{- (c) The AQUA Project, Glasgow University, 1993-1998 \section[Simplify]{The main module of the simplifier} -} {-# LANGUAGE CPP #-} {-# LANGUAGE TypeFamilies #-} {-# OPTIONS_GHC -Wno-incomplete-record-updates -Wno-incomplete-uni-patterns #-} module GHC.Core.Opt.Simplify ( simplTopBinds, simplExpr, simplRules ) where #include "HsVersions.h" import GHC.Prelude import GHC.Platform import GHC.Driver.Session import GHC.Driver.Ppr import GHC.Driver.Config import GHC.Core.Opt.Simplify.Monad import GHC.Core.Type hiding ( substTy, substTyVar, extendTvSubst, extendCvSubst ) import GHC.Core.Opt.Simplify.Env import GHC.Core.Opt.Simplify.Utils import GHC.Core.Opt.OccurAnal ( occurAnalyseExpr ) import GHC.Types.Literal ( litIsLifted ) --, mkLitInt ) -- temporalily commented out. See #8326 import GHC.Types.SourceText import GHC.Types.Id import GHC.Types.Id.Make ( seqId ) import GHC.Core.Make ( FloatBind, mkImpossibleExpr, castBottomExpr ) import qualified GHC.Core.Make import GHC.Types.Id.Info import GHC.Types.Name ( mkSystemVarName, isExternalName, getOccFS ) import GHC.Core.Coercion hiding ( substCo, substCoVar ) import GHC.Core.Coercion.Opt ( optCoercion ) import GHC.Core.FamInstEnv ( FamInstEnv, topNormaliseType_maybe ) import GHC.Core.DataCon ( DataCon, dataConWorkId, dataConRepStrictness , dataConRepArgTys, isUnboxedTupleDataCon , StrictnessMark (..) ) import GHC.Core.Opt.Monad ( Tick(..), SimplMode(..) ) import GHC.Core import GHC.Builtin.Types.Prim( realWorldStatePrimTy ) import GHC.Builtin.Names( runRWKey ) import GHC.Types.Demand ( StrictSig(..), Demand, dmdTypeDepth, isStrUsedDmd , mkClosedStrictSig, topDmd, seqDmd, isDeadEndDiv ) import GHC.Types.Cpr ( mkCprSig, botCpr ) import GHC.Core.Ppr ( pprCoreExpr ) import GHC.Types.Unique ( hasKey ) import GHC.Core.Unfold import GHC.Core.Unfold.Make import GHC.Core.Utils import GHC.Core.Opt.Arity ( ArityType(..) , pushCoTyArg, pushCoValArg , idArityType, etaExpandAT ) import GHC.Core.SimpleOpt ( exprIsConApp_maybe, joinPointBinding_maybe, joinPointBindings_maybe ) import GHC.Core.FVs ( mkRuleInfo ) import GHC.Core.Rules ( lookupRule, getRules, initRuleOpts ) import GHC.Types.Basic import GHC.Utils.Monad ( mapAccumLM, liftIO ) import GHC.Utils.Logger import GHC.Types.Tickish import GHC.Types.Var ( isTyCoVar ) import GHC.Data.Maybe ( orElse ) import Control.Monad import GHC.Utils.Outputable import GHC.Utils.Panic import GHC.Data.FastString import GHC.Utils.Misc import GHC.Unit.Module ( moduleName, pprModuleName ) import GHC.Core.Multiplicity import GHC.Builtin.PrimOps ( PrimOp (SeqOp) ) {- The guts of the simplifier is in this module, but the driver loop for the simplifier is in GHC.Core.Opt.Pipeline Note [The big picture] ~~~~~~~~~~~~~~~~~~~~~~ The general shape of the simplifier is this: simplExpr :: SimplEnv -> InExpr -> SimplCont -> SimplM (SimplFloats, OutExpr) simplBind :: SimplEnv -> InBind -> SimplM (SimplFloats, SimplEnv) * SimplEnv contains - Simplifier mode (which includes DynFlags for convenience) - Ambient substitution - InScopeSet * SimplFloats contains - Let-floats (which includes ok-for-spec case-floats) - Join floats - InScopeSet (including all the floats) * Expressions simplExpr :: SimplEnv -> InExpr -> SimplCont -> SimplM (SimplFloats, OutExpr) The result of simplifying an /expression/ is (floats, expr) - A bunch of floats (let bindings, join bindings) - A simplified expression. The overall result is effectively (let floats in expr) * Bindings simplBind :: SimplEnv -> InBind -> SimplM (SimplFloats, SimplEnv) The result of simplifying a binding is - A bunch of floats, the last of which is the simplified binding There may be auxiliary bindings too; see prepareRhs - An environment suitable for simplifying the scope of the binding The floats may also be empty, if the binding is inlined unconditionally; in that case the returned SimplEnv will have an augmented substitution. The returned floats and env both have an in-scope set, and they are guaranteed to be the same. Note [Shadowing] ~~~~~~~~~~~~~~~~ The simplifier used to guarantee that the output had no shadowing, but it does not do so any more. (Actually, it never did!) The reason is documented with simplifyArgs. Eta expansion ~~~~~~~~~~~~~~ For eta expansion, we want to catch things like case e of (a,b) -> \x -> case a of (p,q) -> \y -> r If the \x was on the RHS of a let, we'd eta expand to bring the two lambdas together. And in general that's a good thing to do. Perhaps we should eta expand wherever we find a (value) lambda? Then the eta expansion at a let RHS can concentrate solely on the PAP case. Note [In-scope set as a substitution] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ As per Note [Lookups in in-scope set], an in-scope set can act as a substitution. Specifically, it acts as a substitution from variable to variables /with the same unique/. Why do we need this? Well, during the course of the simplifier, we may want to adjust inessential properties of a variable. For instance, when performing a beta-reduction, we change (\x. e) u ==> let x = u in e We typically want to add an unfolding to `x` so that it inlines to (the simplification of) `u`. We do that by adding the unfolding to the binder `x`, which is added to the in-scope set. When simplifying occurrences of `x` (every occurrence!), they are replaced by their “updated” version from the in-scope set, hence inherit the unfolding. This happens in `SimplEnv.substId`. Another example. Consider case x of y { Node a b -> ...y... ; Leaf v -> ...y... } In the Node branch want y's unfolding to be (Node a b); in the Leaf branch we want y's unfolding to be (Leaf v). We achieve this by adding the appropriate unfolding to y, and re-adding it to the in-scope set. See the calls to `addBinderUnfolding` in `Simplify.addAltUnfoldings` and elsewhere. It's quite convenient. This way we don't need to manipulate the substitution all the time: every update to a binder is automatically reflected to its bound occurrences. Note [Bangs in the Simplifier] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Both SimplFloats and SimplEnv do *not* generally benefit from making their fields strict. I don't know if this is because of good use of laziness or unintended side effects like closures capturing more variables after WW has run. But the end result is that we keep these lazy, but force them in some places where we know it's beneficial to the compiler. Similarly environments returned from functions aren't *always* beneficial to force. In some places they would never be demanded so forcing them early increases allocation. In other places they almost always get demanded so it's worthwhile to force them early. Would it be better to through every allocation of e.g. SimplEnv and decide wether or not to make this one strict? Absolutely! Would be a good use of someones time? Absolutely not! I made these strict that showed up during a profiled build or which I noticed while looking at core for one reason or another. The result sadly is that we end up with "random" bangs in the simplifier where we sometimes force e.g. the returned environment from a function and sometimes we don't for the same function. Depending on the context around the call. The treatment is also not very consistent. I only added bangs where I saw it making a difference either in the core or benchmarks. Some patterns where it would be beneficial aren't convered as a consequence as I neither have the time to go through all of the core and some cases are too small to show up in benchmarks. ************************************************************************ * * \subsection{Bindings} * * ************************************************************************ -} simplTopBinds :: SimplEnv -> [InBind] -> SimplM (SimplFloats, SimplEnv) -- See Note [The big picture] simplTopBinds env0 binds0 = do { -- Put all the top-level binders into scope at the start -- so that if a rewrite rule has unexpectedly brought -- anything into scope, then we don't get a complaint about that. -- It's rather as if the top-level binders were imported. -- See note [Glomming] in "GHC.Core.Opt.OccurAnal". -- See Note [Bangs in the Simplifier] ; !env1 <- {-#SCC "simplTopBinds-simplRecBndrs" #-} simplRecBndrs env0 (bindersOfBinds binds0) ; (floats, env2) <- {-#SCC "simplTopBinds-simpl_binds" #-} simpl_binds env1 binds0 ; freeTick SimplifierDone ; return (floats, env2) } where -- We need to track the zapped top-level binders, because -- they should have their fragile IdInfo zapped (notably occurrence info) -- That's why we run down binds and bndrs' simultaneously. -- simpl_binds :: SimplEnv -> [InBind] -> SimplM (SimplFloats, SimplEnv) simpl_binds env [] = return (emptyFloats env, env) simpl_binds env (bind:binds) = do { (float, env1) <- simpl_bind env bind ; (floats, env2) <- simpl_binds env1 binds -- See Note [Bangs in the Simplifier] ; let !floats1 = float `addFloats` floats ; return (floats1, env2) } simpl_bind env (Rec pairs) = simplRecBind env TopLevel Nothing pairs simpl_bind env (NonRec b r) = do { (env', b') <- addBndrRules env b (lookupRecBndr env b) Nothing ; simplRecOrTopPair env' TopLevel NonRecursive Nothing b b' r } {- ************************************************************************ * * Lazy bindings * * ************************************************************************ simplRecBind is used for * recursive bindings only -} simplRecBind :: SimplEnv -> TopLevelFlag -> MaybeJoinCont -> [(InId, InExpr)] -> SimplM (SimplFloats, SimplEnv) simplRecBind env0 top_lvl mb_cont pairs0 = do { (env_with_info, triples) <- mapAccumLM add_rules env0 pairs0 ; (rec_floats, env1) <- go env_with_info triples ; return (mkRecFloats rec_floats, env1) } where add_rules :: SimplEnv -> (InBndr,InExpr) -> SimplM (SimplEnv, (InBndr, OutBndr, InExpr)) -- Add the (substituted) rules to the binder add_rules env (bndr, rhs) = do { (env', bndr') <- addBndrRules env bndr (lookupRecBndr env bndr) mb_cont ; return (env', (bndr, bndr', rhs)) } go env [] = return (emptyFloats env, env) go env ((old_bndr, new_bndr, rhs) : pairs) = do { (float, env1) <- simplRecOrTopPair env top_lvl Recursive mb_cont old_bndr new_bndr rhs ; (floats, env2) <- go env1 pairs ; return (float `addFloats` floats, env2) } {- simplOrTopPair is used for * recursive bindings (whether top level or not) * top-level non-recursive bindings It assumes the binder has already been simplified, but not its IdInfo. -} simplRecOrTopPair :: SimplEnv -> TopLevelFlag -> RecFlag -> MaybeJoinCont -> InId -> OutBndr -> InExpr -- Binder and rhs -> SimplM (SimplFloats, SimplEnv) simplRecOrTopPair env top_lvl is_rec mb_cont old_bndr new_bndr rhs | Just env' <- preInlineUnconditionally env top_lvl old_bndr rhs env = {-#SCC "simplRecOrTopPair-pre-inline-uncond" #-} trace_bind "pre-inline-uncond" $ do { tick (PreInlineUnconditionally old_bndr) ; return ( emptyFloats env, env' ) } | Just cont <- mb_cont = {-#SCC "simplRecOrTopPair-join" #-} ASSERT( isNotTopLevel top_lvl && isJoinId new_bndr ) trace_bind "join" $ simplJoinBind env cont old_bndr new_bndr rhs env | otherwise = {-#SCC "simplRecOrTopPair-normal" #-} trace_bind "normal" $ simplLazyBind env top_lvl is_rec old_bndr new_bndr rhs env where dflags = seDynFlags env logger = seLogger env -- trace_bind emits a trace for each top-level binding, which -- helps to locate the tracing for inlining and rule firing trace_bind what thing_inside | not (dopt Opt_D_verbose_core2core dflags) = thing_inside | otherwise = putTraceMsg logger dflags ("SimplBind " ++ what) (ppr old_bndr) thing_inside -------------------------- simplLazyBind :: SimplEnv -> TopLevelFlag -> RecFlag -> InId -> OutId -- Binder, both pre-and post simpl -- Not a JoinId -- The OutId has IdInfo, except arity, unfolding -- Ids only, no TyVars -> InExpr -> SimplEnv -- The RHS and its environment -> SimplM (SimplFloats, SimplEnv) -- Precondition: not a JoinId -- Precondition: rhs obeys the let/app invariant -- NOT used for JoinIds simplLazyBind env top_lvl is_rec bndr bndr1 rhs rhs_se = ASSERT( isId bndr ) ASSERT2( not (isJoinId bndr), ppr bndr ) -- pprTrace "simplLazyBind" ((ppr bndr <+> ppr bndr1) $$ ppr rhs $$ ppr (seIdSubst rhs_se)) $ do { let !rhs_env = rhs_se `setInScopeFromE` env -- See Note [Bangs in the Simplifier] (tvs, body) = case collectTyAndValBinders rhs of (tvs, [], body) | surely_not_lam body -> (tvs, body) _ -> ([], rhs) surely_not_lam (Lam {}) = False surely_not_lam (Tick t e) | not (tickishFloatable t) = surely_not_lam e -- eta-reduction could float surely_not_lam _ = True -- Do not do the "abstract tyvar" thing if there's -- a lambda inside, because it defeats eta-reduction -- f = /\a. \x. g a x -- should eta-reduce. ; (body_env, tvs') <- {-#SCC "simplBinders" #-} simplBinders rhs_env tvs -- See Note [Floating and type abstraction] in GHC.Core.Opt.Simplify.Utils -- Simplify the RHS ; let rhs_cont = mkRhsStop (substTy body_env (exprType body)) ; (body_floats0, body0) <- {-#SCC "simplExprF" #-} simplExprF body_env body rhs_cont -- Never float join-floats out of a non-join let-binding (which this is) -- So wrap the body in the join-floats right now -- Hence: body_floats1 consists only of let-floats ; let (body_floats1, body1) = wrapJoinFloatsX body_floats0 body0 -- ANF-ise a constructor or PAP rhs -- We get at most one float per argument here ; (let_floats, bndr2, body2) <- {-#SCC "prepareBinding" #-} prepareBinding env top_lvl bndr bndr1 body1 ; let body_floats2 = body_floats1 `addLetFloats` let_floats ; (rhs_floats, rhs') <- if not (doFloatFromRhs top_lvl is_rec False body_floats2 body2) then -- No floating, revert to body1 {-#SCC "simplLazyBind-no-floating" #-} do { rhs' <- mkLam env tvs' (wrapFloats body_floats2 body1) rhs_cont ; return (emptyFloats env, rhs') } else if null tvs then -- Simple floating {-#SCC "simplLazyBind-simple-floating" #-} do { tick LetFloatFromLet ; return (body_floats2, body2) } else -- Do type-abstraction first {-#SCC "simplLazyBind-type-abstraction-first" #-} do { tick LetFloatFromLet ; (poly_binds, body3) <- abstractFloats (seUnfoldingOpts env) top_lvl tvs' body_floats2 body2 ; let floats = foldl' extendFloats (emptyFloats env) poly_binds ; rhs' <- mkLam env tvs' body3 rhs_cont ; return (floats, rhs') } ; (bind_float, env2) <- completeBind (env `setInScopeFromF` rhs_floats) top_lvl Nothing bndr bndr2 rhs' ; return (rhs_floats `addFloats` bind_float, env2) } -------------------------- simplJoinBind :: SimplEnv -> SimplCont -> InId -> OutId -- Binder, both pre-and post simpl -- The OutId has IdInfo, except arity, -- unfolding -> InExpr -> SimplEnv -- The right hand side and its env -> SimplM (SimplFloats, SimplEnv) simplJoinBind env cont old_bndr new_bndr rhs rhs_se = do { let rhs_env = rhs_se `setInScopeFromE` env ; rhs' <- simplJoinRhs rhs_env old_bndr rhs cont ; completeBind env NotTopLevel (Just cont) old_bndr new_bndr rhs' } -------------------------- simplNonRecX :: SimplEnv -> InId -- Old binder; not a JoinId -> OutExpr -- Simplified RHS -> SimplM (SimplFloats, SimplEnv) -- A specialised variant of simplNonRec used when the RHS is already -- simplified, notably in knownCon. It uses case-binding where necessary. -- -- Precondition: rhs satisfies the let/app invariant simplNonRecX env bndr new_rhs | ASSERT2( not (isJoinId bndr), ppr bndr ) isDeadBinder bndr -- Not uncommon; e.g. case (a,b) of c { (p,q) -> p } = return (emptyFloats env, env) -- Here c is dead, and we avoid -- creating the binding c = (a,b) | Coercion co <- new_rhs = return (emptyFloats env, extendCvSubst env bndr co) | otherwise = do { (env', bndr') <- simplBinder env bndr ; completeNonRecX NotTopLevel env' (isStrictId bndr') bndr bndr' new_rhs } -- NotTopLevel: simplNonRecX is only used for NotTopLevel things -- -- isStrictId: use bndr' because in a levity-polymorphic setting -- the InId bndr might have a levity-polymorphic type, which -- which isStrictId doesn't expect -- c.f. Note [Dark corner with levity polymorphism] -------------------------- completeNonRecX :: TopLevelFlag -> SimplEnv -> Bool -> InId -- Old binder; not a JoinId -> OutId -- New binder -> OutExpr -- Simplified RHS -> SimplM (SimplFloats, SimplEnv) -- The new binding is in the floats -- Precondition: rhs satisfies the let/app invariant -- See Note [Core let/app invariant] in GHC.Core completeNonRecX top_lvl env is_strict old_bndr new_bndr new_rhs = ASSERT2( not (isJoinId new_bndr), ppr new_bndr ) do { (prepd_floats, new_bndr, new_rhs) <- prepareBinding env top_lvl old_bndr new_bndr new_rhs ; let floats = emptyFloats env `addLetFloats` prepd_floats ; (rhs_floats, rhs2) <- if doFloatFromRhs NotTopLevel NonRecursive is_strict floats new_rhs then -- Add the floats to the main env do { tick LetFloatFromLet ; return (floats, new_rhs) } else -- Do not float; wrap the floats around the RHS return (emptyFloats env, wrapFloats floats new_rhs) ; (bind_float, env2) <- completeBind (env `setInScopeFromF` rhs_floats) NotTopLevel Nothing old_bndr new_bndr rhs2 ; return (rhs_floats `addFloats` bind_float, env2) } {- ********************************************************************* * * prepareBinding, prepareRhs, makeTrivial * * ************************************************************************ Note [Cast worker/wrappers] ~~~~~~~~~~~~~~~~~~~~~~~~~~~ When we have a binding x = e |> co we want to do something very similar to worker/wrapper: $wx = e x = $wx |> co So now x can be inlined freely. There's a chance that e will be a constructor application or function, or something like that, so moving the coercion to the usage site may well cancel the coercions and lead to further optimisation. Example: data family T a :: * data instance T Int = T Int foo :: Int -> Int -> Int foo m n = ... where t = T m go 0 = 0 go n = case t of { T m -> go (n-m) } -- This case should optimise We call this making a cast worker/wrapper, and it's done by prepareBinding. We need to be careful with inline/noinline pragmas: rec { {-# NOINLINE f #-} f = (...g...) |> co ; g = ...f... } This is legitimate -- it tells GHC to use f as the loop breaker rather than g. Now we do the cast thing, to get something like rec { $wf = ...g... ; f = $wf |> co ; g = ...f... } Where should the NOINLINE pragma go? If we leave it on f we'll get rec { $wf = ...g... ; {-# NOINLINE f #-} f = $wf |> co ; g = ...f... } and that is bad: the whole point is that we want to inline that cast! We want to transfer the pagma to $wf: rec { {-# NOINLINE $wf #-} $wf = ...g... ; f = $wf |> co ; g = ...f... } It's exactly like worker/wrapper for strictness analysis: f is the wrapper and must inline like crazy $wf is the worker and must carry f's original pragma See Note [Worker-wrapper for NOINLINE functions] in GHC.Core.Opt.WorkWrap. See #17673, #18093, #18078. Note [Preserve strictness in cast w/w] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ In the Note [Cast worker/wrappers] transformation, keep the strictness info. Eg f = e `cast` co -- f has strictness SSL When we transform to f' = e -- f' also has strictness SSL f = f' `cast` co -- f still has strictness SSL Its not wrong to drop it on the floor, but better to keep it. Note [Cast w/w: unlifted] ~~~~~~~~~~~~~~~~~~~~~~~~~ BUT don't do cast worker/wrapper if 'e' has an unlifted type. This *can* happen: foo :: Int = (error (# Int,Int #) "urk") `cast` CoUnsafe (# Int,Int #) Int If do the makeTrivial thing to the error call, we'll get foo = case error (# Int,Int #) "urk" of v -> v `cast` ... But 'v' isn't in scope! These strange casts can happen as a result of case-of-case bar = case (case x of { T -> (# 2,3 #); F -> error "urk" }) of (# p,q #) -> p+q NOTE: Nowadays we don't use casts for these error functions; instead, we use (case erorr ... of {}). So I'm not sure this Note makes much sense any more. -} prepareBinding :: SimplEnv -> TopLevelFlag -> InId -> OutId -> OutExpr -> SimplM (LetFloats, OutId, OutExpr) prepareBinding env top_lvl old_bndr bndr rhs | Cast rhs1 co <- rhs -- Try for cast worker/wrapper -- See Note [Cast worker/wrappers] , not (isStableUnfolding (realIdUnfolding old_bndr)) -- Don't make a cast w/w if the thing is going to be inlined anyway , not (exprIsTrivial rhs1) -- Nor if the RHS is trivial; then again it'll be inlined , let ty1 = coercionLKind co , not (isUnliftedType ty1) -- Not if rhs has an unlifted type; see Note [Cast w/w: unlifted] = do { (floats, new_id) <- makeTrivialBinding (getMode env) top_lvl (getOccFS bndr) worker_info rhs1 ty1 ; let bndr' = bndr `setInlinePragma` mkCastWrapperInlinePrag (idInlinePragma bndr) ; return (floats, bndr', Cast (Var new_id) co) } | otherwise = do { (floats, rhs') <- prepareRhs (getMode env) top_lvl (getOccFS bndr) rhs ; return (floats, bndr, rhs') } where info = idInfo bndr worker_info = vanillaIdInfo `setStrictnessInfo` strictnessInfo info `setCprInfo` cprInfo info `setDemandInfo` demandInfo info `setInlinePragInfo` inlinePragInfo info `setArityInfo` arityInfo info -- We do /not/ want to transfer OccInfo, Rules, Unfolding -- Note [Preserve strictness in cast w/w] mkCastWrapperInlinePrag :: InlinePragma -> InlinePragma -- See Note [Cast wrappers] mkCastWrapperInlinePrag (InlinePragma { inl_act = act, inl_rule = rule_info }) = InlinePragma { inl_src = SourceText "{-# INLINE" , inl_inline = NoUserInlinePrag -- See Note [Wrapper NoUserInline] , inl_sat = Nothing -- in GHC.Core.Opt.WorkWrap , inl_act = wrap_act -- See Note [Wrapper activation] , inl_rule = rule_info } -- in GHC.Core.Opt.WorkWrap -- RuleMatchInfo is (and must be) unaffected where -- See Note [Wrapper activation] in GHC.Core.Opt.WorkWrap -- But simpler, because we don't need to disable during InitialPhase wrap_act | isNeverActive act = activateDuringFinal | otherwise = act {- Note [prepareRhs] ~~~~~~~~~~~~~~~~~~~~ prepareRhs takes a putative RHS, checks whether it's a PAP or constructor application and, if so, converts it to ANF, so that the resulting thing can be inlined more easily. Thus x = (f a, g b) becomes t1 = f a t2 = g b x = (t1,t2) We also want to deal well cases like this v = (f e1 `cast` co) e2 Here we want to make e1,e2 trivial and get x1 = e1; x2 = e2; v = (f x1 `cast` co) v2 That's what the 'go' loop in prepareRhs does -} prepareRhs :: SimplMode -> TopLevelFlag -> FastString -- Base for any new variables -> OutExpr -> SimplM (LetFloats, OutExpr) -- Transforms a RHS into a better RHS by ANF'ing args -- for expandable RHSs: constructors and PAPs -- e.g x = Just e -- becomes a = e -- x = Just a -- See Note [prepareRhs] prepareRhs mode top_lvl occ rhs0 = do { (_is_exp, floats, rhs1) <- go 0 rhs0 ; return (floats, rhs1) } where go :: Int -> OutExpr -> SimplM (Bool, LetFloats, OutExpr) go n_val_args (Cast rhs co) = do { (is_exp, floats, rhs') <- go n_val_args rhs ; return (is_exp, floats, Cast rhs' co) } go n_val_args (App fun (Type ty)) = do { (is_exp, floats, rhs') <- go n_val_args fun ; return (is_exp, floats, App rhs' (Type ty)) } go n_val_args (App fun arg) = do { (is_exp, floats1, fun') <- go (n_val_args+1) fun ; case is_exp of False -> return (False, emptyLetFloats, App fun arg) True -> do { (floats2, arg') <- makeTrivial mode top_lvl topDmd occ arg ; return (True, floats1 `addLetFlts` floats2, App fun' arg') } } go n_val_args (Var fun) = return (is_exp, emptyLetFloats, Var fun) where is_exp = isExpandableApp fun n_val_args -- The fun a constructor or PAP -- See Note [CONLIKE pragma] in GHC.Types.Basic -- The definition of is_exp should match that in -- 'GHC.Core.Opt.OccurAnal.occAnalApp' go n_val_args (Tick t rhs) -- We want to be able to float bindings past this -- tick. Non-scoping ticks don't care. | tickishScoped t == NoScope = do { (is_exp, floats, rhs') <- go n_val_args rhs ; return (is_exp, floats, Tick t rhs') } -- On the other hand, for scoping ticks we need to be able to -- copy them on the floats, which in turn is only allowed if -- we can obtain non-counting ticks. | (not (tickishCounts t) || tickishCanSplit t) = do { (is_exp, floats, rhs') <- go n_val_args rhs ; let tickIt (id, expr) = (id, mkTick (mkNoCount t) expr) floats' = mapLetFloats floats tickIt ; return (is_exp, floats', Tick t rhs') } go _ other = return (False, emptyLetFloats, other) makeTrivialArg :: SimplMode -> ArgSpec -> SimplM (LetFloats, ArgSpec) makeTrivialArg mode arg@(ValArg { as_arg = e, as_dmd = dmd }) = do { (floats, e') <- makeTrivial mode NotTopLevel dmd (fsLit "arg") e ; return (floats, arg { as_arg = e' }) } makeTrivialArg _ arg = return (emptyLetFloats, arg) -- CastBy, TyArg makeTrivial :: SimplMode -> TopLevelFlag -> Demand -> FastString -- ^ A "friendly name" to build the new binder from -> OutExpr -- ^ This expression satisfies the let/app invariant -> SimplM (LetFloats, OutExpr) -- Binds the expression to a variable, if it's not trivial, returning the variable -- For the Demand argument, see Note [Keeping demand info in StrictArg Plan A] makeTrivial mode top_lvl dmd occ_fs expr | exprIsTrivial expr -- Already trivial || not (bindingOk top_lvl expr expr_ty) -- Cannot trivialise -- See Note [Cannot trivialise] = return (emptyLetFloats, expr) | Cast expr' co <- expr = do { (floats, triv_expr) <- makeTrivial mode top_lvl dmd occ_fs expr' ; return (floats, Cast triv_expr co) } | otherwise = do { (floats, new_id) <- makeTrivialBinding mode top_lvl occ_fs id_info expr expr_ty ; return (floats, Var new_id) } where id_info = vanillaIdInfo `setDemandInfo` dmd expr_ty = exprType expr makeTrivialBinding :: SimplMode -> TopLevelFlag -> FastString -- ^ a "friendly name" to build the new binder from -> IdInfo -> OutExpr -- ^ This expression satisfies the let/app invariant -> OutType -- Type of the expression -> SimplM (LetFloats, OutId) makeTrivialBinding mode top_lvl occ_fs info expr expr_ty = do { (floats, expr1) <- prepareRhs mode top_lvl occ_fs expr ; uniq <- getUniqueM ; let name = mkSystemVarName uniq occ_fs var = mkLocalIdWithInfo name Many expr_ty info -- Now something very like completeBind, -- but without the postInlineUnconditionally part ; (arity_type, expr2) <- tryEtaExpandRhs mode var expr1 ; unf <- mkLetUnfolding (sm_uf_opts mode) top_lvl InlineRhs var expr2 ; let final_id = addLetBndrInfo var arity_type unf bind = NonRec final_id expr2 ; return ( floats `addLetFlts` unitLetFloat bind, final_id ) } bindingOk :: TopLevelFlag -> CoreExpr -> Type -> Bool -- True iff we can have a binding of this expression at this level -- Precondition: the type is the type of the expression bindingOk top_lvl expr expr_ty | isTopLevel top_lvl = exprIsTopLevelBindable expr expr_ty | otherwise = True {- Note [Cannot trivialise] ~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider: f :: Int -> Addr# foo :: Bar foo = Bar (f 3) Then we can't ANF-ise foo, even though we'd like to, because we can't make a top-level binding for the Addr# (f 3). And if so we don't want to turn it into foo = let x = f 3 in Bar x because we'll just end up inlining x back, and that makes the simplifier loop. Better not to ANF-ise it at all. Literal strings are an exception. foo = Ptr "blob"# We want to turn this into: foo1 = "blob"# foo = Ptr foo1 See Note [Core top-level string literals] in GHC.Core. ************************************************************************ * * Completing a lazy binding * * ************************************************************************ completeBind * deals only with Ids, not TyVars * takes an already-simplified binder and RHS * is used for both recursive and non-recursive bindings * is used for both top-level and non-top-level bindings It does the following: - tries discarding a dead binding - tries PostInlineUnconditionally - add unfolding [this is the only place we add an unfolding] - add arity It does *not* attempt to do let-to-case. Why? Because it is used for - top-level bindings (when let-to-case is impossible) - many situations where the "rhs" is known to be a WHNF (so let-to-case is inappropriate). Nor does it do the atomic-argument thing -} completeBind :: SimplEnv -> TopLevelFlag -- Flag stuck into unfolding -> MaybeJoinCont -- Required only for join point -> InId -- Old binder -> OutId -> OutExpr -- New binder and RHS -> SimplM (SimplFloats, SimplEnv) -- completeBind may choose to do its work -- * by extending the substitution (e.g. let x = y in ...) -- * or by adding to the floats in the envt -- -- Binder /can/ be a JoinId -- Precondition: rhs obeys the let/app invariant completeBind env top_lvl mb_cont old_bndr new_bndr new_rhs | isCoVar old_bndr = case new_rhs of Coercion co -> return (emptyFloats env, extendCvSubst env old_bndr co) _ -> return (mkFloatBind env (NonRec new_bndr new_rhs)) | otherwise = ASSERT( isId new_bndr ) do { let old_info = idInfo old_bndr old_unf = unfoldingInfo old_info occ_info = occInfo old_info -- Do eta-expansion on the RHS of the binding -- See Note [Eta-expanding at let bindings] in GHC.Core.Opt.Simplify.Utils ; (new_arity, final_rhs) <- tryEtaExpandRhs (getMode env) new_bndr new_rhs -- Simplify the unfolding ; new_unfolding <- simplLetUnfolding env top_lvl mb_cont old_bndr final_rhs (idType new_bndr) new_arity old_unf ; let final_bndr = addLetBndrInfo new_bndr new_arity new_unfolding -- See Note [In-scope set as a substitution] ; if postInlineUnconditionally env top_lvl final_bndr occ_info final_rhs then -- Inline and discard the binding do { tick (PostInlineUnconditionally old_bndr) ; return ( emptyFloats env , extendIdSubst env old_bndr $ DoneEx final_rhs (isJoinId_maybe new_bndr)) } -- Use the substitution to make quite, quite sure that the -- substitution will happen, since we are going to discard the binding else -- Keep the binding -- pprTrace "Binding" (ppr final_bndr <+> ppr new_unfolding) $ return (mkFloatBind env (NonRec final_bndr final_rhs)) } addLetBndrInfo :: OutId -> ArityType -> Unfolding -> OutId addLetBndrInfo new_bndr new_arity_type new_unf = new_bndr `setIdInfo` info5 where AT oss div = new_arity_type new_arity = length oss info1 = idInfo new_bndr `setArityInfo` new_arity -- Unfolding info: Note [Setting the new unfolding] info2 = info1 `setUnfoldingInfo` new_unf -- Demand info: Note [Setting the demand info] -- We also have to nuke demand info if for some reason -- eta-expansion *reduces* the arity of the binding to less -- than that of the strictness sig. This can happen: see Note [Arity decrease]. info3 | isEvaldUnfolding new_unf || (case strictnessInfo info2 of StrictSig dmd_ty -> new_arity < dmdTypeDepth dmd_ty) = zapDemandInfo info2 `orElse` info2 | otherwise = info2 -- Bottoming bindings: see Note [Bottoming bindings] info4 | isDeadEndDiv div = info3 `setStrictnessInfo` bot_sig `setCprInfo` bot_cpr | otherwise = info3 bot_sig = mkClosedStrictSig (replicate new_arity topDmd) div bot_cpr = mkCprSig new_arity botCpr -- Zap call arity info. We have used it by now (via -- `tryEtaExpandRhs`), and the simplifier can invalidate this -- information, leading to broken code later (e.g. #13479) info5 = zapCallArityInfo info4 {- Note [Arity decrease] ~~~~~~~~~~~~~~~~~~~~~~~~ Generally speaking the arity of a binding should not decrease. But it *can* legitimately happen because of RULES. Eg f = g @Int where g has arity 2, will have arity 2. But if there's a rewrite rule g @Int --> h where h has arity 1, then f's arity will decrease. Here's a real-life example, which is in the output of Specialise: Rec { $dm {Arity 2} = \d.\x. op d {-# RULES forall d. $dm Int d = $s$dm #-} dInt = MkD .... opInt ... opInt {Arity 1} = $dm dInt $s$dm {Arity 0} = \x. op dInt } Here opInt has arity 1; but when we apply the rule its arity drops to 0. That's why Specialise goes to a little trouble to pin the right arity on specialised functions too. Note [Bottoming bindings] ~~~~~~~~~~~~~~~~~~~~~~~~~ Suppose we have let x = error "urk" in ...(case x of <alts>)... or let f = \x. error (x ++ "urk") in ...(case f "foo" of <alts>)... Then we'd like to drop the dead <alts> immediately. So it's good to propagate the info that x's RHS is bottom to x's IdInfo as rapidly as possible. We use tryEtaExpandRhs on every binding, and it turns out that the arity computation it performs (via GHC.Core.Opt.Arity.findRhsArity) already does a simple bottoming-expression analysis. So all we need to do is propagate that info to the binder's IdInfo. This showed up in #12150; see comment:16. Note [Setting the demand info] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ If the unfolding is a value, the demand info may go pear-shaped, so we nuke it. Example: let x = (a,b) in case x of (p,q) -> h p q x Here x is certainly demanded. But after we've nuked the case, we'll get just let x = (a,b) in h a b x and now x is not demanded (I'm assuming h is lazy) This really happens. Similarly let f = \x -> e in ...f..f... After inlining f at some of its call sites the original binding may (for example) be no longer strictly demanded. The solution here is a bit ad hoc... ************************************************************************ * * \subsection[Simplify-simplExpr]{The main function: simplExpr} * * ************************************************************************ The reason for this OutExprStuff stuff is that we want to float *after* simplifying a RHS, not before. If we do so naively we get quadratic behaviour as things float out. To see why it's important to do it after, consider this (real) example: let t = f x in fst t ==> let t = let a = e1 b = e2 in (a,b) in fst t ==> let a = e1 b = e2 t = (a,b) in a -- Can't inline a this round, cos it appears twice ==> e1 Each of the ==> steps is a round of simplification. We'd save a whole round if we float first. This can cascade. Consider let f = g d in \x -> ...f... ==> let f = let d1 = ..d.. in \y -> e in \x -> ...f... ==> let d1 = ..d.. in \x -> ...(\y ->e)... Only in this second round can the \y be applied, and it might do the same again. -} simplExpr :: SimplEnv -> CoreExpr -> SimplM CoreExpr simplExpr !env (Type ty) -- See Note [Bangs in the Simplifier] = do { ty' <- simplType env ty -- See Note [Avoiding space leaks in OutType] ; return (Type ty') } simplExpr env expr = simplExprC env expr (mkBoringStop expr_out_ty) where expr_out_ty :: OutType expr_out_ty = substTy env (exprType expr) -- NB: Since 'expr' is term-valued, not (Type ty), this call -- to exprType will succeed. exprType fails on (Type ty). simplExprC :: SimplEnv -> InExpr -- A term-valued expression, never (Type ty) -> SimplCont -> SimplM OutExpr -- Simplify an expression, given a continuation simplExprC env expr cont = -- pprTrace "simplExprC" (ppr expr $$ ppr cont {- $$ ppr (seIdSubst env) -} $$ ppr (seLetFloats env) ) $ do { (floats, expr') <- simplExprF env expr cont ; -- pprTrace "simplExprC ret" (ppr expr $$ ppr expr') $ -- pprTrace "simplExprC ret3" (ppr (seInScope env')) $ -- pprTrace "simplExprC ret4" (ppr (seLetFloats env')) $ return (wrapFloats floats expr') } -------------------------------------------------- simplExprF :: SimplEnv -> InExpr -- A term-valued expression, never (Type ty) -> SimplCont -> SimplM (SimplFloats, OutExpr) simplExprF !env e !cont -- See Note [Bangs in the Simplifier] = {- pprTrace "simplExprF" (vcat [ ppr e , text "cont =" <+> ppr cont , text "inscope =" <+> ppr (seInScope env) , text "tvsubst =" <+> ppr (seTvSubst env) , text "idsubst =" <+> ppr (seIdSubst env) , text "cvsubst =" <+> ppr (seCvSubst env) ]) $ -} simplExprF1 env e cont simplExprF1 :: SimplEnv -> InExpr -> SimplCont -> SimplM (SimplFloats, OutExpr) simplExprF1 _ (Type ty) cont = pprPanic "simplExprF: type" (ppr ty <+> text"cont: " <+> ppr cont) -- simplExprF does only with term-valued expressions -- The (Type ty) case is handled separately by simplExpr -- and by the other callers of simplExprF simplExprF1 env (Var v) cont = {-#SCC "simplIdF" #-} simplIdF env v cont simplExprF1 env (Lit lit) cont = {-#SCC "rebuild" #-} rebuild env (Lit lit) cont simplExprF1 env (Tick t expr) cont = {-#SCC "simplTick" #-} simplTick env t expr cont simplExprF1 env (Cast body co) cont = {-#SCC "simplCast" #-} simplCast env body co cont simplExprF1 env (Coercion co) cont = {-#SCC "simplCoercionF" #-} simplCoercionF env co cont simplExprF1 env (App fun arg) cont = {-#SCC "simplExprF1-App" #-} case arg of Type ty -> do { -- The argument type will (almost) certainly be used -- in the output program, so just force it now. -- See Note [Avoiding space leaks in OutType] arg' <- simplType env ty -- But use substTy, not simplType, to avoid forcing -- the hole type; it will likely not be needed. -- See Note [The hole type in ApplyToTy] ; let hole' = substTy env (exprType fun) ; simplExprF env fun $ ApplyToTy { sc_arg_ty = arg' , sc_hole_ty = hole' , sc_cont = cont } } _ -> -- Crucially, sc_hole_ty is a /lazy/ binding. It will -- be forced only if we need to run contHoleType. -- When these are forced, we might get quadratic behavior; -- this quadratic blowup could be avoided by drilling down -- to the function and getting its multiplicities all at once -- (instead of one-at-a-time). But in practice, we have not -- observed the quadratic behavior, so this extra entanglement -- seems not worthwhile. simplExprF env fun $ ApplyToVal { sc_arg = arg, sc_env = env , sc_hole_ty = substTy env (exprType fun) , sc_dup = NoDup, sc_cont = cont } simplExprF1 env expr@(Lam {}) cont = {-#SCC "simplExprF1-Lam" #-} simplLam env zapped_bndrs body cont -- The main issue here is under-saturated lambdas -- (\x1. \x2. e) arg1 -- Here x1 might have "occurs-once" occ-info, because occ-info -- is computed assuming that a group of lambdas is applied -- all at once. If there are too few args, we must zap the -- occ-info, UNLESS the remaining binders are one-shot where (bndrs, body) = collectBinders expr zapped_bndrs = zapLamBndrs n_args bndrs n_args = countArgs cont -- NB: countArgs counts all the args (incl type args) -- and likewise drop counts all binders (incl type lambdas) simplExprF1 env (Case scrut bndr _ alts) cont = {-#SCC "simplExprF1-Case" #-} simplExprF env scrut (Select { sc_dup = NoDup, sc_bndr = bndr , sc_alts = alts , sc_env = env, sc_cont = cont }) simplExprF1 env (Let (Rec pairs) body) cont | Just pairs' <- joinPointBindings_maybe pairs = {-#SCC "simplRecJoinPoin" #-} simplRecJoinPoint env pairs' body cont | otherwise = {-#SCC "simplRecE" #-} simplRecE env pairs body cont simplExprF1 env (Let (NonRec bndr rhs) body) cont | Type ty <- rhs -- First deal with type lets (let a = Type ty in e) = {-#SCC "simplExprF1-NonRecLet-Type" #-} ASSERT( isTyVar bndr ) do { ty' <- simplType env ty ; simplExprF (extendTvSubst env bndr ty') body cont } | Just (bndr', rhs') <- joinPointBinding_maybe bndr rhs = {-#SCC "simplNonRecJoinPoint" #-} simplNonRecJoinPoint env bndr' rhs' body cont | otherwise = {-#SCC "simplNonRecE" #-} simplNonRecE env bndr (rhs, env) ([], body) cont {- Note [Avoiding space leaks in OutType] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Since the simplifier is run for multiple iterations, we need to ensure that any thunks in the output of one simplifier iteration are forced by the evaluation of the next simplifier iteration. Otherwise we may retain multiple copies of the Core program and leak a terrible amount of memory (as in #13426). The simplifier is naturally strict in the entire "Expr part" of the input Core program, because any expression may contain binders, which we must find in order to extend the SimplEnv accordingly. But types do not contain binders and so it is tempting to write things like simplExpr env (Type ty) = return (Type (substTy env ty)) -- Bad! This is Bad because the result includes a thunk (substTy env ty) which retains a reference to the whole simplifier environment; and the next simplifier iteration will not force this thunk either, because the line above is not strict in ty. So instead our strategy is for the simplifier to fully evaluate OutTypes when it emits them into the output Core program, for example simplExpr env (Type ty) = do { ty' <- simplType env ty -- Good ; return (Type ty') } where the only difference from above is that simplType calls seqType on the result of substTy. However, SimplCont can also contain OutTypes and it's not necessarily a good idea to force types on the way in to SimplCont, because they may end up not being used and forcing them could be a lot of wasted work. T5631 is a good example of this. - For ApplyToTy's sc_arg_ty, we force the type on the way in because the type will almost certainly appear as a type argument in the output program. - For the hole types in Stop and ApplyToTy, we force the type when we emit it into the output program, after obtaining it from contResultType. (The hole type in ApplyToTy is only directly used to form the result type in a new Stop continuation.) -} --------------------------------- -- Simplify a join point, adding the context. -- Context goes *inside* the lambdas. IOW, if the join point has arity n, we do: -- \x1 .. xn -> e => \x1 .. xn -> E[e] -- Note that we need the arity of the join point, since e may be a lambda -- (though this is unlikely). See Note [Join points and case-of-case]. simplJoinRhs :: SimplEnv -> InId -> InExpr -> SimplCont -> SimplM OutExpr simplJoinRhs env bndr expr cont | Just arity <- isJoinId_maybe bndr = do { let (join_bndrs, join_body) = collectNBinders arity expr mult = contHoleScaling cont ; (env', join_bndrs') <- simplLamBndrs env (map (scaleVarBy mult) join_bndrs) ; join_body' <- simplExprC env' join_body cont ; return $ mkLams join_bndrs' join_body' } | otherwise = pprPanic "simplJoinRhs" (ppr bndr) --------------------------------- simplType :: SimplEnv -> InType -> SimplM OutType -- Kept monadic just so we can do the seqType -- See Note [Avoiding space leaks in OutType] simplType env ty = -- pprTrace "simplType" (ppr ty $$ ppr (seTvSubst env)) $ seqType new_ty `seq` return new_ty where new_ty = substTy env ty --------------------------------- simplCoercionF :: SimplEnv -> InCoercion -> SimplCont -> SimplM (SimplFloats, OutExpr) simplCoercionF env co cont = do { co' <- simplCoercion env co ; rebuild env (Coercion co') cont } simplCoercion :: SimplEnv -> InCoercion -> SimplM OutCoercion simplCoercion env co = do { opts <- getOptCoercionOpts ; let opt_co = optCoercion opts (getTCvSubst env) co ; seqCo opt_co `seq` return opt_co } ----------------------------------- -- | Push a TickIt context outwards past applications and cases, as -- long as this is a non-scoping tick, to let case and application -- optimisations apply. simplTick :: SimplEnv -> CoreTickish -> InExpr -> SimplCont -> SimplM (SimplFloats, OutExpr) simplTick env tickish expr cont -- A scoped tick turns into a continuation, so that we can spot -- (scc t (\x . e)) in simplLam and eliminate the scc. If we didn't do -- it this way, then it would take two passes of the simplifier to -- reduce ((scc t (\x . e)) e'). -- NB, don't do this with counting ticks, because if the expr is -- bottom, then rebuildCall will discard the continuation. -- XXX: we cannot do this, because the simplifier assumes that -- the context can be pushed into a case with a single branch. e.g. -- scc<f> case expensive of p -> e -- becomes -- case expensive of p -> scc<f> e -- -- So I'm disabling this for now. It just means we will do more -- simplifier iterations that necessary in some cases. -- | tickishScoped tickish && not (tickishCounts tickish) -- = simplExprF env expr (TickIt tickish cont) -- For unscoped or soft-scoped ticks, we are allowed to float in new -- cost, so we simply push the continuation inside the tick. This -- has the effect of moving the tick to the outside of a case or -- application context, allowing the normal case and application -- optimisations to fire. | tickish `tickishScopesLike` SoftScope = do { (floats, expr') <- simplExprF env expr cont ; return (floats, mkTick tickish expr') } -- Push tick inside if the context looks like this will allow us to -- do a case-of-case - see Note [case-of-scc-of-case] | Select {} <- cont, Just expr' <- push_tick_inside = simplExprF env expr' cont -- We don't want to move the tick, but we might still want to allow -- floats to pass through with appropriate wrapping (or not, see -- wrap_floats below) --- | not (tickishCounts tickish) || tickishCanSplit tickish -- = wrap_floats | otherwise = no_floating_past_tick where -- Try to push tick inside a case, see Note [case-of-scc-of-case]. push_tick_inside = case expr0 of Case scrut bndr ty alts -> Just $ Case (tickScrut scrut) bndr ty (map tickAlt alts) _other -> Nothing where (ticks, expr0) = stripTicksTop movable (Tick tickish expr) movable t = not (tickishCounts t) || t `tickishScopesLike` NoScope || tickishCanSplit t tickScrut e = foldr mkTick e ticks -- Alternatives get annotated with all ticks that scope in some way, -- but we don't want to count entries. tickAlt (Alt c bs e) = Alt c bs (foldr mkTick e ts_scope) ts_scope = map mkNoCount $ filter (not . (`tickishScopesLike` NoScope)) ticks no_floating_past_tick = do { let (inc,outc) = splitCont cont ; (floats, expr1) <- simplExprF env expr inc ; let expr2 = wrapFloats floats expr1 tickish' = simplTickish env tickish ; rebuild env (mkTick tickish' expr2) outc } -- Alternative version that wraps outgoing floats with the tick. This -- results in ticks being duplicated, as we don't make any attempt to -- eliminate the tick if we re-inline the binding (because the tick -- semantics allows unrestricted inlining of HNFs), so I'm not doing -- this any more. FloatOut will catch any real opportunities for -- floating. -- -- wrap_floats = -- do { let (inc,outc) = splitCont cont -- ; (env', expr') <- simplExprF (zapFloats env) expr inc -- ; let tickish' = simplTickish env tickish -- ; let wrap_float (b,rhs) = (zapIdStrictness (setIdArity b 0), -- mkTick (mkNoCount tickish') rhs) -- -- when wrapping a float with mkTick, we better zap the Id's -- -- strictness info and arity, because it might be wrong now. -- ; let env'' = addFloats env (mapFloats env' wrap_float) -- ; rebuild env'' expr' (TickIt tickish' outc) -- } simplTickish env tickish | Breakpoint ext n ids <- tickish = Breakpoint ext n (map (getDoneId . substId env) ids) | otherwise = tickish -- Push type application and coercion inside a tick splitCont :: SimplCont -> (SimplCont, SimplCont) splitCont cont@(ApplyToTy { sc_cont = tail }) = (cont { sc_cont = inc }, outc) where (inc,outc) = splitCont tail splitCont (CastIt co c) = (CastIt co inc, outc) where (inc,outc) = splitCont c splitCont other = (mkBoringStop (contHoleType other), other) getDoneId (DoneId id) = id getDoneId (DoneEx e _) = getIdFromTrivialExpr e -- Note [substTickish] in GHC.Core.Subst getDoneId other = pprPanic "getDoneId" (ppr other) -- Note [case-of-scc-of-case] -- It's pretty important to be able to transform case-of-case when -- there's an SCC in the way. For example, the following comes up -- in nofib/real/compress/Encode.hs: -- -- case scctick<code_string.r1> -- case $wcode_string_r13s wild_XC w1_s137 w2_s138 l_aje -- of _ { (# ww1_s13f, ww2_s13g, ww3_s13h #) -> -- (ww1_s13f, ww2_s13g, ww3_s13h) -- } -- of _ { (ww_s12Y, ww1_s12Z, ww2_s130) -> -- tick<code_string.f1> -- (ww_s12Y, -- ww1_s12Z, -- PTTrees.PT -- @ GHC.Types.Char @ GHC.Types.Int wild2_Xj ww2_s130 r_ajf) -- } -- -- We really want this case-of-case to fire, because then the 3-tuple -- will go away (indeed, the CPR optimisation is relying on this -- happening). But the scctick is in the way - we need to push it -- inside to expose the case-of-case. So we perform this -- transformation on the inner case: -- -- scctick c (case e of { p1 -> e1; ...; pn -> en }) -- ==> -- case (scctick c e) of { p1 -> scc c e1; ...; pn -> scc c en } -- -- So we've moved a constant amount of work out of the scc to expose -- the case. We only do this when the continuation is interesting: in -- for now, it has to be another Case (maybe generalise this later). {- ************************************************************************ * * \subsection{The main rebuilder} * * ************************************************************************ -} rebuild :: SimplEnv -> OutExpr -> SimplCont -> SimplM (SimplFloats, OutExpr) -- At this point the substitution in the SimplEnv should be irrelevant; -- only the in-scope set matters rebuild env expr cont = case cont of Stop {} -> return (emptyFloats env, expr) TickIt t cont -> rebuild env (mkTick t expr) cont CastIt co cont -> rebuild env (mkCast expr co) cont -- NB: mkCast implements the (Coercion co |> g) optimisation Select { sc_bndr = bndr, sc_alts = alts, sc_env = se, sc_cont = cont } -> rebuildCase (se `setInScopeFromE` env) expr bndr alts cont StrictArg { sc_fun = fun, sc_cont = cont, sc_fun_ty = fun_ty } -> rebuildCall env (addValArgTo fun expr fun_ty ) cont StrictBind { sc_bndr = b, sc_bndrs = bs, sc_body = body , sc_env = se, sc_cont = cont } -> do { (floats1, env') <- simplNonRecX (se `setInScopeFromE` env) b expr -- expr satisfies let/app since it started life -- in a call to simplNonRecE ; (floats2, expr') <- simplLam env' bs body cont ; return (floats1 `addFloats` floats2, expr') } ApplyToTy { sc_arg_ty = ty, sc_cont = cont} -> rebuild env (App expr (Type ty)) cont ApplyToVal { sc_arg = arg, sc_env = se, sc_dup = dup_flag, sc_cont = cont} -- See Note [Avoid redundant simplification] -> do { (_, _, arg') <- simplArg env dup_flag se arg ; rebuild env (App expr arg') cont } {- ************************************************************************ * * \subsection{Lambdas} * * ************************************************************************ -} {- Note [Optimising reflexivity] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ It's important (for compiler performance) to get rid of reflexivity as soon as it appears. See #11735, #14737, and #15019. In particular, we want to behave well on * e |> co1 |> co2 where the two happen to cancel out entirely. That is quite common; e.g. a newtype wrapping and unwrapping cancel. * (f |> co) @t1 @t2 ... @tn x1 .. xm Here we will use pushCoTyArg and pushCoValArg successively, which build up NthCo stacks. Silly to do that if co is reflexive. However, we don't want to call isReflexiveCo too much, because it uses type equality which is expensive on big types (#14737 comment:7). A good compromise (determined experimentally) seems to be to call isReflexiveCo * when composing casts, and * at the end In investigating this I saw missed opportunities for on-the-fly coercion shrinkage. See #15090. -} simplCast :: SimplEnv -> InExpr -> Coercion -> SimplCont -> SimplM (SimplFloats, OutExpr) simplCast env body co0 cont0 = do { co1 <- {-#SCC "simplCast-simplCoercion" #-} simplCoercion env co0 ; cont1 <- {-#SCC "simplCast-addCoerce" #-} if isReflCo co1 then return cont0 -- See Note [Optimising reflexivity] else addCoerce co1 cont0 ; {-#SCC "simplCast-simplExprF" #-} simplExprF env body cont1 } where -- If the first parameter is MRefl, then simplifying revealed a -- reflexive coercion. Omit. addCoerceM :: MOutCoercion -> SimplCont -> SimplM SimplCont addCoerceM MRefl cont = return cont addCoerceM (MCo co) cont = addCoerce co cont addCoerce :: OutCoercion -> SimplCont -> SimplM SimplCont addCoerce co1 (CastIt co2 cont) -- See Note [Optimising reflexivity] | isReflexiveCo co' = return cont | otherwise = addCoerce co' cont where co' = mkTransCo co1 co2 addCoerce co (ApplyToTy { sc_arg_ty = arg_ty, sc_cont = tail }) | Just (arg_ty', m_co') <- pushCoTyArg co arg_ty = {-#SCC "addCoerce-pushCoTyArg" #-} do { tail' <- addCoerceM m_co' tail ; return (ApplyToTy { sc_arg_ty = arg_ty' , sc_cont = tail' , sc_hole_ty = coercionLKind co }) } -- NB! As the cast goes past, the -- type of the hole changes (#16312) -- (f |> co) e ===> (f (e |> co1)) |> co2 -- where co :: (s1->s2) ~ (t1->t2) -- co1 :: t1 ~ s1 -- co2 :: s2 ~ t2 addCoerce co cont@(ApplyToVal { sc_arg = arg, sc_env = arg_se , sc_dup = dup, sc_cont = tail }) | Just (m_co1, m_co2) <- pushCoValArg co , levity_ok m_co1 = {-#SCC "addCoerce-pushCoValArg" #-} do { tail' <- addCoerceM m_co2 tail ; case m_co1 of { MRefl -> return (cont { sc_cont = tail' , sc_hole_ty = coercionLKind co }) ; -- Avoid simplifying if possible; -- See Note [Avoiding exponential behaviour] MCo co1 -> do { (dup', arg_se', arg') <- simplArg env dup arg_se arg -- When we build the ApplyTo we can't mix the OutCoercion -- 'co' with the InExpr 'arg', so we simplify -- to make it all consistent. It's a bit messy. -- But it isn't a common case. -- Example of use: #995 ; return (ApplyToVal { sc_arg = mkCast arg' co1 , sc_env = arg_se' , sc_dup = dup' , sc_cont = tail' , sc_hole_ty = coercionLKind co }) } } } addCoerce co cont | isReflexiveCo co = return cont -- Having this at the end makes a huge -- difference in T12227, for some reason -- See Note [Optimising reflexivity] | otherwise = return (CastIt co cont) levity_ok :: MCoercionR -> Bool levity_ok MRefl = True levity_ok (MCo co) = not $ isTypeLevPoly $ coercionRKind co -- Without this check, we get a lev-poly arg -- See Note [Levity polymorphism invariants] in GHC.Core -- test: typecheck/should_run/EtaExpandLevPoly simplArg :: SimplEnv -> DupFlag -> StaticEnv -> CoreExpr -> SimplM (DupFlag, StaticEnv, OutExpr) simplArg env dup_flag arg_env arg | isSimplified dup_flag = return (dup_flag, arg_env, arg) | otherwise = do { arg' <- simplExpr (arg_env `setInScopeFromE` env) arg ; return (Simplified, zapSubstEnv arg_env, arg') } {- ************************************************************************ * * \subsection{Lambdas} * * ************************************************************************ -} simplLam :: SimplEnv -> [InId] -> InExpr -> SimplCont -> SimplM (SimplFloats, OutExpr) simplLam env [] body cont = simplExprF env body cont simplLam env (bndr:bndrs) body (ApplyToTy { sc_arg_ty = arg_ty, sc_cont = cont }) = do { tick (BetaReduction bndr) ; simplLam (extendTvSubst env bndr arg_ty) bndrs body cont } simplLam env (bndr:bndrs) body (ApplyToVal { sc_arg = arg, sc_env = arg_se , sc_cont = cont, sc_dup = dup }) | isSimplified dup -- Don't re-simplify if we've simplified it once -- See Note [Avoiding exponential behaviour] = do { tick (BetaReduction bndr) ; (floats1, env') <- simplNonRecX env zapped_bndr arg ; (floats2, expr') <- simplLam env' bndrs body cont ; return (floats1 `addFloats` floats2, expr') } | otherwise = do { tick (BetaReduction bndr) ; simplNonRecE env zapped_bndr (arg, arg_se) (bndrs, body) cont } where zapped_bndr -- See Note [Zap unfolding when beta-reducing] | isId bndr = zapStableUnfolding bndr | otherwise = bndr -- Discard a non-counting tick on a lambda. This may change the -- cost attribution slightly (moving the allocation of the -- lambda elsewhere), but we don't care: optimisation changes -- cost attribution all the time. simplLam env bndrs body (TickIt tickish cont) | not (tickishCounts tickish) = simplLam env bndrs body cont -- Not enough args, so there are real lambdas left to put in the result simplLam env bndrs body cont = do { (env', bndrs') <- simplLamBndrs env bndrs ; body' <- simplExpr env' body ; new_lam <- mkLam env bndrs' body' cont ; rebuild env' new_lam cont } ------------- simplLamBndr :: SimplEnv -> InBndr -> SimplM (SimplEnv, OutBndr) -- Used for lambda binders. These sometimes have unfoldings added by -- the worker/wrapper pass that must be preserved, because they can't -- be reconstructed from context. For example: -- f x = case x of (a,b) -> fw a b x -- fw a b x{=(a,b)} = ... -- The "{=(a,b)}" is an unfolding we can't reconstruct otherwise. simplLamBndr env bndr | isId bndr && hasCoreUnfolding old_unf -- Special case = do { (env1, bndr1) <- simplBinder env bndr ; unf' <- simplStableUnfolding env1 NotTopLevel Nothing bndr (idType bndr1) (idArityType bndr1) old_unf ; let bndr2 = bndr1 `setIdUnfolding` unf' ; return (modifyInScope env1 bndr2, bndr2) } | otherwise = simplBinder env bndr -- Normal case where old_unf = idUnfolding bndr simplLamBndrs :: SimplEnv -> [InBndr] -> SimplM (SimplEnv, [OutBndr]) simplLamBndrs env bndrs = mapAccumLM simplLamBndr env bndrs ------------------ simplNonRecE :: SimplEnv -> InId -- The binder, always an Id -- Never a join point -> (InExpr, SimplEnv) -- Rhs of binding (or arg of lambda) -> ([InBndr], InExpr) -- Body of the let/lambda -- \xs.e -> SimplCont -> SimplM (SimplFloats, OutExpr) -- simplNonRecE is used for -- * non-top-level non-recursive non-join-point lets in expressions -- * beta reduction -- -- simplNonRec env b (rhs, rhs_se) (bs, body) k -- = let env in -- cont< let b = rhs_se(rhs) in \bs.body > -- -- It deals with strict bindings, via the StrictBind continuation, -- which may abort the whole process -- -- Precondition: rhs satisfies the let/app invariant -- Note [Core let/app invariant] in GHC.Core -- -- The "body" of the binding comes as a pair of ([InId],InExpr) -- representing a lambda; so we recurse back to simplLam -- Why? Because of the binder-occ-info-zapping done before -- the call to simplLam in simplExprF (Lam ...) simplNonRecE env bndr (rhs, rhs_se) (bndrs, body) cont | ASSERT( isId bndr && not (isJoinId bndr) ) True , Just env' <- preInlineUnconditionally env NotTopLevel bndr rhs rhs_se = do { tick (PreInlineUnconditionally bndr) ; -- pprTrace "preInlineUncond" (ppr bndr <+> ppr rhs) $ simplLam env' bndrs body cont } | otherwise = do { (env1, bndr1) <- simplNonRecBndr env bndr -- Deal with strict bindings -- See Note [Dark corner with levity polymorphism] ; if isStrictId bndr1 && sm_case_case (getMode env) then simplExprF (rhs_se `setInScopeFromE` env) rhs (StrictBind { sc_bndr = bndr, sc_bndrs = bndrs, sc_body = body , sc_env = env, sc_cont = cont, sc_dup = NoDup }) -- Deal with lazy bindings else do { (env2, bndr2) <- addBndrRules env1 bndr bndr1 Nothing ; (floats1, env3) <- simplLazyBind env2 NotTopLevel NonRecursive bndr bndr2 rhs rhs_se ; (floats2, expr') <- simplLam env3 bndrs body cont ; return (floats1 `addFloats` floats2, expr') } } ------------------ simplRecE :: SimplEnv -> [(InId, InExpr)] -> InExpr -> SimplCont -> SimplM (SimplFloats, OutExpr) -- simplRecE is used for -- * non-top-level recursive lets in expressions simplRecE env pairs body cont = do { let bndrs = map fst pairs ; MASSERT(all (not . isJoinId) bndrs) ; env1 <- simplRecBndrs env bndrs -- NB: bndrs' don't have unfoldings or rules -- We add them as we go down ; (floats1, env2) <- simplRecBind env1 NotTopLevel Nothing pairs ; (floats2, expr') <- simplExprF env2 body cont ; return (floats1 `addFloats` floats2, expr') } {- Note [Dark corner with levity polymorphism] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ In `simplNonRecE`, the call to `isStrictId` will fail if the binder has a levity-polymorphic type, of kind (TYPE r). So we are careful to call `isStrictId` on the OutId, not the InId, in case we have ((\(r::RuntimeRep) \(x::Type r). blah) Lifted arg) That will lead to `simplNonRecE env (x::Type r) arg`, and we can't tell if x is lifted or unlifted from that. We only get such redexes from the compulsory inlining of a wired-in, levity-polymorphic function like `rightSection` (see GHC.Types.Id.Make). Mind you, SimpleOpt should probably have inlined such compulsory inlinings already, but belt and braces does no harm. Plus, it turns out that GHC.Driver.Main.hscCompileCoreExpr calls the Simplifier without first calling SimpleOpt, so anything involving GHCi or TH and operator sections will fall over if we don't take care here. Note [Avoiding exponential behaviour] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ One way in which we can get exponential behaviour is if we simplify a big expression, and the re-simplify it -- and then this happens in a deeply-nested way. So we must be jolly careful about re-simplifying an expression. That is why completeNonRecX does not try preInlineUnconditionally. Example: f BIG, where f has a RULE Then * We simplify BIG before trying the rule; but the rule does not fire * We inline f = \x. x True * So if we did preInlineUnconditionally we'd re-simplify (BIG True) However, if BIG has /not/ already been simplified, we'd /like/ to simplify BIG True; maybe good things happen. That is why * simplLam has - a case for (isSimplified dup), which goes via simplNonRecX, and - a case for the un-simplified case, which goes via simplNonRecE * We go to some efforts to avoid unnecessarily simplifying ApplyToVal, in at least two places - In simplCast/addCoerce, where we check for isReflCo - In rebuildCall we avoid simplifying arguments before we have to (see Note [Trying rewrite rules]) Note [Zap unfolding when beta-reducing] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Lambda-bound variables can have stable unfoldings, such as $j = \x. \b{Unf=Just x}. e See Note [Case binders and join points] below; the unfolding for lets us optimise e better. However when we beta-reduce it we want to revert to using the actual value, otherwise we can end up in the stupid situation of let x = blah in let b{Unf=Just x} = y in ...b... Here it'd be far better to drop the unfolding and use the actual RHS. ************************************************************************ * * Join points * * ********************************************************************* -} {- Note [Rules and unfolding for join points] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Suppose we have simplExpr (join j x = rhs ) cont ( {- RULE j (p:ps) = blah -} ) ( {- StableUnfolding j = blah -} ) (in blah ) Then we will push 'cont' into the rhs of 'j'. But we should *also* push 'cont' into the RHS of * Any RULEs for j, e.g. generated by SpecConstr * Any stable unfolding for j, e.g. the result of an INLINE pragma Simplifying rules and stable-unfoldings happens a bit after simplifying the right-hand side, so we remember whether or not it is a join point, and what 'cont' is, in a value of type MaybeJoinCont #13900 was caused by forgetting to push 'cont' into the RHS of a SpecConstr-generated RULE for a join point. -} type MaybeJoinCont = Maybe SimplCont -- Nothing => Not a join point -- Just k => This is a join binding with continuation k -- See Note [Rules and unfolding for join points] simplNonRecJoinPoint :: SimplEnv -> InId -> InExpr -> InExpr -> SimplCont -> SimplM (SimplFloats, OutExpr) simplNonRecJoinPoint env bndr rhs body cont | ASSERT( isJoinId bndr ) True , Just env' <- preInlineUnconditionally env NotTopLevel bndr rhs env = do { tick (PreInlineUnconditionally bndr) ; simplExprF env' body cont } | otherwise = wrapJoinCont env cont $ \ env cont -> do { -- We push join_cont into the join RHS and the body; -- and wrap wrap_cont around the whole thing ; let mult = contHoleScaling cont res_ty = contResultType cont ; (env1, bndr1) <- simplNonRecJoinBndr env bndr mult res_ty ; (env2, bndr2) <- addBndrRules env1 bndr bndr1 (Just cont) ; (floats1, env3) <- simplJoinBind env2 cont bndr bndr2 rhs env ; (floats2, body') <- simplExprF env3 body cont ; return (floats1 `addFloats` floats2, body') } ------------------ simplRecJoinPoint :: SimplEnv -> [(InId, InExpr)] -> InExpr -> SimplCont -> SimplM (SimplFloats, OutExpr) simplRecJoinPoint env pairs body cont = wrapJoinCont env cont $ \ env cont -> do { let bndrs = map fst pairs mult = contHoleScaling cont res_ty = contResultType cont ; env1 <- simplRecJoinBndrs env bndrs mult res_ty -- NB: bndrs' don't have unfoldings or rules -- We add them as we go down ; (floats1, env2) <- simplRecBind env1 NotTopLevel (Just cont) pairs ; (floats2, body') <- simplExprF env2 body cont ; return (floats1 `addFloats` floats2, body') } -------------------- wrapJoinCont :: SimplEnv -> SimplCont -> (SimplEnv -> SimplCont -> SimplM (SimplFloats, OutExpr)) -> SimplM (SimplFloats, OutExpr) -- Deal with making the continuation duplicable if necessary, -- and with the no-case-of-case situation. wrapJoinCont env cont thing_inside | contIsStop cont -- Common case; no need for fancy footwork = thing_inside env cont | not (sm_case_case (getMode env)) -- See Note [Join points with -fno-case-of-case] = do { (floats1, expr1) <- thing_inside env (mkBoringStop (contHoleType cont)) ; let (floats2, expr2) = wrapJoinFloatsX floats1 expr1 ; (floats3, expr3) <- rebuild (env `setInScopeFromF` floats2) expr2 cont ; return (floats2 `addFloats` floats3, expr3) } | otherwise -- Normal case; see Note [Join points and case-of-case] = do { (floats1, cont') <- mkDupableCont env cont ; (floats2, result) <- thing_inside (env `setInScopeFromF` floats1) cont' ; return (floats1 `addFloats` floats2, result) } -------------------- trimJoinCont :: Id -> Maybe JoinArity -> SimplCont -> SimplCont -- Drop outer context from join point invocation (jump) -- See Note [Join points and case-of-case] trimJoinCont _ Nothing cont = cont -- Not a jump trimJoinCont var (Just arity) cont = trim arity cont where trim 0 cont@(Stop {}) = cont trim 0 cont = mkBoringStop (contResultType cont) trim n cont@(ApplyToVal { sc_cont = k }) = cont { sc_cont = trim (n-1) k } trim n cont@(ApplyToTy { sc_cont = k }) = cont { sc_cont = trim (n-1) k } -- join arity counts types! trim _ cont = pprPanic "completeCall" $ ppr var $$ ppr cont {- Note [Join points and case-of-case] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ When we perform the case-of-case transform (or otherwise push continuations inward), we want to treat join points specially. Since they're always tail-called and we want to maintain this invariant, we can do this (for any evaluation context E): E[join j = e in case ... of A -> jump j 1 B -> jump j 2 C -> f 3] --> join j = E[e] in case ... of A -> jump j 1 B -> jump j 2 C -> E[f 3] As is evident from the example, there are two components to this behavior: 1. When entering the RHS of a join point, copy the context inside. 2. When a join point is invoked, discard the outer context. We need to be very careful here to remain consistent---neither part is optional! We need do make the continuation E duplicable (since we are duplicating it) with mkDupableCont. Note [Join points with -fno-case-of-case] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Supose case-of-case is switched off, and we are simplifying case (join j x = <j-rhs> in case y of A -> j 1 B -> j 2 C -> e) of <outer-alts> Usually, we'd push the outer continuation (case . of <outer-alts>) into both the RHS and the body of the join point j. But since we aren't doing case-of-case we may then end up with this totally bogus result join x = case <j-rhs> of <outer-alts> in case (case y of A -> j 1 B -> j 2 C -> e) of <outer-alts> This would be OK in the language of the paper, but not in GHC: j is no longer a join point. We can only do the "push continuation into the RHS of the join point j" if we also push the continuation right down to the /jumps/ to j, so that it can evaporate there. If we are doing case-of-case, we'll get to join x = case <j-rhs> of <outer-alts> in case y of A -> j 1 B -> j 2 C -> case e of <outer-alts> which is great. Bottom line: if case-of-case is off, we must stop pushing the continuation inwards altogether at any join point. Instead simplify the (join ... in ...) with a Stop continuation, and wrap the original continuation around the outside. Surprisingly tricky! ************************************************************************ * * Variables * * ************************************************************************ -} simplVar :: SimplEnv -> InVar -> SimplM OutExpr -- Look up an InVar in the environment simplVar env var -- Why $! ? See Note [Bangs in the Simplifier] | isTyVar var = return $! Type $! (substTyVar env var) | isCoVar var = return $! Coercion $! (substCoVar env var) | otherwise = case substId env var of ContEx tvs cvs ids e -> let env' = setSubstEnv env tvs cvs ids in simplExpr env' e DoneId var1 -> return (Var var1) DoneEx e _ -> return e simplIdF :: SimplEnv -> InId -> SimplCont -> SimplM (SimplFloats, OutExpr) simplIdF env var cont = case substId env var of ContEx tvs cvs ids e -> let env' = setSubstEnv env tvs cvs ids in simplExprF env' e cont -- Don't trim; haven't already simplified e, -- so the cont is not embodied in e DoneId var1 -> let cont' = trimJoinCont var (isJoinId_maybe var1) cont in completeCall env var1 cont' DoneEx e mb_join -> let env' = zapSubstEnv env cont' = trimJoinCont var mb_join cont in simplExprF env' e cont' -- Note [zapSubstEnv] -- The template is already simplified, so don't re-substitute. -- This is VITAL. Consider -- let x = e in -- let y = \z -> ...x... in -- \ x -> ...y... -- We'll clone the inner \x, adding x->x' in the id_subst -- Then when we inline y, we must *not* replace x by x' in -- the inlined copy!! --------------------------------------------------------- -- Dealing with a call site completeCall :: SimplEnv -> OutId -> SimplCont -> SimplM (SimplFloats, OutExpr) completeCall env var cont | Just expr <- callSiteInline logger dflags case_depth var active_unf lone_variable arg_infos interesting_cont -- Inline the variable's RHS = do { checkedTick (UnfoldingDone var) ; dump_inline expr cont ; let env1 = zapSubstEnv env ; simplExprF env1 expr cont } | otherwise -- Don't inline; instead rebuild the call = do { rule_base <- getSimplRules ; let rules = getRules rule_base var info = mkArgInfo env var rules n_val_args call_cont ; rebuildCall env info cont } where dflags = seDynFlags env case_depth = seCaseDepth env logger = seLogger env (lone_variable, arg_infos, call_cont) = contArgs cont n_val_args = length arg_infos interesting_cont = interestingCallContext env call_cont active_unf = activeUnfolding (getMode env) var log_inlining doc = liftIO $ putDumpMsg logger dflags (mkDumpStyle alwaysQualify) Opt_D_dump_inlinings "" FormatText doc dump_inline unfolding cont | not (dopt Opt_D_dump_inlinings dflags) = return () | not (dopt Opt_D_verbose_core2core dflags) = when (isExternalName (idName var)) $ log_inlining $ sep [text "Inlining done:", nest 4 (ppr var)] | otherwise = log_inlining $ sep [text "Inlining done: " <> ppr var, nest 4 (vcat [text "Inlined fn: " <+> nest 2 (ppr unfolding), text "Cont: " <+> ppr cont])] rebuildCall :: SimplEnv -> ArgInfo -> SimplCont -> SimplM (SimplFloats, OutExpr) -- We decided not to inline, so -- - simplify the arguments -- - try rewrite rules -- - and rebuild ---------- Bottoming applications -------------- rebuildCall env (ArgInfo { ai_fun = fun, ai_args = rev_args, ai_dmds = [] }) cont -- When we run out of strictness args, it means -- that the call is definitely bottom; see GHC.Core.Opt.Simplify.Utils.mkArgInfo -- Then we want to discard the entire strict continuation. E.g. -- * case (error "hello") of { ... } -- * (error "Hello") arg -- * f (error "Hello") where f is strict -- etc -- Then, especially in the first of these cases, we'd like to discard -- the continuation, leaving just the bottoming expression. But the -- type might not be right, so we may have to add a coerce. | not (contIsTrivial cont) -- Only do this if there is a non-trivial -- continuation to discard, else we do it -- again and again! = seqType cont_ty `seq` -- See Note [Avoiding space leaks in OutType] return (emptyFloats env, castBottomExpr res cont_ty) where res = argInfoExpr fun rev_args cont_ty = contResultType cont ---------- Try rewrite RULES -------------- -- See Note [Trying rewrite rules] rebuildCall env info@(ArgInfo { ai_fun = fun, ai_args = rev_args , ai_rules = Just (nr_wanted, rules) }) cont | nr_wanted == 0 || no_more_args , let info' = info { ai_rules = Nothing } = -- We've accumulated a simplified call in <fun,rev_args> -- so try rewrite rules; see Note [RULEs apply to simplified arguments] -- See also Note [Rules for recursive functions] do { mb_match <- tryRules env rules fun (reverse rev_args) cont ; case mb_match of Just (env', rhs, cont') -> simplExprF env' rhs cont' Nothing -> rebuildCall env info' cont } where no_more_args = case cont of ApplyToTy {} -> False ApplyToVal {} -> False _ -> True ---------- Simplify applications and casts -------------- rebuildCall env info (CastIt co cont) = rebuildCall env (addCastTo info co) cont rebuildCall env info (ApplyToTy { sc_arg_ty = arg_ty, sc_hole_ty = hole_ty, sc_cont = cont }) = rebuildCall env (addTyArgTo info arg_ty hole_ty) cont ---------- The runRW# rule. Do this after absorbing all arguments ------ -- See Note [Simplification of runRW#] in GHC.CoreToSTG.Prep. -- -- runRW# :: forall (r :: RuntimeRep) (o :: TYPE r). (State# RealWorld -> o) -> o -- K[ runRW# rr ty body ] --> runRW rr' ty' (\s. K[ body s ]) rebuildCall env (ArgInfo { ai_fun = fun_id, ai_args = rev_args }) (ApplyToVal { sc_arg = arg, sc_env = arg_se , sc_cont = cont, sc_hole_ty = fun_ty }) | fun_id `hasKey` runRWKey , not (contIsStop cont) -- Don't fiddle around if the continuation is boring , [ TyArg {}, TyArg {} ] <- rev_args = do { s <- newId (fsLit "s") Many realWorldStatePrimTy ; let (m,_,_) = splitFunTy fun_ty env' = (arg_se `setInScopeFromE` env) `addNewInScopeIds` [s] ty' = contResultType cont cont' = ApplyToVal { sc_dup = Simplified, sc_arg = Var s , sc_env = env', sc_cont = cont , sc_hole_ty = mkVisFunTy m realWorldStatePrimTy ty' } -- cont' applies to s, then K ; body' <- simplExprC env' arg cont' ; let arg' = Lam s body' rr' = getRuntimeRep ty' call' = mkApps (Var fun_id) [mkTyArg rr', mkTyArg ty', arg'] ; return (emptyFloats env, call') } rebuildCall env fun_info (ApplyToVal { sc_arg = arg, sc_env = arg_se , sc_dup = dup_flag, sc_hole_ty = fun_ty , sc_cont = cont }) -- Argument is already simplified | isSimplified dup_flag -- See Note [Avoid redundant simplification] = rebuildCall env (addValArgTo fun_info arg fun_ty) cont -- Strict arguments | isStrictArgInfo fun_info , sm_case_case (getMode env) = -- pprTrace "Strict Arg" (ppr arg $$ ppr (seIdSubst env) $$ ppr (seInScope env)) $ simplExprF (arg_se `setInScopeFromE` env) arg (StrictArg { sc_fun = fun_info, sc_fun_ty = fun_ty , sc_dup = Simplified , sc_cont = cont }) -- Note [Shadowing] -- Lazy arguments | otherwise -- DO NOT float anything outside, hence simplExprC -- There is no benefit (unlike in a let-binding), and we'd -- have to be very careful about bogus strictness through -- floating a demanded let. = do { arg' <- simplExprC (arg_se `setInScopeFromE` env) arg (mkLazyArgStop arg_ty (lazyArgContext fun_info)) ; rebuildCall env (addValArgTo fun_info arg' fun_ty) cont } where arg_ty = funArgTy fun_ty ---------- No further useful info, revert to generic rebuild ------------ rebuildCall env (ArgInfo { ai_fun = fun, ai_args = rev_args }) cont = rebuild env (argInfoExpr fun rev_args) cont {- Note [Trying rewrite rules] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider an application (f e1 e2 e3) where the e1,e2,e3 are not yet simplified. We want to simplify enough arguments to allow the rules to apply, but it's more efficient to avoid simplifying e2,e3 if e1 alone is sufficient. Example: class ops (+) dNumInt e2 e3 If we rewrite ((+) dNumInt) to plusInt, we can take advantage of the latter's strictness when simplifying e2, e3. Moreover, suppose we have RULE f Int = \x. x True Then given (f Int e1) we rewrite to (\x. x True) e1 without simplifying e1. Now we can inline x into its unique call site, and absorb the True into it all in the same pass. If we simplified e1 first, we couldn't do that; see Note [Avoiding exponential behaviour]. So we try to apply rules if either (a) no_more_args: we've run out of argument that the rules can "see" (b) nr_wanted: none of the rules wants any more arguments Note [RULES apply to simplified arguments] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ It's very desirable to try RULES once the arguments have been simplified, because doing so ensures that rule cascades work in one pass. Consider {-# RULES g (h x) = k x f (k x) = x #-} ...f (g (h x))... Then we want to rewrite (g (h x)) to (k x) and only then try f's rules. If we match f's rules against the un-simplified RHS, it won't match. This makes a particularly big difference when superclass selectors are involved: op ($p1 ($p2 (df d))) We want all this to unravel in one sweep. Note [Avoid redundant simplification] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Because RULES apply to simplified arguments, there's a danger of repeatedly simplifying already-simplified arguments. An important example is that of (>>=) d e1 e2 Here e1, e2 are simplified before the rule is applied, but don't really participate in the rule firing. So we mark them as Simplified to avoid re-simplifying them. Note [Shadowing] ~~~~~~~~~~~~~~~~ This part of the simplifier may break the no-shadowing invariant Consider f (...(\a -> e)...) (case y of (a,b) -> e') where f is strict in its second arg If we simplify the innermost one first we get (...(\a -> e)...) Simplifying the second arg makes us float the case out, so we end up with case y of (a,b) -> f (...(\a -> e)...) e' So the output does not have the no-shadowing invariant. However, there is no danger of getting name-capture, because when the first arg was simplified we used an in-scope set that at least mentioned all the variables free in its static environment, and that is enough. We can't just do innermost first, or we'd end up with a dual problem: case x of (a,b) -> f e (...(\a -> e')...) I spent hours trying to recover the no-shadowing invariant, but I just could not think of an elegant way to do it. The simplifier is already knee-deep in continuations. We have to keep the right in-scope set around; AND we have to get the effect that finding (error "foo") in a strict arg position will discard the entire application and replace it with (error "foo"). Getting all this at once is TOO HARD! ************************************************************************ * * Rewrite rules * * ************************************************************************ -} tryRules :: SimplEnv -> [CoreRule] -> Id -> [ArgSpec] -> SimplCont -> SimplM (Maybe (SimplEnv, CoreExpr, SimplCont)) tryRules env rules fn args call_cont | null rules = return Nothing {- Disabled until we fix #8326 | fn `hasKey` tagToEnumKey -- See Note [Optimising tagToEnum#] , [_type_arg, val_arg] <- args , Select dup bndr ((_,[],rhs1) : rest_alts) se cont <- call_cont , isDeadBinder bndr = do { let enum_to_tag :: CoreAlt -> CoreAlt -- Takes K -> e into tagK# -> e -- where tagK# is the tag of constructor K enum_to_tag (DataAlt con, [], rhs) = ASSERT( isEnumerationTyCon (dataConTyCon con) ) (LitAlt tag, [], rhs) where tag = mkLitInt dflags (toInteger (dataConTag con - fIRST_TAG)) enum_to_tag alt = pprPanic "tryRules: tagToEnum" (ppr alt) new_alts = (DEFAULT, [], rhs1) : map enum_to_tag rest_alts new_bndr = setIdType bndr intPrimTy -- The binder is dead, but should have the right type ; return (Just (val_arg, Select dup new_bndr new_alts se cont)) } -} | Just (rule, rule_rhs) <- lookupRule ropts (getUnfoldingInRuleMatch env) (activeRule (getMode env)) fn (argInfoAppArgs args) rules -- Fire a rule for the function = do { checkedTick (RuleFired (ruleName rule)) ; let cont' = pushSimplifiedArgs zapped_env (drop (ruleArity rule) args) call_cont -- (ruleArity rule) says how -- many args the rule consumed occ_anald_rhs = occurAnalyseExpr rule_rhs -- See Note [Occurrence-analyse after rule firing] ; dump rule rule_rhs ; return (Just (zapped_env, occ_anald_rhs, cont')) } -- The occ_anald_rhs and cont' are all Out things -- hence zapping the environment | otherwise -- No rule fires = do { nodump -- This ensures that an empty file is written ; return Nothing } where ropts = initRuleOpts dflags dflags = seDynFlags env logger = seLogger env zapped_env = zapSubstEnv env -- See Note [zapSubstEnv] printRuleModule rule = parens (maybe (text "BUILTIN") (pprModuleName . moduleName) (ruleModule rule)) dump rule rule_rhs | dopt Opt_D_dump_rule_rewrites dflags = log_rule dflags Opt_D_dump_rule_rewrites "Rule fired" $ vcat [ text "Rule:" <+> ftext (ruleName rule) , text "Module:" <+> printRuleModule rule , text "Before:" <+> hang (ppr fn) 2 (sep (map ppr args)) , text "After: " <+> hang (pprCoreExpr rule_rhs) 2 (sep $ map ppr $ drop (ruleArity rule) args) , text "Cont: " <+> ppr call_cont ] | dopt Opt_D_dump_rule_firings dflags = log_rule dflags Opt_D_dump_rule_firings "Rule fired:" $ ftext (ruleName rule) <+> printRuleModule rule | otherwise = return () nodump | dopt Opt_D_dump_rule_rewrites dflags = liftIO $ touchDumpFile logger dflags Opt_D_dump_rule_rewrites | dopt Opt_D_dump_rule_firings dflags = liftIO $ touchDumpFile logger dflags Opt_D_dump_rule_firings | otherwise = return () log_rule dflags flag hdr details = liftIO $ do let sty = mkDumpStyle alwaysQualify putDumpMsg logger dflags sty flag "" FormatText $ sep [text hdr, nest 4 details] trySeqRules :: SimplEnv -> OutExpr -> InExpr -- Scrutinee and RHS -> SimplCont -> SimplM (Maybe (SimplEnv, CoreExpr, SimplCont)) -- See Note [User-defined RULES for seq] trySeqRules in_env scrut rhs cont = do { rule_base <- getSimplRules ; tryRules in_env (getRules rule_base seqId) seqId out_args rule_cont } where no_cast_scrut = drop_casts scrut scrut_ty = exprType no_cast_scrut seq_id_ty = idType seqId -- forall r a (b::TYPE r). a -> b -> b res1_ty = piResultTy seq_id_ty rhs_rep -- forall a (b::TYPE rhs_rep). a -> b -> b res2_ty = piResultTy res1_ty scrut_ty -- forall (b::TYPE rhs_rep). scrut_ty -> b -> b res3_ty = piResultTy res2_ty rhs_ty -- scrut_ty -> rhs_ty -> rhs_ty res4_ty = funResultTy res3_ty -- rhs_ty -> rhs_ty rhs_ty = substTy in_env (exprType rhs) rhs_rep = getRuntimeRep rhs_ty out_args = [ TyArg { as_arg_ty = rhs_rep , as_hole_ty = seq_id_ty } , TyArg { as_arg_ty = scrut_ty , as_hole_ty = res1_ty } , TyArg { as_arg_ty = rhs_ty , as_hole_ty = res2_ty } , ValArg { as_arg = no_cast_scrut , as_dmd = seqDmd , as_hole_ty = res3_ty } ] rule_cont = ApplyToVal { sc_dup = NoDup, sc_arg = rhs , sc_env = in_env, sc_cont = cont , sc_hole_ty = res4_ty } -- Lazily evaluated, so we don't do most of this drop_casts (Cast e _) = drop_casts e drop_casts e = e {- Note [User-defined RULES for seq] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Given case (scrut |> co) of _ -> rhs look for rules that match the expression seq @t1 @t2 scrut where scrut :: t1 rhs :: t2 If you find a match, rewrite it, and apply to 'rhs'. Notice that we can simply drop casts on the fly here, which makes it more likely that a rule will match. See Note [User-defined RULES for seq] in GHC.Types.Id.Make. Note [Occurrence-analyse after rule firing] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ After firing a rule, we occurrence-analyse the instantiated RHS before simplifying it. Usually this doesn't make much difference, but it can be huge. Here's an example (simplCore/should_compile/T7785) map f (map f (map f xs) = -- Use build/fold form of map, twice map f (build (\cn. foldr (mapFB c f) n (build (\cn. foldr (mapFB c f) n xs)))) = -- Apply fold/build rule map f (build (\cn. (\cn. foldr (mapFB c f) n xs) (mapFB c f) n)) = -- Beta-reduce -- Alas we have no occurrence-analysed, so we don't know -- that c is used exactly once map f (build (\cn. let c1 = mapFB c f in foldr (mapFB c1 f) n xs)) = -- Use mapFB rule: mapFB (mapFB c f) g = mapFB c (f.g) -- We can do this because (mapFB c n) is a PAP and hence expandable map f (build (\cn. let c1 = mapFB c n in foldr (mapFB c (f.f)) n x)) This is not too bad. But now do the same with the outer map, and we get another use of mapFB, and t can interact with /both/ remaining mapFB calls in the above expression. This is stupid because actually that 'c1' binding is dead. The outer map introduces another c2. If there is a deep stack of maps we get lots of dead bindings, and lots of redundant work as we repeatedly simplify the result of firing rules. The easy thing to do is simply to occurrence analyse the result of the rule firing. Note that this occ-anals not only the RHS of the rule, but also the function arguments, which by now are OutExprs. E.g. RULE f (g x) = x+1 Call f (g BIG) --> (\x. x+1) BIG The rule binders are lambda-bound and applied to the OutExpr arguments (here BIG) which lack all internal occurrence info. Is this inefficient? Not really: we are about to walk over the result of the rule firing to simplify it, so occurrence analysis is at most a constant factor. Possible improvement: occ-anal the rules when putting them in the database; and in the simplifier just occ-anal the OutExpr arguments. But that's more complicated and the rule RHS is usually tiny; so I'm just doing the simple thing. Historical note: previously we did occ-anal the rules in Rule.hs, but failed to occ-anal the OutExpr arguments, which led to the nasty performance problem described above. Note [Optimising tagToEnum#] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ If we have an enumeration data type: data Foo = A | B | C Then we want to transform case tagToEnum# x of ==> case x of A -> e1 DEFAULT -> e1 B -> e2 1# -> e2 C -> e3 2# -> e3 thereby getting rid of the tagToEnum# altogether. If there was a DEFAULT alternative we retain it (remember it comes first). If not the case must be exhaustive, and we reflect that in the transformed version by adding a DEFAULT. Otherwise Lint complains that the new case is not exhaustive. See #8317. Note [Rules for recursive functions] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ You might think that we shouldn't apply rules for a loop breaker: doing so might give rise to an infinite loop, because a RULE is rather like an extra equation for the function: RULE: f (g x) y = x+y Eqn: f a y = a-y But it's too drastic to disable rules for loop breakers. Even the foldr/build rule would be disabled, because foldr is recursive, and hence a loop breaker: foldr k z (build g) = g k z So it's up to the programmer: rules can cause divergence ************************************************************************ * * Rebuilding a case expression * * ************************************************************************ Note [Case elimination] ~~~~~~~~~~~~~~~~~~~~~~~ The case-elimination transformation discards redundant case expressions. Start with a simple situation: case x# of ===> let y# = x# in e y# -> e (when x#, y# are of primitive type, of course). We can't (in general) do this for algebraic cases, because we might turn bottom into non-bottom! The code in GHC.Core.Opt.Simplify.Utils.prepareAlts has the effect of generalise this idea to look for a case where we're scrutinising a variable, and we know that only the default case can match. For example: case x of 0# -> ... DEFAULT -> ...(case x of 0# -> ... DEFAULT -> ...) ... Here the inner case is first trimmed to have only one alternative, the DEFAULT, after which it's an instance of the previous case. This really only shows up in eliminating error-checking code. Note that GHC.Core.Opt.Simplify.Utils.mkCase combines identical RHSs. So case e of ===> case e of DEFAULT -> r True -> r False -> r Now again the case may be eliminated by the CaseElim transformation. This includes things like (==# a# b#)::Bool so that we simplify case ==# a# b# of { True -> x; False -> x } to just x This particular example shows up in default methods for comparison operations (e.g. in (>=) for Int.Int32) Note [Case to let transformation] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ If a case over a lifted type has a single alternative, and is being used as a strict 'let' (all isDeadBinder bndrs), we may want to do this transformation: case e of r ===> let r = e in ...r... _ -> ...r... We treat the unlifted and lifted cases separately: * Unlifted case: 'e' satisfies exprOkForSpeculation (ok-for-spec is needed to satisfy the let/app invariant). This turns case a +# b of r -> ...r... into let r = a +# b in ...r... and thence .....(a +# b).... However, if we have case indexArray# a i of r -> ...r... we might like to do the same, and inline the (indexArray# a i). But indexArray# is not okForSpeculation, so we don't build a let in rebuildCase (lest it get floated *out*), so the inlining doesn't happen either. Annoying. * Lifted case: we need to be sure that the expression is already evaluated (exprIsHNF). If it's not already evaluated - we risk losing exceptions, divergence or user-specified thunk-forcing - even if 'e' is guaranteed to converge, we don't want to create a thunk (call by need) instead of evaluating it right away (call by value) However, we can turn the case into a /strict/ let if the 'r' is used strictly in the body. Then we won't lose divergence; and we won't build a thunk because the let is strict. See also Note [Case-to-let for strictly-used binders] NB: absentError satisfies exprIsHNF: see Note [aBSENT_ERROR_ID] in GHC.Core.Make. We want to turn case (absentError "foo") of r -> ...MkT r... into let r = absentError "foo" in ...MkT r... Note [Case-to-let for strictly-used binders] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ If we have this: case <scrut> of r { _ -> ..r.. } where 'r' is used strictly in (..r..), we can safely transform to let r = <scrut> in ...r... This is a Good Thing, because 'r' might be dead (if the body just calls error), or might be used just once (in which case it can be inlined); or we might be able to float the let-binding up or down. E.g. #15631 has an example. Note that this can change the error behaviour. For example, we might transform case x of { _ -> error "bad" } --> error "bad" which is might be puzzling if 'x' currently lambda-bound, but later gets let-bound to (error "good"). Nevertheless, the paper "A semantics for imprecise exceptions" allows this transformation. If you want to fix the evaluation order, use 'pseq'. See #8900 for an example where the loss of this transformation bit us in practice. See also Note [Empty case alternatives] in GHC.Core. Historical notes There have been various earlier versions of this patch: * By Sept 18 the code looked like this: || scrut_is_demanded_var scrut scrut_is_demanded_var :: CoreExpr -> Bool scrut_is_demanded_var (Cast s _) = scrut_is_demanded_var s scrut_is_demanded_var (Var _) = isStrUsedDmd (idDemandInfo case_bndr) scrut_is_demanded_var _ = False This only fired if the scrutinee was a /variable/, which seems an unnecessary restriction. So in #15631 I relaxed it to allow arbitrary scrutinees. Less code, less to explain -- but the change had 0.00% effect on nofib. * Previously, in Jan 13 the code looked like this: || case_bndr_evald_next rhs case_bndr_evald_next :: CoreExpr -> Bool -- See Note [Case binder next] case_bndr_evald_next (Var v) = v == case_bndr case_bndr_evald_next (Cast e _) = case_bndr_evald_next e case_bndr_evald_next (App e _) = case_bndr_evald_next e case_bndr_evald_next (Case e _ _ _) = case_bndr_evald_next e case_bndr_evald_next _ = False This patch was part of fixing #7542. See also Note [Eta reduction of an eval'd function] in GHC.Core.Utils.) Further notes about case elimination ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider: test :: Integer -> IO () test = print Turns out that this compiles to: Print.test = \ eta :: Integer eta1 :: Void# -> case PrelNum.< eta PrelNum.zeroInteger of wild { __DEFAULT -> case hPutStr stdout (PrelNum.jtos eta ($w[] @ Char)) eta1 of wild1 { (# new_s, a4 #) -> PrelIO.lvl23 new_s }} Notice the strange '<' which has no effect at all. This is a funny one. It started like this: f x y = if x < 0 then jtos x else if y==0 then "" else jtos x At a particular call site we have (f v 1). So we inline to get if v < 0 then jtos x else if 1==0 then "" else jtos x Now simplify the 1==0 conditional: if v<0 then jtos v else jtos v Now common-up the two branches of the case: case (v<0) of DEFAULT -> jtos v Why don't we drop the case? Because it's strict in v. It's technically wrong to drop even unnecessary evaluations, and in practice they may be a result of 'seq' so we *definitely* don't want to drop those. I don't really know how to improve this situation. Note [FloatBinds from constructor wrappers] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ If we have FloatBinds coming from the constructor wrapper (as in Note [exprIsConApp_maybe on data constructors with wrappers]), we cannot float past them. We'd need to float the FloatBind together with the simplify floats, unfortunately the simplifier doesn't have case-floats. The simplest thing we can do is to wrap all the floats here. The next iteration of the simplifier will take care of all these cases and lets. Given data T = MkT !Bool, this allows us to simplify case $WMkT b of { MkT x -> f x } to case b of { b' -> f b' }. We could try and be more clever (like maybe wfloats only contain let binders, so we could float them). But the need for the extra complication is not clear. -} --------------------------------------------------------- -- Eliminate the case if possible rebuildCase, reallyRebuildCase :: SimplEnv -> OutExpr -- Scrutinee -> InId -- Case binder -> [InAlt] -- Alternatives (increasing order) -> SimplCont -> SimplM (SimplFloats, OutExpr) -------------------------------------------------- -- 1. Eliminate the case if there's a known constructor -------------------------------------------------- rebuildCase env scrut case_bndr alts cont | Lit lit <- scrut -- No need for same treatment as constructors -- because literals are inlined more vigorously , not (litIsLifted lit) = do { tick (KnownBranch case_bndr) ; case findAlt (LitAlt lit) alts of Nothing -> missingAlt env case_bndr alts cont Just (Alt _ bs rhs) -> simple_rhs env [] scrut bs rhs } | Just (in_scope', wfloats, con, ty_args, other_args) <- exprIsConApp_maybe (getUnfoldingInRuleMatch env) scrut -- Works when the scrutinee is a variable with a known unfolding -- as well as when it's an explicit constructor application , let env0 = setInScopeSet env in_scope' = do { tick (KnownBranch case_bndr) ; let scaled_wfloats = map scale_float wfloats ; case findAlt (DataAlt con) alts of Nothing -> missingAlt env0 case_bndr alts cont Just (Alt DEFAULT bs rhs) -> let con_app = Var (dataConWorkId con) `mkTyApps` ty_args `mkApps` other_args in simple_rhs env0 scaled_wfloats con_app bs rhs Just (Alt _ bs rhs) -> knownCon env0 scrut scaled_wfloats con ty_args other_args case_bndr bs rhs cont } where simple_rhs env wfloats scrut' bs rhs = ASSERT( null bs ) do { (floats1, env') <- simplNonRecX env case_bndr scrut' -- scrut is a constructor application, -- hence satisfies let/app invariant ; (floats2, expr') <- simplExprF env' rhs cont ; case wfloats of [] -> return (floats1 `addFloats` floats2, expr') _ -> return -- See Note [FloatBinds from constructor wrappers] ( emptyFloats env, GHC.Core.Make.wrapFloats wfloats $ wrapFloats (floats1 `addFloats` floats2) expr' )} -- This scales case floats by the multiplicity of the continuation hole (see -- Note [Scaling in case-of-case]). Let floats are _not_ scaled, because -- they are aliases anyway. scale_float (GHC.Core.Make.FloatCase scrut case_bndr con vars) = let scale_id id = scaleVarBy holeScaling id in GHC.Core.Make.FloatCase scrut (scale_id case_bndr) con (map scale_id vars) scale_float f = f holeScaling = contHoleScaling cont `mkMultMul` idMult case_bndr -- We are in the following situation -- case[p] case[q] u of { D x -> C v } of { C x -> w } -- And we are producing case[??] u of { D x -> w[x\v]} -- -- What should the multiplicity `??` be? In order to preserve the usage of -- variables in `u`, it needs to be `pq`. -- -- As an illustration, consider the following -- case[Many] case[1] of { C x -> C x } of { C x -> (x, x) } -- Where C :: A %1 -> T is linear -- If we were to produce a case[1], like the inner case, we would get -- case[1] of { C x -> (x, x) } -- Which is ill-typed with respect to linearity. So it needs to be a -- case[Many]. -------------------------------------------------- -- 2. Eliminate the case if scrutinee is evaluated -------------------------------------------------- rebuildCase env scrut case_bndr alts@[Alt _ bndrs rhs] cont -- See if we can get rid of the case altogether -- See Note [Case elimination] -- mkCase made sure that if all the alternatives are equal, -- then there is now only one (DEFAULT) rhs -- 2a. Dropping the case altogether, if -- a) it binds nothing (so it's really just a 'seq') -- b) evaluating the scrutinee has no side effects | is_plain_seq , exprOkForSideEffects scrut -- The entire case is dead, so we can drop it -- if the scrutinee converges without having imperative -- side effects or raising a Haskell exception -- See Note [PrimOp can_fail and has_side_effects] in GHC.Builtin.PrimOps = simplExprF env rhs cont -- 2b. Turn the case into a let, if -- a) it binds only the case-binder -- b) unlifted case: the scrutinee is ok-for-speculation -- lifted case: the scrutinee is in HNF (or will later be demanded) -- See Note [Case to let transformation] | all_dead_bndrs , doCaseToLet scrut case_bndr = do { tick (CaseElim case_bndr) ; (floats1, env') <- simplNonRecX env case_bndr scrut ; (floats2, expr') <- simplExprF env' rhs cont ; return (floats1 `addFloats` floats2, expr') } -- 2c. Try the seq rules if -- a) it binds only the case binder -- b) a rule for seq applies -- See Note [User-defined RULES for seq] in GHC.Types.Id.Make | is_plain_seq = do { mb_rule <- trySeqRules env scrut rhs cont ; case mb_rule of Just (env', rule_rhs, cont') -> simplExprF env' rule_rhs cont' Nothing -> reallyRebuildCase env scrut case_bndr alts cont } where all_dead_bndrs = all isDeadBinder bndrs -- bndrs are [InId] is_plain_seq = all_dead_bndrs && isDeadBinder case_bndr -- Evaluation *only* for effect rebuildCase env scrut case_bndr alts cont = reallyRebuildCase env scrut case_bndr alts cont doCaseToLet :: OutExpr -- Scrutinee -> InId -- Case binder -> Bool -- The situation is case scrut of b { DEFAULT -> body } -- Can we transform thus? let { b = scrut } in body doCaseToLet scrut case_bndr | isTyCoVar case_bndr -- Respect GHC.Core = isTyCoArg scrut -- Note [Core type and coercion invariant] | isUnliftedType (idType case_bndr) = exprOkForSpeculation scrut | otherwise -- Scrut has a lifted type = exprIsHNF scrut || isStrUsedDmd (idDemandInfo case_bndr) -- See Note [Case-to-let for strictly-used binders] -------------------------------------------------- -- 3. Catch-all case -------------------------------------------------- reallyRebuildCase env scrut case_bndr alts cont | not (sm_case_case (getMode env)) = do { case_expr <- simplAlts env scrut case_bndr alts (mkBoringStop (contHoleType cont)) ; rebuild env case_expr cont } | otherwise = do { (floats, env', cont') <- mkDupableCaseCont env alts cont ; case_expr <- simplAlts env' scrut (scaleIdBy holeScaling case_bndr) (scaleAltsBy holeScaling alts) cont' ; return (floats, case_expr) } where holeScaling = contHoleScaling cont -- Note [Scaling in case-of-case] {- simplCaseBinder checks whether the scrutinee is a variable, v. If so, try to eliminate uses of v in the RHSs in favour of case_bndr; that way, there's a chance that v will now only be used once, and hence inlined. Historical note: we use to do the "case binder swap" in the Simplifier so there were additional complications if the scrutinee was a variable. Now the binder-swap stuff is done in the occurrence analyser; see "GHC.Core.Opt.OccurAnal" Note [Binder swap]. Note [knownCon occ info] ~~~~~~~~~~~~~~~~~~~~~~~~ If the case binder is not dead, then neither are the pattern bound variables: case <any> of x { (a,b) -> case x of { (p,q) -> p } } Here (a,b) both look dead, but come alive after the inner case is eliminated. The point is that we bring into the envt a binding let x = (a,b) after the outer case, and that makes (a,b) alive. At least we do unless the case binder is guaranteed dead. Note [Case alternative occ info] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ When we are simply reconstructing a case (the common case), we always zap the occurrence info on the binders in the alternatives. Even if the case binder is dead, the scrutinee is usually a variable, and *that* can bring the case-alternative binders back to life. See Note [Add unfolding for scrutinee] Note [Improving seq] ~~~~~~~~~~~~~~~~~~~ Consider type family F :: * -> * type instance F Int = Int We'd like to transform case e of (x :: F Int) { DEFAULT -> rhs } ===> case e `cast` co of (x'::Int) I# x# -> let x = x' `cast` sym co in rhs so that 'rhs' can take advantage of the form of x'. Notice that Note [Case of cast] (in OccurAnal) may then apply to the result. We'd also like to eliminate empty types (#13468). So if data Void type instance F Bool = Void then we'd like to transform case (x :: F Bool) of { _ -> error "urk" } ===> case (x |> co) of (x' :: Void) of {} Nota Bene: we used to have a built-in rule for 'seq' that dropped casts, so that case (x |> co) of { _ -> blah } dropped the cast; in order to improve the chances of trySeqRules firing. But that works in the /opposite/ direction to Note [Improving seq] so there's a danger of flip/flopping. Better to make trySeqRules insensitive to the cast, which is now is. The need for [Improving seq] showed up in Roman's experiments. Example: foo :: F Int -> Int -> Int foo t n = t `seq` bar n where bar 0 = 0 bar n = bar (n - case t of TI i -> i) Here we'd like to avoid repeated evaluating t inside the loop, by taking advantage of the `seq`. At one point I did transformation in LiberateCase, but it's more robust here. (Otherwise, there's a danger that we'll simply drop the 'seq' altogether, before LiberateCase gets to see it.) Note [Scaling in case-of-case] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ When two cases commute, if done naively, the multiplicities will be wrong: case (case u of w[1] { (x[1], y[1]) } -> f x y) of w'[Many] { (z[Many], t[Many]) -> z } The multiplicities here, are correct, but if I perform a case of case: case u of w[1] { (x[1], y[1]) -> case f x y of w'[Many] of { (z[Many], t[Many]) -> z } } This is wrong! Using `f x y` inside a `case … of w'[Many]` means that `x` and `y` must have multiplicities `Many` not `1`! The correct solution is to make all the `1`-s be `Many`-s instead: case u of w[Many] { (x[Many], y[Many]) -> case f x y of w'[Many] of { (z[Many], t[Many]) -> z } } In general, when commuting two cases, the rule has to be: case (case … of x[p] {…}) of y[q] { … } ===> case … of x[p*q] { … case … of y[q] { … } } This is materialised, in the simplifier, by the fact that every time we simplify case alternatives with a continuation (the surrounded case (or more!)), we must scale the entire case we are simplifying, by a scaling factor which can be computed in the continuation (with function `contHoleScaling`). -} simplAlts :: SimplEnv -> OutExpr -- Scrutinee -> InId -- Case binder -> [InAlt] -- Non-empty -> SimplCont -> SimplM OutExpr -- Returns the complete simplified case expression simplAlts env0 scrut case_bndr alts cont' = do { traceSmpl "simplAlts" (vcat [ ppr case_bndr , text "cont':" <+> ppr cont' , text "in_scope" <+> ppr (seInScope env0) ]) ; (env1, case_bndr1) <- simplBinder env0 case_bndr ; let case_bndr2 = case_bndr1 `setIdUnfolding` evaldUnfolding env2 = modifyInScope env1 case_bndr2 -- See Note [Case binder evaluated-ness] ; fam_envs <- getFamEnvs ; (alt_env', scrut', case_bndr') <- improveSeq fam_envs env2 scrut case_bndr case_bndr2 alts ; (imposs_deflt_cons, in_alts) <- prepareAlts scrut' case_bndr' alts -- NB: it's possible that the returned in_alts is empty: this is handled -- by the caller (rebuildCase) in the missingAlt function ; alts' <- mapM (simplAlt alt_env' (Just scrut') imposs_deflt_cons case_bndr' cont') in_alts ; -- pprTrace "simplAlts" (ppr case_bndr $$ ppr alts_ty $$ ppr alts_ty' $$ ppr alts $$ ppr cont') $ ; let alts_ty' = contResultType cont' -- See Note [Avoiding space leaks in OutType] ; seqType alts_ty' `seq` mkCase (seDynFlags env0) scrut' case_bndr' alts_ty' alts' } ------------------------------------ improveSeq :: (FamInstEnv, FamInstEnv) -> SimplEnv -> OutExpr -> InId -> OutId -> [InAlt] -> SimplM (SimplEnv, OutExpr, OutId) -- Note [Improving seq] improveSeq fam_envs env scrut case_bndr case_bndr1 [Alt DEFAULT _ _] | Just (co, ty2) <- topNormaliseType_maybe fam_envs (idType case_bndr1) = do { case_bndr2 <- newId (fsLit "nt") Many ty2 ; let rhs = DoneEx (Var case_bndr2 `Cast` mkSymCo co) Nothing env2 = extendIdSubst env case_bndr rhs ; return (env2, scrut `Cast` co, case_bndr2) } improveSeq _ env scrut _ case_bndr1 _ = return (env, scrut, case_bndr1) ------------------------------------ simplAlt :: SimplEnv -> Maybe OutExpr -- The scrutinee -> [AltCon] -- These constructors can't be present when -- matching the DEFAULT alternative -> OutId -- The case binder -> SimplCont -> InAlt -> SimplM OutAlt simplAlt env _ imposs_deflt_cons case_bndr' cont' (Alt DEFAULT bndrs rhs) = ASSERT( null bndrs ) do { let env' = addBinderUnfolding env case_bndr' (mkOtherCon imposs_deflt_cons) -- Record the constructors that the case-binder *can't* be. ; rhs' <- simplExprC env' rhs cont' ; return (Alt DEFAULT [] rhs') } simplAlt env scrut' _ case_bndr' cont' (Alt (LitAlt lit) bndrs rhs) = ASSERT( null bndrs ) do { env' <- addAltUnfoldings env scrut' case_bndr' (Lit lit) ; rhs' <- simplExprC env' rhs cont' ; return (Alt (LitAlt lit) [] rhs') } simplAlt env scrut' _ case_bndr' cont' (Alt (DataAlt con) vs rhs) = do { -- See Note [Adding evaluatedness info to pattern-bound variables] let vs_with_evals = addEvals scrut' con vs ; (env', vs') <- simplLamBndrs env vs_with_evals -- Bind the case-binder to (con args) ; let inst_tys' = tyConAppArgs (idType case_bndr') con_app :: OutExpr con_app = mkConApp2 con inst_tys' vs' ; env'' <- addAltUnfoldings env' scrut' case_bndr' con_app ; rhs' <- simplExprC env'' rhs cont' ; return (Alt (DataAlt con) vs' rhs') } {- Note [Adding evaluatedness info to pattern-bound variables] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ addEvals records the evaluated-ness of the bound variables of a case pattern. This is *important*. Consider data T = T !Int !Int case x of { T a b -> T (a+1) b } We really must record that b is already evaluated so that we don't go and re-evaluate it when constructing the result. See Note [Data-con worker strictness] in GHC.Core.DataCon NB: simplLamBndrs preserves this eval info In addition to handling data constructor fields with !s, addEvals also records the fact that the result of seq# is always in WHNF. See Note [seq# magic] in GHC.Core.Opt.ConstantFold. Example (#15226): case seq# v s of (# s', v' #) -> E we want the compiler to be aware that v' is in WHNF in E. Open problem: we don't record that v itself is in WHNF (and we can't do it here). The right thing is to do some kind of binder-swap; see #15226 for discussion. -} addEvals :: Maybe OutExpr -> DataCon -> [Id] -> [Id] -- See Note [Adding evaluatedness info to pattern-bound variables] addEvals scrut con vs -- Deal with seq# applications | Just scr <- scrut , isUnboxedTupleDataCon con , [s,x] <- vs -- Use stripNArgs rather than collectArgsTicks to avoid building -- a list of arguments only to throw it away immediately. , Just (Var f) <- stripNArgs 4 scr , Just SeqOp <- isPrimOpId_maybe f , let x' = zapIdOccInfoAndSetEvald MarkedStrict x = [s, x'] -- Deal with banged datacon fields addEvals _scrut con vs = go vs the_strs where the_strs = dataConRepStrictness con go [] [] = [] go (v:vs') strs | isTyVar v = v : go vs' strs go (v:vs') (str:strs) = zapIdOccInfoAndSetEvald str v : go vs' strs go _ _ = pprPanic "Simplify.addEvals" (ppr con $$ ppr vs $$ ppr_with_length (map strdisp the_strs) $$ ppr_with_length (dataConRepArgTys con) $$ ppr_with_length (dataConRepStrictness con)) where ppr_with_length list = ppr list <+> parens (text "length =" <+> ppr (length list)) strdisp MarkedStrict = text "MarkedStrict" strdisp NotMarkedStrict = text "NotMarkedStrict" zapIdOccInfoAndSetEvald :: StrictnessMark -> Id -> Id zapIdOccInfoAndSetEvald str v = setCaseBndrEvald str $ -- Add eval'dness info zapIdOccInfo v -- And kill occ info; -- see Note [Case alternative occ info] addAltUnfoldings :: SimplEnv -> Maybe OutExpr -> OutId -> OutExpr -> SimplM SimplEnv addAltUnfoldings env scrut case_bndr con_app = do { let con_app_unf = mk_simple_unf con_app env1 = addBinderUnfolding env case_bndr con_app_unf -- See Note [Add unfolding for scrutinee] env2 | Many <- idMult case_bndr = case scrut of Just (Var v) -> addBinderUnfolding env1 v con_app_unf Just (Cast (Var v) co) -> addBinderUnfolding env1 v $ mk_simple_unf (Cast con_app (mkSymCo co)) _ -> env1 | otherwise = env1 ; traceSmpl "addAltUnf" (vcat [ppr case_bndr <+> ppr scrut, ppr con_app]) ; return env2 } where mk_simple_unf = mkSimpleUnfolding (seUnfoldingOpts env) addBinderUnfolding :: SimplEnv -> Id -> Unfolding -> SimplEnv addBinderUnfolding env bndr unf | debugIsOn, Just tmpl <- maybeUnfoldingTemplate unf = WARN( not (eqType (idType bndr) (exprType tmpl)), ppr bndr $$ ppr (idType bndr) $$ ppr tmpl $$ ppr (exprType tmpl) ) modifyInScope env (bndr `setIdUnfolding` unf) | otherwise = modifyInScope env (bndr `setIdUnfolding` unf) zapBndrOccInfo :: Bool -> Id -> Id -- Consider case e of b { (a,b) -> ... } -- Then if we bind b to (a,b) in "...", and b is not dead, -- then we must zap the deadness info on a,b zapBndrOccInfo keep_occ_info pat_id | keep_occ_info = pat_id | otherwise = zapIdOccInfo pat_id {- Note [Case binder evaluated-ness] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We pin on a (OtherCon []) unfolding to the case-binder of a Case, even though it'll be over-ridden in every case alternative with a more informative unfolding. Why? Because suppose a later, less clever, pass simply replaces all occurrences of the case binder with the binder itself; then Lint may complain about the let/app invariant. Example case e of b { DEFAULT -> let v = reallyUnsafePtrEq# b y in .... ; K -> blah } The let/app invariant requires that y is evaluated in the call to reallyUnsafePtrEq#, which it is. But we still want that to be true if we propagate binders to occurrences. This showed up in #13027. Note [Add unfolding for scrutinee] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ In general it's unlikely that a variable scrutinee will appear in the case alternatives case x of { ...x unlikely to appear... } because the binder-swap in OccurAnal has got rid of all such occurrences See Note [Binder swap] in "GHC.Core.Opt.OccurAnal". BUT it is still VERY IMPORTANT to add a suitable unfolding for a variable scrutinee, in simplAlt. Here's why case x of y (a,b) -> case b of c I# v -> ...(f y)... There is no occurrence of 'b' in the (...(f y)...). But y gets the unfolding (a,b), and *that* mentions b. If f has a RULE RULE f (p, I# q) = ... we want that rule to match, so we must extend the in-scope env with a suitable unfolding for 'y'. It's *essential* for rule matching; but it's also good for case-elimination -- suppose that 'f' was inlined and did multi-level case analysis, then we'd solve it in one simplifier sweep instead of two. Exactly the same issue arises in GHC.Core.Opt.SpecConstr; see Note [Add scrutinee to ValueEnv too] in GHC.Core.Opt.SpecConstr HOWEVER, given case x of y { Just a -> r1; Nothing -> r2 } we do not want to add the unfolding x -> y to 'x', which might seem cool, since 'y' itself has different unfoldings in r1 and r2. Reason: if we did that, we'd have to zap y's deadness info and that is a very useful piece of information. So instead we add the unfolding x -> Just a, and x -> Nothing in the respective RHSs. Since this transformation is tantamount to a binder swap, the same caveat as in Note [Suppressing binder-swaps on linear case] in OccurAnal apply. ************************************************************************ * * \subsection{Known constructor} * * ************************************************************************ We are a bit careful with occurrence info. Here's an example (\x* -> case x of (a*, b) -> f a) (h v, e) where the * means "occurs once". This effectively becomes case (h v, e) of (a*, b) -> f a) and then let a* = h v; b = e in f a and then f (h v) All this should happen in one sweep. -} knownCon :: SimplEnv -> OutExpr -- The scrutinee -> [FloatBind] -> DataCon -> [OutType] -> [OutExpr] -- The scrutinee (in pieces) -> InId -> [InBndr] -> InExpr -- The alternative -> SimplCont -> SimplM (SimplFloats, OutExpr) knownCon env scrut dc_floats dc dc_ty_args dc_args bndr bs rhs cont = do { (floats1, env1) <- bind_args env bs dc_args ; (floats2, env2) <- bind_case_bndr env1 ; (floats3, expr') <- simplExprF env2 rhs cont ; case dc_floats of [] -> return (floats1 `addFloats` floats2 `addFloats` floats3, expr') _ -> return ( emptyFloats env -- See Note [FloatBinds from constructor wrappers] , GHC.Core.Make.wrapFloats dc_floats $ wrapFloats (floats1 `addFloats` floats2 `addFloats` floats3) expr') } where zap_occ = zapBndrOccInfo (isDeadBinder bndr) -- bndr is an InId -- Ugh! bind_args env' [] _ = return (emptyFloats env', env') bind_args env' (b:bs') (Type ty : args) = ASSERT( isTyVar b ) bind_args (extendTvSubst env' b ty) bs' args bind_args env' (b:bs') (Coercion co : args) = ASSERT( isCoVar b ) bind_args (extendCvSubst env' b co) bs' args bind_args env' (b:bs') (arg : args) = ASSERT( isId b ) do { let b' = zap_occ b -- Note that the binder might be "dead", because it doesn't -- occur in the RHS; and simplNonRecX may therefore discard -- it via postInlineUnconditionally. -- Nevertheless we must keep it if the case-binder is alive, -- because it may be used in the con_app. See Note [knownCon occ info] ; (floats1, env2) <- simplNonRecX env' b' arg -- arg satisfies let/app invariant ; (floats2, env3) <- bind_args env2 bs' args ; return (floats1 `addFloats` floats2, env3) } bind_args _ _ _ = pprPanic "bind_args" $ ppr dc $$ ppr bs $$ ppr dc_args $$ text "scrut:" <+> ppr scrut -- It's useful to bind bndr to scrut, rather than to a fresh -- binding x = Con arg1 .. argn -- because very often the scrut is a variable, so we avoid -- creating, and then subsequently eliminating, a let-binding -- BUT, if scrut is a not a variable, we must be careful -- about duplicating the arg redexes; in that case, make -- a new con-app from the args bind_case_bndr env | isDeadBinder bndr = return (emptyFloats env, env) | exprIsTrivial scrut = return (emptyFloats env , extendIdSubst env bndr (DoneEx scrut Nothing)) | otherwise = do { dc_args <- mapM (simplVar env) bs -- dc_ty_args are already OutTypes, -- but bs are InBndrs ; let con_app = Var (dataConWorkId dc) `mkTyApps` dc_ty_args `mkApps` dc_args ; simplNonRecX env bndr con_app } ------------------- missingAlt :: SimplEnv -> Id -> [InAlt] -> SimplCont -> SimplM (SimplFloats, OutExpr) -- This isn't strictly an error, although it is unusual. -- It's possible that the simplifier might "see" that -- an inner case has no accessible alternatives before -- it "sees" that the entire branch of an outer case is -- inaccessible. So we simply put an error case here instead. missingAlt env case_bndr _ cont = WARN( True, text "missingAlt" <+> ppr case_bndr ) -- See Note [Avoiding space leaks in OutType] let cont_ty = contResultType cont in seqType cont_ty `seq` return (emptyFloats env, mkImpossibleExpr cont_ty) {- ************************************************************************ * * \subsection{Duplicating continuations} * * ************************************************************************ Consider let x* = case e of { True -> e1; False -> e2 } in b where x* is a strict binding. Then mkDupableCont will be given the continuation case [] of { True -> e1; False -> e2 } ; let x* = [] in b ; stop and will split it into dupable: case [] of { True -> $j1; False -> $j2 } ; stop join floats: $j1 = e1, $j2 = e2 non_dupable: let x* = [] in b; stop Putting this back together would give let x* = let { $j1 = e1; $j2 = e2 } in case e of { True -> $j1; False -> $j2 } in b (Of course we only do this if 'e' wants to duplicate that continuation.) Note how important it is that the new join points wrap around the inner expression, and not around the whole thing. In contrast, any let-bindings introduced by mkDupableCont can wrap around the entire thing. Note [Bottom alternatives] ~~~~~~~~~~~~~~~~~~~~~~~~~~ When we have case (case x of { A -> error .. ; B -> e; C -> error ..) of alts then we can just duplicate those alts because the A and C cases will disappear immediately. This is more direct than creating join points and inlining them away. See #4930. -} -------------------- mkDupableCaseCont :: SimplEnv -> [InAlt] -> SimplCont -> SimplM ( SimplFloats -- Join points (if any) , SimplEnv -- Use this for the alts , SimplCont) mkDupableCaseCont env alts cont | altsWouldDup alts = do { (floats, cont) <- mkDupableCont env cont ; let env' = bumpCaseDepth $ env `setInScopeFromF` floats ; return (floats, env', cont) } | otherwise = return (emptyFloats env, env, cont) altsWouldDup :: [InAlt] -> Bool -- True iff strictly > 1 non-bottom alternative altsWouldDup [] = False -- See Note [Bottom alternatives] altsWouldDup [_] = False altsWouldDup (alt:alts) | is_bot_alt alt = altsWouldDup alts | otherwise = not (all is_bot_alt alts) -- otherwise case: first alt is non-bot, so all the rest must be bot where is_bot_alt (Alt _ _ rhs) = exprIsDeadEnd rhs ------------------------- mkDupableCont :: SimplEnv -> SimplCont -> SimplM ( SimplFloats -- Incoming SimplEnv augmented with -- extra let/join-floats and in-scope variables , SimplCont) -- dup_cont: duplicable continuation mkDupableCont env cont = mkDupableContWithDmds env (repeat topDmd) cont mkDupableContWithDmds :: SimplEnv -> [Demand] -- Demands on arguments; always infinite -> SimplCont -> SimplM ( SimplFloats, SimplCont) mkDupableContWithDmds env _ cont | contIsDupable cont = return (emptyFloats env, cont) mkDupableContWithDmds _ _ (Stop {}) = panic "mkDupableCont" -- Handled by previous eqn mkDupableContWithDmds env dmds (CastIt ty cont) = do { (floats, cont') <- mkDupableContWithDmds env dmds cont ; return (floats, CastIt ty cont') } -- Duplicating ticks for now, not sure if this is good or not mkDupableContWithDmds env dmds (TickIt t cont) = do { (floats, cont') <- mkDupableContWithDmds env dmds cont ; return (floats, TickIt t cont') } mkDupableContWithDmds env _ (StrictBind { sc_bndr = bndr, sc_bndrs = bndrs , sc_body = body, sc_env = se, sc_cont = cont}) -- See Note [Duplicating StrictBind] -- K[ let x = <> in b ] --> join j x = K[ b ] -- j <> = do { let sb_env = se `setInScopeFromE` env ; (sb_env1, bndr') <- simplBinder sb_env bndr ; (floats1, join_inner) <- simplLam sb_env1 bndrs body cont -- No need to use mkDupableCont before simplLam; we -- use cont once here, and then share the result if necessary ; let join_body = wrapFloats floats1 join_inner res_ty = contResultType cont ; mkDupableStrictBind env bndr' join_body res_ty } mkDupableContWithDmds env _ (StrictArg { sc_fun = fun, sc_cont = cont , sc_fun_ty = fun_ty }) -- NB: sc_dup /= OkToDup; that is caught earlier by contIsDupable | thumbsUpPlanA cont = -- Use Plan A of Note [Duplicating StrictArg] do { let (_ : dmds) = ai_dmds fun ; (floats1, cont') <- mkDupableContWithDmds env dmds cont -- Use the demands from the function to add the right -- demand info on any bindings we make for further args ; (floats_s, args') <- mapAndUnzipM (makeTrivialArg (getMode env)) (ai_args fun) ; return ( foldl' addLetFloats floats1 floats_s , StrictArg { sc_fun = fun { ai_args = args' } , sc_cont = cont' , sc_fun_ty = fun_ty , sc_dup = OkToDup} ) } | otherwise = -- Use Plan B of Note [Duplicating StrictArg] -- K[ f a b <> ] --> join j x = K[ f a b x ] -- j <> do { let rhs_ty = contResultType cont (m,arg_ty,_) = splitFunTy fun_ty ; arg_bndr <- newId (fsLit "arg") m arg_ty ; let env' = env `addNewInScopeIds` [arg_bndr] ; (floats, join_rhs) <- rebuildCall env' (addValArgTo fun (Var arg_bndr) fun_ty) cont ; mkDupableStrictBind env' arg_bndr (wrapFloats floats join_rhs) rhs_ty } where thumbsUpPlanA (StrictArg {}) = False thumbsUpPlanA (CastIt _ k) = thumbsUpPlanA k thumbsUpPlanA (TickIt _ k) = thumbsUpPlanA k thumbsUpPlanA (ApplyToVal { sc_cont = k }) = thumbsUpPlanA k thumbsUpPlanA (ApplyToTy { sc_cont = k }) = thumbsUpPlanA k thumbsUpPlanA (Select {}) = True thumbsUpPlanA (StrictBind {}) = True thumbsUpPlanA (Stop {}) = True mkDupableContWithDmds env dmds (ApplyToTy { sc_cont = cont, sc_arg_ty = arg_ty, sc_hole_ty = hole_ty }) = do { (floats, cont') <- mkDupableContWithDmds env dmds cont ; return (floats, ApplyToTy { sc_cont = cont' , sc_arg_ty = arg_ty, sc_hole_ty = hole_ty }) } mkDupableContWithDmds env dmds (ApplyToVal { sc_arg = arg, sc_dup = dup, sc_env = se , sc_cont = cont, sc_hole_ty = hole_ty }) = -- e.g. [...hole...] (...arg...) -- ==> -- let a = ...arg... -- in [...hole...] a -- NB: sc_dup /= OkToDup; that is caught earlier by contIsDupable do { let (dmd:_) = dmds -- Never fails ; (floats1, cont') <- mkDupableContWithDmds env dmds cont ; let env' = env `setInScopeFromF` floats1 ; (_, se', arg') <- simplArg env' dup se arg ; (let_floats2, arg'') <- makeTrivial (getMode env) NotTopLevel dmd (fsLit "karg") arg' ; let all_floats = floats1 `addLetFloats` let_floats2 ; return ( all_floats , ApplyToVal { sc_arg = arg'' , sc_env = se' `setInScopeFromF` all_floats -- Ensure that sc_env includes the free vars of -- arg'' in its in-scope set, even if makeTrivial -- has turned arg'' into a fresh variable -- See Note [StaticEnv invariant] in GHC.Core.Opt.Simplify.Utils , sc_dup = OkToDup, sc_cont = cont' , sc_hole_ty = hole_ty }) } mkDupableContWithDmds env _ (Select { sc_bndr = case_bndr, sc_alts = alts, sc_env = se, sc_cont = cont }) = -- e.g. (case [...hole...] of { pi -> ei }) -- ===> -- let ji = \xij -> ei -- in case [...hole...] of { pi -> ji xij } -- NB: sc_dup /= OkToDup; that is caught earlier by contIsDupable do { tick (CaseOfCase case_bndr) ; (floats, alt_env, alt_cont) <- mkDupableCaseCont (se `setInScopeFromE` env) alts cont -- NB: We call mkDupableCaseCont here to make cont duplicable -- (if necessary, depending on the number of alts) -- And this is important: see Note [Fusing case continuations] ; let cont_scaling = contHoleScaling cont -- See Note [Scaling in case-of-case] ; (alt_env', case_bndr') <- simplBinder alt_env (scaleIdBy cont_scaling case_bndr) ; alts' <- mapM (simplAlt alt_env' Nothing [] case_bndr' alt_cont) (scaleAltsBy cont_scaling alts) -- Safe to say that there are no handled-cons for the DEFAULT case -- NB: simplBinder does not zap deadness occ-info, so -- a dead case_bndr' will still advertise its deadness -- This is really important because in -- case e of b { (# p,q #) -> ... } -- b is always dead, and indeed we are not allowed to bind b to (# p,q #), -- which might happen if e was an explicit unboxed pair and b wasn't marked dead. -- In the new alts we build, we have the new case binder, so it must retain -- its deadness. -- NB: we don't use alt_env further; it has the substEnv for -- the alternatives, and we don't want that ; (join_floats, alts'') <- mapAccumLM (mkDupableAlt (targetPlatform (seDynFlags env)) case_bndr') emptyJoinFloats alts' ; let all_floats = floats `addJoinFloats` join_floats -- Note [Duplicated env] ; return (all_floats , Select { sc_dup = OkToDup , sc_bndr = case_bndr' , sc_alts = alts'' , sc_env = zapSubstEnv se `setInScopeFromF` all_floats -- See Note [StaticEnv invariant] in GHC.Core.Opt.Simplify.Utils , sc_cont = mkBoringStop (contResultType cont) } ) } mkDupableStrictBind :: SimplEnv -> OutId -> OutExpr -> OutType -> SimplM (SimplFloats, SimplCont) mkDupableStrictBind env arg_bndr join_rhs res_ty | exprIsDupable (targetPlatform (seDynFlags env)) join_rhs = return (emptyFloats env , StrictBind { sc_bndr = arg_bndr, sc_bndrs = [] , sc_body = join_rhs , sc_env = zapSubstEnv env -- See Note [StaticEnv invariant] in GHC.Core.Opt.Simplify.Utils , sc_dup = OkToDup , sc_cont = mkBoringStop res_ty } ) | otherwise = do { join_bndr <- newJoinId [arg_bndr] res_ty ; let arg_info = ArgInfo { ai_fun = join_bndr , ai_rules = Nothing, ai_args = [] , ai_encl = False, ai_dmds = repeat topDmd , ai_discs = repeat 0 } ; return ( addJoinFloats (emptyFloats env) $ unitJoinFloat $ NonRec join_bndr $ Lam (setOneShotLambda arg_bndr) join_rhs , StrictArg { sc_dup = OkToDup , sc_fun = arg_info , sc_fun_ty = idType join_bndr , sc_cont = mkBoringStop res_ty } ) } mkDupableAlt :: Platform -> OutId -> JoinFloats -> OutAlt -> SimplM (JoinFloats, OutAlt) mkDupableAlt platform case_bndr jfloats (Alt con bndrs' rhs') | exprIsDupable platform rhs' -- Note [Small alternative rhs] = return (jfloats, Alt con bndrs' rhs') | otherwise = do { simpl_opts <- initSimpleOpts <$> getDynFlags ; let rhs_ty' = exprType rhs' scrut_ty = idType case_bndr case_bndr_w_unf = case con of DEFAULT -> case_bndr DataAlt dc -> setIdUnfolding case_bndr unf where -- See Note [Case binders and join points] unf = mkInlineUnfolding simpl_opts rhs rhs = mkConApp2 dc (tyConAppArgs scrut_ty) bndrs' LitAlt {} -> WARN( True, text "mkDupableAlt" <+> ppr case_bndr <+> ppr con ) case_bndr -- The case binder is alive but trivial, so why has -- it not been substituted away? final_bndrs' | isDeadBinder case_bndr = filter abstract_over bndrs' | otherwise = bndrs' ++ [case_bndr_w_unf] abstract_over bndr | isTyVar bndr = True -- Abstract over all type variables just in case | otherwise = not (isDeadBinder bndr) -- The deadness info on the new Ids is preserved by simplBinders final_args = varsToCoreExprs final_bndrs' -- Note [Join point abstraction] -- We make the lambdas into one-shot-lambdas. The -- join point is sure to be applied at most once, and doing so -- prevents the body of the join point being floated out by -- the full laziness pass really_final_bndrs = map one_shot final_bndrs' one_shot v | isId v = setOneShotLambda v | otherwise = v join_rhs = mkLams really_final_bndrs rhs' ; join_bndr <- newJoinId final_bndrs' rhs_ty' ; let join_call = mkApps (Var join_bndr) final_args alt' = Alt con bndrs' join_call ; return ( jfloats `addJoinFlts` unitJoinFloat (NonRec join_bndr join_rhs) , alt') } -- See Note [Duplicated env] {- Note [Fusing case continuations] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ It's important to fuse two successive case continuations when the first has one alternative. That's why we call prepareCaseCont here. Consider this, which arises from thunk splitting (see Note [Thunk splitting] in GHC.Core.Opt.WorkWrap): let x* = case (case v of {pn -> rn}) of I# a -> I# a in body The simplifier will find (Var v) with continuation Select (pn -> rn) ( Select [I# a -> I# a] ( StrictBind body Stop So we'll call mkDupableCont on Select [I# a -> I# a] (StrictBind body Stop) There is just one alternative in the first Select, so we want to simplify the rhs (I# a) with continuation (StrictBind body Stop) Supposing that body is big, we end up with let $j a = <let x = I# a in body> in case v of { pn -> case rn of I# a -> $j a } This is just what we want because the rn produces a box that the case rn cancels with. See #4957 a fuller example. Note [Case binders and join points] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider this case (case .. ) of c { I# c# -> ....c.... If we make a join point with c but not c# we get $j = \c -> ....c.... But if later inlining scrutinises the c, thus $j = \c -> ... case c of { I# y -> ... } ... we won't see that 'c' has already been scrutinised. This actually happens in the 'tabulate' function in wave4main, and makes a significant difference to allocation. An alternative plan is this: $j = \c# -> let c = I# c# in ...c.... but that is bad if 'c' is *not* later scrutinised. So instead we do both: we pass 'c' and 'c#' , and record in c's inlining (a stable unfolding) that it's really I# c#, thus $j = \c# -> \c[=I# c#] -> ...c.... Absence analysis may later discard 'c'. NB: take great care when doing strictness analysis; see Note [Lambda-bound unfoldings] in GHC.Core.Opt.DmdAnal. Also note that we can still end up passing stuff that isn't used. Before strictness analysis we have let $j x y c{=(x,y)} = (h c, ...) in ... After strictness analysis we see that h is strict, we end up with let $j x y c{=(x,y)} = ($wh x y, ...) and c is unused. Note [Duplicated env] ~~~~~~~~~~~~~~~~~~~~~ Some of the alternatives are simplified, but have not been turned into a join point So they *must* have a zapped subst-env. So we can't use completeNonRecX to bind the join point, because it might to do PostInlineUnconditionally, and we'd lose that when zapping the subst-env. We could have a per-alt subst-env, but zapping it (as we do in mkDupableCont, the Select case) is safe, and at worst delays the join-point inlining. Note [Small alternative rhs] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ It is worth checking for a small RHS because otherwise we get extra let bindings that may cause an extra iteration of the simplifier to inline back in place. Quite often the rhs is just a variable or constructor. The Ord instance of Maybe in PrelMaybe.hs, for example, took several extra iterations because the version with the let bindings looked big, and so wasn't inlined, but after the join points had been inlined it looked smaller, and so was inlined. NB: we have to check the size of rhs', not rhs. Duplicating a small InAlt might invalidate occurrence information However, if it *is* dupable, we return the *un* simplified alternative, because otherwise we'd need to pair it up with an empty subst-env.... but we only have one env shared between all the alts. (Remember we must zap the subst-env before re-simplifying something). Rather than do this we simply agree to re-simplify the original (small) thing later. Note [Funky mkLamTypes] ~~~~~~~~~~~~~~~~~~~~~~ Notice the funky mkLamTypes. If the constructor has existentials it's possible that the join point will be abstracted over type variables as well as term variables. Example: Suppose we have data T = forall t. C [t] Then faced with case (case e of ...) of C t xs::[t] -> rhs We get the join point let j :: forall t. [t] -> ... j = /\t \xs::[t] -> rhs in case (case e of ...) of C t xs::[t] -> j t xs Note [Duplicating StrictArg] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Dealing with making a StrictArg continuation duplicable has turned out to be one of the trickiest corners of the simplifier, giving rise to several cases in which the simplier expanded the program's size *exponentially*. They include #13253 exponential inlining #10421 ditto #18140 strict constructors #18282 another nested-function call case Suppose we have a call f e1 (case x of { True -> r1; False -> r2 }) e3 and f is strict in its second argument. Then we end up in mkDupableCont with a StrictArg continuation for (f e1 <> e3). There are two ways to make it duplicable. * Plan A: move the entire call inwards, being careful not to duplicate e1 or e3, thus: let a1 = e1 a3 = e3 in case x of { True -> f a1 r1 a3 ; False -> f a1 r2 a3 } * Plan B: make a join point: join $j x = f e1 x e3 in case x of { True -> jump $j r1 ; False -> jump $j r2 } Notice that Plan B is very like the way we handle strict bindings; see Note [Duplicating StrictBind]. Plan A is good. Here's an example from #3116 go (n+1) (case l of 1 -> bs' _ -> Chunk p fpc (o+1) (l-1) bs') If we pushed the entire call for 'go' inside the case, we get call-pattern specialisation for 'go', which is *crucial* for this particular program. Here is another example. && E (case x of { T -> F; F -> T }) Pushing the call inward (being careful not to duplicate E) let a = E in case x of { T -> && a F; F -> && a T } and now the (&& a F) etc can optimise. Moreover there might be a RULE for the function that can fire when it "sees" the particular case alternative. But Plan A can have terrible, terrible behaviour. Here is a classic case: f (f (f (f (f True)))) Suppose f is strict, and has a body that is small enough to inline. The innermost call inlines (seeing the True) to give f (f (f (f (case v of { True -> e1; False -> e2 })))) Now, suppose we naively push the entire continuation into both case branches (it doesn't look large, just f.f.f.f). We get case v of True -> f (f (f (f e1))) False -> f (f (f (f e2))) And now the process repeats, so we end up with an exponentially large number of copies of f. No good! CONCLUSION: we want Plan A in general, but do Plan B is there a danger of this nested call behaviour. The function that decides this is called thumbsUpPlanA. Note [Keeping demand info in StrictArg Plan A] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Following on from Note [Duplicating StrictArg], another common code pattern that can go bad is this: f (case x1 of { T -> F; F -> T }) (case x2 of { T -> F; F -> T }) ...etc... when f is strict in all its arguments. (It might, for example, be a strict data constructor whose wrapper has not yet been inlined.) We use Plan A (because there is no nesting) giving let a2 = case x2 of ... a3 = case x3 of ... in case x1 of { T -> f F a2 a3 ... ; F -> f T a2 a3 ... } Now we must be careful! a2 and a3 are small, and the OneOcc code in postInlineUnconditionally may inline them both at both sites; see Note Note [Inline small things to avoid creating a thunk] in Simplify.Utils. But if we do inline them, the entire process will repeat -- back to exponential behaviour. So we are careful to keep the demand-info on a2 and a3. Then they'll be /strict/ let-bindings, which will be dealt with by StrictBind. That's why contIsDupableWithDmds is careful to propagage demand info to the auxiliary bindings it creates. See the Demand argument to makeTrivial. Note [Duplicating StrictBind] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We make a StrictBind duplicable in a very similar way to that for case expressions. After all, let x* = e in b is similar to case e of x -> b So we potentially make a join-point for the body, thus: let x = <> in b ==> join j x = b in j <> Just like StrictArg in fact -- and indeed they share code. Note [Join point abstraction] Historical note ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ NB: This note is now historical, describing how (in the past) we used to add a void argument to nullary join points. But now that "join point" is not a fuzzy concept but a formal syntactic construct (as distinguished by the JoinId constructor of IdDetails), each of these concerns is handled separately, with no need for a vestigial extra argument. Join points always have at least one value argument, for several reasons * If we try to lift a primitive-typed something out for let-binding-purposes, we will *caseify* it (!), with potentially-disastrous strictness results. So instead we turn it into a function: \v -> e where v::Void#. The value passed to this function is void, which generates (almost) no code. * CPR. We used to say "&& isUnliftedType rhs_ty'" here, but now we make the join point into a function whenever used_bndrs' is empty. This makes the join-point more CPR friendly. Consider: let j = if .. then I# 3 else I# 4 in case .. of { A -> j; B -> j; C -> ... } Now CPR doesn't w/w j because it's a thunk, so that means that the enclosing function can't w/w either, which is a lose. Here's the example that happened in practice: kgmod :: Int -> Int -> Int kgmod x y = if x > 0 && y < 0 || x < 0 && y > 0 then 78 else 5 * Let-no-escape. We want a join point to turn into a let-no-escape so that it is implemented as a jump, and one of the conditions for LNE is that it's not updatable. In CoreToStg, see Note [What is a non-escaping let] * Floating. Since a join point will be entered once, no sharing is gained by floating out, but something might be lost by doing so because it might be allocated. I have seen a case alternative like this: True -> \v -> ... It's a bit silly to add the realWorld dummy arg in this case, making $j = \s v -> ... True -> $j s (the \v alone is enough to make CPR happy) but I think it's rare There's a slight infelicity here: we pass the overall case_bndr to all the join points if it's used in *any* RHS, because we don't know its usage in each RHS separately ************************************************************************ * * Unfoldings * * ************************************************************************ -} simplLetUnfolding :: SimplEnv-> TopLevelFlag -> MaybeJoinCont -> InId -> OutExpr -> OutType -> ArityType -> Unfolding -> SimplM Unfolding simplLetUnfolding env top_lvl cont_mb id new_rhs rhs_ty arity unf | isStableUnfolding unf = simplStableUnfolding env top_lvl cont_mb id rhs_ty arity unf | isExitJoinId id = return noUnfolding -- See Note [Do not inline exit join points] in GHC.Core.Opt.Exitify | otherwise = mkLetUnfolding (seUnfoldingOpts env) top_lvl InlineRhs id new_rhs ------------------- mkLetUnfolding :: UnfoldingOpts -> TopLevelFlag -> UnfoldingSource -> InId -> OutExpr -> SimplM Unfolding mkLetUnfolding uf_opts top_lvl src id new_rhs = is_bottoming `seq` -- See Note [Force bottoming field] return (mkUnfolding uf_opts src is_top_lvl is_bottoming new_rhs) -- We make an unfolding *even for loop-breakers*. -- Reason: (a) It might be useful to know that they are WHNF -- (b) In GHC.Iface.Tidy we currently assume that, if we want to -- expose the unfolding then indeed we *have* an unfolding -- to expose. (We could instead use the RHS, but currently -- we don't.) The simple thing is always to have one. where is_top_lvl = isTopLevel top_lvl is_bottoming = isDeadEndId id ------------------- simplStableUnfolding :: SimplEnv -> TopLevelFlag -> MaybeJoinCont -- Just k => a join point with continuation k -> InId -> OutType -> ArityType -- Used to eta expand, but only for non-join-points -> Unfolding ->SimplM Unfolding -- Note [Setting the new unfolding] simplStableUnfolding env top_lvl mb_cont id rhs_ty id_arity unf = case unf of NoUnfolding -> return unf BootUnfolding -> return unf OtherCon {} -> return unf DFunUnfolding { df_bndrs = bndrs, df_con = con, df_args = args } -> do { (env', bndrs') <- simplBinders unf_env bndrs ; args' <- mapM (simplExpr env') args ; return (mkDFunUnfolding bndrs' con args') } CoreUnfolding { uf_tmpl = expr, uf_src = src, uf_guidance = guide } | isStableSource src -> do { expr' <- case mb_cont of Just cont -> -- Binder is a join point -- See Note [Rules and unfolding for join points] simplJoinRhs unf_env id expr cont Nothing -> -- Binder is not a join point do { expr' <- simplExprC unf_env expr (mkBoringStop rhs_ty) ; return (eta_expand expr') } ; case guide of UnfWhen { ug_arity = arity , ug_unsat_ok = sat_ok , ug_boring_ok = boring_ok } -- Happens for INLINE things -> let guide' = UnfWhen { ug_arity = arity , ug_unsat_ok = sat_ok , ug_boring_ok = boring_ok || inlineBoringOk expr' } -- Refresh the boring-ok flag, in case expr' -- has got small. This happens, notably in the inlinings -- for dfuns for single-method classes; see -- Note [Single-method classes] in GHC.Tc.TyCl.Instance. -- A test case is #4138 -- But retain a previous boring_ok of True; e.g. see -- the way it is set in calcUnfoldingGuidanceWithArity in return (mkCoreUnfolding src is_top_lvl expr' guide') -- See Note [Top-level flag on inline rules] in GHC.Core.Unfold _other -- Happens for INLINABLE things -> mkLetUnfolding uf_opts top_lvl src id expr' } -- If the guidance is UnfIfGoodArgs, this is an INLINABLE -- unfolding, and we need to make sure the guidance is kept up -- to date with respect to any changes in the unfolding. | otherwise -> return noUnfolding -- Discard unstable unfoldings where uf_opts = seUnfoldingOpts env is_top_lvl = isTopLevel top_lvl act = idInlineActivation id unf_env = updMode (updModeForStableUnfoldings act) env -- See Note [Simplifying inside stable unfoldings] in GHC.Core.Opt.Simplify.Utils -- See Note [Eta-expand stable unfoldings] eta_expand expr | not eta_on = expr | exprIsTrivial expr = expr | otherwise = etaExpandAT id_arity expr eta_on = sm_eta_expand (getMode env) {- Note [Eta-expand stable unfoldings] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ For INLINE/INLINABLE things (which get stable unfoldings) there's a danger of getting f :: Int -> Int -> Int -> Blah [ Arity = 3 -- Good arity , Unf=Stable (\xy. blah) -- Less good arity, only 2 f = \pqr. e This can happen because f's RHS is optimised more vigorously than its stable unfolding. Now suppose we have a call g = f x Because f has arity=3, g will have arity=2. But if we inline f (using its stable unfolding) g's arity will reduce to 1, because <blah> hasn't been optimised yet. This happened in the 'parsec' library, for Text.Pasec.Char.string. Generally, if we know that 'f' has arity N, it seems sensible to eta-expand the stable unfolding to arity N too. Simple and consistent. Wrinkles * Don't eta-expand a trivial expr, else each pass will eta-reduce it, and then eta-expand again. See Note [Do not eta-expand trivial expressions] in GHC.Core.Opt.Simplify.Utils. * Don't eta-expand join points; see Note [Do not eta-expand join points] in GHC.Core.Opt.Simplify.Utils. We uphold this because the join-point case (mb_cont = Just _) doesn't use eta_expand. Note [Force bottoming field] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We need to force bottoming, or the new unfolding holds on to the old unfolding (which is part of the id). Note [Setting the new unfolding] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ * If there's an INLINE pragma, we simplify the RHS gently. Maybe we should do nothing at all, but simplifying gently might get rid of more crap. * If not, we make an unfolding from the new RHS. But *only* for non-loop-breakers. Making loop breakers not have an unfolding at all means that we can avoid tests in exprIsConApp, for example. This is important: if exprIsConApp says 'yes' for a recursive thing, then we can get into an infinite loop If there's a stable unfolding on a loop breaker (which happens for INLINABLE), we hang on to the inlining. It's pretty dodgy, but the user did say 'INLINE'. May need to revisit this choice. ************************************************************************ * * Rules * * ************************************************************************ Note [Rules in a letrec] ~~~~~~~~~~~~~~~~~~~~~~~~ After creating fresh binders for the binders of a letrec, we substitute the RULES and add them back onto the binders; this is done *before* processing any of the RHSs. This is important. Manuel found cases where he really, really wanted a RULE for a recursive function to apply in that function's own right-hand side. See Note [Forming Rec groups] in "GHC.Core.Opt.OccurAnal" -} addBndrRules :: SimplEnv -> InBndr -> OutBndr -> MaybeJoinCont -- Just k for a join point binder -- Nothing otherwise -> SimplM (SimplEnv, OutBndr) -- Rules are added back into the bin addBndrRules env in_id out_id mb_cont | null old_rules = return (env, out_id) | otherwise = do { new_rules <- simplRules env (Just out_id) old_rules mb_cont ; let final_id = out_id `setIdSpecialisation` mkRuleInfo new_rules ; return (modifyInScope env final_id, final_id) } where old_rules = ruleInfoRules (idSpecialisation in_id) simplRules :: SimplEnv -> Maybe OutId -> [CoreRule] -> MaybeJoinCont -> SimplM [CoreRule] simplRules env mb_new_id rules mb_cont = mapM simpl_rule rules where simpl_rule rule@(BuiltinRule {}) = return rule simpl_rule rule@(Rule { ru_bndrs = bndrs, ru_args = args , ru_fn = fn_name, ru_rhs = rhs , ru_act = act }) = do { (env', bndrs') <- simplBinders env bndrs ; let rhs_ty = substTy env' (exprType rhs) rhs_cont = case mb_cont of -- See Note [Rules and unfolding for join points] Nothing -> mkBoringStop rhs_ty Just cont -> ASSERT2( join_ok, bad_join_msg ) cont lhs_env = updMode updModeForRules env' rhs_env = updMode (updModeForStableUnfoldings act) env' -- See Note [Simplifying the RHS of a RULE] fn_name' = case mb_new_id of Just id -> idName id Nothing -> fn_name -- join_ok is an assertion check that the join-arity of the -- binder matches that of the rule, so that pushing the -- continuation into the RHS makes sense join_ok = case mb_new_id of Just id | Just join_arity <- isJoinId_maybe id -> length args == join_arity _ -> False bad_join_msg = vcat [ ppr mb_new_id, ppr rule , ppr (fmap isJoinId_maybe mb_new_id) ] ; args' <- mapM (simplExpr lhs_env) args ; rhs' <- simplExprC rhs_env rhs rhs_cont ; return (rule { ru_bndrs = bndrs' , ru_fn = fn_name' , ru_args = args' , ru_rhs = rhs' }) } {- Note [Simplifying the RHS of a RULE] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We can simplify the RHS of a RULE much as we do the RHS of a stable unfolding. We used to use the much more conservative updModeForRules for the RHS as well as the LHS, but that seems more conservative than necesary. Allowing some inlining might, for example, eliminate a binding. -}