use std::str; use nom::branch::alt; use nom::bytes::complete::{tag, take_till}; use nom::character::complete::char; use nom::combinator::{cut, map, not, opt, peek, recognize}; use nom::error::ErrorKind; use nom::multi::{fold_many0, many0, separated_list0, separated_list1}; use nom::sequence::{delimited, pair, preceded, terminated, tuple}; use nom::{error_position, IResult}; use super::{ bool_lit, char_lit, identifier, nested_parenthesis, not_ws, num_lit, path, str_lit, ws, }; #[derive(Debug, PartialEq)] pub(crate) enum Expr<'a> { BoolLit(&'a str), NumLit(&'a str), StrLit(&'a str), CharLit(&'a str), Var(&'a str), Path(Vec<&'a str>), Array(Vec>), Attr(Box>, &'a str), Index(Box>, Box>), Filter(&'a str, Vec>), Unary(&'a str, Box>), BinOp(&'a str, Box>, Box>), Range(&'a str, Option>>, Option>>), Group(Box>), Tuple(Vec>), Call(Box>, Vec>), RustMacro(Vec<&'a str>, &'a str), Try(Box>), } impl Expr<'_> { pub(super) fn parse(i: &str) -> IResult<&str, Expr<'_>> { expr_any(i) } pub(super) fn parse_arguments(i: &str) -> IResult<&str, Vec>> { arguments(i) } } fn expr_bool_lit(i: &str) -> IResult<&str, Expr<'_>> { map(bool_lit, Expr::BoolLit)(i) } fn expr_num_lit(i: &str) -> IResult<&str, Expr<'_>> { map(num_lit, Expr::NumLit)(i) } fn expr_array_lit(i: &str) -> IResult<&str, Expr<'_>> { delimited( ws(char('[')), map(separated_list1(ws(char(',')), expr_any), Expr::Array), ws(char(']')), )(i) } fn expr_str_lit(i: &str) -> IResult<&str, Expr<'_>> { map(str_lit, Expr::StrLit)(i) } fn expr_char_lit(i: &str) -> IResult<&str, Expr<'_>> { map(char_lit, Expr::CharLit)(i) } fn expr_var(i: &str) -> IResult<&str, Expr<'_>> { map(identifier, Expr::Var)(i) } fn expr_path(i: &str) -> IResult<&str, Expr<'_>> { let (i, path) = path(i)?; Ok((i, Expr::Path(path))) } fn expr_group(i: &str) -> IResult<&str, Expr<'_>> { let (i, expr) = preceded(ws(char('(')), opt(expr_any))(i)?; let expr = match expr { Some(expr) => expr, None => { let (i, _) = char(')')(i)?; return Ok((i, Expr::Tuple(vec![]))); } }; let (i, comma) = ws(opt(peek(char(','))))(i)?; if comma.is_none() { let (i, _) = char(')')(i)?; return Ok((i, Expr::Group(Box::new(expr)))); } let mut exprs = vec![expr]; let (i, _) = fold_many0( preceded(char(','), ws(expr_any)), || (), |_, expr| { exprs.push(expr); }, )(i)?; let (i, _) = pair(ws(opt(char(','))), char(')'))(i)?; Ok((i, Expr::Tuple(exprs))) } fn expr_single(i: &str) -> IResult<&str, Expr<'_>> { alt(( expr_bool_lit, expr_num_lit, expr_str_lit, expr_char_lit, expr_path, expr_array_lit, expr_var, expr_group, ))(i) } enum Suffix<'a> { Attr(&'a str), Index(Expr<'a>), Call(Vec>), // The value is the arguments of the macro call. MacroCall(&'a str), Try, } fn expr_attr(i: &str) -> IResult<&str, Suffix<'_>> { map( preceded( ws(pair(char('.'), not(char('.')))), cut(alt((num_lit, identifier))), ), Suffix::Attr, )(i) } fn expr_index(i: &str) -> IResult<&str, Suffix<'_>> { map( preceded(ws(char('[')), cut(terminated(expr_any, ws(char(']'))))), Suffix::Index, )(i) } fn expr_call(i: &str) -> IResult<&str, Suffix<'_>> { map(arguments, Suffix::Call)(i) } fn expr_macro(i: &str) -> IResult<&str, Suffix<'_>> { preceded( pair(ws(char('!')), char('(')), cut(terminated( map(recognize(nested_parenthesis), Suffix::MacroCall), char(')'), )), )(i) } fn expr_try(i: &str) -> IResult<&str, Suffix<'_>> { map(preceded(take_till(not_ws), char('?')), |_| Suffix::Try)(i) } fn filter(i: &str) -> IResult<&str, (&str, Option>>)> { let (i, (_, fname, args)) = tuple((char('|'), ws(identifier), opt(arguments)))(i)?; Ok((i, (fname, args))) } fn expr_filtered(i: &str) -> IResult<&str, Expr<'_>> { let (i, (obj, filters)) = tuple((expr_prefix, many0(filter)))(i)?; let mut res = obj; for (fname, args) in filters { res = Expr::Filter(fname, { let mut args = match args { Some(inner) => inner, None => Vec::new(), }; args.insert(0, res); args }); } Ok((i, res)) } fn expr_prefix(i: &str) -> IResult<&str, Expr<'_>> { let (i, (ops, mut expr)) = pair(many0(ws(alt((tag("!"), tag("-"))))), expr_suffix)(i)?; for op in ops.iter().rev() { expr = Expr::Unary(op, Box::new(expr)); } Ok((i, expr)) } fn expr_suffix(i: &str) -> IResult<&str, Expr<'_>> { let (mut i, mut expr) = expr_single(i)?; loop { let (j, suffix) = opt(alt(( expr_attr, expr_index, expr_call, expr_try, expr_macro, )))(i)?; match suffix { Some(Suffix::Attr(attr)) => expr = Expr::Attr(expr.into(), attr), Some(Suffix::Index(index)) => expr = Expr::Index(expr.into(), index.into()), Some(Suffix::Call(args)) => expr = Expr::Call(expr.into(), args), Some(Suffix::Try) => expr = Expr::Try(expr.into()), Some(Suffix::MacroCall(args)) => match expr { Expr::Path(path) => expr = Expr::RustMacro(path, args), Expr::Var(name) => expr = Expr::RustMacro(vec![name], args), _ => return Err(nom::Err::Failure(error_position!(i, ErrorKind::Tag))), }, None => break, } i = j; } Ok((i, expr)) } macro_rules! expr_prec_layer { ( $name:ident, $inner:ident, $op:expr ) => { fn $name(i: &str) -> IResult<&str, Expr<'_>> { let (i, left) = $inner(i)?; let (i, right) = many0(pair( ws(tag($op)), $inner, ))(i)?; Ok(( i, right.into_iter().fold(left, |left, (op, right)| { Expr::BinOp(op, Box::new(left), Box::new(right)) }), )) } }; ( $name:ident, $inner:ident, $( $op:expr ),+ ) => { fn $name(i: &str) -> IResult<&str, Expr<'_>> { let (i, left) = $inner(i)?; let (i, right) = many0(pair( ws(alt(($( tag($op) ),+,))), $inner, ))(i)?; Ok(( i, right.into_iter().fold(left, |left, (op, right)| { Expr::BinOp(op, Box::new(left), Box::new(right)) }), )) } } } expr_prec_layer!(expr_muldivmod, expr_filtered, "*", "/", "%"); expr_prec_layer!(expr_addsub, expr_muldivmod, "+", "-"); expr_prec_layer!(expr_shifts, expr_addsub, ">>", "<<"); expr_prec_layer!(expr_band, expr_shifts, "&"); expr_prec_layer!(expr_bxor, expr_band, "^"); expr_prec_layer!(expr_bor, expr_bxor, "|"); expr_prec_layer!(expr_compare, expr_bor, "==", "!=", ">=", ">", "<=", "<"); expr_prec_layer!(expr_and, expr_compare, "&&"); expr_prec_layer!(expr_or, expr_and, "||"); fn expr_any(i: &str) -> IResult<&str, Expr<'_>> { let range_right = |i| pair(ws(alt((tag("..="), tag("..")))), opt(expr_or))(i); alt(( map(range_right, |(op, right)| { Expr::Range(op, None, right.map(Box::new)) }), map( pair(expr_or, opt(range_right)), |(left, right)| match right { Some((op, right)) => Expr::Range(op, Some(Box::new(left)), right.map(Box::new)), None => left, }, ), ))(i) } fn arguments(i: &str) -> IResult<&str, Vec>> { delimited( ws(char('(')), separated_list0(char(','), ws(expr_any)), ws(char(')')), )(i) }