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FairShipTools / newGen / ntuple_nuVeto_small_newVar.py
import sys, re, getopt
from array import array
from ROOT import *

fileName, fileNameGeo, outputFileName, sampleType, jobID = None, None, None, None, None
maxevents = 0
verbose = True
# Energy deposit threshold for the liquid scintillator
threshold = 0.045

# Parse commandline inputs
try:
    opts, args = getopt.getopt(sys.argv[1:], "n:t:f:o:v:j:", ['Ethr='])
except getopt.GetoptError:
    # print help information and exit:
    print '\tUSAGE: -f inputfile.root -o outputfile.root -t sampleType (sig, nuBg or cosmics) -n maxevents -v verbose (0 or 1) -j jobID (0 to ...) '
    sys.exit()
for o, a in opts:
    if o in ("-f",):
        fileName = a
    if o in ("-o",):
        outputFileName = a
    if o in ("-n",):
        print "-n",a
        maxevents = int(a)
    if o in ("-j",):
        print "-j",a
        jobID = long(a)
    if o in ("-t",):
        sampleType = str(a)
    if o in ("-v",):
        verbose = bool(int(a))
    if o in ("--Ethr=",):
        threshold = float(a)
    
fileNameGeo = fileName.replace('ship', 'geofile_full').replace("_rec","")
# fileNameGeo = "geofile_full.10.0.newGen_15340000_nuBg81.root"#fileName.replace('ship', 'geofile_full').replace("_rec","")

def namestr(obj, namespace=globals()):
    return [name for name in namespace if namespace[name] is obj]

for item in [fileName, fileNameGeo, outputFileName, sampleType]:
    if not item:
        print '\tFATAL! %s not defined!'%namestr(item)[0]
        sys.exit()

for item in [fileName, fileNameGeo, outputFileName, sampleType, maxevents, verbose, threshold]:
    print '\tINFO: %s set to %s'%(namestr(item)[0], item)

# Load SHiP (LHCb) style
gROOT.ProcessLine(".x mystyle.C")
# Obsolete debug flags
oldGeo = False
ON = True
# Load PDG database
pdg = TDatabasePDG.Instance()
# Add elements to PDG database
import pythia8_conf
pythia8_conf.addHNLtoROOT()
# TODO: MAKE THIS A DICTIONARY AND DE-VERBOSIZE IT!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!1
if not(pdg.GetParticle(1000010020)):
    pdg.AddParticle("Deuteron","Deuteron", 1.875613e+00, kTRUE, 0,3,"Ion",1000010020)
    pdg.AddAntiParticle("AntiDeuteron", - 1000010020)
if not(pdg.GetParticle(1000010030)):
    pdg.AddParticle("Triton","Triton", 2.808921e+00, kFALSE, 3.885235e+17,3,"Ion",1000010030);
    pdg.AddAntiParticle("AntiTriton", - 1000010030);
if not(pdg.GetParticle(1000020040) ):
    pdg.AddParticle("Alpha","Alpha",3.727379e+00,kFALSE,0,6,"Ion",1000020040);
    pdg.AddAntiParticle("AntiAlpha", - 1000020040);
if not(pdg.GetParticle(1000020030) ):
    pdg.AddParticle("HE3","HE3",2.808391e+00,kFALSE,0,6,"Ion",1000020030);
    pdg.AddAntiParticle("AntiHE3", -1000020030);
if not(pdg.GetParticle(1000030070) ):
    print "TO BE CHECKED the data insert for Li7Nucleus"
    pdg.AddParticle("Li7Nucleus","Li7Nucleus",3.727379e+00/4.*7.,kFALSE,0,0,"Boson",1000030070);
if not(pdg.GetParticle(1000060120) ):
    print "ERROR: random values insert for C12Nucleus"
    pdg.AddParticle("C12Nucleus","C12Nucleus",0.1,kFALSE,0,0,"Isotope",1000060120);
if not(pdg.GetParticle(1000030060) ):
    print "ERROR: random values insert for Li6Nucleus"
    pdg.AddParticle("Li6Nucleus","Li6Nucleus",6.015121,kFALSE,0,0,"Isotope",1000030060);       
if not(pdg.GetParticle(1000070140) ):
    print "ERROR: random values insert for for N14"
    pdg.AddParticle("N14","N14",0.1,kTRUE,0,0,"Isotope",1000070140);       
if not(pdg.GetParticle(1000050100) ):
    print "TO BE CHECKED the data insert for B10"
    pdg.AddParticle("B10","B10",10.0129370,kTRUE,0,0,"Isotope",1000050100);
if not(pdg.GetParticle(1000020060) ):
    print "TO BE CHECKED the data insert for He6"
    pdg.AddParticle("He6","He6",6.0188891,kFALSE,806.7e-3,0,"Isotope",1000020060);
if not(pdg.GetParticle(1000040080) ):
    print "TO BE CHECKED the data insert for Be8"
    pdg.AddParticle("Be8","Be8",8.00530510,kFALSE,6.7e-17,0,"Isotope",1000040080);
if not(pdg.GetParticle(1000030080) ):
    print "TO BE CHECKED the data insert for Li8"
    pdg.AddParticle("Li8","Li8",8.002248736,kTRUE,178.3e-3,0,"Isotope",1000030080);    
if not(pdg.GetParticle(1000040170) ):
    print "ERROR: didn't find what is it particle with code 1000040170, random number inserted!"
    pdg.AddParticle("None","None",0.1,kFALSE,0,0,"Isotope",1000040170);    
if not(pdg.GetParticle(1000040100) ):
    print "TO BE CHECKED the data insert for Be10"
    pdg.AddParticle("Be10","Be10",10.0135338,kTRUE,5.004e+9,0,"Isotope",1000040100);    
if not(pdg.GetParticle(1000040070) ):
    print "TO BE CHECKED the data insert for Be7"
    pdg.AddParticle("Be7","Be7",11.021658,kTRUE,13.81,0,"Isotope",1000040070);    
if not(pdg.GetParticle(1000230470) ):
    print "ERROR: didn't find what is it particle with code 1000230470, random number inserted!"
    pdg.AddParticle("None2","None2",0.1,kFALSE,0,0,"Isotope",1000230470);    
if not(pdg.GetParticle(1000080170) ):
    print "ERROR: didn't find what is it particle with code 1000080170, random number inserted!"
    pdg.AddParticle("None3","None3",0.1,kFALSE,0,0,"Isotope",1000080170);    
if not(pdg.GetParticle(1000240500) ):
    print "ERROR: didn't find what is it particle with code 1000240500, random number inserted!"
    pdg.AddParticle("None4","None4",0.1,kFALSE,0,0,"Isotope",1000240500);    
if not(pdg.GetParticle(1000210450) ):
    print "ERROR: didn't find what is it particle with code 1000210450, random number inserted (Sc45Nucleus)!"
    pdg.AddParticle("Sc45Nucleus","Sc45Nucleus",0.1,kFALSE,0,0,"Isotope",1000210450);    
if not(pdg.GetParticle(1000040090) ):
    print "TO BE CHECKED the data insert for Be9"
    pdg.AddParticle("Be9","Be9",9.0121822,kFALSE,0,0,"Isotope",1000040090);    
if not(pdg.GetParticle(1000080160) ):
    print "TO BE CHECKED the data insert for O16"
    pdg.AddParticle("O16","O16",15.99491461956,kFALSE,0,0,"Isotope",1000080160);    
if not(pdg.GetParticle(1000220460) ):
    print "TO BE CHECKED the data insert for Ar40"
    pdg.AddParticle("Ar40","Ar40",39.9623831225,kFALSE,0,0,"Isotope",1000220460);   
if not(pdg.GetParticle(1000050110) ):
    print "TO BE CHECKED the data insert for B11"
    pdg.AddParticle("B11","B11",11.0093054,kFALSE,0,0,"Isotope",1000050110);   

def PrintEventPart(particles,pdg):
    print "Particles in the event:"
    for (pid,part) in enumerate(particles):
        print pid, pdg.GetParticle(part.GetPdgCode()).GetName(), part.GetMotherId()
    print

def PrintRPChits(rpc,pdg):
    print "Hits in:"
    for (ix,RPCpt) in enumerate(rpc):
        tmpName = pdg.GetParticle(RPCpt.PdgCode())
        print ix,RPCpt.GetZ(), tmpName, RPCpt.GetTrackID() , fGeo.FindNode(RPCpt.GetX(),RPCpt.GetY(),RPCpt.GetZ()).GetVolume().GetName()
    print

# weight computation moved to offlineForBarbara.py

def addVect(t,name,vectType):
    vect =  vector(vectType)()
    t.Branch( name, vect )
    return t, vect

def addVar(t,name,varType):
    var = array(varType,[-999])
    t.Branch(name,var,name+"/"+varType.upper())
    return t, var

def putToZero(var):
    var[0] = 0
    
def getPartName(partId):
    return pdg.GetParticle(partId).GetName()

def lookingForDecay(particles):
    decayMotherList = []
    for p in particles:
        mID = p.GetMotherId()
        if mID>=0 and not (mID in decayMotherList): 
            decayMotherList.append(mID)
            decayPartIndex.push_back(mID)
            decayPartID.push_back(particles[mID].GetPdgCode())
            decayPartStrID.push_back(pdg.GetParticle(particles[mID].GetPdgCode()).GetName())
            decayPos_x.push_back(p.GetStartX())
            decayPos_y.push_back(p.GetStartY())
            decayPos_z.push_back(p.GetStartZ())
            decayMother.push_back(particles[mID].GetMotherId())
            decayP.push_back(p.GetP())

def wasFired(indexKids, detPoints, detPos, hitCharges, hitTrackId, checkOn, pointVects=None, Ethr=0):
    #
    def lookingForHits(detPoints,flag,flag_eff,nstat,nstat_eff,indexKids,Eloss,Ethr,hitCharges, hitTrackId):
        charges = []
        trackids = []
        if hitCharges is None:
            assert(hitTrackId is None)
        for pos in detPos:
            foundStat = False
            foundStat_eff = False
            for hit in detPoints:
                if (indexKids is None) or (hit.GetTrackID() in indexKids):
                    # check if it is in one of the considered active layer
                    if pos[0]<=hit.GetZ()<=pos[1]:
                        Eloss += hit.GetEnergyLoss()
                        hitID = hit.GetTrackID()
                        if not hitID in trackids and not hitCharges is None:
                            if  hit.PdgCode()>100000:
                                charges.append(9)
                            else:
                                charges.append(int(pdg.GetParticle(hit.PdgCode()).Charge()))
                            trackids.append(hitID)
                            hitCharges.push_back(charges[-1])
                            hitTrackId.push_back(trackids[-1])
                        if pointVects is not None:
                            pointVects[0].push_back(hit.GetX())
                            pointVects[1].push_back(hit.GetY())
                            pointVects[2].push_back(hit.GetZ())
                        flag = True
                        foundStat = True
                        eff_val = gRandom.Uniform(0.,1.)
                        if eff_val<0.9:
                            flag_eff = flag_eff or True
                            foundStat_eff = True
                        else:
                            flag_eff = flag_eff or False
            if foundStat:
                nstat+=1
            if foundStat_eff:
                nstat_eff+=1
        particles = 0
        flag_Ethr = Eloss>=Ethr
        return flag, flag_eff, nstat, nstat_eff, Eloss, flag_Ethr,particles
    #
    # Now in partKidTrackID I should have the trackID connected to my charged particles
    flag_eff = False
    flag = False
    nstat = 0
    nstat_eff = 0
    Eloss = 0
    flag,flag_eff,nstat,nstat_eff,Eloss,flag_Ethr,particles = lookingForHits(detPoints,flag,flag_eff,nstat,nstat_eff,indexKids,Eloss,Ethr,hitCharges, hitTrackId)
    if flag==False and checkOn:
        print "To be study event %s"%entry        
    return flag, flag_eff, nstat, nstat_eff, flag_Ethr, particles

def convertion(tmpName):
    if "Rib" in tmpName: tmpName = "Rib"
    elif "LiSc" in tmpName: tmpName= "LiSc"
    elif "Tr" in tmpName: tmpName = "Tr"
    elif "Startplate" in tmpName: tmpName = "Startplate"
    elif re.search("T\d+O", tmpName): tmpName = "TO"
    elif re.search("T\d+I", tmpName): tmpName = "TI"
    elif "Endplate" in tmpName: tmpName = "Endplate"
    elif "volCoil" in tmpName: tmpName = "volCoil"
    elif "volFeYoke" in tmpName: tmpName = "volFeYoke"
    elif "gas" in tmpName: tmpName = "gas"
    elif "wire" in tmpName: tmpName == "wire"
    elif "VetoTimeDet" in tmpName: tmpName = "upstreamVeto"
    elif "Veto" in tmpName: tmpName = "strawVeto"
    return tmpName

def wasFired_node(indexKids, detPoints, detVolNames, hitCharges, hitTrackId, checkOn, pointVects=None, Ethr=0):
    #
    def lookingForHits(detPoints,flag,hitCharges, hitTrackId):
        if hitCharges is None:
            assert(hitTrackId is None)
        for hit in detPoints:
            if (indexKids is None) or (hit.GetTrackID() in indexKids):
                tmpName = fGeo.FindNode(hit.GetX(),hit.GetY(),hit.GetZ()).GetVolume().GetName()
                tmpName = convertion(tmpName)
                if hit.GetZ()>8000:
                    continue
                if tmpName in detVolNames:
                    ## trick to remove the case of the tracking system the hits in the gas or straw from the straw-veto:
                    if 'trackingSystem' in detVolNames and hit.GetZ()<0:
                        continue
                    if "strawVetoSystem" in detVolNames and hit.GetZ()>0:
                        continue
                    if "upstreamVeto" in detVolNames and not(hit.GetZ()>= upstreamVetoPos[0][0] and hit.GetZ()<=upstreamVetoPos[0][1]):    
                        continue
                    # check if it is in one of the considered active layer
                    if True: #pos[0]<=hit.GetZ()<=pos[1]:
                        flag = True
        return flag
    #
    # Now in partKidTrackID I should have the trackID connected to my charged particles
    flag = False
    flag = lookingForHits(detPoints,flag,hitCharges, hitTrackId)
    if flag==False and checkOn:
        print "To be study event %s"%entry        
    return flag


""" Main program """

# Open file
f = TFile(fileName)
t = f.Get("cbmsim")

totentries = t.GetEntries()
if verbose:
    print
    print
    print "Program started, reading %s from %s"%(t.GetName(), fileName)
if (maxevents>0) and (maxevents < totentries):
    entries = maxevents
else:
    entries = totentries
if verbose:
    print "Requested to process %s events out of %s in tree"%(entries, totentries)

# Load geometry
from lookAtGeo import *
r = loadGeometry(fileNameGeo)
fGeo = r['fGeo']

# Functions by Elena for offline selection
# (Also includes another dictionary of all geometry nodes)
import offlineForBarbara as offline
offline.loadNodes(fGeo)
offline.ShipGeo = r['ShipGeo']
offline.initBField(fileNameGeo)
offline.sh = offline.StrawHits(t, offline.modules, offline.ShipGeo.straw.resol, 0, None, offline.ShipGeo)
offline.pdg = pdg

# Handle geometry
# Names of useful geometry nodes
myNodes_name = ["VetoTimeDet_1"]
myNodes_name += ["Tr%s_%s"%(i,i) for i in xrange(1,5)]
myNodes_name += ["Veto_5"]
# Positions of selected nodes
myGeoEl = findPositionGeoElement(fileNameGeo, myNodes_name,None)
# Places where a neutrino can interact
lastPassive_nodeName = ["volIron_23"]
OPERA_nodeName = ["volIron", "volRPC", "volHPT","volArm2MS","volFeYokes","volCoil","volFeYoke"]#["volIron_%s"%i for i in xrange(12,24)]+["volRpc_%s"%i for i in xrange(11,22)]+["volArm2MS_1"] 
entrance_nodeName = ["T1Lid"]#['T1lid_1']
volumeIn_nodeName = ["TI"]#['T%sI'%i for i in [1,2,3,5]]
volumeOut_nodeName = ["TO"]#['T%sO'%i for i in [1,2,3,5]]
OPERA_volNames = ["volIron","volRpc","volHPT"]
strawVeto_volNames = ["Veto"]
# Z positions of the VETO and tracking systems
Tracking = [myGeoEl["Tr1_1"]['z']-myGeoEl["Tr1_1"]['dimZ'],myGeoEl["Tr4_4"]['z']+myGeoEl["Tr4_4"]['dimZ']]
upstreamVeto = [myGeoEl["VetoTimeDet_1"]['z']-myGeoEl["VetoTimeDet_1"]['dimZ'],myGeoEl["VetoTimeDet_1"]['z']+myGeoEl["VetoTimeDet_1"]['dimZ']]
trackStationsPos = [[myGeoEl["Tr%s_%s"%(i,i)]['z']-myGeoEl["Tr%s_%s"%(i,i)]['dimZ'],myGeoEl["Tr%s_%s"%(i,i)]['z']+myGeoEl["Tr%s_%s"%(i,i)]['dimZ']] for i in xrange(1,5)]
strawVetoPos = [[myGeoEl["Veto_5"]['z']-myGeoEl["Veto_5"]['dimZ'],myGeoEl["Veto_5"]['z']+myGeoEl["Veto_5"]['dimZ']]]
vetoWall = [[myGeoEl["VetoTimeDet_1"]['z']+myGeoEl["VetoTimeDet_1"]['dimZ']+0.001,myGeoEl["Tr%s_%s"%(i,i)]['z']-myGeoEl["Tr%s_%s"%(i,i)]['dimZ']]]#myGeoEl["VetoTimeDet_1"]['z']+myGeoEl["VetoTimeDet_1"]['dimZ']+6000.]]
upstreamVetoPos = [[myGeoEl["VetoTimeDet_1"]['z']-myGeoEl["VetoTimeDet_1"]['dimZ'],myGeoEl["VetoTimeDet_1"]['z']+myGeoEl["VetoTimeDet_1"]['dimZ']]]
RPCstationsPos = [[-3500,myGeoEl["VetoTimeDet_1"]['z']-myGeoEl["VetoTimeDet_1"]['dimZ']-0.5]]
# Places where a neutrino can interact (some duplicates?)
trackStationsPos_node = ["Tr", "gas", "straw", 'trackingSystem']
## should be that this does not work since it could be that hits are also assigned to gas or straw
strawVetoPos_node = ["strawVeto", "gas", "straw", "strawVetoSystem"]
vetoWall_node = ["LiSc","cave","Rib","TI","TO","Tr","strawVeto"]
upstreamVetoPos_node = ["upstreamVeto","cave"]
RPCstationsPos_node = ["volRpc","volMagneticSpectrometer","volIron","volHPT"]
# Printout positions
print "OPERApos: ",RPCstationsPos
print "trackingPos: ",trackStationsPos
print "strawVetoPos: ",strawVetoPos
print "scintPos: ",vetoWall
print "upstreamVetoPos: ",upstreamVetoPos

# Prepare output ntuple
nf = TFile(outputFileName,"RECREATE")
nt = TTree("t","t")
# Event number --------------------------------------------
nt, event = addVar(nt, 'event','i')
# Neutrino information ------------------------------------
nt, nNu = addVar(nt, 'nNu', 'i')
nt, isPrimary = addVar(nt, 'isPrimary','i')
nt, startZ_nu = addVar(nt, 'startZ_nu', 'f')
nt, startY_nu = addVar(nt, 'startY_nu', 'f')
nt, startX_nu = addVar(nt, 'startX_nu', 'f')
nt, nuE = addVar(nt, 'nuE', 'f')
nt, weight = addVar(nt, 'weight', 'f')
# Interaction element code --------------------------------
## 0: last passive material opera-mu-system
## 1: two windows around liquid scintillator
## 2: along vaccum tank
## 3: along all OPERA
## 4: between the two entrance windows
## 5: along vacuum tank outer window
## 6: along vacuum tank inner window
## 999: wrong OPERA place ## needed until we have the new production
## -1: anything else, but what???? #it should never been present
nt, interactionElement = addVar(nt, 'interactionElement','i')
# Neutrino daughters --------------------------------------
# Do the particles come from a neutrino?
nt, nPart_fromNu = addVar(nt, 'nPart_fromNu', 'i')
nt, idPart_fromNu = addVect(nt, 'idPart_fromNu', 'int')
#nt, idStrPart_fromNu = addVect(nt, 'idStrPart_fromNu', 'string')
# Do charged particles come from a neutrino?
nt, nChargedPart_fromNu = addVar(nt, 'nChargedPart_fromNu', 'i')
nt, idChargedPart_fromNu =  addVect(nt, 'idChargedPart_fromNu', 'int')
#nt, idStrChargedPart_fromNu =  addVect(nt, 'idStrChargedPart_fromNu', 'string')
# Do neutral particles come from a neutrino?
nt, nNeutrPart_fromNu = addVar(nt, 'nNeutrPart_fromNu', 'i')
nt, idNeutrPart_fromNu = addVect(nt, 'idNeutrPart_fromNu', 'int')
#nt, idStrNeutrPart_fromNu = addVect(nt, 'idStrNeutrPart_fromNu', 'string')
# RPC -----------------------------------------------------
# In case something (no matter if it comes from the nu-interaction kids) fired the RPC
nt, RPCany = addVar(nt,'RPCany', 'i' )
# accounting for an eff. of each station of 90%
nt, RPCany_eff = addVar(nt,'RPCany_eff', 'i' )
# upstreamVeto --------------------------------------------
nt, upstreamVetoany = addVar(nt,'upstreamVetoAny', 'i' )
# accounting for an eff. of each station of 90%
nt, upstreamVetoany_eff = addVar(nt,'upstreamVetoAny_eff', 'i' )
# scintVeto -----------------------------------------------
## In case something (no matter if it comes from the nu-interaction kids) fired the surroundin walls
nt, scintVetoAny = addVar(nt,'scintVetoAny', 'i' )
nt, scintVetoAny_eff = addVar(nt,'scintVetoAny_eff', 'i' )
# strawVeto -----------------------------------------------
# In case something (no matter if it comes from the nu-interaction kids) fired the strawVeto
nt, strawVetoAny = addVar(nt,'strawVetoAny', 'i' )
nt, strawVetoAny_eff = addVar(nt,'strawVetoAny_eff', 'i' )
# TrackSyst -----------------------------------------------
# only the case of anything fired it is considered, obviously
nt, TrackSyst = addVar(nt, "TrackSyst", 'i')
nt, TrackSyst_eff = addVar(nt, "TrackSyst_eff", 'i')
# VETO and tracking systems with thresholds ---------------
nt, strawVetoAny_Ethr = addVar(nt,"strawVetoAny_Ethr","i")
nt, scintVetoAny_Ethr = addVar(nt,"scintVetoAny_Ethr","i")
nt, upstreamVetoAny_Ethr = addVar(nt,"upstreamVetoAny_Ethr","i")
nt, RPCany_Ethr = addVar(nt,"RPCany_Ethr","i")
nt, TrackSyst_Ethr = addVar(nt, "TrackSyst_Ethr", "i")
# Decay information ---------------------------------------
nt, decayPartIndex = addVect(nt, "decayPartIndex", "float")
nt, decayPartID = addVect(nt, "decayPartID", "float")
nt, decayPartStrID = addVect(nt, "decayPartStrID", "string")
nt, decayPos_x = addVect(nt, "decayPos_x", "float")
nt, decayPos_y = addVect(nt, "decayPos_y", "float")
nt, decayPos_z = addVect(nt, "decayPos_z", "float")
nt, decayMother = addVect(nt, "decayMother", "float")
nt, decayP = addVect(nt,"decayP","float")
# Is this a NC interaction? -------------------------------
nt, NC = addVar(nt, "NC", "i")
# Store where the neutrino interacted ---------------------
#nt, nuInteractionNode = addVect(nt, "nuInteractionNode", "string")
nt, nuIntNumSimpl = addVar(nt,"nuIntNumSimpl","i")
dictNodeNames = {'volIron':0, 'cave':1, 'LiSc':2, 'Startplate':3, 'TI':4, 'rockD':5, 'Endplate':6, 'Rib':7, 'volFeYoke':8, 'volHPT':9, 'TO':10, 'volRpc':11, 'volCoil':12, 'T1Lid':13, 'straw':14, 'strawVeto':15, 'volBase':16, 'Tr':17, 'gas':18, 'wire':19, 'others':20}
# Was the event reconstructed? ----------------------------
nt, recoed = addVar(nt, "recoed","i")
# How many candidates in the reco event? ------------------
nt, nRecoed = addVar(nt, "nRecoed","i")
# Add stuff for online selection --------------------------
offline.addOfflineToTree(nt)
# Leaf for job ID
nt, jID = addVar(nt, "jobID", "l")

####### New Variables after TP
# original interaction element
nt, originalIntEl = addVect(nt, "originalIntEl","string")
# PDG Code of Particles with Hits in Tracking system
nt, PdgPartTrackSyst  = addVect(nt, "PdgPartTrackSyst","int")
# It's Momentum
nt, PPartTrackSyst = addVect(nt, "PPartTrackSyst","float")
# It's Energy
nt, EPartTrackSyst = addVect(nt, "EPartTrackSyst","float")
# Where it interacted
nt, intElPartTrackSyst = addVect(nt, "intElPartTrackSyst","string")
# number of Hits left by the particle in the Tracking system per particle
nt, nHitsPartTrackSyst = addVect(nt, "nHitsPartTrackSyst","int")
# number of Hits per Event
nt, nHitsTrackSystEvent = addVar(nt, "nHitsTrackSystEvent","i")
# PDG Code of mother of these particles
nt, PdgMotherTrackSyst = addVect(nt, "PdgMotherTrackSyst","int")
# interaction Element of the mother
nt, intElMotherTrackSyst = addVect(nt, "intElMotherTrackSyst", "string")
# Energy mother
nt, EMotherTrackSyst = addVect(nt,"EMotherTrackSyst","float")




# Now loop on the tree
# t = original tree
# nt = new tree
for entry in xrange(entries):
    if not (entry%1000):
        print "\tProcessing entry %s of %s..."%(entry,entries)
    t.GetEntry(entry)
    putToZero(jID)
    jID[0] = jobID
    event[0] = entry #+(jobID*entries)

    ####################
    particles = t.MCTrack
    rpc = t.ShipRpcPoint
    scint = t.vetoPoint
    strawPoints = t.strawtubesPoint
    vetoScint = t.vetoPoint
    recoParts = t.Particles
    trackFit = t.FitTracks
    ####################
    
    # initialize containers
    putToZero(nNu)
    putToZero(nPart_fromNu)
    putToZero(nChargedPart_fromNu)
    putToZero(nNeutrPart_fromNu)
    idPart_fromNu.clear()
    idChargedPart_fromNu.clear()
    idNeutrPart_fromNu.clear()
    #idStrPart_fromNu.clear()
    #idStrChargedPart_fromNu.clear()
    #idStrNeutrPart_fromNu.clear()
    decayPartIndex.clear()
    decayPartID.clear()
    decayPartStrID.clear()
    decayPos_x.clear()
    decayPos_y.clear()
    decayPos_z.clear()
    decayMother.clear()
    decayP.clear()

    ## new vars
    originalIntEl.clear()
    PdgPartTrackSyst.clear()
    PPartTrackSyst.clear()
    EPartTrackSyst.clear()
    intElPartTrackSyst.clear()
    nHitsPartTrackSyst.clear()
    putToZero(nHitsTrackSystEvent)
    PdgMotherTrackSyst.clear()
    intElMotherTrackSyst.clear()
    EMotherTrackSyst.clear()

    
    #nuInteractionNode.clear()
    primaryDone=False
    isPrimary[0] = int(False)
    lookingForDecay(particles)
    nRecoed[0] = 0
    recoed[0] = 0
    # Which one is the "primary" particle?
    if sampleType=="nuBg" or sampleType == "cosmics":
        startPartRange = [0] 
        primaryMum = -1
    elif sampleType=="sig":
        startPartRange = [1] 
        primaryMum = 0
    # Look at the primary particle
    ip = startPartRange[0]
    skipEvent=False
    # Were there any hit in the tracking stations?
    TrackSyst[0],TrackSyst_eff[0],dummy,dummy,TrackSyst_Ethr[0], dummy = wasFired(None, strawPoints, trackStationsPos, None, None, checkOn=False, pointVects=None)#[strawPoint_x, strawPoint_y, strawPoint_z] )
    # If no, skip this event
    if TrackSyst[0]==0:
        skipEvent=True
        #print "i am jumping this one"
        continue
        # exit from loop on particles
        #break
    # Select the primary MC particle
    part = particles[ip]
    pdgPart = pdg.GetParticle(part.GetPdgCode())
    if sampleType=="nuBg":
        assert("nu" in pdgPart.GetName())        
    ## Looking for a neutrino: it should have the correct pdg code and it should not have a mother
    #if (("nu" in pdgPart.GetName())):# and part.GetMotherId()==-1): # commented out by elena
    ## (and de-indented the following block)
    ## Starting the counter of how many particles were produced by the interaction of this specific nu
    for recoP in recoParts:
        nRecoed[0] += 1
        #offline.pushOfflineByParticle(t, recoP)
    if nRecoed[0]>0:
        recoed[0]=1
    else:
        skipEvent=True
        continue
        #break
    nNu[0]+=1
    if part.GetMotherId()==primaryMum:
        assert(primaryDone==False)
        primaryDone=True
        isPrimary[0] = int(True) 
        assert(len(idPart_fromNu)==0)
        assert(len(idNeutrPart_fromNu)==0)
    else: 
        continue
    # Where did this guy interact?
    tmpName = fGeo.FindNode(part.GetStartX(),part.GetStartY(),part.GetStartZ()).GetVolume().GetName()
    #nuInteractionNode.push_back(tmpName)
    tmpName = convertion(tmpName)
    if not tmpName in dictNodeNames:
        tmpName = "others"
    nuIntNumSimpl[0] = dictNodeNames[tmpName]
    originalIntEl.push_back(tmpName)
    # Store interaction point coordinates
    startZ_nu[0] = part.GetStartZ()
    startY_nu[0] = part.GetStartY()
    startX_nu[0] = part.GetStartX()
    # Primary particle information
    nuE[0] = part.GetEnergy()
    # Looking for particles produced by the neutrino interaction
    interacted = False
    partKidsId = []
    NC[0] = 0

    # Add information for offline selection
    # (mainly signal normalisation and zeroing of particle-wise arrays)
    ntr, nref = offline.pushOfflineByEvent(t, vetoScint, sampleType, verbose, threshold)
    for recoP in recoParts:
       offline.pushOfflineByParticle(t, recoP, ntr, nref)

    # Loop on MCTracks
    for ip2 in xrange(0,len(particles)):
        part2 = particles[ip2]
        # exit if we have reached the empty part of the array
        if not (type(part2)==type(ShipMCTrack())):
            break
        if part2.GetMotherId()==ip:
            interacted = True 
            part2Id = part2.GetPdgCode()
            partKidsId.append(part2Id)
            # Was this a neutral current interaction?
            if not (pdg.GetParticle(part2.GetPdgCode()) == None) and ("nu" in pdg.GetParticle(part2.GetPdgCode()).GetName()) and (part2.GetMotherId()==0):
                NC[0] = 1
            nPart_fromNu[0]+=1
            idPart_fromNu.push_back(part2Id)
            if pdg.GetParticle(part2.GetPdgCode()) == None:
                part2Name = str(part2Id)
            else:
                part2Name = getPartName(part2Id)
            #idStrPart_fromNu.push_back(part2Name)
            # Counting how many particles produced by the nu-interaction are charged or neutral
            if (pdg.GetParticle(part2.GetPdgCode())) == None or (int(fabs(pdg.GetParticle(part2Id).Charge()))==int(0)):
                nNeutrPart_fromNu[0]+=1
                idNeutrPart_fromNu.push_back(part2Id)
                #idStrNeutrPart_fromNu.push_back(part2Name)
            else:
                nChargedPart_fromNu[0]+=1
                idChargedPart_fromNu.push_back(part2Id)
                #idStrChargedPart_fromNu.push_back(part2Name)
            # How many are produced by the interaction in the last passive element of the "opera-mu system"?
            # Finding out the "interaction element code"
            part2Z = part2.GetStartZ()
            part2X = part2.GetStartX()
            part2Y = part2.GetStartY()
            somewhere = False
            nodeName = fGeo.FindNode(part2X,part2Y,part2Z).GetName()
            if  nodeName in lastPassive_nodeName:
                somewhere = True
                interactionElement[0] = 0 
                intElName = 'OPERA'
            # To know if it was in the full OPERA-system (excluded last passive)
            if tmpName in OPERA_nodeName and somewhere==False:
                somewhere = True
                interactionElement[0] = 3
                intElName = 'OPERA'
            # To know if it was between the two windows
            if tmpName in entrance_nodeName:
                assert(somewhere==False)
                somewhere = True
                interactionElement[0] = 1
            # Vacuum tank outer window
            if tmpName in volumeIn_nodeName and somewhere==False:
                interactionElement[0] = 5
                somewhere = True 
            # Vacuum tank inner window
            elif nodeName in volumeOut_nodeName and somewhere==False:
                interactionElement[0] = 6
                somewhere = True 
            # Vacuum tank ribs
            if "Rib" in tmpName:
                interactionElement[0] = 7
            # Somewhere else
            if somewhere==False:
                interactionElement[0] = -1
        # End loop on MCTracks
    # Should be changed to avoid entering in the loop if there isn't anything in the tracking
    if skipEvent:
        continue
    strawVetoAny[0],strawVetoAny_eff[0],dummy,dummy,strawVetoAny_Ethr[0],dummy  = wasFired(None, strawPoints, strawVetoPos,None,None, checkOn=False, pointVects=None)#[strawVetoPoint_x, strawVetoPoint_y, strawVetoPoint_z])
    upstreamVetoany[0], upstreamVetoany_eff[0], dummy,dummy, upstreamVetoAny_Ethr[0],dummy = wasFired(None, vetoScint, upstreamVetoPos, None, None, checkOn=False, pointVects=None)#[upstreamVetoPoint_x, upstreamVetoPoint_y, upstreamVetoPoint_z])
    RPCany[0], RPCany_eff[0],dummy,dummy, RPCany_Ethr[0],dummy = wasFired(None, rpc, RPCstationsPos, None, None, checkOn=False, pointVects=None)#[rpcPoint_x, rpcPoint_y, rpcPoint_z])
    scintVetoAny[0], scintVetoAny_eff[0], dummy,dummy, scintVetoAny_Ethr[0],dummy = wasFired(None, vetoScint, vetoWall, None, None, checkOn=False, pointVects=None, Ethr=threshold)
    #assert(len(idStrPart_fromNu)==len(idPart_fromNu))
    #assert(len(idStrChargedPart_fromNu)==len(idChargedPart_fromNu))
    #assert(len(idStrNeutrPart_fromNu)==len(idNeutrPart_fromNu))
    #assert(len(idStrPart_fromNu)==nChargedPart_fromNu[0]+nNeutrPart_fromNu[0])
    #assert(len(idStrChargedPart_fromNu)==nChargedPart_fromNu[0])
    #assert(len(idStrNeutrPart_fromNu)==nNeutrPart_fromNu[0])
    if not primaryDone:
        print "It looks like there is no primary nu interacting"
        PrintEventPart(particles,pdg)
        sys.exit()
    weight[0] = offline.findWeight(sampleType, NC[0], nuE[0], part, entries, pdgPart.GetName(), ON)#calcWeight(NC[0], nuE[0], part.GetWeight(), entries, pdgPart.GetName(), ON)


    # Fill Particle in Tracking System Variables
    # helping variables: hitlist and tracklist
    hitlist={}
    for hit in strawPoints:
        trId = hit.GetTrackID()
        if (trId in hitlist.keys()):
            hitlist[trId] += 1
        else:
            hitlist[trId] = 1
    # Save the trackIDs of the FitTracks in a list
    tracklist = []
    for i in xrange(len(trackFit)):
        tracklist.append(t.fitTrack2MC[i])
    # Fill the information to the Tree
    for trId in tracklist:
        part = particles[trId]
        mother = particles[part.GetMotherId()]
        PdgPartTrackSyst.push_back(part.GetPdgCode())
        PdgMotherTrackSyst.push_back(mother.GetPdgCode())
        EPartTrackSyst.push_back(part.GetEnergy())
        EMotherTrackSyst.push_back(mother.GetEnergy())
        tmpPart = fGeo.FindNode(part.GetStartX(),part.GetStartY(),part.GetStartZ()).GetVolume().GetName()
        tmpPart = convertion(tmpPart)
        tmpMother = fGeo.FindNode(mother.GetStartX(),mother.GetStartY(),mother.GetStartZ()).GetVolume().GetName()
        tmpMother = convertion(tmpMother)
        intElPartTrackSyst.push_back(tmpPart)
        intElMotherTrackSyst.push_back(tmpMother)
        PPartTrackSyst.push_back(part.GetP())
        nHitsPartTrackSyst.push_back(hitlist[trId])
        nHitsTrackSystEvent[0] += hitlist[trId]

    
    nt.Fill()
    # End loop on tree        
nt.Write()
nf.Save()
nf.Close()
f.Close()
print "Output wrote to %s"%outputFileName
print "Number of events with vertex outside Veto_5-500 - Tr4_4: %s"%offline.num_bad_z