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According to Wikipedia it's supposed to be a wee bit faster than Euclid's algorithm (not much, but I was at least expecting to get equal performance). For me it is an order of magnitude slower. Could you guys help me figure out why?

I tried implementing it in Ruby. First I went with a recursive solution

def gcd_recursive(u, v)
return u|v if u==0 or v==0

if u.even?
  if v.even?
    return gcd(u>>1, v>>1)<<1
    return gcd(u>>1, v) if v.odd?
elsif u.odd? and v.even?
  return gcd(u, v>>1)
  if u < v
    u, v = v, u
  return gcd((u-v)>>1, v)

That didn't work that well, so I wanted to check how fast it would be if it was a loop

def gcd(u, v)
  return u|v if u==0 or v==0
  while ((u|v)&1)==0 do
    u=u >> 1;
    v=v >> 1;
    shift += 1
  while ((u&1) == 0) do 
    u=u >> 1
    while ((v & 1) == 0) do
      v=v >> 1

    if u < v
      v -= u
      diff = u - v
      u = v
      v = diff
  end while v != 0

These are the benchmark results

       user     system      total        real
std  0.300000   0.000000   0.300000 (  0.313091)
rbn  0.850000   0.000000   0.850000 (  0.872319)
bin  2.730000   0.000000   2.730000 (  2.782937)
rec  3.070000   0.000000   3.070000 (  3.136301)

std is the native ruby 1.9.3 C implementation.

rbn is basically the same thing (Euclid's algorithm), but written in Ruby.

bin is the loop code you see above.

rec is the recursive version.

EDIT: I ran the benchmark up there on matz' ruby 1.9.3. I tried running the same test on Rubinius and this is what I got. This is also confusing...

 rbn  1.268079   0.024001   1.292080 (  1.585107)
 bin  1.300082   0.000000   1.300082 (  1.775378)
 rec  1.396087   0.000000   1.396087 (  2.348785)
share|improve this question

This is just a guess, but I suspect it's a combination of two reasons:

  1. The binary GCD algorithm is more complex than Euclid's algorithm, and involves lower-level operations, so it suffers more from interpretation overhead when implemented in a high-level language like Ruby.
  2. Modern computers tend to have fast division (and modulo) instructions, making the standard Euclidean algorithm hard to compete with.
share|improve this answer
This is almost certainly #1 and almost certainly not #2. If most computers have fast division and modulo instructions, then all computers have very fast shift instructions, many with single cycle implementations. – brc Oct 18 '11 at 23:43
bcr, I'm not sure sure... check out my little "edit". I also did some experiments on how rubinius and matz ruby handle xor and AND. turns out matz is way faster with xors and rubinius is much faster with and operations. gist.github.com/1297201 – davorb Oct 19 '11 at 1:08
Fast division? I wish.. – harold Oct 19 '11 at 8:22
This says 77-191 clocks per 64-bit DIV; much slower than I was expecting! Bignum performance (e.g. with GMP) would be interesting to look at, as would hand-tuned assembly, but I'm not that bored. Memory allocation is another potential overhead, especially if you use bignums. – tc. Feb 22 '13 at 2:53
Am I wrong or everything is writing just here: en.wikipedia.org/wiki/Binary_GCD_algorithm#Efficiency? – Ehouarn Perret Mar 31 at 18:44

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