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This is an interview question: "Given 2 integers x and y, check if x is an integer power of y" (e.g. for x = 8 and y = 2 the answer is "true", and for x = 10 and y = 2 "false").

The obvious solution is:

int n = y; while(n < x) n *= y; return n == x

Now I am thinking about how to improve it.

Of course, I can check some special cases: e.g. both x and y should be either odd or even numbers, i.e. we can check the least significant bit of x and y. However I wonder if I can improve the core algorithm itself.

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1  
Your obvious solution is wrong: consider y=2, x=8 –  Chowlett Dec 13 '10 at 13:03
1  
Err, the "obvious solution" will actually return false for x=8 and y=2. In first iteration y becomes 4, in second 16, oops... –  Dialecticus Dec 13 '10 at 13:03
    
Thanks, I will fix it. –  Michael Dec 13 '10 at 13:06
2  
Actually, I thought the obvious solution is to divide x by y then divide the result by y continually until you reach a number that is not divisible by y. If that number is 1, x is a power of y. –  JeremyP Dec 13 '10 at 13:19
    
Unfortunate that not a single user here noticed that every piece of code posted fails miserably for x = ±1 –  Nabb Dec 15 '10 at 12:06

9 Answers 9

You'd do better to repeatedly divide y into x. The first time you get a non-zero remainder you know x is not an integer power of y.

while (x%y == 0)  x = x / y
return x == 1

This deals with your odd/even point on the first iteration.

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1  
Why is division better than multiplication ? –  Michael Dec 13 '10 at 13:11
2  
@Michael: Suppose x is 123456789 and y is 2. Figure out how many iterations of multiplying by y you would have to do to get the answer and then figure out how many divisions you would have to do. –  JeremyP Dec 13 '10 at 13:21
2  
It's also better than multiplication because it cannot overflow. And it could be possible that optimized code would skip your tries to detect the overflow. –  ruslik Dec 13 '10 at 19:15
2  
@Paul - 32-bit integer division would be about 10 times slower than multiplication (on x86 at least). You have to factor that into the analysis. –  Axn Dec 14 '10 at 21:06
1  
@Axn: then you can double that because the mod takes about as long as the division. –  Tony D Dec 15 '10 at 4:14

It means logy(x) should be an integer. Don't need any loop. in O(1) time

public class PowerTest {

    public static boolean isPower(int x, int y) {
        double d = Math.log(Math.abs(x)) / Math.log(Math.abs(y));

        if ((x > 0 && y > 0) || (x < 0 && y < 0)) {
            if (d == (int) d) {
                return true;
            } else {
                return false;
            }
        } else if (x > 0 && y < 0) {
            if ((int) d % 2 == 0) {
                return true;
            } else {
                return false;
            }
        } else {
            return false;
        }
    }

    /**
     * @param args
     */
    public static void main(String[] args) {

        System.out.println(isPower(-32, -2));
        System.out.println(isPower(2, 8));
        System.out.println(isPower(8, 12));
        System.out.println(isPower(9, 9));
        System.out.println(isPower(-16, 2));
        System.out.println(isPower(-8, -2));
        System.out.println(isPower(16, -2));
        System.out.println(isPower(8, -2));
    }

}
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7  
You need to be careful of rounding issues with floating point numbers. Also how does isPower(-8, -2) fair? –  JeremyP Dec 13 '10 at 13:25
    
Yes, you are right. I thought integer is positive. Then, I should think it's abs version –  user467871 Dec 13 '10 at 13:43
    
You should try isPower(1162261467, 3) x is greater one (int the question) –  user467871 Dec 13 '10 at 13:46
    
Oops, yes, my error. –  Paul Dec 13 '10 at 13:50
1  
+1 nice way, but, It's not O(1), Is O(log(x) + log(y)), Also using decimal is better to avoid rounding problems. –  Saeed Amiri Dec 17 '10 at 15:14

This looks for the exponent in O(log N) steps:

#define MAX_POWERS 100

int is_power(unsigned long x, unsigned long y) {
  int i;
  unsigned long powers[MAX_POWERS];
  unsigned long last;
  last = powers[0] = y;

  for (i = 1; last < x; i++) {
    last *= last; // note that last * last can overflow here!
    powers[i] = last;
  }
  while (x >= y) {
    unsigned long top = powers[--i];
    if (x >= top) {
      unsigned long x1 = x / top;
      if (x1 * top != x) return 0;
      x = x1;
    }
  }
  return (x == 1);
}

Negative numbers are not handled by this code, but it can be done easyly with some conditional code when i = 1

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Thanks for the idea of pre-calculating powers of y ! –  Michael Dec 13 '10 at 17:19
    
This solution should be upvoted more. BTW, there is no way powers[99] will fit in an unsigned long if x > 1. For example, if x == 2 then powers 99 is roughly a one followed by a thousand billion billion billion zeros. –  jonderry Dec 14 '10 at 23:00

This looks to be pretty fast for positive numbers as it finds the lower and upper limits for desired power and then applies binary search.

#include <iostream>
#include <cmath>
using namespace std;

//x is the dividend, y the divisor.
bool isIntegerPower(int x, int y)
{
    int low = 0, high;
    int exp = 1;
    int val = y;
    //Loop by changing exponent in the powers of 2 and
    //Find out low and high exponents between which the required exponent lies.
    while(1)
    {
        val = pow((double)y, exp);
        if(val == x)
            return true;
        else if(val > x)
            break;
        low = exp;
        exp = exp * 2;
        high = exp;
    }
    //Use binary search to find out the actual integer exponent if exists
    //Otherwise, return false as no integer power.
    int mid = (low + high)/2;
    while(low < high)
    {
        val = pow((double)y, mid);
        if(val > x)
        {
            high = mid-1;
        }
        else if(val == x)
        {
            return true;
        }
        else if(val < x)
        {
            low = mid+1;
        }
        mid = (low + high)/2;
    }
    return false;
}

int main()
{
    cout<<isIntegerPower(1024,2);
}
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I would implement the function like so:

bool IsWholeNumberPower(int x, int y)
{
    double power = log(x)/log(y);
    return floor(power) == power;
}

This shouldn't need check within a delta as is common with floating point comparisons, since we're checking whole numbers.

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1  
Now the question is how the "log" is implemented and why it is better than the loop. –  Michael Dec 13 '10 at 13:19
    
log(x) where x is a whole number is not a whole number. So, no you are not dealing with whole numbers. Also consider IsWholeNumberPower(-8, -2). The answer should be true. –  JeremyP Dec 13 '10 at 13:29
1  
The log approach is better than the loop, IMO, because it makes clear your intention. So long as you know that the log of a number divided by the log of another number gives you the power the second number is raised to get the first, I can't think of a clearer method (I assume most people learn this at school, but I could be way off base). If you're looking for faster code, then I can't tell you, as I've not tested this in any language. –  Matt Ellen Dec 13 '10 at 13:29
    
@JeremyP: I did not meant that log(x) would give a whole number, I meant that you only want to check that log(x)/log(y) is a whole number, so checking that the answer is within a delta of floor the answer is not necessary. You are however correct, this won't work for negative numbers. –  Matt Ellen Dec 13 '10 at 13:33
    
This one works for IsWholeNumberPower(1162261467,3) –  Paul Dec 13 '10 at 13:41

On second thoughts, don't do this. It does not work for negative x and/or y. Note that all other log-based answers presented right now are also broken in exactly the same manner.

The following is a fast general solution (in Java):

static boolean isPow(int x, int y) {
    int logyx = (int)(Math.log(x) / Math.log(y));
    return pow(y, logyx) == x || pow(y, logyx + 1) == x;
}

Where pow() is an integer exponentiation function such as the following in Java:

static int pow(int a, int b) {
    return (int)Math.pow(a, b);
}

(This works due to the following guarantee provided by Math.pow: "If both arguments are integers, then the result is exactly equal to the mathematical result of raising the first argument to the power of the second argument...")

The reason to go with logarithms instead of repeated division is performance: while log is slower than division, it is slower by a small fixed multiple. At the same time it does remove the need for a loop and therefore gives you a constant-time algorithm.

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This one works for isPow(1162261467,3) –  Paul Dec 13 '10 at 13:45

In cases where y is 2, there is a quick approach that avoids the need for a loop. This approach can be extended to cases where y is some larger power of 2.

If x is a power of 2, the binary representation of x has a single set bit. There is a fairly simple bit-fiddling algorithm for counting the bits in an integer in O(log n) time where n is the bit-width of an integer. Many processors also have specialised instructions that can handle this as a single operation, about as fast as (for example) an integer negation.

To extend the approach, though, first take a slightly different approach to checking for a single bit. First determine the position of the least significant bit. Again, there is a simple bit-fiddling algorithm, and many processors have fast specialised instructions.

If this bit is the only bit, then (1 << pos) == x. The advantage here is that if you're testing for a power of 4, you can test for pos % 2 == 0 (the single bit is at an even position). Testing for a power of any power of two, you can test for pos % (y >> 1) == 0.

In principle, you could do something similar for testing for powers of 3 and powers of powers of 3. The problem is that you'd need a machine that works in base 3, which is a tad unlikely. You can certainly test any value x to see if its representation in base y has a single non-zero digit, but you'd be doing more work that you're already doing. The above exploits the fact that computers work in binary.

Probably not worth doing in the real world, though.

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the same idea can be applied to any base. It is not easy as shifting bits but it can be done using only basic arithmetic operations (+, *, /). See my own reply to the OP for an implementation in C. –  salva Dec 13 '10 at 16:03
2  
There is a faster check for power-of-2. (x & (x-1)) == 0 –  Axn Dec 14 '10 at 21:20
    
@Axn - I've seen that trick before, but I'm very prone to forgetting about it. Of course it's not faster than an intrinsic, but it's portable. –  Steve314 Dec 18 '10 at 4:45

Previous answers are correct, I liked Paul's answer the best. It's Simple and clean. Here is the Java implementation of what he suggested:

public static boolean isPowerOfaNumber(int baseOrg, int powerOrg) {
    double base = baseOrg;
    double power = powerOrg;

    while (base % power == 0)
        base = base / power;
    // return true if base is equal 1
    return base == 1;
}
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    double a=8;
    double b=64;

    double n = Math.log(b)/Math.log(a);
    double e = Math.ceil(n);

    if((n/e) == 1){
        System.out.println("true");
    } else{
       System.out.println("false");
    }
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