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# Ractor is a Actor-model abstraction for Ruby that provides thread-safe parallel execution.
#
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# Ractor.new can make a new Ractor, and it will run in parallel.
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#
# # The simplest ractor
# r = Ractor.new {puts "I am in Ractor!"}
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# r.take # wait for it to finish
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# # here "I am in Ractor!" would be printed
#
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# Ractors do not share usual objects, so the same kinds of thread-safety concerns such as data-race,
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# race-conditions are not available on multi-ractor programming.
#
# To achieve this, ractors severely limit object sharing between different ractors.
# For example, unlike threads, ractors can't access each other's objects, nor any objects through
# variables of the outer scope.
#
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# a = 1
# r = Ractor.new {puts "I am in Ractor! a=#{a}"}
# # fails immediately with
# # ArgumentError (can not isolate a Proc because it accesses outer variables (a).)
#
# On CRuby (the default implementation), Global Virtual Machine Lock (GVL) is held per ractor, so
# ractors are performed in parallel without locking each other.
#
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# Instead of accessing the shared state, the objects should be passed to and from ractors via
# sending and receiving objects as messages.
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#
# a = 1
# r = Ractor.new do
# a_in_ractor = receive # receive blocks till somebody will pass message
# puts "I am in Ractor! a=#{a_in_ractor}"
# end
# r.send(a) # pass it
# r.take
# # here "I am in Ractor! a=1" would be printed
#
# There are two pairs of methods for sending/receiving messages:
#
# * Ractor#send and Ractor.receive for when the _sender_ knows the receiver (push);
# * Ractor.yield and Ractor#take for when the _receiver_ knows the sender (pull);
#
# In addition to that, an argument to Ractor.new would be passed to block and available there
# as if received by Ractor.receive, and the last block value would be sent outside of the
# ractor as if sent by Ractor.yield.
#
# A little demonstration on a classic ping-pong:
#
# server = Ractor.new do
# puts "Server starts: #{self.inspect}"
# puts "Server sends: ping"
# Ractor.yield 'ping' # The server doesn't know the receiver and sends to whoever interested
# received = Ractor.receive # The server doesn't know the sender and receives from whoever sent
# puts "Server received: #{received}"
# end
#
# client = Ractor.new(server) do |srv| # The server is sent inside client, and available as srv
# puts "Client starts: #{self.inspect}"
# received = srv.take # The Client takes a message specifically from the server
# puts "Client received from " \
# "#{srv.inspect}: #{received}"
# puts "Client sends to " \
# "#{srv.inspect}: pong"
# srv.send 'pong' # The client sends a message specifically to the server
# end
#
# [client, server].each(&:take) # Wait till they both finish
#
# This will output:
#
# Server starts: #<Ractor:#2 test.rb:1 running>
# Server sends: ping
# Client starts: #<Ractor:#3 test.rb:8 running>
# Client received from #<Ractor:#2 rac.rb:1 blocking>: ping
# Client sends to #<Ractor:#2 rac.rb:1 blocking>: pong
# Server received: pong
#
# It is said that Ractor receives messages via the <em>incoming port</em>, and sends them
# to the <em>outgoing port</em>. Either one can be disabled with Ractor#close_incoming and
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# Ractor#close_outgoing respectively. If a ractor terminated, its ports will be closed
# automatically.
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#
# == Shareable and unshareable objects
#
# When the object is sent to and from the ractor, it is important to understand whether the
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# object is shareable or unshareable. Most of objects are unshareable objects.
#
# Shareable objects are basically those which can be used by several threads without compromising
# thread-safety; e.g. immutable ones. Ractor.shareable? allows to check this, and Ractor.make_shareable
# tries to make object shareable if it is not.
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#
# Ractor.shareable?(1) #=> true -- numbers and other immutable basic values are
# Ractor.shareable?('foo') #=> false, unless the string is frozen due to # freeze_string_literals: true
# Ractor.shareable?('foo'.freeze) #=> true
#
# ary = ['hello', 'world']
# ary.frozen? #=> false
# ary[0].frozen? #=> false
# Ractor.make_shareable(ary)
# ary.frozen? #=> true
# ary[0].frozen? #=> true
# ary[1].frozen? #=> true
#
# When a shareable object is sent (via #send or Ractor.yield), no additional processing happens,
# and it just becomes usable by both ractors. When an unshareable object is sent, it can be
# either _copied_ or _moved_. The first is the default, and it makes the object's full copy by
# deep cloning of non-shareable parts of its structure.
#
# data = ['foo', 'bar'.freeze]
# r = Ractor.new do
# data2 = Ractor.receive
# puts "In ractor: #{data2.object_id}, #{data2[0].object_id}, #{data2[1].object_id}"
# end
# r.send(data)
# r.take
# puts "Outside : #{data.object_id}, #{data[0].object_id}, #{data[1].object_id}"
#
# This will output:
#
# In ractor: 340, 360, 320
# Outside : 380, 400, 320
#
# (Note that object id of both array and non-frozen string inside array have changed inside
# the ractor, showing it is different objects. But the second array's element, which is a
# shareable frozen string, has the same object_id.)
#
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# Deep cloning of the objects may be slow, and sometimes impossible. Alternatively,
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# <tt>move: true</tt> may be used on sending. This will <em>move</em> the object to the
# receiving ractor, making it inaccessible for a sending ractor.
#
# data = ['foo', 'bar']
# r = Ractor.new do
# data_in_ractor = Ractor.receive
# puts "In ractor: #{data_in_ractor.object_id}, #{data_in_ractor[0].object_id}"
# end
# r.send(data, move: true)
# r.take
# puts "Outside: moved? #{Ractor::MovedObject === data}"
# puts "Outside: #{data.inspect}"
#
# This will output:
#
# In ractor: 100, 120
# Outside: moved? true
# test.rb:9:in `method_missing': can not send any methods to a moved object (Ractor::MovedError)
#
# Notice that even +inspect+ (and more basic methods like <tt>__id__</tt>) is inaccessible
# on a moved object.
#
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# Besides frozen objects, there are shareable objects. Class and Module objects are shareable so
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# the Class/Module definitions are shared between ractors. Ractor objects are also shareable objects.
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# All operations for the shareable mutable objects are thread-safe, so the thread-safety property
# will be kept. We can not define mutable shareable objects in Ruby, but C extensions can introduce them.
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#
# It is prohibited to access instance variables of mutable shareable objects (especially Modules and classes)
# from ractors other than main:
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#
# class C
# class << self
# attr_accessor :tricky
# end
# end
#
# C.tricky = 'test'
#
# r = Ractor.new(C) do |cls|
# puts "I see #{cls}"
# puts "I can't see #{cls.tricky}"
# end
# r.take
# # I see C
# # can not access instance variables of classes/modules from non-main Ractors (RuntimeError)
#
# Ractors can access constants if they are shareable. The main Ractor is the only one that can
# access non-shareable constants.
#
# GOOD = 'good'.freeze
# BAD = 'bad'
#
# r = Ractor.new do
# puts "GOOD=#{GOOD}"
# puts "BAD=#{BAD}"
# end
# r.take
# # GOOD=good
# # can not access non-shareable objects in constant Object::BAD by non-main Ractor. (NameError)
#
# # Consider the same C class from above
#
# r = Ractor.new do
# puts "I see #{C}"
# puts "I can't see #{C.tricky}"
# end
# r.take
# # I see C
# # can not access instance variables of classes/modules from non-main Ractors (RuntimeError)
#
# See also the description of <tt># shareable_constant_value</tt> pragma in
# {Comments syntax}[rdoc-ref:syntax/comments.rdoc] explanation.
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#
# == Ractors vs threads
#
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# Each ractor creates its own thread. New threads can be created from inside ractor
# (and, on CRuby, sharing GVL with other threads of this ractor).
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#
# r = Ractor.new do
# a = 1
# Thread.new {puts "Thread in ractor: a=#{a}"}.join
# end
# r.take
# # Here "Thread in ractor: a=1" will be printed
#
# == Note on code examples
#
# In examples below, sometimes we use the following method to wait till ractors that
# are not currently blocked will finish (or process till next blocking) method.
#
# def wait
# sleep(0.1)
# end
#
# It is **only for demonstration purposes** and shouldn't be used in a real code.
# Most of the times, just #take is used to wait till ractor will finish.
#
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# == Reference
#
# See {Ractor design doc}[rdoc-ref:ractor.md] for more details.
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#
class Ractor
#
# call-seq:
# Ractor.new(*args, name: nil) {|*args| block } -> ractor
#
# Create a new Ractor with args and a block.
#
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# A block (Proc) will be isolated (can't access to outer variables). +self+
# inside the block will refer to the current Ractor.
#
# r = Ractor.new { puts "Hi, I am #{self.inspect}" }
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# r.take
# # Prints "Hi, I am #<Ractor:#2 test.rb:1 running>"
#
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# +args+ passed to the method would be propagated to block args by the same rules as
# objects passed through #send/Ractor.receive: if +args+ are not shareable, they
# will be copied (via deep cloning, which might be inefficient).
#
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# arg = [1, 2, 3]
# puts "Passing: #{arg} (##{arg.object_id})"
# r = Ractor.new(arg) {|received_arg|
# puts "Received: #{received_arg} (##{received_arg.object_id})"
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# }
# r.take
# # Prints:
# # Passing: [1, 2, 3] (#280)
# # Received: [1, 2, 3] (#300)
#
# Ractor's +name+ can be set for debugging purposes:
#
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# r = Ractor.new(name: 'my ractor') {}
# p r
# #=> #<Ractor:#3 my ractor test.rb:1 terminated>
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#
def self.new(*args, name: nil, &block)
b = block # TODO: builtin bug
raise ArgumentError, "must be called with a block" unless block
loc = caller_locations(1, 1).first
loc = "#{loc.path}:#{loc.lineno}"
__builtin_ractor_create(loc, name, args, b)
end
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# Returns the currently executing Ractor.
#
# Ractor.current #=> #<Ractor:#1 running>
def self.current
__builtin_cexpr! %q{
rb_ractor_self(rb_ec_ractor_ptr(ec));
}
end
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# Returns total count of Ractors currently running.
#
# Ractor.count #=> 1
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# r = Ractor.new(name: 'example') { Ractor.yield(1) }
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# Ractor.count #=> 2 (main + example ractor)
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# r.take # wait for Ractor.yield(1)
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# r.take # wait till r will finish
# Ractor.count #=> 1
def self.count
__builtin_cexpr! %q{
ULONG2NUM(GET_VM()->ractor.cnt);
}
end
#
# call-seq:
# Ractor.select(*ractors, [yield_value:, move: false]) -> [ractor or symbol, obj]
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#
# Waits for the first ractor to have something in its outgoing port, reads from this ractor, and
# returns that ractor and the object received.
#
# r1 = Ractor.new {Ractor.yield 'from 1'}
# r2 = Ractor.new {Ractor.yield 'from 2'}
#
# r, obj = Ractor.select(r1, r2)
#
# puts "received #{obj.inspect} from #{r.inspect}"
# # Prints: received "from 1" from #<Ractor:#2 test.rb:1 running>
#
# If one of the given ractors is the current ractor, and it would be selected, +r+ will contain
# +:receive+ symbol instead of the ractor object.
#
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# r1 = Ractor.new(Ractor.current) do |main|
# main.send 'to main'
# Ractor.yield 'from 1'
# end
# r2 = Ractor.new do
# Ractor.yield 'from 2'
# end
#
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# r, obj = Ractor.select(r1, r2, Ractor.current)
# puts "received #{obj.inspect} from #{r.inspect}"
# # Prints: received "to main" from :receive
#
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# If +yield_value+ is provided, that value may be yielded if another Ractor is calling #take.
# In this case, the pair <tt>[:yield, nil]</tt> would be returned:
#
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# r1 = Ractor.new(Ractor.current) do |main|
# puts "Received from main: #{main.take}"
# end
#
# puts "Trying to select"
# r, obj = Ractor.select(r1, Ractor.current, yield_value: 123)
# wait
# puts "Received #{obj.inspect} from #{r.inspect}"
#
# This will print:
#
# Trying to select
# Received from main: 123
# Received nil from :yield
#
# +move+ boolean flag defines whether yielded value should be copied (default) or moved.
def self.select(*ractors, yield_value: yield_unspecified = true, move: false)
raise ArgumentError, 'specify at least one ractor or `yield_value`' if yield_unspecified && ractors.empty?
__builtin_cstmt! %q{
const VALUE *rs = RARRAY_CONST_PTR_TRANSIENT(ractors);
VALUE rv;
VALUE v = ractor_select(ec, rs, RARRAY_LENINT(ractors),
yield_unspecified == Qtrue ? Qundef : yield_value,
(bool)RTEST(move) ? true : false, &rv);
return rb_ary_new_from_args(2, rv, v);
}
end
#
# call-seq:
# Ractor.receive -> msg
#
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# Receive an incoming message from the current Ractor's incoming port's queue, which was
# sent there by #send.
#
# r = Ractor.new do
# v1 = Ractor.receive
# puts "Received: #{v1}"
# end
# r.send('message1')
# r.take
# # Here will be printed: "Received: message1"
#
# Alternatively, private instance method +receive+ may be used:
#
# r = Ractor.new do
# v1 = receive
# puts "Received: #{v1}"
# end
# r.send('message1')
# r.take
# # Here will be printed: "Received: message1"
#
# The method blocks if the queue is empty.
#
# r = Ractor.new do
# puts "Before first receive"
# v1 = Ractor.receive
# puts "Received: #{v1}"
# v2 = Ractor.receive
# puts "Received: #{v2}"
# end
# wait
# puts "Still not received"
# r.send('message1')
# wait
# puts "Still received only one"
# r.send('message2')
# r.take
#
# Output:
#
# Before first receive
# Still not received
# Received: message1
# Still received only one
# Received: message2
#
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# If close_incoming was called on the ractor, the method raises Ractor::ClosedError
# if there are no more messages in incoming queue:
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#
# Ractor.new do
# close_incoming
# receive
# end
# wait
# # in `receive': The incoming port is already closed => #<Ractor:#2 test.rb:1 running> (Ractor::ClosedError)
#
def self.receive
__builtin_cexpr! %q{
ractor_receive(ec, rb_ec_ractor_ptr(ec))
}
end
class << self
alias recv receive
end
# same as Ractor.receive
private def receive
__builtin_cexpr! %q{
ractor_receive(ec, rb_ec_ractor_ptr(ec))
}
end
alias recv receive
#
# call-seq:
# Ractor.receive_if {|msg| block } -> msg
#
# Receive only a specific message.
#
# Instead of Ractor.receive, Ractor.receive_if can provide a pattern
# by a block and you can choose the receiving message.
#
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# r = Ractor.new do
# p Ractor.receive_if{|msg| msg.match?(/foo/)} #=> "foo3"
# p Ractor.receive_if{|msg| msg.match?(/bar/)} #=> "bar1"
# p Ractor.receive_if{|msg| msg.match?(/baz/)} #=> "baz2"
# end
# r << "bar1"
# r << "baz2"
# r << "foo3"
# r.take
#
# This will output:
#
# foo3
# bar1
# baz2
#
# If the block returns a truthy value, the message will be removed from the incoming queue
# and returned.
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# Otherwise, the message remains in the incoming queue and the following received
# messages are checked by the given block.
#
# If there are no messages left in the incoming queue, the method will
# block until new messages arrive.
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#
# If the block is escaped by break/return/exception/throw, the message is removed from
# the incoming queue as if a truthy value had been returned.
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#
# r = Ractor.new do
# val = Ractor.receive_if{|msg| msg.is_a?(Array)}
# puts "Received successfully: #{val}"
# end
#
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# r.send(1)
# r.send('test')
# wait
# puts "2 non-matching sent, nothing received"
# r.send([1, 2, 3])
# wait
#
# Prints:
#
# 2 non-matching sent, nothing received
# Received successfully: [1, 2, 3]
#
# Note that you can not call receive/receive_if in the given block recursively.
# It means that you should not do any tasks in the block.
#
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# Ractor.current << true
# Ractor.receive_if{|msg| Ractor.receive}
# #=> `receive': can not call receive/receive_if recursively (Ractor::Error)
#
def self.receive_if &b
Primitive.ractor_receive_if b
end
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private def receive_if &b
Primitive.ractor_receive_if b
end
#
# call-seq:
# ractor.send(msg, move: false) -> self
#
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# Send a message to a Ractor's incoming queue to be consumed by Ractor.receive.
#
# r = Ractor.new do
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# value = Ractor.receive
# puts "Received #{value}"
# end
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# r.send 'message'
# # Prints: "Received: message"
#
# The method is non-blocking (will return immediately even if the ractor is not ready
# to receive anything):
#
# r = Ractor.new {sleep(5)}
# r.send('test')
# puts "Sent successfully"
# # Prints: "Sent successfully" immediately
#
# Attempt to send to ractor which already finished its execution will raise Ractor::ClosedError.
#
# r = Ractor.new {}
# r.take
# p r
# # "#<Ractor:#6 (irb):23 terminated>"
# r.send('test')
# # Ractor::ClosedError (The incoming-port is already closed)
#
# If close_incoming was called on the ractor, the method also raises Ractor::ClosedError.
#
# r = Ractor.new do
# sleep(500)
# receive
# end
# r.close_incoming
# r.send('test')
# # Ractor::ClosedError (The incoming-port is already closed)
# # The error would be raised immediately, not when ractor will try to receive
#
# If the +obj+ is unshareable, by default it would be copied into ractor by deep cloning.
# If the <tt>move: true</tt> is passed, object is _moved_ into ractor and becomes
# inaccessible to sender.
#
# r = Ractor.new {puts "Received: #{receive}"}
# msg = 'message'
# r.send(msg, move: true)
# r.take
# p msg
#
# This prints:
#
# Received: message
# in `p': undefined method `inspect' for #<Ractor::MovedObject:0x000055c99b9b69b8>
#
# All references to the object and its parts will become invalid in sender.
#
# r = Ractor.new {puts "Received: #{receive}"}
# s = 'message'
# ary = [s]
# copy = ary.dup
# r.send(ary, move: true)
#
# s.inspect
# # Ractor::MovedError (can not send any methods to a moved object)
# ary.class
# # Ractor::MovedError (can not send any methods to a moved object)
# copy.class
# # => Array, it is different object
# copy[0].inspect
# # Ractor::MovedError (can not send any methods to a moved object)
# # ...but its item was still a reference to `s`, which was moved
#
# If the object was shareable, <tt>move: true</tt> has no effect on it:
#
# r = Ractor.new {puts "Received: #{receive}"}
# s = 'message'.freeze
# r.send(s, move: true)
# s.inspect #=> "message", still available
#
def send(obj, move: false)
__builtin_cexpr! %q{
ractor_send(ec, RACTOR_PTR(self), obj, move)
}
end
alias << send
#
# call-seq:
# Ractor.yield(msg, move: false) -> nil
#
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# Send a message to the current ractor's outgoing port to be consumed by #take.
#
# r = Ractor.new {Ractor.yield 'Hello from ractor'}
# puts r.take
# # Prints: "Hello from ractor"
#
# The method is blocking, and will return only when somebody consumes the
# sent message.
#
# r = Ractor.new do
# Ractor.yield 'Hello from ractor'
# puts "Ractor: after yield"
# end
# wait
# puts "Still not taken"
# puts r.take
#
# This will print:
#
# Still not taken
# Hello from ractor
# Ractor: after yield
#
# If the outgoing port was closed with #close_outgoing, the method will raise:
#
# r = Ractor.new do
# close_outgoing
# Ractor.yield 'Hello from ractor'
# end
# wait
# # `yield': The outgoing-port is already closed (Ractor::ClosedError)
#
# The meaning of +move+ argument is the same as for #send.
def self.yield(obj, move: false)
__builtin_cexpr! %q{
ractor_yield(ec, rb_ec_ractor_ptr(ec), obj, move)
}
end
#
# call-seq:
# ractor.take -> msg
#
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# Take a message from ractor's outgoing port, which was put there by Ractor.yield or at ractor's
# finalization.
#
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# r = Ractor.new do
# Ractor.yield 'explicit yield'
# 'last value'
# end
# puts r.take #=> 'explicit yield'
# puts r.take #=> 'last value'
# puts r.take # Ractor::ClosedError (The outgoing-port is already closed)
#
# The fact that the last value is also put to outgoing port means that +take+ can be used
# as some analog of Thread#join ("just wait till ractor finishes"), but don't forget it
# will raise if somebody had already consumed everything ractor have produced.
#
# If the outgoing port was closed with #close_outgoing, the method will raise Ractor::ClosedError.
#
# r = Ractor.new do
# sleep(500)
# Ractor.yield 'Hello from ractor'
# end
# r.close_outgoing
# r.take
# # Ractor::ClosedError (The outgoing-port is already closed)
# # The error would be raised immediately, not when ractor will try to receive
#
# If an uncaught exception is raised in the Ractor, it is propagated on take as a
# Ractor::RemoteError.
#
# r = Ractor.new {raise "Something weird happened"}
#
# begin
# r.take
# rescue => e
# p e # => #<Ractor::RemoteError: thrown by remote Ractor.>
# p e.ractor == r # => true
# p e.cause # => #<RuntimeError: Something weird happened>
# end
#
# Ractor::ClosedError is a descendant of StopIteration, so the closing of the ractor will break
# the loops without propagating the error:
#
# r = Ractor.new do
# 3.times {|i| Ractor.yield "message #{i}"}
# "finishing"
# end
#
# loop {puts "Received: " + r.take}
# puts "Continue successfully"
#
# This will print:
#
# Received: message 0
# Received: message 1
# Received: message 2
# Received: finishing
# Continue successfully
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def take
__builtin_cexpr! %q{
ractor_take(ec, RACTOR_PTR(self))
}
end
def inspect
loc = __builtin_cexpr! %q{ RACTOR_PTR(self)->loc }
name = __builtin_cexpr! %q{ RACTOR_PTR(self)->name }
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id = __builtin_cexpr! %q{ UINT2NUM(rb_ractor_id(RACTOR_PTR(self))) }
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status = __builtin_cexpr! %q{
rb_str_new2(ractor_status_str(RACTOR_PTR(self)->status_))
}
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"#<Ractor:##{id}#{name ? ' '+name : ''}#{loc ? " " + loc : ''} #{status}>"
end
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alias to_s inspect
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# The name set in Ractor.new, or +nil+.
def name
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__builtin_cexpr! %q{RACTOR_PTR(self)->name}
end
class RemoteError
attr_reader :ractor
end
#
# call-seq:
# ractor.close_incoming -> true | false
#
# Closes the incoming port and returns its previous state.
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# All further attempts to Ractor.receive in the ractor, and #send to the ractor
# will fail with Ractor::ClosedError.
#
# r = Ractor.new {sleep(500)}
# r.close_incoming #=> false
# r.close_incoming #=> true
# r.send('test')
# # Ractor::ClosedError (The incoming-port is already closed)
def close_incoming
__builtin_cexpr! %q{
ractor_close_incoming(ec, RACTOR_PTR(self));
}
end
#
# call-seq:
# ractor.close_outgoing -> true | false
#
# Closes the outgoing port and returns its previous state.
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# All further attempts to Ractor.yield in the ractor, and #take from the ractor
# will fail with Ractor::ClosedError.
#
# r = Ractor.new {sleep(500)}
# r.close_outgoing #=> false
# r.close_outgoing #=> true
# r.take
# # Ractor::ClosedError (The outgoing-port is already closed)
def close_outgoing
__builtin_cexpr! %q{
ractor_close_outgoing(ec, RACTOR_PTR(self));
}
end
#
# call-seq:
# Ractor.shareable?(obj) -> true | false
#
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# Checks if the object is shareable by ractors.
#
# Ractor.shareable?(1) #=> true -- numbers and other immutable basic values are frozen
# Ractor.shareable?('foo') #=> false, unless the string is frozen due to # freeze_string_literals: true
# Ractor.shareable?('foo'.freeze) #=> true
#
# See also the "Shareable and unshareable objects" section in the Ractor class docs.
def self.shareable? obj
__builtin_cexpr! %q{
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RBOOL(rb_ractor_shareable_p(obj));
}
end
#
# call-seq:
# Ractor.make_shareable(obj, copy: false) -> shareable_obj
#
# Make +obj+ shareable between ractors.
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#
# +obj+ and all the objects it refers to will be frozen, unless they are
# already shareable.
#
# If +copy+ keyword is +true+, the method will copy objects before freezing them
# This is safer option but it can take be slower.
#
# Note that the specification and implementation of this method are not
# mature and may be changed in the future.
#
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# obj = ['test']
# Ractor.shareable?(obj) #=> false
# Ractor.make_shareable(obj) #=> ["test"]
# Ractor.shareable?(obj) #=> true
# obj.frozen? #=> true
# obj[0].frozen? #=> true
#
# # Copy vs non-copy versions:
# obj1 = ['test']
# obj1s = Ractor.make_shareable(obj1)
# obj1.frozen? #=> true
# obj1s.object_id == obj1.object_id #=> true
# obj2 = ['test']
# obj2s = Ractor.make_shareable(obj2, copy: true)
# obj2.frozen? #=> false
# obj2s.frozen? #=> true
# obj2s.object_id == obj2.object_id #=> false
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# obj2s[0].object_id == obj2[0].object_id #=> false
#
# See also the "Shareable and unshareable objects" section in the Ractor class docs.
def self.make_shareable obj, copy: false
if copy
__builtin_cexpr! %q{
rb_ractor_make_shareable_copy(obj);
}
else
__builtin_cexpr! %q{
rb_ractor_make_shareable(obj);
}
end
end
# get a value from ractor-local storage
def [](sym)
Primitive.ractor_local_value(sym)
end
# set a value in ractor-local storage
def []=(sym, val)
Primitive.ractor_local_value_set(sym, val)
end
# returns main ractor
def self.main
__builtin_cexpr! %q{
rb_ractor_self(GET_VM()->ractor.main_ractor);
}
end
end