Пример #1
0
void dump_required_lvl2(TTree *tree, TLeaf &leaf, CodedOutputStream &o, CodedOutputStream &o2) {
    const int DL = 1; // definition level multiplier
    const int RL = 4; // repetition level multiplier

    std::cout << "Dump vector vector: " << leaf.GetName() << " " << leaf.GetTypeName() << std::endl;
    auto * branch = leaf.GetBranch();

    std::vector<std::vector<T> > * data = NULL;
    tree->SetBranchAddress(leaf.GetBranch()->GetName(), &data);
    int entries = tree->GetEntries();
    for (int i = 0; i < entries; i++) { 
        branch->GetEntry(i);
        if (data->size() == 0) {
            write_out_32(o2, DL*0 + RL*0);
        }
        for (int j = 0; j < data->size(); j++) {
            if (data->at(j).size() == 0) {
                int dl = 1;
                int rl = (j > 0 ? 1 : 0);
                write_out_32(o2, dl*DL + rl*RL);
            }
            for (int k = 0; k < data->at(j).size(); k++) {
                int dl = 2;
                int rl = (k > 0 ? 2 : (j > 0 ? 1 : 0));
                write_out_32(o2, dl*DL + rl*RL);
                write_out_type(o, data->at(j).at(k));
            }
        }
    }
}
Пример #2
0
// This piece of code is borrowed from Argo written by Nathaniel Tagg
std::vector<std::string> DataFetcher::FindLeavesOfType(std::string pattern) {
  /// Look in the tree and try to find a leaf element that matches 'pattern'.
  /// Return the full name of that leaf.
  std::vector<std::string> leaf_names;

  // Strip whitespace from pattern.
  pattern.erase(std::remove_if(pattern.begin(), pattern.end(), ::isspace),
      pattern.end());

  TObjArray * list = tree_->GetListOfLeaves();
  for (int i = 0; i < list->GetEntriesFast(); ++i) {
    TObject * o = list->At(i);
    TLeaf * leaf = (TLeaf *) o;
    std::string name = leaf->GetTypeName();
    // Strip whitespace from pattern.
    name.erase(std::remove_if(name.begin(), name.end(), ::isspace),
        name.end());
    size_t found = name.find(pattern);
    if (found != std::string::npos) {
      // Return this match.
      leaf_names.push_back(leaf->GetName());
    }
  }
  return leaf_names;
}
Пример #3
0
void dump_required_lvl0(TTree *tree, TLeaf &leaf, CodedOutputStream &o) {
    std::cout << "Dump " << leaf.GetName() << std::endl;
    auto *branch = leaf.GetBranch();

    T data; 
    tree->SetBranchAddress(leaf.GetBranch()->GetName(), &data);
    int entries = tree->GetEntries();
    for (int i = 0; i < entries; i++) { 
        branch->GetEntry(i);
        write_out_type(o, data);
    }
}
Пример #4
0
void getlist(ostream& out, TBranch* branch, int depth=0)
{
  TObjArray* array = branch->GetListOfBranches();
  if ( ! array ) return;
  if ( depth > 10 ) return;

  string name;
  int nitems = array->GetEntries();

  for (int i = 0; i < nitems; i++)
	{
	  TBranch* b = (TBranch*)((*array)[i]);
      if ( ! b ) continue;

      string branchname(b->GetName());
      out << SPACE.substr(0,4*depth) << branchname << endl;
 
      TObjArray* a = b->GetListOfLeaves();
      if ( a )
        {
          int n = a->GetEntries();
          {
              for (int j = 0; j < n; j++)
                {
                  TLeaf* leaf = (TLeaf*)((*a)[j]);
                  int count = 0;
                  int ndata = 0;
                  TLeaf* leafc = leaf->GetLeafCounter(count);
                  if ( ! leafc)
                    ndata = leaf->GetLen();
                  else
                    ndata = leafc->GetMaximum();

                  string leafname(leaf->GetName());
                  out << SPACE.substr(0,4*(depth+1)) 
                      << ndata << " " << leafname << endl;
                }
          }
//           else if ( n == 1 )
//             {
//               TBranch* bc = (TBranch*)((*a)[j]);
//               string leafname(bc->GetName());
//               if ( leafname != branchname )
//               out << SPACE.substr(0,4*(depth+1)) << leafname << endl;
//             }
        }
      getlist(out, b, depth+1);
    }
}
Пример #5
0
void paracoor( TString fin = "TMVA.root", Bool_t useTMVAStyle = kTRUE )
{
   // set style and remove existing canvas'
   TMVAGlob::Initialize( useTMVAStyle );

   // checks if file with name "fin" is already open, and if not opens one
   TFile* file = TMVAGlob::OpenFile( fin );  
   TTree* tree = (TTree*)file->Get("TestTree");
   if(!tree) {
      cout << "--- No TestTree saved in ROOT file. Parallel coordinates will not be plotted" << endl;
      return;
   }

   // first get list of leaves in tree
   TObjArray* leafList = tree->GetListOfLeaves();
   vector<TString> vars;
   vector<TString> mvas;   
   for (Int_t iar=0; iar<leafList->GetSize(); iar++) {
      TLeaf* leaf = (TLeaf*)leafList->At(iar);
      if (leaf != 0) {
         TString leafName = leaf->GetName();
         if (leafName != "type" && leafName != "weight"  && leafName != "boostweight" &&
             leafName != "class" && leafName != "className" && leafName != "classID" && 
             !leafName.Contains("prob_")) {
            // is MVA ?
            if (TMVAGlob::ExistMethodName( leafName )) {
               mvas.push_back( leafName );
            }
            else {
               vars.push_back( leafName );
            }
         }
      }
   }

   cout << "--- Found: " << vars.size() << " variables" << endl;
   cout << "--- Found: " << mvas.size() << " MVA(s)" << endl;
   

   TString type[2] = { "Signal", "Background" };
   const Int_t nmva = mvas.size();
   TCanvas* csig[nmva];
   TCanvas* cbkg[nmva];
   for (Int_t imva=0; imva<mvas.size(); imva++) {
      cout << "--- Plotting parallel coordinates for : " << mvas[imva] << " & input variables" << endl;

      for (Int_t itype=0; itype<2; itype++) {

         // create draw option
         TString varstr = mvas[imva] + ":";
         for (Int_t ivar=0; ivar<vars.size(); ivar++) varstr += vars[ivar] + ":";
         varstr.Resize( varstr.Last( ':' ) );

         // create canvas
         TString mvashort = mvas[imva]; mvashort.ReplaceAll("MVA_","");
         TCanvas* c1 = (itype == 0) ? csig[imva] : cbkg[imva];
         c1 = new TCanvas( Form( "c1_%i",itype ), 
                           Form( "Parallel coordinate representation for %s and input variables (%s events)", 
                                 mvashort.Data(), type[itype].Data() ), 
                           50*(itype), 50*(itype), 750, 500 );      
         tree->Draw( varstr.Data(), Form("classID==%i",1-itype) , "para" );
         c1->ToggleEditor();
         gStyle->SetOptTitle(0);

         TParallelCoord*    para   = (TParallelCoord*)gPad->GetListOfPrimitives()->FindObject( "ParaCoord" );
         TParallelCoordVar* mvavar = (TParallelCoordVar*)para->GetVarList()->FindObject( mvas[imva] );
         Double_t minrange = tree->GetMinimum( mvavar->GetName() );
         Double_t maxrange = tree->GetMaximum( mvavar->GetName() );
         Double_t width    = 0.2*(maxrange - minrange);
         Double_t x1 = minrange, x2 = x1 + width;
         TParallelCoordRange* parrange = new TParallelCoordRange( mvavar, x1, x2 );
         parrange->SetLineColor(4);
         mvavar->AddRange( parrange );

         para->AddSelection("-1");

         for (Int_t ivar=1; ivar<TMath::Min(Int_t(vars.size()) + 1,3); ivar++) {
            TParallelCoordVar* var = (TParallelCoordVar*)para->GetVarList()->FindObject( vars[ivar] );
            minrange = tree->GetMinimum( var->GetName() );
            maxrange = tree->GetMaximum( var->GetName() );
            width    = 0.2*(maxrange - minrange);

            switch (ivar) {
            case 0: { x1 = minrange; x2 = x1 + width; break; }
            case 1: { x1 = 0.5*(maxrange + minrange - width)*0.02; x2 = x1 + width*0.02; break; }
            case 2: { x1 = maxrange - width; x2 = x1 + width; break; }
            }

            parrange = new TParallelCoordRange( var, x1, x2 );
            parrange->SetLineColor( ivar == 0 ? 2 : ivar == 1 ? 5 : 6 );
            var->AddRange( parrange );

            para->AddSelection( Form("%i",ivar) );
         }

         c1->Update();

         TString fname = Form( "plots/paracoor_c%i_%s", imva, itype == 0 ? "S" : "B" );
         TMVAGlob::imgconv( c1, fname );
      }
   }
}
Пример #6
0
void dump_tree(TTree *tree, const char *outdir) {
    GzipOutputStream::Options options;
    options.compression_level = 1;

    for(int li = 0; li < tree->GetListOfLeaves()->GetEntries(); li++) {
        TLeaf *l = (TLeaf*) tree->GetListOfLeaves()->At(li);

        if (lstat(outdir, NULL) == -1) {
            mkdir(outdir, 0777);
        }

        // Open data file
        std::string fn = std::string(outdir) + "/" + l->GetName() + ".dit";
        auto fd = open(fn.c_str(), O_CREAT | O_TRUNC | O_RDWR, S_IRUSR | S_IWUSR);
        assert(fd != -1);
        FileOutputStream fstream(fd);
        GzipOutputStream zstream(&fstream, options);


        // Open meta file
        std::string mfn = fn + "m";
        auto mfd = open(mfn.c_str(), O_CREAT | O_TRUNC | O_RDWR, S_IRUSR | S_IWUSR);
        assert(mfd != -1);
        FileOutputStream meta_fstream(mfd);
        GzipOutputStream meta_zstream(&meta_fstream, options);
        { // Coded stream block 
            CodedOutputStream o(&zstream);
            CodedOutputStream o2(&meta_zstream);

            // determine level and type name
            int level = 0;
            std::string tn = l->GetTypeName();
            while (tn.substr(0,6) == "vector") {
                level = level + 1;
                tn = remove_vector(tn);
            }

            if (tn == "double") {
                dump_required<double>(level, tree, *l, o, o2);
            } else if (tn == "float") {
                dump_required<float>(level, tree, *l, o, o2);
            } else if (tn == "int") {
                dump_required<int>(level, tree, *l, o, o2);
            } else if (tn == "short" || tn == "Short_t") {
                dump_required<short>(level, tree, *l, o, o2);
            } else if (tn == "unsigned int") {
                dump_required<unsigned int>(level, tree, *l, o, o2);
            } else if (tn == "unsigned short") {
                dump_required<unsigned short>(level, tree, *l, o, o2);
            } else if (tn == "Float_t") {
                dump_required<Float_t>(level, tree, *l, o, o2);
            } else if (tn == "Bool_t") {
                dump_required<Bool_t>(level, tree, *l, o, o2);
            } else if (tn == "Char_t") {
                dump_required<Char_t>(level, tree, *l, o, o2);
            } else if (tn == "Double_t") {
                dump_required<Double_t>(level, tree, *l, o, o2);
            } else if (tn == "Int_t") {
                dump_required<Int_t>(level, tree, *l, o, o2);
            } else if (tn == "UInt_t") {
                dump_required<UInt_t>(level, tree, *l, o, o2);
            } else if (tn == "string") {
                dump_required<std::string>(level, tree, *l, o, o2);
            } else {
                std::cerr << "Unknown branch type: " << tn << std::endl;
                assert(false);
            }
        }
        meta_zstream.Close();
        zstream.Close();
        meta_fstream.Close();
        fstream.Close();
    }
}
Пример #7
0
bool TreeReader::Initialize(vector <string> br, string opt)
{
	if(!init)
	{
	    if( !fChain )
		{
		        cout << endl;
			cout << "No tree to initialize" << endl;
			cout << endl;
			return false;
		}

		TObjArray *fileElements = fChain->GetListOfFiles();
		if( !fileElements || ( fileElements->GetEntries() == 0 ))
		{
		        cout << endl;
			cout << "No file(s) to initialize" << endl;
			cout << endl;
			return false;
		}
	}

	varList.clear();

	TObjArray* branches = fChain->GetListOfBranches();
	int nBranches = branches->GetEntries();

	for (int i = 0; i < nBranches; ++i)
	{
		TBranch* branch = (TBranch*)branches->At(i);
		string brname = branch->GetName();
		TLeaf* leaf = branch->GetLeaf(branch->GetName());

		if ( leaf == 0 )  // leaf name is different from branch name
		{
			TObjArray* leafs = branch->GetListOfLeaves();
			leaf = (TLeaf*)leafs->At(0);
		}

		string curtype = leaf->GetTypeName();
        int id = TypeDB::getType(curtype.c_str());
		int arreysize = 1;
		string title = leaf->GetTitle();
        //cout << curtype << "   " << title << endl;

		// Find out whether we have array by inspecting leaf title
		if ( title.find("[")!=std::string::npos )
		{
			TLeaf * nelem = leaf->GetLeafCounter(arreysize);
			if(arreysize == 1 && nelem != NULL) arreysize = nelem->GetMaximum() + 1; //search for maximum value of the lenght
		}


		if(id >= 0)
		{
			bool addVar = true;
			if(br.size()>0)
			{
				addVar = false;
				for(unsigned b = 0; b < br.size(); b++)
				{
					if(opt == "names" || opt == "except")
					{
						if(br[b] == brname) { addVar = true; break;}
					}
					else if(opt.find("contains")!=string::npos)
					{
						if((string(brname)).find(br[b])!=string::npos) { addVar = true; break;}
					}
					else if(opt.find("except")==string::npos) cout << "Option " << opt << " not found" << endl;
				}

				if(opt.find("except")!=string::npos) addVar = !addVar;
			}

			if(addVar)
			{
				variable * tmpVar = new variable(id,arreysize);

				tmpVar->name = leaf->GetName();
				tmpVar->bname = branch->GetName();
				tmpVar->title = title;

				varList.push_back(tmpVar);
				fChain->SetBranchAddress(tmpVar->bname,tmpVar->value.address);
			}
		}
		else
		{
			cout << curtype << ": type not found" << endl;
			exit(1);
			return false;
		}
	}

	init = true;
	continueSorting = true;
	if(pmode=="v") cout << endl << "Set up " << varList.size() << " / " << nBranches << " branches" << endl;

	return true;
}