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An article in MSDN Magazine discusses the notion of Read Introduction and gives a code sample which can be broken by it.

public class ReadIntro {
  private Object _obj = new Object();
  void PrintObj() {
    Object obj = _obj;
    if (obj != null) {
      Console.WriteLine(obj.ToString()); // May throw a NullReferenceException
  void Uninitialize() {
    _obj = null;

Notice this "May throw a NullReferenceException" comment - I never knew this was possible.

So my question is: how can I protect against read introduction?

I would also be really grateful for an explanation exactly when the compiler decides to introduce reads, because the article doesn't include it.

share|improve this question
A JIT compiler changing code semantics, worries me. Perhaps it was a JIT bug before .NET 4.5. – leppie Feb 10 '13 at 16:38
Yup, this looks definitely like a JIT bug. In fact, I’d classify it as a bug no matter what. The article is a bit useless – it mentions the concept but doesn’t really say how it occurs and how to guard against it. – Konrad Rudolph Feb 10 '13 at 16:41
@svick: Even with multithreading, this should never happen. No other threads can affect a local variable. – leppie Feb 10 '13 at 16:50
Just another reminder that you should never write multi-threaded code without protecting shared variables with a lock. – Hans Passant Feb 10 '13 at 17:40
@Konrad - The _obj variable is a field, not a local variable, that's the one getting whacked. Access to the backing field of an event is protected with a lock in .NET < 4, Interlocked in .NET 4+. – Hans Passant Feb 10 '13 at 18:04
up vote 14 down vote accepted

Let me try to clarify this complicated question by breaking it down.

What is "read introduction"?

"Read introduction" is an optimization whereby the code:

public static Foo foo; // I can be changed on another thread!
void DoBar() {
  Foo fooLocal = foo;
  if (fooLocal != null) fooLocal.Bar();

is optimized by eliminating the local variable. The compiler can reason that if there is only one thread then foo and fooLocal are the same thing. The compiler is explicitly permitted to make any optimization that would be invisible on a single thread, even if it becomes visible in a multithreaded scenario. The compiler is therefore permitted to rewrite this as:

void DoBar() {
  if (foo != null) foo.Bar();

And now there is a race condition. If foo turns from non-null to null after the check then it is possible that foo is read a second time, and the second time it could be null, which would then crash. From the perspective of the person diagnosing the crash dump this would be completely mysterious.

Can this actually happen?

As the article you linked to called out:

Note that you won’t be able to reproduce the NullReferenceException using this code sample in the .NET Framework 4.5 on x86-x64. Read introduction is very difficult to reproduce in the .NET Framework 4.5, but it does nevertheless occur in certain special circumstances.

x86/x64 chips have a "strong" memory model and the jit compilers are not aggressive in this area; they will not do this optimization.

If you happen to be running your code on a weak memory model processor, like an ARM chip, then all bets are off.

When you say "the compiler" which compiler do you mean?

I mean the jit compiler. The C# compiler never introduces reads in this manner. (It is permitted to, but in practice it never does.)

Isn't it a bad practice to be sharing memory between threads without memory barriers?

Yes. Something should be done here to introduce a memory barrier because the value of foo could already be a stale cached value in the processor cache. My preference for introducing a memory barrier is to use a lock. You could also make the field volatile, or use VolatileRead, or use one of the Interlocked methods. All of those introduce a memory barrier. (volatile introduces only a "half fence" FYI.)

Just because there's a memory barrier does not necessarily mean that read introduction optimizations are not performed. However, the jitter is far less aggressive about pursuing optimizations that affect code that contains a memory barrier.

Are there other dangers to this pattern?

Sure! Let's suppose there are no read introductions. You still have a race condition. What if another thread sets foo to null after the check, and also modifies global state that Bar is going to consume? Now you have two threads, one of which believes that foo is not null and the global state is OK for a call to Bar, and another thread which believes the opposite, and you're running Bar. This is a recipe for disaster.

So what's the best practice here?

First, do not share memory across threads. This whole idea that there are two threads of control inside the main line of your program is just crazy to begin with. It never should have been a thing in the first place. Use threads as lightweight processes; give them an independent task to perform that does not interact with the memory of the main line of the program at all, and just use them to farm out computationally intensive work.

Second, if you are going to share memory across threads then use locks to serialize access to that memory. Locks are cheap if they are not contended, and if you have contention, then fix that problem. Low-lock and no-lock solutions are notoriously difficult to get right.

Third, if you are going to share memory across threads then every single method you call that involves that shared memory must either be robust in the face of race conditions, or the races must be eliminated. That is a heavy burden to bear, and that is why you shouldn't go there in the first place.

My point is: read introductions are scary but frankly they are the least of your worries if you are writing code that blithely shares memory across threads. There are a thousand and one other things to worry about first.

share|improve this answer
So, today, this can only happen on ARM? – leppie Feb 11 '13 at 16:41
Thank you for this great answer! I would still argue that there are situations where read introduction is the only concern. See for example the method WaitWhilePausedAsync in Stephen Toub's implementation of cooperative pausing. – Gebb Feb 11 '13 at 17:14
@Gebb: Your point is well taken. This illustrates that it is a good reason to leave the production of threading primitives to people like Stephen Toub and Joe Duffy! Don't try to write your own primitives; raise the level of abstraction by using types like Lazy<T> or Task<T> that were written by people who understand this stuff. – Eric Lippert Feb 11 '13 at 17:42

You cant really "protect" against read introduction as it's a compiler optimization (excepting using Debug builds with no optimization of course). It's pretty well documented that the optimizer will maintain the single-threaded semantics of the function, which as the article notes can cause issues in multi-threaded situations.

That said, I'm confused by his example. In Jeffrey Richter's book CLR via C# (v3 in this case), in the Events section he covers this pattern, and notes that in the example snippet you have above, in THEORY it wouldn't work. But, it was a recommended pattern by Microsoft early in .Net's existence, and therefore the JIT compiler people he spoke to said that they would have to make sure that sort of snippet never breaks. (It's always possible they may decide that it's worth breaking for some reason though - I imagine Eric Lippert could shed light on that).

Finally, unlike the article, Jeffrey offers the "proper" way to handle this in multi-threaded situations (I've modified his example with your sample code):

Object temp = Interlocked.CompareExchange(ref _obj, null, null);
if(temp != null)
share|improve this answer
Just to get this straight: the only reason for using CompareExchange here is to get a memory fence around the read of _obj to prevent the compiler from doing its shenanigans, right? – Konrad Rudolph Feb 10 '13 at 17:54
Correct. Ideally you would use Interlocked.VolatileRead, but it doesn't have a generic version, so CompareExchange is the better solution. It's also a better solution than declaring _obj as volatile, as you should avoid volatile for performance reasons unless you need to have it "safe" everywhere it's used, which is rare.. – Gjeltema Feb 10 '13 at 17:57

I only skimmed the article, but it seems that what the author is looking for is that you need to declare the _obj member as volatile.

share|improve this answer
My first thought was also that surely with private volatile Object _obj this could not fail. But maybe that intuition of mine is wrong. – Jeppe Stig Nielsen Feb 10 '13 at 20:44
If you're worrying about that, check out this question: stackoverflow.com/questions/394898/… – erikkallen Feb 10 '13 at 21:31
@erikkallen: Stephen Toub seems to confirm your hypothesis. At least I got this impression from this conversation with him. – Gebb Feb 11 '13 at 16:17

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