bytemuck/contiguous.rs
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206
#![allow(clippy::legacy_numeric_constants)]
use super::*;
/// A trait indicating that:
///
/// 1. A type has an equivalent representation to some known integral type.
/// 2. All instances of this type fall in a fixed range of values.
/// 3. Within that range, there are no gaps.
///
/// This is generally useful for fieldless enums (aka "c-style" enums), however
/// it's important that it only be used for those with an explicit `#[repr]`, as
/// `#[repr(Rust)]` fieldess enums have an unspecified layout.
///
/// Additionally, you shouldn't assume that all implementations are enums. Any
/// type which meets the requirements above while following the rules under
/// "Safety" below is valid.
///
/// # Example
///
/// ```
/// # use bytemuck::Contiguous;
/// #[repr(u8)]
/// #[derive(Debug, Copy, Clone, PartialEq)]
/// enum Foo {
/// A = 0,
/// B = 1,
/// C = 2,
/// D = 3,
/// E = 4,
/// }
/// unsafe impl Contiguous for Foo {
/// type Int = u8;
/// const MIN_VALUE: u8 = Foo::A as u8;
/// const MAX_VALUE: u8 = Foo::E as u8;
/// }
/// assert_eq!(Foo::from_integer(3).unwrap(), Foo::D);
/// assert_eq!(Foo::from_integer(8), None);
/// assert_eq!(Foo::C.into_integer(), 2);
/// ```
/// # Safety
///
/// This is an unsafe trait, and incorrectly implementing it is undefined
/// behavior.
///
/// Informally, by implementing it, you're asserting that `C` is identical to
/// the integral type `C::Int`, and that every `C` falls between `C::MIN_VALUE`
/// and `C::MAX_VALUE` exactly once, without any gaps.
///
/// Precisely, the guarantees you must uphold when implementing `Contiguous` for
/// some type `C` are:
///
/// 1. The sizeĀ of `C` and `C::Int` must be the same, and neither may be a ZST.
/// (Note: alignment is explicitly allowed to differ)
///
/// 2. `C::Int` must be a primitive integer, and not a wrapper type. In the
/// future, this may be lifted to include cases where the behavior is
/// identical for a relevant set of traits (Ord, arithmetic, ...).
///
/// 3. All `C::Int`s which are in the *inclusive* range between `C::MIN_VALUE`
/// and `C::MAX_VALUE` are bitwise identical to unique valid instances of
/// `C`.
///
/// 4. There exist no instances of `C` such that their bitpatterns, when
/// interpreted as instances of `C::Int`, fall outside of the `MAX_VALUE` /
/// `MIN_VALUE` range -- It is legal for unsafe code to assume that if it
/// gets a `C` that implements `Contiguous`, it is in the appropriate range.
///
/// 5. Finally, you promise not to provide overridden implementations of
/// `Contiguous::from_integer` and `Contiguous::into_integer`.
///
/// For clarity, the following rules could be derived from the above, but are
/// listed explicitly:
///
/// - `C::MAX_VALUE` must be greater or equal to `C::MIN_VALUE` (therefore, `C`
/// must be an inhabited type).
///
/// - There exist no two values between `MIN_VALUE` and `MAX_VALUE` such that
/// when interpreted as a `C` they are considered identical (by, say, match).
pub unsafe trait Contiguous: Copy + 'static {
/// The primitive integer type with an identical representation to this
/// type.
///
/// Contiguous is broadly intended for use with fieldless enums, and for
/// these the correct integer type is easy: The enum should have a
/// `#[repr(Int)]` or `#[repr(C)]` attribute, (if it does not, it is
/// *unsound* to implement `Contiguous`!).
///
/// - For `#[repr(Int)]`, use the listed `Int`. e.g. `#[repr(u8)]` should use
/// `type Int = u8`.
///
/// - For `#[repr(C)]`, use whichever type the C compiler will use to
/// represent the given enum. This is usually `c_int` (from `std::os::raw`
/// or `libc`), but it's up to you to make the determination as the
/// implementer of the unsafe trait.
///
/// For precise rules, see the list under "Safety" above.
type Int: Copy + Ord;
/// The upper *inclusive* bound for valid instances of this type.
const MAX_VALUE: Self::Int;
/// The lower *inclusive* bound for valid instances of this type.
const MIN_VALUE: Self::Int;
/// If `value` is within the range for valid instances of this type,
/// returns `Some(converted_value)`, otherwise, returns `None`.
///
/// This is a trait method so that you can write `value.into_integer()` in
/// your code. It is a contract of this trait that if you implement
/// `Contiguous` on your type you **must not** override this method.
///
/// # Panics
///
/// We will not panic for any correct implementation of `Contiguous`, but
/// *may* panic if we detect an incorrect one.
///
/// This is undefined behavior regardless, so it could have been the nasal
/// demons at that point anyway ;).
#[inline]
#[cfg_attr(feature = "track_caller", track_caller)]
fn from_integer(value: Self::Int) -> Option<Self> {
// Guard against an illegal implementation of Contiguous. Annoyingly we
// can't rely on `transmute` to do this for us (see below), but
// whatever, this gets compiled into nothing in release.
assert!(size_of::<Self>() == size_of::<Self::Int>());
if Self::MIN_VALUE <= value && value <= Self::MAX_VALUE {
// SAFETY: We've checked their bounds (and their size, even though
// they've sworn under the Oath Of Unsafe Rust that that already
// matched) so this is allowed by `Contiguous`'s unsafe contract.
//
// So, the `transmute!`. ideally we'd use transmute here, which
// is more obviously safe. Sadly, we can't, as these types still
// have unspecified sizes.
Some(unsafe { transmute!(value) })
} else {
None
}
}
/// Perform the conversion from `C` into the underlying integral type. This
/// mostly exists otherwise generic code would need unsafe for the `value as
/// integer`
///
/// This is a trait method so that you can write `value.into_integer()` in
/// your code. It is a contract of this trait that if you implement
/// `Contiguous` on your type you **must not** override this method.
///
/// # Panics
///
/// We will not panic for any correct implementation of `Contiguous`, but
/// *may* panic if we detect an incorrect one.
///
/// This is undefined behavior regardless, so it could have been the nasal
/// demons at that point anyway ;).
#[inline]
#[cfg_attr(feature = "track_caller", track_caller)]
fn into_integer(self) -> Self::Int {
// Guard against an illegal implementation of Contiguous. Annoyingly we
// can't rely on `transmute` to do the size check for us (see
// `from_integer's comment`), but whatever, this gets compiled into
// nothing in release. Note that we don't check the result of cast
assert!(size_of::<Self>() == size_of::<Self::Int>());
// SAFETY: The unsafe contract requires that these have identical
// representations, and that the range be entirely valid. Using
// transmute! instead of transmute here is annoying, but is required
// as `Self` and `Self::Int` have unspecified sizes still.
unsafe { transmute!(self) }
}
}
macro_rules! impl_contiguous {
($($src:ty as $repr:ident in [$min:expr, $max:expr];)*) => {$(
unsafe impl Contiguous for $src {
type Int = $repr;
const MAX_VALUE: $repr = $max;
const MIN_VALUE: $repr = $min;
}
)*};
}
impl_contiguous! {
bool as u8 in [0, 1];
u8 as u8 in [0, u8::max_value()];
u16 as u16 in [0, u16::max_value()];
u32 as u32 in [0, u32::max_value()];
u64 as u64 in [0, u64::max_value()];
u128 as u128 in [0, u128::max_value()];
usize as usize in [0, usize::max_value()];
i8 as i8 in [i8::min_value(), i8::max_value()];
i16 as i16 in [i16::min_value(), i16::max_value()];
i32 as i32 in [i32::min_value(), i32::max_value()];
i64 as i64 in [i64::min_value(), i64::max_value()];
i128 as i128 in [i128::min_value(), i128::max_value()];
isize as isize in [isize::min_value(), isize::max_value()];
NonZeroU8 as u8 in [1, u8::max_value()];
NonZeroU16 as u16 in [1, u16::max_value()];
NonZeroU32 as u32 in [1, u32::max_value()];
NonZeroU64 as u64 in [1, u64::max_value()];
NonZeroU128 as u128 in [1, u128::max_value()];
NonZeroUsize as usize in [1, usize::max_value()];
}