Nesting await in Parallel.ForEach [duplicate]

Question

In a metro app, I need to execute a number of WCF calls. There are a significant number of calls to be made, so I need to do them in a parallel loop. The problem is that the parallel loop exits before the WCF calls are all complete.

How would you refactor this to work as expected?

var ids = new List<string>() { "1", "2", "3", "4", "5", "6", "7", "8", "9", "10" };
var customers = new  System.Collections.Concurrent.BlockingCollection<Customer>();

Parallel.ForEach(ids, async i =>
{
    ICustomerRepo repo = new CustomerRepo();
    var cust = await repo.GetCustomer(i);
    customers.Add(cust);
});

foreach ( var customer in customers )
{
    Console.WriteLine(customer.ID);
}

Console.ReadKey();

Answer 1

The whole idea behind Parallel.ForEach() is that you have a set of threads and each thread processes part of the collection. As you noticed, this doesn't work with async-await, where you want to release the thread for the duration of the async call.

You could “fix” that by blocking the ForEach() threads, but that defeats the whole point of async-await.

What you could do is to use TPL Dataflow instead of Parallel.ForEach(), which supports asynchronous Tasks well.

Specifically, your code could be written using a TransformBlock that transforms each id into a Customer using the async lambda. This block can be configured to execute in parallel. You would link that block to an ActionBlock that writes each Customer to the console. After you set up the block network, you can Post() each id to the TransformBlock.

In code:

var ids = new List<string> { "1", "2", "3", "4", "5", "6", "7", "8", "9", "10" };

var getCustomerBlock = new TransformBlock<string, Customer>(
    async i =>
    {
        ICustomerRepo repo = new CustomerRepo();
        return await repo.GetCustomer(i);
    }, new ExecutionDataflowBlockOptions
    {
        MaxDegreeOfParallelism = DataflowBlockOptions.Unbounded
    });
var writeCustomerBlock = new ActionBlock<Customer>(c => Console.WriteLine(c.ID));
getCustomerBlock.LinkTo(
    writeCustomerBlock, new DataflowLinkOptions
    {
        PropagateCompletion = true
    });

foreach (var id in ids)
    getCustomerBlock.Post(id);

getCustomerBlock.Complete();
writeCustomerBlock.Completion.Wait();

Although you probably want to limit the parallelism of the TransformBlock to some small constant. Also, you could limit the capacity of the TransformBlock and add the items to it asynchronously using SendAsync(), for example if the collection is too big.

As an added benefit when compared to your code (if it worked) is that the writing will start as soon as a single item is finished, and not wait until all of the processing is finished.

Answer 2

svick's answer is (as usual) excellent.

However, I find Dataflow to be more useful when you actually have large amounts of data to transfer. Or when you need an async-compatible queue.

In your case, a simpler solution is to just use the async-style parallelism:

var ids = new List<string>() { "1", "2", "3", "4", "5", "6", "7", "8", "9", "10" };

var customerTasks = ids.Select(i =>
  {
    ICustomerRepo repo = new CustomerRepo();
    return repo.GetCustomer(i);
  });
var customers = await Task.WhenAll(customerTasks);

foreach (var customer in customers)
{
  Console.WriteLine(customer.ID);
}

Console.ReadKey();

Answer 3

Using DataFlow as svick suggested may be overkill, and Stephen's answer does not provide the means to control the concurrency of the operation. However, that can be achieved rather simply:

public static async Task RunWithMaxDegreeOfConcurrency<T>(
     int maxDegreeOfConcurrency, IEnumerable<T> collection, Func<T, Task> taskFactory)
{
    var activeTasks = new List<Task>(maxDegreeOfConcurrency);
    foreach (var task in collection.Select(taskFactory))
    {
        activeTasks.Add(task);
        if (activeTasks.Count == maxDegreeOfConcurrency)
        {
            await Task.WhenAny(activeTasks.ToArray());
            //observe exceptions here
            activeTasks.RemoveAll(t => t.IsCompleted); 
        }
    }
    await Task.WhenAll(activeTasks.ToArray()).ContinueWith(t => 
    {
        //observe exceptions in a manner consistent with the above   
    });
}

The ToArray() calls can be optimized by using an array instead of a list and replacing completed tasks, but I doubt it would make much of a difference in most scenarios. Sample usage per the OP's question:

RunWithMaxDegreeOfConcurrency(10, ids, async i =>
{
    ICustomerRepo repo = new CustomerRepo();
    var cust = await repo.GetCustomer(i);
    customers.Add(cust);
});

EDIT Fellow SO user and TPL wiz Eli Arbel pointed me to a related article from Stephen Toub. As usual, his implementation is both elegant and efficient:

public static Task ForEachAsync<T>(
      this IEnumerable<T> source, int dop, Func<T, Task> body) 
{ 
    return Task.WhenAll( 
        from partition in Partitioner.Create(source).GetPartitions(dop) 
        select Task.Run(async delegate { 
            using (partition) 
                while (partition.MoveNext()) 
                    await body(partition.Current).ContinueWith(t => 
                          {
                              //observe exceptions
                          });
                      
        })); 
}

Answer 4

You can save effort with the new AsyncEnumerator NuGet Package, which didn't exist 4 years ago when the question was originally posted. It allows you to control the degree of parallelism:

using System.Collections.Async;
...

await ids.ParallelForEachAsync(async i =>
{
    ICustomerRepo repo = new CustomerRepo();
    var cust = await repo.GetCustomer(i);
    customers.Add(cust);
},
maxDegreeOfParallelism: 10);

Disclaimer: I'm the author of the AsyncEnumerator library, which is open source and licensed under MIT, and I'm posting this message just to help the community.

Answer 5

Wrap the Parallel.Foreach into a Task.Run() and instead of the await keyword use [yourasyncmethod].Result

(you need to do the Task.Run thing to not block the UI thread)

Something like this:

var yourForeachTask = Task.Run(() =>
        {
            Parallel.ForEach(ids, i =>
            {
                ICustomerRepo repo = new CustomerRepo();
                var cust = repo.GetCustomer(i).Result;
                customers.Add(cust);
            });
        });
await yourForeachTask;

Answer 6

This should be pretty efficient, and easier than getting the whole TPL Dataflow working:

var customers = await ids.SelectAsync(async i =>
{
    ICustomerRepo repo = new CustomerRepo();
    return await repo.GetCustomer(i);
});

...

public static async Task<IList<TResult>> SelectAsync<TSource, TResult>(this IEnumerable<TSource> source, Func<TSource, Task<TResult>> selector, int maxDegreesOfParallelism = 4)
{
    var results = new List<TResult>();

    var activeTasks = new HashSet<Task<TResult>>();
    foreach (var item in source)
    {
        activeTasks.Add(selector(item));
        if (activeTasks.Count >= maxDegreesOfParallelism)
        {
            var completed = await Task.WhenAny(activeTasks);
            activeTasks.Remove(completed);
            results.Add(completed.Result);
        }
    }

    results.AddRange(await Task.WhenAll(activeTasks));
    return results;
}

Answer 7

An extension method for this which makes use of SemaphoreSlim and also allows to set maximum degree of parallelism

    /// <summary>
    /// Concurrently Executes async actions for each item of <see cref="IEnumerable<typeparamref name="T"/>
    /// </summary>
    /// <typeparam name="T">Type of IEnumerable</typeparam>
    /// <param name="enumerable">instance of <see cref="IEnumerable<typeparamref name="T"/>"/></param>
    /// <param name="action">an async <see cref="Action" /> to execute</param>
    /// <param name="maxDegreeOfParallelism">Optional, An integer that represents the maximum degree of parallelism,
    /// Must be grater than 0</param>
    /// <returns>A Task representing an async operation</returns>
    /// <exception cref="ArgumentOutOfRangeException">If the maxActionsToRunInParallel is less than 1</exception>
    public static async Task ForEachAsyncConcurrent<T>(
        this IEnumerable<T> enumerable,
        Func<T, Task> action,
        int? maxDegreeOfParallelism = null)
    {
        if (maxDegreeOfParallelism.HasValue)
        {
            using (var semaphoreSlim = new SemaphoreSlim(
                maxDegreeOfParallelism.Value, maxDegreeOfParallelism.Value))
            {
                var tasksWithThrottler = new List<Task>();

                foreach (var item in enumerable)
                {
                    // Increment the number of currently running tasks and wait if they are more than limit.
                    await semaphoreSlim.WaitAsync();

                    tasksWithThrottler.Add(Task.Run(async () =>
                    {
                        await action(item).ContinueWith(res =>
                        {
                            // action is completed, so decrement the number of currently running tasks
                            semaphoreSlim.Release();
                        });
                    }));
                }

                // Wait for all tasks to complete.
                await Task.WhenAll(tasksWithThrottler.ToArray());
            }
        }
        else
        {
            await Task.WhenAll(enumerable.Select(item => action(item)));
        }
    }

Sample Usage:

await enumerable.ForEachAsyncConcurrent(
    async item =>
    {
        await SomeAsyncMethod(item);
    },
    5);

Answer 8

I am a little late to party but you may want to consider using GetAwaiter.GetResult() to run your async code in sync context but as paralled as below;

 Parallel.ForEach(ids, i =>
{
    ICustomerRepo repo = new CustomerRepo();
    // Run this in thread which Parallel library occupied.
    var cust = repo.GetCustomer(i).GetAwaiter().GetResult();
    customers.Add(cust);
});

Answer 9

After introducing a bunch of helper methods, you will be able run parallel queries with this simple syntax:

const int DegreeOfParallelism = 10;
IEnumerable<double> result = await Enumerable.Range(0, 1000000)
    .Split(DegreeOfParallelism)
    .SelectManyAsync(async i => await CalculateAsync(i).ConfigureAwait(false))
    .ConfigureAwait(false);

What happens here is: we split source collection into 10 chunks (.Split(DegreeOfParallelism)), then run 10 tasks each processing its items one by one (.SelectManyAsync(...)) and merge those back into a single list.

Worth mentioning there is a simpler approach:

double[] result2 = await Enumerable.Range(0, 1000000)
    .Select(async i => await CalculateAsync(i).ConfigureAwait(false))
    .WhenAll()
    .ConfigureAwait(false);

But it needs a precaution: if you have a source collection that is too big, it will schedule a Task for every item right away, which may cause significant performance hits.

Extension methods used in examples above look as follows:

public static class CollectionExtensions
{
    /// <summary>
    /// Splits collection into number of collections of nearly equal size.
    /// </summary>
    public static IEnumerable<List<T>> Split<T>(this IEnumerable<T> src, int slicesCount)
    {
        if (slicesCount <= 0) throw new ArgumentOutOfRangeException(nameof(slicesCount));

        List<T> source = src.ToList();
        var sourceIndex = 0;
        for (var targetIndex = 0; targetIndex < slicesCount; targetIndex++)
        {
            var list = new List<T>();
            int itemsLeft = source.Count - targetIndex;
            while (slicesCount * list.Count < itemsLeft)
            {
                list.Add(source[sourceIndex++]);
            }

            yield return list;
        }
    }

    /// <summary>
    /// Takes collection of collections, projects those in parallel and merges results.
    /// </summary>
    public static async Task<IEnumerable<TResult>> SelectManyAsync<T, TResult>(
        this IEnumerable<IEnumerable<T>> source,
        Func<T, Task<TResult>> func)
    {
        List<TResult>[] slices = await source
            .Select(async slice => await slice.SelectListAsync(func).ConfigureAwait(false))
            .WhenAll()
            .ConfigureAwait(false);
        return slices.SelectMany(s => s);
    }

    /// <summary>Runs selector and awaits results.</summary>
    public static async Task<List<TResult>> SelectListAsync<TSource, TResult>(this IEnumerable<TSource> source, Func<TSource, Task<TResult>> selector)
    {
        List<TResult> result = new List<TResult>();
        foreach (TSource source1 in source)
        {
            TResult result1 = await selector(source1).ConfigureAwait(false);
            result.Add(result1);
        }
        return result;
    }

    /// <summary>Wraps tasks with Task.WhenAll.</summary>
    public static Task<TResult[]> WhenAll<TResult>(this IEnumerable<Task<TResult>> source)
    {
        return Task.WhenAll<TResult>(source);
    }
}

Answer 10

The problem of parallelizing asynchronous operations has been solved with the introduction of the Parallel.ForEachAsync API in .NET 6, but people who are using older .NET platforms might still need a decent substitute. A solid base for implementing one is the ActionBlock<T> component from the TPL Dataflow library. This is part of the standard .NET libraries (.NET Core and .NET 5+), and available as a NuGet package for the .NET Framework. Here is how it can be used:

public static Task Parallel_ForEachAsync<T>(IEnumerable<T> source,
    int maxDegreeOfParallelism, Func<T, Task> action)
{
    var options = new ExecutionDataflowBlockOptions();
    options.MaxDegreeOfParallelism = maxDegreeOfParallelism;
    var block = new ActionBlock<T>(action, options);
    foreach (var item in source) block.Post(item);
    block.Complete();
    return block.Completion;
}

This solution enumerates eagerly the supplied IEnumerable<T>, and sends immediately all of its elements to the ActionBlock<T>. Then it signals that no more items are going to be sent to the block, and returns the Completion property of the block. The Completion is a Task that will complete when the block has processed all the items with the specified MaxDegreeOfParallelism, or when an exception has occurred while processing an item (and after all pending operations have completed). This should be sufficient for more applications, but the resulting behavior is not identical with the behavior of the Parallel.ForEachAsync. Here are the differences:

1. The enumeration of the source enumerable happens synchronously, on the current thread. This is OK if the source is a materialized collection like a List<T>, but not if it's a deferred enumerable like for example a BlockingCollection<T>.GetConsumingEnumerable. Not only the current thread might be blocked, but also any exception thrown during the enumeration will be propagated synchronously instead of being wrapped in the resulting Task. On the contrary the Parallel.ForEachAsync takes items from the source enumerable one at a time, not all at once.¹
2. An exception thrown during the enumeration of the source will result in all work already scheduled in the ActionBlock<T> to become fire-and-forget.
3. Any OperationCanceledExceptions thrown by the action are suppressed. That's how the TPL Dataflow library behaves by design.

The first two issues are quite serious, and indicate that the type of the source parameter should be something else than IEnumerable<T>, like for example an IReadOnlyCollection<T> or an IList<T>. These interfaces are typically not implemented by deferred collections. The third issue is less serious, but this too can be annoying in some scenarios.

Below is a more sophisticated implementation that attempts to be a complete substitute of the Parallel.ForEachAsync API, both in the signature and the behavior. It might be useful in advanced scenarios, where the simple implementation above is not sufficient.

public static Task Parallel_ForEachAsync<TSource>(IEnumerable<TSource> source,
    ParallelOptions parallelOptions,
    Func<TSource, CancellationToken, Task> body)
{
    if (source == null) throw new ArgumentNullException("source");
    if (parallelOptions == null) throw new ArgumentNullException("parallelOptions");
    if (body == null) throw new ArgumentNullException("body");
    var options = new ExecutionDataflowBlockOptions()
    {
        MaxDegreeOfParallelism = parallelOptions.MaxDegreeOfParallelism,
        CancellationToken = parallelOptions.CancellationToken,
        TaskScheduler = parallelOptions.TaskScheduler
    };
    // Immitate the default degree of parallelism of the Parallel.ForEachAsync.
    if (options.MaxDegreeOfParallelism == DataflowBlockOptions.Unbounded)
        options.MaxDegreeOfParallelism = Environment.ProcessorCount;
    options.BoundedCapacity = options.MaxDegreeOfParallelism;

    var block = new ActionBlock<TSource>(item =>
    {
        return body(item, options.CancellationToken)?.ContinueWith(t =>
        {
            // Fix TPL Dataflow's OperationCanceledException-swallowing behavior.
            if (t.IsCanceled && !options.CancellationToken.IsCancellationRequested)
                return Task.FromException(new TaskCanceledException(t));
            return t;
        }, CancellationToken.None, TaskContinuationOptions.DenyChildAttach |
            TaskContinuationOptions.ExecuteSynchronously,
            TaskScheduler.Default).Unwrap();
    }, options);

    Task enumerationTask = Task.Factory.StartNew(async () =>
    {
        // Feed the block with data, allowing for backpressure, and funnel any
        // exception to the ActionBlock.
        try
        {
            foreach (TSource item in source)
                if (!await block.SendAsync(item)) // Continue on captured context
                    break; // The block rejected the item
            block.Complete();
        }
        catch (Exception ex) { ((IDataflowBlock)block).Fault(ex); }
    }, CancellationToken.None, TaskCreationOptions.DenyChildAttach,
        options.TaskScheduler).Unwrap();

    return enumerationTask.ContinueWith(t =>
    {
        Debug.Assert(t.Status == TaskStatus.RanToCompletion);
        if (t.Status != TaskStatus.RanToCompletion) return t; // Should never happen
        return block.Completion;
    }, CancellationToken.None, TaskContinuationOptions.DenyChildAttach |
        TaskContinuationOptions.ExecuteSynchronously,
        TaskScheduler.Default).Unwrap();
}

The only difference is that the body parameter is of type Func<TSource, CancellationToken, Task> instead of Func<TSource, CancellationToken, ValueTask>. This is because value-tasks are a relatively recent feature, and are not available in .NET Framework.

¹ _{This is not documented, and the behavior could change in the future, but currently (.NET 7) this is how it works.}

Answer 11

Easy native way without TPL:

int totalThreads = 0; int maxThreads = 3;

foreach (var item in YouList)
{
    while (totalThreads >= maxThreads) await Task.Delay(500);
    Interlocked.Increment(ref totalThreads);

    MyAsyncTask(item).ContinueWith((res) => Interlocked.Decrement(ref totalThreads));
}

you can check this solution with next task:

async static Task MyAsyncTask(string item)
{
    await Task.Delay(2500);
    Console.WriteLine(item);
}