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I have a WCF service hosted in a Windows Service. This service exposes 2 methods:

  1. bool ProcessClaim(string options, ref string xml); Takes some data as an input, does some processing (including IO-bound operations, like DB queries), and returns the result back.
  2. void RunJob(string ticket); Returns immediately. According to ticket, reads input data from storage (e.g. DB or file system), does the same processing for each data element, and saves result back to storage. Batch usually consists of many claims.

Users can call ProcessClaim to process single requests and RunJob to run batches. Several batches can run simultaneously. Each processing request is wrapped as Task, therefore all requests are executed in parallel. The problem was not to allow batches to chock up processing queue by scheduling a lot of requests. Other words, if user executes huge batch, it would block small batches and single processing requests for significant amount of time. So I came up with the following schema, well described by Albahari (very briefly):

public sealed class ProcessingQueue : IDisposable
    private class WorkItem
        public readonly TaskCompletionSource<string> TaskSource;
        public readonly string Options;
        public readonly string Claim;
        public readonly CancellationToken? CancelToken;

        public WorkItem(
            TaskCompletionSource<string> taskSource,
            string options,
            string claim,
            CancellationToken? cancelToken)
            TaskSource = taskSource;
            Options = options;
            Claim = claim;
            CancelToken = cancelToken;

    public ProcessingQueue()
        : this(Environment.ProcessorCount)

    public ProcessingQueue(int workerCount)
        _taskQ = new BlockingCollection<WorkItem>(workerCount * 2);

        for (var i = 0; i < workerCount; i++)

    public void Dispose()

    private readonly BlockingCollection<WorkItem> _taskQ;

    public Task<string> EnqueueTask(string options, string claim, CancellationToken? cancelToken = null)
        var tcs = new TaskCompletionSource<string>();
        _taskQ.Add(new WorkItem(tcs, options, claim, cancelToken));
        return tcs.Task;

    public static Task<string> ProcessRequest(string options, string claim, CancellationToken? cancelToken = null)
        return Task<string>.Factory.StartNew(() => ProcessItem(options, claim));

    private void Consume()
        foreach (var workItem in _taskQ.GetConsumingEnumerable())
            if (workItem.CancelToken.HasValue && workItem.CancelToken.Value.IsCancellationRequested)
                    workItem.TaskSource.SetResult(ProcessItem(workItem.Options, workItem.Claim));
                catch (Exception ex)

    private static string ProcessItem(string options, string claim)
        // do some actual work here
        Thread.Sleep(2000); // simulate work;
        return options + claim; // return final result

Static method ProcessRequest can be used to process single requests, whereas instance method EnqueueTask - for batch processing. Of course all batches must use a single shared instance of ProcessingQueue. Although this approach works pretty good and allows to control the pace of multiple batches running simultaneously, there is something that seems wrong to me:

  • Have to maintain a pool of working threads manually
  • Difficult to guess the optimal number of working threads (I use the number of processor cores by default)
  • Bunch of threads remain blocked when no batches are running, wasting system resources
  • IO-bound portions of processing block worker threads reducing efficiency of CPU usage

I wonder, is there a better way of dealing with this type of scenarios?

Update: One of the requirements is to provide full power for batches, meaning when user executes one batch, and there are no other incoming requests, all resources must be dedicated towards processing this batch.

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It sounds like you want to distribute load in a more consistent way. I would look at a service bus to do this. – Davin Tryon Feb 6 '12 at 15:20

1 Answer 1

up vote 4 down vote accepted

I would say that it may be a mistake to have a single service interface and a single hosting container to handle these two very different types of requirement.

You should decouple your service into two - one returns responses to individual requests on demand, the other queues batch queries and processes them on a single thread.

This way you can provide a high-availability channel to your real-time consumers, and an offline channel to your volume consumers. These can be deployed and managed as separate concerns allowing you to offer different service levels on each service interface.

Just my thoughts on the proposed architecture.


The fact is that your volume processing channel is an offline channel. This kind of means that consumers will have to queue and wait and indeterminate amount of time for their request to return.

So how about a job queue? Each job gets all the resources available while it's being processed. Once a job is processed the caller gets a notification that the job has been finished.

share|improve this answer
This is a very good point, and I should definitely split these functions up. However, one of the requirements is to provide full power for batches, meaning when user executes one batch, and there are no other incoming requests, all resources must be dedicated towards processing this batch. Your suggestion to process batch in a single thread doesn't meat this requirement. On the other hand, increasing number of threads for a batch would lead to the same initial problem. – yuramag Feb 6 '12 at 17:11
I agree with you. I don't know how best to approach your problem. Your challenge is to somehow dedicate more threads to processing a batch and at the same time to maximise thread availability. At least by de-coupling your channels you avoid impacting the real-time endpoints. – Tom Redfern Feb 10 '12 at 11:58
See update to my answer – Tom Redfern Feb 10 '12 at 12:00
Thanks for an update. In fact, I implemented it in a similar way - single requests are not being queued up, but executed right away like simple WCF calls, whereas batch requests organize their own queues issuing concurrent requests. I rely on this wonderful TPL Dataflow library that does all the magic I need... – yuramag Oct 17 '12 at 13:37

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