It's not clear what "applicative" is being used to mean without knowing the context.

If it's truly not referring to applicative functors (i.e. `Applicative`

), then it's probably referring to the form of application itself: `f a b c`

is an *applicative* form, and this is where applicative functors get their name from: `f <$> a <*> b <*> c`

is analogous. (Indeed, idiom brackets take this connection further, by letting you write it as `(| f a b c |)`

.)

Similarly, "applicative languages" can be contrasted with languages that are not primarily based on the application of function to argument (usually in prefix form); concatenative ("stack based") languages aren't applicative, for instance.

To answer the question of why applicative functors are called what they are in depth, I recommend reading
*Applicative programming with effects*; the basic idea is that a lot of situations call for something like "enhanced application": applying pure functions within some effectful context. Compare these definitions of `map`

and `mapM`

:

```
map :: (a -> b) -> [a] -> [b]
map _ [] = []
map f (x:xs) = f x : map f xs
mapM :: (Monad m) => (a -> m b) -> [a] -> m [b]
mapM _ [] = return []
mapM f (x:xs) = do
x' <- f x
xs' <- mapM f xs
return (x' : xs')
```

with `mapA`

(usually called `traverse`

):

```
mapA :: (Applicative f) => (a -> f b) -> [a] -> f [b]
mapA _ [] = pure []
mapA f (x:xs) = (:) <$> f x <*> mapA f xs
```

As you can see, `mapA`

is much more concise, and more obviously related to `map`

(even more so if you use the prefix form of `(:)`

in `map`

too). Indeed, using the applicative functor notation even when you have a full `Monad`

is common in Haskell, since it's often much more clear.

Looking at the definition helps, too:

```
class (Functor f) => Applicative f where
pure :: a -> f a
(<*>) :: f (a -> b) -> f a -> f b
```

Compare the type of `(<*>)`

to the type of application: `($) :: (a -> b) -> a -> b`

. What `Applicative`

offers is a generalised "lifted" form of application, and code using it is written in an *applicative* style.

More formally, as mentioned in the paper and pointed out by ertes, `Applicative`

is a generalisation of the SK combinators; `pure`

is a generalisation of `K :: a -> (r -> a)`

(aka `const`

), and `(<*>)`

is a generalisation of `S :: (r -> a -> b) -> (r -> a) -> (r -> b)`

. The `r -> a`

part is simply generalised to `f a`

; the original types are obtained with the `Applicative`

instance for `((->) r)`

.

As a practical matter, `pure`

also allows you to write applicative expressions in a more uniform manner: `pure f <*> effectful <*> pure x <*> effectful`

as opposed to `(\a b -> f a x b) <$> effectful <*> effectful`

.

`Applicative`

is also a`Functor`

... it's only for lack of foresight that we don't have`class Functor a => Applicative a`

. – Tom Crockett Jan 10 '12 at 20:01`Monad`

that escapes the hierarchy. – ehird Jan 11 '12 at 7:32`Applicative`

instances are functors... – Tom Crockett Jan 11 '12 at 9:12