Related
This is one of a number of things that's been bugging me for a while and for which quibbling over the correct interpretation of this has been leading me in a number of attempted coding projects to more fussing around with design, than it has with making steady forward progress, because I want to make sure I've gotten it "right".
In this case, I have a question about the "interface segregation principle" (ISP) of the five "SOLID" principles of basic object oriented design. Its "canonical" statement is this:
Clients should not be forced to depend on methods they do not use.
However, the question here is, is what is the "client" - because this leads to very different interpretations, and also leads to a seeming dilemma when applied in practice, which is what I'd like to understand if first actually is one, and second, how to best solve it.
One interpretation of this is that it is a "single responsibility principle" for interfaces instead of just classes: i.e. if you have an interface IMessageReceiver, it better not include a Send method. Another possible interpretation is that it means that the implementer of an interface should not be required to implement empty methods, while a third interpretation is that the caller should not be able to see any more methods than it actually needs. And the thing is, I can see merit in all three of these interpretations, yet when you apply them all, it seems that in any suitably large project, highly counterintuitive and seemingly problematic things result. In particular, it's that third one that seems to be the rub.
For one, if something gets used in enough places, it is particularly that last one - the "caller" one - which generally tends to "bite" in that it results naturally in your interfaces being atomized down to single methods only. For example, consider a simple interface to a backend storage or database, which may have a load, save, and update method. Some callers of that, though, may not want to save anything. They may just want to peek at the data. Hence to avoid violating the caller interpretation, we must split off the load method. Add a few more use cases and now it's atomized into a IDataLoader, IDataSaver, and IDataUpdater which all have 1 method each.
And I can't help but feel this almost seems like an anti-pattern, particularly if it happens with enough objects owing to them being used in a suitably wide variety of places. Is it? Or am I misinterpreting something here? After all, nobody makes a generic container class (like the "list", "map", etc. things in a lot of languages) with single-method interfaces to be piecemealed out to whatever it gets passed to.
One interpretation of this is that it is a "single responsibility principle" for interfaces...
Robert Martin has addressed this question directly, and his answer is that ISP separates things that SRP does not, thus the two principles differ.
Another possible interpretation is that it means that the implementer of an interface...
We also see in his answer that the client is the caller of the interface, not the implementer. I've touched on that in another answer regarding default methods. The implementer should be implementing exactly as many methods as the caller needs: no more, no less.
a third interpretation is that the caller should not be able to see any more methods than it actually needs.
This is correct, and it is also correct to note that a single-method interface cannot violate the ISP. While this may result in a "lowest-common-denominator" approach where every interface is a single method, they should be highly composable in that case; i.e. implementations can select several interfaces to implement, making them highly customizable to client needs.
The database example of separating read from write is so common that is has its own pattern: CQRS. There are arguments both ways. Likewise, generic collections may choose to avoid creating too many interfaces, which is a design counter to the ISP.
I would suggest that in most applications (particularly service applications as opposed to libraries) if rigorously applying the ISP results exclusively in single-method interfaces, it indicates the clients are not cohesive and not complex. If this is an accurate description of the clients, then single-method interfaces are probably appropriate. You may also consider a different architecture such as a separate service for each client if their requirements have so little overlap.
When somebody wants to develop a feature, then he/she tries to map real world object to unit where code can be put. It is done to imitate behavior.
This unit can be called class. And this class has to have just one feature. It is place where we use SRP.
E.g., if programmer maps real world object person to class Person.
Then this class Person does not have to have methods/behavior of other objects. E.g. the Person class does not have to have methods of Car class. This is what SRP about.
Clients should not be forced to depend on methods they do not use.
We've created a Person class so far. Now we want to log all speech of person. So we need to log it. How? We can use interface ILogging with one method Log. Why does this interface have just one method?
Because clients will only have to know about the methods that are of interest to them.
Here Person class is client of interface ILogging.
SRP means that a class is responsible just for one feature. E.g. if you want to edit logging in Person class, then it is violation of SRP.
public class Person
{
public string FirstName { get; set; }
public void Say(string message)
{
File.WriteAllText("path", message); // violation of SRP
}
}
How can we avoid violation of SRP? We should create an abstraction of logging:
public interface ILogging
{
void Write(string address, string content);
}
and use it:
public class PersonWithSRP
{
private readonly ILogging _logging;
public string FirstName { get; set; }
public PersonWithSRP(ILogging logging)
{
_logging = logging;
}
public void Say(string message)
{
_logging.Write("path", message);
}
}
public class Logging : ILogging
{
public void Write(string address, string content)
{
File.WriteAllText(address, content);
}
}
By extracting logic of logging in separate class, we moved logic of logging in special, single class or place where we can edit only logic of logging on one place.
What is about ISP?
nobody makes a generic container class
yeah, you are right. Interface should have only necessary methods which client class needs.
An example with HDD that uses ISP:
public interface IReadable
{
string Read();
}
public interface IWriteable
{
void Write();
}
public class HDD : IReadable, IWriteable
{
public string Read() { }
public void Write() { }
}
By creating one interface for Read() and Write() methods, it would obligate class to implement both methods in class. But some classes only want to read data, others want to write data, and some to do both. So in this case it is better to create separate interfaces.
So let's look another example with CardReader. CardReader just reads data, it does not write data. So, if we inherit one interface with Read() and Write() methods, then we would violate ISP principle. An example of violation of ISP:
public interface IWriteReadable
{
string Read();
void Write();
}
public class CardReader : IWriteReadable
{
// this is a necessary method
public string Read() { }
// here we are obligating to implement unnecessary method of interface
public void Write() { }
}
So by applying ISP, you only puts methods in interface that are necessary for the client class. If your class/client just wants to read data, then you need to use IReadable interface, not IReadableWriteable.
I understand the advantages of composition over inheritance. Among others, it makes unit testing (and mocking) easier, your code is not coupled with base class etc. I've also watched nice talks about testable, clean code, which successfully stick the ideas in my mind through excellent pictures like this:
I tried posts that explain the meaning of abstract classes, but it's still not clear to me: Since I can achieve polymorphic behaviour through interfaces, and I can delegate tasks to my dependencies through composition, where should I use abstract classes, or even base concrete classes?
One advantage is convenience. An abstract class can provide default implementations. You can override only the methods you want, without needing to implement all the others at all.
For example, Java's MouseListener interface has five methods; and the abstract class MouseAdapter provides default implementations of those. An implementation based on extending the abstract class MouseAdapter needs to implement only the desired methods.
Another advantage is that superclass method calls can call subclass methods. For example, the C++ non-virtual idiom uses this to allow a superclass method to enforce the method contract before and after delegating to a subclass method.
If you did away with abstract classes, how would you implement part of an interface in a reusable way? You would create an interface and some helper class that did the implementation that you could delegate to, but this helper class would not implement the interface and so it would not be clear that it is related to the interface. You would have decoupled too much.
Alternately, you would have people fully implementing the interface so that other people would know it has a base implementation, but then they would have to do some hack to indicate that certain methods had to be overridden (e.g. throw an exception when they were called).
Abstract classes provide a clean way to provide an interface along with a partial implementation of the interface that is visible to the complier and other tools.
Abstract classes are still quite useful for cases in which it is desirable to share implementation, as opposed to interface (in the generic sense).
For example, consider the template method design pattern. This is an example of shared implementation. The bulk of an algorithm is implemented in an abstract base class, but certain pieces are supplied by subclasses. These subclasses need only extend their base class and implement the abstract template method(s) in them to get the job done.
Contrast this with the strategy pattern, where the entire algorithm is abstracted and implementations are injected wholesale into classes that require them using delegation/composition. This is an example of shared interface. Though the algorithms themselves may be totally different, they all implement the same basic operations.
Inheritance is still useful even you have used composition. IMHO, this explicitly apply for framework architecture.
Facade parent class
You can use facade class to wrap your composition over inheritance. Example will be:
public class Parent : IService
{
public Parent(IService1 s1, IService2 s2)
{
}
}
public class Child : Parent
{
public Child()
: base(Service1, Service2)
{
}
private static IService1 Service1
{
get
{
// return Service1
}
}
private static IService2 Service2
{
get
{
// return Service2
}
}
}
Source Syntax. This facade class, can be used as default functioning object, useful in framework-level object. Then if inherited again, you can extend the functionality for one method only, and leave the rest as is.
Extend third party library
Not all third party library use Dependency Injection. In order to extend the functionality, you often need to inherit it (example: System.Windows.Forms.Form). Especially in custom Framework level (enterprise), it is better to inherit it. If the framework change, other method than your overridden will be changed as well, rather than use composition. It may be double-edged though.
I already know the fundamentals of the implements and interfaces. I don't understand when to use an interface. What is the requirement to have an interface?
Example:
/// Interface demo
Interface IDemo
{
// Function prototype
public void Show();
}
// First class using the interface
Class MyClass1 : IDemo
{
public void Show()
{
// Function body comes here
Response.Write("I'm in MyClass");
}
}
// Second class using the interface
Class MyClass2 : IDemo
{
public void Show()
{
// Function body comes here
Response.Write("I'm in MyClass2");
Response.Write("So, what?");
}
}
These two classes have the same function name with different bodies. This can also be achieved without interfaces. What's the purpose of having the method reference? When I extend a superclass, at least I get the superclass's properties and methods.
Please give me a clear explaining and a real world scenario for me to understand well.
First they provide a contract for users, so a user doesn't need to know what underlying implementation is used but rather just the contract. This creates loose coupling in case underlying implementation changes.
Real World Examples
In this manner we can use certain patterns like strategy and command pattern: Using a strategy pattern and a command pattern
Real World Example of the Strategy Pattern
Real world example of application of the command pattern
Difference Between Abstract Class and Interface
Much of this can be said about abstract classes, see here for the differences: Interface vs Abstract Class (general OO)
You need an interface if you need multiple inheritance.
Suppose you have a class that needs to be Comparable and also a List. Since you can only inherit one class in some languages, in order to prove to the compiler that it has both Comparable's compareTo() method as well as List's add() method, you need interfaces. That's the very simplest explanation but I'm sure others will give more reasons.
Also interfaces make multiple inheritance easier in some cases since there is nothing going on "in the background." they only specify what an object needs to offer in terms of methods.
Two reasons to use interfaces:
You need multiple inheritance, and your programming language does not support it (e.g., Java, C#). In this case, most (all but one) of the base classes you inherit in your derived class will need to be defined as interface classes.
You expect to use multiple implementations of a certain class. In this cases, the class can be an abstract class or an interface. Your client provides a specific concrete implementation of this class, which can vary from client to client. The interface (or abstract class) requires the same behavior (methods) for each implementation.
I believe one of the most inportant reasons for using interfaces is type matching. Your programe can be much more flixible by programming to an interface instead of an implementation.
You could take a look at different design patterns (I suggest you start with Strategy Pattern, http://en.wikipedia.org/wiki/Strategy_pattern#Example) I reckon you will instantly understand how program to interfaces makes your code more flexible.
Hope this can help.
Much of the power comes from the fact that an object can be referenced by a variable of the interface type. This is subtly vary powerful.
private foo()
{
IDemo demoOne = new MyClass1();
IDemo demoTwo = new MyClass2();
}
This can become vary powerful because you can encapsulate different behaviors. For example:
private foo(bool option)
{
IDemo demo = option ? new MyClass1() : new MyClass2();
}
private bar (IDemo demo)
{
demo.Show();
}
Now bar can use the IDemo object without having to know which concrete implementation of IDemo is passed in. The decision about which implementation to use is encapsulated in the foo method. This might not seem like a big deal in such a simple example. If you look at the links posted in tigger's answer, you will see where this can become very useful.
One case where this is particularly useful is with unit testing. You can have a business logic class that takes an interface to a data layer object. When the application runs, the business logic class is passed an instance of the real data layer object. When the class is unit tested, it is passed an instance of a object that returns test data. This allows the unit test to run with predictable data inputs. This is known at Dependency Injection.
Another useful case is when you want to interact with framework or third-party code. Let's say you want to implement a custom collection. If your class implements the IEnumerable interface, you can iterate through the items in the collection in a foreach loop. The framework doesn't need to know how your class stores the items or what is in the items, but if it knows that you implemented IEnumerable, it can allow you to use a foreach loop.
What exactly is the difference between an interface and an abstract class?
Interfaces
An interface is a contract: The person writing the interface says, "hey, I accept things looking that way", and the person using the interface says "OK, the class I write looks that way".
An interface is an empty shell. There are only the signatures of the methods, which implies that the methods do not have a body. The interface can't do anything. It's just a pattern.
For example (pseudo code):
// I say all motor vehicles should look like this:
interface MotorVehicle
{
void run();
int getFuel();
}
// My team mate complies and writes vehicle looking that way
class Car implements MotorVehicle
{
int fuel;
void run()
{
print("Wrroooooooom");
}
int getFuel()
{
return this.fuel;
}
}
Implementing an interface consumes very little CPU, because it's not a class, just a bunch of names, and therefore there isn't any expensive look-up to do. It's great when it matters, such as in embedded devices.
Abstract classes
Abstract classes, unlike interfaces, are classes. They are more expensive to use, because there is a look-up to do when you inherit from them.
Abstract classes look a lot like interfaces, but they have something more: You can define a behavior for them. It's more about a person saying, "these classes should look like that, and they have that in common, so fill in the blanks!".
For example:
// I say all motor vehicles should look like this:
abstract class MotorVehicle
{
int fuel;
// They ALL have fuel, so lets implement this for everybody.
int getFuel()
{
return this.fuel;
}
// That can be very different, force them to provide their
// own implementation.
abstract void run();
}
// My teammate complies and writes vehicle looking that way
class Car extends MotorVehicle
{
void run()
{
print("Wrroooooooom");
}
}
Implementation
While abstract classes and interfaces are supposed to be different concepts, the implementations make that statement sometimes untrue. Sometimes, they are not even what you think they are.
In Java, this rule is strongly enforced, while in PHP, interfaces are abstract classes with no method declared.
In Python, abstract classes are more a programming trick you can get from the ABC module and is actually using metaclasses, and therefore classes. And interfaces are more related to duck typing in this language and it's a mix between conventions and special methods that call descriptors (the __method__ methods).
As usual with programming, there is theory, practice, and practice in another language :-)
The key technical differences between an abstract class and an interface are:
Abstract classes can have constants, members, method stubs (methods without a body) and defined methods, whereas interfaces can only have constants and methods stubs.
Methods and members of an abstract class can be defined with any visibility, whereas all methods of an interface must be defined as public (they are defined public by default).
When inheriting an abstract class, a concrete child class must define the abstract methods, whereas an abstract class can extend another abstract class and abstract methods from the parent class don't have to be defined.
Similarly, an interface extending another interface is not responsible for implementing methods from the parent interface. This is because interfaces cannot define any implementation.
A child class can only extend a single class (abstract or concrete), whereas an interface can extend or a class can implement multiple other interfaces.
A child class can define abstract methods with the same or less restrictive visibility, whereas a class implementing an interface must define the methods with the exact same visibility (public).
An Interface contains only the definition / signature of functionality, and if we have some common functionality as well as common signatures, then we need to use an abstract class. By using an abstract class, we can provide behavior as well as functionality both in the same time. Another developer inheriting abstract class can use this functionality easily, as they would only need to fill in the blanks.
Taken from:
http://www.dotnetbull.com/2011/11/difference-between-abstract-class-and.html
http://www.dotnetbull.com/2011/11/what-is-abstract-class-in-c-net.html
http://www.dotnetbull.com/2011/11/what-is-interface-in-c-net.html
An explanation can be found here: http://www.developer.com/lang/php/article.php/3604111/PHP-5-OOP-Interfaces-Abstract-Classes-and-the-Adapter-Pattern.htm
An abstract class is a class that is
only partially implemented by the
programmer. It may contain one or more
abstract methods. An abstract method
is simply a function definition that
serves to tell the programmer that the
method must be implemented in a child
class.
An interface is similar to an abstract
class; indeed interfaces occupy the
same namespace as classes and abstract
classes. For that reason, you cannot
define an interface with the same name
as a class. An interface is a fully
abstract class; none of its methods
are implemented and instead of a class
sub-classing from it, it is said to
implement that interface.
Anyway I find this explanation of interfaces somewhat confusing. A more common definition is: An interface defines a contract that implementing classes must fulfill. An interface definition consists of signatures of public members, without any implementing code.
I don't want to highlight the differences, which have been already said in many answers ( regarding public static final modifiers for variables in interface & support for protected, private methods in abstract classes)
In simple terms, I would like to say:
interface: To implement a contract by multiple unrelated objects
abstract class: To implement the same or different behaviour among multiple related objects
From the Oracle documentation
Consider using abstract classes if :
You want to share code among several closely related classes.
You expect that classes that extend your abstract class have many common methods or fields, or require access modifiers other than public (such as protected and private).
You want to declare non-static or non-final fields.
Consider using interfaces if :
You expect that unrelated classes would implement your interface. For example,many unrelated objects can implement Serializable interface.
You want to specify the behaviour of a particular data type, but not concerned about who implements its behaviour.
You want to take advantage of multiple inheritance of type.
abstract class establishes "is a" relation with concrete classes. interface provides "has a" capability for classes.
If you are looking for Java as programming language, here are a few more updates:
Java 8 has reduced the gap between interface and abstract classes to some extent by providing a default method feature. An interface does not have an implementation for a method is no longer valid now.
Refer to this documentation page for more details.
Have a look at this SE question for code examples to understand better.
How should I have explained the difference between an Interface and an Abstract class?
Some important differences:
In the form of a table:
As stated by Joe from javapapers:
1.Main difference is methods of a Java interface are implicitly abstract and cannot have implementations. A Java abstract class can
have instance methods that implements a default behavior.
2.Variables declared in a Java interface is by default final. An abstract class may contain non-final variables.
3.Members of a Java interface are public by default. A Java abstract class can have the usual flavors of class members like private,
protected, etc..
4.Java interface should be implemented using keyword “implements”; A Java abstract class should be extended using keyword “extends”.
5.An interface can extend another Java interface only, an abstract class can extend another Java class and implement multiple Java
interfaces.
6.A Java class can implement multiple interfaces but it can extend only one abstract class.
7.Interface is absolutely abstract and cannot be instantiated; A Java abstract class also cannot be instantiated, but can be invoked if a
main() exists.
8.In comparison with java abstract classes, java interfaces are slow as it requires extra indirection.
The main point is that:
Abstract is object oriented. It offers the basic data an 'object' should have and/or functions it should be able to do. It is concerned with the object's basic characteristics: what it has and what it can do. Hence objects which inherit from the same abstract class share the basic characteristics (generalization).
Interface is functionality oriented. It defines functionalities an object should have. Regardless what object it is, as long as it can do these functionalities, which are defined in the interface, it's fine. It ignores everything else. An object/class can contain several (groups of) functionalities; hence it is possible for a class to implement multiple interfaces.
When you want to provide polymorphic behaviour in an inheritance hierarchy, use abstract classes.
When you want polymorphic behaviour for classes which are completely unrelated, use an interface.
I am constructing a building of 300 floors
The building's blueprint interface
For example, Servlet(I)
Building constructed up to 200 floors - partially completed---abstract
Partial implementation, for example, generic and HTTP servlet
Building construction completed-concrete
Full implementation, for example, own servlet
Interface
We don't know anything about implementation, just requirements. We can
go for an interface.
Every method is public and abstract by default
It is a 100% pure abstract class
If we declare public we cannot declare private and protected
If we declare abstract we cannot declare final, static, synchronized, strictfp and native
Every interface has public, static and final
Serialization and transient is not applicable, because we can't create an instance for in interface
Non-volatile because it is final
Every variable is static
When we declare a variable inside an interface we need to initialize variables while declaring
Instance and static block not allowed
Abstract
Partial implementation
It has an abstract method. An addition, it uses concrete
No restriction for abstract class method modifiers
No restriction for abstract class variable modifiers
We cannot declare other modifiers except abstract
No restriction to initialize variables
Taken from DurgaJobs Website
Let's work on this question again:
The first thing to let you know is that 1/1 and 1*1 results in the same, but it does not mean that multiplication and division are same. Obviously, they hold some good relationship, but mind you both are different.
I will point out main differences, and the rest have already been explained:
Abstract classes are useful for modeling a class hierarchy. At first glance of any requirement, we are partially clear on what exactly is to be built, but we know what to build. And so your abstract classes are your base classes.
Interfaces are useful for letting other hierarchy or classes to know that what I am capable of doing. And when you say I am capable of something, you must have that capacity. Interfaces will mark it as compulsory for a class to implement the same functionalities.
If you have some common methods that can be used by multiple classes go for abstract classes.
Else if you want the classes to follow some definite blueprint go for interfaces.
Following examples demonstrate this.
Abstract class in Java:
abstract class Animals
{
// They all love to eat. So let's implement them for everybody
void eat()
{
System.out.println("Eating...");
}
// The make different sounds. They will provide their own implementation.
abstract void sound();
}
class Dog extends Animals
{
void sound()
{
System.out.println("Woof Woof");
}
}
class Cat extends Animals
{
void sound()
{
System.out.println("Meoww");
}
}
Following is an implementation of interface in Java:
interface Shape
{
void display();
double area();
}
class Rectangle implements Shape
{
int length, width;
Rectangle(int length, int width)
{
this.length = length;
this.width = width;
}
#Override
public void display()
{
System.out.println("****\n* *\n* *\n****");
}
#Override
public double area()
{
return (double)(length*width);
}
}
class Circle implements Shape
{
double pi = 3.14;
int radius;
Circle(int radius)
{
this.radius = radius;
}
#Override
public void display()
{
System.out.println("O"); // :P
}
#Override
public double area()
{
return (double)((pi*radius*radius)/2);
}
}
Some Important Key points in a nutshell:
The variables declared in Java interface are by default final. Abstract classes can have non-final variables.
The variables declared in Java interface are by default static. Abstract classes can have non-static variables.
Members of a Java interface are public by default. A Java abstract class can have the usual flavors of class members like private, protected, etc..
It's pretty simple actually.
You can think of an interface as a class which is only allowed to have abstract methods and nothing else.
So an interface can only "declare" and not define the behavior you want the class to have.
An abstract class allows you to do both declare (using abstract methods) as well as define (using full method implementations) the behavior you want the class to have.
And a regular class only allows you to define, not declare, the behavior/actions you want the class to have.
One last thing,
In Java, you can implement multiple interfaces, but you can only extend one (Abstract Class or Class)...
This means inheritance of defined behavior is restricted to only allow one per class... ie if you wanted a class that encapsulated behavior from Classes A,B&C you would need to do the following: Class A extends B, Class C extends A .. its a bit of a round about way to have multiple inheritance...
Interfaces on the other hand, you could simply do: interface C implements A, B
So in effect Java supports multiple inheritance only in "declared behavior" ie interfaces, and only single inheritance with defined behavior.. unless you do the round about way I described...
Hopefully that makes sense.
The comparison of interface vs. abstract class is wrong. There should be two other comparisons instead: 1) interface vs. class and 2) abstract vs. final class.
Interface vs Class
Interface is a contract between two objects. E.g., I'm a Postman and you're a Package to deliver. I expect you to know your delivery address. When someone gives me a Package, it has to know its delivery address:
interface Package {
String address();
}
Class is a group of objects that obey the contract. E.g., I'm a box from "Box" group and I obey the contract required by the Postman. At the same time I obey other contracts:
class Box implements Package, Property {
#Override
String address() {
return "5th Street, New York, NY";
}
#Override
Human owner() {
// this method is part of another contract
}
}
Abstract vs Final
Abstract class is a group of incomplete objects. They can't be used, because they miss some parts. E.g., I'm an abstract GPS-aware box - I know how to check my position on the map:
abstract class GpsBox implements Package {
#Override
public abstract String address();
protected Coordinates whereAmI() {
// connect to GPS and return my current position
}
}
This class, if inherited/extended by another class, can be very useful. But by itself - it is useless, since it can't have objects. Abstract classes can be building elements of final classes.
Final class is a group of complete objects, which can be used, but can't be modified. They know exactly how to work and what to do. E.g., I'm a Box that always goes to the address specified during its construction:
final class DirectBox implements Package {
private final String to;
public DirectBox(String addr) {
this.to = addr;
}
#Override
public String address() {
return this.to;
}
}
In most languages, like Java or C++, it is possible to have just a class, neither abstract nor final. Such a class can be inherited and can be instantiated. I don't think this is strictly in line with object-oriented paradigm, though.
Again, comparing interfaces with abstract classes is not correct.
The only difference is that one can participate in multiple inheritance and other cannot.
The definition of an interface has changed over time. Do you think an interface just has method declarations only and are just contracts? What about static final variables and what about default definitions after Java 8?
Interfaces were introduced to Java because of the diamond problem with multiple inheritance and that's what they actually intend to do.
Interfaces are the constructs that were created to get away with the multiple inheritance problem and can have abstract methods, default definitions and static final variables.
See Why does Java allow static final variables in interfaces when they are only intended to be contracts?.
Interface: Turn ( Turn Left, Turn Right.)
Abstract Class: Wheel.
Class: Steering Wheel, derives from Wheel, exposes Interface Turn
One is for categorizing behavior that can be offered across a diverse range of things, the other is for modelling an ontology of things.
In short the differences are the following:
Syntactical Differences Between Interface and Abstract Class:
Methods and members of an abstract class can have any visibility. All methods of an interface must be public. //Does not hold true from Java 9 anymore
A concrete child class of an Abstract Class must define all the abstract methods. An Abstract child class can have abstract methods. An interface extending another interface need not provide default implementation for methods inherited from the parent interface.
A child class can only extend a single class. An interface can extend multiple interfaces. A class can implement multiple interfaces.
A child class can define abstract methods with the same or less restrictive visibility, whereas class implementing an interface must define all interface methods as public.
Abstract Classes can have constructors but not interfaces.
Interfaces from Java 9 have private static methods.
In Interfaces now:
public static - supported
public abstract - supported
public default - supported
private static - supported
private abstract - compile error
private default - compile error
private - supported
Many junior developers make the mistake of thinking of interfaces, abstract and concrete classes as slight variations of the same thing, and choose one of them purely on technical grounds: Do I need multiple inheritance? Do I need some place to put common methods? Do I need to bother with something other than just a concrete class? This is wrong, and hidden in these questions is the main problem: "I". When you write code for yourself, by yourself, you rarely think of other present or future developers working on or with your code.
Interfaces and abstract classes, although apparently similar from a technical point of view, have completely different meanings and purposes.
Summary
An interface defines a contract that some implementation will fulfill for you.
An abstract class provides a default behavior that your implementation can reuse.
Alternative summary
An interface is for defining public APIs
An abstract class is for internal use, and for defining SPIs
On the importance of hiding implementation details
A concrete class does the actual work, in a very specific way. For example, an ArrayList uses a contiguous area of memory to store a list of objects in a compact manner which offers fast random access, iteration, and in-place changes, but is terrible at insertions, deletions, and occasionally even additions; meanwhile, a LinkedList uses double-linked nodes to store a list of objects, which instead offers fast iteration, in-place changes, and insertion/deletion/addition, but is terrible at random access. These two types of lists are optimized for different use cases, and it matters a lot how you're going to use them. When you're trying to squeeze performance out of a list that you're heavily interacting with, and when picking the type of list is up to you, you should carefully pick which one you're instantiating.
On the other hand, high level users of a list don't really care how it is actually implemented, and they should be insulated from these details. Let's imagine that Java didn't expose the List interface, but only had a concrete List class that's actually what LinkedList is right now. All Java developers would have tailored their code to fit the implementation details: avoid random access, add a cache to speed up access, or just reimplement ArrayList on their own, although it would be incompatible with all the other code that actually works with List only. That would be terrible... But now imagine that the Java masters actually realize that a linked list is terrible for most actual use cases, and decided to switch over to an array list for their only List class available. This would affect the performance of every Java program in the world, and people wouldn't be happy about it. And the main culprit is that implementation details were available, and the developers assumed that those details are a permanent contract that they can rely on. This is why it's important to hide implementation details, and only define an abstract contract. This is the purpose of an interface: define what kind of input a method accepts, and what kind of output is expected, without exposing all the guts that would tempt programmers to tweak their code to fit the internal details that might change with any future update.
An abstract class is in the middle between interfaces and concrete classes. It is supposed to help implementations share common or boring code. For example, AbstractCollection provides basic implementations for isEmpty based on size is 0, contains as iterate and compare, addAll as repeated add, and so on. This lets implementations focus on the crucial parts that differentiate between them: how to actually store and retrieve data.
APIs versus SPIs
Interfaces are low-cohesion gateways between different parts of code. They allow libraries to exist and evolve without breaking every library user when something changes internally. It's called Application Programming Interface, not Application Programming Classes. On a smaller scale, they also allow multiple developers to collaborate successfully on large scale projects, by separating different modules through well documented interfaces.
Abstract classes are high-cohesion helpers to be used when implementing an interface, assuming some level of implementation details. Alternatively, abstract classes are used for defining SPIs, Service Provider Interfaces.
The difference between an API and an SPI is subtle, but important: for an API, the focus is on who uses it, and for an SPI the focus is on who implements it.
Adding methods to an API is easy, all existing users of the API will still compile. Adding methods to an SPI is hard, since every service provider (concrete implementation) will have to implement the new methods. If interfaces are used to define an SPI, a provider will have to release a new version whenever the SPI contract changes. If abstract classes are used instead, new methods could either be defined in terms of existing abstract methods, or as empty throw not implemented exception stubs, which will at least allow an older version of a service implementation to still compile and run.
A note on Java 8 and default methods
Although Java 8 introduced default methods for interfaces, which makes the line between interfaces and abstract classes even blurrier, this wasn't so that implementations can reuse code, but to make it easier to change interfaces that serve both as an API and as an SPI (or are wrongly used for defining SPIs instead of abstract classes).
Which one to use?
Is the thing supposed to be publicly used by other parts of the code, or by other external code? Add an interface to it to hide the implementation details from the public abstract contract, which is the general behavior of the thing.
Is the thing something that's supposed to have multiple implementations with a lot of code in common? Make both an interface and an abstract, incomplete implementation.
Is there ever going to be only one implementation, and nobody else will use it? Just make it a concrete class.
"ever" is long time, you could play it safe and still add an interface on top of it.
A corollary: the other way around is often wrongly done: when using a thing, always try to use the most generic class/interface that you actually need. In other words, don't declare your variables as ArrayList theList = new ArrayList(), unless you actually have a very strong dependency on it being an array list, and no other type of list would cut it for you. Use List theList = new ArrayList instead, or even Collection theCollection = new ArrayList if the fact that it's a list, and not any other type of collection doesn't actually matter.
Not really the answer to the original question, but once you have the answer to the difference between them, you will enter the when-to-use-each dilemma:
When to use interfaces or abstract classes? When to use both?
I've limited knowledge of OOP, but seeing interfaces as an equivalent of an adjective in grammar has worked for me until now (correct me if this method is bogus!). For example, interface names are like attributes or capabilities you can give to a class, and a class can have many of them: ISerializable, ICountable, IList, ICacheable, IHappy, ...
You can find clear difference between interface and abstract class.
Interface
Interface only contains abstract methods.
Force users to implement all methods when implements the interface.
Contains only final and static variables.
Declare using interface keyword.
All methods of an interface must be defined as public.
An interface can extend or a class can implement multiple other
interfaces.
Abstract class
Abstract class contains abstract and non-abstract methods.
Does not force users to implement all methods when inherited the
abstract class.
Contains all kinds of variables including primitive and non-primitive
Declare using abstract keyword.
Methods and members of an abstract class can be defined with any
visibility.
A child class can only extend a single class (abstract or concrete).
I am 10 yrs late to the party but would like to attempt any way. Wrote a post about the same on medium few days back. Thought of posting it here.
tl;dr; When you see “Is A” relationship use inheritance/abstract class. when you see “has a” relationship create member variables. When you see “relies on external provider” implement (not inherit) an interface.
Interview Question: What is the difference between an interface and an abstract class? And how do you decide when to use what?
I mostly get one or all of the below answers:
Answer 1: You cannot create an object of abstract class and interfaces.
ZK (That’s my initials): You cannot create an object of either. So this is not a difference. This is a similarity between an interface and an abstract class. Counter
Question: Why can’t you create an object of abstract class or interface?
Answer 2: Abstract classes can have a function body as partial/default implementation.
ZK: Counter Question: So if I change it to a pure abstract class, marking all the virtual functions as abstract and provide no default implementation for any virtual function. Would that make abstract classes and interfaces the same? And could they be used interchangeably after that?
Answer 3: Interfaces allow multi-inheritance and abstract classes don’t.
ZK: Counter Question: Do you really inherit from an interface? or do you just implement an interface and, inherit from an abstract class? What’s the difference between implementing and inheriting?
These counter questions throw candidates off and make most scratch their heads or just pass to the next question. That makes me think people need help with these basic building blocks of Object-Oriented Programming.
The answer to the original question and all the counter questions is found in the English language and the UML.
You must know at least below to understand these two constructs better.
Common Noun: A common noun is a name given “in common” to things of the same class or kind. For e.g. fruits, animals, city, car etc.
Proper Noun: A proper noun is the name of an object, place or thing. Apple, Cat, New York, Honda Accord etc.
Car is a Common Noun. And Honda Accord is a Proper Noun, and probably a Composit Proper noun, a proper noun made using two nouns.
Coming to the UML Part. You should be familiar with below relationships:
Is A
Has A
Uses
Let’s consider the below two sentences.
- HondaAccord Is A Car?
- HondaAccord Has A Car?
Which one sounds correct? Plain English and comprehension. HondaAccord and Cars share an “Is A” relationship. Honda accord doesn’t have a car in it. It “is a” car. Honda Accord “has a” music player in it.
When two entities share the “Is A” relationship it’s a better candidate for inheritance. And Has a relationship is a better candidate for creating member variables.
With this established our code looks like this:
abstract class Car
{
string color;
int speed;
}
class HondaAccord : Car
{
MusicPlayer musicPlayer;
}
Now Honda doesn't manufacture music players. Or at least it’s not their main business.
So they reach out to other companies and sign a contract. If you receive power here and the output signal on these two wires it’ll play just fine on these speakers.
This makes Music Player a perfect candidate for an interface. You don’t care who provides support for it as long as the connections work just fine.
You can replace the MusicPlayer of LG with Sony or the other way. And it won’t change a thing in Honda Accord.
Why can’t you create an object of abstract classes?
Because you can’t walk into a showroom and say give me a car. You’ll have to provide a proper noun. What car? Probably a honda accord. And that’s when a sales agent could get you something.
Why can’t you create an object of an interface?
Because you can’t walk into a showroom and say give me a contract of music player. It won’t help. Interfaces sit between consumers and providers just to facilitate an agreement. What will you do with a copy of the agreement? It won’t play music.
Why do interfaces allow multiple inheritance?
Interfaces are not inherited. Interfaces are implemented.
The interface is a candidate for interaction with the external world.
Honda Accord has an interface for refueling. It has interfaces for inflating tires. And the same hose that is used to inflate a football. So the new code will look like below:
abstract class Car
{
string color;
int speed;
}
class HondaAccord : Car, IInflateAir, IRefueling
{
MusicPlayer musicPlayer;
}
And the English will read like this “Honda Accord is a Car that supports inflating tire and refueling”.
Key Points:
Abstract class can have property, Data fields ,Methods (complete /
incomplete) both.
If method or Properties define in abstract keyword that must override in derived class.(its work as a tightly coupled
functionality)
If define abstract keyword for method or properties in abstract class you can not define body of method and get/set value for
properties and that must override in derived class.
Abstract class does not support multiple inheritance.
Abstract class contains Constructors.
An abstract class can contain access modifiers for the subs, functions, properties.
Only Complete Member of abstract class can be Static.
An interface can inherit from another interface only and cannot inherit from an abstract class, where as an abstract class can inherit from another abstract class or another interface.
Advantage:
It is a kind of contract that forces all the subclasses to carry on the same hierarchies or standards.
If various implementations are of the same kind and use common behavior or status then abstract class is better to use.
If we add a new method to an abstract class then we have the option of providing default implementation and therefore all the existing code might work properly.
Its allow fast execution than interface.(interface Requires more time to find the actual method in the corresponding classes.)
It can use for tight and loosely coupling.
find details here...
http://pradeepatkari.wordpress.com/2014/11/20/interface-and-abstract-class-in-c-oops/
The shortest way to sum it up is that an interface is:
Fully abstract, apart from default and static methods; while it has definitions (method signatures + implementations) for default and static methods, it only has declarations (method signatures) for other methods.
Subject to laxer rules than classes (a class can implement multiple interfaces, and an interface can inherit from multiple interfaces). All variables are implicitly constant, whether specified as public static final or not. All members are implicitly public, whether specified as such or not.
Generally used as a guarantee that the implementing class will have the specified features and/or be compatible with any other class which implements the same interface.
Meanwhile, an abstract class is:
Anywhere from fully abstract to fully implemented, with a tendency to have one or more abstract methods. Can contain both declarations and definitions, with declarations marked as abstract.
A full-fledged class, and subject to the rules that govern other classes (can only inherit from one class), on the condition that it cannot be instantiated (because there's no guarantee that it's fully implemented). Can have non-constant member variables. Can implement member access control, restricting members as protected, private, or private package (unspecified).
Generally used either to provide as much of the implementation as can be shared by multiple subclasses, or to provide as much of the implementation as the programmer is able to supply.
Or, if we want to boil it all down to a single sentence: An interface is what the implementing class has, but an abstract class is what the subclass is.
Inheritance is used for two purposes:
To allow an object to regard parent-type data members and method implementations as its own.
To allow a reference to an objects of one type to be used by code which expects a reference to supertype object.
In languages/frameworks which support generalized multiple inheritance, there is often little need to classify a type as either being an "interface" or an "abstract class". Popular languages and frameworks, however, will allow a type to regard one other type's data members or method implementations as its own even though they allow a type to be substitutable for an arbitrary number of other types.
Abstract classes may have data members and method implementations, but can only be inherited by classes which don't inherit from any other classes. Interfaces put almost no restrictions on the types which implement them, but cannot include any data members or method implementations.
There are times when it's useful for types to be substitutable for many different things; there are other times when it's useful for objects to regard parent-type data members and method implementations as their own. Making a distinction between interfaces and abstract classes allows each of those abilities to be used in cases where it is most relevant.
Differences between abstract class and interface on behalf of real implementation.
Interface: It is a keyword and it is used to define the template or blue print of an object and it forces all the sub classes would follow the same prototype,as for as implementation, all the sub classes are free to implement the functionality as per it's requirement.
Some of other use cases where we should use interface.
Communication between two external objects(Third party integration in our application) done through Interface here Interface works as Contract.
Abstract Class: Abstract,it is a keyword and when we use this keyword before any class then it becomes abstract class.It is mainly used when we need to define the template as well as some default functionality of an object that is followed by all the sub classes and this way it removes the redundant code and one more use cases where we can use abstract class, such as we want no other classes can directly instantiate an object of the class, only derived classes can use the functionality.
Example of Abstract Class:
public abstract class DesireCar
{
//It is an abstract method that defines the prototype.
public abstract void Color();
// It is a default implementation of a Wheel method as all the desire cars have the same no. of wheels.
// and hence no need to define this in all the sub classes in this way it saves the code duplicasy
public void Wheel() {
Console.WriteLine("Car has four wheel");
}
}
**Here is the sub classes:**
public class DesireCar1 : DesireCar
{
public override void Color()
{
Console.WriteLine("This is a red color Desire car");
}
}
public class DesireCar2 : DesireCar
{
public override void Color()
{
Console.WriteLine("This is a red white Desire car");
}
}
Example Of Interface:
public interface IShape
{
// Defines the prototype(template)
void Draw();
}
// All the sub classes follow the same template but implementation can be different.
public class Circle : IShape
{
public void Draw()
{
Console.WriteLine("This is a Circle");
}
}
public class Rectangle : IShape
{
public void Draw()
{
Console.WriteLine("This is a Rectangle");
}
}
I'd like to add one more difference which makes sense.
For example, you have a framework with thousands of lines of code. Now if you want to add a new feature throughout the code using a method enhanceUI(), then it's better to add that method in abstract class rather in interface. Because, if you add this method in an interface then you should implement it in all the implemented class but it's not the case if you add the method in abstract class.
To give a simple but clear answer, it helps to set the context : you use both when you do not want to provide full implementations.
The main difference then is an interface has no implementation at all (only methods without a body) while abstract classes can have members and methods with a body as well, i.e. can be partially implemented.
usually Abstract class used for core of something but interface used for appending peripheral.
when you want to create base type for vehicle you should use abstract class but if you want to add some functionality or property that is not part of base concept of vehicle you should use interface,for example you want to add "ToJSON()" function.
interface has wide range of abstraction rather than abstract class.
you can see this in passing arguments.look this example:
if you use vehicle as argument you just can use one of its derived type (bus or car-same category-just vehicle category).
but when you use IMoveable interface as argument you have more choices.
The topic of abstract classes vs interfaces is mostly about semantics.
Abstract classes act in different programming languages often as a superset of interfaces, except one thing and that is, that you can implement multiple interfaces, but inherit only one class.
An interface defines what something must be able to do; like a contract, but does not provide an implementation of it.
An abstract class defines what something is and it commonly hosts shared code between the subclasses.
For example a Formatter should be able to format() something. The common semantics to describe something like that would be to create an interface IFormatter with a declaration of format() that acts like a contract. But IFormatter does not describe what something is, but just what it should be able to to. The common semantics to describe what something actually is, is to create a class. In this case we create an abstract class... So we create an abstract class Formatter which implements the interface. That is a very descriptive code, because we now know we have a Formatter and we now know what every Formatter must be able to do.
Also one very important topic is documentation (at least for some people...). In your documentation you probably want to explain within your subclasses what a Formatter actually is. It is very convenient to have an abstract class Formatter to which documentation you can link to within your subclasses. That is very convenient and generic. On the other hand if you do not have an abstract class Formatter and only an interface IFormatter you would have to explain in each of your subclasses what a Formatter actucally is, because an interface is a contract and you would not describe what a Formatter actually is within the documentation of an interface — at least it would be not something common to do and you would break the semantics that most developers consider to be correct.
Note: It is a very common pattern to make an abstract class implement an interface.
An abstract class is a class whose object cannot be created or a class which cannot be instantiated.
An abstract method makes a class abstract.
An abstract class needs to be inherited in order to override the methods that are declared in the abstract class.
No restriction on access specifiers.
An abstract class can have constructor and other concrete(non abstarct methods ) methods in them but interface cannot have.
An interface is a blueprint/template of methods.(eg. A house on a paper is given(interface house) and different architects will use their ideas to build it(the classes of architects implementing the house interface) .
It is a collection of abstract methods , default methods , static methods , final variables and nested classes.
All members will be either final or public , protected and private access specifiers are not allowed.No object creation is allowed.
A class has to be made in order to use the implementing interface and also to override the abstract method declared in the interface. An interface is a good example of loose coupling(dynamic polymorphism/dynamic binding)
An interface implements polymorphism and abstraction.It tells what to do but how to do is defined by the implementing class.
For Eg. There's a car company and it wants that some features to be same for all the car it is manufacturing so for that the company would be making an interface vehicle which will have those features and different classes of car(like Maruti Suzkhi , Maruti 800) will override those features(functions).
Why interface when we already have abstract class?
Java supports only multilevel and hierarchal inheritance but with the help of interface we can implement multiple inheritance.
In an interface all methods must be only definitions, not single one should be implemented.
But in an abstract class there must an abstract method with only definition, but other methods can be also in the abstract class with implementation...
Could someone please demystify interfaces for me or point me to some good examples? I keep seeing interfaces popup here and there, but I haven't ever really been exposed to good explanations of interfaces or when to use them.
I am talking about interfaces in a context of interfaces vs. abstract classes.
Interfaces allow you to program against a "description" instead of a type, which allows you to more-loosely associate elements of your software.
Think of it this way: You want to share data with someone in the cube next to you, so you pull out your flash stick and copy/paste. You walk next door and the guy says "is that USB?" and you say yes - all set. It doesn't matter the size of the flash stick, nor the maker - all that matters is that it's USB.
In the same way, interfaces allow you to generisize your development. Using another analogy - imagine you wanted to create an application that virtually painted cars. You might have a signature like this:
public void Paint(Car car, System.Drawing.Color color)...
This would work until your client said "now I want to paint trucks" so you could do this:
public void Paint (Vehicle vehicle, System.Drawing.Color color)...
this would broaden your app... until your client said "now I want to paint houses!" What you could have done from the very beginning is created an interface:
public interface IPaintable{
void Paint(System.Drawing.Color color);
}
...and passed that to your routine:
public void Paint(IPaintable item, System.Drawing.Color color){
item.Paint(color);
}
Hopefully this makes sense - it's a pretty simplistic explanation but hopefully gets to the heart of it.
Interfaces establish a contract between a class and the code that calls it. They also allow you to have similar classes that implement the same interface but do different actions or events and not have to know which you are actually working with. This might make more sense as an example so let me try one here.
Say you have a couple classes called Dog, Cat, and Mouse. Each of these classes is a Pet and in theory you could inherit them all from another class called Pet but here's the problem. Pets in and of themselves don't do anything. You can't go to the store and buy a pet. You can go and buy a dog or a cat but a pet is an abstract concept and not concrete.
So You know pets can do certain things. They can sleep, or eat, etc. So you define an interface called IPet and it looks something like this (C# syntax)
public interface IPet
{
void Eat(object food);
void Sleep(int duration);
}
Each of your Dog, Cat, and Mouse classes implement IPet.
public class Dog : IPet
So now each of those classes has to have it's own implementation of Eat and Sleep. Yay you have a contract... Now what's the point.
Next let's say you want to make a new object called PetStore. And this isn't a very good PetStore so they basically just sell you a random pet (yes i know this is a contrived example).
public class PetStore
{
public static IPet GetRandomPet()
{
//Code to return a random Dog, Cat, or Mouse
}
}
IPet myNewRandomPet = PetStore.GetRandomPet();
myNewRandomPet.Sleep(10);
The problem is you don't know what type of pet it will be. Thanks to the interface though you know whatever it is it will Eat and Sleep.
So this answer may not have been helpful at all but the general idea is that interfaces let you do neat stuff like Dependency Injection and Inversion of Control where you can get an object, have a well defined list of stuff that object can do without ever REALLY knowing what the concrete type of that object is.
The easiest answer is that interfaces define a what your class can do. It's a "contract" that says that your class will be able to do that action.
Public Interface IRollOver
Sub RollOver()
End Interface
Public Class Dog Implements IRollOver
Public Sub RollOver() Implements IRollOver.RollOver
Console.WriteLine("Rolling Over!")
End Sub
End Class
Public Sub Main()
Dim d as New Dog()
Dim ro as IRollOver = TryCast(d, IRollOver)
If ro isNot Nothing Then
ro.RollOver()
End If
End Sub
Basically, you are guaranteeing that the Dog class always has the ability to roll over as long as it continues to implement that Interface. Should cats ever gain the ability to RollOver(), they too could implement that interface, and you can treat both Dogs and Cats homogeneously when asking them to RollOver().
When you drive a friend's car, you more or less know how to do that. This is because conventional cars all have a very similar interface: steering wheel, pedals, and so forth. Think of this interface as a contract between car manufacturers and drivers. As a driver (the user/client of the interface in software terms), you don't need to learn the particulars of different cars to be able to drive them: e.g., all you need to know is that turning the steering wheel makes the car turn. As a car manufacturer (the provider of an implementation of the interface in software terms) you have a clear idea what your new car should have and how it should behave so that drivers can use them without much extra training. This contract is what people in software design refer to as decoupling (the user from the provider) -- the client code is in terms of using an interface rather than a particular implementation thereof and hence doesn't need to know the details of the objects implementing the interface.
Interfaces are a mechanism to reduce coupling between different, possibly disparate parts of a system.
From a .NET perspective
The interface definition is a list of operations and/or properties.
Interface methods are always public.
The interface itself doesn't have to be public.
When you create a class that implements the interface, you must provide either an explicit or implicit implementation of all methods and properties defined by the interface.
Further, .NET has only single inheritance, and interfaces are a necessity for an object to expose methods to other objects that aren't aware of, or lie outside of its class hierarchy. This is also known as exposing behaviors.
An example that's a little more concrete:
Consider is we have many DTO's (data transfer objects) that have properties for who updated last, and when that was. The problem is that not all the DTO's have this property because it's not always relevant.
At the same time we desire a generic mechanism to guarantee these properties are set if available when submitted to the workflow, but the workflow object should be loosely coupled from the submitted objects. i.e. the submit workflow method shouldn't really know about all the subtleties of each object, and all objects in the workflow aren't necessarily DTO objects.
// First pass - not maintainable
void SubmitToWorkflow(object o, User u)
{
if (o is StreetMap)
{
var map = (StreetMap)o;
map.LastUpdated = DateTime.UtcNow;
map.UpdatedByUser = u.UserID;
}
else if (o is Person)
{
var person = (Person)o;
person.LastUpdated = DateTime.Now; // Whoops .. should be UtcNow
person.UpdatedByUser = u.UserID;
}
// Whoa - very unmaintainable.
In the code above, SubmitToWorkflow() must know about each and every object. Additionally, the code is a mess with one massive if/else/switch, violates the don't repeat yourself (DRY) principle, and requires developers to remember copy/paste changes every time a new object is added to the system.
// Second pass - brittle
void SubmitToWorkflow(object o, User u)
{
if (o is DTOBase)
{
DTOBase dto = (DTOBase)o;
dto.LastUpdated = DateTime.UtcNow;
dto.UpdatedByUser = u.UserID;
}
It is slightly better, but it is still brittle. If we want to submit other types of objects, we need still need more case statements. etc.
// Third pass pass - also brittle
void SubmitToWorkflow(DTOBase dto, User u)
{
dto.LastUpdated = DateTime.UtcNow;
dto.UpdatedByUser = u.UserID;
It is still brittle, and both methods impose the constraint that all the DTOs have to implement this property which we indicated wasn't universally applicable. Some developers might be tempted to write do-nothing methods, but that smells bad. We don't want classes pretending they support update tracking but don't.
Interfaces, how can they help?
If we define a very simple interface:
public interface IUpdateTracked
{
DateTime LastUpdated { get; set; }
int UpdatedByUser { get; set; }
}
Any class that needs this automatic update tracking can implement the interface.
public class SomeDTO : IUpdateTracked
{
// IUpdateTracked implementation as well as other methods for SomeDTO
}
The workflow method can be made to be a lot more generic, smaller, and more maintainable, and it will continue to work no matter how many classes implement the interface (DTOs or otherwise) because it only deals with the interface.
void SubmitToWorkflow(object o, User u)
{
IUpdateTracked updateTracked = o as IUpdateTracked;
if (updateTracked != null)
{
updateTracked.LastUpdated = DateTime.UtcNow;
updateTracked.UpdatedByUser = u.UserID;
}
// ...
We can note the variation void SubmitToWorkflow(IUpdateTracked updateTracked, User u) would guarantee type safety, however it doesn't seem as relevant in these circumstances.
In some production code we use, we have code generation to create these DTO classes from the database definition. The only thing the developer does is have to create the field name correctly and decorate the class with the interface. As long as the properties are called LastUpdated and UpdatedByUser, it just works.
Maybe you're asking What happens if my database is legacy and that's not possible? You just have to do a little more typing; another great feature of interfaces is they can allow you to create a bridge between the classes.
In the code below we have a fictitious LegacyDTO, a pre-existing object having similarly-named fields. It's implementing the IUpdateTracked interface to bridge the existing, but differently named properties.
// Using an interface to bridge properties
public class LegacyDTO : IUpdateTracked
{
public int LegacyUserID { get; set; }
public DateTime LastSaved { get; set; }
public int UpdatedByUser
{
get { return LegacyUserID; }
set { LegacyUserID = value; }
}
public DateTime LastUpdated
{
get { return LastSaved; }
set { LastSaved = value; }
}
}
You might thing Cool, but isn't it confusing having multiple properties? or What happens if there are already those properties, but they mean something else? .NET gives you the ability to explicitly implement the interface.
What this means is that the IUpdateTracked properties will only be visible when we're using a reference to IUpdateTracked. Note how there is no public modifier on the declaration, and the declaration includes the interface name.
// Explicit implementation of an interface
public class YetAnotherObject : IUpdatable
{
int IUpdatable.UpdatedByUser
{ ... }
DateTime IUpdatable.LastUpdated
{ ... }
Having so much flexibility to define how the class implements the interface gives the developer a lot of freedom to decouple the object from methods that consume it. Interfaces are a great way to break coupling.
There is a lot more to interfaces than just this. This is just a simplified real-life example that utilizes one aspect of interface based programming.
As I mentioned earlier, and by other responders, you can create methods that take and/or return interface references rather than a specific class reference. If I needed to find duplicates in a list, I could write a method that takes and returns an IList (an interface defining operations that work on lists) and I'm not constrained to a concrete collection class.
// Decouples the caller and the code as both
// operate only on IList, and are free to swap
// out the concrete collection.
public IList<T> FindDuplicates( IList<T> list )
{
var duplicates = new List<T>()
// TODO - write some code to detect duplicate items
return duplicates;
}
Versioning caveat
If it's a public interface, you're declaring I guarantee interface x looks like this! And once you have shipped code and published the interface, you should never change it. As soon as consumer code starts to rely on that interface, you don't want to break their code in the field.
See this Haacked post for a good discussion.
Interfaces versus abstract (base) classes
Abstract classes can provide implementation whereas Interfaces cannot. Abstract classes are in some ways more flexible in the versioning aspect if you follow some guidelines like the NVPI (Non-Virtual Public Interface) pattern.
It's worth reiterating that in .NET, a class can only inherit from a single class, but a class can implement as many interfaces as it likes.
Dependency Injection
The quick summary of interfaces and dependency injection (DI) is that the use of interfaces enables developers to write code that is programmed against an interface to provide services. In practice you can end up with a lot of small interfaces and small classes, and one idea is that small classes that do one thing and only one thing are much easier to code and maintain.
class AnnualRaiseAdjuster
: ISalaryAdjuster
{
AnnualRaiseAdjuster(IPayGradeDetermination payGradeDetermination) { ... }
void AdjustSalary(Staff s)
{
var payGrade = payGradeDetermination.Determine(s);
s.Salary = s.Salary * 1.01 + payGrade.Bonus;
}
}
In brief, the benefit shown in the above snippet is that the pay grade determination is just injected into the annual raise adjuster. How pay grade is determined doesn't actually matter to this class. When testing, the developer can mock pay grade determination results to ensure the salary adjuster functions as desired. The tests are also fast because the test is only testing the class, and not everything else.
This isn't a DI primer though as there are whole books devoted to the subject; the above example is very simplified.
This is a rather "long" subject, but let me try to put it simple.
An interface is -as "they name it"- a Contract. But forget about that word.
The best way to understand them is through some sort of pseudo-code example. That's how I understood them long time ago.
Suppose you have an app that processes Messages. A Message contains some stuff, like a subject, a text, etc.
So you write your MessageController to read a database, and extract messages. It's very nice until you suddenly hear that Faxes will be also implemented soon. So you will now have to read "Faxes" and process them as messages!
This could easily turn into a Spagetti code. So what you do instead of having a MessageController than controls "Messages" only, you make it able to work with an interface called IMessage (the I is just common usage, but not required).
Your IMessage interface, contains some basic data you need to make sure that you're able to process the Message as such.
So when you create your EMail, Fax, PhoneCall classes, you make them Implement the Interface called IMessage.
So in your MessageController, you can have a method called like this:
private void ProcessMessage(IMessage oneMessage)
{
DoSomething();
}
If you had not used Interfaces, you'd have to have:
private void ProcessEmail(Email someEmail);
private void ProcessFax(Fax someFax);
etc.
So, by using a common interface, you just made sure that the ProcessMessage method will be able to work with it, no matter if it was a Fax, an Email a PhoneCall, etc.
Why or how?
Because the interface is a contract that specifies some things you must adhere (or implement) in order to be able to use it. Think of it as a badge. If your object "Fax" doesn't have the IMessage interface, then your ProcessMessage method wouldn't be able to work with that, it will give you an invalid type, because you're passing a Fax to a method that expects an IMessage object.
Do you see the point?
Think of the interface as a "subset" of methods and properties that you will have available, despite the real object type. If the original object (Fax, Email, PhoneCall, etc) implements that interface, you can safety pass it across methods that need that Interface.
There's more magic hidden in there, you can CAST the interfaces back to their original objects:
Fax myFax = (Fax)SomeIMessageThatIReceive;
The ArrayList() in .NET 1.1 had a nice interface called IList. If you had an IList (very "generic") you could transform it into an ArrayList:
ArrayList ar = (ArrayList)SomeIList;
And there are thousands of samples out there in the wild.
Interfaces like ISortable, IComparable, etc., define the methods and properties you must implement in your class in order to achieve that functionality.
To expand our sample, you could have a List<> of Emails, Fax, PhoneCall, all in the same List, if the Type is IMessage, but you couldn't have them all together if the objects were simply Email, Fax, etc.
If you wanted to sort (or enumerate for example) your objects, you'd need them to implement the corresponding interface. In the .NET sample, if you have a list of "Fax" objects and want to be able to sort them by using MyList.Sort(), you need to make your fax class like this:
public class Fax : ISorteable
{
//implement the ISorteable stuff here.
}
I hope this gives you a hint. Other users will possibly post other good examples. Good luck! and Embrace the power of INterfaces.
warning: Not everything is good about interfaces, there are some issues with them, OOP purists will start a war on this. I shall remain aside. One drawback of an Interfce (in .NET 2.0 at least) is that you cannot have PRIVATE members, or protected, it must be public. This makes some sense, but sometimes you wish you could simply declare stuff as private or protected.
In addition to the function interfaces have within programming languages, they also are a powerful semantic tool when expressing design ideas to other people.
A code base with well-designed interfaces is suddenly a lot easier to discuss. "Yes, you need a CredentialsManager to register new remote servers." "Pass a PropertyMap to ThingFactory to get a working instance."
Ability to address a complex thing with a single word is pretty useful.
Interfaces let you code against objects in a generic way. For instance, say you have a method that sends out reports. Now say you have a new requirement that comes in where you need to write a new report. It would be nice if you could reuse the method you already had written right? Interfaces makes that easy:
interface IReport
{
string RenderReport();
}
class MyNewReport : IReport
{
public string RenderReport()
{
return "Hello World Report!";
}
}
class AnotherReport : IReport
{
public string RenderReport()
{
return "Another Report!";
}
}
//This class can process any report that implements IReport!
class ReportEmailer()
{
public void EmailReport(IReport report)
{
Email(report.RenderReport());
}
}
class MyApp()
{
void Main()
{
//create specific "MyNewReport" report using interface
IReport newReport = new MyNewReport();
//create specific "AnotherReport" report using interface
IReport anotherReport = new AnotherReport();
ReportEmailer reportEmailer = new ReportEmailer();
//emailer expects interface
reportEmailer.EmailReport(newReport);
reportEmailer.EmailReport(anotherReport);
}
}
Interfaces are also key to polymorphism, one of the "THREE PILLARS OF OOD".
Some people touched on it above, polymorphism just means a given class can take on different "forms". Meaning, if we have two classes, "Dog" and "Cat" and both implement the interface "INeedFreshFoodAndWater" (hehe) - your code can do something like this (pseudocode):
INeedFreshFoodAndWater[] array = new INeedFreshFoodAndWater[];
array.Add(new Dog());
array.Add(new Cat());
foreach(INeedFreshFoodAndWater item in array)
{
item.Feed();
item.Water();
}
This is powerful because it allows you to treat different classes of objects abstractly, and allows you to do things like make your objects more loosely coupled, etc.
OK, so it's about abstract classes vs. interfaces...
Conceptually, abstract classes are there to be used as base classes. Quite often they themselves already provide some basic functionality, and the subclasses have to provide their own implementation of the abstract methods (those are the methods which aren't implemented in the abstract base class).
Interfaces are mostly used for decoupling the client code from the details of a particular implementation. Also, sometimes the ability to switch the implementation without changing the client code makes the client code more generic.
On the technical level, it's harder to draw the line between abstract classes and interfaces, because in some languages (e.g., C++), there's no syntactic difference, or because you could also use abstract classes for the purposes of decoupling or generalization. Using an abstract class as an interface is possible because every base class, by definition, defines an interface that all of its subclasses should honor (i.e., it should be possible to use a subclass instead of a base class).
Interfaces are a way to enforce that an object implements a certain amount of functionality, without having to use inheritance (which leads to strongly coupled code, instead of loosely coupled which can be achieved through using interfaces).
Interfaces describe the functionality, not the implementation.
Most of the interfaces you come across are a collection of method and property signatures. Any one who implements an interface must provide definitions to what ever is in the interface.
Simply put: An interface is a class that methods defined but no implementation in them. In contrast an abstract class has some of the methods implemented but not all.
Think of an interface as a contract. When a class implements an interface, it is essentially agreeing to honor the terms of that contract. As a consumer, you only care that the objects you have can perform their contractual duties. Their inner workings and details aren't important.
One good reason for using an interface vs. an abstract class in Java is that a subclass cannot extend multiple base classes, but it CAN implement multiple interfaces.
Java does not allow multiple inheritance (for very good reasons, look up dreadful diamond) but what if you want to have your class supply several sets of behavior? Say you want anyone who uses it to know it can be serialized, and also that it can paint itself on the screen. the answer is to implement two different interfaces.
Because interfaces contain no implementation of their own and no instance members it is safe to implement several of them in the same class with no ambiguities.
The down side is that you will have to have the implementation in each class separately. So if your hierarchy is simple and there are parts of the implementation that should be the same for all the inheriting classes use an abstract class.
Assuming you're referring to interfaces in statically-typed object-oriented languages, the primary use is in asserting that your class follows a particular contract or protocol.
Say you have:
public interface ICommand
{
void Execute();
}
public class PrintSomething : ICommand
{
OutputStream Stream { get; set; }
String Content {get; set;}
void Execute()
{
Stream.Write(content);
}
}
Now you have a substitutable command structure. Any instance of a class that implements IExecute can be stored in a list of some sort, say something that implements IEnumerable and you can loop through that and execute each one, knowing that each object will Just Do The Right Thing. You can create a composite command by implementing CompositeCommand which will have its own list of commands to run, or a LoopingCommand to run a set of commands repeatedly, then you'll have most of a simple interpreter.
When you can reduce a set of objects to a behavior that they all have in common, you might have cause to extract an interface. Also, sometimes you can use interfaces to prevent objects from accidentally intruding on the concerns of that class; for example, you may implement an interface that only allows clients to retrieve, rather than change data in your object, and have most objects receive only a reference to the retrieval interface.
Interfaces work best when your interfaces are relatively simple and make few assumptions.
Look up the Liskov subsitution principle to make more sense of this.
Some statically-typed languages like C++ don't support interfaces as a first-class concept, so you create interfaces using pure abstract classes.
Update
Since you seem to be asking about abstract classes vs. interfaces, here's my preferred oversimplification:
Interfaces define capabilities and features.
Abstract classes define core functionality.
Typically, I do an extract interface refactoring before I build an abstract class. I'm more likely to build an abstract class if I think there should be a creational contract (specifically, that a specific type of constructor should always be supported by subclasses). However, I rarely use "pure" abstract classes in C#/java. I'm far more likely to implement a class with at least one method containing meaningful behavior, and use abstract methods to support template methods called by that method. Then the abstract class is a base implementation of a behavior, which all concrete subclasses can take advantage of without having to reimplement.
Simple answer: An interface is a bunch of method signatures (+ return type). When an object says it implements an interface, you know it exposes that set of methods.
Interfaces are a way to implement conventions in a way that is still strongly typed and polymorphic.
A good real world example would be IDisposable in .NET. A class that implements the IDisposable interface forces that class to implement the Dispose() method. If the class doesn't implement Dispose() you'll get a compiler error when trying to build. Additionally, this code pattern:
using (DisposableClass myClass = new DisposableClass())
{
// code goes here
}
Will cause myClass.Dispose() to be executed automatically when execution exits the inner block.
However, and this is important, there is no enforcement as to what your Dispose() method should do. You could have your Dispose() method pick random recipes from a file and email them to a distribution list, the compiler doesn't care. The intent of the IDisposable pattern is to make cleaning up resources easier. If instances of a class will hold onto file handles then IDisposable makes it very easy to centralize the deallocation and cleanup code in one spot and to promote a style of use which ensures that deallocation always occurs.
And that's the key to interfaces. They are a way to streamline programming conventions and design patterns. Which, when used correctly, promotes simpler, self-documenting code which is easier to use, easier to maintain, and more correct.
Here is a db related example I often use. Let us say you have an object and a container object like an list. Let us assume that sometime you might want to store the objects in a particular sequence. Assume that the sequence is not related to the position in the array but instead that the objects are a subset of a larger set of objects and the sequence position is related to the database sql filtering.
To keep track of your customized sequence positions you could make your object implement a custom interface. The custom interface could mediate the organizational effort required to maintain such sequences.
For example, the sequence you are interested in has nothing to do with primary keys in the records. With the object implementing the interface you could say myObject.next() or myObject.prev().
I have had the same problem as you and I find the "contract" explanation a bit confusing.
If you specify that a method takes an IEnumerable interface as an in-parameter you could say that this is a contract specifying that the parameter must be of a type that inherits from the IEnumerable interface and hence supports all methods specified in the IEnumerable interface. The same would be true though if we used an abstract class or a normal class. Any object that inherits from those classes would be ok to pass in as a parameter. You would in any case be able to say that the inherited object supports all public methods in the base class whether the base class is a normal class, an abstract class or an interface.
An abstract class with all abstract methods is basically the same as an interface so you could say an interface is simply a class without implemented methods. You could actually drop interfaces from the language and just use abstract class with only abstract methods instead. I think the reason we separate them is for semantic reasons but for coding reasons I don't see the reason and find it just confusing.
Another suggestion could be to rename the interface to interface class as the interface is just another variation of a class.
In certain languages there are subtle differences that allows a class to inherit only 1 class but multiple interfaces while in others you could have many of both, but that is another issue and not directly related I think
The simplest way to understand interfaces is to start by considering what class inheritance means. It includes two aspects:
Members of a derived class can use public or protected members of a base class as their own.
Members of a derived class can be used by code which expects a member of the base class (meaning they are substitutable).
Both of these features are useful, but because it is difficult to allow a class to use members of more than one class as its own, many languages and frameworks only allow classes to inherit from a single base class. On the other hand, there is no particular difficulty with having a class be substitutable for multiple other unrelated things.
Further, because the first benefit of inheritance can be largely achieved via encapsulation, the relative benefit from allowing multiple-inheritance of the first type is somewhat limited. On the other hand, being able to substitute an object for multiple unrelated types of things is a useful ability which cannot be readily achieved without language support.
Interfaces provide a means by which a language/framework can allow programs to benefit from the second aspect of inheritance for multiple base types, without requiring it to also provide the first.
Interface is like a fully abstract class. That is, an abstract class with only abstract members. You can also implement multiple interfaces, it's like inheriting from multiple fully abstract classes. Anyway.. this explanation only helps if you understand what an abstract class is.
Like others have said here, interfaces define a contract (how the classes who use the interface will "look") and abstract classes define shared functionality.
Let's see if the code helps:
public interface IReport
{
void RenderReport(); // This just defines the method prototype
}
public abstract class Reporter
{
protected void DoSomething()
{
// This method is the same for every class that inherits from this class
}
}
public class ReportViolators : Reporter, IReport
{
public void RenderReport()
{
// Some kind of implementation specific to this class
}
}
public class ClientApp
{
var violatorsReport = new ReportViolators();
// The interface method
violatorsReport.RenderReport();
// The abstract class method
violatorsReport.DoSomething();
}
Interfaces require any class that implements them to contain the methods defined in the interface.
The purpose is so that, without having to see the code in a class, you can know if it can be used for a certain task. For example, the Integer class in Java implements the comparable interface, so, if you only saw the method header (public class String implements Comparable), you would know that it contains a compareTo() method.
In your simple case, you could achieve something similar to what you get with interfaces by using a common base class that implements show() (or perhaps defines it as abstract). Let me change your generic names to something more concrete, Eagle and Hawk instead of MyClass1 and MyClass2. In that case you could write code like
Bird bird = GetMeAnInstanceOfABird(someCriteriaForSelectingASpecificKindOfBird);
bird.Fly(Direction.South, Speed.CruisingSpeed);
That lets you write code that can handle anything that is a Bird. You could then write code that causes the Bird to do its thing (fly, eat, lay eggs, and so forth) that acts on an instance it treats as a Bird. That code would work whether Bird is really an Eagle, Hawk, or anything else that derives from Bird.
That paradigm starts to get messy, though, when you don't have a true is a relationship. Say you want to write code that flies things around in the sky. If you write that code to accept a Bird base class, it suddenly becomes hard to evolve that code to work on a JumboJet instance, because while a Bird and a JumboJet can certainly both fly, a JumboJet is most certainly not a Bird.
Enter the interface.
What Bird (and Eagle, and Hawk) do have in common is that they can all fly. If you write the above code instead to act on an interface, IFly, that code can be applied to anything that provides an implementation to that interface.