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//! Traits for conversions between types.
//!
//! The traits in this module provide a way to convert from one type to another type.
//! Each trait serves a different purpose:
//!
//! - Implement the [`AsRef`] trait for cheap reference-to-reference conversions
//! - Implement the [`AsMut`] trait for cheap mutable-to-mutable conversions
//! - Implement the [`From`] trait for consuming value-to-value conversions
//! - Implement the [`Into`] trait for consuming value-to-value conversions to types
//! outside the current crate
//! - The [`TryFrom`] and [`TryInto`] traits behave like [`From`] and [`Into`],
//! but should be implemented when the conversion can fail.
//!
//! The traits in this module are often used as trait bounds for generic functions such that to
//! arguments of multiple types are supported. See the documentation of each trait for examples.
//!
//! As a library author, you should always prefer implementing [`From<T>`][`From`] or
//! [`TryFrom<T>`][`TryFrom`] rather than [`Into<U>`][`Into`] or [`TryInto<U>`][`TryInto`],
//! as [`From`] and [`TryFrom`] provide greater flexibility and offer
//! equivalent [`Into`] or [`TryInto`] implementations for free, thanks to a
//! blanket implementation in the standard library. When targeting a version prior to Rust 1.41, it
//! may be necessary to implement [`Into`] or [`TryInto`] directly when converting to a type
//! outside the current crate.
//!
//! # Generic Implementations
//!
//! - [`AsRef`] and [`AsMut`] auto-dereference if the inner type is a reference
//! - [`From`]`<U> for T` implies [`Into`]`<T> for U`
//! - [`TryFrom`]`<U> for T` implies [`TryInto`]`<T> for U`
//! - [`From`] and [`Into`] are reflexive, which means that all types can
//! `into` themselves and `from` themselves
//!
//! See each trait for usage examples.
#![stable(feature = "rust1", since = "1.0.0")]
use crate::fmt;
use crate::hash::{Hash, Hasher};
mod num;
#[unstable(feature = "convert_float_to_int", issue = "67057")]
pub use num::FloatToInt;
/// The identity function.
///
/// Two things are important to note about this function:
///
/// - It is not always equivalent to a closure like `|x| x`, since the
/// closure may coerce `x` into a different type.
///
/// - It moves the input `x` passed to the function.
///
/// While it might seem strange to have a function that just returns back the
/// input, there are some interesting uses.
///
/// # Examples
///
/// Using `identity` to do nothing in a sequence of other, interesting,
/// functions:
///
/// ```rust
/// use std::convert::identity;
///
/// fn manipulation(x: u32) -> u32 {
/// // Let's pretend that adding one is an interesting function.
/// x + 1
/// }
///
/// let _arr = &[identity, manipulation];
/// ```
///
/// Using `identity` as a "do nothing" base case in a conditional:
///
/// ```rust
/// use std::convert::identity;
///
/// # let condition = true;
/// #
/// # fn manipulation(x: u32) -> u32 { x + 1 }
/// #
/// let do_stuff = if condition { manipulation } else { identity };
///
/// // Do more interesting stuff...
///
/// let _results = do_stuff(42);
/// ```
///
/// Using `identity` to keep the `Some` variants of an iterator of `Option<T>`:
///
/// ```rust
/// use std::convert::identity;
///
/// let iter = [Some(1), None, Some(3)].into_iter();
/// let filtered = iter.filter_map(identity).collect::<Vec<_>>();
/// assert_eq!(vec![1, 3], filtered);
/// ```
#[stable(feature = "convert_id", since = "1.33.0")]
#[rustc_const_stable(feature = "const_identity", since = "1.33.0")]
#[inline]
pub const fn identity<T>(x: T) -> T {
x
}
/// Used to do a cheap reference-to-reference conversion.
///
/// This trait is similar to [`AsMut`] which is used for converting between mutable references.
/// If you need to do a costly conversion it is better to implement [`From`] with type
/// `&T` or write a custom function.
///
/// `AsRef` has the same signature as [`Borrow`], but [`Borrow`] is different in few aspects:
///
/// - Unlike `AsRef`, [`Borrow`] has a blanket impl for any `T`, and can be used to accept either
/// a reference or a value.
/// - [`Borrow`] also requires that [`Hash`], [`Eq`] and [`Ord`] for borrowed value are
/// equivalent to those of the owned value. For this reason, if you want to
/// borrow only a single field of a struct you can implement `AsRef`, but not [`Borrow`].
///
/// **Note: This trait must not fail**. If the conversion can fail, use a
/// dedicated method which returns an [`Option<T>`] or a [`Result<T, E>`].
///
/// # Generic Implementations
///
/// - `AsRef` auto-dereferences if the inner type is a reference or a mutable
/// reference (e.g.: `foo.as_ref()` will work the same if `foo` has type
/// `&mut Foo` or `&&mut Foo`)
///
/// # Examples
///
/// By using trait bounds we can accept arguments of different types as long as they can be
/// converted to the specified type `T`.
///
/// For example: By creating a generic function that takes an `AsRef<str>` we express that we
/// want to accept all references that can be converted to [`&str`] as an argument.
/// Since both [`String`] and [`&str`] implement `AsRef<str>` we can accept both as input argument.
///
/// [`&str`]: primitive@str
/// [`Borrow`]: crate::borrow::Borrow
/// [`Eq`]: crate::cmp::Eq
/// [`Ord`]: crate::cmp::Ord
/// [`String`]: ../../std/string/struct.String.html
///
/// ```
/// fn is_hello<T: AsRef<str>>(s: T) {
/// assert_eq!("hello", s.as_ref());
/// }
///
/// let s = "hello";
/// is_hello(s);
///
/// let s = "hello".to_string();
/// is_hello(s);
/// ```
#[stable(feature = "rust1", since = "1.0.0")]
#[cfg_attr(not(test), rustc_diagnostic_item = "AsRef")]
pub trait AsRef<T: ?Sized> {
/// Performs the conversion.
#[stable(feature = "rust1", since = "1.0.0")]
fn as_ref(&self) -> &T;
}
/// Used to do a cheap mutable-to-mutable reference conversion.
///
/// This trait is similar to [`AsRef`] but used for converting between mutable
/// references. If you need to do a costly conversion it is better to
/// implement [`From`] with type `&mut T` or write a custom function.
///
/// **Note: This trait must not fail**. If the conversion can fail, use a
/// dedicated method which returns an [`Option<T>`] or a [`Result<T, E>`].
///
/// # Generic Implementations
///
/// - `AsMut` auto-dereferences if the inner type is a mutable reference
/// (e.g.: `foo.as_mut()` will work the same if `foo` has type `&mut Foo`
/// or `&mut &mut Foo`)
///
/// # Examples
///
/// Using `AsMut` as trait bound for a generic function we can accept all mutable references
/// that can be converted to type `&mut T`. Because [`Box<T>`] implements `AsMut<T>` we can
/// write a function `add_one` that takes all arguments that can be converted to `&mut u64`.
/// Because [`Box<T>`] implements `AsMut<T>`, `add_one` accepts arguments of type
/// `&mut Box<u64>` as well:
///
/// ```
/// fn add_one<T: AsMut<u64>>(num: &mut T) {
/// *num.as_mut() += 1;
/// }
///
/// let mut boxed_num = Box::new(0);
/// add_one(&mut boxed_num);
/// assert_eq!(*boxed_num, 1);
/// ```
///
/// [`Box<T>`]: ../../std/boxed/struct.Box.html
#[stable(feature = "rust1", since = "1.0.0")]
#[cfg_attr(not(test), rustc_diagnostic_item = "AsMut")]
pub trait AsMut<T: ?Sized> {
/// Performs the conversion.
#[stable(feature = "rust1", since = "1.0.0")]
fn as_mut(&mut self) -> &mut T;
}
/// A value-to-value conversion that consumes the input value. The
/// opposite of [`From`].
///
/// One should avoid implementing [`Into`] and implement [`From`] instead.
/// Implementing [`From`] automatically provides one with an implementation of [`Into`]
/// thanks to the blanket implementation in the standard library.
///
/// Prefer using [`Into`] over [`From`] when specifying trait bounds on a generic function
/// to ensure that types that only implement [`Into`] can be used as well.
///
/// **Note: This trait must not fail**. If the conversion can fail, use [`TryInto`].
///
/// # Generic Implementations
///
/// - [`From`]`<T> for U` implies `Into<U> for T`
/// - [`Into`] is reflexive, which means that `Into<T> for T` is implemented
///
/// # Implementing [`Into`] for conversions to external types in old versions of Rust
///
/// Prior to Rust 1.41, if the destination type was not part of the current crate
/// then you couldn't implement [`From`] directly.
/// For example, take this code:
///
/// ```
/// struct Wrapper<T>(Vec<T>);
/// impl<T> From<Wrapper<T>> for Vec<T> {
/// fn from(w: Wrapper<T>) -> Vec<T> {
/// w.0
/// }
/// }
/// ```
/// This will fail to compile in older versions of the language because Rust's orphaning rules
/// used to be a little bit more strict. To bypass this, you could implement [`Into`] directly:
///
/// ```
/// struct Wrapper<T>(Vec<T>);
/// impl<T> Into<Vec<T>> for Wrapper<T> {
/// fn into(self) -> Vec<T> {
/// self.0
/// }
/// }
/// ```
///
/// It is important to understand that [`Into`] does not provide a [`From`] implementation
/// (as [`From`] does with [`Into`]). Therefore, you should always try to implement [`From`]
/// and then fall back to [`Into`] if [`From`] can't be implemented.
///
/// # Examples
///
/// [`String`] implements [`Into`]`<`[`Vec`]`<`[`u8`]`>>`:
///
/// In order to express that we want a generic function to take all arguments that can be
/// converted to a specified type `T`, we can use a trait bound of [`Into`]`<T>`.
/// For example: The function `is_hello` takes all arguments that can be converted into a
/// [`Vec`]`<`[`u8`]`>`.
///
/// ```
/// fn is_hello<T: Into<Vec<u8>>>(s: T) {
/// let bytes = b"hello".to_vec();
/// assert_eq!(bytes, s.into());
/// }
///
/// let s = "hello".to_string();
/// is_hello(s);
/// ```
///
/// [`String`]: ../../std/string/struct.String.html
/// [`Vec`]: ../../std/vec/struct.Vec.html
#[rustc_diagnostic_item = "Into"]
#[stable(feature = "rust1", since = "1.0.0")]
pub trait Into<T>: Sized {
/// Performs the conversion.
#[must_use]
#[stable(feature = "rust1", since = "1.0.0")]
fn into(self) -> T;
}
/// Used to do value-to-value conversions while consuming the input value. It is the reciprocal of
/// [`Into`].
///
/// One should always prefer implementing `From` over [`Into`]
/// because implementing `From` automatically provides one with an implementation of [`Into`]
/// thanks to the blanket implementation in the standard library.
///
/// Only implement [`Into`] when targeting a version prior to Rust 1.41 and converting to a type
/// outside the current crate.
/// `From` was not able to do these types of conversions in earlier versions because of Rust's
/// orphaning rules.
/// See [`Into`] for more details.
///
/// Prefer using [`Into`] over using `From` when specifying trait bounds on a generic function.
/// This way, types that directly implement [`Into`] can be used as arguments as well.
///
/// The `From` is also very useful when performing error handling. When constructing a function
/// that is capable of failing, the return type will generally be of the form `Result<T, E>`.
/// The `From` trait simplifies error handling by allowing a function to return a single error type
/// that encapsulate multiple error types. See the "Examples" section and [the book][book] for more
/// details.
///
/// **Note: This trait must not fail**. If the conversion can fail, use [`TryFrom`].
///
/// # Generic Implementations
///
/// - `From<T> for U` implies [`Into`]`<U> for T`
/// - `From` is reflexive, which means that `From<T> for T` is implemented
///
/// # Examples
///
/// [`String`] implements `From<&str>`:
///
/// An explicit conversion from a `&str` to a String is done as follows:
///
/// ```
/// let string = "hello".to_string();
/// let other_string = String::from("hello");
///
/// assert_eq!(string, other_string);
/// ```
///
/// While performing error handling it is often useful to implement `From` for your own error type.
/// By converting underlying error types to our own custom error type that encapsulates the
/// underlying error type, we can return a single error type without losing information on the
/// underlying cause. The '?' operator automatically converts the underlying error type to our
/// custom error type by calling `Into<CliError>::into` which is automatically provided when
/// implementing `From`. The compiler then infers which implementation of `Into` should be used.
///
/// ```
/// use std::fs;
/// use std::io;
/// use std::num;
///
/// enum CliError {
/// IoError(io::Error),
/// ParseError(num::ParseIntError),
/// }
///
/// impl From<io::Error> for CliError {
/// fn from(error: io::Error) -> Self {
/// CliError::IoError(error)
/// }
/// }
///
/// impl From<num::ParseIntError> for CliError {
/// fn from(error: num::ParseIntError) -> Self {
/// CliError::ParseError(error)
/// }
/// }
///
/// fn open_and_parse_file(file_name: &str) -> Result<i32, CliError> {
/// let mut contents = fs::read_to_string(&file_name)?;
/// let num: i32 = contents.trim().parse()?;
/// Ok(num)
/// }
/// ```
///
/// [`String`]: ../../std/string/struct.String.html
/// [`from`]: From::from
/// [book]: ../../book/ch09-00-error-handling.html
#[rustc_diagnostic_item = "From"]
#[stable(feature = "rust1", since = "1.0.0")]
#[rustc_on_unimplemented(on(
all(_Self = "&str", T = "std::string::String"),
note = "to coerce a `{T}` into a `{Self}`, use `&*` as a prefix",
))]
pub trait From<T>: Sized {
/// Performs the conversion.
#[lang = "from"]
#[must_use]
#[stable(feature = "rust1", since = "1.0.0")]
fn from(_: T) -> Self;
}
/// An attempted conversion that consumes `self`, which may or may not be
/// expensive.
///
/// Library authors should usually not directly implement this trait,
/// but should prefer implementing the [`TryFrom`] trait, which offers
/// greater flexibility and provides an equivalent `TryInto`
/// implementation for free, thanks to a blanket implementation in the
/// standard library. For more information on this, see the
/// documentation for [`Into`].
///
/// # Implementing `TryInto`
///
/// This suffers the same restrictions and reasoning as implementing
/// [`Into`], see there for details.
#[rustc_diagnostic_item = "TryInto"]
#[stable(feature = "try_from", since = "1.34.0")]
pub trait TryInto<T>: Sized {
/// The type returned in the event of a conversion error.
#[stable(feature = "try_from", since = "1.34.0")]
type Error;
/// Performs the conversion.
#[stable(feature = "try_from", since = "1.34.0")]
fn try_into(self) -> Result<T, Self::Error>;
}
/// Simple and safe type conversions that may fail in a controlled
/// way under some circumstances. It is the reciprocal of [`TryInto`].
///
/// This is useful when you are doing a type conversion that may
/// trivially succeed but may also need special handling.
/// For example, there is no way to convert an [`i64`] into an [`i32`]
/// using the [`From`] trait, because an [`i64`] may contain a value
/// that an [`i32`] cannot represent and so the conversion would lose data.
/// This might be handled by truncating the [`i64`] to an [`i32`] (essentially
/// giving the [`i64`]'s value modulo [`i32::MAX`]) or by simply returning
/// [`i32::MAX`], or by some other method. The [`From`] trait is intended
/// for perfect conversions, so the `TryFrom` trait informs the
/// programmer when a type conversion could go bad and lets them
/// decide how to handle it.
///
/// # Generic Implementations
///
/// - `TryFrom<T> for U` implies [`TryInto`]`<U> for T`
/// - [`try_from`] is reflexive, which means that `TryFrom<T> for T`
/// is implemented and cannot fail -- the associated `Error` type for
/// calling `T::try_from()` on a value of type `T` is [`Infallible`].
/// When the [`!`] type is stabilized [`Infallible`] and [`!`] will be
/// equivalent.
///
/// `TryFrom<T>` can be implemented as follows:
///
/// ```
/// struct GreaterThanZero(i32);
///
/// impl TryFrom<i32> for GreaterThanZero {
/// type Error = &'static str;
///
/// fn try_from(value: i32) -> Result<Self, Self::Error> {
/// if value <= 0 {
/// Err("GreaterThanZero only accepts value superior than zero!")
/// } else {
/// Ok(GreaterThanZero(value))
/// }
/// }
/// }
/// ```
///
/// # Examples
///
/// As described, [`i32`] implements `TryFrom<`[`i64`]`>`:
///
/// ```
/// let big_number = 1_000_000_000_000i64;
/// // Silently truncates `big_number`, requires detecting
/// // and handling the truncation after the fact.
/// let smaller_number = big_number as i32;
/// assert_eq!(smaller_number, -727379968);
///
/// // Returns an error because `big_number` is too big to
/// // fit in an `i32`.
/// let try_smaller_number = i32::try_from(big_number);
/// assert!(try_smaller_number.is_err());
///
/// // Returns `Ok(3)`.
/// let try_successful_smaller_number = i32::try_from(3);
/// assert!(try_successful_smaller_number.is_ok());
/// ```
///
/// [`try_from`]: TryFrom::try_from
#[rustc_diagnostic_item = "TryFrom"]
#[stable(feature = "try_from", since = "1.34.0")]
pub trait TryFrom<T>: Sized {
/// The type returned in the event of a conversion error.
#[stable(feature = "try_from", since = "1.34.0")]
type Error;
/// Performs the conversion.
#[stable(feature = "try_from", since = "1.34.0")]
fn try_from(value: T) -> Result<Self, Self::Error>;
}
////////////////////////////////////////////////////////////////////////////////
// GENERIC IMPLS
////////////////////////////////////////////////////////////////////////////////
// As lifts over &
#[stable(feature = "rust1", since = "1.0.0")]
#[rustc_const_unstable(feature = "const_convert", issue = "88674")]
impl<T: ?Sized, U: ?Sized> const AsRef<U> for &T
where
T: ~const AsRef<U>,
{
fn as_ref(&self) -> &U {
<T as AsRef<U>>::as_ref(*self)
}
}
// As lifts over &mut
#[stable(feature = "rust1", since = "1.0.0")]
#[rustc_const_unstable(feature = "const_convert", issue = "88674")]
impl<T: ?Sized, U: ?Sized> const AsRef<U> for &mut T
where
T: ~const AsRef<U>,
{
fn as_ref(&self) -> &U {
<T as AsRef<U>>::as_ref(*self)
}
}
// FIXME (#45742): replace the above impls for &/&mut with the following more general one:
// // As lifts over Deref
// impl<D: ?Sized + Deref<Target: AsRef<U>>, U: ?Sized> AsRef<U> for D {
// fn as_ref(&self) -> &U {
// self.deref().as_ref()
// }
// }
// AsMut lifts over &mut
#[stable(feature = "rust1", since = "1.0.0")]
#[rustc_const_unstable(feature = "const_convert", issue = "88674")]
impl<T: ?Sized, U: ?Sized> const AsMut<U> for &mut T
where
T: ~const AsMut<U>,
{
fn as_mut(&mut self) -> &mut U {
(*self).as_mut()
}
}
// FIXME (#45742): replace the above impl for &mut with the following more general one:
// // AsMut lifts over DerefMut
// impl<D: ?Sized + Deref<Target: AsMut<U>>, U: ?Sized> AsMut<U> for D {
// fn as_mut(&mut self) -> &mut U {
// self.deref_mut().as_mut()
// }
// }
// From implies Into
#[stable(feature = "rust1", since = "1.0.0")]
#[rustc_const_unstable(feature = "const_convert", issue = "88674")]
impl<T, U> const Into<U> for T
where
U: ~const From<T>,
{
fn into(self) -> U {
U::from(self)
}
}
// From (and thus Into) is reflexive
#[stable(feature = "rust1", since = "1.0.0")]
#[rustc_const_unstable(feature = "const_convert", issue = "88674")]
impl<T> const From<T> for T {
fn from(t: T) -> T {
t
}
}
/// **Stability note:** This impl does not yet exist, but we are
/// "reserving space" to add it in the future. See
/// [rust-lang/rust#64715][#64715] for details.
///
/// [#64715]: https://github.com/rust-lang/rust/issues/64715
#[stable(feature = "convert_infallible", since = "1.34.0")]
#[allow(unused_attributes)] // FIXME(#58633): do a principled fix instead.
#[rustc_reservation_impl = "permitting this impl would forbid us from adding \
`impl<T> From<!> for T` later; see rust-lang/rust#64715 for details"]
#[rustc_const_unstable(feature = "const_convert", issue = "88674")]
impl<T> const From<!> for T {
fn from(t: !) -> T {
t
}
}
// TryFrom implies TryInto
#[stable(feature = "try_from", since = "1.34.0")]
#[rustc_const_unstable(feature = "const_convert", issue = "88674")]
impl<T, U> const TryInto<U> for T
where
U: ~const TryFrom<T>,
{
type Error = U::Error;
fn try_into(self) -> Result<U, U::Error> {
U::try_from(self)
}
}
// Infallible conversions are semantically equivalent to fallible conversions
// with an uninhabited error type.
#[stable(feature = "try_from", since = "1.34.0")]
#[rustc_const_unstable(feature = "const_convert", issue = "88674")]
impl<T, U> const TryFrom<U> for T
where
U: ~const Into<T>,
{
type Error = Infallible;
fn try_from(value: U) -> Result<Self, Self::Error> {
Ok(U::into(value))
}
}
////////////////////////////////////////////////////////////////////////////////
// CONCRETE IMPLS
////////////////////////////////////////////////////////////////////////////////
#[stable(feature = "rust1", since = "1.0.0")]
impl<T> AsRef<[T]> for [T] {
fn as_ref(&self) -> &[T] {
self
}
}
#[stable(feature = "rust1", since = "1.0.0")]
impl<T> AsMut<[T]> for [T] {
fn as_mut(&mut self) -> &mut [T] {
self
}
}
#[stable(feature = "rust1", since = "1.0.0")]
impl AsRef<str> for str {
#[inline]
fn as_ref(&self) -> &str {
self
}
}
#[stable(feature = "as_mut_str_for_str", since = "1.51.0")]
impl AsMut<str> for str {
#[inline]
fn as_mut(&mut self) -> &mut str {
self
}
}
////////////////////////////////////////////////////////////////////////////////
// THE NO-ERROR ERROR TYPE
////////////////////////////////////////////////////////////////////////////////
/// The error type for errors that can never happen.
///
/// Since this enum has no variant, a value of this type can never actually exist.
/// This can be useful for generic APIs that use [`Result`] and parameterize the error type,
/// to indicate that the result is always [`Ok`].
///
/// For example, the [`TryFrom`] trait (conversion that returns a [`Result`])
/// has a blanket implementation for all types where a reverse [`Into`] implementation exists.
///
/// ```ignore (illustrates std code, duplicating the impl in a doctest would be an error)
/// impl<T, U> TryFrom<U> for T where U: Into<T> {
/// type Error = Infallible;
///
/// fn try_from(value: U) -> Result<Self, Infallible> {
/// Ok(U::into(value)) // Never returns `Err`
/// }
/// }
/// ```
///
/// # Future compatibility
///
/// This enum has the same role as [the `!` “never” type][never],
/// which is unstable in this version of Rust.
/// When `!` is stabilized, we plan to make `Infallible` a type alias to it:
///
/// ```ignore (illustrates future std change)
/// pub type Infallible = !;
/// ```
///
/// … and eventually deprecate `Infallible`.
///
/// However there is one case where `!` syntax can be used
/// before `!` is stabilized as a full-fledged type: in the position of a function’s return type.
/// Specifically, it is possible to have implementations for two different function pointer types:
///
/// ```
/// trait MyTrait {}
/// impl MyTrait for fn() -> ! {}
/// impl MyTrait for fn() -> std::convert::Infallible {}
/// ```
///
/// With `Infallible` being an enum, this code is valid.
/// However when `Infallible` becomes an alias for the never type,
/// the two `impl`s will start to overlap
/// and therefore will be disallowed by the language’s trait coherence rules.
#[stable(feature = "convert_infallible", since = "1.34.0")]
#[derive(Copy)]
pub enum Infallible {}
#[stable(feature = "convert_infallible", since = "1.34.0")]
impl Clone for Infallible {
fn clone(&self) -> Infallible {
match *self {}
}
}
#[stable(feature = "convert_infallible", since = "1.34.0")]
impl fmt::Debug for Infallible {
fn fmt(&self, _: &mut fmt::Formatter<'_>) -> fmt::Result {
match *self {}
}
}
#[stable(feature = "convert_infallible", since = "1.34.0")]
impl fmt::Display for Infallible {
fn fmt(&self, _: &mut fmt::Formatter<'_>) -> fmt::Result {
match *self {}
}
}
#[stable(feature = "convert_infallible", since = "1.34.0")]
impl PartialEq for Infallible {
fn eq(&self, _: &Infallible) -> bool {
match *self {}
}
}
#[stable(feature = "convert_infallible", since = "1.34.0")]
impl Eq for Infallible {}
#[stable(feature = "convert_infallible", since = "1.34.0")]
impl PartialOrd for Infallible {
fn partial_cmp(&self, _other: &Self) -> Option<crate::cmp::Ordering> {
match *self {}
}
}
#[stable(feature = "convert_infallible", since = "1.34.0")]
impl Ord for Infallible {
fn cmp(&self, _other: &Self) -> crate::cmp::Ordering {
match *self {}
}
}
#[stable(feature = "convert_infallible", since = "1.34.0")]
#[rustc_const_unstable(feature = "const_convert", issue = "88674")]
impl const From<!> for Infallible {
fn from(x: !) -> Self {
x
}
}
#[stable(feature = "convert_infallible_hash", since = "1.44.0")]
impl Hash for Infallible {
fn hash<H: Hasher>(&self, _: &mut H) {
match *self {}
}
}