def __init__(self, data, gene_length, genome_length):
""""""
BinaryClassifier.__init__(self, data, gene_length, genome_length)
self.representation = Representation(
{"length": genome_length, "type": "enum", "values": ["0", "1"], "duplicates": True}
)
self.population_size = 100
self.generations = 250
self.selection_func = tournament
self.tournament_size = 10
self.genome_lengths = list()
self.mutation_prob = 0.01
self.mutation_func = self.mutation_func_variable_length
self.crossover_prob = 0.2
self.elite_count = 6
def main():
"""
Run the classification GA on the data file given on the the command line
"""
if len(sys.argv) != 2:
sys.exit('usage: classifier.py datafile')
data_file = sys.argv[1]
with open(data_file, 'r') as f:
# Read the first (informational) line
info_line = f.readline().split()
# Set length of variables + class
gene_length = int(info_line[3]) + 1
# Derive the length of an individual
genome_length = (int(info_line[0]) * gene_length)
# Binary data (data1.txt)
if genome_length == 192:
data = [list(line.rstrip().replace(' ', '')) for line in f]
classifier = BinaryClassifier(data, gene_length,
genome_length)
# Binary data (data2.txt)
elif genome_length == 448:
data = [list(line.rstrip().replace(' ', '')) for line in f]
classifier = VariableLengthBinaryClassifier(data, gene_length,
genome_length)
# Real-valued data
elif genome_length == 14000:
data = [map(float, line.rstrip().split()) for line in f]
# 2 floats (upper, lower) per "bit", plus class
gene_length = (gene_length * 2) - 2
genome_length = (int(info_line[0]) * gene_length)
classifier = RealValueClassifier(data, gene_length,
genome_length)
else:
raise IOError('unknown data file format')
print '[i] loaded data file:', data_file
#---------------------------------------------------------------------------
# Generate the initial population
#---------------------------------------------------------------------------
generations = classifier.generations
p = Population(representation=classifier.representation,
size=classifier.population_size,
fitness_func=classifier.fitness_func,
selection_func=classifier.selection_func,
crossover_func=classifier.crossover_func,
mutation_func=classifier.mutation_func,
natural_fitness=True,
crossover_probability=classifier.crossover_prob,
mutation_probability=classifier.mutation_prob,
elite_count=classifier.elite_count,
tournament_size=classifier.tournament_size)
p.gen_population()
#---------------------------------------------------------------------------
# Fiddle the population (ugly hack alert)
#---------------------------------------------------------------------------
step = classifier.gene_length
if isinstance(classifier, VariableLengthBinaryClassifier):
for individual in p:
# Fix a 0 or 1 in the class position
for i in xrange(step - 1, len(individual.genes), step):
if individual.genes[i] == '#':
individual.genes[i] = '1' if random.random() < 0.5 else '0'
classifier.genome_lengths.append(len(individual.genes))
if isinstance(classifier, RealValueClassifier):
for i, individual in enumerate(p.population):
new_genes = list()
average_sigmas = list()
individual.average_sigmas = list()
for genes in classifier.batch_gen(individual.genes,
classifier.gene_length):
g = Gene(genes)
g.class_label = 1 if random.random() < 0.5 else 0
g.mutation_step_sizes = [0.05 for _
in xrange(classifier.gene_length)]
new_genes.append(g)
# Update info for plotter
average_sigmas.append(sum(g.mutation_step_sizes)
/ len(g.mutation_step_sizes))
individual.genes = new_genes
individual.average_sigmas.append(sum(average_sigmas)
/ len(average_sigmas))
# Add strategy parameters
individual.strategy_params = {'mutation_step_size':
0.05}
print '[i] fiddled population'
# if hasattr(classifier, 'genome_lengths'):
# p.add_to_plot([len(i) for i in p], 'avg genome length')
#---------------------------------------------------------------------------
# Run the GA
#---------------------------------------------------------------------------
p.run(generations)
#---------------------------------------------------------------------------
# Validate the population
#---------------------------------------------------------------------------
print
avg = 0
for individual in p:
avg += classifier.fitness_func(individual.genes, validate=True)
print 'min individual: %d/%dt, %d/%dv (len=%d, num genes=%d) %s' % \
(classifier.fitness_func(p.min_individual().genes),
len(classifier.training_set),
classifier.fitness_func(p.min_individual().genes, validate=True),
len(classifier.validation_set),
len(p.min_individual()),
len(p.min_individual()) / classifier.gene_length,
p.min_individual())
print 'mean validation fitness:', avg / len(p)
print 'max individual: %d/%dt, %d/%dv (len=%d, num genes=%d) %s' % \
(classifier.fitness_func(p.max_individual().genes),
len(classifier.training_set),
classifier.fitness_func(p.max_individual().genes, validate=True),
len(classifier.validation_set),
len(p.max_individual()),
len(p.max_individual()) / classifier.gene_length,
p.max_individual())
# TODO: plot amount of generalisation
if isinstance(classifier, VariableLengthBinaryClassifier):
data = list()
for chunk in classifier.chunker(classifier.genome_lengths, p.size):
data.append(sum(chunk) / len(chunk))
p.add_to_plot(data, 'avg genome length')
for gene in classifier.chunker(p.max_individual().genes,
classifier.gene_length):
print gene[:-1], gene[-1]
elif isinstance(classifier, RealValueClassifier):
data = list()
for chunk in chunker(p.average_sigmas, p.size):
data.append(sum(chunk) / len(chunk))
p.add_to_plot(data, 'average sigma')
for gene in p.max_individual().genes:
for pair in chunker(gene.alleles, 2):
print pair
print gene.class_label
print
p.show_plot()
