One can produce an arbitrarily thin slice of the Hamming sequence around n-th member in time `~ n^(2/3)`

by direct enumeration of triples `(i,j,k)`

such that `N = 2^i * 3^j * 5^k`

.

WP says that `n ~ (log N)^3`

, i.e. run time `~ (log N)^2`

. Here we don't care for the exact position of the found triple in the sequence, so all the count calculations from the original code can be thrown away:

```
slice hi w = sortBy (compare `on` fst) b where -- hi>log2(N) is a top value
lb5=logBase 2 5 ; lb3=logBase 2 3 -- w<1 (NB!) is log2(width)
b = concat -- the slice
[ [ (r,(i,j,k)) | frac < w ] -- store it, if inside width
| 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)=properFraction(hi-q) ; r = hi - frac ] -- r = i + q
```

Having enumerated the triples in the slice, it is a simple matter of sorting and searching, taking practically `O(1)`

time (for *arbitrarily thin* a slice) to find the first triple above `N`

. Well, actually, for constant width (logarithmic), the amount of numbers in the slice (members of the "upper crust" in the `(i,j,k)`

-space below the `log(N)`

plane) is again `m ~ n^2/3 ~ (log N)^2`

and sorting takes `m log m`

time (so that searching, even linear, takes `~ m`

run time then). But the width can be made smaller for bigger `N`

s, following some empirical observations; and constant factors for the enumeration of triples are much higher than for the subsequent sorting anyway.

Even with constant width (logarthmic) it runs very fast, calculating the 1,000,000-th value in the Hamming sequence in a few hundredths of a second.

The original idea of "top band of triples" is due Louis Klauder, from DDJ discussion some years back.