ortools-clone/ortools/constraint_solver/samples/vrp_global_span.py

# Copyright 2010-2018 Google LLC
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
#     http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# [START program]
"""Vehicles Routing Problem (VRP)."""

# [START import]
from ortools.constraint_solver import routing_enums_pb2
from ortools.constraint_solver import pywrapcp
# [END import]


# [START data_model]
def create_data_model():
    """Stores the data for the problem."""
    data = {}
    data['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
        ],
    ]
    data['num_vehicles'] = 4
    data['depot'] = 0
    return data
    # [END data_model]


# [START solution_printer]
def print_solution(data, manager, routing, solution):
    """Prints solution on console."""
    max_route_distance = 0
    for vehicle_id in range(data['num_vehicles']):
        index = routing.Start(vehicle_id)
        plan_output = 'Route for vehicle {}:\n'.format(vehicle_id)
        route_distance = 0
        while not routing.IsEnd(index):
            plan_output += ' {} -> '.format(manager.IndexToNode(index))
            previous_index = index
            index = solution.Value(routing.NextVar(index))
            route_distance += routing.GetArcCostForVehicle(
                previous_index, index, vehicle_id)
        plan_output += '{}\n'.format(manager.IndexToNode(index))
        plan_output += 'Distance of the route: {}m\n'.format(route_distance)
        print(plan_output)
        max_route_distance = max(route_distance, max_route_distance)
    print('Maximum of the route distances: {}m'.format(max_route_distance))

# [END solution_printer]


def main():
    """Solve the CVRP problem."""
    # Instantiate the data problem.
    # [START data]
    data = create_data_model()
    # [END data]

    # Create the routing index manager.
    # [START index_manager]
    manager = pywrapcp.RoutingIndexManager(len(data['distance_matrix']),
                                           data['num_vehicles'], data['depot'])
    # [END index_manager]

    # Create Routing Model.
    # [START routing_model]
    routing = pywrapcp.RoutingModel(manager)

    # [END routing_model]

    # Create and register a transit callback.
    # [START 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)
    # [END transit_callback]

    # Define cost of each arc.
    # [START arc_cost]
    routing.SetArcCostEvaluatorOfAllVehicles(transit_callback_index)
    # [END arc_cost]

    # Add Distance constraint.
    # [START distance_constraint]
    dimension_name = 'Distance'
    routing.AddDimension(
        transit_callback_index,
        0,  # no slack
        3000,  # vehicle maximum travel distance
        True,  # start cumul to zero
        dimension_name)
    distance_dimension = routing.GetDimensionOrDie(dimension_name)
    distance_dimension.SetGlobalSpanCostCoefficient(100)
    # [END distance_constraint]

    # Setting first solution heuristic.
    # [START parameters]
    search_parameters = pywrapcp.DefaultRoutingSearchParameters()
    search_parameters.first_solution_strategy = (
        routing_enums_pb2.FirstSolutionStrategy.PATH_CHEAPEST_ARC)
    # [END parameters]

    # Solve the problem.
    # [START solve]
    solution = routing.SolveWithParameters(search_parameters)
    # [END solve]

    # Print solution on console.
    # [START print_solution]
    if solution:
        print_solution(data, manager, routing, solution)
    # [END print_solution]


if __name__ == '__main__':
    main()
# [END program]
Export python routing samples from g3 2019-01-10 10:49:36 +01:00			`# Copyright 2010-2018 Google LLC`
			`# Licensed under the Apache License, Version 2.0 (the "License");`
			`# you may not use this file except in compliance with the License.`
			`# You may obtain a copy of the License at`
			`#`
			`# http://www.apache.org/licenses/LICENSE-2.0`
			`#`
			`# Unless required by applicable law or agreed to in writing, software`
			`# distributed under the License is distributed on an "AS IS" BASIS,`
			`# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.`
			`# See the License for the specific language governing permissions and`
			`# limitations under the License.`
			`# [START program]`
			`"""Vehicles Routing Problem (VRP)."""`

			`# [START import]`
			`from ortools.constraint_solver import routing_enums_pb2`
			`from ortools.constraint_solver import pywrapcp`
			`# [END import]`


			`# [START data_model]`
			`def create_data_model():`
			`"""Stores the data for the problem."""`
			`data = {}`
			`data['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`
			`],`
			`]`
			`data['num_vehicles'] = 4`
			`data['depot'] = 0`
			`return data`
			`# [END data_model]`


			`# [START solution_printer]`
Sync g3 -> github 2019-03-04 11:27:22 +01:00			`def print_solution(data, manager, routing, solution):`
			`"""Prints solution on console."""`
			`max_route_distance = 0`
Export python routing samples from g3 2019-01-10 10:49:36 +01:00			`for vehicle_id in range(data['num_vehicles']):`
			`index = routing.Start(vehicle_id)`
			`plan_output = 'Route for vehicle {}:\n'.format(vehicle_id)`
			`route_distance = 0`
			`while not routing.IsEnd(index):`
			`plan_output += ' {} -> '.format(manager.IndexToNode(index))`
			`previous_index = index`
Sync g3 -> github 2019-03-04 11:27:22 +01:00			`index = solution.Value(routing.NextVar(index))`
Export python routing samples from g3 2019-01-10 10:49:36 +01:00			`route_distance += routing.GetArcCostForVehicle(`
			`previous_index, index, vehicle_id)`
			`plan_output += '{}\n'.format(manager.IndexToNode(index))`
			`plan_output += 'Distance of the route: {}m\n'.format(route_distance)`
			`print(plan_output)`
Sync g3 -> github 2019-03-04 11:27:22 +01:00			`max_route_distance = max(route_distance, max_route_distance)`
			`print('Maximum of the route distances: {}m'.format(max_route_distance))`

			`# [END solution_printer]`
Export python routing samples from g3 2019-01-10 10:49:36 +01:00

			`def main():`
Sync g3 -> github 2019-03-04 11:27:22 +01:00			`"""Solve the CVRP problem."""`
Export python routing samples from g3 2019-01-10 10:49:36 +01:00			`# Instantiate the data problem.`
			`# [START data]`
			`data = create_data_model()`
			`# [END data]`

			`# Create the routing index manager.`
			`# [START index_manager]`
update routing/local search internal API 2019-08-06 15:54:57 -07:00			`manager = pywrapcp.RoutingIndexManager(len(data['distance_matrix']),`
			`data['num_vehicles'], data['depot'])`
Export python routing samples from g3 2019-01-10 10:49:36 +01:00			`# [END index_manager]`

			`# Create Routing Model.`
			`# [START routing_model]`
			`routing = pywrapcp.RoutingModel(manager)`

			`# [END routing_model]`

Sync routing sample with g3 2019-02-05 15:10:20 +01:00			`# Create and register a transit callback.`
			`# [START transit_callback]`
Export python routing samples from g3 2019-01-10 10:49:36 +01:00			`def distance_callback(from_index, to_index):`
Export g3 to github 2019-02-18 15:27:32 +01:00			`"""Returns the distance between the two nodes."""`
Update samples 2019-01-11 16:49:07 +01:00			`# Convert from routing variable Index to distance matrix NodeIndex.`
Export python routing samples from g3 2019-01-10 10:49:36 +01:00			`from_node = manager.IndexToNode(from_index)`
			`to_node = manager.IndexToNode(to_index)`
			`return data['distance_matrix'][from_node][to_node]`

Routing Samples cleanup 2019-01-11 12:03:44 +01:00			`transit_callback_index = routing.RegisterTransitCallback(distance_callback)`
Sync routing sample with g3 2019-02-05 15:10:20 +01:00			`# [END transit_callback]`

			`# Define cost of each arc.`
			`# [START arc_cost]`
Routing Samples cleanup 2019-01-11 12:03:44 +01:00			`routing.SetArcCostEvaluatorOfAllVehicles(transit_callback_index)`
Export python routing samples from g3 2019-01-10 10:49:36 +01:00			`# [END arc_cost]`

			`# Add Distance constraint.`
			`# [START distance_constraint]`
			`dimension_name = 'Distance'`
			`routing.AddDimension(`
Routing Samples cleanup 2019-01-11 12:03:44 +01:00			`transit_callback_index,`
Export python routing samples from g3 2019-01-10 10:49:36 +01:00			`0, # no slack`
			`3000, # vehicle maximum travel distance`
			`True, # start cumul to zero`
			`dimension_name)`
			`distance_dimension = routing.GetDimensionOrDie(dimension_name)`
			`distance_dimension.SetGlobalSpanCostCoefficient(100)`
			`# [END distance_constraint]`

			`# Setting first solution heuristic.`
			`# [START parameters]`
			`search_parameters = pywrapcp.DefaultRoutingSearchParameters()`
			`search_parameters.first_solution_strategy = (`
			`routing_enums_pb2.FirstSolutionStrategy.PATH_CHEAPEST_ARC)`
			`# [END parameters]`

			`# Solve the problem.`
			`# [START solve]`
Sync g3 -> github 2019-03-04 11:27:22 +01:00			`solution = routing.SolveWithParameters(search_parameters)`
Export python routing samples from g3 2019-01-10 10:49:36 +01:00			`# [END solve]`

			`# Print solution on console.`
			`# [START print_solution]`
Sync g3 -> github 2019-03-04 11:27:22 +01:00			`if solution:`
			`print_solution(data, manager, routing, solution)`
Export python routing samples from g3 2019-01-10 10:49:36 +01:00			`# [END print_solution]`


			`if __name__ == '__main__':`
			`main()`
			`# [END program]`