В этом разделе мы объясним, как справляться с проблемами маршрутизации, которые не имеют подходящего решения из-за ограничений. Например, если у вас есть VRP с ограничениями по вместимости, в котором общий спрос во всех местах превышает общую вместимость транспортных средств, никакое решение невозможно. В таких случаях автомобили должны отказаться от посещения некоторых мест. Проблема заключается в том, как решить, какие посещения следует исключить.
Чтобы решить эту проблему, мы вводим новые затраты, называемые штрафами , во всех местах. Всякий раз, когда посещение локации пропускается, штраф добавляется к общему пройденному расстоянию. Затем решатель находит маршрут, минимизирующий общее расстояние плюс сумму штрафов за все пропущенные местоположения.
В качестве примера рассмотрим простой VRP с ограничениями пропускной способности, представленными на графике ниже, в котором числа рядом с тремя местоположениями (кроме депо) являются потребностями.
Предположим, есть только одно транспортное средство вместимостью 50 человек. Оно не может посетить все три места, A, B и C, потому что общий спрос равен 60. Чтобы решить проблему, вы назначаете большой штраф, скажем, 100, для каждого места. . Обнаружив, что проблема неразрешима, решатель отбрасывает местоположение B и возвращает следующий маршрут: Depot -> A -> C -> Depot
Это кратчайший маршрут, который проходит через две из трех локаций (расстояние 55).
Штрафные размеры
В приведенном выше примере мы выбрали штрафы, превышающие сумму всех расстояний между локациями (исключая депо). В результате, после удаления одного местоположения, чтобы сделать задачу возможной, решатель не отбрасывает никаких дополнительных местоположений, потому что штраф за это превысит любое дальнейшее сокращение расстояния перемещения.
Предполагая, что вы хотите сделать как можно больше доставок, это дает удовлетворительное решение проблемы.
Если вам не нужно делать как можно больше доставок, вы можете назначить меньшие штрафы, и в этом случае решатель может отбросить больше местоположений, чем необходимо для решения проблемы. Например, вы можете сделать это, если есть дополнительные расходы, помимо основных расходов на поездку, для посещения определенных мест.
Пример
Далее мы представляем более крупный пример задачи VRP, которую можно решить с помощью штрафов. Пример аналогичен предыдущему примеру CVRP , но на этот раз мы увеличили некоторые требования, заставив некоторые транспортные средства отказаться от посещений.
График локаций и новых требований показан ниже.
Решение примера с помощью OR-Tools
В следующих разделах объясняется, как решить пример с помощью OR-Tools.
Создайте данные
Данные для этого примера включают данные из предыдущего примера VRP и добавляют следующие требования и мощности:
Питон
data["demands"] = [0, 1, 1, 3, 6, 3, 6, 8, 8, 1, 2, 1, 2, 6, 6, 8, 8]
data["vehicle_capacities"] = [15, 15, 15, 15]С++
const std::vector<int64_t> demands{
0, 1, 1, 3, 6, 3, 6, 8, 8, 1, 2, 1, 2, 6, 6, 8, 8,
};
const std::vector<int64_t> vehicle_capacities{15, 15, 15, 15};Джава
public final long[] demands = {0, 1, 1, 3, 6, 3, 6, 8, 8, 1, 2, 1, 2, 6, 6, 8, 8};
public final long[] vehicleCapacities = {15, 15, 15, 15};С#
public long[] Demands = { 0, 1, 1, 3, 6, 3, 6, 8, 8, 1, 2, 1, 2, 6, 6, 8, 8 };
public long[] VehicleCapacities = { 15, 15, 15, 15 };Добавьте ограничения пропускной способности и штрафы
Следующий код добавляет обратный вызов спроса и ограничения емкости, а также добавляет штрафы с помощью метода AddDisjunction .
Питон
def demand_callback(from_index):
"""Returns the demand of the node."""
# Convert from routing variable Index to demands NodeIndex.
from_node = manager.IndexToNode(from_index)
return data["demands"][from_node]
demand_callback_index = routing.RegisterUnaryTransitCallback(demand_callback)
routing.AddDimensionWithVehicleCapacity(
demand_callback_index,
0, # null capacity slack
data["vehicle_capacities"], # vehicle maximum capacities
True, # start cumul to zero
"Capacity",
)
# Allow to drop nodes.
penalty = 1000
for node in range(1, len(data["distance_matrix"])):
routing.AddDisjunction([manager.NodeToIndex(node)], penalty)С++
const int demand_callback_index = routing.RegisterUnaryTransitCallback(
[&data, &manager](const int64_t from_index) -> int64_t {
// Convert from routing variable Index to demand NodeIndex.
const int from_node = manager.IndexToNode(from_index).value();
return data.demands[from_node];
});
routing.AddDimensionWithVehicleCapacity(
demand_callback_index, // transit callback index
int64_t{0}, // null capacity slack
data.vehicle_capacities, // vehicle maximum capacities
true, // start cumul to zero
"Capacity");
// Allow to drop nodes.
int64_t penalty{1000};
for (int i = 1; i < data.distance_matrix.size(); ++i) {
routing.AddDisjunction(
{manager.NodeToIndex(RoutingIndexManager::NodeIndex(i))}, penalty);
}Джава
final int demandCallbackIndex = routing.registerUnaryTransitCallback((long fromIndex) -> {
// Convert from routing variable Index to user NodeIndex.
int fromNode = manager.indexToNode(fromIndex);
return data.demands[fromNode];
});
routing.addDimensionWithVehicleCapacity(demandCallbackIndex, 0, // null capacity slack
data.vehicleCapacities, // vehicle maximum capacities
true, // start cumul to zero
"Capacity");
// Allow to drop nodes.
long penalty = 1000;
for (int i = 1; i < data.distanceMatrix.length; ++i) {
routing.addDisjunction(new long[] {manager.nodeToIndex(i)}, penalty);
}С#
int demandCallbackIndex = routing.RegisterUnaryTransitCallback((long fromIndex) =>
{
// Convert from routing variable Index to
// demand NodeIndex.
var fromNode =
manager.IndexToNode(fromIndex);
return data.Demands[fromNode];
});
routing.AddDimensionWithVehicleCapacity(demandCallbackIndex, 0, // null capacity slack
data.VehicleCapacities, // vehicle maximum capacities
true, // start cumul to zero
"Capacity");
// Allow to drop nodes.
long penalty = 1000;
for (int i = 1; i < data.DistanceMatrix.GetLength(0); ++i)
{
routing.AddDisjunction(new long[] { manager.NodeToIndex(i) }, penalty);
}В этом контексте дизъюнкция — это просто переменная, которую решатель использует, чтобы решить, включать ли данное местоположение в решение. В этом примере метод добавляет один и тот же штраф к каждому местоположению, но в целом вы можете добавлять разные штрафы к разным местоположениям.
Добавьте принтер решения
Принтер решения, показанный ниже, аналогичен принтеру в примере CVRP , но также отображает перетащенные местоположения.
питон
def print_solution(data, manager, routing, assignment):
"""Prints assignment on console."""
print(f"Objective: {assignment.ObjectiveValue()}")
# Display dropped nodes.
dropped_nodes = "Dropped nodes:"
for node in range(routing.Size()):
if routing.IsStart(node) or routing.IsEnd(node):
continue
if assignment.Value(routing.NextVar(node)) == node:
dropped_nodes += f" {manager.IndexToNode(node)}"
print(dropped_nodes)
# Display routes
total_distance = 0
total_load = 0
for vehicle_id in range(data["num_vehicles"]):
index = routing.Start(vehicle_id)
plan_output = f"Route for vehicle {vehicle_id}:\n"
route_distance = 0
route_load = 0
while not routing.IsEnd(index):
node_index = manager.IndexToNode(index)
route_load += data["demands"][node_index]
plan_output += f" {node_index} Load({route_load}) -> "
previous_index = index
index = assignment.Value(routing.NextVar(index))
route_distance += routing.GetArcCostForVehicle(
previous_index, index, vehicle_id
)
plan_output += f" {manager.IndexToNode(index)} Load({route_load})\n"
plan_output += f"Distance of the route: {route_distance}m\n"
plan_output += f"Load of the route: {route_load}\n"
print(plan_output)
total_distance += route_distance
total_load += route_load
print(f"Total Distance of all routes: {total_distance}m")
print(f"Total Load of all routes: {total_load}")С++
//! @brief Print the solution.
//! @param[in] data Data of the problem.
//! @param[in] manager Index manager used.
//! @param[in] routing Routing solver used.
//! @param[in] solution Solution found by the solver.
void PrintSolution(const DataModel& data, const RoutingIndexManager& manager,
const RoutingModel& routing, const Assignment& solution) {
// Display dropped nodes.
std::ostringstream dropped_nodes;
for (int64_t node = 0; node < routing.Size(); ++node) {
if (routing.IsStart(node) || routing.IsEnd(node)) continue;
if (solution.Value(routing.NextVar(node)) == node) {
dropped_nodes << " " << manager.IndexToNode(node).value();
}
}
LOG(INFO) << "Dropped nodes:" << dropped_nodes.str();
// Display routes
int64_t total_distance{0};
int64_t total_load{0};
for (int vehicle_id = 0; vehicle_id < data.num_vehicles; ++vehicle_id) {
int64_t index = routing.Start(vehicle_id);
LOG(INFO) << "Route for Vehicle " << vehicle_id << ":";
int64_t route_distance{0};
int64_t route_load{0};
std::ostringstream route;
while (!routing.IsEnd(index)) {
const int node_index = manager.IndexToNode(index).value();
route_load += data.demands[node_index];
route << node_index << " Load(" << route_load << ") -> ";
const int64_t previous_index = index;
index = solution.Value(routing.NextVar(index));
route_distance += routing.GetArcCostForVehicle(previous_index, index,
int64_t{vehicle_id});
}
LOG(INFO) << route.str() << manager.IndexToNode(index).value();
LOG(INFO) << "Distance of the route: " << route_distance << "m";
LOG(INFO) << "Load of the route: " << route_load;
total_distance += route_distance;
total_load += route_load;
}
LOG(INFO) << "Total distance of all routes: " << total_distance << "m";
LOG(INFO) << "Total load of all routes: " << total_load;
LOG(INFO) << "";
LOG(INFO) << "Advanced usage:";
LOG(INFO) << "Problem solved in " << routing.solver()->wall_time() << "ms";
}Джава
/// @brief Print the solution.
static void printSolution(
DataModel data, RoutingModel routing, RoutingIndexManager manager, Assignment solution) {
// Solution cost.
logger.info("Objective: " + solution.objectiveValue());
// Inspect solution.
// Display dropped nodes.
String droppedNodes = "Dropped nodes:";
for (int node = 0; node < routing.size(); ++node) {
if (routing.isStart(node) || routing.isEnd(node)) {
continue;
}
if (solution.value(routing.nextVar(node)) == node) {
droppedNodes += " " + manager.indexToNode(node);
}
}
logger.info(droppedNodes);
// Display routes
long totalDistance = 0;
long totalLoad = 0;
for (int i = 0; i < data.vehicleNumber; ++i) {
long index = routing.start(i);
logger.info("Route for Vehicle " + i + ":");
long routeDistance = 0;
long routeLoad = 0;
String route = "";
while (!routing.isEnd(index)) {
long nodeIndex = manager.indexToNode(index);
routeLoad += data.demands[(int) nodeIndex];
route += nodeIndex + " Load(" + routeLoad + ") -> ";
long previousIndex = index;
index = solution.value(routing.nextVar(index));
routeDistance += routing.getArcCostForVehicle(previousIndex, index, i);
}
route += manager.indexToNode(routing.end(i));
logger.info(route);
logger.info("Distance of the route: " + routeDistance + "m");
totalDistance += routeDistance;
totalLoad += routeLoad;
}
logger.info("Total Distance of all routes: " + totalDistance + "m");
logger.info("Total Load of all routes: " + totalLoad);
}С#
/// <summary>
/// Print the solution.
/// </summary>
static void PrintSolution(in DataModel data, in RoutingModel routing, in RoutingIndexManager manager,
in Assignment solution)
{
Console.WriteLine($"Objective {solution.ObjectiveValue()}:");
// Inspect solution.
// Display dropped nodes.
string droppedNodes = "Dropped nodes:";
for (int index = 0; index < routing.Size(); ++index)
{
if (routing.IsStart(index) || routing.IsEnd(index))
{
continue;
}
if (solution.Value(routing.NextVar(index)) == index)
{
droppedNodes += " " + manager.IndexToNode(index);
}
}
Console.WriteLine("{0}", droppedNodes);
// Inspect solution.
long totalDistance = 0;
long totalLoad = 0;
for (int i = 0; i < data.VehicleNumber; ++i)
{
Console.WriteLine("Route for Vehicle {0}:", i);
long routeDistance = 0;
long routeLoad = 0;
var index = routing.Start(i);
while (routing.IsEnd(index) == false)
{
long nodeIndex = manager.IndexToNode(index);
routeLoad += data.Demands[nodeIndex];
Console.Write("{0} Load({1}) -> ", nodeIndex, routeLoad);
var previousIndex = index;
index = solution.Value(routing.NextVar(index));
routeDistance += routing.GetArcCostForVehicle(previousIndex, index, 0);
}
Console.WriteLine("{0}", manager.IndexToNode((int)index));
Console.WriteLine("Distance of the route: {0}m", routeDistance);
totalDistance += routeDistance;
totalLoad += routeLoad;
}
Console.WriteLine("Total Distance of all routes: {0}m", totalDistance);
Console.WriteLine("Total Load of all routes: {0}m", totalLoad);
}Запуск программы
Когда вы запускаете программу, она возвращает следующий вывод, показанный ниже. Обратите внимание, что решатель отбрасывает точки 6 и 15.
Objective: 7936 Dropped nodes: 6 15 Route for vehicle 0: 0 Load(0) -> 9 Load(1) -> 14 Load(7) -> 16 Load(15) -> 0 Load(15) Distance of the route: 1324m Load of the route: 15 Route for vehicle 1: 0 Load(0) -> 12 Load(2) -> 11 Load(3) -> 4 Load(9) -> 3 Load(12) -> 1 Load(13) -> 0 Load(13) Distance of the route: 1872m Load of the route: 13 Route for vehicle 2: 0 Load(0) -> 7 Load(8) -> 13 Load(14) -> 0 Load(14) Distance of the route: 868m Load of the route: 14 Route for vehicle 3: 0 Load(0) -> 8 Load(8) -> 10 Load(10) -> 2 Load(11) -> 5 Load(14) -> 0 Load(14) Distance of the route: 1872m Load of the route: 14 Total Distance of all routes: 5936m Total Load of all routes: 56
Вот схемы маршрутов.
Полные программы
Вот полные программы.
питон
"""Capacited Vehicles Routing Problem (CVRP)."""
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"] = [
# fmt: off
[0, 548, 776, 696, 582, 274, 502, 194, 308, 194, 536, 502, 388, 354, 468, 776, 662],
[548, 0, 684, 308, 194, 502, 730, 354, 696, 742, 1084, 594, 480, 674, 1016, 868, 1210],
[776, 684, 0, 992, 878, 502, 274, 810, 468, 742, 400, 1278, 1164, 1130, 788, 1552, 754],
[696, 308, 992, 0, 114, 650, 878, 502, 844, 890, 1232, 514, 628, 822, 1164, 560, 1358],
[582, 194, 878, 114, 0, 536, 764, 388, 730, 776, 1118, 400, 514, 708, 1050, 674, 1244],
[274, 502, 502, 650, 536, 0, 228, 308, 194, 240, 582, 776, 662, 628, 514, 1050, 708],
[502, 730, 274, 878, 764, 228, 0, 536, 194, 468, 354, 1004, 890, 856, 514, 1278, 480],
[194, 354, 810, 502, 388, 308, 536, 0, 342, 388, 730, 468, 354, 320, 662, 742, 856],
[308, 696, 468, 844, 730, 194, 194, 342, 0, 274, 388, 810, 696, 662, 320, 1084, 514],
[194, 742, 742, 890, 776, 240, 468, 388, 274, 0, 342, 536, 422, 388, 274, 810, 468],
[536, 1084, 400, 1232, 1118, 582, 354, 730, 388, 342, 0, 878, 764, 730, 388, 1152, 354],
[502, 594, 1278, 514, 400, 776, 1004, 468, 810, 536, 878, 0, 114, 308, 650, 274, 844],
[388, 480, 1164, 628, 514, 662, 890, 354, 696, 422, 764, 114, 0, 194, 536, 388, 730],
[354, 674, 1130, 822, 708, 628, 856, 320, 662, 388, 730, 308, 194, 0, 342, 422, 536],
[468, 1016, 788, 1164, 1050, 514, 514, 662, 320, 274, 388, 650, 536, 342, 0, 764, 194],
[776, 868, 1552, 560, 674, 1050, 1278, 742, 1084, 810, 1152, 274, 388, 422, 764, 0, 798],
[662, 1210, 754, 1358, 1244, 708, 480, 856, 514, 468, 354, 844, 730, 536, 194, 798, 0],
# fmt: on
]
data["demands"] = [0, 1, 1, 3, 6, 3, 6, 8, 8, 1, 2, 1, 2, 6, 6, 8, 8]
data["vehicle_capacities"] = [15, 15, 15, 15]
data["num_vehicles"] = 4
data["depot"] = 0
return data
def print_solution(data, manager, routing, assignment):
"""Prints assignment on console."""
print(f"Objective: {assignment.ObjectiveValue()}")
# Display dropped nodes.
dropped_nodes = "Dropped nodes:"
for node in range(routing.Size()):
if routing.IsStart(node) or routing.IsEnd(node):
continue
if assignment.Value(routing.NextVar(node)) == node:
dropped_nodes += f" {manager.IndexToNode(node)}"
print(dropped_nodes)
# Display routes
total_distance = 0
total_load = 0
for vehicle_id in range(data["num_vehicles"]):
index = routing.Start(vehicle_id)
plan_output = f"Route for vehicle {vehicle_id}:\n"
route_distance = 0
route_load = 0
while not routing.IsEnd(index):
node_index = manager.IndexToNode(index)
route_load += data["demands"][node_index]
plan_output += f" {node_index} Load({route_load}) -> "
previous_index = index
index = assignment.Value(routing.NextVar(index))
route_distance += routing.GetArcCostForVehicle(
previous_index, index, vehicle_id
)
plan_output += f" {manager.IndexToNode(index)} Load({route_load})\n"
plan_output += f"Distance of the route: {route_distance}m\n"
plan_output += f"Load of the route: {route_load}\n"
print(plan_output)
total_distance += route_distance
total_load += route_load
print(f"Total Distance of all routes: {total_distance}m")
print(f"Total Load of all routes: {total_load}")
def main():
"""Solve the CVRP problem."""
# 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)
# Create and register a transit callback.
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)
# Add Capacity constraint.
def demand_callback(from_index):
"""Returns the demand of the node."""
# Convert from routing variable Index to demands NodeIndex.
from_node = manager.IndexToNode(from_index)
return data["demands"][from_node]
demand_callback_index = routing.RegisterUnaryTransitCallback(demand_callback)
routing.AddDimensionWithVehicleCapacity(
demand_callback_index,
0, # null capacity slack
data["vehicle_capacities"], # vehicle maximum capacities
True, # start cumul to zero
"Capacity",
)
# Allow to drop nodes.
penalty = 1000
for node in range(1, len(data["distance_matrix"])):
routing.AddDisjunction([manager.NodeToIndex(node)], penalty)
# Setting first solution heuristic.
search_parameters = pywrapcp.DefaultRoutingSearchParameters()
search_parameters.first_solution_strategy = (
routing_enums_pb2.FirstSolutionStrategy.PATH_CHEAPEST_ARC
)
search_parameters.local_search_metaheuristic = (
routing_enums_pb2.LocalSearchMetaheuristic.GUIDED_LOCAL_SEARCH
)
search_parameters.time_limit.FromSeconds(1)
# Solve the problem.
assignment = routing.SolveWithParameters(search_parameters)
# Print solution on console.
if assignment:
print_solution(data, manager, routing, assignment)
if __name__ == "__main__":
main()С++
#include <cstdint>
#include <sstream>
#include <vector>
#include "google/protobuf/duration.pb.h"
#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, 548, 776, 696, 582, 274, 502, 194, 308, 194, 536, 502, 388, 354, 468,
776, 662},
{548, 0, 684, 308, 194, 502, 730, 354, 696, 742, 1084, 594, 480, 674,
1016, 868, 1210},
{776, 684, 0, 992, 878, 502, 274, 810, 468, 742, 400, 1278, 1164, 1130,
788, 1552, 754},
{696, 308, 992, 0, 114, 650, 878, 502, 844, 890, 1232, 514, 628, 822,
1164, 560, 1358},
{582, 194, 878, 114, 0, 536, 764, 388, 730, 776, 1118, 400, 514, 708,
1050, 674, 1244},
{274, 502, 502, 650, 536, 0, 228, 308, 194, 240, 582, 776, 662, 628, 514,
1050, 708},
{502, 730, 274, 878, 764, 228, 0, 536, 194, 468, 354, 1004, 890, 856, 514,
1278, 480},
{194, 354, 810, 502, 388, 308, 536, 0, 342, 388, 730, 468, 354, 320, 662,
742, 856},
{308, 696, 468, 844, 730, 194, 194, 342, 0, 274, 388, 810, 696, 662, 320,
1084, 514},
{194, 742, 742, 890, 776, 240, 468, 388, 274, 0, 342, 536, 422, 388, 274,
810, 468},
{536, 1084, 400, 1232, 1118, 582, 354, 730, 388, 342, 0, 878, 764, 730,
388, 1152, 354},
{502, 594, 1278, 514, 400, 776, 1004, 468, 810, 536, 878, 0, 114, 308,
650, 274, 844},
{388, 480, 1164, 628, 514, 662, 890, 354, 696, 422, 764, 114, 0, 194, 536,
388, 730},
{354, 674, 1130, 822, 708, 628, 856, 320, 662, 388, 730, 308, 194, 0, 342,
422, 536},
{468, 1016, 788, 1164, 1050, 514, 514, 662, 320, 274, 388, 650, 536, 342,
0, 764, 194},
{776, 868, 1552, 560, 674, 1050, 1278, 742, 1084, 810, 1152, 274, 388,
422, 764, 0, 798},
{662, 1210, 754, 1358, 1244, 708, 480, 856, 514, 468, 354, 844, 730, 536,
194, 798, 0},
};
const std::vector<int64_t> demands{
0, 1, 1, 3, 6, 3, 6, 8, 8, 1, 2, 1, 2, 6, 6, 8, 8,
};
const std::vector<int64_t> vehicle_capacities{15, 15, 15, 15};
const int num_vehicles = 4;
const RoutingIndexManager::NodeIndex depot{0};
};
//! @brief Print the solution.
//! @param[in] data Data of the problem.
//! @param[in] manager Index manager used.
//! @param[in] routing Routing solver used.
//! @param[in] solution Solution found by the solver.
void PrintSolution(const DataModel& data, const RoutingIndexManager& manager,
const RoutingModel& routing, const Assignment& solution) {
// Display dropped nodes.
std::ostringstream dropped_nodes;
for (int64_t node = 0; node < routing.Size(); ++node) {
if (routing.IsStart(node) || routing.IsEnd(node)) continue;
if (solution.Value(routing.NextVar(node)) == node) {
dropped_nodes << " " << manager.IndexToNode(node).value();
}
}
LOG(INFO) << "Dropped nodes:" << dropped_nodes.str();
// Display routes
int64_t total_distance{0};
int64_t total_load{0};
for (int vehicle_id = 0; vehicle_id < data.num_vehicles; ++vehicle_id) {
int64_t index = routing.Start(vehicle_id);
LOG(INFO) << "Route for Vehicle " << vehicle_id << ":";
int64_t route_distance{0};
int64_t route_load{0};
std::ostringstream route;
while (!routing.IsEnd(index)) {
const int node_index = manager.IndexToNode(index).value();
route_load += data.demands[node_index];
route << node_index << " Load(" << route_load << ") -> ";
const int64_t previous_index = index;
index = solution.Value(routing.NextVar(index));
route_distance += routing.GetArcCostForVehicle(previous_index, index,
int64_t{vehicle_id});
}
LOG(INFO) << route.str() << manager.IndexToNode(index).value();
LOG(INFO) << "Distance of the route: " << route_distance << "m";
LOG(INFO) << "Load of the route: " << route_load;
total_distance += route_distance;
total_load += route_load;
}
LOG(INFO) << "Total distance of all routes: " << total_distance << "m";
LOG(INFO) << "Total load of all routes: " << total_load;
LOG(INFO) << "";
LOG(INFO) << "Advanced usage:";
LOG(INFO) << "Problem solved in " << routing.solver()->wall_time() << "ms";
}
void VrpDropNodes() {
// 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);
// Create and register a transit callback.
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);
// Add Capacity constraint.
const int demand_callback_index = routing.RegisterUnaryTransitCallback(
[&data, &manager](const int64_t from_index) -> int64_t {
// Convert from routing variable Index to demand NodeIndex.
const int from_node = manager.IndexToNode(from_index).value();
return data.demands[from_node];
});
routing.AddDimensionWithVehicleCapacity(
demand_callback_index, // transit callback index
int64_t{0}, // null capacity slack
data.vehicle_capacities, // vehicle maximum capacities
true, // start cumul to zero
"Capacity");
// Allow to drop nodes.
int64_t penalty{1000};
for (int i = 1; i < data.distance_matrix.size(); ++i) {
routing.AddDisjunction(
{manager.NodeToIndex(RoutingIndexManager::NodeIndex(i))}, penalty);
}
// Setting first solution heuristic.
RoutingSearchParameters search_parameters = DefaultRoutingSearchParameters();
search_parameters.set_first_solution_strategy(
FirstSolutionStrategy::PATH_CHEAPEST_ARC);
search_parameters.set_local_search_metaheuristic(
LocalSearchMetaheuristic::GUIDED_LOCAL_SEARCH);
search_parameters.mutable_time_limit()->set_seconds(1);
// Solve the problem.
const Assignment* solution = routing.SolveWithParameters(search_parameters);
// Print solution on console.
PrintSolution(data, manager, routing, *solution);
}
} // namespace operations_research
int main(int /*argc*/, char* /*argv*/[]) {
operations_research::VrpDropNodes();
return EXIT_SUCCESS;
}Джава
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.LocalSearchMetaheuristic;
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 com.google.protobuf.Duration;
import java.util.logging.Logger;
/** Minimal VRP.*/
public class VrpDropNodes {
private static final Logger logger = Logger.getLogger(VrpDropNodes.class.getName());
static class DataModel {
public final long[][] distanceMatrix = {
{0, 548, 776, 696, 582, 274, 502, 194, 308, 194, 536, 502, 388, 354, 468, 776, 662},
{548, 0, 684, 308, 194, 502, 730, 354, 696, 742, 1084, 594, 480, 674, 1016, 868, 1210},
{776, 684, 0, 992, 878, 502, 274, 810, 468, 742, 400, 1278, 1164, 1130, 788, 1552, 754},
{696, 308, 992, 0, 114, 650, 878, 502, 844, 890, 1232, 514, 628, 822, 1164, 560, 1358},
{582, 194, 878, 114, 0, 536, 764, 388, 730, 776, 1118, 400, 514, 708, 1050, 674, 1244},
{274, 502, 502, 650, 536, 0, 228, 308, 194, 240, 582, 776, 662, 628, 514, 1050, 708},
{502, 730, 274, 878, 764, 228, 0, 536, 194, 468, 354, 1004, 890, 856, 514, 1278, 480},
{194, 354, 810, 502, 388, 308, 536, 0, 342, 388, 730, 468, 354, 320, 662, 742, 856},
{308, 696, 468, 844, 730, 194, 194, 342, 0, 274, 388, 810, 696, 662, 320, 1084, 514},
{194, 742, 742, 890, 776, 240, 468, 388, 274, 0, 342, 536, 422, 388, 274, 810, 468},
{536, 1084, 400, 1232, 1118, 582, 354, 730, 388, 342, 0, 878, 764, 730, 388, 1152, 354},
{502, 594, 1278, 514, 400, 776, 1004, 468, 810, 536, 878, 0, 114, 308, 650, 274, 844},
{388, 480, 1164, 628, 514, 662, 890, 354, 696, 422, 764, 114, 0, 194, 536, 388, 730},
{354, 674, 1130, 822, 708, 628, 856, 320, 662, 388, 730, 308, 194, 0, 342, 422, 536},
{468, 1016, 788, 1164, 1050, 514, 514, 662, 320, 274, 388, 650, 536, 342, 0, 764, 194},
{776, 868, 1552, 560, 674, 1050, 1278, 742, 1084, 810, 1152, 274, 388, 422, 764, 0, 798},
{662, 1210, 754, 1358, 1244, 708, 480, 856, 514, 468, 354, 844, 730, 536, 194, 798, 0},
};
public final long[] demands = {0, 1, 1, 3, 6, 3, 6, 8, 8, 1, 2, 1, 2, 6, 6, 8, 8};
public final long[] vehicleCapacities = {15, 15, 15, 15};
public final int vehicleNumber = 4;
public final int depot = 0;
}
/// @brief Print the solution.
static void printSolution(
DataModel data, RoutingModel routing, RoutingIndexManager manager, Assignment solution) {
// Solution cost.
logger.info("Objective: " + solution.objectiveValue());
// Inspect solution.
// Display dropped nodes.
String droppedNodes = "Dropped nodes:";
for (int node = 0; node < routing.size(); ++node) {
if (routing.isStart(node) || routing.isEnd(node)) {
continue;
}
if (solution.value(routing.nextVar(node)) == node) {
droppedNodes += " " + manager.indexToNode(node);
}
}
logger.info(droppedNodes);
// Display routes
long totalDistance = 0;
long totalLoad = 0;
for (int i = 0; i < data.vehicleNumber; ++i) {
long index = routing.start(i);
logger.info("Route for Vehicle " + i + ":");
long routeDistance = 0;
long routeLoad = 0;
String route = "";
while (!routing.isEnd(index)) {
long nodeIndex = manager.indexToNode(index);
routeLoad += data.demands[(int) nodeIndex];
route += nodeIndex + " Load(" + routeLoad + ") -> ";
long previousIndex = index;
index = solution.value(routing.nextVar(index));
routeDistance += routing.getArcCostForVehicle(previousIndex, index, i);
}
route += manager.indexToNode(routing.end(i));
logger.info(route);
logger.info("Distance of the route: " + routeDistance + "m");
totalDistance += routeDistance;
totalLoad += routeLoad;
}
logger.info("Total Distance of all routes: " + totalDistance + "m");
logger.info("Total Load of all routes: " + totalLoad);
}
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);
// Add Capacity constraint.
final int demandCallbackIndex = routing.registerUnaryTransitCallback((long fromIndex) -> {
// Convert from routing variable Index to user NodeIndex.
int fromNode = manager.indexToNode(fromIndex);
return data.demands[fromNode];
});
routing.addDimensionWithVehicleCapacity(demandCallbackIndex, 0, // null capacity slack
data.vehicleCapacities, // vehicle maximum capacities
true, // start cumul to zero
"Capacity");
// Allow to drop nodes.
long penalty = 1000;
for (int i = 1; i < data.distanceMatrix.length; ++i) {
routing.addDisjunction(new long[] {manager.nodeToIndex(i)}, penalty);
}
// Setting first solution heuristic.
RoutingSearchParameters searchParameters =
main.defaultRoutingSearchParameters()
.toBuilder()
.setFirstSolutionStrategy(FirstSolutionStrategy.Value.PATH_CHEAPEST_ARC)
.setLocalSearchMetaheuristic(LocalSearchMetaheuristic.Value.GUIDED_LOCAL_SEARCH)
.setTimeLimit(Duration.newBuilder().setSeconds(1).build())
.build();
// Solve the problem.
Assignment solution = routing.solveWithParameters(searchParameters);
// Print solution on console.
printSolution(data, routing, manager, solution);
}
}С#
using System;
using System.Collections.Generic;
using Google.OrTools.ConstraintSolver;
using Google.Protobuf.WellKnownTypes; // Duration
/// <summary>
/// Minimal Vrp with drop nodes.
/// </summary>
public class VrpDropNodes
{
class DataModel
{
public long[,] DistanceMatrix = {
{ 0, 548, 776, 696, 582, 274, 502, 194, 308, 194, 536, 502, 388, 354, 468, 776, 662 },
{ 548, 0, 684, 308, 194, 502, 730, 354, 696, 742, 1084, 594, 480, 674, 1016, 868, 1210 },
{ 776, 684, 0, 992, 878, 502, 274, 810, 468, 742, 400, 1278, 1164, 1130, 788, 1552, 754 },
{ 696, 308, 992, 0, 114, 650, 878, 502, 844, 890, 1232, 514, 628, 822, 1164, 560, 1358 },
{ 582, 194, 878, 114, 0, 536, 764, 388, 730, 776, 1118, 400, 514, 708, 1050, 674, 1244 },
{ 274, 502, 502, 650, 536, 0, 228, 308, 194, 240, 582, 776, 662, 628, 514, 1050, 708 },
{ 502, 730, 274, 878, 764, 228, 0, 536, 194, 468, 354, 1004, 890, 856, 514, 1278, 480 },
{ 194, 354, 810, 502, 388, 308, 536, 0, 342, 388, 730, 468, 354, 320, 662, 742, 856 },
{ 308, 696, 468, 844, 730, 194, 194, 342, 0, 274, 388, 810, 696, 662, 320, 1084, 514 },
{ 194, 742, 742, 890, 776, 240, 468, 388, 274, 0, 342, 536, 422, 388, 274, 810, 468 },
{ 536, 1084, 400, 1232, 1118, 582, 354, 730, 388, 342, 0, 878, 764, 730, 388, 1152, 354 },
{ 502, 594, 1278, 514, 400, 776, 1004, 468, 810, 536, 878, 0, 114, 308, 650, 274, 844 },
{ 388, 480, 1164, 628, 514, 662, 890, 354, 696, 422, 764, 114, 0, 194, 536, 388, 730 },
{ 354, 674, 1130, 822, 708, 628, 856, 320, 662, 388, 730, 308, 194, 0, 342, 422, 536 },
{ 468, 1016, 788, 1164, 1050, 514, 514, 662, 320, 274, 388, 650, 536, 342, 0, 764, 194 },
{ 776, 868, 1552, 560, 674, 1050, 1278, 742, 1084, 810, 1152, 274, 388, 422, 764, 0, 798 },
{ 662, 1210, 754, 1358, 1244, 708, 480, 856, 514, 468, 354, 844, 730, 536, 194, 798, 0 }
};
public long[] Demands = { 0, 1, 1, 3, 6, 3, 6, 8, 8, 1, 2, 1, 2, 6, 6, 8, 8 };
public long[] VehicleCapacities = { 15, 15, 15, 15 };
public int VehicleNumber = 4;
public int Depot = 0;
};
/// <summary>
/// Print the solution.
/// </summary>
static void PrintSolution(in DataModel data, in RoutingModel routing, in RoutingIndexManager manager,
in Assignment solution)
{
Console.WriteLine($"Objective {solution.ObjectiveValue()}:");
// Inspect solution.
// Display dropped nodes.
string droppedNodes = "Dropped nodes:";
for (int index = 0; index < routing.Size(); ++index)
{
if (routing.IsStart(index) || routing.IsEnd(index))
{
continue;
}
if (solution.Value(routing.NextVar(index)) == index)
{
droppedNodes += " " + manager.IndexToNode(index);
}
}
Console.WriteLine("{0}", droppedNodes);
// Inspect solution.
long totalDistance = 0;
long totalLoad = 0;
for (int i = 0; i < data.VehicleNumber; ++i)
{
Console.WriteLine("Route for Vehicle {0}:", i);
long routeDistance = 0;
long routeLoad = 0;
var index = routing.Start(i);
while (routing.IsEnd(index) == false)
{
long nodeIndex = manager.IndexToNode(index);
routeLoad += data.Demands[nodeIndex];
Console.Write("{0} Load({1}) -> ", nodeIndex, routeLoad);
var previousIndex = index;
index = solution.Value(routing.NextVar(index));
routeDistance += routing.GetArcCostForVehicle(previousIndex, index, 0);
}
Console.WriteLine("{0}", manager.IndexToNode((int)index));
Console.WriteLine("Distance of the route: {0}m", routeDistance);
totalDistance += routeDistance;
totalLoad += routeLoad;
}
Console.WriteLine("Total Distance of all routes: {0}m", totalDistance);
Console.WriteLine("Total Load of all routes: {0}m", totalLoad);
}
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);
// Create and register a transit callback.
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);
// Add Capacity constraint.
int demandCallbackIndex = routing.RegisterUnaryTransitCallback((long fromIndex) =>
{
// Convert from routing variable Index to
// demand NodeIndex.
var fromNode =
manager.IndexToNode(fromIndex);
return data.Demands[fromNode];
});
routing.AddDimensionWithVehicleCapacity(demandCallbackIndex, 0, // null capacity slack
data.VehicleCapacities, // vehicle maximum capacities
true, // start cumul to zero
"Capacity");
// Allow to drop nodes.
long penalty = 1000;
for (int i = 1; i < data.DistanceMatrix.GetLength(0); ++i)
{
routing.AddDisjunction(new long[] { manager.NodeToIndex(i) }, penalty);
}
// Setting first solution heuristic.
RoutingSearchParameters searchParameters =
operations_research_constraint_solver.DefaultRoutingSearchParameters();
searchParameters.FirstSolutionStrategy = FirstSolutionStrategy.Types.Value.PathCheapestArc;
searchParameters.LocalSearchMetaheuristic = LocalSearchMetaheuristic.Types.Value.GuidedLocalSearch;
searchParameters.TimeLimit = new Duration { Seconds = 1 };
// Solve the problem.
Assignment solution = routing.SolveWithParameters(searchParameters);
// Print solution on console.
PrintSolution(data, routing, manager, solution);
}
}