`<<`

is a function composition operator, defined in core library `Basics`

. All functions from Basics are imported into Elm projects unqualified.

### Elm's type system

Let's recall basics of Elm type system.

Elm is statically typed. This means that in Elm every variable or function has a type, and this type never changes. Examples of types in Elm are:

`Int`

`String`

`Maybe Bool`

`{ name : String, age : Int }`

`Int -> Int`

`Int -> String -> Maybe Char`

.

Static typing means that compiler ensures types of all functions and variables are correct during compilation, so you don't have runtime type errors. In other words, you'll never have a function of type `String -> String`

receiving or returning `Int`

, code that allows this won't even compile.

You can also make your functions polymorphic by replacing a concrete type such as `String`

or `Maybe Int`

with a type variable, which is an arbitrary lowercase string, such as `a`

. Many Elm core functions are type polymorphic, for example `List.isEmpty`

has the type `List a -> Bool`

. It takes a `List`

of some type and returns a value of type `Bool`

.

If you see the same type variable again, then instances of this type variable must be of same type. For example `List.reverse`

has type `List a -> List a`

. So if you apply `List.reverse`

to a list of integers (i.e. to something that has type `List Int`

), it *will* return a list of integers back. No way such function can take a list of integers, but return a list of strings. This is guaranteed by the compiler.

All functions in Elm are curried by default. This means that if you have a function of 2 arguments, it is transformed into a function of 1 argument that returns a function of 1 argument. That's why you function application syntax of Elm is so different from function application in other languages such as Java, C++, C#, Python, etc. There's no reason to write `someFunction(arg1, arg2)`

, when you can write `someFunction arg1 arg2`

. Why? Because in reality `someFunction arg1 arg2`

is actually `((someFunction arg1) arg2)`

.

Currying makes partial application possible. Suppose you want to partially apply `List.member`

. `List.member`

has a type `a -> List a -> Bool`

. We can read the type as “`List.member`

takes 2 arguments, of type `a`

and type `List a`

”. But we can also read the type as “`List.member`

takes 1 argument of type `a`

. It returns a function of type `List a -> Bool`

”. Therefore we can create a function `isOneMemberOf = List.member 1`

, which will have the type `List Int -> Bool`

.

This means that `->`

in type annotations of functions is right-associative. In other words, `a -> List a -> Bool`

is the same as `a -> (List a -> Bool)`

.

### Infix and prefix notation

Any infix operator is actually an ordinary function behind the curtains. It's just when a function name consists solely of non-alphanumeric symbols (such as $, <|, <<, etc), it is placed between 2 arguments, not in front of them (like ordinary functions).

But you still can put a binary operator like `+`

in front of the 2 arguments, by enclosing it in parentheses, so the 2 function applications below are equivalent:

```
2 + 3 -- returns 5
(+) 2 3 -- returns 5, just like the previous one
```

*Infix operators are just ordinary functions.* There's nothing special about them. You can partially apply them just like any other function:

```
addTwo : Int -> Int
addTwo = (+) 2
addTwo 3 -- returns 5
```

### Function composition

`(<<)`

is a function composition operator, defined in core library `Basics`

. All functions from basics are imported into Elm projects unqualified, meaning you don't have to write `import Basics exposing (..)`

, it is already done by default.

So just like any other operator, `(<<)`

is just a function, like any other. What is its type?

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

Because `->`

is right-associative, this is equivalent to:

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

In other words, `(<<)`

takes 2 functions of types `b -> c`

and `a -> b`

respectively, and returns a function of type `a -> c`

. It composes 2 functions into one. How does that work? Let's look at a contrived example for simplicity's sake. Suppose we have 2 simple functions:

```
addOne = (+) 1
multTwo = (*) 2
```

Suppose we don't have `(+)`

, only `addOne`

, how would we create a function that adds 3, not 1? Very simple, we would compose `addOne`

together 3 times:

```
addThree : Int -> Int
addThree = addOne << addOne << addOne
```

What if we want to create a function that adds 2, then multiples by 4?

```
ourFunction : Int -> Int
ourFunction = multTwo << multTwo << addOne << addOne
```

`(<<)`

composes functions from right-to-left. But the above example is simple, because all the types are the same. How would we find a sum of all even cubes of the list?

```
isEven : Int -> Bool
isEven n = n % 2 == 0
cube : Int -> Int
cube n = n * n * n
ourFunction2 : List Int -> Int
ourFunction2 = List.sum << filter isEven << map cube
```

`(>>)`

is the same function, but with arguments flipped, so we can write the same composition from left to right instead:

```
ourFunction2 = map cube >> filter isEven >> List.sum
```

### Recap

When you see something like `h << g << f`

, then you know that `f`

, `g`

, `h`

are functions. When this construct `h << g << f`

is applied to a value `x`

, then you know:

- Elm first applies
`f`

to `x`

- then applies
`g`

to the result of the previous step
- then applies
`h`

to the result of the previous step

Therefore `(negate << (*) 10 << sqrt) 25`

equals `-50.0`

, because you first take a square root of 25 and get 5, then you multiply 5 by 10 and get 50, then you negate 50 and get -50.

### Why << and not .

Before Elm 0.13 (see announcement) function composition operator was `(.)`

, and its behavior was identical to current `(<<)`

. `(<<)`

was adopted in Elm 0.13 from F# language (see Github issue). Elm 0.13 also added `(>>)`

as equivalent to `flip (<<)`

, and `(<|)`

as replacement for function application operator `($)`

, and `(|>)`

as equivalent to `flip (<|)`

.

### Infix function call

You might be wondering if you can turn an ordinary alphanumeric function name into an infix binary operator. Before Elm 0.18 you'd use backticks to make a function infix, so below 2 would be equivalent:

```
max 1 2 -- returns 2
1 `max` 2 -- returns 2
```

Elm 0.18 removed this feature. You can't do it in Elm anymore, but languages like Haskell and PureScript still have it.

`<<`

is the analog of`.`

in Haskell