256

What is the difference between the below code snippets? Won't both be using threadpool threads?

For instance if I want to call a function for each item in a collection,

Parallel.ForEach<Item>(items, item => DoSomething(item));

vs

foreach(var item in items)
{
  Task.Factory.StartNew(() => DoSomething(item));
}
288

The first is a much better option.

Parallel.ForEach, internally, uses a Partitioner<T> to distribute your collection into work items. It will not do one task per item, but rather batch this to lower the overhead involved.

The second option will schedule a single Task per item in your collection. While the results will be (nearly) the same, this will introduce far more overhead than necessary, especially for large collections, and cause the overall runtimes to be slower.

FYI - The Partitioner used can be controlled by using the appropriate overloads to Parallel.ForEach, if so desired. For details, see Custom Partitioners on MSDN.

The main difference, at runtime, is the second will act asynchronous. This can be duplicated using Parallel.ForEach by doing:

Task.Factory.StartNew( () => Parallel.ForEach<Item>(items, item => DoSomething(item)));

By doing this, you still take advantage of the partitioners, but don't block until the operation is complete.

  • 8
    IIRC, the default partitioning done by Parallel.ForEach also takes into account the number of hardware threads available, saving you from having to work out the optimum number of Tasks to start. Check out Microsoft's Patterns of Parallel Programming article; it's got great explanations of all of this stuff in it. – Mal Ross Feb 17 '11 at 14:37
  • 2
    @Mal: Sort of... That's actually not the Partitioner, but rather the job of the TaskScheduler. The TaskScheduler, by default, uses the new ThreadPool, which handles this very well now. – Reed Copsey Feb 17 '11 at 16:42
  • Thanks. I knew I should've left in the "I'm no expert, but..." caveat. :) – Mal Ross Feb 17 '11 at 17:05
  • @ReedCopsey: How to attach tasks started via Parallel.ForEach to the wrapper task? So that when you call .Wait() on a wrapper task it hangs until tasks running in parallel are completed? – Konstantin Tarkus May 29 '12 at 0:29
  • 1
    @Tarkus If you're making multiple requests, you're better off just using HttpClient.GetString in each work item (in your Parallel loop). No reason to put an async option inside of the already concurrent loop, typically... – Reed Copsey May 29 '12 at 16:44
83

I did a small experiment of running a method "1000000000" times with "Parallel.For" and one with "Task" objects.

I measured the processor time and found Parallel more efficient. Parallel.For divides your task in to small work items and executes them on all the cores parallely in a optimal way. While creating lot of task objects ( FYI TPL will use thread pooling internally) will move every execution on each task creating more stress in the box which is evident from the experiment below.

I have also created a small video which explains basic TPL and also demonstrated how Parallel.For utilizes your core more efficiently http://www.youtube.com/watch?v=No7QqSc5cl8 as compared to normal tasks and threads.

Experiment 1

Parallel.For(0, 1000000000, x => Method1());

Experiment 2

for (int i = 0; i < 1000000000; i++)
{
    Task o = new Task(Method1);
    o.Start();
}

Processor time comparison

  • It would be more efficient and the reason behind that creating threads is costly Experiment 2 is a very bad practice. – Tim Oct 20 '13 at 23:38
  • @Georgi-it please care about talking more on what is bad. – Shivprasad Koirala Jun 26 '14 at 7:55
  • 3
    I am sorry, my mistake, I should have clarified. I mean the creation of Tasks in a loop to 1000000000. The overhead is unimaginable. Not to mention that the Parallel cannot create more than 63 tasks at a time, which makes it much more optimized in the case. – Georgi-it Jun 26 '14 at 7:58
  • This is true for 1000000000 tasks. However when I process an image (repeatedly, zooming fractal) and do Parallel.For on lines a lot of the cores are idle while waiting for the last threads to finish up. To make it faster I subdivided the data myself into 64 work packages and created tasks for it. (Then Task.WaitAll to wait for completion.) The idea is to have idle threads pick up a work package to help finish the work instead of waiting for 1-2 threads to finish up their (Parallel.For) assigned chunk. – Tedd Hansen Jun 15 '15 at 9:28
  • What does Mehthod1() do in this example? – Zapnologica May 9 '17 at 18:38
17

Parallel.ForEach will optimize(may not even start new threads) and block until the loop is finished, and Task.Factory will explicitly create a new task instance for each item, and return before they are finished (asynchronous tasks). Parallel.Foreach is much more efficient.

8

In my view the most realistic scenario is when tasks have a heavy operation to complete. Shivprasad's approach focuses more on object creation/memory allocation than on computing itself. I made a research calling the following method:

public static double SumRootN(int root)
{
    double result = 0;
    for (int i = 1; i < 10000000; i++)
        {
            result += Math.Exp(Math.Log(i) / root);
        }
        return result; 
}

Execution of this method takes about 0.5sec.

I called it 200 times using Parallel:

Parallel.For(0, 200, (int i) =>
{
    SumRootN(10);
});

Then I called it 200 times using the old-fashioned way:

List<Task> tasks = new List<Task>() ;
for (int i = 0; i < loopCounter; i++)
{
    Task t = new Task(() => SumRootN(10));
    t.Start();
    tasks.Add(t);
}

Task.WaitAll(tasks.ToArray()); 

First case completed in 26656ms, the second in 24478ms. I repeated it many times. Everytime the second approach is marginaly faster.

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