CSC/ECE 517 Fall 2007/wiki1b 1 as: Difference between revisions
(33 intermediate revisions by 2 users not shown) | |||
Line 1: | Line 1: | ||
__TOC__ | __TOC__ | ||
= Background = | |||
Ruby does not implement true multiple inheritance, but provides Modules as a way to reuse chunks of codes in many classes. | Ruby does not implement true multiple inheritance, but provides Modules as a way to reuse chunks of codes in many classes. Modules, unlike classes in OO languages such as Java, cannot be instantiated or sub-classed. Modules are included in class definitions by using the ‘include’ method which will mix that module’s methods into the calling class. The module’s methods will then become instance methods. | ||
A class can include several modules within the class definition. However, a problem exists when a class includes multiple modules that contain a method of the same name. Since the class will have access to both of these methods, unexpected behavior may occur when a call is made to a method with an ambiguous name. | |||
A class can include several modules within the class definition. However, a problem exists when a class includes multiple modules that contain a method of the same name. Since the class will have access to both of these methods, unexpected behavior may occur when | |||
Let’s look at a few examples! | Let’s look at a few examples! | ||
= Examples = | |||
== 1. Method Name Conflict == | |||
In the following example, we have the class Zap. This class includes the module Foo and the module Test. Both modules contain a method named bar. | |||
module Foo | |||
def bar | |||
"hello" | |||
end | |||
end | |||
module Test | |||
def bar | |||
"goodbye" | |||
end | |||
end | |||
class Zap | |||
include Foo | |||
include Test | |||
end | |||
If a call is made to Zap's bar method, the caller is unsure whether the result will be "hello" or "goodbye". | |||
z = Zap.new | |||
puts z.bar | |||
The result of this call is: | |||
goodbye | |||
This is because Ruby will first search the last module included, and continue in a descending order until it finds a method with that name. Since in this case, Test was the last module included, its method was the one invoked. The method that is invoked may not be the method that the caller expected to run. Therefore, precaution should be taken to eliminate ambiguity. | |||
== 2. Using Namespaces to Avoid Conflict == | |||
Using namespaces within the modules will make the method names unique and help disambiguate any conflicts. The namespace is created simply by prefixing the method name with the module name and a period (i.e., Module.method). | |||
Let's modify the previous example to include namespaces. | |||
module Foo | |||
def Foo.bar #the method name is qualified | |||
"hello" | |||
end | |||
end | |||
module Test | |||
def Test.bar #the method name is qualified | |||
"goodbye" | |||
end | |||
end | |||
class Zap | |||
include Foo | |||
include Test | |||
Zap class defines a method named bar, and makes a call to both bar methods in Foo and Test. However, if the programmer knew for sure that any call to the bar method should invoke only one of the modules, this could be handled here by only calling the module of choice. | |||
def bar | |||
puts Foo.bar | |||
puts Test.bar | |||
end | |||
z = Zap.new | |||
puts z.bar | |||
This will produce: | |||
Hello | |||
Goodbye | |||
== 3. Using Aliases to Avoid Conflict == | |||
An alternative to using namespaces is to use alias to disambiguate method names in different modules. Again, looking at the first example, we have modified it to show the use of aliases. | |||
module Foo | |||
def bar | |||
"hello" | |||
end | |||
end | |||
module Test | |||
def bar | |||
"goodbye" | |||
end | |||
end | |||
In the Zap class, we define two aliases, one for Foo's bar method and another for Test's bar method. The alias syntax is ''alias :new_name :old_name''. So, to disambiguate, we first include Foo, and give an alias to its bar method. Then include Test and give an alias to its bar method. | |||
class Zap | |||
include Foo | |||
alias :Foo_bar :bar | |||
include Test | |||
alias :Test_bar :bar | |||
end | |||
The caller then can make a call to the new method names defined by the aliases to choose exactly which call they want to make. | |||
z = Zap.new | |||
puts z.Foo_bar | |||
puts z.Test_bar | |||
The result of this call is: | |||
hello | |||
goodbye | |||
Note: A call to z.bar would react the same way as shown in example one, with the result being a call to the last module included. | |||
= Conclusion = | |||
As illustrated in the examples, there are at least two ways to ensure that your class runs as expected even when using modules with method name conflicts. | |||
The two approaches are: | |||
#using namespaces | |||
#using aliases | |||
With namespaces, the class controls what module will be invoked. However, with aliases, the caller controls what will be invoked. These two approaches have their advantages and disadvantages. | |||
An advantage of using namespaces is that the logic that the programmer envisions is captured in the code. For example, the programmer may only be interested in Foo's bar method and not Test's bar method. This can be controlled by internally making the call to Foo.bar anytime the class's bar method is invoked. By the same token, this causes less flexibility, which is a disadvantage. | |||
When using aliases, the caller is more in control. The caller can leverage the fact that the class it is calling has access to the bar method of two different modules, thus providing more power and flexibility. However, the disadvantage of this is that the caller must know the internals of the class it is calling. It must know which aliased method calls what module, and also what that module's method does. | |||
In our opinion, using namespaces is the more efficient object-oriented (OO) design approach. Encapsulation is an important OO concept, and taxing the caller to research the internals of the code, while powerful, is inefficient. | |||
= References = | |||
#[http://www.recentrambles.com/pragmatic/view/69 Modules, Mixins, and Inheritance] | #[http://www.recentrambles.com/pragmatic/view/69 Modules, Mixins, and Inheritance] | ||
#[http://www.rubyist.net/~slagell/ruby/modules.html Ruby User's Guide] | #[http://www.rubyist.net/~slagell/ruby/modules.html Ruby User's Guide] | ||
#[http://www.ruby-doc.org/docs/ProgrammingRuby/html/tut_modules.html Programming Ruby] | |||
#[http://blade.nagaokaut.ac.jp/cgi-bin/scat.rb/ruby/ruby-talk/164209 Class and Mixin with same name method problem] |
Latest revision as of 03:28, 13 October 2007
Background
Ruby does not implement true multiple inheritance, but provides Modules as a way to reuse chunks of codes in many classes. Modules, unlike classes in OO languages such as Java, cannot be instantiated or sub-classed. Modules are included in class definitions by using the ‘include’ method which will mix that module’s methods into the calling class. The module’s methods will then become instance methods.
A class can include several modules within the class definition. However, a problem exists when a class includes multiple modules that contain a method of the same name. Since the class will have access to both of these methods, unexpected behavior may occur when a call is made to a method with an ambiguous name.
Let’s look at a few examples!
Examples
1. Method Name Conflict
In the following example, we have the class Zap. This class includes the module Foo and the module Test. Both modules contain a method named bar.
module Foo def bar "hello" end end module Test def bar "goodbye" end end class Zap include Foo include Test end
If a call is made to Zap's bar method, the caller is unsure whether the result will be "hello" or "goodbye".
z = Zap.new puts z.bar
The result of this call is:
goodbye
This is because Ruby will first search the last module included, and continue in a descending order until it finds a method with that name. Since in this case, Test was the last module included, its method was the one invoked. The method that is invoked may not be the method that the caller expected to run. Therefore, precaution should be taken to eliminate ambiguity.
2. Using Namespaces to Avoid Conflict
Using namespaces within the modules will make the method names unique and help disambiguate any conflicts. The namespace is created simply by prefixing the method name with the module name and a period (i.e., Module.method).
Let's modify the previous example to include namespaces.
module Foo def Foo.bar #the method name is qualified "hello" end end module Test def Test.bar #the method name is qualified "goodbye" end end class Zap include Foo include Test
Zap class defines a method named bar, and makes a call to both bar methods in Foo and Test. However, if the programmer knew for sure that any call to the bar method should invoke only one of the modules, this could be handled here by only calling the module of choice.
def bar puts Foo.bar puts Test.bar end z = Zap.new puts z.bar
This will produce:
Hello Goodbye
3. Using Aliases to Avoid Conflict
An alternative to using namespaces is to use alias to disambiguate method names in different modules. Again, looking at the first example, we have modified it to show the use of aliases.
module Foo def bar "hello" end end module Test def bar "goodbye" end end
In the Zap class, we define two aliases, one for Foo's bar method and another for Test's bar method. The alias syntax is alias :new_name :old_name. So, to disambiguate, we first include Foo, and give an alias to its bar method. Then include Test and give an alias to its bar method.
class Zap include Foo alias :Foo_bar :bar include Test alias :Test_bar :bar end
The caller then can make a call to the new method names defined by the aliases to choose exactly which call they want to make.
z = Zap.new puts z.Foo_bar puts z.Test_bar
The result of this call is:
hello goodbye
Note: A call to z.bar would react the same way as shown in example one, with the result being a call to the last module included.
Conclusion
As illustrated in the examples, there are at least two ways to ensure that your class runs as expected even when using modules with method name conflicts.
The two approaches are:
- using namespaces
- using aliases
With namespaces, the class controls what module will be invoked. However, with aliases, the caller controls what will be invoked. These two approaches have their advantages and disadvantages.
An advantage of using namespaces is that the logic that the programmer envisions is captured in the code. For example, the programmer may only be interested in Foo's bar method and not Test's bar method. This can be controlled by internally making the call to Foo.bar anytime the class's bar method is invoked. By the same token, this causes less flexibility, which is a disadvantage.
When using aliases, the caller is more in control. The caller can leverage the fact that the class it is calling has access to the bar method of two different modules, thus providing more power and flexibility. However, the disadvantage of this is that the caller must know the internals of the class it is calling. It must know which aliased method calls what module, and also what that module's method does.
In our opinion, using namespaces is the more efficient object-oriented (OO) design approach. Encapsulation is an important OO concept, and taxing the caller to research the internals of the code, while powerful, is inefficient.