이 섹션에서는 아래 지도에 표시된 위치의 TSP (Traveling Salesman Problem)를 해결하는 방법을 보여주는 예를 보여줍니다.
다음 섹션에서는 OR 도구를 사용하여 TSP를 해결하는 Python, C++, 자바, C# 의 프로그램을 보여줍니다.
데이터 만들기
아래 코드는 문제에 대한 데이터를 생성합니다.
Python
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], ] data["num_vehicles"] = 1 data["depot"] = 0 return data
C++
struct DataModel { const std::vector<std::vector<int64_t>> 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}, }; const int num_vehicles = 1; const RoutingIndexManager::NodeIndex depot{0}; };
자바
static class DataModel { public final long[][] distanceMatrix = { {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}, }; public final int vehicleNumber = 1; public final int depot = 0; }
C#
class DataModel { public long[,] DistanceMatrix = { { 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 }, }; public int VehicleNumber = 1; public int Depot = 0; };
거리 행렬은 i
, j
항목이 i
위치에서 j
까지의 거리(마일 단위)인 배열이며, 여기서 배열 색인은 다음과 같은 위치입니다.
0. New York - 1. Los Angeles - 2. Chicago - 3. Minneapolis - 4. Denver - 5. Dallas
- 6. Seattle - 7. Boston - 8. San Francisco - 9. St. Louis - 10. Houston - 11. Phoenix - 12. Salt Lake City
데이터에는 다음 정보도 포함됩니다.
- 문제의 차량 수(TSP이므로 1개) 차량 이동 문제(VRP)의 경우 차량 수가 1보다 클 수 있습니다.
- Depot: 경로의 시작 위치와 종료 위치입니다. 이 경우 depot은 뉴욕에 해당하는 0입니다.
거리 행렬을 만드는 다른 방법
이 예에서 거리 행렬은 프로그램에서 명시적으로 정의됩니다. 함수를 사용하여 위치 간 거리를 계산할 수도 있습니다. 예를 들어 평면에서 지점 간 거리의 유클리드 수식을 사용할 수 있습니다. 그러나 런타임에 계산하기보다는 위치 간의 모든 거리를 미리 계산하고 행렬에 저장하는 것이 더 효율적입니다. 이런 식으로 거리 행렬을 만드는 예는 예: 회로 기판 드릴다운을 참고하세요.
또 다른 방법은 Google Maps Distance Matrix API를 사용하여 경로 문제를 위한 거리 (또는 이동 시간) 행렬을 동적으로 생성하는 것입니다.
라우팅 모델 만들기
프로그램의 기본 섹션에 있는 다음 코드는 색인 관리자 (manager
) 및 라우팅 모델 (routing
)을 만듭니다. manager.IndexToNode
메서드는 솔버의 내부 색인 (무시할 수 있음)을 위치의 숫자로 변환합니다. 위치 번호는 거리 행렬의 색인에 해당합니다.
Python
data = create_data_model() manager = pywrapcp.RoutingIndexManager( len(data["distance_matrix"]), data["num_vehicles"], data["depot"] ) routing = pywrapcp.RoutingModel(manager)
C++
DataModel data; RoutingIndexManager manager(data.distance_matrix.size(), data.num_vehicles, data.depot); RoutingModel routing(manager);
자바
final DataModel data = new DataModel(); RoutingIndexManager manager = new RoutingIndexManager(data.distanceMatrix.length, data.vehicleNumber, data.depot); RoutingModel routing = new RoutingModel(manager);
C#
DataModel data = new DataModel(); RoutingIndexManager manager = new RoutingIndexManager(data.DistanceMatrix.GetLength(0), data.VehicleNumber, data.Depot); RoutingModel routing = new RoutingModel(manager);
RoutingIndexManager
에 대한 입력은 다음과 같습니다.
- 거리 행렬의 행 수로, 위치(디포 포함) 수입니다.
- 문제가 있는 차량 수입니다.
- 디포에 해당하는 노드입니다.
거리 콜백 만들기
라우팅 솔버를 사용하려면 위치 쌍을 가져와서 위치 간 거리를 반환하는 함수인 거리 (또는 대중교통) 콜백을 만들어야 합니다. 가장 쉬운 방법은 거리 행렬을 사용하는 것입니다.
다음 함수는 콜백을 만들고 솔버에 transit_callback_index
로 등록합니다.
Python
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)
C++
const int transit_callback_index = routing.RegisterTransitCallback( [&data, &manager](const int64_t from_index, const int64_t to_index) -> int64_t { // Convert from routing variable Index to distance matrix NodeIndex. const int from_node = manager.IndexToNode(from_index).value(); const int to_node = manager.IndexToNode(to_index).value(); return data.distance_matrix[from_node][to_node]; });
Java
final int transitCallbackIndex = routing.registerTransitCallback((long fromIndex, long toIndex) -> { // Convert from routing variable Index to user NodeIndex. int fromNode = manager.indexToNode(fromIndex); int toNode = manager.indexToNode(toIndex); return data.distanceMatrix[fromNode][toNode]; });
C#
int transitCallbackIndex = routing.RegisterTransitCallback((long fromIndex, long toIndex) => { // Convert from routing variable Index to // distance matrix NodeIndex. var fromNode = manager.IndexToNode(fromIndex); var toNode = manager.IndexToNode(toIndex); return data.DistanceMatrix[fromNode, toNode]; });
The callback accepts two indices, from_index
and to_index
, and returns the
corresponding entry of the distance matrix.
Set the cost of travel
The arc cost evaluator tells the solver how to calculate the cost of travel between any two locations — in other words, the cost of the edge (or arc) joining them in the graph for the problem. The following code sets the arc cost evaluator.
Python
routing.SetArcCostEvaluatorOfAllVehicles(transit_callback_index)
C++
routing.SetArcCostEvaluatorOfAllVehicles(transit_callback_index);
자바
routing.setArcCostEvaluatorOfAllVehicles(transitCallbackIndex);
C#
routing.SetArcCostEvaluatorOfAllVehicles(transitCallbackIndex);
이 예에서 원호 비용 평가자는 transit_callback_index
이며, 이는 솔버의 거리 콜백 참조입니다. 즉, 두 위치 간의 이동 비용은 두 위치 간의 거리에 불과합니다.
그러나 일반적으로 비용은 다른 요인도 수반될 수 있습니다.
routing.SetArcCostEvaluatorOfVehicle()
메서드를 사용하여 위치 간에 이동하는 차량에 종속되는 여러 원호 비용 평가자를 정의할 수도 있습니다.
예를 들어 차량의 속도가 다르면 위치 간의 이동 비용을 차량의 거리로 나눈 값, 즉 이동 시간으로 정의할 수 있습니다.
검색 매개변수 설정
다음 코드는 첫 번째 솔루션을 찾기 위한 기본 검색 매개변수와 휴리스틱 메서드를 설정합니다.
Python
search_parameters = pywrapcp.DefaultRoutingSearchParameters() search_parameters.first_solution_strategy = ( routing_enums_pb2.FirstSolutionStrategy.PATH_CHEAPEST_ARC )
C++
RoutingSearchParameters searchParameters = DefaultRoutingSearchParameters(); searchParameters.set_first_solution_strategy( FirstSolutionStrategy::PATH_CHEAPEST_ARC);
자바
RoutingSearchParameters searchParameters = main.defaultRoutingSearchParameters() .toBuilder() .setFirstSolutionStrategy(FirstSolutionStrategy.Value.PATH_CHEAPEST_ARC) .build();
C#
RoutingSearchParameters searchParameters = operations_research_constraint_solver.DefaultRoutingSearchParameters(); searchParameters.FirstSolutionStrategy = FirstSolutionStrategy.Types.Value.PathCheapestArc;
이 코드는 첫 번째 솔루션 전략을 PATH_CHEAPEST_ARC
로 설정합니다. 그러면 이전에 방문한 노드 (디포)가 발생하지 않는 최소 가중치를 갖는 에지를 반복적으로 추가하여 솔버의 초기 경로를 만듭니다. 다른 옵션은 첫 번째 솔루션 전략을 참조하세요.
솔루션 프린터 추가
솔버가 반환한 솔루션을 표시하는 함수는 다음과 같습니다. 함수는 솔루션에서 경로를 추출하고 콘솔에 출력합니다.
Python
def print_solution(manager, routing, solution): """Prints solution on console.""" print(f"Objective: {solution.ObjectiveValue()} miles") index = routing.Start(0) plan_output = "Route for vehicle 0:\n" route_distance = 0 while not routing.IsEnd(index): plan_output += f" {manager.IndexToNode(index)} ->" previous_index = index index = solution.Value(routing.NextVar(index)) route_distance += routing.GetArcCostForVehicle(previous_index, index, 0) plan_output += f" {manager.IndexToNode(index)}\n" print(plan_output) plan_output += f"Route distance: {route_distance}miles\n"
C++
//! @brief Print the solution. //! @param[in] manager Index manager used. //! @param[in] routing Routing solver used. //! @param[in] solution Solution found by the solver. void PrintSolution(const RoutingIndexManager& manager, const RoutingModel& routing, const Assignment& solution) { // Inspect solution. LOG(INFO) << "Objective: " << solution.ObjectiveValue() << " miles"; int64_t index = routing.Start(0); LOG(INFO) << "Route:"; int64_t distance{0}; std::stringstream route; while (!routing.IsEnd(index)) { route << manager.IndexToNode(index).value() << " -> "; const int64_t previous_index = index; index = solution.Value(routing.NextVar(index)); distance += routing.GetArcCostForVehicle(previous_index, index, int64_t{0}); } LOG(INFO) << route.str() << manager.IndexToNode(index).value(); LOG(INFO) << "Route distance: " << distance << "miles"; LOG(INFO) << ""; LOG(INFO) << "Advanced usage:"; LOG(INFO) << "Problem solved in " << routing.solver()->wall_time() << "ms"; }
자바
/// @brief Print the solution. static void printSolution( RoutingModel routing, RoutingIndexManager manager, Assignment solution) { // Solution cost. logger.info("Objective: " + solution.objectiveValue() + "miles"); // Inspect solution. logger.info("Route:"); long routeDistance = 0; String route = ""; long index = routing.start(0); while (!routing.isEnd(index)) { route += manager.indexToNode(index) + " -> "; long previousIndex = index; index = solution.value(routing.nextVar(index)); routeDistance += routing.getArcCostForVehicle(previousIndex, index, 0); } route += manager.indexToNode(routing.end(0)); logger.info(route); logger.info("Route distance: " + routeDistance + "miles"); }
C#
/// <summary> /// Print the solution. /// </summary> static void PrintSolution(in RoutingModel routing, in RoutingIndexManager manager, in Assignment solution) { Console.WriteLine("Objective: {0} miles", solution.ObjectiveValue()); // Inspect solution. Console.WriteLine("Route:"); long routeDistance = 0; var index = routing.Start(0); while (routing.IsEnd(index) == false) { Console.Write("{0} -> ", manager.IndexToNode((int)index)); var previousIndex = index; index = solution.Value(routing.NextVar(index)); routeDistance += routing.GetArcCostForVehicle(previousIndex, index, 0); } Console.WriteLine("{0}", manager.IndexToNode((int)index)); Console.WriteLine("Route distance: {0}miles", routeDistance); }
이 함수는 ObjectiveValue()
로 주어진 최적의 경로와 거리를 표시합니다.
해답 해결 및 인쇄
마지막으로, 솔버를 호출하고 솔루션을 출력할 수 있습니다.
Python
solution = routing.SolveWithParameters(search_parameters) if solution: print_solution(manager, routing, solution)
C++
const Assignment* solution = routing.SolveWithParameters(searchParameters); PrintSolution(manager, routing, *solution);
자바
Assignment solution = routing.solveWithParameters(searchParameters); printSolution(routing, manager, solution);
C#
Assignment solution = routing.SolveWithParameters(searchParameters); PrintSolution(routing, manager, solution);
이렇게 하면 솔루션이 반환되고 최적의 경로가 표시됩니다.
프로그램 실행
프로그램을 실행하면 다음과 같은 출력이 표시됩니다.
Objective: 7293 miles Route for vehicle 0: 0 -> 7 -> 2 -> 3 -> 4 -> 12 -> 6 -> 8 -> 1 -> 11 -> 10 -> 5 -> 9 -> 0
이 예시에서는 TSP이기 때문에 경로가 하나뿐입니다. 그러나 보다 일반적인 차량 라우팅 문제에서는 솔루션에 여러 경로가 포함됩니다.
목록 또는 배열에 경로 저장
솔루션을 직접 인쇄하는 대신 경로 (VRP의 경우 경로)를 목록 또는 배열에 저장할 수 있습니다. 이렇게 하면 나중에 경로를 작업할 때를 대비해 경로를 사용할 수 있다는 장점이 있습니다. 예를 들어 서로 다른 매개변수를 사용하여 프로그램을 여러 번 실행하고 반환된 솔루션의 경로를 비교를 위해 파일에 저장할 수 있습니다.
다음 함수는 솔루션의 경로를 목록 (Python) 또는 배열 (C++)로 모든 VRP (여러 차량 포함)에 저장합니다.
Python
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
C++
std::vector<std::vector<int>> GetRoutes(const Assignment& solution, const RoutingModel& routing, const RoutingIndexManager& manager) { // Get vehicle routes and store them in a two dimensional array, whose // i, j entry is the node for the jth visit of vehicle i. std::vector<std::vector<int>> routes(manager.num_vehicles()); // Get routes. for (int vehicle_id = 0; vehicle_id < manager.num_vehicles(); ++vehicle_id) { int64_t index = routing.Start(vehicle_id); routes[vehicle_id].push_back(manager.IndexToNode(index).value()); while (!routing.IsEnd(index)) { index = solution.Value(routing.NextVar(index)); routes[vehicle_id].push_back(manager.IndexToNode(index).value()); } } return routes; }
이러한 함수를 사용하여 라우팅 섹션의 VRP 예시에서 경로를 가져올 수 있습니다.
다음 코드는 경로를 보여줍니다.
Python
routes = get_routes(solution, routing, manager) # Display the routes. for i, route in enumerate(routes): print('Route', i, route)
C++
const std::vector⟨std::vector⟨int⟩⟩ routes = GetRoutes(*solution, routing, manager); // Display the routes. for (int vehicle_id = 0; vehicle_id < routes.size(); ++vehicle_id) { LOG(INFO) << "Route " << vehicle_id; for (int j = 1; j < routes[vehicle_id].size(); ++j) { LOG(INFO) << routes[vehicle_id][j]; } }
현재 예에서 이 코드는 다음 경로를 반환합니다.
Route 0 [0, 7, 2, 3, 4, 12, 6, 8, 1, 11, 10, 5, 9, 0]
연습 삼아 위의 코드를 수정하여 프로그램용 솔루션 프린터와 같은 방식으로 출력 형식을 지정합니다.
프로그램 완료
전체 TSP 프로그램은 다음과 같습니다.
Python
"""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], ] data["num_vehicles"] = 1 data["depot"] = 0 return data def print_solution(manager, routing, solution): """Prints solution on console.""" print(f"Objective: {solution.ObjectiveValue()} miles") index = routing.Start(0) plan_output = "Route for vehicle 0:\n" route_distance = 0 while not routing.IsEnd(index): plan_output += f" {manager.IndexToNode(index)} ->" previous_index = index index = solution.Value(routing.NextVar(index)) route_distance += routing.GetArcCostForVehicle(previous_index, index, 0) plan_output += f" {manager.IndexToNode(index)}\n" print(plan_output) plan_output += f"Route distance: {route_distance}miles\n" 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()
C++
#include <cmath> #include <cstdint> #include <sstream> #include <vector> #include "ortools/constraint_solver/routing.h" #include "ortools/constraint_solver/routing_enums.pb.h" #include "ortools/constraint_solver/routing_index_manager.h" #include "ortools/constraint_solver/routing_parameters.h" namespace operations_research { struct DataModel { const std::vector<std::vector<int64_t>> 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}, }; const int num_vehicles = 1; const RoutingIndexManager::NodeIndex depot{0}; }; //! @brief Print the solution. //! @param[in] manager Index manager used. //! @param[in] routing Routing solver used. //! @param[in] solution Solution found by the solver. void PrintSolution(const RoutingIndexManager& manager, const RoutingModel& routing, const Assignment& solution) { // Inspect solution. LOG(INFO) << "Objective: " << solution.ObjectiveValue() << " miles"; int64_t index = routing.Start(0); LOG(INFO) << "Route:"; int64_t distance{0}; std::stringstream route; while (!routing.IsEnd(index)) { route << manager.IndexToNode(index).value() << " -> "; const int64_t previous_index = index; index = solution.Value(routing.NextVar(index)); distance += routing.GetArcCostForVehicle(previous_index, index, int64_t{0}); } LOG(INFO) << route.str() << manager.IndexToNode(index).value(); LOG(INFO) << "Route distance: " << distance << "miles"; LOG(INFO) << ""; LOG(INFO) << "Advanced usage:"; LOG(INFO) << "Problem solved in " << routing.solver()->wall_time() << "ms"; } void Tsp() { // Instantiate the data problem. DataModel data; // Create Routing Index Manager RoutingIndexManager manager(data.distance_matrix.size(), data.num_vehicles, data.depot); // Create Routing Model. RoutingModel routing(manager); const int transit_callback_index = routing.RegisterTransitCallback( [&data, &manager](const int64_t from_index, const int64_t to_index) -> int64_t { // Convert from routing variable Index to distance matrix NodeIndex. const int from_node = manager.IndexToNode(from_index).value(); const int to_node = manager.IndexToNode(to_index).value(); return data.distance_matrix[from_node][to_node]; }); // Define cost of each arc. routing.SetArcCostEvaluatorOfAllVehicles(transit_callback_index); // Setting first solution heuristic. RoutingSearchParameters searchParameters = DefaultRoutingSearchParameters(); searchParameters.set_first_solution_strategy( FirstSolutionStrategy::PATH_CHEAPEST_ARC); // Solve the problem. const Assignment* solution = routing.SolveWithParameters(searchParameters); // Print solution on console. PrintSolution(manager, routing, *solution); } } // namespace operations_research int main(int /*argc*/, char* /*argv*/[]) { operations_research::Tsp(); return EXIT_SUCCESS; }
자바
package com.google.ortools.constraintsolver.samples; import com.google.ortools.Loader; import com.google.ortools.constraintsolver.Assignment; import com.google.ortools.constraintsolver.FirstSolutionStrategy; import com.google.ortools.constraintsolver.RoutingIndexManager; import com.google.ortools.constraintsolver.RoutingModel; import com.google.ortools.constraintsolver.RoutingSearchParameters; import com.google.ortools.constraintsolver.main; import java.util.logging.Logger; /** Minimal TSP using distance matrix. */ public class TspCities { private static final Logger logger = Logger.getLogger(TspCities.class.getName()); static class DataModel { public final long[][] distanceMatrix = { {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}, }; public final int vehicleNumber = 1; public final int depot = 0; } /// @brief Print the solution. static void printSolution( RoutingModel routing, RoutingIndexManager manager, Assignment solution) { // Solution cost. logger.info("Objective: " + solution.objectiveValue() + "miles"); // Inspect solution. logger.info("Route:"); long routeDistance = 0; String route = ""; long index = routing.start(0); while (!routing.isEnd(index)) { route += manager.indexToNode(index) + " -> "; long previousIndex = index; index = solution.value(routing.nextVar(index)); routeDistance += routing.getArcCostForVehicle(previousIndex, index, 0); } route += manager.indexToNode(routing.end(0)); logger.info(route); logger.info("Route distance: " + routeDistance + "miles"); } public static void main(String[] args) throws Exception { Loader.loadNativeLibraries(); // Instantiate the data problem. final DataModel data = new DataModel(); // Create Routing Index Manager RoutingIndexManager manager = new RoutingIndexManager(data.distanceMatrix.length, data.vehicleNumber, data.depot); // Create Routing Model. RoutingModel routing = new RoutingModel(manager); // Create and register a transit callback. final int transitCallbackIndex = routing.registerTransitCallback((long fromIndex, long toIndex) -> { // Convert from routing variable Index to user NodeIndex. int fromNode = manager.indexToNode(fromIndex); int toNode = manager.indexToNode(toIndex); return data.distanceMatrix[fromNode][toNode]; }); // Define cost of each arc. routing.setArcCostEvaluatorOfAllVehicles(transitCallbackIndex); // Setting first solution heuristic. RoutingSearchParameters searchParameters = main.defaultRoutingSearchParameters() .toBuilder() .setFirstSolutionStrategy(FirstSolutionStrategy.Value.PATH_CHEAPEST_ARC) .build(); // Solve the problem. Assignment solution = routing.solveWithParameters(searchParameters); // Print solution on console. printSolution(routing, manager, solution); } }
C#
using System; using System.Collections.Generic; using Google.OrTools.ConstraintSolver; /// <summary> /// Minimal TSP using distance matrix. /// </summary> public class TspCities { class DataModel { public long[,] DistanceMatrix = { { 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 }, }; public int VehicleNumber = 1; public int Depot = 0; }; /// <summary> /// Print the solution. /// </summary> static void PrintSolution(in RoutingModel routing, in RoutingIndexManager manager, in Assignment solution) { Console.WriteLine("Objective: {0} miles", solution.ObjectiveValue()); // Inspect solution. Console.WriteLine("Route:"); long routeDistance = 0; var index = routing.Start(0); while (routing.IsEnd(index) == false) { Console.Write("{0} -> ", manager.IndexToNode((int)index)); var previousIndex = index; index = solution.Value(routing.NextVar(index)); routeDistance += routing.GetArcCostForVehicle(previousIndex, index, 0); } Console.WriteLine("{0}", manager.IndexToNode((int)index)); Console.WriteLine("Route distance: {0}miles", routeDistance); } public static void Main(String[] args) { // Instantiate the data problem. DataModel data = new DataModel(); // Create Routing Index Manager RoutingIndexManager manager = new RoutingIndexManager(data.DistanceMatrix.GetLength(0), data.VehicleNumber, data.Depot); // Create Routing Model. RoutingModel routing = new RoutingModel(manager); int transitCallbackIndex = routing.RegisterTransitCallback((long fromIndex, long toIndex) => { // Convert from routing variable Index to // distance matrix NodeIndex. var fromNode = manager.IndexToNode(fromIndex); var toNode = manager.IndexToNode(toIndex); return data.DistanceMatrix[fromNode, toNode]; }); // Define cost of each arc. routing.SetArcCostEvaluatorOfAllVehicles(transitCallbackIndex); // Setting first solution heuristic. RoutingSearchParameters searchParameters = operations_research_constraint_solver.DefaultRoutingSearchParameters(); searchParameters.FirstSolutionStrategy = FirstSolutionStrategy.Types.Value.PathCheapestArc; // Solve the problem. Assignment solution = routing.SolveWithParameters(searchParameters); // Print solution on console. PrintSolution(routing, manager, solution); } }
예: 회로 기판 드릴다운
다음 예는 자동화된 드릴로 회로 기판에 구멍을 뚫는 것입니다. 문제는 필요한 모든 구멍을 뚫기 위해 보드에서 실행할 최단 경로를 찾는 것입니다. 이 예시는 TSP 문제의 라이브러리인 TSPLIB에서 가져왔습니다.
다음은 구멍 위치를 분산형 차트로 보여줍니다.
다음 섹션에서는 솔버의 기본 검색 매개변수를 사용하여 회로 기판 문제에 적합한 솔루션을 찾는 프로그램을 제공합니다. 그런 다음 검색 전략을 변경하여 더 나은 솔루션을 찾는 방법을 알아봅니다.
데이터 만들기
문제에 대한 데이터는 위의 분산형 차트에 표시된 것처럼 평면의 280포인트로 구성됩니다. 프로그램은 아래와 같이 평면의 점에 해당하는 순서가 지정된 쌍의 배열에 데이터를 만듭니다.
Python
def create_data_model(): """Stores the data for the problem.""" data = {} # Locations in block units data["locations"] = [ # fmt: off (288, 149), (288, 129), (270, 133), (256, 141), (256, 157), (246, 157), (236, 169), (228, 169), (228, 161), (220, 169), (212, 169), (204, 169), (196, 169), (188, 169), (196, 161), (188, 145), (172, 145), (164, 145), (156, 145), (148, 145), (140, 145), (148, 169), (164, 169), (172, 169), (156, 169), (140, 169), (132, 169), (124, 169), (116, 161), (104, 153), (104, 161), (104, 169), (90, 165), (80, 157), (64, 157), (64, 165), (56, 169), (56, 161), (56, 153), (56, 145), (56, 137), (56, 129), (56, 121), (40, 121), (40, 129), (40, 137), (40, 145), (40, 153), (40, 161), (40, 169), (32, 169), (32, 161), (32, 153), (32, 145), (32, 137), (32, 129), (32, 121), (32, 113), (40, 113), (56, 113), (56, 105), (48, 99), (40, 99), (32, 97), (32, 89), (24, 89), (16, 97), (16, 109), (8, 109), (8, 97), (8, 89), (8, 81), (8, 73), (8, 65), (8, 57), (16, 57), (8, 49), (8, 41), (24, 45), (32, 41), (32, 49), (32, 57), (32, 65), (32, 73), (32, 81), (40, 83), (40, 73), (40, 63), (40, 51), (44, 43), (44, 35), (44, 27), (32, 25), (24, 25), (16, 25), (16, 17), (24, 17), (32, 17), (44, 11), (56, 9), (56, 17), (56, 25), (56, 33), (56, 41), (64, 41), (72, 41), (72, 49), (56, 49), (48, 51), (56, 57), (56, 65), (48, 63), (48, 73), (56, 73), (56, 81), (48, 83), (56, 89), (56, 97), (104, 97), (104, 105), (104, 113), (104, 121), (104, 129), (104, 137), (104, 145), (116, 145), (124, 145), (132, 145), (132, 137), (140, 137), (148, 137), (156, 137), (164, 137), (172, 125), (172, 117), (172, 109), (172, 101), (172, 93), (172, 85), (180, 85), (180, 77), (180, 69), (180, 61), (180, 53), (172, 53), (172, 61), (172, 69), (172, 77), (164, 81), (148, 85), (124, 85), (124, 93), (124, 109), (124, 125), (124, 117), (124, 101), (104, 89), (104, 81), (104, 73), (104, 65), (104, 49), (104, 41), (104, 33), (104, 25), (104, 17), (92, 9), (80, 9), (72, 9), (64, 21), (72, 25), (80, 25), (80, 25), (80, 41), (88, 49), (104, 57), (124, 69), (124, 77), (132, 81), (140, 65), (132, 61), (124, 61), (124, 53), (124, 45), (124, 37), (124, 29), (132, 21), (124, 21), (120, 9), (128, 9), (136, 9), (148, 9), (162, 9), (156, 25), (172, 21), (180, 21), (180, 29), (172, 29), (172, 37), (172, 45), (180, 45), (180, 37), (188, 41), (196, 49), (204, 57), (212, 65), (220, 73), (228, 69), (228, 77), (236, 77), (236, 69), (236, 61), (228, 61), (228, 53), (236, 53), (236, 45), (228, 45), (228, 37), (236, 37), (236, 29), (228, 29), (228, 21), (236, 21), (252, 21), (260, 29), (260, 37), (260, 45), (260, 53), (260, 61), (260, 69), (260, 77), (276, 77), (276, 69), (276, 61), (276, 53), (284, 53), (284, 61), (284, 69), (284, 77), (284, 85), (284, 93), (284, 101), (288, 109), (280, 109), (276, 101), (276, 93), (276, 85), (268, 97), (260, 109), (252, 101), (260, 93), (260, 85), (236, 85), (228, 85), (228, 93), (236, 93), (236, 101), (228, 101), (228, 109), (228, 117), (228, 125), (220, 125), (212, 117), (204, 109), (196, 101), (188, 93), (180, 93), (180, 101), (180, 109), (180, 117), (180, 125), (196, 145), (204, 145), (212, 145), (220, 145), (228, 145), (236, 145), (246, 141), (252, 125), (260, 129), (280, 133) # fmt: on ] data["num_vehicles"] = 1 data["depot"] = 0 return data
C++
struct DataModel { const std::vector<std::vector<int>> locations{ {288, 149}, {288, 129}, {270, 133}, {256, 141}, {256, 157}, {246, 157}, {236, 169}, {228, 169}, {228, 161}, {220, 169}, {212, 169}, {204, 169}, {196, 169}, {188, 169}, {196, 161}, {188, 145}, {172, 145}, {164, 145}, {156, 145}, {148, 145}, {140, 145}, {148, 169}, {164, 169}, {172, 169}, {156, 169}, {140, 169}, {132, 169}, {124, 169}, {116, 161}, {104, 153}, {104, 161}, {104, 169}, {90, 165}, {80, 157}, {64, 157}, {64, 165}, {56, 169}, {56, 161}, {56, 153}, {56, 145}, {56, 137}, {56, 129}, {56, 121}, {40, 121}, {40, 129}, {40, 137}, {40, 145}, {40, 153}, {40, 161}, {40, 169}, {32, 169}, {32, 161}, {32, 153}, {32, 145}, {32, 137}, {32, 129}, {32, 121}, {32, 113}, {40, 113}, {56, 113}, {56, 105}, {48, 99}, {40, 99}, {32, 97}, {32, 89}, {24, 89}, {16, 97}, {16, 109}, {8, 109}, {8, 97}, {8, 89}, {8, 81}, {8, 73}, {8, 65}, {8, 57}, {16, 57}, {8, 49}, {8, 41}, {24, 45}, {32, 41}, {32, 49}, {32, 57}, {32, 65}, {32, 73}, {32, 81}, {40, 83}, {40, 73}, {40, 63}, {40, 51}, {44, 43}, {44, 35}, {44, 27}, {32, 25}, {24, 25}, {16, 25}, {16, 17}, {24, 17}, {32, 17}, {44, 11}, {56, 9}, {56, 17}, {56, 25}, {56, 33}, {56, 41}, {64, 41}, {72, 41}, {72, 49}, {56, 49}, {48, 51}, {56, 57}, {56, 65}, {48, 63}, {48, 73}, {56, 73}, {56, 81}, {48, 83}, {56, 89}, {56, 97}, {104, 97}, {104, 105}, {104, 113}, {104, 121}, {104, 129}, {104, 137}, {104, 145}, {116, 145}, {124, 145}, {132, 145}, {132, 137}, {140, 137}, {148, 137}, {156, 137}, {164, 137}, {172, 125}, {172, 117}, {172, 109}, {172, 101}, {172, 93}, {172, 85}, {180, 85}, {180, 77}, {180, 69}, {180, 61}, {180, 53}, {172, 53}, {172, 61}, {172, 69}, {172, 77}, {164, 81}, {148, 85}, {124, 85}, {124, 93}, {124, 109}, {124, 125}, {124, 117}, {124, 101}, {104, 89}, {104, 81}, {104, 73}, {104, 65}, {104, 49}, {104, 41}, {104, 33}, {104, 25}, {104, 17}, {92, 9}, {80, 9}, {72, 9}, {64, 21}, {72, 25}, {80, 25}, {80, 25}, {80, 41}, {88, 49}, {104, 57}, {124, 69}, {124, 77}, {132, 81}, {140, 65}, {132, 61}, {124, 61}, {124, 53}, {124, 45}, {124, 37}, {124, 29}, {132, 21}, {124, 21}, {120, 9}, {128, 9}, {136, 9}, {148, 9}, {162, 9}, {156, 25}, {172, 21}, {180, 21}, {180, 29}, {172, 29}, {172, 37}, {172, 45}, {180, 45}, {180, 37}, {188, 41}, {196, 49}, {204, 57}, {212, 65}, {220, 73}, {228, 69}, {228, 77}, {236, 77}, {236, 69}, {236, 61}, {228, 61}, {228, 53}, {236, 53}, {236, 45}, {228, 45}, {228, 37}, {236, 37}, {236, 29}, {228, 29}, {228, 21}, {236, 21}, {252, 21}, {260, 29}, {260, 37}, {260, 45}, {260, 53}, {260, 61}, {260, 69}, {260, 77}, {276, 77}, {276, 69}, {276, 61}, {276, 53}, {284, 53}, {284, 61}, {284, 69}, {284, 77}, {284, 85}, {284, 93}, {284, 101}, {288, 109}, {280, 109}, {276, 101}, {276, 93}, {276, 85}, {268, 97}, {260, 109}, {252, 101}, {260, 93}, {260, 85}, {236, 85}, {228, 85}, {228, 93}, {236, 93}, {236, 101}, {228, 101}, {228, 109}, {228, 117}, {228, 125}, {220, 125}, {212, 117}, {204, 109}, {196, 101}, {188, 93}, {180, 93}, {180, 101}, {180, 109}, {180, 117}, {180, 125}, {196, 145}, {204, 145}, {212, 145}, {220, 145}, {228, 145}, {236, 145}, {246, 141}, {252, 125}, {260, 129}, {280, 133}, }; const int num_vehicles = 1; const RoutingIndexManager::NodeIndex depot{0}; };
자바
static class DataModel { public final int[][] locations = {{288, 149}, {288, 129}, {270, 133}, {256, 141}, {256, 157}, {246, 157}, {236, 169}, {228, 169}, {228, 161}, {220, 169}, {212, 169}, {204, 169}, {196, 169}, {188, 169}, {196, 161}, {188, 145}, {172, 145}, {164, 145}, {156, 145}, {148, 145}, {140, 145}, {148, 169}, {164, 169}, {172, 169}, {156, 169}, {140, 169}, {132, 169}, {124, 169}, {116, 161}, {104, 153}, {104, 161}, {104, 169}, {90, 165}, {80, 157}, {64, 157}, {64, 165}, {56, 169}, {56, 161}, {56, 153}, {56, 145}, {56, 137}, {56, 129}, {56, 121}, {40, 121}, {40, 129}, {40, 137}, {40, 145}, {40, 153}, {40, 161}, {40, 169}, {32, 169}, {32, 161}, {32, 153}, {32, 145}, {32, 137}, {32, 129}, {32, 121}, {32, 113}, {40, 113}, {56, 113}, {56, 105}, {48, 99}, {40, 99}, {32, 97}, {32, 89}, {24, 89}, {16, 97}, {16, 109}, {8, 109}, {8, 97}, {8, 89}, {8, 81}, {8, 73}, {8, 65}, {8, 57}, {16, 57}, {8, 49}, {8, 41}, {24, 45}, {32, 41}, {32, 49}, {32, 57}, {32, 65}, {32, 73}, {32, 81}, {40, 83}, {40, 73}, {40, 63}, {40, 51}, {44, 43}, {44, 35}, {44, 27}, {32, 25}, {24, 25}, {16, 25}, {16, 17}, {24, 17}, {32, 17}, {44, 11}, {56, 9}, {56, 17}, {56, 25}, {56, 33}, {56, 41}, {64, 41}, {72, 41}, {72, 49}, {56, 49}, {48, 51}, {56, 57}, {56, 65}, {48, 63}, {48, 73}, {56, 73}, {56, 81}, {48, 83}, {56, 89}, {56, 97}, {104, 97}, {104, 105}, {104, 113}, {104, 121}, {104, 129}, {104, 137}, {104, 145}, {116, 145}, {124, 145}, {132, 145}, {132, 137}, {140, 137}, {148, 137}, {156, 137}, {164, 137}, {172, 125}, {172, 117}, {172, 109}, {172, 101}, {172, 93}, {172, 85}, {180, 85}, {180, 77}, {180, 69}, {180, 61}, {180, 53}, {172, 53}, {172, 61}, {172, 69}, {172, 77}, {164, 81}, {148, 85}, {124, 85}, {124, 93}, {124, 109}, {124, 125}, {124, 117}, {124, 101}, {104, 89}, {104, 81}, {104, 73}, {104, 65}, {104, 49}, {104, 41}, {104, 33}, {104, 25}, {104, 17}, {92, 9}, {80, 9}, {72, 9}, {64, 21}, {72, 25}, {80, 25}, {80, 25}, {80, 41}, {88, 49}, {104, 57}, {124, 69}, {124, 77}, {132, 81}, {140, 65}, {132, 61}, {124, 61}, {124, 53}, {124, 45}, {124, 37}, {124, 29}, {132, 21}, {124, 21}, {120, 9}, {128, 9}, {136, 9}, {148, 9}, {162, 9}, {156, 25}, {172, 21}, {180, 21}, {180, 29}, {172, 29}, {172, 37}, {172, 45}, {180, 45}, {180, 37}, {188, 41}, {196, 49}, {204, 57}, {212, 65}, {220, 73}, {228, 69}, {228, 77}, {236, 77}, {236, 69}, {236, 61}, {228, 61}, {228, 53}, {236, 53}, {236, 45}, {228, 45}, {228, 37}, {236, 37}, {236, 29}, {228, 29}, {228, 21}, {236, 21}, {252, 21}, {260, 29}, {260, 37}, {260, 45}, {260, 53}, {260, 61}, {260, 69}, {260, 77}, {276, 77}, {276, 69}, {276, 61}, {276, 53}, {284, 53}, {284, 61}, {284, 69}, {284, 77}, {284, 85}, {284, 93}, {284, 101}, {288, 109}, {280, 109}, {276, 101}, {276, 93}, {276, 85}, {268, 97}, {260, 109}, {252, 101}, {260, 93}, {260, 85}, {236, 85}, {228, 85}, {228, 93}, {236, 93}, {236, 101}, {228, 101}, {228, 109}, {228, 117}, {228, 125}, {220, 125}, {212, 117}, {204, 109}, {196, 101}, {188, 93}, {180, 93}, {180, 101}, {180, 109}, {180, 117}, {180, 125}, {196, 145}, {204, 145}, {212, 145}, {220, 145}, {228, 145}, {236, 145}, {246, 141}, {252, 125}, {260, 129}, {280, 133}}; public final int vehicleNumber = 1; public final int depot = 0; }
C#
class DataModel { public int[,] Locations = { { 288, 149 }, { 288, 129 }, { 270, 133 }, { 256, 141 }, { 256, 157 }, { 246, 157 }, { 236, 169 }, { 228, 169 }, { 228, 161 }, { 220, 169 }, { 212, 169 }, { 204, 169 }, { 196, 169 }, { 188, 169 }, { 196, 161 }, { 188, 145 }, { 172, 145 }, { 164, 145 }, { 156, 145 }, { 148, 145 }, { 140, 145 }, { 148, 169 }, { 164, 169 }, { 172, 169 }, { 156, 169 }, { 140, 169 }, { 132, 169 }, { 124, 169 }, { 116, 161 }, { 104, 153 }, { 104, 161 }, { 104, 169 }, { 90, 165 }, { 80, 157 }, { 64, 157 }, { 64, 165 }, { 56, 169 }, { 56, 161 }, { 56, 153 }, { 56, 145 }, { 56, 137 }, { 56, 129 }, { 56, 121 }, { 40, 121 }, { 40, 129 }, { 40, 137 }, { 40, 145 }, { 40, 153 }, { 40, 161 }, { 40, 169 }, { 32, 169 }, { 32, 161 }, { 32, 153 }, { 32, 145 }, { 32, 137 }, { 32, 129 }, { 32, 121 }, { 32, 113 }, { 40, 113 }, { 56, 113 }, { 56, 105 }, { 48, 99 }, { 40, 99 }, { 32, 97 }, { 32, 89 }, { 24, 89 }, { 16, 97 }, { 16, 109 }, { 8, 109 }, { 8, 97 }, { 8, 89 }, { 8, 81 }, { 8, 73 }, { 8, 65 }, { 8, 57 }, { 16, 57 }, { 8, 49 }, { 8, 41 }, { 24, 45 }, { 32, 41 }, { 32, 49 }, { 32, 57 }, { 32, 65 }, { 32, 73 }, { 32, 81 }, { 40, 83 }, { 40, 73 }, { 40, 63 }, { 40, 51 }, { 44, 43 }, { 44, 35 }, { 44, 27 }, { 32, 25 }, { 24, 25 }, { 16, 25 }, { 16, 17 }, { 24, 17 }, { 32, 17 }, { 44, 11 }, { 56, 9 }, { 56, 17 }, { 56, 25 }, { 56, 33 }, { 56, 41 }, { 64, 41 }, { 72, 41 }, { 72, 49 }, { 56, 49 }, { 48, 51 }, { 56, 57 }, { 56, 65 }, { 48, 63 }, { 48, 73 }, { 56, 73 }, { 56, 81 }, { 48, 83 }, { 56, 89 }, { 56, 97 }, { 104, 97 }, { 104, 105 }, { 104, 113 }, { 104, 121 }, { 104, 129 }, { 104, 137 }, { 104, 145 }, { 116, 145 }, { 124, 145 }, { 132, 145 }, { 132, 137 }, { 140, 137 }, { 148, 137 }, { 156, 137 }, { 164, 137 }, { 172, 125 }, { 172, 117 }, { 172, 109 }, { 172, 101 }, { 172, 93 }, { 172, 85 }, { 180, 85 }, { 180, 77 }, { 180, 69 }, { 180, 61 }, { 180, 53 }, { 172, 53 }, { 172, 61 }, { 172, 69 }, { 172, 77 }, { 164, 81 }, { 148, 85 }, { 124, 85 }, { 124, 93 }, { 124, 109 }, { 124, 125 }, { 124, 117 }, { 124, 101 }, { 104, 89 }, { 104, 81 }, { 104, 73 }, { 104, 65 }, { 104, 49 }, { 104, 41 }, { 104, 33 }, { 104, 25 }, { 104, 17 }, { 92, 9 }, { 80, 9 }, { 72, 9 }, { 64, 21 }, { 72, 25 }, { 80, 25 }, { 80, 25 }, { 80, 41 }, { 88, 49 }, { 104, 57 }, { 124, 69 }, { 124, 77 }, { 132, 81 }, { 140, 65 }, { 132, 61 }, { 124, 61 }, { 124, 53 }, { 124, 45 }, { 124, 37 }, { 124, 29 }, { 132, 21 }, { 124, 21 }, { 120, 9 }, { 128, 9 }, { 136, 9 }, { 148, 9 }, { 162, 9 }, { 156, 25 }, { 172, 21 }, { 180, 21 }, { 180, 29 }, { 172, 29 }, { 172, 37 }, { 172, 45 }, { 180, 45 }, { 180, 37 }, { 188, 41 }, { 196, 49 }, { 204, 57 }, { 212, 65 }, { 220, 73 }, { 228, 69 }, { 228, 77 }, { 236, 77 }, { 236, 69 }, { 236, 61 }, { 228, 61 }, { 228, 53 }, { 236, 53 }, { 236, 45 }, { 228, 45 }, { 228, 37 }, { 236, 37 }, { 236, 29 }, { 228, 29 }, { 228, 21 }, { 236, 21 }, { 252, 21 }, { 260, 29 }, { 260, 37 }, { 260, 45 }, { 260, 53 }, { 260, 61 }, { 260, 69 }, { 260, 77 }, { 276, 77 }, { 276, 69 }, { 276, 61 }, { 276, 53 }, { 284, 53 }, { 284, 61 }, { 284, 69 }, { 284, 77 }, { 284, 85 }, { 284, 93 }, { 284, 101 }, { 288, 109 }, { 280, 109 }, { 276, 101 }, { 276, 93 }, { 276, 85 }, { 268, 97 }, { 260, 109 }, { 252, 101 }, { 260, 93 }, { 260, 85 }, { 236, 85 }, { 228, 85 }, { 228, 93 }, { 236, 93 }, { 236, 101 }, { 228, 101 }, { 228, 109 }, { 228, 117 }, { 228, 125 }, { 220, 125 }, { 212, 117 }, { 204, 109 }, { 196, 101 }, { 188, 93 }, { 180, 93 }, { 180, 101 }, { 180, 109 }, { 180, 117 }, { 180, 125 }, { 196, 145 }, { 204, 145 }, { 212, 145 }, { 220, 145 }, { 228, 145 }, { 236, 145 }, { 246, 141 }, { 252, 125 }, { 260, 129 }, { 280, 133 }, }; public int VehicleNumber = 1; public int Depot = 0; };
거리 행렬 계산
아래 함수는 데이터의 두 지점 간 유클리드 거리를 계산하여 배열에 저장합니다. 라우팅 솔버는 정수를 대상으로 하므로 이 함수는 계산된 거리를 정수로 반올림합니다. 반올림은 이 예시의 솔루션에 영향을 미치지 않지만 다른 경우에는 영향을 미칠 수 있습니다. 발생 가능한 반올림 문제를 방지하는 방법은 거리 행렬 확장을 참고하세요.
Python
def compute_euclidean_distance_matrix(locations): """Creates callback to return distance between points.""" distances = {} for from_counter, from_node in enumerate(locations): distances[from_counter] = {} for to_counter, to_node in enumerate(locations): if from_counter == to_counter: distances[from_counter][to_counter] = 0 else: # Euclidean distance distances[from_counter][to_counter] = int( math.hypot((from_node[0] - to_node[0]), (from_node[1] - to_node[1])) ) return distances
C++
// @brief Generate distance matrix. std::vector<std::vector<int64_t>> ComputeEuclideanDistanceMatrix( const std::vector<std::vector<int>>& locations) { std::vector<std::vector<int64_t>> distances = std::vector<std::vector<int64_t>>( locations.size(), std::vector<int64_t>(locations.size(), int64_t{0})); for (int from_node = 0; from_node < locations.size(); from_node++) { for (int to_node = 0; to_node < locations.size(); to_node++) { if (from_node != to_node) distances[from_node][to_node] = static_cast<int64_t>( std::hypot((locations[to_node][0] - locations[from_node][0]), (locations[to_node][1] - locations[from_node][1]))); } } return distances; }
자바
/// @brief Compute Euclidean distance matrix from locations array. /// @details It uses an array of locations and computes /// the Euclidean distance between any two locations. private static long[][] computeEuclideanDistanceMatrix(int[][] locations) { // Calculate distance matrix using Euclidean distance. long[][] distanceMatrix = new long[locations.length][locations.length]; for (int fromNode = 0; fromNode < locations.length; ++fromNode) { for (int toNode = 0; toNode < locations.length; ++toNode) { if (fromNode == toNode) { distanceMatrix[fromNode][toNode] = 0; } else { distanceMatrix[fromNode][toNode] = (long) Math.hypot(locations[toNode][0] - locations[fromNode][0], locations[toNode][1] - locations[fromNode][1]); } } } return distanceMatrix; }
C#
/// <summary> /// Euclidean distance implemented as a callback. It uses an array of /// positions and computes the Euclidean distance between the two /// positions of two different indices. /// </summary> static long[,] ComputeEuclideanDistanceMatrix(in int[,] locations) { // Calculate the distance matrix using Euclidean distance. int locationNumber = locations.GetLength(0); long[,] distanceMatrix = new long[locationNumber, locationNumber]; for (int fromNode = 0; fromNode < locationNumber; fromNode++) { for (int toNode = 0; toNode < locationNumber; toNode++) { if (fromNode == toNode) distanceMatrix[fromNode, toNode] = 0; else distanceMatrix[fromNode, toNode] = (long)Math.Sqrt(Math.Pow(locations[toNode, 0] - locations[fromNode, 0], 2) + Math.Pow(locations[toNode, 1] - locations[fromNode, 1], 2)); } } return distanceMatrix; }
거리 콜백 추가
거리 콜백을 생성하는 코드는 이전 예와 거의 동일합니다. 그러나 이 경우 프로그램은 콜백을 추가하기 전에 거리 행렬을 계산하는 함수를 호출합니다.
Python
distance_matrix = compute_euclidean_distance_matrix(data["locations"]) 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 distance_matrix[from_node][to_node] transit_callback_index = routing.RegisterTransitCallback(distance_callback) routing.SetArcCostEvaluatorOfAllVehicles(transit_callback_index)
C++
const auto distance_matrix = ComputeEuclideanDistanceMatrix(data.locations); const int transit_callback_index = routing.RegisterTransitCallback( [&distance_matrix, &manager](const int64_t from_index, const int64_t to_index) -> int64_t { // Convert from routing variable Index to distance matrix NodeIndex. const int from_node = manager.IndexToNode(from_index).value(); const int to_node = manager.IndexToNode(to_index).value(); return distance_matrix[from_node][to_node]; }); routing.SetArcCostEvaluatorOfAllVehicles(transit_callback_index);
자바
final long[][] distanceMatrix = computeEuclideanDistanceMatrix(data.locations); final int transitCallbackIndex = routing.registerTransitCallback((long fromIndex, long toIndex) -> { // Convert from routing variable Index to user NodeIndex. int fromNode = manager.indexToNode(fromIndex); int toNode = manager.indexToNode(toIndex); return distanceMatrix[fromNode][toNode]; }); routing.setArcCostEvaluatorOfAllVehicles(transitCallbackIndex);
C#
long[,] distanceMatrix = ComputeEuclideanDistanceMatrix(data.Locations); int transitCallbackIndex = routing.RegisterTransitCallback((long fromIndex, long toIndex) => { // Convert from routing variable Index to // distance matrix NodeIndex. var fromNode = manager.IndexToNode(fromIndex); var toNode = manager.IndexToNode(toIndex); return distanceMatrix[fromNode, toNode]; }); routing.SetArcCostEvaluatorOfAllVehicles(transitCallbackIndex);
솔루션 프린터
다음 함수는 솔루션을 콘솔에 출력합니다. 출력을 더 압축하기 위해 이 함수는 경로에 있는 위치의 색인만 표시합니다.
Python
def print_solution(manager, routing, solution): """Prints solution on console.""" print(f"Objective: {solution.ObjectiveValue()}") index = routing.Start(0) plan_output = "Route:\n" route_distance = 0 while not routing.IsEnd(index): plan_output += f" {manager.IndexToNode(index)} ->" previous_index = index index = solution.Value(routing.NextVar(index)) route_distance += routing.GetArcCostForVehicle(previous_index, index, 0) plan_output += f" {manager.IndexToNode(index)}\n" print(plan_output) plan_output += f"Objective: {route_distance}m\n"
C++
//! @brief Print the solution //! @param[in] manager Index manager used. //! @param[in] routing Routing solver used. //! @param[in] solution Solution found by the solver. void PrintSolution(const RoutingIndexManager& manager, const RoutingModel& routing, const Assignment& solution) { LOG(INFO) << "Objective: " << solution.ObjectiveValue(); // Inspect solution. int64_t index = routing.Start(0); LOG(INFO) << "Route:"; int64_t distance{0}; std::stringstream route; while (!routing.IsEnd(index)) { route << manager.IndexToNode(index).value() << " -> "; const int64_t previous_index = index; index = solution.Value(routing.NextVar(index)); distance += routing.GetArcCostForVehicle(previous_index, index, int64_t{0}); } LOG(INFO) << route.str() << manager.IndexToNode(index).value(); LOG(INFO) << "Route distance: " << distance << "miles"; LOG(INFO) << ""; LOG(INFO) << "Advanced usage:"; LOG(INFO) << "Problem solved in " << routing.solver()->wall_time() << "ms"; }
자바
/// @brief Print the solution. static void printSolution( RoutingModel routing, RoutingIndexManager manager, Assignment solution) { // Solution cost. logger.info("Objective: " + solution.objectiveValue()); // Inspect solution. logger.info("Route:"); long routeDistance = 0; String route = ""; long index = routing.start(0); while (!routing.isEnd(index)) { route += manager.indexToNode(index) + " -> "; long previousIndex = index; index = solution.value(routing.nextVar(index)); routing.getArcCostForVehicle(previousIndex, index, 0); } route += manager.indexToNode(routing.end(0)); logger.info(route); logger.info("Route distance: " + routeDistance); }
C#
/// <summary> /// Print the solution. /// </summary> static void PrintSolution(in RoutingModel routing, in RoutingIndexManager manager, in Assignment solution) { Console.WriteLine("Objective: {0}", solution.ObjectiveValue()); // Inspect solution. Console.WriteLine("Route:"); long routeDistance = 0; var index = routing.Start(0); while (routing.IsEnd(index) == false) { Console.Write("{0} -> ", manager.IndexToNode((int)index)); var previousIndex = index; index = solution.Value(routing.NextVar(index)); routeDistance += routing.GetArcCostForVehicle(previousIndex, index, 0); } Console.WriteLine("{0}", manager.IndexToNode((int)index)); Console.WriteLine("Route distance: {0}m", routeDistance); }
기본 함수
main 함수는 본질적으로 이전 예의 함수와 같지만 거리 행렬을 만드는 함수에 대한 호출도 포함합니다.
프로그램 실행
전체 프로그램은 다음 섹션에 나와 있습니다. 프로그램을 실행하면 다음 경로가 표시됩니다.
Total distance: 2790 Route of vehicle 0: 0 -> 1 -> 279 -> 2 -> 278 -> 277 -> 247 -> 248 -> 249 -> 246 -> 244 -> 243 -> 242 -> 241 -> 240 -> 239 -> 238 -> 237 -> 236 -> 235 -> 234 -> 233 -> 232 -> 231 -> 230 -> 245 -> 250 -> 229 -> 228 -> 227 -> 226 -> 225 -> 224 -> 223 -> 222 -> 221 -> 220 -> 219 -> 218 -> 217 -> 216 -> 215 -> 214 -> 213 -> 212 -> 211 -> 210 -> 209 -> 208 -> 251 -> 254 -> 255 -> 257 -> 256 -> 253 -> 252 -> 207 -> 206 -> 205 -> 204 -> 203 -> 202 -> 142 -> 141 -> 146 -> 147 -> 140 -> 139 -> 265 -> 136 -> 137 -> 138 -> 148 -> 149 -> 177 -> 176 -> 175 -> 178 -> 179 -> 180 -> 181 -> 182 -> 183 -> 184 -> 186 -> 185 -> 192 -> 196 -> 197 -> 198 -> 144 -> 145 -> 143 -> 199 -> 201 -> 200 -> 195 -> 194 -> 193 -> 191 -> 190 -> 189 -> 188 -> 187 -> 163 -> 164 -> 165 -> 166 -> 167 -> 168 -> 169 -> 171 -> 170 -> 172 -> 105 -> 106 -> 104 -> 103 -> 107 -> 109 -> 110 -> 113 -> 114 -> 116 -> 117 -> 61 -> 62 -> 63 -> 65 -> 64 -> 84 -> 85 -> 115 -> 112 -> 86 -> 83 -> 82 -> 87 -> 111 -> 108 -> 89 -> 90 -> 91 -> 102 -> 101 -> 100 -> 99 -> 98 -> 97 -> 96 -> 95 -> 94 -> 93 -> 92 -> 79 -> 88 -> 81 -> 80 -> 78 -> 77 -> 76 -> 74 -> 75 -> 73 -> 72 -> 71 -> 70 -> 69 -> 66 -> 68 -> 67 -> 57 -> 56 -> 55 -> 54 -> 53 -> 52 -> 51 -> 50 -> 49 -> 48 -> 47 -> 46 -> 45 -> 44 -> 43 -> 58 -> 60 -> 59 -> 42 -> 41 -> 40 -> 39 -> 38 -> 37 -> 36 -> 35 -> 34 -> 33 -> 32 -> 31 -> 30 -> 29 -> 124 -> 123 -> 122 -> 121 -> 120 -> 119 -> 118 -> 156 -> 157 -> 158 -> 173 -> 162 -> 161 -> 160 -> 174 -> 159 -> 150 -> 151 -> 155 -> 152 -> 154 -> 153 -> 128 -> 129 -> 130 -> 131 -> 18 -> 19 -> 20 -> 127 -> 126 -> 125 -> 28 -> 27 -> 26 -> 25 -> 21 -> 24 -> 22 -> 23 -> 13 -> 12 -> 14 -> 11 -> 10 -> 9 -> 7 -> 8 -> 6 -> 5 -> 275 -> 274 -> 273 -> 272 -> 271 -> 270 -> 15 -> 16 -> 17 -> 132 -> 133 -> 269 -> 268 -> 134 -> 135 -> 267 -> 266 -> 264 -> 263 -> 262 -> 261 -> 260 -> 258 -> 259 -> 276 -> 3 -> 4 -> 0
다음은 해당 경로의 그래프입니다.
OR 도구 라이브러리는 위의 둘러보기를 매우 빠르게 찾습니다. 일반적인 컴퓨터의 경우에는 1초도 걸리지 않습니다. 위 둘러보기의 총 길이는 2,790회입니다.
프로그램 완료
회로 기판의 전체 프로그램은 다음과 같습니다.
Python
"""Simple Travelling Salesperson Problem (TSP) on a circuit board.""" import math 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 = {} # Locations in block units data["locations"] = [ # fmt: off (288, 149), (288, 129), (270, 133), (256, 141), (256, 157), (246, 157), (236, 169), (228, 169), (228, 161), (220, 169), (212, 169), (204, 169), (196, 169), (188, 169), (196, 161), (188, 145), (172, 145), (164, 145), (156, 145), (148, 145), (140, 145), (148, 169), (164, 169), (172, 169), (156, 169), (140, 169), (132, 169), (124, 169), (116, 161), (104, 153), (104, 161), (104, 169), (90, 165), (80, 157), (64, 157), (64, 165), (56, 169), (56, 161), (56, 153), (56, 145), (56, 137), (56, 129), (56, 121), (40, 121), (40, 129), (40, 137), (40, 145), (40, 153), (40, 161), (40, 169), (32, 169), (32, 161), (32, 153), (32, 145), (32, 137), (32, 129), (32, 121), (32, 113), (40, 113), (56, 113), (56, 105), (48, 99), (40, 99), (32, 97), (32, 89), (24, 89), (16, 97), (16, 109), (8, 109), (8, 97), (8, 89), (8, 81), (8, 73), (8, 65), (8, 57), (16, 57), (8, 49), (8, 41), (24, 45), (32, 41), (32, 49), (32, 57), (32, 65), (32, 73), (32, 81), (40, 83), (40, 73), (40, 63), (40, 51), (44, 43), (44, 35), (44, 27), (32, 25), (24, 25), (16, 25), (16, 17), (24, 17), (32, 17), (44, 11), (56, 9), (56, 17), (56, 25), (56, 33), (56, 41), (64, 41), (72, 41), (72, 49), (56, 49), (48, 51), (56, 57), (56, 65), (48, 63), (48, 73), (56, 73), (56, 81), (48, 83), (56, 89), (56, 97), (104, 97), (104, 105), (104, 113), (104, 121), (104, 129), (104, 137), (104, 145), (116, 145), (124, 145), (132, 145), (132, 137), (140, 137), (148, 137), (156, 137), (164, 137), (172, 125), (172, 117), (172, 109), (172, 101), (172, 93), (172, 85), (180, 85), (180, 77), (180, 69), (180, 61), (180, 53), (172, 53), (172, 61), (172, 69), (172, 77), (164, 81), (148, 85), (124, 85), (124, 93), (124, 109), (124, 125), (124, 117), (124, 101), (104, 89), (104, 81), (104, 73), (104, 65), (104, 49), (104, 41), (104, 33), (104, 25), (104, 17), (92, 9), (80, 9), (72, 9), (64, 21), (72, 25), (80, 25), (80, 25), (80, 41), (88, 49), (104, 57), (124, 69), (124, 77), (132, 81), (140, 65), (132, 61), (124, 61), (124, 53), (124, 45), (124, 37), (124, 29), (132, 21), (124, 21), (120, 9), (128, 9), (136, 9), (148, 9), (162, 9), (156, 25), (172, 21), (180, 21), (180, 29), (172, 29), (172, 37), (172, 45), (180, 45), (180, 37), (188, 41), (196, 49), (204, 57), (212, 65), (220, 73), (228, 69), (228, 77), (236, 77), (236, 69), (236, 61), (228, 61), (228, 53), (236, 53), (236, 45), (228, 45), (228, 37), (236, 37), (236, 29), (228, 29), (228, 21), (236, 21), (252, 21), (260, 29), (260, 37), (260, 45), (260, 53), (260, 61), (260, 69), (260, 77), (276, 77), (276, 69), (276, 61), (276, 53), (284, 53), (284, 61), (284, 69), (284, 77), (284, 85), (284, 93), (284, 101), (288, 109), (280, 109), (276, 101), (276, 93), (276, 85), (268, 97), (260, 109), (252, 101), (260, 93), (260, 85), (236, 85), (228, 85), (228, 93), (236, 93), (236, 101), (228, 101), (228, 109), (228, 117), (228, 125), (220, 125), (212, 117), (204, 109), (196, 101), (188, 93), (180, 93), (180, 101), (180, 109), (180, 117), (180, 125), (196, 145), (204, 145), (212, 145), (220, 145), (228, 145), (236, 145), (246, 141), (252, 125), (260, 129), (280, 133) # fmt: on ] data["num_vehicles"] = 1 data["depot"] = 0 return data def compute_euclidean_distance_matrix(locations): """Creates callback to return distance between points.""" distances = {} for from_counter, from_node in enumerate(locations): distances[from_counter] = {} for to_counter, to_node in enumerate(locations): if from_counter == to_counter: distances[from_counter][to_counter] = 0 else: # Euclidean distance distances[from_counter][to_counter] = int( math.hypot((from_node[0] - to_node[0]), (from_node[1] - to_node[1])) ) return distances def print_solution(manager, routing, solution): """Prints solution on console.""" print(f"Objective: {solution.ObjectiveValue()}") index = routing.Start(0) plan_output = "Route:\n" route_distance = 0 while not routing.IsEnd(index): plan_output += f" {manager.IndexToNode(index)} ->" previous_index = index index = solution.Value(routing.NextVar(index)) route_distance += routing.GetArcCostForVehicle(previous_index, index, 0) plan_output += f" {manager.IndexToNode(index)}\n" print(plan_output) plan_output += f"Objective: {route_distance}m\n" 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["locations"]), data["num_vehicles"], data["depot"] ) # Create Routing Model. routing = pywrapcp.RoutingModel(manager) distance_matrix = compute_euclidean_distance_matrix(data["locations"]) 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 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()
C++
#include <cmath> #include <cstdint> #include <sstream> #include <vector> #include "ortools/constraint_solver/routing.h" #include "ortools/constraint_solver/routing_enums.pb.h" #include "ortools/constraint_solver/routing_index_manager.h" #include "ortools/constraint_solver/routing_parameters.h" namespace operations_research { struct DataModel { const std::vector<std::vector<int>> locations{ {288, 149}, {288, 129}, {270, 133}, {256, 141}, {256, 157}, {246, 157}, {236, 169}, {228, 169}, {228, 161}, {220, 169}, {212, 169}, {204, 169}, {196, 169}, {188, 169}, {196, 161}, {188, 145}, {172, 145}, {164, 145}, {156, 145}, {148, 145}, {140, 145}, {148, 169}, {164, 169}, {172, 169}, {156, 169}, {140, 169}, {132, 169}, {124, 169}, {116, 161}, {104, 153}, {104, 161}, {104, 169}, {90, 165}, {80, 157}, {64, 157}, {64, 165}, {56, 169}, {56, 161}, {56, 153}, {56, 145}, {56, 137}, {56, 129}, {56, 121}, {40, 121}, {40, 129}, {40, 137}, {40, 145}, {40, 153}, {40, 161}, {40, 169}, {32, 169}, {32, 161}, {32, 153}, {32, 145}, {32, 137}, {32, 129}, {32, 121}, {32, 113}, {40, 113}, {56, 113}, {56, 105}, {48, 99}, {40, 99}, {32, 97}, {32, 89}, {24, 89}, {16, 97}, {16, 109}, {8, 109}, {8, 97}, {8, 89}, {8, 81}, {8, 73}, {8, 65}, {8, 57}, {16, 57}, {8, 49}, {8, 41}, {24, 45}, {32, 41}, {32, 49}, {32, 57}, {32, 65}, {32, 73}, {32, 81}, {40, 83}, {40, 73}, {40, 63}, {40, 51}, {44, 43}, {44, 35}, {44, 27}, {32, 25}, {24, 25}, {16, 25}, {16, 17}, {24, 17}, {32, 17}, {44, 11}, {56, 9}, {56, 17}, {56, 25}, {56, 33}, {56, 41}, {64, 41}, {72, 41}, {72, 49}, {56, 49}, {48, 51}, {56, 57}, {56, 65}, {48, 63}, {48, 73}, {56, 73}, {56, 81}, {48, 83}, {56, 89}, {56, 97}, {104, 97}, {104, 105}, {104, 113}, {104, 121}, {104, 129}, {104, 137}, {104, 145}, {116, 145}, {124, 145}, {132, 145}, {132, 137}, {140, 137}, {148, 137}, {156, 137}, {164, 137}, {172, 125}, {172, 117}, {172, 109}, {172, 101}, {172, 93}, {172, 85}, {180, 85}, {180, 77}, {180, 69}, {180, 61}, {180, 53}, {172, 53}, {172, 61}, {172, 69}, {172, 77}, {164, 81}, {148, 85}, {124, 85}, {124, 93}, {124, 109}, {124, 125}, {124, 117}, {124, 101}, {104, 89}, {104, 81}, {104, 73}, {104, 65}, {104, 49}, {104, 41}, {104, 33}, {104, 25}, {104, 17}, {92, 9}, {80, 9}, {72, 9}, {64, 21}, {72, 25}, {80, 25}, {80, 25}, {80, 41}, {88, 49}, {104, 57}, {124, 69}, {124, 77}, {132, 81}, {140, 65}, {132, 61}, {124, 61}, {124, 53}, {124, 45}, {124, 37}, {124, 29}, {132, 21}, {124, 21}, {120, 9}, {128, 9}, {136, 9}, {148, 9}, {162, 9}, {156, 25}, {172, 21}, {180, 21}, {180, 29}, {172, 29}, {172, 37}, {172, 45}, {180, 45}, {180, 37}, {188, 41}, {196, 49}, {204, 57}, {212, 65}, {220, 73}, {228, 69}, {228, 77}, {236, 77}, {236, 69}, {236, 61}, {228, 61}, {228, 53}, {236, 53}, {236, 45}, {228, 45}, {228, 37}, {236, 37}, {236, 29}, {228, 29}, {228, 21}, {236, 21}, {252, 21}, {260, 29}, {260, 37}, {260, 45}, {260, 53}, {260, 61}, {260, 69}, {260, 77}, {276, 77}, {276, 69}, {276, 61}, {276, 53}, {284, 53}, {284, 61}, {284, 69}, {284, 77}, {284, 85}, {284, 93}, {284, 101}, {288, 109}, {280, 109}, {276, 101}, {276, 93}, {276, 85}, {268, 97}, {260, 109}, {252, 101}, {260, 93}, {260, 85}, {236, 85}, {228, 85}, {228, 93}, {236, 93}, {236, 101}, {228, 101}, {228, 109}, {228, 117}, {228, 125}, {220, 125}, {212, 117}, {204, 109}, {196, 101}, {188, 93}, {180, 93}, {180, 101}, {180, 109}, {180, 117}, {180, 125}, {196, 145}, {204, 145}, {212, 145}, {220, 145}, {228, 145}, {236, 145}, {246, 141}, {252, 125}, {260, 129}, {280, 133}, }; const int num_vehicles = 1; const RoutingIndexManager::NodeIndex depot{0}; }; // @brief Generate distance matrix. std::vector<std::vector<int64_t>> ComputeEuclideanDistanceMatrix( const std::vector<std::vector<int>>& locations) { std::vector<std::vector<int64_t>> distances = std::vector<std::vector<int64_t>>( locations.size(), std::vector<int64_t>(locations.size(), int64_t{0})); for (int from_node = 0; from_node < locations.size(); from_node++) { for (int to_node = 0; to_node < locations.size(); to_node++) { if (from_node != to_node) distances[from_node][to_node] = static_cast<int64_t>( std::hypot((locations[to_node][0] - locations[from_node][0]), (locations[to_node][1] - locations[from_node][1]))); } } return distances; } //! @brief Print the solution //! @param[in] manager Index manager used. //! @param[in] routing Routing solver used. //! @param[in] solution Solution found by the solver. void PrintSolution(const RoutingIndexManager& manager, const RoutingModel& routing, const Assignment& solution) { LOG(INFO) << "Objective: " << solution.ObjectiveValue(); // Inspect solution. int64_t index = routing.Start(0); LOG(INFO) << "Route:"; int64_t distance{0}; std::stringstream route; while (!routing.IsEnd(index)) { route << manager.IndexToNode(index).value() << " -> "; const int64_t previous_index = index; index = solution.Value(routing.NextVar(index)); distance += routing.GetArcCostForVehicle(previous_index, index, int64_t{0}); } LOG(INFO) << route.str() << manager.IndexToNode(index).value(); LOG(INFO) << "Route distance: " << distance << "miles"; LOG(INFO) << ""; LOG(INFO) << "Advanced usage:"; LOG(INFO) << "Problem solved in " << routing.solver()->wall_time() << "ms"; } void Tsp() { // Instantiate the data problem. DataModel data; // Create Routing Index Manager RoutingIndexManager manager(data.locations.size(), data.num_vehicles, data.depot); // Create Routing Model. RoutingModel routing(manager); const auto distance_matrix = ComputeEuclideanDistanceMatrix(data.locations); const int transit_callback_index = routing.RegisterTransitCallback( [&distance_matrix, &manager](const int64_t from_index, const int64_t to_index) -> int64_t { // Convert from routing variable Index to distance matrix NodeIndex. const int from_node = manager.IndexToNode(from_index).value(); const int to_node = manager.IndexToNode(to_index).value(); return distance_matrix[from_node][to_node]; }); // Define cost of each arc. routing.SetArcCostEvaluatorOfAllVehicles(transit_callback_index); // Setting first solution heuristic. RoutingSearchParameters searchParameters = DefaultRoutingSearchParameters(); searchParameters.set_first_solution_strategy( FirstSolutionStrategy::PATH_CHEAPEST_ARC); // Solve the problem. const Assignment* solution = routing.SolveWithParameters(searchParameters); // Print solution on console. PrintSolution(manager, routing, *solution); } } // namespace operations_research int main(int /*argc*/, char* /*argv*/[]) { operations_research::Tsp(); return EXIT_SUCCESS; }
자바
package com.google.ortools.constraintsolver.samples; import com.google.ortools.Loader; import com.google.ortools.constraintsolver.Assignment; import com.google.ortools.constraintsolver.FirstSolutionStrategy; import com.google.ortools.constraintsolver.RoutingIndexManager; import com.google.ortools.constraintsolver.RoutingModel; import com.google.ortools.constraintsolver.RoutingSearchParameters; import com.google.ortools.constraintsolver.main; import java.util.logging.Logger; /** Minimal TSP. */ public class TspCircuitBoard { private static final Logger logger = Logger.getLogger(TspCircuitBoard.class.getName()); static class DataModel { public final int[][] locations = {{288, 149}, {288, 129}, {270, 133}, {256, 141}, {256, 157}, {246, 157}, {236, 169}, {228, 169}, {228, 161}, {220, 169}, {212, 169}, {204, 169}, {196, 169}, {188, 169}, {196, 161}, {188, 145}, {172, 145}, {164, 145}, {156, 145}, {148, 145}, {140, 145}, {148, 169}, {164, 169}, {172, 169}, {156, 169}, {140, 169}, {132, 169}, {124, 169}, {116, 161}, {104, 153}, {104, 161}, {104, 169}, {90, 165}, {80, 157}, {64, 157}, {64, 165}, {56, 169}, {56, 161}, {56, 153}, {56, 145}, {56, 137}, {56, 129}, {56, 121}, {40, 121}, {40, 129}, {40, 137}, {40, 145}, {40, 153}, {40, 161}, {40, 169}, {32, 169}, {32, 161}, {32, 153}, {32, 145}, {32, 137}, {32, 129}, {32, 121}, {32, 113}, {40, 113}, {56, 113}, {56, 105}, {48, 99}, {40, 99}, {32, 97}, {32, 89}, {24, 89}, {16, 97}, {16, 109}, {8, 109}, {8, 97}, {8, 89}, {8, 81}, {8, 73}, {8, 65}, {8, 57}, {16, 57}, {8, 49}, {8, 41}, {24, 45}, {32, 41}, {32, 49}, {32, 57}, {32, 65}, {32, 73}, {32, 81}, {40, 83}, {40, 73}, {40, 63}, {40, 51}, {44, 43}, {44, 35}, {44, 27}, {32, 25}, {24, 25}, {16, 25}, {16, 17}, {24, 17}, {32, 17}, {44, 11}, {56, 9}, {56, 17}, {56, 25}, {56, 33}, {56, 41}, {64, 41}, {72, 41}, {72, 49}, {56, 49}, {48, 51}, {56, 57}, {56, 65}, {48, 63}, {48, 73}, {56, 73}, {56, 81}, {48, 83}, {56, 89}, {56, 97}, {104, 97}, {104, 105}, {104, 113}, {104, 121}, {104, 129}, {104, 137}, {104, 145}, {116, 145}, {124, 145}, {132, 145}, {132, 137}, {140, 137}, {148, 137}, {156, 137}, {164, 137}, {172, 125}, {172, 117}, {172, 109}, {172, 101}, {172, 93}, {172, 85}, {180, 85}, {180, 77}, {180, 69}, {180, 61}, {180, 53}, {172, 53}, {172, 61}, {172, 69}, {172, 77}, {164, 81}, {148, 85}, {124, 85}, {124, 93}, {124, 109}, {124, 125}, {124, 117}, {124, 101}, {104, 89}, {104, 81}, {104, 73}, {104, 65}, {104, 49}, {104, 41}, {104, 33}, {104, 25}, {104, 17}, {92, 9}, {80, 9}, {72, 9}, {64, 21}, {72, 25}, {80, 25}, {80, 25}, {80, 41}, {88, 49}, {104, 57}, {124, 69}, {124, 77}, {132, 81}, {140, 65}, {132, 61}, {124, 61}, {124, 53}, {124, 45}, {124, 37}, {124, 29}, {132, 21}, {124, 21}, {120, 9}, {128, 9}, {136, 9}, {148, 9}, {162, 9}, {156, 25}, {172, 21}, {180, 21}, {180, 29}, {172, 29}, {172, 37}, {172, 45}, {180, 45}, {180, 37}, {188, 41}, {196, 49}, {204, 57}, {212, 65}, {220, 73}, {228, 69}, {228, 77}, {236, 77}, {236, 69}, {236, 61}, {228, 61}, {228, 53}, {236, 53}, {236, 45}, {228, 45}, {228, 37}, {236, 37}, {236, 29}, {228, 29}, {228, 21}, {236, 21}, {252, 21}, {260, 29}, {260, 37}, {260, 45}, {260, 53}, {260, 61}, {260, 69}, {260, 77}, {276, 77}, {276, 69}, {276, 61}, {276, 53}, {284, 53}, {284, 61}, {284, 69}, {284, 77}, {284, 85}, {284, 93}, {284, 101}, {288, 109}, {280, 109}, {276, 101}, {276, 93}, {276, 85}, {268, 97}, {260, 109}, {252, 101}, {260, 93}, {260, 85}, {236, 85}, {228, 85}, {228, 93}, {236, 93}, {236, 101}, {228, 101}, {228, 109}, {228, 117}, {228, 125}, {220, 125}, {212, 117}, {204, 109}, {196, 101}, {188, 93}, {180, 93}, {180, 101}, {180, 109}, {180, 117}, {180, 125}, {196, 145}, {204, 145}, {212, 145}, {220, 145}, {228, 145}, {236, 145}, {246, 141}, {252, 125}, {260, 129}, {280, 133}}; public final int vehicleNumber = 1; public final int depot = 0; } /// @brief Compute Euclidean distance matrix from locations array. /// @details It uses an array of locations and computes /// the Euclidean distance between any two locations. private static long[][] computeEuclideanDistanceMatrix(int[][] locations) { // Calculate distance matrix using Euclidean distance. long[][] distanceMatrix = new long[locations.length][locations.length]; for (int fromNode = 0; fromNode < locations.length; ++fromNode) { for (int toNode = 0; toNode < locations.length; ++toNode) { if (fromNode == toNode) { distanceMatrix[fromNode][toNode] = 0; } else { distanceMatrix[fromNode][toNode] = (long) Math.hypot(locations[toNode][0] - locations[fromNode][0], locations[toNode][1] - locations[fromNode][1]); } } } return distanceMatrix; } /// @brief Print the solution. static void printSolution( RoutingModel routing, RoutingIndexManager manager, Assignment solution) { // Solution cost. logger.info("Objective: " + solution.objectiveValue()); // Inspect solution. logger.info("Route:"); long routeDistance = 0; String route = ""; long index = routing.start(0); while (!routing.isEnd(index)) { route += manager.indexToNode(index) + " -> "; long previousIndex = index; index = solution.value(routing.nextVar(index)); routing.getArcCostForVehicle(previousIndex, index, 0); } route += manager.indexToNode(routing.end(0)); logger.info(route); logger.info("Route distance: " + routeDistance); } public static void main(String[] args) throws Exception { Loader.loadNativeLibraries(); // Instantiate the data problem. final DataModel data = new DataModel(); // Create Routing Index Manager RoutingIndexManager manager = new RoutingIndexManager(data.locations.length, data.vehicleNumber, data.depot); // Create Routing Model. RoutingModel routing = new RoutingModel(manager); // Create and register a transit callback. final long[][] distanceMatrix = computeEuclideanDistanceMatrix(data.locations); final int transitCallbackIndex = routing.registerTransitCallback((long fromIndex, long toIndex) -> { // Convert from routing variable Index to user NodeIndex. int fromNode = manager.indexToNode(fromIndex); int toNode = manager.indexToNode(toIndex); return distanceMatrix[fromNode][toNode]; }); // Define cost of each arc. routing.setArcCostEvaluatorOfAllVehicles(transitCallbackIndex); // Setting first solution heuristic. RoutingSearchParameters searchParameters = main.defaultRoutingSearchParameters() .toBuilder() .setFirstSolutionStrategy(FirstSolutionStrategy.Value.PATH_CHEAPEST_ARC) .build(); // Solve the problem. Assignment solution = routing.solveWithParameters(searchParameters); // Print solution on console. printSolution(routing, manager, solution); } }
C#
using System; using System.Collections.Generic; using Google.OrTools.ConstraintSolver; /// <summary> /// Minimal TSP. /// A description of the problem can be found here: /// http://en.wikipedia.org/wiki/Travelling_salesperson_problem. /// </summary> public class TspCircuitBoard { class DataModel { public int[,] Locations = { { 288, 149 }, { 288, 129 }, { 270, 133 }, { 256, 141 }, { 256, 157 }, { 246, 157 }, { 236, 169 }, { 228, 169 }, { 228, 161 }, { 220, 169 }, { 212, 169 }, { 204, 169 }, { 196, 169 }, { 188, 169 }, { 196, 161 }, { 188, 145 }, { 172, 145 }, { 164, 145 }, { 156, 145 }, { 148, 145 }, { 140, 145 }, { 148, 169 }, { 164, 169 }, { 172, 169 }, { 156, 169 }, { 140, 169 }, { 132, 169 }, { 124, 169 }, { 116, 161 }, { 104, 153 }, { 104, 161 }, { 104, 169 }, { 90, 165 }, { 80, 157 }, { 64, 157 }, { 64, 165 }, { 56, 169 }, { 56, 161 }, { 56, 153 }, { 56, 145 }, { 56, 137 }, { 56, 129 }, { 56, 121 }, { 40, 121 }, { 40, 129 }, { 40, 137 }, { 40, 145 }, { 40, 153 }, { 40, 161 }, { 40, 169 }, { 32, 169 }, { 32, 161 }, { 32, 153 }, { 32, 145 }, { 32, 137 }, { 32, 129 }, { 32, 121 }, { 32, 113 }, { 40, 113 }, { 56, 113 }, { 56, 105 }, { 48, 99 }, { 40, 99 }, { 32, 97 }, { 32, 89 }, { 24, 89 }, { 16, 97 }, { 16, 109 }, { 8, 109 }, { 8, 97 }, { 8, 89 }, { 8, 81 }, { 8, 73 }, { 8, 65 }, { 8, 57 }, { 16, 57 }, { 8, 49 }, { 8, 41 }, { 24, 45 }, { 32, 41 }, { 32, 49 }, { 32, 57 }, { 32, 65 }, { 32, 73 }, { 32, 81 }, { 40, 83 }, { 40, 73 }, { 40, 63 }, { 40, 51 }, { 44, 43 }, { 44, 35 }, { 44, 27 }, { 32, 25 }, { 24, 25 }, { 16, 25 }, { 16, 17 }, { 24, 17 }, { 32, 17 }, { 44, 11 }, { 56, 9 }, { 56, 17 }, { 56, 25 }, { 56, 33 }, { 56, 41 }, { 64, 41 }, { 72, 41 }, { 72, 49 }, { 56, 49 }, { 48, 51 }, { 56, 57 }, { 56, 65 }, { 48, 63 }, { 48, 73 }, { 56, 73 }, { 56, 81 }, { 48, 83 }, { 56, 89 }, { 56, 97 }, { 104, 97 }, { 104, 105 }, { 104, 113 }, { 104, 121 }, { 104, 129 }, { 104, 137 }, { 104, 145 }, { 116, 145 }, { 124, 145 }, { 132, 145 }, { 132, 137 }, { 140, 137 }, { 148, 137 }, { 156, 137 }, { 164, 137 }, { 172, 125 }, { 172, 117 }, { 172, 109 }, { 172, 101 }, { 172, 93 }, { 172, 85 }, { 180, 85 }, { 180, 77 }, { 180, 69 }, { 180, 61 }, { 180, 53 }, { 172, 53 }, { 172, 61 }, { 172, 69 }, { 172, 77 }, { 164, 81 }, { 148, 85 }, { 124, 85 }, { 124, 93 }, { 124, 109 }, { 124, 125 }, { 124, 117 }, { 124, 101 }, { 104, 89 }, { 104, 81 }, { 104, 73 }, { 104, 65 }, { 104, 49 }, { 104, 41 }, { 104, 33 }, { 104, 25 }, { 104, 17 }, { 92, 9 }, { 80, 9 }, { 72, 9 }, { 64, 21 }, { 72, 25 }, { 80, 25 }, { 80, 25 }, { 80, 41 }, { 88, 49 }, { 104, 57 }, { 124, 69 }, { 124, 77 }, { 132, 81 }, { 140, 65 }, { 132, 61 }, { 124, 61 }, { 124, 53 }, { 124, 45 }, { 124, 37 }, { 124, 29 }, { 132, 21 }, { 124, 21 }, { 120, 9 }, { 128, 9 }, { 136, 9 }, { 148, 9 }, { 162, 9 }, { 156, 25 }, { 172, 21 }, { 180, 21 }, { 180, 29 }, { 172, 29 }, { 172, 37 }, { 172, 45 }, { 180, 45 }, { 180, 37 }, { 188, 41 }, { 196, 49 }, { 204, 57 }, { 212, 65 }, { 220, 73 }, { 228, 69 }, { 228, 77 }, { 236, 77 }, { 236, 69 }, { 236, 61 }, { 228, 61 }, { 228, 53 }, { 236, 53 }, { 236, 45 }, { 228, 45 }, { 228, 37 }, { 236, 37 }, { 236, 29 }, { 228, 29 }, { 228, 21 }, { 236, 21 }, { 252, 21 }, { 260, 29 }, { 260, 37 }, { 260, 45 }, { 260, 53 }, { 260, 61 }, { 260, 69 }, { 260, 77 }, { 276, 77 }, { 276, 69 }, { 276, 61 }, { 276, 53 }, { 284, 53 }, { 284, 61 }, { 284, 69 }, { 284, 77 }, { 284, 85 }, { 284, 93 }, { 284, 101 }, { 288, 109 }, { 280, 109 }, { 276, 101 }, { 276, 93 }, { 276, 85 }, { 268, 97 }, { 260, 109 }, { 252, 101 }, { 260, 93 }, { 260, 85 }, { 236, 85 }, { 228, 85 }, { 228, 93 }, { 236, 93 }, { 236, 101 }, { 228, 101 }, { 228, 109 }, { 228, 117 }, { 228, 125 }, { 220, 125 }, { 212, 117 }, { 204, 109 }, { 196, 101 }, { 188, 93 }, { 180, 93 }, { 180, 101 }, { 180, 109 }, { 180, 117 }, { 180, 125 }, { 196, 145 }, { 204, 145 }, { 212, 145 }, { 220, 145 }, { 228, 145 }, { 236, 145 }, { 246, 141 }, { 252, 125 }, { 260, 129 }, { 280, 133 }, }; public int VehicleNumber = 1; public int Depot = 0; }; /// <summary> /// Euclidean distance implemented as a callback. It uses an array of /// positions and computes the Euclidean distance between the two /// positions of two different indices. /// </summary> static long[,] ComputeEuclideanDistanceMatrix(in int[,] locations) { // Calculate the distance matrix using Euclidean distance. int locationNumber = locations.GetLength(0); long[,] distanceMatrix = new long[locationNumber, locationNumber]; for (int fromNode = 0; fromNode < locationNumber; fromNode++) { for (int toNode = 0; toNode < locationNumber; toNode++) { if (fromNode == toNode) distanceMatrix[fromNode, toNode] = 0; else distanceMatrix[fromNode, toNode] = (long)Math.Sqrt(Math.Pow(locations[toNode, 0] - locations[fromNode, 0], 2) + Math.Pow(locations[toNode, 1] - locations[fromNode, 1], 2)); } } return distanceMatrix; } /// <summary> /// Print the solution. /// </summary> static void PrintSolution(in RoutingModel routing, in RoutingIndexManager manager, in Assignment solution) { Console.WriteLine("Objective: {0}", solution.ObjectiveValue()); // Inspect solution. Console.WriteLine("Route:"); long routeDistance = 0; var index = routing.Start(0); while (routing.IsEnd(index) == false) { Console.Write("{0} -> ", manager.IndexToNode((int)index)); var previousIndex = index; index = solution.Value(routing.NextVar(index)); routeDistance += routing.GetArcCostForVehicle(previousIndex, index, 0); } Console.WriteLine("{0}", manager.IndexToNode((int)index)); Console.WriteLine("Route distance: {0}m", routeDistance); } public static void Main(String[] args) { // Instantiate the data problem. DataModel data = new DataModel(); // Create Routing Index Manager RoutingIndexManager manager = new RoutingIndexManager(data.Locations.GetLength(0), data.VehicleNumber, data.Depot); // Create Routing Model. RoutingModel routing = new RoutingModel(manager); // Define cost of each arc. long[,] distanceMatrix = ComputeEuclideanDistanceMatrix(data.Locations); int transitCallbackIndex = routing.RegisterTransitCallback((long fromIndex, long toIndex) => { // Convert from routing variable Index to // distance matrix NodeIndex. var fromNode = manager.IndexToNode(fromIndex); var toNode = manager.IndexToNode(toIndex); return distanceMatrix[fromNode, toNode]; }); routing.SetArcCostEvaluatorOfAllVehicles(transitCallbackIndex); // Setting first solution heuristic. RoutingSearchParameters searchParameters = operations_research_constraint_solver.DefaultRoutingSearchParameters(); searchParameters.FirstSolutionStrategy = FirstSolutionStrategy.Types.Value.PathCheapestArc; // Solve the problem. Assignment solution = routing.SolveWithParameters(searchParameters); // Print solution on console. PrintSolution(routing, manager, solution); } }
검색 전략 변경
라우팅 문제는 계산이 어렵기 때문에 라우팅 솔버가 항상 최적의 솔루션을 TSP에 반환하지는 않습니다. 예를 들어 이전 예시에서 반환된 솔루션은 최적의 경로가 아닙니다.
더 나은 해결 방법을 찾으려면 가이드 로컬 검색이라는 고급 검색 전략을 사용하면 됩니다. 이 전략을 통해 솔버가 로컬 최소값을 이스케이프 처리할 수 있습니다. 이 솔루션은 근처의 모든 경로보다 짧지만 전역 최솟값은 아닙니다. 솔버는 로컬 최솟값에서 벗어난 후 검색을 계속합니다.
아래의 예는 회로 기판 예시에 대해 지역 가이드 검색을 설정하는 방법을 보여줍니다.
Python
search_parameters = pywrapcp.DefaultRoutingSearchParameters() search_parameters.local_search_metaheuristic = ( routing_enums_pb2.LocalSearchMetaheuristic.GUIDED_LOCAL_SEARCH) search_parameters.time_limit.seconds = 30 search_parameters.log_search = True
C++
RoutingSearchParameters searchParameters = DefaultRoutingSearchParameters(); searchParameters.set_local_search_metaheuristic( LocalSearchMetaheuristic::GUIDED_LOCAL_SEARCH); searchParameters.mutable_time_limit()->set_seconds(30); search_parameters.set_log_search(true);
자바
프로그램 시작 부분에 다음 `import` 문을 추가합니다.import com.google.protobuf.Duration;그런 다음 검색 매개변수를 다음과 같이 설정합니다.
RoutingSearchParameters searchParameters = main.defaultRoutingSearchParameters() .toBuilder() .setFirstSolutionStrategy(FirstSolutionStrategy.Value.PATH_CHEAPEST_ARC) .setLocalSearchMetaheuristic(LocalSearchMetaheuristic.Value.GUIDED_LOCAL_SEARCH) .setTimeLimit(Duration.newBuilder().setSeconds(30).build()) .setLogSearch(true) .build();
C#
프로그램 시작 부분에 다음 줄을 추가합니다.using Google.Protobuf.WellKnownTypes; // Duration그런 다음 검색 매개변수를 다음과 같이 설정합니다.
RoutingSearchParameters searchParameters = operations_research_constraint_solver.DefaultRoutingSearchParameters(); searchParameters.FirstSolutionStrategy = FirstSolutionStrategy.Types.Value.PathCheapestArc; searchParameters.LocalSearchMetaheuristic = LocalSearchMetaheuristic.Types.Value.GuidedLocalSearch; searchParameters.TimeLimit = new Duration { Seconds = 30 }; searchParameters.LogSearch = true;
다른 지역 검색 전략은 지역 검색 옵션을 참고하세요.
위의 예시는 검색 로깅을 사용 설정합니다. 로깅은 필수는 아니지만 디버깅에 유용할 수 있습니다.
위에 표시된 내용을 변경한 후 프로그램을 실행하면 다음과 같은 솔루션이 제공되며, 이는 이전 섹션에 표시된 솔루션보다 짧습니다.
Objective: 2672 Route: 0 -> 3 -> 276 -> 4 -> 5 -> 6 -> 8 -> 7 -> 9 -> 10 -> 11 -> 14 -> 12 -> 13 -> 23 -> 22 -> 24 -> 21 -> 25 -> 26 -> 27 -> 28 -> 125 -> 126 -> 127 -> 20 -> 19 -> 130 -> 129 -> 128 -> 153 -> 154 -> 152 -> 155 -> 151 -> 150 -> 177 -> 176 -> 175 -> 180 -> 161 -> 160 -> 174 -> 159 -> 158 -> 157 -> 156 -> 118 -> 119 -> 120 -> 121 -> 122 -> 123 -> 124 -> 29 -> 30 -> 31 -> 32 -> 33 -> 34 -> 35 -> 36 -> 37 -> 38 -> 39 -> 40 -> 41 -> 42 -> 59 -> 60 -> 58 -> 43 -> 44 -> 45 -> 46 -> 47 -> 48 -> 49 -> 50 -> 51 -> 52 -> 53 -> 54 -> 55 -> 56 -> 57 -> 67 -> 68 -> 66 -> 69 -> 70 -> 71 -> 72 -> 73 -> 75 -> 74 -> 76 -> 77 -> 78 -> 80 -> 81 -> 88 -> 79 -> 92 -> 93 -> 94 -> 95 -> 96 -> 97 -> 98 -> 99 -> 100 -> 101 -> 102 -> 91 -> 90 -> 89 -> 108 -> 111 -> 87 -> 82 -> 83 -> 86 -> 112 -> 115 -> 85 -> 84 -> 64 -> 65 -> 63 -> 62 -> 61 -> 117 -> 116 -> 114 -> 113 -> 110 -> 109 -> 107 -> 103 -> 104 -> 105 -> 106 -> 173 -> 172 -> 171 -> 170 -> 169 -> 168 -> 167 -> 166 -> 165 -> 164 -> 163 -> 162 -> 187 -> 188 -> 189 -> 190 -> 191 -> 192 -> 185 -> 186 -> 184 -> 183 -> 182 -> 181 -> 179 -> 178 -> 149 -> 148 -> 138 -> 137 -> 136 -> 266 -> 267 -> 135 -> 134 -> 268 -> 269 -> 133 -> 132 -> 131 -> 18 -> 17 -> 16 -> 15 -> 270 -> 271 -> 272 -> 273 -> 274 -> 275 -> 259 -> 258 -> 260 -> 261 -> 262 -> 263 -> 264 -> 265 -> 139 -> 140 -> 147 -> 146 -> 141 -> 142 -> 145 -> 144 -> 198 -> 197 -> 196 -> 193 -> 194 -> 195 -> 200 -> 201 -> 199 -> 143 -> 202 -> 203 -> 204 -> 205 -> 206 -> 207 -> 252 -> 253 -> 256 -> 257 -> 255 -> 254 -> 251 -> 208 -> 209 -> 210 -> 211 -> 212 -> 213 -> 214 -> 215 -> 216 -> 217 -> 218 -> 219 -> 220 -> 221 -> 222 -> 223 -> 224 -> 225 -> 226 -> 227 -> 232 -> 233 -> 234 -> 235 -> 236 -> 237 -> 230 -> 231 -> 228 -> 229 -> 250 -> 245 -> 238 -> 239 -> 240 -> 241 -> 242 -> 243 -> 244 -> 246 -> 249 -> 248 -> 247 -> 277 -> 278 -> 2 -> 279 -> 1 -> 0
추가 검색 옵션은 라우팅 옵션을 참조하세요.
이제 최적의 알고리즘으로 수만 개의 노드가 있는 TSP 인스턴스를 주기적으로 해결할 수 있습니다. (이 문서를 작성하는 시점의 레코드는 노드가 85,900개인 VLSI 애플리케이션인 TSPLIB의 plat85900 인스턴스입니다. 수백만 개의 노드가 있는 특정 인스턴스의 경우 솔루션이 최적의 둘러보기의 1% 이내에 있는 것이 보장됩니다.)
거리 행렬 조정
라우팅 솔버는 정수를 대상으로 하므로 거리 행렬에 정수가 아닌 항목이 있으면 거리를 정수로 반올림해야 합니다. 거리가 짧으면 반올림이 솔루션에 영향을 미칠 수 있습니다.
반올림에 문제가 발생하지 않도록 거리 행렬의 scale
를 수행하면 됩니다. 행렬의 모든 항목에 큰 숫자(예: 100)를 곱할 수 있습니다. 이렇게 하면 경로의 길이가 100배가 되지만 솔루션은 변경되지 않습니다. 이제 행렬 항목을 반올림할 때 반올림 금액(최대 0.5)이 거리에 비해 매우 작으므로 솔루션에 큰 영향을 미치지 않습니다.
거리 행렬을 조정하는 경우 솔루션 프린터를 변경하여 조정된 경로 길이를 배율로 나누면 경로의 조정되지 않은 거리가 표시됩니다.