{-# LANGUAGE GADTs #-}
{-# LANGUAGE NamedFieldPuns #-}
{-# LANGUAGE NoRebindableSyntax #-}
module Duckling.Engine
( parseAndResolve
, lookupRegexAnywhere
, runDuckling
) where
import Control.DeepSeq
import Control.Monad.Extra
import Data.Aeson (toJSON)
import Data.ByteString (ByteString)
import Data.Functor.Identity
import Data.Maybe
import Data.Text (Text)
import Prelude
import qualified Data.Array as Array
import qualified Data.Foldable as Foldable
import qualified Data.List as L
import qualified Text.Regex.PCRE as PCRE
import Duckling.Dimensions.Types
import Duckling.Regex.Types
import Duckling.Resolve
import Duckling.Types
import Duckling.Types.Document (Document)
import Duckling.Types.Stash (Stash)
import qualified Duckling.Engine.Regex as Regex
import qualified Duckling.Types.Document as Document
import qualified Duckling.Types.Stash as Stash
type Duckling a = Identity a
runDuckling :: Duckling a -> a
runDuckling ma = runIdentity ma
parseAndResolve :: [Rule] -> Text -> Context -> Options -> [ResolvedToken]
parseAndResolve rules input context options =
mapMaybe (resolveNode context options) . force $ Stash.toPosOrderedList $
runDuckling $ parseString rules (Document.fromText input)
produce :: Match -> Maybe Node
produce (_, _, []) = Nothing
produce (Rule name _ production, _, etuor@(Node {nodeRange = Range _ e}:_)) = do
let route = reverse etuor
token <- force $ production $ map token route
case route of
(Node {nodeRange = Range p _}:_) -> Just Node
{ nodeRange = Range p e
, token = token
, children = route
, rule = Just name
}
[] -> Nothing
lookupRegex :: Document -> PCRE.Regex -> Int -> Duckling [Node]
lookupRegex doc _regex position | position >= Document.length doc = return []
lookupRegex doc regex position =
lookupRegexCommon doc regex position Regex.matchOnce
lookupRegexAnywhere :: Document -> PCRE.Regex -> Duckling [Node]
lookupRegexAnywhere doc regex = lookupRegexCommon doc regex 0 Regex.matchAll
{-# INLINE lookupRegexCommon #-}
lookupRegexCommon
:: Foldable t
=> Document
-> PCRE.Regex
-> Int
-> (PCRE.Regex -> ByteString -> t PCRE.MatchArray)
-> Duckling [Node]
lookupRegexCommon doc regex position matchFun = return nodes
where
(substring, rangeToText, translateRange) =
Document.byteStringFromPos doc position
nodes = mapMaybe (f . Array.elems) $ Foldable.toList $
matchFun regex substring
f :: [(Int, Int)] -> Maybe Node
f [] = Nothing
f ((0,0):_) = Nothing
f ((bsStart, bsLen):groups) =
if Document.isRangeValid doc start end
then Just node
else Nothing
where
textGroups = map rangeToText groups
(start, end) = translateRange bsStart bsLen
node = Node
{ nodeRange = Range start end
, token = Token RegexMatch (GroupMatch textGroups)
, children = []
, rule = Nothing
}
lookupItem :: Document -> PatternItem -> Stash -> Int -> Duckling [Node]
lookupItem doc (Regex re) _ position =
filter (isPositionValid position doc) <$>
lookupRegex doc re position
lookupItem doc (Predicate p) stash position =
return $
filter (p . token) $
takeWhile (isPositionValid position doc) $
Stash.toPosOrderedListFrom stash position
lookupItemAnywhere :: Document -> PatternItem -> Stash -> Duckling [Node]
lookupItemAnywhere doc (Regex re) _ = lookupRegexAnywhere doc re
lookupItemAnywhere _doc (Predicate p) stash =
return $ filter (p . token) $ Stash.toPosOrderedList stash
isPositionValid :: Int -> Document -> Node -> Bool
isPositionValid position sentence Node{nodeRange = Range start _} =
Document.isAdjacent sentence position start
type Match = (Rule, Int, [Node])
matchAll :: Document -> Stash -> [Match] -> Duckling [Match]
matchAll sentence stash matches = concatMapM mkNextMatches matches
where
mkNextMatches :: Match -> Duckling [Match]
mkNextMatches match@(Rule {pattern = []}, _, _) = return [ match ]
mkNextMatches match@(Rule {pattern = p:_}, _, _) = do
nextMatches <- matchAll sentence stash =<< matchFirst sentence stash match
return $ case p of
Regex _ -> nextMatches
Predicate _ -> match:nextMatches
matchFirst :: Document -> Stash -> Match -> Duckling [Match]
matchFirst _ _ (Rule {pattern = []}, _, _) = return []
matchFirst sentence stash (rule@Rule{pattern = p : ps}, position, route) =
map (mkMatch route newRule) <$> lookupItem sentence p stash position
where
newRule = rule { pattern = ps }
matchFirstAnywhere :: Document -> Stash -> Rule -> Duckling [Match]
matchFirstAnywhere _sentence _stash Rule {pattern = []} = return []
matchFirstAnywhere sentence stash rule@Rule{pattern = p : ps} =
map (mkMatch [] newRule) <$> lookupItemAnywhere sentence p stash
where
newRule = rule { pattern = ps }
{-# INLINE mkMatch #-}
mkMatch :: [Node] -> Rule -> Node -> Match
mkMatch route newRule (node@Node {nodeRange = Range _ pos'}) =
newRoute `seq` (newRule, pos', newRoute)
where newRoute = node:route
parseString1
:: [Rule] -> Document -> Stash -> Stash -> [Match]
-> Duckling (Stash, [Match])
parseString1 rules sentence stash new matches = do
newPartial <- concatMapM (matchFirst sentence new) matches
newMatches <- concatMapM (matchFirstAnywhere sentence new) rules
(full, partial) <- L.partition (\(Rule {pattern}, _, _) -> null pattern)
<$> matchAll sentence stash (newPartial ++ newMatches)
return ( Stash.fromList $ mapMaybe produce full
, partial ++ matches
)
saturateParseString
:: [Rule] -> Document -> Stash -> Stash -> [Match] -> Duckling Stash
saturateParseString rules sentence stash new matches = do
(new', matches') <- parseString1 rules sentence stash new matches
let stash' = Stash.union stash new'
if Stash.null new'
then return stash
else saturateParseString rules sentence stash' new' matches'
parseString :: [Rule] -> Document -> Duckling Stash
parseString rules sentence = do
(new, partialMatches) <-
parseString1 rules sentence Stash.empty Stash.empty []
if Stash.null new
then return Stash.empty
else
saturateParseString headPredicateRules sentence new new partialMatches
where
headPredicateRules =
[ rule | rule@Rule{pattern = (Predicate _ : _)} <- rules ]
resolveNode :: Context -> Options -> Node -> Maybe ResolvedToken
resolveNode context options n@Node{token = (Token dim dd), nodeRange = r}
= do
(val, latent) <- resolve context options dd
Just Resolved
{ range = r
, node = n
, rval = RVal dim val
, isLatent = latent
}