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Actors based concurrency library for Ruby.
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 Dependencies

Development

~> 1.10
~> 10.0

Runtime

~> 0.6.1
 Project Readme

Tribe Build Status Coverage Status

Tribe is a Ruby gem that implements the actor model in an event-driven way.

Tribe focuses on high performance, low latency, a simple API, and flexibility. It's goal is to support at least one million actors running on a small group of threads. It is built on top of the Workers gem.

Contents

  • Installation
  • Actors
    • Root
    • Handlers
  • Messages
  • Registries
  • Futures
    • Non-blocking
    • Blocking
    • Timeouts
    • Performance
  • Forwarding
  • Timers
  • Linking
  • Supervisors
  • Blocking code
  • Debugging
  • Benchmarks
  • Ruby's main thread
  • Contributing

Installation

Add this line to your application's Gemfile:

gem 'tribe'

And then execute:

$ bundle

Or install it yourself as:

$ gem install tribe

Actors

Actors are the building blocks of your application. There are three ways to create an actor class:

  • Inherit from Tribe::Actor (uses the shared thread pool).
  • Inherit from Tribe::DedicatedActor (uses a dedicated thread).
  • Mixin Tribe::Actable and call the init_actable in your constructor.

Root

A well designed application organizes its actors in a tree like structure. To encourage this, Tribe has a special built-in actor known as the root actor. You should use the root actor to spawn all of your application specific actors.

class MyActor < Tribe::Actor
  private
  # Your code goes here.
end

Tribe.root.spawn!(MyActor)

Command Handlers

Command handlers are how you customize your actors. They are private methods that are prefixed with "on_" and they define the commands your actor knows how to handle. They accept one argument, an instance of Tribe::Event that shouuld always be named event.

A few command handlers are built into every actor to handle system specific events. They are:

  • on_initialize: This handler takes the place of Ruby's initialize. It is the first event processsed by all actors.
  • on_exception: This handler will be called whenever an exception occurs. You can access the exception through event.data in case you want to print it, log it, etc. An exception inside of an actor will result in that actor's death.
  • on_shutdown: This handler will be called whenever an actor is asked to shutdown cleanly.
  • on_child_died: This handler gives an actor a chance to spawn a replacement child. You can access a reference to the child through event.data. If the actor is a supervisor, it will continue to live otherwise it will die too.
  • on_child_shutdown: This handler is similar to on_child_died, but for when a child is shutdown cleanly.
  • on_parent_died: This handler is also similar to on_child_died except for the parent actor. Child actors die when their parent dies.

You should never call the built in command handlers yourself. They are reserved for the actor system and calling them yourself could result in unexpected behavior.

Messages

Messages are the most basic type of communication. They are sent using using two methods:

  • message!: This method is used to tell one actor to send another actor a message. A reference to the source actor is included in the message in case the destination actor wants to respond. Usually it is used when your actor code wants to message another actor.
  • direct_message!: This method is used to directly message an actor. Usually it is used when non-actor code wants to message an actor. No source actor is associated with the message.

Since messages are fire-and-forget, both of the above methods always return nil.

Messages can include data that you want to pass between actors. It is best practice to treat data as owned by only one actor at a time. By doing this, you prevent race conditions and the need to create locks for your data.

# Create your custom actor class.
class MyActor < Tribe::Actor
  private
  def on_my_custom(event)
    puts "Received a custom event (#{event.inspect})."
  end

  def on_shutdown(event)
    puts "MyActor (#{identifier}) is shutting down."
  end
end

# Create some named actors that are children of the root actor.
100.times do |i|
  Tribe.root.spawn!(MyActor, :name => "my_actor_#{i}")
end

# Send an event to each actor.
100.times do |i|
  actor = Tribe.registry["my_actor_#{i}"]
  actor.direct_message!(:my_custom, 'hello world')
end

# Shutdown the actors.
100.times do |i|
  actor = Tribe.registry["my_actor_#{i}"]
  actor.shutdown!
end

Registries

Registries hold references to named actors so that you can easily find them. You don't have to create your own since there is a global one called Tribe.registry. The Root actor is named 'root' and stored in the default registry.

actor = Tribe.root.spawn!(Tribe::Actor, :name => 'some_actor')

if actor == Tribe.registry['some_actor']
  puts 'Successfully found some_actor in the registry.'
end

Futures

Messages are limited in that they are one way (fire-and-forget). Many times you'll be interested in receiving a response and this is when futures become useful. To send a future you use future! instead of message!. It will return a Future object (instead of nil) that will give you access to the result when it becomes available.

Non-blocking API

Non-blocking futures are asynchronous and use callbacks. No waiting for a result is involved and the actor will continue to process other events.

class ActorA < Tribe::Actor
  private
  def on_start(event)
    friend = registry['actor_b']
    future = future!(friend, :compute, 10)

    future.success do |result|
      puts "ActorA (#{identifier}) future result: #{result}"
    end
  end

  def on_shutdown(event)
    puts "MyActor (#{identifier}) is shutting down."
  end
end

class ActorB < Tribe::Actor
  private
  def on_shutdown(event)
    puts "MyActor (#{identifier}) is shutting down."
  end
  def on_compute(event)
    return factorial(event.data)
  end

  def factorial(num)
    return 1 if num <= 0
    return num * factorial(num - 1)
  end
end

actor_a = Tribe.root.spawn!(ActorA, :name => 'actor_a')
actor_b = Tribe.root.spawn!(ActorB, :name => 'actor_b')

actor_a.direct_message!(:start)

# Shutdown the actors.
sleep(3)
actor_a.shutdown!
actor_b.shutdown!

Blocking API

Blocking futures are synchronous. The actor won't process any other events until the future has a result.

class ActorA < Tribe::Actor
  private
  def on_start(event)
    friend = registry['actor_b']
    future = future!(friend, :compute, 10)

    wait!(future) # The current thread will sleep until a result is available.

    if future.success?
      puts "ActorA (#{identifier}) future result: #{future.result}"
    else
      puts "ActorA (#{identifier}) future failure: #{future.result}"
    end
  end
end

class ActorB < Tribe::Actor
  private
  def on_compute(event)
    return factorial(event.data)
  end

  def factorial(num)
    return 1 if num <= 0
    return num * factorial(num - 1)
  end
end

actor_a = Tribe.root.spawn!(ActorA, :name => 'actor_a')
actor_b = Tribe.root.spawn!(ActorB, :name => 'actor_b')

actor_a.direct_message!(:start)

sleep(3)

actor_a.shutdown!
actor_b.shutdown!

Timeouts

Futures can be confgured to timeout after a specified number of seconds. When a timeout occurs, the result of the future will be a Tribe::FutureTimeout exception.

class ActorA < Tribe::Actor
  private
  def on_start(event)
    friend = registry['actor_b']
    future = future!(friend, :compute, 10)
    future.timeout = 2

    wait!(future) # The current thread will sleep until a result is available.

    if future.success?
      puts "ActorA (#{identifier}) future result: #{future.result}"
    else
      puts "ActorA (#{identifier}) future failure: #{future.result}"
    end
  end
end

class ActorB < Tribe::Actor
  private
  def on_compute(event)
    sleep(4) # Force a timeout.
    return event.data * 2
  end
end

actor_a = Tribe.root.spawn!(ActorA, :name => 'actor_a')
actor_b = Tribe.root.spawn!(ActorB, :name => 'actor_b')

actor_a.direct_message!(:start)

sleep(6)

actor_a.shutdown!
actor_b.shutdown!

Performance Summary

Below you will find a summary of performance recommendations for futures:

  • Use message! unless you really need future! since futures have overhead.
  • If you use future!, prefer the non-blocking API over the blocking one.
  • If you use future! with the blocking API, the actor calling wait! will create a temporary thread. Since threads are a a finite resource, you should be careful to not create more of them than your operating system can simultaneously support. There is no such concern with the non-blocking API.

Forwarding

Messages and futures can be forwarded to other actors. This lets you build routers that delegate work to other actors.

# Create your router class.
class MyRouter < Tribe::Actor
  private
  def on_initialize(event)
    @processors = 100.times.map { spawn!(MyProcessor) }
  end

  def on_process(event)
    forward!(@processors[rand(100)])
  end
end

# Create your processor class.
class MyProcessor < Tribe::Actor
  private
  def on_process(event)
    puts "MyProcessor (#{identifier}) received a process event (#{event.inspect})."
  end
end

# Create the router.
router = Tribe.root.spawn!(MyRouter, :name => 'router')

# Send an event to the router and it will forward it to a random processor.
100.times do |i|
  router.direct_message!(:process, i)
end

# Shutdown the router.
sleep(3)
router.shutdown!

Timers

Actors can create timers to perform some work in the future. Both one-shot and periodic timers are provided.

class MyActor < Tribe::Actor
  private
  def on_initialize(event)
    timer!(1, :timer, 'hello once')
    periodic_timer!(1, :periodic_timer, 'hello many times')
  end

  def on_timer(event)
    puts "MyActor (#{identifier}) ONE-SHOT: #{event.data}"
  end

  def on_periodic_timer(event)
    puts "MyActor (#{identifier}) PERIODIC: #{event.data}"
  end
end

# Create some named actors.
10.times do |i|
  Tribe.root.spawn!(MyActor, :name => "my_actor_#{i}")
end

# Sleep in order to observe the timers.
sleep(10)

# Shutdown the actors.
10.times do |i|
  actor = Tribe.registry["my_actor_#{i}"]
  actor.shutdown!
end

Linking

Linking allows actors to group together so that they all live or die together. Such linking is useful for breaking up complex problems into multiple smaller units. To create a linked actor you use the spawn! method. By default, if a linked actor dies, it will cause its parent and children to die too. You an override this behavior by using supervisors.

# Create some linked actors.
top = Tribe::Actor.new
middle = top.spawn!(Tribe::Actor)
bottom = middle.spawn!(Tribe::Actor)

# Force an exception on the middle actor (it has a parent and a child).
middle.perform! { raise 'uh oh' }

# Wait.
sleep(3)

# All actors died together.
puts "Top: #{top.alive?}: #{top.exception.class}"
puts "Middle: #{middle.alive?}: #{middle.exception.class}"
puts "Bottom: #{bottom.alive?}: #{bottom.exception.class}"

Supervisors

A failure in a linked actor will cause all associated actors (parent and children) to die. Supervisors can be used to block the failure from propogating. You then have the option to re-spawn the failed actor. They are created by passing {:supervise => true} as a third argument to spawn!. You can then detect dead children by overriding on_child_died.

# Create some linked actors.
top = Tribe::Actor.new
middle = top.spawn!(Tribe::Actor, {}, {:supervise => true})
bottom = middle.spawn!(Tribe::Actor)

# Force an exception on the middle actor (it has a parent and a child).
middle.perform! { raise 'uh oh' }

# Wait.
sleep(3)

# Top actor lives because it's a supervisor.  The other two die.
puts "Top: #{top.alive?}: #{top.exception.class}"
puts "Middle: #{middle.alive?}: #{middle.exception.class}"
puts "Bottom: #{bottom.alive?}: #{bottom.exception.class}"

Logging exceptions

It is common practice to log actor exceptions or print them to stdout. This is easily accomplished with the on_exception handler in a base class:

class MyBaseActor < Tribe::Actor
  private
  def on_exception(event)
    e = event.data[:exception]
    puts "#{e.class.name}: #{e.message}:\n#{e.backtrace.join("\n")}"
  end
end

class CustomActor < MyBaseActor
end

actor = Tribe.root.spawn!(CustomActor)
actor.perform! { raise 'goodbye' }

Note that you should be careful to make sure on_exception never raises an exception itself. If it does, this second exception will be ignored. Thus it is best to limit the use of on_exception to logging exceptions in a common base class.

Blocking code

Occassionally you will have a need to execute blocking code in one of your actors. The most common cases of blocking code are network IO, disk IO, database queries, and the sleep function.

Actors have a convenient method named blocking! that you should use to wrap such code. Under the hood this method is expanding and contracting the thread pool to compensate for the blocked thread. This will prevent thread pool starvation.

The blocking! method is designed to work with dedicated and non-dedicated actors. By using this method in all of your actors, you will make it easy to convert between the two types.

An actor's wait! method (used with futures) already calls blocking! for you.

If for some reason Ruby can't create a new thread, Ruby will raise a ThreadError and your actor will die. Most modern operating systems can support many thousands of simultanous threads so refer to your operating system documentation as you may need to increase the limits.

To support in the tens of thousands, hundreds of thousands, or potentially millions of actors, you will need to use non-blocking actors.

class MyActor < Tribe::Actor
  private
  def on_start(event)
    blocking! do
      sleep 6
    end
  end

end

# Print the default pool size.
puts "Pool size (before): #{Workers.pool.size}"

# Spawn some actors that go to sleep for a bit.
100.times do
  actor = Tribe.root.spawn!(MyActor)
  actor.direct_message!(:start)
end

# Wait for all of the actors to sleep.
sleep(2)

# The pool size is increased by 100 threads.
puts "Pool size (during): #{Workers.pool.size}"

# Wait for all of the actors to stop sleeping.
sleep(10)

# The pool size is back to the default size.
puts "Pool size (after): #{Workers.pool.size}"

Logging

Tribe provides a shared instance of Logger for your convenience:

Tribe.logger

Every actor also has access to it through the logger convenience method. This local instance of the logger is wrapped in a proxy for your convenience. This way your code can assume the logger exists even if Tribe.logger is set to nil.

class MyActor < Tribe::Actor
  private
  def on_initialize(event)
    logger.debug("hello world.")
  end
end

actor = MyActor.new
actor.perform! { raise 'uh oh' }

By default, the logger will log to STDOUT. You should change this to a file in your application.

Debugging

Tribe is written in pure Ruby so it will work with all existing debuggers that support Ruby & threads. Byebug is commonly used with MRI Ruby 2.X and will let you set breakpoints.

The most common problem you will encounter with actors is that they die due to exceptions. You can access the exception by calling the exception method on the actor:

actor = Tribe::Actor.new
actor.perform! { raise 'goodbye' }
sleep(3)
e = actor.exception
puts "#{e.class.name}: #{e.message}:\n#{e.backtrace.join("\n")}"

Benchmarks

Please see the performance wiki page for more information.

Ruby's main thread

Please read Ruby's main thread on the Workers gem homepage. Tribe is asynchrous and it is your responsibility to keep the main thread from exiting.

Contributing

Bug reports and pull requests are welcome on GitHub at https://github.com/chadrem/tribe.