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Let's say I want to benchmark two competing implementations of some function double a(double b, double c). I already have a large array <double, 1000000> vals from which I can take input values, so my benchmarking would look roughly like this:

//start timer here
double r;
for (int i = 0; i < 1000000; i+=2) {
    r = a(vals[i], vals[i+1]);
//stop timer here

Now, a clever compiler could realize that I can only ever use the result of the last iteration and simply kill the rest, leaving me with double r = a(vals[999998], vals[999999]). This of course defeats the purpose of benchmarking.

Is there a good way (bonus points if it works on multiple compilers) to prevent this kind of optimization while keeping all other optimizations in place?

(I have seen other threads about inserting empty asm blocks but I'm worried that might prevent inlining or reordering. I'm also not particularly fond of the idea of adding the results sum += r; during each iteration because that's extra work that should not be included in the resulting timings. For the purposes of this question, it would be great if we could focus on other alternative solutions, although for anyone interested in this there is a lively discussion in the comments where the consensus is that += is the most appropriate method in many cases. )

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Why should you want to do that, exactly? –  Bartek Banachewicz Mar 9 '13 at 11:12
Then use += for both versions. –  Mysticial Mar 9 '13 at 11:13
@us2012 I highly doubt that a += is going to be "too much overhead" based on what I'm seeing so far. –  Mysticial Mar 9 '13 at 11:15
@us2012: that is the general way to tackle it. There are plenty of specialized ways to do it (place the function in a separate translation unit and disable link-time code gen, or place it in a dll, so the compiler doesn't know the function call could be omitted. But the general approach is to make sure the result from the call is used. And if you care about performance, then you owe it to yourself to have at least a basic understanding of modern CPU performance. And then you'll know that the overhead of that += operation is basically nil. –  jalf Mar 9 '13 at 11:17
By the way, I love that your question states that you're worried about solutions that may prevent inlining, and then you accept the answer which guarantees* that inlining will be prevented, and which involves actually disabling certain compiler optimizations. While, apparently, ignoring the solution that will allow the compiler to inline as much as it would otherwise. –  jalf Mar 9 '13 at 12:22

1 Answer 1

up vote 3 down vote accepted

Put a in a separate compilation unit and do not use LTO (link-time optimizations). That way:

  • The loop is always identical (no difference due to optimizations based on a)
  • The overhead of the function call is always the same
  • To measure the pure overhead and to have a baseline to compare implementations, just benchmark an empty version of a

Note that the compiler can not assume that the call to a has no side-effect, so it can not optimize the loop away and replace it with just the last call.

A totally different approach could use RDTSC, which is a hardware register in the CPU core that measures the clock cycles. It's sometimes useful for micro-benchmarks, but it's not exactly trivial to understand the results correctly. For example, check out this and goggle/search SO for more information on RDTSCs.

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That will prevent inlining though, no? –  us2012 Mar 9 '13 at 11:20
Yes, as without LTO the compiler can't inline a method from one TU into another TU. –  Daniel Frey Mar 9 '13 at 11:21
@us2012: Added RDTSC, maybe that's an option/idea for you? –  Daniel Frey Mar 9 '13 at 11:43
@us2012 It might be useful to know that RDTSC has a variable overhead that is almost 100x the cost of a +=. –  Mysticial Mar 9 '13 at 11:50
@Mysticial: True, that's why I linked that other SO qeustion. If us2012 really goes down that rabbit hole, I'm pretty sure we will see some more questions from him/her in the near future :) –  Daniel Frey Mar 9 '13 at 11:53

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