import sys,os import ROOT as r import numpy as np import funcsByBarbara as tools #r.gROOT.SetBatch(r.kTRUE) r.gROOT.ProcessLine(".X lhcbStyle.C") plots = {} pdg = r.TDatabasePDG.Instance() def addPlot(key, x_axis, tree, string, cuts=None): if not cuts: tree.Draw(string+'>>h1') else: tree.Draw(string+'>>h1', cuts) plots[key] = r.gDirectory.Get('h1') plots[key].GetXaxis().SetTitle(x_axis) plots[key].SetTitle(key) plots[key].SetName(key) c1 = r.TCanvas(); c1.cd() if "IP" in key or "Mass" in key or "DOCA" in key or "dChi2" in key: c1.SetLogy() plots[key].Draw() c1.Print('accPlots/%s.pdf'%key) c1.Print('accPlots/%s.png'%key) key += "-WEIGHTED" if 'bg' in key or ('nu' in key and key != 'mumunu'): if not cuts: tree.Draw(string+'>>h1', "NuWeight") else: cuts = "NuWeight*("+cuts+")" tree.Draw(string+'>>h1', cuts) plots[key] = r.gDirectory.Get('h1') plots[key].GetXaxis().SetTitle(x_axis) plots[key].SetTitle(key) plots[key].SetName(key) c1 = r.TCanvas(); c1.cd() if "IP" in key or "Mass" in key or "DOCA" in key or "dChi2" in key: c1.SetLogy() plots[key].Draw() c1.Print('accPlots/%s.pdf'%key) c1.Print('accPlots/%s.png'%key) elif 'cosmics' in key: if not cuts: tree.Draw(string+'>>h1',"HNLw*1.e6/200.") else: cuts = "HNLw*1.e6/200.*("+cuts+")" tree.Draw(string+'>>h1', cuts) plots[key] = r.gDirectory.Get('h1') plots[key].GetXaxis().SetTitle(x_axis) plots[key].SetTitle(key) plots[key].SetName(key) c1 = r.TCanvas(); c1.cd() if "IP" in key or "Mass" in key or "DOCA" in key or "dChi2" in key: c1.SetLogy() plots[key].Draw() c1.Print('accPlots/%s.pdf'%key) c1.Print('accPlots/%s.png'%key) else: if not cuts: tree.Draw(string+'>>h1',"HNLw") else: cuts = "HNLw*("+cuts+")" tree.Draw(string+'>>h1', cuts) plots[key] = r.gDirectory.Get('h1') plots[key].GetXaxis().SetTitle(x_axis) plots[key].SetTitle(key) plots[key].SetName(key) c1 = r.TCanvas(); c1.cd() if "IP" in key or "Mass" in key or "DOCA" in key or "dChi2" in key: c1.SetLogy() plots[key].Draw() c1.Print('accPlots/%s.pdf'%key) c1.Print('accPlots/%s.png'%key) fpimu = r.TFile('../DATA/NewPIMU/ShipAna_newGen.root','read')#r.TFile('../DATA/MUPI/ShipAna.root','read') pimu = fpimu.Get('t') pimu_geo = tools.searchForNodes3_xyz_dict('../DATA/NewPIMU/geofile_full.10.0.Pythia8-TGeant4-1.0GeV-008.root')#'../DATA/MUPI/geofile_full.10.0.Pythia8-TGeant4-1.0GeV-008-2985556.root') fmumunu = r.TFile('../DATA/NewMUMUNU/ShipAna_newGen.root','read')#r.TFile('../DATA/MUMUNU/ShipAna.root','read') mumunu = fmumunu.Get('t') mumunu_geo = tools.searchForNodes3_xyz_dict('../DATA/NewMUMUNU/geofile_full.10.0.Pythia8-TGeant4-1.0GeV-008-mumunu.root')#'../DATA/MUMUNU/geofile_full.10.0.Pythia8-TGeant4-1.0GeV-008-TOTAL.root') ftiny = r.TFile('../DATA/SmallHNLs/ShipAna_newGen.root', 'read') tiny = ftiny.Get('t') tiny_geo = tools.searchForNodes3_xyz_dict('../DATA/SmallHNLs/geofile_full.10.0.Pythia8-TGeant4-0.1GeV-011.root') #fcosmics = r.TFile('../DATA/Cosmics/ShipAna.root','read') #cosmics = fcosmics.Get('ShipAna') #cosmics_geo = tools.searchForNodes2_xyz_dict('../DATA/Cosmics/geofile_full.Signal.10.0.Cosmics3.25.1-8.root') # #fnubar = r.TFile('../DATA/NewKLONG/ShipAna_nubar.root','read')#'../DATA/NewKLONG/ShipAna74-75_nubar.root','read') #nubar = fnubar.Get('ShipAna') #nubar_geo = tools.searchForNodes3_xyz_dict('../DATA/NewKLONG/geofile_full.10.0.Genie-TGeant4_nubar.root')#neutrino74-75.root') # #fnu = r.TFile('../DATA/NewKLONG/ShipAna_nu.root','read')#'../DATA/NewKLONG/ShipAna77_nu.root','read') #nu = fnu.Get('ShipAna') #nu_geo = tools.searchForNodes3_xyz_dict('../DATA/NewKLONG/geofile_full.10.0.Genie-TGeant4_nu.root')#neutrino77.root') # Neutrinos from yandex fnu = r.TFile('../DATA/nuFromYandex/newGen_15340000_nuBg.root') nu = fnu.Get('t') nu_geo = tools.searchForNodes3_xyz_dict('../DATA/nuFromYandex/geofile_full.10.0.Genie-TGeant4.root')#neutrino77.root') # For a correct normalisation, we subtract the events that have an HNL vertex produced outside of the 60m fiducial volume studies = { 'pimu': {'data':pimu, 'geo':pimu_geo, 'seen':[], 'ntot':20000-125},#136}, 'mumunu': {'data':mumunu, 'geo':mumunu_geo, 'seen':[], 'ntot':20000-280},#289}, 'tiny': {'data': tiny, 'geo':tiny_geo, 'seen':[], 'ntot':20000-43},#66}, 'nu': {'data': nu, 'geo':nu_geo, 'seen':[], 'ntot':1.534e7}, #'cosmics': {'data':cosmics, 'geo':cosmics_geo, 'seen':[], 'ntot':cosmics.GetEntriesFast()}, #'nubar': {'data': nubar, 'geo':nubar_geo, 'seen':[], 'ntot':99999*2},#99999*2}, #'nu': {'data': nu, 'geo':nu_geo, 'seen':[], 'ntot':99999*2}#99999} } #print 'Found %s entries in the cosmics file'%cosmics.GetEntriesFast() # Cuts: # - z_vertex in [vol[0]+5m, straw[0]] # - has track converged # - chi2/ndof < 10 # - DOCA < 10 cm # - has no veto? flux_nu = 1.05e+11 * 2.e+20/ 5.e+13#1.61e+11 * 2.e+20/ 4.e+13 flux_anti = 7.38e+10 * 2.e+20 / 5.e+13#1.02e+11 * 2.e+20 / 4.e+13 #flux_nu = (1.09e+12 * 2.e+20)/ 5.e+13 #flux_anti = 6.98e+11 * 2.e+20 / 5.e+13 entries_nu = 1.534e7#200000-2 entries_anti =175*10e+3#entries_anti = 200000-2 weight_nu = "(weight * %s / %s)"%(flux_nu,entries_nu) weight_anti ="(weight * %s / %s)"%(flux_anti,entries_anti) class MyParticle(object): """ Simulating an ntuple filled by particle from one filled by event :) """ def __init__(self, event, index, noB='', eff=''): self.EventNumber = event.__getattr__('event') self.DaughtersFitConverged = [event.__getattr__('DaughtersFitConverged')[index], event.__getattr__('DaughtersFitConverged')[index]] chi2red = [event.__getattr__('%sMaxDaughtersRedChi2'%noB)[index], event.__getattr__('%sMaxDaughtersRedChi2'%noB)[index]] ndf = [event.__getattr__('%sMinDaughtersNdf'%noB)[index], event.__getattr__('%sMinDaughtersNdf'%noB)[index]] self.DaughtersChi2 = [chi2red[i]*ndf[i] for i in xrange(len(ndf))] self.DaughtersNPoints = ndf self.DOCA = event.__getattr__('%sDOCA'%noB)[index] self.vtxz = event.__getattr__('%svtxz'%noB)[index] try: self.vtxy = event.__getattr__('%svtxy'%noB)[index] self.vtxx = event.__getattr__('%svtxx'%noB)[index] except: self.vtxy = r.TMath.Sqrt(event.__getattr__('%svtxySqr'%noB)[index]) self.vtxx = r.TMath.Sqrt(event.__getattr__('%svtxxSqr'%noB)[index]) self.IP0 = event.__getattr__('%sIP0'%noB)[index] self.BadTruthVtx = event.__getattr__('BadTruthVtx') self.NParticles = event.__getattr__('nRecoed') self.DaughtersAlwaysIn = event.__getattr__('DaughtersAlwaysIn')[index] self.Has1Muon1 = event.__getattr__('Has1Muon1')[index] self.Has2Muon1 = event.__getattr__('Has2Muon1')[index] self.Has1Muon2 = event.__getattr__('Has1Muon2')[index] self.Has2Muon2 = event.__getattr__('Has2Muon2')[index] self.HasEcal = event.__getattr__('HasEcal')[index] self.HNLw = event.__getattr__('weight') self.NuWeight = event.__getattr__('weight')*flux_nu/entries_nu self.numberOfHitLSSegments = event.__getattr__('numberOfHitLSSegments') self.strawVetoAny = event.__getattr__('strawVetoAny%s'%eff) self.upstreamVetoAny = event.__getattr__('upstreamVetoAny%s'%eff) self.RPCany = event.__getattr__('RPCany%s'%eff) class Cuts(object): def __init__(self, cutConfigList, study, byEvent=True): self.byEvent = byEvent self.cutList = [] try: for (index,cutConfig) in enumerate(cutConfigList): self.cutList.append( self.Cut( self, index, cutConfig['name'], study, cutConfig['params'] ) ) except BaseException,e: print "cutConfigList badly set: %r" %e def process(self, eventList, noB, eff=''): if self.byEvent: for event in eventList: for index in xrange(event.nRecoed): for cut in self.cutList: if not cut.count(MyParticle(event, index, noB, eff)): break else: for event in eventList: for cut in self.cutList: if not cut.count(event): break return self def select(self, event, imax): for i in xrange(imax): if not self.cutList[i].selection(event, self.cutList[i].study, self.cutList[i].params): return False return True class Cut(object): def __init__(self, cutCollection, index, cutName, study, params): self.cutCollection = cutCollection self.index = index self.name = cutName self.params = params self.study = study self.total = 0 self.weight = 0 self.eventNumbers = [] self.duplicates = [] self.selection = self.__get(cutName) def __get(self, cutName): name = "cut_"+cutName if hasattr(self,name): try: return getattr(self,name) except AttributeError,e: return None else: raise BaseException ( "bad cut name: %r" %cutName ) return None def count(self, event): try: if (self.selection(event,self.study,self.params)): self.total += 1 if (event.EventNumber not in self.eventNumbers): self.weight += self.compute_weight(event, self.study) self.eventNumbers.append(event.EventNumber) else: self.duplicates.append(event.EventNumber) return True else : return False except BaseException,e: print "Error performing %r: %r" %(self.name,e) def cut_fit_converged(self, event, study, params): return fit_converged(event) def cut_chi2(self, event, study, params): return chi2_cut(event,params['chi2max']) def cut_has_muons(self, event, study, params): for station in params['stations']: if not has_muon_station(event, study, station): return False return True def cut_doca(self, event, study, params): return doca_cut(event, params['docamax']) def cut_z(self, event, study, params): return z_cut(event, study) def cut_normalization(self, event, study, params): return goodTruthVtx(event, study) def cut_good_tracks(self, event, study, params): return goodTrack(event) def cut_ip(self, event, study, params): return ip_cut(event, params['ipmax']) def cut_vtx_in_ellipse(self, event, study, params): return vtxInAcceptance(event, study) def cut_vtxSq_in_ellipse(self, event, study, params): return vtxSqInAcceptance(event, study) def cut_n_candidates(self, event, study, params): #print self.cutCollection.cutList[self.index-1].name if (event.EventNumber in self.cutCollection.cutList[self.index-1].duplicates): #if self.cutCollection.select(event, self.index): return nParticles_cut(event, params['nmax']) return True def cut_has_ecal(self, event, study, params): return has_ecalDeposit(event) def cut_has_n_muons_in(self, event, study, params): return has_n_muons_in_station(event, params['n'], params['station']) def cut_not_vetoed(self, event, study, params): return was_not_vetoed(event, study) def compute_weight(self, event, study): return weight(event, study) def was_not_vetoed(event, study): if study in ['pimu', 'mumunu', 'tiny']: return True flag = (event.numberOfHitLSSegments == 0) and (event.strawVetoAny==0) and (event.upstreamVetoAny==0) and (event.RPCany==0) return flag def fit_converged(event): flags = event.DaughtersFitConverged if np.product(flags): return True return False def chi2_cut(event, chi2max): chi2 = event.DaughtersChi2 n = event.DaughtersNPoints for i in xrange(len(n)): if not n[i]: print event.EventNumber return False if chi2[i]/n[i] > chi2max: return False return True def has_muon_station(event, study, station): zIn = studies[study]['geo']['muondet%s_1'%(station-1)]['z']['pos'] - studies[study]['geo']['muondet%s_1'%(station-1)]['z']['dim'] zOut = studies[study]['geo']['muondet%s_1'%(station-1)]['z']['pos'] + studies[study]['geo']['muondet%s_1'%(station-1)]['z']['dim'] for z in event.muon_z: if zIn <= z <= zOut: return True return False def has_n_muons_in_station(event, n, station): if n>2: print "has_n_muons_in_station ERROR: we have maximum 2 tracks!!" sys.exit() if station>2: print "has_n_muons_in_station ERROR: we looked only at the first and second stations!!" sys.exit() if n==1 and station==1: return event.Has1Muon1 if n==2 and station==1: return event.Has2Muon1 if n==1 and station==2: return event.Has1Muon2 if n==2 and station==2: return event.Has2Muon2 def has_ecalDeposit(event): return event.HasEcal def doca_cut(event, doca_max): if event.DOCA < doca_max: return True return False def z_cut(event, study): z = event.vtxz #try: # minz = studies[study]['geo']['lidT1I_1']['z']['pos'] + studies[study]['geo']['lidT1I_1']['z']['dim'] + 500. # maxz = studies[study]['geo']['lidT6I_1']['z']['pos'] - studies[study]['geo']['lidT6I_1']['z']['dim'] #except: minz = studies[study]['geo']['Veto_5']['z']['pos'] + studies[study]['geo']['Veto_5']['z']['dim'] + 0.01 maxz = studies[study]['geo']['Tr1_1']['z']['pos'] - studies[study]['geo']['Tr1_1']['z']['dim'] - 0.01 if minz < z < maxz: return True return False def goodTruthVtx(event, study): if study in ['pimu', 'mumunu', 'tiny']: if not event.BadTruthVtx: return True return True def nParticles_cut(event, nmax): if event.NParticles > nmax: return False return True # This checks that: # - there is at least one tracking station before and one after the magnet # - hits in these tracking stations are within a 5x10m ellipse def goodTrack(event): if event.DaughtersAlwaysIn: return True return False def ip_cut(event, maxip): if event.IP0 < maxip: return True return False def nothing_in_veto5(event): if len(event.veto5_x) > 0: return False return True def nothing_in_liquidscint(event): if len(event.liquidscint_x) > 0: return False return True def something_in_muon(event): if len(event.muon_x) > 0: return True return False def something_in_ecal(event): if len(event.ecal_x) > 0: return True return False def vtxInAcceptance(event, study): x = event.vtxx y = event.vtxy #if 'cosmics' in study or 'bg' in study: # print study, x, y return tools.inEllipse(x,y,500./2,1000./2) def vtxSqInAcceptance(event, study): xSq = event.vtxxSqr ySq = event.vtxySqr #if 'cosmics' in study or 'bg' in study: # print study, x, y return tools.inEllipse(r.TMath.Sqrt(xSq), r.TMath.Sqrt(ySq), 500./2, 1000./2) def weight(event, study): #if event.EventNumber not in studies[study]['seen']: #studies[study]['seen'].append(event.EventNumber) if ('bg' in study) or (study == 'nu' or study == 'nubar'): w = event.NuWeight elif 'cosmics' in study: w = event.HNLw * 1.e6 / 200. elif study in ['pimu', 'mumunu', 'tiny']: w = event.HNLw / studies[study]['ntot'] else: print 'WEIGHTING ERROR: ', study sys.exit() #else: # w = 0. #if study in ['pimu', 'mumunu', 'tiny']: # print study, event.EventNumber, event.NParticles return w def computeResidualWeight(filename=None): if not filename: filename = "forElena_nu_notVetoed.txt" fScan = file(filename) lines = fScan.readlines() sample = nu s = 'nu' if ('bar' in filename) or ('anti' in filename): sample = nubar s = 'nubar' lines = lines[3:-1] events = [] for line in lines: events.append(int(line.rsplit("*")[1].replace(" ",""))) count_reco = 0 count = 0 weighted_count = 0. print "unvetoed: ", len(events) print "total Reconstructed: ", sample.GetEntriesFast() for event in sample: if event.EventNumber in events: count_reco +=1 if (fit_converged(event) and chi2_cut(event, 5.) and z_cut(event, s) and vtxInAcceptance(event, s) and goodTrack(event) and doca_cut(event, 30) and has_muon_station(event, s, 1) and has_muon_station(event, s, 2) and ip_cut(event, 250.)): #if True:#fit_converged(event): #and doca_cut(event, 50.) and ip_cut(event, 250.) and z_cut(event, 'nu') and vtxInAcceptance(event, 'nu'): #print event.EventNumber, 'mothers: ', event.DaughtersTruthMotherPDG[0], event.DaughtersTruthMotherPDG[1] print event.EventNumber print 'mothers: ', event.DaughtersTruthMotherPDG[0], event.DaughtersTruthMotherPDG[1] #print event.DOCA, event.IP0, event.DaughtersChi2[0]/event.DaughtersNPoints[0], event.DaughtersChi2[1]/event.DaughtersNPoints[1], event.DaughtersTruthPDG[0], event.DaughtersTruthPDG[1] print "tracks: ", event.DaughtersTruthPDG[0], event.DaughtersTruthPDG[1] print "vtx: ", event.vtxx, event.vtxy, event.vtxz print 'DOCA, IP: ', event.DOCA, event.IP0 #print tools.interactionElement(event.DaughtersTruthProdX[0], event.DaughtersTruthProdY[0], event.DaughtersTruthProdZ[0], nu_geo), tools.interactionElement(event.DaughtersTruthProdX[1], event.DaughtersTruthProdY[1], event.DaughtersTruthProdZ[1],nu_geo) count +=1 weighted_count += event.NuWeight print "Reconstructed: %s"%count_reco return count, weighted_count def latex_float(f): float_str = "{0:.3g}".format(f) if "e" in float_str: base, exponent = float_str.split("e") return "${0} \\times 10^{{{1}}}$".format(base, int(exponent)) else: return float_str class cutsWithDraw(object): def __init__(self): self.noB = '' self.opt = '' # '_eff' # 'Ethr' self.nu = False def setNoB(self, noB): # to ignore or take into account Katerina's modifications self.noB = noB def recoed(self): cut = " recoed==1 && Sum$(BadTruthVtx==0) " if self.nu: cut = " recoed==1 " string = "Event reconstructed" return cut, string def nRecoed(self, num): cut = " nRecoed==%s "%num if num == 1: strn = "1 HNL candidate" elif num>1: strn = "%s HNL candidates"%num string = strn return cut, string def doca(self, th, noB=None): if not noB: noB = self.noB cut = " Sum$(%sDOCA < %s) "%(noB, th) if th == int(round(th)): th = int(round(th)) string = "DOCA $<$ %s~cm"%th return cut, string def ip(self, th, noB=None): if not noB: noB = self.noB cut = " Sum$(%sIP0 < %s) "%(noB, th) string = "IP $<$ %.1f m"%(th/100.) return cut, string def z(self, zmin, zmax, noB=None): if not noB: noB = self.noB cut = " Sum$(%svtxz > %s && %svtxz < %s) "%(noB, zmin, noB, zmax) string = "$z_{straw\, veto} < z_{vtx} < z_{trk1}$" return cut, string def ellipse(self, a, b, noB=None): if not noB: noB = self.noB cut = " Sum$(( (%svtxx*%svtxx)/(%s*%s) + (%svtxy*%svtxy)/(%s*%s) ) < 1.) "%(noB,noB, a,a, noB,noB, b,b) string = "Vertex $\\in $ ellipse" return cut, string def fiducial(self, zmin, zmax, a, b, noB=None): cutz = self.z(zmin, zmax, noB)[0] cute = self.ellipseSq(a, b, noB)[0] string = "Vtx in fiducial vol." cut = cutz+"&&"+cute return cut, string def ellipseSq(self, a, b, noB=None): if not noB: noB = self.noB cut = " Sum$(( (%svtxxSqr)/(%s*%s) + (%svtxySqr)/(%s*%s) ) < 1.) "%(noB, a,a, noB, b,b) string = "Vertex $\\in $ ellipse" return cut, string def converged(self): cut = " Sum$(DaughtersFitConverged==1) " string = "Track fit converged" return cut, string def goodtracks(self): cut = " Sum$(DaughtersAlwaysIn==1) " string = "Tracks $\\in$ ellipse" return cut, string def redChi2(self, th, noB=None): if not noB: noB = self.noB cut = " Sum$(%sMaxDaughtersRedChi2<%s) "%(noB, th) if th == int(round(th)): th = int(round(th)) string = "$\\chi^2/\\text{N.d.f.} < %s $"%th return cut, string def ndf(self, th, noB=None): if not noB: noB = self.noB cut = " Sum$(%sMinDaughtersNdf>%s) "%(noB, th) string = "$\\text{N.d.f.} > %s$"%th return cut, string def muon1(self, num): cut = " Sum$(Has%sMuon1==1) "%num if num==1: strn = "1 muon" elif num==2: strn = "2 muons" string = strn+" in 1$^{\\text{st}}$ muon station" return cut, string def muon2(self, num): cut = " Sum$(Has%sMuon2==1) "%num if num==1: strn = "1 muon" elif num==2: strn = "2 muons" string = strn+" in 2$^{\\text{nd}}$ muon station" return cut, string def ecal(self): cut = " Sum$(HasEcal==1) " string = "150~MeV in Ecal" return cut, string def notVetoed(self, th, noB=None, opt=None): if not noB: noB = self.noB if not opt: opt = self.opt cut = " Sum$(%sIP0 < %s) &&"%(noB, th)+" Sum$(numberOfHitLSSegments == 0) && Sum$(strawVetoAny%s==0) && Sum$(upstreamVetoAny%s==0) && Sum$(RPCany%s==0) "%(opt, opt, opt) string = "Event not vetoed" return cut, string def countWithDraw(study): t = studies[study]['data'] geo = studies[study]['geo'] ntot = studies[study]['ntot'] tc = cutsWithDraw() if study == 'nu': tc.setNoB('NoB_') tc.nu = True zmin = geo['Veto_5']['z']['pos']+geo['Veto_5']['z']['dim'] zmax = geo['Tr1_1']['z']['pos']-geo['Tr1_1']['z']['dim'] if (study == 'pimu'): cuts = [ tc.recoed()[0], tc.notVetoed(1000.)[0], tc.redChi2(5.)[0], tc.ndf(25)[0], tc.z(zmin, zmax)[0], tc.ellipseSq(250., 500.)[0], tc.goodtracks()[0], tc.ecal()[0], tc.muon1(1)[0], tc.muon2(1)[0], tc.doca(30.)[0], tc.ip(250.)[0] ] cutnames = [ tc.recoed()[1], tc.notVetoed(1000.)[1], tc.redChi2(5.)[1], tc.ndf(25)[1], tc.z(zmin, zmax)[1], tc.ellipseSq(250., 500.)[1], tc.goodtracks()[1], tc.ecal()[1], tc.muon1(1)[1], tc.muon2(1)[1], tc.doca(30.)[1], tc.ip(250.)[1] ] elif (study == 'nu'): cuts = [ tc.recoed()[0], tc.notVetoed(1000.)[0], tc.redChi2(5.)[0], tc.ndf(25)[0], tc.z(zmin, zmax)[0], tc.ellipseSq(250., 500.)[0], tc.goodtracks()[0], tc.ecal()[0], tc.muon1(1)[0], tc.muon2(1)[0], tc.doca(30.)[0], tc.ip(250.)[0] ] cutnames = [ tc.recoed()[1], tc.notVetoed(1000.)[1], tc.redChi2(5.)[1], tc.ndf(25)[1], tc.z(zmin, zmax)[1], tc.ellipseSq(250., 500.)[1], tc.goodtracks()[1], tc.ecal()[1], tc.muon1(1)[1], tc.muon2(1)[1], tc.doca(30.)[1], tc.ip(250.)[1] ] elif (study == 'mumunu'): cuts = [ tc.recoed()[0], tc.notVetoed(1000.)[0], tc.redChi2(5.)[0], tc.ndf(25)[0], tc.z(zmin, zmax)[0], tc.ellipseSq(250., 500.)[0], tc.goodtracks()[0], tc.muon1(2)[0], tc.muon2(2)[0], tc.doca(30.)[0], tc.ip(250.)[0] ] cutnames = [ tc.recoed()[1], tc.notVetoed(1000.)[1], tc.redChi2(5.)[1], tc.ndf(25)[1], tc.z(zmin, zmax)[1], tc.ellipseSq(250., 500.)[1], tc.goodtracks()[1], tc.muon1(2)[1], tc.muon2(2)[1], tc.doca(30.)[1], tc.ip(250.)[1] ] elif (study == 'tiny'): cuts = [ tc.recoed()[0], tc.notVetoed(1000.)[0], tc.redChi2(5.)[0], tc.ndf(25)[0], tc.z(zmin, zmax)[0], tc.ellipseSq(250., 500.)[0], tc.goodtracks()[0], tc.ecal()[0], tc.doca(30.)[0], tc.ip(250.)[0] ] cutnames = [ tc.recoed()[1], tc.notVetoed(1000.)[1], tc.redChi2(5.)[1], tc.ndf(25)[1], tc.z(zmin, zmax)[1], tc.ellipseSq(250., 500.)[1], tc.goodtracks()[1], tc.ecal()[1], tc.doca(30.)[1], tc.ip(250.)[1] ] # if not cutnames: # cutnames = [ "converged", "not vetoed", "chi2/n<5", "ndf>15", "z", "ellipse", "good tracks", "ecal", "muon1", "muon2", "doca<30", "IP<250" ] # cutStrings = [ "Track fit converged", # "Event not vetoed", # "$\\xi^2/ndf < 5 $", # "$ndf > 15$", # "$z_{straw veto} < z_{vtx} < z_{Trk1}$", # "Vertex $\\in $ ellipse", # "Tracks $\\in$ ellipse", # "150~MeV in Ecal", # "1$^{\\text{st}}$ muon station", # "2$^{\\text{nd}}$ muon station", # "DOCA $<$ 30~cm", # "IP $<$ 2.5~m", # ] entries = [] weights = [] print r.gROOT.SetBatch(r.kTRUE) for i,cut in enumerate(cuts): n = t.Draw("event", "&&".join([c for c in cuts[:i+1]])) #if study == 'nu': # t.Draw("1.>>hw","(weight*%s/%s)*("%(flux_nu, entries_nu) + str("&&".join([c for c in cuts[:i+1]])) + ")") #elif study == 'nubar': # t.Draw("1.>>hw","(weight*%s/%s)*("%(flux_anti, entries_anti) + str("&&".join([c for c in cuts[:i+1]])) + ")") #else: # t.Draw("1.>>hw","(weight/%s)*("%studies[study]['ntot'] + str("&&".join([c for c in cuts[:i+1]])) + ")") if study == 'nu': t.Draw("1.>>hw","(weight*%s/%s)*("%(flux_nu, entries_nu) + str("&&".join([c for c in cuts[:i+1]])) + ")") elif study == 'nubar': t.Draw("1.>>hw","(weight*%s/%s)*("%(flux_anti, entries_anti) + str("&&".join([c for c in cuts[:i+1]])) + ")") else: t.Draw("1.>>hw","(weight/%s)*("%ntot + str("&&".join([c for c in cuts[:i+1]])) + ")") w = t.GetHistogram().GetSumOfWeights()#Integral()#Integral('width')#GetSum() #w = r.gDirectory.Get('hw').Integral() entries.append(n) weights.append(w) print cutnames[i], '\t\t\t', n, '\t', w, cuts[i] print r.gROOT.SetBatch(r.kFALSE) return entries, weights, cutnames def tableWithDraw(): results = {} for study in ['nu', 'pimu', 'mumunu', 'tiny']: results[study] = {} numbers, numbersWithWeights, cuts = countWithDraw(study) results[study]['numbers'] = numbers results[study]['numbersWithWeights'] = numbersWithWeights results[study]['cuts'] = cuts return results def plotSigBg(cSaver, name, sig_tree, sig_ntot, bg_tree, what, cuts, xaxis, legSize, log, sig_cuts=None, bg_cuts=None): if not sig_cuts: sig_cuts = cuts if not bg_cuts: bg_cuts = cuts.replace("&& Sum$(BadTruthVtx==0) ", "") # colors bgcolor = r.kRed sigcolor = r.kBlack sigfill = r.kGray bgstyle = 1#9 r.gStyle.SetOptTitle(r.kFALSE) # draw normalized c1 = r.TCanvas(name, name) whatbg = what if what in ["DOCA", "vtxz"]: whatbg = "NoB_"+what sig_tree.Draw(what+'>>h_sig_%s'%name, "(weight/%s)*("%sig_ntot + sig_cuts + ")", 'norm') hsig = r.gDirectory.Get('h_sig_%s'%name) hsig.SetMarkerColor(sigcolor) hsig.SetLineColor(sigcolor) hsig.SetFillColor(sigfill) hsig.GetXaxis().SetTitle(xaxis) hsig.GetYaxis().SetTitle("a. u.") hsig.GetYaxis().SetDecimals() if ("mumunu-mass" in name) or ("mumunu-IP0" in name) or ("tiny-mass" in name) or ("tiny-IP0" in name): hsig.GetYaxis().SetRangeUser(0.0001,5.) bg_tree.Draw(whatbg+'>>h_bg_%s'%name, "(weight*%s/%s)*("%(flux_nu, entries_nu) + bg_cuts + ")", 'norm same') hbg = r.gDirectory.Get('h_bg_%s'%name) hbg.SetMarkerColor(bgcolor) hbg.SetLineColor(bgcolor) hbg.SetLineStyle(bgstyle) if "y" in log: c1.SetLogy() if "x" in log: c1.SetLogx() newLegSize = list(legSize) if ("tiny" in name) and not ("2" in name): newLegSize[2] += 0.02 newLegSize[3] += 0.02 leg = r.TLegend(*newLegSize) leg.SetTextFont(42) leg.SetLineColor(r.kWhite) leg.SetBorderSize(0) sigstring = "HNL #rightarrow #pi#mu" if ('eenu' in name) or ('tiny' in name): sigstring = sigstring.replace("#pi#mu", "ee#nu") if ('mumu' in name): sigstring = sigstring.replace("#pi#mu", "#mu#mu#nu") leg.AddEntry(hsig, sigstring, 'lf' ) leg.AddEntry(hbg, "Neutrino BG", 'l' ) leg.Draw("same") c1.Modified(); c1.Update() print "\n", name, hsig.GetMean(), hsig.GetRMS() cSaver[name] = (c1, leg, hsig, hbg) return c1, leg, hsig, hbg cSaver = [] def accPlotsTP(study): if not os.path.exists('accPlotsTP'): os.system('mkdir accPlotsTP') r.gROOT.ProcessLine(".x newGen/mystyle.C") t = studies[study]['data'] geo = studies[study]['geo'] ntot = studies[study]['ntot'] tc = cutsWithDraw() zmin = geo['Veto_5']['z']['pos']+geo['Veto_5']['z']['dim'] zmax = geo['Tr1_1']['z']['pos']-geo['Tr1_1']['z']['dim'] # BG stuff bg_t = studies['nu']['data'] bg_geo = studies['nu']['geo'] bg_ntot = studies['nu']['ntot'] bg_tc = cutsWithDraw() bg_tc.setNoB('NoB_') bg_zmin = geo['Veto_5']['z']['pos']+geo['Veto_5']['z']['dim'] bg_zmax = geo['Tr1_1']['z']['pos']-geo['Tr1_1']['z']['dim'] plot_ip = plotSigBg(study+"-IP0", t, ntot, bg_t, "IP0", tc.notVetoed(1000.)[0], "Impact parameter to target [cm]")[0] cSaver.append(plot_ip) raw_input('') # per particle cutConfigList = [ {'name': 'normalization', 'params':{}}, {'name': 'fit_converged', 'params':{}}, {'name': 'chi2', 'params':{'chi2max':5.}}, {'name': 'z', 'params':{}}, {'name': 'vtx_in_ellipse','params':{}}, {'name': 'good_tracks', 'params':{}}, {'name': 'doca', 'params':{'docamax':50.}}, {'name': 'ip', 'params':{'ipmax':500.}}, {'name': 'has_muons', 'params':{'stations':[1,2]}}, {'name': 'doca', 'params':{'docamax':30.}}, {'name': 'ip', 'params':{'ipmax':250.}}, {'name': 'n_candidates', 'params':{'nmax':1}}, ] # new analysis sw - per event cutConfigList = [ {'name': 'normalization', 'params':{}}, {'name': 'fit_converged', 'params':{}}, {'name': 'chi2', 'params':{'chi2max':5.}}, {'name': 'z', 'params':{}}, {'name': 'vtx_in_ellipse', 'params':{}}, {'name': 'good_tracks', 'params':{}}, {'name': 'doca', 'params':{'docamax':50.}}, {'name': 'ip', 'params':{'ipmax':500.}}, {'name': 'has_n_muons_in', 'params':{'n':1,'station':1}}, {'name': 'has_n_muons_in', 'params':{'n':1,'station':2}}, {'name': 'has_ecal', 'params':{}}, {'name': 'doca', 'params':{'docamax':30.}}, {'name': 'ip', 'params':{'ipmax':250.}}, ] cutConfigDict = { 'sig': [{'name': 'normalization', 'params':{}}, {'name': 'fit_converged', 'params':{}}, {'name': 'chi2', 'params':{'chi2max':5.}}, {'name': 'z', 'params':{}}, {'name': 'vtx_in_ellipse', 'params':{}}, {'name': 'good_tracks', 'params':{}}, {'name': 'doca', 'params':{'docamax':50.}}, {'name': 'ip', 'params':{'ipmax':500.}}, {'name': 'has_n_muons_in', 'params':{'n':1,'station':1}}, {'name': 'has_n_muons_in', 'params':{'n':1,'station':2}}, {'name': 'has_ecal', 'params':{}}, {'name': 'doca', 'params':{'docamax':30.}}, {'name': 'ip', 'params':{'ipmax':250.}}], 'bg': [{'name': 'not_vetoed', 'params':{}}, {'name': 'fit_converged', 'params':{}}, {'name': 'chi2', 'params':{'chi2max':5.}}, {'name': 'z', 'params':{}}, {'name': 'vtx_in_ellipse', 'params':{}}, {'name': 'good_tracks', 'params':{}}, {'name': 'doca', 'params':{'docamax':50.}}, {'name': 'ip', 'params':{'ipmax':500.}}, {'name': 'has_n_muons_in', 'params':{'n':1,'station':1}}, {'name': 'has_n_muons_in', 'params':{'n':1,'station':2}}, {'name': 'has_ecal', 'params':{}}, {'name': 'doca', 'params':{'docamax':30.}}, {'name': 'ip', 'params':{'ipmax':250.}}] } def numbers_v2(): mycuts, results = {}, {} for study in studies: print 'Reading %s...'%study if study in ['tiny', 'pimu', 'mumunu']: cutConfigList = cutConfigDict['sig'] noB = '' else: cutConfigList = cutConfigDict['bg'] noB = 'NoB_' mycuts[study] = Cuts(cutConfigList, study).process(studies[study]['data'], noB) for cut in mycuts[study].cutList: assert( len(cut.eventNumbers) == len(list(set(cut.eventNumbers))) ) print '%s\t%s\t%s\t%s'%(cut.name, cut.total, len(cut.eventNumbers), cut.weight) results[study] = {} results[study]['numbers']=[ cut.total for cut in mycuts[study].cutList[1:] ] results[study]['numbersWithWeights']=[ cut.weight for cut in mycuts[study].cutList[1:] ] print #print 'Events with more than one particle:' #for entry in mycuts[study].cutList[-2].duplicates: #[ x for x in mycuts[study].cutList[-1].eventNumbers if mycuts[study].cutList[-1].eventNumbers.count(x) > 1 ]: # for tr in studies[study]['data']: # if tr.EventNumber == entry: # if mycuts[study].select(tr, len(mycuts[study].cutList)-1): # print tr.EventNumber, tr.vtxz, tr.IP0, [pdg.GetParticle(code).GetName() for code in tr.DaughtersTruthPDG] #print print return results header = { 'pimu': "$HNL \\to \\pi \\mu$", 'mumunu': "$HNL \\to \\mu \\mu \\nu$", 'tiny': "$HNL \\to e e \\nu$", 'nu': "neutrino-induced background" } def makeTex(results): for study in results.keys(): weighted_string = "Acceptance" if study == 'nu': weighted_string = "Events / 5 years" results[study]['efficiencies'] = [ results[study]['numbersWithWeights'][i]/results[study]['numbersWithWeights'][i-1] for i in xrange(1, len(results[study]['numbersWithWeights']))] results[study]['effStrings'] = ['-'] + [ "{:.1f} \\%".format(float(e) * 100) for e in results[study]['efficiencies'] ] #for s in results[study]['effStrings']: # print s print '\n\n\n' print '\t\\begin{table}' print '\t\t\\centering Cut flow for %s:'%header[study] print '\t\t\\begin{tabular}{|l|c|c|c|}' print '\t\t\t\\hline' print '\t\t\t\\textbf{Selection} & \\textbf{Entries} & \\textbf{%s} & \\textbf{Selection efficiency} \\\\'%weighted_string print '\t\t\t\\hline' assert(len(results[study]['cuts']) == len(results[study]['numbers']) == len(results[study]['numbersWithWeights'])) for i in xrange(len(results[study]['cuts'])): print '\t\t\t', results[study]['cuts'][i], ' & ', '%s'%int(results[study]['numbers'][i]), ' & ', '%s'%latex_float(results[study]['numbersWithWeights'][i]), ' & ', results[study]['effStrings'][i], '\\\\' print '\t\t\t\\hline' print '\t\t\\end{tabular}' print '\t\\end{table}' print '\n\n' def makeTexOld(results, cuts=None): print print 'Background:' print '\t\\begin{table}' print '\t\\centering Backgrounds: \\tiny' print '\t\t\\begin{tabular}{|l|c|c|c|c|c|c|}' print '\t\t\t\\hline' print '\t\t\tCut & Weighted $\\nu$ & $\\nu$ entries & Weighted $\\bar{\\nu}$ & $\\bar{\\nu}$ entries & Weighted cosmics & cosmics entries \\\\' print '\t\t\t\\hline' if not cuts: cuts = ['Track fit converged', '$\chi^2/n < 5$', '$z_{in}+5~\\text{m} < z_{vtx} < z_{out}$', '$z_{vtx} \in $ ellipse', 'Tracks $\in$ ellipse', 'DOCA $<$ 50 cm', 'IP $<$ 5 m', 'Muon1 \& Muon2', 'DOCA $<$ 30 cm', 'IP $<$ 2.5 m', '$N_{candidates} = 1$'] for i in xrange(len(results['nu']['numbers'])): print '\t\t\t', cuts[i], ' & ', '%s'%latex_float(results['nu']['numbersWithWeights'][i]), ' & ', '%s'%results['nu']['numbers'][i], ' & ',\ '%s'%latex_float(results['nubar']['numbersWithWeights'][i]), ' & ', '%s'%results['nubar']['numbers'][i], ' & ',\ '%s'%latex_float(results['cosmics']['numbersWithWeights'][i]), ' & ', '%s'%results['cosmics']['numbers'][i], '\\\\ ' print '\t\t\t\\hline' print '\t\t\\end{tabular}' print '\t\\end{table}' print print 'Signal:' print '\t\\begin{table}' print '\t\\centering Signal: \\tiny' print '\t\t\\begin{tabular}{|l|c|c|c|c|c|c|}' print '\t\t\t\\hline' print '\t\t\tCut & $\\mathcal{A}(\\pi\\mu)$ & $\\pi\\mu$ entries & $\\mathcal{A}(\\mu\\mu\\nu)$ & $\\mu\\mu\\nu$ entries & $\\mathcal{A}(ee\\nu)$ & $ee\\nu$ entries \\\\' print '\t\t\t\\hline' #cuts = ['Track fit converged', '$\chi^2/n < 5$', '$z_{in}+5~\\text{m} < z_{vtx} < z_{out}$', '$z_{vtx} \in $ ellipse', 'Tracks $\in$ ellipse', 'DOCA $<$ 50 cm', # 'IP $<$ 5 m', 'Muon1 \& Muon2', 'DOCA $<$ 30 cm', 'IP $<$ 2.5 m', '$N_{candidates} = 1$'] for i in xrange(len(results['nu']['numbers'])): print '\t\t\t', cuts[i], ' & ', '%s'%latex_float(results['pimu']['numbersWithWeights'][i]), ' & ', '%s'%results['pimu']['numbers'][i], ' & ',\ '%s'%latex_float(results['mumunu']['numbersWithWeights'][i]), ' & ', '%s'%results['mumunu']['numbers'][i], ' & ',\ '%s'%latex_float(results['tiny']['numbersWithWeights'][i]), ' & ', '%s'%results['tiny']['numbers'][i], '\\\\ ' print '\t\t\t\\hline' print '\t\t\\end{tabular}' print '\t\\end{table}' print def numbers_for_TP(): results = {} for s in ['pimu', 'mumunu', 'tiny', 'nu', 'nubar', 'cosmics']:#studies: print 'Reading %s...'%s t = studies[s]['data'] ntot = t.GetEntriesFast() nAfterCuts = [0]*10 nAfterCuts_weighted = [0.]*10 initialEventNums = [] eventNums = [] for event in t: w = weight(event,s) # e' importante fare questa cosa a monte, x come e' definita la funzione! if fit_converged(event) and goodTruthVtx(event,s): nAfterCuts[0] +=1 nAfterCuts_weighted[0] += w initialEventNums.append(int(event.EventNumber)) if chi2_cut(event, 5.): nAfterCuts[1]+=1 nAfterCuts_weighted[1]+=w if z_cut(event, s):#chi2_cut(event, 5): nAfterCuts[1+1] += 1 nAfterCuts_weighted[1+1] += w if vtxInAcceptance(event, s):#goodTrack(event): nAfterCuts[2+1] +=1 nAfterCuts_weighted[2+1] +=w #if 'cosmics' in s: # print 'mothers: ', event.DaughtersTruthMotherPDG[0], event.DaughtersTruthMotherPDG[1] # print "tracks: ", event.DaughtersTruthPDG[0], event.DaughtersTruthPDG[1] # print "p candidate: ", event.P, "\t IP: ", event.IP0 # print "pt candidate: ", event.Pt if goodTrack(event):#doca_cut(event, 50): nAfterCuts[3+1] +=1 nAfterCuts_weighted[3+1] +=w if doca_cut(event, 50):#vtxInAcceptance(event, s): nAfterCuts[4+1]+=1 nAfterCuts_weighted[4+1]+=w if has_muon_station(event, s, 1) and has_muon_station(event, s, 2):#ip_cut(event,500):#something_in_muon(event): nAfterCuts[5+1] +=1 nAfterCuts_weighted[5+1] +=w if doca_cut(event, 30.):#something_in_ecal(event): nAfterCuts[6+1] +=1 nAfterCuts_weighted[6+1] +=w if ip_cut(event, 500.): nAfterCuts[7+1] +=1 nAfterCuts_weighted[7+1] +=w if ip_cut(event, 250.): nAfterCuts[8+1] +=1 nAfterCuts_weighted[8+1] +=w eventNums.append(int(event.EventNumber)) studies[s]['seen'].append(event.EventNumber) print '%s \t survived particles: '%s, nAfterCuts, ' of %s total'%ntot print '%s \t weighted survived particles: '%s, nAfterCuts_weighted, ' of %s total'%ntot results[s] = {} results[s]['ntot']=studies[s]['ntot'] results[s]['numbers']=nAfterCuts results[s]['numbersWithWeights']=nAfterCuts_weighted results[s]['listOfSurvivors']=list(set(eventNums)) studies[s]['listOfSurvivors']=list(set(eventNums)) results[s]['listOfRecoed']=list(set(initialEventNums)) studies[s]['listOfRecoed']=list(set(initialEventNums)) print for s in ['pimu', 'mumunu', 'tiny']:#studies.keys():#['pimu', 'mumunu', 'bg']: for lst in results[s]: if not ('Survivors' in lst) and not ('Recoed' in lst): print s,list,results[s][lst] print print 'Events with surviving nu: %s \t with nubar: %s'%(len(results['nu']['listOfSurvivors']), len(results['nubar']['listOfSurvivors'])) print print 'Background:' print '\t\\begin{table}' print '\t\\centering Backgrounds: \\tiny' print '\t\t\\begin{tabular}{|l|c|c|c|c|c|c|}' print '\t\t\t\\hline' print '\t\t\tCut & Weighted $\\nu$ & $\\nu$ entries & Weighted $\\bar{\\nu}$ & $\\bar{\\nu}$ entries & Weighted cosmics & cosmics entries \\\\' print '\t\t\t\\hline' cuts = ['Track fit converged', '$\chi^2/n < 5$', '$z_{in}+5~\\text{m} < z_{vtx} < z_{out}$', '$z_{vtx} \in $ ellipse', 'Tracks $\in$ ellipse', 'DOCA $<$ 50 cm', 'Muon1 \& Muon2', 'DOCA $<$ 30 cm', 'IP $<$ 5 m', 'IP $<$ 2.5 m'] for i in xrange(len(results['nu']['numbers'])): print '\t\t\t', cuts[i], ' & ', '%s'%latex_float(results['nu']['numbersWithWeights'][i]), ' & ', '%s'%results['nu']['numbers'][i], ' & ',\ '%s'%latex_float(results['nubar']['numbersWithWeights'][i]), ' & ', '%s'%results['nubar']['numbers'][i], ' & ',\ '%s'%latex_float(results['cosmics']['numbersWithWeights'][i]), ' & ', '%s'%results['cosmics']['numbers'][i], '\\\\ ' print '\t\t\t\\hline' print '\t\t\\end{tabular}' print '\t\\end{table}' print 'Signal:' print '\t\\begin{table}' print '\t\\centering Signal: \\tiny' print '\t\t\\begin{tabular}{|l|c|c|c|c|c|c|}' print '\t\t\t\\hline' print '\t\t\tCut & $\\mathcal{A}(\\pi\\mu)$ & $\\pi\\mu$ entries & $\\mathcal{A}(\\mu\\mu\\nu)$ & $\\mu\\mu\\nu$ entries & $\\mathcal{A}(ee\\nu)$ & $ee\\nu$ entries \\\\' print '\t\t\t\\hline' cuts = ['Track fit converged', '$\chi^2/n < 5$', '$z_{in}+5~\\text{m} < z_{vtx} < z_{out}$', '$z_{vtx} \in $ ellipse', 'Tracks $\in$ ellipse', 'DOCA $<$ 50 cm', 'Muon1 \& Muon2', 'DOCA $<$ 30 cm', 'IP $<$ 5 m', 'IP $<$ 2.5 m'] for i in xrange(len(results['nu']['numbers'])): print '\t\t\t', cuts[i], ' & ', '%s'%latex_float(results['pimu']['numbersWithWeights'][i]), ' & ', '%s'%results['pimu']['numbers'][i], ' & ',\ '%s'%latex_float(results['mumunu']['numbersWithWeights'][i]), ' & ', '%s'%results['mumunu']['numbers'][i], ' & ',\ '%s'%latex_float(results['tiny']['numbersWithWeights'][i]), ' & ', '%s'%results['tiny']['numbers'][i], '\\\\ ' print '\t\t\t\\hline' print '\t\t\\end{tabular}' print '\t\\end{table}' print out = {'pimu':[], 'mumunu':[], 'tiny':[]} for s in ['pimu', 'mumunu', 'tiny']: for event in studies[s]['data']: if event.EventNumber in studies[s]['listOfSurvivors']: if event.NParticles > 1: out[s].append(event.EventNumber) #print s, event.EventNumber, event.NParticles, r.gGeoManager.FindNode(event.vtxx, event.vtxy, event.vtxz).GetName() print s, list(set(out[s])) def badEvents(): numbers_for_TP() hnpnu_recoed = r.TH1F('np nu recoed', 'np nu recoed', 60, 0, 59) hnpnu_survivors = r.TH1F('np nu survived', 'np nu survived', 60, 0, 59) seen = [] for part in studies['nu']['data']: if not (part.EventNumber in seen): if part.EventNumber in studies['nu']['listOfSurvivors']: hnpnu_survivors.Fill(part.NParticles) if part.EventNumber in studies['nu']['listOfRecoed']: hnpnu_recoed.Fill(part.NParticles) seen.append(part.EventNumber) #c1 = r.TCanvas(); c1.cd() #hnpnu.Draw() #c1.Print('badEvents_nu_nparticles.png') hnpnubar_recoed = r.TH1F('np nubar recoed', 'np nubar recoed', 60, 0, 59) hnpnubar_survivors = r.TH1F('np nubar survived', 'np nubar survived', 60, 0, 59) seen = [] for part in studies['nubar']['data']: if not (part.EventNumber in seen): if part.EventNumber in studies['nubar']['listOfSurvivors']: hnpnubar_survivors.Fill(part.NParticles) if part.EventNumber in studies['nubar']['listOfRecoed']: hnpnubar_recoed.Fill(part.NParticles) seen.append(part.EventNumber) #c1 = r.TCanvas(); c1.cd() #hnpnubar.Draw() #c1.Print('badEvents_nubar_nparticles.png') hnpnu_recoed.SetLineColor(r.kBlack); hnpnu_recoed.SetMarkerColor(r.kBlack) hnpnu_survivors.SetLineColor(r.kMagenta); hnpnu_survivors.SetMarkerColor(r.kMagenta) c1 = r.TCanvas(); c1.cd() hnpnu_recoed.DrawNormalized('p'); hnpnu_survivors.DrawNormalized('p same') c1.Print('nuAndNubar/nu_recoed_and_survived.png') c1.Print('nuAndNubar/nu_recoed_and_survived.pdf') c1.Close() hnpnubar_recoed.SetLineColor(r.kBlack); hnpnubar_recoed.SetMarkerColor(r.kBlack) hnpnubar_survivors.SetLineColor(r.kMagenta); hnpnubar_survivors.SetMarkerColor(r.kMagenta) c1 = r.TCanvas(); c1.cd() hnpnubar_recoed.DrawNormalized('p'); hnpnubar_survivors.DrawNormalized('p same') c1.Print('nuAndNubar/nubar_recoed_and_survived.png') c1.Print('nuAndNubar/nubar_recoed_and_survived.pdf') c1.Close() hnpnu_recoed.SetLineColor(r.kBlue); hnpnu_recoed.SetMarkerColor(r.kBlue) hnpnubar_recoed.SetLineColor(r.kGreen); hnpnubar_recoed.SetMarkerColor(r.kGreen) c1 = r.TCanvas(); c1.cd() hnpnu_recoed.DrawNormalized('p'); hnpnubar_recoed.DrawNormalized('p same') c1.Print('nuAndNubar/nu_and_nubar_recoed.png') c1.Print('nuAndNubar/nu_and_nubar_recoed.pdf') c1.Close() hnpnu_survivors.SetLineColor(r.kBlue); hnpnu_survivors.SetMarkerColor(r.kBlue) hnpnubar_survivors.SetLineColor(r.kGreen); hnpnubar_survivors.SetMarkerColor(r.kGreen) c1 = r.TCanvas(); c1.cd() hnpnu_survivors.DrawNormalized('p'); hnpnubar_survivors.DrawNormalized('p same') c1.Print('nuAndNubar/nu_and_nubar_survived.png') c1.Print('nuAndNubar/nu_and_nubar_survived.pdf') c1.Close() def do_my_studies(): results = {} for s in studies: print 'Reading %s...'%s t = studies[s]['data'] ntot = t.GetEntriesFast() nAfterCuts = [0]*10 nAfterCuts_weighted = [0.]*10 for event in t: w = weight(event,s) if fit_converged(event): nAfterCuts[0] += 1 nAfterCuts_weighted[0] += w if chi2_cut(event,25): nAfterCuts[1] +=1 nAfterCuts_weighted[1] +=w #if chi2_cut(event,15): if chi2_cut(event,5): nAfterCuts[2]+=1 nAfterCuts_weighted[2]+=w if doca_cut(event, 50.): nAfterCuts[2+1] += 1 nAfterCuts_weighted[2+1] += w if doca_cut(event, 30.): nAfterCuts[3+1]+=1 nAfterCuts_weighted[3+1]+=w if z_cut(event, s): nAfterCuts[4+1] += 1 nAfterCuts_weighted[4+1] += w if ip_cut(event,500.): nAfterCuts[5+1]+=1 nAfterCuts_weighted[5+1]+=w if ip_cut(event,250.): nAfterCuts[6+1]+=1 nAfterCuts_weighted[6+1]+=w if nothing_in_veto5(event): nAfterCuts[7+1] += 1 nAfterCuts_weighted[7+1] += w if nothing_in_liquidscint(event): nAfterCuts[8+1] += 1 nAfterCuts_weighted[8+1] += w print '%s \t survived particles: '%s, nAfterCuts, ' of %s total'%ntot print '%s \t weighted survived particles: '%s, nAfterCuts_weighted, ' of %s total'%ntot results[s] = {} results[s]['ntot']=studies[s]['ntot'] results[s]['numbers']=nAfterCuts results[s]['numbersWithWeights']=nAfterCuts_weighted addPlot(s+'-0cuts-IP', 'Impact parameter to target [cm]', t, 'IP0') addPlot(s+'-0cuts-Mass', 'Reco inv. mass', t, 'Mass' ) addPlot(s+'-0cuts-dPt', 'Tracks Pt', t, 'DaughtersPt' ) addPlot(s+'-0cuts-P','Reconstructed Momentum', t, 'P') addPlot(s+'-0cuts-Pt', 'Reconstructed Pt', t, 'Pt') addPlot(s+'-0cuts-PtOverP', 'Reconstructed Pt/P', t, 'Pt/P') addPlot(s+'-0cuts-dMinP', 'Min Tracks P', t, 'DaughterMinP' ) addPlot(s+'-0cuts-dMinPt', 'Min Tracks Pt', t, 'DaughterMinPt' ) addPlot(s+'-0cuts-VtxZ', 'Reco vertex z position [cm]', t, 'vtxz' ) addPlot(s+'-0cuts-DOCA', 'Daughter tracks DOCA [cm]', t, 'DOCA' ) addPlot(s+'-0cuts-dChi2', 'Daughter tracks #chi^{2}/n', t, 'DaughtersChi2/DaughtersNPoints' ) #cut = "DaughtersChi2<25*DaughtersNPoints" cut = "DaughtersChi2<5*DaughtersNPoints" addPlot(s+'-chi2cut-IP', 'Impact parameter to target [cm]', t, 'IP0', cut) addPlot(s+'-chi2cut-Mass', 'Reco inv. mass', t, 'Mass' , cut) addPlot(s+'-chi2cut-dPt', 'Tracks Pt', t, 'DaughtersPt' , cut) addPlot(s+'-chi2cut-P', 'Reconstructed Momentum', t, 'P', cut) addPlot(s+'-chi2cut-Pt','Reconstructed Pt', t, 'Pt', cut) addPlot(s+'-chi2cut-PtOverP', 'Reconstructed Pt/P', t, 'Pt/P', cut) addPlot(s+'-chi2cut-dMinP', 'Min Tracks P', t, 'DaughterMinP' , cut ) addPlot(s+'-chi2cut-dMinPt', 'Min Tracks Pt', t, 'DaughterMinPt' , cut ) addPlot(s+'-chi2cut-VtxZ', 'Reco vertex z position [cm]', t, 'vtxz' , cut) addPlot(s+'-chi2cut-DOCA', 'Daughter tracks DOCA [cm]', t, 'DOCA' , cut) cut += " && DOCA < 25" addPlot(s+'-chi2andDOCAcuts-IP', 'Impact parameter to target [cm]', t, 'IP0', cut) addPlot(s+'-chi2andDOCAcuts-Mass', 'Reco inv. mass', t, 'Mass' , cut) addPlot(s+'-chi2andDOCAcuts-P','Reconstructed Momentum', t, 'P', cut) addPlot(s+'-chi2andDOCAcuts-Pt','Reconstructed Pt', t, 'Pt', cut) addPlot(s+'-chi2andDOCAcuts-PtOverP', 'Reconstructed Pt/P', t, 'Pt/P', cut) addPlot(s+'-chi2andDOCAcuts-dPt', 'Tracks Pt', t, 'DaughtersPt' , cut) addPlot(s+'-chi2andDOCAcuts-dMinP', 'Min Tracks P', t, 'DaughterMinP' , cut ) addPlot(s+'-chi2andDOCAcuts-dMinPt', 'Min Tracks Pt', t, 'DaughterMinPt' , cut ) addPlot(s+'-chi2andDOCAcuts-VtxZ', 'Reco vertex z position [cm]', t, 'vtxz' , cut) #try: # minz = studies[s]['geo']['lidT1I_1']['z']['pos'] + studies[s]['geo']['lidT1I_1']['z']['dim'] + 500. # maxz = studies[s]['geo']['lidT6I_1']['z']['pos'] - studies[s]['geo']['lidT6I_1']['z']['dim'] #except: minz = studies[s]['geo']['Veto_5']['z']['pos'] + studies[s]['geo']['Veto_5']['z']['dim'] maxz = studies[s]['geo']['Tr1_1']['z']['pos'] + studies[s]['geo']['Tr1_1']['z']['dim'] cut += " && vtxz > %s && vtxz < %s"%(minz, maxz) addPlot(s+'-chi2andDOCAandZcuts-IP', 'Impact parameter to target [cm]', t, 'IP0', cut) addPlot(s+'-chi2andDOCAandZcuts-Mass', 'Reco inv. mass', t, 'Mass' , cut) addPlot(s+'-chi2andDOCAandZcuts-P','Reconstructed Momentum', t, 'P', cut) addPlot(s+'-chi2andDOCAandZcuts-Pt','Reconstructed Pt', t, 'Pt', cut) addPlot(s+'-chi2andDOCAandZcuts-PtOverP', 'Reconstructed Pt/P', t, 'Pt/P', cut) addPlot(s+'-chi2andDOCAandZcuts-dPt', 'Tracks Pt', t, 'DaughtersPt' , cut) addPlot(s+'-chi2andDOCAandZcuts-dMinP', 'Min Tracks P', t, 'DaughterMinP' , cut ) addPlot(s+'-chi2andDOCAandZcuts-dMinPt', 'Min Tracks Pt', t, 'DaughterMinPt' , cut ) addPlot(s+'-chi2andDOCAandZcuts-VtxZ', 'Reco vertex z position [cm]', t, 'vtxz' , cut) for s in studies.keys():#['pimu', 'mumunu', 'bg']: for list in results[s]: print s,list,results[s][list]