Bu bölümde, aşağıdaki haritada gösterilen yerler için Seyahat eden Satış Görevlisi Sorununun (TSP) nasıl çözüleceğini gösteren bir örnek sunulmaktadır.
Aşağıdaki bölümlerde Python, C++, Java ve C# ile OR-Araçlar'ı kullanarak TSP'yi çözen programlar sunulmaktadır
Verileri oluşturma
Aşağıdaki kod, sorunla ilgili verileri oluşturur.
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}; };
Java
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; };
Uzaklık matrisi, i
, j
girişinin i
konumu ile j
konumu arasındaki mesafeyi mil cinsinden belirtir. Dizi dizinleri, konumlara aşağıdaki sırayla karşılık gelir:
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
Bu veriler şunları da içerir:
- TSP olduğu için sorundaki araç sayısı 1'dir. (Araç yönlendirme sorunu (VRP) söz konusu olduğunda, araç sayısı 1'den fazla olabilir.)
- Depot: Rotanın başlangıç ve bitiş konumu. Bu durumda, 0 değeri New York'a karşılık gelen 0'dır.
Mesafe matrisini oluşturmanın diğer yolları
Bu örnekte, mesafe matrisi programda açıkça tanımlanmıştır. Konumlar arasındaki mesafeleri hesaplamak için bir işlev de kullanılabilir: Örneğin, uçaktaki noktalar arasındaki mesafeye ilişkin Öklid formülü. Ancak konumlar arasındaki tüm mesafeleri önceden hesaplamak ve çalışma zamanında hesaplamak yerine bu değerleri bir matriste depolamak daha verimlidir. Mesafe matrisini bu şekilde oluşturan bir örnek için Örnek: devre kartı delik bölümüne bakın.
Diğer bir alternatif, yönlendirme sorunu için dinamik olarak mesafe (veya seyahat süresi) matrisi oluşturmak üzere Google Haritalar Mesafe Matrisi API'sini kullanmaktır.
Yönlendirme modelini oluşturma
Programların ana bölümünde yer alan aşağıdaki kod, dizin yöneticisi'ni (manager
) ve yönlendirme modelini (routing
) oluşturur. manager.IndexToNode
yöntemi, çözme aracındaki dahili dizinleri (güvenli bir şekilde yoksayabilirsiniz) konumlara ilişkin sayılara dönüştürür. Konum sayıları, mesafe matrisine ilişkin dizinlere karşılık gelir.
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);
Java
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
için giriş sayısı:
- Mesafe matrisinin satır sayısı. Bu, konumların sayısıdır (depo dahil).
- Sorunlu taşıtların sayısı.
- Depoya karşılık gelen düğüm.
Mesafe geri çağırması oluşturma
Yönlendirme çözümleyiciyi kullanmak için bir mesafe (veya toplu taşıma) geri çağırması oluşturmanız gerekir: Herhangi bir konum çiftini alan ve bunlar arasındaki mesafeyi döndüren bir işlev. Bunu yapmanın en kolay yolu mesafe matrisini kullanmaktır.
Aşağıdaki işlev geri çağırmayı oluşturur ve çözümleyiciye transit_callback_index
olarak kaydeder.
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);
Java
routing.setArcCostEvaluatorOfAllVehicles(transitCallbackIndex);
C#
routing.SetArcCostEvaluatorOfAllVehicles(transitCallbackIndex);
Bu örnekte, yay maliyeti değerlendirme aracı, çözümleyicinin uzak geri çağırma ile ilgili dahili referansı olan transit_callback_index
'dir. Bu, iki konum arasındaki seyahat maliyetinin yalnızca aralarında mesafeye eşit olduğu anlamına gelir.
Ancak maliyetler genel anlamda başka etkenler de içerebilir.
routing.SetArcCostEvaluatorOfVehicle()
yöntemini kullanarak, hangi aracın konumlar arasında seyahat ettiğine bağlı olan birden fazla arket maliyeti değerlendirme aracı da tanımlayabilirsiniz.
Örneğin, araçların hızları farklıysa konumlar arasındaki seyahat maliyetinin mesafeye olan mesafesine, diğer bir deyişle seyahat süresine bölünmesiyle elde edilebilir.
Arama parametrelerini ayarla
Aşağıdaki kod, varsayılan arama parametrelerini ve ilk çözümü bulmak için buluşsal bir yöntem belirler:
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);
Java
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;
Kod, ilk çözüm stratejisini PATH_CHEAPEST_ARC
olarak ayarlar. Bu strateji, daha önce ziyaret edilen düğüme (depodan farklı) yönlendirmeyen, en az ağırlığa sahip kenarları sürekli olarak ekleyerek çözümleyici için ilk rota oluşturur. Diğer seçenekler için İlk çözüm stratejisi bölümüne göz atın.
Çözüm yazıcısını ekleyin
Çözme aracı tarafından döndürülen çözümü gösteren işlev aşağıda gösterilmiştir. İşlev, rotayı çözümden çıkarır ve konsola yazdırır.
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"; }
Java
/// @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); }
İşlev, en uygun rotayı ve ObjectiveValue()
ile verilen mesafeyi görüntüler.
Çözümü çözün ve yazdırın
Son olarak, çözümleyiciyi arayabilir ve çözümü yazdırabilirsiniz:
Python
solution = routing.SolveWithParameters(search_parameters) if solution: print_solution(manager, routing, solution)
C++
const Assignment* solution = routing.SolveWithParameters(searchParameters); PrintSolution(manager, routing, *solution);
Java
Assignment solution = routing.solveWithParameters(searchParameters); printSolution(routing, manager, solution);
C#
Assignment solution = routing.SolveWithParameters(searchParameters); PrintSolution(routing, manager, solution);
Bu işlem çözümü döndürür ve en uygun rotayı gösterir.
Programları çalıştırma
Çalıştırdığınız programlar aşağıdaki çıkışı gösterir.
Objective: 7293 miles Route for vehicle 0: 0 -> 7 -> 2 -> 3 -> 4 -> 12 -> 6 -> 8 -> 1 -> 11 -> 10 -> 5 -> 9 -> 0
Bu örnekte, TSP olması nedeniyle yalnızca bir rota mevcuttur. Ancak daha genel araç yönlendirme sorunlarında bu çözüm birden fazla rota içerir.
Rotaları bir listeye veya diziye kaydetme
Çözümü doğrudan yazdırmaya alternatif olarak, yolu (veya VRP için rotaları) bir listeye veya diziye kaydedebilirsiniz. Bu seçenek, daha sonra yapmak istediğiniz bir rota olması durumunda rotaları kullanılabilir hale getirme avantajına sahiptir. Örneğin, programı farklı parametrelerle birkaç kez çalıştırabilir ve döndürülen çözümlerdeki rotaları karşılaştırma amacıyla bir dosyaya kaydedebilirsiniz.
Aşağıdaki işlevler, çözümdeki rotaları herhangi bir VRP'ye (muhtemelen birden fazla araçla) liste (Python) veya dizi (C++) olarak kaydeder.
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; }
Yönlendirme bölümündeki VRP örneklerinde rotalara ulaşmak için bu işlevleri kullanabilirsiniz.
Aşağıdaki kod, rotaları gösterir.
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]; } }
Mevcut örnek için bu kod aşağıdaki rotayı döndürür:
Route 0 [0, 7, 2, 3, 4, 12, 6, 8, 1, 11, 10, 5, 9, 0]
Alıştırma olarak, çıktıyı programın çözüm yazıcısıyla aynı şekilde biçimlendirmek için yukarıdaki kodu değiştirin.
Tamamlanan programlar
TSP programlarının tamamı aşağıda gösterilmektedir.
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; }
Java
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); } }
Örnek: devre kartı delme
Bir sonraki örnekte, otomatik delik bulunan bir devre kartındaki delikler yer alır. Sorun, gerekli tüm delikleri açmak için matkabın gidebileceği en kısa rotayı bulmaktır. Örnek, TSP sorunları kitaplığı olan TSPLIB'den alınmıştır.
Aşağıda, deliklerin bulunduğu konumların dağılım grafiğini görebilirsiniz:
Aşağıdaki bölümlerde, problem çözücünün varsayılan arama parametrelerini kullanarak devre kartı sorunu için iyi bir çözüm bulan programlar gösterilmektedir. Ardından, arama stratejisini değiştirerek daha iyi bir çözümü nasıl bulacağınızı göstereceğiz.
Verileri oluşturma
Sorunun verileri, yukarıdaki dağılım grafiğinde gösterilen uçaktaki 280 noktadan oluşur. Program, aşağıda gösterildiği gibi verileri, düzlemdeki noktalara karşılık gelen sıralı çiftlerden oluşan bir dizi halinde oluşturur.
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}; };
Java
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; };
Mesafe matrisini hesaplama
Aşağıdaki işlev, verilerdeki iki nokta arasındaki Öklid mesafesini hesaplar ve bir dizide depolar. Yönlendirme çözümleyici tam sayılar üzerinde çalıştığından, işlev, hesaplanan mesafeleri tam sayılara yuvarlar. Yuvarlama bu örnekteki çözümü etkilemez ancak diğer durumlarda geçerli olabilir. Olası yuvarlama sorunlarından kaçınmak için Mesafe matrisini ölçeklendirme konusuna bakın.
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; }
Java
/// @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; }
Mesafe geri çağırmasını ekle
Mesafe geri çağırmayı oluşturan kod, önceki örnektekiyle neredeyse aynıdır. Ancak bu durumda program, geri çağırmayı eklemeden önce mesafe matrisini hesaplayan işlevi çağırır.
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);
Java
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);
Çözüm yazıcısı
Aşağıdaki işlev, çözümü konsola yazdırır. Çıkışı daha kompakt tutmak için işlev yalnızca rotadaki konumların dizinlerini gösterir.
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"; }
Java
/// @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); }
Ana işlev
Ana işlev, temelde önceki örnekteki işlevle aynıdır ancak mesafe matrisini oluşturan işleve çağrı da içerir.
Programı çalıştırma
Tüm programlar sonraki bölümde gösterilmektedir. Programı çalıştırdığınızda aşağıdaki rota gösterilir:
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
İlgili rotayı burada görebilirsiniz:
OR-Araçlar kitaplığı, yukarıdaki turu çok hızlı bir şekilde bulur: Tipik bir bilgisayarda bir saniyeden kısa bir sürede gerçekleşir. Yukarıdaki turun toplam uzunluğu 2790'dır.
Tamamlanan programlar
Devre kartı örneğinin tüm programları aşağıda verilmiştir.
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; }
Java
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); } }
Arama stratejisini değiştirme
Yönlendirme problemi sayısal olarak zorlayıcı olduğundan yönlendirme çözümleyicisi her zaman en iyi çözümü bir TSP'ye döndürmez. Örneğin, önceki örnekte döndürülen çözüm optimum rota değildir.
Daha iyi bir çözüm bulmak için, rehberli yerel arama adı verilen daha gelişmiş bir arama stratejisi kullanabilirsiniz. Bu strateji, çözümleyicinin yerel minimum değerden kaçmasını sağlar. Yakındaki rotalardan daha kısa olan ve küresel minimum sınır olmayan çözüm. Çözümleyici, yerel minimumdan uzaklaştıktan sonra aramaya devam eder.
Aşağıdaki örnekler, devre kartı örneği için nasıl rehberli yerel arama yapılacağını göstermektedir.
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);
Java
Programın başına aşağıdaki "import" ifadesini ekleyin:import com.google.protobuf.Duration;Ardından arama parametrelerini şu şekilde ayarlayın:
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#
Programın başına şu satırı ekleyin:using Google.Protobuf.WellKnownTypes; // DurationArdından arama parametrelerini şu şekilde ayarlayın:
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;
Diğer yerel arama stratejileri için Yerel arama seçenekleri bölümüne göz atın.
Yukarıdaki örnekler arama için günlük kaydını da etkinleştirir. Günlük kaydı gerekmese de hata ayıklama açısından faydalı olabilir.
Yukarıda gösterilen değişiklikleri yaptıktan sonra programı çalıştırdığınızda aşağıdaki çözüme ulaşırsınız. Bu çözüm, bir önceki bölümde gösterilen çözümden daha kısadır.
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
Diğer arama seçenekleri için Yönlendirme Seçenekleri konusuna bakın.
En iyi algoritmalar artık on binlerce düğüm içeren TSP örneklerini düzenli olarak çözebiliyor. (Yazma sırasındaki kayıt, 85.900 düğümlü bir VLSI uygulaması olan TSPLIB'daki pla85900 örneğidir. Milyonlarca düğüme sahip bazı durumlarda, çözümlerin optimum tura% 1 oranında dahil olduğu garanti edilmiştir.)
Mesafe matrisini ölçeklendirme
Yönlendirme çözümleyici tam sayılar üzerinde çalıştığından, mesafe matrisinizde tam sayı olmayan girişler varsa mesafeleri tam sayılara yuvarlamanız gerekir. Bazı mesafeler küçükse yuvarlama çözümü etkileyebilir.
Yuvarlamayla ilgili herhangi bir sorun yaşamamak için mesafe matrisini scale
: Matrisin tüm girişlerini büyük bir sayıyla (ör. 100) çarpın. Bu işlem, herhangi bir rotanın uzunluğunu 100 faktör ile çarpar ancak çözümü değiştirmez. Ancak matris girişlerini yuvarladığınızda yuvarlama tutarı (en fazla 0,5) mesafelere kıyasla çok küçük olur.Bu da çözümü önemli ölçüde etkilemez.
Mesafe matrisini ölçeklendirirseniz çözüm yazıcısını, ölçeklendirilmiş rota uzunluklarını ölçeklendirme faktörüne bölerek ölçeklendirmek için rotaların ölçeklendirilmemiş mesafelerini gösterecek şekilde değiştirmeniz gerekir.