I need a high-resolution timer for the embedded profiler in the Linux build of our application. Our profiler measures scopes as small as individual functions, so it needs a timer precision of better than 25 nanoseconds.

Previously our implementation used inline assembly and the rdtsc operation to query the high-frequency timer from the CPU directly, but this is problematic and requires frequent recalibration.

So I tried using the clock_gettime function instead to query CLOCK_PROCESS_CPUTIME_ID. The docs allege this gives me nanosecond timing, but I found that the overhead of a single call to clock_gettime() was over 250ns. That makes it impossible to time events 100ns long, and having such high overhead on the timer function seriously drags down app performance, distorting the profiles beyond value. (We have hundreds of thousands of profiling nodes per second.)

Is there a way to call clock_gettime() that has less than ¼μs overhead? Or is there some other way that I can reliably get the timestamp counter with <25ns overhead? Or am I stuck with using rdtsc?

Below is the code I used to time clock_gettime().

// calls gettimeofday() to return wall-clock time in seconds:
extern double Get_FloatTime();
enum { TESTRUNS = 1024*1024*4 };

// time the high-frequency timer against the wall clock
    double fa = Get_FloatTime();
    timespec spec; 
    clock_getres( CLOCK_PROCESS_CPUTIME_ID, &spec );
    printf("CLOCK_PROCESS_CPUTIME_ID resolution: %ld sec %ld nano\n", 
            spec.tv_sec, spec.tv_nsec );
    for ( int i = 0 ; i < TESTRUNS ; ++ i )
        clock_gettime( CLOCK_PROCESS_CPUTIME_ID, &spec );
    double fb = Get_FloatTime();
    printf( "clock_gettime %d iterations : %.6f msec %.3f microsec / call\n",
        TESTRUNS, ( fb - fa ) * 1000.0, (( fb - fa ) * 1000000.0) / TESTRUNS );


CLOCK_PROCESS_CPUTIME_ID resolution: 0 sec 1 nano
clock_gettime 8388608 iterations : 3115.784947 msec 0.371 microsec / call
CLOCK_MONOTONIC resolution: 0 sec 1 nano
clock_gettime 8388608 iterations : 2505.122119 msec 0.299 microsec / call
CLOCK_REALTIME resolution: 0 sec 1 nano
clock_gettime 8388608 iterations : 2456.186031 msec 0.293 microsec / call
CLOCK_THREAD_CPUTIME_ID resolution: 0 sec 1 nano
clock_gettime 8388608 iterations : 2956.633930 msec 0.352 microsec / call

This is on a standard Ubuntu kernel. The app is a port of a Windows app (where our rdtsc inline assembly works just fine).


Does x86-64 GCC have some intrinsic equivalent to __rdtsc(), so I can at least avoid inline assembly?

  • The answers to this question may be helpful to you: stackoverflow.com/questions/638269/… – Steven T. Snyder Oct 28 '11 at 22:36
  • @Crash: My sympathies :) Wanna have a bake-off some time? Who can speed up some code the most? – Mike Dunlavey Oct 28 '11 at 23:26
  • @Mike I wish! Right now I'm in more of a "we need to speed up this code by 20% or we're totally screwed" kind of situation. And looking at the function list in a sampling profiler, there's not a one over 2% of the main loop. (I tried your stopwatch-and-debugger-break trick and got twenty different callstacks from twenty different pauses.) – Crashworks Nov 2 '11 at 2:54
  • @Crash: I'm sure you did. What I do is look at each sample and just explain to myself (make a description, on paper or in my head) what the program was doing at that time and why it was doing it. That means paying attention to the source code at each level of the stack. (It might also mean looking at other state information, like related variables.) If there's something that doesn't strictly have to be done, and if you see a similar thing on >1 sample, go fix it and get your speedup. Your code could be really tight, but if there's anything to be squeezed out, this should find it. – Mike Dunlavey Nov 2 '11 at 14:29
  • @Crash: Example, bear with me. I often find samples in data structure code, like indexing, incrementing iterators, or testing for end conditions. I could see this on different lines of code in different routines, so no line of code or routine rises to a significant percent. Even just one of those things, like indexing or incrementing, might not rise to a significant percent. But taken together, they could. Often plain old arrays, while maybe less orthodox, can save all that time. – Mike Dunlavey Nov 2 '11 at 17:07

No. You'll have to use platform-specific code to do it. On x86 and x86-64, you can use 'rdtsc' to read the Time Stamp Counter.

Just port the rdtsc assembly you're using.

__inline__ uint64_t rdtsc(void) {
  uint32_t lo, hi;
  __asm__ __volatile__ (      // serialize
  "xorl %%eax,%%eax \n        cpuid"
  ::: "%rax", "%rbx", "%rcx", "%rdx");
  /* We cannot use "=A", since this would use %rax on x86_64 and return only the lower 32bits of the TSC */
  __asm__ __volatile__ ("rdtsc" : "=a" (lo), "=d" (hi));
  return (uint64_t)hi << 32 | lo;
  • He said his previous implementation used rdtsc but had problems and didn't like having to recalibrate. – Steven T. Snyder Oct 28 '11 at 22:33
  • 5
    Those problems are six years out of date and now part of the dustbin of history. You are unlikely to see a modern server without constant TSC. – David Schwartz Oct 28 '11 at 22:34
  • 2
    @David Do you have some sources to back that up? How have the timing issues related to multi-CPU synchronization and clock-throttling power saving features changed in the last few years? – Steven T. Snyder Oct 28 '11 at 22:39
  • 5
    If you check /proc/cpuinfo, you should see 'constant_tsc' on every modern CPU. If the TSCs are not synchronized across cores or are not constant when they should be, that's a bug. (You should report it.) – David Schwartz Oct 28 '11 at 23:12
  • 2
    I agree with @DavidSchwartz : e.g. for my sandy bridge box : i see flags : fpu vme de pse tsc msr pae mce cx8 apic sep mtrr pge mca cmov pat pse36 clflush dts acpi mmx fxsr sse sse2 ss ht tm pbe syscall nx pdpe1gb rdtscp lm constant_tsc arch_perfmon pebs bts rep_good nopl pni monitor ds_cpl vmx smx est tm2 ssse3 cx16 xtpr dca sse4_1 sse4_2 x2apic popcnt lahf_lm ida constant_tsc set. also you may want to refer to download.intel.com/design/processor/manuals/253668.pdf section 16.12.1 "Invariant TSC" – Jay D Jun 7 '12 at 23:25

I ran some benchmarks on my system which is a quad core E5645 Xeon supporting a constant TSC running kernel 3.2.54 and the results were:

clock_gettime(CLOCK_MONOTONIC_RAW)       100ns/call
clock_gettime(CLOCK_MONOTONIC)           25ns/call
clock_gettime(CLOCK_REALTIME)            25ns/call
clock_gettime(CLOCK_PROCESS_CPUTIME_ID)  400ns/call
rdtsc (implementation @DavidSchwarz)     600ns/call

So it looks like on a reasonably modern system the (accepted answer) rdtsc is the worst route to go down.

  • 1
    not sure how exactly you have measured this but I see entirely different results (1e9 times calling each options). rdtsc is significantly faster than [CLOCK_REALTIME] option – Nuray Altin Oct 12 '16 at 20:18
  • On my 2.6.32-431.el6.x86_64 and 3.10.0-693.21.1.el7.x86_64 box, rdtsc is about 80% faster than clock_gettime(). One is i7 and another Xeon. – Hei Mar 26 '18 at 5:47
  • Something is wrong with the rdtsc option here: it should be around 20 ns per call. The fastest clock_gettime options (the 25 ns ones) are based on rdtsc, plus some extra work to turn the time into wall-clock time so they can't really be faster. – BeeOnRope May 24 '18 at 6:53

I need a high-resolution timer for the embedded profiler in the Linux build of our application. Our profiler measures scopes as small as individual functions, so it needs a timer precision of better than 25 nanoseconds.

Have you considered oprofile or perf? You can use the performance counter hardware on your CPU to get profiling data without adding instrumentation to the code itself. You can see data per-function, or even per-line-of-code. The "only" drawback is that it won't measure wall clock time consumed, it will measure CPU time consumed, so it's not appropriate for all investigations.

  • If I was just profiling on my bench, those would be fine. But I'm trying to fix an embedded instrumented profiler that we've used for a while, and on which many other of our tools depend. – Crashworks Oct 29 '11 at 20:13

Give clockid_t CLOCK_MONOTONIC_RAW a try?

CLOCK_MONOTONIC_RAW (since Linux 2.6.28; Linux-specific) Similar to CLOCK_MONOTONIC, but provides access to a raw hardware-based time that is not subject to NTP adjustments or the incremental adjustments performed by adjtime(3).

From Man7.org

  • On x86/x86_64 Linux (at least up to 4.15) the call to read the clock is actually slower with CLOCK_MONOTONIC_RAW (because it doesn't use the vDSO and makes a real syscall) in comparison to when CLOCK_MONOTONIC is used. See the results in stackoverflow.com/a/13096917/9109338 for some data. If this matters make sure you check your platform's behaviour! – Anon Feb 15 '18 at 6:40

You are calling clock_getttime with control parameter which means the api is branching through if-else tree to see what kind of time you want. I know you cant't avoid that with this call, but see if you can dig into the system code and call what the kernal is eventually calling directly. Also, I note that you are including the loop time (i++, and conditional branch).


Yes, most modern platforms will have a suitable clock_gettime call that is implemented purely in user-space using the VDSO mechanism, and will reliably take something like 20 to 30 nanoseconds to complete.

Internally, this is using rdtsc or rdtscp for the fine-grained portion of the time-keeping, plus adjustments to keep this in sync with wall-clock time (depending on the clock you choose) and a multiplication to convert from whatever units rdtsc has on your platform to nanoseconds.

Not all of the clocks offered by clock_gettime will implement this fast method, and it's not always obvious which ones do. Usually CLOCK_MONOTONIC is a good option, but you should test this on your own system.

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