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[haskell/symantic.git] / Language / Symantic / Expr / Lambda.hs
1 {-# LANGUAGE DefaultSignatures #-}
2 {-# LANGUAGE DataKinds #-}
3 {-# LANGUAGE FlexibleContexts #-}
4 {-# LANGUAGE FlexibleInstances #-}
5 {-# LANGUAGE MultiParamTypeClasses #-}
6 {-# LANGUAGE Rank2Types #-}
7 {-# LANGUAGE ScopedTypeVariables #-}
8 {-# LANGUAGE TypeFamilies #-}
9 {-# LANGUAGE TypeOperators #-}
10 -- | Expression for /lambda abstraction/s
11 -- in /Higher-Order Abstract Syntax/ (HOAS).
12 module Language.Symantic.Expr.Lambda where
13
14 import Data.Proxy (Proxy(..))
15 import Data.Type.Equality ((:~:)(Refl))
16 import Data.Text (Text)
17
18 import Language.Symantic.Type
19 import Language.Symantic.Expr.Root
20 import Language.Symantic.Expr.Error
21 import Language.Symantic.Expr.From
22 import Language.Symantic.Trans.Common
23
24 -- * Class 'Lambda_from_Repr'
25 -- | This type constructor is used like
26 -- the functional dependency: @repr -> lam@
27 -- (ie. knowing @repr@ one can determine @lam@)
28 -- in order to avoid to introduce a 'Proxy' @lam@
29 -- in 'let_inline', 'let_val' and 'let_lazy'.
30 --
31 -- Distinguishing between @lam@ and @repr@ is used to maintain
32 -- the universal polymorphism of @repr@ in 'Expr_from';
33 -- a downside of this approach is
34 -- that to be an instance of 'Sym_Lambda' for all @lam@,
35 -- the @repr@ type of an interpreter
36 -- has to be parameterized by @lam@,
37 -- even when it does not actually need @lam@ to do its work
38 -- (eg. 'Repr_Text').
39 --
40 -- Basically this means having sometimes to add a type annotation
41 -- to the interpreter call to specify @lam@.
42 --
43 -- FIXME: 'lazy' requires @lam@ to contain 'IO',
44 -- which is not escapable (there is no safe function: @IO a -> a@),
45 -- this is problematic when writing 'Repr_Host' instances
46 -- where 'app'lying an object-function on the elements of a 'Functor'
47 -- return a value wrapped inside @lam@, which is then not unwrappable
48 -- as needed to write the instance.
49 -- I think the way to solve this is to require all object-values
50 -- to be wrapped inside @lam@.
51 type family Lambda_from_Repr (repr:: * -> *) :: {-lam-}(* -> *)
52
53 -- * Class 'Sym_Lambda_App'
54 -- | Symantic.
55 class (lam ~ Lambda_from_Repr repr) => Sym_Lambda_App lam repr where
56 -- | /Lambda application/.
57 app :: repr (Lambda lam arg res) -> repr arg -> repr res
58 default app :: Trans t repr => t repr (Lambda lam arg res) -> t repr arg -> t repr res
59 app f x = trans_lift $ trans_apply f `app` trans_apply x
60 infixl 5 `app`
61 -- * Class 'Sym_Lambda_Inline'
62 -- | Symantic.
63 class (lam ~ Lambda_from_Repr repr, Sym_Lambda_App lam repr) => Sym_Lambda_Inline lam repr where
64 -- | /Call-by-name/ /lambda abstraction/.
65 inline :: (repr arg -> repr res) -> repr (Lambda lam arg res)
66 default inline :: Trans t repr => (t repr arg -> t repr res) -> t repr (Lambda lam arg res)
67 inline f = trans_lift $ inline $ trans_apply . f . trans_lift
68
69 -- | Convenient 'inline' wrapper.
70 let_inline
71 :: Sym_Lambda_Inline lam repr
72 => repr var -> (repr var -> repr res) -> repr res
73 let_inline x y = inline y `app` x
74 -- * Class 'Sym_Lambda_Val'
75 -- | Symantic.
76 class (lam ~ Lambda_from_Repr repr, Sym_Lambda_App lam repr) => Sym_Lambda_Val lam repr where
77 -- | /Call-by-value/ /lambda abstraction/.
78 val :: (repr arg -> repr res) -> repr (Lambda lam arg res)
79 default val :: Trans t repr => (t repr arg -> t repr res) -> t repr (Lambda lam arg res)
80 val f = trans_lift $ val $ trans_apply . f . trans_lift
81
82 -- | Convenient 'val' wrapper.
83 let_val
84 :: Sym_Lambda_Val lam repr
85 => repr var -> (repr var -> repr res) -> repr res
86 let_val x y = val y `app` x
87 -- * Class 'Sym_Lambda_Lazy'
88 -- | Symantic.
89 class (lam ~ Lambda_from_Repr repr, Sym_Lambda_App lam repr) => Sym_Lambda_Lazy lam repr where
90 -- | /Call-by-need/ /lambda abstraction/ (aka. /lazyness/): lazy shares its argument, no matter what.
91 lazy :: (repr arg -> repr res) -> repr (Lambda lam arg res)
92 default lazy :: Trans t repr => (t repr arg -> t repr res) -> t repr (Lambda lam arg res)
93 lazy f = trans_lift $ lazy $ trans_apply . f . trans_lift
94
95 -- | Convenient 'lazy' wrapper.
96 let_lazy
97 :: Sym_Lambda_Lazy lam repr
98 => repr var -> (repr var -> repr res) -> repr res
99 let_lazy x y = lazy y `app` x
100
101 -- * Type 'Expr_Lambda_App'
102 -- | Expression.
103 data Expr_Lambda_App (lam:: * -> *) (root:: *)
104 type instance Root_of_Expr (Expr_Lambda_App lam root) = root
105 type instance Type_of_Expr (Expr_Lambda_App lam root) = Type_Fun lam
106 type instance Sym_of_Expr (Expr_Lambda_App lam root) repr = Sym_Lambda_App lam repr
107 type instance Error_of_Expr ast (Expr_Lambda_App lam root) = Error_Expr_Lambda ast
108
109 -- * Type 'Expr_Lambda_Inline'
110 -- | Expression.
111 data Expr_Lambda_Inline (lam:: * -> *) (root:: *)
112 type instance Root_of_Expr (Expr_Lambda_Inline lam root) = root
113 type instance Type_of_Expr (Expr_Lambda_Inline lam root) = No_Type
114 type instance Sym_of_Expr (Expr_Lambda_Inline lam root) repr = Sym_Lambda_Inline lam repr
115 type instance Error_of_Expr ast (Expr_Lambda_Inline lam root) = No_Error_Expr
116
117 -- * Type 'Expr_Lambda_Val'
118 -- | Expression.
119 data Expr_Lambda_Val (lam:: * -> *) (root:: *)
120 type instance Root_of_Expr (Expr_Lambda_Val lam root) = root
121 type instance Type_of_Expr (Expr_Lambda_Val lam root) = No_Type
122 type instance Sym_of_Expr (Expr_Lambda_Val lam root) repr = Sym_Lambda_Val lam repr
123 type instance Error_of_Expr ast (Expr_Lambda_Val lam root) = No_Error_Expr
124
125 -- * Type 'Expr_Lambda_Lazy'
126 -- | Expression.
127 data Expr_Lambda_Lazy (lam:: * -> *) (root:: *)
128 type instance Root_of_Expr (Expr_Lambda_Lazy lam root) = root
129 type instance Type_of_Expr (Expr_Lambda_Lazy lam root) = No_Type
130 type instance Sym_of_Expr (Expr_Lambda_Lazy lam root) repr = Sym_Lambda_Lazy lam repr
131 type instance Error_of_Expr ast (Expr_Lambda_Lazy lam root) = No_Error_Expr
132
133 -- | Parsing utility to check that the given type is a 'Type_Fun'
134 -- or raise 'Error_Expr_Type_mismatch'.
135 check_type_fun
136 :: forall ast ex root lam ty h ret.
137 ( root ~ Root_of_Expr ex
138 , ty ~ Type_Root_of_Expr ex
139 , Lift_Type (Type_Fun lam) (Type_of_Expr root)
140 , Unlift_Type (Type_Fun lam) (Type_of_Expr root)
141 , Lift_Error_Expr (Error_Expr (Error_of_Type ast ty) ty ast)
142 (Error_of_Expr ast root)
143 )
144 => Proxy ex -> ast -> ty h
145 -> (Type_Fun lam ty h -> Either (Error_of_Expr ast root) ret)
146 -> Either (Error_of_Expr ast root) ret
147 check_type_fun ex ast ty k =
148 case unlift_type $ unType_Root ty of
149 Just ty_f -> k ty_f
150 Nothing -> Left $
151 error_expr ex $
152 Error_Expr_Type_mismatch ast
153 (Exists_Type (type_var0 SZero `type_fun` type_var0 (SSucc SZero)
154 :: Type_Root_of_Expr ex (Lambda lam Var0 Var0)))
155 (Exists_Type ty)
156
157 -- | Parse a /lambda variable/.
158 var_from
159 :: forall ast lam root hs ret.
160 ( Type_from ast (Type_Root_of_Expr root)
161 , Lift_Error_Expr (Error_Expr_Lambda ast)
162 (Error_of_Expr ast root)
163 , Root_of_Expr root ~ root
164 ) => Text -> Expr_From ast (Expr_Lambda_App lam root) hs ret
165 var_from name _ex ast = go
166 where
167 go :: forall ex hs'. (ex ~ (Expr_Lambda_App lam root))
168 => Context (Lambda_Var (Type_Root_of_Expr ex)) hs'
169 -> ( forall h. Type_Root_of_Expr ex h
170 -> Forall_Repr_with_Context ex hs' h
171 -> Either (Error_of_Expr ast (Root_of_Expr ex)) ret )
172 -> Either (Error_of_Expr ast (Root_of_Expr ex)) ret
173 go c k' =
174 case c of
175 Context_Empty -> Left $ lift_error_expr $
176 Error_Expr_Lambda_Var_unbound name ast
177 Lambda_Var n ty `Context_Next` _ | n == name ->
178 k' ty $ Forall_Repr_with_Context $
179 \(repr `Context_Next` _) -> repr
180 _ `Context_Next` ctx' ->
181 go ctx' $ \ty (Forall_Repr_with_Context repr) ->
182 k' ty $ Forall_Repr_with_Context $
183 \(_ `Context_Next` c') -> repr c'
184
185 -- | Parse 'app'.
186 app_from
187 :: forall ty ast lam root hs ret.
188 ( ty ~ Type_Root_of_Expr root
189 , Type_from ast ty
190 , Eq_Type ty
191 , Expr_from ast root
192 , Lift_Type_Root (Type_Fun lam) ty
193 , Lift_Error_Expr (Error_Expr (Error_of_Type ast ty) ty ast)
194 (Error_of_Expr ast root)
195 , Unlift_Type (Type_Fun lam) (Type_of_Expr root)
196 , Root_of_Expr root ~ root
197 ) => ast -> ast
198 -> Expr_From ast (Expr_Lambda_App lam root) hs ret
199 app_from ast_lam ast_arg_actual ex ast ctx k =
200 expr_from (Proxy::Proxy root) ast_lam ctx $
201 \(ty_lam::Type_Root_of_Expr root h_lam) (Forall_Repr_with_Context lam) ->
202 expr_from (Proxy::Proxy root) ast_arg_actual ctx $
203 \(ty_arg_actual::Type_Root_of_Expr root h_arg_actual)
204 (Forall_Repr_with_Context arg_actual) ->
205 case unlift_type $ unType_Root ty_lam of
206 Nothing -> Left $
207 error_expr ex $
208 Error_Expr_Type_mismatch ast
209 (Exists_Type (type_var0 SZero `type_fun` type_var0 (SSucc SZero)
210 :: Type_Root_of_Expr (Expr_Lambda_App lam root) (Lambda lam Var0 Var0)))
211 (Exists_Type ty_lam)
212 Just (Type_Type2 Proxy ty_arg_expected ty_res
213 :: Type_Fun lam (Type_Root_of_Expr root) h_lam) ->
214 check_eq_type ex ast
215 ty_arg_expected ty_arg_actual $ \Refl ->
216 k ty_res $ Forall_Repr_with_Context $
217 \c -> lam c `app` arg_actual c
218
219 -- | Parse given /lambda abstraction/.
220 lam_from
221 :: forall ty ast (lam:: * -> *) root hs ret ex.
222 ( ty ~ Type_Root_of_Expr root
223 , root ~ Root_of_Expr ex
224 , root ~ Root_of_Expr root
225 , Type_from ast ty
226 , Expr_from ast root
227 , Lift_Type_Root (Type_Fun lam) ty
228 , Lift_Error_Expr (Error_Expr (Error_of_Type ast ty) ty ast)
229 (Error_of_Expr ast root)
230 ) => Proxy lam
231 -> (forall repr arg res
232 . Sym_of_Expr ex repr
233 => (repr arg -> repr res)
234 -> repr (Lambda lam arg res))
235 -> Text -> ast -> ast
236 -> Expr_From ast ex hs ret
237 lam_from _ lam name ast_ty_arg ast_body ex ast ctx k =
238 case type_from
239 (Proxy::Proxy (Type_Root_of_Expr root))
240 ast_ty_arg (Right . Exists_Type) of
241 Left err -> Left $ error_expr ex $ Error_Expr_Type err ast
242 Right (Exists_Type (ty_arg::Type_Root_of_Expr root h_arg)) ->
243 expr_from (Proxy::Proxy root) ast_body
244 (Lambda_Var name ty_arg `Context_Next` ctx) $
245 \(ty_res::Type_Root_of_Expr root h_res) (Forall_Repr_with_Context res) ->
246 k (ty_arg `type_fun` ty_res
247 :: Root_of_Type (Type_Root_of_Expr root)
248 (Lambda lam h_arg h_res)) $
249 Forall_Repr_with_Context $
250 \c -> lam $
251 \arg -> res (arg `Context_Next` c)
252
253 -- | Parse given /let/.
254 let_from
255 :: forall ty ast root hs ret ex.
256 ( ty ~ Type_Root_of_Expr root
257 , root ~ Root_of_Expr ex
258 , root ~ Root_of_Expr root
259 , Type_from ast ty
260 , Expr_from ast root
261 -- , Lift_Type_Root (Type_Fun lam) ty
262 , Lift_Error_Expr (Error_Expr (Error_of_Type ast ty) ty ast)
263 (Error_of_Expr ast root)
264 ) => (forall repr var res. Sym_of_Expr ex repr
265 => repr var -> (repr var -> repr res) -> repr res)
266 -> Text -> ast -> ast
267 -> Expr_From ast ex hs ret
268 let_from let_ name ast_var ast_body _ex _ast ctx k =
269 expr_from (Proxy::Proxy root) ast_var ctx $
270 \(ty_var::Type_Root_of_Expr root h_var) (Forall_Repr_with_Context var) ->
271 expr_from (Proxy::Proxy root) ast_body
272 (Lambda_Var name ty_var `Context_Next` ctx) $
273 \(ty_res::Type_Root_of_Expr root h_res) (Forall_Repr_with_Context res) ->
274 k ty_res $ Forall_Repr_with_Context $
275 \c -> let_ (var c) $
276 \arg -> res (arg `Context_Next` c)
277
278 -- * Type 'Error_Expr_Lambda'
279 data Error_Expr_Lambda ast
280 = Error_Expr_Lambda_Var_unbound Lambda_Var_Name ast
281 deriving (Eq, Show)