Well this was easier than I thought. This will do 1000 Hammings in 0.05 seconds on my slow PC at home. This afternoon at work and a faster PC times of less than 600 were coming out as zero seconds.

This take Hammings from Hammings. It's based on doing it fastest in Excel.

I was getting wrong numbers after 250000, with `Int`

. The numbers grow very big very fast, so `Integer`

must be used to be sure, because `Int`

is bounded.

```
mkHamm :: [Integer] -> [Integer] -> [Integer] -> [Integer]
-> Int -> (Integer, [Int])
mkHamm ml (x:xs) (y:ys) (z:zs) n =
if n <= 1
then (last ml, map length [(x:xs), (y:ys), (z:zs)])
else mkHamm (ml++[m]) as bs cs (n-1)
where
m = minimum [x,y,z]
as = if x == m then xs ++ [m*2] else (x:xs) ++ [m*2]
bs = if y == m then ys ++ [m*3] else (y:ys) ++ [m*3]
cs = if z == m then zs ++ [m*5] else (z:zs) ++ [m*5]
```

Testing,

```
> mkHamm [1] [2] [3] [5] 5000
(50837316566580,[306,479,692]) -- (0.41 secs)
> mkHamm [1] [2] [3] [5] 10000
(288325195312500000,[488,767,1109]) -- (1.79 secs)
> logBase 2 (1.79/0.41) -- log of times ratio =
2.1262637726461726 -- empirical order of growth
> map (logBase 2) [488/306, 767/479, 1109/692] :: [Float]
[0.6733495, 0.6792009, 0.68041545] -- leftovers sizes ratios
```

This means that this code's run time's empirical order of growth is above quadratic (`~n^2.13`

as measured, interpreted, at GHCi prompt).

Also, the sizes of the three dangling overproduced segments of the sequence are each `~n^0.67`

i.e. `~n^(2/3)`

.

Additionally, this code is non-lazy: the resulting sequence's first element can only be accessed *only after* the *very last* one is calculated.

The state of the art code in the question is linear, overproduces exactly *0* elements past the point of interest, and is properly lazy: it starts producing its numbers immediately.

So, though an immense improvement over the previous answers by this poster, it is still significantly worse than the original, let alone its improvement as appearing in the top two answers.

**12.31.2018**

Only the very best people educate. @Will Ness also has authored or co-authored 19 chapters in GoalKicker.com “Haskell for Professionals”. The free book is a treasure.

I had carried around the idea of a function that would do this, like this. I was apprehensive because I thought it would be convoluted and involved logic like in some modern languages. I decided to start writing and was amazed how easy Haskell makes the realization of even bad ideas.

I've not had difficulty generating unique lists. My problem is the lists I generate do not end well. Even when I use diagonalization they leave residual values making their use unreliable at best.

Here is a reworked 3's and 5's list with nothing residual at the end. The denationalization is to reduce residual values not to eliminate duplicates which are never included anyway.

```
g3s5s n=[t*b|(a,b)<-[ (((d+n)-(d*2)), 5^d) | d <- [0..n]],
t <-[ 3^e | e <- [0..a+8]],
(t*b)<-(3^(n+6))+a]
ham2 n = take n $ ham2' (drop 1.sort.g3s5s $ 48) [1]
ham2' o@(f:fo) e@(h:hx) = if h == min h f
then h:ham2' o (hx ++ [h*2])
else f:ham2' fo ( e ++ [f*2])
```

The `twos`

list can be generated with all `2^e`

s multiplied by each of the `3s5s`

but when identity `2^0`

is included, then, in total, it is the Hammings.

**3/25/2019**

Well, finally. I knew this some time ago but could not implement it without excess values at the end. The problem was how to not generate the excess that is the result of a Cartesian Product. I use Excel a lot and could not see the pattern of values to exclude from the Cartesian Product worksheet. Then, eureka! The functions generate lists of each lead factor. The value to limit the values in each list is the end point of the first list. When this is done, all Hammings are produced with no excess.

Two functions for Hammings. The first is a new 3's & 5's list which is then used to create multiples with the 2's. The multiples are Hammings.

```
h35r x = h3s5s x (5^x)
h3s5s x c = [t| n<-[3^e|e<-[0..x]],
m<-[5^e|e<-[0..x]],
t<-[n*m],
t <= c ]
a2r n = sort $ a2s n (2^n)
a2s n c = [h| b<-h35r n,
a<-[2^e| e<-[0..n]],
h<-[a*b],
h <= c ]
```

`last $ a2r 50`

1125899906842624

(0.16 secs, 321,326,648 bytes)

2^50

1125899906842624

(0.00 secs, 95,424 bytes

This is an alternate, cleaner & faster with less memory usage implementation.

```
gnf n f = scanl (*) 1 $ replicate f n
mk35 n = (\c-> [m| t<- gnf 3 n, f<- gnf 5 n, m<- [t*f], m<= c]) (2^(n+1))
mkHams n = (\c-> sort [m| t<- mk35 n, f<- gnf 2 (n+1), m<- [t*f], m<= c]) (2^(n+1))
```

`last $ mkHams 50`

2251799813685248

(0.03 secs, 12,869,000 bytes)

`2^51`

2251799813685248

**5/6/2019**

Well, I tried limiting differently but always come back to what is simplest. I am opting for the least memory usage as also seeming to be the fastest.

I also opted to use `map`

with an implicit parameter.

I also found that `mergeAll`

from `Data.List.Ordered`

is faster that `sort`

or `sort`

and `concat`

.

I also like when sublists are created so I can analyze the data much easier.

Then, because of @Will Ness switched to `iterate`

instead of `scanl`

making much cleaner code. Also because of @Will Ness I stopped using the last of of 2s list and switched to one value determining all lengths.

I do think recursively defined lists are more efficient, the previous number multiplied by a factor.

Just separating the function into two doesn't make a difference so the 3 and 5 multiples would be

```
m35 lim = mergeAll $
map (takeWhile (<=lim).iterate (*3)) $
takeWhile (<=lim).iterate (*5) $ 1
```

And the 2s each multiplied by the product of 3s and 5s

```
ham n = mergeAll $
map (takeWhile (<=lim).iterate (*2)) $ m35 lim
where lim= 2^n
```

After editing the function I ran it

`last $ ham 50`

1125899906842624

(0.00 secs, 7,029,728 bytes)

then

`last $ ham 100`

1267650600228229401496703205376

(0.03 secs, 64,395,928 bytes)

It is probably better to use `10^n`

but for comparison I again used `2^n`

**5/11/2019**

Because I so prefer infinite and recursive lists I became a bit obsessed with making these infinite.

I was so impressed and inspired with @Daniel Wagner and his `Data.Universe.Helpers`

I started using `+*+`

and `+++`

but then added my own infinite list. I had to `mergeAll`

my list to work but then realized the infinite 3 and 5 multiples were exactly what they should be. So, I added the 2s and `mergeAll`

d everything and they came out. Before, I stupidly thought `mergeAll`

would not handle infinite list but it does most marvelously.

When a list is infinite in Haskell, Haskell calculates just what is needed, that is, is lazy. The adjunct is that it does calculate from, the start.

Now, since Haskell multiples until the limit of what is wanted, no limit is needed in the function, that is, no more `takeWhile`

. The speed up is incredible and the memory lowered too,

The following is on my slow home PC with 3GB of RAM.

```
tia = mergeAll.map (iterate (*2)) $
mergeAll.map (iterate (*3)) $ iterate (*5) 1
```

last $ take 10000 tia

288325195312500000

(0.02 secs, 5,861,656 bytes)

**6.5.2019**
I learned how to `ghc -02`

So the following is for 50000 Hammings to 2.38E+30. And this is further proof my code is garbage.

```
INIT time 0.000s ( 0.000s elapsed)
MUT time 0.000s ( 0.916s elapsed)
GC time 0.047s ( 0.041s elapsed)
EXIT time 0.000s ( 0.005s elapsed)
Total time 0.047s ( 0.962s elapsed)
Alloc rate 0 bytes per MUT second
Productivity 0.0% of total user, 95.8% of total elapsed
```

**6.13.2019**

@Will Ness rawks. He provided a clean and elegant revision of `tia`

above and it proved to be five times as fast in `GHCi`

. When I `ghc -O2 +RTS -s`

his against mine, mine was several times as fast. There had to be a compromise.

So, I started reading about fusion that I had encountered in R. Bird's *Thinking Functionally with Haskell* and almost immediately tried this.

```
mai n = mergeAll.map (iterate (*n))
mai 2 $ mai 3 $ iterate (*5) 1
```

It matched Will's at 0.08 for 100K Hammings in `GHCi`

but what really surprised me is (also for 100K Hammings.) this and especially the elapsed times. 100K is up to 2.9e+38.

```
TASKS: 3 (1 bound, 2 peak workers (2 total), using -N1)
SPARKS: 0 (0 converted, 0 overflowed, 0 dud, 0 GC'd, 0 fizzled)
INIT time 0.000s ( 0.000s elapsed)
MUT time 0.000s ( 0.002s elapsed)
GC time 0.000s ( 0.000s elapsed)
EXIT time 0.000s ( 0.000s elapsed)
Total time 0.000s ( 0.002s elapsed)
Alloc rate 0 bytes per MUT second
Productivity 100.0% of total user, 90.2% of total elapsed
```

`~ n log n`

is usually manifesting itself as`n^(1+a)`

with low`a`

's ) 2. thatisthe question.... :) – Will Ness Sep 18 '12 at 15:51`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`O(n)`

algorithm. – Will Ness Sep 18 '12 at 17:00