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Diffstat (limited to 'compiler/rustc_typeck/src/check/check.rs')
-rw-r--r-- | compiler/rustc_typeck/src/check/check.rs | 1712 |
1 files changed, 1712 insertions, 0 deletions
diff --git a/compiler/rustc_typeck/src/check/check.rs b/compiler/rustc_typeck/src/check/check.rs new file mode 100644 index 000000000..9c1fd9b30 --- /dev/null +++ b/compiler/rustc_typeck/src/check/check.rs @@ -0,0 +1,1712 @@ +use crate::check::intrinsicck::InlineAsmCtxt; + +use super::coercion::CoerceMany; +use super::compare_method::check_type_bounds; +use super::compare_method::{compare_const_impl, compare_impl_method, compare_ty_impl}; +use super::*; +use rustc_attr as attr; +use rustc_errors::{Applicability, ErrorGuaranteed, MultiSpan}; +use rustc_hir as hir; +use rustc_hir::def::{DefKind, Res}; +use rustc_hir::def_id::{DefId, LocalDefId}; +use rustc_hir::intravisit::Visitor; +use rustc_hir::lang_items::LangItem; +use rustc_hir::{ItemKind, Node, PathSegment}; +use rustc_infer::infer::outlives::env::OutlivesEnvironment; +use rustc_infer::infer::type_variable::{TypeVariableOrigin, TypeVariableOriginKind}; +use rustc_infer::infer::{DefiningAnchor, RegionVariableOrigin, TyCtxtInferExt}; +use rustc_infer::traits::Obligation; +use rustc_lint::builtin::REPR_TRANSPARENT_EXTERNAL_PRIVATE_FIELDS; +use rustc_middle::hir::nested_filter; +use rustc_middle::ty::layout::{LayoutError, MAX_SIMD_LANES}; +use rustc_middle::ty::subst::GenericArgKind; +use rustc_middle::ty::util::{Discr, IntTypeExt}; +use rustc_middle::ty::{ + self, ParamEnv, ToPredicate, Ty, TyCtxt, TypeSuperVisitable, TypeVisitable, +}; +use rustc_session::lint::builtin::{UNINHABITED_STATIC, UNSUPPORTED_CALLING_CONVENTIONS}; +use rustc_span::symbol::sym; +use rustc_span::{self, Span}; +use rustc_target::spec::abi::Abi; +use rustc_trait_selection::traits::error_reporting::InferCtxtExt as _; +use rustc_trait_selection::traits::{self, ObligationCtxt}; +use rustc_ty_utils::representability::{self, Representability}; + +use std::iter; +use std::ops::ControlFlow; + +pub(super) fn check_abi(tcx: TyCtxt<'_>, hir_id: hir::HirId, span: Span, abi: Abi) { + match tcx.sess.target.is_abi_supported(abi) { + Some(true) => (), + Some(false) => { + struct_span_err!( + tcx.sess, + span, + E0570, + "`{abi}` is not a supported ABI for the current target", + ) + .emit(); + } + None => { + tcx.struct_span_lint_hir(UNSUPPORTED_CALLING_CONVENTIONS, hir_id, span, |lint| { + lint.build("use of calling convention not supported on this target").emit(); + }); + } + } + + // This ABI is only allowed on function pointers + if abi == Abi::CCmseNonSecureCall { + struct_span_err!( + tcx.sess, + span, + E0781, + "the `\"C-cmse-nonsecure-call\"` ABI is only allowed on function pointers" + ) + .emit(); + } +} + +/// Helper used for fns and closures. Does the grungy work of checking a function +/// body and returns the function context used for that purpose, since in the case of a fn item +/// there is still a bit more to do. +/// +/// * ... +/// * inherited: other fields inherited from the enclosing fn (if any) +#[instrument(skip(inherited, body), level = "debug")] +pub(super) fn check_fn<'a, 'tcx>( + inherited: &'a Inherited<'a, 'tcx>, + param_env: ty::ParamEnv<'tcx>, + fn_sig: ty::FnSig<'tcx>, + decl: &'tcx hir::FnDecl<'tcx>, + fn_id: hir::HirId, + body: &'tcx hir::Body<'tcx>, + can_be_generator: Option<hir::Movability>, + return_type_pre_known: bool, +) -> (FnCtxt<'a, 'tcx>, Option<GeneratorTypes<'tcx>>) { + // Create the function context. This is either derived from scratch or, + // in the case of closures, based on the outer context. + let mut fcx = FnCtxt::new(inherited, param_env, body.value.hir_id); + fcx.ps.set(UnsafetyState::function(fn_sig.unsafety, fn_id)); + fcx.return_type_pre_known = return_type_pre_known; + + let tcx = fcx.tcx; + let hir = tcx.hir(); + + let declared_ret_ty = fn_sig.output(); + + let ret_ty = + fcx.register_infer_ok_obligations(fcx.infcx.replace_opaque_types_with_inference_vars( + declared_ret_ty, + body.value.hir_id, + decl.output.span(), + param_env, + )); + // If we replaced declared_ret_ty with infer vars, then we must be infering + // an opaque type, so set a flag so we can improve diagnostics. + fcx.return_type_has_opaque = ret_ty != declared_ret_ty; + + fcx.ret_coercion = Some(RefCell::new(CoerceMany::new(ret_ty))); + fcx.ret_type_span = Some(decl.output.span()); + + let span = body.value.span; + + fn_maybe_err(tcx, span, fn_sig.abi); + + if fn_sig.abi == Abi::RustCall { + let expected_args = if let ImplicitSelfKind::None = decl.implicit_self { 1 } else { 2 }; + + let err = || { + let item = match tcx.hir().get(fn_id) { + Node::Item(hir::Item { kind: ItemKind::Fn(header, ..), .. }) => Some(header), + Node::ImplItem(hir::ImplItem { + kind: hir::ImplItemKind::Fn(header, ..), .. + }) => Some(header), + Node::TraitItem(hir::TraitItem { + kind: hir::TraitItemKind::Fn(header, ..), + .. + }) => Some(header), + // Closures are RustCall, but they tuple their arguments, so shouldn't be checked + Node::Expr(hir::Expr { kind: hir::ExprKind::Closure { .. }, .. }) => None, + node => bug!("Item being checked wasn't a function/closure: {:?}", node), + }; + + if let Some(header) = item { + tcx.sess.span_err(header.span, "functions with the \"rust-call\" ABI must take a single non-self argument that is a tuple"); + } + }; + + if fn_sig.inputs().len() != expected_args { + err() + } else { + // FIXME(CraftSpider) Add a check on parameter expansion, so we don't just make the ICE happen later on + // This will probably require wide-scale changes to support a TupleKind obligation + // We can't resolve this without knowing the type of the param + if !matches!(fn_sig.inputs()[expected_args - 1].kind(), ty::Tuple(_) | ty::Param(_)) { + err() + } + } + } + + if body.generator_kind.is_some() && can_be_generator.is_some() { + let yield_ty = fcx + .next_ty_var(TypeVariableOrigin { kind: TypeVariableOriginKind::TypeInference, span }); + fcx.require_type_is_sized(yield_ty, span, traits::SizedYieldType); + + // Resume type defaults to `()` if the generator has no argument. + let resume_ty = fn_sig.inputs().get(0).copied().unwrap_or_else(|| tcx.mk_unit()); + + fcx.resume_yield_tys = Some((resume_ty, yield_ty)); + } + + GatherLocalsVisitor::new(&fcx).visit_body(body); + + // C-variadic fns also have a `VaList` input that's not listed in `fn_sig` + // (as it's created inside the body itself, not passed in from outside). + let maybe_va_list = if fn_sig.c_variadic { + let span = body.params.last().unwrap().span; + let va_list_did = tcx.require_lang_item(LangItem::VaList, Some(span)); + let region = fcx.next_region_var(RegionVariableOrigin::MiscVariable(span)); + + Some(tcx.bound_type_of(va_list_did).subst(tcx, &[region.into()])) + } else { + None + }; + + // Add formal parameters. + let inputs_hir = hir.fn_decl_by_hir_id(fn_id).map(|decl| &decl.inputs); + let inputs_fn = fn_sig.inputs().iter().copied(); + for (idx, (param_ty, param)) in inputs_fn.chain(maybe_va_list).zip(body.params).enumerate() { + // Check the pattern. + let ty_span = try { inputs_hir?.get(idx)?.span }; + fcx.check_pat_top(¶m.pat, param_ty, ty_span, false); + + // Check that argument is Sized. + // The check for a non-trivial pattern is a hack to avoid duplicate warnings + // for simple cases like `fn foo(x: Trait)`, + // where we would error once on the parameter as a whole, and once on the binding `x`. + if param.pat.simple_ident().is_none() && !tcx.features().unsized_fn_params { + fcx.require_type_is_sized(param_ty, param.pat.span, traits::SizedArgumentType(ty_span)); + } + + fcx.write_ty(param.hir_id, param_ty); + } + + inherited.typeck_results.borrow_mut().liberated_fn_sigs_mut().insert(fn_id, fn_sig); + + fcx.in_tail_expr = true; + if let ty::Dynamic(..) = declared_ret_ty.kind() { + // FIXME: We need to verify that the return type is `Sized` after the return expression has + // been evaluated so that we have types available for all the nodes being returned, but that + // requires the coerced evaluated type to be stored. Moving `check_return_expr` before this + // causes unsized errors caused by the `declared_ret_ty` to point at the return expression, + // while keeping the current ordering we will ignore the tail expression's type because we + // don't know it yet. We can't do `check_expr_kind` while keeping `check_return_expr` + // because we will trigger "unreachable expression" lints unconditionally. + // Because of all of this, we perform a crude check to know whether the simplest `!Sized` + // case that a newcomer might make, returning a bare trait, and in that case we populate + // the tail expression's type so that the suggestion will be correct, but ignore all other + // possible cases. + fcx.check_expr(&body.value); + fcx.require_type_is_sized(declared_ret_ty, decl.output.span(), traits::SizedReturnType); + } else { + fcx.require_type_is_sized(declared_ret_ty, decl.output.span(), traits::SizedReturnType); + fcx.check_return_expr(&body.value, false); + } + fcx.in_tail_expr = false; + + // We insert the deferred_generator_interiors entry after visiting the body. + // This ensures that all nested generators appear before the entry of this generator. + // resolve_generator_interiors relies on this property. + let gen_ty = if let (Some(_), Some(gen_kind)) = (can_be_generator, body.generator_kind) { + let interior = fcx + .next_ty_var(TypeVariableOrigin { kind: TypeVariableOriginKind::MiscVariable, span }); + fcx.deferred_generator_interiors.borrow_mut().push((body.id(), interior, gen_kind)); + + let (resume_ty, yield_ty) = fcx.resume_yield_tys.unwrap(); + Some(GeneratorTypes { + resume_ty, + yield_ty, + interior, + movability: can_be_generator.unwrap(), + }) + } else { + None + }; + + // Finalize the return check by taking the LUB of the return types + // we saw and assigning it to the expected return type. This isn't + // really expected to fail, since the coercions would have failed + // earlier when trying to find a LUB. + let coercion = fcx.ret_coercion.take().unwrap().into_inner(); + let mut actual_return_ty = coercion.complete(&fcx); + debug!("actual_return_ty = {:?}", actual_return_ty); + if let ty::Dynamic(..) = declared_ret_ty.kind() { + // We have special-cased the case where the function is declared + // `-> dyn Foo` and we don't actually relate it to the + // `fcx.ret_coercion`, so just substitute a type variable. + actual_return_ty = + fcx.next_ty_var(TypeVariableOrigin { kind: TypeVariableOriginKind::DynReturnFn, span }); + debug!("actual_return_ty replaced with {:?}", actual_return_ty); + } + + // HACK(oli-obk, compiler-errors): We should be comparing this against + // `declared_ret_ty`, but then anything uninferred would be inferred to + // the opaque type itself. That again would cause writeback to assume + // we have a recursive call site and do the sadly stabilized fallback to `()`. + fcx.demand_suptype(span, ret_ty, actual_return_ty); + + // Check that a function marked as `#[panic_handler]` has signature `fn(&PanicInfo) -> !` + if let Some(panic_impl_did) = tcx.lang_items().panic_impl() + && panic_impl_did == hir.local_def_id(fn_id).to_def_id() + { + check_panic_info_fn(tcx, panic_impl_did.expect_local(), fn_sig, decl, declared_ret_ty); + } + + // Check that a function marked as `#[alloc_error_handler]` has signature `fn(Layout) -> !` + if let Some(alloc_error_handler_did) = tcx.lang_items().oom() + && alloc_error_handler_did == hir.local_def_id(fn_id).to_def_id() + { + check_alloc_error_fn(tcx, alloc_error_handler_did.expect_local(), fn_sig, decl, declared_ret_ty); + } + + (fcx, gen_ty) +} + +fn check_panic_info_fn( + tcx: TyCtxt<'_>, + fn_id: LocalDefId, + fn_sig: ty::FnSig<'_>, + decl: &hir::FnDecl<'_>, + declared_ret_ty: Ty<'_>, +) { + let Some(panic_info_did) = tcx.lang_items().panic_info() else { + tcx.sess.err("language item required, but not found: `panic_info`"); + return; + }; + + if *declared_ret_ty.kind() != ty::Never { + tcx.sess.span_err(decl.output.span(), "return type should be `!`"); + } + + let inputs = fn_sig.inputs(); + if inputs.len() != 1 { + tcx.sess.span_err(tcx.def_span(fn_id), "function should have one argument"); + return; + } + + let arg_is_panic_info = match *inputs[0].kind() { + ty::Ref(region, ty, mutbl) => match *ty.kind() { + ty::Adt(ref adt, _) => { + adt.did() == panic_info_did && mutbl == hir::Mutability::Not && !region.is_static() + } + _ => false, + }, + _ => false, + }; + + if !arg_is_panic_info { + tcx.sess.span_err(decl.inputs[0].span, "argument should be `&PanicInfo`"); + } + + let DefKind::Fn = tcx.def_kind(fn_id) else { + let span = tcx.def_span(fn_id); + tcx.sess.span_err(span, "should be a function"); + return; + }; + + let generic_counts = tcx.generics_of(fn_id).own_counts(); + if generic_counts.types != 0 { + let span = tcx.def_span(fn_id); + tcx.sess.span_err(span, "should have no type parameters"); + } + if generic_counts.consts != 0 { + let span = tcx.def_span(fn_id); + tcx.sess.span_err(span, "should have no const parameters"); + } +} + +fn check_alloc_error_fn( + tcx: TyCtxt<'_>, + fn_id: LocalDefId, + fn_sig: ty::FnSig<'_>, + decl: &hir::FnDecl<'_>, + declared_ret_ty: Ty<'_>, +) { + let Some(alloc_layout_did) = tcx.lang_items().alloc_layout() else { + tcx.sess.err("language item required, but not found: `alloc_layout`"); + return; + }; + + if *declared_ret_ty.kind() != ty::Never { + tcx.sess.span_err(decl.output.span(), "return type should be `!`"); + } + + let inputs = fn_sig.inputs(); + if inputs.len() != 1 { + tcx.sess.span_err(tcx.def_span(fn_id), "function should have one argument"); + return; + } + + let arg_is_alloc_layout = match inputs[0].kind() { + ty::Adt(ref adt, _) => adt.did() == alloc_layout_did, + _ => false, + }; + + if !arg_is_alloc_layout { + tcx.sess.span_err(decl.inputs[0].span, "argument should be `Layout`"); + } + + let DefKind::Fn = tcx.def_kind(fn_id) else { + let span = tcx.def_span(fn_id); + tcx.sess.span_err(span, "`#[alloc_error_handler]` should be a function"); + return; + }; + + let generic_counts = tcx.generics_of(fn_id).own_counts(); + if generic_counts.types != 0 { + let span = tcx.def_span(fn_id); + tcx.sess.span_err(span, "`#[alloc_error_handler]` function should have no type parameters"); + } + if generic_counts.consts != 0 { + let span = tcx.def_span(fn_id); + tcx.sess + .span_err(span, "`#[alloc_error_handler]` function should have no const parameters"); + } +} + +fn check_struct(tcx: TyCtxt<'_>, def_id: LocalDefId) { + let def = tcx.adt_def(def_id); + let span = tcx.def_span(def_id); + def.destructor(tcx); // force the destructor to be evaluated + check_representable(tcx, span, def_id); + + if def.repr().simd() { + check_simd(tcx, span, def_id); + } + + check_transparent(tcx, span, def); + check_packed(tcx, span, def); +} + +fn check_union(tcx: TyCtxt<'_>, def_id: LocalDefId) { + let def = tcx.adt_def(def_id); + let span = tcx.def_span(def_id); + def.destructor(tcx); // force the destructor to be evaluated + check_representable(tcx, span, def_id); + check_transparent(tcx, span, def); + check_union_fields(tcx, span, def_id); + check_packed(tcx, span, def); +} + +/// Check that the fields of the `union` do not need dropping. +fn check_union_fields(tcx: TyCtxt<'_>, span: Span, item_def_id: LocalDefId) -> bool { + let item_type = tcx.type_of(item_def_id); + if let ty::Adt(def, substs) = item_type.kind() { + assert!(def.is_union()); + + fn allowed_union_field<'tcx>( + ty: Ty<'tcx>, + tcx: TyCtxt<'tcx>, + param_env: ty::ParamEnv<'tcx>, + span: Span, + ) -> bool { + // We don't just accept all !needs_drop fields, due to semver concerns. + match ty.kind() { + ty::Ref(..) => true, // references never drop (even mutable refs, which are non-Copy and hence fail the later check) + ty::Tuple(tys) => { + // allow tuples of allowed types + tys.iter().all(|ty| allowed_union_field(ty, tcx, param_env, span)) + } + ty::Array(elem, _len) => { + // Like `Copy`, we do *not* special-case length 0. + allowed_union_field(*elem, tcx, param_env, span) + } + _ => { + // Fallback case: allow `ManuallyDrop` and things that are `Copy`. + ty.ty_adt_def().is_some_and(|adt_def| adt_def.is_manually_drop()) + || ty.is_copy_modulo_regions(tcx.at(span), param_env) + } + } + } + + let param_env = tcx.param_env(item_def_id); + for field in &def.non_enum_variant().fields { + let field_ty = field.ty(tcx, substs); + + if !allowed_union_field(field_ty, tcx, param_env, span) { + let (field_span, ty_span) = match tcx.hir().get_if_local(field.did) { + // We are currently checking the type this field came from, so it must be local. + Some(Node::Field(field)) => (field.span, field.ty.span), + _ => unreachable!("mir field has to correspond to hir field"), + }; + struct_span_err!( + tcx.sess, + field_span, + E0740, + "unions cannot contain fields that may need dropping" + ) + .note( + "a type is guaranteed not to need dropping \ + when it implements `Copy`, or when it is the special `ManuallyDrop<_>` type", + ) + .multipart_suggestion_verbose( + "when the type does not implement `Copy`, \ + wrap it inside a `ManuallyDrop<_>` and ensure it is manually dropped", + vec![ + (ty_span.shrink_to_lo(), "std::mem::ManuallyDrop<".into()), + (ty_span.shrink_to_hi(), ">".into()), + ], + Applicability::MaybeIncorrect, + ) + .emit(); + return false; + } else if field_ty.needs_drop(tcx, param_env) { + // This should never happen. But we can get here e.g. in case of name resolution errors. + tcx.sess.delay_span_bug(span, "we should never accept maybe-dropping union fields"); + } + } + } else { + span_bug!(span, "unions must be ty::Adt, but got {:?}", item_type.kind()); + } + true +} + +/// Check that a `static` is inhabited. +fn check_static_inhabited<'tcx>(tcx: TyCtxt<'tcx>, def_id: LocalDefId) { + // Make sure statics are inhabited. + // Other parts of the compiler assume that there are no uninhabited places. In principle it + // would be enough to check this for `extern` statics, as statics with an initializer will + // have UB during initialization if they are uninhabited, but there also seems to be no good + // reason to allow any statics to be uninhabited. + let ty = tcx.type_of(def_id); + let span = tcx.def_span(def_id); + let layout = match tcx.layout_of(ParamEnv::reveal_all().and(ty)) { + Ok(l) => l, + // Foreign statics that overflow their allowed size should emit an error + Err(LayoutError::SizeOverflow(_)) + if { + let node = tcx.hir().get_by_def_id(def_id); + matches!( + node, + hir::Node::ForeignItem(hir::ForeignItem { + kind: hir::ForeignItemKind::Static(..), + .. + }) + ) + } => + { + tcx.sess + .struct_span_err(span, "extern static is too large for the current architecture") + .emit(); + return; + } + // Generic statics are rejected, but we still reach this case. + Err(e) => { + tcx.sess.delay_span_bug(span, &e.to_string()); + return; + } + }; + if layout.abi.is_uninhabited() { + tcx.struct_span_lint_hir( + UNINHABITED_STATIC, + tcx.hir().local_def_id_to_hir_id(def_id), + span, + |lint| { + lint.build("static of uninhabited type") + .note("uninhabited statics cannot be initialized, and any access would be an immediate error") + .emit(); + }, + ); + } +} + +/// Checks that an opaque type does not contain cycles and does not use `Self` or `T::Foo` +/// projections that would result in "inheriting lifetimes". +pub(super) fn check_opaque<'tcx>( + tcx: TyCtxt<'tcx>, + def_id: LocalDefId, + substs: SubstsRef<'tcx>, + origin: &hir::OpaqueTyOrigin, +) { + let span = tcx.def_span(def_id); + check_opaque_for_inheriting_lifetimes(tcx, def_id, span); + if tcx.type_of(def_id).references_error() { + return; + } + if check_opaque_for_cycles(tcx, def_id, substs, span, origin).is_err() { + return; + } + check_opaque_meets_bounds(tcx, def_id, substs, span, origin); +} + +/// Checks that an opaque type does not use `Self` or `T::Foo` projections that would result +/// in "inheriting lifetimes". +#[instrument(level = "debug", skip(tcx, span))] +pub(super) fn check_opaque_for_inheriting_lifetimes<'tcx>( + tcx: TyCtxt<'tcx>, + def_id: LocalDefId, + span: Span, +) { + let item = tcx.hir().expect_item(def_id); + debug!(?item, ?span); + + struct FoundParentLifetime; + struct FindParentLifetimeVisitor<'tcx>(&'tcx ty::Generics); + impl<'tcx> ty::visit::TypeVisitor<'tcx> for FindParentLifetimeVisitor<'tcx> { + type BreakTy = FoundParentLifetime; + + fn visit_region(&mut self, r: ty::Region<'tcx>) -> ControlFlow<Self::BreakTy> { + debug!("FindParentLifetimeVisitor: r={:?}", r); + if let ty::ReEarlyBound(ty::EarlyBoundRegion { index, .. }) = *r { + if index < self.0.parent_count as u32 { + return ControlFlow::Break(FoundParentLifetime); + } else { + return ControlFlow::CONTINUE; + } + } + + r.super_visit_with(self) + } + + fn visit_const(&mut self, c: ty::Const<'tcx>) -> ControlFlow<Self::BreakTy> { + if let ty::ConstKind::Unevaluated(..) = c.kind() { + // FIXME(#72219) We currently don't detect lifetimes within substs + // which would violate this check. Even though the particular substitution is not used + // within the const, this should still be fixed. + return ControlFlow::CONTINUE; + } + c.super_visit_with(self) + } + } + + struct ProhibitOpaqueVisitor<'tcx> { + tcx: TyCtxt<'tcx>, + opaque_identity_ty: Ty<'tcx>, + generics: &'tcx ty::Generics, + selftys: Vec<(Span, Option<String>)>, + } + + impl<'tcx> ty::visit::TypeVisitor<'tcx> for ProhibitOpaqueVisitor<'tcx> { + type BreakTy = Ty<'tcx>; + + fn visit_ty(&mut self, t: Ty<'tcx>) -> ControlFlow<Self::BreakTy> { + debug!("check_opaque_for_inheriting_lifetimes: (visit_ty) t={:?}", t); + if t == self.opaque_identity_ty { + ControlFlow::CONTINUE + } else { + t.super_visit_with(&mut FindParentLifetimeVisitor(self.generics)) + .map_break(|FoundParentLifetime| t) + } + } + } + + impl<'tcx> Visitor<'tcx> for ProhibitOpaqueVisitor<'tcx> { + type NestedFilter = nested_filter::OnlyBodies; + + fn nested_visit_map(&mut self) -> Self::Map { + self.tcx.hir() + } + + fn visit_ty(&mut self, arg: &'tcx hir::Ty<'tcx>) { + match arg.kind { + hir::TyKind::Path(hir::QPath::Resolved(None, path)) => match &path.segments { + [ + PathSegment { + res: Some(Res::SelfTy { trait_: _, alias_to: impl_ref }), + .. + }, + ] => { + let impl_ty_name = + impl_ref.map(|(def_id, _)| self.tcx.def_path_str(def_id)); + self.selftys.push((path.span, impl_ty_name)); + } + _ => {} + }, + _ => {} + } + hir::intravisit::walk_ty(self, arg); + } + } + + if let ItemKind::OpaqueTy(hir::OpaqueTy { + origin: hir::OpaqueTyOrigin::AsyncFn(..) | hir::OpaqueTyOrigin::FnReturn(..), + .. + }) = item.kind + { + let mut visitor = ProhibitOpaqueVisitor { + opaque_identity_ty: tcx.mk_opaque( + def_id.to_def_id(), + InternalSubsts::identity_for_item(tcx, def_id.to_def_id()), + ), + generics: tcx.generics_of(def_id), + tcx, + selftys: vec![], + }; + let prohibit_opaque = tcx + .explicit_item_bounds(def_id) + .iter() + .try_for_each(|(predicate, _)| predicate.visit_with(&mut visitor)); + debug!( + "check_opaque_for_inheriting_lifetimes: prohibit_opaque={:?}, visitor.opaque_identity_ty={:?}, visitor.generics={:?}", + prohibit_opaque, visitor.opaque_identity_ty, visitor.generics + ); + + if let Some(ty) = prohibit_opaque.break_value() { + visitor.visit_item(&item); + let is_async = match item.kind { + ItemKind::OpaqueTy(hir::OpaqueTy { origin, .. }) => { + matches!(origin, hir::OpaqueTyOrigin::AsyncFn(..)) + } + _ => unreachable!(), + }; + + let mut err = struct_span_err!( + tcx.sess, + span, + E0760, + "`{}` return type cannot contain a projection or `Self` that references lifetimes from \ + a parent scope", + if is_async { "async fn" } else { "impl Trait" }, + ); + + for (span, name) in visitor.selftys { + err.span_suggestion( + span, + "consider spelling out the type instead", + name.unwrap_or_else(|| format!("{:?}", ty)), + Applicability::MaybeIncorrect, + ); + } + err.emit(); + } + } +} + +/// Checks that an opaque type does not contain cycles. +pub(super) fn check_opaque_for_cycles<'tcx>( + tcx: TyCtxt<'tcx>, + def_id: LocalDefId, + substs: SubstsRef<'tcx>, + span: Span, + origin: &hir::OpaqueTyOrigin, +) -> Result<(), ErrorGuaranteed> { + if tcx.try_expand_impl_trait_type(def_id.to_def_id(), substs).is_err() { + let reported = match origin { + hir::OpaqueTyOrigin::AsyncFn(..) => async_opaque_type_cycle_error(tcx, span), + _ => opaque_type_cycle_error(tcx, def_id, span), + }; + Err(reported) + } else { + Ok(()) + } +} + +/// Check that the concrete type behind `impl Trait` actually implements `Trait`. +/// +/// This is mostly checked at the places that specify the opaque type, but we +/// check those cases in the `param_env` of that function, which may have +/// bounds not on this opaque type: +/// +/// type X<T> = impl Clone +/// fn f<T: Clone>(t: T) -> X<T> { +/// t +/// } +/// +/// Without this check the above code is incorrectly accepted: we would ICE if +/// some tried, for example, to clone an `Option<X<&mut ()>>`. +#[instrument(level = "debug", skip(tcx))] +fn check_opaque_meets_bounds<'tcx>( + tcx: TyCtxt<'tcx>, + def_id: LocalDefId, + substs: SubstsRef<'tcx>, + span: Span, + origin: &hir::OpaqueTyOrigin, +) { + let hidden_type = tcx.bound_type_of(def_id.to_def_id()).subst(tcx, substs); + + let hir_id = tcx.hir().local_def_id_to_hir_id(def_id); + let defining_use_anchor = match *origin { + hir::OpaqueTyOrigin::FnReturn(did) | hir::OpaqueTyOrigin::AsyncFn(did) => did, + hir::OpaqueTyOrigin::TyAlias => def_id, + }; + let param_env = tcx.param_env(defining_use_anchor); + + tcx.infer_ctxt().with_opaque_type_inference(DefiningAnchor::Bind(defining_use_anchor)).enter( + move |infcx| { + let ocx = ObligationCtxt::new(&infcx); + let opaque_ty = tcx.mk_opaque(def_id.to_def_id(), substs); + + let misc_cause = traits::ObligationCause::misc(span, hir_id); + + match infcx.at(&misc_cause, param_env).eq(opaque_ty, hidden_type) { + Ok(infer_ok) => ocx.register_infer_ok_obligations(infer_ok), + Err(ty_err) => { + tcx.sess.delay_span_bug( + span, + &format!("could not unify `{hidden_type}` with revealed type:\n{ty_err}"), + ); + } + } + + // Additionally require the hidden type to be well-formed with only the generics of the opaque type. + // Defining use functions may have more bounds than the opaque type, which is ok, as long as the + // hidden type is well formed even without those bounds. + let predicate = ty::Binder::dummy(ty::PredicateKind::WellFormed(hidden_type.into())) + .to_predicate(tcx); + ocx.register_obligation(Obligation::new(misc_cause, param_env, predicate)); + + // Check that all obligations are satisfied by the implementation's + // version. + let errors = ocx.select_all_or_error(); + if !errors.is_empty() { + infcx.report_fulfillment_errors(&errors, None, false); + } + match origin { + // Checked when type checking the function containing them. + hir::OpaqueTyOrigin::FnReturn(..) | hir::OpaqueTyOrigin::AsyncFn(..) => {} + // Can have different predicates to their defining use + hir::OpaqueTyOrigin::TyAlias => { + let outlives_environment = OutlivesEnvironment::new(param_env); + infcx.check_region_obligations_and_report_errors( + defining_use_anchor, + &outlives_environment, + ); + } + } + // Clean up after ourselves + let _ = infcx.inner.borrow_mut().opaque_type_storage.take_opaque_types(); + }, + ); +} + +fn check_item_type<'tcx>(tcx: TyCtxt<'tcx>, id: hir::ItemId) { + debug!( + "check_item_type(it.def_id={:?}, it.name={})", + id.def_id, + tcx.def_path_str(id.def_id.to_def_id()) + ); + let _indenter = indenter(); + match tcx.def_kind(id.def_id) { + DefKind::Static(..) => { + tcx.ensure().typeck(id.def_id); + maybe_check_static_with_link_section(tcx, id.def_id); + check_static_inhabited(tcx, id.def_id); + } + DefKind::Const => { + tcx.ensure().typeck(id.def_id); + } + DefKind::Enum => { + let item = tcx.hir().item(id); + let hir::ItemKind::Enum(ref enum_definition, _) = item.kind else { + return; + }; + check_enum(tcx, &enum_definition.variants, item.def_id); + } + DefKind::Fn => {} // entirely within check_item_body + DefKind::Impl => { + let it = tcx.hir().item(id); + let hir::ItemKind::Impl(ref impl_) = it.kind else { + return; + }; + debug!("ItemKind::Impl {} with id {:?}", it.ident, it.def_id); + if let Some(impl_trait_ref) = tcx.impl_trait_ref(it.def_id) { + check_impl_items_against_trait( + tcx, + it.span, + it.def_id, + impl_trait_ref, + &impl_.items, + ); + check_on_unimplemented(tcx, it); + } + } + DefKind::Trait => { + let it = tcx.hir().item(id); + let hir::ItemKind::Trait(_, _, _, _, ref items) = it.kind else { + return; + }; + check_on_unimplemented(tcx, it); + + for item in items.iter() { + let item = tcx.hir().trait_item(item.id); + match item.kind { + hir::TraitItemKind::Fn(ref sig, _) => { + let abi = sig.header.abi; + fn_maybe_err(tcx, item.ident.span, abi); + } + hir::TraitItemKind::Type(.., Some(default)) => { + let assoc_item = tcx.associated_item(item.def_id); + let trait_substs = + InternalSubsts::identity_for_item(tcx, it.def_id.to_def_id()); + let _: Result<_, rustc_errors::ErrorGuaranteed> = check_type_bounds( + tcx, + assoc_item, + assoc_item, + default.span, + ty::TraitRef { def_id: it.def_id.to_def_id(), substs: trait_substs }, + ); + } + _ => {} + } + } + } + DefKind::Struct => { + check_struct(tcx, id.def_id); + } + DefKind::Union => { + check_union(tcx, id.def_id); + } + DefKind::OpaqueTy => { + let item = tcx.hir().item(id); + let hir::ItemKind::OpaqueTy(hir::OpaqueTy { origin, .. }) = item.kind else { + return; + }; + // HACK(jynelson): trying to infer the type of `impl trait` breaks documenting + // `async-std` (and `pub async fn` in general). + // Since rustdoc doesn't care about the concrete type behind `impl Trait`, just don't look at it! + // See https://github.com/rust-lang/rust/issues/75100 + if !tcx.sess.opts.actually_rustdoc { + let substs = InternalSubsts::identity_for_item(tcx, item.def_id.to_def_id()); + check_opaque(tcx, item.def_id, substs, &origin); + } + } + DefKind::TyAlias => { + let pty_ty = tcx.type_of(id.def_id); + let generics = tcx.generics_of(id.def_id); + check_type_params_are_used(tcx, &generics, pty_ty); + } + DefKind::ForeignMod => { + let it = tcx.hir().item(id); + let hir::ItemKind::ForeignMod { abi, items } = it.kind else { + return; + }; + check_abi(tcx, it.hir_id(), it.span, abi); + + if abi == Abi::RustIntrinsic { + for item in items { + let item = tcx.hir().foreign_item(item.id); + intrinsic::check_intrinsic_type(tcx, item); + } + } else if abi == Abi::PlatformIntrinsic { + for item in items { + let item = tcx.hir().foreign_item(item.id); + intrinsic::check_platform_intrinsic_type(tcx, item); + } + } else { + for item in items { + let def_id = item.id.def_id; + let generics = tcx.generics_of(def_id); + let own_counts = generics.own_counts(); + if generics.params.len() - own_counts.lifetimes != 0 { + let (kinds, kinds_pl, egs) = match (own_counts.types, own_counts.consts) { + (_, 0) => ("type", "types", Some("u32")), + // We don't specify an example value, because we can't generate + // a valid value for any type. + (0, _) => ("const", "consts", None), + _ => ("type or const", "types or consts", None), + }; + struct_span_err!( + tcx.sess, + item.span, + E0044, + "foreign items may not have {kinds} parameters", + ) + .span_label(item.span, &format!("can't have {kinds} parameters")) + .help( + // FIXME: once we start storing spans for type arguments, turn this + // into a suggestion. + &format!( + "replace the {} parameters with concrete {}{}", + kinds, + kinds_pl, + egs.map(|egs| format!(" like `{}`", egs)).unwrap_or_default(), + ), + ) + .emit(); + } + + let item = tcx.hir().foreign_item(item.id); + match item.kind { + hir::ForeignItemKind::Fn(ref fn_decl, _, _) => { + require_c_abi_if_c_variadic(tcx, fn_decl, abi, item.span); + } + hir::ForeignItemKind::Static(..) => { + check_static_inhabited(tcx, def_id); + } + _ => {} + } + } + } + } + DefKind::GlobalAsm => { + let it = tcx.hir().item(id); + let hir::ItemKind::GlobalAsm(asm) = it.kind else { span_bug!(it.span, "DefKind::GlobalAsm but got {:#?}", it) }; + InlineAsmCtxt::new_global_asm(tcx).check_asm(asm, id.hir_id()); + } + _ => {} + } +} + +pub(super) fn check_on_unimplemented(tcx: TyCtxt<'_>, item: &hir::Item<'_>) { + // an error would be reported if this fails. + let _ = traits::OnUnimplementedDirective::of_item(tcx, item.def_id.to_def_id()); +} + +pub(super) fn check_specialization_validity<'tcx>( + tcx: TyCtxt<'tcx>, + trait_def: &ty::TraitDef, + trait_item: &ty::AssocItem, + impl_id: DefId, + impl_item: &hir::ImplItemRef, +) { + let Ok(ancestors) = trait_def.ancestors(tcx, impl_id) else { return }; + let mut ancestor_impls = ancestors.skip(1).filter_map(|parent| { + if parent.is_from_trait() { + None + } else { + Some((parent, parent.item(tcx, trait_item.def_id))) + } + }); + + let opt_result = ancestor_impls.find_map(|(parent_impl, parent_item)| { + match parent_item { + // Parent impl exists, and contains the parent item we're trying to specialize, but + // doesn't mark it `default`. + Some(parent_item) if traits::impl_item_is_final(tcx, &parent_item) => { + Some(Err(parent_impl.def_id())) + } + + // Parent impl contains item and makes it specializable. + Some(_) => Some(Ok(())), + + // Parent impl doesn't mention the item. This means it's inherited from the + // grandparent. In that case, if parent is a `default impl`, inherited items use the + // "defaultness" from the grandparent, else they are final. + None => { + if tcx.impl_defaultness(parent_impl.def_id()).is_default() { + None + } else { + Some(Err(parent_impl.def_id())) + } + } + } + }); + + // If `opt_result` is `None`, we have only encountered `default impl`s that don't contain the + // item. This is allowed, the item isn't actually getting specialized here. + let result = opt_result.unwrap_or(Ok(())); + + if let Err(parent_impl) = result { + report_forbidden_specialization(tcx, impl_item, parent_impl); + } +} + +fn check_impl_items_against_trait<'tcx>( + tcx: TyCtxt<'tcx>, + full_impl_span: Span, + impl_id: LocalDefId, + impl_trait_ref: ty::TraitRef<'tcx>, + impl_item_refs: &[hir::ImplItemRef], +) { + // If the trait reference itself is erroneous (so the compilation is going + // to fail), skip checking the items here -- the `impl_item` table in `tcx` + // isn't populated for such impls. + if impl_trait_ref.references_error() { + return; + } + + // Negative impls are not expected to have any items + match tcx.impl_polarity(impl_id) { + ty::ImplPolarity::Reservation | ty::ImplPolarity::Positive => {} + ty::ImplPolarity::Negative => { + if let [first_item_ref, ..] = impl_item_refs { + let first_item_span = tcx.hir().impl_item(first_item_ref.id).span; + struct_span_err!( + tcx.sess, + first_item_span, + E0749, + "negative impls cannot have any items" + ) + .emit(); + } + return; + } + } + + let trait_def = tcx.trait_def(impl_trait_ref.def_id); + + for impl_item in impl_item_refs { + let ty_impl_item = tcx.associated_item(impl_item.id.def_id); + let ty_trait_item = if let Some(trait_item_id) = ty_impl_item.trait_item_def_id { + tcx.associated_item(trait_item_id) + } else { + // Checked in `associated_item`. + tcx.sess.delay_span_bug(impl_item.span, "missing associated item in trait"); + continue; + }; + let impl_item_full = tcx.hir().impl_item(impl_item.id); + match impl_item_full.kind { + hir::ImplItemKind::Const(..) => { + // Find associated const definition. + compare_const_impl( + tcx, + &ty_impl_item, + impl_item.span, + &ty_trait_item, + impl_trait_ref, + ); + } + hir::ImplItemKind::Fn(..) => { + let opt_trait_span = tcx.hir().span_if_local(ty_trait_item.def_id); + compare_impl_method( + tcx, + &ty_impl_item, + &ty_trait_item, + impl_trait_ref, + opt_trait_span, + ); + } + hir::ImplItemKind::TyAlias(impl_ty) => { + let opt_trait_span = tcx.hir().span_if_local(ty_trait_item.def_id); + compare_ty_impl( + tcx, + &ty_impl_item, + impl_ty.span, + &ty_trait_item, + impl_trait_ref, + opt_trait_span, + ); + } + } + + check_specialization_validity( + tcx, + trait_def, + &ty_trait_item, + impl_id.to_def_id(), + impl_item, + ); + } + + if let Ok(ancestors) = trait_def.ancestors(tcx, impl_id.to_def_id()) { + // Check for missing items from trait + let mut missing_items = Vec::new(); + + let mut must_implement_one_of: Option<&[Ident]> = + trait_def.must_implement_one_of.as_deref(); + + for &trait_item_id in tcx.associated_item_def_ids(impl_trait_ref.def_id) { + let is_implemented = ancestors + .leaf_def(tcx, trait_item_id) + .map_or(false, |node_item| node_item.item.defaultness(tcx).has_value()); + + if !is_implemented && tcx.impl_defaultness(impl_id).is_final() { + missing_items.push(tcx.associated_item(trait_item_id)); + } + + if let Some(required_items) = &must_implement_one_of { + // true if this item is specifically implemented in this impl + let is_implemented_here = ancestors + .leaf_def(tcx, trait_item_id) + .map_or(false, |node_item| !node_item.defining_node.is_from_trait()); + + if is_implemented_here { + let trait_item = tcx.associated_item(trait_item_id); + if required_items.contains(&trait_item.ident(tcx)) { + must_implement_one_of = None; + } + } + } + } + + if !missing_items.is_empty() { + missing_items_err(tcx, tcx.def_span(impl_id), &missing_items, full_impl_span); + } + + if let Some(missing_items) = must_implement_one_of { + let attr_span = tcx + .get_attr(impl_trait_ref.def_id, sym::rustc_must_implement_one_of) + .map(|attr| attr.span); + + missing_items_must_implement_one_of_err( + tcx, + tcx.def_span(impl_id), + missing_items, + attr_span, + ); + } + } +} + +/// Checks whether a type can be represented in memory. In particular, it +/// identifies types that contain themselves without indirection through a +/// pointer, which would mean their size is unbounded. +pub(super) fn check_representable(tcx: TyCtxt<'_>, sp: Span, item_def_id: LocalDefId) -> bool { + let rty = tcx.type_of(item_def_id); + + // Check that it is possible to represent this type. This call identifies + // (1) types that contain themselves and (2) types that contain a different + // recursive type. It is only necessary to throw an error on those that + // contain themselves. For case 2, there must be an inner type that will be + // caught by case 1. + match representability::ty_is_representable(tcx, rty, sp, None) { + Representability::SelfRecursive(spans) => { + recursive_type_with_infinite_size_error(tcx, item_def_id.to_def_id(), spans); + return false; + } + Representability::Representable | Representability::ContainsRecursive => (), + } + true +} + +pub fn check_simd(tcx: TyCtxt<'_>, sp: Span, def_id: LocalDefId) { + let t = tcx.type_of(def_id); + if let ty::Adt(def, substs) = t.kind() + && def.is_struct() + { + let fields = &def.non_enum_variant().fields; + if fields.is_empty() { + struct_span_err!(tcx.sess, sp, E0075, "SIMD vector cannot be empty").emit(); + return; + } + let e = fields[0].ty(tcx, substs); + if !fields.iter().all(|f| f.ty(tcx, substs) == e) { + struct_span_err!(tcx.sess, sp, E0076, "SIMD vector should be homogeneous") + .span_label(sp, "SIMD elements must have the same type") + .emit(); + return; + } + + let len = if let ty::Array(_ty, c) = e.kind() { + c.try_eval_usize(tcx, tcx.param_env(def.did())) + } else { + Some(fields.len() as u64) + }; + if let Some(len) = len { + if len == 0 { + struct_span_err!(tcx.sess, sp, E0075, "SIMD vector cannot be empty").emit(); + return; + } else if len > MAX_SIMD_LANES { + struct_span_err!( + tcx.sess, + sp, + E0075, + "SIMD vector cannot have more than {MAX_SIMD_LANES} elements", + ) + .emit(); + return; + } + } + + // Check that we use types valid for use in the lanes of a SIMD "vector register" + // These are scalar types which directly match a "machine" type + // Yes: Integers, floats, "thin" pointers + // No: char, "fat" pointers, compound types + match e.kind() { + ty::Param(_) => (), // pass struct<T>(T, T, T, T) through, let monomorphization catch errors + ty::Int(_) | ty::Uint(_) | ty::Float(_) | ty::RawPtr(_) => (), // struct(u8, u8, u8, u8) is ok + ty::Array(t, _) if matches!(t.kind(), ty::Param(_)) => (), // pass struct<T>([T; N]) through, let monomorphization catch errors + ty::Array(t, _clen) + if matches!( + t.kind(), + ty::Int(_) | ty::Uint(_) | ty::Float(_) | ty::RawPtr(_) + ) => + { /* struct([f32; 4]) is ok */ } + _ => { + struct_span_err!( + tcx.sess, + sp, + E0077, + "SIMD vector element type should be a \ + primitive scalar (integer/float/pointer) type" + ) + .emit(); + return; + } + } + } +} + +pub(super) fn check_packed(tcx: TyCtxt<'_>, sp: Span, def: ty::AdtDef<'_>) { + let repr = def.repr(); + if repr.packed() { + for attr in tcx.get_attrs(def.did(), sym::repr) { + for r in attr::parse_repr_attr(&tcx.sess, attr) { + if let attr::ReprPacked(pack) = r + && let Some(repr_pack) = repr.pack + && pack as u64 != repr_pack.bytes() + { + struct_span_err!( + tcx.sess, + sp, + E0634, + "type has conflicting packed representation hints" + ) + .emit(); + } + } + } + if repr.align.is_some() { + struct_span_err!( + tcx.sess, + sp, + E0587, + "type has conflicting packed and align representation hints" + ) + .emit(); + } else { + if let Some(def_spans) = check_packed_inner(tcx, def.did(), &mut vec![]) { + let mut err = struct_span_err!( + tcx.sess, + sp, + E0588, + "packed type cannot transitively contain a `#[repr(align)]` type" + ); + + err.span_note( + tcx.def_span(def_spans[0].0), + &format!( + "`{}` has a `#[repr(align)]` attribute", + tcx.item_name(def_spans[0].0) + ), + ); + + if def_spans.len() > 2 { + let mut first = true; + for (adt_def, span) in def_spans.iter().skip(1).rev() { + let ident = tcx.item_name(*adt_def); + err.span_note( + *span, + &if first { + format!( + "`{}` contains a field of type `{}`", + tcx.type_of(def.did()), + ident + ) + } else { + format!("...which contains a field of type `{ident}`") + }, + ); + first = false; + } + } + + err.emit(); + } + } + } +} + +pub(super) fn check_packed_inner( + tcx: TyCtxt<'_>, + def_id: DefId, + stack: &mut Vec<DefId>, +) -> Option<Vec<(DefId, Span)>> { + if let ty::Adt(def, substs) = tcx.type_of(def_id).kind() { + if def.is_struct() || def.is_union() { + if def.repr().align.is_some() { + return Some(vec![(def.did(), DUMMY_SP)]); + } + + stack.push(def_id); + for field in &def.non_enum_variant().fields { + if let ty::Adt(def, _) = field.ty(tcx, substs).kind() + && !stack.contains(&def.did()) + && let Some(mut defs) = check_packed_inner(tcx, def.did(), stack) + { + defs.push((def.did(), field.ident(tcx).span)); + return Some(defs); + } + } + stack.pop(); + } + } + + None +} + +pub(super) fn check_transparent<'tcx>(tcx: TyCtxt<'tcx>, sp: Span, adt: ty::AdtDef<'tcx>) { + if !adt.repr().transparent() { + return; + } + + if adt.is_union() && !tcx.features().transparent_unions { + feature_err( + &tcx.sess.parse_sess, + sym::transparent_unions, + sp, + "transparent unions are unstable", + ) + .emit(); + } + + if adt.variants().len() != 1 { + bad_variant_count(tcx, adt, sp, adt.did()); + if adt.variants().is_empty() { + // Don't bother checking the fields. No variants (and thus no fields) exist. + return; + } + } + + // For each field, figure out if it's known to be a ZST and align(1), with "known" + // respecting #[non_exhaustive] attributes. + let field_infos = adt.all_fields().map(|field| { + let ty = field.ty(tcx, InternalSubsts::identity_for_item(tcx, field.did)); + let param_env = tcx.param_env(field.did); + let layout = tcx.layout_of(param_env.and(ty)); + // We are currently checking the type this field came from, so it must be local + let span = tcx.hir().span_if_local(field.did).unwrap(); + let zst = layout.map_or(false, |layout| layout.is_zst()); + let align1 = layout.map_or(false, |layout| layout.align.abi.bytes() == 1); + if !zst { + return (span, zst, align1, None); + } + + fn check_non_exhaustive<'tcx>( + tcx: TyCtxt<'tcx>, + t: Ty<'tcx>, + ) -> ControlFlow<(&'static str, DefId, SubstsRef<'tcx>, bool)> { + match t.kind() { + ty::Tuple(list) => list.iter().try_for_each(|t| check_non_exhaustive(tcx, t)), + ty::Array(ty, _) => check_non_exhaustive(tcx, *ty), + ty::Adt(def, subst) => { + if !def.did().is_local() { + let non_exhaustive = def.is_variant_list_non_exhaustive() + || def + .variants() + .iter() + .any(ty::VariantDef::is_field_list_non_exhaustive); + let has_priv = def.all_fields().any(|f| !f.vis.is_public()); + if non_exhaustive || has_priv { + return ControlFlow::Break(( + def.descr(), + def.did(), + subst, + non_exhaustive, + )); + } + } + def.all_fields() + .map(|field| field.ty(tcx, subst)) + .try_for_each(|t| check_non_exhaustive(tcx, t)) + } + _ => ControlFlow::Continue(()), + } + } + + (span, zst, align1, check_non_exhaustive(tcx, ty).break_value()) + }); + + let non_zst_fields = field_infos + .clone() + .filter_map(|(span, zst, _align1, _non_exhaustive)| if !zst { Some(span) } else { None }); + let non_zst_count = non_zst_fields.clone().count(); + if non_zst_count >= 2 { + bad_non_zero_sized_fields(tcx, adt, non_zst_count, non_zst_fields, sp); + } + let incompatible_zst_fields = + field_infos.clone().filter(|(_, _, _, opt)| opt.is_some()).count(); + let incompat = incompatible_zst_fields + non_zst_count >= 2 && non_zst_count < 2; + for (span, zst, align1, non_exhaustive) in field_infos { + if zst && !align1 { + struct_span_err!( + tcx.sess, + span, + E0691, + "zero-sized field in transparent {} has alignment larger than 1", + adt.descr(), + ) + .span_label(span, "has alignment larger than 1") + .emit(); + } + if incompat && let Some((descr, def_id, substs, non_exhaustive)) = non_exhaustive { + tcx.struct_span_lint_hir( + REPR_TRANSPARENT_EXTERNAL_PRIVATE_FIELDS, + tcx.hir().local_def_id_to_hir_id(adt.did().expect_local()), + span, + |lint| { + let note = if non_exhaustive { + "is marked with `#[non_exhaustive]`" + } else { + "contains private fields" + }; + let field_ty = tcx.def_path_str_with_substs(def_id, substs); + lint.build("zero-sized fields in repr(transparent) cannot contain external non-exhaustive types") + .note(format!("this {descr} contains `{field_ty}`, which {note}, \ + and makes it not a breaking change to become non-zero-sized in the future.")) + .emit(); + }, + ) + } + } +} + +#[allow(trivial_numeric_casts)] +fn check_enum<'tcx>(tcx: TyCtxt<'tcx>, vs: &'tcx [hir::Variant<'tcx>], def_id: LocalDefId) { + let def = tcx.adt_def(def_id); + let sp = tcx.def_span(def_id); + def.destructor(tcx); // force the destructor to be evaluated + + if vs.is_empty() { + if let Some(attr) = tcx.get_attr(def_id.to_def_id(), sym::repr) { + struct_span_err!( + tcx.sess, + attr.span, + E0084, + "unsupported representation for zero-variant enum" + ) + .span_label(sp, "zero-variant enum") + .emit(); + } + } + + let repr_type_ty = def.repr().discr_type().to_ty(tcx); + if repr_type_ty == tcx.types.i128 || repr_type_ty == tcx.types.u128 { + if !tcx.features().repr128 { + feature_err( + &tcx.sess.parse_sess, + sym::repr128, + sp, + "repr with 128-bit type is unstable", + ) + .emit(); + } + } + + for v in vs { + if let Some(ref e) = v.disr_expr { + tcx.ensure().typeck(tcx.hir().local_def_id(e.hir_id)); + } + } + + if tcx.adt_def(def_id).repr().int.is_none() && tcx.features().arbitrary_enum_discriminant { + let is_unit = |var: &hir::Variant<'_>| matches!(var.data, hir::VariantData::Unit(..)); + + let has_disr = |var: &hir::Variant<'_>| var.disr_expr.is_some(); + let has_non_units = vs.iter().any(|var| !is_unit(var)); + let disr_units = vs.iter().any(|var| is_unit(&var) && has_disr(&var)); + let disr_non_unit = vs.iter().any(|var| !is_unit(&var) && has_disr(&var)); + + if disr_non_unit || (disr_units && has_non_units) { + let mut err = + struct_span_err!(tcx.sess, sp, E0732, "`#[repr(inttype)]` must be specified"); + err.emit(); + } + } + + let mut disr_vals: Vec<Discr<'tcx>> = Vec::with_capacity(vs.len()); + // This tracks the previous variant span (in the loop) incase we need it for diagnostics + let mut prev_variant_span: Span = DUMMY_SP; + for ((_, discr), v) in iter::zip(def.discriminants(tcx), vs) { + // Check for duplicate discriminant values + if let Some(i) = disr_vals.iter().position(|&x| x.val == discr.val) { + let variant_did = def.variant(VariantIdx::new(i)).def_id; + let variant_i_hir_id = tcx.hir().local_def_id_to_hir_id(variant_did.expect_local()); + let variant_i = tcx.hir().expect_variant(variant_i_hir_id); + let i_span = match variant_i.disr_expr { + Some(ref expr) => tcx.hir().span(expr.hir_id), + None => tcx.def_span(variant_did), + }; + let span = match v.disr_expr { + Some(ref expr) => tcx.hir().span(expr.hir_id), + None => v.span, + }; + let display_discr = format_discriminant_overflow(tcx, v, discr); + let display_discr_i = format_discriminant_overflow(tcx, variant_i, disr_vals[i]); + let no_disr = v.disr_expr.is_none(); + let mut err = struct_span_err!( + tcx.sess, + sp, + E0081, + "discriminant value `{}` assigned more than once", + discr, + ); + + err.span_label(i_span, format!("first assignment of {display_discr_i}")); + err.span_label(span, format!("second assignment of {display_discr}")); + + if no_disr { + err.span_label( + prev_variant_span, + format!( + "assigned discriminant for `{}` was incremented from this discriminant", + v.ident + ), + ); + } + err.emit(); + } + + disr_vals.push(discr); + prev_variant_span = v.span; + } + + check_representable(tcx, sp, def_id); + check_transparent(tcx, sp, def); +} + +/// In the case that a discriminant is both a duplicate and an overflowing literal, +/// we insert both the assigned discriminant and the literal it overflowed from into the formatted +/// output. Otherwise we format the discriminant normally. +fn format_discriminant_overflow<'tcx>( + tcx: TyCtxt<'tcx>, + variant: &hir::Variant<'_>, + dis: Discr<'tcx>, +) -> String { + if let Some(expr) = &variant.disr_expr { + let body = &tcx.hir().body(expr.body).value; + if let hir::ExprKind::Lit(lit) = &body.kind + && let rustc_ast::LitKind::Int(lit_value, _int_kind) = &lit.node + && dis.val != *lit_value + { + return format!("`{dis}` (overflowed from `{lit_value}`)"); + } + } + + format!("`{dis}`") +} + +pub(super) fn check_type_params_are_used<'tcx>( + tcx: TyCtxt<'tcx>, + generics: &ty::Generics, + ty: Ty<'tcx>, +) { + debug!("check_type_params_are_used(generics={:?}, ty={:?})", generics, ty); + + assert_eq!(generics.parent, None); + + if generics.own_counts().types == 0 { + return; + } + + let mut params_used = BitSet::new_empty(generics.params.len()); + + if ty.references_error() { + // If there is already another error, do not emit + // an error for not using a type parameter. + assert!(tcx.sess.has_errors().is_some()); + return; + } + + for leaf in ty.walk() { + if let GenericArgKind::Type(leaf_ty) = leaf.unpack() + && let ty::Param(param) = leaf_ty.kind() + { + debug!("found use of ty param {:?}", param); + params_used.insert(param.index); + } + } + + for param in &generics.params { + if !params_used.contains(param.index) + && let ty::GenericParamDefKind::Type { .. } = param.kind + { + let span = tcx.def_span(param.def_id); + struct_span_err!( + tcx.sess, + span, + E0091, + "type parameter `{}` is unused", + param.name, + ) + .span_label(span, "unused type parameter") + .emit(); + } + } +} + +pub(super) fn check_mod_item_types(tcx: TyCtxt<'_>, module_def_id: LocalDefId) { + let module = tcx.hir_module_items(module_def_id); + for id in module.items() { + check_item_type(tcx, id); + } +} + +fn async_opaque_type_cycle_error(tcx: TyCtxt<'_>, span: Span) -> ErrorGuaranteed { + struct_span_err!(tcx.sess, span, E0733, "recursion in an `async fn` requires boxing") + .span_label(span, "recursive `async fn`") + .note("a recursive `async fn` must be rewritten to return a boxed `dyn Future`") + .note( + "consider using the `async_recursion` crate: https://crates.io/crates/async_recursion", + ) + .emit() +} + +/// Emit an error for recursive opaque types. +/// +/// If this is a return `impl Trait`, find the item's return expressions and point at them. For +/// direct recursion this is enough, but for indirect recursion also point at the last intermediary +/// `impl Trait`. +/// +/// If all the return expressions evaluate to `!`, then we explain that the error will go away +/// after changing it. This can happen when a user uses `panic!()` or similar as a placeholder. +fn opaque_type_cycle_error(tcx: TyCtxt<'_>, def_id: LocalDefId, span: Span) -> ErrorGuaranteed { + let mut err = struct_span_err!(tcx.sess, span, E0720, "cannot resolve opaque type"); + + let mut label = false; + if let Some((def_id, visitor)) = get_owner_return_paths(tcx, def_id) { + let typeck_results = tcx.typeck(def_id); + if visitor + .returns + .iter() + .filter_map(|expr| typeck_results.node_type_opt(expr.hir_id)) + .all(|ty| matches!(ty.kind(), ty::Never)) + { + let spans = visitor + .returns + .iter() + .filter(|expr| typeck_results.node_type_opt(expr.hir_id).is_some()) + .map(|expr| expr.span) + .collect::<Vec<Span>>(); + let span_len = spans.len(); + if span_len == 1 { + err.span_label(spans[0], "this returned value is of `!` type"); + } else { + let mut multispan: MultiSpan = spans.clone().into(); + for span in spans { + multispan.push_span_label(span, "this returned value is of `!` type"); + } + err.span_note(multispan, "these returned values have a concrete \"never\" type"); + } + err.help("this error will resolve once the item's body returns a concrete type"); + } else { + let mut seen = FxHashSet::default(); + seen.insert(span); + err.span_label(span, "recursive opaque type"); + label = true; + for (sp, ty) in visitor + .returns + .iter() + .filter_map(|e| typeck_results.node_type_opt(e.hir_id).map(|t| (e.span, t))) + .filter(|(_, ty)| !matches!(ty.kind(), ty::Never)) + { + struct OpaqueTypeCollector(Vec<DefId>); + impl<'tcx> ty::visit::TypeVisitor<'tcx> for OpaqueTypeCollector { + fn visit_ty(&mut self, t: Ty<'tcx>) -> ControlFlow<Self::BreakTy> { + match *t.kind() { + ty::Opaque(def, _) => { + self.0.push(def); + ControlFlow::CONTINUE + } + _ => t.super_visit_with(self), + } + } + } + let mut visitor = OpaqueTypeCollector(vec![]); + ty.visit_with(&mut visitor); + for def_id in visitor.0 { + let ty_span = tcx.def_span(def_id); + if !seen.contains(&ty_span) { + err.span_label(ty_span, &format!("returning this opaque type `{ty}`")); + seen.insert(ty_span); + } + err.span_label(sp, &format!("returning here with type `{ty}`")); + } + } + } + } + if !label { + err.span_label(span, "cannot resolve opaque type"); + } + err.emit() +} |