Here's how I'd write your code:

```
increasing :: Integer -> [Integer]
increasing 1 = [1..9]
increasing n = let allEndings x = map (10*x +) [x `mod` 10 .. 9]
in concatMap allEndings $ increasing (n - 1)
```

I arrived at this code as follows. The first thing I did was to use pattern matching instead of guards, since it's clearer here. The next thing I did was to eliminate the `liftM2`

s. They're unnecessary here, because they're always called with one size-one list; in that case, it's the same as calling `map`

. So `liftM2 (*) ps [10]`

is just `map (* 10) ps`

, and similarly for the other call sites. If you want a general replacement for `liftM2`

, though, you can use `Control.Applicative`

's `<$>`

(which is just `fmap`

) and `<*>`

to replace `liftMn`

for any `n`

: `liftMn f a b c ... z`

becomes `f <$> a <*> b <*> c <*> ... <*> z`

. Whether or not it's nicer is a matter of taste; I happen to like it.^{1} But here, we can eliminate that entirely.

The next place I simplified the original code is the `do ...`

. You never actually take advantage of the fact that you're in a `do`

-block, and so that code can become

```
let ps = increasing (n - 1)
last = map (`mod` 10) ps
next = map (* 10) ps
in alternateEndings next last
```

From here, arriving at my code essentially involved writing fusing all of your `map`

s together. One of the only remaining calls that wasn't a `map`

was `zipWith`

. But because you effectively have `zipWith alts next last`

, you only work with `10*p`

and `p `mod` 10`

at the same time, so we can calculate them in the same function. This leads to

```
let ps = increasing (n - 1)
in concat $ map alts ps
where alts p = map (10*p +) [y `mod` 10..9]
```

And this is basically my code: `concat $ map ...`

should always become `concatMap`

(which, incidentally, is `=<<`

in the list monad), we only use `ps`

once so we can fold it in, and I prefer `let`

to `where`

.

**1:** Technically, this only works for `Applicative`

s, so if you happen to be using a monad which hasn't been made one, `<$>`

is ``liftM``

and `<*>`

is ``ap``

. All monads can be made applicative functors, though, and many of them have been.