[Git][ghc/ghc][wip/marge_bot_batch_merge_job] 2 commits: Refactor the simplifier a bit to fix #22761
Marge Bot (@marge-bot)
gitlab at gitlab.haskell.org
Fri Feb 10 07:51:38 UTC 2023
Marge Bot pushed to branch wip/marge_bot_batch_merge_job at Glasgow Haskell Compiler / GHC
Commits:
eaf5554b by Simon Peyton Jones at 2023-02-10T02:51:20-05:00
Refactor the simplifier a bit to fix #22761
The core change in this commit, which fixes #22761, is that
* In a Core rule, ru_rhs is always occ-analysed.
This means adding a couple of calls to occurAnalyseExpr when
building a Rule, in
* GHC.Core.Rules.mkRule
* GHC.Core.Opt.Simplify.Iteration.simplRules
But diagosing the bug made me stare carefully at the code of the
Simplifier, and I ended up doing some only-loosely-related refactoring.
* I think that RULES could be lost because not every code path
did addBndrRules
* The code around lambdas was very convoluted
It's mainly moving deck chairs around, but I like it more now.
- - - - -
f8370c8b by Rebecca Turner at 2023-02-10T02:51:23-05:00
Detect the `mold` linker
Enables support for the `mold` linker by rui314.
- - - - -
14 changed files:
- compiler/GHC/Core.hs
- compiler/GHC/Core/Opt/Arity.hs
- compiler/GHC/Core/Opt/OccurAnal.hs
- compiler/GHC/Core/Opt/Simplify/Env.hs
- compiler/GHC/Core/Opt/Simplify/Iteration.hs
- compiler/GHC/Core/Opt/Simplify/Utils.hs
- compiler/GHC/Core/Rules.hs
- compiler/GHC/Core/Utils.hs
- compiler/GHC/Driver/Session.hs
- compiler/GHC/SysTools/Info.hs
- compiler/GHC/Types/Id.hs
- + testsuite/tests/simplCore/should_compile/T22761.hs
- + testsuite/tests/simplCore/should_compile/T22761a.hs
- testsuite/tests/simplCore/should_compile/all.T
Changes:
=====================================
compiler/GHC/Core.hs
=====================================
@@ -1300,16 +1300,19 @@ data Unfolding
df_args :: [CoreExpr] -- Args of the data con: types, superclasses and methods,
} -- in positional order
- | CoreUnfolding { -- An unfolding for an Id with no pragma,
- -- or perhaps a NOINLINE pragma
- -- (For NOINLINE, the phase, if any, is in the
- -- InlinePragInfo for this Id.)
- uf_tmpl :: CoreExpr, -- Template; occurrence info is correct
- uf_src :: UnfoldingSource, -- Where the unfolding came from
- uf_is_top :: Bool, -- True <=> top level binding
- uf_cache :: UnfoldingCache, -- Cache of flags computable from the expr
- -- See Note [Tying the 'CoreUnfolding' knot]
- uf_guidance :: UnfoldingGuidance -- Tells about the *size* of the template.
+ | CoreUnfolding { -- An unfolding for an Id with no pragma,
+ -- or perhaps a NOINLINE pragma
+ -- (For NOINLINE, the phase, if any, is in the
+ -- InlinePragInfo for this Id.)
+ uf_tmpl :: CoreExpr, -- The unfolding itself (aka "template")
+ -- Always occ-analysed;
+ -- See Note [OccInfo in unfoldings and rules]
+
+ uf_src :: UnfoldingSource, -- Where the unfolding came from
+ uf_is_top :: Bool, -- True <=> top level binding
+ uf_cache :: UnfoldingCache, -- Cache of flags computable from the expr
+ -- See Note [Tying the 'CoreUnfolding' knot]
+ uf_guidance :: UnfoldingGuidance -- Tells about the *size* of the template.
}
-- ^ An unfolding with redundant cached information. Parameters:
--
@@ -1637,14 +1640,37 @@ change was requested by Roman, but it seems to make sense.
Note [OccInfo in unfoldings and rules]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
-In unfoldings and rules, we guarantee that the template is occ-analysed,
-so that the occurrence info on the binders is correct. This is important,
-because the Simplifier does not re-analyse the template when using it. If
-the occurrence info is wrong
- - We may get more simplifier iterations than necessary, because
- once-occ info isn't there
- - More seriously, we may get an infinite loop if there's a Rec
- without a loop breaker marked
+In unfoldings and rules, we guarantee that the template is occ-analysed, so
+that the occurrence info on the binders is correct. That way, when the
+Simplifier inlines an unfolding, it doesn't need to occ-analysis it first.
+(The Simplifier is designed to simplify occ-analysed expressions.)
+
+Given this decision it's vital that we do *always* do it.
+
+* If we don't, we may get more simplifier iterations than necessary,
+ because once-occ info isn't there
+
+* More seriously, we may get an infinite loop if there's a Rec without a
+ loop breaker marked.
+
+* Or we may get code that mentions variables not in scope: #22761
+ e.g. Suppose we have a stable unfolding : \y. let z = p+1 in 3
+ Then the pre-simplifier occ-anal will occ-anal the unfolding
+ (redundantly perhaps, but we need its free vars); this will not report
+ the use of `p`; so p's binding will be discarded, and yet `p` is still
+ mentioned.
+
+ Better to occ-anal the unfolding at birth, which will drop the
+ z-binding as dead code. (Remember, it's the occurrence analyser that
+ drops dead code.)
+
+* Another example is #8892:
+ \x -> letrec { f = ...g...; g* = f } in body
+ where g* is (for some strange reason) the loop breaker. If we don't
+ occ-anal it when reading it in, we won't mark g as a loop breaker, and we
+ may inline g entirely in body, dropping its binding, and leaving the
+ occurrence in f out of scope. This happened in #8892, where the unfolding
+ in question was a DFun unfolding.
************************************************************************
=====================================
compiler/GHC/Core/Opt/Arity.hs
=====================================
@@ -3088,8 +3088,15 @@ etaExpandToJoinPointRule join_arity rule@(Rule { ru_bndrs = bndrs, ru_rhs = rhs
| need_args < 0
= pprPanic "etaExpandToJoinPointRule" (ppr join_arity $$ ppr rule)
| otherwise
- = rule { ru_bndrs = bndrs ++ new_bndrs, ru_args = args ++ new_args
- , ru_rhs = new_rhs }
+ = rule { ru_bndrs = bndrs ++ new_bndrs
+ , ru_args = args ++ new_args
+ , ru_rhs = new_rhs }
+ -- new_rhs really ought to be occ-analysed (see GHC.Core Note
+ -- [OccInfo in unfoldings and rules]), but it makes a module loop to
+ -- do so; it doesn't happen often; and it doesn't really matter if
+ -- the outer binders have bogus occurrence info; and new_rhs won't
+ -- have dead code if rhs didn't.
+
where
need_args = join_arity - length args
(new_bndrs, new_rhs) = etaBodyForJoinPoint need_args rhs
=====================================
compiler/GHC/Core/Opt/OccurAnal.hs
=====================================
@@ -2165,6 +2165,17 @@ So we have a fast-path that keeps the old tree if the occ_bs_env is
empty. This just saves a bit of allocation and reconstruction; not
a big deal.
+This fast path exposes a tricky cornder, though (#22761). Supose we have
+ Unfolding = \x. let y = foo in x+1
+which includes a dead binding for `y`. In occAnalUnfolding we occ-anal
+the unfolding and produce /no/ occurrences of `foo` (since `y` is
+dead). But if we discard the occ-analysed syntax tree (which we do on
+our fast path), and use the old one, we still /have/ an occurrence of
+`foo` -- and that can lead to out-of-scope variables (#22761).
+
+Solution: always keep occ-analysed trees in unfoldings and rules, so they
+have no dead code. See Note [OccInfo in unfoldings and rules] in GHC.Core.
+
Note [Cascading inlines]
~~~~~~~~~~~~~~~~~~~~~~~~
By default we use an rhsCtxt for the RHS of a binding. This tells the
=====================================
compiler/GHC/Core/Opt/Simplify/Env.hs
=====================================
@@ -1065,7 +1065,7 @@ subst_id_bndr env@(SimplEnv { seInScope = in_scope, seIdSubst = id_subst })
-- See Note [Bangs in the Simplifier]
!id1 = uniqAway in_scope old_id
!id2 = substIdType env id1
- !id3 = zapFragileIdInfo id2 -- Zaps rules, worker-info, unfolding
+ !id3 = zapFragileIdInfo id2 -- Zaps rules, worker-info, unfolding
-- and fragile OccInfo
!new_id = adjust_type id3
=====================================
compiler/GHC/Core/Opt/Simplify/Iteration.hs
=====================================
@@ -319,14 +319,14 @@ simplLazyBind :: SimplEnv
-> TopLevelFlag -> RecFlag
-> InId -> OutId -- Binder, both pre-and post simpl
-- Not a JoinId
- -- The OutId has IdInfo, except arity, unfolding
+ -- The OutId has IdInfo (notably RULES),
+ -- except arity, unfolding
-- Ids only, no TyVars
-> InExpr -> SimplEnv -- The RHS and its environment
-> SimplM (SimplFloats, SimplEnv)
-- Precondition: the OutId is already in the InScopeSet of the incoming 'env'
-- Precondition: not a JoinId
-- Precondition: rhs obeys the let-can-float invariant
--- NOT used for JoinIds
simplLazyBind env top_lvl is_rec bndr bndr1 rhs rhs_se
= assert (isId bndr )
assertPpr (not (isJoinId bndr)) (ppr bndr) $
@@ -398,48 +398,45 @@ simplJoinBind env is_rec cont old_bndr new_bndr rhs rhs_se
; completeBind env (BC_Join is_rec cont) old_bndr new_bndr rhs' }
--------------------------
-simplNonRecX :: SimplEnv
+simplAuxBind :: 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.
+-- A specialised variant of completeBindX used to construct non-recursive
+-- auxiliary bindings, notably in knownCon.
+--
+-- The binder comes from a case expression (case binder or alternative)
+-- and so does not have rules, inline pragmas etc.
--
-- Precondition: rhs satisfies the let-can-float invariant
-simplNonRecX env bndr new_rhs
- | assertPpr (not (isJoinId bndr)) (ppr bndr) $
+simplAuxBind env bndr new_rhs
+ | assertPpr (isId bndr && 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)
+ -- creating the binding c = (a,b)
+ -- The cases would be inlined unconditionally by completeBind:
+ -- but it seems not uncommon, and avoids faff to do it here
+ -- This is safe because it's only used for auxiliary bindings, which
+ -- have no NOLINE pragmas, nor RULEs
| exprIsTrivial new_rhs -- Short-cut for let x = y in ...
- -- This case would ultimately land in postInlineUnconditionally
- -- but it seems not uncommon, and avoids a lot of faff to do it here
- = return (emptyFloats env
- , extendIdSubst env bndr (DoneEx new_rhs Nothing))
+ = return ( emptyFloats env
+ , case new_rhs of
+ Coercion co -> extendCvSubst env bndr co
+ _ -> extendIdSubst env bndr (DoneEx new_rhs Nothing) )
| otherwise
- = do { (env1, new_bndr) <- simplBinder env bndr
- ; let is_strict = isStrictId new_bndr
- -- isStrictId: use new_bndr because the InId bndr might not have
- -- a fixed runtime representation, which isStrictId doesn't expect
- -- c.f. Note [Dark corner with representation polymorphism]
-
- ; (rhs_floats, rhs1) <- prepareBinding env NotTopLevel NonRecursive is_strict
- new_bndr (emptyFloats env) new_rhs
- -- NB: it makes a surprisingly big difference (5% in compiler allocation
- -- in T9630) to pass 'env' rather than 'env1'. It's fine to pass 'env',
- -- because this is simplNonRecX, so bndr is not in scope in the RHS.
-
- ; (bind_float, env2) <- completeBind (env1 `setInScopeFromF` rhs_floats)
- (BC_Let NotTopLevel NonRecursive)
+ = do { -- ANF-ise the RHS
+ let !occ_fs = getOccFS bndr
+ ; (anf_floats, rhs1) <- prepareRhs env NotTopLevel occ_fs new_rhs
+ ; unless (isEmptyLetFloats anf_floats) (tick LetFloatFromLet)
+ ; let rhs_floats = emptyFloats env `addLetFloats` anf_floats
+
+ -- Simplify the binder and complete the binding
+ ; (env1, new_bndr) <- simplBinder (env `setInScopeFromF` rhs_floats) bndr
+ ; (bind_float, env2) <- completeBind env1 (BC_Let NotTopLevel NonRecursive)
bndr new_bndr rhs1
- -- Must pass env1 to completeBind in case simplBinder had to clone,
- -- and extended the substitution with [bndr :-> new_bndr]
; return (rhs_floats `addFloats` bind_float, env2) }
@@ -761,49 +758,54 @@ prepareRhs :: HasDebugCallStack
-- x = Just a
-- See Note [prepareRhs]
prepareRhs env top_lvl occ rhs0
- = do { (_is_exp, floats, rhs1) <- go 0 rhs0
- ; return (floats, rhs1) }
+ | is_expandable = anfise rhs0
+ | otherwise = return (emptyLetFloats, rhs0)
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
- ; if is_exp
- then do { (floats2, arg') <- makeTrivial env top_lvl topDmd occ arg
- ; return (True, floats1 `addLetFlts` floats2, App fun' arg') }
- else return (False, emptyLetFloats, 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 can' use exprIsExpandable because the WHOLE POINT is that
+ -- we want to treat (K <big>) as expandable, because we are just
+ -- about "anfise" the <big> expression. exprIsExpandable would
+ -- just say no!
+ is_expandable = go rhs0 0
+ where
+ go (Var fun) n_val_args = isExpandableApp fun n_val_args
+ go (App fun arg) n_val_args
+ | isTypeArg arg = go fun n_val_args
+ | otherwise = go fun (n_val_args + 1)
+ go (Cast rhs _) n_val_args = go rhs n_val_args
+ go (Tick _ rhs) n_val_args = go rhs n_val_args
+ go _ _ = False
+
+ anfise :: OutExpr -> SimplM (LetFloats, OutExpr)
+ anfise (Cast rhs co)
+ = do { (floats, rhs') <- anfise rhs
+ ; return (floats, Cast rhs' co) }
+ anfise (App fun (Type ty))
+ = do { (floats, rhs') <- anfise fun
+ ; return (floats, App rhs' (Type ty)) }
+ anfise (App fun arg)
+ = do { (floats1, fun') <- anfise fun
+ ; (floats2, arg') <- makeTrivial env top_lvl topDmd occ arg
+ ; return (floats1 `addLetFlts` floats2, App fun' arg') }
+ anfise (Var fun)
+ = return (emptyLetFloats, Var fun)
+
+ anfise (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') }
+ = do { (floats, rhs') <- anfise rhs
+ ; return (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
+ = do { (floats, rhs') <- anfise rhs
; let tickIt (id, expr) = (id, mkTick (mkNoCount t) expr)
floats' = mapLetFloats floats tickIt
- ; return (is_exp, floats', Tick t rhs') }
+ ; return (floats', Tick t rhs') }
- go _ other
- = return (False, emptyLetFloats, other)
+ anfise other = return (emptyLetFloats, other)
makeTrivialArg :: HasDebugCallStack => SimplEnv -> ArgSpec -> SimplM (LetFloats, ArgSpec)
makeTrivialArg env arg@(ValArg { as_arg = e, as_dmd = dmd })
@@ -1244,7 +1246,7 @@ simplExprF1 env (Let (NonRec bndr rhs) body) cont
| otherwise
= {-#SCC "simplNonRecE" #-}
- simplNonRecE env False bndr (rhs, env) body cont
+ simplNonRecE env FromLet bndr (rhs, env) body cont
{- Note [Avoiding space leaks in OutType]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
@@ -1505,8 +1507,9 @@ rebuild env expr 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_body = body, sc_env = se, sc_cont = cont }
- -> completeBindX (se `setInScopeFromE` env) b expr body cont
+ StrictBind { sc_bndr = b, sc_body = body, sc_env = se
+ , sc_cont = cont, sc_from = from_what }
+ -> completeBindX (se `setInScopeFromE` env) from_what b expr body cont
ApplyToTy { sc_arg_ty = ty, sc_cont = cont}
-> rebuild env (App expr (Type ty)) cont
@@ -1518,25 +1521,48 @@ rebuild env expr cont
; rebuild env (App expr arg') cont }
completeBindX :: SimplEnv
+ -> FromWhat
-> InId -> OutExpr -- Bind this Id to this (simplified) expression
-- (the let-can-float invariant may not be satisfied)
- -> InExpr -- In this lambda
+ -> InExpr -- In this body
-> SimplCont -- Consumed by this continuation
-> SimplM (SimplFloats, OutExpr)
-completeBindX env bndr rhs body cont
- | needsCaseBinding (idType bndr) rhs -- Enforcing the let-can-float-invariant
- = do { (env1, bndr1) <- simplNonRecBndr env bndr
- ; (floats, expr') <- simplLam env1 body cont
+completeBindX env from_what bndr rhs body cont
+ | FromBeta arg_ty <- from_what
+ , needsCaseBinding arg_ty rhs -- Enforcing the let-can-float-invariant
+ = do { (env1, bndr1) <- simplNonRecBndr env bndr -- Lambda binders don't have rules
+ ; (floats, expr') <- simplNonRecBody env1 from_what body cont
-- Do not float floats past the Case binder below
; let expr'' = wrapFloats floats expr'
- ; let case_expr = Case rhs bndr1 (contResultType cont) [Alt DEFAULT [] expr'']
+ case_expr = Case rhs bndr1 (contResultType cont) [Alt DEFAULT [] expr'']
; return (emptyFloats env, case_expr) }
- | otherwise
- = do { (floats1, env') <- simplNonRecX env bndr rhs
- ; (floats2, expr') <- simplLam env' body cont
- ; return (floats1 `addFloats` floats2, expr') }
+ | otherwise -- Make a let-binding
+ = do { (env1, bndr1) <- simplNonRecBndr env bndr
+ ; (env2, bndr2) <- addBndrRules env1 bndr bndr1 (BC_Let NotTopLevel NonRecursive)
+
+ ; let is_strict = isStrictId bndr2
+ -- isStrictId: use simplified binder because the InId bndr might not have
+ -- a fixed runtime representation, which isStrictId doesn't expect
+ -- c.f. Note [Dark corner with representation polymorphism]
+
+ ; (rhs_floats, rhs1) <- prepareBinding env NotTopLevel NonRecursive is_strict
+ bndr2 (emptyFloats env) rhs
+ -- NB: it makes a surprisingly big difference (5% in compiler allocation
+ -- in T9630) to pass 'env' rather than 'env1'. It's fine to pass 'env',
+ -- because this is simplNonRecX, so bndr is not in scope in the RHS.
+
+ ; (bind_float, env2) <- completeBind (env2 `setInScopeFromF` rhs_floats)
+ (BC_Let NotTopLevel NonRecursive)
+ bndr bndr2 rhs1
+ -- Must pass env1 to completeBind in case simplBinder had to clone,
+ -- and extended the substitution with [bndr :-> new_bndr]
+
+ -- Simplify the body
+ ; (body_floats, body') <- simplNonRecBody env2 from_what body cont
+ ; let all_floats = rhs_floats `addFloats` bind_float `addFloats` body_floats
+ ; return ( all_floats, body' ) }
{-
************************************************************************
@@ -1674,6 +1700,14 @@ simplArg env dup_flag fun_ty arg_env arg
************************************************************************
-}
+simplNonRecBody :: SimplEnv -> FromWhat
+ -> InExpr -> SimplCont
+ -> SimplM (SimplFloats, OutExpr)
+simplNonRecBody env from_what body cont
+ = case from_what of
+ FromLet -> simplExprF env body cont
+ FromBeta {} -> simplLam env body cont
+
simplLam :: SimplEnv -> InExpr -> SimplCont
-> SimplM (SimplFloats, OutExpr)
@@ -1690,15 +1724,24 @@ simpl_lam env bndr body (ApplyToTy { sc_arg_ty = arg_ty, sc_cont = cont })
-- Value beta-reduction
simpl_lam env bndr 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]
+ , sc_cont = cont, sc_dup = dup
+ , sc_hole_ty = fun_ty})
= do { tick (BetaReduction bndr)
- ; completeBindX env bndr arg body cont }
+ ; let arg_ty = funArgTy fun_ty
+ ; if | isSimplified dup -- Don't re-simplify if we've simplified it once
+ -- Including don't preInlineUnconditionally
+ -- See Note [Avoiding exponential behaviour]
+ -> completeBindX env (FromBeta arg_ty) bndr arg body cont
+
+ | Just env' <- preInlineUnconditionally env NotTopLevel bndr arg arg_se
+ , not (needsCaseBinding arg_ty arg)
+ -- Ok to test arg::InExpr in needsCaseBinding because
+ -- exprOkForSpeculation is stable under simplification
+ -> do { tick (PreInlineUnconditionally bndr)
+ ; simplLam env' body cont }
- | otherwise -- See Note [Avoiding exponential behaviour]
- = do { tick (BetaReduction bndr)
- ; simplNonRecE env True bndr (arg, arg_se) body cont }
+ | otherwise
+ -> simplNonRecE env (FromBeta arg_ty) bndr (arg, arg_se) body cont }
-- Discard a non-counting tick on a lambda. This may change the
-- cost attribution slightly (moving the allocation of the
@@ -1730,8 +1773,7 @@ simplLamBndrs env bndrs = mapAccumLM simplLamBndr env bndrs
------------------
simplNonRecE :: SimplEnv
- -> Bool -- True <=> from a lambda
- -- False <=> from a let
+ -> FromWhat
-> InId -- The binder, always an Id
-- Never a join point
-> (InExpr, SimplEnv) -- Rhs of binding (or arg of lambda)
@@ -1740,56 +1782,48 @@ simplNonRecE :: SimplEnv
-> SimplM (SimplFloats, OutExpr)
-- simplNonRecE is used for
--- * non-top-level non-recursive non-join-point lets in expressions
--- * beta reduction
+-- * from=FromLet: a non-top-level non-recursive non-join-point let-expression
+-- * from=FromBeta: a binding arising from a beta reduction
--
--- simplNonRec env b (rhs, rhs_se) body k
+-- simplNonRecE env b (rhs, rhs_se) body k
-- = let env in
-- cont< let b = rhs_se(rhs) in body >
--
-- It deals with strict bindings, via the StrictBind continuation,
-- which may abort the whole process.
--
--- from_lam=False => the RHS satisfies the let-can-float invariant
+-- from_what=FromLet => the RHS satisfies the let-can-float invariant
-- Otherwise it may or may not satisfy it.
-simplNonRecE env from_lam bndr (rhs, rhs_se) body cont
- = assert (isId bndr && not (isJoinId bndr) ) $
- do { (env1, bndr1) <- simplNonRecBndr env bndr
- ; let needs_case_binding = needsCaseBinding (idType bndr1) rhs
- -- See Note [Dark corner with representation polymorphism]
- -- If from_lam=False then needs_case_binding is False,
- -- because the binding started as a let, which must
- -- satisfy let-can-float
-
- ; if | from_lam && not needs_case_binding
- -- If not from_lam we are coming from a (NonRec bndr rhs) binding
- -- and preInlineUnconditionally has been done already;
- -- no need to repeat it. But for lambdas we must be careful about
- -- preInlineUndonditionally: consider (\(x:Int#). 3) (error "urk")
- -- We must not drop the (error "urk").
- , Just env' <- preInlineUnconditionally env NotTopLevel bndr rhs rhs_se
- -> do { tick (PreInlineUnconditionally bndr)
- ; -- pprTrace "preInlineUncond" (ppr bndr <+> ppr rhs) $
- simplLam env' body cont }
-
- -- Deal with strict bindings
- | isStrictId bndr1 && seCaseCase env
- || from_lam && needs_case_binding
- -- The important bit here is needs_case_binds; but no need to
- -- test it if from_lam is False because then needs_case_binding is False too
- -- NB: either way, the RHS may or may not satisfy let-can-float
- -- but that's ok for StrictBind.
- -> simplExprF (rhs_se `setInScopeFromE` env) rhs
- (StrictBind { sc_bndr = bndr, sc_body = body
- , sc_env = env, sc_cont = cont, sc_dup = NoDup })
-
- -- Deal with lazy bindings
- | otherwise
- -> do { (env2, bndr2) <- addBndrRules env1 bndr bndr1 (BC_Let NotTopLevel NonRecursive)
- ; (floats1, env3) <- simplLazyBind env2 NotTopLevel NonRecursive bndr bndr2 rhs rhs_se
- ; (floats2, expr') <- simplLam env3 body cont
- ; return (floats1 `addFloats` floats2, expr') } }
+simplNonRecE env from_what bndr (rhs, rhs_se) body cont
+ | assert (isId bndr && not (isJoinId bndr) ) $
+ is_strict_bind
+ = -- Evaluate RHS strictly
+ simplExprF (rhs_se `setInScopeFromE` env) rhs
+ (StrictBind { sc_bndr = bndr, sc_body = body, sc_from = from_what
+ , sc_env = env, sc_cont = cont, sc_dup = NoDup })
+
+ | otherwise -- Evaluate RHS lazily
+ = do { (env1, bndr1) <- simplNonRecBndr env bndr
+ ; (env2, bndr2) <- addBndrRules env1 bndr bndr1 (BC_Let NotTopLevel NonRecursive)
+ ; (floats1, env3) <- simplLazyBind env2 NotTopLevel NonRecursive
+ bndr bndr2 rhs rhs_se
+ ; (floats2, expr') <- simplNonRecBody env3 from_what body cont
+ ; return (floats1 `addFloats` floats2, expr') }
+
+ where
+ is_strict_bind = case from_what of
+ FromBeta arg_ty | isUnliftedType arg_ty -> True
+ -- If we are coming from a beta-reduction (FromBeta) we must
+ -- establish the let-can-float invariant, so go via StrictBind
+ -- If not, the invariant holds already, and it's optional.
+ -- Using arg_ty: see Note [Dark corner with representation polymorphism]
+ -- e.g (\r \(a::TYPE r) \(x::a). blah) @LiftedRep @Int arg
+ -- When we come to `x=arg` we myst choose lazy/strict correctly
+ -- It's wrong to err in either directly
+
+ _ -> seCaseCase env && isStrUsedDmd (idDemandInfo bndr)
+
------------------
simplRecE :: SimplEnv
@@ -1835,7 +1869,7 @@ Note [Avoiding exponential behaviour]
One way in which we can get exponential behaviour is if we simplify a
big expression, and then 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 simplNonRecX does not try
+an expression (#13379). That is why simplNonRecX does not try
preInlineUnconditionally (unlike simplNonRecE).
Example:
@@ -2618,15 +2652,10 @@ 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, however, that the rule RHS is /already/ occ-analysed; see
+Note [OccInfo in unfoldings and rules] in GHC.Core. There is something
+unsatisfactory about doing it twice; but the rule RHS is usually very
+small, and this is simple.
Note [Optimising tagToEnum#]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~
@@ -2930,7 +2959,7 @@ rebuildCase env scrut case_bndr alts cont
where
simple_rhs env wfloats case_bndr_rhs bs rhs =
assert (null bs) $
- do { (floats1, env') <- simplNonRecX env case_bndr case_bndr_rhs
+ do { (floats1, env') <- simplAuxBind env case_bndr case_bndr_rhs
-- scrut is a constructor application,
-- hence satisfies let-can-float invariant
; (floats2, expr') <- simplExprF env' rhs cont
@@ -2997,7 +3026,7 @@ rebuildCase env scrut case_bndr alts@[Alt _ bndrs rhs] cont
| all_dead_bndrs
, doCaseToLet scrut case_bndr
= do { tick (CaseElim case_bndr)
- ; (floats1, env') <- simplNonRecX env case_bndr scrut
+ ; (floats1, env') <- simplAuxBind env case_bndr scrut
; (floats2, expr') <- simplExprF env' rhs cont
; return (floats1 `addFloats` floats2, expr') }
@@ -3483,12 +3512,11 @@ knownCon env scrut dc_floats dc dc_ty_args dc_args bndr bs rhs cont
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.
+ -- zap_occ: the binder might be "dead", because it doesn't
+ -- occur in the RHS; and simplAuxBind may therefore discard it.
-- 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-can-float invariant
+ ; (floats1, env2) <- simplAuxBind env' b' arg -- arg satisfies let-can-float invariant
; (floats2, env3) <- bind_args env2 bs' args
; return (floats1 `addFloats` floats2, env3) }
@@ -3514,7 +3542,7 @@ knownCon env scrut dc_floats dc dc_ty_args dc_args bndr bs rhs cont
; let con_app = Var (dataConWorkId dc)
`mkTyApps` dc_ty_args
`mkApps` dc_args
- ; simplNonRecX env bndr con_app }
+ ; simplAuxBind env bndr con_app }
-------------------
missingAlt :: SimplEnv -> Id -> [InAlt] -> SimplCont
@@ -3621,15 +3649,15 @@ mkDupableContWithDmds env dmds (TickIt t cont)
; return (floats, TickIt t cont') }
mkDupableContWithDmds env _
- (StrictBind { sc_bndr = bndr, sc_body = body
+ (StrictBind { sc_bndr = bndr, sc_body = body, sc_from = from_what
, 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 body cont
- -- No need to use mkDupableCont before simplLam; we
+ ; (floats1, join_inner) <- simplNonRecBody sb_env1 from_what body cont
+ -- No need to use mkDupableCont before simplNonRecBody; we
-- use cont once here, and then share the result if necessary
; let join_body = wrapFloats floats1 join_inner
@@ -3757,6 +3785,7 @@ mkDupableStrictBind env arg_bndr join_rhs res_ty
, StrictBind { sc_bndr = arg_bndr
, sc_body = join_rhs
, sc_env = zapSubstEnv env
+ , sc_from = FromLet
-- See Note [StaticEnv invariant] in GHC.Core.Opt.Simplify.Utils
, sc_dup = OkToDup
, sc_cont = mkBoringStop res_ty } )
@@ -4430,7 +4459,9 @@ simplRules env mb_new_id rules bind_cxt
; return (rule { ru_bndrs = bndrs'
, ru_fn = fn_name'
, ru_args = args'
- , ru_rhs = rhs' }) }
+ , ru_rhs = occurAnalyseExpr rhs' }) }
+ -- Remember to occ-analyse, to drop dead code.
+ -- See Note [OccInfo in unfoldings and rules] in GHC.Core
{- Note [Simplifying the RHS of a RULE]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
=====================================
compiler/GHC/Core/Opt/Simplify/Utils.hs
=====================================
@@ -21,7 +21,7 @@ module GHC.Core.Opt.Simplify.Utils (
BindContext(..), bindContextLevel,
-- The continuation type
- SimplCont(..), DupFlag(..), StaticEnv,
+ SimplCont(..), DupFlag(..), FromWhat(..), StaticEnv,
isSimplified, contIsStop,
contIsDupable, contResultType, contHoleType, contHoleScaling,
contIsTrivial, contArgs, contIsRhs,
@@ -192,6 +192,7 @@ data SimplCont
-- or, equivalently, = K[ (\x.b) e ]
{ sc_dup :: DupFlag -- See Note [DupFlag invariants]
, sc_bndr :: InId
+ , sc_from :: FromWhat
, sc_body :: InExpr
, sc_env :: StaticEnv -- See Note [StaticEnv invariant]
, sc_cont :: SimplCont }
@@ -213,6 +214,8 @@ data SimplCont
type StaticEnv = SimplEnv -- Just the static part is relevant
+data FromWhat = FromLet | FromBeta OutType
+
-- See Note [DupFlag invariants]
data DupFlag = NoDup -- Unsimplified, might be big
| Simplified -- Simplified
=====================================
compiler/GHC/Core/Rules.hs
=====================================
@@ -63,6 +63,7 @@ import GHC.Core.Tidy ( tidyRules )
import GHC.Core.Map.Expr ( eqCoreExpr )
import GHC.Core.Opt.Arity( etaExpandToJoinPointRule )
import GHC.Core.Make ( mkCoreLams )
+import GHC.Core.Opt.OccurAnal( occurAnalyseExpr )
import GHC.Tc.Utils.TcType ( tcSplitTyConApp_maybe )
import GHC.Builtin.Types ( anyTypeOfKind )
@@ -189,13 +190,18 @@ mkRule :: Module -> Bool -> Bool -> RuleName -> Activation
-- ^ Used to make 'CoreRule' for an 'Id' defined in the module being
-- compiled. See also 'GHC.Core.CoreRule'
mkRule this_mod is_auto is_local name act fn bndrs args rhs
- = Rule { ru_name = name, ru_fn = fn, ru_act = act,
- ru_bndrs = bndrs, ru_args = args,
- ru_rhs = rhs,
- ru_rough = roughTopNames args,
- ru_origin = this_mod,
- ru_orphan = orph,
- ru_auto = is_auto, ru_local = is_local }
+ = Rule { ru_name = name
+ , ru_act = act
+ , ru_fn = fn
+ , ru_bndrs = bndrs
+ , ru_args = args
+ , ru_rhs = occurAnalyseExpr rhs
+ -- See Note [OccInfo in unfoldings and rules]
+ , ru_rough = roughTopNames args
+ , ru_origin = this_mod
+ , ru_orphan = orph
+ , ru_auto = is_auto
+ , ru_local = is_local }
where
-- Compute orphanhood. See Note [Orphans] in GHC.Core.InstEnv
-- A rule is an orphan only if none of the variables
=====================================
compiler/GHC/Core/Utils.hs
=====================================
@@ -513,8 +513,8 @@ bindNonRec bndr rhs body
-- | Tests whether we have to use a @case@ rather than @let@ binding for this
-- expression as per the invariants of 'CoreExpr': see "GHC.Core#let_can_float_invariant"
needsCaseBinding :: Type -> CoreExpr -> Bool
-needsCaseBinding ty rhs =
- mightBeUnliftedType ty && not (exprOkForSpeculation rhs)
+needsCaseBinding ty rhs
+ = mightBeUnliftedType ty && not (exprOkForSpeculation rhs)
-- Make a case expression instead of a let
-- These can arise either from the desugarer,
-- or from beta reductions: (\x.e) (x +# y)
=====================================
compiler/GHC/Driver/Session.hs
=====================================
@@ -4939,6 +4939,7 @@ needSourceNotes dflags = debugLevel dflags > 0
-- LinkerInfo contains any extra options needed by the system linker.
data LinkerInfo
= GnuLD [Option]
+ | Mold [Option]
| GnuGold [Option]
| LlvmLLD [Option]
| DarwinLD [Option]
=====================================
compiler/GHC/SysTools/Info.hs
=====================================
@@ -70,6 +70,7 @@ The flag is only needed on ELF systems. On Windows (PE) and Mac OS X
neededLinkArgs :: LinkerInfo -> [Option]
neededLinkArgs (GnuLD o) = o
+neededLinkArgs (Mold o) = o
neededLinkArgs (GnuGold o) = o
neededLinkArgs (LlvmLLD o) = o
neededLinkArgs (DarwinLD o) = o
@@ -106,6 +107,10 @@ getLinkerInfo' logger dflags = do
-- see Note [ELF needed shared libs]
"-Wl,--no-as-needed"])
+ | any ("mold" `isPrefixOf`) stdo =
+ return (Mold $ map Option [ --see Note [ELF needed shared libs]
+ "-Wl,--no-as-needed"])
+
| any ("GNU gold" `isPrefixOf`) stdo =
-- GNU gold only needs --no-as-needed. #10110.
-- ELF specific flag, see Note [ELF needed shared libs]
=====================================
compiler/GHC/Types/Id.hs
=====================================
@@ -723,12 +723,14 @@ setIdCprSig id sig = modifyIdInfo (\info -> setCprSigInfo info sig) id
zapIdDmdSig :: Id -> Id
zapIdDmdSig id = modifyIdInfo (`setDmdSigInfo` nopSig) id
--- | This predicate says whether the 'Id' has a strict demand placed on it or
--- has a type such that it can always be evaluated strictly (i.e an
--- unlifted type, as of GHC 7.6). We need to
--- check separately whether the 'Id' has a so-called \"strict type\" because if
--- the demand for the given @id@ hasn't been computed yet but @id@ has a strict
--- type, we still want @isStrictId id@ to be @True at .
+-- | `isStrictId` says whether either
+-- (a) the 'Id' has a strict demand placed on it or
+-- (b) definitely has a \"strict type\", such that it can always be
+-- evaluated strictly (i.e an unlifted type)
+-- We need to check (b) as well as (a), because when the demand for the
+-- given `id` hasn't been computed yet but `id` has a strict
+-- type, we still want `isStrictId id` to be `True`.
+-- Returns False if the type is levity polymorphic; False is always safe.
isStrictId :: Id -> Bool
isStrictId id
| assertPpr (isId id) (text "isStrictId: not an id: " <+> ppr id) $
=====================================
testsuite/tests/simplCore/should_compile/T22761.hs
=====================================
@@ -0,0 +1,40 @@
+module T22761 where
+
+import T22761a
+
+newtype Mod m = Mod m deriving Num
+
+gcdExt :: Integer -> (Integer, Integer)
+gcdExt x = go 0 x
+ where
+ go !_ 0 = (1, 1)
+ go r _ = go r r
+
+pow :: (Num m) => Mod m -> Mod m
+pow x = x*x*x
+{-# NOINLINE [1] pow #-}
+{-# RULES
+"powMod/3/Int" forall x. pow x = x*x*x
+#-}
+
+
+-- GHC puts `boo1` after `wom1` (since they don't appear connected)
+-- Then { wom1 = foo True } rewrites to { wom1 = boo False }
+-- so we need to do glomming. And that triggers the bug
+-- in the RULE for `pow`!
+--
+-- wom2/boo2 are there to still elicit the bug if
+-- GHC reverses its default ordering
+
+{-# RULES
+"wombat1" foo True = boo1 False
+#-}
+
+wom1 = foo True
+boo1 x = x
+
+{-# RULES
+"wombat2" foo True = boo2 False
+#-}
+boo2 x = x
+wom2 = foo True
=====================================
testsuite/tests/simplCore/should_compile/T22761a.hs
=====================================
@@ -0,0 +1,4 @@
+module T22761a where
+
+{-# NOINLINE [0] foo #-}
+foo x = x
=====================================
testsuite/tests/simplCore/should_compile/all.T
=====================================
@@ -471,5 +471,6 @@ test('T22611', [when(wordsize(32), skip), grep_errmsg(r'\$salterF') ], compile,
test('T22715_2', normal, multimod_compile, ['T22715_2', '-v0 -O -fspecialise-aggressively'])
test('T22802', normal, compile, ['-O'])
test('T15205', normal, compile, ['-O -ddump-simpl -dno-typeable-binds -dsuppress-uniques'])
+test('T22761', normal, multimod_compile, ['T22761', '-O2 -v0'])
test('RewriteHigherOrderPatterns', normal, compile, ['-O -ddump-rule-rewrites -dsuppress-all -dsuppress-uniques'])
View it on GitLab: https://gitlab.haskell.org/ghc/ghc/-/compare/d4a099d28f3ba9f4df563083b3f2014d6d154a76...f8370c8b77ba1a7db7db0474139ac70565e2b0ba
--
View it on GitLab: https://gitlab.haskell.org/ghc/ghc/-/compare/d4a099d28f3ba9f4df563083b3f2014d6d154a76...f8370c8b77ba1a7db7db0474139ac70565e2b0ba
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