# Calculating CPU frequency in C with RDTSC always returns 0

The following piece of code was given to us from our instructor so we could measure some algorithms performance:

``````#include <stdio.h>
#include <unistd.h>

static unsigned cyc_hi = 0, cyc_lo = 0;

static void access_counter(unsigned *hi, unsigned *lo) {
asm("rdtsc; movl %%edx,%0; movl %%eax,%1"
: "=r" (*hi), "=r" (*lo)
: /* No input */
: "%edx", "%eax");
}

void start_counter() {
access_counter(&cyc_hi, &cyc_lo);
}

double get_counter() {
unsigned ncyc_hi, ncyc_lo, hi, lo, borrow;
double result;

access_counter(&ncyc_hi, &ncyc_lo);

lo = ncyc_lo - cyc_lo;
borrow = lo > ncyc_lo;
hi = ncyc_hi - cyc_hi - borrow;

result = (double) hi * (1 << 30) * 4 + lo;

return result;
}
``````

However, I need this code to be portable to machines with different CPU frequencies. For that, I'm trying to calculate the CPU frequency of the machine where the code is being run like this:

``````int main(void)
{
double c1, c2;

start_counter();

c1 = get_counter();
sleep(1);
c2 = get_counter();

printf("CPU Frequency: %.1f MHz\n", (c2-c1)/1E6);
printf("CPU Frequency: %.1f GHz\n", (c2-c1)/1E9);

return 0;
}
``````

The problem is that the result is always 0 and I can't understand why. I'm running Linux (Arch) as guest on VMware.

On a friend's machine (MacBook) it is working to some extent; I mean, the result is bigger than 0 but it's variable because the CPU frequency is not fixed (we tried to fix it but for some reason we are not able to do it). He has a different machine which is running Linux (Ubuntu) as host and it also reports 0. This rules out the problem being on the virtual machine, which I thought it was the issue at first.

Any ideas why this is happening and how can I fix it?

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Though the question was (a bit) different, most of my answer at: stackoverflow.com/questions/2658699/… applies here. –  Jerry Coffin May 11 '10 at 21:32
@Jerry Coffin I can't see how your answer on that question helps me. But than again, I didn't understand most of what you wrote lol. –  Ricardo Amaral May 11 '10 at 21:36
@Tim Post: His problem is not (at least exclusively) VMWare -- it's that RDTSC can be executed out of order, so without executing a serializing instruction (typically `CPUID`) it produces nearly meaningless results. –  Jerry Coffin May 11 '10 at 21:38
Write a small loop and repeatedly print the output of get_counter(). Make sure it's actually counting. –  ajs410 May 11 '10 at 21:48
If you want to measure wallclock time, don't measure cycles and try to convert to time; just directly measure time (eg with `gettimeofday()`, or `clock_gettime()` with either `CLOCK_MONOTONIC` or `CLOCK_PROCESS_CPUTIME_ID`). –  caf May 12 '10 at 0:58

Okay, since the other answer wasn't helpful, I'll try to explain on more detail. The problem is that a modern CPU can execute instructions out of order. Your code starts out as something like:

``````rdtsc
push 1
call sleep
rdtsc
``````

Modern CPUs do not necessarily execute instructions in their original order though. Despite your original order, the CPU is (mostly) free to execute that just like:

``````rdtsc
rdtsc
push 1
call sleep
``````

In this case, it's clear why the difference between the two `rdtsc`s would be (at least very close to) 0. To prevent that, you need to execute an instruction that the CPU will never rearrange to execute out of order. The most common instruction to use for that is `CPUID`. The other answer I linked should (if memory serves) start roughly from there, about the steps necessary to use `CPUID` correctly/effectively for this task.

Of course, it's possible that Tim Post was right, and you're also seeing problems because of a virtual machine. Nonetheless, as it stands right now, there's no guarantee that your code will work correctly even on real hardware.

Edit: as to why the code would work: well, first of all, the fact that instructions can be executed out of order doesn't guarantee that they will be. Second, it's possible that (at least some implementations of) `sleep` contain serializing instructions that prevent `rdtsc` from being rearranged around it, while others don't (or may contain them, but only execute them under specific (but unspecified) circumstances).

What you're left with is behavior that could change with almost any re-compilation, or even just between one run and the next. It could produce extremely accurate results dozens of times in a row, then fail for some (almost) completely unexplainable reason (e.g., something that happened in some other process entirely).

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I just dug into the VMWare time keeping spec, his code should be working. From the docs, rdtsc should work as expected, though I'm quite sure accuracy is better when paravirtualized. –  Tim Post May 11 '10 at 21:55
Out of order execution will NOT account for his problem. Sleep is not a single instruction, and no amount of out of order execution will re-order both RDTSC to be right next to each other. Even if it did, on an intel CPU rdtsc increments for every clock cycle of the chip. It is impossible for two calls, even if consecutive, to return the same value. –  SoapBox May 11 '10 at 22:03
I agree with SoapBox - after all, inside the `sleep()` function is a call into the kernel; there's a very large number of instructions hidden behind that `call`. –  caf May 11 '10 at 22:30
@caf: if he was using a single-core processor, that would be true. With two (or more) cores, it's entirely possible for two executions of RDTSC to return exactly the same value, one from each core (though this would be rare and isn't likely the source of what he's seeing). –  Jerry Coffin May 11 '10 at 22:57
@Nazgulled: if you're truly getting a difference of 0 (not just a number than seems smaller than reasonable), then I'd have to say it sounds like a problem being caused by the virtual machine, regardless of what their docs say. On a (properly functioning) single core, no two executions of RDTSC should return the same value (without using `WRMSR` to modify it in between). –  Jerry Coffin May 11 '10 at 23:11

I can't say for certain what exactly is wrong with your code, but you're doing quite a bit of unnecessary work for such a simple instruction. I recommend you simplify your `rdtsc` code substantially. You don't need to do 64-bit math carries your self, and you don't need to store the result of that operation as a double. You don't need to use separate outputs in your inline asm, you can tell GCC to use eax and edx.

Here is a greatly simplified version of this code:

``````#include <stdint.h>

uint64_t rdtsc() {
uint64_t ret;

# if __WORDSIZE == 64
asm ("rdtsc; shl \$32, %%rdx; or %%rdx, %%rax;"
: "=A"(ret)
: /* no input */
: "%edx"
);
#else
asm ("rdtsc"
: "=A"(ret)
);
#endif
return ret;
}
``````

Also you should consider printing out the values you're getting out of this so you can see if you're getting out 0s, or something else.

-
I get an error compiling your code: `expected string literal before ')' token`. –  Ricardo Amaral May 11 '10 at 22:54
Fixed it, sorry. –  SoapBox May 11 '10 at 23:27
It compiles now, thanks for the example. However, I still get a frenquency of zero. I don't think the problem is not on how rdtsc is implemented. And since this doesn't fix my problem, I rather use the code provided by the instructor. –  Ricardo Amaral May 12 '10 at 0:56

As for VMWare, take a look at the time keeping spec (PDF Link), as well as this thread. TSC instructions are (depending on the guest OS):

• Passed directly to the real hardware (PV guest)
• Count cycles while the VM is executing on the host processor (Windows / etc)

Note, in #2 the while the VM is executing on the host processor. The same phenomenon would go for Xen, as well, if I recall correctly. In essence, you can expect that the code should work as expected on a paravirtualized guest. If emulated, its entirely unreasonable to expect hardware like consistency.

-

hmmm I'm not positive but I suspect the problem may be inside this line:

result = (double) hi * (1 << 30) * 4 + lo;

I'm suspicious if you can safely carry out such huge multiplications in an "unsigned"... isn't that often a 32-bit number? ...just the fact that you couldn't safely multiply by 2^32 and had to append it as an extra "* 4" added to the 2^30 at the end already hints at this possibility... you might need to convert each sub-component hi and lo to a double (instead of a single one at the very end) and do the multiplication using the two doubles

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