Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

So lets say I have this interface:

public interface IBox
{
   public void setSize(int size);
   public int getSize();
   public int getArea();
  //...and so on
}

And I have a class that implements it:

public class Rectangle implements IBox
{
   private int size;
   //Methods here
}

If I wanted to use the interface IBox, i can't actually create an instance of it, in the way:

public static void main(String args[])
{
    Ibox myBox=new Ibox();
}

right? So I'd actually have to do this:

public static void main(String args[])
{
    Rectangle myBox=new Rectangle();
}

If that's true, then the only purpose of interfaces is to make sure that the class which implements an interface has got the correct methods in it as described by an interface? Or is there any other use of interfaces?

share|improve this question
    
Remember, interfaces aren't specific to Java. All OOP languages have them in some form or another, though not always as explicitly defined as Java. –  Herms Feb 2 '09 at 21:19
    
Technically, all strongly-typed OOP languages have them in some form or another. Untyped, or duck typed, languages don't have a similar concept. –  Jared Feb 2 '09 at 21:24
    
@Jared Aren't you confusing strong typing with static typing, and "untyped" with dynamically typed? –  eljenso Feb 4 '09 at 10:47
    
Polymorphism can be accomplished via interfaces also. Check the last section of this page codenuggets.com/2014/06/20/java-interface –  Jeff Jul 1 at 4:32
add comment

15 Answers 15

up vote 64 down vote accepted

Interfaces are a way to make your code more flexible. What you do is this:

Ibox myBox=new Rectangle();

Then, later, if you decide you want to use a different kind of box (maybe there's another library, with a better kind of box), you switch your code to:

Ibox myBox=new OtherKindOfBox();

Once you get used to it, you'll find it's a great (actually essential) way to work.

Another reason is, for example, if you want to create a list of boxes and perform some operation on each one, but you want the list to contain different kinds of boxes. On each box you could do:

myBox.close()

(assuming IBox has a close() method) even though the actual class of myBox changes depending on which box you're at in the iteration.

share|improve this answer
21  
There is nothing in this answer that is exclusive to Java interfaces. The same applies equaly well to abstract classes, or even concrete ones. I would expect a good answer to mention the ability to implement multiple interfaces, and when/why that would be useful. –  Rogério Oct 13 '10 at 20:04
    
How did this get selected as the answer? It's a brief description of why polymorphism is useful, but as the poster above said, I would expect a better explanation of multiple interfaces and even more importantly when it is appropriate to use an interface vs an abstract class. –  trevorkavanaugh May 28 at 21:31
add comment

What makes interfaces useful is not the fact that "you can change your mind and use a different implementation later and only have to change the one place where the object is created". That's a non-issue.

The real point is already in the name: they define an interface that anyone at all can implement to use all code that operates on that interface. The best example is java.util.Collections which provides all kinds of useful methods that operate exclusively on interfaces, such as sort() or reverse() for List. The point here is that this code can now be used to sort or reverse any class that implements the List interfaces - not just ArrayList and LinkedList, but also classes that you write yourself, which may be implemented in a way the people who wrote java.util.Collections never imagined.

In the same way, you can write code that operates on well-known interfaces, or interfaces you define, and other people can use your code without having to ask you to support their classes.

Another common use of interfaces is for Callbacks. For example, java.swing.table.TableCellRenderer, which allows you to influence how a Swing table displays the data in a certain column. You implement that interface, pass an instance to the JTable, and at some point during the rendering of the table, your code will get called to do its stuff.

share|improve this answer
1  
That's a pretty good answer ,I like it when you gave examples from java package classes... –  dotNetSoldier Dec 1 '13 at 21:04
    
I liked you can write code that operates on well-known interfaces, or interfaces you define –  Manish Feb 8 at 5:24
add comment

One of the many uses I have read is where its difficult without multiple-inheritance-using-interfaces in Java :

class Animal
{
void walk() { } 
....
.... //other methods and finally
void chew() { } //concentrate on this
} 

Now, Imagine a case where:

class Reptile extends Animal 
{ 
//reptile specific code here
} //not a problem here

but,

class Bird extends Animal
{
...... //other Bird specific code
} //now Birds cannot chew so this would a problem in the sense Bird classes can also call chew() method which is unwanted

Better design would be:

class Animal
{
void walk() { } 
....
.... //other methods 
} 

Animal does not have the chew() method and instead is put in an interface as :

interface Chewable {
void chew();
}

and have Reptile class implement this and not Birds (since Birds cannot chew) :

class Reptile extends Animal implements Chewable { } 

and incase of Birds simply:

class Bird extends Animal { }
share|improve this answer
1  
good explanation +1 –  CHEBURASHKA Nov 23 '13 at 21:14
add comment

The purpose of interfaces is polymorphism, a.k.a. type substitution. For example, given the following method:

public void scale(IBox b, int i) {
   b.setSize(b.getSize() * i);
}

When calling the scale method, you can provide any value that is of a type that implements the IBox interface. In other words, if Rectangle and Square both implement IBox, you can provide either a Rectangle or a Square wherever an IBox is expected.

share|improve this answer
4  
Why is the purpose of interfaces polymorphism, if I can already achieve that in Java with subclassing and method overriding? –  eljenso Feb 4 '09 at 11:13
    
It's the same thing, except that interfaces must omit any implementation. Classes can therefore implement more than one interface. –  Apocalisp Feb 4 '09 at 14:25
    
I asked, because you could also say that the primary purpose of interfaces is abstraction (i.e. decoupling from implementation), and just like any Java type (be it declared as class or interface) they allow for polymorphism through inheritance. –  eljenso Feb 4 '09 at 14:49
2  
Hey, I never said Java had any kind of conceptual integrity. Type substitution is the purpose of all subtyping. Java happens to have more than one subtyping mechanism, none of which are particularly good. –  Apocalisp Feb 4 '09 at 17:55
    
I never said anything about conceptual integrity as well. But let's move on. If you can scale every IBox with your method, shouldn't it be an operation declared on IBox: IBox.scale(int)? –  eljenso Feb 4 '09 at 18:39
show 2 more comments

Interfaces allow statically typed languages to support polymorphism. An Object Oriented purist would insist that a language should provide inheritance, encapsulation, modularity and polymorphism in order to be a fully-featured Object Oriented language. In dynamically-typed - or duck typed - languages (like Smalltalk,) polymorphism is trivial; however, in statically typed languages (like Java or C#,) polymorphism is far from trivial (in fact, on the surface it seems to be at odds with the notion of strong typing.)

Let me demonstrate:

In a dynamically-typed (or duck typed) language (like Smalltalk), all variables are references to objects (nothing less and nothing more.) So, in Smalltalk, I can do this:

|anAnimal|    
anAnimal := Pig new.
anAnimal makeNoise.

anAnimal := Cow new.
anAnimal makeNoise.

That code:

  1. Declares a local variable called anAnimal (note that we DO NOT specify the TYPE of the variable - all variables are references to an object, no more and no less.)
  2. Creates a new instance of the class named "Pig"
  3. Assigns that new instance of Pig to the variable anAnimal.
  4. Sends the message makeNoise to the pig.
  5. Repeats the whole thing using a cow, but assigning it to the same exact variable as the Pig.

The same Java code would look something like this (making the assumption that Duck and Cow are subclasses of Animal:

Animal anAnimal = new Pig();
duck.makeNoise();

anAnimal = new Cow();
cow.makeNoise();

That's all well and good, until we introduce class Vegetable. Vegetables have some of the same behavior as Animal, but not all. For example, both Animal and Vegetable might be able to grow, but clearly vegetables don't make noise and animals cannot be harvested.

In Smalltalk, we can write this:

|aFarmObject|
aFarmObject := Cow new.
aFarmObject grow.
aFarmObject makeNoise.

aFarmObject := Corn new.
aFarmObject grow.
aFarmObject harvest.

This works perfectly well in Smalltalk because it is duck-typed (if it walks like a duck, and quacks like a duck - it is a duck.) In this case, when a message is sent to an object, a lookup is performed on the receiver's method list, and if a matching method is found, it is called. If not, some kind of NoSuchMethodError exception is thrown - but it's all done at runtime.

But in Java, a statically typed language, what type can we assign to our variable? Corn needs to inherit from Vegetable, to support grow, but cannot inherit from Animal, because it does not make noise. Cow needs to inherit from Animal to support makeNoise, but cannot inherit from Vegetable because it should not implement harvest. It looks like we need multiple inheritance - the ability to inherit from more than one class. But that turns out to be a pretty difficult language feature because of all the edge cases that pop up (what happens when more than one parallel superclass implement the same method?, etc.)

Along come interfaces...

If we make Animal and Vegetable classes, with each implementing Growable, we can declare that our Cow is Animal and our Corn is Vegetable. We can also declare that both Animal and Vegetable are Growable. That lets us write this to grow everything:

List<Growable> list = new ArrayList<Growable>();
list.add(new Cow());
list.add(new Corn());
list.add(new Pig());

for(Growable g : list) {
   g.grow();
}

And it lets us do this, to make animal noises:

List<Animal> list = new ArrayList<Animal>();
list.add(new Cow());
list.add(new Pig());
for(Animal a : list) {
  a.makeNoise();
}

The advantage to the duck-typed language is that you get really nice polymorphism: all a class has to do to provide behavior is provide the method. As long as everyone plays nice, and only sends messages that match defined methods, all is good. The downside is that the kind of error below isn't caught until runtime:

|aFarmObject|
aFarmObject := Corn new.
aFarmObject makeNoise. // No compiler error - not checked until runtime.

Statically-typed languages provide much better "programming by contract," because they will catch the two kinds of error below at compile-time:

// Compiler error: Corn cannot be cast to Animal.
Animal farmObject = new Corn();  
farmObject makeNoise();

--

// Compiler error: Animal doesn't have the harvest message.
Animal farmObject = new Cow();
farmObject.harvest();

So....to summarize:

  1. Interface implementation allows you to specify what kinds of things objects can do (interaction) and Class inheritance lets you specify how things should be done (implementation).

  2. Interfaces give us many of the benefits of "true" polymorphism, without sacrificing compiler type checking.

share|improve this answer
1  
This is the text of my answer to another question: stackoverflow.com/questions/379282/…. But, they're related answers. –  Jared Feb 2 '09 at 21:31
2  
So may I ask, how does a duck typed language distinguish between Animal.water() (which, the prudish farmer used to say that it takes a leak) and Plant.water() which he uses to water plants. Ambiguity is the enemy. Any amount of verbosity necessary to overcome ambiguity is acceptable IMO. –  Bill K Feb 2 '09 at 22:11
    
Yep..ambiguity is the name of the game with duck typed languages. When working professionally in a duck typed language, it's not uncommon to see members (methods and variables) with names that are 50-100 characters in length. –  Jared Feb 2 '09 at 22:17
1  
Another big downside of duck typed languages is the inability to do programmatic refactoring based on static analysis - try asking a Smalltalk image for the list of all callers of your printString method...you will get the list of all callers of ALL printString methods.... –  Jared Feb 2 '09 at 22:19
    
...because the caller of Automobile#printString cannot be programmatically differentiated from the caller of NearEarthOrbit#printString. –  Jared Feb 2 '09 at 22:20
show 3 more comments

Normally Interfaces define the interface you should use (as the name says it ;-) ). Sample


public void foo(List l) {
   ... do something
}

Now your function foo accepts ArrayLists, LinkedLists, ... not only one type.

The most important thing in Java is that you can implement multiple interfaces but you can only extend ONE class! Sample:


class Test extends Foo implements Comparable, Serializable, Formattable {
...
}
is possible but

class Test extends Foo, Bar, Buz {
...
}
is not!

Your code above could also be: IBox myBox = new Rectangle();. The important thing is now, that myBox ONLY contains the methods/fields from IBox and not the (possibly existing) other methods from Rectangle.

share|improve this answer
    
Is 'List' supposed to be an interface member? –  Click Upvote Feb 2 '09 at 21:16
    
List is an interface in the java collections library. –  rmeador Feb 2 '09 at 21:21
    
List is an interface in the standard Java library (java.sun.com/javase/6/docs/api/java/util/List.html). He's just using it to illustrate his point. –  Michael Myers Feb 2 '09 at 21:21
add comment

I think you understand everything Interfaces do, but you're not yet imagining the situations in which an Interface is useful.

If you're instantiating, using and releasing an object all within a narrow scope (for example, within one method call), an Interface doesn't really add anything. Like you noted, the concrete class is known.

Where Interfaces are useful is when an object needs to be created one place and returned to a caller that may not care about the implementation details. Let's change your IBox example to an Shape. Now we can have implementations of Shape such as Rectangle, Circle, Triangle, etc., The implementations of the getArea() and getSize() methods will be completely different for each concrete class.

Now you can use a factory with a variety of createShape(params) methods which will return an appropriate Shape depending on the params passed in. Obviously, the factory will know about what type of Shape is being created, but the caller won't have to care about whether it's a circle, or a square, or so on.

Now, imagine you have a variety of operations you have to perform on your shapes. Maybe you need to sort them by area, set them all to a new size, and then display them in a UI. The Shapes are all created by the factory and then can be passed to the Sorter, Sizer and Display classes very easily. If you need to add a hexagon class some time in the future, you don't have to change anything but the factory. Without the Interface, adding another shape becomes a very messy process.

share|improve this answer
add comment

you could do

Ibox myBox=new Rectangle();

that way you are using this object as Ibox and you dont care that its really Rectangle

share|improve this answer
add comment

Interfaces where a fetature added to java to allow multiple inheritance. The developers of Java though/realized that having multiple inheritance was a "dangerous" feature, that is why the came up with the idea of an interface.

multiple inheritance is dangerous because you might have a class like the following:


class Box{
    public int getSize(){
       return 0;
    }
    public int getArea(){
       return 1;
    }

}

class Triangle{
    public int getSize(){
       return 1;
    }
    public int getArea(){
       return 0;
    }

}

class FunckyFigure extends Box, Triable{
   // we do not implement the methods we will used the inherited ones
}

Which would be the method that should be called when we use


   FunckyFigure.GetArea(); 

All the problems are solved with interfaces, because you do know you can extend the interfaces and that they wont have classing methods... ofcourse the compiler is nice and tells you if you did not implemented a methods, but I like to think that is a side effect of a more interesting idea.

share|improve this answer
    
You might want to make a difference between multiple implementation inheritance and multiple interface inheritance in your answer, otherwise it gets confusing. –  eljenso Feb 4 '09 at 11:03
add comment

This is the reason why Factory Patterns and other creational patterns are so popular in Java. You are correct that without them Java doesn't provide an out of the box mechanism for easy abstraction of instantiation. Still, you get abstraction everywhere where you don't create an object in your method, which should be most of your code.

As an aside, I generally encourage people to not follow the "IRealname" mechanism for naming interfaces. That's a Windows/COM thing that puts one foot in the grave of Hungarian notation and really isn't necessary (Java is already strongly typed, and the whole point of having interfaces is to have them as largely indistinguishable from class types as possible).

share|improve this answer
1  
You are confusing strong typing with static typing. –  eljenso Feb 4 '09 at 11:08
add comment

Don't forget that at a later date you can take an existing class, and make it implement IBox, and it will then become available to all your box-aware code.

This becomes a bit clearer if interfaces are named -able. e.g.

public interface Saveable {
....

public interface Printable {
....

etc. (Naming schemes don't always work e.g. I'm not sure Boxable is appropriate here)

share|improve this answer
add comment

The purpose of interfaces is abstraction, or decoupling from implementation.

If you introduce an abstraction in your program, you don't care about the possible implementations. You are interested in what it can do and not how, and you use an interface to express this in Java.

share|improve this answer
    
The purpose of all structured programming is abstraction. Why would you say that the purpose of interfaces is abstraction, since I can achieve the exact same thing using generics and class composition? –  Apocalisp Feb 4 '09 at 18:08
    
If all structured programming is abstraction (your claim), then interfaces are abstractions in that abstraction. –  eljenso Feb 4 '09 at 18:15
add comment

If you have CardboardBox and HtmlBox (both of which implement IBox), you can pass both of them to any method that accepts a IBox. Even though they are both very different and not completely interchangable, methods that don't care about "open" or "resize" can still use your classes (perhaps because they care about how many pixels are needed to display something on a screen).

share|improve this answer
add comment

A great example of how interfaces are used is in the Collections framework. If you write a function that takes a List, then it doesn't matter if the user passes in a Vector or an ArrayList or a HashList or whatever. And you can pass that List to any function requiring a Collection or Iterable interface too.

This makes functions like Collections.sort(List list) possible, regardless of how the List is implemented.

share|improve this answer
add comment

Interfaces

There are a number of situations in software engineering when it is important for disparate groups of programmers to agree to a "contract" that spells out how their software interacts. Each group should be able to write their code without any knowledge of how the other group's code is written. Generally speaking, interfaces are such contracts.

For example, imagine a futuristic society where computer-controlled robotic cars transport passengers through city streets without a human operator. Automobile manufacturers write software (Java, of course) that operates the automobile—stop, start, accelerate, turn left, and so forth. Another industrial group, electronic guidance instrument manufacturers, make computer systems that receive GPS (Global Positioning System) position data and wireless transmission of traffic conditions and use that information to drive the car.

The auto manufacturers must publish an industry-standard interface that spells out in detail what methods can be invoked to make the car move (any car, from any manufacturer). The guidance manufacturers can then write software that invokes the methods described in the interface to command the car. Neither industrial group needs to know how the other group's software is implemented. In fact, each group considers its software highly proprietary and reserves the right to modify it at any time, as long as it continues to adhere to the published interface.

share|improve this answer
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.