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rust/compiler/rustc_resolve/src/macros.rs

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//! A bunch of methods and structures more or less related to resolving macros and
//! interface provided by `Resolver` to macro expander.
use crate::errors::CannotDetermineMacroResolution;
use crate::errors::{self, AddAsNonDerive, CannotFindIdentInThisScope};
use crate::errors::{MacroExpectedFound, RemoveSurroundingDerive};
use crate::Namespace::*;
use crate::{BuiltinMacroState, Determinacy, MacroData, Used};
use crate::{DeriveData, Finalize, ParentScope, ResolutionError, Resolver, ScopeSet};
use crate::{ModuleKind, ModuleOrUniformRoot, NameBinding, PathResult, Segment, ToNameBinding};
use rustc_ast::expand::StrippedCfgItem;
use rustc_ast::{self as ast, attr, Crate, Inline, ItemKind, ModKind, NodeId};
use rustc_ast_pretty::pprust;
use rustc_attr::StabilityLevel;
use rustc_data_structures::intern::Interned;
use rustc_data_structures::sync::Lrc;
use rustc_errors::{codes::*, struct_span_code_err, Applicability, StashKey};
use rustc_expand::base::{Annotatable, DeriveResolutions, Indeterminate, ResolverExpand};
use rustc_expand::base::{SyntaxExtension, SyntaxExtensionKind};
use rustc_expand::compile_declarative_macro;
use rustc_expand::expand::{AstFragment, Invocation, InvocationKind, SupportsMacroExpansion};
use rustc_hir::def::{self, DefKind, Namespace, NonMacroAttrKind};
use rustc_hir::def_id::{CrateNum, DefId, LocalDefId};
use rustc_middle::middle::stability;
use rustc_middle::ty::RegisteredTools;
use rustc_middle::ty::{TyCtxt, Visibility};
use rustc_session::lint::builtin::UNKNOWN_OR_MALFORMED_DIAGNOSTIC_ATTRIBUTES;
use rustc_session::lint::builtin::{LEGACY_DERIVE_HELPERS, SOFT_UNSTABLE};
use rustc_session::lint::builtin::{UNUSED_MACROS, UNUSED_MACRO_RULES};
use rustc_session::lint::BuiltinLintDiag;
use rustc_session::parse::feature_err;
use rustc_span::edition::Edition;
use rustc_span::hygiene::{self, ExpnData, ExpnKind, LocalExpnId};
use rustc_span::hygiene::{AstPass, MacroKind};
use rustc_span::symbol::{kw, sym, Ident, Symbol};
use rustc_span::{Span, DUMMY_SP};
use std::cell::Cell;
use std::mem;
type Res = def::Res<NodeId>;
/// Binding produced by a `macro_rules` item.
/// Not modularized, can shadow previous `macro_rules` bindings, etc.
#[derive(Debug)]
pub(crate) struct MacroRulesBinding<'a> {
pub(crate) binding: NameBinding<'a>,
/// `macro_rules` scope into which the `macro_rules` item was planted.
pub(crate) parent_macro_rules_scope: MacroRulesScopeRef<'a>,
pub(crate) ident: Ident,
}
/// The scope introduced by a `macro_rules!` macro.
/// This starts at the macro's definition and ends at the end of the macro's parent
/// module (named or unnamed), or even further if it escapes with `#[macro_use]`.
/// Some macro invocations need to introduce `macro_rules` scopes too because they
/// can potentially expand into macro definitions.
#[derive(Copy, Clone, Debug)]
pub(crate) enum MacroRulesScope<'a> {
/// Empty "root" scope at the crate start containing no names.
Empty,
/// The scope introduced by a `macro_rules!` macro definition.
Binding(&'a MacroRulesBinding<'a>),
/// The scope introduced by a macro invocation that can potentially
/// create a `macro_rules!` macro definition.
Invocation(LocalExpnId),
}
/// `macro_rules!` scopes are always kept by reference and inside a cell.
/// The reason is that we update scopes with value `MacroRulesScope::Invocation(invoc_id)`
/// in-place after `invoc_id` gets expanded.
/// This helps to avoid uncontrollable growth of `macro_rules!` scope chains,
/// which usually grow linearly with the number of macro invocations
/// in a module (including derives) and hurt performance.
pub(crate) type MacroRulesScopeRef<'a> = Interned<'a, Cell<MacroRulesScope<'a>>>;
/// Macro namespace is separated into two sub-namespaces, one for bang macros and
/// one for attribute-like macros (attributes, derives).
/// We ignore resolutions from one sub-namespace when searching names in scope for another.
pub(crate) fn sub_namespace_match(
candidate: Option<MacroKind>,
requirement: Option<MacroKind>,
) -> bool {
#[derive(PartialEq)]
enum SubNS {
Bang,
AttrLike,
}
let sub_ns = |kind| match kind {
MacroKind::Bang => SubNS::Bang,
MacroKind::Attr | MacroKind::Derive => SubNS::AttrLike,
};
let candidate = candidate.map(sub_ns);
let requirement = requirement.map(sub_ns);
// "No specific sub-namespace" means "matches anything" for both requirements and candidates.
candidate.is_none() || requirement.is_none() || candidate == requirement
}
// We don't want to format a path using pretty-printing,
// `format!("{}", path)`, because that tries to insert
// line-breaks and is slow.
fn fast_print_path(path: &ast::Path) -> Symbol {
if path.segments.len() == 1 {
path.segments[0].ident.name
} else {
let mut path_str = String::with_capacity(64);
for (i, segment) in path.segments.iter().enumerate() {
if i != 0 {
path_str.push_str("::");
}
if segment.ident.name != kw::PathRoot {
path_str.push_str(segment.ident.as_str())
}
}
Symbol::intern(&path_str)
}
}
pub(crate) fn registered_tools(tcx: TyCtxt<'_>, (): ()) -> RegisteredTools {
let mut registered_tools = RegisteredTools::default();
let (_, pre_configured_attrs) = &*tcx.crate_for_resolver(()).borrow();
for attr in attr::filter_by_name(pre_configured_attrs, sym::register_tool) {
for nested_meta in attr.meta_item_list().unwrap_or_default() {
match nested_meta.ident() {
Some(ident) => {
if let Some(old_ident) = registered_tools.replace(ident) {
let msg = format!("{} `{}` was already registered", "tool", ident);
tcx.dcx()
.struct_span_err(ident.span, msg)
.with_span_label(old_ident.span, "already registered here")
.emit();
}
}
None => {
let msg = format!("`{}` only accepts identifiers", sym::register_tool);
let span = nested_meta.span();
tcx.dcx()
.struct_span_err(span, msg)
.with_span_label(span, "not an identifier")
.emit();
}
}
}
}
// We implicitly add `rustfmt`, `clippy`, `diagnostic` to known tools,
// but it's not an error to register them explicitly.
let predefined_tools = [sym::clippy, sym::rustfmt, sym::diagnostic];
registered_tools.extend(predefined_tools.iter().cloned().map(Ident::with_dummy_span));
registered_tools
}
// Some feature gates for inner attributes are reported as lints for backward compatibility.
fn soft_custom_inner_attributes_gate(path: &ast::Path, invoc: &Invocation) -> bool {
match &path.segments[..] {
// `#![test]`
[seg] if seg.ident.name == sym::test => return true,
// `#![rustfmt::skip]` on out-of-line modules
[seg1, seg2] if seg1.ident.name == sym::rustfmt && seg2.ident.name == sym::skip => {
if let InvocationKind::Attr { item, .. } = &invoc.kind {
if let Annotatable::Item(item) = item {
if let ItemKind::Mod(_, ModKind::Loaded(_, Inline::No, _)) = item.kind {
return true;
}
}
}
}
_ => {}
}
false
}
impl<'a, 'tcx> ResolverExpand for Resolver<'a, 'tcx> {
fn next_node_id(&mut self) -> NodeId {
self.next_node_id()
}
fn invocation_parent(&self, id: LocalExpnId) -> LocalDefId {
self.invocation_parents[&id].0
}
fn resolve_dollar_crates(&mut self) {
hygiene::update_dollar_crate_names(|ctxt| {
let ident = Ident::new(kw::DollarCrate, DUMMY_SP.with_ctxt(ctxt));
match self.resolve_crate_root(ident).kind {
ModuleKind::Def(.., name) if name != kw::Empty => name,
_ => kw::Crate,
}
});
}
fn visit_ast_fragment_with_placeholders(
&mut self,
expansion: LocalExpnId,
fragment: &AstFragment,
) {
// Integrate the new AST fragment into all the definition and module structures.
// We are inside the `expansion` now, but other parent scope components are still the same.
let parent_scope = ParentScope { expansion, ..self.invocation_parent_scopes[&expansion] };
let output_macro_rules_scope = self.build_reduced_graph(fragment, parent_scope);
self.output_macro_rules_scopes.insert(expansion, output_macro_rules_scope);
parent_scope.module.unexpanded_invocations.borrow_mut().remove(&expansion);
}
fn register_builtin_macro(&mut self, name: Symbol, ext: SyntaxExtensionKind) {
if self.builtin_macros.insert(name, BuiltinMacroState::NotYetSeen(ext)).is_some() {
self.dcx().bug(format!("built-in macro `{name}` was already registered"));
}
}
// Create a new Expansion with a definition site of the provided module, or
// a fake empty `#[no_implicit_prelude]` module if no module is provided.
fn expansion_for_ast_pass(
&mut self,
call_site: Span,
pass: AstPass,
features: &[Symbol],
parent_module_id: Option<NodeId>,
) -> LocalExpnId {
let parent_module =
parent_module_id.map(|module_id| self.local_def_id(module_id).to_def_id());
let expn_id = LocalExpnId::fresh(
ExpnData::allow_unstable(
ExpnKind::AstPass(pass),
call_site,
self.tcx.sess.edition(),
features.into(),
None,
parent_module,
),
self.create_stable_hashing_context(),
);
let parent_scope =
parent_module.map_or(self.empty_module, |def_id| self.expect_module(def_id));
self.ast_transform_scopes.insert(expn_id, parent_scope);
expn_id
}
fn resolve_imports(&mut self) {
self.resolve_imports()
}
fn resolve_macro_invocation(
&mut self,
invoc: &Invocation,
eager_expansion_root: LocalExpnId,
force: bool,
) -> Result<Lrc<SyntaxExtension>, Indeterminate> {
let invoc_id = invoc.expansion_data.id;
let parent_scope = match self.invocation_parent_scopes.get(&invoc_id) {
Some(parent_scope) => *parent_scope,
None => {
// If there's no entry in the table, then we are resolving an eagerly expanded
// macro, which should inherit its parent scope from its eager expansion root -
// the macro that requested this eager expansion.
let parent_scope = *self
.invocation_parent_scopes
.get(&eager_expansion_root)
.expect("non-eager expansion without a parent scope");
self.invocation_parent_scopes.insert(invoc_id, parent_scope);
parent_scope
}
};
let (path, kind, inner_attr, derives) = match invoc.kind {
InvocationKind::Attr { ref attr, ref derives, .. } => (
&attr.get_normal_item().path,
MacroKind::Attr,
attr.style == ast::AttrStyle::Inner,
self.arenas.alloc_ast_paths(derives),
),
InvocationKind::Bang { ref mac, .. } => (&mac.path, MacroKind::Bang, false, &[][..]),
InvocationKind::Derive { ref path, .. } => (path, MacroKind::Derive, false, &[][..]),
};
// Derives are not included when `invocations` are collected, so we have to add them here.
let parent_scope = &ParentScope { derives, ..parent_scope };
let supports_macro_expansion = invoc.fragment_kind.supports_macro_expansion();
let node_id = invoc.expansion_data.lint_node_id;
let (ext, res) = self.smart_resolve_macro_path(
path,
kind,
supports_macro_expansion,
inner_attr,
parent_scope,
node_id,
force,
soft_custom_inner_attributes_gate(path, invoc),
)?;
let span = invoc.span();
let def_id = res.opt_def_id();
invoc_id.set_expn_data(
ext.expn_data(
parent_scope.expansion,
span,
fast_print_path(path),
def_id,
def_id.map(|def_id| self.macro_def_scope(def_id).nearest_parent_mod()),
),
self.create_stable_hashing_context(),
);
Ok(ext)
}
fn record_macro_rule_usage(&mut self, id: NodeId, rule_i: usize) {
let did = self.local_def_id(id);
self.unused_macro_rules.remove(&(did, rule_i));
}
fn check_unused_macros(&mut self) {
for (_, &(node_id, ident)) in self.unused_macros.iter() {
self.lint_buffer.buffer_lint(
UNUSED_MACROS,
node_id,
ident.span,
format!("unused macro definition: `{}`", ident.name),
);
}
for (&(def_id, arm_i), &(ident, rule_span)) in self.unused_macro_rules.iter() {
if self.unused_macros.contains_key(&def_id) {
// We already lint the entire macro as unused
continue;
}
let node_id = self.def_id_to_node_id[def_id];
self.lint_buffer.buffer_lint(
UNUSED_MACRO_RULES,
node_id,
rule_span,
format!(
"{} rule of macro `{}` is never used",
crate::diagnostics::ordinalize(arm_i + 1),
ident.name
),
);
}
}
fn has_derive_copy(&self, expn_id: LocalExpnId) -> bool {
self.containers_deriving_copy.contains(&expn_id)
}
fn resolve_derives(
&mut self,
expn_id: LocalExpnId,
force: bool,
derive_paths: &dyn Fn() -> DeriveResolutions,
) -> Result<(), Indeterminate> {
// Block expansion of the container until we resolve all derives in it.
// This is required for two reasons:
// - Derive helper attributes are in scope for the item to which the `#[derive]`
// is applied, so they have to be produced by the container's expansion rather
// than by individual derives.
// - Derives in the container need to know whether one of them is a built-in `Copy`.
// Temporarily take the data to avoid borrow checker conflicts.
let mut derive_data = mem::take(&mut self.derive_data);
let entry = derive_data.entry(expn_id).or_insert_with(|| DeriveData {
resolutions: derive_paths(),
helper_attrs: Vec::new(),
has_derive_copy: false,
});
let parent_scope = self.invocation_parent_scopes[&expn_id];
for (i, (path, _, opt_ext, _)) in entry.resolutions.iter_mut().enumerate() {
if opt_ext.is_none() {
*opt_ext = Some(
match self.resolve_macro_path(
path,
Some(MacroKind::Derive),
&parent_scope,
true,
force,
) {
Ok((Some(ext), _)) => {
if !ext.helper_attrs.is_empty() {
let last_seg = path.segments.last().unwrap();
let span = last_seg.ident.span.normalize_to_macros_2_0();
entry.helper_attrs.extend(
ext.helper_attrs
.iter()
.map(|name| (i, Ident::new(*name, span))),
);
}
entry.has_derive_copy |= ext.builtin_name == Some(sym::Copy);
ext
}
Ok(_) | Err(Determinacy::Determined) => self.dummy_ext(MacroKind::Derive),
Err(Determinacy::Undetermined) => {
assert!(self.derive_data.is_empty());
self.derive_data = derive_data;
return Err(Indeterminate);
}
},
);
}
}
// Sort helpers in a stable way independent from the derive resolution order.
entry.helper_attrs.sort_by_key(|(i, _)| *i);
let helper_attrs = entry
.helper_attrs
.iter()
.map(|(_, ident)| {
let res = Res::NonMacroAttr(NonMacroAttrKind::DeriveHelper);
let binding = (res, Visibility::<DefId>::Public, ident.span, expn_id)
.to_name_binding(self.arenas);
(*ident, binding)
})
.collect();
self.helper_attrs.insert(expn_id, helper_attrs);
// Mark this derive as having `Copy` either if it has `Copy` itself or if its parent derive
// has `Copy`, to support cases like `#[derive(Clone, Copy)] #[derive(Debug)]`.
if entry.has_derive_copy || self.has_derive_copy(parent_scope.expansion) {
self.containers_deriving_copy.insert(expn_id);
}
assert!(self.derive_data.is_empty());
self.derive_data = derive_data;
Ok(())
}
fn take_derive_resolutions(&mut self, expn_id: LocalExpnId) -> Option<DeriveResolutions> {
self.derive_data.remove(&expn_id).map(|data| data.resolutions)
}
// The function that implements the resolution logic of `#[cfg_accessible(path)]`.
// Returns true if the path can certainly be resolved in one of three namespaces,
// returns false if the path certainly cannot be resolved in any of the three namespaces.
// Returns `Indeterminate` if we cannot give a certain answer yet.
fn cfg_accessible(
&mut self,
expn_id: LocalExpnId,
path: &ast::Path,
) -> Result<bool, Indeterminate> {
self.path_accessible(expn_id, path, &[TypeNS, ValueNS, MacroNS])
}
fn macro_accessible(
&mut self,
expn_id: LocalExpnId,
path: &ast::Path,
) -> Result<bool, Indeterminate> {
self.path_accessible(expn_id, path, &[MacroNS])
}
fn get_proc_macro_quoted_span(&self, krate: CrateNum, id: usize) -> Span {
self.cstore().get_proc_macro_quoted_span_untracked(krate, id, self.tcx.sess)
}
fn declare_proc_macro(&mut self, id: NodeId) {
self.proc_macros.push(id)
}
fn append_stripped_cfg_item(&mut self, parent_node: NodeId, name: Ident, cfg: ast::MetaItem) {
self.stripped_cfg_items.push(StrippedCfgItem { parent_module: parent_node, name, cfg });
}
fn registered_tools(&self) -> &RegisteredTools {
self.registered_tools
}
}
impl<'a, 'tcx> Resolver<'a, 'tcx> {
/// Resolve macro path with error reporting and recovery.
/// Uses dummy syntax extensions for unresolved macros or macros with unexpected resolutions
/// for better error recovery.
fn smart_resolve_macro_path(
&mut self,
path: &ast::Path,
kind: MacroKind,
supports_macro_expansion: SupportsMacroExpansion,
inner_attr: bool,
parent_scope: &ParentScope<'a>,
node_id: NodeId,
force: bool,
soft_custom_inner_attributes_gate: bool,
) -> Result<(Lrc<SyntaxExtension>, Res), Indeterminate> {
let (ext, res) = match self.resolve_macro_path(path, Some(kind), parent_scope, true, force)
{
Ok((Some(ext), res)) => (ext, res),
Ok((None, res)) => (self.dummy_ext(kind), res),
Err(Determinacy::Determined) => (self.dummy_ext(kind), Res::Err),
Err(Determinacy::Undetermined) => return Err(Indeterminate),
};
// Report errors for the resolved macro.
for segment in &path.segments {
if let Some(args) = &segment.args {
self.dcx().span_err(args.span(), "generic arguments in macro path");
}
if kind == MacroKind::Attr && segment.ident.as_str().starts_with("rustc") {
self.dcx().span_err(
segment.ident.span,
"attributes starting with `rustc` are reserved for use by the `rustc` compiler",
);
}
}
match res {
Res::Def(DefKind::Macro(_), def_id) => {
if let Some(def_id) = def_id.as_local() {
self.unused_macros.remove(&def_id);
if self.proc_macro_stubs.contains(&def_id) {
self.dcx().emit_err(errors::ProcMacroSameCrate {
span: path.span,
is_test: self.tcx.sess.is_test_crate(),
});
}
}
}
Res::NonMacroAttr(..) | Res::Err => {}
_ => panic!("expected `DefKind::Macro` or `Res::NonMacroAttr`"),
};
self.check_stability_and_deprecation(&ext, path, node_id);
let unexpected_res = if ext.macro_kind() != kind {
Some((kind.article(), kind.descr_expected()))
} else if matches!(res, Res::Def(..)) {
match supports_macro_expansion {
SupportsMacroExpansion::No => Some(("a", "non-macro attribute")),
SupportsMacroExpansion::Yes { supports_inner_attrs } => {
if inner_attr && !supports_inner_attrs {
Some(("a", "non-macro inner attribute"))
} else {
None
}
}
}
} else {
None
};
if let Some((article, expected)) = unexpected_res {
let path_str = pprust::path_to_string(path);
let mut err = MacroExpectedFound {
span: path.span,
expected,
found: res.descr(),
macro_path: &path_str,
remove_surrounding_derive: None,
add_as_non_derive: None,
};
// Suggest moving the macro out of the derive() if the macro isn't Derive
if !path.span.from_expansion()
&& kind == MacroKind::Derive
&& ext.macro_kind() != MacroKind::Derive
{
err.remove_surrounding_derive = Some(RemoveSurroundingDerive { span: path.span });
err.add_as_non_derive = Some(AddAsNonDerive { macro_path: &path_str });
}
self.dcx()
.create_err(err)
.with_span_label(path.span, format!("not {article} {expected}"))
.emit();
return Ok((self.dummy_ext(kind), Res::Err));
}
// We are trying to avoid reporting this error if other related errors were reported.
if res != Res::Err && inner_attr && !self.tcx.features().custom_inner_attributes {
let msg = match res {
Res::Def(..) => "inner macro attributes are unstable",
Res::NonMacroAttr(..) => "custom inner attributes are unstable",
_ => unreachable!(),
};
if soft_custom_inner_attributes_gate {
self.tcx.sess.psess.buffer_lint(SOFT_UNSTABLE, path.span, node_id, msg);
} else {
feature_err(&self.tcx.sess, sym::custom_inner_attributes, path.span, msg).emit();
}
}
if res == Res::NonMacroAttr(NonMacroAttrKind::Tool)
&& path.segments.len() >= 2
&& path.segments[0].ident.name == sym::diagnostic
&& path.segments[1].ident.name != sym::on_unimplemented
{
self.tcx.sess.psess.buffer_lint(
UNKNOWN_OR_MALFORMED_DIAGNOSTIC_ATTRIBUTES,
path.segments[1].span(),
node_id,
"unknown diagnostic attribute",
);
}
Ok((ext, res))
}
pub(crate) fn resolve_macro_path(
&mut self,
path: &ast::Path,
kind: Option<MacroKind>,
parent_scope: &ParentScope<'a>,
trace: bool,
force: bool,
) -> Result<(Option<Lrc<SyntaxExtension>>, Res), Determinacy> {
let path_span = path.span;
let mut path = Segment::from_path(path);
// Possibly apply the macro helper hack
if kind == Some(MacroKind::Bang)
&& path.len() == 1
&& path[0].ident.span.ctxt().outer_expn_data().local_inner_macros
{
let root = Ident::new(kw::DollarCrate, path[0].ident.span);
path.insert(0, Segment::from_ident(root));
}
let res = if path.len() > 1 {
let res = match self.maybe_resolve_path(&path, Some(MacroNS), parent_scope) {
PathResult::NonModule(path_res) if let Some(res) = path_res.full_res() => Ok(res),
PathResult::Indeterminate if !force => return Err(Determinacy::Undetermined),
PathResult::NonModule(..)
| PathResult::Indeterminate
| PathResult::Failed { .. } => Err(Determinacy::Determined),
PathResult::Module(..) => unreachable!(),
};
if trace {
let kind = kind.expect("macro kind must be specified if tracing is enabled");
self.multi_segment_macro_resolutions.push((
path,
path_span,
kind,
*parent_scope,
res.ok(),
));
}
self.prohibit_imported_non_macro_attrs(None, res.ok(), path_span);
res
} else {
let scope_set = kind.map_or(ScopeSet::All(MacroNS), ScopeSet::Macro);
let binding = self.early_resolve_ident_in_lexical_scope(
path[0].ident,
scope_set,
parent_scope,
None,
force,
None,
);
if let Err(Determinacy::Undetermined) = binding {
return Err(Determinacy::Undetermined);
}
if trace {
let kind = kind.expect("macro kind must be specified if tracing is enabled");
self.single_segment_macro_resolutions.push((
path[0].ident,
kind,
*parent_scope,
binding.ok(),
));
}
let res = binding.map(|binding| binding.res());
self.prohibit_imported_non_macro_attrs(binding.ok(), res.ok(), path_span);
res
};
res.map(|res| (self.get_macro(res).map(|macro_data| macro_data.ext.clone()), res))
}
pub(crate) fn finalize_macro_resolutions(&mut self, krate: &Crate) {
let check_consistency = |this: &mut Self,
path: &[Segment],
span,
kind: MacroKind,
initial_res: Option<Res>,
res: Res| {
if let Some(initial_res) = initial_res {
if res != initial_res {
// Make sure compilation does not succeed if preferred macro resolution
// has changed after the macro had been expanded. In theory all such
// situations should be reported as errors, so this is a bug.
this.dcx().span_delayed_bug(span, "inconsistent resolution for a macro");
}
} else if this.tcx.dcx().has_errors().is_none() && this.privacy_errors.is_empty() {
// It's possible that the macro was unresolved (indeterminate) and silently
// expanded into a dummy fragment for recovery during expansion.
// Now, post-expansion, the resolution may succeed, but we can't change the
// past and need to report an error.
// However, non-speculative `resolve_path` can successfully return private items
// even if speculative `resolve_path` returned nothing previously, so we skip this
// less informative error if no other error is reported elsewhere.
let err = this.dcx().create_err(CannotDetermineMacroResolution {
span,
kind: kind.descr(),
path: Segment::names_to_string(path),
});
err.stash(span, StashKey::UndeterminedMacroResolution);
}
};
let macro_resolutions = mem::take(&mut self.multi_segment_macro_resolutions);
for (mut path, path_span, kind, parent_scope, initial_res) in macro_resolutions {
// FIXME: Path resolution will ICE if segment IDs present.
for seg in &mut path {
seg.id = None;
}
match self.resolve_path(
&path,
Some(MacroNS),
&parent_scope,
Some(Finalize::new(ast::CRATE_NODE_ID, path_span)),
None,
) {
PathResult::NonModule(path_res) if let Some(res) = path_res.full_res() => {
check_consistency(self, &path, path_span, kind, initial_res, res)
}
path_res @ (PathResult::NonModule(..) | PathResult::Failed { .. }) => {
let mut suggestion = None;
let (span, label, module) =
if let PathResult::Failed { span, label, module, .. } = path_res {
// try to suggest if it's not a macro, maybe a function
if let PathResult::NonModule(partial_res) =
self.maybe_resolve_path(&path, Some(ValueNS), &parent_scope)
&& partial_res.unresolved_segments() == 0
{
let sm = self.tcx.sess.source_map();
let exclamation_span = sm.next_point(span);
suggestion = Some((
vec![(exclamation_span, "".to_string())],
format!(
"{} is not a macro, but a {}, try to remove `!`",
Segment::names_to_string(&path),
partial_res.base_res().descr()
),
Applicability::MaybeIncorrect,
));
}
(span, label, module)
} else {
(
path_span,
format!(
"partially resolved path in {} {}",
kind.article(),
kind.descr()
),
None,
)
};
self.report_error(
span,
ResolutionError::FailedToResolve {
segment: path.last().map(|segment| segment.ident.name),
label,
suggestion,
module,
},
);
}
PathResult::Module(..) | PathResult::Indeterminate => unreachable!(),
}
}
let macro_resolutions = mem::take(&mut self.single_segment_macro_resolutions);
for (ident, kind, parent_scope, initial_binding) in macro_resolutions {
match self.early_resolve_ident_in_lexical_scope(
ident,
ScopeSet::Macro(kind),
&parent_scope,
Some(Finalize::new(ast::CRATE_NODE_ID, ident.span)),
true,
None,
) {
Ok(binding) => {
let initial_res = initial_binding.map(|initial_binding| {
self.record_use(ident, initial_binding, Used::Other);
initial_binding.res()
});
let res = binding.res();
let seg = Segment::from_ident(ident);
check_consistency(self, &[seg], ident.span, kind, initial_res, res);
if res == Res::NonMacroAttr(NonMacroAttrKind::DeriveHelperCompat) {
let node_id = self
.invocation_parents
.get(&parent_scope.expansion)
.map_or(ast::CRATE_NODE_ID, |id| self.def_id_to_node_id[id.0]);
self.lint_buffer.buffer_lint_with_diagnostic(
LEGACY_DERIVE_HELPERS,
node_id,
ident.span,
"derive helper attribute is used before it is introduced",
BuiltinLintDiag::LegacyDeriveHelpers(binding.span),
);
}
}
Err(..) => {
let expected = kind.descr_expected();
let mut err = self.dcx().create_err(CannotFindIdentInThisScope {
span: ident.span,
expected,
ident,
});
self.unresolved_macro_suggestions(&mut err, kind, &parent_scope, ident, krate);
err.emit();
}
}
}
let builtin_attrs = mem::take(&mut self.builtin_attrs);
for (ident, parent_scope) in builtin_attrs {
let _ = self.early_resolve_ident_in_lexical_scope(
ident,
ScopeSet::Macro(MacroKind::Attr),
&parent_scope,
Some(Finalize::new(ast::CRATE_NODE_ID, ident.span)),
true,
None,
);
}
}
fn check_stability_and_deprecation(
&mut self,
ext: &SyntaxExtension,
path: &ast::Path,
node_id: NodeId,
) {
let span = path.span;
if let Some(stability) = &ext.stability {
if let StabilityLevel::Unstable { reason, issue, is_soft, implied_by } = stability.level
{
let feature = stability.feature;
let is_allowed = |feature| {
self.declared_features.contains(&feature) || span.allows_unstable(feature)
};
let allowed_by_implication = implied_by.is_some_and(|feature| is_allowed(feature));
if !is_allowed(feature) && !allowed_by_implication {
let lint_buffer = &mut self.lint_buffer;
let soft_handler =
|lint, span, msg: String| lint_buffer.buffer_lint(lint, node_id, span, msg);
stability::report_unstable(
self.tcx.sess,
feature,
reason.to_opt_reason(),
issue,
None,
is_soft,
span,
soft_handler,
);
}
}
}
if let Some(depr) = &ext.deprecation {
let path = pprust::path_to_string(path);
let (message, lint) = stability::deprecation_message_and_lint(depr, "macro", &path);
stability::early_report_deprecation(
&mut self.lint_buffer,
message,
depr.suggestion,
lint,
span,
node_id,
);
}
}
fn prohibit_imported_non_macro_attrs(
&self,
binding: Option<NameBinding<'a>>,
res: Option<Res>,
span: Span,
) {
if let Some(Res::NonMacroAttr(kind)) = res {
if kind != NonMacroAttrKind::Tool && binding.map_or(true, |b| b.is_import()) {
let msg =
format!("cannot use {} {} through an import", kind.article(), kind.descr());
let mut err = self.dcx().struct_span_err(span, msg);
if let Some(binding) = binding {
err.span_note(binding.span, format!("the {} imported here", kind.descr()));
}
err.emit();
}
}
}
pub(crate) fn check_reserved_macro_name(&mut self, ident: Ident, res: Res) {
// Reserve some names that are not quite covered by the general check
// performed on `Resolver::builtin_attrs`.
if ident.name == sym::cfg || ident.name == sym::cfg_attr {
let macro_kind = self.get_macro(res).map(|macro_data| macro_data.ext.macro_kind());
if macro_kind.is_some() && sub_namespace_match(macro_kind, Some(MacroKind::Attr)) {
self.dcx().span_err(
ident.span,
format!("name `{ident}` is reserved in attribute namespace"),
);
}
}
}
/// Compile the macro into a `SyntaxExtension` and its rule spans.
///
/// Possibly replace its expander to a pre-defined one for built-in macros.
pub(crate) fn compile_macro(&mut self, item: &ast::Item, edition: Edition) -> MacroData {
let (mut ext, mut rule_spans) =
compile_declarative_macro(self.tcx.sess, self.tcx.features(), item, edition);
if let Some(builtin_name) = ext.builtin_name {
// The macro was marked with `#[rustc_builtin_macro]`.
if let Some(builtin_macro) = self.builtin_macros.get_mut(&builtin_name) {
// The macro is a built-in, replace its expander function
// while still taking everything else from the source code.
// If we already loaded this builtin macro, give a better error message than 'no such builtin macro'.
match mem::replace(builtin_macro, BuiltinMacroState::AlreadySeen(item.span)) {
BuiltinMacroState::NotYetSeen(builtin_ext) => {
ext.kind = builtin_ext;
rule_spans = Vec::new();
}
BuiltinMacroState::AlreadySeen(span) => {
struct_span_code_err!(
self.dcx(),
item.span,
E0773,
"attempted to define built-in macro more than once"
)
.with_span_note(span, "previously defined here")
.emit();
}
}
} else {
let msg = format!("cannot find a built-in macro with name `{}`", item.ident);
self.dcx().span_err(item.span, msg);
}
}
let ItemKind::MacroDef(def) = &item.kind else { unreachable!() };
MacroData { ext: Lrc::new(ext), rule_spans, macro_rules: def.macro_rules }
}
fn path_accessible(
&mut self,
expn_id: LocalExpnId,
path: &ast::Path,
namespaces: &[Namespace],
) -> Result<bool, Indeterminate> {
let span = path.span;
let path = &Segment::from_path(path);
let parent_scope = self.invocation_parent_scopes[&expn_id];
let mut indeterminate = false;
for ns in namespaces {
match self.maybe_resolve_path(path, Some(*ns), &parent_scope) {
PathResult::Module(ModuleOrUniformRoot::Module(_)) => return Ok(true),
PathResult::NonModule(partial_res) if partial_res.unresolved_segments() == 0 => {
return Ok(true);
}
PathResult::NonModule(..) |
// HACK(Urgau): This shouldn't be necessary
PathResult::Failed { is_error_from_last_segment: false, .. } => {
self.dcx()
.emit_err(errors::CfgAccessibleUnsure { span });
// If we get a partially resolved NonModule in one namespace, we should get the
// same result in any other namespaces, so we can return early.
return Ok(false);
}
PathResult::Indeterminate => indeterminate = true,
// We can only be sure that a path doesn't exist after having tested all the
// possibilities, only at that time we can return false.
PathResult::Failed { .. } => {}
PathResult::Module(_) => panic!("unexpected path resolution"),
}
}
if indeterminate {
return Err(Indeterminate);
}
Ok(false)
}
}
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