# What effects are modeled by the stream (infinite list) monad?

Various instances of monads model different type of effects: for example, `Maybe` models partiality, `List` non-determinism, `Reader` read-only state. I would like to know if there is such an intuitive explanation for the monad instance of the stream data type (or infinite list or co-list), `data Stream a = Cons a (Stream a)` (see below its monad instance definition). I've stumbled upon the stream monad on a few different occasions and I would like to understand better its uses.

``````data Stream a = Cons a (Stream a)

instance Functor Stream where
fmap f (Cons x xs) = Cons (f x) (fmap f xs)

instance Applicative Stream where
pure a                      = Cons a (pure a)
(Cons f fs) <*> (Cons a as) = Cons (f a) (fs <*> as)

xs >>= f = diag (fmap f xs)

diag :: Stream (Stream a) -> Stream a
diag (Cons xs xss) = Cons (hd xs) (diag (fmap tl xss))
where
hd (Cons a _ ) = a
tl (Cons _ as) = as
``````

P.S.: I'm not sure if I'm very precise in my language (especially when using the word "effect"), so feel free to correct me.

• It models infinite computations in which you can observe individual steps of the computation. Feb 14, 2018 at 13:04

The `Stream` monad is isomorphic to `Reader Natural` (`Natural`: natural numbers), meaning that there is a bijection between `Stream` and `Reader Natural` which preserves their monadic structure.

### Intuitively

Both `Stream a` and `Reader Natural a` (`Natural -> a`) can be seen as representing infinite collections of `a` indexed by integers.

``````fStream = Cons a0 (Cons a1 (Cons a2 ...))

fReader = \i -> case i of
0 -> a0
1 -> a1
2 -> a2
...
``````

Their `Applicative` and `Monad` instances both compose elements index-wise. It's easier to show the intuition for `Applicative`. Below, we show a stream `A` of `a0, a1, ...`, and `B` of `b0, b1, ...`, and their composition `AB = liftA2 (+) A B`, and an equivalent presentation of functions.

``````fStreamA  = Cons  a0     (Cons  a1     ...)
fStreamB  = Cons     b0  (Cons     b1  ...)
fStreamAB = Cons (a0+b0) (Cons (a1+b1) ...)
fStreamAB = liftA2 (+) fStreamA fStreamB

-- lambda case "\case" is sugar for "\x -> case x of"
fReaderA = \case 0 -> a0    ; 1 -> a1    ; ...
fReaderB = \case 0 ->    b0 ; 1 -> b1    ; ...
fReaderC = \case 0 -> a0+b0 ; 1 -> a1+b1 ; ...
``````

### Formally

The bijection:

``````import Numeric.Natural  -- in the base library

-- It could also be Integer, there is a bijection Integer <-> Natural
type ReaderN a = Natural -> a

tailReader r = \i -> r (i+1)

toStream :: ReaderN a -> Stream a
toStream r = Cons (r 0) (toStream (tailReader r))

fromStream :: Stream a -> ReaderN a
fromStream (Cons a s) = \i -> case i of
0 -> a
i -> fromStream s (i-1)
``````

`toStream` and `fromStream` are bijections, meaning that they satisfy these equations:

``````toStream (fromStream s) = s :: Stream a
fromStream (toStream r) = r :: ReaderN a
``````

"Isomorphism" is a general notion; two things being isomorphic usually means that there is a bijection satisfying certain equations, which depend on the structure or interface being considered. In this case, we are talking about the structure of monads, and we say that two monads are isomorphic if there is a bijection which satisfies these equations:

``````toStream (return a) = return a
toStream (u >>= k) = toStream u >>= (toStream . k)
``````

The idea is that we get the same result whether we apply the functions `return` and `(>>=)` "before or after" the bijection. (The similar equations using `fromStream` can then be derived from these two equations and the other two above).

• Can you elaborate a bit? It's hard for me to understand how exactly do you see `ask' :: a` defined here. Feb 14, 2018 at 13:51
• The `Reader` is another name for the type of functions (I should have said that from the start): `type Reader r a = r -> a`. I added an explanation of what it means for these types to be isomorphic. Feb 14, 2018 at 14:33

@Li-yao Xia's answer pretty much covers it, but if it helps your intuition, think of the `Stream` monad as modeling an infinite sequence of parallel computations. A `Stream` value itself is an (infinite) sequence of values, and I can use the `Functor` instance to apply the same function in parallel to all values in the sequence; the `Applicative` instance to apply a sequence of given functions to a sequence of values, pointwise with each function applied to the corresponding value; and the `Monad` instance to apply a computation to each value in the sequence with a result that can depend on both the value and its position within the sequence.

As an example of some typical operations, here are some sample sequences plus a Show-instance

``````instance (Show a) => Show (Stream a) where
show = show . take 10 . toList
nat = go 1 where go x = Cons x (go (x+1))
odds = go 1 where go x = Cons x (go (x+2))
``````

giving:

``````> odds
[1,3,5,7,9,11,13,15,17,19]
> -- apply same function to all values
> let evens = fmap (1+) odds
> evens
[2,4,6,8,10,12,14,16,18,20]
> -- pointwise application of functions to values
> (+) <\$> odds <*> evens
[3,7,11,15,19,23,27,31,35,39]
> -- computation that depends on value and structure (position)
> odds >>= \val -> fmap (\pos -> (pos,val)) nat
[(1,1),(2,3),(3,5),(4,7),(5,9),(6,11),(7,13),(8,15),(9,17),(10,19)]
>
``````

The difference between the `Applicative` and `Monad`ic computations here is similar to other monads: the applicative operations have a static structure, in the sense that each result in `a <*> b` depends only on the values of the corresponding elements in `a` and `b` independent of how they fit in to the larger structure (i.e., their positions in the sequence); in contrast, the monadic operations can have a structure that depends on the underlying values, so that in the expression `as >>= f`, for a given value `a` in `as`, the corresponding result can depend both on the specific value `a` and structurally on its position within the sequence (since this will determine which element of the sequence `f a` will provide the result).

It turns out that in this case the apparent additional generality of monadic computations doesn't translate into any actual additional generality, as you can see by the fact that the last example above is equivalent to the purely applicative operation:

``````(,) <\$> nat <*> odds
``````

More generally, given a monadic action `f :: a -> Stream b`, it will always be possible to write it as:

``````f a = Cons (f1 a) (Cons (f2 a) ...))
``````

for appropriately defined `f1 :: a -> b`, `f2 :: a -> b`, etc., after which we'll be able to express the monadic action as an application action:

``````as >>= f = (Cons f1 (Cons f2 ...)) <*> as
``````

Contrast this with what happens in the `List` monad: Given `f :: a -> List b`, if we could write:

``````f a = [f1 a, f2 a, ..., fn a]
``````

(meaning in particular that the number of elements in the result would be determined by `f` alone, regardless of the value of `a`), then we'd have the same situation:

``````as >>= f = as <**> [f1,...,fn]
``````

and every monadic list operation would be a fundamentally applicative operation.

So, the fact that not all finite lists are the same length makes the `List` monad more powerful than its applicative, but because all (infinite) sequences are the same length, the `Stream` monad adds nothing over the applicative instance.

• I've found your observation that the `Monad` and `Applicative` instances of the `Stream` are similar in power very enlightening. Thank you! Feb 15, 2018 at 10:23
• re your "the Applicative instance appl[ies] a sequence of given functions [emphasis mine] to a sequence of values", but what about `xs = liftA2 (+) (Cons 0 (Cons 1 xs)) (Cons 1 xs)`? there's no (fully) given functions there, i.e. though Applicative it is an essentially sequential computation. maybe what's a "fully given function" can be debated but the essentially sequential nature of that computation I think is totally self-evident. (see this for the background). could you clarify? May 12, 2019 at 17:51