It is concurrent, in the sense that many outstanding asychronous operations may be in progress at any time. It may or may not be multithreaded.
await will schedule the continuation back to the "current execution context". The "current execution context" is defined as
SynchronizationContext.Current if it is non-
TaskScheduler.Current if there's no
You can override this default behavior by calling
ConfigureAwait and passing
false for the
continueOnCapturedContext parameter. In that case, the continuation will not be scheduled back to that execution context. This usually means it will be run on a threadpool thread.
Unless you're writing library code, the default behavior is exactly what's desired. WinForms, WPF, and Silverlight (i.e., all the UI frameworks) supply a
SynchronizationContext, so the continuation executes on the UI thread (and can safely access UI objects). ASP.NET also supplies a
SynchronizationContext that ensures the continuation executes in the correct request context.
Other threads (including threadpool threads,
BackgroundWorker) do not supply a
SynchronizationContext. So Console apps and Win32 services by default do not have a
SynchronizationContext at all. In this situation, continuations execute on threadpool threads. This is why Console app demos using
async include a call to
ReadKey or do a blocking
Wait on a
If you find yourself needing a
SynchronizationContext, you can use
AsyncContext from my Nito.AsyncEx library; it basically just provides an
async-compatible "main loop" with a
SynchronizationContext. I find it useful for Console apps
and unit tests (VS2012 now has built-in support for
async Task unit tests).
For more information about
SynchronizationContext, see my Feb MSDN article.
At no time is
DoEvents or an equivalent called; rather, control flow returns all the way out, and the continuation (the rest of the function) is scheduled to be run later. This is a much cleaner solution because it doesn't cause reentrancy issues like you would have if
DoEvents was used.