diff options
Diffstat (limited to 'vendor/zerocopy/src/wrappers.rs')
-rw-r--r-- | vendor/zerocopy/src/wrappers.rs | 503 |
1 files changed, 503 insertions, 0 deletions
diff --git a/vendor/zerocopy/src/wrappers.rs b/vendor/zerocopy/src/wrappers.rs new file mode 100644 index 000000000..532d87297 --- /dev/null +++ b/vendor/zerocopy/src/wrappers.rs @@ -0,0 +1,503 @@ +// Copyright 2023 The Fuchsia Authors +// +// Licensed under a BSD-style license <LICENSE-BSD>, Apache License, Version 2.0 +// <LICENSE-APACHE or https://www.apache.org/licenses/LICENSE-2.0>, or the MIT +// license <LICENSE-MIT or https://opensource.org/licenses/MIT>, at your option. +// This file may not be copied, modified, or distributed except according to +// those terms. + +use core::{ + cmp::Ordering, + fmt::{self, Debug, Display, Formatter}, + hash::Hash, + mem::{self, ManuallyDrop}, + ops::{Deref, DerefMut}, + ptr, +}; + +use super::*; + +/// A type with no alignment requirement. +/// +/// An `Unalign` wraps a `T`, removing any alignment requirement. `Unalign<T>` +/// has the same size and bit validity as `T`, but not necessarily the same +/// alignment [or ABI]. This is useful if a type with an alignment requirement +/// needs to be read from a chunk of memory which provides no alignment +/// guarantees. +/// +/// Since `Unalign` has no alignment requirement, the inner `T` may not be +/// properly aligned in memory. There are five ways to access the inner `T`: +/// - by value, using [`get`] or [`into_inner`] +/// - by reference inside of a callback, using [`update`] +/// - fallibly by reference, using [`try_deref`] or [`try_deref_mut`]; these can +/// fail if the `Unalign` does not satisfy `T`'s alignment requirement at +/// runtime +/// - unsafely by reference, using [`deref_unchecked`] or +/// [`deref_mut_unchecked`]; it is the caller's responsibility to ensure that +/// the `Unalign` satisfies `T`'s alignment requirement +/// - (where `T: Unaligned`) infallibly by reference, using [`Deref::deref`] or +/// [`DerefMut::deref_mut`] +/// +/// [or ABI]: https://github.com/google/zerocopy/issues/164 +/// [`get`]: Unalign::get +/// [`into_inner`]: Unalign::into_inner +/// [`update`]: Unalign::update +/// [`try_deref`]: Unalign::try_deref +/// [`try_deref_mut`]: Unalign::try_deref_mut +/// [`deref_unchecked`]: Unalign::deref_unchecked +/// [`deref_mut_unchecked`]: Unalign::deref_mut_unchecked +// NOTE: This type is sound to use with types that need to be dropped. The +// reason is that the compiler-generated drop code automatically moves all +// values to aligned memory slots before dropping them in-place. This is not +// well-documented, but it's hinted at in places like [1] and [2]. However, this +// also means that `T` must be `Sized`; unless something changes, we can never +// support unsized `T`. [3] +// +// [1] https://github.com/rust-lang/rust/issues/54148#issuecomment-420529646 +// [2] https://github.com/google/zerocopy/pull/126#discussion_r1018512323 +// [3] https://github.com/google/zerocopy/issues/209 +#[allow(missing_debug_implementations)] +#[derive(Default, Copy)] +#[cfg_attr( + any(feature = "derive", test), + derive(KnownLayout, FromZeroes, FromBytes, AsBytes, Unaligned) +)] +#[repr(C, packed)] +pub struct Unalign<T>(T); + +#[cfg(not(any(feature = "derive", test)))] +impl_known_layout!(T => Unalign<T>); + +safety_comment! { + /// SAFETY: + /// - `Unalign<T>` is `repr(packed)`, so it is unaligned regardless of the + /// alignment of `T`, and so we don't require that `T: Unaligned` + /// - `Unalign<T>` has the same bit validity as `T`, and so it is + /// `FromZeroes`, `FromBytes`, or `AsBytes` exactly when `T` is as well. + impl_or_verify!(T => Unaligned for Unalign<T>); + impl_or_verify!(T: FromZeroes => FromZeroes for Unalign<T>); + impl_or_verify!(T: FromBytes => FromBytes for Unalign<T>); + impl_or_verify!(T: AsBytes => AsBytes for Unalign<T>); +} + +// Note that `Unalign: Clone` only if `T: Copy`. Since the inner `T` may not be +// aligned, there's no way to safely call `T::clone`, and so a `T: Clone` bound +// is not sufficient to implement `Clone` for `Unalign`. +impl<T: Copy> Clone for Unalign<T> { + #[inline(always)] + fn clone(&self) -> Unalign<T> { + *self + } +} + +impl<T> Unalign<T> { + /// Constructs a new `Unalign`. + #[inline(always)] + pub const fn new(val: T) -> Unalign<T> { + Unalign(val) + } + + /// Consumes `self`, returning the inner `T`. + #[inline(always)] + pub const fn into_inner(self) -> T { + // Use this instead of `mem::transmute` since the latter can't tell + // that `Unalign<T>` and `T` have the same size. + #[repr(C)] + union Transmute<T> { + u: ManuallyDrop<Unalign<T>>, + t: ManuallyDrop<T>, + } + + // SAFETY: Since `Unalign` is `#[repr(C, packed)]`, it has the same + // layout as `T`. `ManuallyDrop<U>` is guaranteed to have the same + // layout as `U`, and so `ManuallyDrop<Unalign<T>>` has the same layout + // as `ManuallyDrop<T>`. Since `Transmute<T>` is `#[repr(C)]`, its `t` + // and `u` fields both start at the same offset (namely, 0) within the + // union. + // + // We do this instead of just destructuring in order to prevent + // `Unalign`'s `Drop::drop` from being run, since dropping is not + // supported in `const fn`s. + // + // TODO(https://github.com/rust-lang/rust/issues/73255): Destructure + // instead of using unsafe. + unsafe { ManuallyDrop::into_inner(Transmute { u: ManuallyDrop::new(self) }.t) } + } + + /// Attempts to return a reference to the wrapped `T`, failing if `self` is + /// not properly aligned. + /// + /// If `self` does not satisfy `mem::align_of::<T>()`, then it is unsound to + /// return a reference to the wrapped `T`, and `try_deref` returns `None`. + /// + /// If `T: Unaligned`, then `Unalign<T>` implements [`Deref`], and callers + /// may prefer [`Deref::deref`], which is infallible. + #[inline(always)] + pub fn try_deref(&self) -> Option<&T> { + if !crate::util::aligned_to::<_, T>(self) { + return None; + } + + // SAFETY: `deref_unchecked`'s safety requirement is that `self` is + // aligned to `align_of::<T>()`, which we just checked. + unsafe { Some(self.deref_unchecked()) } + } + + /// Attempts to return a mutable reference to the wrapped `T`, failing if + /// `self` is not properly aligned. + /// + /// If `self` does not satisfy `mem::align_of::<T>()`, then it is unsound to + /// return a reference to the wrapped `T`, and `try_deref_mut` returns + /// `None`. + /// + /// If `T: Unaligned`, then `Unalign<T>` implements [`DerefMut`], and + /// callers may prefer [`DerefMut::deref_mut`], which is infallible. + #[inline(always)] + pub fn try_deref_mut(&mut self) -> Option<&mut T> { + if !crate::util::aligned_to::<_, T>(&*self) { + return None; + } + + // SAFETY: `deref_mut_unchecked`'s safety requirement is that `self` is + // aligned to `align_of::<T>()`, which we just checked. + unsafe { Some(self.deref_mut_unchecked()) } + } + + /// Returns a reference to the wrapped `T` without checking alignment. + /// + /// If `T: Unaligned`, then `Unalign<T>` implements[ `Deref`], and callers + /// may prefer [`Deref::deref`], which is safe. + /// + /// # Safety + /// + /// If `self` does not satisfy `mem::align_of::<T>()`, then + /// `self.deref_unchecked()` may cause undefined behavior. + #[inline(always)] + pub const unsafe fn deref_unchecked(&self) -> &T { + // SAFETY: `Unalign<T>` is `repr(transparent)`, so there is a valid `T` + // at the same memory location as `self`. It has no alignment guarantee, + // but the caller has promised that `self` is properly aligned, so we + // know that it is sound to create a reference to `T` at this memory + // location. + // + // We use `mem::transmute` instead of `&*self.get_ptr()` because + // dereferencing pointers is not stable in `const` on our current MSRV + // (1.56 as of this writing). + unsafe { mem::transmute(self) } + } + + /// Returns a mutable reference to the wrapped `T` without checking + /// alignment. + /// + /// If `T: Unaligned`, then `Unalign<T>` implements[ `DerefMut`], and + /// callers may prefer [`DerefMut::deref_mut`], which is safe. + /// + /// # Safety + /// + /// If `self` does not satisfy `mem::align_of::<T>()`, then + /// `self.deref_mut_unchecked()` may cause undefined behavior. + #[inline(always)] + pub unsafe fn deref_mut_unchecked(&mut self) -> &mut T { + // SAFETY: `self.get_mut_ptr()` returns a raw pointer to a valid `T` at + // the same memory location as `self`. It has no alignment guarantee, + // but the caller has promised that `self` is properly aligned, so we + // know that the pointer itself is aligned, and thus that it is sound to + // create a reference to a `T` at this memory location. + unsafe { &mut *self.get_mut_ptr() } + } + + /// Gets an unaligned raw pointer to the inner `T`. + /// + /// # Safety + /// + /// The returned raw pointer is not necessarily aligned to + /// `align_of::<T>()`. Most functions which operate on raw pointers require + /// those pointers to be aligned, so calling those functions with the result + /// of `get_ptr` will be undefined behavior if alignment is not guaranteed + /// using some out-of-band mechanism. In general, the only functions which + /// are safe to call with this pointer are those which are explicitly + /// documented as being sound to use with an unaligned pointer, such as + /// [`read_unaligned`]. + /// + /// [`read_unaligned`]: core::ptr::read_unaligned + #[inline(always)] + pub const fn get_ptr(&self) -> *const T { + ptr::addr_of!(self.0) + } + + /// Gets an unaligned mutable raw pointer to the inner `T`. + /// + /// # Safety + /// + /// The returned raw pointer is not necessarily aligned to + /// `align_of::<T>()`. Most functions which operate on raw pointers require + /// those pointers to be aligned, so calling those functions with the result + /// of `get_ptr` will be undefined behavior if alignment is not guaranteed + /// using some out-of-band mechanism. In general, the only functions which + /// are safe to call with this pointer are those which are explicitly + /// documented as being sound to use with an unaligned pointer, such as + /// [`read_unaligned`]. + /// + /// [`read_unaligned`]: core::ptr::read_unaligned + // TODO(https://github.com/rust-lang/rust/issues/57349): Make this `const`. + #[inline(always)] + pub fn get_mut_ptr(&mut self) -> *mut T { + ptr::addr_of_mut!(self.0) + } + + /// Sets the inner `T`, dropping the previous value. + // TODO(https://github.com/rust-lang/rust/issues/57349): Make this `const`. + #[inline(always)] + pub fn set(&mut self, t: T) { + *self = Unalign::new(t); + } + + /// Updates the inner `T` by calling a function on it. + /// + /// If [`T: Unaligned`], then `Unalign<T>` implements [`DerefMut`], and that + /// impl should be preferred over this method when performing updates, as it + /// will usually be faster and more ergonomic. + /// + /// For large types, this method may be expensive, as it requires copying + /// `2 * size_of::<T>()` bytes. \[1\] + /// + /// \[1\] Since the inner `T` may not be aligned, it would not be sound to + /// invoke `f` on it directly. Instead, `update` moves it into a + /// properly-aligned location in the local stack frame, calls `f` on it, and + /// then moves it back to its original location in `self`. + /// + /// [`T: Unaligned`]: Unaligned + #[inline] + pub fn update<O, F: FnOnce(&mut T) -> O>(&mut self, f: F) -> O { + // On drop, this moves `copy` out of itself and uses `ptr::write` to + // overwrite `slf`. + struct WriteBackOnDrop<T> { + copy: ManuallyDrop<T>, + slf: *mut Unalign<T>, + } + + impl<T> Drop for WriteBackOnDrop<T> { + fn drop(&mut self) { + // SAFETY: We never use `copy` again as required by + // `ManuallyDrop::take`. + let copy = unsafe { ManuallyDrop::take(&mut self.copy) }; + // SAFETY: `slf` is the raw pointer value of `self`. We know it + // is valid for writes and properly aligned because `self` is a + // mutable reference, which guarantees both of these properties. + unsafe { ptr::write(self.slf, Unalign::new(copy)) }; + } + } + + // SAFETY: We know that `self` is valid for reads, properly aligned, and + // points to an initialized `Unalign<T>` because it is a mutable + // reference, which guarantees all of these properties. + // + // Since `T: !Copy`, it would be unsound in the general case to allow + // both the original `Unalign<T>` and the copy to be used by safe code. + // We guarantee that the copy is used to overwrite the original in the + // `Drop::drop` impl of `WriteBackOnDrop`. So long as this `drop` is + // called before any other safe code executes, soundness is upheld. + // While this method can terminate in two ways (by returning normally or + // by unwinding due to a panic in `f`), in both cases, `write_back` is + // dropped - and its `drop` called - before any other safe code can + // execute. + let copy = unsafe { ptr::read(self) }.into_inner(); + let mut write_back = WriteBackOnDrop { copy: ManuallyDrop::new(copy), slf: self }; + + let ret = f(&mut write_back.copy); + + drop(write_back); + ret + } +} + +impl<T: Copy> Unalign<T> { + /// Gets a copy of the inner `T`. + // TODO(https://github.com/rust-lang/rust/issues/57349): Make this `const`. + #[inline(always)] + pub fn get(&self) -> T { + let Unalign(val) = *self; + val + } +} + +impl<T: Unaligned> Deref for Unalign<T> { + type Target = T; + + #[inline(always)] + fn deref(&self) -> &T { + // SAFETY: `deref_unchecked`'s safety requirement is that `self` is + // aligned to `align_of::<T>()`. `T: Unaligned` guarantees that + // `align_of::<T>() == 1`, and all pointers are one-aligned because all + // addresses are divisible by 1. + unsafe { self.deref_unchecked() } + } +} + +impl<T: Unaligned> DerefMut for Unalign<T> { + #[inline(always)] + fn deref_mut(&mut self) -> &mut T { + // SAFETY: `deref_mut_unchecked`'s safety requirement is that `self` is + // aligned to `align_of::<T>()`. `T: Unaligned` guarantees that + // `align_of::<T>() == 1`, and all pointers are one-aligned because all + // addresses are divisible by 1. + unsafe { self.deref_mut_unchecked() } + } +} + +impl<T: Unaligned + PartialOrd> PartialOrd<Unalign<T>> for Unalign<T> { + #[inline(always)] + fn partial_cmp(&self, other: &Unalign<T>) -> Option<Ordering> { + PartialOrd::partial_cmp(self.deref(), other.deref()) + } +} + +impl<T: Unaligned + Ord> Ord for Unalign<T> { + #[inline(always)] + fn cmp(&self, other: &Unalign<T>) -> Ordering { + Ord::cmp(self.deref(), other.deref()) + } +} + +impl<T: Unaligned + PartialEq> PartialEq<Unalign<T>> for Unalign<T> { + #[inline(always)] + fn eq(&self, other: &Unalign<T>) -> bool { + PartialEq::eq(self.deref(), other.deref()) + } +} + +impl<T: Unaligned + Eq> Eq for Unalign<T> {} + +impl<T: Unaligned + Hash> Hash for Unalign<T> { + #[inline(always)] + fn hash<H>(&self, state: &mut H) + where + H: Hasher, + { + self.deref().hash(state); + } +} + +impl<T: Unaligned + Debug> Debug for Unalign<T> { + #[inline(always)] + fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result { + Debug::fmt(self.deref(), f) + } +} + +impl<T: Unaligned + Display> Display for Unalign<T> { + #[inline(always)] + fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result { + Display::fmt(self.deref(), f) + } +} + +#[cfg(test)] +mod tests { + use core::panic::AssertUnwindSafe; + + use super::*; + use crate::util::testutil::*; + + /// A `T` which is guaranteed not to satisfy `align_of::<A>()`. + /// + /// It must be the case that `align_of::<T>() < align_of::<A>()` in order + /// fot this type to work properly. + #[repr(C)] + struct ForceUnalign<T, A> { + // The outer struct is aligned to `A`, and, thanks to `repr(C)`, `t` is + // placed at the minimum offset that guarantees its alignment. If + // `align_of::<T>() < align_of::<A>()`, then that offset will be + // guaranteed *not* to satisfy `align_of::<A>()`. + _u: u8, + t: T, + _a: [A; 0], + } + + impl<T, A> ForceUnalign<T, A> { + const fn new(t: T) -> ForceUnalign<T, A> { + ForceUnalign { _u: 0, t, _a: [] } + } + } + + #[test] + fn test_unalign() { + // Test methods that don't depend on alignment. + let mut u = Unalign::new(AU64(123)); + assert_eq!(u.get(), AU64(123)); + assert_eq!(u.into_inner(), AU64(123)); + assert_eq!(u.get_ptr(), <*const _>::cast::<AU64>(&u)); + assert_eq!(u.get_mut_ptr(), <*mut _>::cast::<AU64>(&mut u)); + u.set(AU64(321)); + assert_eq!(u.get(), AU64(321)); + + // Test methods that depend on alignment (when alignment is satisfied). + let mut u: Align<_, AU64> = Align::new(Unalign::new(AU64(123))); + assert_eq!(u.t.try_deref(), Some(&AU64(123))); + assert_eq!(u.t.try_deref_mut(), Some(&mut AU64(123))); + // SAFETY: The `Align<_, AU64>` guarantees proper alignment. + assert_eq!(unsafe { u.t.deref_unchecked() }, &AU64(123)); + // SAFETY: The `Align<_, AU64>` guarantees proper alignment. + assert_eq!(unsafe { u.t.deref_mut_unchecked() }, &mut AU64(123)); + *u.t.try_deref_mut().unwrap() = AU64(321); + assert_eq!(u.t.get(), AU64(321)); + + // Test methods that depend on alignment (when alignment is not + // satisfied). + let mut u: ForceUnalign<_, AU64> = ForceUnalign::new(Unalign::new(AU64(123))); + assert_eq!(u.t.try_deref(), None); + assert_eq!(u.t.try_deref_mut(), None); + + // Test methods that depend on `T: Unaligned`. + let mut u = Unalign::new(123u8); + assert_eq!(u.try_deref(), Some(&123)); + assert_eq!(u.try_deref_mut(), Some(&mut 123)); + assert_eq!(u.deref(), &123); + assert_eq!(u.deref_mut(), &mut 123); + *u = 21; + assert_eq!(u.get(), 21); + + // Test that some `Unalign` functions and methods are `const`. + const _UNALIGN: Unalign<u64> = Unalign::new(0); + const _UNALIGN_PTR: *const u64 = _UNALIGN.get_ptr(); + const _U64: u64 = _UNALIGN.into_inner(); + // Make sure all code is considered "used". + // + // TODO(https://github.com/rust-lang/rust/issues/104084): Remove this + // attribute. + #[allow(dead_code)] + const _: () = { + let x: Align<_, AU64> = Align::new(Unalign::new(AU64(123))); + // Make sure that `deref_unchecked` is `const`. + // + // SAFETY: The `Align<_, AU64>` guarantees proper alignment. + let au64 = unsafe { x.t.deref_unchecked() }; + match au64 { + AU64(123) => {} + _ => unreachable!(), + } + }; + } + + #[test] + fn test_unalign_update() { + let mut u = Unalign::new(AU64(123)); + u.update(|a| a.0 += 1); + assert_eq!(u.get(), AU64(124)); + + // Test that, even if the callback panics, the original is still + // correctly overwritten. Use a `Box` so that Miri is more likely to + // catch any unsoundness (which would likely result in two `Box`es for + // the same heap object, which is the sort of thing that Miri would + // probably catch). + let mut u = Unalign::new(Box::new(AU64(123))); + let res = std::panic::catch_unwind(AssertUnwindSafe(|| { + u.update(|a| { + a.0 += 1; + panic!(); + }) + })); + assert!(res.is_err()); + assert_eq!(u.into_inner(), Box::new(AU64(124))); + } +} |