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path: root/src/GF/Canon/CanonToGFCC.hs
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----------------------------------------------------------------------
-- |
-- Module      : CanonToGFCC
-- Maintainer  : AR
-- Stability   : (stable)
-- Portability : (portable)
--
-- > CVS $Date: 2005/06/17 14:15:17 $ 
-- > CVS $Author: aarne $
-- > CVS $Revision: 1.15 $
--
-- GFC to GFCC compiler. AR Aug-Oct 2006
-----------------------------------------------------------------------------

module GF.Canon.CanonToGFCC (
  prCanon2gfcc, mkCanon2gfcc, mkCanon2gfccNoUTF8) where

import GF.Canon.AbsGFC
import qualified GF.Canon.GFC as GFC
import qualified GF.Canon.Look as Look
import qualified GF.Canon.Subexpressions as Sub

import qualified GF.GFCC.Macros as CM
import qualified GF.GFCC.AbsGFCC as C
import qualified GF.GFCC.DataGFCC as D
import GF.GFCC.OptimizeGFCC

import GF.Canon.GFC
import GF.Canon.Share
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 (expandLinTables, unoptimizeCanon)

import GF.Infra.Ident
import GF.Data.Operations
import GF.Text.UTF8

import Data.List
import qualified Data.Map as Map
import Debug.Trace ----

-- the main function: generate GFCC from GFCM.

prCanon2gfcc :: CanonGrammar -> String
prCanon2gfcc = D.printGFCC . mkCanon2gfcc

-- this variant makes utf8 conversion; used in back ends
mkCanon2gfcc :: CanonGrammar -> D.GFCC
mkCanon2gfcc = 
-- canon2gfcc . reorder abs . utf8Conv . canon2canon abs
  optGFCC . canon2gfcc . reorder . utf8Conv . canon2canon . normalize

-- this variant makes no utf8 conversion; used in ShellState
mkCanon2gfccNoUTF8 :: CanonGrammar -> D.GFCC
mkCanon2gfccNoUTF8 = optGFCC . canon2gfcc . reorder . canon2canon . normalize

-- This is needed to reorganize the grammar. 
-- GFCC has its own back-end optimization.
-- But we need to have the canonical order in tables, created by valOpt
normalize :: CanonGrammar -> CanonGrammar
normalize = share . unoptimizeCanon . Sub.unSubelimCanon where
  share = M.MGrammar . map (shareModule valOpt) . M.modules --- allOpt

-- Generate GFCC from GFCM.
-- this assumes a grammar normalized and transformed by canon2canon

canon2gfcc :: CanonGrammar -> D.GFCC
canon2gfcc cgr@(M.MGrammar ((a,M.ModMod abm):cms)) = 
     D.GFCC an cns abs cncs 
 where
  an  = (i2i a)
  cns = map (i2i . fst) cms
  abs = D.Abstr aflags funs cats catfuns
  aflags = Map.fromAscList [] ---- flags
  lfuns = [(f', (mkType ty,CM.primNotion)) | ---- defs 
             (f,GFC.AbsFun ty _) <- tree2list (M.jments abm), let f' = i2i f]
  funs = Map.fromAscList lfuns
  lcats = [(i2i c,[]) | ---- context
            (c,GFC.AbsCat _ _) <- tree2list (M.jments abm)]
  cats = Map.fromAscList lcats
  catfuns = Map.fromAscList 
    [(cat,[f | (f, (C.DTyp _ c _,_)) <- lfuns, c==cat]) | (cat,_) <- lcats]

  cncs  = Map.fromList [mkConcr (i2i lang) mo | (lang,M.ModMod mo) <- cms]
  mkConcr lang mo = (lang,D.Concr flags lins opers lincats lindefs printnames)
    where
      flags   = Map.fromAscList [] ---- flags
      opers   = Map.fromAscList [] -- opers will be created as optimization
      lins    = Map.fromAscList 
        [(i2i f, mkTerm tr) | (f,GFC.CncFun _ _ tr _) <- tree2list (M.jments mo)]
      lincats = Map.fromAscList 
        [(i2i c, mkCType ty) | (c,GFC.CncCat ty _ _) <- tree2list (M.jments mo)]
      lindefs = Map.fromAscList 
        [(i2i c, mkTerm tr) | (c,GFC.CncCat _ tr _) <- tree2list (M.jments mo)]
      printnames = Map.fromAscList [] ---- printnames

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) -> CM.cftype (map (i2i . snd) cs) (i2i $ snd c)

mkCType :: CType -> C.Term
mkCType t = case t of
  TInts i      -> C.C $ fromInteger i
  -- record parameter alias - created in gfc preprocessing
  RecType [Lbg (L (IC "_")) i, Lbg (L (IC "__")) t] -> C.RP (mkCType i) (mkCType t)
  RecType rs  -> C.R [mkCType t | Lbg _ t <- rs]
  Table pt vt -> C.R $ replicate (getI (mkCType pt)) $ mkCType vt
  TStr     -> C.S []
 where
  getI pt = case pt of
    C.C i -> i + 1
    C.RP i _ -> getI i

mkTerm :: Term -> C.Term
mkTerm tr = case tr of
  Arg (A _ i) -> C.V $ fromInteger i
  EInt i      -> C.C $ fromInteger i
  -- record parameter alias - created in gfc preprocessing
  R [Ass (L (IC "_")) i, Ass (L (IC "__")) t] -> C.RP (mkTerm i) (mkTerm t)
  -- ordinary record
  R rs     -> C.R [mkTerm t | Ass _ t <- rs]
  P t l    -> C.P (mkTerm t) (C.C (mkLab l))

  T _ cs   -> error $ "improper optimization for gfcc in" +++ A.prt tr
  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 _ _  -> prtTrace tr $ C.C 66661          ---- for debugging
  _ -> C.S [C.K (C.KS (A.prt tr +++ "66662"))] ---- for debugging
 where
   mkLab (L (IC l)) = case l of
     '_':ds -> (read ds) :: Int
     _ -> prtTrace tr $ 66663

-- return just one module per language

reorder :: CanonGrammar -> CanonGrammar
reorder cg = M.MGrammar $ 
    (abs, M.ModMod $ 
          M.Module M.MTAbstract M.MSComplete [] [] [] adefs):
      [(c, M.ModMod $ 
          M.Module (M.MTConcrete abs) M.MSComplete [] [] [] (sorted2tree js)) 
            | (c,js) <- cncs] 
     where
       abs = maybe (error "no abstract") id $ M.greatestAbstract cg
       mos = M.allModMod cg
       adefs = 
         sorted2tree $ sortBy (\ (f,_) (g,_) -> compare f g) 
            [finfo | 
              (i,mo) <- M.allModMod cg, M.isModAbs mo, 
              finfo <- tree2list (M.jments mo)]
       cncs = sortBy (\ (x,_) (y,_) -> compare x y)
            [(lang, concr lang) | lang <- M.allConcretes cg abs]
       concr la = sortBy (\ (f,_) (g,_) -> compare f g) 
            [finfo | 
              (i,mo) <- mos, M.isModCnc mo, elem i (M.allExtends cg la),
              finfo <- tree2list (M.jments mo)]

-- one grammar per language - needed for symtab generation
repartition :: CanonGrammar -> [CanonGrammar]
repartition cg = [M.partOfGrammar cg (lang,mo) | 
  let abs = maybe (error "no abstract") id $ M.greatestAbstract cg,
  let mos = M.allModMod cg,
  lang <- M.allConcretes cg abs,
  let mo = errVal 
       (error ("no module found for " ++ A.prt lang)) $ M.lookupModule cg lang
  ]

-- convert to UTF8 if not yet converted
utf8Conv :: CanonGrammar -> CanonGrammar
utf8Conv = M.MGrammar . map toUTF8 . M.modules where
  toUTF8 mo = case mo of
    (i, M.ModMod m) 
      | hasFlagCanon (flagCanon "coding" "utf8") mo -> mo
      | otherwise -> (i, M.ModMod $
          m{ M.jments = 
              mapTree (onSnd (mapInfoTerms (onTokens encodeUTF8))) (M.jments m),
	     M.flags = setFlag "coding" "utf8" (M.flags m) }
          )
    _ -> mo
 

-- translate tables and records to arrays, parameters and labels to indices

canon2canon :: CanonGrammar -> CanonGrammar
canon2canon = recollect . map cl2cl . repartition where
  recollect = 
    M.MGrammar . nubBy (\ (i,_) (j,_) -> i==j) . concatMap M.modules
  cl2cl cg = {-tr $-} M.MGrammar $ map c2c $ M.modules cg where
    c2c (c,m) = case m of
      M.ModMod mo@(M.Module _ _ _ _ _ js) ->
        (c, M.ModMod $ M.replaceJudgements mo $ mapTree j2j js)
      _ -> (c,m)
    j2j (f,j) = case j of
      GFC.CncFun x y tr z -> (f,GFC.CncFun x y (t2t tr) z)
      GFC.CncCat ty x y   -> (f,GFC.CncCat (ty2ty ty) (t2t x) y)
      _ -> (f,j)
    t2t = term2term cg pv
    ty2ty = type2type cg pv
    pv@(labels,untyps,typs) = paramValues cg
    tr = trace $
     (unlines [A.prt c ++ "." ++ unwords (map A.prt l) +++ "=" +++ show i  | 
       ((c,l),i) <- Map.toList labels]) ++
     (unlines [A.prt t +++ "=" +++ show i  | 
       (t,i) <- Map.toList untyps]) ++
     (unlines [A.prt t | 
       (t,_) <- Map.toList typs])

type ParamEnv =
  (Map.Map (Ident,[Label]) (CType,Integer), -- numbered labels
   Map.Map Term Integer,                    -- untyped terms to values
   Map.Map CType (Map.Map Term Integer))    -- types to their terms to values

--- gathers those param types that are actually used in lincats and in lin terms
paramValues :: CanonGrammar -> ParamEnv
paramValues cgr = (labels,untyps,typs) where
  params = [(ty, errVal [] $ Look.allParamValues cgr ty) | ty <- partyps]
  partyps = nub $ [ty | 
              (_,(_,CncCat (RecType ls) _ _)) <- jments,
              ty0 <- [ty | Lbg _ ty <- unlockTyp ls],
              ty  <- typsFrom ty0
            ] ++ [
             Cn (CIQ m ty) | 
              (m,(ty,ResPar _)) <- jments
            ] ++ [ty | 
              (_,(_,CncFun _ _ tr _)) <- jments,
              ty  <- err (const []) snd $ appSTM (typsFromTrm tr) []
            ]
  typsFrom ty = case ty of
    Table p t  -> typsFrom p ++ typsFrom t
    RecType ls -> RecType (unlockTyp ls) : concat [typsFrom t | Lbg _ t <- ls]
    _ -> [ty]
 
  typsFromTrm :: Term -> STM [CType] Term
  typsFromTrm tr = case tr of
    V ty ts -> updateSTM (ty:) >> mapM_ typsFromTrm ts >> return tr
    T ty cs -> updateSTM (ty:) >> mapM_ typsFromTrm [t | Cas _ t <- cs] >> return tr
    _ -> composOp typsFromTrm tr


  jments = [(m,j) | (m,mo) <- M.allModMod cgr, j <- tree2list $ M.jments mo]
  typs = Map.fromList [(ci,Map.fromList (zip vs [0..])) | (ci,vs) <- params]
  untyps = Map.fromList $ concatMap Map.toList [typ | (_,typ) <- Map.toList typs]
  lincats = 
    [(IC cat,[Lbg (L (IC "s")) TStr]) | cat <- ["Int", "Float", "String"]] ++
    [(cat,(unlockTyp ls)) | (_,(cat,CncCat (RecType ls) _ _)) <- jments]
  labels = Map.fromList $ concat 
    [((cat,[lab]),(typ,i)): 
      [((cat,[lab,lab2]),(ty,j)) | 
        rs <- getRec typ, (Lbg lab2 ty,j) <- zip rs [0..]] 
      | 
        (cat,ls) <- lincats, (Lbg lab typ,i) <- zip ls [0..]]
    -- go to tables recursively
    ---- TODO: even go to deeper records
   where
     getRec typ = case typ of
       RecType rs -> [rs]
       Table _ t  -> getRec t
       _ -> []

type2type :: CanonGrammar -> ParamEnv -> CType -> CType
type2type cgr env@(labels,untyps,typs) ty = case ty of
  RecType rs ->
    let
      rs' = [Lbg (mkLab i) (t2t t) | 
               (i,Lbg l t) <- zip [0..] (unlockTyp rs)]
    in if (any isStrType [t | Lbg _ t <- rs])
      then RecType rs'
      else RecType [Lbg (L (IC "_")) (look ty), Lbg (L (IC "__")) (RecType rs')]

  Table pt vt -> Table (t2t pt) (t2t vt)
  Cn _ -> look ty
  _ -> ty
 where
   t2t = type2type cgr env
   look ty = TInts $ (+ (-1)) $ toInteger $ case Map.lookup ty typs of
     Just vs -> length $ Map.assocs vs
     _ -> trace ("unknown partype " ++ show ty) 1 ---- 66669

term2term :: CanonGrammar -> ParamEnv -> Term -> Term
term2term cgr env@(labels,untyps,typs) tr = case tr of
  Par _ _ -> mkValCase tr 
  R rs ->
    let
      rs' = [Ass (mkLab i) (t2t t) | 
               (i,Ass l t) <- zip [0..] (unlock rs)]
    in if (any (isStr . trmAss) rs)
      then R rs'
      else R [Ass (L (IC "_")) (mkValCase tr), Ass (L (IC "__")) (R rs')]
  P t l    -> r2r tr

  T ti [Cas ps@[PV _] t] -> T ti [Cas ps (t2t t)]

  T _ cs0  -> case expandLinTables cgr tr of  -- normalize order of cases
    Ok (T ty cs) -> checkCases cs $ V ty [t2t t | Cas _ t <- cs]
    _ -> K (KS (A.prt tr +++ prtTrace tr "66668"))
  V ty ts  -> V ty [t2t t | t <- ts]
  S t p    -> S (t2t t) (t2t p)
  _ -> composSafeOp t2t tr
 where
   t2t = term2term cgr env

   checkCases cs a = 
     if null [() | Cas (_:_:_) _ <- cs] -- no share option active
       then a
       else error $ "Share optimization illegal for gfcc in" +++ A.prt tr ++++
         "Recompile with -optimize=(values | none | subs | all_subs)."

   r2r tr@(P (S (V ty ts) v) l) = t2t $ S (V ty [comp (P t l) | t <- ts]) v

   r2r tr@(P p _) = case getLab tr of
     Ok (cat,labs) -> P (t2t p) . mkLab $ maybe (prtTrace tr $ 66664) snd $ 
          Map.lookup (cat,labs) labels
     _ -> K (KS (A.prt tr +++ prtTrace tr "66665"))

   -- this goes recursively into tables (ignored) and records (accumulated)
   getLab tr = case tr of
     Arg (A cat _) -> return (cat,[])
     P p lab2 -> do
       (cat,labs) <- getLab p
       return (cat,labs++[lab2]) 
     S p _ -> getLab p
     _ -> Bad "getLab"

   doVar :: Term -> STM [((CType,[Term]),(Term,Term))] Term
   doVar tr = case getLab tr of
     Ok (cat, lab) -> do
       k <- readSTM >>= return . length
       let tr' = LI $ identC $ show k

       let tyvs = case Map.lookup (cat,lab) labels of
             Just (ty,_) -> case Map.lookup ty typs of
               Just vs -> (ty,[t | 
                            (t,_) <- sortBy (\x y -> compare (snd x) (snd y)) 
                                            (Map.assocs vs)])
               _ -> error $ A.prt ty
             _ -> error $ A.prt tr
       updateSTM ((tyvs, (tr', tr)):) 
       return tr'
     _ -> composOp doVar tr

   mkValCase tr = case appSTM (doVar tr) [] of
     Ok (tr', st@(_:_)) -> t2t $ comp $ foldr mkCase tr' st
     _ -> valNum tr

   mkCase ((ty,vs),(x,p)) tr = 
     S (V ty [mkBranch x v tr | v <- vs]) p
   mkBranch x t tr = case tr of
     _ | tr == x -> t
     _ -> composSafeOp (mkBranch x t) tr     

   valNum tr = maybe (tryPerm tr) EInt $ Map.lookup tr untyps
    where
      tryPerm tr = case tr of
        R rs -> case Map.lookup (R rs) untyps of
	  Just v -> EInt v
          _ -> valNumFV $ tryVar tr
        _ -> valNumFV $ tryVar tr
      tryVar tr = case tr of
        Par c ts -> [Par c ts' | ts' <- combinations (map tryVar ts)]
        FV ts -> ts
        _ -> [tr]
      valNumFV ts = case ts of
        [tr] -> EInt 66667 ----K (KS (A.prt tr +++ prtTrace tr "66667"))
        _ -> FV $ map valNum ts
   isStr tr = case tr of
     Par _ _ -> False
     EInt _  -> False
     R rs    -> any (isStr . trmAss) rs
     FV ts   -> any isStr ts
     S t _   -> isStr t
     E       -> True
     T _ cs  -> any isStr [v | Cas _ v <- cs]
     V _ ts  -> any isStr ts
     P t r   -> case getLab tr of
       Ok (cat,labs) -> case 
          Map.lookup (cat,labs) labels of
            Just (ty,_) -> isStrType ty 
            _ -> True ---- TODO?
       _ -> True
     _ -> True ----
   trmAss (Ass _ t) = t

   --- this is mainly needed for parameter record projections
   comp t = errVal t $ Look.ccompute cgr [] t

isStrType ty = case ty of
     TStr -> True
     RecType ts -> any isStrType [t | Lbg _ t <- ts]
     Table _ t -> isStrType t
     _ -> False

mkLab k = L (IC ("_" ++ show k))

-- remove lock fields; in fact, any empty records and record types
unlock = filter notlock where
  notlock (Ass l t) = case t of --- need not look at l
     R [] -> False
     _ -> True
unlockTyp = filter notlock where
  notlock (Lbg l t) = case t of --- need not look at l
     RecType [] -> False
     _ -> True


prtTrace tr n = n ----trace ("-- ERROR" +++ A.prt tr +++ show n +++ show tr) n
prTrace  tr n = trace ("-- OBSERVE" +++ A.prt tr +++ show n +++ show tr) n