use rustc_errors::ErrorGuaranteed; use rustc_hir::def_id::DefId; use rustc_hir::LangItem; use rustc_infer::infer::TyCtxtInferExt; use rustc_middle::bug; use rustc_middle::query::Providers; use rustc_middle::traits::{BuiltinImplSource, CodegenObligationError}; use rustc_middle::ty::util::AsyncDropGlueMorphology; use rustc_middle::ty::{self, GenericArgsRef, Instance, TyCtxt, TypeVisitableExt}; use rustc_span::sym; use rustc_trait_selection::traits; use rustc_type_ir::ClosureKind; use tracing::debug; use traits::{translate_args, Reveal}; use crate::errors::UnexpectedFnPtrAssociatedItem; fn resolve_instance_raw<'tcx>( tcx: TyCtxt<'tcx>, key: ty::ParamEnvAnd<'tcx, (DefId, GenericArgsRef<'tcx>)>, ) -> Result>, ErrorGuaranteed> { let (param_env, (def_id, args)) = key.into_parts(); let result = if let Some(trait_def_id) = tcx.trait_of_item(def_id) { debug!(" => associated item, attempting to find impl in param_env {:#?}", param_env); resolve_associated_item( tcx, def_id, param_env, trait_def_id, tcx.normalize_erasing_regions(param_env, args), ) } else { let def = if tcx.intrinsic(def_id).is_some() { debug!(" => intrinsic"); ty::InstanceKind::Intrinsic(def_id) } else if tcx.is_lang_item(def_id, LangItem::DropInPlace) { let ty = args.type_at(0); if ty.needs_drop(tcx, param_env) { debug!(" => nontrivial drop glue"); match *ty.kind() { ty::Closure(..) | ty::CoroutineClosure(..) | ty::Coroutine(..) | ty::Tuple(..) | ty::Adt(..) | ty::Dynamic(..) | ty::Array(..) | ty::Slice(..) => {} // Drop shims can only be built from ADTs. _ => return Ok(None), } ty::InstanceKind::DropGlue(def_id, Some(ty)) } else { debug!(" => trivial drop glue"); ty::InstanceKind::DropGlue(def_id, None) } } else if tcx.is_lang_item(def_id, LangItem::AsyncDropInPlace) { let ty = args.type_at(0); if ty.async_drop_glue_morphology(tcx) != AsyncDropGlueMorphology::Noop { match *ty.kind() { ty::Closure(..) | ty::CoroutineClosure(..) | ty::Coroutine(..) | ty::Tuple(..) | ty::Adt(..) | ty::Dynamic(..) | ty::Array(..) | ty::Slice(..) => {} // Async destructor ctor shims can only be built from ADTs. _ => return Ok(None), } debug!(" => nontrivial async drop glue ctor"); ty::InstanceKind::AsyncDropGlueCtorShim(def_id, Some(ty)) } else { debug!(" => trivial async drop glue ctor"); ty::InstanceKind::AsyncDropGlueCtorShim(def_id, None) } } else { debug!(" => free item"); // FIXME(effects): we may want to erase the effect param if that is present on this item. ty::InstanceKind::Item(def_id) }; Ok(Some(Instance { def, args })) }; debug!("resolve_instance: result={:?}", result); result } fn resolve_associated_item<'tcx>( tcx: TyCtxt<'tcx>, trait_item_id: DefId, param_env: ty::ParamEnv<'tcx>, trait_id: DefId, rcvr_args: GenericArgsRef<'tcx>, ) -> Result>, ErrorGuaranteed> { debug!(?trait_item_id, ?param_env, ?trait_id, ?rcvr_args, "resolve_associated_item"); let trait_ref = ty::TraitRef::from_method(tcx, trait_id, rcvr_args); let vtbl = match tcx.codegen_select_candidate((param_env, trait_ref)) { Ok(vtbl) => vtbl, Err( CodegenObligationError::Ambiguity | CodegenObligationError::Unimplemented | CodegenObligationError::FulfillmentError, ) => return Ok(None), }; // Now that we know which impl is being used, we can dispatch to // the actual function: Ok(match vtbl { traits::ImplSource::UserDefined(impl_data) => { debug!( "resolving ImplSource::UserDefined: {:?}, {:?}, {:?}, {:?}", param_env, trait_item_id, rcvr_args, impl_data ); assert!(!rcvr_args.has_infer()); assert!(!trait_ref.has_infer()); let trait_def_id = tcx.trait_id_of_impl(impl_data.impl_def_id).unwrap(); let trait_def = tcx.trait_def(trait_def_id); let leaf_def = trait_def .ancestors(tcx, impl_data.impl_def_id)? .leaf_def(tcx, trait_item_id) .unwrap_or_else(|| { bug!("{:?} not found in {:?}", trait_item_id, impl_data.impl_def_id); }); let infcx = tcx.infer_ctxt().build(); let param_env = param_env.with_reveal_all_normalized(tcx); let args = rcvr_args.rebase_onto(tcx, trait_def_id, impl_data.args); let args = translate_args( &infcx, param_env, impl_data.impl_def_id, args, leaf_def.defining_node, ); let args = infcx.tcx.erase_regions(args); // Since this is a trait item, we need to see if the item is either a trait default item // or a specialization because we can't resolve those unless we can `Reveal::All`. // NOTE: This should be kept in sync with the similar code in // `rustc_trait_selection::traits::project::assemble_candidates_from_impls()`. let eligible = if leaf_def.is_final() { // Non-specializable items are always projectable. true } else { // Only reveal a specializable default if we're past type-checking // and the obligation is monomorphic, otherwise passes such as // transmute checking and polymorphic MIR optimizations could // get a result which isn't correct for all monomorphizations. if param_env.reveal() == Reveal::All { !trait_ref.still_further_specializable() } else { false } }; if !eligible { return Ok(None); } // HACK: We may have overlapping `dyn Trait` built-in impls and // user-provided blanket impls. Detect that case here, and return // ambiguity. // // This should not affect totally monomorphized contexts, only // resolve calls that happen polymorphically, such as the mir-inliner // and const-prop (and also some lints). let self_ty = rcvr_args.type_at(0); if !self_ty.is_known_rigid() { let predicates = tcx .predicates_of(impl_data.impl_def_id) .instantiate(tcx, impl_data.args) .predicates; let sized_def_id = tcx.lang_items().sized_trait(); // If we find a `Self: Sized` bound on the item, then we know // that `dyn Trait` can certainly never apply here. if !predicates.into_iter().filter_map(ty::Clause::as_trait_clause).any(|clause| { Some(clause.def_id()) == sized_def_id && clause.skip_binder().self_ty() == self_ty }) { return Ok(None); } } // Any final impl is required to define all associated items. if !leaf_def.item.defaultness(tcx).has_value() { let guar = tcx.dcx().span_delayed_bug( tcx.def_span(leaf_def.item.def_id), "missing value for assoc item in impl", ); return Err(guar); } // Make sure that we're projecting to an item that has compatible args. // This may happen if we are resolving an instance before codegen, such // as during inlining. This check is also done in projection. if !tcx.check_args_compatible(leaf_def.item.def_id, args) { let guar = tcx.dcx().span_delayed_bug( tcx.def_span(leaf_def.item.def_id), "missing value for assoc item in impl", ); return Err(guar); } let args = tcx.erase_regions(args); // Check if we just resolved an associated `const` declaration from // a `trait` to an associated `const` definition in an `impl`, where // the definition in the `impl` has the wrong type (for which an // error has already been/will be emitted elsewhere). if leaf_def.item.kind == ty::AssocKind::Const && trait_item_id != leaf_def.item.def_id && let Some(leaf_def_item) = leaf_def.item.def_id.as_local() { tcx.compare_impl_const((leaf_def_item, trait_item_id))?; } Some(ty::Instance::new(leaf_def.item.def_id, args)) } traits::ImplSource::Builtin(BuiltinImplSource::Object(_), _) => { let trait_ref = ty::TraitRef::from_method(tcx, trait_id, rcvr_args); if trait_ref.has_non_region_infer() || trait_ref.has_non_region_param() { // We only resolve totally substituted vtable entries. None } else { let vtable_base = tcx.first_method_vtable_slot(trait_ref); let offset = tcx .own_existential_vtable_entries(trait_id) .iter() .copied() .position(|def_id| def_id == trait_item_id); offset.map(|offset| Instance { def: ty::InstanceKind::Virtual(trait_item_id, vtable_base + offset), args: rcvr_args, }) } } traits::ImplSource::Builtin(BuiltinImplSource::Misc, _) => { if tcx.is_lang_item(trait_ref.def_id, LangItem::Clone) { // FIXME(eddyb) use lang items for methods instead of names. let name = tcx.item_name(trait_item_id); if name == sym::clone { let self_ty = trait_ref.self_ty(); match self_ty.kind() { ty::FnDef(..) | ty::FnPtr(..) => (), ty::Coroutine(..) | ty::CoroutineWitness(..) | ty::Closure(..) | ty::CoroutineClosure(..) | ty::Tuple(..) => {} _ => return Ok(None), }; Some(Instance { def: ty::InstanceKind::CloneShim(trait_item_id, self_ty), args: rcvr_args, }) } else { assert_eq!(name, sym::clone_from); // Use the default `fn clone_from` from `trait Clone`. let args = tcx.erase_regions(rcvr_args); Some(ty::Instance::new(trait_item_id, args)) } } else if tcx.is_lang_item(trait_ref.def_id, LangItem::FnPtrTrait) { if tcx.is_lang_item(trait_item_id, LangItem::FnPtrAddr) { let self_ty = trait_ref.self_ty(); if !matches!(self_ty.kind(), ty::FnPtr(..)) { return Ok(None); } Some(Instance { def: ty::InstanceKind::FnPtrAddrShim(trait_item_id, self_ty), args: rcvr_args, }) } else { tcx.dcx().emit_fatal(UnexpectedFnPtrAssociatedItem { span: tcx.def_span(trait_item_id), }) } } else if let Some(target_kind) = tcx.fn_trait_kind_from_def_id(trait_ref.def_id) { // FIXME: This doesn't check for malformed libcore that defines, e.g., // `trait Fn { fn call_once(&self) { .. } }`. This is mostly for extension // methods. if cfg!(debug_assertions) && ![sym::call, sym::call_mut, sym::call_once] .contains(&tcx.item_name(trait_item_id)) { // For compiler developers who'd like to add new items to `Fn`/`FnMut`/`FnOnce`, // you either need to generate a shim body, or perhaps return // `InstanceKind::Item` pointing to a trait default method body if // it is given a default implementation by the trait. bug!( "no definition for `{trait_ref}::{}` for built-in callable type", tcx.item_name(trait_item_id) ) } match *rcvr_args.type_at(0).kind() { ty::Closure(closure_def_id, args) => { Some(Instance::resolve_closure(tcx, closure_def_id, args, target_kind)) } ty::FnDef(..) | ty::FnPtr(..) => Some(Instance { def: ty::InstanceKind::FnPtrShim(trait_item_id, rcvr_args.type_at(0)), args: rcvr_args, }), ty::CoroutineClosure(coroutine_closure_def_id, args) => { // When a coroutine-closure implements the `Fn` traits, then it // always dispatches to the `FnOnce` implementation. This is to // ensure that the `closure_kind` of the resulting closure is in // sync with the built-in trait implementations (since all of the // implementations return `FnOnce::Output`). if ty::ClosureKind::FnOnce == args.as_coroutine_closure().kind() { Some(Instance::new(coroutine_closure_def_id, args)) } else { Some(Instance { def: ty::InstanceKind::ConstructCoroutineInClosureShim { coroutine_closure_def_id, receiver_by_ref: target_kind != ty::ClosureKind::FnOnce, }, args, }) } } _ => bug!( "no built-in definition for `{trait_ref}::{}` for non-fn type", tcx.item_name(trait_item_id) ), } } else if let Some(target_kind) = tcx.async_fn_trait_kind_from_def_id(trait_ref.def_id) { match *rcvr_args.type_at(0).kind() { ty::CoroutineClosure(coroutine_closure_def_id, args) => { if target_kind == ClosureKind::FnOnce && args.as_coroutine_closure().kind() != ClosureKind::FnOnce { // If we're computing `AsyncFnOnce` for a by-ref closure then // construct a new body that has the right return types. Some(Instance { def: ty::InstanceKind::ConstructCoroutineInClosureShim { coroutine_closure_def_id, receiver_by_ref: false, }, args, }) } else { Some(Instance::new(coroutine_closure_def_id, args)) } } ty::Closure(closure_def_id, args) => { Some(Instance::resolve_closure(tcx, closure_def_id, args, target_kind)) } ty::FnDef(..) | ty::FnPtr(..) => Some(Instance { def: ty::InstanceKind::FnPtrShim(trait_item_id, rcvr_args.type_at(0)), args: rcvr_args, }), _ => bug!( "no built-in definition for `{trait_ref}::{}` for non-lending-closure type", tcx.item_name(trait_item_id) ), } } else { Instance::try_resolve_item_for_coroutine(tcx, trait_item_id, trait_id, rcvr_args) } } traits::ImplSource::Param(..) | traits::ImplSource::Builtin(BuiltinImplSource::TraitUpcasting { .. }, _) | traits::ImplSource::Builtin(BuiltinImplSource::TupleUnsizing, _) => None, }) } pub(crate) fn provide(providers: &mut Providers) { *providers = Providers { resolve_instance_raw, ..*providers }; }