Due to Ruby's open classes you can redefine or add functionality to existing classes. This is called a “monkey patch”. Unfortunately the scope of such changes is global. All users of the monkey-patched class see the same changes. This can cause unintended side-effects or breakage of programs.
Refinements are designed to reduce the impact of monkey patching on other users of the monkey-patched class. Refinements provide a way to extend a class locally.
Here is a basic refinement:
class C def foo puts "C#foo" end end module M refine C do def foo puts "C#foo in M" end end end
First, a class C
is defined. Next a refinement for
C
is created using Module#refine. Refinements
only modify classes, not modules so the argument must be a class.
Module#refine creates an
anonymous module that contains the changes or refinements to the class
(C
in the example). self
in the refine block is
this anonymous module similar to Module#module_eval.
Activate the refinement with using:
using M c = C.new c.foo # prints "C#foo in M"
You may activate refinements at top-level, and inside classes and modules. You may not activate refinements in method scope. Refinements are activated until the end of the current class or module definition, or until the end of the current file if used at the top-level.
You may activate refinements in a string passed to Kernel#eval. Refinements are active until the end of the eval string.
Refinements are lexical in scope. Refinements are only active within a
scope after the call to using
. Any code before the
using
statement will not have the refinement activated.
When control is transferred outside the scope, the refinement is deactivated. This means that if you require or load a file or call a method that is defined outside the current scope the refinement will be deactivated:
class C end module M refine C do def foo puts "C#foo in M" end end end def call_foo(x) x.foo end using M x = C.new x.foo # prints "C#foo in M" call_foo(x) #=> raises NoMethodError
If a method is defined in a scope where a refinement is active, the refinement will be active when the method is called. This example spans multiple files:
c.rb:
class C end
m.rb:
require "c" module M refine C do def foo puts "C#foo in M" end end end
m_user.rb:
require "m" using M class MUser def call_foo(x) x.foo end end
main.rb:
require "m_user" x = C.new m_user = MUser.new m_user.call_foo(x) # prints "C#foo in M" x.foo #=> raises NoMethodError
Since the refinement M
is active in m_user.rb
where MUser#call_foo
is defined it is also active when
main.rb
calls call_foo
.
Since using is a method, refinements are only active when it is called.
Here are examples of where a refinement M
is and is not
active.
In a file:
# not activated here using M # activated here class Foo # activated here def foo # activated here end # activated here end # activated here
In a class:
# not activated here class Foo # not activated here def foo # not activated here end using M # activated here def bar # activated here end # activated here end # not activated here
Note that the refinements in M
are not
activated automatically if the class Foo
is reopened later.
In eval:
# not activated here eval <<EOF # not activated here using M # activated here EOF # not activated here
When not evaluated:
# not activated here if false using M end # not activated here
When defining multiple refinements in the same module inside multiple
refine
blocks, all refinements from the same module are active
when a refined method (any of the to_json
methods from the
example below) is called:
module ToJSON refine Integer do def to_json to_s end end refine Array do def to_json "[" + map { |i| i.to_json }.join(",") + "]" end end refine Hash do def to_json "{" + map { |k, v| k.to_s.dump + ":" + v.to_json }.join(",") + "}" end end end using ToJSON p [{1=>2}, {3=>4}].to_json # prints "[{\"1\":2},{\"3\":4}]"
When looking up a method for an instance of class C
Ruby
checks:
If refinements are active for C
, in the reverse order they
were activated:
The prepended modules from the refinement for C
The refinement for C
The included modules from the refinement for C
The prepended modules of C
C
The included modules of C
If no method was found at any point this repeats with the superclass of
C
.
Note that methods in a subclass have priority over refinements in a
superclass. For example, if the method /
is defined in a
refinement for Numeric 1 / 2
invokes the original Integer#/ because Integer is a subclass of Numeric and is searched before the
refinements for the superclass Numeric.
Since the method /
is also present in child
Integer
, the method lookup does not move up to the superclass.
However, if a method foo
is defined on Numeric in a refinement, 1.foo
invokes that method since foo
does not exist on Integer.
super
¶ ↑When super
is invoked method lookup checks:
The included modules of the current class. Note that the current class may be a refinement.
If the current class is a refinement, the method lookup proceeds as in the Method Lookup section above.
If the current class has a direct superclass, the method proceeds as in the Method Lookup section above using the superclass.
Note that super
in a method of a refinement invokes the method
in the refined class even if there is another refinement which has been
activated in the same context.
When using indirect method access such as Kernel#send, Kernel#method or Kernel#respond_to? refinements are not honored for the caller context during method lookup.
This behavior may be changed in the future.
When a module X is included into a module Y, Y inherits refinements from X.
For exmaple, C inherits refinements from A and B in the following code:
module A refine X do ... end refine Y do ... end end module B refine Z do ... end end module C include A include B end using C # Refinements in A and B are activated here.
Refinements in descendants have higher precedence than those of ancestors.
See bugs.ruby-lang.org/projects/ruby-trunk/wiki/RefinementsSpec for the current specification for implementing refinements. The specification also contains more details.