// Copyright 2012-2014 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. // Functions dealing with attributes and meta items pub use self::StabilityLevel::*; pub use self::ReprAttr::*; pub use self::IntType::*; use ast; use ast::{AttrId, Attribute, Attribute_, MetaItem, MetaItemKind}; use ast::{Stmt, StmtKind, DeclKind}; use ast::{Expr, Item, Local, Decl}; use codemap::{Span, Spanned, spanned, dummy_spanned}; use codemap::BytePos; use config::CfgDiag; use errors::Handler; use feature_gate::{GatedCfg, GatedCfgAttr}; use parse::lexer::comments::{doc_comment_style, strip_doc_comment_decoration}; use parse::token::InternedString; use parse::token; use ptr::P; use std::cell::{RefCell, Cell}; use std::collections::HashSet; thread_local! { static USED_ATTRS: RefCell> = RefCell::new(Vec::new()) } pub fn mark_used(attr: &Attribute) { let AttrId(id) = attr.node.id; USED_ATTRS.with(|slot| { let idx = (id / 64) as usize; let shift = id % 64; if slot.borrow().len() <= idx { slot.borrow_mut().resize(idx + 1, 0); } slot.borrow_mut()[idx] |= 1 << shift; }); } pub fn is_used(attr: &Attribute) -> bool { let AttrId(id) = attr.node.id; USED_ATTRS.with(|slot| { let idx = (id / 64) as usize; let shift = id % 64; slot.borrow().get(idx).map(|bits| bits & (1 << shift) != 0) .unwrap_or(false) }) } pub trait AttrMetaMethods { fn check_name(&self, name: &str) -> bool { name == &self.name()[..] } /// Retrieve the name of the meta item, e.g. `foo` in `#[foo]`, /// `#[foo="bar"]` and `#[foo(bar)]` fn name(&self) -> InternedString; /// Gets the string value if self is a MetaItemKind::NameValue variant /// containing a string, otherwise None. fn value_str(&self) -> Option; /// Gets a list of inner meta items from a list MetaItem type. fn meta_item_list(&self) -> Option<&[P]>; fn span(&self) -> Span; } impl AttrMetaMethods for Attribute { fn check_name(&self, name: &str) -> bool { let matches = name == &self.name()[..]; if matches { mark_used(self); } matches } fn name(&self) -> InternedString { self.meta().name() } fn value_str(&self) -> Option { self.meta().value_str() } fn meta_item_list(&self) -> Option<&[P]> { self.node.value.meta_item_list() } fn span(&self) -> Span { self.meta().span } } impl AttrMetaMethods for MetaItem { fn name(&self) -> InternedString { match self.node { MetaItemKind::Word(ref n) => (*n).clone(), MetaItemKind::NameValue(ref n, _) => (*n).clone(), MetaItemKind::List(ref n, _) => (*n).clone(), } } fn value_str(&self) -> Option { match self.node { MetaItemKind::NameValue(_, ref v) => { match v.node { ast::LitKind::Str(ref s, _) => Some((*s).clone()), _ => None, } }, _ => None } } fn meta_item_list(&self) -> Option<&[P]> { match self.node { MetaItemKind::List(_, ref l) => Some(&l[..]), _ => None } } fn span(&self) -> Span { self.span } } // Annoying, but required to get test_cfg to work impl AttrMetaMethods for P { fn name(&self) -> InternedString { (**self).name() } fn value_str(&self) -> Option { (**self).value_str() } fn meta_item_list(&self) -> Option<&[P]> { (**self).meta_item_list() } fn span(&self) -> Span { (**self).span() } } pub trait AttributeMethods { fn meta(&self) -> &MetaItem; fn with_desugared_doc(&self, f: F) -> T where F: FnOnce(&Attribute) -> T; } impl AttributeMethods for Attribute { /// Extract the MetaItem from inside this Attribute. fn meta(&self) -> &MetaItem { &self.node.value } /// Convert self to a normal #[doc="foo"] comment, if it is a /// comment like `///` or `/** */`. (Returns self unchanged for /// non-sugared doc attributes.) fn with_desugared_doc(&self, f: F) -> T where F: FnOnce(&Attribute) -> T, { if self.node.is_sugared_doc { let comment = self.value_str().unwrap(); let meta = mk_name_value_item_str( InternedString::new("doc"), token::intern_and_get_ident(&strip_doc_comment_decoration( &comment))); if self.node.style == ast::AttrStyle::Outer { f(&mk_attr_outer(self.node.id, meta)) } else { f(&mk_attr_inner(self.node.id, meta)) } } else { f(self) } } } /* Constructors */ pub fn mk_name_value_item_str(name: InternedString, value: InternedString) -> P { let value_lit = dummy_spanned(ast::LitKind::Str(value, ast::StrStyle::Cooked)); mk_name_value_item(name, value_lit) } pub fn mk_name_value_item(name: InternedString, value: ast::Lit) -> P { P(dummy_spanned(MetaItemKind::NameValue(name, value))) } pub fn mk_list_item(name: InternedString, items: Vec>) -> P { P(dummy_spanned(MetaItemKind::List(name, items))) } pub fn mk_word_item(name: InternedString) -> P { P(dummy_spanned(MetaItemKind::Word(name))) } thread_local! { static NEXT_ATTR_ID: Cell = Cell::new(0) } pub fn mk_attr_id() -> AttrId { let id = NEXT_ATTR_ID.with(|slot| { let r = slot.get(); slot.set(r + 1); r }); AttrId(id) } /// Returns an inner attribute with the given value. pub fn mk_attr_inner(id: AttrId, item: P) -> Attribute { dummy_spanned(Attribute_ { id: id, style: ast::AttrStyle::Inner, value: item, is_sugared_doc: false, }) } /// Returns an outer attribute with the given value. pub fn mk_attr_outer(id: AttrId, item: P) -> Attribute { dummy_spanned(Attribute_ { id: id, style: ast::AttrStyle::Outer, value: item, is_sugared_doc: false, }) } pub fn mk_sugared_doc_attr(id: AttrId, text: InternedString, lo: BytePos, hi: BytePos) -> Attribute { let style = doc_comment_style(&text); let lit = spanned(lo, hi, ast::LitKind::Str(text, ast::StrStyle::Cooked)); let attr = Attribute_ { id: id, style: style, value: P(spanned(lo, hi, MetaItemKind::NameValue(InternedString::new("doc"), lit))), is_sugared_doc: true }; spanned(lo, hi, attr) } /* Searching */ /// Check if `needle` occurs in `haystack` by a structural /// comparison. This is slightly subtle, and relies on ignoring the /// span included in the `==` comparison a plain MetaItem. pub fn contains(haystack: &[P], needle: &MetaItem) -> bool { debug!("attr::contains (name={})", needle.name()); haystack.iter().any(|item| { debug!(" testing: {}", item.name()); item.node == needle.node }) } pub fn contains_name(metas: &[AM], name: &str) -> bool { debug!("attr::contains_name (name={})", name); metas.iter().any(|item| { debug!(" testing: {}", item.name()); item.check_name(name) }) } pub fn first_attr_value_str_by_name(attrs: &[Attribute], name: &str) -> Option { attrs.iter() .find(|at| at.check_name(name)) .and_then(|at| at.value_str()) } pub fn last_meta_item_value_str_by_name(items: &[P], name: &str) -> Option { items.iter() .rev() .find(|mi| mi.check_name(name)) .and_then(|i| i.value_str()) } /* Higher-level applications */ pub fn sort_meta_items(items: Vec>) -> Vec> { // This is sort of stupid here, but we need to sort by // human-readable strings. let mut v = items.into_iter() .map(|mi| (mi.name(), mi)) .collect::)>>(); v.sort_by(|&(ref a, _), &(ref b, _)| a.cmp(b)); // There doesn't seem to be a more optimal way to do this v.into_iter().map(|(_, m)| m.map(|Spanned {node, span}| { Spanned { node: match node { MetaItemKind::List(n, mis) => MetaItemKind::List(n, sort_meta_items(mis)), _ => node }, span: span } })).collect() } pub fn find_crate_name(attrs: &[Attribute]) -> Option { first_attr_value_str_by_name(attrs, "crate_name") } /// Find the value of #[export_name=*] attribute and check its validity. pub fn find_export_name_attr(diag: &Handler, attrs: &[Attribute]) -> Option { attrs.iter().fold(None, |ia,attr| { if attr.check_name("export_name") { if let s@Some(_) = attr.value_str() { s } else { diag.struct_span_err(attr.span, "export_name attribute has invalid format") .help("use #[export_name=\"*\"]") .emit(); None } } else { ia } }) } pub fn contains_extern_indicator(diag: &Handler, attrs: &[Attribute]) -> bool { contains_name(attrs, "no_mangle") || find_export_name_attr(diag, attrs).is_some() } #[derive(Copy, Clone, PartialEq)] pub enum InlineAttr { None, Hint, Always, Never, } /// Determine what `#[inline]` attribute is present in `attrs`, if any. pub fn find_inline_attr(diagnostic: Option<&Handler>, attrs: &[Attribute]) -> InlineAttr { attrs.iter().fold(InlineAttr::None, |ia,attr| { match attr.node.value.node { MetaItemKind::Word(ref n) if *n == "inline" => { mark_used(attr); InlineAttr::Hint } MetaItemKind::List(ref n, ref items) if *n == "inline" => { mark_used(attr); if items.len() != 1 { diagnostic.map(|d|{ d.span_err(attr.span, "expected one argument"); }); InlineAttr::None } else if contains_name(&items[..], "always") { InlineAttr::Always } else if contains_name(&items[..], "never") { InlineAttr::Never } else { diagnostic.map(|d|{ d.span_err((*items[0]).span, "invalid argument"); }); InlineAttr::None } } _ => ia } }) } /// True if `#[inline]` or `#[inline(always)]` is present in `attrs`. pub fn requests_inline(attrs: &[Attribute]) -> bool { match find_inline_attr(None, attrs) { InlineAttr::Hint | InlineAttr::Always => true, InlineAttr::None | InlineAttr::Never => false, } } /// Tests if a cfg-pattern matches the cfg set pub fn cfg_matches(cfgs: &[P], cfg: &ast::MetaItem, diag: &mut T) -> bool { match cfg.node { ast::MetaItemKind::List(ref pred, ref mis) if &pred[..] == "any" => mis.iter().any(|mi| cfg_matches(cfgs, &mi, diag)), ast::MetaItemKind::List(ref pred, ref mis) if &pred[..] == "all" => mis.iter().all(|mi| cfg_matches(cfgs, &mi, diag)), ast::MetaItemKind::List(ref pred, ref mis) if &pred[..] == "not" => { if mis.len() != 1 { diag.emit_error(|diagnostic| { diagnostic.span_err(cfg.span, "expected 1 cfg-pattern"); }); return false; } !cfg_matches(cfgs, &mis[0], diag) } ast::MetaItemKind::List(ref pred, _) => { diag.emit_error(|diagnostic| { diagnostic.span_err(cfg.span, &format!("invalid predicate `{}`", pred)); }); false }, ast::MetaItemKind::Word(_) | ast::MetaItemKind::NameValue(..) => { diag.flag_gated(|feature_gated_cfgs| { feature_gated_cfgs.extend( GatedCfg::gate(cfg).map(GatedCfgAttr::GatedCfg)); }); contains(cfgs, cfg) } } } /// Represents the #[stable], #[unstable] and #[rustc_deprecated] attributes. #[derive(RustcEncodable, RustcDecodable, Clone, Debug, PartialEq, Eq, Hash)] pub struct Stability { pub level: StabilityLevel, pub feature: InternedString, pub rustc_depr: Option, } /// The available stability levels. #[derive(RustcEncodable, RustcDecodable, PartialEq, PartialOrd, Clone, Debug, Eq, Hash)] pub enum StabilityLevel { // Reason for the current stability level and the relevant rust-lang issue Unstable { reason: Option, issue: u32 }, Stable { since: InternedString }, } #[derive(RustcEncodable, RustcDecodable, PartialEq, PartialOrd, Clone, Debug, Eq, Hash)] pub struct RustcDeprecation { pub since: InternedString, pub reason: InternedString, } #[derive(RustcEncodable, RustcDecodable, PartialEq, PartialOrd, Clone, Debug, Eq, Hash)] pub struct Deprecation { pub since: Option, pub note: Option, } impl StabilityLevel { pub fn is_unstable(&self) -> bool { if let Unstable {..} = *self { true } else { false }} pub fn is_stable(&self) -> bool { if let Stable {..} = *self { true } else { false }} } fn find_stability_generic<'a, I>(diagnostic: &Handler, attrs_iter: I, item_sp: Span) -> Option where I: Iterator { let mut stab: Option = None; let mut rustc_depr: Option = None; 'outer: for attr in attrs_iter { let tag = attr.name(); let tag = &*tag; if tag != "rustc_deprecated" && tag != "unstable" && tag != "stable" { continue // not a stability level } mark_used(attr); if let Some(metas) = attr.meta_item_list() { let get = |meta: &MetaItem, item: &mut Option| { if item.is_some() { diagnostic.span_err(meta.span, &format!("multiple '{}' items", meta.name())); return false } if let Some(v) = meta.value_str() { *item = Some(v); true } else { diagnostic.span_err(meta.span, "incorrect meta item"); false } }; match tag { "rustc_deprecated" => { if rustc_depr.is_some() { diagnostic.span_err(item_sp, "multiple rustc_deprecated attributes"); break } let mut since = None; let mut reason = None; for meta in metas { match &*meta.name() { "since" => if !get(meta, &mut since) { continue 'outer }, "reason" => if !get(meta, &mut reason) { continue 'outer }, _ => { diagnostic.span_err(meta.span, &format!("unknown meta item '{}'", meta.name())); continue 'outer } } } match (since, reason) { (Some(since), Some(reason)) => { rustc_depr = Some(RustcDeprecation { since: since, reason: reason, }) } (None, _) => { diagnostic.span_err(attr.span(), "missing 'since'"); continue } _ => { diagnostic.span_err(attr.span(), "missing 'reason'"); continue } } } "unstable" => { if stab.is_some() { diagnostic.span_err(item_sp, "multiple stability levels"); break } let mut feature = None; let mut reason = None; let mut issue = None; for meta in metas { match &*meta.name() { "feature" => if !get(meta, &mut feature) { continue 'outer }, "reason" => if !get(meta, &mut reason) { continue 'outer }, "issue" => if !get(meta, &mut issue) { continue 'outer }, _ => { diagnostic.span_err(meta.span, &format!("unknown meta item '{}'", meta.name())); continue 'outer } } } match (feature, reason, issue) { (Some(feature), reason, Some(issue)) => { stab = Some(Stability { level: Unstable { reason: reason, issue: { if let Ok(issue) = issue.parse() { issue } else { diagnostic.span_err(attr.span(), "incorrect 'issue'"); continue } } }, feature: feature, rustc_depr: None, }) } (None, _, _) => { diagnostic.span_err(attr.span(), "missing 'feature'"); continue } _ => { diagnostic.span_err(attr.span(), "missing 'issue'"); continue } } } "stable" => { if stab.is_some() { diagnostic.span_err(item_sp, "multiple stability levels"); break } let mut feature = None; let mut since = None; for meta in metas { match &*meta.name() { "feature" => if !get(meta, &mut feature) { continue 'outer }, "since" => if !get(meta, &mut since) { continue 'outer }, _ => { diagnostic.span_err(meta.span, &format!("unknown meta item '{}'", meta.name())); continue 'outer } } } match (feature, since) { (Some(feature), Some(since)) => { stab = Some(Stability { level: Stable { since: since, }, feature: feature, rustc_depr: None, }) } (None, _) => { diagnostic.span_err(attr.span(), "missing 'feature'"); continue } _ => { diagnostic.span_err(attr.span(), "missing 'since'"); continue } } } _ => unreachable!() } } else { diagnostic.span_err(attr.span(), "incorrect stability attribute type"); continue } } // Merge the deprecation info into the stability info if let Some(rustc_depr) = rustc_depr { if let Some(ref mut stab) = stab { if let Unstable {reason: ref mut reason @ None, ..} = stab.level { *reason = Some(rustc_depr.reason.clone()) } stab.rustc_depr = Some(rustc_depr); } else { diagnostic.span_err(item_sp, "rustc_deprecated attribute must be paired with \ either stable or unstable attribute"); } } stab } fn find_deprecation_generic<'a, I>(diagnostic: &Handler, attrs_iter: I, item_sp: Span) -> Option where I: Iterator { let mut depr: Option = None; 'outer: for attr in attrs_iter { if attr.name() != "deprecated" { continue } mark_used(attr); if depr.is_some() { diagnostic.span_err(item_sp, "multiple deprecated attributes"); break } depr = if let Some(metas) = attr.meta_item_list() { let get = |meta: &MetaItem, item: &mut Option| { if item.is_some() { diagnostic.span_err(meta.span, &format!("multiple '{}' items", meta.name())); return false } if let Some(v) = meta.value_str() { *item = Some(v); true } else { diagnostic.span_err(meta.span, "incorrect meta item"); false } }; let mut since = None; let mut note = None; for meta in metas { match &*meta.name() { "since" => if !get(meta, &mut since) { continue 'outer }, "note" => if !get(meta, &mut note) { continue 'outer }, _ => { diagnostic.span_err(meta.span, &format!("unknown meta item '{}'", meta.name())); continue 'outer } } } Some(Deprecation {since: since, note: note}) } else { Some(Deprecation{since: None, note: None}) } } depr } /// Find the first stability attribute. `None` if none exists. pub fn find_stability(diagnostic: &Handler, attrs: &[Attribute], item_sp: Span) -> Option { find_stability_generic(diagnostic, attrs.iter(), item_sp) } /// Find the deprecation attribute. `None` if none exists. pub fn find_deprecation(diagnostic: &Handler, attrs: &[Attribute], item_sp: Span) -> Option { find_deprecation_generic(diagnostic, attrs.iter(), item_sp) } pub fn require_unique_names(diagnostic: &Handler, metas: &[P]) { let mut set = HashSet::new(); for meta in metas { let name = meta.name(); if !set.insert(name.clone()) { panic!(diagnostic.span_fatal(meta.span, &format!("duplicate meta item `{}`", name))); } } } /// Parse #[repr(...)] forms. /// /// Valid repr contents: any of the primitive integral type names (see /// `int_type_of_word`, below) to specify enum discriminant type; `C`, to use /// the same discriminant size that the corresponding C enum would or C /// structure layout, and `packed` to remove padding. pub fn find_repr_attrs(diagnostic: &Handler, attr: &Attribute) -> Vec { let mut acc = Vec::new(); match attr.node.value.node { ast::MetaItemKind::List(ref s, ref items) if *s == "repr" => { mark_used(attr); for item in items { match item.node { ast::MetaItemKind::Word(ref word) => { let hint = match &word[..] { // Can't use "extern" because it's not a lexical identifier. "C" => Some(ReprExtern), "packed" => Some(ReprPacked), "simd" => Some(ReprSimd), _ => match int_type_of_word(&word) { Some(ity) => Some(ReprInt(item.span, ity)), None => { // Not a word we recognize diagnostic.span_err(item.span, "unrecognized representation hint"); None } } }; match hint { Some(h) => acc.push(h), None => { } } } // Not a word: _ => diagnostic.span_err(item.span, "unrecognized enum representation hint") } } } // Not a "repr" hint: ignore. _ => { } } acc } fn int_type_of_word(s: &str) -> Option { match s { "i8" => Some(SignedInt(ast::IntTy::I8)), "u8" => Some(UnsignedInt(ast::UintTy::U8)), "i16" => Some(SignedInt(ast::IntTy::I16)), "u16" => Some(UnsignedInt(ast::UintTy::U16)), "i32" => Some(SignedInt(ast::IntTy::I32)), "u32" => Some(UnsignedInt(ast::UintTy::U32)), "i64" => Some(SignedInt(ast::IntTy::I64)), "u64" => Some(UnsignedInt(ast::UintTy::U64)), "isize" => Some(SignedInt(ast::IntTy::Is)), "usize" => Some(UnsignedInt(ast::UintTy::Us)), _ => None } } #[derive(PartialEq, Debug, RustcEncodable, RustcDecodable, Copy, Clone)] pub enum ReprAttr { ReprAny, ReprInt(Span, IntType), ReprExtern, ReprPacked, ReprSimd, } impl ReprAttr { pub fn is_ffi_safe(&self) -> bool { match *self { ReprAny => false, ReprInt(_sp, ity) => ity.is_ffi_safe(), ReprExtern => true, ReprPacked => false, ReprSimd => true, } } } #[derive(Eq, Hash, PartialEq, Debug, RustcEncodable, RustcDecodable, Copy, Clone)] pub enum IntType { SignedInt(ast::IntTy), UnsignedInt(ast::UintTy) } impl IntType { #[inline] pub fn is_signed(self) -> bool { match self { SignedInt(..) => true, UnsignedInt(..) => false } } fn is_ffi_safe(self) -> bool { match self { SignedInt(ast::IntTy::I8) | UnsignedInt(ast::UintTy::U8) | SignedInt(ast::IntTy::I16) | UnsignedInt(ast::UintTy::U16) | SignedInt(ast::IntTy::I32) | UnsignedInt(ast::UintTy::U32) | SignedInt(ast::IntTy::I64) | UnsignedInt(ast::UintTy::U64) => true, SignedInt(ast::IntTy::Is) | UnsignedInt(ast::UintTy::Us) => false } } } /// A list of attributes, behind a optional box as /// a space optimization. pub type ThinAttributes = Option>>; pub trait ThinAttributesExt { fn map_thin_attrs(self, f: F) -> Self where F: FnOnce(Vec) -> Vec; fn prepend(mut self, attrs: Self) -> Self; fn append(mut self, attrs: Self) -> Self; fn update(&mut self, f: F) where Self: Sized, F: FnOnce(Self) -> Self; fn as_attr_slice(&self) -> &[Attribute]; fn into_attr_vec(self) -> Vec; } impl ThinAttributesExt for ThinAttributes { fn map_thin_attrs(self, f: F) -> Self where F: FnOnce(Vec) -> Vec { f(self.map(|b| *b).unwrap_or(Vec::new())).into_thin_attrs() } fn prepend(self, attrs: ThinAttributes) -> Self { attrs.map_thin_attrs(|mut attrs| { attrs.extend(self.into_attr_vec()); attrs }) } fn append(self, attrs: ThinAttributes) -> Self { self.map_thin_attrs(|mut self_| { self_.extend(attrs.into_attr_vec()); self_ }) } fn update(&mut self, f: F) where Self: Sized, F: FnOnce(ThinAttributes) -> ThinAttributes { let self_ = f(self.take()); *self = self_; } fn as_attr_slice(&self) -> &[Attribute] { match *self { Some(ref b) => b, None => &[], } } fn into_attr_vec(self) -> Vec { match self { Some(b) => *b, None => Vec::new(), } } } pub trait AttributesExt { fn into_thin_attrs(self) -> ThinAttributes; } impl AttributesExt for Vec { fn into_thin_attrs(self) -> ThinAttributes { if self.len() == 0 { None } else { Some(Box::new(self)) } } } /// A cheap way to add Attributes to an AST node. pub trait WithAttrs { // FIXME: Could be extended to anything IntoIter fn with_attrs(self, attrs: ThinAttributes) -> Self; } impl WithAttrs for P { fn with_attrs(self, attrs: ThinAttributes) -> Self { self.map(|mut e| { e.attrs.update(|a| a.append(attrs)); e }) } } impl WithAttrs for P { fn with_attrs(self, attrs: ThinAttributes) -> Self { self.map(|Item { ident, attrs: mut ats, id, node, vis, span }| { ats.extend(attrs.into_attr_vec()); Item { ident: ident, attrs: ats, id: id, node: node, vis: vis, span: span, } }) } } impl WithAttrs for P { fn with_attrs(self, attrs: ThinAttributes) -> Self { self.map(|Local { pat, ty, init, id, span, attrs: mut ats }| { ats.update(|a| a.append(attrs)); Local { pat: pat, ty: ty, init: init, id: id, span: span, attrs: ats, } }) } } impl WithAttrs for P { fn with_attrs(self, attrs: ThinAttributes) -> Self { self.map(|Spanned { span, node }| { Spanned { span: span, node: match node { DeclKind::Local(local) => DeclKind::Local(local.with_attrs(attrs)), DeclKind::Item(item) => DeclKind::Item(item.with_attrs(attrs)), } } }) } } impl WithAttrs for P { fn with_attrs(self, attrs: ThinAttributes) -> Self { self.map(|Spanned { span, node }| { Spanned { span: span, node: match node { StmtKind::Decl(decl, id) => StmtKind::Decl(decl.with_attrs(attrs), id), StmtKind::Expr(expr, id) => StmtKind::Expr(expr.with_attrs(attrs), id), StmtKind::Semi(expr, id) => StmtKind::Semi(expr.with_attrs(attrs), id), StmtKind::Mac(mac, style, mut ats) => { ats.update(|a| a.append(attrs)); StmtKind::Mac(mac, style, ats) } }, } }) } }