-- top level function "normalize", and defines the actual transformation passes that
-- are performed.
--
-module CLasH.Normalize (getNormalized, normalizeExpr) where
+module CLasH.Normalize (getNormalized, normalizeExpr, splitNormalized) where
-- Standard modules
import Debug.Trace
import qualified Maybe
+import qualified List
import qualified "transformers" Control.Monad.Trans as Trans
import qualified Control.Monad as Monad
import qualified Control.Monad.Trans.Writer as Writer
castproptop = everywhere ("castprop", castprop)
--------------------------------
--- let recursification
+-- Cast simplification. Mostly useful for state packing and unpacking, but
+-- perhaps for others as well.
--------------------------------
-letrec, letrectop :: Transform
-letrec (Let (NonRec b expr) res) = change $ Let (Rec [(b, expr)]) res
+castsimpl, castsimpltop :: Transform
+castsimpl expr@(Cast val ty) = do
+ -- Don't extract values that are already simpl
+ local_var <- Trans.lift $ is_local_var val
+ -- Don't extract values that are not representable, to prevent loops with
+ -- inlinenonrep
+ repr <- isRepr val
+ if (not local_var) && repr
+ then do
+ -- Generate a binder for the expression
+ id <- Trans.lift $ mkBinderFor val "castval"
+ -- Extract the expression
+ change $ Let (NonRec id val) (Cast (Var id) ty)
+ else
+ return expr
+-- Leave all other expressions unchanged
+castsimpl expr = return expr
+-- Perform this transform everywhere
+castsimpltop = everywhere ("castsimpl", castsimpl)
+
+--------------------------------
+-- let derecursification
+--------------------------------
+letderec, letderectop :: Transform
+letderec expr@(Let (Rec binds) res) = case liftable of
+ -- Nothing is liftable, just return
+ [] -> return expr
+ -- Something can be lifted, generate a new let expression
+ _ -> change $ MkCore.mkCoreLets newbinds res
+ where
+ -- Make a list of all the binders bound in this recursive let
+ bndrs = map fst binds
+ -- See which bindings are liftable
+ (liftable, nonliftable) = List.partition canlift binds
+ -- Create nonrec bindings for each liftable binding and a single recursive
+ -- binding for all others
+ newbinds = (map (uncurry NonRec) liftable) ++ [Rec nonliftable]
+ -- Any expression that does not use any of the binders in this recursive let
+ -- can be lifted into a nonrec let. It can't use its own binder either,
+ -- since that would mean the binding is self-recursive and should be in a
+ -- single bind recursive let.
+ canlift (bndr, e) = not $ expr_uses_binders bndrs e
-- Leave all other expressions unchanged
-letrec expr = return expr
+letderec expr = return expr
-- Perform this transform everywhere
-letrectop = everywhere ("letrec", letrec)
+letderectop = everywhere ("letderec", letderec)
--------------------------------
-- let simplification
--------------------------------
letsimpl, letsimpltop :: Transform
+-- Don't simplify a let that evaluates to another let, since this is already
+-- normal form (and would cause infinite loops with letflat below).
+letsimpl expr@(Let _ (Let _ _)) = return expr
-- Put the "in ..." value of a let in its own binding, but not when the
-- expression is already a local variable, or not representable (to prevent loops with inlinenonrep).
-letsimpl expr@(Let (Rec binds) res) = do
+letsimpl expr@(Let binds res) = do
repr <- isRepr res
local_var <- Trans.lift $ is_local_var res
if not local_var && repr
then do
-- If the result is not a local var already (to prevent loops with
-- ourselves), extract it.
- id <- Trans.lift $ mkInternalVar "foo" (CoreUtils.exprType res)
- let bind = (id, res)
- change $ Let (Rec (bind:binds)) (Var id)
+ id <- Trans.lift $ mkBinderFor res "foo"
+ change $ Let binds (Let (NonRec id res) (Var id))
else
-- If the result is already a local var, don't extract it.
return expr
--------------------------------
-- let flattening
--------------------------------
+-- Takes a let that binds another let, and turns that into two nested lets.
+-- e.g., from:
+-- let b = (let b' = expr' in res') in res
+-- to:
+-- let b' = expr' in (let b = res' in res)
letflat, letflattop :: Transform
-letflat (Let (Rec binds) expr) = do
- -- Turn each binding into a list of bindings (possibly containing just one
- -- element, of course)
- bindss <- Monad.mapM flatbind binds
- -- Concat all the bindings
- let binds' = concat bindss
- -- Return the new let. We don't use change here, since possibly nothing has
- -- changed. If anything has changed, flatbind has already flagged that
- -- change.
- return $ Let (Rec binds') expr
- where
- -- Turns a binding of a let into a multiple bindings, or any other binding
- -- into a list with just that binding
- flatbind :: (CoreBndr, CoreExpr) -> TransformMonad [(CoreBndr, CoreExpr)]
- flatbind (b, Let (Rec binds) expr) = change ((b, expr):binds)
- flatbind (b, expr) = return [(b, expr)]
+letflat (Let (NonRec b (Let (NonRec b' expr') res')) res) =
+ change $ Let (NonRec b' expr') (Let (NonRec b res') res)
-- Leave all other expressions unchanged
letflat expr = return expr
-- Perform this transform everywhere
letflattop = everywhere ("letflat", letflat)
+--------------------------------
+-- empty let removal
+--------------------------------
+-- Remove empty (recursive) lets
+letremove, letremovetop :: Transform
+letremove (Let (Rec []) res) = change $ res
+-- Leave all other expressions unchanged
+letremove expr = return expr
+-- Perform this transform everywhere
+letremovetop = everywhere ("letremove", letremove)
+
--------------------------------
-- Simple let binding removal
--------------------------------
-- Remove a = b bindings from let expressions everywhere
-letremovetop :: Transform
-letremovetop = everywhere ("letremove", inlinebind (\(b, e) -> Trans.lift $ is_local_var e))
+letremovesimpletop :: Transform
+letremovesimpletop = everywhere ("letremovesimple", inlinebind (\(b, e) -> Trans.lift $ is_local_var e))
+--------------------------------
+-- Unused let binding removal
+--------------------------------
+letremoveunused, letremoveunusedtop :: Transform
+letremoveunused expr@(Let (Rec binds) res) = do
+ -- Filter out all unused binds.
+ let binds' = filter dobind binds
+ -- Only set the changed flag if binds got removed
+ changeif (length binds' /= length binds) (Let (Rec binds') res)
+ where
+ bound_exprs = map snd binds
+ -- For each bind check if the bind is used by res or any of the bound
+ -- expressions
+ dobind (bndr, _) = any (expr_uses_binders [bndr]) (res:bound_exprs)
+-- Leave all other expressions unchanged
+letremoveunused expr = return expr
+letremoveunusedtop = everywhere ("letremoveunused", letremoveunused)
+
+--------------------------------
+-- Identical let binding merging
+--------------------------------
+-- Merge two bindings in a let if they are identical
+-- TODO: We would very much like to use GHC's CSE module for this, but that
+-- doesn't track if something changed or not, so we can't use it properly.
+letmerge, letmergetop :: Transform
+letmerge expr@(Let (Rec binds) res) = do
+ binds' <- domerge binds
+ return (Let (Rec binds') res)
+ where
+ domerge :: [(CoreBndr, CoreExpr)] -> TransformMonad [(CoreBndr, CoreExpr)]
+ domerge [] = return []
+ domerge (e:es) = do
+ es' <- mapM (mergebinds e) es
+ es'' <- domerge es'
+ return (e:es'')
+
+ -- Uses the second bind to simplify the second bind, if applicable.
+ mergebinds :: (CoreBndr, CoreExpr) -> (CoreBndr, CoreExpr) -> TransformMonad (CoreBndr, CoreExpr)
+ mergebinds (b1, e1) (b2, e2)
+ -- Identical expressions? Replace the second binding with a reference to
+ -- the first binder.
+ | CoreUtils.cheapEqExpr e1 e2 = change $ (b2, Var b1)
+ -- Different expressions? Don't change
+ | otherwise = return (b2, e2)
+-- Leave all other expressions unchanged
+letmerge expr = return expr
+letmergetop = everywhere ("letmerge", letmerge)
+
--------------------------------
-- Function inlining
--------------------------------
repr <- isRepr scrut
if repr
then do
- id <- Trans.lift $ mkInternalVar "scrut" (CoreUtils.exprType scrut)
- change $ Let (Rec [(id, scrut)]) (Case (Var id) b ty alts)
+ id <- Trans.lift $ mkBinderFor scrut "scrut"
+ change $ Let (NonRec id scrut) (Case (Var id) b ty alts)
else
return expr
-- Leave all other expressions unchanged
-- prevent loops with inlinenonrep).
if (not uses_bndrs) && (not local_var) && repr
then do
- id <- Trans.lift $ mkInternalVar "caseval" (CoreUtils.exprType expr)
+ id <- Trans.lift $ mkBinderFor expr "caseval"
-- We don't flag a change here, since casevalsimpl will do that above
-- based on Just we return here.
return $ (Just (id, expr), Var id)
local_var <- Trans.lift $ is_local_var arg
if repr && not local_var
then do -- Extract representable arguments
- id <- Trans.lift $ mkInternalVar "arg" (CoreUtils.exprType arg)
- change $ Let (Rec [(id, arg)]) (App f (Var id))
+ id <- Trans.lift $ mkBinderFor arg "arg"
+ change $ Let (NonRec id arg) (App f (Var id))
else -- Leave non-representable arguments unchanged
return expr
-- Leave all other expressions unchanged
-- What transforms to run?
-transforms = [argproptop, funextracttop, etatop, betatop, castproptop, letremovetop, letrectop, letsimpltop, letflattop, scrutsimpltop, casesimpltop, caseremovetop, inlinenonreptop, appsimpltop]
+transforms = [argproptop, funextracttop, etatop, betatop, castproptop, letremovesimpletop, letderectop, letremovetop, letsimpltop, letflattop, scrutsimpltop, casesimpltop, caseremovetop, inlinenonreptop, appsimpltop, letmergetop, letremoveunusedtop, castsimpltop]
-- | Returns the normalized version of the given function.
getNormalized ::
-> TranslatorSession CoreSyn.CoreExpr -- ^ The normalized expression
normalizeExpr what expr = do
- -- Introduce an empty Let at the top level, so there will always be
- -- a let in the expression (none of the transformations will remove
- -- the last let).
- let expr' = Let (Rec []) expr
-- Normalize this expression
- trace ("Transforming " ++ what ++ "\nBefore:\n\n" ++ showSDoc ( ppr expr' ) ++ "\n") $ return ()
- expr'' <- dotransforms transforms expr'
- trace ("\nAfter:\n\n" ++ showSDoc ( ppr expr')) $ return ()
- return expr''
+ trace (what ++ " before normalization:\n\n" ++ showSDoc ( ppr expr ) ++ "\n") $ return ()
+ expr' <- dotransforms transforms expr
+ trace ("\n" ++ what ++ " after normalization:\n\n" ++ showSDoc ( ppr expr')) $ return ()
+ return expr'
-- | Get the value that is bound to the given binder at top level. Fails when
-- there is no such binding.
-- If the binding isn't in the "cache" (bindings map), then we can't create
-- it out of thin air, so return an error.
error $ "Normalize.getBinding: Unknown function requested: " ++ show bndr
+
+-- | Split a normalized expression into the argument binders, top level
+-- bindings and the result binder.
+splitNormalized ::
+ CoreExpr -- ^ The normalized expression
+ -> ([CoreBndr], [Binding], CoreBndr)
+splitNormalized expr = (args, binds, res)
+ where
+ (args, letexpr) = CoreSyn.collectBinders expr
+ (binds, resexpr) = flattenLets letexpr
+ res = case resexpr of
+ (Var x) -> x
+ _ -> error $ "Normalize.splitNormalized: Not in normal form: " ++ pprString expr ++ "\n"
+
+-- | Flattens nested lets into a single list of bindings. The expression
+-- passed does not have to be a let expression, if it isn't an empty list of
+-- bindings is returned.
+flattenLets ::
+ CoreExpr -- ^ The expression to flatten.
+ -> ([Binding], CoreExpr) -- ^ The bindings and resulting expression.
+flattenLets (Let binds expr) =
+ (bindings ++ bindings', expr')
+ where
+ -- Recursively flatten the contained expression
+ (bindings', expr') =flattenLets expr
+ -- Flatten our own bindings to remove the Rec / NonRec constructors
+ bindings = CoreSyn.flattenBinds [binds]
+flattenLets expr = ([], expr)
projects / matthijs / master-project / cλash.git / blobdiff