def make_ttbarReco_plot( channel, x_axis_title, y_axis_title, signal_region_tree, control_region_tree, branchName, name_prefix, x_limits, nBins, use_qcd_data_region = False, y_limits = [], y_max_scale = 1.2, rebin = 1, legend_location = ( 0.98, 0.78 ), cms_logo_location = 'right', log_y = False, legend_color = False, ratio_y_limits = [0.3, 1.7], normalise = False, ): global output_folder, measurement_config, category, normalise_to_fit global preliminary, norm_variable, sum_bins, b_tag_bin, histogram_files # Input files, normalisations, tree/region names qcd_data_region = '' title = title_template % ( measurement_config.new_luminosity / 1000., measurement_config.centre_of_mass_energy ) normalisation = None if channel == 'electron': histogram_files['data'] = measurement_config.data_file_electron_trees histogram_files['QCD'] = measurement_config.electron_QCD_MC_category_templates_trees[category] if normalise_to_fit: normalisation = normalisations_electron[norm_variable] if use_qcd_data_region: qcd_data_region = 'QCDConversions' if channel == 'muon': histogram_files['data'] = measurement_config.data_file_muon_trees histogram_files['QCD'] = measurement_config.muon_QCD_MC_category_templates_trees[category] if normalise_to_fit: normalisation = normalisations_muon[norm_variable] if use_qcd_data_region: qcd_data_region = 'QCD non iso mu+jets ge3j' histograms = get_histograms_from_trees( trees = [signal_region_tree, control_region_tree], branch = branchName, weightBranch = '1', files = histogram_files, nBins = nBins, xMin = x_limits[0], xMax = x_limits[-1] ) selection = 'SolutionCategory == 0' histogramsNoSolution = get_histograms_from_trees( trees = [signal_region_tree], branch = branchName, weightBranch = '1', selection = selection, files = histogram_files, nBins = nBins, xMin = x_limits[0], xMax = x_limits[-1] ) selection = 'SolutionCategory == 1' histogramsCorrect = get_histograms_from_trees( trees = [signal_region_tree], branch = branchName, weightBranch = '1', selection = selection, files = histogram_files, nBins = nBins, xMin = x_limits[0], xMax = x_limits[-1] ) selection = 'SolutionCategory == 2' histogramsNotSL = get_histograms_from_trees( trees = [signal_region_tree], branch = branchName, weightBranch = '1', selection = selection, files = histogram_files, nBins = nBins, xMin = x_limits[0], xMax = x_limits[-1] ) selection = 'SolutionCategory == 3' histogramsNotReco = get_histograms_from_trees( trees = [signal_region_tree], branch = branchName, weightBranch = '1', selection = selection, files = histogram_files, nBins = nBins, xMin = x_limits[0], xMax = x_limits[-1] ) selection = 'SolutionCategory > 3' histogramsWrong = get_histograms_from_trees( trees = [signal_region_tree], branch = branchName, weightBranch = '1', selection = selection, files = histogram_files, nBins = nBins, xMin = x_limits[0], xMax = x_limits[-1] ) # Split histograms up into signal/control (?) signal_region_hists = {} inclusive_control_region_hists = {} for sample in histograms.keys(): signal_region_hists[sample] = histograms[sample][signal_region_tree] if use_qcd_data_region: inclusive_control_region_hists[sample] = histograms[sample][control_region_tree] prepare_histograms( histograms, rebin = 1, scale_factor = measurement_config.luminosity_scale ) prepare_histograms( histogramsNoSolution, rebin = 1, scale_factor = measurement_config.luminosity_scale ) prepare_histograms( histogramsCorrect, rebin = 1, scale_factor = measurement_config.luminosity_scale ) prepare_histograms( histogramsNotSL, rebin = 1, scale_factor = measurement_config.luminosity_scale ) prepare_histograms( histogramsNotReco, rebin = 1, scale_factor = measurement_config.luminosity_scale ) prepare_histograms( histogramsWrong, rebin = 1, scale_factor = measurement_config.luminosity_scale ) qcd_from_data = signal_region_hists['QCD'] # Which histograms to draw, and properties histograms_to_draw = [signal_region_hists['data'], qcd_from_data, signal_region_hists['V+Jets'], signal_region_hists['SingleTop'], histogramsNoSolution['TTJet'][signal_region_tree], histogramsNotSL['TTJet'][signal_region_tree], histogramsNotReco['TTJet'][signal_region_tree], histogramsWrong['TTJet'][signal_region_tree], histogramsCorrect['TTJet'][signal_region_tree] ] histogram_lables = ['data', 'QCD', 'V+Jets', 'Single-Top', samples_latex['TTJet'] + ' - no solution', samples_latex['TTJet'] + ' - not SL', samples_latex['TTJet'] + ' - not reconstructible', samples_latex['TTJet'] + ' - wrong reco', samples_latex['TTJet'] + ' - correct', ] histogram_colors = ['black', 'yellow', 'green', 'magenta', 'black', 'burlywood', 'chartreuse', 'blue', 'red' ] histogram_properties = Histogram_properties() histogram_properties.name = name_prefix + b_tag_bin if category != 'central': histogram_properties.name += '_' + category histogram_properties.title = title histogram_properties.x_axis_title = x_axis_title histogram_properties.y_axis_title = y_axis_title histogram_properties.x_limits = x_limits histogram_properties.y_limits = y_limits histogram_properties.y_max_scale = y_max_scale histogram_properties.xerr = None # workaround for rootpy issue #638 histogram_properties.emptybins = True if b_tag_bin: histogram_properties.additional_text = channel_latex[channel] + ', ' + b_tag_bins_latex[b_tag_bin] else: histogram_properties.additional_text = channel_latex[channel] histogram_properties.legend_location = legend_location histogram_properties.cms_logo_location = cms_logo_location histogram_properties.preliminary = preliminary histogram_properties.set_log_y = log_y histogram_properties.legend_color = legend_color if ratio_y_limits: histogram_properties.ratio_y_limits = ratio_y_limits if normalise_to_fit: histogram_properties.mc_error = get_normalisation_error( normalisation ) histogram_properties.mc_errors_label = 'fit uncertainty' else: histogram_properties.mc_error = mc_uncertainty histogram_properties.mc_errors_label = 'MC unc.' # Actually draw histograms make_data_mc_comparison_plot( histograms_to_draw, histogram_lables, histogram_colors, histogram_properties, save_folder = output_folder, show_ratio = False, normalise = normalise, ) histogram_properties.name += '_with_ratio' loc = histogram_properties.legend_location # adjust legend location as it is relative to canvas! histogram_properties.legend_location = ( loc[0], loc[1] + 0.05 ) make_data_mc_comparison_plot( histograms_to_draw, histogram_lables, histogram_colors, histogram_properties, save_folder = output_folder, show_ratio = True, normalise = normalise, )
def make_plot( channel, x_axis_title, y_axis_title, signal_region_tree, control_region_tree, branchName, name_prefix, x_limits, nBins, use_qcd_data_region=False, compare_qcd_signal_with_data_control=False, y_limits=[], y_max_scale=1.3, rebin=1, legend_location=(0.98, 0.78), cms_logo_location='right', log_y=False, legend_color=False, ratio_y_limits=[0.3, 2.5], normalise=False, ): global output_folder, measurement_config, category, normalise_to_fit global preliminary, norm_variable, sum_bins, b_tag_bin, histogram_files controlToCompare = [] if 'electron' in channel: controlToCompare = ['QCDConversions', 'QCD non iso e+jets'] elif 'muon' in channel: controlToCompare = ['QCD iso > 0.3', 'QCD 0.12 < iso <= 0.3'] histogramsToCompare = {} for qcd_data_region in controlToCompare: print 'Doing ', qcd_data_region # Input files, normalisations, tree/region names title = title_template % (measurement_config.new_luminosity, measurement_config.centre_of_mass_energy) normalisation = None weightBranchSignalRegion = 'EventWeight' if 'electron' in channel: histogram_files[ 'data'] = measurement_config.data_file_electron_trees histogram_files[ 'QCD'] = measurement_config.electron_QCD_MC_category_templates_trees[ category] if normalise_to_fit: normalisation = normalisations_electron[norm_variable] # if use_qcd_data_region: # qcd_data_region = 'QCDConversions' # # qcd_data_region = 'QCD non iso e+jets' if not 'QCD' in channel and not 'NPU' in branchName: weightBranchSignalRegion += ' * ElectronEfficiencyCorrection' if 'muon' in channel: histogram_files['data'] = measurement_config.data_file_muon_trees histogram_files[ 'QCD'] = measurement_config.muon_QCD_MC_category_templates_trees[ category] if normalise_to_fit: normalisation = normalisations_muon[norm_variable] # if use_qcd_data_region: # qcd_data_region = 'QCD iso > 0.3' if not 'QCD' in channel and not 'NPU' in branchName: weightBranchSignalRegion += ' * MuonEfficiencyCorrection' if not "_NPUNoWeight" in name_prefix: weightBranchSignalRegion += ' * PUWeight' if not "_NBJetsNoWeight" in name_prefix: weightBranchSignalRegion += ' * BJetWeight' selection = '1' if branchName == 'abs(lepton_eta)': selection = 'lepton_eta > -10' else: selection = '%s >= 0' % branchName # if 'QCDConversions' in signal_region_tree: # selection += '&& isTightElectron' # print selection histograms = get_histograms_from_trees( trees=[signal_region_tree, control_region_tree], branch=branchName, weightBranch=weightBranchSignalRegion, files=histogram_files, nBins=nBins, xMin=x_limits[0], xMax=x_limits[-1], selection=selection) histograms_QCDControlRegion = None if use_qcd_data_region: qcd_control_region = signal_region_tree.replace( 'Ref selection', qcd_data_region) histograms_QCDControlRegion = get_histograms_from_trees( trees=[qcd_control_region], branch=branchName, weightBranch='EventWeight', files=histogram_files, nBins=nBins, xMin=x_limits[0], xMax=x_limits[-1], selection=selection) # Split histograms up into signal/control (?) signal_region_hists = {} control_region_hists = {} for sample in histograms.keys(): signal_region_hists[sample] = histograms[sample][ signal_region_tree] if compare_qcd_signal_with_data_control: if sample is 'data': signal_region_hists[sample] = histograms[sample][ control_region_tree] elif sample is 'QCD': signal_region_hists[sample] = histograms[sample][ signal_region_tree] else: del signal_region_hists[sample] if use_qcd_data_region: control_region_hists[sample] = histograms_QCDControlRegion[ sample][qcd_control_region] # Prepare histograms if normalise_to_fit: # only scale signal region to fit (results are invalid for control region) prepare_histograms( signal_region_hists, rebin=rebin, scale_factor=measurement_config.luminosity_scale, normalisation=normalisation) elif normalise_to_data: totalMC = 0 for sample in signal_region_hists: if sample is 'data': continue totalMC += signal_region_hists[sample].Integral() newScale = signal_region_hists['data'].Integral() / totalMC prepare_histograms( signal_region_hists, rebin=rebin, scale_factor=newScale, ) else: print measurement_config.luminosity_scale prepare_histograms( signal_region_hists, rebin=rebin, scale_factor=measurement_config.luminosity_scale) prepare_histograms( control_region_hists, rebin=rebin, scale_factor=measurement_config.luminosity_scale) # Use qcd from data control region or not qcd_from_data = None if use_qcd_data_region: qcd_from_data = clean_control_region( control_region_hists, subtract=['TTJet', 'V+Jets', 'SingleTop']) # Normalise control region correctly nBins = signal_region_hists['QCD'].GetNbinsX() n, error = signal_region_hists['QCD'].integral(0, nBins + 1, error=True) n_qcd_predicted_mc_signal = ufloat(n, error) n, error = control_region_hists['QCD'].integral(0, nBins + 1, error=True) n_qcd_predicted_mc_control = ufloat(n, error) n, error = qcd_from_data.integral(0, nBins + 1, error=True) n_qcd_control_region = ufloat(n, error) if not n_qcd_control_region == 0: dataDrivenQCDScale = n_qcd_predicted_mc_signal / n_qcd_predicted_mc_control print 'Overall scale : ', dataDrivenQCDScale qcd_from_data.Scale(dataDrivenQCDScale.nominal_value) signalToControlScale = n_qcd_predicted_mc_signal / n_qcd_control_region dataToMCscale = n_qcd_control_region / n_qcd_predicted_mc_control print "Signal to control :", signalToControlScale print "QCD scale : ", dataToMCscale else: qcd_from_data = signal_region_hists['QCD'] # Which histograms to draw, and properties histograms_to_draw = [] histogram_lables = [] histogram_colors = [] if compare_qcd_signal_with_data_control: histograms_to_draw = [signal_region_hists['data'], qcd_from_data] histogram_lables = ['data', 'QCD'] histogram_colors = ['black', 'yellow'] else: histograms_to_draw = [ signal_region_hists['data'], qcd_from_data, signal_region_hists['V+Jets'], signal_region_hists['SingleTop'], signal_region_hists['TTJet'] ] histogram_lables = [ 'data', 'QCD', 'V+Jets', 'Single-Top', samples_latex['TTJet'] ] histogram_colors = [ colours['data'], colours['QCD'], colours['V+Jets'], colours['Single-Top'], colours['TTJet'] ] print list(qcd_from_data.y()) histogramsToCompare[qcd_data_region] = qcd_from_data print histogramsToCompare histogram_properties = Histogram_properties() histogram_properties.name = 'QCD_control_region_comparison_' + channel + '_' + branchName histogram_properties.title = title histogram_properties.x_axis_title = x_axis_title histogram_properties.y_axis_title = y_axis_title histogram_properties.x_limits = x_limits histogram_properties.y_limits = y_limits histogram_properties.mc_error = 0.0 histogram_properties.legend_location = (0.98, 0.78) histogram_properties.ratio_y_limits = ratio_y_limits if 'electron' in channel: make_control_region_comparison( histogramsToCompare['QCDConversions'], histogramsToCompare['QCD non iso e+jets'], name_region_1='Conversions', name_region_2='Non Iso', histogram_properties=histogram_properties, save_folder=output_folder) elif 'muon' in channel: make_control_region_comparison( histogramsToCompare['QCD iso > 0.3'], histogramsToCompare['QCD 0.12 < iso <= 0.3'], name_region_1='QCD iso > 0.3', name_region_2='QCD 0.12 < iso <= 0.3', histogram_properties=histogram_properties, save_folder=output_folder)
def make_plot( channel, x_axis_title, y_axis_title, signal_region_tree, control_region_tree, branchName, name_prefix, x_limits, nBins, use_qcd_data_region = False, compare_qcd_signal_with_data_control = False, y_limits = [], y_max_scale = 1.3, rebin = 1, legend_location = ( 0.98, 0.78 ), cms_logo_location = 'right', log_y = False, legend_color = False, ratio_y_limits = [0.3, 2.5], normalise = False, ): global output_folder, measurement_config, category, normalise_to_fit global preliminary, norm_variable, sum_bins, b_tag_bin, histogram_files controlToCompare = [] if 'electron' in channel : controlToCompare = ['QCDConversions', 'QCD non iso e+jets'] elif 'muon' in channel : controlToCompare = ['QCD iso > 0.3', 'QCD 0.12 < iso <= 0.3'] histogramsToCompare = {} for qcd_data_region in controlToCompare: print 'Doing ',qcd_data_region # Input files, normalisations, tree/region names title = title_template % ( measurement_config.new_luminosity, measurement_config.centre_of_mass_energy ) normalisation = None weightBranchSignalRegion = 'EventWeight' if 'electron' in channel: histogram_files['data'] = measurement_config.data_file_electron_trees histogram_files['QCD'] = measurement_config.electron_QCD_MC_category_templates_trees[category] if normalise_to_fit: normalisation = normalisations_electron[norm_variable] # if use_qcd_data_region: # qcd_data_region = 'QCDConversions' # # qcd_data_region = 'QCD non iso e+jets' if not 'QCD' in channel and not 'NPU' in branchName: weightBranchSignalRegion += ' * ElectronEfficiencyCorrection' if 'muon' in channel: histogram_files['data'] = measurement_config.data_file_muon_trees histogram_files['QCD'] = measurement_config.muon_QCD_MC_category_templates_trees[category] if normalise_to_fit: normalisation = normalisations_muon[norm_variable] # if use_qcd_data_region: # qcd_data_region = 'QCD iso > 0.3' if not 'QCD' in channel and not 'NPU' in branchName: weightBranchSignalRegion += ' * MuonEfficiencyCorrection' if not "_NPUNoWeight" in name_prefix: weightBranchSignalRegion += ' * PUWeight' if not "_NBJetsNoWeight" in name_prefix: weightBranchSignalRegion += ' * BJetWeight' selection = '1' if branchName == 'abs(lepton_eta)' : selection = 'lepton_eta > -10' else: selection = '%s >= 0' % branchName # if 'QCDConversions' in signal_region_tree: # selection += '&& isTightElectron' # print selection histograms = get_histograms_from_trees( trees = [signal_region_tree, control_region_tree], branch = branchName, weightBranch = weightBranchSignalRegion, files = histogram_files, nBins = nBins, xMin = x_limits[0], xMax = x_limits[-1], selection = selection ) histograms_QCDControlRegion = None if use_qcd_data_region: qcd_control_region = signal_region_tree.replace( 'Ref selection', qcd_data_region ) histograms_QCDControlRegion = get_histograms_from_trees( trees = [qcd_control_region], branch = branchName, weightBranch = 'EventWeight', files = histogram_files, nBins = nBins, xMin = x_limits[0], xMax = x_limits[-1], selection = selection ) # Split histograms up into signal/control (?) signal_region_hists = {} control_region_hists = {} for sample in histograms.keys(): signal_region_hists[sample] = histograms[sample][signal_region_tree] if compare_qcd_signal_with_data_control: if sample is 'data': signal_region_hists[sample] = histograms[sample][control_region_tree] elif sample is 'QCD' : signal_region_hists[sample] = histograms[sample][signal_region_tree] else: del signal_region_hists[sample] if use_qcd_data_region: control_region_hists[sample] = histograms_QCDControlRegion[sample][qcd_control_region] # Prepare histograms if normalise_to_fit: # only scale signal region to fit (results are invalid for control region) prepare_histograms( signal_region_hists, rebin = rebin, scale_factor = measurement_config.luminosity_scale, normalisation = normalisation ) elif normalise_to_data: totalMC = 0 for sample in signal_region_hists: if sample is 'data' : continue totalMC += signal_region_hists[sample].Integral() newScale = signal_region_hists['data'].Integral() / totalMC prepare_histograms( signal_region_hists, rebin = rebin, scale_factor = newScale, ) else: print measurement_config.luminosity_scale prepare_histograms( signal_region_hists, rebin = rebin, scale_factor = measurement_config.luminosity_scale ) prepare_histograms( control_region_hists, rebin = rebin, scale_factor = measurement_config.luminosity_scale ) # Use qcd from data control region or not qcd_from_data = None if use_qcd_data_region: qcd_from_data = clean_control_region( control_region_hists, subtract = ['TTJet', 'V+Jets', 'SingleTop'] ) # Normalise control region correctly nBins = signal_region_hists['QCD'].GetNbinsX() n, error = signal_region_hists['QCD'].integral(0,nBins+1,error=True) n_qcd_predicted_mc_signal = ufloat( n, error) n, error = control_region_hists['QCD'].integral(0,nBins+1,error=True) n_qcd_predicted_mc_control = ufloat( n, error) n, error = qcd_from_data.integral(0,nBins+1,error=True) n_qcd_control_region = ufloat( n, error) if not n_qcd_control_region == 0: dataDrivenQCDScale = n_qcd_predicted_mc_signal / n_qcd_predicted_mc_control print 'Overall scale : ',dataDrivenQCDScale qcd_from_data.Scale( dataDrivenQCDScale.nominal_value ) signalToControlScale = n_qcd_predicted_mc_signal / n_qcd_control_region dataToMCscale = n_qcd_control_region / n_qcd_predicted_mc_control print "Signal to control :",signalToControlScale print "QCD scale : ",dataToMCscale else: qcd_from_data = signal_region_hists['QCD'] # Which histograms to draw, and properties histograms_to_draw = [] histogram_lables = [] histogram_colors = [] if compare_qcd_signal_with_data_control : histograms_to_draw = [signal_region_hists['data'], qcd_from_data ] histogram_lables = ['data', 'QCD'] histogram_colors = ['black', 'yellow'] else : histograms_to_draw = [signal_region_hists['data'], qcd_from_data, signal_region_hists['V+Jets'], signal_region_hists['SingleTop'], signal_region_hists['TTJet']] histogram_lables = ['data', 'QCD', 'V+Jets', 'Single-Top', samples_latex['TTJet']] histogram_colors = [colours['data'], colours['QCD'], colours['V+Jets'], colours['Single-Top'], colours['TTJet'] ] print list(qcd_from_data.y()) histogramsToCompare[qcd_data_region] = qcd_from_data print histogramsToCompare histogram_properties = Histogram_properties() histogram_properties.name = 'QCD_control_region_comparison_' + channel + '_' + branchName histogram_properties.title = title histogram_properties.x_axis_title = x_axis_title histogram_properties.y_axis_title = y_axis_title histogram_properties.x_limits = x_limits histogram_properties.y_limits = y_limits histogram_properties.mc_error = 0.0 histogram_properties.legend_location = ( 0.98, 0.78 ) histogram_properties.ratio_y_limits = ratio_y_limits if 'electron' in channel: make_control_region_comparison(histogramsToCompare['QCDConversions'], histogramsToCompare['QCD non iso e+jets'], name_region_1='Conversions', name_region_2='Non Iso', histogram_properties=histogram_properties, save_folder=output_folder) elif 'muon' in channel: make_control_region_comparison(histogramsToCompare['QCD iso > 0.3'], histogramsToCompare['QCD 0.12 < iso <= 0.3'], name_region_1='QCD iso > 0.3', name_region_2='QCD 0.12 < iso <= 0.3', histogram_properties=histogram_properties, save_folder=output_folder)
def make_ttbarReco_plot( channel, x_axis_title, y_axis_title, signal_region_tree, control_region_tree, branchName, name_prefix, x_limits, nBins, use_qcd_data_region=False, y_limits=[], y_max_scale=1.2, rebin=1, legend_location=(0.98, 0.78), cms_logo_location='right', log_y=False, legend_color=False, ratio_y_limits=[0.3, 1.7], normalise=False, ): global output_folder, measurement_config, category, normalise_to_fit global preliminary, norm_variable, sum_bins, b_tag_bin, histogram_files # Input files, normalisations, tree/region names qcd_data_region = '' title = title_template % (measurement_config.new_luminosity / 1000., measurement_config.centre_of_mass_energy) normalisation = None if channel == 'electron': histogram_files['data'] = measurement_config.data_file_electron_trees histogram_files[ 'QCD'] = measurement_config.electron_QCD_MC_category_templates_trees[ category] if normalise_to_fit: normalisation = normalisations_electron[norm_variable] if use_qcd_data_region: qcd_data_region = 'QCDConversions' if channel == 'muon': histogram_files['data'] = measurement_config.data_file_muon_trees histogram_files[ 'QCD'] = measurement_config.muon_QCD_MC_category_templates_trees[ category] if normalise_to_fit: normalisation = normalisations_muon[norm_variable] if use_qcd_data_region: qcd_data_region = 'QCD non iso mu+jets ge3j' histograms = get_histograms_from_trees( trees=[signal_region_tree, control_region_tree], branch=branchName, weightBranch='1', files=histogram_files, nBins=nBins, xMin=x_limits[0], xMax=x_limits[-1]) selection = 'SolutionCategory == 0' histogramsNoSolution = get_histograms_from_trees( trees=[signal_region_tree], branch=branchName, weightBranch='1', selection=selection, files=histogram_files, nBins=nBins, xMin=x_limits[0], xMax=x_limits[-1]) selection = 'SolutionCategory == 1' histogramsCorrect = get_histograms_from_trees(trees=[signal_region_tree], branch=branchName, weightBranch='1', selection=selection, files=histogram_files, nBins=nBins, xMin=x_limits[0], xMax=x_limits[-1]) selection = 'SolutionCategory == 2' histogramsNotSL = get_histograms_from_trees(trees=[signal_region_tree], branch=branchName, weightBranch='1', selection=selection, files=histogram_files, nBins=nBins, xMin=x_limits[0], xMax=x_limits[-1]) selection = 'SolutionCategory == 3' histogramsNotReco = get_histograms_from_trees(trees=[signal_region_tree], branch=branchName, weightBranch='1', selection=selection, files=histogram_files, nBins=nBins, xMin=x_limits[0], xMax=x_limits[-1]) selection = 'SolutionCategory > 3' histogramsWrong = get_histograms_from_trees(trees=[signal_region_tree], branch=branchName, weightBranch='1', selection=selection, files=histogram_files, nBins=nBins, xMin=x_limits[0], xMax=x_limits[-1]) # Split histograms up into signal/control (?) signal_region_hists = {} inclusive_control_region_hists = {} for sample in histograms.keys(): signal_region_hists[sample] = histograms[sample][signal_region_tree] if use_qcd_data_region: inclusive_control_region_hists[sample] = histograms[sample][ control_region_tree] prepare_histograms(histograms, rebin=1, scale_factor=measurement_config.luminosity_scale) prepare_histograms(histogramsNoSolution, rebin=1, scale_factor=measurement_config.luminosity_scale) prepare_histograms(histogramsCorrect, rebin=1, scale_factor=measurement_config.luminosity_scale) prepare_histograms(histogramsNotSL, rebin=1, scale_factor=measurement_config.luminosity_scale) prepare_histograms(histogramsNotReco, rebin=1, scale_factor=measurement_config.luminosity_scale) prepare_histograms(histogramsWrong, rebin=1, scale_factor=measurement_config.luminosity_scale) qcd_from_data = signal_region_hists['QCD'] # Which histograms to draw, and properties histograms_to_draw = [ signal_region_hists['data'], qcd_from_data, signal_region_hists['V+Jets'], signal_region_hists['SingleTop'], histogramsNoSolution['TTJet'][signal_region_tree], histogramsNotSL['TTJet'][signal_region_tree], histogramsNotReco['TTJet'][signal_region_tree], histogramsWrong['TTJet'][signal_region_tree], histogramsCorrect['TTJet'][signal_region_tree] ] histogram_lables = [ 'data', 'QCD', 'V+Jets', 'Single-Top', samples_latex['TTJet'] + ' - no solution', samples_latex['TTJet'] + ' - not SL', samples_latex['TTJet'] + ' - not reconstructible', samples_latex['TTJet'] + ' - wrong reco', samples_latex['TTJet'] + ' - correct', ] histogram_colors = [ 'black', 'yellow', 'green', 'magenta', 'black', 'burlywood', 'chartreuse', 'blue', 'red' ] histogram_properties = Histogram_properties() histogram_properties.name = name_prefix + b_tag_bin if category != 'central': histogram_properties.name += '_' + category histogram_properties.title = title histogram_properties.x_axis_title = x_axis_title histogram_properties.y_axis_title = y_axis_title histogram_properties.x_limits = x_limits histogram_properties.y_limits = y_limits histogram_properties.y_max_scale = y_max_scale histogram_properties.xerr = None # workaround for rootpy issue #638 histogram_properties.emptybins = True if b_tag_bin: histogram_properties.additional_text = channel_latex[ channel] + ', ' + b_tag_bins_latex[b_tag_bin] else: histogram_properties.additional_text = channel_latex[channel] histogram_properties.legend_location = legend_location histogram_properties.cms_logo_location = cms_logo_location histogram_properties.preliminary = preliminary histogram_properties.set_log_y = log_y histogram_properties.legend_color = legend_color if ratio_y_limits: histogram_properties.ratio_y_limits = ratio_y_limits if normalise_to_fit: histogram_properties.mc_error = get_normalisation_error(normalisation) histogram_properties.mc_errors_label = 'fit uncertainty' else: histogram_properties.mc_error = mc_uncertainty histogram_properties.mc_errors_label = 'MC unc.' # Actually draw histograms make_data_mc_comparison_plot( histograms_to_draw, histogram_lables, histogram_colors, histogram_properties, save_folder=output_folder, show_ratio=False, normalise=normalise, ) histogram_properties.name += '_with_ratio' loc = histogram_properties.legend_location # adjust legend location as it is relative to canvas! histogram_properties.legend_location = (loc[0], loc[1] + 0.05) make_data_mc_comparison_plot( histograms_to_draw, histogram_lables, histogram_colors, histogram_properties, save_folder=output_folder, show_ratio=True, normalise=normalise, )