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c63b6a437eb16d13fbc0e72e091813579895bc9f
rust/compiler/rustc_parse/src/parser/path.rs
Nilstrieb c63b6a437e Rip it out 
My type ascription
Oh rip it out
Ah
If you think we live too much then
You can sacrifice diagnostics
Don't mix your garbage
Into my syntax
So many weird hacks keep diagnostics alive
Yet I don't even step outside
So many bad diagnostics keep tyasc alive
Yet tyasc doesn't even bother to survive!
2023-05-01 16:15:13 +08:00

843 lines
36 KiB
Rust
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use super::ty::{AllowPlus, RecoverQPath, RecoverReturnSign};
use super::{Parser, Restrictions, TokenType};
use crate::errors::PathSingleColon;
use crate::{errors, maybe_whole};
use rustc_ast::ptr::P;
use rustc_ast::token::{self, Delimiter, Token, TokenKind};
use rustc_ast::{
self as ast, AngleBracketedArg, AngleBracketedArgs, AnonConst, AssocConstraint,
AssocConstraintKind, BlockCheckMode, GenericArg, GenericArgs, Generics, ParenthesizedArgs,
Path, PathSegment, QSelf,
};
use rustc_errors::{pluralize, Applicability, IntoDiagnostic, PResult};
use rustc_span::source_map::{BytePos, Span};
use rustc_span::symbol::{kw, sym, Ident};
use std::mem;
use thin_vec::ThinVec;
use tracing::debug;
/// Specifies how to parse a path.
#[derive(Copy, Clone, PartialEq, Debug)]
pub enum PathStyle {
/// In some contexts, notably in expressions, paths with generic arguments are ambiguous
/// with something else. For example, in expressions `segment < ....` can be interpreted
/// as a comparison and `segment ( ....` can be interpreted as a function call.
/// In all such contexts the non-path interpretation is preferred by default for practical
/// reasons, but the path interpretation can be forced by the disambiguator `::`, e.g.
/// `x<y>` - comparisons, `x::<y>` - unambiguously a path.
///
/// Also, a path may never be followed by a `:`. This means that we can eagerly recover if
/// we encounter it.
Expr,
/// The same as `Expr`, but may be followed by a `:`.
/// For example, this code:
/// ```rust
/// struct S;
///
/// let S: S;
/// // ^ Followed by a `:`
/// ```
Pat,
/// In other contexts, notably in types, no ambiguity exists and paths can be written
/// without the disambiguator, e.g., `x<y>` - unambiguously a path.
/// Paths with disambiguators are still accepted, `x::<Y>` - unambiguously a path too.
Type,
/// A path with generic arguments disallowed, e.g., `foo::bar::Baz`, used in imports,
/// visibilities or attributes.
/// Technically, this variant is unnecessary and e.g., `Expr` can be used instead
/// (paths in "mod" contexts have to be checked later for absence of generic arguments
/// anyway, due to macros), but it is used to avoid weird suggestions about expected
/// tokens when something goes wrong.
Mod,
}
impl PathStyle {
fn has_generic_ambiguity(&self) -> bool {
matches!(self, Self::Expr | Self::Pat)
}
}
impl<'a> Parser<'a> {
/// Parses a qualified path.
/// Assumes that the leading `<` has been parsed already.
///
/// `qualified_path = <type [as trait_ref]>::path`
///
/// # Examples
/// `<T>::default`
/// `<T as U>::a`
/// `<T as U>::F::a<S>` (without disambiguator)
/// `<T as U>::F::a::<S>` (with disambiguator)
pub(super) fn parse_qpath(&mut self, style: PathStyle) -> PResult<'a, (P<QSelf>, Path)> {
let lo = self.prev_token.span;
let ty = self.parse_ty()?;
// `path` will contain the prefix of the path up to the `>`,
// if any (e.g., `U` in the `<T as U>::*` examples
// above). `path_span` has the span of that path, or an empty
// span in the case of something like `<T>::Bar`.
let (mut path, path_span);
if self.eat_keyword(kw::As) {
let path_lo = self.token.span;
path = self.parse_path(PathStyle::Type)?;
path_span = path_lo.to(self.prev_token.span);
} else {
path_span = self.token.span.to(self.token.span);
path = ast::Path { segments: ThinVec::new(), span: path_span, tokens: None };
}
// See doc comment for `unmatched_angle_bracket_count`.
self.expect(&token::Gt)?;
if self.unmatched_angle_bracket_count > 0 {
self.unmatched_angle_bracket_count -= 1;
debug!("parse_qpath: (decrement) count={:?}", self.unmatched_angle_bracket_count);
}
if !self.recover_colon_before_qpath_proj() {
self.expect(&token::ModSep)?;
}
let qself = P(QSelf { ty, path_span, position: path.segments.len() });
self.parse_path_segments(&mut path.segments, style, None)?;
Ok((
qself,
Path { segments: path.segments, span: lo.to(self.prev_token.span), tokens: None },
))
}
/// Recover from an invalid single colon, when the user likely meant a qualified path.
/// We avoid emitting this if not followed by an identifier, as our assumption that the user
/// intended this to be a qualified path may not be correct.
///
/// ```ignore (diagnostics)
/// <Bar as Baz<T>>:Qux
/// ^ help: use double colon
/// ```
fn recover_colon_before_qpath_proj(&mut self) -> bool {
if !self.check_noexpect(&TokenKind::Colon)
|| self.look_ahead(1, |t| !t.is_ident() || t.is_reserved_ident())
{
return false;
}
self.bump(); // colon
self.diagnostic()
.struct_span_err(
self.prev_token.span,
"found single colon before projection in qualified path",
)
.span_suggestion(
self.prev_token.span,
"use double colon",
"::",
Applicability::MachineApplicable,
)
.emit();
true
}
pub(super) fn parse_path(&mut self, style: PathStyle) -> PResult<'a, Path> {
self.parse_path_inner(style, None)
}
/// Parses simple paths.
///
/// `path = [::] segment+`
/// `segment = ident | ident[::]<args> | ident[::](args) [-> type]`
///
/// # Examples
/// `a::b::C<D>` (without disambiguator)
/// `a::b::C::<D>` (with disambiguator)
/// `Fn(Args)` (without disambiguator)
/// `Fn::(Args)` (with disambiguator)
pub(super) fn parse_path_inner(
&mut self,
style: PathStyle,
ty_generics: Option<&Generics>,
) -> PResult<'a, Path> {
let reject_generics_if_mod_style = |parser: &Parser<'_>, path: &Path| {
// Ensure generic arguments don't end up in attribute paths, such as:
//
// macro_rules! m {
// ($p:path) => { #[$p] struct S; }
// }
//
// m!(inline<u8>); //~ ERROR: unexpected generic arguments in path
//
if style == PathStyle::Mod && path.segments.iter().any(|segment| segment.args.is_some())
{
let span = path
.segments
.iter()
.filter_map(|segment| segment.args.as_ref())
.map(|arg| arg.span())
.collect::<Vec<_>>();
parser.sess.emit_err(errors::GenericsInPath { span });
}
};
maybe_whole!(self, NtPath, |path| {
reject_generics_if_mod_style(self, &path);
path.into_inner()
});
if let token::Interpolated(nt) = &self.token.kind {
if let token::NtTy(ty) = &**nt {
if let ast::TyKind::Path(None, path) = &ty.kind {
let path = path.clone();
self.bump();
reject_generics_if_mod_style(self, &path);
return Ok(path);
}
}
}
let lo = self.token.span;
let mut segments = ThinVec::new();
let mod_sep_ctxt = self.token.span.ctxt();
if self.eat(&token::ModSep) {
segments.push(PathSegment::path_root(lo.shrink_to_lo().with_ctxt(mod_sep_ctxt)));
}
self.parse_path_segments(&mut segments, style, ty_generics)?;
if segments.len() > 1 {
//panic!("debug now ...");
}
Ok(Path { segments, span: lo.to(self.prev_token.span), tokens: None })
}
pub(super) fn parse_path_segments(
&mut self,
segments: &mut ThinVec<PathSegment>,
style: PathStyle,
ty_generics: Option<&Generics>,
) -> PResult<'a, ()> {
loop {
let segment = self.parse_path_segment(style, ty_generics)?;
if style.has_generic_ambiguity() {
// In order to check for trailing angle brackets, we must have finished
// recursing (`parse_path_segment` can indirectly call this function),
// that is, the next token must be the highlighted part of the below example:
//
// `Foo::<Bar as Baz<T>>::Qux`
// ^ here
//
// As opposed to the below highlight (if we had only finished the first
// recursion):
//
// `Foo::<Bar as Baz<T>>::Qux`
// ^ here
//
// `PathStyle::Expr` is only provided at the root invocation and never in
// `parse_path_segment` to recurse and therefore can be checked to maintain
// this invariant.
self.check_trailing_angle_brackets(&segment, &[&token::ModSep]);
}
segments.push(segment);
if self.is_import_coupler() || !self.eat(&token::ModSep) {
if style == PathStyle::Expr
&& self.may_recover()
&& self.token == token::Colon
&& self.look_ahead(1, |token| token.is_ident() && !token.is_reserved_ident())
{
// Emit a special error message for `a::b:c` to help users
// otherwise, `a: c` might have meant to introduce a new binding
if self.token.span.lo() == self.prev_token.span.hi()
&& self.look_ahead(1, |token| self.token.span.hi() == token.span.lo())
{
self.bump(); // bump past the colon
self.sess.emit_err(PathSingleColon {
span: self.prev_token.span,
type_ascription: self
.sess
.unstable_features
.is_nightly_build()
.then_some(()),
});
}
continue;
}
return Ok(());
}
}
}
pub(super) fn parse_path_segment(
&mut self,
style: PathStyle,
ty_generics: Option<&Generics>,
) -> PResult<'a, PathSegment> {
let ident = self.parse_path_segment_ident()?;
let is_args_start = |token: &Token| {
matches!(
token.kind,
token::Lt
| token::BinOp(token::Shl)
| token::OpenDelim(Delimiter::Parenthesis)
| token::LArrow
)
};
let check_args_start = |this: &mut Self| {
this.expected_tokens.extend_from_slice(&[
TokenType::Token(token::Lt),
TokenType::Token(token::OpenDelim(Delimiter::Parenthesis)),
]);
is_args_start(&this.token)
};
Ok(
if style == PathStyle::Type && check_args_start(self)
|| style != PathStyle::Mod
&& self.check(&token::ModSep)
&& self.look_ahead(1, |t| is_args_start(t))
{
// We use `style == PathStyle::Expr` to check if this is in a recursion or not. If
// it isn't, then we reset the unmatched angle bracket count as we're about to start
// parsing a new path.
if style == PathStyle::Expr {
self.unmatched_angle_bracket_count = 0;
self.max_angle_bracket_count = 0;
}
// Generic arguments are found - `<`, `(`, `::<` or `::(`.
self.eat(&token::ModSep);
let lo = self.token.span;
let args = if self.eat_lt() {
// `<'a, T, A = U>`
let args = self.parse_angle_args_with_leading_angle_bracket_recovery(
style,
lo,
ty_generics,
)?;
self.expect_gt().map_err(|mut err| {
// Try to recover a `:` into a `::`
if self.token == token::Colon
&& self.look_ahead(1, |token| {
token.is_ident() && !token.is_reserved_ident()
})
{
err.cancel();
err = PathSingleColon {
span: self.token.span,
type_ascription: self
.sess
.unstable_features
.is_nightly_build()
.then_some(()),
}
.into_diagnostic(self.diagnostic());
}
// Attempt to find places where a missing `>` might belong.
else if let Some(arg) = args
.iter()
.rev()
.find(|arg| !matches!(arg, AngleBracketedArg::Constraint(_)))
{
err.span_suggestion_verbose(
arg.span().shrink_to_hi(),
"you might have meant to end the type parameters here",
">",
Applicability::MaybeIncorrect,
);
}
err
})?;
let span = lo.to(self.prev_token.span);
AngleBracketedArgs { args, span }.into()
} else if self.may_recover()
&& self.token.kind == token::OpenDelim(Delimiter::Parenthesis)
// FIXME(return_type_notation): Could also recover `...` here.
&& self.look_ahead(1, |tok| tok.kind == token::DotDot)
{
self.bump();
self.sess
.emit_err(errors::BadReturnTypeNotationDotDot { span: self.token.span });
self.bump();
self.expect(&token::CloseDelim(Delimiter::Parenthesis))?;
let span = lo.to(self.prev_token.span);
if self.eat_noexpect(&token::RArrow) {
let lo = self.prev_token.span;
let ty = self.parse_ty()?;
self.sess
.emit_err(errors::BadReturnTypeNotationOutput { span: lo.to(ty.span) });
}
ParenthesizedArgs {
span,
inputs: ThinVec::new(),
inputs_span: span,
output: ast::FnRetTy::Default(self.prev_token.span.shrink_to_hi()),
}
.into()
} else {
// `(T, U) -> R`
let (inputs, _) = self.parse_paren_comma_seq(|p| p.parse_ty())?;
let inputs_span = lo.to(self.prev_token.span);
let output =
self.parse_ret_ty(AllowPlus::No, RecoverQPath::No, RecoverReturnSign::No)?;
let span = ident.span.to(self.prev_token.span);
ParenthesizedArgs { span, inputs, inputs_span, output }.into()
};
PathSegment { ident, args: Some(args), id: ast::DUMMY_NODE_ID }
} else {
// Generic arguments are not found.
PathSegment::from_ident(ident)
},
)
}
pub(super) fn parse_path_segment_ident(&mut self) -> PResult<'a, Ident> {
match self.token.ident() {
Some((ident, false)) if ident.is_path_segment_keyword() => {
self.bump();
Ok(ident)
}
_ => self.parse_ident(),
}
}
/// Parses generic args (within a path segment) with recovery for extra leading angle brackets.
/// For the purposes of understanding the parsing logic of generic arguments, this function
/// can be thought of being the same as just calling `self.parse_angle_args()` if the source
/// had the correct amount of leading angle brackets.
///
/// ```ignore (diagnostics)
/// bar::<<<<T as Foo>::Output>();
/// ^^ help: remove extra angle brackets
/// ```
fn parse_angle_args_with_leading_angle_bracket_recovery(
&mut self,
style: PathStyle,
lo: Span,
ty_generics: Option<&Generics>,
) -> PResult<'a, ThinVec<AngleBracketedArg>> {
// We need to detect whether there are extra leading left angle brackets and produce an
// appropriate error and suggestion. This cannot be implemented by looking ahead at
// upcoming tokens for a matching `>` character - if there are unmatched `<` tokens
// then there won't be matching `>` tokens to find.
//
// To explain how this detection works, consider the following example:
//
// ```ignore (diagnostics)
// bar::<<<<T as Foo>::Output>();
// ^^ help: remove extra angle brackets
// ```
//
// Parsing of the left angle brackets starts in this function. We start by parsing the
// `<` token (incrementing the counter of unmatched angle brackets on `Parser` via
// `eat_lt`):
//
// *Upcoming tokens:* `<<<<T as Foo>::Output>;`
// *Unmatched count:* 1
// *`parse_path_segment` calls deep:* 0
//
// This has the effect of recursing as this function is called if a `<` character
// is found within the expected generic arguments:
//
// *Upcoming tokens:* `<<<T as Foo>::Output>;`
// *Unmatched count:* 2
// *`parse_path_segment` calls deep:* 1
//
// Eventually we will have recursed until having consumed all of the `<` tokens and
// this will be reflected in the count:
//
// *Upcoming tokens:* `T as Foo>::Output>;`
// *Unmatched count:* 4
// `parse_path_segment` calls deep:* 3
//
// The parser will continue until reaching the first `>` - this will decrement the
// unmatched angle bracket count and return to the parent invocation of this function
// having succeeded in parsing:
//
// *Upcoming tokens:* `::Output>;`
// *Unmatched count:* 3
// *`parse_path_segment` calls deep:* 2
//
// This will continue until the next `>` character which will also return successfully
// to the parent invocation of this function and decrement the count:
//
// *Upcoming tokens:* `;`
// *Unmatched count:* 2
// *`parse_path_segment` calls deep:* 1
//
// At this point, this function will expect to find another matching `>` character but
// won't be able to and will return an error. This will continue all the way up the
// call stack until the first invocation:
//
// *Upcoming tokens:* `;`
// *Unmatched count:* 2
// *`parse_path_segment` calls deep:* 0
//
// In doing this, we have managed to work out how many unmatched leading left angle
// brackets there are, but we cannot recover as the unmatched angle brackets have
// already been consumed. To remedy this, we keep a snapshot of the parser state
// before we do the above. We can then inspect whether we ended up with a parsing error
// and unmatched left angle brackets and if so, restore the parser state before we
// consumed any `<` characters to emit an error and consume the erroneous tokens to
// recover by attempting to parse again.
//
// In practice, the recursion of this function is indirect and there will be other
// locations that consume some `<` characters - as long as we update the count when
// this happens, it isn't an issue.
let is_first_invocation = style == PathStyle::Expr;
// Take a snapshot before attempting to parse - we can restore this later.
let snapshot = is_first_invocation.then(|| self.clone());
debug!("parse_generic_args_with_leading_angle_bracket_recovery: (snapshotting)");
match self.parse_angle_args(ty_generics) {
Ok(args) => Ok(args),
Err(e) if is_first_invocation && self.unmatched_angle_bracket_count > 0 => {
// Swap `self` with our backup of the parser state before attempting to parse
// generic arguments.
let snapshot = mem::replace(self, snapshot.unwrap());
// Eat the unmatched angle brackets.
let all_angle_brackets = (0..snapshot.unmatched_angle_bracket_count)
.fold(true, |a, _| a && self.eat_lt());
if !all_angle_brackets {
// If there are other tokens in between the extraneous `<`s, we cannot simply
// suggest to remove them. This check also prevents us from accidentally ending
// up in the middle of a multibyte character (issue #84104).
let _ = mem::replace(self, snapshot);
Err(e)
} else {
// Cancel error from being unable to find `>`. We know the error
// must have been this due to a non-zero unmatched angle bracket
// count.
e.cancel();
debug!(
"parse_generic_args_with_leading_angle_bracket_recovery: (snapshot failure) \
snapshot.count={:?}",
snapshot.unmatched_angle_bracket_count,
);
// Make a span over ${unmatched angle bracket count} characters.
// This is safe because `all_angle_brackets` ensures that there are only `<`s,
// i.e. no multibyte characters, in this range.
let span =
lo.with_hi(lo.lo() + BytePos(snapshot.unmatched_angle_bracket_count));
self.sess.emit_err(errors::UnmatchedAngle {
span,
plural: snapshot.unmatched_angle_bracket_count > 1,
});
// Try again without unmatched angle bracket characters.
self.parse_angle_args(ty_generics)
}
}
Err(e) => Err(e),
}
}
/// Parses (possibly empty) list of generic arguments / associated item constraints,
/// possibly including trailing comma.
pub(super) fn parse_angle_args(
&mut self,
ty_generics: Option<&Generics>,
) -> PResult<'a, ThinVec<AngleBracketedArg>> {
let mut args = ThinVec::new();
while let Some(arg) = self.parse_angle_arg(ty_generics)? {
args.push(arg);
if !self.eat(&token::Comma) {
if self.check_noexpect(&TokenKind::Semi)
&& self.look_ahead(1, |t| t.is_ident() || t.is_lifetime())
{
// Add `>` to the list of expected tokens.
self.check(&token::Gt);
// Handle `,` to `;` substitution
let mut err = self.unexpected::<()>().unwrap_err();
self.bump();
err.span_suggestion_verbose(
self.prev_token.span.until(self.token.span),
"use a comma to separate type parameters",
", ",
Applicability::MachineApplicable,
);
err.emit();
continue;
}
if !self.token.kind.should_end_const_arg() {
if self.handle_ambiguous_unbraced_const_arg(&mut args)? {
// We've managed to (partially) recover, so continue trying to parse
// arguments.
continue;
}
}
break;
}
}
Ok(args)
}
/// Parses a single argument in the angle arguments `<...>` of a path segment.
fn parse_angle_arg(
&mut self,
ty_generics: Option<&Generics>,
) -> PResult<'a, Option<AngleBracketedArg>> {
let lo = self.token.span;
let arg = self.parse_generic_arg(ty_generics)?;
match arg {
Some(arg) => {
// we are using noexpect here because we first want to find out if either `=` or `:`
// is present and then use that info to push the other token onto the tokens list
let separated =
self.check_noexpect(&token::Colon) || self.check_noexpect(&token::Eq);
if separated && (self.check(&token::Colon) | self.check(&token::Eq)) {
let arg_span = arg.span();
let (binder, ident, gen_args) = match self.get_ident_from_generic_arg(&arg) {
Ok(ident_gen_args) => ident_gen_args,
Err(()) => return Ok(Some(AngleBracketedArg::Arg(arg))),
};
if binder {
// FIXME(compiler-errors): this could be improved by suggesting lifting
// this up to the trait, at least before this becomes real syntax.
// e.g. `Trait<for<'a> Assoc = Ty>` -> `for<'a> Trait<Assoc = Ty>`
return Err(self.struct_span_err(
arg_span,
"`for<...>` is not allowed on associated type bounds",
));
}
let kind = if self.eat(&token::Colon) {
// Parse associated type constraint bound.
let bounds = self.parse_generic_bounds(Some(self.prev_token.span))?;
AssocConstraintKind::Bound { bounds }
} else if self.eat(&token::Eq) {
self.parse_assoc_equality_term(ident, self.prev_token.span)?
} else {
unreachable!();
};
let span = lo.to(self.prev_token.span);
// Gate associated type bounds, e.g., `Iterator<Item: Ord>`.
if let AssocConstraintKind::Bound { .. } = kind {
if let Some(ast::GenericArgs::Parenthesized(args)) = &gen_args
&& args.inputs.is_empty()
&& matches!(args.output, ast::FnRetTy::Default(..))
{
self.sess.gated_spans.gate(sym::return_type_notation, span);
} else {
self.sess.gated_spans.gate(sym::associated_type_bounds, span);
}
}
let constraint =
AssocConstraint { id: ast::DUMMY_NODE_ID, ident, gen_args, kind, span };
Ok(Some(AngleBracketedArg::Constraint(constraint)))
} else {
// we only want to suggest `:` and `=` in contexts where the previous token
// is an ident and the current token or the next token is an ident
if self.prev_token.is_ident()
&& (self.token.is_ident() || self.look_ahead(1, |token| token.is_ident()))
{
self.check(&token::Colon);
self.check(&token::Eq);
}
Ok(Some(AngleBracketedArg::Arg(arg)))
}
}
_ => Ok(None),
}
}
/// Parse the term to the right of an associated item equality constraint.
/// That is, parse `<term>` in `Item = <term>`.
/// Right now, this only admits types in `<term>`.
fn parse_assoc_equality_term(
&mut self,
ident: Ident,
eq: Span,
) -> PResult<'a, AssocConstraintKind> {
let arg = self.parse_generic_arg(None)?;
let span = ident.span.to(self.prev_token.span);
let term = match arg {
Some(GenericArg::Type(ty)) => ty.into(),
Some(GenericArg::Const(c)) => {
self.sess.gated_spans.gate(sym::associated_const_equality, span);
c.into()
}
Some(GenericArg::Lifetime(lt)) => {
self.sess.emit_err(errors::AssocLifetime { span, lifetime: lt.ident.span });
self.mk_ty(span, ast::TyKind::Err).into()
}
None => {
let after_eq = eq.shrink_to_hi();
let before_next = self.token.span.shrink_to_lo();
let mut err = self
.struct_span_err(after_eq.to(before_next), "missing type to the right of `=`");
if matches!(self.token.kind, token::Comma | token::Gt) {
err.span_suggestion(
self.sess.source_map().next_point(eq).to(before_next),
"to constrain the associated type, add a type after `=`",
" TheType",
Applicability::HasPlaceholders,
);
err.span_suggestion(
eq.to(before_next),
&format!("remove the `=` if `{}` is a type", ident),
"",
Applicability::MaybeIncorrect,
)
} else {
err.span_label(
self.token.span,
&format!("expected type, found {}", super::token_descr(&self.token)),
)
};
return Err(err);
}
};
Ok(AssocConstraintKind::Equality { term })
}
/// We do not permit arbitrary expressions as const arguments. They must be one of:
/// - An expression surrounded in `{}`.
/// - A literal.
/// - A numeric literal prefixed by `-`.
/// - A single-segment path.
pub(super) fn expr_is_valid_const_arg(&self, expr: &P<rustc_ast::Expr>) -> bool {
match &expr.kind {
ast::ExprKind::Block(_, _)
| ast::ExprKind::Lit(_)
| ast::ExprKind::IncludedBytes(..) => true,
ast::ExprKind::Unary(ast::UnOp::Neg, expr) => {
matches!(expr.kind, ast::ExprKind::Lit(_))
}
// We can only resolve single-segment paths at the moment, because multi-segment paths
// require type-checking: see `visit_generic_arg` in `src/librustc_resolve/late.rs`.
ast::ExprKind::Path(None, path)
if path.segments.len() == 1 && path.segments[0].args.is_none() =>
{
true
}
_ => false,
}
}
/// Parse a const argument, e.g. `<3>`. It is assumed the angle brackets will be parsed by
/// the caller.
pub(super) fn parse_const_arg(&mut self) -> PResult<'a, AnonConst> {
// Parse const argument.
let value = if let token::OpenDelim(Delimiter::Brace) = self.token.kind {
self.parse_expr_block(None, self.token.span, BlockCheckMode::Default)?
} else {
self.handle_unambiguous_unbraced_const_arg()?
};
Ok(AnonConst { id: ast::DUMMY_NODE_ID, value })
}
/// Parse a generic argument in a path segment.
/// This does not include constraints, e.g., `Item = u8`, which is handled in `parse_angle_arg`.
pub(super) fn parse_generic_arg(
&mut self,
ty_generics: Option<&Generics>,
) -> PResult<'a, Option<GenericArg>> {
debug!("pain");
let start = self.token.span;
let arg = if self.check_lifetime() && self.look_ahead(1, |t| !t.is_like_plus()) {
// Parse lifetime argument.
GenericArg::Lifetime(self.expect_lifetime())
} else if self.check_const_arg() {
// Parse const argument.
GenericArg::Const(self.parse_const_arg()?)
} else if self.check_type() {
debug!("type");
// Parse type argument.
// Proactively create a parser snapshot enabling us to rewind and try to reparse the
// input as a const expression in case we fail to parse a type. If we successfully
// do so, we will report an error that it needs to be wrapped in braces.
let mut snapshot = None;
if self.may_recover() && self.token.can_begin_expr() {
snapshot = Some(self.create_snapshot_for_diagnostic());
}
match self.parse_ty() {
Ok(ty) => {
// Since the type parser recovers from some malformed slice and array types and
// successfully returns a type, we need to look for `TyKind::Err`s in the
// type to determine if error recovery has occurred and if the input is not a
// syntactically valid type after all.
if let ast::TyKind::Slice(inner_ty) | ast::TyKind::Array(inner_ty, _) = &ty.kind
&& let ast::TyKind::Err = inner_ty.kind
&& let Some(snapshot) = snapshot
&& let Some(expr) = self.recover_unbraced_const_arg_that_can_begin_ty(snapshot)
{
return Ok(Some(self.dummy_const_arg_needs_braces(
self.struct_span_err(expr.span, "invalid const generic expression"),
expr.span,
)));
}
GenericArg::Type(ty)
}
Err(err) => {
if let Some(snapshot) = snapshot
&& let Some(expr) = self.recover_unbraced_const_arg_that_can_begin_ty(snapshot)
{
return Ok(Some(self.dummy_const_arg_needs_braces(
err,
expr.span,
)));
}
// Try to recover from possible `const` arg without braces.
return self.recover_const_arg(start, err).map(Some);
}
}
} else if self.token.is_keyword(kw::Const) {
return self.recover_const_param_declaration(ty_generics);
} else {
// Fall back by trying to parse a const-expr expression. If we successfully do so,
// then we should report an error that it needs to be wrapped in braces.
let snapshot = self.create_snapshot_for_diagnostic();
match self.parse_expr_res(Restrictions::CONST_EXPR, None) {
Ok(expr) => {
return Ok(Some(self.dummy_const_arg_needs_braces(
self.struct_span_err(expr.span, "invalid const generic expression"),
expr.span,
)));
}
Err(err) => {
self.restore_snapshot(snapshot);
err.cancel();
return Ok(None);
}
}
};
Ok(Some(arg))
}
/// Given a arg inside of generics, we try to destructure it as if it were the LHS in
/// `LHS = ...`, i.e. an associated type binding.
/// This returns a bool indicating if there are any `for<'a, 'b>` binder args, the
/// identifier, and any GAT arguments.
fn get_ident_from_generic_arg(
&self,
gen_arg: &GenericArg,
) -> Result<(bool, Ident, Option<GenericArgs>), ()> {
if let GenericArg::Type(ty) = gen_arg {
if let ast::TyKind::Path(qself, path) = &ty.kind
&& qself.is_none()
&& let [seg] = path.segments.as_slice()
{
return Ok((false, seg.ident, seg.args.as_deref().cloned()));
} else if let ast::TyKind::TraitObject(bounds, ast::TraitObjectSyntax::None) = &ty.kind
&& let [ast::GenericBound::Trait(trait_ref, ast::TraitBoundModifier::None)] =
bounds.as_slice()
&& let [seg] = trait_ref.trait_ref.path.segments.as_slice()
{
return Ok((true, seg.ident, seg.args.as_deref().cloned()));
}
}
Err(())
}
}
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