use std::borrow::Cow; use nom::character::complete::{digit1, multispace0, multispace1}; use nom::{ alt, call, char, complete, delimited, do_parse, flat_map, many0, map, named, opt, parse_to, preceded, separated_list0, separated_list1, tag, tuple, }; use pratt::{Affix, Associativity, PrattParser, Precedence}; use super::util::comma; use crate::ast::{BinaryOperator, Binding, Expr, Fun, Literal, Pattern, UnaryOperator}; use crate::parser::{arg, ident, type_}; #[derive(Debug)] enum TokenTree<'a> { Prefix(UnaryOperator), // Postfix(char), Infix(BinaryOperator), Primary(Expr<'a>), Group(Vec<TokenTree<'a>>), } named!(prefix(&str) -> TokenTree, map!(alt!( complete!(char!('-')) => { |_| UnaryOperator::Neg } | complete!(char!('!')) => { |_| UnaryOperator::Not } ), TokenTree::Prefix)); named!(infix(&str) -> TokenTree, map!(alt!( complete!(tag!("==")) => { |_| BinaryOperator::Equ } | complete!(tag!("!=")) => { |_| BinaryOperator::Neq } | complete!(char!('+')) => { |_| BinaryOperator::Add } | complete!(char!('-')) => { |_| BinaryOperator::Sub } | complete!(char!('*')) => { |_| BinaryOperator::Mul } | complete!(char!('/')) => { |_| BinaryOperator::Div } | complete!(char!('^')) => { |_| BinaryOperator::Pow } ), TokenTree::Infix)); named!(primary(&str) -> TokenTree, alt!( do_parse!( multispace0 >> char!('(') >> multispace0 >> group: group >> multispace0 >> char!(')') >> multispace0 >> (TokenTree::Group(group)) ) | delimited!(multispace0, simple_expr, multispace0) => { |s| TokenTree::Primary(s) } )); named!( rest(&str) -> Vec<(TokenTree, Vec<TokenTree>, TokenTree)>, many0!(tuple!( infix, delimited!(multispace0, many0!(prefix), multispace0), primary // many0!(postfix) )) ); named!(group(&str) -> Vec<TokenTree>, do_parse!( prefix: many0!(prefix) >> primary: primary // >> postfix: many0!(postfix) >> rest: rest >> ({ let mut res = prefix; res.push(primary); // res.append(&mut postfix); for (infix, mut prefix, primary/*, mut postfix*/) in rest { res.push(infix); res.append(&mut prefix); res.push(primary); // res.append(&mut postfix); } res }) )); fn token_tree(i: &str) -> nom::IResult<&str, Vec<TokenTree>> { group(i) } struct ExprParser; impl<'a, I> PrattParser<I> for ExprParser where I: Iterator<Item = TokenTree<'a>>, { type Error = pratt::NoError; type Input = TokenTree<'a>; type Output = Expr<'a>; fn query(&mut self, input: &Self::Input) -> Result<Affix, Self::Error> { use BinaryOperator::*; use UnaryOperator::*; Ok(match input { TokenTree::Infix(Add) => Affix::Infix(Precedence(6), Associativity::Left), TokenTree::Infix(Sub) => Affix::Infix(Precedence(6), Associativity::Left), TokenTree::Infix(Mul) => Affix::Infix(Precedence(7), Associativity::Left), TokenTree::Infix(Div) => Affix::Infix(Precedence(7), Associativity::Left), TokenTree::Infix(Pow) => Affix::Infix(Precedence(8), Associativity::Right), TokenTree::Infix(Equ) => Affix::Infix(Precedence(4), Associativity::Right), TokenTree::Infix(Neq) => Affix::Infix(Precedence(4), Associativity::Right), TokenTree::Prefix(Neg) => Affix::Prefix(Precedence(6)), TokenTree::Prefix(Not) => Affix::Prefix(Precedence(6)), TokenTree::Primary(_) => Affix::Nilfix, TokenTree::Group(_) => Affix::Nilfix, }) } fn primary(&mut self, input: Self::Input) -> Result<Self::Output, Self::Error> { Ok(match input { TokenTree::Primary(expr) => expr, TokenTree::Group(group) => self.parse(&mut group.into_iter()).unwrap(), _ => unreachable!(), }) } fn infix( &mut self, lhs: Self::Output, op: Self::Input, rhs: Self::Output, ) -> Result<Self::Output, Self::Error> { let op = match op { TokenTree::Infix(op) => op, _ => unreachable!(), }; Ok(Expr::BinaryOp { lhs: Box::new(lhs), op, rhs: Box::new(rhs), }) } fn prefix(&mut self, op: Self::Input, rhs: Self::Output) -> Result<Self::Output, Self::Error> { let op = match op { TokenTree::Prefix(op) => op, _ => unreachable!(), }; Ok(Expr::UnaryOp { op, rhs: Box::new(rhs), }) } fn postfix( &mut self, _lhs: Self::Output, _op: Self::Input, ) -> Result<Self::Output, Self::Error> { unreachable!() } } named!(int(&str) -> Literal, map!(flat_map!(digit1, parse_to!(u64)), Literal::Int)); named!(bool_(&str) -> Literal, alt!( complete!(tag!("true")) => { |_| Literal::Bool(true) } | complete!(tag!("false")) => { |_| Literal::Bool(false) } )); fn string_internal(i: &str) -> nom::IResult<&str, Cow<'_, str>, nom::error::Error<&str>> { // TODO(grfn): use String::split_once when that's stable let (s, rem) = if let Some(pos) = i.find('"') { (&i[..pos], &i[(pos + 1)..]) } else { return Err(nom::Err::Error(nom::error::Error::new( i, nom::error::ErrorKind::Tag, ))); }; Ok((rem, Cow::Borrowed(s))) } named!(string(&str) -> Literal, preceded!( complete!(char!('"')), map!( string_internal, |s| Literal::String(s) ) )); named!(unit(&str) -> Literal, map!(complete!(tag!("()")), |_| Literal::Unit)); named!(literal(&str) -> Literal, alt!(int | bool_ | string | unit)); named!(literal_expr(&str) -> Expr, map!(literal, Expr::Literal)); named!(tuple(&str) -> Expr, do_parse!( complete!(tag!("(")) >> multispace0 >> fst: expr >> comma >> rest: separated_list0!( comma, expr ) >> multispace0 >> tag!(")") >> ({ let mut members = Vec::with_capacity(rest.len() + 1); members.push(fst); members.append(&mut rest.clone()); Expr::Tuple(members) }) )); named!(tuple_pattern(&str) -> Pattern, do_parse!( complete!(tag!("(")) >> multispace0 >> pats: separated_list0!( comma, pattern ) >> multispace0 >> tag!(")") >> (Pattern::Tuple(pats)) )); named!(pattern(&str) -> Pattern, alt!( ident => { |id| Pattern::Id(id) } | tuple_pattern )); named!(binding(&str) -> Binding, do_parse!( multispace0 >> pat: pattern >> multispace0 >> type_: opt!(preceded!(tuple!(tag!(":"), multispace0), type_)) >> multispace0 >> char!('=') >> multispace0 >> body: expr >> (Binding { pat, type_, body }) )); named!(let_(&str) -> Expr, do_parse!( tag!("let") >> multispace0 >> bindings: separated_list1!(alt!(char!(';') | char!('\n')), binding) >> multispace0 >> tag!("in") >> multispace0 >> body: expr >> (Expr::Let { bindings, body: Box::new(body) }) )); named!(if_(&str) -> Expr, do_parse! ( tag!("if") >> multispace0 >> condition: expr >> multispace0 >> tag!("then") >> multispace0 >> then: expr >> multispace0 >> tag!("else") >> multispace0 >> else_: expr >> (Expr::If { condition: Box::new(condition), then: Box::new(then), else_: Box::new(else_) }) )); named!(ident_expr(&str) -> Expr, map!(ident, Expr::Ident)); fn ascripted<'a>( p: impl Fn(&'a str) -> nom::IResult<&'a str, Expr, nom::error::Error<&'a str>> + 'a, ) -> impl Fn(&'a str) -> nom::IResult<&str, Expr, nom::error::Error<&'a str>> { move |i| { do_parse!( i, expr: p >> multispace0 >> complete!(tag!(":")) >> multispace0 >> type_: type_ >> (Expr::Ascription { expr: Box::new(expr), type_ }) ) } } named!(paren_expr(&str) -> Expr, delimited!(complete!(tag!("(")), expr, complete!(tag!(")")))); named!(funcref(&str) -> Expr, alt!( ident_expr | tuple | paren_expr )); named!(no_arg_call(&str) -> Expr, do_parse!( fun: funcref >> complete!(tag!("()")) >> (Expr::Call { fun: Box::new(fun), args: vec![], }) )); named!(fun_expr(&str) -> Expr, do_parse!( tag!("fn") >> multispace1 >> args: separated_list0!(multispace1, arg) >> multispace0 >> char!('=') >> multispace0 >> body: expr >> (Expr::Fun(Box::new(Fun { args, body }))) )); named!(fn_arg(&str) -> Expr, alt!( ident_expr | literal_expr | tuple | paren_expr )); named!(call_with_args(&str) -> Expr, do_parse!( fun: funcref >> multispace1 >> args: separated_list1!(multispace1, fn_arg) >> (Expr::Call { fun: Box::new(fun), args }) )); named!(simple_expr_unascripted(&str) -> Expr, alt!( let_ | if_ | fun_expr | literal_expr | ident_expr | tuple )); named!(simple_expr(&str) -> Expr, alt!( call!(ascripted(simple_expr_unascripted)) | simple_expr_unascripted )); named!(pub expr(&str) -> Expr, alt!( no_arg_call | call_with_args | map!(token_tree, |tt| { ExprParser.parse(&mut tt.into_iter()).unwrap() }) | simple_expr )); #[cfg(test)] pub(crate) mod tests { use super::*; use crate::ast::{Arg, Ident, Pattern, Type}; use std::convert::TryFrom; use BinaryOperator::*; use Expr::{BinaryOp, If, Let, UnaryOp}; use UnaryOperator::*; pub(crate) fn ident_expr(s: &str) -> Box<Expr> { Box::new(Expr::Ident(Ident::try_from(s).unwrap())) } mod operators { use super::*; #[test] fn mul_plus() { let (rem, res) = expr("x*y+z").unwrap(); assert!(rem.is_empty()); assert_eq!( res, BinaryOp { lhs: Box::new(BinaryOp { lhs: ident_expr("x"), op: Mul, rhs: ident_expr("y") }), op: Add, rhs: ident_expr("z") } ) } #[test] fn mul_plus_ws() { let (rem, res) = expr("x * y + z").unwrap(); assert!(rem.is_empty(), "non-empty remainder: \"{}\"", rem); assert_eq!( res, BinaryOp { lhs: Box::new(BinaryOp { lhs: ident_expr("x"), op: Mul, rhs: ident_expr("y") }), op: Add, rhs: ident_expr("z") } ) } #[test] fn unary() { let (rem, res) = expr("x * -z").unwrap(); assert!(rem.is_empty(), "non-empty remainder: \"{}\"", rem); assert_eq!( res, BinaryOp { lhs: ident_expr("x"), op: Mul, rhs: Box::new(UnaryOp { op: Neg, rhs: ident_expr("z"), }) } ) } #[test] fn mul_literal() { let (rem, res) = expr("x * 3").unwrap(); assert!(rem.is_empty()); assert_eq!( res, BinaryOp { lhs: ident_expr("x"), op: Mul, rhs: Box::new(Expr::Literal(Literal::Int(3))), } ) } #[test] fn equ() { let res = test_parse!(expr, "x * 7 == 7"); assert_eq!( res, BinaryOp { lhs: Box::new(BinaryOp { lhs: ident_expr("x"), op: Mul, rhs: Box::new(Expr::Literal(Literal::Int(7))) }), op: Equ, rhs: Box::new(Expr::Literal(Literal::Int(7))) } ) } } #[test] fn unit() { assert_eq!(test_parse!(expr, "()"), Expr::Literal(Literal::Unit)); } #[test] fn bools() { assert_eq!( test_parse!(expr, "true"), Expr::Literal(Literal::Bool(true)) ); assert_eq!( test_parse!(expr, "false"), Expr::Literal(Literal::Bool(false)) ); } #[test] fn tuple() { assert_eq!( test_parse!(expr, "(1, \"seven\")"), Expr::Tuple(vec![ Expr::Literal(Literal::Int(1)), Expr::Literal(Literal::String(Cow::Borrowed("seven"))) ]) ) } #[test] fn simple_string_lit() { assert_eq!( test_parse!(expr, "\"foobar\""), Expr::Literal(Literal::String(Cow::Borrowed("foobar"))) ) } #[test] fn let_complex() { let res = test_parse!(expr, "let x = 1; y = x * 7 in (x + y) * 4"); assert_eq!( res, Let { bindings: vec![ Binding { pat: Pattern::Id(Ident::try_from("x").unwrap()), type_: None, body: Expr::Literal(Literal::Int(1)) }, Binding { pat: Pattern::Id(Ident::try_from("y").unwrap()), type_: None, body: Expr::BinaryOp { lhs: ident_expr("x"), op: Mul, rhs: Box::new(Expr::Literal(Literal::Int(7))) } } ], body: Box::new(Expr::BinaryOp { lhs: Box::new(Expr::BinaryOp { lhs: ident_expr("x"), op: Add, rhs: ident_expr("y"), }), op: Mul, rhs: Box::new(Expr::Literal(Literal::Int(4))), }) } ) } #[test] fn if_simple() { let res = test_parse!(expr, "if x == 8 then 9 else 20"); assert_eq!( res, If { condition: Box::new(BinaryOp { lhs: ident_expr("x"), op: Equ, rhs: Box::new(Expr::Literal(Literal::Int(8))), }), then: Box::new(Expr::Literal(Literal::Int(9))), else_: Box::new(Expr::Literal(Literal::Int(20))) } ) } #[test] fn no_arg_call() { let res = test_parse!(expr, "f()"); assert_eq!( res, Expr::Call { fun: ident_expr("f"), args: vec![] } ); } #[test] fn unit_call() { let res = test_parse!(expr, "f ()"); assert_eq!( res, Expr::Call { fun: ident_expr("f"), args: vec![Expr::Literal(Literal::Unit)] } ) } #[test] fn call_with_args() { let res = test_parse!(expr, "f x 1"); assert_eq!( res, Expr::Call { fun: ident_expr("f"), args: vec![*ident_expr("x"), Expr::Literal(Literal::Int(1))] } ) } #[test] fn call_funcref() { let res = test_parse!(expr, "(let x = 1 in x) 2"); assert_eq!( res, Expr::Call { fun: Box::new(Expr::Let { bindings: vec![Binding { pat: Pattern::Id(Ident::try_from("x").unwrap()), type_: None, body: Expr::Literal(Literal::Int(1)) }], body: ident_expr("x") }), args: vec![Expr::Literal(Literal::Int(2))] } ) } #[test] fn anon_function() { let res = test_parse!(expr, "let id = fn x = x in id 1"); assert_eq!( res, Expr::Let { bindings: vec![Binding { pat: Pattern::Id(Ident::try_from("id").unwrap()), type_: None, body: Expr::Fun(Box::new(Fun { args: vec![Arg::try_from("x").unwrap()], body: *ident_expr("x") })) }], body: Box::new(Expr::Call { fun: ident_expr("id"), args: vec![Expr::Literal(Literal::Int(1))], }) } ); } #[test] fn tuple_binding() { let res = test_parse!(expr, "let (x, y) = (1, 2) in x"); assert_eq!( res, Expr::Let { bindings: vec![Binding { pat: Pattern::Tuple(vec![ Pattern::Id(Ident::from_str_unchecked("x")), Pattern::Id(Ident::from_str_unchecked("y")) ]), body: Expr::Tuple(vec![ Expr::Literal(Literal::Int(1)), Expr::Literal(Literal::Int(2)) ]), type_: None }], body: Box::new(Expr::Ident(Ident::from_str_unchecked("x"))) } ) } mod ascriptions { use super::*; #[test] fn bare_ascription() { let res = test_parse!(expr, "1: float"); assert_eq!( res, Expr::Ascription { expr: Box::new(Expr::Literal(Literal::Int(1))), type_: Type::Float } ) } #[test] fn fn_body_ascription() { let res = test_parse!(expr, "let const_1 = fn x = 1: int in const_1 2"); assert_eq!( res, Expr::Let { bindings: vec![Binding { pat: Pattern::Id(Ident::try_from("const_1").unwrap()), type_: None, body: Expr::Fun(Box::new(Fun { args: vec![Arg::try_from("x").unwrap()], body: Expr::Ascription { expr: Box::new(Expr::Literal(Literal::Int(1))), type_: Type::Int, } })) }], body: Box::new(Expr::Call { fun: ident_expr("const_1"), args: vec![Expr::Literal(Literal::Int(2))] }) } ) } #[test] fn let_binding_ascripted() { let res = test_parse!(expr, "let x: int = 1 in x"); assert_eq!( res, Expr::Let { bindings: vec![Binding { pat: Pattern::Id(Ident::try_from("x").unwrap()), type_: Some(Type::Int), body: Expr::Literal(Literal::Int(1)) }], body: ident_expr("x") } ) } } }