Why is it a good idea to put deriving Read, Show underneath and what do they do?
3 Answers
When you define your own data types, often there's a lot of boilerplate code for typeclasses that you don't really want to have to write yourself. The compiler can often figure this out for you.
For example, if you had the type
data Direction = North | South | East | West
You wouldn't be able to do
if direction == North then ...
because you haven't written the instance of Eq
for Direction
. You could write
instance Eq Direction where
North == North = True
South == South = True
East == East = True
West == West = True
_ == _ = False
but that's 6 extra lines of code that really don't help your or someone else understand your code. The same goes with classes like Show
, Ord
, Enum
, Bounded
, Read
, and Functor
, these all take up precious time and energy to write when it's pretty trivial for the compiler to figure it out all by itself. That's where the deriving
clause comes in. All of the type classes I've mentioned are derivable (although Functor
needs the DeriveFunctor
extension in GHC), and there's a handful of others. All it does is instruct the compiler to figure out the implementations for these typeclasses itself, so
data Direction = North | South | East | West
deriving (Eq, Ord, Enum, Bounded, Show, Read)
will generate a lot of code that you could write yourself, but isn't much fun to do so. You can see the code that gets generated by compiling with the -ddump-deriv
flag, if you want, but it won't be very pretty since it's compiler generated.
Instance deriving is a powerful feature in Haskell which has the compiler automatically create reasonable instances of some typeclasses for types you create. Oftentimes there are reasonable default instances for things like Eq
, Ord
, Show
, Read
, Enum
, and Bounded
which the compiler can just guess. For instance, Eq
on a finite sum type.
data Sum = A | B | C deriving ( Eq )
-- is equivalent to
instance Eq Sum where
A == A = True
B == B = True
C == C = True
_ == _ = False
Deriving thus cuts down on a lot of boilerplate when it's appropriate. Altogether deriving is considered to be a core feature of Haskell and it has both been extended by compiler extensions like GeneralizedNewtypeDeriving
, DeriveFunctor
, DeriveFoldable
, DeriveTraversable
, DeriveGeneric
, and DeriveDataTypeable
and embraced by the community using Generics
deriving and TemplateHaskell
automatically generated instances.
For instance, if you use the aeson
Haskell-JSON data binding library you'll often see the Template Haskell
deriveJSON ''MyType
which automatically creates instances for both ToJSON
and FromJSON
.
Taken together, these are all methods to ensure that only the most important and specific parts of your code have to be written. Derived instances tend to be the "simplest possible instances" and thus have the least surprising behavior possible. Small deviations from these defaults can be coded more directly after they form the base layer of functionality.
Read
, Show
, Eq
and friends are typeclasses. Basically they're interfaces that can make certain functions, like show
, read
, ==
and others work for your type. The two that you mentioned, Show
and Read
define two functions on your type.
read :: String -> YourType
show :: YourType -> String
In fact, what it actually does is generate a typeclass instance that lets you use read
and show
as if they had these types.
It's often nice to just let deriving
take care of this since it's just boilerplate, often for debugging. Often you just want to print stuff out and deriving Show
gives you a nice quick way to do that.
In essence, deriving
is just a way to get the compiler to generate code for you. This is especially helpful with Eq
, Ord
, and Bounded
where you could easily make a trivial mistake that would be very very hard to debug.