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Two common locking idioms are:

if (!atomic_swap(lockaddr, 1)) /* got the lock */

and:

if (!atomic_compare_and_swap(lockaddr, 0, val)) /* got the lock */

where val could simply be a constant or an identifier for the new prospective owner of the lock.

What I'd like to know is whether there tends to be any significant performance difference between the two on x86 (and x86_64) machines. I know this is a fairly broad question since the answer might vary a lot between individual cpu models, but that's part of the reason I'm asking SO rather than just doing benchmarks on a few cpus I have access to.

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+1 just for braving the "profile it!" and "don't even think about it unless it's a proven bottleneck!" comments :-) –  Steve Jessop Mar 17 '11 at 13:42
    
Just to make it worse, I'd not be surprised that the contention and the nature of the parallelism available (one multi-core processor or multiple processors) may be also an important factor. –  AProgrammer Mar 17 '11 at 14:04
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3 Answers

up vote 5 down vote accepted

I assume atomic_swap(lockaddr, 1) gets translated to a xchg reg,mem instruction and atomic_compare_and_swap(lockaddr, 0, val) gets translated to a cmpxchg[8b|16b].

Some linux kernel developers think cmpxchg ist faster, because the lock prefix isn't implied as with xchg. So if you are on a uniprocessor, multithread or can otherwise make sure the lock isn't needed, you are probably better of with cmpxchg.

But chances are your compiler will translate it to a "lock cmpxchg" and in that case it doesn't really matter. Also note that while latencies for this instructions are low (1 cycle without lock and about 20 with lock), if you happen to use are common sync variable between two threads, which is quite usual, some additional bus cycles will be enforced, which last forever compared to the instruction latencies. These will most likely completly be hidden by a 200 or 500 cpu cycles long cache snoop/sync/mem access/bus lock/whatever.

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+1 and thanks for the link. I want to accept an answer but I'm not sure which one to go with - neither really covers the topic completely but both have good info. –  R.. Mar 30 '11 at 12:40
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I found this Intel document, stating that there is no difference in practice:

http://software.intel.com/en-us/articles/implementing-scalable-atomic-locks-for-multi-core-intel-em64t-and-ia32-architectures/

One common myth is that the lock utilizing a cmpxchg instruction is cheaper than a lock utilizing an xchg instruction. This is used because cmpxchg will not attempt to get the lock in exclusive mode since the cmp will go through first. Figure 9 shows that the cmpxchg is just as expensive as the xchg instruction.

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+1 for the link. That myth makes no sense though. I would naively assume the xchg would be cheaper, just because (1) it's less powerful, and (2) cmpxchg has "more to do" while the bus lock (or whatever mechanism) is held. –  R.. Mar 17 '11 at 16:05
    
The myth makes perfect sense. xchg always locks the bus, so it's normally (without the lock prefix) slower. But for atomic operations you'll need to use "lock cmpxchg" which is just as slow as "lock xchg". And there isn't really more for the CPU to do, not really, both are "load something save", the slow part is the load and save, the something (swap or compare and swap) takes no time at all in CPU. In fact, cmpxchg can be faster if it fails the comparison, e.g. it won't need to save. –  Martin Mar 8 at 5:50
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On x86, any instruction with a LOCK prefix does all memory operations as read-modify-write cycles. This means that XCHG (with its implicit LOCK) and LOCK CMPXCHG (in all cases, even if the comparison fails) always get an exclusive lock on the cache line. The result is that there is basically no difference in performance.

Note that many CPUs all spinning on the same lock can cause a lot of bus overhead in this model. This is one reason that spin-lock loops should contain PAUSE instructions. Some other architectures have better operations for this.

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