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I've been studying the actor model (specifically the implementation in Scala) but I can't understand why there's a requirement that messages arrive in no particular order.

It seems like there are at least some elegant, actor-based solutions to concurrency problems that would work if only the messages arrived in order (e.g. producer-consumer variants, deferred database writes, concurrency-safe caches).

So why don't actor messages arrive in order? Is it to permit efficient implementation or maybe to prevent some kind of deadlock that would arise when messages are ordered?

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The guarantee that erlang's BEAM provides is very significant, I touched on this in the errata to the Oreilly book (p 196) but haven't done any further investigation oreilly.com/catalog/errata.csp?isbn=9780596155964 –  Gene T Apr 22 '11 at 7:09

4 Answers 4

up vote 12 down vote accepted

My impression is that if two threads send a message to an actor a, there is no particular guarantee about which will be received by the actor first. But if you have code that looks like

a ! "one"
a ! "two"

then a will always get "one" before "two" (though who knows what else might have arrived in between from other threads).

Thus, I don't think it is the case that messages arrive in no particular order at all. Multiple messages from within one thread will (as far as I can tell from the code or from experience) arrive in order.

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You are very much correct, Rex. –  Viktor Klang Apr 22 '11 at 20:06
@Viktor - Hopefully I'm correct for Akka and Lift and Scalaz also. Putting messages into a set or stack just doesn't seem right! –  Rex Kerr Apr 22 '11 at 21:02
There is one exception though - prioritized message queues. –  Viktor Klang Apr 23 '11 at 20:29

I'm not privy to the reasons why Scala's Actors (those in the standard library, at any rate -- there are also Akka, Lift and Scalaz implementations of Actors) chose that particular implementation. Probably as a copy of Erlang's own restrictions -- but without the guarantees for communication between two single threads. Or maybe with that guarantee as well -- I wish Phillip Haller was here to comment.

BUT, I do question your statement about concurrency problems. When studying asynchronous distributed algorithms, a basic tenet is that you can't guarantee any ordering of message receipt.

To quote Distributed Computing: Fundamentals, Simulation and Advanced Topics, by Hagit Attiya and Jennifer Welch,

A system is said to be asynchronous if there is no fixed upper bound on how long it takes for a message to be delivered or how much time elapses between consecutive steps of a processor.

The actor model is an asynchronous one. That enables it to work over distributed hardware -- be it different computers communicating through a network, or different processors on a system that does not provide synchronous guarantees.

Furthermore, even the multi-threading model on a multi-core processor is mostly asynchronous, with the primitives that enable synchronism being extremely expensive.

So a simple answer to the question might be:

Messages are not guaranteed to arrive in order because that's an underlying limitation of asynchronous systems, which is the basic model of computation used by actors.

This model is the one we actually have on any system distributed over TCP/IP, and the most efficient over i386/x64 multicore/multiprocessor hardware.

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Daniel, always you cut to the heart of the matter and state it so well. –  wheaties Apr 23 '11 at 20:46
@wheaties I should be more concise, imo, but thanks. –  Daniel C. Sobral Apr 23 '11 at 23:45

The following simple example shows messages arriving out of order to a very simple actor:

import scala.actors._
import scala.actors.Actor._
import scala.collection.mutable._

val adder = actor {
  loop {
    react {
      case x: Int => println(" Computing " + x); reply(x+2)
      case Exit => println("Exiting"); exit

actor {
  for (i <- 1 to 5) {
    println("Sending " + i)
    adder !! (i, { case answer => println("Computed " + i + " -> " + answer) })

  println("Sending Exit")
  adder !! Exit

Here is the output from one run of the above code with Scala 2.9.0 final on Windows 64-bit with Sun JDK 1.6.0u25:

Sending 1
Sending 2
Sending 3
Sending 4
Sending 5
Sending Exit
 Computing 1
Computed 1 -> 3
 Computing 4
Computed 4 -> 6
 Computing 3
Computed 3 -> 5
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Very interesting. I can reproduce this behaviour using the code above, but if the use of futures is removed (by replacing operator "!!" with "!") then the tests I've run have all shown the messages being processed in order. –  Todd Owen Jul 2 '11 at 1:03

What order would you choose? Should it be by when they were sent or when they were recieved? Should we freeze the entire mailbox whilst we sort the messages? Imagine sorting a large and nearly full mailbox, wouldn't that put an arbitrary lock on the queue? I think the messages don't arrive in order because there is no guaranteed way to enforce such an order. We have latency in networks and between processors.

We have no idea where the messages are coming from, only that they have arrived. So how about this, we make the guarantee that we have no ordering and don't even try to think about ordering. Instead of having to come up with some impressive logic to keep things organized while remaining as contention-free as possible we can just focus on keeping things as contention-free as possible.

Someone else probably has an even better answer than I on this.


Now that I've had time to sleep on it, I think it's a stipulation that allows for a much more vibrant Actor ecosystem to be created. Hence, why restrict one Actor or one thread or partial ownership of a thread from a thread pool? What if someone wanted to have an Actor which could grab as many threads as possible to process as many messages in its mailbox as it could?

If you made the stipulation up front that messages had to be done in the order they proceeded you'd never be able to allow for this. The minute multiple threads could be assigned by an Actor to process messages within the mailbox you'd be in the situation whereby you had no control over which message was processed first.

Phew, what your dreams say about your mind as you sleep.

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I'm not talking about distributed actors, necessarily. For simplicity, assume they're all in the same process. And I don't think it's particularly arbitrary for the mailbox to be treated as a queue, i.e. messages are handled in the order in which they were added to the mailbox... –  Bill Apr 22 '11 at 3:36
@Bill But if you're writing a library how can you enforce that the message come only from within the same computer and not the network? –  wheaties Apr 22 '11 at 3:39
@wheaties: I think you have misunderstood the question. The question is not about sorting messages received from arbitrary clients. It is about keeping or not keeping the order of messages that have been sent from the same client, since this is the only case in which we could and should assume messages are processed in a FIFO manner. For most applications this is essential and users would anyway have to implement it. --> continue in next comment –  Stefan Endrullis Apr 22 '11 at 11:23
Moreover adding a message to a queue (for keeping the retrieval order) is by far not comparable to sorting messages. It has the same effort as putting new messages into an unordered set or whatever. Anyway you have to synchronize the manipulation of the set or queue in a multi-threaded environment. Thus, I hope that Rex Kerr is right when he says that Scalas actors keep already the order of incoming messages from the same client, although the question of Bill suggests that it does not. –  Stefan Endrullis Apr 22 '11 at 11:25
If the same Actor processes more than one message at a time, then it's not an actor anymore. –  Viktor Klang Apr 22 '11 at 20:03

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