Have a look at the following code to find X^y.

```
/* Find exponent in logarithmic complexity */
int findPower(int base, exponent){
if( 1 == exponent ) return base;
return (findPower(base, exponent/2)*findPower(base, exponent-exponent/2));
}
int main(int argc, char *argv[]){
if(argc < 3) {
printf("Usage :: logpow baseNumber power\n");
return -1;
}
printf("%s ^ %s = %d\n", argv[1], argv[2], findPow( atoi(argv[1]),
atoi(argv[2])) );
return 0;
}
```

Analysis shows that this has a complexity of theta(log(n)). But I ran it to measure time, and here are the results

```
Run 1: (calculating 1^500_million)
user-lm Programming # time ./a.out 1 500000000
1 ^ 500000000 = 1
real 0m5.009s
user 0m5.000s
sys 0m0.000s
Run 2: (calculating 1^1_Billion)
user-lm Programming # time ./a.out 1 1000000000
1 ^ 1000000000 = 1
real 0m9.667s
user 0m9.640s
sys 0m0.000s
Run 3: (calculating 1^2_Billion)
user-lm Programming # time ./a.out 1 2000000000
1 ^ 2000000000 = 1
real 0m18.649s
user 0m18.630s
sys 0m0.000s
```

From above we can see that the actual time complexity has linear behaviour rather than logarithmic!

What could be the reason for such a huge difference in complexity?

Regards,

Microkernel