1 {-# LANGUAGE DeriveFunctor #-}
3 {-# LANGUAGE GeneralizedNewtypeDeriving #-}
4 {-# LANGUAGE NoMonomorphismRestriction #-}
5 {-# LANGUAGE OverloadedStrings #-}
6 {-# LANGUAGE StandaloneDeriving #-}
7 {-# OPTIONS_GHC -fno-warn-tabs #-}
8 module Language.Symantic.Grammar.EBNF where
10 import Control.Applicative (Applicative(..))
12 import Data.Bool as Bool
13 import Data.Semigroup hiding (option)
14 import Data.String (IsString(..))
15 import Data.Text (Text)
16 import qualified Data.Text as Text
17 import Prelude hiding (any)
20 -- | Extended Backus-Naur-Form, following the
21 -- <http://standards.iso.org/ittf/PubliclyAvailableStandards/s026153_ISO_IEC_14977_1996(E).zip ISO-IEC-14977>
22 -- notations, augmented with the following notations:
24 -- * @("U+", code_point)@: for <http://unicode.org/versions/Unicode8.0.0/ ISO-IEC-10646> (aka. Unicode).
25 -- * @(char, "…", char)@: for character range.
26 -- * @(rule, "&", rule)@: for the intersection.
27 -- * @(rule, "-", rule)@: for the difference.
28 -- * @(rule, " ", rule)@: for rule application.
29 data EBNF a = EBNF { unEBNF :: RuleMode -> (Infix, LR) -> Text }
31 runEBNF :: EBNF a -> Text
32 runEBNF (EBNF g) = g RuleMode_Body (infixN0, L)
34 -- | Get textual rendition of given EBNF rule.
35 renderEBNF :: RuleDef a -> Text
36 renderEBNF = runEBNF . unRuleDef
38 ebnf_const :: Text -> EBNF a
39 ebnf_const t = EBNF $ \_rm _op -> t
41 -- * Class 'Gram_Rule'
43 class Gram_Rule g where
44 rule :: Text -> Id (g a)
46 rule1 :: Text -> Id (g a -> g b)
48 rule2 :: Text -> Id (g a -> g b -> g c)
50 rule3 :: Text -> Id (g a -> g b -> g c -> g d)
52 rule4 :: Text -> Id (g a -> g b -> g c -> g d -> g e)
57 = RuleMode_Body -- ^ Generate the body of the rule.
58 | RuleMode_Ref -- ^ Generate a ref to the rule.
62 newtype RuleDef a = RuleDef { unRuleDef :: EBNF a }
63 deriving (Functor, Applicative)
64 deriving instance Gram_RuleDef RuleDef
65 deriving instance Try RuleDef
66 instance Gram_Rule RuleDef where
67 rule n = rule_def (ebnf_const n)
68 rule1 n g a = rule_def (ebnf_const n `ebnf_arg` unRuleDef a) (g a)
69 rule2 n g a b = rule_def (ebnf_const n `ebnf_arg` unRuleDef a `ebnf_arg` unRuleDef b) (g a b)
70 rule3 n g a b c = rule_def (ebnf_const n `ebnf_arg` unRuleDef a `ebnf_arg` unRuleDef b `ebnf_arg` unRuleDef c) (g a b c)
71 rule4 n g a b c d = rule_def (ebnf_const n `ebnf_arg` unRuleDef a `ebnf_arg` unRuleDef b `ebnf_arg` unRuleDef c `ebnf_arg` unRuleDef d) (g a b c d)
73 -- *** Class 'Gram_RuleDef'
74 class Gram_RuleDef g where
75 rule_def :: EBNF () -> g a -> RuleDef a
76 rule_arg :: Text -> g a
77 instance Show (EBNF a) where
78 show = Text.unpack . runEBNF
79 instance Functor EBNF where
80 fmap _f (EBNF x) = EBNF x
81 instance Applicative EBNF where
82 pure _ = ebnf_const $ "\"\""
83 EBNF f <*> EBNF x = EBNF $ \bo po -> infix_paren po op $
84 f bo (op, L) <> ", " <> x bo (op, R)
85 where op = infixB L 10
86 instance Gram_Rule EBNF where
87 rule n g = EBNF $ \rm po ->
89 RuleMode_Body -> unEBNF g RuleMode_Ref po
91 rule1 n g a = EBNF $ \rm po ->
93 RuleMode_Body -> unEBNF (g a) RuleMode_Ref po
94 RuleMode_Ref -> unEBNF (ebnf_const n `ebnf_arg` a) RuleMode_Ref po
95 rule2 n g a b = EBNF $ \rm po ->
97 RuleMode_Body -> unEBNF (g a b) RuleMode_Ref po
98 RuleMode_Ref -> unEBNF (ebnf_const n `ebnf_arg` a `ebnf_arg` b) RuleMode_Ref po
99 rule3 n g a b c = EBNF $ \rm po ->
101 RuleMode_Body -> unEBNF (g a b c) RuleMode_Ref po
102 RuleMode_Ref -> unEBNF (ebnf_const n `ebnf_arg` a `ebnf_arg` b `ebnf_arg` c) RuleMode_Ref po
103 rule4 n g a b c d = EBNF $ \rm po ->
105 RuleMode_Body -> unEBNF (g a b c d) RuleMode_Ref po
106 RuleMode_Ref -> unEBNF (ebnf_const n `ebnf_arg` a `ebnf_arg` b `ebnf_arg` c `ebnf_arg` d) RuleMode_Ref po
107 instance Gram_RuleDef EBNF where
108 rule_arg = ebnf_const
110 RuleDef $ EBNF $ \mo po ->
112 RuleMode_Ref -> unEBNF call mo po
115 [ unEBNF call RuleMode_Ref (infixN0, L)
117 , unEBNF body RuleMode_Ref (infixN0, R)
121 -- | Helper for 'Gram_Rule' 'EBNF'.
122 ebnf_arg :: EBNF a -> EBNF b -> EBNF ()
123 ebnf_arg (EBNF a) (EBNF b) = EBNF $ \bo po -> infix_paren po op $
124 a bo (op, L) <> " " <> b bo (op, R)
128 -- ** Type 'Precedence'
129 type Precedence = Int
131 -- ** Type 'Associativity'
132 -- type Associativity = LR
134 = AssocL -- ^ Associate to the left: @a ¹ b ² c == (a ¹ b) ² c@
135 | AssocR -- ^ Associate to the right: @a ¹ b ² c == a ¹ (b ² c)@
136 | AssocB LR -- ^ Associate to both side, but to 'LR' when reading.
142 { infix_assoc :: Maybe Associativity
143 , infix_prece :: Precedence
144 } deriving (Eq, Show)
146 infixL :: Precedence -> Infix
147 infixL = Infix (Just AssocL)
149 infixR :: Precedence -> Infix
150 infixR = Infix (Just AssocR)
152 infixB :: LR -> Precedence -> Infix
153 infixB = Infix . Just . AssocB
155 infixN :: Precedence -> Infix
156 infixN = Infix Nothing
165 :: (Semigroup s, IsString s)
166 => (Infix, LR) -> Infix -> s -> s
167 infix_paren (po, lr) op s =
168 if infix_prece op < infix_prece po
169 || infix_prece op == infix_prece po
170 && Bool.not associate
171 then fromString "(" <> s <> fromString ")"
175 case (lr, infix_assoc po) of
176 (_, Just AssocB{}) -> True
177 (L, Just AssocL) -> True
178 (R, Just AssocR) -> True
190 instance Try EBNF where