{-# LANGUAGE DeriveFunctor, GeneralizedNewtypeDeriving #-} module BuildIR(buildIR) where import Control.Monad.Except import Control.Monad.State.Strict import Data.Char import Data.List import qualified Data.Map.Strict as Map import Data.Maybe import AST import Defs import Intermediate import Pretty import TypeRules type Scope = Map.Map Name (Ref, Type) data BuildState = BuildState { nextId :: Id, scopeStack :: [Scope], currentBlock :: Id, blockMap :: Map.Map Id BB } initBuildState :: BuildState initBuildState = BuildState { nextId = 0, scopeStack = [], currentBlock = undefined, blockMap = Map.empty } newtype BuildM a = BuildM {unBuildM :: StateT BuildState (Except String) a} deriving (Functor, Applicative, Monad, MonadState BuildState, MonadError String) genId :: BuildM Id genId = state $ \s -> (nextId s, s {nextId = nextId s + 1}) genTemp :: Size -> BuildM Ref genTemp sz = liftM (Temp sz) genId newBlock :: BuildM Id newBlock = do i <- genId let block = BB i [] ITermNone modify $ \s -> s {currentBlock = i, blockMap = Map.insert i block (blockMap s)} return i newBlockNoSwitch :: BuildM Id newBlockNoSwitch = do i <- genId let block = BB i [] ITermNone modify $ \s -> s {blockMap = Map.insert i block (blockMap s)} return i addIns :: IRIns -> BuildM () addIns ins = modify $ \s -> s { blockMap = Map.adjust bbAddIns (currentBlock s) (blockMap s)} where bbAddIns :: BB -> BB bbAddIns (BB bid inss term) = BB bid (inss ++ [ins]) term setTerm :: IRTerm -> BuildM () setTerm term = modify $ \s -> s { blockMap = Map.adjust bbSetTerm (currentBlock s) (blockMap s)} where bbSetTerm :: BB -> BB bbSetTerm (BB bid inss oldterm) = case oldterm of ITermNone -> BB bid inss term _ -> error "setTerm: oldterm /= ITermNone" clearBlockMap :: BuildM () clearBlockMap = modify $ \s -> s {currentBlock = undefined, blockMap = Map.empty} getAllBlocks :: BuildM [BB] getAllBlocks = liftM Map.elems (gets blockMap) switchBlock :: Id -> BuildM () switchBlock bid = modify $ \s -> s {currentBlock = bid} withScope :: BuildM a -> BuildM a withScope act = do modify $ \s -> s {scopeStack = Map.empty : scopeStack s} res <- act modify $ \s -> s {scopeStack = tail (scopeStack s)} return res modifyScope :: (Scope -> Scope) -> BuildM () modifyScope f = modify $ \s -> s {scopeStack = f (head (scopeStack s)) : tail (scopeStack s)} scopeInsert :: Name -> Ref -> Type -> BuildM () scopeInsert n ref t = modifyScope $ Map.insert n (ref, t) findVar :: Name -> BuildM (Maybe (Int, (Ref, Type))) findVar n = do stk <- gets scopeStack let results = map (Map.lookup n) stk return $ fmap (\idx -> (idx, fromJust (results !! idx))) $ findIndex isJust results buildIR :: Program -> Error IRProgram buildIR (Program vars funcs) = runExcept $ evalStateT (unBuildM result) initBuildState where goDFunc :: DFunc -> BuildM IRFunc goDFunc (DFunc rt n al bl) = do clearBlockMap firstid <- newBlock lastid <- newBlockNoSwitch withScope $ do forM_ al $ \(at, an) -> scopeInsert an (Argument (sizeof at) an) at convertBlock bl lastid switchBlock lastid setTerm IRet bblist <- getAllBlocks return $ IRFunc rt n al bblist firstid result :: BuildM IRProgram result = do withScope $ do mapM_ (\(DVar t n _) -> scopeInsert n (Global (sizeof t) n) t) vars IRProgram vars <$> mapM goDFunc funcs convertBlock :: Block -> Id -> BuildM () convertBlock (Block sts) nextnext = do withScope $ forM_ sts $ \st -> do endid <- newBlockNoSwitch convertStatement st endid switchBlock endid setTerm $ IJmp nextnext convertStatement :: Statement -> Id -> BuildM () convertStatement (SDecl t n e) nextnext = do endid <- newBlockNoSwitch ref <- convertExpression e endid varref <- genTemp (sizeof t) scopeInsert n varref t switchBlock endid addIns $ IMov varref ref setTerm $ IJmp nextnext convertStatement (SAs ae e) nextnext = do bl2 <- newBlockNoSwitch eref <- convertExpression e bl2 switchBlock bl2 convertAsExpression ae eref nextnext convertStatement (SIf c b1 b2) nextnext = do cend <- newBlockNoSwitch blThen <- newBlockNoSwitch blElse <- newBlockNoSwitch cref <- convertExpression c cend switchBlock cend setTerm $ IJcc CNeq cref (Constant (refSize cref) 0) blThen blElse switchBlock blThen convertBlock b1 nextnext switchBlock blElse convertBlock b2 nextnext convertStatement (SWhile c b) nextnext = do cond <- newBlockNoSwitch setTerm $ IJmp cond cend <- newBlockNoSwitch body <- newBlockNoSwitch bodyend <- newBlockNoSwitch switchBlock cond cref <- convertExpression c cend switchBlock cend setTerm $ IJcc CNeq cref (Constant (refSize cref) 0) body nextnext switchBlock body convertBlock b bodyend switchBlock bodyend setTerm $ IJmp cond convertStatement (SReturn Nothing) _ = do setTerm IRet convertStatement (SReturn (Just e)) _ = do bl <- newBlockNoSwitch ref <- convertExpression e bl switchBlock bl setTerm $ IRetr ref convertStatement (SExpr e) nextnext = do void $ convertExpression e nextnext convertExpression :: Expression -> Id -> BuildM Ref convertExpression (ELit (LInt n) _) nextnext = do ref <- genTemp (sizeof TInt) addIns $ IMov ref (Constant (sizeof TInt) (fromInteger n)) setTerm $ IJmp nextnext return ref convertExpression (ELit (LChar c) _) nextnext = do ref <- genTemp (sizeof TChar) addIns $ IMov ref (Constant (sizeof TChar) (fromIntegral $ ord c)) setTerm $ IJmp nextnext return ref convertExpression (ELit (LVar n) _) nextnext = do mres <- findVar n case mres of Just (_, (r, t)) -> do ref <- genTemp (sizeof t) addIns $ IMov ref r setTerm $ IJmp nextnext return ref Nothing -> throwError $ "Undefined variable '" ++ n ++ "' referenced" convertExpression (ELit (LCall n al) mrt) nextnext = do refs <- withScope $ forM al $ \arg -> do endid <- newBlockNoSwitch r <- convertExpression arg endid switchBlock endid return r destref <- case mrt of Nothing -> do addIns $ ICall n refs return $ Temp 0 (-1) Just typ -> do r <- genTemp (sizeof typ) addIns $ ICallr r n refs return r setTerm $ IJmp nextnext return destref convertExpression (EBin BOAnd e1 e2 _) nextnext = do destref <- genTemp (sizeof TInt) bl2 <- newBlockNoSwitch blTryR <- newBlockNoSwitch bl3 <- newBlockNoSwitch blNope <- newBlockNoSwitch blYes <- newBlockNoSwitch ref1 <- convertExpression e1 bl2 switchBlock bl2 setTerm $ IJcc CNeq ref1 (Constant (refSize ref1) 0) blTryR blNope switchBlock blTryR ref2 <- convertExpression e2 bl3 switchBlock bl3 setTerm $ IJcc CNeq ref2 (Constant (refSize ref2) 0) blYes blNope switchBlock blYes addIns $ IMov destref (Constant (refSize destref) 1) setTerm $ IJmp nextnext switchBlock blNope addIns $ IMov destref (Constant (refSize destref) 0) setTerm $ IJmp nextnext return destref convertExpression (EBin bo e1 e2 _) nextnext = do bl2 <- newBlockNoSwitch ref1 <- convertExpression e1 bl2 switchBlock bl2 bl3 <- newBlockNoSwitch ref2 <- convertExpression e2 bl3 switchBlock bl3 ref <- genTemp (sizeof $ fromJust $ retTypeBO bo (fromJust $ typeof e1) (fromJust $ typeof e2)) case bo of BOAdd -> addIns $ IAri AAdd ref ref1 ref2 BOSub -> addIns $ IAri ASub ref ref1 ref2 BOMul -> addIns $ IAri AMul ref ref1 ref2 BODiv -> addIns $ IAri ADiv ref ref1 ref2 BOMod -> addIns $ IAri AMod ref ref1 ref2 BOEq -> addIns $ IAri AEq ref ref1 ref2 BONeq -> addIns $ IAri ANeq ref ref1 ref2 BOGt -> addIns $ IAri AGt ref ref1 ref2 BOLt -> addIns $ IAri ALt ref ref1 ref2 BOGeq -> addIns $ IAri AGeq ref ref1 ref2 BOLeq -> addIns $ IAri ALeq ref ref1 ref2 BOPow -> error $ "Pow operator not implemented" BOAnd -> undefined BOOr -> undefined setTerm $ IJmp nextnext return ref convertExpression (EUn UONot e mt) nextnext = convertExpression (EBin BOEq e (ELit (LInt 0) (typeof e)) mt) nextnext convertExpression (EUn UONeg e mt) nextnext = convertExpression (EBin BOSub (ELit (LInt 0) (typeof e)) e mt) nextnext convertExpression (ESubscript arr sub t) nextnext = do let elemsz = sizeof $ fromJust t bl2 <- newBlockNoSwitch arrref <- convertExpression arr bl2 switchBlock bl2 bl3 <- newBlockNoSwitch subref <- convertExpression sub bl3 switchBlock bl3 offref <- genTemp (refSize subref) off8ref <- genTemp (refSize subref) elemptr <- genTemp (refSize arrref) addIns $ IAri AMul offref subref (Constant (refSize subref) (fromIntegral elemsz)) addIns $ IAri AAdd off8ref offref (Constant (refSize subref) (fromIntegral $ sizeof TInt)) addIns $ IAri AAdd elemptr arrref off8ref ref <- genTemp elemsz addIns $ ILoad ref elemptr setTerm $ IJmp nextnext return ref convertExpression (ECast dt e) nextnext = do let typ = case typeof e of Nothing -> error $ "Cast subject " ++ show e ++ " has Nothing type" Just t -> t when (not $ isIntegralType typ && isIntegralType dt) $ error $ "convertExpression: unimplemented cast from " ++ pretty typ ++ " to " ++ pretty dt ref <- genTemp (sizeof dt) bl <- newBlockNoSwitch eref <- convertExpression e bl switchBlock bl addIns $ IResize ref eref setTerm $ IJmp nextnext return ref convertExpression (ENew t sze) nextnext = do when (not $ isBasicType t) $ throwError $ "Array element type in 'new' expression is not a basic type (" ++ pretty t ++ ")" bl2 <- newBlockNoSwitch szref <- convertExpression sze bl2 switchBlock bl2 ref <- genTemp (sizeof $ TArr t Nothing) argref' <- genTemp (sizeof TInt) argref <- genTemp (sizeof TInt) addIns $ IAri AMul argref' szref (Constant (sizeof TInt) (fromIntegral $ sizeof t)) addIns $ IAri AAdd argref argref' (Constant (sizeof TInt) (fromIntegral $ sizeof TInt)) addIns $ ICallr ref "_builtin_malloc" [argref] addIns $ IStore ref szref setTerm $ IJmp nextnext return ref convertAsExpression :: AsExpression -> Ref -> Id -> BuildM () convertAsExpression (AEVar n _) valueref nextnext = do mres <- findVar n vref <- case mres of Just (_, (r, _)) -> return r Nothing -> throwError $ "Undefined variable '" ++ n ++ "'" ++ " used in assignment expression" addIns $ IMov vref valueref setTerm $ IJmp nextnext convertAsExpression (AESubscript ae2 expr mrt) valueref nextnext = do let elemsz = sizeof $ fromJust mrt ae2ref <- goLoad ae2 bl2 <- newBlockNoSwitch subref <- convertExpression expr bl2 switchBlock bl2 offref' <- genTemp (sizeof TInt) offref <- genTemp (sizeof TInt) elemptr <- genTemp (sizeof TInt) -- TODO: do bounds checking addIns $ IAri AMul offref' subref (Constant (sizeof TInt) (fromIntegral elemsz)) addIns $ IAri AAdd offref offref' (Constant (sizeof TInt) (fromIntegral $ sizeof TInt)) addIns $ IAri AAdd elemptr ae2ref offref addIns $ IStore elemptr valueref setTerm $ IJmp nextnext where goLoad :: AsExpression -> BuildM Ref goLoad (AEVar n _) = do mres <- findVar n (vref, t) <- case mres of Just (_, (r, t)) -> return (r, t) Nothing -> throwError $ "Undefined variable '" ++ n ++ "'" ++ " used in assignment expression" ref <- genTemp (sizeof t) addIns $ IMov ref vref return ref goLoad (AESubscript ae expr' _) = do let elemsz = sizeof $ fromJust $ typeof ae ref <- goLoad ae bl2 <- newBlockNoSwitch eref <- convertExpression expr' bl2 switchBlock bl2 offref' <- genTemp (sizeof TInt) offref <- genTemp (sizeof TInt) elemptr <- genTemp (sizeof TInt) -- TODO: do bounds checking addIns $ IAri AMul offref' eref (Constant (sizeof TInt) (fromIntegral elemsz)) addIns $ IAri AAdd offref offref' (Constant (sizeof TInt) (fromIntegral $ sizeof TInt)) addIns $ IAri AAdd elemptr ref offref dstref <- genTemp elemsz addIns $ ILoad dstref elemptr return dstref