ortools-clone/examples/python/cvrp_reload.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.
"""Capacitated Vehicle Routing Problem (CVRP).

   This is a sample using the routing library python wrapper to solve a CVRP
   problem.
   A description of the problem can be found here:
   http://en.wikipedia.org/wiki/Vehicle_routing_problem.

   Distances are in meters.
"""

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 #
###########################
def create_data_model():
    """Stores the data for the problem"""
    data = {}
    _capacity = 15
    # Locations in block unit
    _locations = [
        (4, 4),  # depot
        (4, 4),  # unload depot_prime
        (4, 4),  # unload depot_second
        (4, 4),  # unload depot_fourth
        (4, 4),  # unload depot_fourth
        (4, 4),  # unload depot_fifth
        (2, 0),
        (8, 0),  # locations to visit
        (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)
    ]
    # Compute locations in meters using the block dimension defined as follow
    # Manhattan average block: 750ft x 264ft -> 228m x 80m
    # here we use: 114m x 80m city block
    # src: https://nyti.ms/2GDoRIe "NY Times: Know Your distance"
    data["locations"] = [(l[0] * 114, l[1] * 80) for l in _locations]
    data["num_locations"] = len(data["locations"])
    data["demands"] = \
          [0, # depot
           -_capacity,
           -_capacity,
           -_capacity,
           -_capacity,
           -_capacity,
           1, 1, # 1, 2
           2, 4, # 3, 4
           2, 4, # 5, 6
           8, 8, # 7, 8
           1, 2, # 9,10
           1, 2, # 11,12
           4, 4, # 13, 14
           8, 8] # 15, 16
    data["time_per_demand_unit"] = 5  # 5 minutes/unit
    data["time_windows"] = \
          [(0, 0), # depot
           (0, 1000),
           (0, 1000),
           (0, 1000),
           (0, 1000),
           (0, 1000),
           (75, 8500), (75, 8500), # 1, 2
           (60, 7000), (45, 5500), # 3, 4
           (0,  8000), (50, 6000), # 5, 6
           (0,  1000), (10, 2000), # 7, 8
           (0,  1000), (75, 8500), # 9, 10
           (85, 9500), (5,  1500), # 11, 12
           (15, 2500), (10, 2000), # 13, 14
           (45, 5500), (30, 4000)] # 15, 16
    data["num_vehicles"] = 3
    data["vehicle_capacity"] = _capacity
    data[
        "vehicle_speed"] = 5 * 60 / 3.6  # Travel speed: 5km/h to convert in m/min
    data["depot"] = 0
    return data


#######################
# 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]))


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

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

    return distance_evaluator


def add_distance_dimension(routing, distance_evaluator):
    """Add Global Span constraint"""
    distance = 'Distance'
    routing.AddDimension(
        distance_evaluator,
        0,  # null slack
        10000,  # maximum distance per vehicle
        True,  # start cumul to zero
        distance)
    distance_dimension = routing.GetDimensionOrDie(distance)
    # Try to minimize the max distance among vehicles.
    # /!\ It doesn't mean the standard deviation is minimized
    distance_dimension.SetGlobalSpanCostCoefficient(100)


def create_demand_evaluator(data):
    """Creates callback to get demands at each location."""
    _demands = data["demands"]

    def demand_evaluator(from_node, to_node):
        """Returns the demand of the current node"""
        del to_node
        return _demands[from_node]

    return demand_evaluator


def add_capacity_constraints(routing, data, demand_evaluator):
    """Adds capacity constraint"""
    vehicle_capacity = data["vehicle_capacity"]
    capacity = 'Capacity'
    routing.AddDimension(
        demand_evaluator,
        0,  # Null slack
        vehicle_capacity,
        True,  # start cumul to zero
        capacity)

    # Add Slack for reseting to zero unload depot nodes.
    # e.g. vehicle with load 10/15 arrives at node 1 (depot unload)
    # so we have CumulVar = 10(current load) + -15(unload) + 5(slack) = 0.
    capacity_dimension = routing.GetDimensionOrDie(capacity)
    for node_index in [1, 2, 3, 4, 5]:
        index = routing.NodeToIndex(node_index)
        capacity_dimension.SlackVar(index).SetRange(0, vehicle_capacity)
        routing.AddDisjunction([node_index], 0)


def create_time_evaluator(data):
    """Creates callback to get total times between locations."""

    def service_time(data, node):
        """Gets the service time for the specified location."""
        return abs(data["demands"][node]) * data["time_per_demand_unit"]

    def travel_time(data, from_node, to_node):
        """Gets the travel times between two locations."""
        if from_node == to_node:
            travel_time = 0
        else:
            travel_time = manhattan_distance(
                data["locations"][from_node],
                data["locations"][to_node]) / data["vehicle_speed"]
        return travel_time

    _total_time = {}
    # precompute total time to have time callback in O(1)
    for from_node in xrange(data["num_locations"]):
        _total_time[from_node] = {}
        for to_node in xrange(data["num_locations"]):
            if from_node == to_node:
                _total_time[from_node][to_node] = 0
            else:
                _total_time[from_node][to_node] = int(
                    service_time(data, from_node) +
                    travel_time(data, from_node, to_node))

    def time_evaluator(from_node, to_node):
        """Returns the total time between the two nodes"""
        return _total_time[from_node][to_node]

    return time_evaluator


def add_time_window_constraints(routing, data, time_evaluator):
    """Add Time windows constraint"""
    time = 'Time'
    horizon = 1500
    routing.AddDimension(
        time_evaluator,
        horizon,  # allow waiting time
        horizon,  # maximum time per vehicle
        False,  # don't force start cumul to zero since we are giving TW to start nodes
        time)
    time_dimension = routing.GetDimensionOrDie(time)
    # Add time window constraints for each location except depot
    # and "copy" the slack var in the solution object (aka Assignment) to print it
    for location_idx, time_window in enumerate(data["time_windows"]):
        if location_idx == 0:
            continue
        index = routing.NodeToIndex(location_idx)
        time_dimension.CumulVar(index).SetRange(time_window[0], time_window[1])
        routing.AddToAssignment(time_dimension.SlackVar(index))
    # Add time window constraints for each vehicle start node
    # and "copy" the slack var in the solution object (aka Assignment) to print it
    for vehicle_id in xrange(data["num_vehicles"]):
        index = routing.Start(vehicle_id)
        time_dimension.CumulVar(index).SetRange(data["time_windows"][0][0],
                                                data["time_windows"][0][1])
        routing.AddToAssignment(time_dimension.SlackVar(index))
        # Warning: Slack var is not defined for vehicle's end node
        #routing.AddToAssignment(time_dimension.SlackVar(self.routing.End(vehicle_id)))


###########
# Printer #
###########
def print_solution(data, routing, assignment):
    """Prints assignment on console"""
    print('Objective: {}'.format(assignment.ObjectiveValue()))
    total_distance = 0
    total_load = 0
    total_time = 0
    capacity_dimension = routing.GetDimensionOrDie('Capacity')
    time_dimension = routing.GetDimensionOrDie('Time')
    dropped = []
    for order in xrange(0, routing.nodes()):
        index = routing.NodeToIndex(order)
        if assignment.Value(routing.NextVar(index)) == index:
            dropped.append(order)
    print('dropped orders: {}'.format(dropped))

    for vehicle_id in xrange(data["num_vehicles"]):
        index = routing.Start(vehicle_id)
        plan_output = 'Route for vehicle {}:\n'.format(vehicle_id)
        distance = 0
        while not routing.IsEnd(index):
            load_var = capacity_dimension.CumulVar(index)
            time_var = time_dimension.CumulVar(index)
            plan_output += ' {0} Load({1}) Time({2},{3}) ->'.format(
                routing.IndexToNode(index), assignment.Value(load_var),
                assignment.Min(time_var), assignment.Max(time_var))
            previous_index = index
            index = assignment.Value(routing.NextVar(index))
            distance += routing.GetArcCostForVehicle(previous_index, index,
                                                     vehicle_id)
        load_var = capacity_dimension.CumulVar(index)
        time_var = time_dimension.CumulVar(index)
        plan_output += ' {0} Load({1}) Time({2},{3})\n'.format(
            routing.IndexToNode(index), assignment.Value(load_var),
            assignment.Min(time_var), assignment.Max(time_var))
        plan_output += 'Distance of the route: {}m\n'.format(distance)
        plan_output += 'Load of the route: {}\n'.format(
            assignment.Value(load_var))
        plan_output += 'Time of the route: {}min\n'.format(
            assignment.Value(time_var))
        print(plan_output)
        total_distance += distance
        total_load += assignment.Value(load_var)
        total_time += assignment.Value(time_var)
    print('Total Distance of all routes: {}m'.format(total_distance))
    print('Total Load of all routes: {}'.format(total_load))
    print('Total Time of all routes: {}min'.format(total_time))


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

    # Create Routing Model
    routing = pywrapcp.RoutingModel(data["num_locations"],
                                    data["num_vehicles"], data["depot"])
    # Define weight of each edge
    distance_evaluator = create_distance_evaluator(data)
    routing.SetArcCostEvaluatorOfAllVehicles(distance_evaluator)
    # Add Distance constraint to minimize the longuest route
    add_distance_dimension(routing, distance_evaluator)
    # Add Capacity constraint
    demand_evaluator = create_demand_evaluator(data)
    add_capacity_constraints(routing, data, demand_evaluator)
    # Add Time Window constraint
    time_evaluator = create_time_evaluator(data)
    add_time_window_constraints(routing, data, time_evaluator)

    # Setting first solution heuristic (cheapest addition).
    search_parameters = pywrapcp.RoutingModel.DefaultSearchParameters()
    search_parameters.first_solution_strategy = (
        routing_enums_pb2.FirstSolutionStrategy.PATH_CHEAPEST_ARC)  # pylint: disable=no-member
    # Solve the problem.
    assignment = routing.SolveWithParameters(search_parameters)
    print_solution(data, routing, assignment)


if __name__ == '__main__':
    main()