While this is a great exercise for getting to understand lists and Haskell in general, it is also a great exercise for understanding what the `Applicative`

class is all about. In particular, the `[]`

instance for `Applicative`

. Your `zipInf`

that you want is exactly `liftA2 (,)`

```
λ: :t liftA2
liftA2 :: Applicative f => (a -> b -> c) -> f a -> f b -> f c
λ: :t (,)
(,) :: a -> b -> (a, b)
λ: :t liftA2 (,)
liftA2 (,) :: Applicative f => f a -> f b -> f (a, b)
```

We just need to make sure that `[]`

is an `Applicative`

.

```
λ: :i []
...
instance Applicative [] -- Defined in `Control.Applicative'
...
```

So it's an `Applicative`

. It might make it easier to understand if we annotate our type a bit

```
λ: :t liftA2 (,) `asAppliedTo` []
[a] -> [b] -> [(a, b)]
```

Yep, that's the same type.

```
λ: liftA2 (,) [0..2] ['A'..'C']
[(0,'A'),(0,'B'),(0,'C'),(1,'A'),(1,'B'),(1,'C'),(2,'A'),(2,'B'),(2,'C')]
```

Looks like it works!
So you didn't have to do anything to write this, and it's arguably more understandable than a recursive definition would be. Plus, you didn't have to worry about edge cases like you would when rolling your own solution.

You can also write it a bit more idiomantically using `<$>`

(or `fmap`

) and `<*>`

.

```
λ: (,) <$> [0..2] <*> ['A'..'C']
[(0,'A'),(0,'B'),(0,'C'),(1,'A'),(1,'B'),(1,'C'),(2,'A'),(2,'B'),(2,'C')]
λ: take 9 $ (,) <$> "A" <*> [0..]
[('A',0),('A',1),('A',2),('A',3),('A',4),('A',5),('A',6),('A',7),('A',8)]
```

Or you could leverage the full power of `Monad`

(which is quite unnecessary in this case):

```
λ: do {n <- [0..2]; c <- ['A'..'C']; return (n, c)}
[(0,'A'),(0,'B'),(0,'C'),(1,'A'),(1,'B'),(1,'C'),(2,'A'),(2,'B'),(2,'C')]
```

Also, if you're wondering how you could get different semantics from `Applicative`

for `[]`

there is at least one other List instance for `Applicative`

: `ZipList`

```
λ: :i ZipList
newtype ZipList a = ZipList {getZipList :: [a]}
-- Defined in `Control.Applicative'
instance Functor ZipList -- Defined in `Control.Applicative'
instance Applicative ZipList -- Defined in `Control.Applicative'
```

This instance provides zipping style semantics for its `Applicative`

instance.

```
λ: getZipList $ (,) <$> ZipList [0..2] <*> ZipList ['A'..'C']
[(0,'A'),(1,'B'),(2,'C')]
```

Both of these are good introductions to the `Applicative`

typeclass, because they're readily available, fairly intuitive, help prevent you from making bugs, and show that there are cases where a single type has more than one instance of a typeclass.