alexprengere/main.py

## main.py
#!/usr/bin/env python
# -*- coding: utf-8 -*-

"""
Code from https://lethain.com/genetic-algorithms-cool-name-damn-simple
"""

from random import randint, random
from operator import add


def individual(length, min, max):
    'Create a member of the population.'
    return [randint(min, max) for x in xrange(length)]


def population(count, length, min, max):
    """
    Create a number of individuals (i.e. a population).

    count: the number of individuals in the population
    length: the number of values per individual
    min: the minimum possible value in an individual's list of values
    max: the maximum possible value in an individual's list of values

    """
    return [individual(length, min, max) for x in xrange(count)]


def fitness(individual, target):
    """
    Determine the fitness of an individual. Higher is better.

    individual: the individual to evaluate
    target: the target number individuals are aiming for
    """
    sum = reduce(add, individual, 0)
    return abs(target - sum)


def grade(pop, target):
    'Find average fitness for a population.'
    summed = reduce(add, (fitness(x, target) for x in pop))
    return summed / (len(pop) * 1.0)


def evolve(pop, target, retain=0.2, random_select=0.05, mutate=0.01):
    graded = [(fitness(x, target), x) for x in pop]
    graded = [x[1] for x in sorted(graded)]
    retain_length = int(len(graded) * retain)
    parents = graded[:retain_length]
    # randomly add other individuals to
    # promote genetic diversity
    for individual in graded[retain_length:]:
        if random_select > random():
            parents.append(individual)
    # mutate some individuals
    for individual in parents:
        if mutate > random():
            pos_to_mutate = randint(0, len(individual) - 1)
            # this mutation is not ideal, because it
            # restricts the range of possible values,
            # but the function is unaware of the min/max
            # values used to create the individuals,
            individual[pos_to_mutate] = randint(
                min(individual), max(individual))
    # crossover parents to create children
    parents_length = len(parents)
    desired_length = len(pop) - parents_length
    children = []
    while len(children) < desired_length:
        male = randint(0, parents_length - 1)
        female = randint(0, parents_length - 1)
        if male != female:
            male = parents[male]
            female = parents[female]
            half = len(male) / 2
            child = male[:half] + female[half:]
            children.append(child)
    parents.extend(children)
    return parents


if __name__ == '__main__':
    target = 371
    p_count = 100
    i_length = 6
    i_min = 0
    i_max = 100
    p = population(p_count, i_length, i_min, i_max)
    fitness_history = [grade(p, target)]
    for i in xrange(100):
        p = evolve(p, target)
        fitness_history.append(grade(p, target))

    for datum in fitness_history:
        print datum
	#!/usr/bin/env python
	# -- coding: utf-8 --

	"""
	Code from https://lethain.com/genetic-algorithms-cool-name-damn-simple
	"""

	from random import randint, random
	from operator import add


	def individual(length, min, max):
	'Create a member of the population.'
	return [randint(min, max) for x in xrange(length)]


	def population(count, length, min, max):
	"""
	Create a number of individuals (i.e. a population).

	count: the number of individuals in the population
	length: the number of values per individual
	min: the minimum possible value in an individual's list of values
	max: the maximum possible value in an individual's list of values

	"""
	return [individual(length, min, max) for x in xrange(count)]


	def fitness(individual, target):
	"""
	Determine the fitness of an individual. Higher is better.

	individual: the individual to evaluate
	target: the target number individuals are aiming for
	"""
	sum = reduce(add, individual, 0)
	return abs(target - sum)


	def grade(pop, target):
	'Find average fitness for a population.'
	summed = reduce(add, (fitness(x, target) for x in pop))
	return summed / (len(pop) * 1.0)


	def evolve(pop, target, retain=0.2, random_select=0.05, mutate=0.01):
	graded = [(fitness(x, target), x) for x in pop]
	graded = [x[1] for x in sorted(graded)]
	retain_length = int(len(graded) * retain)
	parents = graded[:retain_length]
	# randomly add other individuals to
	# promote genetic diversity
	for individual in graded[retain_length:]:
	if random_select > random():
	parents.append(individual)
	# mutate some individuals
	for individual in parents:
	if mutate > random():
	pos_to_mutate = randint(0, len(individual) - 1)
	# this mutation is not ideal, because it
	# restricts the range of possible values,
	# but the function is unaware of the min/max
	# values used to create the individuals,
	individual[pos_to_mutate] = randint(
	min(individual), max(individual))
	# crossover parents to create children
	parents_length = len(parents)
	desired_length = len(pop) - parents_length
	children = []
	while len(children) < desired_length:
	male = randint(0, parents_length - 1)
	female = randint(0, parents_length - 1)
	if male != female:
	male = parents[male]
	female = parents[female]
	half = len(male) / 2
	child = male[:half] + female[half:]
	children.append(child)
	parents.extend(children)
	return parents


	if __name__ == '__main__':
	target = 371
	p_count = 100
	i_length = 6
	i_min = 0
	i_max = 100
	p = population(p_count, i_length, i_min, i_max)
	fitness_history = [grade(p, target)]
	for i in xrange(100):
	p = evolve(p, target)
	fitness_history.append(grade(p, target))

	for datum in fitness_history:
	print datum