I found it helpful to define an auxiliary function, `partitionsCap`

, which does not let any of the items be larger than a given value. Used recursively, it can be used to only produce the monotonically decreasing results you want (i.e. no `[1,3,1]`

when you already have `[1,1,3]`

):

```
partitions :: Int -> [[Int]]
partitions n = partitionsCap n n
partitionsCap :: Int -> Int -> [[Int]]
partitionsCap cap n
| n < 0 = error "partitions: negative number"
| n == 0 = [[]]
| n > 0 = [i : p | i <- [hi,hi-1..1], p <- partitionsCap i (n-i)]
where hi = min cap n
```

At the heart of the algorithm is the idea that, when partitioning N, you take `i`

from `n`

down to 1, and prepend `i`

to the partitions of `n-i`

. Simplified:

```
concat [map (i:) $ partitions (n-i) | i <- [n,n-1..1]]
```

but wrong:

```
> partitions 3
[[3],[2,1],[1,2],[1,1,1]]
```

We want that `[1,2]`

to go away. Hence, we need to cap the partitions we're prepending to so they won't go above `i`

:

```
concat [map (i:) $ partitionsCap i (n-i) | i <- [hi,hi-1..1]]
where hi = min cap n
```

Now, to clean it up: that *concat* and *map* so close together got my attention. A little background: list comprehensions and the list monad are very closely related, and *concatMap* is the same as `>>=`

with its arguments flipped, in the list monad. So I wondered: can those *concat* and *map* somehow turn into a `>>=`

, and can that `>>=`

somehow sweet-talk its way into the list comprehension?

In this case, the answer is yes :-)

```
[i : p | i <- [hi,hi-1..1], p <- partitionsCap i (n-i)]
where hi = min cap n
```