//! # Feature gating //! //! This module implements the gating necessary for preventing certain compiler //! features from being used by default. This module will crawl a pre-expanded //! AST to ensure that there are no features which are used that are not //! enabled. //! //! Features are enabled in programs via the crate-level attributes of //! `#![feature(...)]` with a comma-separated list of features. //! //! For the purpose of future feature-tracking, once code for detection of feature //! gate usage is added, *do not remove it again* even once the feature //! becomes stable. mod accepted; use accepted::ACCEPTED_FEATURES; mod removed; use removed::{REMOVED_FEATURES, STABLE_REMOVED_FEATURES}; mod active; use active::{ACTIVE_FEATURES}; pub use active::{Features, INCOMPLETE_FEATURES}; mod builtin_attrs; pub use builtin_attrs::{ AttributeGate, AttributeType, GatedCfg, BuiltinAttribute, BUILTIN_ATTRIBUTES, BUILTIN_ATTRIBUTE_MAP, deprecated_attributes, is_builtin_attr, is_builtin_attr_name, }; use crate::ast::{ self, AssocTyConstraint, AssocTyConstraintKind, NodeId, GenericParam, GenericParamKind, PatKind, RangeEnd, }; use crate::attr::{self, check_builtin_attribute}; use crate::source_map::Spanned; use crate::edition::{ALL_EDITIONS, Edition}; use crate::visit::{self, FnKind, Visitor}; use crate::parse::{token, ParseSess}; use crate::parse::parser::Parser; use crate::symbol::{Symbol, sym}; use crate::tokenstream::TokenTree; use errors::{Applicability, DiagnosticBuilder, Handler}; use rustc_data_structures::fx::FxHashMap; use rustc_target::spec::abi::Abi; use syntax_pos::{Span, DUMMY_SP, MultiSpan}; use log::debug; use std::env; #[derive(Copy, Clone, Debug)] pub enum Stability { Unstable, // First argument is tracking issue link; second argument is an optional // help message, which defaults to "remove this attribute" Deprecated(&'static str, Option<&'static str>), } struct Context<'a> { features: &'a Features, parse_sess: &'a ParseSess, plugin_attributes: &'a [(Symbol, AttributeType)], } macro_rules! gate_feature_fn { ($cx: expr, $has_feature: expr, $span: expr, $name: expr, $explain: expr, $level: expr) => {{ let (cx, has_feature, span, name, explain, level) = ($cx, $has_feature, $span, $name, $explain, $level); let has_feature: bool = has_feature(&$cx.features); debug!("gate_feature(feature = {:?}, span = {:?}); has? {}", name, span, has_feature); if !has_feature && !span.allows_unstable($name) { leveled_feature_err(cx.parse_sess, name, span, GateIssue::Language, explain, level) .emit(); } }} } macro_rules! gate_feature { ($cx: expr, $feature: ident, $span: expr, $explain: expr) => { gate_feature_fn!($cx, |x:&Features| x.$feature, $span, sym::$feature, $explain, GateStrength::Hard) }; ($cx: expr, $feature: ident, $span: expr, $explain: expr, $level: expr) => { gate_feature_fn!($cx, |x:&Features| x.$feature, $span, sym::$feature, $explain, $level) }; } impl<'a> Context<'a> { fn check_attribute( &self, attr: &ast::Attribute, attr_info: Option<&BuiltinAttribute>, is_macro: bool ) { debug!("check_attribute(attr = {:?})", attr); if let Some(&(name, ty, _template, ref gateage)) = attr_info { if let AttributeGate::Gated(_, name, desc, ref has_feature) = *gateage { if !attr.span.allows_unstable(name) { gate_feature_fn!( self, has_feature, attr.span, name, desc, GateStrength::Hard ); } } else if name == sym::doc { if let Some(content) = attr.meta_item_list() { if content.iter().any(|c| c.check_name(sym::include)) { gate_feature!(self, external_doc, attr.span, "`#[doc(include = \"...\")]` is experimental" ); } } } debug!("check_attribute: {:?} is builtin, {:?}, {:?}", attr.path, ty, gateage); return; } else { for segment in &attr.path.segments { if segment.ident.as_str().starts_with("rustc") { let msg = "attributes starting with `rustc` are \ reserved for use by the `rustc` compiler"; gate_feature!(self, rustc_attrs, segment.ident.span, msg); } } } for &(n, ty) in self.plugin_attributes { if attr.path == n { // Plugins can't gate attributes, so we don't check for it // unlike the code above; we only use this loop to // short-circuit to avoid the checks below. debug!("check_attribute: {:?} is registered by a plugin, {:?}", attr.path, ty); return; } } if !is_macro && !attr::is_known(attr) { // Only run the custom attribute lint during regular feature gate // checking. Macro gating runs before the plugin attributes are // registered, so we skip this in that case. let msg = format!("the attribute `{}` is currently unknown to the compiler and \ may have meaning added to it in the future", attr.path); gate_feature!(self, custom_attribute, attr.span, &msg); } } } pub fn check_attribute(attr: &ast::Attribute, parse_sess: &ParseSess, features: &Features) { let cx = Context { features, parse_sess, plugin_attributes: &[] }; cx.check_attribute( attr, attr.ident().and_then(|ident| BUILTIN_ATTRIBUTE_MAP.get(&ident.name).map(|a| *a)), true ); } fn find_lang_feature_issue(feature: Symbol) -> Option { if let Some(info) = ACTIVE_FEATURES.iter().find(|t| t.0 == feature) { let issue = info.2; // FIXME (#28244): enforce that active features have issue numbers // assert!(issue.is_some()) issue } else { // search in Accepted, Removed, or Stable Removed features let found = ACCEPTED_FEATURES.iter().chain(REMOVED_FEATURES).chain(STABLE_REMOVED_FEATURES) .find(|t| t.0 == feature); match found { Some(&(_, _, issue, _)) => issue, None => panic!("Feature `{}` is not declared anywhere", feature), } } } pub enum GateIssue { Language, Library(Option) } #[derive(Debug, Copy, Clone, PartialEq)] pub enum GateStrength { /// A hard error. (Most feature gates should use this.) Hard, /// Only a warning. (Use this only as backwards-compatibility demands.) Soft, } pub fn emit_feature_err( sess: &ParseSess, feature: Symbol, span: Span, issue: GateIssue, explain: &str, ) { feature_err(sess, feature, span, issue, explain).emit(); } pub fn feature_err<'a, S: Into>( sess: &'a ParseSess, feature: Symbol, span: S, issue: GateIssue, explain: &str, ) -> DiagnosticBuilder<'a> { leveled_feature_err(sess, feature, span, issue, explain, GateStrength::Hard) } fn leveled_feature_err<'a, S: Into>( sess: &'a ParseSess, feature: Symbol, span: S, issue: GateIssue, explain: &str, level: GateStrength, ) -> DiagnosticBuilder<'a> { let diag = &sess.span_diagnostic; let issue = match issue { GateIssue::Language => find_lang_feature_issue(feature), GateIssue::Library(lib) => lib, }; let mut err = match level { GateStrength::Hard => { diag.struct_span_err_with_code(span, explain, stringify_error_code!(E0658)) } GateStrength::Soft => diag.struct_span_warn(span, explain), }; match issue { None | Some(0) => {} // We still accept `0` as a stand-in for backwards compatibility Some(n) => { err.note(&format!( "for more information, see https://github.com/rust-lang/rust/issues/{}", n, )); } } // #23973: do not suggest `#![feature(...)]` if we are in beta/stable if sess.unstable_features.is_nightly_build() { err.help(&format!("add `#![feature({})]` to the crate attributes to enable", feature)); } // If we're on stable and only emitting a "soft" warning, add a note to // clarify that the feature isn't "on" (rather than being on but // warning-worthy). if !sess.unstable_features.is_nightly_build() && level == GateStrength::Soft { err.help("a nightly build of the compiler is required to enable this feature"); } err } const EXPLAIN_BOX_SYNTAX: &str = "box expression syntax is experimental; you can call `Box::new` instead"; pub const EXPLAIN_STMT_ATTR_SYNTAX: &str = "attributes on expressions are experimental"; pub const EXPLAIN_ALLOW_INTERNAL_UNSTABLE: &str = "allow_internal_unstable side-steps feature gating and stability checks"; pub const EXPLAIN_ALLOW_INTERNAL_UNSAFE: &str = "allow_internal_unsafe side-steps the unsafe_code lint"; pub const EXPLAIN_UNSIZED_TUPLE_COERCION: &str = "unsized tuple coercion is not stable enough for use and is subject to change"; struct PostExpansionVisitor<'a> { context: &'a Context<'a>, builtin_attributes: &'static FxHashMap, } macro_rules! gate_feature_post { ($cx: expr, $feature: ident, $span: expr, $explain: expr) => {{ let (cx, span) = ($cx, $span); if !span.allows_unstable(sym::$feature) { gate_feature!(cx.context, $feature, span, $explain) } }}; ($cx: expr, $feature: ident, $span: expr, $explain: expr, $level: expr) => {{ let (cx, span) = ($cx, $span); if !span.allows_unstable(sym::$feature) { gate_feature!(cx.context, $feature, span, $explain, $level) } }} } impl<'a> PostExpansionVisitor<'a> { fn check_abi(&self, abi: Abi, span: Span) { match abi { Abi::RustIntrinsic => { gate_feature_post!(&self, intrinsics, span, "intrinsics are subject to change"); }, Abi::PlatformIntrinsic => { gate_feature_post!(&self, platform_intrinsics, span, "platform intrinsics are experimental and possibly buggy"); }, Abi::Vectorcall => { gate_feature_post!(&self, abi_vectorcall, span, "vectorcall is experimental and subject to change"); }, Abi::Thiscall => { gate_feature_post!(&self, abi_thiscall, span, "thiscall is experimental and subject to change"); }, Abi::RustCall => { gate_feature_post!(&self, unboxed_closures, span, "rust-call ABI is subject to change"); }, Abi::PtxKernel => { gate_feature_post!(&self, abi_ptx, span, "PTX ABIs are experimental and subject to change"); }, Abi::Unadjusted => { gate_feature_post!(&self, abi_unadjusted, span, "unadjusted ABI is an implementation detail and perma-unstable"); }, Abi::Msp430Interrupt => { gate_feature_post!(&self, abi_msp430_interrupt, span, "msp430-interrupt ABI is experimental and subject to change"); }, Abi::X86Interrupt => { gate_feature_post!(&self, abi_x86_interrupt, span, "x86-interrupt ABI is experimental and subject to change"); }, Abi::AmdGpuKernel => { gate_feature_post!(&self, abi_amdgpu_kernel, span, "amdgpu-kernel ABI is experimental and subject to change"); }, // Stable Abi::Cdecl | Abi::Stdcall | Abi::Fastcall | Abi::Aapcs | Abi::Win64 | Abi::SysV64 | Abi::Rust | Abi::C | Abi::System => {} } } } impl<'a> Visitor<'a> for PostExpansionVisitor<'a> { fn visit_attribute(&mut self, attr: &ast::Attribute) { let attr_info = attr.ident().and_then(|ident| { self.builtin_attributes.get(&ident.name).map(|a| *a) }); // Check for gated attributes. self.context.check_attribute(attr, attr_info, false); if attr.check_name(sym::doc) { if let Some(content) = attr.meta_item_list() { if content.len() == 1 && content[0].check_name(sym::cfg) { gate_feature_post!(&self, doc_cfg, attr.span, "`#[doc(cfg(...))]` is experimental" ); } else if content.iter().any(|c| c.check_name(sym::masked)) { gate_feature_post!(&self, doc_masked, attr.span, "`#[doc(masked)]` is experimental" ); } else if content.iter().any(|c| c.check_name(sym::spotlight)) { gate_feature_post!(&self, doc_spotlight, attr.span, "`#[doc(spotlight)]` is experimental" ); } else if content.iter().any(|c| c.check_name(sym::alias)) { gate_feature_post!(&self, doc_alias, attr.span, "`#[doc(alias = \"...\")]` is experimental" ); } else if content.iter().any(|c| c.check_name(sym::keyword)) { gate_feature_post!(&self, doc_keyword, attr.span, "`#[doc(keyword = \"...\")]` is experimental" ); } } } match attr_info { // `rustc_dummy` doesn't have any restrictions specific to built-in attributes. Some(&(name, _, template, _)) if name != sym::rustc_dummy => check_builtin_attribute(self.context.parse_sess, attr, name, template), _ => if let Some(TokenTree::Token(token)) = attr.tokens.trees().next() { if token == token::Eq { // All key-value attributes are restricted to meta-item syntax. attr.parse_meta(self.context.parse_sess).map_err(|mut err| err.emit()).ok(); } } } } fn visit_name(&mut self, sp: Span, name: ast::Name) { if !name.as_str().is_ascii() { gate_feature_post!( &self, non_ascii_idents, self.context.parse_sess.source_map().def_span(sp), "non-ascii idents are not fully supported" ); } } fn visit_item(&mut self, i: &'a ast::Item) { match i.node { ast::ItemKind::ForeignMod(ref foreign_module) => { self.check_abi(foreign_module.abi, i.span); } ast::ItemKind::Fn(..) => { if attr::contains_name(&i.attrs[..], sym::plugin_registrar) { gate_feature_post!(&self, plugin_registrar, i.span, "compiler plugins are experimental and possibly buggy"); } if attr::contains_name(&i.attrs[..], sym::start) { gate_feature_post!(&self, start, i.span, "a `#[start]` function is an experimental \ feature whose signature may change \ over time"); } if attr::contains_name(&i.attrs[..], sym::main) { gate_feature_post!(&self, main, i.span, "declaration of a non-standard `#[main]` \ function may change over time, for now \ a top-level `fn main()` is required"); } } ast::ItemKind::Struct(..) => { for attr in attr::filter_by_name(&i.attrs[..], sym::repr) { for item in attr.meta_item_list().unwrap_or_else(Vec::new) { if item.check_name(sym::simd) { gate_feature_post!(&self, repr_simd, attr.span, "SIMD types are experimental and possibly buggy"); } } } } ast::ItemKind::Enum(ast::EnumDef{ref variants, ..}, ..) => { for variant in variants { match (&variant.data, &variant.disr_expr) { (ast::VariantData::Unit(..), _) => {}, (_, Some(disr_expr)) => gate_feature_post!( &self, arbitrary_enum_discriminant, disr_expr.value.span, "discriminants on non-unit variants are experimental"), _ => {}, } } let has_feature = self.context.features.arbitrary_enum_discriminant; if !has_feature && !i.span.allows_unstable(sym::arbitrary_enum_discriminant) { Parser::maybe_report_invalid_custom_discriminants( self.context.parse_sess, &variants, ); } } ast::ItemKind::Impl(_, polarity, defaultness, _, _, _, _) => { if polarity == ast::ImplPolarity::Negative { gate_feature_post!(&self, optin_builtin_traits, i.span, "negative trait bounds are not yet fully implemented; \ use marker types for now"); } if let ast::Defaultness::Default = defaultness { gate_feature_post!(&self, specialization, i.span, "specialization is unstable"); } } ast::ItemKind::Trait(ast::IsAuto::Yes, ..) => { gate_feature_post!(&self, optin_builtin_traits, i.span, "auto traits are experimental and possibly buggy"); } ast::ItemKind::TraitAlias(..) => { gate_feature_post!( &self, trait_alias, i.span, "trait aliases are experimental" ); } ast::ItemKind::MacroDef(ast::MacroDef { legacy: false, .. }) => { let msg = "`macro` is experimental"; gate_feature_post!(&self, decl_macro, i.span, msg); } ast::ItemKind::OpaqueTy(..) => { gate_feature_post!( &self, type_alias_impl_trait, i.span, "`impl Trait` in type aliases is unstable" ); } _ => {} } visit::walk_item(self, i); } fn visit_foreign_item(&mut self, i: &'a ast::ForeignItem) { match i.node { ast::ForeignItemKind::Fn(..) | ast::ForeignItemKind::Static(..) => { let link_name = attr::first_attr_value_str_by_name(&i.attrs, sym::link_name); let links_to_llvm = match link_name { Some(val) => val.as_str().starts_with("llvm."), _ => false }; if links_to_llvm { gate_feature_post!(&self, link_llvm_intrinsics, i.span, "linking to LLVM intrinsics is experimental"); } } ast::ForeignItemKind::Ty => { gate_feature_post!(&self, extern_types, i.span, "extern types are experimental"); } ast::ForeignItemKind::Macro(..) => {} } visit::walk_foreign_item(self, i) } fn visit_ty(&mut self, ty: &'a ast::Ty) { match ty.node { ast::TyKind::BareFn(ref bare_fn_ty) => { self.check_abi(bare_fn_ty.abi, ty.span); } ast::TyKind::Never => { gate_feature_post!(&self, never_type, ty.span, "The `!` type is experimental"); } _ => {} } visit::walk_ty(self, ty) } fn visit_fn_ret_ty(&mut self, ret_ty: &'a ast::FunctionRetTy) { if let ast::FunctionRetTy::Ty(ref output_ty) = *ret_ty { if let ast::TyKind::Never = output_ty.node { // Do nothing. } else { self.visit_ty(output_ty) } } } fn visit_expr(&mut self, e: &'a ast::Expr) { match e.node { ast::ExprKind::Box(_) => { gate_feature_post!(&self, box_syntax, e.span, EXPLAIN_BOX_SYNTAX); } ast::ExprKind::Type(..) => { // To avoid noise about type ascription in common syntax errors, only emit if it // is the *only* error. if self.context.parse_sess.span_diagnostic.err_count() == 0 { gate_feature_post!(&self, type_ascription, e.span, "type ascription is experimental"); } } ast::ExprKind::TryBlock(_) => { gate_feature_post!(&self, try_blocks, e.span, "`try` expression is experimental"); } ast::ExprKind::Block(_, opt_label) => { if let Some(label) = opt_label { gate_feature_post!(&self, label_break_value, label.ident.span, "labels on blocks are unstable"); } } _ => {} } visit::walk_expr(self, e) } fn visit_arm(&mut self, arm: &'a ast::Arm) { visit::walk_arm(self, arm) } fn visit_pat(&mut self, pattern: &'a ast::Pat) { match &pattern.node { PatKind::Slice(pats) => { for pat in &*pats { let span = pat.span; let inner_pat = match &pat.node { PatKind::Ident(.., Some(pat)) => pat, _ => pat, }; if inner_pat.is_rest() { gate_feature_post!( &self, slice_patterns, span, "subslice patterns are unstable" ); } } } PatKind::Box(..) => { gate_feature_post!(&self, box_patterns, pattern.span, "box pattern syntax is experimental"); } PatKind::Range(_, _, Spanned { node: RangeEnd::Excluded, .. }) => { gate_feature_post!(&self, exclusive_range_pattern, pattern.span, "exclusive range pattern syntax is experimental"); } _ => {} } visit::walk_pat(self, pattern) } fn visit_fn(&mut self, fn_kind: FnKind<'a>, fn_decl: &'a ast::FnDecl, span: Span, _node_id: NodeId) { if let Some(header) = fn_kind.header() { // Stability of const fn methods are covered in // `visit_trait_item` and `visit_impl_item` below; this is // because default methods don't pass through this point. self.check_abi(header.abi, span); } if fn_decl.c_variadic { gate_feature_post!(&self, c_variadic, span, "C-variadic functions are unstable"); } visit::walk_fn(self, fn_kind, fn_decl, span) } fn visit_generic_param(&mut self, param: &'a GenericParam) { match param.kind { GenericParamKind::Const { .. } => gate_feature_post!(&self, const_generics, param.ident.span, "const generics are unstable"), _ => {} } visit::walk_generic_param(self, param) } fn visit_assoc_ty_constraint(&mut self, constraint: &'a AssocTyConstraint) { match constraint.kind { AssocTyConstraintKind::Bound { .. } => gate_feature_post!(&self, associated_type_bounds, constraint.span, "associated type bounds are unstable"), _ => {} } visit::walk_assoc_ty_constraint(self, constraint) } fn visit_trait_item(&mut self, ti: &'a ast::TraitItem) { match ti.node { ast::TraitItemKind::Method(ref sig, ref block) => { if block.is_none() { self.check_abi(sig.header.abi, ti.span); } if sig.decl.c_variadic { gate_feature_post!(&self, c_variadic, ti.span, "C-variadic functions are unstable"); } if sig.header.constness.node == ast::Constness::Const { gate_feature_post!(&self, const_fn, ti.span, "const fn is unstable"); } } ast::TraitItemKind::Type(_, ref default) => { // We use three if statements instead of something like match guards so that all // of these errors can be emitted if all cases apply. if default.is_some() { gate_feature_post!(&self, associated_type_defaults, ti.span, "associated type defaults are unstable"); } if !ti.generics.params.is_empty() { gate_feature_post!(&self, generic_associated_types, ti.span, "generic associated types are unstable"); } if !ti.generics.where_clause.predicates.is_empty() { gate_feature_post!(&self, generic_associated_types, ti.span, "where clauses on associated types are unstable"); } } _ => {} } visit::walk_trait_item(self, ti) } fn visit_impl_item(&mut self, ii: &'a ast::ImplItem) { if ii.defaultness == ast::Defaultness::Default { gate_feature_post!(&self, specialization, ii.span, "specialization is unstable"); } match ii.node { ast::ImplItemKind::Method(..) => {} ast::ImplItemKind::OpaqueTy(..) => { gate_feature_post!( &self, type_alias_impl_trait, ii.span, "`impl Trait` in type aliases is unstable" ); } ast::ImplItemKind::TyAlias(_) => { if !ii.generics.params.is_empty() { gate_feature_post!(&self, generic_associated_types, ii.span, "generic associated types are unstable"); } if !ii.generics.where_clause.predicates.is_empty() { gate_feature_post!(&self, generic_associated_types, ii.span, "where clauses on associated types are unstable"); } } _ => {} } visit::walk_impl_item(self, ii) } fn visit_vis(&mut self, vis: &'a ast::Visibility) { if let ast::VisibilityKind::Crate(ast::CrateSugar::JustCrate) = vis.node { gate_feature_post!(&self, crate_visibility_modifier, vis.span, "`crate` visibility modifier is experimental"); } visit::walk_vis(self, vis) } } pub fn get_features(span_handler: &Handler, krate_attrs: &[ast::Attribute], crate_edition: Edition, allow_features: &Option>) -> Features { fn feature_removed(span_handler: &Handler, span: Span, reason: Option<&str>) { let mut err = struct_span_err!(span_handler, span, E0557, "feature has been removed"); if let Some(reason) = reason { err.span_note(span, reason); } else { err.span_label(span, "feature has been removed"); } err.emit(); } let mut features = Features::new(); let mut edition_enabled_features = FxHashMap::default(); for &edition in ALL_EDITIONS { if edition <= crate_edition { // The `crate_edition` implies its respective umbrella feature-gate // (i.e., `#![feature(rust_20XX_preview)]` isn't needed on edition 20XX). edition_enabled_features.insert(edition.feature_name(), edition); } } for &(name, .., f_edition, set) in ACTIVE_FEATURES { if let Some(f_edition) = f_edition { if f_edition <= crate_edition { set(&mut features, DUMMY_SP); edition_enabled_features.insert(name, crate_edition); } } } // Process the edition umbrella feature-gates first, to ensure // `edition_enabled_features` is completed before it's queried. for attr in krate_attrs { if !attr.check_name(sym::feature) { continue } let list = match attr.meta_item_list() { Some(list) => list, None => continue, }; for mi in list { if !mi.is_word() { continue; } let name = mi.name_or_empty(); if let Some(edition) = ALL_EDITIONS.iter().find(|e| name == e.feature_name()) { if *edition <= crate_edition { continue; } for &(name, .., f_edition, set) in ACTIVE_FEATURES { if let Some(f_edition) = f_edition { if f_edition <= *edition { // FIXME(Manishearth) there is currently no way to set // lib features by edition set(&mut features, DUMMY_SP); edition_enabled_features.insert(name, *edition); } } } } } } for attr in krate_attrs { if !attr.check_name(sym::feature) { continue } let list = match attr.meta_item_list() { Some(list) => list, None => continue, }; let bad_input = |span| { struct_span_err!(span_handler, span, E0556, "malformed `feature` attribute input") }; for mi in list { let name = match mi.ident() { Some(ident) if mi.is_word() => ident.name, Some(ident) => { bad_input(mi.span()).span_suggestion( mi.span(), "expected just one word", format!("{}", ident.name), Applicability::MaybeIncorrect, ).emit(); continue } None => { bad_input(mi.span()).span_label(mi.span(), "expected just one word").emit(); continue } }; if let Some(edition) = edition_enabled_features.get(&name) { struct_span_warn!( span_handler, mi.span(), E0705, "the feature `{}` is included in the Rust {} edition", name, edition, ).emit(); continue; } if ALL_EDITIONS.iter().any(|e| name == e.feature_name()) { // Handled in the separate loop above. continue; } let removed = REMOVED_FEATURES.iter().find(|f| name == f.0); let stable_removed = STABLE_REMOVED_FEATURES.iter().find(|f| name == f.0); if let Some((.., reason)) = removed.or(stable_removed) { feature_removed(span_handler, mi.span(), *reason); continue; } if let Some((_, since, ..)) = ACCEPTED_FEATURES.iter().find(|f| name == f.0) { let since = Some(Symbol::intern(since)); features.declared_lang_features.push((name, mi.span(), since)); continue; } if let Some(allowed) = allow_features.as_ref() { if allowed.iter().find(|f| *f == name.as_str()).is_none() { span_err!(span_handler, mi.span(), E0725, "the feature `{}` is not in the list of allowed features", name); continue; } } if let Some((.., set)) = ACTIVE_FEATURES.iter().find(|f| name == f.0) { set(&mut features, mi.span()); features.declared_lang_features.push((name, mi.span(), None)); continue; } features.declared_lib_features.push((name, mi.span())); } } features } pub fn check_crate(krate: &ast::Crate, sess: &ParseSess, features: &Features, plugin_attributes: &[(Symbol, AttributeType)], unstable: UnstableFeatures) { maybe_stage_features(&sess.span_diagnostic, krate, unstable); let ctx = Context { features, parse_sess: sess, plugin_attributes, }; macro_rules! gate_all { ($gate:ident, $msg:literal) => { gate_all!($gate, $gate, $msg); }; ($spans:ident, $gate:ident, $msg:literal) => { for span in &*sess.gated_spans.$spans.borrow() { gate_feature!(&ctx, $gate, *span, $msg); } } } gate_all!(param_attrs, "attributes on function parameters are unstable"); gate_all!(let_chains, "`let` expressions in this position are experimental"); gate_all!(async_closure, "async closures are unstable"); gate_all!(yields, generators, "yield syntax is experimental"); gate_all!(or_patterns, "or-patterns syntax is experimental"); let visitor = &mut PostExpansionVisitor { context: &ctx, builtin_attributes: &*BUILTIN_ATTRIBUTE_MAP, }; visit::walk_crate(visitor, krate); } #[derive(Clone, Copy, Hash)] pub enum UnstableFeatures { /// Hard errors for unstable features are active, as on beta/stable channels. Disallow, /// Allow features to be activated, as on nightly. Allow, /// Errors are bypassed for bootstrapping. This is required any time /// during the build that feature-related lints are set to warn or above /// because the build turns on warnings-as-errors and uses lots of unstable /// features. As a result, this is always required for building Rust itself. Cheat } impl UnstableFeatures { pub fn from_environment() -> UnstableFeatures { // Whether this is a feature-staged build, i.e., on the beta or stable channel let disable_unstable_features = option_env!("CFG_DISABLE_UNSTABLE_FEATURES").is_some(); // Whether we should enable unstable features for bootstrapping let bootstrap = env::var("RUSTC_BOOTSTRAP").is_ok(); match (disable_unstable_features, bootstrap) { (_, true) => UnstableFeatures::Cheat, (true, _) => UnstableFeatures::Disallow, (false, _) => UnstableFeatures::Allow } } pub fn is_nightly_build(&self) -> bool { match *self { UnstableFeatures::Allow | UnstableFeatures::Cheat => true, _ => false, } } } fn maybe_stage_features(span_handler: &Handler, krate: &ast::Crate, unstable: UnstableFeatures) { let allow_features = match unstable { UnstableFeatures::Allow => true, UnstableFeatures::Disallow => false, UnstableFeatures::Cheat => true }; if !allow_features { for attr in &krate.attrs { if attr.check_name(sym::feature) { let release_channel = option_env!("CFG_RELEASE_CHANNEL").unwrap_or("(unknown)"); span_err!(span_handler, attr.span, E0554, "`#![feature]` may not be used on the {} release channel", release_channel); } } } }