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use std::{borrow::Borrow, ops::Deref};
use crate::sync::Lrc;
// Use our fake Send/Sync traits when on not parallel compiler,
// so that `OwnedSlice` only implements/requires Send/Sync
// for parallel compiler builds.
use crate::sync;
/// An owned slice.
///
/// This is similar to `Lrc<[u8]>` but allows slicing and using anything as the
/// backing buffer.
///
/// See [`slice_owned`] for `OwnedSlice` construction and examples.
///
/// ---------------------------------------------------------------------------
///
/// This is essentially a replacement for `owning_ref` which is a lot simpler
/// and even sound! 🌸
#[derive(Clone)]
pub struct OwnedSlice {
/// This is conceptually a `&'self.owner [u8]`.
bytes: *const [u8],
// +---------------------------------------+
// | We expect `dead_code` lint here, |
// | because we don't want to accidentally |
// | touch the owner — otherwise the owner |
// | could invalidate out `bytes` pointer |
// | |
// | so be quiet |
// +----+ +-------------------------------+
// \/
// ⊂(´・◡・⊂ )∘˚˳° (I am the phantom remnant of #97770)
#[expect(dead_code)]
owner: Lrc<dyn sync::Send + sync::Sync>,
}
/// Makes an [`OwnedSlice`] out of an `owner` and a `slicer` function.
///
/// ## Examples
///
/// ```rust
/// # use rustc_data_structures::owned_slice::{OwnedSlice, slice_owned};
/// let vec = vec![1, 2, 3, 4];
///
/// // Identical to slicing via `&v[1..3]` but produces an owned slice
/// let slice: OwnedSlice = slice_owned(vec, |v| &v[1..3]);
/// assert_eq!(&*slice, [2, 3]);
/// ```
///
/// ```rust
/// # use rustc_data_structures::owned_slice::{OwnedSlice, slice_owned};
/// # use std::ops::Deref;
/// let vec = vec![1, 2, 3, 4];
///
/// // Identical to slicing via `&v[..]` but produces an owned slice
/// let slice: OwnedSlice = slice_owned(vec, Deref::deref);
/// assert_eq!(&*slice, [1, 2, 3, 4]);
/// ```
pub fn slice_owned<O, F>(owner: O, slicer: F) -> OwnedSlice
where
O: sync::Send + sync::Sync + 'static,
F: FnOnce(&O) -> &[u8],
{
try_slice_owned(owner, |x| Ok::<_, !>(slicer(x))).into_ok()
}
/// Makes an [`OwnedSlice`] out of an `owner` and a `slicer` function that can fail.
///
/// See [`slice_owned`] for the infallible version.
pub fn try_slice_owned<O, F, E>(owner: O, slicer: F) -> Result<OwnedSlice, E>
where
O: sync::Send + sync::Sync + 'static,
F: FnOnce(&O) -> Result<&[u8], E>,
{
// We wrap the owner of the bytes in, so it doesn't move.
//
// Since the owner does not move and we don't access it in any way
// before dropping, there is nothing that can invalidate the bytes pointer.
//
// Thus, "extending" the lifetime of the reference returned from `F` is fine.
// We pretend that we pass it a reference that lives as long as the returned slice.
//
// N.B. the HRTB on the `slicer` is important — without it the caller could provide
// a short lived slice, unrelated to the owner.
let owner = Lrc::new(owner);
let bytes = slicer(&*owner)?;
Ok(OwnedSlice { bytes, owner })
}
impl OwnedSlice {
/// Slice this slice by `slicer`.
///
/// # Examples
///
/// ```rust
/// # use rustc_data_structures::owned_slice::{OwnedSlice, slice_owned};
/// let vec = vec![1, 2, 3, 4];
///
/// // Identical to slicing via `&v[1..3]` but produces an owned slice
/// let slice: OwnedSlice = slice_owned(vec, |v| &v[..]);
/// assert_eq!(&*slice, [1, 2, 3, 4]);
///
/// let slice = slice.slice(|slice| &slice[1..][..2]);
/// assert_eq!(&*slice, [2, 3]);
/// ```
///
pub fn slice(self, slicer: impl FnOnce(&[u8]) -> &[u8]) -> OwnedSlice {
// This is basically identical to `try_slice_owned`,
// `slicer` can only return slices of its argument or some static data,
// both of which are valid while `owner` is alive.
let bytes = slicer(&self);
OwnedSlice { bytes, ..self }
}
}
impl Deref for OwnedSlice {
type Target = [u8];
#[inline]
fn deref(&self) -> &[u8] {
// Safety:
// `self.bytes` is valid per the construction in `slice_owned`
// (which is the only constructor)
unsafe { &*self.bytes }
}
}
impl Borrow<[u8]> for OwnedSlice {
#[inline]
fn borrow(&self) -> &[u8] {
self
}
}
// Safety: `OwnedSlice` is conceptually `(&'self.1 [u8], Arc<dyn Send + Sync>)`, which is `Send`
#[cfg(parallel_compiler)]
unsafe impl sync::Send for OwnedSlice {}
// Safety: `OwnedSlice` is conceptually `(&'self.1 [u8], Arc<dyn Send + Sync>)`, which is `Sync`
#[cfg(parallel_compiler)]
unsafe impl sync::Sync for OwnedSlice {}
#[cfg(test)]
mod tests;