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|
----------------------------------------------------------------------
-- |
-- Module : Generate
-- Maintainer : AR
-- Stability : (stable)
-- Portability : (portable)
--
-- > CVS $Date: 2005/05/30 18:39:44 $
-- > CVS $Author: aarne $
-- > CVS $Revision: 1.15 $
--
-- Generate all trees of given category and depth. AR 30\/4\/2004
--
-- (c) Aarne Ranta 2004 under GNU GPL
--
-- Purpose: to generate corpora. We use simple types and don't
-- guarantee the correctness of bindings\/dependences.
-----------------------------------------------------------------------------
module GF.UseGrammar.Generate (generateTrees) where
import GF.Canon.GFC
import GF.Grammar.LookAbs
import GF.Grammar.PrGrammar
import GF.Grammar.Macros
import GF.Grammar.Values
import GF.Grammar.Grammar (Cat)
import GF.Data.Operations
import GF.Data.Zipper
import Data.List
-- Generate all trees of given category and depth. AR 30/4/2004
-- (c) Aarne Ranta 2004 under GNU GPL
--
-- Purpose: to generate corpora. We use simple types and don't
-- guarantee the correctness of bindings/dependences.
-- | the main function takes an abstract syntax and returns a list of trees
generateTrees :: GFCGrammar -> Bool -> Cat -> Int -> Maybe Int -> Maybe Tree -> [Exp]
generateTrees gr ifm cat n mn mt = map str2tr $ generate gr' ifm cat' n mn mt'
where
gr' = gr2sgr gr
cat' = prt $ snd cat
mt' = maybe Nothing (return . tr2str) mt
------------------------------------------
-- translate grammar to simpler form and generated trees back
gr2sgr :: GFCGrammar -> SGrammar
gr2sgr gr = buildTree [(c,rs) | rs@((_,(_,c)):_) <- rules] where
rules =
groupBy (\x y -> scat x == scat y) $
sortBy (\x y -> compare (scat x) (scat y))
[(trId f, ty') | (f,ty) <- funRulesOf gr, ty' <- trTy ty]
trId = prt . snd
trTy ty = case catSkeleton ty of
Ok (mcs,mc) -> [(map trCat mcs, trCat mc)]
_ -> []
trCat (m,c) = prt c ---
scat (_,(_,c)) = c
-- str2tr :: STree -> Exp
str2tr t = case t of
SApp (f,ts) -> mkApp (trId f) (map str2tr ts)
SMeta _ -> mkMeta 0
---- SString s -> K s
where
trId = cn . zIdent
-- tr2str :: Tree -> STree
tr2str (Tr (N (_,at,val,_,_),ts)) = case (at,val) of
(AtC (_,f), _) -> SApp (prt_ f,map tr2str ts)
(AtM _, v) -> SMeta (catOf v)
(AtL s, _) -> SString s
(AtI i, _) -> SInt i
_ -> SMeta "FAILED_TO_GENERATE" ---- err monad!
where
catOf v = case v of
VApp w _ -> catOf w
VCn (_,c) -> prt_ c
_ -> "FAILED_TO_GENERATE_FROM_META"
------------------------------------------
-- do the main thing with a simpler data structure
-- the first Int gives tree depth, the second constrains subtrees
-- chosen for each branch. A small number, such as 2, is a good choice
-- if the depth is large (more than 3)
-- If a tree is given as argument, generation concerns its metavariables.
generate :: SGrammar -> Bool -> SCat -> Int -> Maybe Int -> Maybe STree -> [STree]
generate gr ifm cat i mn mt = case mt of
Nothing -> gen cat
Just t -> genM t
where
gen cat = concat $ errVal [] $ lookupTree id cat $ allTrees
allTrees = genAll i
-- dynamic generation
genAll :: Int -> BinTree SCat [[STree]]
genAll i = iter i genNext (mapTree (\ (c,_) -> (c,[[]])) gr)
iter 0 f tr = tr
iter n f tr = iter (n-1) f (f tr)
genNext tr = mapTree (genNew tr) tr
genNew tr (cat,ts) = let size = length ts in
(cat, [SApp (f, xs) |
(f,(cs,_)) <- funs cat,
xs <- combinations (map look cs),
let fxs = SApp (f, xs),
depth fxs == size]
: ts)
where
look c = concat $ errVal [] $ lookupTree id c tr
funs cat = maybe id take mn $ errVal [] $ lookupTree id cat gr
genM t = case t of
SApp (f,ts) -> [SApp (f,ts') | ts' <- combinations (map genM ts)]
SMeta k -> gen k
_ -> [t]
type SGrammar = BinTree SCat [SRule]
type SIdent = String
type SRule = (SFun,SType)
type SType = ([SCat],SCat)
type SCat = SIdent
type SFun = SIdent
allRules gr = concat [rs | (c,rs) <- tree2list gr]
data STree =
SApp (SFun,[STree])
| SMeta SCat
| SString String
| SInt Int
deriving (Show,Eq)
depth :: STree -> Int
depth t = case t of
SApp (_,ts@(_:_)) -> maximum (map depth ts) + 1
_ -> 1
------------------------------------------
-- to test
prSTree t = case t of
SApp (f,ts) -> f ++ concat (map pr1 ts)
SMeta c -> '?':c
SString s -> prQuotedString s
SInt i -> show i
where
pr1 t@(SApp (_,ts)) = ' ' : (if null ts then id else prParenth) (prSTree t)
pr1 t = prSTree t
pSRule :: String -> SRule
pSRule s = case words s of
f : _ : cs -> (f,(init cs', last cs'))
where cs' = [cs !! i | i <- [0,2..length cs - 1]]
_ -> error $ "not a rule" +++ s
exSgr = map pSRule [
"Pred : NP -> VP -> S"
,"Compl : TV -> NP -> VP"
,"PredVV : VV -> VP -> VP"
,"DefCN : CN -> NP"
,"ModCN : AP -> CN -> CN"
,"john : NP"
,"walk : VP"
,"love : TV"
,"try : VV"
,"girl : CN"
,"big : AP"
]
|
