//! Visitor for a run-time value with a given layout: Traverse enums, structs and other compound //! types until we arrive at the leaves, with custom handling for primitive types. use rustc_middle::mir::interpret::InterpResult; use rustc_middle::ty; use rustc_middle::ty::layout::TyAndLayout; use rustc_target::abi::{FieldsShape, VariantIdx, Variants}; use std::num::NonZeroUsize; use super::{InterpCx, MPlaceTy, Machine, OpTy, PlaceTy}; /// A thing that we can project into, and that has a layout. /// This wouldn't have to depend on `Machine` but with the current type inference, /// that's just more convenient to work with (avoids repeating all the `Machine` bounds). pub trait Value<'mir, 'tcx, M: Machine<'mir, 'tcx>>: Sized { /// Gets this value's layout. fn layout(&self) -> TyAndLayout<'tcx>; /// Makes this into an `OpTy`, in a cheap way that is good for reading. fn to_op_for_read( &self, ecx: &InterpCx<'mir, 'tcx, M>, ) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>>; /// Makes this into an `OpTy`, in a potentially more expensive way that is good for projections. fn to_op_for_proj( &self, ecx: &InterpCx<'mir, 'tcx, M>, ) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> { self.to_op_for_read(ecx) } /// Creates this from an `OpTy`. /// /// If `to_op_for_proj` only ever produces `Indirect` operands, then this one is definitely `Indirect`. fn from_op(op: &OpTy<'tcx, M::Provenance>) -> Self; /// Projects to the given enum variant. fn project_downcast( &self, ecx: &InterpCx<'mir, 'tcx, M>, variant: VariantIdx, ) -> InterpResult<'tcx, Self>; /// Projects to the n-th field. fn project_field( &self, ecx: &InterpCx<'mir, 'tcx, M>, field: usize, ) -> InterpResult<'tcx, Self>; } /// A thing that we can project into given *mutable* access to `ecx`, and that has a layout. /// This wouldn't have to depend on `Machine` but with the current type inference, /// that's just more convenient to work with (avoids repeating all the `Machine` bounds). pub trait ValueMut<'mir, 'tcx, M: Machine<'mir, 'tcx>>: Sized { /// Gets this value's layout. fn layout(&self) -> TyAndLayout<'tcx>; /// Makes this into an `OpTy`, in a cheap way that is good for reading. fn to_op_for_read( &self, ecx: &InterpCx<'mir, 'tcx, M>, ) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>>; /// Makes this into an `OpTy`, in a potentially more expensive way that is good for projections. fn to_op_for_proj( &self, ecx: &mut InterpCx<'mir, 'tcx, M>, ) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>>; /// Creates this from an `OpTy`. /// /// If `to_op_for_proj` only ever produces `Indirect` operands, then this one is definitely `Indirect`. fn from_op(op: &OpTy<'tcx, M::Provenance>) -> Self; /// Projects to the given enum variant. fn project_downcast( &self, ecx: &mut InterpCx<'mir, 'tcx, M>, variant: VariantIdx, ) -> InterpResult<'tcx, Self>; /// Projects to the n-th field. fn project_field( &self, ecx: &mut InterpCx<'mir, 'tcx, M>, field: usize, ) -> InterpResult<'tcx, Self>; } // We cannot have a general impl which shows that Value implies ValueMut. (When we do, it says we // cannot `impl ValueMut for PlaceTy` because some downstream crate could `impl Value for PlaceTy`.) // So we have some copy-paste here. (We could have a macro but since we only have 2 types with this // double-impl, that would barely make the code shorter, if at all.) impl<'mir, 'tcx: 'mir, M: Machine<'mir, 'tcx>> Value<'mir, 'tcx, M> for OpTy<'tcx, M::Provenance> { #[inline(always)] fn layout(&self) -> TyAndLayout<'tcx> { self.layout } #[inline(always)] fn to_op_for_read( &self, _ecx: &InterpCx<'mir, 'tcx, M>, ) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> { Ok(self.clone()) } #[inline(always)] fn from_op(op: &OpTy<'tcx, M::Provenance>) -> Self { op.clone() } #[inline(always)] fn project_downcast( &self, ecx: &InterpCx<'mir, 'tcx, M>, variant: VariantIdx, ) -> InterpResult<'tcx, Self> { ecx.operand_downcast(self, variant) } #[inline(always)] fn project_field( &self, ecx: &InterpCx<'mir, 'tcx, M>, field: usize, ) -> InterpResult<'tcx, Self> { ecx.operand_field(self, field) } } impl<'mir, 'tcx: 'mir, M: Machine<'mir, 'tcx>> ValueMut<'mir, 'tcx, M> for OpTy<'tcx, M::Provenance> { #[inline(always)] fn layout(&self) -> TyAndLayout<'tcx> { self.layout } #[inline(always)] fn to_op_for_read( &self, _ecx: &InterpCx<'mir, 'tcx, M>, ) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> { Ok(self.clone()) } #[inline(always)] fn to_op_for_proj( &self, _ecx: &mut InterpCx<'mir, 'tcx, M>, ) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> { Ok(self.clone()) } #[inline(always)] fn from_op(op: &OpTy<'tcx, M::Provenance>) -> Self { op.clone() } #[inline(always)] fn project_downcast( &self, ecx: &mut InterpCx<'mir, 'tcx, M>, variant: VariantIdx, ) -> InterpResult<'tcx, Self> { ecx.operand_downcast(self, variant) } #[inline(always)] fn project_field( &self, ecx: &mut InterpCx<'mir, 'tcx, M>, field: usize, ) -> InterpResult<'tcx, Self> { ecx.operand_field(self, field) } } impl<'mir, 'tcx: 'mir, M: Machine<'mir, 'tcx>> Value<'mir, 'tcx, M> for MPlaceTy<'tcx, M::Provenance> { #[inline(always)] fn layout(&self) -> TyAndLayout<'tcx> { self.layout } #[inline(always)] fn to_op_for_read( &self, _ecx: &InterpCx<'mir, 'tcx, M>, ) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> { Ok(self.into()) } #[inline(always)] fn from_op(op: &OpTy<'tcx, M::Provenance>) -> Self { // assert is justified because our `to_op_for_read` only ever produces `Indirect` operands. op.assert_mem_place() } #[inline(always)] fn project_downcast( &self, ecx: &InterpCx<'mir, 'tcx, M>, variant: VariantIdx, ) -> InterpResult<'tcx, Self> { ecx.mplace_downcast(self, variant) } #[inline(always)] fn project_field( &self, ecx: &InterpCx<'mir, 'tcx, M>, field: usize, ) -> InterpResult<'tcx, Self> { ecx.mplace_field(self, field) } } impl<'mir, 'tcx: 'mir, M: Machine<'mir, 'tcx>> ValueMut<'mir, 'tcx, M> for MPlaceTy<'tcx, M::Provenance> { #[inline(always)] fn layout(&self) -> TyAndLayout<'tcx> { self.layout } #[inline(always)] fn to_op_for_read( &self, _ecx: &InterpCx<'mir, 'tcx, M>, ) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> { Ok(self.into()) } #[inline(always)] fn to_op_for_proj( &self, _ecx: &mut InterpCx<'mir, 'tcx, M>, ) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> { Ok(self.into()) } #[inline(always)] fn from_op(op: &OpTy<'tcx, M::Provenance>) -> Self { // assert is justified because our `to_op_for_proj` only ever produces `Indirect` operands. op.assert_mem_place() } #[inline(always)] fn project_downcast( &self, ecx: &mut InterpCx<'mir, 'tcx, M>, variant: VariantIdx, ) -> InterpResult<'tcx, Self> { ecx.mplace_downcast(self, variant) } #[inline(always)] fn project_field( &self, ecx: &mut InterpCx<'mir, 'tcx, M>, field: usize, ) -> InterpResult<'tcx, Self> { ecx.mplace_field(self, field) } } impl<'mir, 'tcx: 'mir, M: Machine<'mir, 'tcx>> ValueMut<'mir, 'tcx, M> for PlaceTy<'tcx, M::Provenance> { #[inline(always)] fn layout(&self) -> TyAndLayout<'tcx> { self.layout } #[inline(always)] fn to_op_for_read( &self, ecx: &InterpCx<'mir, 'tcx, M>, ) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> { // We `force_allocation` here so that `from_op` below can work. ecx.place_to_op(self) } #[inline(always)] fn to_op_for_proj( &self, ecx: &mut InterpCx<'mir, 'tcx, M>, ) -> InterpResult<'tcx, OpTy<'tcx, M::Provenance>> { // We `force_allocation` here so that `from_op` below can work. Ok(ecx.force_allocation(self)?.into()) } #[inline(always)] fn from_op(op: &OpTy<'tcx, M::Provenance>) -> Self { // assert is justified because our `to_op` only ever produces `Indirect` operands. op.assert_mem_place().into() } #[inline(always)] fn project_downcast( &self, ecx: &mut InterpCx<'mir, 'tcx, M>, variant: VariantIdx, ) -> InterpResult<'tcx, Self> { ecx.place_downcast(self, variant) } #[inline(always)] fn project_field( &self, ecx: &mut InterpCx<'mir, 'tcx, M>, field: usize, ) -> InterpResult<'tcx, Self> { ecx.place_field(self, field) } } macro_rules! make_value_visitor { ($visitor_trait:ident, $value_trait:ident, $($mutability:ident)?) => { /// How to traverse a value and what to do when we are at the leaves. pub trait $visitor_trait<'mir, 'tcx: 'mir, M: Machine<'mir, 'tcx>>: Sized { type V: $value_trait<'mir, 'tcx, M>; /// The visitor must have an `InterpCx` in it. fn ecx(&$($mutability)? self) -> &$($mutability)? InterpCx<'mir, 'tcx, M>; /// `read_discriminant` can be hooked for better error messages. #[inline(always)] fn read_discriminant( &mut self, op: &OpTy<'tcx, M::Provenance>, ) -> InterpResult<'tcx, VariantIdx> { Ok(self.ecx().read_discriminant(op)?.1) } // Recursive actions, ready to be overloaded. /// Visits the given value, dispatching as appropriate to more specialized visitors. #[inline(always)] fn visit_value(&mut self, v: &Self::V) -> InterpResult<'tcx> { self.walk_value(v) } /// Visits the given value as a union. No automatic recursion can happen here. #[inline(always)] fn visit_union(&mut self, _v: &Self::V, _fields: NonZeroUsize) -> InterpResult<'tcx> { Ok(()) } /// Visits the given value as the pointer of a `Box`. There is nothing to recurse into. /// The type of `v` will be a raw pointer, but this is a field of `Box` and the /// pointee type is the actual `T`. #[inline(always)] fn visit_box(&mut self, _v: &Self::V) -> InterpResult<'tcx> { Ok(()) } /// Visits this value as an aggregate, you are getting an iterator yielding /// all the fields (still in an `InterpResult`, you have to do error handling yourself). /// Recurses into the fields. #[inline(always)] fn visit_aggregate( &mut self, v: &Self::V, fields: impl Iterator>, ) -> InterpResult<'tcx> { self.walk_aggregate(v, fields) } /// Called each time we recurse down to a field of a "product-like" aggregate /// (structs, tuples, arrays and the like, but not enums), passing in old (outer) /// and new (inner) value. /// This gives the visitor the chance to track the stack of nested fields that /// we are descending through. #[inline(always)] fn visit_field( &mut self, _old_val: &Self::V, _field: usize, new_val: &Self::V, ) -> InterpResult<'tcx> { self.visit_value(new_val) } /// Called when recursing into an enum variant. /// This gives the visitor the chance to track the stack of nested fields that /// we are descending through. #[inline(always)] fn visit_variant( &mut self, _old_val: &Self::V, _variant: VariantIdx, new_val: &Self::V, ) -> InterpResult<'tcx> { self.visit_value(new_val) } // Default recursors. Not meant to be overloaded. fn walk_aggregate( &mut self, v: &Self::V, fields: impl Iterator>, ) -> InterpResult<'tcx> { // Now iterate over it. for (idx, field_val) in fields.enumerate() { self.visit_field(v, idx, &field_val?)?; } Ok(()) } fn walk_value(&mut self, v: &Self::V) -> InterpResult<'tcx> { let ty = v.layout().ty; trace!("walk_value: type: {ty}"); // Special treatment for special types, where the (static) layout is not sufficient. match *ty.kind() { // If it is a trait object, switch to the real type that was used to create it. ty::Dynamic(..) => { // unsized values are never immediate, so we can assert_mem_place let op = v.to_op_for_read(self.ecx())?; let dest = op.assert_mem_place(); let inner_mplace = self.ecx().unpack_dyn_trait(&dest)?; trace!("walk_value: dyn object layout: {:#?}", inner_mplace.layout); // recurse with the inner type return self.visit_field(&v, 0, &$value_trait::from_op(&inner_mplace.into())); }, // Slices do not need special handling here: they have `Array` field // placement with length 0, so we enter the `Array` case below which // indirectly uses the metadata to determine the actual length. // However, `Box`... let's talk about `Box`. ty::Adt(def, ..) if def.is_box() => { // `Box` is a hybrid primitive-library-defined type that one the one hand is // a dereferenceable pointer, on the other hand has *basically arbitrary // user-defined layout* since the user controls the 'allocator' field. So it // cannot be treated like a normal pointer, since it does not fit into an // `Immediate`. Yeah, it is quite terrible. But many visitors want to do // something with "all boxed pointers", so we handle this mess for them. // // When we hit a `Box`, we do not do the usual `visit_aggregate`; instead, // we (a) call `visit_box` on the pointer value, and (b) recurse on the // allocator field. We also assert tons of things to ensure we do not miss // any other fields. // `Box` has two fields: the pointer we care about, and the allocator. assert_eq!(v.layout().fields.count(), 2, "`Box` must have exactly 2 fields"); let (unique_ptr, alloc) = (v.project_field(self.ecx(), 0)?, v.project_field(self.ecx(), 1)?); // Unfortunately there is some type junk in the way here: `unique_ptr` is a `Unique`... // (which means another 2 fields, the second of which is a `PhantomData`) assert_eq!(unique_ptr.layout().fields.count(), 2); let (nonnull_ptr, phantom) = ( unique_ptr.project_field(self.ecx(), 0)?, unique_ptr.project_field(self.ecx(), 1)?, ); assert!( phantom.layout().ty.ty_adt_def().is_some_and(|adt| adt.is_phantom_data()), "2nd field of `Unique` should be PhantomData but is {:?}", phantom.layout().ty, ); // ... that contains a `NonNull`... (gladly, only a single field here) assert_eq!(nonnull_ptr.layout().fields.count(), 1); let raw_ptr = nonnull_ptr.project_field(self.ecx(), 0)?; // the actual raw ptr // ... whose only field finally is a raw ptr we can dereference. self.visit_box(&raw_ptr)?; // The second `Box` field is the allocator, which we recursively check for validity // like in regular structs. self.visit_field(v, 1, &alloc)?; // We visited all parts of this one. return Ok(()); } _ => {}, }; // Visit the fields of this value. match &v.layout().fields { FieldsShape::Primitive => {} &FieldsShape::Union(fields) => { self.visit_union(v, fields)?; } FieldsShape::Arbitrary { offsets, .. } => { // FIXME: We collect in a vec because otherwise there are lifetime // errors: Projecting to a field needs access to `ecx`. let fields: Vec> = (0..offsets.len()).map(|i| { v.project_field(self.ecx(), i) }) .collect(); self.visit_aggregate(v, fields.into_iter())?; } FieldsShape::Array { .. } => { // Let's get an mplace (or immediate) first. // This might `force_allocate` if `v` is a `PlaceTy`, but `place_index` does that anyway. let op = v.to_op_for_proj(self.ecx())?; // Now we can go over all the fields. // This uses the *run-time length*, i.e., if we are a slice, // the dynamic info from the metadata is used. let iter = self.ecx().operand_array_fields(&op)? .map(|f| f.and_then(|f| { Ok($value_trait::from_op(&f)) })); self.visit_aggregate(v, iter)?; } } match v.layout().variants { // If this is a multi-variant layout, find the right variant and proceed // with *its* fields. Variants::Multiple { .. } => { let op = v.to_op_for_read(self.ecx())?; let idx = self.read_discriminant(&op)?; let inner = v.project_downcast(self.ecx(), idx)?; trace!("walk_value: variant layout: {:#?}", inner.layout()); // recurse with the inner type self.visit_variant(v, idx, &inner) } // For single-variant layouts, we already did anything there is to do. Variants::Single { .. } => Ok(()) } } } } } make_value_visitor!(ValueVisitor, Value,); make_value_visitor!(MutValueVisitor, ValueMut, mut);