mirror of
https://github.com/torvalds/linux.git
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b33bf37adb
Add safe methods for reading and writing Rust values to and from userspace pointers. The C methods for copying to/from userspace use a function called `check_object_size` to verify that the kernel pointer is not dangling. However, this check is skipped when the length is a compile-time constant, with the assumption that such cases trivially have a correct kernel pointer. In this patch, we apply the same optimization to the typed accessors. For both methods, the size of the operation is known at compile time to be size_of of the type being read or written. Since the C side doesn't provide a variant that skips only this check, we create custom helpers for this purpose. The majority of reads and writes to userspace pointers in the Rust Binder driver uses these accessor methods. Benchmarking has found that skipping the `check_object_size` check makes a big difference for the cases being skipped here. (And that the check doesn't make a difference for the cases that use the raw read/write methods.) This code is based on something that was originally written by Wedson on the old rust branch. It was modified by Alice to skip the `check_object_size` check, and to update various comments, including the notes about kernel pointers in `WritableToBytes`. Co-developed-by: Wedson Almeida Filho <wedsonaf@gmail.com> Signed-off-by: Wedson Almeida Filho <wedsonaf@gmail.com> Reviewed-by: Benno Lossin <benno.lossin@proton.me> Reviewed-by: Boqun Feng <boqun.feng@gmail.com> Reviewed-by: Trevor Gross <tmgross@umich.edu> Reviewed-by: Gary Guo <gary@garyguo.net> Signed-off-by: Alice Ryhl <aliceryhl@google.com> Link: https://lore.kernel.org/r/20240528-alice-mm-v7-3-78222c31b8f4@google.com [ Wrapped docs to 100 and added a few intra-doc links. - Miguel ] Signed-off-by: Miguel Ojeda <ojeda@kernel.org>
476 lines
17 KiB
Rust
476 lines
17 KiB
Rust
// SPDX-License-Identifier: GPL-2.0
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//! Kernel types.
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use crate::init::{self, PinInit};
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use alloc::boxed::Box;
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use core::{
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cell::UnsafeCell,
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marker::{PhantomData, PhantomPinned},
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mem::MaybeUninit,
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ops::{Deref, DerefMut},
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ptr::NonNull,
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};
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/// Used to transfer ownership to and from foreign (non-Rust) languages.
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///
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/// Ownership is transferred from Rust to a foreign language by calling [`Self::into_foreign`] and
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/// later may be transferred back to Rust by calling [`Self::from_foreign`].
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///
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/// This trait is meant to be used in cases when Rust objects are stored in C objects and
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/// eventually "freed" back to Rust.
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pub trait ForeignOwnable: Sized {
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/// Type of values borrowed between calls to [`ForeignOwnable::into_foreign`] and
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/// [`ForeignOwnable::from_foreign`].
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type Borrowed<'a>;
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/// Converts a Rust-owned object to a foreign-owned one.
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///
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/// The foreign representation is a pointer to void.
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fn into_foreign(self) -> *const core::ffi::c_void;
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/// Borrows a foreign-owned object.
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///
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/// # Safety
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///
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/// `ptr` must have been returned by a previous call to [`ForeignOwnable::into_foreign`] for
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/// which a previous matching [`ForeignOwnable::from_foreign`] hasn't been called yet.
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unsafe fn borrow<'a>(ptr: *const core::ffi::c_void) -> Self::Borrowed<'a>;
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/// Converts a foreign-owned object back to a Rust-owned one.
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///
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/// # Safety
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///
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/// `ptr` must have been returned by a previous call to [`ForeignOwnable::into_foreign`] for
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/// which a previous matching [`ForeignOwnable::from_foreign`] hasn't been called yet.
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/// Additionally, all instances (if any) of values returned by [`ForeignOwnable::borrow`] for
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/// this object must have been dropped.
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unsafe fn from_foreign(ptr: *const core::ffi::c_void) -> Self;
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/// Tries to convert a foreign-owned object back to a Rust-owned one.
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///
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/// A convenience wrapper over [`ForeignOwnable::from_foreign`] that returns [`None`] if `ptr`
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/// is null.
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///
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/// # Safety
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///
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/// `ptr` must either be null or satisfy the safety requirements for
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/// [`ForeignOwnable::from_foreign`].
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unsafe fn try_from_foreign(ptr: *const core::ffi::c_void) -> Option<Self> {
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if ptr.is_null() {
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None
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} else {
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// SAFETY: Since `ptr` is not null here, then `ptr` satisfies the safety requirements
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// of `from_foreign` given the safety requirements of this function.
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unsafe { Some(Self::from_foreign(ptr)) }
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}
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}
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}
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impl<T: 'static> ForeignOwnable for Box<T> {
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type Borrowed<'a> = &'a T;
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fn into_foreign(self) -> *const core::ffi::c_void {
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Box::into_raw(self) as _
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}
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unsafe fn borrow<'a>(ptr: *const core::ffi::c_void) -> &'a T {
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// SAFETY: The safety requirements for this function ensure that the object is still alive,
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// so it is safe to dereference the raw pointer.
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// The safety requirements of `from_foreign` also ensure that the object remains alive for
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// the lifetime of the returned value.
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unsafe { &*ptr.cast() }
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}
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unsafe fn from_foreign(ptr: *const core::ffi::c_void) -> Self {
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// SAFETY: The safety requirements of this function ensure that `ptr` comes from a previous
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// call to `Self::into_foreign`.
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unsafe { Box::from_raw(ptr as _) }
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}
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}
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impl ForeignOwnable for () {
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type Borrowed<'a> = ();
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fn into_foreign(self) -> *const core::ffi::c_void {
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core::ptr::NonNull::dangling().as_ptr()
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}
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unsafe fn borrow<'a>(_: *const core::ffi::c_void) -> Self::Borrowed<'a> {}
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unsafe fn from_foreign(_: *const core::ffi::c_void) -> Self {}
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}
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/// Runs a cleanup function/closure when dropped.
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///
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/// The [`ScopeGuard::dismiss`] function prevents the cleanup function from running.
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///
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/// # Examples
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///
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/// In the example below, we have multiple exit paths and we want to log regardless of which one is
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/// taken:
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///
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/// ```
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/// # use kernel::types::ScopeGuard;
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/// fn example1(arg: bool) {
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/// let _log = ScopeGuard::new(|| pr_info!("example1 completed\n"));
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///
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/// if arg {
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/// return;
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/// }
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///
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/// pr_info!("Do something...\n");
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/// }
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///
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/// # example1(false);
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/// # example1(true);
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/// ```
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///
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/// In the example below, we want to log the same message on all early exits but a different one on
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/// the main exit path:
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///
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/// ```
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/// # use kernel::types::ScopeGuard;
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/// fn example2(arg: bool) {
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/// let log = ScopeGuard::new(|| pr_info!("example2 returned early\n"));
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///
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/// if arg {
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/// return;
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/// }
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///
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/// // (Other early returns...)
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///
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/// log.dismiss();
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/// pr_info!("example2 no early return\n");
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/// }
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///
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/// # example2(false);
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/// # example2(true);
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/// ```
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///
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/// In the example below, we need a mutable object (the vector) to be accessible within the log
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/// function, so we wrap it in the [`ScopeGuard`]:
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///
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/// ```
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/// # use kernel::types::ScopeGuard;
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/// fn example3(arg: bool) -> Result {
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/// let mut vec =
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/// ScopeGuard::new_with_data(Vec::new(), |v| pr_info!("vec had {} elements\n", v.len()));
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///
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/// vec.push(10u8, GFP_KERNEL)?;
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/// if arg {
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/// return Ok(());
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/// }
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/// vec.push(20u8, GFP_KERNEL)?;
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/// Ok(())
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/// }
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///
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/// # assert_eq!(example3(false), Ok(()));
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/// # assert_eq!(example3(true), Ok(()));
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/// ```
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///
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/// # Invariants
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///
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/// The value stored in the struct is nearly always `Some(_)`, except between
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/// [`ScopeGuard::dismiss`] and [`ScopeGuard::drop`]: in this case, it will be `None` as the value
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/// will have been returned to the caller. Since [`ScopeGuard::dismiss`] consumes the guard,
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/// callers won't be able to use it anymore.
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pub struct ScopeGuard<T, F: FnOnce(T)>(Option<(T, F)>);
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impl<T, F: FnOnce(T)> ScopeGuard<T, F> {
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/// Creates a new guarded object wrapping the given data and with the given cleanup function.
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pub fn new_with_data(data: T, cleanup_func: F) -> Self {
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// INVARIANT: The struct is being initialised with `Some(_)`.
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Self(Some((data, cleanup_func)))
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}
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/// Prevents the cleanup function from running and returns the guarded data.
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pub fn dismiss(mut self) -> T {
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// INVARIANT: This is the exception case in the invariant; it is not visible to callers
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// because this function consumes `self`.
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self.0.take().unwrap().0
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}
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}
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impl ScopeGuard<(), fn(())> {
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/// Creates a new guarded object with the given cleanup function.
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pub fn new(cleanup: impl FnOnce()) -> ScopeGuard<(), impl FnOnce(())> {
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ScopeGuard::new_with_data((), move |_| cleanup())
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}
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}
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impl<T, F: FnOnce(T)> Deref for ScopeGuard<T, F> {
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type Target = T;
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fn deref(&self) -> &T {
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// The type invariants guarantee that `unwrap` will succeed.
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&self.0.as_ref().unwrap().0
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}
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}
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impl<T, F: FnOnce(T)> DerefMut for ScopeGuard<T, F> {
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fn deref_mut(&mut self) -> &mut T {
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// The type invariants guarantee that `unwrap` will succeed.
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&mut self.0.as_mut().unwrap().0
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}
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}
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impl<T, F: FnOnce(T)> Drop for ScopeGuard<T, F> {
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fn drop(&mut self) {
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// Run the cleanup function if one is still present.
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if let Some((data, cleanup)) = self.0.take() {
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cleanup(data)
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}
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}
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}
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/// Stores an opaque value.
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///
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/// This is meant to be used with FFI objects that are never interpreted by Rust code.
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#[repr(transparent)]
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pub struct Opaque<T> {
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value: UnsafeCell<MaybeUninit<T>>,
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_pin: PhantomPinned,
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}
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impl<T> Opaque<T> {
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/// Creates a new opaque value.
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pub const fn new(value: T) -> Self {
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Self {
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value: UnsafeCell::new(MaybeUninit::new(value)),
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_pin: PhantomPinned,
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}
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}
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/// Creates an uninitialised value.
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pub const fn uninit() -> Self {
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Self {
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value: UnsafeCell::new(MaybeUninit::uninit()),
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_pin: PhantomPinned,
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}
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}
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/// Creates a pin-initializer from the given initializer closure.
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///
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/// The returned initializer calls the given closure with the pointer to the inner `T` of this
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/// `Opaque`. Since this memory is uninitialized, the closure is not allowed to read from it.
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///
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/// This function is safe, because the `T` inside of an `Opaque` is allowed to be
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/// uninitialized. Additionally, access to the inner `T` requires `unsafe`, so the caller needs
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/// to verify at that point that the inner value is valid.
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pub fn ffi_init(init_func: impl FnOnce(*mut T)) -> impl PinInit<Self> {
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// SAFETY: We contain a `MaybeUninit`, so it is OK for the `init_func` to not fully
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// initialize the `T`.
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unsafe {
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init::pin_init_from_closure::<_, ::core::convert::Infallible>(move |slot| {
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init_func(Self::raw_get(slot));
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Ok(())
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})
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}
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}
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/// Returns a raw pointer to the opaque data.
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pub const fn get(&self) -> *mut T {
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UnsafeCell::get(&self.value).cast::<T>()
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}
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/// Gets the value behind `this`.
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///
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/// This function is useful to get access to the value without creating intermediate
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/// references.
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pub const fn raw_get(this: *const Self) -> *mut T {
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UnsafeCell::raw_get(this.cast::<UnsafeCell<MaybeUninit<T>>>()).cast::<T>()
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}
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}
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/// Types that are _always_ reference counted.
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///
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/// It allows such types to define their own custom ref increment and decrement functions.
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/// Additionally, it allows users to convert from a shared reference `&T` to an owned reference
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/// [`ARef<T>`].
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///
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/// This is usually implemented by wrappers to existing structures on the C side of the code. For
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/// Rust code, the recommendation is to use [`Arc`](crate::sync::Arc) to create reference-counted
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/// instances of a type.
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///
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/// # Safety
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///
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/// Implementers must ensure that increments to the reference count keep the object alive in memory
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/// at least until matching decrements are performed.
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///
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/// Implementers must also ensure that all instances are reference-counted. (Otherwise they
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/// won't be able to honour the requirement that [`AlwaysRefCounted::inc_ref`] keep the object
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/// alive.)
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pub unsafe trait AlwaysRefCounted {
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/// Increments the reference count on the object.
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fn inc_ref(&self);
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/// Decrements the reference count on the object.
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///
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/// Frees the object when the count reaches zero.
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///
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/// # Safety
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///
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/// Callers must ensure that there was a previous matching increment to the reference count,
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/// and that the object is no longer used after its reference count is decremented (as it may
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/// result in the object being freed), unless the caller owns another increment on the refcount
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/// (e.g., it calls [`AlwaysRefCounted::inc_ref`] twice, then calls
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/// [`AlwaysRefCounted::dec_ref`] once).
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unsafe fn dec_ref(obj: NonNull<Self>);
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}
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/// An owned reference to an always-reference-counted object.
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///
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/// The object's reference count is automatically decremented when an instance of [`ARef`] is
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/// dropped. It is also automatically incremented when a new instance is created via
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/// [`ARef::clone`].
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///
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/// # Invariants
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///
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/// The pointer stored in `ptr` is non-null and valid for the lifetime of the [`ARef`] instance. In
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/// particular, the [`ARef`] instance owns an increment on the underlying object's reference count.
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pub struct ARef<T: AlwaysRefCounted> {
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ptr: NonNull<T>,
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_p: PhantomData<T>,
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}
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// SAFETY: It is safe to send `ARef<T>` to another thread when the underlying `T` is `Sync` because
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// it effectively means sharing `&T` (which is safe because `T` is `Sync`); additionally, it needs
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// `T` to be `Send` because any thread that has an `ARef<T>` may ultimately access `T` using a
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// mutable reference, for example, when the reference count reaches zero and `T` is dropped.
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unsafe impl<T: AlwaysRefCounted + Sync + Send> Send for ARef<T> {}
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// SAFETY: It is safe to send `&ARef<T>` to another thread when the underlying `T` is `Sync`
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// because it effectively means sharing `&T` (which is safe because `T` is `Sync`); additionally,
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// it needs `T` to be `Send` because any thread that has a `&ARef<T>` may clone it and get an
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// `ARef<T>` on that thread, so the thread may ultimately access `T` using a mutable reference, for
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// example, when the reference count reaches zero and `T` is dropped.
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unsafe impl<T: AlwaysRefCounted + Sync + Send> Sync for ARef<T> {}
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impl<T: AlwaysRefCounted> ARef<T> {
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/// Creates a new instance of [`ARef`].
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///
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/// It takes over an increment of the reference count on the underlying object.
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///
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/// # Safety
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///
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/// Callers must ensure that the reference count was incremented at least once, and that they
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/// are properly relinquishing one increment. That is, if there is only one increment, callers
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/// must not use the underlying object anymore -- it is only safe to do so via the newly
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/// created [`ARef`].
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pub unsafe fn from_raw(ptr: NonNull<T>) -> Self {
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// INVARIANT: The safety requirements guarantee that the new instance now owns the
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// increment on the refcount.
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Self {
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ptr,
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_p: PhantomData,
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}
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}
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}
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impl<T: AlwaysRefCounted> Clone for ARef<T> {
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fn clone(&self) -> Self {
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self.inc_ref();
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// SAFETY: We just incremented the refcount above.
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unsafe { Self::from_raw(self.ptr) }
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}
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}
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impl<T: AlwaysRefCounted> Deref for ARef<T> {
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type Target = T;
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fn deref(&self) -> &Self::Target {
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// SAFETY: The type invariants guarantee that the object is valid.
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unsafe { self.ptr.as_ref() }
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}
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}
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impl<T: AlwaysRefCounted> From<&T> for ARef<T> {
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fn from(b: &T) -> Self {
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b.inc_ref();
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// SAFETY: We just incremented the refcount above.
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unsafe { Self::from_raw(NonNull::from(b)) }
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}
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}
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impl<T: AlwaysRefCounted> Drop for ARef<T> {
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fn drop(&mut self) {
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// SAFETY: The type invariants guarantee that the `ARef` owns the reference we're about to
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// decrement.
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unsafe { T::dec_ref(self.ptr) };
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}
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}
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/// A sum type that always holds either a value of type `L` or `R`.
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pub enum Either<L, R> {
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/// Constructs an instance of [`Either`] containing a value of type `L`.
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Left(L),
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/// Constructs an instance of [`Either`] containing a value of type `R`.
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Right(R),
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}
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/// Types for which any bit pattern is valid.
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///
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/// Not all types are valid for all values. For example, a `bool` must be either zero or one, so
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/// reading arbitrary bytes into something that contains a `bool` is not okay.
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///
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/// It's okay for the type to have padding, as initializing those bytes has no effect.
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///
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/// # Safety
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///
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/// All bit-patterns must be valid for this type. This type must not have interior mutability.
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pub unsafe trait FromBytes {}
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// SAFETY: All bit patterns are acceptable values of the types below.
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unsafe impl FromBytes for u8 {}
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unsafe impl FromBytes for u16 {}
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unsafe impl FromBytes for u32 {}
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unsafe impl FromBytes for u64 {}
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unsafe impl FromBytes for usize {}
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unsafe impl FromBytes for i8 {}
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unsafe impl FromBytes for i16 {}
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unsafe impl FromBytes for i32 {}
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unsafe impl FromBytes for i64 {}
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unsafe impl FromBytes for isize {}
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// SAFETY: If all bit patterns are acceptable for individual values in an array, then all bit
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// patterns are also acceptable for arrays of that type.
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unsafe impl<T: FromBytes> FromBytes for [T] {}
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unsafe impl<T: FromBytes, const N: usize> FromBytes for [T; N] {}
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/// Types that can be viewed as an immutable slice of initialized bytes.
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///
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/// If a struct implements this trait, then it is okay to copy it byte-for-byte to userspace. This
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/// means that it should not have any padding, as padding bytes are uninitialized. Reading
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/// uninitialized memory is not just undefined behavior, it may even lead to leaking sensitive
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/// information on the stack to userspace.
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///
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/// The struct should also not hold kernel pointers, as kernel pointer addresses are also considered
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/// sensitive. However, leaking kernel pointers is not considered undefined behavior by Rust, so
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/// this is a correctness requirement, but not a safety requirement.
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///
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/// # Safety
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///
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/// Values of this type may not contain any uninitialized bytes. This type must not have interior
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/// mutability.
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pub unsafe trait AsBytes {}
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// SAFETY: Instances of the following types have no uninitialized portions.
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unsafe impl AsBytes for u8 {}
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unsafe impl AsBytes for u16 {}
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unsafe impl AsBytes for u32 {}
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unsafe impl AsBytes for u64 {}
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unsafe impl AsBytes for usize {}
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unsafe impl AsBytes for i8 {}
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|
unsafe impl AsBytes for i16 {}
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|
unsafe impl AsBytes for i32 {}
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|
unsafe impl AsBytes for i64 {}
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|
unsafe impl AsBytes for isize {}
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|
unsafe impl AsBytes for bool {}
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unsafe impl AsBytes for char {}
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|
unsafe impl AsBytes for str {}
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// SAFETY: If individual values in an array have no uninitialized portions, then the array itself
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|
// does not have any uninitialized portions either.
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|
unsafe impl<T: AsBytes> AsBytes for [T] {}
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|
unsafe impl<T: AsBytes, const N: usize> AsBytes for [T; N] {}
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