\begin{code}
module SimplMonad (
- InId, InBind, InExpr, InAlt, InArg, InType, InBinder,
- OutId, OutBind, OutExpr, OutAlt, OutArg, OutType, OutBinder,
- OutExprStuff, OutStuff,
-
- -- The continuation type
- SimplCont(..), DupFlag(..), contIsDupable, contResultType,
- contIsInteresting, pushArgs, discardCont, countValArgs, countArgs,
- contArgs, contIsInline, discardInline,
-
-- The monad
SimplM,
initSmpl, returnSmpl, thenSmpl, thenSmpl_,
mapSmpl, mapAndUnzipSmpl, mapAccumLSmpl,
-
- -- The inlining black-list
- getBlackList,
+ getDOptsSmpl,
-- Unique supply
- getUniqueSmpl, getUniquesSmpl,
- newId, newIds,
+ getUniqueSmpl, getUniquesSmpl, getUniqSupplySmpl, newId,
-- Counting
SimplCount, Tick(..),
plusSimplCount, isZeroSimplCount,
-- Switch checker
- SwitchChecker, getSwitchChecker, getSimplIntSwitch,
-
- -- Cost centres
- getEnclosingCC, setEnclosingCC,
-
- -- Environments
- getSubst, setSubst,
- getSubstEnv, extendSubst, extendSubstList,
- getInScope, setInScope, extendInScope, extendInScopes, modifyInScope,
- setSubstEnv, zapSubstEnv,
- getSimplBinderStuff, setSimplBinderStuff,
- switchOffInlining
+ SwitchChecker, SwitchResult(..), getSimplIntSwitch,
+ isAmongSimpl, intSwitchSet, switchIsOn
) where
#include "HsVersions.h"
-import Const ( Con(DEFAULT) )
-import Id ( Id, mkSysLocal, idMustBeINLINEd )
-import IdInfo ( InlinePragInfo(..) )
-import Demand ( Demand )
-import CoreSyn
-import PprCore () -- Instances
-import Rules ( RuleBase )
-import CostCentre ( CostCentreStack, subsumedCCS )
-import Var ( TyVar )
-import VarEnv
-import VarSet
-import qualified Subst
-import Subst ( Subst, emptySubst, mkSubst,
- substTy, substEnv, substExpr,
- InScopeSet, substInScope, isInScope, lookupInScope
- )
-import Type ( Type, TyVarSubst, applyTy )
+import Id ( Id, mkSysLocal )
+import Type ( Type )
import UniqSupply ( uniqsFromSupply, uniqFromSupply, splitUniqSupply,
UniqSupply
)
-import FiniteMap
-import CmdLineOpts ( SimplifierSwitch(..), SwitchResult(..),
- opt_PprStyle_Debug, opt_HistorySize,
- intSwitchSet
- )
+import DynFlags ( SimplifierSwitch(..), DynFlags, DynFlag(..), dopt )
+import StaticFlags ( opt_PprStyle_Debug, opt_HistorySize )
+import OccName ( EncodedFS )
import Unique ( Unique )
import Maybes ( expectJust )
-import Util ( zipWithEqual )
+import FiniteMap ( FiniteMap, emptyFM, isEmptyFM, lookupFM, addToFM, plusFM_C, fmToList )
+import FastString ( FastString )
import Outputable
+import FastTypes
-infixr 9 `thenSmpl`, `thenSmpl_`
-\end{code}
-
-%************************************************************************
-%* *
-\subsection[Simplify-types]{Type declarations}
-%* *
-%************************************************************************
-
-\begin{code}
-type InBinder = CoreBndr
-type InId = Id -- Not yet cloned
-type InType = Type -- Ditto
-type InBind = CoreBind
-type InExpr = CoreExpr
-type InAlt = CoreAlt
-type InArg = CoreArg
-
-type OutBinder = CoreBndr
-type OutId = Id -- Cloned
-type OutType = Type -- Cloned
-type OutBind = CoreBind
-type OutExpr = CoreExpr
-type OutAlt = CoreAlt
-type OutArg = CoreArg
-
-type SwitchChecker = SimplifierSwitch -> SwitchResult
-\end{code}
-
-
-%************************************************************************
-%* *
-\subsection{The continuation data type}
-%* *
-%************************************************************************
-
-\begin{code}
-type OutExprStuff = OutStuff (InScopeSet, OutExpr)
-type OutStuff a = ([OutBind], a)
- -- We return something equivalent to (let b in e), but
- -- in pieces to avoid the quadratic blowup when floating
- -- incrementally. Comments just before simplExprB in Simplify.lhs
-
-data SimplCont -- Strict contexts
- = Stop OutType -- Type of the result
-
- | CoerceIt OutType -- The To-type, simplified
- SimplCont
-
- | InlinePlease -- This continuation makes a function very
- SimplCont -- keen to inline itelf
-
- | ApplyTo DupFlag
- InExpr SubstEnv -- The argument, as yet unsimplified,
- SimplCont -- and its subst-env
-
- | Select DupFlag
- InId [InAlt] SubstEnv -- The case binder, alts, and subst-env
- SimplCont
-
- | ArgOf DupFlag -- An arbitrary strict context: the argument
- -- of a strict function, or a primitive-arg fn
- -- or a PrimOp
- OutType -- The type of the expression being sought by the context
- -- f (error "foo") ==> coerce t (error "foo")
- -- when f is strict
- -- We need to know the type t, to which to coerce.
- (OutExpr -> SimplM OutExprStuff) -- What to do with the result
-
-instance Outputable SimplCont where
- ppr (Stop _) = ptext SLIT("Stop")
- ppr (ApplyTo dup arg se cont) = (ptext SLIT("ApplyTo") <+> ppr dup <+> ppr arg) $$ ppr cont
- ppr (ArgOf dup _ _) = ptext SLIT("ArgOf...") <+> ppr dup
- ppr (Select dup bndr alts se cont) = (ptext SLIT("Select") <+> ppr dup <+> ppr bndr) $$
- (nest 4 (ppr alts)) $$ ppr cont
- ppr (CoerceIt ty cont) = (ptext SLIT("CoerceIt") <+> ppr ty) $$ ppr cont
- ppr (InlinePlease cont) = ptext SLIT("InlinePlease") $$ ppr cont
-
-data DupFlag = OkToDup | NoDup
-
-instance Outputable DupFlag where
- ppr OkToDup = ptext SLIT("ok")
- ppr NoDup = ptext SLIT("nodup")
-
-contIsDupable :: SimplCont -> Bool
-contIsDupable (Stop _) = True
-contIsDupable (ApplyTo OkToDup _ _ _) = True
-contIsDupable (ArgOf OkToDup _ _) = True
-contIsDupable (Select OkToDup _ _ _ _) = True
-contIsDupable (CoerceIt _ cont) = contIsDupable cont
-contIsDupable (InlinePlease cont) = contIsDupable cont
-contIsDupable other = False
-
-contArgs :: InScopeSet -> SimplCont -> ([OutExpr], SimplCont)
- -- Get the arguments from the continuation
- -- Apply the appropriate substitution first;
- -- this is done lazily and typically only the bit at the top is used
-contArgs in_scope (ApplyTo _ e s cont)
- = case contArgs in_scope cont of
- (args, result) -> (substExpr (mkSubst in_scope s) e : args, result)
-contArgs in_scope result_cont
- = ([], result_cont)
-
-contIsInline :: SimplCont -> Bool
-contIsInline (InlinePlease cont) = True
-contIsInline other = False
-
-discardInline :: SimplCont -> SimplCont
-discardInline (InlinePlease cont) = cont
-discardInline (ApplyTo d e s cont) = ApplyTo d e s (discardInline cont)
-discardInline cont = cont
-\end{code}
+import GLAEXTS ( indexArray# )
+#if __GLASGOW_HASKELL__ < 503
+import PrelArr ( Array(..) )
+#else
+import GHC.Arr ( Array(..) )
+#endif
-Comment about contIsInteresting
-~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
-We want to avoid inlining an expression where there can't possibly be
-any gain, such as in an argument position. Hence, if the continuation
-is interesting (eg. a case scrutinee, application etc.) then we
-inline, otherwise we don't.
-
-Previously some_benefit used to return True only if the variable was
-applied to some value arguments. This didn't work:
-
- let x = _coerce_ (T Int) Int (I# 3) in
- case _coerce_ Int (T Int) x of
- I# y -> ....
-
-we want to inline x, but can't see that it's a constructor in a case
-scrutinee position, and some_benefit is False.
-
-Another example:
-
-dMonadST = _/\_ t -> :Monad (g1 _@_ t, g2 _@_ t, g3 _@_ t)
-
-.... case dMonadST _@_ x0 of (a,b,c) -> ....
-
-we'd really like to inline dMonadST here, but we *don't* want to
-inline if the case expression is just
-
- case x of y { DEFAULT -> ... }
-
-since we can just eliminate this case instead (x is in WHNF). Similar
-applies when x is bound to a lambda expression. Hence
-contIsInteresting looks for case expressions with just a single
-default case.
-
-\begin{code}
-contIsInteresting :: SimplCont -> Bool
-contIsInteresting (Select _ _ alts _ _) = not (just_default alts)
-contIsInteresting (CoerceIt _ cont) = contIsInteresting cont
-contIsInteresting (ApplyTo _ (Type _) _ cont) = contIsInteresting cont
-contIsInteresting (ApplyTo _ _ _ _) = True
-
-contIsInteresting (ArgOf _ _ _) = False
- -- If this call is the arg of a strict function, the context
- -- is a bit interesting. If we inline here, we may get useful
- -- evaluation information to avoid repeated evals: e.g.
- -- x + (y * z)
- -- Here the contIsInteresting makes the '*' keener to inline,
- -- which in turn exposes a constructor which makes the '+' inline.
- -- Assuming that +,* aren't small enough to inline regardless.
- --
- -- HOWEVER, I put this back to False when I discovered that strings
- -- were getting inlined straight back into applications of 'error'
- -- because the latter is strict.
- -- s = "foo"
- -- f = \x -> ...(error s)...
-
-contIsInteresting (InlinePlease _) = True
-contIsInteresting other = False
-
-just_default [(DEFAULT,_,_)] = True -- See notes below for why we look
-just_default alts = False -- for this special case
-\end{code}
-
+import Array ( array, (//) )
-\begin{code}
-pushArgs :: SubstEnv -> [InExpr] -> SimplCont -> SimplCont
-pushArgs se [] cont = cont
-pushArgs se (arg:args) cont = ApplyTo NoDup arg se (pushArgs se args cont)
-
-discardCont :: SimplCont -- A continuation, expecting
- -> SimplCont -- Replace the continuation with a suitable coerce
-discardCont (Stop to_ty) = Stop to_ty
-discardCont cont = CoerceIt to_ty (Stop to_ty)
- where
- to_ty = contResultType cont
-
-contResultType :: SimplCont -> OutType
-contResultType (Stop to_ty) = to_ty
-contResultType (ArgOf _ to_ty _) = to_ty
-contResultType (ApplyTo _ _ _ cont) = contResultType cont
-contResultType (CoerceIt _ cont) = contResultType cont
-contResultType (InlinePlease cont) = contResultType cont
-contResultType (Select _ _ _ _ cont) = contResultType cont
-
-countValArgs :: SimplCont -> Int
-countValArgs (ApplyTo _ (Type ty) se cont) = countValArgs cont
-countValArgs (ApplyTo _ val_arg se cont) = 1 + countValArgs cont
-countValArgs other = 0
-
-countArgs :: SimplCont -> Int
-countArgs (ApplyTo _ arg se cont) = 1 + countArgs cont
-countArgs other = 0
+infixr 0 `thenSmpl`, `thenSmpl_`
\end{code}
-
%************************************************************************
%* *
\subsection{Monad plumbing}
(Command-line switches move around through the explicitly-passed SimplEnv.)
\begin{code}
-type SimplM result -- We thread the unique supply because
- = SimplEnv -- constantly splitting it is rather expensive
- -> UniqSupply
- -> SimplCount
- -> (result, UniqSupply, SimplCount)
-
-data SimplEnv
- = SimplEnv {
- seChkr :: SwitchChecker,
- seCC :: CostCentreStack, -- The enclosing CCS (when profiling)
- seBlackList :: Id -> Bool, -- True => don't inline this Id
- seSubst :: Subst -- The current substitution
- }
- -- The range of the substitution is OutType and OutExpr resp
- --
- -- The substitution is idempotent
- -- It *must* be applied; things in its domain simply aren't
- -- bound in the result.
- --
- -- The substitution usually maps an Id to its clone,
- -- but if the orig defn is a let-binding, and
- -- the RHS of the let simplifies to an atom,
- -- we just add the binding to the substitution and elide the let.
-
- -- The in-scope part of Subst includes *all* in-scope TyVars and Ids
- -- The elements of the set may have better IdInfo than the
- -- occurrences of in-scope Ids, and (more important) they will
- -- have a correctly-substituted type. So we use a lookup in this
- -- set to replace occurrences
+newtype SimplM result
+ = SM { unSM :: DynFlags -- We thread the unique supply because
+ -> UniqSupply -- constantly splitting it is rather expensive
+ -> SimplCount
+ -> (result, UniqSupply, SimplCount)}
\end{code}
\begin{code}
-initSmpl :: SwitchChecker
+initSmpl :: DynFlags
-> UniqSupply -- No init count; set to 0
- -> VarSet -- In scope (usually empty, but useful for nested calls)
- -> (Id -> Bool) -- Black-list function
-> SimplM a
-> (a, SimplCount)
-initSmpl chkr us in_scope black_list m
- = case m (emptySimplEnv chkr in_scope black_list) us zeroSimplCount of
+initSmpl dflags us m
+ = case unSM m dflags us (zeroSimplCount dflags) of
(result, _, count) -> (result, count)
{-# INLINE thenSmpl_ #-}
{-# INLINE returnSmpl #-}
+instance Monad SimplM where
+ (>>) = thenSmpl_
+ (>>=) = thenSmpl
+ return = returnSmpl
+
returnSmpl :: a -> SimplM a
-returnSmpl e env us sc = (e, us, sc)
+returnSmpl e = SM (\ dflags us sc -> (e, us, sc))
thenSmpl :: SimplM a -> (a -> SimplM b) -> SimplM b
thenSmpl_ :: SimplM a -> SimplM b -> SimplM b
-thenSmpl m k env us0 sc0
- = case (m env us0 sc0) of
- (m_result, us1, sc1) -> k m_result env us1 sc1
+thenSmpl m k
+ = SM (\ dflags us0 sc0 ->
+ case (unSM m dflags us0 sc0) of
+ (m_result, us1, sc1) -> unSM (k m_result) dflags us1 sc1 )
-thenSmpl_ m k env us0 sc0
- = case (m env us0 sc0) of
- (_, us1, sc1) -> k env us1 sc1
+thenSmpl_ m k
+ = SM (\dflags us0 sc0 ->
+ case (unSM m dflags us0 sc0) of
+ (_, us1, sc1) -> unSM k dflags us1 sc1)
\end{code}
mapAndUnzipSmpl f xs `thenSmpl` \ (rs1, rs2) ->
returnSmpl (r1:rs1, r2:rs2)
+mapAccumLSmpl :: (acc -> b -> SimplM (acc,c)) -> acc -> [b] -> SimplM (acc, [c])
mapAccumLSmpl f acc [] = returnSmpl (acc, [])
mapAccumLSmpl f acc (x:xs) = f acc x `thenSmpl` \ (acc', x') ->
mapAccumLSmpl f acc' xs `thenSmpl` \ (acc'', xs') ->
%************************************************************************
\begin{code}
-getUniqueSmpl :: SimplM Unique
-getUniqueSmpl env us sc = case splitUniqSupply us of
- (us1, us2) -> (uniqFromSupply us1, us2, sc)
+getUniqSupplySmpl :: SimplM UniqSupply
+getUniqSupplySmpl
+ = SM (\dflags us sc -> case splitUniqSupply us of
+ (us1, us2) -> (us1, us2, sc))
-getUniquesSmpl :: Int -> SimplM [Unique]
-getUniquesSmpl n env us sc = case splitUniqSupply us of
- (us1, us2) -> (uniqsFromSupply n us1, us2, sc)
+getUniqueSmpl :: SimplM Unique
+getUniqueSmpl
+ = SM (\dflags us sc -> case splitUniqSupply us of
+ (us1, us2) -> (uniqFromSupply us1, us2, sc))
+
+getUniquesSmpl :: SimplM [Unique]
+getUniquesSmpl
+ = SM (\dflags us sc -> case splitUniqSupply us of
+ (us1, us2) -> (uniqsFromSupply us1, us2, sc))
+
+getDOptsSmpl :: SimplM DynFlags
+getDOptsSmpl
+ = SM (\dflags us sc -> (dflags, us, sc))
+
+newId :: EncodedFS -> Type -> SimplM Id
+newId fs ty = getUniqueSmpl `thenSmpl` \ uniq ->
+ returnSmpl (mkSysLocal fs uniq ty)
\end{code}
\begin{code}
getSimplCount :: SimplM SimplCount
-getSimplCount env us sc = (sc, us, sc)
+getSimplCount = SM (\dflags us sc -> (sc, us, sc))
tick :: Tick -> SimplM ()
-tick t env us sc = sc' `seq` ((), us, sc')
- where
- sc' = doTick t sc
+tick t
+ = SM (\dflags us sc -> let sc' = doTick t sc
+ in sc' `seq` ((), us, sc'))
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 env us sc = sc' `seq` ((), us, sc')
- where
- sc' = doFreeTick t sc
+freeTick t
+ = SM (\dflags us sc -> let sc' = doFreeTick t sc
+ in sc' `seq` ((), us, sc'))
\end{code}
\begin{code}
verboseSimplStats = opt_PprStyle_Debug -- For now, anyway
--- Defined both with and without debugging
-zeroSimplCount :: SimplCount
+zeroSimplCount :: DynFlags -> SimplCount
isZeroSimplCount :: SimplCount -> Bool
pprSimplCount :: SimplCount -> SDoc
doTick, doFreeTick :: Tick -> SimplCount -> SimplCount
\end{code}
\begin{code}
-#ifndef DEBUG
-----------------------------------------------------------
--- Debugging OFF
-----------------------------------------------------------
-type SimplCount = Int
-
-zeroSimplCount = 0
-
-isZeroSimplCount n = n==0
-
-doTick t n = n+1 -- Very basic when not debugging
-doFreeTick t n = n -- Don't count leaf visits
+data SimplCount = VerySimplZero -- These two are used when
+ | VerySimplNonZero -- we are only interested in
+ -- termination info
-pprSimplCount n = ptext SLIT("Total ticks:") <+> int n
-
-plusSimplCount n m = n+m
-
-#else
-----------------------------------------------------------
--- Debugging ON
-----------------------------------------------------------
-
-data SimplCount = SimplCount {
+ | SimplCount {
ticks :: !Int, -- Total ticks
details :: !TickCounts, -- How many of each type
n_log :: !Int, -- N
type TickCounts = FiniteMap Tick Int
-zeroSimplCount = SimplCount {ticks = 0, details = emptyFM,
- n_log = 0, log1 = [], log2 = []}
+zeroSimplCount dflags
+ -- This is where we decide whether to do
+ -- the VerySimpl version or the full-stats version
+ | dopt Opt_D_dump_simpl_stats dflags
+ = SimplCount {ticks = 0, details = emptyFM,
+ n_log = 0, log1 = [], log2 = []}
+ | otherwise
+ = VerySimplZero
-isZeroSimplCount sc = ticks sc == 0
+isZeroSimplCount VerySimplZero = True
+isZeroSimplCount (SimplCount { ticks = 0 }) = True
+isZeroSimplCount other = False
doFreeTick tick sc@SimplCount { details = dts }
= dts' `seqFM` sc { details = dts' }
where
dts' = dts `addTick` tick
+doFreeTick tick sc = sc
-- Gross hack to persuade GHC 3.03 to do this important seq
seqFM fm x | isEmptyFM fm = x
where
sc1 = sc { ticks = tks+1, details = dts `addTick` tick }
+doTick tick sc = VerySimplNonZero -- The very simple case
+
+
-- Don't use plusFM_C because that's lazy, and we want to
-- be pretty strict here!
addTick :: TickCounts -> Tick -> TickCounts
where
n1 = n+1
+
plusSimplCount sc1@(SimplCount { ticks = tks1, details = dts1 })
sc2@(SimplCount { ticks = tks2, details = dts2 })
= log_base { ticks = tks1 + tks2, details = plusFM_C (+) dts1 dts2 }
| null (log2 sc2) = sc2 { log2 = log1 sc1 }
| otherwise = sc2
+plusSimplCount VerySimplZero VerySimplZero = VerySimplZero
+plusSimplCount sc1 sc2 = VerySimplNonZero
+pprSimplCount VerySimplZero = ptext SLIT("Total ticks: ZERO!")
+pprSimplCount VerySimplNonZero = ptext SLIT("Total ticks: NON-ZERO!")
pprSimplCount (SimplCount { ticks = tks, details = dts, log1 = l1, log2 = l2 })
= vcat [ptext SLIT("Total ticks: ") <+> int tks,
text "",
= nest 4 (vcat [int n <+> pprTickCts tick | (tick,n) <- ticks])
| otherwise
= empty
-#endif
\end{code}
%************************************************************************
| PostInlineUnconditionally Id
| UnfoldingDone Id
- | RuleFired FAST_STRING -- Rule name
+ | RuleFired FastString -- Rule name
- | LetFloatFromLet Id -- Thing floated out
+ | LetFloatFromLet
| EtaExpansion Id -- LHS binder
| EtaReduction Id -- Binder on outer lambda
| BetaReduction Id -- Lambda binder
| CaseOfCase Id -- Bndr on *inner* case
| KnownBranch Id -- Case binder
| CaseMerge Id -- Binder on outer case
+ | AltMerge Id -- Case binder
| CaseElim Id -- Case binder
| CaseIdentity Id -- Case binder
| FillInCaseDefault Id -- Case binder
| BottomFound
- | LeafVisit
| SimplifierDone -- Ticked at each iteration of the simplifier
isRuleFired (RuleFired _) = True
tickToTag (PostInlineUnconditionally _) = 1
tickToTag (UnfoldingDone _) = 2
tickToTag (RuleFired _) = 3
-tickToTag (LetFloatFromLet _) = 4
+tickToTag LetFloatFromLet = 4
tickToTag (EtaExpansion _) = 5
tickToTag (EtaReduction _) = 6
tickToTag (BetaReduction _) = 7
tickToTag (CaseIdentity _) = 12
tickToTag (FillInCaseDefault _) = 13
tickToTag BottomFound = 14
-tickToTag LeafVisit = 15
tickToTag SimplifierDone = 16
+tickToTag (AltMerge _) = 17
tickString :: Tick -> String
tickString (PreInlineUnconditionally _) = "PreInlineUnconditionally"
tickString (PostInlineUnconditionally _)= "PostInlineUnconditionally"
tickString (UnfoldingDone _) = "UnfoldingDone"
tickString (RuleFired _) = "RuleFired"
-tickString (LetFloatFromLet _) = "LetFloatFromLet"
+tickString LetFloatFromLet = "LetFloatFromLet"
tickString (EtaExpansion _) = "EtaExpansion"
tickString (EtaReduction _) = "EtaReduction"
tickString (BetaReduction _) = "BetaReduction"
tickString (CaseOfCase _) = "CaseOfCase"
tickString (KnownBranch _) = "KnownBranch"
tickString (CaseMerge _) = "CaseMerge"
+tickString (AltMerge _) = "AltMerge"
tickString (CaseElim _) = "CaseElim"
tickString (CaseIdentity _) = "CaseIdentity"
tickString (FillInCaseDefault _) = "FillInCaseDefault"
tickString BottomFound = "BottomFound"
tickString SimplifierDone = "SimplifierDone"
-tickString LeafVisit = "LeafVisit"
pprTickCts :: Tick -> SDoc
pprTickCts (PreInlineUnconditionally v) = ppr v
pprTickCts (PostInlineUnconditionally v)= ppr v
pprTickCts (UnfoldingDone v) = ppr v
pprTickCts (RuleFired v) = ppr v
-pprTickCts (LetFloatFromLet v) = ppr v
+pprTickCts LetFloatFromLet = empty
pprTickCts (EtaExpansion v) = ppr v
pprTickCts (EtaReduction v) = ppr v
pprTickCts (BetaReduction v) = ppr v
pprTickCts (CaseOfCase v) = ppr v
pprTickCts (KnownBranch v) = ppr v
pprTickCts (CaseMerge v) = ppr v
+pprTickCts (AltMerge v) = ppr v
pprTickCts (CaseElim v) = ppr v
pprTickCts (CaseIdentity v) = ppr v
pprTickCts (FillInCaseDefault v) = ppr v
cmpEqTick (PostInlineUnconditionally a) (PostInlineUnconditionally b) = a `compare` b
cmpEqTick (UnfoldingDone a) (UnfoldingDone b) = a `compare` b
cmpEqTick (RuleFired a) (RuleFired b) = a `compare` b
-cmpEqTick (LetFloatFromLet a) (LetFloatFromLet b) = a `compare` b
cmpEqTick (EtaExpansion a) (EtaExpansion b) = a `compare` b
cmpEqTick (EtaReduction a) (EtaReduction b) = a `compare` b
cmpEqTick (BetaReduction a) (BetaReduction b) = a `compare` b
cmpEqTick (CaseOfCase a) (CaseOfCase b) = a `compare` b
cmpEqTick (KnownBranch a) (KnownBranch b) = a `compare` b
cmpEqTick (CaseMerge a) (CaseMerge b) = a `compare` b
+cmpEqTick (AltMerge a) (AltMerge b) = a `compare` b
cmpEqTick (CaseElim a) (CaseElim b) = a `compare` b
cmpEqTick (CaseIdentity a) (CaseIdentity b) = a `compare` b
cmpEqTick (FillInCaseDefault a) (FillInCaseDefault b) = a `compare` b
%************************************************************************
\begin{code}
-getSwitchChecker :: SimplM SwitchChecker
-getSwitchChecker env us sc = (seChkr env, us, sc)
+type SwitchChecker = SimplifierSwitch -> SwitchResult
-getSimplIntSwitch :: SwitchChecker -> (Int-> SimplifierSwitch) -> Int
-getSimplIntSwitch chkr switch
- = expectJust "getSimplIntSwitch" (intSwitchSet chkr switch)
+data SwitchResult
+ = SwBool Bool -- on/off
+ | SwString FastString -- nothing or a String
+ | SwInt Int -- nothing or an Int
+
+isAmongSimpl :: [SimplifierSwitch] -> SimplifierSwitch -> SwitchResult
+isAmongSimpl on_switches -- Switches mentioned later occur *earlier*
+ -- in the list; defaults right at the end.
+ = let
+ tidied_on_switches = foldl rm_dups [] on_switches
+ -- The fold*l* ensures that we keep the latest switches;
+ -- ie the ones that occur earliest in the list.
+
+ sw_tbl :: Array Int SwitchResult
+ sw_tbl = (array (0, lAST_SIMPL_SWITCH_TAG) -- bounds...
+ all_undefined)
+ // defined_elems
+
+ all_undefined = [ (i, SwBool False) | i <- [0 .. lAST_SIMPL_SWITCH_TAG ] ]
+
+ defined_elems = map mk_assoc_elem tidied_on_switches
+ in
+ -- (avoid some unboxing, bounds checking, and other horrible things:)
+ case sw_tbl of { Array _ _ stuff ->
+ \ switch ->
+ case (indexArray# stuff (tagOf_SimplSwitch switch)) of
+ (# v #) -> v
+ }
+ where
+ mk_assoc_elem k@(MaxSimplifierIterations lvl)
+ = (iBox (tagOf_SimplSwitch k), SwInt lvl)
+ mk_assoc_elem k
+ = (iBox (tagOf_SimplSwitch k), SwBool True) -- I'm here, Mom!
+
+ -- cannot have duplicates if we are going to use the array thing
+ rm_dups switches_so_far switch
+ = if switch `is_elem` switches_so_far
+ then switches_so_far
+ else switch : switches_so_far
+ where
+ sw `is_elem` [] = False
+ sw `is_elem` (s:ss) = (tagOf_SimplSwitch sw) ==# (tagOf_SimplSwitch s)
+ || sw `is_elem` ss
\end{code}
-
-@switchOffInlining@ is used to prepare the environment for simplifying
-the RHS of an Id that's marked with an INLINE pragma. It is going to
-be inlined wherever they are used, and then all the inlining will take
-effect. Meanwhile, there isn't much point in doing anything to the
-as-yet-un-INLINEd rhs. Furthremore, it's very important to switch off
-inlining! because
- (a) not doing so will inline a worker straight back into its wrapper!
-
-and (b) Consider the following example
- let f = \pq -> BIG
- in
- let g = \y -> f y y
- {-# INLINE g #-}
- in ...g...g...g...g...g...
-
- Now, if that's the ONLY occurrence of f, it will be inlined inside g,
- and thence copied multiple times when g is inlined.
-
- Andy disagrees! Example:
- all xs = foldr (&&) True xs
- any p = all . map p {-# INLINE any #-}
-
- Problem: any won't get deforested, and so if it's exported and
- the importer doesn't use the inlining, (eg passes it as an arg)
- then we won't get deforestation at all.
- We havn't solved this problem yet!
-
-We prepare the envt by simply modifying the in_scope_env, which has all the
-unfolding info. At one point we did it by modifying the chkr so that
-it said "EssentialUnfoldingsOnly", but that prevented legitmate, and
-important, simplifications happening in the body of the RHS.
-
-6/98 update:
-
-We *don't* prevent inlining from happening for identifiers
-that are marked as IMustBeINLINEd. An example of where
-doing this is crucial is:
-
- class Bar a => Foo a where
- ...g....
- {-# INLINE f #-}
- f :: Foo a => a -> b
- f x = ....Foo_sc1...
-
-If `f' needs to peer inside Foo's superclass, Bar, it refers
-to the appropriate super class selector, which is marked as
-must-inlineable. We don't generate any code for a superclass
-selector, so failing to inline it in the RHS of `f' will
-leave a reference to a non-existent id, with bad consequences.
-
-ALSO NOTE that we do all this by modifing the inline-pragma,
-not by zapping the unfolding. The latter may still be useful for
-knowing when something is evaluated.
-
-June 98 update: I've gone back to dealing with this by adding
-the EssentialUnfoldingsOnly switch. That doesn't stop essential
-unfoldings, nor inlineUnconditionally stuff; and the thing's going
-to be inlined at every call site anyway. Running over the whole
-environment seems like wild overkill.
-
\begin{code}
-switchOffInlining :: SimplM a -> SimplM a
-switchOffInlining m env us sc
- = m (env { seBlackList = \v -> True }) us sc
-\end{code}
+getSimplIntSwitch :: SwitchChecker -> (Int-> SimplifierSwitch) -> Int
+getSimplIntSwitch chkr switch
+ = expectJust "getSimplIntSwitch" (intSwitchSet chkr switch)
+switchIsOn :: (switch -> SwitchResult) -> switch -> Bool
-%************************************************************************
-%* *
-\subsubsection{The ``enclosing cost-centre''}
-%* *
-%************************************************************************
+switchIsOn lookup_fn switch
+ = case (lookup_fn switch) of
+ SwBool False -> False
+ _ -> True
-\begin{code}
-getEnclosingCC :: SimplM CostCentreStack
-getEnclosingCC env us sc = (seCC env, us, sc)
+intSwitchSet :: (switch -> SwitchResult)
+ -> (Int -> switch)
+ -> Maybe Int
-setEnclosingCC :: CostCentreStack -> SimplM a -> SimplM a
-setEnclosingCC cc m env us sc = m (env { seCC = cc }) us sc
+intSwitchSet lookup_fn switch
+ = case (lookup_fn (switch (panic "intSwitchSet"))) of
+ SwInt int -> Just int
+ _ -> Nothing
\end{code}
-%************************************************************************
-%* *
-\subsubsection{The @SimplEnv@ type}
-%* *
-%************************************************************************
-
+These things behave just like enumeration types.
\begin{code}
-emptySimplEnv :: SwitchChecker -> InScopeSet -> (Id -> Bool) -> SimplEnv
-
-emptySimplEnv sw_chkr in_scope black_list
- = SimplEnv { seChkr = sw_chkr, seCC = subsumedCCS,
- seBlackList = black_list,
- seSubst = mkSubst in_scope emptySubstEnv }
- -- The top level "enclosing CC" is "SUBSUMED".
-
-getSubst :: SimplM Subst
-getSubst env us sc = (seSubst env, us, sc)
-
-getBlackList :: SimplM (Id -> Bool)
-getBlackList env us sc = (seBlackList env, us, sc)
-
-setSubst :: Subst -> SimplM a -> SimplM a
-setSubst subst m env us sc = m (env {seSubst = subst}) us sc
-
-getSubstEnv :: SimplM SubstEnv
-getSubstEnv env us sc = (substEnv (seSubst env), us, sc)
+instance Eq SimplifierSwitch where
+ a == b = tagOf_SimplSwitch a ==# tagOf_SimplSwitch b
-extendInScope :: CoreBndr -> SimplM a -> SimplM a
-extendInScope v m env@(SimplEnv {seSubst = subst}) us sc
- = m (env {seSubst = Subst.extendInScope subst v}) us sc
+instance Ord SimplifierSwitch where
+ a < b = tagOf_SimplSwitch a <# tagOf_SimplSwitch b
+ a <= b = tagOf_SimplSwitch a <=# tagOf_SimplSwitch b
-extendInScopes :: [CoreBndr] -> SimplM a -> SimplM a
-extendInScopes vs m env@(SimplEnv {seSubst = subst}) us sc
- = m (env {seSubst = Subst.extendInScopes subst vs}) us sc
-getInScope :: SimplM InScopeSet
-getInScope env us sc = (substInScope (seSubst env), us, sc)
+tagOf_SimplSwitch (MaxSimplifierIterations _) = _ILIT(1)
+tagOf_SimplSwitch NoCaseOfCase = _ILIT(2)
-setInScope :: InScopeSet -> SimplM a -> SimplM a
-setInScope in_scope m env@(SimplEnv {seSubst = subst}) us sc
- = m (env {seSubst = Subst.setInScope subst in_scope}) us sc
+-- If you add anything here, be sure to change lAST_SIMPL_SWITCH_TAG, too!
-modifyInScope :: CoreBndr -> SimplM a -> SimplM a
-modifyInScope v m env us sc
-#ifdef DEBUG
- | not (v `isInScope` seSubst env)
- = pprTrace "modifyInScope: not in scope:" (ppr v)
- m env us sc
-#endif
- | otherwise
- = extendInScope v m env us sc
-
-extendSubst :: CoreBndr -> SubstResult -> SimplM a -> SimplM a
-extendSubst var res m env@(SimplEnv {seSubst = subst}) us sc
- = m (env { seSubst = Subst.extendSubst subst var res }) us sc
-
-extendSubstList :: [CoreBndr] -> [SubstResult] -> SimplM a -> SimplM a
-extendSubstList vars ress m env@(SimplEnv {seSubst = subst}) us sc
- = m (env { seSubst = Subst.extendSubstList subst vars ress }) us sc
-
-setSubstEnv :: SubstEnv -> SimplM a -> SimplM a
-setSubstEnv senv m env@(SimplEnv {seSubst = subst}) us sc
- = m (env {seSubst = Subst.setSubstEnv subst senv}) us sc
-
-zapSubstEnv :: SimplM a -> SimplM a
-zapSubstEnv m env@(SimplEnv {seSubst = subst}) us sc
- = m (env {seSubst = Subst.zapSubstEnv subst}) us sc
-
-getSimplBinderStuff :: SimplM (Subst, UniqSupply)
-getSimplBinderStuff (SimplEnv {seSubst = subst}) us sc
- = ((subst, us), us, sc)
-
-setSimplBinderStuff :: (Subst, UniqSupply) -> SimplM a -> SimplM a
-setSimplBinderStuff (subst, us) m env _ sc
- = m (env {seSubst = subst}) us sc
+lAST_SIMPL_SWITCH_TAG = 2
\end{code}
-
-\begin{code}
-newId :: Type -> (Id -> SimplM a) -> SimplM a
- -- Extends the in-scope-env too
-newId ty m env@(SimplEnv {seSubst = subst}) us sc
- = case splitUniqSupply us of
- (us1, us2) -> m v (env {seSubst = Subst.extendInScope subst v}) us2 sc
- where
- v = mkSysLocal SLIT("s") (uniqFromSupply us1) ty
-
-newIds :: [Type] -> ([Id] -> SimplM a) -> SimplM a
-newIds tys m env@(SimplEnv {seSubst = subst}) us sc
- = case splitUniqSupply us of
- (us1, us2) -> m vs (env {seSubst = Subst.extendInScopes subst vs}) us2 sc
- where
- vs = zipWithEqual "newIds" (mkSysLocal SLIT("s"))
- (uniqsFromSupply (length tys) us1) tys
-
-\end{code}