# F# types

Let's begin from the beginning.

F# uses the colon (`:`

) notation to indicate types of things. Let's say you define a value of type `int`

:

```
let myNumber = 5
```

F# Interactive will understand that `myNumber`

is an integer, and will tell you this by:

```
myNumber : int
```

which is read as

`myNumber`

is of type `int`

# F# functional types

So far so good. Let's introduce something else, **functional types**. A functional type is simply the *type of a function*. F# uses `->`

to denote a functional type. This arrow symbolizes that what is written on its left-hand side is transformed into what is written into its right-hand side.

Let's consider a simple function, that takes one argument and transforms it into one output. An example of such a function would be:

```
isEven : int -> bool
```

This introduces the name of the function (on the left of the `:`

), and its type. This line can be read in English as:

`isEven`

is of type function that transforms an `int`

into a `bool`

.

Note that to correctly interpret what is being said, you should make a short pause just after the part "is of type", and then read the rest of the sentence at once, without pausing.

# In F# functions are values

In F#, functions are (almost) no more special than *ordinary* types. They are things that you can pass around to functions, return from functions, just like bools, ints or strings.

So if you have:

```
myNumber : int
isEven : int -> bool
```

You should consider `int`

and `int -> bool`

as two entities of the same kind: types. Here, `myNumber`

is a value of type `int`

, and `isEven`

is a value of type `int -> bool`

(this is what I'm trying to symbolize when I talk about the *short pause* above).

# Function application

Values of types that contain `->`

happens to be also called *functions*, and have special powers: you can *apply* a function to a value. So, for example,

```
isEven myNumber
```

means that you are applying the function called `isEven`

to the value `myNumber`

. As you can expect by inspecting the type of `isEven`

, it will return a boolean value. If you have correctly implemented `isEven`

, it would obviously return `false`

.

# A function that returns a value of a functional type

Let's define a generic function to determine is an integer is multiple of some other integer. We can imagine that our function's type will be (the parenthesis are here to help you understand, they might or might not be present, they have a special meaning):

```
isMultipleOf : int -> (int -> bool)
```

As you can guess, this is read as:

`isMultipleOf`

is of type (PAUSE) function that transforms an `int`

into (PAUSE) function that transforms an `int`

into a `bool`

.

(here the (PAUSE) denote the pauses when reading out loud).

We will define this function later. Before that, let's see how we can use it:

```
let isEven = isMultipleOf 2
```

F# interactive would answer:

```
isEven : int -> bool
```

which is read as

`isEven`

is of type `int -> bool`

Here, `isEven`

has type `int -> bool`

, since we have just given the value 2 (`int`

) to `isMultipleOf`

, which, as we have already seen, transforms an `int`

into an `int -> bool`

.

We can view this function `isMultipleOf`

as a sort of *function creator*.

## Definition of `isMultipleOf`

So now let's define this mystical function-creating function.

```
let isMultipleOf n x =
(x % n) = 0
```

Easy, huh?

If you type this into F# Interactive, it will answer:

```
isMultipleOf : int -> int -> bool
```

### Where are the parenthesis?

Note that there are no parenthesis. This is not particularly important for you now. Just remember that the arrows are *right associative*. That is, if you have

```
a -> b -> c
```

you should interpret it as

```
a -> (b -> c)
```

The *right* in *right associative* means that you should interpret as if there were parenthesis around the rightmost operator. So:

```
a -> b -> c -> d
```

should be interpreted as

```
a -> (b -> (c -> d))
```

## Usages of `isMultipleOf`

So, as you have seen, we can use `isMultipleOf`

to create new functions:

```
let isEven = isMultipleOf 2
let isOdd = not << isEven
let isMultipleOfThree = isMultipleOf 3
let endsWithZero = isMultipleOf 10
```

F# Interactive would respond:

```
isEven : int -> bool
isOdd : int -> bool
isMultipleOfThree : int -> bool
endsWithZero : int -> bool
```

But you can use it differently. If you don't want to (or need to) create a new function, you can use it as follows:

```
isMultipleOf 10 150
```

This would return `true`

, as 150 is multiple of 10. This is exactly the same as create the function `endsWithZero`

and then applying it to the value 150.

Actually, **function application is left associative**, which means that the line above should be interpreted as:

```
(isMultipleOf 10) 150
```

That is, you put the parenthesis around the leftmost function application.

Now, if you can understand all this, your example (which is the canonical `CreateAdder`

) should be trivial!

Sometime ago someone asked this question which deals with exactly the same concept, but in Javascript. In my answer I give two canonical examples (CreateAdder, CreateMultiplier) inf Javascript, that are somewhat more explicit about returning functions.

I hope this helps.