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Add plain Text rendering (fixup).
[doclang.git] / Language / TCT / Read / Token.hs
1 {-# LANGUAGE FlexibleContexts #-}
2 {-# LANGUAGE OverloadedStrings #-}
3 {-# LANGUAGE Rank2Types #-}
4 {-# LANGUAGE TypeFamilies #-}
5 module Language.TCT.Read.Token where
6
7 import Control.Applicative (Applicative(..), Alternative(..))
8 import Control.Monad (Monad(..))
9 import Data.Bool
10 import Data.Char (Char)
11 import Data.Eq (Eq(..))
12 import Data.Foldable (Foldable(..))
13 import Data.Function (($), (.), flip)
14 import Data.Functor ((<$>), ($>), (<$))
15 import Data.Maybe (Maybe(..), fromMaybe)
16 import Data.Monoid (Monoid(..))
17 import Data.Semigroup (Semigroup(..))
18 import Data.Sequence (ViewL(..), (<|))
19 import Data.Text (Text)
20 import Data.Text.Buildable (Buildable(..))
21 import Data.Tuple (fst,snd)
22 import Text.Show (Show(..))
23 import qualified Data.Char as Char
24 import qualified Data.Sequence as Seq
25 import qualified Data.Text as Text
26 import qualified Data.Text.Lazy as TL
27 import qualified Data.Text.Lazy.Builder as Builder
28 import qualified Text.Megaparsec as P
29
30 import Language.TCT.Token
31 import Language.TCT.Elem
32 import Language.TCT.Read.Elem -- hiding (pdbg)
33
34 -- pdbg m p = P.dbg m p
35
36 textOf :: Buildable a => a -> Text
37 textOf = TL.toStrict . Builder.toLazyText . build
38
39 -- * Type 'Pairs'
40 type Pairs = (Token,[(Pair,Token)])
41
42 openPair :: Pair -> Pairs -> Pairs
43 openPair g (t,ms) = (t,(g,mempty):ms)
44
45 insertToken :: Token -> Pairs -> Pairs
46 insertToken tok (t,[]) = (t<>tok,[])
47 insertToken tok (t,(g0,t0):gs) = (t,(g0,t0<>tok):gs)
48
49 -- | Close a 'Pair' when there is a matching 'LexemePairClose'.
50 closePair :: Pair -> Pairs -> Pairs
51 closePair g (t,[]) = dbg "closePair" $ (t<>TokenPlain (snd $ pairBorders g mempty),[])
52 closePair g (t,(g1,m1):ms) = dbg "closePair" $
53 case (g,g1) of
54 (PairElem x ax, PairElem y ay) | x == y ->
55 insertToken (TokenPair (PairElem x (ax<>ay)) m1) (t,ms)
56 (x,y) | x == y -> insertToken (TokenPair g1 m1) (t,ms)
57 _ ->
58 closePair g $
59 insertToken
60 (closelessPair mempty (g1,m1))
61 (t,ms)
62
63 -- | Close a 'Pair' when there is not a matching 'LexemePairClose'.
64 closelessPair :: Token -> (Pair,Token) -> Token
65 closelessPair acc (g,t) = dbg "closelessPair" $
66 case g of
67 -- NOTE: try to close 'PairHash' as 'TokenTag' instead of 'TokenPlain'.
68 PairHash | TokenPlain p :< toks <- Seq.viewl $ unTokens $ t <> acc ->
69 case Text.findIndex (not . isTagChar) p of
70 Just 0 -> TokenPlain (fst $ pairBorders g mempty) <> t <> acc
71 Just i -> Tokens $ TokenTag tag <| TokenPlain p' <| toks
72 where (tag,p') = Text.splitAt i p
73 Nothing -> Tokens $ TokenTag p <| toks
74 _ -> TokenPlain (fst $ pairBorders g mempty) <> t <> acc
75 where
76 isTagChar c =
77 Char.isAlphaNum c ||
78 c=='·' ||
79 case Char.generalCategory c of
80 Char.DashPunctuation -> True
81 Char.ConnectorPunctuation -> True
82 _ -> False
83
84 -- | Close remaining 'Pair's at end of parsing.
85 closePairs :: Pairs -> Token
86 closePairs (t0,gs) = dbg "closePairs" $
87 t0 <> foldl' closelessPair mempty gs
88
89 -- * Type 'Lexeme'
90 data Lexeme
91 = LexemePairOpen Pair
92 | LexemePairClose Pair
93 | LexemePunctOrSym Char
94 | LexemeWhite Text
95 | LexemeWord Text
96 | LexemeToken Token
97 | LexemeEscape Char
98 | LexemeLink Text
99 deriving (Show, Eq)
100
101 appendLexeme :: Lexeme -> Pairs -> Pairs
102 appendLexeme lex gs =
103 dbg "appendLexeme" $
104 case dbg "appendLexeme" lex of
105 LexemePairOpen g -> openPair g gs
106 LexemePairClose g -> closePair g gs
107 LexemePunctOrSym c -> insertToken (TokenPlain (Text.singleton c)) gs
108 LexemeWhite wh -> insertToken (TokenPlain wh) gs
109 LexemeWord wo -> insertToken (TokenPlain wo) gs
110 LexemeToken tok -> insertToken tok gs
111 LexemeEscape c -> insertToken (TokenEscape c) gs
112 LexemeLink lnk -> insertToken (TokenLink lnk) gs
113
114 appendLexemes :: Pairs -> [Lexeme] -> Pairs
115 appendLexemes = foldl' (flip appendLexeme)
116
117 -- * Parsers
118
119 p_Token :: Parser e s Token
120 p_Token = closePairs <$> p_Pairs (mempty,[])
121
122 p_Pairs :: Pairs -> Parser e s Pairs
123 p_Pairs gs = pdbg "Pairs" $
124 (p_Lexemes (mempty == gs) >>= p_Pairs . appendLexemes gs) <|>
125 (P.eof $> gs)
126
127 p_Lexemes :: Bool -> Parser e s [Lexeme]
128 p_Lexemes isBOF = pdbg "Lexemes" $
129 P.choice
130 [ P.try $ p_PairCloseWhite
131 , P.try $ p_PairWhiteOpen isBOF
132 , P.try $ p_PairCloseBorder
133 , P.try $ p_PairBorderOpen
134 , P.try $ p_PairClose
135 , P.try $ p_PairOpen
136 , P.try $ pure . LexemePunctOrSym <$> p_PunctOrSym
137 , P.try $ pure <$> p_White
138 , pure . LexemeWord <$> p_Word
139 ]
140
141 p_White :: Parser e s Lexeme
142 p_White = pdbg "White" $ LexemeWhite <$> p_Spaces
143
144 p_PunctOrSym :: Parser e s Char
145 p_PunctOrSym = P.satisfy $ \c ->
146 Char.isPunctuation c ||
147 Char.isSymbol c
148
149 p_PairCloseWhite :: Parser e s [Lexeme]
150 p_PairCloseWhite = pdbg "PairCloseWhite" $
151 (\c b -> mconcat c <> b)
152 <$> P.some (P.try p_PairClose <|> pure . LexemePunctOrSym <$> p_PunctOrSym)
153 <*> ((pure <$> p_White) <|> P.eof $> [])
154
155 p_PairWhiteOpen :: Bool -> Parser e s [Lexeme]
156 p_PairWhiteOpen isBOF = pdbg "PairWhiteOpen" $
157 (\b o -> b <> mconcat o)
158 <$> (if isBOF then return [] else pure <$> p_White)
159 <*> P.some (P.try p_PairOpen <|> pure . LexemePunctOrSym <$> p_PunctOrSym)
160
161 p_PairCloseBorder :: Parser e s [Lexeme]
162 p_PairCloseBorder = pdbg "PairCloseBorder" $
163 P.try p0 <|> p1
164 where
165 p0 =
166 (\c b -> mconcat $ c <> b)
167 <$> P.some (P.try p_PairClose)
168 <*> P.some (P.try $ P.choice
169 [ P.try p_ElemOpen
170 , P.try p_ElemClose
171 , do
172 c <- p_PunctOrSym
173 case l_PairClose c of
174 Just l -> return [l]
175 Nothing ->
176 case l_PairOpenAndClose LexemePairOpen c <|> l_PairOpen c of
177 Nothing -> return [LexemePunctOrSym c]
178 _ -> fail ""
179 ])
180 p1 =
181 (\c b -> mconcat c <> [LexemePunctOrSym b])
182 <$> P.some (P.try p_PairClose)
183 <*> p_PunctOrSym
184
185 p_PairBorderOpen :: Parser e s [Lexeme]
186 p_PairBorderOpen = pdbg "PairBorderOpen" $
187 P.try p0 <|> p1
188 where
189 p0 =
190 (\b o -> mconcat $ b <> o)
191 <$> P.some (P.try $ P.choice
192 [ P.try p_ElemOpen
193 , P.try p_ElemClose
194 , do
195 c <- p_PunctOrSym
196 case l_PairOpen c <|> l_PairClose c of
197 Just l -> return [l]
198 Nothing -> fail ""
199 ])
200 <*> P.some (P.try p_PairOpen)
201 p1 =
202 (\b o -> LexemePunctOrSym b : mconcat o)
203 <$> p_PunctOrSym
204 <*> P.some (P.try p_PairOpen)
205
206 p_PairOpen :: Parser e s [Lexeme]
207 p_PairOpen = pdbg "PairOpen" $ do
208 P.choice
209 [ P.try p_ElemOpen
210 , P.try (pure <$> p_Escape)
211 , P.try (pure <$> p_Link)
212 , do
213 c <- p_PunctOrSym
214 case l_PairOpenOrClose LexemePairOpen c of
215 Just l -> return [l]
216 _ -> fail ""
217 ]
218
219 p_PairClose :: Parser e s [Lexeme]
220 p_PairClose = pdbg "PairClose" $ do
221 P.choice
222 [ P.try p_ElemClose
223 , P.try p_ElemSingle
224 , P.try (pure <$> p_Escape)
225 , P.try (pure <$> p_Link)
226 , do
227 c <- p_PunctOrSym
228 case l_PairOpenOrClose LexemePairClose c of
229 Just l -> return [l]
230 _ -> fail ""
231 ]
232
233 p_PairPlain :: (Char -> Maybe Lexeme) -> Parser e s [Lexeme]
234 p_PairPlain pair = pdbg "PairPlain" $ do
235 (<$> p_PunctOrSym) $ \c ->
236 pure $
237 LexemePunctOrSym c `fromMaybe`
238 pair c
239
240 l_PairOpenAndClose :: (Pair -> Lexeme) -> Char -> Maybe Lexeme
241 l_PairOpenAndClose lxm c =
242 case c of
243 '/' -> Just $ lxm PairSlash
244 '-' -> Just $ lxm PairDash
245 '"' -> Just $ lxm PairDoublequote
246 '\'' -> Just $ lxm PairSinglequote
247 '`' -> Just $ lxm PairBackquote
248 '_' -> Just $ lxm PairUnderscore
249 '*' -> Just $ lxm PairStar
250 '#' -> Just $ lxm PairHash
251 _ -> Nothing
252
253 l_PairOpenOrClose :: (Pair -> Lexeme) -> Char -> Maybe Lexeme
254 l_PairOpenOrClose lxm c =
255 l_PairOpenAndClose lxm c <|>
256 l_PairOpen c <|>
257 l_PairClose c
258
259 l_PairOpen :: Char -> Maybe Lexeme
260 l_PairOpen c =
261 case c of
262 '(' -> Just $ LexemePairOpen PairParen
263 '[' -> Just $ LexemePairOpen PairBracket
264 '{' -> Just $ LexemePairOpen PairBrace
265 '«' -> Just $ LexemePairOpen PairFrenchquote
266 _ -> Nothing
267
268 l_PairClose :: Char -> Maybe Lexeme
269 l_PairClose c =
270 case c of
271 ')' -> Just $ LexemePairClose PairParen
272 ']' -> Just $ LexemePairClose PairBracket
273 '}' -> Just $ LexemePairClose PairBrace
274 '»' -> Just $ LexemePairClose PairFrenchquote
275 _ -> Nothing
276
277 p_Link :: Parser e s Lexeme
278 p_Link =
279 (\scheme ss addr -> LexemeLink $ Text.pack $ scheme <> ss <> addr)
280 <$> P.option "" (P.try p_scheme)
281 <*> P.string "//"
282 <*> p_addr
283 where
284 p_scheme =
285 (<>)
286 <$> P.some (P.satisfy $ \c ->
287 Char.isAlphaNum c
288 || c=='_'
289 || c=='-'
290 || c=='+')
291 <*> P.string ":"
292 p_addr =
293 P.many $
294 P.satisfy $ \c ->
295 Char.isAlphaNum c
296 || c=='%'
297 || c=='/'
298 || c=='('
299 || c==')'
300 || c=='-'
301 || c=='_'
302 || c=='.'
303
304 p_Escape :: Parser e s Lexeme
305 p_Escape =
306 LexemeEscape
307 <$ P.char '\\'
308 <*> P.satisfy Char.isPrint
309
310 p_ElemSingle :: Parser e s [Lexeme]
311 p_ElemSingle = pdbg "ElemOpen" $
312 (\e as ->
313 [ LexemePairOpen $ PairElem e as
314 , LexemeToken $ Tokens mempty
315 -- NOTE: encode that it's the same Elem for open and close
316 , LexemePairClose $ PairElem e [] ])
317 <$ P.char '<'
318 <*> p_Word
319 <*> p_Attrs
320 <* P.string "/>"
321
322 p_ElemOpen :: Parser e s [Lexeme]
323 p_ElemOpen = pdbg "ElemOpen" $
324 (\e as oc ->
325 case oc of
326 True -> [ LexemePairOpen $ PairElem e as
327 , LexemeToken $ Tokens mempty
328 , LexemePairClose $ PairElem e [] ]
329 False -> [LexemePairOpen $ PairElem e as])
330 <$ P.char '<'
331 <*> p_Word
332 <*> p_Attrs
333 <*> P.option False (True <$ P.char '/')
334 <* P.char '>'
335
336 p_ElemClose :: Parser e s [Lexeme]
337 p_ElemClose = pdbg "ElemClose" $
338 (\e -> [LexemePairClose $ PairElem e []])
339 <$ P.string "</"
340 <*> p_Word
341 <* P.char '>'