x86_64/usr/lib/rustlib/src/rust/library/stdarch/crates/core_arch/src/x86/sha.rs - manifest_repos/toolchain - Git at Google

 use crate::{
     core_arch::{simd::*, x86::*},
     mem::transmute,
 };

 #[allow(improper_ctypes)]
 extern "C" {
     #[link_name = "llvm.x86.sha1msg1"]
     fn sha1msg1(a: i32x4, b: i32x4) -> i32x4;
     #[link_name = "llvm.x86.sha1msg2"]
     fn sha1msg2(a: i32x4, b: i32x4) -> i32x4;
     #[link_name = "llvm.x86.sha1nexte"]
     fn sha1nexte(a: i32x4, b: i32x4) -> i32x4;
     #[link_name = "llvm.x86.sha1rnds4"]
     fn sha1rnds4(a: i32x4, b: i32x4, c: i8) -> i32x4;
     #[link_name = "llvm.x86.sha256msg1"]
     fn sha256msg1(a: i32x4, b: i32x4) -> i32x4;
     #[link_name = "llvm.x86.sha256msg2"]
     fn sha256msg2(a: i32x4, b: i32x4) -> i32x4;
     #[link_name = "llvm.x86.sha256rnds2"]
     fn sha256rnds2(a: i32x4, b: i32x4, k: i32x4) -> i32x4;
 }

 #[cfg(test)]
 use stdarch_test::assert_instr;

 /// Performs an intermediate calculation for the next four SHA1 message values
 /// (unsigned 32-bit integers) using previous message values from `a` and `b`,
 /// and returning the result.
 ///
 /// [Intel's documentation](https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=_mm_sha1msg1_epu32)
 #[inline]
 #[target_feature(enable = "sha")]
 #[cfg_attr(test, assert_instr(sha1msg1))]
 #[stable(feature = "simd_x86", since = "1.27.0")]
 pub unsafe fn _mm_sha1msg1_epu32(a: __m128i, b: __m128i) -> __m128i {
     transmute(sha1msg1(a.as_i32x4(), b.as_i32x4()))
 }

 /// Performs the final calculation for the next four SHA1 message values
 /// (unsigned 32-bit integers) using the intermediate result in `a` and the
 /// previous message values in `b`, and returns the result.
 ///
 /// [Intel's documentation](https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=_mm_sha1msg2_epu32)
 #[inline]
 #[target_feature(enable = "sha")]
 #[cfg_attr(test, assert_instr(sha1msg2))]
 #[stable(feature = "simd_x86", since = "1.27.0")]
 pub unsafe fn _mm_sha1msg2_epu32(a: __m128i, b: __m128i) -> __m128i {
     transmute(sha1msg2(a.as_i32x4(), b.as_i32x4()))
 }

 /// Calculate SHA1 state variable E after four rounds of operation from the
 /// current SHA1 state variable `a`, add that value to the scheduled values
 /// (unsigned 32-bit integers) in `b`, and returns the result.
 ///
 /// [Intel's documentation](https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=_mm_sha1nexte_epu32)
 #[inline]
 #[target_feature(enable = "sha")]
 #[cfg_attr(test, assert_instr(sha1nexte))]
 #[stable(feature = "simd_x86", since = "1.27.0")]
 pub unsafe fn _mm_sha1nexte_epu32(a: __m128i, b: __m128i) -> __m128i {
     transmute(sha1nexte(a.as_i32x4(), b.as_i32x4()))
 }

 /// Performs four rounds of SHA1 operation using an initial SHA1 state (A,B,C,D)
 /// from `a` and some pre-computed sum of the next 4 round message values
 /// (unsigned 32-bit integers), and state variable E from `b`, and return the
 /// updated SHA1 state (A,B,C,D). `FUNC` contains the logic functions and round
 /// constants.
 ///
 /// [Intel's documentation](https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=_mm_sha1rnds4_epu32)
 #[inline]
 #[target_feature(enable = "sha")]
 #[cfg_attr(test, assert_instr(sha1rnds4, FUNC = 0))]
 #[rustc_legacy_const_generics(2)]
 #[stable(feature = "simd_x86", since = "1.27.0")]
 pub unsafe fn _mm_sha1rnds4_epu32<const FUNC: i32>(a: __m128i, b: __m128i) -> __m128i {
     static_assert_imm2!(FUNC);
     transmute(sha1rnds4(a.as_i32x4(), b.as_i32x4(), FUNC as i8))
 }

 /// Performs an intermediate calculation for the next four SHA256 message values
 /// (unsigned 32-bit integers) using previous message values from `a` and `b`,
 /// and return the result.
 ///
 /// [Intel's documentation](https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=_mm_sha256msg1_epu32)
 #[inline]
 #[target_feature(enable = "sha")]
 #[cfg_attr(test, assert_instr(sha256msg1))]
 #[stable(feature = "simd_x86", since = "1.27.0")]
 pub unsafe fn _mm_sha256msg1_epu32(a: __m128i, b: __m128i) -> __m128i {
     transmute(sha256msg1(a.as_i32x4(), b.as_i32x4()))
 }

 /// Performs the final calculation for the next four SHA256 message values
 /// (unsigned 32-bit integers) using previous message values from `a` and `b`,
 /// and return the result.
 ///
 /// [Intel's documentation](https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=_mm_sha256msg2_epu32)
 #[inline]
 #[target_feature(enable = "sha")]
 #[cfg_attr(test, assert_instr(sha256msg2))]
 #[stable(feature = "simd_x86", since = "1.27.0")]
 pub unsafe fn _mm_sha256msg2_epu32(a: __m128i, b: __m128i) -> __m128i {
     transmute(sha256msg2(a.as_i32x4(), b.as_i32x4()))
 }

 /// Performs 2 rounds of SHA256 operation using an initial SHA256 state
 /// (C,D,G,H) from `a`, an initial SHA256 state (A,B,E,F) from `b`, and a
 /// pre-computed sum of the next 2 round message values (unsigned 32-bit
 /// integers) and the corresponding round constants from `k`, and store the
 /// updated SHA256 state (A,B,E,F) in dst.
 ///
 /// [Intel's documentation](https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=_mm_sha256rnds2_epu32)
 #[inline]
 #[target_feature(enable = "sha")]
 #[cfg_attr(test, assert_instr(sha256rnds2))]
 #[stable(feature = "simd_x86", since = "1.27.0")]
 pub unsafe fn _mm_sha256rnds2_epu32(a: __m128i, b: __m128i, k: __m128i) -> __m128i {
     transmute(sha256rnds2(a.as_i32x4(), b.as_i32x4(), k.as_i32x4()))
 }

 #[cfg(test)]
 mod tests {
     use std::{
         f32,
         f64::{self, NAN},
         i32,
         mem::{self, transmute},
     };

     use crate::{
         core_arch::{simd::*, x86::*},
         hint::black_box,
     };
     use stdarch_test::simd_test;

     #[simd_test(enable = "sha")]
     #[allow(overflowing_literals)]
     unsafe fn test_mm_sha1msg1_epu32() {
         let a = _mm_set_epi64x(0xe9b5dba5b5c0fbcf, 0x71374491428a2f98);
         let b = _mm_set_epi64x(0xab1c5ed5923f82a4, 0x59f111f13956c25b);
         let expected = _mm_set_epi64x(0x98829f34f74ad457, 0xda2b1a44d0b5ad3c);
         let r = _mm_sha1msg1_epu32(a, b);
         assert_eq_m128i(r, expected);
     }

     #[simd_test(enable = "sha")]
     #[allow(overflowing_literals)]
     unsafe fn test_mm_sha1msg2_epu32() {
         let a = _mm_set_epi64x(0xe9b5dba5b5c0fbcf, 0x71374491428a2f98);
         let b = _mm_set_epi64x(0xab1c5ed5923f82a4, 0x59f111f13956c25b);
         let expected = _mm_set_epi64x(0xf714b202d863d47d, 0x90c30d946b3d3b35);
         let r = _mm_sha1msg2_epu32(a, b);
         assert_eq_m128i(r, expected);
     }

     #[simd_test(enable = "sha")]
     #[allow(overflowing_literals)]
     unsafe fn test_mm_sha1nexte_epu32() {
         let a = _mm_set_epi64x(0xe9b5dba5b5c0fbcf, 0x71374491428a2f98);
         let b = _mm_set_epi64x(0xab1c5ed5923f82a4, 0x59f111f13956c25b);
         let expected = _mm_set_epi64x(0x2589d5be923f82a4, 0x59f111f13956c25b);
         let r = _mm_sha1nexte_epu32(a, b);
         assert_eq_m128i(r, expected);
     }

     #[simd_test(enable = "sha")]
     #[allow(overflowing_literals)]
     unsafe fn test_mm_sha1rnds4_epu32() {
         let a = _mm_set_epi64x(0xe9b5dba5b5c0fbcf, 0x71374491428a2f98);
         let b = _mm_set_epi64x(0xab1c5ed5923f82a4, 0x59f111f13956c25b);
         let expected = _mm_set_epi64x(0x32b13cd8322f5268, 0xc54420862bd9246f);
         let r = _mm_sha1rnds4_epu32::<0>(a, b);
         assert_eq_m128i(r, expected);

         let expected = _mm_set_epi64x(0x6d4c43e56a3c25d9, 0xa7e00fb775cbd3fe);
         let r = _mm_sha1rnds4_epu32::<1>(a, b);
         assert_eq_m128i(r, expected);

         let expected = _mm_set_epi64x(0xb304e383c01222f4, 0x66f6b3b1f89d8001);
         let r = _mm_sha1rnds4_epu32::<2>(a, b);
         assert_eq_m128i(r, expected);

         let expected = _mm_set_epi64x(0x8189b758bfabfa79, 0xdb08f6e78cae098b);
         let r = _mm_sha1rnds4_epu32::<3>(a, b);
         assert_eq_m128i(r, expected);
     }

     #[simd_test(enable = "sha")]
     #[allow(overflowing_literals)]
     unsafe fn test_mm_sha256msg1_epu32() {
         let a = _mm_set_epi64x(0xe9b5dba5b5c0fbcf, 0x71374491428a2f98);
         let b = _mm_set_epi64x(0xab1c5ed5923f82a4, 0x59f111f13956c25b);
         let expected = _mm_set_epi64x(0xeb84973fd5cda67d, 0x2857b88f406b09ee);
         let r = _mm_sha256msg1_epu32(a, b);
         assert_eq_m128i(r, expected);
     }

     #[simd_test(enable = "sha")]
     #[allow(overflowing_literals)]
     unsafe fn test_mm_sha256msg2_epu32() {
         let a = _mm_set_epi64x(0xe9b5dba5b5c0fbcf, 0x71374491428a2f98);
         let b = _mm_set_epi64x(0xab1c5ed5923f82a4, 0x59f111f13956c25b);
         let expected = _mm_set_epi64x(0xb58777ce887fd851, 0x15d1ec8b73ac8450);
         let r = _mm_sha256msg2_epu32(a, b);
         assert_eq_m128i(r, expected);
     }

     #[simd_test(enable = "sha")]
     #[allow(overflowing_literals)]
     unsafe fn test_mm_sha256rnds2_epu32() {
         let a = _mm_set_epi64x(0xe9b5dba5b5c0fbcf, 0x71374491428a2f98);
         let b = _mm_set_epi64x(0xab1c5ed5923f82a4, 0x59f111f13956c25b);
         let k = _mm_set_epi64x(0, 0x12835b01d807aa98);
         let expected = _mm_set_epi64x(0xd3063037effb15ea, 0x187ee3db0d6d1d19);
         let r = _mm_sha256rnds2_epu32(a, b, k);
         assert_eq_m128i(r, expected);
     }
 }
	use crate::{
	core_arch::{simd::, x86::},
	mem::transmute,
	};

	#[allow(improper_ctypes)]
	extern "C" {
	#[link_name = "llvm.x86.sha1msg1"]
	fn sha1msg1(a: i32x4, b: i32x4) -> i32x4;
	#[link_name = "llvm.x86.sha1msg2"]
	fn sha1msg2(a: i32x4, b: i32x4) -> i32x4;
	#[link_name = "llvm.x86.sha1nexte"]
	fn sha1nexte(a: i32x4, b: i32x4) -> i32x4;
	#[link_name = "llvm.x86.sha1rnds4"]
	fn sha1rnds4(a: i32x4, b: i32x4, c: i8) -> i32x4;
	#[link_name = "llvm.x86.sha256msg1"]
	fn sha256msg1(a: i32x4, b: i32x4) -> i32x4;
	#[link_name = "llvm.x86.sha256msg2"]
	fn sha256msg2(a: i32x4, b: i32x4) -> i32x4;
	#[link_name = "llvm.x86.sha256rnds2"]
	fn sha256rnds2(a: i32x4, b: i32x4, k: i32x4) -> i32x4;
	}

	#[cfg(test)]
	use stdarch_test::assert_instr;

	/// Performs an intermediate calculation for the next four SHA1 message values
	/// (unsigned 32-bit integers) using previous message values from `a` and `b`,
	/// and returning the result.
	///
	/// [Intel's documentation](https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=_mm_sha1msg1_epu32)
	#[inline]
	#[target_feature(enable = "sha")]
	#[cfg_attr(test, assert_instr(sha1msg1))]
	#[stable(feature = "simd_x86", since = "1.27.0")]
	pub unsafe fn _mm_sha1msg1_epu32(a: __m128i, b: __m128i) -> __m128i {
	transmute(sha1msg1(a.as_i32x4(), b.as_i32x4()))
	}

	/// Performs the final calculation for the next four SHA1 message values
	/// (unsigned 32-bit integers) using the intermediate result in `a` and the
	/// previous message values in `b`, and returns the result.
	///
	/// [Intel's documentation](https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=_mm_sha1msg2_epu32)
	#[inline]
	#[target_feature(enable = "sha")]
	#[cfg_attr(test, assert_instr(sha1msg2))]
	#[stable(feature = "simd_x86", since = "1.27.0")]
	pub unsafe fn _mm_sha1msg2_epu32(a: __m128i, b: __m128i) -> __m128i {
	transmute(sha1msg2(a.as_i32x4(), b.as_i32x4()))
	}

	/// Calculate SHA1 state variable E after four rounds of operation from the
	/// current SHA1 state variable `a`, add that value to the scheduled values
	/// (unsigned 32-bit integers) in `b`, and returns the result.
	///
	/// [Intel's documentation](https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=_mm_sha1nexte_epu32)
	#[inline]
	#[target_feature(enable = "sha")]
	#[cfg_attr(test, assert_instr(sha1nexte))]
	#[stable(feature = "simd_x86", since = "1.27.0")]
	pub unsafe fn _mm_sha1nexte_epu32(a: __m128i, b: __m128i) -> __m128i {
	transmute(sha1nexte(a.as_i32x4(), b.as_i32x4()))
	}

	/// Performs four rounds of SHA1 operation using an initial SHA1 state (A,B,C,D)
	/// from `a` and some pre-computed sum of the next 4 round message values
	/// (unsigned 32-bit integers), and state variable E from `b`, and return the
	/// updated SHA1 state (A,B,C,D). `FUNC` contains the logic functions and round
	/// constants.
	///
	/// [Intel's documentation](https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=_mm_sha1rnds4_epu32)
	#[inline]
	#[target_feature(enable = "sha")]
	#[cfg_attr(test, assert_instr(sha1rnds4, FUNC = 0))]
	#[rustc_legacy_const_generics(2)]
	#[stable(feature = "simd_x86", since = "1.27.0")]
	pub unsafe fn _mm_sha1rnds4_epu32<const FUNC: i32>(a: __m128i, b: __m128i) -> __m128i {
	static_assert_imm2!(FUNC);
	transmute(sha1rnds4(a.as_i32x4(), b.as_i32x4(), FUNC as i8))
	}

	/// Performs an intermediate calculation for the next four SHA256 message values
	/// (unsigned 32-bit integers) using previous message values from `a` and `b`,
	/// and return the result.
	///
	/// [Intel's documentation](https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=_mm_sha256msg1_epu32)
	#[inline]
	#[target_feature(enable = "sha")]
	#[cfg_attr(test, assert_instr(sha256msg1))]
	#[stable(feature = "simd_x86", since = "1.27.0")]
	pub unsafe fn _mm_sha256msg1_epu32(a: __m128i, b: __m128i) -> __m128i {
	transmute(sha256msg1(a.as_i32x4(), b.as_i32x4()))
	}

	/// Performs the final calculation for the next four SHA256 message values
	/// (unsigned 32-bit integers) using previous message values from `a` and `b`,
	/// and return the result.
	///
	/// [Intel's documentation](https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=_mm_sha256msg2_epu32)
	#[inline]
	#[target_feature(enable = "sha")]
	#[cfg_attr(test, assert_instr(sha256msg2))]
	#[stable(feature = "simd_x86", since = "1.27.0")]
	pub unsafe fn _mm_sha256msg2_epu32(a: __m128i, b: __m128i) -> __m128i {
	transmute(sha256msg2(a.as_i32x4(), b.as_i32x4()))
	}

	/// Performs 2 rounds of SHA256 operation using an initial SHA256 state
	/// (C,D,G,H) from `a`, an initial SHA256 state (A,B,E,F) from `b`, and a
	/// pre-computed sum of the next 2 round message values (unsigned 32-bit
	/// integers) and the corresponding round constants from `k`, and store the
	/// updated SHA256 state (A,B,E,F) in dst.
	///
	/// [Intel's documentation](https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=_mm_sha256rnds2_epu32)
	#[inline]
	#[target_feature(enable = "sha")]
	#[cfg_attr(test, assert_instr(sha256rnds2))]
	#[stable(feature = "simd_x86", since = "1.27.0")]
	pub unsafe fn _mm_sha256rnds2_epu32(a: __m128i, b: __m128i, k: __m128i) -> __m128i {
	transmute(sha256rnds2(a.as_i32x4(), b.as_i32x4(), k.as_i32x4()))
	}

	#[cfg(test)]
	mod tests {
	use std::{
	f32,
	f64::{self, NAN},
	i32,
	mem::{self, transmute},
	};

	use crate::{
	core_arch::{simd::, x86::},
	hint::black_box,
	};
	use stdarch_test::simd_test;

	#[simd_test(enable = "sha")]
	#[allow(overflowing_literals)]
	unsafe fn test_mm_sha1msg1_epu32() {
	let a = _mm_set_epi64x(0xe9b5dba5b5c0fbcf, 0x71374491428a2f98);
	let b = _mm_set_epi64x(0xab1c5ed5923f82a4, 0x59f111f13956c25b);
	let expected = _mm_set_epi64x(0x98829f34f74ad457, 0xda2b1a44d0b5ad3c);
	let r = _mm_sha1msg1_epu32(a, b);
	assert_eq_m128i(r, expected);
	}

	#[simd_test(enable = "sha")]
	#[allow(overflowing_literals)]
	unsafe fn test_mm_sha1msg2_epu32() {
	let a = _mm_set_epi64x(0xe9b5dba5b5c0fbcf, 0x71374491428a2f98);
	let b = _mm_set_epi64x(0xab1c5ed5923f82a4, 0x59f111f13956c25b);
	let expected = _mm_set_epi64x(0xf714b202d863d47d, 0x90c30d946b3d3b35);
	let r = _mm_sha1msg2_epu32(a, b);
	assert_eq_m128i(r, expected);
	}

	#[simd_test(enable = "sha")]
	#[allow(overflowing_literals)]
	unsafe fn test_mm_sha1nexte_epu32() {
	let a = _mm_set_epi64x(0xe9b5dba5b5c0fbcf, 0x71374491428a2f98);
	let b = _mm_set_epi64x(0xab1c5ed5923f82a4, 0x59f111f13956c25b);
	let expected = _mm_set_epi64x(0x2589d5be923f82a4, 0x59f111f13956c25b);
	let r = _mm_sha1nexte_epu32(a, b);
	assert_eq_m128i(r, expected);
	}

	#[simd_test(enable = "sha")]
	#[allow(overflowing_literals)]
	unsafe fn test_mm_sha1rnds4_epu32() {
	let a = _mm_set_epi64x(0xe9b5dba5b5c0fbcf, 0x71374491428a2f98);
	let b = _mm_set_epi64x(0xab1c5ed5923f82a4, 0x59f111f13956c25b);
	let expected = _mm_set_epi64x(0x32b13cd8322f5268, 0xc54420862bd9246f);
	let r = _mm_sha1rnds4_epu32::<0>(a, b);
	assert_eq_m128i(r, expected);

	let expected = _mm_set_epi64x(0x6d4c43e56a3c25d9, 0xa7e00fb775cbd3fe);
	let r = _mm_sha1rnds4_epu32::<1>(a, b);
	assert_eq_m128i(r, expected);

	let expected = _mm_set_epi64x(0xb304e383c01222f4, 0x66f6b3b1f89d8001);
	let r = _mm_sha1rnds4_epu32::<2>(a, b);
	assert_eq_m128i(r, expected);

	let expected = _mm_set_epi64x(0x8189b758bfabfa79, 0xdb08f6e78cae098b);
	let r = _mm_sha1rnds4_epu32::<3>(a, b);
	assert_eq_m128i(r, expected);
	}

	#[simd_test(enable = "sha")]
	#[allow(overflowing_literals)]
	unsafe fn test_mm_sha256msg1_epu32() {
	let a = _mm_set_epi64x(0xe9b5dba5b5c0fbcf, 0x71374491428a2f98);
	let b = _mm_set_epi64x(0xab1c5ed5923f82a4, 0x59f111f13956c25b);
	let expected = _mm_set_epi64x(0xeb84973fd5cda67d, 0x2857b88f406b09ee);
	let r = _mm_sha256msg1_epu32(a, b);
	assert_eq_m128i(r, expected);
	}

	#[simd_test(enable = "sha")]
	#[allow(overflowing_literals)]
	unsafe fn test_mm_sha256msg2_epu32() {
	let a = _mm_set_epi64x(0xe9b5dba5b5c0fbcf, 0x71374491428a2f98);
	let b = _mm_set_epi64x(0xab1c5ed5923f82a4, 0x59f111f13956c25b);
	let expected = _mm_set_epi64x(0xb58777ce887fd851, 0x15d1ec8b73ac8450);
	let r = _mm_sha256msg2_epu32(a, b);
	assert_eq_m128i(r, expected);
	}

	#[simd_test(enable = "sha")]
	#[allow(overflowing_literals)]
	unsafe fn test_mm_sha256rnds2_epu32() {
	let a = _mm_set_epi64x(0xe9b5dba5b5c0fbcf, 0x71374491428a2f98);
	let b = _mm_set_epi64x(0xab1c5ed5923f82a4, 0x59f111f13956c25b);
	let k = _mm_set_epi64x(0, 0x12835b01d807aa98);
	let expected = _mm_set_epi64x(0xd3063037effb15ea, 0x187ee3db0d6d1d19);
	let r = _mm_sha256rnds2_epu32(a, b, k);
	assert_eq_m128i(r, expected);
	}
	}