path: root/src/compiler/GF/Compile/Optimize.hs

{-# LANGUAGE PatternGuards #-}
----------------------------------------------------------------------
-- |
-- Module      : Optimize
-- Maintainer  : AR
-- Stability   : (stable)
-- Portability : (portable)
--
-- > CVS $Date: 2005/09/16 13:56:13 $ 
-- > CVS $Author: aarne $
-- > CVS $Revision: 1.18 $
--
-- Top-level partial evaluation for GF source modules.
-----------------------------------------------------------------------------

module GF.Compile.Optimize (optimizeModule) where

import GF.Grammar.Grammar
import GF.Infra.Ident
import GF.Grammar.Printer
import GF.Grammar.Macros
import GF.Grammar.Lookup
import GF.Grammar.Predef
--import GF.Compile.Refresh
import GF.Compile.Compute.Concrete
import GF.Compile.CheckGrammar
import GF.Compile.Update

import GF.Data.Operations
import GF.Infra.CheckM
import GF.Infra.Option

import Control.Monad
import Data.List
import qualified Data.Set as Set
import Text.PrettyPrint
import Debug.Trace
import qualified Data.ByteString.Char8 as BS


-- | partial evaluation of concrete syntax. AR 6\/2001 -- 16\/5\/2003 -- 5\/2\/2005.

optimizeModule :: Options -> SourceGrammar -> SourceModule -> Err SourceModule
optimizeModule opts sgr m@(name,mi)
  | mstatus mi == MSComplete = do
      ids <- topoSortJments m
      mi <- foldM updateEvalInfo mi ids
      return (name,mi)
  | otherwise = return m
 where
   oopts = opts `addOptions` mflags mi

   updateEvalInfo mi (i,info) = do
     info <- evalInfo oopts sgr (name,mi) i info
     return (mi{jments=updateTree (i,info) (jments mi)})

evalInfo :: Options -> SourceGrammar -> SourceModule -> Ident -> Info -> Err Info
evalInfo opts sgr m c info = do

 (if verbAtLeast opts Verbose then trace (" " ++ showIdent c) else id) return ()

 errIn ("optimizing " ++ showIdent c) $ case info of

  CncCat ptyp pde ppr mpmcfg -> do
    pde' <- case (ptyp,pde) of
      (Just (L _ typ), Just (L loc de)) -> do
        de <- partEval opts gr ([(Explicit, varStr, typeStr)], typ) de
        return (Just (L loc (factor param c 0 de)))
      (Just (L loc typ), Nothing) -> do
        de <- mkLinDefault gr typ
        de <- partEval opts gr ([(Explicit, varStr, typeStr)], typ) de
        return (Just (L loc (factor param c 0 de)))
      _ -> return pde   -- indirection

    ppr' <- evalPrintname gr ppr

    return (CncCat ptyp pde' ppr' mpmcfg)

  CncFun (mt@(Just (_,cont,val))) pde ppr mpmcfg -> --trace (prt c) $
       eIn (text "linearization in type" <+> ppTerm Unqualified 0 (mkProd cont val []) $$ text "of function") $ do
    pde' <- case pde of
      Just (L loc de) -> do de <- partEval opts gr (cont,val) de
                            return (Just (L loc (factor param c 0 de)))
      Nothing -> return pde
    ppr' <-  evalPrintname gr ppr
    return $ CncFun mt pde' ppr' mpmcfg -- only cat in type actually needed

  ResOper pty pde 
    | not new && OptExpand `Set.member` optim -> do
         pde' <- case pde of
                   Just (L loc de) -> do de <- computeConcrete gr de
                                         return (Just (L loc (factor param c 0 de)))
                   Nothing -> return Nothing
         return $ ResOper pty pde'

  _ ->  return info
 where
   new = flag optNewComp opts -- computations moved to GF.Compile.GeneratePMCFG

   gr = prependModule sgr m
   optim = flag optOptimizations opts
   param = OptParametrize `Set.member` optim
   eIn cat = errIn (render (text "Error optimizing" <+> cat <+> ppIdent c <+> colon))

-- | the main function for compiling linearizations
partEval :: Options -> SourceGrammar -> (Context,Type) -> Term -> Err Term
partEval opts = if flag optNewComp opts
                then partEvalNew opts
                else partEvalOld opts

partEvalNew opts gr (context, val) trm =
    errIn (render (text "partial evaluation" <+> ppTerm Qualified 0 trm)) $
    checkPredefError gr trm

partEvalOld opts gr (context, val) trm = errIn (render (text "partial evaluation" <+> ppTerm Qualified 0 trm)) $ do
  let vars  = map (\(bt,x,t) -> x) context
      args  = map Vr vars
      subst = [(v, Vr v) | v <- vars]
      trm1 = mkApp trm args
  trm2 <- computeTerm gr subst trm1
  trm3 <- if rightType trm2
          then computeTerm gr subst trm2 -- compute twice??
          else recordExpand val trm2 >>= computeTerm gr subst
  trm4 <- checkPredefError gr trm3
  return $ mkAbs [(Explicit,v) | v <- vars] trm4
  where
    -- don't eta expand records of right length (correct by type checking)
    rightType (R rs) = case val of
                         RecType ts -> length rs == length ts
                         _          -> False
    rightType _      = False




-- here we must be careful not to reduce
--   variants {{s = "Auto" ; g = N} ; {s = "Wagen" ; g = M}}
--   {s  = variants {"Auto" ; "Wagen"} ; g  = variants {N ; M}} ;

recordExpand :: Type -> Term -> Err Term
recordExpand typ trm = case typ of
  RecType tys -> case trm of
    FV rs -> return $ FV [R [assign lab (P r lab) | (lab,_) <- tys] | r <- rs]
    _ -> return $ R [assign lab (P trm lab) | (lab,_) <- tys]
  _ -> return trm


-- | auxiliaries for compiling the resource

mkLinDefault :: SourceGrammar -> Type -> Err Term
mkLinDefault gr typ = liftM (Abs Explicit varStr) $ mkDefField typ
 where
   mkDefField typ = case typ of
     Table p t  -> do
       t' <- mkDefField t
       let T _ cs = mkWildCases t'
       return $ T (TWild p) cs
     Sort s | s == cStr -> return $ Vr varStr
     QC p           -> do vs <- lookupParamValues gr p
                          case vs of
                            v:_ -> return v
                            _   -> Bad (render (text "no parameter values given to type" <+> ppQIdent Qualified p))
     RecType r  -> do
       let (ls,ts) = unzip r
       ts <- mapM mkDefField ts
       return $ R (zipWith assign ls ts)
     _ | Just _ <- isTypeInts typ -> return $ EInt 0 -- exists in all as first val
     _ -> Bad (render (text "linearization type field cannot be" <+> ppTerm Unqualified 0 typ))

evalPrintname :: SourceGrammar -> Maybe (L Term) -> Err (Maybe (L Term))
evalPrintname gr mpr =
  case mpr of
    Just (L loc pr) -> do pr <- computeConcrete gr pr
                          return (Just (L loc pr))
    Nothing         -> return Nothing

-- do even more: factor parametric branches

factor :: Bool -> Ident -> Int -> Term -> Term
factor param c i t =
  case t of
    T (TComp ty) cs -> factors ty [(p, factor param c (i+1) v) | (p, v) <- cs]
    _               -> composSafeOp (factor param c i) t
  where
    factors ty pvs0  
                 | not param = V ty (map snd pvs0)
    factors ty []            = V ty []
    factors ty pvs0@[(p,v)]  = V ty [v]
    factors ty pvs0@(pv:pvs) =
      let t  = mkFun pv
          ts = map mkFun pvs
      in if all (==t) ts
           then T (TTyped ty) (mkCases t)
           else V ty (map snd pvs0)

    --- we hope this will be fresh and don't check... in GFC would be safe
    qvar = identC (BS.pack ("q_" ++ showIdent c ++ "__" ++ show i))

    mkFun (patt, val) = replace (patt2term patt) (Vr qvar) val
    mkCases t = [(PV qvar, t)]

--  we need to replace subterms
replace :: Term -> Term -> Term -> Term
replace old new trm =
  case trm of
    -- these are the important cases, since they can correspond to patterns  
    QC _     | trm == old -> new
    App _ _  | trm == old -> new
    R _      | trm == old -> new
    App x y               -> App (replace old new x) (replace old new y)
    _                     -> composSafeOp (replace old new) trm