//! Parsing tools. //! //! This module provides two parsing options: //! - `parse` convenience function //! - `Parser` struct, which parses the input a statement at a time use std::{ fmt::{self, Display, Formatter}, num::{ParseFloatError, ParseIntError}, str::ParseBoolError, }; use crate::{ast::*, DustError, Identifier, LexError, Lexer, Token, TokenKind, TokenOwned, Type}; /// Parses the input into an abstract syntax tree. /// /// # Examples /// ``` /// # use dust_lang::*; /// let source = "42.to_string()"; /// /// assert_eq!( /// parse(source), /// Ok(AbstractSyntaxTree::with_statements([ /// Statement::Expression(Expression::call( /// Expression::field_access( /// Expression::literal(42, (0, 2)), /// Node::new(Identifier::new("to_string"), (3, 12)), /// (0, 12) /// ), /// vec![], /// (0, 14) /// )) /// ])) /// ); /// ``` pub fn parse(source: &str) -> Result { let mut tree = AbstractSyntaxTree::new(); parse_into(source, &mut tree)?; Ok(tree) } pub fn parse_into<'src>( source: &'src str, tree: &mut AbstractSyntaxTree, ) -> Result<(), DustError<'src>> { let lexer = Lexer::new(source); let mut parser = Parser::new(lexer); loop { let node = parser .parse_statement() .map_err(|parse_error| DustError::Parse { parse_error, source, })?; tree.statements.push_back(node); if let Token::Eof = parser.current_token { break; } } Ok(()) } /// Low-level tool for parsing the input a statement at a time. /// /// # Examples /// ``` /// # use std::collections::VecDeque; /// # use dust_lang::*; /// let source = "x = 42"; /// let lexer = Lexer::new(source); /// let mut parser = Parser::new(lexer); /// let mut statements = VecDeque::new(); /// /// loop { /// let statement = parser.parse_statement().unwrap(); /// /// statements.push_back(statement); /// /// if parser.is_eof() { /// break; /// } /// } /// /// let tree = AbstractSyntaxTree { statements }; /// /// ``` pub struct Parser<'src> { lexer: Lexer<'src>, current_token: Token<'src>, current_position: Span, mode: ParserMode, } impl<'src> Parser<'src> { pub fn new(mut lexer: Lexer<'src>) -> Self { let (current_token, current_position) = lexer.next_token().unwrap_or((Token::Eof, (0, 0))); Parser { lexer, current_token, current_position, mode: ParserMode::Normal, } } pub fn is_eof(&self) -> bool { matches!(self.current_token, Token::Eof) } pub fn parse_statement(&mut self) -> Result { let start_position = self.current_position; if let Token::Let = self.current_token { log::trace!("Parsing let statement"); self.next_token()?; let is_mutable = if let Token::Mut = self.current_token { self.next_token()?; true } else { false }; let identifier = self.parse_identifier()?; if let Token::Equal = self.current_token { self.next_token()?; } else { return Err(ParseError::ExpectedToken { expected: TokenKind::Equal, actual: self.current_token.to_owned(), position: self.current_position, }); } let value = self.parse_expression(0)?; let end = if let Token::Semicolon = self.current_token { let end = self.current_position.1; self.next_token()?; end } else { value.position().1 }; let r#let = if is_mutable { LetStatement::LetMut { identifier, value } } else { LetStatement::Let { identifier, value } }; let position = (start_position.0, end); return Ok(Statement::Let(Node::new(r#let, position))); } if let Token::Struct = self.current_token { log::trace!("Parsing struct definition"); self.next_token()?; let name = if let Token::Identifier(_) = self.current_token { self.parse_identifier()? } else { return Err(ParseError::ExpectedToken { expected: TokenKind::Identifier, actual: self.current_token.to_owned(), position: self.current_position, }); }; if let Token::Semicolon = self.current_token { let end = self.current_position.1; self.next_token()?; return Ok(Statement::struct_definition( StructDefinition::Unit { name }, (start_position.0, end), )); } if let Token::LeftParenthesis = self.current_token { self.next_token()?; let mut types = Vec::new(); loop { if let Token::RightParenthesis = self.current_token { self.next_token()?; if let Token::Semicolon = self.current_token { self.next_token()?; } break; } let type_node = self.parse_type()?; types.push(type_node); if let Token::Comma = self.current_token { self.next_token()?; continue; } } let position = (start_position.0, self.current_position.1); return if types.is_empty() { Ok(Statement::struct_definition( StructDefinition::Unit { name }, position, )) } else { Ok(Statement::struct_definition( StructDefinition::Tuple { name, items: types }, position, )) }; } if let Token::LeftCurlyBrace = self.current_token { self.next_token()?; let mut fields = Vec::new(); loop { if let Token::RightCurlyBrace = self.current_token { self.next_token()?; if let Token::Semicolon = self.current_token { self.next_token()?; } break; } let field_name = self.parse_identifier()?; if let Token::Colon = self.current_token { self.next_token()?; } else { return Err(ParseError::ExpectedToken { expected: TokenKind::Colon, actual: self.current_token.to_owned(), position: self.current_position, }); } let field_type = self.parse_type()?; fields.push((field_name, field_type)); if let Token::Comma = self.current_token { self.next_token()?; continue; } } let position = (start_position.0, self.current_position.1); return if fields.is_empty() { Ok(Statement::struct_definition( StructDefinition::Unit { name }, position, )) } else { Ok(Statement::struct_definition( StructDefinition::Fields { name, fields }, position, )) }; } return Err(ParseError::ExpectedTokenMultiple { expected: vec![ TokenKind::LeftParenthesis, TokenKind::LeftCurlyBrace, TokenKind::Semicolon, ], actual: self.current_token.to_owned(), position: self.current_position, }); } let expression = self.parse_expression(0)?; if let Token::Semicolon = self.current_token { let position = (start_position.0, self.current_position.1); self.next_token()?; Ok(Statement::ExpressionNullified(Node::new( expression, position, ))) } else { Ok(Statement::Expression(expression)) } } fn next_token(&mut self) -> Result<(), ParseError> { let (token, position) = self.lexer.next_token()?; self.current_token = token; self.current_position = position; Ok(()) } fn parse_expression(&mut self, mut precedence: u8) -> Result { // Parse a statement starting from the current node. let mut left = if self.current_token.is_prefix() { self.parse_prefix()? } else { self.parse_primary()? }; // While the current token has a higher precedence than the given precedence while precedence < self.current_token.precedence() { // Give precedence to postfix operations left = if self.current_token.is_postfix() { let statement = self.parse_postfix(left)?; precedence = self.current_token.precedence(); // Replace the left-hand side with the postfix operation statement } else { // Replace the left-hand side with the infix operation self.parse_infix(left)? }; } Ok(left) } fn parse_prefix(&mut self) -> Result { log::trace!("Parsing {} as prefix operator", self.current_token); let operator_start = self.current_position.0; match self.current_token { Token::Bang => { self.next_token()?; let operand = self.parse_expression(0)?; let position = (operator_start, self.current_position.1); Ok(Expression::not(operand, position)) } Token::Minus => { self.next_token()?; let operand = self.parse_expression(0)?; let position = (operator_start, self.current_position.1); Ok(Expression::negation(operand, position)) } _ => Err(ParseError::ExpectedTokenMultiple { expected: vec![TokenKind::Bang, TokenKind::Minus], actual: self.current_token.to_owned(), position: self.current_position, }), } } fn parse_primary(&mut self) -> Result { log::trace!("Parsing {} as primary", self.current_token); let start_position = self.current_position; match self.current_token { Token::Async => { let block = self.parse_block()?; let position = (start_position.0, block.position.1); Ok(Expression::block(block.inner, position)) } Token::Boolean(text) => { self.next_token()?; let boolean = text.parse::().map_err(|error| ParseError::Boolean { error, position: start_position, })?; let expression = Expression::literal(boolean, start_position); Ok(expression) } Token::Break => { let break_end = self.current_position.1; self.next_token()?; let (expression_option, end) = if let Token::Semicolon = self.current_token { // Do not consume the semicolon, allowing it to nullify the expression (None, break_end) } else if let Ok(expression) = self.parse_expression(0) { let end = expression.position().1; (Some(expression), end) } else { return Err(ParseError::ExpectedToken { expected: TokenKind::Semicolon, actual: self.current_token.to_owned(), position: self.current_position, }); }; let position = (start_position.0, end); Ok(Expression::r#break(expression_option, position)) } Token::Character(character) => { self.next_token()?; let expression = Expression::literal(character, start_position); Ok(expression) } Token::Float(text) => { self.next_token()?; let float = text.parse::().map_err(|error| ParseError::Float { error, position: start_position, })?; Ok(Expression::literal(float, start_position)) } Token::Identifier(text) => { self.next_token()?; let identifier = Identifier::new(text); if let ParserMode::Condition = self.mode { return Ok(Expression::identifier(identifier, start_position)); } if let Token::LeftCurlyBrace = self.current_token { self.next_token()?; let name = Node::new(identifier, start_position); let mut fields = Vec::new(); loop { if let Token::RightCurlyBrace = self.current_token { self.next_token()?; break; } let field_name = self.parse_identifier()?; if let Token::Colon = self.current_token { self.next_token()?; } else { return Err(ParseError::ExpectedToken { expected: TokenKind::Colon, actual: self.current_token.to_owned(), position: self.current_position, }); } let field_value = self.parse_expression(0)?; fields.push((field_name, field_value)); if let Token::Comma = self.current_token { self.next_token()?; } } let position = (start_position.0, self.current_position.1); return Ok(Expression::r#struct( StructExpression::Fields { name, fields }, position, )); } Ok(Expression::identifier(identifier, start_position)) } Token::Integer(text) => { self.next_token()?; let integer = text.parse::().map_err(|error| ParseError::Integer { error, position: start_position, })?; Ok(Expression::literal(integer, start_position)) } Token::If => { self.next_token()?; let r#if = self.parse_if()?; let position = (start_position.0, self.current_position.1); Ok(Expression::r#if(r#if, position)) } Token::String(text) => { self.next_token()?; Ok(Expression::literal(text.to_string(), start_position)) } Token::LeftCurlyBrace => { let block_node = self.parse_block()?; Ok(Expression::block(block_node.inner, block_node.position)) } Token::LeftParenthesis => { self.next_token()?; let node = self.parse_expression(0)?; if let Token::RightParenthesis = self.current_token { let position = (start_position.0, self.current_position.1); self.next_token()?; Ok(Expression::grouped(node, position)) } else { Err(ParseError::ExpectedToken { expected: TokenKind::RightParenthesis, actual: self.current_token.to_owned(), position: self.current_position, }) } } Token::LeftSquareBrace => { self.next_token()?; if let Token::RightSquareBrace = self.current_token { let position = (start_position.0, self.current_position.1); self.next_token()?; return Ok(Expression::list(Vec::new(), position)); } let first_expression = self.parse_expression(0)?; if let Token::Semicolon = self.current_token { self.next_token()?; let repeat_operand = self.parse_expression(0)?; if let Token::RightSquareBrace = self.current_token { let position = (start_position.0, self.current_position.1); self.next_token()?; return Ok(Expression::auto_fill_list( first_expression, repeat_operand, position, )); } else { return Err(ParseError::ExpectedToken { expected: TokenKind::RightSquareBrace, actual: self.current_token.to_owned(), position: self.current_position, }); } } let mut expressions = vec![first_expression]; loop { if let Token::RightSquareBrace = self.current_token { let position = (start_position.0, self.current_position.1); self.next_token()?; return Ok(Expression::list(expressions, position)); } if let Token::Comma = self.current_token { self.next_token()?; continue; } let expression = self.parse_expression(0)?; expressions.push(expression); } } Token::Loop => { self.next_token()?; let block = self.parse_block()?; let position = (start_position.0, block.position.1); Ok(Expression::infinite_loop(block, position)) } Token::Map => { self.next_token()?; if let Token::LeftCurlyBrace = self.current_token { self.next_token()?; } else { return Err(ParseError::ExpectedToken { expected: TokenKind::LeftCurlyBrace, actual: self.current_token.to_owned(), position: self.current_position, }); } let mut fields = Vec::new(); loop { if let Token::RightCurlyBrace = self.current_token { let position = (start_position.0, self.current_position.1); self.next_token()?; return Ok(Expression::map(fields, position)); } let field_name = self.parse_identifier()?; if let Token::Equal = self.current_token { self.next_token()?; } else { return Err(ParseError::ExpectedToken { expected: TokenKind::Equal, actual: self.current_token.to_owned(), position: self.current_position, }); } let field_value = self.parse_expression(0)?; fields.push((field_name, field_value)); if let Token::Comma = self.current_token { self.next_token()?; } } } Token::While => { self.next_token()?; let condition = self.parse_expression(0)?; let block = self.parse_block()?; let position = (start_position.0, block.position.1); Ok(Expression::while_loop(condition, block, position)) } _ => Err(ParseError::ExpectedTokenMultiple { expected: vec![ TokenKind::Async, TokenKind::Boolean, TokenKind::Float, TokenKind::Identifier, TokenKind::Integer, TokenKind::If, TokenKind::LeftCurlyBrace, TokenKind::LeftParenthesis, TokenKind::LeftSquareBrace, TokenKind::String, TokenKind::While, ], actual: self.current_token.to_owned(), position: self.current_position, }), } } fn parse_infix(&mut self, left: Expression) -> Result { log::trace!("Parsing {} as infix operator", self.current_token); let operator_precedence = self.current_token.precedence() - if self.current_token.is_right_associative() { 1 } else { 0 }; let left_start = left.position().0; if let Token::Equal = &self.current_token { self.next_token()?; let value = self.parse_expression(operator_precedence)?; let position = (left_start, value.position().1); return Ok(Expression::assignment(left, value, position)); } if let Token::PlusEqual | Token::MinusEqual = &self.current_token { let math_operator = match self.current_token { Token::PlusEqual => MathOperator::Add, Token::MinusEqual => MathOperator::Subtract, _ => unreachable!(), }; let operator = Node::new(math_operator, self.current_position); self.next_token()?; let value = self.parse_expression(operator_precedence)?; let position = (left_start, value.position().1); return Ok(Expression::operator( OperatorExpression::CompoundAssignment { assignee: left, operator, modifier: value, }, position, )); } if let Token::DoubleDot = &self.current_token { self.next_token()?; let end = self.parse_expression(operator_precedence)?; let position = (left_start, end.position().1); return Ok(Expression::exclusive_range(left, end, position)); } if let Token::Minus | Token::Plus | Token::Star | Token::Slash | Token::Percent = &self.current_token { let math_operator = match &self.current_token { Token::Minus => Node::new(MathOperator::Subtract, self.current_position), Token::Plus => Node::new(MathOperator::Add, self.current_position), Token::Star => Node::new(MathOperator::Multiply, self.current_position), Token::Slash => Node::new(MathOperator::Divide, self.current_position), Token::Percent => Node::new(MathOperator::Modulo, self.current_position), _ => unreachable!(), }; self.next_token()?; let right = self.parse_expression(operator_precedence)?; let position = (left_start, right.position().1); return Ok(Expression::operator( OperatorExpression::Math { left, operator: math_operator, right, }, position, )); } if let Token::DoubleEqual | Token::BangEqual | Token::Less | Token::LessEqual | Token::Greater | Token::GreaterEqual = &self.current_token { let comparison_operator = match &self.current_token { Token::DoubleEqual => Node::new(ComparisonOperator::Equal, self.current_position), Token::BangEqual => Node::new(ComparisonOperator::NotEqual, self.current_position), Token::Less => Node::new(ComparisonOperator::LessThan, self.current_position), Token::LessEqual => { Node::new(ComparisonOperator::LessThanOrEqual, self.current_position) } Token::Greater => Node::new(ComparisonOperator::GreaterThan, self.current_position), Token::GreaterEqual => Node::new( ComparisonOperator::GreaterThanOrEqual, self.current_position, ), _ => unreachable!(), }; self.next_token()?; let right = self.parse_expression(operator_precedence)?; let position = (left_start, right.position().1); return Ok(Expression::operator( OperatorExpression::Comparison { left, operator: comparison_operator, right, }, position, )); } let logic_operator = match &self.current_token { Token::DoubleAmpersand => Node::new(LogicOperator::And, self.current_position), Token::DoublePipe => Node::new(LogicOperator::Or, self.current_position), _ => { return Err(ParseError::UnexpectedToken { actual: self.current_token.to_owned(), position: self.current_position, }) } }; self.next_token()?; let right = self.parse_expression(operator_precedence)?; let position = (left_start, right.position().1); Ok(Expression::operator( OperatorExpression::Logic { left, operator: logic_operator, right, }, position, )) } fn parse_postfix(&mut self, left: Expression) -> Result { log::trace!("Parsing {} as postfix operator", self.current_token); let expression = match &self.current_token { Token::Dot => { self.next_token()?; if let Token::Integer(text) = &self.current_token { let index = text.parse::().map_err(|error| ParseError::Integer { error, position: self.current_position, })?; let index_node = Node::new(index, self.current_position); let position = (left.position().0, self.current_position.1); self.next_token()?; Expression::tuple_access(left, index_node, position) } else { let field = self.parse_identifier()?; let position = (left.position().0, field.position.1); Expression::field_access(left, field, position) } } Token::LeftParenthesis => { self.next_token()?; let mut arguments = Vec::new(); while self.current_token != Token::RightParenthesis { let argument = self.parse_expression(0)?; arguments.push(argument); if let Token::Comma = self.current_token { self.next_token()?; } else { break; } } self.next_token()?; let position = (left.position().0, self.current_position.1); Expression::call(left, arguments, position) } Token::LeftSquareBrace => { self.next_token()?; let index = self.parse_expression(0)?; let operator_end = if let Token::RightSquareBrace = self.current_token { let end = self.current_position.1; self.next_token()?; end } else { return Err(ParseError::ExpectedToken { expected: TokenKind::RightSquareBrace, actual: self.current_token.to_owned(), position: self.current_position, }); }; let position = (left.position().0, operator_end); Expression::list_index(left, index, position) } _ => { return Err(ParseError::ExpectedTokenMultiple { expected: vec![ TokenKind::Dot, TokenKind::LeftParenthesis, TokenKind::LeftSquareBrace, ], actual: self.current_token.to_owned(), position: self.current_position, }); } }; if self.current_token.is_postfix() { self.parse_postfix(expression) } else { Ok(expression) } } fn parse_if(&mut self) -> Result { // Assume that the "if" token has already been consumed self.mode = ParserMode::Condition; let condition = self.parse_expression(0)?; self.mode = ParserMode::Normal; let if_block = self.parse_block()?; if let Token::Else = self.current_token { self.next_token()?; let if_keyword_start = self.current_position.0; if let Token::If = self.current_token { self.next_token()?; let if_expression = self.parse_if()?; let position = (if_keyword_start, self.current_position.1); Ok(IfExpression::IfElse { condition, if_block, r#else: ElseExpression::If(Node::new(Box::new(if_expression), position)), }) } else { let else_block = self.parse_block()?; Ok(IfExpression::IfElse { condition, if_block, r#else: ElseExpression::Block(else_block), }) } } else { Ok(IfExpression::If { condition, if_block, }) } } fn parse_identifier(&mut self) -> Result, ParseError> { if let Token::Identifier(text) = self.current_token { let position = self.current_position; self.next_token()?; Ok(Node::new(Identifier::new(text), position)) } else { Err(ParseError::ExpectedToken { expected: TokenKind::Identifier, actual: self.current_token.to_owned(), position: self.current_position, }) } } fn parse_block(&mut self) -> Result, ParseError> { let left_start = self.current_position.0; let is_async = if let Token::Async = self.current_token { self.next_token()?; true } else { false }; if let Token::LeftCurlyBrace = self.current_token { self.next_token()?; } else { return Err(ParseError::ExpectedToken { expected: TokenKind::LeftCurlyBrace, actual: self.current_token.to_owned(), position: self.current_position, }); } let mut statements = Vec::new(); loop { if let Token::RightCurlyBrace = self.current_token { let position = (left_start, self.current_position.1); self.next_token()?; return if is_async { Ok(Node::new(BlockExpression::Async(statements), position)) } else { Ok(Node::new(BlockExpression::Sync(statements), position)) }; } let statement = self.parse_statement()?; statements.push(statement); } } fn parse_type(&mut self) -> Result, ParseError> { let r#type = match self.current_token { Token::Bool => Type::Boolean, Token::FloatKeyword => Type::Float, Token::Int => Type::Integer, _ => { return Err(ParseError::ExpectedTokenMultiple { expected: vec![TokenKind::Bool, TokenKind::FloatKeyword, TokenKind::Int], actual: self.current_token.to_owned(), position: self.current_position, }); } }; let position = self.current_position; self.next_token()?; Ok(Node::new(r#type, position)) } } #[derive(Debug, PartialEq, Clone)] pub enum ParserMode { Condition, Normal, } #[derive(Debug, PartialEq, Clone)] pub enum ParseError { Boolean { error: ParseBoolError, position: Span, }, Lex(LexError), ExpectedAssignment { actual: Statement, }, ExpectedExpression { actual: Statement, }, ExpectedIdentifierNode { actual: Expression, }, ExpectedIdentifierToken { actual: TokenOwned, position: Span, }, ExpectedToken { expected: TokenKind, actual: TokenOwned, position: Span, }, ExpectedTokenMultiple { expected: Vec, actual: TokenOwned, position: Span, }, UnexpectedToken { actual: TokenOwned, position: Span, }, Float { error: ParseFloatError, position: Span, }, Integer { error: ParseIntError, position: Span, }, } impl From for ParseError { fn from(v: LexError) -> Self { Self::Lex(v) } } impl ParseError { pub fn position(&self) -> Span { match self { ParseError::Boolean { position, .. } => *position, ParseError::ExpectedAssignment { actual } => actual.position(), ParseError::ExpectedExpression { actual } => actual.position(), ParseError::ExpectedIdentifierNode { actual } => actual.position(), ParseError::ExpectedIdentifierToken { position, .. } => *position, ParseError::ExpectedToken { position, .. } => *position, ParseError::ExpectedTokenMultiple { position, .. } => *position, ParseError::Float { position, .. } => *position, ParseError::Integer { position, .. } => *position, ParseError::Lex(error) => error.position(), ParseError::UnexpectedToken { position, .. } => *position, } } } impl Display for ParseError { fn fmt(&self, f: &mut Formatter) -> fmt::Result { match self { Self::Boolean { error, .. } => write!(f, "{}", error), Self::ExpectedAssignment { .. } => write!(f, "Expected assignment"), Self::ExpectedExpression { .. } => write!(f, "Expected expression"), Self::ExpectedIdentifierNode { actual } => { write!(f, "Expected identifier, found {actual}") } Self::ExpectedIdentifierToken { actual, .. } => { write!(f, "Expected identifier, found {actual}") } Self::ExpectedToken { expected, actual, .. } => write!(f, "Expected token {expected}, found {actual}"), Self::ExpectedTokenMultiple { expected, actual, .. } => { write!(f, "Expected one of")?; for (i, token_kind) in expected.iter().enumerate() { if i == 0 { write!(f, " {token_kind}")?; } else if i == expected.len() - 1 { write!(f, " or {token_kind}")?; } else { write!(f, ", {token_kind}")?; } } write!(f, ", found {actual}") } Self::Float { error, .. } => write!(f, "{}", error), Self::Integer { error, .. } => write!(f, "{}", error), Self::Lex(error) => write!(f, "{}", error), Self::UnexpectedToken { actual, .. } => write!(f, "Unexpected token {actual}"), } } } #[cfg(test)] mod tests { use crate::{Identifier, Type}; use super::*; #[test] fn character_literal() { let source = "'a'"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::literal('a', (0, 3))) ])) ); } #[test] fn break_loop() { let source = "loop { break; }"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::infinite_loop( Node::new( BlockExpression::Sync(vec![Statement::ExpressionNullified(Node::new( Expression::r#break(None, (7, 12)), (7, 13) ))]), (5, 15) ), (0, 15) )) ])) ); } #[test] fn built_in_function() { let source = "42.to_string()"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::call( Expression::field_access( Expression::literal(42, (0, 2)), Node::new(Identifier::new("to_string"), (3, 12)), (0, 12) ), vec![], (0, 14) )) ])) ); } #[test] fn map_expression() { let source = "map { x = \"1\", y = 2, z = 3.0 }"; assert_eq!( parse(source), Ok(AbstractSyntaxTree { statements: [Statement::Expression(Expression::map( vec![ ( Node::new(Identifier::new("x"), (6, 7)), Expression::literal("1".to_string(), (10, 13)), ), ( Node::new(Identifier::new("y"), (15, 16)), Expression::literal(2, (19, 20)), ), ( Node::new(Identifier::new("z"), (22, 23)), Expression::literal(3.0, (26, 29)), ), ], (0, 31), ))] .into(), }) ); } #[test] fn let_mut_while_loop() { let source = "let mut x = 0; while x < 10 { x += 1 }; x"; assert_eq!( parse(source), Ok(AbstractSyntaxTree { statements: [ Statement::Let(Node::new( LetStatement::LetMut { identifier: Node::new(Identifier::new("x"), (8, 9)), value: Expression::literal(0, (12, 13)), }, (0, 14), )), Statement::ExpressionNullified(Node::new( Expression::while_loop( Expression::comparison( Expression::identifier(Identifier::new("x"), (21, 22)), Node::new(ComparisonOperator::LessThan, (23, 24)), Expression::literal(10, (25, 27)), (21, 27), ), Node::new( BlockExpression::Sync(vec![Statement::Expression( Expression::compound_assignment( Expression::identifier(Identifier::new("x"), (30, 31)), Node::new(MathOperator::Add, (32, 34)), Expression::literal(1, (35, 36)), (30, 36), ), )]), (28, 38), ), (15, 38), ), (15, 39) )), Statement::Expression(Expression::identifier(Identifier::new("x"), (40, 41)),), ] .into() }) ); } #[test] fn let_statement() { let source = "let x = 42;"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([Statement::Let( Node::new( LetStatement::Let { identifier: Node::new(Identifier::new("x"), (4, 5)), value: Expression::literal(42, (8, 10)), }, (0, 11), ) )])) ); } #[test] fn let_mut_statement() { let source = "let mut x = false;"; assert_eq!( parse(source), Ok(AbstractSyntaxTree { statements: [Statement::Let(Node::new( LetStatement::LetMut { identifier: Node::new(Identifier::new("x"), (8, 9)), value: Expression::literal(false, (12, 17)), }, (0, 18), ))] .into() }) ); } #[test] fn async_block() { let source = "async { x = 42; y = 4.0 }"; assert_eq!( parse(source), Ok(AbstractSyntaxTree { statements: [Statement::Expression(Expression::block( BlockExpression::Async(vec![ Statement::ExpressionNullified(Node::new( Expression::operator( OperatorExpression::Assignment { assignee: Expression::identifier(Identifier::new("x"), (8, 9)), value: Expression::literal(42, (12, 14)), }, (8, 14) ), (8, 15) )), Statement::Expression(Expression::operator( OperatorExpression::Assignment { assignee: Expression::identifier(Identifier::new("y"), (16, 17)), value: Expression::literal(4.0, (20, 23)), }, (16, 23) )) ]), (0, 25) ))] .into() }) ); } #[test] fn tuple_struct_access() { let source = "Foo(42, \"bar\").0"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::tuple_access( Expression::call( Expression::identifier(Identifier::new("Foo"), (0, 3)), vec![ Expression::literal(42, (4, 6)), Expression::literal("bar".to_string(), (8, 13)), ], (0, 15) ), Node::new(0, (15, 16)), (0, 16) )) ])) ); } #[test] fn fields_struct_instantiation() { let source = "Foo { a: 42, b: 4.0 }"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::r#struct( StructExpression::Fields { name: Node::new(Identifier::new("Foo"), (0, 3)), fields: vec![ ( Node::new(Identifier::new("a"), (6, 7)), Expression::literal(42, (9, 11)), ), ( Node::new(Identifier::new("b"), (13, 14)), Expression::literal(4.0, (16, 19)) ) ] }, (0, 21) )) ])) ); } #[test] fn fields_struct() { let source = "struct Foo { a: int, b: float }"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::struct_definition( StructDefinition::Fields { name: Node::new(Identifier::new("Foo"), (7, 10)), fields: vec![ ( Node::new(Identifier::new("a"), (13, 14)), Node::new(Type::Integer, (16, 19)) ), ( Node::new(Identifier::new("b"), (21, 22)), Node::new(Type::Float, (24, 29)) ) ] }, (0, 31) ) ])) ); } #[test] fn tuple_struct_instantiation() { let source = "Foo(1, 2.0)"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::call( Expression::identifier(Identifier::new("Foo"), (0, 3)), vec![ Expression::literal(1, (4, 5)), Expression::literal(2.0, (7, 10)) ], (0, 11) )) ])) ); } #[test] fn tuple_struct_definition() { let source = "struct Foo(int, float);"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::StructDefinition(Node::new( StructDefinition::Tuple { name: Node::new(Identifier::new("Foo"), (7, 10)), items: vec![ Node::new(Type::Integer, (11, 14)), Node::new(Type::Float, (16, 21)), ], }, (0, 23) )) ])) ); } #[test] fn unit_struct() { let source = "struct Foo;"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::StructDefinition(Node::new( StructDefinition::Unit { name: Node::new(Identifier::new("Foo"), (7, 10)), }, (0, 11) )) ])) ); } #[test] fn list_index_nested() { let source = "[1, [2], 3][1][0]"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::list_index( Expression::list_index( Expression::list( [ Expression::literal(1, (1, 2)), Expression::list([Expression::literal(2, (5, 6))], (4, 7)), Expression::literal(3, (9, 10)), ], (0, 11) ), Expression::literal(1, (12, 13)), (0, 14) ), Expression::literal(0, (15, 16)), (0, 17) ),) ])) ); } #[test] fn range() { let source = "0..42"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::exclusive_range( Expression::literal(0, (0, 1)), Expression::literal(42, (3, 5)), (0, 5) )) ])) ); } #[test] fn negate_variable() { let source = "a = 1; -a"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::ExpressionNullified(Node::new( Expression::operator( OperatorExpression::Assignment { assignee: Expression::identifier(Identifier::new("a"), (0, 1)), value: Expression::literal(1, (4, 5)), }, (0, 5) ), (0, 6) )), Statement::Expression(Expression::operator( OperatorExpression::Negation(Expression::identifier( Identifier::new("a"), (8, 9) )), (7, 9) )) ])) ); } #[test] fn negate_expression() { let source = "-(1 + 1)"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::operator( OperatorExpression::Negation(Expression::grouped( Expression::operator( OperatorExpression::Math { left: Expression::literal(1, (2, 3)), operator: Node::new(MathOperator::Add, (4, 5)), right: Expression::literal(1, (6, 7)), }, (2, 7) ), (1, 8) )), (0, 8) )) ])) ); } #[test] fn not_expression() { let source = "!(1 > 42)"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::operator( OperatorExpression::Not(Expression::grouped( Expression::operator( OperatorExpression::Comparison { left: Expression::literal(1, (2, 3)), operator: Node::new(ComparisonOperator::GreaterThan, (4, 5)), right: Expression::literal(42, (6, 8)), }, (2, 8) ), (1, 9) )), (0, 9) )) ])) ); } #[test] fn not_variable() { let source = "a = false; !a"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::ExpressionNullified(Node::new( Expression::operator( OperatorExpression::Assignment { assignee: Expression::identifier(Identifier::new("a"), (0, 1)), value: Expression::literal(false, (4, 9)), }, (0, 9) ), (0, 10) )), Statement::Expression(Expression::operator( OperatorExpression::Not(Expression::identifier(Identifier::new("a"), (12, 13))), (11, 13) )), ])) ); } #[test] fn r#if() { let source = "if x { y }"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::r#if( IfExpression::If { condition: Expression::identifier(Identifier::new("x"), (3, 4)), if_block: Node::new( BlockExpression::Sync(vec![Statement::Expression( Expression::identifier(Identifier::new("y"), (7, 8)) )]), (5, 10) ) }, (0, 10) )) ])) ); } #[test] fn if_else() { let source = "if x { y } else { z }"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::r#if( IfExpression::IfElse { condition: Expression::identifier(Identifier::new("x"), (3, 4)), if_block: Node::new( BlockExpression::Sync(vec![Statement::Expression( Expression::identifier(Identifier::new("y"), (7, 8)) )]), (5, 10) ), r#else: ElseExpression::Block(Node::new( BlockExpression::Sync(vec![Statement::Expression( Expression::identifier(Identifier::new("z"), (18, 19)) )]), (16, 21) )) }, (0, 21) )) ])) ); } #[test] fn if_else_if_else() { let source = "if x { y } else if z { a } else { b }"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::r#if( IfExpression::IfElse { condition: Expression::identifier(Identifier::new("x"), (3, 4)), if_block: Node::new( BlockExpression::Sync(vec![Statement::Expression( Expression::identifier(Identifier::new("y"), (7, 8)) )]), (5, 10) ), r#else: ElseExpression::If(Node::new( Box::new(IfExpression::IfElse { condition: Expression::identifier(Identifier::new("z"), (19, 20)), if_block: Node::new( BlockExpression::Sync(vec![Statement::Expression( Expression::identifier(Identifier::new("a"), (23, 24)) )]), (21, 26) ), r#else: ElseExpression::Block(Node::new( BlockExpression::Sync(vec![Statement::Expression( Expression::identifier(Identifier::new("b"), (34, 35)) )]), (32, 37) )), }), (16, 37) )), }, (0, 37) )) ])) ) } #[test] fn while_loop() { let source = "while x < 10 { x += 1 }"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::while_loop( Expression::operator( OperatorExpression::Comparison { left: Expression::identifier(Identifier::new("x"), (6, 7)), operator: Node::new(ComparisonOperator::LessThan, (8, 9)), right: Expression::literal(10, (10, 12)), }, (6, 12) ), Node::new( BlockExpression::Sync(vec![Statement::Expression(Expression::operator( OperatorExpression::CompoundAssignment { assignee: Expression::identifier(Identifier::new("x"), (15, 16)), operator: Node::new(MathOperator::Add, (17, 19)), modifier: Expression::literal(1, (20, 21)), }, (15, 21) ))]), (13, 23) ), (0, 23) )) ])) ) } #[test] fn add_assign() { let source = "a += 1"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::operator( OperatorExpression::CompoundAssignment { assignee: Expression::identifier(Identifier::new("a"), (0, 1)), operator: Node::new(MathOperator::Add, (2, 4)), modifier: Expression::literal(1, (5, 6)), }, (0, 6) )) ])) ) } #[test] fn or() { let source = "true || false"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::operator( OperatorExpression::Logic { left: Expression::literal(true, (0, 4)), operator: Node::new(LogicOperator::Or, (5, 7)), right: Expression::literal(false, (8, 13)), }, (0, 13) )) ])) ) } #[test] fn block_with_one_statement() { let source = "{ 40 + 2 }"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::block( BlockExpression::Sync(vec![Statement::Expression(Expression::operator( OperatorExpression::Math { left: Expression::literal(40, (2, 4)), operator: Node::new(MathOperator::Add, (5, 6)), right: Expression::literal(2, (7, 8)), }, (2, 8) ))]), (0, 10) )) ])) ) } #[test] fn block_with_assignment() { let source = "{ foo = 42; bar = 42; baz = \"42\" }"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::block( BlockExpression::Sync(vec![ Statement::ExpressionNullified(Node::new( Expression::assignment( Expression::identifier("foo", (2, 5)), Expression::literal(42, (8, 10)), (2, 10) ), (2, 11) )), Statement::ExpressionNullified(Node::new( Expression::assignment( Expression::identifier("bar", (12, 15)), Expression::literal(42, (18, 20)), (12, 20) ), (12, 21) )), Statement::Expression(Expression::assignment( Expression::identifier("baz", (22, 25)), Expression::literal("42", (28, 32)), (22, 32) )) ]), (0, 34) )) ])) ) } #[test] fn equal() { let source = "42 == 42"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::comparison( Expression::literal(42, (0, 2)), Node::new(ComparisonOperator::Equal, (3, 5)), Expression::literal(42, (6, 8)), (0, 8) )) ])) ); } #[test] fn less_than() { let source = "1 < 2"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::comparison( Expression::literal(1, (0, 1)), Node::new(ComparisonOperator::LessThan, (2, 3)), Expression::literal(2, (4, 5)), (0, 5) )) ])) ); } #[test] fn less_than_or_equal() { let source = "1 <= 2"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::comparison( Expression::literal(1, (0, 1)), Node::new(ComparisonOperator::LessThanOrEqual, (2, 4)), Expression::literal(2, (5, 6)), (0, 6) )) ])) ); } #[test] fn greater_than_or_equal() { let source = "1 >= 2"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::comparison( Expression::literal(1, (0, 1)), Node::new(ComparisonOperator::GreaterThanOrEqual, (2, 4)), Expression::literal(2, (5, 6)), (0, 6) )) ])) ); } #[test] fn greater_than() { let source = "1 > 2"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::comparison( Expression::literal(1, (0, 1)), Node::new(ComparisonOperator::GreaterThan, (2, 3)), Expression::literal(2, (4, 5)), (0, 5) )) ])) ); } #[test] fn subtract_negative_integers() { let source = "-1 - -2"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::math( Expression::literal(-1, (0, 2)), MathOperator::subtract((3, 4)), Expression::literal(-2, (5, 7)), (0, 7) )) ])) ); } #[test] fn modulo() { let source = "42 % 2"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::math( Expression::literal(42, (0, 2)), MathOperator::modulo((3, 4)), Expression::literal(2, (5, 6)), (0, 6) )) ])) ); } #[test] fn divide() { let source = "42 / 2"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::math( Expression::literal(42, (0, 2)), MathOperator::divide((3, 4)), Expression::literal(2, (5, 6)), (0, 6) )) ])) ); } #[test] fn string_concatenation() { let source = "\"Hello, \" + \"World!\""; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::math( Expression::literal("Hello, ", (0, 9)), MathOperator::add((10, 11)), Expression::literal("World!", (12, 20)), (0, 20) )) ])) ); } #[test] fn string() { let source = "\"Hello, World!\""; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::literal("Hello, World!", (0, 15))) ])) ); } #[test] fn boolean() { let source = "true"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::literal(true, (0, 4))) ])) ); } #[test] fn list_index() { let source = "[1, 2, 3][0]"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::list_index( Expression::list( [ Expression::literal(1, (1, 2)), Expression::literal(2, (4, 5)), Expression::literal(3, (7, 8)), ], (0, 9) ), Expression::literal(0, (10, 11)), (0, 12) )) ])) ); } #[test] fn property_access() { let source = "a.b"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::field_access( Expression::identifier(Identifier::new("a"), (0, 1)), Node::new(Identifier::new("b"), (2, 3)), (0, 3) )) ])) ); } #[test] fn complex_list() { let source = "[1, 1 + 1, 2 + (4 * 10)]"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::list( [ Expression::literal(1, (1, 2)), Expression::math( Expression::literal(1, (4, 5)), MathOperator::add((6, 7)), Expression::literal(1, (8, 9)), (4, 9) ), Expression::math( Expression::literal(2, (11, 12)), Node::new(MathOperator::Add, (13, 14)), Expression::grouped( Expression::math( Expression::literal(4, (16, 17)), MathOperator::multiply((18, 19)), Expression::literal(10, (20, 22)), (16, 22) ), (15, 23) ), (11, 23) ), ], (0, 24) )) ])) ); } #[test] fn list() { let source = "[1, 2]"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::list( [ Expression::literal(1, (1, 2)), Expression::literal(2, (4, 5)) ], (0, 6) )) ])) ); } #[test] fn empty_list() { let source = "[]"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::list(vec![], (0, 2))) ])) ); } #[test] fn float() { let source = "42.0"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::literal(42.0, (0, 4))) ])) ); } #[test] fn add() { let source = "1 + 2"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::math( Expression::literal(1, (0, 1)), MathOperator::add((2, 3)), Expression::literal(2, (4, 5)), (0, 5) )) ])) ); } #[test] fn multiply() { let source = "1 * 2"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::math( Expression::literal(1, (0, 1)), MathOperator::multiply((2, 3)), Expression::literal(2, (4, 5)), (0, 5) ),) ])) ); } #[test] fn add_and_multiply() { let source = "1 + 2 * 3"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::math( Expression::literal(1, (0, 1)), MathOperator::add((2, 3)), Expression::math( Expression::literal(2, (4, 5)), MathOperator::multiply((6, 7)), Expression::literal(3, (8, 9)), (4, 9) ), (0, 9) )), ])) ); } #[test] fn assignment() { let source = "a = 1 + 2 * 3"; assert_eq!( parse(source), Ok(AbstractSyntaxTree::with_statements([ Statement::Expression(Expression::assignment( Expression::identifier("a", (0, 1)), Expression::math( Expression::literal(1, (4, 5)), MathOperator::add((6, 7)), Expression::math( Expression::literal(2, (8, 9)), MathOperator::multiply((10, 11)), Expression::literal(3, (12, 13)), (8, 13) ), (4, 13) ), (0, 13) )) ])) ); } }