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On most moder 64-bit processors (such as Intel Core 2 Duo or the Intel i7 series), does the speed of the x86_64 command mulq and its variants depend on the operands? For example, will multiplying 11 * 13 be faster than 11111111 * 13131313? Or does it always take the time of the worst case?

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Its speed does not depend on the values of the operands. –  harold Jun 5 '12 at 19:58
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if it were floating point multiplication, I would say denormals as operands might slow it down, but since this is integer multiplication, this does not apply. –  noah1989 Jun 6 '12 at 9:05

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I don't have any reference to hand, but I would place money on the latency/throughput being invariant of the values of the operands. Otherwise, it would be a nightmare to schedule.

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Nightmare might be a bit strong. There are all sorts of operations in a CPU with variable latency (loads, integer divide, many floating point operations, various CISCy type instructions). The main reason that it is fixed latency is because it is so important that they put the transistors into it to make it fast (like 3 cycles). The vast majority of operands would take 3 cycles and since it would be expensive and difficult to predict operands that would take 2 cycles or 1 it's not worth it given the penalty for mispredicting the hazard. It is also easy to hide a 3 cycle latency. –  Nathan Binkert Jun 8 '12 at 5:38

TL;DR: No. Constant-length integer math operations (barring division, which is non-linear) consume a constant number of cycles, regardless of the numerical value of the operands.

mulq takes two QWORD arguments.

The values are represented in little-endian binary format (used by x86 architecture) as follows:

1011000000000000000000000000000000000000000000000000000000000000 =       13
1000110001111010000100110000000000000000000000000000000000000000 = 13131313

The processor sees both of these as the same "size", as both are 64-bit values.

Therefore, the cycle count should always be the same, regardless of the actual numerical value of the operands.

More info:

There are the concepts of Leading Zero Anticipation and Leading Zero Detection[1][2] (LZA/LZD) that can be employed to speed up floating-point operations.

To the best of my knowledge however, there are no mainstream processors that employ either of these methods towards integer arithmetic. This is most likely due to the simplistic nature of most integer arithmetic (multiplication in this case). The overhead of LZA/LZD may simply not be worth it, for simple integer math circuits that can complete the full multiplication in less time anyhow.

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Yeah but I heard that there are processors that can tell if the multiplication finished early (like if the rest of the bits are 0s). –  Matt Jun 5 '12 at 19:52
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@Matt - You may be referring to LZA/LZD as described in research.ibm.com/arl/publications/papers/arithlza.PDF or fdi.ucm.es/profesor/mozos/AEC/lza.pdf AFAIK, no such equivalent exists in mainstream processors for integer mathematics. –  Unsigned Jun 5 '12 at 19:58
    
Your link only talks about floating point arithmetic. –  Matt Jun 5 '12 at 20:02
    
@Matt - "AFAIK, no such equivalent exists in mainstream processors for integer mathematics." I have edited my answer as well. –  Unsigned Jun 5 '12 at 20:09
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On your tldr, well, there's also division.. –  harold Jun 5 '12 at 21:05

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