def createWeighterObjects(self, allsourcefiles):
#
# Calculates the weights needed for flattening the pt/eta spectrum
from DeepJetCore.Weighter import Weighter
weighter = Weighter()
weighter.undefTruth = self.undefTruth
weighter.class_weights = self.class_weights
branches = [self.weightbranchX, self.weightbranchY]
branches.extend(self.truth_branches)
if self.remove:
weighter.setBinningAndClasses([self.weight_binX, self.weight_binY],
self.weightbranchX,
self.weightbranchY,
self.truth_branches,
self.red_classes,
self.truth_red_fusion,
method=self.referenceclass)
counter = 0
import ROOT
from root_numpy import tree2array, root2array
if self.remove:
for fname in allsourcefiles:
fileTimeOut(fname, 120)
nparray = uproot_root2array(fname,
treename="ttree",
stop=None,
branches=branches)
norm_hist = True
if self.referenceclass == 'flatten':
norm_hist = False
# from IPython import embed;embed()
weighter.addDistributions(nparray, norm_h=norm_hist)
#del nparray
counter = counter + 1
weighter.createRemoveProbabilitiesAndWeights(self.referenceclass)
print("calculate means")
print("debugging this point here!")
from DeepJetCore.preprocessing import meanNormProd
nparray = self.readTreeFromRootToTuple(
allsourcefiles,
branches=self.vtx_branches + self.eta_rel_branches +
self.track_branches + self.global_branches,
limit=500000)
print("read tree from sourcefiles")
for a in (self.vtx_branches + self.eta_rel_branches +
self.track_branches + self.global_branches):
for b in range(len(nparray[a])):
nparray[a][b] = np.where(
np.logical_and(np.isfinite(nparray[a][b]),
np.abs(nparray[a][b]) < 100000.0),
nparray[a][b], 0)
means = np.array([], dtype='float32')
if len(nparray):
means = meanNormProd(nparray)
print("weigheter created")
return {'weigther': weighter, 'means': means}
def convertFromSourceFile(self, filename, weighterobjects, istraining, treename="Events"):
fileTimeOut(filename, 10)#10 seconds for eos to recover
tree = uproot.open(filename)[treename]
rechitcoll = RecHitCollection(use_true_muon_momentum=self.include_tracks,
cp_plus_pu_mode=self.cp_plus_pu_mode,
tree=tree)
#in a similar manner, we can also add tracks from conversions etc here
if self.include_tracks:
trackcoll = TrackCollection(tree=tree)
rechitcoll.append(trackcoll)
# adds t_is_unique
rechitcoll.addUniqueIndices()
# converts to DeepJetCore.SimpleArray
farr = rechitcoll.getFinalFeaturesSA()
t = rechitcoll.getFinalTruthDictSA()
return [farr,
t['t_idx'], t['t_energy'], t['t_pos'], t['t_time'],
t['t_pid'], t['t_spectator'], t['t_fully_contained'],
t['t_rec_energy'], t['t_is_unique'] ],[], []
def createWeighterObjects(self, allsourcefiles):
#
# Calculates the weights needed for flattening the pt/eta spectrum
from DeepJetCore.Weighter import Weighter
weighter = Weighter()
weighter.undefTruth = self.undefTruth
branches = [self.weightbranchX, self.weightbranchY]
branches.extend(self.truth_branches)
if self.remove:
weighter.setBinningAndClasses([self.weight_binX, self.weight_binY],
self.weightbranchX,
self.weightbranchY,
self.truth_branches)
counter = 0
import ROOT
from root_numpy import tree2array, root2array
if self.remove:
for fname in allsourcefiles:
fileTimeOut(fname, 120)
nparray = root2array(fname,
treename="deepntuplizer/tree",
stop=None,
branches=branches)
weighter.addDistributions(nparray)
#del nparray
counter = counter + 1
weighter.createRemoveProbabilitiesAndWeights(self.referenceclass)
return {'weigther': weighter}
def readFromRootFile(self,filename,TupleMeanStd, weighter):
# this function defines how to convert the root ntuple to the training format
# options are not yet described here
import ROOT
fileTimeOut(filename,120) #give eos a minute to recover
rfile = ROOT.TFile(filename)
tree = rfile.Get("tree")
self.nsamples=tree.GetEntries()
# user code, example works with the example 2D images in root format generated by make_example_data
from DeepJetCore.preprocessing import read2DArray
print(filename)
feature_array = read2DArray(filename,"tree","image2d",self.nsamples,32,32)
print('feature_array',feature_array.shape)
truth = self.read_truthclasses(filename)
#notremoves=weighter.createNotRemoveIndices(Tuple)
# this removes parts of the dataset for weighting the events
#feature_array = feature_array[notremoves > 0]
# call this in the end
self.nsamples=len(feature_array)
self.x=[feature_array] # list of feature numpy arrays
self.y=[truth] # list of target numpy arrays (truth)
self.w=[] # list of weight arrays. One for each truth target, not used
def readFromRootFile(self,filename,TupleMeanStd, weighter):
# this function defines how to convert the root ntuple to the training format
# options are not yet described here
fileTimeOut(filename,120)
uproot_tree = uproot.open(filename)['clusters']
cluster_pt = uproot_tree.array('cluster_pt')
pt_filter = cluster_pt > 5.
n_cell = uproot_tree.array('n_cell')
def to_ndarray(*args):
return numpy.squeeze(numpy.dstack(args))
branches = [
'cell_layer',
'cell_x',
'cell_y',
'cell_z',
'cell_r',
'cell_eta',
'cell_theta',
'cell_phi',
'cell_dist',
'cell_energy',
'cell_wafer',
'cell_wafertype'
]
print("reading feature array")
feature_array = uproot_tree.arrays(branches, outputtype=to_ndarray)
print(feature_array.shape)
print("reading truth")
#truth = self.read_truthclasses(filename)
truth = uproot_tree.arrays(self.truthclasses, outputtype=to_ndarray)
print("creating remove indxs")
Tuple = self.readTreeFromRootToTuple(filename)
notremoves=weighter.createNotRemoveIndices(Tuple)
notremoves += pt_filter
# this removes parts of the dataset for weighting the events
if self.remove:
feature_array = feature_array[notremoves > 0]
n_cell = n_cell[notremoves > 0]
truth = truth[notremoves > 0]
# call this in the end
self.nsamples=len(feature_array)
self.x=[n_cell, feature_array] # list of feature numpy arrays
self.y=[truth] # list of target numpy arrays (truth)
self.w=[] # list of weight arrays. One for each truth target
def readPU(minbias_files, nevents=50, nfiles=5, nPU=200):
from DeepJetCore.TrainData import fileTimeOut
import ROOT
select = np.array(range(len(minbias_files)))
np.random.shuffle(select)
if len(select) < nfiles:
nfiles = len(select)
print(
"mixing.readPU: warning: less PU files available than requested - falling back"
)
print(nfiles)
#print(select)
#open them
#take nPU random events
inarrs = []
i = 0
while len(inarrs) < nfiles:
file = minbias_files[select[i]]
i += 1
#print('mixing: get data '+str(select[i])+' to go '+str(nfiles-i-1))
fileTimeOut(file, 10)
#check if file is valid
try:
f = ROOT.TFile.Open(file)
f.Get("B4")
except:
continue
ramfile = file
try:
tree = uproot.open(ramfile)["B4"]
arr = tonumpy(tree["rechit_energy"].array())
#print('arr',arr.shape)
#arr = np.expand_dims(arr, axis=0)# 1 x nev x rh
#print('arr2',arr.shape, ramfile)
inarrs.append(arr)
except:
continue
allarr = np.concatenate(inarrs, axis=0) # nfiles*nev x rh
#allarr = np.reshape(allarr, [allarr.shape[0]*allarr.shape[1],allarr.shape[2]])
#print(allarr.shape)
#print('mixing events')
evtarrs = []
for ev in range(nevents):
idx = np.random.randint(allarr.shape[0], size=nPU)
evt = allarr[idx]
evt = np.sum(evt, axis=0, keepdims=True)
#print(evt.shape)
evtarrs.append(evt)
evts = np.concatenate(evtarrs, axis=0)
#print('mixed '+str(evts.shape))
return evts
def readFromRootFile(self, filename, TupleMeanStd, weighter):
# this function defines how to convert the root ntuple to the training format
# options are not yet described here
import ROOT
fileTimeOut(filename, 120) #give eos a minute to recover
rfile = ROOT.TFile(filename)
tree = rfile.Get(self.treename)
self.nsamples = tree.GetEntries()
# user code, example works with the example 2D images in root format generated by make_example_data
from DeepJetCore.preprocessing import readListArray
feature_array, n_rechits_cut = readListArray(
filename,
self.treename,
self.feat_branch,
self.nsamples,
list_size=self.max_rechits,
n_feat_per_element=self.n_features,
zeropad=True,
list_size_cut=True)
energy_only = feature_array[:, :, 0:1] #keep dimension
fraction_array, _ = readListArray(
filename,
self.treename,
self.truth_branch,
self.nsamples,
list_size=self.max_rechits,
n_feat_per_element=self.
n_simcluster, #nsimcluster, right now just one, but zero-padded here
zeropad=True,
list_size_cut=True)
print('TrainData_hitlistX: ', filename,
';convert from root: fraction of hits cut ',
100. * float(n_rechits_cut) / float(self.nsamples), '%')
#needs the energy, too to determine weights
fraction_array = numpy.concatenate([fraction_array, energy_only],
axis=-1)
#in case something was removed here
if n_rechits_cut > 0:
feature_array = feature_array[0:self.nsamples - n_rechits_cut]
fraction_array = fraction_array[0:self.nsamples - n_rechits_cut]
self.nsamples = len(feature_array)
self.x = [feature_array]
self.y = [
fraction_array
] # we need the features also in the truth part for weighting
self.w = [] # no event weights
def fileIsValid(self, filename):
try:
fileTimeOut(filename, 2)
tree = uproot.open(filename)["WindowNTupler/tree"]
f = ROOT.TFile.Open(filename)
t = f.Get("WindowNTupler/tree")
if t.GetEntries() < 1:
raise ValueError("")
except Exception as e:
print(e)
return False
return True
def convertFromSourceFile(self, filename, weighterobjects, istraining):
from DeepJetCore.preprocessing import MeanNormApply, MeanNormZeroPad, MeanNormZeroPadParticles
import numpy
from DeepJetCore.stopwatch import stopwatch
sw=stopwatch()
swall=stopwatch()
import ROOT
fileTimeOut(filename,120) #give eos a minute to recover
rfile = ROOT.TFile(filename)
tree = rfile.Get("deepntuplizer/tree")
self.nsamples=tree.GetEntries()
print('took ', sw.getAndReset(), ' seconds for getting tree entries')
# split for convolutional network
x_global = MeanNormZeroPad(filename,None,
[self.branches[0]],
[self.branchcutoffs[0]],self.nsamples)
x_cpf = MeanNormZeroPadParticles(filename,None,
self.branches[1],
self.branchcutoffs[1],self.nsamples)
x_npf = MeanNormZeroPadParticles(filename,None,
self.branches[2],
self.branchcutoffs[2],self.nsamples)
x_sv = MeanNormZeroPadParticles(filename,None,
self.branches[3],
self.branchcutoffs[3],self.nsamples)
print('took ', sw.getAndReset(), ' seconds for mean norm and zero padding (C module)')
Tuple = self.readTreeFromRootToTuple(filename)
truthtuple = Tuple[self.truthclasses]
#print(self.truthclasses)
alltruth=self.reduceTruth(truthtuple)
print(x_global.shape,self.nsamples)
return [x_global,x_cpf,x_npf,x_sv], [alltruth], []
def readFromRootFile(self, filename, TupleMeanStd, weighter):
# this function defines how to convert the root ntuple to the training format
# options are not yet described here
fileTimeOut(filename, 120)
uproot_tree = uproot.open(filename)['clusters']
cluster_pt = uproot_tree.array('cluster_pt')
pt_filter = cluster_pt > 5.
n_cell = uproot_tree.array('n_cell')
def to_ndarray(*args):
return np.stack(args, axis=-1)
branches = ['cell_energy', 'cell_theta', 'cell_phi', 'cell_z']
print("reading feature array")
feature_array = uproot_tree.arrays(branches, outputtype=to_ndarray)
print(feature_array.shape)
print("reading truth")
#truth = self.read_truthclasses(filename)
truth = uproot_tree.arrays(self.truthclasses, outputtype=to_ndarray)
egamma = truth[..., 0:1] + truth[..., 2:3]
muon = truth[..., 1:2]
pi0 = truth[..., 3:4]
hadron = truth[..., 4:5] + truth[..., 5:6]
truth = np.concatenate((egamma, muon, pi0, hadron), axis=-1)
print("creating remove indxs")
Tuple = self.readTreeFromRootToTuple(filename)
notremoves = weighter.createNotRemoveIndices(Tuple)
notremoves += pt_filter
# this removes parts of the dataset for weighting the events
if self.remove:
feature_array = feature_array[notremoves > 0]
n_cell = n_cell[notremoves > 0]
truth = truth[notremoves > 0]
# call this in the end
self.nsamples = len(feature_array)
self.x = [feature_array, n_cell] # list of feature numpy arrays
self.y = [truth] # list of target numpy arrays (truth)
self.w = [] # list of weight arrays. One for each truth target
def convertFromSourceFile(self, filename, weighterobjects, istraining):
# This is the only really mandatory function (unless writeFromSourceFile is defined).
# It defines the conversion rule from an input source file to the lists of training
# arrays self.x, self.y, self.w
# self.x is a list of input feature arrays
# self.y is a list of truth arrays
# self.w is optional and can contain a weight array
# (needs to have same number of entries as truth array)
# If no weights are needed, this can be left completely empty
#
# The conversion should convert finally to numpy arrays. In the future,
# also tensorflow tensors will be supported.
#
# In this example, differnt ways of reading files are deliberatly mixed
#
print('reading ' + filename)
import ROOT
fileTimeOut(filename, 120) #give eos a minute to recover
rfile = ROOT.TFile(filename)
tree = rfile.Get("tree")
nsamples = tree.GetEntries()
# user code, example works with the example 2D images in root format generated by make_example_data
from DeepJetCore.preprocessing import read2DArray
feature_array = read2DArray(filename, "tree", "image2d", nsamples, 32,
32)
print('feature_array', feature_array.shape)
import uproot
urfile = uproot.open(filename)["tree"]
truth = np.concatenate([
np.expand_dims(urfile.array("isA"), axis=1),
np.expand_dims(urfile.array("isB"), axis=1),
np.expand_dims(urfile.array("isC"), axis=1)
],
axis=1)
truth = truth.astype(dtype='float32',
order='C') #important, float32 and C-type!
self.nsamples = len(feature_array)
#returns a list of feature arrays, a list of truth arrays and a list of weight arrays
return [feature_array], [truth], []
def fileIsValid(self, filename):
#uproot does not raise exceptions early enough for testing
import ROOT
try:
fileTimeOut(filename, 2)
tree = uproot.open(filename)["Events"]
f=ROOT.TFile.Open(filename)
t=f.Get("Events")
if t.GetEntries() < 1:
raise ValueError("")
except Exception as e:
print('problem with file',filename)
print(e)
return False
return True
def createWeighterObjects(self, allsourcefiles):
#
# Calculates the weights needed for flattening the pt/eta spectrum
from DeepJetCore.Weighter import Weighter
weighter = Weighter()
weighter.undefTruth = self.undefTruth
branches = [self.weightbranchX, self.weightbranchY]
branches.extend(self.truth_branches)
if self.remove:
weighter.setBinningAndClasses([self.weight_binX, self.weight_binY],
self.weightbranchX,
self.weightbranchY,
self.truth_branches)
counter = 0
import ROOT
from root_numpy import tree2array, root2array
if self.remove:
for fname in allsourcefiles:
fileTimeOut(fname, 120)
nparray = root2array(fname,
treename="deepntuplizer/tree",
stop=None,
branches=branches)
weighter.addDistributions(nparray)
#del nparray
counter = counter + 1
weighter.createRemoveProbabilitiesAndWeights(self.referenceclass)
print("calculate means")
from DeepJetCore.preprocessing import meanNormProd
nparray = self.readTreeFromRootToTuple(
allsourcefiles,
branches=self.vtx_branches + self.eta_rel_branches +
self.track_branches + self.global_branches,
limit=500000)
for a in (self.vtx_branches + self.eta_rel_branches +
self.track_branches + self.global_branches):
for b in range(len(nparray[a])):
nparray[a][b] = np.where(nparray[a][b] < 100000.0,
nparray[a][b], 0)
means = np.array([], dtype='float32')
if len(nparray):
means = meanNormProd(nparray)
return {'weigther': weighter, 'means': means}
def convertFromSourceFile(self, filename, weighterobjects, istraining, treename="SLCIOConverted"):
fileTimeOut(filename, 10)#10 seconds for eos to recover
tree = uproot.open(filename)[treename]
nevents = tree.numentries
selection=None
hit_energy , rs = self.branchToFlatArray(tree["energy"], True,selection)
hit_x = self.branchToFlatArray(tree["positionX"], False,selection)
hit_y = self.branchToFlatArray(tree["positionY"], False,selection)
hit_z = self.branchToFlatArray(tree["positionZ"], False,selection)
hit_ass_truth_idx = self.branchToFlatArray(tree["maxE_particle_index"], False,selection)
hit_ass_truth_energy = self.branchToFlatArray(tree["maxE_particle_energy"], False,selection)
#not used right now
hit_ass_truth_pX = self.branchToFlatArray(tree["maxE_particle_pX"], False,selection)
hit_ass_truth_pY = self.branchToFlatArray(tree["maxE_particle_pY"], False,selection)
hit_ass_truth_pZ = self.branchToFlatArray(tree["maxE_particle_pZ"], False,selection)
features = np.concatenate([
hit_energy,
hit_x ,
hit_y,
hit_z
], axis=-1)
farr = SimpleArray(features,rs,name="features")
t_idxarr = SimpleArray(hit_ass_truth_idx,rs,name="t_idx")
t_energyarr = SimpleArray(hit_ass_truth_energy,rs,name="t_energy")
zeros = np.zeros_like(hit_ass_truth_energy)
#just for compatibility
t_posarr = SimpleArray(zeros,rs,name="t_pos")
t_time = SimpleArray(zeros,rs,name="t_time")
t_pid = SimpleArray(zeros,rs,name="t_pid") #this would need some massaging so we can't use the PID directly
t_spectator = SimpleArray(zeros,rs,name="t_spectator")
t_fully_contained = SimpleArray(zeros,rs,name="t_fully_contained")
t_rest = SimpleArray(zeros,rs,name="t_rest") #breaks with old plotting but needs to be done at some point
return [farr, t_idxarr, t_energyarr, t_posarr, t_time, t_pid, t_spectator, t_fully_contained],[t_rest], []
def readTreeFromRootToTuple(self, filenames, limit=None, branches=None):
'''
To be used to get the initial tupel for further processing in inherting classes
Makes sure the number of entries is properly set
can also read a list of files (e.g. to produce weights/removes from larger statistics
(not fully tested, yet)
'''
if branches is None or len(branches) == 0:
return np.array([], dtype='float32')
#print(branches)
#remove duplicates
usebranches = list(set(branches))
tmpbb = []
for b in usebranches:
if len(b):
tmpbb.append(b)
usebranches = tmpbb
import ROOT
from root_numpy import tree2array, root2array
if isinstance(filenames, list):
for f in filenames:
fileTimeOut(f, 120)
print('add files')
print('debugging this')
print("Branches:\n{}".format(usebranches))
import uproot as ur
import awkward as ak
# this was substituted from the old root2array function
nparray = uproot_root2array(filenames,
treename="ttree",
stop=limit,
branches=usebranches)
print('done add files')
return nparray
else:
fileTimeOut(filenames, 120) #give eos a minute to recover
rfile = ROOT.TFile(filenames)
tree = rfile.Get(self.treename)
if not self.nsamples:
self.nsamples = tree.GetEntries()
nparray = tree2array(tree, stop=limit, branches=usebranches)
return nparray
def readFromRootFile(self,filename,TupleMeanStd, weighter):
# this function defines how to convert the root ntuple to the training format
# options are not yet described here
import ROOT
fileTimeOut(filename,120) #give eos a minute to recover
rfile = ROOT.TFile(filename)
tree = rfile.Get(self.treename)
self.nsamples=tree.GetEntries()
max_rechits = 40000
# user code, example works with the example 2D images in root format generated by make_example_data
from DeepJetCore.preprocessing import readListArray
feature_array = readListArray(filename,
self.treename,
"rechit_features",
self.nsamples,
list_size=max_rechits,
n_feat_per_element=7,
zeropad=True)
energy_only = feature_array[:,:,0:1]#keep dimension
fraction_array = readListArray(filename,
self.treename,
"simcluster_fractions",
self.nsamples,
list_size=max_rechits,
n_feat_per_element=7,#nsimcluster, right now just one, but zero-padded here
zeropad=True)
#needs the energy, too to determine weights
fraction_array = numpy.concatenate([fraction_array,energy_only],axis=-1)
#in case something was removed here
self.nsamples=len(feature_array)
self.x=[feature_array]
self.y=[fraction_array] # we need the features also in the truth part for weighting
self.w=[] # no event weights
def convertFromSourceFile(self, filename, weighterobjects, istraining):
from DeepJetCore.preprocessing import MeanNormApply, MeanNormZeroPad, MeanNormZeroPadParticles
import numpy
from DeepJetCore.stopwatch import stopwatch
sw = stopwatch()
swall = stopwatch()
import ROOT
fileTimeOut(filename, 120) #give eos a minute to recover
rfile = ROOT.TFile(filename)
tree = rfile.Get("deepntuplizer/tree")
self.nsamples = tree.GetEntries()
print('took ', sw.getAndReset(), ' seconds for getting tree entries')
# split for convolutional network
x_global = MeanNormZeroPad(filename, None, ['x'], [1], self.nsamples)
print('took ', sw.getAndReset(),
' seconds for mean norm and zero padding (C module)')
Tuple = self.readTreeFromRootToTuple(
filename, branches=['class1', 'class2', 'x'])
truthtuple = Tuple[self.truthclasses]
alltruth = self.reduceTruth(truthtuple)
#print(x_global.shape,x_global[0:10])
#print(alltruth.shape,alltruth[0:10])
#print(alltruth.flags)
newnsamp = x_global.shape[0]
self.nsamples = newnsamp
print(x_global.shape, alltruth.shape, self.nsamples)
truth = SimpleArray(alltruth, name="truth")
feat = SimpleArray(x_global, name="features0")
return [feat], [truth], []
def readFromRootFile(self,filename,TupleMeanStd, weighter):
# this function defines how to convert the root ntuple to the training format
# options are not yet described here
import numpy as np
import ROOT
fileTimeOut(filename,120) #give eos a minute to recover
rfile = ROOT.TFile(filename)
tree = rfile.Get("tree")
self.nsamples=tree.GetEntries()
# user code, example works with the example 2D images in root format generated by make_example_data
from DeepJetCore.preprocessing import read2DArray,readListArray
print(filename)
feature_image = read2DArray(filename,"tree","image2d",self.nsamples,24,24)
npy_array = self.readTreeFromRootToTuple(filename)
scale = np.expand_dims(npy_array['scale'],axis=1)
xcenter = np.expand_dims(npy_array['xcenter'],axis=1)
ycenter = np.expand_dims(npy_array['ycenter'],axis=1)
ptype = np.expand_dims(npy_array['type'],axis=1)
print('ycenter',ycenter.shape)
add_features = np.concatenate([scale,xcenter,ycenter,ptype],axis=1)
xcoords = numpy.expand_dims( numpy.array(list(npy_array['xcoords']),dtype='float32'), axis=2)
ycoords = numpy.expand_dims( numpy.array(list(npy_array['ycoords']),dtype='float32'), axis=2)
xcoords = numpy.reshape(xcoords, newshape=[xcoords.shape[0],24,24,1])
ycoords = numpy.reshape(ycoords, newshape=[xcoords.shape[0],24,24,1])
print('xcoords',xcoords.shape)
all_coords = numpy.concatenate([xcoords,ycoords],axis=-1)
#readListArray(filename,"tree","frac_at_idxs",self.nsamples,4,1)
alltruth = numpy.zeros(self.nsamples)+1. #this is real data
self.x = [feature_image,all_coords,add_features]
self.y = [alltruth]
self.w=[]
def readFromRootFile(self, filename, TupleMeanStd, weighter):
# this function defines how to convert the root ntuple to the training format
# options are not yet described here
fileTimeOut(filename, 120)
uproot_tree = uproot.open(filename)['clusters']
def to_ndarray(*args):
return numpy.squeeze(numpy.dstack(args))
branches_template = [
'bin_eta', 'bin_theta', 'bin_phi', 'bin_x', 'bin_y',
'bin_eta_global', 'bin_theta_global', 'bin_phi_global',
'bin_dist_global', 'bin_x_global', 'bin_y_global', 'bin_z_global',
'bin_energy', 'bin_layer'
]
branches = []
for icell in range(2):
branches.extend([b + ('_%d' % icell) for b in branches_template])
feature_array = uproot_tree.arrays(branches, outputtype=to_ndarray)
feature_array = numpy.reshape(feature_array, (-1, 5, 5, 38, 28))
print("reading truth")
truth = uproot_tree.arrays(self.truthclasses, outputtype=to_ndarray)
Tuple = self.readTreeFromRootToTuple(filename)
print("creating remove indxs")
notremoves = weighter.createNotRemoveIndices(Tuple)
# this removes parts of the dataset for weighting the events
if self.remove:
feature_array = feature_array[notremoves > 0]
truth = truth[notremoves > 0]
# call this in the end
self.nsamples = len(feature_array)
self.x = [feature_array] # list of feature numpy arrays
self.y = [truth] # list of target numpy arrays (truth)
self.w = [] # list of weight arrays. One for each truth target
def readFromRootFile(self, filename, TupleMeanStd, weighter):
# this function defines how to convert the root ntuple to the training format
# options are not yet described here
from DeepJetCore.preprocessing import MeanNormApply, MeanNormZeroPad, MeanNormZeroPadParticles
import ROOT
fileTimeOut(filename, 120) #give eos a minute to recover
rfile = ROOT.TFile(filename)
tree = rfile.Get("tree")
self.nsamples = tree.GetEntries()
npy_array = self.readTreeFromRootToTuple(filename)
truthtuple = npy_array[self.truthclasses]
alltruth = self.reduceTruth(truthtuple)
alltruept = npy_array[self.regtruth]
# user code
x_global = MeanNormZeroPad(filename, None, [self.branches[0]],
[self.branchcutoffs[0]], self.nsamples)
x_cpf = MeanNormZeroPadParticles(filename, None, self.branches[1],
self.branchcutoffs[1], self.nsamples)
x_npf = MeanNormZeroPadParticles(filename, None, self.branches[2],
self.branchcutoffs[2], self.nsamples)
x_recopts = MeanNormZeroPad(filename, None, [self.branches[3]],
[self.branchcutoffs[3]], self.nsamples)
nold = self.nsamples
self.x = [x_global, x_cpf, x_npf,
x_recopts] # list of feature numpy arrays
self.y = [alltruth, alltruept] # list of target numpy arrays (truth)
self.w = [] # list of weight arrays. One for each truth target
self._normalize_input_(weighter, npy_array)
print('reduced to ', self.nsamples, 'of', nold)
def readFromRootFile(self, filename, TupleMeanStd, weighter):
from DeepJetCore.preprocessing import MeanNormApply, MeanNormZeroPad, MeanNormZeroPadParticles
import numpy
from DeepJetCore.stopwatch import stopwatch
sw = stopwatch()
swall = stopwatch()
import ROOT
fileTimeOut(filename, 120) #give eos a minute to recover
rfile = ROOT.TFile(filename)
tree = rfile.Get("deepntuplizer/tree")
self.nsamples = tree.GetEntries()
print('took ', sw.getAndReset(), ' seconds for getting tree entries')
# split for convolutional network
x_global = MeanNormZeroPad(filename, None, [self.branches[0]],
[self.branchcutoffs[0]], self.nsamples)
print('took ', sw.getAndReset(),
' seconds for mean norm and zero padding (C module)')
Tuple = self.readTreeFromRootToTuple(filename)
truthtuple = Tuple[self.truthclasses]
alltruth = self.reduceTruth(truthtuple)
newnsamp = x_global.shape[0]
print('reduced content to ',
int(float(newnsamp) / float(self.nsamples) * 100), '%')
self.nsamples = newnsamp
print(x_global.shape, self.nsamples)
self.w = []
self.x = [x_global]
self.y = [alltruth]
def createWeighterObjects(self, allsourcefiles):
#
# Calculates the weights needed for flattening the pt/eta spectrum
from DeepJetCore.Weighter import Weighter
weighter = Weighter()
weighter.undefTruth = self.undefTruth
weighter.class_weights = self.class_weights
branches = [self.weightbranchX, self.weightbranchY]
branches.extend(self.truth_branches)
if self.remove:
weighter.setBinningAndClasses([self.weight_binX, self.weight_binY],
self.weightbranchX,
self.weightbranchY,
self.truth_branches,
self.red_classes,
self.truth_red_fusion,
method=self.referenceclass)
counter = 0
import ROOT
from root_numpy import tree2array, root2array
if self.remove:
for fname in allsourcefiles:
fileTimeOut(fname, 120)
nparray = root2array(fname,
treename="deepntuplizer/tree",
stop=None,
branches=branches)
norm_hist = True
if self.referenceclass == 'flatten':
norm_hist = False
weighter.addDistributions(nparray, norm_h=norm_hist)
#del nparray
counter = counter + 1
weighter.createRemoveProbabilitiesAndWeights(self.referenceclass)
#weighter.printHistos('/afs/cern.ch/user/a/ademoor/Flatten/') #If you need to print the 2D histo, choose your output dir
return {'weigther': weighter}
def readFromRootFile(self, filename, TupleMeanStd, weighter):
#the first part is standard, no changes needed
from DeepJetCore.preprocessing import MeanNormApply, MeanNormZeroPad, MeanNormZeroPadParticles, ZeroPadParticles
import numpy
import ROOT
fileTimeOut(filename, 120) #give eos 2 minutes to recover
rfile = ROOT.TFile(filename)
tree = rfile.Get("deepntuplizer/tree")
self.nsamples = tree.GetEntries()
#the definition of what to do with the branches
# those are the global branches (jet pt etc)
# they should be just glued to each other in one vector
# and zero padded (and mean subtracted and normalised)
#x_global = MeanNormZeroPad(filename,TupleMeanStd,
# [self.branches[0]],
# [self.branchcutoffs[0]],self.nsamples)
# the second part (the pf candidates) should be treated particle wise
# an array with (njets, nparticles, nproperties) is created
x_glb = ZeroPadParticles(filename, TupleMeanStd, self.branches[0],
self.branchcutoffs[0], self.nsamples)
x_db = MeanNormZeroPadParticles(filename, TupleMeanStd,
self.branches[1],
self.branchcutoffs[1], self.nsamples)
x_db_raw = ZeroPadParticles(filename, TupleMeanStd, self.branches[1],
self.branchcutoffs[1], self.nsamples)
x_cpf = MeanNormZeroPadParticles(filename, TupleMeanStd,
self.branches[2],
self.branchcutoffs[2], self.nsamples)
x_sv = MeanNormZeroPadParticles(filename, TupleMeanStd,
self.branches[3],
self.branchcutoffs[3], self.nsamples)
# now, some jets are removed to avoid pt and eta biases
Tuple = self.readTreeFromRootToTuple(filename)
if self.remove:
# jets are removed until the shapes in eta and pt are the same as
# the truth class 'fj_isNonBB'
notremoves = weighter.createNotRemoveIndices(Tuple)
#undef=Tuple[self.undefTruth]
#notremoves-=undef
if self.weight:
weights = weighter.getJetWeights(Tuple)
elif self.remove:
weights = notremoves #weighter.createNotRemoveIndices(Tuple)
else:
print('neither remove nor weight')
weights = numpy.empty(self.nsamples)
weights.fill(1.)
truthtuple = Tuple[self.truthclasses]
alltruth = self.reduceTruth(Tuple)
undef = numpy.sum(alltruth, axis=1)
if self.weight or self.remove:
print('Training samples, remove undefined')
weights = weights[undef > 0]
x_glb = x_glb[undef > 0]
x_db = x_db[undef > 0]
x_db_raw = x_db_raw[undef > 0]
x_sv = x_sv[undef > 0]
x_cpf = x_cpf[undef > 0]
alltruth = alltruth[undef > 0]
if self.remove:
print('Removing to match weighting')
notremoves = notremoves[undef > 0]
weights = weights[notremoves > 0]
x_glb = x_glb[notremoves > 0]
x_db = x_db[notremoves > 0]
x_db_raw = x_db_raw[notremoves > 0]
x_sv = x_sv[notremoves > 0]
x_cpf = x_cpf[notremoves > 0]
alltruth = alltruth[notremoves > 0]
if self.weight:
print('Adding weights, removing events with 0 weight')
x_glb = x_glb[weights > 0]
x_db = x_db[weights > 0]
x_db_raw = x_db_raw[weights > 0]
x_sv = x_sv[weights > 0]
x_cpf = x_cpf[weights > 0]
alltruth = alltruth[weights > 0]
# Weights get adjusted last so they can be used as an index
weights = weights[weights > 0]
newnsamp = x_glb.shape[0]
print('Keeping {}% of input events in the training dataCollection'.
format(int(float(newnsamp) / float(self.nsamples) * 100)))
self.nsamples = newnsamp
#print("Subsample composition:")
#for lab in ['fJ_isQCD', 'fj_isH', 'fj_isCC', 'fj_isBB']:
# print(numpy.sum((Tuple[lab].view(numpy.ndarray))), lab)
#for lab, stat in zip(self.reducedtruthclasses, stats):
# print(lab, ': {}%'.format(stat))
# fill everything
self.w = [weights]
self.x = [x_db, x_cpf, x_sv]
self.z = [x_glb, x_db_raw]
self.y = [alltruth]
def readFromRootFile(self, filename, TupleMeanStd, weighter):
#the first part is standard, no changes needed
from DeepJetCore.preprocessing import MeanNormApply, MeanNormZeroPad, MeanNormZeroPadParticles, ZeroPadParticles
import numpy
import ROOT
fileTimeOut(filename, 120) #give eos 2 minutes to recover
rfile = ROOT.TFile(filename)
tree = rfile.Get("deepntuplizer/tree")
self.nsamples = tree.GetEntries()
x_glb = ZeroPadParticles(filename, TupleMeanStd, self.branches[0],
self.branchcutoffs[0], self.nsamples)
x_db = MeanNormZeroPadParticles(filename, TupleMeanStd,
self.branches[1],
self.branchcutoffs[1], self.nsamples)
# now, some jets are removed to avoid pt and eta biases
Tuple = self.readTreeFromRootToTuple(filename)
#if self.remove:
# jets are removed until the shapes in eta and pt are the same as
# the truth class 'fj_isNonBB'
notremoves = weighter.createNotRemoveIndices(Tuple)
if self.weight:
weights = weighter.getJetWeights(Tuple)
elif self.remove:
weights = notremoves
else:
print('neither remove nor weight')
weights = numpy.empty(self.nsamples)
weights.fill(1.)
# create all collections:
#truthtuple = Tuple[self.truthclasses]
alltruth = self.reduceTruth(Tuple)
undef = numpy.sum(alltruth, axis=1)
#weights=weights[undef > 0]
#x_glb=x_glb[undef > 0]
#x_db=x_db[undef > 0]
#alltruth=alltruth[undef > 0]
notremoves = notremoves[undef > 0]
undef = Tuple['fj_isNonCC'] * Tuple['sample_isQCD'] * Tuple[
'fj_isQCD'] + Tuple['fj_isCC'] * Tuple['fj_isH']
# remove the entries to get same jet shapes
if self.remove:
print('remove')
weights = weights[notremoves > 0]
x_glb = x_glb[notremoves > 0]
x_db = x_db[notremoves > 0]
alltruth = alltruth[notremoves > 0]
newnsamp = x_glb.shape[0]
print('reduced content to ',
int(float(newnsamp) / float(self.nsamples) * 100), '%')
self.nsamples = newnsamp
# fill everything
self.w = [weights]
self.x = [x_db]
self.z = [x_glb]
self.y = [alltruth]
def convertFromSourceFile(self, filename, weighterobjects, istraining):
# This is the only really mandatory function (unless writeFromSourceFile is defined).
# It defines the conversion rule from an input source file to the lists of training
# arrays self.x, self.y, self.w
# self.x is a list of input feature arrays
# self.y is a list of truth arrays
# self.w is optional and can contain a weight array
# (needs to have same number of entries as truth array)
# If no weights are needed, this can be left completely empty
#
# The conversion should convert finally to numpy arrays. In the future,
# also tensorflow tensors will be supported.
#
# In this example, differnt ways of reading files are deliberatly mixed
#
print('reading ' + filename)
import ROOT
fileTimeOut(filename, 120) #give eos a minute to recover
rfile = ROOT.TFile(filename)
tree = rfile.Get("tree")
self.nsamples = tree.GetEntries()
# user code, example works with the example 2D images in root format generated by make_example_data
#from DeepJetCore.preprocessing import read2DArray
#feature_array = read2DArray(filename,"tree","image2d",self.nsamples,32,32)
#print('feature_array',feature_array.shape)
import uproot3 as uproot
urfile = uproot.open(filename)["tree"]
truth = np.concatenate([
np.expand_dims(urfile.array("lep_isPromptId_Training"), axis=1),
np.expand_dims(urfile.array("lep_isNonPromptId_Training"), axis=1),
np.expand_dims(urfile.array("lep_isFakeId_Training"), axis=1)
],
axis=1)
truth = truth.astype(dtype='float32',
order='C') #important, float32 and C-type!
self.global_branches = [
'lep_pt',
'lep_eta',
'lep_phi',
'lep_mediumId',
'lep_miniPFRelIso_all',
'lep_pfRelIso03_all',
'lep_sip3d',
'lep_dxy',
'lep_dz',
'lep_charge',
'lep_dxyErr',
'lep_dzErr',
'lep_ip3d',
'lep_jetPtRelv2',
'lep_jetRelIso',
'lep_miniPFRelIso_chg',
'lep_mvaLowPt',
'lep_nStations',
'lep_nTrackerLayers',
'lep_pfRelIso03_all',
'lep_pfRelIso03_chg',
'lep_pfRelIso04_all',
'lep_ptErr',
'lep_segmentComp',
'lep_tkRelIso',
'lep_tunepRelPt',
]
self.pfCand_neutral_branches = [
'pfCand_neutral_eta',
'pfCand_neutral_phi',
'pfCand_neutral_pt',
'pfCand_neutral_puppiWeight',
'pfCand_neutral_puppiWeightNoLep',
'pfCand_neutral_ptRel',
'pfCand_neutral_deltaR',
]
self.npfCand_neutral = 5
## works:
#x_global = np.concatenate([np.expand_dims(urfile.array(var), axis=1) for var in self.global_branches], axis=1)
#x_global = x_global.astype(dtype='float32', order='C') #important, float32 and C-type!
#self.nsamples=len(x_global)
from DeepJetCore.preprocessing import MeanNormZeroPad, MeanNormZeroPadParticles
x_global = MeanNormZeroPad(filename, None, [self.global_branches], [1],
self.nsamples)
x_pfCand_neutral = MeanNormZeroPadParticles(
filename, None, self.pfCand_neutral_branches, self.npfCand_neutral,
self.nsamples)
x_global = x_global.astype(dtype='float32', order='C')
x_pfCand_neutral = x_pfCand_neutral.astype(dtype='float32', order='C')
#returns a list of feature arrays, a list of truth arrays and a list of weight arrays
return [x_global, x_pfCand_neutral], [truth], []
def _convertFromSourceFile(self, filename, weighterobjects, istraining):
fileTimeOut(filename, 10) #10 seconds for eos to recover
tree = uproot.open(filename)["B4"]
nevents = tree.numentries
#truth
isElectron = self.tonumpy(tree["isElectron"].array())
isGamma = self.tonumpy(tree["isGamma"].array())
isPositron = self.tonumpy(tree["isPositron"].array())
true_energy = self.tonumpy(tree["true_energy"].array())
true_x = self.tonumpy(tree["true_x"].array())
true_y = self.tonumpy(tree["true_y"].array())
rechit_energy = self.tonumpy(tree["rechit_energy"].array())
rechit_x = self.tonumpy(tree["rechit_x"].array())
rechit_y = self.tonumpy(tree["rechit_y"].array())
rechit_z = self.tonumpy(tree["rechit_z"].array())
rechit_layer = self.tonumpy(tree["rechit_layer"].array())
rechit_detid = self.tonumpy(tree['rechit_detid'].array())
#print('rechit_energy',rechit_energy,rechit_energy.shape)
#print(rechit_detid)
#for ...
feat, truth, layers, npart_arr, truth_en = self.mergeShowers(
isElectron,
isGamma,
isPositron,
true_energy,
true_x,
true_y,
rechit_energy,
rechit_x,
rechit_y,
rechit_z,
rechit_layer,
rechit_detid,
maxpart=self.npart,
istraining=istraining)
print('feat', feat.shape)
calo, track = self.separateLayers(feat, layers)
calo = np.reshape(calo, [truth.shape[0], 16, 16, -1])
track = np.reshape(track, [truth.shape[0], 64, 64, -1])
#print(calo[0,:,:,1:3])
#this needs to be rebinned in x and y
#calosort = np.argsort(calo[:,:,1]*100+calo[:,:,2], axis=-1)
#calo = calo[calosort]
#calo = np.reshape(calo, [truth.shape[0],16,16,-1])
debug = False
if debug:
import matplotlib.pyplot as plt
calotruth = truth[:, 0:16 * 16, :]
calotruth = np.reshape(calotruth, [truth.shape[0], 16, 16, -1])
tracktruth = truth[:, 16 * 16:, :]
tracktruth = np.reshape(tracktruth, [truth.shape[0], 64, 64, -1])
for event in range(10):
#print truth index and rec energy
fig, ax = plt.subplots(1, 1)
ax.imshow(calotruth[event, :, :, 6], aspect=1)
fig.savefig("calo_idx" + str(event) + ".pdf")
ax.imshow(calo[event, :, :, 0], aspect=1)
fig.savefig("calo_en" + str(event) + ".pdf")
ax.imshow(calotruth[event, :, :, 0], aspect=1)
fig.savefig("calo_tmask" + str(event) + ".pdf")
ax.imshow(tracktruth[event, :, :, 6], aspect=1)
fig.savefig("tracktruth_idx" + str(event) + ".pdf")
ax.imshow(track[event, :, :, 0], aspect=1)
fig.savefig("track_en" + str(event) + ".pdf")
ax.imshow(tracktruth[event, :, :, 0], aspect=1)
fig.savefig("tracktruth_tmask" + str(event) + ".pdf")
print('calo', calo.shape)
print('track', track.shape)
print('truth', truth.shape)
#np.set_printoptions(threshold=10*1280)
#print('calo',calo[0])
#print('track',track[0])
if hasattr(self, "truth_en"):
self.truth_en = truth_en
return [calo, track], [truth], [
] #[tracker0, tracker1, tracker2, tracker3, calo] , [trutharray], []
def base_convertFromSourceFile(self,
filename,
weighterobjects,
istraining,
treename="Events",
removeTracks=True):
fileTimeOut(filename, 10) #10 seconds for eos to recover
tree = uproot.open(filename)[treename]
hits = "RecHitHGC"
front_face_z = 323 #this needs to be more precise
recHitZUnsplit = self.hitObservable(tree,
hits,
"z",
split=False,
flatten=False)
self.setSplitIdx(recHitZUnsplit < 0)
recHitZ = self.splitJaggedArray(recHitZUnsplit)
offsets = recHitZ.offsets
recHitX = self.hitObservable(tree,
hits,
"x",
split=True,
flatten=False)
recHitY = self.hitObservable(tree,
hits,
"y",
split=True,
flatten=False)
recHitSimClusIdx = self.hitObservable(tree,
hits,
"BestMergedSimClusterIdx",
split=True,
flatten=False)
#Define spectators
recHit_df_events = [
pd.DataFrame({
"recHitX": recHitX[i],
"recHitY": recHitY[i],
"recHitZ": recHitZ[i],
"recHitSimClusIdx": recHitSimClusIdx[i]
}) for i in range(recHitX.shape[0])
]
for ievent in range(len(recHit_df_events)):
df_event = recHit_df_events[ievent]
unique_shower_idx = np.unique(df_event['recHitSimClusIdx'])
df_event['spectator_distance'] = 0 #
df_event['recHitSimClus_nHits'] = df_event.groupby(
'recHitSimClusIdx'
).recHitX.transform(
len
) #adding number of rec hits that are associated to this truth cluster
for idx in unique_shower_idx:
df_shower = df_event[df_event['recHitSimClusIdx'] == idx]
x_to_fit = df_shower[['recHitX', 'recHitY',
'recHitZ']].to_numpy()
spectators_shower_dist = find_pcas(x_to_fit,
PCA_n=2,
min_hits=10)
if (spectators_shower_dist is not None):
spectators_idx = (df_shower.index.tolist())
df_event.loc[spectators_idx,
'spectator_distance'] = spectators_shower_dist
del df_shower
del df_event
#Expand back
recHitX = np.expand_dims(recHitX.content, axis=1)
recHitY = np.expand_dims(recHitY.content, axis=1)
recHitZ = np.expand_dims(recHitZ.content, axis=1)
recHitSpectatorFlag = np.concatenate(
np.array([
recHit_df_events[i]['spectator_distance'].to_numpy()
for i in range(len(recHit_df_events))
],
dtype=object)).reshape(-1, 1)
recHitSimClusterNumHits = np.concatenate(
np.array([
recHit_df_events[i]['recHitSimClus_nHits'].to_numpy()
for i in range(len(recHit_df_events))
],
dtype=object)).reshape(-1, 1) #number of rec hits
del recHit_df_events
recHitEnergy = self.hitObservable(tree, hits, "energy")
recHitDetaId = self.hitObservable(tree, hits, "detId")
recHitTime = self.hitObservable(tree, hits, "time")
recHitR = np.sqrt(recHitX * recHitX + recHitY * recHitY +
recHitZ * recHitZ)
recHitTheta = np.arccos(recHitZ / recHitR)
recHitEta = -np.log(np.tan(recHitTheta / 2))
# Don't split this until the end, so it can be used to index the truth arrays
recHitSimClusIdx = self.hitObservable(tree,
hits,
"BestMergedSimClusterIdx",
split=False,
flatten=False)
simClusterDepEnergy = tree["MergedSimCluster_recEnergy"].array()
simClusterEnergy = tree["MergedSimCluster_boundaryEnergy"].array()
simClusterEnergyNoMu = tree[
"MergedSimCluster_boundaryEnergyNoMu"].array()
simClusterNumHits = tree["MergedSimCluster_nHits"].array(
) #numebr of sim hits
# Remove muon energy, add back muon deposited energy
unmergedId = tree["SimCluster_pdgId"].array()
unmergedDepE = tree["SimCluster_recEnergy"].array()
unmergedMatchIdx = tree["MergedSimCluster_SimCluster_MatchIdx"].array()
unmergedMatches = tree["MergedSimCluster_SimClusterNumMatch"].array()
unmergedDepEMuOnly = unmergedDepE
unmergedDepEMuOnly[np.abs(unmergedId) != 13] = 0
# Add another layer of nesting, then sum over all unmerged associated to merged
unmergedDepEMuOnly = ak.JaggedArray.fromcounts(
unmergedMatches.counts,
ak.JaggedArray.fromcounts(
unmergedMatches.content,
unmergedDepEMuOnly[unmergedMatchIdx].flatten()))
depEMuOnly = unmergedDepEMuOnly.sum()
#why wasn't it possible to just do instead of all of the above : simClusterEnergy[simClusterPdgId == 13] = simClusterDepEnergy ?
simClusterEnergyMuCorr = simClusterEnergyNoMu + depEMuOnly
simClusterX = tree["MergedSimCluster_impactPoint_x"].array()
simClusterY = tree["MergedSimCluster_impactPoint_y"].array()
simClusterZ = tree["MergedSimCluster_impactPoint_z"].array()
simClusterTime = tree["MergedSimCluster_impactPoint_t"].array()
simClusterEta = tree["MergedSimCluster_impactPoint_eta"].array()
simClusterPhi = tree["MergedSimCluster_impactPoint_phi"].array()
simClusterPdgId = tree["MergedSimCluster_pdgId"].array()
# Mark simclusters outside of volume or with very few hits as noise
# Maybe not a good idea if the merged SC pdgId is screwed up
# Probably removing neutrons is a good idea though
#noNeutrons = simClusterPdgId[recHitSimClusIdx] == 2112
#filter non-boundary positions. Hopefully working?
goodSimClus = tree["MergedSimCluster_isTrainable"].array()
# Don't split by index here to keep same dimensions as SimClusIdx
markNoise = self.truthObjects(~goodSimClus,
recHitSimClusIdx,
False,
split=False,
flatten=False).astype(np.bool_)
nbefore = (recHitSimClusIdx < 0).sum().sum()
recHitSimClusIdx[markNoise] = -1
nafter = (recHitSimClusIdx < 0).sum().sum()
print("Number of noise hits before", nbefore, "after", nafter)
print('removed another factor of', nafter / nbefore,
' bad simclusters')
recHitTruthPID = self.truthObjects(simClusterPdgId, recHitSimClusIdx,
0.)
recHitTruthDepEnergy = self.truthObjects(simClusterDepEnergy,
recHitSimClusIdx, 0)
recHitTruthEnergy = self.truthObjects(simClusterEnergy,
recHitSimClusIdx, 0)
recHitTruthEnergyCorrMu = self.truthObjects(simClusterEnergyMuCorr,
recHitSimClusIdx, 0)
low_energy_shower_cutoff = 3
# Uncorrected currently not used
recHitTruthEnergy = np.where(
recHitTruthEnergy > low_energy_shower_cutoff, recHitTruthEnergy,
recHitTruthDepEnergy)
recHitTruthEnergy = np.where(
recHitTruthEnergyCorrMu > low_energy_shower_cutoff,
recHitTruthEnergyCorrMu, recHitTruthDepEnergy)
#very bad names because these quatities are associated to Merged Clusters and not hits
recHitTruthX = self.truthObjects(simClusterX, recHitSimClusIdx, 0)
recHitTruthY = self.truthObjects(simClusterY, recHitSimClusIdx, 0)
recHitTruthZ = self.truthObjects(simClusterZ, recHitSimClusIdx, 0)
recHitTruthTime = self.truthObjects(simClusterTime, recHitSimClusIdx,
0)
recHitTruthR = np.sqrt(recHitTruthX * recHitTruthX +
recHitTruthY * recHitTruthY +
recHitTruthZ * recHitTruthZ)
recHitTruthTheta = np.arccos(
np.divide(recHitTruthZ,
recHitTruthR,
out=np.zeros_like(recHitTruthZ),
where=recHitTruthR != 0))
recHitTruthPhi = self.truthObjects(simClusterPhi, recHitSimClusIdx, 0)
recHitTruthEta = self.truthObjects(simClusterEta, recHitSimClusIdx, 0)
#recHitAverageEnergy = self.truthObjects(simClusterDepEnergy/simClusterNumHits, recHitSimClusIdx, 0) #this is not technically very good because simClusterNumHits is number of sim clusters, not reco
recHitAverageEnergy = recHitTruthDepEnergy / recHitSimClusterNumHits
#print(recHitTruthPhi)
#print(np.max(recHitTruthPhi))
#print(np.min(recHitTruthPhi))
# Placeholder
zeroFeature = np.zeros(shape=(len(recHitEnergy), 1), dtype='float32')
features = np.concatenate(
[
recHitEnergy,
recHitEta,
zeroFeature, #indicator if it is track or not
recHitTheta,
recHitR,
recHitX,
recHitY,
recHitZ,
recHitTime,
],
axis=1)
farr = SimpleArray(name="recHitFeatures")
farr.createFromNumpy(features, offsets)
del features
recHitSimClusIdx = np.expand_dims(
self.splitJaggedArray(recHitSimClusIdx).content.astype(np.int32),
axis=1)
print('noise', (100 * np.count_nonzero(recHitSimClusIdx < 0)) //
recHitSimClusIdx.shape[0], '% of hits')
print('truth eta min max',
np.min(np.abs(recHitTruthEta[recHitSimClusIdx >= 0])),
np.max(np.abs(recHitTruthEta[recHitSimClusIdx >= 0])))
print(
'non-boundary truth positions',
np.count_nonzero(
np.abs(np.abs(recHitTruthZ[recHitSimClusIdx >= 0]) - 320) > 5)
/ recHitTruthZ[recHitSimClusIdx >= 0].shape[0])
#now all numpy
#Why do we want noise (-1) sim hits to be equal rec?
recHitTruthX[recHitSimClusIdx < 0] = recHitX[recHitSimClusIdx < 0]
recHitTruthY[recHitSimClusIdx < 0] = recHitY[recHitSimClusIdx < 0]
recHitTruthZ[recHitSimClusIdx < 0] = recHitZ[recHitSimClusIdx < 0]
recHitTruthEnergyCorrMu[recHitSimClusIdx < 0] = recHitEnergy[
recHitSimClusIdx < 0]
recHitTruthTime[recHitSimClusIdx < 0] = recHitTime[
recHitSimClusIdx < 0]
#import matplotlib.pyplot as plt
#plt.hist(np.abs(recHitTruthEnergyCorrMu[recHitSimClusIdx>=0]/recHitTruthDepEnergy[recHitSimClusIdx>=0]))
#plt.yscale('log')
#plt.savefig("scat.pdf")
truth = np.concatenate(
[
np.array(recHitSimClusIdx, dtype='float32'), # 0
recHitTruthEnergyCorrMu,
recHitTruthX,
recHitTruthY,
recHitTruthZ, #4
zeroFeature, #truthHitAssignedDirX,
zeroFeature, #6
zeroFeature,
recHitTruthEta,
recHitTruthPhi,
recHitTruthTime, #10
zeroFeature,
zeroFeature,
recHitTruthDepEnergy, #13
zeroFeature, #14
zeroFeature, #15
recHitTruthPID, #16 - 16+n_classes #won't be used anymore
np.array(recHitSpectatorFlag, dtype='float32'),
np.where(recHitTruthZ < front_face_z, 1., 0.).astype('float32')
],
axis=1)
t_idxarr = SimpleArray(recHitSimClusIdx,
offsets,
name="recHitTruthClusterIdx")
t_energyarr = SimpleArray(name="recHitTruthEnergy")
t_energyarr.createFromNumpy(recHitTruthEnergyCorrMu, offsets)
t_posarr = SimpleArray(name="recHitTruthPosition")
t_posarr.createFromNumpy(
np.concatenate([recHitTruthX, recHitTruthY], axis=-1), offsets)
t_time = SimpleArray(name="recHitTruthTime")
t_time.createFromNumpy(recHitTruthTime, offsets)
t_pid = SimpleArray(name="recHitTruthID")
t_pid.createFromNumpy(recHitTruthPID, offsets)
t_spectator = SimpleArray(
name="recHitSpectatorFlag"
) #why do we have inconsistent namings, where is it needed? wrt. to truth array
t_spectator.createFromNumpy(recHitSpectatorFlag.astype('float32'),
offsets)
t_fully_contained = SimpleArray(name="recHitFullyContainedFlag")
t_fully_contained.createFromNumpy(
np.where(recHitTruthZ < front_face_z, 1., 0.).astype('float32'),
offsets)
#remaining truth is mostly for consistency in the plotting tools
t_rest = SimpleArray(name="recHitTruth")
t_rest.createFromNumpy(truth, offsets)
return [
farr, t_idxarr, t_energyarr, t_posarr, t_time, t_pid, t_spectator,
t_fully_contained
], [t_rest], []
def convertFromSourceFile(self, filename, weighterobjects, istraining):
# Function to produce the numpy training arrays from root files
from DeepJetCore.Weighter import Weighter
from DeepJetCore.stopwatch import stopwatch
sw = stopwatch()
swall = stopwatch()
if not istraining:
self.remove = False
def reduceTruth(uproot_arrays):
b = uproot_arrays[b'isB']
bb = uproot_arrays[b'isBB']
gbb = uproot_arrays[b'isGBB']
bl = uproot_arrays[b'isLeptonicB']
blc = uproot_arrays[b'isLeptonicB_C']
lepb = bl + blc
c = uproot_arrays[b'isC']
cc = uproot_arrays[b'isCC']
gcc = uproot_arrays[b'isGCC']
ud = uproot_arrays[b'isUD']
s = uproot_arrays[b'isS']
uds = ud + s
g = uproot_arrays[b'isG']
return np.vstack(
(b + lepb, bb + gbb, c + cc + gcc, uds + g)).transpose()
print('reading ' + filename)
import ROOT
from root_numpy import tree2array, root2array
fileTimeOut(filename, 120) #give eos a minute to recover
rfile = ROOT.TFile(filename)
tree = rfile.Get("deepntuplizer/tree")
self.nsamples = tree.GetEntries()
# user code, example works with the example 2D images in root format generated by make_example_data
from DeepJetCore.preprocessing import MeanNormZeroPad, MeanNormZeroPadParticles
x_global = MeanNormZeroPad(filename, weighterobjects['means'], [
self.global_branches, self.track_branches, self.eta_rel_branches,
self.vtx_branches
], [1, self.n_track, self.n_eta_rel, self.n_vtx], self.nsamples)
import uproot3 as uproot
urfile = uproot.open(filename)["deepntuplizer/tree"]
truth_arrays = urfile.arrays(self.truth_branches)
truth = reduceTruth(truth_arrays)
truth = truth.astype(dtype='float32',
order='C') #important, float32 and C-type!
x_global = x_global.astype(dtype='float32', order='C')
if self.remove:
b = [self.weightbranchX, self.weightbranchY]
b.extend(self.truth_branches)
b.extend(self.undefTruth)
fileTimeOut(filename, 120)
for_remove = root2array(filename,
treename="deepntuplizer/tree",
stop=None,
branches=b)
notremoves = weighterobjects['weigther'].createNotRemoveIndices(
for_remove)
undef = for_remove['isUndefined']
notremoves -= undef
print('took ', sw.getAndReset(), ' to create remove indices')
if self.remove:
print('remove')
x_global = x_global[notremoves > 0]
truth = truth[notremoves > 0]
newnsamp = x_global.shape[0]
print('reduced content to ',
int(float(newnsamp) / float(self.nsamples) * 100), '%')
print('remove nans')
x_global = np.where(
np.logical_and(np.isfinite(x_global),
(np.abs(x_global) < 100000.0)), x_global, 0)
return [x_global], [truth], []
def readFromRootFile(self, filename, TupleMeanStd, weighter):
from DeepJetCore.preprocessing import MeanNormApply, MeanNormZeroPad, MeanNormZeroPadParticles
import numpy
from DeepJetCore.stopwatch import stopwatch
sw = stopwatch()
swall = stopwatch()
import ROOT
fileTimeOut(filename, 120) #give eos a minute to recover
rfile = ROOT.TFile(filename)
tree = rfile.Get("deepntuplizer/tree")
self.nsamples = tree.GetEntries()
print('took ', sw.getAndReset(), ' seconds for getting tree entries')
# split for convolutional network
x_global = MeanNormZeroPad(filename, TupleMeanStd, [self.branches[0]],
[self.branchcutoffs[0]], self.nsamples)
x_cpf = MeanNormZeroPadParticles(filename, TupleMeanStd,
self.branches[1],
self.branchcutoffs[1], self.nsamples)
x_npf = MeanNormZeroPadParticles(filename, TupleMeanStd,
self.branches[2],
self.branchcutoffs[2], self.nsamples)
x_sv = MeanNormZeroPadParticles(filename, TupleMeanStd,
self.branches[3],
self.branchcutoffs[3], self.nsamples)
print('took ', sw.getAndReset(),
' seconds for mean norm and zero padding (C module)')
Tuple = self.readTreeFromRootToTuple(filename)
if self.remove:
notremoves = weighter.createNotRemoveIndices(Tuple)
undef = Tuple['isUndefined']
notremoves -= undef
print('took ', sw.getAndReset(), ' to create remove indices')
if self.weight:
weights = weighter.getJetWeights(Tuple)
elif self.remove:
weights = notremoves
else:
print('neither remove nor weight')
weights = numpy.empty(self.nsamples)
weights.fill(1.)
truthtuple = Tuple[self.truthclasses]
#print(self.truthclasses)
alltruth = self.reduceTruth(truthtuple)
#print(alltruth.shape)
if self.remove:
print('remove')
weights = weights[notremoves > 0]
x_global = x_global[notremoves > 0]
x_cpf = x_cpf[notremoves > 0]
x_npf = x_npf[notremoves > 0]
x_sv = x_sv[notremoves > 0]
alltruth = alltruth[notremoves > 0]
newnsamp = x_global.shape[0]
print('reduced content to ',
int(float(newnsamp) / float(self.nsamples) * 100), '%')
self.nsamples = newnsamp
print(x_global.shape, self.nsamples)
self.w = [weights]
self.x = [x_global, x_cpf, x_npf, x_sv]
self.y = [alltruth]
def convertFromSourceFile(self, filename, weighterobjects, istraining):
# Function to produce the numpy training arrays from root files
from DeepJetCore.Weighter import Weighter
from DeepJetCore.stopwatch import stopwatch
sw = stopwatch()
swall = stopwatch()
if not istraining:
self.remove = False
def reduceTruth(uproot_arrays):
b = uproot_arrays[str.encode(map_prefix(b'Jet_isB'))]
bb = uproot_arrays[str.encode(map_prefix(b'Jet_isBB'))]
gbb = uproot_arrays[str.encode(map_prefix(b'Jet_isGBB'))]
bl = uproot_arrays[str.encode(map_prefix(b'Jet_isLeptonicB'))]
blc = uproot_arrays[str.encode(map_prefix(b'Jet_isLeptonicB_C'))]
lepb = bl + blc
c = uproot_arrays[str.encode(map_prefix(b'Jet_isC'))]
cc = uproot_arrays[str.encode(map_prefix(b'Jet_isCC'))]
gcc = uproot_arrays[str.encode(map_prefix(b'Jet_isGCC'))]
ud = uproot_arrays[str.encode(map_prefix(b'Jet_isUD'))]
s = uproot_arrays[str.encode(map_prefix(b'Jet_isS'))]
uds = ud + s
g = uproot_arrays[str.encode(map_prefix(b'Jet_isG'))]
return np.vstack(
(b + lepb, bb + gbb, c + cc + gcc, uds + g)).transpose()
print('reading ' + filename)
import ROOT
from root_numpy import tree2array, root2array
fileTimeOut(filename, 600) #give eos a minute to recover
rfile = ROOT.TFile(filename)
# tree = rfile.Get("ttree")
# self.nsamples = tree.GetEntries()
# from IPython import embed;embed()
tree = u3.open(filename)["ttree"]
self.nsamples = tree.numentries
print("Nsamples: {}".format(self.nsamples))
# user code, example works with the example 2D images in root format generated by make_example_data
from DeepJetCore.preprocessing import MeanNormZeroPad, MeanNormZeroPadParticles
for obj in [
filename, weighterobjects['means'],
[
self.global_branches, self.track_branches,
self.eta_rel_branches, self.vtx_branches
], [1, self.n_track, self.n_eta_rel, self.n_vtx], self.nsamples
]:
print("DEBUGGING:\t{}".format(type(obj)))
print("DEBUGGING:\n\tPrinting MeanNormZeroPad arguments:")
print("\t{}\n\t{}\n\t{}".format(filename, weighterobjects['means'],
self.nsamples))
print("reading in with new uproot+awkward function")
nparr = uproot_tree_to_numpy(
filename,
weighterobjects['means'], [
self.global_branches, self.track_branches,
self.eta_rel_branches, self.vtx_branches
], [1, self.n_track, self.n_eta_rel, self.n_vtx],
self.nsamples,
treename="ttree")
print("succesfully created numpy array")
x_global = nparr
# x_global = MeanNormZeroPad(filename,weighterobjects['means'],
# [self.global_branches,self.track_branches,self.eta_rel_branches,self.vtx_branches],
# [1,self.n_track,self.n_eta_rel,self.n_vtx],self.nsamples)
print("opening file with uproot")
import uproot3 as uproot
urfile = uproot.open(filename)["ttree"]
truth_arrays = urfile.arrays(self.truth_branches)
print("truth_branches:")
print(self.truth_branches)
print("truth_arrays:")
print(truth_arrays)
truth = reduceTruth(truth_arrays)
truth = truth.astype(dtype='float32',
order='C') #important, float32 and C-type!
x_global = x_global.astype(dtype='float32', order='C')
if self.remove:
b = [self.weightbranchX, self.weightbranchY]
b.extend(self.truth_branches)
b.extend(self.undefTruth)
fileTimeOut(filename, 120)
for_remove = uproot_root2array(filename,
treename="ttree",
stop=None,
branches=b)
notremoves = weighterobjects['weigther'].createNotRemoveIndices(
for_remove)
undef = for_remove['Jet_isUndefined']
print("\nundef:")
print(undef)
print("undef dtype: ", undef.dtype)
print()
print(notremoves)
notremoves -= np.array(undef, dtype=np.float32)
print('took ', sw.getAndReset(), ' to create remove indices')
if self.remove:
print('remove')
x_global = x_global[notremoves > 0]
truth = truth[notremoves > 0]
newnsamp = x_global.shape[0]
print('reduced content to ',
int(float(newnsamp) / float(self.nsamples) * 100), '%')
print('remove nans')
x_global = np.where(
np.logical_and(np.isfinite(x_global),
(np.abs(x_global) < 100000.0)), x_global, 0)
return [x_global], [truth], []
