Sign up ×
Stack Overflow is a community of 4.7 million programmers, just like you, helping each other. Join them, it only takes a minute:

To implement a spinlock in assembly. Here I post a solution I came up with. Is it correct? Do you know a shorter one?


    mov ecx, 0
    xchg [eax], ecx
    cmp ecx, 0
    je .loop


    lock dec dword [eax]

eax is initialized to -1 (which means lock is free). This should work for many threads (not necessarily 2).

share|improve this question
Note: xor ecx, ecx is favoured over mov ecx, 0 for size and speed. –  Polynomial Apr 8 '14 at 17:00
On another note, you missed the lock prefix from your first xchg. –  Polynomial Apr 8 '14 at 17:00
@Polynomial no need for the lock prefix on xchg, it is implied. –  Jester Apr 8 '14 at 17:03
@Jester Ah yes, I forgot about that. –  Polynomial Apr 8 '14 at 17:05

3 Answers 3

up vote 4 down vote accepted

Shortest would probably be:

    lock bts [eax],0
    jc acquire

    mov [eax],0

For performance, it's best to use a "test, test and set" approach, and use pause, like this:

    lock bts [eax],0    ;Optimistic first attempt
    jnc l2              ;Success if acquired
    test [eax],1        
    jne l1              ;Don't attempt again unless there's a chance

    lock bts [eax],0    ;Attempt to acquire
    jc l1               ;Wait again if failed


    mov [eax],0

For debugging, you can add extra data to make it easier to detect problems, like this:

    lock bts [eax],31         ;Optimistic first attempt
    jnc l2                    ;Success if acquired

    mov ebx,[CPUnumber]
    lea ebx,[ebx+0x80000000]
    cmp [eax],ebx             ;Is the lock acquired by this CPU?
    je .bad                   ; yes, deadlock
    lock inc dword [eax+4]    ;Increase "lock contention counter"
    test [eax],0x80000000        
    jne l1                    ;Don't attempt again unless there's a chance

    lock bts [eax],31         ;Attempt to acquire
    jc l1                     ;Wait again if failed

l2: mov [eax],ebx             ;Store CPU number

    mov ebx,[CPUnumber]
    lea ebx,[ebx+0x80000000]
    cmp [eax],ebx             ;Is lock acquired, and is CPU same?
    jne .bad                  ; no, either not acquired or wrong CPU
    mov [eax],0
share|improve this answer
If the first attempt succeeds, wouldn't it store junk in [eax]? (in the debugging version) –  harold Apr 8 '14 at 18:41
@harold: It uses one bit for the lock, and the remaining 31 bits to keep track of who acquired the lock (so that it can detect when you're releasing a lock that you didn't acquire but someone else did; and deadlocks). –  Brendan Apr 8 '14 at 18:55
Yes but I mean ebx hasn't been set to a sensible value yet if you take that path, right? –  harold Apr 8 '14 at 18:59

Your code is fine, but if you're looking for high performance I'd suggest this instead:

  xor ecx, ecx
  lock xchg [eax], ecx
  test ecx, ecx
  jz .loop


  • xor ecx, ecx is smaller and doesn't require a literal, and modern CPUs have this hardwired to fast register zero.
  • test ecx, ecx can be marginally smaller and faster than cmp ecx, 0, because you don't need to load a literal and test is just a bitwise AND operation rather than a subtraction.

P.S. I always put the lock prefix in there regardless of whether it is implied, for readability reasons - it makes it obvious that I'm doing a locked operation.

share|improve this answer
Note that the prefix isn't free - it occupies a byte. That's hardly the end of the world, but if you are paying attention to the size of the other instructions... –  gsg Apr 8 '14 at 18:18
@gsg I just checked on my compiler, and it doesn't add the additional byte for the lock prefix, as it detects that it's superfluous on xchg. –  Polynomial Apr 8 '14 at 18:39
Huh, ok. I checked gcc and as, which both do. Know your tools, I guess. –  gsg Apr 8 '14 at 18:44
I'm a Windows-monkey, no gcc for me! ;] –  Polynomial Apr 8 '14 at 18:45
High performance? With bus-locking? –  Olof Forshell Apr 9 '14 at 8:58

Your code is fine and you can always try to make it shorter if you have space problems.

Other answers mention performance and that displays a basic ignorance of how locks work.

When an attempt to lock is initiated the CPU in question raises a signal on one of its pins (LOCK) which tells all cores, all memory and all bus-mastering devices (because they can independently update RAM) to complete any outstanding memory operations. When they have done this they collectively raise another signal - lock acknowledge (LOCKA) - which is returned to the CPU and the memory exchange takes place. After this the LOCK signal is switched off.

Once you have arrived here you are able to look at the value you fetched using xchg. If it turns out that another task/thread owns the lock you will need to perform the lock sequence all over again.

Assume the slowest bus-mastering device anywhere on your computer is a 33MHz PCI card. If it is doing something it will need any number of bus clock cycles to complete. Every cycle there means one hundred wait cycles on a 3.3GHz CPU. Put this in the perspective of saving a cycle or two in the lock sequence. The lock completion time varies with the memory activity on the host.

Try it yourself: measure how long it takes to do ten million spinlocks (grab and release).

I wrote some more on spinlocks here, here and here.

The performance trick with bus-locks (spinlocks, critical sections in Windows) is to use them as seldom as possible which means organizing your data to make this possible. A bus-lock will likely complete faster on a non-server computer. This is because the bus-mastering devices on a server are operating more or less constantly. So if your application is server-based economizing on bus-locks can be critical to maintain performance.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.