{- (c) The AQUA Project, Glasgow University, 1993-1998 \section[SimplMonad]{The simplifier Monad} -} module SimplMonad ( -- The monad SimplM, initSmpl, traceSmpl, getSimplRules, getFamEnvs, -- Unique supply MonadUnique(..), newId, newJoinId, -- Counting SimplCount, tick, freeTick, checkedTick, getSimplCount, zeroSimplCount, pprSimplCount, plusSimplCount, isZeroSimplCount ) where import GhcPrelude import Var ( Var, isTyVar, mkLocalVar ) import Name ( mkSystemVarName ) import Id ( Id, mkSysLocalOrCoVar ) import IdInfo ( IdDetails(..), vanillaIdInfo, setArityInfo ) import Type ( Type, mkLamTypes ) import FamInstEnv ( FamInstEnv ) import CoreSyn ( RuleEnv(..) ) import UniqSupply import DynFlags import CoreMonad import Outputable import FastString import MonadUtils import ErrUtils as Err import Panic (throwGhcExceptionIO, GhcException (..)) import BasicTypes ( IntWithInf, treatZeroAsInf, mkIntWithInf ) import Control.Monad ( liftM, ap ) {- ************************************************************************ * * \subsection{Monad plumbing} * * ************************************************************************ For the simplifier monad, we want to {\em thread} a unique supply and a counter. (Command-line switches move around through the explicitly-passed SimplEnv.) -} newtype SimplM result = SM { unSM :: SimplTopEnv -- Envt that does not change much -> UniqSupply -- We thread the unique supply because -- constantly splitting it is rather expensive -> SimplCount -> IO (result, UniqSupply, SimplCount)} -- we only need IO here for dump output data SimplTopEnv = STE { st_flags :: DynFlags , st_max_ticks :: IntWithInf -- Max #ticks in this simplifier run , st_rules :: RuleEnv , st_fams :: (FamInstEnv, FamInstEnv) } initSmpl :: DynFlags -> RuleEnv -> (FamInstEnv, FamInstEnv) -> UniqSupply -- No init count; set to 0 -> Int -- Size of the bindings, used to limit -- the number of ticks we allow -> SimplM a -> IO (a, SimplCount) initSmpl dflags rules fam_envs us size m = do (result, _, count) <- unSM m env us (zeroSimplCount dflags) return (result, count) where env = STE { st_flags = dflags, st_rules = rules , st_max_ticks = computeMaxTicks dflags size , st_fams = fam_envs } computeMaxTicks :: DynFlags -> Int -> IntWithInf -- Compute the max simplifier ticks as -- (base-size + pgm-size) * magic-multiplier * tick-factor/100 -- where -- magic-multiplier is a constant that gives reasonable results -- base-size is a constant to deal with size-zero programs computeMaxTicks dflags size = treatZeroAsInf $ fromInteger ((toInteger (size + base_size) * toInteger (tick_factor * magic_multiplier)) `div` 100) where tick_factor = simplTickFactor dflags base_size = 100 magic_multiplier = 40 -- MAGIC NUMBER, multiplies the simplTickFactor -- We can afford to be generous; this is really -- just checking for loops, and shouldn't usually fire -- A figure of 20 was too small: see Trac #5539. {-# INLINE thenSmpl #-} {-# INLINE thenSmpl_ #-} {-# INLINE returnSmpl #-} instance Functor SimplM where fmap = liftM instance Applicative SimplM where pure = returnSmpl (<*>) = ap (*>) = thenSmpl_ instance Monad SimplM where (>>) = (*>) (>>=) = thenSmpl returnSmpl :: a -> SimplM a returnSmpl e = SM (\_st_env us sc -> return (e, us, sc)) thenSmpl :: SimplM a -> (a -> SimplM b) -> SimplM b thenSmpl_ :: SimplM a -> SimplM b -> SimplM b thenSmpl m k = SM $ \st_env us0 sc0 -> do (m_result, us1, sc1) <- unSM m st_env us0 sc0 unSM (k m_result) st_env us1 sc1 thenSmpl_ m k = SM $ \st_env us0 sc0 -> do (_, us1, sc1) <- unSM m st_env us0 sc0 unSM k st_env us1 sc1 -- TODO: this specializing is not allowed -- {-# SPECIALIZE mapM :: (a -> SimplM b) -> [a] -> SimplM [b] #-} -- {-# SPECIALIZE mapAndUnzipM :: (a -> SimplM (b, c)) -> [a] -> SimplM ([b],[c]) #-} -- {-# SPECIALIZE mapAccumLM :: (acc -> b -> SimplM (acc,c)) -> acc -> [b] -> SimplM (acc, [c]) #-} traceSmpl :: String -> SDoc -> SimplM () traceSmpl herald doc = do { dflags <- getDynFlags ; liftIO $ Err.dumpIfSet_dyn dflags Opt_D_dump_simpl_trace "Simpl Trace" (hang (text herald) 2 doc) } {- ************************************************************************ * * \subsection{The unique supply} * * ************************************************************************ -} instance MonadUnique SimplM where getUniqueSupplyM = SM (\_st_env us sc -> case splitUniqSupply us of (us1, us2) -> return (us1, us2, sc)) getUniqueM = SM (\_st_env us sc -> case takeUniqFromSupply us of (u, us') -> return (u, us', sc)) getUniquesM = SM (\_st_env us sc -> case splitUniqSupply us of (us1, us2) -> return (uniqsFromSupply us1, us2, sc)) instance HasDynFlags SimplM where getDynFlags = SM (\st_env us sc -> return (st_flags st_env, us, sc)) instance MonadIO SimplM where liftIO m = SM $ \_ us sc -> do x <- m return (x, us, sc) getSimplRules :: SimplM RuleEnv getSimplRules = SM (\st_env us sc -> return (st_rules st_env, us, sc)) getFamEnvs :: SimplM (FamInstEnv, FamInstEnv) getFamEnvs = SM (\st_env us sc -> return (st_fams st_env, us, sc)) newId :: FastString -> Type -> SimplM Id newId fs ty = do uniq <- getUniqueM return (mkSysLocalOrCoVar fs uniq ty) newJoinId :: [Var] -> Type -> SimplM Id newJoinId bndrs body_ty = do { uniq <- getUniqueM ; let name = mkSystemVarName uniq (fsLit "$j") join_id_ty = mkLamTypes bndrs body_ty -- Note [Funky mkLamTypes] arity = length (filter (not . isTyVar) bndrs) join_arity = length bndrs details = JoinId join_arity id_info = vanillaIdInfo `setArityInfo` arity -- `setOccInfo` strongLoopBreaker ; return (mkLocalVar details name join_id_ty id_info) } {- ************************************************************************ * * \subsection{Counting up what we've done} * * ************************************************************************ -} getSimplCount :: SimplM SimplCount getSimplCount = SM (\_st_env us sc -> return (sc, us, sc)) tick :: Tick -> SimplM () tick t = SM (\st_env us sc -> let sc' = doSimplTick (st_flags st_env) t sc in sc' `seq` return ((), us, sc')) checkedTick :: Tick -> SimplM () -- Try to take a tick, but fail if too many checkedTick t = SM (\st_env us sc -> if st_max_ticks st_env <= mkIntWithInf (simplCountN sc) then throwGhcExceptionIO $ PprProgramError "Simplifier ticks exhausted" (msg sc) else let sc' = doSimplTick (st_flags st_env) t sc in sc' `seq` return ((), us, sc')) where msg sc = vcat [ text "When trying" <+> ppr t , text "To increase the limit, use -fsimpl-tick-factor=N (default 100)." , space , text "If you need to increase the limit substantially, please file a" , text "bug report and indicate the factor you needed." , space , text "If GHC was unable to complete compilation even" <+> text "with a very large factor" , text "(a thousand or more), please consult the" <+> doubleQuotes (text "Known bugs or infelicities") , text "section in the Users Guide before filing a report. There are a" , text "few situations unlikely to occur in practical programs for which" , text "simplifier non-termination has been judged acceptable." , space , pp_details sc , pprSimplCount sc ] pp_details sc | hasDetailedCounts sc = empty | otherwise = text "To see detailed counts use -ddump-simpl-stats" freeTick :: Tick -> SimplM () -- Record a tick, but don't add to the total tick count, which is -- used to decide when nothing further has happened freeTick t = SM (\_st_env us sc -> let sc' = doFreeSimplTick t sc in sc' `seq` return ((), us, sc'))