{-# LANGUAGE DeriveFunctor, GeneralizedNewtypeDeriving, TupleSections, QuasiQuotes, ScopedTypeVariables #-} module CodeGen(codegen) where import Control.Monad import Control.Monad.Except import Control.Monad.State.Strict import Data.List import Data.Maybe import Data.Map.Strict ((!)) import qualified Data.Map.Strict as Map import Debug.Trace import AST import Defs import Intermediate import qualified LifetimeAnalysis as LA import RegAlloc import Utils import X64 (Register(..), CondCode(..), XRef(..), Ins(..), xref) import qualified X64 as X64 import X64Optimiser data CGState = CGState { nextId :: Int, regsToRestore :: [Register], spillSize :: Size, x64Result :: X64.Asm } newtype CGMonad a = CGMonad { unCGMonad :: StateT CGState (Except String) a } deriving (Functor, Applicative, Monad, MonadState CGState, MonadError String) initState :: CGState initState = CGState {nextId = 1, regsToRestore = [], spillSize = 0, x64Result = X64.Asm []} execCGMonad :: CGMonad a -> Error X64.Asm execCGMonad = fmap x64Result . runExcept . flip execStateT initState . unCGMonad addIns :: X64.Ins -> CGMonad () addIns ins = modify $ \s -> let (X64.Asm funcs) = x64Result s (pre, (lab, inss)) = (init funcs, last funcs) in s {x64Result = X64.Asm $ pre ++ [(lab, inss ++ [ins])]} newLabel :: String -> CGMonad () newLabel lab = modify $ \s -> let (X64.Asm funcs) = x64Result s in s {x64Result = X64.Asm $ funcs ++ [(lab, [])]} -- genId :: CGMonad Int -- genId = state $ \s -> (nextId s, s {nextId = nextId s + 1}) setRegsToRestore :: [Register] -> CGMonad () setRegsToRestore regs = modify $ \s -> s {regsToRestore = regs} setSpillSize :: Size -> CGMonad () setSpillSize sz = modify $ \s -> s {spillSize = sz} codegen :: IRProgram -> Error String codegen (IRProgram vars funcs) = do x64 <- execCGMonad $ mapM_ codegenFunc funcs -- traceShowM x64 X64.verify x64 varcg <- liftM unlines $ mapM codegenVar vars x64opt <- x64Optimise x64 return $ "extern putc, putint, getc, _builtin_malloc\n" ++ "global main\ndefault rel\nsection .text\n" ++ X64.stringify x64opt ++ "\nsection .data\n" ++ varcg codegenVar :: DVar -> Error String codegenVar (DVar TInt n (ELit (LInt i) (Just TInt))) = Right $ n ++ ": dq " ++ show i codegenVar _ = Left "Unsupported global variable declaration" type AllocMap = Map.Map Ref XRef codegenFunc :: IRFunc -> CGMonad () codegenFunc (IRFunc _ name al bbs sid) = do let temprefsperbb = collectTempRefs bbs alltemprefs = uniq $ sort $ map LA.unAccess $ concat $ concat $ map fst temprefsperbb lifespans = map (\r -> (findLifeSpan r, r)) alltemprefs where findLifeSpan ref = fromJust $ findFirstLast id $ concat $ LA.lifetimeAnalysis ref temprefsperbb aliascandidates = findAliasCandidates bbs :: [(Ref, Ref)] gpRegs = [R8, R9, R10, R11, R12, R13, R14, R15] allocation = regalloc lifespans gpRegs aliascandidates :: Map.Map Ref (Allocation Register) spillrefs = map fst $ filter (isAllocMem . snd) $ Map.toList allocation (spilloffsets, spillsz) = initLast $ scanl (+) 0 $ map refSize spillrefs spilloffsetmap = Map.fromList $ zip spillrefs spilloffsets usedregs = uniq $ sort $ catMaybes $ flip map (Map.toList allocation) $ \(_, a) -> case a of AllocReg reg -> Just reg AllocMem -> Nothing -- traceShowM temprefsperbb -- traceShowM lifespans traceM $ "ALLOCATION: " ++ show allocation let nsaves = length usedregs allocationXref = flip Map.mapWithKey allocation $ \ref alloc -> case alloc of AllocReg reg -> XReg (fromIntegral $ refSize ref) reg AllocMem -> XMem (fromIntegral $ refSize ref) (Just RSP) (0, RAX) Nothing (fromIntegral $ spilloffsetmap ! ref) allocmap = foldl inserter allocationXref (zip al [0::Int ..]) where inserter m ((t, n), i) = let offset = fromIntegral spillsz + 8 * nsaves + 8 {- rbp -} + 8 {- ret addr -} + 8 * i in Map.insert (Argument (sizeof t) n) (XMem (fromIntegral $ sizeof t) (Just RSP) (0, RAX) Nothing (fromIntegral offset)) m newLabel name addIns $ PUSH (xref $ XReg 8 RBP) addIns $ MOV (xref $ XReg 8 RBP) (xref $ XReg 8 RSP) forM_ usedregs $ \reg -> addIns $ PUSH (xref $ XReg 8 reg) when (spillsz /= 0) $ addIns $ SUB (xref $ XReg 8 RSP) (xref $ XImm $ fromIntegral spillsz) setRegsToRestore usedregs setSpillSize spillsz let ([startbb], rest) = partition (\(BB i _ _) -> i == sid) bbs codegenBB allocmap startbb mapM_ (codegenBB allocmap) rest findAliasCandidates :: [BB] -> [(Ref, Ref)] findAliasCandidates = concatMap (\(BB _ inss _) -> concatMap goI inss) where goI :: IRIns -> [(Ref, Ref)] goI (IMov d s) = [(d, s)] goI (IAri at d s1 s2) | isCommutative at = [(d, s1), (d, s2)] | otherwise = [(d, s1)] goI _ = [] findFirstLast :: forall a. (a -> Bool) -> [a] -> Maybe (Int, Int) findFirstLast f l = go Nothing 0 l where go :: Maybe (Int, Int) -> Int -> [a] -> Maybe (Int, Int) go mr _ [] = mr go mr i (x:xs) | f x = go (note mr i) (i+1) xs | otherwise = go mr (i+1) xs note :: Maybe (Int, Int) -> Int -> Maybe (Int, Int) note Nothing i = Just (i, i) note (Just (a, _)) i = Just (a, i) isAllocMem :: Allocation a -> Bool isAllocMem AllocMem = True isAllocMem _ = False initLast :: [a] -> ([a], a) initLast [] = undefined initLast [x] = ([], x) initLast (x:xs) = let (acc, l) = initLast xs in (x : acc, l) codegenBB :: AllocMap -> BB -> CGMonad () codegenBB allocmap (BB bid inss term) = do newLabel $ ".bb" ++ show bid mapM_ (codegenIns allocmap) inss codegenTerm allocmap term mkxref :: Ref -> AllocMap -> XRef mkxref (Constant _ v) _ = XImm v mkxref (Global sz n) _ = XMem (fromIntegral sz) Nothing (0, RAX) (Just n) 0 mkxref r m = fromJust $ Map.lookup r m mkmov :: XRef -> XRef -> X64.Ins mkmov a@(XReg _ _) b@(XReg _ _) = MOV (xref a) (xref b) mkmov a@(XReg _ _) b@(XMem _ _ _ _ _) = MOV (xref a) (xref b) mkmov a@(XReg _ _) b@(XImm _) = MOVi64 (xref a) (xref b) mkmov a@(XMem _ _ _ _ _) b@(XReg _ _) = MOV (xref a) (xref b) mkmov a@(XMem _ _ _ _ _) b@(XImm v) | v < 2 ^ (32 :: Int) = MOVi (xref a) (xref b) mkmov a b = CALL $ "Invalid mkmov: " ++ show a ++ "; " ++ show b -- mkmov a b = error $ "Invalid mkmov: " ++ show a ++ "; " ++ show b mkcmp :: XRef -> XRef -> X64.Ins mkcmp a b@(XImm _) = CMPi (xref a) (xref b) mkcmp a b = CMP (xref a) (xref b) codegenIns :: AllocMap -> IRIns -> CGMonad () codegenIns m (IMov d s) | dm == sm = return () | X64.isXMem dm && X64.isXMem sm = do addIns $ mkmov (XReg (fromIntegral $ refSize s) RAX) sm addIns $ mkmov dm (XReg (fromIntegral $ refSize d) RAX) | otherwise = addIns $ mkmov dm sm where dm = mkxref d m sm = mkxref s m codegenIns m (IStore d s) = do sourcexref <- if X64.isXMem sm then do addIns $ mkmov (XReg sz RBX) sm return $ XReg sz RBX else return sm destxref <- case dm of XReg _ r -> return $ XMem sz (Just r) (0, RAX) Nothing 0 x@(XMem xsz _ _ _ _) -> do addIns $ mkmov (XReg xsz RAX) x return $ XMem sz (Just RAX) (0, RAX) Nothing 0 XImm _ -> throwError $ "IStore to [immediate] not expected" addIns $ mkmov destxref sourcexref where dm = mkxref d m sm = mkxref s m sz = fromIntegral $ refSize s codegenIns m (ILoad d s) = do sourcexref <- case sm of XReg _ r -> return $ XMem sz (Just r) (0, RAX) Nothing 0 x@(XMem xsz _ _ _ _) -> do addIns $ mkmov (XReg xsz RAX) x return $ XMem sz (Just RAX) (0, RAX) Nothing 0 XImm _ -> throwError $ "ILoad from [immediate] not expected" if X64.isXMem dm then do addIns $ mkmov (XReg sz RAX) sourcexref addIns $ mkmov dm (XReg sz RAX) else do addIns $ mkmov dm sourcexref where dm = mkxref d m sm = mkxref s m sz = fromIntegral $ refSize d codegenIns m (IAri AMul d s1 s2) = do let sz = fromIntegral $ refSize d addIns $ mkmov (XReg sz RAX) (mkxref s1 m) addIns $ mkmov (XReg sz RBX) (mkxref s2 m) addIns $ IMULDA (xref $ XReg sz RBX) addIns $ mkmov (mkxref d m) (XReg sz RAX) codegenIns m (IAri ADiv d s1 s2) = do let sz = fromIntegral $ refSize d addIns $ XOR (xref $ XReg 4 RDX) (xref $ XReg 4 RDX) addIns $ mkmov (XReg sz RAX) (mkxref s1 m) addIns $ mkmov (XReg sz RBX) (mkxref s2 m) addIns $ IDIVDA (xref $ XReg sz RBX) addIns $ mkmov (mkxref d m) (XReg sz RAX) codegenIns m (IAri AMod d s1 s2) = do let sz = fromIntegral $ refSize d addIns $ XOR (xref $ XReg 4 RDX) (xref $ XReg 4 RDX) addIns $ mkmov (XReg sz RAX) (mkxref s1 m) addIns $ mkmov (XReg sz RBX) (mkxref s2 m) addIns $ IDIVDA (xref $ XReg sz RBX) addIns $ mkmov (mkxref d m) (XReg sz RDX) codegenIns m (IAri at d s1 s2) = case arithTypeToCondCode at of Just cc -> do arg2 <- if X64.isXMem s1m && X64.isXMem s2m then do addIns $ mkmov (XReg (fromIntegral $ refSize s2) RAX) s2m return $ XReg (fromIntegral $ refSize s2) RAX else return s2m addIns $ mkcmp s1m arg2 addIns $ SETCC cc (xref $ X64.xrefSetSize 1 dm) addIns $ AND (xref $ X64.xrefSetSize 4 dm) (xref $ XImm 0xff) Nothing -> do (_, s1m', s2', s2m') <- if dm == s2m then if dm == s1m then return (s1, s1m, s2, s2m) else if isCommutative at then return (s2, s2m, s1, s1m) else throwError "Noncommutative op with d==s2/=s1" else return (s1, s1m, s2, s2m) arg2 <- if X64.isXMem s1m' && X64.isXMem s2m' then do addIns $ mkmov (XReg (fromIntegral $ refSize s2') RAX) s2m' return $ XReg (fromIntegral $ refSize s2') RAX else return s2m' when (dm /= s1m') $ addIns $ mkmov dm s1m' addIns $ fromJust (arithTypeToIns at) dm arg2 where dm = mkxref d m s1m = mkxref s1 m s2m = mkxref s2 m codegenIns m (ICall n rs) = do forM_ (zip (reverse rs) [1::Int ..]) $ \(r, i) -> let sz = fromIntegral $ refSize r src = (mkxref r m) dst = (XMem sz (Just RSP) (0, RAX) Nothing (fromIntegral $ (-8) * i)) in if X64.isXMem (mkxref r m) then do addIns $ mkmov (XReg sz RAX) src addIns $ mkmov dst (XReg sz RAX) else do addIns $ mkmov dst src when (length rs > 0) $ addIns $ SUB (xref $ XReg 8 RSP) (xref $ XImm (fromIntegral $ 8 * length rs)) addIns $ CALL n when (length rs > 0) $ addIns $ ADD (xref $ XReg 8 RSP) (xref $ XImm (fromIntegral $ 8 * length rs)) codegenIns m (ICallr d n rs) = do codegenIns m (ICall n rs) addIns $ mkmov (mkxref d m) (XReg (fromIntegral $ refSize d) RAX) codegenIns m fullins@(IResize d s) = do let dsz = fromIntegral $ refSize d ssz = fromIntegral $ refSize s dm = mkxref d m sm = mkxref s m when (X64.isXImm sm) $ throwError $ "Resized value is an immediate in " ++ show fullins ++ "; (dm = " ++ show dm ++ "; sm = " ++ show sm ++ ")" case compare dsz ssz of EQ -> codegenIns m (IMov d s) GT -> if X64.isXMem dm then do addIns $ MOVSX (xref $ XReg dsz RAX) (xref sm) addIns $ mkmov dm (XReg dsz RAX) else do addIns $ MOVSX (xref dm) (xref sm) LT -> if X64.isXMem dm && X64.isXMem sm then do addIns $ mkmov (XReg dsz RAX) (X64.xrefSetSize dsz sm) addIns $ mkmov dm (XReg dsz RAX) else do addIns $ mkmov dm (X64.xrefSetSize dsz sm) codegenIns _ INop = return () arithTypeToCondCode :: ArithType -> Maybe X64.CondCode arithTypeToCondCode AEq = Just CCE arithTypeToCondCode ANeq = Just CCNE arithTypeToCondCode AGt = Just CCG arithTypeToCondCode ALt = Just CCL arithTypeToCondCode AGeq = Just CCGE arithTypeToCondCode ALeq = Just CCLE arithTypeToCondCode _ = Nothing cmpTypeToCondCode :: CmpType -> X64.CondCode cmpTypeToCondCode CEq = CCE cmpTypeToCondCode CNeq = CCNE cmpTypeToCondCode CGt = CCG cmpTypeToCondCode CLt = CCL cmpTypeToCondCode CGeq = CCGE cmpTypeToCondCode CLeq = CCLE arithTypeToIns :: ArithType -> Maybe (XRef -> XRef -> X64.Ins) arithTypeToIns AAdd = Just $ \a b -> ADD (xref a) (xref b) arithTypeToIns ASub = Just $ \a b -> SUB (xref a) (xref b) arithTypeToIns AAnd = Just $ \a b -> AND (xref a) (xref b) arithTypeToIns AOr = Just $ \a b -> OR (xref a) (xref b) arithTypeToIns AXor = Just $ \a b -> XOR (xref a) (xref b) arithTypeToIns _ = Nothing codegenTerm :: AllocMap -> IRTerm -> CGMonad () codegenTerm m (IJcc ct a b t e) = do if X64.isXMem am && X64.isXMem bm then do addIns $ mkmov (XReg (fromIntegral $ refSize b) RAX) bm addIns $ mkcmp am (XReg (fromIntegral $ refSize b) RAX) else do addIns $ mkcmp am bm addIns $ JCC (cmpTypeToCondCode ct) (".bb" ++ show t) addIns $ JMP (".bb" ++ show e) where am = mkxref a m bm = mkxref b m codegenTerm _ (IJmp i) = addIns $ JMP (".bb" ++ show i) codegenTerm _ IRet = do spillsz <- gets spillSize when (spillsz /= 0) $ addIns $ ADD (xref $ XReg 8 RSP) (xref $ XImm $ fromIntegral spillsz) usedregs <- gets regsToRestore forM_ (reverse usedregs) $ \reg -> addIns $ POP (xref $ XReg 8 reg) addIns $ mkmov (XReg 8 RSP) (XReg 8 RBP) addIns $ POP (xref $ XReg 8 RBP) addIns RET codegenTerm m (IRetr r) = do addIns $ mkmov (XReg (fromIntegral $ refSize r) RAX) (mkxref r m) spillsz <- gets spillSize when (spillsz /= 0) $ addIns $ ADD (xref $ XReg 8 RSP) (xref $ XImm $ fromIntegral spillsz) usedregs <- gets regsToRestore forM_ (reverse usedregs) $ \reg -> addIns $ POP (xref $ XReg 8 reg) addIns $ mkmov (XReg 8 RSP) (XReg 8 RBP) addIns $ POP (xref $ XReg 8 RBP) addIns RET codegenTerm _ ITermNone = undefined collectTempRefs :: [BB] -> [([[LA.Access Ref]], [Int])] collectTempRefs bbs = flip map bbs $ \(BB _ inss term) -> let refs = map (filter (isTemp . LA.unAccess)) $ concatMap listRefsIns inss ++ listRefsTerm term nexts = map (\i -> fromJust $ findIndex (\(BB j _ _) -> j == i) bbs) $ listNextIds term in (refs, nexts) where listRefsIns :: IRIns -> [[LA.Access Ref]] listRefsIns (IMov a b) = [[LA.Read b], [LA.Write a]] listRefsIns (IStore a b) = [[LA.Read a, LA.Read b]] listRefsIns (ILoad a b) = [[LA.Read b], [LA.Write a]] listRefsIns (IAri at a b c) -- if not commutative, we don't want to have to xchg the operands | isCommutative at = [[LA.Read b, LA.Read c], [LA.Write a]] | otherwise = [[LA.Read b], [LA.Read c, LA.Write a]] listRefsIns (ICall _ l) = [map LA.Read l] listRefsIns (ICallr a _ l) = [LA.Write a : map LA.Read l] listRefsIns (IResize a b) = [[LA.Read b], [LA.Write a]] listRefsIns INop = [[]] listRefsTerm :: IRTerm -> [[LA.Access Ref]] listRefsTerm (IJcc _ a b _ _) = [[LA.Read a, LA.Read b]] listRefsTerm (IJmp _) = [[]] listRefsTerm IRet = [[]] listRefsTerm (IRetr a) = [[LA.Read a]] listRefsTerm ITermNone = undefined listNextIds :: IRTerm -> [Id] listNextIds (IJcc _ _ _ a b) = [a, b] listNextIds (IJmp a) = [a] listNextIds IRet = [] listNextIds (IRetr _) = [] listNextIds ITermNone = undefined isTemp :: Ref -> Bool isTemp (Temp _ _) = True isTemp _ = False