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'''method_missing in Ruby'''
'''method_missing in Ruby:'''




=='''Introduction'''==
=='''Introduction'''==
When we define a method in a class and decide to call that method, how do we do it?
A method of a class is called by creating an object of the class and passing the method name to the object as a message. The object then looks up into its [http://blog.rubybestpractices.com/posts/gregory/031-issue-2-method-lookup.html method lookup path] and tries to match the called method with the defined methods in the class. On success, the method is executed along with the parameters passed and the result is returned.


We simply create an object of the class and pass the method name to the object as a message. The object then looks up into its [http://blog.rubybestpractices.com/posts/gregory/031-issue-2-method-lookup.html method lookup path] and tries to match the called method (passed as a message to the object) with the defined methods in the class. When there is a match, the method is executed along with the parameters passed and the result is returned.
=='''Method Lookup Path'''==
=='''What is a Method Lookup Path?'''==
The object of a class receives a method name to be executed, these are the following steps carried for executing the method called:
When the object receives a method name that is to be executed, these are the steps carried out for finding out that method called:


*It looks in the current self object’s own [http://docs.oracle.com/javase/tutorial/java/javaOO/classvars.html instance methods].
*First, the object looks in its own [http://docs.oracle.com/javase/tutorial/java/javaOO/classvars.html instance methods].
*Then it looks in the list of instance methods that all objects of that class share.
*Second, it looks in the list of instance methods that all objects of that class share.
*Then in each of the included [http://www.tutorialspoint.com/ruby/ruby_modules.html modules] of that class, in reverse order of inclusion.  
*Third, in each of the included [http://www.tutorialspoint.com/ruby/ruby_modules.html modules] of that class, in reverse order of inclusion.  
*Then it looks in that class’s superclass.  
*Fourth, it looks in that class’s superclass.  
*Then in the superclass’s included modules, all the way up until it reaches the class Object.  
*Fifth, in the superclass’s included modules, all the way up until it reaches the class Object.  
*If it still can’t find a method, the very last place it looks is in the [http://linux.die.net/lkmpg/x40.html Kernel module], included in the class Object.  
*Sixth, if it still can’t find a method, the very last place it looks is in the [http://linux.die.net/lkmpg/x40.html Kernel module], included in the class Object.  
*Finally, it calls method_missing (if defined in the class), else throws up the NOMethodError exception.
*Finally, it calls method_missing (if defined in the class), else throws up the [http://www.ruby-doc.org/core-1.9.3/NoMethodError.html NOMethodError exception].


This entire tracing that the object does is the method lookup path.
This entire tracing that the object does is the method lookup path.


=='''What is method_missing?<ref>http://rubylearning.com/satishtalim/ruby_method_missing.html</ref>'''==
=='''method_missing<ref>http://rubylearning.com/satishtalim/ruby_method_missing.html</ref>'''==
Now suppose that the object does not find a matching method in its method lookup path i.e there is no such method defined in the class. Then what?
If the object does not find a match in its method lookup, in normal circumstances the NoMethodError Exception is raised .
In normal circumstances the [http://www.ruby-doc.org/core-1.9.3/NoMethodError.html NoMethodError Exception] is raised .


Here is where the method_missing comes into picture. The name “method_missing” should be self explanatory that it is invoked when a method is not found. It is a method of last resort. This method accepts the name of the non-existing method, the array of arguments passed and also any associated block to the method.
“method_missing” is invoked when a method is not found. It is a method of last resort.  


=='''The format for defining method_missing'''==
=='''The format for defining method_missing'''==
Line 30: Line 27:
  => def method_missing(m,*args,&block)
  => def method_missing(m,*args,&block)


There are 3 arguments: (i) '''m->''' Takes the symbol/name of the undefined method (ii) '''*args->''' Takes the array of arguments passed in the method call  (iii) '''&block->''' Takes any block passes to the method  
(i) '''m->''' symbol/name of the undefined method (ii) '''*args->''' array of arguments passed in the method call  (iii) '''&block->'''block passes to the method  


=='''Examples'''==
=='''Examples'''==
===(i)simple illustration===
===(i)Calling defined and undefined methods===


  class A // creating a class A
  class A // creating a class 'A'
  def say // defining a method say
  def say // defining a method 'say'
  puts " say Hi "               // body of method say
  puts " say Hi "       // body of method say
  end
  end
  end
  end


Now, creating the object of the class
Creating the object of the class
   
   
   a=A.new         // object of the class
   a=A.new         // object of the class
   => #<A:0x2a082e0>     //object id
   => #<A:0x2a082e0>     //object id


Calling the defined method
Calling the defined method
Line 53: Line 50:
Calling the undefined method
Calling the undefined method
   
   
  a.sayhi                 // undefined method sayhi
  a.sayhi               // undefined method sayhi
  NoMethodError: undefined method `sayhi' for #<A:0x2a082e0>  // the NoMethodError is raised
  NoMethodError: undefined method `sayhi' for #<A:0x2a082e0>  // the NoMethodError is raised


Line 62: Line 59:
  puts " say hi "
  puts " say hi "
  end
  end
  def method_missing(m,*args,&block) // defining method_missing
  def method_missing(m,*args,&block) // defining method_missing
  puts " This method does not exist" // body of method_missing
  puts " This method does not exist" // body of method_missing
  end
  end
  end
  end
Line 70: Line 67:
   
   
  a=A.new
  a=A.new
  a.sayhi                                 // calling the undefined method sayhi with no arguments
  a.sayhi                               // calling the undefined method sayhi with no arguments
  => This method does not exist // this result returned when method_missing is executed
  => This method does not exist // this result returned when method_missing is executed


'''Explanation:''' When the object 'a' traces its method lookup path for a matching method as 'sayhi', after a failure it resorts to method_missing and the body of method_missing is executed.
When the object 'a' traces its method lookup path for a matching method as 'sayhi', upon failure it resorts to method_missing and the body of method_missing is executed.


'''Note:''' There is something interesting that programmers do. Sometimes when a class has many methods that do generally the same kinds of things, and the programmer is not sure in advance which methods will the user call since there are so many of them, and they are all so similar, implementing all of them by hand seems futile. In these situations method_missing makes a new method that was previously not defined and adds it to the class ; or it just does what needs to be done, this is in the hands of the programmer. You can look at the Generic Handler example for this.
'''Note:'''Sometimes when a class has many methods that do generally the same kinds of things, and the programmer is not sure in advance which methods the user will call since there are so many of them, and they are all so similar, implementing all of them by hand seems futile. In these situations method_missing makes a new method that was previously not defined and adds it to the class. The following example Generic Handler implements this.  




Now, let us look into a few more examples to get the concept right.
===(iii)passing parameters to an undefined method call===
 
===(iii)passing parameters in an undefined method call===


  class A
  class A
Line 92: Line 87:
  end
  end


The passed parameters are stored in the array 'args' and can be accessed like a normal array                 
The passed parameters are stored in the array 'args' and can be accessed like a normal array                 
                                                    
                                                    
   
   
Line 105: Line 100:
  => You have typed the method name wrong and these were the parameters passed; 4, 2
  => You have typed the method name wrong and these were the parameters passed; 4, 2


'''Explanation:''' There is a genuine mistake that the user instead of add has typed in adds and this method is not defined. Here when the adds method with parameters is called, the object 'a' tries to look up the method in the method lookup path. When upon failure it invokes method_missing then the args passed in the 'adds' method are stored in the array “args”. It then executes the body of method_missing making use of the parameters.
The user made a genuine mistake by typing 'adds' and this method is not defined. When the 'adds' method with parameters is called, the object 'a' tries to match the method in the method lookup path. Upon failure it invokes method_missing, the args are passed and stored in the array 'args'.


===(iv)converting numbers from roman representation to integer representation<ref>http://www.rubyquiz.com/quiz22.html</ref>===
===(iv)converting numbers from roman representation to integer representation<ref>http://www.rubyquiz.com/quiz22.html</ref>===
Line 163: Line 158:


===(v)method_missing to log method calls<ref>http://expertiza.csc.ncsu.edu/wiki/index.php/CSC/ECE_517_Fall_2007/wiki1b_2_22</ref>===
===(v)method_missing to log method calls<ref>http://expertiza.csc.ncsu.edu/wiki/index.php/CSC/ECE_517_Fall_2007/wiki1b_2_22</ref>===
Another application that makes use of method_missing could be a simple logger used for debugging purposes. Many times, it may be required to log the trace of called methods and provide information such as: called method-name, arguments, return type. It can be tedious to repeat this part of code in every method. So, a simple solution to this problem can be obtained using method_missing as:
Another application that makes use of method_missing could be a simple logger used for debugging purposes. Many times, it may be required to log the trace of called methods and provide information such as: called method-name, arguments, return type. It can be tedious to repeat this part of code in every method. A simple solution to this problem can be obtained using method_missing as:


   class SimpleCallLogger
   class SimpleCallLogger
Line 177: Line 172:
   end
   end


'''EXPLANATION:''' This program makes use of method_missing in a way that it wraps around called method to output the logging information on entry and on exit, it logs the return type. Further, method_missing intercepts the method call and forward it to internal object with ‘send’ method of ruby. Hence, this use of method_missing acts as wrapper.
This program makes use of method_missing in a way that it wraps around called method to output the logging information on entry and on exit, it logs the return type. Further, method_missing intercepts the method call and forward it to internal object with ‘send’ method of ruby. Hence, this use of method_missing acts as wrapper.


===(vi)Generic Handler===
===(vi)Generic Handler===
Line 191: Line 186:
=='''Advantages of method_missing'''==
=='''Advantages of method_missing'''==


*In addition to specifying the error messages for the methods that are not defined, method_missing provides a more dynamic behavior in the programming environment.
*In addition to specifying the error messages for the undefined methods, method_missing provides a more dynamic behavior in the programming environment.
*If we are unfamiliar with the usage of the object we created but it must support unexpected method calls, then using method_missing is a good option.
*If we are unfamiliar with the usage of the object we created, then using method_missing is a good implementation.
*Allows to catch problem at runtime.
*Handles problems at runtime.
*Allows to define a generic method_missing and handle any undefined method. This is a big advantage over Java. In Java, when you call an undefined method, the program will not compile.
*Define's a generic method_missing and handle's any undefined method, a big advantage over Java. In Java, when you call an undefined method, the program will not compile.
*The use of method_missing falls under the general technique of meta-programming. You can employ meta-programming in missing_function to write a another function to handle the call.
*method_missing falls under the general technique of meta-programming. Employ meta-programming in missing_function to write an another function to handle the call.


=='''Disadvantages of method_missing'''==
=='''Disadvantages of method_missing'''==
*It is slower than conventional method lookup. Simple tests indicate that method dispatch with method_missing is at least two to three times as expensive in time as conventional dispatch.
*Slower than conventional method lookup. Simple tests indicate that method dispatch with method_missing is at least two to three times as expensive in time as conventional dispatch.


*Since the methods being called never actually exist—they are just intercepted at the last step of the method lookup process—they cannot be documented or introspected as conventional methods can.
*Since the methods being called never actually exist—they are just intercepted at the last step of the method lookup process—they cannot be documented or introspected as conventional methods can.


*Because all dynamic methods must go through the method_missing method, the body of that method can become quite large if there are many different aspects of the code that need to add methods dynamically.
*Dynamic methods must go through the method_missing method, the body of that method can become quite large if there are many different aspects of the code that needs to add methods dynamically.
 
*method_missing restricts compatibility with future versions of an API. Introducing new methods in a future API version can break users' expectations.


*Using method_missing restricts compatibility with future versions of an API. Once you rely on method_missing to do something interesting with undefined methods, introducing new methods in a future API version can break your users' expectations.
=='''Key Points'''==
*Ruby knows method_missing( ) exisits, because it's a private instance method of 'BasicObject' that every object inherits. The BasicObject#method_missing( ) responds by raising the NoMethodError. Overriding this method_missing( ) allows you to call methods that don't really exist.  


=='''Things to remember'''==
*If method_missing is only looking for certain method names, don't forget to call super if you haven't found what you're looking for, so that the other superclass' method_missing can handle it.
*Ruby knows that method_missing( ) is there, because it's a private instance method of BasicObject that every object inherits. The BasicObject#method_missing( ) responds by raising a NoMethodError. Overriding this method_missing( ) allows you to call methods that don't really exist. If your method_missing method is only looking for certain method names, don't forget to call super if you haven't found what you're looking for, so that the other superclass method_missing can handle it.


*obj.respond_to? function returns true if the obj responds to the given method. So if you want to know whether your class will respond to a function you can use respond_to? to know the answer. But if method_missing() is used the output may not be what you expected.
*obj.respond_to? function returns 'true' if the obj responds to the given method. So if you want to know whether your class will respond to a function you can use respond_to? to know the answer. But if method_missing() is used, the output may not be what you expect.


*Take the case of the below program. Class A defines only method method_missing() and no other method. Now when a new object is created for class A and when that tries to access a method say, foo, the respond_to? will return the value false. But when you try to actually implement it using “a.foo”, the code will get executed courtesy of method_missing(). So even though the respond_to? says that you cannot access foo function using class A object, if you have method_missing() defined you can access the method.
*Below class A defines only method method_missing() and no other method. When a new object of class A tries to access a method say 'foo', the respond_to? will return the value 'false'. When you actually try to implement it using “a.foo”, the code will get executed, courtesy of method_missing(). Even though the respond_to? says that you cannot access 'foo' method using object of class A, if you have method_missing() defined, you can access the method.


  class A
  class A
Line 227: Line 224:
  In method_missing
  In method_missing


*What if within the method_missing() we define an undefined method? Then what is the result expected? Try to run this code and see what is the result:
*If within method_missing() we define an undefined method.


  class A
  class A
Line 240: Line 237:
  a = A.new
  a = A.new
  puts a.respond_to?(:foo) // just checking whether the receiver 'a' responds to the method 'foo'
  puts a.respond_to?(:foo) // just checking whether the receiver 'a' responds to the method 'foo'
  even though the result is false the execution will proceed normally
 
  a.foo  
  a.foo  


Output
Output


  The expected result would be an "stack level too deep" error.  
  The expected result would be a 'stack level too deep' error.  


'''Explanation:''' when the “foo” method is called upon the object, the method_missing is run and in this block you have a method “self.fun” that is undefined (its a random name that we gave). Here when the program execution encounters “self.fun” it again calls upon method_missing and this goes on in an endless loop till the stack is full.
When the 'foo' method is called, after no method match the method_missing is run and this block has a method “self.fun” that is undefined. Here when the program execution encounters 'self.fun' it once again calls method_missing. This goes on in an endless loop till the stack memory is full.


=='''References'''==
=='''References'''==

Revision as of 05:13, 10 September 2012

method_missing in Ruby:


Introduction

A method of a class is called by creating an object of the class and passing the method name to the object as a message. The object then looks up into its method lookup path and tries to match the called method with the defined methods in the class. On success, the method is executed along with the parameters passed and the result is returned.

Method Lookup Path

The object of a class receives a method name to be executed, these are the following steps carried for executing the method called:

  • First, the object looks in its own instance methods.
  • Second, it looks in the list of instance methods that all objects of that class share.
  • Third, in each of the included modules of that class, in reverse order of inclusion.
  • Fourth, it looks in that class’s superclass.
  • Fifth, in the superclass’s included modules, all the way up until it reaches the class Object.
  • Sixth, if it still can’t find a method, the very last place it looks is in the Kernel module, included in the class Object.
  • Finally, it calls method_missing (if defined in the class), else throws up the NOMethodError exception.

This entire tracing that the object does is the method lookup path.

method_missing<ref>http://rubylearning.com/satishtalim/ruby_method_missing.html</ref>

If the object does not find a match in its method lookup, in normal circumstances the NoMethodError Exception is raised .

“method_missing” is invoked when a method is not found. It is a method of last resort.

The format for defining method_missing

=> def method_missing(m,*args,&block)

(i) m-> symbol/name of the undefined method (ii) *args-> array of arguments passed in the method call (iii) &block->block passes to the method

Examples

(i)Calling defined and undefined methods

class A		// creating a class 'A'
def say		// defining a method 'say'
puts " say Hi "        // body of method say
end
end

Creating the object of the class

 a=A.new	        // object of the class
 => #<A:0x2a082e0>     //object id

Calling the defined method

a.say                  // defined method
=> say Hi	        // returned result

Calling the undefined method

a.sayhi                // undefined method sayhi
NoMethodError: undefined method `sayhi' for #<A:0x2a082e0>   // the NoMethodError is raised

(ii)method_missing implementation<ref>http://www.thirdbit.net/articles/2007/08/01/10-things-you-should-know-about-method_missing/</ref>

class A
def say
puts " say hi "
end
def method_missing(m,*args,&block)	// defining method_missing
puts " This method does not exist"	// body of method_missing
end
end

Calling a method that is not defined

a=A.new
a.sayhi                                // calling the undefined method sayhi with no arguments
=> This method does not exist		// this result returned when method_missing is executed

When the object 'a' traces its method lookup path for a matching method as 'sayhi', upon failure it resorts to method_missing and the body of method_missing is executed.

Note:Sometimes when a class has many methods that do generally the same kinds of things, and the programmer is not sure in advance which methods the user will call since there are so many of them, and they are all so similar, implementing all of them by hand seems futile. In these situations method_missing makes a new method that was previously not defined and adds it to the class. The following example Generic Handler implements this.


(iii)passing parameters to an undefined method call

class A
def add(a,b)
a+b
end
def method_missing(name,*args,&block)    // the method_missing is defined and the *args parameter accepts all the parameters passed during 								                                 
                                            the method call   
puts “You have typed the method name wrong and these were the parameters passed ; #{args[0]}, #{args[1]}”								
end                         			
end

The passed parameters are stored in the array 'args' and can be accessed like a normal array


Calling the defined method

a.add(1,2)			// calling the defined method add and passing the parameters (1,2)
=> 3                           // result

Calling the undefined method

a.adds(4,2) 			// calling the undefined method adds and passing the parameter (4,2)
=> You have typed the method name wrong and these were the parameters passed; 4, 2

The user made a genuine mistake by typing 'adds' and this method is not defined. When the 'adds' method with parameters is called, the object 'a' tries to match the method in the method lookup path. Upon failure it invokes method_missing, the args are passed and stored in the array 'args'.

(iv)converting numbers from roman representation to integer representation<ref>http://www.rubyquiz.com/quiz22.html</ref>

class Roman
@@Roman_to_Numeric = {'i' => 1, 'v' => 5, 'x' => 10, 'l' => 50, 'c' => 100, 'd' => 500, 'm' => 1000}   
def method_missing(method_var,*args,&block)
numeric_value = 0
roman_string = method_var.to_s.downcase
for i in 0...roman_string.length-1
if (cond) == nil
else
puts "Roman string is invalid"
return
end
end
while roman_string != ""
if roman_string[roman_string.length - 1] == 'x' && roman_string[roman_string.length - 2] == 'i'
numeric_value += 9
roman_string.chop!
roman_string.chop!
elsif
roman_string[roman_string.length - 1] == 'v' && roman_string[roman_string.length - 2] == 'i'
numeric_value += 4
roman_string.chop!
roman_string.chop!
else
numeric_value += @@Roman_to_Numeric[roman_string[(roman_string.length)-1]]
roman_string.chop!
end
end
puts "Numeric Value for #{method_var} is: #{numeric_value}"
end
end

cond = @@Roman_to_Numeric[roman_string[i]]-@@Roman_to_Numeric[roman_string[i+1]] == 0 || @@Roman_to_Numeric[roman_string[i]]-@@Roman _ to_ Numeric [ roman _ string [ i + 1 ] ] == - 9 || @@Roman_to_Numeric[roman_string[i]]-@@Roman_to_Numeric[roman_string[i+1]] == -4 || @@Roman_to_Numeric[roman_string[i]]-@@Roman_to_Numeric[roman_string[i+1]] >= 4) && (/.v.x/ =~ roman_string


Calling the undefined methods

r= Roman.new
r.vii
r.iClx
r.xxix
r.xxxi
r.xxiv
r.xxvi
r.vx

The Output

Numeric Value for vii is: 7
Roman string is invalid
Numeric Value for xxix is: 29
Numeric Value for xxxi is: 31
Numeric Value for xxiv is: 24
Numeric Value for xxvi is: 26
Roman string is invalid

(v)method_missing to log method calls<ref>http://expertiza.csc.ncsu.edu/wiki/index.php/CSC/ECE_517_Fall_2007/wiki1b_2_22</ref>

Another application that makes use of method_missing could be a simple logger used for debugging purposes. Many times, it may be required to log the trace of called methods and provide information such as: called method-name, arguments, return type. It can be tedious to repeat this part of code in every method. A simple solution to this problem can be obtained using method_missing as:

 class SimpleCallLogger
 def initialize(o)
 @obj = o
 end
 def method_missing(methodname, *args)
 puts "called: #{methodname}(#{args})"
 a = @obj.send(methodname, *args)
 puts "\t-> returned: #{a}"
 return a
 end
 end

This program makes use of method_missing in a way that it wraps around called method to output the logging information on entry and on exit, it logs the return type. Further, method_missing intercepts the method call and forward it to internal object with ‘send’ method of ruby. Hence, this use of method_missing acts as wrapper.

(vi)Generic Handler

class NoBar
def method_missing(methodname, *args)
define_method(:bar) if "bar" == methodname.to_s
define_method(:nobar) if "nobar" == methodname.to_s
end
end

This is an example of using method_missing as a generic handler to handle when a calling method is not exist. You can use missing_method to dynamically create a method at a runtime.

Advantages of method_missing

  • In addition to specifying the error messages for the undefined methods, method_missing provides a more dynamic behavior in the programming environment.
  • If we are unfamiliar with the usage of the object we created, then using method_missing is a good implementation.
  • Handles problems at runtime.
  • Define's a generic method_missing and handle's any undefined method, a big advantage over Java. In Java, when you call an undefined method, the program will not compile.
  • method_missing falls under the general technique of meta-programming. Employ meta-programming in missing_function to write an another function to handle the call.

Disadvantages of method_missing

  • Slower than conventional method lookup. Simple tests indicate that method dispatch with method_missing is at least two to three times as expensive in time as conventional dispatch.
  • Since the methods being called never actually exist—they are just intercepted at the last step of the method lookup process—they cannot be documented or introspected as conventional methods can.
  • Dynamic methods must go through the method_missing method, the body of that method can become quite large if there are many different aspects of the code that needs to add methods dynamically.
  • method_missing restricts compatibility with future versions of an API. Introducing new methods in a future API version can break users' expectations.

Key Points

  • Ruby knows method_missing( ) exisits, because it's a private instance method of 'BasicObject' that every object inherits. The BasicObject#method_missing( ) responds by raising the NoMethodError. Overriding this method_missing( ) allows you to call methods that don't really exist.
  • If method_missing is only looking for certain method names, don't forget to call super if you haven't found what you're looking for, so that the other superclass' method_missing can handle it.
  • obj.respond_to? function returns 'true' if the obj responds to the given method. So if you want to know whether your class will respond to a function you can use respond_to? to know the answer. But if method_missing() is used, the output may not be what you expect.
  • Below class A defines only method method_missing() and no other method. When a new object of class A tries to access a method say 'foo', the respond_to? will return the value 'false'. When you actually try to implement it using “a.foo”, the code will get executed, courtesy of method_missing(). Even though the respond_to? says that you cannot access 'foo' method using object of class A, if you have method_missing() defined, you can access the method.
class A
def method_missing(method_id)
puts "In method_missing"
end
end
a = A.new
puts a.respond_to?(:foo)
a.foo

Output

false
In method_missing
  • If within method_missing() we define an undefined method.
class A
@@i = 0
def method_missing(method_id)
puts "In Method Missing #{@@i}"
@@i += 1
self.fun
end
end
a = A.new
puts a.respond_to?(:foo)	// just checking whether the receiver 'a' responds to the method 'foo'
a.foo 

Output

The expected result would be a 'stack level too deep' error. 

When the 'foo' method is called, after no method match the method_missing is run and this block has a method “self.fun” that is undefined. Here when the program execution encounters 'self.fun' it once again calls method_missing. This goes on in an endless loop till the stack memory is full.

References

<references/>

Further Suggested Reading