// Copyright 2016 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. use super::{OverlapError, specializes}; use hir::def_id::DefId; use traits::{self, Reveal}; use ty::{self, TyCtxt, TraitDef, TypeFoldable}; use ty::fast_reject::{self, SimplifiedType}; use syntax::ast::Name; use util::nodemap::{DefIdMap, FxHashMap}; /// A per-trait graph of impls in specialization order. At the moment, this /// graph forms a tree rooted with the trait itself, with all other nodes /// representing impls, and parent-child relationships representing /// specializations. /// /// The graph provides two key services: /// /// - Construction, which implicitly checks for overlapping impls (i.e., impls /// that overlap but where neither specializes the other -- an artifact of the /// simple "chain" rule. /// /// - Parent extraction. In particular, the graph can give you the *immediate* /// parents of a given specializing impl, which is needed for extracting /// default items amongst other thigns. In the simple "chain" rule, every impl /// has at most one parent. pub struct Graph { // all impls have a parent; the "root" impls have as their parent the def_id // of the trait parent: DefIdMap, // the "root" impls are found by looking up the trait's def_id. children: DefIdMap, } /// Children of a given impl, grouped into blanket/non-blanket varieties as is /// done in `TraitDef`. struct Children { // Impls of a trait (or specializations of a given impl). To allow for // quicker lookup, the impls are indexed by a simplified version of their // `Self` type: impls with a simplifiable `Self` are stored in // `nonblanket_impls` keyed by it, while all other impls are stored in // `blanket_impls`. // // A similar division is used within `TraitDef`, but the lists there collect // together *all* the impls for a trait, and are populated prior to building // the specialization graph. /// Impls of the trait. nonblanket_impls: FxHashMap>, /// Blanket impls associated with the trait. blanket_impls: Vec, } /// The result of attempting to insert an impl into a group of children. enum Inserted { /// The impl was inserted as a new child in this group of children. BecameNewSibling, /// The impl replaced an existing impl that specializes it. Replaced(DefId), /// The impl is a specialization of an existing child. ShouldRecurseOn(DefId), } impl<'a, 'gcx, 'tcx> Children { fn new() -> Children { Children { nonblanket_impls: FxHashMap(), blanket_impls: vec![], } } /// Insert an impl into this set of children without comparing to any existing impls fn insert_blindly(&mut self, tcx: TyCtxt<'a, 'gcx, 'tcx>, impl_def_id: DefId) { let trait_ref = tcx.impl_trait_ref(impl_def_id).unwrap(); if let Some(sty) = fast_reject::simplify_type(tcx, trait_ref.self_ty(), false) { self.nonblanket_impls.entry(sty).or_insert(vec![]).push(impl_def_id) } else { self.blanket_impls.push(impl_def_id) } } /// Attempt to insert an impl into this set of children, while comparing for /// specialiation relationships. fn insert(&mut self, tcx: TyCtxt<'a, 'gcx, 'tcx>, impl_def_id: DefId, simplified_self: Option) -> Result { for slot in match simplified_self { Some(sty) => self.filtered_mut(sty), None => self.iter_mut(), } { let possible_sibling = *slot; let tcx = tcx.global_tcx(); let (le, ge) = tcx.infer_ctxt(None, None, Reveal::ExactMatch).enter(|infcx| { let overlap = traits::overlapping_impls(&infcx, possible_sibling, impl_def_id); if let Some(impl_header) = overlap { let le = specializes(tcx, impl_def_id, possible_sibling); let ge = specializes(tcx, possible_sibling, impl_def_id); if le == ge { // overlap, but no specialization; error out let trait_ref = impl_header.trait_ref.unwrap(); let self_ty = trait_ref.self_ty(); Err(OverlapError { with_impl: possible_sibling, trait_desc: trait_ref.to_string(), // only report the Self type if it has at least // some outer concrete shell; otherwise, it's // not adding much information. self_desc: if self_ty.has_concrete_skeleton() { Some(self_ty.to_string()) } else { None } }) } else { Ok((le, ge)) } } else { Ok((false, false)) } })?; if le && !ge { debug!("descending as child of TraitRef {:?}", tcx.impl_trait_ref(possible_sibling).unwrap()); // the impl specializes possible_sibling return Ok(Inserted::ShouldRecurseOn(possible_sibling)); } else if ge && !le { debug!("placing as parent of TraitRef {:?}", tcx.impl_trait_ref(possible_sibling).unwrap()); // possible_sibling specializes the impl *slot = impl_def_id; return Ok(Inserted::Replaced(possible_sibling)); } else { // no overlap (error bailed already via ?) } } // no overlap with any potential siblings, so add as a new sibling debug!("placing as new sibling"); self.insert_blindly(tcx, impl_def_id); Ok(Inserted::BecameNewSibling) } fn iter_mut(&'a mut self) -> Box + 'a> { let nonblanket = self.nonblanket_impls.iter_mut().flat_map(|(_, v)| v.iter_mut()); Box::new(self.blanket_impls.iter_mut().chain(nonblanket)) } fn filtered_mut(&'a mut self, sty: SimplifiedType) -> Box + 'a> { let nonblanket = self.nonblanket_impls.entry(sty).or_insert(vec![]).iter_mut(); Box::new(self.blanket_impls.iter_mut().chain(nonblanket)) } } impl<'a, 'gcx, 'tcx> Graph { pub fn new() -> Graph { Graph { parent: Default::default(), children: Default::default(), } } /// Insert a local impl into the specialization graph. If an existing impl /// conflicts with it (has overlap, but neither specializes the other), /// information about the area of overlap is returned in the `Err`. pub fn insert(&mut self, tcx: TyCtxt<'a, 'gcx, 'tcx>, impl_def_id: DefId) -> Result<(), OverlapError> { assert!(impl_def_id.is_local()); let trait_ref = tcx.impl_trait_ref(impl_def_id).unwrap(); let trait_def_id = trait_ref.def_id; debug!("insert({:?}): inserting TraitRef {:?} into specialization graph", impl_def_id, trait_ref); // if the reference itself contains an earlier error (e.g., due to a // resolution failure), then we just insert the impl at the top level of // the graph and claim that there's no overlap (in order to supress // bogus errors). if trait_ref.references_error() { debug!("insert: inserting dummy node for erroneous TraitRef {:?}, \ impl_def_id={:?}, trait_def_id={:?}", trait_ref, impl_def_id, trait_def_id); self.parent.insert(impl_def_id, trait_def_id); self.children.entry(trait_def_id).or_insert(Children::new()) .insert_blindly(tcx, impl_def_id); return Ok(()); } let mut parent = trait_def_id; let simplified = fast_reject::simplify_type(tcx, trait_ref.self_ty(), false); // Descend the specialization tree, where `parent` is the current parent node loop { use self::Inserted::*; let insert_result = self.children.entry(parent).or_insert(Children::new()) .insert(tcx, impl_def_id, simplified)?; match insert_result { BecameNewSibling => { break; } Replaced(new_child) => { self.parent.insert(new_child, impl_def_id); let mut new_children = Children::new(); new_children.insert_blindly(tcx, new_child); self.children.insert(impl_def_id, new_children); break; } ShouldRecurseOn(new_parent) => { parent = new_parent; } } } self.parent.insert(impl_def_id, parent); Ok(()) } /// Insert cached metadata mapping from a child impl back to its parent. pub fn record_impl_from_cstore(&mut self, tcx: TyCtxt<'a, 'gcx, 'tcx>, parent: DefId, child: DefId) { if self.parent.insert(child, parent).is_some() { bug!("When recording an impl from the crate store, information about its parent \ was already present."); } self.children.entry(parent).or_insert(Children::new()).insert_blindly(tcx, child); } /// The parent of a given impl, which is the def id of the trait when the /// impl is a "specialization root". pub fn parent(&self, child: DefId) -> DefId { *self.parent.get(&child).unwrap() } } /// A node in the specialization graph is either an impl or a trait /// definition; either can serve as a source of item definitions. /// There is always exactly one trait definition node: the root. #[derive(Debug, Copy, Clone)] pub enum Node { Impl(DefId), Trait(DefId), } impl<'a, 'gcx, 'tcx> Node { pub fn is_from_trait(&self) -> bool { match *self { Node::Trait(..) => true, _ => false, } } /// Iterate over the items defined directly by the given (impl or trait) node. #[inline] // FIXME(#35870) Avoid closures being unexported due to impl Trait. pub fn items(&self, tcx: TyCtxt<'a, 'gcx, 'tcx>) -> impl Iterator + 'a { tcx.associated_items(self.def_id()) } pub fn def_id(&self) -> DefId { match *self { Node::Impl(did) => did, Node::Trait(did) => did, } } } pub struct Ancestors<'a, 'tcx: 'a> { trait_def: &'a TraitDef<'tcx>, current_source: Option, } impl<'a, 'tcx> Iterator for Ancestors<'a, 'tcx> { type Item = Node; fn next(&mut self) -> Option { let cur = self.current_source.take(); if let Some(Node::Impl(cur_impl)) = cur { let parent = self.trait_def.specialization_graph.borrow().parent(cur_impl); if parent == self.trait_def.def_id() { self.current_source = Some(Node::Trait(parent)); } else { self.current_source = Some(Node::Impl(parent)); } } cur } } pub struct NodeItem { pub node: Node, pub item: T, } impl NodeItem { pub fn map U>(self, f: F) -> NodeItem { NodeItem { node: self.node, item: f(self.item), } } } impl<'a, 'gcx, 'tcx> Ancestors<'a, 'tcx> { /// Search the items from the given ancestors, returning each definition /// with the given name and the given kind. #[inline] // FIXME(#35870) Avoid closures being unexported due to impl Trait. pub fn defs(self, tcx: TyCtxt<'a, 'gcx, 'tcx>, name: Name, kind: ty::AssociatedKind) -> impl Iterator> + 'a { self.flat_map(move |node| { node.items(tcx).filter(move |item| item.kind == kind && item.name == name) .map(move |item| NodeItem { node: node, item: item }) }) } } /// Walk up the specialization ancestors of a given impl, starting with that /// impl itself. pub fn ancestors<'a, 'tcx>(trait_def: &'a TraitDef<'tcx>, start_from_impl: DefId) -> Ancestors<'a, 'tcx> { Ancestors { trait_def: trait_def, current_source: Some(Node::Impl(start_from_impl)), } }