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293 lines
11 KiB
Python
293 lines
11 KiB
Python
"""
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This is pure Python implementation of Tabu search algorithm for a Travelling Salesman
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Problem, that the distances between the cities are symmetric (the distance between city
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'a' and city 'b' is the same between city 'b' and city 'a').
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The TSP can be represented into a graph. The cities are represented by nodes and the
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distance between them is represented by the weight of the ark between the nodes.
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The .txt file with the graph has the form:
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node1 node2 distance_between_node1_and_node2
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node1 node3 distance_between_node1_and_node3
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...
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Be careful node1, node2 and the distance between them, must exist only once. This means
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in the .txt file should not exist:
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node1 node2 distance_between_node1_and_node2
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node2 node1 distance_between_node2_and_node1
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For pytests run following command:
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pytest
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For manual testing run:
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python tabu_search.py -f your_file_name.txt -number_of_iterations_of_tabu_search \
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-s size_of_tabu_search
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e.g. python tabu_search.py -f tabudata2.txt -i 4 -s 3
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"""
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import argparse
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import copy
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def generate_neighbours(path):
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"""
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Pure implementation of generating a dictionary of neighbors and the cost with each
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neighbor, given a path file that includes a graph.
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:param path: The path to the .txt file that includes the graph (e.g.tabudata2.txt)
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:return dict_of_neighbours: Dictionary with key each node and value a list of lists
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with the neighbors of the node and the cost (distance) for each neighbor.
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Example of dict_of_neighbours:
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>>) dict_of_neighbours[a]
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[[b,20],[c,18],[d,22],[e,26]]
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This indicates the neighbors of node (city) 'a', which has neighbor the node 'b'
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with distance 20, the node 'c' with distance 18, the node 'd' with distance 22 and
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the node 'e' with distance 26.
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"""
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dict_of_neighbours = {}
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with open(path) as f:
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for line in f:
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if line.split()[0] not in dict_of_neighbours:
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_list = list()
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_list.append([line.split()[1], line.split()[2]])
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dict_of_neighbours[line.split()[0]] = _list
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else:
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dict_of_neighbours[line.split()[0]].append(
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[line.split()[1], line.split()[2]]
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)
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if line.split()[1] not in dict_of_neighbours:
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_list = list()
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_list.append([line.split()[0], line.split()[2]])
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dict_of_neighbours[line.split()[1]] = _list
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else:
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dict_of_neighbours[line.split()[1]].append(
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[line.split()[0], line.split()[2]]
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)
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return dict_of_neighbours
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def generate_first_solution(path, dict_of_neighbours):
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"""
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Pure implementation of generating the first solution for the Tabu search to start,
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with the redundant resolution strategy. That means that we start from the starting
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node (e.g. node 'a'), then we go to the city nearest (lowest distance) to this node
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(let's assume is node 'c'), then we go to the nearest city of the node 'c', etc.
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till we have visited all cities and return to the starting node.
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:param path: The path to the .txt file that includes the graph (e.g.tabudata2.txt)
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:param dict_of_neighbours: Dictionary with key each node and value a list of lists
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with the neighbors of the node and the cost (distance) for each neighbor.
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:return first_solution: The solution for the first iteration of Tabu search using
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the redundant resolution strategy in a list.
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:return distance_of_first_solution: The total distance that Travelling Salesman
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will travel, if he follows the path in first_solution.
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"""
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with open(path) as f:
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start_node = f.read(1)
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end_node = start_node
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first_solution = []
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visiting = start_node
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distance_of_first_solution = 0
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while visiting not in first_solution:
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minim = 10000
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for k in dict_of_neighbours[visiting]:
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if int(k[1]) < int(minim) and k[0] not in first_solution:
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minim = k[1]
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best_node = k[0]
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first_solution.append(visiting)
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distance_of_first_solution = distance_of_first_solution + int(minim)
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visiting = best_node
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first_solution.append(end_node)
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position = 0
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for k in dict_of_neighbours[first_solution[-2]]:
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if k[0] == start_node:
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break
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position += 1
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distance_of_first_solution = (
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distance_of_first_solution
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+ int(dict_of_neighbours[first_solution[-2]][position][1])
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- 10000
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)
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return first_solution, distance_of_first_solution
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def find_neighborhood(solution, dict_of_neighbours):
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"""
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Pure implementation of generating the neighborhood (sorted by total distance of
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each solution from lowest to highest) of a solution with 1-1 exchange method, that
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means we exchange each node in a solution with each other node and generating a
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number of solution named neighborhood.
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:param solution: The solution in which we want to find the neighborhood.
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:param dict_of_neighbours: Dictionary with key each node and value a list of lists
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with the neighbors of the node and the cost (distance) for each neighbor.
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:return neighborhood_of_solution: A list that includes the solutions and the total
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distance of each solution (in form of list) that are produced with 1-1 exchange
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from the solution that the method took as an input
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Example:
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>>> find_neighborhood(['a', 'c', 'b', 'd', 'e', 'a'],
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... {'a': [['b', '20'], ['c', '18'], ['d', '22'], ['e', '26']],
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... 'c': [['a', '18'], ['b', '10'], ['d', '23'], ['e', '24']],
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... 'b': [['a', '20'], ['c', '10'], ['d', '11'], ['e', '12']],
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... 'e': [['a', '26'], ['b', '12'], ['c', '24'], ['d', '40']],
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... 'd': [['a', '22'], ['b', '11'], ['c', '23'], ['e', '40']]}
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... ) # doctest: +NORMALIZE_WHITESPACE
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[['a', 'e', 'b', 'd', 'c', 'a', 90],
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['a', 'c', 'd', 'b', 'e', 'a', 90],
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['a', 'd', 'b', 'c', 'e', 'a', 93],
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['a', 'c', 'b', 'e', 'd', 'a', 102],
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['a', 'c', 'e', 'd', 'b', 'a', 113],
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['a', 'b', 'c', 'd', 'e', 'a', 119]]
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"""
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neighborhood_of_solution = []
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for n in solution[1:-1]:
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idx1 = solution.index(n)
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for kn in solution[1:-1]:
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idx2 = solution.index(kn)
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if n == kn:
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continue
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_tmp = copy.deepcopy(solution)
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_tmp[idx1] = kn
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_tmp[idx2] = n
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distance = 0
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for k in _tmp[:-1]:
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next_node = _tmp[_tmp.index(k) + 1]
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for i in dict_of_neighbours[k]:
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if i[0] == next_node:
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distance = distance + int(i[1])
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_tmp.append(distance)
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if _tmp not in neighborhood_of_solution:
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neighborhood_of_solution.append(_tmp)
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indexOfLastItemInTheList = len(neighborhood_of_solution[0]) - 1
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neighborhood_of_solution.sort(key=lambda x: x[indexOfLastItemInTheList])
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return neighborhood_of_solution
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def tabu_search(
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first_solution, distance_of_first_solution, dict_of_neighbours, iters, size
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):
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"""
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Pure implementation of Tabu search algorithm for a Travelling Salesman Problem in
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Python.
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:param first_solution: The solution for the first iteration of Tabu search using
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the redundant resolution strategy in a list.
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:param distance_of_first_solution: The total distance that Travelling Salesman will
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travel, if he follows the path in first_solution.
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:param dict_of_neighbours: Dictionary with key each node and value a list of lists
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with the neighbors of the node and the cost (distance) for each neighbor.
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:param iters: The number of iterations that Tabu search will execute.
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:param size: The size of Tabu List.
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:return best_solution_ever: The solution with the lowest distance that occurred
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during the execution of Tabu search.
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:return best_cost: The total distance that Travelling Salesman will travel, if he
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follows the path in best_solution ever.
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"""
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count = 1
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solution = first_solution
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tabu_list = list()
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best_cost = distance_of_first_solution
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best_solution_ever = solution
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while count <= iters:
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neighborhood = find_neighborhood(solution, dict_of_neighbours)
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index_of_best_solution = 0
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best_solution = neighborhood[index_of_best_solution]
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best_cost_index = len(best_solution) - 1
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found = False
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while not found:
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i = 0
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while i < len(best_solution):
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if best_solution[i] != solution[i]:
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first_exchange_node = best_solution[i]
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second_exchange_node = solution[i]
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break
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i = i + 1
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if [first_exchange_node, second_exchange_node] not in tabu_list and [
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second_exchange_node,
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first_exchange_node,
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] not in tabu_list:
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tabu_list.append([first_exchange_node, second_exchange_node])
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found = True
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solution = best_solution[:-1]
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cost = neighborhood[index_of_best_solution][best_cost_index]
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if cost < best_cost:
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best_cost = cost
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best_solution_ever = solution
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else:
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index_of_best_solution = index_of_best_solution + 1
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best_solution = neighborhood[index_of_best_solution]
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if len(tabu_list) >= size:
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tabu_list.pop(0)
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count = count + 1
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return best_solution_ever, best_cost
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def main(args=None):
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dict_of_neighbours = generate_neighbours(args.File)
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first_solution, distance_of_first_solution = generate_first_solution(
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args.File, dict_of_neighbours
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)
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best_sol, best_cost = tabu_search(
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first_solution,
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distance_of_first_solution,
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dict_of_neighbours,
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args.Iterations,
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args.Size,
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)
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print(f"Best solution: {best_sol}, with total distance: {best_cost}.")
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if __name__ == "__main__":
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parser = argparse.ArgumentParser(description="Tabu Search")
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parser.add_argument(
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"-f",
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"--File",
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type=str,
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help="Path to the file containing the data",
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required=True,
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)
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parser.add_argument(
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"-i",
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"--Iterations",
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type=int,
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help="How many iterations the algorithm should perform",
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required=True,
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)
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parser.add_argument(
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"-s", "--Size", type=int, help="Size of the tabu list", required=True
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)
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# Pass the arguments to main method
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main(parser.parse_args())
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