// SPDX-License-Identifier: GPL-2.0 //! Kernel types. use crate::init::{self, PinInit}; use core::{ cell::UnsafeCell, marker::{PhantomData, PhantomPinned}, mem::{ManuallyDrop, MaybeUninit}, ops::{Deref, DerefMut}, ptr::NonNull, }; /// Used to transfer ownership to and from foreign (non-Rust) languages. /// /// Ownership is transferred from Rust to a foreign language by calling [`Self::into_foreign`] and /// later may be transferred back to Rust by calling [`Self::from_foreign`]. /// /// This trait is meant to be used in cases when Rust objects are stored in C objects and /// eventually "freed" back to Rust. pub trait ForeignOwnable: Sized { /// Type of values borrowed between calls to [`ForeignOwnable::into_foreign`] and /// [`ForeignOwnable::from_foreign`]. type Borrowed<'a>; /// Converts a Rust-owned object to a foreign-owned one. /// /// The foreign representation is a pointer to void. There are no guarantees for this pointer. /// For example, it might be invalid, dangling or pointing to uninitialized memory. Using it in /// any way except for [`ForeignOwnable::from_foreign`], [`ForeignOwnable::borrow`], /// [`ForeignOwnable::try_from_foreign`] can result in undefined behavior. fn into_foreign(self) -> *const core::ffi::c_void; /// Borrows a foreign-owned object. /// /// # Safety /// /// `ptr` must have been returned by a previous call to [`ForeignOwnable::into_foreign`] for /// which a previous matching [`ForeignOwnable::from_foreign`] hasn't been called yet. unsafe fn borrow<'a>(ptr: *const core::ffi::c_void) -> Self::Borrowed<'a>; /// Converts a foreign-owned object back to a Rust-owned one. /// /// # Safety /// /// `ptr` must have been returned by a previous call to [`ForeignOwnable::into_foreign`] for /// which a previous matching [`ForeignOwnable::from_foreign`] hasn't been called yet. /// Additionally, all instances (if any) of values returned by [`ForeignOwnable::borrow`] for /// this object must have been dropped. unsafe fn from_foreign(ptr: *const core::ffi::c_void) -> Self; /// Tries to convert a foreign-owned object back to a Rust-owned one. /// /// A convenience wrapper over [`ForeignOwnable::from_foreign`] that returns [`None`] if `ptr` /// is null. /// /// # Safety /// /// `ptr` must either be null or satisfy the safety requirements for /// [`ForeignOwnable::from_foreign`]. unsafe fn try_from_foreign(ptr: *const core::ffi::c_void) -> Option { if ptr.is_null() { None } else { // SAFETY: Since `ptr` is not null here, then `ptr` satisfies the safety requirements // of `from_foreign` given the safety requirements of this function. unsafe { Some(Self::from_foreign(ptr)) } } } } impl ForeignOwnable for () { type Borrowed<'a> = (); fn into_foreign(self) -> *const core::ffi::c_void { core::ptr::NonNull::dangling().as_ptr() } unsafe fn borrow<'a>(_: *const core::ffi::c_void) -> Self::Borrowed<'a> {} unsafe fn from_foreign(_: *const core::ffi::c_void) -> Self {} } /// Runs a cleanup function/closure when dropped. /// /// The [`ScopeGuard::dismiss`] function prevents the cleanup function from running. /// /// # Examples /// /// In the example below, we have multiple exit paths and we want to log regardless of which one is /// taken: /// /// ``` /// # use kernel::types::ScopeGuard; /// fn example1(arg: bool) { /// let _log = ScopeGuard::new(|| pr_info!("example1 completed\n")); /// /// if arg { /// return; /// } /// /// pr_info!("Do something...\n"); /// } /// /// # example1(false); /// # example1(true); /// ``` /// /// In the example below, we want to log the same message on all early exits but a different one on /// the main exit path: /// /// ``` /// # use kernel::types::ScopeGuard; /// fn example2(arg: bool) { /// let log = ScopeGuard::new(|| pr_info!("example2 returned early\n")); /// /// if arg { /// return; /// } /// /// // (Other early returns...) /// /// log.dismiss(); /// pr_info!("example2 no early return\n"); /// } /// /// # example2(false); /// # example2(true); /// ``` /// /// In the example below, we need a mutable object (the vector) to be accessible within the log /// function, so we wrap it in the [`ScopeGuard`]: /// /// ``` /// # use kernel::types::ScopeGuard; /// fn example3(arg: bool) -> Result { /// let mut vec = /// ScopeGuard::new_with_data(KVec::new(), |v| pr_info!("vec had {} elements\n", v.len())); /// /// vec.push(10u8, GFP_KERNEL)?; /// if arg { /// return Ok(()); /// } /// vec.push(20u8, GFP_KERNEL)?; /// Ok(()) /// } /// /// # assert_eq!(example3(false), Ok(())); /// # assert_eq!(example3(true), Ok(())); /// ``` /// /// # Invariants /// /// The value stored in the struct is nearly always `Some(_)`, except between /// [`ScopeGuard::dismiss`] and [`ScopeGuard::drop`]: in this case, it will be `None` as the value /// will have been returned to the caller. Since [`ScopeGuard::dismiss`] consumes the guard, /// callers won't be able to use it anymore. pub struct ScopeGuard(Option<(T, F)>); impl ScopeGuard { /// Creates a new guarded object wrapping the given data and with the given cleanup function. pub fn new_with_data(data: T, cleanup_func: F) -> Self { // INVARIANT: The struct is being initialised with `Some(_)`. Self(Some((data, cleanup_func))) } /// Prevents the cleanup function from running and returns the guarded data. pub fn dismiss(mut self) -> T { // INVARIANT: This is the exception case in the invariant; it is not visible to callers // because this function consumes `self`. self.0.take().unwrap().0 } } impl ScopeGuard<(), fn(())> { /// Creates a new guarded object with the given cleanup function. pub fn new(cleanup: impl FnOnce()) -> ScopeGuard<(), impl FnOnce(())> { ScopeGuard::new_with_data((), move |()| cleanup()) } } impl Deref for ScopeGuard { type Target = T; fn deref(&self) -> &T { // The type invariants guarantee that `unwrap` will succeed. &self.0.as_ref().unwrap().0 } } impl DerefMut for ScopeGuard { fn deref_mut(&mut self) -> &mut T { // The type invariants guarantee that `unwrap` will succeed. &mut self.0.as_mut().unwrap().0 } } impl Drop for ScopeGuard { fn drop(&mut self) { // Run the cleanup function if one is still present. if let Some((data, cleanup)) = self.0.take() { cleanup(data) } } } /// Stores an opaque value. /// /// This is meant to be used with FFI objects that are never interpreted by Rust code. #[repr(transparent)] pub struct Opaque { value: UnsafeCell>, _pin: PhantomPinned, } impl Opaque { /// Creates a new opaque value. pub const fn new(value: T) -> Self { Self { value: UnsafeCell::new(MaybeUninit::new(value)), _pin: PhantomPinned, } } /// Creates an uninitialised value. pub const fn uninit() -> Self { Self { value: UnsafeCell::new(MaybeUninit::uninit()), _pin: PhantomPinned, } } /// Creates a pin-initializer from the given initializer closure. /// /// The returned initializer calls the given closure with the pointer to the inner `T` of this /// `Opaque`. Since this memory is uninitialized, the closure is not allowed to read from it. /// /// This function is safe, because the `T` inside of an `Opaque` is allowed to be /// uninitialized. Additionally, access to the inner `T` requires `unsafe`, so the caller needs /// to verify at that point that the inner value is valid. pub fn ffi_init(init_func: impl FnOnce(*mut T)) -> impl PinInit { Self::try_ffi_init(move |slot| { init_func(slot); Ok(()) }) } /// Similar to [`Self::ffi_init`], except that the closure can fail. /// /// To avoid leaks on failure, the closure must drop any fields it has initialised before the /// failure. pub fn try_ffi_init( init_func: impl FnOnce(*mut T) -> Result<(), E>, ) -> impl PinInit { // SAFETY: We contain a `MaybeUninit`, so it is OK for the `init_func` to not fully // initialize the `T`. unsafe { init::pin_init_from_closure(|slot| init_func(Self::raw_get(slot))) } } /// Returns a raw pointer to the opaque data. pub const fn get(&self) -> *mut T { UnsafeCell::get(&self.value).cast::() } /// Gets the value behind `this`. /// /// This function is useful to get access to the value without creating intermediate /// references. pub const fn raw_get(this: *const Self) -> *mut T { UnsafeCell::raw_get(this.cast::>>()).cast::() } } /// Types that are _always_ reference counted. /// /// It allows such types to define their own custom ref increment and decrement functions. /// Additionally, it allows users to convert from a shared reference `&T` to an owned reference /// [`ARef`]. /// /// This is usually implemented by wrappers to existing structures on the C side of the code. For /// Rust code, the recommendation is to use [`Arc`](crate::sync::Arc) to create reference-counted /// instances of a type. /// /// # Safety /// /// Implementers must ensure that increments to the reference count keep the object alive in memory /// at least until matching decrements are performed. /// /// Implementers must also ensure that all instances are reference-counted. (Otherwise they /// won't be able to honour the requirement that [`AlwaysRefCounted::inc_ref`] keep the object /// alive.) pub unsafe trait AlwaysRefCounted { /// Increments the reference count on the object. fn inc_ref(&self); /// Decrements the reference count on the object. /// /// Frees the object when the count reaches zero. /// /// # Safety /// /// Callers must ensure that there was a previous matching increment to the reference count, /// and that the object is no longer used after its reference count is decremented (as it may /// result in the object being freed), unless the caller owns another increment on the refcount /// (e.g., it calls [`AlwaysRefCounted::inc_ref`] twice, then calls /// [`AlwaysRefCounted::dec_ref`] once). unsafe fn dec_ref(obj: NonNull); } /// An owned reference to an always-reference-counted object. /// /// The object's reference count is automatically decremented when an instance of [`ARef`] is /// dropped. It is also automatically incremented when a new instance is created via /// [`ARef::clone`]. /// /// # Invariants /// /// The pointer stored in `ptr` is non-null and valid for the lifetime of the [`ARef`] instance. In /// particular, the [`ARef`] instance owns an increment on the underlying object's reference count. pub struct ARef { ptr: NonNull, _p: PhantomData, } // SAFETY: It is safe to send `ARef` to another thread when the underlying `T` is `Sync` because // it effectively means sharing `&T` (which is safe because `T` is `Sync`); additionally, it needs // `T` to be `Send` because any thread that has an `ARef` may ultimately access `T` using a // mutable reference, for example, when the reference count reaches zero and `T` is dropped. unsafe impl Send for ARef {} // SAFETY: It is safe to send `&ARef` to another thread when the underlying `T` is `Sync` // because it effectively means sharing `&T` (which is safe because `T` is `Sync`); additionally, // it needs `T` to be `Send` because any thread that has a `&ARef` may clone it and get an // `ARef` on that thread, so the thread may ultimately access `T` using a mutable reference, for // example, when the reference count reaches zero and `T` is dropped. unsafe impl Sync for ARef {} impl ARef { /// Creates a new instance of [`ARef`]. /// /// It takes over an increment of the reference count on the underlying object. /// /// # Safety /// /// Callers must ensure that the reference count was incremented at least once, and that they /// are properly relinquishing one increment. That is, if there is only one increment, callers /// must not use the underlying object anymore -- it is only safe to do so via the newly /// created [`ARef`]. pub unsafe fn from_raw(ptr: NonNull) -> Self { // INVARIANT: The safety requirements guarantee that the new instance now owns the // increment on the refcount. Self { ptr, _p: PhantomData, } } /// Consumes the `ARef`, returning a raw pointer. /// /// This function does not change the refcount. After calling this function, the caller is /// responsible for the refcount previously managed by the `ARef`. /// /// # Examples /// /// ``` /// use core::ptr::NonNull; /// use kernel::types::{ARef, AlwaysRefCounted}; /// /// struct Empty {} /// /// # // SAFETY: TODO. /// unsafe impl AlwaysRefCounted for Empty { /// fn inc_ref(&self) {} /// unsafe fn dec_ref(_obj: NonNull) {} /// } /// /// let mut data = Empty {}; /// let ptr = NonNull::::new(&mut data as *mut _).unwrap(); /// # // SAFETY: TODO. /// let data_ref: ARef = unsafe { ARef::from_raw(ptr) }; /// let raw_ptr: NonNull = ARef::into_raw(data_ref); /// /// assert_eq!(ptr, raw_ptr); /// ``` pub fn into_raw(me: Self) -> NonNull { ManuallyDrop::new(me).ptr } } impl Clone for ARef { fn clone(&self) -> Self { self.inc_ref(); // SAFETY: We just incremented the refcount above. unsafe { Self::from_raw(self.ptr) } } } impl Deref for ARef { type Target = T; fn deref(&self) -> &Self::Target { // SAFETY: The type invariants guarantee that the object is valid. unsafe { self.ptr.as_ref() } } } impl From<&T> for ARef { fn from(b: &T) -> Self { b.inc_ref(); // SAFETY: We just incremented the refcount above. unsafe { Self::from_raw(NonNull::from(b)) } } } impl Drop for ARef { fn drop(&mut self) { // SAFETY: The type invariants guarantee that the `ARef` owns the reference we're about to // decrement. unsafe { T::dec_ref(self.ptr) }; } } /// A sum type that always holds either a value of type `L` or `R`. /// /// # Examples /// /// ``` /// use kernel::types::Either; /// /// let left_value: Either = Either::Left(7); /// let right_value: Either = Either::Right("right value"); /// ``` pub enum Either { /// Constructs an instance of [`Either`] containing a value of type `L`. Left(L), /// Constructs an instance of [`Either`] containing a value of type `R`. Right(R), }