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Quickstart: Submitting a work item to the thread pool (XAML)

[This article is for Windows 8.x and Windows Phone 8.x developers writing Windows Runtime apps. If you’re developing for Windows 10, see the latest documentation]

Learn how to do work in a separate thread by submitting a work item to the thread pool. Use this to maintain a responsive UI while still completing work that takes a noticeable amount of time, and use it to complete multiple tasks in parallel.

Prerequisites

None.

Instructions

1. Create and submit the work item

Create a work item by calling RunAsync. Supply a delegate to do the work (you can use a lambda, or a delegate function). Note that RunAsync returns an IAsyncAction object; store this object for use in the next step.

Three versions of RunAsync are available so that you can optionally specify the priority of the work item, and control whether it runs concurrently with other work items.

Note  Use CoreDispatcher.RunAsync to access the UI thread and show progress from the work item. 

The following example creates a work item and supplies a lambda to do the work:

// The nth prime number to find.
const unsigned int n = 9999;

// A shared pointer to the result.
// We use a shared pointer to keep the result alive until the 
// thread is done.
std::shared_ptr<unsigned long> nthPrime = make_shared<unsigned long int>(0);

// Simulates work by searching for the nth prime number. Uses a
// naive algorithm and counts 2 as the first prime number.
auto workItem = ref new WorkItemHandler(
    [this, n, nthPrime](IAsyncAction^ workItem)
{
    unsigned int progress = 0; // For progress reporting.
    unsigned int primes = 0;   // Number of primes found so far.
    unsigned long int i = 2;   // Number iterator.

    if ((n >= 0) && (n <= 2))
    {
        *nthPrime = n;
        return;
    }

    while (primes < (n - 1))
    {
        if (workItem->Status == AsyncStatus::Canceled)
        {
            break;
        }

        // Go to the next number.
        i++;

        // Check for prime.
        bool prime = true;
        for (unsigned int j = 2; j < i; ++j)
        {
            if ((i % j) == 0)
            {
                prime = false;
                break;
            }
        };

        if (prime)
        {
            // Found another prime number.
            primes++;

            // Report progress at every 10 percent.
            unsigned int temp = progress;
            progress = static_cast<unsigned int>(10.f*primes / n);

            if (progress != temp)
            {
                String^ updateString;
                updateString = "Progress to " + n + "th prime: "
                    + (10 * progress).ToString() + "%\n";

                // Update the UI thread with the CoreDispatcher.
                CoreApplication::MainView->CoreWindow->Dispatcher->RunAsync(
                    CoreDispatcherPriority::High,
                    ref new DispatchedHandler([this, updateString]()
                {
                    UpdateUI(updateString);
                }));
            }
        }
    }

    // Return the nth prime number.
    *nthPrime = i;
});

auto asyncAction = ThreadPool::RunAsync(workItem);

// A reference to the work item is cached so that we can trigger a 
// cancellation when the user presses the Cancel button.
m_workItem = asyncAction;
// The nth prime number to find.
const uint n = 9999;

// A shared pointer to the result.
// We use a shared pointer to keep the result alive until the 
// thread is done.
ulong nthPrime = 0;

// Simulates work by searching for the nth prime number. Uses a
// naive algorithm and counts 2 as the first prime number.
IAsyncAction asyncAction = Windows.System.Threading.ThreadPool.RunAsync(
    (workItem) =>
{
    uint  progress = 0; // For progress reporting.
    uint  primes = 0;   // Number of primes found so far.
    ulong i = 2;        // Number iterator.

    if ((n >= 0) && (n <= 2))
    {
        nthPrime = n;
        return;
    }

    while (primes < (n - 1))
    {
        if (workItem.Status == AsyncStatus.Canceled)
        {
            break;
        }

        // Go to the next number.
        i++;

        // Check for prime.
        bool prime = true;
        for (uint j = 2; j < i; ++j)
        {
            if ((i % j) == 0)
            {
                prime = false;
                break;
            }
        };

        if (prime)
        {
            // Found another prime number.
            primes++;

            // Report progress at every 10 percent.
            uint temp = progress;
            progress = (uint)(10.0*primes/n);

            if (progress != temp)
            {
                String updateString;
                updateString = "Progress to " + n + "th prime: "
                    + (10 * progress) + "%\n";

                // Update the UI thread with the CoreDispatcher.
                CoreApplication.MainView.CoreWindow.Dispatcher.RunAsync(
                    CoreDispatcherPriority.High,
                    new DispatchedHandler(() =>
                {
                    UpdateUI(updateString);
                }));
            }
        }
    }

    // Return the nth prime number.
    nthPrime = i;
});

// A reference to the work item is cached so that we can trigger a
// cancellation when the user presses the Cancel button.
m_workItem = asyncAction;

Following the call to RunAsync, the work item is queued by the thread pool and runs when a thread becomes available. Thread pool work items run asynchronously and they can run in any order, so make sure your work items function independently.

Note that the work item checks the IAsyncInfo.Status property, and exits if the work item is cancelled.

2. Handle work item completion

Provide a completion handler by setting the IAsyncAction.Completed property of the work item. Supply a delegate (you can use a lambda or a delegate function) to handle work item completion. For example, use CoreDispatcher.RunAsync to access the UI thread and show the result.

The following example updates the UI with the result of the work item submitted in step 1:

asyncAction->Completed = ref new AsyncActionCompletedHandler(
    [this, n, nthPrime](IAsyncAction^ asyncInfo, AsyncStatus asyncStatus)
{
    if (asyncStatus == AsyncStatus::Canceled)
    {
        return;
    }
    
    String^ updateString;
    updateString = "\n" + "The " + n + "th prime number is " 
        + (*nthPrime).ToString() + ".\n";

    // Update the UI thread with the CoreDispatcher.
    CoreApplication::MainView->CoreWindow->Dispatcher->RunAsync(
        CoreDispatcherPriority::High,
        ref new DispatchedHandler([this, updateString]()
    {
        UpdateUI(updateString);
    }));
});
asyncAction.Completed = new AsyncActionCompletedHandler(
    (IAsyncAction asyncInfo, AsyncStatus asyncStatus) =>
{
    if (asyncStatus == AsyncStatus.Canceled)
    {
        return;
    }

    String updateString;
    updateString = "\n" + "The " + n + "th prime number is " 
        + nthPrime + ".\n";

    // Update the UI thread with the CoreDispatcher.
    CoreApplication.MainView.CoreWindow.Dispatcher.RunAsync(
        CoreDispatcherPriority.High,
        new DispatchedHandler(()=>
    {
        UpdateUI(updateString);
    }));
});

Note that the completion handler checks whether the work item was cancelled before dispatching a UI update.

Summary

Download the code from this quickstart in the Creating a ThreadPool work item sample.

See the Thread Pool SDK sample for a complete code sample that demonstrates a wider range WinRT thread pool functionality.

See the following related topics to read more about the WinRT thread pool.

How to submit a work item using a timer

How to create a periodic work item

How to create and use pre-allocated work items

How to respond to named events and semaphores

How to use functions as work item delegates

Best practices for using the thread pool