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It is known that a reference takes 4 Bytes of memory in 32 bit processor and 8 Bytes - in 64 bit processor. So, processors guarantee that single reads from and writes to memory in increments of the natural word size of the machine will be carried out atomically. On the other hand there are 2 methods in Interlocked class:

public static int Exchange(
    ref int location1,
    int value


public static T Exchange<T>(
    ref T location1,
    T value
where T : class

So, the question is why Interlocked.Exchange is needed for Int32 and for reference types? Couldn't it be done safely by just using of simple assignment because it is atomic?

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up vote 3 down vote accepted

It is not only about atomicity. It is also about memory visibility. Variable can be stored in main memory or in CPU cache. If the variable is only stored in CPU cache it will not be visible to threads running on different CPU. Consider following example:

public class Test {
    private Int32 i = 5;

    public void ChangeUsingAssignment() {
        i = 10;

    public void ChangeUsingInterlocked() {
        Interlocked.Exchange(ref i, 10);

    public Int32 Read() {
        return Interlocked.CompareExchange(ref i, 0, 0);

Now if you call 'ChangeUsingAssignment' on one thread and 'Read' on another thread the return value may be 5, not 10. But if you call ChangeUsingInterlocked, 'Read' will return 10 as expected.

 ----------         ------------         -------------------
|   CPU 1  |  -->  |   CACHE 1  |  -->  |                   |
 ----------         ------------        |                   |
                                        |        RAM        |
 ----------         ------------        |                   |
|   CPU 2  |  -->  |   CACHE 2  |  -->  |                   |
 ----------         ------------         -------------------

In the diagram above 'ChangeUsingAssignement' method may result in value 10 get 'stuck' in CACHE 2 and not make it to RAM. When CPU 1 later tries to read it, it will get the value from RAM where it is still 5. Using Interlocked instead of ordinary write will make sure that value 10 gets all the way to the RAM.

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Thank you very much. It is clear enough now. – gorik Aug 4 '11 at 5:55
I know this is obviously a year later, but if possible, could you please review this? This website seems to imply that all writes in C# are already volatile. – user981225 Oct 19 '12 at 18:51

Interlocked.Exchange has a return value, allowing you to know what value you just replaced. It's the combination of setting a new value and obtaining the old value that these methods achieve.

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So if you don't need the old value you could simply assign, but then you'd also need a Barrier call to invalidate the cache(s). – Henk Holterman Aug 3 '11 at 15:04
@Henk: Could you please give more details what do you mean by a Barrier call? – gorik Aug 3 '11 at 15:20
The classic reference: – Henk Holterman Aug 3 '11 at 15:54
@Henk: I am soory, but nothing about Barrier call there:… Could you give some example? – gorik Aug 3 '11 at 16:57
@gorik: It's part 4 and the full name is MemoryBarrier. But don't go that way. – Henk Holterman Aug 3 '11 at 17:32

Exchanging a memory value and the contents of a CPU register is in general not atomic. You both need to read and write the memory location. Furthermore, the Interlocked methods guarantees that the operation is atomic even on multi-core computers where each core has its own cache and potentially its own view of the main memory.

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But if I do not need to have old value and want just assign new value to some variable. This is only writing and atomic, right? – gorik Aug 3 '11 at 15:08

Interlock.Exchange returns the original value while performing an atomic operation. The whole point is to provide a locking mechanism. So it is actually two operations: read original value and set new value. Those two together are not atomic.

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But if I do not need to have old value and want just assign new value to some variable. This is only writing and atomic, right? – gorik Aug 3 '11 at 15:08
@gorik: If it is a read or write operation on a variable of any reference type, or any built-in value type that takes up four bytes or less (for a 32 bit machine) then yes, it is guaranteed to be atomic. Check this series of posts by Eric Lippert on the subject, they will be of some help: Atomicity, volatility and immutability are different, part one – InBetween Aug 3 '11 at 15:10

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