# GCD function in c++ sans cmath library

I'm writing a mixed numeral class and need a quick and easy 'greatest common denominator' function. Can anyone give me the code or a link to the code?

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BTW: it is called 'Greatest Common Divisor'. –  bjoernz Jun 17 '13 at 11:00

I'm tempted to vote to close -- it seems difficult to believe that an implementation would be hard to find, but who knows for sure.

``````unsigned GCD(unsigned u, unsigned v) {
while ( v != 0) {
unsigned r = u % v;
u = v;
v = r;
}
return u;
}
``````
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Thanks. And I googled for a good 20 minute and didn't yield any clear results. –  Connor Black Jun 8 '12 at 22:14

A quick recursive version:

``````unsigned int gcd (unsigned int n1, unsigned int n2) {
return (n2 == 0) ? n1 : gcd (n2, n1 % n2);
}
``````

or the equivalent iterative version if you're violently opposed to recursion (a):

``````unsigned int gcd (unsigned int n1, unsigned int n2) {
unsigned int tmp;
while (n2 != 0) {
tmp = n1;
n1 = n2;
n2 = tmp % n2;
}
return n1;
}
``````

Just substitute in your own data type, zero comparison, assignment and modulus method (if you're using some non-basic type like a `bignum` class, for example).

This function actually came from an earlier answer of mine for working out integral aspect ratios for screen sizes but the original source was the Euclidean algorithm I learnt a long time ago, detailed here on Wikipedia if you want to know the math behind it.

(a) The problem with some recursive solutions is that they approach the answer so slowly you tend to run out of stack space before you get there, such as with the very badly thought out (pseudo-code):

``````def sum (a:unsigned, b:unsigned):
if b == 0: return a
return sum (a + 1, b - 1)
``````

You'll find that very expensive on something like `sum (1, 1000000000)` as you (try to) use up a billion or so stack frames. The ideal use case for recursion is something like a binary search where you reduce the solution space by half for each iteration. The greatest common divisor is also one where the solution space reduces rapidly so fears about massive stack use are unfounded there.

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+1 You can even add `template<class Integral>` to replace the `int`, add a `constexpr` keyword before the function and you have a nice compile-time/runtime generic function. –  authchir Jun 9 '12 at 3:36
Possible typo in your second method. Should it `return n1`? n2 will by definition always be zero at that point. –  Jim Blackler Jan 16 at 0:37
Good catch, @Jim, fixed that up. –  paxdiablo Jan 16 at 0:50
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Sorry I forgot to say- I need the implementation using only <iostream>. –  Connor Black Jun 8 '12 at 22:08

The Euclidean algorithm is quite easy to write in C.

``````int gcd(int a, int b) {
while (b != 0)  {
int t = b;
b = a % b;
a = t;
}
return a;
}
``````
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STL algorithm library has a hidden gcd function (I'm using g++ 4.6.3).

``````#include <iostream>
#include <alogrithm>

int main()
{
cout << std::__gcd(100,24);
return 0;
}
``````

You are welcome :)

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alogrithm --> algorithm –  Mbt925 Jan 19 at 12:53
You shouldn't rely on undocumented features like that as they can change between library releases. –  vmrob Jan 21 at 19:06