module UU.Parsing.Offside( parseOffside
, pBlock
, pBlock1
, pOffside
, pOpen
, pClose
, pSeparator
, scanOffside
, scanOffsideWithTriggers
, scanLiftTokensToOffside
, OffsideTrigger(..)
, OffsideSymbol(..)
, OffsideInput
, Stream
, OffsideParser(..)
) where
import GHC.Prim
import Data.Maybe
import UU.Parsing.Interface
import UU.Parsing.Machine
import UU.Parsing.Derived(opt, pFoldr1Sep,pList,pList1, pList1Sep)
import UU.Scanner.Position
data OffsideTrigger
= Trigger_IndentGT
| Trigger_IndentGE
deriving Eq
data OffsideSymbol s
= Symbol s
| SemiColon
| CloseBrace
| OpenBrace
deriving (Ord,Eq,Show)
data Stream inp s p
= Cons (OffsideSymbol s) (OffsideInput inp s p)
| End inp
data IndentContext
= Cxt Bool
Int
data OffsideInput inp s p
= Off p
(Stream inp s p)
(Maybe (OffsideInput inp s p))
scanLiftTokensToOffside ts rest
= lift ts
where cons p s r = Off p (Cons (Symbol s) r) Nothing
lift tss = case splitStateE tss of
Left' t ts -> cons (getPosition tss) t (lift ts)
_ -> rest
scanOffside :: (InputState i s p, Position p, Eq s)
=> s -> s -> s -> [s] -> i -> OffsideInput i s p
scanOffside mod open close triggers ts
= scanOffsideWithTriggers mod open close (zip (repeat Trigger_IndentGT) triggers) ts
scanOffsideWithTriggers :: (InputState i s p, Position p, Eq s)
=> s -> s -> s -> [(OffsideTrigger,s)] -> i -> OffsideInput i s p
scanOffsideWithTriggers mod open close triggers ts = start ts []
where
isModule t = t == mod
isOpen t = t == open
isClose t = t == close
isTrigger tr = \t -> t `elem` triggers'
where triggers' = [ s | (tr',s) <- triggers, tr == tr' ]
isTriggerGT = isTrigger Trigger_IndentGT
isTriggerGE = isTrigger Trigger_IndentGE
end ts = Off (getPosition ts) (End ts)
cons :: p -> OffsideSymbol s -> OffsideInput i s p -> OffsideInput i s p
cons p s r = Off p (Cons s r) Nothing
start = case splitStateE ts of
Left' t _ | not (isModule t || isOpen t) -> implicitL 0 (Cxt False (column (getPosition ts)))
_ -> layoutL 0
startlnL l n ts (m:ms) | m == n = cons (getPosition ts) SemiColon (layoutL (line (getPosition ts)) ts (m:ms))
| n < m = cons (getPosition ts) CloseBrace (startlnL l n ts ms)
startlnL l n ts ms = layoutL (line (getPosition ts)) ts ms
implicitL l (Cxt ge n) ts (m:ms) | n > m
|| (n >= m && ge)
= cons (getPosition ts) OpenBrace (layoutL (line (getPosition ts)) ts (n:m:ms))
implicitL l (Cxt _ n) ts [] | n > 0 = cons (getPosition ts) OpenBrace (layoutL (line (getPosition ts)) ts [n])
implicitL l (Cxt _ n) ts ms = cons (getPosition ts) OpenBrace (cons (getPosition ts) CloseBrace (startlnL l n ts ms))
layoutL ln ts ms | ln /= sln = startln (column pos) ts ms
| otherwise = sameln ts ms
where sln = line pos
pos = getPosition ts
layout = layoutL ln
implicit = implicitL ln
startln = startlnL ln
aftertrigger isTriggerGE ts ms
= case splitStateE ts of
Left' t _ | isOpen t -> layout ts ms
| otherwise -> implicit (Cxt isTriggerGE (column(getPosition ts))) ts ms
Right' _ -> implicit (Cxt False 0 ) ts ms
sameln tts ms
= case splitStateE tts of
Left' t ts ->
let tail
| isTriggerGE t = aftertrigger True ts ms
| isTriggerGT t = aftertrigger False ts ms
| isClose t = case ms of
0:rs -> layout ts rs
_ -> layout ts ms
| isOpen t = layout ts (0:ms)
| otherwise = layout ts ms
parseError = case ms of
m:ms | m /= 0 -> Just (layout tts ms)
_ -> Nothing
in Off pos (Cons (Symbol t) tail) parseError
Right' rest -> endofinput pos rest ms
where pos = getPosition tts
endofinput pos rest [] = Off pos (End rest) Nothing
endofinput pos rest (m:ms) | m /= 0 = cons pos CloseBrace (endofinput pos rest ms)
| otherwise = endofinput pos rest ms
instance InputState inp s p => InputState (OffsideInput inp s p) (OffsideSymbol s) p where
splitStateE inp@(Off p stream _)
= case stream of
Cons s rest -> Left' s rest
where take 0 _ = []
take _ (Off _ (End _) _) = []
take n (Off _ (Cons h t) _) = h : take (n1) t
_ -> Right' inp
splitState (Off _ stream _)
= case stream of
Cons s rest -> (# s, rest #)
getPosition (Off pos _ _ ) = pos
instance Symbol s => Symbol (OffsideSymbol s) where
deleteCost s = case s of
Symbol s -> deleteCost s
SemiColon -> 5#
OpenBrace -> 5#
CloseBrace -> 5#
symBefore s = case s of
Symbol s -> Symbol (symBefore s)
SemiColon -> error "Symbol.symBefore SemiColon"
OpenBrace -> error "Symbol.symBefore OpenBrace"
CloseBrace -> error "Symbol.symBefore CloseBrace"
symAfter s = case s of
Symbol s -> Symbol (symAfter s)
SemiColon -> error "Symbol.symAfter SemiColon"
OpenBrace -> error "Symbol.symAfter OpenBrace"
CloseBrace -> error "Symbol.symAfter CloseBrace"
newtype OffsideParser i o s p a = OP (AnaParser (OffsideInput i s p) o (OffsideSymbol s) p a)
instance (Symbol s, Ord s, InputState i s p, OutputState o) => IsParser (OffsideParser i o s p) s where
(<*>) = operator (<*>)
(<* ) = operator (<* )
( *>) = operator ( *>)
(<|>) = operator (<|>)
(<$>) = operatorr (<$>)
(<$ ) = operatorr (<$ )
pSucceed = OP . pSucceed
pLow = OP . pLow
pFail = OP pFail
pCostRange c s (Range l r) = OP (getSymbol <$> pCostRange c (Symbol s) (Range (Symbol l)(Symbol r)))
pCostSym c s t = OP (getSymbol <$> pCostSym c (Symbol s) (Symbol t))
pSym s = OP (getSymbol <$> pSym (Symbol s))
pRange s (Range l r) = OP (getSymbol <$> pRange (Symbol s) (Range (Symbol l)(Symbol r)))
getfirsts (OP p) = removeSymbol (getfirsts p)
setfirsts exp (OP p) = OP (setfirsts (addSymbol exp) p)
getzerop (OP p) = fmap OP (getzerop p)
getonep (OP p) = fmap OP (getonep p)
removeSymbol exp = case exp of
ESym (Range (Symbol l) (Symbol r)) -> ESym (Range l r)
ESym _ -> EOr []
EStr txt -> EStr txt
EOr exps -> EOr (map removeSymbol exps)
ESeq exps -> ESeq (map removeSymbol exps)
addSymbol exp = case exp of
ESym (Range l r) -> ESym (Range (Symbol l) (Symbol r))
EStr txt -> EStr txt
EOr exps -> EOr (map addSymbol exps)
ESeq exps -> ESeq (map addSymbol exps)
getSymbol (Symbol s) = s
operator f (OP p) (OP q) = OP (f p q)
operatorr f g (OP p) = OP (f g p)
pSeparator :: (OutputState o, InputState i s p, Position p, Symbol s, Ord s)
=> OffsideParser i o s p ()
pSeparator = OP (() <$ pCostSym 5# SemiColon SemiColon)
pClose, pOpen :: (OutputState o, InputState i s p, Position p, Symbol s, Ord s)
=> OffsideParser i o s p ()
pClose = OP (pWrap f g ( () <$ pSym CloseBrace) )
where g state steps1 k = (state,ar,k)
where ar = case state of
Off _ _ (Just state')
-> let steps2 = k state'
in if not (hasSuccess steps1) && hasSuccess steps2
then Cost 1# steps2
else steps1
_ -> steps1
f acc state steps k = let (stl,ar,str2rr) = g state (val snd steps) k
in (stl ,val (acc ()) ar , str2rr )
pOpen = OP (() <$ pSym OpenBrace)
pOffside :: (InputState i s p, OutputState o, Position p, Symbol s, Ord s)
=> OffsideParser i o s p x
-> OffsideParser i o s p y
-> OffsideParser i o s p a
-> OffsideParser i o s p a
-> OffsideParser i o s p a
pOffside open close bodyE bodyI =
open *> bodyE <* close
<|> pOpen *> bodyI <* pClose
pBlock :: (InputState i s p, OutputState o, Position p, Symbol s, Ord s)
=> OffsideParser i o s p x
-> OffsideParser i o s p y
-> OffsideParser i o s p z
-> OffsideParser i o s p a
-> OffsideParser i o s p [a]
pBlock open sep close p = pOffside open close explicit implicit
where elem = (Just <$> p) `opt` Nothing
sep' = () <$ sep
elems s = (\h t -> catMaybes (h:t)) <$> elem <*> pList (s *> elem)
explicit = elems sep'
implicit = elems (sep' <|> pSeparator)
pBlock1 :: (InputState i s p, OutputState o, Position p, Symbol s, Ord s)
=> OffsideParser i o s p x
-> OffsideParser i o s p y
-> OffsideParser i o s p z
-> OffsideParser i o s p a
-> OffsideParser i o s p [a]
pBlock1 open sep close p = pOffside open close explicit implicit
where elem = (Just <$> p) `opt` Nothing
sep' = () <$ sep
elems s = (\h t -> catMaybes (h:t)) <$ pList s <*> (Just <$> p) <*> pList (s *> elem)
explicit = elems sep'
implicit = elems (sep' <|> pSeparator)
parseOffside :: (Symbol s, InputState i s p, Position p)
=> OffsideParser i Pair s p a
-> OffsideInput i s p
-> Steps (a, OffsideInput i s p) (OffsideSymbol s) p
parseOffside (OP p) inp = val fromPair (parse p inp)
where fromPair (Pair x (Pair y _)) = (x,y)