use std::borrow::Cow;
use nom::alt;
use nom::character::complete::{digit1, multispace0, multispace1};
use nom::{
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 crate::ast::{BinaryOperator, Binding, Expr, Fun, Literal, UnaryOperator};
use crate::parser::{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>> {
let (s, rem) = i
.split_once('"')
.ok_or_else(|| 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!(literal(&str) -> Literal, alt!(int | bool_ | string));
named!(literal_expr(&str) -> Expr, map!(literal, Expr::Literal));
named!(binding(&str) -> Binding, do_parse!(
multispace0
>> ident: ident
>> multispace0
>> type_: opt!(preceded!(tuple!(tag!(":"), multispace0), type_))
>> multispace0
>> char!('=')
>> multispace0
>> body: expr
>> (Binding {
ident,
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 |
paren_expr
));
named!(no_arg_call(&str) -> Expr, do_parse!(
fun: funcref
>> multispace0
>> complete!(tag!("()"))
>> (Expr::Call {
fun: Box::new(fun),
args: vec![],
})
));
named!(fun_expr(&str) -> Expr, do_parse!(
tag!("fn")
>> multispace1
>> args: separated_list0!(multispace1, ident)
>> multispace0
>> char!('=')
>> multispace0
>> body: expr
>> (Expr::Fun(Box::new(Fun {
args,
body
})))
));
named!(arg(&str) -> Expr, alt!(
ident_expr |
literal_expr |
paren_expr
));
named!(call_with_args(&str) -> Expr, do_parse!(
fun: funcref
>> multispace1
>> args: separated_list1!(multispace1, arg)
>> (Expr::Call {
fun: Box::new(fun),
args
})
));
named!(simple_expr_unascripted(&str) -> Expr, alt!(
let_ |
if_ |
fun_expr |
literal_expr |
ident_expr
));
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::{Ident, 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 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 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 {
ident: Ident::try_from("x").unwrap(),
type_: None,
body: Expr::Literal(Literal::Int(1))
},
Binding {
ident: 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 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 {
ident: 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 {
ident: Ident::try_from("id").unwrap(),
type_: None,
body: Expr::Fun(Box::new(Fun {
args: vec![Ident::try_from("x").unwrap()],
body: *ident_expr("x")
}))
}],
body: Box::new(Expr::Call {
fun: ident_expr("id"),
args: vec![Expr::Literal(Literal::Int(1))],
})
}
);
}
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 {
ident: Ident::try_from("const_1").unwrap(),
type_: None,
body: Expr::Fun(Box::new(Fun {
args: vec![Ident::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 {
ident: Ident::try_from("x").unwrap(),
type_: Some(Type::Int),
body: Expr::Literal(Literal::Int(1))
}],
body: ident_expr("x")
}
)
}
}
}