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I recently found an interesting article on implicit contexts in Ruby, and I found the experience quite mind opening. I understood that Ruby holds a reference not only to self (the default method receiver), but also to the current class (also known as default definee or `klass').

From the article, It should be correct to assume that class definition sets both self and the current class to the class that is being defined; as far as we consider normal method definition (i.e. not using the dot syntax to define singleton methods), in the context of method definition with def, self refers to the receiving object, and the current class isn't changed.

The reason i find safe to not consider the dot syntax for defining is that Ruby also offers an explicit way to open the eigenclass of a class, and the very thing I'm interested is understanding how these two implicit contexts are managed when opening a eigenclass.

Using def with the well known syntax for opening a eigenclass:

class << A
  p self

  def foo
    # ...

defines foo as a singleton method of A, i.e. an instance method of its eigenclass (be it A'). This code also prints #<Class:A>, so is it correct to say that the << syntax sets both self and the current class to A'?

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2 Answers 2

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Yes it actually opens the block under the control of A'. Also you can say that it works like class_eval of A'.

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I found the comparison with class_eval really interesting. While these implementation details are usually hidden (and probably should be), i think they're needed to understand why, e.g., self is A and not A' inside of foo, but if you define a method inside of foo, it's defined into A' and not A (to even further stress the difference between self and the current class!). This also makes clear the fact that in the idiom class Object; def eigen; class << self; self; end; end; end to get the eigenclass, you need to explicitly open the eigenclass inside the def. –  Alberto Moriconi Nov 4 '12 at 14:17
You can eigen class, but you wont be able to instantiate it. Also 1 more fact i would like to tell is that you can also define methods for eigen class too, which can be called with eigen class only... and this can be done by writing class<<self ;end; in control of eigen class...This is wonderful that we can create eigen class of eigen class. –  Akshay Vishnoi Nov 4 '12 at 14:37
Yes, i already noticed that it's possible to get the eigenclass of an eigenclass of an... even if this is hardly useful in everyday programming :) I noticed however things can get a bit messy if we consider the full class hierarchy of higher grade eigenclasses. –  Alberto Moriconi Nov 4 '12 at 14:57

Actually, what you wrote is exactly the same as writing:

class A
  class << self
    def foo

the class << self syntax indicates that a block of definitions will follow, and this is going to go straight to the eigenclass of the object passed to <<. And yes, I said Object, not Class. Try this (provided the class definition above):

a = A.new
class << a
  def foo2
b = A.new

this means, in this case, you are defining the method foo2 in the eigenclass of the object a. But this is the eigenclass of the object itself, not the class. So, further objects of the same class will not share this foo2 definition.

So what this means? Ruby is (or claims to be) a pure OO language. Everything is an object. An Object of a class defined by you is an Object. A Class defined by you is also an Object. Of type Class. Which inherits from Object. In Ruby, all objects have an eigenclass. Actually, the definition of "class methods" is just an interpretation of its concept. "Class Methods" are not really class methods, but methods defined in the eigenclass of the class. So, when you are calling a "class method", you are indeed calling an object method. This object just happens to be a class you defined. How you define eigenclass methods? Exactly the class << self syntax. The "self" in this context is whatever you passed as an argument to class <<.

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Of course I'm well aware of this; however, the concept I'm trying to tackle is somehow a bit more obscure: the difference between self and what is sometimes called 'klass', i.e. the class on which def defines a method (cfr. with define_method that always work on self, instead). Thanks anyway for your clear explaination. –  Alberto Moriconi Nov 4 '12 at 13:46
My apologies for not tackling the right issue. But what do you mean by 'klass' then? Technically this doesn't exist. As for self, I just take it as a scope in such meta block definitions. –  ChuckE Nov 4 '12 at 13:57
You can read about it in the article I linked; basically, it refers to the class to which the methods defined with def are added. To better clarify: when using instance_eval and class_eval on an object, be it a class A, the value of self inside both the blocks associated with the two evals is A. However def works differently inside the two blocks: this is because 'klass' refers to A when using class_eval, to A' when using instance_eval. I'm interested with the mechanics of how this context is managed by Ruby. –  Alberto Moriconi Nov 4 '12 at 14:02
An even more obvious example where the two differ is the top-level: at the top-level self is main, but the definition context is Object (and private, interestingly!) –  Jörg W Mittag Nov 4 '12 at 14:18
I see. The way I see if, when doing class_eval on A you are defining methods in its definition, i.e. they are instance_methods of A (doing class A; def foo; ; end; end is the same as A = Class.new; A.class_eval do; def foo; ; end ; end (for both: A.instance_methods). By using instance_eval, you are not accessing A, but its singleton/eigenclass (maybe what you refer by A'). and A.instance_eval &block is the same as class << A &block. self in both cases will be the eigenclass (for both: A.singleton_methods). –  ChuckE Nov 4 '12 at 14:31

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