module Language.Elna.Frontend.Parser ( Parser , programP ) where import Control.Monad (void) import Control.Monad.Combinators.Expr (Operator(..), makeExprParser) import Data.Text (Text) import qualified Data.Text as Text import Data.Void (Void) import Language.Elna.Frontend.AST ( Declaration(..) , Identifier(..) , Parameter(..) , Program(..) , Statement(..) , TypeExpression(..) , VariableDeclaration(..) , VariableAccess(..) , Condition(..) , Expression(..) , Literal(..) ) import Text.Megaparsec ( Parsec , () , MonadParsec(..) , eof , optional , between , sepBy , choice ) import qualified Text.Megaparsec.Char.Lexer as Lexer import Text.Megaparsec.Char ( alphaNumChar , char , letterChar , space1 , string ) import Control.Applicative (Alternative(..)) import Data.Maybe (isJust) type Parser = Parsec Void Text literalP :: Parser Literal literalP = HexadecimalLiteral <$> Lexer.signed space hexadecimalP <|> DecimalLiteral <$> Lexer.signed space decimalP <|> CharacterLiteral <$> lexeme charP where charP = fromIntegral . fromEnum <$> between (char '\'') (char '\'') Lexer.charLiteral typeDefinitionP :: Parser Declaration typeDefinitionP = TypeDefinition <$> (symbol "type" *> identifierP) <*> (symbol "=" *> typeExpressionP) <* semicolonP "type definition" termP :: Parser Expression termP = choice [ parensP expressionP , LiteralExpression <$> literalP , VariableExpression <$> variableAccessP ] operatorTable :: [[Operator Parser Expression]] operatorTable = [ unaryOperator , factorOperator , termOperator ] where unaryOperator = [ prefix "-" NegationExpression , prefix "+" id ] factorOperator = [ binary "*" ProductExpression , binary "/" DivisionExpression ] termOperator = [ binary "+" SumExpression , binary "-" SubtractionExpression ] prefix name f = Prefix (f <$ symbol name) binary name f = InfixL (f <$ symbol name) expressionP :: Parser Expression expressionP = makeExprParser termP operatorTable variableAccessP :: Parser VariableAccess variableAccessP = VariableAccess <$> identifierP {- do identifier <- identifierP indices <- many $ bracketsP expressionP pure $ foldr (flip ArrayAccess) (VariableAccess identifier) indices -} conditionP :: Parser Condition conditionP = do lhs <- expressionP conditionCons <- choice comparisonOperator conditionCons lhs <$> expressionP where comparisonOperator = [ symbol "<=" >> pure LessOrEqualCondition , symbol "<" >> pure LessCondition , symbol ">=" >> pure GreaterOrEqualCondition , symbol ">" >> pure GreaterCondition , symbol "=" >> pure EqualCondition , symbol "#" >> pure NonEqualCondition ] symbol :: Text -> Parser Text symbol = Lexer.symbol space space :: Parser () space = Lexer.space space1 (Lexer.skipLineComment "//") $ Lexer.skipBlockComment "/*" "*/" lexeme :: forall a. Parser a -> Parser a lexeme = Lexer.lexeme space blockP :: forall a. Parser a -> Parser a blockP = between (symbol "{") (symbol "}") parensP :: forall a. Parser a -> Parser a parensP = between (symbol "(") (symbol ")") bracketsP :: forall a. Parser a -> Parser a bracketsP = between (symbol "[") (symbol "]") colonP :: Parser () colonP = void $ symbol ":" commaP :: Parser () commaP = void $ symbol "," semicolonP :: Parser () semicolonP = void $ symbol ";" decimalP :: Integral a => Parser a decimalP = lexeme Lexer.decimal hexadecimalP :: Integral a => Parser a hexadecimalP = string "0x" *> lexeme Lexer.hexadecimal identifierP :: Parser Identifier identifierP = let wordParser = (:) <$> letterChar <*> many alphaNumChar "identifier" in fmap Identifier $ lexeme $ Text.pack <$> wordParser procedureP :: Parser () procedureP = void $ symbol "proc" parameterP :: Parser Parameter parameterP = paramCons <$> optional (symbol "ref") <*> identifierP <*> (colonP *> typeExpressionP) where paramCons ref name typeName = Parameter name typeName (isJust ref) typeExpressionP :: Parser TypeExpression typeExpressionP = arrayTypeExpression <|> NamedType <$> identifierP "type expression" where arrayTypeExpression = ArrayType <$> (symbol "array" *> bracketsP literalP) <*> (symbol "of" *> typeExpressionP) procedureDeclarationP :: Parser Declaration procedureDeclarationP = procedureCons <$> (procedureP *> identifierP) <*> parensP (sepBy parameterP commaP) <*> blockP ((,) <$> many variableDeclarationP <*> many statementP) "procedure definition" where procedureCons procedureName parameters (variables, body) = ProcedureDeclaration procedureName parameters variables body statementP :: Parser Statement statementP = EmptyStatement <$ semicolonP <|> ifElseP <|> CompoundStatement <$> blockP (many statementP) <|> try assignmentP -- <|> try whileP <|> callP "statement" where callP = CallStatement <$> identifierP <*> parensP (sepBy expressionP commaP) <* semicolonP ifElseP = IfStatement <$> (symbol "if" *> parensP conditionP) <*> statementP <*> optional (symbol "else" *> statementP) {-whileP = WhileStatement <$> (symbol "while" *> parensP conditionP) <*> statementP -} assignmentP = AssignmentStatement <$> variableAccessP <* symbol ":=" <*> expressionP <* semicolonP variableDeclarationP :: Parser VariableDeclaration variableDeclarationP = VariableDeclaration <$> (symbol "var" *> identifierP) <*> (colonP *> typeExpressionP) <* semicolonP "variable declaration" declarationP :: Parser Declaration declarationP = procedureDeclarationP <|> typeDefinitionP programP :: Parser Program programP = Program <$> many declarationP <* eof