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authorkrasimir <krasimir@chalmers.se>2009-12-13 18:50:29 +0000
committerkrasimir <krasimir@chalmers.se>2009-12-13 18:50:29 +0000
commitf85232947e74ee7ef8c7b0ad2338212e7e68f1be (patch)
tree667b886a5e3a4b026a63d4e3597f32497d824761 /src/runtime/haskell/PGF/Parsing/FCFG/Utilities.hs
parentd88a865faff59c98fc91556ff8700b10ee5f2df8 (diff)
reorganize the directories under src, and rescue the JavaScript interpreter from deprecated
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+----------------------------------------------------------------------
+-- |
+-- Maintainer : PL
+-- Stability : (stable)
+-- Portability : (portable)
+--
+-- > CVS $Date: 2005/05/13 12:40:19 $
+-- > CVS $Author: peb $
+-- > CVS $Revision: 1.6 $
+--
+-- Basic type declarations and functions for grammar formalisms
+-----------------------------------------------------------------------------
+
+
+module PGF.Parsing.FCFG.Utilities where
+
+import Control.Monad
+import Data.Array
+import Data.List (groupBy)
+
+import PGF.CId
+import PGF.Data
+import PGF.Tree
+import GF.Data.Assoc
+import GF.Data.Utilities (sameLength, foldMerge, splitBy)
+
+
+------------------------------------------------------------
+-- ranges as single pairs
+
+type RangeRec = [Range]
+
+data Range = Range {-# UNPACK #-} !Int {-# UNPACK #-} !Int
+ | EmptyRange
+ deriving (Eq, Ord, Show)
+
+makeRange :: Int -> Int -> Range
+makeRange = Range
+
+concatRange :: Range -> Range -> [Range]
+concatRange EmptyRange rng = return rng
+concatRange rng EmptyRange = return rng
+concatRange (Range i j) (Range j' k) = [Range i k | j==j']
+
+minRange :: Range -> Int
+minRange (Range i j) = i
+
+maxRange :: Range -> Int
+maxRange (Range i j) = j
+
+
+------------------------------------------------------------
+-- * representaions of input tokens
+
+data Input t = MkInput { inputBounds :: (Int, Int),
+ inputToken :: Assoc t [Range]
+ }
+
+input :: Ord t => [t] -> Input t
+input toks = MkInput inBounds inToken
+ where
+ inBounds = (0, length toks)
+ inToken = accumAssoc id [ (tok, makeRange i j) | (i,j,tok) <- zip3 [0..] [1..] toks ]
+
+inputMany :: Ord t => [[t]] -> Input t
+inputMany toks = MkInput inBounds inToken
+ where
+ inBounds = (0, length toks)
+ inToken = accumAssoc id [ (tok, makeRange i j) | (i,j,ts) <- zip3 [0..] [1..] toks, tok <- ts ]
+
+
+------------------------------------------------------------
+-- * representations of syntactical analyses
+
+-- ** charts as finite maps over edges
+
+-- | The values of the chart, a list of key-daughters pairs,
+-- has unique keys. In essence, it is a map from 'n' to daughters.
+-- The daughters should be a set (not necessarily sorted) of rhs's.
+type SyntaxChart n e = Assoc e [SyntaxNode n [e]]
+
+data SyntaxNode n e = SMeta
+ | SNode n [e]
+ | SString String
+ | SInt Integer
+ | SFloat Double
+ deriving (Eq,Ord,Show)
+
+groupSyntaxNodes :: Ord n => [SyntaxNode n e] -> [SyntaxNode n [e]]
+groupSyntaxNodes [] = []
+groupSyntaxNodes (SNode n0 es0:xs) = (SNode n0 (es0:ess)) : groupSyntaxNodes xs'
+ where
+ (ess,xs') = span xs
+
+ span [] = ([],[])
+ span xs@(SNode n es:xs')
+ | n0 == n = let (ess,xs) = span xs' in (es:ess,xs)
+ | otherwise = ([],xs)
+groupSyntaxNodes (SString s:xs) = (SString s) : groupSyntaxNodes xs
+groupSyntaxNodes (SInt n:xs) = (SInt n) : groupSyntaxNodes xs
+groupSyntaxNodes (SFloat f:xs) = (SFloat f) : groupSyntaxNodes xs
+
+-- ** syntax forests
+
+data SyntaxForest n = FMeta
+ | FNode n [[SyntaxForest n]]
+ -- ^ The outer list should be a set (not necessarily sorted)
+ -- of possible alternatives. Ie. the outer list
+ -- is a disjunctive node, and the inner lists
+ -- are (conjunctive) concatenative nodes
+ | FString String
+ | FInt Integer
+ | FFloat Double
+ deriving (Eq, Ord, Show)
+
+instance Functor SyntaxForest where
+ fmap f (FNode n forests) = FNode (f n) $ map (map (fmap f)) forests
+ fmap _ (FString s) = FString s
+ fmap _ (FInt n) = FInt n
+ fmap _ (FFloat f) = FFloat f
+ fmap _ (FMeta) = FMeta
+
+forestName :: SyntaxForest n -> Maybe n
+forestName (FNode n _) = Just n
+forestName _ = Nothing
+
+unifyManyForests :: (Monad m, Eq n) => [SyntaxForest n] -> m (SyntaxForest n)
+unifyManyForests = foldM unifyForests FMeta
+
+-- | two forests can be unified, if either is 'FMeta', or both have the same parent,
+-- and all children can be unified
+unifyForests :: (Monad m, Eq n) => SyntaxForest n -> SyntaxForest n -> m (SyntaxForest n)
+unifyForests FMeta forest = return forest
+unifyForests forest FMeta = return forest
+unifyForests (FNode name1 children1) (FNode name2 children2)
+ | name1 == name2 && not (null children) = return $ FNode name1 children
+ where children = [ forests | forests1 <- children1, forests2 <- children2,
+ sameLength forests1 forests2,
+ forests <- zipWithM unifyForests forests1 forests2 ]
+unifyForests (FString s1) (FString s2)
+ | s1 == s2 = return $ FString s1
+unifyForests (FInt n1) (FInt n2)
+ | n1 == n2 = return $ FInt n1
+unifyForests (FFloat f1) (FFloat f2)
+ | f1 == f2 = return $ FFloat f1
+unifyForests _ _ = fail "forest unification failure"
+
+
+-- ** conversions between representations
+
+chart2forests :: (Ord n, Ord e) =>
+ SyntaxChart n e -- ^ The complete chart
+ -> (e -> Bool) -- ^ When is an edge 'FMeta'?
+ -> [e] -- ^ The starting edges
+ -> [SyntaxForest n] -- ^ The result has unique keys, ie. all 'n' are joined together.
+ -- In essence, the result is a map from 'n' to forest daughters
+chart2forests chart isMeta = concatMap (edge2forests [])
+ where edge2forests edges edge
+ | isMeta edge = [FMeta]
+ | edge `elem` edges = []
+ | otherwise = map (item2forest (edge:edges)) $ chart ? edge
+ item2forest edges (SMeta) = FMeta
+ item2forest edges (SNode name children) =
+ FNode name $ children >>= mapM (edge2forests edges)
+ item2forest edges (SString s) = FString s
+ item2forest edges (SInt n) = FInt n
+ item2forest edges (SFloat f) = FFloat f
+
+
+applyProfileToForest :: SyntaxForest (CId,[Profile]) -> [SyntaxForest CId]
+applyProfileToForest (FNode (fun,profiles) children)
+ | fun == wildCId = concat chForests
+ | otherwise = [ FNode fun chForests | not (null chForests) ]
+ where chForests = concat [ mapM (unifyManyForests . map (forests !!)) profiles |
+ forests0 <- children,
+ forests <- mapM applyProfileToForest forests0 ]
+applyProfileToForest (FString s) = [FString s]
+applyProfileToForest (FInt n) = [FInt n]
+applyProfileToForest (FFloat f) = [FFloat f]
+applyProfileToForest (FMeta) = [FMeta]
+
+
+forest2trees :: SyntaxForest CId -> [Tree]
+forest2trees (FNode n forests) = map (Fun n) $ forests >>= mapM forest2trees
+forest2trees (FString s) = [Lit (LStr s)]
+forest2trees (FInt n) = [Lit (LInt n)]
+forest2trees (FFloat f) = [Lit (LFlt f)]
+forest2trees (FMeta) = [Meta 0]