If I have this:

public string DoSomething(string arg)
{
    string someVar = arg;
    DoStuffThatMightTakeAWhile();
    return SomeControl.Invoke(new Func<string>(() => someVar));
}

And this method can be called concurrently from multiple threads, and one thread is stuck at DoStuffThatMightTakeAWhile, and then a second thread calls DoSomething with a different arg, will this change the value of someVar for all threads and consequently, DoSomething return the second version of someArg on both calls, or will one someVar exist for each thread?

Edit I think my Action should have been a Func so edited it.

up vote 16 down vote accepted

There are a number of confusions in the answers here, mostly based upon the untruth that local variables are allocated "on the stack of the thread". This is both false and irrelevant.

It's false because the local variable may be allocated on some temporary pool or the long-term storage pool; even if it is allocated on a temporary pool, that need not be stack memory; it could be a register. It's irrelevant because who cares what pool the storage is allocated on?

The relevant fact is that a top-level local variable is allocated per method activation. More generally, a local variable in a block is allocated once per the block being entered; a local variable declared in the body of a loop, for example, is allocated every time the loop goes around.

So, let's consider your question:

This method can be called concurrently from multiple threads. If one thread is stuck at DoStuffThatMightTakeAWhile, and then a second thread calls DoSomething with a different arg, will this change the value of someVar for all threads?

No. There is a new "someVar" for each activation of DoSomething.

will one someVar exist for each thread?

One "someVar" will exist for each activation. If a thread does exactly one activation then there will be exactly one someVar per thread; if a thread does a million activations then there will be a million of them.

That said, Jon Hanna's answer is also correct: if you make a delegate which both reads and writes a local variable, and you hand that delegate out to multiple threads, then all the activations of the delegate share the same local variable. There is no magical thread safety created for you; if you want to do that then you are responsible for ensuring thread safety.

  • So in a few words, a declaration like string myVar; will create a new myVar pretty much like I'd creating an object with the new keyword? Would this also apply to recursive calls (if DoSomething would call DoSomething)? – Juan Dec 20 '11 at 17:30
  • 2
    @jsoldi: The way the memory allocator creates new locals and the way it creates new storage for objects can be very different behind the scenes, but conceptually they are the same thing. And yes, recursive calls are activations just like non-recursive calls. Every activation gets a new batch of locals. – Eric Lippert Dec 20 '11 at 18:10
  • 1
    Why you are calling this a "method activation" and not a "method call". Is this a special term? – Restuta Dec 21 '11 at 10:02

Local variables stored in the current thread's stack, so each thread will have its own stack and each own someVar variable in it.

Since it would be different values in each thread

new Action(() => someVar)); 

will capture it's own value of someVar.

Edit

I was simply wrong saying that, as Eric pointed. See his answer for correct explanation.

  • 1
    Saying "local variables are stored on the current thread's stack" isn't correct. Any variable that is captured in a closure is allocated on the heap. – Jason Malinowski Dec 20 '11 at 4:07
  • Jason is correct. This answer does not have sound logic in it. – Eric Lippert Dec 20 '11 at 17:00
  • Yep, my bad, I won't modify my answer, cos your one is just perfectly good. – Restuta Dec 21 '11 at 9:54

As said, each thread hitting DoSomething is creating a separate someVar on its stack, and therefore no thread has any effect on another's someVar.

It is worth noting though, that if a local is captured in a closure and there is multi-threading initiated in that scope, that this can indeed cause different threads to affect the values each other sees, even in the case of value types (which we would normally think of as not something that another method can affect - in this way closures are not like class methods:

public static void Main(string[] args)
{
    int x = 0;
    new Thread(() => {while(x != 100){Console.WriteLine(x);}}).Start();
    for(int i = 0; i != 100; ++i)
    {
        x = i;
        Thread.Sleep(10);
    }
    x = 100;
    Console.ReadLine();
}

Demonstrates this.

  • If I understand correctly, in your example there is only one x (the one created in the main thread) that is being accessed by every thread? – Juan Dec 20 '11 at 4:30
  • Exactly, the thread manually created keeps writing it to the console, while the main thread increments it. – Jon Hanna Dec 20 '11 at 5:15
  • 1
    Note that someVar is not allocated on the stack in the first place. Closed-over locals are allocated on the heap because their lifetimes are extended. – Eric Lippert Dec 20 '11 at 17:01
  • Yep. @EricLippert succinctly says something that wasn't quite coming out right when I posted. Indeed, my first sentence incorrectly says the opposite, though since the lifetime isn't extended in that case it's logically the same as far as multithreading goes, my point being that sometimes the only-one-thread-can-see this reasoning that applies to locals still applies, and sometimes it doesn't. – Jon Hanna Dec 20 '11 at 23:18

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