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So given x, and power, n, solve for X^n. There's the easy way that's O(n)... I can get it down to O(n/2), by doing

numSquares = n/2;
numOnes = n%2;
return (numSquares * x * x + numOnes * x);

Now there's a O(log(n)) solution, does anyone know how to do it? It can be done recursively.

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It doesn't need to be done recursively; it can be done with simple iteration. –  Jonathan Leffler Mar 30 '10 at 3:33
6  
Are you aware O(n/2) is the same as O(n)? –  Suma Apr 1 '10 at 13:07

6 Answers 6

up vote 17 down vote accepted

Well, you know that xa+b = xa xb so...

int pow(int x, unsigned int y)
{
  if (y == 0) return 1;
  if (y == 1) return x;
  int a = y / 2;
  int xa = pow(x, a);
  if (a + a == y) // y even
    return xa * xa;
  else
    return xa * xa * x;
}
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you also need a if (y<0) { return (x==1)?1:0; } and to throw an exception for y<0, x==0 –  Inverse Mar 30 '10 at 3:38
    
Recursion for something already so computationally expensive as calculating the power of a number seems a tad bit overkill –  susmits Mar 30 '10 at 13:18
2  
What's overkill about recursion exactly? Also, it's not computationally expensive, it has O(lg(n)) run time. –  Peter Alexander Mar 30 '10 at 13:53
    
I should have said computationally intensive, sorry about that. The function isn't tail-call optimizable, and I have a suspicion the function call overhead here would be comparable to the execution time of each call. –  susmits Mar 30 '10 at 14:19
4  
If he wants to make micro-optimisations then that's up to him. I'm presenting something that is elegant so as to demonstrate the concept. Recursive solutions are almost always easier to understand that iterative ones. –  Peter Alexander Mar 30 '10 at 16:17

The mathematical concept that can be exploited is that x2n+1 = x2n ⋅ x and x2n = xn ⋅ xn.

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+1. Nice selective hint. –  user166390 Mar 30 '10 at 3:03

The usual implementation is something along these lines (cribbed from the wikipedia article):

long power(long x, unsigned long n)
{
    long result = 1;
    while (n > 0) {
        /* n is odd, bitwise test */ 
        if (n & 1) {
            result *= x;
        }
        x *= x;
        n /= 2;     /* integer division, rounds down */
    }
    return result;
}

Recursion isn't necessary or (I'd say) particularly desirable, although it can win on obviousness:

long power(long x, unsigned long n)
{
    if (n == 0) return 1;
    long result = power(x, n/2); // x ^ (n/2)
    result *= result;            // x ^ (n/2)*2
    if (n & 1) result *= x;      // x ^ n
    return result;
}

Of course in any version you overflow a long pretty quickly. You can apply the same algorithms to your favourite bigint representation, although any bigint library is going to include an integer power function already.

Both versions of the function above return 1 for power(0,0). You may or may not consider this a bug.

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How can we mark answers as Community Wikipedia? –  Windows programmer Mar 30 '10 at 3:05
    
Fun fact: g77 uses exponentiation by squaring to calculate integral powers. –  susmits Mar 30 '10 at 13:13

You'll find an explanation here: Fast exponentiation. For some values of n, you can calculate x^n with fewer multiplications than by using the powers of two trick.

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The standard trick is to generate the powers of x in sequence x2, x4, x8, x16, x32, ... and include those that are needed in the result.

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unless i'm not getting your answer, you can't do this infinitely though right? –  Mike Mar 30 '10 at 2:33
    
@Mike: You can only do anything infinitely if you have an infinite computer, and most of us are stuck with ordinary, very finite computers. If you use a multi-precision arithmetic package, you can work with numbers big enough that they'll blow your brains out. –  Jonathan Leffler Mar 30 '10 at 2:37
1  
Mike: Why do you need to do it infinitely? You only have to do it up to n. –  Gabe Mar 30 '10 at 2:37
    
@gabe that's true. nevertheless, i think Poita_ provided the best answer. –  Mike Mar 30 '10 at 2:40
1  
+1: Here is an example to illustrate this answer. Assume we have to compute x^26. Now, 26 = 11010 in binary. The '1' positions signify 16, 8, and 2. So, x^26 = (x^16) * (x^8) * (x^2). Now, if have the series x, x^2, x^4, x^8, x^16 computed, then we can pick selected items of the series and multiple them. Summary: To compute x^n, convert n to binary, find the bit positions (always 2's power) that are 1, compute them starting from the lower side, and multiply the suitable ones. –  Arun Mar 30 '10 at 6:06

x^n = e^(n*ln x), if i get you right?

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You've produce a solution that's O(1) and requires floating-point operations. He's looking for an integer-only solution that's O(lg n). –  Gabe Mar 30 '10 at 2:45
1  
His solution is certainly not O(1), unless you have have a constant time algorithm for e^(x), which would be great news. –  JSchlather Mar 30 '10 at 3:57
1  
but it is O(1). Increasing x doesn't increase the time to evaluate e^x. –  Jason S Mar 30 '10 at 12:33
    
Most likely for a wide variety of numbers the constant is higher than the entire non-constant time for integer only algorithms. –  Mark B Mar 30 '10 at 13:40
    
@Marck B: really doubt this to be frank, exp implemented at very low level –  vittore Mar 30 '10 at 17:08

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