Removing a number and reinserting *all its multiples* (by the primes in the set) into a priority queue is *wrong* (in the sense of the question) - i.e. it produces correct sequence but *inefficiently* so.

It is inefficient in two ways - first, it *overproduces* the sequence; second, each PriorityQueue operation incurs extra cost (the operations `remove_top`

and `insert`

are not usually both *O(1)*, certainly not in any list- or tree-based PriorityQueue implementation).

The efficient *O(n)* algorithm maintains pointers back into the sequence itself as it is being produced, to find and append the next number in *O(1)* time. In pseudocode:

```
return array h where
h[0]=1; n=0; ps=[2,3,5, ... ]; // base primes
is=[0 for each p in ps]; // indices back into h
xs=[p for each p in ps] // next multiples: xs[k]==ps[k]*h[is[k]]
repeat:
h[++n] := minimum xs
for each ref (i,x,p) in (is,xs,ps):
if( x==h[n] )
{ x := p*h[++i]; } // advance the minimal multiple/pointer
```

For each minimal multiple it advances its pointer, while at the same time calculating its next multiple value. This too effectively implements a PriorityQueue but with crucial distinctions - it is *before* the end point, not after; it doesn't create any additional storage except for the sequence itself; and its size is constant (just *k* numbers, for *k* base primes) whereas the size of past-the-end PriorityQueue grows as we progress along the sequence (in the case of Hamming sequence, based on set of *3* primes, as *n*^{2/3}, for *n* numbers of the sequence).

The classic Hamming sequence in Haskell is essentially the same algorithm:

```
h = 1 : map (2*) h `union` map (3*) h `union` map (5*) h
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
```

We can generate the smooth numbers for *arbitrary* base primes using the `foldi`

function (see Wikipedia) to fold lists in a *tree-like* fashion for efficiency, creating a fixed sized tree of comparisons:

```
smooth base_primes = h where -- strictly increasing base_primes NB!
h = 1 : foldi g [] [map (p*) h | p <- base_primes]
g (x:xs) ys = x : union xs ys
foldi f z [] = z
foldi f z (x:xs) = f x (foldi f z (pairs f xs))
pairs f (x:y:t) = f x y : pairs f t
pairs f t = t
```

It is also possible to directly calculate a *slice* of Hamming sequence around its *n*th member in *O(n*^{2/3}) time, by direct enumeration of the triples and assessing their values through logarithms, `logval(i,j,k) = i*log 2+j*log 3+k*log 5`

. This Ideone.com test entry calculates *1 billionth* Hamming number in ~~1.12~~ 0.05 seconds _{(2016-08-18: main speedup due to usage of Int instead of the default Integer where possible, even on 32-bit; additional 20% thanks to the tweak suggested by @GordonBGood, bringing band size complexity down to O(n1/3)).}

This is discussed some more in this answer where we also find its full attribution:

```
slice hi w = (c, sortBy (compare `on` fst) b) where -- hi is a top log2 value
lb5=logBase 2 5 ; lb3=logBase 2 3 -- w<1 (NB!) is (log2 width)
(Sum c, b) = fold -- total count, the band
[ ( Sum (i+1), -- total triples w/this j,k
[ (r,(i,j,k)) | frac < w ] ) -- store it, if inside the band
| k <- [ 0 .. floor ( hi /lb5) ], let p = fromIntegral k*lb5,
j <- [ 0 .. floor ((hi-p)/lb3) ], let q = fromIntegral j*lb3 + p,
let (i,frac) = pr (hi-q) ; r = hi - frac -- r = i + q
] -- (sum . map fst &&& concat . map snd)
pr = properFraction
```

This can be generalized for *k* base primes as well, probably running in *O(n*^{(k-1)/k}) time.

see this SO entry for an important later development. also, this answer is interesting. and another related answer.