Ractor.new creates a new Ractor, which can run in parallel with other ractors.
# The simplest ractor r = Ractor.new {puts "I am in Ractor!"} r.join # wait for it to finish # Here, "I am in Ractor!" is printed
Ractors do not share all objects with each other. There are two main benefits to this: across ractors, thread-safety concerns such as data-races and race-conditions are not possible. The other benefit is parallelism.
To achieve this, object sharing is limited across ractors. Unlike in threads, ractors can’t access all the objects available in other ractors. For example, objects normally available through variables in the outer scope are prohibited from being used across ractors.
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).)
The object must be explicitly shared:
a = 1 r = Ractor.new(a) { |a1| puts "I am in Ractor! a=#{a1}"}
On CRuby (the default implementation), the Global Virtual Machine Lock (GVL) is held per ractor, so ractors can run in parallel. This is unlike the situation with threads on CRuby.
Instead of accessing shared state, objects should be passed to and from ractors by sending and receiving them as messages.
a = 1 r = Ractor.new do a_in_ractor = receive # receive blocks the Thread until our default port gets sent a message puts "I am in Ractor! a=#{a_in_ractor}" end r.send(a) # pass it r.join # Here, "I am in Ractor! a=1" is printed
In addition to that, any arguments passed to Ractor.new are passed to the block and available there as if received by Ractor.receive, and the last block value can be received with Ractor#value.
Shareable and unshareable objects
When an object is sent to a ractor, it’s important to understand whether the object is shareable or unshareable. Most Ruby objects are unshareable objects. Even frozen objects can be unshareable if they contain (through their instance variables) unfrozen objects.
Shareable objects are those which can be used by several ractors at once without compromising thread-safety, for example numbers, true and false. Ractor.shareable? allows you to check this, and Ractor.make_shareable tries to make the object shareable if it’s not already and gives an error if it can’t do it.
Ractor.shareable?(1) #=> true -- numbers and other immutable basic values are shareable Ractor.shareable?('foo') #=> false, unless the string is frozen due to # frozen_string_literal: true Ractor.shareable?('foo'.freeze) #=> true Ractor.shareable?([Object.new].freeze) #=> false, inner object is unfrozen 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, no additional processing occurs on it and it becomes usable by both ractors. When an unshareable object is sent, it can be either copied or moved. Copying is the default, and it copies the object fully by deep cloning (Object#clone) the non-shareable parts of its structure.
data = ['foo'.dup, '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.join puts "Outside : #{data.object_id}, #{data[0].object_id}, #{data[1].object_id}"
This will output something like:
In ractor: 8, 16, 24 Outside : 32, 40, 24
Note that the object ids of the array and the non-frozen string inside the array have changed in the ractor because they are different objects. The second array’s element, which is a shareable frozen string, is the same object.
Deep cloning of objects may be slow, and sometimes impossible. Alternatively, move: true may be used during sending. This will move the unshareable object to the receiving ractor, making it inaccessible to the 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.join 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 __id__ are inaccessible on a moved object.
Class and Module objects are shareable and their class/module definitions are shared between ractors. Ractor objects are also shareable. All operations on shareable objects are thread-safe across ractors. Defining mutable, shareable objects in Ruby is not possible, but C extensions can introduce them.
It is prohibited to access (get) instance variables of shareable objects in other ractors if the values of the variables aren’t shareable. This can occur because modules/classes are shareable, but they can have instance variables whose values are not. In non-main ractors, it’s also prohibited to set instance variables on classes/modules (even if the value is shareable).
class C class << self attr_accessor :tricky end end C.tricky = "unshareable".dup r = Ractor.new(C) do |cls| puts "I see #{cls}" puts "I can't see #{cls.tricky}" cls.tricky = true # doesn't get here, but this would also raise an error end r.join # 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'.dup r = Ractor.new do puts "GOOD=#{GOOD}" puts "BAD=#{BAD}" end r.join # 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.join # I see C # can not access instance variables of classes/modules from non-main Ractors (RuntimeError)
See also the description of # shareable_constant_value pragma in Comments syntax explanation.
Ractors vs threads
Each ractor has its own main Thread. New threads can be created from inside ractors (and, on CRuby, they share the GVL with other threads of this ractor).
r = Ractor.new do a = 1 Thread.new {puts "Thread in ractor: a=#{a}"}.join end r.join # Here "Thread in ractor: a=1" will be printed
Note on code examples
In the examples below, sometimes we use the following method to wait for ractors to make progress or finish.
def wait sleep(0.1) end
This is **only for demonstration purposes** and shouldn’t be used in a real code. Most of the time, join is used to wait for ractors to finish and Ractor.receive is used to wait for messages.
Reference
See Ractor design doc for more details.
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 490
def self.[](sym)
Primitive.ractor_local_value(sym)
end
Gets a value from ractor-local storage for the current Ractor.
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 495
def self.[]=(sym, val)
Primitive.ractor_local_value_set(sym, val)
end
Sets a value in ractor-local storage for the current Ractor.
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 258
def self.count
__builtin_cexpr! %q{
ULONG2NUM(GET_VM()->ractor.cnt);
}
end
Returns the number of ractors currently running or blocking (waiting).
Ractor.count #=> 1 r = Ractor.new(name: 'example') { Ractor.receive } Ractor.count #=> 2 (main + example ractor) r << 42 # r's Ractor.receive will resume r.join # wait for r's termination Ractor.count #=> 1
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 244
def self.current
__builtin_cexpr! %q{
rb_ractor_self(rb_ec_ractor_ptr(ec));
}
end
Returns the currently executing Ractor.
Ractor.current #=> #<Ractor:#1 running>
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 519
def self.main
__builtin_cexpr! %q{
rb_ractor_self(GET_VM()->ractor.main_ractor);
}
end
Returns the main ractor.
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 526
def self.main?
__builtin_cexpr! %q{
RBOOL(GET_VM()->ractor.main_ractor == rb_ec_ractor_ptr(ec))
}
end
Returns true if the current ractor is the main ractor.
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 459
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
Makes obj shareable between ractors.
obj and all the objects it refers to will be frozen, unless they are already shareable.
If copy keyword is true, it will copy objects before freezing them, and will not modify obj or its internal objects.
Note that the specification and implementation of this method are not mature and may be changed in the future.
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 obj2s[0].object_id == obj2[0].object_id #=> false
See also the “Shareable and unshareable objects” section in the Ractor class docs.
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 229
def self.new(*args, name: nil, &block)
b = block # TODO: builtin bug
raise ArgumentError, "must be called with a block" unless block
if __builtin_cexpr!("RBOOL(ruby_single_main_ractor)")
Kernel.warn("Ractor API is experimental and may change in future versions of Ruby.",
uplevel: 0, category: :experimental)
end
loc = caller_locations(1, 1).first
loc = "#{loc.path}:#{loc.lineno}"
__builtin_ractor_create(loc, name, args, b)
end
Creates a new Ractor with args and a block.
The given block (Proc) is isolated (can’t access any outer variables). self inside the block will refer to the current Ractor.
r = Ractor.new { puts "Hi, I am #{self.inspect}" } r.join # Prints "Hi, I am #<Ractor:#2 test.rb:1 running>"
Any args passed are propagated to the block arguments by the same rules as objects sent via send/Ractor.receive. If an argument in args is not shareable, it will be copied (via deep cloning, which might be inefficient).
arg = [1, 2, 3] puts "Passing: #{arg} (##{arg.object_id})" r = Ractor.new(arg) {|received_arg| puts "Received: #{received_arg} (##{received_arg.object_id})" } r.join # Prints: # Passing: [1, 2, 3] (#280) # Received: [1, 2, 3] (#300)
Ractor’s name can be set for debugging purposes:
r = Ractor.new(name: 'my ractor') {}; r.join p r #=> #<Ractor:#3 my ractor test.rb:1 terminated>
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 349
def self.receive
Ractor.current.default_port.receive
end
Receives a message from the current ractor’s default port.
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 308
def self.select(*ports)
raise ArgumentError, 'specify at least one Ractor::Port or Ractor' if ports.empty?
monitors = {} # Ractor::Port => Ractor
ports = ports.map do |arg|
case arg
when Ractor
port = Ractor::Port.new
monitors[port] = arg
arg.monitor port
port
when Ractor::Port
arg
else
raise ArgumentError, "should be Ractor::Port or Ractor"
end
end
begin
result_port, obj = __builtin_ractor_select_internal(ports)
if r = monitors[result_port]
[r, r.value]
else
[result_port, obj]
end
ensure
# close all ports for join
monitors.each do |port, r|
r.unmonitor port
port.close
end
end
end
Blocks the current Thread until one of the given ports has received a message. Returns an array of two elements where the first element is the Port and the second is the received object. This method can also accept Ractor objects themselves, and in that case will wait until one has terminated and return a two-element array where the first element is the ractor and the second is its termination value.
p1, p2 = Ractor::Port.new, Ractor::Port.new ps = [p1, p2] rs = 2.times.map do |i| Ractor.new(ps.shift, i) do |p, i| sleep rand(0.99) p.send("r#{i}") sleep rand(0.99) "r#{i} done" end end waiting_on = [p1, p2, *rs] until waiting_on.empty? received_on, obj = Ractor.select(*waiting_on) waiting_on.delete(received_on) puts obj end # r0 # r1 # r1 done # r0 done
The following example is almost equivalent to ractors.map(&:value) except the thread is unblocked when any of the ractors has terminated as opposed to waiting for their termination in the array element order.
values = [] until ractors.empty? r, val = Ractor.select(*ractors) ractors.delete(r) values << val end
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 418
def self.shareable? obj
__builtin_cexpr! %q{
RBOOL(rb_ractor_shareable_p(obj));
}
end
Checks if the object is shareable by ractors.
Ractor.shareable?(1) #=> true -- numbers are shareable Ractor.shareable?('foo') #=> false, unless the string is frozen due to # frozen_string_literal: true Ractor.shareable?('foo'.freeze) #=> true
See also the “Shareable and unshareable objects” section in the Ractor class docs.
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 681
def self.shareable_lambda self: nil
Primitive.attr! :use_block
__builtin_cexpr!(%Q{
ractor_shareable_proc(ec, *LOCAL_PTR(self), true)
})
end
Same as Ractor.shareable_proc, but returns a lambda Proc.
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 667
def self.shareable_proc self: nil
Primitive.attr! :use_block
__builtin_cexpr!(%Q{
ractor_shareable_proc(ec, *LOCAL_PTR(self), false)
})
end
Returns a shareable copy of the given block’s Proc. The value of self in the Proc will be replaced with the value passed via the ‘self:` keyword, or nil if not given.
In a shareable Proc, access to any outer variables if prohibited.
a = 42 Ractor.shareable_proc{ p a } #=> can not isolate a Proc because it accesses outer variables (a). (ArgumentError)
The value of ‘self` in the Proc must be a shareable object.
Ractor.shareable_proc(self: self){} #=> self should be shareable: main (Ractor::IsolationError)
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 513
def self.store_if_absent(sym)
Primitive.attr! :use_block
Primitive.ractor_local_value_store_if_absent(sym)
end
If the corresponding ractor-local value is not set, yields a value with init_block and stores the value in a thread-safe manner. This method returns the stored value.
(1..10).map{ Thread.new(it){|i| Ractor.store_if_absent(:s){ f(); i } #=> return stored value of key :s } }.map(&:value).uniq.size #=> 1 and f() is called only once
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 473
def [](sym)
if (self != Ractor.current)
raise RuntimeError, "Cannot get ractor local storage for non-current ractor"
end
Primitive.ractor_local_value(sym)
end
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 482
def []=(sym, val)
if (self != Ractor.current)
raise RuntimeError, "Cannot set ractor local storage for non-current ractor"
end
Primitive.ractor_local_value_set(sym, val)
end
Sets a value in ractor-local storage for the current Ractor. Obsolete, use Ractor.[]= instead.
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 403
def close
default_port.close
end
Closes the default port. Closing a port is allowed only by the ractor which created the port. Therefore, the receiver must be the current ractor.
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 566
def default_port
__builtin_cexpr! %q{
ractor_default_port_value(RACTOR_PTR(self))
}
end
Returns the default port of the Ractor.
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 374
def inspect
loc = __builtin_cexpr! %q{ RACTOR_PTR(self)->loc }
name = __builtin_cexpr! %q{ RACTOR_PTR(self)->name }
id = __builtin_cexpr! %q{ UINT2NUM(rb_ractor_id(RACTOR_PTR(self))) }
status = __builtin_cexpr! %q{
rb_str_new2(ractor_status_str(RACTOR_PTR(self)->status_))
}
"#<Ractor:##{id}#{name ? ' '+name : ''}#{loc ? " " + loc : ''} #{status}>"
end
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 585
def join
port = Port.new
self.monitor port
if port.receive == :aborted
__builtin_ractor_value
end
self
ensure
port.close
end
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 634
def monitor port
__builtin_ractor_monitor(port)
end
Registers the port as a monitoring port for this ractor. When the ractor terminates, the port receives a Symbol object.
-
:exitedis sent if the ractor terminates without an unhandled exception. -
:abortedis sent if the ractor terminates by an unhandled exception.r = Ractor.new{ some_task() } r.monitor(port = Ractor::Port.new) port.receive #=> :exited and r is terminated r = Ractor.new{ raise "foo" } r.monitor(port = Ractor::Port.new) port.receive #=> :aborted and r is terminated by the RuntimeError "foo"
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 387
def name
__builtin_cexpr! %q{RACTOR_PTR(self)->name}
end
Returns the name set in Ractor.new, or nil.
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 358
def receive
default_port.receive
end
same as Ractor.receive
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 368
def send(...)
default_port.send(...)
self
end
This is equivalent to Port#send to the ractor’s default_port.
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 644
def unmonitor port
__builtin_ractor_unmonitor(port)
end
Unregisters the port from the monitoring ports for this ractor.
# File tmp/rubies/ruby-4.0.0/ractor.rb, line 611
def value
self.join
__builtin_ractor_value
end
Waits for ractor to complete and returns its value or raises the exception which terminated the Ractor. The termination value will be moved to the calling Ractor. Therefore, at most 1 Ractor can receive another ractor’s termination value.
r = Ractor.new{ [1, 2] } r.value #=> [1, 2] (unshareable object) Ractor.new(r){|r| r.value} #=> Ractor::Error