milos-linux/drivers/android/binder/page_range.rs
Alice Ryhl 9e5946de3a rust: declare cfi_encoding for lru_status
By default bindgen will convert 'enum lru_status' into a typedef for an
integer. For the most part, an integer of the same size as the enum
results in the correct ABI, but in the specific case of CFI, that is not
the case. The CFI encoding is supposed to be the same as a struct called
'lru_status' rather than the name of the underlying native integer type.

To fix this, tell bindgen to generate a newtype and set the CFI type
explicitly. Note that we need to set the CFI attribute explicitly as
bindgen is using repr(transparent), which is otherwise identical to the
inner type for ABI purposes.

This allows us to remove the page range helper C function in Binder
without risking a CFI failure when list_lru_walk calls the provided
function pointer.

The --with-attribute-custom-enum argument requires bindgen v0.71 or
greater.

[ In particular, the feature was added in 0.71.0 [1][2].

  In addition, `feature(cfi_encoding)` has been available since
  Rust 1.71.0 [3].

  Link: https://github.com/rust-lang/rust-bindgen/issues/2520 [1]
  Link: https://github.com/rust-lang/rust-bindgen/pull/2866 [2]
  Link: https://github.com/rust-lang/rust/pull/105452 [3]

    - Miguel ]

My testing procedure was to add this to the android17-6.18 branch and
verify that rust_shrink_free_page is successfully called without crash,
and verify that it does in fact crash when the cfi_encoding is set to
other values. Note that I couldn't test this on android16-6.12 as that
branch uses a bindgen version that is too old.

Signed-off-by: Alice Ryhl <aliceryhl@google.com>
Link: https://patch.msgid.link/20260223-cfi-lru-status-v2-1-89c6448a63a4@google.com
[ Rebased on top of the minimum Rust version bump series which provide
  the required `bindgen` version. - Miguel ]
Reviewed-by: Gary Guo <gary@garyguo.net>
Link: https://patch.msgid.link/20260405235309.418950-32-ojeda@kernel.org
Signed-off-by: Miguel Ojeda <ojeda@kernel.org>
2026-04-07 10:00:25 +02:00

731 lines
27 KiB
Rust

// SPDX-License-Identifier: GPL-2.0
// Copyright (C) 2025 Google LLC.
//! This module has utilities for managing a page range where unused pages may be reclaimed by a
//! vma shrinker.
// To avoid deadlocks, locks are taken in the order:
//
// 1. mmap lock
// 2. spinlock
// 3. lru spinlock
//
// The shrinker will use trylock methods because it locks them in a different order.
use core::{
marker::PhantomPinned,
mem::{size_of, size_of_val, MaybeUninit},
ptr,
};
use kernel::{
bindings,
error::Result,
ffi::{c_ulong, c_void},
mm::{virt, Mm, MmWithUser},
new_mutex, new_spinlock,
page::{Page, PAGE_SHIFT, PAGE_SIZE},
prelude::*,
str::CStr,
sync::{aref::ARef, Mutex, SpinLock},
task::Pid,
transmute::FromBytes,
types::Opaque,
uaccess::UserSliceReader,
};
/// Represents a shrinker that can be registered with the kernel.
///
/// Each shrinker can be used by many `ShrinkablePageRange` objects.
#[repr(C)]
pub(crate) struct Shrinker {
inner: Opaque<*mut bindings::shrinker>,
list_lru: Opaque<bindings::list_lru>,
}
// SAFETY: The shrinker and list_lru are thread safe.
unsafe impl Send for Shrinker {}
// SAFETY: The shrinker and list_lru are thread safe.
unsafe impl Sync for Shrinker {}
impl Shrinker {
/// Create a new shrinker.
///
/// # Safety
///
/// Before using this shrinker with a `ShrinkablePageRange`, the `register` method must have
/// been called exactly once, and it must not have returned an error.
pub(crate) const unsafe fn new() -> Self {
Self {
inner: Opaque::uninit(),
list_lru: Opaque::uninit(),
}
}
/// Register this shrinker with the kernel.
pub(crate) fn register(&'static self, name: &CStr) -> Result<()> {
// SAFETY: These fields are not yet used, so it's okay to zero them.
unsafe {
self.inner.get().write(ptr::null_mut());
self.list_lru.get().write_bytes(0, 1);
}
// SAFETY: The field is not yet used, so we can initialize it.
let ret = unsafe { bindings::__list_lru_init(self.list_lru.get(), false, ptr::null_mut()) };
if ret != 0 {
return Err(Error::from_errno(ret));
}
// SAFETY: The `name` points at a valid c string.
let shrinker = unsafe { bindings::shrinker_alloc(0, name.as_char_ptr()) };
if shrinker.is_null() {
// SAFETY: We initialized it, so its okay to destroy it.
unsafe { bindings::list_lru_destroy(self.list_lru.get()) };
return Err(Error::from_errno(ret));
}
// SAFETY: We're about to register the shrinker, and these are the fields we need to
// initialize. (All other fields are already zeroed.)
unsafe {
(&raw mut (*shrinker).count_objects).write(Some(rust_shrink_count));
(&raw mut (*shrinker).scan_objects).write(Some(rust_shrink_scan));
(&raw mut (*shrinker).private_data).write(self.list_lru.get().cast());
}
// SAFETY: The new shrinker has been fully initialized, so we can register it.
unsafe { bindings::shrinker_register(shrinker) };
// SAFETY: This initializes the pointer to the shrinker so that we can use it.
unsafe { self.inner.get().write(shrinker) };
Ok(())
}
}
/// A container that manages a page range in a vma.
///
/// The pages can be thought of as an array of booleans of whether the pages are usable. The
/// methods `use_range` and `stop_using_range` set all booleans in a range to true or false
/// respectively. Initially, no pages are allocated. When a page is not used, it is not freed
/// immediately. Instead, it is made available to the memory shrinker to free it if the device is
/// under memory pressure.
///
/// It's okay for `use_range` and `stop_using_range` to race with each other, although there's no
/// way to know whether an index ends up with true or false if a call to `use_range` races with
/// another call to `stop_using_range` on a given index.
///
/// It's also okay for the two methods to race with themselves, e.g. if two threads call
/// `use_range` on the same index, then that's fine and neither call will return until the page is
/// allocated and mapped.
///
/// The methods that read or write to a range require that the page is marked as in use. So it is
/// _not_ okay to call `stop_using_range` on a page that is in use by the methods that read or
/// write to the page.
#[pin_data(PinnedDrop)]
pub(crate) struct ShrinkablePageRange {
/// Shrinker object registered with the kernel.
shrinker: &'static Shrinker,
/// Pid using this page range. Only used as debugging information.
pid: Pid,
/// The mm for the relevant process.
mm: ARef<Mm>,
/// Used to synchronize calls to `vm_insert_page` and `zap_page_range_single`.
#[pin]
mm_lock: Mutex<()>,
/// Spinlock protecting changes to pages.
#[pin]
lock: SpinLock<Inner>,
/// Must not move, since page info has pointers back.
#[pin]
_pin: PhantomPinned,
}
struct Inner {
/// Array of pages.
///
/// Since this is also accessed by the shrinker, we can't use a `Box`, which asserts exclusive
/// ownership. To deal with that, we manage it using raw pointers.
pages: *mut PageInfo,
/// Length of the `pages` array.
size: usize,
/// The address of the vma to insert the pages into.
vma_addr: usize,
}
// SAFETY: proper locking is in place for `Inner`
unsafe impl Send for Inner {}
type StableMmGuard =
kernel::sync::lock::Guard<'static, (), kernel::sync::lock::mutex::MutexBackend>;
/// An array element that describes the current state of a page.
///
/// There are three states:
///
/// * Free. The page is None. The `lru` element is not queued.
/// * Available. The page is Some. The `lru` element is queued to the shrinker's lru.
/// * Used. The page is Some. The `lru` element is not queued.
///
/// When an element is available, the shrinker is able to free the page.
#[repr(C)]
struct PageInfo {
lru: bindings::list_head,
page: Option<Page>,
range: *const ShrinkablePageRange,
}
impl PageInfo {
/// # Safety
///
/// The caller ensures that writing to `me.page` is ok, and that the page is not currently set.
unsafe fn set_page(me: *mut PageInfo, page: Page) {
// SAFETY: This pointer offset is in bounds.
let ptr = unsafe { &raw mut (*me).page };
// SAFETY: The pointer is valid for writing, so also valid for reading.
if unsafe { (*ptr).is_some() } {
pr_err!("set_page called when there is already a page");
// SAFETY: We will initialize the page again below.
unsafe { ptr::drop_in_place(ptr) };
}
// SAFETY: The pointer is valid for writing.
unsafe { ptr::write(ptr, Some(page)) };
}
/// # Safety
///
/// The caller ensures that reading from `me.page` is ok for the duration of 'a.
unsafe fn get_page<'a>(me: *const PageInfo) -> Option<&'a Page> {
// SAFETY: This pointer offset is in bounds.
let ptr = unsafe { &raw const (*me).page };
// SAFETY: The pointer is valid for reading.
unsafe { (*ptr).as_ref() }
}
/// # Safety
///
/// The caller ensures that writing to `me.page` is ok for the duration of 'a.
unsafe fn take_page(me: *mut PageInfo) -> Option<Page> {
// SAFETY: This pointer offset is in bounds.
let ptr = unsafe { &raw mut (*me).page };
// SAFETY: The pointer is valid for reading.
unsafe { (*ptr).take() }
}
/// Add this page to the lru list, if not already in the list.
///
/// # Safety
///
/// The pointer must be valid, and it must be the right shrinker and nid.
unsafe fn list_lru_add(me: *mut PageInfo, nid: i32, shrinker: &'static Shrinker) {
// SAFETY: This pointer offset is in bounds.
let lru_ptr = unsafe { &raw mut (*me).lru };
// SAFETY: The lru pointer is valid, and we're not using it with any other lru list.
unsafe { bindings::list_lru_add(shrinker.list_lru.get(), lru_ptr, nid, ptr::null_mut()) };
}
/// Remove this page from the lru list, if it is in the list.
///
/// # Safety
///
/// The pointer must be valid, and it must be the right shrinker and nid.
unsafe fn list_lru_del(me: *mut PageInfo, nid: i32, shrinker: &'static Shrinker) {
// SAFETY: This pointer offset is in bounds.
let lru_ptr = unsafe { &raw mut (*me).lru };
// SAFETY: The lru pointer is valid, and we're not using it with any other lru list.
unsafe { bindings::list_lru_del(shrinker.list_lru.get(), lru_ptr, nid, ptr::null_mut()) };
}
}
impl ShrinkablePageRange {
/// Create a new `ShrinkablePageRange` using the given shrinker.
pub(crate) fn new(shrinker: &'static Shrinker) -> impl PinInit<Self, Error> {
try_pin_init!(Self {
shrinker,
pid: kernel::current!().pid(),
mm: ARef::from(&**kernel::current!().mm().ok_or(ESRCH)?),
mm_lock <- new_mutex!((), "ShrinkablePageRange::mm"),
lock <- new_spinlock!(Inner {
pages: ptr::null_mut(),
size: 0,
vma_addr: 0,
}, "ShrinkablePageRange"),
_pin: PhantomPinned,
})
}
pub(crate) fn stable_trylock_mm(&self) -> Option<StableMmGuard> {
// SAFETY: This extends the duration of the reference. Since this call happens before
// `mm_lock` is taken in the destructor of `ShrinkablePageRange`, the destructor will block
// until the returned guard is dropped. This ensures that the guard is valid until dropped.
let mm_lock = unsafe { &*ptr::from_ref(&self.mm_lock) };
mm_lock.try_lock()
}
/// Register a vma with this page range. Returns the size of the region.
pub(crate) fn register_with_vma(&self, vma: &virt::VmaNew) -> Result<usize> {
let num_bytes = usize::min(vma.end() - vma.start(), bindings::SZ_4M as usize);
let num_pages = num_bytes >> PAGE_SHIFT;
if !ptr::eq::<Mm>(&*self.mm, &**vma.mm()) {
pr_debug!("Failed to register with vma: invalid vma->vm_mm");
return Err(EINVAL);
}
if num_pages == 0 {
pr_debug!("Failed to register with vma: size zero");
return Err(EINVAL);
}
let mut pages = KVVec::<PageInfo>::with_capacity(num_pages, GFP_KERNEL)?;
// SAFETY: This just initializes the pages array.
unsafe {
let self_ptr = self as *const ShrinkablePageRange;
for i in 0..num_pages {
let info = pages.as_mut_ptr().add(i);
(&raw mut (*info).range).write(self_ptr);
(&raw mut (*info).page).write(None);
let lru = &raw mut (*info).lru;
(&raw mut (*lru).next).write(lru);
(&raw mut (*lru).prev).write(lru);
}
}
let mut inner = self.lock.lock();
if inner.size > 0 {
pr_debug!("Failed to register with vma: already registered");
drop(inner);
return Err(EBUSY);
}
inner.pages = pages.into_raw_parts().0;
inner.size = num_pages;
inner.vma_addr = vma.start();
Ok(num_pages)
}
/// Make sure that the given pages are allocated and mapped.
///
/// Must not be called from an atomic context.
pub(crate) fn use_range(&self, start: usize, end: usize) -> Result<()> {
if start >= end {
return Ok(());
}
let mut inner = self.lock.lock();
assert!(end <= inner.size);
for i in start..end {
// SAFETY: This pointer offset is in bounds.
let page_info = unsafe { inner.pages.add(i) };
// SAFETY: The pointer is valid, and we hold the lock so reading from the page is okay.
if let Some(page) = unsafe { PageInfo::get_page(page_info) } {
// Since we're going to use the page, we should remove it from the lru list so that
// the shrinker will not free it.
//
// SAFETY: The pointer is valid, and this is the right shrinker.
//
// The shrinker can't free the page between the check and this call to
// `list_lru_del` because we hold the lock.
unsafe { PageInfo::list_lru_del(page_info, page.nid(), self.shrinker) };
} else {
// We have to allocate a new page. Use the slow path.
drop(inner);
// SAFETY: `i < end <= inner.size` so `i` is in bounds.
match unsafe { self.use_page_slow(i) } {
Ok(()) => {}
Err(err) => {
pr_warn!("Error in use_page_slow: {:?}", err);
return Err(err);
}
}
inner = self.lock.lock();
}
}
Ok(())
}
/// Mark the given page as in use, slow path.
///
/// Must not be called from an atomic context.
///
/// # Safety
///
/// Assumes that `i` is in bounds.
#[cold]
unsafe fn use_page_slow(&self, i: usize) -> Result<()> {
let new_page = Page::alloc_page(GFP_KERNEL | __GFP_HIGHMEM | __GFP_ZERO)?;
let mm_mutex = self.mm_lock.lock();
let inner = self.lock.lock();
// SAFETY: This pointer offset is in bounds.
let page_info = unsafe { inner.pages.add(i) };
// SAFETY: The pointer is valid, and we hold the lock so reading from the page is okay.
if let Some(page) = unsafe { PageInfo::get_page(page_info) } {
// The page was already there, or someone else added the page while we didn't hold the
// spinlock.
//
// SAFETY: The pointer is valid, and this is the right shrinker.
//
// The shrinker can't free the page between the check and this call to
// `list_lru_del` because we hold the lock.
unsafe { PageInfo::list_lru_del(page_info, page.nid(), self.shrinker) };
return Ok(());
}
let vma_addr = inner.vma_addr;
// Release the spinlock while we insert the page into the vma.
drop(inner);
// No overflow since we stay in bounds of the vma.
let user_page_addr = vma_addr + (i << PAGE_SHIFT);
// We use `mmput_async` when dropping the `mm` because `use_page_slow` is usually used from
// a remote process. If the call to `mmput` races with the process shutting down, then the
// caller of `use_page_slow` becomes responsible for cleaning up the `mm`, which doesn't
// happen until it returns to userspace. However, the caller might instead go to sleep and
// wait for the owner of the `mm` to wake it up, which doesn't happen because it's in the
// middle of a shutdown process that won't complete until the `mm` is dropped. This can
// amount to a deadlock.
//
// Using `mmput_async` avoids this, because then the `mm` cleanup is instead queued to a
// workqueue.
MmWithUser::into_mmput_async(self.mm.mmget_not_zero().ok_or(ESRCH)?)
.mmap_read_lock()
.vma_lookup(vma_addr)
.ok_or(ESRCH)?
.as_mixedmap_vma()
.ok_or(ESRCH)?
.vm_insert_page(user_page_addr, &new_page)
.inspect_err(|err| {
pr_warn!(
"Failed to vm_insert_page({}): vma_addr:{} i:{} err:{:?}",
user_page_addr,
vma_addr,
i,
err
)
})?;
let inner = self.lock.lock();
// SAFETY: The `page_info` pointer is valid and currently does not have a page. The page
// can be written to since we hold the lock.
//
// We released and reacquired the spinlock since we checked that the page is null, but we
// always hold the mm_lock mutex when setting the page to a non-null value, so it's not
// possible for someone else to have changed it since our check.
unsafe { PageInfo::set_page(page_info, new_page) };
drop(inner);
drop(mm_mutex);
Ok(())
}
/// If the given page is in use, then mark it as available so that the shrinker can free it.
///
/// May be called from an atomic context.
pub(crate) fn stop_using_range(&self, start: usize, end: usize) {
if start >= end {
return;
}
let inner = self.lock.lock();
assert!(end <= inner.size);
for i in (start..end).rev() {
// SAFETY: The pointer is in bounds.
let page_info = unsafe { inner.pages.add(i) };
// SAFETY: Okay for reading since we have the lock.
if let Some(page) = unsafe { PageInfo::get_page(page_info) } {
// SAFETY: The pointer is valid, and it's the right shrinker.
unsafe { PageInfo::list_lru_add(page_info, page.nid(), self.shrinker) };
}
}
}
/// Helper for reading or writing to a range of bytes that may overlap with several pages.
///
/// # Safety
///
/// All pages touched by this operation must be in use for the duration of this call.
unsafe fn iterate<T>(&self, mut offset: usize, mut size: usize, mut cb: T) -> Result
where
T: FnMut(&Page, usize, usize) -> Result,
{
if size == 0 {
return Ok(());
}
let (pages, num_pages) = {
let inner = self.lock.lock();
(inner.pages, inner.size)
};
let num_bytes = num_pages << PAGE_SHIFT;
// Check that the request is within the buffer.
if offset.checked_add(size).ok_or(EFAULT)? > num_bytes {
return Err(EFAULT);
}
let mut page_index = offset >> PAGE_SHIFT;
offset &= PAGE_SIZE - 1;
while size > 0 {
let available = usize::min(size, PAGE_SIZE - offset);
// SAFETY: The pointer is in bounds.
let page_info = unsafe { pages.add(page_index) };
// SAFETY: The caller guarantees that this page is in the "in use" state for the
// duration of this call to `iterate`, so nobody will change the page.
let page = unsafe { PageInfo::get_page(page_info) };
if page.is_none() {
pr_warn!("Page is null!");
}
let page = page.ok_or(EFAULT)?;
cb(page, offset, available)?;
size -= available;
page_index += 1;
offset = 0;
}
Ok(())
}
/// Copy from userspace into this page range.
///
/// # Safety
///
/// All pages touched by this operation must be in use for the duration of this call.
pub(crate) unsafe fn copy_from_user_slice(
&self,
reader: &mut UserSliceReader,
offset: usize,
size: usize,
) -> Result {
// SAFETY: `self.iterate` has the same safety requirements as `copy_from_user_slice`.
unsafe {
self.iterate(offset, size, |page, offset, to_copy| {
page.copy_from_user_slice_raw(reader, offset, to_copy)
})
}
}
/// Copy from this page range into kernel space.
///
/// # Safety
///
/// All pages touched by this operation must be in use for the duration of this call.
pub(crate) unsafe fn read<T: FromBytes>(&self, offset: usize) -> Result<T> {
let mut out = MaybeUninit::<T>::uninit();
let mut out_offset = 0;
// SAFETY: `self.iterate` has the same safety requirements as `read`.
unsafe {
self.iterate(offset, size_of::<T>(), |page, offset, to_copy| {
// SAFETY: The sum of `offset` and `to_copy` is bounded by the size of T.
let obj_ptr = (out.as_mut_ptr() as *mut u8).add(out_offset);
// SAFETY: The pointer points is in-bounds of the `out` variable, so it is valid.
page.read_raw(obj_ptr, offset, to_copy)?;
out_offset += to_copy;
Ok(())
})?;
}
// SAFETY: We just initialised the data.
Ok(unsafe { out.assume_init() })
}
/// Copy from kernel space into this page range.
///
/// # Safety
///
/// All pages touched by this operation must be in use for the duration of this call.
pub(crate) unsafe fn write<T: ?Sized>(&self, offset: usize, obj: &T) -> Result {
let mut obj_offset = 0;
// SAFETY: `self.iterate` has the same safety requirements as `write`.
unsafe {
self.iterate(offset, size_of_val(obj), |page, offset, to_copy| {
// SAFETY: The sum of `offset` and `to_copy` is bounded by the size of T.
let obj_ptr = (obj as *const T as *const u8).add(obj_offset);
// SAFETY: We have a reference to the object, so the pointer is valid.
page.write_raw(obj_ptr, offset, to_copy)?;
obj_offset += to_copy;
Ok(())
})
}
}
/// Write zeroes to the given range.
///
/// # Safety
///
/// All pages touched by this operation must be in use for the duration of this call.
pub(crate) unsafe fn fill_zero(&self, offset: usize, size: usize) -> Result {
// SAFETY: `self.iterate` has the same safety requirements as `copy_into`.
unsafe {
self.iterate(offset, size, |page, offset, len| {
page.fill_zero_raw(offset, len)
})
}
}
}
#[pinned_drop]
impl PinnedDrop for ShrinkablePageRange {
fn drop(self: Pin<&mut Self>) {
let (pages, size) = {
let lock = self.lock.lock();
(lock.pages, lock.size)
};
if size == 0 {
return;
}
// Note: This call is also necessary for the safety of `stable_trylock_mm`.
let mm_lock = self.mm_lock.lock();
// This is the destructor, so unlike the other methods, we only need to worry about races
// with the shrinker here. Since we hold the `mm_lock`, we also can't race with the
// shrinker, and after this loop, the shrinker will not access any of our pages since we
// removed them from the lru list.
for i in 0..size {
// SAFETY: Loop is in-bounds of the size.
let p_ptr = unsafe { pages.add(i) };
// SAFETY: No other readers, so we can read.
if let Some(p) = unsafe { PageInfo::get_page(p_ptr) } {
// SAFETY: The pointer is valid and it's the right shrinker.
unsafe { PageInfo::list_lru_del(p_ptr, p.nid(), self.shrinker) };
}
}
drop(mm_lock);
// SAFETY: `pages` was allocated as an `KVVec<PageInfo>` with capacity `size`. Furthermore,
// all `size` elements are initialized. Also, the array is no longer shared with the
// shrinker due to the above loop.
drop(unsafe { KVVec::from_raw_parts(pages, size, size) });
}
}
/// # Safety
/// Called by the shrinker.
#[no_mangle]
unsafe extern "C" fn rust_shrink_count(
shrink: *mut bindings::shrinker,
_sc: *mut bindings::shrink_control,
) -> c_ulong {
// SAFETY: We can access our own private data.
let list_lru = unsafe { (*shrink).private_data.cast::<bindings::list_lru>() };
// SAFETY: Accessing the lru list is okay. Just an FFI call.
unsafe { bindings::list_lru_count(list_lru) }
}
/// # Safety
/// Called by the shrinker.
#[no_mangle]
unsafe extern "C" fn rust_shrink_scan(
shrink: *mut bindings::shrinker,
sc: *mut bindings::shrink_control,
) -> c_ulong {
// SAFETY: We can access our own private data.
let list_lru = unsafe { (*shrink).private_data.cast::<bindings::list_lru>() };
// SAFETY: Caller guarantees that it is safe to read this field.
let nr_to_scan = unsafe { (*sc).nr_to_scan };
// SAFETY: Accessing the lru list is okay. Just an FFI call.
unsafe {
bindings::list_lru_walk(
list_lru,
Some(rust_shrink_free_page),
ptr::null_mut(),
nr_to_scan,
)
}
}
const LRU_SKIP: bindings::lru_status = bindings::lru_status::LRU_SKIP;
const LRU_REMOVED_ENTRY: bindings::lru_status = bindings::lru_status::LRU_REMOVED_RETRY;
/// # Safety
/// Called by the shrinker.
#[no_mangle]
unsafe extern "C" fn rust_shrink_free_page(
item: *mut bindings::list_head,
lru: *mut bindings::list_lru_one,
_cb_arg: *mut c_void,
) -> bindings::lru_status {
// Fields that should survive after unlocking the lru lock.
let page;
let page_index;
let mm;
let mmap_read;
let mm_mutex;
let vma_addr;
{
// CAST: The `list_head` field is first in `PageInfo`.
let info = item as *mut PageInfo;
// SAFETY: The `range` field of `PageInfo` is immutable.
let range = unsafe { &*((*info).range) };
mm = match range.mm.mmget_not_zero() {
Some(mm) => MmWithUser::into_mmput_async(mm),
None => return LRU_SKIP,
};
mm_mutex = match range.stable_trylock_mm() {
Some(guard) => guard,
None => return LRU_SKIP,
};
mmap_read = match mm.mmap_read_trylock() {
Some(guard) => guard,
None => return LRU_SKIP,
};
// We can't lock it normally here, since we hold the lru lock.
let inner = match range.lock.try_lock() {
Some(inner) => inner,
None => return LRU_SKIP,
};
// SAFETY: The item is in this lru list, so it's okay to remove it.
unsafe { bindings::list_lru_isolate(lru, item) };
// SAFETY: Both pointers are in bounds of the same allocation.
page_index = unsafe { info.offset_from(inner.pages) } as usize;
// SAFETY: We hold the spinlock, so we can take the page.
//
// This sets the page pointer to zero before we unmap it from the vma. However, we call
// `zap_page_range` before we release the mmap lock, so `use_page_slow` will not be able to
// insert a new page until after our call to `zap_page_range`.
page = unsafe { PageInfo::take_page(info) };
vma_addr = inner.vma_addr;
// From this point on, we don't access this PageInfo or ShrinkablePageRange again, because
// they can be freed at any point after we unlock `lru_lock`. This is with the exception of
// `mm_mutex` which is kept alive by holding the lock.
}
// SAFETY: The lru lock is locked when this method is called.
unsafe { bindings::spin_unlock(&raw mut (*lru).lock) };
if let Some(vma) = mmap_read.vma_lookup(vma_addr) {
let user_page_addr = vma_addr + (page_index << PAGE_SHIFT);
vma.zap_page_range_single(user_page_addr, PAGE_SIZE);
}
drop(mmap_read);
drop(mm_mutex);
drop(mm);
drop(page);
LRU_REMOVED_ENTRY
}