Quote Wikipedia:

A combinator is a higher-order function that uses only function application and earlier defined combinators to define a result from its arguments.

Now what does this mean? It means a combinator is a function (output is determined solely by its input) whose input includes a function as an argument.

What do such functions look like and what are they used for? Here are some examples:

`(f o g)(x) = f(g(x))`

Here `o`

is a combinator that takes in 2 functions , `f`

and `g`

, and returns a function as its result, the composition of `f`

with `g`

, namely `f o g`

.

Combinators can be used to hide logic. Say we have a data type `NumberUndefined`

, where `NumberUndefined`

can take on a numeric value `Num x`

or a value `Undefined`

, where `x`

a is a `Number`

. Now we want to construct addition, subtraction, multiplication, and division for this new numeric type. The semantics are the same as for those of `Number`

except if `Undefined`

is an input, the output must also be `Undefined`

and when dividing by the number `0`

the output is also `Undefined`

.

One could write the tedious code as below:

```
Undefined +' num = Undefined
num +' Undefined = Undefined
(Num x) +' (Num y) = Num (x + y)
Undefined -' num = Undefined
num -' Undefined = Undefined
(Num x) -' (Num y) = Num (x - y)
Undefined *' num = Undefined
num *' Undefined = Undefined
(Num x) *' (Num y) = Num (x * y)
Undefined /' num = Undefined
num /' Undefined = Undefined
(Num x) /' (Num y) = if y == 0 then Undefined else Num (x / y)
```

Notice how the all have the same logic concerning `Undefined`

input values. Only division does a bit more. The solution is to extract out the logic by making it a combinator.

```
comb (~) Undefined num = Undefined
comb (~) num Undefined = Undefined
comb (~) (Num x) (Num y) = Num (x ~ y)
x +' y = comb (+) x y
x -' y = comb (-) x y
x *' y = comb (*) x y
x /' y = if y == Num 0 then Undefined else comb (/) x y
```

This can be generalized into the so-called `Maybe`

monad that programmers make use of in functional languages like Haskell, but I won't go there.