@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.