""" Use an ant colony optimization algorithm to solve the travelling salesman problem (TSP) which asks the following question: "Given a list of cities and the distances between each pair of cities, what is the shortest possible route that visits each city exactly once and returns to the origin city?" https://en.wikipedia.org/wiki/Ant_colony_optimization_algorithms https://en.wikipedia.org/wiki/Travelling_salesman_problem Author: Clark """ import copy import random cities = { 0: [0, 0], 1: [0, 5], 2: [3, 8], 3: [8, 10], 4: [12, 8], 5: [12, 4], 6: [8, 0], 7: [6, 2], } def main( cities: dict[int, list[int]], ants_num: int, iterations_num: int, pheromone_evaporation: float, alpha: float, beta: float, q: float, # Pheromone system parameters Q, which is a constant ) -> tuple[list[int], float]: """ Ant colony algorithm main function >>> main(cities=cities, ants_num=10, iterations_num=20, ... pheromone_evaporation=0.7, alpha=1.0, beta=5.0, q=10) ([0, 1, 2, 3, 4, 5, 6, 7, 0], 37.909778143828696) >>> main(cities={0: [0, 0], 1: [2, 2]}, ants_num=5, iterations_num=5, ... pheromone_evaporation=0.7, alpha=1.0, beta=5.0, q=10) ([0, 1, 0], 5.656854249492381) >>> main(cities={0: [0, 0], 1: [2, 2], 4: [4, 4]}, ants_num=5, iterations_num=5, ... pheromone_evaporation=0.7, alpha=1.0, beta=5.0, q=10) Traceback (most recent call last): ... IndexError: list index out of range >>> main(cities={}, ants_num=5, iterations_num=5, ... pheromone_evaporation=0.7, alpha=1.0, beta=5.0, q=10) Traceback (most recent call last): ... StopIteration >>> main(cities={0: [0, 0], 1: [2, 2]}, ants_num=0, iterations_num=5, ... pheromone_evaporation=0.7, alpha=1.0, beta=5.0, q=10) ([], inf) >>> main(cities={0: [0, 0], 1: [2, 2]}, ants_num=5, iterations_num=0, ... pheromone_evaporation=0.7, alpha=1.0, beta=5.0, q=10) ([], inf) >>> main(cities={0: [0, 0], 1: [2, 2]}, ants_num=5, iterations_num=5, ... pheromone_evaporation=1, alpha=1.0, beta=5.0, q=10) ([0, 1, 0], 5.656854249492381) >>> main(cities={0: [0, 0], 1: [2, 2]}, ants_num=5, iterations_num=5, ... pheromone_evaporation=0, alpha=1.0, beta=5.0, q=10) ([0, 1, 0], 5.656854249492381) """ # Initialize the pheromone matrix cities_num = len(cities) pheromone = [[1.0] * cities_num] * cities_num best_path: list[int] = [] best_distance = float("inf") for _ in range(iterations_num): ants_route = [] for _ in range(ants_num): unvisited_cities = copy.deepcopy(cities) current_city = {next(iter(cities.keys())): next(iter(cities.values()))} del unvisited_cities[next(iter(current_city.keys()))] ant_route = [next(iter(current_city.keys()))] while unvisited_cities: current_city, unvisited_cities = city_select( pheromone, current_city, unvisited_cities, alpha, beta ) ant_route.append(next(iter(current_city.keys()))) ant_route.append(0) ants_route.append(ant_route) pheromone, best_path, best_distance = pheromone_update( pheromone, cities, pheromone_evaporation, ants_route, q, best_path, best_distance, ) return best_path, best_distance def distance(city1: list[int], city2: list[int]) -> float: """ Calculate the distance between two coordinate points >>> distance([0, 0], [3, 4] ) 5.0 >>> distance([0, 0], [-3, 4] ) 5.0 >>> distance([0, 0], [-3, -4] ) 5.0 """ return (((city1[0] - city2[0]) ** 2) + ((city1[1] - city2[1]) ** 2)) ** 0.5 def pheromone_update( pheromone: list[list[float]], cities: dict[int, list[int]], pheromone_evaporation: float, ants_route: list[list[int]], q: float, # Pheromone system parameters Q, which is a constant best_path: list[int], best_distance: float, ) -> tuple[list[list[float]], list[int], float]: """ Update pheromones on the route and update the best route >>> >>> pheromone_update(pheromone=[[1.0, 1.0], [1.0, 1.0]], ... cities={0: [0,0], 1: [2,2]}, pheromone_evaporation=0.7, ... ants_route=[[0, 1, 0]], q=10, best_path=[], ... best_distance=float("inf")) ([[0.7, 4.235533905932737], [4.235533905932737, 0.7]], [0, 1, 0], 5.656854249492381) >>> pheromone_update(pheromone=[], ... cities={0: [0,0], 1: [2,2]}, pheromone_evaporation=0.7, ... ants_route=[[0, 1, 0]], q=10, best_path=[], ... best_distance=float("inf")) Traceback (most recent call last): ... IndexError: list index out of range >>> pheromone_update(pheromone=[[1.0, 1.0], [1.0, 1.0]], ... cities={}, pheromone_evaporation=0.7, ... ants_route=[[0, 1, 0]], q=10, best_path=[], ... best_distance=float("inf")) Traceback (most recent call last): ... KeyError: 0 """ for a in range(len(cities)): # Update the volatilization of pheromone on all routes for b in range(len(cities)): pheromone[a][b] *= pheromone_evaporation for ant_route in ants_route: total_distance = 0.0 for i in range(len(ant_route) - 1): # Calculate total distance total_distance += distance(cities[ant_route[i]], cities[ant_route[i + 1]]) delta_pheromone = q / total_distance for i in range(len(ant_route) - 1): # Update pheromones pheromone[ant_route[i]][ant_route[i + 1]] += delta_pheromone pheromone[ant_route[i + 1]][ant_route[i]] = pheromone[ant_route[i]][ ant_route[i + 1] ] if total_distance < best_distance: best_path = ant_route best_distance = total_distance return pheromone, best_path, best_distance def city_select( pheromone: list[list[float]], current_city: dict[int, list[int]], unvisited_cities: dict[int, list[int]], alpha: float, beta: float, ) -> tuple[dict[int, list[int]], dict[int, list[int]]]: """ Choose the next city for ants >>> city_select(pheromone=[[1.0, 1.0], [1.0, 1.0]], current_city={0: [0, 0]}, ... unvisited_cities={1: [2, 2]}, alpha=1.0, beta=5.0) ({1: [2, 2]}, {}) >>> city_select(pheromone=[], current_city={0: [0,0]}, ... unvisited_cities={1: [2, 2]}, alpha=1.0, beta=5.0) Traceback (most recent call last): ... IndexError: list index out of range >>> city_select(pheromone=[[1.0, 1.0], [1.0, 1.0]], current_city={}, ... unvisited_cities={1: [2, 2]}, alpha=1.0, beta=5.0) Traceback (most recent call last): ... StopIteration >>> city_select(pheromone=[[1.0, 1.0], [1.0, 1.0]], current_city={0: [0, 0]}, ... unvisited_cities={}, alpha=1.0, beta=5.0) Traceback (most recent call last): ... IndexError: list index out of range """ probabilities = [] for city, value in unvisited_cities.items(): city_distance = distance(value, next(iter(current_city.values()))) probability = (pheromone[city][next(iter(current_city.keys()))] ** alpha) * ( (1 / city_distance) ** beta ) probabilities.append(probability) chosen_city_i = random.choices( list(unvisited_cities.keys()), weights=probabilities )[0] chosen_city = {chosen_city_i: unvisited_cities[chosen_city_i]} del unvisited_cities[next(iter(chosen_city.keys()))] return chosen_city, unvisited_cities if __name__ == "__main__": best_path, best_distance = main( cities=cities, ants_num=10, iterations_num=20, pheromone_evaporation=0.7, alpha=1.0, beta=5.0, q=10, ) print(f"{best_path = }") print(f"{best_distance = }")