{-# LANGUAGE TemplateHaskell, CPP #-} -- | -- Module : Data.Express.Name.Derive -- Copyright : (c) 2019-2020 Rudy Matela -- License : 3-Clause BSD (see the file LICENSE) -- Maintainer : Rudy Matela -- -- Template Haskell utilities. module Data.Express.Utils.TH ( reallyDeriveCascading , deriveWhenNeeded , deriveWhenNeededOrWarn , typeConArgs , typeConArgsThat , typeConCascadingArgsThat , normalizeType , normalizeTypeUnits , isInstanceOf , isntInstanceOf , typeArity , typeConstructors , isTypeSynonym , typeSynonymType , mergeIFns , mergeI , lookupValN , showJustName , typeConstructorsArgNames , (|=>|) , (|++|) , whereI , module Language.Haskell.TH ) where import Control.Monad import Data.List import Language.Haskell.TH deriveWhenNeeded :: Name -> (Name -> DecsQ) -> Name -> DecsQ deriveWhenNeeded = deriveWhenNeededX False deriveWhenNeededOrWarn :: Name -> (Name -> DecsQ) -> Name -> DecsQ deriveWhenNeededOrWarn = deriveWhenNeededX True deriveWhenNeededX :: Bool -> Name -> (Name -> DecsQ) -> Name -> DecsQ deriveWhenNeededX warnExisting cls reallyDerive t = do is <- t `isInstanceOf` cls if is then do unless (not warnExisting) (reportWarning $ "Instance " ++ showJustName cls ++ " " ++ showJustName t ++ " already exists, skipping derivation") return [] else reallyDerive t showJustName :: Name -> String showJustName = reverse . takeWhile (/= '.') . reverse . show reallyDeriveCascading :: Name -> (Name -> DecsQ) -> Name -> DecsQ reallyDeriveCascading cls reallyDerive t = return . concat =<< mapM reallyDerive =<< filterM (liftM not . isTypeSynonym) =<< return . (t:) . delete t =<< t `typeConCascadingArgsThat` (`isntInstanceOf` cls) typeConArgs :: Name -> Q [Name] typeConArgs t = do is <- isTypeSynonym t if is then liftM typeConTs $ typeSynonymType t else liftM (nubMerges . map typeConTs . concat . map snd) $ typeConstructors t where typeConTs :: Type -> [Name] typeConTs (AppT t1 t2) = typeConTs t1 `nubMerge` typeConTs t2 typeConTs (SigT t _) = typeConTs t typeConTs (VarT _) = [] typeConTs (ConT n) = [n] #if __GLASGOW_HASKELL__ >= 800 -- typeConTs (PromotedT n) = [n] ? typeConTs (InfixT t1 n t2) = typeConTs t1 `nubMerge` typeConTs t2 typeConTs (UInfixT t1 n t2) = typeConTs t1 `nubMerge` typeConTs t2 typeConTs (ParensT t) = typeConTs t #endif typeConTs _ = [] typeConArgsThat :: Name -> (Name -> Q Bool) -> Q [Name] typeConArgsThat t p = do targs <- typeConArgs t tbs <- mapM (\t' -> do is <- p t'; return (t',is)) targs return [t' | (t',p) <- tbs, p] typeConCascadingArgsThat :: Name -> (Name -> Q Bool) -> Q [Name] t `typeConCascadingArgsThat` p = do ts <- t `typeConArgsThat` p let p' t' = do is <- p t'; return $ t' `notElem` (t:ts) && is tss <- mapM (`typeConCascadingArgsThat` p') ts return $ nubMerges (ts:tss) -- Normalizes a type by applying it to necessary type variables, making it -- accept "zero" parameters. The normalized type is tupled with a list of -- necessary type variables. -- -- Suppose: -- -- > data DT a b c ... = ... -- -- Then, in pseudo-TH: -- -- > normalizeType [t|DT|] == Q (DT a b c ..., [a, b, c, ...]) normalizeType :: Name -> Q (Type, [Type]) normalizeType t = do ar <- typeArity t vs <- newVarTs ar return (foldl AppT (ConT t) vs, vs) where newNames :: [String] -> Q [Name] newNames = mapM newName newVarTs :: Int -> Q [Type] newVarTs n = liftM (map VarT) $ newNames (take n . map (:[]) $ cycle ['a'..'z']) -- Normalizes a type by applying it to units (`()`) while possible. -- -- > normalizeTypeUnits ''Int === [t| Int |] -- > normalizeTypeUnits ''Maybe === [t| Maybe () |] -- > normalizeTypeUnits ''Either === [t| Either () () |] normalizeTypeUnits :: Name -> Q Type normalizeTypeUnits t = do ar <- typeArity t return (foldl AppT (ConT t) (replicate ar (TupleT 0))) -- Given a type name and a class name, -- returns whether the type is an instance of that class. isInstanceOf :: Name -> Name -> Q Bool isInstanceOf tn cl = do ty <- normalizeTypeUnits tn isInstance cl [ty] isntInstanceOf :: Name -> Name -> Q Bool isntInstanceOf tn cl = liftM not (isInstanceOf tn cl) -- | Given a type name, return the number of arguments taken by that type. -- Examples in partially broken TH: -- -- > arity ''Int === Q 0 -- > arity ''Int->Int === Q 0 -- > arity ''Maybe === Q 1 -- > arity ''Either === Q 2 -- > arity ''Int-> === Q 1 -- -- This works for Data's and Newtype's and it is useful when generating -- typeclass instances. typeArity :: Name -> Q Int typeArity t = do ti <- reify t return . length $ case ti of #if __GLASGOW_HASKELL__ < 800 TyConI (DataD _ _ ks _ _) -> ks TyConI (NewtypeD _ _ ks _ _) -> ks #else TyConI (DataD _ _ ks _ _ _) -> ks TyConI (NewtypeD _ _ ks _ _ _) -> ks #endif TyConI (TySynD _ ks _) -> ks _ -> error $ "error (typeArity): symbol " ++ show t ++ " is not a newtype, data or type synonym" -- Given a type name, returns a list of its type constructor names paired with -- the type arguments they take. -- -- > typeConstructors ''() === Q [('(),[])] -- -- > typeConstructors ''(,) === Q [('(,),[VarT a, VarT b])] -- -- > typeConstructors ''[] === Q [('[],[]),('(:),[VarT a,AppT ListT (VarT a)])] -- -- > data Pair a = P a a -- > typeConstructors ''Pair === Q [('P,[VarT a, VarT a])] -- -- > data Point = Pt Int Int -- > typeConstructors ''Point === Q [('Pt,[ConT Int, ConT Int])] typeConstructors :: Name -> Q [(Name,[Type])] typeConstructors t = do ti <- reify t return . map simplify $ case ti of #if __GLASGOW_HASKELL__ < 800 TyConI (DataD _ _ _ cs _) -> cs TyConI (NewtypeD _ _ _ c _) -> [c] #else TyConI (DataD _ _ _ _ cs _) -> cs TyConI (NewtypeD _ _ _ _ c _) -> [c] #endif _ -> error $ "error (typeConstructors): symbol " ++ show t ++ " is neither newtype nor data" where simplify (NormalC n ts) = (n,map snd ts) simplify (RecC n ts) = (n,map trd ts) simplify (InfixC t1 n t2) = (n,[snd t1,snd t2]) trd (x,y,z) = z isTypeSynonym :: Name -> Q Bool isTypeSynonym t = do ti <- reify t return $ case ti of TyConI (TySynD _ _ _) -> True _ -> False typeSynonymType :: Name -> Q Type typeSynonymType t = do ti <- reify t return $ case ti of TyConI (TySynD _ _ t') -> t' _ -> error $ "error (typeSynonymType): symbol " ++ show t ++ " is not a type synonym" -- Append to instance contexts in a declaration. -- -- > sequence [[|Eq b|],[|Eq c|]] |=>| [t|instance Eq a => Cl (Ty a) where f=g|] -- > == [t| instance (Eq a, Eq b, Eq c) => Cl (Ty a) where f = g |] (|=>|) :: Cxt -> DecsQ -> DecsQ c |=>| qds = do ds <- qds return $ map (`ac` c) ds #if __GLASGOW_HASKELL__ < 800 where ac (InstanceD c ts ds) c' = InstanceD (c++c') ts ds ac d _ = d #else where ac (InstanceD o c ts ds) c' = InstanceD o (c++c') ts ds ac d _ = d #endif (|++|) :: DecsQ -> DecsQ -> DecsQ (|++|) = liftM2 (++) mergeIFns :: DecsQ -> DecsQ mergeIFns qds = do ds <- qds return $ map m' ds where #if __GLASGOW_HASKELL__ < 800 m' (InstanceD c ts ds) = InstanceD c ts [foldr1 m ds] #else m' (InstanceD o c ts ds) = InstanceD o c ts [foldr1 m ds] #endif FunD n cs1 `m` FunD _ cs2 = FunD n (cs1 ++ cs2) mergeI :: DecsQ -> DecsQ -> DecsQ qds1 `mergeI` qds2 = do ds1 <- qds1 ds2 <- qds2 return $ ds1 `m` ds2 where #if __GLASGOW_HASKELL__ < 800 [InstanceD c ts ds1] `m` [InstanceD _ _ ds2] = [InstanceD c ts (ds1 ++ ds2)] #else [InstanceD o c ts ds1] `m` [InstanceD _ _ _ ds2] = [InstanceD o c ts (ds1 ++ ds2)] #endif whereI :: DecsQ -> [Dec] -> DecsQ qds `whereI` w = do ds <- qds return $ map (`aw` w) ds #if __GLASGOW_HASKELL__ < 800 where aw (InstanceD c ts ds) w' = InstanceD c ts (ds++w') aw d _ = d #else where aw (InstanceD o c ts ds) w' = InstanceD o c ts (ds++w') aw d _ = d #endif -- > nubMerge xs ys == nub (merge xs ys) -- > nubMerge xs ys == nub (sort (xs ++ ys)) nubMerge :: Ord a => [a] -> [a] -> [a] nubMerge [] ys = ys nubMerge xs [] = xs nubMerge (x:xs) (y:ys) | x < y = x : xs `nubMerge` (y:ys) | x > y = y : (x:xs) `nubMerge` ys | otherwise = x : xs `nubMerge` ys nubMerges :: Ord a => [[a]] -> [a] nubMerges = foldr nubMerge [] typeConstructorsArgNames :: Name -> Q [(Name,[Name])] typeConstructorsArgNames t = do cs <- typeConstructors t sequence [ do ns <- sequence [newName "x" | _ <- ts] return (c,ns) | (c,ts) <- cs ] lookupValN :: String -> Q Name lookupValN s = do mn <- lookupValueName s case mn of Just n -> return n Nothing -> fail $ "lookupValN: cannot find " ++ s