{-# LANGUAGE ScopedTypeVariables #-}

-----------------------------------------------------------------------------
-- |
-- Module      :  Data.Singletons.Deriving.Infer
-- Copyright   :  (C) 2015 Richard Eisenberg
-- License     :  BSD-style (see LICENSE)
-- Maintainer  :  Ryan Scott
-- Stability   :  experimental
-- Portability :  non-portable
--
-- Infers constraints for a `deriving` class
--
----------------------------------------------------------------------------

module Data.Singletons.Deriving.Infer ( inferConstraints, inferConstraintsDef ) where

import Language.Haskell.TH.Desugar
import Language.Haskell.TH.Syntax
import Data.Singletons.Deriving.Util
import Data.Singletons.Util
import Data.List (nub)
import Data.Maybe (fromJust)

-- @inferConstraints cls inst_ty cons@ infers the instance context for a
-- derived type class instance of @cls@ for @inst_ty@, using the constructors
-- @cons@. For instance, if @cls@ is 'Ord' and @inst_ty@ is @Either a b@, then
-- that means we are attempting to derive the instance:
--
-- @
-- instance ??? => Ord (Either a b)
-- @
--
-- The role of 'inferConstraints' is to determine what @???@ should be in that
-- derived instance. To accomplish this, the list of @cons@ (in this example,
-- @cons@ would be @[Left a, Right b]@) is used as follows:
--
-- 1. For each @con@ in @cons@, find the types of each of its fields
--    (call these @field_tys@), perhaps after renaming the type variables of
--    @field_tys@.
-- 2. For each @field_ty@ in @field_tys@, apply @cls@ to @field_ty@ to obtain
--    a constraint.
-- 3. The final instance context is the set of all such constraints obtained
--    in step 2.
--
-- To complete the running example, this algorithm would produce the instance
-- context @(Ord a, Ord b)@, since @Left a@ has one field of type @a@, and
-- @Right b@ has one field of type @b@.
--
-- This algorithm is a crude approximation of what GHC actually does when
-- deriving instances. It is crude in the sense that one can end up with
-- redundant constraints. For instance, if the data type for which an 'Ord'
-- instance is being derived is @data Foo = MkFoo Bool Foo@, then the
-- inferred constraints would be @(Ord Bool, Ord Foo)@. Technically, neither
-- constraint is necessary, but it is not simple in general to eliminate
-- redundant constraints like these, so we do not attept to do so. (This is
-- one reason why @singletons@ requires the use of the @UndecidableInstances@
-- GHC extension.)
--
-- Observant readers will notice that the phrase \"perhaps afer renaming the
-- type variables\" was casually dropped in step 1 of the above algorithm.
-- For more information on what this means, refer to the documentation for
-- infer_ct below.
inferConstraints :: forall q. DsMonad q => DPred -> DType -> [DCon] -> q DCxt
inferConstraints :: DPred -> DPred -> [DCon] -> q DCxt
inferConstraints DPred
pr DPred
inst_ty = (DCxt -> DCxt) -> q DCxt -> q DCxt
forall (f :: * -> *) a b. Functor f => (a -> b) -> f a -> f b
fmap DCxt -> DCxt
forall a. Eq a => [a] -> [a]
nub (q DCxt -> q DCxt) -> ([DCon] -> q DCxt) -> [DCon] -> q DCxt
forall b c a. (b -> c) -> (a -> b) -> a -> c
. (DCon -> q DCxt) -> [DCon] -> q DCxt
forall (monad :: * -> *) monoid (t :: * -> *) a.
(Monad monad, Monoid monoid, Traversable t) =>
(a -> monad monoid) -> t a -> monad monoid
concatMapM DCon -> q DCxt
infer_ct
  where
    -- A thorny situation arises when attempting to infer an instance context
    -- for a GADT. Consider the following example:
    --
    --   newtype Bar a where
    --     MkBar :: b -> Bar b
    --   deriving Show
    --
    -- If we blindly apply 'Show' to the field type of @MkBar@, we will end up
    -- with a derived instance of:
    --
    --   instance Show b => Show (Bar a)
    --
    -- This is completely wrong, since the type variable @b@ is never used in
    -- the instance head! This reveals that we need a slightly more nuanced
    -- strategy for gathering constraints for GADT constructors. To account
    -- for this, when gathering @field_tys@ (from step 1 in the above algorithm)
    -- we perform the following extra steps:
    --
    -- 1(a). Take the return type of @con@ and match it with @inst_ty@ (e.g.,
    --       match @Bar b@ with @Bar a@). Doing so will produce a substitution
    --       that maps the universally quantified type variables in the GADT
    --       (i.e., @b@) to the corresponding type variables in the data type
    --       constructor (i.e., @a@).
    -- 1(b). Use the resulting substitution to rename the universally
    --       quantified type variables of @con@ as necessary.
    --
    -- After this renaming, the algorithm will produce an instance context of
    -- @Show a@ (since @b@ was renamed to @a@), as expected.
    infer_ct :: DCon -> q DCxt
    infer_ct :: DCon -> q DCxt
infer_ct (DCon [DTyVarBndr]
_ DCxt
_ Name
_ DConFields
fields DPred
res_ty) = do
      let field_tys :: DCxt
field_tys = DConFields -> DCxt
tysOfConFields DConFields
fields
          -- We need to match the constructor's result type with the type given
          -- in the generated instance. But if we have:
          --
          --   data Foo a where
          --     MkFoo :: a -> Foo a
          --     deriving Functor
          --
          -- Then the generated instance will be:
          --
          --   instance Functor Foo where ...
          --
          -- Which means that if we're not careful, we might try to match the
          -- types (Foo a) and (Foo), which will fail.
          --
          -- To avoid this, we employ a grimy hack where we pad the instance
          -- type with an extra (dummy) type variable. It doesn't matter what
          -- we name it, since none of the inferred constraints will mention
          -- it anyway.
          eta_expanded_inst_ty :: DPred
eta_expanded_inst_ty
            | Bool
is_functor_like = DPred
inst_ty DPred -> DPred -> DPred
`DAppT` Name -> DPred
DVarT (String -> Name
mkName String
"dummy")
            | Bool
otherwise       = DPred
inst_ty
      DPred
res_ty'  <- DPred -> q DPred
forall (q :: * -> *). DsMonad q => DPred -> q DPred
expandType DPred
res_ty
      DPred
inst_ty' <- DPred -> q DPred
forall (q :: * -> *). DsMonad q => DPred -> q DPred
expandType DPred
eta_expanded_inst_ty
      DCxt
field_tys' <- case IgnoreKinds -> DPred -> DPred -> Maybe DSubst
matchTy IgnoreKinds
YesIgnore DPred
res_ty' DPred
inst_ty' of
                      Maybe DSubst
Nothing -> String -> q DCxt
forall (m :: * -> *) a. MonadFail m => String -> m a
fail (String -> q DCxt) -> String -> q DCxt
forall a b. (a -> b) -> a -> b
$ String -> ShowS
showString String
"Unable to match type "
                                      ShowS -> ShowS -> ShowS
forall b c a. (b -> c) -> (a -> b) -> a -> c
. Int -> DPred -> ShowS
forall a. Show a => Int -> a -> ShowS
showsPrec Int
11 DPred
res_ty'
                                      ShowS -> ShowS -> ShowS
forall b c a. (b -> c) -> (a -> b) -> a -> c
. String -> ShowS
showString String
" with "
                                      ShowS -> ShowS -> ShowS
forall b c a. (b -> c) -> (a -> b) -> a -> c
. Int -> DPred -> ShowS
forall a. Show a => Int -> a -> ShowS
showsPrec Int
11 DPred
inst_ty'
                                      ShowS -> ShowS
forall a b. (a -> b) -> a -> b
$ String
""
                      Just DSubst
subst -> (DPred -> q DPred) -> DCxt -> q DCxt
forall (t :: * -> *) (f :: * -> *) a b.
(Traversable t, Applicative f) =>
(a -> f b) -> t a -> f (t b)
traverse (DSubst -> DPred -> q DPred
forall (q :: * -> *). Quasi q => DSubst -> DPred -> q DPred
substTy DSubst
subst) DCxt
field_tys
      if Bool
is_functor_like
         then DCxt -> DPred -> q DCxt
mk_functor_like_constraints DCxt
field_tys' DPred
res_ty'
         else DCxt -> q DCxt
forall (f :: * -> *) a. Applicative f => a -> f a
pure (DCxt -> q DCxt) -> DCxt -> q DCxt
forall a b. (a -> b) -> a -> b
$ (DPred -> DPred) -> DCxt -> DCxt
forall a b. (a -> b) -> [a] -> [b]
map (DPred
pr DPred -> DPred -> DPred
`DAppT`) DCxt
field_tys'

    -- If we derive a Functor-like class, e.g.,
    --
    --   data Foo f g h a = MkFoo (f a) (g (h a)) deriving Functor
    --
    -- Then we infer constraints by sticking Functor on the subtypes of kind
    -- (Type -> Type). In the example above, that would give us
    -- (Functor f, Functor g, Functor h).
    mk_functor_like_constraints :: [DType] -> DType -> q DCxt
    mk_functor_like_constraints :: DCxt -> DPred -> q DCxt
mk_functor_like_constraints DCxt
fields DPred
res_ty = do
      -- This function is partial. But that's OK, because
      -- functorLikeValidityChecks ensures that this is total by the time
      -- we invoke this.
      let (DPred
_, [DTypeArg]
res_ty_args)     = DPred -> (DPred, [DTypeArg])
unfoldDType DPred
res_ty
          (DCxt
_, DPred
last_res_ty_arg) = DCxt -> (DCxt, DPred)
forall a. [a] -> ([a], a)
snocView (DCxt -> (DCxt, DPred)) -> DCxt -> (DCxt, DPred)
forall a b. (a -> b) -> a -> b
$ [DTypeArg] -> DCxt
filterDTANormals [DTypeArg]
res_ty_args
          last_tv :: Name
last_tv              = Maybe Name -> Name
forall a. HasCallStack => Maybe a -> a
fromJust (Maybe Name -> Name) -> Maybe Name -> Name
forall a b. (a -> b) -> a -> b
$ DPred -> Maybe Name
getDVarTName_maybe DPred
last_res_ty_arg
      DCxt
deep_subtypes <- (DPred -> q DCxt) -> DCxt -> q DCxt
forall (monad :: * -> *) monoid (t :: * -> *) a.
(Monad monad, Monoid monoid, Traversable t) =>
(a -> monad monoid) -> t a -> monad monoid
concatMapM (Name -> DPred -> q DCxt
forall (q :: * -> *). DsMonad q => Name -> DPred -> q DCxt
deepSubtypesContaining Name
last_tv) DCxt
fields
      DCxt -> q DCxt
forall (f :: * -> *) a. Applicative f => a -> f a
pure (DCxt -> q DCxt) -> DCxt -> q DCxt
forall a b. (a -> b) -> a -> b
$ (DPred -> DPred) -> DCxt -> DCxt
forall a b. (a -> b) -> [a] -> [b]
map (DPred
pr DPred -> DPred -> DPred
`DAppT`) DCxt
deep_subtypes

    is_functor_like :: Bool
    is_functor_like :: Bool
is_functor_like
      | (DConT Name
pr_class_name, [DTypeArg]
_) <- DPred -> (DPred, [DTypeArg])
unfoldDType DPred
pr
      = Name -> Bool
isFunctorLikeClassName Name
pr_class_name
      | Bool
otherwise
      = Bool
False

-- For @inferConstraintsDef mb_cxt@, if @mb_cxt@ is 'Just' a context, then it will
-- simply return that context. Otherwise, if @mb_cxt@ is 'Nothing', then
-- 'inferConstraintsDef' will infer an instance context (using 'inferConstraints').
inferConstraintsDef :: DsMonad q => Maybe DCxt -> DPred -> DType -> [DCon] -> q DCxt
inferConstraintsDef :: Maybe DCxt -> DPred -> DPred -> [DCon] -> q DCxt
inferConstraintsDef Maybe DCxt
mb_ctxt DPred
pr DPred
inst_ty [DCon]
cons =
  q DCxt -> (DCxt -> q DCxt) -> Maybe DCxt -> q DCxt
forall b a. b -> (a -> b) -> Maybe a -> b
maybe (DPred -> DPred -> [DCon] -> q DCxt
forall (q :: * -> *).
DsMonad q =>
DPred -> DPred -> [DCon] -> q DCxt
inferConstraints DPred
pr DPred
inst_ty [DCon]
cons) DCxt -> q DCxt
forall (f :: * -> *) a. Applicative f => a -> f a
pure Maybe DCxt
mb_ctxt