//! Determining which types for which we cannot emit `#[derive(Trait)]`. use std::fmt; use super::{generate_dependencies, ConstrainResult, MonotoneFramework}; use crate::ir::analysis::has_vtable::HasVtable; use crate::ir::comp::CompKind; use crate::ir::context::{BindgenContext, ItemId}; use crate::ir::derive::CanDerive; use crate::ir::function::FunctionSig; use crate::ir::item::{IsOpaque, Item}; use crate::ir::template::TemplateParameters; use crate::ir::traversal::{EdgeKind, Trace}; use crate::ir::ty::RUST_DERIVE_IN_ARRAY_LIMIT; use crate::ir::ty::{Type, TypeKind}; use crate::{Entry, HashMap, HashSet}; /// Which trait to consider when doing the `CannotDerive` analysis. #[derive(Debug, Copy, Clone, Hash, PartialEq, Eq)] pub enum DeriveTrait { /// The `Copy` trait. Copy, /// The `Debug` trait. Debug, /// The `Default` trait. Default, /// The `Hash` trait. Hash, /// The `PartialEq` and `PartialOrd` traits. PartialEqOrPartialOrd, } /// An analysis that finds for each IR item whether a trait cannot be derived. /// /// We use the monotone constraint function `cannot_derive`, defined as follows /// for type T: /// /// * If T is Opaque and the layout of the type is known, get this layout as an /// opaquetype and check whether it can derive using trivial checks. /// /// * If T is Array, a trait cannot be derived if the array is incomplete, /// if the length of the array is larger than the limit (unless the trait /// allows it), or the trait cannot be derived for the type of data the array /// contains. /// /// * If T is Vector, a trait cannot be derived if the trait cannot be derived /// for the type of data the vector contains. /// /// * If T is a type alias, a templated alias or an indirection to another type, /// the trait cannot be derived if the trait cannot be derived for type T /// refers to. /// /// * If T is a compound type, the trait cannot be derived if the trait cannot /// be derived for any of its base members or fields. /// /// * If T is an instantiation of an abstract template definition, the trait /// cannot be derived if any of the template arguments or template definition /// cannot derive the trait. /// /// * For all other (simple) types, compiler and standard library limitations /// dictate whether the trait is implemented. #[derive(Debug, Clone)] pub struct CannotDerive<'ctx> { ctx: &'ctx BindgenContext, derive_trait: DeriveTrait, // The incremental result of this analysis's computation. // Contains information whether particular item can derive `derive_trait` can_derive: HashMap, // Dependencies saying that if a key ItemId has been inserted into the // `cannot_derive_partialeq_or_partialord` 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 // can derive `derive_trait`. dependencies: HashMap>, } type EdgePredicate = fn(EdgeKind) -> bool; fn consider_edge_default(kind: EdgeKind) -> bool { match kind { // These are the only edges that can affect whether a type can derive EdgeKind::BaseMember | EdgeKind::Field | EdgeKind::TypeReference | EdgeKind::VarType | EdgeKind::TemplateArgument | EdgeKind::TemplateDeclaration | EdgeKind::TemplateParameterDefinition => true, EdgeKind::Constructor | EdgeKind::Destructor | EdgeKind::FunctionReturn | EdgeKind::FunctionParameter | EdgeKind::InnerType | EdgeKind::InnerVar | EdgeKind::Method | EdgeKind::Generic => false, } } impl<'ctx> CannotDerive<'ctx> { fn insert>( &mut self, id: Id, can_derive: CanDerive, ) -> ConstrainResult { let id = id.into(); trace!( "inserting {:?} can_derive<{}>={:?}", id, self.derive_trait, can_derive ); if let CanDerive::Yes = can_derive { return ConstrainResult::Same; } match self.can_derive.entry(id) { Entry::Occupied(mut entry) => { if *entry.get() < can_derive { entry.insert(can_derive); ConstrainResult::Changed } else { ConstrainResult::Same } } Entry::Vacant(entry) => { entry.insert(can_derive); ConstrainResult::Changed } } } fn constrain_type(&mut self, item: &Item, ty: &Type) -> CanDerive { if !self.ctx.allowlisted_items().contains(&item.id()) { let can_derive = self .ctx .blocklisted_type_implements_trait(item, self.derive_trait); match can_derive { CanDerive::Yes => trace!( " blocklisted type explicitly implements {}", self.derive_trait ), CanDerive::Manually => trace!( " blocklisted type requires manual implementation of {}", self.derive_trait ), CanDerive::No => trace!( " cannot derive {} for blocklisted type", self.derive_trait ), } return can_derive; } if self.derive_trait.not_by_name(self.ctx, &item) { trace!( " cannot derive {} for explicitly excluded type", self.derive_trait ); return CanDerive::No; } trace!("ty: {:?}", ty); if item.is_opaque(self.ctx, &()) { if !self.derive_trait.can_derive_union() && ty.is_union() && self.ctx.options().rust_features().untagged_union { trace!( " cannot derive {} for Rust unions", self.derive_trait ); return CanDerive::No; } let layout_can_derive = ty.layout(self.ctx).map_or(CanDerive::Yes, |l| { l.opaque().array_size_within_derive_limit(self.ctx) }); match layout_can_derive { CanDerive::Yes => { trace!( " we can trivially derive {} for the layout", self.derive_trait ); } _ => { trace!( " we cannot derive {} for the layout", self.derive_trait ); } }; return layout_can_derive; } match *ty.kind() { // Handle the simple cases. These can derive traits without further // information. TypeKind::Void | TypeKind::NullPtr | TypeKind::Int(..) | TypeKind::Complex(..) | TypeKind::Float(..) | TypeKind::Enum(..) | TypeKind::TypeParam | TypeKind::UnresolvedTypeRef(..) | TypeKind::Reference(..) | TypeKind::ObjCInterface(..) | TypeKind::ObjCId | TypeKind::ObjCSel => { return self.derive_trait.can_derive_simple(ty.kind()); } TypeKind::Pointer(inner) => { let inner_type = self.ctx.resolve_type(inner).canonical_type(self.ctx); if let TypeKind::Function(ref sig) = *inner_type.kind() { return self.derive_trait.can_derive_fnptr(sig); } else { return self.derive_trait.can_derive_pointer(); } } TypeKind::Function(ref sig) => { return self.derive_trait.can_derive_fnptr(sig) } // Complex cases need more information TypeKind::Array(t, len) => { let inner_type = self.can_derive.get(&t.into()).cloned().unwrap_or_default(); if inner_type != CanDerive::Yes { trace!( " arrays of T for which we cannot derive {} \ also cannot derive {}", self.derive_trait, self.derive_trait ); return CanDerive::No; } if len == 0 && !self.derive_trait.can_derive_incomplete_array() { trace!( " cannot derive {} for incomplete arrays", self.derive_trait ); return CanDerive::No; } if self.derive_trait.can_derive_large_array() { trace!(" array can derive {}", self.derive_trait); return CanDerive::Yes; } if len > RUST_DERIVE_IN_ARRAY_LIMIT { trace!( " array is too large to derive {}, but it may be implemented", self.derive_trait ); return CanDerive::Manually; } trace!( " array is small enough to derive {}", self.derive_trait ); return CanDerive::Yes; } TypeKind::Vector(t, len) => { let inner_type = self.can_derive.get(&t.into()).cloned().unwrap_or_default(); if inner_type != CanDerive::Yes { trace!( " vectors of T for which we cannot derive {} \ also cannot derive {}", self.derive_trait, self.derive_trait ); return CanDerive::No; } assert_ne!(len, 0, "vectors cannot have zero length"); return self.derive_trait.can_derive_vector(); } TypeKind::Comp(ref info) => { assert!( !info.has_non_type_template_params(), "The early ty.is_opaque check should have handled this case" ); if !self.derive_trait.can_derive_compound_forward_decl() && info.is_forward_declaration() { trace!( " cannot derive {} for forward decls", self.derive_trait ); return CanDerive::No; } // NOTE: Take into account that while unions in C and C++ are copied by // default, the may have an explicit destructor in C++, so we can't // defer this check just for the union case. if !self.derive_trait.can_derive_compound_with_destructor() && self.ctx.lookup_has_destructor( item.id().expect_type_id(self.ctx), ) { trace!( " comp has destructor which cannot derive {}", self.derive_trait ); return CanDerive::No; } if info.kind() == CompKind::Union { if self.derive_trait.can_derive_union() { if self.ctx.options().rust_features().untagged_union && // https://github.com/rust-lang/rust/issues/36640 (!info.self_template_params(self.ctx).is_empty() || !item.all_template_params(self.ctx).is_empty()) { trace!( " cannot derive {} for Rust union because issue 36640", self.derive_trait ); return CanDerive::No; } // fall through to be same as non-union handling } else { if self.ctx.options().rust_features().untagged_union { trace!( " cannot derive {} for Rust unions", self.derive_trait ); return CanDerive::No; } let layout_can_derive = ty.layout(self.ctx).map_or(CanDerive::Yes, |l| { l.opaque() .array_size_within_derive_limit(self.ctx) }); match layout_can_derive { CanDerive::Yes => { trace!( " union layout can trivially derive {}", self.derive_trait ); } _ => { trace!( " union layout cannot derive {}", self.derive_trait ); } }; return layout_can_derive; } } if !self.derive_trait.can_derive_compound_with_vtable() && item.has_vtable(self.ctx) { trace!( " cannot derive {} for comp with vtable", self.derive_trait ); return CanDerive::No; } // Bitfield units are always represented as arrays of u8, but // they're not traced as arrays, so we need to check here // instead. if !self.derive_trait.can_derive_large_array() && info.has_too_large_bitfield_unit() && !item.is_opaque(self.ctx, &()) { trace!( " cannot derive {} for comp with too large bitfield unit", self.derive_trait ); return CanDerive::No; } let pred = self.derive_trait.consider_edge_comp(); return self.constrain_join(item, pred); } TypeKind::ResolvedTypeRef(..) | TypeKind::TemplateAlias(..) | TypeKind::Alias(..) | TypeKind::BlockPointer(..) => { let pred = self.derive_trait.consider_edge_typeref(); return self.constrain_join(item, pred); } TypeKind::TemplateInstantiation(..) => { let pred = self.derive_trait.consider_edge_tmpl_inst(); return self.constrain_join(item, pred); } TypeKind::Opaque => unreachable!( "The early ty.is_opaque check should have handled this case" ), } } fn constrain_join( &mut self, item: &Item, consider_edge: EdgePredicate, ) -> CanDerive { let mut candidate = None; item.trace( self.ctx, &mut |sub_id, edge_kind| { // Ignore ourselves, since union with ourself is a // no-op. Ignore edges that aren't relevant to the // analysis. if sub_id == item.id() || !consider_edge(edge_kind) { return; } let can_derive = self.can_derive .get(&sub_id) .cloned() .unwrap_or_default(); match can_derive { CanDerive::Yes => trace!(" member {:?} can derive {}", sub_id, self.derive_trait), CanDerive::Manually => trace!(" member {:?} cannot derive {}, but it may be implemented", sub_id, self.derive_trait), CanDerive::No => trace!(" member {:?} cannot derive {}", sub_id, self.derive_trait), } *candidate.get_or_insert(CanDerive::Yes) |= can_derive; }, &(), ); if candidate.is_none() { trace!( " can derive {} because there are no members", self.derive_trait ); } candidate.unwrap_or_default() } } impl DeriveTrait { fn not_by_name(&self, ctx: &BindgenContext, item: &Item) -> bool { match self { DeriveTrait::Copy => ctx.no_copy_by_name(item), DeriveTrait::Debug => ctx.no_debug_by_name(item), DeriveTrait::Default => ctx.no_default_by_name(item), DeriveTrait::Hash => ctx.no_hash_by_name(item), DeriveTrait::PartialEqOrPartialOrd => { ctx.no_partialeq_by_name(item) } } } fn consider_edge_comp(&self) -> EdgePredicate { match self { DeriveTrait::PartialEqOrPartialOrd => consider_edge_default, _ => |kind| match kind { EdgeKind::BaseMember | EdgeKind::Field => true, _ => false, }, } } fn consider_edge_typeref(&self) -> EdgePredicate { match self { DeriveTrait::PartialEqOrPartialOrd => consider_edge_default, _ => |kind| kind == EdgeKind::TypeReference, } } fn consider_edge_tmpl_inst(&self) -> EdgePredicate { match self { DeriveTrait::PartialEqOrPartialOrd => consider_edge_default, _ => |kind| match kind { EdgeKind::TemplateArgument | EdgeKind::TemplateDeclaration => { true } _ => false, }, } } fn can_derive_large_array(&self) -> bool { match self { DeriveTrait::Copy => true, _ => false, } } fn can_derive_union(&self) -> bool { match self { DeriveTrait::Copy => true, _ => false, } } fn can_derive_compound_with_destructor(&self) -> bool { match self { DeriveTrait::Copy => false, _ => true, } } fn can_derive_compound_with_vtable(&self) -> bool { match self { DeriveTrait::Default => false, _ => true, } } fn can_derive_compound_forward_decl(&self) -> bool { match self { DeriveTrait::Copy | DeriveTrait::Debug => true, _ => false, } } fn can_derive_incomplete_array(&self) -> bool { match self { DeriveTrait::Copy | DeriveTrait::Hash | DeriveTrait::PartialEqOrPartialOrd => false, _ => true, } } fn can_derive_fnptr(&self, f: &FunctionSig) -> CanDerive { match (self, f.function_pointers_can_derive()) { (DeriveTrait::Copy, _) | (DeriveTrait::Default, _) | (_, true) => { trace!(" function pointer can derive {}", self); CanDerive::Yes } (DeriveTrait::Debug, false) => { trace!(" function pointer cannot derive {}, but it may be implemented", self); CanDerive::Manually } (_, false) => { trace!(" function pointer cannot derive {}", self); CanDerive::No } } } fn can_derive_vector(&self) -> CanDerive { match self { DeriveTrait::PartialEqOrPartialOrd => { // FIXME: vectors always can derive PartialEq, but they should // not derive PartialOrd: // https://github.com/rust-lang-nursery/packed_simd/issues/48 trace!(" vectors cannot derive PartialOrd"); CanDerive::No } _ => { trace!(" vector can derive {}", self); CanDerive::Yes } } } fn can_derive_pointer(&self) -> CanDerive { match self { DeriveTrait::Default => { trace!(" pointer cannot derive Default"); CanDerive::No } _ => { trace!(" pointer can derive {}", self); CanDerive::Yes } } } fn can_derive_simple(&self, kind: &TypeKind) -> CanDerive { match (self, kind) { // === Default === (DeriveTrait::Default, TypeKind::Void) | (DeriveTrait::Default, TypeKind::NullPtr) | (DeriveTrait::Default, TypeKind::Enum(..)) | (DeriveTrait::Default, TypeKind::Reference(..)) | (DeriveTrait::Default, TypeKind::TypeParam) | (DeriveTrait::Default, TypeKind::ObjCInterface(..)) | (DeriveTrait::Default, TypeKind::ObjCId) | (DeriveTrait::Default, TypeKind::ObjCSel) => { trace!(" types that always cannot derive Default"); CanDerive::No } (DeriveTrait::Default, TypeKind::UnresolvedTypeRef(..)) => { unreachable!( "Type with unresolved type ref can't reach derive default" ) } // === Hash === (DeriveTrait::Hash, TypeKind::Float(..)) | (DeriveTrait::Hash, TypeKind::Complex(..)) => { trace!(" float cannot derive Hash"); CanDerive::No } // === others === _ => { trace!(" simple type that can always derive {}", self); CanDerive::Yes } } } } impl fmt::Display for DeriveTrait { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { let s = match self { DeriveTrait::Copy => "Copy", DeriveTrait::Debug => "Debug", DeriveTrait::Default => "Default", DeriveTrait::Hash => "Hash", DeriveTrait::PartialEqOrPartialOrd => "PartialEq/PartialOrd", }; s.fmt(f) } } impl<'ctx> MonotoneFramework for CannotDerive<'ctx> { type Node = ItemId; type Extra = (&'ctx BindgenContext, DeriveTrait); type Output = HashMap; fn new( (ctx, derive_trait): (&'ctx BindgenContext, DeriveTrait), ) -> CannotDerive<'ctx> { let can_derive = HashMap::default(); let dependencies = generate_dependencies(ctx, consider_edge_default); CannotDerive { ctx, derive_trait, can_derive, dependencies, } } fn initial_worklist(&self) -> Vec { // The transitive closure of all allowlisted items, including explicitly // blocklisted items. self.ctx .allowlisted_items() .iter() .cloned() .flat_map(|i| { let mut reachable = vec![i]; i.trace( self.ctx, &mut |s, _| { reachable.push(s); }, &(), ); reachable }) .collect() } fn constrain(&mut self, id: ItemId) -> ConstrainResult { trace!("constrain: {:?}", id); if let Some(CanDerive::No) = self.can_derive.get(&id).cloned() { trace!(" already know it cannot derive {}", self.derive_trait); return ConstrainResult::Same; } let item = self.ctx.resolve_item(id); let can_derive = match item.as_type() { Some(ty) => { let mut can_derive = self.constrain_type(item, ty); if let CanDerive::Yes = can_derive { if !self.derive_trait.can_derive_large_array() && ty.layout(self.ctx).map_or(false, |l| { l.align > RUST_DERIVE_IN_ARRAY_LIMIT }) { // We have to be conservative: the struct *could* have enough // padding that we emit an array that is longer than // `RUST_DERIVE_IN_ARRAY_LIMIT`. If we moved padding calculations // into the IR and computed them before this analysis, then we could // be precise rather than conservative here. can_derive = CanDerive::Manually; } } can_derive } None => self.constrain_join(item, consider_edge_default), }; self.insert(id, can_derive) } 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: CannotDerive<'ctx>) -> Self { extra_assert!(analysis .can_derive .values() .all(|v| *v != CanDerive::Yes)); analysis.can_derive } } /// Convert a `HashMap` into a `HashSet`. /// /// Elements that are not `CanDerive::Yes` are kept in the set, so that it /// represents all items that cannot derive. pub fn as_cannot_derive_set( can_derive: HashMap, ) -> HashSet { can_derive .into_iter() .filter_map(|(k, v)| if v != CanDerive::Yes { Some(k) } else { None }) .collect() }