We are nearing the end of one of the main sections of this function series, but we have yet to look at one of the main elements you will see when using F#, which is signatures of functions.

In order to understand function signatures we will be revisiting our own old friend the “FSI Window”. We will start with some simple examples and then build up to more complex cases. So without further ado let’s begin.

**The Basics**

**Unit : **Unit is essentially void, and is expressed using the notation “**()**”

**->** : Is the separator between the parameter, and the last arrow will point to the return value

**Tuples :** Are expressed using the familiar notation **(x * y) **

**Functions : **Are wrapped in “**(..)**” parentheses

**Understanding Functions That Taken No Parameters**

We will start with functions that take no parameters at all, and return values.

**Returning A Int**

let aSimpleIntegerFunction() = 12

Gives us this type definition

- aSimpleIntegerFunction : unit –> int

What that means is that the function takes unit (void) and returns an int

**Returning A String**

let aSimpleStringFunction() = "cat"

Gives us this type definition

- aSimpleStringFunction : unit -> string

What that means is that the function takes unit (void) and returns an string

**Returning A Bool**

let aSimpleBoolFunction() = true

Gives us this type definition

- aSimpleBoolFunction : unit -> bool

What that means is that the function takes unit (void) and returns an bool

**Returning A Tuple**

let aSimpleTupleFunction() = (1,"one")

Gives us this type definition

- aSimpleTupleFunction : unit -> int * string

What that means is that the function takes unit (void) and returns an tuple of int and string

**Returning A Record**

type SimplePerson = { Name : string; } ..... let aSimpleRecordFunction() = { Name = "Alf" }

Gives us this type definition

- aSimpleRecordFunction : unit -> SimplePerson

What that means is that the function takes unit (void) and returns a SimplePerson record type

**Returning A List**

let aSimpleListFunction() = [1,2,3]

Gives us this type definition

- aSimpleListFunction : unit -> (int * int * int) list

What that means is that the function takes unit (void) and returns a list with 3 int elements in it. If we increased the size of the list returned by the function the signature would change accordingly

**Returning A Sequence**

let aSimpleSequenceFunction() = seq { 1..3}

Gives us this type definition

- aSimpleSequenceFunction : unit -> seq<int>

What that means is that the function takes unit (void) and returns a sequence of int values

**Returning A Function (Higher Order Functions)**

In F# it is perfectly legal to return functions too. Any function that takes or returns another function is known as a **Higher Order Function**. Here is an example.

let doubleFunction x = x * 2 let aSimpleHigherOrderFunction = doubleFunction

Which gives us this type definition

- aSimpleHigherOrderFunction : (int -> int)

Since our “**aSimpleHigherOrderFunction**” simply returns the original function “**doublerFunction**” it is that original function “**doubleFunction**” that is the one that is returned, and as such it is that functions signature that we see in the FSI window. So we get a function that takes an int and returns an int. As stated earlier functions are shown as “**(**“ and “**)**”, though watch out for tuple which also use braces, but they also use “*****” so they should be easy to spot. They will take the form “**(a *b)**”

While we are on the subject of** Higher Order Functions**, we should probably mention the more common use cases examples, which would likely involve one of the many functions available within the List/Sequence modules. For example** List.Map**, which has the type signature :

- List.map : (‘T -> ‘U) -> ‘T list -> ‘U list

Which takes the following input parameters

A function that takes a generic parameter ‘T, and returns a new generic value ‘U

- Takes a list of generic values ‘T
- Which returns a new list of generic values ‘U

So lets see an example of this in action.

Here is a small example that will negate a list of numbers, where we declare a “**negate**” function that takes a value and returns a new value. So this will work with **List.Map**, as its type signature fits with what **List.Map** requires.

let negate x = -x let newList = List.map negate [1;2;3;4]

We could of course make this a bit more succinct by using a lambda function, which would give us this:

let newList = List.map (fun x -> -x) [1;2;3;4]

**Understanding Functions That Taken Parameters**

Ok so we have now seen what return values look like, so lets start adding in some input parameters into the mix.

**Generic Function**

So let’s start with a generic function, where we let the F# type inference system decide what the type will be.

Here is the function we will be using:

let aSimpleGenericFunction x = ()

Which when inspected in the FSI Window gives us this type definition

- aSimpleGenericFunction : x:’a –> unit

Which as you can see has a strange “ **’a** “ type for the parameter named X. What is this, well in F# that is how generics are represented. So this function is completely generic as far as the input parameter goes, and simply returned unit “**()**”

So since it is completely generic these are all valid calls to the function:

aSimpleGenericFunction 12 aSimpleGenericFunction "cat" aSimpleGenericFunction true

**Taking A Single Parameter**

So what about when we don’t want to use generics and want to specify the type we want, how do we do that. Well we can do that as follows:

let aSimpleIntOnlyFunction (x : int) = ()

Which when inspected in the FSI Window gives us this type definition

- aSimpleIntOnlyFunction : x:int -> unit

Which as you can is a function that takes a single int value, and simply returned unit “**()**”

So since we have now locked down the type accepted as an input parameter to this function, we can’t pass in anything other than a single int value.

**Taking Several Parameters**

So how about we now look at taking a few parameters, for the sake of simplicity I will fix the types allowed. So here is an example:

let aMultipleParamsFunction (x : int) (y: string) = ()

Which when inspected in the FSI Window gives us this type definition

- aMultipleParamsFunction : x:int -> y:string -> unit

Which as you can is a function that takes a int and a string value, and simply returned unit “**()**”

**Taking A Mix Bag Of Parameters**

Ok so we now have the basics covered, lets mix it up a bit by looking at what you we get if we create a pretty full on function that takes a variety of the types we have looked as so far:

let theUberFunction (a : int option) (b : int list) (c : string) (d) = ()

Which when inspected in the FSI Window gives us this type definition

- theUberFunction : a:int option -> b:int list -> c:string -> d:’a -> unit

Which as you can is a function that takes

- A int option
- A int list
- A string
- A generic type

And returns unit “**()**”

Just for completeness here is what an example of calling this function looks like

theUberFunction (Some 12) [1;2;3] "dog" { Name = "Alf" }

**Taking Parameters And Having A Non Unit Return Value**

So lets finish this section with a truly weird function, which looks like this:

let someCrazedFunction (a:int) (b:string) (c:SimplePerson) (d: Collections.List<int>) (e) = (a,b,c,d,e)

Ok, I have gone a bit over the top with this one, but the point is it is still totally valid, and you may see things like this in the wild, although I do not think this is a great idea at all, we would likely tuple the parameters instead. Let’s continue though and see what the signature for this one looks like. The first 4 parameters should be pretty obvious, and the last one is a generic one, but what would the return value of this be? Lets find out.

- someCrazedFunction :

a:int ->b:string ->

c:SimplePerson ->

d:List<int> -> e:’a -> int * string * SimplePerson * List<int> * ‘a

This looks a little nuts, but lets just break it down. From left to right (which is the correct way to read F# signatures)

This function is one that takes the following input parameters:

- An Int
- A String
- A SimplePerson record
- A list of Ints
- A generic value

And it returns a tuple of **int * string * SimplePerson * List<int> * ‘a**

I deliberately made this one a bit strange, so that we could see a somewhat weird signature

**One To Watch Out For**

You may on occasion see a function that includes a “**inline**” keyword.This F# keyword is used to integrate the function directly into the calling code. Here are some examples of where you might see **inline** used:

type WrapInt32() = member inline this.IncrementByOne(x) = x + 1 static member inline Increment(x) = x + 1 ... ... let inline Increment x = x + 1

The thing is, using the **inline** keyword, **DOES** effect the signature of a function, so that is why I am bringing this up in this blog post.

For example lets say I had this function

let PrintAsFloatingPoint number = printfn"%f" (float number)

I think this would pretty easy to guess the signature of, it takes an ‘a generic, and the last line of the function is a **printfn** one, which returns Unit, that was my guess The actual signature is

- PrintAsFloatingPoint : number:int –> unit

This is due to the F# tylpe inference system deducing a input type, in this case int.

But let’s see what happens when we use the **inline** keyword. So sticking with the same example:

let inline InlinePrintAsFloatingPoint number = printfn"%f" (float number)

Which when examined in the FSI Window has the following signature, which is very very different:

- inline InlinePrintAsFloatingPoint : number: ^a -> unit when ^a : (static member op_Explicit : ^a -> float)

Using the inline keyword forces the F# type inference system to infer that the function can take a statically resolved typed parameter. This means that the function accepts any type that has a conversion to float. That is why we see the use of the “**op_Explicit**” and “**^a –> float**” (the **^a** specifies types that must be resolved at compile time not at runtime) which makes sure it is convertible to float.

Interestingly enough if we actually lock down the type for the number parameter for both these demo functions to an int, so we have these new functions:

let PrintAsFloatingPoint (number :int) = printfn"%f" (float number) let inline InlinePrintAsFloatingPoint (number :int) = printfn"%f" (float number)

And now look at the type signatures, we can see that they are identical.

- PrintAsFloatingPoint : number:int –> unit
- inline InlinePrintAsFloatingPoint : number:int -> unit

So beware **inline** may catch you out