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Let's say that a class has a public int counter field that is accessed by multiple threads. This int is only incremented or decremented.

To increment this field, which approach should be used, and why?

  • lock(this.locker) this.counter++;,
  • Interlocked.Increment(ref this.counter);,
  • Change the access modifier of counter to public volatile.

Now that I've discovered volatile, I've been removing many lock statements and the use of Interlocked. But is there a reason not to do this?

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simple-talk.com/blogs/2012/01/24/… you can see the use of volitable in arrays , i don't completly understand it , but it's anouther reference to what this does. –  eran otzap Sep 28 '13 at 16:18
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This is like saying "I've discovered that the sprinkler system is never activated, so I'm going to remove it and replace it with smoke alarms". The reason not to do this is because it is incredibly dangerous and gives you almost no benefit. If you have time to spend changing the code then find a way to make it less multithreaded! Don't find a way to make the multithreaded code more dangerous and easily broken! –  Eric Lippert Feb 18 at 17:25
    
My house has both sprinklers and smoke alarms. When incrementing a counter on one thread and reading it on another it seems like you need both a lock (or an Interlocked) and the volatile keyword. Truth? –  yoyo Nov 5 at 0:17

9 Answers 9

up vote 412 down vote accepted

Worst (won't actually work)

Change the access modifier of counter to public volatile

As other people have mentioned, this on it's own isn't actually safe at all. The point of volatile is that multiple threads running on multiple CPU's can and will cache data and re-order instructions.

If it is not volatile, and CPU A increments a value, then CPU B may not actually see that incremented value until some time later, which may cause problems.

If it is volatile, this just ensures the 2 CPU's see the same data at the same time. It doesn't stop them at all from interleaving their reads and write operations which is the problem you are trying to avoid.

Second Best:

lock(this.locker) this.counter++;

This is safe to do (provided you remember to lock everywhere else that you access this.counter). It prevents any other threads from executing any other code which is guarded by locker. Using locks also, prevents the multi-cpu reordering problems as above, which is great.

The problem is, locking is slow, and if you re-use the locker in some other place which is not really related then you can end up blocking your other threads for no reason.

Best

Interlocked.Increment(ref this.counter);

This is safe, as it effectively does the read, increment, and write in 'one hit' which can't be interrupted. Because of this it won't affect any other code and you don't need to remember to lock elsewhere either. It's also very fast (as MSDN says, on modern CPU's this is often literally a single CPU instruction).

I'm not entirely sure however if it gets around other CPU's reordering things, or if you also need to combine volatile with the increment.

Footnote: What volatile is actually good for.

As volatile doesn't prevent these kind of multithreading issues, what's it for? A good example is say you have 2 threads, one which always writes to a variable (say queueLength), and one which always reads from that same variable.

If queueLength is not volatile, thread A may write 5 times, but thread B may see those writes as being delayed (or even potentially in the wrong order).

A solution would be to lock, but you could also in this situation use volatile. This would ensure that thread B will always see the most up-to-date thing that thread A has written. Note however that this logic only works if you have writers who never read, and readers who never write, and if the thing you're writing is an atomic value. As soon as you do a single read-modify-write, you need to go to Interlocked operations or use a Lock.

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14  
"I'm not entirely sure ... if you also need to combine volatile with the increment." They cannot be combined AFAIK, as we can't pass a volatile by ref. Great answer by the way. –  Hosam Aly Jan 17 '09 at 13:07
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Thanx much! Your footnote on "What volatile is actually good for" is what I was looking for and confirmed how I want to use volatile. –  Jacques Bosch May 10 '10 at 6:22
4  
In other words, if a var is declared as volatile, the compiler will assume that the var's value will not remain the same (i.e. volatile) each time your code comes across it. So in a loop such as: while (m_Var) { }, and m_Var is set to false in another thread, the compiler won't simply check what's already in a register that was previously loaded with m_Var's value but reads the value out from m_Var again. However, it doesn't mean that not declaring volatile will cause the loop to go on infinitely - specifying volatile only guarantees that it won't if m_Var is set to false in another thread. –  Zach Saw Jun 23 '11 at 7:41
24  
@Zach Saw: Under the memory model for C++, volatile is how you've described it (basically useful for device-mapped memory and not a lot else). Under the memory model for the CLR (this question is tagged C#) is that volatile will insert memory barriers around reads and writes to that storage location. Memory barriers (and special locked variations of some assembly instructions) are you you tell the processor not to reorder things, and they're fairly important... –  Orion Edwards Jul 8 '11 at 3:39
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@ZachSaw: A volatile field in C# prevents the C# compiler and jit compiler from making certain optimizations that would cache the value. It also makes certain guarantees about what order reads and writes may be observed to be in on multiple threads. As an implementation detail it may do so by introducing memory barriers on reads and writes. The precise semantics guaranteed are described in the specification; note that the specification does not guarantee that a consistent ordering of all volatile writes and reads will be observed by all threads. –  Eric Lippert Dec 3 '13 at 17:22

EDIT: As noted in comments, these days I'm happy to use Interlocked for the cases of a single variable where it's obviously okay. When it gets more complicated, I'll still revert to locking...

Using volatile won't help when you need to increment - because the read and the write are separate instructions. Another thread could change the value after you've read but before you write back.

Personally I almost always just lock - it's easier to get right in a way which is obviously right than either volatility or Interlocked.Increment. As far as I'm concerned, lock-free multi-threading is for real threading experts, of which I'm not one. If Joe Duffy and his team build nice libraries which will parallelise things without as much locking as something I'd build, that's fabulous, and I'll use it in a heartbeat - but when I'm doing the threading myself, I try to keep it simple.

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5  
+1 for ensuring me to forget about lock-free coding from now. –  Xaqron Jan 3 '11 at 1:51
2  
lock-free codes are definitely not truly lock-free as they lock at some stage - whether at (FSB) bus or interCPU level, there's still a penalty you'd have to pay. However locking at these lower levels are generally faster so long as you don't saturate the bandwidth of where the lock occurs. –  Zach Saw Jul 7 '11 at 1:25
    
There is nothing wrong with Interlocked, it is exactly what your looking for and faster than a full lock() –  Jaap Mar 22 '12 at 20:24
2  
@Jaap: Yes, these days I would use interlocked for a genuine single counter. I just wouldn't want to start messing around trying to work out interactions between multiple lock-free updates to variables. –  Jon Skeet Mar 22 '12 at 20:30
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@ZachSaw: Your second comment says that interlocked operations "lock" at some stage; the term "lock" generally implies that one task can maintain exclusive control of a resource for an unbounded length of time; the primary advantage of lock-free programming is that it avoids the danger of resource becoming unusable as a result of the owning task getting waylaid. The bus synchronization used by the interlocked class isn't just "generally faster"--on most systems it has a bounded worst-case time, whereas locks do not. –  supercat Aug 21 '12 at 15:01

"volatile" does not replace Interlocked.Increment! It just makes sure that the variable is not cached, but used directly.

Incrementing a variable requires actually three operations:

  1. read
  2. increment
  3. write

Interlocked.Increment performs all three parts as a single atomic operation.

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1  
I hope you don't mean cached as in cached in CPU cache!!! –  Zach Saw Jul 7 '11 at 1:19
4  
Said another way, Interlocked changes are full-fenced and as such are atomic. Volatile members are only partially-fenced and as such are not guarenteed to be thread-safe. –  JoeGeeky Dec 4 '11 at 19:58

Either lock or interlocked increment is what you are looking for.

Volatile is definitely not what you're after - it simply tells the compiler to treat the variable as always changing even if the current code path allows the compiler to optimize a read from memory otherwise.

e.g.

while (m_Var)
{ }

if m_Var is set to false in another thread but it's not declared as volatile, the compiler is free to make it an infinite loop (but doesn't mean it always will) by making it check against a CPU register (e.g. EAX because that was what m_Var was fetched into from the very beginning) instead of issuing another read to the memory location of m_Var (this may be cached - we don't know and don't care and that's the point of cache coherency of x86/x64). All the posts earlier by others who mentioned instruction reordering simply show they don't understand x86/x64 architectures. Volatile does not issue read/write barriers as implied by the earlier posts saying 'it prevents reordering'. In fact, thanks again to MESI protocol, we are guaranteed the result we read is always the same across CPUs regardless of whether the actual results have been retired to physical memory or simply reside in the local CPU's cache. I won't go too far into the details of this but rest assured that if this goes wrong, Intel/AMD would likely issue a processor recall! This also means that we do not have to care about out of order execution etc. Results are always guaranteed to retire in order - otherwise we are stuffed!

With Interlocked Increment, the processor needs to go out, fetch the value from the address given, then increment and write it back -- all that while having exclusive ownership of the entire cache line (lock xadd) to make sure no other processors can modify its value.

With volatile, you'll still end up with just 1 instruction (assuming the JIT is efficient as it should) - inc dword ptr [m_Var]. However, the processor (cpuA) doesn't ask for exclusive ownership of the cache line while doing all it did with the interlocked version. As you can imagine, this means other processors could write an updated value back to m_Var after it's been read by cpuA. So instead of now having incremented the value twice, you end up with just once.

Hope this clears up the issue.

For more info, see 'Understand the Impact of Low-Lock Techniques in Multithreaded Apps' - http://msdn.microsoft.com/en-au/magazine/cc163715.aspx

p.s. What prompted this very late reply? All the replies were so blatantly incorrect (especially the one marked as answer) in their explanation I just had to clear it up for anyone else reading this. shrugs

p.p.s. I'm assuming that the target is x86/x64 and not IA64 (it has a different memory model). Note that Microsoft's ECMA specs is screwed up in that it specifies the weakest memory model instead of the strongest one (it's always better to specify against the strongest memory model so it is consistent across platforms - otherwise code that would run 24-7 on x86/x64 may not run at all on IA64 although Intel has implemented similarly strong memory model for IA64) - Microsoft admitted this themselves - http://blogs.msdn.com/b/cbrumme/archive/2003/05/17/51445.aspx.

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2  
Interesting. Can you reference this? I'd happily vote this up, but posting with some aggressive language 3 years after a highly voted answer that is consistent with the resources I've read is going to require a bit more tangible proof. –  SnOrfus Jul 7 '11 at 3:28
    
If you can point to which part you want referencing, I'd be happy to dig up some stuff from somewhere (I highly doubt I've given any x86/x64 vendor trade secrets away, so these should be easily available off wiki, Intel PRMs (programmer's reference manuals), MSFT blogs, MSDN or something similar)... –  Zach Saw Jul 7 '11 at 4:19
    
Also, I don't think it's that inconsistent with what the others have replied, only in their explanation -- suggesting that volatile prevents CPU from caching the result of the variable. That's utterly ridiculous. How is that consistent with anything you've read? If you can find anything in x86/x64 that allows you to set just a 32-bit/64-bit wide memory location to write-through cache or Windows allowing clients to change a specific memory location to write-through on the fly, and then adjusting that accordingly when GC compacts the heap, hence by-passing CPU cache... –  Zach Saw Jul 7 '11 at 4:27
    
Why anyone would want to prevent the CPU from caching is beyond me. The whole real estate (definitely not negligible in size and cost) dedicated to perform cache coherency is completely wasted if that's the case... Unless you require no cache coherency, such as a graphics card, PCI device etc, you wouldn't set a cache line to write-through. –  Zach Saw Jul 7 '11 at 4:29
2  
Yes, everything you say is if not 100% at least 99% on the mark. This site is (mostly) pretty useful when you are in the rush of development at work but unfortunately the accuracy of the answers corresponding to the (game of) votes is not there. So basically in stackoverflow you can get a feeling of what is the popular understanding of the readers not what it really is. Sometimes the top answers are just pure gibberish - myths of kind. And unfortunately this is what breeds into the folks who come across the read while solving the problem. It's understandable though, nobody can know everything. –  user1416420 Dec 14 '12 at 8:03

lock(...) works, but may block a thread, and could cause deadlock if other code is using the same locks in an incompatible way.

Interlocked.* is the correct way to do it ... much less overhead as modern CPUs support this as a primitive.

volatile on its own is not correct. A thread attempting to retrieve and then write back a modified value could still conflict with another thread doing the same.

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Interlocked functions do not lock. They are atomic, meaning that they can complete without the possibility of a context switch during increment. So there is no chance of deadlock or wait.

I would say that you should always prefer it to a lock and increment.

Volatile is useful if you need writes in one thread to be read in another, and if you want the optimizer to not reorder operations on a variable (because things are happening in another thread that the optimizer doesn't know about). It's an orthogonal choice to how you increment.

This is a really good article if you want to read more about lock-free code, and the right way to approach writing it

http://www.ddj.com/hpc-high-performance-computing/210604448

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Read the Threading in C# reference. It covers the ins and outs of your question. Each of the three have different purposes and side effects.

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I did some test to see how the theory actually works: kennethxu.blogspot.com/2009/05/interlocked-vs-monitor-performance.html. My test was more focused on CompareExchnage but the result for Increment is similar. Interlocked is not necessary faster in multi-cpu environment. Here is the test result for Increment on a 2 years old 16 CPU server. Bare in mind that the test also involves the safe read after increase, which is typical in real world.

D:\>InterlockVsMonitor.exe 16
Using 16 threads:
          InterlockAtomic.RunIncrement         (ns):   8355 Average,   8302 Minimal,   8409 Maxmial
    MonitorVolatileAtomic.RunIncrement         (ns):   7077 Average,   6843 Minimal,   7243 Maxmial

D:\>InterlockVsMonitor.exe 4
Using 4 threads:
          InterlockAtomic.RunIncrement         (ns):   4319 Average,   4319 Minimal,   4321 Maxmial
    MonitorVolatileAtomic.RunIncrement         (ns):    933 Average,    802 Minimal,   1018 Maxmial
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The code sample you tested was soooo trivial though - it really doesn't make much sense testing it that way! The best would be to understand what the different methods are actually doing and use the appropriate one based on the usage scenario you have. –  Zach Saw Jun 23 '11 at 15:10
    
@Zach, the how discussion here was about the scenario of increasing a counter in a thread safe manner. What other usage scenario was in your mind or how would you test it? Thanks for the comment BTW. –  Kenneth Xu Jun 27 '11 at 21:05
    
Point is, it's an artificial test. You're not going to hammer the same location that often in any real world scenario. If you are, then well you're bottlenecked by the FSB (as shown in your server boxes). Anyway, look at my reply on your blog. –  Zach Saw Jul 7 '11 at 1:18
    
Looking it back again. If the true bottleneck is with FSB, the the monitor implementation should observe the same bottleneck. The real difference is that Interlocked is doing busy wait and retry which becomes a real issue with high performance counting. At least I hope my comment raise the attention that Interlocked is not always the right choice for counting. The fact the people are looking at alternatives well explained it. You need a long adder gee.cs.oswego.edu/dl/jsr166/dist/jsr166edocs/jsr166e/… –  Kenneth Xu Oct 6 '13 at 16:01

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