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//! Compiler intrinsics.
//!
//! The corresponding definitions are in `compiler/rustc_codegen_llvm/src/intrinsic.rs`.
//! The corresponding const implementations are in `compiler/rustc_mir/src/interpret/intrinsics.rs`
//!
//! # Const intrinsics
//!
//! Note: any changes to the constness of intrinsics should be discussed with the language team.
//! This includes changes in the stability of the constness.
//!
//! In order to make an intrinsic usable at compile-time, one needs to copy the implementation
//! from <https://github.com/rust-lang/miri/blob/master/src/shims/intrinsics.rs> to
//! `compiler/rustc_mir/src/interpret/intrinsics.rs` and add a
//! `#[rustc_const_unstable(feature = "foo", issue = "01234")]` to the intrinsic.
//!
//! If an intrinsic is supposed to be used from a `const fn` with a `rustc_const_stable` attribute,
//! the intrinsic's attribute must be `rustc_const_stable`, too. Such a change should not be done
//! without T-lang consultation, because it bakes a feature into the language that cannot be
//! replicated in user code without compiler support.
//!
//! # Volatiles
//!
//! The volatile intrinsics provide operations intended to act on I/O
//! memory, which are guaranteed to not be reordered by the compiler
//! across other volatile intrinsics. See the LLVM documentation on
//! [[volatile]].
//!
//! [volatile]: https://llvm.org/docs/LangRef.html#volatile-memory-accesses
//!
//! # Atomics
//!
//! The atomic intrinsics provide common atomic operations on machine
//! words, with multiple possible memory orderings. They obey the same
//! semantics as C++11. See the LLVM documentation on [[atomics]].
//!
//! [atomics]: https://llvm.org/docs/Atomics.html
//!
//! A quick refresher on memory ordering:
//!
//! * Acquire - a barrier for acquiring a lock. Subsequent reads and writes
//! take place after the barrier.
//! * Release - a barrier for releasing a lock. Preceding reads and writes
//! take place before the barrier.
//! * Sequentially consistent - sequentially consistent operations are
//! guaranteed to happen in order. This is the standard mode for working
//! with atomic types and is equivalent to Java's `volatile`.
#![unstable(
feature = "core_intrinsics",
reason = "intrinsics are unlikely to ever be stabilized, instead \
they should be used through stabilized interfaces \
in the rest of the standard library",
issue = "none"
)]
#![allow(missing_docs)]
use crate::marker::DiscriminantKind;
use crate::mem;
// These imports are used for simplifying intra-doc links
#[allow(unused_imports)]
#[cfg(all(target_has_atomic = "8", target_has_atomic = "32", target_has_atomic = "ptr"))]
use crate::sync::atomic::{self, AtomicBool, AtomicI32, AtomicIsize, AtomicU32, Ordering};
#[stable(feature = "drop_in_place", since = "1.8.0")]
#[rustc_deprecated(
reason = "no longer an intrinsic - use `ptr::drop_in_place` directly",
since = "1.52.0"
)]
#[inline]
pub unsafe fn drop_in_place<T: ?Sized>(to_drop: *mut T) {
// SAFETY: see `ptr::drop_in_place`
unsafe { crate::ptr::drop_in_place(to_drop) }
}
extern "rust-intrinsic" {
// N.B., these intrinsics take raw pointers because they mutate aliased
// memory, which is not valid for either `&` or `&mut`.
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange` method by passing
/// [`Ordering::SeqCst`] as both the `success` and `failure` parameters.
/// For example, [`AtomicBool::compare_exchange`].
pub fn atomic_cxchg<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange` method by passing
/// [`Ordering::Acquire`] as both the `success` and `failure` parameters.
/// For example, [`AtomicBool::compare_exchange`].
pub fn atomic_cxchg_acq<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange` method by passing
/// [`Ordering::Release`] as the `success` and [`Ordering::Relaxed`] as the
/// `failure` parameters. For example, [`AtomicBool::compare_exchange`].
pub fn atomic_cxchg_rel<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange` method by passing
/// [`Ordering::AcqRel`] as the `success` and [`Ordering::Acquire`] as the
/// `failure` parameters. For example, [`AtomicBool::compare_exchange`].
pub fn atomic_cxchg_acqrel<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange` method by passing
/// [`Ordering::Relaxed`] as both the `success` and `failure` parameters.
/// For example, [`AtomicBool::compare_exchange`].
pub fn atomic_cxchg_relaxed<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange` method by passing
/// [`Ordering::SeqCst`] as the `success` and [`Ordering::Relaxed`] as the
/// `failure` parameters. For example, [`AtomicBool::compare_exchange`].
pub fn atomic_cxchg_failrelaxed<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange` method by passing
/// [`Ordering::SeqCst`] as the `success` and [`Ordering::Acquire`] as the
/// `failure` parameters. For example, [`AtomicBool::compare_exchange`].
pub fn atomic_cxchg_failacq<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange` method by passing
/// [`Ordering::Acquire`] as the `success` and [`Ordering::Relaxed`] as the
/// `failure` parameters. For example, [`AtomicBool::compare_exchange`].
pub fn atomic_cxchg_acq_failrelaxed<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange` method by passing
/// [`Ordering::AcqRel`] as the `success` and [`Ordering::Relaxed`] as the
/// `failure` parameters. For example, [`AtomicBool::compare_exchange`].
pub fn atomic_cxchg_acqrel_failrelaxed<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange_weak` method by passing
/// [`Ordering::SeqCst`] as both the `success` and `failure` parameters.
/// For example, [`AtomicBool::compare_exchange_weak`].
pub fn atomic_cxchgweak<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange_weak` method by passing
/// [`Ordering::Acquire`] as both the `success` and `failure` parameters.
/// For example, [`AtomicBool::compare_exchange_weak`].
pub fn atomic_cxchgweak_acq<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange_weak` method by passing
/// [`Ordering::Release`] as the `success` and [`Ordering::Relaxed`] as the
/// `failure` parameters. For example, [`AtomicBool::compare_exchange_weak`].
pub fn atomic_cxchgweak_rel<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange_weak` method by passing
/// [`Ordering::AcqRel`] as the `success` and [`Ordering::Acquire`] as the
/// `failure` parameters. For example, [`AtomicBool::compare_exchange_weak`].
pub fn atomic_cxchgweak_acqrel<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange_weak` method by passing
/// [`Ordering::Relaxed`] as both the `success` and `failure` parameters.
/// For example, [`AtomicBool::compare_exchange_weak`].
pub fn atomic_cxchgweak_relaxed<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange_weak` method by passing
/// [`Ordering::SeqCst`] as the `success` and [`Ordering::Relaxed`] as the
/// `failure` parameters. For example, [`AtomicBool::compare_exchange_weak`].
pub fn atomic_cxchgweak_failrelaxed<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange_weak` method by passing
/// [`Ordering::SeqCst`] as the `success` and [`Ordering::Acquire`] as the
/// `failure` parameters. For example, [`AtomicBool::compare_exchange_weak`].
pub fn atomic_cxchgweak_failacq<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange_weak` method by passing
/// [`Ordering::Acquire`] as the `success` and [`Ordering::Relaxed`] as the
/// `failure` parameters. For example, [`AtomicBool::compare_exchange_weak`].
pub fn atomic_cxchgweak_acq_failrelaxed<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Stores a value if the current value is the same as the `old` value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `compare_exchange_weak` method by passing
/// [`Ordering::AcqRel`] as the `success` and [`Ordering::Relaxed`] as the
/// `failure` parameters. For example, [`AtomicBool::compare_exchange_weak`].
pub fn atomic_cxchgweak_acqrel_failrelaxed<T: Copy>(dst: *mut T, old: T, src: T) -> (T, bool);
/// Loads the current value of the pointer.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `load` method by passing
/// [`Ordering::SeqCst`] as the `order`. For example, [`AtomicBool::load`].
pub fn atomic_load<T: Copy>(src: *const T) -> T;
/// Loads the current value of the pointer.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `load` method by passing
/// [`Ordering::Acquire`] as the `order`. For example, [`AtomicBool::load`].
pub fn atomic_load_acq<T: Copy>(src: *const T) -> T;
/// Loads the current value of the pointer.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `load` method by passing
/// [`Ordering::Relaxed`] as the `order`. For example, [`AtomicBool::load`].
pub fn atomic_load_relaxed<T: Copy>(src: *const T) -> T;
pub fn atomic_load_unordered<T: Copy>(src: *const T) -> T;
/// Stores the value at the specified memory location.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `store` method by passing
/// [`Ordering::SeqCst`] as the `order`. For example, [`AtomicBool::store`].
pub fn atomic_store<T: Copy>(dst: *mut T, val: T);
/// Stores the value at the specified memory location.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `store` method by passing
/// [`Ordering::Release`] as the `order`. For example, [`AtomicBool::store`].
pub fn atomic_store_rel<T: Copy>(dst: *mut T, val: T);
/// Stores the value at the specified memory location.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `store` method by passing
/// [`Ordering::Relaxed`] as the `order`. For example, [`AtomicBool::store`].
pub fn atomic_store_relaxed<T: Copy>(dst: *mut T, val: T);
pub fn atomic_store_unordered<T: Copy>(dst: *mut T, val: T);
/// Stores the value at the specified memory location, returning the old value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `swap` method by passing
/// [`Ordering::SeqCst`] as the `order`. For example, [`AtomicBool::swap`].
pub fn atomic_xchg<T: Copy>(dst: *mut T, src: T) -> T;
/// Stores the value at the specified memory location, returning the old value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `swap` method by passing
/// [`Ordering::Acquire`] as the `order`. For example, [`AtomicBool::swap`].
pub fn atomic_xchg_acq<T: Copy>(dst: *mut T, src: T) -> T;
/// Stores the value at the specified memory location, returning the old value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `swap` method by passing
/// [`Ordering::Release`] as the `order`. For example, [`AtomicBool::swap`].
pub fn atomic_xchg_rel<T: Copy>(dst: *mut T, src: T) -> T;
/// Stores the value at the specified memory location, returning the old value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `swap` method by passing
/// [`Ordering::AcqRel`] as the `order`. For example, [`AtomicBool::swap`].
pub fn atomic_xchg_acqrel<T: Copy>(dst: *mut T, src: T) -> T;
/// Stores the value at the specified memory location, returning the old value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `swap` method by passing
/// [`Ordering::Relaxed`] as the `order`. For example, [`AtomicBool::swap`].
pub fn atomic_xchg_relaxed<T: Copy>(dst: *mut T, src: T) -> T;
/// Adds to the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_add` method by passing
/// [`Ordering::SeqCst`] as the `order`. For example, [`AtomicIsize::fetch_add`].
pub fn atomic_xadd<T: Copy>(dst: *mut T, src: T) -> T;
/// Adds to the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_add` method by passing
/// [`Ordering::Acquire`] as the `order`. For example, [`AtomicIsize::fetch_add`].
pub fn atomic_xadd_acq<T: Copy>(dst: *mut T, src: T) -> T;
/// Adds to the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_add` method by passing
/// [`Ordering::Release`] as the `order`. For example, [`AtomicIsize::fetch_add`].
pub fn atomic_xadd_rel<T: Copy>(dst: *mut T, src: T) -> T;
/// Adds to the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_add` method by passing
/// [`Ordering::AcqRel`] as the `order`. For example, [`AtomicIsize::fetch_add`].
pub fn atomic_xadd_acqrel<T: Copy>(dst: *mut T, src: T) -> T;
/// Adds to the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_add` method by passing
/// [`Ordering::Relaxed`] as the `order`. For example, [`AtomicIsize::fetch_add`].
pub fn atomic_xadd_relaxed<T: Copy>(dst: *mut T, src: T) -> T;
/// Subtract from the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_sub` method by passing
/// [`Ordering::SeqCst`] as the `order`. For example, [`AtomicIsize::fetch_sub`].
pub fn atomic_xsub<T: Copy>(dst: *mut T, src: T) -> T;
/// Subtract from the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_sub` method by passing
/// [`Ordering::Acquire`] as the `order`. For example, [`AtomicIsize::fetch_sub`].
pub fn atomic_xsub_acq<T: Copy>(dst: *mut T, src: T) -> T;
/// Subtract from the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_sub` method by passing
/// [`Ordering::Release`] as the `order`. For example, [`AtomicIsize::fetch_sub`].
pub fn atomic_xsub_rel<T: Copy>(dst: *mut T, src: T) -> T;
/// Subtract from the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_sub` method by passing
/// [`Ordering::AcqRel`] as the `order`. For example, [`AtomicIsize::fetch_sub`].
pub fn atomic_xsub_acqrel<T: Copy>(dst: *mut T, src: T) -> T;
/// Subtract from the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_sub` method by passing
/// [`Ordering::Relaxed`] as the `order`. For example, [`AtomicIsize::fetch_sub`].
pub fn atomic_xsub_relaxed<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise and with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_and` method by passing
/// [`Ordering::SeqCst`] as the `order`. For example, [`AtomicBool::fetch_and`].
pub fn atomic_and<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise and with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_and` method by passing
/// [`Ordering::Acquire`] as the `order`. For example, [`AtomicBool::fetch_and`].
pub fn atomic_and_acq<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise and with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_and` method by passing
/// [`Ordering::Release`] as the `order`. For example, [`AtomicBool::fetch_and`].
pub fn atomic_and_rel<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise and with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_and` method by passing
/// [`Ordering::AcqRel`] as the `order`. For example, [`AtomicBool::fetch_and`].
pub fn atomic_and_acqrel<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise and with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_and` method by passing
/// [`Ordering::Relaxed`] as the `order`. For example, [`AtomicBool::fetch_and`].
pub fn atomic_and_relaxed<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise nand with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`AtomicBool`] type via the `fetch_nand` method by passing
/// [`Ordering::SeqCst`] as the `order`. For example, [`AtomicBool::fetch_nand`].
pub fn atomic_nand<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise nand with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`AtomicBool`] type via the `fetch_nand` method by passing
/// [`Ordering::Acquire`] as the `order`. For example, [`AtomicBool::fetch_nand`].
pub fn atomic_nand_acq<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise nand with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`AtomicBool`] type via the `fetch_nand` method by passing
/// [`Ordering::Release`] as the `order`. For example, [`AtomicBool::fetch_nand`].
pub fn atomic_nand_rel<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise nand with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`AtomicBool`] type via the `fetch_nand` method by passing
/// [`Ordering::AcqRel`] as the `order`. For example, [`AtomicBool::fetch_nand`].
pub fn atomic_nand_acqrel<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise nand with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`AtomicBool`] type via the `fetch_nand` method by passing
/// [`Ordering::Relaxed`] as the `order`. For example, [`AtomicBool::fetch_nand`].
pub fn atomic_nand_relaxed<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise or with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_or` method by passing
/// [`Ordering::SeqCst`] as the `order`. For example, [`AtomicBool::fetch_or`].
pub fn atomic_or<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise or with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_or` method by passing
/// [`Ordering::Acquire`] as the `order`. For example, [`AtomicBool::fetch_or`].
pub fn atomic_or_acq<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise or with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_or` method by passing
/// [`Ordering::Release`] as the `order`. For example, [`AtomicBool::fetch_or`].
pub fn atomic_or_rel<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise or with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_or` method by passing
/// [`Ordering::AcqRel`] as the `order`. For example, [`AtomicBool::fetch_or`].
pub fn atomic_or_acqrel<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise or with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_or` method by passing
/// [`Ordering::Relaxed`] as the `order`. For example, [`AtomicBool::fetch_or`].
pub fn atomic_or_relaxed<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise xor with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_xor` method by passing
/// [`Ordering::SeqCst`] as the `order`. For example, [`AtomicBool::fetch_xor`].
pub fn atomic_xor<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise xor with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_xor` method by passing
/// [`Ordering::Acquire`] as the `order`. For example, [`AtomicBool::fetch_xor`].
pub fn atomic_xor_acq<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise xor with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_xor` method by passing
/// [`Ordering::Release`] as the `order`. For example, [`AtomicBool::fetch_xor`].
pub fn atomic_xor_rel<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise xor with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_xor` method by passing
/// [`Ordering::AcqRel`] as the `order`. For example, [`AtomicBool::fetch_xor`].
pub fn atomic_xor_acqrel<T: Copy>(dst: *mut T, src: T) -> T;
/// Bitwise xor with the current value, returning the previous value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] types via the `fetch_xor` method by passing
/// [`Ordering::Relaxed`] as the `order`. For example, [`AtomicBool::fetch_xor`].
pub fn atomic_xor_relaxed<T: Copy>(dst: *mut T, src: T) -> T;
/// Maximum with the current value using a signed comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] signed integer types via the `fetch_max` method by passing
/// [`Ordering::SeqCst`] as the `order`. For example, [`AtomicI32::fetch_max`].
pub fn atomic_max<T: Copy>(dst: *mut T, src: T) -> T;
/// Maximum with the current value using a signed comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] signed integer types via the `fetch_max` method by passing
/// [`Ordering::Acquire`] as the `order`. For example, [`AtomicI32::fetch_max`].
pub fn atomic_max_acq<T: Copy>(dst: *mut T, src: T) -> T;
/// Maximum with the current value using a signed comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] signed integer types via the `fetch_max` method by passing
/// [`Ordering::Release`] as the `order`. For example, [`AtomicI32::fetch_max`].
pub fn atomic_max_rel<T: Copy>(dst: *mut T, src: T) -> T;
/// Maximum with the current value using a signed comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] signed integer types via the `fetch_max` method by passing
/// [`Ordering::AcqRel`] as the `order`. For example, [`AtomicI32::fetch_max`].
pub fn atomic_max_acqrel<T: Copy>(dst: *mut T, src: T) -> T;
/// Maximum with the current value.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] signed integer types via the `fetch_max` method by passing
/// [`Ordering::Relaxed`] as the `order`. For example, [`AtomicI32::fetch_max`].
pub fn atomic_max_relaxed<T: Copy>(dst: *mut T, src: T) -> T;
/// Minimum with the current value using a signed comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] signed integer types via the `fetch_min` method by passing
/// [`Ordering::SeqCst`] as the `order`. For example, [`AtomicI32::fetch_min`].
pub fn atomic_min<T: Copy>(dst: *mut T, src: T) -> T;
/// Minimum with the current value using a signed comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] signed integer types via the `fetch_min` method by passing
/// [`Ordering::Acquire`] as the `order`. For example, [`AtomicI32::fetch_min`].
pub fn atomic_min_acq<T: Copy>(dst: *mut T, src: T) -> T;
/// Minimum with the current value using a signed comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] signed integer types via the `fetch_min` method by passing
/// [`Ordering::Release`] as the `order`. For example, [`AtomicI32::fetch_min`].
pub fn atomic_min_rel<T: Copy>(dst: *mut T, src: T) -> T;
/// Minimum with the current value using a signed comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] signed integer types via the `fetch_min` method by passing
/// [`Ordering::AcqRel`] as the `order`. For example, [`AtomicI32::fetch_min`].
pub fn atomic_min_acqrel<T: Copy>(dst: *mut T, src: T) -> T;
/// Minimum with the current value using a signed comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] signed integer types via the `fetch_min` method by passing
/// [`Ordering::Relaxed`] as the `order`. For example, [`AtomicI32::fetch_min`].
pub fn atomic_min_relaxed<T: Copy>(dst: *mut T, src: T) -> T;
/// Minimum with the current value using an unsigned comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] unsigned integer types via the `fetch_min` method by passing
/// [`Ordering::SeqCst`] as the `order`. For example, [`AtomicU32::fetch_min`].
pub fn atomic_umin<T: Copy>(dst: *mut T, src: T) -> T;
/// Minimum with the current value using an unsigned comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] unsigned integer types via the `fetch_min` method by passing
/// [`Ordering::Acquire`] as the `order`. For example, [`AtomicU32::fetch_min`].
pub fn atomic_umin_acq<T: Copy>(dst: *mut T, src: T) -> T;
/// Minimum with the current value using an unsigned comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] unsigned integer types via the `fetch_min` method by passing
/// [`Ordering::Release`] as the `order`. For example, [`AtomicU32::fetch_min`].
pub fn atomic_umin_rel<T: Copy>(dst: *mut T, src: T) -> T;
/// Minimum with the current value using an unsigned comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] unsigned integer types via the `fetch_min` method by passing
/// [`Ordering::AcqRel`] as the `order`. For example, [`AtomicU32::fetch_min`].
pub fn atomic_umin_acqrel<T: Copy>(dst: *mut T, src: T) -> T;
/// Minimum with the current value using an unsigned comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] unsigned integer types via the `fetch_min` method by passing
/// [`Ordering::Relaxed`] as the `order`. For example, [`AtomicU32::fetch_min`].
pub fn atomic_umin_relaxed<T: Copy>(dst: *mut T, src: T) -> T;
/// Maximum with the current value using an unsigned comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] unsigned integer types via the `fetch_max` method by passing
/// [`Ordering::SeqCst`] as the `order`. For example, [`AtomicU32::fetch_max`].
pub fn atomic_umax<T: Copy>(dst: *mut T, src: T) -> T;
/// Maximum with the current value using an unsigned comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] unsigned integer types via the `fetch_max` method by passing
/// [`Ordering::Acquire`] as the `order`. For example, [`AtomicU32::fetch_max`].
pub fn atomic_umax_acq<T: Copy>(dst: *mut T, src: T) -> T;
/// Maximum with the current value using an unsigned comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] unsigned integer types via the `fetch_max` method by passing
/// [`Ordering::Release`] as the `order`. For example, [`AtomicU32::fetch_max`].
pub fn atomic_umax_rel<T: Copy>(dst: *mut T, src: T) -> T;
/// Maximum with the current value using an unsigned comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] unsigned integer types via the `fetch_max` method by passing
/// [`Ordering::AcqRel`] as the `order`. For example, [`AtomicU32::fetch_max`].
pub fn atomic_umax_acqrel<T: Copy>(dst: *mut T, src: T) -> T;
/// Maximum with the current value using an unsigned comparison.
///
/// The stabilized version of this intrinsic is available on the
/// [`atomic`] unsigned integer types via the `fetch_max` method by passing
/// [`Ordering::Relaxed`] as the `order`. For example, [`AtomicU32::fetch_max`].
pub fn atomic_umax_relaxed<T: Copy>(dst: *mut T, src: T) -> T;
/// The `prefetch` intrinsic is a hint to the code generator to insert a prefetch instruction
/// if supported; otherwise, it is a no-op.
/// Prefetches have no effect on the behavior of the program but can change its performance
/// characteristics.
///
/// The `locality` argument must be a constant integer and is a temporal locality specifier
/// ranging from (0) - no locality, to (3) - extremely local keep in cache.
///
/// This intrinsic does not have a stable counterpart.
pub fn prefetch_read_data<T>(data: *const T, locality: i32);
/// The `prefetch` intrinsic is a hint to the code generator to insert a prefetch instruction
/// if supported; otherwise, it is a no-op.
/// Prefetches have no effect on the behavior of the program but can change its performance
/// characteristics.
///
/// The `locality` argument must be a constant integer and is a temporal locality specifier
/// ranging from (0) - no locality, to (3) - extremely local keep in cache.
///
/// This intrinsic does not have a stable counterpart.
pub fn prefetch_write_data<T>(data: *const T, locality: i32);
/// The `prefetch` intrinsic is a hint to the code generator to insert a prefetch instruction
/// if supported; otherwise, it is a no-op.
/// Prefetches have no effect on the behavior of the program but can change its performance
/// characteristics.
///
/// The `locality` argument must be a constant integer and is a temporal locality specifier
/// ranging from (0) - no locality, to (3) - extremely local keep in cache.
///
/// This intrinsic does not have a stable counterpart.
pub fn prefetch_read_instruction<T>(data: *const T, locality: i32);
/// The `prefetch` intrinsic is a hint to the code generator to insert a prefetch instruction
/// if supported; otherwise, it is a no-op.
/// Prefetches have no effect on the behavior of the program but can change its performance
/// characteristics.
///
/// The `locality` argument must be a constant integer and is a temporal locality specifier
/// ranging from (0) - no locality, to (3) - extremely local keep in cache.
///
/// This intrinsic does not have a stable counterpart.
pub fn prefetch_write_instruction<T>(data: *const T, locality: i32);
}
extern "rust-intrinsic" {
/// An atomic fence.
///
/// The stabilized version of this intrinsic is available in
/// [`atomic::fence`] by passing [`Ordering::SeqCst`]
/// as the `order`.
pub fn atomic_fence();
/// An atomic fence.
///
/// The stabilized version of this intrinsic is available in
/// [`atomic::fence`] by passing [`Ordering::Acquire`]
/// as the `order`.
pub fn atomic_fence_acq();
/// An atomic fence.
///
/// The stabilized version of this intrinsic is available in
/// [`atomic::fence`] by passing [`Ordering::Release`]
/// as the `order`.
pub fn atomic_fence_rel();
/// An atomic fence.
///
/// The stabilized version of this intrinsic is available in
/// [`atomic::fence`] by passing [`Ordering::AcqRel`]
/// as the `order`.
pub fn atomic_fence_acqrel();
/// A compiler-only memory barrier.
///
/// Memory accesses will never be reordered across this barrier by the
/// compiler, but no instructions will be emitted for it. This is
/// appropriate for operations on the same thread that may be preempted,
/// such as when interacting with signal handlers.
///
/// The stabilized version of this intrinsic is available in
/// [`atomic::compiler_fence`] by passing [`Ordering::SeqCst`]
/// as the `order`.
pub fn atomic_singlethreadfence();
/// A compiler-only memory barrier.
///
/// Memory accesses will never be reordered across this barrier by the
/// compiler, but no instructions will be emitted for it. This is
/// appropriate for operations on the same thread that may be preempted,
/// such as when interacting with signal handlers.
///
/// The stabilized version of this intrinsic is available in
/// [`atomic::compiler_fence`] by passing [`Ordering::Acquire`]
/// as the `order`.
pub fn atomic_singlethreadfence_acq();
/// A compiler-only memory barrier.
///
/// Memory accesses will never be reordered across this barrier by the
/// compiler, but no instructions will be emitted for it. This is
/// appropriate for operations on the same thread that may be preempted,
/// such as when interacting with signal handlers.
///
/// The stabilized version of this intrinsic is available in
/// [`atomic::compiler_fence`] by passing [`Ordering::Release`]
/// as the `order`.
pub fn atomic_singlethreadfence_rel();
/// A compiler-only memory barrier.
///
/// Memory accesses will never be reordered across this barrier by the
/// compiler, but no instructions will be emitted for it. This is
/// appropriate for operations on the same thread that may be preempted,
/// such as when interacting with signal handlers.
///
/// The stabilized version of this intrinsic is available in
/// [`atomic::compiler_fence`] by passing [`Ordering::AcqRel`]
/// as the `order`.
pub fn atomic_singlethreadfence_acqrel();
/// Magic intrinsic that derives its meaning from attributes
/// attached to the function.
///
/// For example, dataflow uses this to inject static assertions so
/// that `rustc_peek(potentially_uninitialized)` would actually
/// double-check that dataflow did indeed compute that it is
/// uninitialized at that point in the control flow.
///
/// This intrinsic should not be used outside of the compiler.
pub fn rustc_peek<T>(_: T) -> T;
/// Aborts the execution of the process.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// [`std::process::abort`](../../std/process/fn.abort.html) is to be preferred if possible,
/// as its behavior is more user-friendly and more stable.
///
/// The current implementation of `intrinsics::abort` is to invoke an invalid instruction,
/// on most platforms.
/// On Unix, the
/// process will probably terminate with a signal like `SIGABRT`, `SIGILL`, `SIGTRAP`, `SIGSEGV` or
/// `SIGBUS`. The precise behaviour is not guaranteed and not stable.
pub fn abort() -> !;
/// Informs the optimizer that this point in the code is not reachable,
/// enabling further optimizations.
///
/// N.B., this is very different from the `unreachable!()` macro: Unlike the
/// macro, which panics when it is executed, it is *undefined behavior* to
/// reach code marked with this function.
///
/// The stabilized version of this intrinsic is [`core::hint::unreachable_unchecked`].
#[rustc_const_stable(feature = "const_unreachable_unchecked", since = "1.57.0")]
pub fn unreachable() -> !;
/// Informs the optimizer that a condition is always true.
/// If the condition is false, the behavior is undefined.
///
/// No code is generated for this intrinsic, but the optimizer will try
/// to preserve it (and its condition) between passes, which may interfere
/// with optimization of surrounding code and reduce performance. It should
/// not be used if the invariant can be discovered by the optimizer on its
/// own, or if it does not enable any significant optimizations.
///
/// This intrinsic does not have a stable counterpart.
#[rustc_const_unstable(feature = "const_assume", issue = "76972")]
pub fn assume(b: bool);
/// Hints to the compiler that branch condition is likely to be true.
/// Returns the value passed to it.
///
/// Any use other than with `if` statements will probably not have an effect.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// This intrinsic does not have a stable counterpart.
#[rustc_const_unstable(feature = "const_likely", issue = "none")]
pub fn likely(b: bool) -> bool;
/// Hints to the compiler that branch condition is likely to be false.
/// Returns the value passed to it.
///
/// Any use other than with `if` statements will probably not have an effect.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// This intrinsic does not have a stable counterpart.
#[rustc_const_unstable(feature = "const_likely", issue = "none")]
pub fn unlikely(b: bool) -> bool;
/// Executes a breakpoint trap, for inspection by a debugger.
///
/// This intrinsic does not have a stable counterpart.
pub fn breakpoint();
/// The size of a type in bytes.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// More specifically, this is the offset in bytes between successive
/// items of the same type, including alignment padding.
///
/// The stabilized version of this intrinsic is [`core::mem::size_of`].
#[rustc_const_stable(feature = "const_size_of", since = "1.40.0")]
pub fn size_of<T>() -> usize;
/// The minimum alignment of a type.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized version of this intrinsic is [`core::mem::align_of`].
#[rustc_const_stable(feature = "const_min_align_of", since = "1.40.0")]
pub fn min_align_of<T>() -> usize;
/// The preferred alignment of a type.
///
/// This intrinsic does not have a stable counterpart.
/// It's "tracking issue" is [#91971](https://github.com/rust-lang/rust/issues/91971).
#[rustc_const_unstable(feature = "const_pref_align_of", issue = "91971")]
pub fn pref_align_of<T>() -> usize;
/// The size of the referenced value in bytes.
///
/// The stabilized version of this intrinsic is [`mem::size_of_val`].
#[rustc_const_unstable(feature = "const_size_of_val", issue = "46571")]
pub fn size_of_val<T: ?Sized>(_: *const T) -> usize;
/// The required alignment of the referenced value.
///
/// The stabilized version of this intrinsic is [`core::mem::align_of_val`].
#[rustc_const_unstable(feature = "const_align_of_val", issue = "46571")]
pub fn min_align_of_val<T: ?Sized>(_: *const T) -> usize;
/// Gets a static string slice containing the name of a type.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized version of this intrinsic is [`core::any::type_name`].
#[rustc_const_unstable(feature = "const_type_name", issue = "63084")]
pub fn type_name<T: ?Sized>() -> &'static str;
/// Gets an identifier which is globally unique to the specified type. This
/// function will return the same value for a type regardless of whichever
/// crate it is invoked in.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized version of this intrinsic is [`core::any::TypeId::of`].
#[rustc_const_unstable(feature = "const_type_id", issue = "77125")]
pub fn type_id<T: ?Sized + 'static>() -> u64;
/// A guard for unsafe functions that cannot ever be executed if `T` is uninhabited:
/// This will statically either panic, or do nothing.
///
/// This intrinsic does not have a stable counterpart.
#[rustc_const_stable(feature = "const_assert_type", since = "1.59.0")]
pub fn assert_inhabited<T>();
/// A guard for unsafe functions that cannot ever be executed if `T` does not permit
/// zero-initialization: This will statically either panic, or do nothing.
///
/// This intrinsic does not have a stable counterpart.
#[rustc_const_unstable(feature = "const_assert_type2", issue = "none")]
pub fn assert_zero_valid<T>();
/// A guard for unsafe functions that cannot ever be executed if `T` has invalid
/// bit patterns: This will statically either panic, or do nothing.
///
/// This intrinsic does not have a stable counterpart.
#[rustc_const_unstable(feature = "const_assert_type2", issue = "none")]
pub fn assert_uninit_valid<T>();
/// Gets a reference to a static `Location` indicating where it was called.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// Consider using [`core::panic::Location::caller`] instead.
#[rustc_const_unstable(feature = "const_caller_location", issue = "76156")]
pub fn caller_location() -> &'static crate::panic::Location<'static>;
/// Moves a value out of scope without running drop glue.
///
/// This exists solely for [`mem::forget_unsized`]; normal `forget` uses
/// `ManuallyDrop` instead.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
#[rustc_const_unstable(feature = "const_intrinsic_forget", issue = "none")]
pub fn forget<T: ?Sized>(_: T);
/// Reinterprets the bits of a value of one type as another type.
///
/// Both types must have the same size. Neither the original, nor the result,
/// may be an [invalid value](../../nomicon/what-unsafe-does.html).
///
/// `transmute` is semantically equivalent to a bitwise move of one type
/// into another. It copies the bits from the source value into the
/// destination value, then forgets the original. It's equivalent to C's
/// `memcpy` under the hood, just like `transmute_copy`.
///
/// Because `transmute` is a by-value operation, alignment of the *transmuted values
/// themselves* is not a concern. As with any other function, the compiler already ensures
/// both `T` and `U` are properly aligned. However, when transmuting values that *point
/// elsewhere* (such as pointers, references, boxes…), the caller has to ensure proper
/// alignment of the pointed-to values.
///
/// `transmute` is **incredibly** unsafe. There are a vast number of ways to
/// cause [undefined behavior][ub] with this function. `transmute` should be
/// the absolute last resort.
///
/// Transmuting pointers to integers in a `const` context is [undefined behavior][ub].
/// Any attempt to use the resulting value for integer operations will abort const-evaluation.
///
/// The [nomicon](../../nomicon/transmutes.html) has additional
/// documentation.
///
/// [ub]: ../../reference/behavior-considered-undefined.html
///
/// # Examples
///
/// There are a few things that `transmute` is really useful for.
///
/// Turning a pointer into a function pointer. This is *not* portable to
/// machines where function pointers and data pointers have different sizes.
///
/// ```
/// fn foo() -> i32 {
/// 0
/// }
/// let pointer = foo as *const ();
/// let function = unsafe {
/// std::mem::transmute::<*const (), fn() -> i32>(pointer)
/// };
/// assert_eq!(function(), 0);
/// ```
///
/// Extending a lifetime, or shortening an invariant lifetime. This is
/// advanced, very unsafe Rust!
///
/// ```
/// struct R<'a>(&'a i32);
/// unsafe fn extend_lifetime<'b>(r: R<'b>) -> R<'static> {
/// std::mem::transmute::<R<'b>, R<'static>>(r)
/// }
///
/// unsafe fn shorten_invariant_lifetime<'b, 'c>(r: &'b mut R<'static>)
/// -> &'b mut R<'c> {
/// std::mem::transmute::<&'b mut R<'static>, &'b mut R<'c>>(r)
/// }
/// ```
///
/// # Alternatives
///
/// Don't despair: many uses of `transmute` can be achieved through other means.
/// Below are common applications of `transmute` which can be replaced with safer
/// constructs.
///
/// Turning raw bytes(`&[u8]`) to `u32`, `f64`, etc.:
///
/// ```
/// let raw_bytes = [0x78, 0x56, 0x34, 0x12];
///
/// let num = unsafe {
/// std::mem::transmute::<[u8; 4], u32>(raw_bytes)
/// };
///
/// // use `u32::from_ne_bytes` instead
/// let num = u32::from_ne_bytes(raw_bytes);
/// // or use `u32::from_le_bytes` or `u32::from_be_bytes` to specify the endianness
/// let num = u32::from_le_bytes(raw_bytes);
/// assert_eq!(num, 0x12345678);
/// let num = u32::from_be_bytes(raw_bytes);
/// assert_eq!(num, 0x78563412);
/// ```
///
/// Turning a pointer into a `usize`:
///
/// ```
/// let ptr = &0;
/// let ptr_num_transmute = unsafe {
/// std::mem::transmute::<&i32, usize>(ptr)
/// };
///
/// // Use an `as` cast instead
/// let ptr_num_cast = ptr as *const i32 as usize;
/// ```
///
/// Turning a `*mut T` into an `&mut T`:
///
/// ```
/// let ptr: *mut i32 = &mut 0;
/// let ref_transmuted = unsafe {
/// std::mem::transmute::<*mut i32, &mut i32>(ptr)
/// };
///
/// // Use a reborrow instead
/// let ref_casted = unsafe { &mut *ptr };
/// ```
///
/// Turning an `&mut T` into an `&mut U`:
///
/// ```
/// let ptr = &mut 0;
/// let val_transmuted = unsafe {
/// std::mem::transmute::<&mut i32, &mut u32>(ptr)
/// };
///
/// // Now, put together `as` and reborrowing - note the chaining of `as`
/// // `as` is not transitive
/// let val_casts = unsafe { &mut *(ptr as *mut i32 as *mut u32) };
/// ```
///
/// Turning an `&str` into a `&[u8]`:
///
/// ```
/// // this is not a good way to do this.
/// let slice = unsafe { std::mem::transmute::<&str, &[u8]>("Rust") };
/// assert_eq!(slice, &[82, 117, 115, 116]);
///
/// // You could use `str::as_bytes`
/// let slice = "Rust".as_bytes();
/// assert_eq!(slice, &[82, 117, 115, 116]);
///
/// // Or, just use a byte string, if you have control over the string
/// // literal
/// assert_eq!(b"Rust", &[82, 117, 115, 116]);
/// ```
///
/// Turning a `Vec<&T>` into a `Vec<Option<&T>>`.
///
/// To transmute the inner type of the contents of a container, you must make sure to not
/// violate any of the container's invariants. For `Vec`, this means that both the size
/// *and alignment* of the inner types have to match. Other containers might rely on the
/// size of the type, alignment, or even the `TypeId`, in which case transmuting wouldn't
/// be possible at all without violating the container invariants.
///
/// ```
/// let store = [0, 1, 2, 3];
/// let v_orig = store.iter().collect::<Vec<&i32>>();
///
/// // clone the vector as we will reuse them later
/// let v_clone = v_orig.clone();
///
/// // Using transmute: this relies on the unspecified data layout of `Vec`, which is a
/// // bad idea and could cause Undefined Behavior.
/// // However, it is no-copy.
/// let v_transmuted = unsafe {
/// std::mem::transmute::<Vec<&i32>, Vec<Option<&i32>>>(v_clone)
/// };
///
/// let v_clone = v_orig.clone();
///
/// // This is the suggested, safe way.
/// // It does copy the entire vector, though, into a new array.
/// let v_collected = v_clone.into_iter()
/// .map(Some)
/// .collect::<Vec<Option<&i32>>>();
///
/// let v_clone = v_orig.clone();
///
/// // This is the proper no-copy, unsafe way of "transmuting" a `Vec`, without relying on the
/// // data layout. Instead of literally calling `transmute`, we perform a pointer cast, but
/// // in terms of converting the original inner type (`&i32`) to the new one (`Option<&i32>`),
/// // this has all the same caveats. Besides the information provided above, also consult the
/// // [`from_raw_parts`] documentation.
/// let v_from_raw = unsafe {
// FIXME Update this when vec_into_raw_parts is stabilized
/// // Ensure the original vector is not dropped.
/// let mut v_clone = std::mem::ManuallyDrop::new(v_clone);
/// Vec::from_raw_parts(v_clone.as_mut_ptr() as *mut Option<&i32>,
/// v_clone.len(),
/// v_clone.capacity())
/// };
/// ```
///
/// [`from_raw_parts`]: ../../std/vec/struct.Vec.html#method.from_raw_parts
///
/// Implementing `split_at_mut`:
///
/// ```
/// use std::{slice, mem};
///
/// // There are multiple ways to do this, and there are multiple problems
/// // with the following (transmute) way.
/// fn split_at_mut_transmute<T>(slice: &mut [T], mid: usize)
/// -> (&mut [T], &mut [T]) {
/// let len = slice.len();
/// assert!(mid <= len);
/// unsafe {
/// let slice2 = mem::transmute::<&mut [T], &mut [T]>(slice);
/// // first: transmute is not type safe; all it checks is that T and
/// // U are of the same size. Second, right here, you have two
/// // mutable references pointing to the same memory.
/// (&mut slice[0..mid], &mut slice2[mid..len])
/// }
/// }
///
/// // This gets rid of the type safety problems; `&mut *` will *only* give
/// // you an `&mut T` from an `&mut T` or `*mut T`.
/// fn split_at_mut_casts<T>(slice: &mut [T], mid: usize)
/// -> (&mut [T], &mut [T]) {
/// let len = slice.len();
/// assert!(mid <= len);
/// unsafe {
/// let slice2 = &mut *(slice as *mut [T]);
/// // however, you still have two mutable references pointing to
/// // the same memory.
/// (&mut slice[0..mid], &mut slice2[mid..len])
/// }
/// }
///
/// // This is how the standard library does it. This is the best method, if
/// // you need to do something like this
/// fn split_at_stdlib<T>(slice: &mut [T], mid: usize)
/// -> (&mut [T], &mut [T]) {
/// let len = slice.len();
/// assert!(mid <= len);
/// unsafe {
/// let ptr = slice.as_mut_ptr();
/// // This now has three mutable references pointing at the same
/// // memory. `slice`, the rvalue ret.0, and the rvalue ret.1.
/// // `slice` is never used after `let ptr = ...`, and so one can
/// // treat it as "dead", and therefore, you only have two real
/// // mutable slices.
/// (slice::from_raw_parts_mut(ptr, mid),
/// slice::from_raw_parts_mut(ptr.add(mid), len - mid))
/// }
/// }
/// ```
#[stable(feature = "rust1", since = "1.0.0")]
#[rustc_const_stable(feature = "const_transmute", since = "1.46.0")]
#[rustc_diagnostic_item = "transmute"]
pub fn transmute<T, U>(e: T) -> U;
/// Returns `true` if the actual type given as `T` requires drop
/// glue; returns `false` if the actual type provided for `T`
/// implements `Copy`.
///
/// If the actual type neither requires drop glue nor implements
/// `Copy`, then the return value of this function is unspecified.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized version of this intrinsic is [`mem::needs_drop`](crate::mem::needs_drop).
#[rustc_const_stable(feature = "const_needs_drop", since = "1.40.0")]
pub fn needs_drop<T>() -> bool;
/// Calculates the offset from a pointer.
///
/// This is implemented as an intrinsic to avoid converting to and from an
/// integer, since the conversion would throw away aliasing information.
///
/// # Safety
///
/// Both the starting and resulting pointer must be either in bounds or one
/// byte past the end of an allocated object. If either pointer is out of
/// bounds or arithmetic overflow occurs then any further use of the
/// returned value will result in undefined behavior.
///
/// The stabilized version of this intrinsic is [`pointer::offset`].
#[must_use = "returns a new pointer rather than modifying its argument"]
#[rustc_const_unstable(feature = "const_ptr_offset", issue = "71499")]
pub fn offset<T>(dst: *const T, offset: isize) -> *const T;
/// Calculates the offset from a pointer, potentially wrapping.
///
/// This is implemented as an intrinsic to avoid converting to and from an
/// integer, since the conversion inhibits certain optimizations.
///
/// # Safety
///
/// Unlike the `offset` intrinsic, this intrinsic does not restrict the
/// resulting pointer to point into or one byte past the end of an allocated
/// object, and it wraps with two's complement arithmetic. The resulting
/// value is not necessarily valid to be used to actually access memory.
///
/// The stabilized version of this intrinsic is [`pointer::wrapping_offset`].
#[must_use = "returns a new pointer rather than modifying its argument"]
#[rustc_const_unstable(feature = "const_ptr_offset", issue = "71499")]
pub fn arith_offset<T>(dst: *const T, offset: isize) -> *const T;
/// Equivalent to the appropriate `llvm.memcpy.p0i8.0i8.*` intrinsic, with
/// a size of `count` * `size_of::<T>()` and an alignment of
/// `min_align_of::<T>()`
///
/// The volatile parameter is set to `true`, so it will not be optimized out
/// unless size is equal to zero.
///
/// This intrinsic does not have a stable counterpart.
pub fn volatile_copy_nonoverlapping_memory<T>(dst: *mut T, src: *const T, count: usize);
/// Equivalent to the appropriate `llvm.memmove.p0i8.0i8.*` intrinsic, with
/// a size of `count * size_of::<T>()` and an alignment of
/// `min_align_of::<T>()`
///
/// The volatile parameter is set to `true`, so it will not be optimized out
/// unless size is equal to zero.
///
/// This intrinsic does not have a stable counterpart.
pub fn volatile_copy_memory<T>(dst: *mut T, src: *const T, count: usize);
/// Equivalent to the appropriate `llvm.memset.p0i8.*` intrinsic, with a
/// size of `count * size_of::<T>()` and an alignment of
/// `min_align_of::<T>()`.
///
/// The volatile parameter is set to `true`, so it will not be optimized out
/// unless size is equal to zero.
///
/// This intrinsic does not have a stable counterpart.
pub fn volatile_set_memory<T>(dst: *mut T, val: u8, count: usize);
/// Performs a volatile load from the `src` pointer.
///
/// The stabilized version of this intrinsic is [`core::ptr::read_volatile`].
pub fn volatile_load<T>(src: *const T) -> T;
/// Performs a volatile store to the `dst` pointer.
///
/// The stabilized version of this intrinsic is [`core::ptr::write_volatile`].
pub fn volatile_store<T>(dst: *mut T, val: T);
/// Performs a volatile load from the `src` pointer
/// The pointer is not required to be aligned.
///
/// This intrinsic does not have a stable counterpart.
pub fn unaligned_volatile_load<T>(src: *const T) -> T;
/// Performs a volatile store to the `dst` pointer.
/// The pointer is not required to be aligned.
///
/// This intrinsic does not have a stable counterpart.
pub fn unaligned_volatile_store<T>(dst: *mut T, val: T);
/// Returns the square root of an `f32`
///
/// The stabilized version of this intrinsic is
/// [`f32::sqrt`](../../std/primitive.f32.html#method.sqrt)
pub fn sqrtf32(x: f32) -> f32;
/// Returns the square root of an `f64`
///
/// The stabilized version of this intrinsic is
/// [`f64::sqrt`](../../std/primitive.f64.html#method.sqrt)
pub fn sqrtf64(x: f64) -> f64;
/// Raises an `f32` to an integer power.
///
/// The stabilized version of this intrinsic is
/// [`f32::powi`](../../std/primitive.f32.html#method.powi)
pub fn powif32(a: f32, x: i32) -> f32;
/// Raises an `f64` to an integer power.
///
/// The stabilized version of this intrinsic is
/// [`f64::powi`](../../std/primitive.f64.html#method.powi)
pub fn powif64(a: f64, x: i32) -> f64;
/// Returns the sine of an `f32`.
///
/// The stabilized version of this intrinsic is
/// [`f32::sin`](../../std/primitive.f32.html#method.sin)
pub fn sinf32(x: f32) -> f32;
/// Returns the sine of an `f64`.
///
/// The stabilized version of this intrinsic is
/// [`f64::sin`](../../std/primitive.f64.html#method.sin)
pub fn sinf64(x: f64) -> f64;
/// Returns the cosine of an `f32`.
///
/// The stabilized version of this intrinsic is
/// [`f32::cos`](../../std/primitive.f32.html#method.cos)
pub fn cosf32(x: f32) -> f32;
/// Returns the cosine of an `f64`.
///
/// The stabilized version of this intrinsic is
/// [`f64::cos`](../../std/primitive.f64.html#method.cos)
pub fn cosf64(x: f64) -> f64;
/// Raises an `f32` to an `f32` power.
///
/// The stabilized version of this intrinsic is
/// [`f32::powf`](../../std/primitive.f32.html#method.powf)
pub fn powf32(a: f32, x: f32) -> f32;
/// Raises an `f64` to an `f64` power.
///
/// The stabilized version of this intrinsic is
/// [`f64::powf`](../../std/primitive.f64.html#method.powf)
pub fn powf64(a: f64, x: f64) -> f64;
/// Returns the exponential of an `f32`.
///
/// The stabilized version of this intrinsic is
/// [`f32::exp`](../../std/primitive.f32.html#method.exp)
pub fn expf32(x: f32) -> f32;
/// Returns the exponential of an `f64`.
///
/// The stabilized version of this intrinsic is
/// [`f64::exp`](../../std/primitive.f64.html#method.exp)
pub fn expf64(x: f64) -> f64;
/// Returns 2 raised to the power of an `f32`.
///
/// The stabilized version of this intrinsic is
/// [`f32::exp2`](../../std/primitive.f32.html#method.exp2)
pub fn exp2f32(x: f32) -> f32;
/// Returns 2 raised to the power of an `f64`.
///
/// The stabilized version of this intrinsic is
/// [`f64::exp2`](../../std/primitive.f64.html#method.exp2)
pub fn exp2f64(x: f64) -> f64;
/// Returns the natural logarithm of an `f32`.
///
/// The stabilized version of this intrinsic is
/// [`f32::ln`](../../std/primitive.f32.html#method.ln)
pub fn logf32(x: f32) -> f32;
/// Returns the natural logarithm of an `f64`.
///
/// The stabilized version of this intrinsic is
/// [`f64::ln`](../../std/primitive.f64.html#method.ln)
pub fn logf64(x: f64) -> f64;
/// Returns the base 10 logarithm of an `f32`.
///
/// The stabilized version of this intrinsic is
/// [`f32::log10`](../../std/primitive.f32.html#method.log10)
pub fn log10f32(x: f32) -> f32;
/// Returns the base 10 logarithm of an `f64`.
///
/// The stabilized version of this intrinsic is
/// [`f64::log10`](../../std/primitive.f64.html#method.log10)
pub fn log10f64(x: f64) -> f64;
/// Returns the base 2 logarithm of an `f32`.
///
/// The stabilized version of this intrinsic is
/// [`f32::log2`](../../std/primitive.f32.html#method.log2)
pub fn log2f32(x: f32) -> f32;
/// Returns the base 2 logarithm of an `f64`.
///
/// The stabilized version of this intrinsic is
/// [`f64::log2`](../../std/primitive.f64.html#method.log2)
pub fn log2f64(x: f64) -> f64;
/// Returns `a * b + c` for `f32` values.
///
/// The stabilized version of this intrinsic is
/// [`f32::mul_add`](../../std/primitive.f32.html#method.mul_add)
pub fn fmaf32(a: f32, b: f32, c: f32) -> f32;
/// Returns `a * b + c` for `f64` values.
///
/// The stabilized version of this intrinsic is
/// [`f64::mul_add`](../../std/primitive.f64.html#method.mul_add)
pub fn fmaf64(a: f64, b: f64, c: f64) -> f64;
/// Returns the absolute value of an `f32`.
///
/// The stabilized version of this intrinsic is
/// [`f32::abs`](../../std/primitive.f32.html#method.abs)
pub fn fabsf32(x: f32) -> f32;
/// Returns the absolute value of an `f64`.
///
/// The stabilized version of this intrinsic is
/// [`f64::abs`](../../std/primitive.f64.html#method.abs)
pub fn fabsf64(x: f64) -> f64;
/// Returns the minimum of two `f32` values.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized version of this intrinsic is
/// [`f32::min`]
pub fn minnumf32(x: f32, y: f32) -> f32;
/// Returns the minimum of two `f64` values.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized version of this intrinsic is
/// [`f64::min`]
pub fn minnumf64(x: f64, y: f64) -> f64;
/// Returns the maximum of two `f32` values.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized version of this intrinsic is
/// [`f32::max`]
pub fn maxnumf32(x: f32, y: f32) -> f32;
/// Returns the maximum of two `f64` values.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized version of this intrinsic is
/// [`f64::max`]
pub fn maxnumf64(x: f64, y: f64) -> f64;
/// Copies the sign from `y` to `x` for `f32` values.
///
/// The stabilized version of this intrinsic is
/// [`f32::copysign`](../../std/primitive.f32.html#method.copysign)
pub fn copysignf32(x: f32, y: f32) -> f32;
/// Copies the sign from `y` to `x` for `f64` values.
///
/// The stabilized version of this intrinsic is
/// [`f64::copysign`](../../std/primitive.f64.html#method.copysign)
pub fn copysignf64(x: f64, y: f64) -> f64;
/// Returns the largest integer less than or equal to an `f32`.
///
/// The stabilized version of this intrinsic is
/// [`f32::floor`](../../std/primitive.f32.html#method.floor)
pub fn floorf32(x: f32) -> f32;
/// Returns the largest integer less than or equal to an `f64`.
///
/// The stabilized version of this intrinsic is
/// [`f64::floor`](../../std/primitive.f64.html#method.floor)
pub fn floorf64(x: f64) -> f64;
/// Returns the smallest integer greater than or equal to an `f32`.
///
/// The stabilized version of this intrinsic is
/// [`f32::ceil`](../../std/primitive.f32.html#method.ceil)
pub fn ceilf32(x: f32) -> f32;
/// Returns the smallest integer greater than or equal to an `f64`.
///
/// The stabilized version of this intrinsic is
/// [`f64::ceil`](../../std/primitive.f64.html#method.ceil)
pub fn ceilf64(x: f64) -> f64;
/// Returns the integer part of an `f32`.
///
/// The stabilized version of this intrinsic is
/// [`f32::trunc`](../../std/primitive.f32.html#method.trunc)
pub fn truncf32(x: f32) -> f32;
/// Returns the integer part of an `f64`.
///
/// The stabilized version of this intrinsic is
/// [`f64::trunc`](../../std/primitive.f64.html#method.trunc)
pub fn truncf64(x: f64) -> f64;
/// Returns the nearest integer to an `f32`. May raise an inexact floating-point exception
/// if the argument is not an integer.
pub fn rintf32(x: f32) -> f32;
/// Returns the nearest integer to an `f64`. May raise an inexact floating-point exception
/// if the argument is not an integer.
pub fn rintf64(x: f64) -> f64;
/// Returns the nearest integer to an `f32`.
///
/// This intrinsic does not have a stable counterpart.
pub fn nearbyintf32(x: f32) -> f32;
/// Returns the nearest integer to an `f64`.
///
/// This intrinsic does not have a stable counterpart.
pub fn nearbyintf64(x: f64) -> f64;
/// Returns the nearest integer to an `f32`. Rounds half-way cases away from zero.
///
/// The stabilized version of this intrinsic is
/// [`f32::round`](../../std/primitive.f32.html#method.round)
pub fn roundf32(x: f32) -> f32;
/// Returns the nearest integer to an `f64`. Rounds half-way cases away from zero.
///
/// The stabilized version of this intrinsic is
/// [`f64::round`](../../std/primitive.f64.html#method.round)
pub fn roundf64(x: f64) -> f64;
/// Float addition that allows optimizations based on algebraic rules.
/// May assume inputs are finite.
///
/// This intrinsic does not have a stable counterpart.
pub fn fadd_fast<T: Copy>(a: T, b: T) -> T;
/// Float subtraction that allows optimizations based on algebraic rules.
/// May assume inputs are finite.
///
/// This intrinsic does not have a stable counterpart.
pub fn fsub_fast<T: Copy>(a: T, b: T) -> T;
/// Float multiplication that allows optimizations based on algebraic rules.
/// May assume inputs are finite.
///
/// This intrinsic does not have a stable counterpart.
pub fn fmul_fast<T: Copy>(a: T, b: T) -> T;
/// Float division that allows optimizations based on algebraic rules.
/// May assume inputs are finite.
///
/// This intrinsic does not have a stable counterpart.
pub fn fdiv_fast<T: Copy>(a: T, b: T) -> T;
/// Float remainder that allows optimizations based on algebraic rules.
/// May assume inputs are finite.
///
/// This intrinsic does not have a stable counterpart.
pub fn frem_fast<T: Copy>(a: T, b: T) -> T;
/// Convert with LLVM’s fptoui/fptosi, which may return undef for values out of range
/// (<https://github.com/rust-lang/rust/issues/10184>)
///
/// Stabilized as [`f32::to_int_unchecked`] and [`f64::to_int_unchecked`].
pub fn float_to_int_unchecked<Float: Copy, Int: Copy>(value: Float) -> Int;
/// Returns the number of bits set in an integer type `T`
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized versions of this intrinsic are available on the integer
/// primitives via the `count_ones` method. For example,
/// [`u32::count_ones`]
#[rustc_const_stable(feature = "const_ctpop", since = "1.40.0")]
pub fn ctpop<T: Copy>(x: T) -> T;
/// Returns the number of leading unset bits (zeroes) in an integer type `T`.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized versions of this intrinsic are available on the integer
/// primitives via the `leading_zeros` method. For example,
/// [`u32::leading_zeros`]
///
/// # Examples
///
/// ```
/// #![feature(core_intrinsics)]
///
/// use std::intrinsics::ctlz;
///
/// let x = 0b0001_1100_u8;
/// let num_leading = ctlz(x);
/// assert_eq!(num_leading, 3);
/// ```
///
/// An `x` with value `0` will return the bit width of `T`.
///
/// ```
/// #![feature(core_intrinsics)]
///
/// use std::intrinsics::ctlz;
///
/// let x = 0u16;
/// let num_leading = ctlz(x);
/// assert_eq!(num_leading, 16);
/// ```
#[rustc_const_stable(feature = "const_ctlz", since = "1.40.0")]
pub fn ctlz<T: Copy>(x: T) -> T;
/// Like `ctlz`, but extra-unsafe as it returns `undef` when
/// given an `x` with value `0`.
///
/// This intrinsic does not have a stable counterpart.
///
/// # Examples
///
/// ```
/// #![feature(core_intrinsics)]
///
/// use std::intrinsics::ctlz_nonzero;
///
/// let x = 0b0001_1100_u8;
/// let num_leading = unsafe { ctlz_nonzero(x) };
/// assert_eq!(num_leading, 3);
/// ```
#[rustc_const_stable(feature = "constctlz", since = "1.50.0")]
pub fn ctlz_nonzero<T: Copy>(x: T) -> T;
/// Returns the number of trailing unset bits (zeroes) in an integer type `T`.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized versions of this intrinsic are available on the integer
/// primitives via the `trailing_zeros` method. For example,
/// [`u32::trailing_zeros`]
///
/// # Examples
///
/// ```
/// #![feature(core_intrinsics)]
///
/// use std::intrinsics::cttz;
///
/// let x = 0b0011_1000_u8;
/// let num_trailing = cttz(x);
/// assert_eq!(num_trailing, 3);
/// ```
///
/// An `x` with value `0` will return the bit width of `T`:
///
/// ```
/// #![feature(core_intrinsics)]
///
/// use std::intrinsics::cttz;
///
/// let x = 0u16;
/// let num_trailing = cttz(x);
/// assert_eq!(num_trailing, 16);
/// ```
#[rustc_const_stable(feature = "const_cttz", since = "1.40.0")]
pub fn cttz<T: Copy>(x: T) -> T;
/// Like `cttz`, but extra-unsafe as it returns `undef` when
/// given an `x` with value `0`.
///
/// This intrinsic does not have a stable counterpart.
///
/// # Examples
///
/// ```
/// #![feature(core_intrinsics)]
///
/// use std::intrinsics::cttz_nonzero;
///
/// let x = 0b0011_1000_u8;
/// let num_trailing = unsafe { cttz_nonzero(x) };
/// assert_eq!(num_trailing, 3);
/// ```
#[rustc_const_stable(feature = "const_cttz", since = "1.53.0")]
pub fn cttz_nonzero<T: Copy>(x: T) -> T;
/// Reverses the bytes in an integer type `T`.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized versions of this intrinsic are available on the integer
/// primitives via the `swap_bytes` method. For example,
/// [`u32::swap_bytes`]
#[rustc_const_stable(feature = "const_bswap", since = "1.40.0")]
pub fn bswap<T: Copy>(x: T) -> T;
/// Reverses the bits in an integer type `T`.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized versions of this intrinsic are available on the integer
/// primitives via the `reverse_bits` method. For example,
/// [`u32::reverse_bits`]
#[rustc_const_stable(feature = "const_bitreverse", since = "1.40.0")]
pub fn bitreverse<T: Copy>(x: T) -> T;
/// Performs checked integer addition.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized versions of this intrinsic are available on the integer
/// primitives via the `overflowing_add` method. For example,
/// [`u32::overflowing_add`]
#[rustc_const_stable(feature = "const_int_overflow", since = "1.40.0")]
pub fn add_with_overflow<T: Copy>(x: T, y: T) -> (T, bool);
/// Performs checked integer subtraction
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized versions of this intrinsic are available on the integer
/// primitives via the `overflowing_sub` method. For example,
/// [`u32::overflowing_sub`]
#[rustc_const_stable(feature = "const_int_overflow", since = "1.40.0")]
pub fn sub_with_overflow<T: Copy>(x: T, y: T) -> (T, bool);
/// Performs checked integer multiplication
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized versions of this intrinsic are available on the integer
/// primitives via the `overflowing_mul` method. For example,
/// [`u32::overflowing_mul`]
#[rustc_const_stable(feature = "const_int_overflow", since = "1.40.0")]
pub fn mul_with_overflow<T: Copy>(x: T, y: T) -> (T, bool);
/// Performs an exact division, resulting in undefined behavior where
/// `x % y != 0` or `y == 0` or `x == T::MIN && y == -1`
///
/// This intrinsic does not have a stable counterpart.
pub fn exact_div<T: Copy>(x: T, y: T) -> T;
/// Performs an unchecked division, resulting in undefined behavior
/// where `y == 0` or `x == T::MIN && y == -1`
///
/// Safe wrappers for this intrinsic are available on the integer
/// primitives via the `checked_div` method. For example,
/// [`u32::checked_div`]
#[rustc_const_stable(feature = "const_int_unchecked_arith", since = "1.52.0")]
pub fn unchecked_div<T: Copy>(x: T, y: T) -> T;
/// Returns the remainder of an unchecked division, resulting in
/// undefined behavior when `y == 0` or `x == T::MIN && y == -1`
///
/// Safe wrappers for this intrinsic are available on the integer
/// primitives via the `checked_rem` method. For example,
/// [`u32::checked_rem`]
#[rustc_const_stable(feature = "const_int_unchecked_arith", since = "1.52.0")]
pub fn unchecked_rem<T: Copy>(x: T, y: T) -> T;
/// Performs an unchecked left shift, resulting in undefined behavior when
/// `y < 0` or `y >= N`, where N is the width of T in bits.
///
/// Safe wrappers for this intrinsic are available on the integer
/// primitives via the `checked_shl` method. For example,
/// [`u32::checked_shl`]
#[rustc_const_stable(feature = "const_int_unchecked", since = "1.40.0")]
pub fn unchecked_shl<T: Copy>(x: T, y: T) -> T;
/// Performs an unchecked right shift, resulting in undefined behavior when
/// `y < 0` or `y >= N`, where N is the width of T in bits.
///
/// Safe wrappers for this intrinsic are available on the integer
/// primitives via the `checked_shr` method. For example,
/// [`u32::checked_shr`]
#[rustc_const_stable(feature = "const_int_unchecked", since = "1.40.0")]
pub fn unchecked_shr<T: Copy>(x: T, y: T) -> T;
/// Returns the result of an unchecked addition, resulting in
/// undefined behavior when `x + y > T::MAX` or `x + y < T::MIN`.
///
/// This intrinsic does not have a stable counterpart.
#[rustc_const_unstable(feature = "const_int_unchecked_arith", issue = "none")]
pub fn unchecked_add<T: Copy>(x: T, y: T) -> T;
/// Returns the result of an unchecked subtraction, resulting in
/// undefined behavior when `x - y > T::MAX` or `x - y < T::MIN`.
///
/// This intrinsic does not have a stable counterpart.
#[rustc_const_unstable(feature = "const_int_unchecked_arith", issue = "none")]
pub fn unchecked_sub<T: Copy>(x: T, y: T) -> T;
/// Returns the result of an unchecked multiplication, resulting in
/// undefined behavior when `x * y > T::MAX` or `x * y < T::MIN`.
///
/// This intrinsic does not have a stable counterpart.
#[rustc_const_unstable(feature = "const_int_unchecked_arith", issue = "none")]
pub fn unchecked_mul<T: Copy>(x: T, y: T) -> T;
/// Performs rotate left.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized versions of this intrinsic are available on the integer
/// primitives via the `rotate_left` method. For example,
/// [`u32::rotate_left`]
#[rustc_const_stable(feature = "const_int_rotate", since = "1.40.0")]
pub fn rotate_left<T: Copy>(x: T, y: T) -> T;
/// Performs rotate right.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized versions of this intrinsic are available on the integer
/// primitives via the `rotate_right` method. For example,
/// [`u32::rotate_right`]
#[rustc_const_stable(feature = "const_int_rotate", since = "1.40.0")]
pub fn rotate_right<T: Copy>(x: T, y: T) -> T;
/// Returns (a + b) mod 2<sup>N</sup>, where N is the width of T in bits.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized versions of this intrinsic are available on the integer
/// primitives via the `wrapping_add` method. For example,
/// [`u32::wrapping_add`]
#[rustc_const_stable(feature = "const_int_wrapping", since = "1.40.0")]
pub fn wrapping_add<T: Copy>(a: T, b: T) -> T;
/// Returns (a - b) mod 2<sup>N</sup>, where N is the width of T in bits.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized versions of this intrinsic are available on the integer
/// primitives via the `wrapping_sub` method. For example,
/// [`u32::wrapping_sub`]
#[rustc_const_stable(feature = "const_int_wrapping", since = "1.40.0")]
pub fn wrapping_sub<T: Copy>(a: T, b: T) -> T;
/// Returns (a * b) mod 2<sup>N</sup>, where N is the width of T in bits.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized versions of this intrinsic are available on the integer
/// primitives via the `wrapping_mul` method. For example,
/// [`u32::wrapping_mul`]
#[rustc_const_stable(feature = "const_int_wrapping", since = "1.40.0")]
pub fn wrapping_mul<T: Copy>(a: T, b: T) -> T;
/// Computes `a + b`, saturating at numeric bounds.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized versions of this intrinsic are available on the integer
/// primitives via the `saturating_add` method. For example,
/// [`u32::saturating_add`]
#[rustc_const_stable(feature = "const_int_saturating", since = "1.40.0")]
pub fn saturating_add<T: Copy>(a: T, b: T) -> T;
/// Computes `a - b`, saturating at numeric bounds.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized versions of this intrinsic are available on the integer
/// primitives via the `saturating_sub` method. For example,
/// [`u32::saturating_sub`]
#[rustc_const_stable(feature = "const_int_saturating", since = "1.40.0")]
pub fn saturating_sub<T: Copy>(a: T, b: T) -> T;
/// Returns the value of the discriminant for the variant in 'v';
/// if `T` has no discriminant, returns `0`.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The stabilized version of this intrinsic is [`core::mem::discriminant`].
#[rustc_const_unstable(feature = "const_discriminant", issue = "69821")]
pub fn discriminant_value<T>(v: &T) -> <T as DiscriminantKind>::Discriminant;
/// Returns the number of variants of the type `T` cast to a `usize`;
/// if `T` has no variants, returns `0`. Uninhabited variants will be counted.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
///
/// The to-be-stabilized version of this intrinsic is [`mem::variant_count`].
#[rustc_const_unstable(feature = "variant_count", issue = "73662")]
pub fn variant_count<T>() -> usize;
/// Rust's "try catch" construct which invokes the function pointer `try_fn`
/// with the data pointer `data`.
///
/// The third argument is a function called if a panic occurs. This function
/// takes the data pointer and a pointer to the target-specific exception
/// object that was caught. For more information see the compiler's
/// source as well as std's catch implementation.
pub fn r#try(try_fn: fn(*mut u8), data: *mut u8, catch_fn: fn(*mut u8, *mut u8)) -> i32;
/// Emits a `!nontemporal` store according to LLVM (see their docs).
/// Probably will never become stable.
pub fn nontemporal_store<T>(ptr: *mut T, val: T);
/// See documentation of `<*const T>::offset_from` for details.
#[rustc_const_unstable(feature = "const_ptr_offset_from", issue = "41079")]
pub fn ptr_offset_from<T>(ptr: *const T, base: *const T) -> isize;
/// See documentation of `<*const T>::guaranteed_eq` for details.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
#[rustc_const_unstable(feature = "const_raw_ptr_comparison", issue = "53020")]
pub fn ptr_guaranteed_eq<T>(ptr: *const T, other: *const T) -> bool;
/// See documentation of `<*const T>::guaranteed_ne` for details.
///
/// Note that, unlike most intrinsics, this is safe to call;
/// it does not require an `unsafe` block.
/// Therefore, implementations must not require the user to uphold
/// any safety invariants.
#[rustc_const_unstable(feature = "const_raw_ptr_comparison", issue = "53020")]
pub fn ptr_guaranteed_ne<T>(ptr: *const T, other: *const T) -> bool;
/// Allocate at compile time. Should not be called at runtime.
#[rustc_const_unstable(feature = "const_heap", issue = "79597")]
pub fn const_allocate(size: usize, align: usize) -> *mut u8;
/// Determines whether the raw bytes of the two values are equal.
///
/// This is particularly handy for arrays, since it allows things like just
/// comparing `i96`s instead of forcing `alloca`s for `[6 x i16]`.
///
/// Above some backend-decided threshold this will emit calls to `memcmp`,
/// like slice equality does, instead of causing massive code size.
///
/// # Safety
///
/// It's UB to call this if any of the *bytes* in `*a` or `*b` are uninitialized.
/// Note that this is a stricter criterion than just the *values* being
/// fully-initialized: if `T` has padding, it's UB to call this intrinsic.
///
/// (The implementation is allowed to branch on the results of comparisons,
/// which is UB if any of their inputs are `undef`.)
#[rustc_const_unstable(feature = "const_intrinsic_raw_eq", issue = "none")]
pub fn raw_eq<T>(a: &T, b: &T) -> bool;
/// See documentation of [`std::hint::black_box`] for details.
///
/// [`std::hint::black_box`]: crate::hint::black_box
#[rustc_const_unstable(feature = "const_black_box", issue = "none")]
pub fn black_box<T>(dummy: T) -> T;
}
// Some functions are defined here because they accidentally got made
// available in this module on stable. See <https://github.com/rust-lang/rust/issues/15702>.
// (`transmute` also falls into this category, but it cannot be wrapped due to the
// check that `T` and `U` have the same size.)
/// Checks whether `ptr` is properly aligned with respect to
/// `align_of::<T>()`.
pub(crate) fn is_aligned_and_not_null<T>(ptr: *const T) -> bool {
!ptr.is_null() && ptr as usize % mem::align_of::<T>() == 0
}
/// Checks whether the regions of memory starting at `src` and `dst` of size
/// `count * size_of::<T>()` do *not* overlap.
#[cfg(debug_assertions)]
pub(crate) fn is_nonoverlapping<T>(src: *const T, dst: *const T, count: usize) -> bool {
let src_usize = src as usize;
let dst_usize = dst as usize;
let size = mem::size_of::<T>().checked_mul(count).unwrap();
let diff = if src_usize > dst_usize { src_usize - dst_usize } else { dst_usize - src_usize };
// If the absolute distance between the ptrs is at least as big as the size of the buffer,
// they do not overlap.
diff >= size
}
/// Copies `count * size_of::<T>()` bytes from `src` to `dst`. The source
/// and destination must *not* overlap.
///
/// For regions of memory which might overlap, use [`copy`] instead.
///
/// `copy_nonoverlapping` is semantically equivalent to C's [`memcpy`], but
/// with the argument order swapped.
///
/// [`memcpy`]: https://en.cppreference.com/w/c/string/byte/memcpy
///
/// # Safety
///
/// Behavior is undefined if any of the following conditions are violated:
///
/// * `src` must be [valid] for reads of `count * size_of::<T>()` bytes.
///
/// * `dst` must be [valid] for writes of `count * size_of::<T>()` bytes.
///
/// * Both `src` and `dst` must be properly aligned.
///
/// * The region of memory beginning at `src` with a size of `count *
/// size_of::<T>()` bytes must *not* overlap with the region of memory
/// beginning at `dst` with the same size.
///
/// Like [`read`], `copy_nonoverlapping` creates a bitwise copy of `T`, regardless of
/// whether `T` is [`Copy`]. If `T` is not [`Copy`], using *both* the values
/// in the region beginning at `*src` and the region beginning at `*dst` can
/// [violate memory safety][read-ownership].
///
/// Note that even if the effectively copied size (`count * size_of::<T>()`) is
/// `0`, the pointers must be non-null and properly aligned.
///
/// [`read`]: crate::ptr::read
/// [read-ownership]: crate::ptr::read#ownership-of-the-returned-value
/// [valid]: crate::ptr#safety
///
/// # Examples
///
/// Manually implement [`Vec::append`]:
///
/// ```
/// use std::ptr;
///
/// /// Moves all the elements of `src` into `dst`, leaving `src` empty.
/// fn append<T>(dst: &mut Vec<T>, src: &mut Vec<T>) {
/// let src_len = src.len();
/// let dst_len = dst.len();
///
/// // Ensure that `dst` has enough capacity to hold all of `src`.
/// dst.reserve(src_len);
///
/// unsafe {
/// // The call to offset is always safe because `Vec` will never
/// // allocate more than `isize::MAX` bytes.
/// let dst_ptr = dst.as_mut_ptr().offset(dst_len as isize);
/// let src_ptr = src.as_ptr();
///
/// // Truncate `src` without dropping its contents. We do this first,
/// // to avoid problems in case something further down panics.
/// src.set_len(0);
///
/// // The two regions cannot overlap because mutable references do
/// // not alias, and two different vectors cannot own the same
/// // memory.
/// ptr::copy_nonoverlapping(src_ptr, dst_ptr, src_len);
///
/// // Notify `dst` that it now holds the contents of `src`.
/// dst.set_len(dst_len + src_len);
/// }
/// }
///
/// let mut a = vec!['r'];
/// let mut b = vec!['u', 's', 't'];
///
/// append(&mut a, &mut b);
///
/// assert_eq!(a, &['r', 'u', 's', 't']);
/// assert!(b.is_empty());
/// ```
///
/// [`Vec::append`]: ../../std/vec/struct.Vec.html#method.append
#[doc(alias = "memcpy")]
#[stable(feature = "rust1", since = "1.0.0")]
#[rustc_const_unstable(feature = "const_intrinsic_copy", issue = "80697")]
#[inline]
pub const unsafe fn copy_nonoverlapping<T>(src: *const T, dst: *mut T, count: usize) {
extern "rust-intrinsic" {
#[rustc_const_unstable(feature = "const_intrinsic_copy", issue = "80697")]
pub fn copy_nonoverlapping<T>(src: *const T, dst: *mut T, count: usize);
}
#[cfg(debug_assertions)]
fn runtime_check<T>(src: *const T, dst: *mut T, count: usize) {
if !is_aligned_and_not_null(src)
|| !is_aligned_and_not_null(dst)
|| !is_nonoverlapping(src, dst, count)
{
// Not panicking to keep codegen impact smaller.
abort();
}
}
#[cfg(debug_assertions)]
const fn compiletime_check<T>(_src: *const T, _dst: *mut T, _count: usize) {}
#[cfg(debug_assertions)]
// SAFETY: As per our safety precondition, we may assume that the `abort` above is never reached.
// Therefore, compiletime_check and runtime_check are observably equivalent.
unsafe {
const_eval_select((src, dst, count), compiletime_check, runtime_check);
}
// SAFETY: the safety contract for `copy_nonoverlapping` must be
// upheld by the caller.
unsafe { copy_nonoverlapping(src, dst, count) }
}
/// Copies `count * size_of::<T>()` bytes from `src` to `dst`. The source
/// and destination may overlap.
///
/// If the source and destination will *never* overlap,
/// [`copy_nonoverlapping`] can be used instead.
///
/// `copy` is semantically equivalent to C's [`memmove`], but with the argument
/// order swapped. Copying takes place as if the bytes were copied from `src`
/// to a temporary array and then copied from the array to `dst`.
///
/// [`memmove`]: https://en.cppreference.com/w/c/string/byte/memmove
///
/// # Safety
///
/// Behavior is undefined if any of the following conditions are violated:
///
/// * `src` must be [valid] for reads of `count * size_of::<T>()` bytes.
///
/// * `dst` must be [valid] for writes of `count * size_of::<T>()` bytes.
///
/// * Both `src` and `dst` must be properly aligned.
///
/// Like [`read`], `copy` creates a bitwise copy of `T`, regardless of
/// whether `T` is [`Copy`]. If `T` is not [`Copy`], using both the values
/// in the region beginning at `*src` and the region beginning at `*dst` can
/// [violate memory safety][read-ownership].
///
/// Note that even if the effectively copied size (`count * size_of::<T>()`) is
/// `0`, the pointers must be non-null and properly aligned.
///
/// [`read`]: crate::ptr::read
/// [read-ownership]: crate::ptr::read#ownership-of-the-returned-value
/// [valid]: crate::ptr#safety
///
/// # Examples
///
/// Efficiently create a Rust vector from an unsafe buffer:
///
/// ```
/// use std::ptr;
///
/// /// # Safety
/// ///
/// /// * `ptr` must be correctly aligned for its type and non-zero.
/// /// * `ptr` must be valid for reads of `elts` contiguous elements of type `T`.
/// /// * Those elements must not be used after calling this function unless `T: Copy`.
/// # #[allow(dead_code)]
/// unsafe fn from_buf_raw<T>(ptr: *const T, elts: usize) -> Vec<T> {
/// let mut dst = Vec::with_capacity(elts);
///
/// // SAFETY: Our precondition ensures the source is aligned and valid,
/// // and `Vec::with_capacity` ensures that we have usable space to write them.
/// ptr::copy(ptr, dst.as_mut_ptr(), elts);
///
/// // SAFETY: We created it with this much capacity earlier,
/// // and the previous `copy` has initialized these elements.
/// dst.set_len(elts);
/// dst
/// }
/// ```
#[doc(alias = "memmove")]
#[stable(feature = "rust1", since = "1.0.0")]
#[rustc_const_unstable(feature = "const_intrinsic_copy", issue = "80697")]
#[inline]
pub const unsafe fn copy<T>(src: *const T, dst: *mut T, count: usize) {
extern "rust-intrinsic" {
#[rustc_const_unstable(feature = "const_intrinsic_copy", issue = "80697")]
fn copy<T>(src: *const T, dst: *mut T, count: usize);
}
#[cfg(debug_assertions)]
fn runtime_check<T>(src: *const T, dst: *mut T) {
if !is_aligned_and_not_null(src) || !is_aligned_and_not_null(dst) {
// Not panicking to keep codegen impact smaller.
abort();
}
}
#[cfg(debug_assertions)]
const fn compiletime_check<T>(_src: *const T, _dst: *mut T) {}
#[cfg(debug_assertions)]
// SAFETY: As per our safety precondition, we may assume that the `abort` above is never reached.
// Therefore, compiletime_check and runtime_check are observably equivalent.
unsafe {
const_eval_select((src, dst), compiletime_check, runtime_check);
}
// SAFETY: the safety contract for `copy` must be upheld by the caller.
unsafe { copy(src, dst, count) }
}
/// Sets `count * size_of::<T>()` bytes of memory starting at `dst` to
/// `val`.
///
/// `write_bytes` is similar to C's [`memset`], but sets `count *
/// size_of::<T>()` bytes to `val`.
///
/// [`memset`]: https://en.cppreference.com/w/c/string/byte/memset
///
/// # Safety
///
/// Behavior is undefined if any of the following conditions are violated:
///
/// * `dst` must be [valid] for writes of `count * size_of::<T>()` bytes.
///
/// * `dst` must be properly aligned.
///
/// Additionally, the caller must ensure that writing `count *
/// size_of::<T>()` bytes to the given region of memory results in a valid
/// value of `T`. Using a region of memory typed as a `T` that contains an
/// invalid value of `T` is undefined behavior.
///
/// Note that even if the effectively copied size (`count * size_of::<T>()`) is
/// `0`, the pointer must be non-null and properly aligned.
///
/// [valid]: crate::ptr#safety
///
/// # Examples
///
/// Basic usage:
///
/// ```
/// use std::ptr;
///
/// let mut vec = vec![0u32; 4];
/// unsafe {
/// let vec_ptr = vec.as_mut_ptr();
/// ptr::write_bytes(vec_ptr, 0xfe, 2);
/// }
/// assert_eq!(vec, [0xfefefefe, 0xfefefefe, 0, 0]);
/// ```
///
/// Creating an invalid value:
///
/// ```
/// use std::ptr;
///
/// let mut v = Box::new(0i32);
///
/// unsafe {
/// // Leaks the previously held value by overwriting the `Box<T>` with
/// // a null pointer.
/// ptr::write_bytes(&mut v as *mut Box<i32>, 0, 1);
/// }
///
/// // At this point, using or dropping `v` results in undefined behavior.
/// // drop(v); // ERROR
///
/// // Even leaking `v` "uses" it, and hence is undefined behavior.
/// // mem::forget(v); // ERROR
///
/// // In fact, `v` is invalid according to basic type layout invariants, so *any*
/// // operation touching it is undefined behavior.
/// // let v2 = v; // ERROR
///
/// unsafe {
/// // Let us instead put in a valid value
/// ptr::write(&mut v as *mut Box<i32>, Box::new(42i32));
/// }
///
/// // Now the box is fine
/// assert_eq!(*v, 42);
/// ```
#[stable(feature = "rust1", since = "1.0.0")]
#[rustc_const_unstable(feature = "const_ptr_write", issue = "86302")]
#[inline]
pub const unsafe fn write_bytes<T>(dst: *mut T, val: u8, count: usize) {
extern "rust-intrinsic" {
#[rustc_const_unstable(feature = "const_ptr_write", issue = "86302")]
fn write_bytes<T>(dst: *mut T, val: u8, count: usize);
}
#[cfg(debug_assertions)]
fn runtime_check<T>(ptr: *mut T) {
debug_assert!(
is_aligned_and_not_null(ptr),
"attempt to write to unaligned or null pointer"
);
}
#[cfg(debug_assertions)]
const fn compiletime_check<T>(_ptr: *mut T) {}
#[cfg(debug_assertions)]
// SAFETY: runtime debug-assertions are a best-effort basis; it's fine to
// not do them during compile time
unsafe {
const_eval_select((dst,), compiletime_check, runtime_check);
}
// SAFETY: the safety contract for `write_bytes` must be upheld by the caller.
unsafe { write_bytes(dst, val, count) }
}
/// Selects which function to call depending on the context.
///
/// If this function is evaluated at compile-time, then a call to this
/// intrinsic will be replaced with a call to `called_in_const`. It gets
/// replaced with a call to `called_at_rt` otherwise.
///
/// # Type Requirements
///
/// The two functions must be both function items. They cannot be function
/// pointers or closures.
///
/// `arg` will be the arguments that will be passed to either one of the
/// two functions, therefore, both functions must accept the same type of
/// arguments. Both functions must return RET.
///
/// # Safety
///
/// The two functions must behave observably equivalent. Safe code in other
/// crates may assume that calling a `const fn` at compile-time and at run-time
/// produces the same result. A function that produces a different result when
/// evaluated at run-time, or has any other observable side-effects, is
/// *unsound*.
///
/// Here is an example of how this could cause a problem:
/// ```no_run
/// #![feature(const_eval_select)]
/// use std::hint::unreachable_unchecked;
/// use std::intrinsics::const_eval_select;
///
/// // Crate A
/// pub const fn inconsistent() -> i32 {
/// fn runtime() -> i32 { 1 }
/// const fn compiletime() -> i32 { 2 }
///
/// unsafe {
// // ⚠ This code violates the required equivalence of `compiletime`
/// // and `runtime`.
/// const_eval_select((), compiletime, runtime)
/// }
/// }
///
/// // Crate B
/// const X: i32 = inconsistent();
/// let x = inconsistent();
/// if x != X { unsafe { unreachable_unchecked(); }}
/// ```
///
/// This code causes Undefined Behavior when being run, since the
/// `unreachable_unchecked` is actually being reached. The bug is in *crate A*,
/// which violates the principle that a `const fn` must behave the same at
/// compile-time and at run-time. The unsafe code in crate B is fine.
#[unstable(
feature = "const_eval_select",
issue = "none",
reason = "const_eval_select will never be stable"
)]
#[rustc_const_unstable(feature = "const_eval_select", issue = "none")]
#[lang = "const_eval_select"]
#[rustc_do_not_const_check]
pub const unsafe fn const_eval_select<ARG, F, G, RET>(
arg: ARG,
_called_in_const: F,
called_at_rt: G,
) -> RET
where
F: ~const FnOnce<ARG, Output = RET>,
G: FnOnce<ARG, Output = RET> + ~const Drop,
{
called_at_rt.call_once(arg)
}
#[unstable(
feature = "const_eval_select",
issue = "none",
reason = "const_eval_select will never be stable"
)]
#[rustc_const_unstable(feature = "const_eval_select", issue = "none")]
#[lang = "const_eval_select_ct"]
pub const unsafe fn const_eval_select_ct<ARG, F, G, RET>(
arg: ARG,
called_in_const: F,
_called_at_rt: G,
) -> RET
where
F: ~const FnOnce<ARG, Output = RET>,
G: FnOnce<ARG, Output = RET> + ~const Drop,
{
called_in_const.call_once(arg)
}