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I'm writing a multithreaded application in c++, where performance is critical. I need to use a lot of locking while copying small structures between threads, for this I have chosen to use spinlocks.

I have done some research and speed testing on this and I found that most implementations are roughly equally fast:

  • Microsofts CRITICAL_SECTION, with SpinCount set to 1000, scores about 140 time units
  • Implementing this algorithm with Microsofts InterlockedCompareExchange scores about 95 time units
  • Ive also tried to use some inline assembly with __asm {} using something like this code and it scores about 70 time units, but I am not sure that a proper memory barrier has been created.

Edit: The times given here are the time it takes for 2 threads to lock and unlock the spinlock 1,000,000 times.

I know this isn't a lot of difference but as a spinlock is a heavily used object, one would think that programmers would have agreed on the fastest possible way to make a spinlock. Googling it leads to many different approaches however. I would think this aforementioned method would be the fastest if implemented using inline assembly and using the instruction CMPXCHG8B instead of comparing 32bit registers. Furthermore memory barriers must be taken into account, this could be done by LOCK CMPXHG8B (I think?), which guarantees "exclusive rights" to the shared memory between cores. At last [some suggests] that for busy waits should be accompanied by NOP:REP that would enable Hyper-threading processors to switch to another thread, but I am not sure whether this is true or not?

From my performance-test of different spinlocks, it is seen that there is not much difference, but for purely academic purpose I would like to know which one is fastest. However as I have extremely limited experience in the assembly-language and with memory barriers, I would be happy if someone could write the assembly code for the last example I provided with LOCK CMPXCHG8B and proper memory barriers in the following template:

         ;locking code.
         ;unlocking code.
share|improve this question
+1 for giving good sources and info before asking. i think you gave more than you need. thx – huseyin tugrul buyukisik Aug 14 '12 at 19:29
How much exactly is a lot? It would need to be an awful damn lot to worry about how fast you can spin. You're sure there is no better way you can restrict access here? Remember also that the speed you're spinning at doesn't affect when you actually acquire the lock. It doesn't matter how fast you're spinning, the other guy has to unlock it first. Consider looping over a yield() to pass execution to another running thread or process if it turns out that you're going to be spinning for a long time. – Wug Aug 14 '12 at 19:36
rep nop aka pause also makes P4 not do retarded things when you leave the spin loop. Intel's manual explicitly recommends its use in spin-wait loops. Are you allowed to use XACQUIRE and XRELEASE (not available until Haswell)? – harold Aug 14 '12 at 19:38
@Wug The time given in the performance tests, are the time it takes 2 threads to simultanously lock, copy 4 ints(to add realism) and unlock spinlock maybe 10000000 times (I don't the source code on this computer). The time units given does not give any information about how many loops have been run. – sigvardsen Aug 14 '12 at 19:42
When you want performance, use lock free/contention free data structures on your fast path, and only locks on your slow path – PlasmaHH Aug 14 '12 at 19:49

5 Answers 5

up vote 2 down vote accepted

Just look here: x86 spinlock using cmpxchg

And thanks to Cory Nelson

xorl %ecx, %ecx
incl %ecx
xorl %eax, %eax
lock; cmpxchgl %ecx, (lock_addr)
jnz spin_lock_retry

movl $0 (lock_addr)

And another source says:

       lock    cmpxchg8b qword ptr [esi]
is replaceable with the following sequence

        lock    bts dword ptr [edi],0
        jnb     acquired
        test    dword ptr [edi],1
        je      try
        pause                   ; if available
        jmp     wait

        cmp     eax,[esi]
        jne     fail
        cmp     edx,[esi+4]
        je      exchange

        mov     eax,[esi]
        mov     edx,[esi+4]
        jmp     done

        mov     [esi],ebx
        mov     [esi+4],ecx

        mov     byte ptr [edi],0

And here is a discussion about lock-free vs lock implementations:

share|improve this answer
Where would you place the PAUSE (NOP:REP) instruction? inside the loop or before? – sigvardsen Aug 15 '12 at 21:40
in the place of "pause" at the "wait" part. But for older cpu s as far as i know – huseyin tugrul buyukisik Aug 16 '12 at 4:09
it is a two-byte nop – huseyin tugrul buyukisik Aug 16 '12 at 4:14

Although there is already an accepted answer, there are a few things that where missed that could be used to improve all the answers, taken from this Intel article, all above fast lock implementation:

  1. Spin on a volatile read, not an atomic instruction, this avoids unneeded bus locking, especially on highly contended locks.
  2. Use back-off for highly contested locks
  3. Inline the lock, preferably with intrinsics for compilers where inline asm is detrimental (basically MSVC).
share|improve this answer

Wikipedia has a good article on spinlocks, here is the x86 implementation

Notice their implementation doesn't use the "lock" prefix, because it is redundant on x86 for the "xchg" instruction - it implicitly has lock semantics, as discussed in this Stackoverflow discussion:

On a multicore x86, is a LOCK necessary as a prefix to XCHG?

The REP:NOP is an alias for the PAUSE instruction, you can learn more about that here

How does x86 pause instruction work in spinlock *and* can it be used in other scenarios?

On the issue of memory barriers, here's everything you might want to know

Memory Barriers: a Hardware View for Software Hackers by Paul E. McKenney

share|improve this answer
In the code you linked to the Wikipedia implementation, why does the instruction to set the lock value in memory to 0 have to be atomic (using xchg instruction)? It would seem that even if another thread accesses the memory location before it's set to 0, all it would see is that the lock is still locked - wouldn't a direct mov to the memory location work too? – VF1 Jan 31 '14 at 20:43
Yes, a mov works on new x86 processors but not on some older ones, that is explained in the next section titled "Significant Optimizations" On later implementations of the x86 architecture, spin_unlock can safely use an unlocked MOV instead of the slower locked XCHG. This is due to subtle memory ordering rules which support this, even though MOV is not a full memory barrier. However, some processors (some Cyrix processors, some revisions of the Intel Pentium Pro (due to bugs), and earlier Pentium and i486 SMP systems) will do the wrong thing and data protected by the lock could be corrupted. – amdn Jan 31 '14 at 21:42
Thanks for pointing that out. If you don't mind me asking, what is the problem avoided by these "subtle memory ordering rules?" – VF1 Jan 31 '14 at 22:29
X86 memory ordering requires that stores by one thread be seen by other threads in the same order, which means there is no way another thread can acquire the lock and not see stores done in the critical section before the lock was released. See section (4) of this paper – amdn Jan 31 '14 at 22:57
Ah! that makes sense, thanks. – VF1 Feb 1 '14 at 0:19

I'm usually not one to gripe about someone striving to achieve fast code: it's usually a very good exercise which results in better understanding of programming and faster code.

I won't gripe here either but I can state unequivocally that the question of a fast spinlock 3 instructions long or a few more is - at least on the x86 achitecture - a futile chase.

Here's why:

Invoking a spinlock with a typical code sequence

lock_variable DW 0    ; 0 <=> free

mov ebx,offset lock_variable
mov eax,1
xchg eax,[ebx]

; if eax contains 0 (no one owned it) you own the lock,
; if eax contains 1 (someone already does) you don't

Freeing a spinlock is trivial

mov ebx,offset lock_variable
mov dword ptr [ebx],0

The xchg instruction raises the lock pin on the processor which in effect means I want the bus during the next few clock cycles. This signal weaves its way through the caches and down to the slowest bus-mastering device which is usually the PCI bus. When every busmastering device has completed the locka (lock acknowledge) signal is sent back. Then the actual exchange takes place. The problem is that the lock/locka sequence takes a VERY long time. The PCI bus may run at 33MHz with several cycles of latency. On a 3.3 GHz CPU that means each PCI bus cycle takes one hundred CPU cycles.

As a rule of thumb I assume that a lock will take between 300 and 3000 CPU cycles to complete and in the end I don't know if I'll even own the lock. So the few cycles you can save by a "fast" spinlock will be a mirage because no lock is like the next, it will depend on your bus situation during that short time.


I just read that the spinlock is a "heavily used object." Well, you obviously don't understand that a spinlock consumes an enormous amount of CPU cycles evey time it is invoked. Or, to put it another way, every time you invoke it you lose a significant amount of your processing capability.

The trick when using spinlocks (or their bigger sibling, the critical section) is to use them as sparingly as possible while still achieving the intended program function. Using them all over the place is easy and you'll end up with lackluster performance as a result.

It's not all about writing fast code, it's also about organizing your data. When you write "copying small structures between threads" you should realize that the lock may take hundreds of times longer to complete than the actual copying.


When you compute an average lock time it will probably say very little as it is measured on your machine which may not be the intended target (which may have entirely different bus usage characteristics). For your machine the average will be made up of individual very fast times (when the bus-mastering activities didn't interfere) all the way up to very slow times (when bus-mastering interference was significant).

You could introduce code which determines the fastest and slowest cases and calculate the quotient to see just how greatly the spinlock times can vary.

share|improve this answer

Just asking:

Before you dig that deep into spinlock and nearly-lockless data structures:

Have you - in your benchmarks and your application - made sure that the competing threads are guaranteed to run on different cores?

If not you may end up with a program that works great on your development machine but sucks/fails hard in the field because one thread has to be both the locker and unlocker of your spinlock.

To give you a figure: On Windows you have standard time-slice of 10 milliseconds. If you don't make sure that two physical threads are involved in locking/unlocking you'll end up with around 500 locks/unlocks per second, and this result will be very meh

share|improve this answer
Of course one thread has to lock/unlock the spin lock. Or else it won't protect anything. And there's no reason why a thread will acquire the lock, be descheduled and then unlock for each time slice. – dave Aug 15 '12 at 5:15

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