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ty.rs
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ty.rs
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use super::{Parser, PathStyle, TokenType};
use crate::errors::{
self, DynAfterMut, ExpectedFnPathFoundFnKeyword, ExpectedMutOrConstInRawPointerType,
FnPointerCannotBeAsync, FnPointerCannotBeConst, FnPtrWithGenerics, FnPtrWithGenericsSugg,
HelpUseLatestEdition, InvalidDynKeyword, LifetimeAfterMut, NeedPlusAfterTraitObjectLifetime,
NestedCVariadicType, ReturnTypesUseThinArrow,
};
use crate::{maybe_recover_from_interpolated_ty_qpath, maybe_whole};
use rustc_ast::ptr::P;
use rustc_ast::token::{self, Delimiter, Token, TokenKind};
use rustc_ast::util::case::Case;
use rustc_ast::{
self as ast, BareFnTy, BoundAsyncness, BoundConstness, BoundPolarity, FnRetTy, GenericBound,
GenericBounds, GenericParam, Generics, Lifetime, MacCall, MutTy, Mutability, PolyTraitRef,
TraitBoundModifiers, TraitObjectSyntax, Ty, TyKind, DUMMY_NODE_ID,
};
use rustc_errors::{Applicability, PResult};
use rustc_span::symbol::{kw, sym, Ident};
use rustc_span::{Span, Symbol};
use thin_vec::{thin_vec, ThinVec};
#[derive(Copy, Clone, PartialEq)]
pub(super) enum AllowPlus {
Yes,
No,
}
#[derive(PartialEq)]
pub(super) enum RecoverQPath {
Yes,
No,
}
pub(super) enum RecoverQuestionMark {
Yes,
No,
}
/// Signals whether parsing a type should recover `->`.
///
/// More specifically, when parsing a function like:
/// ```compile_fail
/// fn foo() => u8 { 0 }
/// fn bar(): u8 { 0 }
/// ```
/// The compiler will try to recover interpreting `foo() => u8` as `foo() -> u8` when calling
/// `parse_ty` with anything except `RecoverReturnSign::No`, and it will try to recover `bar(): u8`
/// as `bar() -> u8` when passing `RecoverReturnSign::Yes` to `parse_ty`
#[derive(Copy, Clone, PartialEq)]
pub(super) enum RecoverReturnSign {
Yes,
OnlyFatArrow,
No,
}
impl RecoverReturnSign {
/// [RecoverReturnSign::Yes] allows for recovering `fn foo() => u8` and `fn foo(): u8`,
/// [RecoverReturnSign::OnlyFatArrow] allows for recovering only `fn foo() => u8` (recovering
/// colons can cause problems when parsing where clauses), and
/// [RecoverReturnSign::No] doesn't allow for any recovery of the return type arrow
fn can_recover(self, token: &TokenKind) -> bool {
match self {
Self::Yes => matches!(token, token::FatArrow | token::Colon),
Self::OnlyFatArrow => matches!(token, token::FatArrow),
Self::No => false,
}
}
}
// Is `...` (`CVarArgs`) legal at this level of type parsing?
#[derive(PartialEq)]
enum AllowCVariadic {
Yes,
No,
}
/// Returns `true` if `IDENT t` can start a type -- `IDENT::a::b`, `IDENT<u8, u8>`,
/// `IDENT<<u8 as Trait>::AssocTy>`.
///
/// Types can also be of the form `IDENT(u8, u8) -> u8`, however this assumes
/// that `IDENT` is not the ident of a fn trait.
fn can_continue_type_after_non_fn_ident(t: &Token) -> bool {
t == &token::ModSep || t == &token::Lt || t == &token::BinOp(token::Shl)
}
fn can_begin_dyn_bound_in_edition_2015(t: &Token) -> bool {
// `Not`, `Tilde` & `Const` are deliberately not part of this list to
// contain the number of potential regressions esp. in MBE code.
// `Const` would regress `rfc-2632-const-trait-impl/mbe-dyn-const-2015.rs`.
// `Not` would regress `dyn!(...)` macro calls in Rust 2015.
t.is_path_start()
|| t.is_lifetime()
|| t == &TokenKind::Question
|| t.is_keyword(kw::For)
|| t == &TokenKind::OpenDelim(Delimiter::Parenthesis)
}
impl<'a> Parser<'a> {
/// Parses a type.
pub fn parse_ty(&mut self) -> PResult<'a, P<Ty>> {
self.parse_ty_common(
AllowPlus::Yes,
AllowCVariadic::No,
RecoverQPath::Yes,
RecoverReturnSign::Yes,
None,
RecoverQuestionMark::Yes,
)
}
pub(super) fn parse_ty_with_generics_recovery(
&mut self,
ty_params: &Generics,
) -> PResult<'a, P<Ty>> {
self.parse_ty_common(
AllowPlus::Yes,
AllowCVariadic::No,
RecoverQPath::Yes,
RecoverReturnSign::Yes,
Some(ty_params),
RecoverQuestionMark::Yes,
)
}
/// Parse a type suitable for a field definition.
/// The difference from `parse_ty` is that this version
/// allows anonymous structs and unions.
pub fn parse_ty_for_field_def(&mut self) -> PResult<'a, P<Ty>> {
if self.can_begin_anon_struct_or_union() {
self.parse_anon_struct_or_union()
} else {
self.parse_ty()
}
}
/// Parse a type suitable for a function or function pointer parameter.
/// The difference from `parse_ty` is that this version allows `...`
/// (`CVarArgs`) at the top level of the type.
pub(super) fn parse_ty_for_param(&mut self) -> PResult<'a, P<Ty>> {
self.parse_ty_common(
AllowPlus::Yes,
AllowCVariadic::Yes,
RecoverQPath::Yes,
RecoverReturnSign::Yes,
None,
RecoverQuestionMark::Yes,
)
}
/// Parses a type in restricted contexts where `+` is not permitted.
///
/// Example 1: `&'a TYPE`
/// `+` is prohibited to maintain operator priority (P(+) < P(&)).
/// Example 2: `value1 as TYPE + value2`
/// `+` is prohibited to avoid interactions with expression grammar.
pub(super) fn parse_ty_no_plus(&mut self) -> PResult<'a, P<Ty>> {
self.parse_ty_common(
AllowPlus::No,
AllowCVariadic::No,
RecoverQPath::Yes,
RecoverReturnSign::Yes,
None,
RecoverQuestionMark::Yes,
)
}
/// Parses a type following an `as` cast. Similar to `parse_ty_no_plus`, but signaling origin
/// for better diagnostics involving `?`.
pub(super) fn parse_as_cast_ty(&mut self) -> PResult<'a, P<Ty>> {
self.parse_ty_common(
AllowPlus::No,
AllowCVariadic::No,
RecoverQPath::Yes,
RecoverReturnSign::Yes,
None,
RecoverQuestionMark::No,
)
}
pub(super) fn parse_ty_no_question_mark_recover(&mut self) -> PResult<'a, P<Ty>> {
self.parse_ty_common(
AllowPlus::Yes,
AllowCVariadic::No,
RecoverQPath::Yes,
RecoverReturnSign::Yes,
None,
RecoverQuestionMark::No,
)
}
/// Parse a type without recovering `:` as `->` to avoid breaking code such as `where fn() : for<'a>`
pub(super) fn parse_ty_for_where_clause(&mut self) -> PResult<'a, P<Ty>> {
self.parse_ty_common(
AllowPlus::Yes,
AllowCVariadic::Yes,
RecoverQPath::Yes,
RecoverReturnSign::OnlyFatArrow,
None,
RecoverQuestionMark::Yes,
)
}
/// Parses an optional return type `[ -> TY ]` in a function declaration.
pub(super) fn parse_ret_ty(
&mut self,
allow_plus: AllowPlus,
recover_qpath: RecoverQPath,
recover_return_sign: RecoverReturnSign,
) -> PResult<'a, FnRetTy> {
Ok(if self.eat(&token::RArrow) {
// FIXME(Centril): Can we unconditionally `allow_plus`?
let ty = self.parse_ty_common(
allow_plus,
AllowCVariadic::No,
recover_qpath,
recover_return_sign,
None,
RecoverQuestionMark::Yes,
)?;
FnRetTy::Ty(ty)
} else if recover_return_sign.can_recover(&self.token.kind) {
// Don't `eat` to prevent `=>` from being added as an expected token which isn't
// actually expected and could only confuse users
self.bump();
self.dcx().emit_err(ReturnTypesUseThinArrow { span: self.prev_token.span });
let ty = self.parse_ty_common(
allow_plus,
AllowCVariadic::No,
recover_qpath,
recover_return_sign,
None,
RecoverQuestionMark::Yes,
)?;
FnRetTy::Ty(ty)
} else {
FnRetTy::Default(self.prev_token.span.shrink_to_hi())
})
}
fn parse_ty_common(
&mut self,
allow_plus: AllowPlus,
allow_c_variadic: AllowCVariadic,
recover_qpath: RecoverQPath,
recover_return_sign: RecoverReturnSign,
ty_generics: Option<&Generics>,
recover_question_mark: RecoverQuestionMark,
) -> PResult<'a, P<Ty>> {
let allow_qpath_recovery = recover_qpath == RecoverQPath::Yes;
maybe_recover_from_interpolated_ty_qpath!(self, allow_qpath_recovery);
maybe_whole!(self, NtTy, |x| x);
let lo = self.token.span;
let mut impl_dyn_multi = false;
let kind = if self.check(&token::OpenDelim(Delimiter::Parenthesis)) {
self.parse_ty_tuple_or_parens(lo, allow_plus)?
} else if self.eat(&token::Not) {
// Never type `!`
TyKind::Never
} else if self.eat(&token::BinOp(token::Star)) {
self.parse_ty_ptr()?
} else if self.eat(&token::OpenDelim(Delimiter::Bracket)) {
self.parse_array_or_slice_ty()?
} else if self.check(&token::BinOp(token::And)) || self.check(&token::AndAnd) {
// Reference
self.expect_and()?;
self.parse_borrowed_pointee()?
} else if self.eat_keyword_noexpect(kw::Typeof) {
self.parse_typeof_ty()?
} else if self.eat_keyword(kw::Underscore) {
// A type to be inferred `_`
TyKind::Infer
} else if self.check_fn_front_matter(false, Case::Sensitive) {
// Function pointer type
self.parse_ty_bare_fn(lo, ThinVec::new(), None, recover_return_sign)?
} else if self.check_keyword(kw::For) {
let for_span = self.token.span;
// Function pointer type or bound list (trait object type) starting with a poly-trait.
// `for<'lt> [unsafe] [extern "ABI"] fn (&'lt S) -> T`
// `for<'lt> Trait1<'lt> + Trait2 + 'a`
let lifetime_defs = self.parse_late_bound_lifetime_defs()?;
if self.check_fn_front_matter(false, Case::Sensitive) {
self.parse_ty_bare_fn(
lo,
lifetime_defs,
Some(self.prev_token.span.shrink_to_lo()),
recover_return_sign,
)?
} else {
// Try to recover `for<'a> dyn Trait` or `for<'a> impl Trait`.
if self.may_recover()
&& (self.eat_keyword_noexpect(kw::Impl) || self.eat_keyword_noexpect(kw::Dyn))
{
let kw = self.prev_token.ident().unwrap().0;
let removal_span = kw.span.with_hi(self.token.span.lo());
let path = self.parse_path(PathStyle::Type)?;
let parse_plus = allow_plus == AllowPlus::Yes && self.check_plus();
let kind =
self.parse_remaining_bounds_path(lifetime_defs, path, lo, parse_plus)?;
let err = self.dcx().create_err(errors::TransposeDynOrImpl {
span: kw.span,
kw: kw.name.as_str(),
sugg: errors::TransposeDynOrImplSugg {
removal_span,
insertion_span: for_span.shrink_to_lo(),
kw: kw.name.as_str(),
},
});
// Take the parsed bare trait object and turn it either
// into a `dyn` object or an `impl Trait`.
let kind = match (kind, kw.name) {
(TyKind::TraitObject(bounds, _), kw::Dyn) => {
TyKind::TraitObject(bounds, TraitObjectSyntax::Dyn)
}
(TyKind::TraitObject(bounds, _), kw::Impl) => {
TyKind::ImplTrait(ast::DUMMY_NODE_ID, bounds)
}
_ => return Err(err),
};
err.emit();
kind
} else {
let path = self.parse_path(PathStyle::Type)?;
let parse_plus = allow_plus == AllowPlus::Yes && self.check_plus();
self.parse_remaining_bounds_path(lifetime_defs, path, lo, parse_plus)?
}
}
} else if self.eat_keyword(kw::Impl) {
self.parse_impl_ty(&mut impl_dyn_multi)?
} else if self.is_explicit_dyn_type() {
self.parse_dyn_ty(&mut impl_dyn_multi)?
} else if self.eat_lt() {
// Qualified path
let (qself, path) = self.parse_qpath(PathStyle::Type)?;
TyKind::Path(Some(qself), path)
} else if self.check_path() {
self.parse_path_start_ty(lo, allow_plus, ty_generics)?
} else if self.can_begin_bound() {
self.parse_bare_trait_object(lo, allow_plus)?
} else if self.eat(&token::DotDotDot) {
match allow_c_variadic {
AllowCVariadic::Yes => TyKind::CVarArgs,
AllowCVariadic::No => {
// FIXME(Centril): Should we just allow `...` syntactically
// anywhere in a type and use semantic restrictions instead?
self.dcx().emit_err(NestedCVariadicType { span: lo.to(self.prev_token.span) });
TyKind::Err
}
}
} else {
let msg = format!("expected type, found {}", super::token_descr(&self.token));
let mut err = self.dcx().struct_span_err(self.token.span, msg);
err.span_label(self.token.span, "expected type");
return Err(err);
};
let span = lo.to(self.prev_token.span);
let mut ty = self.mk_ty(span, kind);
// Try to recover from use of `+` with incorrect priority.
match allow_plus {
AllowPlus::Yes => self.maybe_recover_from_bad_type_plus(&ty)?,
AllowPlus::No => self.maybe_report_ambiguous_plus(impl_dyn_multi, &ty),
}
if let RecoverQuestionMark::Yes = recover_question_mark {
ty = self.maybe_recover_from_question_mark(ty);
}
if allow_qpath_recovery { self.maybe_recover_from_bad_qpath(ty) } else { Ok(ty) }
}
/// Parse an anonymous struct or union (only for field definitions):
/// ```ignore (feature-not-ready)
/// #[repr(C)]
/// struct Foo {
/// _: struct { // anonymous struct
/// x: u32,
/// y: f64,
/// }
/// _: union { // anonymous union
/// z: u32,
/// w: f64,
/// }
/// }
/// ```
fn parse_anon_struct_or_union(&mut self) -> PResult<'a, P<Ty>> {
assert!(self.token.is_keyword(kw::Union) || self.token.is_keyword(kw::Struct));
let is_union = self.token.is_keyword(kw::Union);
let lo = self.token.span;
self.bump();
let (fields, _recovered) =
self.parse_record_struct_body(if is_union { "union" } else { "struct" }, lo, false)?;
let span = lo.to(self.prev_token.span);
self.sess.gated_spans.gate(sym::unnamed_fields, span);
let id = ast::DUMMY_NODE_ID;
let kind =
if is_union { TyKind::AnonUnion(id, fields) } else { TyKind::AnonStruct(id, fields) };
Ok(self.mk_ty(span, kind))
}
/// Parses either:
/// - `(TYPE)`, a parenthesized type.
/// - `(TYPE,)`, a tuple with a single field of type TYPE.
fn parse_ty_tuple_or_parens(&mut self, lo: Span, allow_plus: AllowPlus) -> PResult<'a, TyKind> {
let mut trailing_plus = false;
let (ts, trailing) = self.parse_paren_comma_seq(|p| {
let ty = p.parse_ty()?;
trailing_plus = p.prev_token.kind == TokenKind::BinOp(token::Plus);
Ok(ty)
})?;
if ts.len() == 1 && !trailing {
let ty = ts.into_iter().next().unwrap().into_inner();
let maybe_bounds = allow_plus == AllowPlus::Yes && self.token.is_like_plus();
match ty.kind {
// `(TY_BOUND_NOPAREN) + BOUND + ...`.
TyKind::Path(None, path) if maybe_bounds => {
self.parse_remaining_bounds_path(ThinVec::new(), path, lo, true)
}
TyKind::TraitObject(bounds, TraitObjectSyntax::None)
if maybe_bounds && bounds.len() == 1 && !trailing_plus =>
{
self.parse_remaining_bounds(bounds, true)
}
// `(TYPE)`
_ => Ok(TyKind::Paren(P(ty))),
}
} else {
Ok(TyKind::Tup(ts))
}
}
fn parse_bare_trait_object(&mut self, lo: Span, allow_plus: AllowPlus) -> PResult<'a, TyKind> {
let lt_no_plus = self.check_lifetime() && !self.look_ahead(1, |t| t.is_like_plus());
let bounds = self.parse_generic_bounds_common(allow_plus)?;
if lt_no_plus {
self.dcx().emit_err(NeedPlusAfterTraitObjectLifetime { span: lo });
}
Ok(TyKind::TraitObject(bounds, TraitObjectSyntax::None))
}
fn parse_remaining_bounds_path(
&mut self,
generic_params: ThinVec<GenericParam>,
path: ast::Path,
lo: Span,
parse_plus: bool,
) -> PResult<'a, TyKind> {
let poly_trait_ref = PolyTraitRef::new(generic_params, path, lo.to(self.prev_token.span));
let bounds = vec![GenericBound::Trait(poly_trait_ref, TraitBoundModifiers::NONE)];
self.parse_remaining_bounds(bounds, parse_plus)
}
/// Parse the remainder of a bare trait object type given an already parsed list.
fn parse_remaining_bounds(
&mut self,
mut bounds: GenericBounds,
plus: bool,
) -> PResult<'a, TyKind> {
if plus {
self.eat_plus(); // `+`, or `+=` gets split and `+` is discarded
bounds.append(&mut self.parse_generic_bounds()?);
}
Ok(TyKind::TraitObject(bounds, TraitObjectSyntax::None))
}
/// Parses a raw pointer type: `*[const | mut] $type`.
fn parse_ty_ptr(&mut self) -> PResult<'a, TyKind> {
let mutbl = self.parse_const_or_mut().unwrap_or_else(|| {
let span = self.prev_token.span;
self.dcx().emit_err(ExpectedMutOrConstInRawPointerType {
span,
after_asterisk: span.shrink_to_hi(),
});
Mutability::Not
});
let ty = self.parse_ty_no_plus()?;
Ok(TyKind::Ptr(MutTy { ty, mutbl }))
}
/// Parses an array (`[TYPE; EXPR]`) or slice (`[TYPE]`) type.
/// The opening `[` bracket is already eaten.
fn parse_array_or_slice_ty(&mut self) -> PResult<'a, TyKind> {
let elt_ty = match self.parse_ty() {
Ok(ty) => ty,
Err(err)
if self.look_ahead(1, |t| t.kind == token::CloseDelim(Delimiter::Bracket))
| self.look_ahead(1, |t| t.kind == token::Semi) =>
{
// Recover from `[LIT; EXPR]` and `[LIT]`
self.bump();
err.emit();
self.mk_ty(self.prev_token.span, TyKind::Err)
}
Err(err) => return Err(err),
};
let ty = if self.eat(&token::Semi) {
let mut length = self.parse_expr_anon_const()?;
if let Err(e) = self.expect(&token::CloseDelim(Delimiter::Bracket)) {
// Try to recover from `X<Y, ...>` when `X::<Y, ...>` works
self.check_mistyped_turbofish_with_multiple_type_params(e, &mut length.value)?;
self.expect(&token::CloseDelim(Delimiter::Bracket))?;
}
TyKind::Array(elt_ty, length)
} else {
self.expect(&token::CloseDelim(Delimiter::Bracket))?;
TyKind::Slice(elt_ty)
};
Ok(ty)
}
fn parse_borrowed_pointee(&mut self) -> PResult<'a, TyKind> {
let and_span = self.prev_token.span;
let mut opt_lifetime = self.check_lifetime().then(|| self.expect_lifetime());
let mut mutbl = self.parse_mutability();
if self.token.is_lifetime() && mutbl == Mutability::Mut && opt_lifetime.is_none() {
// A lifetime is invalid here: it would be part of a bare trait bound, which requires
// it to be followed by a plus, but we disallow plus in the pointee type.
// So we can handle this case as an error here, and suggest `'a mut`.
// If there *is* a plus next though, handling the error later provides better suggestions
// (like adding parentheses)
if !self.look_ahead(1, |t| t.is_like_plus()) {
let lifetime_span = self.token.span;
let span = and_span.to(lifetime_span);
let (suggest_lifetime, snippet) =
if let Ok(lifetime_src) = self.span_to_snippet(lifetime_span) {
(Some(span), lifetime_src)
} else {
(None, String::new())
};
self.dcx().emit_err(LifetimeAfterMut { span, suggest_lifetime, snippet });
opt_lifetime = Some(self.expect_lifetime());
}
} else if self.token.is_keyword(kw::Dyn)
&& mutbl == Mutability::Not
&& self.look_ahead(1, |t| t.is_keyword(kw::Mut))
{
// We have `&dyn mut ...`, which is invalid and should be `&mut dyn ...`.
let span = and_span.to(self.look_ahead(1, |t| t.span));
self.dcx().emit_err(DynAfterMut { span });
// Recovery
mutbl = Mutability::Mut;
let (dyn_tok, dyn_tok_sp) = (self.token.clone(), self.token_spacing);
self.bump();
self.bump_with((dyn_tok, dyn_tok_sp));
}
let ty = self.parse_ty_no_plus()?;
Ok(TyKind::Ref(opt_lifetime, MutTy { ty, mutbl }))
}
// Parses the `typeof(EXPR)`.
// To avoid ambiguity, the type is surrounded by parentheses.
fn parse_typeof_ty(&mut self) -> PResult<'a, TyKind> {
self.expect(&token::OpenDelim(Delimiter::Parenthesis))?;
let expr = self.parse_expr_anon_const()?;
self.expect(&token::CloseDelim(Delimiter::Parenthesis))?;
Ok(TyKind::Typeof(expr))
}
/// Parses a function pointer type (`TyKind::BareFn`).
/// ```ignore (illustrative)
/// [unsafe] [extern "ABI"] fn (S) -> T
/// // ^~~~~^ ^~~~^ ^~^ ^
/// // | | | |
/// // | | | Return type
/// // Function Style ABI Parameter types
/// ```
/// We actually parse `FnHeader FnDecl`, but we error on `const` and `async` qualifiers.
fn parse_ty_bare_fn(
&mut self,
lo: Span,
mut params: ThinVec<GenericParam>,
param_insertion_point: Option<Span>,
recover_return_sign: RecoverReturnSign,
) -> PResult<'a, TyKind> {
let inherited_vis = rustc_ast::Visibility {
span: rustc_span::DUMMY_SP,
kind: rustc_ast::VisibilityKind::Inherited,
tokens: None,
};
let span_start = self.token.span;
let ast::FnHeader { ext, unsafety, constness, coroutine_kind } =
self.parse_fn_front_matter(&inherited_vis, Case::Sensitive)?;
if self.may_recover() && self.token.kind == TokenKind::Lt {
self.recover_fn_ptr_with_generics(lo, &mut params, param_insertion_point)?;
}
let decl = self.parse_fn_decl(|_| false, AllowPlus::No, recover_return_sign)?;
let whole_span = lo.to(self.prev_token.span);
if let ast::Const::Yes(span) = constness {
// If we ever start to allow `const fn()`, then update
// feature gating for `#![feature(const_extern_fn)]` to
// cover it.
self.dcx().emit_err(FnPointerCannotBeConst { span: whole_span, qualifier: span });
}
if let Some(ast::CoroutineKind::Async { span, .. }) = coroutine_kind {
self.dcx().emit_err(FnPointerCannotBeAsync { span: whole_span, qualifier: span });
}
// FIXME(gen_blocks): emit a similar error for `gen fn()`
let decl_span = span_start.to(self.token.span);
Ok(TyKind::BareFn(P(BareFnTy { ext, unsafety, generic_params: params, decl, decl_span })))
}
/// Recover from function pointer types with a generic parameter list (e.g. `fn<'a>(&'a str)`).
fn recover_fn_ptr_with_generics(
&mut self,
lo: Span,
params: &mut ThinVec<GenericParam>,
param_insertion_point: Option<Span>,
) -> PResult<'a, ()> {
let generics = self.parse_generics()?;
let arity = generics.params.len();
let mut lifetimes: ThinVec<_> = generics
.params
.into_iter()
.filter(|param| matches!(param.kind, ast::GenericParamKind::Lifetime))
.collect();
let sugg = if !lifetimes.is_empty() {
let snippet =
lifetimes.iter().map(|param| param.ident.as_str()).intersperse(", ").collect();
let (left, snippet) = if let Some(span) = param_insertion_point {
(span, if params.is_empty() { snippet } else { format!(", {snippet}") })
} else {
(lo.shrink_to_lo(), format!("for<{snippet}> "))
};
Some(FnPtrWithGenericsSugg {
left,
snippet,
right: generics.span,
arity,
for_param_list_exists: param_insertion_point.is_some(),
})
} else {
None
};
self.dcx().emit_err(FnPtrWithGenerics { span: generics.span, sugg });
params.append(&mut lifetimes);
Ok(())
}
/// Parses an `impl B0 + ... + Bn` type.
fn parse_impl_ty(&mut self, impl_dyn_multi: &mut bool) -> PResult<'a, TyKind> {
// Always parse bounds greedily for better error recovery.
if self.token.is_lifetime() {
self.look_ahead(1, |t| {
if let token::Ident(sym, _) = t.kind {
// parse pattern with "'a Sized" we're supposed to give suggestion like
// "'a + Sized"
self.dcx().emit_err(errors::MissingPlusBounds {
span: self.token.span,
hi: self.token.span.shrink_to_hi(),
sym,
});
}
})
}
let bounds = self.parse_generic_bounds()?;
*impl_dyn_multi = bounds.len() > 1 || self.prev_token.kind == TokenKind::BinOp(token::Plus);
Ok(TyKind::ImplTrait(ast::DUMMY_NODE_ID, bounds))
}
/// Is a `dyn B0 + ... + Bn` type allowed here?
fn is_explicit_dyn_type(&mut self) -> bool {
self.check_keyword(kw::Dyn)
&& (self.token.uninterpolated_span().at_least_rust_2018()
|| self.look_ahead(1, |t| {
(can_begin_dyn_bound_in_edition_2015(t)
|| t.kind == TokenKind::BinOp(token::Star))
&& !can_continue_type_after_non_fn_ident(t)
}))
}
/// Parses a `dyn B0 + ... + Bn` type.
///
/// Note that this does *not* parse bare trait objects.
fn parse_dyn_ty(&mut self, impl_dyn_multi: &mut bool) -> PResult<'a, TyKind> {
let lo = self.token.span;
self.bump(); // `dyn`
// parse dyn* types
let syntax = if self.eat(&TokenKind::BinOp(token::Star)) {
self.sess.gated_spans.gate(sym::dyn_star, lo.to(self.prev_token.span));
TraitObjectSyntax::DynStar
} else {
TraitObjectSyntax::Dyn
};
// Always parse bounds greedily for better error recovery.
let bounds = self.parse_generic_bounds()?;
*impl_dyn_multi = bounds.len() > 1 || self.prev_token.kind == TokenKind::BinOp(token::Plus);
Ok(TyKind::TraitObject(bounds, syntax))
}
/// Parses a type starting with a path.
///
/// This can be:
/// 1. a type macro, `mac!(...)`,
/// 2. a bare trait object, `B0 + ... + Bn`,
/// 3. or a path, `path::to::MyType`.
fn parse_path_start_ty(
&mut self,
lo: Span,
allow_plus: AllowPlus,
ty_generics: Option<&Generics>,
) -> PResult<'a, TyKind> {
// Simple path
let path = self.parse_path_inner(PathStyle::Type, ty_generics)?;
if self.eat(&token::Not) {
// Macro invocation in type position
Ok(TyKind::MacCall(P(MacCall { path, args: self.parse_delim_args()? })))
} else if allow_plus == AllowPlus::Yes && self.check_plus() {
// `Trait1 + Trait2 + 'a`
self.parse_remaining_bounds_path(ThinVec::new(), path, lo, true)
} else {
// Just a type path.
Ok(TyKind::Path(None, path))
}
}
pub(super) fn parse_generic_bounds(&mut self) -> PResult<'a, GenericBounds> {
self.parse_generic_bounds_common(AllowPlus::Yes)
}
/// Parses bounds of a type parameter `BOUND + BOUND + ...`, possibly with trailing `+`.
///
/// See `parse_generic_bound` for the `BOUND` grammar.
fn parse_generic_bounds_common(&mut self, allow_plus: AllowPlus) -> PResult<'a, GenericBounds> {
let mut bounds = Vec::new();
// In addition to looping while we find generic bounds:
// We continue even if we find a keyword. This is necessary for error recovery on,
// for example, `impl fn()`. The only keyword that can go after generic bounds is
// `where`, so stop if it's it.
// We also continue if we find types (not traits), again for error recovery.
while self.can_begin_bound()
|| (self.may_recover()
&& (self.token.can_begin_type()
|| (self.token.is_reserved_ident() && !self.token.is_keyword(kw::Where))))
{
if self.token.is_keyword(kw::Dyn) {
// Account for `&dyn Trait + dyn Other`.
self.dcx().emit_err(InvalidDynKeyword { span: self.token.span });
self.bump();
}
bounds.push(self.parse_generic_bound()?);
if allow_plus == AllowPlus::No || !self.eat_plus() {
break;
}
}
Ok(bounds)
}
pub(super) fn can_begin_anon_struct_or_union(&mut self) -> bool {
(self.token.is_keyword(kw::Struct) || self.token.is_keyword(kw::Union))
&& self.look_ahead(1, |t| t == &token::OpenDelim(Delimiter::Brace))
}
/// Can the current token begin a bound?
fn can_begin_bound(&mut self) -> bool {
self.check_path()
|| self.check_lifetime()
|| self.check(&token::Not)
|| self.check(&token::Question)
|| self.check(&token::Tilde)
|| self.check_keyword(kw::Const)
|| self.check_keyword(kw::For)
|| self.check(&token::OpenDelim(Delimiter::Parenthesis))
}
/// Parses a bound according to the grammar:
/// ```ebnf
/// BOUND = TY_BOUND | LT_BOUND
/// ```
fn parse_generic_bound(&mut self) -> PResult<'a, GenericBound> {
let lo = self.token.span;
let leading_token = self.prev_token.clone();
let has_parens = self.eat(&token::OpenDelim(Delimiter::Parenthesis));
let inner_lo = self.token.span;
let modifiers = self.parse_trait_bound_modifiers()?;
let bound = if self.token.is_lifetime() {
self.error_lt_bound_with_modifiers(modifiers);
self.parse_generic_lt_bound(lo, inner_lo, has_parens)?
} else {
self.parse_generic_ty_bound(lo, has_parens, modifiers, &leading_token)?
};
Ok(bound)
}
/// Parses a lifetime ("outlives") bound, e.g. `'a`, according to:
/// ```ebnf
/// LT_BOUND = LIFETIME
/// ```
fn parse_generic_lt_bound(
&mut self,
lo: Span,
inner_lo: Span,
has_parens: bool,
) -> PResult<'a, GenericBound> {
let bound = GenericBound::Outlives(self.expect_lifetime());
if has_parens {
// FIXME(Centril): Consider not erroring here and accepting `('lt)` instead,
// possibly introducing `GenericBound::Paren(P<GenericBound>)`?
self.recover_paren_lifetime(lo, inner_lo)?;
}
Ok(bound)
}
/// Emits an error if any trait bound modifiers were present.
fn error_lt_bound_with_modifiers(&self, modifiers: TraitBoundModifiers) {
match modifiers.constness {
BoundConstness::Never => {}
BoundConstness::Always(span) | BoundConstness::Maybe(span) => {
self.dcx().emit_err(errors::ModifierLifetime {
span,
modifier: modifiers.constness.as_str(),
});
}
}
match modifiers.polarity {
BoundPolarity::Positive => {}
BoundPolarity::Negative(span) | BoundPolarity::Maybe(span) => {
self.dcx().emit_err(errors::ModifierLifetime {
span,
modifier: modifiers.polarity.as_str(),
});
}
}
}
/// Recover on `('lifetime)` with `(` already eaten.
fn recover_paren_lifetime(&mut self, lo: Span, inner_lo: Span) -> PResult<'a, ()> {
let inner_span = inner_lo.to(self.prev_token.span);
self.expect(&token::CloseDelim(Delimiter::Parenthesis))?;
let span = lo.to(self.prev_token.span);
let (sugg, snippet) = if let Ok(snippet) = self.span_to_snippet(inner_span) {
(Some(span), snippet)
} else {
(None, String::new())
};
self.dcx().emit_err(errors::ParenthesizedLifetime { span, sugg, snippet });
Ok(())
}
/// Parses the modifiers that may precede a trait in a bound, e.g. `?Trait` or `~const Trait`.
///
/// If no modifiers are present, this does not consume any tokens.
///
/// ```ebnf
/// TRAIT_BOUND_MODIFIERS = [["~"] "const"] ["?" | "!"]
/// ```
fn parse_trait_bound_modifiers(&mut self) -> PResult<'a, TraitBoundModifiers> {
let constness = if self.eat(&token::Tilde) {
let tilde = self.prev_token.span;
self.expect_keyword(kw::Const)?;
let span = tilde.to(self.prev_token.span);
self.sess.gated_spans.gate(sym::const_trait_impl, span);
BoundConstness::Maybe(span)
} else if self.eat_keyword(kw::Const) {
self.sess.gated_spans.gate(sym::const_trait_impl, self.prev_token.span);
BoundConstness::Always(self.prev_token.span)
} else {
BoundConstness::Never
};
let asyncness = if self.token.span.at_least_rust_2018() && self.eat_keyword(kw::Async) {
self.sess.gated_spans.gate(sym::async_closure, self.prev_token.span);
BoundAsyncness::Async(self.prev_token.span)
} else if self.may_recover()
&& self.token.span.is_rust_2015()
&& self.is_kw_followed_by_ident(kw::Async)
{
self.bump(); // eat `async`
self.dcx().emit_err(errors::AsyncBoundModifierIn2015 {
span: self.prev_token.span,
help: HelpUseLatestEdition::new(),
});
self.sess.gated_spans.gate(sym::async_closure, self.prev_token.span);
BoundAsyncness::Async(self.prev_token.span)
} else {
BoundAsyncness::Normal
};
let polarity = if self.eat(&token::Question) {
BoundPolarity::Maybe(self.prev_token.span)
} else if self.eat(&token::Not) {
self.sess.gated_spans.gate(sym::negative_bounds, self.prev_token.span);
BoundPolarity::Negative(self.prev_token.span)
} else {
BoundPolarity::Positive
};
Ok(TraitBoundModifiers { constness, asyncness, polarity })
}
/// Parses a type bound according to:
/// ```ebnf
/// TY_BOUND = TY_BOUND_NOPAREN | (TY_BOUND_NOPAREN)
/// TY_BOUND_NOPAREN = [TRAIT_BOUND_MODIFIERS] [for<LT_PARAM_DEFS>] SIMPLE_PATH
/// ```
///
/// For example, this grammar accepts `~const ?for<'a: 'b> m::Trait<'a>`.
fn parse_generic_ty_bound(
&mut self,
lo: Span,
has_parens: bool,
modifiers: TraitBoundModifiers,
leading_token: &Token,
) -> PResult<'a, GenericBound> {
let mut lifetime_defs = self.parse_late_bound_lifetime_defs()?;
let mut path = if self.token.is_keyword(kw::Fn)
&& self.look_ahead(1, |tok| tok.kind == TokenKind::OpenDelim(Delimiter::Parenthesis))
&& let Some(path) = self.recover_path_from_fn()
{
path
} else if !self.token.is_path_start() && self.token.can_begin_type() {
let ty = self.parse_ty_no_plus()?;
// Instead of finding a path (a trait), we found a type.
let mut err = self.dcx().struct_span_err(ty.span, "expected a trait, found type");
// If we can recover, try to extract a path from the type. Note
// that we do not use the try operator when parsing the type because
// if it fails then we get a parser error which we don't want (we're trying
// to recover from errors, not make more).
let path = if self.may_recover() {
let (span, message, sugg, path, applicability) = match &ty.kind {
TyKind::Ptr(..) | TyKind::Ref(..)
if let TyKind::Path(_, path) = &ty.peel_refs().kind =>
{
(
ty.span.until(path.span),
"consider removing the indirection",
"",
path,
Applicability::MaybeIncorrect,
)
}
TyKind::ImplTrait(_, bounds)
if let [GenericBound::Trait(tr, ..), ..] = bounds.as_slice() =>
{
(
ty.span.until(tr.span),
"use the trait bounds directly",
"",
&tr.trait_ref.path,
Applicability::MachineApplicable,
)
}
_ => return Err(err),
};
err.span_suggestion_verbose(span, message, sugg, applicability);
path.clone()
} else {
return Err(err);
};
err.emit();
path
} else {
self.parse_path(PathStyle::Type)?
};
if self.may_recover() && self.token == TokenKind::OpenDelim(Delimiter::Parenthesis) {
self.recover_fn_trait_with_lifetime_params(&mut path, &mut lifetime_defs)?;
}
if has_parens {
// Someone has written something like `&dyn (Trait + Other)`. The correct code
// would be `&(dyn Trait + Other)`
if self.token.is_like_plus() && leading_token.is_keyword(kw::Dyn) {
let bounds = vec![];
self.parse_remaining_bounds(bounds, true)?;
self.expect(&token::CloseDelim(Delimiter::Parenthesis))?;
self.dcx().emit_err(errors::IncorrectParensTraitBounds {
span: vec![lo, self.prev_token.span],
sugg: errors::IncorrectParensTraitBoundsSugg {
wrong_span: leading_token.span.shrink_to_hi().to(lo),
new_span: leading_token.span.shrink_to_lo(),
},
});