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1e5f02e5ce
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coolneng | 1e5f02e5ce |
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@ -4,6 +4,7 @@ from pandas import DataFrame
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from math import ceil
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from functools import partial
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from multiprocessing import Pool
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from copy import deepcopy
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from preprocessing import parse_file
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@ -169,7 +170,7 @@ def mutate(offspring, data, probability=0.001):
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return offspring
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def get_individual_index(population, element):
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def get_individual_index(element, population):
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for index in range(len(population)):
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if population[index].fitness.values[0] == element.fitness.values[0]:
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return index
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@ -178,25 +179,33 @@ def get_individual_index(population, element):
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def tournament_selection(population):
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individuals = [population[randint(len(population))] for _ in range(2)]
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best_element = max(individuals, key=lambda x: x.fitness.values[0])
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population_index = get_individual_index(population, best_element)
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population_index = get_individual_index(best_element, population)
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return best_element, population_index
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def generational_replacement(previous_population, current_population):
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def check_element_population(element, population):
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for item in population:
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if all(element.point.values) == all(item.point.values):
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return True
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return False
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def generational_replacement(prev_population, current_population):
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new_population = current_population
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best_previous_individual = max(previous_population, key=lambda x: all(x.fitness))
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if best_previous_individual not in new_population:
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worst_index = new_population.index(
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min(new_population, key=lambda x: all(x.fitness))
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)
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best_previous_individual = max(prev_population, key=lambda x: x.fitness.values[0])
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if check_element_population(best_previous_individual, new_population):
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worst_element = min(new_population, key=lambda x: x.fitness.values[0])
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worst_index = get_individual_index(worst_element, new_population)
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new_population[worst_index] = best_previous_individual
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return new_population
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def get_best_elements(population):
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first_index = population.index(max(population, key=lambda x: all(x.fitness)))
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first_element = max(population, key=lambda x: x.fitness.values[0])
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first_index = get_individual_index(first_element, population)
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population.pop(first_index)
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second_index = population.index(max(population, key=lambda x: all(x.fitness)))
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second_element = max(population, key=lambda x: x.fitness.values[0])
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second_index = get_individual_index(second_element, population)
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return first_index, second_index
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@ -231,7 +240,7 @@ def evaluate_population(population, data, cores=4):
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def select_parents(population, n, mode):
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select_population = population
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select_population = deepcopy(population)
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parents = []
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if mode == "generational":
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for _ in range(n):
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@ -255,8 +264,8 @@ def genetic_algorithm(n, m, data, select_mode, crossover_mode, max_iterations=10
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offspring = mutate(offspring, data)
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population = replace_population(population, offspring, select_mode)
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population = evaluate_population(population, data)
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best_solution, _ = get_best_elements(population)
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return best_solution
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best_index, _ = get_best_elements(population)
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return population[best_index]
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n, m, data = parse_file("data/GKD-c_11_n500_m50.txt")
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