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1 {-# LANGUAGE FlexibleContexts #-}
2 {-# LANGUAGE FlexibleInstances #-}
3 {-# LANGUAGE MultiParamTypeClasses #-}
4 {-# LANGUAGE NoImplicitPrelude #-}
5 {-# LANGUAGE TypeFamilies #-}
6 {-# LANGUAGE UndecidableInstances #-}
7 -- | Interpreter to duplicate the representation of an expression
8 -- in order to evaluate it with different interpreters.
9 --
10 -- NOTE: this is a more verbose, less clear,
11 -- and maybe less efficient alternative
12 -- to maintaining the universal polymorphism of @repr@ at parsing time
13 -- as done with 'Forall_Repr_with_Context';
14 -- it is mainly here for the sake of curiosity.
15 module Language.Symantic.Repr.Dup where
16
17 import Data.Foldable (foldr)
18
19 import Language.Symantic.Expr
20
21 -- | Interpreter's data.
22 data Dup repr1 repr2 a
23 = Dup
24 { dup1 :: repr1 a
25 , dup2 :: repr2 a
26 }
27
28 instance -- Sym_Bool
29 ( Sym_Bool r1
30 , Sym_Bool r2
31 ) => Sym_Bool (Dup r1 r2) where
32 bool x = bool x `Dup` bool x
33 not (x1 `Dup` x2) = not x1 `Dup` not x2
34 (&&) (x1 `Dup` x2) (y1 `Dup` y2) = (&&) x1 y1 `Dup` (&&) x2 y2
35 (||) (x1 `Dup` x2) (y1 `Dup` y2) = (||) x1 y1 `Dup` (||) x2 y2
36 xor (x1 `Dup` x2) (y1 `Dup` y2) = xor x1 y1 `Dup` xor x2 y2
37 instance -- Sym_Int
38 ( Sym_Int r1
39 , Sym_Int r2
40 ) => Sym_Int (Dup r1 r2) where
41 int x = int x `Dup` int x
42 abs (x1 `Dup` x2) = abs x1 `Dup` abs x2
43 negate (x1 `Dup` x2) = negate x1 `Dup` negate x2
44 (+) (x1 `Dup` x2) (y1 `Dup` y2) = (+) x1 y1 `Dup` (+) x2 y2
45 (-) (x1 `Dup` x2) (y1 `Dup` y2) = (-) x1 y1 `Dup` (-) x2 y2
46 (*) (x1 `Dup` x2) (y1 `Dup` y2) = (*) x1 y1 `Dup` (*) x2 y2
47 mod (x1 `Dup` x2) (y1 `Dup` y2) = mod x1 y1 `Dup` mod x2 y2
48 instance -- Sym_Eq
49 ( Sym_Eq r1
50 , Sym_Eq r2
51 ) => Sym_Eq (Dup r1 r2) where
52 (==) (x1 `Dup` x2) (y1 `Dup` y2) = (==) x1 y1 `Dup` (==) x2 y2
53 instance -- Sym_Ord
54 ( Sym_Ord r1
55 , Sym_Ord r2
56 ) => Sym_Ord (Dup r1 r2) where
57 compare (x1 `Dup` x2) (y1 `Dup` y2) =
58 compare x1 y1 `Dup` compare x2 y2
59 instance -- Sym_If
60 ( Sym_If r1
61 , Sym_If r2
62 ) => Sym_If (Dup r1 r2) where
63 if_ (c1 `Dup` c2) (ok1 `Dup` ok2) (ko1 `Dup` ko2) =
64 if_ c1 ok1 ko1 `Dup` if_ c2 ok2 ko2
65 instance -- Sym_When
66 ( Sym_When r1
67 , Sym_When r2
68 ) => Sym_When (Dup r1 r2) where
69 when (c1 `Dup` c2) (ok1 `Dup` ok2) =
70 when c1 ok1 `Dup` when c2 ok2
71 instance -- Sym_List
72 ( Sym_List r1
73 , Sym_List r2
74 ) => Sym_List (Dup r1 r2) where
75 list_empty = list_empty `Dup` list_empty
76 list_cons (a1 `Dup` a2) (l1 `Dup` l2) = list_cons a1 l1 `Dup` list_cons a2 l2
77 list l =
78 let (l1, l2) =
79 foldr (\(x1 `Dup` x2) (xs1, xs2) ->
80 (x1:xs1, x2:xs2)) ([], []) l in
81 list l1 `Dup` list l2
82 instance -- Sym_List_Lam
83 ( Sym_List_Lam lam r1
84 , Sym_List_Lam lam r2
85 ) => Sym_List_Lam lam (Dup r1 r2) where
86 list_filter (f1 `Dup` f2) (l1 `Dup` l2) =
87 list_filter f1 l1 `Dup` list_filter f2 l2
88 instance -- Sym_Maybe
89 ( Sym_Maybe r1
90 , Sym_Maybe r2
91 ) => Sym_Maybe (Dup r1 r2) where
92 nothing = nothing `Dup` nothing
93 just (a1 `Dup` a2) = just a1 `Dup` just a2
94 instance -- Sym_Maybe_Lam
95 ( Sym_Maybe_Lam lam r1
96 , Sym_Maybe_Lam lam r2
97 ) => Sym_Maybe_Lam lam (Dup r1 r2) where
98 maybe (m1 `Dup` m2) (n1 `Dup` n2) (j1 `Dup` j2) =
99 maybe m1 n1 j1 `Dup`
100 maybe m2 n2 j2
101 type instance Lambda_from_Repr (Dup r1 r2) = Lambda_from_Repr r1
102 instance -- Sym_Lambda_App
103 ( Sym_Lambda_App lam r1
104 , Sym_Lambda_App lam r2
105 ) => Sym_Lambda_App lam (Dup r1 r2) where
106 app (f1 `Dup` f2) (x1 `Dup` x2) = app f1 x1 `Dup` app f2 x2
107 instance -- Sym_Lambda_Inline
108 ( Sym_Lambda_Inline lam r1
109 , Sym_Lambda_Inline lam r2
110 ) => Sym_Lambda_Inline lam (Dup r1 r2) where
111 inline f = dup1 (inline f) `Dup` dup2 (inline f)
112 instance -- Sym_Lambda_Val
113 ( Sym_Lambda_Val lam r1
114 , Sym_Lambda_Val lam r2
115 ) => Sym_Lambda_Val lam (Dup r1 r2) where
116 val f = dup1 (val f) `Dup` dup2 (val f)
117 instance -- Sym_Lambda_Lazy
118 ( Sym_Lambda_Lazy lam r1
119 , Sym_Lambda_Lazy lam r2
120 ) => Sym_Lambda_Lazy lam (Dup r1 r2) where
121 lazy f = dup1 (lazy f) `Dup` dup2 (lazy f)
122 instance -- Sym_Tuple2
123 ( Sym_Tuple2 r1
124 , Sym_Tuple2 r2
125 ) => Sym_Tuple2 (Dup r1 r2) where
126 tuple2 (a1 `Dup` a2) (b1 `Dup` b2) =
127 tuple2 a1 b1 `Dup` tuple2 a2 b2
128 instance -- Sym_Map
129 ( Sym_Map r1
130 , Sym_Map r2
131 ) => Sym_Map (Dup r1 r2) where
132 map_from_list (l1 `Dup` l2) =
133 map_from_list l1 `Dup` map_from_list l2
134 instance -- Sym_Map_Lam
135 ( Sym_Map_Lam lam r1
136 , Sym_Map_Lam lam r2
137 ) => Sym_Map_Lam lam (Dup r1 r2) where
138 map_map (f1 `Dup` f2) (m1 `Dup` m2) =
139 map_map f1 m1 `Dup` map_map f2 m2
140 instance -- Sym_Functor
141 ( Sym_Functor lam r1
142 , Sym_Functor lam r2
143 ) => Sym_Functor lam (Dup r1 r2) where
144 fmap (f1 `Dup` f2) (m1 `Dup` m2) =
145 fmap f1 m1 `Dup` fmap f2 m2
146 instance -- Sym_Applicative
147 ( Sym_Applicative r1
148 , Sym_Applicative r2
149 , Sym_Applicative_Lam (Lambda_from_Repr r1) (Dup r1 r2)
150 ) => Sym_Applicative (Dup r1 r2) where
151 pure (a1 `Dup` a2) =
152 pure a1 `Dup` pure a2
153 instance -- Sym_Applicative_Lam
154 ( Sym_Applicative_Lam lam r1
155 , Sym_Applicative_Lam lam r2
156 ) => Sym_Applicative_Lam lam (Dup r1 r2) where
157 (<*>) (f1 `Dup` f2) (m1 `Dup` m2) =
158 (<*>) f1 m1 `Dup` (<*>) f2 m2
159 instance -- Sym_Traversable
160 ( Sym_Traversable lam r1
161 , Sym_Traversable lam r2
162 , lam ~ Lambda_from_Repr r1
163 ) => Sym_Traversable lam (Dup r1 r2) where
164 traverse (f1 `Dup` f2) (m1 `Dup` m2) =
165 traverse f1 m1 `Dup` traverse f2 m2
166 instance -- Sym_Monad
167 ( Sym_Monad_Lam lam r1
168 , Sym_Monad_Lam lam r2
169 , lam ~ Lambda_from_Repr r1
170 ) => Sym_Monad_Lam lam (Dup r1 r2) where
171 (>>=) (m1 `Dup` m2) (f1 `Dup` f2) =
172 (>>=) m1 f1 `Dup` (>>=) m2 f2