Implement early version of CodeGen

Use TAst in CodeGen
Implement conversion from Ast to TAst
2024-12-11 16:11:05 -05:00 · 2024-12-11 15:58:59 -05:00 · 2024-12-11 15:58:01 -05:00 · 2024-12-11 15:57:23 -05:00
6 changed files with 674 additions and 6 deletions
--- a/src/Main.hs
+++ b/src/Main.hs
@ -12,6 +12,7 @@ import Windows12.Parser (programP)
 import System.Environment (getArgs)
 import LLVM.Pretty
 import Windows12.Ast
 import Windows12.Semant (convert)
 import Windows12.CodeGen (codegen)
@ -26,4 +27,7 @@ main = do
      test <- T.readFile inputFile
      case parse programP inputFile test of
        Left err -> print err
        Right ast ->
          case convert ast of
            Left err -> putStrLn err
            Right ast -> TL.writeFile outputFile (ppllvm (codegen (cs inputFile) ast))
--- a/src/Windows12.hs
+++ b/src/Windows12.hs
@ -4,3 +4,5 @@ import Windows12.Ast
 import Windows12.Lexer
 import Windows12.Parser
 import Windows12.CodeGen
 import Windows12.TAst
 import Windows12.Semant
--- a/src/Windows12/CodeGen.hs
+++ b/src/Windows12/CodeGen.hs
@ -1,8 +1,351 @@
 {-# LANGUAGE FlexibleContexts #-}
 {-# LANGUAGE TupleSections #-}
 {-# LANGUAGE OverloadedStrings #-}
 {-# LANGUAGE RecursiveDo #-}
 {-# LANGUAGE MultiParamTypeClasses #-}
 module Windows12.CodeGen where
-import Data.Text (Text)
+import Windows12.Ast (BinOp(..), UnOp(..), AssignOp(..), Type(..),
-import Windows12.Ast
+    Bind(..), TLStruct(..), TLEnum(..))
-import LLVM.AST (Module)
+import Windows12.TAst
-codegen :: Text -> Program -> Module
+import LLVM.AST hiding (ArrayType, VoidType, Call, function)
-codegen filename (Program structs enums funcs) = undefined
+import LLVM.AST.Type (i32, i1, i8, double, ptr, void)
 import qualified LLVM.AST.Constant as C
 import LLVM.IRBuilder hiding (double, IRBuilder, ModuleBuilder)
 import LLVM.AST.Typed (typeOf)
 import LLVM.Prelude (ShortByteString)
 import qualified LLVM.AST.IntegerPredicate as IP
 import qualified LLVM.AST.FloatingPointPredicate as FP
 import Control.Monad.State hiding (void)
 import Data.Text (Text, unpack)
 import Data.String.Conversions
 import Data.String
 -- Global program context, used to keep track of operands
 data Ctx =  Ctx { operands :: [(Text, Operand)],
                  structs :: [TLStruct],
                  enums :: [TLEnum],
                  strings :: [(Text, Operand)] }
    deriving (Eq, Show)
 type ModuleBuilder = ModuleBuilderT (State Ctx)
 type IRBuilder = IRBuilderT ModuleBuilder
 -- Allow easy string conversion
 instance ConvertibleStrings Text ShortByteString where
  convertString = Data.String.fromString . Data.Text.unpack
 -- Put an operand into the context with a name
 createOperand :: MonadState Ctx m => Text -> Operand -> m ()
 createOperand name op = do
  ctx <- get
  put $ ctx { operands = (name, op) : operands ctx }
 -- Take in a source file name, the AST, and return the LLVM IR module
 codegen :: Text -> TProgram -> Module
 codegen filename (TProgram structs enums funcs) = 
    flip evalState (Ctx [] [] [] [])
    $ buildModuleT (cs filename)
    $ do
        printf <- externVarArgs (mkName "printf") [ptr i8] i32
        createOperand "printf" printf
        mapM_ emitTypeDef structs
        mapM_ codegenFunc funcs
 -- Given a struct name, search the context for the struct and return its fields
 getStructFields :: MonadState Ctx m => Text -> m [Bind]
 getStructFields name = do
  ctx <- get
  case filter (\(Struct n _) -> n == name) (structs ctx) of
    [] -> error $ "Struct " ++ show name ++ " not found. Valid structs: " ++ show (map (\(Struct n _) -> n) (structs ctx))
    [Struct _ fields] -> return fields
    _ -> error $ "Multiple structs with name " ++ show name
 -- Convert a Windows12 type to an LLVM type
 convertType :: MonadState Ctx m => Windows12.Ast.Type -> m LLVM.AST.Type
 convertType IntType = return i32
 convertType UIntType = return i32
 convertType FloatType = return double
 convertType StrType = convertType (PtrType CharType)
 convertType BoolType = return i1
 convertType CharType = return i8
 convertType (PtrType t) = ptr <$> convertType t
 convertType (ArrayType t) = convertType (PtrType t)
 convertType (StructType name) = do
  fields <- getStructFields name
  types <- mapM (convertType . bindType) fields
  return $ StructureType True types -- True indicates packed
 convertType (EnumType name) = return i32
 convertType VoidType = return void
 -- Get the size of a type in bytes
 size :: MonadState Ctx m => Windows12.Ast.Type -> m Int
 size IntType = return 4
 size UIntType = return 4
 size FloatType = return 8
 size StrType = size (PtrType CharType)
 size BoolType = return 1
 size CharType = return 1
 size (PtrType _) = return 4
 size (ArrayType t) = size (PtrType t)
 size (StructType name) = do
  fields <- getStructFields name
  sizes <- mapM (size . bindType) fields
  return $ sum sizes
 size (EnumType _) = return 8
 size VoidType = return 0
 -- CodeGen for LValues
 codegenLVal :: TLVal -> IRBuilder Operand
 codegenLVal (t, (TId name)) = do
  ctx <- get
  case lookup name (operands ctx) of
    Just op -> return op
    Nothing -> error $ "Variable " ++ show name ++ " not found"
 -- TODO support members of members
 codegenLVal ((StructType t), (LTMember ((_, TId sName)) field)) = do
    ctx <- get
    case lookup sName (operands ctx) of
        Just struct -> do
            fields <- getStructFields t
            offset <- structFieldOffset (Struct sName fields) field
            gep struct [ConstantOperand (C.Int 32 0), ConstantOperand (C.Int 32 (fromIntegral offset))]
        Nothing -> error $ "Struct " ++ show sName ++ " not found"
 codeGenLVal (t, (TDeref e)) = codegenExpr e
 codeGenLVal (t, _) = error "Unimplemented or invalid LValue"
 -- Given a struct and a field name, return the offset of the field in the struct.
 -- In LLVM each field is actually size 1
 structFieldOffset :: MonadState Ctx m => TLStruct -> Text -> m Int
 structFieldOffset (Struct name fields) field = do
    return $ length $ takeWhile (\(Bind n _) -> n /= field) fields
 -- CodeGen for expressions
 codegenExpr :: TExpr -> IRBuilder Operand
 codegenExpr (t, (TVar name)) = flip load 0 =<< codegenLVal (t, (TId name))
 codegenExpr (t, (TIntLit i)) = return $ ConstantOperand (C.Int 32 (fromIntegral i))
 codegenExpr (t, (TUIntLit i)) = return $ ConstantOperand (C.Int 32 (fromIntegral i))
 codegenExpr (t, (TFloatLit f)) = undefined -- TODO floats
 codegenExpr (t, (TStrLit s)) = do
    strs <- gets strings
    case lookup s strs of
        -- If the string is already in the context, return it
        Just str -> return str
        -- Otherwise, create a new global string and add it to the context
        Nothing -> do
            let str_name = mkName ("str." <> show (length strs))
            op <- globalStringPtr (cs s) str_name
            modify $ \ctx -> ctx { strings = (s, (ConstantOperand op)) : strs }
            return (ConstantOperand op)
 codegenExpr (t, (TBoolLit b)) = return $ ConstantOperand (C.Int 1 (if b then 1 else 0))
 codegenExpr (t, (TCharLit c)) = return $ ConstantOperand (C.Int 8 (fromIntegral (fromEnum c)))
 codegenExpr (t, (TBinOp op lhs rhs)) = do
    lhs' <- codegenExpr lhs
    rhs' <- codegenExpr rhs
    -- TODO pointers, floating points
    case op of
        Windows12.Ast.Add -> case (typeOf lhs', typeOf rhs') of
            (IntegerType 32, IntegerType 32) -> add lhs' rhs'
            _ -> error "Invalid types for add"
        Windows12.Ast.Sub -> case (typeOf lhs', typeOf rhs') of
            (IntegerType 32, IntegerType 32) -> sub lhs' rhs'
            _ -> error "Invalid types for sub"
        Windows12.Ast.Mul -> case (typeOf lhs', typeOf rhs') of
            (IntegerType 32, IntegerType 32) -> mul lhs' rhs'
            _ -> error "Invalid types for mul"
        Windows12.Ast.Div -> case (typeOf lhs', typeOf rhs') of
            (IntegerType 32, IntegerType 32) -> sdiv lhs' rhs'
            _ -> error "Invalid types for div"
        Windows12.Ast.Mod -> case (typeOf lhs', typeOf rhs') of
            (IntegerType 32, IntegerType 32) -> srem lhs' rhs'
            _ -> error "Invalid types for mod"
        Windows12.Ast.Eq -> case (typeOf lhs', typeOf rhs') of
            (IntegerType 32, IntegerType 32) -> icmp IP.EQ lhs' rhs'
            _ -> error "Invalid types for eq"
        Windows12.Ast.Ne -> case (typeOf lhs', typeOf rhs') of
            (IntegerType 32, IntegerType 32) -> icmp IP.NE lhs' rhs'
            _ -> error "Invalid types for ne"
        Windows12.Ast.Lt -> case (typeOf lhs', typeOf rhs') of
            (IntegerType 32, IntegerType 32) -> icmp IP.SLT lhs' rhs'
            _ -> error "Invalid types for lt"
        Windows12.Ast.Gt -> case (typeOf lhs', typeOf rhs') of
            (IntegerType 32, IntegerType 32) -> icmp IP.SGT lhs' rhs'
            _ -> error "Invalid types for gt"
        Windows12.Ast.Le -> case (typeOf lhs', typeOf rhs') of
            (IntegerType 32, IntegerType 32) -> icmp IP.SLE lhs' rhs'
            _ -> error "Invalid types for le"
        Windows12.Ast.Ge -> case (typeOf lhs', typeOf rhs') of
            (IntegerType 32, IntegerType 32) -> icmp IP.SGE lhs' rhs'
            _ -> error "Invalid types for ge"
        other -> error $ "Operator " ++ show other ++ " not implemented"
 codegenExpr (t, (TUnOp op e)) = undefined -- TODO handle unary operators
 -- Function calls: look up the function in operands, then call it with the args
 codegenExpr (t, (TCall f args)) = do
    ctx <- get
    f <- case lookup f (operands ctx) of
        Just f -> return f
        Nothing -> error $ "Function " ++ show f ++ " not found"
    args <- mapM (fmap (, []) . codegenExpr) args
    call f args
 codegenExpr (t, (TIndex arr idx))  = undefined -- TODO arrays
 -- Get the address of the struct field and load it
 codegenExpr (t, (TMember ((StructType sName), (TVar sVarName)) m)) = do
    ctx <- get
    case lookup sVarName (operands ctx) of
        Just struct -> do
            fields <- getStructFields sName
            offset <- structFieldOffset (Struct sVarName fields) m
            addr <- gep struct [ConstantOperand (C.Int 32 0), ConstantOperand (C.Int 32 (fromIntegral offset))]
            load addr 0
        Nothing -> error $ "Struct operand " ++ show sVarName ++ " not found"
 codegenExpr (_, (TCast t e)) = undefined -- TODO casts
 codegenExpr (_, (TSizeof t)) = ConstantOperand . C.Int 32 . fromIntegral <$> size t
 mkTerminator :: IRBuilder () -> IRBuilder ()
 mkTerminator instr = do
 check <- hasTerminator
 unless check instr
 -- Codegen for statements
 codegenStmt :: TStmt -> IRBuilder ()
 -- For expression statements, just evaluate the expression and discard the result
 codegenStmt (TExprStmt e) = do
    _expr <- codegenExpr e
    return ()
 codegenStmt (TReturn e) = ret =<< codegenExpr e
 -- Generate if statements, with a merge block at the end
 codegenStmt (TIf cond t f) = mdo
    cond' <- codegenExpr cond
    condBr cond' then' else'
    then' <- block `named` "then"
    codegenStmt (TBlock t)
    mkTerminator $ br merge
    else' <- block `named` "else"
    codegenStmt (case f of
        Just f' -> TBlock f'
        Nothing -> TBlock [])
    mkTerminator $ br merge
    merge <- block `named` "merge"
    return ()
 -- Generate while loops, with a merge block at the end
 codegenStmt (TWhile cond body) = mdo
    br condBlock
    condBlock <- block `named` "cond"
    cond' <- codegenExpr cond
    condBr cond' loop end
    loop <- block `named` "loop"
    codegenStmt (TBlock body)
    mkTerminator $ br condBlock
    end <- block `named` "end"
    return ()
 codegenStmt (TAssign BaseAssign l@(t, (TId name)) e) = do
    op <- codegenExpr e
    var <- codegenLVal l
    store var 0 op
 codegenStmt (TAssign BaseAssign l@((StructType tName), (LTMember ((_, TId sName)) field)) e) = do
    op <- codegenExpr e
    struct <- codegenLVal l
    store struct 0 op
 codegenStmt (TAssign AddAssign l@(t, (TId name)) e) = do
    op <- codegenExpr e
    var <- codegenLVal l
    val <- load var 0
    store var 0 =<< add val op
 codegenStmt (TAssign SubAssign l@(t, (TId name)) e) = do
    op <- codegenExpr e
    var <- codegenLVal l
    val <- load var 0
    store var 0 =<< sub val op
 -- A block is just a list of statements
 codegenStmt (TBlock stmts) = mapM_ codegenStmt stmts
 -- Since the vars are already allocated by genBody, we just need to assign the value
 codegenStmt (TDeclVar name t (Just e)) = codegenStmt (TAssign BaseAssign (t, (TId name)) e)
 -- Do nothing with variable declaration if no expression is given
 -- This is because allocation is done already
 codegenStmt (TDeclVar name _ Nothing) = return ()
 codegenStmt s = error $ "Unimplemented or invalid statement " ++ show s
 -- Generate code for a function
 -- First create the function, then allocate space for the arguments and locals
 codegenFunc :: TTLFunc -> ModuleBuilder ()
 codegenFunc func@(TTLFunc name args retType body) = mdo
    createOperand name f
    (f, strs) <- do
        params' <- mapM mkParam args
        retType' <- convertType retType
        f <- function (mkName (cs name)) params' retType' genBody
        strs <- gets strings
        return (f, strs)
    modify $ \ctx -> ctx { strings = strs }
  where
    mkParam (Bind name t) = (,) <$> convertType t <*> pure (ParameterName (cs name))
    genBody :: [Operand] -> IRBuilder ()
    genBody ops = do
        forM_ (zip ops args) $ \(op, (Bind name t)) -> do
            addr <- alloca (typeOf op) Nothing 0
            store addr 0 op
            createOperand name addr
        forM_ (getLocals func) $ \(Bind name t) -> do
            ltype <- convertType t
            addr <- alloca ltype Nothing 0
            createOperand name addr
        codegenStmt (TBlock body)
 -- Given a function, get all the local variables
 -- Used so allocation can be done before the function body
 getLocals :: TTLFunc -> [Bind]
 getLocals (TTLFunc _ args _ body) = blockGetLocals body
 blockGetLocals :: [TStmt] -> [Bind]
 blockGetLocals = concatMap stmtGetLocals
 stmtGetLocals :: TStmt -> [Bind]
 stmtGetLocals (TDeclVar n t _) = [Bind n t]
 stmtGetLocals (TBlock stmts) = blockGetLocals stmts
 stmtGetLocals (TIf _ t f) = blockGetLocals t ++ maybe [] blockGetLocals f
 stmtGetLocals (TWhile _ body) = blockGetLocals body
 stmtGetLocals _ = []
 -- Create structs
 emitTypeDef :: TLStruct -> ModuleBuilder LLVM.AST.Type
 emitTypeDef (Struct name fields) = do
    modify $ \ctx -> ctx { structs = Struct name fields : structs ctx }
    sType <- convertType (StructType name)
    typedef (mkName (cs ("struct." <> name))) (Just sType)
--- a/src/Windows12/Semant.hs
+++ b/src/Windows12/Semant.hs
@ -0,0 +1,263 @@
 {-# LANGUAGE FlexibleContexts #-}
 {-# LANGUAGE OverloadedStrings #-}
 module Windows12.Semant where
 import Data.Text (Text)
 import Control.Monad.State
 import Data.List (find)
 import Windows12.Ast as Ast
 import Windows12.TAst as TAst
 suppliedFuncs :: [Text]
 suppliedFuncs = ["printf"]
 -- Convert an Ast to a TAst
 -- Performs type inference and type checking
 data Ctx = Ctx { structs :: [TLStruct],
                 enums :: [TLEnum],
                 funcs :: [TTLFunc],
                 vars :: [(Text, Type)] }
    deriving (Eq, Show)
 -- Main conversion function. May return an error message if the program
 -- is not well-typed.
 convert :: Ast.Program -> Either String TAst.TProgram
 convert (Ast.Program structs enums funcs) = do
    let ctx = Ctx structs enums [] []
    let (funcs', _) = runState (mapM convertFunc funcs) ctx
    return $ TAst.TProgram structs enums funcs'
 -- Convert a TLFunc (Top Level Function) to a TTLFunc (Typed Top Level Function)
 -- Note that the function must be added to the context before converting statements
 -- of the function. This is because the function may call itself recursively.
 -- After converting the function, the function's statements are converted
 -- and added to the context.
 convertFunc :: MonadState Ctx m => Ast.TLFunc -> m TAst.TTLFunc
 convertFunc (Ast.Func name args retType body) = do
    args' <- mapM (\(Bind name t) -> return (name, t)) args
    oldFuncs <- gets funcs
    modify (\ctx -> ctx { funcs = funcs ctx ++ [TTLFunc name args retType []], vars = args' })
    body' <- mapM convertStmt body
    ctx <- get
    let func = (last $ funcs ctx) { TAst.funcBody = body' }
    put $ ctx { funcs = oldFuncs ++ [func] }
    return func
 -- Convert a statement
 convertStmt :: MonadState Ctx m => Ast.Stmt -> m TAst.TStmt
 convertStmt (Ast.Expr expr) = do
    expr' <- convertExpr expr
    return $ TAst.TExprStmt expr'
 convertStmt (Ast.Return expr) = do
    expr' <- convertExpr expr
    return $ TAst.TReturn expr'
 convertStmt (Ast.If cond thenStmts elseStmts) = do
    thenStmts' <- mapM convertStmt thenStmts
    elseStmts' <- mapM convertStmt $ maybe [] id elseStmts
    cond' <- convertExpr cond
    return $ TAst.TIf cond' thenStmts' (Just elseStmts')
 convertStmt (Ast.While cond stmts) = do
    stmts' <- mapM convertStmt stmts
    cond' <- convertExpr cond
    return $ TAst.TWhile cond' stmts'
 convertStmt (Ast.Assign op lval expr) = do
    lval' <- convertLVal lval
    expr' <- convertExpr expr
    return $ TAst.TAssign op lval' expr'
 convertStmt (Ast.Block stmts) = do
    stmts' <- mapM convertStmt stmts
    return $ TAst.TBlock stmts'
 convertStmt (Ast.Var name (Just t) maybeExpr) = do
    expr' <- maybe (return Nothing) (fmap Just . convertExpr) maybeExpr
    modify (\ctx -> ctx { vars = (name, t) : vars ctx })
    return $ TAst.TDeclVar name t expr'
 -- TODO
 convertStmt (Ast.Var name Nothing maybeExpr) = error "Type inference not implemented"
 -- Convert an expression to an LValue
 -- Only certain expressions are allowed as LValues
 convertLVal :: MonadState Ctx m => Ast.Expr -> m TAst.TLVal
 convertLVal (Ast.Id name) = do
    ctx <- get
    case lookup name (vars ctx) of
        Just t -> return (t, TAst.TId name)
        Nothing -> error $ "Variable " ++ show name ++ " not in scope"
 convertLVal (Ast.Index arr idx) = do
    arr' <- convertLVal arr
    idx' <- convertExpr idx
    return (fst arr', TAst.LTIndex arr' idx')
 convertLVal (Ast.Member e (Id m)) = do
    e' <- convertLVal e
    return (fst e', TAst.LTMember e' m)
 convertLVal (Ast.Member e m) = do error $ "Invalid member access " ++ show m ++ " on " ++ show e
 convertLVal (Ast.UnOp Ast.Deref e) = error "Dereferencing not implemented"
 convertLVal e = do error $ "Invalid or unimplemented LValue " ++ show e
 -- Convert an expression
 convertExpr :: MonadState Ctx m => Ast.Expr -> m TAst.TExpr
 convertExpr (Ast.Id name) = do
    ctx <- get
    case lookup name (vars ctx) of
        Just t -> return (t, TAst.TVar name)
        Nothing -> error $ "Variable " ++ show name ++ " not in scope"
 convertExpr (Ast.IntLit x) = return (IntType, TAst.TIntLit x)
 convertExpr (Ast.UIntLit x) = return (UIntType, TAst.TUIntLit x)
 convertExpr (Ast.FloatLit x) = return (FloatType, TAst.TFloatLit x)
 convertExpr (Ast.StrLit x) = return (StrType, TAst.TStrLit x)
 convertExpr (Ast.BoolLit x) = return (BoolType, TAst.TBoolLit x)
 convertExpr (Ast.CharLit x) = return (CharType, TAst.TCharLit x)
 convertExpr (Ast.BinOp Add l r) = arithOp Add l r
 convertExpr (Ast.BinOp Sub l r) = arithOp Sub l r
 convertExpr (Ast.BinOp Mul l r) = arithOp Mul l r
 convertExpr (Ast.BinOp Div l r) = arithOp Div l r
 convertExpr (Ast.BinOp Mod l r) = arithOp Mod l r
 convertExpr (Ast.BinOp Eq l r) = compOp Eq l r
 convertExpr (Ast.BinOp Ne l r) = compOp Ne l r
 convertExpr (Ast.BinOp Lt l r) = compOp Lt l r
 convertExpr (Ast.BinOp Gt l r) = compOp Gt l r
 convertExpr (Ast.BinOp Le l r) = compOp Le l r
 convertExpr (Ast.BinOp Ge l r) = compOp Ge l r
 convertExpr (Ast.BinOp And l r) = boolOp And l r
 convertExpr (Ast.BinOp Or l r) = boolOp Or l r
 convertExpr (Ast.BinOp BitAnd l r) = bitOp BitAnd l r
 convertExpr (Ast.BinOp BitOr l r) = bitOp BitOr l r
 convertExpr (Ast.BinOp BitXor l r) = bitOp BitXor l r
 convertExpr (Ast.BinOp ShiftL l r) = shiftOp ShiftL l r
 convertExpr (Ast.BinOp ShiftR l r) = shiftOp ShiftR l r
 convertExpr (Ast.UnOp Neg e) = do
    e' <- convertExpr e
    if fst e' `elem` [IntType, UIntType, FloatType]
        then return (fst e', TAst.TUnOp Neg e')
        else error $ "Type mismatch: " ++ show e
 convertExpr (Ast.UnOp Not e) = do
    e' <- convertExpr e
    if fst e' == BoolType
        then return (BoolType, TAst.TUnOp Not e')
        else error $ "Type mismatch: " ++ show e
 convertExpr (Ast.UnOp BitNot e) = undefined
 convertExpr (Ast.UnOp Deref e) = undefined
 convertExpr (Ast.UnOp AddrOf e) = undefined
 -- TODO type check function return
 -- TODO ensure returns on all paths
 -- Lower priority since LLVM checks this also
 convertExpr (Ast.Call (Id f) args) = do
    ctx <- get
    if f == "printf"
        then do
            args' <- mapM convertExpr args
            return (IntType, TAst.TCall "printf" args')
        else case find (\(TTLFunc n a r _) -> n == f) (funcs ctx) of
            Just t -> do
                args' <- mapM convertExpr args
                if length args' == length (TAst.funcArgs t) && all (\(t1, t2) -> t1 == t2) (zip (map fst args') (map bindType (TAst.funcArgs t)))
                    then return (TAst.funcRetType t, TAst.TCall f args')
                    else error $ "Type mismatch in call to " ++ show f
            Nothing -> error $ "Function " ++ show f ++ " not in scope. Available functions: " ++ show (map TAst.funcName (funcs ctx))
 convertExpr (Ast.Index arr idx) = do
    arr' <- convertExpr arr
    idx' <- convertExpr idx
    case fst arr' of
        ArrayType t -> if fst idx' == IntType
            then return (t, TAst.TIndex arr' idx')
            else error $ "Index must be an integer: " ++ show idx
        _ -> error $ "Indexing non-array: " ++ show arr
 convertExpr (Ast.Cast t e) = do
    e' <- convertExpr e
    return (t, TAst.TCast t e')
 convertExpr (Ast.Sizeof t) = return (IntType, TAst.TSizeof t)
 convertExpr (Ast.Member e (Id m)) = do
    e' <- convertExpr e
    case fst e' of
        StructType name -> do
            ctx <- get
            case find (\(Struct n _) -> n == name) (structs ctx) of
                Just (Struct _ binds) -> case find (\(Bind n t) -> n == m) binds of
                    Just (Bind _ t) -> return (t, TAst.TMember e' m)
                    Nothing -> error $ "Field " ++ show m ++ " not in struct " ++ show name
                Nothing -> error $ "Struct " ++ show name ++ " not in scope"
        _ -> error $ "Member access on non-struct " ++ show e
 convertExpr (Ast.StructInit name fields) = do
    ctx <- get
    case find (\(Struct n _) -> n == name) (structs ctx) of
        Just (Struct _ binds) -> do
            fields' <- mapM (\(n, e) -> do
                e' <- convertExpr e
                case find (\(Bind n' t) -> n == n') binds of
                    Just (Bind _ t) -> if fst e' == t
                        then return (n, e')
                        else error $ "Type mismatch in struct initialization: " ++ show e
                    Nothing -> error $ "Field " ++ show n ++ " not in struct " ++ show name) fields
            return (StructType name, TAst.TStructInit name fields')
        Nothing -> error $ "Struct " ++ show name ++ " not in scope"
 convertExpr e = error $ "Invalid or Unimplemented conversion for expression " ++ show e
 -- Ensure that the types of the left and right expressions are the same
 -- and return the type of the result
 arithOp :: MonadState Ctx m => Ast.BinOp -> Ast.Expr -> Ast.Expr -> m TAst.TExpr
 arithOp o l r = do
    l' <- convertExpr l
    r' <- convertExpr r
    if fst l' == fst r'
        then return (fst l', TAst.TBinOp o l' r')
        else error $ "Type mismatch: " ++ show l ++ " and " ++ show r
 -- Ensure that the types of the left and right expressions are the same
 -- and return a boolean type
 compOp :: MonadState Ctx m => Ast.BinOp -> Ast.Expr -> Ast.Expr -> m TAst.TExpr
 compOp o l r = do
    l' <- convertExpr l
    r' <- convertExpr r
    if fst l' == fst r'
        then return (BoolType, TAst.TBinOp o l' r')
        else error $ "Type mismatch: " ++ show l ++ " and " ++ show r
 -- Ensure that the types of both expressions are boolean
 -- and return a boolean type
 boolOp :: MonadState Ctx m => Ast.BinOp -> Ast.Expr -> Ast.Expr -> m TAst.TExpr
 boolOp o l r = do
    l' <- convertExpr l
    r' <- convertExpr r
    if fst l' == fst r' && fst l' == BoolType
        then return (BoolType, TAst.TBinOp o l' r')
        else error $ "Type mismatch: " ++ show l ++ " and " ++ show r
 bitOp :: MonadState Ctx m => Ast.BinOp -> Ast.Expr -> Ast.Expr -> m TAst.TExpr
 bitOp o l r = do error $ "Bit operations not implemented"
 shiftOp :: MonadState Ctx m => Ast.BinOp -> Ast.Expr -> Ast.Expr -> m TAst.TExpr
 shiftOp o l r = do error $ "Shift operations not implemented"
--- a/src/Windows12/TAst.hs
+++ b/src/Windows12/TAst.hs
@ -0,0 +1,54 @@
 module Windows12.TAst where
 import Data.Text (Text)
 import Windows12.Ast as Ast
 -- "Typed AST". A second AST that contains more type information
 -- Makes verification easier, and is needed to determine type
 -- of structs when accessing members in CodeGen
 type TExpr = (Type, TExpr')
 data TExpr'
  = TVar Text
  | TIntLit Int
  | TUIntLit Word
  | TFloatLit Double
  | TStrLit Text
  | TBoolLit Bool
  | TCharLit Char
  | TBinOp BinOp TExpr TExpr
  | TUnOp UnOp TExpr
  | TCall Text [TExpr]
  | TIndex TExpr TExpr
  | TMember TExpr Text
  | TCast Type TExpr
  | TSizeof Type
  | TStructInit Text [(Text, TExpr)]
  deriving (Show, Eq)
 type TLVal = (Type, TLVal')
 data TLVal'
  = TDeref TExpr 
  | TId Text 
  | LTIndex TLVal TExpr
  | LTMember TLVal Text
  deriving (Show, Eq)
 data TStmt
  = TExprStmt TExpr
  | TReturn TExpr
  | TIf TExpr [TStmt] (Maybe [TStmt])
  | TWhile TExpr [TStmt]
  | TAssign AssignOp TLVal TExpr
  | TBlock [TStmt]
  | TDeclVar Text Type (Maybe TExpr)
  deriving (Show, Eq)
 data TTLFunc = TTLFunc {funcName :: Text, funcArgs :: [Bind], funcRetType :: Type, funcBody :: [TStmt]}
  deriving (Show, Eq)
 data TProgram = TProgram [TLStruct] [TLEnum] [TTLFunc]
  deriving (Show, Eq)
--- a/windows12.cabal
+++ b/windows12.cabal
@ -69,6 +69,8 @@ executable windows12
        Windows12.Lexer
        Windows12.Parser
        Windows12.CodeGen
        Windows12.TAst
        Windows12.Semant
    -- LANGUAGE extensions used by modules in this package.
    -- other-extensions:
Author	SHA1	Message	Date
Ethan Girouard	3d17813eb4	Implement early version of CodeGen	2024-12-11 16:11:05 -05:00
Ethan Girouard	5a63229e74	Use TAst in CodeGen	2024-12-11 15:58:59 -05:00
Ethan Girouard	d53362f882	Implement conversion from Ast to TAst	2024-12-11 15:58:01 -05:00
Ethan Girouard	fe335fa16e	Create TAst	2024-12-11 15:57:23 -05:00