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author | Gregor Kleen <gkleen@yggdrasil.li> | 2018-05-21 21:36:57 +0200 |
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committer | Gregor Kleen <gkleen@yggdrasil.li> | 2018-05-21 21:36:57 +0200 |
commit | b8c5ae5af83015c1c0671cb9c5360d3e4b6df4e0 (patch) | |
tree | 07b64ed3ebd9d252b6b8538df7aae43e02bfdd35 /edit-lens/src/Control | |
parent | fbddba9ee102358aad7783997ab210c198daff4c (diff) | |
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FST operations
Diffstat (limited to 'edit-lens/src/Control')
-rw-r--r-- | edit-lens/src/Control/DFST.lhs | 2 | ||||
-rw-r--r-- | edit-lens/src/Control/FST.lhs | 114 |
2 files changed, 113 insertions, 3 deletions
diff --git a/edit-lens/src/Control/DFST.lhs b/edit-lens/src/Control/DFST.lhs index 94df533..9bd1629 100644 --- a/edit-lens/src/Control/DFST.lhs +++ b/edit-lens/src/Control/DFST.lhs | |||
@@ -46,7 +46,7 @@ toFST :: forall state input output. (Ord state, Ord input, Ord output) => DFST s | |||
46 | toFST DFST{..} = flip execState initialFST $ forM_ (Map.toList stTransition) handleTransition | 46 | toFST DFST{..} = flip execState initialFST $ forM_ (Map.toList stTransition) handleTransition |
47 | where | 47 | where |
48 | initialFST = FST | 48 | initialFST = FST |
49 | { stInitial = (stInitial, Nothing) | 49 | { stInitial = Set.singleton (stInitial, Nothing) |
50 | , stTransition = Map.empty | 50 | , stTransition = Map.empty |
51 | , stAccept = Set.map (, Nothing) stAccept | 51 | , stAccept = Set.map (, Nothing) stAccept |
52 | } | 52 | } |
diff --git a/edit-lens/src/Control/FST.lhs b/edit-lens/src/Control/FST.lhs index d3c8ca9..d37072f 100644 --- a/edit-lens/src/Control/FST.lhs +++ b/edit-lens/src/Control/FST.lhs | |||
@@ -1,24 +1,134 @@ | |||
1 | \begin{code} | 1 | \begin{code} |
2 | {-# LANGUAGE ScopedTypeVariables | ||
3 | #-} | ||
2 | 4 | ||
3 | {-| | 5 | {-| |
4 | Description: Finite state transducers with epsilon-transitions | 6 | Description: Finite state transducers with epsilon-transitions |
5 | -} | 7 | -} |
6 | module Control.FST | 8 | module Control.FST |
7 | ( FST(..) | 9 | ( FST(..) |
10 | -- * Constructing FSTs | ||
11 | , wordFST | ||
12 | -- * Operations on FSTs | ||
13 | , productFST, invertFST, restrictFST | ||
14 | -- * Debugging Utilities | ||
15 | , liveFST | ||
8 | ) where | 16 | ) where |
9 | 17 | ||
10 | import Data.Map.Strict (Map) | 18 | import Data.Map.Strict (Map, (!?)) |
11 | import qualified Data.Map.Strict as Map | 19 | import qualified Data.Map.Strict as Map |
12 | 20 | ||
13 | import Data.Set (Set) | 21 | import Data.Set (Set) |
22 | import qualified Data.Set as Set | ||
14 | 23 | ||
15 | import Data.Sequence (Seq) | 24 | import Data.Sequence (Seq) |
25 | import qualified Data.Sequence as Seq | ||
26 | |||
27 | import Data.Maybe (mapMaybe, fromMaybe) | ||
28 | |||
29 | import Numeric.Natural | ||
16 | 30 | ||
17 | import Control.Lens.TH | 31 | import Control.Lens.TH |
18 | 32 | ||
33 | import Control.Monad.State.Strict | ||
34 | |||
35 | import Text.PrettyPrint.Leijen (Pretty(..)) | ||
36 | import qualified Text.PrettyPrint.Leijen as PP | ||
37 | |||
38 | import Debug.Trace | ||
39 | |||
19 | data FST state input output = FST | 40 | data FST state input output = FST |
20 | { stInitial :: state | 41 | { stInitial :: Set state |
21 | , stTransition :: Map (state, Maybe input) (Set (state, Maybe output)) | 42 | , stTransition :: Map (state, Maybe input) (Set (state, Maybe output)) |
22 | , stAccept :: Set state | 43 | , stAccept :: Set state |
44 | } deriving (Show, Read) | ||
45 | |||
46 | instance (Show state, Show input, Show output) => Pretty (FST state input output) where | ||
47 | pretty FST{..} = PP.vsep | ||
48 | [ PP.text "Initial states:" PP.</> PP.hang 2 (PP.list . map (PP.text . show) $ Set.toAscList stInitial) | ||
49 | , PP.text "State transitions:" PP.<$> PP.indent 2 (PP.vsep | ||
50 | [ PP.text (show st) | ||
51 | PP.<+> (PP.text "-" PP.<> PP.tupled [label inS, label outS] PP.<> PP.text "→") | ||
52 | PP.<+> PP.text (show st') | ||
53 | | ((st, inS), to) <- Map.toList stTransition | ||
54 | , (st', outS) <- Set.toAscList to | ||
55 | ]) | ||
56 | , PP.text "Accepting states:" PP.</> PP.hang 2 (PP.list . map (PP.text . show) $ Set.toAscList stAccept) | ||
57 | ] | ||
58 | where | ||
59 | label :: Show a => Maybe a -> PP.Doc | ||
60 | label = maybe (PP.text "ɛ") (PP.text . show) | ||
61 | |||
62 | wordFST :: forall input output. Seq output -> FST Natural input output | ||
63 | -- ^ @wordFST str@ is the minimal FST generating @str@ as output when given no input | ||
64 | wordFST outs = FST | ||
65 | { stInitial = Set.singleton 0 | ||
66 | , stAccept = Set.singleton l | ||
67 | , stTransition = Map.fromSet next states | ||
23 | } | 68 | } |
69 | where | ||
70 | l :: Natural | ||
71 | l = fromIntegral $ Seq.length outs | ||
72 | states :: Set (Natural, Maybe input) | ||
73 | states = Set.fromDistinctAscList [ (n, Nothing) | n <- [0..pred l] ] | ||
74 | next :: (Natural, Maybe input) -> Set (Natural, Maybe output) | ||
75 | next (i, _) = Set.singleton (succ i, Just . Seq.index outs $ fromIntegral i) | ||
76 | |||
77 | productFST :: forall state1 state2 input output. (Ord state1, Ord state2, Ord input, Ord output) => FST state1 input output -> FST state2 input output -> FST (state1, state2) input output | ||
78 | -- ^ Cartesian product on states, logical conjunction on transitions and state-properties (initial and accept) | ||
79 | -- | ||
80 | -- This is most intuitive when thought of as the component-wise product of weighted FSTs with weights in the boolean semiring. | ||
81 | productFST fst1 fst2 = FST | ||
82 | { stInitial = stInitial fst1 `setProduct` stInitial fst2 | ||
83 | , stAccept = stAccept fst1 `setProduct` stAccept fst2 | ||
84 | , stTransition = Map.fromSet transitions . Set.fromList . mapMaybe filterTransition . Set.toAscList $ Map.keysSet (stTransition fst1) `setProduct` Map.keysSet (stTransition fst2) | ||
85 | } | ||
86 | where | ||
87 | setProduct :: forall a b. Set a -> Set b -> Set (a, b) | ||
88 | setProduct as bs = Set.fromDistinctAscList $ (,) <$> Set.toAscList as <*> Set.toAscList bs | ||
89 | filterTransition :: forall label. Eq label => ((state1, Maybe label), (state2, Maybe label)) -> Maybe ((state1, state2), Maybe label) | ||
90 | filterTransition ((st1, Nothing ), (st2, in2 )) = Just ((st1, st2), in2) | ||
91 | filterTransition ((st1, in1 ), (st2, Nothing )) = Just ((st1, st2), in1) | ||
92 | filterTransition ((st1, Just in1), (st2, Just in2)) | ||
93 | | in1 == in2 = Just ((st1, st2), Just in1) | ||
94 | | otherwise = Nothing | ||
95 | transitions :: ((state1, state2), Maybe input) -> Set ((state1, state2), Maybe output) | ||
96 | transitions ((st1, st2), inS) = Set.fromList . mapMaybe filterTransition . Set.toAscList $ out1 `setProduct` out2 | ||
97 | where | ||
98 | out1 = (fromMaybe Set.empty $ stTransition fst1 !? (st1, inS)) `Set.union` (fromMaybe Set.empty $ stTransition fst1 !? (st1, Nothing)) | ||
99 | out2 = (fromMaybe Set.empty $ stTransition fst2 !? (st2, inS)) `Set.union` (fromMaybe Set.empty $ stTransition fst2 !? (st2, Nothing)) | ||
100 | |||
101 | restrictFST :: forall state input output. (Ord state, Ord input, Ord output) => Set state -> FST state input output -> FST state input output | ||
102 | restrictFST sts FST{..} = FST | ||
103 | { stInitial = stInitial `Set.intersection` sts | ||
104 | , stAccept = stAccept `Set.intersection` sts | ||
105 | , stTransition = Map.mapMaybeWithKey restrictTransition stTransition | ||
106 | } | ||
107 | where | ||
108 | restrictTransition :: (state, Maybe input) -> Set (state, Maybe output) -> Maybe (Set (state, Maybe output)) | ||
109 | restrictTransition (st, _) tos = tos' <$ guard (st `Set.member` sts) | ||
110 | where | ||
111 | tos' = Set.filter (\(st', _) -> st' `Set.member` sts) tos | ||
112 | |||
113 | |||
114 | liveFST :: forall state input output. (Ord state, Ord input, Ord output, Show state) => FST state input output -> Set state | ||
115 | -- ^ Compute the set of "live" states (with no particular complexity) | ||
116 | -- | ||
117 | -- A state is "live" iff there is a path from it to an accepting state and a path from an initial state to it | ||
118 | liveFST fst@FST{..} = flip execState Set.empty $ mapM_ (depthSearch Set.empty) stInitial | ||
119 | where | ||
120 | stTransition' :: Map state (Set state) | ||
121 | stTransition' = Map.map (Set.map $ \(st, _) -> st) $ Map.mapKeysWith Set.union (\(st, _) -> st) stTransition | ||
122 | depthSearch :: Set state -> state -> State (Set state) () | ||
123 | depthSearch acc curr = do | ||
124 | let acc' = Set.insert curr acc | ||
125 | next = fromMaybe Set.empty $ stTransition' !? curr | ||
126 | alreadyLive <- get | ||
127 | when (not . Set.null $ Set.insert curr next `Set.intersection` Set.union stAccept alreadyLive) $ | ||
128 | modify $ Set.union acc' | ||
129 | mapM_ (depthSearch acc') $ next `Set.difference` alreadyLive | ||
130 | |||
131 | |||
132 | invertFST :: FST state input output -> Seq output -> Set (Seq input) | ||
133 | invertFST = undefined | ||
24 | \end{code} | 134 | \end{code} |