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Introduction to Object Oriented Programming Concepts (OOP) and More

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9 Oct 2021CPOL42 min read 188   1  
This article helps to understand OOP concepts, focusing on .NET/ C#. This is written in the form of asking questions and writing answers to them, making it easy to understand.
This article is a constructive attempt to group/define/explain all introductory concepts of software architecture for seasoned developers who are looking to take their next step as system architects. We'll cover large topics like what is Software Architecture and OOP, and smaller ones like: What is an Object? What is a Class? We also look at Use Case, MVC architecture, SOA, Data Access Layer, and Design Patterns.

Table of Contents

  1. Introduction
  2. Background
  3. Prerequisites
  4. The Main Content
    1. What is Software Architecture?
    2. Why Architecture is important?
    3. What is OOP?
    4. What is an Object?
    5. What is a Class?
    6. How to identify and design a Class?
    7. What is Encapsulation (or information hiding)?
    8. What is Association?
    9. What is the difference between Association, Aggregation and Composition?
    10. What is Abstraction and Generalization?
    11. What is an Abstract class?
    12. What is an Interface?
    13. What is the difference between a Class and an Interface?
    14. What is the difference between an Interface and an Abstract class?
    15. What are Implicit and Explicit interface implementations?
    16. What is Inheritance?
    17. What is Polymorphism?
    18. What is Method Overloading?
    19. What is Operator overloading?
    20. What is Method Overriding?
    21. What is a Use Case?
    22. What is a Class Diagram?
    23. What is a Package Diagram?
    24. What is a Sequence Diagram?
    25. What is two-tier architecture?
    26. What is three-tier architecture?
    27. What is MVC architecture?
    28. What is SOA?
    29. What is the Data Access Layer?
    30. What is the Business Logic Layer?
    31. What is Gang of Four (GoF) Design Patterns?
    32. What is the difference between Abstract Factory and Builder design patterns?
  5. What is the Conclusion?
  6. What I Referred?
  7. History

1. Introduction

I have noticed an increase in the number of articles published in the Architecture category on Code Project during the last few months. The number of readers for most of these articles is also high, though the ratings for the articles are not. This indicates that readers are interested in reading articles on architecture, but the quality does not match their expectations. This article is a constructive attempt to group/define/explain all introductory concepts of software architecture for seasoned developers who are looking to take their next step as system architects.

One day, I read an article that said that the richest two percent own half the world's wealth. It also said that the richest one percent of adults owned 40 percent of global assets in the year 2000. And further, the richest 10 percent of adults accounted for 85 percent of the world's total wealth. So there is an unbalanced distribution of wealth in the physical world. Have you ever thought of an unbalanced distribution of knowledge in the software world? According to my view point, the massive expansion of the software industry is forcing developers to use already implemented libraries, services, and frameworks to develop software within ever shorter periods of time. New developers are trained to use (I would say more often) already developed software components to complete the development quicker. They just plug in an existing library and somehow manage to achieve the requirements. But the sad part of the story is, they never get the training to define, design the architecture for, and implement such components. As a number of years pass by, these developers become leads and software architects. Their titles change, but the old legacy of not understanding, of not having any architectural experience, continues, creating a vacuum of good architects. The bottom line is that only a small percentage of developers know how to design a truly object oriented system. The solution to this problem is getting harder every day as the aggressive nature of the software industry does not support an easy adjustment to existing processes, and also the related online teaching materials are either complex, or less practical, or sometimes even wrong. Most of them use impractical, irrelevant examples of shapes, animals, and many other physical world entities to teach the concepts of software architecture. There are only very few good business-oriented design references. Unfortunately, I myself am no exception and am a result of this very same system. I got the same education that all of you did, and also referred to the same resource set you all read.

Coming back to the initial point, I noticed that there is a knowledge gap, increasing every day, between architects who know how to architect a system properly and others who do not. The ones who know, know it right. But the ones who do not know, know nothing. Just like the world’s wealth distribution, it is an unbalanced distribution of knowledge.

2. Background

This article began after reading and hearing questions new developers have on the basics of software architecture. There are some good articles out there, but developers still struggle to understand the basic concepts, and more importantly, the way to apply them correctly.

As I see it, newcomers will always struggle to understand the precise definition of a new concept, because it is always a new and hence unfamiliar idea. The ones who have experience understand the meaning, but the ones who don’t struggle to understand the very definition. It is like that. Employers want experienced employees. So they say, you need to have experience to get a job. But how the hell is one supposed to have experience if no one is willing to give him a job? As in the general case, the start with software architecture is no exception. It will be difficult. When you start to design your very first system, you will try to apply everything you know or have learned from everywhere. You will feel that an interface needs to be defined for every class, like I did once. You will find it harder to understand when and when not to do something. Just prepare to go through the painful process. Others will criticize you, may laugh at you, and say that the way you have designed is wrong. Listen to them, and learn continuously. In this process, you will also have to read and think a lot. I hope that this article will give you the right start for that long journey.

The knowledge of the actions of great men, acquired by long experience in contemporary affairs, and a continual study of antiquity” – I read this phrase when I was reading the book named “The Art of War”, seems applicable here, isn’t it?

3. Prerequisites

This article is an effort to provide an accurate information pool for new developers on the basics of software architecture, focusing on Object Oriented Programming (OOP). If you are a developer who has a minimum of three years of continuous development experience and has that hunger to learn more, to step-in to the next level to become a software architect, this article is for you.

4. The Main Content

4.1. What is Software Architecture?

Software architecture is defined to be the rules, heuristics, and patterns governing:

  • Partitioning the problem and the system to be built into discrete pieces
  • Techniques used to create interfaces between these pieces
  • Techniques used to manage overall structure and flow
  • Techniques used to interface the system to its environment
  • Appropriate use of development and delivery approaches, techniques and tools

4.2. Why Architecture is Important?

OOP_Concepts_and_manymore/oop.jpg

The primary goal of software architecture is to define the non-functional requirements of a system and define the environment. The detailed design is followed by a definition of how to deliver the functional behavior within the architectural rules. Architecture is important because it:

  • Controls complexity
  • Enforces best practices
  • Gives consistency and uniformity
  • Increases predictability
  • Enables re-use

4.3. What is OOP?

OOP is a design philosophy. It stands for Object Oriented Programming. Object-Oriented Programming (OOP) uses a different set of programming languages than old procedural programming languages (C, Pascal, etc.). Everything in OOP is grouped as self sustainable "objects". Hence, you gain reusability by means of four main object-oriented programming concepts.

In order to clearly understand the object orientation model, let’s take your “hand” as an example. The “hand” is a class. Your body has two objects of the type "hand", named "left hand" and "right hand". Their main functions are controlled or managed by a set of electrical signals sent through your shoulders (through an interface). So the shoulder is an interface that your body uses to interact with your hands. The hand is a well-architected class. The hand is being reused to create the left hand and the right hand by slightly changing the properties of it.

4.4. What is an Object?

An object can be considered a "thing" that can perform a set of related activities. The set of activities that the object performs defines the object's behavior. For example, the Hand (object) can grip something, or a Student (object) can give their name or address.

In pure OOP terms, an object is an instance of a class.

4.5. What is a Class?

OOP_Concepts_and_manymore/class.gif

A class is simply a representation of a type of object. It is the blueprint, or plan, or template, that describes the details of an object. A class is the blueprint from which the individual objects are created. Class is composed of three things: a name, attributes, and operations.

C#
public class Student
{
}

According to the sample given below, we can say that the Student object, named objectStudent, has been created out of the Student class.

C#
Student objectStudent = new Student();

In the real world, you'll often find many individual objects all of the same kind. As an example, there may be thousands of other bicycles in existence, all of the same make and model. Each bicycle has built from the same blueprint. In object-oriented terms, we say that the bicycle is an instance of the class of objects known as bicycles.

In the software world, though you may not have realized it, you have already used classes. For example, the TextBox control, you always used, is made out of the TextBox class, which defines its appearance and capabilities. Each time you drag a TextBox control, you are actually creating a new instance of the TextBox class.

4.6. How to Identify and Design a Class?

This is an art; each designer uses different techniques to identify classes. However according to Object Oriented Design Principles, there are five principles that you must follow when designing a class:

  1. SRP - The Single Responsibility Principle - a class should have one, and only one, reason to change.
  2. OCP - The Open Closed Principle - should be able to extend any classes' behaviors, without modifying the classes
  3. LSP - The Liskov Substitution Principle - derived classes must be substitutable for their base classes.
  4. DIP - The Dependency Inversion Principle - depend on abstractions, not on concretions
  5. ISP - The Interface Segregation Principle - make fine grained interfaces that are client specific

For more information on design principles, please refer to Object Mentor.

Additionally to identify a class correctly, you need to identify the full list of leaf-level functions or operations of the system (granular level use cases of the system). Then you can proceed to group each function to form classes (classes will group same types of functions or operations). However a well-defined class must be a meaningful grouping of a set of functions and should support the reusability, while increasing expandability or maintainability, of the overall system.

In the software world, the concept of dividing and conquering is always recommended, if you start analyzing a full system at the start, you will find it harder to manage. So the better approach is to identify the module of the system first and then dig deep into each module separately to seek out classes.

A software system may consist of many classes. When you have many classes, it needs to be managed. Think of a big organization, with its work force exceeding several thousand employees (let’s take one employee as one class). In order to manage such a work force, you need to have proper management policies in place. Same technique can be applied to manage classes of your software system. In order to manage the classes of a software system, and to reduce the complexity, system designers use several techniques, which can be grouped under four main concepts named:

  1. Encapsulation
  2. Abstraction
  3. Inheritance
  4. Polymorphism

These concepts are the four main Gods of OOP world and in software term, they are called four main Object Oriented Programming (OOP) Concepts.

4.7. What is Encapsulation (or Information Hiding)?

Encapsulation is the inclusion - within a program object - of all the resources needed for the object to function, basically, the methods and the data. In OOP, the encapsulation is mainly achieved by creating classes, the classes expose public methods and properties. A class is kind of a container or capsule or a cell, which encapsulates a set of methods, attribute and properties to provide its indented functionalities to other classes. In that sense, encapsulation also allows a class to change its internal implementation without hurting the overall functioning of the system. That idea of encapsulation is to hide how a class does its business, while allowing other classes to make requests of it.

OOP_Concepts_and_manymore/class.gif

In order to modularize / define the functionality of a one class, that class can uses functions or properties exposed by another class in many different ways. According to Object Oriented Programming, there are several techniques classes can use to link with each other. Those techniques are named association, aggregation, and composition.

There are several other ways that an encapsulation can be used, as an example, we can take the usage of an interface. The interface can be used to hide the information of an implemented class.

C#
IStudent myLStudent = new LocalStudent();
IStudent myFStudent = new ForeignStudent();

According to the sample above (let’s assume that both LocalStudent and ForeignStudent classes have implemented the IStudent interface), we can see how LocalStudent and ForeignStudent hide their localize implementing through the IStudent interface.

As an example in both instances, ‘myLStudent’ and 'myFStudent' are of type IStudent, but they both carry two separate local and foreign implementation underneath. This way, a method call like 'DoLearn(object)' to 'myLStudent' and 'myFStudent' object will trigger their respective foreign and local implementation. This way, 'myFStudent' carrying 'ForeignStudent' will trigger the respective learning function with foreign syllabus while the other one with 'LocalStudent' will trigger the learning function with local syllabus.

4.8. What is Association?

Association is a (*a*) relationship between two classes. It allows one object instance to cause another to perform an action on its behalf. Association is the more general term that defines the relationship between two classes, whereas the aggregation and composition are relatively special.

C#
public class StudentRegistrar
{
    public StudentRegistrar ();
    {
        new RecordManager().Initialize();
    }
}

In this case, we can say that there is an association between StudentRegistrar and RecordManager or there is a directional association from StudentRegistrar to RecordManager or StudentRegistrar use a (*Use*) RecordManager. Since a direction is explicitly specified, in this case, the controller class is the StudentRegistrar.

OOP_Concepts_and_manymore/association.gif

To some beginners, association is a confusing concept. The troubles created not only by the association alone, but with two other OOP concepts, that is association, aggregation and composition. Every one understands association, before aggregation and composition are described. Aggregation or composition cannot be separately understood. If you understand aggregation alone, it will crack the definition given for association, and if you try to understand composition alone, it will always threaten the definition given for aggregation, all three concepts are closely related, hence must be studed together, by comparing one definition to another. Let’s explore all three and see whether we can understand the differences between these useful concepts.

4.9. What Is the Difference Between Association, Aggregation, and Composition?

Association is a *has-a* relationship between two classes where there is no particular ownership in place. It is just the connectivity between the two classes. When you define a variable of one class in another class, you enable first to associate functions and properties of the second class. Then again, both Aggregation and Composition are types of Association.

Aggregation is a weak type of Association with partial ownership. For an Aggregation relationship, we use the term *uses* to imply a weak *has-a* relationship. This is weak compared to Composition. Then again, weak meaning the linked components of the aggregator may survive the aggregations life-cycle without the existence of their parent objects. For example, a school department *uses* teachers. Any teacher may belong to more than one department. And so, if a department ceases to exist, the teacher will still exist.

On the other hand, Composition is a strong type of Association with full ownership. This is strong compared to the weak Aggregation. For a Composition relationship, we use the term *owns* to imply a strong *has-a* relationship. For example, a department *owns* courses, which means that the any course's life-cycle depends on the department's life-cycle. Hence, if a department ceases to exist, the underlying courses will cease to exist as well.

Whenever there is no ownership in place, we regard such a relationship as just an Association and we simply use the *has-a* term, or sometimes the verb describing the relationship. For example, a teacher *has-a* or *teaches* a student. There is no ownership between the teacher and the student, and each has their own life-cycle.

C#
public class University
{
    private Chancellor  universityChancellor = new Chancellor();
}

OOP_Concepts_and_manymore/aggregation.gif

In the example given above, I can say that University aggregate Chancellor or University has an (*has-a*) Chancellor. But even without a Chancellor, a University can exists. But the Faculties cannot exist without the University, the life time of a Faculty (or Faculties) attached with the life time of the University . If University is disposed, the Faculties will not exist. In that case, we called that University is composed of Faculties. So that composition can be recognized as a special type (strong kind) of an aggregation.

OOP_Concepts_and_manymore/composite.gif

Same way, as another example, you can say that, there is a composite relationship in-between a KeyValuePairCollection and a KeyValuePair. As it was with the Faculty and the University, the two mutually depend on each other.

.NET and Java uses the Composite relation to define their Collections. I see Composition is being used in many other ways too. However, the more important factor, that most people forget is the life time factor. The life time of the two classes that has bond with a composite relation mutually depend on each other. If you take the .NET Collection to understand this, there you have the Collection element define inside (it is an inner part, hence called it is composed of) the Collection, farcing the Element to get disposed with the Collection. If not, as an example, if you define the Collection and its Element to be independent, then the relationship would be more of a type Aggregation, than a Composition. So the point is, if you want to bind two classes with Composite relation, more accurate way is to have a one define inside the other class (making it a protected or private class). This way, you are allowing the outer class to fulfill its purpose, while tying the lifetime of the inner class with the outer class.

So in summary, we can say that aggregation is a special kind of an association and composition is a special kind of an aggregation. (Association->Aggregation->Composition)

OOP_Concepts_and_manymore/association_aggre_com.gif

4.10. What is Abstraction and Generalization?

Abstraction is an emphasis on the idea, qualities and properties rather than the particulars (a suppression of detail). The importance of abstraction is derived from its ability to hide irrelevant details and from the use of names to reference objects. Abstraction is essential in the construction of programs. It places the emphasis on what an object is or does rather than how it is represented or how it works. Thus, it is the primary means of managing complexity in large programs.

While abstraction reduces complexity by hiding irrelevant detail, generalization reduces complexity by replacing multiple entities which perform similar functions with a single construct. Generalization is the broadening of application to encompass a larger domain of objects of the same or different type. Programming languages provide generalization through variables, parameterization, generics and polymorphism. It places the emphasis on the similarities between objects. Thus, it helps to manage complexity by collecting individuals into groups and providing a representative which can be used to specify any individual of the group.

Abstraction and generalization are often used together. Abstracts are generalized through parameterization to provide greater utility. In parameterization, one or more parts of an entity are replaced with a name which is new to the entity. The name is used as a parameter. When the parameterized abstract is invoked, it is invoked with a binding of the parameter to an argument.

4.11. What is an Abstract Class?

Abstract classes, which are declared with the abstract keyword, cannot be instantiated. It can only be used as a super-class for other classes that extend the abstract class. Abstract class is the concept and implementation gets completed when it is being realized by a subclass. In addition to this, a class can inherit only from one abstract class (but a class may implement many interfaces) and must override all its methods/properties that are declared to be abstract and may override virtual methods/ properties.

Abstract classes are ideal when implementing frameworks. As an example, let’s study the abstract class named LoggerBase below. Please carefully read the comments as it will help you to understand the reasoning behind this code:

C#
public abstract class LoggerBase
{
    /// <summary>
    /// field is private, so it intend to use inside the class only
    /// </summary>
    private log4net.ILog logger = null;

    /// <summary>
    /// protected, so it only visible for inherited class
    /// </summary>
    protected LoggerBase()
    {
        // The private object is created inside the constructor
        logger = log4net.LogManager.GetLogger(this.LogPrefix);
        // The additional initialization is done immediately after
        log4net.Config.DOMConfigurator.Configure();
    }

    /// <summary>
    /// When you define the property as abstract,
    /// it forces the inherited class to override the LogPrefix
    /// So, with the help of this technique the log can be made,
    /// inside the abstract class itself, irrespective of its origin.
    /// If you study carefully, you will find a reason for not to have "set" method here.
    /// </summary>
    protected abstract System.Type LogPrefix
    {
        get;
    }

    /// <summary>
    /// Simple log method,
    /// which is only visible for inherited classes
    /// </summary>
    /// <param name="message"></param>
    protected void LogError(string message)
    {
        if (this.logger.IsErrorEnabled)
        {
            this.logger.Error(message);
        }
    }

    /// <summary>
    /// Public properties which expose to inherited class
    /// and all other classes that have access to inherited class
    /// </summary>
    public bool IsThisLogError
    {
        get
        {
            return this.logger.IsErrorEnabled;
        }
    }
}

The idea of having this class as an abstract is to define a framework for exception logging. This class will allow all subclasses to gain access to a common exception logging module and will facilitate to easily replace the logging library. By the time you define the LoggerBase, you wouldn’t have an idea about other modules of the system. But you do have a concept in mind and that is, if a class is going to log an exception, they have to inherit the LoggerBase. In other words, the LoggerBase provides a framework for exception logging.

Let’s try to understand each line of the above code.

Like any other class, an abstract class can contain fields, hence I used a private field named logger declare the ILog interface of the famous log4net library. This will allow the Loggerbase class to control, what to use, for logging, hence, will allow changing the source logger library easily.

The access modifier of the constructor of the LoggerBase is protected. The public constructor has no use when the class is of type abstract. The abstract classes are not allowed to instantiate the class. So I went for the protected constructor.

The abstract property named LogPrefix is an important one. It enforces and guarantees to have a value for LogPrefix (LogPrefix uses to obtain the detail of the source class, which the exception has occurred) for every subclass, before they invoke a method to log an error.

The method named LogError is protected, hence exposed to all subclasses. You are not allowed or rather you cannot make it public, as any class, without inheriting the LoggerBase cannot use it meaningfully.

Let’s find out why the property named IsThisLogError is public. It may be important/ useful for other associated classes of an inherited class to know whether the associated member logs its errors or not.

Apart from these, you can also have virtual methods defined in an abstract class. The virtual method may have its default implementation, where a subclass can override it when required.

All and all, the important factor here is that all OOP concepts should be used carefully with reasons, you should be able to logically explain, why you make a property a public or a field a private or a class an abstract. Additionally, when architecting frameworks, the OOP concepts can be used to forcefully guide the system to be developed in the way framework architect’s wanted it to be architected initially.

4.12. What is an Interface?

In summary, the Interface separates the implementation and defines the structure, and this concept is very useful in cases where you need the implementation to be interchangeable. Apart from that, an interface is very useful when the implementation changes frequently. Some say you should define all classes in terms of interfaces, but I think recommendation seems a bit extreme.

Interface can be used to define a generic template and then one or more abstract classes to define partial implementations of the interface. Interfaces just specify the method declaration (implicitly public and abstract) and can contain properties (which are also implicitly public and abstract). Interface definition begins with the keyword interface. An interface like that of an abstract class cannot be instantiated.

If a class that implements an interface does not define all the methods of the interface, then it must be declared abstract and the method definitions must be provided by the subclass that extends the abstract class. In addition to this, an interface can inherit other interfaces.

The sample below will provide an interface for our LoggerBase abstract class.

C#
public interface ILogger
{
    bool IsThisLogError { get; }
}

4.13. What Is the Difference Between a Class and an Interface?

In .NET/ C#, a class can be defined to implement an interface and also it supports multiple implementations. When a class implements an interface, an object of such class can be encapsulated inside an interface.

If MyLogger is a class, which implements ILogger, there we can write:

C#
ILogger log = new MyLogger();

A class and an interface are two different types (conceptually). Theoretically, a class emphasizes the idea of encapsulation, while an interface emphasizes the idea of abstraction (by suppressing the details of the implementation). The two pose a clear separation from one to another. Therefore, it is very difficult or rather impossible to have an effective meaningful comparison between the two, but it is very useful and also meaningful to have a comparison between an interface and an abstract class.

4.14. What Is the Difference Between an Interface and an Abstract Class?

There is quite a big difference between an interface and an abstract class, even though both look similar:

  • Interface definition begins with a keyword interface so it is of type interface.
  • Abstract classes are declared with the abstract keyword so it is of type class.
  • Interface has no implementation, but they have to be implemented.
  • Abstract class’s methods can have their own default implementations and they may be extended. The Abstract class’s methods could run independent of the inheriting class.
  • Interfaces can only have method declaration (implicitly public and abstract) and properties (implicitly public static)
  • Abstract class’s methods can’t have implementation only when declared abstract.
  • Interface can inherit more than one interface.
  • Abstract class can implement more than one interface, but can inherit only one class.
  • Abstract class must override all abstract method and may override virtual methods.
  • Interface can be used when the implementation is changing.
  • Abstract class can be used to provide some default behavior for a base class.
  • Interface makes implementation interchangeable.
  • Interface increase security by hiding the implementation.
  • Abstract class can be used when implementing framework.
  • Abstract classes are an excellent way to create planned inheritance hierarchies and also to use as non-leaf classes in class hierarchies.

Abstract classes let you define some behaviors; they force your subclasses to provide others. For example, if you have an application framework, an abstract class can be used to provide the default implementation of the services and all mandatory modules such as event logging and message handling, etc. This approach allows the developers to develop the application within the guided help provided by the framework.

However, in practice, when you come across with some application-specific functionality that only your application can perform, such as startup and shutdown tasks, etc. The abstract base class can declare virtual shutdown and startup methods. The base class knows that it needs those methods, but an abstract class lets your class admit that it doesn't know how to perform those actions; it only knows that it must initiate the actions. When it is time to start up, the abstract class can call the startup method. When the base class calls this method, it can execute the method defined by the child class.

4.15. What are Implicit and Explicit Interface Implementations?

As mentioned before, .NET supports multiple implementations, the concept of implicit and explicit implementation provide safe way to implement methods of multiple interfaces by hiding, exposing or preserving identities of each interface method, even when the method signatures are the same.

Let's consider the interfaces defined below:

C#
interface IDisposable
{
    void Dispose();
}

Here, you can see that the class Student has implicitly and explicitly implemented the method named Dispose() via Dispose and IDisposable.Dispose.

C#
class Student : IDisposable
{
    public void Dispose()
    {
        Console.WriteLine("Student.Dispose");
    }

    void IDisposable.Dispose()
    {
        Console.WriteLine("IDisposable.Dispose");
    }
}

4.16. What is Inheritance?

The ability of a new class to be created, from an existing class by extending it, is called inheritance.

OOP_Concepts_and_manymore/inheritance.gif

C#
public class Exception
{
}

public class IOException : Exception
{
}

According to the above example, the new class (IOException), which is called the derived class or subclass, inherits the members of an existing class (Exception), which is called the base class or super-class. The class IOException can extend the functionality of the class Exception by adding new types and methods and by overriding existing ones.

Just like abstraction is closely related with generalization, the inheritance is closely related with specialization. It is important to discuss those two concepts together with generalization to better understand and to reduce the complexity.

One of the most important relationships among objects in the real world is specialization, which can be described as the “is-a” relationship. When we say that a dog is a mammal, we mean that the dog is a specialized kind of mammal. It has all the characteristics of any mammal (it bears live young, nurses with milk, has hair), but it specializes these characteristics to the familiar characteristics of canis domesticus. A cat is also a mammal. As such, we expect it to share certain characteristics with the dog that are generalized in Mammal, but to differ in those characteristics that are specialized in cats.

The specialization and generalization relationships are both reciprocal and hierarchical. Specialization is just the other side of the generalization coin: Mammal generalizes what is common between dogs and cats, and dogs and cats specialize mammals to their own specific subtypes.

Similarly, as an example, you can say that both IOException and SecurityException are of type Exception. They have all characteristics and behaviors of an Exception that mean the IOException is a specialized kind of Exception. A SecurityException is also an Exception. As such, we expect it to share certain characteristics with IOException that are generalized in Exception, but to differ in those characteristics that are specialized in SecurityExceptions. In other words, Exception generalizes the shared characteristics of both IOException and SecurityException, while IOException and SecurityException specialize with their characteristics and behaviors.

In OOP, the specialization relationship is implemented using the principle called inheritance. This is the most common and most natural and widely accepted way of implement this relationship.

4.17. What is Polymorphism?

Polymorphisms is a generic term that means 'many shapes'. More precisely Polymorphisms means the ability to request that the same operations be performed by a wide range of different types of things.

At times, I used to think that understanding Object Oriented Programming concepts has made it difficult since they have grouped under four main concepts, while each concept is closely related with one another. Hence, one has to be extremely careful to correctly understand each concept separately, while understanding the way each related with other concepts.

In OOP, the polymorphisms is achieved by using many different techniques named method overloading, operator overloading and method overriding,

4.18. What is Method Overloading?

Method overloading is the ability to define several methods all with the same name.

C#
public class MyLogger
{
    public void LogError(Exception e)
    {
        // Implementation goes here
    }

    public bool LogError(Exception e, string message)
    {
        // Implementation goes here
    }
}

4.19. What is Operator Overloading?

The operator overloading (less commonly known as ad-hoc polymorphisms) is a specific case of polymorphisms in which some or all of operators like +, - or == are treated as polymorphic functions and as such have different behaviors depending on the types of its arguments.

C#
public class Complex
{
    private int real;
    public int Real
    { get { return real; } }

    private int imaginary;
    public int Imaginary
    { get { return imaginary; } }

    public Complex(int real, int imaginary)
    {
        this.real = real;
        this.imaginary = imaginary;
    }

    public static Complex operator +(Complex c1, Complex c2)
    {
        return new Complex(c1.Real + c2.Real, c1.Imaginary + c2.Imaginary);
    }
}

In the above example, I have overloaded the plus operator for adding two complex numbers. There the two properties named Real and Imaginary have been declared exposing only the required “get” method, while the object’s constructor is demanding for mandatory real and imaginary values with the user defined constructor of the class.

4.20. What is Method Overriding?

Method overriding is a language feature that allows a subclass to override a specific implementation of a method that is already provided by one of its super-classes.

A subclass can give its own definition of methods but needs to have the same signature as the method in its super-class. This means that when overriding a method, the subclass's method has to have the same name and parameter list as the super-class' overridden method.

C#
using System;
public class Complex
{
    private int real;
    public int Real
    { get { return real; } }

    private int imaginary;
    public int Imaginary
    { get { return imaginary; } }

    public Complex(int real, int imaginary)
    {
        this.real = real;
        this.imaginary = imaginary;
    }

    public static Complex operator +(Complex c1, Complex c2)
    {
        return new Complex(c1.Real + c2.Real, c1.Imaginary + c2.Imaginary);
    }

    public override string ToString()
    {
        return (String.Format("{0} + {1}i", real, imaginary));
    }
}

In the above example, I have extended the implementation of the sample Complex class given under operator overloading section. This class has one overridden method named ToString, which overrides the default implementation of the standard ToString method to support the correct string conversion of a complex number.

C#
Complex num1 = new Complex(5, 7);
Complex num2 = new Complex(3, 8);

// Add two Complex numbers using the
// overloaded plus operator
Complex sum = num1 + num2;

// Print the numbers and the sum
// using the overridden ToString method
Console.WriteLine("({0}) + ({1}) = {2}", num1, num2, sum);
Console.ReadLine();

4.21. What is a Use Case?

A Use Case is a thing an actor perceives from the system. A Use Case maps actors with functions. Importantly, the actors need not be people. As an example, a system can perform the role of an actor, when it communicates with another system.

OOP_Concepts_and_manymore/usercase1.gif

In another angle, a Use Case encodes a typical user interaction with the system. In particular, it:

  • captures some user-visible function.
  • achieves some concrete goal for the user.

A complete set of Use Cases largely defines the requirements for your system: everything the user can see, and would like to do. The below diagram contains a set of use cases that describes a simple login module of a gaming website.

OOP_Concepts_and_manymore/usecaselogin.gif

4.22. What is a Class Diagram?

Class diagrams are widely used to describe the types of objects in a system and their relationships. Class diagrams model class structure and contents using design elements such as classes, packages and objects. Class diagrams describe three different perspectives when designing a system, conceptual, specification, and implementation. These perspectives become evident as the diagram is created and help solidify the design.

The Class diagrams, physical data models, along with the system overview diagram are in my opinion, the most important diagrams that suit the current day rapid application development requirements.

UML notations:

OOP_Concepts_and_manymore/notation.jpg

4.23. What is a Package Diagram?

Package diagrams are used to reflect the organization of packages and their elements. When used to represent class elements, package diagrams provide a visualization of the name-spaces. In my designs, I use the package diagrams to organize classes into different modules of the system.

4.24. What is a Sequence Diagram?

A sequence diagram models the flow of logic within a system in a visual manner, it enables both to document and validates your logic, and are used for both analysis and design purposes. Sequence diagrams are the most popular UML artifact for dynamic modeling, which focuses on identifying the behavior within your system.

4.25. What Is Two-Tier Architecture?

The two-tier architecture refers to client/ server architectures as well, the term client/ server was first used in the 1980s in reference to personal computers (PCs) on a network. The actual client/ server model started gaining acceptance in the late 1980s, and later it was adapted to World Wide Web programming.

According to the modern days use of two-tier architecture, the user interfaces (or with ASP.NET, all web pages) runs on the client and the database is stored on the server. The actual application logic can run on either the client or the server. So in this case, the user interfaces are directly access the database. Those can also be non-interface processing engines, which provide solutions to other remote/ local systems. In either case, today the two-tier model is not as reputed as the three-tier model. The advantage of the two-tier design is its simplicity, but the simplicity comes with the cost of scalability. The newer three-tier architecture, which is more famous, introduces a middle tier for the application logic.

OOP_Concepts_and_manymore/2-tier.jpg

4.26. What Is Three-Tier Architecture?

The three tier software architecture (also known as three layer architectures) emerged in the 1990s to overcome the limitations of the two tier architecture. This architecture has been aggressively customized and adopted by modern day system designer to web systems.

Three-tier is a client-server architecture in which the user interface, functional process logic, data storage and data access are developed and maintained as independent modules, some time on separate platforms. The term "three-tier" or "three-layer", as well as the concept of multi-tier architectures (often refers to as three-tier architecture), seems to have originated within Rational Software.

OOP_Concepts_and_manymore/3-tier.jpg

The three-tier architecture has the following three tiers:

  1. Presentation Tier or Web Server: User Interface, displaying/ accepting data/ input to/ from the user
  2. Application Logic/ Business Logic/ Transaction Tier or Application Server: Data validation, acceptability check before being added to the database and all other business/ application specific operations
  3. Data Tier or Database server: Simple reading and writing method to database or any other storage, connection, command, stored procedures, etc.

4.27. What is MVC architecture?

The Model-View-Controller (MVC) architecture separates the modeling of the domain, the presentation, and the actions based on user input into three separate classes.

Unfortunately, the popularity of this pattern has resulted in a number of faulty usages; each technology (Java, ASP.NET, etc.) has defined it in their own way making it difficult to understand. In particular, the term "controller" has been used to mean different things in different contexts. The definitions given bellow are the closes possible ones I found for ASP.NET version of MVC.

OOP_Concepts_and_manymore/mvc.jpg

  1. Model: DataSet and typed DataSet (some times business object, object collection, XML, etc.) are the most common uses of the model.
  2. View: The ASPX and ASCX files generally handle the responsibilities of the view.
  3. Controllers: The handling of events or the controlling is usually done in the code-behind class.

In a complex n-tier distributed system, the MVC architecture places the vital role of organizing the presentation tier of the system.

4.28. What is SOA?

A service-oriented architecture is essentially a collection of services. These services communicate with each other. The communication can involve either simple data passing or it could involve two or more services coordinating some activity. Some means of connecting services to each other is needed.

.NET Framework introduced SOA by means of web services.

OOP_Concepts_and_manymore/soa.gif

The SOA can be used as the concept to connect multiple systems to provide services. It has its great share in the future of the IT world.

According to the imaginary diagram above, we can see how the Service Oriented Architecture is being used to provide a set of centralized services to the citizens of a country. The citizens are given a unique identifying card, where that card carries all personal information of each citizen. Each service centers such as shopping complex, hospital, station, and factory are equipped with a computer system where that system is connected to a central server, which is responsible for providing service to a city. As an example, when a customer enter the shopping complex, the regional computer system reports it to the central server and obtains information about the customer before providing access to the premises. The system welcomes the customer. The customer finished the shopping and then by the time he leaves the shopping complex, he will be asked to go through a billing process, where the regional computer system will manage the process. The payment will be automatically handled with the input details obtain from the customer identifying card.

The regional system will report to the city (computer system of the city) while the city will report to the country (computer system of the country).

4.29. What is the Data Access Layer?

The data access layer (DAL), which is a key part of every n-tier system, mainly consists of a simple set of code that does basic interactions with the database or any other storage device. These functionalities are often referred to as CRUD (Create, Retrieve, Update, and Delete).

The data access layer need to be generic, simple, quick and efficient as much as possible. It should not include complex application/ business logics.

I have seen systems with lengthy, complex store procedures (SP), which run through several cases before doing a simple retrieval. They contain not only most part of the business logic, but application logic and user interface logic as well. If SP is getting longer and complicated, then it is a good indication that you are burring your business logic inside the data access layer.

4.30. What is the Business Logic Layer?

I know for a fact that this is a question for most, but from the other hand by reading many articles, I have become aware that not everyone agrees to what business logic actually is, and in many cases it's just the bridge in between the presentation layer and the data access layer with having nothing much, except taking from one and passing to the other. In some other cases, it is not even been well thought out, they just take the leftovers from the presentation layer and the data access layer then put them in another layer which automatically is called the business logic layer. However, there are no god said things that cannot be changed in software world. You can change as and when you feel comfortable that the method you apply is flexible enough to support the growth of your system. There are many great ways, but be careful when selecting them, they can over complicating the simple system. It is a balance one needs to find with one's experience.

As a general advice, when you define business entities, you must decide how to map the data in your tables to correctly defined business entities. The business entities should meaningfully define considering various types of requirements and functioning of your system. It is recommended to identify the business entities to encapsulate the functional/ UI (User Interface) requirements of your application, rather than define a separate business entity for each table of your database. For example, if you want to combine data from couple of tables to build a UI (User Interface) control (Web Control), implement that function in the Business Logic Layer with a business object that uses couple of data object to support with your complex business requirement.

4.31. What is Gang of Four (GoF) Design Patterns?

The Gang of Four (GoF) patterns are generally considered the foundation for all other patterns. They are categorized in three groups: Creational, Structural, and Behavioral. Here, you will find information on these important patterns.

Creational Patterns

  • Abstract Factory - creates an instance of several families of classes
  • Builder - separates object construction from its representation
  • Factory method - creates an instance of several derived classes
  • Prototype - A fully initialized instance to be copied or cloned
  • Singleton - A class of which only a single instance can exist

Structural Patterns

  • Adapter - match interfaces of different classes
  • Bridge - separates an object’s interface from its implementation
  • Composite - a tree structure of simple and composite objects
  • Decorator - adds responsibilities to objects dynamically
  • Facade - a single class that represents an entire subsystem
  • Flyweight - a fine-grained instance used for efficient sharing
  • Proxy - an object representing another object

Behavioral Patterns

  • Chain of resp - a way of passing a request between a chain of objects
  • Command - encapsulate a command request as an object
  • Interpreter - a way to include language elements in a program
  • Iterator - sequentially access the elements of a collection
  • Mediator - defines simplified communication between classes
  • Memento - captures and restores an object's internal state
  • Observer - a way of notifying change to a number of classes
  • State - alter an object's behavior when its state changes
  • Strategy - encapsulates an algorithm inside a class
  • Template method - defers the exact steps of an algorithm to a subclass
  • Visitor - defines a new operation to a class without change

4.32. What Is the Difference Between Abstract Factory and Builder Design Patterns?

The two design patterns are fundamentally different. However, when you learn them for the first time, you will see a confusing similarity. So that will make it harder for you to understand them. But if you continue to study eventually, you will get afraid of design patterns too. It is like infant phobia, once you get afraid at your early age, it stays with you forever. So the result would be that you never look back at design patterns again. Let me see whether I can solve this brain teaser for you.

In the image below, you have both design pattern listed in. I am trying to compare the two one on one to identify the similarities. If you observe the figure carefully, you will see an easily understandable color pattern (same color is used to mark the classes that are of similar kind).

Factory and Builder

Please follow up with the numbers in the image when reading the listing below:

  • Mark #1: Both patterns have used a generic class as the entry-class. The only difference is the name of the class. One pattern has named it as “Client”, while the other named it as “Director”.
  • Mark #2: Here again, the difference is the class name. It is “AbstractFactory” for one and “Builder” for the other. Additionally, both classes are of type abstract.
  • Mark #3: Once again, both patterns have defined two generic (WindowsFactory and ConcreteBuilder) classes. They both have created by inheriting their respective abstract class.
  • Mark #4: Finally, both seem to produce some kind of a generic output.

Now, where are we? Aren’t they looking almost identical? So then, why are we having two different patterns here?

Let’s compare the two again side by side for one last time, but this time, focusing on the differences.

  • Abstract Factory: Emphasizes a family of product objects (either simple or complex)
  • Builder: Focuses on constructing a complex object step by step
  • Abstract Factory: Focus on *what* is made
  • Builder: Focus on *how* it is made
  • Abstract Factory: Focus on defining many different types of *factories* to build many *products*, and it is not a one builder for just one product
  • Builder: Focus on building a one complex but one single *product*
  • Abstract Factory: Defers the choice of what concrete type of object to make until run time
  • Builder: Hide the logic/ operation of how to compile that complex object
  • Abstract Factory: *Every* method call creates and returns different objects
  • Builder: Only the *last* method call returns the object, while other calls partially build the object

Sometimes creational patterns are complementary: so you can join one or many patterns when you design your system. As an example builder can use one of the other patterns to implement which components get built or in another case Abstract Factory, Builder, and Prototype can use Singleton in their implementations. So the conclusion would be that the two design patterns exist to resolve two type of business problems, so even though they look similar, they are not.

I hope that this shed some light to resolve the puzzle. If you still don’t understand it, then this time it is not you, it has to be me and it is since that I don’t know how to explain it.

5. What is the Conclusion?

I don't think that it is realistic trying to make a programming language be everything to everybody. The language becomes bloated, hard to learn, and hard to read if everything plus the kitchen sink is thrown in. In other words, every language has its limitations. As system architect and designer, we should be able to fully and more importantly correctly (this also means that you shouldn’t use a ballistic missile to kill a fly or hire FBI to catch the fly) utilize the available tools and features to build usable, sustainable, maintainable and also very importantly expandable software systems, that fully utilize the feature of the language to bring a competitively advance system to their customers. In order to do it, the foundation of a system places a vital role. The design or the architecture of a software system is the foundation. It holds the system together, hence designing a system properly (this never mean an *over* designing) is the key to the success. When you talk about designing a software system, the correct handling of OOP concept is very important. I have made the above article richer with idea but still kept it short so that one can learn/ remind all of important concept at a glance. Hope you all will enjoy reading it.

 

What Next?

It is good to learn all these theories, but one can ask the point of learning them if you don't know how to put them into practise. These need to give us some benefits, right? Therefore, I thought that I should demonstrate the use of these concepts at least in one concrete project.

Therefore, a team of us developed a framework called 'Nido' Framework. This virtually demonstrates the use of most of these OOP concepts.

It is very popular among developers these days. Nido Framework is a reusable, highly generic code library developed using Microsoft .NET/ C# to provide a common platform for all .NET systems. You can derive your project from Nido and quickly develop your systems.

If you want to beat your colleague with your coding speed or want to meet those tough deadlines which you always failed to hit, try using Nido. Today, most the university students and professionals use Nido for their development and share their success stories.

We have tested it with a number of complex business applications where it has proved to deliver stable, robust system at an extremely short time frame. If you want to check Nido source code or learn the architecture, please visit the links given below. By the way, it is open source and free to use in commercial projects.

6. What I Referred?

7. History

  • 28th January, 2008
    • Added more content base on design principles
    • Added History section
  • 4th February, 2008
    • Added more details to explain the Composition
  • 15th April, 2008
    • Added comparison between Abstract Factory and Builder
    • Updated some of the wording slightly
  • 31st May, 2010
    • - Corrected the 'Composition' related description, as pointed here
  • 26th January, 2011
    • Conclusion is updated and a link is added to Rocket-Framework
  • 23rd October, 2014
    • Added 'What Next' Section
  • 27th January, 2015

License

This article, along with any associated source code and files, is licensed under The Code Project Open License (CPOL)