-- Don't touch scrutinees that are already simple
scrutsimpl expr@(Case (Var _) _ _ _) = return expr
-- Replace all other cases with a let that binds the scrutinee and a new
--- simple scrutinee, but not when the scrutinee is applicable (to prevent
--- loops with inlinefun, though I don't think a scrutinee can be
--- applicable...)
-scrutsimpl (Case scrut b ty alts) | not $ is_applicable scrut = do
- id <- mkInternalVar "scrut" (CoreUtils.exprType scrut)
- change $ Let (Rec [(id, scrut)]) (Case (Var id) b ty alts)
+-- simple scrutinee, but only when the scrutinee is representable (to prevent
+-- loops with inlinenonrep, though I don't think a non-representable scrutinee
+-- will be supported anyway...)
+scrutsimpl expr@(Case scrut b ty alts) = do
+ repr <- isRepr scrut
+ if repr
+ then do
+ id <- mkInternalVar "scrut" (CoreUtils.exprType scrut)
+ change $ Let (Rec [(id, scrut)]) (Case (Var id) b ty alts)
+ else
+ return expr
-- Leave all other expressions unchanged
scrutsimpl expr = return expr
-- Perform this transform everywhere
-- Case binder wildening
--------------------------------
casewild, casewildtop :: Transform
+-- Make sure that all case alternatives have only wild binders, except for
+-- simple selector cases (e.g., case x of (a, ) -> a). This is done by
+-- creating a new let binding for each non-wild binder, which is bound to a
+-- new simple selector case statement. We do this only for binders with a
+-- representable type, to prevent loops with inlinenonrep.
casewild expr@(Case scrut b ty alts) = do
(bindingss, alts') <- (Monad.liftM unzip) $ mapM doalt alts
let bindings = concat bindingss
-- Creates a case statement to retrieve the ith element from the scrutinee
-- and binds that to b.
mkextracts :: CoreBndr -> Int -> TransformMonad (Maybe (CoreBndr, CoreExpr))
- mkextracts b i =
- if not (VarSet.elemVarSet b free_vars) || Type.isFunTy (Id.idType b)
- -- Don't create extra bindings for binders that are already wild
- -- (e.g. not in the free variables of expr, so unused), or for
- -- binders that bind function types (to prevent loops with
- -- inlinefun).
- then return Nothing
- else do
+ mkextracts b i = do
+ repr <- isRepr (Var b)
+ -- Is b wild (e.g., not a free var of expr. Since b is only in scope
+ -- in expr, this means that b is unused if expr does not use it.)
+ let wild = not (VarSet.elemVarSet b free_vars)
+ -- Create a new binding for any representable binder that is not
+ -- already wild.
+ if (not wild) && repr
+ then do
-- Create on new binder that will actually capture a value in this
- -- case statement, and return it
+ -- case statement, and return it.
let bty = (Id.idType b)
id <- mkInternalVar "sel" bty
let binders = take i wildbndrs ++ [id] ++ drop (i+1) wildbndrs
return $ Just (b, Case scrut b bty [(con, binders, Var id)])
+ else
+ return Nothing
-- Leave all other expressions unchanged
casewild expr = return expr
-- Perform this transform everywhere
-- replacing the case value with that id. Only do this when the case value
-- does not use any of the binders bound by this alternative, for that would
-- cause those binders to become unbound when moving the value outside of
- -- the case statement. Also, don't create a binding for applicable
- -- expressions, to prevent loops with inlinefun.
- doalt (con, bndrs, expr) | (not usesvars) && (not $ is_applicable expr) = do
- id <- mkInternalVar "caseval" (CoreUtils.exprType expr)
- -- We don't flag a change here, since casevalsimpl will do that above
- -- based on Just we return here.
- return $ (Just (id, expr), (con, bndrs, Var id))
+ -- the case statement. Also, don't create a binding for non-representable
+ -- expressions, to prevent loops with inlinenonrep.
+ doalt alt@(con, bndrs, expr) = do
+ repr <- isRepr expr
-- Find if any of the binders are used by expr
- where usesvars = (not . VarSet.isEmptyVarSet . (CoreFVs.exprSomeFreeVars (`elem` bndrs))) expr
- -- Don't simplify anything else
- doalt alt = return (Nothing, alt)
+ let usesvars = (not . VarSet.isEmptyVarSet . (CoreFVs.exprSomeFreeVars (`elem` bndrs))) expr
+ if (not usesvars && repr)
+ then do
+ id <- mkInternalVar "caseval" (CoreUtils.exprType expr)
+ -- We don't flag a change here, since casevalsimpl will do that above
+ -- based on Just we return here.
+ return $ (Just (id, expr), (con, bndrs, Var id))
+ else
+ -- Don't simplify anything else
+ return (Nothing, alt)
-- Leave all other expressions unchanged
casevalsimpl expr = return expr
-- Perform this transform everywhere
-- This transform takes any function-typed argument that cannot be propagated
-- (because the function that is applied to it is a builtin function), and
-- puts it in a brand new top level binder. This allows us to for example
--- apply map to a lambda expression This will not conflict with inlinefun,
+-- apply map to a lambda expression This will not conflict with inlinenonrep,
-- since that only inlines local let bindings, not top level bindings.
funextract, funextracttop :: Transform
funextract expr@(App _ _) | is_var fexpr = do
projects / matthijs / master-project / cλash.git / commitdiff