Consider:

#include <time.h>
#include <unistd.h>
#include <iostream>
using namespace std;

const int times = 1000;
const int N = 100000;

void run() {
  for (int j = 0; j < N; j++) {
  }
}

int main() {
  clock_t main_start = clock();
  for (int i = 0; i < times; i++) {
    clock_t start = clock();
    run();
    cout << "cost: " << (clock() - start) / 1000.0 << " ms." << endl;
    //usleep(1000);
  }
  cout << "total cost: " << (clock() - main_start) / 1000.0 << " ms." << endl;
}

Here is the example code. In the first 26 iterations of the timing loop, the run function costs about 0.4 ms, but then the cost reduces to 0.2 ms.

When the usleep is uncommented, the delay-loop takes 0.4 ms for all runs, never speeding up. Why?

The code is compiled with g++ -O0 (no optimization), so the delay loop isn't optimized away. It's run on Intel(R) Core(TM) i3-3220 CPU @ 3.30 GHz, with 3.13.0-32-generic Ubuntu 14.04.1 LTS (Trusty Tahr).

  • You should probably check the result of usleep() as it may be interrupted or it may do nothing because your parameter isn't valid. This would make any timings unreliable. – John3136 Jul 11 '16 at 4:11
  • @John3136: The usleep is outside the timing window. He's timing a busy-loop either back to back or separated by 1ms sleeps. – Peter Cordes Jul 11 '16 at 6:00
  • 1
    For benchmarking purposes, you should compile with gcc -O2 or (since your code is C++) g++ -O2 at least. – Basile Starynkevitch Jul 11 '16 at 8:02
  • @BasileStarynkevitch: Problem with that in the present example: At any optimization level, the compiler would dead-strip the whole code. (Which leads to the question: Why would I want to benchmark an empty, invariant loop in the first place?). – Damon Jul 11 '16 at 15:00
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    @AdrianMcCarthy: the usleep is outside the timing window – Peter Cordes Jul 12 '16 at 22:43
up vote 121 down vote accepted

After 26 iterations, Linux ramps the CPU up to the maximum clock speed since your process uses its full time slice a couple of times in a row.

If you checked with performance counters instead of wall-clock time, you'd see that the core clock cycles per delay-loop stayed constant, confirming that it's just an effect of DVFS (which all modern CPUs use to run at a more energy-efficient frequency and voltage most of the time).

If you tested on a Skylake with kernel support for the new power-management mode (where the hardware takes full control of the clock speed), ramp-up would happen much faster.

If you leave it running for a while on an Intel CPU with Turbo, you'll probably see the time per iteration increase again slightly once thermal limits require the clock speed to reduce back down to the maximum sustained frequency.


Introducing a usleep prevents Linux's CPU frequency governor from ramping up the clock speed, because the process isn't generating 100% load even at minimum frequency. (I.e. the kernel's heuristic decides that the CPU is running fast enough for the workload that's running on it.)



comments on other theories:

re: David's theory that a potential context switch from usleep could pollute caches: That's not a bad idea in general, but it doesn't help explain this code.

Cache / TLB pollution isn't important at all for this experiment. There's basically nothing inside the timing window that touches memory other than the end of the stack. Most of the time is spent in a tiny loop (1 line of instruction cache) that only touches one int of stack memory. Any potential cache pollution during usleep is a tiny fraction of the time for this code (real code will be different)!

In more detail for x86:

The call to clock() itself might cache-miss, but a code-fetch cache miss delays the starting-time measurement, rather than being part of what's measured. The second call to clock() will almost never be delayed, because it should still be hot in cache.

The run function may be in a different cache line from main (since gcc marks main as "cold", so it gets optimized less and placed with other cold functions/data). We can expect one or two instruction-cache misses. They're probably still in the same 4k page, though, so main will have triggered the potential TLB miss before entering the timed region of the program.

gcc -O0 will compile the OP's code to something like this (Godbolt Compiler explorer): keeping the loop counter in memory on the stack.

The empty loop keeps the loop counter in stack memory, so on a typical Intel x86 CPU the loop runs at one iteration per ~6 cycles on the OP's IvyBridge CPU, thanks to the store-forwarding latency that's part of add with a memory destination (read-modify-write). 100k iterations * 6 cycles/iteration is 600k cycles, which dominates the contribution of at most a couple cache misses (~200 cycles each for code-fetch misses which prevent further instructions from issuing until they're resolved).

Out-of-order execution and store-forwarding should mostly hide the potential cache miss on accessing the stack (as part of the call instruction).

Even if the loop-counter was kept in a register, 100k cycles is a lot.

  • I increase the value of N by 100x and use cpufreq-info command, I found the cpu is still work on the minimum frequency when the code is running. – phyxnj Jul 11 '16 at 7:17
  • @phyxnj: with usleep un-commented? It ramps up for me with N=10000000. (I use grep MHz /proc/cpuinfo since I never got around to installing cpufreq-utils on this machine). Actually I just found that cpupower frequency-info shows what cpufreq-info did, for one core. – Peter Cordes Jul 11 '16 at 7:30
  • @phyxnj: are you sure you're looking at all cores, and not just one core? cpupower seems to default to just core 0. – Peter Cordes Jul 11 '16 at 7:34
  • grep MHz /proc/cpuinfo shows cpu frequency increase indeed. cpufreq-info maybe monitor a random core of cpu. I think you are right, maybe this is the cause of the problem. – phyxnj Jul 11 '16 at 7:42
  • 1
    @phyxnj: It's not random, and the core number is printed out in the output. e.g. thinkwiki.org/wiki/How_to_use_cpufrequtils. It almost certainly defaults to core 0 only. The only thing that's unpredictable is which core your process will run on. – Peter Cordes Jul 11 '16 at 8:33

A call to usleep may or may not result in a context switch. If it does, it will take longer than if it doesn't.

  • 1
    usleep relinquishes the CPU voluntarily, so there should be a context switch for sure (even if the system is idle), isn't it? – rakib_ Jul 11 '16 at 4:49
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    @rakib Not if there's nothing to switch contexts to or if the time interval is too short. When you're talking about less than 10ms or so, the OS may decide not to do a context switch. – David Schwartz Jul 11 '16 at 4:59
  • @rakib: There's a switch to kernel mode and back for sure. There might not be a switch to another process before resuming the process that called usleep, so pollution of caches / TLBs / branch predictors may be minimal. – Peter Cordes Jul 11 '16 at 5:52
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    @rakib Then schedule figures out how long until the next thing it has to do and then decides how to wait, possibly scheduling something else, possibly using a hardware timer, possibly not. – David Schwartz Jul 11 '16 at 6:42
  • 1
    @rakib: If nothing significant runs on the CPU before it returns to the caller of usleep, some people would say there was no context switch, even if the hardware went to sleep (with a hlt instruction) for a short time. There's definitely minimal cache / TLB pollution in that case, and IIRC no TLB invalidation. (I forget exactly how the page tables for kernel mode work, but I don't think the whole TLB has to be blown away every system call). – Peter Cordes Jul 11 '16 at 7:24

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