module Text.Regex.TDFA.NewDFA.Engine(execMatch) where
import Control.Monad(when,forM,forM_,liftM2,foldM,join,filterM)
import Data.Array.Base(unsafeRead,unsafeWrite,STUArray(..))
import GHC.Arr(STArray(..))
import GHC.ST(ST(..))
import GHC.Prim(MutableByteArray#,RealWorld,Int#,sizeofMutableByteArray#,unsafeCoerce#)
import Prelude hiding ((!!))
import Data.Array.MArray(MArray(..),unsafeFreeze)
import Data.Array.IArray(Array,bounds,assocs,Ix(rangeSize,range))
import qualified Data.IntMap.CharMap2 as CMap(findWithDefault)
import Data.IntMap(IntMap)
import qualified Data.IntMap as IMap(null,toList,lookup,insert)
import Data.Maybe(catMaybes)
import Data.Monoid(Monoid(..))
import qualified Data.IntSet as ISet(toAscList)
import Data.Array.IArray((!))
import Data.List(partition,sort,foldl',sortBy,groupBy)
import Data.STRef(STRef,newSTRef,readSTRef,writeSTRef)
import qualified Control.Monad.ST.Lazy as L(ST,runST,strictToLazyST)
import qualified Control.Monad.ST.Strict as S(ST)
import Data.Sequence(Seq,ViewL(..),viewl)
import qualified Data.Sequence as Seq(null)
import qualified Data.ByteString.Char8 as SBS(ByteString)
import qualified Data.ByteString.Lazy.Char8 as LBS(ByteString)
import Text.Regex.Base(MatchArray,MatchOffset,MatchLength)
import qualified Text.Regex.TDFA.IntArrTrieSet as Trie(lookupAsc)
import Text.Regex.TDFA.Common hiding (indent)
import Text.Regex.TDFA.NewDFA.Uncons(Uncons(uncons))
import Text.Regex.TDFA.NewDFA.MakeTest(test_singleline,test_multiline)
import qualified Text.Regex.TDFA.NewDFA.Engine_FA as FA(execMatch)
import qualified Text.Regex.TDFA.NewDFA.Engine_NC as NC(execMatch)
import qualified Text.Regex.TDFA.NewDFA.Engine_NC_FA as NC_FA(execMatch)
err :: String -> a
err s = common_error "Text.Regex.TDFA.NewDFA.Engine" s
(!!) :: (MArray a e (S.ST s),Ix i) => a i e -> Int -> S.ST s e
(!!) = unsafeRead
set :: (MArray a e (S.ST s),Ix i) => a i e -> Int -> e -> S.ST s ()
set = unsafeWrite
execMatch :: Uncons text => Regex -> Position -> Char -> text -> [MatchArray]
execMatch r@(Regex { regex_dfa = DFA {d_id=didIn,d_dt=dtIn}
, regex_init = startState
, regex_b_index = b_index
, regex_b_tags = b_tags_all
, regex_trie = trie
, regex_tags = aTags
, regex_groups = aGroups
, regex_isFrontAnchored = frontAnchored
, regex_compOptions = CompOption { multiline = newline }
, regex_execOptions = ExecOption { captureGroups = capture }})
offsetIn prevIn inputIn = case (subCapture,frontAnchored) of
(True ,False) -> L.runST runCaptureGroup
(True ,True) -> FA.execMatch r offsetIn prevIn inputIn
(False ,False) -> NC.execMatch r offsetIn prevIn inputIn
(False ,True) -> NC_FA.execMatch r offsetIn prevIn inputIn
where
subCapture :: Bool
subCapture = capture && (1<=rangeSize (bounds aGroups))
b_tags :: (Tag,Tag)
!b_tags = b_tags_all
orbitTags :: [Tag]
!orbitTags = map fst . filter ((Orbit==).snd) . assocs $ aTags
!test = mkTest newline
comp :: C s
comp = ditzyComp'3 aTags
runCaptureGroup :: L.ST s [MatchArray]
runCaptureGroup = do
obtainNext <- L.strictToLazyST constructNewEngine
let loop = do vals <- L.strictToLazyST obtainNext
if null vals
then return []
else do valsRest <- loop
return (vals ++ valsRest)
loop
constructNewEngine :: S.ST s (S.ST s [MatchArray])
constructNewEngine = do
storeNext <- newSTRef undefined
writeSTRef storeNext (goNext storeNext)
let obtainNext = join (readSTRef storeNext)
return obtainNext
goNext storeNext = do
(SScratch s1In s2In (winQ,blank,which)) <- newScratch b_index b_tags
_ <- spawnStart b_tags blank startState s1In offsetIn
eliminatedStateFlag <- newSTRef False
eliminatedRespawnFlag <- newSTRef False
let next s1 s2 did dt offset prev input =
case dt of
Testing' {dt_test=wt,dt_a=a,dt_b=b} ->
if test wt offset prev input
then next s1 s2 did a offset prev input
else next s1 s2 did b offset prev input
Simple' {dt_win=w,dt_trans=t, dt_other=o}
| IMap.null w ->
case uncons input of
Nothing -> finalizeWinners
Just (c,input') ->
case CMap.findWithDefault o c t of
Transition {trans_many=DFA {d_id=did',d_dt=dt'},trans_how=dtrans} ->
findTrans s1 s2 did did' dt' dtrans offset c input'
| otherwise -> do
(did',dt') <- processWinner s1 did dt w offset
next' s1 s2 did' dt' offset prev input
next' s1 s2 did dt offset prev input =
case dt of
Testing' {dt_test=wt,dt_a=a,dt_b=b} ->
if test wt offset prev input
then next' s1 s2 did a offset prev input
else next' s1 s2 did b offset prev input
Simple' {dt_trans=t, dt_other=o} ->
case uncons input of
Nothing -> finalizeWinners
Just (c,input') ->
case CMap.findWithDefault o c t of
Transition {trans_many=DFA {d_id=did',d_dt=dt'},trans_how=dtrans} ->
findTrans s1 s2 did did' dt' dtrans offset c input'
compressOrbits s1 did offset = do
let getStart state = do start <- maybe (err "compressOrbit,1") (!! 0) =<< m_pos s1 !! state
return (state,start)
cutoff = offset 50
ss <- mapM getStart (ISet.toAscList did)
let compressOrbit tag = do
mos <- forM ss ( \ p@(state,_start) -> do
mo <- fmap (IMap.lookup tag) (m_orbit s1 !! state)
case mo of
Just orbits | basePos orbits < cutoff -> return (Just (p,orbits))
| otherwise -> return Nothing
_ -> return Nothing )
let compressGroup [((state,_),orbit)] | Seq.null (getOrbits orbit) = return ()
| otherwise =
set (m_orbit s1) state
. (IMap.insert tag $! (orbit { ordinal = Nothing, getOrbits = mempty}))
=<< m_orbit s1 !! state
compressGroup gs = do
let sortPos (_,b1) (_,b2) = compare (ordinal b1) (ordinal b2) `mappend`
compare (inOrbit b2) (inOrbit b1) `mappend`
comparePos (viewl (getOrbits b1)) (viewl (getOrbits b2))
groupPos (_,b1) (_,b2) = ordinal b1 == ordinal b2 && getOrbits b1 == getOrbits b2
gs' = zip [(1::Int)..] (groupBy groupPos . sortBy sortPos $ gs)
forM_ gs' $ \ (!n,eqs) -> do
forM_ eqs $ \ ((state,_),orbit) ->
set (m_orbit s1) state
. (IMap.insert tag $! (orbit { ordinal = Just n, getOrbits = mempty }))
=<< m_orbit s1 !! state
let sorter ((_,a1),b1) ((_,a2),b2) = compare a1 a2 `mappend` compare (basePos b1) (basePos b2)
grouper ((_,a1),b1) ((_,a2),b2) = a1==a2 && basePos b1 == basePos b2
orbitGroups = groupBy grouper . sortBy sorter . catMaybes $ mos
mapM_ compressGroup orbitGroups
mapM_ compressOrbit orbitTags
findTrans s1 s2 did did' dt' dtrans offset prev' input' = do
when (not (null orbitTags) && (offset `rem` 100 == 99)) (compressOrbits s1 did offset)
let findTransTo (destIndex,sources) | IMap.null sources =
set which destIndex ((1,Instructions { newPos = [(0,SetPost)], newOrbits = Nothing })
,blank_pos blank,mempty)
| otherwise = do
let prep (sourceIndex,(_dopa,instructions)) = do
pos <- maybe (err $ "findTrans,1 : "++show (sourceIndex,destIndex,did')) return
=<< m_pos s1 !! sourceIndex
orbit <- m_orbit s1 !! sourceIndex
let orbit' = maybe orbit (\ f -> f offset orbit) (newOrbits instructions)
return ((sourceIndex,instructions),pos,orbit')
challenge x1@((_si1,ins1),_p1,_o1) x2@((_si2,ins2),_p2,_o2) = do
check <- comp offset x1 (newPos ins1) x2 (newPos ins2)
if check==LT then return x2 else return x1
(first:rest) <- mapM prep (IMap.toList sources)
set which destIndex =<< foldM challenge first rest
let dl = IMap.toList dtrans
mapM_ findTransTo dl
let performTransTo (destIndex,_) = do
x@((sourceIndex,_instructions),_pos,_orbit') <- which !! destIndex
if sourceIndex == (1)
then spawnStart b_tags blank destIndex s2 (succ offset)
else updateCopy x offset s2 destIndex
earlyStart <- fmap minimum $ mapM performTransTo dl
earlyWin <- readSTRef (mq_earliest winQ)
if earlyWin < earlyStart
then do
winners <- fmap (foldl' (\ rest ws -> ws : rest) []) $
getMQ earlyStart winQ
writeSTRef storeNext (next s2 s1 did' dt' (succ offset) prev' input')
mapM (tagsToGroupsST aGroups) winners
else do
let offset' = succ offset in seq offset' $ next s2 s1 did' dt' offset' prev' input'
processWinner s1 did dt w offset = do
let prep x@(sourceIndex,instructions) = do
pos <- maybe (err "newWinnerThenProceed,1") return =<< m_pos s1 !! sourceIndex
startPos <- pos !! 0
orbit <- m_orbit s1 !! sourceIndex
let orbit' = maybe orbit (\ f -> f offset orbit) (newOrbits instructions)
return (startPos,(x,pos,orbit'))
challenge x1@((_si1,ins1),_p1,_o1) x2@((_si2,ins2),_p2,_o2) = do
check <- comp offset x1 (newPos ins1) x2 (newPos ins2)
if check==LT then return x2 else return x1
prep'd <- mapM prep (IMap.toList w)
let (emptyFalse,emptyTrue) = partition ((offset >) . fst) prep'd
mayID <-
case map snd emptyFalse of
[] -> return Nothing
(first:rest) -> do
best@((_sourceIndex,_instructions),bp,_orbit') <- foldM challenge first rest
newWinner offset best
startWin <- bp !! 0
let states = ISet.toAscList did
keepState i1 = do
pos <- maybe (err "newWinnerThenProceed,2") return =<< m_pos s1 !! i1
startsAt <- pos !! 0
let keep = (startsAt <= startWin) || (offset <= startsAt)
when (not keep) $ do
writeSTRef eliminatedStateFlag True
when (i1 == startState) (writeSTRef eliminatedRespawnFlag True)
return keep
states' <- filterM keepState states
changed <- readSTRef eliminatedStateFlag
if changed then return (Just states') else return Nothing
case emptyTrue of
[] -> case IMap.lookup startState w of
Nothing -> return ()
Just ins -> winEmpty offset ins
[first] -> newWinner offset (snd first)
_ -> err "newWinnerThenProceed,3 : too many emptyTrue values"
case mayID of
Nothing -> return (did,dt)
Just states' -> do
writeSTRef eliminatedStateFlag False
respawn <- readSTRef eliminatedRespawnFlag
DFA {d_id=did',d_dt=dt'} <-
if respawn
then do
writeSTRef eliminatedRespawnFlag False
_ <- spawnStart b_tags blank startState s1 (succ offset)
return (Trie.lookupAsc trie (sort (states'++[startState])))
else return (Trie.lookupAsc trie states')
return (did',dt')
winEmpty preTag winInstructions = do
newerPos <- newA_ b_tags
copySTU (blank_pos blank) newerPos
set newerPos 0 preTag
doActions preTag newerPos (newPos winInstructions)
putMQ (WScratch newerPos) winQ
newWinner preTag ((_sourceIndex,winInstructions),oldPos,_newOrbit) = do
newerPos <- newA_ b_tags
copySTU oldPos newerPos
doActions preTag newerPos (newPos winInstructions)
putMQ (WScratch newerPos) winQ
finalizeWinners = do
winners <- fmap (foldl' (\ rest mqa -> mqa_ws mqa : rest) []) $
readSTRef (mq_list winQ)
resetMQ winQ
writeSTRef storeNext (return [])
mapM (tagsToGroupsST aGroups) winners
next s1In s2In didIn dtIn offsetIn prevIn inputIn
doActions :: Position -> STUArray s Tag Position -> [(Tag, Action)] -> ST s ()
doActions preTag pos ins = mapM_ doAction ins where
postTag = succ preTag
doAction (tag,SetPre) = set pos tag preTag
doAction (tag,SetPost) = set pos tag postTag
doAction (tag,SetVal v) = set pos tag v
mkTest :: Uncons text => Bool -> WhichTest -> Index -> Char -> text -> Bool
mkTest isMultiline = if isMultiline then test_multiline else test_singleline
data MQA s = MQA {mqa_start :: !Position, mqa_ws :: !(WScratch s)}
data MQ s = MQ { mq_earliest :: !(STRef s Position)
, mq_list :: !(STRef s [MQA s])
}
newMQ :: S.ST s (MQ s)
newMQ = do
earliest <- newSTRef maxBound
list <- newSTRef []
return (MQ earliest list)
resetMQ :: MQ s -> S.ST s ()
resetMQ (MQ {mq_earliest=earliest,mq_list=list}) = do
writeSTRef earliest maxBound
writeSTRef list []
putMQ :: WScratch s -> MQ s -> S.ST s ()
putMQ ws (MQ {mq_earliest=earliest,mq_list=list}) = do
start <- w_pos ws !! 0
let mqa = MQA start ws
startE <- readSTRef earliest
if start <= startE
then writeSTRef earliest start >> writeSTRef list [mqa]
else do
old <- readSTRef list
let !rest = dropWhile (\ m -> start <= mqa_start m) old
!new = mqa : rest
writeSTRef list new
getMQ :: Position -> MQ s -> ST s [WScratch s]
getMQ pos (MQ {mq_earliest=earliest,mq_list=list}) = do
old <- readSTRef list
case span (\m -> pos <= mqa_start m) old of
([],ans) -> do
writeSTRef earliest maxBound
writeSTRef list []
return (map mqa_ws ans)
(new,ans) -> do
writeSTRef earliest (mqa_start (last new))
writeSTRef list new
return (map mqa_ws ans)
data SScratch s = SScratch { _s_1 :: !(MScratch s)
, _s_2 :: !(MScratch s)
, _s_rest :: !( MQ s
, BlankScratch s
, STArray s Index ((Index,Instructions),STUArray s Tag Position,OrbitLog)
)
}
data MScratch s = MScratch { m_pos :: !(STArray s Index (Maybe (STUArray s Tag Position)))
, m_orbit :: !(STArray s Index OrbitLog)
}
newtype BlankScratch s = BlankScratch { blank_pos :: (STUArray s Tag Position)
}
newtype WScratch s = WScratch { w_pos :: (STUArray s Tag Position)
}
newA :: (MArray (STUArray s) e (ST s)) => (Tag,Tag) -> e -> S.ST s (STUArray s Tag e)
newA b_tags initial = newArray b_tags initial
newA_ :: (MArray (STUArray s) e (ST s)) => (Tag,Tag) -> S.ST s (STUArray s Tag e)
newA_ b_tags = newArray_ b_tags
newScratch :: (Index,Index) -> (Tag,Tag) -> S.ST s (SScratch s)
newScratch b_index b_tags = do
s1 <- newMScratch b_index
s2 <- newMScratch b_index
winQ <- newMQ
blank <- fmap BlankScratch (newA b_tags (1))
which <- (newArray b_index ((1,err "newScratch which 1"),err "newScratch which 2",err "newScratch which 3"))
return (SScratch s1 s2 (winQ,blank,which))
newMScratch :: (Index,Index) -> S.ST s (MScratch s)
newMScratch b_index = do
pos's <- newArray b_index Nothing
orbit's <- newArray b_index mempty
return (MScratch pos's orbit's)
newtype F s = F ([F s] -> C s)
type C s = Position
-> ((Int, Instructions), STUArray s Tag Position, IntMap Orbits)
-> [(Int, Action)]
-> ((Int, Instructions), STUArray s Tag Position, IntMap Orbits)
-> [(Int, Action)]
-> ST s Ordering
orderOf :: Action -> Action -> Ordering
orderOf post1 post2 =
case (post1,post2) of
(SetPre,SetPre) -> EQ
(SetPost,SetPost) -> EQ
(SetPre,SetPost) -> LT
(SetPost,SetPre) -> GT
(SetVal v1,SetVal v2) -> compare v1 v2
_ -> err $ "bestTrans.compareWith.choose sees incomparable "++show (post1,post2)
ditzyComp'3 :: forall s. Array Tag OP -> C s
ditzyComp'3 aTagOP = comp0 where
(F comp1:compsRest) = allcomps 1
comp0 :: C s
comp0 preTag x1@(_state1,pos1,_orbit1') np1 x2@(_state2,pos2,_orbit2') np2 = do
c <- liftM2 compare (pos2!!0) (pos1!!0)
case c of
EQ -> comp1 compsRest preTag x1 np1 x2 np2
answer -> return answer
allcomps :: Tag -> [F s]
allcomps tag | tag > top = [F (\ _ _ _ _ _ _ -> return EQ)]
| otherwise =
case aTagOP ! tag of
Orbit -> F (challenge_Orb tag) : allcomps (succ tag)
Maximize -> F (challenge_Max tag) : allcomps (succ tag)
Ignore -> F (challenge_Ignore tag) : allcomps (succ tag)
Minimize -> err "allcomps Minimize"
where top = snd (bounds aTagOP)
challenge_Ignore !tag (F next:comps) preTag x1 np1 x2 np2 =
case np1 of
((t1,_):rest1) | t1==tag ->
case np2 of
((t2,_):rest2) | t2==tag -> next comps preTag x1 rest1 x2 rest2
_ -> next comps preTag x1 rest1 x2 np2
_ -> do
case np2 of
((t2,_):rest2) | t2==tag -> next comps preTag x1 np1 x2 rest2
_ -> next comps preTag x1 np1 x2 np2
challenge_Ignore _ [] _ _ _ _ _ = err "impossible 2347867"
challenge_Max !tag (F next:comps) preTag x1@(_state1,pos1,_orbit1') np1 x2@(_state2,pos2,_orbit2') np2 =
case np1 of
((t1,b1):rest1) | t1==tag ->
case np2 of
((t2,b2):rest2) | t2==tag ->
if b1==b2 then next comps preTag x1 rest1 x2 rest2
else return (orderOf b1 b2)
_ -> do
p2 <- pos2 !! tag
let p1 = case b1 of SetPre -> preTag
SetPost -> succ preTag
SetVal v -> v
if p1==p2 then next comps preTag x1 rest1 x2 np2
else return (compare p1 p2)
_ -> do
p1 <- pos1 !! tag
case np2 of
((t2,b2):rest2) | t2==tag -> do
let p2 = case b2 of SetPre -> preTag
SetPost -> succ preTag
SetVal v -> v
if p1==p2 then next comps preTag x1 np1 x2 rest2
else return (compare p1 p2)
_ -> do
p2 <- pos2 !! tag
if p1==p2 then next comps preTag x1 np1 x2 np2
else return (compare p1 p2)
challenge_Max _ [] _ _ _ _ _ = err "impossible 9384324"
challenge_Orb !tag (F next:comps) preTag x1@(_state1,_pos1,orbit1') np1 x2@(_state2,_pos2,orbit2') np2 =
let s1 = IMap.lookup tag orbit1'
s2 = IMap.lookup tag orbit2'
in case (s1,s2) of
(Nothing,Nothing) -> next comps preTag x1 np1 x2 np2
(Just o1,Just o2) | inOrbit o1 == inOrbit o2 ->
case compare (ordinal o1) (ordinal o2) `mappend`
comparePos (viewl (getOrbits o1)) (viewl (getOrbits o2)) of
EQ -> next comps preTag x1 np1 x2 np2
answer -> return answer
_ -> err $ unlines [ "challenge_Orb is too stupid to handle mismatched orbit data :"
, show(tag,preTag,np1,np2)
, show s1
, show s2
]
challenge_Orb _ [] _ _ _ _ _ = err "impossible 0298347"
comparePos :: (ViewL Position) -> (ViewL Position) -> Ordering
comparePos EmptyL EmptyL = EQ
comparePos EmptyL _ = GT
comparePos _ EmptyL = LT
comparePos (p1 :< ps1) (p2 :< ps2) =
compare p1 p2 `mappend` comparePos (viewl ps1) (viewl ps2)
tagsToGroupsST :: forall s. Array GroupIndex [GroupInfo] -> WScratch s -> S.ST s MatchArray
tagsToGroupsST aGroups (WScratch {w_pos=pos})= do
let b_max = snd (bounds (aGroups))
ma <- newArray (0,b_max) (1,0) :: ST s (STArray s Int (MatchOffset,MatchLength))
startPos0 <- pos !! 0
stopPos0 <- pos !! 1
set ma 0 (startPos0,stopPos0startPos0)
let act _this_index [] = return ()
act this_index ((GroupInfo _ parent start stop flagtag):gs) = do
flagVal <- pos !! flagtag
if (1) == flagVal then act this_index gs
else do
startPos <- pos !! start
stopPos <- pos !! stop
(startParent,lengthParent) <- ma !! parent
let ok = (0 <= startParent &&
0 <= lengthParent &&
startParent <= startPos &&
stopPos <= startPos + lengthParent)
if not ok then act this_index gs
else set ma this_index (startPos,stopPosstartPos)
forM_ (range (1,b_max)) $ (\i -> act i (aGroups!i))
unsafeFreeze ma
spawnStart :: (Tag,Tag) -> BlankScratch s -> Index -> MScratch s -> Position -> S.ST s Position
spawnStart b_tags (BlankScratch blankPos) i s1 thisPos = do
oldPos <- m_pos s1 !! i
pos <- case oldPos of
Nothing -> do
pos' <- newA_ b_tags
set (m_pos s1) i (Just pos')
return pos'
Just pos -> return pos
copySTU blankPos pos
set (m_orbit s1) i $! mempty
set pos 0 thisPos
return thisPos
updateCopy :: ((Index, Instructions), STUArray s Tag Position, OrbitLog)
-> Index
-> MScratch s
-> Int
-> ST s Position
updateCopy ((_i1,instructions),oldPos,newOrbit) preTag s2 i2 = do
b_tags <- getBounds oldPos
newerPos <- maybe (do
a <- newA_ b_tags
set (m_pos s2) i2 (Just a)
return a) return =<< m_pos s2 !! i2
copySTU oldPos newerPos
doActions preTag newerPos (newPos instructions)
set (m_orbit s2) i2 $! newOrbit
newerPos !! 0
foreign import ccall unsafe "memcpy"
memcpy :: MutableByteArray# RealWorld -> MutableByteArray# RealWorld -> Int# -> IO ()
copySTU :: (Show i,Ix i,MArray (STUArray s) e (S.ST s)) => STUArray s i e -> STUArray s i e -> S.ST s ()
copySTU _souce@(STUArray _ _ _ msource) _destination@(STUArray _ _ _ mdest) =
ST $ \s1# ->
case sizeofMutableByteArray# msource of { n# ->
case unsafeCoerce# memcpy mdest msource n# s1# of { (# s2#, () #) ->
(# s2#, () #) }}