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Is Interlocked.Increment(ref x) faster or slower than x++ for ints and longs on various platforms?

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As others point out, it's not the same thing. That said, according to msdn.microsoft.com/en-us/magazine/cc163726.aspx an Interlocked.Increment takes some 14nS (or about 71'000'000 per second) so I wouldn't worry to much about performance –  smirkingman Sep 27 '12 at 20:03
    
Interlocked.Increment is intended to be used under threads environments –  EProgrammerNotFound Aug 8 '13 at 15:29

6 Answers 6

up vote 30 down vote accepted

It is slower since it forces the action to occur atomically and it acts as a memory barrier, eliminating the processor's ability to re-order memory accesses around the instruction.

You should be using Interlocked.Increment when you want the action to be atomic on state that can be shared between threads - it's not intended to be a full replacement for x++.

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+1 for it's not intended to be a full replacement for x++. –  EProgrammerNotFound Aug 8 '13 at 15:30

In our experience the InterlockedIncrement() et al on Windows are quite significant impacts. In one sample case we were able to eliminate the interlock and use ++/-- instead. This alone reduced run time from 140 seconds to 110 seconds. My analysis is that the interlock forces a memory roundtrip (otherwise how could other cores see it?). An L1 cache read/write is around 10 clock cycles, but a memory read/write more like 100.

In this sample case, I estimated the number of increment/decrement operations at about 1 billion. So on a 2Ghz CPU this is something like 5 seconds for the ++/--, and 50 seconds for the interlock. Spread the difference across several threads, and its close to 30 seconds.

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Micrsoft says: InterlockedIncrement was measured as taking 36-90 cycles in msdn.microsoft.com/en-us/library/windows/desktop/… –  Lothar Oct 15 '12 at 2:57
    
36 sounds right for uncontested operation, I'm measuring about 120 times for heavily contested operation on a Core i7, but maybe I botched it? Anyway, "interlock forces a memory roundtrip (otherwise how could other cores see it?). An L1 cache read/write is around 10 clock cycles..." - it's enough to mark that page as changed and only flush from L1 to memory if another core needs to see it, so uncontested operation can be closer to the 10 end of the spectrum (at 36) rather than 100+.... –  Tony D Apr 24 '13 at 8:50

Think about it for a moment, and you'll realize an Increment call cannot be any faster than a simple application of the increment operator. If it were, then the compiler's implementation of the increment operator would call Increment internally, and they'd perform the same.

But, as you can see by testing it for yourself, they don't perform the same.

The two options have different purposes. Use the increment operator generally. Use Increment when you need the operation to be atomic and you're sure all other users of that variable are also using interlocked operations. (If they're not all cooperating, then it doesn't really help.)

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No, it wouldn't - Interlocked.Increment cannot be called on a property, while the ++ operator can. Therefore, ++ wouldn't be able to call it. –  SLaks Jun 23 '09 at 17:55
    
To be more precise, Increment takes a ref int (or long); ++ takes a non-ref int (or long) –  SLaks Jun 23 '09 at 17:55
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The compiler could certainly implement ++ via Increment. It wouldn't be implemented with a simple "call" instruction, but it could be done using a temporary introduced by the compiler. The point is that the compiler uses the fasted available method of incrementing a number; if there were something faster, the compiler would have used it instead. –  Rob Kennedy Jun 23 '09 at 18:43

It's slower. However, it's the most performant general way I know of for achieving thread safety on scalar variables.

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volatile is more performant on scalars, but has the downside of requiring good coding practices to be used well. –  Abel Nov 12 '09 at 12:02
    
Careful with volatile; some processor architectures (x86/x64) have the ability to reorder accesses to memory, regardless of whether that memory was marked as volatile for the compiler. –  Drew Hoskins Nov 26 '09 at 17:49

My perfomance test:

volatile: 65,174,400

lock: 62,428,600

interlocked: 113,248,900

TimeSpan span = TimeSpan.FromSeconds(5);

object syncRoot = new object();
long test = long.MinValue;

Do(span, "volatile", () => {

    long r = Thread.VolatileRead(ref test);

    r++;

    Thread.VolatileWrite(ref test, r);
});

Do(span, "lock", () =>
{
    lock (syncRoot)
    {
        test++;
    }
});

Do(span, "interlocked", () =>
{
    Interlocked.Increment(ref test);
});
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What's​​​ Do? –  SLaks Apr 15 '12 at 3:40
    
It runs the method n times until the timespan has been reached –  MastsrOfDesaster Apr 30 '12 at 11:40
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So, wait, more is better in this case? Could you please specify what your metrics are? –  Kevin Fee Oct 25 '12 at 15:45
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Doesn't using VolatileRead and VolatileWrite in this manner leave you open to the same race condition that lock and Interlocked.Increment avoid? –  ta.speot.is Dec 23 '12 at 9:43

It will always be slower because it has to perform a CPU bus lock vs just updating a register. However modern CPUs achieve near register performance so it's negligible even in real-time processing.

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While X86 CPU's perform a buslock during Interlocked operations, a buslock is not required by all CPU's that provide Interlocked operations. Some CPU's are capable of signally that they have reserved a single cache line and can perform Interlocked operations on that cacheline without a buslock. –  Adisak Oct 30 '09 at 16:33

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