//! Collects trait impls for each item in the crate. For example, if a crate //! defines a struct that implements a trait, this pass will note that the //! struct implements that trait. use super::Pass; use crate::clean::*; use crate::core::DocContext; use crate::formats::cache::Cache; use crate::visit::DocVisitor; use rustc_data_structures::fx::{FxHashMap, FxHashSet}; use rustc_hir::def_id::{DefId, LOCAL_CRATE}; use rustc_middle::ty::{self, DefIdTree}; use rustc_span::symbol::sym; pub(crate) const COLLECT_TRAIT_IMPLS: Pass = Pass { name: "collect-trait-impls", run: collect_trait_impls, description: "retrieves trait impls for items in the crate", }; pub(crate) fn collect_trait_impls(mut krate: Crate, cx: &mut DocContext<'_>) -> Crate { // We need to check if there are errors before running this pass because it would crash when // we try to get auto and blanket implementations. if cx.tcx.sess.diagnostic().has_errors_or_lint_errors().is_some() { return krate; } let synth_impls = cx.sess().time("collect_synthetic_impls", || { let mut synth = SyntheticImplCollector { cx, impls: Vec::new() }; synth.visit_crate(&krate); synth.impls }); let local_crate = ExternalCrate { crate_num: LOCAL_CRATE }; let prims: FxHashSet = local_crate.primitives(cx.tcx).iter().map(|p| p.1).collect(); let crate_items = { let mut coll = ItemCollector::new(); cx.sess().time("collect_items_for_trait_impls", || coll.visit_crate(&krate)); coll.items }; let mut new_items_external = Vec::new(); let mut new_items_local = Vec::new(); // External trait impls. cx.with_all_trait_impls(|cx, all_trait_impls| { let _prof_timer = cx.tcx.sess.prof.generic_activity("build_extern_trait_impls"); for &impl_def_id in all_trait_impls.iter().skip_while(|def_id| def_id.is_local()) { inline::build_impl(cx, None, impl_def_id, None, &mut new_items_external); } }); // Local trait impls. cx.with_all_trait_impls(|cx, all_trait_impls| { let _prof_timer = cx.tcx.sess.prof.generic_activity("build_local_trait_impls"); let mut attr_buf = Vec::new(); for &impl_def_id in all_trait_impls.iter().take_while(|def_id| def_id.is_local()) { let mut parent = Some(cx.tcx.parent(impl_def_id)); while let Some(did) = parent { attr_buf.extend( cx.tcx .get_attrs(did, sym::doc) .filter(|attr| { if let Some([attr]) = attr.meta_item_list().as_deref() { attr.has_name(sym::cfg) } else { false } }) .cloned(), ); parent = cx.tcx.opt_parent(did); } inline::build_impl(cx, None, impl_def_id, Some(&attr_buf), &mut new_items_local); attr_buf.clear(); } }); cx.tcx.sess.prof.generic_activity("build_primitive_trait_impls").run(|| { for def_id in PrimitiveType::all_impls(cx.tcx) { // Try to inline primitive impls from other crates. if !def_id.is_local() { inline::build_impl(cx, None, def_id, None, &mut new_items_external); } } for (prim, did) in PrimitiveType::primitive_locations(cx.tcx) { // Do not calculate blanket impl list for docs that are not going to be rendered. // While the `impl` blocks themselves are only in `libcore`, the module with `doc` // attached is directly included in `libstd` as well. let tcx = cx.tcx; if did.is_local() { for def_id in prim.impls(tcx).filter(|def_id| { // Avoid including impl blocks with filled-in generics. // https://github.com/rust-lang/rust/issues/94937 // // FIXME(notriddle): https://github.com/rust-lang/rust/issues/97129 // // This tactic of using inherent impl blocks for getting // auto traits and blanket impls is a hack. What we really // want is to check if `[T]` impls `Send`, which has // nothing to do with the inherent impl. // // Rustdoc currently uses these `impl` block as a source of // the `Ty`, as well as the `ParamEnv`, `SubstsRef`, and // `Generics`. To avoid relying on the `impl` block, these // things would need to be created from wholecloth, in a // form that is valid for use in type inference. let ty = tcx.type_of(def_id); match ty.kind() { ty::Slice(ty) | ty::Ref(_, ty, _) | ty::RawPtr(ty::TypeAndMut { ty, .. }) => { matches!(ty.kind(), ty::Param(..)) } ty::Tuple(tys) => tys.iter().all(|ty| matches!(ty.kind(), ty::Param(..))), _ => true, } }) { let impls = get_auto_trait_and_blanket_impls(cx, def_id); new_items_external.extend(impls.filter(|i| cx.inlined.insert(i.item_id))); } } } }); let mut cleaner = BadImplStripper { prims, items: crate_items, cache: &cx.cache }; let mut type_did_to_deref_target: FxHashMap = FxHashMap::default(); // Follow all `Deref` targets of included items and recursively add them as valid fn add_deref_target( cx: &DocContext<'_>, map: &FxHashMap, cleaner: &mut BadImplStripper<'_>, targets: &mut FxHashSet, type_did: DefId, ) { if let Some(target) = map.get(&type_did) { debug!("add_deref_target: type {:?}, target {:?}", type_did, target); if let Some(target_prim) = target.primitive_type() { cleaner.prims.insert(target_prim); } else if let Some(target_did) = target.def_id(&cx.cache) { // `impl Deref for S` if !targets.insert(target_did) { // Avoid infinite cycles return; } cleaner.items.insert(target_did.into()); add_deref_target(cx, map, cleaner, targets, target_did); } } } // scan through included items ahead of time to splice in Deref targets to the "valid" sets for it in new_items_external.iter().chain(new_items_local.iter()) { if let ImplItem(box Impl { ref for_, ref trait_, ref items, .. }) = *it.kind { if trait_.as_ref().map(|t| t.def_id()) == cx.tcx.lang_items().deref_trait() && cleaner.keep_impl(for_, true) { let target = items .iter() .find_map(|item| match *item.kind { AssocTypeItem(ref t, _) => Some(&t.type_), _ => None, }) .expect("Deref impl without Target type"); if let Some(prim) = target.primitive_type() { cleaner.prims.insert(prim); } else if let Some(did) = target.def_id(&cx.cache) { cleaner.items.insert(did.into()); } if let Some(for_did) = for_.def_id(&cx.cache) { if type_did_to_deref_target.insert(for_did, target).is_none() { // Since only the `DefId` portion of the `Type` instances is known to be same for both the // `Deref` target type and the impl for type positions, this map of types is keyed by // `DefId` and for convenience uses a special cleaner that accepts `DefId`s directly. if cleaner.keep_impl_with_def_id(for_did.into()) { let mut targets = FxHashSet::default(); targets.insert(for_did); add_deref_target( cx, &type_did_to_deref_target, &mut cleaner, &mut targets, for_did, ); } } } } } } // Filter out external items that are not needed new_items_external.retain(|it| { if let ImplItem(box Impl { ref for_, ref trait_, ref kind, .. }) = *it.kind { cleaner.keep_impl( for_, trait_.as_ref().map(|t| t.def_id()) == cx.tcx.lang_items().deref_trait(), ) || trait_.as_ref().map_or(false, |t| cleaner.keep_impl_with_def_id(t.def_id().into())) || kind.is_blanket() } else { true } }); if let ModuleItem(Module { items, .. }) = &mut *krate.module.kind { items.extend(synth_impls); items.extend(new_items_external); items.extend(new_items_local); } else { panic!("collect-trait-impls can't run"); }; krate } struct SyntheticImplCollector<'a, 'tcx> { cx: &'a mut DocContext<'tcx>, impls: Vec, } impl<'a, 'tcx> DocVisitor for SyntheticImplCollector<'a, 'tcx> { fn visit_item(&mut self, i: &Item) { if i.is_struct() || i.is_enum() || i.is_union() { // FIXME(eddyb) is this `doc(hidden)` check needed? if !self.cx.tcx.is_doc_hidden(i.item_id.expect_def_id()) { self.impls .extend(get_auto_trait_and_blanket_impls(self.cx, i.item_id.expect_def_id())); } } self.visit_item_recur(i) } } #[derive(Default)] struct ItemCollector { items: FxHashSet, } impl ItemCollector { fn new() -> Self { Self::default() } } impl DocVisitor for ItemCollector { fn visit_item(&mut self, i: &Item) { self.items.insert(i.item_id); self.visit_item_recur(i) } } struct BadImplStripper<'a> { prims: FxHashSet, items: FxHashSet, cache: &'a Cache, } impl<'a> BadImplStripper<'a> { fn keep_impl(&self, ty: &Type, is_deref: bool) -> bool { if let Generic(_) = ty { // keep impls made on generics true } else if let Some(prim) = ty.primitive_type() { self.prims.contains(&prim) } else if let Some(did) = ty.def_id(self.cache) { is_deref || self.keep_impl_with_def_id(did.into()) } else { false } } fn keep_impl_with_def_id(&self, item_id: ItemId) -> bool { self.items.contains(&item_id) } }