I am trying to understand the "Streams as arrows" section in John Hughes' famous "Generalising Arrows to Monads". To be more precise, I am interested in writing down the Fibonacci stream.

I tweaked Hughes' definition a bit:

```
data StreamProcessor a b = Get (a -> StreamProcessor a b) |
Put b (StreamProcessor a b) |
Halt
put = Put
get = Get
```

First of all, I treat stream processors as lists which may block (waiting for input). That is:

`Put :: b -> StreamProcessor a b -> StreamProcessor a b`

matches`(:) :: a -> [a] -> [a]`

;`Halt :: StreamProcessor a b`

matches`[] :: [a]`

;`Get :: (a -> StreamProcessor a b) -> StreamProcessor a b`

helps us block the stream and wait for input.

Therefore, if we drop the `Get`

we get a list-like structure. If we also drop `Halt`

we get an infinite-list-like structure.

Here are two ways I would understand "a stream of Fibonaccis":

a non-blocked infinite stream (infinite-list-like):

`zipNonBlockedStreamsWith :: (a -> b -> c) -> StreamProcessor () a -> StreamProcessor () b -> StreamProcessor () c zipNonBlockedStreamsWith f (Put x sp) (Put y sp') = Put (f x y) (zipNonBlockedStreamsWith f sp sp') zipNonBlockedStreamsWith f Halt sp = Halt zipNonBlockedStreamsWith f sp Halt = Halt fibs :: StreamProcessor () Int fibs = put 0 (put 1 $ zipNonBlockedStreamsWith (+) fibs (tailNonBlockedStream fibs)) -- matches a well-known definition of an infinite Fibonacci list. fibsList :: [Int] fibsList = 0 : 1 : (zipWith (+) fibsList (tail fibsList)) -- with the 'fibsList', we can use folds to do the same thing. putStream :: [b] -> StreamProcessor a b -> StreamProcessor a b putStream bs sp = foldr Put sp bs fibs' :: StreamProcessor () Int fibs' = putStream fibsList Halt`

A blocked stream waits for

`n`

, outputs the`n`

th Fibonacci number and blocks again. Hughes'`Arrow`

interface helps us express it in a quite concise way:`instance Category StreamProcessor where ... instance Arrow StreamProcessor where arr f = Get $ \ a -> Put (f a) (arr f) ... fibsList :: [Int] fibsList = 0 : 1 : (zipWith (+) fibsList (tail fibsList)) blockedFibs :: StreamProcessor Int Int blockedFibs = arr (fibsList !!)`

Yet, in the paper I linked John Hughes shows another solution, `Arrow`

ing his way through:

```
instance Category StreamProcessor where
id = Get (\ x -> Put x id)
Put c bc . ab = Put c (bc . ab)
Get bbc . Put b ab = (bbc b) . ab
Get bbc . Get aab = Get $ \ a -> (Get bbc) . (aab a)
Get bbc . Halt = Halt
Halt . ab = Halt
bypass :: [b] -> [d] -> StreamProcessor b c -> StreamProcessor (b, d) (c, d)
bypass [] ds (Get f) = Get $ \ ~(b, d) -> bypass [] (ds ++ [d]) (f b)
bypass (b : bs) [] (Get f) = bypass bs [] (f b)
bypass [] (d : ds) (Put c sp) = Put (c, d) $ bypass [] ds sp
bypass bs [] (Put c sp) =
Get $ \ ~(b, d) -> Put (c, d) (bypass (bs ++ [b]) [] sp)
bypass bs ds Halt = Halt
instance Arrow StreamProcessor where
arr f = Get $ \ a -> Put (f a) (arr f)
first = bypass [] []
liftArr2 :: Arrow k => (a -> b -> c) -> k r a -> k r b -> k r c
liftArr2 f a b = a &&& b >>^ uncurry f
fibsHughes = let
fibsHughes' = put 1 (liftArr2 (+) fibsHughes fibsHughes')
in put 0 fibsHughes'
```

But it does not work the way I expect. The following function would help us take the values from the stream until it blocks or halts (using `Data.List.unfoldr`

):

```
popToTheBlockOrHalt :: StreamProcessor a b -> [b]
popToTheBlockOrHalt = let
getOutput (Put x sp) = Just (x, sp)
getOutput getOrHalt = Nothing
in unfoldr getOutput
```

So, here is what we get:

```
GHCi> popToTheBlockOrHalt fibsHughes
[0, 1]
GHCi> :t fibsHughes
fibsHughes :: StreamProcessor a Integer
```

If we check the patterns, we would see that it blocks (that is we stumble into `Get`

).

I cannot tell whether it should be that way. If it is what we want, why? If not, what is the problem? I checked and rechecked the code I wrote and it pretty much matches the definitions in Hughes' article (well, I had to add `id`

and patterns for `Halt`

- I cannot see how they could have messed the process up).

**Edit:** As it is said in the comments, in the later edition of the paper `bypass`

was slightly changed (we use that one). It is able to accumulate both withheld `b`

s and `d`

s (that is has two queues), whereas the `bypass`

from the original paper accumulates just `d`

s (that is one queue).

**Edit #2:** I just wanted to write down a function which would pop the Fibonacci numbers from the `fibsHughes`

:

```
popToTheHaltThroughImproperBlocks :: StreamProcessor () b -> [b]
popToTheHaltThroughImproperBlocks = let
getOutput (Put x sp) = Just (x, sp)
getOutput (Get c) = getOutput $ c ()
getOutput Halt = Nothing
in unfoldr getOutput
```

And here we go:

```
GHCi> (take 10 . popToTheHaltThroughImproperBlocks) fibsHughes
[0,1,1,2,3,5,8,13,21,34]
```

`(&&&)`

but I'm still trying to pinpoint the core issue.