import os, sys import ROOT # To run, do an "execfile( '/demo.py' )" or "python /demo.py" # enable running from another directory than the one where demo.py resides workdir = os.path.dirname( sys.argv[0] ) if workdir: os.chdir( workdir ) # This macro generates a Controlbar menu: To see the output, click begin_html here end_html # To execute an item, click with the left mouse button. # To see the HELP of a button, click on the right mouse button. ROOT.gROOT.Reset() ROOT.gStyle.SetScreenFactor(1) # if you have a large screen, select 1.2 or 1.4 bar = ROOT.TControlBar( 'vertical', 'Demos', 10, 10 ) # The callbacks to python work by having CINT call the python interpreter through # the "TPython" class. Note the use of "raw strings." bar.AddButton( 'Help on Demos', r'TPython::Exec( "execfile( \'demoshelp.py\' )" );', 'Click Here For Help on Running the Demos' ) bar.AddButton( 'browser', r'TPython::Exec( "b = ROOT.TBrowser()" );', 'Start the ROOT browser' ) bar.AddButton( 'framework', r'TPython::Exec( "execfile( \'framework.py\' )" );', 'An Example of Object Oriented User Interface' ) bar.AddButton( 'first', r'TPython::Exec( "execfile( \'first.py\' )" );', 'An Example of Slide with Root' ) bar.AddButton( 'hsimple', r'TPython::Exec( "execfile( \'hsimple.py\' )" );', 'Creating histograms/Ntuples on file', "button" ) bar.AddButton( 'hsum', r'TPython::Exec( "execfile( \'hsum.py\' )" );', 'Filling Histograms and Some Graphics Options' ) bar.AddButton( 'formula1', r'TPython::Exec( "execfile( \'formula1.py\' )" );', 'Simple Formula and Functions' ) bar.AddButton( 'surfaces', r'TPython::Exec( "execfile( \'surfaces.py\' )" );', 'Surface Drawing Options' ) bar.AddButton( 'fillrandom', r'TPython::Exec( "execfile( \'fillrandom.py\' )" );','Histograms with Random Numbers from a Function' ) bar.AddButton( 'fit1', r'TPython::Exec( "execfile( \'fit1.py\' )" );', 'A Simple Fitting Example' ) bar.AddButton( 'multifit', r'TPython::Exec( "execfile( \'multifit.py\' )" );', 'Fitting in Subranges of Histograms' ) bar.AddButton( 'h1draw', r'TPython::Exec( "execfile( \'h1draw.py\' )" );', 'Drawing Options for 1D Histograms' ) bar.AddButton( 'graph', r'TPython::Exec( "execfile( \'graph.py\' )" );', 'Example of a Simple Graph' ) bar.AddButton( 'gerrors', r'TPython::Exec( "execfile( \'gerrors.py\' )" );', 'Example of a Graph with Error Bars' ) bar.AddButton( 'tornado', r'TPython::Exec( "execfile( \'tornado.py\' )" );', 'Examples of 3-D PolyMarkers' ) bar.AddButton( 'shapes', r'TPython::Exec( "execfile( \'shapes.py\' )" );', 'The Geometry Shapes' ) bar.AddButton( 'geometry', r'TPython::Exec( "execfile( \'geometry.py\' )" );', 'Creation of the NA49 Geometry File' ) bar.AddButton( 'na49view', r'TPython::Exec( "execfile( \'na49view.py\' )" );', 'Two Views of the NA49 Detector Geometry' ) bar.AddButton( 'file', r'TPython::Exec( "execfile( \'file.py\' )" );', 'The ROOT File Format' ) bar.AddButton( 'fildir', r'TPython::Exec( "execfile( \'fildir.py\' )" );', 'The ROOT File, Directories and Keys' ) bar.AddButton( 'tree', r'TPython::Exec( "execfile( \'tree.py\' )" );', 'The Tree Data Structure' ) bar.AddButton( 'ntuple1', r'TPython::Exec( "execfile( \'ntuple1.py\' )" );', 'Ntuples and Selections' ) bar.AddButton( 'rootmarks', r'TPython::Exec( "execfile( \'rootmarks.py\' )" );', 'Prints an Estimated ROOTMARKS for Your Machine' ) bar.AddSeparator() # not implemented bar.AddButton( 'make ntuple', r'TPython::Exec( "execfile( \'mrt.py\' )" );', 'Convert a text file to an ntuple' ) bar.Show() ROOT.gROOT.SaveContext() ## wait for input to keep the GUI (which lives on a ROOT event dispatcher) alive if __name__ == '__main__': rep = '' while not rep in [ 'q', 'Q' ]: rep = raw_input( 'enter "q" to quit: ' ) if 1 < len(rep): rep = rep[0]