(not exactly an answer to the question, but related)

I like to represent trees of a as "`ListT [] a`

". (`ListT`

from the `List`

package in hackage)

Then the answer for this question is just to use the function `lastL`

.

"`Monad m => ListT m a`

" is a monadic list containing "`a`

"s, where trying to get the next list item (which may find out there is no such item) is a monadic action in "`m`

".

A usage example for `ListT`

- a program that reads numbers from the user until the user does not type a number and prints the sum of numbers after each input:

```
main =
execute . joinM . fmap print .
scanl (+) 0 .
fmap (fst . head) .
takeWhile (not . null) .
fmap reads .
joinM $ (repeat getLine :: ListT IO (IO String))
```

Where `repeat`

, `scanl`

and `takeWhile`

are from `Data.List.Class`

. They work both for regular lists and monadic lists.

```
joinM :: List l => l (ItemM l a) -> l a -- (l = ListT IO, ItemM l = IO)
execute :: List l => l a -> ItemM l () -- consume the whole list and run its actions
```

If you are familiar with Python, python iterators/generators are "`ListT IO`

"s.

When using `[]`

instead of `IO`

as the monad of the monadic list, the result is a tree. Why? Imagine a list where getting the next item is an action in the list monad - the list monad means there are several options, therefore there are several "next items", which makes it a tree.

You can construct monadic lists either with higher-order functions (like the example above), or with `cons`

, or with a python-generator notation (with `yield`

) using the `GeneratorT`

monad transformer from the `generator`

package in hackage.

Disclaimer: `ListT`

and `GeneratorT`

are in no way widely used. I wrote those and I am not aware of any other users except for myself. There are several of users of equivalent `ListT`

s, such as the one from the Haskell wiki, `NondetT`

, and others.