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Purescript-Typeable
Reified types for Purescript
This is an implementation of indexed typereps for Purescript, similar to the corresponding implementation in Haskell.
Slides for a talk about Purescript-Typeable, presented at the Purescript semi-monthly meetup on 18 January 2021, are available.
Data.Typeable
TypeReps
are values that represent types (i.e. they reify types). When they are indexed they have the type itself as a parameter.
data TypeRep a -- A *value* that represents the type 'a'
All typeable things have typereps -
class Typeable a where
typeRep :: TypeRep a
Instances are provided for common data types.
We can recover the unindexed representation by making it existential -
data SomeTypeRep
We can also test any two typereps for equality -
eqTypeRep :: forall a b. TypeRep a -> TypeRep b -> Boolean
We can compare two typeReps and extract a witness for type equality.
eqT :: forall a b. TypeRep a -> TypeRep b -> Maybe (a ~ b)
Deriving Typeable
for custom data types
It's extremely easy. You just need to create a mechanical Taggable
class instance for your datatype. The instance will always use the provided makeTag
function. There is no other possible way to create an instance.
For example -
data Person = Person {name::String, age::Int}
instance Tagged Person where tag = makeTag unit
This is valid even for data types that take parameters. For example -
data Optional a = Some a | None
instance Tagged Optional where tag = makeTag unit
Don't worry about getting it wrong since the type system will prevent you from writing an invalid instance.
CAVEAT
Do not add any extra constraints to the instances. For example don't do
Foo => Taggable Person
. This currently cannot be caught by the type checker, but will break typerep comparisons for your data type.
And that's it! You are done! Now your datatype will have a Typeable
instance.
Note that you will have Typeable
instances even for unsaturated types. For example, with the tagTOptional
instance above, you have instances for TypeRep (Optional a)
as well as for TypeRep Optional
.
Data.Dynamic
We can have dynamic values which holds a value a
in a context t
and forgets the type of a
data Dynamic t
We can wrap a value into a dynamic
dynamic :: forall a t. Typeable a => t a -> Dynamic t
We can recover the value from a dynamic if supply the type we expect to find in the Dynamic
unwrapDynamic :: forall a. TypeRep a -> Dynamic t -> Maybe a
Data.Data
This is an implementation of the Data class Purescript, similar to the corresponding implementation of Data in Haskell. Check the documentation there for more information on the API. A brief overview is provided below.
class Typeable a <= Data a where
dataDict :: DataDict a
Where DataDict
is a manually reified dictionary because PureScript has trouble with constraints inside records.
Common instances are provided for Data
. You can define Data
instances for your own datatypes though it is slightly involved due to the dictionary reification.
When you cut through the dictionary reification noise, the definition of Data
looks like the following -
class Typeable a => Data a where
gmapT :: (forall b. Data b => b -> b) -> a -> a
Basically Data
encodes a traversal through the structure of the data.
Let's say you have the following data structure -
data Foo = Foo Bar Baz
You would define a Data
instance for Foo
like the following -
instance Data Foo where
gmapT k (Foo a b) = Foo (k a) (k b)
i.e. You apply the supplied function to the immediate children of the top level structure.
Now because of the dictionary reification in PureScript, you can't directly write the instance that way. You need to do the following instead -
instance Data Foo where
dataDict = DataDict \k z (Foo a b) -> z Foo `k` a `k` b
i.e. You are doing the same traversal, but start with the z
, and intersperse all the immediate children of the data structure with k
.
If your data structure has multiple branches, for example -
data Foo = Bar Baz | Buzz Int
Simply handle the branches separately, for example -
instance Data Foo where
dataDict = DataDict \k z foo -> case foo of
Bar b -> z Bar `k` b
Buzz i -> z Buzz `k` i
Using Data.Data
Once you have a Data
instance for your datatype, you can use gmapT
, and functions that depend on gmapT
, such as everywhere
.
For example, to apply a function f :: forall a. Typeable a => a -> a
to all leaves of your data structure, you can do everywhere f
. Inside f
, you can use the Typeable
instance to decide when to change the data structure. For example, if you want the function to increment all integers, but leave all other data intact, use -
f :: forall a. Typeable a => a -> a
f a =
-- Check if `a` is an int
case (typeRep :: _ a) `eqT` (typeRep :: _ Int) of
-- Return unmodified if `a` is not an int
Nothing -> a
Just witness -> do
-- If `a` is an int, we get access to bidirectional conversion functions
let aToI = coerce witness
let iToA = coerce (symm witness)
-- Increment and return
iToA (aToI a + 1)