mikros/rust
1
0
Fork 0
Code Issues Pull Requests Packages Projects Releases Wiki Activity
rust/compiler/rustc_resolve/src/lib.rs

3429 lines
133 KiB
Rust
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

// ignore-tidy-filelength
//! This crate is responsible for the part of name resolution that doesn't require type checker.
//!
//! Module structure of the crate is built here.
//! Paths in macros, imports, expressions, types, patterns are resolved here.
//! Label and lifetime names are resolved here as well.
//!
//! Type-relative name resolution (methods, fields, associated items) happens in `librustc_typeck`.
#![doc(html_root_url = "https://doc.rust-lang.org/nightly/nightly-rustc/")]
#![feature(bool_to_option)]
#![feature(crate_visibility_modifier)]
#![feature(format_args_capture)]
#![feature(nll)]
#![feature(or_patterns)]
#![recursion_limit = "256"]
pub use rustc_hir::def::{Namespace, PerNS};
use Determinacy::*;
use rustc_arena::{DroplessArena, TypedArena};
use rustc_ast::node_id::NodeMap;
use rustc_ast::unwrap_or;
use rustc_ast::visit::{self, Visitor};
use rustc_ast::{self as ast, FloatTy, IntTy, NodeId, UintTy};
use rustc_ast::{Crate, CRATE_NODE_ID};
use rustc_ast::{ItemKind, Path};
use rustc_ast_lowering::ResolverAstLowering;
use rustc_ast_pretty::pprust;
use rustc_data_structures::fx::{FxHashMap, FxHashSet, FxIndexMap};
use rustc_data_structures::ptr_key::PtrKey;
use rustc_data_structures::sync::Lrc;
use rustc_errors::{struct_span_err, Applicability, DiagnosticBuilder};
use rustc_expand::base::{SyntaxExtension, SyntaxExtensionKind};
use rustc_hir::def::Namespace::*;
use rustc_hir::def::{self, CtorOf, DefKind, NonMacroAttrKind, PartialRes};
use rustc_hir::def_id::{CrateNum, DefId, DefIdMap, LocalDefId, CRATE_DEF_INDEX};
use rustc_hir::definitions::{DefKey, DefPathData, Definitions};
use rustc_hir::PrimTy::{self, Bool, Char, Float, Int, Str, Uint};
use rustc_hir::TraitCandidate;
use rustc_index::vec::IndexVec;
use rustc_metadata::creader::{CStore, CrateLoader};
use rustc_middle::hir::exports::ExportMap;
use rustc_middle::middle::cstore::{CrateStore, MetadataLoaderDyn};
use rustc_middle::ty::query::Providers;
use rustc_middle::ty::{self, DefIdTree, ResolverOutputs};
use rustc_middle::{bug, span_bug};
use rustc_session::lint;
use rustc_session::lint::{BuiltinLintDiagnostics, LintBuffer};
use rustc_session::Session;
use rustc_span::edition::Edition;
use rustc_span::hygiene::{ExpnId, ExpnKind, MacroKind, SyntaxContext, Transparency};
use rustc_span::source_map::Spanned;
use rustc_span::symbol::{kw, sym, Ident, Symbol};
use rustc_span::{Span, DUMMY_SP};
use smallvec::{smallvec, SmallVec};
use std::cell::{Cell, RefCell};
use std::collections::BTreeSet;
use std::{cmp, fmt, iter, ptr};
use tracing::debug;
use diagnostics::{extend_span_to_previous_binding, find_span_of_binding_until_next_binding};
use diagnostics::{ImportSuggestion, LabelSuggestion, Suggestion};
use imports::{Import, ImportKind, ImportResolver, NameResolution};
use late::{ConstantItemKind, HasGenericParams, PathSource, Rib, RibKind::*};
use macros::{MacroRulesBinding, MacroRulesScope, MacroRulesScopeRef};
type Res = def::Res<NodeId>;
mod build_reduced_graph;
mod check_unused;
mod def_collector;
mod diagnostics;
mod imports;
mod late;
mod macros;
enum Weak {
Yes,
No,
}
#[derive(Copy, Clone, PartialEq, Debug)]
pub enum Determinacy {
Determined,
Undetermined,
}
impl Determinacy {
fn determined(determined: bool) -> Determinacy {
if determined { Determinacy::Determined } else { Determinacy::Undetermined }
}
}
/// A specific scope in which a name can be looked up.
/// This enum is currently used only for early resolution (imports and macros),
/// but not for late resolution yet.
#[derive(Clone, Copy)]
enum Scope<'a> {
DeriveHelpers(ExpnId),
DeriveHelpersCompat,
MacroRules(MacroRulesScopeRef<'a>),
CrateRoot,
Module(Module<'a>),
RegisteredAttrs,
MacroUsePrelude,
BuiltinAttrs,
ExternPrelude,
ToolPrelude,
StdLibPrelude,
BuiltinTypes,
}
/// Names from different contexts may want to visit different subsets of all specific scopes
/// with different restrictions when looking up the resolution.
/// This enum is currently used only for early resolution (imports and macros),
/// but not for late resolution yet.
enum ScopeSet {
/// All scopes with the given namespace.
All(Namespace, /*is_import*/ bool),
/// Crate root, then extern prelude (used for mixed 2015-2018 mode in macros).
AbsolutePath(Namespace),
/// All scopes with macro namespace and the given macro kind restriction.
Macro(MacroKind),
}
/// Everything you need to know about a name's location to resolve it.
/// Serves as a starting point for the scope visitor.
/// This struct is currently used only for early resolution (imports and macros),
/// but not for late resolution yet.
#[derive(Clone, Copy, Debug)]
pub struct ParentScope<'a> {
module: Module<'a>,
expansion: ExpnId,
macro_rules: MacroRulesScopeRef<'a>,
derives: &'a [ast::Path],
}
impl<'a> ParentScope<'a> {
/// Creates a parent scope with the passed argument used as the module scope component,
/// and other scope components set to default empty values.
pub fn module(module: Module<'a>, resolver: &Resolver<'a>) -> ParentScope<'a> {
ParentScope {
module,
expansion: ExpnId::root(),
macro_rules: resolver.arenas.alloc_macro_rules_scope(MacroRulesScope::Empty),
derives: &[],
}
}
}
#[derive(Eq)]
struct BindingError {
name: Symbol,
origin: BTreeSet<Span>,
target: BTreeSet<Span>,
could_be_path: bool,
}
impl PartialOrd for BindingError {
fn partial_cmp(&self, other: &BindingError) -> Option<cmp::Ordering> {
Some(self.cmp(other))
}
}
impl PartialEq for BindingError {
fn eq(&self, other: &BindingError) -> bool {
self.name == other.name
}
}
impl Ord for BindingError {
fn cmp(&self, other: &BindingError) -> cmp::Ordering {
self.name.cmp(&other.name)
}
}
enum ResolutionError<'a> {
/// Error E0401: can't use type or const parameters from outer function.
GenericParamsFromOuterFunction(Res, HasGenericParams),
/// Error E0403: the name is already used for a type or const parameter in this generic
/// parameter list.
NameAlreadyUsedInParameterList(Symbol, Span),
/// Error E0407: method is not a member of trait.
MethodNotMemberOfTrait(Symbol, &'a str),
/// Error E0437: type is not a member of trait.
TypeNotMemberOfTrait(Symbol, &'a str),
/// Error E0438: const is not a member of trait.
ConstNotMemberOfTrait(Symbol, &'a str),
/// Error E0408: variable `{}` is not bound in all patterns.
VariableNotBoundInPattern(&'a BindingError),
/// Error E0409: variable `{}` is bound in inconsistent ways within the same match arm.
VariableBoundWithDifferentMode(Symbol, Span),
/// Error E0415: identifier is bound more than once in this parameter list.
IdentifierBoundMoreThanOnceInParameterList(Symbol),
/// Error E0416: identifier is bound more than once in the same pattern.
IdentifierBoundMoreThanOnceInSamePattern(Symbol),
/// Error E0426: use of undeclared label.
UndeclaredLabel { name: Symbol, suggestion: Option<LabelSuggestion> },
/// Error E0429: `self` imports are only allowed within a `{ }` list.
SelfImportsOnlyAllowedWithin { root: bool, span_with_rename: Span },
/// Error E0430: `self` import can only appear once in the list.
SelfImportCanOnlyAppearOnceInTheList,
/// Error E0431: `self` import can only appear in an import list with a non-empty prefix.
SelfImportOnlyInImportListWithNonEmptyPrefix,
/// Error E0433: failed to resolve.
FailedToResolve { label: String, suggestion: Option<Suggestion> },
/// Error E0434: can't capture dynamic environment in a fn item.
CannotCaptureDynamicEnvironmentInFnItem,
/// Error E0435: attempt to use a non-constant value in a constant.
AttemptToUseNonConstantValueInConstant(
Ident,
/* suggestion */ &'static str,
/* current */ &'static str,
),
/// Error E0530: `X` bindings cannot shadow `Y`s.
BindingShadowsSomethingUnacceptable(&'static str, Symbol, &'a NameBinding<'a>),
/// Error E0128: type parameters with a default cannot use forward-declared identifiers.
ForwardDeclaredTyParam, // FIXME(const_generics_defaults)
/// ERROR E0770: the type of const parameters must not depend on other generic parameters.
ParamInTyOfConstParam(Symbol),
/// constant values inside of type parameter defaults must not depend on generic parameters.
ParamInAnonConstInTyDefault(Symbol),
/// generic parameters must not be used inside const evaluations.
///
/// This error is only emitted when using `min_const_generics`.
ParamInNonTrivialAnonConst { name: Symbol, is_type: bool },
/// Error E0735: type parameters with a default cannot use `Self`
SelfInTyParamDefault,
/// Error E0767: use of unreachable label
UnreachableLabel { name: Symbol, definition_span: Span, suggestion: Option<LabelSuggestion> },
}
enum VisResolutionError<'a> {
Relative2018(Span, &'a ast::Path),
AncestorOnly(Span),
FailedToResolve(Span, String, Option<Suggestion>),
ExpectedFound(Span, String, Res),
Indeterminate(Span),
ModuleOnly(Span),
}
/// A minimal representation of a path segment. We use this in resolve because we synthesize 'path
/// segments' which don't have the rest of an AST or HIR `PathSegment`.
#[derive(Clone, Copy, Debug)]
pub struct Segment {
ident: Ident,
id: Option<NodeId>,
/// Signals whether this `PathSegment` has generic arguments. Used to avoid providing
/// nonsensical suggestions.
has_generic_args: bool,
}
impl Segment {
fn from_path(path: &Path) -> Vec<Segment> {
path.segments.iter().map(|s| s.into()).collect()
}
fn from_ident(ident: Ident) -> Segment {
Segment { ident, id: None, has_generic_args: false }
}
fn names_to_string(segments: &[Segment]) -> String {
names_to_string(&segments.iter().map(|seg| seg.ident.name).collect::<Vec<_>>())
}
}
impl<'a> From<&'a ast::PathSegment> for Segment {
fn from(seg: &'a ast::PathSegment) -> Segment {
Segment { ident: seg.ident, id: Some(seg.id), has_generic_args: seg.args.is_some() }
}
}
struct UsePlacementFinder {
target_module: NodeId,
span: Option<Span>,
found_use: bool,
}
impl UsePlacementFinder {
fn check(krate: &Crate, target_module: NodeId) -> (Option<Span>, bool) {
let mut finder = UsePlacementFinder { target_module, span: None, found_use: false };
visit::walk_crate(&mut finder, krate);
(finder.span, finder.found_use)
}
}
impl<'tcx> Visitor<'tcx> for UsePlacementFinder {
fn visit_mod(
&mut self,
module: &'tcx ast::Mod,
_: Span,
_: &[ast::Attribute],
node_id: NodeId,
) {
if self.span.is_some() {
return;
}
if node_id != self.target_module {
visit::walk_mod(self, module);
return;
}
// find a use statement
for item in &module.items {
match item.kind {
ItemKind::Use(..) => {
// don't suggest placing a use before the prelude
// import or other generated ones
if !item.span.from_expansion() {
self.span = Some(item.span.shrink_to_lo());
self.found_use = true;
return;
}
}
// don't place use before extern crate
ItemKind::ExternCrate(_) => {}
// but place them before the first other item
_ => {
if self.span.map_or(true, |span| item.span < span)
&& !item.span.from_expansion()
{
// don't insert between attributes and an item
if item.attrs.is_empty() {
self.span = Some(item.span.shrink_to_lo());
} else {
// find the first attribute on the item
for attr in &item.attrs {
if self.span.map_or(true, |span| attr.span < span) {
self.span = Some(attr.span.shrink_to_lo());
}
}
}
}
}
}
}
}
}
/// An intermediate resolution result.
///
/// This refers to the thing referred by a name. The difference between `Res` and `Item` is that
/// items are visible in their whole block, while `Res`es only from the place they are defined
/// forward.
#[derive(Debug)]
enum LexicalScopeBinding<'a> {
Item(&'a NameBinding<'a>),
Res(Res),
}
impl<'a> LexicalScopeBinding<'a> {
fn res(self) -> Res {
match self {
LexicalScopeBinding::Item(binding) => binding.res(),
LexicalScopeBinding::Res(res) => res,
}
}
}
#[derive(Copy, Clone, Debug)]
enum ModuleOrUniformRoot<'a> {
/// Regular module.
Module(Module<'a>),
/// Virtual module that denotes resolution in crate root with fallback to extern prelude.
CrateRootAndExternPrelude,
/// Virtual module that denotes resolution in extern prelude.
/// Used for paths starting with `::` on 2018 edition.
ExternPrelude,
/// Virtual module that denotes resolution in current scope.
/// Used only for resolving single-segment imports. The reason it exists is that import paths
/// are always split into two parts, the first of which should be some kind of module.
CurrentScope,
}
impl ModuleOrUniformRoot<'_> {
fn same_def(lhs: Self, rhs: Self) -> bool {
match (lhs, rhs) {
(ModuleOrUniformRoot::Module(lhs), ModuleOrUniformRoot::Module(rhs)) => {
lhs.def_id() == rhs.def_id()
}
(
ModuleOrUniformRoot::CrateRootAndExternPrelude,
ModuleOrUniformRoot::CrateRootAndExternPrelude,
)
| (ModuleOrUniformRoot::ExternPrelude, ModuleOrUniformRoot::ExternPrelude)
| (ModuleOrUniformRoot::CurrentScope, ModuleOrUniformRoot::CurrentScope) => true,
_ => false,
}
}
}
#[derive(Clone, Debug)]
enum PathResult<'a> {
Module(ModuleOrUniformRoot<'a>),
NonModule(PartialRes),
Indeterminate,
Failed {
span: Span,
label: String,
suggestion: Option<Suggestion>,
is_error_from_last_segment: bool,
},
}
#[derive(Debug)]
enum ModuleKind {
/// An anonymous module; e.g., just a block.
///
/// ```
/// fn main() {
/// fn f() {} // (1)
/// { // This is an anonymous module
/// f(); // This resolves to (2) as we are inside the block.
/// fn f() {} // (2)
/// }
/// f(); // Resolves to (1)
/// }
/// ```
Block(NodeId),
/// Any module with a name.
///
/// This could be:
///
/// * A normal module either `mod from_file;` or `mod from_block { }`
/// or the crate root (which is conceptually a top-level module).
/// Note that the crate root's [name][Self::name] will be [`kw::Empty`].
/// * A trait or an enum (it implicitly contains associated types, methods and variant
/// constructors).
Def(DefKind, DefId, Symbol),
}
impl ModuleKind {
/// Get name of the module.
pub fn name(&self) -> Option<Symbol> {
match self {
ModuleKind::Block(..) => None,
ModuleKind::Def(.., name) => Some(*name),
}
}
}
/// A key that identifies a binding in a given `Module`.
///
/// Multiple bindings in the same module can have the same key (in a valid
/// program) if all but one of them come from glob imports.
#[derive(Copy, Clone, PartialEq, Eq, Hash, Debug)]
struct BindingKey {
/// The identifier for the binding, aways the `normalize_to_macros_2_0` version of the
/// identifier.
ident: Ident,
ns: Namespace,
/// 0 if ident is not `_`, otherwise a value that's unique to the specific
/// `_` in the expanded AST that introduced this binding.
disambiguator: u32,
}
type Resolutions<'a> = RefCell<FxIndexMap<BindingKey, &'a RefCell<NameResolution<'a>>>>;
/// One node in the tree of modules.
///
/// Note that a "module" in resolve is broader than a `mod` that you declare in Rust code. It may be one of these:
///
/// * `mod`
/// * crate root (aka, top-level anonymous module)
/// * `enum`
/// * `trait`
/// * curly-braced block with statements
///
/// You can use [`ModuleData::kind`] to determine the kind of module this is.
pub struct ModuleData<'a> {
/// The direct parent module (it may not be a `mod`, however).
parent: Option<Module<'a>>,
/// What kind of module this is, because this may not be a `mod`.
kind: ModuleKind,
/// The [`DefId`] of the nearest `mod` item ancestor (which may be this module).
/// This may be the crate root.
nearest_parent_mod: DefId,
/// Mapping between names and their (possibly in-progress) resolutions in this module.
/// Resolutions in modules from other crates are not populated until accessed.
lazy_resolutions: Resolutions<'a>,
/// True if this is a module from other crate that needs to be populated on access.
populate_on_access: Cell<bool>,
/// Macro invocations that can expand into items in this module.
unexpanded_invocations: RefCell<FxHashSet<ExpnId>>,
/// Whether `#[no_implicit_prelude]` is active.
no_implicit_prelude: bool,
glob_importers: RefCell<Vec<&'a Import<'a>>>,
globs: RefCell<Vec<&'a Import<'a>>>,
/// Used to memoize the traits in this module for faster searches through all traits in scope.
traits: RefCell<Option<Box<[(Ident, &'a NameBinding<'a>)]>>>,
/// Span of the module itself. Used for error reporting.
span: Span,
expansion: ExpnId,
}
type Module<'a> = &'a ModuleData<'a>;
impl<'a> ModuleData<'a> {
fn new(
parent: Option<Module<'a>>,
kind: ModuleKind,
nearest_parent_mod: DefId,
expansion: ExpnId,
span: Span,
) -> Self {
ModuleData {
parent,
kind,
nearest_parent_mod,
lazy_resolutions: Default::default(),
populate_on_access: Cell::new(!nearest_parent_mod.is_local()),
unexpanded_invocations: Default::default(),
no_implicit_prelude: false,
glob_importers: RefCell::new(Vec::new()),
globs: RefCell::new(Vec::new()),
traits: RefCell::new(None),
span,
expansion,
}
}
fn for_each_child<R, F>(&'a self, resolver: &mut R, mut f: F)
where
R: AsMut<Resolver<'a>>,
F: FnMut(&mut R, Ident, Namespace, &'a NameBinding<'a>),
{
for (key, name_resolution) in resolver.as_mut().resolutions(self).borrow().iter() {
if let Some(binding) = name_resolution.borrow().binding {
f(resolver, key.ident, key.ns, binding);
}
}
}
/// This modifies `self` in place. The traits will be stored in `self.traits`.
fn ensure_traits<R>(&'a self, resolver: &mut R)
where
R: AsMut<Resolver<'a>>,
{
let mut traits = self.traits.borrow_mut();
if traits.is_none() {
let mut collected_traits = Vec::new();
self.for_each_child(resolver, |_, name, ns, binding| {
if ns != TypeNS {
return;
}
if let Res::Def(DefKind::Trait | DefKind::TraitAlias, _) = binding.res() {
collected_traits.push((name, binding))
}
});
*traits = Some(collected_traits.into_boxed_slice());
}
}
fn res(&self) -> Option<Res> {
match self.kind {
ModuleKind::Def(kind, def_id, _) => Some(Res::Def(kind, def_id)),
_ => None,
}
}
fn def_id(&self) -> Option<DefId> {
match self.kind {
ModuleKind::Def(_, def_id, _) => Some(def_id),
_ => None,
}
}
// `self` resolves to the first module ancestor that `is_normal`.
fn is_normal(&self) -> bool {
matches!(self.kind, ModuleKind::Def(DefKind::Mod, _, _))
}
fn is_trait(&self) -> bool {
matches!(self.kind, ModuleKind::Def(DefKind::Trait, _, _))
}
fn nearest_item_scope(&'a self) -> Module<'a> {
match self.kind {
ModuleKind::Def(DefKind::Enum | DefKind::Trait, ..) => {
self.parent.expect("enum or trait module without a parent")
}
_ => self,
}
}
fn is_ancestor_of(&self, mut other: &Self) -> bool {
while !ptr::eq(self, other) {
if let Some(parent) = other.parent {
other = parent;
} else {
return false;
}
}
true
}
}
impl<'a> fmt::Debug for ModuleData<'a> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f, "{:?}", self.res())
}
}
/// Records a possibly-private value, type, or module definition.
#[derive(Clone, Debug)]
pub struct NameBinding<'a> {
kind: NameBindingKind<'a>,
ambiguity: Option<(&'a NameBinding<'a>, AmbiguityKind)>,
expansion: ExpnId,
span: Span,
vis: ty::Visibility,
}
pub trait ToNameBinding<'a> {
fn to_name_binding(self, arenas: &'a ResolverArenas<'a>) -> &'a NameBinding<'a>;
}
impl<'a> ToNameBinding<'a> for &'a NameBinding<'a> {
fn to_name_binding(self, _: &'a ResolverArenas<'a>) -> &'a NameBinding<'a> {
self
}
}
#[derive(Clone, Debug)]
enum NameBindingKind<'a> {
Res(Res, /* is_macro_export */ bool),
Module(Module<'a>),
Import { binding: &'a NameBinding<'a>, import: &'a Import<'a>, used: Cell<bool> },
}
impl<'a> NameBindingKind<'a> {
/// Is this a name binding of a import?
fn is_import(&self) -> bool {
matches!(*self, NameBindingKind::Import { .. })
}
}
struct PrivacyError<'a> {
ident: Ident,
binding: &'a NameBinding<'a>,
dedup_span: Span,
}
struct UseError<'a> {
err: DiagnosticBuilder<'a>,
/// Candidates which user could `use` to access the missing type.
candidates: Vec<ImportSuggestion>,
/// The `DefId` of the module to place the use-statements in.
def_id: DefId,
/// Whether the diagnostic should say "instead" (as in `consider importing ... instead`).
instead: bool,
/// Extra free-form suggestion.
suggestion: Option<(Span, &'static str, String, Applicability)>,
}
#[derive(Clone, Copy, PartialEq, Debug)]
enum AmbiguityKind {
Import,
BuiltinAttr,
DeriveHelper,
MacroRulesVsModularized,
GlobVsOuter,
GlobVsGlob,
GlobVsExpanded,
MoreExpandedVsOuter,
}
impl AmbiguityKind {
fn descr(self) -> &'static str {
match self {
AmbiguityKind::Import => "name vs any other name during import resolution",
AmbiguityKind::BuiltinAttr => "built-in attribute vs any other name",
AmbiguityKind::DeriveHelper => "derive helper attribute vs any other name",
AmbiguityKind::MacroRulesVsModularized => {
"`macro_rules` vs non-`macro_rules` from other module"
}
AmbiguityKind::GlobVsOuter => {
"glob import vs any other name from outer scope during import/macro resolution"
}
AmbiguityKind::GlobVsGlob => "glob import vs glob import in the same module",
AmbiguityKind::GlobVsExpanded => {
"glob import vs macro-expanded name in the same \
module during import/macro resolution"
}
AmbiguityKind::MoreExpandedVsOuter => {
"macro-expanded name vs less macro-expanded name \
from outer scope during import/macro resolution"
}
}
}
}
/// Miscellaneous bits of metadata for better ambiguity error reporting.
#[derive(Clone, Copy, PartialEq)]
enum AmbiguityErrorMisc {
SuggestCrate,
SuggestSelf,
FromPrelude,
None,
}
struct AmbiguityError<'a> {
kind: AmbiguityKind,
ident: Ident,
b1: &'a NameBinding<'a>,
b2: &'a NameBinding<'a>,
misc1: AmbiguityErrorMisc,
misc2: AmbiguityErrorMisc,
}
impl<'a> NameBinding<'a> {
fn module(&self) -> Option<Module<'a>> {
match self.kind {
NameBindingKind::Module(module) => Some(module),
NameBindingKind::Import { binding, .. } => binding.module(),
_ => None,
}
}
fn res(&self) -> Res {
match self.kind {
NameBindingKind::Res(res, _) => res,
NameBindingKind::Module(module) => module.res().unwrap(),
NameBindingKind::Import { binding, .. } => binding.res(),
}
}
fn is_ambiguity(&self) -> bool {
self.ambiguity.is_some()
|| match self.kind {
NameBindingKind::Import { binding, .. } => binding.is_ambiguity(),
_ => false,
}
}
fn is_possibly_imported_variant(&self) -> bool {
match self.kind {
NameBindingKind::Import { binding, .. } => binding.is_possibly_imported_variant(),
_ => self.is_variant(),
}
}
// We sometimes need to treat variants as `pub` for backwards compatibility.
fn pseudo_vis(&self) -> ty::Visibility {
if self.is_variant() && self.res().def_id().is_local() {
ty::Visibility::Public
} else {
self.vis
}
}
fn is_variant(&self) -> bool {
matches!(
self.kind,
NameBindingKind::Res(
Res::Def(DefKind::Variant | DefKind::Ctor(CtorOf::Variant, ..), _),
_,
)
)
}
fn is_extern_crate(&self) -> bool {
match self.kind {
NameBindingKind::Import {
import: &Import { kind: ImportKind::ExternCrate { .. }, .. },
..
} => true,
NameBindingKind::Module(&ModuleData {
kind: ModuleKind::Def(DefKind::Mod, def_id, _),
..
}) => def_id.index == CRATE_DEF_INDEX,
_ => false,
}
}
fn is_import(&self) -> bool {
matches!(self.kind, NameBindingKind::Import { .. })
}
fn is_glob_import(&self) -> bool {
match self.kind {
NameBindingKind::Import { import, .. } => import.is_glob(),
_ => false,
}
}
fn is_importable(&self) -> bool {
!matches!(
self.res(),
Res::Def(DefKind::AssocConst | DefKind::AssocFn | DefKind::AssocTy, _)
)
}
fn is_macro_def(&self) -> bool {
matches!(self.kind, NameBindingKind::Res(Res::Def(DefKind::Macro(..), _), _))
}
fn macro_kind(&self) -> Option<MacroKind> {
self.res().macro_kind()
}
// Suppose that we resolved macro invocation with `invoc_parent_expansion` to binding `binding`
// at some expansion round `max(invoc, binding)` when they both emerged from macros.
// Then this function returns `true` if `self` may emerge from a macro *after* that
// in some later round and screw up our previously found resolution.
// See more detailed explanation in
// https://github.com/rust-lang/rust/pull/53778#issuecomment-419224049
fn may_appear_after(&self, invoc_parent_expansion: ExpnId, binding: &NameBinding<'_>) -> bool {
// self > max(invoc, binding) => !(self <= invoc || self <= binding)
// Expansions are partially ordered, so "may appear after" is an inversion of
// "certainly appears before or simultaneously" and includes unordered cases.
let self_parent_expansion = self.expansion;
let other_parent_expansion = binding.expansion;
let certainly_before_other_or_simultaneously =
other_parent_expansion.is_descendant_of(self_parent_expansion);
let certainly_before_invoc_or_simultaneously =
invoc_parent_expansion.is_descendant_of(self_parent_expansion);
!(certainly_before_other_or_simultaneously || certainly_before_invoc_or_simultaneously)
}
}
/// Interns the names of the primitive types.
///
/// All other types are defined somewhere and possibly imported, but the primitive ones need
/// special handling, since they have no place of origin.
struct PrimitiveTypeTable {
primitive_types: FxHashMap<Symbol, PrimTy>,
}
impl PrimitiveTypeTable {
fn new() -> PrimitiveTypeTable {
let mut table = FxHashMap::default();
table.insert(sym::bool, Bool);
table.insert(sym::char, Char);
table.insert(sym::f32, Float(FloatTy::F32));
table.insert(sym::f64, Float(FloatTy::F64));
table.insert(sym::isize, Int(IntTy::Isize));
table.insert(sym::i8, Int(IntTy::I8));
table.insert(sym::i16, Int(IntTy::I16));
table.insert(sym::i32, Int(IntTy::I32));
table.insert(sym::i64, Int(IntTy::I64));
table.insert(sym::i128, Int(IntTy::I128));
table.insert(sym::str, Str);
table.insert(sym::usize, Uint(UintTy::Usize));
table.insert(sym::u8, Uint(UintTy::U8));
table.insert(sym::u16, Uint(UintTy::U16));
table.insert(sym::u32, Uint(UintTy::U32));
table.insert(sym::u64, Uint(UintTy::U64));
table.insert(sym::u128, Uint(UintTy::U128));
Self { primitive_types: table }
}
}
#[derive(Debug, Default, Clone)]
pub struct ExternPreludeEntry<'a> {
extern_crate_item: Option<&'a NameBinding<'a>>,
pub introduced_by_item: bool,
}
/// Used for better errors for E0773
enum BuiltinMacroState {
NotYetSeen(SyntaxExtensionKind),
AlreadySeen(Span),
}
/// The main resolver class.
///
/// This is the visitor that walks the whole crate.
pub struct Resolver<'a> {
session: &'a Session,
definitions: Definitions,
graph_root: Module<'a>,
prelude: Option<Module<'a>>,
extern_prelude: FxHashMap<Ident, ExternPreludeEntry<'a>>,
/// N.B., this is used only for better diagnostics, not name resolution itself.
has_self: FxHashSet<DefId>,
/// Names of fields of an item `DefId` accessible with dot syntax.
/// Used for hints during error reporting.
field_names: FxHashMap<DefId, Vec<Spanned<Symbol>>>,
/// All imports known to succeed or fail.
determined_imports: Vec<&'a Import<'a>>,
/// All non-determined imports.
indeterminate_imports: Vec<&'a Import<'a>>,
/// FIXME: Refactor things so that these fields are passed through arguments and not resolver.
/// We are resolving a last import segment during import validation.
last_import_segment: bool,
/// This binding should be ignored during in-module resolution, so that we don't get
/// "self-confirming" import resolutions during import validation.
unusable_binding: Option<&'a NameBinding<'a>>,
/// The idents for the primitive types.
primitive_type_table: PrimitiveTypeTable,
/// Resolutions for nodes that have a single resolution.
partial_res_map: NodeMap<PartialRes>,
/// Resolutions for import nodes, which have multiple resolutions in different namespaces.
import_res_map: NodeMap<PerNS<Option<Res>>>,
/// Resolutions for labels (node IDs of their corresponding blocks or loops).
label_res_map: NodeMap<NodeId>,
/// `CrateNum` resolutions of `extern crate` items.
extern_crate_map: FxHashMap<LocalDefId, CrateNum>,
export_map: ExportMap<LocalDefId>,
trait_map: NodeMap<Vec<TraitCandidate>>,
/// A map from nodes to anonymous modules.
/// Anonymous modules are pseudo-modules that are implicitly created around items
/// contained within blocks.
///
/// For example, if we have this:
///
/// fn f() {
/// fn g() {
/// ...
/// }
/// }
///
/// There will be an anonymous module created around `g` with the ID of the
/// entry block for `f`.
block_map: NodeMap<Module<'a>>,
/// A fake module that contains no definition and no prelude. Used so that
/// some AST passes can generate identifiers that only resolve to local or
/// language items.
empty_module: Module<'a>,
module_map: FxHashMap<LocalDefId, Module<'a>>,
extern_module_map: FxHashMap<DefId, Module<'a>>,
binding_parent_modules: FxHashMap<PtrKey<'a, NameBinding<'a>>, Module<'a>>,
underscore_disambiguator: u32,
/// Maps glob imports to the names of items actually imported.
glob_map: FxHashMap<LocalDefId, FxHashSet<Symbol>>,
/// Visibilities in "lowered" form, for all entities that have them.
visibilities: FxHashMap<LocalDefId, ty::Visibility>,
used_imports: FxHashSet<(NodeId, Namespace)>,
maybe_unused_trait_imports: FxHashSet<LocalDefId>,
maybe_unused_extern_crates: Vec<(LocalDefId, Span)>,
/// Privacy errors are delayed until the end in order to deduplicate them.
privacy_errors: Vec<PrivacyError<'a>>,
/// Ambiguity errors are delayed for deduplication.
ambiguity_errors: Vec<AmbiguityError<'a>>,
/// `use` injections are delayed for better placement and deduplication.
use_injections: Vec<UseError<'a>>,
/// Crate-local macro expanded `macro_export` referred to by a module-relative path.
macro_expanded_macro_export_errors: BTreeSet<(Span, Span)>,
arenas: &'a ResolverArenas<'a>,
dummy_binding: &'a NameBinding<'a>,
crate_loader: CrateLoader<'a>,
macro_names: FxHashSet<Ident>,
builtin_macros: FxHashMap<Symbol, BuiltinMacroState>,
registered_attrs: FxHashSet<Ident>,
registered_tools: FxHashSet<Ident>,
macro_use_prelude: FxHashMap<Symbol, &'a NameBinding<'a>>,
all_macros: FxHashMap<Symbol, Res>,
macro_map: FxHashMap<DefId, Lrc<SyntaxExtension>>,
dummy_ext_bang: Lrc<SyntaxExtension>,
dummy_ext_derive: Lrc<SyntaxExtension>,
non_macro_attrs: [Lrc<SyntaxExtension>; 2],
local_macro_def_scopes: FxHashMap<LocalDefId, Module<'a>>,
ast_transform_scopes: FxHashMap<ExpnId, Module<'a>>,
unused_macros: FxHashMap<LocalDefId, (NodeId, Span)>,
proc_macro_stubs: FxHashSet<LocalDefId>,
/// Traces collected during macro resolution and validated when it's complete.
single_segment_macro_resolutions:
Vec<(Ident, MacroKind, ParentScope<'a>, Option<&'a NameBinding<'a>>)>,
multi_segment_macro_resolutions:
Vec<(Vec<Segment>, Span, MacroKind, ParentScope<'a>, Option<Res>)>,
builtin_attrs: Vec<(Ident, ParentScope<'a>)>,
/// `derive(Copy)` marks items they are applied to so they are treated specially later.
/// Derive macros cannot modify the item themselves and have to store the markers in the global
/// context, so they attach the markers to derive container IDs using this resolver table.
containers_deriving_copy: FxHashSet<ExpnId>,
/// Parent scopes in which the macros were invoked.
/// FIXME: `derives` are missing in these parent scopes and need to be taken from elsewhere.
invocation_parent_scopes: FxHashMap<ExpnId, ParentScope<'a>>,
/// `macro_rules` scopes *produced* by expanding the macro invocations,
/// include all the `macro_rules` items and other invocations generated by them.
output_macro_rules_scopes: FxHashMap<ExpnId, MacroRulesScopeRef<'a>>,
/// Helper attributes that are in scope for the given expansion.
helper_attrs: FxHashMap<ExpnId, Vec<Ident>>,
/// Avoid duplicated errors for "name already defined".
name_already_seen: FxHashMap<Symbol, Span>,
potentially_unused_imports: Vec<&'a Import<'a>>,
/// Table for mapping struct IDs into struct constructor IDs,
/// it's not used during normal resolution, only for better error reporting.
/// Also includes of list of each fields visibility
struct_constructors: DefIdMap<(Res, ty::Visibility, Vec<ty::Visibility>)>,
/// Features enabled for this crate.
active_features: FxHashSet<Symbol>,
lint_buffer: LintBuffer,
next_node_id: NodeId,
def_id_to_span: IndexVec<LocalDefId, Span>,
node_id_to_def_id: FxHashMap<ast::NodeId, LocalDefId>,
def_id_to_node_id: IndexVec<LocalDefId, ast::NodeId>,
/// Indices of unnamed struct or variant fields with unresolved attributes.
placeholder_field_indices: FxHashMap<NodeId, usize>,
/// When collecting definitions from an AST fragment produced by a macro invocation `ExpnId`
/// we know what parent node that fragment should be attached to thanks to this table.
invocation_parents: FxHashMap<ExpnId, LocalDefId>,
next_disambiguator: FxHashMap<(LocalDefId, DefPathData), u32>,
/// Some way to know that we are in a *trait* impl in `visit_assoc_item`.
/// FIXME: Replace with a more general AST map (together with some other fields).
trait_impl_items: FxHashSet<LocalDefId>,
}
/// Nothing really interesting here; it just provides memory for the rest of the crate.
#[derive(Default)]
pub struct ResolverArenas<'a> {
modules: TypedArena<ModuleData<'a>>,
local_modules: RefCell<Vec<Module<'a>>>,
imports: TypedArena<Import<'a>>,
name_resolutions: TypedArena<RefCell<NameResolution<'a>>>,
ast_paths: TypedArena<ast::Path>,
dropless: DroplessArena,
}
impl<'a> ResolverArenas<'a> {
fn alloc_module(&'a self, module: ModuleData<'a>) -> Module<'a> {
let module = self.modules.alloc(module);
if module.def_id().map_or(true, |def_id| def_id.is_local()) {
self.local_modules.borrow_mut().push(module);
}
module
}
fn local_modules(&'a self) -> std::cell::Ref<'a, Vec<Module<'a>>> {
self.local_modules.borrow()
}
fn alloc_name_binding(&'a self, name_binding: NameBinding<'a>) -> &'a NameBinding<'a> {
self.dropless.alloc(name_binding)
}
fn alloc_import(&'a self, import: Import<'a>) -> &'a Import<'_> {
self.imports.alloc(import)
}
fn alloc_name_resolution(&'a self) -> &'a RefCell<NameResolution<'a>> {
self.name_resolutions.alloc(Default::default())
}
fn alloc_macro_rules_scope(&'a self, scope: MacroRulesScope<'a>) -> MacroRulesScopeRef<'a> {
PtrKey(self.dropless.alloc(Cell::new(scope)))
}
fn alloc_macro_rules_binding(
&'a self,
binding: MacroRulesBinding<'a>,
) -> &'a MacroRulesBinding<'a> {
self.dropless.alloc(binding)
}
fn alloc_ast_paths(&'a self, paths: &[ast::Path]) -> &'a [ast::Path] {
self.ast_paths.alloc_from_iter(paths.iter().cloned())
}
fn alloc_pattern_spans(&'a self, spans: impl Iterator<Item = Span>) -> &'a [Span] {
self.dropless.alloc_from_iter(spans)
}
}
impl<'a> AsMut<Resolver<'a>> for Resolver<'a> {
fn as_mut(&mut self) -> &mut Resolver<'a> {
self
}
}
impl<'a, 'b> DefIdTree for &'a Resolver<'b> {
fn parent(self, id: DefId) -> Option<DefId> {
match id.as_local() {
Some(id) => self.definitions.def_key(id).parent,
None => self.cstore().def_key(id).parent,
}
.map(|index| DefId { index, ..id })
}
}
/// This interface is used through the AST→HIR step, to embed full paths into the HIR. After that
/// the resolver is no longer needed as all the relevant information is inline.
impl ResolverAstLowering for Resolver<'_> {
fn def_key(&mut self, id: DefId) -> DefKey {
if let Some(id) = id.as_local() {
self.definitions().def_key(id)
} else {
self.cstore().def_key(id)
}
}
fn item_generics_num_lifetimes(&self, def_id: DefId, sess: &Session) -> usize {
self.cstore().item_generics_num_lifetimes(def_id, sess)
}
fn get_partial_res(&mut self, id: NodeId) -> Option<PartialRes> {
self.partial_res_map.get(&id).cloned()
}
fn get_import_res(&mut self, id: NodeId) -> PerNS<Option<Res>> {
self.import_res_map.get(&id).cloned().unwrap_or_default()
}
fn get_label_res(&mut self, id: NodeId) -> Option<NodeId> {
self.label_res_map.get(&id).cloned()
}
fn definitions(&mut self) -> &mut Definitions {
&mut self.definitions
}
fn lint_buffer(&mut self) -> &mut LintBuffer {
&mut self.lint_buffer
}
fn next_node_id(&mut self) -> NodeId {
self.next_node_id()
}
fn trait_map(&self) -> &NodeMap<Vec<TraitCandidate>> {
&self.trait_map
}
fn opt_local_def_id(&self, node: NodeId) -> Option<LocalDefId> {
self.node_id_to_def_id.get(&node).copied()
}
fn local_def_id(&self, node: NodeId) -> LocalDefId {
self.opt_local_def_id(node).unwrap_or_else(|| panic!("no entry for node id: `{:?}`", node))
}
/// Adds a definition with a parent definition.
fn create_def(
&mut self,
parent: LocalDefId,
node_id: ast::NodeId,
data: DefPathData,
expn_id: ExpnId,
span: Span,
) -> LocalDefId {
assert!(
!self.node_id_to_def_id.contains_key(&node_id),
"adding a def'n for node-id {:?} and data {:?} but a previous def'n exists: {:?}",
node_id,
data,
self.definitions.def_key(self.node_id_to_def_id[&node_id]),
);
// Find the next free disambiguator for this key.
let next_disambiguator = &mut self.next_disambiguator;
let next_disambiguator = |parent, data| {
let next_disamb = next_disambiguator.entry((parent, data)).or_insert(0);
let disambiguator = *next_disamb;
*next_disamb = next_disamb.checked_add(1).expect("disambiguator overflow");
disambiguator
};
let def_id = self.definitions.create_def(parent, data, expn_id, next_disambiguator);
assert_eq!(self.def_id_to_span.push(span), def_id);
// Some things for which we allocate `LocalDefId`s don't correspond to
// anything in the AST, so they don't have a `NodeId`. For these cases
// we don't need a mapping from `NodeId` to `LocalDefId`.
if node_id != ast::DUMMY_NODE_ID {
debug!("create_def: def_id_to_node_id[{:?}] <-> {:?}", def_id, node_id);
self.node_id_to_def_id.insert(node_id, def_id);
}
assert_eq!(self.def_id_to_node_id.push(node_id), def_id);
def_id
}
}
impl<'a> Resolver<'a> {
pub fn new(
session: &'a Session,
krate: &Crate,
crate_name: &str,
metadata_loader: &'a MetadataLoaderDyn,
arenas: &'a ResolverArenas<'a>,
) -> Resolver<'a> {
let root_local_def_id = LocalDefId { local_def_index: CRATE_DEF_INDEX };
let root_def_id = root_local_def_id.to_def_id();
let root_module_kind = ModuleKind::Def(DefKind::Mod, root_def_id, kw::Empty);
let graph_root = arenas.alloc_module(ModuleData {
no_implicit_prelude: session.contains_name(&krate.attrs, sym::no_implicit_prelude),
..ModuleData::new(None, root_module_kind, root_def_id, ExpnId::root(), krate.span)
});
let empty_module_kind = ModuleKind::Def(DefKind::Mod, root_def_id, kw::Empty);
let empty_module = arenas.alloc_module(ModuleData {
no_implicit_prelude: true,
..ModuleData::new(
Some(graph_root),
empty_module_kind,
root_def_id,
ExpnId::root(),
DUMMY_SP,
)
});
let mut module_map = FxHashMap::default();
module_map.insert(root_local_def_id, graph_root);
let definitions = Definitions::new(crate_name, session.local_crate_disambiguator());
let root = definitions.get_root_def();
let mut visibilities = FxHashMap::default();
visibilities.insert(root_local_def_id, ty::Visibility::Public);
let mut def_id_to_span = IndexVec::default();
assert_eq!(def_id_to_span.push(rustc_span::DUMMY_SP), root);
let mut def_id_to_node_id = IndexVec::default();
assert_eq!(def_id_to_node_id.push(CRATE_NODE_ID), root);
let mut node_id_to_def_id = FxHashMap::default();
node_id_to_def_id.insert(CRATE_NODE_ID, root);
let mut invocation_parents = FxHashMap::default();
invocation_parents.insert(ExpnId::root(), root);
let mut extern_prelude: FxHashMap<Ident, ExternPreludeEntry<'_>> = session
.opts
.externs
.iter()
.filter(|(_, entry)| entry.add_prelude)
.map(|(name, _)| (Ident::from_str(name), Default::default()))
.collect();
if !session.contains_name(&krate.attrs, sym::no_core) {
extern_prelude.insert(Ident::with_dummy_span(sym::core), Default::default());
if !session.contains_name(&krate.attrs, sym::no_std) {
extern_prelude.insert(Ident::with_dummy_span(sym::std), Default::default());
}
}
let (registered_attrs, registered_tools) =
macros::registered_attrs_and_tools(session, &krate.attrs);
let features = session.features_untracked();
let non_macro_attr =
|mark_used| Lrc::new(SyntaxExtension::non_macro_attr(mark_used, session.edition()));
let mut resolver = Resolver {
session,
definitions,
// The outermost module has def ID 0; this is not reflected in the
// AST.
graph_root,
prelude: None,
extern_prelude,
has_self: FxHashSet::default(),
field_names: FxHashMap::default(),
determined_imports: Vec::new(),
indeterminate_imports: Vec::new(),
last_import_segment: false,
unusable_binding: None,
primitive_type_table: PrimitiveTypeTable::new(),
partial_res_map: Default::default(),
import_res_map: Default::default(),
label_res_map: Default::default(),
extern_crate_map: Default::default(),
export_map: FxHashMap::default(),
trait_map: Default::default(),
underscore_disambiguator: 0,
empty_module,
module_map,
block_map: Default::default(),
extern_module_map: FxHashMap::default(),
binding_parent_modules: FxHashMap::default(),
ast_transform_scopes: FxHashMap::default(),
glob_map: Default::default(),
visibilities,
used_imports: FxHashSet::default(),
maybe_unused_trait_imports: Default::default(),
maybe_unused_extern_crates: Vec::new(),
privacy_errors: Vec::new(),
ambiguity_errors: Vec::new(),
use_injections: Vec::new(),
macro_expanded_macro_export_errors: BTreeSet::new(),
arenas,
dummy_binding: arenas.alloc_name_binding(NameBinding {
kind: NameBindingKind::Res(Res::Err, false),
ambiguity: None,
expansion: ExpnId::root(),
span: DUMMY_SP,
vis: ty::Visibility::Public,
}),
crate_loader: CrateLoader::new(session, metadata_loader, crate_name),
macro_names: FxHashSet::default(),
builtin_macros: Default::default(),
registered_attrs,
registered_tools,
macro_use_prelude: FxHashMap::default(),
all_macros: FxHashMap::default(),
macro_map: FxHashMap::default(),
dummy_ext_bang: Lrc::new(SyntaxExtension::dummy_bang(session.edition())),
dummy_ext_derive: Lrc::new(SyntaxExtension::dummy_derive(session.edition())),
non_macro_attrs: [non_macro_attr(false), non_macro_attr(true)],
invocation_parent_scopes: Default::default(),
output_macro_rules_scopes: Default::default(),
helper_attrs: Default::default(),
local_macro_def_scopes: FxHashMap::default(),
name_already_seen: FxHashMap::default(),
potentially_unused_imports: Vec::new(),
struct_constructors: Default::default(),
unused_macros: Default::default(),
proc_macro_stubs: Default::default(),
single_segment_macro_resolutions: Default::default(),
multi_segment_macro_resolutions: Default::default(),
builtin_attrs: Default::default(),
containers_deriving_copy: Default::default(),
active_features: features
.declared_lib_features
.iter()
.map(|(feat, ..)| *feat)
.chain(features.declared_lang_features.iter().map(|(feat, ..)| *feat))
.collect(),
lint_buffer: LintBuffer::default(),
next_node_id: NodeId::from_u32(1),
def_id_to_span,
node_id_to_def_id,
def_id_to_node_id,
placeholder_field_indices: Default::default(),
invocation_parents,
next_disambiguator: Default::default(),
trait_impl_items: Default::default(),
};
let root_parent_scope = ParentScope::module(graph_root, &resolver);
resolver.invocation_parent_scopes.insert(ExpnId::root(), root_parent_scope);
resolver
}
pub fn next_node_id(&mut self) -> NodeId {
let next = self
.next_node_id
.as_usize()
.checked_add(1)
.expect("input too large; ran out of NodeIds");
self.next_node_id = ast::NodeId::from_usize(next);
self.next_node_id
}
pub fn lint_buffer(&mut self) -> &mut LintBuffer {
&mut self.lint_buffer
}
pub fn arenas() -> ResolverArenas<'a> {
Default::default()
}
pub fn into_outputs(self) -> ResolverOutputs {
let definitions = self.definitions;
let visibilities = self.visibilities;
let extern_crate_map = self.extern_crate_map;
let export_map = self.export_map;
let maybe_unused_trait_imports = self.maybe_unused_trait_imports;
let maybe_unused_extern_crates = self.maybe_unused_extern_crates;
let glob_map = self.glob_map;
ResolverOutputs {
definitions,
cstore: Box::new(self.crate_loader.into_cstore()),
visibilities,
extern_crate_map,
export_map,
glob_map,
maybe_unused_trait_imports,
maybe_unused_extern_crates,
extern_prelude: self
.extern_prelude
.iter()
.map(|(ident, entry)| (ident.name, entry.introduced_by_item))
.collect(),
}
}
pub fn clone_outputs(&self) -> ResolverOutputs {
ResolverOutputs {
definitions: self.definitions.clone(),
cstore: Box::new(self.cstore().clone()),
visibilities: self.visibilities.clone(),
extern_crate_map: self.extern_crate_map.clone(),
export_map: self.export_map.clone(),
glob_map: self.glob_map.clone(),
maybe_unused_trait_imports: self.maybe_unused_trait_imports.clone(),
maybe_unused_extern_crates: self.maybe_unused_extern_crates.clone(),
extern_prelude: self
.extern_prelude
.iter()
.map(|(ident, entry)| (ident.name, entry.introduced_by_item))
.collect(),
}
}
pub fn cstore(&self) -> &CStore {
self.crate_loader.cstore()
}
fn non_macro_attr(&self, mark_used: bool) -> Lrc<SyntaxExtension> {
self.non_macro_attrs[mark_used as usize].clone()
}
fn dummy_ext(&self, macro_kind: MacroKind) -> Lrc<SyntaxExtension> {
match macro_kind {
MacroKind::Bang => self.dummy_ext_bang.clone(),
MacroKind::Derive => self.dummy_ext_derive.clone(),
MacroKind::Attr => self.non_macro_attr(true),
}
}
/// Runs the function on each namespace.
fn per_ns<F: FnMut(&mut Self, Namespace)>(&mut self, mut f: F) {
f(self, TypeNS);
f(self, ValueNS);
f(self, MacroNS);
}
fn is_builtin_macro(&mut self, res: Res) -> bool {
self.get_macro(res).map_or(false, |ext| ext.builtin_name.is_some())
}
fn macro_def(&self, mut ctxt: SyntaxContext) -> DefId {
loop {
match ctxt.outer_expn().expn_data().macro_def_id {
Some(def_id) => return def_id,
None => ctxt.remove_mark(),
};
}
}
/// Entry point to crate resolution.
pub fn resolve_crate(&mut self, krate: &Crate) {
let _prof_timer = self.session.prof.generic_activity("resolve_crate");
ImportResolver { r: self }.finalize_imports();
self.finalize_macro_resolutions();
self.late_resolve_crate(krate);
self.check_unused(krate);
self.report_errors(krate);
self.crate_loader.postprocess(krate);
}
fn get_traits_in_module_containing_item(
&mut self,
ident: Ident,
ns: Namespace,
module: Module<'a>,
found_traits: &mut Vec<TraitCandidate>,
parent_scope: &ParentScope<'a>,
) {
assert!(ns == TypeNS || ns == ValueNS);
module.ensure_traits(self);
let traits = module.traits.borrow();
for &(trait_name, binding) in traits.as_ref().unwrap().iter() {
// Traits have pseudo-modules that can be used to search for the given ident.
if let Some(module) = binding.module() {
let mut ident = ident;
if ident.span.glob_adjust(module.expansion, binding.span).is_none() {
continue;
}
if self
.resolve_ident_in_module_unadjusted(
ModuleOrUniformRoot::Module(module),
ident,
ns,
parent_scope,
false,
module.span,
)
.is_ok()
{
let import_ids = self.find_transitive_imports(&binding.kind, trait_name);
let trait_def_id = module.def_id().unwrap();
found_traits.push(TraitCandidate { def_id: trait_def_id, import_ids });
}
} else if let Res::Def(DefKind::TraitAlias, _) = binding.res() {
// For now, just treat all trait aliases as possible candidates, since we don't
// know if the ident is somewhere in the transitive bounds.
let import_ids = self.find_transitive_imports(&binding.kind, trait_name);
let trait_def_id = binding.res().def_id();
found_traits.push(TraitCandidate { def_id: trait_def_id, import_ids });
} else {
bug!("candidate is not trait or trait alias?")
}
}
}
fn find_transitive_imports(
&mut self,
mut kind: &NameBindingKind<'_>,
trait_name: Ident,
) -> SmallVec<[LocalDefId; 1]> {
let mut import_ids = smallvec![];
while let NameBindingKind::Import { import, binding, .. } = kind {
let id = self.local_def_id(import.id);
self.maybe_unused_trait_imports.insert(id);
self.add_to_glob_map(&import, trait_name);
import_ids.push(id);
kind = &binding.kind;
}
import_ids
}
fn new_module(
&self,
parent: Module<'a>,
kind: ModuleKind,
nearest_parent_mod: DefId,
expn_id: ExpnId,
span: Span,
) -> Module<'a> {
let module = ModuleData::new(Some(parent), kind, nearest_parent_mod, expn_id, span);
self.arenas.alloc_module(module)
}
fn new_key(&mut self, ident: Ident, ns: Namespace) -> BindingKey {
let ident = ident.normalize_to_macros_2_0();
let disambiguator = if ident.name == kw::Underscore {
self.underscore_disambiguator += 1;
self.underscore_disambiguator
} else {
0
};
BindingKey { ident, ns, disambiguator }
}
fn resolutions(&mut self, module: Module<'a>) -> &'a Resolutions<'a> {
if module.populate_on_access.get() {
module.populate_on_access.set(false);
self.build_reduced_graph_external(module);
}
&module.lazy_resolutions
}
fn resolution(
&mut self,
module: Module<'a>,
key: BindingKey,
) -> &'a RefCell<NameResolution<'a>> {
*self
.resolutions(module)
.borrow_mut()
.entry(key)
.or_insert_with(|| self.arenas.alloc_name_resolution())
}
fn record_use(
&mut self,
ident: Ident,
ns: Namespace,
used_binding: &'a NameBinding<'a>,
is_lexical_scope: bool,
) {
if let Some((b2, kind)) = used_binding.ambiguity {
self.ambiguity_errors.push(AmbiguityError {
kind,
ident,
b1: used_binding,
b2,
misc1: AmbiguityErrorMisc::None,
misc2: AmbiguityErrorMisc::None,
});
}
if let NameBindingKind::Import { import, binding, ref used } = used_binding.kind {
// Avoid marking `extern crate` items that refer to a name from extern prelude,
// but not introduce it, as used if they are accessed from lexical scope.
if is_lexical_scope {
if let Some(entry) = self.extern_prelude.get(&ident.normalize_to_macros_2_0()) {
if let Some(crate_item) = entry.extern_crate_item {
if ptr::eq(used_binding, crate_item) && !entry.introduced_by_item {
return;
}
}
}
}
used.set(true);
import.used.set(true);
self.used_imports.insert((import.id, ns));
self.add_to_glob_map(&import, ident);
self.record_use(ident, ns, binding, false);
}
}
#[inline]
fn add_to_glob_map(&mut self, import: &Import<'_>, ident: Ident) {
if import.is_glob() {
let def_id = self.local_def_id(import.id);
self.glob_map.entry(def_id).or_default().insert(ident.name);
}
}
/// A generic scope visitor.
/// Visits scopes in order to resolve some identifier in them or perform other actions.
/// If the callback returns `Some` result, we stop visiting scopes and return it.
fn visit_scopes<T>(
&mut self,
scope_set: ScopeSet,
parent_scope: &ParentScope<'a>,
ctxt: SyntaxContext,
mut visitor: impl FnMut(
&mut Self,
Scope<'a>,
/*use_prelude*/ bool,
SyntaxContext,
) -> Option<T>,
) -> Option<T> {
// General principles:
// 1. Not controlled (user-defined) names should have higher priority than controlled names
// built into the language or standard library. This way we can add new names into the
// language or standard library without breaking user code.
// 2. "Closed set" below means new names cannot appear after the current resolution attempt.
// Places to search (in order of decreasing priority):
// (Type NS)
// 1. FIXME: Ribs (type parameters), there's no necessary infrastructure yet
// (open set, not controlled).
// 2. Names in modules (both normal `mod`ules and blocks), loop through hygienic parents
// (open, not controlled).
// 3. Extern prelude (open, the open part is from macro expansions, not controlled).
// 4. Tool modules (closed, controlled right now, but not in the future).
// 5. Standard library prelude (de-facto closed, controlled).
// 6. Language prelude (closed, controlled).
// (Value NS)
// 1. FIXME: Ribs (local variables), there's no necessary infrastructure yet
// (open set, not controlled).
// 2. Names in modules (both normal `mod`ules and blocks), loop through hygienic parents
// (open, not controlled).
// 3. Standard library prelude (de-facto closed, controlled).
// (Macro NS)
// 1-3. Derive helpers (open, not controlled). All ambiguities with other names
// are currently reported as errors. They should be higher in priority than preludes
// and probably even names in modules according to the "general principles" above. They
// also should be subject to restricted shadowing because are effectively produced by
// derives (you need to resolve the derive first to add helpers into scope), but they
// should be available before the derive is expanded for compatibility.
// It's mess in general, so we are being conservative for now.
// 1-3. `macro_rules` (open, not controlled), loop through `macro_rules` scopes. Have higher
// priority than prelude macros, but create ambiguities with macros in modules.
// 1-3. Names in modules (both normal `mod`ules and blocks), loop through hygienic parents
// (open, not controlled). Have higher priority than prelude macros, but create
// ambiguities with `macro_rules`.
// 4. `macro_use` prelude (open, the open part is from macro expansions, not controlled).
// 4a. User-defined prelude from macro-use
// (open, the open part is from macro expansions, not controlled).
// 4b. "Standard library prelude" part implemented through `macro-use` (closed, controlled).
// 4c. Standard library prelude (de-facto closed, controlled).
// 6. Language prelude: builtin attributes (closed, controlled).
let rust_2015 = ctxt.edition() == Edition::Edition2015;
let (ns, macro_kind, is_absolute_path) = match scope_set {
ScopeSet::All(ns, _) => (ns, None, false),
ScopeSet::AbsolutePath(ns) => (ns, None, true),
ScopeSet::Macro(macro_kind) => (MacroNS, Some(macro_kind), false),
};
// Jump out of trait or enum modules, they do not act as scopes.
let module = parent_scope.module.nearest_item_scope();
let mut scope = match ns {
_ if is_absolute_path => Scope::CrateRoot,
TypeNS | ValueNS => Scope::Module(module),
MacroNS => Scope::DeriveHelpers(parent_scope.expansion),
};
let mut ctxt = ctxt.normalize_to_macros_2_0();
let mut use_prelude = !module.no_implicit_prelude;
loop {
let visit = match scope {
// Derive helpers are not in scope when resolving derives in the same container.
Scope::DeriveHelpers(expn_id) => {
!(expn_id == parent_scope.expansion && macro_kind == Some(MacroKind::Derive))
}
Scope::DeriveHelpersCompat => true,
Scope::MacroRules(macro_rules_scope) => {
// Use "path compression" on `macro_rules` scope chains. This is an optimization
// used to avoid long scope chains, see the comments on `MacroRulesScopeRef`.
// As another consequence of this optimization visitors never observe invocation
// scopes for macros that were already expanded.
while let MacroRulesScope::Invocation(invoc_id) = macro_rules_scope.get() {
if let Some(next_scope) = self.output_macro_rules_scopes.get(&invoc_id) {
macro_rules_scope.set(next_scope.get());
} else {
break;
}
}
true
}
Scope::CrateRoot => true,
Scope::Module(..) => true,
Scope::RegisteredAttrs => use_prelude,
Scope::MacroUsePrelude => use_prelude || rust_2015,
Scope::BuiltinAttrs => true,
Scope::ExternPrelude => use_prelude || is_absolute_path,
Scope::ToolPrelude => use_prelude,
Scope::StdLibPrelude => use_prelude || ns == MacroNS,
Scope::BuiltinTypes => true,
};
if visit {
if let break_result @ Some(..) = visitor(self, scope, use_prelude, ctxt) {
return break_result;
}
}
scope = match scope {
Scope::DeriveHelpers(expn_id) if expn_id != ExpnId::root() => {
// Derive helpers are not visible to code generated by bang or derive macros.
let expn_data = expn_id.expn_data();
match expn_data.kind {
ExpnKind::Root
| ExpnKind::Macro(MacroKind::Bang | MacroKind::Derive, _) => {
Scope::DeriveHelpersCompat
}
_ => Scope::DeriveHelpers(expn_data.parent),
}
}
Scope::DeriveHelpers(..) => Scope::DeriveHelpersCompat,
Scope::DeriveHelpersCompat => Scope::MacroRules(parent_scope.macro_rules),
Scope::MacroRules(macro_rules_scope) => match macro_rules_scope.get() {
MacroRulesScope::Binding(binding) => {
Scope::MacroRules(binding.parent_macro_rules_scope)
}
MacroRulesScope::Invocation(invoc_id) => {
Scope::MacroRules(self.invocation_parent_scopes[&invoc_id].macro_rules)
}
MacroRulesScope::Empty => Scope::Module(module),
},
Scope::CrateRoot => match ns {
TypeNS => {
ctxt.adjust(ExpnId::root());
Scope::ExternPrelude
}
ValueNS | MacroNS => break,
},
Scope::Module(module) => {
use_prelude = !module.no_implicit_prelude;
match self.hygienic_lexical_parent(module, &mut ctxt) {
Some(parent_module) => Scope::Module(parent_module),
None => {
ctxt.adjust(ExpnId::root());
match ns {
TypeNS => Scope::ExternPrelude,
ValueNS => Scope::StdLibPrelude,
MacroNS => Scope::RegisteredAttrs,
}
}
}
}
Scope::RegisteredAttrs => Scope::MacroUsePrelude,
Scope::MacroUsePrelude => Scope::StdLibPrelude,
Scope::BuiltinAttrs => break, // nowhere else to search
Scope::ExternPrelude if is_absolute_path => break,
Scope::ExternPrelude => Scope::ToolPrelude,
Scope::ToolPrelude => Scope::StdLibPrelude,
Scope::StdLibPrelude => match ns {
TypeNS => Scope::BuiltinTypes,
ValueNS => break, // nowhere else to search
MacroNS => Scope::BuiltinAttrs,
},
Scope::BuiltinTypes => break, // nowhere else to search
};
}
None
}
/// This resolves the identifier `ident` in the namespace `ns` in the current lexical scope.
/// More specifically, we proceed up the hierarchy of scopes and return the binding for
/// `ident` in the first scope that defines it (or None if no scopes define it).
///
/// A block's items are above its local variables in the scope hierarchy, regardless of where
/// the items are defined in the block. For example,
/// ```rust
/// fn f() {
/// g(); // Since there are no local variables in scope yet, this resolves to the item.
/// let g = || {};
/// fn g() {}
/// g(); // This resolves to the local variable `g` since it shadows the item.
/// }
/// ```
///
/// Invariant: This must only be called during main resolution, not during
/// import resolution.
fn resolve_ident_in_lexical_scope(
&mut self,
mut ident: Ident,
ns: Namespace,
parent_scope: &ParentScope<'a>,
record_used_id: Option<NodeId>,
path_span: Span,
ribs: &[Rib<'a>],
) -> Option<LexicalScopeBinding<'a>> {
assert!(ns == TypeNS || ns == ValueNS);
if ident.name == kw::Empty {
return Some(LexicalScopeBinding::Res(Res::Err));
}
let (general_span, normalized_span) = if ident.name == kw::SelfUpper {
// FIXME(jseyfried) improve `Self` hygiene
let empty_span = ident.span.with_ctxt(SyntaxContext::root());
(empty_span, empty_span)
} else if ns == TypeNS {
let normalized_span = ident.span.normalize_to_macros_2_0();
(normalized_span, normalized_span)
} else {
(ident.span.normalize_to_macro_rules(), ident.span.normalize_to_macros_2_0())
};
ident.span = general_span;
let normalized_ident = Ident { span: normalized_span, ..ident };
// Walk backwards up the ribs in scope.
let record_used = record_used_id.is_some();
let mut module = self.graph_root;
for i in (0..ribs.len()).rev() {
debug!("walk rib\n{:?}", ribs[i].bindings);
// Use the rib kind to determine whether we are resolving parameters
// (macro 2.0 hygiene) or local variables (`macro_rules` hygiene).
let rib_ident = if ribs[i].kind.contains_params() { normalized_ident } else { ident };
if let Some((original_rib_ident_def, res)) = ribs[i].bindings.get_key_value(&rib_ident)
{
// The ident resolves to a type parameter or local variable.
return Some(LexicalScopeBinding::Res(self.validate_res_from_ribs(
i,
rib_ident,
*res,
record_used,
path_span,
*original_rib_ident_def,
ribs,
)));
}
module = match ribs[i].kind {
ModuleRibKind(module) => module,
MacroDefinition(def) if def == self.macro_def(ident.span.ctxt()) => {
// If an invocation of this macro created `ident`, give up on `ident`
// and switch to `ident`'s source from the macro definition.
ident.span.remove_mark();
continue;
}
_ => continue,
};
let item = self.resolve_ident_in_module_unadjusted(
ModuleOrUniformRoot::Module(module),
ident,
ns,
parent_scope,
record_used,
path_span,
);
if let Ok(binding) = item {
// The ident resolves to an item.
return Some(LexicalScopeBinding::Item(binding));
}
match module.kind {
ModuleKind::Block(..) => {} // We can see through blocks
_ => break,
}
}
ident = normalized_ident;
let mut poisoned = None;
loop {
let mut span_data = ident.span.data();
let opt_module = if let Some(node_id) = record_used_id {
self.hygienic_lexical_parent_with_compatibility_fallback(
module,
&mut span_data.ctxt,
node_id,
&mut poisoned,
)
} else {
self.hygienic_lexical_parent(module, &mut span_data.ctxt)
};
ident.span = span_data.span();
module = unwrap_or!(opt_module, break);
let adjusted_parent_scope = &ParentScope { module, ..*parent_scope };
let result = self.resolve_ident_in_module_unadjusted(
ModuleOrUniformRoot::Module(module),
ident,
ns,
adjusted_parent_scope,
record_used,
path_span,
);
match result {
Ok(binding) => {
if let Some(node_id) = poisoned {
self.lint_buffer.buffer_lint_with_diagnostic(
lint::builtin::PROC_MACRO_DERIVE_RESOLUTION_FALLBACK,
node_id,
ident.span,
&format!("cannot find {} `{}` in this scope", ns.descr(), ident),
BuiltinLintDiagnostics::ProcMacroDeriveResolutionFallback(ident.span),
);
}
return Some(LexicalScopeBinding::Item(binding));
}
Err(Determined) => continue,
Err(Undetermined) => {
span_bug!(ident.span, "undetermined resolution during main resolution pass")
}
}
}
if !module.no_implicit_prelude {
ident.span.adjust(ExpnId::root());
if ns == TypeNS {
if let Some(binding) = self.extern_prelude_get(ident, !record_used) {
return Some(LexicalScopeBinding::Item(binding));
}
if let Some(ident) = self.registered_tools.get(&ident) {
let binding =
(Res::ToolMod, ty::Visibility::Public, ident.span, ExpnId::root())
.to_name_binding(self.arenas);
return Some(LexicalScopeBinding::Item(binding));
}
}
if let Some(prelude) = self.prelude {
if let Ok(binding) = self.resolve_ident_in_module_unadjusted(
ModuleOrUniformRoot::Module(prelude),
ident,
ns,
parent_scope,
false,
path_span,
) {
return Some(LexicalScopeBinding::Item(binding));
}
}
}
if ns == TypeNS {
if let Some(prim_ty) = self.primitive_type_table.primitive_types.get(&ident.name) {
let binding =
(Res::PrimTy(*prim_ty), ty::Visibility::Public, DUMMY_SP, ExpnId::root())
.to_name_binding(self.arenas);
return Some(LexicalScopeBinding::Item(binding));
}
}
None
}
fn hygienic_lexical_parent(
&mut self,
module: Module<'a>,
ctxt: &mut SyntaxContext,
) -> Option<Module<'a>> {
if !module.expansion.outer_expn_is_descendant_of(*ctxt) {
return Some(self.macro_def_scope(ctxt.remove_mark()));
}
if let ModuleKind::Block(..) = module.kind {
return Some(module.parent.unwrap().nearest_item_scope());
}
None
}
fn hygienic_lexical_parent_with_compatibility_fallback(
&mut self,
module: Module<'a>,
ctxt: &mut SyntaxContext,
node_id: NodeId,
poisoned: &mut Option<NodeId>,
) -> Option<Module<'a>> {
if let module @ Some(..) = self.hygienic_lexical_parent(module, ctxt) {
return module;
}
// We need to support the next case under a deprecation warning
// ```
// struct MyStruct;
// ---- begin: this comes from a proc macro derive
// mod implementation_details {
// // Note that `MyStruct` is not in scope here.
// impl SomeTrait for MyStruct { ... }
// }
// ---- end
// ```
// So we have to fall back to the module's parent during lexical resolution in this case.
if let Some(parent) = module.parent {
// Inner module is inside the macro, parent module is outside of the macro.
if module.expansion != parent.expansion
&& module.expansion.is_descendant_of(parent.expansion)
{
// The macro is a proc macro derive
if let Some(def_id) = module.expansion.expn_data().macro_def_id {
let ext = self.get_macro_by_def_id(def_id);
if ext.builtin_name.is_none()
&& ext.macro_kind() == MacroKind::Derive
&& parent.expansion.outer_expn_is_descendant_of(*ctxt)
{
*poisoned = Some(node_id);
return module.parent;
}
}
}
}
None
}
fn resolve_ident_in_module(
&mut self,
module: ModuleOrUniformRoot<'a>,
ident: Ident,
ns: Namespace,
parent_scope: &ParentScope<'a>,
record_used: bool,
path_span: Span,
) -> Result<&'a NameBinding<'a>, Determinacy> {
self.resolve_ident_in_module_ext(module, ident, ns, parent_scope, record_used, path_span)
.map_err(|(determinacy, _)| determinacy)
}
fn resolve_ident_in_module_ext(
&mut self,
module: ModuleOrUniformRoot<'a>,
mut ident: Ident,
ns: Namespace,
parent_scope: &ParentScope<'a>,
record_used: bool,
path_span: Span,
) -> Result<&'a NameBinding<'a>, (Determinacy, Weak)> {
let tmp_parent_scope;
let mut adjusted_parent_scope = parent_scope;
match module {
ModuleOrUniformRoot::Module(m) => {
if let Some(def) = ident.span.normalize_to_macros_2_0_and_adjust(m.expansion) {
tmp_parent_scope =
ParentScope { module: self.macro_def_scope(def), ..*parent_scope };
adjusted_parent_scope = &tmp_parent_scope;
}
}
ModuleOrUniformRoot::ExternPrelude => {
ident.span.normalize_to_macros_2_0_and_adjust(ExpnId::root());
}
ModuleOrUniformRoot::CrateRootAndExternPrelude | ModuleOrUniformRoot::CurrentScope => {
// No adjustments
}
}
self.resolve_ident_in_module_unadjusted_ext(
module,
ident,
ns,
adjusted_parent_scope,
false,
record_used,
path_span,
)
}
fn resolve_crate_root(&mut self, ident: Ident) -> Module<'a> {
debug!("resolve_crate_root({:?})", ident);
let mut ctxt = ident.span.ctxt();
let mark = if ident.name == kw::DollarCrate {
// When resolving `$crate` from a `macro_rules!` invoked in a `macro`,
// we don't want to pretend that the `macro_rules!` definition is in the `macro`
// as described in `SyntaxContext::apply_mark`, so we ignore prepended opaque marks.
// FIXME: This is only a guess and it doesn't work correctly for `macro_rules!`
// definitions actually produced by `macro` and `macro` definitions produced by
// `macro_rules!`, but at least such configurations are not stable yet.
ctxt = ctxt.normalize_to_macro_rules();
debug!(
"resolve_crate_root: marks={:?}",
ctxt.marks().into_iter().map(|(i, t)| (i.expn_data(), t)).collect::<Vec<_>>()
);
let mut iter = ctxt.marks().into_iter().rev().peekable();
let mut result = None;
// Find the last opaque mark from the end if it exists.
while let Some(&(mark, transparency)) = iter.peek() {
if transparency == Transparency::Opaque {
result = Some(mark);
iter.next();
} else {
break;
}
}
debug!(
"resolve_crate_root: found opaque mark {:?} {:?}",
result,
result.map(|r| r.expn_data())
);
// Then find the last semi-transparent mark from the end if it exists.
for (mark, transparency) in iter {
if transparency == Transparency::SemiTransparent {
result = Some(mark);
} else {
break;
}
}
debug!(
"resolve_crate_root: found semi-transparent mark {:?} {:?}",
result,
result.map(|r| r.expn_data())
);
result
} else {
debug!("resolve_crate_root: not DollarCrate");
ctxt = ctxt.normalize_to_macros_2_0();
ctxt.adjust(ExpnId::root())
};
let module = match mark {
Some(def) => self.macro_def_scope(def),
None => {
debug!(
"resolve_crate_root({:?}): found no mark (ident.span = {:?})",
ident, ident.span
);
return self.graph_root;
}
};
let module = self.get_module(DefId { index: CRATE_DEF_INDEX, ..module.nearest_parent_mod });
debug!(
"resolve_crate_root({:?}): got module {:?} ({:?}) (ident.span = {:?})",
ident,
module,
module.kind.name(),
ident.span
);
module
}
fn resolve_self(&mut self, ctxt: &mut SyntaxContext, module: Module<'a>) -> Module<'a> {
let mut module = self.get_module(module.nearest_parent_mod);
while module.span.ctxt().normalize_to_macros_2_0() != *ctxt {
let parent = module.parent.unwrap_or_else(|| self.macro_def_scope(ctxt.remove_mark()));
module = self.get_module(parent.nearest_parent_mod);
}
module
}
fn resolve_path(
&mut self,
path: &[Segment],
opt_ns: Option<Namespace>, // `None` indicates a module path in import
parent_scope: &ParentScope<'a>,
record_used: bool,
path_span: Span,
crate_lint: CrateLint,
) -> PathResult<'a> {
self.resolve_path_with_ribs(
path,
opt_ns,
parent_scope,
record_used,
path_span,
crate_lint,
None,
)
}
fn resolve_path_with_ribs(
&mut self,
path: &[Segment],
opt_ns: Option<Namespace>, // `None` indicates a module path in import
parent_scope: &ParentScope<'a>,
record_used: bool,
path_span: Span,
crate_lint: CrateLint,
ribs: Option<&PerNS<Vec<Rib<'a>>>>,
) -> PathResult<'a> {
let mut module = None;
let mut allow_super = true;
let mut second_binding = None;
debug!(
"resolve_path(path={:?}, opt_ns={:?}, record_used={:?}, \
path_span={:?}, crate_lint={:?})",
path, opt_ns, record_used, path_span, crate_lint,
);
for (i, &Segment { ident, id, has_generic_args: _ }) in path.iter().enumerate() {
debug!("resolve_path ident {} {:?} {:?}", i, ident, id);
let record_segment_res = |this: &mut Self, res| {
if record_used {
if let Some(id) = id {
if !this.partial_res_map.contains_key(&id) {
assert!(id != ast::DUMMY_NODE_ID, "Trying to resolve dummy id");
this.record_partial_res(id, PartialRes::new(res));
}
}
}
};
let is_last = i == path.len() - 1;
let ns = if is_last { opt_ns.unwrap_or(TypeNS) } else { TypeNS };
let name = ident.name;
allow_super &= ns == TypeNS && (name == kw::SelfLower || name == kw::Super);
if ns == TypeNS {
if allow_super && name == kw::Super {
let mut ctxt = ident.span.ctxt().normalize_to_macros_2_0();
let self_module = match i {
0 => Some(self.resolve_self(&mut ctxt, parent_scope.module)),
_ => match module {
Some(ModuleOrUniformRoot::Module(module)) => Some(module),
_ => None,
},
};
if let Some(self_module) = self_module {
if let Some(parent) = self_module.parent {
module = Some(ModuleOrUniformRoot::Module(
self.resolve_self(&mut ctxt, parent),
));
continue;
}
}
let msg = "there are too many leading `super` keywords".to_string();
return PathResult::Failed {
span: ident.span,
label: msg,
suggestion: None,
is_error_from_last_segment: false,
};
}
if i == 0 {
if name == kw::SelfLower {
let mut ctxt = ident.span.ctxt().normalize_to_macros_2_0();
module = Some(ModuleOrUniformRoot::Module(
self.resolve_self(&mut ctxt, parent_scope.module),
));
continue;
}
if name == kw::PathRoot && ident.span.rust_2018() {
module = Some(ModuleOrUniformRoot::ExternPrelude);
continue;
}
if name == kw::PathRoot && ident.span.rust_2015() && self.session.rust_2018() {
// `::a::b` from 2015 macro on 2018 global edition
module = Some(ModuleOrUniformRoot::CrateRootAndExternPrelude);
continue;
}
if name == kw::PathRoot || name == kw::Crate || name == kw::DollarCrate {
// `::a::b`, `crate::a::b` or `$crate::a::b`
module = Some(ModuleOrUniformRoot::Module(self.resolve_crate_root(ident)));
continue;
}
}
}
// Report special messages for path segment keywords in wrong positions.
if ident.is_path_segment_keyword() && i != 0 {
let name_str = if name == kw::PathRoot {
"crate root".to_string()
} else {
format!("`{}`", name)
};
let label = if i == 1 && path[0].ident.name == kw::PathRoot {
format!("global paths cannot start with {}", name_str)
} else {
format!("{} in paths can only be used in start position", name_str)
};
return PathResult::Failed {
span: ident.span,
label,
suggestion: None,
is_error_from_last_segment: false,
};
}
enum FindBindingResult<'a> {
Binding(Result<&'a NameBinding<'a>, Determinacy>),
PathResult(PathResult<'a>),
}
let find_binding_in_ns = |this: &mut Self, ns| {
let binding = if let Some(module) = module {
this.resolve_ident_in_module(
module,
ident,
ns,
parent_scope,
record_used,
path_span,
)
} else if ribs.is_none() || opt_ns.is_none() || opt_ns == Some(MacroNS) {
let scopes = ScopeSet::All(ns, opt_ns.is_none());
this.early_resolve_ident_in_lexical_scope(
ident,
scopes,
parent_scope,
record_used,
record_used,
path_span,
)
} else {
let record_used_id = if record_used {
crate_lint.node_id().or(Some(CRATE_NODE_ID))
} else {
None
};
match this.resolve_ident_in_lexical_scope(
ident,
ns,
parent_scope,
record_used_id,
path_span,
&ribs.unwrap()[ns],
) {
// we found a locally-imported or available item/module
Some(LexicalScopeBinding::Item(binding)) => Ok(binding),
// we found a local variable or type param
Some(LexicalScopeBinding::Res(res))
if opt_ns == Some(TypeNS) || opt_ns == Some(ValueNS) =>
{
record_segment_res(this, res);
return FindBindingResult::PathResult(PathResult::NonModule(
PartialRes::with_unresolved_segments(res, path.len() - 1),
));
}
_ => Err(Determinacy::determined(record_used)),
}
};
FindBindingResult::Binding(binding)
};
let binding = match find_binding_in_ns(self, ns) {
FindBindingResult::PathResult(x) => return x,
FindBindingResult::Binding(binding) => binding,
};
match binding {
Ok(binding) => {
if i == 1 {
second_binding = Some(binding);
}
let res = binding.res();
let maybe_assoc = opt_ns != Some(MacroNS) && PathSource::Type.is_expected(res);
if let Some(next_module) = binding.module() {
module = Some(ModuleOrUniformRoot::Module(next_module));
record_segment_res(self, res);
} else if res == Res::ToolMod && i + 1 != path.len() {
if binding.is_import() {
self.session
.struct_span_err(
ident.span,
"cannot use a tool module through an import",
)
.span_note(binding.span, "the tool module imported here")
.emit();
}
let res = Res::NonMacroAttr(NonMacroAttrKind::Tool);
return PathResult::NonModule(PartialRes::new(res));
} else if res == Res::Err {
return PathResult::NonModule(PartialRes::new(Res::Err));
} else if opt_ns.is_some() && (is_last || maybe_assoc) {
self.lint_if_path_starts_with_module(
crate_lint,
path,
path_span,
second_binding,
);
return PathResult::NonModule(PartialRes::with_unresolved_segments(
res,
path.len() - i - 1,
));
} else {
let label = format!(
"`{}` is {} {}, not a module",
ident,
res.article(),
res.descr(),
);
return PathResult::Failed {
span: ident.span,
label,
suggestion: None,
is_error_from_last_segment: is_last,
};
}
}
Err(Undetermined) => return PathResult::Indeterminate,
Err(Determined) => {
if let Some(ModuleOrUniformRoot::Module(module)) = module {
if opt_ns.is_some() && !module.is_normal() {
return PathResult::NonModule(PartialRes::with_unresolved_segments(
module.res().unwrap(),
path.len() - i,
));
}
}
let module_res = match module {
Some(ModuleOrUniformRoot::Module(module)) => module.res(),
_ => None,
};
let (label, suggestion) = if module_res == self.graph_root.res() {
let is_mod = |res| matches!(res, Res::Def(DefKind::Mod, _));
// Don't look up import candidates if this is a speculative resolve
let mut candidates = if record_used {
self.lookup_import_candidates(ident, TypeNS, parent_scope, is_mod)
} else {
Vec::new()
};
candidates.sort_by_cached_key(|c| {
(c.path.segments.len(), pprust::path_to_string(&c.path))
});
if let Some(candidate) = candidates.get(0) {
(
String::from("unresolved import"),
Some((
vec![(ident.span, pprust::path_to_string(&candidate.path))],
String::from("a similar path exists"),
Applicability::MaybeIncorrect,
)),
)
} else {
(format!("maybe a missing crate `{}`?", ident), None)
}
} else if i == 0 {
if ident
.name
.as_str()
.chars()
.next()
.map_or(false, |c| c.is_ascii_uppercase())
{
(format!("use of undeclared type `{}`", ident), None)
} else {
(format!("use of undeclared crate or module `{}`", ident), None)
}
} else {
let mut msg =
format!("could not find `{}` in `{}`", ident, path[i - 1].ident);
if ns == TypeNS || ns == ValueNS {
let ns_to_try = if ns == TypeNS { ValueNS } else { TypeNS };
if let FindBindingResult::Binding(Ok(binding)) =
find_binding_in_ns(self, ns_to_try)
{
let mut found = |what| {
msg = format!(
"expected {}, found {} `{}` in `{}`",
ns.descr(),
what,
ident,
path[i - 1].ident
)
};
if binding.module().is_some() {
found("module")
} else {
match binding.res() {
def::Res::<NodeId>::Def(kind, id) => found(kind.descr(id)),
_ => found(ns_to_try.descr()),
}
}
};
}
(msg, None)
};
return PathResult::Failed {
span: ident.span,
label,
suggestion,
is_error_from_last_segment: is_last,
};
}
}
}
self.lint_if_path_starts_with_module(crate_lint, path, path_span, second_binding);
PathResult::Module(match module {
Some(module) => module,
None if path.is_empty() => ModuleOrUniformRoot::CurrentScope,
_ => span_bug!(path_span, "resolve_path: non-empty path `{:?}` has no module", path),
})
}
fn lint_if_path_starts_with_module(
&mut self,
crate_lint: CrateLint,
path: &[Segment],
path_span: Span,
second_binding: Option<&NameBinding<'_>>,
) {
let (diag_id, diag_span) = match crate_lint {
CrateLint::No => return,
CrateLint::SimplePath(id) => (id, path_span),
CrateLint::UsePath { root_id, root_span } => (root_id, root_span),
CrateLint::QPathTrait { qpath_id, qpath_span } => (qpath_id, qpath_span),
};
let first_name = match path.get(0) {
// In the 2018 edition this lint is a hard error, so nothing to do
Some(seg) if seg.ident.span.rust_2015() && self.session.rust_2015() => seg.ident.name,
_ => return,
};
// We're only interested in `use` paths which should start with
// `{{root}}` currently.
if first_name != kw::PathRoot {
return;
}
match path.get(1) {
// If this import looks like `crate::...` it's already good
Some(Segment { ident, .. }) if ident.name == kw::Crate => return,
// Otherwise go below to see if it's an extern crate
Some(_) => {}
// If the path has length one (and it's `PathRoot` most likely)
// then we don't know whether we're gonna be importing a crate or an
// item in our crate. Defer this lint to elsewhere
None => return,
}
// If the first element of our path was actually resolved to an
// `ExternCrate` (also used for `crate::...`) then no need to issue a
// warning, this looks all good!
if let Some(binding) = second_binding {
if let NameBindingKind::Import { import, .. } = binding.kind {
// Careful: we still want to rewrite paths from renamed extern crates.
if let ImportKind::ExternCrate { source: None, .. } = import.kind {
return;
}
}
}
let diag = BuiltinLintDiagnostics::AbsPathWithModule(diag_span);
self.lint_buffer.buffer_lint_with_diagnostic(
lint::builtin::ABSOLUTE_PATHS_NOT_STARTING_WITH_CRATE,
diag_id,
diag_span,
"absolute paths must start with `self`, `super`, \
`crate`, or an external crate name in the 2018 edition",
diag,
);
}
// Validate a local resolution (from ribs).
fn validate_res_from_ribs(
&mut self,
rib_index: usize,
rib_ident: Ident,
mut res: Res,
record_used: bool,
span: Span,
original_rib_ident_def: Ident,
all_ribs: &[Rib<'a>],
) -> Res {
const CG_BUG_STR: &str = "min_const_generics resolve check didn't stop compilation";
debug!("validate_res_from_ribs({:?})", res);
let ribs = &all_ribs[rib_index + 1..];
// An invalid forward use of a type parameter from a previous default.
if let ForwardTyParamBanRibKind = all_ribs[rib_index].kind {
if record_used {
let res_error = if rib_ident.name == kw::SelfUpper {
ResolutionError::SelfInTyParamDefault
} else {
ResolutionError::ForwardDeclaredTyParam
};
self.report_error(span, res_error);
}
assert_eq!(res, Res::Err);
return Res::Err;
}
match res {
Res::Local(_) => {
use ResolutionError::*;
let mut res_err = None;
for rib in ribs {
match rib.kind {
NormalRibKind
| ClosureOrAsyncRibKind
| ModuleRibKind(..)
| MacroDefinition(..)
| ForwardTyParamBanRibKind => {
// Nothing to do. Continue.
}
ItemRibKind(_) | FnItemRibKind | AssocItemRibKind => {
// This was an attempt to access an upvar inside a
// named function item. This is not allowed, so we
// report an error.
if record_used {
// We don't immediately trigger a resolve error, because
// we want certain other resolution errors (namely those
// emitted for `ConstantItemRibKind` below) to take
// precedence.
res_err = Some(CannotCaptureDynamicEnvironmentInFnItem);
}
}
ConstantItemRibKind(_, item) => {
// Still doesn't deal with upvars
if record_used {
let (span, resolution_error) =
if let Some((ident, constant_item_kind)) = item {
let kind_str = match constant_item_kind {
ConstantItemKind::Const => "const",
ConstantItemKind::Static => "static",
};
(
span,
AttemptToUseNonConstantValueInConstant(
ident, "let", kind_str,
),
)
} else {
(
rib_ident.span,
AttemptToUseNonConstantValueInConstant(
original_rib_ident_def,
"const",
"let",
),
)
};
self.report_error(span, resolution_error);
}
return Res::Err;
}
ConstParamTyRibKind => {
if record_used {
self.report_error(span, ParamInTyOfConstParam(rib_ident.name));
}
return Res::Err;
}
}
}
if let Some(res_err) = res_err {
self.report_error(span, res_err);
return Res::Err;
}
}
Res::Def(DefKind::TyParam, _) | Res::SelfTy(..) => {
let mut in_ty_param_default = false;
for rib in ribs {
let has_generic_params = match rib.kind {
NormalRibKind
| ClosureOrAsyncRibKind
| AssocItemRibKind
| ModuleRibKind(..)
| MacroDefinition(..) => {
// Nothing to do. Continue.
continue;
}
// We only forbid constant items if we are inside of type defaults,
// for example `struct Foo<T, U = [u8; std::mem::size_of::<T>()]>`
ForwardTyParamBanRibKind => {
in_ty_param_default = true;
continue;
}
ConstantItemRibKind(trivial, _) => {
let features = self.session.features_untracked();
// HACK(min_const_generics): We currently only allow `N` or `{ N }`.
if !(trivial
|| features.const_generics
|| features.lazy_normalization_consts)
{
// HACK(min_const_generics): If we encounter `Self` in an anonymous constant
// we can't easily tell if it's generic at this stage, so we instead remember
// this and then enforce the self type to be concrete later on.
if let Res::SelfTy(trait_def, Some((impl_def, _))) = res {
res = Res::SelfTy(trait_def, Some((impl_def, true)));
} else {
if record_used {
self.report_error(
span,
ResolutionError::ParamInNonTrivialAnonConst {
name: rib_ident.name,
is_type: true,
},
);
}
self.session.delay_span_bug(span, CG_BUG_STR);
return Res::Err;
}
}
if in_ty_param_default {
if record_used {
self.report_error(
span,
ResolutionError::ParamInAnonConstInTyDefault(
rib_ident.name,
),
);
}
return Res::Err;
} else {
continue;
}
}
// This was an attempt to use a type parameter outside its scope.
ItemRibKind(has_generic_params) => has_generic_params,
FnItemRibKind => HasGenericParams::Yes,
ConstParamTyRibKind => {
if record_used {
self.report_error(
span,
ResolutionError::ParamInTyOfConstParam(rib_ident.name),
);
}
return Res::Err;
}
};
if record_used {
self.report_error(
span,
ResolutionError::GenericParamsFromOuterFunction(
res,
has_generic_params,
),
);
}
return Res::Err;
}
}
Res::Def(DefKind::ConstParam, _) => {
let mut ribs = ribs.iter().peekable();
if let Some(Rib { kind: FnItemRibKind, .. }) = ribs.peek() {
// When declaring const parameters inside function signatures, the first rib
// is always a `FnItemRibKind`. In this case, we can skip it, to avoid it
// (spuriously) conflicting with the const param.
ribs.next();
}
let mut in_ty_param_default = false;
for rib in ribs {
let has_generic_params = match rib.kind {
NormalRibKind
| ClosureOrAsyncRibKind
| AssocItemRibKind
| ModuleRibKind(..)
| MacroDefinition(..) => continue,
// We only forbid constant items if we are inside of type defaults,
// for example `struct Foo<T, U = [u8; std::mem::size_of::<T>()]>`
ForwardTyParamBanRibKind => {
in_ty_param_default = true;
continue;
}
ConstantItemRibKind(trivial, _) => {
let features = self.session.features_untracked();
// HACK(min_const_generics): We currently only allow `N` or `{ N }`.
if !(trivial
|| features.const_generics
|| features.lazy_normalization_consts)
{
if record_used {
self.report_error(
span,
ResolutionError::ParamInNonTrivialAnonConst {
name: rib_ident.name,
is_type: false,
},
);
}
self.session.delay_span_bug(span, CG_BUG_STR);
return Res::Err;
}
if in_ty_param_default {
if record_used {
self.report_error(
span,
ResolutionError::ParamInAnonConstInTyDefault(
rib_ident.name,
),
);
}
return Res::Err;
} else {
continue;
}
}
ItemRibKind(has_generic_params) => has_generic_params,
FnItemRibKind => HasGenericParams::Yes,
ConstParamTyRibKind => {
if record_used {
self.report_error(
span,
ResolutionError::ParamInTyOfConstParam(rib_ident.name),
);
}
return Res::Err;
}
};
// This was an attempt to use a const parameter outside its scope.
if record_used {
self.report_error(
span,
ResolutionError::GenericParamsFromOuterFunction(
res,
has_generic_params,
),
);
}
return Res::Err;
}
}
_ => {}
}
res
}
fn record_partial_res(&mut self, node_id: NodeId, resolution: PartialRes) {
debug!("(recording res) recording {:?} for {}", resolution, node_id);
if let Some(prev_res) = self.partial_res_map.insert(node_id, resolution) {
panic!("path resolved multiple times ({:?} before, {:?} now)", prev_res, resolution);
}
}
fn is_accessible_from(&self, vis: ty::Visibility, module: Module<'a>) -> bool {
vis.is_accessible_from(module.nearest_parent_mod, self)
}
fn set_binding_parent_module(&mut self, binding: &'a NameBinding<'a>, module: Module<'a>) {
if let Some(old_module) = self.binding_parent_modules.insert(PtrKey(binding), module) {
if !ptr::eq(module, old_module) {
span_bug!(binding.span, "parent module is reset for binding");
}
}
}
fn disambiguate_macro_rules_vs_modularized(
&self,
macro_rules: &'a NameBinding<'a>,
modularized: &'a NameBinding<'a>,
) -> bool {
// Some non-controversial subset of ambiguities "modularized macro name" vs "macro_rules"
// is disambiguated to mitigate regressions from macro modularization.
// Scoping for `macro_rules` behaves like scoping for `let` at module level, in general.
match (
self.binding_parent_modules.get(&PtrKey(macro_rules)),
self.binding_parent_modules.get(&PtrKey(modularized)),
) {
(Some(macro_rules), Some(modularized)) => {
macro_rules.nearest_parent_mod == modularized.nearest_parent_mod
&& modularized.is_ancestor_of(macro_rules)
}
_ => false,
}
}
fn report_errors(&mut self, krate: &Crate) {
self.report_with_use_injections(krate);
for &(span_use, span_def) in &self.macro_expanded_macro_export_errors {
let msg = "macro-expanded `macro_export` macros from the current crate \
cannot be referred to by absolute paths";
self.lint_buffer.buffer_lint_with_diagnostic(
lint::builtin::MACRO_EXPANDED_MACRO_EXPORTS_ACCESSED_BY_ABSOLUTE_PATHS,
CRATE_NODE_ID,
span_use,
msg,
BuiltinLintDiagnostics::MacroExpandedMacroExportsAccessedByAbsolutePaths(span_def),
);
}
for ambiguity_error in &self.ambiguity_errors {
self.report_ambiguity_error(ambiguity_error);
}
let mut reported_spans = FxHashSet::default();
for error in &self.privacy_errors {
if reported_spans.insert(error.dedup_span) {
self.report_privacy_error(error);
}
}
}
fn report_with_use_injections(&mut self, krate: &Crate) {
for UseError { mut err, candidates, def_id, instead, suggestion } in
self.use_injections.drain(..)
{
let (span, found_use) = if let Some(def_id) = def_id.as_local() {
UsePlacementFinder::check(krate, self.def_id_to_node_id[def_id])
} else {
(None, false)
};
if !candidates.is_empty() {
diagnostics::show_candidates(&mut err, span, &candidates, instead, found_use);
} else if let Some((span, msg, sugg, appl)) = suggestion {
err.span_suggestion(span, msg, sugg, appl);
}
err.emit();
}
}
fn report_conflict<'b>(
&mut self,
parent: Module<'_>,
ident: Ident,
ns: Namespace,
new_binding: &NameBinding<'b>,
old_binding: &NameBinding<'b>,
) {
// Error on the second of two conflicting names
if old_binding.span.lo() > new_binding.span.lo() {
return self.report_conflict(parent, ident, ns, old_binding, new_binding);
}
let container = match parent.kind {
ModuleKind::Def(kind, _, _) => kind.descr(parent.def_id().unwrap()),
ModuleKind::Block(..) => "block",
};
let old_noun = match old_binding.is_import() {
true => "import",
false => "definition",
};
let new_participle = match new_binding.is_import() {
true => "imported",
false => "defined",
};
let (name, span) =
(ident.name, self.session.source_map().guess_head_span(new_binding.span));
if let Some(s) = self.name_already_seen.get(&name) {
if s == &span {
return;
}
}
let old_kind = match (ns, old_binding.module()) {
(ValueNS, _) => "value",
(MacroNS, _) => "macro",
(TypeNS, _) if old_binding.is_extern_crate() => "extern crate",
(TypeNS, Some(module)) if module.is_normal() => "module",
(TypeNS, Some(module)) if module.is_trait() => "trait",
(TypeNS, _) => "type",
};
let msg = format!("the name `{}` is defined multiple times", name);
let mut err = match (old_binding.is_extern_crate(), new_binding.is_extern_crate()) {
(true, true) => struct_span_err!(self.session, span, E0259, "{}", msg),
(true, _) | (_, true) => match new_binding.is_import() && old_binding.is_import() {
true => struct_span_err!(self.session, span, E0254, "{}", msg),
false => struct_span_err!(self.session, span, E0260, "{}", msg),
},
_ => match (old_binding.is_import(), new_binding.is_import()) {
(false, false) => struct_span_err!(self.session, span, E0428, "{}", msg),
(true, true) => struct_span_err!(self.session, span, E0252, "{}", msg),
_ => struct_span_err!(self.session, span, E0255, "{}", msg),
},
};
err.note(&format!(
"`{}` must be defined only once in the {} namespace of this {}",
name,
ns.descr(),
container
));
err.span_label(span, format!("`{}` re{} here", name, new_participle));
err.span_label(
self.session.source_map().guess_head_span(old_binding.span),
format!("previous {} of the {} `{}` here", old_noun, old_kind, name),
);
// See https://github.com/rust-lang/rust/issues/32354
use NameBindingKind::Import;
let import = match (&new_binding.kind, &old_binding.kind) {
// If there are two imports where one or both have attributes then prefer removing the
// import without attributes.
(Import { import: new, .. }, Import { import: old, .. })
if {
!new_binding.span.is_dummy()
&& !old_binding.span.is_dummy()
&& (new.has_attributes || old.has_attributes)
} =>
{
if old.has_attributes {
Some((new, new_binding.span, true))
} else {
Some((old, old_binding.span, true))
}
}
// Otherwise prioritize the new binding.
(Import { import, .. }, other) if !new_binding.span.is_dummy() => {
Some((import, new_binding.span, other.is_import()))
}
(other, Import { import, .. }) if !old_binding.span.is_dummy() => {
Some((import, old_binding.span, other.is_import()))
}
_ => None,
};
// Check if the target of the use for both bindings is the same.
let duplicate = new_binding.res().opt_def_id() == old_binding.res().opt_def_id();
let has_dummy_span = new_binding.span.is_dummy() || old_binding.span.is_dummy();
let from_item =
self.extern_prelude.get(&ident).map_or(true, |entry| entry.introduced_by_item);
// Only suggest removing an import if both bindings are to the same def, if both spans
// aren't dummy spans. Further, if both bindings are imports, then the ident must have
// been introduced by a item.
let should_remove_import = duplicate
&& !has_dummy_span
&& ((new_binding.is_extern_crate() || old_binding.is_extern_crate()) || from_item);
match import {
Some((import, span, true)) if should_remove_import && import.is_nested() => {
self.add_suggestion_for_duplicate_nested_use(&mut err, import, span)
}
Some((import, _, true)) if should_remove_import && !import.is_glob() => {
// Simple case - remove the entire import. Due to the above match arm, this can
// only be a single use so just remove it entirely.
err.tool_only_span_suggestion(
import.use_span_with_attributes,
"remove unnecessary import",
String::new(),
Applicability::MaybeIncorrect,
);
}
Some((import, span, _)) => {
self.add_suggestion_for_rename_of_use(&mut err, name, import, span)
}
_ => {}
}
err.emit();
self.name_already_seen.insert(name, span);
}
/// This function adds a suggestion to change the binding name of a new import that conflicts
/// with an existing import.
///
/// ```text,ignore (diagnostic)
/// help: you can use `as` to change the binding name of the import
/// |
/// LL | use foo::bar as other_bar;
/// | ^^^^^^^^^^^^^^^^^^^^^
/// ```
fn add_suggestion_for_rename_of_use(
&self,
err: &mut DiagnosticBuilder<'_>,
name: Symbol,
import: &Import<'_>,
binding_span: Span,
) {
let suggested_name = if name.as_str().chars().next().unwrap().is_uppercase() {
format!("Other{}", name)
} else {
format!("other_{}", name)
};
let mut suggestion = None;
match import.kind {
ImportKind::Single { type_ns_only: true, .. } => {
suggestion = Some(format!("self as {}", suggested_name))
}
ImportKind::Single { source, .. } => {
if let Some(pos) =
source.span.hi().0.checked_sub(binding_span.lo().0).map(|pos| pos as usize)
{
if let Ok(snippet) = self.session.source_map().span_to_snippet(binding_span) {
if pos <= snippet.len() {
suggestion = Some(format!(
"{} as {}{}",
&snippet[..pos],
suggested_name,
if snippet.ends_with(';') { ";" } else { "" }
))
}
}
}
}
ImportKind::ExternCrate { source, target, .. } => {
suggestion = Some(format!(
"extern crate {} as {};",
source.unwrap_or(target.name),
suggested_name,
))
}
_ => unreachable!(),
}
let rename_msg = "you can use `as` to change the binding name of the import";
if let Some(suggestion) = suggestion {
err.span_suggestion(
binding_span,
rename_msg,
suggestion,
Applicability::MaybeIncorrect,
);
} else {
err.span_label(binding_span, rename_msg);
}
}
/// This function adds a suggestion to remove a unnecessary binding from an import that is
/// nested. In the following example, this function will be invoked to remove the `a` binding
/// in the second use statement:
///
/// ```ignore (diagnostic)
/// use issue_52891::a;
/// use issue_52891::{d, a, e};
/// ```
///
/// The following suggestion will be added:
///
/// ```ignore (diagnostic)
/// use issue_52891::{d, a, e};
/// ^-- help: remove unnecessary import
/// ```
///
/// If the nested use contains only one import then the suggestion will remove the entire
/// line.
///
/// It is expected that the provided import is nested - this isn't checked by the
/// function. If this invariant is not upheld, this function's behaviour will be unexpected
/// as characters expected by span manipulations won't be present.
fn add_suggestion_for_duplicate_nested_use(
&self,
err: &mut DiagnosticBuilder<'_>,
import: &Import<'_>,
binding_span: Span,
) {
assert!(import.is_nested());
let message = "remove unnecessary import";
// Two examples will be used to illustrate the span manipulations we're doing:
//
// - Given `use issue_52891::{d, a, e};` where `a` is a duplicate then `binding_span` is
// `a` and `import.use_span` is `issue_52891::{d, a, e};`.
// - Given `use issue_52891::{d, e, a};` where `a` is a duplicate then `binding_span` is
// `a` and `import.use_span` is `issue_52891::{d, e, a};`.
let (found_closing_brace, span) =
find_span_of_binding_until_next_binding(self.session, binding_span, import.use_span);
// If there was a closing brace then identify the span to remove any trailing commas from
// previous imports.
if found_closing_brace {
if let Some(span) = extend_span_to_previous_binding(self.session, span) {
err.tool_only_span_suggestion(
span,
message,
String::new(),
Applicability::MaybeIncorrect,
);
} else {
// Remove the entire line if we cannot extend the span back, this indicates a
// `issue_52891::{self}` case.
err.span_suggestion(
import.use_span_with_attributes,
message,
String::new(),
Applicability::MaybeIncorrect,
);
}
return;
}
err.span_suggestion(span, message, String::new(), Applicability::MachineApplicable);
}
fn extern_prelude_get(
&mut self,
ident: Ident,
speculative: bool,
) -> Option<&'a NameBinding<'a>> {
if ident.is_path_segment_keyword() {
// Make sure `self`, `super` etc produce an error when passed to here.
return None;
}
self.extern_prelude.get(&ident.normalize_to_macros_2_0()).cloned().and_then(|entry| {
if let Some(binding) = entry.extern_crate_item {
if !speculative && entry.introduced_by_item {
self.record_use(ident, TypeNS, binding, false);
}
Some(binding)
} else {
let crate_id = if !speculative {
self.crate_loader.process_path_extern(ident.name, ident.span)
} else {
self.crate_loader.maybe_process_path_extern(ident.name)?
};
let crate_root = self.get_module(DefId { krate: crate_id, index: CRATE_DEF_INDEX });
Some(
(crate_root, ty::Visibility::Public, DUMMY_SP, ExpnId::root())
.to_name_binding(self.arenas),
)
}
})
}
/// This is equivalent to `get_traits_in_module_containing_item`, but without filtering by the associated item.
///
/// This is used by rustdoc for intra-doc links.
pub fn traits_in_scope(&mut self, module_id: DefId) -> Vec<TraitCandidate> {
let module = self.get_module(module_id);
module.ensure_traits(self);
let traits = module.traits.borrow();
let to_candidate =
|this: &mut Self, &(trait_name, binding): &(Ident, &NameBinding<'_>)| TraitCandidate {
def_id: binding.res().def_id(),
import_ids: this.find_transitive_imports(&binding.kind, trait_name),
};
let mut candidates: Vec<_> =
traits.as_ref().unwrap().iter().map(|x| to_candidate(self, x)).collect();
if let Some(prelude) = self.prelude {
if !module.no_implicit_prelude {
prelude.ensure_traits(self);
candidates.extend(
prelude.traits.borrow().as_ref().unwrap().iter().map(|x| to_candidate(self, x)),
);
}
}
candidates
}
/// Rustdoc uses this to resolve things in a recoverable way. `ResolutionError<'a>`
/// isn't something that can be returned because it can't be made to live that long,
/// and also it's a private type. Fortunately rustdoc doesn't need to know the error,
/// just that an error occurred.
// FIXME(Manishearth): intra-doc links won't get warned of epoch changes.
pub fn resolve_str_path_error(
&mut self,
span: Span,
path_str: &str,
ns: Namespace,
module_id: DefId,
) -> Result<(ast::Path, Res), ()> {
let path = if path_str.starts_with("::") {
ast::Path {
span,
segments: iter::once(Ident::with_dummy_span(kw::PathRoot))
.chain(path_str.split("::").skip(1).map(Ident::from_str))
.map(|i| self.new_ast_path_segment(i))
.collect(),
tokens: None,
}
} else {
ast::Path {
span,
segments: path_str
.split("::")
.map(Ident::from_str)
.map(|i| self.new_ast_path_segment(i))
.collect(),
tokens: None,
}
};
let module = self.get_module(module_id);
let parent_scope = &ParentScope::module(module, self);
let res = self.resolve_ast_path(&path, ns, parent_scope).map_err(|_| ())?;
Ok((path, res))
}
// Resolve a path passed from rustdoc or HIR lowering.
fn resolve_ast_path(
&mut self,
path: &ast::Path,
ns: Namespace,
parent_scope: &ParentScope<'a>,
) -> Result<Res, (Span, ResolutionError<'a>)> {
match self.resolve_path(
&Segment::from_path(path),
Some(ns),
parent_scope,
false,
path.span,
CrateLint::No,
) {
PathResult::Module(ModuleOrUniformRoot::Module(module)) => Ok(module.res().unwrap()),
PathResult::NonModule(path_res) if path_res.unresolved_segments() == 0 => {
Ok(path_res.base_res())
}
PathResult::NonModule(..) => Err((
path.span,
ResolutionError::FailedToResolve {
label: String::from("type-relative paths are not supported in this context"),
suggestion: None,
},
)),
PathResult::Module(..) | PathResult::Indeterminate => unreachable!(),
PathResult::Failed { span, label, suggestion, .. } => {
Err((span, ResolutionError::FailedToResolve { label, suggestion }))
}
}
}
fn new_ast_path_segment(&mut self, ident: Ident) -> ast::PathSegment {
let mut seg = ast::PathSegment::from_ident(ident);
seg.id = self.next_node_id();
seg
}
// For rustdoc.
pub fn graph_root(&self) -> Module<'a> {
self.graph_root
}
// For rustdoc.
pub fn all_macros(&self) -> &FxHashMap<Symbol, Res> {
&self.all_macros
}
/// Retrieves the span of the given `DefId` if `DefId` is in the local crate.
#[inline]
pub fn opt_span(&self, def_id: DefId) -> Option<Span> {
if let Some(def_id) = def_id.as_local() { Some(self.def_id_to_span[def_id]) } else { None }
}
}
fn names_to_string(names: &[Symbol]) -> String {
let mut result = String::new();
for (i, name) in names.iter().filter(|name| **name != kw::PathRoot).enumerate() {
if i > 0 {
result.push_str("::");
}
if Ident::with_dummy_span(*name).is_raw_guess() {
result.push_str("r#");
}
result.push_str(&name.as_str());
}
result
}
fn path_names_to_string(path: &Path) -> String {
names_to_string(&path.segments.iter().map(|seg| seg.ident.name).collect::<Vec<_>>())
}
/// A somewhat inefficient routine to obtain the name of a module.
fn module_to_string(module: Module<'_>) -> Option<String> {
let mut names = Vec::new();
fn collect_mod(names: &mut Vec<Symbol>, module: Module<'_>) {
if let ModuleKind::Def(.., name) = module.kind {
if let Some(parent) = module.parent {
names.push(name);
collect_mod(names, parent);
}
} else {
names.push(Symbol::intern("<opaque>"));
collect_mod(names, module.parent.unwrap());
}
}
collect_mod(&mut names, module);
if names.is_empty() {
return None;
}
names.reverse();
Some(names_to_string(&names))
}
#[derive(Copy, Clone, Debug)]
enum CrateLint {
/// Do not issue the lint.
No,
/// This lint applies to some arbitrary path; e.g., `impl ::foo::Bar`.
/// In this case, we can take the span of that path.
SimplePath(NodeId),
/// This lint comes from a `use` statement. In this case, what we
/// care about really is the *root* `use` statement; e.g., if we
/// have nested things like `use a::{b, c}`, we care about the
/// `use a` part.
UsePath { root_id: NodeId, root_span: Span },
/// This is the "trait item" from a fully qualified path. For example,
/// we might be resolving `X::Y::Z` from a path like `<T as X::Y>::Z`.
/// The `path_span` is the span of the to the trait itself (`X::Y`).
QPathTrait { qpath_id: NodeId, qpath_span: Span },
}
impl CrateLint {
fn node_id(&self) -> Option<NodeId> {
match *self {
CrateLint::No => None,
CrateLint::SimplePath(id)
| CrateLint::UsePath { root_id: id, .. }
| CrateLint::QPathTrait { qpath_id: id, .. } => Some(id),
}
}
}
pub fn provide(providers: &mut Providers) {
late::lifetimes::provide(providers);
}
Reference in New Issue View Git Blame Copy Permalink