import Type hiding ( substTy, extendTvSubst )
import SimplEnv
import SimplUtils
-import MkId ( rUNTIME_ERROR_ID )
import FamInstEnv ( FamInstEnv )
import Id
+import MkId ( mkImpossibleExpr, seqId )
import Var
import IdInfo
import Coercion
import CoreUtils
import CoreArity ( exprArity )
import Rules ( lookupRule, getRules )
-import BasicTypes ( isMarkedStrict )
-import CostCentre ( currentCCS )
+import BasicTypes ( isMarkedStrict, Arity )
+import CostCentre ( currentCCS, pushCCisNop )
import TysPrim ( realWorldStatePrimTy )
import PrelInfo ( realWorldPrimId )
import BasicTypes ( TopLevelFlag(..), isTopLevel,
addNonRecWithUnf env new_bndr rhs unfolding wkr
= ASSERT( isId new_bndr )
WARN( new_arity < old_arity || new_arity < dmd_arity,
- (ppr final_id <+> ppr old_arity <+> ppr new_arity <+> ppr dmd_arity) $$ ppr rhs )
+ (ptext (sLit "Arity decrease:") <+> ppr final_id <+> ppr old_arity
+ <+> ppr new_arity <+> ppr dmd_arity) $$ ppr rhs )
+ -- Note [Arity decrease]
final_id `seq` -- This seq forces the Id, and hence its IdInfo,
-- and hence any inner substitutions
addNonRec env final_id rhs
final_id = new_bndr `setIdInfo` final_info
\end{code}
+Note [Arity decrease]
+~~~~~~~~~~~~~~~~~~~~~
+Generally speaking the arity of a binding should not decrease. But it *can*
+legitimately happen becuase 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.
%************************************************************************
seqType new_ty `seq` return new_ty
where
new_ty = substTy env ty
+
+---------------------------------
+simplCoercion :: SimplEnv -> InType -> SimplM OutType
+simplCoercion env co
+ = do { co' <- simplType env co
+ ; return (optCoercion co') }
\end{code}
simplCast :: SimplEnv -> InExpr -> Coercion -> SimplCont
-> SimplM (SimplEnv, OutExpr)
simplCast env body co0 cont0
- = do { co1 <- simplType env co0
+ = do { co1 <- simplCoercion env co0
; simplExprF env body (addCoerce co1 cont0) }
where
addCoerce co cont = add_coerce co (coercionKind co) cont
| (_l1, t1) <- coercionKind co2
-- e |> (g1 :: S1~L) |> (g2 :: L~T1)
-- ==>
- -- e, if T1=T2
- -- e |> (g1 . g2 :: T1~T2) otherwise
+ -- e, if S1=T1
+ -- e |> (g1 . g2 :: S1~T1) otherwise
--
-- For example, in the initial form of a worker
-- we may find (coerce T (coerce S (\x.e))) y
simplNote :: SimplEnv -> Note -> CoreExpr -> SimplCont
-> SimplM (SimplEnv, OutExpr)
simplNote env (SCC cc) e cont
+ | pushCCisNop cc (getEnclosingCC env) -- scc "f" (...(scc "f" e)...)
+ = simplExprF env e cont -- ==> scc "f" (...e...)
+ | otherwise
= do { e' <- simplExpr (setEnclosingCC env currentCCS) e
; rebuild env (mkSCC cc e') cont }
completeCall :: SimplEnv -> Id -> SimplCont -> SimplM (SimplEnv, OutExpr)
completeCall env var cont
- = do { dflags <- getDOptsSmpl
- ; let (args,call_cont) = contArgs cont
+ = do { let (args,call_cont) = contArgs cont
-- The args are OutExprs, obtained by *lazily* substituting
-- in the args found in cont. These args are only examined
-- to limited depth (unless a rule fires). But we must do
-- We used to use the black-listing mechanism to ensure that inlining of
-- the wrapper didn't occur for things that have specialisations till a
-- later phase, so but now we just try RULES first
- --
- -- 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
- ; rule_base <- getSimplRules
- ; let in_scope = getInScope env
- rules = getRules rule_base var
- maybe_rule = case activeRule dflags env of
- Nothing -> Nothing -- No rules apply
- Just act_fn -> lookupRule act_fn in_scope
- var args rules
- ; case maybe_rule of {
- Just (rule, rule_rhs) -> do
- tick (RuleFired (ru_name rule))
- (if dopt Opt_D_dump_rule_firings dflags then
- pprTrace "Rule fired" (vcat [
- text "Rule:" <+> ftext (ru_name rule),
- text "Before:" <+> ppr var <+> sep (map pprParendExpr args),
- text "After: " <+> pprCoreExpr rule_rhs,
- text "Cont: " <+> ppr call_cont])
- else
- id) $
- simplExprF env rule_rhs (dropArgs (ruleArity rule) cont)
+ --
+ -- See also Note [Rules for recursive functions]
+ ; mb_rule <- tryRules env var args call_cont
+ ; case mb_rule of {
+ Just (n_args, rule_rhs) -> simplExprF env rule_rhs (dropArgs n_args cont) ;
-- The ruleArity says how many args the rule consumed
+ ; Nothing -> do -- No rules
- ; Nothing -> do -- No rules
------------- Next try inlining ----------------
- { let arg_infos = [interestingArg arg | arg <- args, isValArg arg]
+ { dflags <- getDOptsSmpl
+ ; let arg_infos = [interestingArg arg | arg <- args, isValArg arg]
n_val_args = length arg_infos
interesting_cont = interestingCallContext call_cont
active_inline = activeInline env var
discard the entire application and replace it with (error "foo"). Getting
all this at once is TOO HARD!
+
+%************************************************************************
+%* *
+ Rewrite rules
+%* *
+%************************************************************************
+
+\begin{code}
+tryRules :: SimplEnv -> Id -> [OutExpr] -> SimplCont
+ -> SimplM (Maybe (Arity, CoreExpr)) -- The arity is the number of
+ -- args consumed by the rule
+tryRules env fn args call_cont
+ = do { dflags <- getDOptsSmpl
+ ; rule_base <- getSimplRules
+ ; let in_scope = getInScope env
+ rules = getRules rule_base fn
+ maybe_rule = case activeRule dflags env of
+ Nothing -> Nothing -- No rules apply
+ Just act_fn -> lookupRule act_fn in_scope
+ fn args rules
+ ; case (rules, maybe_rule) of {
+ ([], _) -> return Nothing ;
+ (_, Nothing) -> return Nothing ;
+ (_, Just (rule, rule_rhs)) -> do
+
+ { tick (RuleFired (ru_name rule))
+ ; (if dopt Opt_D_dump_rule_firings dflags then
+ pprTrace "Rule fired" (vcat [
+ text "Rule:" <+> ftext (ru_name rule),
+ text "Before:" <+> ppr fn <+> sep (map pprParendExpr args),
+ text "After: " <+> pprCoreExpr rule_rhs,
+ text "Cont: " <+> ppr call_cont])
+ else
+ id) $
+ return (Just (ruleArity rule, rule_rhs)) }}}
+\end{code}
+
+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 cse expression
---------------------------------------------------------
-- Eliminate the case if possible
-rebuildCase :: SimplEnv
- -> OutExpr -- Scrutinee
- -> InId -- Case binder
- -> [InAlt] -- Alternatives (inceasing order)
- -> SimplCont
- -> SimplM (SimplEnv, OutExpr)
+rebuildCase, reallyRebuildCase
+ :: SimplEnv
+ -> OutExpr -- Scrutinee
+ -> InId -- Case binder
+ -> [InAlt] -- Alternatives (inceasing order)
+ -> SimplCont
+ -> SimplM (SimplEnv, OutExpr)
--------------------------------------------------
-- 1. Eliminate the case if there's a known constructor
-- exprOkForSpeculation was intended for.
var_demanded_later _ = False
+rebuildCase env scrut case_bndr alts@[(_, bndrs, rhs)] cont
+ | all isDeadBinder (case_bndr : bndrs) -- So this is just 'seq'
+ = -- For this case, see Note [Rules for seq] in MkId
+ do { let rhs' = substExpr env rhs
+ out_args = [Type (substTy env (idType case_bndr)),
+ Type (exprType rhs'), scrut, rhs']
+ -- Lazily evaluated, so we don't do most of this
+ ; mb_rule <- tryRules env seqId out_args cont
+ ; case mb_rule of
+ Just (n_args, res) -> simplExprF (zapSubstEnv env)
+ (mkApps res (drop n_args out_args))
+ cont
+ Nothing -> reallyRebuildCase env scrut case_bndr alts cont }
+
+rebuildCase env scrut case_bndr alts cont
+ = reallyRebuildCase env scrut case_bndr alts cont
--------------------------------------------------
-- 3. Catch-all case
--------------------------------------------------
-rebuildCase env scrut case_bndr alts cont
+reallyRebuildCase env scrut case_bndr alts cont
= do { -- Prepare the continuation;
-- The new subst_env is in place
(env', dup_cont, nodup_cont) <- prepareCaseCont env alts cont
; (scrut', case_bndr', alts') <- simplAlts env' scrut case_bndr alts dup_cont
-- Check for empty alternatives
- ; if null alts' then
- -- This isn't strictly an error, although it is unusual.
- -- It's possible that the simplifer 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.
- pprTrace "mkCase: null alts" (ppr case_bndr <+> ppr scrut) $
- let res_ty' = contResultType env' (substTy env' (coreAltsType alts)) dup_cont
- lit = mkStringLit "Impossible alternative"
- in return (env', mkApps (Var rUNTIME_ERROR_ID) [Type res_ty', lit])
-
+ ; if null alts' then missingAlt env case_bndr alts cont
else do
{ case_expr <- mkCase scrut' case_bndr' alts'
knownCon env scrut con args bndr alts cont
= do { tick (KnownBranch bndr)
- ; knownAlt env scrut args bndr (findAlt con alts) cont }
+ ; case findAlt con alts of
+ Nothing -> missingAlt env bndr alts cont
+ Just alt -> knownAlt env scrut args bndr alt cont
+ }
+-------------------
knownAlt :: SimplEnv -> OutExpr -> [OutExpr]
- -> InId -> (AltCon, [CoreBndr], InExpr) -> SimplCont
+ -> InId -> InAlt -> SimplCont
-> SimplM (SimplEnv, OutExpr)
-knownAlt env scrut _ bndr (DEFAULT, bs, rhs) cont
- = ASSERT( null bs )
- do { env' <- simplNonRecX env bndr scrut
- -- This might give rise to a binding with non-atomic args
- -- like x = Node (f x) (g x)
- -- but simplNonRecX will atomic-ify it
- ; simplExprF env' rhs cont }
-
-knownAlt env scrut _ bndr (LitAlt _, bs, rhs) cont
- = ASSERT( null bs )
- do { env' <- simplNonRecX env bndr scrut
- ; simplExprF env' rhs cont }
knownAlt env scrut the_args bndr (DataAlt dc, bs, rhs) cont
= do { let n_drop_tys = length (dataConUnivTyVars dc)
bind_args _ _ _ =
pprPanic "bind_args" $ ppr dc $$ ppr bs $$ ppr the_args $$
text "scrut:" <+> ppr scrut
+
+knownAlt env scrut _ bndr (_, bs, rhs) cont
+ = ASSERT( null bs ) -- Works for LitAlt and DEFAULT
+ do { env' <- simplNonRecX env bndr scrut
+ ; simplExprF env' rhs cont }
+
+
+-------------------
+missingAlt :: SimplEnv -> Id -> [InAlt] -> SimplCont -> SimplM (SimplEnv, OutExpr)
+ -- This isn't strictly an error, although it is unusual.
+ -- It's possible that the simplifer 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 alts cont
+ = WARN( True, ptext (sLit "missingAlt") <+> ppr case_bndr )
+ return (env, mkImpossibleExpr res_ty)
+ where
+ res_ty = contResultType env (substTy env (coreAltsType alts)) cont
\end{code}
mkDupableCont env cont@(StrictBind {})
= return (env, mkBoringStop, cont)
- -- See Note [Duplicating strict continuations]
+ -- See Note [Duplicating StrictBind]
-mkDupableCont env cont@(StrictArg {})
- = return (env, mkBoringStop, cont)
- -- See Note [Duplicating strict continuations]
+mkDupableCont env (StrictArg fun cci ai cont)
+ -- See Note [Duplicating StrictArg]
+ = do { (env', dup, nodup) <- mkDupableCont env cont
+ ; (env'', fun') <- mk_dupable_call env' fun
+ ; return (env'', StrictArg fun' cci ai dup, nodup) }
+ where
+ mk_dupable_call env (Var v) = return (env, Var v)
+ mk_dupable_call env (App fun arg) = do { (env', fun') <- mk_dupable_call env fun
+ ; (env'', arg') <- makeTrivial env' arg
+ ; return (env'', fun' `App` arg') }
+ mk_dupable_call _ other = pprPanic "mk_dupable_call" (ppr other)
+ -- The invariant of StrictArg is that the first arg is always an App chain
mkDupableCont env (ApplyTo _ arg se cont)
= -- e.g. [...hole...] (...arg...)
but zapping it (as we do in mkDupableCont, the Select case) is safe, and
at worst delays the join-point inlining.
-Note [Small alterantive rhs]
+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
True -> $j s
(the \v alone is enough to make CPR happy) but I think it's rare
-Note [Duplicating strict continuations]
-~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
-Do *not* duplicate StrictBind and StritArg continuations. We gain
-nothing by propagating them into the expressions, and we do lose a
-lot. Here's an example:
- && (case x of { T -> F; F -> T }) E
+Note [Duplicating StrictArg]
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+The original plan had (where E is a big argument)
+e.g. f E [..hole..]
+ ==> let $j = \a -> f E a
+ in $j [..hole..]
+
+But this is terrible! Here's an example:
+ && E (case x of { T -> F; F -> T })
Now, && is strict so we end up simplifying the case with
an ArgOf continuation. If we let-bind it, we get
-
- let $j = \v -> && v E
+ let $j = \v -> && E v
in simplExpr (case x of { T -> F; F -> T })
(ArgOf (\r -> $j r)
And after simplifying more we get
-
- let $j = \v -> && v E
+ let $j = \v -> && E v
in case x of { T -> $j F; F -> $j T }
Which is a Very Bad Thing
+What we do now is this
+ f E [..hole..]
+ ==> let a = E
+ in f a [..hole..]
+Now if the thing in the hole is a case expression (which is when
+we'll call mkDupableCont), we'll push the function call into the
+branches, which is what we want. Now RULES for f may fire, and
+call-pattern specialisation. Here's an example from Trac #3116
+ go (n+1) (case l of
+ 1 -> bs'
+ _ -> Chunk p fpc (o+1) (l-1) bs')
+If we can push the call for 'go' inside the case, we get
+call-pattern specialisation for 'go', which is *crucial* for
+this program.
+
+Here is the (&&) example:
+ && E (case x of { T -> F; F -> T })
+ ==> let a = E in
+ case x of { T -> && a F; F -> && a T }
+Much better!
+
+Notice that
+ * Arguments to f *after* the strict one are handled by
+ the ApplyTo case of mkDupableCont. Eg
+ f [..hole..] E
+
+ * We can only do the let-binding of E because the function
+ part of a StrictArg continuation is an explicit syntax
+ tree. In earlier versions we represented it as a function
+ (CoreExpr -> CoreEpxr) which we couldn't take apart.
+
+Do *not* duplicate StrictBind and StritArg continuations. We gain
+nothing by propagating them into the expressions, and we do lose a
+lot.
+
+The desire not to duplicate is the entire reason that
+mkDupableCont returns a pair of continuations.
+
+Note [Duplicating StrictBind]
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+Unlike StrictArg, there doesn't seem anything to gain from
+duplicating a StrictBind continuation, so we don't.
+
The desire not to duplicate is the entire reason that
mkDupableCont returns a pair of continuations.
-The original plan had:
-e.g. (...strict-fn...) [...hole...]
- ==>
- let $j = \a -> ...strict-fn...
- in $j [...hole...]
Note [Single-alternative cases]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~