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= Duck Typing = | = Duck Typing = | ||
[[Image:Duck.png|frame]] | |||
If it walks like a duck and quacks like a duck, I would call it a duck.[1] | The term “duck typing” comes from the common American analogy of the duck test, which can be summed up with the following phrase: | ||
''If it walks like a duck and quacks like a duck, I would call it a duck.'' [1] | |||
That is to say that, if object A displays the behavior of another object B, object A can be treated as if it was the same as object B. In computer science, this concept can be applied to the virtual objects used in object-oriented languages like Smalltalk, Java, and C#. In this case, "duck typing" is also known as unbounded polymorphism. | |||
rubylearning.com describes duck typing in this way: | |||
''In Ruby, we rely less on the type (or class) of an object and more on its capabilities. Hence, Duck Typing means an object type is defined by what it can do, not by what it is. Duck Typing refers to the tendency of Ruby to be less concerned with the class of an object and more concerned with what methods can be called on it and what operations can be performed on it. In Ruby, we would use respond_to? or might simply pass an object to a method and know that an exception will be raised if it is used inappropriately. [4]'' | |||
In dynamically typed languages, such as Ruby, the parameters of a given method do not need to have a pre-specified type. At run time, if the argument passed to the parameter has the necessary methods, the code will run. [2] This is in contrast to statically typed languages, such as Java. In these languages, if a parameter is passed to a method, that method my only use methods defined in that parameter or it's superclasses. If this rule is violated, an error is generated at compile time. | |||
==Java Example== | ==Java Example== | ||
Let us examine the following code snippet: | |||
<code><pre> | <code><pre> | ||
class ImaginaryNumber extends Object { | |||
public int realPart; | public int realPart; | ||
public int imaginaryPart; | public int imaginaryPart; | ||
public ImaginaryNumber(int realPart, int imaginaryPart) { | |||
this.realPart = realPart; | |||
this.imaginaryPart = imaginaryPart; | |||
} | |||
public int getRealPart() { | public int getRealPart() { | ||
return realPart; | return realPart; | ||
} | } | ||
public int getImaginaryPart() { | public int getImaginaryPart() { | ||
return imaginaryPart; | return imaginaryPart; | ||
} | } | ||
} | } | ||
</pre></code> | </pre></code> | ||
Line 25: | Line 41: | ||
class MyMath { | class MyMath { | ||
public boolean | public static boolean equals(Object a, Object b) { | ||
// this will create a compile-time error in Java | |||
return (a.getRealPart() == b.getRealPart()); | |||
} | } | ||
} | } | ||
</pre></code> | </pre></code> | ||
In a non-duck typed language, such as Java, the Equals() method above has two parameters a and b. It is required that these parameters have a specific type, in this case “Object”. A compile-time error will be generated even if two ImaginaryNumber objects are passed to the method. This occurs in spite of the fact that ImaginaryNumber has definitions for all of the methods called in Equals() and that ImaginaryNumber is a subclass of Object. In order to correct this error, Equals() would have to be changed to take two ImaginaryNumber objects as parameters. | In a non-duck typed language, such as Java, the Equals() method above has two parameters a and b. It is required that these parameters have a specific type, in this case “Object”. A compile-time error will be generated even if two ImaginaryNumber objects are passed to the method. This occurs in spite of the fact that ImaginaryNumber has definitions for all of the methods called in Equals() and that ImaginaryNumber is a subclass of Object. In order to correct this error, Equals() would have to be changed to take two ImaginaryNumber objects as parameters. The corrected, functional version of the MyMath class is shown below. | ||
<code><pre> | |||
class MyMath { | |||
public static boolean equals(ImaginaryNumber a, ImaginaryNumber b) { | |||
return (a.getRealPart() == b.getRealPart()); | |||
} | |||
} | |||
</pre></code> | |||
==Ruby Example== | ==Ruby Example== | ||
Line 54: | Line 77: | ||
</pre></code> | </pre></code> | ||
== | ==Duck Typing vs. Interfaces and Inheritance== | ||
The most obvious advantage of duck typing over interfaces and inheritance is conciseness of code. In a statically typed language that makes use of interfaces and inheritance, more code is often required to ensure type safety. Another major advantage is that duck typing is less restrictive since it allows the the end user to choose what type of object will be passed as parameters to any method at run time. As long as that argument has the required behavior, the method will function properly. | |||
The disadvantage of duck typing is the potential for errors to occur at run time when the program is out of the control of the programmer. In a statically typed language, type safety errors can be caught and corrected at compile time, before product release. As a result, statically typed languages are more suited for safety critical software, such as control systems. [3] | |||
==See Also== | |||
For another code example using Ruby, go to http://rubylearning.com/satishtalim/duck_typing.html | |||
A Sun blog entry about duck typing: http://blogs.sun.com/bblfish/entry/duck_typing_done_right | |||
Dave Thomas's entry about duck typing: http://blade.nagaokaut.ac.jp/cgi-bin/scat.rb/ruby/ruby-talk/78502 | |||
For a more detailed example using Boo, a language that uses both static typing and duck typing, see http://boo.codehaus.org/Duck+Typing. For a real-world example of duck-typing in C#, visit http://haacked.com/archive/2007/08/19/why-duck-typing-matters-to-c-developers.aspx | |||
Dr. Ed Gehringer's notes on duck typing can be found at http://courses.ncsu.edu/csc517/common/lectures/notes/lec6.doc. | |||
For a more detailed example using Boo, a language that uses both static typing and duck typing, see http://boo.codehaus.org/Duck+Typing. | |||
For a real-world example of duck-typing in C#, visit http://haacked.com/archive/2007/08/19/why-duck-typing-matters-to-c-developers.aspx. | |||
==References== | ==References== | ||
[1] http://en.wikipedia.org/wiki/Duck_test | [1] http://en.wikipedia.org/wiki/Duck_test | ||
[2] http://en.wikipedia.org/wiki/Duck_typing | |||
[3] http://courses.ncsu.edu/csc517/common/lectures/notes/lec6.doc | |||
[4] http://rubylearning.com/satishtalim/duck_typing.html |
Latest revision as of 18:52, 19 September 2007
Duck Typing
The term “duck typing” comes from the common American analogy of the duck test, which can be summed up with the following phrase:
If it walks like a duck and quacks like a duck, I would call it a duck. [1]
That is to say that, if object A displays the behavior of another object B, object A can be treated as if it was the same as object B. In computer science, this concept can be applied to the virtual objects used in object-oriented languages like Smalltalk, Java, and C#. In this case, "duck typing" is also known as unbounded polymorphism.
rubylearning.com describes duck typing in this way:
In Ruby, we rely less on the type (or class) of an object and more on its capabilities. Hence, Duck Typing means an object type is defined by what it can do, not by what it is. Duck Typing refers to the tendency of Ruby to be less concerned with the class of an object and more concerned with what methods can be called on it and what operations can be performed on it. In Ruby, we would use respond_to? or might simply pass an object to a method and know that an exception will be raised if it is used inappropriately. [4]
In dynamically typed languages, such as Ruby, the parameters of a given method do not need to have a pre-specified type. At run time, if the argument passed to the parameter has the necessary methods, the code will run. [2] This is in contrast to statically typed languages, such as Java. In these languages, if a parameter is passed to a method, that method my only use methods defined in that parameter or it's superclasses. If this rule is violated, an error is generated at compile time.
Java Example
Let us examine the following code snippet:
class ImaginaryNumber extends Object {
public int realPart;
public int imaginaryPart;
public ImaginaryNumber(int realPart, int imaginaryPart) {
this.realPart = realPart;
this.imaginaryPart = imaginaryPart;
}
public int getRealPart() {
return realPart;
}
public int getImaginaryPart() {
return imaginaryPart;
}
}
class MyMath {
public static boolean equals(Object a, Object b) {
// this will create a compile-time error in Java
return (a.getRealPart() == b.getRealPart());
}
}
In a non-duck typed language, such as Java, the Equals() method above has two parameters a and b. It is required that these parameters have a specific type, in this case “Object”. A compile-time error will be generated even if two ImaginaryNumber objects are passed to the method. This occurs in spite of the fact that ImaginaryNumber has definitions for all of the methods called in Equals() and that ImaginaryNumber is a subclass of Object. In order to correct this error, Equals() would have to be changed to take two ImaginaryNumber objects as parameters. The corrected, functional version of the MyMath class is shown below.
class MyMath {
public static boolean equals(ImaginaryNumber a, ImaginaryNumber b) {
return (a.getRealPart() == b.getRealPart());
}
}
Ruby Example
In a duck typed language, such as Ruby, the Equals() method below would require parameters to have a defined type. A runtime error would be generated only if a non-ImaginaryNumber object was passed to the Equals() method. As long as only objects of type ImaginaryNumber are passed to the Equals() method, no error will ever be generated. The equivalent Ruby code is shown below.
class ImaginaryNumber
def initialize(realPart, imaginaryPart)
@realPart = realPart
@imaginaryPart = imaginaryPart
end
attr_reader :realPart, :imaginaryPart
end
class MyMath
def self.equals(a, b)
a.realPart == b.realPart
end
end
Duck Typing vs. Interfaces and Inheritance
The most obvious advantage of duck typing over interfaces and inheritance is conciseness of code. In a statically typed language that makes use of interfaces and inheritance, more code is often required to ensure type safety. Another major advantage is that duck typing is less restrictive since it allows the the end user to choose what type of object will be passed as parameters to any method at run time. As long as that argument has the required behavior, the method will function properly.
The disadvantage of duck typing is the potential for errors to occur at run time when the program is out of the control of the programmer. In a statically typed language, type safety errors can be caught and corrected at compile time, before product release. As a result, statically typed languages are more suited for safety critical software, such as control systems. [3]
See Also
For another code example using Ruby, go to http://rubylearning.com/satishtalim/duck_typing.html
A Sun blog entry about duck typing: http://blogs.sun.com/bblfish/entry/duck_typing_done_right
Dave Thomas's entry about duck typing: http://blade.nagaokaut.ac.jp/cgi-bin/scat.rb/ruby/ruby-talk/78502
Dr. Ed Gehringer's notes on duck typing can be found at http://courses.ncsu.edu/csc517/common/lectures/notes/lec6.doc.
For a more detailed example using Boo, a language that uses both static typing and duck typing, see http://boo.codehaus.org/Duck+Typing.
For a real-world example of duck-typing in C#, visit http://haacked.com/archive/2007/08/19/why-duck-typing-matters-to-c-developers.aspx.
References
[1] http://en.wikipedia.org/wiki/Duck_test
[2] http://en.wikipedia.org/wiki/Duck_typing
[3] http://courses.ncsu.edu/csc517/common/lectures/notes/lec6.doc