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'''Types vs Classes''' | '''Types vs Classes''' | ||
<blockquote style="background-color: #F2F2F2; border: solid thin black; padding: 5px;"><small> | |||
Survey the differences on type vs. class in object-oriented languages. Often, the distinction is that class pertains to an object, whereas type pertains to a variable. Consider the distinction between the two terms in several different programming languages. Cover the differences between type and class, from type-theoretic definitions to practical aspects. This topic was covered three years ago (http://pg-server.csc.ncsu.edu/mediawiki/index.php/CSC/ECE_517_Fall_2007), but all of the articles considered one language after the other, in a set of examples rather than a discussion of issues. Make sure that you discuss the issues, using languages as examples rather than making language the primary means of organizing the chapter. | |||
</small></blockquote> | |||
[[Image:Overall s.png|right|frame|Relationship between Type and Class]] | |||
[[Image:Overall s.png|right| | |||
==Introduction== | ==Introduction== | ||
Line 8: | Line 10: | ||
It is often that we talk about types, strongly typed, weakly typed, classes. To make it clear, let us look into it clearly. Every programming language has a way to define a variable. A variable is a named address location which stores a particular value. | It is often that we talk about types, strongly typed, weakly typed, classes. To make it clear, let us look into it clearly. Every programming language has a way to define a variable. A variable is a named address location which stores a particular value. | ||
[[Image:Connection s.png|right|thumb|Classes are a 'type' that can combine other types.]] | |||
===Types=== | ===Types=== | ||
Line 35: | Line 37: | ||
as well as | as well as | ||
<code><pre> | <code><pre> | ||
variable1 = “Good morning Vietnam” | variable1 = “Good morning Vietnam” | ||
</pre></code> | </pre></code> | ||
Line 61: | Line 63: | ||
Classes, Interfaces, Arrays are all consolidations of Primitive types, so they just need to “point” to or reference the primitive ones, hence the name. | Classes, Interfaces, Arrays are all consolidations of Primitive types, so they just need to “point” to or reference the primitive ones, hence the name. | ||
It is sometimes confusing and difficult to come up with a clear and robust distinction between Types and Classes. One might think "Class to be a Type of Type". | |||
It is however important to know that in strict Object Oriented Languages, Type is a union of Classes and Primitives. This rule, more or less consistent (with some deviations where primitives are treated as classes). | |||
==Types and Classes in Languages== | ==Types and Classes in Languages== | ||
===Ruby=== | ===Ruby=== | ||
Line 108: | Line 112: | ||
* Reference Types:- class types, interface types and array types. [2] | * Reference Types:- class types, interface types and array types. [2] | ||
Java is an object-oriented language, but it does make a clear distinction between the primitive type and Classes. int, float, char etc. are primitives, and the other data types other than the primitives are references. It is an interesting distinction to note, because of the differences in method calling system in different languages. Java makes a distinction in "calling-by-value" when a primitive is passed as a parameter, and "calling-by-reference" when an object is passed. | Java is an object-oriented language, but it does make a clear distinction between the primitive type and Classes. int, float, char etc. are primitives, and the other data types other than the primitives are references. It is an interesting distinction to note, because of the differences in method calling system in different languages. Java makes a distinction in "calling-by-value" when a primitive is passed as a parameter, and "calling-by-reference" when an object is passed. In fact, if a primitive is passed, a call by value is invoked, but when a Class object is passed, only a reference is passed to the object. | ||
For a more language specific treatment of types and classes, you can refer: http://pg-server.csc.ncsu.edu/mediawiki/index.php/CSC/ECE_517_Fall_2007/wiki2_6_ap | |||
==Discussion of Issues== | |||
Okay, so you're about to write a program and you need to represent data somehow. Should you use a primitive type? What about a class? There are several features that are handed to you with each. | |||
=== Primitive Types === | |||
==== Advantages ==== | |||
===== Simplicity ===== | |||
In strongly typed languages, primitive types are ideal for data which doesn't necessarily need to be partitioned into several smaller components. If you are looking to store and represent a simple throw-away integer for looping, for example, there's little reason why one would want to construct a class for this throw-away integer purpose. | |||
Primitive types are also often times coupled with native operations, handed to you by the language. For example, in Java, variables of type int are automatically given operations such as addition, subtraction, multiplication, and so on. These operations work as follows: | |||
# Receive both inputs | |||
# Cast if necessary (for example, from an int to a double) | |||
# Perform calculation | |||
# Return result | |||
It is important to note that the primitive types themselves are left ''unchanged'', and the result is returned from the operation, giving the programmer the ability to place the result elsewhere. | |||
===== Efficiency ===== | |||
In efficiency-critical applications, primitive types and their operations are oftentimes mapped directly to hardware-supported equivalents, thus operations can be performed very quickly. This style of downgrading the logic to more so the hardware level has been replaced over the years for general applications, since improvements to hardware components have eradicated the once-imperative necessity to program efficiently. Another point of view concerning efficiency could be from development time: if the program one is writing doesn't require complex design, it would be quicker to use the language's built-in types instead of taking the time to design a class to do the same feature. | |||
=== | ==== Disadvantages ==== | ||
===== Single-state storage ===== | |||
One large disadvantages to primitive types are that they are generally capable of only holding a single dimension state. This limitation requires the programmer to use other variables in conjunction if they desire to hold more than one field of data. | |||
===== Refactoring ===== | |||
Since primitive types do not allow you to encapsulate your data, if you ever desire to change the behavior of your program, you are forced to manually check each use of the variable for enforcement. | |||
For example, suppose you have a system designed in Java that maintains an integer value which represents the number of books you have in a library. | |||
<code><pre> | |||
int numBooks; | |||
... | |||
numBooks = 0; | |||
... | |||
numBooks++; | |||
... | |||
numBooks--; | |||
... | |||
</pre></code> | |||
= | A few days later, you realize that you should probably refactor your system to maintain a log of when this variable updates. You immediately face a problem since, as it is, your code directly manipulates a single-state type integer. Without resorting to a more object-oriented solution, you would have to update each location in the code of where a change takes place in order to establish this bookkeeping (pun intended). | ||
<code id="bookKeeping"><pre> | |||
public static void integerValueChanged(){ | |||
// records that the value has been changed | |||
... | |||
} | |||
= | public static void main(String[]args){ | ||
int numBooks; | |||
... | |||
numBooks = 0; | |||
integerValueChanged(); | |||
... | |||
numBooks++; | |||
integerValueChanged(); | |||
... | |||
numBooks--; | |||
integerValueChanged(); | |||
... | |||
} | |||
</pre></code> | |||
To generalize this concept, it is oftentimes necessary to modify "what happens" when something is updated, and this cannot be easily accomplished by merely using primitive types. | |||
=== Class Types === | === Class Types === | ||
Classes to the rescue! Classes give programmers the ability to construct complex data types that are also capable of defining their own operations, all while keeping the details and specifics black-boxed outsize of where the class will be used in the code. | |||
==== Advantages ==== | ==== Advantages ==== | ||
===== Multi-dimensional Storage ===== | |||
Contrasting to primitive types, classes allow programmers to couple a varying number of fields. Grouping fields of data into a single class, then instantiating such an object and manipulating it is much more convenient than keeping track of several individual variables. | |||
===== Refactoring ===== | |||
Oftentimes it is necessary to refactor a system to execute code when a change happens. In object-land, we are able to do this through the ability to control what happens in our methods. | |||
Taking our [[#bookKeeping| example from above]], we can give a quick example of how a class could be defined to handle the situation much more elegantly. | |||
<code><pre> | |||
public class RecordedNumber{ | |||
// The integer value, kept concealed in the class | |||
private int value; | |||
public RecordedNumber(int value){ | |||
this.value = value; | |||
} | |||
public int getValue(){ | |||
return value; | |||
} | |||
public void setValue(int newValue){ | |||
// code to do any necessary recording. | |||
... | |||
this.value = newValue; | |||
} | |||
} | |||
public class MyExample{ | |||
public static void main(String[]args){ | |||
RecordedNumber numBooks = new RecordedNumber(0); | |||
... | |||
numBooks.setValue(4); // the object handles all necessary bookkeeping | |||
... | |||
} | |||
} | |||
</pre></code> | |||
<br /> | |||
===== Code-reuse ===== | |||
Another nice feature to class-types encapsulate the concept surrounding code re-usability, especially in topics such as inheritance. Classes allow the programmer to enhance an already existing class-type to be more specific, which in turn can prevent excessive code duplication. | |||
===== Application Structure ===== | |||
Designing an application in a object-oriented / class-specific style can reduce the challenges of designing and building a difficult system into merely making objects successfully interact. It is from this concept that languages such as [http://en.wikipedia.org/wiki/Unified_Modeling_Language Unified Modeling Language (UML)] have been created, allowing software engineers to build around the notion of classes and their relationships to one another. | |||
<br /> | |||
==== Disadvantages ==== | ==== Disadvantages ==== | ||
===== Speed Considerations ===== | |||
In computational-intensive applications, objects built from classes tend to be less efficient than primitive data types built around procedural context. This is due in part because of the object's creation, since it isn't supported directly hardware level. Consideration is placed more so on good-design and coding-practices when implementing functionality around classes. | |||
<br /> | |||
===== Complexity ===== | |||
Oftentimes one doesn't need the functionality provided by classes to handle the problem they are trying to solve. Consequently, such an unnecessary use oftentimes over-complicates the principle design and may add unnecessary burdens to maintain the code. This regard is more so geared towards small-programs where objects and classes may not be the best fit for their implementation. Examples of this situation vary, since it is highly opinionated, but are more so an example of bad design in an object-oriented sense: to quote Albert Einstein, "Everything should be made as simple as possible, but no simpler." | |||
<br /> | |||
Latest revision as of 05:45, 21 October 2010
Types vs Classes
Survey the differences on type vs. class in object-oriented languages. Often, the distinction is that class pertains to an object, whereas type pertains to a variable. Consider the distinction between the two terms in several different programming languages. Cover the differences between type and class, from type-theoretic definitions to practical aspects. This topic was covered three years ago (http://pg-server.csc.ncsu.edu/mediawiki/index.php/CSC/ECE_517_Fall_2007), but all of the articles considered one language after the other, in a set of examples rather than a discussion of issues. Make sure that you discuss the issues, using languages as examples rather than making language the primary means of organizing the chapter.
Introduction
It is often that we talk about types, strongly typed, weakly typed, classes. To make it clear, let us look into it clearly. Every programming language has a way to define a variable. A variable is a named address location which stores a particular value.
Types
Time for an analogy? Imagine a variable to be a vacant house. It could have animals, humans, robots, or another smaller house, or whatever you can think of. There has to be a way, from a third party perspective, so as to be cognizant of the kind of things that reside in the house. Types and typing is a concept which realizes this concept. A typed language or a strongly typed language is one where the type of a variable has to be declared so as to avoid any wrong dealings of the value during run time. For example, Java is a strongly typed language. If I need to use two integers for addition, I would explicitly have to mention them as an integer:-
int integer1;
int integer2;
However, we can’t then re-initialize it to any other type in its defined scope.
integer1 = “Hello World”; // cannot map an int to a String
In the case of non-typed languages, say Ruby, or Visual Basic, etc. We don’t need to specify a type.
def variable1;
def variable2;
Now, it could be initialized with anything,
variable1 = 3
as well as
variable1 = “Good morning Vietnam”
Classes
A class is a “type” of variable specification. The difference between a class and a regular primitive integer, character, etc is that a class:-
- consists of one or more primitive or non-primitive variables
- is a pre-defined structure
- defines methods which operate on the internal state of the object
The Type of Class is “Class”, just like the Type of integer is “integer” in case of strongly typed languages.
For example, in case of Java:-
“The types of the Java programming language are divided into two categories: primitive types and reference types. The primitive types are the boolean type and the numeric types. The numeric types are the integral types byte, short, int, long, and char, and the floating-point types float and double. The reference types are class types, interface types, and array types. There is also a special null type. An object is a dynamically created instance of a class type or a dynamically created array. The values of a reference type are references to objects. All objects, including arrays, support the methods of class Object . String literals are represented by String objects .” [2]
So, as mentioned before, in Java, there are two “Types”:-
- Primitive Type
- Reference Type
Classes, Interfaces, Arrays are all consolidations of Primitive types, so they just need to “point” to or reference the primitive ones, hence the name. It is sometimes confusing and difficult to come up with a clear and robust distinction between Types and Classes. One might think "Class to be a Type of Type". It is however important to know that in strict Object Oriented Languages, Type is a union of Classes and Primitives. This rule, more or less consistent (with some deviations where primitives are treated as classes).
Types and Classes in Languages
Ruby
Ruby claims to be a strong object oriented language. It is object oriented to the extent that every thing is an object. Primitive datatypes are objects, and we can make use of the object oriented techniques on even the primitives. As mentioned before, Ruby is a dynamic typed language, as the type is bound at compile time. Everything in Ruby has a class. Every class in Ruby is inherited from class Class.
Type in Ruby is well defined as well. Using self inspection (reflection), we can find out whether a name is a Class, or a method. Let us see this in action:-
The first thing that comes to a one’s mind is something like :
5.class #=> Fixnum
"hello".class #=> String
But have you thought of your class as an object? Well that seems odd, but that’s how ruby works:
5.class #=> Fixnum
class Foo;end #=> nil
Foo.class #=> Class
What does the above snippet of code mean exactly? It means 2 things : Foo is a constant and that constant holds(refers to) an object of Class type.
Let us prove that:
Foo = Class.new
(irb):8 warning: already initialized constant Foo
=> Foo
As you can see, we got a warning because we tried to initialize the constant Foo again.
So ,when you define some class ‘Foo’ in ruby, all you are doing is: 1-instantiating an object of type Class. 2-initializing a constant Foo that refers to that created object .
So, when we say “object” ,then we do mean any object; an object of Class type, or any object of any type.[3]
Java
As mentioned before, Java is a strongly typed language. The type of data needs to be declared before using. The types of "types" in Java are :
* Primitive Types:- boolean and numeric. The numeric types are the integral types byte, short, int, long, and char, and the floating-point types float and double. * Reference Types:- class types, interface types and array types. [2]
Java is an object-oriented language, but it does make a clear distinction between the primitive type and Classes. int, float, char etc. are primitives, and the other data types other than the primitives are references. It is an interesting distinction to note, because of the differences in method calling system in different languages. Java makes a distinction in "calling-by-value" when a primitive is passed as a parameter, and "calling-by-reference" when an object is passed. In fact, if a primitive is passed, a call by value is invoked, but when a Class object is passed, only a reference is passed to the object.
For a more language specific treatment of types and classes, you can refer: http://pg-server.csc.ncsu.edu/mediawiki/index.php/CSC/ECE_517_Fall_2007/wiki2_6_ap
Discussion of Issues
Okay, so you're about to write a program and you need to represent data somehow. Should you use a primitive type? What about a class? There are several features that are handed to you with each.
Primitive Types
Advantages
Simplicity
In strongly typed languages, primitive types are ideal for data which doesn't necessarily need to be partitioned into several smaller components. If you are looking to store and represent a simple throw-away integer for looping, for example, there's little reason why one would want to construct a class for this throw-away integer purpose.
Primitive types are also often times coupled with native operations, handed to you by the language. For example, in Java, variables of type int are automatically given operations such as addition, subtraction, multiplication, and so on. These operations work as follows:
- Receive both inputs
- Cast if necessary (for example, from an int to a double)
- Perform calculation
- Return result
It is important to note that the primitive types themselves are left unchanged, and the result is returned from the operation, giving the programmer the ability to place the result elsewhere.
Efficiency
In efficiency-critical applications, primitive types and their operations are oftentimes mapped directly to hardware-supported equivalents, thus operations can be performed very quickly. This style of downgrading the logic to more so the hardware level has been replaced over the years for general applications, since improvements to hardware components have eradicated the once-imperative necessity to program efficiently. Another point of view concerning efficiency could be from development time: if the program one is writing doesn't require complex design, it would be quicker to use the language's built-in types instead of taking the time to design a class to do the same feature.
Disadvantages
Single-state storage
One large disadvantages to primitive types are that they are generally capable of only holding a single dimension state. This limitation requires the programmer to use other variables in conjunction if they desire to hold more than one field of data.
Refactoring
Since primitive types do not allow you to encapsulate your data, if you ever desire to change the behavior of your program, you are forced to manually check each use of the variable for enforcement.
For example, suppose you have a system designed in Java that maintains an integer value which represents the number of books you have in a library.
int numBooks;
...
numBooks = 0;
...
numBooks++;
...
numBooks--;
...
A few days later, you realize that you should probably refactor your system to maintain a log of when this variable updates. You immediately face a problem since, as it is, your code directly manipulates a single-state type integer. Without resorting to a more object-oriented solution, you would have to update each location in the code of where a change takes place in order to establish this bookkeeping (pun intended).
public static void integerValueChanged(){
// records that the value has been changed
...
}
public static void main(String[]args){
int numBooks;
...
numBooks = 0;
integerValueChanged();
...
numBooks++;
integerValueChanged();
...
numBooks--;
integerValueChanged();
...
}
To generalize this concept, it is oftentimes necessary to modify "what happens" when something is updated, and this cannot be easily accomplished by merely using primitive types.
Class Types
Classes to the rescue! Classes give programmers the ability to construct complex data types that are also capable of defining their own operations, all while keeping the details and specifics black-boxed outsize of where the class will be used in the code.
Advantages
Multi-dimensional Storage
Contrasting to primitive types, classes allow programmers to couple a varying number of fields. Grouping fields of data into a single class, then instantiating such an object and manipulating it is much more convenient than keeping track of several individual variables.
Refactoring
Oftentimes it is necessary to refactor a system to execute code when a change happens. In object-land, we are able to do this through the ability to control what happens in our methods.
Taking our example from above, we can give a quick example of how a class could be defined to handle the situation much more elegantly.
public class RecordedNumber{
// The integer value, kept concealed in the class
private int value;
public RecordedNumber(int value){
this.value = value;
}
public int getValue(){
return value;
}
public void setValue(int newValue){
// code to do any necessary recording.
...
this.value = newValue;
}
}
public class MyExample{
public static void main(String[]args){
RecordedNumber numBooks = new RecordedNumber(0);
...
numBooks.setValue(4); // the object handles all necessary bookkeeping
...
}
}
Code-reuse
Another nice feature to class-types encapsulate the concept surrounding code re-usability, especially in topics such as inheritance. Classes allow the programmer to enhance an already existing class-type to be more specific, which in turn can prevent excessive code duplication.
Application Structure
Designing an application in a object-oriented / class-specific style can reduce the challenges of designing and building a difficult system into merely making objects successfully interact. It is from this concept that languages such as Unified Modeling Language (UML) have been created, allowing software engineers to build around the notion of classes and their relationships to one another.
Disadvantages
Speed Considerations
In computational-intensive applications, objects built from classes tend to be less efficient than primitive data types built around procedural context. This is due in part because of the object's creation, since it isn't supported directly hardware level. Consideration is placed more so on good-design and coding-practices when implementing functionality around classes.
Complexity
Oftentimes one doesn't need the functionality provided by classes to handle the problem they are trying to solve. Consequently, such an unnecessary use oftentimes over-complicates the principle design and may add unnecessary burdens to maintain the code. This regard is more so geared towards small-programs where objects and classes may not be the best fit for their implementation. Examples of this situation vary, since it is highly opinionated, but are more so an example of bad design in an object-oriented sense: to quote Albert Einstein, "Everything should be made as simple as possible, but no simpler."
References
[1] http://download.oracle.com/javase/tutorial/java/nutsandbolts/datatypes.html
[2] Java:- Types, Values and Variables
http://java.sun.com/docs/books/jls/third_edition/html/typesValues.html
[3] Ruby Reflection ,http://www.khelll.com/blog/ruby/ruby-reflection/