# How to get 100% CPU usage from a C program

This is quite an interesting question so let me set the scene. I work at The National Museum of Computing, and we have just managed to get a Cray Y-MP EL super computer from 1992 running, and we really want to see how fast it can go!

We decided the best way to do this was to write a simple C program that would calculate prime numbers and show how long it took to do so, then run the program on a fast modern desktop PC and compare the results.

We quickly came up with this code to count prime numbers:

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

void main() {
clock_t start, end;
double runTime;
start = clock();
int i, num = 1, primes = 0;

while (num <= 1000) {
i = 2;
while (i <= num) {
if(num % i == 0)
break;
i++;
}
if (i == num)
primes++;

system("clear");
printf("%d prime numbers calculated\n",primes);
num++;
}

end = clock();
runTime = (end - start) / (double) CLOCKS_PER_SEC;
printf("This machine calculated all %d prime numbers under 1000 in %g seconds\n", primes, runTime);
}
``````

Which on our dual core laptop running Ubuntu (The Cray runs UNICOS), worked perfectly, getting 100% CPU usage and taking about 10 minutes or so. When I got home I decided to try it on my hex-core modern gaming PC, and this is where we get our first issues.

I first adapted the code to run on Windows since that is what the gaming PC was using, but was saddened to find that the process was only getting about 15% of the CPU's power. I figured that must be Windows being Windows, so I booted into a Live CD of Ubuntu thinking that Ubuntu would allow the process to run with its full potential as it had done earlier on my laptop.

However I only got 5% usage! So my question is, how can I adapt the program to run on my gaming machine in either Windows 7 or live Linux at 100% CPU utilisation? Another thing that would be great but not necessary is if the end product can be one .exe that could be easily distributed and ran on Windows machines.

Thanks a lot!

P.S. Of course this program didn't really work with the Crays 8 specialist processors, and that is a whole other issue... If you know anything about optimising code to work on 90's Cray super computers give us a shout too!

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I can't believe there's not a unicos tag. ;) – Edward Thomson Feb 11 '12 at 22:15
It is a strange thing that this single thread program took 100% of CPU usage on DUAL CORE processor ))) – mikithskegg Feb 11 '12 at 22:15
Am I the only one who doesn't find this question interesting at all? Come one, running a single threaded program on a n-core machine and asking why it uses 1/n of the the cpu is just... never mind, I just downvote :-) – hirschhornsalz Feb 12 '12 at 2:04
@drhirsch Well, the question shows research effort. I +1'ed for that - even if the OP is missing something fundamental about multi-core computing. – Mysticial Feb 12 '12 at 2:14
@drhirsch There are a lot of uninteresting questions on the site. However, interesting or not is subjective. He may be missing the fundamentals and that isn't subjective. Like Mystical said, it does show research effort and isn't as easy to answer as it would appear. – carleeto Feb 12 '12 at 23:48

If you want 100% CPU, you need to use more than 1 core. To do that, you need multiple threads.

Here's a parallel version using OpenMP:

I had to increase the limit to `1000000` to make it take more than 1 second on my machine.

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

int main() {
double start, end;
double runTime;
start = omp_get_wtime();
int num = 1,primes = 0;

int limit = 1000000;

#pragma omp parallel for schedule(dynamic) reduction(+ : primes)
for (num = 1; num <= limit; num++) {
int i = 2;
while(i <= num) {
if(num % i == 0)
break;
i++;
}
if(i == num)
primes++;
//      printf("%d prime numbers calculated\n",primes);
}

end = omp_get_wtime();
runTime = end - start;
printf("This machine calculated all %d prime numbers under %d in %g seconds\n",primes,limit,runTime);

return 0;
}
``````

Output:

``````This machine calculated all 78498 prime numbers under 1000000 in 29.753 seconds
``````

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Wow that didn't take you long! I forgot to say the end value we will use is 1,000,000 1000 was for testing (Which as you saw was just silly!) I will test this out now, thanks a lot! – Owen Garland Feb 11 '12 at 22:30
@cha0site Yes, I mainly answered the question for the gaming machine. There are definitely more interesting ways to peg the CPU. One of the more notorious benchmarks I've done is my answer to this question - which overheated 2 of 4 machines I tested. – Mysticial Feb 11 '12 at 22:54
@Mystical Offtopic: What hardware are you running? My Hex-Core AMD @ 3.2Ghz did it in 92 seconds... – Owen Garland Feb 11 '12 at 23:15
Augh! Too... much... pink! – muntoo Feb 12 '12 at 3:54
@MohammadFadin en.wikipedia.org/wiki/Parallel_computing Basically, you need to be able to process multiple tasks in parallel to be able to utilize a multi-core computer. – Mysticial Feb 13 '12 at 20:06

You're running one process on a multi-core machine - so it only runs on one core.

The solution is easy enough, since you're just trying to peg the processor - if you have N cores, run your program N times (in parallel, of course).

## Example

Here is some code that runs your program `NUM_OF_CORES` times in parallel. It's POSIXy code - it uses `fork` - so you should run that under Linux. If what I'm reading about the Cray is correct, it might be easier to port this code than the OpenMP code in the other answer.

``````#include <stdio.h>
#include <time.h>
#include <stdlib.h>
#include <unistd.h>
#include <errno.h>

#define NUM_OF_CORES 8
#define MAX_PRIME 100000

void do_primes()
{
unsigned long i, num, primes = 0;
for (num = 1; num <= MAX_PRIME; ++num) {
for (i = 2; (i <= num) && (num % i != 0); ++i);
if (i == num)
++primes;
}
printf("Calculated %d primes.\n", primes);
}

int main(int argc, char ** argv)
{
time_t start, end;
time_t run_time;
unsigned long i;
pid_t pids[NUM_OF_CORES];

/* start of test */
start = time(NULL);
for (i = 0; i < NUM_OF_CORES; ++i) {
if (!(pids[i] = fork())) {
do_primes();
exit(0);
}
if (pids[i] < 0) {
perror("Fork");
exit(1);
}
}
for (i = 0; i < NUM_OF_CORES; ++i) {
waitpid(pids[i], NULL, 0);
}
end = time(NULL);
run_time = (end - start);
printf("This machine calculated all prime numbers under %d %d times "
"in %d seconds\n", MAX_PRIME, NUM_OF_CORES, run_time);
return 0;
}
``````

### Output

``````\$ ./primes
Calculated 9592 primes.
Calculated 9592 primes.
Calculated 9592 primes.
Calculated 9592 primes.
Calculated 9592 primes.
Calculated 9592 primes.
Calculated 9592 primes.
Calculated 9592 primes.
This machine calculated all prime numbers under 100000 8 times in 8 seconds
``````
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Ah kind of like when you need to run Prime95, you have multiple instances of it... Surely there is a way for one process to use multiple cores? Like hash cracking programs do. – Owen Garland Feb 11 '12 at 22:19
Well, one process could use threads to do multiprocessing, but I don't think that's what you meant since a thread is almost a separate process in this context. What we're really talking about here is "heads of execution", be they threads or processes. So, no, there isn't a way to make a single-threaded program run on multiple cores, you have to rewrite it. And sometimes it's really hard. And sometimes it's actually impossible. – cha0site Feb 11 '12 at 22:23
Well I guess it won't be as hard as getting the program to work for the Cray as well. Considering I am pretty new to this (What gave me away :P) where would be a good place to start? – Owen Garland Feb 11 '12 at 22:26
@Owen: Well, `UNICOS` looks like it is somewhat similar to Unix (Wikipedia makes think so anyway), so it probably has `fork()`. You should go learn how to use that, I think. – cha0site Feb 11 '12 at 22:32
Oooh! +1'ed now that you have the example. :) – Mysticial Feb 12 '12 at 18:52

we really want to see how fast it can go!

Your algorithm to generate prime numbers is very inefficient. Compare it to primegen that generates the 50847534 primes up to 1000000000 in just 8 seconds on a Pentium II-350.

To consume all CPUs easily you could solve an embarrassingly parallel problem e.g., compute Mandelbrot set or use genetic programming to paint Mona Lisa in multiple threads (processes).

Another approach is to take an existing benchmark program for the Cray supercomputer and port it to a modern PC.

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The reason you're getting 15% on a hex core processor is because your code uses 1 core at 100%. 100/6 = 16.67%, which using a moving average with process scheduling (your process would be running under normal priority) could easily be reported as 15%.

Therefore, in order to use 100% cpu, you would need to use all the cores of your CPU - launch 6 parallel execution code paths for a hex core CPU and have this scale right up to however many processors your Cray machine has :)

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 The issue with doing this is that how can I get a clear figure of the speed of each of the machine? Also the Cray has "vector processors" apparently, so it requires a load more work than this to get it to run properly – Owen Garland Feb 11 '12 at 22:27 You're right. It does. – carleeto Feb 11 '12 at 23:24 y is linux just at 5% – Web Developer Feb 12 '12 at 15:17 Don't know. Probably differences in scheduling processes. – carleeto Feb 12 '12 at 23:36

Try to parallelize your program using, e.g., OpenMP. It is a very simple and effective framework for making up parallel programs.

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For a quick improvement on one core, remove system calls to reduce context-switching. Remove these lines:

``````system("clear");
printf("%d prime numbers calculated\n",primes);
``````

The first is particularly bad, as it will spawn a new process every iteration.

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Also be very aware how you're loading the CPU. A CPU can do a lot of different tasks, and while many of them will be reported as "loading the CPU 100%" they may each use 100% of different parts of the CPU. In other words, it's very hard to compare two different CPUs for performance, and especially two different CPU architectures. Executing task A may favor one CPU over another, while executing task B it can easily be the other way around (since the two CPUs may have different resources internally and may execute code very differently).

This is the reason software is just as important for making computers perform optimal as hardware is. This is indeed very true for "supercomputers" as well.

One measure for CPU performance could be instructions per second, but then again instructions aren't created equal on different CPU architectures. Another measure could be cache IO performance, but cache infrastructure is not equal either. Then a measure could be number of instructions per watt used, as power delivery and dissipation is often a limiting factor when designing a cluster computer.

So your first question should be: Which performance parameter is important to you? What do you want to measure? If you want to see which machine gets the most FPS out of Quake 4, the answer is easy; your gaming rig will, as the Cray can't run that program at all ;-)

Cheers, Steen

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