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//! This module contains type aliases for C's fixed-width integer types .
//!
//! These aliases are deprecated: use the Rust types instead.
#[deprecated(since = "0.2.55", note = "Use i8 instead.")]
pub type int8_t = i8;
#[deprecated(since = "0.2.55", note = "Use i16 instead.")]
pub type int16_t = i16;
#[deprecated(since = "0.2.55", note = "Use i32 instead.")]
pub type int32_t = i32;
#[deprecated(since = "0.2.55", note = "Use i64 instead.")]
pub type int64_t = i64;
#[deprecated(since = "0.2.55", note = "Use u8 instead.")]
pub type uint8_t = u8;
#[deprecated(since = "0.2.55", note = "Use u16 instead.")]
pub type uint16_t = u16;
#[deprecated(since = "0.2.55", note = "Use u32 instead.")]
pub type uint32_t = u32;
#[deprecated(since = "0.2.55", note = "Use u64 instead.")]
pub type uint64_t = u64;
cfg_if! {
if #[cfg(all(libc_int128, target_arch = "aarch64", not(target_os = "windows")))] {
// This introduces partial support for FFI with __int128 and
// equivalent types on platforms where Rust's definition is validated
// to match the standard C ABI of that platform.
//
// Rust does not guarantee u128/i128 are sound for FFI, and its
// definitions are in fact known to be incompatible. [0]
//
// However these problems aren't fundamental, and are just platform
// inconsistencies. Specifically at the time of this writing:
//
// * For x64 SysV ABIs (everything but Windows), the types are underaligned.
// * For all Windows ABIs, Microsoft doesn't actually officially define __int128,
// and as a result different implementations don't actually agree on its ABI.
//
// But on the other major aarch64 platforms (android, linux, ios, macos) we have
// validated that rustc has the right ABI for these types. This is important because
// aarch64 uses these types in some fundamental OS types like user_fpsimd_struct,
// which represents saved simd registers.
//
// Any API which uses these types will need to `#[ignore(improper_ctypes)]`
// until the upstream rust issue is resolved, but this at least lets us make
// progress on platforms where this type is important.
//
// The list of supported architectures and OSes is intentionally very restricted,
// as careful work needs to be done to verify that a particular platform
// has a conformant ABI.
//
/// C `__int128` (a GCC extension that's part of many ABIs)
pub type __int128 = i128;
/// C `unsigned __int128` (a GCC extension that's part of many ABIs)
pub type __uint128 = u128;
/// C __int128_t (alternate name for [__int128][])
pub type __int128_t = i128;
/// C __uint128_t (alternate name for [__uint128][])
pub type __uint128_t = u128;
cfg_if! {
if #[cfg(libc_underscore_const_names)] {
macro_rules! static_assert_eq {
($a:expr, $b:expr) => {
const _: [(); $a] = [(); $b];
};
}
// NOTE: if you add more platforms to here, you may need to cfg
// these consts. They should always match the platform's values
// for `sizeof(__int128)` and `_Alignof(__int128)`.
const _SIZE_128: usize = 16;
const _ALIGN_128: usize = 16;
// Since Rust doesn't officially guarantee that these types
// have compatible ABIs, we const assert that these values have the
// known size/align of the target platform's libc. If rustc ever
// tries to regress things, it will cause a compilation error.
//
// This isn't a bullet-proof solution because e.g. it doesn't
// catch the fact that llvm and gcc disagree on how x64 __int128
// is actually *passed* on the stack (clang underaligns it for
// the same reason that rustc *never* properly aligns it).
static_assert_eq!(core::mem::size_of::<__int128>(), _SIZE_128);
static_assert_eq!(core::mem::align_of::<__int128>(), _ALIGN_128);
static_assert_eq!(core::mem::size_of::<__uint128>(), _SIZE_128);
static_assert_eq!(core::mem::align_of::<__uint128>(), _ALIGN_128);
static_assert_eq!(core::mem::size_of::<__int128_t>(), _SIZE_128);
static_assert_eq!(core::mem::align_of::<__int128_t>(), _ALIGN_128);
static_assert_eq!(core::mem::size_of::<__uint128_t>(), _SIZE_128);
static_assert_eq!(core::mem::align_of::<__uint128_t>(), _ALIGN_128);
}
}
}
}