Unfolding, UnfoldingGuidance, -- Abstract types
noUnfolding, mkTopUnfolding, mkUnfolding, mkCompulsoryUnfolding, seqUnfolding,
- mkOtherCon, otherCons,
+ evaldUnfolding, mkOtherCon, otherCons,
unfoldingTemplate, maybeUnfoldingTemplate,
isEvaldUnfolding, isValueUnfolding, isCheapUnfolding, isCompulsoryUnfolding,
hasUnfolding, hasSomeUnfolding, neverUnfold,
couldBeSmallEnoughToInline,
certainlyWillInline,
- okToUnfoldInHiFile,
callSiteInline
) where
#include "HsVersions.h"
-import CmdLineOpts ( opt_UF_CreationThreshold,
- opt_UF_UseThreshold,
- opt_UF_FunAppDiscount,
- opt_UF_KeenessFactor,
- opt_UF_DearOp, opt_UnfoldCasms,
- DynFlags, DynFlag(..), dopt
+import StaticFlags ( opt_UF_CreationThreshold, opt_UF_UseThreshold,
+ opt_UF_FunAppDiscount, opt_UF_KeenessFactor,
+ opt_UF_DearOp,
)
+import DynFlags ( DynFlags, DynFlag(..), dopt )
import CoreSyn
import PprCore ( pprCoreExpr )
import OccurAnal ( occurAnalyseGlobalExpr )
import CoreUtils ( exprIsValue, exprIsCheap, exprIsTrivial )
import Id ( Id, idType, isId,
- idUnfolding,
- isFCallId_maybe, globalIdDetails
+ idUnfolding, globalIdDetails
)
import DataCon ( isUnboxedTupleCon )
-import Literal ( isLitLitLit, litSize )
+import Literal ( litSize )
import PrimOp ( primOpIsDupable, primOpOutOfLine )
-import ForeignCall ( okToExposeFCall )
import IdInfo ( OccInfo(..), GlobalIdDetails(..) )
import Type ( isUnLiftedType )
import PrelNames ( hasKey, buildIdKey, augmentIdKey )
| not inline -> UnfoldNever
-- A big function with an INLINE pragma must
-- have an UnfoldIfGoodArgs guidance
- | inline -> UnfoldIfGoodArgs n_val_binders
+ | otherwise -> UnfoldIfGoodArgs n_val_binders
(map (const 0) val_binders)
max_inline_size 0
where
rhs_size = foldr (addSize . size_up . snd) sizeZero pairs
- size_up (Case (Var v) _ alts)
+ size_up (Case (Var v) _ _ alts)
| v `elem` top_args -- We are scrutinising an argument variable
=
{- I'm nuking this special case; BUT see the comment with case alternatives.
-- into h; if we inline f first, while it looks small, then g's
-- wrapper will get inlined later anyway. To avoid this nasty
-- ordering difference, we make (case a of (x,y) -> ...),
- -- *where a is one of the arguments* look free.
+ -- *where a is one of the arguments* look free.
other ->
-}
-- The 1+ is a little discount for reduced allocation in the caller
alts_size tot_size _ = tot_size
-
- size_up (Case e _ alts) = nukeScrutDiscount (size_up e) `addSize`
- foldr (addSize . size_up_alt) sizeZero alts
+-- gaw 2004
+ size_up (Case e _ _ alts) = nukeScrutDiscount (size_up e) `addSize`
+ foldr (addSize . size_up_alt) sizeZero alts
-- We don't charge for the case itself
-- It's a strict thing, and the price of the call
-- is paid by scrut. Also consider
= False
\end{code}
-@okToUnfoldInHifile@ is used when emitting unfolding info into an interface
-file to determine whether an unfolding candidate really should be unfolded.
-The predicate is needed to prevent @_casm_@s (+ lit-lits) from being emitted
-into interface files.
-
-The reason for inlining expressions containing _casm_s into interface files
-is that these fragments of C are likely to mention functions/#defines that
-will be out-of-scope when inlined into another module. This is not an
-unfixable problem for the user (just need to -#include the approp. header
-file), but turning it off seems to the simplest thing to do.
-
-\begin{code}
-okToUnfoldInHiFile :: CoreExpr -> Bool
-okToUnfoldInHiFile e = opt_UnfoldCasms || go e
- where
- -- Race over an expression looking for CCalls..
- go (Var v) = case isFCallId_maybe v of
- Just fcall -> okToExposeFCall fcall
- Nothing -> True
- go (Lit lit) = not (isLitLitLit lit)
- go (App fun arg) = go fun && go arg
- go (Lam _ body) = go body
- go (Let binds body) = and (map go (body :rhssOfBind binds))
- go (Case scrut bndr alts) = and (map go (scrut:rhssOfAlts alts)) &&
- not (any isLitLitLit [ lit | (LitAlt lit, _, _) <- alts ])
- go (Note _ body) = go body
- go (Type _) = True
-\end{code}
-
-
%************************************************************************
%* *
\subsection{callSiteInline}
| otherwise
= case guidance of
- UnfoldNever -> False ;
+ UnfoldNever -> False
UnfoldIfGoodArgs n_vals_wanted arg_discounts size res_discount
| enough_args && size <= (n_vals_wanted + 1)
computeDiscount n_vals_wanted arg_discounts res_discount arg_infos result_used
-- We multiple the raw discounts (args_discount and result_discount)
-- ty opt_UnfoldingKeenessFactor because the former have to do with
- -- *size* whereas the discounts imply that there's some extra
- -- *efficiency* to be gained (e.g. beta reductions, case reductions)
+ -- *size* whereas the discounts imply that there's some extra
+ -- *efficiency* to be gained (e.g. beta reductions, case reductions)
-- by inlining.
-- we also discount 1 for each argument passed, because these will