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|
// SPDX-License-Identifier: GPL-2.0
use core::{convert::TryFrom, mem::take, ops::Range};
use kernel::{
bindings,
cred::Credential,
file::{self, File, IoctlCommand, IoctlHandler, PollTable},
io_buffer::{IoBufferReader, IoBufferWriter},
linked_list::List,
mm,
pages::Pages,
prelude::*,
rbtree::RBTree,
sync::{Arc, ArcBorrow, Guard, Mutex, UniqueArc},
task::Task,
user_ptr::{UserSlicePtr, UserSlicePtrReader},
Either,
};
use crate::{
allocation::Allocation,
context::Context,
defs::*,
node::{Node, NodeDeath, NodeRef},
range_alloc::RangeAllocator,
thread::{BinderError, BinderResult, Thread},
DeliverToRead, DeliverToReadListAdapter,
};
// TODO: Review this:
// Lock order: Process::node_refs -> Process::inner -> Thread::inner
pub(crate) struct AllocationInfo {
/// Range within the allocation where we can find the offsets to the object descriptors.
pub(crate) offsets: Range<usize>,
}
struct Mapping {
address: usize,
alloc: RangeAllocator<AllocationInfo>,
pages: Arc<[Pages<0>]>,
}
impl Mapping {
fn new(address: usize, size: usize, pages: Arc<[Pages<0>]>) -> Result<Self> {
let alloc = RangeAllocator::new(size)?;
Ok(Self {
address,
alloc,
pages,
})
}
}
// TODO: Make this private.
pub(crate) struct ProcessInner {
is_manager: bool,
is_dead: bool,
threads: RBTree<i32, Arc<Thread>>,
ready_threads: List<Arc<Thread>>,
work: List<DeliverToReadListAdapter>,
mapping: Option<Mapping>,
nodes: RBTree<usize, Arc<Node>>,
delivered_deaths: List<Arc<NodeDeath>>,
/// The number of requested threads that haven't registered yet.
requested_thread_count: u32,
/// The maximum number of threads used by the process thread pool.
max_threads: u32,
/// The number of threads the started and registered with the thread pool.
started_thread_count: u32,
}
impl ProcessInner {
fn new() -> Self {
Self {
is_manager: false,
is_dead: false,
threads: RBTree::new(),
ready_threads: List::new(),
work: List::new(),
mapping: None,
nodes: RBTree::new(),
requested_thread_count: 0,
max_threads: 0,
started_thread_count: 0,
delivered_deaths: List::new(),
}
}
fn push_work(&mut self, work: Arc<dyn DeliverToRead>) -> BinderResult {
// Try to find a ready thread to which to push the work.
if let Some(thread) = self.ready_threads.pop_front() {
// Push to thread while holding state lock. This prevents the thread from giving up
// (for example, because of a signal) when we're about to deliver work.
thread.push_work(work)
} else if self.is_dead {
Err(BinderError::new_dead())
} else {
// There are no ready threads. Push work to process queue.
self.work.push_back(work);
// Wake up polling threads, if any.
for thread in self.threads.values() {
thread.notify_if_poll_ready();
}
Ok(())
}
}
// TODO: Should this be private?
pub(crate) fn remove_node(&mut self, ptr: usize) {
self.nodes.remove(&ptr);
}
/// Updates the reference count on the given node.
// TODO: Decide if this should be private.
pub(crate) fn update_node_refcount(
&mut self,
node: &Arc<Node>,
inc: bool,
strong: bool,
biased: bool,
othread: Option<&Thread>,
) {
let push = node.update_refcount_locked(inc, strong, biased, self);
// If we decided that we need to push work, push either to the process or to a thread if
// one is specified.
if push {
if let Some(thread) = othread {
thread.push_work_deferred(node.clone());
} else {
let _ = self.push_work(node.clone());
// Nothing to do: `push_work` may fail if the process is dead, but that's ok as in
// that case, it doesn't care about the notification.
}
}
}
// TODO: Make this private.
pub(crate) fn new_node_ref(
&mut self,
node: Arc<Node>,
strong: bool,
thread: Option<&Thread>,
) -> NodeRef {
self.update_node_refcount(&node, true, strong, false, thread);
let strong_count = if strong { 1 } else { 0 };
NodeRef::new(node, strong_count, 1 - strong_count)
}
/// Returns an existing node with the given pointer and cookie, if one exists.
///
/// Returns an error if a node with the given pointer but a different cookie exists.
fn get_existing_node(&self, ptr: usize, cookie: usize) -> Result<Option<Arc<Node>>> {
match self.nodes.get(&ptr) {
None => Ok(None),
Some(node) => {
let (_, node_cookie) = node.get_id();
if node_cookie == cookie {
Ok(Some(node.clone()))
} else {
Err(EINVAL)
}
}
}
}
/// Returns a reference to an existing node with the given pointer and cookie. It requires a
/// mutable reference because it needs to increment the ref count on the node, which may
/// require pushing work to the work queue (to notify userspace of 0 to 1 transitions).
fn get_existing_node_ref(
&mut self,
ptr: usize,
cookie: usize,
strong: bool,
thread: Option<&Thread>,
) -> Result<Option<NodeRef>> {
Ok(self
.get_existing_node(ptr, cookie)?
.map(|node| self.new_node_ref(node, strong, thread)))
}
fn register_thread(&mut self) -> bool {
if self.requested_thread_count == 0 {
return false;
}
self.requested_thread_count -= 1;
self.started_thread_count += 1;
true
}
/// Finds a delivered death notification with the given cookie, removes it from the thread's
/// delivered list, and returns it.
fn pull_delivered_death(&mut self, cookie: usize) -> Option<Arc<NodeDeath>> {
let mut cursor = self.delivered_deaths.cursor_front_mut();
while let Some(death) = cursor.current() {
if death.cookie == cookie {
return cursor.remove_current();
}
cursor.move_next();
}
None
}
pub(crate) fn death_delivered(&mut self, death: Arc<NodeDeath>) {
self.delivered_deaths.push_back(death);
}
}
struct NodeRefInfo {
node_ref: NodeRef,
death: Option<Arc<NodeDeath>>,
}
impl NodeRefInfo {
fn new(node_ref: NodeRef) -> Self {
Self {
node_ref,
death: None,
}
}
}
struct ProcessNodeRefs {
by_handle: RBTree<u32, NodeRefInfo>,
by_global_id: RBTree<u64, u32>,
}
impl ProcessNodeRefs {
fn new() -> Self {
Self {
by_handle: RBTree::new(),
by_global_id: RBTree::new(),
}
}
}
pub(crate) struct Process {
ctx: Arc<Context>,
// The task leader (process).
pub(crate) task: ARef<Task>,
// Credential associated with file when `Process` is created.
pub(crate) cred: ARef<Credential>,
// TODO: For now this a mutex because we have allocations in RangeAllocator while holding the
// lock. We may want to split up the process state at some point to use a spin lock for the
// other fields.
// TODO: Make this private again.
pub(crate) inner: Mutex<ProcessInner>,
// References are in a different mutex to avoid recursive acquisition when
// incrementing/decrementing a node in another process.
node_refs: Mutex<ProcessNodeRefs>,
}
#[allow(clippy::non_send_fields_in_send_ty)]
unsafe impl Send for Process {}
unsafe impl Sync for Process {}
impl Process {
fn new(ctx: Arc<Context>, cred: ARef<Credential>) -> Result<Arc<Self>> {
let mut process = Pin::from(UniqueArc::try_new(Self {
ctx,
cred,
task: Task::current().group_leader().into(),
// SAFETY: `inner` is initialised in the call to `mutex_init` below.
inner: unsafe { Mutex::new(ProcessInner::new()) },
// SAFETY: `node_refs` is initialised in the call to `mutex_init` below.
node_refs: unsafe { Mutex::new(ProcessNodeRefs::new()) },
})?);
// SAFETY: `inner` is pinned when `Process` is.
let pinned = unsafe { process.as_mut().map_unchecked_mut(|p| &mut p.inner) };
kernel::mutex_init!(pinned, "Process::inner");
// SAFETY: `node_refs` is pinned when `Process` is.
let pinned = unsafe { process.as_mut().map_unchecked_mut(|p| &mut p.node_refs) };
kernel::mutex_init!(pinned, "Process::node_refs");
Ok(process.into())
}
/// Attempts to fetch a work item from the process queue.
pub(crate) fn get_work(&self) -> Option<Arc<dyn DeliverToRead>> {
self.inner.lock().work.pop_front()
}
/// Attempts to fetch a work item from the process queue. If none is available, it registers the
/// given thread as ready to receive work directly.
///
/// This must only be called when the thread is not participating in a transaction chain; when
/// it is, work will always be delivered directly to the thread (and not through the process
/// queue).
pub(crate) fn get_work_or_register<'a>(
&'a self,
thread: &'a Arc<Thread>,
) -> Either<Arc<dyn DeliverToRead>, Registration<'a>> {
let mut inner = self.inner.lock();
// Try to get work from the process queue.
if let Some(work) = inner.work.pop_front() {
return Either::Left(work);
}
// Register the thread as ready.
Either::Right(Registration::new(self, thread, &mut inner))
}
fn get_thread(self: ArcBorrow<'_, Self>, id: i32) -> Result<Arc<Thread>> {
// TODO: Consider using read/write locks here instead.
{
let inner = self.inner.lock();
if let Some(thread) = inner.threads.get(&id) {
return Ok(thread.clone());
}
}
// Allocate a new `Thread` without holding any locks.
let ta = Thread::new(id, self.into())?;
let node = RBTree::try_allocate_node(id, ta.clone())?;
let mut inner = self.inner.lock();
// Recheck. It's possible the thread was create while we were not holding the lock.
if let Some(thread) = inner.threads.get(&id) {
return Ok(thread.clone());
}
inner.threads.insert(node);
Ok(ta)
}
pub(crate) fn push_work(&self, work: Arc<dyn DeliverToRead>) -> BinderResult {
self.inner.lock().push_work(work)
}
fn set_as_manager(
self: ArcBorrow<'_, Self>,
info: Option<FlatBinderObject>,
thread: &Thread,
) -> Result {
let (ptr, cookie, flags) = if let Some(obj) = info {
(
// SAFETY: The object type for this ioctl is implicitly `BINDER_TYPE_BINDER`, so it
// is safe to access the `binder` field.
unsafe { obj.__bindgen_anon_1.binder },
obj.cookie,
obj.flags,
)
} else {
(0, 0, 0)
};
let node_ref = self.get_node(ptr as _, cookie as _, flags as _, true, Some(thread))?;
let node = node_ref.node.clone();
self.ctx.set_manager_node(node_ref)?;
self.inner.lock().is_manager = true;
// Force the state of the node to prevent the delivery of acquire/increfs.
let mut owner_inner = node.owner.inner.lock();
node.force_has_count(&mut owner_inner);
Ok(())
}
pub(crate) fn get_node(
self: ArcBorrow<'_, Self>,
ptr: usize,
cookie: usize,
flags: u32,
strong: bool,
thread: Option<&Thread>,
) -> Result<NodeRef> {
// Try to find an existing node.
{
let mut inner = self.inner.lock();
if let Some(node) = inner.get_existing_node_ref(ptr, cookie, strong, thread)? {
return Ok(node);
}
}
// Allocate the node before reacquiring the lock.
let node = Arc::try_new(Node::new(ptr, cookie, flags, self.into()))?;
let rbnode = RBTree::try_allocate_node(ptr, node.clone())?;
let mut inner = self.inner.lock();
if let Some(node) = inner.get_existing_node_ref(ptr, cookie, strong, thread)? {
return Ok(node);
}
inner.nodes.insert(rbnode);
Ok(inner.new_node_ref(node, strong, thread))
}
pub(crate) fn insert_or_update_handle(
&self,
node_ref: NodeRef,
is_mananger: bool,
) -> Result<u32> {
{
let mut refs = self.node_refs.lock();
// Do a lookup before inserting.
if let Some(handle_ref) = refs.by_global_id.get(&node_ref.node.global_id) {
let handle = *handle_ref;
let info = refs.by_handle.get_mut(&handle).unwrap();
info.node_ref.absorb(node_ref);
return Ok(handle);
}
}
// Reserve memory for tree nodes.
let reserve1 = RBTree::try_reserve_node()?;
let reserve2 = RBTree::try_reserve_node()?;
let mut refs = self.node_refs.lock();
// Do a lookup again as node may have been inserted before the lock was reacquired.
if let Some(handle_ref) = refs.by_global_id.get(&node_ref.node.global_id) {
let handle = *handle_ref;
let info = refs.by_handle.get_mut(&handle).unwrap();
info.node_ref.absorb(node_ref);
return Ok(handle);
}
// Find id.
let mut target = if is_mananger { 0 } else { 1 };
for handle in refs.by_handle.keys() {
if *handle > target {
break;
}
if *handle == target {
target = target.checked_add(1).ok_or(ENOMEM)?;
}
}
// Ensure the process is still alive while we insert a new reference.
let inner = self.inner.lock();
if inner.is_dead {
return Err(ESRCH);
}
refs.by_global_id
.insert(reserve1.into_node(node_ref.node.global_id, target));
refs.by_handle
.insert(reserve2.into_node(target, NodeRefInfo::new(node_ref)));
Ok(target)
}
pub(crate) fn get_transaction_node(&self, handle: u32) -> BinderResult<NodeRef> {
// When handle is zero, try to get the context manager.
if handle == 0 {
self.ctx.get_manager_node(true)
} else {
self.get_node_from_handle(handle, true)
}
}
pub(crate) fn get_node_from_handle(&self, handle: u32, strong: bool) -> BinderResult<NodeRef> {
self.node_refs
.lock()
.by_handle
.get(&handle)
.ok_or(ENOENT)?
.node_ref
.clone(strong)
}
pub(crate) fn remove_from_delivered_deaths(&self, death: &Arc<NodeDeath>) {
let mut inner = self.inner.lock();
let removed = unsafe { inner.delivered_deaths.remove(death) };
drop(inner);
drop(removed);
}
pub(crate) fn update_ref(&self, handle: u32, inc: bool, strong: bool) -> Result {
if inc && handle == 0 {
if let Ok(node_ref) = self.ctx.get_manager_node(strong) {
if core::ptr::eq(self, &*node_ref.node.owner) {
return Err(EINVAL);
}
let _ = self.insert_or_update_handle(node_ref, true);
return Ok(());
}
}
// To preserve original binder behaviour, we only fail requests where the manager tries to
// increment references on itself.
let mut refs = self.node_refs.lock();
if let Some(info) = refs.by_handle.get_mut(&handle) {
if info.node_ref.update(inc, strong) {
// Clean up death if there is one attached to this node reference.
if let Some(death) = info.death.take() {
death.set_cleared(true);
self.remove_from_delivered_deaths(&death);
}
// Remove reference from process tables.
let id = info.node_ref.node.global_id;
refs.by_handle.remove(&handle);
refs.by_global_id.remove(&id);
}
}
Ok(())
}
/// Decrements the refcount of the given node, if one exists.
pub(crate) fn update_node(&self, ptr: usize, cookie: usize, strong: bool, biased: bool) {
let mut inner = self.inner.lock();
if let Ok(Some(node)) = inner.get_existing_node(ptr, cookie) {
inner.update_node_refcount(&node, false, strong, biased, None);
}
}
pub(crate) fn inc_ref_done(&self, reader: &mut UserSlicePtrReader, strong: bool) -> Result {
let ptr = reader.read::<usize>()?;
let cookie = reader.read::<usize>()?;
self.update_node(ptr, cookie, strong, true);
Ok(())
}
pub(crate) fn buffer_alloc(&self, size: usize) -> BinderResult<Allocation<'_>> {
let mut inner = self.inner.lock();
let mapping = inner.mapping.as_mut().ok_or_else(BinderError::new_dead)?;
let offset = mapping.alloc.reserve_new(size)?;
Ok(Allocation::new(
self,
offset,
size,
mapping.address + offset,
mapping.pages.clone(),
))
}
// TODO: Review if we want an Option or a Result.
pub(crate) fn buffer_get(&self, ptr: usize) -> Option<Allocation<'_>> {
let mut inner = self.inner.lock();
let mapping = inner.mapping.as_mut()?;
let offset = ptr.checked_sub(mapping.address)?;
let (size, odata) = mapping.alloc.reserve_existing(offset).ok()?;
let mut alloc = Allocation::new(self, offset, size, ptr, mapping.pages.clone());
if let Some(data) = odata {
alloc.set_info(data);
}
Some(alloc)
}
pub(crate) fn buffer_raw_free(&self, ptr: usize) {
let mut inner = self.inner.lock();
if let Some(ref mut mapping) = &mut inner.mapping {
if ptr < mapping.address
|| mapping
.alloc
.reservation_abort(ptr - mapping.address)
.is_err()
{
pr_warn!(
"Pointer {:x} failed to free, base = {:x}\n",
ptr,
mapping.address
);
}
}
}
pub(crate) fn buffer_make_freeable(&self, offset: usize, data: Option<AllocationInfo>) {
let mut inner = self.inner.lock();
if let Some(ref mut mapping) = &mut inner.mapping {
if mapping.alloc.reservation_commit(offset, data).is_err() {
pr_warn!("Offset {} failed to be marked freeable\n", offset);
}
}
}
fn create_mapping(&self, vma: &mut mm::virt::Area) -> Result {
let size = core::cmp::min(vma.end() - vma.start(), bindings::SZ_4M as usize);
let page_count = size / kernel::PAGE_SIZE;
// Allocate and map all pages.
//
// N.B. If we fail halfway through mapping these pages, the kernel will unmap them.
let mut pages = Vec::new();
pages.try_reserve_exact(page_count)?;
let mut address = vma.start();
for _ in 0..page_count {
let page = Pages::<0>::new()?;
vma.insert_page(address, &page)?;
pages.try_push(page)?;
address += kernel::PAGE_SIZE;
}
let ref_pages = Arc::try_from(pages)?;
// Save pages for later.
let mut inner = self.inner.lock();
match &inner.mapping {
None => inner.mapping = Some(Mapping::new(vma.start(), size, ref_pages)?),
Some(_) => return Err(EBUSY),
}
Ok(())
}
fn version(&self, data: UserSlicePtr) -> Result {
data.writer().write(&BinderVersion::current())
}
pub(crate) fn register_thread(&self) -> bool {
self.inner.lock().register_thread()
}
fn remove_thread(&self, thread: Arc<Thread>) {
self.inner.lock().threads.remove(&thread.id);
thread.release();
}
fn set_max_threads(&self, max: u32) {
self.inner.lock().max_threads = max;
}
fn get_node_debug_info(&self, data: UserSlicePtr) -> Result {
let (mut reader, mut writer) = data.reader_writer();
// Read the starting point.
let ptr = reader.read::<BinderNodeDebugInfo>()?.ptr as usize;
let mut out = BinderNodeDebugInfo::default();
{
let inner = self.inner.lock();
for (node_ptr, node) in &inner.nodes {
if *node_ptr > ptr {
node.populate_debug_info(&mut out, &inner);
break;
}
}
}
writer.write(&out)
}
fn get_node_info_from_ref(&self, data: UserSlicePtr) -> Result {
let (mut reader, mut writer) = data.reader_writer();
let mut out = reader.read::<BinderNodeInfoForRef>()?;
if out.strong_count != 0
|| out.weak_count != 0
|| out.reserved1 != 0
|| out.reserved2 != 0
|| out.reserved3 != 0
{
return Err(EINVAL);
}
// Only the context manager is allowed to use this ioctl.
if !self.inner.lock().is_manager {
return Err(EPERM);
}
let node_ref = self
.get_node_from_handle(out.handle, true)
.or(Err(EINVAL))?;
// Get the counts from the node.
{
let owner_inner = node_ref.node.owner.inner.lock();
node_ref.node.populate_counts(&mut out, &owner_inner);
}
// Write the result back.
writer.write(&out)
}
pub(crate) fn needs_thread(&self) -> bool {
let mut inner = self.inner.lock();
let ret = inner.requested_thread_count == 0
&& inner.ready_threads.is_empty()
&& inner.started_thread_count < inner.max_threads;
if ret {
inner.requested_thread_count += 1
};
ret
}
pub(crate) fn request_death(
self: &Arc<Self>,
reader: &mut UserSlicePtrReader,
thread: &Thread,
) -> Result {
let handle: u32 = reader.read()?;
let cookie: usize = reader.read()?;
// TODO: First two should result in error, but not the others.
// TODO: Do we care about the context manager dying?
// Queue BR_ERROR if we can't allocate memory for the death notification.
let death = UniqueArc::try_new_uninit().map_err(|err| {
thread.push_return_work(BR_ERROR);
err
})?;
let mut refs = self.node_refs.lock();
let info = refs.by_handle.get_mut(&handle).ok_or(EINVAL)?;
// Nothing to do if there is already a death notification request for this handle.
if info.death.is_some() {
return Ok(());
}
let death = {
let mut pinned = Pin::from(death.write(
// SAFETY: `init` is called below.
unsafe { NodeDeath::new(info.node_ref.node.clone(), self.clone(), cookie) },
));
pinned.as_mut().init();
Arc::<NodeDeath>::from(pinned)
};
info.death = Some(death.clone());
// Register the death notification.
{
let mut owner_inner = info.node_ref.node.owner.inner.lock();
if owner_inner.is_dead {
drop(owner_inner);
let _ = self.push_work(death);
} else {
info.node_ref.node.add_death(death, &mut owner_inner);
}
}
Ok(())
}
pub(crate) fn clear_death(&self, reader: &mut UserSlicePtrReader, thread: &Thread) -> Result {
let handle: u32 = reader.read()?;
let cookie: usize = reader.read()?;
let mut refs = self.node_refs.lock();
let info = refs.by_handle.get_mut(&handle).ok_or(EINVAL)?;
let death = info.death.take().ok_or(EINVAL)?;
if death.cookie != cookie {
info.death = Some(death);
return Err(EINVAL);
}
// Update state and determine if we need to queue a work item. We only need to do it when
// the node is not dead or if the user already completed the death notification.
if death.set_cleared(false) {
let _ = thread.push_work_if_looper(death);
}
Ok(())
}
pub(crate) fn dead_binder_done(&self, cookie: usize, thread: &Thread) {
if let Some(death) = self.inner.lock().pull_delivered_death(cookie) {
death.set_notification_done(thread);
}
}
}
impl IoctlHandler for Process {
type Target<'a> = ArcBorrow<'a, Process>;
fn write(
this: ArcBorrow<'_, Process>,
_file: &File,
cmd: u32,
reader: &mut UserSlicePtrReader,
) -> Result<i32> {
let thread = this.get_thread(Task::current().pid())?;
match cmd {
bindings::BINDER_SET_MAX_THREADS => this.set_max_threads(reader.read()?),
bindings::BINDER_SET_CONTEXT_MGR => this.set_as_manager(None, &thread)?,
bindings::BINDER_THREAD_EXIT => this.remove_thread(thread),
bindings::BINDER_SET_CONTEXT_MGR_EXT => {
this.set_as_manager(Some(reader.read()?), &thread)?
}
_ => return Err(EINVAL),
}
Ok(0)
}
fn read_write(
this: ArcBorrow<'_, Process>,
file: &File,
cmd: u32,
data: UserSlicePtr,
) -> Result<i32> {
let thread = this.get_thread(Task::current().pid())?;
let blocking = (file.flags() & file::flags::O_NONBLOCK) == 0;
match cmd {
bindings::BINDER_WRITE_READ => thread.write_read(data, blocking)?,
bindings::BINDER_GET_NODE_DEBUG_INFO => this.get_node_debug_info(data)?,
bindings::BINDER_GET_NODE_INFO_FOR_REF => this.get_node_info_from_ref(data)?,
bindings::BINDER_VERSION => this.version(data)?,
_ => return Err(EINVAL),
}
Ok(0)
}
}
#[vtable]
impl file::Operations for Process {
type Data = Arc<Self>;
type OpenData = Arc<Context>;
fn open(ctx: &Arc<Context>, file: &File) -> Result<Self::Data> {
Self::new(ctx.clone(), file.cred().into())
}
fn release(obj: Self::Data, _file: &File) {
// Mark this process as dead. We'll do the same for the threads later.
obj.inner.lock().is_dead = true;
// If this process is the manager, unset it.
if obj.inner.lock().is_manager {
obj.ctx.unset_manager_node();
}
// TODO: Do this in a worker?
// Cancel all pending work items.
while let Some(work) = obj.get_work() {
work.cancel();
}
// Free any resources kept alive by allocated buffers.
let omapping = obj.inner.lock().mapping.take();
if let Some(mut mapping) = omapping {
let address = mapping.address;
let pages = mapping.pages.clone();
mapping.alloc.for_each(|offset, size, odata| {
let ptr = offset + address;
let mut alloc = Allocation::new(&obj, offset, size, ptr, pages.clone());
if let Some(data) = odata {
alloc.set_info(data);
}
drop(alloc)
});
}
// Drop all references. We do this dance with `swap` to avoid destroying the references
// while holding the lock.
let mut refs = obj.node_refs.lock();
let mut node_refs = take(&mut refs.by_handle);
drop(refs);
// Remove all death notifications from the nodes (that belong to a different process).
for info in node_refs.values_mut() {
let death = if let Some(existing) = info.death.take() {
existing
} else {
continue;
};
death.set_cleared(false);
}
// Do similar dance for the state lock.
let mut inner = obj.inner.lock();
let threads = take(&mut inner.threads);
let nodes = take(&mut inner.nodes);
drop(inner);
// Release all threads.
for thread in threads.values() {
thread.release();
}
// Deliver death notifications.
for node in nodes.values() {
loop {
let death = {
let mut inner = obj.inner.lock();
if let Some(death) = node.next_death(&mut inner) {
death
} else {
break;
}
};
death.set_dead();
}
}
}
fn ioctl(this: ArcBorrow<'_, Process>, file: &File, cmd: &mut IoctlCommand) -> Result<i32> {
cmd.dispatch::<Self>(this, file)
}
fn compat_ioctl(
this: ArcBorrow<'_, Process>,
file: &File,
cmd: &mut IoctlCommand,
) -> Result<i32> {
cmd.dispatch::<Self>(this, file)
}
fn mmap(this: ArcBorrow<'_, Process>, _file: &File, vma: &mut mm::virt::Area) -> Result {
// We don't allow mmap to be used in a different process.
if !core::ptr::eq(Task::current().group_leader(), &*this.task) {
return Err(EINVAL);
}
if vma.start() == 0 {
return Err(EINVAL);
}
let mut flags = vma.flags();
use mm::virt::flags::*;
if flags & WRITE != 0 {
return Err(EPERM);
}
flags |= DONTCOPY | MIXEDMAP;
flags &= !MAYWRITE;
vma.set_flags(flags);
// TODO: Set ops. We need to learn when the user unmaps so that we can stop using it.
this.create_mapping(vma)
}
fn poll(this: ArcBorrow<'_, Process>, file: &File, table: &PollTable) -> Result<u32> {
let thread = this.get_thread(Task::current().pid())?;
let (from_proc, mut mask) = thread.poll(file, table);
if mask == 0 && from_proc && !this.inner.lock().work.is_empty() {
mask |= bindings::POLLIN;
}
Ok(mask)
}
}
pub(crate) struct Registration<'a> {
process: &'a Process,
thread: &'a Arc<Thread>,
}
impl<'a> Registration<'a> {
fn new(
process: &'a Process,
thread: &'a Arc<Thread>,
guard: &mut Guard<'_, Mutex<ProcessInner>>,
) -> Self {
guard.ready_threads.push_back(thread.clone());
Self { process, thread }
}
}
impl Drop for Registration<'_> {
fn drop(&mut self) {
let mut inner = self.process.inner.lock();
unsafe { inner.ready_threads.remove(self.thread) };
}
}
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