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I have read various optimization guides that claim ADD 1 is faster than using INC in x86. Is this really true?

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possible duplicate of Relative performance of x86 inc vs. add instruction – unwind Nov 14 '12 at 16:55
Why not test it? – A. Webb Nov 14 '12 at 16:56
@A.Webb because it depends on the microarchitecture and the context. He'd have to do complicated tests on a lot of different cpu's. Why do that if you can just ask? – harold Nov 14 '12 at 17:03
@harold: to be fair, everyone can test this themselves. The only required materials are an x86 machine, an assembler and a stopwatch. Crafting an instruction stream to exhibit the difference requires a little creativity, but it's not rocket science (for that matter, rocket science isn't rocket science). – Stephen Canon Nov 14 '12 at 17:43
Really guys, this is a hard one. If it was "add vs and" or something like that then sure, anyone could figure it out. But this is altogether different. Most people are just going to throw an inc and an add in a loop and they would conclude there is no difference. And there would be no indication that the answer was inaccurate. – harold Nov 14 '12 at 22:59

2 Answers 2

up vote 14 down vote accepted

On some micro-architectures, with some instruction streams, INC will incur a "partial flags update stall" (because it updates some of the flags while preserving the others). ADD sets the value of all of the flags, and so does not risk such a stall.

ADD is not always faster than INC, but it is almost always at least as fast (there are a few corner cases on certain older micro-architectures, but they are exceedingly rare), and sometimes significantly faster.

For more details, consult Intel's Optimization Reference Manual or Agner Fog's micro-architecture notes.

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+1, the true master of low-level optimization. – Mysticial Nov 14 '12 at 17:26
Today anyways, was quite different back when I started programming. Back then INC was faster. :-) – Brian Knoblauch Nov 14 '12 at 20:24
When P4 was current, add was preferred. Now that P4 is more or less dead and buried, inc is preferred in most cases because it's shorter, and runs at the same speed as add. If you want to avoid modifying the carry flag, use lea reg, [reg+1] to not modify any flags, avoiding the dreaded partial-flag stall. Or if possible, avoid doing the increment between the flag producer and flag consumer. AMD K8 through Steamroller, and Intel P6 / Sandybridge families all track flag dependencies separately for different flag bits. e.g. CF is tracked by itself, to avoid false deps like with inc – Peter Cordes Oct 28 at 7:17

In 80's or 90's simple instruction execution times were primarily determined by the number of components in the instruction: add ax,1 contains one more decodable unit (the immediate) compared to, inc ax, or add ax,bx. And thus the 80286 spent one more clock cycle to decode the instruction.

Then there was/is the era, when intel particularly optimized most RISC type instructions at the expense of CISC type instructions. (eg. add ax,[mem]; add [mem],ax). Today or at least tomorrow, those are cheap... Complex branch sequences will be resolved in 30-unit pipeline that does automatic register renaming.

So, we are more likely now at the era, where inc eax is CISC, aka bad and add eax,1 is RISC, which is good. But these things can change over night.

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Somehow I doubt you read the question .. or the other answer. – harold Nov 14 '12 at 17:23
Its really not easy to answer this question. It depends on the underlying micro architecture. I agree with you, the reason for that has to do with some trends in the past and will change with the new trends in the future. – David J Nov 15 '12 at 2:41

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