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I'm trying to write a C program which, given a positive integer n (> 1) detect whether exists numbers x and r so that n = x^r

This is what I did so far:

while (c>=d) {
    double y = pow(sum, 1.0/d);
    if (floor(y) == y) {
        out = y;


In the program above, "c" is the maxium value for the exponent (r) and "d" will start by being equal to 2. Y is the value to be checked and the variable "out" is set to output that value later on. Basically, what the script does, is to check if the square roots of y exists: if not, he tries with the square cube and so on... When he finds it, he store the value of y in "out" so that: y = out^d

My question is, is there any more efficient way to find these values? I found some documentation online, but that's far more complicated than my high-school algebra. How can I implement this in a more efficient way?


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I think you meant n = x^r, right? –  Matias Valdenegro May 28 '11 at 17:13
yea! Sorry, my bad! n = x^r –  Joseph May 28 '11 at 17:15
Using floating point is a bad idea for finding anything perfect... –  R.. May 28 '11 at 17:19
I'd worry about getting a "small" y: floor(16.9999999999999999987643254532423) != 17 –  pmg May 28 '11 at 17:21
In particular, using floor here is definitely wrong. –  R.. May 28 '11 at 17:22

4 Answers 4

up vote 3 down vote accepted

In one of your comments, you state you want this to be compatible with gigantic numbers. In that case, you may want to bring in the GMP library, which supports operations on arbitrarily large numbers, one of those operations being checking if it is a perfect power.

It is open source, so you can check out the source code and see how they do it, if you don't want to bring in the whole library.

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Well, I've followed your suggestion and they do it through a gigantic complicated code in which I'll dive in right now. Thanks! –  Joseph May 29 '11 at 0:23
I just looked at the code... definitely non-trivial. –  Jeff Mercado May 29 '11 at 3:41

If n fits in a fixed-size (e.g. 32-bit) integer variable, the optimal solution is probably just hard-coding the list of such numbers and binary-searching it. Keep in mind, in int range, there are roughly

  • sqrt(INT_MAX) perfect squares
  • cbrt(INT_MAX) perfect cubes
  • etc.

In 32 bits, that's roughly 65536 + 2048 + 256 + 128 + 64 + ... < 70000.

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my +1 for absolute brute force performance thinking –  sehe May 28 '11 at 17:32
The problem is that I'm using unsigned long long int. I want the program to be compatible with gigantic numbers also... –  Joseph May 28 '11 at 17:36
In that case you'd need a several-gigabyte table.. :-) So other solutions might be preferable. –  R.. May 28 '11 at 17:36

You need the r-base logarithm, use an identity to calculate it using the natural log


log_r(x) = log(x)/log(r)

So you need to calculate:

x = log(n)/log(r)

(In my neck of the wood, this is highschool math. Which immediately explains my having to look up whether I remembered that identity correctly :))

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I didn't any logarithm :( How can I use this? –  Joseph May 28 '11 at 17:28
eg. double log(double x) -- Compute log(x). in math.h? –  sehe May 28 '11 at 17:31

After you are calculating y in

double y = pow(sum, 1.0/d);

you can get the nearest int to it and you can use your own power function to check for the equality condition with sum.

int x = (int)(y+0.5);
int a = your_power_func(x,d);
if (a == sum)

I guess this way you can confirm whether a number is integer power of some other number or not.

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