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Rollup merge of #110340 - jmaargh:jmaargh/deref-docs, r=Mark-Simulacrum
Deref docs: expand and remove "smart pointer" qualifier **Ready for review** ~~This is an unpolished draft to be sanity-checked~~ Fixes #91004 ~~Comments on substance and content of this are welcome. This is deliberately unpolished until ready to review so please try to stay focused on the big-picture.~~ ~~Once this has been sanity checked, I will similarly update `DerefMut` and polish for review.~~
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@ -138,7 +138,7 @@ pub const fn identity<T>(x: T) -> T {
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///
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/// [dereferenceable types]: core::ops::Deref
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/// [pointed-to value]: core::ops::Deref::Target
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/// ['`Deref` coercion']: core::ops::Deref#more-on-deref-coercion
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/// ['`Deref` coercion']: core::ops::Deref#deref-coercion
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///
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/// ```
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/// let x = Box::new(5i32);
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@ -244,7 +244,7 @@ pub trait AsRef<T: ?Sized> {
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///
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/// [mutably dereferenceable types]: core::ops::DerefMut
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/// [pointed-to value]: core::ops::Deref::Target
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/// ['`Deref` coercion']: core::ops::DerefMut#more-on-deref-coercion
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/// ['`Deref` coercion']: core::ops::DerefMut#mutable-deref-coercion
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///
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/// ```
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/// let mut x = Box::new(5i32);
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@ -3,40 +3,107 @@
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/// In addition to being used for explicit dereferencing operations with the
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/// (unary) `*` operator in immutable contexts, `Deref` is also used implicitly
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/// by the compiler in many circumstances. This mechanism is called
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/// ['`Deref` coercion'][more]. In mutable contexts, [`DerefMut`] is used.
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/// ["`Deref` coercion"][coercion]. In mutable contexts, [`DerefMut`] is used and
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/// mutable deref coercion similarly occurs.
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///
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/// Implementing `Deref` for smart pointers makes accessing the data behind them
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/// convenient, which is why they implement `Deref`. On the other hand, the
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/// rules regarding `Deref` and [`DerefMut`] were designed specifically to
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/// accommodate smart pointers. Because of this, **`Deref` should only be
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/// implemented for smart pointers** to avoid confusion.
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/// **Warning:** Deref coercion is a powerful language feature which has
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/// far-reaching implications for every type that implements `Deref`. The
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/// compiler will silently insert calls to `Deref::deref`. For this reason, one
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/// should be careful about implementing `Deref` and only do so when deref
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/// coercion is desirable. See [below][implementing] for advice on when this is
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/// typically desirable or undesirable.
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///
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/// For similar reasons, **this trait should never fail**. Failure during
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/// dereferencing can be extremely confusing when `Deref` is invoked implicitly.
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/// Types that implement `Deref` or `DerefMut` are often called "smart
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/// pointers" and the mechanism of deref coercion has been specifically designed
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/// to facilitate the pointer-like behaviour that name suggests. Often, the
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/// purpose of a "smart pointer" type is to change the ownership semantics
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/// of a contained value (for example, [`Rc`][rc] or [`Cow`][cow]) or the
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/// storage semantics of a contained value (for example, [`Box`][box]).
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///
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/// Violating these requirements is a logic error. The behavior resulting from a logic error is not
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/// specified, but users of the trait must ensure that such logic errors do *not* result in
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/// undefined behavior. This means that `unsafe` code **must not** rely on the correctness of this
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/// method.
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/// # Deref coercion
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///
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/// # More on `Deref` coercion
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/// If `T` implements `Deref<Target = U>`, and `v` is a value of type `T`, then:
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///
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/// If `T` implements `Deref<Target = U>`, and `x` is a value of type `T`, then:
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///
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/// * In immutable contexts, `*x` (where `T` is neither a reference nor a raw pointer)
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/// is equivalent to `*Deref::deref(&x)`.
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/// * In immutable contexts, `*v` (where `T` is neither a reference nor a raw
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/// pointer) is equivalent to `*Deref::deref(&v)`.
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/// * Values of type `&T` are coerced to values of type `&U`
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/// * `T` implicitly implements all the (immutable) methods of the type `U`.
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/// * `T` implicitly implements all the methods of the type `U` which take the
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/// `&self` receiver.
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///
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/// For more details, visit [the chapter in *The Rust Programming Language*][book]
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/// as well as the reference sections on [the dereference operator][ref-deref-op],
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/// [method resolution] and [type coercions].
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/// [method resolution], and [type coercions].
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///
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/// # When to implement `Deref` or `DerefMut`
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///
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/// The same advice applies to both deref traits. In general, deref traits
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/// **should** be implemented if:
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///
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/// 1. a value of the type transparently behaves like a value of the target
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/// type;
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/// 1. the implementation of the deref function is cheap; and
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/// 1. users of the type will not be surprised by any deref coercion behaviour.
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///
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/// In general, deref traits **should not** be implemented if:
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///
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/// 1. the deref implementations could fail unexpectedly; or
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/// 1. the type has methods that are likely to collide with methods on the
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/// target type; or
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/// 1. committing to deref coercion as part of the public API is not desirable.
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///
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/// Note that there's a large difference between implementing deref traits
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/// generically over many target types, and doing so only for specific target
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/// types.
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///
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/// Generic implementations, such as for [`Box<T>`][box] (which is generic over
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/// every type and dereferences to `T`) should be careful to provide few or no
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/// methods, since the target type is unknown and therefore every method could
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/// collide with one on the target type, causing confusion for users.
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/// `impl<T> Box<T>` has no methods (though several associated functions),
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/// partly for this reason.
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///
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/// Specific implementations, such as for [`String`][string] (whose `Deref`
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/// implementation has `Target = str`) can have many methods, since avoiding
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/// collision is much easier. `String` and `str` both have many methods, and
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/// `String` additionally behaves as if it has every method of `str` because of
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/// deref coercion. The implementing type may also be generic while the
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/// implementation is still specific in this sense; for example, [`Vec<T>`][vec]
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/// dereferences to `[T]`, so methods of `T` are not applicable.
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///
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/// Consider also that deref coericion means that deref traits are a much larger
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/// part of a type's public API than any other trait as it is implicitly called
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/// by the compiler. Therefore, it is advisable to consider whether this is
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/// something you are comfortable supporting as a public API.
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///
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/// The [`AsRef`] and [`Borrow`][core::borrow::Borrow] traits have very similar
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/// signatures to `Deref`. It may be desirable to implement either or both of
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/// these, whether in addition to or rather than deref traits. See their
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/// documentation for details.
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///
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/// # Fallibility
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///
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/// **This trait's method should never unexpectedly fail**. Deref coercion means
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/// the compiler will often insert calls to `Deref::deref` implicitly. Failure
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/// during dereferencing can be extremely confusing when `Deref` is invoked
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/// implicitly. In the majority of uses it should be infallible, though it may
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/// be acceptable to panic if the type is misused through programmer error, for
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/// example.
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///
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/// However, infallibility is not enforced and therefore not guaranteed.
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/// As such, `unsafe` code should not rely on infallibility in general for
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/// soundness.
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///
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/// [book]: ../../book/ch15-02-deref.html
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/// [more]: #more-on-deref-coercion
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/// [coercion]: #deref-coercion
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/// [implementing]: #when-to-implement-deref-or-derefmut
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/// [ref-deref-op]: ../../reference/expressions/operator-expr.html#the-dereference-operator
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/// [method resolution]: ../../reference/expressions/method-call-expr.html
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/// [type coercions]: ../../reference/type-coercions.html
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/// [box]: ../../alloc/boxed/struct.Box.html
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/// [string]: ../../alloc/string/struct.String.html
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/// [vec]: ../../alloc/vec/struct.Vec.html
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/// [rc]: ../../alloc/rc/struct.Rc.html
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/// [cow]: ../../alloc/borrow/enum.Cow.html
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///
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/// # Examples
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///
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@ -107,30 +174,29 @@ impl<T: ?Sized> Deref for &mut T {
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/// In addition to being used for explicit dereferencing operations with the
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/// (unary) `*` operator in mutable contexts, `DerefMut` is also used implicitly
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/// by the compiler in many circumstances. This mechanism is called
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/// ['`Deref` coercion'][more]. In immutable contexts, [`Deref`] is used.
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/// ["mutable deref coercion"][coercion]. In immutable contexts, [`Deref`] is used.
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///
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/// Implementing `DerefMut` for smart pointers makes mutating the data behind
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/// them convenient, which is why they implement `DerefMut`. On the other hand,
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/// the rules regarding [`Deref`] and `DerefMut` were designed specifically to
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/// accommodate smart pointers. Because of this, **`DerefMut` should only be
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/// implemented for smart pointers** to avoid confusion.
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/// **Warning:** Deref coercion is a powerful language feature which has
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/// far-reaching implications for every type that implements `DerefMut`. The
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/// compiler will silently insert calls to `DerefMut::deref_mut`. For this
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/// reason, one should be careful about implementing `DerefMut` and only do so
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/// when mutable deref coercion is desirable. See [the `Deref` docs][implementing]
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/// for advice on when this is typically desirable or undesirable.
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///
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/// For similar reasons, **this trait should never fail**. Failure during
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/// dereferencing can be extremely confusing when `DerefMut` is invoked
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/// implicitly.
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/// Types that implement `DerefMut` or `Deref` are often called "smart
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/// pointers" and the mechanism of deref coercion has been specifically designed
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/// to facilitate the pointer-like behaviour that name suggests. Often, the
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/// purpose of a "smart pointer" type is to change the ownership semantics
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/// of a contained value (for example, [`Rc`][rc] or [`Cow`][cow]) or the
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/// storage semantics of a contained value (for example, [`Box`][box]).
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///
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/// Violating these requirements is a logic error. The behavior resulting from a logic error is not
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/// specified, but users of the trait must ensure that such logic errors do *not* result in
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/// undefined behavior. This means that `unsafe` code **must not** rely on the correctness of this
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/// method.
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/// # Mutable deref coercion
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///
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/// # More on `Deref` coercion
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///
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/// If `T` implements `DerefMut<Target = U>`, and `x` is a value of type `T`,
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/// If `T` implements `DerefMut<Target = U>`, and `v` is a value of type `T`,
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/// then:
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///
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/// * In mutable contexts, `*x` (where `T` is neither a reference nor a raw pointer)
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/// is equivalent to `*DerefMut::deref_mut(&mut x)`.
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/// * In mutable contexts, `*v` (where `T` is neither a reference nor a raw pointer)
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/// is equivalent to `*DerefMut::deref_mut(&mut v)`.
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/// * Values of type `&mut T` are coerced to values of type `&mut U`
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/// * `T` implicitly implements all the (mutable) methods of the type `U`.
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///
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@ -138,11 +204,29 @@ impl<T: ?Sized> Deref for &mut T {
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/// as well as the reference sections on [the dereference operator][ref-deref-op],
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/// [method resolution] and [type coercions].
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///
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/// # Fallibility
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///
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/// **This trait's method should never unexpectedly fail**. Deref coercion means
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/// the compiler will often insert calls to `DerefMut::deref_mut` implicitly.
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/// Failure during dereferencing can be extremely confusing when `DerefMut` is
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/// invoked implicitly. In the majority of uses it should be infallible, though
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/// it may be acceptable to panic if the type is misused through programmer
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/// error, for example.
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///
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/// However, infallibility is not enforced and therefore not guaranteed.
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/// As such, `unsafe` code should not rely on infallibility in general for
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/// soundness.
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///
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/// [book]: ../../book/ch15-02-deref.html
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/// [more]: #more-on-deref-coercion
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/// [coercion]: #mutable-deref-coercion
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/// [implementing]: Deref#when-to-implement-deref-or-derefmut
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/// [ref-deref-op]: ../../reference/expressions/operator-expr.html#the-dereference-operator
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/// [method resolution]: ../../reference/expressions/method-call-expr.html
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/// [type coercions]: ../../reference/type-coercions.html
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/// [box]: ../../alloc/boxed/struct.Box.html
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/// [string]: ../../alloc/string/struct.String.html
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/// [rc]: ../../alloc/rc/struct.Rc.html
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/// [cow]: ../../alloc/borrow/enum.Cow.html
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///
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/// # Examples
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///
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