Learning the structure of a Bayesian network¶
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In [1]:
%matplotlib inline
from pylab import *
import matplotlib.pyplot as plt
import os
In [2]:
import pyAgrum as gum
import pyAgrum.lib.notebook as gnb
import pyAgrum.lib.explain as explain
import pyAgrum.lib.bn_vs_bn as bnvsbn
gum.about()
gnb.configuration()
pyAgrum 1.1.0.9
(c) 2015-2022 Pierre-Henri Wuillemin, Christophe Gonzales
This is free software; see the source code for copying conditions.
There is ABSOLUTELY NO WARRANTY; not even for MERCHANTABILITY or
FITNESS FOR A PARTICULAR PURPOSE. For details, see 'pyAgrum.warranty'.
| Library | Version |
|---|---|
| OS | nt [win32] |
| Python | 3.10.4 (tags/v3.10.4:9d38120, Mar 23 2022, 23:13:41) [MSC v.1929 64 bit (AMD64)] |
| IPython | 8.4.0 |
| Matplotlib | 3.5.2 |
| Numpy | 1.22.4 |
| pyDot | 1.4.2 |
| pyAgrum | 1.1.0.9 |
Sun Jun 05 12:19:57 2022 Paris, Madrid (heure d’été)
Generating the database from a BN¶
In [3]:
bn=gum.loadBN("res/asia.bif")
bn
Out[3]:
In [4]:
gum.generateSample(bn,500000,"out/sample_asia.csv",True);
out/sample_asia.csv: 100%|█████████████████████████████████|
Log2-Likelihood : -1613285.0339585799
In [5]:
with open("out/sample_asia.csv","r") as src:
for _ in range(10):
print(src.readline(),end="")
tuberculosis,smoking,tuberculos_or_cancer,visit_to_Asia,positive_XraY,bronchitis,lung_cancer,dyspnoea
1,0,1,1,1,1,1,0
1,0,1,1,1,0,1,1
1,1,1,1,1,1,1,1
1,1,1,1,1,1,1,1
1,1,1,1,1,1,1,1
1,0,0,1,0,1,0,0
1,0,1,1,1,1,1,0
1,1,1,1,1,0,1,0
1,1,1,1,1,0,1,0
In [6]:
learner=gum.BNLearner("out/sample_asia.csv",bn) #using bn as template for variables
print(learner)
Filename : out/sample_asia.csv
Size : (500000,8)
Variables : visit_to_Asia[2], tuberculosis[2], tuberculos_or_cancer[2], positive_XraY[2], lung_cancer[2], smoking[2], bronchitis[2], dyspnoea[2]
Induced types : False
Missing values : False
Algorithm : Greedy Hill Climbing
Score : BDeu
Prior : -
In [7]:
print(f"Row of visit_to_Asia : {learner.idFromName('visit_to_Asia')}") # first row is 0
Row of visit_to_Asia : 0
In [8]:
print(f"Variable in row 4 : {learner.nameFromId(4)}")
Variable in row 4 : lung_cancer
The BNLearner is capable of recognizing missing values in databases. For this purpose, just indicate as a last argument the list of the strings that represent missing values.
In [9]:
# it is possible to add as a last argument a list of the symbols that represent missing values:
# whenever a cell of the database is equal to one of these strings, it is considered as a
# missing value
learner=gum.BNLearner("res/asia_missing.csv",bn, ['?', 'N/A'] )
print(f"Are there missing values in the database ? {learner.state()['Missing values'][0]}")
Are there missing values in the database ? True
type induction¶
When reading a csv file, BNLearner can try to find the correct type for discrete variable. Especially for numeric values.
In [10]:
%%writefile out/testTypeInduction.csv
A,B,C,D
1,2,0,hot
0,3,-2,cold
0,1,2,hot
1,2,2,warm
Overwriting out/testTypeInduction.csv
In [11]:
print("* by default, type induction is on (True) :")
learner=gum.BNLearner("out/testTypeInduction.csv")
bn3=learner.learnBN()
for v in sorted(bn3.names()):
print(f" - {bn3.variable(v)}")
print("")
print("* but you can disable it :")
learner=gum.BNLearner("out/testTypeInduction.csv",["?"],False)
bn3=learner.learnBN()
for v in sorted(bn3.names()):
print(f" - {bn3.variable(v)}")
print("")
print("Note that when a Labelized variable is found, the labesl are alphabetically sorted.")
* by default, type induction is on (True) :
- A:Range([0,1])
- B:Range([1,3])
- C:Integer({-2|0|2})
- D:Labelized({cold|hot|warm})
* but you can disable it :
- A:Labelized({0|1})
- B:Labelized({1|2|3})
- C:Labelized({-2|0|2})
- D:Labelized({cold|hot|warm})
Note that when a Labelized variable is found, the labesl are alphabetically sorted.
Parameters learning from the database¶
We give the \(bn\) as a parameter for the learner in order to have the variables and the order of the labels for each variables. Please try to remove the argument \(bn\) in the first line below to see the difference …
In [12]:
learner=gum.BNLearner("out/sample_asia.csv",bn) #using bn as template for variables and labels
bn2=learner.learnParameters(bn.dag())
gnb.showBN(bn2)
In [13]:
from IPython.display import HTML
gnb.sideBySide("<H3>Original BN</H3>","<H3>Learned NB</H3>",
bn.cpt ('visit_to_Asia'),bn2.cpt ('visit_to_Asia'),
bn.cpt ('tuberculosis'),bn2.cpt ('tuberculosis'),
ncols=2)
Structural learning a BN from the database¶
Note that, currently, the BNLearner is not yet able to learn in the presence of missing values. This is the reason why, when it discovers that there exist such values, it raises a gum.MissingValueInDatabase exception.
In [14]:
with open("res/asia_missing.csv","r") as asiafile:
for _ in range(10):
print(asiafile.readline(),end="")
try:
learner=gum.BNLearner("res/asia_missing.csv",bn, ['?', 'N/A'] )
bn2=learner.learnBN()
except gum.MissingValueInDatabase:
print ( "exception raised: there are missing values in the database" )
smoking,lung_cancer,bronchitis,visit_to_Asia,tuberculosis,tuberculos_or_cancer,dyspnoea,positive_XraY
0,0,0,1,1,0,0,0
1,1,0,1,1,1,0,1
1,1,1,1,1,1,1,1
1,1,0,1,1,1,0,N/A
0,1,0,1,1,1,1,1
1,1,1,1,1,1,1,1
1,1,1,1,1,1,0,1
1,1,0,1,1,1,0,1
1,1,1,1,1,1,1,1
exception raised: there are missing values in the database
Different learning algorithms¶
For now, there are three algorithms that are wrapped in pyAgrum : LocalSearchWithTabuList,
In [15]:
learner=gum.BNLearner("out/sample_asia.csv",bn) #using bn as template for variables
learner.useLocalSearchWithTabuList()
print(learner)
bn2=learner.learnBN()
print("Learned in {0}ms".format(1000*learner.currentTime()))
gnb.flow.row(bn,bn2,explain.getInformation(bn2),captions=["Original BN","Learned BN","information"])
Filename : out/sample_asia.csv
Size : (500000,8)
Variables : visit_to_Asia[2], tuberculosis[2], tuberculos_or_cancer[2], positive_XraY[2], lung_cancer[2], smoking[2], bronchitis[2], dyspnoea[2]
Induced types : False
Missing values : False
Algorithm : Local Search with Tabu List
Tabu list size : 2
Score : BDeu
Prior : -
Learned in 131.2133ms
To apprehend the distance between the original and the learned BN, we have several tools : - Compute the KL divergence (and other distance) between original and learned joint distribution
In [16]:
kl=gum.ExactBNdistance(bn,bn2)
kl.compute()
Out[16]:
{'klPQ': 2.111734327848637e-05,
'errorPQ': 0,
'klQP': 1.8016224314088024e-05,
'errorQP': 128,
'hellinger': 0.0027903639478247424,
'bhattacharya': 3.887431170729849e-06,
'jensen-shannon': 5.392839278947e-06}
Compute some scores on the BNs (as binary classifiers) abd show the graphical diff between the two graphs
In [17]:
gcmp=bnvsbn.GraphicalBNComparator(bn,bn2)
gnb.flow.add(bnvsbn.graphDiff(bn,bn2))
gnb.flow.add(bnvsbn.graphDiffLegend())
gnb.flow.new_line()
gnb.flow.add_html("<br/>".join([f"{k} : {v:.2f}" for k,v in gcmp.skeletonScores().items() if k!='count']),"Skeleton scores")
gnb.flow.add_html("<br/>".join([f"{k} : {v:.2f}" for k,v in gcmp.scores().items() if k!='count']),"Scores")
gnb.flow.display()
recall : 0.88
precision : 0.70
fscore : 0.78
dist2opt : 0.33
Skeleton scores
precision : 0.70
fscore : 0.78
dist2opt : 0.33
recall : 0.62
precision : 0.50
fscore : 0.56
dist2opt : 0.62
Scores
precision : 0.50
fscore : 0.56
dist2opt : 0.62
A greedy Hill Climbing algorithm (with insert, remove and change arc as atomic operations).
In [18]:
learner=gum.BNLearner("out/sample_asia.csv",bn) #using bn as template for variables
learner.useGreedyHillClimbing()
print(learner)
bn2=learner.learnBN()
print("Learned in {0}ms".format(1000*learner.currentTime()))
gnb.sideBySide(bn,bn2,gnb.getBNDiff(bn,bn2),explain.getInformation(bn2),captions=["Original BN","Learned BN","Graphical diff","information"])
Filename : out/sample_asia.csv
Size : (500000,8)
Variables : visit_to_Asia[2], tuberculosis[2], tuberculos_or_cancer[2], positive_XraY[2], lung_cancer[2], smoking[2], bronchitis[2], dyspnoea[2]
Induced types : False
Missing values : False
Algorithm : Greedy Hill Climbing
Score : BDeu
Prior : -
Learned in 108.212ms
And a K2 for those who likes it :)
In [19]:
learner=gum.BNLearner("out/sample_asia.csv",bn) #using bn as template for variables
learner.useK2([0,1,2,3,4,5,6,7])
print(learner)
bn2=learner.learnBN()
print("Learned in {0}ms".format(1000*learner.currentTime()))
gnb.sideBySide(bn,bn2,gnb.getBNDiff(bn,bn2),explain.getInformation(bn2),captions=["Original BN","Learned BN","Graphical diff","information"])
Filename : out/sample_asia.csv
Size : (500000,8)
Variables : visit_to_Asia[2], tuberculosis[2], tuberculos_or_cancer[2], positive_XraY[2], lung_cancer[2], smoking[2], bronchitis[2], dyspnoea[2]
Induced types : False
Missing values : False
Algorithm : K2
K2 order : visit_to_Asia, tuberculosis, tuberculos_or_cancer, positive_XraY, lung_cancer, smoking, bronchitis, dyspnoea
Score : BDeu
Prior : -
Learned in 51.1976ms
K2 can be very good if the order is the good one (a topological order of nodes in the reference)
In [20]:
learner=gum.BNLearner("out/sample_asia.csv",bn) #using bn as template for variables
learner.useK2([7,6,5,4,3,2,1,0])
print(learner)
bn2=learner.learnBN()
print("Learned in {0}s".format(learner.currentTime()))
gnb.sideBySide(bn,bn2,gnb.getBNDiff(bn,bn2),explain.getInformation(bn2),captions=["Original BN","Learned BN","Graphical diff","information"])
Filename : out/sample_asia.csv
Size : (500000,8)
Variables : visit_to_Asia[2], tuberculosis[2], tuberculos_or_cancer[2], positive_XraY[2], lung_cancer[2], smoking[2], bronchitis[2], dyspnoea[2]
Induced types : False
Missing values : False
Algorithm : K2
K2 order : dyspnoea, bronchitis, smoking, lung_cancer, positive_XraY, tuberculos_or_cancer, tuberculosis, visit_to_Asia
Score : BDeu
Prior : -
Learned in 0.065218s
Following the learning curve¶
In [21]:
import numpy as np
%matplotlib inline
learner=gum.BNLearner("out/sample_asia.csv",bn) #using bn as template for variables
learner.useLocalSearchWithTabuList()
# we could prefere a log2likelihood score
# learner.useScoreLog2Likelihood()
learner.setMaxTime(10)
# representation of the error as a pseudo log (negative values really represents negative epsilon
@np.vectorize
def pseudolog(x):
res=np.log(x)#np.log(y)
return res if x>0 else -res
# in order to control the complexity, we limit the number of parents
learner.setMaxIndegree(7) # no more than 3 parent by node
learner.setEpsilon(1e-10)
gnb.animApproximationScheme(learner,
scale=pseudolog) # scale by default is np.log10
bn2=learner.learnBN()
Customizing the learning algorithms¶
1. Learn a tree ?¶
In [22]:
learner=gum.BNLearner("out/sample_asia.csv",bn) #using bn as template for variables
learner.useGreedyHillClimbing()
learner.setMaxIndegree(1) # no more than 1 parent by node
print(learner)
bntree=learner.learnBN()
gnb.sideBySide(bn,bntree,gnb.getBNDiff(bn,bntree),explain.getInformation(bntree),captions=["Original BN","Learned BN","Graphical diff","information"])
Filename : out/sample_asia.csv
Size : (500000,8)
Variables : visit_to_Asia[2], tuberculosis[2], tuberculos_or_cancer[2], positive_XraY[2], lung_cancer[2], smoking[2], bronchitis[2], dyspnoea[2]
Induced types : False
Missing values : False
Algorithm : Greedy Hill Climbing
Score : BDeu
Prior : -
Constraint Max InDegree : 1 (Used only for score-based algorithms.)
2. with prior structural knowledge¶
In [23]:
learner=gum.BNLearner("out/sample_asia.csv",bn) #using bn as template for variables
learner.useGreedyHillClimbing()
# I know that smoking causes cancer
learner.addMandatoryArc("smoking","lung_cancer") # smoking->lung_cancer
# I know that visit to Asia may change the risk of tuberculosis
learner.addMandatoryArc("visit_to_Asia","tuberculosis") # visit_to_Asia->tuberculosis
print(learner)
bn2=learner.learnBN()
gnb.sideBySide(bn,bn2,gnb.getBNDiff(bn,bn2),explain.getInformation(bn2),captions=["Original BN","Learned BN","Graphical diff","information"])
Filename : out/sample_asia.csv
Size : (500000,8)
Variables : visit_to_Asia[2], tuberculosis[2], tuberculos_or_cancer[2], positive_XraY[2], lung_cancer[2], smoking[2], bronchitis[2], dyspnoea[2]
Induced types : False
Missing values : False
Algorithm : Greedy Hill Climbing
Score : BDeu
Prior : -
Constraint Mandatory Arcs : {visit_to_Asia->tuberculosis, smoking->lung_cancer}
3. changing the scores¶
By default, a BDEU score is used. But it can be changed.
In [24]:
learner=gum.BNLearner("out/sample_asia.csv",bn) #using bn as template for variables
learner.useGreedyHillClimbing()
# I know that smoking causes cancer
learner.addMandatoryArc(0,1)
# we prefere a log2likelihood score
learner.useScoreLog2Likelihood()
# in order to control the complexity, we limit the number of parents
learner.setMaxIndegree(1) # no more than 1 parent by node
print(learner)
bn2=learner.learnBN()
kl=gum.ExactBNdistance(bn,bn2)
gnb.sideBySide(bn,bn2,gnb.getBNDiff(bn,bn2),
"<br/>".join(["<b>"+k+"</b> :"+str(v) for k,v in kl.compute().items()]),
captions=["original","learned BN","diff","distances"])
Filename : out/sample_asia.csv
Size : (500000,8)
Variables : visit_to_Asia[2], tuberculosis[2], tuberculos_or_cancer[2], positive_XraY[2], lung_cancer[2], smoking[2], bronchitis[2], dyspnoea[2]
Induced types : False
Missing values : False
Algorithm : Greedy Hill Climbing
Score : Log2Likelihood
Prior : -
Constraint Max InDegree : 1 (Used only for score-based algorithms.)
Constraint Mandatory Arcs : {visit_to_Asia->tuberculosis}
4. comparing BNs¶
There are multiple ways to compare Bayes net…
In [25]:
help(gnb.getBNDiff)
Help on function getBNDiff in module pyAgrum.lib.notebook:
getBNDiff(bn1, bn2, size=None, noStyle=False)
get a HTML string representation of a graphical diff between the arcs of _bn1 (reference) with those of _bn2.
if `noStyle` is False use 4 styles (fixed in pyAgrum.config) :
- the arc is common for both
- the arc is common but inverted in `bn2`
- the arc is added in `bn2`
- the arc is removed in `bn2`
Parameters
----------
bn1: pyAgrum.BayesNet
the reference
bn2: pyAgrum.BayesNet
the compared one
size: float|str
size of the rendered graph
noStyle: bool
with style or not.
Returns
-------
the HTML representation of the comparison
In [26]:
gnb.showBNDiff(bn,bn2)
In [27]:
import pyAgrum.lib.bn_vs_bn as gbnbn
help(gbnbn.graphDiff)
Help on function graphDiff in module pyAgrum.lib.bn_vs_bn:
graphDiff(bnref, bncmp, noStyle=False)
Return a pydot graph that compares the arcs of bnref to bncmp.
graphDiff allows bncmp to have less nodes than bnref. (this is not the case in GraphicalBNComparator.dotDiff())
if noStyle is False use 4 styles (fixed in pyAgrum.config) :
- the arc is common for both
- the arc is common but inverted in _bn2
- the arc is added in _bn2
- the arc is removed in _bn2
See graphDiffLegend() to add a legend to the graph.
Warning
-------
if pydot is not installed, this function just returns None
Returns
-------
pydot.Dot
the result dot graph or None if pydot can not be imported
In [28]:
gbnbn.GraphicalBNComparator?
Init signature: gbnbn.GraphicalBNComparator(name1, name2, delta=1e-06)
Docstring:
BNGraphicalComparator allows to compare in multiple way 2 BNs...The smallest assumption is that the names of the variables are the same in the 2 BNs. But some comparisons will have also to check the type and domainSize of the variables. The bns have not exactly the same role : _bn1 is rather the referent model for the comparison whereas _bn2 is the compared one to the referent model.
Parameters
----------
name1 : str or pyAgrum.BayesNet
a BN or a filename for reference
name2 : str or pyAgrum.BayesNet
another BN or antoher filename for comparison
File: c:\users\phw\scoop\apps\python\current\lib\site-packages\pyagrum\lib\bn_vs_bn.py
Type: type
Subclasses:
In [29]:
gcmp=gbnbn.GraphicalBNComparator(bn,bn2)
gnb.sideBySide(bn,bn2,gcmp.dotDiff(),gbnbn.graphDiffLegend(),
bn2,bn,gbnbn.graphDiff(bn2,bn),gbnbn.graphDiffLegend(),
ncols=4)
In [30]:
print("But also gives access to different scores :")
print(gcmp.scores())
print(gcmp.skeletonScores())
print(gcmp.hamming())
But also gives access to different scores :
{'count': {'tp': 4, 'tn': 45, 'fp': 3, 'fn': 4}, 'recall': 0.5, 'precision': 0.5714285714285714, 'fscore': 0.5333333333333333, 'dist2opt': 0.6585388898066349}
{'count': {'tp': 6, 'tn': 19, 'fp': 1, 'fn': 2}, 'recall': 0.75, 'precision': 0.8571428571428571, 'fscore': 0.7999999999999999, 'dist2opt': 0.2879377767249482}
{'hamming': 3, 'structural hamming': 7}
In [31]:
print("KL divergence can be computed")
kl=gum.ExactBNdistance (bn,bn2)
kl.compute()
KL divergence can be computed
Out[31]:
{'klPQ': 0.12241870078655698,
'errorPQ': 0,
'klQP': 0.03312237743290082,
'errorQP': 64,
'hellinger': 0.20546805471860538,
'bhattacharya': 0.02133452626980637,
'jensen-shannon': 0.024300742692194646}
5. Mixing algorithms¶
First we learn a structure with HillClimbing (faster ?)
In [32]:
learner=gum.BNLearner("out/sample_asia.csv",bn) #using bn as template for variables
learner.useGreedyHillClimbing()
learner.addMandatoryArc(0,1)
bn2=learner.learnBN()
kl=gum.ExactBNdistance(bn,bn2)
gnb.sideBySide(bn,bn2,gnb.getBNDiff(bn,bn2),
"<br/>".join(["<b>"+k+"</b> :"+str(v) for k,v in kl.compute().items()]),
captions=["original","learned BN","diff","distances"])
And then we refine with tabuList
In [33]:
learner=gum.BNLearner("out/sample_asia.csv",bn) #using bn as template for variables
learner.useLocalSearchWithTabuList()
learner.setInitialDAG(bn2.dag())
print(learner)
bn3=learner.learnBN()
kl=gum.ExactBNdistance(bn,bn3)
gnb.sideBySide(bn,bn2,gnb.getBNDiff(bn,bn2),
"<br/>".join(["<b>"+k+"</b> :"+str(v) for k,v in kl.compute().items()]),
captions=["original","learned BN","diff","distances"])
Filename : out/sample_asia.csv
Size : (500000,8)
Variables : visit_to_Asia[2], tuberculosis[2], tuberculos_or_cancer[2], positive_XraY[2], lung_cancer[2], smoking[2], bronchitis[2], dyspnoea[2]
Induced types : False
Missing values : False
Algorithm : Local Search with Tabu List
Tabu list size : 2
Score : BDeu
Prior : -
Initial DAG : True (digraph {
0;
1;
2;
3;
4;
5;
6;
7;
1 -> 7;
0 -> 1;
6 -> 5;
2 -> 1;
4 -> 1;
4 -> 5;
4 -> 2;
2 -> 6;
0 -> 2;
4 -> 6;
2 -> 3;
2 -> 7;
7 -> 6;
}
)
Impact of the size of the database for the learning¶
In [34]:
import IPython.display
rows=3
sizes=[400,500,700,1000,2000,5000,
10000,50000,75000,
100000,150000,175000,
200000,300000,500000]
def extract_asia(n):
"""
extract n line from asia.csv to extract.csv
"""
with open("out/sample_asia.csv","r") as src:
with open("out/extract_asia.csv","w") as dst:
for _ in range(n+1):
print(src.readline(),end="",file=dst)
In [35]:
gnb.flow.clear()
nbr=0
l=[]
for i in sizes:
extract_asia(i)
learner=gum.BNLearner("out/extract_asia.csv",bn) # using bn as template for variables
learner.useGreedyHillClimbing()
print(learner.state()["Size"][0])
bn2=learner.learnBN()
kl=gum.ExactBNdistance(bn,bn2)
r=kl.compute()
l.append(r['klPQ'])
gnb.flow.add(gnb.getBNDiff(bn,bn2,size='3!'),f"size={i}")
gnb.flow.display()
plot(sizes,l)
print(l[-1])
(400,8)
(500,8)
(700,8)
(1000,8)
(2000,8)
(5000,8)
(10000,8)
(50000,8)
(75000,8)
(100000,8)
(150000,8)
(175000,8)
(200000,8)
(300000,8)
(500000,8)
1.7210567024329108e-05
In [36]:
gnb.flow.clear()
nbr=0
l=[]
for i in sizes:
extract_asia(i)
learner=gum.BNLearner("out/extract_asia.csv",bn) #using bn as template for variables
learner.useLocalSearchWithTabuList()
print(learner.state()["Size"][0])
bn2=learner.learnBN()
kl=gum.ExactBNdistance(bn,bn2)
r=kl.compute()
l.append(r['klPQ'])
gnb.flow.add(gnb.getBNDiff(bn,bn2,size='3!'),f"size={i}")
gnb.flow.display()
plot(sizes,l)
print(l[-1])
(400,8)
(500,8)
(700,8)
(1000,8)
(2000,8)
(5000,8)
(10000,8)
(50000,8)
(75000,8)
(100000,8)
(150000,8)
(175000,8)
(200000,8)
(300000,8)
(500000,8)
2.111734327848637e-05
In [ ]: