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(this is exciting!) I know, the subject matter is well known. The state of the art (in Haskell as well as other languages) for efficient generation of unbounded increasing sequence of Hamming numbers, without duplicates and without omissions, has long been the following (AFAIK - and btw it is equivalent to the original Edsger Dijkstra's code too):

hamm :: [Integer]
hamm = 1 : map (2*) hamm `union` map (3*) hamm `union` map (5*) hamm
    union a@(x:xs) b@(y:ys) = case compare x y of
        LT -> x : union  xs  b
        EQ -> x : union  xs  ys
        GT -> y : union  a   ys

The question I'm asking is, can you find the way to make it more efficient in any significant measure? Is it still the state of the art or is it in fact possible to improve this to run twice faster and with better empirical orders of growth to boot?

If your answer is yes, please show the code and discuss its speed and empirical orders of growth in comparison to the above (it runs at about ~ n^1.05 .. n^1.10 for first few hundreds of thousands of numbers produced). Also, if it exists, can this efficient algorithm be extended to producing a sequence of smooth numbers with any given set of primes?

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1. I would have expected an analysis like O(n log n), are you sure this is as bad as the polynomial you're suggesting? 2. Isn't this pretty much the state of the art regardless of language? –  Daniel Wagner Sep 18 '12 at 15:49
@DanielWagner 1. that's the empirical figure, check out the WP link (~ n log n is usually manifesting itself as n^(1+a) with low a's ) 2. that is the question.... :) –  Will Ness Sep 18 '12 at 15:51
@DanielWagner I mean, is it still the state of the art? –  Will Ness Sep 18 '12 at 15:57
@DanielWagner about your 1., the a in n^(1+a) for true ~ n log n should diminish as n grows, but here the memory retention comes into play, and then bignum arithmetic starts taking its toll; so in practice the a for the classical code grows, for n = 100,000 ... 1 mil and up. –  Will Ness Sep 18 '12 at 16:01
also, this is theoretically an O(n) algorithm. –  Will Ness Sep 18 '12 at 17:00

2 Answers 2

up vote 7 down vote accepted

If a constant factor(1) speedup counts as significant, then I can offer a significantly more efficient version:

hamm :: [Integer]
hamm = mrg1 hamm3 (map (2*) hamm)
    hamm5 = iterate (5*) 1
    hamm3 = mrg1 hamm5 (map (3*) hamm3)
    merge a@(x:xs) b@(y:ys)
        | x < y     = x : merge xs b
        | otherwise = y : merge a ys
    mrg1 (x:xs) ys = x : merge xs ys

You can easily generalise it to smooth numbers for a given set of primes:

hamm :: [Integer] -> [Integer]
hamm [] = [1]
hamm [p] = iterate (p*) 1
hamm ps = foldl' next (iterate (q*) 1) qs
    (q:qs) = sortBy (flip compare) ps
    next prev m = let res = mrg1 prev (map (m*) res) in res
    merge a@(x:xs) b@(y:ys)
        | x < y     = x : merge xs b
        | otherwise = y : merge a ys
    mrg1 (x:xs) ys = x : merge xs ys

It's more efficient because that algorithm doesn't produce any duplicates and it uses less memory. In your version, when a Hamming number near h is produced, the part of the list between h/5 and h has to be in memory. In my version, only the part between h/2 and h of the full list, and the part between h/3 and h of the 3-5-list needs to be in memory. Since the 3-5-list is much sparser, and the density of k-smooth numbers decreases, those two list parts need much less memory that the larger part of the full list.

Some timings for the two algorithms to produce the kth Hamming number, with empirical complexity of each target relative to the previous, excluding and including GC time:

  k            Yours (MUT/GC)               Mine (MUT/GC)
 10^5           0.03/0.01                    0.01/0.01      -- too short to say much, really
2*10^5          0.07/0.02                    0.02/0.01
5*10^5          0.17/0.06  0.968  1.024      0.06/0.04      1.199    1.314
 10^6           0.36/0.13  1.082  1.091      0.11/0.10      0.874    1.070
2*10^6          0.77/0.27  1.097  1.086      0.21/0.21      0.933    1.000
5*10^6          1.96/0.71  1.020  1.029      0.55/0.59      1.051    1.090
 10^7           4.05/1.45  1.047  1.043      1.14/1.25      1.052    1.068
2*10^7          8.73/2.99  1.108  1.091      2.31/2.65      1.019    1.053
5*10^7         21.53/7.83  0.985  1.002      6.01/7.05      1.044    1.057
 10^8          45.83/16.79 1.090  1.093     12.42/15.26     1.047    1.084

As you can see, the factor between the MUT times is about 3.5, but the GC time is not much different.

(1) Well, it looks constant, and I think both variants have the same computational complexity, but I haven't pulled out pencil and paper to prove it, nor do I intend to.

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I meant empirical orders of growth, as in WP link in my question. It's just logBase (n2/n1) (t2/t1). taking 10^7 vs 10^6, it's logBase 10 (1.14/0.11) = 1.016, so it's n^1.016 empirically, at that range (and the classical is ~ n^1.051, if you make the calculation. Theoretically, the classical one is O(n) though empirically it's ~ n^1.03..1.10. –  Will Ness Sep 18 '12 at 18:08
so yes, you nailed it. I'll post an answer later with more details. Credit goes not to me; I just came across it somewhere, and wanted to make it known. Notice that at lower range your speedup is not 3.6, but 3.3 and 2.8. What I have right now, gives a speedup of 2.5 at low range. But you've successfully reinvented this wheel, and made it even faster, it seems. I think this is an exciting news. :) –  Will Ness Sep 18 '12 at 18:22
(actually, the speedup is roughly the same; I compared total times; comparing total times in your answer the speedup is around 2.3x). –  Will Ness Sep 18 '12 at 20:09
Within experimental error, I get the same times for the fix version and mine. Mine allocates about 200 bytes more and has slightly higher residency, but the figures are very close (no wonder, it's basically the same algorithm). –  Daniel Fischer Sep 18 '12 at 20:18
yeah, but the code to which I referred, originally used the increasing order of factors, and it is your analysis that points out it is better to use the opposite order...!! :) –  Will Ness Sep 19 '12 at 6:15

So basically, now that Daniel Fischer gave his answer, I can say that I came across this recently, and I think this is an exciting development, since the classical code was known for ages, since Dijkstra.

Daniel correctly identified the redundancy of the duplicates generation which must then be removed, in the classical version.

The credit for the original discovery (AFAIK) goes to Rosettacode.org's contributor Ledrug, as of 2012-08-26. And of course the independent discovery by Daniel Fischer, here (2012-09-18).

Re-written slightly, that code is:

import Data.Function (fix)

hamm = 1:foldl (\s n->fix (merge s.(n:).map (n*))) [] [5,3,2]

with the usual implementation of merge,

merge a@(x:xs) b@(y:ys) | x < y     = x:merge xs b
                        | otherwise = y:merge a ys
merge [] b = b
merge a [] = a

It gives about 2.0x - 2.5x a speedup, and slight improvement in the empirical orders of growth, vs. the classical version.

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