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For MIRI, cfg out the swap logic from 94212
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@ -708,7 +708,10 @@ pub const fn swap<T>(x: &mut T, y: &mut T) {
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// understanding `mem::replace`, `Option::take`, etc. - a better overall
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// solution might be to make `ptr::swap_nonoverlapping` into an intrinsic, which
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// a backend can choose to implement using the block optimization, or not.
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#[cfg(not(target_arch = "spirv"))]
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// NOTE(scottmcm) MIRI is disabled here as reading in smaller units is a
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// pessimization for it. Also, if the type contains any unaligned pointers,
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// copying those over multiple reads is difficult to support.
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#[cfg(not(any(target_arch = "spirv", miri)))]
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{
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// For types that are larger multiples of their alignment, the simple way
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// tends to copy the whole thing to stack rather than doing it one part
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@ -737,12 +740,26 @@ pub const fn swap<T>(x: &mut T, y: &mut T) {
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#[rustc_const_unstable(feature = "const_swap", issue = "83163")]
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#[inline]
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pub(crate) const fn swap_simple<T>(x: &mut T, y: &mut T) {
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// We arrange for this to typically be called with small types,
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// so this reads-and-writes approach is actually better than using
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// copy_nonoverlapping as it easily puts things in LLVM registers
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// directly and doesn't end up inlining allocas.
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// And LLVM actually optimizes it to 3×memcpy if called with
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// a type larger than it's willing to keep in a register.
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// Having typed reads and writes in MIR here is also good as
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// it lets MIRI and CTFE understand them better, including things
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// like enforcing type validity for them.
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// Importantly, read+copy_nonoverlapping+write introduces confusing
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// asymmetry to the behaviour where one value went through read+write
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// whereas the other was copied over by the intrinsic (see #94371).
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// SAFETY: exclusive references are always valid to read/write,
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// are non-overlapping, and nothing here panics so it's drop-safe.
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// including being aligned, and nothing here panics so it's drop-safe.
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unsafe {
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let z = ptr::read(x);
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ptr::copy_nonoverlapping(y, x, 1);
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ptr::write(y, z);
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let a = ptr::read(x);
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let b = ptr::read(y);
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ptr::write(x, b);
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ptr::write(y, a);
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}
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}
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@ -419,6 +419,7 @@ pub const unsafe fn swap<T>(x: *mut T, y: *mut T) {
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#[stable(feature = "swap_nonoverlapping", since = "1.27.0")]
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#[rustc_const_unstable(feature = "const_swap", issue = "83163")]
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pub const unsafe fn swap_nonoverlapping<T>(x: *mut T, y: *mut T, count: usize) {
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#[allow(unused)]
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macro_rules! attempt_swap_as_chunks {
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($ChunkTy:ty) => {
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if mem::align_of::<T>() >= mem::align_of::<$ChunkTy>()
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@ -437,15 +438,21 @@ pub const unsafe fn swap_nonoverlapping<T>(x: *mut T, y: *mut T, count: usize) {
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};
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}
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// Split up the slice into small power-of-two-sized chunks that LLVM is able
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// to vectorize (unless it's a special type with more-than-pointer alignment,
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// because we don't want to pessimize things like slices of SIMD vectors.)
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if mem::align_of::<T>() <= mem::size_of::<usize>()
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&& (!mem::size_of::<T>().is_power_of_two()
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|| mem::size_of::<T>() > mem::size_of::<usize>() * 2)
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// NOTE(scottmcm) MIRI is disabled here as reading in smaller units is a
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// pessimization for it. Also, if the type contains any unaligned pointers,
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// copying those over multiple reads is difficult to support.
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#[cfg(not(miri))]
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{
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attempt_swap_as_chunks!(usize);
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attempt_swap_as_chunks!(u8);
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// Split up the slice into small power-of-two-sized chunks that LLVM is able
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// to vectorize (unless it's a special type with more-than-pointer alignment,
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// because we don't want to pessimize things like slices of SIMD vectors.)
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if mem::align_of::<T>() <= mem::size_of::<usize>()
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&& (!mem::size_of::<T>().is_power_of_two()
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|| mem::size_of::<T>() > mem::size_of::<usize>() * 2)
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{
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attempt_swap_as_chunks!(usize);
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attempt_swap_as_chunks!(u8);
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}
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}
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// SAFETY: Same preconditions as this function
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@ -39,6 +39,9 @@ pub fn swap_std(x: &mut KeccakBuffer, y: &mut KeccakBuffer) {
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swap(x, y)
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}
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// Verify that types with usize alignment are swapped via vectored usizes,
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// not falling back to byte-level code.
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// CHECK-LABEL: @swap_slice
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#[no_mangle]
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pub fn swap_slice(x: &mut [KeccakBuffer], y: &mut [KeccakBuffer]) {
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@ -50,6 +53,8 @@ pub fn swap_slice(x: &mut [KeccakBuffer], y: &mut [KeccakBuffer]) {
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}
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}
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// But for a large align-1 type, vectorized byte copying is what we want.
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type OneKilobyteBuffer = [u8; 1024];
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// CHECK-LABEL: @swap_1kb_slices
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@ -62,3 +67,25 @@ pub fn swap_1kb_slices(x: &mut [OneKilobyteBuffer], y: &mut [OneKilobyteBuffer])
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x.swap_with_slice(y);
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}
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}
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// This verifies that the 2×read + 2×write optimizes to just 3 memcpys
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// for an unusual type like this. It's not clear whether we should do anything
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// smarter in Rust for these, so for now it's fine to leave these up to the backend.
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// That's not as bad as it might seem, as for example, LLVM will lower the
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// memcpys below to VMOVAPS on YMMs if one enables the AVX target feature.
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// Eventually we'll be able to pass `align_of::<T>` to a const generic and
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// thus pick a smarter chunk size ourselves without huge code duplication.
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#[repr(align(64))]
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pub struct BigButHighlyAligned([u8; 64 * 3]);
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// CHECK-LABEL: @swap_big_aligned
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#[no_mangle]
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pub fn swap_big_aligned(x: &mut BigButHighlyAligned, y: &mut BigButHighlyAligned) {
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// CHECK-NOT: call void @llvm.memcpy
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// CHECK: call void @llvm.memcpy.p0i8.p0i8.i64(i8* noundef nonnull align 64 dereferenceable(192)
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// CHECK: call void @llvm.memcpy.p0i8.p0i8.i64(i8* noundef nonnull align 64 dereferenceable(192)
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// CHECK: call void @llvm.memcpy.p0i8.p0i8.i64(i8* noundef nonnull align 64 dereferenceable(192)
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// CHECK-NOT: call void @llvm.memcpy
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swap(x, y)
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}
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