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use core::fmt;
use core::mem::MaybeUninit;
use crate::allocate::Allocator;
/// A wrapper around a byte buffer that is incrementally filled and initialized.
///
/// This type is a sort of "double cursor". It tracks three regions in the
/// buffer: a region at the beginning of the buffer that has been logically
/// filled with data, a region that has been initialized at some point but not
/// yet logically filled, and a region at the end that may be uninitialized.
/// The filled region is guaranteed to be a subset of the initialized region.
///
/// In summary, the contents of the buffer can be visualized as:
///
/// ```not_rust
/// [ capacity ]
/// [ filled | unfilled ]
/// [ initialized | uninitialized ]
/// ```
///
/// It is undefined behavior to de-initialize any bytes from the uninitialized
/// region, since it is merely unknown whether this region is uninitialized or
/// not, and if part of it turns out to be initialized, it must stay initialized.
pub struct ReadBuf<'a> {
buf: &'a mut [MaybeUninit<u8>],
filled: usize,
initialized: usize,
}
impl<'a> ReadBuf<'a> {
/// Creates a new `ReadBuf` from a fully initialized buffer.
#[inline]
pub fn new(buf: &'a mut [u8]) -> ReadBuf<'a> {
let initialized = buf.len();
let buf = unsafe { slice_to_uninit_mut(buf) };
ReadBuf {
buf,
filled: 0,
initialized,
}
}
/// Pointer to where the next byte will be written
#[inline]
pub fn next_out(&mut self) -> *mut MaybeUninit<u8> {
self.buf[self.filled..].as_mut_ptr()
}
/// Pointer to the start of the `ReadBuf`
#[inline]
pub fn as_mut_ptr(&mut self) -> *mut MaybeUninit<u8> {
self.buf.as_mut_ptr()
}
/// Returns the total capacity of the buffer.
#[inline]
pub fn capacity(&self) -> usize {
self.buf.len()
}
/// Returns the length of the filled part of the buffer
#[inline]
pub fn len(&self) -> usize {
self.filled
}
/// Returns true if there are no bytes in this ReadBuf
#[inline]
pub fn is_empty(&self) -> bool {
self.filled == 0
}
/// Returns a shared reference to the filled portion of the buffer.
#[inline]
pub fn filled(&self) -> &[u8] {
let slice = &self.buf[..self.filled];
// safety: filled describes how far into the buffer that the
// user has filled with bytes, so it's been initialized.
unsafe { slice_assume_init(slice) }
}
/// Returns a mutable reference to the entire buffer, without ensuring that it has been fully
/// initialized.
///
/// The elements between 0 and `self.len()` are filled, and those between 0 and
/// `self.initialized().len()` are initialized (and so can be converted to a `&mut [u8]`).
///
/// The caller of this method must ensure that these invariants are upheld. For example, if the
/// caller initializes some of the uninitialized section of the buffer, it must call
/// [`assume_init`](Self::assume_init) with the number of bytes initialized.
///
/// # Safety
///
/// The caller must not de-initialize portions of the buffer that have already been initialized.
/// This includes any bytes in the region marked as uninitialized by `ReadBuf`.
#[inline]
pub unsafe fn inner_mut(&mut self) -> &mut [MaybeUninit<u8>] {
self.buf
}
/// Returns the number of bytes at the end of the slice that have not yet been filled.
#[inline]
pub fn remaining(&self) -> usize {
self.capacity() - self.filled
}
/// Clears the buffer, resetting the filled region to empty.
///
/// The number of initialized bytes is not changed, and the contents of the buffer are not modified.
#[inline]
pub fn clear(&mut self) {
self.filled = 0;
}
/// Advances the size of the filled region of the buffer.
///
/// The number of initialized bytes is not changed.
///
/// # Panics
///
/// Panics if the filled region of the buffer would become larger than the initialized region.
#[inline]
#[track_caller]
pub fn advance(&mut self, n: usize) {
let new = self.filled.checked_add(n).expect("filled overflow");
self.set_filled(new);
}
/// Sets the size of the filled region of the buffer.
///
/// The number of initialized bytes is not changed.
///
/// Note that this can be used to *shrink* the filled region of the buffer in addition to growing it (for
/// example, by a `AsyncRead` implementation that compresses data in-place).
///
/// # Panics
///
/// Panics if the filled region of the buffer would become larger than the initialized region.
#[inline]
#[track_caller]
pub fn set_filled(&mut self, n: usize) {
assert!(
n <= self.initialized,
"filled must not become larger than initialized"
);
self.filled = n;
}
/// Asserts that the first `n` unfilled bytes of the buffer are initialized.
///
/// `ReadBuf` assumes that bytes are never de-initialized, so this method does nothing when called with fewer
/// bytes than are already known to be initialized.
///
/// # Safety
///
/// The caller must ensure that `n` unfilled bytes of the buffer have already been initialized.
#[inline]
pub unsafe fn assume_init(&mut self, n: usize) {
self.initialized = Ord::max(self.initialized, self.filled + n);
}
#[track_caller]
pub fn push(&mut self, byte: u8) {
assert!(
self.remaining() >= 1,
"read_buf is full ({} bytes)",
self.capacity()
);
self.buf[self.filled] = MaybeUninit::new(byte);
self.initialized = Ord::max(self.initialized, self.filled + 1);
self.filled += 1;
}
/// Appends data to the buffer, advancing the written position and possibly also the initialized position.
///
/// # Panics
///
/// Panics if `self.remaining()` is less than `buf.len()`.
#[inline(always)]
#[track_caller]
pub fn extend(&mut self, buf: &[u8]) {
assert!(
self.remaining() >= buf.len(),
"buf.len() must fit in remaining()"
);
// using simd here (on x86_64) was not fruitful
self.buf[self.filled..][..buf.len()].copy_from_slice(slice_to_uninit(buf));
let end = self.filled + buf.len();
self.initialized = Ord::max(self.initialized, end);
self.filled = end;
}
#[inline(always)]
pub fn copy_match(&mut self, offset_from_end: usize, length: usize) {
#[cfg(target_arch = "x86_64")]
if crate::cpu_features::is_enabled_avx512() {
return self.copy_match_help::<core::arch::x86_64::__m512i>(offset_from_end, length);
}
#[cfg(target_arch = "x86_64")]
if crate::cpu_features::is_enabled_avx2() {
return self.copy_match_help::<core::arch::x86_64::__m256i>(offset_from_end, length);
}
#[cfg(target_arch = "x86_64")]
if crate::cpu_features::is_enabled_sse() {
return self.copy_match_help::<core::arch::x86_64::__m128i>(offset_from_end, length);
}
self.copy_match_help::<u64>(offset_from_end, length)
}
fn copy_match_help<C: Chunk>(&mut self, offset_from_end: usize, length: usize) {
let current = self.filled;
let start = current.checked_sub(offset_from_end).expect("in bounds");
let end = start.checked_add(length).expect("in bounds");
// Note also that the referenced string may overlap the current
// position; for example, if the last 2 bytes decoded have values
// X and Y, a string reference with <length = 5, distance = 2>
// adds X,Y,X,Y,X to the output stream.
if end > current {
if offset_from_end == 1 {
// this will just repeat this value many times
let element = self.buf[current - 1];
self.buf[current..][..length].fill(element);
} else {
for i in 0..length {
self.buf[current + i] = self.buf[start + i];
}
}
} else {
Self::copy_chunked_within::<C>(self.buf, current, start, end)
}
// safety: we just copied length initialized bytes right beyond self.filled
unsafe { self.assume_init(length) };
self.advance(length);
}
#[inline(always)]
fn copy_chunked_within<C: Chunk>(
buf: &mut [MaybeUninit<u8>],
current: usize,
start: usize,
end: usize,
) {
if (end - start).next_multiple_of(core::mem::size_of::<C>()) <= (buf.len() - current) {
unsafe {
Self::copy_chunk_unchecked::<C>(
buf.as_ptr().add(start),
buf.as_mut_ptr().add(current),
buf.as_ptr().add(end),
)
}
} else {
// a full simd copy does not fit in the output buffer
buf.copy_within(start..end, current);
}
}
/// # Safety
///
/// `src` must be safe to perform unaligned reads in `core::mem::size_of::<C>()` chunks until
/// `end` is reached. `dst` must be safe to (unalingned) write that number of chunks.
#[inline(always)]
unsafe fn copy_chunk_unchecked<C: Chunk>(
mut src: *const MaybeUninit<u8>,
mut dst: *mut MaybeUninit<u8>,
end: *const MaybeUninit<u8>,
) {
while src < end {
let chunk = C::load_chunk(src);
C::store_chunk(dst, chunk);
src = src.add(core::mem::size_of::<C>());
dst = dst.add(core::mem::size_of::<C>());
}
}
pub(crate) fn new_in(alloc: &Allocator<'a>, len: usize) -> Option<Self> {
let buf = alloc.allocate_slice::<u8>(len)?;
Some(Self {
buf,
filled: 0,
initialized: 0,
})
}
pub(crate) fn clone_in(&self, alloc: &Allocator<'a>) -> Option<Self> {
let mut clone = Self::new_in(alloc, self.buf.len())?;
clone.buf.copy_from_slice(self.buf);
clone.filled = self.filled;
clone.initialized = self.initialized;
Some(clone)
}
pub(crate) unsafe fn drop_in(&mut self, alloc: &Allocator<'a>) {
if !self.buf.is_empty() {
let buf = core::mem::take(&mut self.buf);
alloc.deallocate(buf.as_mut_ptr(), buf.len());
}
}
}
impl fmt::Debug for ReadBuf<'_> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.debug_struct("ReadBuf")
.field("filled", &self.filled)
.field("initialized", &self.initialized)
.field("capacity", &self.capacity())
.finish()
}
}
fn slice_to_uninit(slice: &[u8]) -> &[MaybeUninit<u8>] {
unsafe { &*(slice as *const [u8] as *const [MaybeUninit<u8>]) }
}
unsafe fn slice_to_uninit_mut(slice: &mut [u8]) -> &mut [MaybeUninit<u8>] {
&mut *(slice as *mut [u8] as *mut [MaybeUninit<u8>])
}
// TODO: This could use `MaybeUninit::slice_assume_init` when it is stable.
unsafe fn slice_assume_init(slice: &[MaybeUninit<u8>]) -> &[u8] {
&*(slice as *const [MaybeUninit<u8>] as *const [u8])
}
trait Chunk {
/// Safety: must be valid to read a `Self::Chunk` value from `from` with an unaligned read.
unsafe fn load_chunk(from: *const MaybeUninit<u8>) -> Self;
/// Safety: must be valid to write a `Self::Chunk` value to `out` with an unaligned write.
unsafe fn store_chunk(out: *mut MaybeUninit<u8>, chunk: Self);
}
impl Chunk for u64 {
unsafe fn load_chunk(from: *const MaybeUninit<u8>) -> Self {
u64::to_le(core::ptr::read_unaligned(from.cast()))
}
unsafe fn store_chunk(out: *mut MaybeUninit<u8>, chunk: Self) {
core::ptr::copy_nonoverlapping(
chunk.to_le_bytes().as_ptr().cast(),
out,
core::mem::size_of::<Self>(),
)
}
}
#[cfg(target_arch = "x86_64")]
impl Chunk for core::arch::x86_64::__m128i {
#[inline(always)]
unsafe fn load_chunk(from: *const MaybeUninit<u8>) -> Self {
core::arch::x86_64::_mm_loadu_si128(from.cast())
}
#[inline(always)]
unsafe fn store_chunk(out: *mut MaybeUninit<u8>, chunk: Self) {
core::arch::x86_64::_mm_storeu_si128(out as *mut Self, chunk);
}
}
#[cfg(target_arch = "x86_64")]
impl Chunk for core::arch::x86_64::__m256i {
#[inline(always)]
unsafe fn load_chunk(from: *const MaybeUninit<u8>) -> Self {
core::arch::x86_64::_mm256_loadu_si256(from.cast())
}
#[inline(always)]
unsafe fn store_chunk(out: *mut MaybeUninit<u8>, chunk: Self) {
core::arch::x86_64::_mm256_storeu_si256(out as *mut Self, chunk);
}
}
#[cfg(target_arch = "x86_64")]
impl Chunk for core::arch::x86_64::__m512i {
#[inline(always)]
unsafe fn load_chunk(from: *const MaybeUninit<u8>) -> Self {
// TODO AVX-512 is effectively unstable.
// We cross our fingers that LLVM optimizes this into a vmovdqu32
//
core::ptr::read_unaligned(from.cast())
}
#[inline(always)]
unsafe fn store_chunk(out: *mut MaybeUninit<u8>, chunk: Self) {
// TODO AVX-512 is effectively unstable.
// We cross our fingers that LLVM optimizes this into a vmovdqu32
//
core::ptr::write_unaligned(out.cast(), chunk)
}
}