I have a C program that aims to be run in parallel on several processors. I need to be able to record the execution time (which could be anywhere from 1 second to several minutes). I have searched for answers, but they all seem to suggest using the clock() function, which then involves calculating the number of clocks the program took divided by the Clocks_per_second value.

I'm not sure how the Clocks_per_second value is calculated?

In Java, I just take the current time in milliseconds before and after execution.

Is there a similar thing in C? I've had a look, but I can't seem to find a way of getting anything better than a second resolution.

I'm also aware a profiler would be an option, but am looking to implement a timer myself.



16 Answers 16


CLOCKS_PER_SEC is a constant which is declared in <time.h>. To get the CPU time used by a task within a C application, use:

clock_t begin = clock();

/* here, do your time-consuming job */

clock_t end = clock();
double time_spent = (double)(end - begin) / CLOCKS_PER_SEC;

Note that this returns the time as a floating point type. This can be more precise than a second (e.g. you measure 4.52 seconds). Precision depends on the architecture; on modern systems you easily get 10ms or lower, but on older Windows machines (from the Win98 era) it was closer to 60ms.

clock() is standard C; it works "everywhere". There are system-specific functions, such as getrusage() on Unix-like systems.

Java's System.currentTimeMillis() does not measure the same thing. It is a "wall clock": it can help you measure how much time it took for the program to execute, but it does not tell you how much CPU time was used. On a multitasking systems (i.e. all of them), these can be widely different.

  • 1
    It gives me very random result - I get a mixture of large/small/negative number over the same piece of code. GCC 4.7 Linux 3.2 AMD64 – user972946 Jun 2 '13 at 1:40
  • 3
    Yes: clock() returns a time in some internal scale called "clocks", and CLOCKS_PER_SEC is the number of clocks per second, so dividing by CLOCKS_PER_SEC yields a time in seconds. In the code above, the value is a double so you can scale it at will. – Thomas Pornin Nov 7 '15 at 16:56
  • 25
    Big warning: clock() returns the amount of time the OS has spent running your process, and not the actual amount of time elapsed. However, this is fine for timing a block of code, but not measuring time elapsing in the real world. – user3703887 Mar 28 '16 at 18:31
  • 2
    He said he wants to measure a multi-threaded program. I'm not sure a clock() is suitable for this, because it sums up running times of all threads, so the result will look like if the code was run sequentially. For such things i use omp_get_wtime(), but of course i need to make sure, the system is not busy with other processes. – Youda008 Oct 15 '16 at 8:12
  • 1
    I should mention some things even though this thread was more relevant a year ago: CLOCKS_PER_SEC is a long int with the value 1000000, giving time in microseconds when not divided; not CPU clock cycles. Therefore, it doesn't need to account for dynamic frequency as the clock here is in microseconds (maybe clock cycles for a 1 MHz CPU?) I made a short C program printing that value and it was 1000000 on my i7-2640M laptop, with dynamic frequency allowing 800 MHz to 2.8 GHz, even using Turbo Boost to go as high as 3.5 GHz. – DDPWNAGE Aug 17 '17 at 0:32

If you are using the Unix shell for running, you can use the time command.


$ time ./a.out

assuming a.out as the executable will give u the time taken to run this

  • 4
    @acgtyrant but only for simple programs, because it'll take the whole program time, including input, output, etc. – phuclv Dec 17 '15 at 6:55
  • 1
    If you're on Linux, and you've reduced your (micro)benchmark to a program with negligible startup overhead, e.g. a static executable that runs your hot loop for a few seconds, you can use perf stat ./a.out to get HW performance counters for cache misses and branch mispredicts, and IPC. – Peter Cordes Apr 5 '19 at 8:12

In plain vanilla C:

#include <time.h>
#include <stdio.h>

int main()
    clock_t tic = clock();


    clock_t toc = clock();

    printf("Elapsed: %f seconds\n", (double)(toc - tic) / CLOCKS_PER_SEC);

    return 0;
  • 18
    Best variable names I've seen in awhile. tic = "time in clock", toc = "time out clock". But also tic-toc = "tick-tock". This is how I'm labeling time grabs from here on out. – Logan Schelly Mar 30 '20 at 2:57

You functionally want this:

#include <sys/time.h>

struct timeval  tv1, tv2;
gettimeofday(&tv1, NULL);
/* stuff to do! */
gettimeofday(&tv2, NULL);

printf ("Total time = %f seconds\n",
         (double) (tv2.tv_usec - tv1.tv_usec) / 1000000 +
         (double) (tv2.tv_sec - tv1.tv_sec));

Note that this measures in microseconds, not just seconds.

  • 2
    MinGW compiler is GCC based. So it will work on it. But if you use visual C compiler, then you will get error. – user2550754 Jan 9 '14 at 11:37
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    Yes, it'll work on windows with a c library that supports the gettimeofday call. It actually doesn't matter what the compiler is, you just have to link it against a decent libc library. Which, in the case of mingw, is not the default windows one. – Wes Hardaker Jan 10 '14 at 18:22
  • 1
    This works for me on Windows XP with cygwin gcc & Linux Ubuntu. This is just what i wanted. – Love and peace - Joe Codeswell May 21 '15 at 2:20
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    gettimeofday is obsolete and not recommended for new code. Its POSIX man page recommends clock_gettime instead, which lets you ask for CLOCK_MONOTONIC that isn't affected by changes to the system clock, and thus it's better as an interval time. (See JohnSll's answer). On modern Linux systems, for example, gettimeofday is basically a wrapper for clock_gettime that converts nanoseconds to microseconds. – Peter Cordes Apr 5 '19 at 8:11

Most of the simple programs have computation time in milli-seconds. So, i suppose, you will find this useful.

#include <time.h>
#include <stdio.h>

int main(){
    clock_t start = clock();
    // Execuatable code
    clock_t stop = clock();
    double elapsed = (double)(stop - start) * 1000.0 / CLOCKS_PER_SEC;
    printf("Time elapsed in ms: %f", elapsed);

If you want to compute the runtime of the entire program and you are on a Unix system, run your program using the time command like this time ./a.out

  • In Windows at least the factor is at least 100 but not 1000 and it's not exact – boctulus Apr 16 '16 at 12:29
  • 6
    This answer doesn't add anything that wasn't in Alexandre C's answer from two year's earlier. – Jonathan Leffler Dec 5 '16 at 1:25
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    @boctulus: 1s is always 1000ms, also on windows. – alk Jul 21 '17 at 15:09

Thomas Pornin's answer as macros:

#define TICK(X) clock_t X = clock()
#define TOCK(X) printf("time %s: %g sec.\n", (#X), (double)(clock() - (X)) / CLOCKS_PER_SEC)

Use it like this:




time TIME_A: 0.001652 sec.
time TIME_B: 0.004028 sec.

A lot of answers have been suggesting clock() and then CLOCKS_PER_SEC from time.h. This is probably a bad idea, because this is what my /bits/time.h file says:

/* ISO/IEC 9899:1990 7.12.1: <time.h>
The macro `CLOCKS_PER_SEC' is the number per second of the value
returned by the `clock' function. */
/* CAE XSH, Issue 4, Version 2: <time.h>
The value of CLOCKS_PER_SEC is required to be 1 million on all
XSI-conformant systems. */
#  define CLOCKS_PER_SEC  1000000l

#  if !defined __STRICT_ANSI__ && !defined __USE_XOPEN2K
/* Even though CLOCKS_PER_SEC has such a strange value CLK_TCK
presents the real value for clock ticks per second for the system.  */
#   include <bits/types.h>
extern long int __sysconf (int);
#   define CLK_TCK ((__clock_t) __sysconf (2))  /* 2 is _SC_CLK_TCK */
#  endif

So CLOCKS_PER_SEC might be defined as 1000000, depending on what options you use to compile, and thus it does not seem like a good solution.

  • 1
    Thanks for the information but is there any better alternative yet? – ozanmuyes Oct 16 '14 at 21:00
  • 4
    This is not a pratical problem: yes Posix systems always have CLOCK_PER_SEC==1000000, but in the same time, they all use 1-µs precision for their clock() implementation; by the way, it has the nice property to reduce sharing problems. If you want to measure potentially very quick events, say below 1 ms, then you should first worry about the accuracy (or resolution) of the clock() function, which is necessarily coarser than 1µs in Posix, but is also often much coarser; the usual solution is to run the test many times; the question as asked did not seem to require it, though. – AntoineL Apr 22 '15 at 15:29
  • Why would it not be a good solution? You get some value from clock(), if you divide that value with CLOCK_PER_SEC you are guaranteed to get time in seconds cpu took. The responsibility of measuring actual clock speed is responsibility of clock() function, not yours. – Zaffy Aug 28 '19 at 12:23

(All answers here are lacking, if your sysadmin changes the systemtime, or your timezone has differing winter- and sommer-times. Therefore...)

On linux use: clock_gettime(CLOCK_MONOTONIC_RAW, &time_variable); It's not affected if the system-admin changes the time, or you live in a country with winter-time different from summer-time, etc.

#include <stdio.h>
#include <time.h>

#include <unistd.h> /* for sleep() */

int main() {
    struct timespec begin, end;
    clock_gettime(CLOCK_MONOTONIC_RAW, &begin);

    sleep(1);      // waste some time

    clock_gettime(CLOCK_MONOTONIC_RAW, &end);

    printf ("Total time = %f seconds\n",
            (end.tv_nsec - begin.tv_nsec) / 1000000000.0 +
            (end.tv_sec  - begin.tv_sec));


man clock_gettime states:

              Clock  that  cannot  be set and represents monotonic time since some unspecified starting point.  This clock is not affected by discontinuous jumps in the system time
              (e.g., if the system administrator manually changes the clock), but is affected by the incremental adjustments performed by adjtime(3) and NTP.
  • Can you explain the calculation that you used to get the number of seconds? It is not obvious what's going on. – Colin Keenan Mar 30 '17 at 17:29
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    Wouldn't this (end.tv_nsec - begin.tv_nsec) / 1000000000.0 result in 0 always? – alk Jul 21 '17 at 15:15
  • @alk: no, dividing by a double literal triggers int or long to double conversion before the division. Of course you could just stick to integer and print the tv_sec part and then the fractional part with zero like %ld.%09ld, but converting to double is easy and 53 bits of precision are usually plenty for benchmark times. – Peter Cordes Apr 5 '19 at 7:59
  • 2
    (Oops, the subtraction of the nanoseconds part may need to carry into the seconds part, so using double and letting it be negative avoids that problem. To use a pure integer format string, you'd need a timespec_subtract like the timeval_subtract suggested in the glibc manual: gnu.org/software/libc/manual/html_node/Elapsed-Time.html) – Peter Cordes Apr 5 '19 at 8:07

You have to take into account that measuring the time that took a program to execute depends a lot on the load that the machine has in that specific moment.

Knowing that, the way of obtain the current time in C can be achieved in different ways, an easier one is:

#include <time.h>

#define CPU_TIME (getrusage(RUSAGE_SELF,&ruse), ruse.ru_utime.tv_sec + \
  ruse.ru_stime.tv_sec + 1e-6 * \
  (ruse.ru_utime.tv_usec + ruse.ru_stime.tv_usec))

int main(void) {
    time_t start, end;
    double first, second;

    // Save user and CPU start time
    first = CPU_TIME;

    // Perform operations

    // Save end time
    second = CPU_TIME;

    printf("cpu  : %.2f secs\n", second - first); 
    printf("user : %d secs\n", (int)(end - start));

Hope it helps.



ANSI C only specifies second precision time functions. However, if you are running in a POSIX environment you can use the gettimeofday() function that provides microseconds resolution of time passed since the UNIX Epoch.

As a side note, I wouldn't recommend using clock() since it is badly implemented on many(if not all?) systems and not accurate, besides the fact that it only refers to how long your program has spent on the CPU and not the total lifetime of the program, which according to your question is what I assume you would like to measure.

  • ISO C Standard (assuming this is what ANSI C means) purposely does not specify the precision of the time functions. Then specifically on a POSIX implementation, or on Windows, precision of the wall-clock (see Thomas' answer) functions are in seconds. But clock()'s precision is usually greater, and always 1µs in Posix (independently of the accuracy.) – AntoineL Apr 22 '15 at 15:18

Every solution's are not working in my system.

I can get using

#include <time.h>

double difftime(time_t time1, time_t time0);
  • 3
    This gives the difference between two time_t values as a double. Since time_t values are only accurate to a second, it is of limited value in printing out the time taken by short running programs, though it may be useful for programs that run for long periods. – Jonathan Leffler Dec 5 '16 at 1:12
  • For whatever reason, passing in a pair of clock_ts to difftime seems to work for me to the precision of a hundredth of a second. This is on linux x86. I also can't get the subtraction of stop and start to work. – interestedparty333 Dec 13 '16 at 19:39
  • @ragerdl: You need to pass to difftime() clock() / CLOCKS_PER_SEC, as it expects seconds. – alk Jul 21 '17 at 15:11
    int main(){
clock_t begin=clock();

    int i;

clock_t end=clock();
printf("Time taken:%lf",(double)(end-begin)/CLOCKS_PER_SEC);

This program will work like charm.


I've found that the usual clock(), everyone recommends here, for some reason deviates wildly from run to run, even for static code without any side effects, like drawing to screen or reading files. It could be because CPU changes power consumption modes, OS giving different priorities, etc...

So the only way to reliably get the same result every time with clock() is to run the measured code in a loop multiple times (for several minutes), taking precautions to prevent the compiler from optimizing it out: modern compilers can precompute the code without side effects running in a loop, and move it out of the loop., like i.e. using random input for each iteration.

After enough samples are collected into an array, one sorts that array, and takes the middle element, called median. Median is better than average, because it throws away extreme deviations, like say antivirus taking up all CPU up or OS doing some update.

Here is a simple utility to measure execution performance of C/C++ code, averaging the values near median: https://github.com/saniv/gauge

I'm myself still looking for a more robust and faster way to measure code. One could probably try running the code in controlled conditions on bare metal without any OS, but that will give unrealistic result, because in reality OS does get involved.

x86 has these hardware performance counters, which including the actual number of instructions executed, but they are tricky to access without OS help, hard to interpret and have their own issues ( http://archive.gamedev.net/archive/reference/articles/article213.html ). Still they could be helpful investigating the nature of the bottle neck (data access or actual computations on that data).

  • Yes, modern x86 CPUs idle much slower than max turbo. Depending on "governor" settings, ramp up to max clock speed might take a millisecond (Skylake with hardware P-state management, especially with energy_performance_preference set to performance) or many tens of milliseconds. en.wikipedia.org/wiki/Dynamic_frequency_scaling. And yes, median performance is usually a good choice; the high end usually has some spikes from interference. – Peter Cordes Aug 18 '19 at 22:50
  • Often your best bet to avoid having work optimize away is a command-line input and return the result. Or write a function in a separate file from main that takes an arg and returns a result, and don't use link-time optimization. Then the compiler can't inline it into the caller. Only works if the function already includes some kind of loop, otherwise call/ret overhead is too high. – Peter Cordes Aug 18 '19 at 22:52
  • Compiler can still optimize the single command line input out of the loop, if you process it with static code without any side effects. So it is best to generate a random input for each iteration. Obviously rand() should be called outside of measured code, before the first clock(), because rand() could as well result into a system call, sampling some hardware entropy generator (which on older systems was mouse movement). Just don't forget to printf every bit of the output, otherwise compiler may decide you don't need all the output as whole or part of it. That can be done with say CRC32. – SmugLispWeenie Aug 19 '19 at 8:50
  • If your code-under-test in in a separate file and you don't use link-time optimization, there's no way the compiler can do CSE to optimize between calls. The caller can't assume anything about the callee not having any visible side-effects. This lets you put something relatively short inside a repeat loop to make it long enough to time, with just call/ret overhead. If you let it inline, then you have to check the generated asm to make sure it didn't hoist a computation out of a loop as you say. – Peter Cordes Aug 19 '19 at 9:05
  • The compiler-specific way is to use (for example) GNU C inline asm to force a compiler to materialize a result in a register, and/or to forget what it knows about the value of a variable, without actually introducing extra instructions. "Escape" and "Clobber" equivalent in MSVC links to a video about profiling and microbenchmarking (clang developer Chandler Carruth's CppCon 2015 talk) There is no MSVC equivalent, but the question itself shows the GNU C functions and how to use them. – Peter Cordes Aug 19 '19 at 9:07

Some might find a different kind of input useful: I was given this method of measuring time as part of a university course on GPGPU-programming with NVidia CUDA (course description). It combines methods seen in earlier posts, and I simply post it because the requirements give it credibility:

unsigned long int elapsed;
struct timeval t_start, t_end, t_diff;
gettimeofday(&t_start, NULL);

// perform computations ...

gettimeofday(&t_end, NULL);
timeval_subtract(&t_diff, &t_end, &t_start);
elapsed = (t_diff.tv_sec*1e6 + t_diff.tv_usec);
printf("GPU version runs in: %lu microsecs\n", elapsed);

I suppose you could multiply with e.g. 1.0 / 1000.0 to get the unit of measurement that suits your needs.

  • 1
    gettimeofday is obsolete and not recommended. Its POSIX man page recommends clock_gettime instead, which lets you ask for CLOCK_MONOTONIC that isn't affected by changes to the system clock, and thus it's better as an interval timer. On modern Linux systems, for example, gettimeofday is basically a wrapper for clock_gettime that converts nanoseconds to microseconds. (See JohnSll's answer). – Peter Cordes Apr 5 '19 at 7:55
  • This method was added by @Wes Hardaker, the main difference is using timeval_subtract. – ワイきんぐ Apr 5 '19 at 7:58
  • Ok, so the only useful part of your answer is the name of a function that you don't define, and that isn't in the standard library. (Only in the glibc manual: gnu.org/software/libc/manual/html_node/Elapsed-Time.html). – Peter Cordes Apr 5 '19 at 8:09

perf tool is more accurate to be used in order to collect and profile the running program. Use perf stat to show all information related to the program being executed.


Comparison of execution time of bubble sort and selection sort I have a program which compares the execution time of bubble sort and selection sort. To find out the time of execution of a block of code compute the time before and after the block by

 clock_t start=clock();
 clock_t end=clock();
 CLOCKS_PER_SEC is constant in time.h library

Example code:

#include <stdio.h>
#include <stdlib.h>
#include <time.h>
int main()
   int a[10000],i,j,min,temp;
   //The bubble Sort
   clock_t start,end;
         int temp=a[i];
   double extime=(double) (end-start)/CLOCKS_PER_SEC;
   printf("\n\tExecution time for the bubble sort is %f seconds\n ",extime);

   clock_t start1,end1;
   // The Selection Sort
   double extime1=(double) (end1-start1)/CLOCKS_PER_SEC;
   printf("\tExecution time for the selection sort is %f seconds\n\n", extime1);
     printf("\tSelection sort is faster than Bubble sort by %f seconds\n\n", extime - extime1);
   else if(extime1>extime)
     printf("\tBubble sort is faster than Selection sort by %f seconds\n\n", extime1 - extime);
     printf("\tBoth algorithms have the same execution time\n\n");
  • 4
    This doesn't really add anything new compared with adimoh's answer, except that it fills in 'the executable code' block (or two of them) with some actual code. And that answer doesn't add anything that wasn't in Alexandre C's answer from two year's earlier. – Jonathan Leffler Dec 5 '16 at 1:22

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