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collect_intra_doc_links.rs
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collect_intra_doc_links.rs
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//! This module implements [RFC 1946]: Intra-rustdoc-links
//!
//! [RFC 1946]: https://github.com/rust-lang/rfcs/blob/master/text/1946-intra-rustdoc-links.md
use rustc_ast as ast;
use rustc_data_structures::{fx::FxHashMap, stable_set::FxHashSet};
use rustc_errors::{Applicability, DiagnosticBuilder};
use rustc_expand::base::SyntaxExtensionKind;
use rustc_hir as hir;
use rustc_hir::def::{
DefKind,
Namespace::{self, *},
PerNS,
};
use rustc_hir::def_id::{CrateNum, DefId};
use rustc_middle::ty::TyCtxt;
use rustc_middle::{bug, ty};
use rustc_resolve::ParentScope;
use rustc_session::lint::{
builtin::{BROKEN_INTRA_DOC_LINKS, PRIVATE_INTRA_DOC_LINKS},
Lint,
};
use rustc_span::hygiene::{MacroKind, SyntaxContext};
use rustc_span::symbol::{sym, Ident, Symbol};
use rustc_span::DUMMY_SP;
use smallvec::{smallvec, SmallVec};
use pulldown_cmark::LinkType;
use std::borrow::Cow;
use std::cell::Cell;
use std::convert::{TryFrom, TryInto};
use std::mem;
use std::ops::Range;
use crate::clean::{self, utils::find_nearest_parent_module, Crate, Item, ItemLink, PrimitiveType};
use crate::core::DocContext;
use crate::fold::DocFolder;
use crate::html::markdown::{markdown_links, MarkdownLink};
use crate::passes::Pass;
use super::span_of_attrs;
crate const COLLECT_INTRA_DOC_LINKS: Pass = Pass {
name: "collect-intra-doc-links",
run: collect_intra_doc_links,
description: "resolves intra-doc links",
};
crate fn collect_intra_doc_links(krate: Crate, cx: &mut DocContext<'_>) -> Crate {
LinkCollector {
cx,
mod_ids: Vec::new(),
kind_side_channel: Cell::new(None),
visited_links: FxHashMap::default(),
}
.fold_crate(krate)
}
/// Top-level errors emitted by this pass.
enum ErrorKind<'a> {
Resolve(Box<ResolutionFailure<'a>>),
AnchorFailure(AnchorFailure),
}
impl<'a> From<ResolutionFailure<'a>> for ErrorKind<'a> {
fn from(err: ResolutionFailure<'a>) -> Self {
ErrorKind::Resolve(box err)
}
}
#[derive(Copy, Clone, Debug, Hash)]
enum Res {
Def(DefKind, DefId),
Primitive(PrimitiveType),
}
type ResolveRes = rustc_hir::def::Res<rustc_ast::NodeId>;
impl Res {
fn descr(self) -> &'static str {
match self {
Res::Def(kind, id) => ResolveRes::Def(kind, id).descr(),
Res::Primitive(_) => "builtin type",
}
}
fn article(self) -> &'static str {
match self {
Res::Def(kind, id) => ResolveRes::Def(kind, id).article(),
Res::Primitive(_) => "a",
}
}
fn name(self, tcx: TyCtxt<'_>) -> String {
match self {
Res::Def(_, id) => tcx.item_name(id).to_string(),
Res::Primitive(prim) => prim.as_str().to_string(),
}
}
fn def_id(self) -> DefId {
self.opt_def_id().expect("called def_id() on a primitive")
}
fn opt_def_id(self) -> Option<DefId> {
match self {
Res::Def(_, id) => Some(id),
Res::Primitive(_) => None,
}
}
fn as_hir_res(self) -> Option<rustc_hir::def::Res> {
match self {
Res::Def(kind, id) => Some(rustc_hir::def::Res::Def(kind, id)),
// FIXME: maybe this should handle the subset of PrimitiveType that fits into hir::PrimTy?
Res::Primitive(_) => None,
}
}
}
impl TryFrom<ResolveRes> for Res {
type Error = ();
fn try_from(res: ResolveRes) -> Result<Self, ()> {
use rustc_hir::def::Res::*;
match res {
Def(kind, id) => Ok(Res::Def(kind, id)),
PrimTy(prim) => Ok(Res::Primitive(PrimitiveType::from_hir(prim))),
// e.g. `#[derive]`
NonMacroAttr(..) | Err => Result::Err(()),
other => bug!("unrecognized res {:?}", other),
}
}
}
/// A link failed to resolve.
#[derive(Debug)]
enum ResolutionFailure<'a> {
/// This resolved, but with the wrong namespace.
WrongNamespace {
/// What the link resolved to.
res: Res,
/// The expected namespace for the resolution, determined from the link's disambiguator.
///
/// E.g., for `[fn@Result]` this is [`Namespace::ValueNS`],
/// even though `Result`'s actual namespace is [`Namespace::TypeNS`].
expected_ns: Namespace,
},
/// The link failed to resolve. [`resolution_failure`] should look to see if there's
/// a more helpful error that can be given.
NotResolved {
/// The scope the link was resolved in.
module_id: DefId,
/// If part of the link resolved, this has the `Res`.
///
/// In `[std::io::Error::x]`, `std::io::Error` would be a partial resolution.
partial_res: Option<Res>,
/// The remaining unresolved path segments.
///
/// In `[std::io::Error::x]`, `x` would be unresolved.
unresolved: Cow<'a, str>,
},
/// This happens when rustdoc can't determine the parent scope for an item.
/// It is always a bug in rustdoc.
NoParentItem,
/// This link has malformed generic parameters; e.g., the angle brackets are unbalanced.
MalformedGenerics(MalformedGenerics),
/// Used to communicate that this should be ignored, but shouldn't be reported to the user.
///
/// This happens when there is no disambiguator and one of the namespaces
/// failed to resolve.
Dummy,
}
#[derive(Debug)]
enum MalformedGenerics {
/// This link has unbalanced angle brackets.
///
/// For example, `Vec<T` should trigger this, as should `Vec<T>>`.
UnbalancedAngleBrackets,
/// The generics are not attached to a type.
///
/// For example, `<T>` should trigger this.
///
/// This is detected by checking if the path is empty after the generics are stripped.
MissingType,
/// The link uses fully-qualified syntax, which is currently unsupported.
///
/// For example, `<Vec as IntoIterator>::into_iter` should trigger this.
///
/// This is detected by checking if ` as ` (the keyword `as` with spaces around it) is inside
/// angle brackets.
HasFullyQualifiedSyntax,
/// The link has an invalid path separator.
///
/// For example, `Vec:<T>:new()` should trigger this. Note that `Vec:new()` will **not**
/// trigger this because it has no generics and thus [`strip_generics_from_path`] will not be
/// called.
///
/// Note that this will also **not** be triggered if the invalid path separator is inside angle
/// brackets because rustdoc mostly ignores what's inside angle brackets (except for
/// [`HasFullyQualifiedSyntax`](MalformedGenerics::HasFullyQualifiedSyntax)).
///
/// This is detected by checking if there is a colon followed by a non-colon in the link.
InvalidPathSeparator,
/// The link has too many angle brackets.
///
/// For example, `Vec<<T>>` should trigger this.
TooManyAngleBrackets,
/// The link has empty angle brackets.
///
/// For example, `Vec<>` should trigger this.
EmptyAngleBrackets,
}
impl ResolutionFailure<'a> {
/// This resolved fully (not just partially) but is erroneous for some other reason
///
/// Returns the full resolution of the link, if present.
fn full_res(&self) -> Option<Res> {
match self {
Self::WrongNamespace { res, expected_ns: _ } => Some(*res),
_ => None,
}
}
}
enum AnchorFailure {
/// User error: `[std#x#y]` is not valid
MultipleAnchors,
/// The anchor provided by the user conflicts with Rustdoc's generated anchor.
///
/// This is an unfortunate state of affairs. Not every item that can be
/// linked to has its own page; sometimes it is a subheading within a page,
/// like for associated items. In those cases, rustdoc uses an anchor to
/// link to the subheading. Since you can't have two anchors for the same
/// link, Rustdoc disallows having a user-specified anchor.
///
/// Most of the time this is fine, because you can just link to the page of
/// the item if you want to provide your own anchor. For primitives, though,
/// rustdoc uses the anchor as a side channel to know which page to link to;
/// it doesn't show up in the generated link. Ideally, rustdoc would remove
/// this limitation, allowing you to link to subheaders on primitives.
RustdocAnchorConflict(Res),
}
#[derive(Clone, Debug, Hash, PartialEq, Eq)]
struct ResolutionInfo {
module_id: DefId,
dis: Option<Disambiguator>,
path_str: String,
extra_fragment: Option<String>,
}
struct DiagnosticInfo<'a> {
item: &'a Item,
dox: &'a str,
ori_link: &'a str,
link_range: Range<usize>,
}
#[derive(Clone, Debug, Hash)]
struct CachedLink {
pub res: (Res, Option<String>),
pub side_channel: Option<(DefKind, DefId)>,
}
struct LinkCollector<'a, 'tcx> {
cx: &'a mut DocContext<'tcx>,
/// A stack of modules used to decide what scope to resolve in.
///
/// The last module will be used if the parent scope of the current item is
/// unknown.
mod_ids: Vec<DefId>,
/// This is used to store the kind of associated items,
/// because `clean` and the disambiguator code expect them to be different.
/// See the code for associated items on inherent impls for details.
kind_side_channel: Cell<Option<(DefKind, DefId)>>,
/// Cache the resolved links so we can avoid resolving (and emitting errors for) the same link.
/// The link will be `None` if it could not be resolved (i.e. the error was cached).
visited_links: FxHashMap<ResolutionInfo, Option<CachedLink>>,
}
impl<'a, 'tcx> LinkCollector<'a, 'tcx> {
/// Given a full link, parse it as an [enum struct variant].
///
/// In particular, this will return an error whenever there aren't three
/// full path segments left in the link.
///
/// [enum struct variant]: hir::VariantData::Struct
fn variant_field(
&self,
path_str: &'path str,
module_id: DefId,
) -> Result<(Res, Option<String>), ErrorKind<'path>> {
let tcx = self.cx.tcx;
let no_res = || ResolutionFailure::NotResolved {
module_id,
partial_res: None,
unresolved: path_str.into(),
};
debug!("looking for enum variant {}", path_str);
let mut split = path_str.rsplitn(3, "::");
let (variant_field_str, variant_field_name) = split
.next()
.map(|f| (f, Symbol::intern(f)))
.expect("fold_item should ensure link is non-empty");
let (variant_str, variant_name) =
// we're not sure this is a variant at all, so use the full string
// If there's no second component, the link looks like `[path]`.
// So there's no partial res and we should say the whole link failed to resolve.
split.next().map(|f| (f, Symbol::intern(f))).ok_or_else(no_res)?;
let path = split
.next()
.map(|f| f.to_owned())
// If there's no third component, we saw `[a::b]` before and it failed to resolve.
// So there's no partial res.
.ok_or_else(no_res)?;
let ty_res = self
.cx
.enter_resolver(|resolver| {
resolver.resolve_str_path_error(DUMMY_SP, &path, TypeNS, module_id)
})
.and_then(|(_, res)| res.try_into())
.map_err(|()| no_res())?;
match ty_res {
Res::Def(DefKind::Enum, did) => {
if tcx
.inherent_impls(did)
.iter()
.flat_map(|imp| tcx.associated_items(*imp).in_definition_order())
.any(|item| item.ident.name == variant_name)
{
// This is just to let `fold_item` know that this shouldn't be considered;
// it's a bug for the error to make it to the user
return Err(ResolutionFailure::Dummy.into());
}
match tcx.type_of(did).kind() {
ty::Adt(def, _) if def.is_enum() => {
if def.all_fields().any(|item| item.ident.name == variant_field_name) {
Ok((
ty_res,
Some(format!(
"variant.{}.field.{}",
variant_str, variant_field_name
)),
))
} else {
Err(ResolutionFailure::NotResolved {
module_id,
partial_res: Some(Res::Def(DefKind::Enum, def.did)),
unresolved: variant_field_str.into(),
}
.into())
}
}
_ => unreachable!(),
}
}
_ => Err(ResolutionFailure::NotResolved {
module_id,
partial_res: Some(ty_res),
unresolved: variant_str.into(),
}
.into()),
}
}
/// Given a primitive type, try to resolve an associated item.
///
/// HACK(jynelson): `item_str` is passed in instead of derived from `item_name` so the
/// lifetimes on `&'path` will work.
fn resolve_primitive_associated_item(
&self,
prim_ty: PrimitiveType,
ns: Namespace,
module_id: DefId,
item_name: Symbol,
item_str: &'path str,
) -> Result<(Res, Option<String>), ErrorKind<'path>> {
let tcx = self.cx.tcx;
prim_ty
.impls(tcx)
.into_iter()
.find_map(|&impl_| {
tcx.associated_items(impl_)
.find_by_name_and_namespace(tcx, Ident::with_dummy_span(item_name), ns, impl_)
.map(|item| {
let kind = item.kind;
self.kind_side_channel.set(Some((kind.as_def_kind(), item.def_id)));
match kind {
ty::AssocKind::Fn => "method",
ty::AssocKind::Const => "associatedconstant",
ty::AssocKind::Type => "associatedtype",
}
})
.map(|out| {
(
Res::Primitive(prim_ty),
Some(format!("{}#{}.{}", prim_ty.as_str(), out, item_str)),
)
})
})
.ok_or_else(|| {
debug!(
"returning primitive error for {}::{} in {} namespace",
prim_ty.as_str(),
item_name,
ns.descr()
);
ResolutionFailure::NotResolved {
module_id,
partial_res: Some(Res::Primitive(prim_ty)),
unresolved: item_str.into(),
}
.into()
})
}
/// Resolves a string as a macro.
///
/// FIXME(jynelson): Can this be unified with `resolve()`?
fn resolve_macro(
&self,
path_str: &'a str,
module_id: DefId,
) -> Result<Res, ResolutionFailure<'a>> {
let path = ast::Path::from_ident(Ident::from_str(path_str));
self.cx.enter_resolver(|resolver| {
// FIXME(jynelson): does this really need 3 separate lookups?
if let Ok((Some(ext), res)) = resolver.resolve_macro_path(
&path,
None,
&ParentScope::module(resolver.graph_root(), resolver),
false,
false,
) {
if let SyntaxExtensionKind::LegacyBang { .. } = ext.kind {
return Ok(res.try_into().unwrap());
}
}
if let Some(&res) = resolver.all_macros().get(&Symbol::intern(path_str)) {
return Ok(res.try_into().unwrap());
}
debug!("resolving {} as a macro in the module {:?}", path_str, module_id);
if let Ok((_, res)) =
resolver.resolve_str_path_error(DUMMY_SP, path_str, MacroNS, module_id)
{
// don't resolve builtins like `#[derive]`
if let Ok(res) = res.try_into() {
return Ok(res);
}
}
Err(ResolutionFailure::NotResolved {
module_id,
partial_res: None,
unresolved: path_str.into(),
})
})
}
/// Convenience wrapper around `resolve_str_path_error`.
///
/// This also handles resolving `true` and `false` as booleans.
/// NOTE: `resolve_str_path_error` knows only about paths, not about types.
/// Associated items will never be resolved by this function.
fn resolve_path(&self, path_str: &str, ns: Namespace, module_id: DefId) -> Option<Res> {
let result = self.cx.enter_resolver(|resolver| {
resolver
.resolve_str_path_error(DUMMY_SP, &path_str, ns, module_id)
.and_then(|(_, res)| res.try_into())
});
debug!("{} resolved to {:?} in namespace {:?}", path_str, result, ns);
match result {
// resolver doesn't know about true, false, and types that aren't paths (e.g. `()`)
// manually as bool
Err(()) => resolve_primitive(path_str, ns),
Ok(res) => Some(res),
}
}
/// Resolves a string as a path within a particular namespace. Returns an
/// optional URL fragment in the case of variants and methods.
fn resolve<'path>(
&self,
path_str: &'path str,
ns: Namespace,
module_id: DefId,
extra_fragment: &Option<String>,
) -> Result<(Res, Option<String>), ErrorKind<'path>> {
let cx = &self.cx;
if let Some(res) = self.resolve_path(path_str, ns, module_id) {
match res {
// FIXME(#76467): make this fallthrough to lookup the associated
// item a separate function.
Res::Def(DefKind::AssocFn | DefKind::AssocConst, _) => assert_eq!(ns, ValueNS),
Res::Def(DefKind::AssocTy, _) => assert_eq!(ns, TypeNS),
Res::Def(DefKind::Variant, _) => return handle_variant(cx, res, extra_fragment),
// Not a trait item; just return what we found.
Res::Primitive(ty) => {
if extra_fragment.is_some() {
return Err(ErrorKind::AnchorFailure(
AnchorFailure::RustdocAnchorConflict(res),
));
}
return Ok((res, Some(ty.as_str().to_owned())));
}
_ => return Ok((res, extra_fragment.clone())),
}
}
// Try looking for methods and associated items.
let mut split = path_str.rsplitn(2, "::");
// NB: `split`'s first element is always defined, even if the delimiter was not present.
// NB: `item_str` could be empty when resolving in the root namespace (e.g. `::std`).
let item_str = split.next().unwrap();
let item_name = Symbol::intern(item_str);
let path_root = split
.next()
.map(|f| f.to_owned())
// If there's no `::`, it's not an associated item.
// So we can be sure that `rustc_resolve` was accurate when it said it wasn't resolved.
.ok_or_else(|| {
debug!("found no `::`, assumming {} was correctly not in scope", item_name);
ResolutionFailure::NotResolved {
module_id,
partial_res: None,
unresolved: item_str.into(),
}
})?;
// FIXME: are these both necessary?
let ty_res = if let Some(ty_res) = resolve_primitive(&path_root, TypeNS)
.or_else(|| self.resolve_path(&path_root, TypeNS, module_id))
{
ty_res
} else {
// FIXME: this is duplicated on the end of this function.
return if ns == Namespace::ValueNS {
self.variant_field(path_str, module_id)
} else {
Err(ResolutionFailure::NotResolved {
module_id,
partial_res: None,
unresolved: path_root.into(),
}
.into())
};
};
let res = match ty_res {
Res::Primitive(prim) => Some(
self.resolve_primitive_associated_item(prim, ns, module_id, item_name, item_str),
),
Res::Def(
DefKind::Struct
| DefKind::Union
| DefKind::Enum
| DefKind::TyAlias
| DefKind::ForeignTy,
did,
) => {
debug!("looking for associated item named {} for item {:?}", item_name, did);
// Checks if item_name belongs to `impl SomeItem`
let assoc_item = cx
.tcx
.inherent_impls(did)
.iter()
.flat_map(|&imp| {
cx.tcx.associated_items(imp).find_by_name_and_namespace(
cx.tcx,
Ident::with_dummy_span(item_name),
ns,
imp,
)
})
.map(|item| (item.kind, item.def_id))
// There should only ever be one associated item that matches from any inherent impl
.next()
// Check if item_name belongs to `impl SomeTrait for SomeItem`
// FIXME(#74563): This gives precedence to `impl SomeItem`:
// Although having both would be ambiguous, use impl version for compatibility's sake.
// To handle that properly resolve() would have to support
// something like [`ambi_fn`](<SomeStruct as SomeTrait>::ambi_fn)
.or_else(|| {
let kind =
resolve_associated_trait_item(did, module_id, item_name, ns, &self.cx);
debug!("got associated item kind {:?}", kind);
kind
});
if let Some((kind, id)) = assoc_item {
let out = match kind {
ty::AssocKind::Fn => "method",
ty::AssocKind::Const => "associatedconstant",
ty::AssocKind::Type => "associatedtype",
};
Some(if extra_fragment.is_some() {
Err(ErrorKind::AnchorFailure(AnchorFailure::RustdocAnchorConflict(ty_res)))
} else {
// HACK(jynelson): `clean` expects the type, not the associated item
// but the disambiguator logic expects the associated item.
// Store the kind in a side channel so that only the disambiguator logic looks at it.
self.kind_side_channel.set(Some((kind.as_def_kind(), id)));
Ok((ty_res, Some(format!("{}.{}", out, item_str))))
})
} else if ns == Namespace::ValueNS {
debug!("looking for variants or fields named {} for {:?}", item_name, did);
// FIXME(jynelson): why is this different from
// `variant_field`?
match cx.tcx.type_of(did).kind() {
ty::Adt(def, _) => {
let field = if def.is_enum() {
def.all_fields().find(|item| item.ident.name == item_name)
} else {
def.non_enum_variant()
.fields
.iter()
.find(|item| item.ident.name == item_name)
};
field.map(|item| {
if extra_fragment.is_some() {
let res = Res::Def(
if def.is_enum() {
DefKind::Variant
} else {
DefKind::Field
},
item.did,
);
Err(ErrorKind::AnchorFailure(
AnchorFailure::RustdocAnchorConflict(res),
))
} else {
Ok((
ty_res,
Some(format!(
"{}.{}",
if def.is_enum() { "variant" } else { "structfield" },
item.ident
)),
))
}
})
}
_ => None,
}
} else {
None
}
}
Res::Def(DefKind::Trait, did) => cx
.tcx
.associated_items(did)
.find_by_name_and_namespace(cx.tcx, Ident::with_dummy_span(item_name), ns, did)
.map(|item| {
let kind = match item.kind {
ty::AssocKind::Const => "associatedconstant",
ty::AssocKind::Type => "associatedtype",
ty::AssocKind::Fn => {
if item.defaultness.has_value() {
"method"
} else {
"tymethod"
}
}
};
if extra_fragment.is_some() {
Err(ErrorKind::AnchorFailure(AnchorFailure::RustdocAnchorConflict(ty_res)))
} else {
let res = Res::Def(item.kind.as_def_kind(), item.def_id);
Ok((res, Some(format!("{}.{}", kind, item_str))))
}
}),
_ => None,
};
res.unwrap_or_else(|| {
if ns == Namespace::ValueNS {
self.variant_field(path_str, module_id)
} else {
Err(ResolutionFailure::NotResolved {
module_id,
partial_res: Some(ty_res),
unresolved: item_str.into(),
}
.into())
}
})
}
/// Used for reporting better errors.
///
/// Returns whether the link resolved 'fully' in another namespace.
/// 'fully' here means that all parts of the link resolved, not just some path segments.
/// This returns the `Res` even if it was erroneous for some reason
/// (such as having invalid URL fragments or being in the wrong namespace).
fn check_full_res(
&self,
ns: Namespace,
path_str: &str,
module_id: DefId,
extra_fragment: &Option<String>,
) -> Option<Res> {
// resolve() can't be used for macro namespace
let result = match ns {
Namespace::MacroNS => self.resolve_macro(path_str, module_id).map_err(ErrorKind::from),
Namespace::TypeNS | Namespace::ValueNS => {
self.resolve(path_str, ns, module_id, extra_fragment).map(|(res, _)| res)
}
};
let res = match result {
Ok(res) => Some(res),
Err(ErrorKind::Resolve(box kind)) => kind.full_res(),
Err(ErrorKind::AnchorFailure(AnchorFailure::RustdocAnchorConflict(res))) => Some(res),
Err(ErrorKind::AnchorFailure(AnchorFailure::MultipleAnchors)) => None,
};
self.kind_side_channel.take().map(|(kind, id)| Res::Def(kind, id)).or(res)
}
}
/// Look to see if a resolved item has an associated item named `item_name`.
///
/// Given `[std::io::Error::source]`, where `source` is unresolved, this would
/// find `std::error::Error::source` and return
/// `<io::Error as error::Error>::source`.
fn resolve_associated_trait_item(
did: DefId,
module: DefId,
item_name: Symbol,
ns: Namespace,
cx: &DocContext<'_>,
) -> Option<(ty::AssocKind, DefId)> {
// FIXME: this should also consider blanket impls (`impl<T> X for T`). Unfortunately
// `get_auto_trait_and_blanket_impls` is broken because the caching behavior is wrong. In the
// meantime, just don't look for these blanket impls.
// Next consider explicit impls: `impl MyTrait for MyType`
// Give precedence to inherent impls.
let traits = traits_implemented_by(cx, did, module);
debug!("considering traits {:?}", traits);
let mut candidates = traits.iter().filter_map(|&trait_| {
cx.tcx
.associated_items(trait_)
.find_by_name_and_namespace(cx.tcx, Ident::with_dummy_span(item_name), ns, trait_)
.map(|assoc| (assoc.kind, assoc.def_id))
});
// FIXME(#74563): warn about ambiguity
debug!("the candidates were {:?}", candidates.clone().collect::<Vec<_>>());
candidates.next()
}
/// Given a type, return all traits in scope in `module` implemented by that type.
///
/// NOTE: this cannot be a query because more traits could be available when more crates are compiled!
/// So it is not stable to serialize cross-crate.
fn traits_implemented_by(cx: &DocContext<'_>, type_: DefId, module: DefId) -> FxHashSet<DefId> {
let mut cache = cx.module_trait_cache.borrow_mut();
let in_scope_traits = cache.entry(module).or_insert_with(|| {
cx.enter_resolver(|resolver| {
let parent_scope = &ParentScope::module(resolver.get_module(module), resolver);
resolver
.traits_in_scope(None, parent_scope, SyntaxContext::root(), None)
.into_iter()
.map(|candidate| candidate.def_id)
.collect()
})
});
let ty = cx.tcx.type_of(type_);
let iter = in_scope_traits.iter().flat_map(|&trait_| {
trace!("considering explicit impl for trait {:?}", trait_);
// Look at each trait implementation to see if it's an impl for `did`
cx.tcx.find_map_relevant_impl(trait_, ty, |impl_| {
let trait_ref = cx.tcx.impl_trait_ref(impl_).expect("this is not an inherent impl");
// Check if these are the same type.
let impl_type = trait_ref.self_ty();
trace!(
"comparing type {} with kind {:?} against type {:?}",
impl_type,
impl_type.kind(),
type_
);
// Fast path: if this is a primitive simple `==` will work
let saw_impl = impl_type == ty
|| match impl_type.kind() {
// Check if these are the same def_id
ty::Adt(def, _) => {
debug!("adt def_id: {:?}", def.did);
def.did == type_
}
ty::Foreign(def_id) => *def_id == type_,
_ => false,
};
if saw_impl { Some(trait_) } else { None }
})
});
iter.collect()
}
/// Check for resolve collisions between a trait and its derive.
///
/// These are common and we should just resolve to the trait in that case.
fn is_derive_trait_collision<T>(ns: &PerNS<Result<(Res, T), ResolutionFailure<'_>>>) -> bool {
matches!(
*ns,
PerNS {
type_ns: Ok((Res::Def(DefKind::Trait, _), _)),
macro_ns: Ok((Res::Def(DefKind::Macro(MacroKind::Derive), _), _)),
..
}
)
}
impl<'a, 'tcx> DocFolder for LinkCollector<'a, 'tcx> {
fn fold_item(&mut self, mut item: Item) -> Option<Item> {
use rustc_middle::ty::DefIdTree;
let parent_node = if item.is_fake() {
None
} else {
find_nearest_parent_module(self.cx.tcx, item.def_id)
};
if parent_node.is_some() {
trace!("got parent node for {:?} {:?}, id {:?}", item.type_(), item.name, item.def_id);
}
// find item's parent to resolve `Self` in item's docs below
debug!("looking for the `Self` type");
let self_id = if item.is_fake() {
None
} else if matches!(
self.cx.tcx.def_kind(item.def_id),
DefKind::AssocConst
| DefKind::AssocFn
| DefKind::AssocTy
| DefKind::Variant
| DefKind::Field
) {
self.cx.tcx.parent(item.def_id)
// HACK(jynelson): `clean` marks associated types as `TypedefItem`, not as `AssocTypeItem`.
// Fixing this breaks `fn render_deref_methods`.
// As a workaround, see if the parent of the item is an `impl`; if so this must be an associated item,
// regardless of what rustdoc wants to call it.
} else if let Some(parent) = self.cx.tcx.parent(item.def_id) {
let parent_kind = self.cx.tcx.def_kind(parent);
Some(if parent_kind == DefKind::Impl { parent } else { item.def_id })
} else {
Some(item.def_id)
};
// FIXME(jynelson): this shouldn't go through stringification, rustdoc should just use the DefId directly
let self_name = self_id.and_then(|self_id| {
if matches!(self.cx.tcx.def_kind(self_id), DefKind::Impl) {
// using `ty.to_string()` (or any variant) has issues with raw idents
let ty = self.cx.tcx.type_of(self_id);
let name = match ty.kind() {
ty::Adt(def, _) => Some(self.cx.tcx.item_name(def.did).to_string()),
other if other.is_primitive() => Some(ty.to_string()),
_ => None,
};
debug!("using type_of(): {:?}", name);
name
} else {
let name = self.cx.tcx.opt_item_name(self_id).map(|sym| sym.to_string());
debug!("using item_name(): {:?}", name);
name
}
});
if item.is_mod() && item.attrs.inner_docs {
self.mod_ids.push(item.def_id);
}
// We want to resolve in the lexical scope of the documentation.
// In the presence of re-exports, this is not the same as the module of the item.
// Rather than merging all documentation into one, resolve it one attribute at a time
// so we know which module it came from.
for (parent_module, doc) in item.attrs.collapsed_doc_value_by_module_level() {
debug!("combined_docs={}", doc);
let (krate, parent_node) = if let Some(id) = parent_module {
(id.krate, Some(id))
} else {
(item.def_id.krate, parent_node)
};
// NOTE: if there are links that start in one crate and end in another, this will not resolve them.
// This is a degenerate case and it's not supported by rustdoc.
for md_link in markdown_links(&doc) {
let link = self.resolve_link(&item, &doc, &self_name, parent_node, krate, md_link);
if let Some(link) = link {
item.attrs.links.push(link);
}
}
}
Some(if item.is_mod() {
if !item.attrs.inner_docs {
self.mod_ids.push(item.def_id);
}
let ret = self.fold_item_recur(item);
self.mod_ids.pop();
ret
} else {
self.fold_item_recur(item)
})
}
}
impl LinkCollector<'_, '_> {
/// This is the entry point for resolving an intra-doc link.
///
/// FIXME(jynelson): this is way too many arguments
fn resolve_link(
&mut self,
item: &Item,
dox: &str,
self_name: &Option<String>,
parent_node: Option<DefId>,
krate: CrateNum,
ori_link: MarkdownLink,
) -> Option<ItemLink> {
trace!("considering link '{}'", ori_link.link);
// Bail early for real links.
if ori_link.link.contains('/') {
return None;
}
// [] is mostly likely not supposed to be a link
if ori_link.link.is_empty() {
return None;
}
let link = ori_link.link.replace("`", "");
let parts = link.split('#').collect::<Vec<_>>();
let (link, extra_fragment) = if parts.len() > 2 {
// A valid link can't have multiple #'s
anchor_failure(
self.cx,
&item,
&link,
dox,
ori_link.range,
AnchorFailure::MultipleAnchors,
);
return None;
} else if parts.len() == 2 {
if parts[0].trim().is_empty() {
// This is an anchor to an element of the current page, nothing to do in here!
return None;
}
(parts[0], Some(parts[1].to_owned()))
} else {
(parts[0], None)
};
// Parse and strip the disambiguator from the link, if present.
let (mut path_str, disambiguator) = if let Ok((d, path)) = Disambiguator::from_str(&link) {
(path.trim(), Some(d))
} else {
(link.trim(), None)
};
if path_str.contains(|ch: char| !(ch.is_alphanumeric() || ":_<>, !*&;".contains(ch))) {
return None;
}
// We stripped `()` and `!` when parsing the disambiguator.
// Add them back to be displayed, but not prefix disambiguators.
let link_text =
disambiguator.map(|d| d.display_for(path_str)).unwrap_or_else(|| path_str.to_owned());
// In order to correctly resolve intra-doc links we need to
// pick a base AST node to work from. If the documentation for
// this module came from an inner comment (//!) then we anchor
// our name resolution *inside* the module. If, on the other
// hand it was an outer comment (///) then we anchor the name
// resolution in the parent module on the basis that the names
// used are more likely to be intended to be parent names. For
// this, we set base_node to None for inner comments since
// we've already pushed this node onto the resolution stack but
// for outer comments we explicitly try and resolve against the
// parent_node first.
let base_node = if item.is_mod() && item.attrs.inner_docs {
self.mod_ids.last().copied()
} else {
parent_node
};