Yes, that's `para`

. Compare with catamorphism, or `foldr`

:

```
para :: (a -> [a] -> b -> b) -> b -> [a] -> b
foldr :: (a -> b -> b) -> b -> [a] -> b
para c n (x : xs) = c x xs (para c n xs)
foldr c n (x : xs) = c x (foldr c n xs)
para c n [] = n
foldr c n [] = n
```

Some people call paramorphisms "primitive recursion" by contrast with catamorphisms (`foldr`

) being "iteration".

Where `foldr`

's two parameters are given a recursively computed value for each recursive subobject of the input data (here, that's the tail of the list), `para`

's parameters get both the original subobject and the value computed recursively from it.

An example function that's nicely expressed with `para`

is the collection of the proper suffices of a list.

```
suff :: [x] -> [[x]]
suff = para (\ x xs suffxs -> xs : suffxs) []
```

so that

```
suff "suffix" = ["uffix", "ffix", "fix", "ix", "x", ""]
```

Possibly simpler still is

```
safeTail :: [x] -> Maybe [x]
safeTail = para (\ _ xs _ -> Just xs) Nothing
```

in which the "cons" branch ignores its recursively computed argument and just gives back the tail. Evaluated lazily, the recursive computation never happens and the tail is extracted in constant time.

You can define `foldr`

using `para`

quite easily; it's a little trickier to define `para`

from `foldr`

, but it's certainly possible, and everyone should know how it's done!

```
foldr c n = para (\ x xs t -> c x t) n
para c n = snd . foldr (\ x (xs, t) -> (x : xs, c x xs t)) ([], n)
```

The trick to defining `para`

with `foldr`

is to reconstruct a *copy* of the original data, so that we gain access to a copy of the tail at each step, even though we had no access to the original. At the end, `snd`

discards the copy of the input and gives just the output value. It's not very efficient, but if you're interested in sheer expressivity, `para`

gives you no more than `foldr`

. If you use this `foldr`

-encoded version of `para`

, then `safeTail`

will take linear time after all, copying the tail element by element.

So, that's it: `para`

is a more convenient version of `foldr`

which gives you immediate access to the tail of the list as well as the value computed from it.

In the general case, working with a datatype generated as the recursive fixpoint of a functor

```
data Fix f = In (f (Fix f))
```

you have

```
cata :: Functor f => (f t -> t) -> Fix f -> t
para :: Functor f => (f (Fix f, t) -> t) -> Fix f -> t
cata phi (In ff) = phi (fmap (cata phi) ff)
para psi (In ff) = psi (fmap keepCopy ff) where
keepCopy x = (x, para psi x)
```

and again, the two are mutually definable, with `para`

defined from `cata`

by the same "make a copy" trick

```
para psi = snd . cata (\ fxt -> (In (fmap fst fxt), psi fxt))
```

Again, `para`

is no more expressive than `cata`

, but more convenient if you need easy access to substructures of the input.

**Edit:** I remembered another nice example.

Consider binary search trees given by `Fix TreeF`

where

```
data TreeF sub = Leaf | Node sub Integer sub
```

and try defining insertion for binary search trees, first as a `cata`

, then as a `para`

. You'll find the `para`

version much easier, as at each node you will need to insert in one subtree but preserve the other as it was.

`para f base xs = foldr (uncurry f) base $ zip xs (tail $tails xs)`

, methinks. – Daniel Fischer Nov 9 '12 at 23:18`para f base xs = foldr g base (init $ tails xs) where g (x:xs) = f x xs`

. This reminds of Common Lisp's`maplist`

. – Will Ness Jul 15 '13 at 7:54