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use crate::ImplTraitPosition;
use super::errors::{
AsyncBoundNotOnTrait, AsyncBoundOnlyForFnTraits, GenericTypeWithParentheses, UseAngleBrackets,
};
use super::ResolverAstLoweringExt;
use super::{GenericArgsCtor, LifetimeRes, ParenthesizedGenericArgs};
use super::{ImplTraitContext, LoweringContext, ParamMode};
use rustc_ast::{self as ast, *};
use rustc_data_structures::sync::Lrc;
use rustc_hir as hir;
use rustc_hir::def::{DefKind, PartialRes, Res};
use rustc_hir::def_id::DefId;
use rustc_hir::GenericArg;
use rustc_middle::span_bug;
use rustc_span::symbol::{kw, sym, Ident};
use rustc_span::{BytePos, DesugaringKind, Span, Symbol, DUMMY_SP};
use smallvec::{smallvec, SmallVec};
impl<'a, 'hir> LoweringContext<'a, 'hir> {
#[instrument(level = "trace", skip(self))]
pub(crate) fn lower_qpath(
&mut self,
id: NodeId,
qself: &Option<ptr::P<QSelf>>,
p: &Path,
param_mode: ParamMode,
itctx: ImplTraitContext,
// modifiers of the impl/bound if this is a trait path
modifiers: Option<ast::TraitBoundModifiers>,
) -> hir::QPath<'hir> {
let qself_position = qself.as_ref().map(|q| q.position);
let qself = qself.as_ref().map(|q| self.lower_ty(&q.ty, itctx));
let partial_res =
self.resolver.get_partial_res(id).unwrap_or_else(|| PartialRes::new(Res::Err));
let base_res = partial_res.base_res();
let unresolved_segments = partial_res.unresolved_segments();
let mut res = self.lower_res(base_res);
// When we have an `async` kw on a bound, map the trait it resolves to.
let mut bound_modifier_allowed_features = None;
if let Some(TraitBoundModifiers { asyncness: BoundAsyncness::Async(_), .. }) = modifiers {
match res {
Res::Def(DefKind::Trait, def_id) => {
if let Some((async_def_id, features)) = self.map_trait_to_async_trait(def_id) {
res = Res::Def(DefKind::Trait, async_def_id);
bound_modifier_allowed_features = Some(features);
} else {
self.dcx().emit_err(AsyncBoundOnlyForFnTraits { span: p.span });
}
}
Res::Err => {
// No additional error.
}
_ => {
// This error isn't actually emitted AFAICT, but it's best to keep
// it around in case the resolver doesn't always check the defkind
// of an item or something.
self.dcx().emit_err(AsyncBoundNotOnTrait { span: p.span, descr: res.descr() });
}
}
}
let path_span_lo = p.span.shrink_to_lo();
let proj_start = p.segments.len() - unresolved_segments;
let path = self.arena.alloc(hir::Path {
res,
segments: self.arena.alloc_from_iter(p.segments[..proj_start].iter().enumerate().map(
|(i, segment)| {
let param_mode = match (qself_position, param_mode) {
(Some(j), ParamMode::Optional) if i < j => {
// This segment is part of the trait path in a
// qualified path - one of `a`, `b` or `Trait`
// in `<X as a::b::Trait>::T::U::method`.
ParamMode::Explicit
}
_ => param_mode,
};
let parenthesized_generic_args = match base_res {
// `a::b::Trait(Args)`
Res::Def(DefKind::Trait, _) if i + 1 == proj_start => {
ParenthesizedGenericArgs::ParenSugar
}
// `a::b::Trait(Args)::TraitItem`
Res::Def(DefKind::AssocFn, _)
| Res::Def(DefKind::AssocConst, _)
| Res::Def(DefKind::AssocTy, _)
if i + 2 == proj_start =>
{
ParenthesizedGenericArgs::ParenSugar
}
// Avoid duplicated errors.
Res::Err => ParenthesizedGenericArgs::ParenSugar,
// An error
_ => ParenthesizedGenericArgs::Err,
};
self.lower_path_segment(
p.span,
segment,
param_mode,
parenthesized_generic_args,
itctx,
// if this is the last segment, add constness to the trait path
if i == proj_start - 1 { modifiers.map(|m| m.constness) } else { None },
bound_modifier_allowed_features.clone(),
)
},
)),
span: self.lower_span(
p.segments[..proj_start]
.last()
.map_or(path_span_lo, |segment| path_span_lo.to(segment.span())),
),
});
if let Some(bound_modifier_allowed_features) = bound_modifier_allowed_features {
path.span = self.mark_span_with_reason(
DesugaringKind::BoundModifier,
path.span,
Some(bound_modifier_allowed_features),
);
}
// Simple case, either no projections, or only fully-qualified.
// E.g., `std::mem::size_of` or `<I as Iterator>::Item`.
if unresolved_segments == 0 {
return hir::QPath::Resolved(qself, path);
}
// Create the innermost type that we're projecting from.
let mut ty = if path.segments.is_empty() {
// If the base path is empty that means there exists a
// syntactical `Self`, e.g., `&i32` in `<&i32>::clone`.
qself.expect("missing QSelf for <T>::...")
} else {
// Otherwise, the base path is an implicit `Self` type path,
// e.g., `Vec` in `Vec::new` or `<I as Iterator>::Item` in
// `<I as Iterator>::Item::default`.
let new_id = self.next_id();
self.arena.alloc(self.ty_path(new_id, path.span, hir::QPath::Resolved(qself, path)))
};
// Anything after the base path are associated "extensions",
// out of which all but the last one are associated types,
// e.g., for `std::vec::Vec::<T>::IntoIter::Item::clone`:
// * base path is `std::vec::Vec<T>`
// * "extensions" are `IntoIter`, `Item` and `clone`
// * type nodes are:
// 1. `std::vec::Vec<T>` (created above)
// 2. `<std::vec::Vec<T>>::IntoIter`
// 3. `<<std::vec::Vec<T>>::IntoIter>::Item`
// * final path is `<<<std::vec::Vec<T>>::IntoIter>::Item>::clone`
for (i, segment) in p.segments.iter().enumerate().skip(proj_start) {
let hir_segment = self.arena.alloc(self.lower_path_segment(
p.span,
segment,
param_mode,
ParenthesizedGenericArgs::Err,
itctx,
None,
None,
));
let qpath = hir::QPath::TypeRelative(ty, hir_segment);
// It's finished, return the extension of the right node type.
if i == p.segments.len() - 1 {
return qpath;
}
// Wrap the associated extension in another type node.
let new_id = self.next_id();
ty = self.arena.alloc(self.ty_path(new_id, path_span_lo.to(segment.span()), qpath));
}
// We should've returned in the for loop above.
self.dcx().span_bug(
p.span,
format!(
"lower_qpath: no final extension segment in {}..{}",
proj_start,
p.segments.len()
),
);
}
pub(crate) fn lower_use_path(
&mut self,
res: SmallVec<[Res; 3]>,
p: &Path,
param_mode: ParamMode,
) -> &'hir hir::UsePath<'hir> {
assert!((1..=3).contains(&res.len()));
self.arena.alloc(hir::UsePath {
res,
segments: self.arena.alloc_from_iter(p.segments.iter().map(|segment| {
self.lower_path_segment(
p.span,
segment,
param_mode,
ParenthesizedGenericArgs::Err,
ImplTraitContext::Disallowed(ImplTraitPosition::Path),
None,
None,
)
})),
span: self.lower_span(p.span),
})
}
pub(crate) fn lower_path_segment(
&mut self,
path_span: Span,
segment: &PathSegment,
param_mode: ParamMode,
parenthesized_generic_args: ParenthesizedGenericArgs,
itctx: ImplTraitContext,
constness: Option<ast::BoundConstness>,
// Additional features ungated with a bound modifier like `async`.
// This is passed down to the implicit associated type binding in
// parenthesized bounds.
bound_modifier_allowed_features: Option<Lrc<[Symbol]>>,
) -> hir::PathSegment<'hir> {
debug!("path_span: {:?}, lower_path_segment(segment: {:?})", path_span, segment);
let (mut generic_args, infer_args) = if let Some(generic_args) = segment.args.as_deref() {
match generic_args {
GenericArgs::AngleBracketed(data) => {
self.lower_angle_bracketed_parameter_data(data, param_mode, itctx)
}
GenericArgs::Parenthesized(data) => match parenthesized_generic_args {
ParenthesizedGenericArgs::ParenSugar => self
.lower_parenthesized_parameter_data(
data,
itctx,
bound_modifier_allowed_features,
),
ParenthesizedGenericArgs::Err => {
// Suggest replacing parentheses with angle brackets `Trait(params...)` to `Trait<params...>`
let sub = if !data.inputs.is_empty() {
// Start of the span to the 1st character of 1st argument
let open_param = data.inputs_span.shrink_to_lo().to(data
.inputs
.first()
.unwrap()
.span
.shrink_to_lo());
// Last character position of last argument to the end of the span
let close_param = data
.inputs
.last()
.unwrap()
.span
.shrink_to_hi()
.to(data.inputs_span.shrink_to_hi());
Some(UseAngleBrackets { open_param, close_param })
} else {
None
};
self.dcx().emit_err(GenericTypeWithParentheses { span: data.span, sub });
(
self.lower_angle_bracketed_parameter_data(
&data.as_angle_bracketed_args(),
param_mode,
itctx,
)
.0,
false,
)
}
},
}
} else {
(
GenericArgsCtor {
args: Default::default(),
bindings: &[],
parenthesized: hir::GenericArgsParentheses::No,
span: path_span.shrink_to_hi(),
},
param_mode == ParamMode::Optional,
)
};
if let Some(constness) = constness {
generic_args.push_constness(self, constness);
}
let has_lifetimes =
generic_args.args.iter().any(|arg| matches!(arg, GenericArg::Lifetime(_)));
// FIXME(return_type_notation): Is this correct? I think so.
if generic_args.parenthesized != hir::GenericArgsParentheses::ParenSugar && !has_lifetimes {
self.maybe_insert_elided_lifetimes_in_path(
path_span,
segment.id,
segment.ident.span,
&mut generic_args,
);
}
let res = self.expect_full_res(segment.id);
let hir_id = self.lower_node_id(segment.id);
debug!(
"lower_path_segment: ident={:?} original-id={:?} new-id={:?}",
segment.ident, segment.id, hir_id,
);
hir::PathSegment {
ident: self.lower_ident(segment.ident),
hir_id,
res: self.lower_res(res),
infer_args,
args: if generic_args.is_empty() && generic_args.span.is_empty() {
None
} else {
Some(generic_args.into_generic_args(self))
},
}
}
fn maybe_insert_elided_lifetimes_in_path(
&mut self,
path_span: Span,
segment_id: NodeId,
segment_ident_span: Span,
generic_args: &mut GenericArgsCtor<'hir>,
) {
let (start, end) = match self.resolver.get_lifetime_res(segment_id) {
Some(LifetimeRes::ElidedAnchor { start, end }) => (start, end),
None => return,
Some(res) => {
span_bug!(path_span, "expected an elided lifetime to insert. found {res:?}")
}
};
let expected_lifetimes = end.as_usize() - start.as_usize();
debug!(expected_lifetimes);
// Note: these spans are used for diagnostics when they can't be inferred.
// See rustc_resolve::late::lifetimes::LifetimeContext::add_missing_lifetime_specifiers_label
let elided_lifetime_span = if generic_args.span.is_empty() {
// If there are no brackets, use the identifier span.
// HACK: we use find_ancestor_inside to properly suggest elided spans in paths
// originating from macros, since the segment's span might be from a macro arg.
segment_ident_span.find_ancestor_inside(path_span).unwrap_or(path_span)
} else if generic_args.is_empty() {
// If there are brackets, but not generic arguments, then use the opening bracket
generic_args.span.with_hi(generic_args.span.lo() + BytePos(1))
} else {
// Else use an empty span right after the opening bracket.
generic_args.span.with_lo(generic_args.span.lo() + BytePos(1)).shrink_to_lo()
};
generic_args.args.insert_many(
0,
(start.as_u32()..end.as_u32()).map(|i| {
let id = NodeId::from_u32(i);
let l = self.lower_lifetime(&Lifetime {
id,
ident: Ident::new(kw::Empty, elided_lifetime_span),
});
GenericArg::Lifetime(l)
}),
);
}
pub(crate) fn lower_angle_bracketed_parameter_data(
&mut self,
data: &AngleBracketedArgs,
param_mode: ParamMode,
itctx: ImplTraitContext,
) -> (GenericArgsCtor<'hir>, bool) {
let has_non_lt_args = data.args.iter().any(|arg| match arg {
AngleBracketedArg::Arg(ast::GenericArg::Lifetime(_))
| AngleBracketedArg::Constraint(_) => false,
AngleBracketedArg::Arg(ast::GenericArg::Type(_) | ast::GenericArg::Const(_)) => true,
});
let args = data
.args
.iter()
.filter_map(|arg| match arg {
AngleBracketedArg::Arg(arg) => Some(self.lower_generic_arg(arg, itctx)),
AngleBracketedArg::Constraint(_) => None,
})
.collect();
let bindings = self.arena.alloc_from_iter(data.args.iter().filter_map(|arg| match arg {
AngleBracketedArg::Constraint(c) => Some(self.lower_assoc_ty_constraint(c, itctx)),
AngleBracketedArg::Arg(_) => None,
}));
let ctor = GenericArgsCtor {
args,
bindings,
parenthesized: hir::GenericArgsParentheses::No,
span: data.span,
};
(ctor, !has_non_lt_args && param_mode == ParamMode::Optional)
}
fn lower_parenthesized_parameter_data(
&mut self,
data: &ParenthesizedArgs,
itctx: ImplTraitContext,
bound_modifier_allowed_features: Option<Lrc<[Symbol]>>,
) -> (GenericArgsCtor<'hir>, bool) {
// Switch to `PassThrough` mode for anonymous lifetimes; this
// means that we permit things like `&Ref<T>`, where `Ref` has
// a hidden lifetime parameter. This is needed for backwards
// compatibility, even in contexts like an impl header where
// we generally don't permit such things (see #51008).
let ParenthesizedArgs { span, inputs, inputs_span, output } = data;
let inputs = self.arena.alloc_from_iter(inputs.iter().map(|ty| {
self.lower_ty_direct(ty, ImplTraitContext::Disallowed(ImplTraitPosition::FnTraitParam))
}));
let output_ty = match output {
// Only allow `impl Trait` in return position. i.e.:
// ```rust
// fn f(_: impl Fn() -> impl Debug) -> impl Fn() -> impl Debug
// // disallowed --^^^^^^^^^^ allowed --^^^^^^^^^^
// ```
FnRetTy::Ty(ty) if matches!(itctx, ImplTraitContext::OpaqueTy { .. }) => {
if self.tcx.features().impl_trait_in_fn_trait_return {
self.lower_ty(ty, itctx)
} else {
self.lower_ty(
ty,
ImplTraitContext::FeatureGated(
ImplTraitPosition::FnTraitReturn,
sym::impl_trait_in_fn_trait_return,
),
)
}
}
FnRetTy::Ty(ty) => {
self.lower_ty(ty, ImplTraitContext::Disallowed(ImplTraitPosition::FnTraitReturn))
}
FnRetTy::Default(_) => self.arena.alloc(self.ty_tup(*span, &[])),
};
let args = smallvec![GenericArg::Type(self.arena.alloc(self.ty_tup(*inputs_span, inputs)))];
// If we have a bound like `async Fn() -> T`, make sure that we mark the
// `Output = T` associated type bound with the right feature gates.
let mut output_span = output_ty.span;
if let Some(bound_modifier_allowed_features) = bound_modifier_allowed_features {
output_span = self.mark_span_with_reason(
DesugaringKind::BoundModifier,
output_span,
Some(bound_modifier_allowed_features),
);
}
let binding = self.assoc_ty_binding(sym::Output, output_span, output_ty);
(
GenericArgsCtor {
args,
bindings: arena_vec![self; binding],
parenthesized: hir::GenericArgsParentheses::ParenSugar,
span: data.inputs_span,
},
false,
)
}
/// An associated type binding `$assoc_ty_name = $ty`.
pub(crate) fn assoc_ty_binding(
&mut self,
assoc_ty_name: rustc_span::Symbol,
span: Span,
ty: &'hir hir::Ty<'hir>,
) -> hir::TypeBinding<'hir> {
let ident = Ident::with_dummy_span(assoc_ty_name);
let kind = hir::TypeBindingKind::Equality { term: ty.into() };
let args = arena_vec![self;];
let bindings = arena_vec![self;];
let gen_args = self.arena.alloc(hir::GenericArgs {
args,
bindings,
parenthesized: hir::GenericArgsParentheses::No,
span_ext: DUMMY_SP,
});
hir::TypeBinding {
hir_id: self.next_id(),
gen_args,
span: self.lower_span(span),
ident,
kind,
}
}
/// When a bound is annotated with `async`, it signals to lowering that the trait
/// that the bound refers to should be mapped to the "async" flavor of the trait.
///
/// This only needs to be done until we unify `AsyncFn` and `Fn` traits into one
/// that is generic over `async`ness, if that's ever possible, or modify the
/// lowering of `async Fn()` bounds to desugar to another trait like `LendingFn`.
fn map_trait_to_async_trait(&self, def_id: DefId) -> Option<(DefId, Lrc<[Symbol]>)> {
let lang_items = self.tcx.lang_items();
if Some(def_id) == lang_items.fn_trait() {
Some((lang_items.async_fn_trait()?, self.allow_async_fn_traits.clone()))
} else if Some(def_id) == lang_items.fn_mut_trait() {
Some((lang_items.async_fn_mut_trait()?, self.allow_async_fn_traits.clone()))
} else if Some(def_id) == lang_items.fn_once_trait() {
Some((lang_items.async_fn_once_trait()?, self.allow_async_fn_traits.clone()))
} else {
None
}
}
}