starting GFCC format

2026-04-24 03:52:50 -06:00 · 2006-09-05 12:14:13 +00:00
parent 1807dc4379
commit 8484cfab1b
12 changed files with 2249 additions and 0 deletions
--- a/src/GF/Canon/CanonToGFCC.hs
+++ b/src/GF/Canon/CanonToGFCC.hs
@@ -0,0 +1,378 @@
 ----------------------------------------------------------------------
 -- |
 -- Module      : CanonToGFCC
 -- Maintainer  : AR
 -- Stability   : (stable)
 -- Portability : (portable)
 --
 -- > CVS $Date: 2005/06/17 14:15:17 $ 
 -- > CVS $Author: aarne $
 -- > CVS $Revision: 1.15 $
 --
 -- a decompiler. AR 12/6/2003 -- 19/4/2004
 -----------------------------------------------------------------------------
 module GF.Canon.CanonToGFCC (prCanon2gfcc) where
 import GF.Canon.AbsGFC
 import qualified GF.Canon.GFC as GFC
 import qualified GF.Canon.GFCC.AbsGFCC as C
 import qualified GF.Canon.GFCC.PrintGFCC as Pr
 import GF.Canon.GFC
 import qualified GF.Grammar.Abstract as A
 import qualified GF.Grammar.Macros as GM
 import GF.Canon.MkGFC
 import GF.Canon.CMacros
 import qualified GF.Infra.Modules as M
 import qualified GF.Infra.Option as O
 import GF.UseGrammar.Linear (unoptimizeCanon)
 import GF.Infra.Ident
 import GF.Data.Operations
 import Data.List
 import qualified Data.Map as Map
 prCanon2gfcc :: CanonGrammar -> String
 prCanon2gfcc = Pr.printTree . canon2gfcc . canon2canon . unoptimizeCanon
 -- this assumes a grammar translated by canon2canon
 canon2gfcc :: CanonGrammar -> C.Grammar
 canon2gfcc cgr@(M.MGrammar ((a,M.ModMod abm):cms)) = 
     C.Grm (C.Hdr (i2i a) cs) (C.Abs adefs) cncs where
  cs  = map (i2i . fst) cms
  adefs = [C.Fun f' (mkType ty) (C.Tr (C.AC f') []) | 
            (f,GFC.AbsFun ty _) <- tree2list (M.jments abm), let f' = i2i f]
  cncs  = [C.Cnc (i2i lang) (concr m) | (lang,M.ModMod m) <- cms]
  concr mo = optConcrete 
               [C.Lin (i2i f) (mkTerm tr) | 
                 (f,GFC.CncFun _ _ tr _) <- tree2list (M.jments mo)]
 i2i :: Ident -> C.CId
 i2i (IC c) = C.CId c
 mkType :: A.Type -> C.Type
 mkType t = case GM.catSkeleton t of
  Ok (cs,c) -> C.Typ (map (i2i . snd) cs) (i2i $ snd c)
 mkTerm :: Term -> C.Term
 mkTerm tr = case tr of
  Arg (A _ i) -> C.V i
  EInt i      -> C.C i
  R rs     -> C.R [mkTerm t | Ass _ t <- rs]
  P t l    -> C.P (mkTerm t) (C.C (mkLab l))
  T _ cs   -> C.R [mkTerm t | Cas _ t <- cs]
  V _ cs   -> C.R [mkTerm t | t <- cs]
  S t p    -> C.P (mkTerm t) (mkTerm p)
  C s t    -> C.S [mkTerm x | x <- [s,t]]
  FV ts    -> C.FV [mkTerm t | t <- ts]
  K (KS s) -> C.K (C.KS s)
  K (KP ss _) -> C.K (C.KP ss []) ---- TODO: prefix variants
  E -> C.S []
  Par _ _  -> C.C 123              ---- just for debugging
  _ -> C.S [C.K (C.KS (A.prt tr))] ---- just for debugging
 where
   mkLab (L (IC l)) = case l of
     '_':ds -> (read ds) :: Integer
     _ -> 789
 -- translate tables and records to arrays, return just one module per language
 canon2canon :: CanonGrammar -> CanonGrammar
 canon2canon cgr = M.MGrammar $ reorder $ map c2c $ M.modules cgr where
  reorder cgr = 
    (abs, M.ModMod $ 
           M.Module M.MTAbstract M.MSComplete [] [] [] (sorted2tree adefs)):
      [(c, M.ModMod $ 
           M.Module (M.MTConcrete abs) M.MSComplete [] [] [] (sorted2tree js)) 
            | (c,js) <- cncs] 
  abs  = maybe (error "no abstract") id $ M.greatestAbstract cgr
  cns  = M.allConcretes cgr abs
  adefs = sortBy (\ (f,_) (g,_) -> compare f g) 
            [finfo | 
              (i,mo) <- mos, M.isModAbs mo, 
              finfo <- tree2list (M.jments mo)]
  cncs = sortBy (\ (x,_) (y,_) -> compare x y)
            [(lang, concr lang) | lang <- cns]
  mos = M.allModMod cgr
  concr la = sortBy (\ (f,_) (g,_) -> compare f g) 
            [finfo | 
              (i,mo) <- mos, M.isModCnc mo, ----- 
              finfo <- tree2list (M.jments mo)]
  c2c (c,m) = case m of
    M.ModMod mo@(M.Module (M.MTConcrete _) M.MSComplete _ _ _ js) ->
      (c, M.ModMod $ M.replaceJudgements mo $ mapTree (j2j c) js)
    _ -> (c,m)
  j2j c (f,j) = case j of
    GFC.CncFun x y tr z -> (f,GFC.CncFun x y (t2t c tr) z)
    _ -> (f,j)
  t2t = term2term cgr
 term2term :: CanonGrammar -> Ident -> Term -> Term
 term2term cgr c tr = case tr of
  Par (CIQ _ c) _ -> EInt 456 ----
  R rs     -> R [Ass (l2l l) (t2t t) | Ass l t <- rs] ----
  P t l    -> P (t2t t) (l2l l)
  T ty cs  -> V ty [t2t t | Cas _ t <- cs]
  S t p    -> S (t2t t) (t2t p)
  _ -> composSafeOp t2t tr
 where
   t2t = term2term cgr c
   l2l l = L (IC "_123") ----
 optConcrete :: [C.CncDef] -> [C.CncDef]
 optConcrete defs = subex [C.Lin f (optTerm t) | C.Lin f t <- defs]
 -- analyse word form lists into prefix + suffixes
 -- suffix sets can later be shared by subex elim
 optTerm :: C.Term -> C.Term  
 optTerm tr = case tr of
    C.R ts@(_:_) | all isK ts -> mkSuff $ optToks [s | C.K (C.KS s) <- ts]
    C.R ts  -> C.R $ map optTerm ts
    C.P t v -> C.P (optTerm t) v
    _ -> tr
 where
  optToks ss = prf : suffs where
    prf = pref (sort ss)
    suffs = map (drop (length prf)) ss
    pref ss = longestPref (head ss) (last ss)
    longestPref w u = if isPrefixOf w u then w else longestPref (init w) u
  isK t = case t of
    C.K (C.KS _) -> True
    _ -> False
  mkSuff (p:ws) = C.W p (C.R (map (C.K . C.KS) ws))
 subex :: [C.CncDef] -> [C.CncDef]
 subex js = errVal js $ do
  (tree,_) <- appSTM (getSubtermsMod js) (Map.empty,0)
  return $ addSubexpConsts tree js
 -- implementation
 type TermList = Map.Map C.Term (Int,Int) -- number of occs, id
 type TermM a = STM (TermList,Int) a
 addSubexpConsts :: TermList -> [C.CncDef] -> [C.CncDef]
 addSubexpConsts tree lins =
  let opers = sortBy (\ (C.Lin f _) (C.Lin g _) -> compare f g)
                [C.Lin (fid id) trm | (trm,(_,id)) <- list]
  in map mkOne $ opers ++ lins
 where
   mkOne (C.Lin f trm) = (C.Lin f (recomp f trm))
   recomp f t = case Map.lookup t tree of
     Just (_,id) | fid id /= f -> C.F $ fid id -- not to replace oper itself
     _ -> case t of
       C.R ts  -> C.R $ map (recomp f) ts
       C.S ts  -> C.S $ map (recomp f) ts
       C.W s t -> C.W s (recomp f t)
       C.P t p -> C.P (recomp f t) (recomp f p)
       _ -> t
   fid n = C.CId $ "_" ++ show n
   list = Map.toList tree
 getSubtermsMod :: [C.CncDef] -> TermM TermList
 getSubtermsMod js = do
  mapM (getInfo collectSubterms) js
  (tree0,_) <- readSTM
  return $ Map.filter (\ (nu,_) -> nu > 1) tree0
 where
   getInfo get (C.Lin f trm) = do
     get trm
     return ()
 collectSubterms :: C.Term -> TermM ()
 collectSubterms t = case t of
  C.R ts -> do
    mapM collectSubterms ts
    add t
  C.S ts -> do
    mapM collectSubterms ts
    add t
  C.W s u -> do
    collectSubterms u
    add t
  _ -> return ()
 where
   add t = do
     (ts,i) <- readSTM
     let 
       ((count,id),next) = case Map.lookup t ts of
         Just (nu,id) -> ((nu+1,id), i)
         _ ->            ((1,   i ), i+1)
     writeSTM (Map.insert t (count,id) ts, next)
 {-
 canon2sourceModule :: CanonModule -> Err G.SourceModule
 canon2sourceModule (i,mi) = do
  i'    <- redIdent i 
  info' <- case mi of
    M.ModMod m -> do
      (e,os) <- redExtOpen m
      flags  <- mapM redFlag $ M.flags m 
      (abstr,mt)  <- case M.mtype m of
          M.MTConcrete a -> do
            a' <- redIdent a
            return (a', M.MTConcrete a') 
          M.MTAbstract -> return (i',M.MTAbstract) --- c' not needed
          M.MTResource -> return (i',M.MTResource) --- c' not needed
          M.MTTransfer x y -> return (i',M.MTTransfer x y) --- c' not needed
      defs   <- mapMTree redInfo $ M.jments m
      return $ M.ModMod $ M.Module mt (M.mstatus m) flags e os defs
    _ -> Bad $ "cannot decompile module type"
  return (i',info')
 where
   redExtOpen m = do
     e'  <- return $ M.extend m
     os' <- mapM (\ (M.OSimple q i) -> liftM (\i -> M.OQualif q i i) (redIdent i)) $ 
                 M.opens m
     return (e',os')
 redInfo :: (Ident,Info) -> Err (Ident,G.Info)
 redInfo (c,info) = errIn ("decompiling abstract" +++ show c) $ do
  c' <- redIdent c 
  info' <- case info of
    AbsCat cont fs -> do
      return $ G.AbsCat (Yes cont) (Yes (map (uncurry G.Q) fs))
    AbsFun typ df -> do
      return $ G.AbsFun (Yes typ) (Yes df)
    AbsTrans t -> do
      return $ G.AbsTrans t
    ResPar par -> liftM (G.ResParam . Yes) $ mapM redParam par
    CncCat pty ptr ppr -> do
      ty'  <- redCType pty
      trm' <- redCTerm ptr
      ppr' <- redCTerm ppr 
      return $ G.CncCat (Yes ty') (Yes trm') (Yes ppr')      
    CncFun (CIQ abstr cat) xx body ppr -> do
      xx'   <- mapM redArgVar xx
      body' <- redCTerm body
      ppr'  <- redCTerm ppr
      cat'  <- redIdent cat
      return $ G.CncFun (Just (cat', ([],F.typeStr))) -- Nothing 
        (Yes (F.mkAbs xx' body')) (Yes ppr')
    AnyInd b c -> liftM (G.AnyInd b) $ redIdent c
  return (c',info')
 redQIdent :: CIdent -> Err G.QIdent
 redQIdent (CIQ m c) = liftM2 (,) (redIdent m) (redIdent c)
 redIdent :: Ident -> Err Ident
 redIdent = return
 redFlag :: Flag -> Err O.Option
 redFlag (Flg f x) = return $ O.Opt (prIdent f,[prIdent x])
 redDecl :: Decl -> Err G.Decl
 redDecl (Decl x a) = liftM2 (,) (redIdent x) (redTerm a)
 redType :: Exp -> Err G.Type
 redType = redTerm
 redTerm :: Exp -> Err G.Term
 redTerm t = return $ trExp t
 -- resource
 redParam (ParD c cont) = do
  c'    <- redIdent c
  cont' <- mapM redCType cont
  return $ (c', [(IW,t) | t <- cont'])
 -- concrete syntax
 redCType :: CType -> Err G.Type
 redCType t = case t of
  RecType lbs -> do
    let (ls,ts) = unzip [(l,t) | Lbg l t <- lbs]
        ls' = map redLabel ls
    ts' <- mapM redCType ts
    return $ G.RecType $ zip ls' ts'
  Table p v  -> liftM2 G.Table (redCType p) (redCType v)
  Cn mc  -> liftM (uncurry G.QC) $ redQIdent mc
  TStr -> return $ F.typeStr
  TInts i -> return $ F.typeInts (fromInteger i)
 redCTerm :: Term -> Err G.Term
 redCTerm x = case x of
  Arg argvar  -> liftM G.Vr $ redArgVar argvar
  I cident  -> liftM (uncurry G.Q) $ redQIdent cident
  Par cident terms  -> liftM2 F.mkApp 
                         (liftM (uncurry G.QC) $ redQIdent cident) 
                         (mapM redCTerm terms)
  LI id  -> liftM G.Vr $ redIdent id
  R assigns  -> do
    let (ls,ts) = unzip [(l,t) | Ass l t <- assigns]
    let ls' = map redLabel ls
    ts' <- mapM redCTerm ts
    return $ G.R [(l,(Nothing,t)) | (l,t) <- zip ls' ts']
  P term label  -> liftM2 G.P (redCTerm term) (return $ redLabel label)
  T ctype cases  -> do
    ctype' <- redCType ctype
    let (ps,ts) = unzip [(ps,t) | Cas ps t <- cases]
    ps' <- mapM (mapM redPatt) ps
    ts' <- mapM redCTerm ts
    let tinfo = case ps' of
                  [[G.PV _]] -> G.TTyped ctype'
                  _ -> G.TComp ctype'
    return $ G.TSh tinfo $ zip ps' ts'
  V ctype ts  -> do
    ctype' <- redCType ctype
    ts' <- mapM redCTerm ts
    return $ G.V ctype' ts'
  S term0 term  -> liftM2 G.S (redCTerm term0) (redCTerm term)
  C term0 term  -> liftM2 G.C (redCTerm term0) (redCTerm term)
  FV terms  -> liftM G.FV $ mapM redCTerm terms
  K (KS str) -> return $ G.K str
  EInt i     -> return $ G.EInt i
  EFloat i   -> return $ G.EFloat i
  E  -> return $ G.Empty
  K (KP d vs)  -> return $ 
                    G.Alts (tList d,[(tList s, G.Strs $ map G.K v) | Var s v <- vs])
 where
   tList ss = case ss of --- this should be in Macros
     [] -> G.Empty
     _ -> foldr1 G.C $ map G.K ss
 failure x = Bad $ "not yet" +++ show x ----
 redArgVar :: ArgVar -> Err Ident
 redArgVar x = case x of
  A x i -> return $ IA (prIdent x, fromInteger i)
  AB x b i -> return $ IAV (prIdent x, fromInteger b, fromInteger i)
 redLabel :: Label -> G.Label
 redLabel (L x) = G.LIdent $ prIdent x
 redLabel (LV i) = G.LVar $ fromInteger i
 redPatt :: Patt -> Err G.Patt
 redPatt p = case p of
  PV x -> liftM G.PV $ redIdent x
  PC mc ps -> do
    (m,c) <- redQIdent mc
    liftM (G.PP m c) (mapM redPatt ps) 
  PR rs -> do
    let (ls,ts) = unzip [(l,t) | PAss l t <- rs]
        ls' = map redLabel ls
    ts <- mapM redPatt ts
    return $ G.PR $ zip ls' ts
  PI i -> return $ G.PInt i
  PF i -> return $ G.PFloat i
  _ -> Bad $ "cannot recompile pattern" +++ show p
 -}
--- a/src/GF/Canon/GFCC/AbsGFCC.hs
+++ b/src/GF/Canon/GFCC/AbsGFCC.hs
@@ -0,0 +1,64 @@
 module GF.Canon.GFCC.AbsGFCC where
 -- Haskell module generated by the BNF converter
 newtype CId = CId String deriving (Eq,Ord,Show)
 data Grammar =
   Grm Header Abstract [Concrete]
  deriving (Eq,Ord,Show)
 data Header =
   Hdr CId [CId]
  deriving (Eq,Ord,Show)
 data Abstract =
   Abs [AbsDef]
  deriving (Eq,Ord,Show)
 data Concrete =
   Cnc CId [CncDef]
  deriving (Eq,Ord,Show)
 data AbsDef =
   Fun CId Type Exp
  deriving (Eq,Ord,Show)
 data CncDef =
   Lin CId Term
  deriving (Eq,Ord,Show)
 data Type =
   Typ [CId] CId
  deriving (Eq,Ord,Show)
 data Exp =
   Tr Atom [Exp]
  deriving (Eq,Ord,Show)
 data Atom =
   AC CId
 | AS String
 | AI Integer
  deriving (Eq,Ord,Show)
 data Term =
   R [Term]
 | P Term Term
 | S [Term]
 | K Tokn
 | V Integer
 | C Integer
 | F CId
 | FV [Term]
 | W String Term
  deriving (Eq,Ord,Show)
 data Tokn =
   KS String
 | KP [String] [Variant]
  deriving (Eq,Ord,Show)
 data Variant =
   Var [String] [String]
  deriving (Eq,Ord,Show)
--- a/src/GF/Canon/GFCC/DataGFCC.hs
+++ b/src/GF/Canon/GFCC/DataGFCC.hs
@@ -0,0 +1,72 @@
 module GF.Canon.GFCC.DataGFCM where
 import GF.Canon.GFCC.AbsGFCC
 import Data.Map
 data GFCC = GFCC {
  absname   :: CId ,
  cncnames  :: [CId] ,
  abstract  :: Abstr ,
  concretes :: Map CId Concr
  }
 type Abstr = Map CId Type
 type Concr = Map CId Term
 lookMap :: (Show i, Ord i) => i -> Map i a -> a 
 lookMap c m = maybe (error ("cannot find " ++ show c)) id $ Data.Map.lookup c m
 lookLin :: GFCC -> CId -> CId -> Term
 lookLin mcfg lang fun = lookMap fun $ lookMap lang $ concretes mcfg
 linearize :: GFCC -> CId -> Exp -> String
 linearize mcfg lang = realize . linExp mcfg lang
 realize :: Term -> String
 realize trm = case trm of
  R (t:_)  -> realize t
  S ss     -> unwords $ Prelude.map realize ss
  K (KS s) -> s
  K (KP s _) -> unwords s ---- prefix choice TODO
 linExp :: GFCC -> CId -> Exp -> Term
 linExp mcfg lang tree@(Tr at trees) = 
  case at of
    AC fun -> comp (Prelude.map lin trees) $ look fun
    AS s   -> R [kks s] ---- quoted
    AI i   -> R [kks (show i)]
 where
   lin  = linExp mcfg lang
   comp = compute mcfg lang
   look = lookLin mcfg lang
 kks :: String -> Term
 kks = K . KS
 compute :: GFCC -> CId -> [Term] -> Term -> Term
 compute mcfg lang args trm = case trm of
  P r p -> case (comp r, comp p) of 
    (W s (R ss), C i) -> case comp $ ss !! (fromInteger i) of
      K (KS u) -> kks (s ++ u)      -- the only case where W occurs 
    (R rs, C i) -> comp $ rs !! (fromInteger i)
    (r',p') -> P r' p'
  V i   -> args !! (fromInteger i)  -- already computed
  S ts  -> S (Prelude.map comp ts)
  F c   -> comp $ look c  -- global constant: not yet comp'd (if contains argvar)
  FV ts -> FV $ Prelude.map comp ts
  _ -> trm
 where
   comp = compute mcfg lang args
   look = lookLin mcfg lang
 mkGFCC :: Grammar -> GFCC
 mkGFCC (Grm (Hdr a cs) ab@(Abs funs) ccs) = GFCC {
  absname = a,
  cncnames = cs,
  abstract = fromAscList [(fun,typ)    | Fun fun typ _ <- funs] ,
  concretes = fromAscList [(lang, mkCnc lins) | Cnc lang lins <- ccs]
  }
 where
   mkCnc lins = fromAscList [(fun,lin) | Lin fun lin <- lins]
--- a/src/GF/Canon/GFCC/ErrM.hs
+++ b/src/GF/Canon/GFCC/ErrM.hs
@@ -0,0 +1,16 @@
 -- BNF Converter: Error Monad
 -- Copyright (C) 2004  Author:  Aarne Ranta
 -- This file comes with NO WARRANTY and may be used FOR ANY PURPOSE.
 module ErrM where
 -- the Error monad: like Maybe type with error msgs
 data Err a = Ok a | Bad String
  deriving (Read, Show, Eq)
 instance Monad Err where
  return      = Ok
  fail        = Bad
  Ok a  >>= f = f a
  Bad s >>= f = Bad s
--- a/src/GF/Canon/GFCC/GFCC.cf
+++ b/src/GF/Canon/GFCC/GFCC.cf
@@ -0,0 +1,42 @@
 Grm. Grammar  ::= Header ";" Abstract ";" [Concrete] ";" ;
 Hdr. Header   ::= "grammar" CId "(" [CId] ")" ;
 Abs. Abstract ::= "abstract" "{" [AbsDef] "}" ";" ;
 Cnc. Concrete ::= "concrete" CId "{" [CncDef] "}" ;
 Fun. AbsDef   ::= CId ":" Type "=" Exp ;
 Lin. CncDef   ::= CId "=" Term ;
 Typ. Type     ::= [CId] "->" CId ;
 Tr.  Exp      ::= "(" Atom [Exp] ")" ;
 AC.  Atom     ::= CId ;
 AS.  Atom     ::= String ;
 AI.  Atom     ::= Integer ;
 R.   Term     ::= "[" [Term] "]" ;          -- record/table
 P.   Term     ::= Term "[" Term "]" ;       -- projection/selection
 S.   Term     ::= "(" [Term] ")" ;          -- sequence with ++
 K.   Term     ::= Tokn ;                    -- token
 V.   Term     ::= "$" Integer ;             -- argument
 C.   Term     ::= Integer ;                 -- parameter value/label
 F.   Term     ::= CId ;                     -- global constant
 FV.  Term     ::= "[|" [Term] "|]" ;        -- free variation
 W.   Term     ::= "(" String "+" Term ")" ; -- prefix + suffix table
 KS.  Tokn  ::= String ;
 KP.  Tokn  ::= "[" "pre" [String] "[" [Variant] "]" "]" ;
 Var. Variant ::= [String] "/" [String] ;
 terminator Concrete ";" ;
 terminator AbsDef ";" ;
 terminator CncDef ";" ;
 terminator CId "" ;
 separator  Term "," ;
 terminator Exp "" ;
 terminator String "" ;
 separator  Variant "," ;
 token CId (('_' | letter) (letter | digit | '\'' | '_')*) ;
--- a/src/GF/Canon/GFCC/LexGFCC.hs
+++ b/src/GF/Canon/GFCC/LexGFCC.hs
@@ -0,0 +1,348 @@
 {-# OPTIONS -fglasgow-exts -cpp #-}
 {-# LINE 3 "LexGFCC.x" #-}
 {-# OPTIONS -fno-warn-incomplete-patterns #-}
 module LexGFCC where
 #if __GLASGOW_HASKELL__ >= 603
 #include "ghcconfig.h"
 #else
 #include "config.h"
 #endif
 #if __GLASGOW_HASKELL__ >= 503
 import Data.Array
 import Data.Char (ord)
 import Data.Array.Base (unsafeAt)
 #else
 import Array
 import Char (ord)
 #endif
 #if __GLASGOW_HASKELL__ >= 503
 import GHC.Exts
 #else
 import GlaExts
 #endif
 alex_base :: AlexAddr
 alex_base = AlexA# "\x01\x00\x00\x00\x39\x00\x00\x00\x42\x00\x00\x00\x00\x00\x00\x00\xcb\xff\xff\xff\x0a\x00\x00\x00\xec\xff\xff\xff\x9a\x00\x00\x00\x6a\x01\x00\x00\x00\x00\x00\x00\x15\x01\x00\x00\xd3\x00\x00\x00\x33\x00\x00\x00"#
 alex_table :: AlexAddr
 alex_table = AlexA# "\x00\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\x02\x00\x02\x00\x02\x00\x02\x00\x02\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\x02\x00\xff\xff\x0a\x00\xff\xff\x03\x00\xff\xff\xff\xff\xff\xff\x03\x00\x03\x00\xff\xff\x03\x00\x03\x00\x05\x00\xff\xff\x03\x00\x0c\x00\x0c\x00\x0c\x00\x0c\x00\x0c\x00\x0c\x00\x0c\x00\x0c\x00\x0c\x00\x0c\x00\x03\x00\x03\x00\xff\xff\x03\x00\xff\xff\xff\xff\xff\xff\x02\x00\x02\x00\x02\x00\x02\x00\x02\x00\x03\x00\x03\x00\x03\x00\x00\x00\x02\x00\x02\x00\x02\x00\x02\x00\x02\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x02\x00\x00\x00\x00\x00\x04\x00\xff\xff\x03\x00\xff\xff\x07\x00\xff\xff\x02\x00\x0c\x00\x0c\x00\x0c\x00\x0c\x00\x0c\x00\x0c\x00\x0c\x00\x0c\x00\x0c\x00\x0c\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x03\x00\x06\x00\x03\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\x07\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x00\x00\x00\x00\x00\x00\x00\x00\xff\xff\x00\x00\x00\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x0a\x00\x00\x00\x00\x00\xff\xff\x07\x00\x0a\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\xff\xff\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x0a\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x09\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x0a\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x0a\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x0b\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x08\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x07\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x00\x00\x00\x00\x00\x00\x00\x00\x08\x00\x00\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x00\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x00\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00\x08\x00"#
 alex_check :: AlexAddr
 alex_check = AlexA# "\xff\xff\x00\x00\x01\x00\x02\x00\x03\x00\x04\x00\x05\x00\x06\x00\x07\x00\x08\x00\x09\x00\x0a\x00\x0b\x00\x0c\x00\x0d\x00\x0e\x00\x0f\x00\x10\x00\x11\x00\x12\x00\x13\x00\x14\x00\x15\x00\x16\x00\x17\x00\x18\x00\x19\x00\x1a\x00\x1b\x00\x1c\x00\x1d\x00\x1e\x00\x1f\x00\x20\x00\x21\x00\x22\x00\x23\x00\x24\x00\x25\x00\x26\x00\x27\x00\x28\x00\x29\x00\x2a\x00\x2b\x00\x2c\x00\x2d\x00\x2e\x00\x2f\x00\x30\x00\x31\x00\x32\x00\x33\x00\x34\x00\x35\x00\x36\x00\x37\x00\x38\x00\x39\x00\x3a\x00\x3b\x00\x3c\x00\x3d\x00\x3e\x00\x3f\x00\x40\x00\x09\x00\x0a\x00\x0b\x00\x0c\x00\x0d\x00\x7c\x00\x3e\x00\x5d\x00\xff\xff\x09\x00\x0a\x00\x0b\x00\x0c\x00\x0d\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\x20\x00\xff\xff\xff\xff\x5b\x00\x5c\x00\x5d\x00\x5e\x00\x5f\x00\x60\x00\x20\x00\x30\x00\x31\x00\x32\x00\x33\x00\x34\x00\x35\x00\x36\x00\x37\x00\x38\x00\x39\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\x7b\x00\x7c\x00\x7d\x00\x7e\x00\x7f\x00\x80\x00\x81\x00\x82\x00\x83\x00\x84\x00\x85\x00\x86\x00\x87\x00\x88\x00\x89\x00\x8a\x00\x8b\x00\x8c\x00\x8d\x00\x8e\x00\x8f\x00\x90\x00\x91\x00\x92\x00\x93\x00\x94\x00\x95\x00\x96\x00\x97\x00\x98\x00\x99\x00\x9a\x00\x9b\x00\x9c\x00\x9d\x00\x9e\x00\x9f\x00\xa0\x00\xa1\x00\xa2\x00\xa3\x00\xa4\x00\xa5\x00\xa6\x00\xa7\x00\xa8\x00\xa9\x00\xaa\x00\xab\x00\xac\x00\xad\x00\xae\x00\xaf\x00\xb0\x00\xb1\x00\xb2\x00\xb3\x00\xb4\x00\xb5\x00\xb6\x00\xb7\x00\xb8\x00\xb9\x00\xba\x00\xbb\x00\xbc\x00\xbd\x00\xbe\x00\xbf\x00\x27\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\x30\x00\x31\x00\x32\x00\x33\x00\x34\x00\x35\x00\x36\x00\x37\x00\x38\x00\x39\x00\xff\xff\xff\xff\xff\xff\xff\xff\xd7\x00\xff\xff\xff\xff\x41\x00\x42\x00\x43\x00\x44\x00\x45\x00\x46\x00\x47\x00\x48\x00\x49\x00\x4a\x00\x4b\x00\x4c\x00\x4d\x00\x4e\x00\x4f\x00\x50\x00\x51\x00\x52\x00\x53\x00\x54\x00\x55\x00\x56\x00\x57\x00\x58\x00\x59\x00\x5a\x00\x22\x00\xff\xff\xff\xff\xf7\x00\x5f\x00\x27\x00\x61\x00\x62\x00\x63\x00\x64\x00\x65\x00\x66\x00\x67\x00\x68\x00\x69\x00\x6a\x00\x6b\x00\x6c\x00\x6d\x00\x6e\x00\x6f\x00\x70\x00\x71\x00\x72\x00\x73\x00\x74\x00\x75\x00\x76\x00\x77\x00\x78\x00\x79\x00\x7a\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\x0a\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\x5c\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\x22\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\x6e\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\x74\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xc0\x00\xc1\x00\xc2\x00\xc3\x00\xc4\x00\xc5\x00\xc6\x00\xc7\x00\xc8\x00\xc9\x00\xca\x00\xcb\x00\xcc\x00\xcd\x00\xce\x00\xcf\x00\xd0\x00\xd1\x00\xd2\x00\xd3\x00\xd4\x00\xd5\x00\xd6\x00\x5c\x00\xd8\x00\xd9\x00\xda\x00\xdb\x00\xdc\x00\xdd\x00\xde\x00\xdf\x00\xe0\x00\xe1\x00\xe2\x00\xe3\x00\xe4\x00\xe5\x00\xe6\x00\xe7\x00\xe8\x00\xe9\x00\xea\x00\xeb\x00\xec\x00\xed\x00\xee\x00\xef\x00\xf0\x00\xf1\x00\xf2\x00\xf3\x00\xf4\x00\xf5\x00\xf6\x00\x27\x00\xf8\x00\xf9\x00\xfa\x00\xfb\x00\xfc\x00\xfd\x00\xfe\x00\xff\x00\x30\x00\x31\x00\x32\x00\x33\x00\x34\x00\x35\x00\x36\x00\x37\x00\x38\x00\x39\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\x41\x00\x42\x00\x43\x00\x44\x00\x45\x00\x46\x00\x47\x00\x48\x00\x49\x00\x4a\x00\x4b\x00\x4c\x00\x4d\x00\x4e\x00\x4f\x00\x50\x00\x51\x00\x52\x00\x53\x00\x54\x00\x55\x00\x56\x00\x57\x00\x58\x00\x59\x00\x5a\x00\xff\xff\xff\xff\xff\xff\xff\xff\x5f\x00\xff\xff\x61\x00\x62\x00\x63\x00\x64\x00\x65\x00\x66\x00\x67\x00\x68\x00\x69\x00\x6a\x00\x6b\x00\x6c\x00\x6d\x00\x6e\x00\x6f\x00\x70\x00\x71\x00\x72\x00\x73\x00\x74\x00\x75\x00\x76\x00\x77\x00\x78\x00\x79\x00\x7a\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xc0\x00\xc1\x00\xc2\x00\xc3\x00\xc4\x00\xc5\x00\xc6\x00\xc7\x00\xc8\x00\xc9\x00\xca\x00\xcb\x00\xcc\x00\xcd\x00\xce\x00\xcf\x00\xd0\x00\xd1\x00\xd2\x00\xd3\x00\xd4\x00\xd5\x00\xd6\x00\xff\xff\xd8\x00\xd9\x00\xda\x00\xdb\x00\xdc\x00\xdd\x00\xde\x00\xdf\x00\xe0\x00\xe1\x00\xe2\x00\xe3\x00\xe4\x00\xe5\x00\xe6\x00\xe7\x00\xe8\x00\xe9\x00\xea\x00\xeb\x00\xec\x00\xed\x00\xee\x00\xef\x00\xf0\x00\xf1\x00\xf2\x00\xf3\x00\xf4\x00\xf5\x00\xf6\x00\xff\xff\xf8\x00\xf9\x00\xfa\x00\xfb\x00\xfc\x00\xfd\x00\xfe\x00\xff\x00"#
 alex_deflt :: AlexAddr
 alex_deflt = AlexA# "\x08\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\x0a\x00\xff\xff\xff\xff"#
 alex_accept = listArray (0::Int,12) [[],[],[(AlexAccSkip)],[(AlexAcc (alex_action_1))],[(AlexAcc (alex_action_1))],[],[],[(AlexAcc (alex_action_2))],[(AlexAcc (alex_action_2))],[(AlexAcc (alex_action_4))],[],[],[(AlexAcc (alex_action_5))]]
 {-# LINE 33 "LexGFCC.x" #-}
 tok f p s = f p s
 share :: String -> String
 share = id
 data Tok =
   TS !String     -- reserved words and symbols
 | TL !String     -- string literals
 | TI !String     -- integer literals
 | TV !String     -- identifiers
 | TD !String     -- double precision float literals
 | TC !String     -- character literals
 | T_CId !String
 deriving (Eq,Show,Ord)
 data Token = 
   PT  Posn Tok
 | Err Posn
  deriving (Eq,Show,Ord)
 tokenPos (PT (Pn _ l _) _ :_) = "line " ++ show l
 tokenPos (Err (Pn _ l _) :_) = "line " ++ show l
 tokenPos _ = "end of file"
 posLineCol (Pn _ l c) = (l,c)
 mkPosToken t@(PT p _) = (posLineCol p, prToken t)
 prToken t = case t of
  PT _ (TS s) -> s
  PT _ (TI s) -> s
  PT _ (TV s) -> s
  PT _ (TD s) -> s
  PT _ (TC s) -> s
  PT _ (T_CId s) -> s
  _ -> show t
 data BTree = N | B String Tok BTree BTree deriving (Show)
 eitherResIdent :: (String -> Tok) -> String -> Tok
 eitherResIdent tv s = treeFind resWords
  where
  treeFind N = tv s
  treeFind (B a t left right) | s < a  = treeFind left
                              | s > a  = treeFind right
                              | s == a = t
 resWords = b "grammar" (b "concrete" (b "abstract" N N) N) (b "pre" N N)
   where b s = B s (TS s)
 unescapeInitTail :: String -> String
 unescapeInitTail = unesc . tail where
  unesc s = case s of
    '\\':c:cs | elem c ['\"', '\\', '\''] -> c : unesc cs
    '\\':'n':cs  -> '\n' : unesc cs
    '\\':'t':cs  -> '\t' : unesc cs
    '"':[]    -> []
    c:cs      -> c : unesc cs
    _         -> []
 -------------------------------------------------------------------
 -- Alex wrapper code.
 -- A modified "posn" wrapper.
 -------------------------------------------------------------------
 data Posn = Pn !Int !Int !Int
      deriving (Eq, Show,Ord)
 alexStartPos :: Posn
 alexStartPos = Pn 0 1 1
 alexMove :: Posn -> Char -> Posn
 alexMove (Pn a l c) '\t' = Pn (a+1)  l     (((c+7) `div` 8)*8+1)
 alexMove (Pn a l c) '\n' = Pn (a+1) (l+1)   1
 alexMove (Pn a l c) _    = Pn (a+1)  l     (c+1)
 type AlexInput = (Posn, -- current position,
 		  Char,	-- previous char
 		  String)	-- current input string
 tokens :: String -> [Token]
 tokens str = go (alexStartPos, '\n', str)
    where
      go :: (Posn, Char, String) -> [Token]
      go inp@(pos, _, str) =
    	  case alexScan inp 0 of
    	    AlexEOF                -> []
    	    AlexError (pos, _, _)  -> [Err pos]
    	    AlexSkip  inp' len     -> go inp'
    	    AlexToken inp' len act -> act pos (take len str) : (go inp')
 alexGetChar :: AlexInput -> Maybe (Char,AlexInput)
 alexGetChar (p, c, [])    = Nothing
 alexGetChar (p, _, (c:s)) =
    let p' = alexMove p c
     in p' `seq` Just (c, (p', c, s))
 alexInputPrevChar :: AlexInput -> Char
 alexInputPrevChar (p, c, s) = c
 alex_action_1 = tok (\p s -> PT p (TS $ share s)) 
 alex_action_2 = tok (\p s -> PT p (eitherResIdent (T_CId . share) s)) 
 alex_action_3 = tok (\p s -> PT p (eitherResIdent (TV . share) s)) 
 alex_action_4 = tok (\p s -> PT p (TL $ share $ unescapeInitTail s)) 
 alex_action_5 = tok (\p s -> PT p (TI $ share s))    
 {-# LINE 1 "GenericTemplate.hs" #-}
 {-# LINE 1 "<built-in>" #-}
 {-# LINE 1 "<command line>" #-}
 {-# LINE 1 "GenericTemplate.hs" #-}
 -- -----------------------------------------------------------------------------
 -- ALEX TEMPLATE
 --
 -- This code is in the PUBLIC DOMAIN; you may copy it freely and use
 -- it for any purpose whatsoever.
 -- -----------------------------------------------------------------------------
 -- INTERNALS and main scanner engine
 {-# LINE 35 "GenericTemplate.hs" #-}
 data AlexAddr = AlexA# Addr#
 #if __GLASGOW_HASKELL__ < 503
 uncheckedShiftL# = shiftL#
 #endif
 {-# INLINE alexIndexInt16OffAddr #-}
 alexIndexInt16OffAddr (AlexA# arr) off =
 #ifdef WORDS_BIGENDIAN
  narrow16Int# i
  where
 	i    = word2Int# ((high `uncheckedShiftL#` 8#) `or#` low)
 	high = int2Word# (ord# (indexCharOffAddr# arr (off' +# 1#)))
 	low  = int2Word# (ord# (indexCharOffAddr# arr off'))
 	off' = off *# 2#
 #else
  indexInt16OffAddr# arr off
 #endif
 {-# INLINE alexIndexInt32OffAddr #-}
 alexIndexInt32OffAddr (AlexA# arr) off = 
 #ifdef WORDS_BIGENDIAN
  narrow32Int# i
  where
   i    = word2Int# ((b3 `uncheckedShiftL#` 24#) `or#`
 		     (b2 `uncheckedShiftL#` 16#) `or#`
 		     (b1 `uncheckedShiftL#` 8#) `or#` b0)
   b3   = int2Word# (ord# (indexCharOffAddr# arr (off' +# 3#)))
   b2   = int2Word# (ord# (indexCharOffAddr# arr (off' +# 2#)))
   b1   = int2Word# (ord# (indexCharOffAddr# arr (off' +# 1#)))
   b0   = int2Word# (ord# (indexCharOffAddr# arr off'))
   off' = off *# 4#
 #else
  indexInt32OffAddr# arr off
 #endif
 #if __GLASGOW_HASKELL__ < 503
 quickIndex arr i = arr ! i
 #else
 -- GHC >= 503, unsafeAt is available from Data.Array.Base.
 quickIndex = unsafeAt
 #endif
 -- -----------------------------------------------------------------------------
 -- Main lexing routines
 data AlexReturn a
  = AlexEOF
  | AlexError  !AlexInput
  | AlexSkip   !AlexInput !Int
  | AlexToken  !AlexInput !Int a
 -- alexScan :: AlexInput -> StartCode -> Maybe (AlexInput,Int,act)
 alexScan input (I# (sc))
  = alexScanUser undefined input (I# (sc))
 alexScanUser user input (I# (sc))
  = case alex_scan_tkn user input 0# input sc AlexNone of
 	(AlexNone, input') ->
 		case alexGetChar input of
 			Nothing -> 
 				   AlexEOF
 			Just _ ->
 				   AlexError input'
 	(AlexLastSkip input len, _) ->
 		AlexSkip input len
 	(AlexLastAcc k input len, _) ->
 		AlexToken input len k
 -- Push the input through the DFA, remembering the most recent accepting
 -- state it encountered.
 alex_scan_tkn user orig_input len input s last_acc =
  input `seq` -- strict in the input
  case s of 
    -1# -> (last_acc, input)
    _ -> alex_scan_tkn' user orig_input len input s last_acc
 alex_scan_tkn' user orig_input len input s last_acc =
  let 
 	new_acc = check_accs (alex_accept `quickIndex` (I# (s)))
  in
  new_acc `seq`
  case alexGetChar input of
     Nothing -> (new_acc, input)
     Just (c, new_input) -> 
 	let
 		base   = alexIndexInt32OffAddr alex_base s
 		(I# (ord_c)) = ord c
 		offset = (base +# ord_c)
 		check  = alexIndexInt16OffAddr alex_check offset
 		new_s = if (offset >=# 0#) && (check ==# ord_c)
 			  then alexIndexInt16OffAddr alex_table offset
 			  else alexIndexInt16OffAddr alex_deflt s
 	in
 	alex_scan_tkn user orig_input (len +# 1#) new_input new_s new_acc
  where
 	check_accs [] = last_acc
 	check_accs (AlexAcc a : _) = AlexLastAcc a input (I# (len))
 	check_accs (AlexAccSkip : _)  = AlexLastSkip  input (I# (len))
 	check_accs (AlexAccPred a pred : rest)
 	   | pred user orig_input (I# (len)) input
 	   = AlexLastAcc a input (I# (len))
 	check_accs (AlexAccSkipPred pred : rest)
 	   | pred user orig_input (I# (len)) input
 	   = AlexLastSkip input (I# (len))
 	check_accs (_ : rest) = check_accs rest
 data AlexLastAcc a
  = AlexNone
  | AlexLastAcc a !AlexInput !Int
  | AlexLastSkip  !AlexInput !Int
 data AlexAcc a user
  = AlexAcc a
  | AlexAccSkip
  | AlexAccPred a (AlexAccPred user)
  | AlexAccSkipPred (AlexAccPred user)
 type AlexAccPred user = user -> AlexInput -> Int -> AlexInput -> Bool
 -- -----------------------------------------------------------------------------
 -- Predicates on a rule
 alexAndPred p1 p2 user in1 len in2
  = p1 user in1 len in2 && p2 user in1 len in2
 --alexPrevCharIsPred :: Char -> AlexAccPred _ 
 alexPrevCharIs c _ input _ _ = c == alexInputPrevChar input
 --alexPrevCharIsOneOfPred :: Array Char Bool -> AlexAccPred _ 
 alexPrevCharIsOneOf arr _ input _ _ = arr ! alexInputPrevChar input
 --alexRightContext :: Int -> AlexAccPred _
 alexRightContext (I# (sc)) user _ _ input = 
     case alex_scan_tkn user input 0# input sc AlexNone of
 	  (AlexNone, _) -> False
 	  _ -> True
 	-- TODO: there's no need to find the longest
 	-- match when checking the right context, just
 	-- the first match will do.
 -- used by wrappers
 iUnbox (I# (i)) = i
--- a/src/GF/Canon/GFCC/ParGFCC.hs
+++ b/src/GF/Canon/GFCC/ParGFCC.hs
@@ -0,0 +1,999 @@
 {-# OPTIONS -fglasgow-exts -cpp #-}
 {-# OPTIONS -fno-warn-incomplete-patterns -fno-warn-overlapping-patterns #-}
 module ParGFCC where
 import AbsGFCC
 import LexGFCC
 import ErrM
 import Array
 #if __GLASGOW_HASKELL__ >= 503
 import GHC.Exts
 #else
 import GlaExts
 #endif
 -- parser produced by Happy Version 1.15
 newtype HappyAbsSyn  = HappyAbsSyn (() -> ())
 happyIn23 :: (String) -> (HappyAbsSyn )
 happyIn23 x = unsafeCoerce# x
 {-# INLINE happyIn23 #-}
 happyOut23 :: (HappyAbsSyn ) -> (String)
 happyOut23 x = unsafeCoerce# x
 {-# INLINE happyOut23 #-}
 happyIn24 :: (Integer) -> (HappyAbsSyn )
 happyIn24 x = unsafeCoerce# x
 {-# INLINE happyIn24 #-}
 happyOut24 :: (HappyAbsSyn ) -> (Integer)
 happyOut24 x = unsafeCoerce# x
 {-# INLINE happyOut24 #-}
 happyIn25 :: (CId) -> (HappyAbsSyn )
 happyIn25 x = unsafeCoerce# x
 {-# INLINE happyIn25 #-}
 happyOut25 :: (HappyAbsSyn ) -> (CId)
 happyOut25 x = unsafeCoerce# x
 {-# INLINE happyOut25 #-}
 happyIn26 :: (Grammar) -> (HappyAbsSyn )
 happyIn26 x = unsafeCoerce# x
 {-# INLINE happyIn26 #-}
 happyOut26 :: (HappyAbsSyn ) -> (Grammar)
 happyOut26 x = unsafeCoerce# x
 {-# INLINE happyOut26 #-}
 happyIn27 :: (Header) -> (HappyAbsSyn )
 happyIn27 x = unsafeCoerce# x
 {-# INLINE happyIn27 #-}
 happyOut27 :: (HappyAbsSyn ) -> (Header)
 happyOut27 x = unsafeCoerce# x
 {-# INLINE happyOut27 #-}
 happyIn28 :: (Abstract) -> (HappyAbsSyn )
 happyIn28 x = unsafeCoerce# x
 {-# INLINE happyIn28 #-}
 happyOut28 :: (HappyAbsSyn ) -> (Abstract)
 happyOut28 x = unsafeCoerce# x
 {-# INLINE happyOut28 #-}
 happyIn29 :: (Concrete) -> (HappyAbsSyn )
 happyIn29 x = unsafeCoerce# x
 {-# INLINE happyIn29 #-}
 happyOut29 :: (HappyAbsSyn ) -> (Concrete)
 happyOut29 x = unsafeCoerce# x
 {-# INLINE happyOut29 #-}
 happyIn30 :: (AbsDef) -> (HappyAbsSyn )
 happyIn30 x = unsafeCoerce# x
 {-# INLINE happyIn30 #-}
 happyOut30 :: (HappyAbsSyn ) -> (AbsDef)
 happyOut30 x = unsafeCoerce# x
 {-# INLINE happyOut30 #-}
 happyIn31 :: (CncDef) -> (HappyAbsSyn )
 happyIn31 x = unsafeCoerce# x
 {-# INLINE happyIn31 #-}
 happyOut31 :: (HappyAbsSyn ) -> (CncDef)
 happyOut31 x = unsafeCoerce# x
 {-# INLINE happyOut31 #-}
 happyIn32 :: (Type) -> (HappyAbsSyn )
 happyIn32 x = unsafeCoerce# x
 {-# INLINE happyIn32 #-}
 happyOut32 :: (HappyAbsSyn ) -> (Type)
 happyOut32 x = unsafeCoerce# x
 {-# INLINE happyOut32 #-}
 happyIn33 :: (Exp) -> (HappyAbsSyn )
 happyIn33 x = unsafeCoerce# x
 {-# INLINE happyIn33 #-}
 happyOut33 :: (HappyAbsSyn ) -> (Exp)
 happyOut33 x = unsafeCoerce# x
 {-# INLINE happyOut33 #-}
 happyIn34 :: (Atom) -> (HappyAbsSyn )
 happyIn34 x = unsafeCoerce# x
 {-# INLINE happyIn34 #-}
 happyOut34 :: (HappyAbsSyn ) -> (Atom)
 happyOut34 x = unsafeCoerce# x
 {-# INLINE happyOut34 #-}
 happyIn35 :: (Term) -> (HappyAbsSyn )
 happyIn35 x = unsafeCoerce# x
 {-# INLINE happyIn35 #-}
 happyOut35 :: (HappyAbsSyn ) -> (Term)
 happyOut35 x = unsafeCoerce# x
 {-# INLINE happyOut35 #-}
 happyIn36 :: (Tokn) -> (HappyAbsSyn )
 happyIn36 x = unsafeCoerce# x
 {-# INLINE happyIn36 #-}
 happyOut36 :: (HappyAbsSyn ) -> (Tokn)
 happyOut36 x = unsafeCoerce# x
 {-# INLINE happyOut36 #-}
 happyIn37 :: (Variant) -> (HappyAbsSyn )
 happyIn37 x = unsafeCoerce# x
 {-# INLINE happyIn37 #-}
 happyOut37 :: (HappyAbsSyn ) -> (Variant)
 happyOut37 x = unsafeCoerce# x
 {-# INLINE happyOut37 #-}
 happyIn38 :: ([Concrete]) -> (HappyAbsSyn )
 happyIn38 x = unsafeCoerce# x
 {-# INLINE happyIn38 #-}
 happyOut38 :: (HappyAbsSyn ) -> ([Concrete])
 happyOut38 x = unsafeCoerce# x
 {-# INLINE happyOut38 #-}
 happyIn39 :: ([AbsDef]) -> (HappyAbsSyn )
 happyIn39 x = unsafeCoerce# x
 {-# INLINE happyIn39 #-}
 happyOut39 :: (HappyAbsSyn ) -> ([AbsDef])
 happyOut39 x = unsafeCoerce# x
 {-# INLINE happyOut39 #-}
 happyIn40 :: ([CncDef]) -> (HappyAbsSyn )
 happyIn40 x = unsafeCoerce# x
 {-# INLINE happyIn40 #-}
 happyOut40 :: (HappyAbsSyn ) -> ([CncDef])
 happyOut40 x = unsafeCoerce# x
 {-# INLINE happyOut40 #-}
 happyIn41 :: ([CId]) -> (HappyAbsSyn )
 happyIn41 x = unsafeCoerce# x
 {-# INLINE happyIn41 #-}
 happyOut41 :: (HappyAbsSyn ) -> ([CId])
 happyOut41 x = unsafeCoerce# x
 {-# INLINE happyOut41 #-}
 happyIn42 :: ([Term]) -> (HappyAbsSyn )
 happyIn42 x = unsafeCoerce# x
 {-# INLINE happyIn42 #-}
 happyOut42 :: (HappyAbsSyn ) -> ([Term])
 happyOut42 x = unsafeCoerce# x
 {-# INLINE happyOut42 #-}
 happyIn43 :: ([Exp]) -> (HappyAbsSyn )
 happyIn43 x = unsafeCoerce# x
 {-# INLINE happyIn43 #-}
 happyOut43 :: (HappyAbsSyn ) -> ([Exp])
 happyOut43 x = unsafeCoerce# x
 {-# INLINE happyOut43 #-}
 happyIn44 :: ([String]) -> (HappyAbsSyn )
 happyIn44 x = unsafeCoerce# x
 {-# INLINE happyIn44 #-}
 happyOut44 :: (HappyAbsSyn ) -> ([String])
 happyOut44 x = unsafeCoerce# x
 {-# INLINE happyOut44 #-}
 happyIn45 :: ([Variant]) -> (HappyAbsSyn )
 happyIn45 x = unsafeCoerce# x
 {-# INLINE happyIn45 #-}
 happyOut45 :: (HappyAbsSyn ) -> ([Variant])
 happyOut45 x = unsafeCoerce# x
 {-# INLINE happyOut45 #-}
 happyInTok :: Token -> (HappyAbsSyn )
 happyInTok x = unsafeCoerce# x
 {-# INLINE happyInTok #-}
 happyOutTok :: (HappyAbsSyn ) -> Token
 happyOutTok x = unsafeCoerce# x
 {-# INLINE happyOutTok #-}
 happyActOffsets :: HappyAddr
 happyActOffsets = HappyA# "\xd1\x00\xd1\x00\xd2\x00\xce\x00\xcb\x00\xcb\x00\x00\x00\xc9\x00\x72\x00\x09\x00\x3a\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x09\x00\x00\x00\x00\x00\xc8\x00\xca\x00\x00\x00\xc6\x00\x6f\x00\xc5\x00\xf1\xff\xff\xff\x00\x00\x00\x00\x00\x00\x71\x00\x00\x00\xc5\x00\x09\x00\x05\x00\xc7\x00\x09\x00\x00\x00\x00\x00\x69\x00\x69\x00\x69\x00\x59\x00\xc3\x00\xc3\x00\xc4\x00\x0e\x00\x00\x00\x00\x00\x00\x00\xc2\x00\xc2\x00\x72\x00\xc2\x00\x2b\x00\xc1\x00\xc0\x00\xbf\x00\xbe\x00\xbe\x00\xb7\x00\xb6\x00\xbd\x00\xb4\x00\xb3\x00\xaa\x00\xbb\x00\xaf\x00\xbc\x00\x00\x00\xb9\x00\x00\x00\x09\x00\x00\x00\x8d\x00\x00\x00\x09\x00\x00\x00\xba\x00\xb8\x00\xb5\x00\xad\x00\x00\x00\xae\x00\xa9\x00\xb2\x00\x09\x00\x00\x00\x00\x00\x00\x00\x1d\x00\x00\x00\x90\x00\x00\x00\x00\x00\x09\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\xfa\xff\x85\x00\x8a\x00\x00\x00\xab\x00\xac\x00\x00\x00\x2a\x00\x00\x00\xb1\x00\x00\x00\x06\x00\xb0\x00\x11\x00\xa8\x00\x00\x00\x00\x00\x1d\x00\x7c\x00\x00\x00\xa6\x00\x00\x00\x00\x00\x00\x00\x00\x00\x01\x00\x00\x00\xa5\x00\x00\x00\x00\x00"#
 happyGotoOffsets :: HappyAddr
 happyGotoOffsets = HappyA# "\x87\x00\xa3\x00\xa4\x00\xa2\x00\x6e\x00\x7b\x00\x5c\x00\xa1\x00\x68\x00\x5a\x00\x51\x00\xf7\xff\x9f\x00\x9d\x00\x9b\x00\x94\x00\x3d\x00\x8f\x00\x8c\x00\x66\x00\x00\x00\x00\x00\x00\x00\xa0\x00\x00\x00\xa0\x00\x98\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x38\x00\x29\x00\x9e\x00\x24\x00\x00\x00\x00\x00\x9c\x00\x55\x00\x39\x00\x97\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x62\x00\x00\x00\x9a\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x99\x00\x00\x00\x00\x00\x00\x00\x96\x00\x00\x00\x00\x00\x95\x00\x00\x00\x89\x00\x00\x00\xfb\xff\x54\x00\x00\x00\x92\x00\x83\x00\x4c\x00\x81\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x21\x00\x00\x00\x00\x00\x80\x00\x63\x00\x00\x00\x93\x00\x00\x00\x00\x00\x46\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x93\x00\x00\x00\x88\x00\x00\x00\x00\x00\x00\x00\x5b\x00\x39\x00\x7f\x00\x00\x00\x77\x00\x5d\x00\x00\x00\x55\x00\x86\x00\x00\x00\x00\x00\x61\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x02\x00\x00\x00\x00\x00\x00\x00\x00\x00"#
 happyDefActions :: HappyAddr
 happyDefActions = HappyA# "\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\xcb\xff\x00\x00\x00\x00\x00\x00\x00\x00\xc4\xff\xd1\xff\xcf\xff\xcd\xff\xcb\xff\xc9\xff\xc6\xff\xc4\xff\xc4\xff\x00\x00\xeb\xff\xc1\xff\x00\x00\x00\x00\x00\x00\x00\x00\xd4\xff\xd8\xff\xd7\xff\xc8\xff\xda\xff\x00\x00\xc9\xff\xc9\xff\x00\x00\xc9\xff\xea\xff\xe9\xff\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\xdf\xff\xde\xff\xe0\xff\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\xcf\xff\x00\x00\xcb\xff\x00\x00\xca\xff\x00\x00\xc6\xff\x00\x00\xc4\xff\x00\x00\x00\x00\x00\x00\x00\x00\xd9\xff\x00\x00\xd4\xff\x00\x00\xc9\xff\xc5\xff\xc3\xff\xc4\xff\xc2\xff\xc0\xff\xd2\xff\xc7\xff\xdb\xff\x00\x00\xdd\xff\xd6\xff\xcc\xff\xce\xff\xd0\xff\x00\x00\x00\x00\x00\x00\xe2\xff\xe3\xff\x00\x00\xcd\xff\x00\x00\xcb\xff\x00\x00\xd1\xff\x00\x00\x00\x00\x00\x00\x00\x00\xe1\xff\xdc\xff\xc2\xff\x00\x00\xd5\xff\x00\x00\xe4\xff\xe5\xff\xe6\xff\xe7\xff\x00\x00\xe8\xff\x00\x00\xd3\xff"#
 happyCheck :: HappyAddr
 happyCheck = HappyA# "\xff\xff\x02\x00\x01\x00\x09\x00\x09\x00\x0e\x00\x15\x00\x02\x00\x06\x00\x03\x00\x19\x00\x02\x00\x15\x00\x12\x00\x09\x00\x15\x00\x0b\x00\x0c\x00\x09\x00\x12\x00\x0b\x00\x0c\x00\x05\x00\x09\x00\x19\x00\x14\x00\x15\x00\x16\x00\x17\x00\x17\x00\x15\x00\x16\x00\x17\x00\x00\x00\x01\x00\x02\x00\x00\x00\x01\x00\x02\x00\x19\x00\x17\x00\x00\x00\x01\x00\x02\x00\x0f\x00\x0c\x00\x0d\x00\x05\x00\x0c\x00\x0d\x00\x15\x00\x08\x00\x13\x00\x0c\x00\x0d\x00\x13\x00\x00\x00\x01\x00\x02\x00\x02\x00\x13\x00\x00\x00\x01\x00\x02\x00\x07\x00\x17\x00\x17\x00\x09\x00\x0c\x00\x0d\x00\x00\x00\x01\x00\x02\x00\x0c\x00\x0d\x00\x13\x00\x00\x00\x01\x00\x02\x00\x15\x00\x13\x00\x00\x00\x0c\x00\x0d\x00\x00\x00\x01\x00\x02\x00\x02\x00\x0c\x00\x0d\x00\x00\x00\x01\x00\x02\x00\x08\x00\x0d\x00\x02\x00\x0c\x00\x0d\x00\x00\x00\x01\x00\x02\x00\x09\x00\x0c\x00\x0d\x00\x00\x00\x01\x00\x02\x00\x12\x00\x11\x00\x0b\x00\x12\x00\x0e\x00\x02\x00\x0e\x00\x19\x00\x0b\x00\x0e\x00\x07\x00\x15\x00\x16\x00\x15\x00\x16\x00\x09\x00\x15\x00\x16\x00\x02\x00\x0f\x00\x03\x00\x17\x00\x10\x00\x19\x00\x08\x00\x15\x00\x09\x00\x0f\x00\x15\x00\x16\x00\x17\x00\x03\x00\x04\x00\x02\x00\x03\x00\x09\x00\x0a\x00\x0a\x00\x12\x00\x0a\x00\x00\x00\x02\x00\x15\x00\x15\x00\x14\x00\x02\x00\x10\x00\x05\x00\x02\x00\x02\x00\x06\x00\x02\x00\x01\x00\x00\x00\x15\x00\x0a\x00\x14\x00\x17\x00\x15\x00\x12\x00\x04\x00\x06\x00\x05\x00\x02\x00\x0a\x00\x11\x00\x10\x00\x0f\x00\x0a\x00\x0a\x00\x01\x00\x01\x00\x07\x00\x09\x00\x03\x00\x01\x00\x0e\x00\x0a\x00\x01\x00\x0d\x00\x01\x00\x01\x00\x04\x00\x02\x00\xff\xff\x11\x00\x04\x00\xff\xff\x19\x00\xff\xff\x06\x00\xff\xff\xff\xff\x07\x00\xff\xff\x17\x00\x02\x00\xff\xff\x19\x00\x17\x00\x19\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\x10\x00\x19\x00\x14\x00\x19\x00\xff\xff\x19\x00\x19\x00\x16\x00\x19\x00\x15\x00\x12\x00\x19\x00\x17\x00\x11\x00\x13\x00\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff\xff"#
 happyTable :: HappyAddr
 happyTable = HappyA# "\x00\x00\x35\x00\x80\x00\x77\x00\x6a\x00\x2b\x00\x16\x00\x22\x00\x4e\x00\x7e\x00\xff\xff\x22\x00\x17\x00\x36\x00\x23\x00\x16\x00\x24\x00\x25\x00\x23\x00\x3d\x00\x24\x00\x25\x00\x7c\x00\x4d\x00\xff\xff\x4e\x00\x16\x00\x26\x00\x27\x00\x27\x00\x16\x00\x26\x00\x27\x00\x1b\x00\x1c\x00\x1d\x00\x1b\x00\x1c\x00\x1d\x00\xff\xff\x27\x00\x1b\x00\x1c\x00\x1d\x00\xc4\xff\x1e\x00\x1f\x00\x72\x00\x1e\x00\x1f\x00\xc4\xff\x4b\x00\x5d\x00\x1e\x00\x1f\x00\x51\x00\x54\x00\x1c\x00\x1d\x00\x39\x00\x53\x00\x1b\x00\x1c\x00\x1d\x00\x4f\x00\x27\x00\x27\x00\x2e\x00\x1e\x00\x1f\x00\x1b\x00\x1c\x00\x1d\x00\x1e\x00\x1f\x00\x55\x00\x1b\x00\x1c\x00\x1d\x00\x16\x00\x20\x00\x1b\x00\x77\x00\x1f\x00\x1b\x00\x1c\x00\x1d\x00\x37\x00\x66\x00\x1f\x00\x1b\x00\x1c\x00\x1d\x00\x50\x00\x2c\x00\x49\x00\x69\x00\x1f\x00\x2f\x00\x30\x00\x31\x00\x35\x00\x2e\x00\x1f\x00\x2f\x00\x30\x00\x31\x00\x3d\x00\x72\x00\x4b\x00\x36\x00\x16\x00\x39\x00\x16\x00\xff\xff\x32\x00\x16\x00\x3a\x00\x17\x00\x79\x00\x17\x00\x5b\x00\x4d\x00\x17\x00\x18\x00\x37\x00\x5a\x00\x79\x00\x27\x00\x57\x00\xff\xff\x38\x00\x16\x00\x4d\x00\x7e\x00\x16\x00\x26\x00\x27\x00\x41\x00\x42\x00\x35\x00\x75\x00\x4d\x00\x76\x00\x7a\x00\x70\x00\x57\x00\x58\x00\x68\x00\x5c\x00\x65\x00\x67\x00\x44\x00\x6c\x00\x6e\x00\x46\x00\x49\x00\x4e\x00\x49\x00\x52\x00\x58\x00\x19\x00\x57\x00\x1a\x00\x27\x00\x16\x00\x27\x00\x3f\x00\x3b\x00\x3d\x00\x35\x00\x33\x00\x28\x00\x29\x00\x2a\x00\x82\x00\x81\x00\x7d\x00\x70\x00\x74\x00\x4d\x00\x5f\x00\x63\x00\x60\x00\x61\x00\x64\x00\x62\x00\x65\x00\x44\x00\x6c\x00\x6e\x00\x00\x00\x3f\x00\x46\x00\x00\x00\xff\xff\x00\x00\x48\x00\x00\x00\x00\x00\x49\x00\x00\x00\x27\x00\x35\x00\x00\x00\xff\xff\x27\x00\xff\xff\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x5b\x00\xff\xff\x4e\x00\xff\xff\x00\x00\xff\xff\xff\xff\x26\x00\xff\xff\x16\x00\x3d\x00\xc2\xff\x27\x00\x3f\x00\x41\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00"#
 happyReduceArr = array (20, 63) [
 	(20 , happyReduce_20),
 	(21 , happyReduce_21),
 	(22 , happyReduce_22),
 	(23 , happyReduce_23),
 	(24 , happyReduce_24),
 	(25 , happyReduce_25),
 	(26 , happyReduce_26),
 	(27 , happyReduce_27),
 	(28 , happyReduce_28),
 	(29 , happyReduce_29),
 	(30 , happyReduce_30),
 	(31 , happyReduce_31),
 	(32 , happyReduce_32),
 	(33 , happyReduce_33),
 	(34 , happyReduce_34),
 	(35 , happyReduce_35),
 	(36 , happyReduce_36),
 	(37 , happyReduce_37),
 	(38 , happyReduce_38),
 	(39 , happyReduce_39),
 	(40 , happyReduce_40),
 	(41 , happyReduce_41),
 	(42 , happyReduce_42),
 	(43 , happyReduce_43),
 	(44 , happyReduce_44),
 	(45 , happyReduce_45),
 	(46 , happyReduce_46),
 	(47 , happyReduce_47),
 	(48 , happyReduce_48),
 	(49 , happyReduce_49),
 	(50 , happyReduce_50),
 	(51 , happyReduce_51),
 	(52 , happyReduce_52),
 	(53 , happyReduce_53),
 	(54 , happyReduce_54),
 	(55 , happyReduce_55),
 	(56 , happyReduce_56),
 	(57 , happyReduce_57),
 	(58 , happyReduce_58),
 	(59 , happyReduce_59),
 	(60 , happyReduce_60),
 	(61 , happyReduce_61),
 	(62 , happyReduce_62),
 	(63 , happyReduce_63)
 	]
 happy_n_terms = 26 :: Int
 happy_n_nonterms = 23 :: Int
 happyReduce_20 = happySpecReduce_1 0# happyReduction_20
 happyReduction_20 happy_x_1
 	 =  case happyOutTok happy_x_1 of { (PT _ (TL happy_var_1)) -> 
 	happyIn23
 		 (happy_var_1
 	)}
 happyReduce_21 = happySpecReduce_1 1# happyReduction_21
 happyReduction_21 happy_x_1
 	 =  case happyOutTok happy_x_1 of { (PT _ (TI happy_var_1)) -> 
 	happyIn24
 		 ((read happy_var_1) :: Integer
 	)}
 happyReduce_22 = happySpecReduce_1 2# happyReduction_22
 happyReduction_22 happy_x_1
 	 =  case happyOutTok happy_x_1 of { (PT _ (T_CId happy_var_1)) -> 
 	happyIn25
 		 (CId (happy_var_1)
 	)}
 happyReduce_23 = happyReduce 6# 3# happyReduction_23
 happyReduction_23 (happy_x_6 `HappyStk`
 	happy_x_5 `HappyStk`
 	happy_x_4 `HappyStk`
 	happy_x_3 `HappyStk`
 	happy_x_2 `HappyStk`
 	happy_x_1 `HappyStk`
 	happyRest)
 	 = case happyOut27 happy_x_1 of { happy_var_1 -> 
 	case happyOut28 happy_x_3 of { happy_var_3 -> 
 	case happyOut38 happy_x_5 of { happy_var_5 -> 
 	happyIn26
 		 (Grm happy_var_1 happy_var_3 (reverse happy_var_5)
 	) `HappyStk` happyRest}}}
 happyReduce_24 = happyReduce 5# 4# happyReduction_24
 happyReduction_24 (happy_x_5 `HappyStk`
 	happy_x_4 `HappyStk`
 	happy_x_3 `HappyStk`
 	happy_x_2 `HappyStk`
 	happy_x_1 `HappyStk`
 	happyRest)
 	 = case happyOut25 happy_x_2 of { happy_var_2 -> 
 	case happyOut41 happy_x_4 of { happy_var_4 -> 
 	happyIn27
 		 (Hdr happy_var_2 (reverse happy_var_4)
 	) `HappyStk` happyRest}}
 happyReduce_25 = happyReduce 5# 5# happyReduction_25
 happyReduction_25 (happy_x_5 `HappyStk`
 	happy_x_4 `HappyStk`
 	happy_x_3 `HappyStk`
 	happy_x_2 `HappyStk`
 	happy_x_1 `HappyStk`
 	happyRest)
 	 = case happyOut39 happy_x_3 of { happy_var_3 -> 
 	happyIn28
 		 (Abs (reverse happy_var_3)
 	) `HappyStk` happyRest}
 happyReduce_26 = happyReduce 5# 6# happyReduction_26
 happyReduction_26 (happy_x_5 `HappyStk`
 	happy_x_4 `HappyStk`
 	happy_x_3 `HappyStk`
 	happy_x_2 `HappyStk`
 	happy_x_1 `HappyStk`
 	happyRest)
 	 = case happyOut25 happy_x_2 of { happy_var_2 -> 
 	case happyOut40 happy_x_4 of { happy_var_4 -> 
 	happyIn29
 		 (Cnc happy_var_2 (reverse happy_var_4)
 	) `HappyStk` happyRest}}
 happyReduce_27 = happyReduce 5# 7# happyReduction_27
 happyReduction_27 (happy_x_5 `HappyStk`
 	happy_x_4 `HappyStk`
 	happy_x_3 `HappyStk`
 	happy_x_2 `HappyStk`
 	happy_x_1 `HappyStk`
 	happyRest)
 	 = case happyOut25 happy_x_1 of { happy_var_1 -> 
 	case happyOut32 happy_x_3 of { happy_var_3 -> 
 	case happyOut33 happy_x_5 of { happy_var_5 -> 
 	happyIn30
 		 (Fun happy_var_1 happy_var_3 happy_var_5
 	) `HappyStk` happyRest}}}
 happyReduce_28 = happySpecReduce_3 8# happyReduction_28
 happyReduction_28 happy_x_3
 	happy_x_2
 	happy_x_1
 	 =  case happyOut25 happy_x_1 of { happy_var_1 -> 
 	case happyOut35 happy_x_3 of { happy_var_3 -> 
 	happyIn31
 		 (Lin happy_var_1 happy_var_3
 	)}}
 happyReduce_29 = happySpecReduce_3 9# happyReduction_29
 happyReduction_29 happy_x_3
 	happy_x_2
 	happy_x_1
 	 =  case happyOut41 happy_x_1 of { happy_var_1 -> 
 	case happyOut25 happy_x_3 of { happy_var_3 -> 
 	happyIn32
 		 (Typ (reverse happy_var_1) happy_var_3
 	)}}
 happyReduce_30 = happyReduce 4# 10# happyReduction_30
 happyReduction_30 (happy_x_4 `HappyStk`
 	happy_x_3 `HappyStk`
 	happy_x_2 `HappyStk`
 	happy_x_1 `HappyStk`
 	happyRest)
 	 = case happyOut34 happy_x_2 of { happy_var_2 -> 
 	case happyOut43 happy_x_3 of { happy_var_3 -> 
 	happyIn33
 		 (Tr happy_var_2 (reverse happy_var_3)
 	) `HappyStk` happyRest}}
 happyReduce_31 = happySpecReduce_1 11# happyReduction_31
 happyReduction_31 happy_x_1
 	 =  case happyOut25 happy_x_1 of { happy_var_1 -> 
 	happyIn34
 		 (AC happy_var_1
 	)}
 happyReduce_32 = happySpecReduce_1 11# happyReduction_32
 happyReduction_32 happy_x_1
 	 =  case happyOut23 happy_x_1 of { happy_var_1 -> 
 	happyIn34
 		 (AS happy_var_1
 	)}
 happyReduce_33 = happySpecReduce_1 11# happyReduction_33
 happyReduction_33 happy_x_1
 	 =  case happyOut24 happy_x_1 of { happy_var_1 -> 
 	happyIn34
 		 (AI happy_var_1
 	)}
 happyReduce_34 = happySpecReduce_3 12# happyReduction_34
 happyReduction_34 happy_x_3
 	happy_x_2
 	happy_x_1
 	 =  case happyOut42 happy_x_2 of { happy_var_2 -> 
 	happyIn35
 		 (R happy_var_2
 	)}
 happyReduce_35 = happyReduce 4# 12# happyReduction_35
 happyReduction_35 (happy_x_4 `HappyStk`
 	happy_x_3 `HappyStk`
 	happy_x_2 `HappyStk`
 	happy_x_1 `HappyStk`
 	happyRest)
 	 = case happyOut35 happy_x_1 of { happy_var_1 -> 
 	case happyOut35 happy_x_3 of { happy_var_3 -> 
 	happyIn35
 		 (P happy_var_1 happy_var_3
 	) `HappyStk` happyRest}}
 happyReduce_36 = happySpecReduce_3 12# happyReduction_36
 happyReduction_36 happy_x_3
 	happy_x_2
 	happy_x_1
 	 =  case happyOut42 happy_x_2 of { happy_var_2 -> 
 	happyIn35
 		 (S happy_var_2
 	)}
 happyReduce_37 = happySpecReduce_1 12# happyReduction_37
 happyReduction_37 happy_x_1
 	 =  case happyOut36 happy_x_1 of { happy_var_1 -> 
 	happyIn35
 		 (K happy_var_1
 	)}
 happyReduce_38 = happySpecReduce_2 12# happyReduction_38
 happyReduction_38 happy_x_2
 	happy_x_1
 	 =  case happyOut24 happy_x_2 of { happy_var_2 -> 
 	happyIn35
 		 (V happy_var_2
 	)}
 happyReduce_39 = happySpecReduce_1 12# happyReduction_39
 happyReduction_39 happy_x_1
 	 =  case happyOut24 happy_x_1 of { happy_var_1 -> 
 	happyIn35
 		 (C happy_var_1
 	)}
 happyReduce_40 = happySpecReduce_1 12# happyReduction_40
 happyReduction_40 happy_x_1
 	 =  case happyOut25 happy_x_1 of { happy_var_1 -> 
 	happyIn35
 		 (F happy_var_1
 	)}
 happyReduce_41 = happySpecReduce_3 12# happyReduction_41
 happyReduction_41 happy_x_3
 	happy_x_2
 	happy_x_1
 	 =  case happyOut42 happy_x_2 of { happy_var_2 -> 
 	happyIn35
 		 (FV happy_var_2
 	)}
 happyReduce_42 = happyReduce 5# 12# happyReduction_42
 happyReduction_42 (happy_x_5 `HappyStk`
 	happy_x_4 `HappyStk`
 	happy_x_3 `HappyStk`
 	happy_x_2 `HappyStk`
 	happy_x_1 `HappyStk`
 	happyRest)
 	 = case happyOut23 happy_x_2 of { happy_var_2 -> 
 	case happyOut35 happy_x_4 of { happy_var_4 -> 
 	happyIn35
 		 (W happy_var_2 happy_var_4
 	) `HappyStk` happyRest}}
 happyReduce_43 = happySpecReduce_1 13# happyReduction_43
 happyReduction_43 happy_x_1
 	 =  case happyOut23 happy_x_1 of { happy_var_1 -> 
 	happyIn36
 		 (KS happy_var_1
 	)}
 happyReduce_44 = happyReduce 7# 13# happyReduction_44
 happyReduction_44 (happy_x_7 `HappyStk`
 	happy_x_6 `HappyStk`
 	happy_x_5 `HappyStk`
 	happy_x_4 `HappyStk`
 	happy_x_3 `HappyStk`
 	happy_x_2 `HappyStk`
 	happy_x_1 `HappyStk`
 	happyRest)
 	 = case happyOut44 happy_x_3 of { happy_var_3 -> 
 	case happyOut45 happy_x_5 of { happy_var_5 -> 
 	happyIn36
 		 (KP (reverse happy_var_3) happy_var_5
 	) `HappyStk` happyRest}}
 happyReduce_45 = happySpecReduce_3 14# happyReduction_45
 happyReduction_45 happy_x_3
 	happy_x_2
 	happy_x_1
 	 =  case happyOut44 happy_x_1 of { happy_var_1 -> 
 	case happyOut44 happy_x_3 of { happy_var_3 -> 
 	happyIn37
 		 (Var (reverse happy_var_1) (reverse happy_var_3)
 	)}}
 happyReduce_46 = happySpecReduce_0 15# happyReduction_46
 happyReduction_46  =  happyIn38
 		 ([]
 	)
 happyReduce_47 = happySpecReduce_3 15# happyReduction_47
 happyReduction_47 happy_x_3
 	happy_x_2
 	happy_x_1
 	 =  case happyOut38 happy_x_1 of { happy_var_1 -> 
 	case happyOut29 happy_x_2 of { happy_var_2 -> 
 	happyIn38
 		 (flip (:) happy_var_1 happy_var_2
 	)}}
 happyReduce_48 = happySpecReduce_0 16# happyReduction_48
 happyReduction_48  =  happyIn39
 		 ([]
 	)
 happyReduce_49 = happySpecReduce_3 16# happyReduction_49
 happyReduction_49 happy_x_3
 	happy_x_2
 	happy_x_1
 	 =  case happyOut39 happy_x_1 of { happy_var_1 -> 
 	case happyOut30 happy_x_2 of { happy_var_2 -> 
 	happyIn39
 		 (flip (:) happy_var_1 happy_var_2
 	)}}
 happyReduce_50 = happySpecReduce_0 17# happyReduction_50
 happyReduction_50  =  happyIn40
 		 ([]
 	)
 happyReduce_51 = happySpecReduce_3 17# happyReduction_51
 happyReduction_51 happy_x_3
 	happy_x_2
 	happy_x_1
 	 =  case happyOut40 happy_x_1 of { happy_var_1 -> 
 	case happyOut31 happy_x_2 of { happy_var_2 -> 
 	happyIn40
 		 (flip (:) happy_var_1 happy_var_2
 	)}}
 happyReduce_52 = happySpecReduce_0 18# happyReduction_52
 happyReduction_52  =  happyIn41
 		 ([]
 	)
 happyReduce_53 = happySpecReduce_2 18# happyReduction_53
 happyReduction_53 happy_x_2
 	happy_x_1
 	 =  case happyOut41 happy_x_1 of { happy_var_1 -> 
 	case happyOut25 happy_x_2 of { happy_var_2 -> 
 	happyIn41
 		 (flip (:) happy_var_1 happy_var_2
 	)}}
 happyReduce_54 = happySpecReduce_0 19# happyReduction_54
 happyReduction_54  =  happyIn42
 		 ([]
 	)
 happyReduce_55 = happySpecReduce_1 19# happyReduction_55
 happyReduction_55 happy_x_1
 	 =  case happyOut35 happy_x_1 of { happy_var_1 -> 
 	happyIn42
 		 ((:[]) happy_var_1
 	)}
 happyReduce_56 = happySpecReduce_3 19# happyReduction_56
 happyReduction_56 happy_x_3
 	happy_x_2
 	happy_x_1
 	 =  case happyOut35 happy_x_1 of { happy_var_1 -> 
 	case happyOut42 happy_x_3 of { happy_var_3 -> 
 	happyIn42
 		 ((:) happy_var_1 happy_var_3
 	)}}
 happyReduce_57 = happySpecReduce_0 20# happyReduction_57
 happyReduction_57  =  happyIn43
 		 ([]
 	)
 happyReduce_58 = happySpecReduce_2 20# happyReduction_58
 happyReduction_58 happy_x_2
 	happy_x_1
 	 =  case happyOut43 happy_x_1 of { happy_var_1 -> 
 	case happyOut33 happy_x_2 of { happy_var_2 -> 
 	happyIn43
 		 (flip (:) happy_var_1 happy_var_2
 	)}}
 happyReduce_59 = happySpecReduce_0 21# happyReduction_59
 happyReduction_59  =  happyIn44
 		 ([]
 	)
 happyReduce_60 = happySpecReduce_2 21# happyReduction_60
 happyReduction_60 happy_x_2
 	happy_x_1
 	 =  case happyOut44 happy_x_1 of { happy_var_1 -> 
 	case happyOut23 happy_x_2 of { happy_var_2 -> 
 	happyIn44
 		 (flip (:) happy_var_1 happy_var_2
 	)}}
 happyReduce_61 = happySpecReduce_0 22# happyReduction_61
 happyReduction_61  =  happyIn45
 		 ([]
 	)
 happyReduce_62 = happySpecReduce_1 22# happyReduction_62
 happyReduction_62 happy_x_1
 	 =  case happyOut37 happy_x_1 of { happy_var_1 -> 
 	happyIn45
 		 ((:[]) happy_var_1
 	)}
 happyReduce_63 = happySpecReduce_3 22# happyReduction_63
 happyReduction_63 happy_x_3
 	happy_x_2
 	happy_x_1
 	 =  case happyOut37 happy_x_1 of { happy_var_1 -> 
 	case happyOut45 happy_x_3 of { happy_var_3 -> 
 	happyIn45
 		 ((:) happy_var_1 happy_var_3
 	)}}
 happyNewToken action sts stk [] =
 	happyDoAction 25# (error "reading EOF!") action sts stk []
 happyNewToken action sts stk (tk:tks) =
 	let cont i = happyDoAction i tk action sts stk tks in
 	case tk of {
 	PT _ (TS ";") -> cont 1#;
 	PT _ (TS "(") -> cont 2#;
 	PT _ (TS ")") -> cont 3#;
 	PT _ (TS "{") -> cont 4#;
 	PT _ (TS "}") -> cont 5#;
 	PT _ (TS ":") -> cont 6#;
 	PT _ (TS "=") -> cont 7#;
 	PT _ (TS "->") -> cont 8#;
 	PT _ (TS "[") -> cont 9#;
 	PT _ (TS "]") -> cont 10#;
 	PT _ (TS "$") -> cont 11#;
 	PT _ (TS "[|") -> cont 12#;
 	PT _ (TS "|]") -> cont 13#;
 	PT _ (TS "+") -> cont 14#;
 	PT _ (TS "/") -> cont 15#;
 	PT _ (TS ",") -> cont 16#;
 	PT _ (TS "abstract") -> cont 17#;
 	PT _ (TS "concrete") -> cont 18#;
 	PT _ (TS "grammar") -> cont 19#;
 	PT _ (TS "pre") -> cont 20#;
 	PT _ (TL happy_dollar_dollar) -> cont 21#;
 	PT _ (TI happy_dollar_dollar) -> cont 22#;
 	PT _ (T_CId happy_dollar_dollar) -> cont 23#;
 	_ -> cont 24#;
 	_ -> happyError' (tk:tks)
 	}
 happyError_ tk tks = happyError' (tk:tks)
 happyThen :: () => Err a -> (a -> Err b) -> Err b
 happyThen = (thenM)
 happyReturn :: () => a -> Err a
 happyReturn = (returnM)
 happyThen1 m k tks = (thenM) m (\a -> k a tks)
 happyReturn1 :: () => a -> b -> Err a
 happyReturn1 = \a tks -> (returnM) a
 happyError' :: () => [Token] -> Err a
 happyError' = happyError
 pGrammar tks = happySomeParser where
  happySomeParser = happyThen (happyParse 0# tks) (\x -> happyReturn (happyOut26 x))
 pHeader tks = happySomeParser where
  happySomeParser = happyThen (happyParse 1# tks) (\x -> happyReturn (happyOut27 x))
 pAbstract tks = happySomeParser where
  happySomeParser = happyThen (happyParse 2# tks) (\x -> happyReturn (happyOut28 x))
 pConcrete tks = happySomeParser where
  happySomeParser = happyThen (happyParse 3# tks) (\x -> happyReturn (happyOut29 x))
 pAbsDef tks = happySomeParser where
  happySomeParser = happyThen (happyParse 4# tks) (\x -> happyReturn (happyOut30 x))
 pCncDef tks = happySomeParser where
  happySomeParser = happyThen (happyParse 5# tks) (\x -> happyReturn (happyOut31 x))
 pType tks = happySomeParser where
  happySomeParser = happyThen (happyParse 6# tks) (\x -> happyReturn (happyOut32 x))
 pExp tks = happySomeParser where
  happySomeParser = happyThen (happyParse 7# tks) (\x -> happyReturn (happyOut33 x))
 pAtom tks = happySomeParser where
  happySomeParser = happyThen (happyParse 8# tks) (\x -> happyReturn (happyOut34 x))
 pTerm tks = happySomeParser where
  happySomeParser = happyThen (happyParse 9# tks) (\x -> happyReturn (happyOut35 x))
 pTokn tks = happySomeParser where
  happySomeParser = happyThen (happyParse 10# tks) (\x -> happyReturn (happyOut36 x))
 pVariant tks = happySomeParser where
  happySomeParser = happyThen (happyParse 11# tks) (\x -> happyReturn (happyOut37 x))
 pListConcrete tks = happySomeParser where
  happySomeParser = happyThen (happyParse 12# tks) (\x -> happyReturn (happyOut38 x))
 pListAbsDef tks = happySomeParser where
  happySomeParser = happyThen (happyParse 13# tks) (\x -> happyReturn (happyOut39 x))
 pListCncDef tks = happySomeParser where
  happySomeParser = happyThen (happyParse 14# tks) (\x -> happyReturn (happyOut40 x))
 pListCId tks = happySomeParser where
  happySomeParser = happyThen (happyParse 15# tks) (\x -> happyReturn (happyOut41 x))
 pListTerm tks = happySomeParser where
  happySomeParser = happyThen (happyParse 16# tks) (\x -> happyReturn (happyOut42 x))
 pListExp tks = happySomeParser where
  happySomeParser = happyThen (happyParse 17# tks) (\x -> happyReturn (happyOut43 x))
 pListString tks = happySomeParser where
  happySomeParser = happyThen (happyParse 18# tks) (\x -> happyReturn (happyOut44 x))
 pListVariant tks = happySomeParser where
  happySomeParser = happyThen (happyParse 19# tks) (\x -> happyReturn (happyOut45 x))
 happySeq = happyDontSeq
 returnM :: a -> Err a
 returnM = return
 thenM :: Err a -> (a -> Err b) -> Err b
 thenM = (>>=)
 happyError :: [Token] -> Err a
 happyError ts =
  Bad $ "syntax error at " ++ tokenPos ts ++ 
  case ts of
    [] -> []
    [Err _] -> " due to lexer error"
    _ -> " before " ++ unwords (map prToken (take 4 ts))
 myLexer = tokens
 {-# LINE 1 "GenericTemplate.hs" #-}
 {-# LINE 1 "<built-in>" #-}
 {-# LINE 1 "<command line>" #-}
 {-# LINE 1 "GenericTemplate.hs" #-}
 -- $Id$
 {-# LINE 28 "GenericTemplate.hs" #-}
 data Happy_IntList = HappyCons Int# Happy_IntList
 {-# LINE 49 "GenericTemplate.hs" #-}
 {-# LINE 59 "GenericTemplate.hs" #-}
 infixr 9 `HappyStk`
 data HappyStk a = HappyStk a (HappyStk a)
 -----------------------------------------------------------------------------
 -- starting the parse
 happyParse start_state = happyNewToken start_state notHappyAtAll notHappyAtAll
 -----------------------------------------------------------------------------
 -- Accepting the parse
 -- If the current token is 0#, it means we've just accepted a partial
 -- parse (a %partial parser).  We must ignore the saved token on the top of
 -- the stack in this case.
 happyAccept 0# tk st sts (_ `HappyStk` ans `HappyStk` _) =
 	happyReturn1 ans
 happyAccept j tk st sts (HappyStk ans _) = 
 	(happyTcHack j (happyTcHack st)) (happyReturn1 ans)
 -----------------------------------------------------------------------------
 -- Arrays only: do the next action
 happyDoAction i tk st
 	= {- nothing -}
 	  case action of
 		0#		  -> {- nothing -}
 				     happyFail i tk st
 		-1# 	  -> {- nothing -}
 				     happyAccept i tk st
 		n | (n <# (0# :: Int#)) -> {- nothing -}
 				     (happyReduceArr ! rule) i tk st
 				     where rule = (I# ((negateInt# ((n +# (1# :: Int#))))))
 		n		  -> {- nothing -}
 				     happyShift new_state i tk st
 				     where new_state = (n -# (1# :: Int#))
   where off    = indexShortOffAddr happyActOffsets st
 	 off_i  = (off +# i)
 	 check  = if (off_i >=# (0# :: Int#))
 			then (indexShortOffAddr happyCheck off_i ==#  i)
 			else False
 	 action | check     = indexShortOffAddr happyTable off_i
 		| otherwise = indexShortOffAddr happyDefActions st
 indexShortOffAddr (HappyA# arr) off =
 #if __GLASGOW_HASKELL__ > 500
 	narrow16Int# i
 #elif __GLASGOW_HASKELL__ == 500
 	intToInt16# i
 #else
 	(i `iShiftL#` 16#) `iShiftRA#` 16#
 #endif
  where
 #if __GLASGOW_HASKELL__ >= 503
 	i = word2Int# ((high `uncheckedShiftL#` 8#) `or#` low)
 #else
 	i = word2Int# ((high `shiftL#` 8#) `or#` low)
 #endif
 	high = int2Word# (ord# (indexCharOffAddr# arr (off' +# 1#)))
 	low  = int2Word# (ord# (indexCharOffAddr# arr off'))
 	off' = off *# 2#
 data HappyAddr = HappyA# Addr#
 -----------------------------------------------------------------------------
 -- HappyState data type (not arrays)
 {-# LINE 170 "GenericTemplate.hs" #-}
 -----------------------------------------------------------------------------
 -- Shifting a token
 happyShift new_state 0# tk st sts stk@(x `HappyStk` _) =
     let i = (case unsafeCoerce# x of { (I# (i)) -> i }) in
 --     trace "shifting the error token" $
     happyDoAction i tk new_state (HappyCons (st) (sts)) (stk)
 happyShift new_state i tk st sts stk =
     happyNewToken new_state (HappyCons (st) (sts)) ((happyInTok (tk))`HappyStk`stk)
 -- happyReduce is specialised for the common cases.
 happySpecReduce_0 i fn 0# tk st sts stk
     = happyFail 0# tk st sts stk
 happySpecReduce_0 nt fn j tk st@((action)) sts stk
     = happyGoto nt j tk st (HappyCons (st) (sts)) (fn `HappyStk` stk)
 happySpecReduce_1 i fn 0# tk st sts stk
     = happyFail 0# tk st sts stk
 happySpecReduce_1 nt fn j tk _ sts@((HappyCons (st@(action)) (_))) (v1`HappyStk`stk')
     = let r = fn v1 in
       happySeq r (happyGoto nt j tk st sts (r `HappyStk` stk'))
 happySpecReduce_2 i fn 0# tk st sts stk
     = happyFail 0# tk st sts stk
 happySpecReduce_2 nt fn j tk _ (HappyCons (_) (sts@((HappyCons (st@(action)) (_))))) (v1`HappyStk`v2`HappyStk`stk')
     = let r = fn v1 v2 in
       happySeq r (happyGoto nt j tk st sts (r `HappyStk` stk'))
 happySpecReduce_3 i fn 0# tk st sts stk
     = happyFail 0# tk st sts stk
 happySpecReduce_3 nt fn j tk _ (HappyCons (_) ((HappyCons (_) (sts@((HappyCons (st@(action)) (_))))))) (v1`HappyStk`v2`HappyStk`v3`HappyStk`stk')
     = let r = fn v1 v2 v3 in
       happySeq r (happyGoto nt j tk st sts (r `HappyStk` stk'))
 happyReduce k i fn 0# tk st sts stk
     = happyFail 0# tk st sts stk
 happyReduce k nt fn j tk st sts stk
     = case happyDrop (k -# (1# :: Int#)) sts of
 	 sts1@((HappyCons (st1@(action)) (_))) ->
        	let r = fn stk in  -- it doesn't hurt to always seq here...
       		happyDoSeq r (happyGoto nt j tk st1 sts1 r)
 happyMonadReduce k nt fn 0# tk st sts stk
     = happyFail 0# tk st sts stk
 happyMonadReduce k nt fn j tk st sts stk =
        happyThen1 (fn stk) (\r -> happyGoto nt j tk st1 sts1 (r `HappyStk` drop_stk))
       where sts1@((HappyCons (st1@(action)) (_))) = happyDrop k (HappyCons (st) (sts))
             drop_stk = happyDropStk k stk
 happyDrop 0# l = l
 happyDrop n (HappyCons (_) (t)) = happyDrop (n -# (1# :: Int#)) t
 happyDropStk 0# l = l
 happyDropStk n (x `HappyStk` xs) = happyDropStk (n -# (1#::Int#)) xs
 -----------------------------------------------------------------------------
 -- Moving to a new state after a reduction
 happyGoto nt j tk st = 
   {- nothing -}
   happyDoAction j tk new_state
   where off    = indexShortOffAddr happyGotoOffsets st
 	 off_i  = (off +# nt)
 	 new_state = indexShortOffAddr happyTable off_i
 -----------------------------------------------------------------------------
 -- Error recovery (0# is the error token)
 -- parse error if we are in recovery and we fail again
 happyFail  0# tk old_st _ stk =
 --	trace "failing" $ 
    	happyError_ tk
 {-  We don't need state discarding for our restricted implementation of
    "error".  In fact, it can cause some bogus parses, so I've disabled it
    for now --SDM
 -- discard a state
 happyFail  0# tk old_st (HappyCons ((action)) (sts)) 
 						(saved_tok `HappyStk` _ `HappyStk` stk) =
 --	trace ("discarding state, depth " ++ show (length stk))  $
 	happyDoAction 0# tk action sts ((saved_tok`HappyStk`stk))
 -}
 -- Enter error recovery: generate an error token,
 --                       save the old token and carry on.
 happyFail  i tk (action) sts stk =
 --      trace "entering error recovery" $
 	happyDoAction 0# tk action sts ( (unsafeCoerce# (I# (i))) `HappyStk` stk)
 -- Internal happy errors:
 notHappyAtAll = error "Internal Happy error\n"
 -----------------------------------------------------------------------------
 -- Hack to get the typechecker to accept our action functions
 happyTcHack :: Int# -> a -> a
 happyTcHack x y = y
 {-# INLINE happyTcHack #-}
 -----------------------------------------------------------------------------
 -- Seq-ing.  If the --strict flag is given, then Happy emits 
 --	happySeq = happyDoSeq
 -- otherwise it emits
 -- 	happySeq = happyDontSeq
 happyDoSeq, happyDontSeq :: a -> b -> b
 happyDoSeq   a b = a `seq` b
 happyDontSeq a b = b
 -----------------------------------------------------------------------------
 -- Don't inline any functions from the template.  GHC has a nasty habit
 -- of deciding to inline happyGoto everywhere, which increases the size of
 -- the generated parser quite a bit.
 {-# NOINLINE happyDoAction #-}
 {-# NOINLINE happyTable #-}
 {-# NOINLINE happyCheck #-}
 {-# NOINLINE happyActOffsets #-}
 {-# NOINLINE happyGotoOffsets #-}
 {-# NOINLINE happyDefActions #-}
 {-# NOINLINE happyShift #-}
 {-# NOINLINE happySpecReduce_0 #-}
 {-# NOINLINE happySpecReduce_1 #-}
 {-# NOINLINE happySpecReduce_2 #-}
 {-# NOINLINE happySpecReduce_3 #-}
 {-# NOINLINE happyReduce #-}
 {-# NOINLINE happyMonadReduce #-}
 {-# NOINLINE happyGoto #-}
 {-# NOINLINE happyFail #-}
 -- end of Happy Template.
--- a/src/GF/Canon/GFCC/PrintGFCC.hs
+++ b/src/GF/Canon/GFCC/PrintGFCC.hs
@@ -0,0 +1,181 @@
 {-# OPTIONS -fno-warn-incomplete-patterns #-}
 module GF.Canon.GFCC.PrintGFCC where
 -- pretty-printer generated by the BNF converter
 import GF.Canon.GFCC.AbsGFCC
 import Data.Char
 -- the top-level printing method
 printTree :: Print a => a -> String
 printTree = render . prt 0
 type Doc = [ShowS] -> [ShowS]
 doc :: ShowS -> Doc
 doc = (:)
 render :: Doc -> String
 render d = rend 0 (map ($ "") $ d []) "" where
  rend i ss = case ss of
    "["      :ts -> showChar '[' . rend i ts
    "("      :ts -> showChar '(' . rend i ts
    "{"      :ts -> showChar '{' . new (i+1) . rend (i+1) ts
    "}" : ";":ts -> new (i-1) . space "}" . showChar ';' . new (i-1) . rend (i-1) ts
    "}"      :ts -> new (i-1) . showChar '}' . new (i-1) . rend (i-1) ts
    ";"      :ts -> showChar ';' . new i . rend i ts
    t  : "," :ts -> showString t . space "," . rend i ts
    t  : ")" :ts -> showString t . showChar ')' . rend i ts
    t  : "]" :ts -> showString t . showChar ']' . rend i ts
    t        :ts -> space t . rend i ts
    _            -> id
  new i   = showChar '\n' . replicateS (2*i) (showChar ' ') . dropWhile isSpace
  space t = showString t . (\s -> if null s then "" else (' ':s))
 parenth :: Doc -> Doc
 parenth ss = doc (showChar '(') . ss . doc (showChar ')')
 concatS :: [ShowS] -> ShowS
 concatS = foldr (.) id
 concatD :: [Doc] -> Doc
 concatD = foldr (.) id
 replicateS :: Int -> ShowS -> ShowS
 replicateS n f = concatS (replicate n f)
 -- the printer class does the job
 class Print a where
  prt :: Int -> a -> Doc
  prtList :: [a] -> Doc
  prtList = concatD . map (prt 0)
 instance Print a => Print [a] where
  prt _ = prtList
 instance Print Char where
  prt _ s = doc (showChar '\'' . mkEsc '\'' s . showChar '\'')
  prtList s = doc (showChar '"' . concatS (map (mkEsc '"') s) . showChar '"')
 mkEsc :: Char -> Char -> ShowS
 mkEsc q s = case s of
  _ | s == q -> showChar '\\' . showChar s
  '\\'-> showString "\\\\"
  '\n' -> showString "\\n"
  '\t' -> showString "\\t"
  _ -> showChar s
 prPrec :: Int -> Int -> Doc -> Doc
 prPrec i j = if j<i then parenth else id
 instance Print Integer where
  prt _ x = doc (shows x)
 instance Print Double where
  prt _ x = doc (shows x)
 instance Print CId where
  prt _ (CId i) = doc (showString i)
  prtList es = case es of
   [] -> (concatD [])
   x:xs -> (concatD [prt 0 x , prt 0 xs])
 instance Print Grammar where
  prt i e = case e of
   Grm header abstract concretes -> prPrec i 0 (concatD [prt 0 header , doc (showString ";") , prt 0 abstract , doc (showString ";") , prt 0 concretes , doc (showString ";")])
 instance Print Header where
  prt i e = case e of
   Hdr cid cids -> prPrec i 0 (concatD [doc (showString "grammar") , prt 0 cid , doc (showString "(") , prt 0 cids , doc (showString ")")])
 instance Print Abstract where
  prt i e = case e of
   Abs absdefs -> prPrec i 0 (concatD [doc (showString "abstract") , doc (showString "{") , prt 0 absdefs , doc (showString "}") , doc (showString ";")])
 instance Print Concrete where
  prt i e = case e of
   Cnc cid cncdefs -> prPrec i 0 (concatD [doc (showString "concrete") , prt 0 cid , doc (showString "{") , prt 0 cncdefs , doc (showString "}")])
  prtList es = case es of
   [] -> (concatD [])
   x:xs -> (concatD [prt 0 x , doc (showString ";") , prt 0 xs])
 instance Print AbsDef where
  prt i e = case e of
   Fun cid type' exp -> prPrec i 0 (concatD [prt 0 cid , doc (showString ":") , prt 0 type' , doc (showString "=") , prt 0 exp])
  prtList es = case es of
   [] -> (concatD [])
   x:xs -> (concatD [prt 0 x , doc (showString ";") , prt 0 xs])
 instance Print CncDef where
  prt i e = case e of
   Lin cid term -> prPrec i 0 (concatD [prt 0 cid , doc (showString "=") , prt 0 term])
  prtList es = case es of
   [] -> (concatD [])
   x:xs -> (concatD [prt 0 x , doc (showString ";") , prt 0 xs])
 instance Print Type where
  prt i e = case e of
   Typ cids cid -> prPrec i 0 (concatD [prt 0 cids , doc (showString "->") , prt 0 cid])
 instance Print Exp where
  prt i e = case e of
   Tr atom exps -> prPrec i 0 (concatD [doc (showString "(") , prt 0 atom , prt 0 exps , doc (showString ")")])
  prtList es = case es of
   [] -> (concatD [])
   x:xs -> (concatD [prt 0 x , prt 0 xs])
 instance Print Atom where
  prt i e = case e of
   AC cid -> prPrec i 0 (concatD [prt 0 cid])
   AS str -> prPrec i 0 (concatD [prt 0 str])
   AI n -> prPrec i 0 (concatD [prt 0 n])
 instance Print Term where
  prt i e = case e of
   R terms -> prPrec i 0 (concatD [doc (showString "[") , prt 0 terms , doc (showString "]")])
   P term0 term -> prPrec i 0 (concatD [prt 0 term0 , doc (showString "[") , prt 0 term , doc (showString "]")])
   S terms -> prPrec i 0 (concatD [doc (showString "(") , prt 0 terms , doc (showString ")")])
   K tokn -> prPrec i 0 (concatD [prt 0 tokn])
   V n -> prPrec i 0 (concatD [doc (showString "$") , prt 0 n])
   C n -> prPrec i 0 (concatD [prt 0 n])
   F cid -> prPrec i 0 (concatD [prt 0 cid])
   FV terms -> prPrec i 0 (concatD [doc (showString "[|") , prt 0 terms , doc (showString "|]")])
   W str term -> prPrec i 0 (concatD [doc (showString "(") , prt 0 str , doc (showString "+") , prt 0 term , doc (showString ")")])
  prtList es = case es of
   [] -> (concatD [])
   [x] -> (concatD [prt 0 x])
   x:xs -> (concatD [prt 0 x , doc (showString ",") , prt 0 xs])
 instance Print Tokn where
  prt i e = case e of
   KS str -> prPrec i 0 (concatD [prt 0 str])
   KP strs variants -> prPrec i 0 (concatD [doc (showString "[") , doc (showString "pre") , prt 0 strs , doc (showString "[") , prt 0 variants , doc (showString "]") , doc (showString "]")])
 instance Print Variant where
  prt i e = case e of
   Var strs0 strs -> prPrec i 0 (concatD [prt 0 strs0 , doc (showString "/") , prt 0 strs])
  prtList es = case es of
   [] -> (concatD [])
   [x] -> (concatD [prt 0 x])
   x:xs -> (concatD [prt 0 x , doc (showString ",") , prt 0 xs])
--- a/src/GF/Canon/GFCC/SkelGFCC.hs
+++ b/src/GF/Canon/GFCC/SkelGFCC.hs
@@ -0,0 +1,88 @@
 module SkelGFCC where
 -- Haskell module generated by the BNF converter
 import AbsGFCC
 import ErrM
 type Result = Err String
 failure :: Show a => a -> Result
 failure x = Bad $ "Undefined case: " ++ show x
 transCId :: CId -> Result
 transCId x = case x of
  CId str  -> failure x
 transGrammar :: Grammar -> Result
 transGrammar x = case x of
  Grm header abstract concretes  -> failure x
 transHeader :: Header -> Result
 transHeader x = case x of
  Hdr cid cids  -> failure x
 transAbstract :: Abstract -> Result
 transAbstract x = case x of
  Abs absdefs  -> failure x
 transConcrete :: Concrete -> Result
 transConcrete x = case x of
  Cnc cid cncdefs  -> failure x
 transAbsDef :: AbsDef -> Result
 transAbsDef x = case x of
  Fun cid type' exp  -> failure x
 transCncDef :: CncDef -> Result
 transCncDef x = case x of
  Lin cid term  -> failure x
 transType :: Type -> Result
 transType x = case x of
  Typ cids cid  -> failure x
 transExp :: Exp -> Result
 transExp x = case x of
  Tr atom exps  -> failure x
 transAtom :: Atom -> Result
 transAtom x = case x of
  AC cid  -> failure x
  AS str  -> failure x
  AI n  -> failure x
 transTerm :: Term -> Result
 transTerm x = case x of
  R terms  -> failure x
  P term0 term  -> failure x
  S terms  -> failure x
  K tokn  -> failure x
  V n  -> failure x
  C n  -> failure x
  F cid  -> failure x
  FV terms  -> failure x
  W str term  -> failure x
 transTokn :: Tokn -> Result
 transTokn x = case x of
  KS str  -> failure x
  KP strs variants  -> failure x
 transVariant :: Variant -> Result
 transVariant x = case x of
  Var strs0 strs  -> failure x
--- a/src/GF/Canon/GFCC/TestGFCC.hs
+++ b/src/GF/Canon/GFCC/TestGFCC.hs
@@ -0,0 +1,58 @@
 -- automatically generated by BNF Converter
 module Main where
 import IO ( stdin, hGetContents )
 import System ( getArgs, getProgName )
 import LexGFCC
 import ParGFCC
 import SkelGFCC
 import PrintGFCC
 import AbsGFCC
 import ErrM
 type ParseFun a = [Token] -> Err a
 myLLexer = myLexer
 type Verbosity = Int
 putStrV :: Verbosity -> String -> IO ()
 putStrV v s = if v > 1 then putStrLn s else return ()
 runFile :: (Print a, Show a) => Verbosity -> ParseFun a -> FilePath -> IO ()
 runFile v p f = putStrLn f >> readFile f >>= run v p
 run :: (Print a, Show a) => Verbosity -> ParseFun a -> String -> IO ()
 run v p s = let ts = myLLexer s in case p ts of
           Bad s    -> do putStrLn "\nParse              Failed...\n"
                          putStrV v "Tokens:"
                          putStrV v $ show ts
                          putStrLn s
           Ok  tree -> do putStrLn "\nParse Successful!"
                          showTree v tree
 showTree :: (Show a, Print a) => Int -> a -> IO ()
 showTree v tree
 = do
      putStrV v $ "\n[Abstract Syntax]\n\n" ++ show tree
      putStrV v $ "\n[Linearized tree]\n\n" ++ printTree tree
 main :: IO ()
 main = do args <- getArgs
          case args of
            [] -> hGetContents stdin >>= run 2 pGrammar
            "-s":fs -> mapM_ (runFile 0 pGrammar) fs
            fs -> mapM_ (runFile 2 pGrammar) fs
--- a/src/GF/UseGrammar/Custom.hs
+++ b/src/GF/UseGrammar/Custom.hs
@@ -34,6 +34,7 @@ import GF.Grammar.Values
 import qualified GF.Grammar.Grammar as G
 import qualified GF.Canon.AbsGFC as A
 import qualified GF.Canon.GFC as C
 import qualified GF.Canon.CanonToGFCC as GFCC
 import qualified GF.Source.AbsGF as GF
 import qualified GF.Grammar.MMacros as MM
 import GF.Grammar.AbsCompute
@@ -341,6 +342,7 @@ customMultiGrammarPrinter =
  customData "Printers for multiple grammars, selected by option -printer=x" $
  [
   (strCI "gfcm", const MC.prCanon)
  ,(strCI "gfcc", const GFCC.prCanon2gfcc)
  ,(strCI "header", const (MC.prCanonMGr . unoptimizeCanon))
  ,(strCI "cfgm", prCanonAsCFGM)
  ,(strCI "graph", visualizeCanonGrammar)
--- a/src/GF/UseGrammar/Linear.hs
+++ b/src/GF/UseGrammar/Linear.hs
@@ -153,6 +153,7 @@ unoptimizeCanonMod g = convMod where
      ps  <- mapM term2patt vs
      return $ T ty [Cas [p] t | (p,t) <- zip ps ts]
    FV ts -> liftM FV $ mapM exp ts
    I _ -> comp t
    _ -> composOp exp t
   where
     alls = allParamValues g