The explanation in https://github.com/hemanth/functional-programming-jargon is unfortunately not very accurate.

A **pointed functor** is really a functor `F`

together with a function `of`

defined for *every type* `a`

, and sending a value `x`

of type `a`

into a value `of(x)`

of type `F a`

. In Hindley-Milner signature it looks like this:

```
of :: a -> F a
```

For instance, the Array functor is pointed with `of = x => [x]`

, defined for every value `x`

of any type `a`

.

Further, the function `of`

(or more precisely, the collection of functions `of`

as you have one for each type `a`

) must be a natural transformation from the identity functor into `F`

. Which means that `of`

applied to a function's value equals `of`

applied to the function's argument and then mapped over the function:

```
of(f(x)) === of(x).map(f)
```

For instance, in the Array example you have

```
[f(x)] === [x].map(f),
```

so `x => [x]`

is indeed a natural transformation.

But you can also redefine `of`

as

```
of = x => [x, x]
[f(x), f(x)] === [x, x].map(f)
```

which makes `Array`

into another pointed functor, even if the `map`

method remains the same. (Note that in each case, you only get very special arrays as values of `of(x)`

.)

However, you cannot define your `of`

as e.g.

```
of = x => [x, 0]
[f(x), 0] !== [x, 0].map(f)
```

Now

```
var grid = Grid.of({ width: 2, height: 2, list: [1, 2, 3, 4] })
```

is perfectly ok and returns your object passed wrapped into `Grid`

. Then you can map your `grid`

with any regular function `f`

from plain objects into plain objects and the result will be the same as applying `f`

and wrapping into `Grid`

, because of the natural transformation law. Note that this way you can also call `Grid.of`

with any other value like `Grid.of({width: 2})`

of even `Grid.of(2)`

. Alternatively, you can restrict the types for which `Grid.of`

is defined, then the value must only be of a type that you allow.

This one is a bit tricky:

```
Grid.of(2, 2, [1, 2, 3, 4])
```

This applies `Grid.of`

to several arguments. Since `Grid.of`

is by definition a function of only one argument, the result will be `Grid.of(2)`

, which may not be what you want. If you really want to feed all values, you probably want to write

```
Grid.of([2, 2, [1, 2, 3, 4]])
```

Alternatively, you can extend `Grid.of`

to multiple arguments by pre-wrapping them into an array internally and then applying `Grid.of`

. It really depends on what you are after.

For a real world usage example, see e.g. here where a "boring" Task is defined via `Task.of`

from a plain value. On the other hand here is a more interesting Task wrapping a function that you wouldn't get with `Task.of`

. What is important though, is that both Tasks can be used with the same uniform interface as shown on both examples.

Also note that no applicative functors are used in these examples, so there are still uses of pointed functors without being applicative.

ADDED.

See also https://github.com/MostlyAdequate/mostly-adequate-guide-it/blob/master/ch9.md#pointy-functor-factory for a nice introduction and real world uses of the Pointed Functor.

`Foo.of`

? did you mean Array.of? I thought, as of Es2015, only Array andTypedArrayhad`of`

– Jaromanda X Aug 27 '16 at 10:11`Foo`

– Jaromanda X Aug 27 '16 at 10:17`Array.of`

is pointed function because, unlike`Array`

, it interprets passed arguments in a single way no metter what arguments and how many arguments you pass, while`Array`

differently interprets`Array(5)`

and`Array(5, 7)`

. If you want to make your`Foo.of`

a pointed function, force it to interpret arguments in a single way no matter what you pass to it. – user6586783 Aug 27 '16 at 10:23