175 lines
5.3 KiB
Python
175 lines
5.3 KiB
Python
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import itertools
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import random
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from data.Order import Order
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from data.enum.GeneticMutationType import GeneticMutationType
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from data.enum.Priority import Priority
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class GeneticOrder:
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mutation_chance = 50
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reverse_chance = 20
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cross_chance = 10
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best_fit_special = 40
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best_fit_special_2 = 20
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population_size = 500
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def __init__(self, orders: [Order]) -> None:
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self.number_of_populations = 10000
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self.orders = orders
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def get_mutation_type(self) -> GeneticMutationType:
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x = random.randint(0, self.mutation_chance + self.cross_chance + self.reverse_chance)
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if (x < self.mutation_chance):
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return GeneticMutationType.MUTATION
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if (x > self.mutation_chance + self.cross_chance):
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return GeneticMutationType.REVERSE
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return GeneticMutationType.CROSS
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def mutation(self, population: [int]) -> [int]:
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x = random.randint(0, len(population)-1)
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y = random.randint(0, len(population)-1)
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while x == y:
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y = random.randint(0, len(population)-1)
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result = population
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pom = population[x]
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result[x] = population[y]
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result[y] = pom
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if(result[x] == result[y]):
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print("PIZDA I CHUJ")
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return result
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def cross(self, population: [int]) -> [int]:
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x = random.randint(1, len(population)-1)
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result = []
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for i in range(len(population)):
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result.append(population[(i + x) % len(population)])
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return result
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def reverse(self, population: [int]) -> [int]:
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x = random.randint(0, len(population))
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y = random.randint(0, len(population)-1)
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while x >= y:
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x = random.randint(0, len(population))
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y = random.randint(0, len(population)-1)
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result = []
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# print("X: ", x, " y: ", y)
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for i in range(len(population)):
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if x <= i <= y:
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new_i = i - x
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# print("len:", len(population), " new_i: ", new_i)
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result.append(population[y - new_i])
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else:
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result.append(population[i])
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return result
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def generate_first_population(self, k: int) -> [[int]]:
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result = []
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s = range(len(self.orders))
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p = itertools.permutations(s)
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while len(result) < k:
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n = p.__next__()
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if n not in result:
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result.append(n)
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return [list(x) for x in result]
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# result = itertools.permutations(range(len(self.orders)))
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#
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# return [list(x) for x in result]
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def evaluate(self, member: [int]) -> int:
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result = 0
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for i in range(len(self.orders) - 1):
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x: Order = self.orders[member[i]]
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y: Order = self.orders[member[i + 1]]
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if ((x.priority == Priority.MEDIUM or x.priority == Priority.LOW) and y.priority == Priority.HIGH) or (x.priority == Priority.LOW and y.priority == Priority.MEDIUM):
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result += 5000
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elif x.sum / x.time < y.sum / y.time:
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result += y.sum * 5 + y.time
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return result
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def mutate_population(self, order_population: [[int]]) -> [[int]]:
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result = []
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for i in range(len(order_population)):
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member: [int] = order_population[i]
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operation: GeneticMutationType = self.get_mutation_type()
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if operation == GeneticMutationType.MUTATION:
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member = self.mutation(member)
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elif operation == GeneticMutationType.REVERSE:
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member = self.reverse(member)
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else:
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member = self.cross(member)
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result.append(member)
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return result
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def get_next_population(self, population: [[int]]) -> [[int]]:
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result = []
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result = population
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# for i in range(len(population) - self.best_fit_special):
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# result.append(population[i])
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#
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# k = len(population) - self.best_fit_special
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# while k < len(population) - self.best_fit_special_2:
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# n = random.randint(0, self.best_fit_special)
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# result.append(population[n])
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#
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# left_size = len(population) - k
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# while left_size < len(population):
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# n = random.randint(0, self.best_fit_special_2)
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# result.append(population[n])
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return result
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def get_orders_sorted(self, orders: [Order]) -> [Order]:
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self.orders = orders
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population: [[int]] = self.generate_first_population(self.population_size)
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print(population)
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population.sort(key=self.evaluate)
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best_fit: [int] = population[0]
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for i in range(self.number_of_populations):
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# print("population: ", i)
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population = self.mutate_population(population)
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population.sort(key=self.evaluate)
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if self.evaluate(best_fit) > self.evaluate(population[0]):
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best_fit = population[0]
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# population = self.get_next_population(population).sort(key=self.evaluate)
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if self.evaluate(best_fit) < self.evaluate(population[0]):
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population[0] = best_fit
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best: [int] = population[0]
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result: [Order] = []
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for i in range(len(best)):
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result.append(self.orders[best[i]])
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return result
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