Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm trying to implement MapReduce on top of Akka and was lucky to find the code of the book Akka Essentials. However, I have found two major issues with this example implementation, and both seem like fundamental concurrency design flaws which btw is quite shocking to find in a book about Akka:

  1. Upon completion the Client side will call shutdown() but at that point there is no guarantee that the messages went through to the WCMapReduceServer. I see that the WCMapReduceServer only gets a partial number of Client messages at any time and then WCMapReduceServer outputs [INFO] [06/25/2013 09:30:01.594] [WCMapReduceApp-5] [ActorSystem(WCMapReduceApp)] REMOTE: RemoteClientShutdown@akka://ClientApplication@192.168.224.65:2552 meaning the Client shutdown() happens before the Client actually manages to flush all pending messages. In the Client code line 41 we see the shutdown() takes place without flushing first. Is there a way in Akka to enforce flushing outbound messages before shutting down the system?

  2. The other actually bigger flaw, which I already fixed, is the way used to signal EOF to the MapReduce server that the main task (file of words) is done given that all subtasks (each line of the file) are done. He sends a special String message DISPLAY_LIST and this message is queued with lowest priority see code. The big flaw here is that even though DISPLAY_LIST has the lowest priority, if any Map (or Reduce) task takes arbitrarily long, the DISPLAY_LIST message will go through before all the MapReduce subtasks have completed and therefore the outcome of this MapReduce example is non-deterministic i.e. you can get different dictionaries out of each run. The issue can be revealed by replacing the MapActor#onReceive implementation with the following i.e. make one Map step arbitrarily long:

    public void onReceive(Object message) {
        System.out.println("MapActor -> onReceive(" + message + ")");
        if (message instanceof String) {
            String work = (String) message;
            // ******** BEGIN SLOW DOWN ONE MAP REQUEST
            if ("Thieves! thieves!".equals(work)) {
                try {
                    System.out.println("*** sleeping!");
                    Thread.sleep(5000);
                    System.out.println("*** back!");
                }
                catch (InterruptedException e) {
                    e.printStackTrace();
                }
            }
            // ******** END SLOW DOWN ONE MAP REQUEST
    
            // perform the work
            List<Result> list = evaluateExpression(work);
    
            // reply with the result
            actor.tell(list);
    
        } else throw new IllegalArgumentException("Unknown message [" + message + "]");
    }
    

Reading the book a bit further one finds:

We have Thread.sleep() because there is no guarantee in which order the messages are processed. The first Thread.sleep() method ensures that all the string sentence messages are processed completely before we send the Result message.

I'm sorry but Thread.sleep() has never been the means of ensuring anything in concurrency. Therefore no wonder books like this will end up full of fundamental concurrency flaws in their examples.

share|improve this question
1  
Interesting points, but may I ask what is the question in the second one? –  TheTerribleSwiftTomato Jun 25 '13 at 8:13
    
The second one is mainly for completeness but also maybe someone here has another insight on that point. –  Giovanni Azua Jun 25 '13 at 8:15
    
For question 1, you should check out this post: letitcrash.com/post/30165507578/shutdown-patterns-in-akka-2 –  cmbaxter Jun 25 '13 at 10:41
    
@cmbaxter thank you, I found that page linked from the documentation Akka.pdf but don't see clearly how to apply it to this simple use-case. Note that all what the agents running in the Client do is send messages. I'd like to know when all those messages have been flushed to the remote Agent. So I'm trying to inspect the state of the outgoing messages as opposed to what's is explained in the shutdown-patterns that seem to only check for the status of the incoming queues and the agents. Furthermore, I am interested in fundamentally asynchronous behavior. –  Giovanni Azua Jun 25 '13 at 11:41
    
I would use a combo of Poison Pill and Deathwatch to accomplish what you want. Have the FileReadActor send a Poison Pill to the ClientActor after it has sent all actual messages to it so that the pill is the last message the ClientActor receives. Then, I would tweak the code in Client so an actor starts up ClientActor (maybe something like ClientMaster) and then registers for lifecycle events on ClientActor. When ClientActor is terminated via the Poison Pill, the ClientMaster can then safely shutdown the actor system when it receives the Terminated lifecycle event. –  cmbaxter Jun 25 '13 at 12:10

1 Answer 1

up vote 1 down vote accepted

I have solved both problems, and also migrated the code to the latest Akka version 2.2-M3.

The solution to the first issue is to have the MapReduce remote MasterActor send back a ShutdownInfo notification as soon as it gets the TaskInfo notification which is sent from the Client once all messages have been sent. The TaskInfo contains the information of how many subtasks a MapReduce task has e.g. in this case how many lines in the text file.

The solution to the second problem is sending the TaskInfo with the total number of subtasks. Here the AggregatorActor counts the number of subtasks it has processed, compares it to the TaskInfo and signals that the job is done when they match (currently just print a message).

The interesting and correct behavior is shown in the output:

  • ClientActor sends a bunch of messages which are "subtasks". Note that the Identity request pattern is used to gain access to the ActorRef of the remote MapReduce MasterActor.
  • ClientActor sends last the TaskInfo message saying how many subtasks were previously sent.
  • MasterActor forwards String messages to MapActor which in turns forwards to ReduceActor
  • One MapActor is a lengthy one namely the one with content "Thieves! thieves!" this slows the MapReduce computation a bit.
  • Meanwhile MasterActor receives the TaskInfo last message and sends back to ClientActor the ShudownInfo
  • ClientActor runs system.shutdown() and Client terminates. Note that the MapReduce is still in the middle of the processing and the Client shutdown does not interfere.
  • The lengthy MapActor comes back and the message processing continues.
  • AggregatorActor receives the TaskInfo and by counting the subtasks confirms that the total number of substasks have been completed and signals completion.

The code may be fetch from my repository: https://github.com/bravegag/akka-mapreduce-example

Feedback always welcome.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.