zerocopy/impls.rs
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// Copyright 2024 The Fuchsia Authors
//
// Licensed under the 2-Clause BSD License <LICENSE-BSD or
// https://opensource.org/license/bsd-2-clause>, 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 super::*;
safety_comment! {
/// SAFETY:
/// Per the reference [1], "the unit tuple (`()`) ... is guaranteed as a
/// zero-sized type to have a size of 0 and an alignment of 1."
/// - `Immutable`: `()` self-evidently does not contain any `UnsafeCell`s.
/// - `TryFromBytes` (with no validator), `FromZeros`, `FromBytes`: There is
/// only one possible sequence of 0 bytes, and `()` is inhabited.
/// - `IntoBytes`: Since `()` has size 0, it contains no padding bytes.
/// - `Unaligned`: `()` has alignment 1.
///
/// [1] https://doc.rust-lang.org/1.81.0/reference/type-layout.html#tuple-layout
unsafe_impl!((): Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned);
assert_unaligned!(());
}
safety_comment! {
/// SAFETY:
/// - `Immutable`: These types self-evidently do not contain any
/// `UnsafeCell`s.
/// - `TryFromBytes` (with no validator), `FromZeros`, `FromBytes`: all bit
/// patterns are valid for numeric types [1]
/// - `IntoBytes`: numeric types have no padding bytes [1]
/// - `Unaligned` (`u8` and `i8` only): The reference [2] specifies the size
/// of `u8` and `i8` as 1 byte. We also know that:
/// - Alignment is >= 1 [3]
/// - Size is an integer multiple of alignment [4]
/// - The only value >= 1 for which 1 is an integer multiple is 1
/// Therefore, the only possible alignment for `u8` and `i8` is 1.
///
/// [1] Per https://doc.rust-lang.org/1.81.0/reference/types/numeric.html#bit-validity:
///
/// For every numeric type, `T`, the bit validity of `T` is equivalent to
/// the bit validity of `[u8; size_of::<T>()]`. An uninitialized byte is
/// not a valid `u8`.
///
/// [2] https://doc.rust-lang.org/1.81.0/reference/type-layout.html#primitive-data-layout
///
/// [3] Per https://doc.rust-lang.org/1.81.0/reference/type-layout.html#size-and-alignment:
///
/// Alignment is measured in bytes, and must be at least 1.
///
/// [4] Per https://doc.rust-lang.org/1.81.0/reference/type-layout.html#size-and-alignment:
///
/// The size of a value is always a multiple of its alignment.
///
/// TODO(#278): Once we've updated the trait docs to refer to `u8`s rather
/// than bits or bytes, update this comment, especially the reference to
/// [1].
unsafe_impl!(u8: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned);
unsafe_impl!(i8: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned);
assert_unaligned!(u8, i8);
unsafe_impl!(u16: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(i16: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(u32: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(i32: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(u64: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(i64: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(u128: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(i128: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(usize: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(isize: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(f32: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(f64: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes);
#[cfg(feature = "float-nightly")]
unsafe_impl!(#[cfg_attr(doc_cfg, doc(cfg(feature = "float-nightly")))] f16: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes);
#[cfg(feature = "float-nightly")]
unsafe_impl!(#[cfg_attr(doc_cfg, doc(cfg(feature = "float-nightly")))] f128: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes);
}
safety_comment! {
/// SAFETY:
/// - `Immutable`: `bool` self-evidently does not contain any `UnsafeCell`s.
/// - `FromZeros`: Valid since "[t]he value false has the bit pattern 0x00"
/// [1].
/// - `IntoBytes`: Since "the boolean type has a size and alignment of 1
/// each" and "The value false has the bit pattern 0x00 and the value true
/// has the bit pattern 0x01" [1]. Thus, the only byte of the bool is
/// always initialized.
/// - `Unaligned`: Per the reference [1], "[a]n object with the boolean type
/// has a size and alignment of 1 each."
///
/// [1] https://doc.rust-lang.org/1.81.0/reference/types/boolean.html
unsafe_impl!(bool: Immutable, FromZeros, IntoBytes, Unaligned);
assert_unaligned!(bool);
/// SAFETY:
/// - The safety requirements for `unsafe_impl!` with an `is_bit_valid`
/// closure:
/// - Given `t: *mut bool` and `let r = *mut u8`, `r` refers to an object
/// of the same size as that referred to by `t`. This is true because
/// `bool` and `u8` have the same size (1 byte) [1]. Neither `r` nor `t`
/// contain `UnsafeCell`s because neither `bool` nor `u8` do [4].
/// - Since the closure takes a `&u8` argument, given a `Maybe<'a,
/// bool>` which satisfies the preconditions of
/// `TryFromBytes::<bool>::is_bit_valid`, it must be guaranteed that the
/// memory referenced by that `MaybeValid` always contains a valid `u8`.
/// Since `bool`'s single byte is always initialized, `is_bit_valid`'s
/// precondition requires that the same is true of its argument. Since
/// `u8`'s only bit validity invariant is that its single byte must be
/// initialized, this memory is guaranteed to contain a valid `u8`.
/// - The impl must only return `true` for its argument if the original
/// `Maybe<bool>` refers to a valid `bool`. We only return true if
/// the `u8` value is 0 or 1, and both of these are valid values for
/// `bool`. [3]
///
/// [1] Per https://doc.rust-lang.org/1.81.0/reference/type-layout.html#primitive-data-layout:
///
/// The size of most primitives is given in this table.
///
/// | Type | `size_of::<Type>() ` |
/// |-----------|----------------------|
/// | `bool` | 1 |
/// | `u8`/`i8` | 1 |
///
/// [2] Per https://doc.rust-lang.org/1.81.0/reference/type-layout.html#size-and-alignment:
///
/// The size of a value is always a multiple of its alignment.
///
/// [3] Per https://doc.rust-lang.org/1.81.0/reference/types/boolean.html:
///
/// The value false has the bit pattern 0x00 and the value true has the
/// bit pattern 0x01.
///
/// [4] TODO(#429): Justify this claim.
unsafe_impl!(bool: TryFromBytes; |byte: MaybeAligned<u8>| *byte.unaligned_as_ref() < 2);
}
safety_comment! {
/// SAFETY:
/// - `Immutable`: `char` self-evidently does not contain any `UnsafeCell`s.
/// - `FromZeros`: Per reference [1], "[a] value of type char is a Unicode
/// scalar value (i.e. a code point that is not a surrogate), represented
/// as a 32-bit unsigned word in the 0x0000 to 0xD7FF or 0xE000 to
/// 0x10FFFF range" which contains 0x0000.
/// - `IntoBytes`: `char` is per reference [1] "represented as a 32-bit
/// unsigned word" (`u32`) which is `IntoBytes`. Note that unlike `u32`,
/// not all bit patterns are valid for `char`.
///
/// [1] https://doc.rust-lang.org/1.81.0/reference/types/textual.html
unsafe_impl!(char: Immutable, FromZeros, IntoBytes);
/// SAFETY:
/// - The safety requirements for `unsafe_impl!` with an `is_bit_valid`
/// closure:
/// - Given `t: *mut char` and `let r = *mut u32`, `r` refers to an object
/// of the same size as that referred to by `t`. This is true because
/// `char` and `u32` have the same size [1]. Neither `r` nor `t` contain
/// `UnsafeCell`s because neither `char` nor `u32` do [4].
/// - Since the closure takes a `&u32` argument, given a `Maybe<'a,
/// char>` which satisfies the preconditions of
/// `TryFromBytes::<char>::is_bit_valid`, it must be guaranteed that the
/// memory referenced by that `MaybeValid` always contains a valid
/// `u32`. Since `char`'s bytes are always initialized [2],
/// `is_bit_valid`'s precondition requires that the same is true of its
/// argument. Since `u32`'s only bit validity invariant is that its
/// bytes must be initialized, this memory is guaranteed to contain a
/// valid `u32`.
/// - The impl must only return `true` for its argument if the original
/// `Maybe<char>` refers to a valid `char`. `char::from_u32`
/// guarantees that it returns `None` if its input is not a valid
/// `char`. [3]
///
/// [1] Per https://doc.rust-lang.org/nightly/reference/types/textual.html#layout-and-bit-validity:
///
/// `char` is guaranteed to have the same size and alignment as `u32` on
/// all platforms.
///
/// [2] Per https://doc.rust-lang.org/core/primitive.char.html#method.from_u32:
///
/// Every byte of a `char` is guaranteed to be initialized.
///
/// [3] Per https://doc.rust-lang.org/core/primitive.char.html#method.from_u32:
///
/// `from_u32()` will return `None` if the input is not a valid value for
/// a `char`.
///
/// [4] TODO(#429): Justify this claim.
unsafe_impl!(char: TryFromBytes; |candidate: MaybeAligned<u32>| {
let candidate = candidate.read_unaligned::<BecauseImmutable>();
char::from_u32(candidate).is_some()
});
}
safety_comment! {
/// SAFETY:
/// Per the Reference [1], `str` has the same layout as `[u8]`.
/// - `Immutable`: `[u8]` does not contain any `UnsafeCell`s.
/// - `FromZeros`, `IntoBytes`, `Unaligned`: `[u8]` is `FromZeros`,
/// `IntoBytes`, and `Unaligned`.
///
/// Note that we don't `assert_unaligned!(str)` because `assert_unaligned!`
/// uses `align_of`, which only works for `Sized` types.
///
/// TODO(#429):
/// - Add quotes from documentation.
/// - Improve safety proof for `FromZeros` and `IntoBytes`; having the same
/// layout as `[u8]` isn't sufficient.
///
/// [1] https://doc.rust-lang.org/1.81.0/reference/type-layout.html#str-layout
unsafe_impl!(str: Immutable, FromZeros, IntoBytes, Unaligned);
/// SAFETY:
/// - The safety requirements for `unsafe_impl!` with an `is_bit_valid`
/// closure:
/// - Given `t: *mut str` and `let r = *mut [u8]`, `r` refers to an object
/// of the same size as that referred to by `t`. This is true because
/// `str` and `[u8]` have the same representation. [1] Neither `t` nor
/// `r` contain `UnsafeCell`s because `[u8]` doesn't, and both `t` and
/// `r` have that representation.
/// - Since the closure takes a `&[u8]` argument, given a `Maybe<'a,
/// str>` which satisfies the preconditions of
/// `TryFromBytes::<str>::is_bit_valid`, it must be guaranteed that the
/// memory referenced by that `MaybeValid` always contains a valid
/// `[u8]`. Since `str`'s bytes are always initialized [1],
/// `is_bit_valid`'s precondition requires that the same is true of its
/// argument. Since `[u8]`'s only bit validity invariant is that its
/// bytes must be initialized, this memory is guaranteed to contain a
/// valid `[u8]`.
/// - The impl must only return `true` for its argument if the original
/// `Maybe<str>` refers to a valid `str`. `str::from_utf8`
/// guarantees that it returns `Err` if its input is not a valid `str`.
/// [2]
///
/// [1] Per https://doc.rust-lang.org/1.81.0/reference/types/textual.html:
///
/// A value of type `str` is represented the same was as `[u8]`.
///
/// [2] Per https://doc.rust-lang.org/core/str/fn.from_utf8.html#errors:
///
/// Returns `Err` if the slice is not UTF-8.
unsafe_impl!(str: TryFromBytes; |candidate: MaybeAligned<[u8]>| {
let candidate = candidate.unaligned_as_ref();
core::str::from_utf8(candidate).is_ok()
});
}
safety_comment! {
// `NonZeroXxx` is `IntoBytes`, but not `FromZeros` or `FromBytes`.
//
/// SAFETY:
/// - `IntoBytes`: `NonZeroXxx` has the same layout as its associated
/// primitive. Since it is the same size, this guarantees it has no
/// padding - integers have no padding, and there's no room for padding
/// if it can represent all of the same values except 0.
/// - `Unaligned`: `NonZeroU8` and `NonZeroI8` document that
/// `Option<NonZeroU8>` and `Option<NonZeroI8>` both have size 1. [1] [2]
/// This is worded in a way that makes it unclear whether it's meant as a
/// guarantee, but given the purpose of those types, it's virtually
/// unthinkable that that would ever change. `Option` cannot be smaller
/// than its contained type, which implies that, and `NonZeroX8` are of
/// size 1 or 0. `NonZeroX8` can represent multiple states, so they cannot
/// be 0 bytes, which means that they must be 1 byte. The only valid
/// alignment for a 1-byte type is 1.
///
/// TODO(#429):
/// - Add quotes from documentation.
/// - Add safety comment for `Immutable`. How can we prove that `NonZeroXxx`
/// doesn't contain any `UnsafeCell`s? It's obviously true, but it's not
/// clear how we'd prove it short of adding text to the stdlib docs that
/// says so explicitly, which likely wouldn't be accepted.
///
/// [1] https://doc.rust-lang.org/1.81.0/std/num/type.NonZeroU8.html
///
/// `NonZeroU8` is guaranteed to have the same layout and bit validity as `u8` with
/// the exception that 0 is not a valid instance
///
/// [2] https://doc.rust-lang.org/1.81.0/std/num/type.NonZeroI8.html
/// TODO(https://github.com/rust-lang/rust/pull/104082): Cite documentation
/// that layout is the same as primitive layout.
unsafe_impl!(NonZeroU8: Immutable, IntoBytes, Unaligned);
unsafe_impl!(NonZeroI8: Immutable, IntoBytes, Unaligned);
assert_unaligned!(NonZeroU8, NonZeroI8);
unsafe_impl!(NonZeroU16: Immutable, IntoBytes);
unsafe_impl!(NonZeroI16: Immutable, IntoBytes);
unsafe_impl!(NonZeroU32: Immutable, IntoBytes);
unsafe_impl!(NonZeroI32: Immutable, IntoBytes);
unsafe_impl!(NonZeroU64: Immutable, IntoBytes);
unsafe_impl!(NonZeroI64: Immutable, IntoBytes);
unsafe_impl!(NonZeroU128: Immutable, IntoBytes);
unsafe_impl!(NonZeroI128: Immutable, IntoBytes);
unsafe_impl!(NonZeroUsize: Immutable, IntoBytes);
unsafe_impl!(NonZeroIsize: Immutable, IntoBytes);
/// SAFETY:
/// - The safety requirements for `unsafe_impl!` with an `is_bit_valid`
/// closure:
/// - Given `t: *mut NonZeroXxx` and `let r = *mut xxx`, `r` refers to an
/// object of the same size as that referred to by `t`. This is true
/// because `NonZeroXxx` and `xxx` have the same size. [1] Neither `r`
/// nor `t` refer to any `UnsafeCell`s because neither `NonZeroXxx` [2]
/// nor `xxx` do.
/// - Since the closure takes a `&xxx` argument, given a `Maybe<'a,
/// NonZeroXxx>` which satisfies the preconditions of
/// `TryFromBytes::<NonZeroXxx>::is_bit_valid`, it must be guaranteed
/// that the memory referenced by that `MabyeValid` always contains a
/// valid `xxx`. Since `NonZeroXxx`'s bytes are always initialized [1],
/// `is_bit_valid`'s precondition requires that the same is true of its
/// argument. Since `xxx`'s only bit validity invariant is that its
/// bytes must be initialized, this memory is guaranteed to contain a
/// valid `xxx`.
/// - The impl must only return `true` for its argument if the original
/// `Maybe<NonZeroXxx>` refers to a valid `NonZeroXxx`. The only
/// `xxx` which is not also a valid `NonZeroXxx` is 0. [1]
///
/// [1] Per https://doc.rust-lang.org/1.81.0/core/num/type.NonZeroU16.html:
///
/// `NonZeroU16` is guaranteed to have the same layout and bit validity as
/// `u16` with the exception that `0` is not a valid instance.
///
/// [2] `NonZeroXxx` self-evidently does not contain `UnsafeCell`s. This is
/// not a proof, but we are accepting this as a known risk per #1358.
unsafe_impl!(NonZeroU8: TryFromBytes; |n: MaybeAligned<u8>| NonZeroU8::new(n.read_unaligned::<BecauseImmutable>()).is_some());
unsafe_impl!(NonZeroI8: TryFromBytes; |n: MaybeAligned<i8>| NonZeroI8::new(n.read_unaligned::<BecauseImmutable>()).is_some());
unsafe_impl!(NonZeroU16: TryFromBytes; |n: MaybeAligned<u16>| NonZeroU16::new(n.read_unaligned::<BecauseImmutable>()).is_some());
unsafe_impl!(NonZeroI16: TryFromBytes; |n: MaybeAligned<i16>| NonZeroI16::new(n.read_unaligned::<BecauseImmutable>()).is_some());
unsafe_impl!(NonZeroU32: TryFromBytes; |n: MaybeAligned<u32>| NonZeroU32::new(n.read_unaligned::<BecauseImmutable>()).is_some());
unsafe_impl!(NonZeroI32: TryFromBytes; |n: MaybeAligned<i32>| NonZeroI32::new(n.read_unaligned::<BecauseImmutable>()).is_some());
unsafe_impl!(NonZeroU64: TryFromBytes; |n: MaybeAligned<u64>| NonZeroU64::new(n.read_unaligned::<BecauseImmutable>()).is_some());
unsafe_impl!(NonZeroI64: TryFromBytes; |n: MaybeAligned<i64>| NonZeroI64::new(n.read_unaligned::<BecauseImmutable>()).is_some());
unsafe_impl!(NonZeroU128: TryFromBytes; |n: MaybeAligned<u128>| NonZeroU128::new(n.read_unaligned::<BecauseImmutable>()).is_some());
unsafe_impl!(NonZeroI128: TryFromBytes; |n: MaybeAligned<i128>| NonZeroI128::new(n.read_unaligned::<BecauseImmutable>()).is_some());
unsafe_impl!(NonZeroUsize: TryFromBytes; |n: MaybeAligned<usize>| NonZeroUsize::new(n.read_unaligned::<BecauseImmutable>()).is_some());
unsafe_impl!(NonZeroIsize: TryFromBytes; |n: MaybeAligned<isize>| NonZeroIsize::new(n.read_unaligned::<BecauseImmutable>()).is_some());
}
safety_comment! {
/// SAFETY:
/// - `TryFromBytes` (with no validator), `FromZeros`, `FromBytes`,
/// `IntoBytes`: The Rust compiler reuses `0` value to represent `None`,
/// so `size_of::<Option<NonZeroXxx>>() == size_of::<xxx>()`; see
/// `NonZeroXxx` documentation.
/// - `Unaligned`: `NonZeroU8` and `NonZeroI8` document that
/// `Option<NonZeroU8>` and `Option<NonZeroI8>` both have size 1. [1] [2]
/// This is worded in a way that makes it unclear whether it's meant as a
/// guarantee, but given the purpose of those types, it's virtually
/// unthinkable that that would ever change. The only valid alignment for
/// a 1-byte type is 1.
///
/// TODO(#429): Add quotes from documentation.
///
/// [1] https://doc.rust-lang.org/stable/std/num/struct.NonZeroU8.html
/// [2] https://doc.rust-lang.org/stable/std/num/struct.NonZeroI8.html
///
/// TODO(https://github.com/rust-lang/rust/pull/104082): Cite documentation
/// for layout guarantees.
unsafe_impl!(Option<NonZeroU8>: TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned);
unsafe_impl!(Option<NonZeroI8>: TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned);
assert_unaligned!(Option<NonZeroU8>, Option<NonZeroI8>);
unsafe_impl!(Option<NonZeroU16>: TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(Option<NonZeroI16>: TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(Option<NonZeroU32>: TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(Option<NonZeroI32>: TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(Option<NonZeroU64>: TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(Option<NonZeroI64>: TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(Option<NonZeroU128>: TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(Option<NonZeroI128>: TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(Option<NonZeroUsize>: TryFromBytes, FromZeros, FromBytes, IntoBytes);
unsafe_impl!(Option<NonZeroIsize>: TryFromBytes, FromZeros, FromBytes, IntoBytes);
}
safety_comment! {
/// SAFETY:
/// While it's not fully documented, the consensus is that `Box<T>` does not
/// contain any `UnsafeCell`s for `T: Sized` [1]. This is not a complete
/// proof, but we are accepting this as a known risk per #1358.
///
/// [1] https://github.com/rust-lang/unsafe-code-guidelines/issues/492
#[cfg(feature = "alloc")]
unsafe_impl!(
#[cfg_attr(doc_cfg, doc(cfg(feature = "alloc")))]
T: Sized => Immutable for Box<T>
);
}
safety_comment! {
/// SAFETY:
/// The following types can be transmuted from `[0u8; size_of::<T>()]`. [1]
///
/// [1] Per https://doc.rust-lang.org/nightly/core/option/index.html#representation:
///
/// Rust guarantees to optimize the following types `T` such that
/// [`Option<T>`] has the same size and alignment as `T`. In some of these
/// cases, Rust further guarantees that `transmute::<_, Option<T>>([0u8;
/// size_of::<T>()])` is sound and produces `Option::<T>::None`. These
/// cases are identified by the second column:
///
/// | `T` | `transmute::<_, Option<T>>([0u8; size_of::<T>()])` sound? |
/// |-----------------------|-----------------------------------------------------------|
/// | [`Box<U>`] | when `U: Sized` |
/// | `&U` | when `U: Sized` |
/// | `&mut U` | when `U: Sized` |
/// | [`ptr::NonNull<U>`] | when `U: Sized` |
/// | `fn`, `extern "C" fn` | always |
///
/// TODO(#429), TODO(https://github.com/rust-lang/rust/pull/115333): Cite
/// the Stable docs once they're available.
#[cfg(feature = "alloc")]
unsafe_impl!(
#[cfg_attr(doc_cfg, doc(cfg(feature = "alloc")))]
T => TryFromBytes for Option<Box<T>>;
|c: Maybe<Option<Box<T>>>| pointer::is_zeroed(c)
);
#[cfg(feature = "alloc")]
unsafe_impl!(
#[cfg_attr(doc_cfg, doc(cfg(feature = "alloc")))]
T => FromZeros for Option<Box<T>>
);
unsafe_impl!(
T => TryFromBytes for Option<&'_ T>;
|c: Maybe<Option<&'_ T>>| pointer::is_zeroed(c)
);
unsafe_impl!(T => FromZeros for Option<&'_ T>);
unsafe_impl!(
T => TryFromBytes for Option<&'_ mut T>;
|c: Maybe<Option<&'_ mut T>>| pointer::is_zeroed(c)
);
unsafe_impl!(T => FromZeros for Option<&'_ mut T>);
unsafe_impl!(
T => TryFromBytes for Option<NonNull<T>>;
|c: Maybe<Option<NonNull<T>>>| pointer::is_zeroed(c)
);
unsafe_impl!(T => FromZeros for Option<NonNull<T>>);
unsafe_impl_for_power_set!(A, B, C, D, E, F, G, H, I, J, K, L -> M => FromZeros for opt_fn!(...));
unsafe_impl_for_power_set!(
A, B, C, D, E, F, G, H, I, J, K, L -> M => TryFromBytes for opt_fn!(...);
|c: Maybe<Self>| pointer::is_zeroed(c)
);
unsafe_impl_for_power_set!(A, B, C, D, E, F, G, H, I, J, K, L -> M => FromZeros for opt_extern_c_fn!(...));
unsafe_impl_for_power_set!(
A, B, C, D, E, F, G, H, I, J, K, L -> M => TryFromBytes for opt_extern_c_fn!(...);
|c: Maybe<Self>| pointer::is_zeroed(c)
);
}
safety_comment! {
/// SAFETY:
/// `fn()` and `extern "C" fn()` self-evidently do not contain
/// `UnsafeCell`s. This is not a proof, but we are accepting this as a known
/// risk per #1358.
unsafe_impl_for_power_set!(A, B, C, D, E, F, G, H, I, J, K, L -> M => Immutable for opt_fn!(...));
unsafe_impl_for_power_set!(A, B, C, D, E, F, G, H, I, J, K, L -> M => Immutable for opt_extern_c_fn!(...));
}
#[cfg(all(
zerocopy_target_has_atomics_1_60_0,
any(
target_has_atomic = "8",
target_has_atomic = "16",
target_has_atomic = "32",
target_has_atomic = "64",
target_has_atomic = "ptr"
)
))]
#[cfg_attr(doc_cfg, doc(cfg(rust = "1.60.0")))]
mod atomics {
use super::*;
macro_rules! impl_traits_for_atomics {
($($atomics:ident),* $(,)?) => {
$(
impl_known_layout!($atomics);
impl_for_transparent_wrapper!(=> TryFromBytes for $atomics);
impl_for_transparent_wrapper!(=> FromZeros for $atomics);
impl_for_transparent_wrapper!(=> FromBytes for $atomics);
impl_for_transparent_wrapper!(=> IntoBytes for $atomics);
)*
};
}
#[cfg(target_has_atomic = "8")]
#[cfg_attr(doc_cfg, doc(cfg(target_has_atomic = "8")))]
mod atomic_8 {
use core::sync::atomic::{AtomicBool, AtomicI8, AtomicU8};
use super::*;
impl_traits_for_atomics!(AtomicU8, AtomicI8);
impl_known_layout!(AtomicBool);
impl_for_transparent_wrapper!(=> TryFromBytes for AtomicBool);
impl_for_transparent_wrapper!(=> FromZeros for AtomicBool);
impl_for_transparent_wrapper!(=> IntoBytes for AtomicBool);
safety_comment! {
/// SAFETY:
/// Per [1], `AtomicBool`, `AtomicU8`, and `AtomicI8` have the same
/// size as `bool`, `u8`, and `i8` respectively. Since a type's
/// alignment cannot be smaller than 1 [2], and since its alignment
/// cannot be greater than its size [3], the only possible value for
/// the alignment is 1. Thus, it is sound to implement `Unaligned`.
///
/// [1] Per (for example) https://doc.rust-lang.org/1.81.0/std/sync/atomic/struct.AtomicU8.html:
///
/// This type has the same size, alignment, and bit validity as
/// the underlying integer type
///
/// [2] Per https://doc.rust-lang.org/1.81.0/reference/type-layout.html#size-and-alignment:
///
/// Alignment is measured in bytes, and must be at least 1.
///
/// [3] Per https://doc.rust-lang.org/1.81.0/reference/type-layout.html#size-and-alignment:
///
/// The size of a value is always a multiple of its alignment.
unsafe_impl!(AtomicBool: Unaligned);
unsafe_impl!(AtomicU8: Unaligned);
unsafe_impl!(AtomicI8: Unaligned);
assert_unaligned!(AtomicBool, AtomicU8, AtomicI8);
/// SAFETY:
/// All of these pass an atomic type and that type's native equivalent, as
/// required by the macro safety preconditions.
unsafe_impl_transparent_wrapper_for_atomic!(AtomicU8 [u8], AtomicI8 [i8], AtomicBool [bool]);
}
}
#[cfg(target_has_atomic = "16")]
#[cfg_attr(doc_cfg, doc(cfg(target_has_atomic = "16")))]
mod atomic_16 {
use core::sync::atomic::{AtomicI16, AtomicU16};
use super::*;
impl_traits_for_atomics!(AtomicU16, AtomicI16);
safety_comment! {
/// SAFETY:
/// All of these pass an atomic type and that type's native equivalent, as
/// required by the macro safety preconditions.
unsafe_impl_transparent_wrapper_for_atomic!(AtomicU16 [u16], AtomicI16 [i16]);
}
}
#[cfg(target_has_atomic = "32")]
#[cfg_attr(doc_cfg, doc(cfg(target_has_atomic = "32")))]
mod atomic_32 {
use core::sync::atomic::{AtomicI32, AtomicU32};
use super::*;
impl_traits_for_atomics!(AtomicU32, AtomicI32);
safety_comment! {
/// SAFETY:
/// All of these pass an atomic type and that type's native equivalent, as
/// required by the macro safety preconditions.
unsafe_impl_transparent_wrapper_for_atomic!(AtomicU32 [u32], AtomicI32 [i32]);
}
}
#[cfg(target_has_atomic = "64")]
#[cfg_attr(doc_cfg, doc(cfg(target_has_atomic = "64")))]
mod atomic_64 {
use core::sync::atomic::{AtomicI64, AtomicU64};
use super::*;
impl_traits_for_atomics!(AtomicU64, AtomicI64);
safety_comment! {
/// SAFETY:
/// All of these pass an atomic type and that type's native equivalent, as
/// required by the macro safety preconditions.
unsafe_impl_transparent_wrapper_for_atomic!(AtomicU64 [u64], AtomicI64 [i64]);
}
}
#[cfg(target_has_atomic = "ptr")]
#[cfg_attr(doc_cfg, doc(cfg(target_has_atomic = "ptr")))]
mod atomic_ptr {
use core::sync::atomic::{AtomicIsize, AtomicPtr, AtomicUsize};
use super::*;
impl_traits_for_atomics!(AtomicUsize, AtomicIsize);
impl_known_layout!(T => AtomicPtr<T>);
// TODO(#170): Implement `FromBytes` and `IntoBytes` once we implement
// those traits for `*mut T`.
impl_for_transparent_wrapper!(T => TryFromBytes for AtomicPtr<T>);
impl_for_transparent_wrapper!(T => FromZeros for AtomicPtr<T>);
safety_comment! {
/// SAFETY:
/// This passes an atomic type and that type's native equivalent, as
/// required by the macro safety preconditions.
unsafe_impl_transparent_wrapper_for_atomic!(AtomicUsize [usize], AtomicIsize [isize]);
unsafe_impl_transparent_wrapper_for_atomic!(T => AtomicPtr<T> [*mut T]);
}
}
}
safety_comment! {
/// SAFETY:
/// Per reference [1]:
/// "For all T, the following are guaranteed:
/// size_of::<PhantomData<T>>() == 0
/// align_of::<PhantomData<T>>() == 1".
/// This gives:
/// - `Immutable`: `PhantomData` has no fields.
/// - `TryFromBytes` (with no validator), `FromZeros`, `FromBytes`: There is
/// only one possible sequence of 0 bytes, and `PhantomData` is inhabited.
/// - `IntoBytes`: Since `PhantomData` has size 0, it contains no padding
/// bytes.
/// - `Unaligned`: Per the preceding reference, `PhantomData` has alignment
/// 1.
///
/// [1] https://doc.rust-lang.org/1.81.0/std/marker/struct.PhantomData.html#layout-1
unsafe_impl!(T: ?Sized => Immutable for PhantomData<T>);
unsafe_impl!(T: ?Sized => TryFromBytes for PhantomData<T>);
unsafe_impl!(T: ?Sized => FromZeros for PhantomData<T>);
unsafe_impl!(T: ?Sized => FromBytes for PhantomData<T>);
unsafe_impl!(T: ?Sized => IntoBytes for PhantomData<T>);
unsafe_impl!(T: ?Sized => Unaligned for PhantomData<T>);
assert_unaligned!(PhantomData<()>, PhantomData<u8>, PhantomData<u64>);
}
impl_for_transparent_wrapper!(T: Immutable => Immutable for Wrapping<T>);
impl_for_transparent_wrapper!(T: TryFromBytes => TryFromBytes for Wrapping<T>);
impl_for_transparent_wrapper!(T: FromZeros => FromZeros for Wrapping<T>);
impl_for_transparent_wrapper!(T: FromBytes => FromBytes for Wrapping<T>);
impl_for_transparent_wrapper!(T: IntoBytes => IntoBytes for Wrapping<T>);
impl_for_transparent_wrapper!(T: Unaligned => Unaligned for Wrapping<T>);
assert_unaligned!(Wrapping<()>, Wrapping<u8>);
safety_comment! {
/// SAFETY:
/// `TryFromBytes` (with no validator), `FromZeros`, `FromBytes`:
/// `MaybeUninit<T>` has no restrictions on its contents.
unsafe_impl!(T => TryFromBytes for MaybeUninit<T>);
unsafe_impl!(T => FromZeros for MaybeUninit<T>);
unsafe_impl!(T => FromBytes for MaybeUninit<T>);
}
impl_for_transparent_wrapper!(T: Immutable => Immutable for MaybeUninit<T>);
impl_for_transparent_wrapper!(T: Unaligned => Unaligned for MaybeUninit<T>);
assert_unaligned!(MaybeUninit<()>, MaybeUninit<u8>);
impl_for_transparent_wrapper!(T: ?Sized + Immutable => Immutable for ManuallyDrop<T>);
impl_for_transparent_wrapper!(T: ?Sized + TryFromBytes => TryFromBytes for ManuallyDrop<T>);
impl_for_transparent_wrapper!(T: ?Sized + FromZeros => FromZeros for ManuallyDrop<T>);
impl_for_transparent_wrapper!(T: ?Sized + FromBytes => FromBytes for ManuallyDrop<T>);
impl_for_transparent_wrapper!(T: ?Sized + IntoBytes => IntoBytes for ManuallyDrop<T>);
impl_for_transparent_wrapper!(T: ?Sized + Unaligned => Unaligned for ManuallyDrop<T>);
assert_unaligned!(ManuallyDrop<()>, ManuallyDrop<u8>);
impl_for_transparent_wrapper!(T: ?Sized + FromZeros => FromZeros for UnsafeCell<T>);
impl_for_transparent_wrapper!(T: ?Sized + FromBytes => FromBytes for UnsafeCell<T>);
impl_for_transparent_wrapper!(T: ?Sized + IntoBytes => IntoBytes for UnsafeCell<T>);
impl_for_transparent_wrapper!(T: ?Sized + Unaligned => Unaligned for UnsafeCell<T>);
assert_unaligned!(UnsafeCell<()>, UnsafeCell<u8>);
// SAFETY: See safety comment in `is_bit_valid` impl.
unsafe impl<T: TryFromBytes + ?Sized> TryFromBytes for UnsafeCell<T> {
#[allow(clippy::missing_inline_in_public_items)]
fn only_derive_is_allowed_to_implement_this_trait()
where
Self: Sized,
{
}
#[inline]
fn is_bit_valid<A: invariant::Aliasing + invariant::AtLeast<invariant::Shared>>(
candidate: Maybe<'_, Self, A>,
) -> bool {
// The only way to implement this function is using an exclusive-aliased
// pointer. `UnsafeCell`s cannot be read via shared-aliased pointers
// (other than by using `unsafe` code, which we can't use since we can't
// guarantee how our users are accessing or modifying the `UnsafeCell`).
//
// `is_bit_valid` is documented as panicking or failing to monomorphize
// if called with a shared-aliased pointer on a type containing an
// `UnsafeCell`. In practice, it will always be a monorphization error.
// Since `is_bit_valid` is `#[doc(hidden)]` and only called directly
// from this crate, we only need to worry about our own code incorrectly
// calling `UnsafeCell::is_bit_valid`. The post-monomorphization error
// makes it easier to test that this is truly the case, and also means
// that if we make a mistake, it will cause downstream code to fail to
// compile, which will immediately surface the mistake and give us a
// chance to fix it quickly.
let c = candidate.into_exclusive_or_post_monomorphization_error();
// SAFETY: Since `UnsafeCell<T>` and `T` have the same layout and bit
// validity, `UnsafeCell<T>` is bit-valid exactly when its wrapped `T`
// is. Thus, this is a sound implementation of
// `UnsafeCell::is_bit_valid`.
T::is_bit_valid(c.get_mut())
}
}
safety_comment! {
/// SAFETY:
/// Per the reference [1]:
///
/// An array of `[T; N]` has a size of `size_of::<T>() * N` and the same
/// alignment of `T`. Arrays are laid out so that the zero-based `nth`
/// element of the array is offset from the start of the array by `n *
/// size_of::<T>()` bytes.
///
/// ...
///
/// Slices have the same layout as the section of the array they slice.
///
/// In other words, the layout of a `[T]` or `[T; N]` is a sequence of `T`s
/// laid out back-to-back with no bytes in between. Therefore, `[T]` or `[T;
/// N]` are `Immutable`, `TryFromBytes`, `FromZeros`, `FromBytes`, and
/// `IntoBytes` if `T` is (respectively). Furthermore, since an array/slice
/// has "the same alignment of `T`", `[T]` and `[T; N]` are `Unaligned` if
/// `T` is.
///
/// Note that we don't `assert_unaligned!` for slice types because
/// `assert_unaligned!` uses `align_of`, which only works for `Sized` types.
///
/// [1] https://doc.rust-lang.org/1.81.0/reference/type-layout.html#array-layout
unsafe_impl!(const N: usize, T: Immutable => Immutable for [T; N]);
unsafe_impl!(const N: usize, T: TryFromBytes => TryFromBytes for [T; N]; |c: Maybe<[T; N]>| {
// Note that this call may panic, but it would still be sound even if it
// did. `is_bit_valid` does not promise that it will not panic (in fact,
// it explicitly warns that it's a possibility), and we have not
// violated any safety invariants that we must fix before returning.
<[T] as TryFromBytes>::is_bit_valid(c.as_slice())
});
unsafe_impl!(const N: usize, T: FromZeros => FromZeros for [T; N]);
unsafe_impl!(const N: usize, T: FromBytes => FromBytes for [T; N]);
unsafe_impl!(const N: usize, T: IntoBytes => IntoBytes for [T; N]);
unsafe_impl!(const N: usize, T: Unaligned => Unaligned for [T; N]);
assert_unaligned!([(); 0], [(); 1], [u8; 0], [u8; 1]);
unsafe_impl!(T: Immutable => Immutable for [T]);
unsafe_impl!(T: TryFromBytes => TryFromBytes for [T]; |c: Maybe<[T]>| {
// SAFETY: Per the reference [1]:
//
// An array of `[T; N]` has a size of `size_of::<T>() * N` and the
// same alignment of `T`. Arrays are laid out so that the zero-based
// `nth` element of the array is offset from the start of the array by
// `n * size_of::<T>()` bytes.
//
// ...
//
// Slices have the same layout as the section of the array they slice.
//
// In other words, the layout of a `[T] is a sequence of `T`s laid out
// back-to-back with no bytes in between. If all elements in `candidate`
// are `is_bit_valid`, so too is `candidate`.
//
// Note that any of the below calls may panic, but it would still be
// sound even if it did. `is_bit_valid` does not promise that it will
// not panic (in fact, it explicitly warns that it's a possibility), and
// we have not violated any safety invariants that we must fix before
// returning.
c.iter().all(<T as TryFromBytes>::is_bit_valid)
});
unsafe_impl!(T: FromZeros => FromZeros for [T]);
unsafe_impl!(T: FromBytes => FromBytes for [T]);
unsafe_impl!(T: IntoBytes => IntoBytes for [T]);
unsafe_impl!(T: Unaligned => Unaligned for [T]);
}
safety_comment! {
/// SAFETY:
/// - `Immutable`: Raw pointers do not contain any `UnsafeCell`s.
/// - `FromZeros`: For thin pointers (note that `T: Sized`), the zero
/// pointer is considered "null". [1] No operations which require
/// provenance are legal on null pointers, so this is not a footgun.
/// - `TryFromBytes`: By the same reasoning as for `FromZeroes`, we can
/// implement `TryFromBytes` for thin pointers provided that
/// [`TryFromByte::is_bit_valid`] only produces `true` for zeroed bytes.
///
/// NOTE(#170): Implementing `FromBytes` and `IntoBytes` for raw pointers
/// would be sound, but carries provenance footguns. We want to support
/// `FromBytes` and `IntoBytes` for raw pointers eventually, but we are
/// holding off until we can figure out how to address those footguns.
///
/// [1] TODO(https://github.com/rust-lang/rust/pull/116988): Cite the
/// documentation once this PR lands.
unsafe_impl!(T: ?Sized => Immutable for *const T);
unsafe_impl!(T: ?Sized => Immutable for *mut T);
unsafe_impl!(T => TryFromBytes for *const T; |c: Maybe<*const T>| {
pointer::is_zeroed(c)
});
unsafe_impl!(T => FromZeros for *const T);
unsafe_impl!(T => TryFromBytes for *mut T; |c: Maybe<*const T>| {
pointer::is_zeroed(c)
});
unsafe_impl!(T => FromZeros for *mut T);
}
safety_comment! {
/// SAFETY:
/// `NonNull<T>` self-evidently does not contain `UnsafeCell`s. This is not
/// a proof, but we are accepting this as a known risk per #1358.
unsafe_impl!(T: ?Sized => Immutable for NonNull<T>);
}
safety_comment! {
/// SAFETY:
/// Reference types do not contain any `UnsafeCell`s.
unsafe_impl!(T: ?Sized => Immutable for &'_ T);
unsafe_impl!(T: ?Sized => Immutable for &'_ mut T);
}
safety_comment! {
/// SAFETY:
/// `Option` is not `#[non_exhaustive]` [1], which means that the types in
/// its variants cannot change, and no new variants can be added.
/// `Option<T>` does not contain any `UnsafeCell`s outside of `T`. [1]
///
/// [1] https://doc.rust-lang.org/core/option/enum.Option.html
unsafe_impl!(T: Immutable => Immutable for Option<T>);
}
// SIMD support
//
// Per the Unsafe Code Guidelines Reference [1]:
//
// Packed SIMD vector types are `repr(simd)` homogeneous tuple-structs
// containing `N` elements of type `T` where `N` is a power-of-two and the
// size and alignment requirements of `T` are equal:
//
// ```rust
// #[repr(simd)]
// struct Vector<T, N>(T_0, ..., T_(N - 1));
// ```
//
// ...
//
// The size of `Vector` is `N * size_of::<T>()` and its alignment is an
// implementation-defined function of `T` and `N` greater than or equal to
// `align_of::<T>()`.
//
// ...
//
// Vector elements are laid out in source field order, enabling random access
// to vector elements by reinterpreting the vector as an array:
//
// ```rust
// union U {
// vec: Vector<T, N>,
// arr: [T; N]
// }
//
// assert_eq!(size_of::<Vector<T, N>>(), size_of::<[T; N]>());
// assert!(align_of::<Vector<T, N>>() >= align_of::<[T; N]>());
//
// unsafe {
// let u = U { vec: Vector<T, N>(t_0, ..., t_(N - 1)) };
//
// assert_eq!(u.vec.0, u.arr[0]);
// // ...
// assert_eq!(u.vec.(N - 1), u.arr[N - 1]);
// }
// ```
//
// Given this background, we can observe that:
// - The size and bit pattern requirements of a SIMD type are equivalent to the
// equivalent array type. Thus, for any SIMD type whose primitive `T` is
// `Immutable`, `TryFromBytes`, `FromZeros`, `FromBytes`, or `IntoBytes`, that
// SIMD type is also `Immutable`, `TryFromBytes`, `FromZeros`, `FromBytes`, or
// `IntoBytes` respectively.
// - Since no upper bound is placed on the alignment, no SIMD type can be
// guaranteed to be `Unaligned`.
//
// Also per [1]:
//
// This chapter represents the consensus from issue #38. The statements in
// here are not (yet) "guaranteed" not to change until an RFC ratifies them.
//
// See issue #38 [2]. While this behavior is not technically guaranteed, the
// likelihood that the behavior will change such that SIMD types are no longer
// `TryFromBytes`, `FromZeros`, `FromBytes`, or `IntoBytes` is next to zero, as
// that would defeat the entire purpose of SIMD types. Nonetheless, we put this
// behavior behind the `simd` Cargo feature, which requires consumers to opt
// into this stability hazard.
//
// [1] https://rust-lang.github.io/unsafe-code-guidelines/layout/packed-simd-vectors.html
// [2] https://github.com/rust-lang/unsafe-code-guidelines/issues/38
#[cfg(feature = "simd")]
#[cfg_attr(doc_cfg, doc(cfg(feature = "simd")))]
mod simd {
/// Defines a module which implements `TryFromBytes`, `FromZeros`,
/// `FromBytes`, and `IntoBytes` for a set of types from a module in
/// `core::arch`.
///
/// `$arch` is both the name of the defined module and the name of the
/// module in `core::arch`, and `$typ` is the list of items from that module
/// to implement `FromZeros`, `FromBytes`, and `IntoBytes` for.
#[allow(unused_macros)] // `allow(unused_macros)` is needed because some
// target/feature combinations don't emit any impls
// and thus don't use this macro.
macro_rules! simd_arch_mod {
(#[cfg $cfg:tt] $arch:ident, $mod:ident, $($typ:ident),*) => {
#[cfg $cfg]
#[cfg_attr(doc_cfg, doc(cfg $cfg))]
mod $mod {
use core::arch::$arch::{$($typ),*};
use crate::*;
impl_known_layout!($($typ),*);
safety_comment! {
/// SAFETY:
/// See comment on module definition for justification.
$( unsafe_impl!($typ: Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes); )*
}
}
};
}
#[rustfmt::skip]
const _: () = {
simd_arch_mod!(
#[cfg(target_arch = "x86")]
x86, x86, __m128, __m128d, __m128i, __m256, __m256d, __m256i
);
simd_arch_mod!(
#[cfg(all(feature = "simd-nightly", target_arch = "x86"))]
x86, x86_nightly, __m512bh, __m512, __m512d, __m512i
);
simd_arch_mod!(
#[cfg(target_arch = "x86_64")]
x86_64, x86_64, __m128, __m128d, __m128i, __m256, __m256d, __m256i
);
simd_arch_mod!(
#[cfg(all(feature = "simd-nightly", target_arch = "x86_64"))]
x86_64, x86_64_nightly, __m512bh, __m512, __m512d, __m512i
);
simd_arch_mod!(
#[cfg(target_arch = "wasm32")]
wasm32, wasm32, v128
);
simd_arch_mod!(
#[cfg(all(feature = "simd-nightly", target_arch = "powerpc"))]
powerpc, powerpc, vector_bool_long, vector_double, vector_signed_long, vector_unsigned_long
);
simd_arch_mod!(
#[cfg(all(feature = "simd-nightly", target_arch = "powerpc64"))]
powerpc64, powerpc64, vector_bool_long, vector_double, vector_signed_long, vector_unsigned_long
);
#[cfg(zerocopy_aarch64_simd_1_59_0)]
#[cfg_attr(doc_cfg, doc(cfg(rust = "1.59.0")))]
simd_arch_mod!(
// NOTE(https://github.com/rust-lang/stdarch/issues/1484): NEON intrinsics are currently
// broken on big-endian platforms.
#[cfg(all(target_arch = "aarch64", target_endian = "little"))]
aarch64, aarch64, float32x2_t, float32x4_t, float64x1_t, float64x2_t, int8x8_t, int8x8x2_t,
int8x8x3_t, int8x8x4_t, int8x16_t, int8x16x2_t, int8x16x3_t, int8x16x4_t, int16x4_t,
int16x8_t, int32x2_t, int32x4_t, int64x1_t, int64x2_t, poly8x8_t, poly8x8x2_t, poly8x8x3_t,
poly8x8x4_t, poly8x16_t, poly8x16x2_t, poly8x16x3_t, poly8x16x4_t, poly16x4_t, poly16x8_t,
poly64x1_t, poly64x2_t, uint8x8_t, uint8x8x2_t, uint8x8x3_t, uint8x8x4_t, uint8x16_t,
uint8x16x2_t, uint8x16x3_t, uint8x16x4_t, uint16x4_t, uint16x8_t, uint32x2_t, uint32x4_t,
uint64x1_t, uint64x2_t
);
simd_arch_mod!(
#[cfg(all(feature = "simd-nightly", target_arch = "arm"))]
arm, arm, int8x4_t, uint8x4_t
);
};
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn test_impls() {
// A type that can supply test cases for testing
// `TryFromBytes::is_bit_valid`. All types passed to `assert_impls!`
// must implement this trait; that macro uses it to generate runtime
// tests for `TryFromBytes` impls.
//
// All `T: FromBytes` types are provided with a blanket impl. Other
// types must implement `TryFromBytesTestable` directly (ie using
// `impl_try_from_bytes_testable!`).
trait TryFromBytesTestable {
fn with_passing_test_cases<F: Fn(Box<Self>)>(f: F);
fn with_failing_test_cases<F: Fn(&mut [u8])>(f: F);
}
impl<T: FromBytes> TryFromBytesTestable for T {
fn with_passing_test_cases<F: Fn(Box<Self>)>(f: F) {
// Test with a zeroed value.
f(Self::new_box_zeroed().unwrap());
let ffs = {
let mut t = Self::new_zeroed();
let ptr: *mut T = &mut t;
// SAFETY: `T: FromBytes`
unsafe { ptr::write_bytes(ptr.cast::<u8>(), 0xFF, mem::size_of::<T>()) };
t
};
// Test with a value initialized with 0xFF.
f(Box::new(ffs));
}
fn with_failing_test_cases<F: Fn(&mut [u8])>(_f: F) {}
}
macro_rules! impl_try_from_bytes_testable_for_null_pointer_optimization {
($($tys:ty),*) => {
$(
impl TryFromBytesTestable for Option<$tys> {
fn with_passing_test_cases<F: Fn(Box<Self>)>(f: F) {
// Test with a zeroed value.
f(Box::new(None));
}
fn with_failing_test_cases<F: Fn(&mut [u8])>(f: F) {
for pos in 0..mem::size_of::<Self>() {
let mut bytes = [0u8; mem::size_of::<Self>()];
bytes[pos] = 0x01;
f(&mut bytes[..]);
}
}
}
)*
};
}
// Implements `TryFromBytesTestable`.
macro_rules! impl_try_from_bytes_testable {
// Base case for recursion (when the list of types has run out).
(=> @success $($success_case:expr),* $(, @failure $($failure_case:expr),*)?) => {};
// Implements for type(s) with no type parameters.
($ty:ty $(,$tys:ty)* => @success $($success_case:expr),* $(, @failure $($failure_case:expr),*)?) => {
impl TryFromBytesTestable for $ty {
impl_try_from_bytes_testable!(
@methods @success $($success_case),*
$(, @failure $($failure_case),*)?
);
}
impl_try_from_bytes_testable!($($tys),* => @success $($success_case),* $(, @failure $($failure_case),*)?);
};
// Implements for multiple types with no type parameters.
($($($ty:ty),* => @success $($success_case:expr), * $(, @failure $($failure_case:expr),*)?;)*) => {
$(
impl_try_from_bytes_testable!($($ty),* => @success $($success_case),* $(, @failure $($failure_case),*)*);
)*
};
// Implements only the methods; caller must invoke this from inside
// an impl block.
(@methods @success $($success_case:expr),* $(, @failure $($failure_case:expr),*)?) => {
fn with_passing_test_cases<F: Fn(Box<Self>)>(_f: F) {
$(
_f(Box::<Self>::from($success_case));
)*
}
fn with_failing_test_cases<F: Fn(&mut [u8])>(_f: F) {
$($(
let mut case = $failure_case;
_f(case.as_mut_bytes());
)*)?
}
};
}
impl_try_from_bytes_testable_for_null_pointer_optimization!(
Box<UnsafeCell<NotZerocopy>>,
&'static UnsafeCell<NotZerocopy>,
&'static mut UnsafeCell<NotZerocopy>,
NonNull<UnsafeCell<NotZerocopy>>,
fn(),
FnManyArgs,
extern "C" fn(),
ECFnManyArgs
);
macro_rules! bx {
($e:expr) => {
Box::new($e)
};
}
// Note that these impls are only for types which are not `FromBytes`.
// `FromBytes` types are covered by a preceding blanket impl.
impl_try_from_bytes_testable!(
bool => @success true, false,
@failure 2u8, 3u8, 0xFFu8;
char => @success '\u{0}', '\u{D7FF}', '\u{E000}', '\u{10FFFF}',
@failure 0xD800u32, 0xDFFFu32, 0x110000u32;
str => @success "", "hello", "โค๏ธ๐งก๐๐๐๐",
@failure [0, 159, 146, 150];
[u8] => @success vec![].into_boxed_slice(), vec![0, 1, 2].into_boxed_slice();
NonZeroU8, NonZeroI8, NonZeroU16, NonZeroI16, NonZeroU32,
NonZeroI32, NonZeroU64, NonZeroI64, NonZeroU128, NonZeroI128,
NonZeroUsize, NonZeroIsize
=> @success Self::new(1).unwrap(),
// Doing this instead of `0` ensures that we always satisfy
// the size and alignment requirements of `Self` (whereas `0`
// may be any integer type with a different size or alignment
// than some `NonZeroXxx` types).
@failure Option::<Self>::None;
[bool; 0] => @success [];
[bool; 1]
=> @success [true], [false],
@failure [2u8], [3u8], [0xFFu8];
[bool]
=> @success vec![true, false].into_boxed_slice(), vec![false, true].into_boxed_slice(),
@failure [2u8], [3u8], [0xFFu8], [0u8, 1u8, 2u8];
Unalign<bool>
=> @success Unalign::new(false), Unalign::new(true),
@failure 2u8, 0xFFu8;
ManuallyDrop<bool>
=> @success ManuallyDrop::new(false), ManuallyDrop::new(true),
@failure 2u8, 0xFFu8;
ManuallyDrop<[u8]>
=> @success bx!(ManuallyDrop::new([])), bx!(ManuallyDrop::new([0u8])), bx!(ManuallyDrop::new([0u8, 1u8]));
ManuallyDrop<[bool]>
=> @success bx!(ManuallyDrop::new([])), bx!(ManuallyDrop::new([false])), bx!(ManuallyDrop::new([false, true])),
@failure [2u8], [3u8], [0xFFu8], [0u8, 1u8, 2u8];
ManuallyDrop<[UnsafeCell<u8>]>
=> @success bx!(ManuallyDrop::new([UnsafeCell::new(0)])), bx!(ManuallyDrop::new([UnsafeCell::new(0), UnsafeCell::new(1)]));
ManuallyDrop<[UnsafeCell<bool>]>
=> @success bx!(ManuallyDrop::new([UnsafeCell::new(false)])), bx!(ManuallyDrop::new([UnsafeCell::new(false), UnsafeCell::new(true)])),
@failure [2u8], [3u8], [0xFFu8], [0u8, 1u8, 2u8];
Wrapping<bool>
=> @success Wrapping(false), Wrapping(true),
@failure 2u8, 0xFFu8;
*const NotZerocopy
=> @success ptr::null::<NotZerocopy>(),
@failure [0x01; mem::size_of::<*const NotZerocopy>()];
*mut NotZerocopy
=> @success ptr::null_mut::<NotZerocopy>(),
@failure [0x01; mem::size_of::<*mut NotZerocopy>()];
);
// Use the trick described in [1] to allow us to call methods
// conditional on certain trait bounds.
//
// In all of these cases, methods return `Option<R>`, where `R` is the
// return type of the method we're conditionally calling. The "real"
// implementations (the ones defined in traits using `&self`) return
// `Some`, and the default implementations (the ones defined as inherent
// methods using `&mut self`) return `None`.
//
// [1] https://github.com/dtolnay/case-studies/blob/master/autoref-specialization/README.md
mod autoref_trick {
use super::*;
pub(super) struct AutorefWrapper<T: ?Sized>(pub(super) PhantomData<T>);
pub(super) trait TestIsBitValidShared<T: ?Sized> {
#[allow(clippy::needless_lifetimes)]
fn test_is_bit_valid_shared<
'ptr,
A: invariant::Aliasing + invariant::AtLeast<invariant::Shared>,
>(
&self,
candidate: Maybe<'ptr, T, A>,
) -> Option<bool>;
}
impl<T: TryFromBytes + Immutable + ?Sized> TestIsBitValidShared<T> for AutorefWrapper<T> {
#[allow(clippy::needless_lifetimes)]
fn test_is_bit_valid_shared<
'ptr,
A: invariant::Aliasing + invariant::AtLeast<invariant::Shared>,
>(
&self,
candidate: Maybe<'ptr, T, A>,
) -> Option<bool> {
Some(T::is_bit_valid(candidate))
}
}
pub(super) trait TestTryFromRef<T: ?Sized> {
#[allow(clippy::needless_lifetimes)]
fn test_try_from_ref<'bytes>(
&self,
bytes: &'bytes [u8],
) -> Option<Option<&'bytes T>>;
}
impl<T: TryFromBytes + Immutable + KnownLayout + ?Sized> TestTryFromRef<T> for AutorefWrapper<T> {
#[allow(clippy::needless_lifetimes)]
fn test_try_from_ref<'bytes>(
&self,
bytes: &'bytes [u8],
) -> Option<Option<&'bytes T>> {
Some(T::try_ref_from_bytes(bytes).ok())
}
}
pub(super) trait TestTryReadFrom<T> {
fn test_try_read_from(&self, bytes: &[u8]) -> Option<Option<T>>;
}
impl<T: TryFromBytes> TestTryReadFrom<T> for AutorefWrapper<T> {
fn test_try_read_from(&self, bytes: &[u8]) -> Option<Option<T>> {
Some(T::try_read_from_bytes(bytes).ok())
}
}
pub(super) trait TestAsBytes<T: ?Sized> {
#[allow(clippy::needless_lifetimes)]
fn test_as_bytes<'slf, 't>(&'slf self, t: &'t T) -> Option<&'t [u8]>;
}
impl<T: IntoBytes + Immutable + ?Sized> TestAsBytes<T> for AutorefWrapper<T> {
#[allow(clippy::needless_lifetimes)]
fn test_as_bytes<'slf, 't>(&'slf self, t: &'t T) -> Option<&'t [u8]> {
Some(t.as_bytes())
}
}
}
use autoref_trick::*;
// Asserts that `$ty` is one of a list of types which are allowed to not
// provide a "real" implementation for `$fn_name`. Since the
// `autoref_trick` machinery fails silently, this allows us to ensure
// that the "default" impls are only being used for types which we
// expect.
//
// Note that, since this is a runtime test, it is possible to have an
// allowlist which is too restrictive if the function in question is
// never called for a particular type. For example, if `as_bytes` is not
// supported for a particular type, and so `test_as_bytes` returns
// `None`, methods such as `test_try_from_ref` may never be called for
// that type. As a result, it's possible that, for example, adding
// `as_bytes` support for a type would cause other allowlist assertions
// to fail. This means that allowlist assertion failures should not
// automatically be taken as a sign of a bug.
macro_rules! assert_on_allowlist {
($fn_name:ident($ty:ty) $(: $($tys:ty),*)?) => {{
use core::any::TypeId;
let allowlist: &[TypeId] = &[ $($(TypeId::of::<$tys>()),*)? ];
let allowlist_names: &[&str] = &[ $($(stringify!($tys)),*)? ];
let id = TypeId::of::<$ty>();
assert!(allowlist.contains(&id), "{} is not on allowlist for {}: {:?}", stringify!($ty), stringify!($fn_name), allowlist_names);
}};
}
// Asserts that `$ty` implements any `$trait` and doesn't implement any
// `!$trait`. Note that all `$trait`s must come before any `!$trait`s.
//
// For `T: TryFromBytes`, uses `TryFromBytesTestable` to test success
// and failure cases.
macro_rules! assert_impls {
($ty:ty: TryFromBytes) => {
// "Default" implementations that match the "real"
// implementations defined in the `autoref_trick` module above.
#[allow(unused, non_local_definitions)]
impl AutorefWrapper<$ty> {
#[allow(clippy::needless_lifetimes)]
fn test_is_bit_valid_shared<'ptr, A: invariant::Aliasing + invariant::AtLeast<invariant::Shared>>(
&mut self,
candidate: Maybe<'ptr, $ty, A>,
) -> Option<bool> {
assert_on_allowlist!(
test_is_bit_valid_shared($ty):
ManuallyDrop<UnsafeCell<()>>,
ManuallyDrop<[UnsafeCell<u8>]>,
ManuallyDrop<[UnsafeCell<bool>]>,
MaybeUninit<NotZerocopy>,
MaybeUninit<UnsafeCell<()>>,
Wrapping<UnsafeCell<()>>
);
None
}
#[allow(clippy::needless_lifetimes)]
fn test_try_from_ref<'bytes>(&mut self, _bytes: &'bytes [u8]) -> Option<Option<&'bytes $ty>> {
assert_on_allowlist!(
test_try_from_ref($ty):
ManuallyDrop<[UnsafeCell<bool>]>
);
None
}
fn test_try_read_from(&mut self, _bytes: &[u8]) -> Option<Option<&$ty>> {
assert_on_allowlist!(
test_try_read_from($ty):
str,
ManuallyDrop<[u8]>,
ManuallyDrop<[bool]>,
ManuallyDrop<[UnsafeCell<bool>]>,
[u8],
[bool]
);
None
}
fn test_as_bytes(&mut self, _t: &$ty) -> Option<&[u8]> {
assert_on_allowlist!(
test_as_bytes($ty):
Option<&'static UnsafeCell<NotZerocopy>>,
Option<&'static mut UnsafeCell<NotZerocopy>>,
Option<NonNull<UnsafeCell<NotZerocopy>>>,
Option<Box<UnsafeCell<NotZerocopy>>>,
Option<fn()>,
Option<FnManyArgs>,
Option<extern "C" fn()>,
Option<ECFnManyArgs>,
MaybeUninit<u8>,
MaybeUninit<NotZerocopy>,
MaybeUninit<UnsafeCell<()>>,
ManuallyDrop<UnsafeCell<()>>,
ManuallyDrop<[UnsafeCell<u8>]>,
ManuallyDrop<[UnsafeCell<bool>]>,
Wrapping<UnsafeCell<()>>,
*const NotZerocopy,
*mut NotZerocopy
);
None
}
}
<$ty as TryFromBytesTestable>::with_passing_test_cases(|mut val| {
// TODO(#494): These tests only get exercised for types
// which are `IntoBytes`. Once we implement #494, we should
// be able to support non-`IntoBytes` types by zeroing
// padding.
// We define `w` and `ww` since, in the case of the inherent
// methods, Rust thinks they're both borrowed mutably at the
// same time (given how we use them below). If we just
// defined a single `w` and used it for multiple operations,
// this would conflict.
//
// We `#[allow(unused_mut]` for the cases where the "real"
// impls are used, which take `&self`.
#[allow(unused_mut)]
let (mut w, mut ww) = (AutorefWrapper::<$ty>(PhantomData), AutorefWrapper::<$ty>(PhantomData));
let c = Ptr::from_ref(&*val);
let c = c.forget_aligned();
// SAFETY: TODO(#899): This is unsound. `$ty` is not
// necessarily `IntoBytes`, but that's the corner we've
// backed ourselves into by using `Ptr::from_ref`.
let c = unsafe { c.assume_initialized() };
let res = w.test_is_bit_valid_shared(c);
if let Some(res) = res {
assert!(res, "{}::is_bit_valid({:?}) (shared `Ptr`): got false, expected true", stringify!($ty), val);
}
let c = Ptr::from_mut(&mut *val);
let c = c.forget_aligned();
// SAFETY: TODO(#899): This is unsound. `$ty` is not
// necessarily `IntoBytes`, but that's the corner we've
// backed ourselves into by using `Ptr::from_ref`.
let c = unsafe { c.assume_initialized() };
let res = <$ty as TryFromBytes>::is_bit_valid(c);
assert!(res, "{}::is_bit_valid({:?}) (exclusive `Ptr`): got false, expected true", stringify!($ty), val);
// `bytes` is `Some(val.as_bytes())` if `$ty: IntoBytes +
// Immutable` and `None` otherwise.
let bytes = w.test_as_bytes(&*val);
// The inner closure returns
// `Some($ty::try_ref_from_bytes(bytes))` if `$ty:
// Immutable` and `None` otherwise.
let res = bytes.and_then(|bytes| ww.test_try_from_ref(bytes));
if let Some(res) = res {
assert!(res.is_some(), "{}::try_ref_from_bytes({:?}): got `None`, expected `Some`", stringify!($ty), val);
}
if let Some(bytes) = bytes {
// We need to get a mutable byte slice, and so we clone
// into a `Vec`. However, we also need these bytes to
// satisfy `$ty`'s alignment requirement, which isn't
// guaranteed for `Vec<u8>`. In order to get around
// this, we create a `Vec` which is twice as long as we
// need. There is guaranteed to be an aligned byte range
// of size `size_of_val(val)` within that range.
let val = &*val;
let size = mem::size_of_val(val);
let align = mem::align_of_val(val);
let mut vec = bytes.to_vec();
vec.extend(bytes);
let slc = vec.as_slice();
let offset = slc.as_ptr().align_offset(align);
let bytes_mut = &mut vec.as_mut_slice()[offset..offset+size];
bytes_mut.copy_from_slice(bytes);
let res = <$ty as TryFromBytes>::try_mut_from_bytes(bytes_mut);
assert!(res.is_ok(), "{}::try_mut_from_bytes({:?}): got `Err`, expected `Ok`", stringify!($ty), val);
}
let res = bytes.and_then(|bytes| ww.test_try_read_from(bytes));
if let Some(res) = res {
assert!(res.is_some(), "{}::try_read_from_bytes({:?}): got `None`, expected `Some`", stringify!($ty), val);
}
});
#[allow(clippy::as_conversions)]
<$ty as TryFromBytesTestable>::with_failing_test_cases(|c| {
#[allow(unused_mut)] // For cases where the "real" impls are used, which take `&self`.
let mut w = AutorefWrapper::<$ty>(PhantomData);
// This is `Some($ty::try_ref_from_bytes(c))` if `$ty:
// Immutable` and `None` otherwise.
let res = w.test_try_from_ref(c);
if let Some(res) = res {
assert!(res.is_none(), "{}::try_ref_from_bytes({:?}): got Some, expected None", stringify!($ty), c);
}
let res = <$ty as TryFromBytes>::try_mut_from_bytes(c);
assert!(res.is_err(), "{}::try_mut_from_bytes({:?}): got Ok, expected Err", stringify!($ty), c);
let res = w.test_try_read_from(c);
if let Some(res) = res {
assert!(res.is_none(), "{}::try_read_from_bytes({:?}): got Some, expected None", stringify!($ty), c);
}
});
#[allow(dead_code)]
const _: () = { static_assertions::assert_impl_all!($ty: TryFromBytes); };
};
($ty:ty: $trait:ident) => {
#[allow(dead_code)]
const _: () = { static_assertions::assert_impl_all!($ty: $trait); };
};
($ty:ty: !$trait:ident) => {
#[allow(dead_code)]
const _: () = { static_assertions::assert_not_impl_any!($ty: $trait); };
};
($ty:ty: $($trait:ident),* $(,)? $(!$negative_trait:ident),*) => {
$(
assert_impls!($ty: $trait);
)*
$(
assert_impls!($ty: !$negative_trait);
)*
};
}
// NOTE: The negative impl assertions here are not necessarily
// prescriptive. They merely serve as change detectors to make sure
// we're aware of what trait impls are getting added with a given
// change. Of course, some impls would be invalid (e.g., `bool:
// FromBytes`), and so this change detection is very important.
assert_impls!(
(): KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
Unaligned
);
assert_impls!(
u8: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
Unaligned
);
assert_impls!(
i8: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
Unaligned
);
assert_impls!(
u16: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
!Unaligned
);
assert_impls!(
i16: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
!Unaligned
);
assert_impls!(
u32: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
!Unaligned
);
assert_impls!(
i32: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
!Unaligned
);
assert_impls!(
u64: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
!Unaligned
);
assert_impls!(
i64: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
!Unaligned
);
assert_impls!(
u128: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
!Unaligned
);
assert_impls!(
i128: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
!Unaligned
);
assert_impls!(
usize: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
!Unaligned
);
assert_impls!(
isize: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
!Unaligned
);
assert_impls!(
f32: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
!Unaligned
);
assert_impls!(
f64: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
!Unaligned
);
assert_impls!(
bool: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
IntoBytes,
Unaligned,
!FromBytes
);
assert_impls!(
char: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
IntoBytes,
!FromBytes,
!Unaligned
);
assert_impls!(
str: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
IntoBytes,
Unaligned,
!FromBytes
);
assert_impls!(
NonZeroU8: KnownLayout,
Immutable,
TryFromBytes,
IntoBytes,
Unaligned,
!FromZeros,
!FromBytes
);
assert_impls!(
NonZeroI8: KnownLayout,
Immutable,
TryFromBytes,
IntoBytes,
Unaligned,
!FromZeros,
!FromBytes
);
assert_impls!(
NonZeroU16: KnownLayout,
Immutable,
TryFromBytes,
IntoBytes,
!FromBytes,
!Unaligned
);
assert_impls!(
NonZeroI16: KnownLayout,
Immutable,
TryFromBytes,
IntoBytes,
!FromBytes,
!Unaligned
);
assert_impls!(
NonZeroU32: KnownLayout,
Immutable,
TryFromBytes,
IntoBytes,
!FromBytes,
!Unaligned
);
assert_impls!(
NonZeroI32: KnownLayout,
Immutable,
TryFromBytes,
IntoBytes,
!FromBytes,
!Unaligned
);
assert_impls!(
NonZeroU64: KnownLayout,
Immutable,
TryFromBytes,
IntoBytes,
!FromBytes,
!Unaligned
);
assert_impls!(
NonZeroI64: KnownLayout,
Immutable,
TryFromBytes,
IntoBytes,
!FromBytes,
!Unaligned
);
assert_impls!(
NonZeroU128: KnownLayout,
Immutable,
TryFromBytes,
IntoBytes,
!FromBytes,
!Unaligned
);
assert_impls!(
NonZeroI128: KnownLayout,
Immutable,
TryFromBytes,
IntoBytes,
!FromBytes,
!Unaligned
);
assert_impls!(
NonZeroUsize: KnownLayout,
Immutable,
TryFromBytes,
IntoBytes,
!FromBytes,
!Unaligned
);
assert_impls!(
NonZeroIsize: KnownLayout,
Immutable,
TryFromBytes,
IntoBytes,
!FromBytes,
!Unaligned
);
assert_impls!(Option<NonZeroU8>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned);
assert_impls!(Option<NonZeroI8>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned);
assert_impls!(Option<NonZeroU16>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, !Unaligned);
assert_impls!(Option<NonZeroI16>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, !Unaligned);
assert_impls!(Option<NonZeroU32>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, !Unaligned);
assert_impls!(Option<NonZeroI32>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, !Unaligned);
assert_impls!(Option<NonZeroU64>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, !Unaligned);
assert_impls!(Option<NonZeroI64>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, !Unaligned);
assert_impls!(Option<NonZeroU128>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, !Unaligned);
assert_impls!(Option<NonZeroI128>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, !Unaligned);
assert_impls!(Option<NonZeroUsize>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, !Unaligned);
assert_impls!(Option<NonZeroIsize>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, !Unaligned);
// Implements none of the ZC traits.
struct NotZerocopy;
#[rustfmt::skip]
type FnManyArgs = fn(
NotZerocopy, u8, u8, u8, u8, u8, u8, u8, u8, u8, u8, u8,
) -> (NotZerocopy, NotZerocopy);
// Allowed, because we're not actually using this type for FFI.
#[allow(improper_ctypes_definitions)]
#[rustfmt::skip]
type ECFnManyArgs = extern "C" fn(
NotZerocopy, u8, u8, u8, u8, u8, u8, u8, u8, u8, u8, u8,
) -> (NotZerocopy, NotZerocopy);
#[cfg(feature = "alloc")]
assert_impls!(Option<Box<UnsafeCell<NotZerocopy>>>: KnownLayout, Immutable, TryFromBytes, FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(Option<Box<[UnsafeCell<NotZerocopy>]>>: KnownLayout, !Immutable, !TryFromBytes, !FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(Option<&'static UnsafeCell<NotZerocopy>>: KnownLayout, Immutable, TryFromBytes, FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(Option<&'static [UnsafeCell<NotZerocopy>]>: KnownLayout, Immutable, !TryFromBytes, !FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(Option<&'static mut UnsafeCell<NotZerocopy>>: KnownLayout, Immutable, TryFromBytes, FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(Option<&'static mut [UnsafeCell<NotZerocopy>]>: KnownLayout, Immutable, !TryFromBytes, !FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(Option<NonNull<UnsafeCell<NotZerocopy>>>: KnownLayout, TryFromBytes, FromZeros, Immutable, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(Option<NonNull<[UnsafeCell<NotZerocopy>]>>: KnownLayout, Immutable, !TryFromBytes, !FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(Option<fn()>: KnownLayout, Immutable, TryFromBytes, FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(Option<FnManyArgs>: KnownLayout, Immutable, TryFromBytes, FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(Option<extern "C" fn()>: KnownLayout, Immutable, TryFromBytes, FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(Option<ECFnManyArgs>: KnownLayout, Immutable, TryFromBytes, FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(PhantomData<NotZerocopy>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned);
assert_impls!(PhantomData<UnsafeCell<()>>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned);
assert_impls!(PhantomData<[u8]>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned);
assert_impls!(ManuallyDrop<u8>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned);
// This test is important because it allows us to test our hand-rolled
// implementation of `<ManuallyDrop<T> as TryFromBytes>::is_bit_valid`.
assert_impls!(ManuallyDrop<bool>: KnownLayout, Immutable, TryFromBytes, FromZeros, IntoBytes, Unaligned, !FromBytes);
assert_impls!(ManuallyDrop<[u8]>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned);
// This test is important because it allows us to test our hand-rolled
// implementation of `<ManuallyDrop<T> as TryFromBytes>::is_bit_valid`.
assert_impls!(ManuallyDrop<[bool]>: KnownLayout, Immutable, TryFromBytes, FromZeros, IntoBytes, Unaligned, !FromBytes);
assert_impls!(ManuallyDrop<NotZerocopy>: !Immutable, !TryFromBytes, !KnownLayout, !FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(ManuallyDrop<[NotZerocopy]>: KnownLayout, !Immutable, !TryFromBytes, !FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(ManuallyDrop<UnsafeCell<()>>: KnownLayout, TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned, !Immutable);
assert_impls!(ManuallyDrop<[UnsafeCell<u8>]>: KnownLayout, TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned, !Immutable);
assert_impls!(ManuallyDrop<[UnsafeCell<bool>]>: KnownLayout, TryFromBytes, FromZeros, IntoBytes, Unaligned, !Immutable, !FromBytes);
assert_impls!(MaybeUninit<u8>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, Unaligned, !IntoBytes);
assert_impls!(MaybeUninit<NotZerocopy>: KnownLayout, TryFromBytes, FromZeros, FromBytes, !Immutable, !IntoBytes, !Unaligned);
assert_impls!(MaybeUninit<UnsafeCell<()>>: KnownLayout, TryFromBytes, FromZeros, FromBytes, Unaligned, !Immutable, !IntoBytes);
assert_impls!(Wrapping<u8>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned);
// This test is important because it allows us to test our hand-rolled
// implementation of `<Wrapping<T> as TryFromBytes>::is_bit_valid`.
assert_impls!(Wrapping<bool>: KnownLayout, Immutable, TryFromBytes, FromZeros, IntoBytes, Unaligned, !FromBytes);
assert_impls!(Wrapping<NotZerocopy>: KnownLayout, !Immutable, !TryFromBytes, !FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(Wrapping<UnsafeCell<()>>: KnownLayout, TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned, !Immutable);
assert_impls!(Unalign<u8>: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, Unaligned);
// This test is important because it allows us to test our hand-rolled
// implementation of `<Unalign<T> as TryFromBytes>::is_bit_valid`.
assert_impls!(Unalign<bool>: KnownLayout, Immutable, TryFromBytes, FromZeros, IntoBytes, Unaligned, !FromBytes);
assert_impls!(Unalign<NotZerocopy>: KnownLayout, Unaligned, !Immutable, !TryFromBytes, !FromZeros, !FromBytes, !IntoBytes);
assert_impls!(
[u8]: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
Unaligned
);
assert_impls!(
[bool]: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
IntoBytes,
Unaligned,
!FromBytes
);
assert_impls!([NotZerocopy]: KnownLayout, !Immutable, !TryFromBytes, !FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(
[u8; 0]: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
Unaligned,
);
assert_impls!(
[NotZerocopy; 0]: KnownLayout,
!Immutable,
!TryFromBytes,
!FromZeros,
!FromBytes,
!IntoBytes,
!Unaligned
);
assert_impls!(
[u8; 1]: KnownLayout,
Immutable,
TryFromBytes,
FromZeros,
FromBytes,
IntoBytes,
Unaligned,
);
assert_impls!(
[NotZerocopy; 1]: KnownLayout,
!Immutable,
!TryFromBytes,
!FromZeros,
!FromBytes,
!IntoBytes,
!Unaligned
);
assert_impls!(*const NotZerocopy: KnownLayout, Immutable, TryFromBytes, FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(*mut NotZerocopy: KnownLayout, Immutable, TryFromBytes, FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(*const [NotZerocopy]: KnownLayout, Immutable, !TryFromBytes, !FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(*mut [NotZerocopy]: KnownLayout, Immutable, !TryFromBytes, !FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(*const dyn Debug: KnownLayout, Immutable, !TryFromBytes, !FromZeros, !FromBytes, !IntoBytes, !Unaligned);
assert_impls!(*mut dyn Debug: KnownLayout, Immutable, !TryFromBytes, !FromZeros, !FromBytes, !IntoBytes, !Unaligned);
#[cfg(feature = "simd")]
{
#[allow(unused_macros)]
macro_rules! test_simd_arch_mod {
($arch:ident, $($typ:ident),*) => {
{
use core::arch::$arch::{$($typ),*};
use crate::*;
$( assert_impls!($typ: KnownLayout, Immutable, TryFromBytes, FromZeros, FromBytes, IntoBytes, !Unaligned); )*
}
};
}
#[cfg(target_arch = "x86")]
test_simd_arch_mod!(x86, __m128, __m128d, __m128i, __m256, __m256d, __m256i);
#[cfg(all(feature = "simd-nightly", target_arch = "x86"))]
test_simd_arch_mod!(x86, __m512bh, __m512, __m512d, __m512i);
#[cfg(target_arch = "x86_64")]
test_simd_arch_mod!(x86_64, __m128, __m128d, __m128i, __m256, __m256d, __m256i);
#[cfg(all(feature = "simd-nightly", target_arch = "x86_64"))]
test_simd_arch_mod!(x86_64, __m512bh, __m512, __m512d, __m512i);
#[cfg(target_arch = "wasm32")]
test_simd_arch_mod!(wasm32, v128);
#[cfg(all(feature = "simd-nightly", target_arch = "powerpc"))]
test_simd_arch_mod!(
powerpc,
vector_bool_long,
vector_double,
vector_signed_long,
vector_unsigned_long
);
#[cfg(all(feature = "simd-nightly", target_arch = "powerpc64"))]
test_simd_arch_mod!(
powerpc64,
vector_bool_long,
vector_double,
vector_signed_long,
vector_unsigned_long
);
#[cfg(all(target_arch = "aarch64", zerocopy_aarch64_simd_1_59_0))]
#[rustfmt::skip]
test_simd_arch_mod!(
aarch64, float32x2_t, float32x4_t, float64x1_t, float64x2_t, int8x8_t, int8x8x2_t,
int8x8x3_t, int8x8x4_t, int8x16_t, int8x16x2_t, int8x16x3_t, int8x16x4_t, int16x4_t,
int16x8_t, int32x2_t, int32x4_t, int64x1_t, int64x2_t, poly8x8_t, poly8x8x2_t, poly8x8x3_t,
poly8x8x4_t, poly8x16_t, poly8x16x2_t, poly8x16x3_t, poly8x16x4_t, poly16x4_t, poly16x8_t,
poly64x1_t, poly64x2_t, uint8x8_t, uint8x8x2_t, uint8x8x3_t, uint8x8x4_t, uint8x16_t,
uint8x16x2_t, uint8x16x3_t, uint8x16x4_t, uint16x4_t, uint16x8_t, uint32x2_t, uint32x4_t,
uint64x1_t, uint64x2_t
);
#[cfg(all(feature = "simd-nightly", target_arch = "arm"))]
#[rustfmt::skip]
test_simd_arch_mod!(arm, int8x4_t, uint8x4_t);
}
}
}