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use rustc_attr_data_structures::{AttributeKind, OptimizeAttr};
use rustc_feature::{AttributeTemplate, template};
use rustc_session::parse::feature_err;
use rustc_span::{Span, Symbol, sym};
use super::{AcceptMapping, AttributeOrder, AttributeParser, OnDuplicate, SingleAttributeParser};
use crate::context::{AcceptContext, FinalizeContext, Stage};
use crate::parser::ArgParser;
use crate::session_diagnostics::{NakedFunctionIncompatibleAttribute, NullOnExport};
pub(crate) struct OptimizeParser;
impl<S: Stage> SingleAttributeParser<S> for OptimizeParser {
const PATH: &[Symbol] = &[sym::optimize];
const ATTRIBUTE_ORDER: AttributeOrder = AttributeOrder::KeepLast;
const ON_DUPLICATE: OnDuplicate<S> = OnDuplicate::WarnButFutureError;
const TEMPLATE: AttributeTemplate = template!(List: "size|speed|none");
fn convert(cx: &mut AcceptContext<'_, '_, S>, args: &ArgParser<'_>) -> Option<AttributeKind> {
let Some(list) = args.list() else {
cx.expected_list(cx.attr_span);
return None;
};
let Some(single) = list.single() else {
cx.expected_single_argument(list.span);
return None;
};
let res = match single.meta_item().and_then(|i| i.path().word().map(|i| i.name)) {
Some(sym::size) => OptimizeAttr::Size,
Some(sym::speed) => OptimizeAttr::Speed,
Some(sym::none) => OptimizeAttr::DoNotOptimize,
_ => {
cx.expected_specific_argument(single.span(), vec!["size", "speed", "none"]);
OptimizeAttr::Default
}
};
Some(AttributeKind::Optimize(res, cx.attr_span))
}
}
pub(crate) struct ColdParser;
impl<S: Stage> SingleAttributeParser<S> for ColdParser {
const PATH: &[Symbol] = &[sym::cold];
const ATTRIBUTE_ORDER: AttributeOrder = AttributeOrder::KeepLast;
const ON_DUPLICATE: OnDuplicate<S> = OnDuplicate::Warn;
const TEMPLATE: AttributeTemplate = template!(Word);
fn convert(cx: &mut AcceptContext<'_, '_, S>, args: &ArgParser<'_>) -> Option<AttributeKind> {
if let Err(span) = args.no_args() {
cx.expected_no_args(span);
return None;
}
Some(AttributeKind::Cold(cx.attr_span))
}
}
pub(crate) struct ExportNameParser;
impl<S: Stage> SingleAttributeParser<S> for ExportNameParser {
const PATH: &[rustc_span::Symbol] = &[sym::export_name];
const ATTRIBUTE_ORDER: AttributeOrder = AttributeOrder::KeepFirst;
const ON_DUPLICATE: OnDuplicate<S> = OnDuplicate::WarnButFutureError;
const TEMPLATE: AttributeTemplate = template!(NameValueStr: "name");
fn convert(cx: &mut AcceptContext<'_, '_, S>, args: &ArgParser<'_>) -> Option<AttributeKind> {
let Some(nv) = args.name_value() else {
cx.expected_name_value(cx.attr_span, None);
return None;
};
let Some(name) = nv.value_as_str() else {
cx.expected_string_literal(nv.value_span, Some(nv.value_as_lit()));
return None;
};
if name.as_str().contains('\0') {
// `#[export_name = ...]` will be converted to a null-terminated string,
// so it may not contain any null characters.
cx.emit_err(NullOnExport { span: cx.attr_span });
return None;
}
Some(AttributeKind::ExportName { name, span: cx.attr_span })
}
}
#[derive(Default)]
pub(crate) struct NakedParser {
span: Option<Span>,
}
impl<S: Stage> AttributeParser<S> for NakedParser {
const ATTRIBUTES: AcceptMapping<Self, S> =
&[(&[sym::naked], template!(Word), |this, cx, args| {
if let Err(span) = args.no_args() {
cx.expected_no_args(span);
return;
}
if let Some(earlier) = this.span {
let span = cx.attr_span;
cx.warn_unused_duplicate(earlier, span);
} else {
this.span = Some(cx.attr_span);
}
})];
fn finalize(self, cx: &FinalizeContext<'_, '_, S>) -> Option<AttributeKind> {
// FIXME(jdonszelmann): upgrade this list to *parsed* attributes
// once all of these have parsed forms. That'd make the check much nicer...
//
// many attributes don't make sense in combination with #[naked].
// Notable attributes that are incompatible with `#[naked]` are:
//
// * `#[inline]`
// * `#[track_caller]`
// * `#[test]`, `#[ignore]`, `#[should_panic]`
//
// NOTE: when making changes to this list, check that `error_codes/E0736.md` remains
// accurate.
const ALLOW_LIST: &[rustc_span::Symbol] = &[
// conditional compilation
sym::cfg_trace,
sym::cfg_attr_trace,
// testing (allowed here so better errors can be generated in `rustc_builtin_macros::test`)
sym::test,
sym::ignore,
sym::should_panic,
sym::bench,
// diagnostics
sym::allow,
sym::warn,
sym::deny,
sym::forbid,
sym::deprecated,
sym::must_use,
// abi, linking and FFI
sym::cold,
sym::export_name,
sym::link_section,
sym::linkage,
sym::no_mangle,
sym::instruction_set,
sym::repr,
sym::rustc_std_internal_symbol,
sym::align,
// obviously compatible with self
sym::naked,
// documentation
sym::doc,
];
let span = self.span?;
// only if we found a naked attribute do we do the somewhat expensive check
'outer: for other_attr in cx.all_attrs {
for allowed_attr in ALLOW_LIST {
if other_attr.segments().next().is_some_and(|i| cx.tools.contains(&i.name)) {
// effectively skips the error message being emitted below
// if it's a tool attribute
continue 'outer;
}
if other_attr.word_is(*allowed_attr) {
// effectively skips the error message being emitted below
// if its an allowed attribute
continue 'outer;
}
if other_attr.word_is(sym::target_feature) {
if !cx.features().naked_functions_target_feature() {
feature_err(
&cx.sess(),
sym::naked_functions_target_feature,
other_attr.span(),
"`#[target_feature(/* ... */)]` is currently unstable on `#[naked]` functions",
).emit();
}
continue 'outer;
}
}
cx.emit_err(NakedFunctionIncompatibleAttribute {
span: other_attr.span(),
naked_span: span,
attr: other_attr.get_attribute_path().to_string(),
});
}
Some(AttributeKind::Naked(span))
}
}
pub(crate) struct TrackCallerParser;
impl<S: Stage> SingleAttributeParser<S> for TrackCallerParser {
const PATH: &[Symbol] = &[sym::track_caller];
const ATTRIBUTE_ORDER: AttributeOrder = AttributeOrder::KeepLast;
const ON_DUPLICATE: OnDuplicate<S> = OnDuplicate::Warn;
const TEMPLATE: AttributeTemplate = template!(Word);
fn convert(cx: &mut AcceptContext<'_, '_, S>, args: &ArgParser<'_>) -> Option<AttributeKind> {
if let Err(span) = args.no_args() {
cx.expected_no_args(span);
return None;
}
Some(AttributeKind::TrackCaller(cx.attr_span))
}
}
pub(crate) struct NoMangleParser;
impl<S: Stage> SingleAttributeParser<S> for NoMangleParser {
const PATH: &[rustc_span::Symbol] = &[sym::no_mangle];
const ATTRIBUTE_ORDER: AttributeOrder = AttributeOrder::KeepLast;
const ON_DUPLICATE: OnDuplicate<S> = OnDuplicate::Warn;
const TEMPLATE: AttributeTemplate = template!(Word);
fn convert(cx: &mut AcceptContext<'_, '_, S>, args: &ArgParser<'_>) -> Option<AttributeKind> {
if let Err(span) = args.no_args() {
cx.expected_no_args(span);
return None;
}
Some(AttributeKind::NoMangle(cx.attr_span))
}
}
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