ADTs (Algebraic Data Types) in Haskell

May 30, 2018

Algebraic Data Types are a way for us to define types like the ones that come with Haskell e.g. Bool and Int .

Single Constructor Without Arguments

The most simple data type we can construct in Haskell is a type with a single constructor,

data Frame = MkFrame x = MkFrame

Examining the type in ghci

:> :type MkFrame MkFrame :: Frame :> :type x x :: Frame

In this example, we use the data keyword to signify a Data Type, Frame is the name of that type and we refer to it as a Type Constructor. MkFrame is called a Data Constructor and this is how we create new instances of the type Frame .

Enums

Enums (Enumeration Types), also referred to as Sum Types allow us to design a type that is reminiscent of a Logical OR. Suppose we want to have a type that will represent a day in the week, the day will be either Saturday, or Monday, or Tuesday, …etc.

data Day = Saturday | Sunday | Monday | Tuesday | Wednesday | Thursday | Friday day = Tuesday

Examining the type in ghci

:> :type Saturday Saturday :: Day :> :type day day :: Day

Pattern Matching

We can pattern match on our data type like so:

dayNumber :: Day -> Int dayNumber Saturday = 1 dayNumber Sunday = 2 dayNumber Monday = 3 dayNumber Tuesday = 4 dayNumber Wednesday = 5 dayNumber Thursday = 6 dayNumber Friday = 7

or using a case of statement:

dayNumberCase :: Day -> Int dayNumberCase x = case x of Saturday -> 0 Sunday -> 2 Monday -> 3 Tuesday -> 4 Wednesday -> 5 Thursday -> 6 Friday -> 7

Constructors with arguments

We can also declare types whose constructor takes one or more arguments, these are commonly referred to as Product Types. Let's say we want to represent a point in the cartesian coordinate system i.e. a point with x and y coordinates,

data Point = P Int Int mypoint = P 1 2

Examining in ghci

:> :type P P :: Int -> Int -> Point :> :type mypoint mypoint :: Point :> :type P 1 2 P 1 2 :: Point

It's a convention in Haskell code to sometimes label the data constructor with the same label as the type constructor, to illustrate this with our Point example:

data Point = Point Int Int mypoint = Point 1 2

Record Syntax

Let's say we want to define a User type that has the name and age of a user, we can try to do something like this

data User = User String Int

where name is of type String and age is of type Int . However, in our application, we will want to get the name and age from an instance of this data type, we can do this like so:

getName :: User -> String getName ( User name _ ) = name getAge :: User -> Int getAge ( User _ age) = age

but, as you can imagine, this would get too daunting and verbose if our data constructor takes a large number of arguments, and we'll have to modify all these accessor functions if we add or remove arguments from the data constructor. Also, we have to keep in mind the position of each argument. Enter records, records allow us to write:

data User = User { name :: String , age :: Int } -- Create a User user1 = User { name = " Oliver Heaviside " , age = 74 } -- This still works user2 = User " James Clerk Maxwell " 48

and get accessor functions for free, these will be automatically generated:

name :: User -> String age :: User -> Int

We also get a nice field update syntax

changeAge user newAge = user { age = newAge} user1 = User { name = " Oliver Heaviside " , age = 74 } newuser = changeAge user1 42

Record Downsides

Unfortunately records have some issues, refer to this for more details.

Parametrized Types

Type constructors can be parametrized with types, the standard Prelude library defines the Maybe type:

data Maybe a = Nothing | Just a

Here, Maybe is parametrized with the generic type a which can take on any type, this is a bit like Generics in other languages. The Maybe type allows us to express the nonexistence of a value, for example when trying to take the head of a list, instead of erroneously applying head to an empty list, we can defend against this:

lhead :: [a] -> Maybe a lhead [] = Nothing lhead xs = Just (head xs)

And, playing around in ghci

:> :type lhead [] lhead [] :: Maybe a :> :type lhead ['a'] lhead ['a'] :: Maybe Char :> :type lhead [1] lhead [1] :: Num a => Maybe a

Recursive Types

Haskell allows us to define types in terms of themselves i.e. recursive types. Let's illustrate this by making a type for a Binary Tree:

data BinTree a = EmptyTree | Node a ( BinTree a) ( BinTree a) mytree = Node 1 EmptyTree EmptyTree

Here, we constructed mytree to be a tree with a single node, with an empty left and right subtrees. We can also construct a tree with 3 nodes: