path: root/src/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.Infra.Modules
import GF.Grammar.PrGrammar
import GF.Grammar.Macros
import GF.Grammar.Lookup
import GF.Grammar.Predef
import GF.Compile.Refresh
import GF.Compile.Compute
import GF.Compile.BackOpt
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 Debug.Trace


-- conditional trace

prtIf :: (Print a) => Bool -> a -> a
prtIf b t = if b then trace (" " ++ prt t) t else t

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

type EEnv = () --- not used

-- only do this for resource: concrete is optimized in gfc form
optimizeModule :: Options -> ([(Ident,SourceModInfo)],EEnv) -> 
                  (Ident,SourceModInfo) -> Err ((Ident,SourceModInfo),EEnv)
optimizeModule opts mse@(ms,eenv) mo@(_,mi) = case mi of
  ModMod m0 | mstatus m0 == MSComplete && isModRes m0 -> do
      (mo1,_) <- evalModule oopts mse mo
      let mo2 = shareModule optim mo1
      return (mo2,eenv)
  _ -> evalModule oopts mse mo
 where
   oopts = addOptions opts (moduleOptions (flagsModule mo))
   optim = moduleFlag optOptimizations oopts

evalModule :: Options -> ([(Ident,SourceModInfo)],EEnv) -> (Ident,SourceModInfo) -> 
               Err ((Ident,SourceModInfo),EEnv)
evalModule oopts (ms,eenv) mo@(name,mod) = case mod of

  ModMod m0 | mstatus m0 == MSComplete -> case mtype m0 of
    _ | isModRes m0 -> do
      let deps = allOperDependencies name (jments m0)
      ids <- topoSortOpers deps
      MGrammar (mod' : _) <- foldM evalOp gr ids
      return $ (mod',eenv)

    MTConcrete a -> do
      js' <- mapMTree (evalCncInfo oopts gr name a) (jments m0)
      return $ ((name, ModMod (replaceJudgements m0 js')),eenv)

    _ -> return $ ((name,mod),eenv)
  _ -> return $ ((name,mod),eenv)
 where
   gr0 = MGrammar $ ms
   gr  = MGrammar $ (name,mod) : ms

   evalOp g@(MGrammar ((_, ModMod m) : _)) i = do
     info  <- lookupTree prt i $ jments m
     info' <- evalResInfo oopts gr (i,info)
     return $ updateRes g name i info'

-- | only operations need be compiled in a resource, and this is local to each
-- definition since the module is traversed in topological order
evalResInfo :: Options -> SourceGrammar -> (Ident,Info) -> Err Info
evalResInfo oopts gr (c,info) = case info of

  ResOper pty pde -> eIn "operation" $ do
    pde' <- case pde of
       Yes de | optres -> liftM yes $ comp de 
       _ -> return pde
    return $ ResOper pty pde'

  _ ->  return info
 where
   comp = if optres then computeConcrete gr else computeConcreteRec gr
   eIn cat = errIn ("Error optimizing" +++ cat +++ prt c +++ ":")
   optim = moduleFlag optOptimizations oopts
   optres = OptExpand `Set.member` optim


evalCncInfo :: 
  Options -> SourceGrammar -> Ident -> Ident -> (Ident,Info) -> Err (Ident,Info)
evalCncInfo opts gr cnc abs (c,info) = do

 seq (prtIf (verbAtLeast opts Verbose) c) $ return ()

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

  CncCat ptyp pde ppr -> do
    pde' <- case (ptyp,pde) of
      (Yes typ, Yes de) -> 
        liftM yes $ pEval ([(varStr, typeStr)], typ) de
      (Yes typ, Nope)   -> 
        liftM yes $ mkLinDefault gr typ >>= partEval noOptions gr ([(varStr, typeStr)],typ)
      (May b, Nope) ->
        return $ May b
      _ -> return pde   -- indirection

    ppr' <- liftM yes $ evalPrintname gr c ppr (yes $ K $ prt c)

    return (c, CncCat ptyp pde' ppr')

  CncFun (mt@(Just (_,ty@(cont,val)))) pde ppr -> --trace (prt c) $
       eIn ("linearization in type" +++ prt (mkProd (cont,val,[])) ++++ "of function") $ do
    pde' <- case pde of
      Yes de -> do
        liftM yes $ pEval ty de

      _ -> return pde
    ppr' <-  liftM yes $ evalPrintname gr c ppr pde'
    return $ (c, CncFun mt pde' ppr') -- only cat in type actually needed

  _ ->  return (c,info)
 where
   pEval = partEval opts gr
   eIn cat = errIn ("Error optimizing" +++ cat +++ prt c +++ ":")

-- | the main function for compiling linearizations
partEval :: Options -> SourceGrammar -> (Context,Type) -> Term -> Err Term
partEval opts gr (context, val) trm = errIn ("parteval" +++ prt_ trm) $ do
  let vars  = map fst 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
            else recordExpand val trm2 >>= computeTerm gr subst
  return $ mkAbs vars trm3
  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 unComputed 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 = do
  case unComputed typ of
    RecType lts -> mapPairsM mkDefField lts >>= (return . Abs varStr . R . mkAssign)
    _ -> liftM (Abs varStr) $ mkDefField typ
----    _ -> prtBad "linearization type must be a record type, not" typ
 where
   mkDefField typ = case unComputed 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 q p             -> lookupFirstTag gr q p
     RecType r  -> do
       let (ls,ts) = unzip r
       ts' <- mapM mkDefField ts
       return $ R $ [assign l t | (l,t) <- zip ls ts']
     _ | Just _ <- isTypeInts typ -> return $ EInt 0 -- exists in all as first val
     _ -> prtBad "linearization type field cannot be" typ

-- | Form the printname: if given, compute. If not, use the computed
-- lin for functions, cat name for cats (dispatch made in evalCncDef above).
--- We cannot use linearization at this stage, since we do not know the
--- defaults we would need for question marks - and we're not yet in canon.
evalPrintname :: SourceGrammar -> Ident -> MPr -> Perh Term -> Err Term
evalPrintname gr c ppr lin =
  case ppr of
    Yes pr -> comp pr
    _ -> case lin of
      Yes t -> return $ K $ clean $ prt $ oneBranch t ---- stringFromTerm
      _ -> return $ K $ prt c ----
 where
   comp = computeConcrete gr

   oneBranch t = case t of
     Abs _ b   -> oneBranch b
     R   (r:_) -> oneBranch $ snd $ snd r
     T _ (c:_) -> oneBranch $ snd c
     V _ (c:_) -> oneBranch c
     FV  (t:_) -> oneBranch t
     C x y     -> C (oneBranch x) (oneBranch y)
     S x _     -> oneBranch x
     P x _     -> oneBranch x
     Alts (d,_) -> oneBranch d
     _ -> t

  --- very unclean cleaner
   clean s = case s of
     '+':'+':' ':cs -> clean cs
     '"':cs -> clean cs
     c:cs -> c: clean cs
     _ -> s