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I've made a compiler for a general-purpose programming language. As part of the toolchain, I'd like to include a profiler with the ability to estimate the time complexity of a given expression. It seems fairly straightforward to calculate the algorithmic complexity—that is, assuming all constant-time operations take the same amount of time—but I'd like to be able to approximate the real complexity as well. To do that, I need information on the relative performance of individual processor operations such as inc, add, mul, etc., as well as certain higher-level operations such as I/O.

I realise this is both architecture- and implementation-dependent, may yield only fuzzy results at best, and is something of a dual question. But does anyone happen to know of any high-quality resources available to get me started? Would looking at open-source implementations of higher-level operations give me enough information to provide a fair estimate of their complexities?

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How is this different from the halting problem? ( ) – cHao Aug 8 '10 at 23:08
The crux of the problem is that you can't always know whether some random program will halt...and you're not going to get an even nearly useful estimate short of actually running the program. I mean, if you wanna try, go for it. But people way smarter than you have proven that what you're looking to do is effectively impossible in the general case -- and the general case is exactly what you're going to need to handle. – cHao Aug 8 '10 at 23:49
@cHao: Setting aside the problem of what constitutes a "random program", the undecideability of the Halting Problem does not mean that we can't determine running times for all or even most programs of interest. It just means that there exist programs for which this is the case. – Rob Lachlan Aug 8 '10 at 23:56
@cHao: See, for instance: – Rob Lachlan Aug 9 '10 at 0:00
@Rob: Thanks for a good explanation that I now don't have to write. @cHao: It may not be possible to detect, in the general case, whether an application will halt, but I'm not asking about that at all. I'm am asking about the specific case of determining the complexity of a definitely-halting expression. All of this talk about whether or not it's related to the halting problem is only detracting from the original question. I simply want general guidelines for how much more expensive operation A is than operation B, especially in the case that they have the same time complexity. – Jon Purdy Aug 9 '10 at 0:28
up vote 2 down vote accepted

On most modern CPUs, the concept of "cycle time for a particular instruction" is not especially helpful. The pipeline will be handling multiple instructions at once, and they will be competing for various resources inside the CPU - so the performance of a given instruction can only be understood in the context of the surrounding instructions. And the details will vary significantly, within even the different models in a processor family.

Furthermore, if you're doing anything that is touching data, then cache behaviour is likely to be just as important as instruction execution times.

For x86: have a look at Agner Fog's "Software optimization resources".

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+1 for the useful link. – Jon Purdy Aug 9 '10 at 0:34

Intel has some information about their assembly implementation in their articles database. The good ones are pretty dense (like this 600-page PDF file), but they've got a lot of interesting information, including some tables with approximate latency times. There's also a table with some latency times for their 64-bit architecture, so you might be able to search for a similar 32-bit one if you want it.

I personally have no idea about any information for AMD's processors. Google might turn up some results, but I haven't used an AMD machine since the Athlon 3000 days, so I haven't had the need to look for this kind of information.

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Ugh. That first one looks very close to what I was looking for. Now if I can just extract the information that I need from the forest of what I don't... – Jon Purdy Aug 8 '10 at 23:36
The tables are fairly noticeable if you skim through...but, like I said, definitely dense... – eldarerathis Aug 8 '10 at 23:37

From what I know:
inc: min O(1) max O(log n)
add, sub: O(log n)
mul, div: O(n)

malloc: O(n*m) n is size allocated, m is number of previous allocations.
free: O(1) (sometimes O(log m)).

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As I said, algorithmic complexity is comparatively simple. I'm looking for specific details on which operations of a given algorithmic complexity are faster than which others, in terms of processor cycles. – Jon Purdy Aug 8 '10 at 23:44

The group of Reinhard Wilhelm in Saarbrücken does research on timing analysis, including cache behavior.

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