{-# LANGUAGE DataKinds, TypeFamilies, KindSignatures, TemplateHaskell, CPP #-} ----------------------------------------------------------------------------- -- | -- Module : Data.Singletons.CustomStar -- Copyright : (C) 2013 Richard Eisenberg -- License : BSD-style (see LICENSE) -- Maintainer : Ryan Scott -- Stability : experimental -- Portability : non-portable -- -- This file implements 'singletonStar', which generates a datatype @Rep@ and associated -- singleton from a list of types. The promoted version of @Rep@ is kind @*@ and the -- Haskell types themselves. This is still very experimental, so expect unusual -- results! -- ---------------------------------------------------------------------------- module Data.Singletons.CustomStar ( singletonStar, module Data.Singletons.Prelude.Eq, module Data.Singletons.Prelude.Bool, module Data.Singletons.TH ) where import Language.Haskell.TH import Data.Singletons.Util import Data.Singletons.Deriving.Infer import Data.Singletons.Deriving.Ord import Data.Singletons.Deriving.Show import Data.Singletons.Promote import Data.Singletons.Promote.Monad import Data.Singletons.Single.Monad import Data.Singletons.Single.Data import Data.Singletons.Single import Data.Singletons.Syntax import Data.Singletons.Names import Data.Singletons.TH import Control.Monad import Data.Maybe import Language.Haskell.TH.Desugar import Data.Singletons.Prelude.Eq import Data.Singletons.Prelude.Bool -- | Produce a representation and singleton for the collection of types given. -- -- A datatype @Rep@ is created, with one constructor per type in the declared -- universe. When this type is promoted by the singletons library, the -- constructors become full types in @*@, not just promoted data constructors. -- -- For example, -- -- > $(singletonStar [''Nat, ''Bool, ''Maybe]) -- -- generates the following: -- -- > data Rep = Nat | Bool | Maybe Rep deriving (Eq, Ord, Read, Show) -- -- and its singleton. However, because @Rep@ is promoted to @*@, the singleton -- is perhaps slightly unexpected: -- -- > data instance Sing (a :: *) where -- > SNat :: Sing Nat -- > SBool :: Sing Bool -- > SMaybe :: Sing a -> Sing (Maybe a) -- -- The unexpected part is that @Nat@, @Bool@, and @Maybe@ above are the real @Nat@, -- @Bool@, and @Maybe@, not just promoted data constructors. -- -- Please note that this function is /very/ experimental. Use at your own risk. singletonStar :: DsMonad q => [Name] -- ^ A list of Template Haskell @Name@s for types -> q [Dec] singletonStar names = do kinds <- mapM getKind names ctors <- zipWithM (mkCtor True) names kinds let repDecl = DDataD Data [] repName [] (Just (DConT typeKindName)) ctors [DDerivClause Nothing (map DConPr [''Eq, ''Ord, ''Read, ''Show])] fakeCtors <- zipWithM (mkCtor False) names kinds let dataDecl = DataDecl repName [] fakeCtors -- Why do we need withLocalDeclarations here? It's because we end up -- expanding type synonyms when deriving instances for Rep, which requires -- reifying Rep itself. Since Rep hasn't been spliced in yet, we must put it -- into the local declarations. withLocalDeclarations (decToTH repDecl) $ do -- We opt to infer the constraints for the Eq instance here so that when it's -- promoted, Rep will be promoted to Type. dataDeclEqCxt <- inferConstraints (DConPr ''Eq) (DConT repName) fakeCtors let dataDeclEqInst = DerivedDecl (Just dataDeclEqCxt) (DConT repName) dataDecl ordInst <- mkOrdInstance Nothing (DConT repName) dataDecl showInst <- mkShowInstance Nothing (DConT repName) dataDecl (pInsts, promDecls) <- promoteM [] $ do promoteDataDec dataDecl promoteDerivedEqDec dataDeclEqInst traverse (promoteInstanceDec mempty) [ordInst, showInst] singletonDecls <- singDecsM [] $ do decs1 <- singDataD dataDecl decs2 <- singDerivedEqDecs dataDeclEqInst decs3 <- traverse singInstD pInsts return (decs1 ++ decs2 ++ decs3) return $ decsToTH $ repDecl : promDecls ++ singletonDecls where -- get the kinds of the arguments to the tycon with the given name getKind :: DsMonad q => Name -> q [DKind] getKind name = do info <- reifyWithLocals name dinfo <- dsInfo info case dinfo of DTyConI (DDataD _ (_:_) _ _ _ _ _) _ -> fail "Cannot make a representation of a constrained data type" DTyConI (DDataD _ [] _ tvbs mk _ _) _ -> do all_tvbs <- buildDataDTvbs tvbs mk return $ map (fromMaybe (DConT typeKindName) . extractTvbKind) all_tvbs DTyConI (DTySynD _ tvbs _) _ -> return $ map (fromMaybe (DConT typeKindName) . extractTvbKind) tvbs DPrimTyConI _ n _ -> return $ replicate n $ DConT typeKindName _ -> fail $ "Invalid thing for representation: " ++ (show name) -- first parameter is whether this is a real ctor (with a fresh name) -- or a fake ctor (when the name is actually a Haskell type) mkCtor :: DsMonad q => Bool -> Name -> [DKind] -> q DCon mkCtor real name args = do (types, vars) <- evalForPair $ mapM (kindToType []) args dataName <- if real then mkDataName (nameBase name) else return name return $ DCon (map DPlainTV vars) [] dataName (DNormalC False (map (\ty -> (noBang, ty)) types)) (DConT repName) where noBang = Bang NoSourceUnpackedness NoSourceStrictness -- demote a kind back to a type, accumulating any unbound parameters kindToType :: DsMonad q => [DType] -> DKind -> QWithAux [Name] q DType kindToType _ (DForallT _ _ _) = fail "Explicit forall encountered in kind" kindToType args (DAppT f a) = do a' <- kindToType [] a kindToType (a' : args) f kindToType args (DSigT t k) = do t' <- kindToType [] t k' <- kindToType [] k return $ DSigT t' k' `foldType` args kindToType args (DVarT n) = do addElement n return $ DVarT n `foldType` args kindToType args (DConT n) = return $ DConT name `foldType` args where name | isTypeKindName n = repName | otherwise = n kindToType args DArrowT = return $ DArrowT `foldType` args kindToType args k@(DLitT {}) = return $ k `foldType` args kindToType args DWildCardT = return $ DWildCardT `foldType` args