use std::char; use std::error::Error; use std::fmt; use std::iter::Peekable; use std::str::Chars; #[derive(Debug, Clone)] pub enum LexError { UnexpectedChar, MalformedEscapeSequence, MalformedNumber, MalformedChar, Nothing, } impl Error for LexError { fn description(&self) -> &str { match *self { LexError::UnexpectedChar => "Unexpected character in input", LexError::MalformedEscapeSequence => "Unexpected values in escape sequence", LexError::MalformedNumber => "Unexpected characters in number", LexError::MalformedChar => "Char constant not a single character", LexError::Nothing => "This error is for internal use only", } } } impl fmt::Display for LexError { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { write!(f, "{}", self.description()) } } #[derive(Debug)] pub enum ParseError { BadInput, InputPastEndOfFile, UnknownOperator, MissingRParen, MissingLCurly, MissingRCurly, MissingRSquare, MalformedCallExpr, MalformedIndexExpr, VarExpectsIdentifier, FnMissingName, FnMissingParams, } impl Error for ParseError { fn description(&self) -> &str { match *self { ParseError::BadInput => "Unparseable characters in the input stream", ParseError::InputPastEndOfFile => "Input past end of file", ParseError::UnknownOperator => "Unknown operator", ParseError::MissingRParen => "Expected ')'", ParseError::MissingLCurly => "Expected '{'", ParseError::MissingRCurly => "Expected '}'", ParseError::MissingRSquare => "Expected ']'", ParseError::MalformedCallExpr => "Call contains bad expression", ParseError::MalformedIndexExpr => "Indexing expression missing correct index", ParseError::VarExpectsIdentifier => "'var' expects the name of a variable", ParseError::FnMissingName => "Function declaration is missing name", ParseError::FnMissingParams => "Function declaration is missing parameters", } } fn cause(&self) -> Option<&dyn Error> { None } } impl fmt::Display for ParseError { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { write!(f, "{}", self.description()) } } #[derive(Debug, Clone)] pub struct FnDef { pub name: String, pub params: Vec, pub body: Box, } #[derive(Debug, Clone)] pub enum Stmt { If(Box, Box), IfElse(Box, Box, Box), While(Box, Box), Loop(Box), Var(String, Option>), Block(Vec), Expr(Box), Break, Return, ReturnWithVal(Box), } #[derive(Debug, Clone)] pub enum Expr { IntConst(i64), FloatConst(f64), Identifier(String), CharConst(char), StringConst(String), FnCall(String, Vec), Assignment(Box, Box), Dot(Box, Box), Index(String, Box), Array(Vec), True, False, Unit, } #[derive(Debug, Clone)] pub enum Token { IntConst(i64), FloatConst(f64), Identifier(String), CharConst(char), StringConst(String), LCurly, RCurly, LParen, RParen, LSquare, RSquare, Plus, UnaryPlus, Minus, UnaryMinus, Multiply, Divide, Semicolon, Colon, Comma, Period, Equals, True, False, Var, If, Else, While, Loop, LessThan, GreaterThan, Bang, LessThanEqual, GreaterThanEqual, EqualTo, NotEqualTo, Pipe, Or, Ampersand, And, Fn, Break, Return, PlusAssign, MinusAssign, MultiplyAssign, DivideAssign, LeftShiftAssign, RightShiftAssign, AndAssign, OrAssign, XOrAssign, LeftShift, RightShift, XOr, Modulo, ModuloAssign, PowerOf, PowerOfAssign, LexErr(LexError), } impl Token { // if another operator is after these, it's probably an unary operator // not sure about fn's name pub fn is_next_unary(&self) -> bool { use self::Token::*; match *self { LCurly | // (+expr) - is unary // RCurly | {expr} - expr not unary & is closing LParen | // {-expr} - is unary // RParen | (expr) - expr not unary & is closing LSquare | // [-expr] - is unary // RSquare | [expr] - expr not unary & is closing Plus | UnaryPlus | Minus | UnaryMinus | Multiply | Divide | Colon | Comma | Period | Equals | LessThan | GreaterThan | Bang | LessThanEqual | GreaterThanEqual | EqualTo | NotEqualTo | Pipe | Or | Ampersand | And | If | While | PlusAssign | MinusAssign | MultiplyAssign | DivideAssign | LeftShiftAssign | RightShiftAssign | AndAssign | OrAssign | XOrAssign | LeftShift | RightShift | XOr | Modulo | ModuloAssign | Return | PowerOf | PowerOfAssign => true, _ => false, } } #[allow(dead_code)] pub fn is_bin_op(&self) -> bool { use self::Token::*; match *self { RCurly | RParen | RSquare | Plus | Minus | Multiply | Divide | Comma | // Period | <- does period count? Equals | LessThan | GreaterThan | LessThanEqual | GreaterThanEqual | EqualTo | NotEqualTo | Pipe | Or | Ampersand | And | PowerOf => true, _ => false, } } #[allow(dead_code)] pub fn is_un_op(&self) -> bool { use self::Token::*; match *self { UnaryPlus | UnaryMinus | Equals | Bang | Return => true, _ => false, } } } pub struct TokenIterator<'a> { last: Token, char_stream: Peekable>, } impl<'a> TokenIterator<'a> { pub fn parse_string_const(&mut self, enclosing_char: char) -> Result { let mut result = Vec::new(); let mut escape = false; while let Some(nxt) = self.char_stream.next() { match nxt { '\\' if !escape => escape = true, '\\' if escape => { escape = false; result.push('\\'); } 't' if escape => { escape = false; result.push('\t'); } 'n' if escape => { escape = false; result.push('\n'); } 'r' if escape => { escape = false; result.push('\r'); } 'x' if escape => { escape = false; let mut out_val: u32 = 0; for _ in 0..2 { if let Some(c) = self.char_stream.next() { if let Some(d1) = c.to_digit(16) { out_val *= 16; out_val += d1; } else { return Err(LexError::MalformedEscapeSequence); } } else { return Err(LexError::MalformedEscapeSequence); } } if let Some(r) = char::from_u32(out_val) { result.push(r); } else { return Err(LexError::MalformedEscapeSequence); } } 'u' if escape => { escape = false; let mut out_val: u32 = 0; for _ in 0..4 { if let Some(c) = self.char_stream.next() { if let Some(d1) = c.to_digit(16) { out_val *= 16; out_val += d1; } else { return Err(LexError::MalformedEscapeSequence); } } else { return Err(LexError::MalformedEscapeSequence); } } if let Some(r) = char::from_u32(out_val) { result.push(r); } else { return Err(LexError::MalformedEscapeSequence); } } 'U' if escape => { escape = false; let mut out_val: u32 = 0; for _ in 0..8 { if let Some(c) = self.char_stream.next() { if let Some(d1) = c.to_digit(16) { out_val *= 16; out_val += d1; } else { return Err(LexError::MalformedEscapeSequence); } } else { return Err(LexError::MalformedEscapeSequence); } } if let Some(r) = char::from_u32(out_val) { result.push(r); } else { return Err(LexError::MalformedEscapeSequence); } } x if enclosing_char == x && escape => result.push(x), x if enclosing_char == x && !escape => break, _ if escape => return Err(LexError::MalformedEscapeSequence), _ => { escape = false; result.push(nxt); } } } let out: String = result.iter().cloned().collect(); Ok(out) } fn inner_next(&mut self) -> Option { while let Some(c) = self.char_stream.next() { match c { '0'..='9' => { let mut result = Vec::new(); let mut radix_base: Option = None; result.push(c); while let Some(&nxt) = self.char_stream.peek() { match nxt { '0'..='9' => { result.push(nxt); self.char_stream.next(); } '.' => { result.push(nxt); self.char_stream.next(); while let Some(&nxt_float) = self.char_stream.peek() { match nxt_float { '0'..='9' => { result.push(nxt_float); self.char_stream.next(); } _ => break, } } } 'x' | 'X' => { result.push(nxt); self.char_stream.next(); while let Some(&nxt_hex) = self.char_stream.peek() { match nxt_hex { '0'..='9' | 'a'..='f' | 'A'..='F' => { result.push(nxt_hex); self.char_stream.next(); } _ => break, } } radix_base = Some(16); } 'o' | 'O' => { result.push(nxt); self.char_stream.next(); while let Some(&nxt_oct) = self.char_stream.peek() { match nxt_oct { '0'..='8' => { result.push(nxt_oct); self.char_stream.next(); } _ => break, } } radix_base = Some(8); } 'b' | 'B' => { result.push(nxt); self.char_stream.next(); while let Some(&nxt_bin) = self.char_stream.peek() { match nxt_bin { '0' | '1' | '_' => { result.push(nxt_bin); self.char_stream.next(); } _ => break, } } radix_base = Some(2); } _ => break, } } if let Some(radix) = radix_base { let out: String = result .iter() .cloned() .skip(2) .filter(|c| c != &'_') .collect(); if let Ok(val) = i64::from_str_radix(&out, radix) { return Some(Token::IntConst(val)); } } let out: String = result.iter().cloned().collect(); if let Ok(val) = out.parse::() { return Some(Token::IntConst(val)); } else if let Ok(val) = out.parse::() { return Some(Token::FloatConst(val)); } return Some(Token::LexErr(LexError::MalformedNumber)); } 'A'..='Z' | 'a'..='z' | '_' => { let mut result = Vec::new(); result.push(c); while let Some(&nxt) = self.char_stream.peek() { match nxt { x if x.is_alphanumeric() || x == '_' => { result.push(x); self.char_stream.next(); } _ => break, } } let out: String = result.iter().cloned().collect(); match out.as_ref() { "true" => return Some(Token::True), "false" => return Some(Token::False), "let" => return Some(Token::Var), "if" => return Some(Token::If), "else" => return Some(Token::Else), "while" => return Some(Token::While), "loop" => return Some(Token::Loop), "break" => return Some(Token::Break), "return" => return Some(Token::Return), "fn" => return Some(Token::Fn), x => return Some(Token::Identifier(x.to_string())), } } '"' => match self.parse_string_const('"') { Ok(out) => return Some(Token::StringConst(out)), Err(e) => return Some(Token::LexErr(e)), }, '\'' => match self.parse_string_const('\'') { Ok(result) => { let mut chars = result.chars(); if let Some(out) = chars.next() { println!("result: {}", result); if chars.count() != 0 { return Some(Token::LexErr(LexError::MalformedChar)); } return Some(Token::CharConst(out)); } else { return Some(Token::LexErr(LexError::MalformedChar)); } } Err(e) => return Some(Token::LexErr(e)), }, '{' => return Some(Token::LCurly), '}' => return Some(Token::RCurly), '(' => return Some(Token::LParen), ')' => return Some(Token::RParen), '[' => return Some(Token::LSquare), ']' => return Some(Token::RSquare), '+' => { return match self.char_stream.peek() { Some(&'=') => { self.char_stream.next(); Some(Token::PlusAssign) } _ if self.last.is_next_unary() => Some(Token::UnaryPlus), _ => Some(Token::Plus), } } '-' => { return match self.char_stream.peek() { Some(&'=') => { self.char_stream.next(); Some(Token::MinusAssign) } _ if self.last.is_next_unary() => Some(Token::UnaryMinus), _ => Some(Token::Minus), } } '*' => { return match self.char_stream.peek() { Some(&'=') => { self.char_stream.next(); Some(Token::MultiplyAssign) } _ => Some(Token::Multiply), } } '/' => match self.char_stream.peek() { Some(&'/') => { self.char_stream.next(); while let Some(c) = self.char_stream.next() { if c == '\n' { break; } } } Some(&'*') => { let mut level = 1; self.char_stream.next(); while let Some(c) = self.char_stream.next() { match c { '/' => { if let Some('*') = self.char_stream.next() { level += 1; } } '*' => { if let Some('/') = self.char_stream.next() { level -= 1; } } _ => (), } if level == 0 { break; } } } Some(&'=') => { self.char_stream.next(); return Some(Token::DivideAssign); } _ => return Some(Token::Divide), }, ';' => return Some(Token::Semicolon), ':' => return Some(Token::Colon), ',' => return Some(Token::Comma), '.' => return Some(Token::Period), '=' => match self.char_stream.peek() { Some(&'=') => { self.char_stream.next(); return Some(Token::EqualTo); } _ => return Some(Token::Equals), }, '<' => match self.char_stream.peek() { Some(&'=') => { self.char_stream.next(); return Some(Token::LessThanEqual); } Some(&'<') => { self.char_stream.next(); return match self.char_stream.peek() { Some(&'=') => { self.char_stream.next(); Some(Token::LeftShiftAssign) } _ => { self.char_stream.next(); Some(Token::LeftShift) } }; } _ => return Some(Token::LessThan), }, '>' => match self.char_stream.peek() { Some(&'=') => { self.char_stream.next(); return Some(Token::GreaterThanEqual); } Some(&'>') => { self.char_stream.next(); return match self.char_stream.peek() { Some(&'=') => { self.char_stream.next(); Some(Token::RightShiftAssign) } _ => { self.char_stream.next(); Some(Token::RightShift) } }; } _ => return Some(Token::GreaterThan), }, '!' => match self.char_stream.peek() { Some(&'=') => { self.char_stream.next(); return Some(Token::NotEqualTo); } _ => return Some(Token::Bang), }, '|' => match self.char_stream.peek() { Some(&'|') => { self.char_stream.next(); return Some(Token::Or); } Some(&'=') => { self.char_stream.next(); return Some(Token::OrAssign); } _ => return Some(Token::Pipe), }, '&' => match self.char_stream.peek() { Some(&'&') => { self.char_stream.next(); return Some(Token::And); } Some(&'=') => { self.char_stream.next(); return Some(Token::AndAssign); } _ => return Some(Token::Ampersand), }, '^' => match self.char_stream.peek() { Some(&'=') => { self.char_stream.next(); return Some(Token::XOrAssign); } _ => return Some(Token::XOr), }, '%' => match self.char_stream.peek() { Some(&'=') => { self.char_stream.next(); return Some(Token::ModuloAssign); } _ => return Some(Token::Modulo), }, '~' => match self.char_stream.peek() { Some(&'=') => { self.char_stream.next(); return Some(Token::PowerOfAssign); } _ => return Some(Token::PowerOf), }, _x if _x.is_whitespace() => (), _ => return Some(Token::LexErr(LexError::UnexpectedChar)), } } None } } impl<'a> Iterator for TokenIterator<'a> { type Item = Token; // TODO - perhaps this could be optimized? fn next(&mut self) -> Option { self.last = match self.inner_next() { Some(c) => c, None => return None, }; Some(self.last.clone()) } } pub fn lex(input: &str) -> TokenIterator<'_> { TokenIterator { last: Token::LexErr(LexError::Nothing), char_stream: input.chars().peekable(), } } fn get_precedence(token: &Token) -> i32 { match *token { Token::Equals | Token::PlusAssign | Token::MinusAssign | Token::MultiplyAssign | Token::DivideAssign | Token::LeftShiftAssign | Token::RightShiftAssign | Token::AndAssign | Token::OrAssign | Token::XOrAssign | Token::ModuloAssign | Token::PowerOfAssign => 10, Token::Or | Token::XOr | Token::Pipe => 11, Token::And | Token::Ampersand => 12, Token::LessThan | Token::LessThanEqual | Token::GreaterThan | Token::GreaterThanEqual | Token::EqualTo | Token::NotEqualTo => 15, Token::Plus | Token::Minus => 20, Token::Divide | Token::Multiply | Token::PowerOf => 40, Token::LeftShift | Token::RightShift => 50, Token::Modulo => 60, Token::Period => 100, _ => -1, } } fn parse_paren_expr<'a>(input: &mut Peekable>) -> Result { let expr = parse_expr(input)?; match input.next() { Some(Token::RParen) => Ok(expr), _ => Err(ParseError::MissingRParen), } } fn parse_call_expr<'a>( id: String, input: &mut Peekable>, ) -> Result { let mut args = Vec::new(); if let Some(&Token::RParen) = input.peek() { input.next(); return Ok(Expr::FnCall(id, args)); } loop { if let Ok(arg) = parse_expr(input) { args.push(arg); } else { return Err(ParseError::MalformedCallExpr); } match input.peek() { Some(&Token::RParen) => { input.next(); return Ok(Expr::FnCall(id, args)); } Some(&Token::Comma) => (), _ => return Err(ParseError::MalformedCallExpr), } input.next(); } } fn parse_index_expr<'a>( id: String, input: &mut Peekable>, ) -> Result { if let Ok(idx) = parse_expr(input) { match input.peek() { Some(&Token::RSquare) => { input.next(); return Ok(Expr::Index(id, Box::new(idx))); } _ => return Err(ParseError::MalformedIndexExpr), } } else { return Err(ParseError::MalformedIndexExpr); } } fn parse_ident_expr<'a>( id: String, input: &mut Peekable>, ) -> Result { match input.peek() { Some(&Token::LParen) => { input.next(); parse_call_expr(id, input) } Some(&Token::LSquare) => { input.next(); parse_index_expr(id, input) } _ => Ok(Expr::Identifier(id)), } } fn parse_array_expr<'a>(input: &mut Peekable>) -> Result { let mut arr = Vec::new(); let skip_contents = match input.peek() { Some(&Token::RSquare) => true, _ => false, }; if !skip_contents { while let Some(_) = input.peek() { arr.push(parse_expr(input)?); if let Some(&Token::Comma) = input.peek() { input.next(); } if let Some(&Token::RSquare) = input.peek() { break; } } } match input.peek() { Some(&Token::RSquare) => { input.next(); Ok(Expr::Array(arr)) } _ => Err(ParseError::MissingRSquare), } } fn parse_primary<'a>(input: &mut Peekable>) -> Result { if let Some(token) = input.next() { match token { Token::IntConst(ref x) => Ok(Expr::IntConst(*x)), Token::FloatConst(ref x) => Ok(Expr::FloatConst(*x)), Token::StringConst(ref s) => Ok(Expr::StringConst(s.clone())), Token::CharConst(ref c) => Ok(Expr::CharConst(*c)), Token::Identifier(ref s) => parse_ident_expr(s.clone(), input), Token::LParen => parse_paren_expr(input), Token::LSquare => parse_array_expr(input), Token::True => Ok(Expr::True), Token::False => Ok(Expr::False), Token::LexErr(le) => { println!("Error: {}", le); Err(ParseError::BadInput) } _ => { println!("Can't parse: {:?}", token); Err(ParseError::BadInput) } } } else { Err(ParseError::InputPastEndOfFile) } } fn parse_unary<'a>(input: &mut Peekable>) -> Result { let tok = match input.peek() { Some(tok) => tok.clone(), None => return Err(ParseError::InputPastEndOfFile), }; match tok { Token::UnaryMinus => { input.next(); Ok(Expr::FnCall("-".to_string(), vec![parse_primary(input)?])) } Token::UnaryPlus => { input.next(); parse_primary(input) } Token::Bang => { input.next(); Ok(Expr::FnCall("!".to_string(), vec![parse_primary(input)?])) } _ => parse_primary(input), } } fn parse_binop<'a>( input: &mut Peekable>, prec: i32, lhs: Expr, ) -> Result { let mut lhs_curr = lhs; loop { let mut curr_prec = -1; if let Some(curr_op) = input.peek() { curr_prec = get_precedence(curr_op); } if curr_prec < prec { return Ok(lhs_curr); } if let Some(op_token) = input.next() { let mut rhs = parse_unary(input)?; let mut next_prec = -1; if let Some(next_op) = input.peek() { next_prec = get_precedence(next_op); } if curr_prec < next_prec { rhs = parse_binop(input, curr_prec + 1, rhs)?; } else if curr_prec >= 100 { // Always bind right to left for precedence over 100 rhs = parse_binop(input, curr_prec, rhs)?; } lhs_curr = match op_token { Token::Plus => Expr::FnCall("+".to_string(), vec![lhs_curr, rhs]), Token::Minus => Expr::FnCall("-".to_string(), vec![lhs_curr, rhs]), Token::Multiply => Expr::FnCall("*".to_string(), vec![lhs_curr, rhs]), Token::Divide => Expr::FnCall("/".to_string(), vec![lhs_curr, rhs]), Token::Equals => Expr::Assignment(Box::new(lhs_curr), Box::new(rhs)), Token::PlusAssign => { let lhs_copy = lhs_curr.clone(); Expr::Assignment( Box::new(lhs_curr), Box::new(Expr::FnCall("+".to_string(), vec![lhs_copy, rhs])), ) } Token::MinusAssign => { let lhs_copy = lhs_curr.clone(); Expr::Assignment( Box::new(lhs_curr), Box::new(Expr::FnCall("-".to_string(), vec![lhs_copy, rhs])), ) } Token::Period => Expr::Dot(Box::new(lhs_curr), Box::new(rhs)), Token::EqualTo => Expr::FnCall("==".to_string(), vec![lhs_curr, rhs]), Token::NotEqualTo => Expr::FnCall("!=".to_string(), vec![lhs_curr, rhs]), Token::LessThan => Expr::FnCall("<".to_string(), vec![lhs_curr, rhs]), Token::LessThanEqual => Expr::FnCall("<=".to_string(), vec![lhs_curr, rhs]), Token::GreaterThan => Expr::FnCall(">".to_string(), vec![lhs_curr, rhs]), Token::GreaterThanEqual => Expr::FnCall(">=".to_string(), vec![lhs_curr, rhs]), Token::Or => Expr::FnCall("||".to_string(), vec![lhs_curr, rhs]), Token::And => Expr::FnCall("&&".to_string(), vec![lhs_curr, rhs]), Token::XOr => Expr::FnCall("^".to_string(), vec![lhs_curr, rhs]), Token::OrAssign => { let lhs_copy = lhs_curr.clone(); Expr::Assignment( Box::new(lhs_curr), Box::new(Expr::FnCall("|".to_string(), vec![lhs_copy, rhs])), ) } Token::AndAssign => { let lhs_copy = lhs_curr.clone(); Expr::Assignment( Box::new(lhs_curr), Box::new(Expr::FnCall("&".to_string(), vec![lhs_copy, rhs])), ) } Token::XOrAssign => { let lhs_copy = lhs_curr.clone(); Expr::Assignment( Box::new(lhs_curr), Box::new(Expr::FnCall("^".to_string(), vec![lhs_copy, rhs])), ) } Token::MultiplyAssign => { let lhs_copy = lhs_curr.clone(); Expr::Assignment( Box::new(lhs_curr), Box::new(Expr::FnCall("*".to_string(), vec![lhs_copy, rhs])), ) } Token::DivideAssign => { let lhs_copy = lhs_curr.clone(); Expr::Assignment( Box::new(lhs_curr), Box::new(Expr::FnCall("/".to_string(), vec![lhs_copy, rhs])), ) } Token::Pipe => Expr::FnCall("|".to_string(), vec![lhs_curr, rhs]), Token::LeftShift => Expr::FnCall("<<".to_string(), vec![lhs_curr, rhs]), Token::RightShift => Expr::FnCall(">>".to_string(), vec![lhs_curr, rhs]), Token::LeftShiftAssign => { let lhs_copy = lhs_curr.clone(); Expr::Assignment( Box::new(lhs_curr), Box::new(Expr::FnCall("<<".to_string(), vec![lhs_copy, rhs])), ) } Token::RightShiftAssign => { let lhs_copy = lhs_curr.clone(); Expr::Assignment( Box::new(lhs_curr), Box::new(Expr::FnCall(">>".to_string(), vec![lhs_copy, rhs])), ) } Token::Ampersand => Expr::FnCall("&".to_string(), vec![lhs_curr, rhs]), Token::Modulo => Expr::FnCall("%".to_string(), vec![lhs_curr, rhs]), Token::ModuloAssign => { let lhs_copy = lhs_curr.clone(); Expr::Assignment( Box::new(lhs_curr), Box::new(Expr::FnCall("%".to_string(), vec![lhs_copy, rhs])), ) } Token::PowerOf => Expr::FnCall("~".to_string(), vec![lhs_curr, rhs]), Token::PowerOfAssign => { let lhs_copy = lhs_curr.clone(); Expr::Assignment( Box::new(lhs_curr), Box::new(Expr::FnCall("~".to_string(), vec![lhs_copy, rhs])), ) } _ => return Err(ParseError::UnknownOperator), }; } } } fn parse_expr<'a>(input: &mut Peekable>) -> Result { match input.peek() { Some(Token::RParen) => Ok(Expr::Unit), _ => { let lhs = parse_unary(input)?; parse_binop(input, 0, lhs) } } } fn parse_if<'a>(input: &mut Peekable>) -> Result { input.next(); let guard = parse_expr(input)?; let body = parse_block(input)?; match input.peek() { Some(&Token::Else) => { input.next(); let else_body = parse_block(input)?; Ok(Stmt::IfElse( Box::new(guard), Box::new(body), Box::new(else_body), )) } _ => Ok(Stmt::If(Box::new(guard), Box::new(body))), } } fn parse_while<'a>(input: &mut Peekable>) -> Result { input.next(); let guard = parse_expr(input)?; let body = parse_block(input)?; Ok(Stmt::While(Box::new(guard), Box::new(body))) } fn parse_loop<'a>(input: &mut Peekable>) -> Result { input.next(); let body = parse_block(input)?; Ok(Stmt::Loop(Box::new(body))) } fn parse_var<'a>(input: &mut Peekable>) -> Result { input.next(); let name = match input.next() { Some(Token::Identifier(ref s)) => s.clone(), _ => return Err(ParseError::VarExpectsIdentifier), }; match input.peek() { Some(&Token::Equals) => { input.next(); let initializer = parse_expr(input)?; Ok(Stmt::Var(name, Some(Box::new(initializer)))) } _ => Ok(Stmt::Var(name, None)), } } fn parse_block<'a>(input: &mut Peekable>) -> Result { match input.peek() { Some(&Token::LCurly) => (), _ => return Err(ParseError::MissingLCurly), } input.next(); let mut stmts = Vec::new(); let skip_body = match input.peek() { Some(&Token::RCurly) => true, _ => false, }; if !skip_body { while let Some(_) = input.peek() { stmts.push(parse_stmt(input)?); if let Some(&Token::Semicolon) = input.peek() { input.next(); } if let Some(&Token::RCurly) = input.peek() { break; } } } match input.peek() { Some(&Token::RCurly) => { input.next(); Ok(Stmt::Block(stmts)) } _ => Err(ParseError::MissingRCurly), } } fn parse_expr_stmt<'a>(input: &mut Peekable>) -> Result { let expr = parse_expr(input)?; Ok(Stmt::Expr(Box::new(expr))) } fn parse_stmt<'a>(input: &mut Peekable>) -> Result { match input.peek() { Some(&Token::If) => parse_if(input), Some(&Token::While) => parse_while(input), Some(&Token::Loop) => parse_loop(input), Some(&Token::Break) => { input.next(); Ok(Stmt::Break) } Some(&Token::Return) => { input.next(); match input.peek() { Some(&Token::Semicolon) => Ok(Stmt::Return), _ => { let ret = parse_expr(input)?; Ok(Stmt::ReturnWithVal(Box::new(ret))) } } } Some(&Token::LCurly) => parse_block(input), Some(&Token::Var) => parse_var(input), _ => parse_expr_stmt(input), } } fn parse_fn<'a>(input: &mut Peekable>) -> Result { input.next(); let name = match input.next() { Some(Token::Identifier(ref s)) => s.clone(), _ => return Err(ParseError::FnMissingName), }; match input.peek() { Some(&Token::LParen) => { input.next(); } _ => return Err(ParseError::FnMissingParams), } let mut params = Vec::new(); let skip_params = match input.peek() { Some(&Token::RParen) => { input.next(); true } _ => false, }; if !skip_params { loop { match input.next() { Some(Token::RParen) => break, Some(Token::Comma) => (), Some(Token::Identifier(ref s)) => { params.push(s.clone()); } _ => return Err(ParseError::MalformedCallExpr), } } } let body = parse_block(input)?; Ok(FnDef { name: name, params: params, body: Box::new(body), }) } fn parse_top_level<'a>( input: &mut Peekable>, ) -> Result<(Vec, Vec), ParseError> { let mut stmts = Vec::new(); let mut fndefs = Vec::new(); while let Some(_) = input.peek() { match input.peek() { Some(&Token::Fn) => fndefs.push(parse_fn(input)?), _ => stmts.push(parse_stmt(input)?), } if let Some(&Token::Semicolon) = input.peek() { input.next(); } } Ok((stmts, fndefs)) } pub fn parse<'a>( input: &mut Peekable>, ) -> Result<(Vec, Vec), ParseError> { parse_top_level(input) }