use clean::*; use rustc::util::nodemap::FxHashSet; use rustc::hir::def_id::DefId; use super::Pass; use core::DocContext; use fold::DocFolder; pub const COLLECT_TRAIT_IMPLS: Pass = Pass::early("collect-trait-impls", collect_trait_impls, "retrieves trait impls for items in the crate"); pub fn collect_trait_impls(krate: Crate, cx: &DocContext) -> Crate { let mut synth = SyntheticImplCollector::new(cx); let mut krate = synth.fold_crate(krate); let prims: FxHashSet = krate.primitives.iter().map(|p| p.1).collect(); let crate_items = { let mut coll = ItemCollector::new(); krate = coll.fold_crate(krate); coll.items }; let mut new_items = Vec::new(); for &cnum in cx.tcx.crates().iter() { for &did in cx.tcx.all_trait_implementations(cnum).iter() { inline::build_impl(cx, did, &mut new_items); } } // Also try to inline primitive impls from other crates. let lang_items = cx.tcx.lang_items(); let primitive_impls = [ lang_items.isize_impl(), lang_items.i8_impl(), lang_items.i16_impl(), lang_items.i32_impl(), lang_items.i64_impl(), lang_items.i128_impl(), lang_items.usize_impl(), lang_items.u8_impl(), lang_items.u16_impl(), lang_items.u32_impl(), lang_items.u64_impl(), lang_items.u128_impl(), lang_items.f32_impl(), lang_items.f64_impl(), lang_items.f32_runtime_impl(), lang_items.f64_runtime_impl(), lang_items.char_impl(), lang_items.str_impl(), lang_items.slice_impl(), lang_items.slice_u8_impl(), lang_items.str_alloc_impl(), lang_items.slice_alloc_impl(), lang_items.slice_u8_alloc_impl(), lang_items.const_ptr_impl(), lang_items.mut_ptr_impl(), ]; for def_id in primitive_impls.iter().filter_map(|&def_id| def_id) { if !def_id.is_local() { inline::build_impl(cx, def_id, &mut new_items); let auto_impls = get_auto_traits_with_def_id(cx, def_id); let blanket_impls = get_blanket_impls_with_def_id(cx, def_id); let mut renderinfo = cx.renderinfo.borrow_mut(); let new_impls: Vec = auto_impls.into_iter() .chain(blanket_impls.into_iter()) .filter(|i| renderinfo.inlined.insert(i.def_id)) .collect(); new_items.extend(new_impls); } } let mut cleaner = BadImplStripper { prims, items: crate_items, }; // scan through included items ahead of time to splice in Deref targets to the "valid" sets for it in &new_items { if let ImplItem(Impl { ref for_, ref trait_, ref items, .. }) = it.inner { if cleaner.keep_item(for_) && trait_.def_id() == cx.tcx.lang_items().deref_trait() { let target = items.iter().filter_map(|item| { match item.inner { TypedefItem(ref t, true) => Some(&t.type_), _ => None, } }).next().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() { cleaner.items.insert(did); } } } } new_items.retain(|it| { if let ImplItem(Impl { ref for_, ref trait_, ref blanket_impl, .. }) = it.inner { cleaner.keep_item(for_) || trait_.as_ref().map_or(false, |t| cleaner.keep_item(t)) || blanket_impl.is_some() } else { true } }); // `tcx.crates()` doesn't include the local crate, and `tcx.all_trait_implementations` // doesn't work with it anyway, so pull them from the HIR map instead for &trait_did in cx.all_traits.iter() { for &impl_node in cx.tcx.hir().trait_impls(trait_did) { let impl_did = cx.tcx.hir().local_def_id(impl_node); inline::build_impl(cx, impl_did, &mut new_items); } } if let Some(ref mut it) = krate.module { if let ModuleItem(Module { ref mut items, .. }) = it.inner { items.extend(synth.impls); items.extend(new_items); } else { panic!("collect-trait-impls can't run"); } } else { panic!("collect-trait-impls can't run"); } krate } struct SyntheticImplCollector<'a, 'tcx: 'a, 'rcx: 'a> { cx: &'a DocContext<'a, 'tcx, 'rcx>, impls: Vec, } impl<'a, 'tcx, 'rcx> SyntheticImplCollector<'a, 'tcx, 'rcx> { fn new(cx: &'a DocContext<'a, 'tcx, 'rcx>) -> Self { SyntheticImplCollector { cx, impls: Vec::new(), } } } impl<'a, 'tcx, 'rcx> DocFolder for SyntheticImplCollector<'a, 'tcx, 'rcx> { fn fold_item(&mut self, i: Item) -> Option { if i.is_struct() || i.is_enum() || i.is_union() { if let (Some(node_id), Some(name)) = (self.cx.tcx.hir().as_local_node_id(i.def_id), i.name.clone()) { self.impls.extend(get_auto_traits_with_node_id(self.cx, node_id, name.clone())); self.impls.extend(get_blanket_impls_with_node_id(self.cx, node_id, name)); } else { self.impls.extend(get_auto_traits_with_def_id(self.cx, i.def_id)); self.impls.extend(get_blanket_impls_with_def_id(self.cx, i.def_id)); } } self.fold_item_recur(i) } } #[derive(Default)] struct ItemCollector { items: FxHashSet, } impl ItemCollector { fn new() -> Self { Self::default() } } impl DocFolder for ItemCollector { fn fold_item(&mut self, i: Item) -> Option { self.items.insert(i.def_id); self.fold_item_recur(i) } } struct BadImplStripper { prims: FxHashSet, items: FxHashSet, } impl BadImplStripper { fn keep_item(&self, ty: &Type) -> 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.items.contains(&did) } else { false } } }