crates/parser/src/grammar/items.rs - third_party/github.com/rust-lang/rust-analyzer - Git at Google

 mod adt;
 mod consts;
 mod traits;
 mod use_item;

 pub(crate) use self::{
     adt::{record_field_list, variant_list},
     expressions::{match_arm_list, record_expr_field_list},
     traits::assoc_item_list,
     use_item::use_tree_list,
 };
 use super::*;

 // test mod_contents
 // fn foo() {}
 // macro_rules! foo {}
 // foo::bar!();
 // super::baz! {}
 // struct S;
 pub(super) fn mod_contents(p: &mut Parser<'_>, stop_on_r_curly: bool) {
     attributes::inner_attrs(p);
     while !(p.at(EOF) || (p.at(T!['}']) && stop_on_r_curly)) {
         // We can set `is_in_extern=true`, because it only allows `safe fn`, and there is no ambiguity here.
         item_or_macro(p, stop_on_r_curly, true);
     }
 }

 pub(super) const ITEM_RECOVERY_SET: TokenSet = TokenSet::new(&[
     T![fn],
     T![struct],
     T![enum],
     T![impl],
     T![trait],
     T![const],
     T![async],
     T![unsafe],
     T![extern],
     T![static],
     T![let],
     T![mod],
     T![pub],
     T![crate],
     T![use],
     T![macro],
     T![;],
 ]);

 pub(super) fn item_or_macro(p: &mut Parser<'_>, stop_on_r_curly: bool, is_in_extern: bool) {
     let m = p.start();
     attributes::outer_attrs(p);

     let m = match opt_item(p, m, is_in_extern) {
         Ok(()) => {
             if p.at(T![;]) {
                 p.err_and_bump(
                     "expected item, found `;`\n\
                      consider removing this semicolon",
                 );
             }
             return;
         }
         Err(m) => m,
     };

     // test macro_rules_as_macro_name
     // macro_rules! {}
     // macro_rules! ();
     // macro_rules! [];
     // fn main() {
     //     let foo = macro_rules!();
     // }

     // test_err macro_rules_as_macro_name
     // macro_rules! {};
     // macro_rules! ()
     // macro_rules! []
     if paths::is_use_path_start(p) {
         paths::use_path(p);
         // Do not create a MACRO_CALL node here if this isn't a macro call, this causes problems with completion.

         // test_err path_item_without_excl
         // foo
         if p.at(T![!]) {
             macro_call(p, m);
             return;
         } else {
             m.complete(p, ERROR);
             p.error("expected an item");
             return;
         }
     }

     m.abandon(p);
     match p.current() {
         T!['{'] => error_block(p, "expected an item"),
         T!['}'] if !stop_on_r_curly => {
             let e = p.start();
             p.error("unmatched `}`");
             p.bump(T!['}']);
             e.complete(p, ERROR);
         }
         EOF | T!['}'] => p.error("expected an item"),
         T![let] => error_let_stmt(p, "expected an item"),
         _ => p.err_and_bump("expected an item"),
     }
 }

 /// Try to parse an item, completing `m` in case of success.
 pub(super) fn opt_item(p: &mut Parser<'_>, m: Marker, is_in_extern: bool) -> Result<(), Marker> {
     // test_err pub_expr
     // fn foo() { pub 92; }
     let has_visibility = opt_visibility(p, false);

     let m = match opt_item_without_modifiers(p, m) {
         Ok(()) => return Ok(()),
         Err(m) => m,
     };

     let mut has_mods = false;
     let mut has_extern = false;

     // modifiers
     if p.at(T![const]) && p.nth(1) != T!['{'] {
         p.eat(T![const]);
         has_mods = true;
     }

     // test_err async_without_semicolon
     // fn foo() { let _ = async {} }
     if p.at(T![async])
         && (!matches!(p.nth(1), T!['{'] | T![gen] | T![move] | T![|])
             || matches!((p.nth(1), p.nth(2)), (T![gen], T![fn])))
     {
         p.eat(T![async]);
         has_mods = true;
     }

     // test_err gen_fn 2021
     // gen fn gen_fn() {}
     // async gen fn async_gen_fn() {}
     if p.at(T![gen]) && p.nth(1) == T![fn] {
         p.eat(T![gen]);
         has_mods = true;
     }

     // test_err unsafe_block_in_mod
     // fn foo(){} unsafe { } fn bar(){}
     if p.at(T![unsafe]) && p.nth(1) != T!['{'] {
         p.eat(T![unsafe]);
         has_mods = true;
     }

     // test safe_outside_of_extern
     // fn foo() { safe = true; }
     if is_in_extern && p.at_contextual_kw(T![safe]) {
         p.eat_contextual_kw(T![safe]);
         has_mods = true;
     }

     if p.at(T![extern]) {
         has_extern = true;
         has_mods = true;
         abi(p);
     }
     if p.at_contextual_kw(T![auto]) && p.nth(1) == T![trait] {
         p.bump_remap(T![auto]);
         has_mods = true;
     }

     // test default_item
     // default impl T for Foo {}
     if p.at_contextual_kw(T![default]) {
         match p.nth(1) {
             T![fn] | T![type] | T![const] | T![impl] => {
                 p.bump_remap(T![default]);
                 has_mods = true;
             }
             // test default_unsafe_item
             // default unsafe impl T for Foo {
             //     default unsafe fn foo() {}
             // }
             T![unsafe] if matches!(p.nth(2), T![impl] | T![fn]) => {
                 p.bump_remap(T![default]);
                 p.bump(T![unsafe]);
                 has_mods = true;
             }
             // test default_async_fn
             // impl T for Foo {
             //     default async fn foo() {}
             // }
             T![async]
                 if p.nth_at(2, T![fn]) || (p.nth_at(2, T![unsafe]) && p.nth_at(3, T![fn])) =>
             {
                 p.bump_remap(T![default]);
                 p.bump(T![async]);

                 // test default_async_unsafe_fn
                 // impl T for Foo {
                 //     default async unsafe fn foo() {}
                 // }
                 p.eat(T![unsafe]);

                 has_mods = true;
             }
             _ => (),
         }
     }

     // items
     match p.current() {
         T![fn] => fn_(p, m),

         T![const] if p.nth(1) != T!['{'] => consts::konst(p, m),
         T![static] if matches!(p.nth(1), IDENT | T![_] | T![mut]) => consts::static_(p, m),

         T![trait] => traits::trait_(p, m),
         T![impl] => traits::impl_(p, m),

         T![type] => type_alias(p, m),

         // test extern_block
         // unsafe extern "C" {}
         // extern {}
         T!['{'] if has_extern => {
             extern_item_list(p);
             m.complete(p, EXTERN_BLOCK);
         }

         _ if has_visibility || has_mods => {
             if has_mods {
                 p.error("expected fn, trait or impl");
             } else {
                 p.error("expected an item");
             }
             m.complete(p, ERROR);
         }

         _ => return Err(m),
     }
     Ok(())
 }

 fn opt_item_without_modifiers(p: &mut Parser<'_>, m: Marker) -> Result<(), Marker> {
     let la = p.nth(1);
     match p.current() {
         T![extern] if la == T![crate] => extern_crate(p, m),
         T![use] => use_item::use_(p, m),
         T![mod] => mod_item(p, m),

         T![type] => type_alias(p, m),
         T![struct] => adt::strukt(p, m),
         T![enum] => adt::enum_(p, m),
         IDENT if p.at_contextual_kw(T![union]) && p.nth(1) == IDENT => adt::union(p, m),

         T![macro] => macro_def(p, m),
         // check if current token is "macro_rules" followed by "!" followed by an identifier
         IDENT if p.at_contextual_kw(T![macro_rules]) && p.nth_at(1, BANG) && p.nth_at(2, IDENT) => {
             macro_rules(p, m)
         }

         T![const] if (la == IDENT || la == T![_] || la == T![mut]) => consts::konst(p, m),
         T![static] if (la == IDENT || la == T![_] || la == T![mut]) => consts::static_(p, m),

         IDENT
             if p.at_contextual_kw(T![builtin])
                 && p.nth_at(1, T![#])
                 && p.nth_at_contextual_kw(2, T![global_asm]) =>
         {
             p.bump_remap(T![builtin]);
             p.bump(T![#]);
             p.bump_remap(T![global_asm]);
             // test global_asm
             // builtin#global_asm("")
             expressions::parse_asm_expr(p, m);
         }

         _ => return Err(m),
     };
     Ok(())
 }

 // test extern_crate
 // extern crate foo;
 // extern crate self;
 fn extern_crate(p: &mut Parser<'_>, m: Marker) {
     p.bump(T![extern]);
     p.bump(T![crate]);

     name_ref_or_self(p);

     // test extern_crate_rename
     // extern crate foo as bar;
     // extern crate self as bar;
     opt_rename(p);
     p.expect(T![;]);
     m.complete(p, EXTERN_CRATE);
 }

 // test mod_item
 // mod a;
 pub(crate) fn mod_item(p: &mut Parser<'_>, m: Marker) {
     p.bump(T![mod]);
     name(p);
     if p.at(T!['{']) {
         // test mod_item_curly
         // mod b { }
         item_list(p);
     } else if !p.eat(T![;]) {
         p.error("expected `;` or `{`");
     }
     m.complete(p, MODULE);
 }

 // test type_alias
 // type Foo = Bar;
 fn type_alias(p: &mut Parser<'_>, m: Marker) {
     p.bump(T![type]);

     name(p);

     // test type_item_type_params
     // type Result<T> = ();
     generic_params::opt_generic_param_list(p);

     if p.at(T![:]) {
         generic_params::bounds(p);
     }

     // test type_item_where_clause_deprecated
     // type Foo where Foo: Copy = ();
     generic_params::opt_where_clause(p);
     if p.eat(T![=]) {
         types::type_(p);
     }

     // test type_item_where_clause
     // type Foo = () where Foo: Copy;
     generic_params::opt_where_clause(p);

     p.expect(T![;]);
     m.complete(p, TYPE_ALIAS);
 }

 pub(crate) fn item_list(p: &mut Parser<'_>) {
     assert!(p.at(T!['{']));
     let m = p.start();
     p.bump(T!['{']);
     mod_contents(p, true);
     p.expect(T!['}']);
     m.complete(p, ITEM_LIST);
 }

 pub(crate) fn extern_item_list(p: &mut Parser<'_>) {
     assert!(p.at(T!['{']));
     let m = p.start();
     p.bump(T!['{']);
     mod_contents(p, true);
     p.expect(T!['}']);
     m.complete(p, EXTERN_ITEM_LIST);
 }

 // test try_macro_rules 2015
 // macro_rules! try { () => {} }
 fn macro_rules(p: &mut Parser<'_>, m: Marker) {
     assert!(p.at_contextual_kw(T![macro_rules]));
     p.bump_remap(T![macro_rules]);
     p.expect(T![!]);

     name(p);

     match p.current() {
         // test macro_rules_non_brace
         // macro_rules! m ( ($i:ident) => {} );
         // macro_rules! m [ ($i:ident) => {} ];
         T!['['] | T!['('] => {
             token_tree(p);
             p.expect(T![;]);
         }
         T!['{'] => token_tree(p),
         _ => p.error("expected `{`, `[`, `(`"),
     }
     m.complete(p, MACRO_RULES);
 }

 // test macro_def
 // macro m($i:ident) {}
 fn macro_def(p: &mut Parser<'_>, m: Marker) {
     p.expect(T![macro]);
     name_r(p, ITEM_RECOVERY_SET);
     if p.at(T!['{']) {
         // test macro_def_curly
         // macro m { ($i:ident) => {} }
         token_tree(p);
     } else if p.at(T!['(']) {
         token_tree(p);
         match p.current() {
             T!['{'] | T!['['] | T!['('] => token_tree(p),
             _ => p.error("expected `{`, `[`, `(`"),
         }
     } else {
         p.error("unmatched `(`");
     }

     m.complete(p, MACRO_DEF);
 }

 // test fn_
 // fn foo() {}
 fn fn_(p: &mut Parser<'_>, m: Marker) {
     p.bump(T![fn]);

     name_r(p, ITEM_RECOVERY_SET);
     // test function_type_params
     // fn foo<T: Clone + Copy>(){}
     generic_params::opt_generic_param_list(p);

     if p.at(T!['(']) {
         params::param_list_fn_def(p);
     } else {
         p.error("expected function arguments");
     }
     // test function_ret_type
     // fn foo() {}
     // fn bar() -> () {}
     opt_ret_type(p);

     // test function_where_clause
     // fn foo<T>() where T: Copy {}
     generic_params::opt_where_clause(p);

     // test fn_decl
     // trait T { fn foo(); }
     if !p.eat(T![;]) {
         expressions::block_expr(p);
     }
     m.complete(p, FN);
 }

 fn macro_call(p: &mut Parser<'_>, m: Marker) {
     assert!(p.at(T![!]));
     match macro_call_after_excl(p) {
         BlockLike::Block => (),
         BlockLike::NotBlock => {
             p.expect(T![;]);
         }
     }
     m.complete(p, MACRO_CALL);
 }

 pub(super) fn macro_call_after_excl(p: &mut Parser<'_>) -> BlockLike {
     p.expect(T![!]);

     match p.current() {
         T!['{'] => {
             token_tree(p);
             BlockLike::Block
         }
         T!['('] | T!['['] => {
             token_tree(p);
             BlockLike::NotBlock
         }
         _ => {
             p.error("expected `{`, `[`, `(`");
             BlockLike::NotBlock
         }
     }
 }

 pub(crate) fn token_tree(p: &mut Parser<'_>) {
     let closing_paren_kind = match p.current() {
         T!['{'] => T!['}'],
         T!['('] => T![')'],
         T!['['] => T![']'],
         _ => unreachable!(),
     };
     let m = p.start();
     p.bump_any();
     while !p.at(EOF) && !p.at(closing_paren_kind) {
         match p.current() {
             T!['{'] | T!['('] | T!['['] => token_tree(p),
             T!['}'] => {
                 p.error("unmatched `}`");
                 m.complete(p, TOKEN_TREE);
                 return;
             }
             T![')'] | T![']'] => p.err_and_bump("unmatched brace"),
             _ => p.bump_any(),
         }
     }
     p.expect(closing_paren_kind);
     m.complete(p, TOKEN_TREE);
 }
	mod adt;
	mod consts;
	mod traits;
	mod use_item;

	pub(crate) use self::{
	adt::{record_field_list, variant_list},
	expressions::{match_arm_list, record_expr_field_list},
	traits::assoc_item_list,
	use_item::use_tree_list,
	};
	use super::*;

	// test mod_contents
	// fn foo() {}
	// macro_rules! foo {}
	// foo::bar!();
	// super::baz! {}
	// struct S;
	pub(super) fn mod_contents(p: &mut Parser<'_>, stop_on_r_curly: bool) {
	attributes::inner_attrs(p);
	while !(p.at(EOF) \|\| (p.at(T!['}']) && stop_on_r_curly)) {
	// We can set `is_in_extern=true`, because it only allows `safe fn`, and there is no ambiguity here.
	item_or_macro(p, stop_on_r_curly, true);
	}
	}

	pub(super) const ITEM_RECOVERY_SET: TokenSet = TokenSet::new(&[
	T![fn],
	T![struct],
	T![enum],
	T![impl],
	T![trait],
	T![const],
	T![async],
	T![unsafe],
	T![extern],
	T![static],
	T![let],
	T![mod],
	T![pub],
	T![crate],
	T![use],
	T![macro],
	T![;],
	]);

	pub(super) fn item_or_macro(p: &mut Parser<'_>, stop_on_r_curly: bool, is_in_extern: bool) {
	let m = p.start();
	attributes::outer_attrs(p);

	let m = match opt_item(p, m, is_in_extern) {
	Ok(()) => {
	if p.at(T![;]) {
	p.err_and_bump(
	"expected item, found `;`\n\
	consider removing this semicolon",
	);
	}
	return;
	}
	Err(m) => m,
	};

	// test macro_rules_as_macro_name
	// macro_rules! {}
	// macro_rules! ();
	// macro_rules! [];
	// fn main() {
	// let foo = macro_rules!();
	// }

	// test_err macro_rules_as_macro_name
	// macro_rules! {};
	// macro_rules! ()
	// macro_rules! []
	if paths::is_use_path_start(p) {
	paths::use_path(p);
	// Do not create a MACRO_CALL node here if this isn't a macro call, this causes problems with completion.

	// test_err path_item_without_excl
	// foo
	if p.at(T![!]) {
	macro_call(p, m);
	return;
	} else {
	m.complete(p, ERROR);
	p.error("expected an item");
	return;
	}
	}

	m.abandon(p);
	match p.current() {
	T!['{'] => error_block(p, "expected an item"),
	T!['}'] if !stop_on_r_curly => {
	let e = p.start();
	p.error("unmatched `}`");
	p.bump(T!['}']);
	e.complete(p, ERROR);
	}
	EOF \| T!['}'] => p.error("expected an item"),
	T![let] => error_let_stmt(p, "expected an item"),
	_ => p.err_and_bump("expected an item"),
	}
	}

	/// Try to parse an item, completing `m` in case of success.
	pub(super) fn opt_item(p: &mut Parser<'_>, m: Marker, is_in_extern: bool) -> Result<(), Marker> {
	// test_err pub_expr
	// fn foo() { pub 92; }
	let has_visibility = opt_visibility(p, false);

	let m = match opt_item_without_modifiers(p, m) {
	Ok(()) => return Ok(()),
	Err(m) => m,
	};

	let mut has_mods = false;
	let mut has_extern = false;

	// modifiers
	if p.at(T![const]) && p.nth(1) != T!['{'] {
	p.eat(T![const]);
	has_mods = true;
	}

	// test_err async_without_semicolon
	// fn foo() { let _ = async {} }
	if p.at(T![async])
	&& (!matches!(p.nth(1), T!['{'] \| T![gen] \| T![move] \| T![\|])
	\|\| matches!((p.nth(1), p.nth(2)), (T![gen], T![fn])))
	{
	p.eat(T![async]);
	has_mods = true;
	}

	// test_err gen_fn 2021
	// gen fn gen_fn() {}
	// async gen fn async_gen_fn() {}
	if p.at(T![gen]) && p.nth(1) == T![fn] {
	p.eat(T![gen]);
	has_mods = true;
	}

	// test_err unsafe_block_in_mod
	// fn foo(){} unsafe { } fn bar(){}
	if p.at(T![unsafe]) && p.nth(1) != T!['{'] {
	p.eat(T![unsafe]);
	has_mods = true;
	}

	// test safe_outside_of_extern
	// fn foo() { safe = true; }
	if is_in_extern && p.at_contextual_kw(T![safe]) {
	p.eat_contextual_kw(T![safe]);
	has_mods = true;
	}

	if p.at(T![extern]) {
	has_extern = true;
	has_mods = true;
	abi(p);
	}
	if p.at_contextual_kw(T![auto]) && p.nth(1) == T![trait] {
	p.bump_remap(T![auto]);
	has_mods = true;
	}

	// test default_item
	// default impl T for Foo {}
	if p.at_contextual_kw(T![default]) {
	match p.nth(1) {
	T![fn] \| T![type] \| T![const] \| T![impl] => {
	p.bump_remap(T![default]);
	has_mods = true;
	}
	// test default_unsafe_item
	// default unsafe impl T for Foo {
	// default unsafe fn foo() {}
	// }
	T![unsafe] if matches!(p.nth(2), T![impl] \| T![fn]) => {
	p.bump_remap(T![default]);
	p.bump(T![unsafe]);
	has_mods = true;
	}
	// test default_async_fn
	// impl T for Foo {
	// default async fn foo() {}
	// }
	T![async]
	if p.nth_at(2, T![fn]) \|\| (p.nth_at(2, T![unsafe]) && p.nth_at(3, T![fn])) =>
	{
	p.bump_remap(T![default]);
	p.bump(T![async]);

	// test default_async_unsafe_fn
	// impl T for Foo {
	// default async unsafe fn foo() {}
	// }
	p.eat(T![unsafe]);

	has_mods = true;
	}
	_ => (),
	}
	}

	// items
	match p.current() {
	T![fn] => fn_(p, m),

	T![const] if p.nth(1) != T!['{'] => consts::konst(p, m),
	T![static] if matches!(p.nth(1), IDENT \| T![_] \| T![mut]) => consts::static_(p, m),

	T![trait] => traits::trait_(p, m),
	T![impl] => traits::impl_(p, m),

	T![type] => type_alias(p, m),

	// test extern_block
	// unsafe extern "C" {}
	// extern {}
	T!['{'] if has_extern => {
	extern_item_list(p);
	m.complete(p, EXTERN_BLOCK);
	}

	_ if has_visibility \|\| has_mods => {
	if has_mods {
	p.error("expected fn, trait or impl");
	} else {
	p.error("expected an item");
	}
	m.complete(p, ERROR);
	}

	_ => return Err(m),
	}
	Ok(())
	}

	fn opt_item_without_modifiers(p: &mut Parser<'_>, m: Marker) -> Result<(), Marker> {
	let la = p.nth(1);
	match p.current() {
	T![extern] if la == T![crate] => extern_crate(p, m),
	T![use] => use_item::use_(p, m),
	T![mod] => mod_item(p, m),

	T![type] => type_alias(p, m),
	T![struct] => adt::strukt(p, m),
	T![enum] => adt::enum_(p, m),
	IDENT if p.at_contextual_kw(T![union]) && p.nth(1) == IDENT => adt::union(p, m),

	T![macro] => macro_def(p, m),
	// check if current token is "macro_rules" followed by "!" followed by an identifier
	IDENT if p.at_contextual_kw(T![macro_rules]) && p.nth_at(1, BANG) && p.nth_at(2, IDENT) => {
	macro_rules(p, m)
	}

	T![const] if (la == IDENT \|\| la == T![_] \|\| la == T![mut]) => consts::konst(p, m),
	T![static] if (la == IDENT \|\| la == T![_] \|\| la == T![mut]) => consts::static_(p, m),

	IDENT
	if p.at_contextual_kw(T![builtin])
	&& p.nth_at(1, T![#])
	&& p.nth_at_contextual_kw(2, T![global_asm]) =>
	{
	p.bump_remap(T![builtin]);
	p.bump(T![#]);
	p.bump_remap(T![global_asm]);
	// test global_asm
	// builtin#global_asm("")
	expressions::parse_asm_expr(p, m);
	}

	_ => return Err(m),
	};
	Ok(())
	}

	// test extern_crate
	// extern crate foo;
	// extern crate self;
	fn extern_crate(p: &mut Parser<'_>, m: Marker) {
	p.bump(T![extern]);
	p.bump(T![crate]);

	name_ref_or_self(p);

	// test extern_crate_rename
	// extern crate foo as bar;
	// extern crate self as bar;
	opt_rename(p);
	p.expect(T![;]);
	m.complete(p, EXTERN_CRATE);
	}

	// test mod_item
	// mod a;
	pub(crate) fn mod_item(p: &mut Parser<'_>, m: Marker) {
	p.bump(T![mod]);
	name(p);
	if p.at(T!['{']) {
	// test mod_item_curly
	// mod b { }
	item_list(p);
	} else if !p.eat(T![;]) {
	p.error("expected `;` or `{`");
	}
	m.complete(p, MODULE);
	}

	// test type_alias
	// type Foo = Bar;
	fn type_alias(p: &mut Parser<'_>, m: Marker) {
	p.bump(T![type]);

	name(p);

	// test type_item_type_params
	// type Result<T> = ();
	generic_params::opt_generic_param_list(p);

	if p.at(T![:]) {
	generic_params::bounds(p);
	}

	// test type_item_where_clause_deprecated
	// type Foo where Foo: Copy = ();
	generic_params::opt_where_clause(p);
	if p.eat(T![=]) {
	types::type_(p);
	}

	// test type_item_where_clause
	// type Foo = () where Foo: Copy;
	generic_params::opt_where_clause(p);

	p.expect(T![;]);
	m.complete(p, TYPE_ALIAS);
	}

	pub(crate) fn item_list(p: &mut Parser<'_>) {
	assert!(p.at(T!['{']));
	let m = p.start();
	p.bump(T!['{']);
	mod_contents(p, true);
	p.expect(T!['}']);
	m.complete(p, ITEM_LIST);
	}

	pub(crate) fn extern_item_list(p: &mut Parser<'_>) {
	assert!(p.at(T!['{']));
	let m = p.start();
	p.bump(T!['{']);
	mod_contents(p, true);
	p.expect(T!['}']);
	m.complete(p, EXTERN_ITEM_LIST);
	}

	// test try_macro_rules 2015
	// macro_rules! try { () => {} }
	fn macro_rules(p: &mut Parser<'_>, m: Marker) {
	assert!(p.at_contextual_kw(T![macro_rules]));
	p.bump_remap(T![macro_rules]);
	p.expect(T![!]);

	name(p);

	match p.current() {
	// test macro_rules_non_brace
	// macro_rules! m ( ($i:ident) => {} );
	// macro_rules! m [ ($i:ident) => {} ];
	T!['['] \| T!['('] => {
	token_tree(p);
	p.expect(T![;]);
	}
	T!['{'] => token_tree(p),
	_ => p.error("expected `{`, `[`, `(`"),
	}
	m.complete(p, MACRO_RULES);
	}

	// test macro_def
	// macro m($i:ident) {}
	fn macro_def(p: &mut Parser<'_>, m: Marker) {
	p.expect(T![macro]);
	name_r(p, ITEM_RECOVERY_SET);
	if p.at(T!['{']) {
	// test macro_def_curly
	// macro m { ($i:ident) => {} }
	token_tree(p);
	} else if p.at(T!['(']) {
	token_tree(p);
	match p.current() {
	T!['{'] \| T!['['] \| T!['('] => token_tree(p),
	_ => p.error("expected `{`, `[`, `(`"),
	}
	} else {
	p.error("unmatched `(`");
	}

	m.complete(p, MACRO_DEF);
	}

	// test fn_
	// fn foo() {}
	fn fn_(p: &mut Parser<'_>, m: Marker) {
	p.bump(T![fn]);

	name_r(p, ITEM_RECOVERY_SET);
	// test function_type_params
	// fn foo<T: Clone + Copy>(){}
	generic_params::opt_generic_param_list(p);

	if p.at(T!['(']) {
	params::param_list_fn_def(p);
	} else {
	p.error("expected function arguments");
	}
	// test function_ret_type
	// fn foo() {}
	// fn bar() -> () {}
	opt_ret_type(p);

	// test function_where_clause
	// fn foo<T>() where T: Copy {}
	generic_params::opt_where_clause(p);

	// test fn_decl
	// trait T { fn foo(); }
	if !p.eat(T![;]) {
	expressions::block_expr(p);
	}
	m.complete(p, FN);
	}

	fn macro_call(p: &mut Parser<'_>, m: Marker) {
	assert!(p.at(T![!]));
	match macro_call_after_excl(p) {
	BlockLike::Block => (),
	BlockLike::NotBlock => {
	p.expect(T![;]);
	}
	}
	m.complete(p, MACRO_CALL);
	}

	pub(super) fn macro_call_after_excl(p: &mut Parser<'_>) -> BlockLike {
	p.expect(T![!]);

	match p.current() {
	T!['{'] => {
	token_tree(p);
	BlockLike::Block
	}
	T!['('] \| T!['['] => {
	token_tree(p);
	BlockLike::NotBlock
	}
	_ => {
	p.error("expected `{`, `[`, `(`");
	BlockLike::NotBlock
	}
	}
	}

	pub(crate) fn token_tree(p: &mut Parser<'_>) {
	let closing_paren_kind = match p.current() {
	T!['{'] => T!['}'],
	T!['('] => T![')'],
	T!['['] => T![']'],
	_ => unreachable!(),
	};
	let m = p.start();
	p.bump_any();
	while !p.at(EOF) && !p.at(closing_paren_kind) {
	match p.current() {
	T!['{'] \| T!['('] \| T!['['] => token_tree(p),
	T!['}'] => {
	p.error("unmatched `}`");
	m.complete(p, TOKEN_TREE);
	return;
	}
	T![')'] \| T![']'] => p.err_and_bump("unmatched brace"),
	_ => p.bump_any(),
	}
	}
	p.expect(closing_paren_kind);
	m.complete(p, TOKEN_TREE);
	}