ortools-clone/examples/python/vrp.py

#!/usr/bin/env python
# This Python file uses the following encoding: utf-8
# Copyright 2015 Tin Arm Engineering AB
# Copyright 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.

"""Vehicle Routing Problem (VRP).
   This is a sample using the routing library python wrapper to solve a VRP problem.
   A description of the problem can be found here:
   http://en.wikipedia.org/wiki/Vehicle_routing_problem.

   Distances are in meters and time in seconds.

   Manhattan average block: 750ft x 264ft -> 228m x 80m
   src: https://nyti.ms/2GDoRIe "NY Times: Know Your distance"
   here we use: 114m x 80m city block
"""

from __future__ import print_function
from six.moves import xrange
from ortools.constraint_solver import pywrapcp
from ortools.constraint_solver import routing_enums_pb2

###########################
# Problem Data Definition #
###########################
class CityBlock():
    """City block definition"""
    @property
    def width(self):
        """Gets Block size West to East"""
        return 228/2

    @property
    def height(self):
        """Gets Block size North to South"""
        return 80

class DataProblem():
    """Stores the data for the problem"""
    def __init__(self):
        """Initializes the data for the problem"""
        self._num_vehicles = 4

        # Locations in block unit
        locations = \
                [(4, 4), # depot
                 (2, 0), (8, 0), # row 0
                 (0, 1), (1, 1),
                 (5, 2), (7, 2),
                 (3, 3), (6, 3),
                 (5, 5), (8, 5),
                 (1, 6), (2, 6),
                 (3, 7), (6, 7),
                 (0, 8), (7, 8)]
        # locations in meters using the block dimension defined
        city_block = CityBlock()
        self._locations = [(
            loc[0]*city_block.width,
            loc[1]*city_block.height) for loc in locations]

        self._depot = 0

    @property
    def num_vehicles(self):
        """Gets number of vehicles"""
        return self._num_vehicles

    @property
    def locations(self):
        """Gets locations"""
        return self._locations

    @property
    def num_locations(self):
        """Gets number of locations"""
        return len(self.locations)

    @property
    def depot(self):
        """Gets depot location index"""
        return self._depot

#######################
# Problem Constraints #
#######################
def manhattan_distance(position_1, position_2):
    """Computes the Manhattan distance between two points"""
    return (abs(position_1[0] - position_2[0]) +
            abs(position_1[1] - position_2[1]))

class CreateDistanceEvaluator(object): # pylint: disable=too-few-public-methods
    """Creates callback to return distance between points."""
    def __init__(self, data):
        """Initializes the distance matrix."""
        self._distances = {}

        # precompute distance between location to have distance callback in O(1)
        for from_node in xrange(data.num_locations):
            self._distances[from_node] = {}
            for to_node in xrange(data.num_locations):
                if from_node == to_node:
                    self._distances[from_node][to_node] = 0
                else:
                    self._distances[from_node][to_node] = (
                        manhattan_distance(
                            data.locations[from_node],
                            data.locations[to_node]))

    def distance_evaluator(self, from_node, to_node):
        """Returns the manhattan distance between the two nodes"""
        return self._distances[from_node][to_node]

###########
# Printer #
###########
class ConsolePrinter():
    """Print solution to console"""
    def __init__(self, data, routing, assignment):
        """Initializes the printer"""
        self._data = data
        self._routing = routing
        self._assignment = assignment

    @property
    def data(self):
        """Gets problem data"""
        return self._data

    @property
    def routing(self):
        """Gets routing model"""
        return self._routing

    @property
    def assignment(self):
        """Gets routing model"""
        return self._assignment

    def print(self):
        """Prints assignment on console"""
        # Inspect solution.
        total_dist = 0
        for vehicle_id in xrange(self.data.num_vehicles):
            index = self.routing.Start(vehicle_id)
            plan_output = 'Route for vehicle {0}:\n'.format(vehicle_id)
            route_dist = 0
            while not self.routing.IsEnd(index):
                node_index = self.routing.IndexToNode(index)
                next_node_index = self.routing.IndexToNode(
                    self.assignment.Value(self.routing.NextVar(index)))
                route_dist += manhattan_distance(
                    self.data.locations[node_index],
                    self.data.locations[next_node_index])
                plan_output += ' {0} -> '.format(node_index)
                index = self.assignment.Value(self.routing.NextVar(index))

            node_index = self.routing.IndexToNode(index)
            total_dist += route_dist
            plan_output += ' {0}\n'.format(node_index)
            plan_output += 'Distance of the route: {0}m\n'.format(route_dist)
            print(plan_output)
        print('Total Distance of all routes: {0}m'.format(total_dist))

########
# Main #
########
def main():
    """Entry point of the program"""
    # Instantiate the data problem.
    data = DataProblem()

    # Create Routing Model
    routing = pywrapcp.RoutingModel(data.num_locations, data.num_vehicles, data.depot)
    # Define weight of each edge
    distance_evaluator = CreateDistanceEvaluator(data).distance_evaluator
    routing.SetArcCostEvaluatorOfAllVehicles(distance_evaluator)

    # Setting first solution heuristic (cheapest addition).
    search_parameters = pywrapcp.RoutingModel.DefaultSearchParameters()
    search_parameters.first_solution_strategy = (
        routing_enums_pb2.FirstSolutionStrategy.PATH_CHEAPEST_ARC)
    # Solve the problem.
    assignment = routing.SolveWithParameters(search_parameters)
    printer = ConsolePrinter(data, routing, assignment)
    printer.print()

if __name__ == '__main__':
    main()
Update routing python examples - add vrp.py - add vrpgs.py - add cvrp.py - update cvrptw.py 2018-04-04 11:26:38 +02:00			`#!/usr/bin/env python`
			`# This Python file uses the following encoding: utf-8`
			`# Copyright 2015 Tin Arm Engineering AB`
			`# Copyright 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.`

			`"""Vehicle Routing Problem (VRP).`
			`This is a sample using the routing library python wrapper to solve a VRP problem.`
			`A description of the problem can be found here:`
			`http://en.wikipedia.org/wiki/Vehicle_routing_problem.`

			`Distances are in meters and time in seconds.`

			`Manhattan average block: 750ft x 264ft -> 228m x 80m`
			`src: https://nyti.ms/2GDoRIe "NY Times: Know Your distance"`
			`here we use: 114m x 80m city block`
			`"""`

			`from __future__ import print_function`
			`from six.moves import xrange`
			`from ortools.constraint_solver import pywrapcp`
			`from ortools.constraint_solver import routing_enums_pb2`

			`###########################`
			`# Problem Data Definition #`
			`###########################`
			`class CityBlock():`
			`"""City block definition"""`
			`@property`
			`def width(self):`
			`"""Gets Block size West to East"""`
			`return 228/2`

			`@property`
			`def height(self):`
			`"""Gets Block size North to South"""`
			`return 80`

			`class DataProblem():`
			`"""Stores the data for the problem"""`
			`def __init__(self):`
			`"""Initializes the data for the problem"""`
			`self._num_vehicles = 4`

			`# Locations in block unit`
			`locations = \`
			`[(4, 4), # depot`
			`(2, 0), (8, 0), # row 0`
			`(0, 1), (1, 1),`
			`(5, 2), (7, 2),`
			`(3, 3), (6, 3),`
			`(5, 5), (8, 5),`
			`(1, 6), (2, 6),`
			`(3, 7), (6, 7),`
			`(0, 8), (7, 8)]`
			`# locations in meters using the block dimension defined`
			`city_block = CityBlock()`
			`self._locations = [(`
			`loc[0]*city_block.width,`
			`loc[1]*city_block.height) for loc in locations]`

			`self._depot = 0`

			`@property`
			`def num_vehicles(self):`
			`"""Gets number of vehicles"""`
			`return self._num_vehicles`

			`@property`
			`def locations(self):`
			`"""Gets locations"""`
			`return self._locations`

			`@property`
			`def num_locations(self):`
			`"""Gets number of locations"""`
			`return len(self.locations)`

			`@property`
			`def depot(self):`
			`"""Gets depot location index"""`
			`return self._depot`

			`#######################`
			`# Problem Constraints #`
			`#######################`
			`def manhattan_distance(position_1, position_2):`
			`"""Computes the Manhattan distance between two points"""`
			`return (abs(position_1[0] - position_2[0]) +`
			`abs(position_1[1] - position_2[1]))`

			`class CreateDistanceEvaluator(object): # pylint: disable=too-few-public-methods`
			`"""Creates callback to return distance between points."""`
			`def __init__(self, data):`
			`"""Initializes the distance matrix."""`
			`self._distances = {}`

			`# precompute distance between location to have distance callback in O(1)`
			`for from_node in xrange(data.num_locations):`
			`self._distances[from_node] = {}`
			`for to_node in xrange(data.num_locations):`
			`if from_node == to_node:`
			`self._distances[from_node][to_node] = 0`
			`else:`
			`self._distances[from_node][to_node] = (`
			`manhattan_distance(`
			`data.locations[from_node],`
			`data.locations[to_node]))`

			`def distance_evaluator(self, from_node, to_node):`
			`"""Returns the manhattan distance between the two nodes"""`
			`return self._distances[from_node][to_node]`

			`###########`
			`# Printer #`
			`###########`
			`class ConsolePrinter():`
			`"""Print solution to console"""`
			`def __init__(self, data, routing, assignment):`
			`"""Initializes the printer"""`
			`self._data = data`
			`self._routing = routing`
			`self._assignment = assignment`

			`@property`
			`def data(self):`
			`"""Gets problem data"""`
			`return self._data`

			`@property`
			`def routing(self):`
			`"""Gets routing model"""`
			`return self._routing`

			`@property`
			`def assignment(self):`
			`"""Gets routing model"""`
			`return self._assignment`

			`def print(self):`
			`"""Prints assignment on console"""`
			`# Inspect solution.`
			`total_dist = 0`
			`for vehicle_id in xrange(self.data.num_vehicles):`
			`index = self.routing.Start(vehicle_id)`
			`plan_output = 'Route for vehicle {0}:\n'.format(vehicle_id)`
			`route_dist = 0`
			`while not self.routing.IsEnd(index):`
			`node_index = self.routing.IndexToNode(index)`
			`next_node_index = self.routing.IndexToNode(`
			`self.assignment.Value(self.routing.NextVar(index)))`
			`route_dist += manhattan_distance(`
			`self.data.locations[node_index],`
			`self.data.locations[next_node_index])`
			`plan_output += ' {0} -> '.format(node_index)`
			`index = self.assignment.Value(self.routing.NextVar(index))`

			`node_index = self.routing.IndexToNode(index)`
			`total_dist += route_dist`
			`plan_output += ' {0}\n'.format(node_index)`
			`plan_output += 'Distance of the route: {0}m\n'.format(route_dist)`
			`print(plan_output)`
			`print('Total Distance of all routes: {0}m'.format(total_dist))`

			`########`
			`# Main #`
			`########`
			`def main():`
			`"""Entry point of the program"""`
			`# Instantiate the data problem.`
			`data = DataProblem()`

			`# Create Routing Model`
			`routing = pywrapcp.RoutingModel(data.num_locations, data.num_vehicles, data.depot)`
			`# Define weight of each edge`
			`distance_evaluator = CreateDistanceEvaluator(data).distance_evaluator`
			`routing.SetArcCostEvaluatorOfAllVehicles(distance_evaluator)`

			`# Setting first solution heuristic (cheapest addition).`
			`search_parameters = pywrapcp.RoutingModel.DefaultSearchParameters()`
			`search_parameters.first_solution_strategy = (`
			`routing_enums_pb2.FirstSolutionStrategy.PATH_CHEAPEST_ARC)`
			`# Solve the problem.`
			`assignment = routing.SolveWithParameters(search_parameters)`
			`printer = ConsolePrinter(data, routing, assignment)`
			`printer.print()`

			`if __name__ == '__main__':`
			`main()`