Beispiel #1
0
int main(int argc, char *argv[]){

	char config_filename[100], filenameX[100], filenameY[100], filenameA[100];

	strcpy(config_filename,argv[1]);
	strcpy(filenameX,argv[2]);
	strcpy(filenameY,argv[3]);
	strcpy(filenameA,argv[4]);

	//long num_steps = atoi(argv[5]);

	// Initialization
	config_t config;
	config.load(config_filename);

	// load X
	config.load_x(filenameX);

	// load Y
	long num_obs = config.num_obs;
	double *Y = new double[num_obs];
	loadVec(Y,num_obs,filenameY);

	// load A
	csrmat_t A;
	long num_variables = config.num_variables;
	A.load(num_obs,num_variables,filenameA);

	// Run RandKaczmarz
	printf("\n----------------------------");
	printf("\nStarting RandKaczmarz ...");
	printf("\n----------------------------");

	//config.num_steps = num_steps;
	RandKaczmarz_t RK;
	RK.init(config);

	RK.Run(Y,A,config);

	printf("\n----------------------------");
	printf("\nRuntime = %lf s",RK.runtime);
	printf("\n----------------------------");

	RK.save(config);
	
	delete [] Y;
	printf("\n");

}
Beispiel #2
0
int main(int argc, char** args){
    PetscErrorCode err;
    PetscViewer fd = NULL;
    Mat invL1 = NULL, invU1 = NULL, invL2 = NULL, invU2 = NULL, H12 = NULL, H21 = NULL;
    Vec order = NULL, r = NULL; //, or = NULL; //dimension: n: n1 + n2
    Vec seeds = NULL;
    //    Vec r1 = NULL, q1 = NULL, t1_1 = NULL, t1_2 = NULL, t1_3 = NULL, t1_4 = NULL, t1_5 = NULL; // dimension: n1
    //    Vec r2 = NULL, q2 = NULL, q_tilda = NULL, t2_1 = NULL, t2_2 = NULL, t2_3 = NULL; // dimension: n2
    PetscRandom rand;

    PetscLogDouble tic, toc, total_time, time;
    PetscInt n, i;
    PetscMPIInt rank, size;
    PetscInt seed;
    PetscScalar c, val;
    PetscInt QN = 100;

    // Initialize PETSC and MPI
    err = PetscInitialize(&argc, &args, (char*) 0, help); CHKERRQ(err);
    err = MPI_Comm_size(PETSC_COMM_WORLD, &size); CHKERRQ(err);
    err = MPI_Comm_rank(PETSC_COMM_WORLD, &rank); CHKERRQ(err);
    err = PetscPrintf(PETSC_COMM_WORLD, "mpi size: %d\n", size); CHKERRQ(err); 

    // Read matrices and an ordering vector
    err = PetscPrintf(PETSC_COMM_WORLD, "Read inputs (invL1, invU1, invL2, invU2, H12, H21, order)\n"); CHKERRQ(err);

    err = loadMat("./data/invL1.dat", &invL1, PETSC_COMM_WORLD, MATMPIAIJ, &fd); CHKERRQ(err);
    err = checkMat("invL1", invL1); CHKERRQ(err);

    err = loadMat("./data/invU1.dat", &invU1, PETSC_COMM_WORLD, MATMPIAIJ, &fd); CHKERRQ(err);
    err = checkMat("invU1", invU1); CHKERRQ(err);

    err = loadMat("./data/invL2.dat", &invL2, PETSC_COMM_WORLD, MATMPIAIJ, &fd); CHKERRQ(err);
    err = checkMat("invL2", invL2); CHKERRQ(err);

    err = loadMat("./data/invU2.dat", &invU2, PETSC_COMM_WORLD, MATMPIAIJ, &fd); CHKERRQ(err);
    err = checkMat("invU2", invU2); CHKERRQ(err);

    err = loadMat("./data/H12.dat", &H12, PETSC_COMM_WORLD, MATMPIAIJ, &fd); CHKERRQ(err);
    err = checkMat("H12", H12); CHKERRQ(err);

    err = loadMat("./data/H21.dat", &H21, PETSC_COMM_WORLD, MATMPIAIJ, &fd); CHKERRQ(err);
    err = checkMat("H21", H21); CHKERRQ(err);

    err = loadVec("./data/order.dat", &order, PETSC_COMM_SELF, &fd); CHKERRQ(err); //all processes must have this vector for ordering the result vector.
    err = checkVec("order", order); CHKERRQ(err);

    // shift -1 for zero-based index
    err = VecShift(order, -1); CHKERRQ(err);
    err = VecGetSize(order, &n); CHKERRQ(err);

    seed = 5;
    c = 0.05;
    err = PetscTime(&tic); CHKERRQ(err);

    //err = BearQueryMat(seed, c, invL1, invU1, invL2, invU2, H12, H21, order); CHKERRQ(err);
    //err = PetscTime(&toc); CHKERRQ(err);
    //time = toc - tic;
    //err = PetscPrintf(PETSC_COMM_WORLD, "running time: %f sec\n", time); CHKERRQ(err);

    ///* 100 times querying
    err = VecCreateSeq(PETSC_COMM_SELF, QN, &seeds); CHKERRQ(err);
    err = VecSetFromOptions(seeds); CHKERRQ(err); 
    err = PetscRandomCreate(PETSC_COMM_WORLD, &rand); CHKERRQ(err);
    err = PetscRandomSetSeed(rand, 100); CHKERRQ(err);
    err = PetscRandomSetInterval(rand, (PetscScalar) 0, (PetscScalar) n); CHKERRQ(err);
    err = PetscRandomSetFromOptions(rand); CHKERRQ(err);
    err = VecSetRandom(seeds, rand); CHKERRQ(err);
    err = PetscRandomDestroy(&rand); CHKERRQ(err);

    seed = 5; //seed is give by user on one-based index
    c = 0.05;

    i = 0;

    err = VecDuplicate(order, &r); CHKERRQ(err);
    for(i = 0; i < QN; i++){
        err = VecGetValues(seeds, 1, &i, &val);
        seed = (PetscInt) val;
        //err = PetscPrintf(PETSC_COMM_SELF, "rank: %d, seed: %d\n", rank, seed);
        err = PetscTime(&tic); CHKERRQ(err);
        err = BearQuery(seed, c, invL1, invU1, invL2, invU2, H12, H21, order, r); CHKERRQ(err);
        err = PetscTime(&toc); CHKERRQ(err);
        time = toc - tic;
        err = PetscPrintf(PETSC_COMM_WORLD, "running time: %f sec\n", time); CHKERRQ(err);
        total_time += time;
    }
    err = PetscPrintf(PETSC_COMM_WORLD, "average running time: %f sec\n", total_time/QN); CHKERRQ(err);
    err = VecDestroy(&r);


    /*    err = MatGetSize(H12, &n1, &n2); CHKERRQ(err);
          n = n1 + n2;
          err = PetscPrintf(PETSC_COMM_WORLD, "n1: %d, n2: %d\n", n1, n2); CHKERRQ(err);

          err = VecCreateMPI(PETSC_COMM_WORLD, PETSC_DECIDE, n, &r); CHKERRQ(err);
          err = VecCreateMPI(PETSC_COMM_WORLD, PETSC_DECIDE, n1, &q1); CHKERRQ(err);
          err = VecCreateMPI(PETSC_COMM_WORLD, PETSC_DECIDE, n2, &q2); CHKERRQ(err);
          err = VecSet(q1, 0); CHKERRQ(err);
          err = VecSet(q2, 0); CHKERRQ(err);

          seed = seed - 1; // shift -1 for zero-based index
          err = VecGetValues(order, 1, &seed, &val); CHKERRQ(err);
          oseed = (PetscInt) val;
          err = PetscPrintf(PETSC_COMM_WORLD, "Given seed: %d, Reorered seed: %d (0 ~ n-1)\n", seed, oseed); CHKERRQ(err);

          if(oseed < n1){
          err = VecSetValues(q1, 1, &oseed, &one, INSERT_VALUES); CHKERRQ(err);
          }else{
          oseed = oseed - n1;
          err = VecSetValues(q2, 1, &oseed, &one, INSERT_VALUES); CHKERRQ(err);
    //err = printVecSum(q2);
    }
    err = VecAssemblyBegin(q1); CHKERRQ(err);
    err = VecAssemblyBegin(q2); CHKERRQ(err);
    err = VecAssemblyEnd(q1); CHKERRQ(err);
    err = VecAssemblyEnd(q2); CHKERRQ(err);

    err = VecDuplicate(q1, &r1); CHKERRQ(err);
    err = VecDuplicate(q1, &t1_1); CHKERRQ(err);
    err = VecDuplicate(q1, &t1_2); CHKERRQ(err);
    err = VecDuplicate(q1, &t1_3); CHKERRQ(err);
    err = VecDuplicate(q1, &t1_4); CHKERRQ(err);
    err = VecDuplicate(q1, &t1_5); CHKERRQ(err);

    err = VecDuplicate(q2, &r2); CHKERRQ(err);
    err = VecDuplicate(q2, &q_tilda); CHKERRQ(err);
    err = VecDuplicate(q2, &t2_1); CHKERRQ(err);
    err = VecDuplicate(q2, &t2_2); CHKERRQ(err);
    err = VecDuplicate(q2, &t2_3); CHKERRQ(err);

    // Start matrix-vec multiplications
    err = MatMult(invL1, q1, t1_1); CHKERRQ(err);
    err = MatMult(invU1, t1_1, t1_2); CHKERRQ(err);
    err = MatMult(H21, t1_2, t2_1); CHKERRQ(err);
    err = VecAXPBYPCZ(q_tilda, 1.0, -1.0, 0.0, q2, t2_1); CHKERRQ(err);
    err = MatMult(invL2, q_tilda, t2_2); CHKERRQ(err);
    err = MatMult(invU2, t2_2, r2); CHKERRQ(err);

    err = MatMult(H12, r2, t1_3); CHKERRQ(err);
    err = VecAXPBYPCZ(t1_4, 1.0, -1.0, 0.0, q1, t1_3); CHKERRQ(err);
    err = MatMult(invL1, t1_4, t1_5); CHKERRQ(err);
    err = MatMult(invU1, t1_5, r1); CHKERRQ(err);
    //err = printVecSum(r1); 

    //err = VecView(r2, PETSC_VIEWER_STDOUT_WORLD);

    // Concatenate r1 and r2
    err = VecMerge(r1, r2, r); CHKERRQ(err);
    err = VecScale(r, c); CHKERRQ(err);

    //err = VecView(r, PETSC_VIEWER_STDOUT_WORLD);

    err = VecDuplicate(r, &or); CHKERRQ(err);
    err = VecReorder(r, order, or); CHKERRQ(err);
    //err = VecView(or, PETSC_VIEWER_STDOUT_WORLD);*/

    // Destory matrices and vectors
    err = MatDestroy(&invL1); CHKERRQ(err);
    err = MatDestroy(&invU1); CHKERRQ(err);
    err = MatDestroy(&invL2); CHKERRQ(err);
    err = MatDestroy(&invU2); CHKERRQ(err);
    err = MatDestroy(&H12); CHKERRQ(err);
    err = MatDestroy(&H21); CHKERRQ(err);
    err = VecDestroy(&order); CHKERRQ(err);
    err = VecDestroy(&r); CHKERRQ(err);
    err = VecDestroy(&seeds); CHKERRQ(err);
    //err = VecDestroy(&or); CHKERRQ(err);

    /*    err = VecDestroy(&r1); CHKERRQ(err);
          err = VecDestroy(&q1); CHKERRQ(err);
          err = VecDestroy(&t1_1); CHKERRQ(err);
          err = VecDestroy(&t1_2); CHKERRQ(err);
          err = VecDestroy(&t1_3); CHKERRQ(err);
          err = VecDestroy(&t1_4); CHKERRQ(err);
          err = VecDestroy(&t1_5); CHKERRQ(err);

          err = VecDestroy(&r2); CHKERRQ(err);
          err = VecDestroy(&q2); CHKERRQ(err);
          err = VecDestroy(&q_tilda); CHKERRQ(err);
          err = VecDestroy(&t2_1); CHKERRQ(err);
          err = VecDestroy(&t2_2); CHKERRQ(err);
          err = VecDestroy(&t2_3); CHKERRQ(err);*/

    // Finalize
    err = PetscFinalize(); CHKERRQ(err);
    return 0;
}
Beispiel #3
0
int plotDYAcceptance(int analysisIs2D,
		     const TString conf,
		     DYTools::TRunMode_t runMode=DYTools::NORMAL_RUN,
		     DYTools::TSystematicsStudy_t systMode=DYTools::NO_SYST,
		     TString rndStudyStr="")
{
  gBenchmark->Start("plotDYAcceptance");

  {
    DYTools::printExecMode(runMode,systMode);
    const int debug_print=1;
    if (!DYTools::checkSystMode(systMode,debug_print,9, DYTools::NO_SYST,
				DYTools::FSR_5plus, DYTools::FSR_5minus,
				DYTools::FSR_RND_STUDY, DYTools::PU_RND_STUDY,
				DYTools::PILEUP_5plus, DYTools::PILEUP_5minus,
				DYTools::NO_REWEIGHT, DYTools::NO_REWEIGHT_FEWZ))
      return retCodeError;
  }
  //
  // A note on systematics mode
  // - FSR_5plus, FSR_5minus should be taken care here
  // - PU_5plus, PU_5minus are taken care by the eventWeight, through
  //   the PUReweight class

  if (!DYTools::setup(analysisIs2D)) {
    std::cout << "failed to initialize the analysis\n";
    return retCodeError;
  }


  //--------------------------------------------------------------------------------------------------------------
  // Settings
  //==============================================================================================================

  InputFileMgr_t inpMgr;
  if (!inpMgr.Load(conf)) return retCodeError;
  // no energy correction for this evaluation
  inpMgr.clearEnergyScaleTag();

  // Construct eventSelector, update mgr and plot directory
  TString extraTag=rndStudyStr;
  EventSelector_t evtSelector(inpMgr,runMode,systMode,
			      extraTag,"",EventSelector::_selectDefault);
  evtSelector.setTriggerActsOnData(false);

  // Acceptance is generator-level quantity and should not
  // depend on the pile-up. The flag is disabled.
  // Correction on May 01, 2014: PU should be applied at all steps
  EventWeight_t evWeight;
  if (!evWeight.init(inpMgr.puReweightFlag(),inpMgr.fewzFlag(),
		     systMode,rndStudyStr)) {
    std::cout << "failed to prepare evWeight\n";
    return retCodeError;
  }
  std::cout << "evWeight: "; evWeight.PrintDetails();

  int useSpecWeight=1;
  double specWeight=1.0;
  const double FSRmassDiff=1.0;
  // FSR_RND_STUDY sets own special weights
  if (systMode==DYTools::FSR_5plus) { specWeight=1.05; useSpecWeight=1; }
  else if (systMode==DYTools::FSR_5minus) { specWeight=0.95; useSpecWeight=1; }

  // Prepare output directory
  inpMgr.constDir(systMode,1);
  TString outFileName=inpMgr.correctionFullFileName("acceptance",systMode,0);
  std::cout << "generated outFileName=<" << outFileName << ">\n";

#ifdef calculate_PreFsrAcc
  std::cout << dashline;
  std::cout << "\t\tcalculate_PreFsrAcc is defined\n";
  std::cout << dashline;
#endif

  //--------------------------------------------------------------------------------------------------------------
  // Main analysis code
  //==============================================================================================================

  std::cout << mainpart;

  //
  // Set up histograms
  //

  // containers to accumulate the events
  std::vector<TH2D*> hvPass, hvTotal;
  std::vector<TH2D*> hvFail;

#ifdef calculate_PreFsrAcc
  std::vector<TH2D*> hvPassPreFsr, hvTotalPreFsr;
#endif

  // debug containters
  std::vector<TH1D*> hMassv;
  std::vector<TH1D*> hMassBinsv;
  std::vector<TH1D*> hZpeakv;
  TH1D *hSelEvents=NULL;

  // the main result of the macro
  createBaseH2Vec(hvPass ,"hvPass_" ,inpMgr.mcSampleNames());
  createBaseH2Vec(hvTotal,"hvTotal_",inpMgr.mcSampleNames());
  createBaseH2Vec(hvFail,"hvFail_",inpMgr.mcSampleNames());

#ifdef calculate_PreFsrAcc
  createBaseH2Vec(hvPassPreFsr ,"hvPassPreFsr_" ,inpMgr.mcSampleNames());
  createBaseH2Vec(hvTotalPreFsr,"hvTotalPreFsr_",inpMgr.mcSampleNames());
#endif

  // debug distributions: 1GeV bins
  createAnyH1Vec(hMassv,"hGenMass_",inpMgr.mcSampleNames(),1990,10.,2000.,"#it{M}_{ee} [GeV]","counts/1GeV");
  // debug distributions for current mass bin
  createBaseH1Vec(hMassBinsv,"hGenMassBins_",inpMgr.mcSampleNames());
  // debug: accumulate info about the selected events in the samples
  hSelEvents=createAnyTH1D("hSelEvents","hSelEvents",inpMgr.mcSampleCount(),0,inpMgr.mcSampleCount(),"sampleId","event count");
  // collect number of events in the Z-peak
  createAnyH1Vec(hZpeakv,"hZpeak_",inpMgr.mcSampleNames(),60,60.,120.,"#it{M}_{ee} [GeV]","counts/1GeV");

  //
  // Access samples and fill histograms
  //
  AccessOrigNtuples_t accessInfo;

  //
  // loop over samples
  //
  if (DYTools::processData(runMode)) {

  double extraWeightFactor=1.0;
  EventCounterExt_t ecTotal("total");
  for (unsigned int isample=0; isample<inpMgr.mcSampleCount(); ++isample) {
    const CSample_t *mcSample=inpMgr.mcSampleInfo(isample);
    std::cout << "Processing " << mcSample->getLabel() << "..." << std::endl;
    std::cout << " of size " << mcSample->size() << "\n";
    if (mcSample->size()!=1) {
      std::cout << "mcSample->size is expected to be 1\n";
      return retCodeError;
    }

    // accumulate info about processed files
    EventCounterExt_t ecSample(mcSample->name);

    for (unsigned int ifile=0; ifile<mcSample->size(); ++ifile) {
      // Read input file
      TFile *infile=new TFile(mcSample->getFName(ifile),"read");
      if (!infile || !infile->IsOpen()) {
	TString skimName=inpMgr.convertSkim2Ntuple(mcSample->getFName(ifile));
	std::cout <<  "  .. failed. Trying <" << skimName << ">" << std::endl;
	infile= new TFile(skimName,"read");
      }
      assert(infile->IsOpen());
      std::cout << " Reading file <" << mcSample->getFName(ifile) << ">\n";

      // Get the TTrees
      if (!accessInfo.setTree(*infile,"Events",true)) {
	return retCodeError;
      }

    // Find weight for events for this file
    // The first file in the list comes with weight 1*extraWeightFactor,
    // all subsequent ones are normalized to xsection and luminosity
      ULong_t maxEvents = accessInfo.getEntries();
      // to match old version package (DYee 7TeV paper),
      if ((inpMgr.userKeyValueAsInt("USE7TEVMCWEIGHT")==1) && (isample==0) && (ifile==0)) {
	extraWeightFactor=maxEvents / (inpMgr.totalLumi() * inpMgr.mcSampleInfo(0)->getXsec(ifile));
      }
      //std::cout << "extraWeightFactor=" << extraWeightFactor << ", chk=" << (maxEvents0/inpMgr.mcSampleInfo(0)->getXsec(ifile)) << "\n";
      //const double extraWeightFactor=1.0;
      if (! evWeight.setWeight_and_adjustMaxEvents(maxEvents, inpMgr.totalLumi(), mcSample->getXsec(ifile),
						   extraWeightFactor, inpMgr.selectEventsFlag())) {
	std::cout << "adjustMaxEvents failed\n";
	return retCodeError;
      }
      std::cout << "mcSample xsec=" << mcSample->getXsec(ifile) << ", nEntries=" << maxEvents << "\n";


      std::cout << "       -> sample base weight is " << evWeight.baseWeight() << "\n";

      // loop through events
      EventCounterExt_t ec(Form("%s_file%d",mcSample->name.Data(),ifile));
      ec.setIgnoreScale(0); // 1 - count events, 0 - take weight in account
      // adjust the scale in the counter
      // if FEWZ weight should be considered, use evWeight.totalWeight() after
      // the FEWZ weight has been identified (see a line below)
      ec.setScale(evWeight.baseWeight());

      std::cout << "numEntries = " << accessInfo.getEntriesFast()
		<< ", " << maxEvents << " events will be used" << std::endl;


      for(ULong_t ientry=0; ientry<maxEvents; ientry++) {
	if (DYTools::isDebugMode(runMode) && (ientry>1000000)) break; // debug option
	//if (DYTools::isDebugMode(runMode) && (ientry>100)) break; // debug option
	printProgress(250000," ientry=",ientry,maxEvents);
	ec.numEvents_inc();
	
	// Load generator level info
	accessInfo.GetGen(ientry);
	// If the Z->ll leptons are not electrons, discard this event.
	// This is needed for signal MC samples such as Madgraph Z->ll
	// where all 3 lepton flavors are possible
	if (!accessInfo.genLeptonsAreElectrons()) continue;

	// Load event info to get nPU
	accessInfo.GetInfoEntry(ientry);

	// FSR study correction for weight
	if (useSpecWeight) {
	  evWeight.setSpecWeightValue(accessInfo,FSRmassDiff,specWeight);
	  if ((systMode==DYTools::FSR_RND_STUDY) && (ientry<100)) {
	    std::cout << "ientry=" << ientry << ", ";
	    evWeight.PrintDetails();
	  }
	}

	// Adjust event weight
	// .. here "false" = "not data"
	evWeight.set_PU_and_FEWZ_weights(accessInfo,false);

	// adjust the scale in the counter to include FEWZ
	// (and possibly PU) weight
	//ec.setScale(evWeight.totalWeight());

	// accumulate denominator
	const mithep::TGenInfo *gen= accessInfo.genPtr();
	hMassv[isample]->Fill(gen->vmass, evWeight.totalWeight());
	hMassBinsv[isample]->Fill(gen->vmass, evWeight.totalWeight());

	hvTotal[isample]->Fill(gen->mass, fabs(gen->y), evWeight.totalWeight());

#ifdef calculate_PreFsrAcc
	hvTotalPreFsr[isample]->Fill(gen->vmass, fabs(gen->vy), evWeight.totalWeight());
#endif

	int failAcc=0;

	// check acceptance at Gen PostFSR level
	if (!evtSelector.inAcceptance(accessInfo)) {
	  hvFail[isample]->Fill(gen->mass, fabs(gen->y), evWeight.totalWeight());
	  failAcc=1;
	}

#ifdef calculate_PreFsrAcc
	if (evtSelector.inAcceptancePreFsr(accessInfo)) {
	  hvPassPreFsr[isample]->Fill(gen->vmass, fabs(gen->vy), evWeight.totalWeight());
	}
#endif

	if (failAcc) continue;

	ec.numEventsPassedAcceptance_inc();

	// accumulate denominator
	hvPass[isample]->Fill(gen->mass, fabs(gen->y), evWeight.totalWeight());
	hSelEvents->Fill(isample,evWeight.totalWeight());

      } // loop over events
      ec.print(2);  // print info about file
      ecSample.add(ec); // accumulate event counts
      ecTotal.add(ec);

      infile->Close();
      delete infile;
    }
    ecSample.print(2); // print info about sample
    evtSelector.printCounts();
  }
  ecTotal.print(2);
  } // if (processData)


  std::cout << "outFileName=<" << outFileName << ">\n";
  if (DYTools::processData(runMode)) {
    TFile file(outFileName,"recreate");
    int res=file.IsOpen();
    if (res) res=saveVec(file,hvPass,"accPassDir");
    if (res) res=saveVec(file,hvTotal,"accTotalDir");
    if (res) res=saveVec(file,hvFail,"accFailDir");
#ifdef calculate_PreFsrAcc
    if (res) res=saveVec(file,hvPassPreFsr,"accPassPreFsrDir");
    if (res) res=saveVec(file,hvTotalPreFsr,"accTotalPreFsrDir");
#endif
    if (res) res=saveVec(file,hMassv,"mass_1GeV_bins");
    if (res) res=saveVec(file,hMassBinsv,"mass_analysis_bins");
    if (res) res=saveVec(file,hZpeakv,"mass_Zpeak_1GeV");
    if (res) res=saveHisto(file,hSelEvents,"procFileInfo");
    if (res) writeBinningArrays(file);
    file.Close();
    if (!res) {
      std::cout << "error occurred during save to file <" << outFileName << ">\n";
      return retCodeError;
    }
  }
  else {
    TFile file(outFileName,"read");
    int res=file.IsOpen();
    if (res) res=checkBinningArrays(file);
    if (res) res=loadVec(file,hvPass,"accPassDir");
    if (res) res=loadVec(file,hvTotal,"accTotalDir");
    if (res) res=loadVec(file,hvFail,"accFailDir");
#ifdef calculate_PreFsrAcc
    if (res) res=saveVec(file,hvPassPreFsr,"accPassPreFsrDir");
    if (res) res=saveVec(file,hvTotalPreFsr,"accTotalPreFsrDir");
#endif
    if (res) res=loadVec(file,hMassv,"mass_1GeV_bins");
    if (res) res=loadVec(file,hMassBinsv,"mass_analysis_bins");
    if (res) res=loadVec(file,hZpeakv,"mass_Zpeak_1GeV");
    if (res) res=loadHisto(file,&hSelEvents,"procFileInfo");
    file.Close();
    if (!res) {
      std::cout << "error occurred during save to file <" << outFileName << ">\n";
      return retCodeError;
    }
  }

  TH2D *hSumPass_BaseH2=createBaseH2("hSumPass_baseH2","hSumPass_baseH2",1);
  TH2D *hSumTotal_BaseH2=createBaseH2("hSumTotal_baseH2","hSumTotal_baseH2",1);
  TH2D *hSumFail_BaseH2=createBaseH2("hSumFail_baseH2","hSumFail_baseH2",1);
  addHistos(hSumPass_BaseH2,hvPass);
  addHistos(hSumTotal_BaseH2,hvTotal);
  addHistos(hSumFail_BaseH2,hvFail);

  TH2D *hAcc_BaseH2 = createBaseH2("hAcceptance_baseH2","hAcc_baseH2",1);
  // We need the binomial error for the acceptance
  // eff=Pass/Tot,
  // (dEff)^2= (1-eff)^2/T^2 (dPass)^2 + eff^2/T^2 (dFail)^2
  // (dFail)^2 = (dTot)^2 - (dPass)^2
  hAcc_BaseH2->Divide(hSumPass_BaseH2,hSumTotal_BaseH2,1,1,"b");

  TH2D *hSumPass=convertBaseH2actual(hSumPass_BaseH2,"hSumPass",1);
  TH2D *hSumFail=convertBaseH2actual(hSumFail_BaseH2,"hSumFail",1);
  TH2D *hSumTotal=convertBaseH2actual(hSumTotal_BaseH2,"hSumTotal",1);
  TH2D *hAcc=Clone(hAcc_BaseH2,"hAcceptance","hAcc");
  hAcc->Divide(hSumPass,hSumTotal,1,1,"b");

#ifdef calculate_PreFsrAcc
  TH2D *hSumPassPreFsr_BaseH2=createBaseH2("hSumPassPreFsr_baseH2","hSumPassPreFsr_baseH2",1);
  TH2D *hSumTotalPreFsr_BaseH2=createBaseH2("hSumTotalPreFsr_baseH2","hSumTotalPreFsr_baseH2",1);
  addHistos(hSumPassPreFsr_BaseH2,hvPassPreFsr);
  addHistos(hSumTotalPreFsr_BaseH2,hvTotalPreFsr);

  TH2D *hSumPassPreFsr=convertBaseH2actual(hSumPassPreFsr_BaseH2,"hSumPassPreFsr",1);
  TH2D *hSumTotalPreFsr=convertBaseH2actual(hSumTotalPreFsr_BaseH2,"hSumTotalPreFsr",1);
  TH2D *hAccPreFsr=Clone(hSumPassPreFsr,"hAccPreFsr","hAccPreFsr");
  hAccPreFsr->Divide(hSumPassPreFsr,hSumTotalPreFsr,1,1,"b");
#endif

  std::cout << dashline;
  std::cout << dashline;

  printHisto(hSumPass_BaseH2);
  printHisto(hSumTotal_BaseH2);
  printHisto(hAcc_BaseH2);

  printHisto(hSumPass);
  printHisto(hSumTotal);
  printHisto(hAcc);

  //printHisto(hSumFail);
  std::cout << dashline;

#ifdef calculate_PreFsrAcc
  std::cout << dashline;
  printHisto(hSumPassPreFsr);
  printHisto(hSumTotalPreFsr);
  printHisto(hAccPreFsr);
  std::cout << dashline;
#endif

  if (DYTools::processData(runMode)) {
    TFile file(outFileName,"update");
    int res=file.IsOpen();
    std::cout << "res=" << res << "\n";
    if (res) res=saveHisto(file,hAcc,"");
    if (res) res=saveHisto(file,hSumPass,"");
    if (res) res=saveHisto(file,hSumTotal,"");
    if (res) res=saveHisto(file,hSumFail,"");
#ifdef calculate_PreFsrAcc
    if (res) res=saveHisto(file,hAccPreFsr,"");
    if (res) res=saveHisto(file,hSumPassPreFsr,"");
    if (res) res=saveHisto(file,hSumTotalPreFsr,"");
#endif
    file.Close();
    if (!res) {
      std::cout << "error occurred during additional save to file <" << outFileName << ">\n";
      return retCodeError;
    }
  }


  //--------------------------------------------------------------------------------------------------------------
  // Make plots
  //==============================================================================================================

  //--------------------------------------------------------------------------------------------------------------
  // Summary print out
  //==============================================================================================================
  /*
  cout << endl;
  cout << "*" << endl;
  cout << "* SUMMARY" << endl;
  cout << "*--------------------------------------------------" << endl;
  cout << endl;
    */

  //gBenchmark->Show("plotDYAcceptance");
  ShowBenchmarkTime("plotDYAcceptance");
  return retCodeOk;
}