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//! # Overview //! //! `once_cell` provides two new cell-like types, [`unsync::OnceCell`] and [`sync::OnceCell`]. A `OnceCell` //! might store arbitrary non-`Copy` types, can be assigned to at most once and provides direct access //! to the stored contents. The core API looks *roughly* like this (and there's much more inside, read on!): //! //! ```rust,ignore //! impl<T> OnceCell<T> { //! fn new() -> OnceCell<T> { ... } //! fn set(&self, value: T) -> Result<(), T> { ... } //! fn get(&self) -> Option<&T> { ... } //! } //! ``` //! //! Note that, like with [`RefCell`] and [`Mutex`], the `set` method requires only a shared reference. //! Because of the single assignment restriction `get` can return a `&T` instead of `Ref<T>` //! or `MutexGuard<T>`. //! //! The `sync` flavor is thread-safe (that is, implements the [`Sync`] trait), while the `unsync` one is not. //! //! [`unsync::OnceCell`]: unsync/struct.OnceCell.html //! [`sync::OnceCell`]: sync/struct.OnceCell.html //! [`RefCell`]: https://doc.rust-lang.org/std/cell/struct.RefCell.html //! [`Mutex`]: https://doc.rust-lang.org/std/sync/struct.Mutex.html //! [`Sync`]: https://doc.rust-lang.org/std/marker/trait.Sync.html //! //! # Patterns //! //! `OnceCell` might be useful for a variety of patterns. //! //! ## Safe Initialization of global data //! //! ```rust //! use std::{env, io}; //! //! use once_cell::sync::OnceCell; //! //! #[derive(Debug)] //! pub struct Logger { //! // ... //! } //! static INSTANCE: OnceCell<Logger> = OnceCell::new(); //! //! impl Logger { //! pub fn global() -> &'static Logger { //! INSTANCE.get().expect("logger is not initialized") //! } //! //! fn from_cli(args: env::Args) -> Result<Logger, std::io::Error> { //! // ... //! # Ok(Logger {}) //! } //! } //! //! fn main() { //! let logger = Logger::from_cli(env::args()).unwrap(); //! INSTANCE.set(logger).unwrap(); //! // use `Logger::global()` from now on //! } //! ``` //! //! ## Lazy initialized global data //! //! This is essentially the `lazy_static!` macro, but without a macro. //! //! ```rust //! use std::{sync::Mutex, collections::HashMap}; //! //! use once_cell::sync::OnceCell; //! //! fn global_data() -> &'static Mutex<HashMap<i32, String>> { //! static INSTANCE: OnceCell<Mutex<HashMap<i32, String>>> = OnceCell::new(); //! INSTANCE.get_or_init(|| { //! let mut m = HashMap::new(); //! m.insert(13, "Spica".to_string()); //! m.insert(74, "Hoyten".to_string()); //! Mutex::new(m) //! }) //! } //! ``` //! //! There are also the [`sync::Lazy`] and [`unsync::Lazy`] convenience types to streamline this pattern: //! //! ```rust //! use std::{sync::Mutex, collections::HashMap}; //! use once_cell::sync::Lazy; //! //! static GLOBAL_DATA: Lazy<Mutex<HashMap<i32, String>>> = Lazy::new(|| { //! let mut m = HashMap::new(); //! m.insert(13, "Spica".to_string()); //! m.insert(74, "Hoyten".to_string()); //! Mutex::new(m) //! }); //! //! fn main() { //! println!("{:?}", GLOBAL_DATA.lock().unwrap()); //! } //! ``` //! //! [`sync::Lazy`]: sync/struct.Lazy.html //! [`unsync::Lazy`]: unsync/struct.Lazy.html //! //! ## General purpose lazy evaluation //! //! Unlike `lazy_static!`, `Lazy` works with local variables. //! //! ```rust //! use once_cell::unsync::Lazy; //! //! fn main() { //! let ctx = vec![1, 2, 3]; //! let thunk = Lazy::new(|| { //! ctx.iter().sum::<i32>() //! }); //! assert_eq!(*thunk, 6); //! } //! ``` //! //! If you need a lazy field in a struct, you probably should use `OnceCell` //! directly, because that will allow you to access `self` during initialization. //! //! ```rust //! use std::{fs, path::PathBuf}; //! //! use once_cell::unsync::OnceCell; //! //! struct Ctx { //! config_path: PathBuf, //! config: OnceCell<String>, //! } //! //! impl Ctx { //! pub fn get_config(&self) -> Result<&str, std::io::Error> { //! let cfg = self.config.get_or_try_init(|| { //! fs::read_to_string(&self.config_path) //! })?; //! Ok(cfg.as_str()) //! } //! } //! ``` //! //! ## Building block //! //! Naturally, it is possible to build other abstractions on top of `OnceCell`. //! For example, this is a `regex!` macro which takes a string literal and returns an //! *expression* that evaluates to a `&'static Regex`: //! //! ``` //! macro_rules! regex { //! ($re:literal $(,)?) => {{ //! static RE: once_cell::sync::OnceCell<regex::Regex> = once_cell::sync::OnceCell::new(); //! RE.get_or_init(|| regex::Regex::new($re).unwrap()) //! }}; //! } //! ``` //! //! This macro can be useful to avoid the "compile regex on every loop iteration" problem. //! //! Another pattern would be a `LateInit` type for delayed initialization: //! //! //! ``` //! use once_cell::sync::OnceCell; //! //! #[derive(Debug)] //! pub struct LateInit<T> { cell: OnceCell<T> } //! //! impl<T> LateInit<T> { //! pub fn init(&self, value: T) { //! assert!(self.cell.set(value).is_ok()) //! } //! } //! //! impl<T> Default for LateInit<T> { //! fn default() -> Self { LateInit { cell: OnceCell::default() } } //! } //! //! impl<T> std::ops::Deref for LateInit<T> { //! type Target = T; //! fn deref(&self) -> &T { //! self.cell.get().unwrap() //! } //! } //! //! #[derive(Default, Debug)] //! struct A<'a> { //! b: LateInit<&'a B<'a>>, //! } //! //! #[derive(Default, Debug)] //! struct B<'a> { //! a: LateInit<&'a A<'a>> //! } //! //! fn build_cycle() { //! let a = A::default(); //! let b = B::default(); //! a.b.init(&b); //! b.a.init(&a); //! println!("{:?}", a.b.a.b.a); //! } //! ``` //! //! # Comparison with std //! //! |`!Sync` types | Access Mode | Drawbacks | //! |----------------------|------------------------|-----------------------------------------------| //! |`Cell<T>` | `T` | requires `T: Copy` for `get` | //! |`RefCell<T>` | `RefMut<T>` / `Ref<T>` | may panic at runtime | //! |`unsync::OnceCell<T>` | `&T` | assignable only once | //! //! |`Sync` types | Access Mode | Drawbacks | //! |----------------------|------------------------|-----------------------------------------------| //! |`AtomicT` | `T` | works only with certain `Copy` types | //! |`Mutex<T>` | `MutexGuard<T>` | may deadlock at runtime, may block the thread | //! |`sync::OnceCell<T>` | `&T` | assignable only once, may block the thread | //! //! Technically, calling `get_or_init` will also cause a panic or a deadlock if it recursively calls //! itself. However, because the assignment can happen only once, such cases should be more rare than //! equivalents with `RefCell` and `Mutex`. //! //! # Minimum Supported `rustc` Version //! //! This crate's minimum supported `rustc` version is `1.36.0`. //! //! If only the `std` feature is enabled, MSRV will be updated conservatively. //! When using other features, like `parking_lot`, MSRV might be updated more frequently, up to the latest stable. //! In both cases, increasing MSRV is *not* considered a semver-breaking change. //! //! # Implementation details //! //! The implementation is based on the [`lazy_static`](https://github.com/rust-lang-nursery/lazy-static.rs/) //! and [`lazy_cell`](https://github.com/indiv0/lazycell/) crates and [`std::sync::Once`]. In some sense, //! `once_cell` just streamlines and unifies those APIs. //! //! To implement a sync flavor of `OnceCell`, this crates uses either a custom //! re-implementation of `std::sync::Once` or `parking_lot::Mutex`. This is //! controlled by the `parking_lot` feature (disabled by default). Performance //! is the same for both cases, but the `parking_lot` based `OnceCell<T>` is //! smaller by up to 16 bytes. //! //! This crate uses `unsafe`. //! //! [`std::sync::Once`]: https://doc.rust-lang.org/std/sync/struct.Once.html //! //! # F.A.Q. //! //! **Should I use lazy_static or once_cell?** //! //! To the first approximation, `once_cell` is both more flexible and more convenient than `lazy_static` //! and should be preferred. //! //! Unlike `once_cell`, `lazy_static` supports spinlock-based implementation of blocking which works with //! `#![no_std]`. //! //! `lazy_static` has received significantly more real world testing, but `once_cell` is also a widely //! used crate. //! //! **Should I use the sync or unsync flavor?** //! //! Because Rust compiler checks thread safety for you, it's impossible to accidentally use `unsync` where //! `sync` is required. So, use `unsync` in single-threaded code and `sync` in multi-threaded. It's easy //! to switch between the two if code becomes multi-threaded later. //! //! At the moment, `unsync` has an additional benefit that reentrant initialization causes a panic, which //! might be easier to debug than a deadlock. //! //! # Related crates //! //! * [double-checked-cell](https://github.com/niklasf/double-checked-cell) //! * [lazy-init](https://crates.io/crates/lazy-init) //! * [lazycell](https://crates.io/crates/lazycell) //! * [mitochondria](https://crates.io/crates/mitochondria) //! * [lazy_static](https://crates.io/crates/lazy_static) //! //! Most of this crate's functionality is available in `std` in nightly Rust. //! See the [tracking issue](https://github.com/rust-lang/rust/issues/74465). #![cfg_attr(not(feature = "std"), no_std)] #[cfg(feature = "alloc")] extern crate alloc; #[cfg(feature = "std")] #[cfg(feature = "parking_lot")] #[path = "imp_pl.rs"] mod imp; #[cfg(feature = "std")] #[cfg(not(feature = "parking_lot"))] #[path = "imp_std.rs"] mod imp; pub mod unsync { use core::{ cell::{Cell, UnsafeCell}, fmt, mem, ops::{Deref, DerefMut}, }; #[cfg(feature = "std")] use std::panic::{RefUnwindSafe, UnwindSafe}; /// A cell which can be written to only once. It is not thread safe. /// /// Unlike [`std::cell::RefCell`], a `OnceCell` provides simple `&` /// references to the contents. /// /// [`std::cell::RefCell`]: https://doc.rust-lang.org/std/cell/struct.RefCell.html /// /// # Example /// ``` /// use once_cell::unsync::OnceCell; /// /// let cell = OnceCell::new(); /// assert!(cell.get().is_none()); /// /// let value: &String = cell.get_or_init(|| { /// "Hello, World!".to_string() /// }); /// assert_eq!(value, "Hello, World!"); /// assert!(cell.get().is_some()); /// ``` pub struct OnceCell<T> { // Invariant: written to at most once. inner: UnsafeCell<Option<T>>, } // Similarly to a `Sync` bound on `sync::OnceCell`, we can use // `&unsync::OnceCell` to sneak a `T` through `catch_unwind`, // by initializing the cell in closure and extracting the value in the // `Drop`. #[cfg(feature = "std")] impl<T: RefUnwindSafe + UnwindSafe> RefUnwindSafe for OnceCell<T> {} #[cfg(feature = "std")] impl<T: UnwindSafe> UnwindSafe for OnceCell<T> {} impl<T> Default for OnceCell<T> { fn default() -> Self { Self::new() } } impl<T: fmt::Debug> fmt::Debug for OnceCell<T> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match self.get() { Some(v) => f.debug_tuple("OnceCell").field(v).finish(), None => f.write_str("OnceCell(Uninit)"), } } } impl<T: Clone> Clone for OnceCell<T> { fn clone(&self) -> OnceCell<T> { let res = OnceCell::new(); if let Some(value) = self.get() { match res.set(value.clone()) { Ok(()) => (), Err(_) => unreachable!(), } } res } } impl<T: PartialEq> PartialEq for OnceCell<T> { fn eq(&self, other: &Self) -> bool { self.get() == other.get() } } impl<T: Eq> Eq for OnceCell<T> {} impl<T> From<T> for OnceCell<T> { fn from(value: T) -> Self { OnceCell { inner: UnsafeCell::new(Some(value)) } } } impl<T> OnceCell<T> { /// Creates a new empty cell. pub const fn new() -> OnceCell<T> { OnceCell { inner: UnsafeCell::new(None) } } /// Gets a reference to the underlying value. /// /// Returns `None` if the cell is empty. pub fn get(&self) -> Option<&T> { // Safe due to `inner`'s invariant unsafe { &*self.inner.get() }.as_ref() } /// Gets a mutable reference to the underlying value. /// /// Returns `None` if the cell is empty. pub fn get_mut(&mut self) -> Option<&mut T> { // Safe because we have unique access unsafe { &mut *self.inner.get() }.as_mut() } /// Sets the contents of this cell to `value`. /// /// Returns `Ok(())` if the cell was empty and `Err(value)` if it was /// full. /// /// # Example /// ``` /// use once_cell::unsync::OnceCell; /// /// let cell = OnceCell::new(); /// assert!(cell.get().is_none()); /// /// assert_eq!(cell.set(92), Ok(())); /// assert_eq!(cell.set(62), Err(62)); /// /// assert!(cell.get().is_some()); /// ``` pub fn set(&self, value: T) -> Result<(), T> { let slot = unsafe { &*self.inner.get() }; if slot.is_some() { return Err(value); } let slot = unsafe { &mut *self.inner.get() }; // This is the only place where we set the slot, no races // due to reentrancy/concurrency are possible, and we've // checked that slot is currently `None`, so this write // maintains the `inner`'s invariant. *slot = Some(value); Ok(()) } /// Gets the contents of the cell, initializing it with `f` /// if the cell was empty. /// /// # Panics /// /// If `f` panics, the panic is propagated to the caller, and the cell /// remains uninitialized. /// /// It is an error to reentrantly initialize the cell from `f`. Doing /// so results in a panic. /// /// # Example /// ``` /// use once_cell::unsync::OnceCell; /// /// let cell = OnceCell::new(); /// let value = cell.get_or_init(|| 92); /// assert_eq!(value, &92); /// let value = cell.get_or_init(|| unreachable!()); /// assert_eq!(value, &92); /// ``` pub fn get_or_init<F>(&self, f: F) -> &T where F: FnOnce() -> T, { enum Void {} match self.get_or_try_init(|| Ok::<T, Void>(f())) { Ok(val) => val, Err(void) => match void {}, } } /// Gets the contents of the cell, initializing it with `f` if /// the cell was empty. If the cell was empty and `f` failed, an /// error is returned. /// /// # Panics /// /// If `f` panics, the panic is propagated to the caller, and the cell /// remains uninitialized. /// /// It is an error to reentrantly initialize the cell from `f`. Doing /// so results in a panic. /// /// # Example /// ``` /// use once_cell::unsync::OnceCell; /// /// let cell = OnceCell::new(); /// assert_eq!(cell.get_or_try_init(|| Err(())), Err(())); /// assert!(cell.get().is_none()); /// let value = cell.get_or_try_init(|| -> Result<i32, ()> { /// Ok(92) /// }); /// assert_eq!(value, Ok(&92)); /// assert_eq!(cell.get(), Some(&92)) /// ``` pub fn get_or_try_init<F, E>(&self, f: F) -> Result<&T, E> where F: FnOnce() -> Result<T, E>, { if let Some(val) = self.get() { return Ok(val); } let val = f()?; // Note that *some* forms of reentrant initialization might lead to // UB (see `reentrant_init` test). I believe that just removing this // `assert`, while keeping `set/get` would be sound, but it seems // better to panic, rather than to silently use an old value. assert!(self.set(val).is_ok(), "reentrant init"); Ok(self.get().unwrap()) } /// Takes the value out of this `OnceCell`, moving it back to an uninitialized state. /// /// Has no effect and returns `None` if the `OnceCell` hasn't been initialized. /// /// # Examples /// /// ``` /// use once_cell::unsync::OnceCell; /// /// let mut cell: OnceCell<String> = OnceCell::new(); /// assert_eq!(cell.take(), None); /// /// let mut cell = OnceCell::new(); /// cell.set("hello".to_string()).unwrap(); /// assert_eq!(cell.take(), Some("hello".to_string())); /// assert_eq!(cell.get(), None); /// ``` pub fn take(&mut self) -> Option<T> { mem::replace(self, Self::default()).into_inner() } /// Consumes the `OnceCell`, returning the wrapped value. /// /// Returns `None` if the cell was empty. /// /// # Examples /// /// ``` /// use once_cell::unsync::OnceCell; /// /// let cell: OnceCell<String> = OnceCell::new(); /// assert_eq!(cell.into_inner(), None); /// /// let cell = OnceCell::new(); /// cell.set("hello".to_string()).unwrap(); /// assert_eq!(cell.into_inner(), Some("hello".to_string())); /// ``` pub fn into_inner(self) -> Option<T> { // Because `into_inner` takes `self` by value, the compiler statically verifies // that it is not currently borrowed. So it is safe to move out `Option<T>`. self.inner.into_inner() } } /// A value which is initialized on the first access. /// /// # Example /// ``` /// use once_cell::unsync::Lazy; /// /// let lazy: Lazy<i32> = Lazy::new(|| { /// println!("initializing"); /// 92 /// }); /// println!("ready"); /// println!("{}", *lazy); /// println!("{}", *lazy); /// /// // Prints: /// // ready /// // initializing /// // 92 /// // 92 /// ``` pub struct Lazy<T, F = fn() -> T> { cell: OnceCell<T>, init: Cell<Option<F>>, } #[cfg(feature = "std")] impl<T, F: RefUnwindSafe> RefUnwindSafe for Lazy<T, F> where OnceCell<T>: RefUnwindSafe {} impl<T: fmt::Debug, F> fmt::Debug for Lazy<T, F> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { f.debug_struct("Lazy").field("cell", &self.cell).field("init", &"..").finish() } } impl<T, F> Lazy<T, F> { /// Creates a new lazy value with the given initializing function. /// /// # Example /// ``` /// # fn main() { /// use once_cell::unsync::Lazy; /// /// let hello = "Hello, World!".to_string(); /// /// let lazy = Lazy::new(|| hello.to_uppercase()); /// /// assert_eq!(&*lazy, "HELLO, WORLD!"); /// # } /// ``` pub const fn new(init: F) -> Lazy<T, F> { Lazy { cell: OnceCell::new(), init: Cell::new(Some(init)) } } /// Consumes this `Lazy` returning the stored value. /// /// Returns `Ok(value)` if `Lazy` is initialized and `Err(f)` otherwise. pub fn into_value(this: Lazy<T, F>) -> Result<T, F> { let cell = this.cell; let init = this.init; cell.into_inner().ok_or_else(|| { init.take().unwrap_or_else(|| panic!("Lazy instance has previously been poisoned")) }) } } impl<T, F: FnOnce() -> T> Lazy<T, F> { /// Forces the evaluation of this lazy value and returns a reference to /// the result. /// /// This is equivalent to the `Deref` impl, but is explicit. /// /// # Example /// ``` /// use once_cell::unsync::Lazy; /// /// let lazy = Lazy::new(|| 92); /// /// assert_eq!(Lazy::force(&lazy), &92); /// assert_eq!(&*lazy, &92); /// ``` pub fn force(this: &Lazy<T, F>) -> &T { this.cell.get_or_init(|| match this.init.take() { Some(f) => f(), None => panic!("Lazy instance has previously been poisoned"), }) } } impl<T, F: FnOnce() -> T> Deref for Lazy<T, F> { type Target = T; fn deref(&self) -> &T { Lazy::force(self) } } impl<T, F: FnOnce() -> T> DerefMut for Lazy<T, F> { fn deref_mut(&mut self) -> &mut T { Lazy::force(self); self.cell.get_mut().unwrap_or_else(|| unreachable!()) } } impl<T: Default> Default for Lazy<T> { /// Creates a new lazy value using `Default` as the initializing function. fn default() -> Lazy<T> { Lazy::new(T::default) } } } #[cfg(feature = "std")] pub mod sync { use std::{ cell::Cell, fmt, mem, ops::{Deref, DerefMut}, panic::RefUnwindSafe, }; use crate::imp::OnceCell as Imp; /// A thread-safe cell which can be written to only once. /// /// `OnceCell` provides `&` references to the contents without RAII guards. /// /// Reading a non-`None` value out of `OnceCell` establishes a /// happens-before relationship with a corresponding write. For example, if /// thread A initializes the cell with `get_or_init(f)`, and thread B /// subsequently reads the result of this call, B also observes all the side /// effects of `f`. /// /// # Example /// ``` /// use once_cell::sync::OnceCell; /// /// static CELL: OnceCell<String> = OnceCell::new(); /// assert!(CELL.get().is_none()); /// /// std::thread::spawn(|| { /// let value: &String = CELL.get_or_init(|| { /// "Hello, World!".to_string() /// }); /// assert_eq!(value, "Hello, World!"); /// }).join().unwrap(); /// /// let value: Option<&String> = CELL.get(); /// assert!(value.is_some()); /// assert_eq!(value.unwrap().as_str(), "Hello, World!"); /// ``` pub struct OnceCell<T>(Imp<T>); impl<T> Default for OnceCell<T> { fn default() -> OnceCell<T> { OnceCell::new() } } impl<T: fmt::Debug> fmt::Debug for OnceCell<T> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match self.get() { Some(v) => f.debug_tuple("OnceCell").field(v).finish(), None => f.write_str("OnceCell(Uninit)"), } } } impl<T: Clone> Clone for OnceCell<T> { fn clone(&self) -> OnceCell<T> { let res = OnceCell::new(); if let Some(value) = self.get() { match res.set(value.clone()) { Ok(()) => (), Err(_) => unreachable!(), } } res } } impl<T> From<T> for OnceCell<T> { fn from(value: T) -> Self { let cell = Self::new(); cell.get_or_init(|| value); cell } } impl<T: PartialEq> PartialEq for OnceCell<T> { fn eq(&self, other: &OnceCell<T>) -> bool { self.get() == other.get() } } impl<T: Eq> Eq for OnceCell<T> {} impl<T> OnceCell<T> { /// Creates a new empty cell. pub const fn new() -> OnceCell<T> { OnceCell(Imp::new()) } /// Gets the reference to the underlying value. /// /// Returns `None` if the cell is empty, or being initialized. This /// method never blocks. pub fn get(&self) -> Option<&T> { if self.0.is_initialized() { // Safe b/c value is initialized. Some(unsafe { self.get_unchecked() }) } else { None } } /// Gets the mutable reference to the underlying value. /// /// Returns `None` if the cell is empty. pub fn get_mut(&mut self) -> Option<&mut T> { self.0.get_mut() } /// Get the reference to the underlying value, without checking if the /// cell is initialized. /// /// # Safety /// /// Caller must ensure that the cell is in initialized state, and that /// the contents are acquired by (synchronized to) this thread. pub unsafe fn get_unchecked(&self) -> &T { self.0.get_unchecked() } /// Sets the contents of this cell to `value`. /// /// Returns `Ok(())` if the cell was empty and `Err(value)` if it was /// full. /// /// # Example /// /// ``` /// use once_cell::sync::OnceCell; /// /// static CELL: OnceCell<i32> = OnceCell::new(); /// /// fn main() { /// assert!(CELL.get().is_none()); /// /// std::thread::spawn(|| { /// assert_eq!(CELL.set(92), Ok(())); /// }).join().unwrap(); /// /// assert_eq!(CELL.set(62), Err(62)); /// assert_eq!(CELL.get(), Some(&92)); /// } /// ``` pub fn set(&self, value: T) -> Result<(), T> { let mut value = Some(value); self.get_or_init(|| value.take().unwrap()); match value { None => Ok(()), Some(value) => Err(value), } } /// Gets the contents of the cell, initializing it with `f` if the cell /// was empty. /// /// Many threads may call `get_or_init` concurrently with different /// initializing functions, but it is guaranteed that only one function /// will be executed. /// /// # Panics /// /// If `f` panics, the panic is propagated to the caller, and the cell /// remains uninitialized. /// /// It is an error to reentrantly initialize the cell from `f`. The /// exact outcome is unspecified. Current implementation deadlocks, but /// this may be changed to a panic in the future. /// /// # Example /// ``` /// use once_cell::sync::OnceCell; /// /// let cell = OnceCell::new(); /// let value = cell.get_or_init(|| 92); /// assert_eq!(value, &92); /// let value = cell.get_or_init(|| unreachable!()); /// assert_eq!(value, &92); /// ``` pub fn get_or_init<F>(&self, f: F) -> &T where F: FnOnce() -> T, { enum Void {} match self.get_or_try_init(|| Ok::<T, Void>(f())) { Ok(val) => val, Err(void) => match void {}, } } /// Gets the contents of the cell, initializing it with `f` if /// the cell was empty. If the cell was empty and `f` failed, an /// error is returned. /// /// # Panics /// /// If `f` panics, the panic is propagated to the caller, and /// the cell remains uninitialized. /// /// It is an error to reentrantly initialize the cell from `f`. /// The exact outcome is unspecified. Current implementation /// deadlocks, but this may be changed to a panic in the future. /// /// # Example /// ``` /// use once_cell::sync::OnceCell; /// /// let cell = OnceCell::new(); /// assert_eq!(cell.get_or_try_init(|| Err(())), Err(())); /// assert!(cell.get().is_none()); /// let value = cell.get_or_try_init(|| -> Result<i32, ()> { /// Ok(92) /// }); /// assert_eq!(value, Ok(&92)); /// assert_eq!(cell.get(), Some(&92)) /// ``` pub fn get_or_try_init<F, E>(&self, f: F) -> Result<&T, E> where F: FnOnce() -> Result<T, E>, { // Fast path check if let Some(value) = self.get() { return Ok(value); } self.0.initialize(f)?; // Safe b/c value is initialized. debug_assert!(self.0.is_initialized()); Ok(unsafe { self.get_unchecked() }) } /// Takes the value out of this `OnceCell`, moving it back to an uninitialized state. /// /// Has no effect and returns `None` if the `OnceCell` hasn't been initialized. /// /// # Examples /// /// ``` /// use once_cell::sync::OnceCell; /// /// let mut cell: OnceCell<String> = OnceCell::new(); /// assert_eq!(cell.take(), None); /// /// let mut cell = OnceCell::new(); /// cell.set("hello".to_string()).unwrap(); /// assert_eq!(cell.take(), Some("hello".to_string())); /// assert_eq!(cell.get(), None); /// ``` pub fn take(&mut self) -> Option<T> { mem::replace(self, Self::default()).into_inner() } /// Consumes the `OnceCell`, returning the wrapped value. Returns /// `None` if the cell was empty. /// /// # Examples /// /// ``` /// use once_cell::sync::OnceCell; /// /// let cell: OnceCell<String> = OnceCell::new(); /// assert_eq!(cell.into_inner(), None); /// /// let cell = OnceCell::new(); /// cell.set("hello".to_string()).unwrap(); /// assert_eq!(cell.into_inner(), Some("hello".to_string())); /// ``` pub fn into_inner(self) -> Option<T> { self.0.into_inner() } } /// A value which is initialized on the first access. /// /// This type is thread-safe and can be used in statics. /// /// # Example /// /// ``` /// use std::collections::HashMap; /// /// use once_cell::sync::Lazy; /// /// static HASHMAP: Lazy<HashMap<i32, String>> = Lazy::new(|| { /// println!("initializing"); /// let mut m = HashMap::new(); /// m.insert(13, "Spica".to_string()); /// m.insert(74, "Hoyten".to_string()); /// m /// }); /// /// fn main() { /// println!("ready"); /// std::thread::spawn(|| { /// println!("{:?}", HASHMAP.get(&13)); /// }).join().unwrap(); /// println!("{:?}", HASHMAP.get(&74)); /// /// // Prints: /// // ready /// // initializing /// // Some("Spica") /// // Some("Hoyten") /// } /// ``` pub struct Lazy<T, F = fn() -> T> { cell: OnceCell<T>, init: Cell<Option<F>>, } impl<T: fmt::Debug, F> fmt::Debug for Lazy<T, F> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { f.debug_struct("Lazy").field("cell", &self.cell).field("init", &"..").finish() } } // We never create a `&F` from a `&Lazy<T, F>` so it is fine // to not impl `Sync` for `F` // we do create a `&mut Option<F>` in `force`, but this is // properly synchronized, so it only happens once // so it also does not contribute to this impl. unsafe impl<T, F: Send> Sync for Lazy<T, F> where OnceCell<T>: Sync {} // auto-derived `Send` impl is OK. #[cfg(feature = "std")] impl<T, F: RefUnwindSafe> RefUnwindSafe for Lazy<T, F> where OnceCell<T>: RefUnwindSafe {} impl<T, F> Lazy<T, F> { /// Creates a new lazy value with the given initializing /// function. pub const fn new(f: F) -> Lazy<T, F> { Lazy { cell: OnceCell::new(), init: Cell::new(Some(f)) } } /// Consumes this `Lazy` returning the stored value. /// /// Returns `Ok(value)` if `Lazy` is initialized and `Err(f)` otherwise. pub fn into_value(this: Lazy<T, F>) -> Result<T, F> { let cell = this.cell; let init = this.init; cell.into_inner().ok_or_else(|| { init.take().unwrap_or_else(|| panic!("Lazy instance has previously been poisoned")) }) } } impl<T, F: FnOnce() -> T> Lazy<T, F> { /// Forces the evaluation of this lazy value and /// returns a reference to the result. This is equivalent /// to the `Deref` impl, but is explicit. /// /// # Example /// ``` /// use once_cell::sync::Lazy; /// /// let lazy = Lazy::new(|| 92); /// /// assert_eq!(Lazy::force(&lazy), &92); /// assert_eq!(&*lazy, &92); /// ``` pub fn force(this: &Lazy<T, F>) -> &T { this.cell.get_or_init(|| match this.init.take() { Some(f) => f(), None => panic!("Lazy instance has previously been poisoned"), }) } } impl<T, F: FnOnce() -> T> Deref for Lazy<T, F> { type Target = T; fn deref(&self) -> &T { Lazy::force(self) } } impl<T, F: FnOnce() -> T> DerefMut for Lazy<T, F> { fn deref_mut(&mut self) -> &mut T { Lazy::force(self); self.cell.get_mut().unwrap_or_else(|| unreachable!()) } } impl<T: Default> Default for Lazy<T> { /// Creates a new lazy value using `Default` as the initializing function. fn default() -> Lazy<T> { Lazy::new(T::default) } } /// ```compile_fail /// struct S(*mut ()); /// unsafe impl Sync for S {} /// /// fn share<T: Sync>(_: &T) {} /// share(&once_cell::sync::OnceCell::<S>::new()); /// ``` /// /// ```compile_fail /// struct S(*mut ()); /// unsafe impl Sync for S {} /// /// fn share<T: Sync>(_: &T) {} /// share(&once_cell::sync::Lazy::<S>::new(|| unimplemented!())); /// ``` fn _dummy() {} } #[cfg(feature = "race")] pub mod race; #[cfg(feature = "std")] unsafe fn take_unchecked<T>(val: &mut Option<T>) -> T { match val.take() { Some(it) => it, None => { debug_assert!(false); std::hint::unreachable_unchecked() } } }