use crate::ty::{self, Ty, TyCtxt}; use rustc_hir as hir; use rustc_hir::lang_items::LangItem; use rustc_macros::HashStable; use rustc_span::Span; use rustc_target::abi::FieldIdx; #[derive(Clone, Copy, Debug, PartialEq, Eq, TyEncodable, TyDecodable, Hash, HashStable)] pub enum PointerCoercion { /// Go from a fn-item type to a fn-pointer type. ReifyFnPointer, /// Go from a safe fn pointer to an unsafe fn pointer. UnsafeFnPointer, /// Go from a non-capturing closure to an fn pointer or an unsafe fn pointer. /// It cannot convert a closure that requires unsafe. ClosureFnPointer(hir::Unsafety), /// Go from a mut raw pointer to a const raw pointer. MutToConstPointer, /// Go from `*const [T; N]` to `*const T` ArrayToPointer, /// Unsize a pointer/reference value, e.g., `&[T; n]` to /// `&[T]`. Note that the source could be a thin or fat pointer. /// This will do things like convert thin pointers to fat /// pointers, or convert structs containing thin pointers to /// structs containing fat pointers, or convert between fat /// pointers. We don't store the details of how the transform is /// done (in fact, we don't know that, because it might depend on /// the precise type parameters). We just store the target /// type. Codegen backends and miri figure out what has to be done /// based on the precise source/target type at hand. Unsize, } /// Represents coercing a value to a different type of value. /// /// We transform values by following a number of `Adjust` steps in order. /// See the documentation on variants of `Adjust` for more details. /// /// Here are some common scenarios: /// /// 1. The simplest cases are where a pointer is not adjusted fat vs thin. /// Here the pointer will be dereferenced N times (where a dereference can /// happen to raw or borrowed pointers or any smart pointer which implements /// `Deref`, including `Box<_>`). The types of dereferences is given by /// `autoderefs`. It can then be auto-referenced zero or one times, indicated /// by `autoref`, to either a raw or borrowed pointer. In these cases unsize is /// `false`. /// /// 2. A thin-to-fat coercion involves unsizing the underlying data. We start /// with a thin pointer, deref a number of times, unsize the underlying data, /// then autoref. The 'unsize' phase may change a fixed length array to a /// dynamically sized one, a concrete object to a trait object, or statically /// sized struct to a dynamically sized one. E.g., `&[i32; 4]` -> `&[i32]` is /// represented by: /// /// ```ignore (illustrative) /// Deref(None) -> [i32; 4], /// Borrow(AutoBorrow::Ref) -> &[i32; 4], /// Unsize -> &[i32], /// ``` /// /// Note that for a struct, the 'deep' unsizing of the struct is not recorded. /// E.g., `struct Foo { x: T }` we can coerce `&Foo<[i32; 4]>` to `&Foo<[i32]>` /// The autoderef and -ref are the same as in the above example, but the type /// stored in `unsize` is `Foo<[i32]>`, we don't store any further detail about /// the underlying conversions from `[i32; 4]` to `[i32]`. /// /// 3. Coercing a `Box` to `Box` is an interesting special case. In /// that case, we have the pointer we need coming in, so there are no /// autoderefs, and no autoref. Instead we just do the `Unsize` transformation. /// At some point, of course, `Box` should move out of the compiler, in which /// case this is analogous to transforming a struct. E.g., `Box<[i32; 4]>` -> /// `Box<[i32]>` is an `Adjust::Unsize` with the target `Box<[i32]>`. #[derive(Clone, TyEncodable, TyDecodable, HashStable, TypeFoldable, TypeVisitable)] pub struct Adjustment<'tcx> { pub kind: Adjust<'tcx>, pub target: Ty<'tcx>, } impl<'tcx> Adjustment<'tcx> { pub fn is_region_borrow(&self) -> bool { matches!(self.kind, Adjust::Borrow(AutoBorrow::Ref(..))) } } #[derive(Clone, Debug, TyEncodable, TyDecodable, HashStable, TypeFoldable, TypeVisitable)] pub enum Adjust<'tcx> { /// Go from ! to any type. NeverToAny, /// Dereference once, producing a place. Deref(Option>), /// Take the address and produce either a `&` or `*` pointer. Borrow(AutoBorrow<'tcx>), Pointer(PointerCoercion), /// Cast into a dyn* object. DynStar, } /// An overloaded autoderef step, representing a `Deref(Mut)::deref(_mut)` /// call, with the signature `&'a T -> &'a U` or `&'a mut T -> &'a mut U`. /// The target type is `U` in both cases, with the region and mutability /// being those shared by both the receiver and the returned reference. #[derive(Copy, Clone, PartialEq, Debug, TyEncodable, TyDecodable, HashStable)] #[derive(TypeFoldable, TypeVisitable)] pub struct OverloadedDeref<'tcx> { pub region: ty::Region<'tcx>, pub mutbl: hir::Mutability, /// The `Span` associated with the field access or method call /// that triggered this overloaded deref. pub span: Span, } impl<'tcx> OverloadedDeref<'tcx> { /// Get the zst function item type for this method call. pub fn method_call(&self, tcx: TyCtxt<'tcx>, source: Ty<'tcx>) -> Ty<'tcx> { let trait_def_id = match self.mutbl { hir::Mutability::Not => tcx.require_lang_item(LangItem::Deref, None), hir::Mutability::Mut => tcx.require_lang_item(LangItem::DerefMut, None), }; let method_def_id = tcx .associated_items(trait_def_id) .in_definition_order() .find(|m| m.kind == ty::AssocKind::Fn) .unwrap() .def_id; Ty::new_fn_def(tcx, method_def_id, [source]) } } /// At least for initial deployment, we want to limit two-phase borrows to /// only a few specific cases. Right now, those are mostly "things that desugar" /// into method calls: /// - using `x.some_method()` syntax, where some_method takes `&mut self`, /// - using `Foo::some_method(&mut x, ...)` syntax, /// - binary assignment operators (`+=`, `-=`, `*=`, etc.). /// Anything else should be rejected until generalized two-phase borrow support /// is implemented. Right now, dataflow can't handle the general case where there /// is more than one use of a mutable borrow, and we don't want to accept too much /// new code via two-phase borrows, so we try to limit where we create two-phase /// capable mutable borrows. /// See #49434 for tracking. #[derive(Copy, Clone, PartialEq, Debug, TyEncodable, TyDecodable, HashStable)] pub enum AllowTwoPhase { Yes, No, } #[derive(Copy, Clone, PartialEq, Debug, TyEncodable, TyDecodable, HashStable)] pub enum AutoBorrowMutability { Mut { allow_two_phase_borrow: AllowTwoPhase }, Not, } impl AutoBorrowMutability { /// Creates an `AutoBorrowMutability` from a mutability and allowance of two phase borrows. /// /// Note that when `mutbl.is_not()`, `allow_two_phase_borrow` is ignored pub fn new(mutbl: hir::Mutability, allow_two_phase_borrow: AllowTwoPhase) -> Self { match mutbl { hir::Mutability::Not => Self::Not, hir::Mutability::Mut => Self::Mut { allow_two_phase_borrow }, } } } impl From for hir::Mutability { fn from(m: AutoBorrowMutability) -> Self { match m { AutoBorrowMutability::Mut { .. } => hir::Mutability::Mut, AutoBorrowMutability::Not => hir::Mutability::Not, } } } #[derive(Copy, Clone, PartialEq, Debug, TyEncodable, TyDecodable, HashStable)] #[derive(TypeFoldable, TypeVisitable)] pub enum AutoBorrow<'tcx> { /// Converts from T to &T. Ref(ty::Region<'tcx>, AutoBorrowMutability), /// Converts from T to *T. RawPtr(hir::Mutability), } /// Information for `CoerceUnsized` impls, storing information we /// have computed about the coercion. /// /// This struct can be obtained via the `coerce_impl_info` query. /// Demanding this struct also has the side-effect of reporting errors /// for inappropriate impls. #[derive(Clone, Copy, TyEncodable, TyDecodable, Debug, HashStable)] pub struct CoerceUnsizedInfo { /// If this is a "custom coerce" impl, then what kind of custom /// coercion is it? This applies to impls of `CoerceUnsized` for /// structs, primarily, where we store a bit of info about which /// fields need to be coerced. pub custom_kind: Option, } #[derive(Clone, Copy, TyEncodable, TyDecodable, Debug, HashStable)] pub enum CustomCoerceUnsized { /// Records the index of the field being coerced. Struct(FieldIdx), }