6

I have java interface and class implementations that have need for different arguments when invoking similar behavior. Which of the following is mostly appropriate?

In first option I have different classes inherit common behavior from base interface and all differences are only implemented directly in the classes and not in interface. This one seems most appropriate, but I have to do manual type-cast in the code.

public class VaryParam1 {

    static Map<VehicleType, Vehicle> list = new HashMap<>();

    static List<Car> carsList = new ArrayList<>();
    static List<TruckWithTrailer> trucksList = new ArrayList<>();

    public static void main(String[] args) {
        list.put(VehicleType.WITHOUT_TRAILER, new Car());
        list.put(VehicleType.WITH_TRAILER, new TruckWithTrailer());

        //violates LSP?
        ((Car)list.get(VehicleType.WITHOUT_TRAILER)).paint(1); //ok - but needed manual cast
        ((TruckWithTrailer)list.get(VehicleType.WITH_TRAILER)).paint(1, "1"); //ok - but needed manual cast

        carsList.add(new Car());
        trucksList.add(new TruckWithTrailer());

        //Does not violate LSP
        carsList.get(0).paint(1);
        trucksList.get(0).paint(1, "1");
    }
}

enum VehicleType {
    WITHOUT_TRAILER,
    WITH_TRAILER;
}

interface Vehicle{
    //definition of all common methods
    void drive();
    void stop();
}

class Car implements Vehicle {

    public void paint(int vehicleColor) {
        System.out.println(vehicleColor);
    }

    @Override
    public void drive() {}

    @Override
    public void stop() {}
}

class TruckWithTrailer implements Vehicle {

    public void paint(int vehicleColor, String trailerColor) {
        System.out.println(vehicleColor + trailerColor);
    }

    @Override
    public void drive() {}

    @Override
    public void stop() {}
}

In second option I have moved methods one level up to the interface, but now I need to implement behavior with UnsupportedOpException. This looks like code smell. In code, I don't have to do manual casting, but I also have possibility to call methods that will produce exception in run time - no compile time checking. This is not that big problem - only this methods with exception that look like code smell. Is this way of implementation best practice?

public class VaryParam2 {

    static Map<VehicleType, Vehicle> list = new HashMap<>();

    public static void main(String[] args) {
        list.put(VehicleType.WITHOUT_TRAILER, new Car());
        list.put(VehicleType.WITH_TRAILER, new TruckWithTrailer());

        list.get(VehicleType.WITHOUT_TRAILER).paint(1); //works
        list.get(VehicleType.WITH_TRAILER).paint(1, "1"); //works

        list.get(VehicleType.WITHOUT_TRAILER).paint(1, "1"); //ok - exception - passing trailer when no trailer - no compile time check!
        list.get(VehicleType.WITH_TRAILER).paint(1); //ok - exception - calling trailer without trailer args - no compile time check!
    }
}

enum VehicleType {
    WITHOUT_TRAILER,
    WITH_TRAILER;
}

interface Vehicle{
    void paint(int vehicleColor);
    void paint(int vehicleColor, String trailerColor);    //code smell - not valid for all vehicles??
}

class Car implements Vehicle {

    @Override
    public void paint(int vehicleColor) {
        System.out.println(vehicleColor);
    }

    @Override
    public void paint(int vehicleColor, String trailerColor) {    //code smell ??
        throw new UnsupportedOperationException("Car has no trailer");
    }
}

class TruckWithTrailer implements Vehicle {

    @Override
    public void paint(int vehicleColor) {  //code smell ??
        throw new UnsupportedOperationException("What to do with the trailer?");
    }

    @Override
    public void paint(int vehicleColor, String trailerColor) {
        System.out.println(vehicleColor + trailerColor);
    }
}

Here I used generics in order to have common method in interface, and parameter type is decided in each class implementation. Problem here is that I have unchecked calls to paint. This is more-less similar to problem of direct casting in option 1. Bur here I also have possibility to call methods that I should not be able to!

public class VaryParam3 {

    static Map<VehicleType, Vehicle> list = new HashMap<>();


    public static void main(String[] args) {
        list.put(VehicleType.WITHOUT_TRAILER, new Car());
        list.put(VehicleType.WITH_TRAILER, new TruckWithTrailer());

        list.get(VehicleType.WITHOUT_TRAILER).paint(new VehicleParam());    //works but unchecked call
        list.get(VehicleType.WITH_TRAILER).paint(new TruckWithTrailerParam());    //works but unchecked call

        list.get(VehicleType.WITHOUT_TRAILER).paint(new TruckWithTrailerParam()); //works but should not!
        list.get(VehicleType.WITH_TRAILER).paint(new VehicleParam());   //ClassCastException in runtime - ok but no compile time check
    }
}

enum VehicleType {
    WITHOUT_TRAILER,
    WITH_TRAILER;
}

class VehicleParam {
    int vehicleColor;
}

class TruckWithTrailerParam extends VehicleParam {
    String trailerColor;
}

interface Vehicle<T extends VehicleParam>{
    void paint(T param);
}

class Car implements Vehicle<VehicleParam> {

    @Override
    public void paint(VehicleParam param) {
        System.out.println(param.vehicleColor);
    }
}

class TruckWithTrailer implements Vehicle<TruckWithTrailerParam> {

    @Override
    public void paint(TruckWithTrailerParam param) {
        System.out.println(param.vehicleColor + param.trailerColor);
    }
}

So question is - which of this 3 options is the best one (or if there is some other option I have not found)? In terms of further maintenance, changing etc.

UPDATE

I updated the question and now I have paint method that can be called only after object is constructed.

So far this looks like the best option as it is suggested in the post below:

public class VaryParam4 {

    static Map<VehicleType, Vehicle> list = new HashMap<>();

    public static void main(String[] args) {
        list.put(VehicleType.WITHOUT_TRAILER, new Car());
        list.put(VehicleType.WITH_TRAILER, new TruckWithTrailer());

        list.get(VehicleType.WITHOUT_TRAILER).paint(new PaintConfigObject());    //works but can pass trailerColor (even if null) that is not needed
        list.get(VehicleType.WITH_TRAILER).paint(new PaintConfigObject());    //works
    }
}

enum VehicleType {
    WITHOUT_TRAILER,
    WITH_TRAILER;
}

class PaintConfigObject {
    int vehicleColor;
    String trailerColor;
}

interface Vehicle{
    void paint(PaintConfigObject param);
}

class Car implements Vehicle {

    @Override
    public void paint(PaintConfigObject param) {
        //param.trailerColor will never be used here but it's passed in param
        System.out.println(param.vehicleColor);
    }
}

class TruckWithTrailer implements Vehicle {

    @Override
    public void paint(PaintConfigObject param) {
        System.out.println(param.vehicleColor + param.trailerColor);
    }
}
12
  • 1
    Why is the number of doors relevant to driving a vehicle? Surely this is something determined at construction time? Feb 18, 2017 at 15:09
  • I will update example with paint() method where car has paint(vehiclecolor) and truck has pain(vehiclecolor, trailercolor). Colors are determined in runtime, after vehicles are already constructed. Feb 18, 2017 at 15:16
  • With your first example, you imply that you already know the type of the Vehicle, based on the enum value you pass. Is that right? Feb 18, 2017 at 15:26
  • Yes. actually the use case for current paint method is that somebody will give me id of vehicle and paints (either vehicle paint or vehicle and trailer paint). Based on this I know when I select vehicle from the map, it is either with or without trailer. Feb 18, 2017 at 15:29
  • @bojanv55 Take a look at my updated answer. I believe it covers all aspects of your question now. Do let me know if you have any further clarifications or if you see any issues with following that approach now? Feb 18, 2017 at 15:30

2 Answers 2

10

A better option would be to get rid of the overloaded versions of the drive method and pass whatever information is required by the subclasses in the constructor instead :

interface Vehicle{
    void drive();
}

class Car implements Vehicle {
    private int numberOfDoors;

    public Car(int numberOfDoors) {
         this.numberOfDoors = numberOfDoors;
     }

    public void drive() {
        System.out.println(numberOfDoors);
    }
}


class TruckWithTrailer implements Vehicle {
    private int numberOfDoors;
    private int numberOfTrailers;

    public TruckWithTrailer(int numberOfDoors,numberOfTrailers) {
          this.numberOfDoors = numberOfDoors;
          this.numberOfTrailers = numberOfTrailers;
    }

    @Override
    public void drive() {
        System.out.println(numberOfDoors + numberOfTrailers);
    }
}

Addressing your comment regarding the paint being decided at runtime, you can add a paint method to vehicle that takes variable arguments :

interface Vehicle{
    void drive();
    void paint(String ...colors);
}

As discussed in the comments, if the number of arguments to be used in the paint method varies for different vehicle types, define a class called PaintSpecification that contains attributes such as vehcileColor, trailerColor and change the paint method to have an argument of type PaintSpecification instead.

interface Vehicle{
    void drive();
    void paint(PaintSpecification spec);
}

The advantage of all the above approaches is that all Vehicle implementations adhere to a single contract allowing you to perform operations such as adding all your Vehicle instances to a List and calling the paint method on them one by one regardless of their type.

32
  • 2
    @bojanv55 Then you don't create the object till you have the required params? Feb 18, 2017 at 15:11
  • 1
    @bojanv55 See edit. I hope you won't add a new requirement now . (You kind of already answered your own question with the title of your question) :) Feb 18, 2017 at 15:22
  • 1
    @bojanv55 I am sorry to say this but if you don't adhere to a fixed contract, the interface is a bit useless since there is no real Polymorphism left in your code. Feb 18, 2017 at 15:32
  • 1
    One option could perhaps to have something like paint(PaintSpecification spec) where the specification is a configuration object that can cover all cases. The Vehicule could then only use what it understands from the specification. The one that constructs the specification needs to know the type of vehicule though.
    – plalx
    Feb 18, 2017 at 15:43
  • 2
    @bojanv55 In this case use 2 lists for Car and Truck and implement paint on both of them, not on Vehicule.
    – plalx
    Feb 18, 2017 at 16:06
2

but I have to do manual type-cast in the code.

It's because you lost the type information that you obviously need.

Your client code depends on concrete type information, because your paint method depends on concrete types.

If your client code should not be aware of the concrete Vehicle types, the Vehicle interface should be designed in a way that does not need concrete type information. E.g.

public void paint();

This would also mean that each Vehicle instance must have all information that it needs to paint itself. You could give the implementations color properties.

public class Car implements Vehicle {

  private int color = 0; // Default color

  public void paint() {
    System.out.println(color);
  }

  public void setColor(int color){
     // maybe some validation first
     this.color = color;
  }
}

or pass them to the paint method:

 public void paint(Color color)

If you need to pass even more properties you can create a PaintContext class and pass it to the paint method.

What else can you do?

If you want to keep your code as it is you must recreate the type infromation in some way.

I see the following solutions:

  • instanceof checks with downcast (you already tried that)
  • Adapter-Pattern
  • Visitor-Pattern

Adapter-Pattern

interface Vehicle {
    public <T extends Vehicle> T getAdapter(Class<T> adapterClass);
}

class Car implements Vehicle {

    @Override
    public <T extends Vehicle> T getAdapter(Class<T> adapterClass) {
        if(adapterClass.isInstance(this)){
            return adapterClass.cast(this);
        }
        return null;
    }
}

Your client code will then look like this:

Vehicle vehicle = ...;

Car car = vehicle.getAdapter(Car.class);
if(car != null){
    // the vehicle can be adapted to a car
    car.paint(1);
}

Pros of the Adapter-Pattern

  • You move the instanceof checks from the client code into the adapter. Thus the client code will be more refactoring-safe. E.g. imagine the following client code:

      if(vehicle instanceof Car){
         // ...
      } else if(vehicle instanceof TruckWithTrailer){
         // ...
      }
    

    Think about what will happen if you refactor your code to TruckWithTrailer extends Car

  • The adapter must not return itself. The concrete Vehicle might instantiate another object that let it look like the adapter type.

      public <T extends Vehicle> T getAdapter(Class<T> adapterClass) {
          if(Car.class.isAssignableFrom(adapterClass)){
              return new CarAdapter(this)
          }
          return null;
      }
    

Cons of the Adapter-Pattern

  • The cyclomatic complexity of client code increases when you add more and more implementations of Vehicle (a lot of if-else statements).

Visitor-Pattern

interface Vehicle {
    public void accept(VehicleVisitor vehicleVisitor);
}

interface VehicleVisitor {
    public void visit(Car car);
    public void visit(TruckWithTrailer truckWithTrailer);
}

The implementations of car will then decide which method of the VihicleVisitor should be invoked.

class Car implements Vehicle {

    public void paint(int vehicleColor) {
        System.out.println(vehicleColor);
    }

    @Override
    public void accept(VehicleVisitor vehicleVisitor) {
        vehicleVisitor.visit(this);
    }
}

Your client code must then provide a VehicleVisitor

    Vehicle vehicle = ...;
    vehicle.accept(new VehicleVisitor() {

        public void visit(TruckWithTrailer truckWithTrailer) {
            truckWithTrailer.paint(1, "1");

        }

        public void visit(Car car) {
            car.paint(1);
        }
    });

Pros of the Visitor-Pattern

  • Separation of type specific logic in separate methods

Cons of the Visitor-Pattern

  • New types require the visitor interface to change and all implementations of the visitor must be changed as well.

PS: With more information about the context of your code there might be other solutions.

2
  • How do you pass parameters 1 and "1" to visitor pattern's VehicleVisitor, since those could always be variable? Then you are back to the source of the problem. Feb 19, 2017 at 11:49
  • @MarkoKraljevic I would either create an own class and pass them through constructor args or in case of an anonymous class use final vars. I would prefer creating an own class anyway, beause it makes the code better testable. I just used an anonymous class in my example to keep it easy and short.
    – René Link
    Feb 19, 2017 at 12:24

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