It is included as a member to allow users to customize it for speed, and I guess because it makes it consistent with `>>`

.

I think it might be faster in the cases of the reader monad `((->) r)`

.

```
x <$ _ = const x
```

vs

```
x <$ fa = fmap (const x) fa = (const x) . fa
```

although, this is really a question of compiler optimization. And, it does not appear to be defined for the reader monad in base.

It also might lead to a performance boost in strict collections. Namely

```
data Strict a = Strict !a
instance Functor Strict where
fmap f (Strict a) = Strict (f a)
x <$ _ = Strict x
```

this does not obey the functor laws, but nonetheless, you might want to do this in some situations.

A third example comes from infinite collections. Consider infinite lists

```
data Long a = Cons a (Long a)
instance Functor Long where
fmap f (Cons x xs) = Cons (f x) (fmap f xs)
```

which works fine, but think about

```
countUpFrom x = Cons x (countUpFrom (x+1))
ones = 1 <$ (countUpFrom 0)
```

now, with our definition that will expand to

```
ones = 1 <$ (countUpFrom 0)
= fmap (const 1) (countUpFrom 0)
= Cons (const 1 0) (fmap (const 1) (countUpFrom 1)
= Cons (const 1 0) (Cons (const 1 1) (fmap (const 1) (countUpFrom 2))
```

that is, it will allocate a whole bunch of `Cons`

cells as you walk this list. While, on the other hand, if you defined

```
x <$ _ = let xs = Cons x xs in xs
```

than

```
ones = 1 <$ countUpFrom 0
= let xs = Cons 1 xs in xs
```

which has tied the knot. An even more extreme example comes with infinite trees

```
data ITree a = ITree a (ITree a) (ITree a)
```