src/libcore/hint.rs - third_party/rust - Git at Google

 #![stable(feature = "core_hint", since = "1.27.0")]

 //! Hints to compiler that affects how code should be emitted or optimized.

 use crate::intrinsics;

 /// Informs the compiler that this point in the code is not reachable, enabling
 /// further optimizations.
 ///
 /// # Safety
 ///
 /// Reaching this function is completely *undefined behavior* (UB). In
 /// particular, the compiler assumes that all UB must never happen, and
 /// therefore will eliminate all branches that reach to a call to
 /// `unreachable_unchecked()`.
 ///
 /// Like all instances of UB, if this assumption turns out to be wrong, i.e., the
 /// `unreachable_unchecked()` call is actually reachable among all possible
 /// control flow, the compiler will apply the wrong optimization strategy, and
 /// may sometimes even corrupt seemingly unrelated code, causing
 /// difficult-to-debug problems.
 ///
 /// Use this function only when you can prove that the code will never call it.
 /// Otherwise, consider using the [`unreachable!`] macro, which does not allow
 /// optimizations but will panic when executed.
 ///
 /// [`unreachable!`]: ../macro.unreachable.html
 ///
 /// # Example
 ///
 /// ```
 /// fn div_1(a: u32, b: u32) -> u32 {
 ///     use std::hint::unreachable_unchecked;
 ///
 ///     // `b.saturating_add(1)` is always positive (not zero),
 ///     // hence `checked_div` will never return `None`.
 ///     // Therefore, the else branch is unreachable.
 ///     a.checked_div(b.saturating_add(1))
 ///         .unwrap_or_else(|| unsafe { unreachable_unchecked() })
 /// }
 ///
 /// assert_eq!(div_1(7, 0), 7);
 /// assert_eq!(div_1(9, 1), 4);
 /// assert_eq!(div_1(11, std::u32::MAX), 0);
 /// ```
 #[inline]
 #[stable(feature = "unreachable", since = "1.27.0")]
 pub unsafe fn unreachable_unchecked() -> ! {
     intrinsics::unreachable()
 }

 /// Emits a machine instruction hinting to the processor that it is running in busy-wait
 /// spin-loop ("spin lock").
 ///
 /// For a discussion of different locking strategies and their trade-offs, see
 /// [`core::sync::atomic::spin_loop_hint`].
 ///
 /// **Note**: On platforms that do not support receiving spin-loop hints this function does not
 /// do anything at all.
 ///
 /// [`core::sync::atomic::spin_loop_hint`]: ./sync/atomic/fn.spin_loop_hint.html
 #[inline]
 #[unstable(feature = "renamed_spin_loop", issue = "55002")]
 pub fn spin_loop() {
     #[cfg(
         all(
             any(target_arch = "x86", target_arch = "x86_64"),
             target_feature = "sse2"
         )
     )] {
         #[cfg(target_arch = "x86")] {
             unsafe { crate::arch::x86::_mm_pause() };
         }

         #[cfg(target_arch = "x86_64")] {
             unsafe { crate::arch::x86_64::_mm_pause() };
         }
     }

     #[cfg(
         any(
             target_arch = "aarch64",
             all(target_arch = "arm", target_feature = "v6")
         )
     )] {
         #[cfg(target_arch = "aarch64")] {
             unsafe { crate::arch::aarch64::__yield() };
         }
         #[cfg(target_arch = "arm")] {
             unsafe { crate::arch::arm::__yield() };
         }
     }
 }

 /// An identity function that *__hints__* to the compiler to be maximally pessimistic about what
 /// `black_box` could do.
 ///
 /// [`std::convert::identity`]: https://doc.rust-lang.org/core/convert/fn.identity.html
 ///
 /// Unlike [`std::convert::identity`], a Rust compiler is encouraged to assume that `black_box` can
 /// use `x` in any possible valid way that Rust code is allowed to without introducing undefined
 /// behavior in the calling code. This property makes `black_box` useful for writing code in which
 /// certain optimizations are not desired, such as benchmarks.
 ///
 /// Note however, that `black_box` is only (and can only be) provided on a "best-effort" basis. The
 /// extent to which it can block optimisations may vary depending upon the platform and code-gen
 /// backend used. Programs cannot rely on `black_box` for *correctness* in any way.
 #[inline]
 #[unstable(feature = "test", issue = "50297")]
 #[allow(unreachable_code)] // this makes #[cfg] a bit easier below.
 pub fn black_box<T>(dummy: T) -> T {
     // We need to "use" the argument in some way LLVM can't introspect, and on
     // targets that support it we can typically leverage inline assembly to do
     // this. LLVM's intepretation of inline assembly is that it's, well, a black
     // box. This isn't the greatest implementation since it probably deoptimizes
     // more than we want, but it's so far good enough.
     #[cfg(not(any(
         target_arch = "asmjs",
         all(
             target_arch = "wasm32",
             target_os = "emscripten"
         )
     )))]
     unsafe {
         asm!("" : : "r"(&dummy));
         return dummy;
     }

     // Not all platforms support inline assembly so try to do something without
     // inline assembly which in theory still hinders at least some optimizations
     // on those targets. This is the "best effort" scenario.
     unsafe {
         let ret = crate::ptr::read_volatile(&dummy);
         crate::mem::forget(dummy);
         ret
     }
 }
	#![stable(feature = "core_hint", since = "1.27.0")]

	//! Hints to compiler that affects how code should be emitted or optimized.

	use crate::intrinsics;

	/// Informs the compiler that this point in the code is not reachable, enabling
	/// further optimizations.
	///
	/// # Safety
	///
	/// Reaching this function is completely undefined behavior (UB). In
	/// particular, the compiler assumes that all UB must never happen, and
	/// therefore will eliminate all branches that reach to a call to
	/// `unreachable_unchecked()`.
	///
	/// Like all instances of UB, if this assumption turns out to be wrong, i.e., the
	/// `unreachable_unchecked()` call is actually reachable among all possible
	/// control flow, the compiler will apply the wrong optimization strategy, and
	/// may sometimes even corrupt seemingly unrelated code, causing
	/// difficult-to-debug problems.
	///
	/// Use this function only when you can prove that the code will never call it.
	/// Otherwise, consider using the [`unreachable!`] macro, which does not allow
	/// optimizations but will panic when executed.
	///
	/// [`unreachable!`]: ../macro.unreachable.html
	///
	/// # Example
	///
	/// ```
	/// fn div_1(a: u32, b: u32) -> u32 {
	/// use std::hint::unreachable_unchecked;
	///
	/// // `b.saturating_add(1)` is always positive (not zero),
	/// // hence `checked_div` will never return `None`.
	/// // Therefore, the else branch is unreachable.
	/// a.checked_div(b.saturating_add(1))
	/// .unwrap_or_else(\|\| unsafe { unreachable_unchecked() })
	/// }
	///
	/// assert_eq!(div_1(7, 0), 7);
	/// assert_eq!(div_1(9, 1), 4);
	/// assert_eq!(div_1(11, std::u32::MAX), 0);
	/// ```
	#[inline]
	#[stable(feature = "unreachable", since = "1.27.0")]
	pub unsafe fn unreachable_unchecked() -> ! {
	intrinsics::unreachable()
	}

	/// Emits a machine instruction hinting to the processor that it is running in busy-wait
	/// spin-loop ("spin lock").
	///
	/// For a discussion of different locking strategies and their trade-offs, see
	/// [`core::sync::atomic::spin_loop_hint`].
	///
	/// Note: On platforms that do not support receiving spin-loop hints this function does not
	/// do anything at all.
	///
	/// [`core::sync::atomic::spin_loop_hint`]: ./sync/atomic/fn.spin_loop_hint.html
	#[inline]
	#[unstable(feature = "renamed_spin_loop", issue = "55002")]
	pub fn spin_loop() {
	#[cfg(
	all(
	any(target_arch = "x86", target_arch = "x86_64"),
	target_feature = "sse2"
	)
	)] {
	#[cfg(target_arch = "x86")] {
	unsafe { crate::arch::x86::_mm_pause() };
	}

	#[cfg(target_arch = "x86_64")] {
	unsafe { crate::arch::x86_64::_mm_pause() };
	}
	}

	#[cfg(
	any(
	target_arch = "aarch64",
	all(target_arch = "arm", target_feature = "v6")
	)
	)] {
	#[cfg(target_arch = "aarch64")] {
	unsafe { crate::arch::aarch64::__yield() };
	}
	#[cfg(target_arch = "arm")] {
	unsafe { crate::arch::arm::__yield() };
	}
	}
	}

	/// An identity function that __hints__ to the compiler to be maximally pessimistic about what
	/// `black_box` could do.
	///
	/// [`std::convert::identity`]: https://doc.rust-lang.org/core/convert/fn.identity.html
	///
	/// Unlike [`std::convert::identity`], a Rust compiler is encouraged to assume that `black_box` can
	/// use `x` in any possible valid way that Rust code is allowed to without introducing undefined
	/// behavior in the calling code. This property makes `black_box` useful for writing code in which
	/// certain optimizations are not desired, such as benchmarks.
	///
	/// Note however, that `black_box` is only (and can only be) provided on a "best-effort" basis. The
	/// extent to which it can block optimisations may vary depending upon the platform and code-gen
	/// backend used. Programs cannot rely on `black_box` for correctness in any way.
	#[inline]
	#[unstable(feature = "test", issue = "50297")]
	#[allow(unreachable_code)] // this makes #[cfg] a bit easier below.
	pub fn black_box<T>(dummy: T) -> T {
	// We need to "use" the argument in some way LLVM can't introspect, and on
	// targets that support it we can typically leverage inline assembly to do
	// this. LLVM's intepretation of inline assembly is that it's, well, a black
	// box. This isn't the greatest implementation since it probably deoptimizes
	// more than we want, but it's so far good enough.
	#[cfg(not(any(
	target_arch = "asmjs",
	all(
	target_arch = "wasm32",
	target_os = "emscripten"
	)
	)))]
	unsafe {
	asm!("" : : "r"(&dummy));
	return dummy;
	}

	// Not all platforms support inline assembly so try to do something without
	// inline assembly which in theory still hinders at least some optimizations
	// on those targets. This is the "best effort" scenario.
	unsafe {
	let ret = crate::ptr::read_volatile(&dummy);
	crate::mem::forget(dummy);
	ret
	}
	}