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Documentation updates to better share the purpose of OnceCell/OnceLock

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This commit is contained in:
Trevor Gross
2022-12-12 04:16:18 -05:00
committed by Trevor Gross
parent dc4ba57566
commit d1b28b75d2
3 changed files with 76 additions and 28 deletions
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93
library/core/src/cell.rs
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@@ -11,36 +11,77 @@
//! mutate it.
//!
//! Shareable mutable containers exist to permit mutability in a controlled manner, even in the
//! presence of aliasing. Both [`Cell<T>`] and [`RefCell<T>`] allow doing this in a single-threaded
//! way. However, neither `Cell<T>` nor `RefCell<T>` are thread safe (they do not implement
//! [`Sync`]). If you need to do aliasing and mutation between multiple threads it is possible to
//! use [`Mutex<T>`], [`RwLock<T>`] or [`atomic`] types.
//! presence of aliasing. [`Cell<T>`], [`RefCell<T>`], and [`OnceCell<T>`] allow doing this in
//! a single-threaded way - they do not implement [`Sync`]. (If you need to do aliasing and
//! mutation among multiple threads, [`Mutex<T>`], [`RwLock<T>`], [`OnceLock<T>`] or [`atomic`]
//! types are the correct data structures to do so).
//!
//! Values of the `Cell<T>` and `RefCell<T>` types may be mutated through shared references (i.e.
//! the common `&T` type), whereas most Rust types can only be mutated through unique (`&mut T`)
//! references. We say that `Cell<T>` and `RefCell<T>` provide 'interior mutability', in contrast
//! with typical Rust types that exhibit 'inherited mutability'.
//! Values of the `Cell<T>`, `RefCell<T>`, and `OnceCell<T>` types may be mutated through shared
//! references (i.e. the common `&T` type), whereas most Rust types can only be mutated through
//! unique (`&mut T`) references. We say these cell types provide 'interior mutability'
//! (mutable via `&T`), in contrast with typical Rust types that exhibit 'inherited mutability'
//! (mutable only via `&mut T`).
//!
//! Cell types come in two flavors: `Cell<T>` and `RefCell<T>`. `Cell<T>` implements interior
//! mutability by moving values in and out of the `Cell<T>`. To use references instead of values,
//! one must use the `RefCell<T>` type, acquiring a write lock before mutating. `Cell<T>` provides
//! methods to retrieve and change the current interior value:
//! Cell types come in three flavors: `Cell<T>`, `RefCell<T>`, and `OnceCell<T>`. Each provides
//! a different way of providing safe interior mutability.
//!
//! ## `Cell<T>`
//!
//! [`Cell<T>`] implements interior mutability by moving values in and out of the cell. That is, an
//! `&mut T` to the inner value can never be obtained, and the value itself cannot be directly
//! obtained without replacing it with something else. Both of these rules ensure that there is
//! never more than one reference pointing to the inner value. This type provides the following
//! methods:
//!
//! - For types that implement [`Copy`], the [`get`](Cell::get) method retrieves the current
//! interior value.
//! interior value by duplicating it.
//! - For types that implement [`Default`], the [`take`](Cell::take) method replaces the current
//! interior value with [`Default::default()`] and returns the replaced value.
//! - For all types, the [`replace`](Cell::replace) method replaces the current interior value and
//! returns the replaced value and the [`into_inner`](Cell::into_inner) method consumes the
//! `Cell<T>` and returns the interior value. Additionally, the [`set`](Cell::set) method
//! replaces the interior value, dropping the replaced value.
//! - All types have:
//! - [`replace`](Cell::replace): replaces the current interior value and returns the replaced
//! value.
//! - [`into_inner`](Cell::into_inner): this method consumes the `Cell<T>` and returns the
//! interior value.
//! - [`set`](Cell::set): this method replaces the interior value, dropping the replaced value.
//!
//! `RefCell<T>` uses Rust's lifetimes to implement 'dynamic borrowing', a process whereby one can
//! `Cell<T>` is typically used for more simple types where copying or moving values isn't too
//! resource intensive (e.g. numbers), and should usually be preferred over other cell types when
//! possible. For larger and non-copy types, `RefCell` provides some advantages.
//!
//! ## `RefCell<T>`
//!
//! [`RefCell<T>`] uses Rust's lifetimes to implement "dynamic borrowing", a process whereby one can
//! claim temporary, exclusive, mutable access to the inner value. Borrows for `RefCell<T>`s are
//! tracked 'at runtime', unlike Rust's native reference types which are entirely tracked
//! statically, at compile time. Because `RefCell<T>` borrows are dynamic it is possible to attempt
//! to borrow a value that is already mutably borrowed; when this happens it results in thread
//! panic.
//! tracked at _runtime_, unlike Rust's native reference types which are entirely tracked
//! statically, at compile time.
//!
//! An immutable reference to a `RefCell`'s inner value (`&T`) can be obtained with
//! [`borrow`](`RefCell::borrow`), and a mutable borrow (`&mut T`) can be obtained with
//! [`borrow_mut`](`RefCell::borrow_mut`). When these functions are called, they first verify that
//! Rust's borrow rules will be satisfied: any number of immutable borrows are allowed or a
//! single immutable borrow is allowed, but never both. If a borrow is attempted that would violate
//! these rules, the thread will panic.
//!
//! The corresponding [`Sync`] version of `RefCell<T>` is [`RwLock<T>`].
//!
//! ## `OnceCell<T>`
//!
//! [`OnceCell<T>`] is somewhat of a hybrid of `Cell` and `RefCell` that works for values that
//! typically only need to be set once. This means that a reference `&T` can be obtained without
//! moving or copying the inner value (unlike `Cell`) but also without runtime checks (unlike
//! `RefCell`). However, its value can also not be updated once set unless you have a mutable
//! reference to the `OnceCell`.
//!
//! `OnceCell` provides the following methods:
//!
//! - [`get`](OnceCell::get): obtain a reference to the inner value
//! - [`set`](OnceCell::set): set the inner value if it is unset (returns a `Result`)
//! - [`get_or_init`](OnceCell::get_or_init): return the inner value, initializing it if needed
//! - [`get_mut`](OnceCell::get_mut): provide a mutable reference to the inner value, only available
//! if you have a mutable reference to the cell itself.
//!
//! The corresponding [`Sync`] version of `OnceCell<T>` is [`OnceLock<T>`].
//!
//!
//! # When to choose interior mutability
//!
@@ -188,6 +229,8 @@
//! [`Rc<T>`]: ../../std/rc/struct.Rc.html
//! [`RwLock<T>`]: ../../std/sync/struct.RwLock.html
//! [`Mutex<T>`]: ../../std/sync/struct.Mutex.html
//! [`OnceLock<T>`]: ../../std/sync/struct.OnceLock.html
//! [`Sync`]: ../../std/marker/trait.Sync.html
//! [`atomic`]: crate::sync::atomic
#![stable(feature = "rust1", since = "1.0.0")]
@@ -419,7 +462,7 @@ impl<T> Cell<T> {
mem::replace(unsafe { &mut *self.value.get() }, val)
}
/// Unwraps the value.
/// Unwraps the value, consuming the cell.
///
/// # Examples
///
@@ -1969,7 +2012,7 @@ impl<T> UnsafeCell<T> {
UnsafeCell { value }
}
/// Unwraps the value.
/// Unwraps the value, consuming the cell.
///
/// # Examples
///
@@ -2133,7 +2176,7 @@ impl<T> SyncUnsafeCell<T> {
Self { value: UnsafeCell { value } }
}
/// Unwraps the value.
/// Unwraps the value, consuming the cell.
#[inline]
pub const fn into_inner(self) -> T {
self.value.into_inner()