//! A simple single-threaded executor that can spawn non-`Send` futures. use std::cell::Cell; use std::future::Future; use std::rc::Rc; use async_task_ffi::{Runnable, Task}; thread_local! { // A queue that holds scheduled tasks. static QUEUE: (flume::Sender, flume::Receiver) = flume::unbounded(); } /// Spawns a future on the executor. fn spawn(future: F) -> Task where F: Future + 'static, T: 'static, { // Create a task that is scheduled by pushing itself into the queue. let schedule = |runnable| QUEUE.with(|(s, _)| s.send(runnable).unwrap()); let (runnable, task) = async_task_ffi::spawn_local(future, schedule); // Schedule the task by pushing it into the queue. runnable.schedule(); task } /// Runs a future to completion. fn run(future: F) -> T where F: Future + 'static, T: 'static, { // Spawn a task that sends its result through a channel. let (s, r) = flume::unbounded(); spawn(async move { drop(s.send(future.await)) }).detach(); loop { // If the original task has completed, return its result. if let Ok(val) = r.try_recv() { return val; } // Otherwise, take a task from the queue and run it. QUEUE.with(|(_, r)| r.recv().unwrap().run()); } } fn main() { let val = Rc::new(Cell::new(0)); // Run a future that increments a non-`Send` value. run({ let val = val.clone(); async move { // Spawn a future that increments the value. let task = spawn({ let val = val.clone(); async move { val.set(dbg!(val.get()) + 1); } }); val.set(dbg!(val.get()) + 1); task.await; } }); // The value should be 2 at the end of the program. dbg!(val.get()); }