Example #1
0
void DataInterface::getDataProfile(TH2F *hProfile, TH2F *hProjection, Int_t energy) {
   if (!existsEnergyFile(energy)) {
      cout << "There are no data files with energy " << energy << endl;
      return;
   }

   TString fn = Form("Data/ExperimentalData/DataFrame_%i_MeV.root", energy);
   TFile *f = new TFile(fn);
   TTree *tree = (TTree*) f->Get("tree");

   Int_t nentries = tree->GetEntries();
   printf("Found %d frames in the DataFrame.\n", nentries);

   TLeaf *lX = tree->GetLeaf("fDataFrame.fX");
   TLeaf *lY = tree->GetLeaf("fDataFrame.fY");
   TLeaf *lLayer = tree->GetLeaf("fDataFrame.fLayer");

   Float_t x, y, layer;

   for (Int_t i=0; i<nentries; i++) {
      tree->GetEntry(i);

      for (Int_t j=0; j<lY->GetLen(); j++) {
         x = lX->GetValue(j)  + nx/2;
         y = lY->GetValue(j)  + ny/2;
         layer = lLayer->GetValue(j);

         hProfile->Fill(y, layer);
         hProjection->Fill(x, y);
      }
   }
}
void NCIdeogram::addTree(TTree *tree, const char *mu, const char *sigma)
{
	TLeaf *leafMu = tree->FindLeaf(mu);
	TLeaf *leafSigma = tree->FindLeaf(sigma);
	TEventList *elist = tree->GetEventList();
	Long64_t j,ix,nbr;
	
	nbr = elist ? elist->GetN() : tree->GetEntries();
	for (j = 0; j < nbr; j++) {
		ix = elist ? elist->GetEntry(j) : j;
		tree->GetEntry(ix);
		addPoint(leafMu->GetValue(), leafSigma->GetValue());
	}
} // addTree()
Example #3
0
void DataInterface::getDataFrame(Int_t runNo, CalorimeterFrame * cf, Int_t energy) {

   if (!existsEnergyFile(energy)) {
      cout << "There are no data files with energy " << energy << endl;
      return;
   }

   Int_t eventIdFrom = runNo * kEventsPerRun;
   Int_t eventIdTo = eventIdFrom + kEventsPerRun;

   TString fn = Form("Data/ExperimentalData/DataFrame_%i_MeV.root", energy);
   TFile *f = new TFile(fn);
   TTree *tree = (TTree*) f->Get("tree");

   Int_t nentries = tree->GetEntries();
   if (eventIdTo > nentries) {
      eventIdTo = nentries;
   }
   cout << "Found " << nentries << " frames in the DataFrame.\n";

   TLeaf *lX = tree->GetLeaf("fDataFrame.fX");
   TLeaf *lY = tree->GetLeaf("fDataFrame.fY");
   TLeaf *lLayer = tree->GetLeaf("fDataFrame.fLayer");

   Int_t counter = 0;
   for (Int_t i=eventIdFrom; i<eventIdTo; i++) {
      tree->GetEntry(i);

      for (Int_t j=0; j<lX->GetLen(); j++) {
         Int_t x = lX->GetValue(j) + nx/2;
         Int_t y = lY->GetValue(j) + ny/2;
         Int_t z = lLayer->GetValue(j);

         cf->fillAt(z, x, y);
      }
      counter++;
   }
   delete f;
}
Example #4
0
/// \brief Cache  MC production trees, store summary information in formated text files -> root trees
/// \param dataType  -
/// \param fileList
void CacheTestMCProductions(TString dataType, const char *fileList=NULL){
  AliExternalInfo info;
  info.fLoadMetadata=kFALSE;
  TObjArray* periodList = NULL;
  TArrayI nRuns;
  if (fileList!=NULL) {
    periodList=(gSystem->GetFromPipe(TString::Format("cat %s", fileList).Data())).Tokenize("\n");
    nRuns.Set(periodList->GetEntries());

  }else{
    TTree * tree = info.GetTree("MonALISA.ProductionMC","","");
    Int_t nProd=tree->GetEntries();
    periodList = new TObjArray(nProd);
    nRuns.Set(nProd);
    TLeaf *leaf = tree->GetLeaf("Tag");
    TLeaf *leafRuns = tree->GetLeaf("Number_of_runs");
    for (Int_t iProd=0; iProd<nProd; iProd++){
      tree->GetEntry(iProd);
      TString prodName=((char*)leaf->GetValuePointer());
      if (prodName.Contains("LHC")==0) continue;
      periodList->AddAt(new TObjString(((char*)leaf->GetValuePointer())),iProd);
      nRuns[iProd]=leafRuns->GetValue();
    }
    delete tree;
  }
  for (Int_t iPeriod=0; iPeriod<periodList->GetEntriesFast(); iPeriod++){
    TObjString * pName= (TObjString*)periodList->At(iPeriod);
    if (pName==NULL) continue;
    TTree* tree = info.GetTree(dataType.Data(),periodList->At(iPeriod)->GetName(),"passMC");
    if (tree){
      Int_t entries=tree->Draw("run","1","goff");
      TString sInfo=periodList->At(iPeriod)->GetName();
      sInfo+="\t";
      sInfo+=dataType;
      sInfo+="\t";
      sInfo+=TString::Format("%d\t",entries);
      sInfo+=TString::Format("%d\t",nRuns[iPeriod]);
      for (Int_t j=0; j<entries; j++) {
        sInfo+=TString::Format("%2.0f,",tree->GetV1()[j]);
        ::Info("CacheTestMCProductionsRun:","%s\t%s\t%d\t%d\t%d\t%2.0f",periodList->At(iPeriod)->GetName(),dataType.Data(),entries,nRuns[iPeriod],j, tree->GetV1()[j]);
      }
      sInfo+="0";
      ::Info("CacheTestMCProductionsPeriod:","%s\n",sInfo.Data());
      delete tree;
    }else{
      ::Error("CacheTestMCProductionsPeriod:","%s\t%s\t-1\t%d\t0",periodList->At(iPeriod)->GetName(), dataType.Data(),nRuns[iPeriod]);
    }
  }
}
Example #5
0
int main() {
    // Get a map of the histograms of the Z Masses
    const std::string Tree_HighCut = "ZFinder/Combined Single Reco/Combined Single Reco";
    const std::string Tree_LowCut = "ZFinder/Combined Single Lowered Threshold Reco/Combined Single Lowered Threshold Reco";
    const std::string file_name = "/data/whybee0a/user/gude_2/Data/20150324_SingleElectron_2012ALL/hadded.root";
    // Open the file and load the tree
    TTree* treeH = GetTTree(file_name, Tree_HighCut);
    TBranch* event_infoH = treeH->GetBranch("event_info");
    TLeaf* EVNumbH = event_infoH->GetLeaf("event_number");
    // Pack into a hitogram
    std::set<int> eventnumber;
    std::set<int> eventnumberLow;
    for (int i = 0; i < treeH->GetEntries(); i++) {
        treeH->GetEntry(i);
        if (eventnumber.find(EVNumbH->GetValue()) == eventnumber.end()) {
            eventnumber.insert(EVNumbH->GetValue());
        } else {
            cout << "multiple events numbered :" << EVNumbH->GetValue()<<" in higher cuts" << endl;
        }

    }

    TTree* TreeLow = GetTTree(file_name, Tree_LowCut);
    TBranch* event_infoL = TreeLow->GetBranch("event_info");
    TLeaf* EVNumbLow = event_infoL->GetLeaf("event_number");
    for (int i = 0; i < TreeLow->GetEntries(); i++) {
        TreeLow->GetEntry(i);
        eventnumberLow.insert(EVNumbLow->GetValue());
        if (eventnumberLow.find(EVNumbLow->GetValue()) == eventnumber.end()) {
            eventnumberLow.insert(EVNumbLow->GetValue());
        } else {
cout << "multiple events numbered :" << EVNumbLow->GetValue()<<" in lowered cuts" << endl;
        }

    }

    return EXIT_SUCCESS;
}
Example #6
0
int analysis(char* filename)
{
    // char* filename = "combined.root";
    // Read in the file
    TFile* f = new TFile(filename);
    TDirectory* hists  = f->GetDirectory("hists;1");
    TDirectory* tuples = f->GetDirectory("tuples;1");

    TTree* accum = tuples->GetObjectUnchecked("AccumulatedEnergy;1");
    TLeaf* einit = accum->GetLeaf("Einit");
    TLeaf* edepo = accum->GetLeaf("Edep");

    TTree* edeps = tuples->GetObjectUnchecked("EnergyDepositions;1");

    TTree* secs  = tuples->GetObjectUnchecked("SecondarySpectrum;1");
    TLeaf* secsenergy = secs->GetLeaf("KineticEnergy");

    double ein = 0;
    double eout = 0;



    int nevents = accum->GetEntries();
    cout << "Making Summary\n";
    FILE* summary = fopen("summ.txt", "a+");

    for (int ii = 0; ii<nevents; ii++)
    {
        accum->GetEntry(ii);
        ein+=einit->GetValue();
        eout+=edepo->GetValue();
    }

    FILE* summary = fopen("summ.txt", "a+");

    time_t t = time(NULL);
    char* c_time_string = ctime(&t);
    char* mytime[20];
    strncpy(mytime, c_time_string, 19);
    mytime[ strlen(mytime) - 1 ] = '\0';

    fprintf(summary, "%s,%s,%e,%e\n", mytime, filename, ein, eout);//*c_time_string, *filename, ein, eout);
    //cout << *c_time_string << "," << *filename << "," << ein << "," << eout << "\n";
    fclose(summary);

    // Print out or save these values
    cout << "Making Histogram\n";

    nevents = secs->GetEntries();
    TH1F* secondaries = new TH1F("secondaries", "Secondary Electrons <100 keV", 92, 0.010, 0.102);

    for (int ii = 0; ii<nevents; ii++)
    {
        secs->GetEntry(ii);
        secondaries->Fill(secsenergy->GetValue());
    }

    char* suffix = ".secondaryhisto";

    cout << "Making Filenames\n";


    char* outfilename = malloc(strlen(filename) + strlen(suffix) + 1);
    strcpy(outfilename, filename);
    strcat(outfilename, suffix);

    printf("Saving Histogram: %s \n", outfilename);
    h12ascii(secondaries, outfilename);

    return 0;

}
Example #7
0
void Example_tags(TString topDir = "/star/rcf/GC/daq/tags")
{
//////////////////////////////////////////////////////////////////////////
//                                                                      //
// Example_tags.C                                                       //
//                                                                      //
// shows how to use the STAR tags files                                 //
// Input: top level directory                                           //
//                                                                      //
// what it does:                                                        //
// 1. creates TChain from all tags files down from the topDir           //
// 2. loops over all events in the chain                                //
//                                                                      //
// owner: Alexandre V. Vaniachine <*****@*****.**>                //
//////////////////////////////////////////////////////////////////////////

  gSystem->Load("libTable");
  gSystem->Load("St_base");
  // start benchmarks
  gBenchmark = new TBenchmark();
  gBenchmark->Start("total");
   
  // set loop optimization level
  gROOT->ProcessLine(".O4");
  // gather all files from the same top directory into one chain
  // topDir must end with "/"
  topDir +='/';
  St_FileSet dirs(topDir);
  St_DataSetIter next(&dirs,0);
  St_DataSet *set = 0; 
  TChain chain("Tag");
  while ( (set = next()) ) {           
    if (strcmp(set->GetTitle(),"file") || 
	!(strstr(set->GetName(),".tags.root"))) continue;
    chain.Add(gSystem->ConcatFileName(topDir,set->Path()));
  }
  UInt_t nEvents = chain->GetEntries();
  cout<<"chained "<<nEvents<<" events "<<endl;

  TObjArray *files = chain.GetListOfFiles();
  UInt_t nFiles = files->GetEntriesFast();
  cout << "chained " << nFiles << " files from " << topDir << endl;

  TObjArray *leaves = chain.GetListOfLeaves();
  Int_t nleaves = leaves->GetEntriesFast();

  TString tableName = " ";
  TObjArray *tagTable = new TObjArray;

  Int_t tableCount = 0;
  Int_t *tableIndex = new Int_t[nleaves];
  Int_t tagCount = 0;

  // decode tag table names
  for (Int_t l=0;l<nleaves;l++) {
    TLeaf *leaf = (TLeaf*)leaves->UncheckedAt(l);
    tagCount+=leaf->GetNdata();
    TBranch *branch = leaf->GetBranch();
    // new tag table name
    if ( strstr(branch->GetName(), tableName.Data()) == 0 ) {
      tableName = branch->GetName();
      // the tableName is encoded in the branch Name before the "."
      tableName.Resize(tableName->Last('.'));
      tagTable->AddLast(new TObjString(tableName.Data()));
      tableCount++;
    }
    tableIndex[l]=tableCount-1;
  }
  cout << " tot num tables, tags = " << tableCount << "   " 
       << tagCount << endl << endl;

  //EXAMPLE 1: how to print out names of all tags and values for first event
  for (l=0;l<nleaves;l++) {
    leaf = (TLeaf*)leaves->UncheckedAt(l);
    branch = leaf->GetBranch();
    branch->GetEntry();
    // tag comment is in the title
    TString Title = leaf->GetTitle();
    Int_t dim = leaf->GetNdata();
    if (dim==1) {
      Title.ReplaceAll('['," '"); 
      Title.ReplaceAll(']',"'"); 
    }
    cout << "\n Table: ";
    cout.width(10);
    cout << ((TObjString*)tagTable->UncheckedAt(tableIndex[l]))->GetString()
	 <<" -- has tag: " << Title << endl;
    for (Int_t i=0;i<dim;i++) {
      cout <<"                               "<< leaf->GetName();
      if (dim>1) cout << '['<<i<<']';
      cout << " = " << leaf->GetValue(i) << endl; 
    }
  }

  // EXAMPLE 2: how to make a plot
  c1 = new TCanvas("c1","Beam-Gas Rejection",600,1000);
  gStyle->SetMarkerStyle(8);
  chain->Draw("n_trk_tpc[0]:n_trk_tpc[1]");

  // EXAMPLE 3: how to make a selection (write selected event numbers on the plot)
  Int_t ncoll=0;
  char aevent[10];
  TText t(0,0,"a");
  t.SetTextFont(52);
  t.SetTextSize(0.02);
  Float_t cut = 0.35;
  cout <<"\n Events with ntrk>400 and |asim|<"<<cut<<endl;
  //loop over all events: READ ONLY n_trk_tpc AND mEventNumber BRANCHES!
  gBenchmark->Start("loop");
  for (Int_t i=0;i<nFiles;i++) {
    chain.LoadTree(*(chain.GetTreeOffset()+i));
    TTree *T = chain.GetTree();
    //must renew leaf pointer for each tree
    TLeaf *ntrk = T->GetLeaf("n_trk_tpc");
    TLeaf *run = T->GetLeaf("mRunNumber");
    TLeaf *event = T->GetLeaf("mEventNumber");
    for (Int_t j=0; j<T->GetEntries(); j++){
      ntrk->GetBranch()->GetEntry(j);
      event->GetBranch()->GetEntry(j);
      run->GetBranch()->GetEntry(j);
      Int_t Nm=ntrk->GetValue(0);
      Int_t Np=ntrk->GetValue(1);
      Int_t Ntrk = Np+Nm;
      // avoid division by 0
      Float_t asim = Np-Nm;
      if (Ntrk>0) asim /= Ntrk;
      if (-cut < asim&&asim < cut && Ntrk>400) {
	cout<<"   Run "<<(UInt_t)run->GetValue()
	    <<", Event "<<event->GetValue() <<endl;
	ncoll++;
	sprintf(aevent,"%d",event->GetValue());
	t.DrawText(Np+10,Nm+10,aevent);
      }
    }
  }
  gBenchmark->Stop("loop");
  t.SetTextSize(0.05);
  t.DrawText(50,2550,"ntrk>400 and |(Np-Nm)/(Np+Nm)| < 0.35 ");
  t.DrawText(500,-300,"Ntrk with tanl<0 ");
  cout << " Selected " << ncoll << " collision candidates out of "
       << nEvents << " events" << endl;
  // stop timer and print benchmarks
  gBenchmark->Print("loop");  
  gBenchmark->Stop("total");
  gBenchmark->Print("total");  
}
Example #8
0
int main() {
  // Get7 a map of the histograms of the Z Masses
  const std::string file_name = "/data/whybee0a/user/lesko_2/fermi/MadWithInitial/Mad2016_8_25/results/AllMHWithMothers.root";
  // Open the file and load the tree
  const std::string TreeName = "ZFinder/Combined Gen Cuts Reco/Combined Gen Cuts Reco";
  TTree* tree = GetTTree(file_name, TreeName);

  TBranch* reco = tree->GetBranch("reco");
  TLeaf* PhiStar = reco->GetLeaf("z_phistar_born");
  TLeaf* Mom1 = reco->GetLeaf("z_mom1PDG");
  TLeaf* Mom2 = reco->GetLeaf("z_mom2PDG");
  TLeaf* PenUltimateMom1 = reco->GetLeaf("z_penultimate1PDG");
  TLeaf* PenUltimateMom2 = reco->GetLeaf("z_penultimate2PDG");
  TLeaf* Z_YBorn = reco->GetLeaf("z_yBorn");

  ExploreTree(tree, Mom1, PenUltimateMom1, Mom2, PenUltimateMom2);

  TBranch* event_info = tree->GetBranch("event_info");
  //TLeaf* EVNumb = event_info->GetLeaf("event_number");
  // Pack into a hitogram

  for (int w = 0; w < 2; w++) {
    string PlotName;
    TLeaf* MomOrPenUltimateMom1 = w == 0 ? Mom1 : PenUltimateMom1;
    TLeaf* MomOrPenUltimateMom2 = w == 0 ? Mom2 : PenUltimateMom2;

    vector<string> NamesOfPlots;
    NamesOfPlots.push_back("UpQuarkPair"); //0
    NamesOfPlots.push_back("DownQuarkPair"); //1
    NamesOfPlots.push_back("StrangeQuarkPair"); //2
    NamesOfPlots.push_back("CharmQuarkPair"); //3
    NamesOfPlots.push_back("BottomQuarkPair"); //4
    NamesOfPlots.push_back("SingleQuark"); //5
    NamesOfPlots.push_back("Gluon"); //6
    NamesOfPlots.push_back("TwoQuarks"); //7
    NamesOfPlots.push_back("TwoAntiQuarks"); //8
    NamesOfPlots.push_back("QuarkAntiQuarkPair"); //9
    NamesOfPlots.push_back("QuarkAntiQuarkNotPair"); //10
    NamesOfPlots.push_back("Quark Quark And AntiQuark AntiQuark"); //11
    NamesOfPlots.push_back("Broken");

    map<string, TH1*> AllPlots;
    AllPlots[NamesOfPlots[0]] = new TH1D(NamesOfPlots[0].c_str(), NamesOfPlots[0].c_str(), nphistar, phistarBins);
    AllPlots[NamesOfPlots[1]] = new TH1D(NamesOfPlots[1].c_str(), NamesOfPlots[1].c_str(), nphistar, phistarBins);
    AllPlots[NamesOfPlots[2]] = new TH1D(NamesOfPlots[2].c_str(), NamesOfPlots[2].c_str(), nphistar, phistarBins);
    AllPlots[NamesOfPlots[3]] = new TH1D(NamesOfPlots[3].c_str(), NamesOfPlots[3].c_str(), nphistar, phistarBins);
    AllPlots[NamesOfPlots[4]] = new TH1D(NamesOfPlots[4].c_str(), NamesOfPlots[4].c_str(), nphistar, phistarBins);
    AllPlots[NamesOfPlots[5]] = new TH1D(NamesOfPlots[5].c_str(), NamesOfPlots[5].c_str(), nphistar, phistarBins);
    AllPlots[NamesOfPlots[6]] = new TH1D(NamesOfPlots[6].c_str(), NamesOfPlots[6].c_str(), nphistar, phistarBins);
    AllPlots[NamesOfPlots[7]] = new TH1D(NamesOfPlots[7].c_str(), NamesOfPlots[7].c_str(), nphistar, phistarBins); //Two quarks
    AllPlots[NamesOfPlots[8]] = new TH1D(NamesOfPlots[8].c_str(), NamesOfPlots[8].c_str(), nphistar, phistarBins); //Two Anti quarks
    AllPlots[NamesOfPlots[9]] = new TH1D(NamesOfPlots[9].c_str(), NamesOfPlots[9].c_str(), nphistar, phistarBins); //
    AllPlots[NamesOfPlots[10]] = new TH1D(NamesOfPlots[10].c_str(), NamesOfPlots[10].c_str(), nphistar, phistarBins);
    AllPlots[NamesOfPlots[11]] = new TH1D(NamesOfPlots[11].c_str(), NamesOfPlots[11].c_str(), nphistar, phistarBins);
    AllPlots[NamesOfPlots[12]] = new TH1D(NamesOfPlots[12].c_str(), NamesOfPlots[12].c_str(), nphistar, phistarBins);

    map<string, TH1*> RatioPlots; //using normalized versions of the pairs to see shape changes

    cout << "test 1" << endl;
    //Vector<TH1*> YplotsFromParents;
    //YplotsFromParents.push_back(new TH1D("YSeperatedUpQuarkPair", "UpQuarkPair", nY, yBins));
    //YplotsFromParents.push_back(new TH1D("YSeperatedDownQuarkPair", "DownQuarkPair", nY, yBins));
    //YplotsFromParents.push_back(new TH1D("YSeperatedStrangeQuarkPair", "StrangeQuarkPair", nY, yBins));
    //YplotsFromParents.push_back(new TH1D("YSeperatedCharmQuarkPair", "CharmQuarkPair", nY, yBins));
    //YplotsFromParents.push_back(new TH1D("YSeperatedBottomQuarkPair", "BottomQuarkPair", nY, yBins));
    //YplotsFromParents.push_back(new TH1D("YSeperatedGluonQuarkPair", "GluonQuarkPair", nY, yBins));
    //YplotsFromParents.push_back(new TH1D("YSeperatedGluon", "Gluon", nY, yBins));
    //YplotsFromParents.push_back(new TH1D("YSeperatedUnmatchingQuarks", "UnmatchingQuarks", nY, yBins));

    //TH2D* Parents = new TH2D("ParentsPDGId", "Parents PDGID", 28, -6.5, 21.5, 28, -6.5, 21.5);
    TH2D* ProductionVsY = new TH2D("ProductionVsY", "ProductionVsY", 7, 0, 7, 6, yBins);

    for (int i = 0; i < tree->GetEntries(); i++) {
      tree->GetEntry(i);
      if(PhiStar->GetValue()==-1)continue;
      if (fabs(MomOrPenUltimateMom1->GetValue()) == 1 && -MomOrPenUltimateMom1->GetValue() == MomOrPenUltimateMom2->GetValue()) {
        AllPlots["QuarkAntiQuarkPair"]->Fill(PhiStar->GetValue());
        AllPlots["UpQuarkPair"]->Fill(PhiStar->GetValue());
        ProductionVsY->Fill(0.1, Z_YBorn->GetValue()
                );
      } else if (fabs(MomOrPenUltimateMom1->GetValue()) == 2 && -MomOrPenUltimateMom1->GetValue() == MomOrPenUltimateMom2->GetValue()) {
        AllPlots["QuarkAntiQuarkPair"]->Fill(PhiStar->GetValue());
        AllPlots["DownQuarkPair"]->Fill(PhiStar->GetValue());
        ProductionVsY->Fill(1.1, Z_YBorn->GetValue());

      } else if (fabs(MomOrPenUltimateMom1->GetValue()) == 3 && -MomOrPenUltimateMom1->GetValue() == MomOrPenUltimateMom2->GetValue()) {
        AllPlots["QuarkAntiQuarkPair"]->Fill(PhiStar->GetValue());
        AllPlots["StrangeQuarkPair"]->Fill(PhiStar->GetValue());
        ProductionVsY->Fill(2.1, Z_YBorn->GetValue());
      } else if (fabs(MomOrPenUltimateMom1->GetValue()) == 4 && -MomOrPenUltimateMom1->GetValue() == MomOrPenUltimateMom2->GetValue()) {
        AllPlots["QuarkAntiQuarkPair"]->Fill(PhiStar->GetValue());
        AllPlots["CharmQuarkPair"]->Fill(PhiStar->GetValue());
        ProductionVsY->Fill(3.1, Z_YBorn->GetValue());
      } else if (fabs(MomOrPenUltimateMom1->GetValue()) == 5 && -MomOrPenUltimateMom1->GetValue() == MomOrPenUltimateMom2->GetValue()) {
        AllPlots["QuarkAntiQuarkPair"]->Fill(PhiStar->GetValue());
        AllPlots["BottomQuarkPair"]->Fill(PhiStar->GetValue());
        ProductionVsY->Fill(4.1, Z_YBorn->GetValue());
      } else if ((MomOrPenUltimateMom1->GetValue() == 21 && fabs(MomOrPenUltimateMom2->GetValue()) < 7) || (MomOrPenUltimateMom2->GetValue() == 21 && fabs(MomOrPenUltimateMom1->GetValue()) < 7)) {
        AllPlots["SingleQuark"]->Fill(PhiStar->GetValue());
        ProductionVsY->Fill(6.1, Z_YBorn->GetValue());
      } else if (fabs(MomOrPenUltimateMom1->GetValue()) == 21 && MomOrPenUltimateMom1->GetValue() == MomOrPenUltimateMom2->GetValue()) {
        AllPlots["Gluon"]->Fill(PhiStar->GetValue());
        ProductionVsY->Fill(6.1, Z_YBorn->GetValue());
      } else if ((MomOrPenUltimateMom1->GetValue()) < 7 && (MomOrPenUltimateMom1->GetValue()) > 0 && (MomOrPenUltimateMom2->GetValue()) < 7 && (MomOrPenUltimateMom2->GetValue()) > 0) {
        AllPlots["TwoQuarks"]->Fill(PhiStar->GetValue());
        ProductionVsY->Fill(7.1, Z_YBorn->GetValue());
      } else if ((MomOrPenUltimateMom1->GetValue()) > -7 && (MomOrPenUltimateMom1->GetValue()) < 0 && (MomOrPenUltimateMom2->GetValue()) > -7 && (MomOrPenUltimateMom2->GetValue()) < 0) {
        AllPlots["TwoAntiQuarks"]->Fill(PhiStar->GetValue());
        ProductionVsY->Fill(7.1, Z_YBorn->GetValue());
      } else if (fabs(MomOrPenUltimateMom1->GetValue()) < 7 && fabs(MomOrPenUltimateMom1->GetValue()) < 7) {
        AllPlots["QuarkAntiQuarkNotPair"]->Fill(PhiStar->GetValue());
        ProductionVsY->Fill(7.1, Z_YBorn->GetValue());
      } else {
        cout << "SOmething broke" << endl;
        AllPlots["Broken"]->Fill(PhiStar->GetValue());
      }
    }
    
    {
        cout<<"Our first bin is "<<AllPlots["UpQuarkPair"]->GetBinContent(1)<<endl;
    }
    
  
    cout << "test 2" << endl;

    AllPlots["Quark Quark And AntiQuark AntiQuark"]->Add(AllPlots["TwoAntiQuarks"]);
    cout << "test 2.1" << endl;
    AllPlots["Quark Quark And AntiQuark AntiQuark"] ->Add(AllPlots["TwoQuarks"]);
    TH1D* AllQuarksNorm = (TH1D*) AllPlots["QuarkAntiQuarkPair"]->Clone("Devisor");
    AllQuarksNorm->Scale(1 / AllQuarksNorm->Integral());
    for (int i = 0; i < 5; i++) {
      string NewName = "Ratio" + NamesOfPlots[i];
      RatioPlots[NewName] = (TH1D*) AllPlots[NamesOfPlots[i]]->Clone(NewName.c_str());
      RatioPlots[NewName]->Scale(1 / RatioPlots[NewName]->Integral());
      RatioPlots[NewName]->Divide(AllQuarksNorm);
    }
    cout << "test 3" << endl;

    for (size_t i = 0; i < AllPlots.size(); i++) {
      for (size_t j = 1; j <= nphistar; j++) {
        AllPlots[NamesOfPlots[i]]->SetBinContent(j, AllPlots[NamesOfPlots[i]]->GetBinContent(j) / (phistarBins[j] - phistarBins[j - 1]));
      }
    }
    cout << "test 4" << endl;
    for (size_t i = 0; i < NamesOfPlots.size(); i++) {

      TCanvas canvas("canvas", "canvas", 1000, 1000);
      canvas.cd();
      canvas.SetLogx();
      canvas.SetLogy();
      gStyle->SetCanvasColor(0);
      gStyle->SetStatBorderSize(1);
      gStyle->SetOptStat("");
      gStyle->SetOptFit();
      AllPlots[NamesOfPlots[i]]->GetXaxis()->SetRangeUser(.004, 10);
      AllPlots[NamesOfPlots[i]]->Draw();
      AllPlots[NamesOfPlots[i]]->SetLineWidth(2);

      string SaveName = NamesOfPlots[i];
      SaveName = 0 == w ? "Mom_" + SaveName : "PenUltimate_" + SaveName;
      string WithType = "PhiStarPlots/Mompng/" + SaveName + ".png";
      canvas.Print(WithType.c_str());
      WithType = "PhiStarPlots/MomPDF/" + SaveName + ".pdf";
      canvas.Print(WithType.c_str());
      WithType = "PhiStarPlots/MomC/" + SaveName + ".C";
      canvas.Print(WithType.c_str());



      //if (i == 8)canvas.Print("Broken.png");
    }
    cout << "test 5" << endl;

    TCanvas canvas("c2", "c2", 1000, 1000);
    canvas.cd();
    canvas.SetLogx();
    canvas.SetLogy();
    gStyle->SetCanvasColor(0);
    gStyle->SetStatBorderSize(1);
    gStyle->SetOptStat("");

    AllPlots[NamesOfPlots[0]]->SetLineColor(kBlack);
    AllPlots[NamesOfPlots[1]]->SetLineColor(kBlue);
    AllPlots[NamesOfPlots[2]]->SetLineColor(kRed);
    AllPlots[NamesOfPlots[3]]->SetLineColor(kGreen + 1);
    AllPlots[NamesOfPlots[4]]->SetLineColor(kMagenta + 1);
    AllPlots[NamesOfPlots[5]]->SetLineColor(kOrange + 1);
    AllPlots[NamesOfPlots[6]]->SetLineColor(TColor::GetColor("#a65628"));
    AllPlots["Quark Quark And AntiQuark AntiQuark"]->SetLineColor(TColor::GetColor("#999999"));

    if (w == 0) {
      AllPlots[NamesOfPlots[0]]->SetTitle("");
      AllPlots[NamesOfPlots[0]]->SetXTitle("#phi^{*}");
      AllPlots[NamesOfPlots[0]]->GetXaxis()->CenterTitle();
      AllPlots[NamesOfPlots[0]]->Draw();
      AllPlots[NamesOfPlots[5]]->Draw("same");
    } else {
      AllPlots[NamesOfPlots[5]]->SetTitle("");
      AllPlots[NamesOfPlots[5]]->SetXTitle("#phi^{*}");
      AllPlots[NamesOfPlots[5]]->GetXaxis()->CenterTitle();
      AllPlots[NamesOfPlots[5]]->Draw();
      AllPlots[NamesOfPlots[0]]->Draw("same");
    }
    AllPlots[NamesOfPlots[1]]->Draw("same");
    AllPlots[NamesOfPlots[2]]->Draw("same");
    if (w == 0) {
      AllPlots[NamesOfPlots[3]]->Draw("same");
      AllPlots[NamesOfPlots[4]]->Draw("same");
    }
    AllPlots[NamesOfPlots[6]]->Draw("same");
    AllPlots["Quark Quark And AntiQuark AntiQuark"]->Draw("same");



    TLegend* leg = new TLegend(0.7, 0.70, 0.87, 0.89);
    leg->AddEntry(AllPlots[NamesOfPlots[0]], "u#bar{u}");
    leg->AddEntry(AllPlots[NamesOfPlots[1]], "d#bar{d}");
    leg->AddEntry(AllPlots[NamesOfPlots[2]], "s#bar{s}");
    if (w == 0) {
      leg->AddEntry(AllPlots[NamesOfPlots[3]], "c#bar{c}");
      leg->AddEntry(AllPlots[NamesOfPlots[4]], "b#bar{b}");
    }
    leg->AddEntry(AllPlots[NamesOfPlots[5]], "qg or #bar{q}g");
    leg->AddEntry(AllPlots[NamesOfPlots[6]], "gg");
    //leg->AddEntry(AllPlots[8], "Broken");NamesOfPlots[0]], "Up");
    leg->AddEntry(AllPlots[NamesOfPlots[11]], "qq or #bar{q}#bar{q}");
    leg->SetFillColor(0);
    leg->SetLineColor(0);
    leg->Draw("same");

    PlotName = w == 0 ? "Mom_AllLines.pn" : "PenUltimate_AllLines";
    string WithType = "PhiStarPlots/Mompng/" + PlotName + ".png";
    canvas.Print(WithType.c_str());
    WithType = "PhiStarPlots/MomPDF/" + PlotName + ".pdf";
    canvas.Print(WithType.c_str());
    WithType = "PhiStarPlots/MomC/" + PlotName + ".C";
    canvas.Print(WithType.c_str());
    TCanvas canvas3("c3", "c3", 1000, 1000);
    canvas3.cd();
    canvas3.SetLogz();
    gStyle->SetCanvasColor(0);
    gStyle->SetStatBorderSize(1);
    gStyle->SetOptStat("");
    cout << "test last" << endl;
    ProductionVsY->Draw("colz");
    PlotName = w == 0 ? "Mom_TwoDCompProductionToY" : "PenUltimate_TwoDCompProductionToY";
    WithType = "PhiStarPlots/Mompng/" + PlotName + ".png";
    canvas3.Print(WithType.c_str());
    WithType = "PhiStarPlots/MomPDF/" + PlotName + ".pdf";
    canvas3.Print(WithType.c_str());
    WithType = "PhiStarPlots/MomC/" + PlotName + ".C";
    canvas3.Print(WithType.c_str());
    cout << "test 7" << endl;

    TCanvas canvas4("c4", "c4", 1000, 1000); //Ratio Plots
    canvas4.Divide(1, 3 + 2 * (1 - w));
    //canvas4.SetLogx();
    //canvas4.SetLogy();
    for (int i = 0; i < 3 + 2 * (1 - w); i++) {
      string NewName = "Ratio" + NamesOfPlots[i];
      TPad * p = (TPad *) canvas4.cd(i + 1);
      p->SetLogx();
      RatioPlots[NewName]->GetXaxis()->SetRangeUser(.004, 10);
      RatioPlots[NewName]->GetXaxis()->SetTitle("#phi^{*}");
      RatioPlots[NewName]->GetXaxis()->CenterTitle();
      cout << "OUR FIRST BIN IS: " << RatioPlots[NewName]->GetBinContent(1) << endl;
      RatioPlots[NewName]->Draw();
    }
    //canvas4.cd(0);

    PlotName = w == 0 ? "Mom_RatioPlots" : "PenUltimate_RatioPlots";
    WithType = "PhiStarPlots/Mompng/" + PlotName + ".png";
    canvas4.Print(WithType.c_str());
    WithType = "PhiStarPlots/MomPDF/" + PlotName + ".pdf";
    canvas4.Print(WithType.c_str());
    WithType = "PhiStarPlots/MomC/" + PlotName + ".C";
    canvas4.Print(WithType.c_str());

    string FileName = w == 0 ? "Mom_PhiStarSeperated.root" : "PenUltimate_PhiStarSeperated.root";
    TFile SavedHistos(FileName.c_str(), "recreate");
    for (size_t i = 0; i < NamesOfPlots.size(); i++) {
      AllPlots[NamesOfPlots[i]]->Write();
    }
    SavedHistos.Write();
  }
  return EXIT_SUCCESS;
}
Example #9
0
int macroanalysis(char* filename)
{
    // char* filename = "combined.root";
    // Read in the file
    TFile* f = new TFile(filename);
    // TDirectory* hists  = f->GetDirectory("hists;1");
    // TDirectory* tuples = f->GetDirectory("tuples;1");

    TTree* accum = (TTree*) f->GetObjectUnchecked("AccumulatedEnergy;1");
    TLeaf* einit = (TLeaf*) accum->GetLeaf("Einit");
    TLeaf* edepo = (TLeaf*) accum->GetLeaf("Edep");

    TTree* edeps = (TTree*) f->GetObjectUnchecked("EnergyDepositions;1");
    TLeaf* individualdepos = (TLeaf*) edeps->GetLeaf("Edep");

    TTree* secs  = (TTree*) f->GetObjectUnchecked("SecondarySpectrum;1");
    TLeaf* secsenergy = (TLeaf*) secs->GetLeaf("KineticEnergy");

    double ein = 0;
    double eout = 0;



    int nevents = accum->GetEntries();
    for (int ii = 0; ii<nevents; ii++)
    {
        accum->GetEntry(ii);
        ein+=einit->GetValue();
        eout+=edepo->GetValue();
    }


    int ndepos = edeps->GetEntries();
    double deposum = 0;
    for (int ii = 0; ii<ndepos; ii++)
    {
        edeps->GetEntry(ii);
        deposum+=individualdepos->GetValue();
    }


    int nsecs = secs->GetEntries();
    double secsum = 0;
    for (int ii = 0; ii<nsecs; ii++)
    {
        secs->GetEntry(ii);
        secsum+=secsenergy->GetValue();
    }

    cout << "Making Summary\n";
    FILE* summary = fopen("macro_summ.txt", "a+");

    time_t t = time(NULL);
    char* c_time_string = std::ctime(&t);
    char mytime[20];
    std::strncpy(mytime, c_time_string, 19);
    mytime[ std::strlen(mytime) - 1 ] = '\0';

    std::fprintf(summary, "%s,%s,%i,%e,%e,%i,%e,%i,%e\n", mytime, filename,
            nevents, ein, eout, ndepos, deposum, nsecs, secsum);
    fclose(summary);

    cout << "Making Histogram\n";

    nevents = secs->GetEntries();
    TH1F* secondarieslow = new TH1F("secondarieslow", "Secondary Electrons <1 keV", 900, 0.000100, 0.001000);
    TH1F* secondariesmid = new TH1F("secondariesmid", "Secondary Electrons 1<E<10 keV", 900, 0.001, 0.010);
    TH1F* secondarieshigh = new TH1F("secondarieshigh", "Secondary Electrons 10<E<100 keV", 900, 0.010, 0.100);
    TH1F* secondariesveryhigh = new TH1F("secondariesveryhigh", "Secondary Electrons 100keV<E<3 MeV", 2902, 0.100, 3.002);

    for (int ii = 0; ii<nevents; ii++)
    {
        secs->GetEntry(ii);
        double en = secsenergy->GetValue();
        if (en < 0.001) secondarieslow->Fill(en, 1);
        else if (en < 0.01) secondariesmid->Fill(en, 0.1);
        else if (en < 0.1) secondarieshigh->Fill(en, 0.01);
        else secondariesveryhigh->Fill(en, 0.001);

    }

    char suffix[] = ".secondaryhisto";

    cout << "Making Filenames\n";


    char* outfilename = (char*) malloc(std::strlen(filename) + std::strlen(suffix) + 1);
    std::strcpy(outfilename, filename);
    std::strcat(outfilename, suffix);

    std::printf("Saving Histogram: %s \n", outfilename);
    h12ascii(secondarieslow, secondariesmid, secondarieshigh, secondariesveryhigh, outfilename);

    return 0;

}
Example #10
0
int main(int argc, char* argv[])
{
  vector<vector<double> >* voltages = new vector<vector<double> >;
  vector<vector<double> >* currents = new vector<vector<double> >;
  voltages->resize(52);
  currents->resize(52);
  TChain* chain = loadChain(argc, argv);
  int entries = chain->GetEntries();

  cout << entries/2 << " files\n";

  for(int i=0; i<entries; i++)
  {
    chain->GetEvent(i);
    for(int slot=0; slot<16; slot++)
    {
      TLeaf* vleaf = chain->GetLeaf(("VHS_"+target_card[slot]+".VM."+target_channel[slot]).c_str());
      voltages->at(slot).push_back(vleaf->GetValue(0));
      TLeaf* ileaf = chain->GetLeaf(("VHS_"+target_card[slot]+".IM."+target_channel[slot]).c_str());
      currents->at(slot).push_back(ileaf->GetValue(0));      
    }
    for(int slot=0; slot<36; slot++)
    {
      if(veto_card[slot]=="4_3")
      {
	voltages->at(slot+16).push_back(-1);
	currents->at(slot+16).push_back(-1);
      }
      else
      {
	TLeaf* vleaf = chain->GetLeaf(("VHS_"+veto_card[slot]+".VM."+veto_channel[slot]).c_str());
	voltages->at(slot+16).push_back(vleaf->GetValue(0));
	TLeaf* ileaf = chain->GetLeaf(("VHS_"+veto_card[slot]+".IM."+veto_channel[slot]).c_str());
	currents->at(slot+16).push_back(ileaf->GetValue(0));
      }
    }
  }
  
  const double allowed_dv = 100;
  const double allowed_di = 50e-06;

  vector<bool> pmt_flags_v;
  vector<bool> pmt_flags_i;
  pmt_flags_v.resize(52,0);
  pmt_flags_i.resize(52,0);


  for( auto pmt = voltages->begin();
       pmt!=voltages->end(); ++pmt )
  {
    double meanvalue = mean(*pmt);
    double deviation = std_dev(*pmt);
    //cout << "Mean: " << meanvalue << " Dev: " << deviation << endl;
    for(auto it2 = (*pmt).begin();
	it2!=(*pmt).end(); ++it2)
    {
      //cout << distance((*it).begin(), it2) << " ";
      if( abs(*it2-meanvalue) > allowed_dv )
	pmt_flags_v.at( distance(voltages->begin(), pmt) ) = true;
    }
  }

  for( auto pmt = currents->begin();
       pmt!=currents->end(); ++pmt )
  {
    double meanvalue = mean(*pmt);
    double deviation = std_dev(*pmt);
    for(auto it2 = (*pmt).begin();
	it2!=(*pmt).end(); ++it2)
      if( abs(*it2-meanvalue) > allowed_di )
	pmt_flags_i.at( distance(currents->begin(), pmt) ) = true;
  }

  bool error = false;
  // Now if we managed to pick up some flags lets say so
  for(auto it = pmt_flags_v.begin();
      it!=pmt_flags_v.end(); ++it)
    if(*it==true)
    {
      cout << "PMT: " << distance(pmt_flags_v.begin(), it) << " varied VOLTAGE more than "
	   << allowed_dv << " from its mean value" << endl;
      error = true;
    }

  for(auto it = pmt_flags_i.begin();
      it!=pmt_flags_i.end(); ++it)
    if(*it==true)
    {
      cout << "PMT: " << distance(pmt_flags_i.begin(), it) << " varied CURRENT more than "
	   << allowed_di << " from its mean value" << endl;
      error = true;
    }

  if(error == true)
  {
    cout << ">>> See error.txt for full report <<<" << endl;
    writeReport(voltages, pmt_flags_v, currents, pmt_flags_i);
  }

  delete currents;
  delete voltages;
  return 0;
}
Example #11
0
/// Cache MC production information
void CacheTrendingProductions(TString dataType){
  AliExternalInfo info;
  info.fLoadMetadata=kFALSE;
  TObjArray* periodList = NULL, *idList=NULL;
  //
  TTree * tree = info.GetTree("MonALISA.ProductionCycle","","");
  Int_t nProd=tree->GetEntries();
  periodList = new TObjArray(nProd);
  idList= new TObjArray(nProd);
  TLeaf *leafTag = tree->GetLeaf("Tag");
  TLeaf *leafID   =  tree->GetLeaf("ID");
  for (Int_t iProd=0; iProd<nProd; iProd++){
    tree->GetEntry(iProd);
    TString prodName=((char*)leafTag->GetValuePointer());
    TString  idName =TString::Format("%d",TMath::Nint(leafID->GetValue()));
    if (prodName.Contains("LHC")==0) continue;
    periodList->AddAt(new TObjString(prodName),iProd);
    idList->AddAt(new TObjString(idName),iProd);
  }
  delete tree;
  //
  for (Int_t iPeriod=0; iPeriod<periodList->GetEntriesFast(); iPeriod++) {
    TObjString * pName= (TObjString*)idList->At(iPeriod);
    if (pName==NULL) continue;
    TTree* treeP = info.GetTreeProdCycleByID(idList->At(iPeriod)->GetName());
    if (treeP==NULL) continue;
    TLeaf *leafOutput = treeP->GetLeaf("outputdir");
    Int_t nRuns= treeP->GetEntries();
    treeP->GetEntry(0);
    TString path=((char*)leafOutput->GetValuePointer());
    TObjArray *pArray = path.Tokenize("/");
    if (pArray==NULL) continue;
    Int_t nElems=pArray->GetEntries();
    if (nElems<4) continue;
    TString aperiod=pArray->At(3)->GetName();
    TString apass =pArray->At(nElems-1)->GetName();
    delete pArray;
    ::Info("CacheTrendingProductions","%s\t%s\t%s\t%s\t%d",idList->At(iPeriod)->GetName(),path.Data(), aperiod.Data(),apass.Data(),nRuns);
    delete treeP;
    TTree* treeQA = info.GetTree(dataType.Data(),aperiod.Data(),apass.Data());
    if (treeQA){
      Int_t entries=treeQA->Draw("run","1","goff");
      TString sInfo=aperiod;
      sInfo+="\t";
      sInfo+=apass;
      sInfo+="\t";
      sInfo+=dataType;
      sInfo+="\t";
      sInfo+=TString::Format("%d\t",entries);
      sInfo+=TString::Format("%d\t",nRuns);
      for (Int_t j=0; j<entries; j++) {
        sInfo+=TString::Format("%2.0f,",treeQA->GetV1()[j]);
        ::Info("CacheTrendingProductionsRun:","%s\t%s\t%s\t%d\t%d\t%2.0f",aperiod.Data(),apass.Data(),dataType.Data(),entries,nRuns,treeQA->GetV1()[j]);
      }
      sInfo+="0";
      ::Info("CacheTrendingProductionsPeriod:","%s\n",sInfo.Data());
      delete treeQA;
    }else{
      ::Error("CacheTrendingProductionsPeriod:","%s\t%s\t%s\t-1\t%d\t0",aperiod.Data(),apass.Data(), dataType.Data(),nRuns);
    }
  }
}