Overloaded Records based on current GHC proposal.
Implementation of Overloaded Record Fields based on current GHC proposal. It is built on top of functionality that is included in GHC 8.0.1, but it works on older GHC versions as well. Most importantly, this library provides Template Haskell functions for automatic deriving of instancess for HasField
and ModifyField
type classes. With these instances overloaded fields can be used directly as getters and lenses.
See README for usage examples.
More about the current status of OverloadedRecordFields language extension can be found on: GHC Wiki: OverloadedRecordFields.
Overloaded Records
Description
Implementation of Overloaded Record Fields based on current GHC proposal. It is built on top of functionality that is included in GHC 8.0.1, but it works on older GHC versions as well. Most importantly, this library provides Template Haskell functions for automatic deriving of instancess for HasField
and ModifyField
type classes. With these instances overloaded fields can be used directly as getters and lenses.
import Data.Default (Default(def))
import Data.OverloadedRecords.TH (overloadedRecord)
newtype Bar a = Bar {_bar :: a}
overloadedRecord def ''Bar
On GHC 8.0.1 it is possible to just write:
{-# LANGUAGE OverloadedLabels #-}
import Control.Lens ((+~))
add :: Int -> Bar Int -> Bar Int
add n = #bar +~ n
For older GHC versions there is a family of Template Haskell functions that will derive overloaded labels in form of standard haskell definitions:
import Control.Lens ((+~))
import Data.OverloadedLabels.TH (label)
label "bar"
add :: Int -> Bar Int -> Bar Int
add n = bar +~ n
More about the current status of OverloadedRecordFields language extension can be found on GHC Wiki: OverloadedRecordFields.
Usage Example
Following is a more complex usage example that demonstrates some of the possibilities of Overloaded Labels provided by this library.
-- Basic set of language extensions required when defining instances for
-- classes and type families from "Data.OverloadedRecords".
{-# LANGUAGE DataKinds #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE MultiParamTypeClasses #-}
{-# LANGUAGE TemplateHaskell #-}
{-# LANGUAGE TypeFamilies #-}
-- Following language extensions are required by code like this:
{-# LANGUAGE ConstraintKinds #-}
-- Codomain of type family 'R' is a 'Constraint' kind.
{-# LANGUAGE FlexibleContexts #-}
-- Required in example when field type (second argument of ':::') is a
-- specific type instead of a polymorphic type.
{-# LANGUAGE TypeOperators #-}
-- Required due to usage of ':::' type alias.
-- Following language extensions are available only in GHC >=8:
{-# LANGUAGE OverloadedLabels #-}
-- Enables #label syntactic sugar.
module Example
where
import Data.Default (Default(def))
-- Provided by one of these packages:
--
-- * data-default
-- * data-default-extra
import Data.OverloadedRecords
import Data.OverloadedRecords.TH (overloadedRecord)
data V3 a = V3
{ v3x :: !a
, v3y :: !a
, v3z :: !a
}
deriving Show
-- Following line derives instances for various type classes and type
-- families that are provided by the overloaded-records library.
--
-- However with def (default settings) this is done only for fields that
-- start with type name, data constructor name, or underscore. Prefix is
-- stripped. In example "v3x" is transformed in to "x" and so would be
-- "_x".
overloadedRecord def ''V3
data V4 a = V4
{ v4x :: !a
, v4y :: !a
, v4z :: !a
, v4t :: !a
}
deriving Show
overloadedRecord def ''V4
zeroV3
:: (Num a, R '["x" ::: a, "y" ::: a, "z" ::: a] r)
=> r -> r
zeroV3 = set' #x 0 . set' #y 0 . set' #z 0
The following type signatures for zeroV3
are equivalent:
zeroV3
:: (Num a, R '["x" ::: a, "y" ::: a, "z" ::: a] r)
=> r -> r
zeroV3
:: ( Num a
, ModifyField' "x" r a
, ModifyField' "y" r a
, ModifyField' "z" r a
)
=> r -> r
One of the biggest features of Overloaded Records is the possibility to define functions that do not depend on concrete data types, but on the "fields" they provide. In example function zeroV3
can be applied to anything that has fields "x"
, "y"
, and "z"
that reference values of some Num
type:
λ> zeroV3 (V3 1 1 1 :: V3 Int)
V3 {_x = 0, _y = 0, _z = 0}
λ> zeroV3 (V4 1 1 1 1 :: V4 Int)
V4 {_x = 0, _y = 0, _z = 0, _t = 1}
Function zeroV3
can be also defined using operators from lens library:
import Control.Lens ((.~), simple)
zeroV3
:: (Num a, R '["x" ::: a, "y" ::: a, "z" ::: a] r)
=> r -> r
zeroV3 r = r
& #x . simple .~ 0
& #y . simple .~ 0
& #z . simple .~ 0
License
The BSD 3-Clause License, see LICENSE file for details. This implementation is based on original prototype, which is under MIT License.
Contributions
Contributions, pull requests and bug reports are welcome! Please don't be afraid to contact author using GitHub or by e-mail.