I asked a similar questions and received a bunch of good answers: http://stackoverflow.com/questions/2314861/shutting-down-a-multithreaded-application
Note: my question did not require a graceful exit, but people still recommended that I gracefully exit from the loop of each thread.
The main thing to remember is that if you want to avoid having your threads prevent your process from terminating you should set all your threads to background:
Thread thread = new Thread(new ThreadStart(testObject.RunLoop));
thread.IsBackground = true;
The preferred way to start and manage threads is in a
ThreadPool, but just about any container out there can be used to keep a reference to your threads. Your threads should always have a flag that will tell them to terminate and they should continually check it.
Furthermore, for better control you can supply your threads with a
CountdownLatch: whenever a thread is exiting its loop it will signal on a
CountdownLatch. Your main thread will call the
CountdownLatch.Wait() method and it will block until all the threads have signaled... this allows you to properly cleanup and ensures that all your threads have shutdown before you start cleaning up.
public class CountdownLatch
private int m_remain;
private EventWaitHandle m_event;
public CountdownLatch(int count)
public void Reset(int count)
if (count < 0)
throw new ArgumentOutOfRangeException();
m_remain = count;
m_event = new ManualResetEvent(false);
if (m_remain == 0)
public void Signal()
// The last thread to signal also sets the event.
if (Interlocked.Decrement(ref m_remain) == 0)
public void Wait()
It's also worthy to mention that the Thread.Abort() method does some strange things:
When a thread calls Abort on itself,
the effect is similar to throwing an
exception; the ThreadAbortException
happens immediately, and the result is
predictable. However, if one thread
calls Abort on another thread, the
abort interrupts whatever code is
running. There is also a chance that a
static constructor could be aborted.
In rare cases, this might prevent
instances of that class from being
created in that application domain. In
the .NET Framework versions 1.0 and
1.1, there is a chance the thread could abort while a finally block is
running, in which case the finally
block is aborted.
The thread that calls Abort might
block if the thread that is being
aborted is in a protected region of
code, such as a catch block, finally
block, or constrained execution
region. If the thread that calls Abort
holds a lock that the aborted thread
requires, a deadlock can occur.