module Agda.Syntax.Abstract.Views where import Prelude hiding (null) import Control.Applicative ( Const(Const), getConst ) import Control.Monad.Identity import Data.Foldable (foldMap) import qualified Data.DList as DL import Data.Semigroup ((<>)) import Data.Void import Agda.Syntax.Common import Agda.Syntax.Abstract as A import Agda.Syntax.Concrete (FieldAssignment', exprFieldA, TacticAttribute') import Agda.Syntax.Info import Agda.Syntax.Scope.Base (KindOfName(..), conKindOfName, WithKind(..)) import Agda.Utils.Either import Agda.Utils.List1 (List1) import Agda.Utils.Null import Agda.Utils.Singleton import Agda.Utils.Impossible data AppView' arg = Application Expr [NamedArg arg] deriving (Functor) type AppView = AppView' Expr -- | Gather applications to expose head and spine. -- -- Note: everything is an application, possibly of itself to 0 arguments appView :: Expr -> AppView appView = fmap snd . appView' appView' :: Expr -> AppView' (AppInfo, Expr) appView' e = f (DL.toList es) where (f, es) = appView'' e appView'' = \case App i e1 e2 | Dot _ e2' <- unScope $ namedArg e2 , Just f <- maybeProjTurnPostfix e2' , getHiding e2 == NotHidden -- Jesper, 2018-12-13: postfix projections shouldn't be hidden -> (Application f, singleton (defaultNamedArg (i, e1))) App i e1 arg | (f, es) <- appView'' e1 -> (f, es `DL.snoc` (fmap . fmap) (i,) arg) ScopedExpr _ e -> appView'' e e -> (Application e, mempty) maybeProjTurnPostfix :: Expr -> Maybe Expr maybeProjTurnPostfix e = case e of ScopedExpr i e' -> ScopedExpr i <$> maybeProjTurnPostfix e' Proj _ x -> return $ Proj ProjPostfix x _ -> Nothing unAppView :: AppView -> Expr unAppView (Application h es) = foldl (App defaultAppInfo_) h es -- | Collects plain lambdas. data LamView = LamView [LamBinding] Expr lamView :: Expr -> LamView lamView (Lam i b e) = cons b $ lamView e where cons b (LamView bs e) = LamView (b : bs) e lamView (ScopedExpr _ e) = lamView e lamView e = LamView [] e -- | Collect @A.Pi@s. data PiView = PiView [(ExprInfo, Telescope1)] Type piView :: Expr -> PiView piView = \case Pi i tel b -> cons $ piView b where cons (PiView tels t) = PiView ((i,tel) : tels) t e -> PiView [] e unPiView :: PiView -> Expr unPiView (PiView tels t) = foldr (uncurry Pi) t tels -- | Gather top-level 'AsP'atterns and 'AnnP'atterns to expose underlying pattern. asView :: A.Pattern -> ([Name], [A.Expr], A.Pattern) asView (A.AsP _ x p) = (\(asb, ann, p) -> (unBind x : asb, ann, p)) $ asView p asView (A.AnnP _ a p) = (\(asb, ann, p) -> (asb, a : ann, p)) $ asView p asView p = ([], [], p) -- | Remove top 'ScopedExpr' wrappers. unScope :: Expr -> Expr unScope (ScopedExpr scope e) = unScope e unScope (QuestionMark i ii) = QuestionMark (i {metaScope = empty}) ii unScope (Underscore i) = Underscore (i {metaScope = empty}) unScope e = e -- | Remove 'ScopedExpr' wrappers everywhere. -- -- NB: Unless the implementation of 'ExprLike' for clauses -- has been finished, this does not work for clauses yet. deepUnscope :: ExprLike a => a -> a deepUnscope = mapExpr unScope deepUnscopeDecls :: [A.Declaration] -> [A.Declaration] deepUnscopeDecls = concatMap deepUnscopeDecl deepUnscopeDecl :: A.Declaration -> [A.Declaration] deepUnscopeDecl = \case A.ScopedDecl _ ds -> deepUnscopeDecls ds A.Mutual i ds -> [A.Mutual i (deepUnscopeDecls ds)] A.Section i e m tel ds -> [A.Section i e m (deepUnscope tel) (deepUnscopeDecls ds)] A.RecDef i x uc dir bs e ds -> [ A.RecDef i x uc dir (deepUnscope bs) (deepUnscope e) (deepUnscopeDecls ds) ] d -> [deepUnscope d] -- * Traversal --------------------------------------------------------------------------- -- Type aliases to abbreviate the quantified foralls which we use to avoid -- giving in to NoMonoLocalBinds. type RecurseExprFn m a = Applicative m => (Expr -> m Expr -> m Expr) -> a -> m a type RecurseExprRecFn m = forall a. ExprLike a => a -> m a type FoldExprFn m a = Monoid m => (Expr -> m) -> a -> m type FoldExprRecFn m = forall a. ExprLike a => a -> m type TraverseExprFn m a = (Applicative m, Monad m) => (Expr -> m Expr) -> a -> m a type TraverseExprRecFn m = forall a. ExprLike a => a -> m a -- | Apply an expression rewriting to every subexpression, inside-out. -- See "Agda.Syntax.Internal.Generic". class ExprLike a where -- | The first expression is pre-traversal, the second one post-traversal. recurseExpr :: RecurseExprFn m a default recurseExpr :: (Traversable f, ExprLike a', a ~ f a', Applicative m) => (Expr -> m Expr -> m Expr) -> a -> m a recurseExpr = traverse . recurseExpr foldExpr :: FoldExprFn m a foldExpr f = getConst . recurseExpr (\ pre post -> Const (f pre) <* post) traverseExpr :: TraverseExprFn m a traverseExpr f = recurseExpr (\ pre post -> f =<< post) mapExpr :: (Expr -> Expr) -> (a -> a) mapExpr f = runIdentity . traverseExpr (Identity . f) instance ExprLike Expr where recurseExpr :: forall m. RecurseExprFn m Expr recurseExpr f e0 = f e0 $ do let recurse :: RecurseExprRecFn m recurse e = recurseExpr f e case e0 of Var{} -> pure e0 Def'{} -> pure e0 Proj{} -> pure e0 Con{} -> pure e0 Lit{} -> pure e0 QuestionMark{} -> pure e0 Underscore{} -> pure e0 Dot ei e -> Dot ei <$> recurse e App ei e arg -> App ei <$> recurse e <*> recurse arg WithApp ei e es -> WithApp ei <$> recurse e <*> recurse es Lam ei b e -> Lam ei <$> recurse b <*> recurse e AbsurdLam{} -> pure e0 ExtendedLam ei di er x cls -> ExtendedLam ei di er x <$> recurse cls Pi ei tel e -> Pi ei <$> recurse tel <*> recurse e Generalized s e -> Generalized s <$> recurse e Fun ei arg e -> Fun ei <$> recurse arg <*> recurse e Let ei bs e -> Let ei <$> recurse bs <*> recurse e Rec ei bs -> Rec ei <$> recurse bs RecUpdate ei e bs -> RecUpdate ei <$> recurse e <*> recurse bs ScopedExpr sc e -> ScopedExpr sc <$> recurse e Quote{} -> pure e0 QuoteTerm{} -> pure e0 Unquote{} -> pure e0 DontCare e -> DontCare <$> recurse e PatternSyn{} -> pure e0 Macro{} -> pure e0 foldExpr :: forall m. FoldExprFn m Expr foldExpr f e = case e of Var{} -> m Def'{} -> m Proj{} -> m Con{} -> m PatternSyn{} -> m Macro{} -> m Lit{} -> m QuestionMark{} -> m Underscore{} -> m Dot _ e -> m `mappend` fold e App _ e e' -> m `mappend` fold e `mappend` fold e' WithApp _ e es -> m `mappend` fold e `mappend` fold es Lam _ b e -> m `mappend` fold b `mappend` fold e AbsurdLam{} -> m ExtendedLam _ _ _ _ cs -> m `mappend` fold cs Pi _ tel e -> m `mappend` fold tel `mappend` fold e Generalized _ e -> m `mappend` fold e Fun _ e e' -> m `mappend` fold e `mappend` fold e' Let _ bs e -> m `mappend` fold bs `mappend` fold e Rec _ as -> m `mappend` fold as RecUpdate _ e as -> m `mappend` fold e `mappend` fold as ScopedExpr _ e -> m `mappend` fold e Quote{} -> m QuoteTerm{} -> m Unquote{} -> m DontCare e -> m `mappend` fold e where m = f e fold :: FoldExprRecFn m fold = foldExpr f traverseExpr :: forall m. TraverseExprFn m Expr traverseExpr f e = do let trav :: TraverseExprRecFn m trav e = traverseExpr f e case e of Var{} -> f e Def'{} -> f e Proj{} -> f e Con{} -> f e Lit{} -> f e QuestionMark{} -> f e Underscore{} -> f e Dot ei e -> f =<< Dot ei <$> trav e App ei e arg -> f =<< App ei <$> trav e <*> trav arg WithApp ei e es -> f =<< WithApp ei <$> trav e <*> trav es Lam ei b e -> f =<< Lam ei <$> trav b <*> trav e AbsurdLam{} -> f e ExtendedLam ei di re x cls -> f =<< ExtendedLam ei di re x <$> trav cls Pi ei tel e -> f =<< Pi ei <$> trav tel <*> trav e Generalized s e -> f =<< Generalized s <$> trav e Fun ei arg e -> f =<< Fun ei <$> trav arg <*> trav e Let ei bs e -> f =<< Let ei <$> trav bs <*> trav e Rec ei bs -> f =<< Rec ei <$> trav bs RecUpdate ei e bs -> f =<< RecUpdate ei <$> trav e <*> trav bs ScopedExpr sc e -> f =<< ScopedExpr sc <$> trav e Quote{} -> f e QuoteTerm{} -> f e Unquote{} -> f e DontCare e -> f =<< DontCare <$> trav e PatternSyn{} -> f e Macro{} -> f e instance ExprLike a => ExprLike (Arg a) instance ExprLike a => ExprLike (Maybe a) instance ExprLike a => ExprLike (Named x a) instance ExprLike a => ExprLike (Ranged a) instance ExprLike a => ExprLike [a] instance ExprLike a => ExprLike (List1 a) instance ExprLike a => ExprLike (TacticAttribute' a) instance (ExprLike a, ExprLike b) => ExprLike (a, b) where recurseExpr f (x, y) = (,) <$> recurseExpr f x <*> recurseExpr f y instance ExprLike Void where recurseExpr f = absurd instance ExprLike a => ExprLike (FieldAssignment' a) where recurseExpr = exprFieldA . recurseExpr instance (ExprLike a, ExprLike b) => ExprLike (Either a b) where recurseExpr f = traverseEither (recurseExpr f) (recurseExpr f) instance ExprLike BindName where recurseExpr f = pure instance ExprLike ModuleName where recurseExpr f = pure instance ExprLike QName where recurseExpr _ = pure instance ExprLike LamBinding where recurseExpr f e = case e of DomainFree t x -> DomainFree <$> recurseExpr f t <*> pure x DomainFull bs -> DomainFull <$> recurseExpr f bs foldExpr f e = case e of DomainFree t _ -> foldExpr f t DomainFull bs -> foldExpr f bs traverseExpr f e = case e of DomainFree t x -> DomainFree <$> traverseExpr f t <*> pure x DomainFull bs -> DomainFull <$> traverseExpr f bs instance ExprLike GeneralizeTelescope where recurseExpr f (GeneralizeTel s tel) = GeneralizeTel s <$> recurseExpr f tel foldExpr f (GeneralizeTel s tel) = foldExpr f tel traverseExpr f (GeneralizeTel s tel) = GeneralizeTel s <$> traverseExpr f tel instance ExprLike DataDefParams where recurseExpr f (DataDefParams s tel) = DataDefParams s <$> recurseExpr f tel foldExpr f (DataDefParams s tel) = foldExpr f tel traverseExpr f (DataDefParams s tel) = DataDefParams s <$> traverseExpr f tel instance ExprLike TypedBindingInfo where recurseExpr f (TypedBindingInfo s t) = TypedBindingInfo <$> recurseExpr f s <*> pure t foldExpr f (TypedBindingInfo s t) = foldExpr f s traverseExpr f (TypedBindingInfo s t) = TypedBindingInfo <$> traverseExpr f s <*> pure t instance ExprLike TypedBinding where recurseExpr f e = case e of TBind r t xs e -> TBind r <$> recurseExpr f t <*> pure xs <*> recurseExpr f e TLet r ds -> TLet r <$> recurseExpr f ds foldExpr f e = case e of TBind _ t _ e -> foldExpr f t `mappend` foldExpr f e TLet _ ds -> foldExpr f ds traverseExpr f e = case e of TBind r t xs e -> TBind r <$> traverseExpr f t <*> pure xs <*> traverseExpr f e TLet r ds -> TLet r <$> traverseExpr f ds instance ExprLike LetBinding where recurseExpr :: forall m. RecurseExprFn m LetBinding recurseExpr f e = do let recurse :: RecurseExprRecFn m recurse e = recurseExpr f e case e of LetBind li ai x e e' -> LetBind li ai x <$> recurse e <*> recurse e' LetPatBind li p e -> LetPatBind li <$> recurse p <*> recurse e LetApply{} -> pure e LetOpen{} -> pure e LetDeclaredVariable _ -> pure e foldExpr :: forall m. FoldExprFn m LetBinding foldExpr f e = case e of LetBind _ _ _ e e' -> fold e `mappend` fold e' LetPatBind _ p e -> fold p `mappend` fold e LetApply{} -> mempty LetOpen{} -> mempty LetDeclaredVariable _ -> mempty where fold :: FoldExprRecFn m fold e = foldExpr f e traverseExpr :: forall m. TraverseExprFn m LetBinding traverseExpr f e = do let trav :: TraverseExprRecFn m trav e = traverseExpr f e case e of LetBind li ai x e e' -> LetBind li ai x <$> trav e <*> trav e' LetPatBind li p e -> LetPatBind li <$> trav p <*> trav e LetApply{} -> pure e LetOpen{} -> pure e LetDeclaredVariable _ -> pure e instance ExprLike a => ExprLike (Pattern' a) where instance ExprLike a => ExprLike (Clause' a) where recurseExpr :: forall m. RecurseExprFn m (Clause' a) recurseExpr f (Clause lhs spats rhs ds ca) = Clause <$> rec lhs <*> pure spats <*> rec rhs <*> rec ds <*> pure ca where rec :: RecurseExprRecFn m rec = recurseExpr f instance ExprLike RHS where recurseExpr :: forall m. RecurseExprFn m RHS recurseExpr f rhs = case rhs of RHS e c -> RHS <$> rec e <*> pure c AbsurdRHS{} -> pure rhs WithRHS x es cs -> WithRHS x <$> rec es <*> rec cs RewriteRHS xes spats rhs ds -> RewriteRHS <$> rec xes <*> pure spats <*> rec rhs <*> rec ds where rec :: RecurseExprRecFn m rec e = recurseExpr f e instance (ExprLike qn, ExprLike nm, ExprLike p, ExprLike e) => ExprLike (RewriteEqn' qn nm p e) where recurseExpr f = \case Rewrite es -> Rewrite <$> recurseExpr f es Invert qn pes -> Invert <$> recurseExpr f qn <*> recurseExpr f pes LeftLet pes -> LeftLet <$> recurseExpr f pes instance ExprLike WhereDeclarations where recurseExpr f (WhereDecls a b c) = WhereDecls a b <$> recurseExpr f c instance ExprLike ModuleApplication where recurseExpr :: forall m. RecurseExprFn m ModuleApplication recurseExpr f a = case a of SectionApp tel m es -> SectionApp <$> rec tel <*> rec m <*> rec es RecordModuleInstance{} -> pure a where rec :: RecurseExprRecFn m rec e = recurseExpr f e instance ExprLike Pragma where recurseExpr :: forall m. RecurseExprFn m Pragma recurseExpr f p = case p of BuiltinPragma s x -> pure p OptionsPragma{} -> pure p BuiltinNoDefPragma{} -> pure p RewritePragma{} -> pure p CompilePragma{} -> pure p StaticPragma{} -> pure p InjectivePragma{} -> pure p InjectiveForInferencePragma{} -> pure p InlinePragma{} -> pure p EtaPragma{} -> pure p NotProjectionLikePragma{} -> pure p OverlapPragma{} -> pure p DisplayPragma f xs e -> DisplayPragma f <$> rec xs <*> rec e where rec :: RecurseExprRecFn m rec e = recurseExpr f e instance ExprLike LHS where recurseExpr f (LHS i p) = LHS i <$> recurseExpr f p instance ExprLike a => ExprLike (LHSCore' a) where instance ExprLike a => ExprLike (WithHiding a) where instance ExprLike SpineLHS where recurseExpr f (SpineLHS i x ps) = SpineLHS i x <$> recurseExpr f ps instance ExprLike Declaration where recurseExpr :: forall m. RecurseExprFn m Declaration recurseExpr f d = case d of Axiom a d i mp x e -> Axiom a d i mp x <$> rec e Generalize s i j x e -> Generalize s i j x <$> rec e Field i x e -> Field i x <$> rec e Primitive i x e -> Primitive i x <$> rec e Mutual i ds -> Mutual i <$> rec ds Section i e m tel ds -> Section i e m <$> rec tel <*> rec ds Apply i e m a ci d -> (\a -> Apply i e m a ci d) <$> rec a Import{} -> pure d Pragma i p -> Pragma i <$> rec p Open{} -> pure d FunDef i f cs -> FunDef i f <$> rec cs DataSig i er d tel e -> DataSig i er d <$> rec tel <*> rec e DataDef i d uc bs cs -> DataDef i d uc <$> rec bs <*> rec cs RecSig i er r tel e -> RecSig i er r <$> rec tel <*> rec e RecDef i r uc dir bs e ds -> RecDef i r uc dir <$> rec bs <*> rec e <*> rec ds PatternSynDef f xs p -> PatternSynDef f xs <$> rec p UnquoteDecl i is xs e -> UnquoteDecl i is xs <$> rec e UnquoteDef i xs e -> UnquoteDef i xs <$> rec e UnquoteData i xs uc j cs e -> UnquoteData i xs uc j cs <$> rec e ScopedDecl s ds -> ScopedDecl s <$> rec ds UnfoldingDecl r ds -> UnfoldingDecl r <$> rec ds where rec :: RecurseExprRecFn m rec e = recurseExpr f e -- * Getting all declared names --------------------------------------------------------------------------- type KName = WithKind QName -- | Extracts "all" names which are declared in a 'Declaration'. -- -- Includes: local modules and @where@ clauses. -- Excludes: @open public@, @let@, @with@ function names, extended lambdas. class DeclaredNames a where declaredNames :: Collection KName m => a -> m default declaredNames :: (Foldable t, DeclaredNames b, t b ~ a) => Collection KName m => a -> m declaredNames = foldMap declaredNames instance DeclaredNames a => DeclaredNames [a] instance DeclaredNames a => DeclaredNames (List1 a) instance DeclaredNames a => DeclaredNames (Maybe a) instance DeclaredNames a => DeclaredNames (Arg a) instance DeclaredNames a => DeclaredNames (Named name a) instance DeclaredNames a => DeclaredNames (FieldAssignment' a) instance (DeclaredNames a, DeclaredNames b) => DeclaredNames (Either a b) where declaredNames = either declaredNames declaredNames instance (DeclaredNames a, DeclaredNames b) => DeclaredNames (a,b) where declaredNames (a,b) = declaredNames a <> declaredNames b instance DeclaredNames KName where declaredNames = singleton instance DeclaredNames RecordDirectives where declaredNames (RecordDirectives i _ _ c) = kc where kc = maybe mempty (singleton . WithKind k) c k = maybe ConName (conKindOfName . rangedThing) i instance DeclaredNames Declaration where declaredNames = \case Axiom _ di _ _ q _ -> singleton . (`WithKind` q) $ case defMacro di of MacroDef -> MacroName NotMacroDef -> AxiomName Generalize _ _ _ q _ -> singleton (WithKind GeneralizeName q) Field _ q _ -> singleton (WithKind FldName q) Primitive _ q _ -> singleton (WithKind PrimName q) Mutual _ decls -> declaredNames decls DataSig _ _ q _ _ -> singleton (WithKind DataName q) DataDef _ q _ _ decls -> singleton (WithKind DataName q) <> foldMap con decls RecSig _ _ q _ _ -> singleton (WithKind RecName q) RecDef _ q _ dir _ _ decls -> singleton (WithKind RecName q) <> declaredNames dir <> declaredNames decls PatternSynDef q _ _ -> singleton (WithKind PatternSynName q) UnquoteDecl _ _ qs _ -> fromList $ map (WithKind OtherDefName) qs -- could be Fun or Axiom UnquoteDef _ qs _ -> fromList $ map (WithKind FunName) qs -- cannot be Axiom UnquoteData _ d _ _ cs _ -> singleton (WithKind DataName d) <> fromList (map (WithKind ConName) cs) -- singleton _ <> map (WithKind ConName) cs FunDef _ q cls -> singleton (WithKind FunName q) <> declaredNames cls ScopedDecl _ decls -> declaredNames decls Section _ _ _ _ decls -> declaredNames decls Pragma _ pragma -> declaredNames pragma Apply{} -> mempty Import{} -> mempty Open{} -> mempty UnfoldingDecl{} -> mempty where con = \case Axiom _ _ _ _ q _ -> singleton $ WithKind ConName q _ -> __IMPOSSIBLE__ instance DeclaredNames Pragma where declaredNames = \case BuiltinNoDefPragma _b kind x -> singleton $ WithKind kind x BuiltinPragma{} -> mempty CompilePragma{} -> mempty RewritePragma{} -> mempty StaticPragma{} -> mempty EtaPragma{} -> mempty InjectivePragma{} -> mempty InjectiveForInferencePragma{} -> mempty InlinePragma{} -> mempty NotProjectionLikePragma{} -> mempty DisplayPragma{} -> mempty OptionsPragma{} -> mempty OverlapPragma{} -> mempty instance DeclaredNames Clause where declaredNames (Clause _ _ rhs decls _) = declaredNames rhs <> declaredNames decls instance DeclaredNames WhereDeclarations where declaredNames (WhereDecls _ _ ds) = declaredNames ds instance DeclaredNames RHS where declaredNames = \case RHS _ _ -> mempty AbsurdRHS -> mempty WithRHS _q _es cls -> declaredNames cls RewriteRHS _qes _ rhs cls -> declaredNames rhs <> declaredNames cls -- Andreas, 2020-04-13: Migration from Agda.Syntax.Abstract.AllNames -- -- Since we are not interested in names of extended lambdas, we do not -- traverse into expression. -- -- However, we keep this code (originally Agda.Syntax.Abstract.AllNames) around -- should arise a need to collect extended lambda names. -- instance (DeclaredNames a, DeclaredNames b, DeclaredNames c) => DeclaredNames (a,b,c) where -- declaredNames (a,b,c) = declaredNames a <> declaredNames b <> declaredNames c -- instance DeclaredNames RHS where -- declaredNames = \case -- RHS e _ -> declaredNames e -- AbsurdRHS{} -> mempty -- WithRHS q _ cls -> singleton (WithKind FunName q) <> declaredNames cls -- RewriteRHS qes _ rhs cls -> declaredNames (qes, rhs, cls) -- instance DeclaredNames ModuleName where -- declaredNames _ = mempty -- instance (DeclaredNames qn, DeclaredNames e) => DeclaredNames (RewriteEqn' qn p e) where -- declaredNames = \case -- Rewrite es -> declaredNames es -- Invert qn pes -> declaredNames qn <> declaredNames pes -- instance DeclaredNames Expr where -- declaredNames = \case -- Var{} -> mempty -- Def{} -> mempty -- Proj{} -> mempty -- Con{} -> mempty -- Lit{} -> mempty -- QuestionMark{} -> mempty -- Underscore{} -> mempty -- Dot _ e -> declaredNames e -- App _ e1 e2 -> declaredNames e1 <> declaredNames e2 -- WithApp _ e es -> declaredNames e <> declaredNames es -- Lam _ b e -> declaredNames b <> declaredNames e -- AbsurdLam{} -> mempty -- ExtendedLam _ _ q cls -> singleton (WithKind FunName q) <> declaredNames cls -- Pi _ tel e -> declaredNames tel <> declaredNames e -- Generalized s e -> declaredNames e -- NOT: fromList (map (WithKind GeneralizeName) $ Set.toList s) <> declaredNames e -- Fun _ e1 e2 -> declaredNames e1 <> declaredNames e2 -- Set{} -> mempty -- Prop{} -> mempty -- Let _ lbs e -> declaredNames lbs <> declaredNames e -- Rec _ fields -> declaredNames fields -- RecUpdate _ e fs -> declaredNames e <> declaredNames fs -- ScopedExpr _ e -> declaredNames e -- Quote{} -> mempty -- QuoteTerm{} -> mempty -- Unquote{} -> mempty -- DontCare{} -> mempty -- PatternSyn{} -> mempty -- Macro{} -> mempty -- instance DeclaredNames LamBinding where -- declaredNames DomainFree{} = mempty -- declaredNames (DomainFull binds) = declaredNames binds -- instance DeclaredNames TypedBinding where -- declaredNames (TBind _ t _ e) = declaredNames (t, e) -- declaredNames (TLet _ lbs) = declaredNames lbs -- instance DeclaredNames LetBinding where -- declaredNames (LetBind _ _ _ e1 e2) = declaredNames e1 <> declaredNames e2 -- declaredNames (LetPatBind _ _ e) = declaredNames e -- declaredNames (LetApply _ _ app _ _) = declaredNames app -- declaredNames LetOpen{} = mempty -- declaredNames (LetDeclaredVariable _) = mempty -- instance DeclaredNames ModuleApplication where -- declaredNames (SectionApp bindss _ es) = declaredNames bindss <> declaredNames es -- declaredNames RecordModuleInstance{} = mempty