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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

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Yeah! wrong analysis from side, as pointed out below, T(n) =2T(n/2)+c => theta(n) @FlopCoder Thanks :), your code runs blazingly fast :) –  Microkernel Feb 8 '12 at 16:32
    
How much time did it take for the last case? –  0605002 Feb 8 '12 at 18:55
    
0.02 Secs!!! Thats impressive :) –  Microkernel Feb 8 '12 at 23:57

3 Answers 3

up vote 9 down vote accepted

You are actually invoking 2 function calls from each call. The recursion tree would be a binary tree of height log(exponent), so the number of nodes in it will be 2^log(exponent) == exponent. So overall it becomes a linear algorithm. You can rewrite it like this for better performance:

int findPower(int base, exponent){
    if( 0 == exponent ) return 1;
    int temp = findPower(base, exponent/2);
    if(exponent % 2 == 0) return temp * temp;
    return temp * temp * base;
}

The trick is, you have to store the value of findPower(base, exponent/2) to get the logarithmic complexity. The recursion tree still has height log(exponent) but each node has only one child now, so there would be log(exponent) nodes. If you actually call it twice it will degrade the performance even more then a linear one. There's no need to calculate the same value second time if you already have that!

As @David Schwartz pointed out, the number of calls made in your code would be doubled if exponent is doubled. But when you save the values, doubling the exponent make only one more call.

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Your analysis is incorrect, it is O(N).

When you raise N from 1 billion to 2 billion, you have to do two power operations on 1 billion. So doubling N doubles the work that needs to be done. That's O(N).

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There is a formal representation of your algorithm complexity :

T(n) = 2T(n/2) + c

Where n is the exponent. Which gives

T(n) = Theta(n)

The analysis is incorrect.

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