CSC/ECE 517 Fall 2011/ch2 2c ds: Difference between revisions
(94 intermediate revisions by 2 users not shown) | |||
Line 1: | Line 1: | ||
=Mixins vs. Interfaces= | |||
=Introduction= | =Introduction= | ||
==Interfaces== | |||
In object oriented programming languages, Mixins and Interfaces provide neat constructs to implement certain functionality and benefit from code re-usability. Understanding these constructs will benefit any programmer in designing any software with maximum polymorphic behavior and code re-usability. | |||
With the advent of object oriented languages, the designers of the language had to come up with the decision of whether or not to include the concept of multiple inheritance. Languages like C++ and Perl allow multiple inheritance whereas the designers of languages like C# and Java decided not to because of the problems associated with multiple inheritance<ref>[http://www.artima.com/intv/gosling13.html Inspiration for Interface]</ref>. | |||
While [http://en.wikipedia.org/wiki/Java_%28programming_language%29 Java] like languages implemented interfaces to allow for [http://en.wikipedia.org/wiki/Polymorphism_in_object-oriented_programming polymorphism],languages like [http://en.wikipedia.org/wiki/Ruby_%28programming_language%29 Ruby] opted not to implement multiple inheritance but to allow the code from one module be added into another class. | |||
Though both interfaces and Mixins simulate multiple inheritance and avoid the common pathologies associated with it , they have their own set of compromises. The below article tries to provide clarity on how this is achieved in each and also provides other distinctive features of Mixins and interfaces. | |||
===Interfaces=== | |||
In an object-oriented programming languages such as Java, C#, an interface<ref>[http://download.oracle.com/javase/tutorial/ Interfaces] </ref> is a reference type, similar to a class that can contain only constants, method signatures, and nested types. There are no method bodies. Interfaces cannot be instantiated and they can only be implemented by classes or extended by other interfaces. All methods are public by default and any fields declared in an interface are by default static and final. | |||
Example: | |||
public interface ParkingLot { | |||
boolean add(Car car, int slot); | |||
boolean remove(Car car); | |||
boolean findCar(Int number); | |||
int freeSlotsCount(); | |||
int occupiedSlots(); | |||
int parkingType(); | |||
int calculateParkingFee(int hours, int charge, int duration); | |||
int findParkingSlot(); | |||
} | |||
public class Mall implements ParkingLot { | |||
boolean add(Car car, int slot) { //... Code to add a car into the parking lot... } | |||
boolean remove(Car car){ // do something } | |||
boolean findCar(Int number){ // do something } | |||
int freeSlotsCount(){ // do something } | |||
int occupiedSlots(){ // do something } | |||
int parkingType(){ // do something } | |||
int calculateParkingFee(int hours, int charge, int duration){ // do something } | |||
int findParkingSlot(){ // do something } | |||
} | |||
Interfaces play another important role in the object-oriented programming language. Interfaces are not part of the class hierarchy, although they work in combination with classes. Interfaces provide an alternative for languages like Java that does not allow multiple inheritance . | |||
In Java, a class can inherit from only one class but it can implement more than one interface. Therefore, objects can have multiple types: the type of their own class and the types of all the interfaces that they implement. This means that if a variable is declared to be the type of an interface, its value can reference any object that is instantiated from any class that implements the interface. | |||
==Mixins== | ==Mixins== | ||
Modules provide a structure to collect classes, methods, and constants into a single, separately defined unit. They provide the simplest and an elegant way to adhere to the [http://en.wikipedia.org/wiki/Don't_repeat_yourself Don't repeat yourself] principle. This is useful so as to avoid clashes with existing classes, methods, and constants. | |||
Modules provide a structure to collect | |||
Modules are defined in Ruby using the module keyword. | Modules are defined in Ruby using the ''module'' keyword. | ||
< | A Mixin is a class that is mixed with a module or a set of modules i.e. the implementation of the modules and the class are intertwined and combined together <ref>[http://www.ruby-doc.org/docs/ProgrammingRuby/html/tut_modules.html Mixins] </ref>. | ||
module | |||
def | This gives us a neat and controlled way of adding new functionality to classes. Modules are similar to classes in that they hold a collection of methods, variables constants and other modules and class definitions. However, the real usage of a Mixin is exploited when the code in the Mixin starts to interact with code in the class that uses it. | ||
Below is an example for modules and Mixins: | |||
The module ParkingSlot consists of the methods park and unpark | |||
<span style="color:#4682B4"> | |||
module ParkingSlot | |||
def park | |||
#code to park the car | |||
end | |||
def unpark | |||
#code to unpark the car | |||
end | |||
end | |||
</span> | |||
The module ParkingMeter consists of the methods calculate and printreceipt | |||
<span style="color:#F4A460"> | |||
module ParkingMeter | |||
def calculate | |||
#code to calculate the parking fee | |||
end | |||
def printreceipt | |||
#code to print the receipt | |||
end | |||
end | end | ||
def | </span> | ||
When a class ''includes'' a module via include Module Name, all the methods on that module become instance methods on the class. | |||
<span style="color:#6B8E23"> | |||
class Parking | |||
include ParkingSlot | |||
include ParkingMeter | |||
def printcardetails | |||
#code to print the details and type of car | |||
end | |||
end | end | ||
</span> | |||
The modules ParkingSlot and ParkingMeter are “included” in the Parking class. All the variables and the instance methods of the modules ParkingSlot and ParkingMeter are now said to be “mixed in” into the class. It is now possible for class instances to use these methods defined in the modules as and when required. | |||
p=Parking.new | |||
p.park # -> Method park from module ParkingSlot | |||
p.unpark # -> Method unpark from module ParkingSlot | |||
p.calculate # -> Method calculate from module ParkingMeter | |||
p.printreceipt # -> Method printreceipt from module ParkingMeter | |||
p.printcardetails # -> Calls printCarDetails from class | |||
The class Parking inherits from both the modules and the module methods are now available in Parking. Hence, it is now possible to use the methods with an instance of the Parking class ''p''. | |||
Hence, Mixins can be thought of taking different methods and variables defined in different modules making them available as instance methods in the class as well, thereby extending the class’ functionality. Effectively mixed in modules behave as [http://en.wikipedia.org/wiki/Inheritance_(object-oriented_programming)#Subclasses_and_superclasses superclass]. | |||
[[Image:ParkingLot.PNG | center]] | |||
==Supported Languages== | ==Supported Languages== | ||
The following table shows support for Mixins and Interfaces by most commonly used languages. | |||
{| class="wikitable" | |||
|- | |||
! Languages | |||
! Mixins | |||
! Interfaces | |||
|- | |||
| Ruby | |||
| Yes | |||
| No | |||
|- | |||
| Java | |||
| No | |||
| Yes | |||
|- | |||
| Python | |||
| Yes | |||
| No | |||
|- | |||
| Smalltalk | |||
| Yes | |||
| No | |||
|- | |||
| Perl | |||
| Yes | |||
| No | |||
|- | |||
| C# | |||
| No | |||
| Yes | |||
|} | |||
=Multiple Inheritance= | =Multiple Inheritance= | ||
[http://en.wikipedia.org/wiki/Multiple_inheritance Multiple Inheritance] refers to a feature in some [http://en.wikipedia.org/wiki/Object-oriented_programming object oriented programming] languages in which a class can inherit behaviors from more than one superclass. This contrasts with single inheritance in which a class can inherit behavior from at most one superclass. | |||
Though Multiple Inheritance provides its own advantages of improved modularity and ease of reuse of code in certain applications, it has its own set of disadvantages which sometimes outweigh the possible advantages. | |||
==Diamond Problem== | ==Diamond Problem== | ||
This section describes the well know “Diamond Problem”<ref>[http://www.artima.com/designtechniques/interfaces2.html Diamond Problem] </ref> associated with multiple Inheritance and the succeeding sections describe how Mixins and interfaces can be used to overcome this problem. | |||
The diamond problem is the ambiguity that can occur when a class inherits from two different classes that both descend from a common superclass. For example, consider a scenario where one decides to combine the Frog and Dinosaur species which both are inherited from the Animal class. The talk() method in the Animal class is abstract and both Frog and Dinosaur needs to implement this method. | |||
Lets say both Frog and Dinosaur implement the talk method like this: | |||
public class Frog extends Animal { | |||
void talk() { | |||
System.out.println(“I am Frog, I can croak “); | |||
} | |||
} | |||
and, | |||
public class Dinosaur extends Animal { | |||
void talk() { | |||
System.out.println(“I am Dinosaur, I can roar “); | |||
} | |||
} | |||
[[Image:Diamond_problem.PNG | center]] | |||
When the Frogsaur is created, it inherits from both Frog and Dinosaur. | |||
public class Frogsaur extends Frog, Dinosaur { | |||
// Note below syntax is used just for demonstration. However java might throw compile time error. | |||
} | |||
The real problem occurs when someone tries to invoke talk() method on a Frogsaur object from the Animal reference. | |||
Animal species = new Frogsaur(); | |||
species.talk(); // which method to invoke ??? | |||
Due to the ambiguity caused by the diamond problem, it isn’t clear whether the runtime system should invoke Frog’s talk() method or Dinosaur talk() method. | |||
==Approaches== | ==Approaches== | ||
Different programming languages have addressed | Different programming languages have addressed the diamond problem in different ways. | ||
In Java, interfaces solve all these ambiguities caused by the diamond problem. Through interfaces, Java allows multiple inheritance of interface but not of implementation. Implementation, which includes instance variables and method implementations, is always singly inherited. As a result, confusion will never arise in Java over which inherited instance variable or method implementation to use. | In Java, interfaces solve all these ambiguities caused by the diamond problem. Through interfaces, Java allows multiple inheritance of interface but not of implementation. Implementation, which includes instance variables and method implementations, is always singly inherited. As a result, confusion will never arise in Java over which inherited instance variable or method implementation to use. | ||
Ruby does not support multiple inheritance. Mixin provide a way which eliminates the need for multiple inheritance. Ruby has modules which are just like abstract classes in Java. Modules can have different methods implemented in them. They cannot be instantiated like abstract classes. They cannot inherit from other modules or classes. Ruby classes can inherit from only one superclass but can have unlimited number of modules in them to exploit the usage of predefined implementations in these modules. This provides functionality similar to multiple inheritance avoiding any ambiguities. | Ruby does not support multiple inheritance. Mixin provide a way which eliminates the need for multiple inheritance. Ruby has modules which are just like abstract classes<ref>[http://download.oracle.com/javase/tutorial/java/IandI/abstract.html Abstract Classes]</ref> in Java. Modules can have different methods implemented in them. They cannot be instantiated like abstract classes. They cannot inherit from other modules or classes. Ruby classes can inherit from only one superclass but can have unlimited number of modules in them to exploit the usage of predefined implementations in these modules. This provides functionality similar to multiple inheritance avoiding any ambiguities. | ||
The below code demonstrates two modules Frog and Dinosaur, each of which contain the talk method defined in them. The Frogsaur class ''includes'' these two methods and defines its own talk method. This example was chosen to exhibit on how Ruby resolves method calls at run time. | The below code in Ruby demonstrates two modules Frog and Dinosaur, each of which contain the talk method defined in them. The Frogsaur class ''includes'' these two methods and defines its own talk method. This example was chosen to exhibit on how Ruby resolves method calls at run time. | ||
module Frog | |||
module Frog | def talk | ||
puts "I can croak" | |||
end | |||
end | |||
end | |||
module Dinosaur | module Dinosaur | ||
def talk | |||
puts "I can roar" | |||
end | |||
end | end | ||
class Frogsaur | class Frogsaur | ||
include Frog | include Frog | ||
include Dinosaur | include Dinosaur | ||
def talk | |||
puts "I can roar like a dinosaur and croak like a frog" | |||
end | |||
end | end | ||
fs = Frogsaur.new | fs = Frogsaur.new | ||
fs.talk | fs.talk # -> Which talk method to call ?? | ||
When the method talk is called on the Frogsaur object, Ruby makes sure that the latest method defined in the hierarchy is chosen. Here in this example, the talk method in the Frogsaur class is defined the latest and hence “I can roar like a dinosaur and croak like a frog” is printed. If there was no method defined in the class, method from the Dinosaur is printed since it is next in the hierarchy specified by the include statements. | |||
=Comparison between Mixins and Interfaces= | =Comparison between Mixins and Interfaces= | ||
== | This is a general comparision: | ||
{| class="wikitable" | |||
|- | |||
! Mixins | |||
! Interfaces | |||
|- | |||
| In Ruby, modules have the implementation of the methods. So all the classes which include the modules gets the same Implementation because classes create a reference to these modules. | |||
|In Java, all classes which implement the interfaces should provide implementation for each of the methods declared in the interface. This might duplicate the code if the two or more classes have similar functionality. | |||
|- | |||
| The size of the code is relatively smaller because the classes automatically get access to methods defined in the modules. Modules server as a central repository | |||
| The size is relatively larger because a class implementing more than one interfaces has to provide implementation. | |||
|- | |||
| Having more modules in the classes can make code less readable. Ideally mixins are suitable for small teams having few modules. | |||
| The code is more readable here as the implementation is provided to each method and can be found in place | |||
|- | |||
| In Ruby, a method inside a module can have Module name as qualifier. Hence it’s possible for a class to have inherit two or more modules which have same names. | |||
| In Java, the class itself has to provide the implementation of the methods. Inheriting methods of same names from different interfaces will signal an error message. | |||
|- | |||
| Modules cannot be inherited and cannot form is-a hierarchy | |||
| Interfaces can extend another interface and hence can form is-a hierarchy | |||
|} | |||
==Drawbacks of Mixins and Interfaces== | |||
The drawbacks of the technique of Mixins are very much debated. Though Mixins provide us with an easy way to write flexible and decoupled code and also help us solve the diamond problem, they pose their own problems. In large programs there could be large number of modules and each module could have loads of methods each performing a certain task.To trace the origin of the methods and to keep in mind the hierarchy is practically impossible. Another issue associated with Mixins pose is silent method overriding. Silent method overriding occurs when different modules are included in a class and each module have a method with the same definition. In such a case, the method which gets executed depends upon the way it is included in the class and this is done without any sort of message to the user (silently). In large scale applications this could certainly be an issue considering the number of modules that would be mixed in and it would be difficult to keep track of the hierarchy in which the modules were included. | |||
Although Java provides polymorphic behavior with the use of interfaces, they sometimes tend to be very slow. The implementation of interfaces are also limited to public methods and constants with no implementation. | |||
=Conclusion= | =Conclusion= | ||
Although mixins have certain advantages over interfaces, they possess their own share of disadvantages. Mixins are generally used in small frameworks and interfaces , more than solving the problem of multiple inheritance provide polymorphism feature which makes object-oriented code more flexible and easy to modify and maintain. | |||
=References= | =References= | ||
<references/> | |||
= | =See Also= | ||
1. http://ruby.about.com/od/beginningruby/a/mixin.html<br> | |||
2. http://juixe.com/techknow/index.php/2006/06/15/mixins-in-ruby/ <br> | |||
3. https://www.re-motion.org/blogs/team/2008/02/20/introducing-mixins-finally/ <br> | |||
4. https://www.cs.washington.edu/education/courses/cse413/11sp/lectures/ruby_interfaces-etc.pdf <br> | |||
5. http://pg-server.csc.ncsu.edu/mediawiki/index.php?title=CSC/ECE_517_Fall_2010/ch3_3b_sv&printable=yes <br> | |||
6. http://csis.pace.edu/~bergin/patterns/multipleinheritance.html |
Latest revision as of 23:48, 30 September 2011
Mixins vs. Interfaces
Introduction
In object oriented programming languages, Mixins and Interfaces provide neat constructs to implement certain functionality and benefit from code re-usability. Understanding these constructs will benefit any programmer in designing any software with maximum polymorphic behavior and code re-usability.
With the advent of object oriented languages, the designers of the language had to come up with the decision of whether or not to include the concept of multiple inheritance. Languages like C++ and Perl allow multiple inheritance whereas the designers of languages like C# and Java decided not to because of the problems associated with multiple inheritance<ref>Inspiration for Interface</ref>.
While Java like languages implemented interfaces to allow for polymorphism,languages like Ruby opted not to implement multiple inheritance but to allow the code from one module be added into another class.
Though both interfaces and Mixins simulate multiple inheritance and avoid the common pathologies associated with it , they have their own set of compromises. The below article tries to provide clarity on how this is achieved in each and also provides other distinctive features of Mixins and interfaces.
Interfaces
In an object-oriented programming languages such as Java, C#, an interface<ref>Interfaces </ref> is a reference type, similar to a class that can contain only constants, method signatures, and nested types. There are no method bodies. Interfaces cannot be instantiated and they can only be implemented by classes or extended by other interfaces. All methods are public by default and any fields declared in an interface are by default static and final.
Example:
public interface ParkingLot { boolean add(Car car, int slot); boolean remove(Car car); boolean findCar(Int number); int freeSlotsCount(); int occupiedSlots(); int parkingType(); int calculateParkingFee(int hours, int charge, int duration); int findParkingSlot(); }
public class Mall implements ParkingLot { boolean add(Car car, int slot) { //... Code to add a car into the parking lot... } boolean remove(Car car){ // do something } boolean findCar(Int number){ // do something } int freeSlotsCount(){ // do something } int occupiedSlots(){ // do something } int parkingType(){ // do something } int calculateParkingFee(int hours, int charge, int duration){ // do something } int findParkingSlot(){ // do something } }
Interfaces play another important role in the object-oriented programming language. Interfaces are not part of the class hierarchy, although they work in combination with classes. Interfaces provide an alternative for languages like Java that does not allow multiple inheritance .
In Java, a class can inherit from only one class but it can implement more than one interface. Therefore, objects can have multiple types: the type of their own class and the types of all the interfaces that they implement. This means that if a variable is declared to be the type of an interface, its value can reference any object that is instantiated from any class that implements the interface.
Mixins
Modules provide a structure to collect classes, methods, and constants into a single, separately defined unit. They provide the simplest and an elegant way to adhere to the Don't repeat yourself principle. This is useful so as to avoid clashes with existing classes, methods, and constants.
Modules are defined in Ruby using the module keyword.
A Mixin is a class that is mixed with a module or a set of modules i.e. the implementation of the modules and the class are intertwined and combined together <ref>Mixins </ref>.
This gives us a neat and controlled way of adding new functionality to classes. Modules are similar to classes in that they hold a collection of methods, variables constants and other modules and class definitions. However, the real usage of a Mixin is exploited when the code in the Mixin starts to interact with code in the class that uses it.
Below is an example for modules and Mixins:
The module ParkingSlot consists of the methods park and unpark
module ParkingSlot
def park
#code to park the car
end
def unpark
#code to unpark the car
end
end
The module ParkingMeter consists of the methods calculate and printreceipt
module ParkingMeter
def calculate
#code to calculate the parking fee
end
def printreceipt
#code to print the receipt
end
end
When a class includes a module via include Module Name, all the methods on that module become instance methods on the class.
class Parking
include ParkingSlot
include ParkingMeter
def printcardetails
#code to print the details and type of car
end
end
The modules ParkingSlot and ParkingMeter are “included” in the Parking class. All the variables and the instance methods of the modules ParkingSlot and ParkingMeter are now said to be “mixed in” into the class. It is now possible for class instances to use these methods defined in the modules as and when required.
p=Parking.new p.park # -> Method park from module ParkingSlot p.unpark # -> Method unpark from module ParkingSlot p.calculate # -> Method calculate from module ParkingMeter p.printreceipt # -> Method printreceipt from module ParkingMeter p.printcardetails # -> Calls printCarDetails from class
The class Parking inherits from both the modules and the module methods are now available in Parking. Hence, it is now possible to use the methods with an instance of the Parking class p.
Hence, Mixins can be thought of taking different methods and variables defined in different modules making them available as instance methods in the class as well, thereby extending the class’ functionality. Effectively mixed in modules behave as superclass.
Supported Languages
The following table shows support for Mixins and Interfaces by most commonly used languages.
Languages | Mixins | Interfaces |
---|---|---|
Ruby | Yes | No |
Java | No | Yes |
Python | Yes | No |
Smalltalk | Yes | No |
Perl | Yes | No |
C# | No | Yes |
Multiple Inheritance
Multiple Inheritance refers to a feature in some object oriented programming languages in which a class can inherit behaviors from more than one superclass. This contrasts with single inheritance in which a class can inherit behavior from at most one superclass. Though Multiple Inheritance provides its own advantages of improved modularity and ease of reuse of code in certain applications, it has its own set of disadvantages which sometimes outweigh the possible advantages.
Diamond Problem
This section describes the well know “Diamond Problem”<ref>Diamond Problem </ref> associated with multiple Inheritance and the succeeding sections describe how Mixins and interfaces can be used to overcome this problem. The diamond problem is the ambiguity that can occur when a class inherits from two different classes that both descend from a common superclass. For example, consider a scenario where one decides to combine the Frog and Dinosaur species which both are inherited from the Animal class. The talk() method in the Animal class is abstract and both Frog and Dinosaur needs to implement this method.
Lets say both Frog and Dinosaur implement the talk method like this:
public class Frog extends Animal { void talk() { System.out.println(“I am Frog, I can croak “); } }
and,
public class Dinosaur extends Animal { void talk() { System.out.println(“I am Dinosaur, I can roar “); } }
When the Frogsaur is created, it inherits from both Frog and Dinosaur.
public class Frogsaur extends Frog, Dinosaur { // Note below syntax is used just for demonstration. However java might throw compile time error. }
The real problem occurs when someone tries to invoke talk() method on a Frogsaur object from the Animal reference.
Animal species = new Frogsaur(); species.talk(); // which method to invoke ???
Due to the ambiguity caused by the diamond problem, it isn’t clear whether the runtime system should invoke Frog’s talk() method or Dinosaur talk() method.
Approaches
Different programming languages have addressed the diamond problem in different ways.
In Java, interfaces solve all these ambiguities caused by the diamond problem. Through interfaces, Java allows multiple inheritance of interface but not of implementation. Implementation, which includes instance variables and method implementations, is always singly inherited. As a result, confusion will never arise in Java over which inherited instance variable or method implementation to use.
Ruby does not support multiple inheritance. Mixin provide a way which eliminates the need for multiple inheritance. Ruby has modules which are just like abstract classes<ref>Abstract Classes</ref> in Java. Modules can have different methods implemented in them. They cannot be instantiated like abstract classes. They cannot inherit from other modules or classes. Ruby classes can inherit from only one superclass but can have unlimited number of modules in them to exploit the usage of predefined implementations in these modules. This provides functionality similar to multiple inheritance avoiding any ambiguities.
The below code in Ruby demonstrates two modules Frog and Dinosaur, each of which contain the talk method defined in them. The Frogsaur class includes these two methods and defines its own talk method. This example was chosen to exhibit on how Ruby resolves method calls at run time.
module Frog def talk puts "I can croak" end end
module Dinosaur def talk puts "I can roar" end end
class Frogsaur include Frog include Dinosaur def talk puts "I can roar like a dinosaur and croak like a frog" end end
fs = Frogsaur.new fs.talk # -> Which talk method to call ??
When the method talk is called on the Frogsaur object, Ruby makes sure that the latest method defined in the hierarchy is chosen. Here in this example, the talk method in the Frogsaur class is defined the latest and hence “I can roar like a dinosaur and croak like a frog” is printed. If there was no method defined in the class, method from the Dinosaur is printed since it is next in the hierarchy specified by the include statements.
Comparison between Mixins and Interfaces
This is a general comparision:
Mixins | Interfaces |
---|---|
In Ruby, modules have the implementation of the methods. So all the classes which include the modules gets the same Implementation because classes create a reference to these modules. | In Java, all classes which implement the interfaces should provide implementation for each of the methods declared in the interface. This might duplicate the code if the two or more classes have similar functionality. |
The size of the code is relatively smaller because the classes automatically get access to methods defined in the modules. Modules server as a central repository | The size is relatively larger because a class implementing more than one interfaces has to provide implementation. |
Having more modules in the classes can make code less readable. Ideally mixins are suitable for small teams having few modules. | The code is more readable here as the implementation is provided to each method and can be found in place |
In Ruby, a method inside a module can have Module name as qualifier. Hence it’s possible for a class to have inherit two or more modules which have same names. | In Java, the class itself has to provide the implementation of the methods. Inheriting methods of same names from different interfaces will signal an error message. |
Modules cannot be inherited and cannot form is-a hierarchy | Interfaces can extend another interface and hence can form is-a hierarchy |
Drawbacks of Mixins and Interfaces
The drawbacks of the technique of Mixins are very much debated. Though Mixins provide us with an easy way to write flexible and decoupled code and also help us solve the diamond problem, they pose their own problems. In large programs there could be large number of modules and each module could have loads of methods each performing a certain task.To trace the origin of the methods and to keep in mind the hierarchy is practically impossible. Another issue associated with Mixins pose is silent method overriding. Silent method overriding occurs when different modules are included in a class and each module have a method with the same definition. In such a case, the method which gets executed depends upon the way it is included in the class and this is done without any sort of message to the user (silently). In large scale applications this could certainly be an issue considering the number of modules that would be mixed in and it would be difficult to keep track of the hierarchy in which the modules were included.
Although Java provides polymorphic behavior with the use of interfaces, they sometimes tend to be very slow. The implementation of interfaces are also limited to public methods and constants with no implementation.
Conclusion
Although mixins have certain advantages over interfaces, they possess their own share of disadvantages. Mixins are generally used in small frameworks and interfaces , more than solving the problem of multiple inheritance provide polymorphism feature which makes object-oriented code more flexible and easy to modify and maintain.
References
<references/>
See Also
1. http://ruby.about.com/od/beginningruby/a/mixin.html
2. http://juixe.com/techknow/index.php/2006/06/15/mixins-in-ruby/
3. https://www.re-motion.org/blogs/team/2008/02/20/introducing-mixins-finally/
4. https://www.cs.washington.edu/education/courses/cse413/11sp/lectures/ruby_interfaces-etc.pdf
5. http://pg-server.csc.ncsu.edu/mediawiki/index.php?title=CSC/ECE_517_Fall_2010/ch3_3b_sv&printable=yes
6. http://csis.pace.edu/~bergin/patterns/multipleinheritance.html