compiler/rustc_middle/src/ty/vtable.rs - rust-lang/rust - Git at Google

 use std::fmt;

 use rustc_ast::Mutability;
 use rustc_macros::HashStable;
 use rustc_type_ir::elaborate;

 use crate::mir::interpret::{
     AllocId, AllocInit, Allocation, CTFE_ALLOC_SALT, Pointer, Scalar, alloc_range,
 };
 use crate::ty::{self, Instance, TraitRef, Ty, TyCtxt};

 #[derive(Clone, Copy, PartialEq, HashStable)]
 pub enum VtblEntry<'tcx> {
     /// destructor of this type (used in vtable header)
     MetadataDropInPlace,
     /// layout size of this type (used in vtable header)
     MetadataSize,
     /// layout align of this type (used in vtable header)
     MetadataAlign,
     /// non-dispatchable associated function that is excluded from trait object
     Vacant,
     /// dispatchable associated function
     Method(Instance<'tcx>),
     /// pointer to a separate supertrait vtable, can be used by trait upcasting coercion
     TraitVPtr(TraitRef<'tcx>),
 }

 impl<'tcx> fmt::Debug for VtblEntry<'tcx> {
     fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
         // We want to call `Display` on `Instance` and `PolyTraitRef`,
         // so we implement this manually.
         match self {
             VtblEntry::MetadataDropInPlace => write!(f, "MetadataDropInPlace"),
             VtblEntry::MetadataSize => write!(f, "MetadataSize"),
             VtblEntry::MetadataAlign => write!(f, "MetadataAlign"),
             VtblEntry::Vacant => write!(f, "Vacant"),
             VtblEntry::Method(instance) => write!(f, "Method({instance})"),
             VtblEntry::TraitVPtr(trait_ref) => write!(f, "TraitVPtr({trait_ref})"),
         }
     }
 }

 // Needs to be associated with the `'tcx` lifetime
 impl<'tcx> TyCtxt<'tcx> {
     pub const COMMON_VTABLE_ENTRIES: &'tcx [VtblEntry<'tcx>] =
         &[VtblEntry::MetadataDropInPlace, VtblEntry::MetadataSize, VtblEntry::MetadataAlign];
 }

 pub const COMMON_VTABLE_ENTRIES_DROPINPLACE: usize = 0;
 pub const COMMON_VTABLE_ENTRIES_SIZE: usize = 1;
 pub const COMMON_VTABLE_ENTRIES_ALIGN: usize = 2;

 // Note that we don't have access to a self type here, this has to be purely based on the trait (and
 // supertrait) definitions. That means we can't call into the same vtable_entries code since that
 // returns a specific instantiation (e.g., with Vacant slots when bounds aren't satisfied). The goal
 // here is to do a best-effort approximation without duplicating a lot of code.
 //
 // This function is used in layout computation for e.g. &dyn Trait, so it's critical that this
 // function is an accurate approximation. We verify this when actually computing the vtable below.
 pub(crate) fn vtable_min_entries<'tcx>(
     tcx: TyCtxt<'tcx>,
     trait_ref: Option<ty::ExistentialTraitRef<'tcx>>,
 ) -> usize {
     let mut count = TyCtxt::COMMON_VTABLE_ENTRIES.len();
     let Some(trait_ref) = trait_ref else {
         return count;
     };

     // This includes self in supertraits.
     for def_id in elaborate::supertrait_def_ids(tcx, trait_ref.def_id) {
         count += tcx.own_existential_vtable_entries(def_id).len();
     }

     count
 }

 /// Retrieves an allocation that represents the contents of a vtable.
 /// Since this is a query, allocations are cached and not duplicated.
 ///
 /// This is an "internal" `AllocId` that should never be used as a value in the interpreted program.
 /// The interpreter should use `AllocId` that refer to a `GlobalAlloc::VTable` instead.
 /// (This is similar to statics, which also have a similar "internal" `AllocId` storing their
 /// initial contents.)
 pub(super) fn vtable_allocation_provider<'tcx>(
     tcx: TyCtxt<'tcx>,
     key: (Ty<'tcx>, Option<ty::ExistentialTraitRef<'tcx>>),
 ) -> AllocId {
     let (ty, poly_trait_ref) = key;

     let vtable_entries = if let Some(poly_trait_ref) = poly_trait_ref {
         let trait_ref = poly_trait_ref.with_self_ty(tcx, ty);
         let trait_ref = tcx.erase_regions(trait_ref);

         tcx.vtable_entries(trait_ref)
     } else {
         TyCtxt::COMMON_VTABLE_ENTRIES
     };

     // This confirms that the layout computation for &dyn Trait has an accurate sizing.
     assert!(vtable_entries.len() >= vtable_min_entries(tcx, poly_trait_ref));

     let layout = tcx
         .layout_of(ty::TypingEnv::fully_monomorphized().as_query_input(ty))
         .expect("failed to build vtable representation");
     assert!(layout.is_sized(), "can't create a vtable for an unsized type");
     let size = layout.size.bytes();
     let align = layout.align.abi.bytes();

     let ptr_size = tcx.data_layout.pointer_size();
     let ptr_align = tcx.data_layout.pointer_align().abi;

     let vtable_size = ptr_size * u64::try_from(vtable_entries.len()).unwrap();
     let mut vtable = Allocation::new(vtable_size, ptr_align, AllocInit::Uninit, ());

     // No need to do any alignment checks on the memory accesses below, because we know the
     // allocation is correctly aligned as we created it above. Also we're only offsetting by
     // multiples of `ptr_align`, which means that it will stay aligned to `ptr_align`.

     for (idx, entry) in vtable_entries.iter().enumerate() {
         let idx: u64 = u64::try_from(idx).unwrap();
         let scalar = match *entry {
             VtblEntry::MetadataDropInPlace => {
                 if ty.needs_drop(tcx, ty::TypingEnv::fully_monomorphized()) {
                     let instance = ty::Instance::resolve_drop_in_place(tcx, ty);
                     let fn_alloc_id = tcx.reserve_and_set_fn_alloc(instance, CTFE_ALLOC_SALT);
                     let fn_ptr = Pointer::from(fn_alloc_id);
                     Scalar::from_pointer(fn_ptr, &tcx)
                 } else {
                     Scalar::from_maybe_pointer(Pointer::null(), &tcx)
                 }
             }
             VtblEntry::MetadataSize => Scalar::from_uint(size, ptr_size),
             VtblEntry::MetadataAlign => Scalar::from_uint(align, ptr_size),
             VtblEntry::Vacant => continue,
             VtblEntry::Method(instance) => {
                 // Prepare the fn ptr we write into the vtable.
                 let fn_alloc_id = tcx.reserve_and_set_fn_alloc(instance, CTFE_ALLOC_SALT);
                 let fn_ptr = Pointer::from(fn_alloc_id);
                 Scalar::from_pointer(fn_ptr, &tcx)
             }
             VtblEntry::TraitVPtr(trait_ref) => {
                 let super_trait_ref = ty::ExistentialTraitRef::erase_self_ty(tcx, trait_ref);
                 let supertrait_alloc_id = tcx.vtable_allocation((ty, Some(super_trait_ref)));
                 let vptr = Pointer::from(supertrait_alloc_id);
                 Scalar::from_pointer(vptr, &tcx)
             }
         };
         vtable
             .write_scalar(&tcx, alloc_range(ptr_size * idx, ptr_size), scalar)
             .expect("failed to build vtable representation");
     }

     vtable.mutability = Mutability::Not;
     tcx.reserve_and_set_memory_alloc(tcx.mk_const_alloc(vtable))
 }
	use std::fmt;

	use rustc_ast::Mutability;
	use rustc_macros::HashStable;
	use rustc_type_ir::elaborate;

	use crate::mir::interpret::{
	AllocId, AllocInit, Allocation, CTFE_ALLOC_SALT, Pointer, Scalar, alloc_range,
	};
	use crate::ty::{self, Instance, TraitRef, Ty, TyCtxt};

	#[derive(Clone, Copy, PartialEq, HashStable)]
	pub enum VtblEntry<'tcx> {
	/// destructor of this type (used in vtable header)
	MetadataDropInPlace,
	/// layout size of this type (used in vtable header)
	MetadataSize,
	/// layout align of this type (used in vtable header)
	MetadataAlign,
	/// non-dispatchable associated function that is excluded from trait object
	Vacant,
	/// dispatchable associated function
	Method(Instance<'tcx>),
	/// pointer to a separate supertrait vtable, can be used by trait upcasting coercion
	TraitVPtr(TraitRef<'tcx>),
	}

	impl<'tcx> fmt::Debug for VtblEntry<'tcx> {
	fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
	// We want to call `Display` on `Instance` and `PolyTraitRef`,
	// so we implement this manually.
	match self {
	VtblEntry::MetadataDropInPlace => write!(f, "MetadataDropInPlace"),
	VtblEntry::MetadataSize => write!(f, "MetadataSize"),
	VtblEntry::MetadataAlign => write!(f, "MetadataAlign"),
	VtblEntry::Vacant => write!(f, "Vacant"),
	VtblEntry::Method(instance) => write!(f, "Method({instance})"),
	VtblEntry::TraitVPtr(trait_ref) => write!(f, "TraitVPtr({trait_ref})"),
	}
	}
	}

	// Needs to be associated with the `'tcx` lifetime
	impl<'tcx> TyCtxt<'tcx> {
	pub const COMMON_VTABLE_ENTRIES: &'tcx [VtblEntry<'tcx>] =
	&[VtblEntry::MetadataDropInPlace, VtblEntry::MetadataSize, VtblEntry::MetadataAlign];
	}

	pub const COMMON_VTABLE_ENTRIES_DROPINPLACE: usize = 0;
	pub const COMMON_VTABLE_ENTRIES_SIZE: usize = 1;
	pub const COMMON_VTABLE_ENTRIES_ALIGN: usize = 2;

	// Note that we don't have access to a self type here, this has to be purely based on the trait (and
	// supertrait) definitions. That means we can't call into the same vtable_entries code since that
	// returns a specific instantiation (e.g., with Vacant slots when bounds aren't satisfied). The goal
	// here is to do a best-effort approximation without duplicating a lot of code.
	//
	// This function is used in layout computation for e.g. &dyn Trait, so it's critical that this
	// function is an accurate approximation. We verify this when actually computing the vtable below.
	pub(crate) fn vtable_min_entries<'tcx>(
	tcx: TyCtxt<'tcx>,
	trait_ref: Option<ty::ExistentialTraitRef<'tcx>>,
	) -> usize {
	let mut count = TyCtxt::COMMON_VTABLE_ENTRIES.len();
	let Some(trait_ref) = trait_ref else {
	return count;
	};

	// This includes self in supertraits.
	for def_id in elaborate::supertrait_def_ids(tcx, trait_ref.def_id) {
	count += tcx.own_existential_vtable_entries(def_id).len();
	}

	count
	}

	/// Retrieves an allocation that represents the contents of a vtable.
	/// Since this is a query, allocations are cached and not duplicated.
	///
	/// This is an "internal" `AllocId` that should never be used as a value in the interpreted program.
	/// The interpreter should use `AllocId` that refer to a `GlobalAlloc::VTable` instead.
	/// (This is similar to statics, which also have a similar "internal" `AllocId` storing their
	/// initial contents.)
	pub(super) fn vtable_allocation_provider<'tcx>(
	tcx: TyCtxt<'tcx>,
	key: (Ty<'tcx>, Option<ty::ExistentialTraitRef<'tcx>>),
	) -> AllocId {
	let (ty, poly_trait_ref) = key;

	let vtable_entries = if let Some(poly_trait_ref) = poly_trait_ref {
	let trait_ref = poly_trait_ref.with_self_ty(tcx, ty);
	let trait_ref = tcx.erase_regions(trait_ref);

	tcx.vtable_entries(trait_ref)
	} else {
	TyCtxt::COMMON_VTABLE_ENTRIES
	};

	// This confirms that the layout computation for &dyn Trait has an accurate sizing.
	assert!(vtable_entries.len() >= vtable_min_entries(tcx, poly_trait_ref));

	let layout = tcx
	.layout_of(ty::TypingEnv::fully_monomorphized().as_query_input(ty))
	.expect("failed to build vtable representation");
	assert!(layout.is_sized(), "can't create a vtable for an unsized type");
	let size = layout.size.bytes();
	let align = layout.align.abi.bytes();

	let ptr_size = tcx.data_layout.pointer_size();
	let ptr_align = tcx.data_layout.pointer_align().abi;

	let vtable_size = ptr_size * u64::try_from(vtable_entries.len()).unwrap();
	let mut vtable = Allocation::new(vtable_size, ptr_align, AllocInit::Uninit, ());

	// No need to do any alignment checks on the memory accesses below, because we know the
	// allocation is correctly aligned as we created it above. Also we're only offsetting by
	// multiples of `ptr_align`, which means that it will stay aligned to `ptr_align`.

	for (idx, entry) in vtable_entries.iter().enumerate() {
	let idx: u64 = u64::try_from(idx).unwrap();
	let scalar = match *entry {
	VtblEntry::MetadataDropInPlace => {
	if ty.needs_drop(tcx, ty::TypingEnv::fully_monomorphized()) {
	let instance = ty::Instance::resolve_drop_in_place(tcx, ty);
	let fn_alloc_id = tcx.reserve_and_set_fn_alloc(instance, CTFE_ALLOC_SALT);
	let fn_ptr = Pointer::from(fn_alloc_id);
	Scalar::from_pointer(fn_ptr, &tcx)
	} else {
	Scalar::from_maybe_pointer(Pointer::null(), &tcx)
	}
	}
	VtblEntry::MetadataSize => Scalar::from_uint(size, ptr_size),
	VtblEntry::MetadataAlign => Scalar::from_uint(align, ptr_size),
	VtblEntry::Vacant => continue,
	VtblEntry::Method(instance) => {
	// Prepare the fn ptr we write into the vtable.
	let fn_alloc_id = tcx.reserve_and_set_fn_alloc(instance, CTFE_ALLOC_SALT);
	let fn_ptr = Pointer::from(fn_alloc_id);
	Scalar::from_pointer(fn_ptr, &tcx)
	}
	VtblEntry::TraitVPtr(trait_ref) => {
	let super_trait_ref = ty::ExistentialTraitRef::erase_self_ty(tcx, trait_ref);
	let supertrait_alloc_id = tcx.vtable_allocation((ty, Some(super_trait_ref)));
	let vptr = Pointer::from(supertrait_alloc_id);
	Scalar::from_pointer(vptr, &tcx)
	}
	};
	vtable
	.write_scalar(&tcx, alloc_range(ptr_size * idx, ptr_size), scalar)
	.expect("failed to build vtable representation");
	}

	vtable.mutability = Mutability::Not;
	tcx.reserve_and_set_memory_alloc(tcx.mk_const_alloc(vtable))
	}