One drawback to using composition in place of inheritance is that all of the methods being provided by the composed classes must be implemented in the derived class, even if they are only forwarding methods.
Looking for the solution to this problem I came cross something called as Traits and mixin ( available in language like scala,Perl 6) . However I haven't been compleltly able to understand the idea behind traits and mixins.
My question is how does traits (or Mixins) solve the problem of delegation with composition ?
I'm not a Perl or Scala programmer, but no one else has tried to answer your question, so I will attempt it. Traits or mixins are an alternative to multiple inheritance. C++ implemented multiple inheritance, but there were some problems with it. Successive languages like Java and C# decided to implement only single inheritance. But single inheritance can be inconvenient, just as you say; if you want to use methods from multiple classes, you must compose instances of those classes and then write methods to forward messages to the composed objects.
Traits/mixins are a solution to inconvenience of single inheritance. Instead of composing objects and writing forwarding methods yourself, the programming language does the work for you. If your object does not understand some message sent to it, the runtime environment will look through all of the traits/mixin to see if one of them understands the message. If a trait/mixin understands the message, then that trait's implementation of the is executed. This lets you bundle commonly used functionality into a single component, called a trait or mixin, so you use it in many places.
I think the important advantage of traits/mixins over multiple inheritance is that when different mixins implement methods with the same name, you can predict which method will be executed. Knowing which method would be executed in C++ was a problem. See the Wikipedia article on the "diamond problem" (http://en.wikipedia.org/wiki/Multiple_inheritance#The_diamond_problem)
I have a Component which has API exposed with some 10 functionality in all. I can think of two ways to achieve it:
Give out all these functionality as separate functions.
Expose only one function which takes an XML as input. Based on request_Type specified and the parameters passed in the XML, I internally call one of the respective functions.
Q1. Will the second design be more loosely coupled than the first ?
I always read about how I should try my components to be loosely coupled, should I really go to this extent to achieve lose coupling ?
Q2. Which one of these would be a better design in terms of OOP and why?
Edit:
If I am exposing this API over D-Bus for others to use, will type checking still be a consideration to compare the two approaches? From what I understand type checking is done at compile time, but in case when this function is exposed over some IPC, issue of type checking comes into picture ?
The two alternatives you propose do not differ in the (obviously quite large) number of "functions" you want to offer from your API. However, the second seems to have many disadvantages because you are loosing any strong type checking, it will become much harder to document the functionality etc. (The only advantage I see is that you don't need to change your API if you add functionality. But at the disadvantage that users will not be able to figure out API changes like deleted functions until run-time.)
What is more related with this question is the Single Responsiblity Principle (http://en.wikipedia.org/wiki/Single_responsibility_principle). As you are talking about OOP, you should not expose your tens of functions within one class but split them among different classes, each with a single responsibility. Defining good "responsibilities" and roles requires some practice, but following some basic guidelines will help you to get started quickly. See Are there any rules for OOP? for a good starting point.
Reply to the question edit
I haven't used D-Bus, so this might be totally wrong. But from a quick look at the tutorial I read
Each object supports one or more interfaces. Think of an interface as
a named group of methods and signals, just as it is in GLib or Qt or
Java. Interfaces define the type of an object instance.
DBus identifies interfaces with a simple namespaced string, something
like org.freedesktop.Introspectable. Most bindings will map these
interface names directly to the appropriate programming language
construct, for example to Java interfaces or C++ pure virtual classes.
As far as I understand, D-Bus has the concept of differnt objects which provide interfaces consisting of several methods. This means (to me) that my answer above still applies. The "D-Bus native" way of specifying your API would mean to exhibit interfaces and I don't see any reason why good OOP design guidelines shouldn't be valid, here. As D-Bus seems to map these even to native language constructs, this is even more likely.
Of course, nobody keeps you from just building your own API description language in XML. However, things like are some kind of abuse of underlying techniques. You should have good reasons for doing such things.
I come from a ECMAScript background (seems to be very C/C++). Thus, I learned classic C++ style inheritance involving classes, objects, and cool stuff like polymorphism.
I like Android and iOS development lately. Java appears to be C-based, so I'm fine using the majority of my C-based rules there, but iOS is different enough that I'm leery with my approaches -- especially with something like object inheritance.
I ask because there seem to be some strong opinions toward composition. From what I've seen with composition so far, I'm not the biggest fan unless the project provides a good reason to work with it.
You pro Obj-C/iOS devs out there, would you recommend composition over classic inheritance? Or is it a situational thing?
The object model of Objective-C is quite different to C/C++/Java. It is message-based and so more emphasis is placed on objects responding to messages rather than calling methods as in C/C++/Java.
The approach to the Cocoa libraries favours a flatter object inheritance hierarchy and relies on the delegate pattern for customisation and to keep those object hierarchies flat. Why do this? A lot of libraries, especially GUI, suffer from complications due to hierarchy bloat to the point that it is not clear which class you'd inherit from. Most modern object systems in video games, for example (being my industry of expertise), use composition paradigms where objects are constructed by mixing behaviors as it's more flexible and easier to maintain in practice.
I wouldn't say Cocoa libraries use the composition model as such, but rather uses the interaction between classes clearly partitioned in one of the Model-View-Controller areas and uses delegation for customisation. Keeping customisation separate from the core functionality keeps complexity down and hierarchies flatter.
If a new class generally follows Liskov Substitution Principle towards the class that it's derived from, use inheritance, otherwise, prefer composition/aggregation. It is not one against another, both are widely used.
To me, this is more a question of what classes you're using. If you're using Apple's core foundation or UI libraries, I would recommend that you avoid subclassing. Many of these classes are not concrete classes but rather are class clusters. In these classes, the os may decide at runtime which class to actually use.
In general, I prefer composition unless I have a very compelling reason to subclass. Even when I have a compelling reason to subclass, I often choose instead to create a category of methods for the original class.
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
This caught my attention last night.
On the latest ALT.NET Podcast Scott Bellware discusses how as opposed to Ruby, languages like C#, Java et al. are not truly object oriented rather opting for the phrase "class-oriented". They talk about this distinction in very vague terms without going into much detail or discussing the pros and cons much.
What is the real difference here and how much does it matter? What are other languages then are "object-oriented"? It sounded pretty interesting but I don't want to have to learn Ruby just to know what if anything I am missing.
Update
After reading some of the answers below it seems like people generally agree that the reference is to duck-typing. What I'm not sure I understand still though is the claim that this ultimately changes all that much. Especially if you are already doing proper TDD with loose coupling etc. Can someone show me an example of a specific thing I could do with Ruby that I cannot do with C# and that exemplifies this different OOP approach?
In an object-oriented language, objects are defined by defining objects rather than classes, although classes can provide some useful templates for specific, cookie-cutter definitions of a given abstraction. In a class-oriented language, like C# for example, objects must be defined by classes, and these templates are usually canned and packaged and made immutable before runtime. This arbitrary constraint that objects must be defined before runtime and that the definitions of objects are immutable is not an object-oriented concept; it's class oriented.
The duck typing comments here are more attributing to the fact that Ruby and Python are more dynamic than C#. It doesn't really have anything to do with it's OO Nature.
What (I think) Bellware meant by that is that in Ruby, everything is an object. Even a class. A class definition is an instance of an object. As such, you can add/change/remove behavior to it at runtime.
Another good example is that NULL is an object as well. In ruby, everything is LITERALLY an object. Having such deep OO in it's entire being allows for some fun meta-programming techniques such as method_missing.
IMO, it's really overly defining "object-oriented", but what they are referring to is that Ruby, unlike C#, C++, Java, et al, does not make use of defining a class -- you really only ever work directly with objects. Conversely, in C# for example, you define classes that you then must instantiate into object by way of the new keyword. The key point being you must declare a class in C# or describe it. Additionally, in Ruby, everything -- even numbers, for example -- is an object. In contrast, C# still retains the concept of an object type and a value type. This in fact, I think illustrates the point they make about C# and other similar languages -- object type and value type imply a type system, meaning you have an entire system of describing types as opposed to just working with objects.
Conceptually, I think OO design is what provides the abstraction for use to deal complexity in software systems these days. The language is a tool use to implement an OO design -- some make it more natural than others. I would still argue that from a more common and broader definition, C# and the others are still object-oriented languages.
There are three pillars of OOP
Encapsulation
Inheritance
Polymorphism
If a language can do those three things it is a OOP language.
I am pretty sure the argument of language X does OOP better than language A will go on forever.
OO is sometimes defined as message oriented. The idea is that a method call (or property access) is really a message sent to another object. How the recieveing object handles the message is completely encapsulated. Often the message corresponds to a method which is then executed, but that is just an implementation detail. You can for example create a catch-all handler which is executed regardless of the method name in the message.
Static OO like in C# does not have this kind of encapsulation. A massage has to correspond to an existing method or property, otherwise the compiler will complain. Dynamic languages like Smalltalk, Ruby or Python does however support "message-based" OO.
So in this sense C# and other statically typed OO languages are not true OO, sine thay lack "true" encapsulation.
Update: Its the new wave.. which suggest everything that we've been doing till now is passe.. Seems to be propping up quite a bit in podcasts and books.. Maybe this is what you heard.
Till now we've been concerned with static classes and not unleashed the power of object oriented development. We've been doing 'class based dev.' Classes are fixed/static templates to create objects. All objects of a class are created equal.
e.g. Just to illustrate what I've been babbling about... let me borrow a Ruby code snippet from PragProg screencast I just had the privilege of watching.
'Prototype based development' blurs the line between objects and classes.. there is no difference.
animal = Object.new # create a new instance of base Object
def animal.number_of_feet=(feet) # adding new methods to an Object instance. What?
#number_of_feet = feet
end
def animal.number_of_feet
#number_of_feet
end
cat = animal.clone #inherits 'number_of_feet' behavior from animal
cat.number_of_feet = 4
felix = cat.clone #inherits state of '4' and behavior from cat
puts felix.number_of_feet # outputs 4
The idea being its a more powerful way to inherit state and behavior than traditional class based inheritance. It gives you more flexibility and control in certain "special" scenarios (that I've yet to fathom). This allows things like Mix-ins (re using behavior without class inheritance)..
By challenging the basic primitives of how we think about problems, 'true OOP' is like 'the Matrix' in a way... You keep going WTF in a loop. Like this one.. where the base class of Container can be either an Array or a Hash based on which side of 0.5 the random number generated is.
class Container < (rand < 0.5 ? Array : Hash)
end
Ruby, javascript and the new brigade seem to be the ones pioneering this. I'm still out on this one... reading up and trying to make sense of this new phenomenon. Seems to be powerful.. too powerful.. Useful? I need my eyes opened a bit more. Interesting times.. these.
I've only listened to the first 6-7 minutes of the podcast that sparked your question. If their intent is to say that C# isn't a purely object-oriented language, that's actually correct. Everything in C# isn't an object (at least the primitives aren't, though boxing creates an object containing the same value). In Ruby, everything is an object. Daren and Ben seem to have covered all the bases in their discussion of "duck-typing", so I won't repeat it.
Whether or not this difference (everything an object versus everything not an object) is material/significant is a question I can't readily answer because I don't have sufficient depth in Ruby to compare it to C#. Those of you who on here who know Smalltalk (I don't, though I wish I did) have probably been looking at the Ruby movement with some amusement since it was the first pure OO language 30 years ago.
Maybe they are alluding to the difference between duck typing and class hierarchies?
if it walks like a duck and quacks like a duck, just pretend it's a duck and kick it.
In C#, Java etc. the compiler fusses a lot about: Are you allowed to do this operation on that object?
Object Oriented vs. Class Oriented could therefore mean: Does the language worry about objects or classes?
For instance: In Python, to implement an iterable object, you only need to supply a method __iter__() that returns an object that has a method named next(). That's all there is to it: No interface implementation (there is no such thing). No subclassing. Just talking like a duck / iterator.
EDIT: This post was upvoted while I rewrote everything. Sorry, won't ever do that again. The original content included advice to learn as many languages as possible and to nary worry about what the language doctors think / say about a language.
That was an abstract-podcast indeed!
But I see what they're getting at - they just dazzled by Ruby Sparkle. Ruby allows you to do things that C-based and Java programmers wouldn't even think of + combinations of those things let you achieve undreamt of possibilities.
Adding new methods to a built-in String class coz you feel like it, passing around unnamed blocks of code for others to execute, mixins... Conventional folks are not used to objects changing too far from the class template.
Its a whole new world out there for sure..
As for the C# guys not being OO enough... dont take it to heart.. Just take it as the stuff you speak when you are flabbergasted for words. Ruby does that to most people.
If I had to recommend one language for people to learn in the current decade.. it would be Ruby. I'm glad I did.. Although some people may claim Python. But its like my opinion.. man! :D
I don't think this is specifically about duck typing. For instance C# supports limited duck-typing already - an example would be that you can use foreach on any class that implements MoveNext and Current.
The concept of duck-typing is compatible with statically typed languages like Java and C#, it's basically an extension of reflection.
This is really the case of static vs dynamic typing. Both are proper-OO, in as much as there is such a thing. Outside of academia it's really not worth debating.
Rubbish code can be written in either. Great code can be written in either. There's absolutely nothing functional that one model can do that the other can't.
The real difference is in the nature of the coding done. Static types reduce freedom, but the advantage is that everyone knows what they're dealing with. The opportunity to change instances on the fly is very powerful, but the cost is that it becomes hard to know what you're deaing with.
For instance for Java or C# intellisense is easy - the IDE can quickly produce a drop list of possibilities. For Javascript or Ruby this becomes a lot harder.
For certain things, for instance producing an API that someone else will code with, there is a real advantage in static typing. For others, for instance rapidly producing prototypes, the advantage goes to dynamic.
It's worth having an understanding of both in your skills toolbox, but nowhere near as important as understanding the one you already use in real depth.
Object Oriented is a concept. This concept is based upon certain ideas. The technical names of these ideas (actually rather principles that evolved over the time and have not been there from the first hour) have already been given above, I'm not going to repeat them. I'm rather explaining this as simple and non-technical as I can.
The idea of OO programming is that there are objects. Objects are small independent entities. These entities may have embedded information or they may not. If they have such information, only the entity itself can access it or change it. The entities communicate with each other by sending messages between each other. Compare this to human beings. Human beings are independent entities, having internal data stored in their brain and the interact with each other by communicating (e.g. talking to each other). If you need knowledge from someone's else brain, you cannot directly access it, you must ask him a question and he may answer that to you, telling you what you wanted to know.
And that's basically it. This is real idea behind OO programming. Writing these entities, define the communication between them and have them interact together to form an application. This concept is not bound to any language. It's just a concept and if you write your code in C#, Java, or Ruby, that is not important. With some extra work this concept can even be done in pure C, even though it is a functional language but it offers everything you need for the concept.
Different languages have now adopted this concept of OO programming and of course the concepts are not always equal. Some languages allow what other languages forbid, for example. Now one of the concepts that involved is the concept of classes. Some languages have classes, some don't. A class is a blueprint how an object looks like. It defines the internal data storage of an object, it defines the messages an object can understand and if there is inheritance (which is not mandatory for OO programming!), classes also defines from which other class (or classes if multiple inheritance is allowed) this class inherits (and which properties if selective inheritance exists). Once you created such a blueprint you can now generate an unlimited amount of objects build according to this blueprint.
There are OO languages that have no classes, though. How are objects then build? Well, usually dynamically. E.g. you can create a new blank object and then dynamically add internal structure like instance variables or methods (messages) to it. Or you can duplicate an already existing object, with all its properties and then modify it. Or possibly merge two objects into a new one. Unlike class based languages these languages are very dynamic, as you can generate objects dynamically during runtime in ways not even you the developer has thought about when starting writing the code.
Usually this dynamic has a price: The more dynamic a language is the more memory (RAM) objects will waste and the slower everything gets as program flow is extremely dynamically as well and it's hard for a compiler to generate effective code if it has no chance to predict code or data flow. JIT compilers can optimize some parts of that during runtime, once they know the program flow, however as these languages are so dynamically, program flow can change at any time, forcing the JIT to throw away all compilation results and re-compile the same code over and over again.
But this is a tiny implementation detail - it has nothing to do with the basic OO principle. It is nowhere said that objects need to be dynamic or must be alterable during runtime. The Wikipedia says it pretty well:
Programming techniques may include
features such as information hiding,
data abstraction, encapsulation,
modularity, polymorphism, and
inheritance.
http://en.wikipedia.org/wiki/Object-oriented_programming
They may or they may not. This is all not mandatory. Mandatory is only the presence of objects and that they must have ways to interact with each other (otherwise objects would be pretty useless if they cannot interact with each other).
You asked: "Can someone show me an example of a wonderous thing I could do with ruby that I cannot do with c# and that exemplifies this different oop approach?"
One good example is active record, the ORM built into rails. The model classes are dynamically built at runtime, based on the database schema.
This is really probably getting down to what these people see others doing in c# and java as opposed to c# and java supporting OOP. Most languages cane be used in different programming paradigms. For example, you can write procedural code in c# and scheme, and you can do functional-style programming in java. It is more about what you are trying to do and what the language supports.
I'll take a stab at this.
Python and Ruby are duck-typed. To generate any maintainable code in these languages, you pretty much have to use test driven development. As such, it is very important for a developer to easily inject dependencies into their code without having to create a giant supporting framework.
Successful dependency-injection depends upon on having a pretty good object model. The two are sort of two sides of the same coin. If you really understand how to use OOP, then you should by default create designs where dependencies can be easily injected.
Because dependency injection is easier in dynamically typed languages, the Ruby/Python developers feel like their language understands the lessons of OO much better than other statically typed counterparts.