Sign up ×
Stack Overflow is a community of 4.7 million programmers, just like you, helping each other. Join them; it only takes a minute:

Consider this implementation of Euclid's algorithm:

function gcd(a, b)
    while b ≠ 0
       t := b
       b := a mod b
       a := t
    return a

A nice proof on wikipedia shows that the algorithm "always needs less than O(h) divisions, where h is the number of digits in the smaller number b".

However, on a Turing Machine a procedure that computes a mod b has a time complexity of O(a+b). My intuition and some large tests tell me that the complexity for Euclid's algorithm is still O(a+b) on a Turing Machine.

Any thoughts on how to prove that?

share|improve this question
Just as a side note: The classical Euclidian algorithm does not know about mod. A repeated minus is used there. – tb- Oct 31 '12 at 19:39

1 Answer 1

up vote 1 down vote accepted

If I were implementing GCD on binary numbers on a Turing machine, I'd implement the following algorithm. I can't see how it would be smaller than O((ln a + ln b)^2) though. The most efficient representation I think would be bitwise interleaving both values after step 2.

  1. Let s1 = the number of zeros in the least significant bits of a. Delete these bottom s1 zero bits.
  2. Let s2 = the number of zeros in the least significant bits of b. Delete these bottom s2 zero bits.
  3. Let s = min(s1,s2)
  4. Now a and b are both odd. If b < a then swap a and b.
  5. b >= a. Set b = b - a, then delete all the least significant zero bits from b.
  6. If b != 0, goto 4.
  7. Add s zero bits onto the end of a. This is the result.
share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.