bytes/bytes.rs
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use core::iter::FromIterator;
use core::mem::{self, ManuallyDrop};
use core::ops::{Deref, RangeBounds};
use core::ptr::NonNull;
use core::{cmp, fmt, hash, ptr, slice, usize};
use alloc::{
alloc::{dealloc, Layout},
borrow::Borrow,
boxed::Box,
string::String,
vec::Vec,
};
use crate::buf::IntoIter;
#[allow(unused)]
use crate::loom::sync::atomic::AtomicMut;
use crate::loom::sync::atomic::{AtomicPtr, AtomicUsize, Ordering};
use crate::{offset_from, Buf, BytesMut};
/// A cheaply cloneable and sliceable chunk of contiguous memory.
///
/// `Bytes` is an efficient container for storing and operating on contiguous
/// slices of memory. It is intended for use primarily in networking code, but
/// could have applications elsewhere as well.
///
/// `Bytes` values facilitate zero-copy network programming by allowing multiple
/// `Bytes` objects to point to the same underlying memory.
///
/// `Bytes` does not have a single implementation. It is an interface, whose
/// exact behavior is implemented through dynamic dispatch in several underlying
/// implementations of `Bytes`.
///
/// All `Bytes` implementations must fulfill the following requirements:
/// - They are cheaply cloneable and thereby shareable between an unlimited amount
/// of components, for example by modifying a reference count.
/// - Instances can be sliced to refer to a subset of the original buffer.
///
/// ```
/// use bytes::Bytes;
///
/// let mut mem = Bytes::from("Hello world");
/// let a = mem.slice(0..5);
///
/// assert_eq!(a, "Hello");
///
/// let b = mem.split_to(6);
///
/// assert_eq!(mem, "world");
/// assert_eq!(b, "Hello ");
/// ```
///
/// # Memory layout
///
/// The `Bytes` struct itself is fairly small, limited to 4 `usize` fields used
/// to track information about which segment of the underlying memory the
/// `Bytes` handle has access to.
///
/// `Bytes` keeps both a pointer to the shared state containing the full memory
/// slice and a pointer to the start of the region visible by the handle.
/// `Bytes` also tracks the length of its view into the memory.
///
/// # Sharing
///
/// `Bytes` contains a vtable, which allows implementations of `Bytes` to define
/// how sharing/cloning is implemented in detail.
/// When `Bytes::clone()` is called, `Bytes` will call the vtable function for
/// cloning the backing storage in order to share it behind multiple `Bytes`
/// instances.
///
/// For `Bytes` implementations which refer to constant memory (e.g. created
/// via `Bytes::from_static()`) the cloning implementation will be a no-op.
///
/// For `Bytes` implementations which point to a reference counted shared storage
/// (e.g. an `Arc<[u8]>`), sharing will be implemented by increasing the
/// reference count.
///
/// Due to this mechanism, multiple `Bytes` instances may point to the same
/// shared memory region.
/// Each `Bytes` instance can point to different sections within that
/// memory region, and `Bytes` instances may or may not have overlapping views
/// into the memory.
///
/// The following diagram visualizes a scenario where 2 `Bytes` instances make
/// use of an `Arc`-based backing storage, and provide access to different views:
///
/// ```text
///
/// Arc ptrs ┌─────────┐
/// ________________________ / │ Bytes 2 │
/// / └─────────┘
/// / ┌───────────┐ | |
/// |_________/ │ Bytes 1 │ | |
/// | └───────────┘ | |
/// | | | ___/ data | tail
/// | data | tail |/ |
/// v v v v
/// ┌─────┬─────┬───────────┬───────────────┬─────┐
/// │ Arc │ │ │ │ │
/// └─────┴─────┴───────────┴───────────────┴─────┘
/// ```
pub struct Bytes {
ptr: *const u8,
len: usize,
// inlined "trait object"
data: AtomicPtr<()>,
vtable: &'static Vtable,
}
pub(crate) struct Vtable {
/// fn(data, ptr, len)
pub clone: unsafe fn(&AtomicPtr<()>, *const u8, usize) -> Bytes,
/// fn(data, ptr, len)
///
/// takes `Bytes` to value
pub to_vec: unsafe fn(&AtomicPtr<()>, *const u8, usize) -> Vec<u8>,
pub to_mut: unsafe fn(&AtomicPtr<()>, *const u8, usize) -> BytesMut,
/// fn(data)
pub is_unique: unsafe fn(&AtomicPtr<()>) -> bool,
/// fn(data, ptr, len)
pub drop: unsafe fn(&mut AtomicPtr<()>, *const u8, usize),
}
impl Bytes {
/// Creates a new empty `Bytes`.
///
/// This will not allocate and the returned `Bytes` handle will be empty.
///
/// # Examples
///
/// ```
/// use bytes::Bytes;
///
/// let b = Bytes::new();
/// assert_eq!(&b[..], b"");
/// ```
#[inline]
#[cfg(not(all(loom, test)))]
pub const fn new() -> Self {
// Make it a named const to work around
// "unsizing casts are not allowed in const fn"
const EMPTY: &[u8] = &[];
Bytes::from_static(EMPTY)
}
/// Creates a new empty `Bytes`.
#[cfg(all(loom, test))]
pub fn new() -> Self {
const EMPTY: &[u8] = &[];
Bytes::from_static(EMPTY)
}
/// Creates a new `Bytes` from a static slice.
///
/// The returned `Bytes` will point directly to the static slice. There is
/// no allocating or copying.
///
/// # Examples
///
/// ```
/// use bytes::Bytes;
///
/// let b = Bytes::from_static(b"hello");
/// assert_eq!(&b[..], b"hello");
/// ```
#[inline]
#[cfg(not(all(loom, test)))]
pub const fn from_static(bytes: &'static [u8]) -> Self {
Bytes {
ptr: bytes.as_ptr(),
len: bytes.len(),
data: AtomicPtr::new(ptr::null_mut()),
vtable: &STATIC_VTABLE,
}
}
/// Creates a new `Bytes` from a static slice.
#[cfg(all(loom, test))]
pub fn from_static(bytes: &'static [u8]) -> Self {
Bytes {
ptr: bytes.as_ptr(),
len: bytes.len(),
data: AtomicPtr::new(ptr::null_mut()),
vtable: &STATIC_VTABLE,
}
}
/// Creates a new `Bytes` with length zero and the given pointer as the address.
fn new_empty_with_ptr(ptr: *const u8) -> Self {
debug_assert!(!ptr.is_null());
// Detach this pointer's provenance from whichever allocation it came from, and reattach it
// to the provenance of the fake ZST [u8;0] at the same address.
let ptr = without_provenance(ptr as usize);
Bytes {
ptr,
len: 0,
data: AtomicPtr::new(ptr::null_mut()),
vtable: &STATIC_VTABLE,
}
}
/// Create [Bytes] with a buffer whose lifetime is controlled
/// via an explicit owner.
///
/// A common use case is to zero-copy construct from mapped memory.
///
/// ```
/// # struct File;
/// #
/// # impl File {
/// # pub fn open(_: &str) -> Result<Self, ()> {
/// # Ok(Self)
/// # }
/// # }
/// #
/// # mod memmap2 {
/// # pub struct Mmap;
/// #
/// # impl Mmap {
/// # pub unsafe fn map(_file: &super::File) -> Result<Self, ()> {
/// # Ok(Self)
/// # }
/// # }
/// #
/// # impl AsRef<[u8]> for Mmap {
/// # fn as_ref(&self) -> &[u8] {
/// # b"buf"
/// # }
/// # }
/// # }
/// use bytes::Bytes;
/// use memmap2::Mmap;
///
/// # fn main() -> Result<(), ()> {
/// let file = File::open("upload_bundle.tar.gz")?;
/// let mmap = unsafe { Mmap::map(&file) }?;
/// let b = Bytes::from_owner(mmap);
/// # Ok(())
/// # }
/// ```
///
/// The `owner` will be transferred to the constructed [Bytes] object, which
/// will ensure it is dropped once all remaining clones of the constructed
/// object are dropped. The owner will then be responsible for dropping the
/// specified region of memory as part of its [Drop] implementation.
///
/// Note that converting [Bytes] constructed from an owner into a [BytesMut]
/// will always create a deep copy of the buffer into newly allocated memory.
pub fn from_owner<T>(owner: T) -> Self
where
T: AsRef<[u8]> + Send + 'static,
{
// Safety & Miri:
// The ownership of `owner` is first transferred to the `Owned` wrapper and `Bytes` object.
// This ensures that the owner is pinned in memory, allowing us to call `.as_ref()` safely
// since the lifetime of the owner is controlled by the lifetime of the new `Bytes` object,
// and the lifetime of the resulting borrowed `&[u8]` matches that of the owner.
// Note that this remains safe so long as we only call `.as_ref()` once.
//
// There are some additional special considerations here:
// * We rely on Bytes's Drop impl to clean up memory should `.as_ref()` panic.
// * Setting the `ptr` and `len` on the bytes object last (after moving the owner to
// Bytes) allows Miri checks to pass since it avoids obtaining the `&[u8]` slice
// from a stack-owned Box.
// More details on this: https://github.com/tokio-rs/bytes/pull/742/#discussion_r1813375863
// and: https://github.com/tokio-rs/bytes/pull/742/#discussion_r1813316032
let owned = Box::into_raw(Box::new(Owned {
lifetime: OwnedLifetime {
ref_cnt: AtomicUsize::new(1),
drop: owned_box_and_drop::<T>,
},
owner,
}));
let mut ret = Bytes {
ptr: NonNull::dangling().as_ptr(),
len: 0,
data: AtomicPtr::new(owned.cast()),
vtable: &OWNED_VTABLE,
};
let buf = unsafe { &*owned }.owner.as_ref();
ret.ptr = buf.as_ptr();
ret.len = buf.len();
ret
}
/// Returns the number of bytes contained in this `Bytes`.
///
/// # Examples
///
/// ```
/// use bytes::Bytes;
///
/// let b = Bytes::from(&b"hello"[..]);
/// assert_eq!(b.len(), 5);
/// ```
#[inline]
pub const fn len(&self) -> usize {
self.len
}
/// Returns true if the `Bytes` has a length of 0.
///
/// # Examples
///
/// ```
/// use bytes::Bytes;
///
/// let b = Bytes::new();
/// assert!(b.is_empty());
/// ```
#[inline]
pub const fn is_empty(&self) -> bool {
self.len == 0
}
/// Returns true if this is the only reference to the data and
/// `Into<BytesMut>` would avoid cloning the underlying buffer.
///
/// Always returns false if the data is backed by a [static slice](Bytes::from_static),
/// or an [owner](Bytes::from_owner).
///
/// The result of this method may be invalidated immediately if another
/// thread clones this value while this is being called. Ensure you have
/// unique access to this value (`&mut Bytes`) first if you need to be
/// certain the result is valid (i.e. for safety reasons).
/// # Examples
///
/// ```
/// use bytes::Bytes;
///
/// let a = Bytes::from(vec![1, 2, 3]);
/// assert!(a.is_unique());
/// let b = a.clone();
/// assert!(!a.is_unique());
/// ```
pub fn is_unique(&self) -> bool {
unsafe { (self.vtable.is_unique)(&self.data) }
}
/// Creates `Bytes` instance from slice, by copying it.
pub fn copy_from_slice(data: &[u8]) -> Self {
data.to_vec().into()
}
/// Returns a slice of self for the provided range.
///
/// This will increment the reference count for the underlying memory and
/// return a new `Bytes` handle set to the slice.
///
/// This operation is `O(1)`.
///
/// # Examples
///
/// ```
/// use bytes::Bytes;
///
/// let a = Bytes::from(&b"hello world"[..]);
/// let b = a.slice(2..5);
///
/// assert_eq!(&b[..], b"llo");
/// ```
///
/// # Panics
///
/// Requires that `begin <= end` and `end <= self.len()`, otherwise slicing
/// will panic.
pub fn slice(&self, range: impl RangeBounds<usize>) -> Self {
use core::ops::Bound;
let len = self.len();
let begin = match range.start_bound() {
Bound::Included(&n) => n,
Bound::Excluded(&n) => n.checked_add(1).expect("out of range"),
Bound::Unbounded => 0,
};
let end = match range.end_bound() {
Bound::Included(&n) => n.checked_add(1).expect("out of range"),
Bound::Excluded(&n) => n,
Bound::Unbounded => len,
};
assert!(
begin <= end,
"range start must not be greater than end: {:?} <= {:?}",
begin,
end,
);
assert!(
end <= len,
"range end out of bounds: {:?} <= {:?}",
end,
len,
);
if end == begin {
return Bytes::new();
}
let mut ret = self.clone();
ret.len = end - begin;
ret.ptr = unsafe { ret.ptr.add(begin) };
ret
}
/// Returns a slice of self that is equivalent to the given `subset`.
///
/// When processing a `Bytes` buffer with other tools, one often gets a
/// `&[u8]` which is in fact a slice of the `Bytes`, i.e. a subset of it.
/// This function turns that `&[u8]` into another `Bytes`, as if one had
/// called `self.slice()` with the offsets that correspond to `subset`.
///
/// This operation is `O(1)`.
///
/// # Examples
///
/// ```
/// use bytes::Bytes;
///
/// let bytes = Bytes::from(&b"012345678"[..]);
/// let as_slice = bytes.as_ref();
/// let subset = &as_slice[2..6];
/// let subslice = bytes.slice_ref(&subset);
/// assert_eq!(&subslice[..], b"2345");
/// ```
///
/// # Panics
///
/// Requires that the given `sub` slice is in fact contained within the
/// `Bytes` buffer; otherwise this function will panic.
pub fn slice_ref(&self, subset: &[u8]) -> Self {
// Empty slice and empty Bytes may have their pointers reset
// so explicitly allow empty slice to be a subslice of any slice.
if subset.is_empty() {
return Bytes::new();
}
let bytes_p = self.as_ptr() as usize;
let bytes_len = self.len();
let sub_p = subset.as_ptr() as usize;
let sub_len = subset.len();
assert!(
sub_p >= bytes_p,
"subset pointer ({:p}) is smaller than self pointer ({:p})",
subset.as_ptr(),
self.as_ptr(),
);
assert!(
sub_p + sub_len <= bytes_p + bytes_len,
"subset is out of bounds: self = ({:p}, {}), subset = ({:p}, {})",
self.as_ptr(),
bytes_len,
subset.as_ptr(),
sub_len,
);
let sub_offset = sub_p - bytes_p;
self.slice(sub_offset..(sub_offset + sub_len))
}
/// Splits the bytes into two at the given index.
///
/// Afterwards `self` contains elements `[0, at)`, and the returned `Bytes`
/// contains elements `[at, len)`. It's guaranteed that the memory does not
/// move, that is, the address of `self` does not change, and the address of
/// the returned slice is `at` bytes after that.
///
/// This is an `O(1)` operation that just increases the reference count and
/// sets a few indices.
///
/// # Examples
///
/// ```
/// use bytes::Bytes;
///
/// let mut a = Bytes::from(&b"hello world"[..]);
/// let b = a.split_off(5);
///
/// assert_eq!(&a[..], b"hello");
/// assert_eq!(&b[..], b" world");
/// ```
///
/// # Panics
///
/// Panics if `at > len`.
#[must_use = "consider Bytes::truncate if you don't need the other half"]
pub fn split_off(&mut self, at: usize) -> Self {
if at == self.len() {
return Bytes::new_empty_with_ptr(self.ptr.wrapping_add(at));
}
if at == 0 {
return mem::replace(self, Bytes::new_empty_with_ptr(self.ptr));
}
assert!(
at <= self.len(),
"split_off out of bounds: {:?} <= {:?}",
at,
self.len(),
);
let mut ret = self.clone();
self.len = at;
unsafe { ret.inc_start(at) };
ret
}
/// Splits the bytes into two at the given index.
///
/// Afterwards `self` contains elements `[at, len)`, and the returned
/// `Bytes` contains elements `[0, at)`.
///
/// This is an `O(1)` operation that just increases the reference count and
/// sets a few indices.
///
/// # Examples
///
/// ```
/// use bytes::Bytes;
///
/// let mut a = Bytes::from(&b"hello world"[..]);
/// let b = a.split_to(5);
///
/// assert_eq!(&a[..], b" world");
/// assert_eq!(&b[..], b"hello");
/// ```
///
/// # Panics
///
/// Panics if `at > len`.
#[must_use = "consider Bytes::advance if you don't need the other half"]
pub fn split_to(&mut self, at: usize) -> Self {
if at == self.len() {
let end_ptr = self.ptr.wrapping_add(at);
return mem::replace(self, Bytes::new_empty_with_ptr(end_ptr));
}
if at == 0 {
return Bytes::new_empty_with_ptr(self.ptr);
}
assert!(
at <= self.len(),
"split_to out of bounds: {:?} <= {:?}",
at,
self.len(),
);
let mut ret = self.clone();
unsafe { self.inc_start(at) };
ret.len = at;
ret
}
/// Shortens the buffer, keeping the first `len` bytes and dropping the
/// rest.
///
/// If `len` is greater than the buffer's current length, this has no
/// effect.
///
/// The [split_off](`Self::split_off()`) method can emulate `truncate`, but this causes the
/// excess bytes to be returned instead of dropped.
///
/// # Examples
///
/// ```
/// use bytes::Bytes;
///
/// let mut buf = Bytes::from(&b"hello world"[..]);
/// buf.truncate(5);
/// assert_eq!(buf, b"hello"[..]);
/// ```
#[inline]
pub fn truncate(&mut self, len: usize) {
if len < self.len {
// The Vec "promotable" vtables do not store the capacity,
// so we cannot truncate while using this repr. We *have* to
// promote using `split_off` so the capacity can be stored.
if self.vtable as *const Vtable == &PROMOTABLE_EVEN_VTABLE
|| self.vtable as *const Vtable == &PROMOTABLE_ODD_VTABLE
{
drop(self.split_off(len));
} else {
self.len = len;
}
}
}
/// Clears the buffer, removing all data.
///
/// # Examples
///
/// ```
/// use bytes::Bytes;
///
/// let mut buf = Bytes::from(&b"hello world"[..]);
/// buf.clear();
/// assert!(buf.is_empty());
/// ```
#[inline]
pub fn clear(&mut self) {
self.truncate(0);
}
/// Try to convert self into `BytesMut`.
///
/// If `self` is unique for the entire original buffer, this will succeed
/// and return a `BytesMut` with the contents of `self` without copying.
/// If `self` is not unique for the entire original buffer, this will fail
/// and return self.
///
/// This will also always fail if the buffer was constructed via either
/// [from_owner](Bytes::from_owner) or [from_static](Bytes::from_static).
///
/// # Examples
///
/// ```
/// use bytes::{Bytes, BytesMut};
///
/// let bytes = Bytes::from(b"hello".to_vec());
/// assert_eq!(bytes.try_into_mut(), Ok(BytesMut::from(&b"hello"[..])));
/// ```
pub fn try_into_mut(self) -> Result<BytesMut, Bytes> {
if self.is_unique() {
Ok(self.into())
} else {
Err(self)
}
}
#[inline]
pub(crate) unsafe fn with_vtable(
ptr: *const u8,
len: usize,
data: AtomicPtr<()>,
vtable: &'static Vtable,
) -> Bytes {
Bytes {
ptr,
len,
data,
vtable,
}
}
// private
#[inline]
fn as_slice(&self) -> &[u8] {
unsafe { slice::from_raw_parts(self.ptr, self.len) }
}
#[inline]
unsafe fn inc_start(&mut self, by: usize) {
// should already be asserted, but debug assert for tests
debug_assert!(self.len >= by, "internal: inc_start out of bounds");
self.len -= by;
self.ptr = self.ptr.add(by);
}
}
// Vtable must enforce this behavior
unsafe impl Send for Bytes {}
unsafe impl Sync for Bytes {}
impl Drop for Bytes {
#[inline]
fn drop(&mut self) {
unsafe { (self.vtable.drop)(&mut self.data, self.ptr, self.len) }
}
}
impl Clone for Bytes {
#[inline]
fn clone(&self) -> Bytes {
unsafe { (self.vtable.clone)(&self.data, self.ptr, self.len) }
}
}
impl Buf for Bytes {
#[inline]
fn remaining(&self) -> usize {
self.len()
}
#[inline]
fn chunk(&self) -> &[u8] {
self.as_slice()
}
#[inline]
fn advance(&mut self, cnt: usize) {
assert!(
cnt <= self.len(),
"cannot advance past `remaining`: {:?} <= {:?}",
cnt,
self.len(),
);
unsafe {
self.inc_start(cnt);
}
}
fn copy_to_bytes(&mut self, len: usize) -> Self {
self.split_to(len)
}
}
impl Deref for Bytes {
type Target = [u8];
#[inline]
fn deref(&self) -> &[u8] {
self.as_slice()
}
}
impl AsRef<[u8]> for Bytes {
#[inline]
fn as_ref(&self) -> &[u8] {
self.as_slice()
}
}
impl hash::Hash for Bytes {
fn hash<H>(&self, state: &mut H)
where
H: hash::Hasher,
{
self.as_slice().hash(state);
}
}
impl Borrow<[u8]> for Bytes {
fn borrow(&self) -> &[u8] {
self.as_slice()
}
}
impl IntoIterator for Bytes {
type Item = u8;
type IntoIter = IntoIter<Bytes>;
fn into_iter(self) -> Self::IntoIter {
IntoIter::new(self)
}
}
impl<'a> IntoIterator for &'a Bytes {
type Item = &'a u8;
type IntoIter = core::slice::Iter<'a, u8>;
fn into_iter(self) -> Self::IntoIter {
self.as_slice().iter()
}
}
impl FromIterator<u8> for Bytes {
fn from_iter<T: IntoIterator<Item = u8>>(into_iter: T) -> Self {
Vec::from_iter(into_iter).into()
}
}
// impl Eq
impl PartialEq for Bytes {
fn eq(&self, other: &Bytes) -> bool {
self.as_slice() == other.as_slice()
}
}
impl PartialOrd for Bytes {
fn partial_cmp(&self, other: &Bytes) -> Option<cmp::Ordering> {
self.as_slice().partial_cmp(other.as_slice())
}
}
impl Ord for Bytes {
fn cmp(&self, other: &Bytes) -> cmp::Ordering {
self.as_slice().cmp(other.as_slice())
}
}
impl Eq for Bytes {}
impl PartialEq<[u8]> for Bytes {
fn eq(&self, other: &[u8]) -> bool {
self.as_slice() == other
}
}
impl PartialOrd<[u8]> for Bytes {
fn partial_cmp(&self, other: &[u8]) -> Option<cmp::Ordering> {
self.as_slice().partial_cmp(other)
}
}
impl PartialEq<Bytes> for [u8] {
fn eq(&self, other: &Bytes) -> bool {
*other == *self
}
}
impl PartialOrd<Bytes> for [u8] {
fn partial_cmp(&self, other: &Bytes) -> Option<cmp::Ordering> {
<[u8] as PartialOrd<[u8]>>::partial_cmp(self, other)
}
}
impl PartialEq<str> for Bytes {
fn eq(&self, other: &str) -> bool {
self.as_slice() == other.as_bytes()
}
}
impl PartialOrd<str> for Bytes {
fn partial_cmp(&self, other: &str) -> Option<cmp::Ordering> {
self.as_slice().partial_cmp(other.as_bytes())
}
}
impl PartialEq<Bytes> for str {
fn eq(&self, other: &Bytes) -> bool {
*other == *self
}
}
impl PartialOrd<Bytes> for str {
fn partial_cmp(&self, other: &Bytes) -> Option<cmp::Ordering> {
<[u8] as PartialOrd<[u8]>>::partial_cmp(self.as_bytes(), other)
}
}
impl PartialEq<Vec<u8>> for Bytes {
fn eq(&self, other: &Vec<u8>) -> bool {
*self == other[..]
}
}
impl PartialOrd<Vec<u8>> for Bytes {
fn partial_cmp(&self, other: &Vec<u8>) -> Option<cmp::Ordering> {
self.as_slice().partial_cmp(&other[..])
}
}
impl PartialEq<Bytes> for Vec<u8> {
fn eq(&self, other: &Bytes) -> bool {
*other == *self
}
}
impl PartialOrd<Bytes> for Vec<u8> {
fn partial_cmp(&self, other: &Bytes) -> Option<cmp::Ordering> {
<[u8] as PartialOrd<[u8]>>::partial_cmp(self, other)
}
}
impl PartialEq<String> for Bytes {
fn eq(&self, other: &String) -> bool {
*self == other[..]
}
}
impl PartialOrd<String> for Bytes {
fn partial_cmp(&self, other: &String) -> Option<cmp::Ordering> {
self.as_slice().partial_cmp(other.as_bytes())
}
}
impl PartialEq<Bytes> for String {
fn eq(&self, other: &Bytes) -> bool {
*other == *self
}
}
impl PartialOrd<Bytes> for String {
fn partial_cmp(&self, other: &Bytes) -> Option<cmp::Ordering> {
<[u8] as PartialOrd<[u8]>>::partial_cmp(self.as_bytes(), other)
}
}
impl PartialEq<Bytes> for &[u8] {
fn eq(&self, other: &Bytes) -> bool {
*other == *self
}
}
impl PartialOrd<Bytes> for &[u8] {
fn partial_cmp(&self, other: &Bytes) -> Option<cmp::Ordering> {
<[u8] as PartialOrd<[u8]>>::partial_cmp(self, other)
}
}
impl PartialEq<Bytes> for &str {
fn eq(&self, other: &Bytes) -> bool {
*other == *self
}
}
impl PartialOrd<Bytes> for &str {
fn partial_cmp(&self, other: &Bytes) -> Option<cmp::Ordering> {
<[u8] as PartialOrd<[u8]>>::partial_cmp(self.as_bytes(), other)
}
}
impl<'a, T: ?Sized> PartialEq<&'a T> for Bytes
where
Bytes: PartialEq<T>,
{
fn eq(&self, other: &&'a T) -> bool {
*self == **other
}
}
impl<'a, T: ?Sized> PartialOrd<&'a T> for Bytes
where
Bytes: PartialOrd<T>,
{
fn partial_cmp(&self, other: &&'a T) -> Option<cmp::Ordering> {
self.partial_cmp(&**other)
}
}
// impl From
impl Default for Bytes {
#[inline]
fn default() -> Bytes {
Bytes::new()
}
}
impl From<&'static [u8]> for Bytes {
fn from(slice: &'static [u8]) -> Bytes {
Bytes::from_static(slice)
}
}
impl From<&'static str> for Bytes {
fn from(slice: &'static str) -> Bytes {
Bytes::from_static(slice.as_bytes())
}
}
impl From<Vec<u8>> for Bytes {
fn from(vec: Vec<u8>) -> Bytes {
let mut vec = ManuallyDrop::new(vec);
let ptr = vec.as_mut_ptr();
let len = vec.len();
let cap = vec.capacity();
// Avoid an extra allocation if possible.
if len == cap {
let vec = ManuallyDrop::into_inner(vec);
return Bytes::from(vec.into_boxed_slice());
}
let shared = Box::new(Shared {
buf: ptr,
cap,
ref_cnt: AtomicUsize::new(1),
});
let shared = Box::into_raw(shared);
// The pointer should be aligned, so this assert should
// always succeed.
debug_assert!(
0 == (shared as usize & KIND_MASK),
"internal: Box<Shared> should have an aligned pointer",
);
Bytes {
ptr,
len,
data: AtomicPtr::new(shared as _),
vtable: &SHARED_VTABLE,
}
}
}
impl From<Box<[u8]>> for Bytes {
fn from(slice: Box<[u8]>) -> Bytes {
// Box<[u8]> doesn't contain a heap allocation for empty slices,
// so the pointer isn't aligned enough for the KIND_VEC stashing to
// work.
if slice.is_empty() {
return Bytes::new();
}
let len = slice.len();
let ptr = Box::into_raw(slice) as *mut u8;
if ptr as usize & 0x1 == 0 {
let data = ptr_map(ptr, |addr| addr | KIND_VEC);
Bytes {
ptr,
len,
data: AtomicPtr::new(data.cast()),
vtable: &PROMOTABLE_EVEN_VTABLE,
}
} else {
Bytes {
ptr,
len,
data: AtomicPtr::new(ptr.cast()),
vtable: &PROMOTABLE_ODD_VTABLE,
}
}
}
}
impl From<Bytes> for BytesMut {
/// Convert self into `BytesMut`.
///
/// If `bytes` is unique for the entire original buffer, this will return a
/// `BytesMut` with the contents of `bytes` without copying.
/// If `bytes` is not unique for the entire original buffer, this will make
/// a copy of `bytes` subset of the original buffer in a new `BytesMut`.
///
/// # Examples
///
/// ```
/// use bytes::{Bytes, BytesMut};
///
/// let bytes = Bytes::from(b"hello".to_vec());
/// assert_eq!(BytesMut::from(bytes), BytesMut::from(&b"hello"[..]));
/// ```
fn from(bytes: Bytes) -> Self {
let bytes = ManuallyDrop::new(bytes);
unsafe { (bytes.vtable.to_mut)(&bytes.data, bytes.ptr, bytes.len) }
}
}
impl From<String> for Bytes {
fn from(s: String) -> Bytes {
Bytes::from(s.into_bytes())
}
}
impl From<Bytes> for Vec<u8> {
fn from(bytes: Bytes) -> Vec<u8> {
let bytes = ManuallyDrop::new(bytes);
unsafe { (bytes.vtable.to_vec)(&bytes.data, bytes.ptr, bytes.len) }
}
}
// ===== impl Vtable =====
impl fmt::Debug for Vtable {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.debug_struct("Vtable")
.field("clone", &(self.clone as *const ()))
.field("drop", &(self.drop as *const ()))
.finish()
}
}
// ===== impl StaticVtable =====
const STATIC_VTABLE: Vtable = Vtable {
clone: static_clone,
to_vec: static_to_vec,
to_mut: static_to_mut,
is_unique: static_is_unique,
drop: static_drop,
};
unsafe fn static_clone(_: &AtomicPtr<()>, ptr: *const u8, len: usize) -> Bytes {
let slice = slice::from_raw_parts(ptr, len);
Bytes::from_static(slice)
}
unsafe fn static_to_vec(_: &AtomicPtr<()>, ptr: *const u8, len: usize) -> Vec<u8> {
let slice = slice::from_raw_parts(ptr, len);
slice.to_vec()
}
unsafe fn static_to_mut(_: &AtomicPtr<()>, ptr: *const u8, len: usize) -> BytesMut {
let slice = slice::from_raw_parts(ptr, len);
BytesMut::from(slice)
}
fn static_is_unique(_: &AtomicPtr<()>) -> bool {
false
}
unsafe fn static_drop(_: &mut AtomicPtr<()>, _: *const u8, _: usize) {
// nothing to drop for &'static [u8]
}
// ===== impl OwnedVtable =====
#[repr(C)]
struct OwnedLifetime {
ref_cnt: AtomicUsize,
drop: unsafe fn(*mut ()),
}
#[repr(C)]
struct Owned<T> {
lifetime: OwnedLifetime,
owner: T,
}
unsafe fn owned_box_and_drop<T>(ptr: *mut ()) {
let b: Box<Owned<T>> = Box::from_raw(ptr as _);
drop(b);
}
unsafe fn owned_clone(data: &AtomicPtr<()>, ptr: *const u8, len: usize) -> Bytes {
let owned = data.load(Ordering::Relaxed);
let ref_cnt = &(*owned.cast::<OwnedLifetime>()).ref_cnt;
let old_cnt = ref_cnt.fetch_add(1, Ordering::Relaxed);
if old_cnt > usize::MAX >> 1 {
crate::abort()
}
Bytes {
ptr,
len,
data: AtomicPtr::new(owned as _),
vtable: &OWNED_VTABLE,
}
}
unsafe fn owned_to_vec(_data: &AtomicPtr<()>, ptr: *const u8, len: usize) -> Vec<u8> {
let slice = slice::from_raw_parts(ptr, len);
slice.to_vec()
}
unsafe fn owned_to_mut(data: &AtomicPtr<()>, ptr: *const u8, len: usize) -> BytesMut {
let bytes_mut = BytesMut::from_vec(owned_to_vec(data, ptr, len));
owned_drop_impl(data.load(Ordering::Relaxed));
bytes_mut
}
unsafe fn owned_is_unique(_data: &AtomicPtr<()>) -> bool {
false
}
unsafe fn owned_drop_impl(owned: *mut ()) {
let lifetime = owned.cast::<OwnedLifetime>();
let ref_cnt = &(*lifetime).ref_cnt;
let old_cnt = ref_cnt.fetch_sub(1, Ordering::Release);
if old_cnt != 1 {
return;
}
ref_cnt.load(Ordering::Acquire);
let drop_fn = &(*lifetime).drop;
drop_fn(owned)
}
unsafe fn owned_drop(data: &mut AtomicPtr<()>, _ptr: *const u8, _len: usize) {
let owned = data.load(Ordering::Relaxed);
owned_drop_impl(owned);
}
static OWNED_VTABLE: Vtable = Vtable {
clone: owned_clone,
to_vec: owned_to_vec,
to_mut: owned_to_mut,
is_unique: owned_is_unique,
drop: owned_drop,
};
// ===== impl PromotableVtable =====
static PROMOTABLE_EVEN_VTABLE: Vtable = Vtable {
clone: promotable_even_clone,
to_vec: promotable_even_to_vec,
to_mut: promotable_even_to_mut,
is_unique: promotable_is_unique,
drop: promotable_even_drop,
};
static PROMOTABLE_ODD_VTABLE: Vtable = Vtable {
clone: promotable_odd_clone,
to_vec: promotable_odd_to_vec,
to_mut: promotable_odd_to_mut,
is_unique: promotable_is_unique,
drop: promotable_odd_drop,
};
unsafe fn promotable_even_clone(data: &AtomicPtr<()>, ptr: *const u8, len: usize) -> Bytes {
let shared = data.load(Ordering::Acquire);
let kind = shared as usize & KIND_MASK;
if kind == KIND_ARC {
shallow_clone_arc(shared.cast(), ptr, len)
} else {
debug_assert_eq!(kind, KIND_VEC);
let buf = ptr_map(shared.cast(), |addr| addr & !KIND_MASK);
shallow_clone_vec(data, shared, buf, ptr, len)
}
}
unsafe fn promotable_to_vec(
data: &AtomicPtr<()>,
ptr: *const u8,
len: usize,
f: fn(*mut ()) -> *mut u8,
) -> Vec<u8> {
let shared = data.load(Ordering::Acquire);
let kind = shared as usize & KIND_MASK;
if kind == KIND_ARC {
shared_to_vec_impl(shared.cast(), ptr, len)
} else {
// If Bytes holds a Vec, then the offset must be 0.
debug_assert_eq!(kind, KIND_VEC);
let buf = f(shared);
let cap = offset_from(ptr, buf) + len;
// Copy back buffer
ptr::copy(ptr, buf, len);
Vec::from_raw_parts(buf, len, cap)
}
}
unsafe fn promotable_to_mut(
data: &AtomicPtr<()>,
ptr: *const u8,
len: usize,
f: fn(*mut ()) -> *mut u8,
) -> BytesMut {
let shared = data.load(Ordering::Acquire);
let kind = shared as usize & KIND_MASK;
if kind == KIND_ARC {
shared_to_mut_impl(shared.cast(), ptr, len)
} else {
// KIND_VEC is a view of an underlying buffer at a certain offset.
// The ptr + len always represents the end of that buffer.
// Before truncating it, it is first promoted to KIND_ARC.
// Thus, we can safely reconstruct a Vec from it without leaking memory.
debug_assert_eq!(kind, KIND_VEC);
let buf = f(shared);
let off = offset_from(ptr, buf);
let cap = off + len;
let v = Vec::from_raw_parts(buf, cap, cap);
let mut b = BytesMut::from_vec(v);
b.advance_unchecked(off);
b
}
}
unsafe fn promotable_even_to_vec(data: &AtomicPtr<()>, ptr: *const u8, len: usize) -> Vec<u8> {
promotable_to_vec(data, ptr, len, |shared| {
ptr_map(shared.cast(), |addr| addr & !KIND_MASK)
})
}
unsafe fn promotable_even_to_mut(data: &AtomicPtr<()>, ptr: *const u8, len: usize) -> BytesMut {
promotable_to_mut(data, ptr, len, |shared| {
ptr_map(shared.cast(), |addr| addr & !KIND_MASK)
})
}
unsafe fn promotable_even_drop(data: &mut AtomicPtr<()>, ptr: *const u8, len: usize) {
data.with_mut(|shared| {
let shared = *shared;
let kind = shared as usize & KIND_MASK;
if kind == KIND_ARC {
release_shared(shared.cast());
} else {
debug_assert_eq!(kind, KIND_VEC);
let buf = ptr_map(shared.cast(), |addr| addr & !KIND_MASK);
free_boxed_slice(buf, ptr, len);
}
});
}
unsafe fn promotable_odd_clone(data: &AtomicPtr<()>, ptr: *const u8, len: usize) -> Bytes {
let shared = data.load(Ordering::Acquire);
let kind = shared as usize & KIND_MASK;
if kind == KIND_ARC {
shallow_clone_arc(shared as _, ptr, len)
} else {
debug_assert_eq!(kind, KIND_VEC);
shallow_clone_vec(data, shared, shared.cast(), ptr, len)
}
}
unsafe fn promotable_odd_to_vec(data: &AtomicPtr<()>, ptr: *const u8, len: usize) -> Vec<u8> {
promotable_to_vec(data, ptr, len, |shared| shared.cast())
}
unsafe fn promotable_odd_to_mut(data: &AtomicPtr<()>, ptr: *const u8, len: usize) -> BytesMut {
promotable_to_mut(data, ptr, len, |shared| shared.cast())
}
unsafe fn promotable_odd_drop(data: &mut AtomicPtr<()>, ptr: *const u8, len: usize) {
data.with_mut(|shared| {
let shared = *shared;
let kind = shared as usize & KIND_MASK;
if kind == KIND_ARC {
release_shared(shared.cast());
} else {
debug_assert_eq!(kind, KIND_VEC);
free_boxed_slice(shared.cast(), ptr, len);
}
});
}
unsafe fn promotable_is_unique(data: &AtomicPtr<()>) -> bool {
let shared = data.load(Ordering::Acquire);
let kind = shared as usize & KIND_MASK;
if kind == KIND_ARC {
let ref_cnt = (*shared.cast::<Shared>()).ref_cnt.load(Ordering::Relaxed);
ref_cnt == 1
} else {
true
}
}
unsafe fn free_boxed_slice(buf: *mut u8, offset: *const u8, len: usize) {
let cap = offset_from(offset, buf) + len;
dealloc(buf, Layout::from_size_align(cap, 1).unwrap())
}
// ===== impl SharedVtable =====
struct Shared {
// Holds arguments to dealloc upon Drop, but otherwise doesn't use them
buf: *mut u8,
cap: usize,
ref_cnt: AtomicUsize,
}
impl Drop for Shared {
fn drop(&mut self) {
unsafe { dealloc(self.buf, Layout::from_size_align(self.cap, 1).unwrap()) }
}
}
// Assert that the alignment of `Shared` is divisible by 2.
// This is a necessary invariant since we depend on allocating `Shared` a
// shared object to implicitly carry the `KIND_ARC` flag in its pointer.
// This flag is set when the LSB is 0.
const _: [(); 0 - mem::align_of::<Shared>() % 2] = []; // Assert that the alignment of `Shared` is divisible by 2.
static SHARED_VTABLE: Vtable = Vtable {
clone: shared_clone,
to_vec: shared_to_vec,
to_mut: shared_to_mut,
is_unique: shared_is_unique,
drop: shared_drop,
};
const KIND_ARC: usize = 0b0;
const KIND_VEC: usize = 0b1;
const KIND_MASK: usize = 0b1;
unsafe fn shared_clone(data: &AtomicPtr<()>, ptr: *const u8, len: usize) -> Bytes {
let shared = data.load(Ordering::Relaxed);
shallow_clone_arc(shared as _, ptr, len)
}
unsafe fn shared_to_vec_impl(shared: *mut Shared, ptr: *const u8, len: usize) -> Vec<u8> {
// Check that the ref_cnt is 1 (unique).
//
// If it is unique, then it is set to 0 with AcqRel fence for the same
// reason in release_shared.
//
// Otherwise, we take the other branch and call release_shared.
if (*shared)
.ref_cnt
.compare_exchange(1, 0, Ordering::AcqRel, Ordering::Relaxed)
.is_ok()
{
// Deallocate the `Shared` instance without running its destructor.
let shared = *Box::from_raw(shared);
let shared = ManuallyDrop::new(shared);
let buf = shared.buf;
let cap = shared.cap;
// Copy back buffer
ptr::copy(ptr, buf, len);
Vec::from_raw_parts(buf, len, cap)
} else {
let v = slice::from_raw_parts(ptr, len).to_vec();
release_shared(shared);
v
}
}
unsafe fn shared_to_vec(data: &AtomicPtr<()>, ptr: *const u8, len: usize) -> Vec<u8> {
shared_to_vec_impl(data.load(Ordering::Relaxed).cast(), ptr, len)
}
unsafe fn shared_to_mut_impl(shared: *mut Shared, ptr: *const u8, len: usize) -> BytesMut {
// The goal is to check if the current handle is the only handle
// that currently has access to the buffer. This is done by
// checking if the `ref_cnt` is currently 1.
//
// The `Acquire` ordering synchronizes with the `Release` as
// part of the `fetch_sub` in `release_shared`. The `fetch_sub`
// operation guarantees that any mutations done in other threads
// are ordered before the `ref_cnt` is decremented. As such,
// this `Acquire` will guarantee that those mutations are
// visible to the current thread.
//
// Otherwise, we take the other branch, copy the data and call `release_shared`.
if (*shared).ref_cnt.load(Ordering::Acquire) == 1 {
// Deallocate the `Shared` instance without running its destructor.
let shared = *Box::from_raw(shared);
let shared = ManuallyDrop::new(shared);
let buf = shared.buf;
let cap = shared.cap;
// Rebuild Vec
let off = offset_from(ptr, buf);
let v = Vec::from_raw_parts(buf, len + off, cap);
let mut b = BytesMut::from_vec(v);
b.advance_unchecked(off);
b
} else {
// Copy the data from Shared in a new Vec, then release it
let v = slice::from_raw_parts(ptr, len).to_vec();
release_shared(shared);
BytesMut::from_vec(v)
}
}
unsafe fn shared_to_mut(data: &AtomicPtr<()>, ptr: *const u8, len: usize) -> BytesMut {
shared_to_mut_impl(data.load(Ordering::Relaxed).cast(), ptr, len)
}
pub(crate) unsafe fn shared_is_unique(data: &AtomicPtr<()>) -> bool {
let shared = data.load(Ordering::Acquire);
let ref_cnt = (*shared.cast::<Shared>()).ref_cnt.load(Ordering::Relaxed);
ref_cnt == 1
}
unsafe fn shared_drop(data: &mut AtomicPtr<()>, _ptr: *const u8, _len: usize) {
data.with_mut(|shared| {
release_shared(shared.cast());
});
}
unsafe fn shallow_clone_arc(shared: *mut Shared, ptr: *const u8, len: usize) -> Bytes {
let old_size = (*shared).ref_cnt.fetch_add(1, Ordering::Relaxed);
if old_size > usize::MAX >> 1 {
crate::abort();
}
Bytes {
ptr,
len,
data: AtomicPtr::new(shared as _),
vtable: &SHARED_VTABLE,
}
}
#[cold]
unsafe fn shallow_clone_vec(
atom: &AtomicPtr<()>,
ptr: *const (),
buf: *mut u8,
offset: *const u8,
len: usize,
) -> Bytes {
// If the buffer is still tracked in a `Vec<u8>`. It is time to
// promote the vec to an `Arc`. This could potentially be called
// concurrently, so some care must be taken.
// First, allocate a new `Shared` instance containing the
// `Vec` fields. It's important to note that `ptr`, `len`,
// and `cap` cannot be mutated without having `&mut self`.
// This means that these fields will not be concurrently
// updated and since the buffer hasn't been promoted to an
// `Arc`, those three fields still are the components of the
// vector.
let shared = Box::new(Shared {
buf,
cap: offset_from(offset, buf) + len,
// Initialize refcount to 2. One for this reference, and one
// for the new clone that will be returned from
// `shallow_clone`.
ref_cnt: AtomicUsize::new(2),
});
let shared = Box::into_raw(shared);
// The pointer should be aligned, so this assert should
// always succeed.
debug_assert!(
0 == (shared as usize & KIND_MASK),
"internal: Box<Shared> should have an aligned pointer",
);
// Try compare & swapping the pointer into the `arc` field.
// `Release` is used synchronize with other threads that
// will load the `arc` field.
//
// If the `compare_exchange` fails, then the thread lost the
// race to promote the buffer to shared. The `Acquire`
// ordering will synchronize with the `compare_exchange`
// that happened in the other thread and the `Shared`
// pointed to by `actual` will be visible.
match atom.compare_exchange(ptr as _, shared as _, Ordering::AcqRel, Ordering::Acquire) {
Ok(actual) => {
debug_assert!(actual as usize == ptr as usize);
// The upgrade was successful, the new handle can be
// returned.
Bytes {
ptr: offset,
len,
data: AtomicPtr::new(shared as _),
vtable: &SHARED_VTABLE,
}
}
Err(actual) => {
// The upgrade failed, a concurrent clone happened. Release
// the allocation that was made in this thread, it will not
// be needed.
let shared = Box::from_raw(shared);
mem::forget(*shared);
// Buffer already promoted to shared storage, so increment ref
// count.
shallow_clone_arc(actual as _, offset, len)
}
}
}
unsafe fn release_shared(ptr: *mut Shared) {
// `Shared` storage... follow the drop steps from Arc.
if (*ptr).ref_cnt.fetch_sub(1, Ordering::Release) != 1 {
return;
}
// This fence is needed to prevent reordering of use of the data and
// deletion of the data. Because it is marked `Release`, the decreasing
// of the reference count synchronizes with this `Acquire` fence. This
// means that use of the data happens before decreasing the reference
// count, which happens before this fence, which happens before the
// deletion of the data.
//
// As explained in the [Boost documentation][1],
//
// > It is important to enforce any possible access to the object in one
// > thread (through an existing reference) to *happen before* deleting
// > the object in a different thread. This is achieved by a "release"
// > operation after dropping a reference (any access to the object
// > through this reference must obviously happened before), and an
// > "acquire" operation before deleting the object.
//
// [1]: (www.boost.org/doc/libs/1_55_0/doc/html/atomic/usage_examples.html)
//
// Thread sanitizer does not support atomic fences. Use an atomic load
// instead.
(*ptr).ref_cnt.load(Ordering::Acquire);
// Drop the data
drop(Box::from_raw(ptr));
}
// Ideally we would always use this version of `ptr_map` since it is strict
// provenance compatible, but it results in worse codegen. We will however still
// use it on miri because it gives better diagnostics for people who test bytes
// code with miri.
//
// See https://github.com/tokio-rs/bytes/pull/545 for more info.
#[cfg(miri)]
fn ptr_map<F>(ptr: *mut u8, f: F) -> *mut u8
where
F: FnOnce(usize) -> usize,
{
let old_addr = ptr as usize;
let new_addr = f(old_addr);
let diff = new_addr.wrapping_sub(old_addr);
ptr.wrapping_add(diff)
}
#[cfg(not(miri))]
fn ptr_map<F>(ptr: *mut u8, f: F) -> *mut u8
where
F: FnOnce(usize) -> usize,
{
let old_addr = ptr as usize;
let new_addr = f(old_addr);
new_addr as *mut u8
}
fn without_provenance(ptr: usize) -> *const u8 {
core::ptr::null::<u8>().wrapping_add(ptr)
}
// compile-fails
/// ```compile_fail
/// use bytes::Bytes;
/// #[deny(unused_must_use)]
/// {
/// let mut b1 = Bytes::from("hello world");
/// b1.split_to(6);
/// }
/// ```
fn _split_to_must_use() {}
/// ```compile_fail
/// use bytes::Bytes;
/// #[deny(unused_must_use)]
/// {
/// let mut b1 = Bytes::from("hello world");
/// b1.split_off(6);
/// }
/// ```
fn _split_off_must_use() {}
// fuzz tests
#[cfg(all(test, loom))]
mod fuzz {
use loom::sync::Arc;
use loom::thread;
use super::Bytes;
#[test]
fn bytes_cloning_vec() {
loom::model(|| {
let a = Bytes::from(b"abcdefgh".to_vec());
let addr = a.as_ptr() as usize;
// test the Bytes::clone is Sync by putting it in an Arc
let a1 = Arc::new(a);
let a2 = a1.clone();
let t1 = thread::spawn(move || {
let b: Bytes = (*a1).clone();
assert_eq!(b.as_ptr() as usize, addr);
});
let t2 = thread::spawn(move || {
let b: Bytes = (*a2).clone();
assert_eq!(b.as_ptr() as usize, addr);
});
t1.join().unwrap();
t2.join().unwrap();
});
}
}