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Introduce the AppendOnlyVec struct for the parallel computing
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milli/src/update/new/append_only_vec.rs
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327
milli/src/update/new/append_only_vec.rs
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// Code taken from <https://github.com/droundy/append-only-vec/blob/main/src/lib.rs>
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// and modified in order to get a ref mut instead of the index of newly inserted items.
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//! AppendOnlyVec
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//!
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//! This is a pretty simple type, which is a vector that you can push into and
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//! receive a reference to the item you just inserted. The data structure never
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//! moves an element once allocated, so you can push to the vec even while holding
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//! mutable references to elements that have already been pushed.
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//!
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//! ### Scaling
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//!
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//! 1. Accessing an element is O(1), but slightly more expensive than for a
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//! standard `Vec`.
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//!
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//! 2. Pushing a new element amortizes to O(1), but may require allocation of a
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//! new chunk.
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//!
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//! ### Example
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//!
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//! ```
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//! use append_only_vec::AppendOnlyVec;
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//!
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//! static V: AppendOnlyVec<String> = AppendOnlyVec::<String>::new();
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//! let mut threads = Vec::new();
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//! for thread_num in 0..10 {
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//! threads.push(std::thread::spawn(move || {
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//! for n in 0..100 {
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//! let s = format!("thread {} says {}", thread_num, n);
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//! let which = V.push(s.clone());
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//! assert_eq!(&which, &s);
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//! }
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//! }));
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//! }
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//!
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//! for t in threads {
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//! t.join();
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//! }
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//!
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//! assert_eq!(V.len(), 1000);
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//! ```
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use std::cell::UnsafeCell;
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use std::fmt::Debug;
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use std::ptr;
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use std::sync::atomic::{AtomicUsize, Ordering};
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pub struct AppendOnlyVec<T> {
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count: AtomicUsize,
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_reserved: AtomicUsize,
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data: [UnsafeCell<*mut T>; BITS_USED - 1 - 3],
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}
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unsafe impl<T: Send> Send for AppendOnlyVec<T> {}
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unsafe impl<T: Sync + Send> Sync for AppendOnlyVec<T> {}
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const BITS: usize = std::mem::size_of::<usize>() * 8;
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#[cfg(target_arch = "x86_64")]
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const BITS_USED: usize = 48;
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#[cfg(all(not(target_arch = "x86_64"), target_pointer_width = "64"))]
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const BITS_USED: usize = 64;
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#[cfg(target_pointer_width = "32")]
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const BITS_USED: usize = 32;
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// This takes an index into a vec, and determines which data array will hold it
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// (the first return value), and what the index will be into that data array
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// (second return value)
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//
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// The ith data array holds 1<<i values.
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const fn indices(i: usize) -> (u32, usize) {
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let i = i + 8;
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let bin = BITS as u32 - 1 - i.leading_zeros();
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let bin = bin - 3;
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let offset = i - bin_size(bin);
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(bin, offset)
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}
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const fn bin_size(array: u32) -> usize {
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(1 << 3) << array
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}
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#[test]
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fn test_indices() {
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for i in 0..32 {
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println!("{:3}: {} {}", i, indices(i).0, indices(i).1);
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}
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let mut array = 0;
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let mut offset = 0;
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let mut index = 0;
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while index < 1000 {
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index += 1;
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offset += 1;
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if offset >= bin_size(array) {
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offset = 0;
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array += 1;
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}
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assert_eq!(indices(index), (array, offset));
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}
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}
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impl<T> Default for AppendOnlyVec<T> {
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fn default() -> Self {
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Self::new()
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}
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}
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impl<T> AppendOnlyVec<T> {
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const EMPTY: UnsafeCell<*mut T> = UnsafeCell::new(ptr::null_mut());
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/// Allocate a new empty array.
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pub const fn new() -> Self {
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AppendOnlyVec {
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count: AtomicUsize::new(0),
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_reserved: AtomicUsize::new(0),
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data: [Self::EMPTY; BITS_USED - 1 - 3],
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}
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}
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/// Find the length of the array.
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#[inline]
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pub fn len(&self) -> usize {
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self.count.load(Ordering::Acquire)
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}
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fn layout(array: u32) -> std::alloc::Layout {
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std::alloc::Layout::array::<T>(bin_size(array)).unwrap()
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}
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/// Append an element to the array and get a mutable ref to it.
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///
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/// This is notable in that it doesn't require a `&mut self`, because it
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/// does appropriate atomic synchronization.
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pub fn push(&self, val: T) -> &mut T {
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let idx = self._reserved.fetch_add(1, Ordering::Relaxed);
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let (array, offset) = indices(idx);
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let ptr = if self.len() < 1 + idx - offset {
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// We are working on a new array, which may not have been allocated...
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if offset == 0 {
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// It is our job to allocate the array! The size of the array
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// is determined in the self.layout method, which needs to be
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// consistent with the indices function.
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let layout = Self::layout(array);
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let ptr = unsafe { std::alloc::alloc(layout) } as *mut T;
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unsafe {
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*self.data[array as usize].get() = ptr;
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}
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ptr
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} else {
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// We need to wait for the array to be allocated.
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while self.len() < 1 + idx - offset {
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std::hint::spin_loop();
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}
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// The Ordering::Acquire semantics of self.len() ensures that
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// this pointer read will get the non-null pointer allocated
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// above.
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unsafe { *self.data[array as usize].get() }
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}
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} else {
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// The Ordering::Acquire semantics of self.len() ensures that
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// this pointer read will get the non-null pointer allocated
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// above.
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unsafe { *self.data[array as usize].get() }
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};
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// The contents of this offset are guaranteed to be unused (so far)
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// because we got the idx from our fetch_add above, and ptr is
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// guaranteed to be valid because of the loop we used above, which used
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// self.len() which has Ordering::Acquire semantics.
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unsafe { (ptr.add(offset)).write(val) };
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// Now we need to increase the size of the vec, so it can get read. We
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// use Release upon success, to ensure that the value which we wrote is
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// visible to any thread that has confirmed that the count is big enough
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// to read that element. In case of failure, we can be relaxed, since
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// we don't do anything with the result other than try again.
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while self
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.count
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.compare_exchange(idx, idx + 1, Ordering::Release, Ordering::Relaxed)
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.is_err()
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{
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// This means that someone else *started* pushing before we started,
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// but hasn't yet finished. We have to wait for them to finish
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// pushing before we can update the count. Note that using a
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// spinloop here isn't really ideal, but except when allocating a
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// new array, the window between reserving space and using it is
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// pretty small, so contention will hopefully be rare, and having a
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// context switch during that interval will hopefully be vanishingly
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// unlikely.
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std::hint::spin_loop();
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}
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unsafe { &mut *ptr }
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}
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/// Convert into a standard `Vec`.
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pub fn into_vec(self) -> Vec<T> {
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let mut vec = Vec::with_capacity(self.len());
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for idx in 0..self.len() {
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let (array, offset) = indices(idx);
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// We use a Relaxed load of the pointer, because the loop above (which
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// ends before `self.len()`) should ensure that the data we want is
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// already visible, since it Acquired `self.count` which synchronizes
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// with the write in `self.push`.
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let ptr = unsafe { *self.data[array as usize].get() };
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// Copy the element value. The copy remaining in the array must not
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// be used again (i.e. make sure we do not drop it)
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let value = unsafe { ptr.add(offset).read() };
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vec.push(value);
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}
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// Prevent dropping the copied-out values by marking the count as 0 before
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// our own drop is run
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self.count.store(0, Ordering::Relaxed);
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vec
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}
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}
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impl<T> Debug for AppendOnlyVec<T> {
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fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
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f.debug_struct("AppendOnlyVec").field("len", &self.len()).finish()
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}
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}
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impl<T> Drop for AppendOnlyVec<T> {
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fn drop(&mut self) {
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// First we'll drop all the `T` in a slightly sloppy way. FIXME this
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// could be optimized to avoid reloading the `ptr`.
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for idx in 0..self.len() {
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let (array, offset) = indices(idx);
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// We use a Relaxed load of the pointer, because the loop above (which
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// ends before `self.len()`) should ensure that the data we want is
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// already visible, since it Acquired `self.count` which synchronizes
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// with the write in `self.push`.
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let ptr = unsafe { *self.data[array as usize].get() };
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unsafe {
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ptr::drop_in_place(ptr.add(offset));
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}
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}
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// Now we will free all the arrays.
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for array in 0..self.data.len() as u32 {
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// This load is relaxed because no other thread can have a reference
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// to Self because we have a &mut self.
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let ptr = unsafe { *self.data[array as usize].get() };
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if !ptr.is_null() {
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let layout = Self::layout(array);
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unsafe { std::alloc::dealloc(ptr as *mut u8, layout) };
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} else {
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break;
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}
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}
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}
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}
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impl<T> IntoIterator for AppendOnlyVec<T> {
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type Item = T;
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type IntoIter = std::vec::IntoIter<T>;
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fn into_iter(self) -> Self::IntoIter {
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self.into_vec().into_iter()
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}
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}
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#[test]
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fn test_parallel_pushing() {
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use std::sync::Arc;
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let v = Arc::new(AppendOnlyVec::<u64>::new());
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let mut threads = Vec::new();
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const N: u64 = 100;
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for thread_num in 0..N {
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let v = v.clone();
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threads.push(std::thread::spawn(move || {
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let which1 = v.push(thread_num);
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let which2 = v.push(thread_num);
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assert_eq!(*which1, thread_num);
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assert_eq!(*which2, thread_num);
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}));
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}
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for t in threads {
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t.join().unwrap();
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}
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let v = Arc::into_inner(v).unwrap().into_vec();
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for thread_num in 0..N {
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assert_eq!(2, v.iter().copied().filter(|&x| x == thread_num).count());
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}
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}
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#[test]
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fn test_into_vec() {
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struct SafeToDrop(bool);
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impl Drop for SafeToDrop {
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fn drop(&mut self) {
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assert!(self.0);
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}
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}
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let v = AppendOnlyVec::new();
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for _ in 0..50 {
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v.push(SafeToDrop(false));
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}
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let mut v = v.into_vec();
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assert_eq!(v.len(), 50);
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for i in v.iter_mut() {
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i.0 = true;
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}
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}
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#[test]
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fn test_push_then_index_mut() {
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let v = AppendOnlyVec::<usize>::new();
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for i in 0..1024 {
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*v.push(i) += 1;
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}
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let v = v.into_vec();
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for i in 0..1024 {
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assert_eq!(v[i], 2 * i);
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}
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}
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@ -5,6 +5,7 @@ pub use top_level_map::{CowStr, TopLevelMap};
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use super::del_add::DelAdd;
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use crate::FieldId;
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mod append_only_vec;
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mod channel;
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mod document_change;
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mod extract;
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