//! Determining the sizedness of types (as base classes and otherwise). use super::{ generate_dependencies, ConstrainResult, HasVtable, MonotoneFramework, }; use crate::ir::context::{BindgenContext, TypeId}; use crate::ir::item::IsOpaque; use crate::ir::traversal::EdgeKind; use crate::ir::ty::TypeKind; use crate::{Entry, HashMap}; use std::{cmp, ops}; /// The result of the `Sizedness` analysis for an individual item. /// /// This is a chain lattice of the form: /// /// ```ignore /// NonZeroSized /// | /// DependsOnTypeParam /// | /// ZeroSized /// ``` /// /// We initially assume that all types are `ZeroSized` and then update our /// understanding as we learn more about each type. #[derive(Copy, Clone, Debug, PartialEq, Eq, PartialOrd, Ord, Default)] pub(crate) enum SizednessResult { /// The type is zero-sized. /// /// This means that if it is a C++ type, and is not being used as a base /// member, then we must add an `_address` byte to enforce the /// unique-address-per-distinct-object-instance rule. #[default] ZeroSized, /// Whether this type is zero-sized or not depends on whether a type /// parameter is zero-sized or not. /// /// For example, given these definitions: /// /// ```c++ /// template /// class Flongo : public T {}; /// /// class Empty {}; /// /// class NonEmpty { int x; }; /// ``` /// /// Then `Flongo` is zero-sized, and needs an `_address` byte /// inserted, while `Flongo` is *not* zero-sized, and should *not* /// have an `_address` byte inserted. /// /// We don't properly handle this situation correctly right now: /// DependsOnTypeParam, /// Has some size that is known to be greater than zero. That doesn't mean /// it has a static size, but it is not zero sized for sure. In other words, /// it might contain an incomplete array or some other dynamically sized /// type. NonZeroSized, } impl SizednessResult { /// Take the least upper bound of `self` and `rhs`. pub(crate) fn join(self, rhs: Self) -> Self { cmp::max(self, rhs) } } impl ops::BitOr for SizednessResult { type Output = Self; fn bitor(self, rhs: SizednessResult) -> Self::Output { self.join(rhs) } } impl ops::BitOrAssign for SizednessResult { fn bitor_assign(&mut self, rhs: SizednessResult) { *self = self.join(rhs) } } /// An analysis that computes the sizedness of all types. /// /// * For types with known sizes -- for example pointers, scalars, etc... -- /// they are assigned `NonZeroSized`. /// /// * For compound structure types with one or more fields, they are assigned /// `NonZeroSized`. /// /// * For compound structure types without any fields, the results of the bases /// are `join`ed. /// /// * For type parameters, `DependsOnTypeParam` is assigned. #[derive(Debug)] pub(crate) struct SizednessAnalysis<'ctx> { ctx: &'ctx BindgenContext, dependencies: HashMap>, // Incremental results of the analysis. Missing entries are implicitly // considered `ZeroSized`. sized: HashMap, } impl<'ctx> SizednessAnalysis<'ctx> { fn consider_edge(kind: EdgeKind) -> bool { // These are the only edges that can affect whether a type is // zero-sized or not. matches!( kind, EdgeKind::TemplateArgument | EdgeKind::TemplateParameterDefinition | EdgeKind::TemplateDeclaration | EdgeKind::TypeReference | EdgeKind::BaseMember | EdgeKind::Field ) } /// Insert an incremental result, and return whether this updated our /// knowledge of types and we should continue the analysis. fn insert( &mut self, id: TypeId, result: SizednessResult, ) -> ConstrainResult { trace!("inserting {:?} for {:?}", result, id); if let SizednessResult::ZeroSized = result { return ConstrainResult::Same; } match self.sized.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: TypeId, to: TypeId) -> ConstrainResult { match self.sized.get(&from).cloned() { None => ConstrainResult::Same, Some(r) => self.insert(to, r), } } } impl<'ctx> MonotoneFramework for SizednessAnalysis<'ctx> { type Node = TypeId; type Extra = &'ctx BindgenContext; type Output = HashMap; fn new(ctx: &'ctx BindgenContext) -> SizednessAnalysis<'ctx> { let dependencies = generate_dependencies(ctx, Self::consider_edge) .into_iter() .filter_map(|(id, sub_ids)| { id.as_type_id(ctx).map(|id| { ( id, sub_ids .into_iter() .filter_map(|s| s.as_type_id(ctx)) .collect::>(), ) }) }) .collect(); let sized = HashMap::default(); SizednessAnalysis { ctx, dependencies, sized, } } fn initial_worklist(&self) -> Vec { self.ctx .allowlisted_items() .iter() .cloned() .filter_map(|id| id.as_type_id(self.ctx)) .collect() } fn constrain(&mut self, id: TypeId) -> ConstrainResult { trace!("constrain {:?}", id); if let Some(SizednessResult::NonZeroSized) = self.sized.get(&id).cloned() { trace!(" already know it is not zero-sized"); return ConstrainResult::Same; } if id.has_vtable_ptr(self.ctx) { trace!(" has an explicit vtable pointer, therefore is not zero-sized"); return self.insert(id, SizednessResult::NonZeroSized); } let ty = self.ctx.resolve_type(id); if id.is_opaque(self.ctx, &()) { trace!(" type is opaque; checking layout..."); let result = ty.layout(self.ctx).map_or(SizednessResult::ZeroSized, |l| { if l.size == 0 { trace!(" ...layout has size == 0"); SizednessResult::ZeroSized } else { trace!(" ...layout has size > 0"); SizednessResult::NonZeroSized } }); return self.insert(id, result); } match *ty.kind() { TypeKind::Void => { trace!(" void is zero-sized"); self.insert(id, SizednessResult::ZeroSized) } TypeKind::TypeParam => { trace!( " type params sizedness depends on what they're \ instantiated as" ); self.insert(id, SizednessResult::DependsOnTypeParam) } TypeKind::Int(..) | TypeKind::Float(..) | TypeKind::Complex(..) | TypeKind::Function(..) | TypeKind::Enum(..) | TypeKind::Reference(..) | TypeKind::NullPtr | TypeKind::ObjCId | TypeKind::ObjCSel | TypeKind::Pointer(..) => { trace!(" {:?} is known not to be zero-sized", ty.kind()); self.insert(id, SizednessResult::NonZeroSized) } TypeKind::ObjCInterface(..) => { trace!(" obj-c interfaces always have at least the `isa` pointer"); self.insert(id, SizednessResult::NonZeroSized) } TypeKind::TemplateAlias(t, _) | TypeKind::Alias(t) | TypeKind::BlockPointer(t) | TypeKind::ResolvedTypeRef(t) => { trace!(" aliases and type refs forward to their inner type"); self.forward(t, id) } TypeKind::TemplateInstantiation(ref inst) => { trace!( " template instantiations are zero-sized if their \ definition is zero-sized" ); self.forward(inst.template_definition(), id) } TypeKind::Array(_, 0) => { trace!(" arrays of zero elements are zero-sized"); self.insert(id, SizednessResult::ZeroSized) } TypeKind::Array(..) => { trace!(" arrays of > 0 elements are not zero-sized"); self.insert(id, SizednessResult::NonZeroSized) } TypeKind::Vector(..) => { trace!(" vectors are not zero-sized"); self.insert(id, SizednessResult::NonZeroSized) } TypeKind::Comp(ref info) => { trace!(" comp considers its own fields and bases"); if !info.fields().is_empty() { return self.insert(id, SizednessResult::NonZeroSized); } let result = info .base_members() .iter() .filter_map(|base| self.sized.get(&base.ty)) .fold(SizednessResult::ZeroSized, |a, b| a.join(*b)); self.insert(id, result) } TypeKind::Opaque => { unreachable!("covered by the .is_opaque() check above") } TypeKind::UnresolvedTypeRef(..) => { unreachable!("Should have been resolved after parsing!"); } } } fn each_depending_on(&self, id: TypeId, mut f: F) where F: FnMut(TypeId), { if let Some(edges) = self.dependencies.get(&id) { for ty in edges { trace!("enqueue {:?} into worklist", ty); f(*ty); } } } } impl<'ctx> From> for HashMap { fn from(analysis: SizednessAnalysis<'ctx>) -> Self { // We let the lack of an entry mean "ZeroSized" to save space. extra_assert!(analysis .sized .values() .all(|v| { *v != SizednessResult::ZeroSized })); analysis.sized } } /// A convenience trait for querying whether some type or ID is sized. /// /// This is not for _computing_ whether the thing is sized, it is for looking up /// the results of the `Sizedness` analysis's computations for a specific thing. pub(crate) trait Sizedness { /// Get the sizedness of this type. fn sizedness(&self, ctx: &BindgenContext) -> SizednessResult; /// Is the sizedness for this type `SizednessResult::ZeroSized`? fn is_zero_sized(&self, ctx: &BindgenContext) -> bool { self.sizedness(ctx) == SizednessResult::ZeroSized } }