the scrutinee of the case, and we can inline it.
\begin{code}
+{-# OPTIONS -w #-}
+-- The above warning supression flag is a temporary kludge.
+-- While working on this module you are encouraged to remove it and fix
+-- any warnings in the module. See
+-- http://hackage.haskell.org/trac/ghc/wiki/Commentary/CodingStyle#Warnings
+-- for details
+
module SetLevels (
setLevels,
import CoreSyn
import DynFlags ( FloatOutSwitches(..) )
-import CoreUtils ( exprType, exprIsTrivial, exprIsCheap, mkPiTypes )
+import CoreUtils ( exprType, exprIsTrivial, mkPiTypes )
import CoreFVs -- all of it
import CoreSubst ( Subst, emptySubst, extendInScope, extendIdSubst,
cloneIdBndr, cloneRecIdBndrs )
context @Level 0 0@.
-InlineCtxt
-~~~~~~~~~~
+Note [FloatOut inside INLINE]
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
@InlineCtxt@ very similar to @Level 0 0@, but is used for one purpose:
to say "don't float anything out of here". That's exactly what we
want for the body of an INLINE, where we don't want to float anything
= lvlExpr ctxt_lvl env expr `thenLvl` \ expr' ->
returnLvl (Note note expr')
+lvlExpr ctxt_lvl env (_, AnnCast expr co)
+ = lvlExpr ctxt_lvl env expr `thenLvl` \ expr' ->
+ returnLvl (Cast expr' co)
+
-- We don't split adjacent lambdas. That is, given
-- \x y -> (x+1,y)
-- we don't float to give
-- that if we'll escape a value lambda, or will go to the top level.
good_destination
| dest_lvl `ltMajLvl` ctxt_lvl -- Escapes a value lambda
- = not (exprIsCheap expr) || isTopLvl dest_lvl
- -- Even if it escapes a value lambda, we only
- -- float if it's not cheap (unless it'll get all the
- -- way to the top). I've seen cases where we
- -- float dozens of tiny free expressions, which cost
- -- more to allocate than to evaluate.
- -- NB: exprIsCheap is also true of bottom expressions, which
- -- is good; we don't want to share them
- --
- -- It's only Really Bad to float a cheap expression out of a
- -- strict context, because that builds a thunk that otherwise
- -- would never be built. So another alternative would be to
- -- add
- -- || (strict_ctxt && not (exprIsBottom expr))
- -- to the condition above. We should really try this out.
+ = True
+ -- OLD CODE: not (exprIsCheap expr) || isTopLvl dest_lvl
+ -- see Note [Escaping a value lambda]
| otherwise -- Does not escape a value lambda
= isTopLvl dest_lvl -- Only float if we are going to the top level
-- which is pretty stupid. Hence the strict_ctxt test
\end{code}
+Note [Escaping a value lambda]
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+We want to float even cheap expressions out of value lambdas,
+because that saves allocation. Consider
+ f = \x. .. (\y.e) ...
+Then we'd like to avoid allocating the (\y.e) every time we call f,
+(assuming e does not mention x).
+
+An example where this really makes a difference is simplrun009.
+
+Another reason it's good is because it makes SpecContr fire on functions.
+Consider
+ f = \x. ....(f (\y.e))....
+After floating we get
+ lvl = \y.e
+ f = \x. ....(f lvl)...
+and that is much easier for SpecConstr to generate a robust specialisation for.
+
+The OLD CODE (given where this Note is referred to) prevents floating
+of the example above, so I just don't understand the old code. I
+don't understand the old comment either (which appears below). I
+measured the effect on nofib of changing OLD CODE to 'True', and got
+zeros everywhere, but a 4% win for 'puzzle'. Very small 0.5% loss for
+'cse'; turns out to be because our arity analysis isn't good enough
+yet (mentioned in Simon-nofib-notes).
+
+OLD comment was:
+ Even if it escapes a value lambda, we only
+ float if it's not cheap (unless it'll get all the
+ way to the top). I've seen cases where we
+ float dozens of tiny free expressions, which cost
+ more to allocate than to evaluate.
+ NB: exprIsCheap is also true of bottom expressions, which
+ is good; we don't want to share them
+
+ It's only Really Bad to float a cheap expression out of a
+ strict context, because that builds a thunk that otherwise
+ would never be built. So another alternative would be to
+ add
+ || (strict_ctxt && not (exprIsBottom expr))
+ to the condition above. We should really try this out.
+
%************************************************************************
%* *
Just (abs_vars, _) -> abs_vars
Nothing -> [v]
- add_tyvars v | isId v = v : varSetElems (idFreeTyVars v)
- | otherwise = [v]
+ add_tyvars v = v : varSetElems (varTypeTyVars v)
-- We are going to lambda-abstract, so nuke any IdInfo,
-- and add the tyvars of the Id (if necessary)
returnUs (env', vs2)
-- VERY IMPORTANT: we must zap the demand info
- -- if the thing is going to float out past a lambda
+ -- if the thing is going to float out past a lambda,
+ -- or if it's going to top level (where things can't be strict)
zap_demand dest_lvl ctxt_lvl id
- | ctxt_lvl == dest_lvl = id -- Stays put
- | otherwise = zapDemandIdInfo id -- Floats out
+ | ctxt_lvl == dest_lvl,
+ not (isTopLvl dest_lvl) = id -- Stays, and not going to top level
+ | otherwise = zapDemandIdInfo id -- Floats out
\end{code}