use super::bitmask::BitMask; use super::EMPTY; use core::{mem, ptr}; // Use the native word size as the group size. Using a 64-bit group size on // a 32-bit architecture will just end up being more expensive because // shifts and multiplies will need to be emulated. cfg_if! { if #[cfg(any( target_pointer_width = "64", target_arch = "aarch64", target_arch = "x86_64", target_arch = "wasm32", ))] { type GroupWord = u64; type NonZeroGroupWord = core::num::NonZeroU64; } else { type GroupWord = u32; type NonZeroGroupWord = core::num::NonZeroU32; } } pub(crate) type BitMaskWord = GroupWord; pub(crate) type NonZeroBitMaskWord = NonZeroGroupWord; pub(crate) const BITMASK_STRIDE: usize = 8; // We only care about the highest bit of each byte for the mask. #[allow(clippy::cast_possible_truncation, clippy::unnecessary_cast)] pub(crate) const BITMASK_MASK: BitMaskWord = 0x8080_8080_8080_8080_u64 as GroupWord; pub(crate) const BITMASK_ITER_MASK: BitMaskWord = !0; /// Helper function to replicate a byte across a `GroupWord`. #[inline] fn repeat(byte: u8) -> GroupWord { GroupWord::from_ne_bytes([byte; Group::WIDTH]) } /// Abstraction over a group of control bytes which can be scanned in /// parallel. /// /// This implementation uses a word-sized integer. #[derive(Copy, Clone)] pub(crate) struct Group(GroupWord); // We perform all operations in the native endianness, and convert to // little-endian just before creating a BitMask. The can potentially // enable the compiler to eliminate unnecessary byte swaps if we are // only checking whether a BitMask is empty. #[allow(clippy::use_self)] impl Group { /// Number of bytes in the group. pub(crate) const WIDTH: usize = mem::size_of::(); /// Returns a full group of empty bytes, suitable for use as the initial /// value for an empty hash table. /// /// This is guaranteed to be aligned to the group size. #[inline] pub(crate) const fn static_empty() -> &'static [u8; Group::WIDTH] { #[repr(C)] struct AlignedBytes { _align: [Group; 0], bytes: [u8; Group::WIDTH], } const ALIGNED_BYTES: AlignedBytes = AlignedBytes { _align: [], bytes: [EMPTY; Group::WIDTH], }; &ALIGNED_BYTES.bytes } /// Loads a group of bytes starting at the given address. #[inline] #[allow(clippy::cast_ptr_alignment)] // unaligned load pub(crate) unsafe fn load(ptr: *const u8) -> Self { Group(ptr::read_unaligned(ptr.cast())) } /// Loads a group of bytes starting at the given address, which must be /// aligned to `mem::align_of::()`. #[inline] #[allow(clippy::cast_ptr_alignment)] pub(crate) unsafe fn load_aligned(ptr: *const u8) -> Self { // FIXME: use align_offset once it stabilizes debug_assert_eq!(ptr as usize & (mem::align_of::() - 1), 0); Group(ptr::read(ptr.cast())) } /// Stores the group of bytes to the given address, which must be /// aligned to `mem::align_of::()`. #[inline] #[allow(clippy::cast_ptr_alignment)] pub(crate) unsafe fn store_aligned(self, ptr: *mut u8) { // FIXME: use align_offset once it stabilizes debug_assert_eq!(ptr as usize & (mem::align_of::() - 1), 0); ptr::write(ptr.cast(), self.0); } /// Returns a `BitMask` indicating all bytes in the group which *may* /// have the given value. /// /// This function may return a false positive in certain cases where /// the byte in the group differs from the searched value only in its /// lowest bit. This is fine because: /// - This never happens for `EMPTY` and `DELETED`, only full entries. /// - The check for key equality will catch these. /// - This only happens if there is at least 1 true match. /// - The chance of this happening is very low (< 1% chance per byte). #[inline] pub(crate) fn match_byte(self, byte: u8) -> BitMask { // This algorithm is derived from // https://graphics.stanford.edu/~seander/bithacks.html##ValueInWord let cmp = self.0 ^ repeat(byte); BitMask((cmp.wrapping_sub(repeat(0x01)) & !cmp & repeat(0x80)).to_le()) } /// Returns a `BitMask` indicating all bytes in the group which are /// `EMPTY`. #[inline] pub(crate) fn match_empty(self) -> BitMask { // If the high bit is set, then the byte must be either: // 1111_1111 (EMPTY) or 1000_0000 (DELETED). // So we can just check if the top two bits are 1 by ANDing them. BitMask((self.0 & (self.0 << 1) & repeat(0x80)).to_le()) } /// Returns a `BitMask` indicating all bytes in the group which are /// `EMPTY` or `DELETED`. #[inline] pub(crate) fn match_empty_or_deleted(self) -> BitMask { // A byte is EMPTY or DELETED iff the high bit is set BitMask((self.0 & repeat(0x80)).to_le()) } /// Returns a `BitMask` indicating all bytes in the group which are full. #[inline] pub(crate) fn match_full(self) -> BitMask { self.match_empty_or_deleted().invert() } /// Performs the following transformation on all bytes in the group: /// - `EMPTY => EMPTY` /// - `DELETED => EMPTY` /// - `FULL => DELETED` #[inline] pub(crate) fn convert_special_to_empty_and_full_to_deleted(self) -> Self { // Map high_bit = 1 (EMPTY or DELETED) to 1111_1111 // and high_bit = 0 (FULL) to 1000_0000 // // Here's this logic expanded to concrete values: // let full = 1000_0000 (true) or 0000_0000 (false) // !1000_0000 + 1 = 0111_1111 + 1 = 1000_0000 (no carry) // !0000_0000 + 0 = 1111_1111 + 0 = 1111_1111 (no carry) let full = !self.0 & repeat(0x80); Group(!full + (full >> 7)) } }