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// SPDX-License-Identifier: GPL-2.0
// Copyright (C) 2025 Google LLC.
use kernel::{page::PAGE_SIZE, prelude::*, seq_file::SeqFile, task::Pid};
mod tree;
use self::tree::{FromArrayAllocs, ReserveNewTreeAlloc, TreeRangeAllocator};
mod array;
use self::array::{ArrayRangeAllocator, EmptyArrayAlloc};
enum DescriptorState<T> {
Reserved(Reservation),
Allocated(Allocation<T>),
}
impl<T> DescriptorState<T> {
fn new(is_oneway: bool, debug_id: usize, pid: Pid) -> Self {
DescriptorState::Reserved(Reservation {
debug_id,
is_oneway,
pid,
})
}
fn pid(&self) -> Pid {
match self {
DescriptorState::Reserved(inner) => inner.pid,
DescriptorState::Allocated(inner) => inner.reservation.pid,
}
}
fn is_oneway(&self) -> bool {
match self {
DescriptorState::Reserved(inner) => inner.is_oneway,
DescriptorState::Allocated(inner) => inner.reservation.is_oneway,
}
}
}
#[derive(Clone)]
struct Reservation {
debug_id: usize,
is_oneway: bool,
pid: Pid,
}
impl Reservation {
fn allocate<T>(self, data: Option<T>) -> Allocation<T> {
Allocation {
data,
reservation: self,
}
}
}
struct Allocation<T> {
reservation: Reservation,
data: Option<T>,
}
impl<T> Allocation<T> {
fn deallocate(self) -> (Reservation, Option<T>) {
(self.reservation, self.data)
}
fn debug_id(&self) -> usize {
self.reservation.debug_id
}
fn take(&mut self) -> Option<T> {
self.data.take()
}
}
/// The array implementation must switch to the tree if it wants to go beyond this number of
/// ranges.
const TREE_THRESHOLD: usize = 8;
/// Represents a range of pages that have just become completely free.
#[derive(Copy, Clone)]
pub(crate) struct FreedRange {
pub(crate) start_page_idx: usize,
pub(crate) end_page_idx: usize,
}
impl FreedRange {
fn interior_pages(offset: usize, size: usize) -> FreedRange {
FreedRange {
// Divide round up
start_page_idx: offset.div_ceil(PAGE_SIZE),
// Divide round down
end_page_idx: (offset + size) / PAGE_SIZE,
}
}
}
struct Range<T> {
offset: usize,
size: usize,
state: DescriptorState<T>,
}
impl<T> Range<T> {
fn endpoint(&self) -> usize {
self.offset + self.size
}
}
pub(crate) struct RangeAllocator<T> {
inner: Impl<T>,
}
enum Impl<T> {
Empty(usize),
Array(ArrayRangeAllocator<T>),
Tree(TreeRangeAllocator<T>),
}
impl<T> RangeAllocator<T> {
pub(crate) fn new(size: usize) -> Self {
Self {
inner: Impl::Empty(size),
}
}
pub(crate) fn free_oneway_space(&self) -> usize {
match &self.inner {
Impl::Empty(size) => size / 2,
Impl::Array(array) => array.free_oneway_space(),
Impl::Tree(tree) => tree.free_oneway_space(),
}
}
pub(crate) fn count_buffers(&self) -> usize {
match &self.inner {
Impl::Empty(_size) => 0,
Impl::Array(array) => array.count_buffers(),
Impl::Tree(tree) => tree.count_buffers(),
}
}
pub(crate) fn debug_print(&self, m: &SeqFile) -> Result<()> {
match &self.inner {
Impl::Empty(_size) => Ok(()),
Impl::Array(array) => array.debug_print(m),
Impl::Tree(tree) => tree.debug_print(m),
}
}
/// Try to reserve a new buffer, using the provided allocation if necessary.
pub(crate) fn reserve_new(&mut self, mut args: ReserveNewArgs<T>) -> Result<ReserveNew<T>> {
match &mut self.inner {
Impl::Empty(size) => {
let empty_array = match args.empty_array_alloc.take() {
Some(empty_array) => ArrayRangeAllocator::new(*size, empty_array),
None => {
return Ok(ReserveNew::NeedAlloc(ReserveNewNeedAlloc {
args,
need_empty_array_alloc: true,
need_new_tree_alloc: false,
need_tree_alloc: false,
}))
}
};
self.inner = Impl::Array(empty_array);
self.reserve_new(args)
}
Impl::Array(array) if array.is_full() => {
let allocs = match args.new_tree_alloc {
Some(ref mut allocs) => allocs,
None => {
return Ok(ReserveNew::NeedAlloc(ReserveNewNeedAlloc {
args,
need_empty_array_alloc: false,
need_new_tree_alloc: true,
need_tree_alloc: true,
}))
}
};
let new_tree =
TreeRangeAllocator::from_array(array.total_size(), &mut array.ranges, allocs);
self.inner = Impl::Tree(new_tree);
self.reserve_new(args)
}
Impl::Array(array) => {
let offset =
array.reserve_new(args.debug_id, args.size, args.is_oneway, args.pid)?;
Ok(ReserveNew::Success(ReserveNewSuccess {
offset,
oneway_spam_detected: false,
_empty_array_alloc: args.empty_array_alloc,
_new_tree_alloc: args.new_tree_alloc,
_tree_alloc: args.tree_alloc,
}))
}
Impl::Tree(tree) => {
let alloc = match args.tree_alloc {
Some(alloc) => alloc,
None => {
return Ok(ReserveNew::NeedAlloc(ReserveNewNeedAlloc {
args,
need_empty_array_alloc: false,
need_new_tree_alloc: false,
need_tree_alloc: true,
}));
}
};
let (offset, oneway_spam_detected) =
tree.reserve_new(args.debug_id, args.size, args.is_oneway, args.pid, alloc)?;
Ok(ReserveNew::Success(ReserveNewSuccess {
offset,
oneway_spam_detected,
_empty_array_alloc: args.empty_array_alloc,
_new_tree_alloc: args.new_tree_alloc,
_tree_alloc: None,
}))
}
}
}
/// Deletes the allocations at `offset`.
pub(crate) fn reservation_abort(&mut self, offset: usize) -> Result<FreedRange> {
match &mut self.inner {
Impl::Empty(_size) => Err(EINVAL),
Impl::Array(array) => array.reservation_abort(offset),
Impl::Tree(tree) => {
let freed_range = tree.reservation_abort(offset)?;
if tree.is_empty() {
self.inner = Impl::Empty(tree.total_size());
}
Ok(freed_range)
}
}
}
/// Called when an allocation is no longer in use by the kernel.
///
/// The value in `data` will be stored, if any. A mutable reference is used to avoid dropping
/// the `T` when an error is returned.
pub(crate) fn reservation_commit(&mut self, offset: usize, data: &mut Option<T>) -> Result {
match &mut self.inner {
Impl::Empty(_size) => Err(EINVAL),
Impl::Array(array) => array.reservation_commit(offset, data),
Impl::Tree(tree) => tree.reservation_commit(offset, data),
}
}
/// Called when the kernel starts using an allocation.
///
/// Returns the size of the existing entry and the data associated with it.
pub(crate) fn reserve_existing(&mut self, offset: usize) -> Result<(usize, usize, Option<T>)> {
match &mut self.inner {
Impl::Empty(_size) => Err(EINVAL),
Impl::Array(array) => array.reserve_existing(offset),
Impl::Tree(tree) => tree.reserve_existing(offset),
}
}
/// Call the provided callback at every allocated region.
///
/// This destroys the range allocator. Used only during shutdown.
pub(crate) fn take_for_each<F: Fn(usize, usize, usize, Option<T>)>(&mut self, callback: F) {
match &mut self.inner {
Impl::Empty(_size) => {}
Impl::Array(array) => array.take_for_each(callback),
Impl::Tree(tree) => tree.take_for_each(callback),
}
}
}
/// The arguments for `reserve_new`.
#[derive(Default)]
pub(crate) struct ReserveNewArgs<T> {
pub(crate) size: usize,
pub(crate) is_oneway: bool,
pub(crate) debug_id: usize,
pub(crate) pid: Pid,
pub(crate) empty_array_alloc: Option<EmptyArrayAlloc<T>>,
pub(crate) new_tree_alloc: Option<FromArrayAllocs<T>>,
pub(crate) tree_alloc: Option<ReserveNewTreeAlloc<T>>,
}
/// The return type of `ReserveNew`.
pub(crate) enum ReserveNew<T> {
Success(ReserveNewSuccess<T>),
NeedAlloc(ReserveNewNeedAlloc<T>),
}
/// Returned by `reserve_new` when the reservation was successul.
pub(crate) struct ReserveNewSuccess<T> {
pub(crate) offset: usize,
pub(crate) oneway_spam_detected: bool,
// If the user supplied an allocation that we did not end up using, then we return it here.
// The caller will kfree it outside of the lock.
_empty_array_alloc: Option<EmptyArrayAlloc<T>>,
_new_tree_alloc: Option<FromArrayAllocs<T>>,
_tree_alloc: Option<ReserveNewTreeAlloc<T>>,
}
/// Returned by `reserve_new` to request the caller to make an allocation before calling the method
/// again.
pub(crate) struct ReserveNewNeedAlloc<T> {
args: ReserveNewArgs<T>,
need_empty_array_alloc: bool,
need_new_tree_alloc: bool,
need_tree_alloc: bool,
}
impl<T> ReserveNewNeedAlloc<T> {
/// Make the necessary allocations for another call to `reserve_new`.
pub(crate) fn make_alloc(mut self) -> Result<ReserveNewArgs<T>> {
if self.need_empty_array_alloc && self.args.empty_array_alloc.is_none() {
self.args.empty_array_alloc = Some(EmptyArrayAlloc::try_new(TREE_THRESHOLD)?);
}
if self.need_new_tree_alloc && self.args.new_tree_alloc.is_none() {
self.args.new_tree_alloc = Some(FromArrayAllocs::try_new(TREE_THRESHOLD)?);
}
if self.need_tree_alloc && self.args.tree_alloc.is_none() {
self.args.tree_alloc = Some(ReserveNewTreeAlloc::try_new()?);
}
Ok(self.args)
}
}
|
