use std::ops::Deref; use std::path::PathBuf; use std::rc::Rc; use std::sync::Arc; use std::{iter, mem}; use rustc_ast as ast; use rustc_ast::mut_visit::*; use rustc_ast::ptr::P; use rustc_ast::token::{self, Delimiter}; use rustc_ast::tokenstream::TokenStream; use rustc_ast::visit::{self, AssocCtxt, Visitor, VisitorResult, try_visit, walk_list}; use rustc_ast::{ AssocItemKind, AstNodeWrapper, AttrArgs, AttrStyle, AttrVec, ExprKind, ForeignItemKind, HasAttrs, HasNodeId, Inline, ItemKind, MacStmtStyle, MetaItemInner, MetaItemKind, ModKind, NodeId, PatKind, StmtKind, TyKind, }; use rustc_ast_pretty::pprust; use rustc_data_structures::flat_map_in_place::FlatMapInPlace; use rustc_errors::PResult; use rustc_feature::Features; use rustc_parse::parser::{ AttemptLocalParseRecovery, CommaRecoveryMode, ForceCollect, Parser, RecoverColon, RecoverComma, token_descr, }; use rustc_parse::validate_attr; use rustc_session::lint::BuiltinLintDiag; use rustc_session::lint::builtin::{UNUSED_ATTRIBUTES, UNUSED_DOC_COMMENTS}; use rustc_session::parse::feature_err; use rustc_session::{Limit, Session}; use rustc_span::hygiene::SyntaxContext; use rustc_span::{ErrorGuaranteed, FileName, Ident, LocalExpnId, Span, sym}; use smallvec::SmallVec; use crate::base::*; use crate::config::StripUnconfigured; use crate::errors::{ EmptyDelegationMac, GlobDelegationOutsideImpls, GlobDelegationTraitlessQpath, IncompleteParse, RecursionLimitReached, RemoveExprNotSupported, RemoveNodeNotSupported, UnsupportedKeyValue, WrongFragmentKind, }; use crate::fluent_generated; use crate::mbe::diagnostics::annotate_err_with_kind; use crate::module::{ DirOwnership, ParsedExternalMod, mod_dir_path, mod_file_path_from_attr, parse_external_mod, }; use crate::placeholders::{PlaceholderExpander, placeholder}; macro_rules! ast_fragments { ( $($Kind:ident($AstTy:ty) { $kind_name:expr; $(one fn $mut_visit_ast:ident; fn $visit_ast:ident;)? $(many fn $flat_map_ast_elt:ident; fn $visit_ast_elt:ident($($args:tt)*);)? fn $make_ast:ident; })* ) => { /// A fragment of AST that can be produced by a single macro expansion. /// Can also serve as an input and intermediate result for macro expansion operations. pub enum AstFragment { OptExpr(Option>), MethodReceiverExpr(P), $($Kind($AstTy),)* } /// "Discriminant" of an AST fragment. #[derive(Copy, Clone, PartialEq, Eq)] pub enum AstFragmentKind { OptExpr, MethodReceiverExpr, $($Kind,)* } impl AstFragmentKind { pub fn name(self) -> &'static str { match self { AstFragmentKind::OptExpr => "expression", AstFragmentKind::MethodReceiverExpr => "expression", $(AstFragmentKind::$Kind => $kind_name,)* } } fn make_from<'a>(self, result: Box) -> Option { match self { AstFragmentKind::OptExpr => result.make_expr().map(Some).map(AstFragment::OptExpr), AstFragmentKind::MethodReceiverExpr => result.make_expr().map(AstFragment::MethodReceiverExpr), $(AstFragmentKind::$Kind => result.$make_ast().map(AstFragment::$Kind),)* } } } impl AstFragment { fn add_placeholders(&mut self, placeholders: &[NodeId]) { if placeholders.is_empty() { return; } match self { $($(AstFragment::$Kind(ast) => ast.extend(placeholders.iter().flat_map(|id| { ${ignore($flat_map_ast_elt)} placeholder(AstFragmentKind::$Kind, *id, None).$make_ast() })),)?)* _ => panic!("unexpected AST fragment kind") } } pub(crate) fn make_opt_expr(self) -> Option> { match self { AstFragment::OptExpr(expr) => expr, _ => panic!("AstFragment::make_* called on the wrong kind of fragment"), } } pub(crate) fn make_method_receiver_expr(self) -> P { match self { AstFragment::MethodReceiverExpr(expr) => expr, _ => panic!("AstFragment::make_* called on the wrong kind of fragment"), } } $(pub fn $make_ast(self) -> $AstTy { match self { AstFragment::$Kind(ast) => ast, _ => panic!("AstFragment::make_* called on the wrong kind of fragment"), } })* fn make_ast(self) -> T::OutputTy { T::fragment_to_output(self) } pub(crate) fn mut_visit_with(&mut self, vis: &mut F) { match self { AstFragment::OptExpr(opt_expr) => { visit_clobber(opt_expr, |opt_expr| { if let Some(expr) = opt_expr { vis.filter_map_expr(expr) } else { None } }); } AstFragment::MethodReceiverExpr(expr) => vis.visit_method_receiver_expr(expr), $($(AstFragment::$Kind(ast) => vis.$mut_visit_ast(ast),)?)* $($(AstFragment::$Kind(ast) => ast.flat_map_in_place(|ast| vis.$flat_map_ast_elt(ast, $($args)*)),)?)* } } pub fn visit_with<'a, V: Visitor<'a>>(&'a self, visitor: &mut V) -> V::Result { match self { AstFragment::OptExpr(Some(expr)) => try_visit!(visitor.visit_expr(expr)), AstFragment::OptExpr(None) => {} AstFragment::MethodReceiverExpr(expr) => try_visit!(visitor.visit_method_receiver_expr(expr)), $($(AstFragment::$Kind(ast) => try_visit!(visitor.$visit_ast(ast)),)?)* $($(AstFragment::$Kind(ast) => walk_list!(visitor, $visit_ast_elt, &ast[..], $($args)*),)?)* } V::Result::output() } } impl<'a> MacResult for crate::mbe::macro_rules::ParserAnyMacro<'a> { $(fn $make_ast(self: Box>) -> Option<$AstTy> { Some(self.make(AstFragmentKind::$Kind).$make_ast()) })* } } } ast_fragments! { Expr(P) { "expression"; one fn visit_expr; fn visit_expr; fn make_expr; } Pat(P) { "pattern"; one fn visit_pat; fn visit_pat; fn make_pat; } Ty(P) { "type"; one fn visit_ty; fn visit_ty; fn make_ty; } Stmts(SmallVec<[ast::Stmt; 1]>) { "statement"; many fn flat_map_stmt; fn visit_stmt(); fn make_stmts; } Items(SmallVec<[P; 1]>) { "item"; many fn flat_map_item; fn visit_item(); fn make_items; } TraitItems(SmallVec<[P; 1]>) { "trait item"; many fn flat_map_assoc_item; fn visit_assoc_item(AssocCtxt::Trait); fn make_trait_items; } ImplItems(SmallVec<[P; 1]>) { "impl item"; many fn flat_map_assoc_item; fn visit_assoc_item(AssocCtxt::Impl); fn make_impl_items; } ForeignItems(SmallVec<[P; 1]>) { "foreign item"; many fn flat_map_foreign_item; fn visit_foreign_item(); fn make_foreign_items; } Arms(SmallVec<[ast::Arm; 1]>) { "match arm"; many fn flat_map_arm; fn visit_arm(); fn make_arms; } ExprFields(SmallVec<[ast::ExprField; 1]>) { "field expression"; many fn flat_map_expr_field; fn visit_expr_field(); fn make_expr_fields; } PatFields(SmallVec<[ast::PatField; 1]>) { "field pattern"; many fn flat_map_pat_field; fn visit_pat_field(); fn make_pat_fields; } GenericParams(SmallVec<[ast::GenericParam; 1]>) { "generic parameter"; many fn flat_map_generic_param; fn visit_generic_param(); fn make_generic_params; } Params(SmallVec<[ast::Param; 1]>) { "function parameter"; many fn flat_map_param; fn visit_param(); fn make_params; } FieldDefs(SmallVec<[ast::FieldDef; 1]>) { "field"; many fn flat_map_field_def; fn visit_field_def(); fn make_field_defs; } Variants(SmallVec<[ast::Variant; 1]>) { "variant"; many fn flat_map_variant; fn visit_variant(); fn make_variants; } WherePredicates(SmallVec<[ast::WherePredicate; 1]>) { "where predicate"; many fn flat_map_where_predicate; fn visit_where_predicate(); fn make_where_predicates; } Crate(ast::Crate) { "crate"; one fn visit_crate; fn visit_crate; fn make_crate; } } pub enum SupportsMacroExpansion { No, Yes { supports_inner_attrs: bool }, } impl AstFragmentKind { pub(crate) fn dummy(self, span: Span, guar: ErrorGuaranteed) -> AstFragment { self.make_from(DummyResult::any(span, guar)).expect("couldn't create a dummy AST fragment") } pub fn supports_macro_expansion(self) -> SupportsMacroExpansion { match self { AstFragmentKind::OptExpr | AstFragmentKind::Expr | AstFragmentKind::MethodReceiverExpr | AstFragmentKind::Stmts | AstFragmentKind::Ty | AstFragmentKind::Pat => SupportsMacroExpansion::Yes { supports_inner_attrs: false }, AstFragmentKind::Items | AstFragmentKind::TraitItems | AstFragmentKind::ImplItems | AstFragmentKind::ForeignItems | AstFragmentKind::Crate => SupportsMacroExpansion::Yes { supports_inner_attrs: true }, AstFragmentKind::Arms | AstFragmentKind::ExprFields | AstFragmentKind::PatFields | AstFragmentKind::GenericParams | AstFragmentKind::Params | AstFragmentKind::FieldDefs | AstFragmentKind::Variants | AstFragmentKind::WherePredicates => SupportsMacroExpansion::No, } } fn expect_from_annotatables>( self, items: I, ) -> AstFragment { let mut items = items.into_iter(); match self { AstFragmentKind::Arms => { AstFragment::Arms(items.map(Annotatable::expect_arm).collect()) } AstFragmentKind::ExprFields => { AstFragment::ExprFields(items.map(Annotatable::expect_expr_field).collect()) } AstFragmentKind::PatFields => { AstFragment::PatFields(items.map(Annotatable::expect_pat_field).collect()) } AstFragmentKind::GenericParams => { AstFragment::GenericParams(items.map(Annotatable::expect_generic_param).collect()) } AstFragmentKind::Params => { AstFragment::Params(items.map(Annotatable::expect_param).collect()) } AstFragmentKind::FieldDefs => { AstFragment::FieldDefs(items.map(Annotatable::expect_field_def).collect()) } AstFragmentKind::Variants => { AstFragment::Variants(items.map(Annotatable::expect_variant).collect()) } AstFragmentKind::WherePredicates => AstFragment::WherePredicates( items.map(Annotatable::expect_where_predicate).collect(), ), AstFragmentKind::Items => { AstFragment::Items(items.map(Annotatable::expect_item).collect()) } AstFragmentKind::ImplItems => { AstFragment::ImplItems(items.map(Annotatable::expect_impl_item).collect()) } AstFragmentKind::TraitItems => { AstFragment::TraitItems(items.map(Annotatable::expect_trait_item).collect()) } AstFragmentKind::ForeignItems => { AstFragment::ForeignItems(items.map(Annotatable::expect_foreign_item).collect()) } AstFragmentKind::Stmts => { AstFragment::Stmts(items.map(Annotatable::expect_stmt).collect()) } AstFragmentKind::Expr => AstFragment::Expr( items.next().expect("expected exactly one expression").expect_expr(), ), AstFragmentKind::MethodReceiverExpr => AstFragment::MethodReceiverExpr( items.next().expect("expected exactly one expression").expect_expr(), ), AstFragmentKind::OptExpr => { AstFragment::OptExpr(items.next().map(Annotatable::expect_expr)) } AstFragmentKind::Crate => { AstFragment::Crate(items.next().expect("expected exactly one crate").expect_crate()) } AstFragmentKind::Pat | AstFragmentKind::Ty => { panic!("patterns and types aren't annotatable") } } } } pub struct Invocation { pub kind: InvocationKind, pub fragment_kind: AstFragmentKind, pub expansion_data: ExpansionData, } pub enum InvocationKind { Bang { mac: P, span: Span, }, Attr { attr: ast::Attribute, // Re-insertion position for inert attributes. pos: usize, item: Annotatable, // Required for resolving derive helper attributes. derives: Vec, }, Derive { path: ast::Path, is_const: bool, item: Annotatable, }, GlobDelegation { item: P, }, } impl InvocationKind { fn placeholder_visibility(&self) -> Option { // HACK: For unnamed fields placeholders should have the same visibility as the actual // fields because for tuple structs/variants resolve determines visibilities of their // constructor using these field visibilities before attributes on them are expanded. // The assumption is that the attribute expansion cannot change field visibilities, // and it holds because only inert attributes are supported in this position. match self { InvocationKind::Attr { item: Annotatable::FieldDef(field), .. } | InvocationKind::Derive { item: Annotatable::FieldDef(field), .. } if field.ident.is_none() => { Some(field.vis.clone()) } _ => None, } } } impl Invocation { pub fn span(&self) -> Span { match &self.kind { InvocationKind::Bang { span, .. } => *span, InvocationKind::Attr { attr, .. } => attr.span, InvocationKind::Derive { path, .. } => path.span, InvocationKind::GlobDelegation { item } => item.span, } } fn span_mut(&mut self) -> &mut Span { match &mut self.kind { InvocationKind::Bang { span, .. } => span, InvocationKind::Attr { attr, .. } => &mut attr.span, InvocationKind::Derive { path, .. } => &mut path.span, InvocationKind::GlobDelegation { item } => &mut item.span, } } } pub struct MacroExpander<'a, 'b> { pub cx: &'a mut ExtCtxt<'b>, monotonic: bool, // cf. `cx.monotonic_expander()` } impl<'a, 'b> MacroExpander<'a, 'b> { pub fn new(cx: &'a mut ExtCtxt<'b>, monotonic: bool) -> Self { MacroExpander { cx, monotonic } } pub fn expand_crate(&mut self, krate: ast::Crate) -> ast::Crate { let file_path = match self.cx.source_map().span_to_filename(krate.spans.inner_span) { FileName::Real(name) => name .into_local_path() .expect("attempting to resolve a file path in an external file"), other => PathBuf::from(other.prefer_local().to_string()), }; let dir_path = file_path.parent().unwrap_or(&file_path).to_owned(); self.cx.root_path = dir_path.clone(); self.cx.current_expansion.module = Rc::new(ModuleData { mod_path: vec![Ident::from_str(&self.cx.ecfg.crate_name)], file_path_stack: vec![file_path], dir_path, }); let krate = self.fully_expand_fragment(AstFragment::Crate(krate)).make_crate(); assert_eq!(krate.id, ast::CRATE_NODE_ID); self.cx.trace_macros_diag(); krate } /// Recursively expand all macro invocations in this AST fragment. pub fn fully_expand_fragment(&mut self, input_fragment: AstFragment) -> AstFragment { let orig_expansion_data = self.cx.current_expansion.clone(); let orig_force_mode = self.cx.force_mode; // Collect all macro invocations and replace them with placeholders. let (mut fragment_with_placeholders, mut invocations) = self.collect_invocations(input_fragment, &[]); // Optimization: if we resolve all imports now, // we'll be able to immediately resolve most of imported macros. self.resolve_imports(); // Resolve paths in all invocations and produce output expanded fragments for them, but // do not insert them into our input AST fragment yet, only store in `expanded_fragments`. // The output fragments also go through expansion recursively until no invocations are left. // Unresolved macros produce dummy outputs as a recovery measure. invocations.reverse(); let mut expanded_fragments = Vec::new(); let mut undetermined_invocations = Vec::new(); let (mut progress, mut force) = (false, !self.monotonic); loop { let Some((invoc, ext)) = invocations.pop() else { self.resolve_imports(); if undetermined_invocations.is_empty() { break; } invocations = mem::take(&mut undetermined_invocations); force = !progress; progress = false; if force && self.monotonic { self.cx.dcx().span_delayed_bug( invocations.last().unwrap().0.span(), "expansion entered force mode without producing any errors", ); } continue; }; let ext = match ext { Some(ext) => ext, None => { let eager_expansion_root = if self.monotonic { invoc.expansion_data.id } else { orig_expansion_data.id }; match self.cx.resolver.resolve_macro_invocation( &invoc, eager_expansion_root, force, ) { Ok(ext) => ext, Err(Indeterminate) => { // Cannot resolve, will retry this invocation later. undetermined_invocations.push((invoc, None)); continue; } } } }; let ExpansionData { depth, id: expn_id, .. } = invoc.expansion_data; let depth = depth - orig_expansion_data.depth; self.cx.current_expansion = invoc.expansion_data.clone(); self.cx.force_mode = force; let fragment_kind = invoc.fragment_kind; match self.expand_invoc(invoc, &ext.kind) { ExpandResult::Ready(fragment) => { let mut derive_invocations = Vec::new(); let derive_placeholders = self .cx .resolver .take_derive_resolutions(expn_id) .map(|derives| { derive_invocations.reserve(derives.len()); derives .into_iter() .map(|DeriveResolution { path, item, exts: _, is_const }| { // FIXME: Consider using the derive resolutions (`_exts`) // instead of enqueuing the derives to be resolved again later. let expn_id = LocalExpnId::fresh_empty(); derive_invocations.push(( Invocation { kind: InvocationKind::Derive { path, item, is_const }, fragment_kind, expansion_data: ExpansionData { id: expn_id, ..self.cx.current_expansion.clone() }, }, None, )); NodeId::placeholder_from_expn_id(expn_id) }) .collect::>() }) .unwrap_or_default(); let (expanded_fragment, collected_invocations) = self.collect_invocations(fragment, &derive_placeholders); // We choose to expand any derive invocations associated with this macro // invocation *before* any macro invocations collected from the output // fragment. derive_invocations.extend(collected_invocations); progress = true; if expanded_fragments.len() < depth { expanded_fragments.push(Vec::new()); } expanded_fragments[depth - 1].push((expn_id, expanded_fragment)); invocations.extend(derive_invocations.into_iter().rev()); } ExpandResult::Retry(invoc) => { if force { self.cx.dcx().span_bug( invoc.span(), "expansion entered force mode but is still stuck", ); } else { // Cannot expand, will retry this invocation later. undetermined_invocations.push((invoc, Some(ext))); } } } } self.cx.current_expansion = orig_expansion_data; self.cx.force_mode = orig_force_mode; // Finally incorporate all the expanded macros into the input AST fragment. let mut placeholder_expander = PlaceholderExpander::default(); while let Some(expanded_fragments) = expanded_fragments.pop() { for (expn_id, expanded_fragment) in expanded_fragments.into_iter().rev() { placeholder_expander .add(NodeId::placeholder_from_expn_id(expn_id), expanded_fragment); } } fragment_with_placeholders.mut_visit_with(&mut placeholder_expander); fragment_with_placeholders } fn resolve_imports(&mut self) { if self.monotonic { self.cx.resolver.resolve_imports(); } } /// Collects all macro invocations reachable at this time in this AST fragment, and replace /// them with "placeholders" - dummy macro invocations with specially crafted `NodeId`s. /// Then call into resolver that builds a skeleton ("reduced graph") of the fragment and /// prepares data for resolving paths of macro invocations. fn collect_invocations( &mut self, mut fragment: AstFragment, extra_placeholders: &[NodeId], ) -> (AstFragment, Vec<(Invocation, Option>)>) { // Resolve `$crate`s in the fragment for pretty-printing. self.cx.resolver.resolve_dollar_crates(); let mut invocations = { let mut collector = InvocationCollector { // Non-derive macro invocations cannot see the results of cfg expansion - they // will either be removed along with the item, or invoked before the cfg/cfg_attr // attribute is expanded. Therefore, we don't need to configure the tokens // Derive macros *can* see the results of cfg-expansion - they are handled // specially in `fully_expand_fragment` cx: self.cx, invocations: Vec::new(), monotonic: self.monotonic, }; fragment.mut_visit_with(&mut collector); fragment.add_placeholders(extra_placeholders); collector.invocations }; if self.monotonic { self.cx .resolver .visit_ast_fragment_with_placeholders(self.cx.current_expansion.id, &fragment); if self.cx.sess.opts.incremental.is_some() { for (invoc, _) in invocations.iter_mut() { let expn_id = invoc.expansion_data.id; let parent_def = self.cx.resolver.invocation_parent(expn_id); let span = invoc.span_mut(); *span = span.with_parent(Some(parent_def)); } } } (fragment, invocations) } fn error_recursion_limit_reached(&mut self) -> ErrorGuaranteed { let expn_data = self.cx.current_expansion.id.expn_data(); let suggested_limit = match self.cx.ecfg.recursion_limit { Limit(0) => Limit(2), limit => limit * 2, }; let guar = self.cx.dcx().emit_err(RecursionLimitReached { span: expn_data.call_site, descr: expn_data.kind.descr(), suggested_limit, crate_name: &self.cx.ecfg.crate_name, }); self.cx.trace_macros_diag(); guar } /// A macro's expansion does not fit in this fragment kind. /// For example, a non-type macro in a type position. fn error_wrong_fragment_kind( &mut self, kind: AstFragmentKind, mac: &ast::MacCall, span: Span, ) -> ErrorGuaranteed { let guar = self.cx.dcx().emit_err(WrongFragmentKind { span, kind: kind.name(), name: &mac.path }); self.cx.trace_macros_diag(); guar } fn expand_invoc( &mut self, invoc: Invocation, ext: &SyntaxExtensionKind, ) -> ExpandResult { let recursion_limit = match self.cx.reduced_recursion_limit { Some((limit, _)) => limit, None => self.cx.ecfg.recursion_limit, }; if !recursion_limit.value_within_limit(self.cx.current_expansion.depth) { let guar = match self.cx.reduced_recursion_limit { Some((_, guar)) => guar, None => self.error_recursion_limit_reached(), }; // Reduce the recursion limit by half each time it triggers. self.cx.reduced_recursion_limit = Some((recursion_limit / 2, guar)); return ExpandResult::Ready(invoc.fragment_kind.dummy(invoc.span(), guar)); } let (fragment_kind, span) = (invoc.fragment_kind, invoc.span()); ExpandResult::Ready(match invoc.kind { InvocationKind::Bang { mac, span } => match ext { SyntaxExtensionKind::Bang(expander) => { match expander.expand(self.cx, span, mac.args.tokens.clone()) { Ok(tok_result) => { self.parse_ast_fragment(tok_result, fragment_kind, &mac.path, span) } Err(guar) => return ExpandResult::Ready(fragment_kind.dummy(span, guar)), } } SyntaxExtensionKind::LegacyBang(expander) => { let tok_result = match expander.expand(self.cx, span, mac.args.tokens.clone()) { ExpandResult::Ready(tok_result) => tok_result, ExpandResult::Retry(_) => { // retry the original return ExpandResult::Retry(Invocation { kind: InvocationKind::Bang { mac, span }, ..invoc }); } }; let result = if let Some(result) = fragment_kind.make_from(tok_result) { result } else { let guar = self.error_wrong_fragment_kind(fragment_kind, &mac, span); fragment_kind.dummy(span, guar) }; result } _ => unreachable!(), }, InvocationKind::Attr { attr, pos, mut item, derives } => match ext { SyntaxExtensionKind::Attr(expander) => { self.gate_proc_macro_input(&item); self.gate_proc_macro_attr_item(span, &item); let tokens = match &item { // FIXME: Collect tokens and use them instead of generating // fake ones. These are unstable, so it needs to be // fixed prior to stabilization // Fake tokens when we are invoking an inner attribute, and // we are invoking it on an out-of-line module or crate. Annotatable::Crate(krate) => { rustc_parse::fake_token_stream_for_crate(&self.cx.sess.psess, krate) } Annotatable::Item(item_inner) if matches!(attr.style, AttrStyle::Inner) && matches!( item_inner.kind, ItemKind::Mod( _, ModKind::Unloaded | ModKind::Loaded(_, Inline::No, _, _), ) ) => { rustc_parse::fake_token_stream_for_item(&self.cx.sess.psess, item_inner) } _ => item.to_tokens(), }; let attr_item = attr.unwrap_normal_item(); if let AttrArgs::Eq { .. } = attr_item.args { self.cx.dcx().emit_err(UnsupportedKeyValue { span }); } let inner_tokens = attr_item.args.inner_tokens(); match expander.expand(self.cx, span, inner_tokens, tokens) { Ok(tok_result) => self.parse_ast_fragment( tok_result, fragment_kind, &attr_item.path, span, ), Err(guar) => return ExpandResult::Ready(fragment_kind.dummy(span, guar)), } } SyntaxExtensionKind::LegacyAttr(expander) => { match validate_attr::parse_meta(&self.cx.sess.psess, &attr) { Ok(meta) => { let items = match expander.expand(self.cx, span, &meta, item, false) { ExpandResult::Ready(items) => items, ExpandResult::Retry(item) => { // Reassemble the original invocation for retrying. return ExpandResult::Retry(Invocation { kind: InvocationKind::Attr { attr, pos, item, derives }, ..invoc }); } }; if matches!( fragment_kind, AstFragmentKind::Expr | AstFragmentKind::MethodReceiverExpr ) && items.is_empty() { let guar = self.cx.dcx().emit_err(RemoveExprNotSupported { span }); fragment_kind.dummy(span, guar) } else { fragment_kind.expect_from_annotatables(items) } } Err(err) => { let guar = err.emit(); fragment_kind.dummy(span, guar) } } } SyntaxExtensionKind::NonMacroAttr => { self.cx.expanded_inert_attrs.mark(&attr); item.visit_attrs(|attrs| attrs.insert(pos, attr)); fragment_kind.expect_from_annotatables(iter::once(item)) } _ => unreachable!(), }, InvocationKind::Derive { path, item, is_const } => match ext { SyntaxExtensionKind::Derive(expander) | SyntaxExtensionKind::LegacyDerive(expander) => { if let SyntaxExtensionKind::Derive(..) = ext { self.gate_proc_macro_input(&item); } // The `MetaItem` representing the trait to derive can't // have an unsafe around it (as of now). let meta = ast::MetaItem { unsafety: ast::Safety::Default, kind: MetaItemKind::Word, span, path, }; let items = match expander.expand(self.cx, span, &meta, item, is_const) { ExpandResult::Ready(items) => items, ExpandResult::Retry(item) => { // Reassemble the original invocation for retrying. return ExpandResult::Retry(Invocation { kind: InvocationKind::Derive { path: meta.path, item, is_const }, ..invoc }); } }; fragment_kind.expect_from_annotatables(items) } _ => unreachable!(), }, InvocationKind::GlobDelegation { item } => { let AssocItemKind::DelegationMac(deleg) = &item.kind else { unreachable!() }; let suffixes = match ext { SyntaxExtensionKind::GlobDelegation(expander) => match expander.expand(self.cx) { ExpandResult::Ready(suffixes) => suffixes, ExpandResult::Retry(()) => { // Reassemble the original invocation for retrying. return ExpandResult::Retry(Invocation { kind: InvocationKind::GlobDelegation { item }, ..invoc }); } }, SyntaxExtensionKind::LegacyBang(..) => { let msg = "expanded a dummy glob delegation"; let guar = self.cx.dcx().span_delayed_bug(span, msg); return ExpandResult::Ready(fragment_kind.dummy(span, guar)); } _ => unreachable!(), }; type Node = AstNodeWrapper, ImplItemTag>; let single_delegations = build_single_delegations::( self.cx, deleg, &item, &suffixes, item.span, true, ); fragment_kind.expect_from_annotatables( single_delegations.map(|item| Annotatable::AssocItem(P(item), AssocCtxt::Impl)), ) } }) } #[allow(rustc::untranslatable_diagnostic)] // FIXME: make this translatable fn gate_proc_macro_attr_item(&self, span: Span, item: &Annotatable) { let kind = match item { Annotatable::Item(_) | Annotatable::AssocItem(..) | Annotatable::ForeignItem(_) | Annotatable::Crate(..) => return, Annotatable::Stmt(stmt) => { // Attributes are stable on item statements, // but unstable on all other kinds of statements if stmt.is_item() { return; } "statements" } Annotatable::Expr(_) => "expressions", Annotatable::Arm(..) | Annotatable::ExprField(..) | Annotatable::PatField(..) | Annotatable::GenericParam(..) | Annotatable::Param(..) | Annotatable::FieldDef(..) | Annotatable::Variant(..) | Annotatable::WherePredicate(..) => panic!("unexpected annotatable"), }; if self.cx.ecfg.features.proc_macro_hygiene() { return; } feature_err( &self.cx.sess, sym::proc_macro_hygiene, span, format!("custom attributes cannot be applied to {kind}"), ) .emit(); } fn gate_proc_macro_input(&self, annotatable: &Annotatable) { struct GateProcMacroInput<'a> { sess: &'a Session, } impl<'ast, 'a> Visitor<'ast> for GateProcMacroInput<'a> { fn visit_item(&mut self, item: &'ast ast::Item) { match &item.kind { ItemKind::Mod(_, mod_kind) if !matches!(mod_kind, ModKind::Loaded(_, Inline::Yes, _, _)) => { feature_err( self.sess, sym::proc_macro_hygiene, item.span, fluent_generated::expand_non_inline_modules_in_proc_macro_input_are_unstable, ) .emit(); } _ => {} } visit::walk_item(self, item); } } if !self.cx.ecfg.features.proc_macro_hygiene() { annotatable.visit_with(&mut GateProcMacroInput { sess: &self.cx.sess }); } } fn parse_ast_fragment( &mut self, toks: TokenStream, kind: AstFragmentKind, path: &ast::Path, span: Span, ) -> AstFragment { let mut parser = self.cx.new_parser_from_tts(toks); match parse_ast_fragment(&mut parser, kind) { Ok(fragment) => { ensure_complete_parse(&parser, path, kind.name(), span); fragment } Err(mut err) => { if err.span.is_dummy() { err.span(span); } annotate_err_with_kind(&mut err, kind, span); let guar = err.emit(); self.cx.trace_macros_diag(); kind.dummy(span, guar) } } } } pub fn parse_ast_fragment<'a>( this: &mut Parser<'a>, kind: AstFragmentKind, ) -> PResult<'a, AstFragment> { Ok(match kind { AstFragmentKind::Items => { let mut items = SmallVec::new(); while let Some(item) = this.parse_item(ForceCollect::No)? { items.push(item); } AstFragment::Items(items) } AstFragmentKind::TraitItems => { let mut items = SmallVec::new(); while let Some(item) = this.parse_trait_item(ForceCollect::No)? { items.extend(item); } AstFragment::TraitItems(items) } AstFragmentKind::ImplItems => { let mut items = SmallVec::new(); while let Some(item) = this.parse_impl_item(ForceCollect::No)? { items.extend(item); } AstFragment::ImplItems(items) } AstFragmentKind::ForeignItems => { let mut items = SmallVec::new(); while let Some(item) = this.parse_foreign_item(ForceCollect::No)? { items.extend(item); } AstFragment::ForeignItems(items) } AstFragmentKind::Stmts => { let mut stmts = SmallVec::new(); // Won't make progress on a `}`. while this.token != token::Eof && this.token != token::CloseDelim(Delimiter::Brace) { if let Some(stmt) = this.parse_full_stmt(AttemptLocalParseRecovery::Yes)? { stmts.push(stmt); } } AstFragment::Stmts(stmts) } AstFragmentKind::Expr => AstFragment::Expr(this.parse_expr()?), AstFragmentKind::MethodReceiverExpr => AstFragment::MethodReceiverExpr(this.parse_expr()?), AstFragmentKind::OptExpr => { if this.token != token::Eof { AstFragment::OptExpr(Some(this.parse_expr()?)) } else { AstFragment::OptExpr(None) } } AstFragmentKind::Ty => AstFragment::Ty(this.parse_ty()?), AstFragmentKind::Pat => AstFragment::Pat(this.parse_pat_allow_top_guard( None, RecoverComma::No, RecoverColon::Yes, CommaRecoveryMode::LikelyTuple, )?), AstFragmentKind::Crate => AstFragment::Crate(this.parse_crate_mod()?), AstFragmentKind::Arms | AstFragmentKind::ExprFields | AstFragmentKind::PatFields | AstFragmentKind::GenericParams | AstFragmentKind::Params | AstFragmentKind::FieldDefs | AstFragmentKind::Variants | AstFragmentKind::WherePredicates => panic!("unexpected AST fragment kind"), }) } pub(crate) fn ensure_complete_parse<'a>( parser: &Parser<'a>, macro_path: &ast::Path, kind_name: &str, span: Span, ) { if parser.token != token::Eof { let descr = token_descr(&parser.token); // Avoid emitting backtrace info twice. let def_site_span = parser.token.span.with_ctxt(SyntaxContext::root()); let semi_span = parser.psess.source_map().next_point(span); let add_semicolon = match &parser.psess.source_map().span_to_snippet(semi_span) { Ok(snippet) if &snippet[..] != ";" && kind_name == "expression" => { Some(span.shrink_to_hi()) } _ => None, }; let expands_to_match_arm = kind_name == "pattern" && parser.token == token::FatArrow; parser.dcx().emit_err(IncompleteParse { span: def_site_span, descr, label_span: span, macro_path, kind_name, expands_to_match_arm, add_semicolon, }); } } /// Wraps a call to `walk_*` / `walk_flat_map_*` /// for an AST node that supports attributes /// (see the `Annotatable` enum) /// This method assigns a `NodeId`, and sets that `NodeId` /// as our current 'lint node id'. If a macro call is found /// inside this AST node, we will use this AST node's `NodeId` /// to emit lints associated with that macro (allowing /// `#[allow]` / `#[deny]` to be applied close to /// the macro invocation). /// /// Do *not* call this for a macro AST node /// (e.g. `ExprKind::MacCall`) - we cannot emit lints /// at these AST nodes, since they are removed and /// replaced with the result of macro expansion. /// /// All other `NodeId`s are assigned by `visit_id`. /// * `self` is the 'self' parameter for the current method, /// * `id` is a mutable reference to the `NodeId` field /// of the current AST node. /// * `closure` is a closure that executes the /// `walk_*` / `walk_flat_map_*` method /// for the current AST node. macro_rules! assign_id { ($self:ident, $id:expr, $closure:expr) => {{ let old_id = $self.cx.current_expansion.lint_node_id; if $self.monotonic { debug_assert_eq!(*$id, ast::DUMMY_NODE_ID); let new_id = $self.cx.resolver.next_node_id(); *$id = new_id; $self.cx.current_expansion.lint_node_id = new_id; } let ret = ($closure)(); $self.cx.current_expansion.lint_node_id = old_id; ret }}; } enum AddSemicolon { Yes, No, } /// A trait implemented for all `AstFragment` nodes and providing all pieces /// of functionality used by `InvocationCollector`. trait InvocationCollectorNode: HasAttrs + HasNodeId + Sized { type OutputTy = SmallVec<[Self; 1]>; type AttrsTy: Deref = ast::AttrVec; type ItemKind = ItemKind; const KIND: AstFragmentKind; fn to_annotatable(self) -> Annotatable; fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy; fn descr() -> &'static str { unreachable!() } fn walk_flat_map(self, _visitor: &mut V) -> Self::OutputTy { unreachable!() } fn walk(&mut self, _visitor: &mut V) { unreachable!() } fn is_mac_call(&self) -> bool { false } fn take_mac_call(self) -> (P, Self::AttrsTy, AddSemicolon) { unreachable!() } fn delegation(&self) -> Option<(&ast::DelegationMac, &ast::Item)> { None } fn delegation_item_kind(_deleg: Box) -> Self::ItemKind { unreachable!() } fn from_item(_item: ast::Item) -> Self { unreachable!() } fn flatten_outputs(_outputs: impl Iterator) -> Self::OutputTy { unreachable!() } fn pre_flat_map_node_collect_attr(_cfg: &StripUnconfigured<'_>, _attr: &ast::Attribute) {} fn post_flat_map_node_collect_bang(_output: &mut Self::OutputTy, _add_semicolon: AddSemicolon) { } fn wrap_flat_map_node_walk_flat_map( node: Self, collector: &mut InvocationCollector<'_, '_>, walk_flat_map: impl FnOnce(Self, &mut InvocationCollector<'_, '_>) -> Self::OutputTy, ) -> Result { Ok(walk_flat_map(node, collector)) } fn expand_cfg_false( &mut self, collector: &mut InvocationCollector<'_, '_>, _pos: usize, span: Span, ) { collector.cx.dcx().emit_err(RemoveNodeNotSupported { span, descr: Self::descr() }); } /// All of the names (items) declared by this node. /// This is an approximation and should only be used for diagnostics. fn declared_names(&self) -> Vec { vec![] } } impl InvocationCollectorNode for P { const KIND: AstFragmentKind = AstFragmentKind::Items; fn to_annotatable(self) -> Annotatable { Annotatable::Item(self) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_items() } fn walk_flat_map(self, visitor: &mut V) -> Self::OutputTy { walk_flat_map_item(visitor, self) } fn is_mac_call(&self) -> bool { matches!(self.kind, ItemKind::MacCall(..)) } fn take_mac_call(self) -> (P, Self::AttrsTy, AddSemicolon) { let node = self.into_inner(); match node.kind { ItemKind::MacCall(mac) => (mac, node.attrs, AddSemicolon::No), _ => unreachable!(), } } fn delegation(&self) -> Option<(&ast::DelegationMac, &ast::Item)> { match &self.kind { ItemKind::DelegationMac(deleg) => Some((deleg, self)), _ => None, } } fn delegation_item_kind(deleg: Box) -> Self::ItemKind { ItemKind::Delegation(deleg) } fn from_item(item: ast::Item) -> Self { P(item) } fn flatten_outputs(items: impl Iterator) -> Self::OutputTy { items.flatten().collect() } fn wrap_flat_map_node_walk_flat_map( mut node: Self, collector: &mut InvocationCollector<'_, '_>, walk_flat_map: impl FnOnce(Self, &mut InvocationCollector<'_, '_>) -> Self::OutputTy, ) -> Result { if !matches!(node.kind, ItemKind::Mod(..)) { return Ok(walk_flat_map(node, collector)); } // Work around borrow checker not seeing through `P`'s deref. let (ident, span, mut attrs) = (node.ident, node.span, mem::take(&mut node.attrs)); let ItemKind::Mod(_, mod_kind) = &mut node.kind else { unreachable!() }; let ecx = &mut collector.cx; let (file_path, dir_path, dir_ownership) = match mod_kind { ModKind::Loaded(_, inline, _, _) => { // Inline `mod foo { ... }`, but we still need to push directories. let (dir_path, dir_ownership) = mod_dir_path( ecx.sess, ident, &attrs, &ecx.current_expansion.module, ecx.current_expansion.dir_ownership, *inline, ); // If the module was parsed from an external file, recover its path. // This lets `parse_external_mod` catch cycles if it's self-referential. let file_path = match inline { Inline::Yes => None, Inline::No => mod_file_path_from_attr(ecx.sess, &attrs, &dir_path), }; node.attrs = attrs; (file_path, dir_path, dir_ownership) } ModKind::Unloaded => { // We have an outline `mod foo;` so we need to parse the file. let old_attrs_len = attrs.len(); let ParsedExternalMod { items, spans, file_path, dir_path, dir_ownership, had_parse_error, } = parse_external_mod( ecx.sess, ident, span, &ecx.current_expansion.module, ecx.current_expansion.dir_ownership, &mut attrs, ); if let Some(lint_store) = ecx.lint_store { lint_store.pre_expansion_lint( ecx.sess, ecx.ecfg.features, ecx.resolver.registered_tools(), ecx.current_expansion.lint_node_id, &attrs, &items, ident.name, ); } *mod_kind = ModKind::Loaded(items, Inline::No, spans, had_parse_error); node.attrs = attrs; if node.attrs.len() > old_attrs_len { // If we loaded an out-of-line module and added some inner attributes, // then we need to re-configure it and re-collect attributes for // resolution and expansion. return Err(node); } (Some(file_path), dir_path, dir_ownership) } }; // Set the module info before we flat map. let mut module = ecx.current_expansion.module.with_dir_path(dir_path); module.mod_path.push(ident); if let Some(file_path) = file_path { module.file_path_stack.push(file_path); } let orig_module = mem::replace(&mut ecx.current_expansion.module, Rc::new(module)); let orig_dir_ownership = mem::replace(&mut ecx.current_expansion.dir_ownership, dir_ownership); let res = Ok(walk_flat_map(node, collector)); collector.cx.current_expansion.dir_ownership = orig_dir_ownership; collector.cx.current_expansion.module = orig_module; res } fn declared_names(&self) -> Vec { if let ItemKind::Use(ut) = &self.kind { fn collect_use_tree_leaves(ut: &ast::UseTree, idents: &mut Vec) { match &ut.kind { ast::UseTreeKind::Glob => {} ast::UseTreeKind::Simple(_) => idents.push(ut.ident()), ast::UseTreeKind::Nested { items, .. } => { for (ut, _) in items { collect_use_tree_leaves(ut, idents); } } } } let mut idents = Vec::new(); collect_use_tree_leaves(ut, &mut idents); return idents; } vec![self.ident] } } struct TraitItemTag; impl InvocationCollectorNode for AstNodeWrapper, TraitItemTag> { type OutputTy = SmallVec<[P; 1]>; type ItemKind = AssocItemKind; const KIND: AstFragmentKind = AstFragmentKind::TraitItems; fn to_annotatable(self) -> Annotatable { Annotatable::AssocItem(self.wrapped, AssocCtxt::Trait) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_trait_items() } fn walk_flat_map(self, visitor: &mut V) -> Self::OutputTy { walk_flat_map_assoc_item(visitor, self.wrapped, AssocCtxt::Trait) } fn is_mac_call(&self) -> bool { matches!(self.wrapped.kind, AssocItemKind::MacCall(..)) } fn take_mac_call(self) -> (P, Self::AttrsTy, AddSemicolon) { let item = self.wrapped.into_inner(); match item.kind { AssocItemKind::MacCall(mac) => (mac, item.attrs, AddSemicolon::No), _ => unreachable!(), } } fn delegation(&self) -> Option<(&ast::DelegationMac, &ast::Item)> { match &self.wrapped.kind { AssocItemKind::DelegationMac(deleg) => Some((deleg, &self.wrapped)), _ => None, } } fn delegation_item_kind(deleg: Box) -> Self::ItemKind { AssocItemKind::Delegation(deleg) } fn from_item(item: ast::Item) -> Self { AstNodeWrapper::new(P(item), TraitItemTag) } fn flatten_outputs(items: impl Iterator) -> Self::OutputTy { items.flatten().collect() } } struct ImplItemTag; impl InvocationCollectorNode for AstNodeWrapper, ImplItemTag> { type OutputTy = SmallVec<[P; 1]>; type ItemKind = AssocItemKind; const KIND: AstFragmentKind = AstFragmentKind::ImplItems; fn to_annotatable(self) -> Annotatable { Annotatable::AssocItem(self.wrapped, AssocCtxt::Impl) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_impl_items() } fn walk_flat_map(self, visitor: &mut V) -> Self::OutputTy { walk_flat_map_assoc_item(visitor, self.wrapped, AssocCtxt::Impl) } fn is_mac_call(&self) -> bool { matches!(self.wrapped.kind, AssocItemKind::MacCall(..)) } fn take_mac_call(self) -> (P, Self::AttrsTy, AddSemicolon) { let item = self.wrapped.into_inner(); match item.kind { AssocItemKind::MacCall(mac) => (mac, item.attrs, AddSemicolon::No), _ => unreachable!(), } } fn delegation(&self) -> Option<(&ast::DelegationMac, &ast::Item)> { match &self.wrapped.kind { AssocItemKind::DelegationMac(deleg) => Some((deleg, &self.wrapped)), _ => None, } } fn delegation_item_kind(deleg: Box) -> Self::ItemKind { AssocItemKind::Delegation(deleg) } fn from_item(item: ast::Item) -> Self { AstNodeWrapper::new(P(item), ImplItemTag) } fn flatten_outputs(items: impl Iterator) -> Self::OutputTy { items.flatten().collect() } } impl InvocationCollectorNode for P { const KIND: AstFragmentKind = AstFragmentKind::ForeignItems; fn to_annotatable(self) -> Annotatable { Annotatable::ForeignItem(self) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_foreign_items() } fn walk_flat_map(self, visitor: &mut V) -> Self::OutputTy { walk_flat_map_foreign_item(visitor, self) } fn is_mac_call(&self) -> bool { matches!(self.kind, ForeignItemKind::MacCall(..)) } fn take_mac_call(self) -> (P, Self::AttrsTy, AddSemicolon) { let node = self.into_inner(); match node.kind { ForeignItemKind::MacCall(mac) => (mac, node.attrs, AddSemicolon::No), _ => unreachable!(), } } } impl InvocationCollectorNode for ast::Variant { const KIND: AstFragmentKind = AstFragmentKind::Variants; fn to_annotatable(self) -> Annotatable { Annotatable::Variant(self) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_variants() } fn walk_flat_map(self, visitor: &mut V) -> Self::OutputTy { walk_flat_map_variant(visitor, self) } } impl InvocationCollectorNode for ast::WherePredicate { const KIND: AstFragmentKind = AstFragmentKind::WherePredicates; fn to_annotatable(self) -> Annotatable { Annotatable::WherePredicate(self) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_where_predicates() } fn walk_flat_map(self, visitor: &mut V) -> Self::OutputTy { walk_flat_map_where_predicate(visitor, self) } } impl InvocationCollectorNode for ast::FieldDef { const KIND: AstFragmentKind = AstFragmentKind::FieldDefs; fn to_annotatable(self) -> Annotatable { Annotatable::FieldDef(self) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_field_defs() } fn walk_flat_map(self, visitor: &mut V) -> Self::OutputTy { walk_flat_map_field_def(visitor, self) } } impl InvocationCollectorNode for ast::PatField { const KIND: AstFragmentKind = AstFragmentKind::PatFields; fn to_annotatable(self) -> Annotatable { Annotatable::PatField(self) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_pat_fields() } fn walk_flat_map(self, visitor: &mut V) -> Self::OutputTy { walk_flat_map_pat_field(visitor, self) } } impl InvocationCollectorNode for ast::ExprField { const KIND: AstFragmentKind = AstFragmentKind::ExprFields; fn to_annotatable(self) -> Annotatable { Annotatable::ExprField(self) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_expr_fields() } fn walk_flat_map(self, visitor: &mut V) -> Self::OutputTy { walk_flat_map_expr_field(visitor, self) } } impl InvocationCollectorNode for ast::Param { const KIND: AstFragmentKind = AstFragmentKind::Params; fn to_annotatable(self) -> Annotatable { Annotatable::Param(self) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_params() } fn walk_flat_map(self, visitor: &mut V) -> Self::OutputTy { walk_flat_map_param(visitor, self) } } impl InvocationCollectorNode for ast::GenericParam { const KIND: AstFragmentKind = AstFragmentKind::GenericParams; fn to_annotatable(self) -> Annotatable { Annotatable::GenericParam(self) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_generic_params() } fn walk_flat_map(self, visitor: &mut V) -> Self::OutputTy { walk_flat_map_generic_param(visitor, self) } } impl InvocationCollectorNode for ast::Arm { const KIND: AstFragmentKind = AstFragmentKind::Arms; fn to_annotatable(self) -> Annotatable { Annotatable::Arm(self) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_arms() } fn walk_flat_map(self, visitor: &mut V) -> Self::OutputTy { walk_flat_map_arm(visitor, self) } } impl InvocationCollectorNode for ast::Stmt { type AttrsTy = ast::AttrVec; const KIND: AstFragmentKind = AstFragmentKind::Stmts; fn to_annotatable(self) -> Annotatable { Annotatable::Stmt(P(self)) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_stmts() } fn walk_flat_map(self, visitor: &mut V) -> Self::OutputTy { walk_flat_map_stmt(visitor, self) } fn is_mac_call(&self) -> bool { match &self.kind { StmtKind::MacCall(..) => true, StmtKind::Item(item) => matches!(item.kind, ItemKind::MacCall(..)), StmtKind::Semi(expr) => matches!(expr.kind, ExprKind::MacCall(..)), StmtKind::Expr(..) => unreachable!(), StmtKind::Let(..) | StmtKind::Empty => false, } } fn take_mac_call(self) -> (P, Self::AttrsTy, AddSemicolon) { // We pull macro invocations (both attributes and fn-like macro calls) out of their // `StmtKind`s and treat them as statement macro invocations, not as items or expressions. let (add_semicolon, mac, attrs) = match self.kind { StmtKind::MacCall(mac) => { let ast::MacCallStmt { mac, style, attrs, .. } = mac.into_inner(); (style == MacStmtStyle::Semicolon, mac, attrs) } StmtKind::Item(item) => match item.into_inner() { ast::Item { kind: ItemKind::MacCall(mac), attrs, .. } => { (mac.args.need_semicolon(), mac, attrs) } _ => unreachable!(), }, StmtKind::Semi(expr) => match expr.into_inner() { ast::Expr { kind: ExprKind::MacCall(mac), attrs, .. } => { (mac.args.need_semicolon(), mac, attrs) } _ => unreachable!(), }, _ => unreachable!(), }; (mac, attrs, if add_semicolon { AddSemicolon::Yes } else { AddSemicolon::No }) } fn delegation(&self) -> Option<(&ast::DelegationMac, &ast::Item)> { match &self.kind { StmtKind::Item(item) => match &item.kind { ItemKind::DelegationMac(deleg) => Some((deleg, item)), _ => None, }, _ => None, } } fn delegation_item_kind(deleg: Box) -> Self::ItemKind { ItemKind::Delegation(deleg) } fn from_item(item: ast::Item) -> Self { ast::Stmt { id: ast::DUMMY_NODE_ID, span: item.span, kind: StmtKind::Item(P(item)) } } fn flatten_outputs(items: impl Iterator) -> Self::OutputTy { items.flatten().collect() } fn post_flat_map_node_collect_bang(stmts: &mut Self::OutputTy, add_semicolon: AddSemicolon) { // If this is a macro invocation with a semicolon, then apply that // semicolon to the final statement produced by expansion. if matches!(add_semicolon, AddSemicolon::Yes) { if let Some(stmt) = stmts.pop() { stmts.push(stmt.add_trailing_semicolon()); } } } } impl InvocationCollectorNode for ast::Crate { type OutputTy = ast::Crate; const KIND: AstFragmentKind = AstFragmentKind::Crate; fn to_annotatable(self) -> Annotatable { Annotatable::Crate(self) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_crate() } fn walk(&mut self, visitor: &mut V) { walk_crate(visitor, self) } fn expand_cfg_false( &mut self, collector: &mut InvocationCollector<'_, '_>, pos: usize, _span: Span, ) { // Attributes above `cfg(FALSE)` are left in place, because we may want to configure // some global crate properties even on fully unconfigured crates. self.attrs.truncate(pos); // Standard prelude imports are left in the crate for backward compatibility. self.items.truncate(collector.cx.num_standard_library_imports); } } impl InvocationCollectorNode for P { type OutputTy = P; const KIND: AstFragmentKind = AstFragmentKind::Ty; fn to_annotatable(self) -> Annotatable { unreachable!() } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_ty() } fn walk(&mut self, visitor: &mut V) { walk_ty(visitor, self) } fn is_mac_call(&self) -> bool { matches!(self.kind, ast::TyKind::MacCall(..)) } fn take_mac_call(self) -> (P, Self::AttrsTy, AddSemicolon) { let node = self.into_inner(); match node.kind { TyKind::MacCall(mac) => (mac, AttrVec::new(), AddSemicolon::No), _ => unreachable!(), } } } impl InvocationCollectorNode for P { type OutputTy = P; const KIND: AstFragmentKind = AstFragmentKind::Pat; fn to_annotatable(self) -> Annotatable { unreachable!() } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_pat() } fn walk(&mut self, visitor: &mut V) { walk_pat(visitor, self) } fn is_mac_call(&self) -> bool { matches!(self.kind, PatKind::MacCall(..)) } fn take_mac_call(self) -> (P, Self::AttrsTy, AddSemicolon) { let node = self.into_inner(); match node.kind { PatKind::MacCall(mac) => (mac, AttrVec::new(), AddSemicolon::No), _ => unreachable!(), } } } impl InvocationCollectorNode for P { type OutputTy = P; type AttrsTy = ast::AttrVec; const KIND: AstFragmentKind = AstFragmentKind::Expr; fn to_annotatable(self) -> Annotatable { Annotatable::Expr(self) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_expr() } fn descr() -> &'static str { "an expression" } fn walk(&mut self, visitor: &mut V) { walk_expr(visitor, self) } fn is_mac_call(&self) -> bool { matches!(self.kind, ExprKind::MacCall(..)) } fn take_mac_call(self) -> (P, Self::AttrsTy, AddSemicolon) { let node = self.into_inner(); match node.kind { ExprKind::MacCall(mac) => (mac, node.attrs, AddSemicolon::No), _ => unreachable!(), } } } struct OptExprTag; impl InvocationCollectorNode for AstNodeWrapper, OptExprTag> { type OutputTy = Option>; type AttrsTy = ast::AttrVec; const KIND: AstFragmentKind = AstFragmentKind::OptExpr; fn to_annotatable(self) -> Annotatable { Annotatable::Expr(self.wrapped) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { fragment.make_opt_expr() } fn walk_flat_map(mut self, visitor: &mut V) -> Self::OutputTy { walk_expr(visitor, &mut self.wrapped); Some(self.wrapped) } fn is_mac_call(&self) -> bool { matches!(self.wrapped.kind, ast::ExprKind::MacCall(..)) } fn take_mac_call(self) -> (P, Self::AttrsTy, AddSemicolon) { let node = self.wrapped.into_inner(); match node.kind { ExprKind::MacCall(mac) => (mac, node.attrs, AddSemicolon::No), _ => unreachable!(), } } fn pre_flat_map_node_collect_attr(cfg: &StripUnconfigured<'_>, attr: &ast::Attribute) { cfg.maybe_emit_expr_attr_err(attr); } } /// This struct is a hack to workaround unstable of `stmt_expr_attributes`. /// It can be removed once that feature is stabilized. struct MethodReceiverTag; impl DummyAstNode for MethodReceiverTag { fn dummy() -> MethodReceiverTag { MethodReceiverTag } } impl InvocationCollectorNode for AstNodeWrapper, MethodReceiverTag> { type OutputTy = Self; type AttrsTy = ast::AttrVec; const KIND: AstFragmentKind = AstFragmentKind::MethodReceiverExpr; fn descr() -> &'static str { "an expression" } fn to_annotatable(self) -> Annotatable { Annotatable::Expr(self.wrapped) } fn fragment_to_output(fragment: AstFragment) -> Self::OutputTy { AstNodeWrapper::new(fragment.make_method_receiver_expr(), MethodReceiverTag) } fn walk(&mut self, visitor: &mut V) { walk_expr(visitor, &mut self.wrapped) } fn is_mac_call(&self) -> bool { matches!(self.wrapped.kind, ast::ExprKind::MacCall(..)) } fn take_mac_call(self) -> (P, Self::AttrsTy, AddSemicolon) { let node = self.wrapped.into_inner(); match node.kind { ExprKind::MacCall(mac) => (mac, node.attrs, AddSemicolon::No), _ => unreachable!(), } } } fn build_single_delegations<'a, Node: InvocationCollectorNode>( ecx: &ExtCtxt<'_>, deleg: &'a ast::DelegationMac, item: &'a ast::Item, suffixes: &'a [(Ident, Option)], item_span: Span, from_glob: bool, ) -> impl Iterator> + 'a { if suffixes.is_empty() { // Report an error for now, to avoid keeping stem for resolution and // stability checks. let kind = String::from(if from_glob { "glob" } else { "list" }); ecx.dcx().emit_err(EmptyDelegationMac { span: item.span, kind }); } suffixes.iter().map(move |&(ident, rename)| { let mut path = deleg.prefix.clone(); path.segments.push(ast::PathSegment { ident, id: ast::DUMMY_NODE_ID, args: None }); ast::Item { attrs: item.attrs.clone(), id: ast::DUMMY_NODE_ID, span: if from_glob { item_span } else { ident.span }, vis: item.vis.clone(), ident: rename.unwrap_or(ident), kind: Node::delegation_item_kind(Box::new(ast::Delegation { id: ast::DUMMY_NODE_ID, qself: deleg.qself.clone(), path, rename, body: deleg.body.clone(), from_glob, })), tokens: None, } }) } struct InvocationCollector<'a, 'b> { cx: &'a mut ExtCtxt<'b>, invocations: Vec<(Invocation, Option>)>, monotonic: bool, } impl<'a, 'b> InvocationCollector<'a, 'b> { fn cfg(&self) -> StripUnconfigured<'_> { StripUnconfigured { sess: self.cx.sess, features: Some(self.cx.ecfg.features), config_tokens: false, lint_node_id: self.cx.current_expansion.lint_node_id, } } fn collect(&mut self, fragment_kind: AstFragmentKind, kind: InvocationKind) -> AstFragment { let expn_id = LocalExpnId::fresh_empty(); if matches!(kind, InvocationKind::GlobDelegation { .. }) { // In resolver we need to know which invocation ids are delegations early, // before their `ExpnData` is filled. self.cx.resolver.register_glob_delegation(expn_id); } let vis = kind.placeholder_visibility(); self.invocations.push(( Invocation { kind, fragment_kind, expansion_data: ExpansionData { id: expn_id, depth: self.cx.current_expansion.depth + 1, ..self.cx.current_expansion.clone() }, }, None, )); placeholder(fragment_kind, NodeId::placeholder_from_expn_id(expn_id), vis) } fn collect_bang(&mut self, mac: P, kind: AstFragmentKind) -> AstFragment { // cache the macro call span so that it can be // easily adjusted for incremental compilation let span = mac.span(); self.collect(kind, InvocationKind::Bang { mac, span }) } fn collect_attr( &mut self, (attr, pos, derives): (ast::Attribute, usize, Vec), item: Annotatable, kind: AstFragmentKind, ) -> AstFragment { self.collect(kind, InvocationKind::Attr { attr, pos, item, derives }) } fn collect_glob_delegation( &mut self, item: P, kind: AstFragmentKind, ) -> AstFragment { self.collect(kind, InvocationKind::GlobDelegation { item }) } /// If `item` is an attribute invocation, remove the attribute and return it together with /// its position and derives following it. We have to collect the derives in order to resolve /// legacy derive helpers (helpers written before derives that introduce them). fn take_first_attr( &self, item: &mut impl HasAttrs, ) -> Option<(ast::Attribute, usize, Vec)> { let mut attr = None; let mut cfg_pos = None; let mut attr_pos = None; for (pos, attr) in item.attrs().iter().enumerate() { if !attr.is_doc_comment() && !self.cx.expanded_inert_attrs.is_marked(attr) { let name = attr.ident().map(|ident| ident.name); if name == Some(sym::cfg) || name == Some(sym::cfg_attr) { cfg_pos = Some(pos); // a cfg attr found, no need to search anymore break; } else if attr_pos.is_none() && !name.is_some_and(rustc_feature::is_builtin_attr_name) { attr_pos = Some(pos); // a non-cfg attr found, still may find a cfg attr } } } item.visit_attrs(|attrs| { attr = Some(match (cfg_pos, attr_pos) { (Some(pos), _) => (attrs.remove(pos), pos, Vec::new()), (_, Some(pos)) => { let attr = attrs.remove(pos); let following_derives = attrs[pos..] .iter() .filter(|a| a.has_name(sym::derive)) .flat_map(|a| a.meta_item_list().unwrap_or_default()) .filter_map(|meta_item_inner| match meta_item_inner { MetaItemInner::MetaItem(ast::MetaItem { kind: MetaItemKind::Word, path, .. }) => Some(path), _ => None, }) .collect(); (attr, pos, following_derives) } _ => return, }); }); attr } // Detect use of feature-gated or invalid attributes on macro invocations // since they will not be detected after macro expansion. fn check_attributes(&self, attrs: &[ast::Attribute], call: &ast::MacCall) { let features = self.cx.ecfg.features; let mut attrs = attrs.iter().peekable(); let mut span: Option = None; while let Some(attr) = attrs.next() { rustc_ast_passes::feature_gate::check_attribute(attr, self.cx.sess, features); validate_attr::check_attr(&self.cx.sess.psess, attr); let current_span = if let Some(sp) = span { sp.to(attr.span) } else { attr.span }; span = Some(current_span); if attrs.peek().is_some_and(|next_attr| next_attr.doc_str().is_some()) { continue; } if attr.is_doc_comment() { self.cx.sess.psess.buffer_lint( UNUSED_DOC_COMMENTS, current_span, self.cx.current_expansion.lint_node_id, BuiltinLintDiag::UnusedDocComment(attr.span), ); } else if rustc_attr_parsing::is_builtin_attr(attr) { let attr_name = attr.ident().unwrap().name; // `#[cfg]` and `#[cfg_attr]` are special - they are // eagerly evaluated. if attr_name != sym::cfg && attr_name != sym::cfg_attr { self.cx.sess.psess.buffer_lint( UNUSED_ATTRIBUTES, attr.span, self.cx.current_expansion.lint_node_id, BuiltinLintDiag::UnusedBuiltinAttribute { attr_name, macro_name: pprust::path_to_string(&call.path), invoc_span: call.path.span, }, ); } } } } fn expand_cfg_true( &mut self, node: &mut impl HasAttrs, attr: ast::Attribute, pos: usize, ) -> (bool, Option) { let (res, meta_item) = self.cfg().cfg_true(&attr); if res { // FIXME: `cfg(TRUE)` attributes do not currently remove themselves during expansion, // and some tools like rustdoc and clippy rely on that. Find a way to remove them // while keeping the tools working. self.cx.expanded_inert_attrs.mark(&attr); node.visit_attrs(|attrs| attrs.insert(pos, attr)); } (res, meta_item) } fn expand_cfg_attr(&self, node: &mut impl HasAttrs, attr: &ast::Attribute, pos: usize) { node.visit_attrs(|attrs| { // Repeated `insert` calls is inefficient, but the number of // insertions is almost always 0 or 1 in practice. for cfg in self.cfg().expand_cfg_attr(attr, false).into_iter().rev() { attrs.insert(pos, cfg) } }); } fn flat_map_node>( &mut self, mut node: Node, ) -> Node::OutputTy { loop { return match self.take_first_attr(&mut node) { Some((attr, pos, derives)) => match attr.name_or_empty() { sym::cfg => { let (res, meta_item) = self.expand_cfg_true(&mut node, attr, pos); if res { continue; } if let Some(meta_item) = meta_item { for name in node.declared_names() { self.cx.resolver.append_stripped_cfg_item( self.cx.current_expansion.lint_node_id, name, meta_item.clone(), ) } } Default::default() } sym::cfg_attr => { self.expand_cfg_attr(&mut node, &attr, pos); continue; } _ => { Node::pre_flat_map_node_collect_attr(&self.cfg(), &attr); self.collect_attr((attr, pos, derives), node.to_annotatable(), Node::KIND) .make_ast::() } }, None if node.is_mac_call() => { let (mac, attrs, add_semicolon) = node.take_mac_call(); self.check_attributes(&attrs, &mac); let mut res = self.collect_bang(mac, Node::KIND).make_ast::(); Node::post_flat_map_node_collect_bang(&mut res, add_semicolon); res } None if let Some((deleg, item)) = node.delegation() => { let Some(suffixes) = &deleg.suffixes else { let traitless_qself = matches!(&deleg.qself, Some(qself) if qself.position == 0); let item = match node.to_annotatable() { Annotatable::AssocItem(item, AssocCtxt::Impl) => item, ann @ (Annotatable::Item(_) | Annotatable::AssocItem(..) | Annotatable::Stmt(_)) => { let span = ann.span(); self.cx.dcx().emit_err(GlobDelegationOutsideImpls { span }); return Default::default(); } _ => unreachable!(), }; if traitless_qself { let span = item.span; self.cx.dcx().emit_err(GlobDelegationTraitlessQpath { span }); return Default::default(); } return self.collect_glob_delegation(item, Node::KIND).make_ast::(); }; let single_delegations = build_single_delegations::( self.cx, deleg, item, suffixes, item.span, false, ); Node::flatten_outputs(single_delegations.map(|item| { let mut item = Node::from_item(item); assign_id!(self, item.node_id_mut(), || item.walk_flat_map(self)) })) } None => { match Node::wrap_flat_map_node_walk_flat_map(node, self, |mut node, this| { assign_id!(this, node.node_id_mut(), || node.walk_flat_map(this)) }) { Ok(output) => output, Err(returned_node) => { node = returned_node; continue; } } } }; } } fn visit_node + DummyAstNode>( &mut self, node: &mut Node, ) { loop { return match self.take_first_attr(node) { Some((attr, pos, derives)) => match attr.name_or_empty() { sym::cfg => { let span = attr.span; if self.expand_cfg_true(node, attr, pos).0 { continue; } node.expand_cfg_false(self, pos, span); continue; } sym::cfg_attr => { self.expand_cfg_attr(node, &attr, pos); continue; } _ => visit_clobber(node, |node| { self.collect_attr((attr, pos, derives), node.to_annotatable(), Node::KIND) .make_ast::() }), }, None if node.is_mac_call() => { visit_clobber(node, |node| { // Do not clobber unless it's actually a macro (uncommon case). let (mac, attrs, _) = node.take_mac_call(); self.check_attributes(&attrs, &mac); self.collect_bang(mac, Node::KIND).make_ast::() }) } None if node.delegation().is_some() => unreachable!(), None => { assign_id!(self, node.node_id_mut(), || node.walk(self)) } }; } } } impl<'a, 'b> MutVisitor for InvocationCollector<'a, 'b> { fn flat_map_item(&mut self, node: P) -> SmallVec<[P; 1]> { self.flat_map_node(node) } fn flat_map_assoc_item( &mut self, node: P, ctxt: AssocCtxt, ) -> SmallVec<[P; 1]> { match ctxt { AssocCtxt::Trait => self.flat_map_node(AstNodeWrapper::new(node, TraitItemTag)), AssocCtxt::Impl => self.flat_map_node(AstNodeWrapper::new(node, ImplItemTag)), } } fn flat_map_foreign_item( &mut self, node: P, ) -> SmallVec<[P; 1]> { self.flat_map_node(node) } fn flat_map_variant(&mut self, node: ast::Variant) -> SmallVec<[ast::Variant; 1]> { self.flat_map_node(node) } fn flat_map_where_predicate( &mut self, node: ast::WherePredicate, ) -> SmallVec<[ast::WherePredicate; 1]> { self.flat_map_node(node) } fn flat_map_field_def(&mut self, node: ast::FieldDef) -> SmallVec<[ast::FieldDef; 1]> { self.flat_map_node(node) } fn flat_map_pat_field(&mut self, node: ast::PatField) -> SmallVec<[ast::PatField; 1]> { self.flat_map_node(node) } fn flat_map_expr_field(&mut self, node: ast::ExprField) -> SmallVec<[ast::ExprField; 1]> { self.flat_map_node(node) } fn flat_map_param(&mut self, node: ast::Param) -> SmallVec<[ast::Param; 1]> { self.flat_map_node(node) } fn flat_map_generic_param( &mut self, node: ast::GenericParam, ) -> SmallVec<[ast::GenericParam; 1]> { self.flat_map_node(node) } fn flat_map_arm(&mut self, node: ast::Arm) -> SmallVec<[ast::Arm; 1]> { self.flat_map_node(node) } fn flat_map_stmt(&mut self, node: ast::Stmt) -> SmallVec<[ast::Stmt; 1]> { // FIXME: invocations in semicolon-less expressions positions are expanded as expressions, // changing that requires some compatibility measures. if node.is_expr() { // The only way that we can end up with a `MacCall` expression statement, // (as opposed to a `StmtKind::MacCall`) is if we have a macro as the // trailing expression in a block (e.g. `fn foo() { my_macro!() }`). // Record this information, so that we can report a more specific // `SEMICOLON_IN_EXPRESSIONS_FROM_MACROS` lint if needed. // See #78991 for an investigation of treating macros in this position // as statements, rather than expressions, during parsing. return match &node.kind { StmtKind::Expr(expr) if matches!(**expr, ast::Expr { kind: ExprKind::MacCall(..), .. }) => { self.cx.current_expansion.is_trailing_mac = true; // Don't use `assign_id` for this statement - it may get removed // entirely due to a `#[cfg]` on the contained expression let res = walk_flat_map_stmt(self, node); self.cx.current_expansion.is_trailing_mac = false; res } _ => walk_flat_map_stmt(self, node), }; } self.flat_map_node(node) } fn visit_crate(&mut self, node: &mut ast::Crate) { self.visit_node(node) } fn visit_ty(&mut self, node: &mut P) { self.visit_node(node) } fn visit_pat(&mut self, node: &mut P) { self.visit_node(node) } fn visit_expr(&mut self, node: &mut P) { // FIXME: Feature gating is performed inconsistently between `Expr` and `OptExpr`. if let Some(attr) = node.attrs.first() { self.cfg().maybe_emit_expr_attr_err(attr); } self.visit_node(node) } fn visit_method_receiver_expr(&mut self, node: &mut P) { visit_clobber(node, |node| { let mut wrapper = AstNodeWrapper::new(node, MethodReceiverTag); self.visit_node(&mut wrapper); wrapper.wrapped }) } fn filter_map_expr(&mut self, node: P) -> Option> { self.flat_map_node(AstNodeWrapper::new(node, OptExprTag)) } fn visit_block(&mut self, node: &mut P) { let orig_dir_ownership = mem::replace( &mut self.cx.current_expansion.dir_ownership, DirOwnership::UnownedViaBlock, ); walk_block(self, node); self.cx.current_expansion.dir_ownership = orig_dir_ownership; } fn visit_id(&mut self, id: &mut NodeId) { // We may have already assigned a `NodeId` // by calling `assign_id` if self.monotonic && *id == ast::DUMMY_NODE_ID { *id = self.cx.resolver.next_node_id(); } } } pub struct ExpansionConfig<'feat> { pub crate_name: String, pub features: &'feat Features, pub recursion_limit: Limit, pub trace_mac: bool, /// If false, strip `#[test]` nodes pub should_test: bool, /// If true, use verbose debugging for `proc_macro::Span` pub span_debug: bool, /// If true, show backtraces for proc-macro panics pub proc_macro_backtrace: bool, } impl ExpansionConfig<'_> { pub fn default(crate_name: String, features: &Features) -> ExpansionConfig<'_> { ExpansionConfig { crate_name, features, recursion_limit: Limit::new(1024), trace_mac: false, should_test: false, span_debug: false, proc_macro_backtrace: false, } } }