mod errors; pubuseself::errors::{InsertError, PushError, RemoveError};
/// Create a [`KVec`] containing the arguments. /// /// New memory is allocated with `GFP_KERNEL`. /// /// # Examples /// /// ``` /// let mut v = kernel::kvec![]; /// v.push(1, GFP_KERNEL)?; /// assert_eq!(v, [1]); /// /// let mut v = kernel::kvec![1; 3]?; /// v.push(4, GFP_KERNEL)?; /// assert_eq!(v, [1, 1, 1, 4]); /// /// let mut v = kernel::kvec![1, 2, 3]?; /// v.push(4, GFP_KERNEL)?; /// assert_eq!(v, [1, 2, 3, 4]); /// /// # Ok::<(), Error>(()) /// ``` #[macro_export]
macro_rules! kvec {
() => (
$crate::alloc::KVec::new()
);
($elem:expr; $n:expr) => (
$crate::alloc::KVec::from_elem($elem, $n, GFP_KERNEL)
);
($($x:expr),+ $(,)?) => ( match $crate::alloc::KBox::new_uninit(GFP_KERNEL) {
Ok(b) => Ok($crate::alloc::KVec::from($crate::alloc::KBox::write(b, [$($x),+]))),
Err(e) => Err(e),
}
);
}
/// The kernel's [`Vec`] type. /// /// A contiguous growable array type with contents allocated with the kernel's allocators (e.g. /// [`Kmalloc`], [`Vmalloc`] or [`KVmalloc`]), written `Vec<T, A>`. /// /// For non-zero-sized values, a [`Vec`] will use the given allocator `A` for its allocation. For /// the most common allocators the type aliases [`KVec`], [`VVec`] and [`KVVec`] exist. /// /// For zero-sized types the [`Vec`]'s pointer must be `dangling_mut::<T>`; no memory is allocated. /// /// Generally, [`Vec`] consists of a pointer that represents the vector's backing buffer, the /// capacity of the vector (the number of elements that currently fit into the vector), its length /// (the number of elements that are currently stored in the vector) and the `Allocator` type used /// to allocate (and free) the backing buffer. /// /// A [`Vec`] can be deconstructed into and (re-)constructed from its previously named raw parts /// and manually modified. /// /// [`Vec`]'s backing buffer gets, if required, automatically increased (re-allocated) when elements /// are added to the vector. /// /// # Invariants /// /// - `self.ptr` is always properly aligned and either points to memory allocated with `A` or, for /// zero-sized types, is a dangling, well aligned pointer. /// /// - `self.len` always represents the exact number of elements stored in the vector. /// /// - `self.layout` represents the absolute number of elements that can be stored within the vector /// without re-allocation. For ZSTs `self.layout`'s capacity is zero. However, it is legal for the /// backing buffer to be larger than `layout`. /// /// - `self.len()` is always less than or equal to `self.capacity()`. /// /// - The `Allocator` type `A` of the vector is the exact same `Allocator` type the backing buffer /// was allocated with (and must be freed with). pubstruct Vec<T, A: Allocator> {
ptr: NonNull<T>, /// Represents the actual buffer size as `cap` times `size_of::<T>` bytes. /// /// Note: This isn't quite the same as `Self::capacity`, which in contrast returns the number of /// elements we can still store without reallocating.
layout: ArrayLayout<T>,
len: usize,
_p: PhantomData<A>,
}
/// Type alias for [`Vec`] with a [`Kmalloc`] allocator. /// /// # Examples /// /// ``` /// let mut v = KVec::new(); /// v.push(1, GFP_KERNEL)?; /// assert_eq!(&v, &[1]); /// /// # Ok::<(), Error>(()) /// ``` pubtype KVec<T> = Vec<T, Kmalloc>;
/// Type alias for [`Vec`] with a [`Vmalloc`] allocator. /// /// # Examples /// /// ``` /// let mut v = VVec::new(); /// v.push(1, GFP_KERNEL)?; /// assert_eq!(&v, &[1]); /// /// # Ok::<(), Error>(()) /// ``` pubtype VVec<T> = Vec<T, Vmalloc>;
/// Type alias for [`Vec`] with a [`KVmalloc`] allocator. /// /// # Examples /// /// ``` /// let mut v = KVVec::new(); /// v.push(1, GFP_KERNEL)?; /// assert_eq!(&v, &[1]); /// /// # Ok::<(), Error>(()) /// ``` pubtype KVVec<T> = Vec<T, KVmalloc>;
// SAFETY: `Vec` is `Send` if `T` is `Send` because `Vec` owns its elements. unsafeimpl<T, A> Send for Vec<T, A> where
T: Send,
A: Allocator,
{
}
// SAFETY: `Vec` is `Sync` if `T` is `Sync` because `Vec` owns its elements. unsafeimpl<T, A> Sync for Vec<T, A> where
T: Sync,
A: Allocator,
{
}
impl<T, A> Vec<T, A> where
A: Allocator,
{ #[inline] constfn is_zst() -> bool {
core::mem::size_of::<T>() == 0
}
/// Returns the number of elements that can be stored within the vector without allocating /// additional memory. pubfn capacity(&self) -> usize { ifconst { Self::is_zst() } {
usize::MAX
} else { self.layout.len()
}
}
/// Returns the number of elements stored within the vector. #[inline] pubfn len(&self) -> usize { self.len
}
/// Increments `self.len` by `additional`. /// /// # Safety /// /// - `additional` must be less than or equal to `self.capacity - self.len`. /// - All elements within the interval [`self.len`,`self.len + additional`) must be initialized. #[inline] pubunsafefn inc_len(&mutself, additional: usize) { // Guaranteed by the type invariant to never underflow.
debug_assert!(additional <= self.capacity() - self.len()); // INVARIANT: By the safety requirements of this method this represents the exact number of // elements stored within `self`. self.len += additional;
}
/// Decreases `self.len` by `count`. /// /// Returns a mutable slice to the elements forgotten by the vector. It is the caller's /// responsibility to drop these elements if necessary. /// /// # Safety /// /// - `count` must be less than or equal to `self.len`. unsafefn dec_len(&mutself, count: usize) -> &mut [T] {
debug_assert!(count <= self.len()); // INVARIANT: We relinquish ownership of the elements within the range `[self.len - count, // self.len)`, hence the updated value of `set.len` represents the exact number of elements // stored within `self`. self.len -= count; // SAFETY: The memory after `self.len()` is guaranteed to contain `count` initialized // elements of type `T`. unsafe { slice::from_raw_parts_mut(self.as_mut_ptr().add(self.len), count) }
}
/// Returns a slice of the entire vector. #[inline] pubfn as_slice(&self) -> &[T] { self
}
/// Returns a mutable slice of the entire vector. #[inline] pubfn as_mut_slice(&mutself) -> &mut [T] { self
}
/// Returns a mutable raw pointer to the vector's backing buffer, or, if `T` is a ZST, a /// dangling raw pointer. #[inline] pubfn as_mut_ptr(&mutself) -> *mut T { self.ptr.as_ptr()
}
/// Returns a raw pointer to the vector's backing buffer, or, if `T` is a ZST, a dangling raw /// pointer. #[inline] pubfn as_ptr(&self) -> *const T { self.ptr.as_ptr()
}
/// Returns `true` if the vector contains no elements, `false` otherwise. /// /// # Examples /// /// ``` /// let mut v = KVec::new(); /// assert!(v.is_empty()); /// /// v.push(1, GFP_KERNEL); /// assert!(!v.is_empty()); /// ``` #[inline] pubfn is_empty(&self) -> bool { self.len() == 0
}
/// Creates a new, empty `Vec<T, A>`. /// /// This method does not allocate by itself. #[inline] pubconstfn new() -> Self { // INVARIANT: Since this is a new, empty `Vec` with no backing memory yet, // - `ptr` is a properly aligned dangling pointer for type `T`, // - `layout` is an empty `ArrayLayout` (zero capacity) // - `len` is zero, since no elements can be or have been stored, // - `A` is always valid. Self {
ptr: NonNull::dangling(),
layout: ArrayLayout::empty(),
len: 0,
_p: PhantomData::<A>,
}
}
/// Returns a slice of `MaybeUninit<T>` for the remaining spare capacity of the vector. pubfn spare_capacity_mut(&mutself) -> &mut [MaybeUninit<T>] { // SAFETY: // - `self.len` is smaller than `self.capacity` by the type invariant and hence, the // resulting pointer is guaranteed to be part of the same allocated object. // - `self.len` can not overflow `isize`. let ptr = unsafe { self.as_mut_ptr().add(self.len) }.cast::<MaybeUninit<T>>();
// SAFETY: The memory between `self.len` and `self.capacity` is guaranteed to be allocated // and valid, but uninitialized. unsafe { slice::from_raw_parts_mut(ptr, self.capacity() - self.len) }
}
/// Appends an element to the back of the [`Vec`] instance. /// /// # Examples /// /// ``` /// let mut v = KVec::new(); /// v.push(1, GFP_KERNEL)?; /// assert_eq!(&v, &[1]); /// /// v.push(2, GFP_KERNEL)?; /// assert_eq!(&v, &[1, 2]); /// # Ok::<(), Error>(()) /// ``` pubfn push(&mutself, v: T, flags: Flags) -> Result<(), AllocError> { self.reserve(1, flags)?; // SAFETY: The call to `reserve` was successful, so the capacity is at least one greater // than the length. unsafe { self.push_within_capacity_unchecked(v) };
Ok(())
}
/// Appends an element to the back of the [`Vec`] instance without reallocating. /// /// Fails if the vector does not have capacity for the new element. /// /// # Examples /// /// ``` /// let mut v = KVec::with_capacity(10, GFP_KERNEL)?; /// for i in 0..10 { /// v.push_within_capacity(i)?; /// } /// /// assert!(v.push_within_capacity(10).is_err()); /// # Ok::<(), Error>(()) /// ``` pubfn push_within_capacity(&mutself, v: T) -> Result<(), PushError<T>> { ifself.len() < self.capacity() { // SAFETY: The length is less than the capacity. unsafe { self.push_within_capacity_unchecked(v) };
Ok(())
} else {
Err(PushError(v))
}
}
/// Appends an element to the back of the [`Vec`] instance without reallocating. /// /// # Safety /// /// The length must be less than the capacity. unsafefn push_within_capacity_unchecked(&mutself, v: T) { let spare = self.spare_capacity_mut();
// SAFETY: By the safety requirements, `spare` is non-empty. unsafe { spare.get_unchecked_mut(0) }.write(v);
// SAFETY: We just initialised the first spare entry, so it is safe to increase the length // by 1. We also know that the new length is <= capacity because the caller guarantees that // the length is less than the capacity at the beginning of this function. unsafe { self.inc_len(1) };
}
/// Inserts an element at the given index in the [`Vec`] instance. /// /// Fails if the vector does not have capacity for the new element. Panics if the index is out /// of bounds. /// /// # Examples /// /// ``` /// use kernel::alloc::kvec::InsertError; /// /// let mut v = KVec::with_capacity(5, GFP_KERNEL)?; /// for i in 0..5 { /// v.insert_within_capacity(0, i)?; /// } /// /// assert!(matches!(v.insert_within_capacity(0, 5), Err(InsertError::OutOfCapacity(_)))); /// assert!(matches!(v.insert_within_capacity(1000, 5), Err(InsertError::IndexOutOfBounds(_)))); /// assert_eq!(v, [4, 3, 2, 1, 0]); /// # Ok::<(), Error>(()) /// ``` pubfn insert_within_capacity(
&mutself,
index: usize,
element: T,
) -> Result<(), InsertError<T>> { let len = self.len(); if index > len { return Err(InsertError::IndexOutOfBounds(element));
}
if len >= self.capacity() { return Err(InsertError::OutOfCapacity(element));
}
// SAFETY: This is in bounds since `index <= len < capacity`. let p = unsafe { self.as_mut_ptr().add(index) }; // INVARIANT: This breaks the Vec invariants by making `index` contain an invalid element, // but we restore the invariants below. // SAFETY: Both the src and dst ranges end no later than one element after the length. // Since the length is less than the capacity, both ranges are in bounds of the allocation. unsafe { ptr::copy(p, p.add(1), len - index) }; // INVARIANT: This restores the Vec invariants. // SAFETY: The pointer is in-bounds of the allocation. unsafe { ptr::write(p, element) }; // SAFETY: Index `len` contains a valid element due to the above copy and write. unsafe { self.inc_len(1) };
Ok(())
}
/// Removes the last element from a vector and returns it, or `None` if it is empty. /// /// # Examples /// /// ``` /// let mut v = KVec::new(); /// v.push(1, GFP_KERNEL)?; /// v.push(2, GFP_KERNEL)?; /// assert_eq!(&v, &[1, 2]); /// /// assert_eq!(v.pop(), Some(2)); /// assert_eq!(v.pop(), Some(1)); /// assert_eq!(v.pop(), None); /// # Ok::<(), Error>(()) /// ``` pubfn pop(&mutself) -> Option<T> { ifself.is_empty() { return None;
}
let removed: *mut T = { // SAFETY: We just checked that the length is at least one. let slice = unsafe { self.dec_len(1) }; // SAFETY: The argument to `dec_len` was 1 so this returns a slice of length 1. unsafe { slice.get_unchecked_mut(0) }
};
// SAFETY: The guarantees of `dec_len` allow us to take ownership of this value.
Some(unsafe { removed.read() })
}
/// Removes the element at the given index. /// /// # Examples /// /// ``` /// let mut v = kernel::kvec![1, 2, 3]?; /// assert_eq!(v.remove(1)?, 2); /// assert_eq!(v, [1, 3]); /// # Ok::<(), Error>(()) /// ``` pubfn remove(&mutself, i: usize) -> Result<T, RemoveError> { let value = { let value_ref = self.get(i).ok_or(RemoveError)?; // INVARIANT: This breaks the invariants by invalidating the value at index `i`, but we // restore the invariants below. // SAFETY: The value at index `i` is valid, because otherwise we would have already // failed with `RemoveError`. unsafe { ptr::read(value_ref) }
};
// SAFETY: We checked that `i` is in-bounds. let p = unsafe { self.as_mut_ptr().add(i) };
// INVARIANT: After this call, the invalid value is at the last slot, so the Vec invariants // are restored after the below call to `dec_len(1)`. // SAFETY: `p.add(1).add(self.len - i - 1)` is `i+1+len-i-1 == len` elements after the // beginning of the vector, so this is in-bounds of the vector's allocation. unsafe { ptr::copy(p.add(1), p, self.len - i - 1) };
// SAFETY: Since the check at the beginning of this call did not fail with `RemoveError`, // the length is at least one. unsafe { self.dec_len(1) };
Ok(value)
}
/// Creates a new [`Vec`] instance with at least the given capacity. /// /// # Examples /// /// ``` /// let v = KVec::<u32>::with_capacity(20, GFP_KERNEL)?; /// /// assert!(v.capacity() >= 20); /// # Ok::<(), Error>(()) /// ``` pubfn with_capacity(capacity: usize, flags: Flags) -> Result<Self, AllocError> { letmut v = Vec::new();
v.reserve(capacity, flags)?;
Ok(v)
}
/// Creates a `Vec<T, A>` from a pointer, a length and a capacity using the allocator `A`. /// /// # Examples /// /// ``` /// let mut v = kernel::kvec![1, 2, 3]?; /// v.reserve(1, GFP_KERNEL)?; /// /// let (mut ptr, mut len, cap) = v.into_raw_parts(); /// /// // SAFETY: We've just reserved memory for another element. /// unsafe { ptr.add(len).write(4) }; /// len += 1; /// /// // SAFETY: We only wrote an additional element at the end of the `KVec`'s buffer and /// // correspondingly increased the length of the `KVec` by one. Otherwise, we construct it /// // from the exact same raw parts. /// let v = unsafe { KVec::from_raw_parts(ptr, len, cap) }; /// /// assert_eq!(v, [1, 2, 3, 4]); /// /// # Ok::<(), Error>(()) /// ``` /// /// # Safety /// /// If `T` is a ZST: /// /// - `ptr` must be a dangling, well aligned pointer. /// /// Otherwise: /// /// - `ptr` must have been allocated with the allocator `A`. /// - `ptr` must satisfy or exceed the alignment requirements of `T`. /// - `ptr` must point to memory with a size of at least `size_of::<T>() * capacity` bytes. /// - The allocated size in bytes must not be larger than `isize::MAX`. /// - `length` must be less than or equal to `capacity`. /// - The first `length` elements must be initialized values of type `T`. /// /// It is also valid to create an empty `Vec` passing a dangling pointer for `ptr` and zero for /// `cap` and `len`. pubunsafefn from_raw_parts(ptr: *mut T, length: usize, capacity: usize) -> Self { let layout = ifSelf::is_zst() {
ArrayLayout::empty()
} else { // SAFETY: By the safety requirements of this function, `capacity * size_of::<T>()` is // smaller than `isize::MAX`. unsafe { ArrayLayout::new_unchecked(capacity) }
};
// INVARIANT: For ZSTs, we store an empty `ArrayLayout`, all other type invariants are // covered by the safety requirements of this function. Self { // SAFETY: By the safety requirements, `ptr` is either dangling or pointing to a valid // memory allocation, allocated with `A`.
ptr: unsafe { NonNull::new_unchecked(ptr) },
layout,
len: length,
_p: PhantomData::<A>,
}
}
/// Consumes the `Vec<T, A>` and returns its raw components `pointer`, `length` and `capacity`. /// /// This will not run the destructor of the contained elements and for non-ZSTs the allocation /// will stay alive indefinitely. Use [`Vec::from_raw_parts`] to recover the [`Vec`], drop the /// elements and free the allocation, if any. pubfn into_raw_parts(self) -> (*mut T, usize, usize) { letmut me = ManuallyDrop::new(self); let len = me.len(); let capacity = me.capacity(); let ptr = me.as_mut_ptr();
(ptr, len, capacity)
}
/// Clears the vector, removing all values. /// /// Note that this method has no effect on the allocated capacity /// of the vector. /// /// # Examples /// /// ``` /// let mut v = kernel::kvec![1, 2, 3]?; /// /// v.clear(); /// /// assert!(v.is_empty()); /// # Ok::<(), Error>(()) /// ``` #[inline] pubfn clear(&mutself) { self.truncate(0);
}
/// Ensures that the capacity exceeds the length by at least `additional` elements. /// /// # Examples /// /// ``` /// let mut v = KVec::new(); /// v.push(1, GFP_KERNEL)?; /// /// v.reserve(10, GFP_KERNEL)?; /// let cap = v.capacity(); /// assert!(cap >= 10); /// /// v.reserve(10, GFP_KERNEL)?; /// let new_cap = v.capacity(); /// assert_eq!(new_cap, cap); /// /// # Ok::<(), Error>(()) /// ``` pubfn reserve(&mutself, additional: usize, flags: Flags) -> Result<(), AllocError> { let len = self.len(); let cap = self.capacity();
if cap - len >= additional { return Ok(());
}
ifSelf::is_zst() { // The capacity is already `usize::MAX` for ZSTs, we can't go higher. return Err(AllocError);
}
// We know that `cap <= isize::MAX` because of the type invariants of `Self`. So the // multiplication by two won't overflow. let new_cap = core::cmp::max(cap * 2, len.checked_add(additional).ok_or(AllocError)?); let layout = ArrayLayout::new(new_cap).map_err(|_| AllocError)?;
// SAFETY: // - `ptr` is valid because it's either `None` or comes from a previous call to // `A::realloc`. // - `self.layout` matches the `ArrayLayout` of the preceding allocation. let ptr = unsafe {
A::realloc(
Some(self.ptr.cast()),
layout.into(), self.layout.into(),
flags,
)?
};
// INVARIANT: // - `layout` is some `ArrayLayout::<T>`, // - `ptr` has been created by `A::realloc` from `layout`. self.ptr = ptr.cast(); self.layout = layout;
Ok(())
}
/// Shortens the vector, setting the length to `len` and drops the removed values. /// If `len` is greater than or equal to the current length, this does nothing. /// /// This has no effect on the capacity and will not allocate. /// /// # Examples /// /// ``` /// let mut v = kernel::kvec![1, 2, 3]?; /// v.truncate(1); /// assert_eq!(v.len(), 1); /// assert_eq!(&v, &[1]); /// /// # Ok::<(), Error>(()) /// ``` pubfn truncate(&mutself, len: usize) { iflet Some(count) = self.len().checked_sub(len) { // SAFETY: `count` is `self.len() - len` so it is guaranteed to be less than or // equal to `self.len()`. let ptr: *mut [T] = unsafe { self.dec_len(count) };
// SAFETY: the contract of `dec_len` guarantees that the elements in `ptr` are // valid elements whose ownership has been transferred to the caller. unsafe { ptr::drop_in_place(ptr) };
}
}
/// Takes ownership of all items in this vector without consuming the allocation. /// /// # Examples /// /// ``` /// let mut v = kernel::kvec![0, 1, 2, 3]?; /// /// for (i, j) in v.drain_all().enumerate() { /// assert_eq!(i, j); /// } /// /// assert!(v.capacity() >= 4); /// # Ok::<(), Error>(()) /// ``` pubfn drain_all(&mutself) -> DrainAll<'_, T> { // SAFETY: This does not underflow the length. let elems = unsafe { self.dec_len(self.len()) }; // INVARIANT: The first `len` elements of the spare capacity are valid values, and as we // just set the length to zero, we may transfer ownership to the `DrainAll` object.
DrainAll {
elements: elems.iter_mut(),
}
}
impl<T: Clone, A: Allocator> Vec<T, A> { /// Extend the vector by `n` clones of `value`. pubfn extend_with(&mutself, n: usize, value: T, flags: Flags) -> Result<(), AllocError> { if n == 0 { return Ok(());
}
self.reserve(n, flags)?;
let spare = self.spare_capacity_mut();
for item in spare.iter_mut().take(n - 1) {
item.write(value.clone());
}
// We can write the last element directly without cloning needlessly.
spare[n - 1].write(value);
// SAFETY: // - `self.len() + n < self.capacity()` due to the call to reserve above, // - the loop and the line above initialized the next `n` elements. unsafe { self.inc_len(n) };
Ok(())
}
/// Pushes clones of the elements of slice into the [`Vec`] instance. /// /// # Examples /// /// ``` /// let mut v = KVec::new(); /// v.push(1, GFP_KERNEL)?; /// /// v.extend_from_slice(&[20, 30, 40], GFP_KERNEL)?; /// assert_eq!(&v, &[1, 20, 30, 40]); /// /// v.extend_from_slice(&[50, 60], GFP_KERNEL)?; /// assert_eq!(&v, &[1, 20, 30, 40, 50, 60]); /// # Ok::<(), Error>(()) /// ``` pubfn extend_from_slice(&mutself, other: &[T], flags: Flags) -> Result<(), AllocError> { self.reserve(other.len(), flags)?; for (slot, item) in core::iter::zip(self.spare_capacity_mut(), other) {
slot.write(item.clone());
}
// SAFETY: // - `other.len()` spare entries have just been initialized, so it is safe to increase // the length by the same number. // - `self.len() + other.len() <= self.capacity()` is guaranteed by the preceding `reserve` // call. unsafe { self.inc_len(other.len()) };
Ok(())
}
/// Create a new `Vec<T, A>` and extend it by `n` clones of `value`. pubfn from_elem(value: T, n: usize, flags: Flags) -> Result<Self, AllocError> { letmut v = Self::with_capacity(n, flags)?;
v.extend_with(n, value, flags)?;
Ok(v)
}
/// Resizes the [`Vec`] so that `len` is equal to `new_len`. /// /// If `new_len` is smaller than `len`, the `Vec` is [`Vec::truncate`]d. /// If `new_len` is larger, each new slot is filled with clones of `value`. /// /// # Examples /// /// ``` /// let mut v = kernel::kvec![1, 2, 3]?; /// v.resize(1, 42, GFP_KERNEL)?; /// assert_eq!(&v, &[1]); /// /// v.resize(3, 42, GFP_KERNEL)?; /// assert_eq!(&v, &[1, 42, 42]); /// /// # Ok::<(), Error>(()) /// ``` pubfn resize(&mutself, new_len: usize, value: T, flags: Flags) -> Result<(), AllocError> { match new_len.checked_sub(self.len()) {
Some(n) => self.extend_with(n, value, flags),
None => { self.truncate(new_len);
Ok(())
}
}
}
}
impl<T, A> Drop for Vec<T, A> where
A: Allocator,
{ fn drop(&mutself) { // SAFETY: `self.as_mut_ptr` is guaranteed to be valid by the type invariant. unsafe {
ptr::drop_in_place(core::ptr::slice_from_raw_parts_mut( self.as_mut_ptr(), self.len,
))
};
// SAFETY: // - `self.ptr` was previously allocated with `A`. // - `self.layout` matches the `ArrayLayout` of the preceding allocation. unsafe { A::free(self.ptr.cast(), self.layout.into()) };
}
}
impl<T, A, const N: usize> From<Box<[T; N], A>> for Vec<T, A> where
A: Allocator,
{ fn from(b: Box<[T; N], A>) -> Vec<T, A> { let len = b.len(); let ptr = Box::into_raw(b);
// SAFETY: // - `b` has been allocated with `A`, // - `ptr` fulfills the alignment requirements for `T`, // - `ptr` points to memory with at least a size of `size_of::<T>() * len`, // - all elements within `b` are initialized values of `T`, // - `len` does not exceed `isize::MAX`. unsafe { Vec::from_raw_parts(ptr.cast(), len, len) }
}
}
impl<T, A: Allocator> Default for Vec<T, A> { #[inline] fn default() -> Self { Self::new()
}
}
impl<T, A> Deref for Vec<T, A> where
A: Allocator,
{ type Target = [T];
#[inline] fn deref(&self) -> &[T] { // SAFETY: The memory behind `self.as_ptr()` is guaranteed to contain `self.len` // initialized elements of type `T`. unsafe { slice::from_raw_parts(self.as_ptr(), self.len) }
}
}
impl<T, A> DerefMut for Vec<T, A> where
A: Allocator,
{ #[inline] fn deref_mut(&mutself) -> &mut [T] { // SAFETY: The memory behind `self.as_ptr()` is guaranteed to contain `self.len` // initialized elements of type `T`. unsafe { slice::from_raw_parts_mut(self.as_mut_ptr(), self.len) }
}
}
/// # Examples /// /// ``` /// # use core::borrow::Borrow; /// struct Foo<B: Borrow<[u32]>>(B); /// /// // Owned array. /// let owned_array = Foo([1, 2, 3]); /// /// // Owned vector. /// let owned_vec = Foo(KVec::from_elem(0, 3, GFP_KERNEL)?); /// /// let arr = [1, 2, 3]; /// // Borrowed slice from `arr`. /// let borrowed_slice = Foo(&arr[..]); /// # Ok::<(), Error>(()) /// ``` impl<T, A> Borrow<[T]> for Vec<T, A> where
A: Allocator,
{ fn borrow(&self) -> &[T] { self.as_slice()
}
}
/// # Examples /// /// ``` /// # use core::borrow::BorrowMut; /// struct Foo<B: BorrowMut<[u32]>>(B); /// /// // Owned array. /// let owned_array = Foo([1, 2, 3]); /// /// // Owned vector. /// let owned_vec = Foo(KVec::from_elem(0, 3, GFP_KERNEL)?); /// /// let mut arr = [1, 2, 3]; /// // Borrowed slice from `arr`. /// let borrowed_slice = Foo(&mut arr[..]); /// # Ok::<(), Error>(()) /// ``` impl<T, A> BorrowMut<[T]> for Vec<T, A> where
A: Allocator,
{ fn borrow_mut(&mutself) -> &mut [T] { self.as_mut_slice()
}
}
impl<T: Eq, A> Eq for Vec<T, A> where A: Allocator {}
impl<T, I: SliceIndex<[T]>, A> Index<I> for Vec<T, A> where
A: Allocator,
{ type Output = I::Output;
/// An [`Iterator`] implementation for [`Vec`] that moves elements out of a vector. /// /// This structure is created by the [`Vec::into_iter`] method on [`Vec`] (provided by the /// [`IntoIterator`] trait). /// /// # Examples /// /// ``` /// let v = kernel::kvec![0, 1, 2]?; /// let iter = v.into_iter(); /// /// # Ok::<(), Error>(()) /// ``` pubstruct IntoIter<T, A: Allocator> {
ptr: *mut T,
buf: NonNull<T>,
len: usize,
layout: ArrayLayout<T>,
_p: PhantomData<A>,
}
impl<T, A> IntoIter<T, A> where
A: Allocator,
{ fn into_raw_parts(self) -> (*mut T, NonNull<T>, usize, usize) { let me = ManuallyDrop::new(self); let ptr = me.ptr; let buf = me.buf; let len = me.len; let cap = me.layout.len();
(ptr, buf, len, cap)
}
/// Same as `Iterator::collect` but specialized for `Vec`'s `IntoIter`. /// /// # Examples /// /// ``` /// let v = kernel::kvec![1, 2, 3]?; /// let mut it = v.into_iter(); /// /// assert_eq!(it.next(), Some(1)); /// /// let v = it.collect(GFP_KERNEL); /// assert_eq!(v, [2, 3]); /// /// # Ok::<(), Error>(()) /// ``` /// /// # Implementation details /// /// Currently, we can't implement `FromIterator`. There are a couple of issues with this trait /// in the kernel, namely: /// /// - Rust's specialization feature is unstable. This prevents us to optimize for the special /// case where `I::IntoIter` equals `Vec`'s `IntoIter` type. /// - We also can't use `I::IntoIter`'s type ID either to work around this, since `FromIterator` /// doesn't require this type to be `'static`. /// - `FromIterator::from_iter` does return `Self` instead of `Result<Self, AllocError>`, hence /// we can't properly handle allocation failures. /// - Neither `Iterator::collect` nor `FromIterator::from_iter` can handle additional allocation /// flags. /// /// Instead, provide `IntoIter::collect`, such that we can at least convert a `IntoIter` into a /// `Vec` again. /// /// Note that `IntoIter::collect` doesn't require `Flags`, since it re-uses the existing backing /// buffer. However, this backing buffer may be shrunk to the actual count of elements. pubfn collect(self, flags: Flags) -> Vec<T, A> { let old_layout = self.layout; let (mut ptr, buf, len, mut cap) = self.into_raw_parts(); let has_advanced = ptr != buf.as_ptr();
if has_advanced { // Copy the contents we have advanced to at the beginning of the buffer. // // SAFETY: // - `ptr` is valid for reads of `len * size_of::<T>()` bytes, // - `buf.as_ptr()` is valid for writes of `len * size_of::<T>()` bytes, // - `ptr` and `buf.as_ptr()` are not be subject to aliasing restrictions relative to // each other, // - both `ptr` and `buf.ptr()` are properly aligned. unsafe { ptr::copy(ptr, buf.as_ptr(), len) };
ptr = buf.as_ptr();
// SAFETY: `len` is guaranteed to be smaller than `self.layout.len()` by the type // invariant. let layout = unsafe { ArrayLayout::<T>::new_unchecked(len) };
// SAFETY: `buf` points to the start of the backing buffer and `len` is guaranteed by // the type invariant to be smaller than `cap`. Depending on `realloc` this operation // may shrink the buffer or leave it as it is.
ptr = matchunsafe {
A::realloc(Some(buf.cast()), layout.into(), old_layout.into(), flags)
} { // If we fail to shrink, which likely can't even happen, continue with the existing // buffer.
Err(_) => ptr,
Ok(ptr) => {
cap = len;
ptr.as_ptr().cast()
}
};
}
// SAFETY: If the iterator has been advanced, the advanced elements have been copied to // the beginning of the buffer and `len` has been adjusted accordingly. // // - `ptr` is guaranteed to point to the start of the backing buffer. // - `cap` is either the original capacity or, after shrinking the buffer, equal to `len`. // - `alloc` is guaranteed to be unchanged since `into_iter` has been called on the original // `Vec`. unsafe { Vec::from_raw_parts(ptr, len, cap) }
}
}
impl<T, A> Iterator for IntoIter<T, A> where
A: Allocator,
{ type Item = T;
// SAFETY: We can't overflow; decreasing `self.len` by one every time we advance `self.ptr` // by one guarantees that. unsafe { self.ptr = self.ptr.add(1) };
self.len -= 1;
// SAFETY: `current` is guaranteed to point at a valid element within the buffer.
Some(unsafe { current.read() })
}
impl<T, A> Drop for IntoIter<T, A> where
A: Allocator,
{ fn drop(&mutself) { // SAFETY: `self.ptr` is guaranteed to be valid by the type invariant. unsafe { ptr::drop_in_place(ptr::slice_from_raw_parts_mut(self.ptr, self.len)) };
// SAFETY: // - `self.buf` was previously allocated with `A`. // - `self.layout` matches the `ArrayLayout` of the preceding allocation. unsafe { A::free(self.buf.cast(), self.layout.into()) };
}
}
impl<T, A> IntoIterator for Vec<T, A> where
A: Allocator,
{ type Item = T; type IntoIter = IntoIter<T, A>;
/// Consumes the `Vec<T, A>` and creates an `Iterator`, which moves each value out of the /// vector (from start to end). /// /// # Examples /// /// ``` /// let v = kernel::kvec![1, 2]?; /// let mut v_iter = v.into_iter(); /// /// let first_element: Option<u32> = v_iter.next(); /// /// assert_eq!(first_element, Some(1)); /// assert_eq!(v_iter.next(), Some(2)); /// assert_eq!(v_iter.next(), None); /// /// # Ok::<(), Error>(()) /// ``` /// /// ``` /// let v = kernel::kvec![]; /// let mut v_iter = v.into_iter(); /// /// let first_element: Option<u32> = v_iter.next(); /// /// assert_eq!(first_element, None); /// /// # Ok::<(), Error>(()) /// ``` #[inline] fn into_iter(self) -> Self::IntoIter { let buf = self.ptr; let layout = self.layout; let (ptr, len, _) = self.into_raw_parts();
/// An iterator that owns all items in a vector, but does not own its allocation. /// /// # Invariants /// /// Every `&mut T` returned by the iterator references a `T` that the iterator may take ownership /// of. pubstruct DrainAll<'vec, T> {
elements: slice::IterMut<'vec, T>,
}
impl<'vec, T> Iterator for DrainAll<'vec, T> { type Item = T;
fn next(&mutself) -> Option<T> { let elem: *mut T = self.elements.next()?; // SAFETY: By the type invariants, we may take ownership of this value.
Some(unsafe { elem.read() })
}
impl<'vec, T> Drop for DrainAll<'vec, T> { fn drop(&mutself) { if core::mem::needs_drop::<T>() { let iter = core::mem::take(&mutself.elements); let ptr: *mut [T] = iter.into_slice(); // SAFETY: By the type invariants, we own these values so we may destroy them. unsafe { ptr::drop_in_place(ptr) };
}
}
}
#[macros::kunit_tests(rust_kvec_kunit)] mod tests { usesuper::*; usecrate::prelude::*;
#[test] fn test_kvec_retain() { /// Verify correctness for one specific function. #[expect(clippy::needless_range_loop)] fn verify(c: &[bool]) { letmut vec1: KVec<usize> = KVec::with_capacity(c.len(), GFP_KERNEL).unwrap(); letmut vec2: KVec<usize> = KVec::with_capacity(c.len(), GFP_KERNEL).unwrap();
for i in0..c.len() {
vec1.push_within_capacity(i).unwrap(); if c[i] {
vec2.push_within_capacity(i).unwrap();
}
}
vec1.retain(|i| c[*i]);
assert_eq!(vec1, vec2);
}
/// Add one to a binary integer represented as a boolean array. fn add(value: &mut [bool]) { letmut carry = true; for v in value { let new_v = carry != *v;
carry = carry && *v;
*v = new_v;
}
}
// This boolean array represents a function from index to boolean. We check that `retain` // behaves correctly for all possible boolean arrays of every possible length less than // ten. letmut func = KVec::with_capacity(10, GFP_KERNEL).unwrap(); for len in0..10 { for _ in0u32..1u32 << len {
verify(&func);
add(&mut func);
}
func.push_within_capacity(false).unwrap();
}
}
}
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