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

 use super::*;

 // test_err generic_arg_list_recover_expr
 // const _: () = T::<0, ,T>;
 // const _: () = T::<0, ,T>();
 pub(super) fn opt_generic_arg_list_expr(p: &mut Parser<'_>) {
     let m;
     if p.at(T![::]) && p.nth(2) == T![<] {
         m = p.start();
         p.bump(T![::]);
     } else {
         return;
     }

     delimited(
         p,
         T![<],
         T![>],
         T![,],
         || "expected generic argument".into(),
         GENERIC_ARG_FIRST,
         generic_arg,
     );
     m.complete(p, GENERIC_ARG_LIST);
 }

 pub(crate) const GENERIC_ARG_FIRST: TokenSet = TokenSet::new(&[
     LIFETIME_IDENT,
     IDENT,
     T!['{'],
     T![true],
     T![false],
     T![-],
     INT_NUMBER,
     FLOAT_NUMBER,
     CHAR,
     BYTE,
     STRING,
     BYTE_STRING,
     C_STRING,
 ])
 .union(types::TYPE_FIRST);

 // Despite its name, it can also be used for generic param list.
 const GENERIC_ARG_RECOVERY_SET: TokenSet = TokenSet::new(&[T![>], T![,]]);

 // test generic_arg
 // type T = S<i32, dyn T, fn()>;
 pub(crate) fn generic_arg(p: &mut Parser<'_>) -> bool {
     match p.current() {
         LIFETIME_IDENT if !p.nth_at(1, T![+]) => lifetime_arg(p),
         T!['{'] | T![true] | T![false] | T![-] => const_arg(p),
         k if k.is_literal() => const_arg(p),
         // test generic_arg_bounds
         // type Plain = Foo<Item, Item::Item, Item: Bound, Item = Item>;
         // type GenericArgs = Foo<Item<T>, Item::<T>, Item<T>: Bound, Item::<T>: Bound, Item<T> = Item, Item::<T> = Item>;
         // type ParenthesizedArgs = Foo<Item(T), Item::(T), Item(T): Bound, Item::(T): Bound, Item(T) = Item, Item::(T) = Item>;
         // type RTN = Foo<Item(..), Item(..), Item(..): Bound, Item(..): Bound, Item(..) = Item, Item(..) = Item>;

         // test edition_2015_dyn_prefix_inside_generic_arg 2015
         // type A = Foo<dyn T>;
         T![ident] if !p.edition().at_least_2018() && types::is_dyn_weak(p) => type_arg(p),
         // test macro_inside_generic_arg
         // type A = Foo<syn::Token![_]>;
         k if PATH_NAME_REF_KINDS.contains(k) => {
             let m = p.start();
             name_ref_mod_path(p);
             paths::opt_path_type_args(p);
             match p.current() {
                 T![=] => {
                     p.bump_any();
                     if types::TYPE_FIRST.contains(p.current()) {
                         // test assoc_type_eq
                         // type T = StreamingIterator<Item<'a> = &'a T>;
                         types::type_(p);
                     } else if p.at_ts(GENERIC_ARG_RECOVERY_SET) {
                         // Although `const_arg()` recovers as expected, we want to
                         // handle those here to give the following message because
                         // we don't know whether this associated item is a type or
                         // const at this point.

                         // test_err recover_from_missing_assoc_item_binding
                         // fn f() -> impl Iterator<Item = , Item = > {}
                         p.error("missing associated item binding");
                     } else {
                         // test assoc_const_eq
                         // fn foo<F: Foo<N=3>>() {}
                         // const TEST: usize = 3;
                         // fn bar<F: Foo<N={TEST}>>() {}
                         const_arg(p);
                     }
                     m.complete(p, ASSOC_TYPE_ARG);
                 }
                 // test assoc_type_bound
                 // type T = StreamingIterator<Item<'a>: Clone>;
                 // type T = StreamingIterator<Item(T): Clone>;
                 T![:] if !p.at(T![::]) => {
                     generic_params::bounds(p);
                     m.complete(p, ASSOC_TYPE_ARG);
                 }
                 // Turned out to be just a normal path type (mirror `path_or_macro_type`)
                 _ => {
                     let m = m.complete(p, PATH_SEGMENT).precede(p).complete(p, PATH);
                     let m = paths::type_path_for_qualifier(p, m);
                     let m = if p.at(T![!]) && !p.at(T![!=]) {
                         let m = m.precede(p);
                         items::macro_call_after_excl(p);
                         m.complete(p, MACRO_CALL).precede(p).complete(p, MACRO_TYPE)
                     } else {
                         m.precede(p).complete(p, PATH_TYPE)
                     };
                     types::opt_type_bounds_as_dyn_trait_type(p, m).precede(p).complete(p, TYPE_ARG);
                 }
             }
         }
         _ if p.at_ts(types::TYPE_FIRST) => type_arg(p),
         _ => return false,
     }
     true
 }

 // test lifetime_arg
 // type T = S<'static>;
 fn lifetime_arg(p: &mut Parser<'_>) {
     let m = p.start();
     lifetime(p);
     m.complete(p, LIFETIME_ARG);
 }

 pub(super) fn const_arg_expr(p: &mut Parser<'_>) {
     // The tests in here are really for `const_arg`, which wraps the content
     // CONST_ARG.
     match p.current() {
         // test const_arg_block
         // type T = S<{90 + 2}>;
         T!['{'] => {
             expressions::block_expr(p);
         }
         // test const_arg_literal
         // type T = S<"hello", 0xdeadbeef>;
         k if k.is_literal() => {
             expressions::literal(p);
         }
         // test const_arg_bool_literal
         // type T = S<true>;
         T![true] | T![false] => {
             expressions::literal(p);
         }
         // test const_arg_negative_number
         // type T = S<-92>;
         T![-] => {
             let lm = p.start();
             p.bump(T![-]);
             expressions::literal(p);
             lm.complete(p, PREFIX_EXPR);
         }
         _ if paths::is_path_start(p) => {
             // This shouldn't be hit by `const_arg`
             let lm = p.start();
             paths::expr_path(p);
             lm.complete(p, PATH_EXPR);
         }
         _ => {
             // test_err recover_from_missing_const_default
             // struct A<const N: i32 = , const M: i32 =>;
             p.err_recover("expected a generic const argument", GENERIC_ARG_RECOVERY_SET);
         }
     }
 }

 // test const_arg
 // type T = S<92>;
 pub(super) fn const_arg(p: &mut Parser<'_>) {
     let m = p.start();
     const_arg_expr(p);
     m.complete(p, CONST_ARG);
 }

 pub(crate) fn type_arg(p: &mut Parser<'_>) {
     let m = p.start();
     types::type_(p);
     m.complete(p, TYPE_ARG);
 }
	use super::*;

	// test_err generic_arg_list_recover_expr
	// const _: () = T::<0, ,T>;
	// const _: () = T::<0, ,T>();
	pub(super) fn opt_generic_arg_list_expr(p: &mut Parser<'_>) {
	let m;
	if p.at(T![::]) && p.nth(2) == T![<] {
	m = p.start();
	p.bump(T![::]);
	} else {
	return;
	}

	delimited(
	p,
	T![<],
	T![>],
	T![,],
	\|\| "expected generic argument".into(),
	GENERIC_ARG_FIRST,
	generic_arg,
	);
	m.complete(p, GENERIC_ARG_LIST);
	}

	pub(crate) const GENERIC_ARG_FIRST: TokenSet = TokenSet::new(&[
	LIFETIME_IDENT,
	IDENT,
	T!['{'],
	T![true],
	T![false],
	T![-],
	INT_NUMBER,
	FLOAT_NUMBER,
	CHAR,
	BYTE,
	STRING,
	BYTE_STRING,
	C_STRING,
	])
	.union(types::TYPE_FIRST);

	// Despite its name, it can also be used for generic param list.
	const GENERIC_ARG_RECOVERY_SET: TokenSet = TokenSet::new(&[T![>], T![,]]);

	// test generic_arg
	// type T = S<i32, dyn T, fn()>;
	pub(crate) fn generic_arg(p: &mut Parser<'_>) -> bool {
	match p.current() {
	LIFETIME_IDENT if !p.nth_at(1, T![+]) => lifetime_arg(p),
	T!['{'] \| T![true] \| T![false] \| T![-] => const_arg(p),
	k if k.is_literal() => const_arg(p),
	// test generic_arg_bounds
	// type Plain = Foo<Item, Item::Item, Item: Bound, Item = Item>;
	// type GenericArgs = Foo<Item<T>, Item::<T>, Item<T>: Bound, Item::<T>: Bound, Item<T> = Item, Item::<T> = Item>;
	// type ParenthesizedArgs = Foo<Item(T), Item::(T), Item(T): Bound, Item::(T): Bound, Item(T) = Item, Item::(T) = Item>;
	// type RTN = Foo<Item(..), Item(..), Item(..): Bound, Item(..): Bound, Item(..) = Item, Item(..) = Item>;

	// test edition_2015_dyn_prefix_inside_generic_arg 2015
	// type A = Foo<dyn T>;
	T![ident] if !p.edition().at_least_2018() && types::is_dyn_weak(p) => type_arg(p),
	// test macro_inside_generic_arg
	// type A = Foo<syn::Token![_]>;
	k if PATH_NAME_REF_KINDS.contains(k) => {
	let m = p.start();
	name_ref_mod_path(p);
	paths::opt_path_type_args(p);
	match p.current() {
	T![=] => {
	p.bump_any();
	if types::TYPE_FIRST.contains(p.current()) {
	// test assoc_type_eq
	// type T = StreamingIterator<Item<'a> = &'a T>;
	types::type_(p);
	} else if p.at_ts(GENERIC_ARG_RECOVERY_SET) {
	// Although `const_arg()` recovers as expected, we want to
	// handle those here to give the following message because
	// we don't know whether this associated item is a type or
	// const at this point.

	// test_err recover_from_missing_assoc_item_binding
	// fn f() -> impl Iterator<Item = , Item = > {}
	p.error("missing associated item binding");
	} else {
	// test assoc_const_eq
	// fn foo<F: Foo<N=3>>() {}
	// const TEST: usize = 3;
	// fn bar<F: Foo<N={TEST}>>() {}
	const_arg(p);
	}
	m.complete(p, ASSOC_TYPE_ARG);
	}
	// test assoc_type_bound
	// type T = StreamingIterator<Item<'a>: Clone>;
	// type T = StreamingIterator<Item(T): Clone>;
	T![:] if !p.at(T![::]) => {
	generic_params::bounds(p);
	m.complete(p, ASSOC_TYPE_ARG);
	}
	// Turned out to be just a normal path type (mirror `path_or_macro_type`)
	_ => {
	let m = m.complete(p, PATH_SEGMENT).precede(p).complete(p, PATH);
	let m = paths::type_path_for_qualifier(p, m);
	let m = if p.at(T![!]) && !p.at(T![!=]) {
	let m = m.precede(p);
	items::macro_call_after_excl(p);
	m.complete(p, MACRO_CALL).precede(p).complete(p, MACRO_TYPE)
	} else {
	m.precede(p).complete(p, PATH_TYPE)
	};
	types::opt_type_bounds_as_dyn_trait_type(p, m).precede(p).complete(p, TYPE_ARG);
	}
	}
	}
	_ if p.at_ts(types::TYPE_FIRST) => type_arg(p),
	_ => return false,
	}
	true
	}

	// test lifetime_arg
	// type T = S<'static>;
	fn lifetime_arg(p: &mut Parser<'_>) {
	let m = p.start();
	lifetime(p);
	m.complete(p, LIFETIME_ARG);
	}

	pub(super) fn const_arg_expr(p: &mut Parser<'_>) {
	// The tests in here are really for `const_arg`, which wraps the content
	// CONST_ARG.
	match p.current() {
	// test const_arg_block
	// type T = S<{90 + 2}>;
	T!['{'] => {
	expressions::block_expr(p);
	}
	// test const_arg_literal
	// type T = S<"hello", 0xdeadbeef>;
	k if k.is_literal() => {
	expressions::literal(p);
	}
	// test const_arg_bool_literal
	// type T = S<true>;
	T![true] \| T![false] => {
	expressions::literal(p);
	}
	// test const_arg_negative_number
	// type T = S<-92>;
	T![-] => {
	let lm = p.start();
	p.bump(T![-]);
	expressions::literal(p);
	lm.complete(p, PREFIX_EXPR);
	}
	_ if paths::is_path_start(p) => {
	// This shouldn't be hit by `const_arg`
	let lm = p.start();
	paths::expr_path(p);
	lm.complete(p, PATH_EXPR);
	}
	_ => {
	// test_err recover_from_missing_const_default
	// struct A<const N: i32 = , const M: i32 =>;
	p.err_recover("expected a generic const argument", GENERIC_ARG_RECOVERY_SET);
	}
	}
	}

	// test const_arg
	// type T = S<92>;
	pub(super) fn const_arg(p: &mut Parser<'_>) {
	let m = p.start();
	const_arg_expr(p);
	m.complete(p, CONST_ARG);
	}

	pub(crate) fn type_arg(p: &mut Parser<'_>) {
	let m = p.start();
	types::type_(p);
	m.complete(p, TYPE_ARG);
	}