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

 use crate::errors::DumpVTableEntries;
 use crate::traits::{impossible_predicates, is_vtable_safe_method};
 use rustc_hir::def_id::DefId;
 use rustc_hir::lang_items::LangItem;
 use rustc_infer::traits::util::PredicateSet;
 use rustc_infer::traits::ImplSource;
 use rustc_middle::ty::visit::TypeVisitableExt;
 use rustc_middle::ty::InternalSubsts;
 use rustc_middle::ty::{self, GenericParamDefKind, ToPredicate, Ty, TyCtxt, VtblEntry};
 use rustc_span::{sym, Span};
 use smallvec::SmallVec;

 use std::fmt::Debug;
 use std::ops::ControlFlow;

 #[derive(Clone, Debug)]
 pub(super) enum VtblSegment<'tcx> {
     MetadataDSA,
     TraitOwnEntries { trait_ref: ty::PolyTraitRef<'tcx>, emit_vptr: bool },
 }

 /// Prepare the segments for a vtable
 pub(super) fn prepare_vtable_segments<'tcx, T>(
     tcx: TyCtxt<'tcx>,
     trait_ref: ty::PolyTraitRef<'tcx>,
     mut segment_visitor: impl FnMut(VtblSegment<'tcx>) -> ControlFlow<T>,
 ) -> Option<T> {
     // The following constraints holds for the final arrangement.
     // 1. The whole virtual table of the first direct super trait is included as the
     //    the prefix. If this trait doesn't have any super traits, then this step
     //    consists of the dsa metadata.
     // 2. Then comes the proper pointer metadata(vptr) and all own methods for all
     //    other super traits except those already included as part of the first
     //    direct super trait virtual table.
     // 3. finally, the own methods of this trait.

     // This has the advantage that trait upcasting to the first direct super trait on each level
     // is zero cost, and to another trait includes only replacing the pointer with one level indirection,
     // while not using too much extra memory.

     // For a single inheritance relationship like this,
     //   D --> C --> B --> A
     // The resulting vtable will consists of these segments:
     //  DSA, A, B, C, D

     // For a multiple inheritance relationship like this,
     //   D --> C --> A
     //           \-> B
     // The resulting vtable will consists of these segments:
     //  DSA, A, B, B-vptr, C, D

     // For a diamond inheritance relationship like this,
     //   D --> B --> A
     //     \-> C -/
     // The resulting vtable will consists of these segments:
     //  DSA, A, B, C, C-vptr, D

     // For a more complex inheritance relationship like this:
     //   O --> G --> C --> A
     //     \     \     \-> B
     //     |     |-> F --> D
     //     |           \-> E
     //     |-> N --> J --> H
     //           \     \-> I
     //           |-> M --> K
     //                 \-> L
     // The resulting vtable will consists of these segments:
     //  DSA, A, B, B-vptr, C, D, D-vptr, E, E-vptr, F, F-vptr, G,
     //  H, H-vptr, I, I-vptr, J, J-vptr, K, K-vptr, L, L-vptr, M, M-vptr,
     //  N, N-vptr, O

     // emit dsa segment first.
     if let ControlFlow::Break(v) = (segment_visitor)(VtblSegment::MetadataDSA) {
         return Some(v);
     }

     let mut emit_vptr_on_new_entry = false;
     let mut visited = PredicateSet::new(tcx);
     let predicate = trait_ref.without_const().to_predicate(tcx);
     let mut stack: SmallVec<[(ty::PolyTraitRef<'tcx>, _, _); 5]> =
         smallvec![(trait_ref, emit_vptr_on_new_entry, None)];
     visited.insert(predicate);

     // the main traversal loop:
     // basically we want to cut the inheritance directed graph into a few non-overlapping slices of nodes
     // that each node is emitted after all its descendents have been emitted.
     // so we convert the directed graph into a tree by skipping all previously visited nodes using a visited set.
     // this is done on the fly.
     // Each loop run emits a slice - it starts by find a "childless" unvisited node, backtracking upwards, and it
     // stops after it finds a node that has a next-sibling node.
     // This next-sibling node will used as the starting point of next slice.

     // Example:
     // For a diamond inheritance relationship like this,
     //   D#1 --> B#0 --> A#0
     //     \-> C#1 -/

     // Starting point 0 stack [D]
     // Loop run #0: Stack after diving in is [D B A], A is "childless"
     // after this point, all newly visited nodes won't have a vtable that equals to a prefix of this one.
     // Loop run #0: Emitting the slice [B A] (in reverse order), B has a next-sibling node, so this slice stops here.
     // Loop run #0: Stack after exiting out is [D C], C is the next starting point.
     // Loop run #1: Stack after diving in is [D C], C is "childless", since its child A is skipped(already emitted).
     // Loop run #1: Emitting the slice [D C] (in reverse order). No one has a next-sibling node.
     // Loop run #1: Stack after exiting out is []. Now the function exits.

     loop {
         // dive deeper into the stack, recording the path
         'diving_in: loop {
             if let Some((inner_most_trait_ref, _, _)) = stack.last() {
                 let inner_most_trait_ref = *inner_most_trait_ref;
                 let mut direct_super_traits_iter = tcx
                     .super_predicates_of(inner_most_trait_ref.def_id())
                     .predicates
                     .into_iter()
                     .filter_map(move |(pred, _)| {
                         pred.subst_supertrait(tcx, &inner_most_trait_ref).to_opt_poly_trait_pred()
                     });

                 'diving_in_skip_visited_traits: loop {
                     if let Some(next_super_trait) = direct_super_traits_iter.next() {
                         if visited.insert(next_super_trait.to_predicate(tcx)) {
                             // We're throwing away potential constness of super traits here.
                             // FIXME: handle ~const super traits
                             let next_super_trait = next_super_trait.map_bound(|t| t.trait_ref);
                             stack.push((
                                 next_super_trait,
                                 emit_vptr_on_new_entry,
                                 Some(direct_super_traits_iter),
                             ));
                             break 'diving_in_skip_visited_traits;
                         } else {
                             continue 'diving_in_skip_visited_traits;
                         }
                     } else {
                         break 'diving_in;
                     }
                 }
             }
         }

         // Other than the left-most path, vptr should be emitted for each trait.
         emit_vptr_on_new_entry = true;

         // emit innermost item, move to next sibling and stop there if possible, otherwise jump to outer level.
         'exiting_out: loop {
             if let Some((inner_most_trait_ref, emit_vptr, siblings_opt)) = stack.last_mut() {
                 if let ControlFlow::Break(v) = (segment_visitor)(VtblSegment::TraitOwnEntries {
                     trait_ref: *inner_most_trait_ref,
                     emit_vptr: *emit_vptr,
                 }) {
                     return Some(v);
                 }

                 'exiting_out_skip_visited_traits: loop {
                     if let Some(siblings) = siblings_opt {
                         if let Some(next_inner_most_trait_ref) = siblings.next() {
                             if visited.insert(next_inner_most_trait_ref.to_predicate(tcx)) {
                                 // We're throwing away potential constness of super traits here.
                                 // FIXME: handle ~const super traits
                                 let next_inner_most_trait_ref =
                                     next_inner_most_trait_ref.map_bound(|t| t.trait_ref);
                                 *inner_most_trait_ref = next_inner_most_trait_ref;
                                 *emit_vptr = emit_vptr_on_new_entry;
                                 break 'exiting_out;
                             } else {
                                 continue 'exiting_out_skip_visited_traits;
                             }
                         }
                     }
                     stack.pop();
                     continue 'exiting_out;
                 }
             }
             // all done
             return None;
         }
     }
 }

 fn dump_vtable_entries<'tcx>(
     tcx: TyCtxt<'tcx>,
     sp: Span,
     trait_ref: ty::PolyTraitRef<'tcx>,
     entries: &[VtblEntry<'tcx>],
 ) {
     tcx.sess.emit_err(DumpVTableEntries {
         span: sp,
         trait_ref,
         entries: format!("{:#?}", entries),
     });
 }

 fn own_existential_vtable_entries(tcx: TyCtxt<'_>, trait_def_id: DefId) -> &[DefId] {
     let trait_methods = tcx
         .associated_items(trait_def_id)
         .in_definition_order()
         .filter(|item| item.kind == ty::AssocKind::Fn);
     // Now list each method's DefId (for within its trait).
     let own_entries = trait_methods.filter_map(move |&trait_method| {
         debug!("own_existential_vtable_entry: trait_method={:?}", trait_method);
         let def_id = trait_method.def_id;

         // Some methods cannot be called on an object; skip those.
         if !is_vtable_safe_method(tcx, trait_def_id, trait_method) {
             debug!("own_existential_vtable_entry: not vtable safe");
             return None;
         }

         Some(def_id)
     });

     tcx.arena.alloc_from_iter(own_entries.into_iter())
 }

 /// Given a trait `trait_ref`, iterates the vtable entries
 /// that come from `trait_ref`, including its supertraits.
 fn vtable_entries<'tcx>(
     tcx: TyCtxt<'tcx>,
     trait_ref: ty::PolyTraitRef<'tcx>,
 ) -> &'tcx [VtblEntry<'tcx>] {
     debug!("vtable_entries({:?})", trait_ref);

     let mut entries = vec![];

     let vtable_segment_callback = |segment| -> ControlFlow<()> {
         match segment {
             VtblSegment::MetadataDSA => {
                 entries.extend(TyCtxt::COMMON_VTABLE_ENTRIES);
             }
             VtblSegment::TraitOwnEntries { trait_ref, emit_vptr } => {
                 let existential_trait_ref = trait_ref
                     .map_bound(|trait_ref| ty::ExistentialTraitRef::erase_self_ty(tcx, trait_ref));

                 // Lookup the shape of vtable for the trait.
                 let own_existential_entries =
                     tcx.own_existential_vtable_entries(existential_trait_ref.def_id());

                 let own_entries = own_existential_entries.iter().copied().map(|def_id| {
                     debug!("vtable_entries: trait_method={:?}", def_id);

                     // The method may have some early-bound lifetimes; add regions for those.
                     let substs = trait_ref.map_bound(|trait_ref| {
                         InternalSubsts::for_item(tcx, def_id, |param, _| match param.kind {
                             GenericParamDefKind::Lifetime => tcx.lifetimes.re_erased.into(),
                             GenericParamDefKind::Type { .. }
                             | GenericParamDefKind::Const { .. } => {
                                 trait_ref.substs[param.index as usize]
                             }
                         })
                     });

                     // The trait type may have higher-ranked lifetimes in it;
                     // erase them if they appear, so that we get the type
                     // at some particular call site.
                     let substs = tcx
                         .normalize_erasing_late_bound_regions(ty::ParamEnv::reveal_all(), substs);

                     // It's possible that the method relies on where-clauses that
                     // do not hold for this particular set of type parameters.
                     // Note that this method could then never be called, so we
                     // do not want to try and codegen it, in that case (see #23435).
                     let predicates = tcx.predicates_of(def_id).instantiate_own(tcx, substs);
                     if impossible_predicates(
                         tcx,
                         predicates.map(|(predicate, _)| predicate).collect(),
                     ) {
                         debug!("vtable_entries: predicates do not hold");
                         return VtblEntry::Vacant;
                     }

                     let instance = ty::Instance::resolve_for_vtable(
                         tcx,
                         ty::ParamEnv::reveal_all(),
                         def_id,
                         substs,
                     )
                     .expect("resolution failed during building vtable representation");
                     VtblEntry::Method(instance)
                 });

                 entries.extend(own_entries);

                 if emit_vptr {
                     entries.push(VtblEntry::TraitVPtr(trait_ref));
                 }
             }
         }

         ControlFlow::Continue(())
     };

     let _ = prepare_vtable_segments(tcx, trait_ref, vtable_segment_callback);

     if tcx.has_attr(trait_ref.def_id(), sym::rustc_dump_vtable) {
         let sp = tcx.def_span(trait_ref.def_id());
         dump_vtable_entries(tcx, sp, trait_ref, &entries);
     }

     tcx.arena.alloc_from_iter(entries.into_iter())
 }

 /// Find slot base for trait methods within vtable entries of another trait
 pub(super) fn vtable_trait_first_method_offset<'tcx>(
     tcx: TyCtxt<'tcx>,
     key: (
         ty::PolyTraitRef<'tcx>, // trait_to_be_found
         ty::PolyTraitRef<'tcx>, // trait_owning_vtable
     ),
 ) -> usize {
     let (trait_to_be_found, trait_owning_vtable) = key;

     // #90177
     let trait_to_be_found_erased = tcx.erase_regions(trait_to_be_found);

     let vtable_segment_callback = {
         let mut vtable_base = 0;

         move |segment| {
             match segment {
                 VtblSegment::MetadataDSA => {
                     vtable_base += TyCtxt::COMMON_VTABLE_ENTRIES.len();
                 }
                 VtblSegment::TraitOwnEntries { trait_ref, emit_vptr } => {
                     if tcx.erase_regions(trait_ref) == trait_to_be_found_erased {
                         return ControlFlow::Break(vtable_base);
                     }
                     vtable_base += count_own_vtable_entries(tcx, trait_ref);
                     if emit_vptr {
                         vtable_base += 1;
                     }
                 }
             }
             ControlFlow::Continue(())
         }
     };

     if let Some(vtable_base) =
         prepare_vtable_segments(tcx, trait_owning_vtable, vtable_segment_callback)
     {
         vtable_base
     } else {
         bug!("Failed to find info for expected trait in vtable");
     }
 }

 /// Find slot offset for trait vptr within vtable entries of another trait
 pub(crate) fn vtable_trait_upcasting_coercion_new_vptr_slot<'tcx>(
     tcx: TyCtxt<'tcx>,
     key: (
         Ty<'tcx>, // trait object type whose trait owning vtable
         Ty<'tcx>, // trait object for supertrait
     ),
 ) -> Option<usize> {
     let (source, target) = key;
     assert!(matches!(&source.kind(), &ty::Dynamic(..)) && !source.needs_infer());
     assert!(matches!(&target.kind(), &ty::Dynamic(..)) && !target.needs_infer());

     // this has been typecked-before, so diagnostics is not really needed.
     let unsize_trait_did = tcx.require_lang_item(LangItem::Unsize, None);

     let trait_ref = tcx.mk_trait_ref(unsize_trait_did, [source, target]);

     match tcx.codegen_select_candidate((ty::ParamEnv::reveal_all(), ty::Binder::dummy(trait_ref))) {
         Ok(ImplSource::TraitUpcasting(implsrc_traitcasting)) => {
             implsrc_traitcasting.vtable_vptr_slot
         }
         otherwise => bug!("expected TraitUpcasting candidate, got {otherwise:?}"),
     }
 }

 /// Given a trait `trait_ref`, returns the number of vtable entries
 /// that come from `trait_ref`, excluding its supertraits. Used in
 /// computing the vtable base for an upcast trait of a trait object.
 pub(crate) fn count_own_vtable_entries<'tcx>(
     tcx: TyCtxt<'tcx>,
     trait_ref: ty::PolyTraitRef<'tcx>,
 ) -> usize {
     tcx.own_existential_vtable_entries(trait_ref.def_id()).len()
 }

 pub(super) fn provide(providers: &mut ty::query::Providers) {
     *providers = ty::query::Providers {
         own_existential_vtable_entries,
         vtable_entries,
         vtable_trait_upcasting_coercion_new_vptr_slot,
         ..*providers
     };
 }
	use crate::errors::DumpVTableEntries;
	use crate::traits::{impossible_predicates, is_vtable_safe_method};
	use rustc_hir::def_id::DefId;
	use rustc_hir::lang_items::LangItem;
	use rustc_infer::traits::util::PredicateSet;
	use rustc_infer::traits::ImplSource;
	use rustc_middle::ty::visit::TypeVisitableExt;
	use rustc_middle::ty::InternalSubsts;
	use rustc_middle::ty::{self, GenericParamDefKind, ToPredicate, Ty, TyCtxt, VtblEntry};
	use rustc_span::{sym, Span};
	use smallvec::SmallVec;

	use std::fmt::Debug;
	use std::ops::ControlFlow;

	#[derive(Clone, Debug)]
	pub(super) enum VtblSegment<'tcx> {
	MetadataDSA,
	TraitOwnEntries { trait_ref: ty::PolyTraitRef<'tcx>, emit_vptr: bool },
	}

	/// Prepare the segments for a vtable
	pub(super) fn prepare_vtable_segments<'tcx, T>(
	tcx: TyCtxt<'tcx>,
	trait_ref: ty::PolyTraitRef<'tcx>,
	mut segment_visitor: impl FnMut(VtblSegment<'tcx>) -> ControlFlow<T>,
	) -> Option<T> {
	// The following constraints holds for the final arrangement.
	// 1. The whole virtual table of the first direct super trait is included as the
	// the prefix. If this trait doesn't have any super traits, then this step
	// consists of the dsa metadata.
	// 2. Then comes the proper pointer metadata(vptr) and all own methods for all
	// other super traits except those already included as part of the first
	// direct super trait virtual table.
	// 3. finally, the own methods of this trait.

	// This has the advantage that trait upcasting to the first direct super trait on each level
	// is zero cost, and to another trait includes only replacing the pointer with one level indirection,
	// while not using too much extra memory.

	// For a single inheritance relationship like this,
	// D --> C --> B --> A
	// The resulting vtable will consists of these segments:
	// DSA, A, B, C, D

	// For a multiple inheritance relationship like this,
	// D --> C --> A
	// \-> B
	// The resulting vtable will consists of these segments:
	// DSA, A, B, B-vptr, C, D

	// For a diamond inheritance relationship like this,
	// D --> B --> A
	// \-> C -/
	// The resulting vtable will consists of these segments:
	// DSA, A, B, C, C-vptr, D

	// For a more complex inheritance relationship like this:
	// O --> G --> C --> A
	// \ \ \-> B
	// \| \|-> F --> D
	// \| \-> E
	// \|-> N --> J --> H
	// \ \-> I
	// \|-> M --> K
	// \-> L
	// The resulting vtable will consists of these segments:
	// DSA, A, B, B-vptr, C, D, D-vptr, E, E-vptr, F, F-vptr, G,
	// H, H-vptr, I, I-vptr, J, J-vptr, K, K-vptr, L, L-vptr, M, M-vptr,
	// N, N-vptr, O

	// emit dsa segment first.
	if let ControlFlow::Break(v) = (segment_visitor)(VtblSegment::MetadataDSA) {
	return Some(v);
	}

	let mut emit_vptr_on_new_entry = false;
	let mut visited = PredicateSet::new(tcx);
	let predicate = trait_ref.without_const().to_predicate(tcx);
	let mut stack: SmallVec<[(ty::PolyTraitRef<'tcx>, _, _); 5]> =
	smallvec![(trait_ref, emit_vptr_on_new_entry, None)];
	visited.insert(predicate);

	// the main traversal loop:
	// basically we want to cut the inheritance directed graph into a few non-overlapping slices of nodes
	// that each node is emitted after all its descendents have been emitted.
	// so we convert the directed graph into a tree by skipping all previously visited nodes using a visited set.
	// this is done on the fly.
	// Each loop run emits a slice - it starts by find a "childless" unvisited node, backtracking upwards, and it
	// stops after it finds a node that has a next-sibling node.
	// This next-sibling node will used as the starting point of next slice.

	// Example:
	// For a diamond inheritance relationship like this,
	// D#1 --> B#0 --> A#0
	// \-> C#1 -/

	// Starting point 0 stack [D]
	// Loop run #0: Stack after diving in is [D B A], A is "childless"
	// after this point, all newly visited nodes won't have a vtable that equals to a prefix of this one.
	// Loop run #0: Emitting the slice [B A] (in reverse order), B has a next-sibling node, so this slice stops here.
	// Loop run #0: Stack after exiting out is [D C], C is the next starting point.
	// Loop run #1: Stack after diving in is [D C], C is "childless", since its child A is skipped(already emitted).
	// Loop run #1: Emitting the slice [D C] (in reverse order). No one has a next-sibling node.
	// Loop run #1: Stack after exiting out is []. Now the function exits.

	loop {
	// dive deeper into the stack, recording the path
	'diving_in: loop {
	if let Some((inner_most_trait_ref, _, _)) = stack.last() {
	let inner_most_trait_ref = *inner_most_trait_ref;
	let mut direct_super_traits_iter = tcx
	.super_predicates_of(inner_most_trait_ref.def_id())
	.predicates
	.into_iter()
	.filter_map(move \|(pred, _)\| {
	pred.subst_supertrait(tcx, &inner_most_trait_ref).to_opt_poly_trait_pred()
	});

	'diving_in_skip_visited_traits: loop {
	if let Some(next_super_trait) = direct_super_traits_iter.next() {
	if visited.insert(next_super_trait.to_predicate(tcx)) {
	// We're throwing away potential constness of super traits here.
	// FIXME: handle ~const super traits
	let next_super_trait = next_super_trait.map_bound(\|t\| t.trait_ref);
	stack.push((
	next_super_trait,
	emit_vptr_on_new_entry,
	Some(direct_super_traits_iter),
	));
	break 'diving_in_skip_visited_traits;
	} else {
	continue 'diving_in_skip_visited_traits;
	}
	} else {
	break 'diving_in;
	}
	}
	}
	}

	// Other than the left-most path, vptr should be emitted for each trait.
	emit_vptr_on_new_entry = true;

	// emit innermost item, move to next sibling and stop there if possible, otherwise jump to outer level.
	'exiting_out: loop {
	if let Some((inner_most_trait_ref, emit_vptr, siblings_opt)) = stack.last_mut() {
	if let ControlFlow::Break(v) = (segment_visitor)(VtblSegment::TraitOwnEntries {
	trait_ref: *inner_most_trait_ref,
	emit_vptr: *emit_vptr,
	}) {
	return Some(v);
	}

	'exiting_out_skip_visited_traits: loop {
	if let Some(siblings) = siblings_opt {
	if let Some(next_inner_most_trait_ref) = siblings.next() {
	if visited.insert(next_inner_most_trait_ref.to_predicate(tcx)) {
	// We're throwing away potential constness of super traits here.
	// FIXME: handle ~const super traits
	let next_inner_most_trait_ref =
	next_inner_most_trait_ref.map_bound(\|t\| t.trait_ref);
	*inner_most_trait_ref = next_inner_most_trait_ref;
	*emit_vptr = emit_vptr_on_new_entry;
	break 'exiting_out;
	} else {
	continue 'exiting_out_skip_visited_traits;
	}
	}
	}
	stack.pop();
	continue 'exiting_out;
	}
	}
	// all done
	return None;
	}
	}
	}

	fn dump_vtable_entries<'tcx>(
	tcx: TyCtxt<'tcx>,
	sp: Span,
	trait_ref: ty::PolyTraitRef<'tcx>,
	entries: &[VtblEntry<'tcx>],
	) {
	tcx.sess.emit_err(DumpVTableEntries {
	span: sp,
	trait_ref,
	entries: format!("{:#?}", entries),
	});
	}

	fn own_existential_vtable_entries(tcx: TyCtxt<'_>, trait_def_id: DefId) -> &[DefId] {
	let trait_methods = tcx
	.associated_items(trait_def_id)
	.in_definition_order()
	.filter(\|item\| item.kind == ty::AssocKind::Fn);
	// Now list each method's DefId (for within its trait).
	let own_entries = trait_methods.filter_map(move \|&trait_method\| {
	debug!("own_existential_vtable_entry: trait_method={:?}", trait_method);
	let def_id = trait_method.def_id;

	// Some methods cannot be called on an object; skip those.
	if !is_vtable_safe_method(tcx, trait_def_id, trait_method) {
	debug!("own_existential_vtable_entry: not vtable safe");
	return None;
	}

	Some(def_id)
	});

	tcx.arena.alloc_from_iter(own_entries.into_iter())
	}

	/// Given a trait `trait_ref`, iterates the vtable entries
	/// that come from `trait_ref`, including its supertraits.
	fn vtable_entries<'tcx>(
	tcx: TyCtxt<'tcx>,
	trait_ref: ty::PolyTraitRef<'tcx>,
	) -> &'tcx [VtblEntry<'tcx>] {
	debug!("vtable_entries({:?})", trait_ref);

	let mut entries = vec![];

	let vtable_segment_callback = \|segment\| -> ControlFlow<()> {
	match segment {
	VtblSegment::MetadataDSA => {
	entries.extend(TyCtxt::COMMON_VTABLE_ENTRIES);
	}
	VtblSegment::TraitOwnEntries { trait_ref, emit_vptr } => {
	let existential_trait_ref = trait_ref
	.map_bound(\|trait_ref\| ty::ExistentialTraitRef::erase_self_ty(tcx, trait_ref));

	// Lookup the shape of vtable for the trait.
	let own_existential_entries =
	tcx.own_existential_vtable_entries(existential_trait_ref.def_id());

	let own_entries = own_existential_entries.iter().copied().map(\|def_id\| {
	debug!("vtable_entries: trait_method={:?}", def_id);

	// The method may have some early-bound lifetimes; add regions for those.
	let substs = trait_ref.map_bound(\|trait_ref\| {
	InternalSubsts::for_item(tcx, def_id, \|param, _\| match param.kind {
	GenericParamDefKind::Lifetime => tcx.lifetimes.re_erased.into(),
	GenericParamDefKind::Type { .. }
	\| GenericParamDefKind::Const { .. } => {
	trait_ref.substs[param.index as usize]
	}
	})
	});

	// The trait type may have higher-ranked lifetimes in it;
	// erase them if they appear, so that we get the type
	// at some particular call site.
	let substs = tcx
	.normalize_erasing_late_bound_regions(ty::ParamEnv::reveal_all(), substs);

	// It's possible that the method relies on where-clauses that
	// do not hold for this particular set of type parameters.
	// Note that this method could then never be called, so we
	// do not want to try and codegen it, in that case (see #23435).
	let predicates = tcx.predicates_of(def_id).instantiate_own(tcx, substs);
	if impossible_predicates(
	tcx,
	predicates.map(\|(predicate, _)\| predicate).collect(),
	) {
	debug!("vtable_entries: predicates do not hold");
	return VtblEntry::Vacant;
	}

	let instance = ty::Instance::resolve_for_vtable(
	tcx,
	ty::ParamEnv::reveal_all(),
	def_id,
	substs,
	)
	.expect("resolution failed during building vtable representation");
	VtblEntry::Method(instance)
	});

	entries.extend(own_entries);

	if emit_vptr {
	entries.push(VtblEntry::TraitVPtr(trait_ref));
	}
	}
	}

	ControlFlow::Continue(())
	};

	let _ = prepare_vtable_segments(tcx, trait_ref, vtable_segment_callback);

	if tcx.has_attr(trait_ref.def_id(), sym::rustc_dump_vtable) {
	let sp = tcx.def_span(trait_ref.def_id());
	dump_vtable_entries(tcx, sp, trait_ref, &entries);
	}

	tcx.arena.alloc_from_iter(entries.into_iter())
	}

	/// Find slot base for trait methods within vtable entries of another trait
	pub(super) fn vtable_trait_first_method_offset<'tcx>(
	tcx: TyCtxt<'tcx>,
	key: (
	ty::PolyTraitRef<'tcx>, // trait_to_be_found
	ty::PolyTraitRef<'tcx>, // trait_owning_vtable
	),
	) -> usize {
	let (trait_to_be_found, trait_owning_vtable) = key;

	// #90177
	let trait_to_be_found_erased = tcx.erase_regions(trait_to_be_found);

	let vtable_segment_callback = {
	let mut vtable_base = 0;

	move \|segment\| {
	match segment {
	VtblSegment::MetadataDSA => {
	vtable_base += TyCtxt::COMMON_VTABLE_ENTRIES.len();
	}
	VtblSegment::TraitOwnEntries { trait_ref, emit_vptr } => {
	if tcx.erase_regions(trait_ref) == trait_to_be_found_erased {
	return ControlFlow::Break(vtable_base);
	}
	vtable_base += count_own_vtable_entries(tcx, trait_ref);
	if emit_vptr {
	vtable_base += 1;
	}
	}
	}
	ControlFlow::Continue(())
	}
	};

	if let Some(vtable_base) =
	prepare_vtable_segments(tcx, trait_owning_vtable, vtable_segment_callback)
	{
	vtable_base
	} else {
	bug!("Failed to find info for expected trait in vtable");
	}
	}

	/// Find slot offset for trait vptr within vtable entries of another trait
	pub(crate) fn vtable_trait_upcasting_coercion_new_vptr_slot<'tcx>(
	tcx: TyCtxt<'tcx>,
	key: (
	Ty<'tcx>, // trait object type whose trait owning vtable
	Ty<'tcx>, // trait object for supertrait
	),
	) -> Option<usize> {
	let (source, target) = key;
	assert!(matches!(&source.kind(), &ty::Dynamic(..)) && !source.needs_infer());
	assert!(matches!(&target.kind(), &ty::Dynamic(..)) && !target.needs_infer());

	// this has been typecked-before, so diagnostics is not really needed.
	let unsize_trait_did = tcx.require_lang_item(LangItem::Unsize, None);

	let trait_ref = tcx.mk_trait_ref(unsize_trait_did, [source, target]);

	match tcx.codegen_select_candidate((ty::ParamEnv::reveal_all(), ty::Binder::dummy(trait_ref))) {
	Ok(ImplSource::TraitUpcasting(implsrc_traitcasting)) => {
	implsrc_traitcasting.vtable_vptr_slot
	}
	otherwise => bug!("expected TraitUpcasting candidate, got {otherwise:?}"),
	}
	}

	/// Given a trait `trait_ref`, returns the number of vtable entries
	/// that come from `trait_ref`, excluding its supertraits. Used in
	/// computing the vtable base for an upcast trait of a trait object.
	pub(crate) fn count_own_vtable_entries<'tcx>(
	tcx: TyCtxt<'tcx>,
	trait_ref: ty::PolyTraitRef<'tcx>,
	) -> usize {
	tcx.own_existential_vtable_entries(trait_ref.def_id()).len()
	}

	pub(super) fn provide(providers: &mut ty::query::Providers) {
	*providers = ty::query::Providers {
	own_existential_vtable_entries,
	vtable_entries,
	vtable_trait_upcasting_coercion_new_vptr_slot,
	..*providers
	};
	}