//! Determining which types has vtable use super::{generate_dependencies, ConstrainResult, MonotoneFramework}; use crate::ir::context::{BindgenContext, ItemId}; use crate::ir::traversal::EdgeKind; use crate::ir::ty::TypeKind; use crate::{Entry, HashMap}; use std::cmp; use std::ops; /// The result of the `HasVtableAnalysis` for an individual item. #[derive(Copy, Clone, Debug, PartialEq, Eq, PartialOrd, Ord)] pub enum HasVtableResult { /// The item does not have a vtable pointer. No, /// The item has a vtable and the actual vtable pointer is within this item. SelfHasVtable, /// The item has a vtable, but the actual vtable pointer is in a base /// member. BaseHasVtable, } impl Default for HasVtableResult { fn default() -> Self { HasVtableResult::No } } impl HasVtableResult { /// Take the least upper bound of `self` and `rhs`. pub fn join(self, rhs: Self) -> Self { cmp::max(self, rhs) } } impl ops::BitOr for HasVtableResult { type Output = Self; fn bitor(self, rhs: HasVtableResult) -> Self::Output { self.join(rhs) } } impl ops::BitOrAssign for HasVtableResult { fn bitor_assign(&mut self, rhs: HasVtableResult) { *self = self.join(rhs) } } /// An analysis that finds for each IR item whether it has vtable or not /// /// We use the monotone function `has vtable`, defined as follows: /// /// * If T is a type alias, a templated alias, an indirection to another type, /// or a reference of a type, T has vtable if the type T refers to has vtable. /// * If T is a compound type, T has vtable if we saw a virtual function when /// parsing it or any of its base member has vtable. /// * If T is an instantiation of an abstract template definition, T has /// vtable if template definition has vtable #[derive(Debug, Clone)] pub struct HasVtableAnalysis<'ctx> { ctx: &'ctx BindgenContext, // The incremental result of this analysis's computation. Everything in this // set definitely has a vtable. have_vtable: HashMap, // Dependencies saying that if a key ItemId has been inserted into the // `have_vtable` set, then each of the ids in Vec need to be // considered again. // // This is a subset of the natural IR graph with reversed edges, where we // only include the edges from the IR graph that can affect whether a type // has a vtable or not. dependencies: HashMap>, } impl<'ctx> HasVtableAnalysis<'ctx> { fn consider_edge(kind: EdgeKind) -> bool { match kind { // These are the only edges that can affect whether a type has a // vtable or not. EdgeKind::TypeReference | EdgeKind::BaseMember | EdgeKind::TemplateDeclaration => true, _ => false, } } fn insert>( &mut self, id: Id, result: HasVtableResult, ) -> ConstrainResult { if let HasVtableResult::No = result { return ConstrainResult::Same; } let id = id.into(); match self.have_vtable.entry(id) { Entry::Occupied(mut entry) => { if *entry.get() < result { entry.insert(result); ConstrainResult::Changed } else { ConstrainResult::Same } } Entry::Vacant(entry) => { entry.insert(result); ConstrainResult::Changed } } } fn forward(&mut self, from: Id1, to: Id2) -> ConstrainResult where Id1: Into, Id2: Into, { let from = from.into(); let to = to.into(); match self.have_vtable.get(&from).cloned() { None => ConstrainResult::Same, Some(r) => self.insert(to, r), } } } impl<'ctx> MonotoneFramework for HasVtableAnalysis<'ctx> { type Node = ItemId; type Extra = &'ctx BindgenContext; type Output = HashMap; fn new(ctx: &'ctx BindgenContext) -> HasVtableAnalysis<'ctx> { let have_vtable = HashMap::default(); let dependencies = generate_dependencies(ctx, Self::consider_edge); HasVtableAnalysis { ctx, have_vtable, dependencies, } } fn initial_worklist(&self) -> Vec { self.ctx.allowlisted_items().iter().cloned().collect() } fn constrain(&mut self, id: ItemId) -> ConstrainResult { trace!("constrain {:?}", id); let item = self.ctx.resolve_item(id); let ty = match item.as_type() { None => return ConstrainResult::Same, Some(ty) => ty, }; // TODO #851: figure out a way to handle deriving from template type parameters. match *ty.kind() { TypeKind::TemplateAlias(t, _) | TypeKind::Alias(t) | TypeKind::ResolvedTypeRef(t) | TypeKind::Reference(t) => { trace!( " aliases and references forward to their inner type" ); self.forward(t, id) } TypeKind::Comp(ref info) => { trace!(" comp considers its own methods and bases"); let mut result = HasVtableResult::No; if info.has_own_virtual_method() { trace!(" comp has its own virtual method"); result |= HasVtableResult::SelfHasVtable; } let bases_has_vtable = info.base_members().iter().any(|base| { trace!(" comp has a base with a vtable: {:?}", base); self.have_vtable.contains_key(&base.ty.into()) }); if bases_has_vtable { result |= HasVtableResult::BaseHasVtable; } self.insert(id, result) } TypeKind::TemplateInstantiation(ref inst) => { self.forward(inst.template_definition(), id) } _ => ConstrainResult::Same, } } fn each_depending_on(&self, id: ItemId, mut f: F) where F: FnMut(ItemId), { if let Some(edges) = self.dependencies.get(&id) { for item in edges { trace!("enqueue {:?} into worklist", item); f(*item); } } } } impl<'ctx> From> for HashMap { fn from(analysis: HasVtableAnalysis<'ctx>) -> Self { // We let the lack of an entry mean "No" to save space. extra_assert!(analysis .have_vtable .values() .all(|v| { *v != HasVtableResult::No })); analysis.have_vtable } } /// A convenience trait for the things for which we might wonder if they have a /// vtable during codegen. /// /// This is not for _computing_ whether the thing has a vtable, it is for /// looking up the results of the HasVtableAnalysis's computations for a /// specific thing. pub trait HasVtable { /// Return `true` if this thing has vtable, `false` otherwise. fn has_vtable(&self, ctx: &BindgenContext) -> bool; /// Return `true` if this thing has an actual vtable pointer in itself, as /// opposed to transitively in a base member. fn has_vtable_ptr(&self, ctx: &BindgenContext) -> bool; }