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I have seen this mentioned a few times and I am not clear on what it means. When and why would you do this?
I know what interfaces do, but the fact I am not clear on this makes me think I am missing out on using them correctly.
Is it just so if you were to do:
IInterface classRef = new ObjectWhatever()
You could use any class that implements IInterface? When would you need to do that? The only thing I can think of is if you have a method and you are unsure of what object will be passed except for it implementing IInterface. I cannot think how often you would need to do that.
Also, how could you write a method that takes in an object that implements an interface? Is that possible?
There are some wonderful answers on here to this questions that get into all sorts of great detail about interfaces and loosely coupling code, inversion of control and so on. There are some fairly heady discussions, so I'd like to take the opportunity to break things down a bit for understanding why an interface is useful.
When I first started getting exposed to interfaces, I too was confused about their relevance. I didn't understand why you needed them. If we're using a language like Java or C#, we already have inheritance and I viewed interfaces as a weaker form of inheritance and thought, "why bother?" In a sense I was right, you can think of interfaces as sort of a weak form of inheritance, but beyond that I finally understood their use as a language construct by thinking of them as a means of classifying common traits or behaviors that were exhibited by potentially many non-related classes of objects.
For example -- say you have a SIM game and have the following classes:
class HouseFly inherits Insect {
void FlyAroundYourHead(){}
void LandOnThings(){}
}
class Telemarketer inherits Person {
void CallDuringDinner(){}
void ContinueTalkingWhenYouSayNo(){}
}
Clearly, these two objects have nothing in common in terms of direct inheritance. But, you could say they are both annoying.
Let's say our game needs to have some sort of random thing that annoys the game player when they eat dinner. This could be a HouseFly or a Telemarketer or both -- but how do you allow for both with a single function? And how do you ask each different type of object to "do their annoying thing" in the same way?
The key to realize is that both a Telemarketer and HouseFly share a common loosely interpreted behavior even though they are nothing alike in terms of modeling them. So, let's make an interface that both can implement:
interface IPest {
void BeAnnoying();
}
class HouseFly inherits Insect implements IPest {
void FlyAroundYourHead(){}
void LandOnThings(){}
void BeAnnoying() {
FlyAroundYourHead();
LandOnThings();
}
}
class Telemarketer inherits Person implements IPest {
void CallDuringDinner(){}
void ContinueTalkingWhenYouSayNo(){}
void BeAnnoying() {
CallDuringDinner();
ContinueTalkingWhenYouSayNo();
}
}
We now have two classes that can each be annoying in their own way. And they do not need to derive from the same base class and share common inherent characteristics -- they simply need to satisfy the contract of IPest -- that contract is simple. You just have to BeAnnoying. In this regard, we can model the following:
class DiningRoom {
DiningRoom(Person[] diningPeople, IPest[] pests) { ... }
void ServeDinner() {
when diningPeople are eating,
foreach pest in pests
pest.BeAnnoying();
}
}
Here we have a dining room that accepts a number of diners and a number of pests -- note the use of the interface. This means that in our little world, a member of the pests array could actually be a Telemarketer object or a HouseFly object.
The ServeDinner method is called when dinner is served and our people in the dining room are supposed to eat. In our little game, that's when our pests do their work -- each pest is instructed to be annoying by way of the IPest interface. In this way, we can easily have both Telemarketers and HouseFlys be annoying in each of their own ways -- we care only that we have something in the DiningRoom object that is a pest, we don't really care what it is and they could have nothing in common with other.
This very contrived pseudo-code example (that dragged on a lot longer than I anticipated) is simply meant to illustrate the kind of thing that finally turned the light on for me in terms of when we might use an interface. I apologize in advance for the silliness of the example, but hope that it helps in your understanding. And, to be sure, the other posted answers you've received here really cover the gamut of the use of interfaces today in design patterns and development methodologies.
The specific example I used to give to students is that they should write
List myList = new ArrayList(); // programming to the List interface
instead of
ArrayList myList = new ArrayList(); // this is bad
These look exactly the same in a short program, but if you go on to use myList 100 times in your program you can start to see a difference. The first declaration ensures that you only call methods on myList that are defined by the List interface (so no ArrayList specific methods). If you've programmed to the interface this way, later on you can decide that you really need
List myList = new TreeList();
and you only have to change your code in that one spot. You already know that the rest of your code doesn't do anything that will be broken by changing the implementation because you programmed to the interface.
The benefits are even more obvious (I think) when you're talking about method parameters and return values. Take this for example:
public ArrayList doSomething(HashMap map);
That method declaration ties you to two concrete implementations (ArrayList and HashMap). As soon as that method is called from other code, any changes to those types probably mean you're going to have to change the calling code as well. It would be better to program to the interfaces.
public List doSomething(Map map);
Now it doesn't matter what kind of List you return, or what kind of Map is passed in as a parameter. Changes that you make inside the doSomething method won't force you to change the calling code.
Programming to an interface is saying, "I need this functionality and I don't care where it comes from."
Consider (in Java), the List interface versus the ArrayList and LinkedList concrete classes. If all I care about is that I have a data structure containing multiple data items that I should access via iteration, I'd pick a List (and that's 99% of the time). If I know that I need constant-time insert/delete from either end of the list, I might pick the LinkedList concrete implementation (or more likely, use the Queue interface). If I know I need random access by index, I'd pick the ArrayList concrete class.
Programming to an interface has absolutely nothing to do with abstract interfaces like we see in Java or .NET. It isn't even an OOP concept.
What it means is don't go messing around with the internals of an object or data structure. Use the Abstract Program Interface, or API, to interact with your data. In Java or C# that means using public properties and methods instead of raw field access. For C that means using functions instead of raw pointers.
EDIT: And with databases it means using views and stored procedures instead of direct table access.
Using interfaces is a key factor in making your code easily testable in addition to removing unnecessary couplings between your classes. By creating an interface that defines the operations on your class, you allow classes that want to use that functionality the ability to use it without depending on your implementing class directly. If later on you decide to change and use a different implementation, you need only change the part of the code where the implementation is instantiated. The rest of the code need not change because it depends on the interface, not the implementing class.
This is very useful in creating unit tests. In the class under test you have it depend on the interface and inject an instance of the interface into the class (or a factory that allows it to build instances of the interface as needed) via the constructor or a property settor. The class uses the provided (or created) interface in its methods. When you go to write your tests, you can mock or fake the interface and provide an interface that responds with data configured in your unit test. You can do this because your class under test deals only with the interface, not your concrete implementation. Any class implementing the interface, including your mock or fake class, will do.
EDIT: Below is a link to an article where Erich Gamma discusses his quote, "Program to an interface, not an implementation."
http://www.artima.com/lejava/articles/designprinciples.html
You should look into Inversion of Control:
Martin Fowler: Inversion of Control Containers and the Dependency Injection pattern
Wikipedia: Inversion of Control
In such a scenario, you wouldn't write this:
IInterface classRef = new ObjectWhatever();
You would write something like this:
IInterface classRef = container.Resolve<IInterface>();
This would go into a rule-based setup in the container object, and construct the actual object for you, which could be ObjectWhatever. The important thing is that you could replace this rule with something that used another type of object altogether, and your code would still work.
If we leave IoC off the table, you can write code that knows that it can talk to an object that does something specific, but not which type of object or how it does it.
This would come in handy when passing parameters.
As for your parenthesized question "Also, how could you write a method that takes in an object that implements an Interface? Is that possible?", in C# you would simply use the interface type for the parameter type, like this:
public void DoSomethingToAnObject(IInterface whatever) { ... }
This plugs right into the "talk to an object that does something specific." The method defined above knows what to expect from the object, that it implements everything in IInterface, but it doesn't care which type of object it is, only that it adheres to the contract, which is what an interface is.
For instance, you're probably familiar with calculators and have probably used quite a few in your days, but most of the time they're all different. You, on the other hand, knows how a standard calculator should work, so you're able to use them all, even if you can't use the specific features that each calculator has that none of the other has.
This is the beauty of interfaces. You can write a piece of code, that knows that it will get objects passed to it that it can expect certain behavior from. It doesn't care one hoot what kind of object it is, only that it supports the behavior needed.
Let me give you a concrete example.
We have a custom-built translation system for windows forms. This system loops through controls on a form and translate text in each. The system knows how to handle basic controls, like the-type-of-control-that-has-a-Text-property, and similar basic stuff, but for anything basic, it falls short.
Now, since controls inherit from pre-defined classes that we have no control over, we could do one of three things:
Build support for our translation system to detect specifically which type of control it is working with, and translate the correct bits (maintenance nightmare)
Build support into base classes (impossible, since all the controls inherit from different pre-defined classes)
Add interface support
So we did nr. 3. All our controls implement ILocalizable, which is an interface that gives us one method, the ability to translate "itself" into a container of translation text/rules. As such, the form doesn't need to know which kind of control it has found, only that it implements the specific interface, and knows that there is a method where it can call to localize the control.
Code to the Interface Not the Implementation has NOTHING to do with Java, nor its Interface construct.
This concept was brought to prominence in the Patterns / Gang of Four books but was most probably around well before that. The concept certainly existed well before Java ever existed.
The Java Interface construct was created to aid in this idea (among other things), and people have become too focused on the construct as the centre of the meaning rather than the original intent. However, it is the reason we have public and private methods and attributes in Java, C++, C#, etc.
It means just interact with an object or system's public interface. Don't worry or even anticipate how it does what it does internally. Don't worry about how it is implemented. In object-oriented code, it is why we have public vs. private methods/attributes. We are intended to use the public methods because the private methods are there only for use internally, within the class. They make up the implementation of the class and can be changed as required without changing the public interface. Assume that regarding functionality, a method on a class will perform the same operation with the same expected result every time you call it with the same parameters. It allows the author to change how the class works, its implementation, without breaking how people interact with it.
And you can program to the interface, not the implementation without ever using an Interface construct. You can program to the interface not the implementation in C++, which does not have an Interface construct. You can integrate two massive enterprise systems much more robustly as long as they interact through public interfaces (contracts) rather than calling methods on objects internal to the systems. The interfaces are expected to always react the same expected way given the same input parameters; if implemented to the interface and not the implementation. The concept works in many places.
Shake the thought that Java Interfaces have anything what-so-ever to do with the concept of 'Program to the Interface, Not the Implementation'. They can help apply the concept, but they are not the concept.
It sounds like you understand how interfaces work but are unsure of when to use them and what advantages they offer. Here are a few examples of when an interface would make sense:
// if I want to add search capabilities to my application and support multiple search
// engines such as Google, Yahoo, Live, etc.
interface ISearchProvider
{
string Search(string keywords);
}
then I could create GoogleSearchProvider, YahooSearchProvider, LiveSearchProvider, etc.
// if I want to support multiple downloads using different protocols
// HTTP, HTTPS, FTP, FTPS, etc.
interface IUrlDownload
{
void Download(string url)
}
// how about an image loader for different kinds of images JPG, GIF, PNG, etc.
interface IImageLoader
{
Bitmap LoadImage(string filename)
}
then create JpegImageLoader, GifImageLoader, PngImageLoader, etc.
Most add-ins and plugin systems work off interfaces.
Another popular use is for the Repository pattern. Say I want to load a list of zip codes from different sources
interface IZipCodeRepository
{
IList<ZipCode> GetZipCodes(string state);
}
then I could create an XMLZipCodeRepository, SQLZipCodeRepository, CSVZipCodeRepository, etc. For my web applications, I often create XML repositories early on so I can get something up and running before the SQL Database is ready. Once the database is ready I write an SQLRepository to replace the XML version. The rest of my code remains unchanged since it runs solely off of interfaces.
Methods can accept interfaces such as:
PrintZipCodes(IZipCodeRepository zipCodeRepository, string state)
{
foreach (ZipCode zipCode in zipCodeRepository.GetZipCodes(state))
{
Console.WriteLine(zipCode.ToString());
}
}
It makes your code a lot more extensible and easier to maintain when you have sets of similar classes. I am a junior programmer, so I am no expert, but I just finished a project that required something similar.
I work on client side software that talks to a server running a medical device. We are developing a new version of this device that has some new components that the customer must configure at times. There are two types of new components, and they are different, but they are also very similar. Basically, I had to create two config forms, two lists classes, two of everything.
I decided that it would be best to create an abstract base class for each control type that would hold almost all of the real logic, and then derived types to take care of the differences between the two components. However, the base classes would not have been able to perform operations on these components if I had to worry about types all of the time (well, they could have, but there would have been an "if" statement or switch in every method).
I defined a simple interface for these components and all of the base classes talk to this interface. Now when I change something, it pretty much 'just works' everywhere and I have no code duplication.
A lot of explanation out there, but to make it even more simpler. Take for instance a List. One can implement a list with as:
An internal array
A linked list
Other implementations
By building to an interface, say a List. You only code as to definition of List or what List means in reality.
You could use any type of implementation internally say an array implementation. But suppose you wish to change the implementation for some reason say a bug or performance. Then you just have to change the declaration List<String> ls = new ArrayList<String>() to List<String> ls = new LinkedList<String>().
Nowhere else in code, will you have to change anything else; Because everything else was built on the definition of List.
If you program in Java, JDBC is a good example. JDBC defines a set of interfaces but says nothing about the implementation. Your applications can be written against this set of interfaces. In theory, you pick some JDBC driver and your application would just work. If you discover there's a faster or "better" or cheaper JDBC driver or for whatever reason, you can again in theory re-configure your property file, and without having to make any change in your application, your application would still work.
I am a late comer to this question, but I want to mention here that the line "Program to an interface, not an implementation" had some good discussion in the GoF (Gang of Four) Design Patterns book.
It stated, on p. 18:
Program to an interface, not an implementation
Don't declare variables to be instances of particular concrete classes. Instead, commit only to an interface defined by an abstract class. You will find this to be a common theme of the design patterns in this book.
and above that, it began with:
There are two benefits to manipulating objects solely in terms of the interface defined by abstract classes:
Clients remain unaware of the specific types of objects they use, as long as the objects adhere to the interface that clients expect.
Clients remain unaware of the classes that implement these objects. Clients only know about the abstract class(es) defining the interface.
So in other words, don't write it your classes so that it has a quack() method for ducks, and then a bark() method for dogs, because they are too specific for a particular implementation of a class (or subclass). Instead, write the method using names that are general enough to be used in the base class, such as giveSound() or move(), so that they can be used for ducks, dogs, or even cars, and then the client of your classes can just say .giveSound() rather than thinking about whether to use quack() or bark() or even determine the type before issuing the correct message to be sent to the object.
Programming to Interfaces is awesome, it promotes loose coupling. As #lassevk mentioned, Inversion of Control is a great use of this.
In addition, look into SOLID principals. here is a video series
It goes through a hard coded (strongly coupled example) then looks at interfaces, finally progressing to a IoC/DI tool (NInject)
To add to the existing posts, sometimes coding to interfaces helps on large projects when developers work on separate components simultaneously. All you need is to define interfaces upfront and write code to them while other developers write code to the interface you are implementing.
It can be advantageous to program to interfaces, even when we are not depending on abstractions.
Programming to interfaces forces us to use a contextually appropriate subset of an object. That helps because it:
prevents us from doing contextually inappropriate things, and
lets us safely change the implementation in the future.
For example, consider a Person class that implements the Friend and the Employee interface.
class Person implements AbstractEmployee, AbstractFriend {
}
In the context of the person's birthday, we program to the Friend interface, to prevent treating the person like an Employee.
function party() {
const friend: Friend = new Person("Kathryn");
friend.HaveFun();
}
In the context of the person's work, we program to the Employee interface, to prevent blurring workplace boundaries.
function workplace() {
const employee: Employee = new Person("Kathryn");
employee.DoWork();
}
Great. We have behaved appropriately in different contexts, and our software is working well.
Far into the future, if our business changes to work with dogs, we can change the software fairly easily. First, we create a Dog class that implements both Friend and Employee. Then, we safely change new Person() to new Dog(). Even if both functions have thousands of lines of code, that simple edit will work because we know the following are true:
Function party uses only the Friend subset of Person.
Function workplace uses only the Employee subset of Person.
Class Dog implements both the Friend and Employee interfaces.
On the other hand, if either party or workplace were to have programmed against Person, there would be a risk of both having Person-specific code. Changing from Person to Dog would require us to comb through the code to extirpate any Person-specific code that Dog does not support.
The moral: programming to interfaces helps our code to behave appropriately and to be ready for change. It also prepares our code to depend on abstractions, which brings even more advantages.
If I'm writing a new class Swimmer to add the functionality swim() and need to use an object of class say Dog, and this Dog class implements interface Animal which declares swim().
At the top of the hierarchy (Animal), it's very abstract while at the bottom (Dog) it's very concrete. The way I think about "programming to interfaces" is that, as I write Swimmer class, I want to write my code against the interface that's as far up that hierarchy which in this case is an Animal object. An interface is free from implementation details and thus makes your code loosely-coupled.
The implementation details can be changed with time, however, it would not affect the remaining code since all you are interacting with is with the interface and not the implementation. You don't care what the implementation is like... all you know is that there will be a class that would implement the interface.
It is also good for Unit Testing, you can inject your own classes (that meet the requirements of the interface) into a class that depends on it
Short story: A postman is asked to go home after home and receive the covers contains (letters, documents, cheques, gift cards, application, love letter) with the address written on it to deliver.
Suppose there is no cover and ask the postman to go home after home and receive all the things and deliver to other people, the postman can get confused.
So better wrap it with cover (in our story it is the interface) then he will do his job fine.
Now the postman's job is to receive and deliver the covers only (he wouldn't bothered what is inside in the cover).
Create a type of interface not actual type, but implement it with actual type.
To create to interface means your components get Fit into the rest of code easily
I give you an example.
you have the AirPlane interface as below.
interface Airplane{
parkPlane();
servicePlane();
}
Suppose you have methods in your Controller class of Planes like
parkPlane(Airplane plane)
and
servicePlane(Airplane plane)
implemented in your program. It will not BREAK your code.
I mean, it need not to change as long as it accepts arguments as AirPlane.
Because it will accept any Airplane despite actual type, flyer, highflyr, fighter, etc.
Also, in a collection:
List<Airplane> plane; // Will take all your planes.
The following example will clear your understanding.
You have a fighter plane that implements it, so
public class Fighter implements Airplane {
public void parkPlane(){
// Specific implementations for fighter plane to park
}
public void servicePlane(){
// Specific implementatoins for fighter plane to service.
}
}
The same thing for HighFlyer and other clasess:
public class HighFlyer implements Airplane {
public void parkPlane(){
// Specific implementations for HighFlyer plane to park
}
public void servicePlane(){
// specific implementatoins for HighFlyer plane to service.
}
}
Now think your controller classes using AirPlane several times,
Suppose your Controller class is ControlPlane like below,
public Class ControlPlane{
AirPlane plane;
// so much method with AirPlane reference are used here...
}
Here magic comes as you may make your new AirPlane type instances as many as you want and you are not changing the code of ControlPlane class.
You can add an instance...
JumboJetPlane // implementing AirPlane interface.
AirBus // implementing AirPlane interface.
You may remove instances of previously created types too.
So, just to get this right, the advantage of a interface is that I can separate the calling of a method from any particular class. Instead creating a instance of the interface, where the implementation is given from whichever class I choose that implements that interface. Thus allowing me to have many classes, which have similar but slightly different functionality and in some cases (the cases related to the intention of the interface) not care which object it is.
For example, I could have a movement interface. A method which makes something 'move' and any object (Person, Car, Cat) that implements the movement interface could be passed in and told to move. Without the method every knowing the type of class it is.
Imagine you have a product called 'Zebra' that can be extended by plugins. It finds the plugins by searching for DLLs in some directory. It loads all those DLLs and uses reflection to find any classes that implement IZebraPlugin, and then calls the methods of that interface to communicate with the plugins.
This makes it completely independent of any specific plugin class - it doesn't care what the classes are. It only cares that they fulfill the interface specification.
Interfaces are a way of defining points of extensibility like this. Code that talks to an interface is more loosely coupled - in fact it is not coupled at all to any other specific code. It can inter-operate with plugins written years later by people who have never met the original developer.
You could instead use a base class with virtual functions - all plugins would be derived from the base class. But this is much more limiting because a class can only have one base class, whereas it can implement any number of interfaces.
C++ explanation.
Think of an interface as your classes public methods.
You then could create a template that 'depends' on these public methods in order to carry out it's own function (it makes function calls defined in the classes public interface). Lets say this template is a container, like a Vector class, and the interface it depends on is a search algorithm.
Any algorithm class that defines the functions/interface Vector makes calls to will satisfy the 'contract' (as someone explained in the original reply). The algorithms don't even need to be of the same base class; the only requirement is that the functions/methods that the Vector depends on (interface) is defined in your algorithm.
The point of all of this is that you could supply any different search algorithm/class just as long as it supplied the interface that Vector depends on (bubble search, sequential search, quick search).
You might also want to design other containers (lists, queues) that would harness the same search algorithm as Vector by having them fulfill the interface/contract that your search algorithms depends on.
This saves time (OOP principle 'code reuse') as you are able to write an algorithm once instead of again and again and again specific to every new object you create without over-complicating the issue with an overgrown inheritance tree.
As for 'missing out' on how things operate; big-time (at least in C++), as this is how most of the Standard TEMPLATE Library's framework operates.
Of course when using inheritance and abstract classes the methodology of programming to an interface changes; but the principle is the same, your public functions/methods are your classes interface.
This is a huge topic and one of the the cornerstone principles of Design Patterns.
In Java these concrete classes all implement the CharSequence interface:
CharBuffer, String, StringBuffer, StringBuilder
These concrete classes do not have a common parent class other than Object, so there is nothing that relates them, other than the fact they each have something to do with arrays of characters, representing such, or manipulating such. For instance, the characters of String cannot be changed once a String object is instantiated, whereas the characters of StringBuffer or StringBuilder can be edited.
Yet each one of these classes is capable of suitably implementing the CharSequence interface methods:
char charAt(int index)
int length()
CharSequence subSequence(int start, int end)
String toString()
In some cases, Java class library classes that used to accept String have been revised to now accept the CharSequence interface. So if you have an instance of StringBuilder, instead of extracting a String object (which means instantiating a new object instance), it can instead just pass the StringBuilder itself as it implements the CharSequence interface.
The Appendable interface that some classes implement has much the same kind of benefit for any situation where characters can be appended to an instance of the underlying concrete class object instance. All of these concrete classes implement the Appendable interface:
BufferedWriter, CharArrayWriter, CharBuffer, FileWriter, FilterWriter, LogStream, OutputStreamWriter, PipedWriter, PrintStream, PrintWriter, StringBuffer, StringBuilder, StringWriter, Writer
Previous answers focus on programming to an abstraction for the sake of extensibility and loose coupling. While these are very important points,
readability is equally important. Readability allows others (and your future self) to understand the code with minimal effort. This is why readability leverages abstractions.
An abstraction is, by definition, simpler than its implementation. An abstraction omits detail in order to convey the essence or purpose of a thing, but nothing more.
Because abstractions are simpler, I can fit a lot more of them in my head at one time, compared to implementations.
As a programmer (in any language) I walk around with a general idea of a List in my head at all times. In particular, a List allows random access, duplicate elements, and maintains order. When I see a declaration like this: List myList = new ArrayList() I think, cool, this is a List that's being used in the (basic) way that I understand; and I don't have to think any more about it.
On the other hand, I do not carry around the specific implementation details of ArrayList in my head. So when I see, ArrayList myList = new ArrayList(). I think, uh-oh, this ArrayList must be used in a way that isn't covered by the List interface. Now I have to track down all the usages of this ArrayList to understand why, because otherwise I won't be able to fully understand this code. It gets even more confusing when I discover that 100% of the usages of this ArrayList do conform to the List interface. Then I'm left wondering... was there some code relying on ArrayList implementation details that got deleted? Was the programmer who instantiated it just incompetent? Is this application locked into that specific implementation in some way at runtime? A way that I don't understand?
I'm now confused and uncertain about this application, and all we're talking about is a simple List. What if this was a complex business object ignoring its interface? Then my knowledge of the business domain is insufficient to understand the purpose of the code.
So even when I need a List strictly within a private method (nothing that would break other applications if it changed, and I could easily find/replace every usage in my IDE) it still benefits readability to program to an abstraction. Because abstractions are simpler than implementation details. You could say that programming to abstractions is one way of adhering to the KISS principle.
An interface is like a contract, where you want your implementation class to implement methods written in the contract (interface). Since Java does not provide multiple inheritance, "programming to interface" is a good way to achieve multiple inheritance.
If you have a class A that is already extending some other class B, but you want that class A to also follow certain guidelines or implement a certain contract, then you can do so by the "programming to interface" strategy.
Q: - ... "Could you use any class that implements an interface?"
A: - Yes.
Q: - ... "When would you need to do that?"
A: - Each time you need a class(es) that implements interface(s).
Note: We couldn't instantiate an interface not implemented by a class - True.
Why?
Because the interface has only method prototypes, not definitions (just functions names, not their logic)
AnIntf anInst = new Aclass();
// we could do this only if Aclass implements AnIntf.
// anInst will have Aclass reference.
Note: Now we could understand what happened if Bclass and Cclass implemented same Dintf.
Dintf bInst = new Bclass();
// now we could call all Dintf functions implemented (defined) in Bclass.
Dintf cInst = new Cclass();
// now we could call all Dintf functions implemented (defined) in Cclass.
What we have: Same interface prototypes (functions names in interface), and call different implementations.
Bibliography:
Prototypes - wikipedia
program to an interface is a term from the GOF book. i would not directly say it has to do with java interface but rather real interfaces. to achieve clean layer separation, you need to create some separation between systems for example: Let's say you had a concrete database you want to use, you would never "program to the database" , instead you would "program to the storage interface". Likewise you would never "program to a Web Service" but rather you would program to a "client interface". this is so you can easily swap things out.
i find these rules help me:
1. we use a java interface when we have multiple types of an object. if i just have single object, i dont see the point. if there are at least two concrete implementations of some idea, then i would use a java interface.
2. if as i stated above, you want to bring decoupling from an external system (storage system) to your own system (local DB) then also use a interface.
notice how there are two ways to consider when to use them.
Coding to an interface is a philosophy, rather than specific language constructs or design patterns - it instructs you what is the correct order of steps to follow in order to create better software systems (e.g. more resilient, more testable, more scalable, more extendible, and other nice traits).
What it actually means is:
===
Before jumping to implementations and coding (the HOW) - think of the WHAT:
What black boxes should make up your system,
What is each box' responsibility,
What are the ways each "client" (that is, one of those other boxes, 3rd party "boxes", or even humans) should communicate with it (the API of each box).
After you figure the above, go ahead and implement those boxes (the HOW).
Thinking first of what a box' is and what its API, leads the developer to distil the box' responsibility, and to mark for himself and future developers the difference between what is its exposed details ("API") and it's hidden details ("implementation details"), which is a very important differentiation to have.
One immediate and easily noticeable gain is the team can then change and improve implementations without affecting the general architecture. It also makes the system MUCH more testable (it goes well with the TDD approach).
===
Beyond the traits I've mentioned above, you also save A LOT OF TIME going this direction.
Micro Services and DDD, when done right, are great examples of "Coding to an interface", however the concept wins in every pattern from monoliths to "serverless", from BE to FE, from OOP to functional, etc....
I strongly recommend this approach for Software Engineering (and I basically believe it makes total sense in other fields as well).
Program to an interface allows to change implementation of contract defined by interface seamlessly. It allows loose coupling between contract and specific implementations.
IInterface classRef = new ObjectWhatever()
You could use any class that implements IInterface? When would you need to do that?
Have a look at this SE question for good example.
Why should the interface for a Java class be preferred?
does using an Interface hit performance?
if so how much?
Yes. It will have slight performance overhead in sub-seconds. But if your application has requirement to change the implementation of interface dynamically, don't worry about performance impact.
how can you avoid it without having to maintain two bits of code?
Don't try to avoid multiple implementations of interface if your application need them. In absence of tight coupling of interface with one specific implementation, you may have to deploy the patch to change one implementation to other implementation.
One good use case: Implementation of Strategy pattern:
Real World Example of the Strategy Pattern
"Program to interface" means don't provide hard code right the way, meaning your code should be extended without breaking the previous functionality. Just extensions, not editing the previous code.
Also I see a lot of good and explanatory answers here, so I want to give my point of view here, including some extra information what I noticed when using this method.
Unit testing
For the last two years, I have written a hobby project and I did not write unit tests for it. After writing about 50K lines I found out it would be really necessary to write unit tests.
I did not use interfaces (or very sparingly) ... and when I made my first unit test, I found out it was complicated. Why?
Because I had to make a lot of class instances, used for input as class variables and/or parameters. So the tests look more like integration tests (having to make a complete 'framework' of classes since all was tied together).
Fear of interfaces
So I decided to use interfaces. My fear was that I had to implement all functionality everywhere (in all used classes) multiple times. In some way this is true, however, by using inheritance it can be reduced a lot.
Combination of interfaces and inheritance
I found out the combination is very good to be used. I give a very simple example.
public interface IPricable
{
int Price { get; }
}
public interface ICar : IPricable
public abstract class Article
{
public int Price { get { return ... } }
}
public class Car : Article, ICar
{
// Price does not need to be defined here
}
This way copying code is not necessary, while still having the benefit of using a car as interface (ICar).
A recent question here made me rethink this whole helper classes are anti pattern thing.
asawyer pointed out a few links in the comments to that question:
Helper classes is an anti-pattern.
While those links go into detail how helperclasses collide with the well known principles of oop some things are still unclear to me.
For example "Do not repeat yourself". How can you acchieve this without creating some sort of helper?
I thought you could derive a certain type and provide some features for it.
But I bellieve that isnt practical all the time.
Lets take a look at the following example,
please keep in mind I tried not to use any higher language features nor "languagespecific" stuff. So this might been ugly nested and not optimal...
//Check if the string is full of whitepsaces
bool allWhiteSpace = true;
if(input == null || input.Length == 0)
allWhiteSpace = false;
else
{
foreach(char c in input)
{
if( c != ' ')
{
allWhiteSpace = false;
break;
}
}
}
Lets create a bad helper class called StringHelper, the code becomes shorter:
bool isAllWhiteSpace = StringHelper.IsAllWhiteSpace(input);
So since this isnt the only time we need to check this, i guess "Do not repeat yourself" is fullfilled here.
How do we acchieve this without a helper ? Considering that this piece of Code isn't bound to a single class?
Do we need to inherit string and call it BetterString ?
bool allWhiteSpace = better.IsAllWhiteSpace;
or do we create a class? StringChecker
StringChecker checker = new StringChecker();
bool allWhiteSpace = checker.IsAllwhiteSpace(input);
So how do we acchieve this?
Some languages (e.g. C#) allow the use of ExtensionMethods. Do they count as helperclasses aswell? I tend to prefer those over helperclasses.
Helper classes may be bad (there are always exceptions) because a well-designed OO system will have clearly understood responsibilities for each class. For example, a List is responsible for managing an ordered list of items. Some people new to OOD who discover that a class has methods to do stuff with its data sometimes ask "why doesn't List have a dispayOnGUI method (or similar such thing)?". The answer is that it is not the responsibility of List to be concerned with the GUI.
If you call a class a "Helper" it really doesn't say anything about what that class is supposed to do.
A typical scenario is that there will be some class and someone decides it is getting too big and carves it up into two smaller classes, one of which is a helper. It often isn't really clear what methods should go in the helper and what methods should stay in the original class: the responsibility of the helper is not defined.
It is hard to explain unless you are experienced with OOD, but let me show by an analogy. By the way, I find this analogy extremely powerful:
Imagine you have a large team in which there are members with different job designations: e.g, front-end developers, back-end developers, testers, analysts, project managers, support engineers, integration specialists, etc. (as you like).
Each role you can think of as a class: it has certain responsibilities and the people fulfilling those responsibilities hopefully have the necessary knowledge to execute them. These roles will interact in a similar way to classes interacting.
Now imagine it is discovered that the back-end developers find their job too complicated. You can hire more if it is simply a throughput problem, but perhaps the problem is that the task requires too much knowledge across too many domains. It is decided to split up the back-end developer role by creating a new role, and maybe hire new people to fill it.
How helpful would it be if that new job description was "Back-end developer helper"? Not very ... the applicants are likely to be given a haphazard set of tasks, they may get confused about what they are supposed to do, their co-workers may not understand what they are supposed to do.
More seriously, the knowledge of the helpers may have to be exactly the same as the original developers as we haven't really narrowed down the actual responsibilities.
So "Helper" isn't really saying anything in terms of defining what the responsibilities of the new role are. Instead, it would be better to split-off, for example, the database part of the role, so "Back-end developer" is split into "Back-end developer" and "Database layer developer".
Calling a class a helper has the same problem and the solution is the same solution. You should think more about what the responsibilities of the new class should be. Ideally, it should not just shave-off some methods, but should also take some data with it that it is responsible for managing and thereby create a solution that is genuinely simpler to understand piece by piece than the original large class, rather than simply placing the same complicated logic in two different places.
I have found in some cases that a helper class is well designed, but all it lacks is a good name. In this case, calling it "Builder" or "Formatter" or "Context" instead of "Helper" immediately makes the solution far easier to understand.
Disclaimer: the following answer is based on my own experience and I'm not making a point of right and wrong.
IMHO, Helper classes are neither good nor bad, it all depends on your business/domain logic and your software architecture.
Here's Why:
lets say that we need to implement the idea of white spaces you proposed, so first I will ask my self.
When would I need to check against white spaces?
Hence, imagine the following scenario: a blogging system with Users, Posts, Comments. Thus, I would have three Classes:
Class User{}
Class Post{}
Class Comment{}
each class would have some field that is a string type. Anyway, I would need to validate these fields so I would create something like:
Class UserValidator{}
Class PostValidator{}
Class CommentValidator{}
and I would place my validation policies in those three classes. But WAIT! all of the aforementioned classes needs a check against null or all whitespaces? Ummmm....
the best solution is to take it higher in the tree and put it in some Father class called Validator:
Class Validator{
//some code
bool function is_all_whitespaces(){}
}
so, if you need the function is_all_whitespaces(){} to be abstract ( with class validator being abstract too) or turn it into an interface that would be another issue and it depends on your way of thinking mostly.
back to the point in this case I would have my classes ( for the sake of giving an example ) look like:
Class UserValidator inherits Validator{}
Class PostValidator inherits Validator{}
Class CommentValidator inherits Validator{}
in this case I really don't need the helper at all. but lets say that you have a function called multiD_array_group_by_key
and you are using it in different positions, but you don't like to have it in some OOP structured place you can have in some ArrayHelper but by that you are a step behind from being fully object oriented.
Q1.
In my university studies of object-oriented modelling and design they recommend thinking about what an object can do for its method, and what its responsibilities are for its attributes. All attempts at clarification have resulted in further confusion.
This tends to generate a class diagram with actors who have all the actions, and inner classes which only hold data.
This doesn't seem correct. Is there another way of thinking about how to model the objects?
Q2. Also, the course seems to emphasize modelling the objects after their real-world counterparts but it doesn't necessarily make sense in the domain model. IE. In a medical practice, they have Patient: CreateAppointment(), CancelAppointment() but that is not how it would be implemented (you would modify a the appointment collection instead). Is there another way of thinking about this?
Example Q1
Secretary: RecordAppointment(), RecordAppointmentCancellation()
Appointment: time, date,... (no methods)
Example Q2
Doctor: SeePatient()
While SeePatient is a use-case, it does not make sense for a method on the actual class. How do you think about this?
Unfortunately, the roadblock you've hit is all too typical in academia. Academic projects tend to start with video rental stores, libraries or student registration systems (yours is a variance of this with a doctor's office) and then inheritance is taught with animals. The guideline you've provided is also very typical
they recommend thinking about what an object can do for its method, and what its responsibilities are for its attributes
In fact when beginners ask I usually explain an object's property's are the things it knows about itself and its methods are the things it knows how to do. Which is really just another way of saying exactly what you have there. As you've discovered this way of thinking quickly breaks down when you start discussing more tangible systems and not just examples.
For instance the guideline works pretty well with this object:
public class Tree
{
public int Height { get; set; }
public void Grow(int byHowMuch)
{
Height += byHowMuch;
}
}
While this certainly fits the bill your right to think that it doesn't "feel" right:
public class Secretary
{
public void MakeAppoinment(Patient patient)
{
//make the appointment
}
}
So what's the solution? It's a matter of taking what you are being taught and applying it. Learning and understanding design patterns will help a lot with developing systems which are more functional than a tree that knows how to grow.
Recommended reading:
Design Patterns: Elements of Reusable Object-Oriented Software (also known as the Gang of Four or GoF)
Head First Design Patterns
Head First Object-Oriented Analysis and Design
To solve the issue you're been presented I would probably use a combination of inherited person classes and interfaces, which would perform their actions through a series of service classes. Essentially a secretary, doctor, and patient would all inherit from person and each of these classes could be passed to accompanying service classes. The service classes may or may not do things like SeePatient(). Please don't take this example to mean that person classes wouldn't have methods.
Stack Overflow has more than a few related questions which may be of use:
Is Single Responsibility Principle a rule of OOP?
Are there any rules for OOP?
why is OOP hard for me?
Additionally, it would be good to check out:
Single responsibility principle
Don't repeat yourself
PrinciplesOfOod
Finally, there isn't a single definition of what makes an application object oriented. How you apply patterns, principles etc. will define your program. The fact that you are asking yourself these questions shows that you are on the right track.
Q1
Is it possible responsibilities of your objects should be interpreted as authorization or contract requirements, as in what actions they should take? So, to take a medical example from your Q2, an object with a Scheduler role (think C#/Java interface, or Obj-C protocol) has attributes around CanEditAppointments or EditsAppointments.
Q2
From a use case perspective, a patient may be able to create an appointment, and so you might implement a Patient in your object model with a method to CreateAppointment(). But, in terms of encapsulation, you would likely instantiate an Appointment object in CreateAppointment(), and then call methods or set properties on the Appointment object to set its time, date, patient, physician, etc.
And because the Appointment collection is likely to be permanent storage like a database, it would likely be the Appointment object's responsibility to add itself to the collection (Appointment.Schedule() goes through your data access layer to save itself to the database).
That also ties back to your Q1, in that the Appointment object's responsibility is to save itself, so it might implement an ISaveAppointment interface that requires fields and methods to carry it out. It also is the Appointment's responsibility to have a date, and time, and patient, etc., before being saved, and so the ISaveAppointment interface should require they exist, and Appointment.Schedule() should validate the values are correct or have been previously validated.
You are right that in many cases there are higher order things which more naturally contain behaviour, like the system, or the user.
You can model this behaviour in classes as static methods which operate on the data model. It isn't OO, but it's fine. You can group related methods together into such classes, and soon you have the notion of "services", as in service oriented programming.
In Java there are specifications and standards for creating such classes, namely the stateless session bean in EJB. The Spring Framework has similar notions with the stereotype "Service" which can be applied to classes to tag them as being facades for business logic.
A service is then a component which encapsulates a certain functionality or behaviour in the system. It operates on a given object model (either its own internal one, or the more general business object model from the system). If you take your use cases and create services which relate directly to them, you can write very maintainable software.
The DCI Architecture is a formalisation of this and an attempt to do the same, but at the same time trying to stay true to object orientation, by adding behaviour to objects as they need it.
I still experience the confusion: "am I telling you to do something else" or "am I doing something someone else asked of me"?
Perhaps all you have to do is play Barbie's, or G.I. Joe's to understand object interaction and where responsibilities go. G.I. Joe got wounded (or Barbie broke a nail) so he calls the Dr's office. "Hey doc, this is Joe, I need an appointment." So you, the kid, tell Barbie to go to the doctor, who needs to know the doc to call and how to call - a reference and public MakeAppointment() method. The Dr. office needs to put the appointment on the books - it's own BookAppointment() method that is the office's procedure for handling appointment requests.
public abstract GenderAppropriateDolly {
protected DrOffice Drkilldare;
public override MakeAppointment() {throw new NotImplementedException();}
}
public class GIJoe : GenderAppropriateDolly {
DrKilldare = new DrOffice();
List<Appointment> myAppointments = new List<Appointment>;
public void MakeAppointment () {
myAppointments.Add(DrKilldare.BookAppointment(this));
}
}
public class DrOffice {
List<Appointment> officeAppointments = new List<Appointments>;
public Appointment BookAppointment(GenderAppropriateDolly forWhom) {
Appointment newappt = new Appointment(formWhom);
this.Appointments.Add(newappt);
return newappt;
}
}
public class Kid {
GenderAppropriateDolly myRoleModel = new GIJoe();
// Joe got wounded so ...
myRoleModel.MakeAppointment();
}
I saw this in someone's code and thought wow, that's an elegant way to solve this particular problem, but it probably violates good OO principles in an epic way.
In the constructor for a set of classes that are all derived from a common base class, he requires a reference to the instancing class to be passed. For example,
Foo Foo_i = new(this);
Then later on Foo would call methods in the instancing class to get information about itself and the other objects contained by the instancing class.
On the one hand, this simplifies a TON of code that models a 5-layer tree structure in hardware (agents plugged into ports on multiple switches, etc). On the other hand, these objects are pretty tightly coupled to each other in a way that seems pretty wrong, but I don't know enough about OOA&D to put my finger on it.
So, is this okay? Or is this the OO equivalent to a goto statement?
You shoud try to avoid mutual references (especially when implemeting containment) but oftentimes they are impossible to avoid. I.e. parent child relationship - children often need to know the parent and notify it if some events happen. If you really need to do that - opt for interfaces (or abstract classes in case of C++).
So you instancing class should implement some interface, and the instanciated class should know it only as interface - this will sigificantly reduce coupling. In some respect this approach is similar to nested listener class as it exposes only part of the class, but it is easier to maintain. Here is little C# example:
interface IParent
{
//some methods here
}
class Child
{
// child will know parent (instancing class) as interface only
private readonly IParent parent_;
public Child(IParent parent)
{
parent_ = parent;
}
}
class Parent : IParent
{
// IParent implementation and other methods here
}
This sounds like it could be violating the Law of Demeter, depending on how much Foo needs to know to fish around in the instancing class. Objects should preferably be loosely coupled. You'd rather not have one class need to know a lot about the structure of another class. One example I've heard a few times is that you wouldn't hand your wallet over to a store clerk and let him fish around inside. Your wallet is your business, and you'll find what you need to give the clerk and hand it over yourself. You can reorganize your wallet and nobody will be the wiser. Looser coupling makes testing easier. Foo should ideally be testable without needing to maintain a complex context.
I try and avoid this if I can just from an information hiding point of view. The less information a class has or needs the easier it is to test and verify. That being said, it does lead to more elegant solutions in some cases so if not doing it is horribly convoluted involving an awful lot of parameter passing then by all means go for it.
Java for example uses this a lot with inner classes:
public class Outer {
private class Inner {
public Inner() {
// has access to the members of Outer for the instance that instantiated it
}
}
}
In Java, I remember avoiding this once by subclassing certain Listeners and Adapters in my controller and adding those listeners and adapters to my subclasses.
In other words my controller was
class p {
private member x
private methods
private class q {
// methods referencing p's private members and methods
}
x.setListener(new q());
}
I think this is more loosely coupled, but I would also like some confirmation.
This design pattern can make a lot of sense in some situations. For example, iterators are always associated with a specific collection, so it makes sense for the iterator's constructor to require a collection.
You didn't provide a concrete example, but if the class reminds you of goto, it probably is a bad idea.
You said the new object must interrogate the instantiating object for information. Perhaps the class makes too many assumptions about its environment? If those assumptions complicate unit testing, debugging, or (non-hypothetical) code reuse, then you should consider refactoring.
But if the design saves developer time overall and you don't expect an unmaintainable beast in two years' time, the practice is completely acceptable from a practical standpoint.
I must confess I'm somewhat of an OOP skeptic. Bad pedagogical and laboral experiences with object orientation didn't help. So I converted into a fervent believer in Visual Basic (the classic one!).
Then one day I found out C++ had changed and now had the STL and templates. I really liked that! Made the language useful. Then another day MS decided to apply facial surgery to VB, and I really hated the end result for the gratuitous changes (using "end while" instead of "wend" will make me into a better developer? Why not drop "next" for "end for", too? Why force the getter alongside the setter? Etc.) plus so much Java features which I found useless (inheritance, for instance, and the concept of a hierarchical framework).
And now, several years afterwards, I find myself asking this philosophical question: Is inheritance really needed?
The gang-of-four say we should favor object composition over inheritance. And after thinking of it, I cannot find something you can do with inheritance you cannot do with object aggregation plus interfaces. So I'm wondering, why do we even have it in the first place?
Any ideas? I'd love to see an example of where inheritance would be definitely needed, or where using inheritance instead of composition+interfaces can lead to a simpler and easier to modify design. In former jobs I've found if you need to change the base class, you need to modify also almost all the derived classes for they depended on the behaviour of parent. And if you make the base class' methods virtual... then not much code sharing takes place :(
Else, when I finally create my own programming language (a long unfulfilled desire I've found most developers share), I'd see no point in adding inheritance to it...
Really really short answer: No. Inheritance is not needed because only byte code is truly needed. But obviously, byte code or assemble is not a practically way to write your program. OOP is not the only paradigm for programming. But, I digress.
I went to college for computer science in the early 2000s when inheritance (is a), compositions (has a), and interfaces (does a) were taught on an equal footing. Because of this, I use very little inheritance because it is often suited better by composition. This was stressed because many of the professors had seen bad code (along with what you have described) because of abuse of inheritance.
Regardless of creating a language with or without inheritances, can you create a programming language which prevents bad habits and bad design decisions?
I think asking for situations where inheritance is really needed is missing the point a bit. You can fake inheritance by using an interface and some composition. This doesnt mean inheritance is useless. You can do anything you did in VB6 in assembly code with some extra typing, that doesn't mean VB6 was useless.
I usually just start using an interface. Sometimes I notice I actually want to inherit behaviour. That usually means I need a base class. It's that simple.
Inheritance defines an "Is-A" relationship.
class Point( object ):
# some set of features: attributes, methods, etc.
class PointWithMass( Point ):
# An additional feature: mass.
Above, I've used inheritance to formally declare that PointWithMass is a Point.
There are several ways to handle object P1 being a PointWithMass as well as Point. Here are two.
Have a reference from PointWithMass object p1 to some Point object p1-friend. The p1-friend has the Point attributes. When p1 needs to engage in Point-like behavior, it needs to delegate the work to its friend.
Rely on language inheritance to assure that all features of Point are also applicable to my PointWithMass object, p1. When p1 needs to engage in Point-like behavior, it already is a Point object and can just do what needs to be done.
I'd rather not manage the extra objects floating around to assure that all superclass features are part of a subclass object. I'd rather have inheritance to be sure that each subclass is an instance of it's own class, plus is an instance of all superclasses, too.
Edit.
For statically-typed languages, there's a bonus. When I rely on the language to handle this, a PointWithMass can be used anywhere a Point was expected.
For really obscure abuse of inheritance, read about C++'s strange "composition through private inheritance" quagmire. See Any sensible examples of creating inheritance without creating subtyping relations? for some further discussion on this. It conflates inheritance and composition; it doesn't seem to add clarity or precision to the resulting code; it only applies to C++.
The GoF (and many others) recommend that you only favor composition over inheritance. If you have a class with a very large API, and you only want to add a very small number of methods to it, leaving the base implementation alone, I would find it inappropriate to use composition. You'd have to re-implement all of the public methods of the encapsulated class to just return their value. This is a waste of time (programmer and CPU) when you can just inherit all of this behavior, and spend your time concentrating on new methods.
So, to answer your question, no you don't absolutely need inheritance. There are, however, many situations where it's the right design choice.
The problem with inheritance is that it conflates the issue of sub-typing (asserting an is-a relationship) and code reuse (e.g., private inheritance is for reuse only).
So, no it's an overloaded word that we don't need. I'd prefer sub-typing (using the 'implements' keyword) and import (kinda like Ruby does it in class definitions)
Inheritance lets me push off a whole bunch of bookkeeping onto the compiler because it gives me polymorphic behavior for object hierarchies that I would otherwise have to create and maintain myself. Regardless of how good a silver bullet OOP is, there will always be instances where you want to employ a certain type of behavior because it just makes sense to do. And ultimately, that's the point of OOP: it makes a certain class of problems much easier to solve.
The downsides of composition is that it may disguise the relatedness of elements and it may be harder for others to understand. With,say, a 2D Point class and the desire to extend it to higher dimensions, you would presumably have to add (at least) Z getter/setter, modify getDistance(), and maybe add a getVolume() method. So you have the Objects 101 elements: related state and behavior.
A developer with a compositional mindset would presumably have defined a getDistance(x, y) -> double method and would now define a getDistance(x, y, z) -> double method. Or, thinking generally, they might define a getDistance(lambdaGeneratingACoordinateForEveryAxis()) -> double method. Then they would probably write createTwoDimensionalPoint() and createThreeDimensionalPoint() factory methods (or perhaps createNDimensionalPoint(n) ) that would stitch together the various state and behavior.
A developer with an OO mindset would use inheritance. Same amount of complexity in the implementation of domain characteristics, less complexity in terms of initializing the object (constructor takes care of it vs. a Factory method), but not as flexible in terms of what can be initialized.
Now think about it from a comprehensibility / readability standpoint. To understand the composition, one has a large number of functions that are composed programmatically inside another function. So there's little in terms of static code 'structure' (files and keywords and so forth) that makes the relatedness of Z and distance() jump out. In the OO world, you have a great big flashing red light telling you the hierarchy. Additionally, you have an essentially universal vocabulary to discuss structure, widely known graphical notations, a natural hierarchy (at least for single inheritance), etc.
Now, on the other hand, a well-named and constructed Factory method will often make explicit more of the sometimes-obscure relationships between state and behavior, since a compositional mindset facilitates functional code (that is, code that passes state via parameters, not via this ).
In a professional environment with experienced developers, the flexibility of composition generally trumps its more abstract nature. However, one should never discount the importance of comprehensibility, especially in teams that have varying degrees of experience and/or high levels of turnover.
Inheritance is an implementation decision. Interfaces almost always represent a better design, and should usually be used in an external API.
Why write a lot of boilerplate code forwarding method calls to a composed member object when the compiler will do it for you with inheritance?
This answer to another question summarises my thinking pretty well.
Does anyone else remember all of the OO-purists going ballistic over the COM implementation of "containment" instead of "inheritance?" It achieved essentially the same thing, but with a different kind of implementation. This reminds me of your question.
I strictly try to avoid religious wars in software development. ("vi" OR "emacs" ... when everybody knows its "vi"!) I think they are a sign of small minds. Comp Sci Professors can afford to sit around and debate these things. I'm working in the real world and could care less. All of this stuff are simply attempts at giving useful solutions to real problems. If they work, people will use them. The fact that OO languages and tools have been commercially available on a wide scale for going on 20 years is a pretty good bet that they are useful to a lot of people.
There are a lot of features in a programming language that are not really needed. But they are there for a variety of reasons that all basically boil down to reusability and maintainability.
All a business cares about is producing (quality of course) cheaply and quickly.
As a developer you help do this is by becoming more efficient and productive. So you need to make sure the code you write is easily reusable and maintainable.
And, among other things, this is what inheritance gives you - the ability to reuse without reinventing the wheel, as well as the ability to easily maintain your base object without having to perform maintenance on all similar objects.
There's lots of useful usages of inheritance, and probably just as many which are less useful. One of the useful ones is the stream class.
You have a method that should be able stream data. By using the stream base class as input to the method you ensure that your method can be used to write to many kinds of streams without change. To the file system, over the network, with compression, etc.
No.
for me, OOP is mostly about encapsulation of state and behavior and polymorphism.
and that is. but if you want static type checking, you'll need some way to group different types, so the compiler can check while still allowing you to use new types in place of another, related type. creating a hierarchy of types lets you use the same concept (classes) for types and for groups of types, so it's the most widely used form.
but there are other ways, i think the most general would be duck typing, and closely related, prototype-based OOP (which isn't inheritance in fact, but it's usually called prototype-based inheritance).
Depends on your definition of "needed". No, there is nothing that is impossible to do without inheritance, although the alternative may require more verbose code, or a major rewrite of your application.
But there are definitely cases where inheritance is useful. As you say, composition plus interfaces together cover almost all cases, but what if I want to supply a default behavior? An interface can't do that. A base class can. Sometimes, what you want to do is really just override individual methods. Not reimplement the class from scratch (as with an interface), but just change one aspect of it. or you may not want all members of the class to be overridable. Perhaps you have only one or two member methods you want the user to override, and the rest, which calls these (and performs validation and other important tasks before and after the user-overridden methods) are specified once and for all in the base class, and can not be overridden.
Inheritance is often used as a crutch by people who are too obsessed with Java's narrow definition of (and obsession with) OOP though, and in most cases I agree, it's the wrong solution, as if the deeper your class hierarchy, the better your software.
Inheritance is a good thing when the subclass really is the same kind of object as the superclass. E.g. if you're implementing the Active Record pattern, you're attempting to map a class to a table in the database, and instances of the class to a row in the database. Consequently, it is highly likely that your Active Record classes will share a common interface and implementation of methods like: what is the primary key, whether the current instance is persisted, saving the current instance, validating the current instance, executing callbacks upon validation and/or saving, deleting the current instance, running a SQL query, returning the name of the table that the class maps to, etc.
It also seems from how you phrase your question that you're assuming that inheritance is single but not multiple. If we need multiple inheritance, then we have to use interfaces plus composition to pull off the job. To put a fine point about it, Java assumes that implementation inheritance is singular and interface inheritance can be multiple. One need not go this route. E.g. C++ and Ruby permit multiple inheritance for your implementation and your interface. That said, one should use multiple inheritance with caution (i.e. keep your abstract classes virtual and/or stateless).
That said, as you note, there are too many real-life class hierarchies where the subclasses inherit from the superclass out of convenience rather than bearing a true is-a relationship. So it's unsurprising that a change in the superclass will have side-effects on the subclasses.
Not needed, but usefull.
Each language has got its own methods to write less code. OOP sometimes gets convoluted, but I think that is the responsability of the developers, the OOP platform is usefull and sharp when it is well used.
I agree with everyone else about the necessary/useful distinction.
The reason I like OOP is because it lets me write code that's cleaner and more logically organized. One of the biggest benefits comes from the ability to "factor-up" logic that's common to a number of classes. I could give you concrete examples where OOP has seriously reduced the complexity of my code, but that would be boring for you.
Suffice it to say, I heart OOP.
Absolutely needed? no,
But think of lamps. You can create a new lamp from scratch each time you make one, or you can take properties from the original lamp and make all sorts of new styles of lamp that have the same properties as the original, each with their own style.
Or you can make a new lamp from scratch or tell people to look at it a certain way to see the light, or , or, or
Not required, but nice :)
Thanks to all for your answers. I maintain my position that, strictly speaking, inheritance isn't needed, though I believe I found a new appreciation for this feature.
Something else: In my job experience, I have found inheritance leads to simpler, clearer designs when it's brought in late in the project, after it's noticed a lot of the classes have much commonality and you create a base class. In projects where a grand-schema was created from the very beginning, with a lot of classes in an inheritance hierarchy, refactoring is usually painful and dificult.
Seeing some answers mentioning something similar makes me wonder if this might not be exactly how inheritance's supposed to be used: ex post facto. Reminds me of Stepanov's quote: "you don't start with axioms, you end up with axioms after you have a bunch of related proofs". He's a mathematician, so he ought to know something.
The biggest problem with interfaces is that they cannot be changed. Make an interface public, then change it (add a new method to it) and break million applications all around the world, because they have implemented your interface, but not the new method. The app may not even start, a VM may refuse to load it.
Use a base class (not abstract) other programmers can inherit from (and override methods as needed); then add a method to it. Every app using your class will still work, this method just won't be overridden by anyone, but since you provide a base implementation, this one will be used and it may work just fine for all subclasses of your class... it may also cause strange behavior because sometimes overriding it would have been necessary, okay, might be the case, but at least all those million apps in the world will still start up!
I rather have my Java application still running after updating the JDK from 1.6 to 1.7 with some minor bugs (that can be fixed over time) than not having it running it at all (forcing an immediate fix or it will be useless to people).
//I found this QA very useful. Many have answered this right. But i wanted to add...
1: Ability to define abstract interface - E.g., for plugin developers. Of course, you can use function pointers, but this is better and simpler.
2: Inheritance helps model types very close to their actual relationships. Sometimes a lot of errors get caught at compile time, because you have the right type hierarchy. For instance, shape <-- triangle (lets say there is a lot of code to be reused). You might want to compose triangle with a shape object, but shape is an incomplete type. Inserting dummy implementations like double getArea() {return -1;} will do, but you are opening up room for error. That return -1 can get executed some day!
3: void func(B* b); ... func(new D()); Implicit type conversion gives a great notational convenience since Derived is Base. I remember having read Straustrup saying that he wanted to make classes first class citizens just like fundamental data types (hence overloading operators etc). Implicit conversion from Derived to Base, behaves just like an implicit conversion from a data type to broader compatible one (short to int).
Inheritance and Composition have their own pros and cons.
Refer to this related SE question on pros of inheritance and cons of composition.
Prefer composition over inheritance?
Have a look at the example in this documentation link:
The example shows different use cases of overriding by using inheritance as a mean to achieve polymorphism.
In the following, inheritance is used to present a particular property for all of several specific incarnations of the same type thing. In this case, the GeneralPresenation has a properties that are relevant to all "presentation" (the data passed to an MVC view). The Master Page is the only thing using it and expects a GeneralPresentation, though the specific views expect more info, tailored to their needs.
public abstract class GeneralPresentation
{
public GeneralPresentation()
{
MenuPages = new List<Page>();
}
public IEnumerable<Page> MenuPages { get; set; }
public string Title { get; set; }
}
public class IndexPresentation : GeneralPresentation
{
public IndexPresentation() { IndexPage = new Page(); }
public Page IndexPage { get; set; }
}
public class InsertPresentation : GeneralPresentation
{
public InsertPresentation() {
InsertPage = new Page();
ValidationInfo = new PageValidationInfo();
}
public PageValidationInfo ValidationInfo { get; set; }
public Page InsertPage { get; set; }
}