module Type.Unify (unify) where import Type.Type import qualified Data.UnionFind.IO as UF import qualified Type.State as TS import Control.Arrow (first,second) import Control.Monad.State import qualified Text.PrettyPrint as P unify :: Variable -> Variable -> StateT TS.SolverState IO () unify variable1 variable2 = do equivalent <- liftIO $ UF.equivalent variable1 variable2 if equivalent then return () else actuallyUnify variable1 variable2 actuallyUnify :: Variable -> Variable -> StateT TS.SolverState IO () actuallyUnify variable1 variable2 = do desc1 <- liftIO $ UF.descriptor variable1 desc2 <- liftIO $ UF.descriptor variable2 let name' :: Maybe String name' = case (name desc1, name desc2) of (Just name1, Just name2) -> case (flex desc1, flex desc2) of (_, Flexible) -> Just name1 (Flexible, _) -> Just name2 (Is Number, Is _) -> Just name1 (Is _, Is Number) -> Just name2 (Is _, Is _) -> Just name1 (_, _) -> Nothing (Just name1, _) -> Just name1 (_, Just name2) -> Just name2 _ -> Nothing flex' :: Flex flex' = case (flex desc1, flex desc2) of (f, Flexible) -> f (Flexible, f) -> f (Is Number, Is _) -> Is Number (Is _, Is Number) -> Is Number (Is super, Is _) -> Is super (_, _) -> Flexible rank' :: Int rank' = min (rank desc1) (rank desc2) merge1 :: StateT TS.SolverState IO () merge1 = liftIO $ do if rank desc1 < rank desc2 then UF.union variable2 variable1 else UF.union variable1 variable2 UF.modifyDescriptor variable1 $ \desc -> desc { structure = structure desc1, flex = flex', name = name' } merge2 :: StateT TS.SolverState IO () merge2 = liftIO $ do if rank desc1 < rank desc2 then UF.union variable2 variable1 else UF.union variable1 variable2 UF.modifyDescriptor variable2 $ \desc -> desc { structure = structure desc2, flex = flex', name = name' } merge = if rank desc1 < rank desc2 then merge1 else merge2 fresh :: Maybe (Term1 Variable) -> StateT TS.SolverState IO Variable fresh structure = do var <- liftIO . UF.fresh $ Descriptor { structure = structure, rank = rank', flex = flex', name = name', copy = Nothing, mark = noMark } TS.register var flexAndUnify var = do liftIO $ UF.modifyDescriptor var $ \desc -> desc { flex = Flexible } unify variable1 variable2 superUnify = case (flex desc1, flex desc2, name desc1, name desc2) of (Is super1, Is super2, _, _) | super1 == super2 -> merge (Is Number, Is Comparable, _, _) -> merge1 (Is Comparable, Is Number, _, _) -> merge2 (Is Number, _, _, Just name) | name `elem` ["Int","Float"] -> flexAndUnify variable1 | otherwise -> TS.addError "Expecting a number (Int or Float)" variable1 variable2 (_, Is Number, Just name, _) | name `elem` ["Int","Float"] -> flexAndUnify variable2 | otherwise -> TS.addError "Expecting a number (Int or Float)" variable1 variable2 (Is Comparable, _, _, Just name) | name `elem` ["Int","Float","Char"] -> flexAndUnify variable1 | otherwise -> TS.addError "Expecting something comparable (Int, Float, Char, [comparable])." variable1 variable2 (_, Is Comparable, Just name, _) | name `elem` ["Int","Float","Char"] -> flexAndUnify variable2 | otherwise -> TS.addError "Expecting something comparable (Int, Float, Char, [comparable])." variable1 variable2 _ -> TS.addError "The following types are not equal" variable1 variable2 case (structure desc1, structure desc2) of (Nothing, Nothing) | flex desc1 == Flexible && flex desc1 == Flexible -> merge (Nothing, _) | flex desc1 == Flexible -> merge2 (_, Nothing) | flex desc2 == Flexible -> merge1 (Just (Var1 v), _) -> unify v variable2 (_, Just (Var1 v)) -> unify v variable1 (Nothing, _) -> superUnify (_, Nothing) -> superUnify (Just type1, Just type2) -> case (type1,type2) of (App1 term1 term2, App1 term1' term2') -> do merge unify term1 term1' unify term2 term2' (Fun1 term1 term2, Fun1 term1' term2') -> do merge unify term1 term1' unify term2 term2' (EmptyRecord1, EmptyRecord1) -> return () (Record1 fields1 ext1, Record1 fields2 ext2) -> TS.addError "did not write record unification yet" variable1 variable2 _ -> TS.addError "could not unify types" variable1 variable2