2 use rustc_data_structures::stable_set::FxHashSet;
3 use rustc_errors::{Applicability, DiagnosticBuilder};
4 use rustc_expand::base::SyntaxExtensionKind;
5 use rustc_feature::UnstableFeatures;
12 use rustc_hir::def_id::DefId;
14 use rustc_resolve::ParentScope;
15 use rustc_session::lint;
16 use rustc_span::hygiene::MacroKind;
17 use rustc_span::symbol::Ident;
18 use rustc_span::symbol::Symbol;
19 use rustc_span::DUMMY_SP;
20 use smallvec::SmallVec;
26 use crate::core::DocContext;
27 use crate::fold::DocFolder;
28 use crate::html::markdown::markdown_links;
29 use crate::passes::Pass;
31 use super::span_of_attrs;
33 pub const COLLECT_INTRA_DOC_LINKS: Pass = Pass {
34 name: "collect-intra-doc-links",
35 run: collect_intra_doc_links,
36 description: "reads a crate's documentation to resolve intra-doc-links",
39 pub fn collect_intra_doc_links(krate: Crate, cx: &DocContext<'_>) -> Crate {
40 if !UnstableFeatures::from_environment().is_nightly_build() {
43 let mut coll = LinkCollector::new(cx);
45 coll.fold_crate(krate)
51 AnchorFailure(AnchorFailure),
64 struct LinkCollector<'a, 'tcx> {
65 cx: &'a DocContext<'tcx>,
66 // NOTE: this may not necessarily be a module in the current crate
68 /// This is used to store the kind of associated items,
69 /// because `clean` and the disambiguator code expect them to be different.
70 /// See the code for associated items on inherent impls for details.
71 kind_side_channel: Cell<Option<DefKind>>,
74 impl<'a, 'tcx> LinkCollector<'a, 'tcx> {
75 fn new(cx: &'a DocContext<'tcx>) -> Self {
76 LinkCollector { cx, mod_ids: Vec::new(), kind_side_channel: Cell::new(None) }
82 current_item: &Option<String>,
84 ) -> Result<(Res, Option<String>), ErrorKind> {
87 let mut split = path_str.rsplitn(3, "::");
88 let variant_field_name =
89 split.next().map(|f| Symbol::intern(f)).ok_or(ErrorKind::ResolutionFailure)?;
91 split.next().map(|f| Symbol::intern(f)).ok_or(ErrorKind::ResolutionFailure)?;
95 if f == "self" || f == "Self" {
96 if let Some(name) = current_item.as_ref() {
102 .ok_or(ErrorKind::ResolutionFailure)?;
104 .enter_resolver(|resolver| {
105 resolver.resolve_str_path_error(DUMMY_SP, &path, TypeNS, module_id)
107 .map_err(|_| ErrorKind::ResolutionFailure)?;
108 if let Res::Err = ty_res {
109 return Err(ErrorKind::ResolutionFailure);
111 let ty_res = ty_res.map_id(|_| panic!("unexpected node_id"));
113 Res::Def(DefKind::Enum, did) => {
118 .flat_map(|imp| cx.tcx.associated_items(*imp).in_definition_order())
119 .any(|item| item.ident.name == variant_name)
121 return Err(ErrorKind::ResolutionFailure);
123 match cx.tcx.type_of(did).kind {
124 ty::Adt(def, _) if def.is_enum() => {
125 if def.all_fields().any(|item| item.ident.name == variant_field_name) {
129 "variant.{}.field.{}",
130 variant_name, variant_field_name
134 Err(ErrorKind::ResolutionFailure)
137 _ => Err(ErrorKind::ResolutionFailure),
140 _ => Err(ErrorKind::ResolutionFailure),
144 /// Resolves a string as a macro.
145 fn macro_resolve(&self, path_str: &str, parent_id: Option<DefId>) -> Option<Res> {
147 let path = ast::Path::from_ident(Ident::from_str(path_str));
148 cx.enter_resolver(|resolver| {
149 if let Ok((Some(ext), res)) = resolver.resolve_macro_path(
152 &ParentScope::module(resolver.graph_root()),
156 if let SyntaxExtensionKind::LegacyBang { .. } = ext.kind {
157 return Some(res.map_id(|_| panic!("unexpected id")));
160 if let Some(res) = resolver.all_macros().get(&Symbol::intern(path_str)) {
161 return Some(res.map_id(|_| panic!("unexpected id")));
163 if let Some(module_id) = parent_id {
164 if let Ok((_, res)) =
165 resolver.resolve_str_path_error(DUMMY_SP, path_str, MacroNS, module_id)
167 // don't resolve builtins like `#[derive]`
168 if let Res::Def(..) = res {
169 let res = res.map_id(|_| panic!("unexpected node_id"));
174 debug!("attempting to resolve item without parent module: {}", path_str);
179 /// Resolves a string as a path within a particular namespace. Also returns an optional
180 /// URL fragment in the case of variants and methods.
185 current_item: &Option<String>,
186 parent_id: Option<DefId>,
187 extra_fragment: &Option<String>,
188 ) -> Result<(Res, Option<String>), ErrorKind> {
191 // In case we're in a module, try to resolve the relative path.
192 if let Some(module_id) = parent_id {
193 let result = cx.enter_resolver(|resolver| {
194 resolver.resolve_str_path_error(DUMMY_SP, &path_str, ns, module_id)
196 debug!("{} resolved to {:?} in namespace {:?}", path_str, result, ns);
197 let result = match result {
198 Ok((_, Res::Err)) => Err(ErrorKind::ResolutionFailure),
199 _ => result.map_err(|_| ErrorKind::ResolutionFailure),
202 if let Ok((_, res)) = result {
203 let res = res.map_id(|_| panic!("unexpected node_id"));
204 // In case this is a trait item, skip the
205 // early return and try looking for the trait.
206 let value = match res {
207 Res::Def(DefKind::AssocFn | DefKind::AssocConst, _) => true,
208 Res::Def(DefKind::AssocTy, _) => false,
209 Res::Def(DefKind::Variant, _) => {
210 return handle_variant(cx, res, extra_fragment);
212 // Not a trait item; just return what we found.
214 if extra_fragment.is_some() {
215 return Err(ErrorKind::AnchorFailure(AnchorFailure::Primitive));
217 return Ok((res, Some(path_str.to_owned())));
219 Res::Def(DefKind::Mod, _) => {
220 return Ok((res, extra_fragment.clone()));
223 return Ok((res, extra_fragment.clone()));
227 if value != (ns == ValueNS) {
228 return Err(ErrorKind::ResolutionFailure);
230 } else if let Some((path, prim)) = is_primitive(path_str, ns) {
231 if extra_fragment.is_some() {
232 return Err(ErrorKind::AnchorFailure(AnchorFailure::Primitive));
234 return Ok((prim, Some(path.to_owned())));
237 // Try looking for methods and associated items.
238 let mut split = path_str.rsplitn(2, "::");
240 split.next().map(|f| Symbol::intern(f)).ok_or(ErrorKind::ResolutionFailure)?;
244 if f == "self" || f == "Self" {
245 if let Some(name) = current_item.as_ref() {
251 .ok_or(ErrorKind::ResolutionFailure)?;
253 if let Some((path, prim)) = is_primitive(&path, TypeNS) {
254 for &impl_ in primitive_impl(cx, &path).ok_or(ErrorKind::ResolutionFailure)? {
257 .associated_items(impl_)
258 .find_by_name_and_namespace(
260 Ident::with_dummy_span(item_name),
264 .and_then(|item| match item.kind {
265 ty::AssocKind::Fn => Some("method"),
268 .map(|out| (prim, Some(format!("{}#{}.{}", path, out, item_name))));
269 if let Some(link) = link {
273 return Err(ErrorKind::ResolutionFailure);
277 .enter_resolver(|resolver| {
278 resolver.resolve_str_path_error(DUMMY_SP, &path, TypeNS, module_id)
280 .map_err(|_| ErrorKind::ResolutionFailure)?;
281 if let Res::Err = ty_res {
282 return if ns == Namespace::ValueNS {
283 self.variant_field(path_str, current_item, module_id)
285 Err(ErrorKind::ResolutionFailure)
288 let ty_res = ty_res.map_id(|_| panic!("unexpected node_id"));
289 let res = match ty_res {
291 DefKind::Struct | DefKind::Union | DefKind::Enum | DefKind::TyAlias,
294 debug!("looking for associated item named {} for item {:?}", item_name, did);
295 // Checks if item_name belongs to `impl SomeItem`
301 cx.tcx.associated_items(imp).find_by_name_and_namespace(
303 Ident::with_dummy_span(item_name),
308 .map(|item| item.kind)
309 // There should only ever be one associated item that matches from any inherent impl
311 // Check if item_name belongs to `impl SomeTrait for SomeItem`
312 // This gives precedence to `impl SomeItem`:
313 // Although having both would be ambiguous, use impl version for compat. sake.
314 // To handle that properly resolve() would have to support
315 // something like [`ambi_fn`](<SomeStruct as SomeTrait>::ambi_fn)
317 let kind = resolve_associated_trait_item(
318 did, module_id, item_name, ns, &self.cx,
320 debug!("got associated item kind {:?}", kind);
324 if let Some(kind) = kind {
325 let out = match kind {
326 ty::AssocKind::Fn => "method",
327 ty::AssocKind::Const => "associatedconstant",
328 ty::AssocKind::Type => "associatedtype",
330 Some(if extra_fragment.is_some() {
331 Err(ErrorKind::AnchorFailure(if kind == ty::AssocKind::Fn {
332 AnchorFailure::Method
334 AnchorFailure::AssocConstant
337 // HACK(jynelson): `clean` expects the type, not the associated item.
338 // but the disambiguator logic expects the associated item.
339 // Store the kind in a side channel so that only the disambiguator logic looks at it.
340 self.kind_side_channel.set(Some(kind.as_def_kind()));
341 Ok((ty_res, Some(format!("{}.{}", out, item_name))))
343 } else if ns == Namespace::ValueNS {
344 match cx.tcx.type_of(did).kind {
346 let field = if def.is_enum() {
347 def.all_fields().find(|item| item.ident.name == item_name)
349 def.non_enum_variant()
352 .find(|item| item.ident.name == item_name)
355 if extra_fragment.is_some() {
356 Err(ErrorKind::AnchorFailure(if def.is_enum() {
357 AnchorFailure::Variant
380 // We already know this isn't in ValueNS, so no need to check variant_field
381 return Err(ErrorKind::ResolutionFailure);
384 Res::Def(DefKind::Trait, did) => cx
386 .associated_items(did)
387 .find_by_name_and_namespace(cx.tcx, Ident::with_dummy_span(item_name), ns, did)
389 let kind = match item.kind {
390 ty::AssocKind::Const => "associatedconstant",
391 ty::AssocKind::Type => "associatedtype",
392 ty::AssocKind::Fn => {
393 if item.defaultness.has_value() {
401 if extra_fragment.is_some() {
402 Err(ErrorKind::AnchorFailure(if item.kind == ty::AssocKind::Const {
403 AnchorFailure::AssocConstant
404 } else if item.kind == ty::AssocKind::Type {
405 AnchorFailure::AssocType
407 AnchorFailure::Method
410 let res = Res::Def(item.kind.as_def_kind(), item.def_id);
411 Ok((res, Some(format!("{}.{}", kind, item_name))))
416 res.unwrap_or_else(|| {
417 if ns == Namespace::ValueNS {
418 self.variant_field(path_str, current_item, module_id)
420 Err(ErrorKind::ResolutionFailure)
424 debug!("attempting to resolve item without parent module: {}", path_str);
425 Err(ErrorKind::ResolutionFailure)
430 fn resolve_associated_trait_item(
436 ) -> Option<ty::AssocKind> {
437 let ty = cx.tcx.type_of(did);
438 // First consider automatic impls: `impl From<T> for T`
439 let implicit_impls = crate::clean::get_auto_trait_and_blanket_impls(cx, ty, did);
440 let mut candidates: Vec<_> = implicit_impls
441 .flat_map(|impl_outer| {
442 match impl_outer.inner {
444 debug!("considering auto or blanket impl for trait {:?}", impl_.trait_);
445 // Give precedence to methods that were overridden
446 if !impl_.provided_trait_methods.contains(&*item_name.as_str()) {
447 let mut items = impl_.items.into_iter().filter_map(|assoc| {
448 if assoc.name.as_deref() != Some(&*item_name.as_str()) {
454 .expect("inner items for a trait should be associated items");
455 if kind.namespace() != ns {
459 trace!("considering associated item {:?}", assoc.inner);
460 // We have a slight issue: normal methods come from `clean` types,
461 // but provided methods come directly from `tcx`.
462 // Fortunately, we don't need the whole method, we just need to know
463 // what kind of associated item it is.
464 Some((assoc.def_id, kind))
466 let assoc = items.next();
467 debug_assert_eq!(items.count(), 0);
470 // These are provided methods or default types:
474 // fn has_default() -> A { 0 }
477 let trait_ = impl_.trait_.unwrap().def_id().unwrap();
479 .associated_items(trait_)
480 .find_by_name_and_namespace(
482 Ident::with_dummy_span(item_name),
486 .map(|assoc| (assoc.def_id, assoc.kind))
489 _ => panic!("get_impls returned something that wasn't an impl"),
494 // Next consider explicit impls: `impl MyTrait for MyType`
495 // Give precedence to inherent impls.
496 if candidates.is_empty() {
497 let traits = traits_implemented_by(cx, did, module);
498 debug!("considering traits {:?}", traits);
499 candidates.extend(traits.iter().filter_map(|&trait_| {
501 .associated_items(trait_)
502 .find_by_name_and_namespace(cx.tcx, Ident::with_dummy_span(item_name), ns, trait_)
503 .map(|assoc| (assoc.def_id, assoc.kind))
506 // FIXME: warn about ambiguity
507 debug!("the candidates were {:?}", candidates);
508 candidates.pop().map(|(_, kind)| kind)
511 /// Given a type, return all traits in scope in `module` implemented by that type.
513 /// NOTE: this cannot be a query because more traits could be available when more crates are compiled!
514 /// So it is not stable to serialize cross-crate.
515 fn traits_implemented_by(cx: &DocContext<'_>, type_: DefId, module: DefId) -> FxHashSet<DefId> {
516 let mut cache = cx.module_trait_cache.borrow_mut();
517 let in_scope_traits = cache.entry(module).or_insert_with(|| {
518 cx.enter_resolver(|resolver| {
519 resolver.traits_in_scope(module).into_iter().map(|candidate| candidate.def_id).collect()
523 let ty = cx.tcx.type_of(type_);
524 let iter = in_scope_traits.iter().flat_map(|&trait_| {
525 trace!("considering explicit impl for trait {:?}", trait_);
526 let mut saw_impl = false;
527 // Look at each trait implementation to see if it's an impl for `did`
528 cx.tcx.for_each_relevant_impl(trait_, ty, |impl_| {
529 // FIXME: this is inefficient, find a way to short-circuit for_each_* so this doesn't take as long
534 let trait_ref = cx.tcx.impl_trait_ref(impl_).expect("this is not an inherent impl");
535 // Check if these are the same type.
536 let impl_type = trait_ref.self_ty();
538 "comparing type {} with kind {:?} against type {:?}",
539 impl_type, impl_type.kind, type_
541 // Fast path: if this is a primitive simple `==` will work
542 saw_impl = impl_type == ty
543 || match impl_type.kind {
544 // Check if these are the same def_id
546 debug!("adt def_id: {:?}", def.did);
549 ty::Foreign(def_id) => def_id == type_,
553 if saw_impl { Some(trait_) } else { None }
558 /// Check for resolve collisions between a trait and its derive
560 /// These are common and we should just resolve to the trait in that case
561 fn is_derive_trait_collision<T>(ns: &PerNS<Option<(Res, T)>>) -> bool {
563 type_ns: Some((Res::Def(DefKind::Trait, _), _)),
564 macro_ns: Some((Res::Def(DefKind::Macro(MacroKind::Derive), _), _)),
574 impl<'a, 'tcx> DocFolder for LinkCollector<'a, 'tcx> {
575 fn fold_item(&mut self, mut item: Item) -> Option<Item> {
576 use rustc_middle::ty::DefIdTree;
578 let parent_node = if item.is_fake() {
579 // FIXME: is this correct?
582 let mut current = item.def_id;
583 // The immediate parent might not always be a module.
584 // Find the first parent which is.
586 if let Some(parent) = self.cx.tcx.parent(current) {
587 if self.cx.tcx.def_kind(parent) == DefKind::Mod {
597 if parent_node.is_some() {
598 trace!("got parent node for {:?} {:?}, id {:?}", item.type_(), item.name, item.def_id);
601 let current_item = match item.inner {
603 if item.attrs.inner_docs {
604 if item.def_id.is_top_level_module() { item.name.clone() } else { None }
606 match parent_node.or(self.mod_ids.last().copied()) {
607 Some(parent) if !parent.is_top_level_module() => {
608 // FIXME: can we pull the parent module's name from elsewhere?
609 Some(self.cx.tcx.item_name(parent).to_string())
615 ImplItem(Impl { ref for_, .. }) => {
616 for_.def_id().map(|did| self.cx.tcx.item_name(did).to_string())
618 // we don't display docs on `extern crate` items anyway, so don't process them.
619 ExternCrateItem(..) => {
620 debug!("ignoring extern crate item {:?}", item.def_id);
621 return self.fold_item_recur(item);
623 ImportItem(Import::Simple(ref name, ..)) => Some(name.clone()),
624 MacroItem(..) => None,
625 _ => item.name.clone(),
628 if item.is_mod() && item.attrs.inner_docs {
629 self.mod_ids.push(item.def_id);
633 let dox = item.attrs.collapsed_doc_value().unwrap_or_else(String::new);
634 trace!("got documentation '{}'", dox);
636 // find item's parent to resolve `Self` in item's docs below
637 let parent_name = self.cx.as_local_hir_id(item.def_id).and_then(|item_hir| {
638 let parent_hir = self.cx.tcx.hir().get_parent_item(item_hir);
639 let item_parent = self.cx.tcx.hir().find(parent_hir);
641 Some(hir::Node::Item(hir::Item {
643 hir::ItemKind::Impl {
647 hir::TyKind::Path(hir::QPath::Resolved(
649 hir::Path { segments, .. },
656 })) => segments.first().map(|seg| seg.ident.to_string()),
657 Some(hir::Node::Item(hir::Item {
658 ident, kind: hir::ItemKind::Enum(..), ..
660 | Some(hir::Node::Item(hir::Item {
661 ident, kind: hir::ItemKind::Struct(..), ..
663 | Some(hir::Node::Item(hir::Item {
664 ident, kind: hir::ItemKind::Union(..), ..
666 | Some(hir::Node::Item(hir::Item {
667 ident, kind: hir::ItemKind::Trait(..), ..
668 })) => Some(ident.to_string()),
673 for (ori_link, link_range) in markdown_links(&dox) {
674 trace!("considering link '{}'", ori_link);
676 // Bail early for real links.
677 if ori_link.contains('/') {
681 // [] is mostly likely not supposed to be a link
682 if ori_link.is_empty() {
686 let link = ori_link.replace("`", "");
687 let parts = link.split('#').collect::<Vec<_>>();
688 let (link, extra_fragment) = if parts.len() > 2 {
689 anchor_failure(cx, &item, &link, &dox, link_range, AnchorFailure::MultipleAnchors);
691 } else if parts.len() == 2 {
692 if parts[0].trim().is_empty() {
693 // This is an anchor to an element of the current page, nothing to do in here!
696 (parts[0].to_owned(), Some(parts[1].to_owned()))
698 (parts[0].to_owned(), None)
703 let (mut res, mut fragment) = {
704 path_str = if let Ok((d, path)) = Disambiguator::from_str(&link) {
705 disambiguator = Some(d);
708 disambiguator = None;
713 if path_str.contains(|ch: char| !(ch.is_alphanumeric() || ch == ':' || ch == '_')) {
717 // In order to correctly resolve intra-doc-links we need to
718 // pick a base AST node to work from. If the documentation for
719 // this module came from an inner comment (//!) then we anchor
720 // our name resolution *inside* the module. If, on the other
721 // hand it was an outer comment (///) then we anchor the name
722 // resolution in the parent module on the basis that the names
723 // used are more likely to be intended to be parent names. For
724 // this, we set base_node to None for inner comments since
725 // we've already pushed this node onto the resolution stack but
726 // for outer comments we explicitly try and resolve against the
727 // parent_node first.
728 let base_node = if item.is_mod() && item.attrs.inner_docs {
729 self.mod_ids.last().copied()
734 // replace `Self` with suitable item's parent name
735 if path_str.starts_with("Self::") {
736 if let Some(ref name) = parent_name {
737 resolved_self = format!("{}::{}", name, &path_str[6..]);
738 path_str = &resolved_self;
742 match disambiguator.map(Disambiguator::ns) {
743 Some(ns @ (ValueNS | TypeNS)) => {
744 match self.resolve(path_str, ns, ¤t_item, base_node, &extra_fragment)
747 Err(ErrorKind::ResolutionFailure) => {
748 resolution_failure(cx, &item, path_str, &dox, link_range);
749 // This could just be a normal link or a broken link
750 // we could potentially check if something is
751 // "intra-doc-link-like" and warn in that case.
754 Err(ErrorKind::AnchorFailure(msg)) => {
755 anchor_failure(cx, &item, &ori_link, &dox, link_range, msg);
762 let mut candidates = PerNS {
764 .macro_resolve(path_str, base_node)
765 .map(|res| (res, extra_fragment.clone())),
766 type_ns: match self.resolve(
774 debug!("got res in TypeNS: {:?}", res);
777 Err(ErrorKind::AnchorFailure(msg)) => {
778 anchor_failure(cx, &item, &ori_link, &dox, link_range, msg);
781 Err(ErrorKind::ResolutionFailure) => None,
783 value_ns: match self.resolve(
790 Ok(res) => Some(res),
791 Err(ErrorKind::AnchorFailure(msg)) => {
792 anchor_failure(cx, &item, &ori_link, &dox, link_range, msg);
795 Err(ErrorKind::ResolutionFailure) => None,
797 .and_then(|(res, fragment)| {
798 // Constructors are picked up in the type namespace.
800 Res::Def(DefKind::Ctor(..), _) | Res::SelfCtor(..) => None,
801 _ => match (fragment, extra_fragment) {
802 (Some(fragment), Some(_)) => {
803 // Shouldn't happen but who knows?
804 Some((res, Some(fragment)))
806 (fragment, None) | (None, fragment) => {
807 Some((res, fragment))
814 if candidates.is_empty() {
815 resolution_failure(cx, &item, path_str, &dox, link_range);
816 // this could just be a normal link
820 let len = candidates.clone().present_items().count();
823 candidates.present_items().next().unwrap()
824 } else if len == 2 && is_derive_trait_collision(&candidates) {
825 candidates.type_ns.unwrap()
827 if is_derive_trait_collision(&candidates) {
828 candidates.macro_ns = None;
831 candidates.map(|candidate| candidate.map(|(res, _)| res));
838 candidates.present_items().collect(),
844 if let Some(res) = self.macro_resolve(path_str, base_node) {
845 (res, extra_fragment)
847 resolution_failure(cx, &item, path_str, &dox, link_range);
854 // Check for a primitive which might conflict with a module
855 // Report the ambiguity and require that the user specify which one they meant.
856 // FIXME: could there ever be a primitive not in the type namespace?
859 None | Some(Disambiguator::Namespace(Namespace::TypeNS) | Disambiguator::Primitive)
860 ) && !matches!(res, Res::PrimTy(_))
862 if let Some((path, prim)) = is_primitive(path_str, TypeNS) {
864 if matches!(disambiguator, Some(Disambiguator::Primitive)) {
865 if fragment.is_some() {
872 AnchorFailure::Primitive,
877 fragment = Some(path.to_owned());
879 // `[char]` when a `char` module is in scope
880 let candidates = vec![res, prim];
881 ambiguity_error(cx, &item, path_str, &dox, link_range, candidates);
887 let report_mismatch = |specified: Disambiguator, resolved: Disambiguator| {
888 // The resolved item did not match the disambiguator; give a better error than 'not found'
889 let msg = format!("incompatible link kind for `{}`", path_str);
890 report_diagnostic(cx, &msg, &item, &dox, link_range.clone(), |diag, sp| {
892 "this link resolved to {} {}, which is not {} {}",
899 suggest_disambiguator(resolved, diag, path_str, &dox, sp, &link_range);
902 if let Res::PrimTy(_) = res {
903 match disambiguator {
904 Some(Disambiguator::Primitive | Disambiguator::Namespace(_)) | None => {
905 item.attrs.links.push((ori_link, None, fragment))
908 report_mismatch(other, Disambiguator::Primitive);
913 debug!("intra-doc link to {} resolved to {:?}", path_str, res);
915 // Disallow e.g. linking to enums with `struct@`
916 if let Res::Def(kind, _) = res {
917 debug!("saw kind {:?} with disambiguator {:?}", kind, disambiguator);
918 match (self.kind_side_channel.take().unwrap_or(kind), disambiguator) {
919 | (DefKind::Const | DefKind::ConstParam | DefKind::AssocConst | DefKind::AnonConst, Some(Disambiguator::Kind(DefKind::Const)))
920 // NOTE: this allows 'method' to mean both normal functions and associated functions
921 // This can't cause ambiguity because both are in the same namespace.
922 | (DefKind::Fn | DefKind::AssocFn, Some(Disambiguator::Kind(DefKind::Fn)))
923 // These are namespaces; allow anything in the namespace to match
924 | (_, Some(Disambiguator::Namespace(_)))
925 // If no disambiguator given, allow anything
927 // All of these are valid, so do nothing
929 (actual, Some(Disambiguator::Kind(expected))) if actual == expected => {}
930 (_, Some(specified @ Disambiguator::Kind(_) | specified @ Disambiguator::Primitive)) => {
931 report_mismatch(specified, Disambiguator::Kind(kind));
937 // item can be non-local e.g. when using #[doc(primitive = "pointer")]
938 if let Some((src_id, dst_id)) = res
940 .and_then(|def_id| def_id.as_local())
941 .and_then(|dst_id| item.def_id.as_local().map(|src_id| (src_id, dst_id)))
943 use rustc_hir::def_id::LOCAL_CRATE;
945 let hir_src = self.cx.tcx.hir().local_def_id_to_hir_id(src_id);
946 let hir_dst = self.cx.tcx.hir().local_def_id_to_hir_id(dst_id);
948 if self.cx.tcx.privacy_access_levels(LOCAL_CRATE).is_exported(hir_src)
949 && !self.cx.tcx.privacy_access_levels(LOCAL_CRATE).is_exported(hir_dst)
951 privacy_error(cx, &item, &path_str, &dox, link_range);
955 let id = register_res(cx, res);
956 item.attrs.links.push((ori_link, Some(id), fragment));
960 if item.is_mod() && !item.attrs.inner_docs {
961 self.mod_ids.push(item.def_id);
965 let ret = self.fold_item_recur(item);
971 self.fold_item_recur(item)
975 // FIXME: if we can resolve intra-doc links from other crates, we can use the stock
976 // `fold_crate`, but until then we should avoid scanning `krate.external_traits` since those
977 // will never resolve properly
978 fn fold_crate(&mut self, mut c: Crate) -> Crate {
979 c.module = c.module.take().and_then(|module| self.fold_item(module));
985 #[derive(Copy, Clone, Debug, PartialEq, Eq)]
989 Namespace(Namespace),
993 /// (disambiguator, path_str)
994 fn from_str(link: &str) -> Result<(Self, &str), ()> {
995 use Disambiguator::{Kind, Namespace as NS, Primitive};
997 let find_suffix = || {
999 ("!()", DefKind::Macro(MacroKind::Bang)),
1000 ("()", DefKind::Fn),
1001 ("!", DefKind::Macro(MacroKind::Bang)),
1003 for &(suffix, kind) in &suffixes {
1004 if link.ends_with(suffix) {
1005 return Ok((Kind(kind), link.trim_end_matches(suffix)));
1011 if let Some(idx) = link.find('@') {
1012 let (prefix, rest) = link.split_at(idx);
1013 let d = match prefix {
1014 "struct" => Kind(DefKind::Struct),
1015 "enum" => Kind(DefKind::Enum),
1016 "trait" => Kind(DefKind::Trait),
1017 "union" => Kind(DefKind::Union),
1018 "module" | "mod" => Kind(DefKind::Mod),
1019 "const" | "constant" => Kind(DefKind::Const),
1020 "static" => Kind(DefKind::Static),
1021 "function" | "fn" | "method" => Kind(DefKind::Fn),
1022 "derive" => Kind(DefKind::Macro(MacroKind::Derive)),
1023 "type" => NS(Namespace::TypeNS),
1024 "value" => NS(Namespace::ValueNS),
1025 "macro" => NS(Namespace::MacroNS),
1026 "prim" | "primitive" => Primitive,
1027 _ => return find_suffix(),
1035 /// WARNING: panics on `Res::Err`
1036 fn from_res(res: Res) -> Self {
1038 Res::Def(kind, _) => Disambiguator::Kind(kind),
1039 Res::PrimTy(_) => Disambiguator::Primitive,
1040 _ => Disambiguator::Namespace(res.ns().expect("can't call `from_res` on Res::err")),
1044 /// Return (description of the change, suggestion)
1045 fn display_for(self, path_str: &str) -> (&'static str, String) {
1046 const PREFIX: &str = "prefix with the item kind";
1047 const FUNCTION: &str = "add parentheses";
1048 const MACRO: &str = "add an exclamation mark";
1050 let kind = match self {
1051 Disambiguator::Primitive => return (PREFIX, format!("prim@{}", path_str)),
1052 Disambiguator::Kind(kind) => kind,
1053 Disambiguator::Namespace(_) => panic!("display_for cannot be used on namespaces"),
1055 if kind == DefKind::Macro(MacroKind::Bang) {
1056 return (MACRO, format!("{}!", path_str));
1057 } else if kind == DefKind::Fn || kind == DefKind::AssocFn {
1058 return (FUNCTION, format!("{}()", path_str));
1061 let prefix = match kind {
1062 DefKind::Struct => "struct",
1063 DefKind::Enum => "enum",
1064 DefKind::Trait => "trait",
1065 DefKind::Union => "union",
1066 DefKind::Mod => "mod",
1067 DefKind::Const | DefKind::ConstParam | DefKind::AssocConst | DefKind::AnonConst => {
1070 DefKind::Static => "static",
1071 DefKind::Macro(MacroKind::Derive) => "derive",
1072 // Now handle things that don't have a specific disambiguator
1075 .expect("tried to calculate a disambiguator for a def without a namespace?")
1077 Namespace::TypeNS => "type",
1078 Namespace::ValueNS => "value",
1079 Namespace::MacroNS => "macro",
1083 // FIXME: if this is an implied shortcut link, it's bad style to suggest `@`
1084 (PREFIX, format!("{}@{}", prefix, path_str))
1087 fn ns(self) -> Namespace {
1089 Self::Namespace(n) => n,
1091 k.ns().expect("only DefKinds with a valid namespace can be disambiguators")
1093 Self::Primitive => TypeNS,
1097 fn article(self) -> &'static str {
1099 Self::Namespace(_) => panic!("article() doesn't make sense for namespaces"),
1100 Self::Kind(k) => k.article(),
1101 Self::Primitive => "a",
1105 fn descr(self) -> &'static str {
1107 Self::Namespace(n) => n.descr(),
1108 // HACK(jynelson): by looking at the source I saw the DefId we pass
1109 // for `expected.descr()` doesn't matter, since it's not a crate
1110 Self::Kind(k) => k.descr(DefId::local(hir::def_id::DefIndex::from_usize(0))),
1111 Self::Primitive => "builtin type",
1116 /// Reports a diagnostic for an intra-doc link.
1118 /// If no link range is provided, or the source span of the link cannot be determined, the span of
1119 /// the entire documentation block is used for the lint. If a range is provided but the span
1120 /// calculation fails, a note is added to the diagnostic pointing to the link in the markdown.
1122 /// The `decorate` callback is invoked in all cases to allow further customization of the
1123 /// diagnostic before emission. If the span of the link was able to be determined, the second
1124 /// parameter of the callback will contain it, and the primary span of the diagnostic will be set
1126 fn report_diagnostic(
1127 cx: &DocContext<'_>,
1131 link_range: Option<Range<usize>>,
1132 decorate: impl FnOnce(&mut DiagnosticBuilder<'_>, Option<rustc_span::Span>),
1134 let hir_id = match cx.as_local_hir_id(item.def_id) {
1135 Some(hir_id) => hir_id,
1137 // If non-local, no need to check anything.
1138 info!("ignoring warning from parent crate: {}", msg);
1143 let attrs = &item.attrs;
1144 let sp = span_of_attrs(attrs).unwrap_or(item.source.span());
1146 cx.tcx.struct_span_lint_hir(lint::builtin::BROKEN_INTRA_DOC_LINKS, hir_id, sp, |lint| {
1147 let mut diag = lint.build(msg);
1149 let span = link_range
1151 .and_then(|range| super::source_span_for_markdown_range(cx, dox, range, attrs));
1153 if let Some(link_range) = link_range {
1154 if let Some(sp) = span {
1157 // blah blah blah\nblah\nblah [blah] blah blah\nblah blah
1160 // last_new_line_offset
1161 let last_new_line_offset = dox[..link_range.start].rfind('\n').map_or(0, |n| n + 1);
1162 let line = dox[last_new_line_offset..].lines().next().unwrap_or("");
1164 // Print the line containing the `link_range` and manually mark it with '^'s.
1166 "the link appears in this line:\n\n{line}\n\
1167 {indicator: <before$}{indicator:^<found$}",
1170 before = link_range.start - last_new_line_offset,
1171 found = link_range.len(),
1176 decorate(&mut diag, span);
1182 fn resolution_failure(
1183 cx: &DocContext<'_>,
1187 link_range: Option<Range<usize>>,
1191 &format!("unresolved link to `{}`", path_str),
1196 if let Some(sp) = sp {
1197 diag.span_label(sp, "unresolved link");
1200 diag.help(r#"to escape `[` and `]` characters, add '\' before them like `\[` or `\]`"#);
1206 cx: &DocContext<'_>,
1210 link_range: Option<Range<usize>>,
1211 failure: AnchorFailure,
1213 let msg = match failure {
1214 AnchorFailure::MultipleAnchors => format!("`{}` contains multiple anchors", path_str),
1215 AnchorFailure::Primitive
1216 | AnchorFailure::Variant
1217 | AnchorFailure::AssocConstant
1218 | AnchorFailure::AssocType
1219 | AnchorFailure::Field
1220 | AnchorFailure::Method => {
1221 let kind = match failure {
1222 AnchorFailure::Primitive => "primitive type",
1223 AnchorFailure::Variant => "enum variant",
1224 AnchorFailure::AssocConstant => "associated constant",
1225 AnchorFailure::AssocType => "associated type",
1226 AnchorFailure::Field => "struct field",
1227 AnchorFailure::Method => "method",
1228 AnchorFailure::MultipleAnchors => unreachable!("should be handled already"),
1232 "`{}` contains an anchor, but links to {kind}s are already anchored",
1239 report_diagnostic(cx, &msg, item, dox, link_range, |diag, sp| {
1240 if let Some(sp) = sp {
1241 diag.span_label(sp, "contains invalid anchor");
1247 cx: &DocContext<'_>,
1251 link_range: Option<Range<usize>>,
1252 candidates: Vec<Res>,
1254 let mut msg = format!("`{}` is ", path_str);
1256 match candidates.as_slice() {
1257 [first_def, second_def] => {
1259 "both {} {} and {} {}",
1260 first_def.article(),
1262 second_def.article(),
1267 let mut candidates = candidates.iter().peekable();
1268 while let Some(res) = candidates.next() {
1269 if candidates.peek().is_some() {
1270 msg += &format!("{} {}, ", res.article(), res.descr());
1272 msg += &format!("and {} {}", res.article(), res.descr());
1278 report_diagnostic(cx, &msg, item, dox, link_range.clone(), |diag, sp| {
1279 if let Some(sp) = sp {
1280 diag.span_label(sp, "ambiguous link");
1282 diag.note("ambiguous link");
1285 for res in candidates {
1286 let disambiguator = Disambiguator::from_res(res);
1287 suggest_disambiguator(disambiguator, diag, path_str, dox, sp, &link_range);
1292 fn suggest_disambiguator(
1293 disambiguator: Disambiguator,
1294 diag: &mut DiagnosticBuilder<'_>,
1297 sp: Option<rustc_span::Span>,
1298 link_range: &Option<Range<usize>>,
1300 let (action, mut suggestion) = disambiguator.display_for(path_str);
1301 let help = format!("to link to the {}, {}", disambiguator.descr(), action);
1303 if let Some(sp) = sp {
1304 let link_range = link_range.as_ref().expect("must have a link range if we have a span");
1305 if dox.bytes().nth(link_range.start) == Some(b'`') {
1306 suggestion = format!("`{}`", suggestion);
1309 diag.span_suggestion(sp, &help, suggestion, Applicability::MaybeIncorrect);
1311 diag.help(&format!("{}: {}", help, suggestion));
1316 cx: &DocContext<'_>,
1320 link_range: Option<Range<usize>>,
1322 let item_name = item.name.as_deref().unwrap_or("<unknown>");
1324 format!("public documentation for `{}` links to private item `{}`", item_name, path_str);
1326 report_diagnostic(cx, &msg, item, dox, link_range, |diag, sp| {
1327 if let Some(sp) = sp {
1328 diag.span_label(sp, "this item is private");
1331 let note_msg = if cx.render_options.document_private {
1332 "this link resolves only because you passed `--document-private-items`, but will break without"
1334 "this link will resolve properly if you pass `--document-private-items`"
1336 diag.note(note_msg);
1340 /// Given an enum variant's res, return the res of its enum and the associated fragment.
1342 cx: &DocContext<'_>,
1344 extra_fragment: &Option<String>,
1345 ) -> Result<(Res, Option<String>), ErrorKind> {
1346 use rustc_middle::ty::DefIdTree;
1348 if extra_fragment.is_some() {
1349 return Err(ErrorKind::AnchorFailure(AnchorFailure::Variant));
1351 let parent = if let Some(parent) = cx.tcx.parent(res.def_id()) {
1354 return Err(ErrorKind::ResolutionFailure);
1356 let parent_def = Res::Def(DefKind::Enum, parent);
1357 let variant = cx.tcx.expect_variant_res(res);
1358 Ok((parent_def, Some(format!("variant.{}", variant.ident.name))))
1361 const PRIMITIVES: &[(&str, Res)] = &[
1362 ("u8", Res::PrimTy(hir::PrimTy::Uint(rustc_ast::UintTy::U8))),
1363 ("u16", Res::PrimTy(hir::PrimTy::Uint(rustc_ast::UintTy::U16))),
1364 ("u32", Res::PrimTy(hir::PrimTy::Uint(rustc_ast::UintTy::U32))),
1365 ("u64", Res::PrimTy(hir::PrimTy::Uint(rustc_ast::UintTy::U64))),
1366 ("u128", Res::PrimTy(hir::PrimTy::Uint(rustc_ast::UintTy::U128))),
1367 ("usize", Res::PrimTy(hir::PrimTy::Uint(rustc_ast::UintTy::Usize))),
1368 ("i8", Res::PrimTy(hir::PrimTy::Int(rustc_ast::IntTy::I8))),
1369 ("i16", Res::PrimTy(hir::PrimTy::Int(rustc_ast::IntTy::I16))),
1370 ("i32", Res::PrimTy(hir::PrimTy::Int(rustc_ast::IntTy::I32))),
1371 ("i64", Res::PrimTy(hir::PrimTy::Int(rustc_ast::IntTy::I64))),
1372 ("i128", Res::PrimTy(hir::PrimTy::Int(rustc_ast::IntTy::I128))),
1373 ("isize", Res::PrimTy(hir::PrimTy::Int(rustc_ast::IntTy::Isize))),
1374 ("f32", Res::PrimTy(hir::PrimTy::Float(rustc_ast::FloatTy::F32))),
1375 ("f64", Res::PrimTy(hir::PrimTy::Float(rustc_ast::FloatTy::F64))),
1376 ("str", Res::PrimTy(hir::PrimTy::Str)),
1377 ("bool", Res::PrimTy(hir::PrimTy::Bool)),
1378 ("true", Res::PrimTy(hir::PrimTy::Bool)),
1379 ("false", Res::PrimTy(hir::PrimTy::Bool)),
1380 ("char", Res::PrimTy(hir::PrimTy::Char)),
1383 fn is_primitive(path_str: &str, ns: Namespace) -> Option<(&'static str, Res)> {
1387 .filter(|x| x.0 == path_str)
1389 .map(|x| if x.0 == "true" || x.0 == "false" { ("bool", x.1) } else { x })
1396 fn primitive_impl(cx: &DocContext<'_>, path_str: &str) -> Option<&'static SmallVec<[DefId; 4]>> {
1397 Some(PrimitiveType::from_symbol(Symbol::intern(path_str))?.impls(cx.tcx))