vendor/portable-atomic/src/gen/utils.rs - toolchain/rustc - Git at Google

 // SPDX-License-Identifier: Apache-2.0 OR MIT
 // This file is @generated by target_spec.sh.
 // It is not intended for manual editing.

 #![allow(unused_macros)]

 // On AArch64, the base register of load/store/atomic instructions must be 64-bit.
 // Passing a 32-bit value to `in(reg)` on AArch64 results in the upper bits
 // having an undefined value, but to work correctly with ILP32 ABI, the upper
 // bits must be zero, which is handled here by casting to u64. Another way to
 // handle this is to pass it as a pointer and clear the upper bits inside asm,
 // but it is easier to overlook than cast, which can catch overlooks by
 // asm_sub_register lint.
 // See also https://github.com/ARM-software/abi-aa/blob/2023Q1/aapcs64/aapcs64.rst#57pointers
 //
 // Except for x86_64, which can use 32-bit registers in the destination operand
 // (on x86_64, we use the ptr_modifier macro to handle this), we need to do the
 // same for ILP32 ABI on other 64-bit architectures. (At least, as far as I can
 // see from the assembly generated by LLVM, this is also required for MIPS64 N32
 // ABI. I don't know about the RISC-V s64ilp32 ABI for which a patch was
 // recently submitted to the kernel, but in any case, this should be a safe
 // default for such ABIs).
 //
 // Known architectures that have such ABI are x86_64 (X32), aarch64 (ILP32),
 // mips64 (N32), and riscv64 (s64ilp32, not merged yet though). (As of
 // 2023-06-05, only the former two are supported by rustc.) However, we list all
 // known 64-bit architectures because similar ABIs may exist or future added for
 // other architectures.
 #[cfg(all(
     target_pointer_width = "32",
     any(
         target_arch = "aarch64",
         target_arch = "bpf",
         target_arch = "loongarch64",
         target_arch = "mips64",
         target_arch = "mips64r6",
         target_arch = "nvptx64",
         target_arch = "powerpc64",
         target_arch = "riscv64",
         target_arch = "s390x",
         target_arch = "sparc64",
         target_arch = "wasm64",
         target_arch = "x86_64",
     ),
 ))]
 macro_rules! ptr_reg {
     ($ptr:ident) => {{
         let _: *const _ = $ptr; // ensure $ptr is a pointer (*mut _ or *const _)
         #[cfg(not(portable_atomic_no_asm_maybe_uninit))]
         #[allow(clippy::ptr_as_ptr)]
         {
             // If we cast to u64 here, the provenance will be lost,
             // so we convert to MaybeUninit<u64> via zero extend helper.
             crate::utils::zero_extend64_ptr($ptr as *mut ())
         }
         #[cfg(portable_atomic_no_asm_maybe_uninit)]
         {
             // Use cast on old rustc because it does not support MaybeUninit
             // registers. This is still permissive-provenance compatible and
             // is sound.
             $ptr as u64
         }
     }};
 }
 #[cfg(not(all(
     target_pointer_width = "32",
     any(
         target_arch = "aarch64",
         target_arch = "bpf",
         target_arch = "loongarch64",
         target_arch = "mips64",
         target_arch = "mips64r6",
         target_arch = "nvptx64",
         target_arch = "powerpc64",
         target_arch = "riscv64",
         target_arch = "s390x",
         target_arch = "sparc64",
         target_arch = "wasm64",
         target_arch = "x86_64",
     ),
 )))]
 macro_rules! ptr_reg {
     ($ptr:ident) => {{
         let _: *const _ = $ptr; // ensure $ptr is a pointer (*mut _ or *const _)
         $ptr // cast is unnecessary here.
     }};
 }

 // Some 64-bit architectures have ABI with 32-bit pointer width (e.g., x86_64 X32 ABI,
 // AArch64 ILP32 ABI, MIPS64 N32 ABI). On those targets, AtomicU64 is available
 // and fast, so use it to implement normal sequence lock.
 //
 // See ptr_reg macro for the reason why all known 64-bit architectures are listed.
 #[cfg(feature = "fallback")]
 #[cfg(any(
     not(any(target_pointer_width = "16", target_pointer_width = "32")), // i.e., 64-bit or greater
     target_arch = "aarch64",
     target_arch = "bpf",
     target_arch = "loongarch64",
     target_arch = "mips64",
     target_arch = "mips64r6",
     target_arch = "nvptx64",
     target_arch = "powerpc64",
     target_arch = "riscv64",
     target_arch = "s390x",
     target_arch = "sparc64",
     target_arch = "wasm64",
     target_arch = "x86_64",
 ))]
 #[macro_use]
 mod fast_atomic_64_macros {
     macro_rules! cfg_has_fast_atomic_64 {
         ($($tt:tt)*) => {
             $($tt)*
         };
     }
     macro_rules! cfg_no_fast_atomic_64 {
         ($($tt:tt)*) => {};
     }
 }
 #[cfg(feature = "fallback")]
 #[cfg(not(any(
     not(any(target_pointer_width = "16", target_pointer_width = "32")), // i.e., 64-bit or greater
     target_arch = "aarch64",
     target_arch = "bpf",
     target_arch = "loongarch64",
     target_arch = "mips64",
     target_arch = "mips64r6",
     target_arch = "nvptx64",
     target_arch = "powerpc64",
     target_arch = "riscv64",
     target_arch = "s390x",
     target_arch = "sparc64",
     target_arch = "wasm64",
     target_arch = "x86_64",
 )))]
 #[macro_use]
 mod fast_atomic_64_macros {
     macro_rules! cfg_has_fast_atomic_64 {
         ($($tt:tt)*) => {};
     }
     macro_rules! cfg_no_fast_atomic_64 {
         ($($tt:tt)*) => {
             $($tt)*
         };
     }
 }
	// SPDX-License-Identifier: Apache-2.0 OR MIT
	// This file is @generated by target_spec.sh.
	// It is not intended for manual editing.

	#![allow(unused_macros)]

	// On AArch64, the base register of load/store/atomic instructions must be 64-bit.
	// Passing a 32-bit value to `in(reg)` on AArch64 results in the upper bits
	// having an undefined value, but to work correctly with ILP32 ABI, the upper
	// bits must be zero, which is handled here by casting to u64. Another way to
	// handle this is to pass it as a pointer and clear the upper bits inside asm,
	// but it is easier to overlook than cast, which can catch overlooks by
	// asm_sub_register lint.
	// See also https://github.com/ARM-software/abi-aa/blob/2023Q1/aapcs64/aapcs64.rst#57pointers
	//
	// Except for x86_64, which can use 32-bit registers in the destination operand
	// (on x86_64, we use the ptr_modifier macro to handle this), we need to do the
	// same for ILP32 ABI on other 64-bit architectures. (At least, as far as I can
	// see from the assembly generated by LLVM, this is also required for MIPS64 N32
	// ABI. I don't know about the RISC-V s64ilp32 ABI for which a patch was
	// recently submitted to the kernel, but in any case, this should be a safe
	// default for such ABIs).
	//
	// Known architectures that have such ABI are x86_64 (X32), aarch64 (ILP32),
	// mips64 (N32), and riscv64 (s64ilp32, not merged yet though). (As of
	// 2023-06-05, only the former two are supported by rustc.) However, we list all
	// known 64-bit architectures because similar ABIs may exist or future added for
	// other architectures.
	#[cfg(all(
	target_pointer_width = "32",
	any(
	target_arch = "aarch64",
	target_arch = "bpf",
	target_arch = "loongarch64",
	target_arch = "mips64",
	target_arch = "mips64r6",
	target_arch = "nvptx64",
	target_arch = "powerpc64",
	target_arch = "riscv64",
	target_arch = "s390x",
	target_arch = "sparc64",
	target_arch = "wasm64",
	target_arch = "x86_64",
	),
	))]
	macro_rules! ptr_reg {
	($ptr:ident) => {{
	let _: const _ = $ptr; // ensure $ptr is a pointer (mut _ or *const _)
	#[cfg(not(portable_atomic_no_asm_maybe_uninit))]
	#[allow(clippy::ptr_as_ptr)]
	{
	// If we cast to u64 here, the provenance will be lost,
	// so we convert to MaybeUninit<u64> via zero extend helper.
	crate::utils::zero_extend64_ptr($ptr as *mut ())
	}
	#[cfg(portable_atomic_no_asm_maybe_uninit)]
	{
	// Use cast on old rustc because it does not support MaybeUninit
	// registers. This is still permissive-provenance compatible and
	// is sound.
	$ptr as u64
	}
	}};
	}
	#[cfg(not(all(
	target_pointer_width = "32",
	any(
	target_arch = "aarch64",
	target_arch = "bpf",
	target_arch = "loongarch64",
	target_arch = "mips64",
	target_arch = "mips64r6",
	target_arch = "nvptx64",
	target_arch = "powerpc64",
	target_arch = "riscv64",
	target_arch = "s390x",
	target_arch = "sparc64",
	target_arch = "wasm64",
	target_arch = "x86_64",
	),
	)))]
	macro_rules! ptr_reg {
	($ptr:ident) => {{
	let _: const _ = $ptr; // ensure $ptr is a pointer (mut _ or *const _)
	$ptr // cast is unnecessary here.
	}};
	}

	// Some 64-bit architectures have ABI with 32-bit pointer width (e.g., x86_64 X32 ABI,
	// AArch64 ILP32 ABI, MIPS64 N32 ABI). On those targets, AtomicU64 is available
	// and fast, so use it to implement normal sequence lock.
	//
	// See ptr_reg macro for the reason why all known 64-bit architectures are listed.
	#[cfg(feature = "fallback")]
	#[cfg(any(
	not(any(target_pointer_width = "16", target_pointer_width = "32")), // i.e., 64-bit or greater
	target_arch = "aarch64",
	target_arch = "bpf",
	target_arch = "loongarch64",
	target_arch = "mips64",
	target_arch = "mips64r6",
	target_arch = "nvptx64",
	target_arch = "powerpc64",
	target_arch = "riscv64",
	target_arch = "s390x",
	target_arch = "sparc64",
	target_arch = "wasm64",
	target_arch = "x86_64",
	))]
	#[macro_use]
	mod fast_atomic_64_macros {
	macro_rules! cfg_has_fast_atomic_64 {
	($($tt:tt)*) => {
	$($tt)*
	};
	}
	macro_rules! cfg_no_fast_atomic_64 {
	($($tt:tt)*) => {};
	}
	}
	#[cfg(feature = "fallback")]
	#[cfg(not(any(
	not(any(target_pointer_width = "16", target_pointer_width = "32")), // i.e., 64-bit or greater
	target_arch = "aarch64",
	target_arch = "bpf",
	target_arch = "loongarch64",
	target_arch = "mips64",
	target_arch = "mips64r6",
	target_arch = "nvptx64",
	target_arch = "powerpc64",
	target_arch = "riscv64",
	target_arch = "s390x",
	target_arch = "sparc64",
	target_arch = "wasm64",
	target_arch = "x86_64",
	)))]
	#[macro_use]
	mod fast_atomic_64_macros {
	macro_rules! cfg_has_fast_atomic_64 {
	($($tt:tt)*) => {};
	}
	macro_rules! cfg_no_fast_atomic_64 {
	($($tt:tt)*) => {
	$($tt)*
	};
	}
	}