I saw this post on SO which contains C code to get the latest CPU Cycle count:

CPU Cycle count based profiling in C/C++ Linux x86_64

Is there a way I can use this code in C++ (windows and linux solutions welcome)? Although written in C (and C being a subset of C++) I am not too certain if this code would work in a C++ project and if not, how to translate it?

I am using x86-64

EDIT2:

Found this function but cannot get VS2010 to recognise the assembler. Do I need to include anything? (I believe I have to swap uint64_t to long long for windows....?)

static inline uint64_t get_cycles()
{
  uint64_t t;
  __asm volatile ("rdtsc" : "=A"(t));
  return t;
}

EDIT3:

From above code I get the error:

"error C2400: inline assembler syntax error in 'opcode'; found 'data type'"

Could someone please help?

  • 1
    "C++ being a subset of C" - did you mean that the other way around? – Mysticial Dec 7 '12 at 23:20
  • @Mysticial yup :)- edited – user997112 Dec 7 '12 at 23:25
  • 1
    Visual Studio does not support assembly on x86-64. – Mark Ransom Dec 7 '12 at 23:31
  • @MarkRansom I presume you mean MSVC? I think I have the ICC compiler installed too and just to be sure I am just installing MinGW – user997112 Dec 7 '12 at 23:34
  • 1
    To get uint64_t you should #include <stdint.h> (actually <cstdint> but your compiler is probably too old to have that one.) – Nikos C. Dec 7 '12 at 23:36
up vote 47 down vote accepted

Starting from GCC 4.5 and later, the __rdtsc() intrinsic is now supported by both MSVC and GCC.

But the include that's needed is different:

#ifdef _WIN32
#include <intrin.h>
#else
#include <x86intrin.h>
#endif

Here's the original answer before GCC 4.5.

Pulled directly out of one of my projects:

#include <stdint.h>

//  Windows
#ifdef _WIN32

#include <intrin.h>
uint64_t rdtsc(){
    return __rdtsc();
}

//  Linux/GCC
#else

uint64_t rdtsc(){
    unsigned int lo,hi;
    __asm__ __volatile__ ("rdtsc" : "=a" (lo), "=d" (hi));
    return ((uint64_t)hi << 32) | lo;
}

#endif
  • That's a nice way to package it. – Nik Bougalis Dec 7 '12 at 23:44
  • Thank you Mystical – user997112 Dec 8 '12 at 0:07
  • 8
    FWIW, gcc 4.5 and newer include __rdtsc() -- #include <x86intrin.h> get it. Header also includes many other intel intrinsics found in Microsoft's <intrin.h>, and it gets included by default these days when you include most any of the SIMD headers -- emmintrin.h, xmmintrin.h, etc. – jstine Jan 18 '13 at 19:23
  • Fantastic, thank you! – CodeMouse92 Oct 8 '15 at 21:32
  • std::uint64_t x; asm volatile ("rdtsc" : "=A"(x)); is another way to read EAX and EDX together. – Orient Apr 27 at 13:32

VC++ uses an entirely different syntax for inline assembly -- but only in the 32-bit versions. The 64-bit compiler doesn't support inline assembly at all.

In this case, that's probably just as well -- rdtsc has (at least) two major problem when it comes to timing code sequences. First (like most instructions) it can be executed out of order, so if you're trying to time a short sequence of code, the rdtsc before and after that code might both be executed before it, or both after it, or what have you (I am fairly sure the two will always execute in order with respect to each other though, so at least the difference will never be negative).

Second, on a multi-core (or multiprocessor) system, one rdtsc might execute on one core/processor and the other on a different core/processor. In such a case, a negative result is entirely possible.

Generally speaking, if you want a precise timer under Windows, you're going to be better off using QueryPerformanceCounter.

If you really insist on using rdtsc, I believe you'll have to do it in a separate module written entirely in assembly language (or use a compiler intrinsic), then linked with your C or C++. I've never written that code for 64-bit mode, but in 32-bit mode it looks something like this:

   xor eax, eax
   cpuid
   xor eax, eax
   cpuid
   xor eax, eax
   cpuid
   rdtsc
   ; save eax, edx

   ; code you're going to time goes here

   xor eax, eax
   cpuid
   rdtsc

I know this looks strange, but it's actually right. You execute CPUID because it's a serializing instruction (can't be executed out of order) and is available in user mode. You execute it three times before you start timing because Intel documents the fact that the first execution can/will run at a different speed than the second (and what they recommend is three, so three it is).

Then you execute your code under test, another cpuid to force serialization, and the final rdtsc to get the time after the code finished.

Along with that, you want to use whatever means your OS supplies to force this all to run on one process/core. In most cases, you also want to force the code alignment -- changes in alignment can lead to fairly substantial differences in execution spee.

Finally you want to execute it a number of times -- and it's always possible it'll get interrupted in the middle of things (e.g., a task switch), so you need to be prepared for the possibility of an execution taking quite a bit longer than the rest -- e.g., 5 runs that take ~40-43 clock cycles apiece, and a sixth that takes 10000+ clock cycles. Clearly, in the latter case, you just throw out the outlier -- it's not from your code.

Summary: managing to execute the rdtsc instruction itself is (almost) the least of your worries. There's quite a bit more you need to do before you can get results from rdtsc that will actually mean anything.

  • I'm pretty sure when I was researching it, I found documentation that QueryPerformanceCounter (which is a thin veil over rdtsc) suffers from the same problem you identified on multicore/multiprocessor systems. But I think I also found documentation that this problem was a real problem on early systems because most BIOSes didn't even attempt to synchronize the counters on the different cores, but most newer BIOSes (perhaps not counting cheap junk machine BIOSes) do make that effort, so they may be off by only a few counts now. – phonetagger Dec 7 '12 at 23:58
  • .... But to avoid that possibility entirely, you can set a thread's processor affinity mask so that it will run on only a single core, eliminating this issue entirely. (which I see you also mentioned) – phonetagger Dec 7 '12 at 23:59
  • QPC can be, but isn't necessarily, a thin veil over rdtsc. At least at one time, the single-processor kernel used rdtsc, but the multiprocessor kernel used the motherboard's 1.024 MHz clock chip instead (for exactly the cited reasons). – Jerry Coffin Dec 8 '12 at 0:01

You don't need inline asm for this. There's no benefit; compilers have built-ins for rdtsc and rdtscp, and (at least these days) all define a __rdtsc intrinsic if you include the right headers. But unlike almost all other cases (https://gcc.gnu.org/wiki/DontUseInlineAsm), there's no serious downside to asm, as long as you're using a good and safe implementation like @Mysticial's, not one with a broken "=A" constraint.

Unfortunately MSVC disagrees with everyone else about which header to use for non-SIMD intrinsics.

Intel's intriniscs guide says _rdtsc (with one underscore) is in <immintrin.h>, but that doesn't work on gcc and clang. They only define SIMD intrinsics in <immintrin.h>, so we're stuck with <intrin.h> (MSVC) vs. <x86intrin.h> (everything else, including recent ICC). For compat with MSVC, and Intel's documentation, gcc and clang define both the one-underscore and two-underscore versions of the function.

Fun fact: the double-underscore version returns an unsigned 64-bit integer, while Intel documents _rdtsc() as returning (signed) __int64.

// valid C99 and C++

#include <stdint.h>  // <cstdint> is preferred in C++, but stdint.h works.

#ifdef _MSC_VER
# include <intrin.h>
#else
# include <x86intrin.h>
#endif

// optional wrapper if you don't want to just use __rdtsc() everywhere
inline
uint64_t readTSC() {
    // _mm_lfence();  // optionally wait for earlier insns to retire before reading the clock
    uint64_t tsc = __rdtsc();
    // _mm_lfence();  // optionally block later instructions until rdtsc retires
    return tsc;
}

// requires a Nehalem or newer CPU.  Not Core2 or earlier.  IDK when AMD added it.
inline
uint64_t readTSCp() {
    unsigned dummy;
    return __rdtscp(&dummy);  // waits for earlier insns to retire, but allows later to start
}

Compiles with all 4 of the major compilers: gcc/clang/ICC/MSVC, for 32 or 64-bit. See the results on the Godbolt compiler explorer, including a couple test callers.

These intrinsics were new in gcc4.5 (from 2010) and clang3.5 (from 2014). gcc4.4 and clang 3.4 on Godbolt don't compile this, but gcc4.5.3 (April 2011) does. You might see inline asm in old code, but you can and should replace it with __rdtsc(). Compilers over a decade old usually make slower code than gcc6, gcc7, or gcc8, and have less useful error messages.

The MSVC intrinsic has (I think) existed far longer, because MSVC never supported inline asm for x86-64. ICC13 has __rdtsc in immintrin.h, but doesn't have an x86intrin.h at all. More recent ICC have x86intrin.h, at least the way Godbolt installs them for Linux they do.

You might want to define them as signed long long, especially if you want to subtract them and convert to float. int64_t -> float/double is more efficient than uint64_t on x86 without AVX512. Also, small negative results could be possible because of CPU migrations if TSCs aren't perfectly synced, and that probably makes more sense than huge unsigned numbers.


BTW, clang also has a portable __builtin_readcyclecounter() which works on any architecture. (Always returns zero on architectures without a cycle counter.) See the clang/LLVM language-extension docs


For more about using lfence (or cpuid) to improve repeatability of rdtsc and control exactly which instructions are / aren't in the timed interval by blocking out-of-order execution, see @HadiBrais' answer on clflush to invalidate cache line via C function and the comments for an example of the difference it makes.

See also Is LFENCE serializing on AMD processors? (TL:DR yes with Spectre mitigation enabled, otherwise kernels leave the relevant MSR unset so you should use cpuid to serialize.) It's always been defined as partially-serializing on Intel.

How to Benchmark Code Execution Times on Intel® IA-32 and IA-64 Instruction Set Architectures, an Intel white-paper from 2010.


rdtsc counts reference cycles, not CPU core clock cycles

It counts at a fixed frequency regardless of turbo / power-saving, so if you want uops-per-clock analysis, use performance counters. rdtsc is exactly correlated with wall-clock time (except for system clock adjustments, so it's a perfect timesource for steady_clock). It ticks at the CPU's rated frequency, i.e. the advertised sticker frequency. (Or nearly that. e.g. 2592 MHz on an i7-6700HQ 2.6 GHz Skylake.)

If you use it for microbenchmarking, include a warm-up period first to make sure your CPU is already at max clock speed before you start timing. (And optionally disable turbo and tell your OS to prefer max clock speed to avoid CPU frequency shifts during your microbenchmark). Or better, use a library that gives you access to hardware performance counters, or a trick like perf stat for part of program if your timed region is long enough that you can attach a perf stat -p PID.

You usually will still want to keep the CPU clock fixed for microbenchmarks, though, unless you want to see how different loads will get Skylake to clock down when memory-bound or whatever. (Note that memory bandwidth / latency is mostly fixed, using a different clock than the cores. At idle clock speed, an L2 or L3 cache miss takes many fewer core clock cycles.)

It's also not guaranteed that the TSCs of all cores are in sync. So if your thread migrates to another CPU core between __rdtsc(), there can be an extra skew. (Most OSes attempt to sync the TSCs of all cores, though, so normally they'll be very close.) If you're using rdtsc directly, you probably want to pin your program or thread to a core, e.g. with taskset -c 0 ./myprogram on Linux.

CPU TSC fetch operation especially in multicore-multi-processor environment says that Nehalem and newer have the TSC synced and locked together for all cores in a package (i.e. invariant TSC). But multi-socket systems can still be a problem. Even older systems (like before Core2 in 2007) might have a TSC that stops when the core clock stops, or that's tied to the actual core clock frequency instead of reference cycles. (Newer CPUs always have constant-TSC and non-stop-TSC.) See @amdn's answer on that question for more details.


How good is the asm from using the intrinsic?

It's about as good as you'd get from @Mysticial's GNU C inline asm, or better because it knows the upper bits of RAX are zeroed. The main reason you'd want to keep inline asm is for compat with crusty old compilers.

A non-inline version of the readTSC function itself compiles with MSVC for x86-64 like this:

unsigned __int64 readTSC(void) PROC                             ; readTSC
    rdtsc
    shl     rdx, 32                             ; 00000020H
    or      rax, rdx
    ret     0
  ; return in RAX

For 32-bit calling conventions that return 64-bit integers in edx:eax, it's just rdtsc/ret. Not that it matters, you always want this to inline.

In a test caller that uses it twice and subtracts to time an interval:

uint64_t time_something() {
    uint64_t start = readTSC();
    // even when empty, back-to-back __rdtsc() don't optimize away
    return readTSC() - start;
}

All 4 compilers make pretty similar code. This is GCC's 32-bit output:

# gcc8.2 -O3 -m32
time_something():
    push    ebx               # save a call-preserved reg: 32-bit only has 3 scratch regs
    rdtsc
    mov     ecx, eax
    mov     ebx, edx          # start in ebx:ecx
      # timed region (empty)

    rdtsc
    sub     eax, ecx
    sbb     edx, ebx          # edx:eax -= ebx:ecx

    pop     ebx
    ret                       # return value in edx:eax

This is MSVC's x86-64 output (with name-demangling applied). gcc/clang/ICC all emit identical code.

# MSVC 19  2017  -Ox
unsigned __int64 time_something(void) PROC                            ; time_something
    rdtsc
    shl     rdx, 32                  ; high <<= 32
    or      rax, rdx
    mov     rcx, rax                 ; missed optimization: lea rcx, [rdx+rax]
                                     ; rcx = start
     ;; timed region (empty)

    rdtsc
    shl     rdx, 32
    or      rax, rdx                 ; rax = end

    sub     rax, rcx                 ; end -= start
    ret     0
unsigned __int64 time_something(void) ENDP                            ; time_something

All 4 compilers use or+mov instead of lea to combine the low and high halves into a different register. I guess it's kind of a canned sequence that they fail to optimize.

But writing a shift/lea in inline asm yourself is hardly better. You'd deprive the compiler of the opportunity to ignore the high 32 bits of the result in EDX, if you're timing such a short interval that you only keep a 32-bit result. Or if the compiler decides to store the start time to memory, it could just use two 32-bit stores instead of shift/or / mov. If 1 extra uop as part of your timing bothers you, you'd better write your whole microbenchmark in pure asm.

However, we can maybe get the best of both worlds with a modified version of @Mysticial's code:

// More efficient than __rdtsc() in some case, but maybe worse in others
uint64_t rdtsc(){
    // long and uintptr_t are 32-bit on the x32 ABI (32-bit pointers in 64-bit mode), so #ifdef would be better if we care about this trick there.

    unsigned long lo,hi;  // let the compiler know that zero-extension to 64 bits isn't required
    __asm__ __volatile__ ("rdtsc" : "=a" (lo), "=d" (hi));
    return ((uint64_t)hi << 32) + lo;
    // + allows LEA or ADD instead of OR
}

On Godbolt, this does sometimes give better asm than __rdtsc() for gcc/clang/ICC, but other times it tricks compilers into using an extra register to save lo and hi separately, so clang can optimize into ((end_hi-start_hi)<<32) + (end_lo-start_lo). Hopefully if there's real register pressure, compilers will combine earlier. (gcc and ICC still save lo/hi separately, but don't optimize as well.)

But 32-bit gcc8 makes a mess of it, compiling even just the rdtsc() function itself with an actual add/adc with zeros instead of just returning the result in edx:eax like clang does. (gcc6 and earlier do ok with | instead of +, but definitely prefer the __rdtsc() intrinsic if you care about 32-bit code-gen from gcc).

  • 1
    The tsc doesn't necessarily tick at the "sticker frequency", but rather at the tsc frequency. On some machines these are the same, but on many recent machines (like Skylake client and derived uarchs) they are often not. For example, my i7-6700HQ sticker frequency is 2600 MHz, but the tsc frequency is 2592 MHz. They are probably not the same in cases the different clocks they are based on can't be made to line up to exactly the same frequency when scaling the frequency by an integer. Many tools don't account for this difference leading to small errors. – BeeOnRope Aug 18 at 18:28
  • @BeeOnRope: Thanks, I hadn't realized that. That probably explains some not-quite-4GHz results I've seen from RDTSC stuff on my machine, like 4008 MHz vs. the sticker frequency of 4.0 GHz. – Peter Cordes Aug 18 at 18:31
  • 1
    On recent enough kernels you can do a dmesg | grep tsc to see both values. I get tsc: Detected 2600.000 MHz processor ... tsc: Detected 2592.000 MHz TSC. You can also use turbostat to show this. – BeeOnRope Aug 18 at 18:33
  • Yup, 4000.000 MHz processor and 4008.000 MHz TSC on i7-6700k. Nifty. – Peter Cordes Aug 18 at 18:35

For Windows, Visual Studio provides a convenient "compiler intrinsic" (i.e. a special function, which the compiler understands) that executes the RDTSC instruction for you and gives you back the result:

unsigned __int64 __rdtsc(void);

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