I am trying to find a way to translate normal recursive notation such as the |fib| function below to an arrow, retaining as much of the structure of the recursive notation as possible. In addition I would like to inspect the arrow. For this I created a datatype containing a constructor for each Arrow{..} class:

Fib:

```
fib 0 = 0
fib 1 = 1
fib n = fib (n-2) + fib (n-1)
```

My R datatype, the instances for this datatype consist of the mapping to the appropriate constructor:

```
data R x y where
-- Category
Id :: R a a
Comp :: R b c -> R a b -> R a c
-- Arrow
Arr :: (a -> b) -> R a b
Split :: R b c -> R b' c' -> R (b,b') (c,c')
Cache :: (a -> a -> Bool) -> R a a
-- ArrowChoice
Choice :: R b c -> R b' c' -> R (Either b b') (Either c c')
-- ArrowLoop
Loop :: R (b, d) (c, d) -> R b c
-- ArrowApply
Apply :: R (R b c, b) c
```

Translating the |fib| function from above first resulted in the following definition. It is not allowed however due to the proc n on the RHS of the declaration for |fibz|. I know that the grammar of the Arrow Notation prevents this, but what is the underlying reason for this?

```
fib' :: (ArrowChoice r, ArrowLoop r) => r Int Int
fib' = proc x -> do
rec fibz <- proc n -> case n of
0 -> returnA -< 0
1 -> returnA -< 1
n' -> do l <- fibz -< (n'-2)
r <- fibz -< (n'-1)
returnA -< (l+r)
fibz -<< x
```

Rewriting the function above to use a let statement compiles. However, here my second problem arises. I want to be able to inspect the recursion where it happens. However, in this case |fibz| is an infinite tree. I would like to capture the recursion into fibz, I hoped the rec would help me with that in combination with |loop| but maybe I am wrong?

```
fib'' :: (ArrowChoice r, ArrowLoop r, ArrowApply r) => r Int Int
fib'' = proc x -> do
let fibz = proc n -> case n of
0 -> returnA -< 0
1 -> returnA -< 1
n' -> do l <- fibz -< (n'-2)
r <- fibz -< (n'-1)
returnA -< (l+r)
fibz -<< x
```

Basically, is it possible to observe this kind of recursion? (Perhaps even within the boundaries of Arrow Notation) I could perhaps add another constructor like fix. Maybe I should be able to observe the binding of variables so that referring to them becomes possible. This would fall outside the scope of Arrows though.

Any thoughts on this?

**Update 1:**
I come up with this form, outside of arrow notation. This hides the recursion inside the `app`

and therefore I end up with a finite representation of the Arrow. However, I still want to be able to e.g. replace the call to `fib`

inside `app`

to a an optimised version of `fib`

.

```
fib :: (ArrowChoice r, ArrowLoop r, ArrowApply r) => r Int Int
fib
= (arr
(\ n ->
case n of
0 -> Left ()
1 -> Right (Left ())
n' -> Right (Right n'))
>>>
(arr (\ () -> 0) |||
(arr (\ () -> 1) |||
(arr (\ n' -> (n', n')) >>>
(first ( arr (\ n' -> app (fib, n' - 2))) >>>
arr (\ (l, n') -> (n', l)))
>>>
(first (arr (\ n' -> app (fib, n' - 1))) >>>
arr (\ (r, l) -> (l + r)))))))
```

This code corresponds with the following in arrow notation:

```
fib :: (ArrowChoice r, ArrowLoop r, ArrowApply r) => r Int Int
fib = proc n ->
case n of
0 -> returnA -< 0
1 -> returnA -< 1
n' ->
do l <- fib -<< (n'-2)
r <- fib -<< (n'-1)
returnA -< (l+r)
```

`fib`

in terms of`R`

? – Sjoerd Visscher Oct 11 '12 at 14:00`fib`

in terms of`R`

. (but using the class methods) – Alessandro Vermeulen Oct 11 '12 at 15:04