compiler/rustc_const_eval/src/interpret/cast.rs - rust-lang/rust - Git at Google

 use std::assert_matches::assert_matches;

 use rustc_abi::{FieldIdx, Integer};
 use rustc_apfloat::ieee::{Double, Half, Quad, Single};
 use rustc_apfloat::{Float, FloatConvert};
 use rustc_middle::mir::CastKind;
 use rustc_middle::mir::interpret::{InterpResult, PointerArithmetic, Scalar};
 use rustc_middle::ty::adjustment::PointerCoercion;
 use rustc_middle::ty::layout::{IntegerExt, TyAndLayout};
 use rustc_middle::ty::{self, FloatTy, Ty};
 use rustc_middle::{bug, span_bug};
 use tracing::trace;

 use super::util::ensure_monomorphic_enough;
 use super::{
     FnVal, ImmTy, Immediate, InterpCx, Machine, OpTy, PlaceTy, err_inval, interp_ok, throw_ub,
     throw_ub_custom,
 };
 use crate::interpret::Writeable;
 use crate::{enter_trace_span, fluent_generated as fluent};

 impl<'tcx, M: Machine<'tcx>> InterpCx<'tcx, M> {
     pub fn cast(
         &mut self,
         src: &OpTy<'tcx, M::Provenance>,
         cast_kind: CastKind,
         cast_ty: Ty<'tcx>,
         dest: &PlaceTy<'tcx, M::Provenance>,
     ) -> InterpResult<'tcx> {
         // `cast_ty` will often be the same as `dest.ty`, but not always, since subtyping is still
         // possible.
         let cast_layout =
             if cast_ty == dest.layout.ty { dest.layout } else { self.layout_of(cast_ty)? };
         // FIXME: In which cases should we trigger UB when the source is uninit?
         match cast_kind {
             CastKind::PointerCoercion(PointerCoercion::Unsize, _) => {
                 self.unsize_into(src, cast_layout, dest)?;
             }

             CastKind::PointerExposeProvenance => {
                 let src = self.read_immediate(src)?;
                 let res = self.pointer_expose_provenance_cast(&src, cast_layout)?;
                 self.write_immediate(*res, dest)?;
             }

             CastKind::PointerWithExposedProvenance => {
                 let src = self.read_immediate(src)?;
                 let res = self.pointer_with_exposed_provenance_cast(&src, cast_layout)?;
                 self.write_immediate(*res, dest)?;
             }

             CastKind::IntToInt | CastKind::IntToFloat => {
                 let src = self.read_immediate(src)?;
                 let res = self.int_to_int_or_float(&src, cast_layout)?;
                 self.write_immediate(*res, dest)?;
             }

             CastKind::FloatToFloat | CastKind::FloatToInt => {
                 let src = self.read_immediate(src)?;
                 let res = self.float_to_float_or_int(&src, cast_layout)?;
                 self.write_immediate(*res, dest)?;
             }

             CastKind::FnPtrToPtr | CastKind::PtrToPtr => {
                 let src = self.read_immediate(src)?;
                 let res = self.ptr_to_ptr(&src, cast_layout)?;
                 self.write_immediate(*res, dest)?;
             }

             CastKind::PointerCoercion(
                 PointerCoercion::MutToConstPointer | PointerCoercion::ArrayToPointer,
                 _,
             ) => {
                 bug!("{cast_kind:?} casts are for borrowck only, not runtime MIR");
             }

             CastKind::PointerCoercion(PointerCoercion::ReifyFnPointer, _) => {
                 // All reifications must be monomorphic, bail out otherwise.
                 ensure_monomorphic_enough(*self.tcx, src.layout.ty)?;

                 // The src operand does not matter, just its type
                 match *src.layout.ty.kind() {
                     ty::FnDef(def_id, args) => {
                         let instance = {
                             let _trace = enter_trace_span!(M, resolve::resolve_for_fn_ptr, ?def_id);
                             ty::Instance::resolve_for_fn_ptr(
                                 *self.tcx,
                                 self.typing_env,
                                 def_id,
                                 args,
                             )
                             .ok_or_else(|| err_inval!(TooGeneric))?
                         };

                         let fn_ptr = self.fn_ptr(FnVal::Instance(instance));
                         self.write_pointer(fn_ptr, dest)?;
                     }
                     _ => span_bug!(self.cur_span(), "reify fn pointer on {}", src.layout.ty),
                 }
             }

             CastKind::PointerCoercion(PointerCoercion::UnsafeFnPointer, _) => {
                 let src = self.read_immediate(src)?;
                 match cast_ty.kind() {
                     ty::FnPtr(..) => {
                         // No change to value
                         self.write_immediate(*src, dest)?;
                     }
                     _ => span_bug!(self.cur_span(), "fn to unsafe fn cast on {}", cast_ty),
                 }
             }

             CastKind::PointerCoercion(PointerCoercion::ClosureFnPointer(_), _) => {
                 // All reifications must be monomorphic, bail out otherwise.
                 ensure_monomorphic_enough(*self.tcx, src.layout.ty)?;

                 // The src operand does not matter, just its type
                 match *src.layout.ty.kind() {
                     ty::Closure(def_id, args) => {
                         let instance = {
                             let _trace = enter_trace_span!(M, resolve::resolve_closure, ?def_id);
                             ty::Instance::resolve_closure(
                                 *self.tcx,
                                 def_id,
                                 args,
                                 ty::ClosureKind::FnOnce,
                             )
                         };
                         let fn_ptr = self.fn_ptr(FnVal::Instance(instance));
                         self.write_pointer(fn_ptr, dest)?;
                     }
                     _ => span_bug!(self.cur_span(), "closure fn pointer on {}", src.layout.ty),
                 }
             }

             CastKind::Transmute | CastKind::Subtype => {
                 assert!(src.layout.is_sized());
                 assert!(dest.layout.is_sized());
                 assert_eq!(cast_ty, dest.layout.ty); // we otherwise ignore `cast_ty` enirely...
                 if src.layout.size != dest.layout.size {
                     throw_ub_custom!(
                         fluent::const_eval_invalid_transmute,
                         src_bytes = src.layout.size.bytes(),
                         dest_bytes = dest.layout.size.bytes(),
                         src = src.layout.ty,
                         dest = dest.layout.ty,
                     );
                 }

                 self.copy_op_allow_transmute(src, dest)?;
             }
         }
         interp_ok(())
     }

     /// Handles 'IntToInt' and 'IntToFloat' casts.
     pub fn int_to_int_or_float(
         &self,
         src: &ImmTy<'tcx, M::Provenance>,
         cast_to: TyAndLayout<'tcx>,
     ) -> InterpResult<'tcx, ImmTy<'tcx, M::Provenance>> {
         assert!(src.layout.ty.is_integral() || src.layout.ty.is_char() || src.layout.ty.is_bool());
         assert!(cast_to.ty.is_floating_point() || cast_to.ty.is_integral() || cast_to.ty.is_char());

         interp_ok(ImmTy::from_scalar(
             self.cast_from_int_like(src.to_scalar(), src.layout, cast_to.ty)?,
             cast_to,
         ))
     }

     /// Handles 'FloatToFloat' and 'FloatToInt' casts.
     pub fn float_to_float_or_int(
         &self,
         src: &ImmTy<'tcx, M::Provenance>,
         cast_to: TyAndLayout<'tcx>,
     ) -> InterpResult<'tcx, ImmTy<'tcx, M::Provenance>> {
         let ty::Float(fty) = src.layout.ty.kind() else {
             bug!("FloatToFloat/FloatToInt cast: source type {} is not a float type", src.layout.ty)
         };
         let val = match fty {
             FloatTy::F16 => self.cast_from_float(src.to_scalar().to_f16()?, cast_to.ty),
             FloatTy::F32 => self.cast_from_float(src.to_scalar().to_f32()?, cast_to.ty),
             FloatTy::F64 => self.cast_from_float(src.to_scalar().to_f64()?, cast_to.ty),
             FloatTy::F128 => self.cast_from_float(src.to_scalar().to_f128()?, cast_to.ty),
         };
         interp_ok(ImmTy::from_scalar(val, cast_to))
     }

     /// Handles 'FnPtrToPtr' and 'PtrToPtr' casts.
     pub fn ptr_to_ptr(
         &self,
         src: &ImmTy<'tcx, M::Provenance>,
         cast_to: TyAndLayout<'tcx>,
     ) -> InterpResult<'tcx, ImmTy<'tcx, M::Provenance>> {
         assert!(src.layout.ty.is_any_ptr());
         assert!(cast_to.ty.is_raw_ptr());
         // Handle casting any ptr to raw ptr (might be a wide ptr).
         if cast_to.size == src.layout.size {
             // Thin or wide pointer that just has the ptr kind of target type changed.
             return interp_ok(ImmTy::from_immediate(**src, cast_to));
         } else {
             // Casting the metadata away from a wide ptr.
             assert_eq!(src.layout.size, 2 * self.pointer_size());
             assert_eq!(cast_to.size, self.pointer_size());
             assert!(src.layout.ty.is_raw_ptr());
             return match **src {
                 Immediate::ScalarPair(data, _) => interp_ok(ImmTy::from_scalar(data, cast_to)),
                 Immediate::Scalar(..) => span_bug!(
                     self.cur_span(),
                     "{:?} input to a fat-to-thin cast ({} -> {})",
                     *src,
                     src.layout.ty,
                     cast_to.ty
                 ),
                 Immediate::Uninit => throw_ub!(InvalidUninitBytes(None)),
             };
         }
     }

     pub fn pointer_expose_provenance_cast(
         &mut self,
         src: &ImmTy<'tcx, M::Provenance>,
         cast_to: TyAndLayout<'tcx>,
     ) -> InterpResult<'tcx, ImmTy<'tcx, M::Provenance>> {
         assert_matches!(src.layout.ty.kind(), ty::RawPtr(_, _) | ty::FnPtr(..));
         assert!(cast_to.ty.is_integral());

         let scalar = src.to_scalar();
         let ptr = scalar.to_pointer(self)?;
         match ptr.into_pointer_or_addr() {
             Ok(ptr) => M::expose_provenance(self, ptr.provenance)?,
             Err(_) => {} // Do nothing, exposing an invalid pointer (`None` provenance) is a NOP.
         };
         interp_ok(ImmTy::from_scalar(
             self.cast_from_int_like(scalar, src.layout, cast_to.ty)?,
             cast_to,
         ))
     }

     pub fn pointer_with_exposed_provenance_cast(
         &self,
         src: &ImmTy<'tcx, M::Provenance>,
         cast_to: TyAndLayout<'tcx>,
     ) -> InterpResult<'tcx, ImmTy<'tcx, M::Provenance>> {
         assert!(src.layout.ty.is_integral());
         assert_matches!(cast_to.ty.kind(), ty::RawPtr(_, _));

         // First cast to usize.
         let scalar = src.to_scalar();
         let addr = self.cast_from_int_like(scalar, src.layout, self.tcx.types.usize)?;
         let addr = addr.to_target_usize(self)?;

         // Then turn address into pointer.
         let ptr = M::ptr_from_addr_cast(self, addr)?;
         interp_ok(ImmTy::from_scalar(Scalar::from_maybe_pointer(ptr, self), cast_to))
     }

     /// Low-level cast helper function. This works directly on scalars and can take 'int-like' input
     /// type (basically everything with a scalar layout) to int/float/char types.
     fn cast_from_int_like(
         &self,
         scalar: Scalar<M::Provenance>, // input value (there is no ScalarTy so we separate data+layout)
         src_layout: TyAndLayout<'tcx>,
         cast_ty: Ty<'tcx>,
     ) -> InterpResult<'tcx, Scalar<M::Provenance>> {
         // Let's make sure v is sign-extended *if* it has a signed type.
         let signed = src_layout.backend_repr.is_signed(); // Also asserts that abi is `Scalar`.

         let v = match src_layout.ty.kind() {
             ty::Uint(_) | ty::RawPtr(..) | ty::FnPtr(..) => scalar.to_uint(src_layout.size)?,
             ty::Int(_) => scalar.to_int(src_layout.size)? as u128, // we will cast back to `i128` below if the sign matters
             ty::Bool => scalar.to_bool()?.into(),
             ty::Char => scalar.to_char()?.into(),
             _ => span_bug!(self.cur_span(), "invalid int-like cast from {}", src_layout.ty),
         };

         interp_ok(match *cast_ty.kind() {
             // int -> int
             ty::Int(_) | ty::Uint(_) => {
                 let size = match *cast_ty.kind() {
                     ty::Int(t) => Integer::from_int_ty(self, t).size(),
                     ty::Uint(t) => Integer::from_uint_ty(self, t).size(),
                     _ => bug!(),
                 };
                 let v = size.truncate(v);
                 Scalar::from_uint(v, size)
             }

             // signed int -> float
             ty::Float(fty) if signed => {
                 let v = v as i128;
                 match fty {
                     FloatTy::F16 => Scalar::from_f16(Half::from_i128(v).value),
                     FloatTy::F32 => Scalar::from_f32(Single::from_i128(v).value),
                     FloatTy::F64 => Scalar::from_f64(Double::from_i128(v).value),
                     FloatTy::F128 => Scalar::from_f128(Quad::from_i128(v).value),
                 }
             }
             // unsigned int -> float
             ty::Float(fty) => match fty {
                 FloatTy::F16 => Scalar::from_f16(Half::from_u128(v).value),
                 FloatTy::F32 => Scalar::from_f32(Single::from_u128(v).value),
                 FloatTy::F64 => Scalar::from_f64(Double::from_u128(v).value),
                 FloatTy::F128 => Scalar::from_f128(Quad::from_u128(v).value),
             },

             // u8 -> char
             ty::Char => Scalar::from_u32(u8::try_from(v).unwrap().into()),

             // Casts to bool are not permitted by rustc, no need to handle them here.
             _ => span_bug!(self.cur_span(), "invalid int to {} cast", cast_ty),
         })
     }

     /// Low-level cast helper function. Converts an apfloat `f` into int or float types.
     fn cast_from_float<F>(&self, f: F, dest_ty: Ty<'tcx>) -> Scalar<M::Provenance>
     where
         F: Float
             + Into<Scalar<M::Provenance>>
             + FloatConvert<Half>
             + FloatConvert<Single>
             + FloatConvert<Double>
             + FloatConvert<Quad>,
     {
         match *dest_ty.kind() {
             // float -> uint
             ty::Uint(t) => {
                 let size = Integer::from_uint_ty(self, t).size();
                 // `to_u128` is a saturating cast, which is what we need
                 // (https://doc.rust-lang.org/nightly/nightly-rustc/rustc_apfloat/trait.Float.html#method.to_i128_r).
                 let v = f.to_u128(size.bits_usize()).value;
                 // This should already fit the bit width
                 Scalar::from_uint(v, size)
             }
             // float -> int
             ty::Int(t) => {
                 let size = Integer::from_int_ty(self, t).size();
                 // `to_i128` is a saturating cast, which is what we need
                 // (https://doc.rust-lang.org/nightly/nightly-rustc/rustc_apfloat/trait.Float.html#method.to_i128_r).
                 let v = f.to_i128(size.bits_usize()).value;
                 Scalar::from_int(v, size)
             }
             // float -> float
             ty::Float(fty) => match fty {
                 FloatTy::F16 => {
                     Scalar::from_f16(self.adjust_nan(f.convert(&mut false).value, &[f]))
                 }
                 FloatTy::F32 => {
                     Scalar::from_f32(self.adjust_nan(f.convert(&mut false).value, &[f]))
                 }
                 FloatTy::F64 => {
                     Scalar::from_f64(self.adjust_nan(f.convert(&mut false).value, &[f]))
                 }
                 FloatTy::F128 => {
                     Scalar::from_f128(self.adjust_nan(f.convert(&mut false).value, &[f]))
                 }
             },
             // That's it.
             _ => span_bug!(self.cur_span(), "invalid float to {} cast", dest_ty),
         }
     }

     /// `src` is a *pointer to* a `source_ty`, and in `dest` we should store a pointer to th same
     /// data at type `cast_ty`.
     fn unsize_into_ptr(
         &mut self,
         src: &OpTy<'tcx, M::Provenance>,
         dest: &impl Writeable<'tcx, M::Provenance>,
         // The pointee types
         source_ty: Ty<'tcx>,
         cast_ty: Ty<'tcx>,
     ) -> InterpResult<'tcx> {
         // A<Struct> -> A<Trait> conversion
         let (src_pointee_ty, dest_pointee_ty) =
             self.tcx.struct_lockstep_tails_for_codegen(source_ty, cast_ty, self.typing_env);

         match (src_pointee_ty.kind(), dest_pointee_ty.kind()) {
             (&ty::Array(_, length), &ty::Slice(_)) => {
                 let ptr = self.read_pointer(src)?;
                 let val = Immediate::new_slice(
                     ptr,
                     length
                         .try_to_target_usize(*self.tcx)
                         .expect("expected monomorphic const in const eval"),
                     self,
                 );
                 self.write_immediate(val, dest)
             }
             (ty::Dynamic(data_a, _), ty::Dynamic(data_b, _)) => {
                 let val = self.read_immediate(src)?;
                 // MIR building generates odd NOP casts, prevent them from causing unexpected trouble.
                 // See <https://github.com/rust-lang/rust/issues/128880>.
                 // FIXME: ideally we wouldn't have to do this.
                 if data_a == data_b {
                     return self.write_immediate(*val, dest);
                 }
                 // Take apart the old pointer, and find the dynamic type.
                 let (old_data, old_vptr) = val.to_scalar_pair();
                 let old_data = old_data.to_pointer(self)?;
                 let old_vptr = old_vptr.to_pointer(self)?;
                 let ty = self.get_ptr_vtable_ty(old_vptr, Some(data_a))?;

                 // Sanity-check that `supertrait_vtable_slot` in this type's vtable indeed produces
                 // our destination trait.
                 let vptr_entry_idx =
                     self.tcx.supertrait_vtable_slot((src_pointee_ty, dest_pointee_ty));
                 let vtable_entries = self.vtable_entries(data_a.principal(), ty);
                 if let Some(entry_idx) = vptr_entry_idx {
                     let Some(&ty::VtblEntry::TraitVPtr(upcast_trait_ref)) =
                         vtable_entries.get(entry_idx)
                     else {
                         span_bug!(
                             self.cur_span(),
                             "invalid vtable entry index in {} -> {} upcast",
                             src_pointee_ty,
                             dest_pointee_ty
                         );
                     };
                     let erased_trait_ref =
                         ty::ExistentialTraitRef::erase_self_ty(*self.tcx, upcast_trait_ref);
                     assert_eq!(
                         data_b.principal().map(|b| {
                             self.tcx.normalize_erasing_late_bound_regions(self.typing_env, b)
                         }),
                         Some(erased_trait_ref),
                     );
                 } else {
                     // In this case codegen would keep using the old vtable. We don't want to do
                     // that as it has the wrong trait. The reason codegen can do this is that
                     // one vtable is a prefix of the other, so we double-check that.
                     let vtable_entries_b = self.vtable_entries(data_b.principal(), ty);
                     assert!(&vtable_entries[..vtable_entries_b.len()] == vtable_entries_b);
                 };

                 // Get the destination trait vtable and return that.
                 let new_vptr = self.get_vtable_ptr(ty, data_b)?;
                 self.write_immediate(Immediate::new_dyn_trait(old_data, new_vptr, self), dest)
             }
             (_, &ty::Dynamic(data, _)) => {
                 // Initial cast from sized to dyn trait
                 let vtable = self.get_vtable_ptr(src_pointee_ty, data)?;
                 let ptr = self.read_pointer(src)?;
                 let val = Immediate::new_dyn_trait(ptr, vtable, &*self.tcx);
                 self.write_immediate(val, dest)
             }
             _ => {
                 // Do not ICE if we are not monomorphic enough.
                 ensure_monomorphic_enough(*self.tcx, src.layout.ty)?;
                 ensure_monomorphic_enough(*self.tcx, cast_ty)?;

                 span_bug!(
                     self.cur_span(),
                     "invalid pointer unsizing {} -> {}",
                     src.layout.ty,
                     cast_ty
                 )
             }
         }
     }

     pub fn unsize_into(
         &mut self,
         src: &OpTy<'tcx, M::Provenance>,
         cast_ty: TyAndLayout<'tcx>,
         dest: &impl Writeable<'tcx, M::Provenance>,
     ) -> InterpResult<'tcx> {
         trace!("Unsizing {:?} of type {} into {}", *src, src.layout.ty, cast_ty.ty);
         match (src.layout.ty.kind(), cast_ty.ty.kind()) {
             (&ty::Pat(_, s_pat), &ty::Pat(cast_ty, c_pat)) if s_pat == c_pat => {
                 let src = self.project_field(src, FieldIdx::ZERO)?;
                 let dest = self.project_field(dest, FieldIdx::ZERO)?;
                 let cast_ty = self.layout_of(cast_ty)?;
                 self.unsize_into(&src, cast_ty, &dest)
             }
             (&ty::Ref(_, s, _), &ty::Ref(_, c, _) | &ty::RawPtr(c, _))
             | (&ty::RawPtr(s, _), &ty::RawPtr(c, _)) => self.unsize_into_ptr(src, dest, s, c),
             (&ty::Adt(def_a, _), &ty::Adt(def_b, _)) => {
                 assert_eq!(def_a, def_b); // implies same number of fields

                 // Unsizing of generic struct with pointer fields, like `Arc<T>` -> `Arc<Trait>`.
                 // There can be extra fields as long as they don't change their type or are 1-ZST.
                 // There might also be no field that actually needs unsizing.
                 let mut found_cast_field = false;
                 for i in 0..src.layout.fields.count() {
                     let cast_ty_field = cast_ty.field(self, i);
                     let i = FieldIdx::from_usize(i);
                     let src_field = self.project_field(src, i)?;
                     let dst_field = self.project_field(dest, i)?;
                     if src_field.layout.is_1zst() && cast_ty_field.is_1zst() {
                         // Skip 1-ZST fields.
                     } else if src_field.layout.ty == cast_ty_field.ty {
                         self.copy_op(&src_field, &dst_field)?;
                     } else {
                         if found_cast_field {
                             span_bug!(self.cur_span(), "unsize_into: more than one field to cast");
                         }
                         found_cast_field = true;
                         self.unsize_into(&src_field, cast_ty_field, &dst_field)?;
                     }
                 }
                 interp_ok(())
             }
             _ => {
                 // Do not ICE if we are not monomorphic enough.
                 ensure_monomorphic_enough(*self.tcx, src.layout.ty)?;
                 ensure_monomorphic_enough(*self.tcx, cast_ty.ty)?;

                 span_bug!(
                     self.cur_span(),
                     "unsize_into: invalid conversion: {:?} -> {:?}",
                     src.layout,
                     dest.layout()
                 )
             }
         }
     }
 }
	use std::assert_matches::assert_matches;

	use rustc_abi::{FieldIdx, Integer};
	use rustc_apfloat::ieee::{Double, Half, Quad, Single};
	use rustc_apfloat::{Float, FloatConvert};
	use rustc_middle::mir::CastKind;
	use rustc_middle::mir::interpret::{InterpResult, PointerArithmetic, Scalar};
	use rustc_middle::ty::adjustment::PointerCoercion;
	use rustc_middle::ty::layout::{IntegerExt, TyAndLayout};
	use rustc_middle::ty::{self, FloatTy, Ty};
	use rustc_middle::{bug, span_bug};
	use tracing::trace;

	use super::util::ensure_monomorphic_enough;
	use super::{
	FnVal, ImmTy, Immediate, InterpCx, Machine, OpTy, PlaceTy, err_inval, interp_ok, throw_ub,
	throw_ub_custom,
	};
	use crate::interpret::Writeable;
	use crate::{enter_trace_span, fluent_generated as fluent};

	impl<'tcx, M: Machine<'tcx>> InterpCx<'tcx, M> {
	pub fn cast(
	&mut self,
	src: &OpTy<'tcx, M::Provenance>,
	cast_kind: CastKind,
	cast_ty: Ty<'tcx>,
	dest: &PlaceTy<'tcx, M::Provenance>,
	) -> InterpResult<'tcx> {
	// `cast_ty` will often be the same as `dest.ty`, but not always, since subtyping is still
	// possible.
	let cast_layout =
	if cast_ty == dest.layout.ty { dest.layout } else { self.layout_of(cast_ty)? };
	// FIXME: In which cases should we trigger UB when the source is uninit?
	match cast_kind {
	CastKind::PointerCoercion(PointerCoercion::Unsize, _) => {
	self.unsize_into(src, cast_layout, dest)?;
	}

	CastKind::PointerExposeProvenance => {
	let src = self.read_immediate(src)?;
	let res = self.pointer_expose_provenance_cast(&src, cast_layout)?;
	self.write_immediate(*res, dest)?;
	}

	CastKind::PointerWithExposedProvenance => {
	let src = self.read_immediate(src)?;
	let res = self.pointer_with_exposed_provenance_cast(&src, cast_layout)?;
	self.write_immediate(*res, dest)?;
	}

	CastKind::IntToInt \| CastKind::IntToFloat => {
	let src = self.read_immediate(src)?;
	let res = self.int_to_int_or_float(&src, cast_layout)?;
	self.write_immediate(*res, dest)?;
	}

	CastKind::FloatToFloat \| CastKind::FloatToInt => {
	let src = self.read_immediate(src)?;
	let res = self.float_to_float_or_int(&src, cast_layout)?;
	self.write_immediate(*res, dest)?;
	}

	CastKind::FnPtrToPtr \| CastKind::PtrToPtr => {
	let src = self.read_immediate(src)?;
	let res = self.ptr_to_ptr(&src, cast_layout)?;
	self.write_immediate(*res, dest)?;
	}

	CastKind::PointerCoercion(
	PointerCoercion::MutToConstPointer \| PointerCoercion::ArrayToPointer,
	_,
	) => {
	bug!("{cast_kind:?} casts are for borrowck only, not runtime MIR");
	}

	CastKind::PointerCoercion(PointerCoercion::ReifyFnPointer, _) => {
	// All reifications must be monomorphic, bail out otherwise.
	ensure_monomorphic_enough(*self.tcx, src.layout.ty)?;

	// The src operand does not matter, just its type
	match *src.layout.ty.kind() {
	ty::FnDef(def_id, args) => {
	let instance = {
	let _trace = enter_trace_span!(M, resolve::resolve_for_fn_ptr, ?def_id);
	ty::Instance::resolve_for_fn_ptr(
	*self.tcx,
	self.typing_env,
	def_id,
	args,
	)
	.ok_or_else(\|\| err_inval!(TooGeneric))?
	};

	let fn_ptr = self.fn_ptr(FnVal::Instance(instance));
	self.write_pointer(fn_ptr, dest)?;
	}
	_ => span_bug!(self.cur_span(), "reify fn pointer on {}", src.layout.ty),
	}
	}

	CastKind::PointerCoercion(PointerCoercion::UnsafeFnPointer, _) => {
	let src = self.read_immediate(src)?;
	match cast_ty.kind() {
	ty::FnPtr(..) => {
	// No change to value
	self.write_immediate(*src, dest)?;
	}
	_ => span_bug!(self.cur_span(), "fn to unsafe fn cast on {}", cast_ty),
	}
	}

	CastKind::PointerCoercion(PointerCoercion::ClosureFnPointer(_), _) => {
	// All reifications must be monomorphic, bail out otherwise.
	ensure_monomorphic_enough(*self.tcx, src.layout.ty)?;

	// The src operand does not matter, just its type
	match *src.layout.ty.kind() {
	ty::Closure(def_id, args) => {
	let instance = {
	let _trace = enter_trace_span!(M, resolve::resolve_closure, ?def_id);
	ty::Instance::resolve_closure(
	*self.tcx,
	def_id,
	args,
	ty::ClosureKind::FnOnce,
	)
	};
	let fn_ptr = self.fn_ptr(FnVal::Instance(instance));
	self.write_pointer(fn_ptr, dest)?;
	}
	_ => span_bug!(self.cur_span(), "closure fn pointer on {}", src.layout.ty),
	}
	}

	CastKind::Transmute \| CastKind::Subtype => {
	assert!(src.layout.is_sized());
	assert!(dest.layout.is_sized());
	assert_eq!(cast_ty, dest.layout.ty); // we otherwise ignore `cast_ty` enirely...
	if src.layout.size != dest.layout.size {
	throw_ub_custom!(
	fluent::const_eval_invalid_transmute,
	src_bytes = src.layout.size.bytes(),
	dest_bytes = dest.layout.size.bytes(),
	src = src.layout.ty,
	dest = dest.layout.ty,
	);
	}

	self.copy_op_allow_transmute(src, dest)?;
	}
	}
	interp_ok(())
	}

	/// Handles 'IntToInt' and 'IntToFloat' casts.
	pub fn int_to_int_or_float(
	&self,
	src: &ImmTy<'tcx, M::Provenance>,
	cast_to: TyAndLayout<'tcx>,
	) -> InterpResult<'tcx, ImmTy<'tcx, M::Provenance>> {
	assert!(src.layout.ty.is_integral() \|\| src.layout.ty.is_char() \|\| src.layout.ty.is_bool());
	assert!(cast_to.ty.is_floating_point() \|\| cast_to.ty.is_integral() \|\| cast_to.ty.is_char());

	interp_ok(ImmTy::from_scalar(
	self.cast_from_int_like(src.to_scalar(), src.layout, cast_to.ty)?,
	cast_to,
	))
	}

	/// Handles 'FloatToFloat' and 'FloatToInt' casts.
	pub fn float_to_float_or_int(
	&self,
	src: &ImmTy<'tcx, M::Provenance>,
	cast_to: TyAndLayout<'tcx>,
	) -> InterpResult<'tcx, ImmTy<'tcx, M::Provenance>> {
	let ty::Float(fty) = src.layout.ty.kind() else {
	bug!("FloatToFloat/FloatToInt cast: source type {} is not a float type", src.layout.ty)
	};
	let val = match fty {
	FloatTy::F16 => self.cast_from_float(src.to_scalar().to_f16()?, cast_to.ty),
	FloatTy::F32 => self.cast_from_float(src.to_scalar().to_f32()?, cast_to.ty),
	FloatTy::F64 => self.cast_from_float(src.to_scalar().to_f64()?, cast_to.ty),
	FloatTy::F128 => self.cast_from_float(src.to_scalar().to_f128()?, cast_to.ty),
	};
	interp_ok(ImmTy::from_scalar(val, cast_to))
	}

	/// Handles 'FnPtrToPtr' and 'PtrToPtr' casts.
	pub fn ptr_to_ptr(
	&self,
	src: &ImmTy<'tcx, M::Provenance>,
	cast_to: TyAndLayout<'tcx>,
	) -> InterpResult<'tcx, ImmTy<'tcx, M::Provenance>> {
	assert!(src.layout.ty.is_any_ptr());
	assert!(cast_to.ty.is_raw_ptr());
	// Handle casting any ptr to raw ptr (might be a wide ptr).
	if cast_to.size == src.layout.size {
	// Thin or wide pointer that just has the ptr kind of target type changed.
	return interp_ok(ImmTy::from_immediate(**src, cast_to));
	} else {
	// Casting the metadata away from a wide ptr.
	assert_eq!(src.layout.size, 2 * self.pointer_size());
	assert_eq!(cast_to.size, self.pointer_size());
	assert!(src.layout.ty.is_raw_ptr());
	return match **src {
	Immediate::ScalarPair(data, _) => interp_ok(ImmTy::from_scalar(data, cast_to)),
	Immediate::Scalar(..) => span_bug!(
	self.cur_span(),
	"{:?} input to a fat-to-thin cast ({} -> {})",
	*src,
	src.layout.ty,
	cast_to.ty
	),
	Immediate::Uninit => throw_ub!(InvalidUninitBytes(None)),
	};
	}
	}

	pub fn pointer_expose_provenance_cast(
	&mut self,
	src: &ImmTy<'tcx, M::Provenance>,
	cast_to: TyAndLayout<'tcx>,
	) -> InterpResult<'tcx, ImmTy<'tcx, M::Provenance>> {
	assert_matches!(src.layout.ty.kind(), ty::RawPtr(_, _) \| ty::FnPtr(..));
	assert!(cast_to.ty.is_integral());

	let scalar = src.to_scalar();
	let ptr = scalar.to_pointer(self)?;
	match ptr.into_pointer_or_addr() {
	Ok(ptr) => M::expose_provenance(self, ptr.provenance)?,
	Err(_) => {} // Do nothing, exposing an invalid pointer (`None` provenance) is a NOP.
	};
	interp_ok(ImmTy::from_scalar(
	self.cast_from_int_like(scalar, src.layout, cast_to.ty)?,
	cast_to,
	))
	}

	pub fn pointer_with_exposed_provenance_cast(
	&self,
	src: &ImmTy<'tcx, M::Provenance>,
	cast_to: TyAndLayout<'tcx>,
	) -> InterpResult<'tcx, ImmTy<'tcx, M::Provenance>> {
	assert!(src.layout.ty.is_integral());
	assert_matches!(cast_to.ty.kind(), ty::RawPtr(_, _));

	// First cast to usize.
	let scalar = src.to_scalar();
	let addr = self.cast_from_int_like(scalar, src.layout, self.tcx.types.usize)?;
	let addr = addr.to_target_usize(self)?;

	// Then turn address into pointer.
	let ptr = M::ptr_from_addr_cast(self, addr)?;
	interp_ok(ImmTy::from_scalar(Scalar::from_maybe_pointer(ptr, self), cast_to))
	}

	/// Low-level cast helper function. This works directly on scalars and can take 'int-like' input
	/// type (basically everything with a scalar layout) to int/float/char types.
	fn cast_from_int_like(
	&self,
	scalar: Scalar<M::Provenance>, // input value (there is no ScalarTy so we separate data+layout)
	src_layout: TyAndLayout<'tcx>,
	cast_ty: Ty<'tcx>,
	) -> InterpResult<'tcx, Scalar<M::Provenance>> {
	// Let's make sure v is sign-extended if it has a signed type.
	let signed = src_layout.backend_repr.is_signed(); // Also asserts that abi is `Scalar`.

	let v = match src_layout.ty.kind() {
	ty::Uint(_) \| ty::RawPtr(..) \| ty::FnPtr(..) => scalar.to_uint(src_layout.size)?,
	ty::Int(_) => scalar.to_int(src_layout.size)? as u128, // we will cast back to `i128` below if the sign matters
	ty::Bool => scalar.to_bool()?.into(),
	ty::Char => scalar.to_char()?.into(),
	_ => span_bug!(self.cur_span(), "invalid int-like cast from {}", src_layout.ty),
	};

	interp_ok(match *cast_ty.kind() {
	// int -> int
	ty::Int(_) \| ty::Uint(_) => {
	let size = match *cast_ty.kind() {
	ty::Int(t) => Integer::from_int_ty(self, t).size(),
	ty::Uint(t) => Integer::from_uint_ty(self, t).size(),
	_ => bug!(),
	};
	let v = size.truncate(v);
	Scalar::from_uint(v, size)
	}

	// signed int -> float
	ty::Float(fty) if signed => {
	let v = v as i128;
	match fty {
	FloatTy::F16 => Scalar::from_f16(Half::from_i128(v).value),
	FloatTy::F32 => Scalar::from_f32(Single::from_i128(v).value),
	FloatTy::F64 => Scalar::from_f64(Double::from_i128(v).value),
	FloatTy::F128 => Scalar::from_f128(Quad::from_i128(v).value),
	}
	}
	// unsigned int -> float
	ty::Float(fty) => match fty {
	FloatTy::F16 => Scalar::from_f16(Half::from_u128(v).value),
	FloatTy::F32 => Scalar::from_f32(Single::from_u128(v).value),
	FloatTy::F64 => Scalar::from_f64(Double::from_u128(v).value),
	FloatTy::F128 => Scalar::from_f128(Quad::from_u128(v).value),
	},

	// u8 -> char
	ty::Char => Scalar::from_u32(u8::try_from(v).unwrap().into()),

	// Casts to bool are not permitted by rustc, no need to handle them here.
	_ => span_bug!(self.cur_span(), "invalid int to {} cast", cast_ty),
	})
	}

	/// Low-level cast helper function. Converts an apfloat `f` into int or float types.
	fn cast_from_float<F>(&self, f: F, dest_ty: Ty<'tcx>) -> Scalar<M::Provenance>
	where
	F: Float
	+ Into<Scalar<M::Provenance>>
	+ FloatConvert<Half>
	+ FloatConvert<Single>
	+ FloatConvert<Double>
	+ FloatConvert<Quad>,
	{
	match *dest_ty.kind() {
	// float -> uint
	ty::Uint(t) => {
	let size = Integer::from_uint_ty(self, t).size();
	// `to_u128` is a saturating cast, which is what we need
	// (https://doc.rust-lang.org/nightly/nightly-rustc/rustc_apfloat/trait.Float.html#method.to_i128_r).
	let v = f.to_u128(size.bits_usize()).value;
	// This should already fit the bit width
	Scalar::from_uint(v, size)
	}
	// float -> int
	ty::Int(t) => {
	let size = Integer::from_int_ty(self, t).size();
	// `to_i128` is a saturating cast, which is what we need
	// (https://doc.rust-lang.org/nightly/nightly-rustc/rustc_apfloat/trait.Float.html#method.to_i128_r).
	let v = f.to_i128(size.bits_usize()).value;
	Scalar::from_int(v, size)
	}
	// float -> float
	ty::Float(fty) => match fty {
	FloatTy::F16 => {
	Scalar::from_f16(self.adjust_nan(f.convert(&mut false).value, &[f]))
	}
	FloatTy::F32 => {
	Scalar::from_f32(self.adjust_nan(f.convert(&mut false).value, &[f]))
	}
	FloatTy::F64 => {
	Scalar::from_f64(self.adjust_nan(f.convert(&mut false).value, &[f]))
	}
	FloatTy::F128 => {
	Scalar::from_f128(self.adjust_nan(f.convert(&mut false).value, &[f]))
	}
	},
	// That's it.
	_ => span_bug!(self.cur_span(), "invalid float to {} cast", dest_ty),
	}
	}

	/// `src` is a pointer to a `source_ty`, and in `dest` we should store a pointer to th same
	/// data at type `cast_ty`.
	fn unsize_into_ptr(
	&mut self,
	src: &OpTy<'tcx, M::Provenance>,
	dest: &impl Writeable<'tcx, M::Provenance>,
	// The pointee types
	source_ty: Ty<'tcx>,
	cast_ty: Ty<'tcx>,
	) -> InterpResult<'tcx> {
	// A<Struct> -> A<Trait> conversion
	let (src_pointee_ty, dest_pointee_ty) =
	self.tcx.struct_lockstep_tails_for_codegen(source_ty, cast_ty, self.typing_env);

	match (src_pointee_ty.kind(), dest_pointee_ty.kind()) {
	(&ty::Array(_, length), &ty::Slice(_)) => {
	let ptr = self.read_pointer(src)?;
	let val = Immediate::new_slice(
	ptr,
	length
	.try_to_target_usize(*self.tcx)
	.expect("expected monomorphic const in const eval"),
	self,
	);
	self.write_immediate(val, dest)
	}
	(ty::Dynamic(data_a, _), ty::Dynamic(data_b, _)) => {
	let val = self.read_immediate(src)?;
	// MIR building generates odd NOP casts, prevent them from causing unexpected trouble.
	// See <https://github.com/rust-lang/rust/issues/128880>.
	// FIXME: ideally we wouldn't have to do this.
	if data_a == data_b {
	return self.write_immediate(*val, dest);
	}
	// Take apart the old pointer, and find the dynamic type.
	let (old_data, old_vptr) = val.to_scalar_pair();
	let old_data = old_data.to_pointer(self)?;
	let old_vptr = old_vptr.to_pointer(self)?;
	let ty = self.get_ptr_vtable_ty(old_vptr, Some(data_a))?;

	// Sanity-check that `supertrait_vtable_slot` in this type's vtable indeed produces
	// our destination trait.
	let vptr_entry_idx =
	self.tcx.supertrait_vtable_slot((src_pointee_ty, dest_pointee_ty));
	let vtable_entries = self.vtable_entries(data_a.principal(), ty);
	if let Some(entry_idx) = vptr_entry_idx {
	let Some(&ty::VtblEntry::TraitVPtr(upcast_trait_ref)) =
	vtable_entries.get(entry_idx)
	else {
	span_bug!(
	self.cur_span(),
	"invalid vtable entry index in {} -> {} upcast",
	src_pointee_ty,
	dest_pointee_ty
	);
	};
	let erased_trait_ref =
	ty::ExistentialTraitRef::erase_self_ty(*self.tcx, upcast_trait_ref);
	assert_eq!(
	data_b.principal().map(\|b\| {
	self.tcx.normalize_erasing_late_bound_regions(self.typing_env, b)
	}),
	Some(erased_trait_ref),
	);
	} else {
	// In this case codegen would keep using the old vtable. We don't want to do
	// that as it has the wrong trait. The reason codegen can do this is that
	// one vtable is a prefix of the other, so we double-check that.
	let vtable_entries_b = self.vtable_entries(data_b.principal(), ty);
	assert!(&vtable_entries[..vtable_entries_b.len()] == vtable_entries_b);
	};

	// Get the destination trait vtable and return that.
	let new_vptr = self.get_vtable_ptr(ty, data_b)?;
	self.write_immediate(Immediate::new_dyn_trait(old_data, new_vptr, self), dest)
	}
	(_, &ty::Dynamic(data, _)) => {
	// Initial cast from sized to dyn trait
	let vtable = self.get_vtable_ptr(src_pointee_ty, data)?;
	let ptr = self.read_pointer(src)?;
	let val = Immediate::new_dyn_trait(ptr, vtable, &*self.tcx);
	self.write_immediate(val, dest)
	}
	_ => {
	// Do not ICE if we are not monomorphic enough.
	ensure_monomorphic_enough(*self.tcx, src.layout.ty)?;
	ensure_monomorphic_enough(*self.tcx, cast_ty)?;

	span_bug!(
	self.cur_span(),
	"invalid pointer unsizing {} -> {}",
	src.layout.ty,
	cast_ty
	)
	}
	}
	}

	pub fn unsize_into(
	&mut self,
	src: &OpTy<'tcx, M::Provenance>,
	cast_ty: TyAndLayout<'tcx>,
	dest: &impl Writeable<'tcx, M::Provenance>,
	) -> InterpResult<'tcx> {
	trace!("Unsizing {:?} of type {} into {}", *src, src.layout.ty, cast_ty.ty);
	match (src.layout.ty.kind(), cast_ty.ty.kind()) {
	(&ty::Pat(_, s_pat), &ty::Pat(cast_ty, c_pat)) if s_pat == c_pat => {
	let src = self.project_field(src, FieldIdx::ZERO)?;
	let dest = self.project_field(dest, FieldIdx::ZERO)?;
	let cast_ty = self.layout_of(cast_ty)?;
	self.unsize_into(&src, cast_ty, &dest)
	}
	(&ty::Ref(_, s, _), &ty::Ref(_, c, _) \| &ty::RawPtr(c, _))
	\| (&ty::RawPtr(s, _), &ty::RawPtr(c, _)) => self.unsize_into_ptr(src, dest, s, c),
	(&ty::Adt(def_a, _), &ty::Adt(def_b, _)) => {
	assert_eq!(def_a, def_b); // implies same number of fields

	// Unsizing of generic struct with pointer fields, like `Arc<T>` -> `Arc<Trait>`.
	// There can be extra fields as long as they don't change their type or are 1-ZST.
	// There might also be no field that actually needs unsizing.
	let mut found_cast_field = false;
	for i in 0..src.layout.fields.count() {
	let cast_ty_field = cast_ty.field(self, i);
	let i = FieldIdx::from_usize(i);
	let src_field = self.project_field(src, i)?;
	let dst_field = self.project_field(dest, i)?;
	if src_field.layout.is_1zst() && cast_ty_field.is_1zst() {
	// Skip 1-ZST fields.
	} else if src_field.layout.ty == cast_ty_field.ty {
	self.copy_op(&src_field, &dst_field)?;
	} else {
	if found_cast_field {
	span_bug!(self.cur_span(), "unsize_into: more than one field to cast");
	}
	found_cast_field = true;
	self.unsize_into(&src_field, cast_ty_field, &dst_field)?;
	}
	}
	interp_ok(())
	}
	_ => {
	// Do not ICE if we are not monomorphic enough.
	ensure_monomorphic_enough(*self.tcx, src.layout.ty)?;
	ensure_monomorphic_enough(*self.tcx, cast_ty.ty)?;

	span_bug!(
	self.cur_span(),
	"unsize_into: invalid conversion: {:?} -> {:?}",
	src.layout,
	dest.layout()
	)
	}
	}
	}
	}