"Code to interfaces" is considered good practice. Such code is easy to unit test and enables loose coupling. Users only know the interfaces and the onus of wiring concrete objects is upon the top-most level (this can be done in some init code or with the help of frameworks).
My question is about following the practice of code to interfaces: does it imply that a concrete class can never declare any public method which is not present in its interface?
Otherwise, it will force users to depend upon the concrete implementation. This will make such methods difficult for unit testing; if the test fails, determining if it failed due to an issue in the caller code or due to the concrete method will require extra effort. This will also break the Dependency Inversion Principle. It will induce type-checking and down-casting, which are considered bad practice.
That is totally acceptable provided that the new methods aren't crucial to the operating of the class, and in particular to how it functions when someone thinks of it as the superclass or interface.
ArrayList provides good examples. It has methods that let you manage its internal memory, like ensureCapacity(int) or trimToSize(). Those are sometimes helpful if you know you're working with an ArrayList and need to be more precise about memory allocation, but they're not required for the basic operation of the ArrayList, and in particular, they're not required for having it operate as a general List.
In fact, interfaces themselves can add new methods in this way. Consider NavigableSet, which extends Set. It adds a whole bunch of methods that rely on the ordering of the set's elements (give me the first, the last, a subtree starting from here, etc). None of those methods are defined on Set, and even the fact that the elements are ordered isn't defined by the Set contract; but the Set methods all work just fine without the additional methods and ordering.
The advice to "code to the interface" is a good start, but it's a bit over-generalized. A refinement of that advice would be, "code to the most general interface that you need." If you don't need ArrayLists's methods (or its contract, such as its random-access performance), code to List; but if you do need them, then by all means use them.
#yshavit's third paragraph hits it right. Implement an extension of the "not enough" base interface, as exampled with public interface NavigableSet<E> extends SortedSet<E> (which, BTW, extends Set<E> extends Collection<E> extends Iterable<E>).
It's his second paragraph that troubles me. Why have "non-crucial" methods of the API that are not surfaced in some interface being implemented? In the ArrayList example, why not have the size management methods declared in an interface? Perhaps ManagedSize which would describe clear behavior for ArrayList (and other) classes to implement, along with the several other interfaces it implements (my JRE source says: public class ArrayList<E> extends AbstractList<E> implements List<E>, RandomAccess, Cloneable, java.io.Serializable).
With such an approach, there is no need to decide which methods are "non-crucial," only to be surprised by some client code that depends on things like ensureSize to help avoid relocation during a time-critical phase, or trimToSize to release excessive overalloaction when it's algorthmically known that further growth will not be needed. Not that I'm promoting such algorthms as best practice, but even non-functional "behavior management" methods deserve their place in the light.
Finally, while I agree with sentiment of "Know Where the Lines Are, and yet Color As You See Fit" it doesn't give practical guidance. Here's attempt at such:
Always start by coding to an interface, ie. all concrete public methods should be declared in an interface:
Use multiple interfaces as needed
Each interface should partition the implemented API into coherent non-overlapping aspects, e.g. List, RandomAccess, Cloneable, Serializable
Tend to start with larger scoped interfaces and break them up as the design develops (before coding ala Waterfall, or as code evolves ala Agile); interfaces are one of the easier design artefacts to refactor.
If a given interface you are implementing is "insufficient":
Extend the base interface and add the methods you need, then implement that one, OR
Create an augmenting interface (like the ManagedSize idea, above) with just the additional methods and then implement them both
Only when you find you can't do that, then relax only as much of the rule as you need to make things work (often, this will be an experimental trial-error "does it work, yet?" cycle).
Reasons for #3's "can't" will vary, but I expect them to be external to the application design, e.g. the ORM I'm using becomes confused, the IDE plug-in doesn't refactor it correctly, the DSL translator I'm forced to use fails when a class implements more than three interfaces...
When do you encourage programming against an interface and not directly to a concrete class?
A guideline that I follow is to create abstractions whenever code requires to cross a logical/physical boundary, most especially when infrastructure-related concerns are involved.
Another checkpoint would be if a dependency will likely change in the future, due to possible additional concerns code (such as caching, transactional awareness, invoking a webservice instead of in-process execution) or if such dependencies have direct references to infrastructure integration points.
If code depends on something that does not require control to cross a logical/physical boundary, I more or less don't create abstractions to interact with those.
Am I missing anything?
Also, use interfaces when
Multiple objects will need to be acted upon in a particular fashion, but are not fundamentally related. Perhaps many of your business objects access a particular utility object, and when they do they need to give a reference of themselves to that utility object so the utility object can call a particular method. Have that method in an interface and pass that interface to that utility object.
Passing around interfaces as parameters can be very helpful in unit testing. Even if you have just one type of object that sports a particular interface, and hence don't really need a defined interface, you might define/implement an interface solely to "fake" that object in unit tests.
related to the first 2 bullets, check out the Observer pattern and the Dependency Injection. I'm not saying to implement these patterns, but they illustrate types of places where interfaces are really helpful.
Another twist on this is for implementing a couple of the SOLID Principals, Open Closed principal and the Interface Segregation principle. Like the previous bullet, don't get stressed about strictly implementing these principals everywhere (right away at least), but use these concepts to help move your thinking away from just what objects go where to thinking more about contracts and dependency
In the end, let's not make it too complicated: we're in a strongly typed world in .NET. If you need to call a method or set a property but the object you're passing/using could be fundamentally different, use an interface.
I would add that if your code is not going to be referenced by another library (for a while at least), then the decision of whether to use an interface in a particular situation is one that you can responsibly put off. The "extract interface" refactoring is easy to do these days. In my current project, I've got an object being passed around that I'm thinking maybe I should switch to an interface; I'm not stressing about it.
Interfaces abstraction are convenient when doing unit test. It helps for mocking test objects. It very useful in TDD for developing without actually using data from your database.
If you don't need any features of the class that aren't found in the Interface...then why not always prefer the Interface implementation?
It will make your code easier to modify in the future and easier to test (mocking).
you have the right idea, already. i would only add a couple of notes to this...
first, abstraction does not mean 'interface'. for example, a "connection string" is an abstraction, even though it's just a string... it's not about the 'type' of the thing in question, it's about the intention of use for that thing.
and secondly, if you are doing test automation of any kind, look for the pain and friction that are exposed by writing the tests. if you find yourself having to set up too many external conditions for a test, it's a sign that you need a better abstraction between the thing your testing and the things it interacts with.
I think you've said it pretty well. Much of this will be a stylistic thing. There are open source projects I've looked at where everything has an interface and an implementation, and it's kind of frustrating, but it might make iterative development a little easier, since any objects implementation can break but dummies will still work. But honestly, I can dummy any class that doesn't overuse the final keyword by inheritance.
I would add to your list this: anything which can be thought of as a black box should be abstracted. This includes some of the things you've mentioned, but it also includes hairy algorithms, which are likely to have multiple useful implementations with different advantages for different situation.
Additionally, interfaces come in handy very often with composite objects. That's the only way something like java's swing library gets anything done, but it can also be useful for more mundane objects. (I personally like having an interface like ValidityChecker with ways to and-compose or or-compose subordinate ValidityCheckers.)
Most of the useful things that come with the Interface passing have been already said. However I would add:
implementing an interface to an object, or later multiple objects, FORCES all the implementers to follow an IDENTICAL pattern to implement contract with the object. This can be useful in case you have not so OOP-experienced-programmers actually writing the implementation code.
in some languages you can add attributes on the interface itself, which can be different from the actual object implementation attribute as sense and intent
Why would anyone want to mark a class as final or sealed?
According to Wikipedia, "Sealed classes are primarily used to prevent derivation. They add another level of strictness during compile-time, improve memory usage, and trigger certain optimizations that improve run-time efficiency."
Also, from Patrick Smacchia's blog:
Versioning: When a class is originally sealed, it can change to unsealed in the future without breaking compatibility. (…)
Performance: (…) if the JIT compiler sees a call to a virtual method using a sealed types, the JIT compiler can produce more efficient code by calling the method non-virtually.(…)
Security and Predictability: A class must protect its own state and not allow itself to ever become corrupted. When a class is unsealed, a derived class can access and manipulate the base class’s state if any data fields or methods that internally manipulate fields are accessible and not private.(…)
Those are all pretty good reasons - I actually wasn't aware of the performance benefit implications until I looked it up just now :)
The versioning and security points seem like a huge benefit in terms of code confidence, which is very well justified on any kind of large project. It's no drop-in for unit testing, of course, but it would help.
Because creating a type for inheritance is much harder work than most folks think. It is best to mark all types this way by default as this will prevent others from inheriting from a type that was never intended to be extended.
Whether or not a type should be extended is a decision of the developer who created it, not the developer who comes along later and wants to extend it.
Joshua Bloch in his book Effective Java talks about it. He says "document for inheritance or disallow it".
The point is that class is sort of a contract between author and client. Allowing client to inherit from base class makes this contract much more strict. If you are going to inherit from it, you most likely are going to override some methods, otherwise you can replace inheritance with composition. Which methods are allowed to be overridden, and what you have to do implementing them - should be documented, or your code can lead to unpredictable results. As far as I remember, he shows such example - here is a collection class with methods
public interface Collection<E> extends Iterable<E> {
...
boolean add(E e);
boolean addAll(Collection<? extends E> c);
...
}
There is some implementation, i.e. ArrayList. Now you want to inherit from it and override some methods, so it prints to console a message when element is added. Now, do you need to override both add and addAll, or only add? It depends on how addAll is implemented - does it work with internal state directly (as ArrayList does) or calls add (as AbstractCollection does). Or may be there is addInternal, which is called by both add and addAll. There were no such questions until you decided to inherit from this class. If you just use it - it does not bother you. So the author of the class has to document it, if he wants you to inherit from his class.
And what if he wants to change the implementation in the future? If his class is only used, never inherited from, nothing stops him from changing implementation to more efficient. Now, if you inherited from that class, looked at source and found that addAll calls add, you override only add. Later author changes implementation so addAll no longer calls add - your program is broken, message is not printed when addAll is called. Or you looked at source and found that addAll does not call add, so you override add and addAll. Now author changes implementation, so addAll calls add - your program is broken again, when addAll is called message is printed twice for each element.
So - if you want your class to be inherited from, you need to document how. If you think that you may need to change something in the future that may break some subclasses - you need to think how to avoid it. By letting your clients inherit from your class you expose much more of internal implementation details that you do when you just let them use your class - you expose internal workflow, that is often subject to changes in future versions.
If you expose some details and clients rely on them - you no longer can change them. If it is ok with you, or you documented what can and what can not be overriden - that's fine. Sometimes you just don't want it. Sometimes you just want to say - "just use this class, never inherit from it, because I want a freedom to change internal implementation details".
So basically comment "Because the class doesn't want to have any children and we should respect it's wishes" is correct.
So, someone wants to mark a class as final/sealed, when he thinks that possible implementation details changes are more valuable than inheritance. There are other ways to achieve results similar to inheritance.
From what I have read best practice is to have classes based on an interface and loosely couple the objects, in order to help code re-use and unit test.
Is this correct and is it a rule that should always be followed?
The reason I ask is I have recently worked on a system with 100’s of very different objects. A few shared common interfaces but most do not and wonder if it should have had an interface mirroring every property and function in those classes?
I am using C# and dot net 2.0 however I believe this question would fit many languages.
It's useful for objects which really provide a service - authentication, storage etc. For simple types which don't have any further dependencies, and where there are never going to be any alternative implementations, I think it's okay to use the concrete types.
If you go overboard with this kind of thing, you end up spending a lot of time mocking/stubbing everything in the world - which can often end up creating brittle tests.
Not really. Service components (class that do things for your application) are a good fit for interfaces, but as a rule I wouldn't bother having interfaces for, say, basic entity classes.
For example:
If you're working on a domain model, then that model shouldn't be interfaces. However if that domain model wants to call service classes (like data access, operating system functions etc) then you should be looking at interfaces for those components. This reduces coupling between the classes and means it's the interface, or "contract" that is coupled.
In this situation you then start to find it much easier to write unit tests (because you can have stubs/mocks/fakes for database access etc) and can use IoC to swap components without recompiling your applications.
I'd only use interfaces where that level of abstraction was required - i.e. you need to use polymorphic behaviour. Common examples would be dependency injection or where you have a factory-type scenario going on somewhere, or you need to establish a "multiple inheritance" type behaviour.
In my case, with my development style, this is quite often (I favour aggregation over deep inheritance hierarchies for most things other than UI controls), but I have seen perfectly fine apps that use very little. It all depends...
Oh yes, and if you do go heavily into interfaces - beware web services. If you need to expose your object methods via a web service they can't really return or take interface types, only concrete types (unless you are going to hand-write all your own serialization/deserialization). Yes, that has bitten me big time...
A downside to interface is that they can't be versioned. Once you shipped the interface you won't be making changes to it. If you use abstract classes then you can easily extend the contract over time by adding new methods and flagging them as virtual.
As an example, all stream objects in .NET derive from System.IO.Stream which is an abstract class. This makes it easy for Microsoft to add new features. In version 2 of the frameworkj they added the ReadTimeout and WriteTimeout properties without breaking any code. If they used an interface(say IStream) then they wouldn't have been able to do this. Instead they'd have had to create a new interface to define the timeout methods and we'd have to write code to conditionally cast to this interface if we wanted to use the functionality.
Interfaces should be used when you want to clearly define the interaction between two different sections of your software. Especially when it is possible that you want to rip out either end of the connection and replace it with something else.
For example in my CAM application I have a CuttingPath connected to a Collection of Points. It makes no sense to have a IPointList interface as CuttingPaths are always going to be comprised of Points in my application.
However I uses the interface IMotionController to communicate with the machine because we support many different types of cutting machine each with their own commend set and method of communications. So in that case it makes sense to put it behind a interface as one installation may be using a different machine than another.
Our applications has been maintain since the mid 80s and went to a object oriented design in late 90s. I have found that what could change greatly exceeded what I originally thought and the use of interfaces has grown. For example it used to be that our DrawingPath was comprised of points. But now it is comprised of entities (splines, arcs, ec) So it is pointed to a EntityList that is a collection of Object implementing IEntity interface.
But that change was propelled by the realization that a DrawingPath could be drawn using many different methods. Once that it was realized that a variety of drawing methods was needed then the need for a interface as opposed to a fixed relationship to a Entity Object was indicated.
Note that in our system DrawingPaths are rendered down to a low level cutting path which are always series of point segments.
I tried to take the advice of 'code to an interface' literally on a recent project. The end result was essentially duplication of the public interface (small i) of each class precisely once in an Interface (big I) implementation. This is pretty pointless in practice.
A better strategy I feel is to confine your interface implementations to verbs:
Print()
Draw()
Save()
Serialize()
Update()
...etc etc. This means that classes whose primary role is to store data - and if your code is well-designed they would usually only do that - don't want or need interface implementations. Anywhere you might want runtime-configurable behaviour, for example a variety of different graph styles representing the same data.
It's better still when the thing asking for the work really doesn't want to know how the work is done. This means you can give it a macguffin that it can simply trust will do whatever its public interface says it does, and let the component in question simply choose when to do the work.
I agree with kpollock. Interfaces are used to get a common ground for objects. The fact that they can be used in IOC containers and other purposes is an added feature.
Let's say you have several types of customer classes that vary slightly but have common properties. In this case it is great to have a ICustomer interface to bound them together, logicaly. By doing that you could create a CustomerHander class/method that handels ICustomer objects the same way instead of creating a handerl method for each variation of customers.
This is the strength of interfaces.
If you only have a single class that implements an interface, then the interface isn't to much help, it just sits there and does nothing.
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; }
}