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Reading Joseph Albahari's threading tutorial, the following are mentioned as generators of memory barriers:

  • C#'s lock statement (Monitor.Enter/Monitor.Exit)
  • All methods on the Interlocked class
  • Asynchronous callbacks that use the thread pool — these include asynchronous delegates, APM callbacks, and Task continuations
  • Setting and waiting on a signaling construct
  • Anything that relies on signaling, such as starting or waiting on a Task

In addition, Hans Passant and Brian Gideon added the following (assuming none of which already fits into one of the previous categories):

  • Starting or waking up a thread
  • Context switch
  • Thread.Sleep()

I was wondering if this list was complete (if a complete list could even be practically made)

EDIT additions suggested:

  • Volatile (reading implies an acquire fence, writing implies a release fence)
share|improve this question
This going to be about Memory Models. On x86/x64 every Write is a fence. Read the part about the Itanium in Albahari's article. This list is not going to be of much practical use. – Henk Holterman Jul 5 '11 at 11:35
Thanks, I'm aware of that article. Actually according to it, in .NET 2 all writes are write fences (regardless of hardware architecture). I'm interested in other .NET implied memory barriers. – Ohad Schneider Jul 5 '11 at 11:41
@ohadsc: The x86-like "all writes are write fences" behaviour is a feature of Microsoft's CLR. The ECMA CLI spec doesn't provide any such guarantee, and I'm not sure what strong guarantees other implementations provide; for example, Mono. – LukeH Jul 5 '11 at 12:10
@LukeH - True, I should have been more specific – Ohad Schneider Jul 5 '11 at 12:18
up vote 27 down vote accepted

Here is my take on the subject and to attempt to provide a quasi-complete list in one answer. If I run across any others I will edit my answer from time to time.

Mechanisms that are generally agreed upon to cause implicit barriers:

  • All Monitor class methods including the C# keyword lock
  • All Interlocked class methods.
  • All Volatile class methods (.NET 4.5+).
  • Most SpinLock methods including Enter and Exit.
  • Thread.Join
  • Thread.VolatileRead and Thread.VolatileWrite
  • Thread.MemoryBarrier
  • The volatile keyword.
  • Anything that starts a thread or causes a delegate to execute on another thread including QueueUserWorkItem, Task.Factory.StartNew, Thread.Start, compiler supplied BeginInvoke methods, etc.
  • Using a signaling mechanism such as ManualResetEvent, AutoResetEvent, CountdownEvent, Semaphore, Barrier, etc.
  • Using marshaling operations such as Control.Invoke, Dispatcher.Invoke, SynchronizationContext.Post, etc.

Mechanisms that are speculated (but not known for certain) to cause implicit barriers:

  • Thread.Sleep (proposed by myself and possibly others due to the fact that code which exhibits a memory barrier problem can be fixed with this method)
  • Thread.Yield
  • Thread.SpinWait
  • Lazy<T> depending on which LazyThreadSafetyMode is specified

Other notable mentions:

  • Default add and remove handlers for events in C# since they use lock or Interlocked.CompareExchange.
  • x86 stores have release fence semantics
  • Microsoft's implemenation of the CLI has release fence semantics on writes despite the fact that the ECMA specification does not mandate it.
  • MarshalByRefObject seems to suppress certain optimizations in subclasses which may make it appear as if an implicit memory barrier were present. Thanks to Hans Passant for discovering this and bringing it to my attention.1

1This explains why BackgroundWorker works correctly without having volatile on the underlying field for the CancellationPending property.

share|improve this answer
Nice! (+1) It was Hans Passant who mentioned the context switch in his comment here: Regarding the event handlers, lock(this) was actually replaced with an Interlocked implementation:… – Ohad Schneider Aug 4 '11 at 11:36
The way I've come to think about memory barriers is that if 2 threads could access some shred state at the same exact time - a memory barrier (preferably lock) is needed. Otherwise, whatever mechanism that was put in place to prevent the concurrency (e.g. signaling, waiting, starting thread B only after thread A accessed the shared state) has probably brought up the required memory barriers. Would you agree with this approach ? – Ohad Schneider Aug 4 '11 at 11:43
@ohadsc: I didn't realize add/remove handlers were now implemented with Interlocked.CompareExchange. Nice catch! – Brian Gideon Aug 4 '11 at 13:12
@ohadsc: Yes, I think I generally agree with that statement. – Brian Gideon Aug 4 '11 at 13:16
I'm glad to hear that, far less headaches with this approach :) – Ohad Schneider Aug 4 '11 at 15:34

I seem to recall that the implementations of the Thread.VolatileRead and Thread.VolatileWrite methods actually cause full fences, not half fences.

This is deeply unfortunate, as people might have come to rely upon this behaviour unknowingly; they might have written a program that requires a full fence, think they need a half fence, think they are getting a half fence, and will be in for a nasty surprise if an implementation of these methods ever does provide a half fence.

I would avoid these methods. Of course, I would avoid everything involving low-lock code, not being smart enough to write it correctly in anything but the most trivial cases.

share|improve this answer
Of course, this is for trivial cases (such as the one depicted in the thread I linked to). I can assure you I'm not smart enough as well :) – Ohad Schneider Jul 5 '11 at 15:47
Looking at the BCL code for VolatileRead/Write (C#4), it looks like only half-fences are set-up (i.e. a call to Thread.MemoryBarrier() only prior to Reads and only after Writes.) Of course I may just be misunderstanding what you meant by half vs. full fence. – dlev Jul 5 '11 at 23:08
@dlev: The full-on MemoryBarrier has a stronger - and more expensive - effect in weak memory models than simply doing a load-with-acquire IL instruction, as you normally would when reading a volatile field. – Eric Lippert Jul 6 '11 at 0:00
Personally, I'd like to use those methods (where the behaviour of the access is highlighted at the place where the access happens) and eschew volatile (where the behaviour of the access is highlighted where the field is, perhaps many lines of code away). As you say though, the way things stand this is both safer than it appears (and hence perhaps suddenly less safe with an implementation change). It's also more expensive (because while I also avoid low-lock code for real-world use unless I've a definite gain to make, I do like optimising to stupid degrees when experimenting for fun). – Jon Hanna Dec 7 '11 at 15:13

The volatile keyword acts as a memory barrier too. See

share|improve this answer
True, I'll add it to the list – Ohad Schneider Jul 5 '11 at 11:43
volatile doesn't cause a memory barrier. In the link, a memory barrier is used to prevent reordering, but that doesn't mean that if you prevent reordering you get a memory barrier! – configurator Jul 5 '11 at 12:01
AFAIK volatile causes all reads/writes to be executed before the volatile variable is read/written. Or am I mistaken @configurator? – Leonard Brünings Jul 5 '11 at 12:13
From Albahari's tutorial: The volatile keyword instructs the compiler to generate an acquire-fence on every read from that field, and a release-fence on every write to that field – Ohad Schneider Jul 5 '11 at 12:19
I could be wrong. Let me qualify my comment appropriately: as far as I know, volatile doesn't cause a memory barrier, but does prevent reordering of reads and writes; a memory barrier is in a sense a stronger promise than volatile field reads or writes are. – configurator Jul 5 '11 at 16:19

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