ruby/lib/singleton.rb

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Ruby
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# The Singleton module implements the Singleton pattern.
#
# Usage:
# class Klass
# include Singleton
# # ...
# end
#
# * this ensures that only one instance of Klass lets call it
# ``the instance'' can be created.
#
# a,b = Klass.instance, Klass.instance
# a == b # => true
# a.new # NoMethodError - new is private ...
#
# * ``The instance'' is created at instanciation time, in other words
# the first call of Klass.instance(), thus
#
# class OtherKlass
# include Singleton
# # ...
# end
# ObjectSpace.each_object(OtherKlass){} # => 0.
#
# * This behavior is preserved under inheritance and cloning.
#
#
# This is achieved by marking
# * Klass.new and Klass.allocate - as private
# * removing #clone and #dup and modifying
# * Klass.inherited(sub_klass) and Klass.clone() -
# to ensure that the Singleton pattern is properly
# inherited and cloned.
#
# In addition Klass is providing the additional class methods
# * Klass.instance() - returning ``the instance''. After a successful
# self modifying instanciating first call the method body is a simple
# def Klass.instance()
# return @__instance__
# end
# * Klass._load(str) - calls instance()
# * Klass._instanciate?() - returning ``the instance'' or nil
# This hook method puts a second (or nth) thread calling
# Klass.instance() on a waiting loop. The return value signifies
# the successful completion or premature termination of the
# first, or more generally, current instanciating thread.
#
# The sole instance method of Singleton is
# * _dump(depth) - returning the empty string. Marshalling strips
# by default all state information, e.g. instance variables and taint
# state, from ``the instance''. Providing custom _load(str) and
# _dump(depth) hooks allows the (partially) resurrections of a
# previous state of ``the instance''.
module Singleton
private
# default marshalling strategy
def _dump(depth=-1) '' end
class << self
# extending an object with Singleton is a bad idea
undef_method :extend_object
private
def append_features(mod)
# This catches ill advisted inclusions of Singleton in
# singletons types (sounds like an oxymoron) and
# helps out people counting on transitive mixins
unless mod.instance_of? (Class)
raise TypeError, "Inclusion of the OO-Singleton module in module #{mod}"
end
unless (class << mod; self end) <= (class << Object; self end)
raise TypeError, "Inclusion of the OO-Singleton module in singleton type"
end
super
end
def included (klass)
# remove build in copying methods
klass.class_eval do
define_method(:clone) {raise TypeError, "can't clone singleton #{self.type}"}
end
# initialize the ``klass instance variable'' @__instance__ to nil
klass.instance_eval do @__instance__ = nil end
class << klass
# a main point of the whole exercise - make
# new and allocate private
private :new, :allocate
# declare the self modifying klass#instance method
define_method (:instance, Singleton::FirstInstanceCall)
# simple waiting loop hook - should do in most cases
# note the pre/post-conditions of a thread-critical state
private
def _instanciate?()
while false.equal?(@__instance__)
Thread.critical = false
sleep(0.08)
Thread.critical = true
end
@__instance__
end
# default Marshalling strategy
def _load(str) instance end
# ensure that the Singleton pattern is properly inherited
def inherited(sub_klass)
super
sub_klass.instance_eval do @__instance__ = nil end
class << sub_klass
define_method (:instance, Singleton::FirstInstanceCall)
end
end
public
# properly clone the Singleton pattern. Question - Did
# you know that duping doesn't copy class methods?
def clone
res = super
res.instance_eval do @__instance__ = nil end
class << res
define_method (:instance, Singleton::FirstInstanceCall)
end
res
end
end # of << klass
end # of included
end # of << Singleton
FirstInstanceCall = proc do
# @__instance__ takes on one of the following values
# * nil - before and after a failed creation
# * false - during creation
# * sub_class instance - after a successful creation
# the form makes up for the lack of returns in progs
Thread.critical = true
if @__instance__.nil?
@__instance__ = false
Thread.critical = false
begin
@__instance__ = new
ensure
if @__instance__
def self.instance() @__instance__ end
else
@__instance__ = nil # failed instance creation
end
end
elsif _instanciate?()
Thread.critical = false
else
@__instance__ = false
Thread.critical = false
begin
@__instance__ = new
ensure
if @__instance__
def self.instance() @__instance__ end
else
@__instance__ = nil
end
end
end
@__instance__
end
end
if __FILE__ == $0
def num_of_instances(klass)
"#{ObjectSpace.each_object(klass){}} #{klass} instance(s)"
end
# The basic and most important example. The latter examples demonstrate
# advanced features that have no relevance for the general usage
class SomeSingletonClass
include Singleton
end
puts "There are #{num_of_instances(SomeSingletonClass)}"
a = SomeSingletonClass.instance
b = SomeSingletonClass.instance # a and b are same object
puts "basic test is #{a == b}"
begin
SomeSingletonClass.new
rescue NoMethodError => mes
puts mes
end
puts "\nThreaded example with exception and customized #_instanciate?() hook"; p
Thread.abort_on_exception = false
class Ups < SomeSingletonClass
def initialize
type.__sleep
puts "initialize called by thread ##{Thread.current[:i]}"
end
class << self
def _instanciate?
@enter.push Thread.current[:i]
while false.equal?(@__instance__)
Thread.critical = false
sleep 0.04
Thread.critical = true
end
@leave.push Thread.current[:i]
@__instance__
end
def __sleep
sleep (rand(0.08))
end
def allocate
__sleep
def self.allocate; __sleep; super() end
raise "boom - allocation in thread ##{Thread.current[:i]} aborted"
end
def instanciate_all
@enter = []
@leave = []
1.upto(9) do |i|
Thread.new do
begin
Thread.current[:i] = i
__sleep
instance
rescue RuntimeError => mes
puts mes
end
end
end
puts "Before there were #{num_of_instances(self)}"
sleep 5
puts "Now there is #{num_of_instances(self)}"
puts "#{@enter.join "; "} was the order of threads entering the waiting loop"
puts "#{@leave.join "; "} was the order of threads leaving the waiting loop"
end
end
end
Ups.instanciate_all
# results in message like
# Before there were 0 Ups instances
# boom - allocation in thread #8 aborted
# initialize called by thread #3
# Now there is 1 Ups instance
# 2; 3; 6; 1; 7; 5; 9; 4 was the order of threads entering the waiting loop
# 3; 2; 1; 7; 6; 5; 4; 9 was the order of threads leaving the waiting loop
puts "\nLets see if class level cloning really works"
Yup = Ups.clone
def Yup.allocate
__sleep
def self.allocate; __sleep; super() end
raise "boom - allocation in thread ##{Thread.current[:i]} aborted"
end
Yup.instanciate_all
puts "\n","Customized marshalling"
class A
include Singleton
attr_accessor :persist, :die
def _dump(depth)
# this strips the @die information from the instance
Marshal.dump(@persist,depth)
end
end
def A._load(str)
instance.persist = Marshal.load(str)
instance
end
a = A.instance
a.persist = ["persist"]
a.die = "die"
a.taint
stored_state = Marshal.dump(a)
# change state
a.persist = nil
a.die = nil
b = Marshal.load(stored_state)
p a == b # => true
p a.persist # => ["persist"]
p a.die # => nil
puts "\n\nSingleton with overridden default #inherited() hook"
class Up
def Up.inherited(sub_klass)
puts "#{sub_klass} subclasses #{self}"
end
end
class Middle < Up
undef_method :dup
include Singleton
end
class Down < Middle; end
puts "basic test is #{Down.instance == Down.instance}"
puts "\n","Various exceptions"
begin
module AModule
include Singleton
end
rescue TypeError => mes
puts mes #=> Inclusion of the OO-Singleton module in module AModule
end
begin
class << 'aString'
include Singleton
end
rescue TypeError => mes
puts mes # => Inclusion of the OO-Singleton module in singleton type
end
begin
'aString'.extend Singleton
rescue NoMethodError => mes
puts mes #=> undefined method `extend_object' for Singleton:Module
end
end