use pool::Pool;
use task::Task;
use std::mem;
use std::ops;
use std::sync::Arc;
use futures::executor::Notify;
/// Implements the future `Notify` API.
///
/// This is how external events are able to signal the task, informing it to try
/// to poll the future again.
#[derive(Debug)]
pub(crate) struct Notifier {
pub pool: Arc<Pool>,
}
/// A guard that ensures that the inner value gets forgotten.
#[derive(Debug)]
struct Forget<T>(Option<T>);
impl Notify for Notifier {
fn notify(&self, id: usize) {
trace!("Notifier::notify; id=0x{:x}", id);
unsafe {
let ptr = id as *const Task;
// We did not actually take ownership of the `Arc` in this function
// so we must ensure that the Arc is forgotten.
let task = Forget::new(Arc::from_raw(ptr));
// TODO: Unify this with Task::notify
if task.schedule() {
// TODO: Check if the pool is still running
//
// Bump the ref count
let task = task.clone();
let _ = self.pool.submit(task, &self.pool);
}
}
}
fn clone_id(&self, id: usize) -> usize {
let ptr = id as *const Task;
// This function doesn't actually get a strong ref to the task here.
// However, the only method we have to convert a raw pointer -> &Arc<T>
// is to call `Arc::from_raw` which returns a strong ref. So, to
// maintain the invariants, `t1` has to be forgotten. This prevents the
// ref count from being decremented.
let t1 = Forget::new(unsafe { Arc::from_raw(ptr) });
// The clone is forgotten so that the fn exits without decrementing the ref
// count. The caller of `clone_id` ensures that `drop_id` is called when
// the ref count needs to be decremented.
let _ = Forget::new(t1.clone());
id
}
fn drop_id(&self, id: usize) {
unsafe {
let ptr = id as *const Task;
let _ = Arc::from_raw(ptr);
}
}
}
// ===== impl Forget =====
impl<T> Forget<T> {
fn new(t: T) -> Self {
Forget(Some(t))
}
}
impl<T> ops::Deref for Forget<T> {
type Target = T;
fn deref(&self) -> &T {
self.0.as_ref().unwrap()
}
}
impl<T> Drop for Forget<T> {
fn drop(&mut self) {
mem::forget(self.0.take());
}
}