ortools-clone/examples/java/CapacitatedVehicleRoutingProblemWithTimeWindows.java

//
// Copyright 2012 Google
//
// 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.
import com.google.ortools.constraintsolver.Assignment;
import com.google.ortools.constraintsolver.IntVar;
import com.google.ortools.constraintsolver.NodeEvaluator2;
import com.google.ortools.constraintsolver.RoutingModel;
import com.google.ortools.constraintsolver.FirstSolutionStrategy;
import com.google.ortools.constraintsolver.RoutingSearchParameters;

import java.util.ArrayList;
import java.util.List;
import java.util.Random;
import java.util.logging.Logger;

// A pair class

class Pair<K, V> {
  final K first;
  final V second;

  public static <K, V> Pair<K, V> of(K element0, V element1) {
    return new Pair<K, V>(element0, element1);
  }

  public Pair(K element0, V element1) {
    this.first = element0;
    this.second = element1;
  }
}

/**
 * Sample showing how to model and solve a capacitated vehicle routing problem
 * with time windows using the swig-wrapped version of the vehicle routing
 * library in src/constraint_solver.
 */

public class CapacitatedVehicleRoutingProblemWithTimeWindows {

  static {
    System.loadLibrary("jniortools");
  }

  private static Logger logger =
      Logger.getLogger(CapacitatedVehicleRoutingProblemWithTimeWindows.class.getName());

  // Locations representing either an order location or a vehicle route
  // start/end.
  private List<Pair<Integer, Integer>> locations = new ArrayList();

  // Quantity to be picked up for each order.
  private List<Integer> orderDemands = new ArrayList();
  // Time duration spent to deliver each order.
  private List<Integer> orderDurations = new ArrayList();
  // Time window in which each order must be performed.
  private List<Pair<Integer, Integer>> orderTimeWindows = new ArrayList();
  // Penalty cost "paid" for dropping an order.
  private List<Integer> orderPenalties = new ArrayList();

  // Capacity of the vehicles.
  private int vehicleCapacity = 0;
  // Earliest time at which each vehicle must start its tour.
  private List<Integer> vehicleStartTime = new ArrayList();
  // Latest time at which each vehicle must end its tour.
  private List<Integer> vehicleEndTime = new ArrayList();
  // Cost per unit of distance of each vehicle.
  private List<Integer> vehicleCostCoefficients = new ArrayList();
  // Vehicle start and end indices. They have to be implemented as int[] due
  // to the available SWIG-ed interface.
  private int vehicleStarts[];
  private int vehicleEnds[];

  // Random number generator to produce data.
  private final Random randomGenerator = new Random(0xBEEF);

  /**
   * Constructs a capacitated vehicle routing problem with time windows.
   */
  private CapacitatedVehicleRoutingProblemWithTimeWindows() {}

  /**
   * Creates order data. Location of the order is random, as well as its
   * demand (quantity), time window and penalty.
   *
   * @param numberOfOrders number of orders to build.
   * @param xMax maximum x coordinate in which orders are located.
   * @param yMax maximum y coordinate in which orders are located.
   * @param demandMax maximum quantity of a demand.
   * @param timeWindowMin minimum starting time of the order time window.
   * @param timeWindowMax maximum starting time of the order time window.
   * @param timeWindowWidth duration of the order time window.
   * @param penaltyMin minimum pernalty cost if order is dropped.
   * @param penaltyMax maximum pernalty cost if order is dropped.
   */
  private void buildOrders(int numberOfOrders,
                           int xMax, int yMax,
                           int demandMax,
                           int timeWindowMin,
                           int timeWindowMax,
                           int timeWindowWidth,
                           int penaltyMin,
                           int penaltyMax) {
    logger.info("Building orders.");
    for (int order = 0; order < numberOfOrders; ++order) {
      locations.add(Pair.of(randomGenerator.nextInt(xMax + 1),
                            randomGenerator.nextInt(yMax + 1)));
      orderDemands.add(randomGenerator.nextInt(demandMax + 1));
      /** @todo 1) Specify deliver duration for each shipment*/
      orderDurations.add(2); // in minutes
      int timeWindowStart = randomGenerator.nextInt(timeWindowMax - timeWindowMin) + timeWindowMin;
      orderTimeWindows.add(Pair.of(timeWindowStart, timeWindowStart + timeWindowWidth));
      orderPenalties.add(randomGenerator.nextInt(penaltyMax - penaltyMin + 1) + penaltyMin);
    }
  }

  /**
   * Creates fleet data. Vehicle starting and ending locations are random, as
   * well as vehicle costs per distance unit.
   *
   * @param numberOfVehicles
   * @param xMax maximum x coordinate in which orders are located.
   * @param yMax maximum y coordinate in which orders are located.
   * @param startTime earliest start time of a tour of a vehicle.
   * @param endTime latest end time of a tour of a vehicle.
   * @param capacity capacity of a vehicle.
   * @param costCoefficientMax maximum cost per distance unit of a vehicle
   *        (mimimum is 1),
   */
  private void buildFleet(int numberOfVehicles,
                          int xMax, int yMax,
                          int startTime,
                          int endTime,
                          int capacity,
                          int costCoefficientMax) {
    logger.info("Building fleet.");
    vehicleCapacity = capacity;
    vehicleStarts = new int[numberOfVehicles];
    vehicleEnds = new int[numberOfVehicles];
    for (int vehicle = 0; vehicle < numberOfVehicles; ++vehicle) {
      vehicleStarts[vehicle] = locations.size();
      locations.add(Pair.of(randomGenerator.nextInt(xMax + 1),
                            randomGenerator.nextInt(yMax + 1)));
      vehicleEnds[vehicle] = locations.size();
      locations.add(Pair.of(randomGenerator.nextInt(xMax + 1),
                            randomGenerator.nextInt(yMax + 1)));
      vehicleStartTime.add(startTime);
      vehicleEndTime.add(endTime);
      vehicleCostCoefficients.add(randomGenerator.nextInt(costCoefficientMax) + 1);
    }
  }

  /**
   * Solves the current routing problem.
   */
  private void solve(final int numberOfOrders, final int numberOfVehicles) {
    logger.info("Creating model with " + numberOfOrders + " orders and " +
      numberOfVehicles + " vehicles.");
    // Finalizing model
    final int numberOfLocations = locations.size();

    RoutingModel model =
        new RoutingModel(numberOfLocations, numberOfVehicles,
            vehicleStarts, vehicleEnds);

    // Setting up dimensions
    final int bigNumber = 100000;
    NodeEvaluator2 timeCallback = new NodeEvaluator2(){
        @Override
        public long run(int firstIndex, int secondIndex) {
          try {
            Pair<Integer, Integer> firstLocation = locations.get(firstIndex);
            Pair<Integer, Integer> secondLocation = locations.get(secondIndex);
            Integer distance = 0;
            Integer duration = 0;
            distance = Math.abs(firstLocation.first - secondLocation.first) +
                       Math.abs(firstLocation.second - secondLocation.second);
            // Deal with Order duration shipment
            if (firstIndex < numberOfOrders) {
              // shipment duration
              duration += orderDurations.get(firstIndex);
            }
            return  distance + duration;
          } catch (Throwable throwed) {
            logger.warning(throwed.getMessage());
            return 0;
          }
        }
      };
    model.addDimension(timeCallback, bigNumber, bigNumber, false, "time");
    NodeEvaluator2 demandCallback = new NodeEvaluator2(){
        @Override
        public long run(int firstIndex, int secondIndex) {
          try {
            if (firstIndex < numberOfOrders) {
              return orderDemands.get(firstIndex);
            }
            return 0;
          } catch (Throwable throwed) {
            logger.warning(throwed.getMessage());
            return 0;
          }
        }
      };
    model.addDimension(demandCallback, 0, vehicleCapacity, true, "capacity");

    // Setting up vehicles
    for (int vehicle = 0; vehicle < numberOfVehicles; ++vehicle) {
      final int costCoefficient = vehicleCostCoefficients.get(vehicle);
      NodeEvaluator2 manhattanCostCallback = new NodeEvaluator2() {
          @Override
          public long run(int firstIndex, int secondIndex) {
            try {
              Pair<Integer, Integer> firstLocation = locations.get(firstIndex);
              Pair<Integer, Integer> secondLocation = locations.get(secondIndex);
              return costCoefficient *
                  (Math.abs(firstLocation.first - secondLocation.first) +
                   Math.abs(firstLocation.second - secondLocation.second));
            } catch (Throwable throwed) {
              logger.warning(throwed.getMessage());
              return 0;
            }
          }
        };
      model.setArcCostEvaluatorOfVehicle(manhattanCostCallback, vehicle);
      model.cumulVar(model.start(vehicle), "time").setMin(vehicleStartTime.get(vehicle));
      model.cumulVar(model.end(vehicle), "time").setMax(vehicleEndTime.get(vehicle));
    }

    // Setting up orders
    for (int order = 0; order < numberOfOrders; ++order) {
      model.cumulVar(model.nodeToIndex(order), "time").setRange(
          orderTimeWindows.get(order).first,
          orderTimeWindows.get(order).second);
      int[] orders = {order};
      model.addDisjunction(orders, orderPenalties.get(order));
    }

    // Solving
    RoutingSearchParameters parameters =
        RoutingSearchParameters.newBuilder()
        .mergeFrom(RoutingModel.defaultSearchParameters())
        .setFirstSolutionStrategy(FirstSolutionStrategy.Value.PATH_CHEAPEST_ARC)
        .build();

    logger.info("Search");
    Assignment solution = model.solveWithParameters(parameters);

    if (solution != null) {
      String output = "Total cost: " + solution.objectiveValue() + "\n";
      // Dropped orders
      String dropped = "";
      for (int order = 0; order < numberOfOrders; ++order) {
        if (solution.value(model.nextVar(order)) == order) {
          dropped += " " + order;
        }
      }
      if (dropped.length() > 0) {
        output += "Dropped orders:" + dropped + "\n";
      }
      // Routes
      for (int vehicle = 0; vehicle < numberOfVehicles; ++vehicle) {
        String route = "Vehicle " + vehicle + ": ";
        long order = model.start(vehicle);
        // Empty route has a minimum of two nodes: Start => End
        if (model.isEnd(solution.value(model.nextVar(order)))) {
          route += "/!\\Empty Route/!\\ ";
        }
        {
          for (;
              !model.isEnd(order);
              order = solution.value(model.nextVar(order))) {
            IntVar load = model.cumulVar(order, "capacity");
            IntVar time = model.cumulVar(order, "time");
            route += order + " Load(" + solution.value(load) + ") " +
              "Time(" + solution.min(time) + ", " + solution.max(time) +
              ") -> ";
          }
          IntVar load = model.cumulVar(order, "capacity");
          IntVar time = model.cumulVar(order, "time");
          route += order + " Load(" + solution.value(load) + ") " +
            "Time(" + solution.min(time) + ", " + solution.max(time) + ")";
        }
        output += route + "\n";
      }
      logger.info(output);
    } else {
      logger.info("No solution Found !");
    }
  }

  public static void main(String[] args) throws Exception {
    CapacitatedVehicleRoutingProblemWithTimeWindows problem =
        new CapacitatedVehicleRoutingProblemWithTimeWindows();
    final int xMax = 20;
    final int yMax = 20;
    final int demandMax = 3;
    final int timeWindowMin = 8 * 60;
    final int timeWindowMax = 17 * 60;
    final int timeWindowWidth = 4 * 60;
    final int penaltyMin = 50;
    final int penaltyMax = 100;
    /** @todo Specify vehicle start time*/
    final int startTime = 8 * 60;
    /** @todo Specify vehicle end time*/
    final int endTime = 17 * 60;
    final int costCoefficientMax = 3;

    final int orders = 100;
    final int vehicles = 20;
    final int capacity = 50;

    problem.buildOrders(orders,
                        xMax,
                        yMax,
                        demandMax,
                        timeWindowMin,
                        timeWindowMax,
                        timeWindowWidth,
                        penaltyMin,
                        penaltyMax);
    problem.buildFleet(vehicles,
                       xMax,
                       yMax,
                       startTime,
                       endTime,
                       capacity,
                       costCoefficientMax);
    problem.solve(orders, vehicles);
  }
}