compiler/rustc_lint/src/traits.rs - toolchain/rustc - Git at Google

 use crate::lints::{DropGlue, DropTraitConstraintsDiag};
 use crate::LateContext;
 use crate::LateLintPass;
 use crate::LintContext;
 use rustc_hir as hir;
 use rustc_span::symbol::sym;

 declare_lint! {
     /// The `drop_bounds` lint checks for generics with `std::ops::Drop` as
     /// bounds.
     ///
     /// ### Example
     ///
     /// ```rust
     /// fn foo<T: Drop>() {}
     /// ```
     ///
     /// {{produces}}
     ///
     /// ### Explanation
     ///
     /// A generic trait bound of the form `T: Drop` is most likely misleading
     /// and not what the programmer intended (they probably should have used
     /// `std::mem::needs_drop` instead).
     ///
     /// `Drop` bounds do not actually indicate whether a type can be trivially
     /// dropped or not, because a composite type containing `Drop` types does
     /// not necessarily implement `Drop` itself. Naïvely, one might be tempted
     /// to write an implementation that assumes that a type can be trivially
     /// dropped while also supplying a specialization for `T: Drop` that
     /// actually calls the destructor. However, this breaks down e.g. when `T`
     /// is `String`, which does not implement `Drop` itself but contains a
     /// `Vec`, which does implement `Drop`, so assuming `T` can be trivially
     /// dropped would lead to a memory leak here.
     ///
     /// Furthermore, the `Drop` trait only contains one method, `Drop::drop`,
     /// which may not be called explicitly in user code (`E0040`), so there is
     /// really no use case for using `Drop` in trait bounds, save perhaps for
     /// some obscure corner cases, which can use `#[allow(drop_bounds)]`.
     pub DROP_BOUNDS,
     Warn,
     "bounds of the form `T: Drop` are most likely incorrect"
 }

 declare_lint! {
     /// The `dyn_drop` lint checks for trait objects with `std::ops::Drop`.
     ///
     /// ### Example
     ///
     /// ```rust
     /// fn foo(_x: Box<dyn Drop>) {}
     /// ```
     ///
     /// {{produces}}
     ///
     /// ### Explanation
     ///
     /// A trait object bound of the form `dyn Drop` is most likely misleading
     /// and not what the programmer intended.
     ///
     /// `Drop` bounds do not actually indicate whether a type can be trivially
     /// dropped or not, because a composite type containing `Drop` types does
     /// not necessarily implement `Drop` itself. Naïvely, one might be tempted
     /// to write a deferred drop system, to pull cleaning up memory out of a
     /// latency-sensitive code path, using `dyn Drop` trait objects. However,
     /// this breaks down e.g. when `T` is `String`, which does not implement
     /// `Drop`, but should probably be accepted.
     ///
     /// To write a trait object bound that accepts anything, use a placeholder
     /// trait with a blanket implementation.
     ///
     /// ```rust
     /// trait Placeholder {}
     /// impl<T> Placeholder for T {}
     /// fn foo(_x: Box<dyn Placeholder>) {}
     /// ```
     pub DYN_DROP,
     Warn,
     "trait objects of the form `dyn Drop` are useless"
 }

 declare_lint_pass!(
     /// Lint for bounds of the form `T: Drop`, which usually
     /// indicate an attempt to emulate `std::mem::needs_drop`.
     DropTraitConstraints => [DROP_BOUNDS, DYN_DROP]
 );

 impl<'tcx> LateLintPass<'tcx> for DropTraitConstraints {
     fn check_item(&mut self, cx: &LateContext<'tcx>, item: &'tcx hir::Item<'tcx>) {
         use rustc_middle::ty::ClauseKind;

         let predicates = cx.tcx.explicit_predicates_of(item.owner_id);
         for &(predicate, span) in predicates.predicates {
             let ClauseKind::Trait(trait_predicate) = predicate.kind().skip_binder() else {
                 continue;
             };
             let def_id = trait_predicate.trait_ref.def_id;
             if cx.tcx.lang_items().drop_trait() == Some(def_id) {
                 // Explicitly allow `impl Drop`, a drop-guards-as-unnameable-type pattern.
                 if trait_predicate.trait_ref.self_ty().is_impl_trait() {
                     continue;
                 }
                 let Some(def_id) = cx.tcx.get_diagnostic_item(sym::needs_drop) else { return };
                 cx.emit_span_lint(
                     DROP_BOUNDS,
                     span,
                     DropTraitConstraintsDiag { predicate, tcx: cx.tcx, def_id },
                 );
             }
         }
     }

     fn check_ty(&mut self, cx: &LateContext<'_>, ty: &'tcx hir::Ty<'tcx>) {
         let hir::TyKind::TraitObject(bounds, _lifetime, _syntax) = &ty.kind else { return };
         for bound in &bounds[..] {
             let def_id = bound.trait_ref.trait_def_id();
             if cx.tcx.lang_items().drop_trait() == def_id {
                 let Some(def_id) = cx.tcx.get_diagnostic_item(sym::needs_drop) else { return };
                 cx.emit_span_lint(DYN_DROP, bound.span, DropGlue { tcx: cx.tcx, def_id });
             }
         }
     }
 }
	use crate::lints::{DropGlue, DropTraitConstraintsDiag};
	use crate::LateContext;
	use crate::LateLintPass;
	use crate::LintContext;
	use rustc_hir as hir;
	use rustc_span::symbol::sym;

	declare_lint! {
	/// The `drop_bounds` lint checks for generics with `std::ops::Drop` as
	/// bounds.
	///
	/// ### Example
	///
	/// ```rust
	/// fn foo<T: Drop>() {}
	/// ```
	///
	/// {{produces}}
	///
	/// ### Explanation
	///
	/// A generic trait bound of the form `T: Drop` is most likely misleading
	/// and not what the programmer intended (they probably should have used
	/// `std::mem::needs_drop` instead).
	///
	/// `Drop` bounds do not actually indicate whether a type can be trivially
	/// dropped or not, because a composite type containing `Drop` types does
	/// not necessarily implement `Drop` itself. Naïvely, one might be tempted
	/// to write an implementation that assumes that a type can be trivially
	/// dropped while also supplying a specialization for `T: Drop` that
	/// actually calls the destructor. However, this breaks down e.g. when `T`
	/// is `String`, which does not implement `Drop` itself but contains a
	/// `Vec`, which does implement `Drop`, so assuming `T` can be trivially
	/// dropped would lead to a memory leak here.
	///
	/// Furthermore, the `Drop` trait only contains one method, `Drop::drop`,
	/// which may not be called explicitly in user code (`E0040`), so there is
	/// really no use case for using `Drop` in trait bounds, save perhaps for
	/// some obscure corner cases, which can use `#[allow(drop_bounds)]`.
	pub DROP_BOUNDS,
	Warn,
	"bounds of the form `T: Drop` are most likely incorrect"
	}

	declare_lint! {
	/// The `dyn_drop` lint checks for trait objects with `std::ops::Drop`.
	///
	/// ### Example
	///
	/// ```rust
	/// fn foo(_x: Box<dyn Drop>) {}
	/// ```
	///
	/// {{produces}}
	///
	/// ### Explanation
	///
	/// A trait object bound of the form `dyn Drop` is most likely misleading
	/// and not what the programmer intended.
	///
	/// `Drop` bounds do not actually indicate whether a type can be trivially
	/// dropped or not, because a composite type containing `Drop` types does
	/// not necessarily implement `Drop` itself. Naïvely, one might be tempted
	/// to write a deferred drop system, to pull cleaning up memory out of a
	/// latency-sensitive code path, using `dyn Drop` trait objects. However,
	/// this breaks down e.g. when `T` is `String`, which does not implement
	/// `Drop`, but should probably be accepted.
	///
	/// To write a trait object bound that accepts anything, use a placeholder
	/// trait with a blanket implementation.
	///
	/// ```rust
	/// trait Placeholder {}
	/// impl<T> Placeholder for T {}
	/// fn foo(_x: Box<dyn Placeholder>) {}
	/// ```
	pub DYN_DROP,
	Warn,
	"trait objects of the form `dyn Drop` are useless"
	}

	declare_lint_pass!(
	/// Lint for bounds of the form `T: Drop`, which usually
	/// indicate an attempt to emulate `std::mem::needs_drop`.
	DropTraitConstraints => [DROP_BOUNDS, DYN_DROP]
	);

	impl<'tcx> LateLintPass<'tcx> for DropTraitConstraints {
	fn check_item(&mut self, cx: &LateContext<'tcx>, item: &'tcx hir::Item<'tcx>) {
	use rustc_middle::ty::ClauseKind;

	let predicates = cx.tcx.explicit_predicates_of(item.owner_id);
	for &(predicate, span) in predicates.predicates {
	let ClauseKind::Trait(trait_predicate) = predicate.kind().skip_binder() else {
	continue;
	};
	let def_id = trait_predicate.trait_ref.def_id;
	if cx.tcx.lang_items().drop_trait() == Some(def_id) {
	// Explicitly allow `impl Drop`, a drop-guards-as-unnameable-type pattern.
	if trait_predicate.trait_ref.self_ty().is_impl_trait() {
	continue;
	}
	let Some(def_id) = cx.tcx.get_diagnostic_item(sym::needs_drop) else { return };
	cx.emit_span_lint(
	DROP_BOUNDS,
	span,
	DropTraitConstraintsDiag { predicate, tcx: cx.tcx, def_id },
	);
	}
	}
	}

	fn check_ty(&mut self, cx: &LateContext<'_>, ty: &'tcx hir::Ty<'tcx>) {
	let hir::TyKind::TraitObject(bounds, _lifetime, _syntax) = &ty.kind else { return };
	for bound in &bounds[..] {
	let def_id = bound.trait_ref.trait_def_id();
	if cx.tcx.lang_items().drop_trait() == def_id {
	let Some(def_id) = cx.tcx.get_diagnostic_item(sym::needs_drop) else { return };
	cx.emit_span_lint(DYN_DROP, bound.span, DropGlue { tcx: cx.tcx, def_id });
	}
	}
	}
	}