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I fully appreciate the atomicity that the Threading.Interlocked class provides; I don't understand, though, why the Add function only offers two overloads: one for Integers, another for Longs. Why not Doubles, or any other numeric type for that matter?

Clearly, the intended method for changing a Double is CompareExchange; I am GUESSING this is because modifying a Double is a more complex operation than modifying an Integer. Still it isn't clear to me why, if CompareExchange and Add can both accept Integers, they can't also both accept Doubles.

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up vote 21 down vote accepted

The Interlocked class wraps around the Windows API Interlocked** functions.

These are, in turn, wrapping around the native processor API, using the LOCK instruction prefix for x86. It only supports prefixing the following instructions:


You'll note that these, in turn, pretty much map to the interlocked methods. Unfortunately, the ADD functions for non-integer types are not supported here. Add for 64bit longs is supported on 64bit platforms.

Here's a great article discussing lock semantics on the instruction level.

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Others have addressed the "why?". It is easy however to roll your own Add(ref double, double), using the CompareExchange primitive:

public static double Add(ref double location1, double value)
    double newCurrentValue = 0;
    while (true)
        double currentValue = newCurrentValue;
        double newValue = currentValue + value;
        newCurrentValue = Interlocked.CompareExchange(ref location1, newValue, currentValue);
        if (newCurrentValue == currentValue)
            return newValue;

CompareExchange sets the value of location1 to be newValue, if the current value equals currentValue. As it does so in thread-safe and atomic fashion, we can rely on it alone without resorting to locks.

Why the while (true) loop? Loops like this are standard when implementing optimistically concurrent algorithms. CompareExchange will not change location1 if the current value is different from currentValue. I initialized currentValue to 0, as I don't know what's currently in location1. If there indeed is a 0, CompareExchange will change the value to newValue. If not, we have to retry CompareExchange with the new current value, as returned by CompareExchange.

If the value is changed by another thread until the time of our next CompareExchange again, it will fail again, necessitating another retry - and this can in theory go on forever, hence the loop. Unless you are constantly changing the value from multiple threads, CompareExchange will most likely be called only once, if the current value happened to be 0, or twice, if it was something other than 0.

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Can you explain a bit more how this works? Why do you loop? And what's the role of CompareExchange? – Mzn Jul 1 '13 at 6:28
@Mzn Added to my answer. Hope that explains it. – Eugene Beresovsky Feb 7 '14 at 0:21
This is now an excellent answer! At least now I think I know what optimistic concurrency means: 'Writing concurrent code with the assumption that things will eventually go right.' In case of our while(true) this means we will not loop forever (we're being reasonably optimistic). Thanks a lot! – Mzn Feb 7 '14 at 15:18
@Mzn pessimistic concurrency: let's take a lock around multiple operations, because it could go wrong with multiple steps. Reliable, and a reliable bottleneck for concurrent code. optimistic concurrency: let's give it a lockless try using CompareExchange, because most of the time it will just work with multiple threads, andf if not, we'll just retry. This allows for more concurrency, and is almost always faster. It's not easy to program, and some things just can't be done without locks. – Eugene Beresovsky Apr 17 '14 at 1:02
Could you explain why you set newCurrentValue = 0 rather than setting newCurrentValue = location1? Wouldn't the latter avoid the first loop iteration if the value is != 0? Thanks – JamPickle Nov 5 '15 at 11:43

As Reed Copsey has said, the Interlocked operations map (via Windows API functions) to instructions supported directly by the x86/x64 processors. Given that one of those functions is XCHG, you can do an atomic XCHG operation without really caring what the bits at the target location represent. In other words, the code can "pretend" that the 64-bit floating point number you are exchanging is in fact a 64-bit integer, and the XCHG instruction won't know the difference. Thus, .Net can provide Interlocked.Exchange functions for floats and doubles by "pretending" that they are integers and long integers, respectively.

However, all of the other operations actually do operate on the individual bits of the destination, and so they won't work unless the values actually represent integers (or bit arrays in some cases.)

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I suspect that there are two reasons.

  1. The processors targeted by .Net support interlocked increment only for integer types. I believe this is the LOCK prefix on x86, probably similar instructions exist for other processors.
  2. Adding one to a floating point number can result in the same number if it is big enough, so I'm not sure if you can call that an increment. Perhaps the framework designers are trying to avoid nonintuitive behavior in this case.
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Regarding your second point: yes, but I am asking about Interlocked.Add, not Interlocked.Increment. – Dan Tao Sep 9 '09 at 15:56

As Adam Robinson pointed out, there IS an overload for Interlocked.Increment that takes an Int64, but note:

The Read method and the 64-bit overloads of the Increment, Decrement, and Add methods are truly atomic only on systems where a System.IntPtr is 64 bits long. On other systems, these methods are atomic with respect to each other, but not with respect to other means of accessing the data. Thus, to be thread safe on 32-bit systems, any access to a 64-bit value must be made through the members of the Interlocked class.

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