def A2():
for att in m.attributes:
#print att[ 0 ]
print "Gain in Monk1 is : ", dT.averageGain( m.monk1, att )
print "Gain in Monk2 is : ", dT.averageGain( m.monk2, att )
print "Gain in Monk3 is : ", dT.averageGain( m.monk3, att )
print '\n'
def A2():
for att in m.attributes:
#print att[ 0 ]
print "Gain in Monk1 is : ", dT.averageGain(m.monk1, att)
print "Gain in Monk2 is : ", dT.averageGain(m.monk2, att)
print "Gain in Monk3 is : ", dT.averageGain(m.monk3, att)
print '\n'
def assignment2():
print("Assignment 2")
l = [[d.averageGain(m.monk1, a) for a in m.attributes],
[d.averageGain(m.monk2, a) for a in m.attributes],
[d.averageGain(m.monk3, a) for a in m.attributes]]
for i in range(0, 3):
# print("MONK-%d: %f %f %f %f %f %f" % tuple([i + 1] + l[i]), end=" | ")
print("Split on: a%d" % (max(enumerate(l[i]), key=lambda p: p[1])[0] + 1))
def assignment2():
print("Assignment 2")
l = [[d.averageGain(m.monk1, a) for a in m.attributes],
[d.averageGain(m.monk2, a) for a in m.attributes],
[d.averageGain(m.monk3, a) for a in m.attributes]]
for i in range(0, 3):
# print("MONK-%d: %f %f %f %f %f %f" % tuple([i + 1] + l[i]), end=" | ")
print("Split on: a%d" %
(max(enumerate(l[i]), key=lambda p: p[1])[0] + 1))
def assignment3():
monk1 = ['monk1']
monk2 = ['monk2']
monk3 = ['monk3']
for j in range (0,6):
monk1.append(round(tree.averageGain(m.monk1,m.attributes[j]),5))
monk2.append(round(tree.averageGain(m.monk2,m.attributes[j]),5))
monk3.append(round(tree.averageGain(m.monk3,m.attributes[j]),5))
print(tabulate([monk1, monk2,monk3], headers=['Dataset', 'a1','a2','a3','a4','a5','a6'], tablefmt='orgtbl'))
def getBestAttribute(dataset, attributes, available):
# Returns the index of the best attribute to split on in attributes[]
mostGain = -1;
bestAttribute = None;
for i in range(0, len(attributes)):
if available[i] and d.averageGain(dataset, attributes[i]) > mostGain:
mostGain = d.averageGain(dataset, attributes[i])
bestAttribute = i
return bestAttribute
def getBestAttribute(dataset, attributes, available):
# Returns the index of the best attribute to split on in attributes[]
mostGain = -1
bestAttribute = None
for i in range(0, len(attributes)):
if available[i] and d.averageGain(dataset, attributes[i]) > mostGain:
mostGain = d.averageGain(dataset, attributes[i])
bestAttribute = i
return bestAttribute
def gain(): monk1_gains = []; monk2_gains = []; monk3_gains = []; for i in range(0,6): monk1_gains.append((mdata.attributes[i],dtree.averageGain(mdata.monk1,mdata.attributes[i]))) monk2_gains.append((mdata.attributes[i],dtree.averageGain(mdata.monk2,mdata.attributes[i]))) monk3_gains.append((mdata.attributes[i],dtree.averageGain(mdata.monk3,mdata.attributes[i]))) return [monk1_gains,monk2_gains,monk3_gains]
def assignment3():
gains1 = [d.averageGain(m.monk1, m.attributes[i]) for i in range(0, 6)]
print("The gains of entropy on the first dataset per attribute is %s" %
gains1)
gains2 = [d.averageGain(m.monk2, m.attributes[i]) for i in range(0, 6)]
print("The gains of entropy on the second dataset per attribute is %s" %
gains2)
gains3 = [d.averageGain(m.monk3, m.attributes[i]) for i in range(0, 6)]
print("The gains of entropy on the third dataset per attribute is %s" %
gains3)
def calc_gain():
print "\n------------------------------\nAssignment 2 - Average gain\n------------------------------"
i = 1
print "Dataset\t a1\t\t a2\t\t a3\t\t a4\t\t a5\t\t a6"
s = "Monk1\t"
for attr in data.attributes:
s = s + "%.6f\t" % (dt.averageGain(data.monk1, attr))
print s
s = "Monk2\t"
for attr in data.attributes:
s = s + "%.6f\t" % (dt.averageGain(data.monk2, attr))
print s
s = "Monk3\t"
for attr in data.attributes:
s = s + "%.6f\t" % (dt.averageGain(data.monk3, attr))
print s
def printGains(datasets, attributes):
# Print GAIN for all datasets
for i in range(0, len(datasets)):
for j in range(0, len(attributes)):
print("Gain monk" + str(i + 1) + ", a" + str(j + 1) + ": " +
str(d.averageGain(datasets[i], attributes[j])))
print("---------------")
def infoGainOnSubsets(subsets):
l = [] # List containing subsets depending on what choice was made
# in previous node
for sset in subsets:
attribute_gains = []
j = 0
while (j < len(m.attributes)):
attribute_gains.append(dtree.averageGain(sset, m.attributes[j]))
j+=1
l.append(attribute_gains)
result = [0] * len(m.attributes)
i = 0
while i < len(l):
j = 0
while j < len(m.attributes):
result[j] += (l[i][j])
#print((l[i][j]))
j+=1
i+=1
"""
Summing over the information gains given by the attributes in different
nodes on level two shows that attribute 1 gives the best information gain
"""
print(result)
return
def get_avg_gain_dict(dataset):
avg_gain_dict = dict()
for i in range(len(m.attributes)):
attribute_key = "A" + str(i + 1)
attribute = m.attributes[i]
avg_gain = d.averageGain(dataset, attribute)
avg_gain_dict[attribute_key] = avg_gain
return avg_gain_dict
def information_gain(datasets):
attributes_names = ['A1', 'A2', 'A3', 'A4', 'A5', 'A6']
information_gain_matrix = np.zeros((len(datasets), len(m.attributes)))
for idx, dataset in enumerate(datasets):
for i in range(len(attributes_names)):
average_gain = round(d.averageGain(dataset, m.attributes[i]), 4)
information_gain_matrix[idx, i] = average_gain
return information_gain_matrix
def print_average_gain(datasets, attributes):
# Calculate average gain for datasets
print("Information gain")
for data in datasets:
print("For " + data + " the:")
for attribute in attributes:
print("information gain for " + attribute + " was: " +
str(d.averageGain(datasets[data], attributes[attribute])))
def informationGainCalculation():
print("Information gain results ", "\n")
for attributeIndex in range(0, 6):
result = d.averageGain(m.monk1, m.attributes[attributeIndex])
print("Monk1| ", attributeIndex + 1, ": ", result, " ")
print("Best attribute: ", d.bestAttribute(m.monk1, m.attributes), "\n")
for attributeIndex in range(0, 6):
result = d.averageGain(m.monk2, m.attributes[attributeIndex])
print("Monk2| ", attributeIndex + 1, ": ", result, " ")
print("Best attribute: ", d.bestAttribute(m.monk2, m.attributes), "\n")
for attributeIndex in range(0, 6):
result = d.averageGain(m.monk3, m.attributes[attributeIndex])
print("Monk3| ", attributeIndex + 1, ": ", result, " ")
print("Best attribute: ", d.bestAttribute(m.monk3, m.attributes), "\n")
def bestAttribute(dataset, attributes):
result = 0
best = attributes[0]
for a in attributes:
value = dt.averageGain(dataset, a)
if value > result:
result = value
best = a
return best
def chosenNode(DataSet, attributes):
IG = {}
for j in range(len(attributes)):
IG[dtree.averageGain(DataSet, attributes[j])] = attributes[j].name
#max IG
maxIGKey = max(IG.keys())
#the chosen attribute that has the highest value of IG such as A5 in monk1
maxIGValue = IG[maxIGKey]
#print('chosen node: %s'%(maxIGValue))
return maxIGValue
def get_avg_gain_dict_exclude(dataset, exclude=[]):
avg_gain_dict = dict()
for i in range(len(m.attributes)):
if i not in exclude:
attribute_key = "A" + str(i + 1)
attribute = m.attributes[i]
avg_gain = d.averageGain(dataset, attribute)
avg_gain_dict[attribute_key] = avg_gain
return avg_gain_dict
def assignment_3():
i = 0
k = 0
while i <= 5:
f = dtree.averageGain(m.monk1, m.attributes[i])
k += f
print(i + 1, rnd(f, 8))
i += 1
print(k)
def assignment2(): print "--- Assignment 2 ---" print "Selecting the root of the decision tree" table = Texttable(max_width=100) table.add_row(["Dataset", "a1", "a2", "a3", "a4", "a5", "a6"]) for i in range(3): gains = map(lambda att: d.averageGain(monkdata[i],att), m.attributes) table.add_row(["Monk-" + str(i+1)] + gains) print table.draw() print
def optimal_attr_split(data, attributes):
maxGain = -1
maxGainInd = 0
for attr in range(0,len(attributes)):
gain = dtree.averageGain(data, attributes[attr])
print("Attribute " + str(attr + 1) + " information gain: " + str(gain))
if (maxGain < gain):
maxGain = gain
maxGainInd = attr
print("Best split attribute is attribute " + str(maxGainInd + 1))
return maxGainInd
def informationGain(data): a1 = tree.averageGain(data.monk3, data.attributes[0]) a2 = tree.averageGain(data.monk3, data.attributes[1]) a3 = tree.averageGain(data.monk3, data.attributes[2]) a4 = tree.averageGain(data.monk3, data.attributes[3]) a5 = tree.averageGain(data.monk3, data.attributes[4]) a6 = tree.averageGain(data.monk3, data.attributes[5])
def getMaxGain(dataset, attributes):
gains = [(a, dtree.averageGain(dataset, a)) for a in attributes]
g = [str(round(b, 5)) for a, b in gains]
print(" & ".join(g))
attribute_max = max(gains, key=lambda x: x[1])
print("Max gain on attribute", attribute_max)
return attribute_max
def compute_gain():
print ("Compute information gain of attributes in training datasets:")
ig_table = PrettyTable(['Dataset', 'a1', 'a2', 'a3', 'a4', 'a5', 'a6'])
for i in range(3):
l = ["MONK-{0}".format(i+1)]
for k in range(6):
l.append(round(dt.averageGain(monks[i], m.attributes[k]), 10))
ig_table.add_row(l)
print(ig_table)
print ()
def find_information_gain(data_set, attributes):
information_gain = [
d.averageGain(data_set, attributes[0]),
d.averageGain(data_set, attributes[1]),
d.averageGain(data_set, attributes[2]),
d.averageGain(data_set, attributes[3]),
d.averageGain(data_set, attributes[4]),
d.averageGain(data_set, attributes[5])
]
return information_gain
def calc_next_level():
#print "\nAverage gain when a5 is choosen"
print "\nA5\t a1\t\t a2\t\t a3\t\t a4\t\t a5\t\t a6"
s = "A5("
for val in data.attributes[4].values:
subset = dt.select(data.monk1, data.attributes[4], val)
t = "\t"
for attr in data.attributes:
t = t + "%.6f\t" % (dt.averageGain(subset, attr))
print val , t
best = dt.bestAttribute(subset, data.attributes)
s = s + best.name + "("
#print "best attribute: ", best.name
for value in best.values:
#print "choose: ", value, "mostCommon: ", dt.mostCommon(dt.select(subset, best, value))
if(dt.mostCommon(dt.select(subset, best, value))):
s = s + "+"
else:
s = s + "-"
s = s + ")"
s = s + ")"
print "\nOur tree:\t", s
print "Build tree:\t", dt.buildTree(data.monk1, data.attributes, 2)
print("3. Building decision tree: \n")
print("Subset division of MONK-1 at attribute 5: \n")
subsets = [];
for x in range(0, len(m.attributes[4].values)):
subsets.append(d.select(m.monk1, m.attributes[4], x+1))
for set in subsets:
gain = 0;
maxgain = 0;
bestatr = 0;
print("Value: %d" % (subsets.index(set) + 1))
print("Most common: " + str(d.mostCommon(set)))
for x in range(0, len(m.attributes)):
gain = d.averageGain(set, m.attributes[x]);
print("Attribute A%d: %f" % (x+1, gain))
if(gain > maxgain):
maxgain = gain;
bestatr = x;
print("Attribute with best information gain: A%d \n" % (bestatr + 1));
maxgain = 0
bestatr = 0;
print("MONK-1:")
t = d.buildTree(m.monk1, m.attributes)
print("Testing set error %f: " % (1 - d.check(t, m.monk1test)))
print("Training set error %f: \n" % (1 - d.check(t, m.monk1)))
print("MONK-2:")
import dtree
import drawtree_qt5 as draw
import numpy as np
import matplotlib.pyplot as plt
import random
entropyMonk1 = dtree.entropy(m.monk1)
entropyMonk2 = dtree.entropy(m.monk2)
entropyMonk3 = dtree.entropy(m.monk3)
print(f'Entropy for monk1: {entropyMonk1}')
print(f'Entropy for monk2: {entropyMonk2}')
print(f'Entropy for monk3: {entropyMonk3}')
informationGainMonk1 = list(
map(lambda x: dtree.averageGain(m.monk1, x), m.attributes))
informationGainMonk2 = list(
map(lambda x: dtree.averageGain(m.monk2, x), m.attributes))
informationGainMonk3 = list(
map(lambda x: dtree.averageGain(m.monk3, x), m.attributes))
print(
f'Information gain for all 6 attuributes for monk1: {informationGainMonk1}'
)
print(
f'Information gain for all 6 attuributes for monk2: {informationGainMonk2}'
)
print(
f'Information gain for all 6 attuributes for monk3: {informationGainMonk3}'
)
def ASSIGNMENT3(dataset):
for idx, attribute in enumerate(m.attributes):
ag = dtree.averageGain(dataset, attribute)
print("Average gain of a{:d}: {:f}".format(idx + 1, ag))
# Needed import for drawing the decision tree.
#import drawtree as drawtree
# Datasets
train = [monk.monk1, monk.monk2, monk.monk3]
test = [monk.monk1test, monk.monk2test, monk.monk3test]
print("Entropy for monk1 dataset is {}".format(dt.entropy(monk.monk1)))
print("Entropy for monk2 dataset is {}".format(dt.entropy(monk.monk2)))
print("Entropy for monk3 dataset is {}".format(dt.entropy(monk.monk3)))
for i, dataset in enumerate(train):
print("")
print("Average gain for monk{} for each attribute".format(i + 1))
for j, attribute in enumerate(monk.attributes):
print("a{} = {}".format(j + 1, dt.averageGain(dataset, attribute)))
monk1a5 = [dt.select(monk.monk1, monk.attributes[4], 1), dt.select(monk.monk1, monk.attributes[4], 2), dt.select(monk.monk1, monk.attributes[4], 3), dt.select(monk.monk1, monk.attributes[4], 4)]
for i, monk1 in enumerate(monk1a5):
print("")
print("Average gain for monk1 where a5 = {} for each attribute".format(i + 1))
for j, attribute in enumerate(monk.attributes):
if j != 4:
print("a{} = {}".format(j + 1, dt.averageGain(monk1, attribute)))
print("Majority class = {}".format(dt.mostCommon(monk1)))
# Building the decision tree.
tree1 = dt.buildTree(monk.monk1, monk.attributes)
tree2 = dt.buildTree(monk.monk2, monk.attributes)
def avgGain(datasets):
return [[dtree.averageGain(d, a) for a in m.attributes] for d in datasets]
def infGain(s): for x in range(0, 6): print "a", x + 1, " ", d.averageGain(s, m.attributes[x])
import monkdata as m import dtree as dtree foo = dtree.select(m.monk1, m.attributes[4], 3) print '-- information gain of monk-1 dataset: --' print 'a_1: ' + str(dtree.averageGain(foo, m.attributes[0])) print 'a_2: ' + str(dtree.averageGain(foo, m.attributes[1])) print 'a_3: ' + str(dtree.averageGain(foo, m.attributes[2])) print 'a_4: ' + str(dtree.averageGain(foo, m.attributes[3])) print 'a_6: ' + str(dtree.averageGain(foo, m.attributes[5])) foo = dtree.select(m.monk1, m.attributes[4], 1) print '-- is a_5 with value = 1 a majority class? --' print dtree.mostCommon(foo)
def printGain(dataset, attributes):
for j in range(0,len(attributes)):
print("Gain a"+str(j+1)+": "+str(d.averageGain(dataset, attributes[j])))
monkEntropy = [round(t.entropy(m.monk1), 5), round(t.entropy(m.monk2), 5), round(t.entropy(m.monk3), 5)]
"--Answer to Assignment 1"
print(monkEntropy, "\n")
"4 INFORMATION GAIN"
"--Assignment 2"
monkTrainingSets = [m.monk1, m.monk2, m.monk3]
informationGain = []
print("Assignment 2: Expected information gains")
att = []
# save values for each attribute
for monk in monkTrainingSets: # for each data set
for attribute in m.attributes: # for every attribute
# calculate the gain of splitting by the attribute
att.append(round(t.averageGain(monk, attribute), 5))
informationGain.append(att) # save a "row vector"
att = []
"--Answer to Assignment 2"
print(informationGain[2], "\n")
# print(t.bestAttribute(m.monk1, m.attributes))
"""
Attribute a5 has the largest information gain meaning that it reduces the
uncertainty the most. Thus, it should be used for splitting at the root node.
"""
def assignment2():
print("Average Gain for ", "Monk-1")
print(
d.averageGain(m.monk1, m.attributes[0]),
d.averageGain(m.monk1, m.attributes[1]),
d.averageGain(m.monk1, m.attributes[2]),
d.averageGain(m.monk1, m.attributes[3]),
d.averageGain(m.monk1, m.attributes[4]),
d.averageGain(m.monk1, m.attributes[5]),
)
print("Average Gain for ", "Monk-2")
print(
d.averageGain(m.monk2, m.attributes[0]),
d.averageGain(m.monk2, m.attributes[1]),
d.averageGain(m.monk2, m.attributes[2]),
d.averageGain(m.monk2, m.attributes[3]),
d.averageGain(m.monk2, m.attributes[4]),
d.averageGain(m.monk2, m.attributes[5]),
)
print("Average Gain for ", "Monk-3")
print(
d.averageGain(m.monk3, m.attributes[0]),
d.averageGain(m.monk3, m.attributes[1]),
d.averageGain(m.monk3, m.attributes[2]),
d.averageGain(m.monk3, m.attributes[3]),
d.averageGain(m.monk3, m.attributes[4]),
d.averageGain(m.monk3, m.attributes[5]),
)
def myBuildTree(dataset, levels):
treeLevels = []
splits = []
treeLevels.append(dataset)
datasubsets = dataset
datasubsetsAvgGains = []
for level in range(0, levels):
print("\n===Level #: ", level)
if level == 0:
attribAvgGains = []
largestGain = 0
largestAttribIndex = 0
if len(datasubsets) > 5:
for attribute in range(0, len(m.attributes)):
avgGain = d.averageGain(datasubsets, m.attributes[attribute])
if avgGain > largestGain:
largestGain = avgGain
largestAttribIndex = attribute
attribAvgGains.append(avgGain)
print("Attribute: ", attribute, "\t\tAverage gain: ", avgGain)
datasubsetsAvgGains.append(attribAvgGains)
print("---Splitting at attribute: ", m.attributes[largestAttribIndex])
datasubsets = split(datasubsets, m.attributes[largestAttribIndex])
splits.append(m.attributes[largestAttribIndex])
treeLevels.append(datasubsets)
elif level > 0:
print("---No. of datasets: ", len(datasubsets))
newdatasubsets = []
for i in range(0, len(datasubsets)):
print("\n---Datasubset: ", i, "\t\tEntropy: ", d.entropy(datasubsets[i]))
attribAvgGains = []
newdatasubsets = []
largestGain = 0
largestAttribIndex = 0
if len(datasubsets[i]) > 5:
for attribute in range(0, len(m.attributes)):
avgGain = d.averageGain(datasubsets[i], m.attributes[attribute])
if avgGain > largestGain:
largestGain = avgGain
largestAttribIndex = attribute
attribAvgGains.append(avgGain)
print("Attribute: ", attribute, "\t\tAverage gain: ", avgGain)
if avgGain > 0:
print("---Splitting at attribute: ", m.attributes[largestAttribIndex].name)
newdatasubsets.append(split(datasubsets[i], m.attributes[largestAttribIndex]))
splits.append(m.attributes[largestAttribIndex])
else:
print(
"---Skipping splitting at attribute: ",
m.attributes[largestAttribIndex].name,
"Dataset #",
i,
)
datasubsetsAvgGains.append(attribAvgGains)
if len(newdatasubsets[0]) > 1:
datasubsets = newdatasubsets[0]
print("---No. of New datasets: ", len(datasubsets))
treeLevels.append(datasubsets)
return splits
__author__ = 'swebo_000'
import monkdata as m
import dtree as d
#import drawtree
monkset = [m.monk1, m.monk2, m.monk3]
print("1. Entropy of the MONK datasets:")
for x in range(0, len(monkset)):
print("MONK-%d: %f" % (x+1, d.entropy(monkset[x])))
print();
print("2. Information gain from attributes:")
for set in monkset:
print("MONK-%d" % (monkset.index(set) + 1))
for x in range(0, len(m.attributes)):
print("Attribute %d: %f" %(x+1, d.averageGain(set, m.attributes[x])))
print()
pruned_trees_performance = [0 for x in range(len(pruned_trees))]
for candidate in pruned_trees:
index = pruned_trees.index(candidate)
pruned_trees_performance[index] = d.check(candidate, validation)
if d.check(tree, validation) <= max(pruned_trees_performance):
tree = pruned_trees[pruned_trees_performance.index(max(pruned_trees_performance))]
tree = prune_tree(tree, validation)
return tree
print(d.entropy(m.monk1))
print(d.entropy(m.monk2))
print(d.entropy(m.monk3))
print("\n")
print("monk-1: %f %f %f %f %f %f" % (
d.averageGain(m.monk1, m.attributes[0]), d.averageGain(m.monk1, m.attributes[1]),
d.averageGain(m.monk1, m.attributes[2]), d.averageGain(m.monk1, m.attributes[3]),
d.averageGain(m.monk1, m.attributes[4]), d.averageGain(m.monk1, m.attributes[5])
))
print("monk-2: %f %f %f %f %f %f" % (
d.averageGain(m.monk2, m.attributes[0]), d.averageGain(m.monk2, m.attributes[1]),
d.averageGain(m.monk2, m.attributes[2]), d.averageGain(m.monk2, m.attributes[3]),
d.averageGain(m.monk2, m.attributes[4]), d.averageGain(m.monk2, m.attributes[5])
))
print("monk-3: %f %f %f %f %f %f" % (
d.averageGain(m.monk3, m.attributes[0]), d.averageGain(m.monk3, m.attributes[1]),
d.averageGain(m.monk3, m.attributes[2]), d.averageGain(m.monk3, m.attributes[3]),
d.averageGain(m.monk3, m.attributes[4]), d.averageGain(m.monk3, m.attributes[5])
))
def getClasification(dataset,fraction):
monk1train, monk1val = partition(dataset,fraction)
testTree = tree.buildTree(monk1val,m.attributes)
prunedTrees = tree.allPruned(testTree)
pValue = 0
for pruned in prunedTrees:
if(tree.check(pruned,monk1train) > pValue):
bestTree = pruned
pValue = tree.check(pruned,monk1train)
return pValue, bestTree
print "Entropy Monk1: " + str(tree.entropy(m.monk1))
print "Entropy Monk2: " + str(tree.entropy(m.monk2))
print "Entropy Monk3: " + str(tree.entropy(m.monk3))
print "Gain Monk1 a1: " + str(tree.averageGain(m.monk1,m.attributes[0]))
print "Gain Monk1 a2: " + str(tree.averageGain(m.monk1,m.attributes[1]))
print "Gain Monk1 a3: " + str(tree.averageGain(m.monk1,m.attributes[2]))
print "Gain Monk1 a4: " + str(tree.averageGain(m.monk1,m.attributes[3]))
print "Gain Monk1 a5: " + str(tree.averageGain(m.monk1,m.attributes[4]))
print "Gain Monk1 a6: " + str(tree.averageGain(m.monk1,m.attributes[5]))
print "Gain Monk2 a1: " + str(tree.averageGain(m.monk2,m.attributes[0]))
print "Gain Monk2 a2: " + str(tree.averageGain(m.monk2,m.attributes[1]))
print "Gain Monk2 a3: " + str(tree.averageGain(m.monk2,m.attributes[2]))
print "Gain Monk2 a4: " + str(tree.averageGain(m.monk2,m.attributes[3]))
print "Gain Monk2 a5: " + str(tree.averageGain(m.monk2,m.attributes[4]))
print "Gain Monk2 a6: " + str(tree.averageGain(m.monk2,m.attributes[5]))
print "Gain Monk3 a1: " + str(tree.averageGain(m.monk3,m.attributes[0]))
print "Gain Monk3 a2: " + str(tree.averageGain(m.monk3,m.attributes[1]))
#!/usr/bin/env python
import dtree as d
import monkdata as m
monkset = [m.monk1, m.monk2, m.monk3]
mtrain = [m.monk1test, m.monk2test, m.monk3test]
#Assignement 1
print 'Entropy for monk1-3'
j = 1
for monk in monkset:
#s = '\ta' + str(j++) + ': ' + str(d.entropy(monk))
print d.entropy(monk)
#Assignement 2
attributes = [0, 0, 0]
print '\nInformation gain for attributes a1 to a6'
for i in range(0, len(monkset)):
print 'Monk', i+1
s = ""
greatest = 0
for x in range(0, 6):
averageGain = d.averageGain(monkset[i], m.attributes[x])
if averageGain > greatest: greatest = averageGain
s = s + str(averageGain)+ ' '
print s
attributes[i] = greatest
def printGains(datasets, attributes):
# Print GAIN for all datasets
for i in range(0, len(datasets)):
for j in range(0,len(attributes)):
print("Gain monk"+str(i+1)+", a"+str(j+1)+": "+str(d.averageGain(datasets[i], attributes[j])))
print("---------------")
#Entorpy
#calling the predefined function that calculates the entropy for all the three datasets
#assignment 1
print dt.entropy(m.monk1)
print dt.entropy(m.monk2)
print dt.entropy(m.monk3)
print '\n'
##############################################################################
#Information Gain
#cycles for calling average gains for all the three datasets and for every attribute
#assignment 2
for atr in m.attributes:
gain = dt.averageGain(m.monk1, atr)
print gain
print '\n'
for atr in m.attributes:
print dt.averageGain(m.monk2, atr)
print '\n'
for atr in m.attributes:
print dt.averageGain(m.monk3, atr)
print '\n'
#############################################################################
#Building decision trees
def calcgainforset(dataset, name):
for attr in m.attributes:
print("Information Gain %s %s %f" % (name, attr.name, d.averageGain(dataset, attr)))
print()
#Assignment 1 calculatee enropy
print("")
m1e = dt.entropy(m.monk1)
m2e = dt.entropy(m.monk2)
m3e = dt.entropy(m.monk3)
print("Monk1 entropy: ", m1e)
print("Monk2 entropy: ", m2e)
print("Monk3 entropy: ", m3e)
print("")
M1 = []
M2 = [None]*6
M3 = [None]*6
for i in range(6):
M1.append(dt.averageGain(m.monk1, m.attributes[i]))
M2[i] = dt.averageGain(m.monk2, m.attributes[i])
M3[i] = dt.averageGain(m.monk3, m.attributes[i])
print("\ta1: \ta2: \ta3: \ta4: \ta5: \ta6:")
print_average_gains(M1, "M1")
print_average_gains(M2, "M2")
print_average_gains(M3, "M3")
#t = dt.buildTree(m.monk1, m.attributes)
#dw.drawtree(dt.check(t, m.monk1test))
#print(dt.check(t, m.monk1test))
def calculateGainTuplesForAllAttributes(dataset, attributes):
gainlist = [d.averageGain(dataset, m.attributes[i]) for i in range(attributes.__len__())]
return zip(gainlist, range(attributes.__len__()))
import matplotlib.pyplot as plot
sets = [monkdata.monk1, monkdata.monk2, monkdata.monk3]
entropies = [dtree.entropy(s) for s in sets]
def printlines(values):
for line in values:
print(', '.join(map(str, line)))
print("Initial entropies:")
print(entropies)
print("")
gain = [[dtree.averageGain(s, attr) for attr in monkdata.attributes] for s in sets]
print("Expected gain:")
printlines(gain)
print("")
def tests(pair):
tree=dtree.buildTree(pair[0], monkdata.attributes)
return [
pair[2],
dtree.check(tree,pair[0]),
dtree.check(tree,pair[1])
]
setpairs = [
t = d.buildTree(m.monk1, m.attributes)
print(d.check(t, m.monk1))
print(d.check(t, m.monk1test))
t = d.buildTree(m.monk2, m.attributes)
print(d.check(t, m.monk2))
print(d.check(t, m.monk2test))
t = d.buildTree(m.monk3, m.attributes)
print(d.check(t, m.monk3))
print(d.check(t, m.monk3test))
print("First Node IG")
for i in range(0, 6):
print(d.averageGain(m.monk1, m.attributes[i]))
a5_1 = d.select(m.monk1, m.attributes[4], 1)
a5_2 = d.select(m.monk1, m.attributes[4], 2)
a5_3 = d.select(m.monk1, m.attributes[4], 3)
a5_4 = d.select(m.monk1, m.attributes[4], 4)
print("subset a5_1 IG")
for i in range(6):
print(d.averageGain(a5_1, m.attributes[i]))
print("subset a5_2 IG")
for i in range(6):
print(d.averageGain(a5_2, m.attributes[i]))
print("subset a5_3 IG")
accuracy = d.check(final_tree, test_data)
#print("Accuracy for Monk1.test", accuracy)
return accuracy
print(d.entropy(m.monk1))
print(d.entropy(m.monk2))
print(d.entropy(m.monk3))
#Printout the entropy of all datasets.
a = list()
b = list()
c = list()
for i in range(0, 6, 1):
a.append(d.averageGain(m.monk1, m.attributes[i]))
for i in range(0, 6, 1):
b.append(d.averageGain(m.monk2, m.attributes[i]))
for i in range(0, 6, 1):
c.append(d.averageGain(m.monk3, m.attributes[i]))
print(a)
print(b)
print(c)
#
#Calculate and printout the information get for all properties and datasets.
#
#r = d.select(m.monk1, m.attributes[1], 2)
#for x in r:
# print(x.attribute, "Positive:", x.positive)
def getClasification(dataset,fraction):
monk1train, monk1val = partition(dataset,fraction)
testTree = tree.buildTree(monk1val,m.attributes)
prunedTrees = tree.allPruned(testTree)
pValue = 0
for pruned in prunedTrees:
if(tree.check(pruned,monk1train) > pValue):
bestTree = pruned
pValue = tree.check(pruned,monk1train)
return pValue, bestTree
print "Entropy Monk1: " + str(tree.entropy(m.monk1))
print "Entropy Monk2: " + str(tree.entropy(m.monk2))
print "Entropy Monk3: " + str(tree.entropy(m.monk3))
print "Gain Monk1 a1: " + str(tree.averageGain(m.monk1,m.attributes[0]))
print "Gain Monk1 a2: " + str(tree.averageGain(m.monk1,m.attributes[1]))
print "Gain Monk1 a3: " + str(tree.averageGain(m.monk1,m.attributes[2]))
print "Gain Monk1 a4: " + str(tree.averageGain(m.monk1,m.attributes[3]))
print "Gain Monk1 a5: " + str(tree.averageGain(m.monk1,m.attributes[4]))
print "Gain Monk1 a6: " + str(tree.averageGain(m.monk1,m.attributes[5]))
print "Gain Monk2 a1: " + str(tree.averageGain(m.monk2,m.attributes[0]))
print "Gain Monk2 a2: " + str(tree.averageGain(m.monk2,m.attributes[1]))
print "Gain Monk2 a3: " + str(tree.averageGain(m.monk2,m.attributes[2]))
print "Gain Monk2 a4: " + str(tree.averageGain(m.monk2,m.attributes[3]))
print "Gain Monk2 a5: " + str(tree.averageGain(m.monk2,m.attributes[4]))
print "Gain Monk2 a6: " + str(tree.averageGain(m.monk2,m.attributes[5]))
print "Gain Monk3 a1: " + str(tree.averageGain(m.monk3,m.attributes[0]))
print "Gain Monk3 a2: " + str(tree.averageGain(m.monk3,m.attributes[1]))
################
#Setting up lists
info_gain_m1 = []
info_gain_m2 = []
info_gain_m3 = []
attribute = []
#starting counter
i = 0;
#iterating over all the test sets
for sets in [info_gain_m1, info_gain_m2, info_gain_m3]:
#for all attributes in the sets, the average information gain is added to the list
for k in range(6):
attribute.append(dtree.averageGain(data_sets[i], m.attributes[k]));
sets.append(attribute)
attribute = []
i += 1;
#print(info_gain_m1)
#print(info_gain_m2)
#print(info_gain_m3)
# Assignment 3 #
################
selected = dtree.select(m.monk1, m.attributes[4], 1)
t=dtree.buildTree(m.monk1, m.attributes);
print "Monk1 entropy: ", init_entropy_monk1 print "Monk2 entropy: ", init_entropy_monk2 print "Monk3 entropy: ", init_entropy_monk3 print print "------------------------------" print "-------- Assignment 2 --------" print gain_monk1 = [] gain_monk2 = [] gain_monk3 = [] for x in range(0, 6): gain_monk1.append(dt.averageGain(m.monk1,m.attributes[x])) gain_monk2.append(dt.averageGain(m.monk2,m.attributes[x])) gain_monk3.append(dt.averageGain(m.monk3,m.attributes[x])) print "Dataset\tA1\t\tA2\t\tA3\t\tA4\t\tA5\t\tA6" print "Monk1: ","\t".join(["%.7f"%y for y in gain_monk1]) print "Monk2: ","\t".join(["%.7f"%y for y in gain_monk2]) print "Monk3: ","\t".join(["%.7f"%y for y in gain_monk3]) print print "------------------------------" print "-------- Assignment 3 --------" print partition1 = dt.select(m.monk1,m.attributes[4],1)
a = dtree.bestAttribute(mdata.monk1, mdata.attributes)
attributesLeft = [x for x in mdata.attributes if x != a]
#print(a,attributesLeft) #a5
subsets = []
for v in a.values:
temp = dtree.select(mdata.monk1, a, v)
subsets.append(temp)
ag_in2level = []
subsets_ag = []
#print(len(a.values))
for subset in subsets:
for i in range(len(attributesLeft)):
gain1 = dtree.averageGain(subset, attributesLeft[i])
ag_in2level.append(gain1)
subsets_ag.append(ag_in2level)
ag_in2level = []
#print(subsets_ag)
def Tree(dataset, attributes, maxdepth=3):
def Branch(dataset, default, attributes):
if not dataset:
return dtree.TreeLeaf(default)
if dtree.allPositive(dataset):
return dtree.TreeLeaf(True)
if dtree.allNegative(dataset):
return dtree.TreeLeaf(False)
return Tree(dataset, attributes, maxdepth - 1)
def avgForDataset(dataset):
res = "";
for attr in m.attributes:
res += "{:.5f}".format(d.averageGain(dataset, attr))
res += " "
return res
def printAverageGain(s, dataset):
for x in range(0, 6):
s = s + str(dt.averageGain(dataset, m.attributes[x])) + " "
print(s)
print("Average gain\n")
import monkdata as m
from dtree import entropy
from dtree import averageGain
print(entropy(m.monk1), 'monk1')
print(entropy(m.monk2), 'monk2')
print(entropy(m.monk3), 'monk3')
for i in range(6):
print("\nattribute ", i)
print(averageGain(m.monk1, m.attributes[i]))
print(averageGain(m.monk2, m.attributes[i]))
print(averageGain(m.monk3, m.attributes[i]))
import monkdata as m
import dtree as dtree
datasets = [{
'name': 'monk1',
'ref': m.monk1
}, {
'name': 'monk2',
'ref': m.monk2
}, {
'name': 'monk3',
'ref': m.monk3
}]
print "Sample class: " + m.Sample.__doc__
# TODO:
# print dtree.averageGain(m.monk1, m.attributes)
for dataset in datasets:
print " Dataset: " + dataset['name']
i = 0
for attribute in m.attributes:
print "a%s - %s" % (i, dtree.averageGain(dataset['ref'], attribute))
i = i + 1
print "monk3 "+ str(d.entropy(m.monk3))
print ""
print ""
#finding information average gain
print " Assignment2"
att =[x for x in m.attributes]
monkar = [m.monk1, m.monk2, m.monk3]
for j in monkar:
entropyGain=[]
for i in att :
entropyGain.append(d.averageGain(j,i))
for i in entropyGain:
print i
print "The attribute used for splitting in data set MONK%d is A%d which has an entropy of %f"%(monkar.index(j)+1,entropyGain.index(max(entropyGain))+1, max(entropyGain))
print ""
print ""
#Building decision Trees
print "Assignment 3"
k=0
print " "+ "e-train " +"e-test"
onkar=[m.monk1test, m.monk2test, m.monk3test]
for j, i in zip(monkar, onkar):
k=k+1
