//! Structural const qualification. //! //! See the `Qualif` trait for more info. use rustc_errors::ErrorGuaranteed; use rustc_hir::LangItem; use rustc_infer::infer::TyCtxtInferExt; use rustc_middle::mir; use rustc_middle::mir::*; use rustc_middle::ty::{self, subst::SubstsRef, AdtDef, Ty}; use rustc_trait_selection::traits::{ self, ImplSource, Obligation, ObligationCause, SelectionContext, }; use super::ConstCx; pub fn in_any_value_of_ty<'tcx>( cx: &ConstCx<'_, 'tcx>, ty: Ty<'tcx>, tainted_by_errors: Option, ) -> ConstQualifs { ConstQualifs { has_mut_interior: HasMutInterior::in_any_value_of_ty(cx, ty), needs_drop: NeedsDrop::in_any_value_of_ty(cx, ty), needs_non_const_drop: NeedsNonConstDrop::in_any_value_of_ty(cx, ty), custom_eq: CustomEq::in_any_value_of_ty(cx, ty), tainted_by_errors, } } /// A "qualif"(-ication) is a way to look for something "bad" in the MIR that would disqualify some /// code for promotion or prevent it from evaluating at compile time. /// /// Normally, we would determine what qualifications apply to each type and error when an illegal /// operation is performed on such a type. However, this was found to be too imprecise, especially /// in the presence of `enum`s. If only a single variant of an enum has a certain qualification, we /// needn't reject code unless it actually constructs and operates on the qualified variant. /// /// To accomplish this, const-checking and promotion use a value-based analysis (as opposed to a /// type-based one). Qualifications propagate structurally across variables: If a local (or a /// projection of a local) is assigned a qualified value, that local itself becomes qualified. pub trait Qualif { /// The name of the file used to debug the dataflow analysis that computes this qualif. const ANALYSIS_NAME: &'static str; /// Whether this `Qualif` is cleared when a local is moved from. const IS_CLEARED_ON_MOVE: bool = false; /// Whether this `Qualif` might be evaluated after the promotion and can encounter a promoted. const ALLOW_PROMOTED: bool = false; /// Extracts the field of `ConstQualifs` that corresponds to this `Qualif`. fn in_qualifs(qualifs: &ConstQualifs) -> bool; /// Returns `true` if *any* value of the given type could possibly have this `Qualif`. /// /// This function determines `Qualif`s when we cannot do a value-based analysis. Since qualif /// propagation is context-insensitive, this includes function arguments and values returned /// from a call to another function. /// /// It also determines the `Qualif`s for primitive types. fn in_any_value_of_ty<'tcx>(cx: &ConstCx<'_, 'tcx>, ty: Ty<'tcx>) -> bool; /// Returns `true` if this `Qualif` is inherent to the given struct or enum. /// /// By default, `Qualif`s propagate into ADTs in a structural way: An ADT only becomes /// qualified if part of it is assigned a value with that `Qualif`. However, some ADTs *always* /// have a certain `Qualif`, regardless of whether their fields have it. For example, a type /// with a custom `Drop` impl is inherently `NeedsDrop`. /// /// Returning `true` for `in_adt_inherently` but `false` for `in_any_value_of_ty` is unsound. fn in_adt_inherently<'tcx>( cx: &ConstCx<'_, 'tcx>, adt: AdtDef<'tcx>, substs: SubstsRef<'tcx>, ) -> bool; } /// Constant containing interior mutability (`UnsafeCell`). /// This must be ruled out to make sure that evaluating the constant at compile-time /// and at *any point* during the run-time would produce the same result. In particular, /// promotion of temporaries must not change program behavior; if the promoted could be /// written to, that would be a problem. pub struct HasMutInterior; impl Qualif for HasMutInterior { const ANALYSIS_NAME: &'static str = "flow_has_mut_interior"; fn in_qualifs(qualifs: &ConstQualifs) -> bool { qualifs.has_mut_interior } fn in_any_value_of_ty<'tcx>(cx: &ConstCx<'_, 'tcx>, ty: Ty<'tcx>) -> bool { !ty.is_freeze(cx.tcx, cx.param_env) } fn in_adt_inherently<'tcx>( _cx: &ConstCx<'_, 'tcx>, adt: AdtDef<'tcx>, _: SubstsRef<'tcx>, ) -> bool { // Exactly one type, `UnsafeCell`, has the `HasMutInterior` qualif inherently. // It arises structurally for all other types. adt.is_unsafe_cell() } } /// Constant containing an ADT that implements `Drop`. /// This must be ruled out because implicit promotion would remove side-effects /// that occur as part of dropping that value. N.B., the implicit promotion has /// to reject const Drop implementations because even if side-effects are ruled /// out through other means, the execution of the drop could diverge. pub struct NeedsDrop; impl Qualif for NeedsDrop { const ANALYSIS_NAME: &'static str = "flow_needs_drop"; const IS_CLEARED_ON_MOVE: bool = true; fn in_qualifs(qualifs: &ConstQualifs) -> bool { qualifs.needs_drop } fn in_any_value_of_ty<'tcx>(cx: &ConstCx<'_, 'tcx>, ty: Ty<'tcx>) -> bool { ty.needs_drop(cx.tcx, cx.param_env) } fn in_adt_inherently<'tcx>( cx: &ConstCx<'_, 'tcx>, adt: AdtDef<'tcx>, _: SubstsRef<'tcx>, ) -> bool { adt.has_dtor(cx.tcx) } } /// Constant containing an ADT that implements non-const `Drop`. /// This must be ruled out because we cannot run `Drop` during compile-time. pub struct NeedsNonConstDrop; impl Qualif for NeedsNonConstDrop { const ANALYSIS_NAME: &'static str = "flow_needs_nonconst_drop"; const IS_CLEARED_ON_MOVE: bool = true; const ALLOW_PROMOTED: bool = true; fn in_qualifs(qualifs: &ConstQualifs) -> bool { qualifs.needs_non_const_drop } #[instrument(level = "trace", skip(cx), ret)] fn in_any_value_of_ty<'tcx>(cx: &ConstCx<'_, 'tcx>, ty: Ty<'tcx>) -> bool { // Avoid selecting for simple cases, such as builtin types. if ty::util::is_trivially_const_drop(ty) { return false; } let obligation = Obligation::new( cx.tcx, ObligationCause::dummy_with_span(cx.body.span), cx.param_env, ty::Binder::dummy(cx.tcx.at(cx.body.span).mk_trait_ref(LangItem::Destruct, [ty])) .with_constness(ty::BoundConstness::ConstIfConst), ); let infcx = cx.tcx.infer_ctxt().build(); let mut selcx = SelectionContext::new(&infcx); let Some(impl_src) = selcx.select(&obligation).ok().flatten() else { // If we couldn't select a const destruct candidate, then it's bad return true; }; trace!(?impl_src); if !matches!( impl_src, ImplSource::ConstDestruct(_) | ImplSource::Param(_, ty::BoundConstness::ConstIfConst) ) { // If our const destruct candidate is not ConstDestruct or implied by the param env, // then it's bad return true; } if impl_src.borrow_nested_obligations().is_empty() { return false; } // If we had any errors, then it's bad !traits::fully_solve_obligations(&infcx, impl_src.nested_obligations()).is_empty() } fn in_adt_inherently<'tcx>( cx: &ConstCx<'_, 'tcx>, adt: AdtDef<'tcx>, _: SubstsRef<'tcx>, ) -> bool { adt.has_non_const_dtor(cx.tcx) } } /// A constant that cannot be used as part of a pattern in a `match` expression. pub struct CustomEq; impl Qualif for CustomEq { const ANALYSIS_NAME: &'static str = "flow_custom_eq"; fn in_qualifs(qualifs: &ConstQualifs) -> bool { qualifs.custom_eq } fn in_any_value_of_ty<'tcx>(cx: &ConstCx<'_, 'tcx>, ty: Ty<'tcx>) -> bool { // If *any* component of a composite data type does not implement `Structural{Partial,}Eq`, // we know that at least some values of that type are not structural-match. I say "some" // because that component may be part of an enum variant (e.g., // `Option::::Some`), in which case some values of this type may be // structural-match (`Option::None`). traits::search_for_structural_match_violation(cx.body.span, cx.tcx, ty).is_some() } fn in_adt_inherently<'tcx>( cx: &ConstCx<'_, 'tcx>, adt: AdtDef<'tcx>, substs: SubstsRef<'tcx>, ) -> bool { let ty = cx.tcx.mk_ty(ty::Adt(adt, substs)); !ty.is_structural_eq_shallow(cx.tcx) } } // FIXME: Use `mir::visit::Visitor` for the `in_*` functions if/when it supports early return. /// Returns `true` if this `Rvalue` contains qualif `Q`. pub fn in_rvalue<'tcx, Q, F>( cx: &ConstCx<'_, 'tcx>, in_local: &mut F, rvalue: &Rvalue<'tcx>, ) -> bool where Q: Qualif, F: FnMut(Local) -> bool, { match rvalue { Rvalue::ThreadLocalRef(_) | Rvalue::NullaryOp(..) => { Q::in_any_value_of_ty(cx, rvalue.ty(cx.body, cx.tcx)) } Rvalue::Discriminant(place) | Rvalue::Len(place) => { in_place::(cx, in_local, place.as_ref()) } Rvalue::CopyForDeref(place) => in_place::(cx, in_local, place.as_ref()), Rvalue::Use(operand) | Rvalue::Repeat(operand, _) | Rvalue::UnaryOp(_, operand) | Rvalue::Cast(_, operand, _) | Rvalue::ShallowInitBox(operand, _) => in_operand::(cx, in_local, operand), Rvalue::BinaryOp(_, box (lhs, rhs)) | Rvalue::CheckedBinaryOp(_, box (lhs, rhs)) => { in_operand::(cx, in_local, lhs) || in_operand::(cx, in_local, rhs) } Rvalue::Ref(_, _, place) | Rvalue::AddressOf(_, place) => { // Special-case reborrows to be more like a copy of the reference. if let Some((place_base, ProjectionElem::Deref)) = place.as_ref().last_projection() { let base_ty = place_base.ty(cx.body, cx.tcx).ty; if let ty::Ref(..) = base_ty.kind() { return in_place::(cx, in_local, place_base); } } in_place::(cx, in_local, place.as_ref()) } Rvalue::Aggregate(kind, operands) => { // Return early if we know that the struct or enum being constructed is always // qualified. if let AggregateKind::Adt(adt_did, _, substs, ..) = **kind { let def = cx.tcx.adt_def(adt_did); if Q::in_adt_inherently(cx, def, substs) { return true; } if def.is_union() && Q::in_any_value_of_ty(cx, rvalue.ty(cx.body, cx.tcx)) { return true; } } // Otherwise, proceed structurally... operands.iter().any(|o| in_operand::(cx, in_local, o)) } } } /// Returns `true` if this `Place` contains qualif `Q`. pub fn in_place<'tcx, Q, F>(cx: &ConstCx<'_, 'tcx>, in_local: &mut F, place: PlaceRef<'tcx>) -> bool where Q: Qualif, F: FnMut(Local) -> bool, { let mut place = place; while let Some((place_base, elem)) = place.last_projection() { match elem { ProjectionElem::Index(index) if in_local(index) => return true, ProjectionElem::Deref | ProjectionElem::Field(_, _) | ProjectionElem::OpaqueCast(_) | ProjectionElem::ConstantIndex { .. } | ProjectionElem::Subslice { .. } | ProjectionElem::Downcast(_, _) | ProjectionElem::Index(_) => {} } let base_ty = place_base.ty(cx.body, cx.tcx); let proj_ty = base_ty.projection_ty(cx.tcx, elem).ty; if !Q::in_any_value_of_ty(cx, proj_ty) { return false; } place = place_base; } assert!(place.projection.is_empty()); in_local(place.local) } /// Returns `true` if this `Operand` contains qualif `Q`. pub fn in_operand<'tcx, Q, F>( cx: &ConstCx<'_, 'tcx>, in_local: &mut F, operand: &Operand<'tcx>, ) -> bool where Q: Qualif, F: FnMut(Local) -> bool, { let constant = match operand { Operand::Copy(place) | Operand::Move(place) => { return in_place::(cx, in_local, place.as_ref()); } Operand::Constant(c) => c, }; // Check the qualifs of the value of `const` items. // FIXME(valtrees): check whether const qualifs should behave the same // way for type and mir constants. let uneval = match constant.literal { ConstantKind::Ty(ct) if matches!(ct.kind(), ty::ConstKind::Param(_) | ty::ConstKind::Error(_)) => { None } ConstantKind::Ty(c) => bug!("expected ConstKind::Param here, found {:?}", c), ConstantKind::Unevaluated(uv, _) => Some(uv), ConstantKind::Val(..) => None, }; if let Some(mir::UnevaluatedConst { def, substs: _, promoted }) = uneval { // Use qualifs of the type for the promoted. Promoteds in MIR body should be possible // only for `NeedsNonConstDrop` with precise drop checking. This is the only const // check performed after the promotion. Verify that with an assertion. assert!(promoted.is_none() || Q::ALLOW_PROMOTED); // Don't peek inside trait associated constants. if promoted.is_none() && cx.tcx.trait_of_item(def.did).is_none() { assert_eq!(def.const_param_did, None, "expected associated const: {def:?}"); let qualifs = cx.tcx.at(constant.span).mir_const_qualif(def.did); if !Q::in_qualifs(&qualifs) { return false; } // Just in case the type is more specific than // the definition, e.g., impl associated const // with type parameters, take it into account. } } // Otherwise use the qualifs of the type. Q::in_any_value_of_ty(cx, constant.literal.ty()) }