ra_ap_parser 0.0.329

use super::*;

pub(super) const PATTERN_FIRST: TokenSet =
    expressions::LITERAL_FIRST.union(paths::PATH_FIRST).union(TokenSet::new(&[
        T![box],
        T![ref],
        T![mut],
        T![const],
        T!['('],
        T!['['],
        T![&],
        T![_],
        T![-],
        T![.],
    ]));

const PAT_TOP_FIRST: TokenSet = PATTERN_FIRST.union(TokenSet::new(&[T![|]]));

/// Set of possible tokens at the start of a range pattern's end bound.
const RANGE_PAT_END_FIRST: TokenSet =
    expressions::LITERAL_FIRST.union(paths::PATH_FIRST).union(TokenSet::new(&[T![-], T![const]]));

/// Parses a pattern list separated by pipes `|`.
pub(crate) fn pattern(p: &mut Parser<'_>) {
    pattern_r(p, PAT_RECOVERY_SET);
}

pub(crate) fn pattern_single(p: &mut Parser<'_>) {
    pattern_single_r(p, PAT_RECOVERY_SET);
}

/// Parses a pattern list separated by pipes `|`
/// using the given `recovery_set`.
pub(super) fn pattern_top_r(p: &mut Parser<'_>, recovery_set: TokenSet) {
    pattern_r(p, recovery_set);
}

// test or_pattern
// fn main() {
//     match () {
//         (_ | _) => (),
//         &(_ | _) => (),
//         (_ | _,) => (),
//         [_ | _,] => (),
//     }
// }
/// Parses a pattern list separated by pipes `|`, with no leading `|`,using the
/// given `recovery_set`.
fn pattern_r(p: &mut Parser<'_>, recovery_set: TokenSet) {
    let m = p.start();
    let has_leading_pipe = p.eat(T![|]);

    pattern_single_r(p, recovery_set);

    if !p.at(T![|]) && !has_leading_pipe {
        m.abandon(p);
        return;
    }
    while p.eat(T![|]) {
        pattern_single_r(p, recovery_set);
    }
    m.complete(p, OR_PAT);
}

fn pattern_single_r(p: &mut Parser<'_>, recovery_set: TokenSet) {
    // test range_pat
    // fn main() {
    //     match 92 {
    //         0 ... 100 => (),
    //         101 ..= 200 => (),
    //         200 .. 301 => (),
    //         302 .. => (),
    //         ..= 303 => (),
    //     }
    //
    //     match Some(10 as u8) {
    //         Some(0) | None => (),
    //         Some(1..) => (),
    //         Some(..=2) => (),
    //     }
    //
    //     match () {
    //         S { a: 0 } => (),
    //         S { a: 1.. } => (),
    //         S { a: ..=2 } => (),
    //     }
    //
    //     match () {
    //         [0] => (),
    //         [1..] => (),
    //         [..=2] => (),
    //     }
    //
    //     match (10 as u8, 5 as u8) {
    //         (0, _) => (),
    //         (1.., _) => (),
    //         (..=2, _) => (),
    //     }
    // }

    if p.at(T![..=]) {
        let m = p.start();
        p.bump(T![..=]);
        atom_pat(p, recovery_set);
        m.complete(p, RANGE_PAT);
        return;
    }

    // test exclusive_range_pat
    // fn main() {
    //     match 42 {
    //         ..0 => {}
    //         1..2 => {}
    //     }
    // }

    // test dot_dot_pat
    // fn main() {
    //     let .. = ();
    //     //
    //     // Tuples
    //     //
    //     let (a, ..) = ();
    //     let (a, ..,) = ();
    //     let Tuple(a, ..) = ();
    //     let Tuple(a, ..,) = ();
    //     let (.., ..) = ();
    //     let Tuple(.., ..) = ();
    //     let (.., a, ..) = ();
    //     let Tuple(.., a, ..) = ();
    //     //
    //     // Slices
    //     //
    //     let [..] = ();
    //     let [head, ..] = ();
    //     let [head, tail @ ..] = ();
    //     let [head, .., cons] = ();
    //     let [head, mid @ .., cons] = ();
    //     let [head, .., .., cons] = ();
    //     let [head, .., mid, tail @ ..] = ();
    //     let [head, .., mid, .., cons] = ();
    // }
    if p.at(T![..]) {
        let m = p.start();
        p.bump(T![..]);
        if p.at_ts(RANGE_PAT_END_FIRST) {
            atom_pat(p, recovery_set);
            m.complete(p, RANGE_PAT);
        } else {
            m.complete(p, REST_PAT);
        }
        return;
    }

    if let Some(lhs) = atom_pat(p, recovery_set) {
        for range_op in [T![...], T![..=], T![..]] {
            if p.at(range_op) {
                let m = lhs.precede(p);
                p.bump(range_op);

                // testing if we're at one of the following positions:
                // `0 .. =>`
                //       ^
                // `let 0 .. =`
                //           ^
                // `let 0..: _ =`
                //         ^
                // (1.., _)
                //     ^
                // `Some(0 .. )`
                //            ^
                // `S { t: 0.. }`
                //             ^
                // `[0..]`
                //      ^
                // `0 .. if`
                //       ^
                if matches!(
                    p.current(),
                    T![=] | T![,] | T![:] | T![')'] | T!['}'] | T![']'] | T![if] | EOF
                ) {
                    // test half_open_range_pat
                    // fn f() {
                    //     let 0 .. = 1u32;
                    //     let 0..: _ = 1u32;
                    //
                    //     match 42 {
                    //         0 .. if true => (),
                    //         _ => (),
                    //     }
                    // }
                } else {
                    atom_pat(p, recovery_set);
                }
                m.complete(p, RANGE_PAT);
                return;
            }
        }
    }
}

const PAT_RECOVERY_SET: TokenSet = TokenSet::new(&[
    T![let],
    T![if],
    T![while],
    T![loop],
    T![match],
    T![')'],
    T![']'],
    T!['}'],
    T![,],
    T![=],
    T![&],
]);

fn atom_pat(p: &mut Parser<'_>, recovery_set: TokenSet) -> Option<CompletedMarker> {
    let m = match p.current() {
        T![box] => box_pat(p),
        T![ref] | T![mut] => ident_pat(p, true),
        T![const] => const_block_pat(p),
        IDENT => match p.nth(1) {
            // Checks the token after an IDENT to see if a pattern is a path (Struct { .. }) or macro
            // (T![x]).
            T!['('] | T!['{'] | T![!] => path_or_macro_pat(p),
            T![:] if p.nth_at(1, T![::]) => path_or_macro_pat(p),
            _ => ident_pat(p, true),
        },

        // test type_path_in_pattern
        // fn main() { let <_>::Foo = (); }
        _ if paths::is_path_start(p) => path_or_macro_pat(p),
        _ if is_literal_pat_start(p) => literal_pat(p),

        T![_] => wildcard_pat(p),
        T![&] => ref_pat(p),
        T!['('] => tuple_pat(p),
        T!['['] => slice_pat(p),

        _ => {
            p.err_recover("expected pattern", recovery_set);
            return None;
        }
    };

    Some(m)
}

fn is_literal_pat_start(p: &Parser<'_>) -> bool {
    p.at(T![-]) && (p.nth(1) == INT_NUMBER || p.nth(1) == FLOAT_NUMBER)
        || p.at_ts(expressions::LITERAL_FIRST)
}

// test literal_pattern
// fn main() {
//     match () {
//         -1 => (),
//         92 => (),
//         'c' => (),
//         "hello" => (),
//     }
// }
fn literal_pat(p: &mut Parser<'_>) -> CompletedMarker {
    assert!(is_literal_pat_start(p));
    let m = p.start();
    p.eat(T![-]);
    expressions::literal(p);
    m.complete(p, LITERAL_PAT)
}

// test path_part
// fn foo() {
//     let foo::Bar = ();
//     let ::Bar = ();
//     let Bar { .. } = ();
//     let Bar(..) = ();
// }
fn path_or_macro_pat(p: &mut Parser<'_>) -> CompletedMarker {
    assert!(paths::is_path_start(p));
    let m = p.start();
    paths::expr_path(p);
    let kind = match p.current() {
        T!['('] => {
            tuple_pat_fields(p);
            TUPLE_STRUCT_PAT
        }
        T!['{'] => {
            record_pat_field_list(p);
            RECORD_PAT
        }
        // test marco_pat
        // fn main() {
        //     let m!(x) = 0;
        // }
        T![!] => {
            items::macro_call_after_excl(p);
            return m.complete(p, MACRO_CALL).precede(p).complete(p, MACRO_PAT);
        }
        _ => PATH_PAT,
    };
    m.complete(p, kind)
}

// test tuple_pat_fields
// fn foo() {
//     let S() = ();
//     let S(_) = ();
//     let S(_,) = ();
//     let S(_, .. , x) = ();
//     let S(| a) = ();
// }
fn tuple_pat_fields(p: &mut Parser<'_>) {
    assert!(p.at(T!['(']));
    p.bump(T!['(']);
    pat_list(p, T![')']);
    p.expect(T![')']);
}

// test record_pat_field
// fn foo() {
//     let S { 0: 1 } = ();
//     let S { x: 1 } = ();
//     let S { #[cfg(any())] x: 1 } = ();
// }
fn record_pat_field(p: &mut Parser<'_>) {
    match p.current() {
        IDENT | INT_NUMBER if p.nth(1) == T![:] => {
            name_ref_or_index(p);
            p.bump(T![:]);
            // test record_field_pat_leading_or
            // fn foo() { let R { a: | 1 | 2 } = 0; }
            pattern(p);
        }
        // test_err record_pat_field_eq_recovery
        // fn main() {
        //     let S { field = foo };
        // }
        IDENT | INT_NUMBER if p.nth(1) == T![=] => {
            name_ref_or_index(p);
            p.err_and_bump("expected `:`");
            pattern(p);
        }
        T![box] => {
            // FIXME: not all box patterns should be allowed
            box_pat(p);
        }
        T![ref] | T![mut] | IDENT => {
            ident_pat(p, false);
        }
        _ => {
            p.err_and_bump("expected identifier");
        }
    }
}

// test record_pat_field_list
// fn foo() {
//     let S {} = ();
//     let S { f, ref mut g } = ();
//     let S { h: _, ..} = ();
//     let S { h: _, } = ();
//     let S { #[cfg(any())] .. } = ();
// }
fn record_pat_field_list(p: &mut Parser<'_>) {
    assert!(p.at(T!['{']));
    let m = p.start();
    p.bump(T!['{']);
    while !p.at(EOF) && !p.at(T!['}']) {
        let m = p.start();
        attributes::outer_attrs(p);

        match p.current() {
            // A trailing `..` is *not* treated as a REST_PAT.
            T![.] if p.at(T![..]) => {
                p.bump(T![..]);
                m.complete(p, REST_PAT);
            }
            T!['{'] => {
                error_block(p, "expected ident");
                m.abandon(p);
            }
            _ => {
                record_pat_field(p);
                m.complete(p, RECORD_PAT_FIELD);
            }
        }
        if !p.at(T!['}']) {
            p.expect(T![,]);
        }
    }
    p.expect(T!['}']);
    m.complete(p, RECORD_PAT_FIELD_LIST);
}

// test placeholder_pat
// fn main() { let _ = (); }
fn wildcard_pat(p: &mut Parser<'_>) -> CompletedMarker {
    assert!(p.at(T![_]));
    let m = p.start();
    p.bump(T![_]);
    m.complete(p, WILDCARD_PAT)
}

// test ref_pat
// fn main() {
//     let &a = ();
//     let &mut b = ();
// }
fn ref_pat(p: &mut Parser<'_>) -> CompletedMarker {
    assert!(p.at(T![&]));
    let m = p.start();
    p.bump(T![&]);
    p.eat(T![mut]);
    pattern_single(p);
    m.complete(p, REF_PAT)
}

// test tuple_pat
// fn main() {
//     let (a, b, ..) = ();
//     let (a,) = ();
//     let (..) = ();
//     let () = ();
//     let (| a | a, | b) = ((),());
// }
fn tuple_pat(p: &mut Parser<'_>) -> CompletedMarker {
    assert!(p.at(T!['(']));
    let m = p.start();
    p.bump(T!['(']);
    let mut has_comma = false;
    let mut has_pat = false;
    let mut has_rest = false;

    // test_err tuple_pat_leading_comma
    // fn foo() {
    //     let (,);
    // }
    if p.eat(T![,]) {
        p.error("expected pattern");
        has_comma = true;
    }

    while !p.at(EOF) && !p.at(T![')']) {
        has_pat = true;
        if !p.at_ts(PAT_TOP_FIRST) {
            p.error("expected a pattern");
            break;
        }
        has_rest |= p.at(T![..]);

        pattern(p);
        if !p.at(T![')']) {
            has_comma = true;
            p.expect(T![,]);
        }
    }
    p.expect(T![')']);

    m.complete(p, if !has_comma && !has_rest && has_pat { PAREN_PAT } else { TUPLE_PAT })
}

// test slice_pat
// fn main() {
//     let [a, b, ..] = [];
//     let [| a, ..] = [];
// }
fn slice_pat(p: &mut Parser<'_>) -> CompletedMarker {
    assert!(p.at(T!['[']));
    let m = p.start();
    p.bump(T!['[']);
    pat_list(p, T![']']);
    p.expect(T![']']);
    m.complete(p, SLICE_PAT)
}

fn pat_list(p: &mut Parser<'_>, ket: SyntaxKind) {
    while !p.at(EOF) && !p.at(ket) {
        pattern(p);
        if !p.eat(T![,]) {
            if p.at_ts(PAT_TOP_FIRST) {
                p.error(format!("expected {:?}, got {:?}", T![,], p.current()));
            } else {
                break;
            }
        }
    }
}

// test bind_pat
// fn main() {
//     let a = ();
//     let mut b = ();
//     let ref c = ();
//     let ref mut d = ();
//     let e @ _ = ();
//     let ref mut f @ g @ _ = ();
// }
fn ident_pat(p: &mut Parser<'_>, with_at: bool) -> CompletedMarker {
    assert!(matches!(p.current(), T![ref] | T![mut] | IDENT));
    let m = p.start();
    p.eat(T![ref]);
    p.eat(T![mut]);
    name_r(p, PAT_RECOVERY_SET);
    if with_at && p.eat(T![@]) {
        pattern_single(p);
    }
    m.complete(p, IDENT_PAT)
}

// test box_pat
// fn main() {
//     let box i = ();
//     let box Outer { box i, j: box Inner(box &x) } = ();
//     let box ref mut i = ();
// }
fn box_pat(p: &mut Parser<'_>) -> CompletedMarker {
    assert!(p.at(T![box]));
    let m = p.start();
    p.bump(T![box]);
    pattern_single(p);
    m.complete(p, BOX_PAT)
}

// test const_block_pat
// fn main() {
//     let const { 15 } = ();
//     let const { foo(); bar() } = ();
//
//     match 42 {
//         const { 0 } .. const { 1 } => (),
//         .. const { 0 } => (),
//         const { 2 } .. => (),
//     }
//
//     let (const { () },) = ();
// }
fn const_block_pat(p: &mut Parser<'_>) -> CompletedMarker {
    assert!(p.at(T![const]));
    let m = p.start();
    p.bump(T![const]);
    expressions::block_expr(p);
    m.complete(p, CONST_BLOCK_PAT)
}