[최적화] Google OR-Tools Routing (1)Traveling Salesperson Problem
in Data on Optimization
Google OR-Tools Routing (1)Traveling Salesperson Problem에 대한 간단한 정리
Traveling Salesperson Problem
Create the data
def create_data_model():
"""Stores the data for the problem."""
data = {}
data['distance_matrix'] = [
[0, 2451, 713, 1018, 1631, 1374, 2408, 213, 2571, 875, 1420, 2145, 1972],
[2451, 0, 1745, 1524, 831, 1240, 959, 2596, 403, 1589, 1374, 357, 579],
[713, 1745, 0, 355, 920, 803, 1737, 851, 1858, 262, 940, 1453, 1260],
[1018, 1524, 355, 0, 700, 862, 1395, 1123, 1584, 466, 1056, 1280, 987],
[1631, 831, 920, 700, 0, 663, 1021, 1769, 949, 796, 879, 586, 371],
[1374, 1240, 803, 862, 663, 0, 1681, 1551, 1765, 547, 225, 887, 999],
[2408, 959, 1737, 1395, 1021, 1681, 0, 2493, 678, 1724, 1891, 1114, 701],
[213, 2596, 851, 1123, 1769, 1551, 2493, 0, 2699, 1038, 1605, 2300, 2099],
[2571, 403, 1858, 1584, 949, 1765, 678, 2699, 0, 1744, 1645, 653, 600],
[875, 1589, 262, 466, 796, 547, 1724, 1038, 1744, 0, 679, 1272, 1162],
[1420, 1374, 940, 1056, 879, 225, 1891, 1605, 1645, 679, 0, 1017, 1200],
[2145, 357, 1453, 1280, 586, 887, 1114, 2300, 653, 1272, 1017, 0, 504],
[1972, 579, 1260, 987, 371, 999, 701, 2099, 600, 1162, 1200, 504, 0],
] # yapf: disable
data['num_vehicles'] = 1
data['depot'] = 0 # 시작 위치와 종료 위치. 이 경우 뉴욕이 0
return data
- Other ways to create the distance matrix
- 함수를 이용하여 위치 간의 거리를 계산할수도 있으나(예를 들어 유클리드 수식)
- 그럴 경우 런타임 계산을 해야하니, 미리 계산하고 행렬에 저장하는것이 더 효율적
Create the routing model
- manager와 routing model을 만들어야한다.
data = create_data_model()
manager = pywrapcp.RoutingIndexManager(len(data['distance_matrix']),
data['num_vehicles'], data['depot'])
routing = pywrapcp.RoutingModel(manager)
RoutingIndexManager는 입렵값은- 거리 행렬 행갯수
- 차량수
- 시작 위치, 종료위치 (당연히 두개 다르게 지정할수 있음)
Create the distance callback
- 라우팅 솔버를 사용하려면 distance callback을 만들어야한다.
- distance callback : 특정 지점의 index를 넣어주면 실제 두 점 사이의 거리를 output 으로 내보내주는 함수
def distance_callback(from_index, to_index):
"""Returns the distance between the two nodes."""
# Convert from routing variable Index to distance matrix NodeIndex.
from_node = manager.IndexToNode(from_index)
to_node = manager.IndexToNode(to_index)
return data['distance_matrix'][from_node][to_node]
transit_callback_index = routing.RegisterTransitCallback(distance_callback)
Set the cost of travel
transit_callback_index는 단지 두위치의 거리에 불과- 비용은 거리 뿐만아니라 차량속도들이 다르면 이동시간으로 정의할수도 있다.
routing.SetArcCostEvaluatorOfAllVehicles(transit_callback_index)
Set search parameters
- 첫번째 솔루션을 찾기위한 김본 검색 매개변수와 휴리스틱 메서드를 설정
- 아래 코드에서는 ```PATH_CHEAPEST_ARC``로 설정한다. 그러면 최소 가중치 노드를 추가하면서 솔버의 초기 경로를 만듬(다른 옵션들도 가능)
search_parameters = pywrapcp.DefaultRoutingSearchParameters()
search_parameters.first_solution_strategy = (
routing_enums_pb2.FirstSolutionStrategy.PATH_CHEAPEST_ARC)
Add the solution printer
- 솔루션 경로 출력 용도
def print_solution(manager, routing, solution):
"""Prints solution on console."""
print('Objective: {} miles'.format(solution.ObjectiveValue()))
index = routing.Start(0)
plan_output = 'Route for vehicle 0:\n'
route_distance = 0
while not routing.IsEnd(index):
plan_output += ' {} ->'.format(manager.IndexToNode(index))
previous_index = index
index = solution.Value(routing.NextVar(index))
route_distance += routing.GetArcCostForVehicle(previous_index, index, 0)
plan_output += ' {}\n'.format(manager.IndexToNode(index))
print(plan_output)
plan_output += 'Route distance: {}miles\n'.format(route_distance)
Solve and print the solution
- 솔버를 호출하고 솔루션을 출력할수 있다.
solution = routing.SolveWithParameters(search_parameters)
if solution:
print_solution(manager, routing, solution)
Run the programs
- 그러면 결과가 나온다.
Save routes to a list or array
- 솔루션 리스트를 저장할수 있다. 매개변수를 변경하면서 솔루션 비교할 수 있게 저장해보자
def get_routes(solution, routing, manager):
"""Get vehicle routes from a solution and store them in an array."""
# Get vehicle routes and store them in a two dimensional array whose
# i,j entry is the jth location visited by vehicle i along its route.
routes = []
for route_nbr in range(routing.vehicles()):
index = routing.Start(route_nbr)
route = [manager.IndexToNode(index)]
while not routing.IsEnd(index):
index = solution.Value(routing.NextVar(index))
route.append(manager.IndexToNode(index))
routes.append(route)
return routes
- 이렇게 경로를 보여줄수 있다.
routes = get_routes(solution, routing, manager)
# Display the routes.
for i, route in enumerate(routes):
print('Route', i, route)
최종 코드
"""Simple Travelling Salesperson Problem (TSP) between cities."""
from ortools.constraint_solver import routing_enums_pb2
from ortools.constraint_solver import pywrapcp
def create_data_model():
"""Stores the data for the problem."""
data = {}
data['distance_matrix'] = [
[0, 2451, 713, 1018, 1631, 1374, 2408, 213, 2571, 875, 1420, 2145, 1972],
[2451, 0, 1745, 1524, 831, 1240, 959, 2596, 403, 1589, 1374, 357, 579],
[713, 1745, 0, 355, 920, 803, 1737, 851, 1858, 262, 940, 1453, 1260],
[1018, 1524, 355, 0, 700, 862, 1395, 1123, 1584, 466, 1056, 1280, 987],
[1631, 831, 920, 700, 0, 663, 1021, 1769, 949, 796, 879, 586, 371],
[1374, 1240, 803, 862, 663, 0, 1681, 1551, 1765, 547, 225, 887, 999],
[2408, 959, 1737, 1395, 1021, 1681, 0, 2493, 678, 1724, 1891, 1114, 701],
[213, 2596, 851, 1123, 1769, 1551, 2493, 0, 2699, 1038, 1605, 2300, 2099],
[2571, 403, 1858, 1584, 949, 1765, 678, 2699, 0, 1744, 1645, 653, 600],
[875, 1589, 262, 466, 796, 547, 1724, 1038, 1744, 0, 679, 1272, 1162],
[1420, 1374, 940, 1056, 879, 225, 1891, 1605, 1645, 679, 0, 1017, 1200],
[2145, 357, 1453, 1280, 586, 887, 1114, 2300, 653, 1272, 1017, 0, 504],
[1972, 579, 1260, 987, 371, 999, 701, 2099, 600, 1162, 1200, 504, 0],
] # yapf: disable
data['num_vehicles'] = 1
data['depot'] = 0
return data
def print_solution(manager, routing, solution):
"""Prints solution on console."""
print('Objective: {} miles'.format(solution.ObjectiveValue()))
index = routing.Start(0)
plan_output = 'Route for vehicle 0:\n'
route_distance = 0
while not routing.IsEnd(index):
plan_output += ' {} ->'.format(manager.IndexToNode(index))
previous_index = index
index = solution.Value(routing.NextVar(index))
route_distance += routing.GetArcCostForVehicle(previous_index, index, 0)
plan_output += ' {}\n'.format(manager.IndexToNode(index))
print(plan_output)
plan_output += 'Route distance: {}miles\n'.format(route_distance)
def main():
"""Entry point of the program."""
# Instantiate the data problem.
data = create_data_model()
# Create the routing index manager.
manager = pywrapcp.RoutingIndexManager(len(data['distance_matrix']),
data['num_vehicles'], data['depot'])
# Create Routing Model.
routing = pywrapcp.RoutingModel(manager)
def distance_callback(from_index, to_index):
"""Returns the distance between the two nodes."""
# Convert from routing variable Index to distance matrix NodeIndex.
from_node = manager.IndexToNode(from_index)
to_node = manager.IndexToNode(to_index)
return data['distance_matrix'][from_node][to_node]
transit_callback_index = routing.RegisterTransitCallback(distance_callback)
# Define cost of each arc.
routing.SetArcCostEvaluatorOfAllVehicles(transit_callback_index)
# Setting first solution heuristic.
search_parameters = pywrapcp.DefaultRoutingSearchParameters()
search_parameters.first_solution_strategy = (
routing_enums_pb2.FirstSolutionStrategy.PATH_CHEAPEST_ARC)
# Solve the problem.
solution = routing.SolveWithParameters(search_parameters)
# Print solution on console.
if solution:
print_solution(manager, routing, solution)
if __name__ == '__main__':
main()
결과
Objective: 7293 miles
Route for vehicle 0:
0 -> 7 -> 2 -> 3 -> 4 -> 12 -> 6 -> 8 -> 1 -> 11 -> 10 -> 5 -> 9 -> 0
