src/soft.rs - platform/external/rust/crates/ppv-lite86 - Git at Google

 //! Implement 256- and 512- bit in terms of 128-bit, for machines without native wide SIMD.

 use core::marker::PhantomData;
 use core::ops::*;
 use crate::types::*;
 use crate::{vec128_storage, vec256_storage, vec512_storage};

 #[derive(Copy, Clone, Default)]
 #[allow(non_camel_case_types)]
 pub struct x2<W, G>(pub [W; 2], PhantomData<G>);
 impl<W, G> x2<W, G> {
     #[inline(always)]
     pub fn new(xs: [W; 2]) -> Self {
         x2(xs, PhantomData)
     }
 }
 macro_rules! fwd_binop_x2 {
     ($trait:ident, $fn:ident) => {
         impl<W: $trait + Copy, G> $trait for x2<W, G> {
             type Output = x2<W::Output, G>;
             #[inline(always)]
             fn $fn(self, rhs: Self) -> Self::Output {
                 x2::new([self.0[0].$fn(rhs.0[0]), self.0[1].$fn(rhs.0[1])])
             }
         }
     };
 }
 macro_rules! fwd_binop_assign_x2 {
     ($trait:ident, $fn_assign:ident) => {
         impl<W: $trait + Copy, G> $trait for x2<W, G> {
             #[inline(always)]
             fn $fn_assign(&mut self, rhs: Self) {
                 (self.0[0]).$fn_assign(rhs.0[0]);
                 (self.0[1]).$fn_assign(rhs.0[1]);
             }
         }
     };
 }
 macro_rules! fwd_unop_x2 {
     ($fn:ident) => {
         #[inline(always)]
         fn $fn(self) -> Self {
             x2::new([self.0[0].$fn(), self.0[1].$fn()])
         }
     };
 }
 impl<W, G> RotateEachWord32 for x2<W, G>
 where
     W: Copy + RotateEachWord32,
 {
     fwd_unop_x2!(rotate_each_word_right7);
     fwd_unop_x2!(rotate_each_word_right8);
     fwd_unop_x2!(rotate_each_word_right11);
     fwd_unop_x2!(rotate_each_word_right12);
     fwd_unop_x2!(rotate_each_word_right16);
     fwd_unop_x2!(rotate_each_word_right20);
     fwd_unop_x2!(rotate_each_word_right24);
     fwd_unop_x2!(rotate_each_word_right25);
 }
 impl<W, G> RotateEachWord64 for x2<W, G>
 where
     W: Copy + RotateEachWord64,
 {
     fwd_unop_x2!(rotate_each_word_right32);
 }
 impl<W, G> RotateEachWord128 for x2<W, G> where W: RotateEachWord128 {}
 impl<W, G> BitOps0 for x2<W, G>
 where
     W: BitOps0,
     G: Copy,
 {
 }
 impl<W, G> BitOps32 for x2<W, G>
 where
     W: BitOps32 + BitOps0,
     G: Copy,
 {
 }
 impl<W, G> BitOps64 for x2<W, G>
 where
     W: BitOps64 + BitOps0,
     G: Copy,
 {
 }
 impl<W, G> BitOps128 for x2<W, G>
 where
     W: BitOps128 + BitOps0,
     G: Copy,
 {
 }
 fwd_binop_x2!(BitAnd, bitand);
 fwd_binop_x2!(BitOr, bitor);
 fwd_binop_x2!(BitXor, bitxor);
 fwd_binop_x2!(AndNot, andnot);
 fwd_binop_assign_x2!(BitAndAssign, bitand_assign);
 fwd_binop_assign_x2!(BitOrAssign, bitor_assign);
 fwd_binop_assign_x2!(BitXorAssign, bitxor_assign);
 impl<W, G> ArithOps for x2<W, G>
 where
     W: ArithOps,
     G: Copy,
 {
 }
 fwd_binop_x2!(Add, add);
 fwd_binop_assign_x2!(AddAssign, add_assign);
 impl<W: Not + Copy, G> Not for x2<W, G> {
     type Output = x2<W::Output, G>;
     #[inline(always)]
     fn not(self) -> Self::Output {
         x2::new([self.0[0].not(), self.0[1].not()])
     }
 }
 impl<W, G> UnsafeFrom<[W; 2]> for x2<W, G> {
     #[inline(always)]
     unsafe fn unsafe_from(xs: [W; 2]) -> Self {
         x2::new(xs)
     }
 }
 impl<W: Copy, G> Vec2<W> for x2<W, G> {
     #[inline(always)]
     fn extract(self, i: u32) -> W {
         self.0[i as usize]
     }
     #[inline(always)]
     fn insert(mut self, w: W, i: u32) -> Self {
         self.0[i as usize] = w;
         self
     }
 }
 impl<W: Copy + Store<vec128_storage>, G> Store<vec256_storage> for x2<W, G> {
     #[inline(always)]
     unsafe fn unpack(p: vec256_storage) -> Self {
         let p = p.split128();
         x2::new([W::unpack(p[0]), W::unpack(p[1])])
     }
 }
 impl<W, G> From<x2<W, G>> for vec256_storage
 where
     W: Copy,
     vec128_storage: From<W>,
 {
     #[inline(always)]
     fn from(x: x2<W, G>) -> Self {
         vec256_storage::new128([x.0[0].into(), x.0[1].into()])
     }
 }
 impl<W, G> Swap64 for x2<W, G>
 where
     W: Swap64 + Copy,
 {
     fwd_unop_x2!(swap1);
     fwd_unop_x2!(swap2);
     fwd_unop_x2!(swap4);
     fwd_unop_x2!(swap8);
     fwd_unop_x2!(swap16);
     fwd_unop_x2!(swap32);
     fwd_unop_x2!(swap64);
 }
 impl<W: Copy, G> MultiLane<[W; 2]> for x2<W, G> {
     #[inline(always)]
     fn to_lanes(self) -> [W; 2] {
         self.0
     }
     #[inline(always)]
     fn from_lanes(lanes: [W; 2]) -> Self {
         x2::new(lanes)
     }
 }
 impl<W: BSwap + Copy, G> BSwap for x2<W, G> {
     #[inline(always)]
     fn bswap(self) -> Self {
         x2::new([self.0[0].bswap(), self.0[1].bswap()])
     }
 }
 impl<W: StoreBytes + BSwap + Copy, G> StoreBytes for x2<W, G> {
     #[inline(always)]
     unsafe fn unsafe_read_le(input: &[u8]) -> Self {
         let input = input.split_at(16);
         x2::new([W::unsafe_read_le(input.0), W::unsafe_read_le(input.1)])
     }
     #[inline(always)]
     unsafe fn unsafe_read_be(input: &[u8]) -> Self {
         x2::unsafe_read_le(input).bswap()
     }
     #[inline(always)]
     fn write_le(self, out: &mut [u8]) {
         let out = out.split_at_mut(16);
         self.0[0].write_le(out.0);
         self.0[1].write_le(out.1);
     }
     #[inline(always)]
     fn write_be(self, out: &mut [u8]) {
         let out = out.split_at_mut(16);
         self.0[0].write_be(out.0);
         self.0[1].write_be(out.1);
     }
 }

 #[derive(Copy, Clone, Default)]
 #[allow(non_camel_case_types)]
 pub struct x4<W>(pub [W; 4]);
 impl<W> x4<W> {
     #[inline(always)]
     pub fn new(xs: [W; 4]) -> Self {
         x4(xs)
     }
 }
 macro_rules! fwd_binop_x4 {
     ($trait:ident, $fn:ident) => {
         impl<W: $trait + Copy> $trait for x4<W> {
             type Output = x4<W::Output>;
             #[inline(always)]
             fn $fn(self, rhs: Self) -> Self::Output {
                 x4([
                     self.0[0].$fn(rhs.0[0]),
                     self.0[1].$fn(rhs.0[1]),
                     self.0[2].$fn(rhs.0[2]),
                     self.0[3].$fn(rhs.0[3]),
                 ])
             }
         }
     };
 }
 macro_rules! fwd_binop_assign_x4 {
     ($trait:ident, $fn_assign:ident) => {
         impl<W: $trait + Copy> $trait for x4<W> {
             #[inline(always)]
             fn $fn_assign(&mut self, rhs: Self) {
                 self.0[0].$fn_assign(rhs.0[0]);
                 self.0[1].$fn_assign(rhs.0[1]);
                 self.0[2].$fn_assign(rhs.0[2]);
                 self.0[3].$fn_assign(rhs.0[3]);
             }
         }
     };
 }
 macro_rules! fwd_unop_x4 {
     ($fn:ident) => {
         #[inline(always)]
         fn $fn(self) -> Self {
             x4([self.0[0].$fn(), self.0[1].$fn(), self.0[2].$fn(), self.0[3].$fn()])
         }
     };
 }
 impl<W> RotateEachWord32 for x4<W>
 where
     W: Copy + RotateEachWord32,
 {
     fwd_unop_x4!(rotate_each_word_right7);
     fwd_unop_x4!(rotate_each_word_right8);
     fwd_unop_x4!(rotate_each_word_right11);
     fwd_unop_x4!(rotate_each_word_right12);
     fwd_unop_x4!(rotate_each_word_right16);
     fwd_unop_x4!(rotate_each_word_right20);
     fwd_unop_x4!(rotate_each_word_right24);
     fwd_unop_x4!(rotate_each_word_right25);
 }
 impl<W> RotateEachWord64 for x4<W>
 where
     W: Copy + RotateEachWord64,
 {
     fwd_unop_x4!(rotate_each_word_right32);
 }
 impl<W> RotateEachWord128 for x4<W> where W: RotateEachWord128 {}
 impl<W> BitOps0 for x4<W> where W: BitOps0 {}
 impl<W> BitOps32 for x4<W> where W: BitOps32 + BitOps0 {}
 impl<W> BitOps64 for x4<W> where W: BitOps64 + BitOps0 {}
 impl<W> BitOps128 for x4<W> where W: BitOps128 + BitOps0 {}
 fwd_binop_x4!(BitAnd, bitand);
 fwd_binop_x4!(BitOr, bitor);
 fwd_binop_x4!(BitXor, bitxor);
 fwd_binop_x4!(AndNot, andnot);
 fwd_binop_assign_x4!(BitAndAssign, bitand_assign);
 fwd_binop_assign_x4!(BitOrAssign, bitor_assign);
 fwd_binop_assign_x4!(BitXorAssign, bitxor_assign);
 impl<W> ArithOps for x4<W> where W: ArithOps {}
 fwd_binop_x4!(Add, add);
 fwd_binop_assign_x4!(AddAssign, add_assign);
 impl<W: Not + Copy> Not for x4<W> {
     type Output = x4<W::Output>;
     #[inline(always)]
     fn not(self) -> Self::Output {
         x4([
             self.0[0].not(),
             self.0[1].not(),
             self.0[2].not(),
             self.0[3].not(),
         ])
     }
 }
 impl<W> UnsafeFrom<[W; 4]> for x4<W> {
     #[inline(always)]
     unsafe fn unsafe_from(xs: [W; 4]) -> Self {
         x4(xs)
     }
 }
 impl<W: Copy> Vec4<W> for x4<W> {
     #[inline(always)]
     fn extract(self, i: u32) -> W {
         self.0[i as usize]
     }
     #[inline(always)]
     fn insert(mut self, w: W, i: u32) -> Self {
         self.0[i as usize] = w;
         self
     }
 }
 impl<W: Copy + Store<vec128_storage>> Store<vec512_storage> for x4<W> {
     #[inline(always)]
     unsafe fn unpack(p: vec512_storage) -> Self {
         let p = p.split128();
         x4([
             W::unpack(p[0]),
             W::unpack(p[1]),
             W::unpack(p[2]),
             W::unpack(p[3]),
         ])
     }
 }
 impl<W> From<x4<W>> for vec512_storage
 where
     W: Copy,
     vec128_storage: From<W>,
 {
     #[inline(always)]
     fn from(x: x4<W>) -> Self {
         vec512_storage::new128([x.0[0].into(), x.0[1].into(), x.0[2].into(), x.0[3].into()])
     }
 }
 impl<W> Swap64 for x4<W>
 where
     W: Swap64 + Copy,
 {
     fwd_unop_x4!(swap1);
     fwd_unop_x4!(swap2);
     fwd_unop_x4!(swap4);
     fwd_unop_x4!(swap8);
     fwd_unop_x4!(swap16);
     fwd_unop_x4!(swap32);
     fwd_unop_x4!(swap64);
 }
 impl<W: Copy> MultiLane<[W; 4]> for x4<W> {
     #[inline(always)]
     fn to_lanes(self) -> [W; 4] {
         self.0
     }
     #[inline(always)]
     fn from_lanes(lanes: [W; 4]) -> Self {
         x4(lanes)
     }
 }
 impl<W: BSwap + Copy> BSwap for x4<W> {
     #[inline(always)]
     fn bswap(self) -> Self {
         x4([
             self.0[0].bswap(),
             self.0[1].bswap(),
             self.0[2].bswap(),
             self.0[3].bswap(),
         ])
     }
 }
 impl<W: StoreBytes + BSwap + Copy> StoreBytes for x4<W> {
     #[inline(always)]
     unsafe fn unsafe_read_le(input: &[u8]) -> Self {
         x4([
             W::unsafe_read_le(&input[0..16]),
             W::unsafe_read_le(&input[16..32]),
             W::unsafe_read_le(&input[32..48]),
             W::unsafe_read_le(&input[48..64]),
         ])
     }
     #[inline(always)]
     unsafe fn unsafe_read_be(input: &[u8]) -> Self {
         x4::unsafe_read_le(input).bswap()
     }
     #[inline(always)]
     fn write_le(self, out: &mut [u8]) {
         self.0[0].write_le(&mut out[0..16]);
         self.0[1].write_le(&mut out[16..32]);
         self.0[2].write_le(&mut out[32..48]);
         self.0[3].write_le(&mut out[48..64]);
     }
     #[inline(always)]
     fn write_be(self, out: &mut [u8]) {
         self.0[0].write_be(&mut out[0..16]);
         self.0[1].write_be(&mut out[16..32]);
         self.0[2].write_be(&mut out[32..48]);
         self.0[3].write_be(&mut out[48..64]);
     }
 }
 impl<W: Copy + LaneWords4> LaneWords4 for x4<W> {
     #[inline(always)]
     fn shuffle_lane_words2301(self) -> Self {
         x4([
             self.0[0].shuffle_lane_words2301(),
             self.0[1].shuffle_lane_words2301(),
             self.0[2].shuffle_lane_words2301(),
             self.0[3].shuffle_lane_words2301(),
         ])
     }
     #[inline(always)]
     fn shuffle_lane_words1230(self) -> Self {
         x4([
             self.0[0].shuffle_lane_words1230(),
             self.0[1].shuffle_lane_words1230(),
             self.0[2].shuffle_lane_words1230(),
             self.0[3].shuffle_lane_words1230(),
         ])
     }
     #[inline(always)]
     fn shuffle_lane_words3012(self) -> Self {
         x4([
             self.0[0].shuffle_lane_words3012(),
             self.0[1].shuffle_lane_words3012(),
             self.0[2].shuffle_lane_words3012(),
             self.0[3].shuffle_lane_words3012(),
         ])
     }
 }
	//! Implement 256- and 512- bit in terms of 128-bit, for machines without native wide SIMD.

	use core::marker::PhantomData;
	use core::ops::*;
	use crate::types::*;
	use crate::{vec128_storage, vec256_storage, vec512_storage};

	#[derive(Copy, Clone, Default)]
	#[allow(non_camel_case_types)]
	pub struct x2<W, G>(pub [W; 2], PhantomData<G>);
	impl<W, G> x2<W, G> {
	#[inline(always)]
	pub fn new(xs: [W; 2]) -> Self {
	x2(xs, PhantomData)
	}
	}
	macro_rules! fwd_binop_x2 {
	($trait:ident, $fn:ident) => {
	impl<W: $trait + Copy, G> $trait for x2<W, G> {
	type Output = x2<W::Output, G>;
	#[inline(always)]
	fn $fn(self, rhs: Self) -> Self::Output {
	x2::new([self.0[0].$fn(rhs.0[0]), self.0[1].$fn(rhs.0[1])])
	}
	}
	};
	}
	macro_rules! fwd_binop_assign_x2 {
	($trait:ident, $fn_assign:ident) => {
	impl<W: $trait + Copy, G> $trait for x2<W, G> {
	#[inline(always)]
	fn $fn_assign(&mut self, rhs: Self) {
	(self.0[0]).$fn_assign(rhs.0[0]);
	(self.0[1]).$fn_assign(rhs.0[1]);
	}
	}
	};
	}
	macro_rules! fwd_unop_x2 {
	($fn:ident) => {
	#[inline(always)]
	fn $fn(self) -> Self {
	x2::new([self.0[0].$fn(), self.0[1].$fn()])
	}
	};
	}
	impl<W, G> RotateEachWord32 for x2<W, G>
	where
	W: Copy + RotateEachWord32,
	{
	fwd_unop_x2!(rotate_each_word_right7);
	fwd_unop_x2!(rotate_each_word_right8);
	fwd_unop_x2!(rotate_each_word_right11);
	fwd_unop_x2!(rotate_each_word_right12);
	fwd_unop_x2!(rotate_each_word_right16);
	fwd_unop_x2!(rotate_each_word_right20);
	fwd_unop_x2!(rotate_each_word_right24);
	fwd_unop_x2!(rotate_each_word_right25);
	}
	impl<W, G> RotateEachWord64 for x2<W, G>
	where
	W: Copy + RotateEachWord64,
	{
	fwd_unop_x2!(rotate_each_word_right32);
	}
	impl<W, G> RotateEachWord128 for x2<W, G> where W: RotateEachWord128 {}
	impl<W, G> BitOps0 for x2<W, G>
	where
	W: BitOps0,
	G: Copy,
	{
	}
	impl<W, G> BitOps32 for x2<W, G>
	where
	W: BitOps32 + BitOps0,
	G: Copy,
	{
	}
	impl<W, G> BitOps64 for x2<W, G>
	where
	W: BitOps64 + BitOps0,
	G: Copy,
	{
	}
	impl<W, G> BitOps128 for x2<W, G>
	where
	W: BitOps128 + BitOps0,
	G: Copy,
	{
	}
	fwd_binop_x2!(BitAnd, bitand);
	fwd_binop_x2!(BitOr, bitor);
	fwd_binop_x2!(BitXor, bitxor);
	fwd_binop_x2!(AndNot, andnot);
	fwd_binop_assign_x2!(BitAndAssign, bitand_assign);
	fwd_binop_assign_x2!(BitOrAssign, bitor_assign);
	fwd_binop_assign_x2!(BitXorAssign, bitxor_assign);
	impl<W, G> ArithOps for x2<W, G>
	where
	W: ArithOps,
	G: Copy,
	{
	}
	fwd_binop_x2!(Add, add);
	fwd_binop_assign_x2!(AddAssign, add_assign);
	impl<W: Not + Copy, G> Not for x2<W, G> {
	type Output = x2<W::Output, G>;
	#[inline(always)]
	fn not(self) -> Self::Output {
	x2::new([self.0[0].not(), self.0[1].not()])
	}
	}
	impl<W, G> UnsafeFrom<[W; 2]> for x2<W, G> {
	#[inline(always)]
	unsafe fn unsafe_from(xs: [W; 2]) -> Self {
	x2::new(xs)
	}
	}
	impl<W: Copy, G> Vec2<W> for x2<W, G> {
	#[inline(always)]
	fn extract(self, i: u32) -> W {
	self.0[i as usize]
	}
	#[inline(always)]
	fn insert(mut self, w: W, i: u32) -> Self {
	self.0[i as usize] = w;
	self
	}
	}
	impl<W: Copy + Store<vec128_storage>, G> Store<vec256_storage> for x2<W, G> {
	#[inline(always)]
	unsafe fn unpack(p: vec256_storage) -> Self {
	let p = p.split128();
	x2::new([W::unpack(p[0]), W::unpack(p[1])])
	}
	}
	impl<W, G> From<x2<W, G>> for vec256_storage
	where
	W: Copy,
	vec128_storage: From<W>,
	{
	#[inline(always)]
	fn from(x: x2<W, G>) -> Self {
	vec256_storage::new128([x.0[0].into(), x.0[1].into()])
	}
	}
	impl<W, G> Swap64 for x2<W, G>
	where
	W: Swap64 + Copy,
	{
	fwd_unop_x2!(swap1);
	fwd_unop_x2!(swap2);
	fwd_unop_x2!(swap4);
	fwd_unop_x2!(swap8);
	fwd_unop_x2!(swap16);
	fwd_unop_x2!(swap32);
	fwd_unop_x2!(swap64);
	}
	impl<W: Copy, G> MultiLane<[W; 2]> for x2<W, G> {
	#[inline(always)]
	fn to_lanes(self) -> [W; 2] {
	self.0
	}
	#[inline(always)]
	fn from_lanes(lanes: [W; 2]) -> Self {
	x2::new(lanes)
	}
	}
	impl<W: BSwap + Copy, G> BSwap for x2<W, G> {
	#[inline(always)]
	fn bswap(self) -> Self {
	x2::new([self.0[0].bswap(), self.0[1].bswap()])
	}
	}
	impl<W: StoreBytes + BSwap + Copy, G> StoreBytes for x2<W, G> {
	#[inline(always)]
	unsafe fn unsafe_read_le(input: &[u8]) -> Self {
	let input = input.split_at(16);
	x2::new([W::unsafe_read_le(input.0), W::unsafe_read_le(input.1)])
	}
	#[inline(always)]
	unsafe fn unsafe_read_be(input: &[u8]) -> Self {
	x2::unsafe_read_le(input).bswap()
	}
	#[inline(always)]
	fn write_le(self, out: &mut [u8]) {
	let out = out.split_at_mut(16);
	self.0[0].write_le(out.0);
	self.0[1].write_le(out.1);
	}
	#[inline(always)]
	fn write_be(self, out: &mut [u8]) {
	let out = out.split_at_mut(16);
	self.0[0].write_be(out.0);
	self.0[1].write_be(out.1);
	}
	}

	#[derive(Copy, Clone, Default)]
	#[allow(non_camel_case_types)]
	pub struct x4<W>(pub [W; 4]);
	impl<W> x4<W> {
	#[inline(always)]
	pub fn new(xs: [W; 4]) -> Self {
	x4(xs)
	}
	}
	macro_rules! fwd_binop_x4 {
	($trait:ident, $fn:ident) => {
	impl<W: $trait + Copy> $trait for x4<W> {
	type Output = x4<W::Output>;
	#[inline(always)]
	fn $fn(self, rhs: Self) -> Self::Output {
	x4([
	self.0[0].$fn(rhs.0[0]),
	self.0[1].$fn(rhs.0[1]),
	self.0[2].$fn(rhs.0[2]),
	self.0[3].$fn(rhs.0[3]),
	])
	}
	}
	};
	}
	macro_rules! fwd_binop_assign_x4 {
	($trait:ident, $fn_assign:ident) => {
	impl<W: $trait + Copy> $trait for x4<W> {
	#[inline(always)]
	fn $fn_assign(&mut self, rhs: Self) {
	self.0[0].$fn_assign(rhs.0[0]);
	self.0[1].$fn_assign(rhs.0[1]);
	self.0[2].$fn_assign(rhs.0[2]);
	self.0[3].$fn_assign(rhs.0[3]);
	}
	}
	};
	}
	macro_rules! fwd_unop_x4 {
	($fn:ident) => {
	#[inline(always)]
	fn $fn(self) -> Self {
	x4([self.0[0].$fn(), self.0[1].$fn(), self.0[2].$fn(), self.0[3].$fn()])
	}
	};
	}
	impl<W> RotateEachWord32 for x4<W>
	where
	W: Copy + RotateEachWord32,
	{
	fwd_unop_x4!(rotate_each_word_right7);
	fwd_unop_x4!(rotate_each_word_right8);
	fwd_unop_x4!(rotate_each_word_right11);
	fwd_unop_x4!(rotate_each_word_right12);
	fwd_unop_x4!(rotate_each_word_right16);
	fwd_unop_x4!(rotate_each_word_right20);
	fwd_unop_x4!(rotate_each_word_right24);
	fwd_unop_x4!(rotate_each_word_right25);
	}
	impl<W> RotateEachWord64 for x4<W>
	where
	W: Copy + RotateEachWord64,
	{
	fwd_unop_x4!(rotate_each_word_right32);
	}
	impl<W> RotateEachWord128 for x4<W> where W: RotateEachWord128 {}
	impl<W> BitOps0 for x4<W> where W: BitOps0 {}
	impl<W> BitOps32 for x4<W> where W: BitOps32 + BitOps0 {}
	impl<W> BitOps64 for x4<W> where W: BitOps64 + BitOps0 {}
	impl<W> BitOps128 for x4<W> where W: BitOps128 + BitOps0 {}
	fwd_binop_x4!(BitAnd, bitand);
	fwd_binop_x4!(BitOr, bitor);
	fwd_binop_x4!(BitXor, bitxor);
	fwd_binop_x4!(AndNot, andnot);
	fwd_binop_assign_x4!(BitAndAssign, bitand_assign);
	fwd_binop_assign_x4!(BitOrAssign, bitor_assign);
	fwd_binop_assign_x4!(BitXorAssign, bitxor_assign);
	impl<W> ArithOps for x4<W> where W: ArithOps {}
	fwd_binop_x4!(Add, add);
	fwd_binop_assign_x4!(AddAssign, add_assign);
	impl<W: Not + Copy> Not for x4<W> {
	type Output = x4<W::Output>;
	#[inline(always)]
	fn not(self) -> Self::Output {
	x4([
	self.0[0].not(),
	self.0[1].not(),
	self.0[2].not(),
	self.0[3].not(),
	])
	}
	}
	impl<W> UnsafeFrom<[W; 4]> for x4<W> {
	#[inline(always)]
	unsafe fn unsafe_from(xs: [W; 4]) -> Self {
	x4(xs)
	}
	}
	impl<W: Copy> Vec4<W> for x4<W> {
	#[inline(always)]
	fn extract(self, i: u32) -> W {
	self.0[i as usize]
	}
	#[inline(always)]
	fn insert(mut self, w: W, i: u32) -> Self {
	self.0[i as usize] = w;
	self
	}
	}
	impl<W: Copy + Store<vec128_storage>> Store<vec512_storage> for x4<W> {
	#[inline(always)]
	unsafe fn unpack(p: vec512_storage) -> Self {
	let p = p.split128();
	x4([
	W::unpack(p[0]),
	W::unpack(p[1]),
	W::unpack(p[2]),
	W::unpack(p[3]),
	])
	}
	}
	impl<W> From<x4<W>> for vec512_storage
	where
	W: Copy,
	vec128_storage: From<W>,
	{
	#[inline(always)]
	fn from(x: x4<W>) -> Self {
	vec512_storage::new128([x.0[0].into(), x.0[1].into(), x.0[2].into(), x.0[3].into()])
	}
	}
	impl<W> Swap64 for x4<W>
	where
	W: Swap64 + Copy,
	{
	fwd_unop_x4!(swap1);
	fwd_unop_x4!(swap2);
	fwd_unop_x4!(swap4);
	fwd_unop_x4!(swap8);
	fwd_unop_x4!(swap16);
	fwd_unop_x4!(swap32);
	fwd_unop_x4!(swap64);
	}
	impl<W: Copy> MultiLane<[W; 4]> for x4<W> {
	#[inline(always)]
	fn to_lanes(self) -> [W; 4] {
	self.0
	}
	#[inline(always)]
	fn from_lanes(lanes: [W; 4]) -> Self {
	x4(lanes)
	}
	}
	impl<W: BSwap + Copy> BSwap for x4<W> {
	#[inline(always)]
	fn bswap(self) -> Self {
	x4([
	self.0[0].bswap(),
	self.0[1].bswap(),
	self.0[2].bswap(),
	self.0[3].bswap(),
	])
	}
	}
	impl<W: StoreBytes + BSwap + Copy> StoreBytes for x4<W> {
	#[inline(always)]
	unsafe fn unsafe_read_le(input: &[u8]) -> Self {
	x4([
	W::unsafe_read_le(&input[0..16]),
	W::unsafe_read_le(&input[16..32]),
	W::unsafe_read_le(&input[32..48]),
	W::unsafe_read_le(&input[48..64]),
	])
	}
	#[inline(always)]
	unsafe fn unsafe_read_be(input: &[u8]) -> Self {
	x4::unsafe_read_le(input).bswap()
	}
	#[inline(always)]
	fn write_le(self, out: &mut [u8]) {
	self.0[0].write_le(&mut out[0..16]);
	self.0[1].write_le(&mut out[16..32]);
	self.0[2].write_le(&mut out[32..48]);
	self.0[3].write_le(&mut out[48..64]);
	}
	#[inline(always)]
	fn write_be(self, out: &mut [u8]) {
	self.0[0].write_be(&mut out[0..16]);
	self.0[1].write_be(&mut out[16..32]);
	self.0[2].write_be(&mut out[32..48]);
	self.0[3].write_be(&mut out[48..64]);
	}
	}
	impl<W: Copy + LaneWords4> LaneWords4 for x4<W> {
	#[inline(always)]
	fn shuffle_lane_words2301(self) -> Self {
	x4([
	self.0[0].shuffle_lane_words2301(),
	self.0[1].shuffle_lane_words2301(),
	self.0[2].shuffle_lane_words2301(),
	self.0[3].shuffle_lane_words2301(),
	])
	}
	#[inline(always)]
	fn shuffle_lane_words1230(self) -> Self {
	x4([
	self.0[0].shuffle_lane_words1230(),
	self.0[1].shuffle_lane_words1230(),
	self.0[2].shuffle_lane_words1230(),
	self.0[3].shuffle_lane_words1230(),
	])
	}
	#[inline(always)]
	fn shuffle_lane_words3012(self) -> Self {
	x4([
	self.0[0].shuffle_lane_words3012(),
	self.0[1].shuffle_lane_words3012(),
	self.0[2].shuffle_lane_words3012(),
	self.0[3].shuffle_lane_words3012(),
	])
	}
	}