I fixed it! Also deleted some unused code, and refactored a little.
parent
fd98d499fe
commit
70b3b7e051
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@ -19,9 +19,10 @@ This is not guaranteed not to capture free variables.
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```
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```
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>> (\D F I. D (F I)) (\x. x x) (\f. f (f y)) (\x. x)
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>> (\D F I. D (F I)) (\x. x x) (\f. f (f y)) (\x. x)
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y y
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y y
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>> (\T f x. T (T (T (T T))) f x) (\f x. f (f x)) (\x. x) y
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y
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>> \x. \y. y x
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>> \x. \y. y x
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\x. \y. y:0 x:1
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\x. \y. y:0 x:1
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>>
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```
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```
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## Syntax
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## Syntax
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@ -12,12 +12,9 @@ prompt text = do
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hFlush stdout
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hFlush stdout
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getLine
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getLine
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-- (\D F I. D (F I)) (\x. x x) (\f. f (f y)) (\x. x)
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main :: IO ()
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main :: IO ()
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main = forever $ do
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main = forever $ do
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expr <- parse expr "stdin" <$> prompt ">> "
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expr <- parse expr "stdin" <$> prompt ">> "
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case expr of
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case expr of
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Left parseError -> putStrLn $ "Parse error: " ++ show parseError
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Left parseError -> putStrLn $ "Parse error: " ++ show parseError
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Right expr -> do
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Right expr -> print $ eval $ canonym expr
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print $ eval [] $ canonym expr
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@ -1,17 +1,20 @@
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{-# LANGUAGE TemplateHaskell, TypeFamilies, DeriveFunctor, DeriveFoldable, DeriveTraversable #-}
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{-# LANGUAGE TemplateHaskell, TypeFamilies, DeriveFunctor, DeriveFoldable, DeriveTraversable #-}
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module UntypedLambdaCalculus where
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module UntypedLambdaCalculus (Expr (Free, Var, Lam, App), canonym, eval, normal, whnf) where
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import Control.Applicative (liftA2)
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import Control.Applicative (liftA2)
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import Control.Monad.Reader (Reader, runReader, ask, local, reader)
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import Control.Monad.Reader (Reader, runReader, ask, local, reader)
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import Data.Function (fix)
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import Data.Function (fix)
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import Data.Functor.Foldable (Base, Recursive, cata, embed)
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import Data.Functor.Foldable (Base, Recursive, cata, embed, project)
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import Data.Functor.Foldable.TH (makeBaseFunctor)
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import Data.Functor.Foldable.TH (makeBaseFunctor)
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import Data.HashSet (HashSet, empty, singleton, union, member, delete)
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import Data.List (findIndex)
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import Data.List (findIndex)
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import UntypedLambdaCalculus.Parser (Ast (AstVar, AstLam, AstApp), AstF (AstVarF, AstLamF, AstAppF))
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import UntypedLambdaCalculus.Parser (Ast (AstVar, AstLam, AstApp), AstF (AstVarF, AstLamF, AstAppF))
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-- | Look up a recursion-schemes tutorial if you don't know what an Algebra means.
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-- | I use recursion-schemes in this project a lot.
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type Algebra f a = f a -> a
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type Algebra f a = f a -> a
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-- | A lambda calculus expression where variables are identified
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-- | by their distance from their binding site (De Bruijn indices).
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data Expr = Free String
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data Expr = Free String
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| Var Int
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| Var Int
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| Lam String Expr
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| Lam String Expr
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@ -19,7 +22,21 @@ data Expr = Free String
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makeBaseFunctor ''Expr
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makeBaseFunctor ''Expr
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instance Show Expr where
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show = cataReader alg []
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where alg :: Algebra ExprF (Reader [String] String)
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alg (FreeF v) = return v
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alg (VarF v) = reader (\vars -> vars !! v ++ ':' : show v)
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alg (LamF v e) = do
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body <- local (v :) e
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return $ "(\\" ++ v ++ ". " ++ body ++ ")"
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alg (AppF f' x') = do
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f <- f'
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x <- x'
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return $ "(" ++ f ++ " " ++ x ++ ")"
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-- | Recursively reduce a `t` into an `a` when inner reductions are dependent on outer context.
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-- | Recursively reduce a `t` into an `a` when inner reductions are dependent on outer context.
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-- | In other words, data flows outside-in, reductions flow inside-out.
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cataReader :: Recursive t => Algebra (Base t) (Reader s a) -> s -> t -> a
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cataReader :: Recursive t => Algebra (Base t) (Reader s a) -> s -> t -> a
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cataReader alg s x = runReader (cata alg x) s
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cataReader alg s x = runReader (cata alg x) s
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@ -33,74 +50,81 @@ unbound = cataReader alg 0
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alg (AppF f x) = (&&) <$> f <*> x
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alg (AppF f x) = (&&) <$> f <*> x
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alg (LamF _ e) = local (+ 1) e
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alg (LamF _ e) = local (+ 1) e
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eval :: [Expr] -> Expr -> Expr
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-- | Convert an Ast into an Expression where all variables have canonical, unique names.
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eval env (Var v) = env !! v
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-- | Namely, bound variables are identified according to their distance from their binding site
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eval env (App f' x') = case f of
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-- | (i.e. De Bruijn indices).
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Lam _ e -> eval (x : env) e
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_ -> App f x
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where f = eval env f'
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x = eval env x'
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eval env o@(Lam _ (App f (Var 0)))
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| unbound f = eval (undefined : env) f
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| otherwise = o
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eval env x = runReader (substExpr x) env
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free :: Ast -> HashSet String
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free = cata alg
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where alg :: Algebra AstF (HashSet String)
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alg (AstVarF x) = singleton x
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alg (AstLamF x m) = delete x m
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alg (AstAppF m n) = m `union` n
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canonym :: Ast -> Expr
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canonym :: Ast -> Expr
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canonym = cataReader alg []
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canonym = cataReader alg []
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where alg :: Algebra AstF (Reader [String] Expr)
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where alg :: Algebra AstF (Reader [String] Expr)
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alg (AstVarF v) = maybe (Free v) Var <$> findIndex (== v) <$> ask
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alg (AstVarF v) = maybe (Free v) Var <$> findIndex (== v) <$> ask
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alg (AstLamF v e') = Lam v <$> local (v :) e'
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alg (AstLamF v e) = Lam v <$> local (v :) e
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alg (AstAppF n m) = App <$> n <*> m
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alg (AstAppF n m) = App <$> n <*> m
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rename :: String -> HashSet String -> String
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rename var free
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-- Continue prepending `_` until the name is free.
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| var `member` free = rename newVar free
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| otherwise = var
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where newVar = '_' : var
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subst :: String -> Ast -> Ast -> Ast
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subst var n o@(AstVar var')
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| var == var' = n
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| otherwise = o
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subst var n (AstApp m1 m2) = AstApp (subst var n m1) (subst var n m2)
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subst var n o@(AstLam var' m)
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| var == var' = o
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-- Alpha-convert as necessary, and then substitute into the body.
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| otherwise = AstLam newVar $ subst var n $ subst var' (AstVar newVar) m
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where newVar = rename var' $ free n
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instance Show Expr where
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-- | When we bind a new variable, we enter a new scope.
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show = cataReader alg []
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-- | Since variables are identified by their distance from their binder,
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where alg :: Algebra ExprF (Reader [String] String)
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-- | we must increment them to account for the incremented distance.
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alg (FreeF v) = return v
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{-introduceBindingInExpr :: Expr -> Expr
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alg (VarF v) = reader (\vars -> vars !! v ++ show v)
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introduceBindingInExpr = cataReader alg 0
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alg (LamF v e) = do
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where alg :: Algebra ExprF (Reader Int Expr)
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body <- local (v :) e
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alg (VarF v) = reader $ \x ->
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return $ "(\\" ++ v ++ ". " ++ body ++ ")"
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if v > x then Var $ v + 1 else Var v
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alg (AppF f' x') = do
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alg (LamF v e) = Lam v <$> local (+ 1) e
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f <- f'
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alg (AppF f x) = App <$> f <*> x
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x <- x'
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alg (FreeF v) = return $ Free v-}
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return $ "(" ++ f ++ " " ++ x ++ ")"
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introduceBindingInExpr :: Expr -> Expr
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introduceBindingInExpr (Var v) = Var $ v + 1
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introduceBindingInExpr o@(Lam _ _) = o
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introduceBindingInExpr x = embed $ fmap introduceBindingInExpr $ project x
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type Eval' = Expr -> Reader [Expr] Expr
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introduceBinding :: Expr -> Reader [Expr] a -> Reader [Expr] a
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introduceBinding x = local (\exprs -> x : map introduceBindingInExpr exprs)
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incrementVars :: Expr -> Expr
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intoBinding :: Reader [Expr] a -> Reader [Expr] a
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incrementVars = cata alg
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intoBinding = introduceBinding (Var 0)
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where alg (VarF x) = Var $ x + 1
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alg x = embed x
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substExpr :: Eval'
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intoEta :: Reader [Expr] a -> Reader [Expr] a
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substExpr = cata alg
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intoEta = introduceBinding undefined
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-- | Substitute all bound variables in an expression for their values,
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-- | without performing any further evaluation.
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subst :: Expr -> Reader [Expr] Expr
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subst = cata alg
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where alg :: Algebra ExprF (Reader [Expr] Expr)
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where alg :: Algebra ExprF (Reader [Expr] Expr)
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alg (VarF v) = reader (!! v)
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alg (VarF v) = reader (!! v)
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alg (AppF f x) = App <$> f <*> x
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alg (AppF f x) = App <$> f <*> x
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alg (FreeF x) = return $ Free x
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alg (FreeF x) = return $ Free x
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alg (LamF v e) = Lam v <$> local (\exprs -> Var 0 : map incrementVars exprs) e
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-- In a lambda expression, we substitute the parameter with itself.
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-- The rest of the substitutions may reference variables outside this binding,
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-- so that (Var 0) would refer not to this lambda, but the lambda outside it.
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-- Thus, we must increment all variables in the expression to be substituted in.
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alg (LamF v e) = Lam v <$> intoBinding e
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-- | Evaluate a variable to normal form.
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eval :: Expr -> Expr
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eval expr = runReader (eval' expr) []
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where eval' (App f' x') = do
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f <- eval' f'
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x <- eval' x'
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case f of
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Lam _ e -> introduceBinding x $ eval' e
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_ -> return $ App f x
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eval' o@(Lam _ (App f (Var 0)))
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| unbound f = intoEta $ eval' f
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| otherwise = subst o
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eval' x = subst x
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-- | Is an expression in normal form?
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normal :: Expr -> Bool
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normal (App (Lam _ _) _) = False
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normal (Lam _ (App f (Var 0))) = unbound f
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normal (App f x) = normal f && normal x
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normal _ = True
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-- | Is an expression in weak head normal form?
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whnf :: Expr -> Bool
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whnf (App (Lam _ _) _) = False
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whnf (Lam _ (App f (Var 0))) = unbound f
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whnf (App f _) = whnf f
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whnf _ = True
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@ -10,6 +10,7 @@ import Data.List (foldl1')
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import Text.Parsec
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import Text.Parsec
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import Text.Parsec.String
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import Text.Parsec.String
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-- | The abstract syntax tree of lambda calculus.
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data Ast = AstVar String
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data Ast = AstVar String
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| AstLam String Ast
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| AstLam String Ast
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| AstApp Ast Ast
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| AstApp Ast Ast
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alg (AstLamF v e) = "(\\" ++ v ++ ". " ++ e ++ ")"
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alg (AstLamF v e) = "(\\" ++ v ++ ". " ++ e ++ ")"
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alg (AstAppF f x) = "(" ++ f ++ " " ++ x ++ ")"
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alg (AstAppF f x) = "(" ++ f ++ " " ++ x ++ ")"
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-- | A variable name.
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name :: Parser String
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name :: Parser String
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name = do
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name = do
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c <- letter
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c <- letter
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cs <- many alphaNum
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cs <- many alphaNum
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return $ c : cs
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return $ c : cs
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-- | A variable expression.
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var :: Parser Ast
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var :: Parser Ast
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var = AstVar <$> name
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var = AstVar <$> name
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-- | Run parser between parentheses.
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parens :: Parser a -> Parser a
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parens :: Parser a -> Parser a
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parens = between (char '(') (char ')')
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parens = between (char '(') (char ')')
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-- | A lambda expression.
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lam :: Parser Ast
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lam :: Parser Ast
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lam = do
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lam = do
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char '\\'
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char '\\'
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@ -43,8 +48,17 @@ lam = do
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body <- expr
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body <- expr
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return $ foldr AstLam body vars
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return $ foldr AstLam body vars
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safeExpr :: Parser Ast
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-- | An application expression.
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safeExpr = var <|> parens (lam <|> expr)
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app :: Parser Ast
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app = foldl1' AstApp <$> sepBy1 safeExpr spaces
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-- | An expression, but where applications must be surrounded by parentheses,
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-- | to avoid ambiguity (infinite recursion on `app` in the case where the first
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-- | expression in the application is also an `app`, consuming no input).
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safeExpr :: Parser Ast
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safeExpr = var <|> lam <|> parens (lam <|> app)
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-- | Since applications do not require parentheses and can contain only a single item,
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-- | the `app` parser is sufficient to parse any expression at all.
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expr :: Parser Ast
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expr :: Parser Ast
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expr = foldl1' AstApp <$> sepBy1 safeExpr spaces
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expr = app
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