X-Git-Url: https://git.stderr.nl/gitweb?a=blobdiff_plain;f=c%CE%BBash%2FCLasH%2FNormalize%2FNormalizeTools.hs;h=803fd958cec82637d8177194da570e89ecf40f2b;hb=0223b461a043e42d3fc5442904b73ce0bd537472;hp=2d2a9068bd8b0d8042aeba6ea60eb4f342916783;hpb=dab01c1b5ee96091a49aba57d9a95cc322427cbd;p=matthijs%2Fmaster-project%2Fc%CE%BBash.git diff --git "a/c\316\273ash/CLasH/Normalize/NormalizeTools.hs" "b/c\316\273ash/CLasH/Normalize/NormalizeTools.hs" index 2d2a906..803fd95 100644 --- "a/c\316\273ash/CLasH/Normalize/NormalizeTools.hs" +++ "b/c\316\273ash/CLasH/Normalize/NormalizeTools.hs" @@ -5,32 +5,28 @@ module CLasH.Normalize.NormalizeTools where -- Standard modules -import Debug.Trace -import qualified List import qualified Data.Monoid as Monoid -import qualified Data.Either as Either -import qualified Control.Arrow as Arrow import qualified Control.Monad as Monad -import qualified Control.Monad.Trans.State as State import qualified Control.Monad.Trans.Writer as Writer import qualified "transformers" Control.Monad.Trans as Trans -import qualified Data.Map as Map -import Data.Accessor -import Data.Accessor.MonadState as MonadState +import qualified Data.Accessor.Monad.Trans.State as MonadState +-- import Debug.Trace -- GHC API import CoreSyn import qualified Name import qualified Id import qualified CoreSubst -import qualified CoreUtils -import Outputable ( showSDoc, ppr, nest ) +import qualified Type +-- import qualified CoreUtils +-- import Outputable ( showSDoc, ppr, nest ) -- Local imports import CLasH.Normalize.NormalizeTypes import CLasH.Translator.TranslatorTypes -import CLasH.Utils.Pretty -import CLasH.VHDL.VHDLTypes +import CLasH.VHDL.Constants (builtinIds) +import CLasH.Utils +import qualified CLasH.Utils.Core.CoreTools as CoreTools import qualified CLasH.VHDL.VHDLTools as VHDLTools -- Apply the given transformation to all expressions in the given expression, @@ -41,106 +37,91 @@ everywhere trans = applyboth (subeverywhere (everywhere trans)) trans -- Apply the first transformation, followed by the second transformation, and -- keep applying both for as long as expression still changes. applyboth :: Transform -> (String, Transform) -> Transform -applyboth first (name, second) expr = do +applyboth first (name, second) context expr = do -- Apply the first - expr' <- first expr + expr' <- first context expr -- Apply the second - (expr'', changed) <- Writer.listen $ second expr' + (expr'', changed) <- Writer.listen $ second context expr' if Monoid.getAny $ --- trace ("Trying to apply transform " ++ name ++ " to:\n" ++ showSDoc (nest 4 $ ppr expr') ++ "\nType: \n" ++ (showSDoc $ nest 4 $ ppr $ CoreUtils.exprType expr') ++ "\n") $ + -- trace ("Trying to apply transform " ++ name ++ " to:\n" ++ showSDoc (nest 4 $ ppr expr') ++ "\nType: \n" ++ (showSDoc $ nest 4 $ ppr $ CoreUtils.exprType expr') ++ "\n") changed - then --- trace ("Applying transform " ++ name ++ " to:\n" ++ showSDoc (nest 4 $ ppr expr') ++ "\nType: \n" ++ (showSDoc $ nest 4 $ ppr $ CoreUtils.exprType expr') ++ "\n") $ --- trace ("Result of applying " ++ name ++ ":\n" ++ showSDoc (nest 4 $ ppr expr'') ++ "\n" ++ "Type: \n" ++ (showSDoc $ nest 4 $ ppr $ CoreUtils.exprType expr'') ++ "\n" ) $ - applyboth first (name, second) $ - expr'' + then do + -- trace ("Applying transform " ++ name ++ " to:\n" ++ showSDoc (nest 4 $ ppr expr') ++ "\nType: \n" ++ (showSDoc $ nest 4 $ ppr $ CoreUtils.exprType expr') ++ "\n" + -- ++ "Context: " ++ show context ++ "\n" + -- ++ "Result of applying " ++ name ++ ":\n" ++ showSDoc (nest 4 $ ppr expr'') ++ "\n" ++ "Type: \n" ++ (showSDoc $ nest 4 $ ppr $ CoreUtils.exprType expr'') ++ "\n" ) $ + Trans.lift $ MonadState.modify tsTransformCounter (+1) + applyboth first (name, second) context expr'' else --- trace ("No changes") $ + -- trace ("No changes") $ return expr'' -- Apply the given transformation to all direct subexpressions (only), not the -- expression itself. subeverywhere :: Transform -> Transform -subeverywhere trans (App a b) = do - a' <- trans a - b' <- trans b +subeverywhere trans c (App a b) = do + a' <- trans (AppFirst:c) a + b' <- trans (AppSecond:c) b return $ App a' b' -subeverywhere trans (Let (NonRec b bexpr) expr) = do - bexpr' <- trans bexpr - expr' <- trans expr +subeverywhere trans c (Let (NonRec b bexpr) expr) = do + bexpr' <- trans (LetBinding:c) bexpr + expr' <- trans (LetBody:c) expr return $ Let (NonRec b bexpr') expr' -subeverywhere trans (Let (Rec binds) expr) = do - expr' <- trans expr +subeverywhere trans c (Let (Rec binds) expr) = do + expr' <- trans (LetBody:c) expr binds' <- mapM transbind binds return $ Let (Rec binds') expr' where transbind :: (CoreBndr, CoreExpr) -> TransformMonad (CoreBndr, CoreExpr) transbind (b, e) = do - e' <- trans e + e' <- trans (LetBinding:c) e return (b, e') -subeverywhere trans (Lam x expr) = do - expr' <- trans expr +subeverywhere trans c (Lam x expr) = do + expr' <- trans (LambdaBody:c) expr return $ Lam x expr' -subeverywhere trans (Case scrut b t alts) = do - scrut' <- trans scrut +subeverywhere trans c (Case scrut b t alts) = do + scrut' <- trans (Other:c) scrut alts' <- mapM transalt alts return $ Case scrut' b t alts' where transalt :: CoreAlt -> TransformMonad CoreAlt transalt (con, binders, expr) = do - expr' <- trans expr + expr' <- trans (Other:c) expr return (con, binders, expr') -subeverywhere trans (Var x) = return $ Var x -subeverywhere trans (Lit x) = return $ Lit x -subeverywhere trans (Type x) = return $ Type x +subeverywhere trans c (Var x) = return $ Var x +subeverywhere trans c (Lit x) = return $ Lit x +subeverywhere trans c (Type x) = return $ Type x -subeverywhere trans (Cast expr ty) = do - expr' <- trans expr +subeverywhere trans c (Cast expr ty) = do + expr' <- trans (Other:c) expr return $ Cast expr' ty -subeverywhere trans expr = error $ "\nNormalizeTools.subeverywhere: Unsupported expression: " ++ show expr - --- Apply the given transformation to all expressions, except for direct --- arguments of an application -notappargs :: (String, Transform) -> Transform -notappargs trans = applyboth (subnotappargs trans) trans - --- Apply the given transformation to all (direct and indirect) subexpressions --- (but not the expression itself), except for direct arguments of an --- application -subnotappargs :: (String, Transform) -> Transform -subnotappargs trans (App a b) = do - a' <- subnotappargs trans a - b' <- subnotappargs trans b - return $ App a' b' - --- Let subeverywhere handle all other expressions -subnotappargs trans expr = subeverywhere (notappargs trans) expr +subeverywhere trans c expr = error $ "\nNormalizeTools.subeverywhere: Unsupported expression: " ++ show expr -- Runs each of the transforms repeatedly inside the State monad. dotransforms :: [Transform] -> CoreExpr -> TranslatorSession CoreExpr dotransforms transs expr = do - (expr', changed) <- Writer.runWriterT $ Monad.foldM (flip ($)) expr transs + (expr', changed) <- Writer.runWriterT $ Monad.foldM (\e trans -> trans [] e) expr transs if Monoid.getAny changed then dotransforms transs expr' else return expr' -- Inline all let bindings that satisfy the given condition inlinebind :: ((CoreBndr, CoreExpr) -> TransformMonad Bool) -> Transform -inlinebind condition expr@(Let (NonRec bndr expr') res) = do +inlinebind condition context expr@(Let (NonRec bndr expr') res) = do applies <- condition (bndr, expr') if applies - then + then do -- Substitute the binding in res and return that - change $ substitute [(bndr, expr')] res + res' <- substitute_clone bndr expr' context res + change res' else -- Don't change this let return expr -- Leave all other expressions unchanged -inlinebind _ expr = return expr +inlinebind _ context expr = return expr -- Sets the changed flag in the TransformMonad, to signify that some -- transform has changed the result @@ -159,45 +140,63 @@ changeif :: Bool -> a -> TransformMonad a changeif True val = change val changeif False val = return val --- Replace each of the binders given with the coresponding expressions in the --- given expression. -substitute :: [(CoreBndr, CoreExpr)] -> CoreExpr -> CoreExpr -substitute [] expr = expr --- Apply one substitution on the expression, but also on any remaining --- substitutions. This seems to be the only way to handle substitutions like --- [(b, c), (a, b)]. This means we reuse a substitution, which is not allowed --- according to CoreSubst documentation (but it doesn't seem to be a problem). --- TODO: Find out how this works, exactly. -substitute ((b, e):subss) expr = substitute subss' expr' - where - -- Create the Subst - subs = (CoreSubst.extendSubst CoreSubst.emptySubst b e) - -- Apply this substitution to the main expression - expr' = CoreSubst.substExpr subs expr - -- Apply this substitution on all the expressions in the remaining - -- substitutions - subss' = map (Arrow.second (CoreSubst.substExpr subs)) subss +-- | Creates a transformation that substitutes the given binder with the given +-- expression (This can be a type variable, replace by a Type expression). +-- Does not set the changed flag. +substitute :: CoreBndr -> CoreExpr -> Transform +-- Use CoreSubst to subst a type var in an expression +substitute find repl context expr = do + let subst = CoreSubst.extendSubst CoreSubst.emptySubst find repl + return $ CoreSubst.substExpr subst expr + +-- | Creates a transformation that substitutes the given binder with the given +-- expression. This does only work for value expressions! All binders in the +-- expression are cloned before the replacement, to guarantee uniqueness. +substitute_clone :: CoreBndr -> CoreExpr -> Transform +-- If we see the var to find, replace it by a uniqued version of repl +substitute_clone find repl context (Var var) | find == var = do + repl' <- Trans.lift $ CoreTools.genUniques repl + change repl' + +-- For all other expressions, just look in subexpressions +substitute_clone find repl context expr = subeverywhere (substitute_clone find repl) context expr -- Is the given expression representable at runtime, based on the type? -isRepr :: CoreSyn.CoreExpr -> TransformMonad Bool -isRepr (Type ty) = return False -isRepr expr = Trans.lift $ MonadState.lift tsType $ VHDLTools.isReprType (CoreUtils.exprType expr) +isRepr :: (CoreTools.TypedThing t) => t -> TransformMonad Bool +isRepr tything = Trans.lift (isRepr' tything) + +isRepr' :: (CoreTools.TypedThing t) => t -> TranslatorSession Bool +isRepr' tything = case CoreTools.getType tything of + Nothing -> return False + Just ty -> MonadState.lift tsType $ VHDLTools.isReprType ty is_local_var :: CoreSyn.CoreExpr -> TranslatorSession Bool is_local_var (CoreSyn.Var v) = do bndrs <- getGlobalBinders - return $ not $ v `elem` bndrs + return $ v `notElem` bndrs is_local_var _ = return False -- Is the given binder defined by the user? isUserDefined :: CoreSyn.CoreBndr -> Bool -- System names are certain to not be user defined isUserDefined bndr | Name.isSystemName (Id.idName bndr) = False --- Check a list of typical compiler-defined names -isUserDefined bndr = str `elem` compiler_names +-- Builtin functions are usually not user-defined either (and would +-- break currently if they are...) +isUserDefined bndr = str `notElem` builtinIds where str = Name.getOccString bndr - -- These are names of bindings usually generated by the compiler. For some - -- reason these are not marked as system, probably because the name itself - -- is not made up by the compiler, just this particular binding is. - compiler_names = ["fromInteger"] + +-- Is the given binder normalizable? This means that its type signature can be +-- represented in hardware, which should (?) guarantee that it can be made +-- into hardware. Note that if a binder is not normalizable, it might become +-- so using argument propagation. +isNormalizeable :: CoreBndr -> TransformMonad Bool +isNormalizeable bndr = Trans.lift (isNormalizeable' bndr) + +isNormalizeable' :: CoreBndr -> TranslatorSession Bool +isNormalizeable' bndr = do + let ty = Id.idType bndr + let (arg_tys, res_ty) = Type.splitFunTys ty + -- This function is normalizable if all its arguments and return value are + -- representable. + andM $ mapM isRepr' (res_ty:arg_tys)