# = Multiton # # == Synopsis # # Multiton design pattern ensures only one object is allocated for a given state. # # The 'multiton' pattern is similar to a singleton, but instead of only one # instance, there are several similar instances. It is useful when you want to # avoid constructing objects many times because of some huge expense (connecting # to a database for example), require a set of similar but not identical # objects, and cannot easily control how many times a contructor may be called. # # class SomeMultitonClass # include Multiton # attr :arg # def initialize(arg) # @arg = arg # end # end # # a = SomeMultitonClass.new(4) # b = SomeMultitonClass.new(4) # a and b are same object # c = SomeMultitonClass.new(2) # c is a different object # # == Previous Behavior # # In previous versions of Multiton the #new method was made # private and #instance had to be used in its stay --just like Singleton. # But this is less desirable for Multiton since Multitions can # have multiple instances, not just one. # # So instead Multiton now defines #create as a private alias of # the original #new method (just in case it is needed) and then # defines #new to handle the multiton; #instance is provided # as an alias for it. # #-- # So if you must have the old behavior, all you need do is re-alias # #new to #create and privatize it. # # class SomeMultitonClass # include Multiton # alias_method :new, :create # private :new # ... # end # # Then only #instance will be available for creating the Multiton. #++ # # == How It Works # # A pool of objects is searched for a previously cached object, # if one is not found we construct one and cache it in the pool # based on class and the args given to the contructor. # # A limitation of this approach is that it is impossible to # detect if different blocks were given to a contructor (if it takes a # block). So it is the constructor arguments _only_ which determine # the uniqueness of an object. To workaround this, define the _class_ # method ::multiton_id. # # def SomeMultitonClass.multiton_id(*args, &block) # # ... # end # # Which should return a hash key used to identify the object being # constructed as (not) unique. # # == Authors # # * Christoph Rippel # * Thomas Sawyer # # = Copying # # Copyright (c) 2007 Christoph Rippel, Thomas Sawyer # # Ruby License # # This module is free software. You may use, modify, and/or redistribute this # software under the same terms as Ruby. # # This program is distributed in the hope that it will be useful, but WITHOUT # ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS # FOR A PARTICULAR PURPOSE. require 'thread' # = Multiton # # Multiton design pattern ensures only one object is allocated for a given state. # # The 'multiton' pattern is similar to a singleton, but instead of only one # instance, there are several similar instances. It is useful when you want to # avoid constructing objects many times because of some huge expense (connecting # to a database for example), require a set of similar but not identical # objects, and cannot easily control how many times a contructor may be called. # # class SomeMultitonClass # include Multiton # attr :arg # def initialize(arg) # @arg = arg # end # end # # a = SomeMultitonClass.new(4) # b = SomeMultitonClass.new(4) # a and b are same object # c = SomeMultitonClass.new(2) # c is a different object # # == How It Works # # A pool of objects is searched for a previously cached object, # if one is not found we construct one and cache it in the pool # based on class and the args given to the contructor. # # A limitation of this approach is that it is impossible to # detect if different blocks were given to a contructor (if it takes a # block). So it is the constructor arguments _only_ which determine # the uniqueness of an object. To workaround this, define the _class_ # method ::multiton_id. # # def SomeMultitonClass.multiton_id(*args, &block) # # ... # end # # Which should return a hash key used to identify the object being # constructed as (not) unique. module Multiton # Disable build-in copying methods. def clone raise TypeError, "can't clone Multiton #{self}" ##self end def dup raise TypeError, "can't dup Multiton #{self}" ##self end # Default marshalling strategy. protected def _dump(depth=-1) Marshal.dump(@multiton_initializer) end # Mutex to safely store multiton instances. class InstanceMutex < Hash #:nodoc: def initialize @global = Mutex.new end def initialized(arg) store(arg, DummyMutex) end def (DummyMutex = Object.new).synchronize yield end def default(arg) @global.synchronize{ fetch(arg){ store(arg, Mutex.new) } } end end # Multiton can be included in another module, in which case that module # effectively becomes a multiton behavior distributor too. This is why we # propogate #included to the base module by putting it in another module. # #-- # def append_features(mod) # # help out people counting on transitive mixins # unless mod.instance_of?(Class) # raise TypeError, "Inclusion of Multiton in module #{mod}" # end # super # end #++ module Inclusive private def included(base) class << base ##alias_method(:new!, :new) unless method_defined?(:new!) ## gracefully handle multiple inclusions of Multiton unless include?(Multiton::MetaMethods) alias_method :new!, :new private :allocate #, :new include Multiton::MetaMethods if method_defined?(:marshal_dump) undef_method :marshal_dump warn "warning: marshal_dump was undefined since it is incompatible with the Multiton pattern" end end end end end extend Inclusive # module MetaMethods include Inclusive def instance(*e, &b) arg = multiton_id(*e, &b) multiton_instance.fetch(arg) do multiton_mutex[arg].synchronize do multiton_instance.fetch(arg) do val = multiton_instance[arg] = new!(*e, &b) #new(*e, &b) val.instance_variable_set(:@multiton_initializer, e, &b) multiton_mutex.initialized(arg) val end end end end alias_method :new, :instance def initialized?(*e, &b) multiton_instance.key?(multiton_id(*e, &b)) end protected def multiton_instance @multiton_instance ||= Hash.new end def multiton_mutex @multiton_mutex ||= InstanceMutex.new end def reinitialize multiton_instance.clear multiton_mutex.clear end def _load(str) instance(*Marshal.load(str)) end private # Default method to to create a key to cache already constructed # instances. In the use case MultitonClass.new(e), MultiClass.new(f) # must be semantically equal if multiton_id(e).eql?(multiton_id(f)) # evaluates to true. def multiton_id(*e, &b) e end def singleton_method_added(sym) super if (sym == :marshal_dump) & singleton_methods.include?('marshal_dump') raise TypeError, "Don't use marshal_dump - rely on _dump and _load instead" end end end end =begin # TODO: Convert this into a real test and/or benchmark. if $0 == __FILE__ ### Simple marshalling test ####### class A def initialize(a,*e) @e = a end include Multiton begin def self.marshal_dump(depth = -1) end rescue => mes p mes class << self; undef marshal_dump end end end C = Class.new(A.clone) s = C.instance('a','b') raise unless Marshal.load(Marshal.dump(s)) == s ### Interdependent initialization example and threading benchmark ### class Regular_SymPlane def self.multiton_id(*e) a,b = e (a+b - 1)*(a+b )/2 + (a > b ? a : b) end def initialize(a,b) klass = self.class if a < b @l = b > 0 ? klass.instance(a,b-1) : nil @r = a > 0 ? klass.instance(a-1,b) : nil else @l = a > 0 ? klass.instance(a-1,b) : nil @r = b > 0 ? klass.instance(a,b-1) : nil end end include Multiton end def nap # Thread.pass sleep(rand(0.01)) end class SymPlane < Regular_SymPlane @m = Mutex.new @count = 0 end class << SymPlane attr_reader :count def reinitialize super @m = Mutex.new @count = 0 end def inherited(sub_class) super sub_class.instance_eval { @m = Mutex.new; @count = 0 } end def multiton_id(*e) nap() super end def new!(*e) # NOTICE!!! super ensure nap() @m.synchronize { p @count if (@count += 1) % 15 == 0 } end def run(k) threads = 0 max = k * (k+1) / 2 puts "" while count() < max Thread.new { threads+= 1; instance(rand(30),rand(30)) } end puts "\nThe simulation created #{threads} threads" end end require 'benchmark' include Benchmark bmbm do |x| x.report('Initialize 465 SymPlane instances') { SymPlane.run(30) } x.report('Reinitialize ') do sleep 3 SymPlane.reinitialize end end end =end