Event-based Asynchronous Pattern Overview
Applications that perform many tasks simultaneously, yet remain responsive to user interaction, often require a design that uses multiple threads. The System.Threading namespace provides all the tools necessary to create high-performance multithreaded applications, but using these tools effectively requires significant experience with multithreaded software engineering. For relatively simple multithreaded applications, the BackgroundWorker component provides a straightforward solution. For more sophisticated asynchronous applications, consider implementing a class that adheres to the Event-based Asynchronous Pattern.
The Event-based Asynchronous Pattern makes available the advantages of multithreaded applications while hiding many of the complex issues inherent in multithreaded design. Using a class that supports this pattern can allow you to:
Perform time-consuming tasks, such as downloads and database operations, "in the background," without interrupting your application.
Execute multiple operations simultaneously, receiving notifications when each completes.
Wait for resources to become available without stopping ("hanging") your application.
Communicate with pending asynchronous operations using the familiar events-and-delegates model. For more information on using event handlers and delegates, see Events and Delegates.
A class that supports the Event-based Asynchronous Pattern will have one or more methods named MethodNameAsync. These methods may mirror synchronous versions, which perform the same operation on the current thread. The class may also have a MethodNameCompleted event and it may have a MethodNameAsyncCancel (or simply CancelAsync) method.
PictureBox is a typical component that supports the Event-based Asynchronous Pattern. You can download an image synchronously by calling its Load method, but if the image is large, or if the network connection is slow, your application will stop ("hang") until the download operation is completed and the call to Load returns.
If you want your application to keep running while the image is loading, you can call the LoadAsync method and handle the LoadCompleted event, just as you would handle any other event. When you call the LoadAsync method, your application will continue to run while the download proceeds on a separate thread ("in the background"). Your event handler will be called when the image-loading operation is complete, and your event handler can examine the AsyncCompletedEventArgs parameter to determine if the download completed successfully.
The Event-based Asynchronous Pattern requires that an asynchronous operation can be canceled, and the PictureBox control supports this requirement with its CancelAsync method. Calling CancelAsync submits a request to stop the pending download, and when the task is canceled, the LoadCompleted event is raised.
Warning
It is possible that the download will finish just as the CancelAsync request is made, so Cancelled may not reflect the request to cancel. This is called a race condition and is a common issue in multithreaded programming. For more information on issues in multithreaded programming, see Managed Threading Best Practices.
Characteristics of the Event-based Asynchronous Pattern
The Event-based Asynchronous Pattern may take several forms, depending on the complexity of the operations supported by a particular class. The simplest classes may have a single MethodNameAsync method and a corresponding MethodNameCompleted event. More complex classes may have several MethodNameAsync methods, each with a corresponding MethodNameCompleted event, as well as synchronous versions of these methods. Classes can optionally support cancellation, progress reporting, and incremental results for each asynchronous method.
An asynchronous method may also support multiple pending calls (multiple concurrent invocations), allowing your code to call it any number of times before it completes other pending operations. Correctly handling this situation may require your application to track the completion of each operation.
Examples of the Event-based Asynchronous Pattern
The SoundPlayer and PictureBox components represent simple implementations of the Event-based Asynchronous Pattern. The WebClient and BackgroundWorker components represent more complex implementations of the Event-based Asynchronous Pattern.
Below is an example class declaration that conforms to the pattern:
Public Class AsyncExample
' Synchronous methods.
Public Function Method1(ByVal param As String) As Integer
Public Sub Method2(ByVal param As Double)
' Asynchronous methods.
Overloads Public Sub Method1Async(ByVal param As String)
Overloads Public Sub Method1Async(ByVal param As String, ByVal userState As Object)
Public Event Method1Completed As Method1CompletedEventHandler
Overloads Public Sub Method2Async(ByVal param As Double)
Overloads Public Sub Method2Async(ByVal param As Double, ByVal userState As Object)
Public Event Method2Completed As Method2CompletedEventHandler
Public Sub CancelAsync(ByVal userState As Object)
Public ReadOnly Property IsBusy () As Boolean
' Class implementation not shown.
End Class
public class AsyncExample
{
// Synchronous methods.
public int Method1(string param);
public void Method2(double param);
// Asynchronous methods.
public void Method1Async(string param);
public void Method1Async(string param, object userState);
public event Method1CompletedEventHandler Method1Completed;
public void Method2Async(double param);
public void Method2Async(double param, object userState);
public event Method2CompletedEventHandler Method2Completed;
public void CancelAsync(object userState);
public bool IsBusy { get; }
// Class implementation not shown.
}
The fictitious AsyncExample class has two methods, both of which support synchronous and asynchronous invocations. The synchronous overloads behave like any method call and execute the operation on the calling thread; if the operation is time-consuming, there may be a noticeable delay before the call returns. The asynchronous overloads will start the operation on another thread and then return immediately, allowing the calling thread to continue while the operation executes "in the background."
Asynchronous Method Overloads
There are potentially two overloads for the asynchronous operations: single-invocation and multiple-invocation. You can distinguish these two forms by their method signatures: the multiple-invocation form has an extra parameter called userState. This form makes it possible for your code to call Method1Async(string param, object userState) multiple times without waiting for any pending asynchronous operations to finish. If, on the other hand, you try to call Method1Async(string param) before a previous invocation has completed, the method raises an InvalidOperationException.
The userState parameter for the multiple-invocation overloads allows you to distinguish among asynchronous operations. You provide a unique value (for example, a GUID or hash code) for each call to Method1Async(string param, object userState), and when each operation is completed, your event handler can determine which instance of the operation raised the completion event.
Tracking Pending Operations
If you use the multiple-invocation overloads, your code will need to keep track of the userState objects (task IDs) for pending tasks. For each call to Method1Async(string param, object userState), you will typically generate a new, unique userState object and add it to a collection. When the task corresponding to this userState object raises the completion event, your completion method implementation will examine AsyncCompletedEventArgs.UserState and remove it from your collection. Used this way, the userState parameter takes the role of a task ID.
Note
You must be careful to provide a unique value for userState in your calls to multiple-invocation overloads. Non-unique task IDs will cause the asynchronous class throw an ArgumentException.
Canceling Pending Operations
It is important to be able to cancel asynchronous operations at any time before their completion. Classes that implement the Event-based Asynchronous Pattern will have a CancelAsync method (if there is only one asynchronous method) or a MethodNameAsyncCancel method (if there are multiple asynchronous methods).
Methods that allow multiple invocations take a userState parameter, which can be used to track the lifetime of each task. CancelAsync takes a userState parameter, which allows you to cancel particular pending tasks.
Methods that support only a single pending operation at a time, like Method1Async(string param), are not cancelable.
Receiving Progress Updates and Incremental Results
A class that adheres to the Event-based Asynchronous Pattern may optionally provide an event for tracking progress and incremental results. This will typically be named ProgressChanged or MethodNameProgressChanged, and its corresponding event handler will take a ProgressChangedEventArgs parameter.
The event handler for the ProgressChangedevent can examine the ProgressChangedEventArgs.ProgressPercentage property to determine what percentage of an asynchronous task has been completed. This property will range from 0 to 100, and it can be used to update the Value property of a ProgressBar. If multiple asynchronous operations are pending, you can use the ProgressChangedEventArgs.UserState property to distinguish which operation is reporting progress.
Some classes may report incremental results as asynchronous operations proceed. These results will be stored in a class that derives from ProgressChangedEventArgs and they will appear as properties in the derived class. You can access these results in the event handler for the ProgressChanged event, just as you would access the ProgressPercentage property. If multiple asynchronous operations are pending, you can use the UserState property to distinguish which operation is reporting incremental results.
See Also
Tasks
How to: Use Components That Support the Event-based Asynchronous Pattern
How to: Run an Operation in the Background
How to: Implement a Form That Uses a Background Operation
Concepts
Best Practices for Implementing the Event-based Asynchronous Pattern
Deciding When to Implement the Event-based Asynchronous Pattern
Reference
Other Resources
Multithreaded Programming with the Event-based Asynchronous Pattern