */
	561	daqDA_progressReport(90);
	562
	563	/* store the result file on FES */
	564	status = daqDA_FES_storeFile(MAPDATA_FILE, "MAPPING");
	565	if(status){
	566	printf("Failed to export file : %d\n",status);
	567	return -1;
	568	}
	569	//
	570	status = daqDA_FES_storeFile(ENCALIBDATA_FILE, "EMDENERGYCALIB");
	571	if(status){
	572	printf("Failed to export file : %d\n",status);
	573	return -1;
	574	}
	575	//
	576	status = daqDA_FES_storeFile(TOWCALIBDATA_FILE, "EMDTOWERCALIB");
	577	if(status){
	578	printf("Failed to export file : %d\n",status);
	579	return -1;
	580	}
	581
	582	/* report progress */
	583	daqDA_progressReport(100);
	584
	585	return status;
	586	}