floatExposesHNF,
- mkCoTyLamTryingEta, mkCoLamTryingEta,
+ etaCoreExpr, mkRhsTyLam,
etaExpandCount,
- mkIdentityAlts,
-
simplIdWantsToBeINLINEd,
- type_ok_for_let_to_case
+ singleConstructorType, typeOkForCase
) where
-IMPORT_Trace -- ToDo: rm (debugging)
-import Pretty
-
-import SimplEnv
-import SimplMonad
+IMP_Ubiq(){-uitous-}
+#if defined(__GLASGOW_HASKELL__) && __GLASGOW_HASKELL__ <= 201
+IMPORT_DELOOPER(SmplLoop) -- paranoia checking
+#endif
import BinderInfo
-
-import PrelInfo ( primOpIsCheap, realWorldStateTy,
- buildId, augmentId
- IF_ATTACK_PRAGMAS(COMMA realWorldTy)
- IF_ATTACK_PRAGMAS(COMMA tagOf_PrimOp)
- IF_ATTACK_PRAGMAS(COMMA pprPrimOp)
- )
-import Type ( extractTyVarsFromTy, getTyVarMaybe, isPrimType,
- splitTypeWithDictsAsArgs, maybeDataTyCon,
- applyTy, isFunType, TyVar, TyVarTemplate
+import CmdLineOpts ( opt_DoEtaReduction, SimplifierSwitch(..) )
+import CoreSyn
+import CoreUnfold ( SimpleUnfolding, mkFormSummary, exprIsTrivial, FormSummary(..) )
+import Id ( idType, isBottomingId, addInlinePragma, addIdDemandInfo,
+ idWantsToBeINLINEd, dataConArgTys, SYN_IE(Id),
+ getIdArity, GenId{-instance Eq-}
)
-import Id ( getInstantiatedDataConSig, isDataCon, idType,
- getIdArity, isBottomingId, idWantsToBeINLINEd,
- DataCon(..), Id
+import IdInfo ( ArityInfo(..), DemandInfo )
+import Maybes ( maybeToBool )
+import PrelVals ( augmentId, buildId )
+import PrimOp ( primOpIsCheap )
+import SimplEnv
+import SimplMonad
+import Type ( tyVarsOfType, mkForAllTys, mkTyVarTys, isPrimType, getTyVar_maybe,
+ maybeAppDataTyConExpandingDicts, SYN_IE(Type)
)
-import IdInfo
-import CmdLineOpts ( SimplifierSwitch(..) )
-import Maybes ( maybeToBool, Maybe(..) )
-import Outputable -- isExported ...
-import Util
+import TyCon ( isDataTyCon )
+import TysWiredIn ( realWorldStateTy )
+import TyVar ( elementOfTyVarSet,
+ GenTyVar{-instance Eq-} )
+import Util ( isIn, panic, assertPanic )
+
\end{code}
:: Bool -- Float let(rec)s out of rhs
-> Bool -- Float cheap primops out of rhs
-> Bool -- OK to duplicate code
- -> GenCoreExpr bdr Id
+ -> GenCoreExpr bdr Id tyvar uvar
-> Bool
floatExposesHNF float_lets float_primops ok_to_dup rhs
= try rhs
where
- try (Case (Prim _ _ _) (PrimAlts alts deflt) )
+ try (Case (Prim _ _) (PrimAlts alts deflt) )
| float_primops && (null alts || ok_to_dup)
= or (try_deflt deflt : map try_alt alts)
-- because it *will* become one.
-- likewise for `augment g h'
--
- try (App (CoTyApp (Var bld) _) _) | bld == buildId = True
- try (App (App (CoTyApp (Var bld) _) _) _) | bld == augmentId = True
+ try (App (App (Var bld) _) _) | bld == buildId = True
+ try (App (App (App (Var aug) _) _) _) | aug == augmentId = True
- try other = manifestlyWHNF other
- {- but *not* necessarily "manifestlyBottom other"...
+ try other = case mkFormSummary other of
+ VarForm -> True
+ ValueForm -> True
+ other -> False
+ {- but *not* necessarily "BottomForm"...
We may want to float a let out of a let to expose WHNFs,
but to do that to expose a "bottom" is a Bad Idea:
to allocate it eagerly as that's a waste.
-}
- try_alt (lit,rhs) = try rhs
+ try_alt (lit,rhs) = try rhs
try_deflt NoDefault = False
try_deflt (BindDefault _ rhs) = try rhs
\end{code}
-Eta reduction on ordinary lambdas
-~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
-We have a go at doing
+Local tyvar-lifting
+~~~~~~~~~~~~~~~~~~~
+mkRhsTyLam tries this transformation, when the big lambda appears as
+the RHS of a let(rec) binding:
+
+ /\abc -> let(rec) x = e in b
+ ==>
+ let(rec) x' = /\abc -> let x = x' a b c in e
+ in
+ /\abc -> let x = x' a b c in b
+
+This is good because it can turn things like:
+
+ let f = /\a -> letrec g = ... g ... in g
+into
+ letrec g' = /\a -> ... g' a ...
+ in
+ let f = /\ a -> f a
+
+which is better. In effect, it means that big lambdas don't impede
+let-floating.
+
+This optimisation is CRUCIAL in eliminating the junk introduced by
+desugaring mutually recursive definitions. Don't eliminate it lightly!
+
+So far as the implemtation is concerned:
+
+ Invariant: go F e = /\tvs -> F e
+
+ Equalities:
+ go F (Let x=e in b)
+ = Let x' = /\tvs -> F e
+ in
+ go G b
+ where
+ G = F . Let x = x' tvs
+
+ go F (Letrec xi=ei in b)
+ = Letrec {xi' = /\tvs -> G ei}
+ in
+ go G b
+ where
+ G = F . Let {xi = xi' tvs}
+
+\begin{code}
+mkRhsTyLam [] body = returnSmpl body
- \ x y -> f x y ===> f
+mkRhsTyLam tyvars body
+ = go (\x -> x) body
+ where
+ tyvar_tys = mkTyVarTys tyvars
+
+ go fn (Let bind@(NonRec var rhs) body) | exprIsTrivial rhs
+ = go (fn . Let bind) body
+
+ go fn (Let bind@(NonRec var rhs) body)
+ = mk_poly var `thenSmpl` \ (var', rhs') ->
+ go (fn . Let (mk_silly_bind var rhs')) body `thenSmpl` \ body' ->
+ returnSmpl (Let (NonRec var' (mkTyLam tyvars (fn rhs))) body')
+
+ go fn (Let (Rec prs) body)
+ = mapAndUnzipSmpl mk_poly vars `thenSmpl` \ (vars', rhss') ->
+ let
+ gn body = fn $ foldr Let body (zipWith mk_silly_bind vars rhss')
+ in
+ go gn body `thenSmpl` \ body' ->
+ returnSmpl (Let (Rec (vars' `zip` [mkTyLam tyvars (gn rhs) | rhs <- rhss])) body')
+ where
+ (vars,rhss) = unzip prs
+
+ go fn body = returnSmpl (mkTyLam tyvars (fn body))
+
+ mk_poly var
+ = newId (mkForAllTys tyvars (idType var)) `thenSmpl` \ poly_id ->
+ returnSmpl (poly_id, mkTyApp (Var poly_id) tyvar_tys)
+
+ mk_silly_bind var rhs = NonRec (addInlinePragma var) rhs
+ -- The addInlinePragma is really important! If we don't say
+ -- INLINE on these silly little bindings then look what happens!
+ -- Suppose we start with:
+ --
+ -- x = let g = /\a -> \x -> f x x
+ -- in
+ -- /\ b -> let g* = g b in E
+ --
+ -- Then: * the binding for g gets floated out
+ -- * but then it gets inlined into the rhs of g*
+ -- * then the binding for g* is floated out of the /\b
+ -- * so we're back to square one
+ -- The silly binding for g* must be INLINE, so that no inlining
+ -- will happen in its RHS.
+\end{code}
+
+Eta reduction
+~~~~~~~~~~~~~
+@etaCoreExpr@ trys an eta reduction at the top level of a Core Expr.
+
+e.g. \ x y -> f x y ===> f
+
+It is used
+ a) Before constructing an Unfolding, to
+ try to make the unfolding smaller;
+ b) In tidyCoreExpr, which is done just before converting to STG.
But we only do this if it gets rid of a whole lambda, not part.
The idea is that lambdas are often quite helpful: they indicate
gives rise to a recursive function for the list comprehension, and
f turns out to be just a single call to this recursive function.
-\begin{code}
-mkCoLamTryingEta :: [Id] -- Args to the lambda
- -> CoreExpr -- Lambda body
- -> CoreExpr
+Doing eta on type lambdas is useful too:
+
+ /\a -> <expr> a ===> <expr>
-mkCoLamTryingEta [] body = body
+where <expr> doesn't mention a.
+This is sometimes quite useful, because we can get the sequence:
-mkCoLamTryingEta orig_ids body
- = reduce_it (reverse orig_ids) body
- where
- bale_out = mkValLam orig_ids body
+ f ab d = let d1 = ...d... in
+ letrec f' b x = ...d...(f' b)... in
+ f' b
+specialise ==>
- reduce_it [] residual
- | residual_ok residual = residual
- | otherwise = bale_out
+ f.Int b = letrec f' b x = ...dInt...(f' b)... in
+ f' b
- reduce_it (id:ids) (App fun (VarArg arg))
- | id == arg
- && idType id /= realWorldStateTy
- -- *never* eta-reduce away a PrimIO state token! (WDP 94/11)
- = reduce_it ids fun
+float ==>
- reduce_it ids other = bale_out
+ f' b x = ...dInt...(f' b)...
+ f.Int b = f' b
- is_elem = isIn "mkCoLamTryingEta"
+Now we really want to simplify to
+
+ f.Int = f'
+
+and then replace all the f's with f.Ints.
+
+N.B. We are careful not to partially eta-reduce a sequence of type
+applications since this breaks the specialiser:
+
+ /\ a -> f Char# a =NO=> f Char#
+
+\begin{code}
+etaCoreExpr :: CoreExpr -> CoreExpr
+
+
+etaCoreExpr expr@(Lam bndr body)
+ | opt_DoEtaReduction
+ = case etaCoreExpr body of
+ App fun arg | eta_match bndr arg &&
+ residual_ok fun
+ -> fun -- Eta
+ other -> expr -- Can't eliminate it, so do nothing at all
+ where
+ eta_match (ValBinder v) (VarArg v') = v == v'
+ eta_match (TyBinder tv) (TyArg ty) = case getTyVar_maybe ty of
+ Nothing -> False
+ Just tv' -> tv == tv'
+ eta_match bndr arg = False
- -----------
residual_ok :: CoreExpr -> Bool -- Checks for type application
- -- and function not one of the
- -- bound vars
- residual_ok (CoTyApp fun ty) = residual_ok fun
- residual_ok (Var v) = not (v `is_elem` orig_ids) -- Fun mustn't be one of
- -- the bound ids
- residual_ok other = False
+ -- and function not one of the
+ -- bound vars
+
+ (VarArg v) `mentions` (ValBinder v') = v == v'
+ (TyArg ty) `mentions` (TyBinder tv) = tv `elementOfTyVarSet` tyVarsOfType ty
+ bndr `mentions` arg = False
+
+ residual_ok (Var v)
+ = not (VarArg v `mentions` bndr)
+ residual_ok (App fun arg)
+ | arg `mentions` bndr = False
+ | otherwise = residual_ok fun
+ residual_ok (Coerce coercion ty body)
+ | TyArg ty `mentions` bndr = False
+ | otherwise = residual_ok body
+
+ residual_ok other = False -- Safe answer
+ -- This last clause may seem conservative, but consider:
+ -- primops, constructors, and literals, are impossible here
+ -- let and case are unlikely (the argument would have been floated inside)
+ -- SCCs we probably want to be conservative about (not sure, but it's safe to be)
+
+etaCoreExpr expr = expr -- The common case
\end{code}
+
Eta expansion
~~~~~~~~~~~~~
E ===> (\x1::t1 x1::t2 ... xn::tn -> E x1 x2 ... xn)
-is a safe transformation. In particular, the transformation should not
-cause work to be duplicated, unless it is ``cheap'' (see @manifestlyCheap@ below).
+is a safe transformation. In particular, the transformation should
+not cause work to be duplicated, unless it is ``cheap'' (see
+@manifestlyCheap@ below).
-@etaExpandCount@ errs on the conservative side. It is always safe to return 0.
+@etaExpandCount@ errs on the conservative side. It is always safe to
+return 0.
An application of @error@ is special, because it can absorb as many
-arguments as you care to give it. For this special case we return 100,
-to represent "infinity", which is a bit of a hack.
+arguments as you care to give it. For this special case we return
+100, to represent "infinity", which is a bit of a hack.
\begin{code}
-etaExpandCount :: GenCoreExpr bdr Id
- -> Int -- Number of extra args you can safely abstract
+etaExpandCount :: GenCoreExpr bdr Id tyvar uvar
+ -> Int -- Number of extra args you can safely abstract
-etaExpandCount (Lam _ body)
+etaExpandCount (Lam (ValBinder _) body)
= 1 + etaExpandCount body
etaExpandCount (Let bind body)
| manifestlyCheap scrut
= minimum [etaExpandCount rhs | rhs <- rhssOfAlts alts]
-etaExpandCount (App fun _) = case etaExpandCount fun of
- 0 -> 0
- n -> n-1 -- Knock off one
-
-etaExpandCount fun@(CoTyApp _ _) = eta_fun fun
etaExpandCount fun@(Var _) = eta_fun fun
+etaExpandCount (App fun arg)
+ | notValArg arg = eta_fun fun
+ | otherwise = case etaExpandCount fun of
+ 0 -> 0
+ n -> n-1 -- Knock off one
-etaExpandCount other = 0 -- Give up
+etaExpandCount other = 0 -- Give up
-- Lit, Con, Prim,
- -- CoTyLam,
+ -- non-val Lam,
-- Scc (pessimistic; ToDo),
-- Let with non-whnf rhs(s),
-- Case with non-whnf scrutinee
-eta_fun :: GenCoreExpr bdr Id -- The function
- -> Int -- How many args it can safely be applied to
+-----------------------------
+eta_fun :: GenCoreExpr bdr Id tv uv -- The function
+ -> Int -- How many args it can safely be applied to
-eta_fun (CoTyApp fun ty) = eta_fun fun
+eta_fun (App fun arg) | notValArg arg = eta_fun fun
eta_fun expr@(Var v)
- | isBottomingId v -- Bottoming ids have "infinite arity"
- = 10000 -- Blargh. Infinite enough!
+ | isBottomingId v -- Bottoming ids have "infinite arity"
+ = 10000 -- Blargh. Infinite enough!
-eta_fun expr@(Var v)
- | maybeToBool arity_maybe -- We know the arity
- = arity
- where
- arity_maybe = arityMaybe (getIdArity v)
- arity = case arity_maybe of { Just arity -> arity }
+eta_fun expr@(Var v) = idMinArity v
-eta_fun other = 0 -- Give up
+eta_fun other = 0 -- Give up
\end{code}
@manifestlyCheap@ looks at a Core expression and returns \tr{True} if
where op is a cheap primitive operator
\begin{code}
-manifestlyCheap :: GenCoreExpr bndr Id -> Bool
+manifestlyCheap :: GenCoreExpr bndr Id tv uv -> Bool
-manifestlyCheap (Var _) = True
-manifestlyCheap (Lit _) = True
-manifestlyCheap (Con _ _ _) = True
-manifestlyCheap (Lam _ _) = True
-manifestlyCheap (CoTyLam _ e) = manifestlyCheap e
-manifestlyCheap (SCC _ e) = manifestlyCheap e
-
-manifestlyCheap (Prim op _ _) = primOpIsCheap op
+manifestlyCheap (Var _) = True
+manifestlyCheap (Lit _) = True
+manifestlyCheap (Con _ _) = True
+manifestlyCheap (SCC _ e) = manifestlyCheap e
+manifestlyCheap (Coerce _ _ e) = manifestlyCheap e
+manifestlyCheap (Lam x e) = if isValBinder x then True else manifestlyCheap e
+manifestlyCheap (Prim op _) = primOpIsCheap op
manifestlyCheap (Let bind body)
= manifestlyCheap body && all manifestlyCheap (rhssOfBind bind)
= manifestlyCheap scrut && all manifestlyCheap (rhssOfAlts alts)
manifestlyCheap other_expr -- look for manifest partial application
- = case (collectArgs other_expr) of { (fun, args) ->
+ = case (collectArgs other_expr) of { (fun, _, _, vargs) ->
case fun of
- Var f | isBottomingId f -> True -- Application of a function which
- -- always gives bottom; we treat this as
- -- a WHNF, because it certainly doesn't
- -- need to be shared!
+ Var f | isBottomingId f -> True -- Application of a function which
+ -- always gives bottom; we treat this as
+ -- a WHNF, because it certainly doesn't
+ -- need to be shared!
Var f -> let
- num_val_args = length [ a | (ValArg a) <- args ]
- in
- num_val_args == 0 || -- Just a type application of
- -- a variable (f t1 t2 t3)
- -- counts as WHNF
- case (arityMaybe (getIdArity f)) of
- Nothing -> False
- Just arity -> num_val_args < arity
+ num_val_args = length vargs
+ in
+ num_val_args == 0 || -- Just a type application of
+ -- a variable (f t1 t2 t3)
+ -- counts as WHNF
+ num_val_args < idMinArity f
_ -> False
}
-\end{code}
-
-Eta reduction on type lambdas
-~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
-We have a go at doing
-
- /\a -> <expr> a ===> <expr>
-
-where <expr> doesn't mention a.
-This is sometimes quite useful, because we can get the sequence:
-
- f ab d = let d1 = ...d... in
- letrec f' b x = ...d...(f' b)... in
- f' b
-specialise ==>
-
- f.Int b = letrec f' b x = ...dInt...(f' b)... in
- f' b
-
-float ==>
-
- f' b x = ...dInt...(f' b)...
- f.Int b = f' b
-
-Now we really want to simplify to
-
- f.Int = f'
-and then replace all the f's with f.Ints.
-
-N.B. We are careful not to partially eta-reduce a sequence of type
-applications since this breaks the specialiser:
-
- /\ a -> f Char# a =NO=> f Char#
-
-\begin{code}
-mkCoTyLamTryingEta :: [TyVar] -> CoreExpr -> CoreExpr
-
-mkCoTyLamTryingEta tyvars tylam_body
- = if
- tyvars == tyvar_args && -- Same args in same order
- check_fun fun -- Function left is ok
- then
- -- Eta reduction worked
- fun
- else
- -- The vastly common case
- mkCoTyLam tyvars tylam_body
- where
- (tyvar_args, fun) = strip_tyvar_args [] tylam_body
-
- strip_tyvar_args args_so_far tyapp@(CoTyApp fun ty)
- = case getTyVarMaybe ty of
- Just tyvar_arg -> strip_tyvar_args (tyvar_arg:args_so_far) fun
- Nothing -> (args_so_far, tyapp)
-
- strip_tyvar_args args_so_far fun
- = (args_so_far, fun)
-
- check_fun (Var f) = True -- Claim: tyvars not mentioned by type of f
- check_fun other = False
\end{code}
-Let to case
-~~~~~~~~~~~
-
-Given a type generate the case alternatives
-
- C a b -> C a b
-
-if there's one constructor, or
-
- x -> x
-
-if there's many, or if it's a primitive type.
-
-
-\begin{code}
-mkIdentityAlts
- :: Type -- type of RHS
- -> SmplM InAlts -- result
-
-mkIdentityAlts rhs_ty
- | isPrimType rhs_ty
- = newId rhs_ty `thenSmpl` \ binder ->
- returnSmpl (PrimAlts [] (BindDefault (binder, bad_occ_info) (Var binder)))
-
- | otherwise
- = case maybeDataTyCon rhs_ty of
- Just (tycon, ty_args, [data_con]) -> -- algebraic type suitable for unpacking
- let
- (_,inst_con_arg_tys,_) = getInstantiatedDataConSig data_con ty_args
- in
- newIds inst_con_arg_tys `thenSmpl` \ new_bindees ->
- let
- new_binders = [ (b, bad_occ_info) | b <- new_bindees ]
- in
- returnSmpl (
- AlgAlts
- [(data_con, new_binders, Con data_con ty_args (map VarArg new_bindees))]
- NoDefault
- )
-
- _ -> -- Multi-constructor or abstract algebraic type
- newId rhs_ty `thenSmpl` \ binder ->
- returnSmpl (AlgAlts [] (BindDefault (binder,bad_occ_info) (Var binder)))
- where
- bad_occ_info = ManyOcc 0 -- Non-committal!
-\end{code}
\begin{code}
simplIdWantsToBeINLINEd :: Id -> SimplEnv -> Bool
simplIdWantsToBeINLINEd id env
- = if switchIsSet env IgnoreINLINEPragma
+ = {- We used to arrange that in the final simplification pass we'd switch
+ off all INLINE pragmas, so that we'd inline workers back into the
+ body of their wrapper if the wrapper hadn't itself been inlined by then.
+ This occurred especially for methods in dictionaries.
+
+ We no longer do this:
+ a) there's a good chance that the exported wrapper will get
+ inlined in some importing scope, in which case we don't
+ want to lose the w/w idea.
+
+ b) The occurrence analyser must agree about what has an
+ INLINE pragma. Not hard, but delicate.
+
+ c) if the worker gets inlined we have to tell the wrapepr
+ that it's no longer a wrapper, else the interface file stuff
+ asks for a worker that no longer exists.
+
+ if switchIsSet env IgnoreINLINEPragma
then False
- else idWantsToBeINLINEd id
-
-type_ok_for_let_to_case :: Type -> Bool
-
-type_ok_for_let_to_case ty
- = case maybeDataTyCon ty of
- Nothing -> False
- Just (tycon, ty_args, []) -> False
- Just (tycon, ty_args, non_null_data_cons) -> True
- -- Null data cons => type is abstract
+ else
+ -}
+
+ idWantsToBeINLINEd id
+
+idMinArity id = case getIdArity id of
+ UnknownArity -> 0
+ ArityAtLeast n -> n
+ ArityExactly n -> n
+
+singleConstructorType :: Type -> Bool
+singleConstructorType ty
+ = case (maybeAppDataTyConExpandingDicts ty) of
+ Just (tycon, ty_args, [con]) | isDataTyCon tycon -> True
+ other -> False
+
+typeOkForCase :: Type -> Bool
+typeOkForCase ty
+ = case (maybeAppDataTyConExpandingDicts ty) of
+ Just (tycon, ty_args, []) -> False
+ Just (tycon, ty_args, non_null_data_cons) | isDataTyCon tycon -> True
+ other -> False
+ -- Null data cons => type is abstract, which code gen can't
+ -- currently handle. (ToDo: when return-in-heap is universal we
+ -- don't need to worry about this.)
\end{code}