#![cfg(not(loom))] //! A mock type implementing [`AsyncRead`] and [`AsyncWrite`]. //! //! //! # Overview //! //! Provides a type that implements [`AsyncRead`] + [`AsyncWrite`] that can be configured //! to handle an arbitrary sequence of read and write operations. This is useful //! for writing unit tests for networking services as using an actual network //! type is fairly non deterministic. //! //! # Usage //! //! Attempting to write data that the mock isn't expecting will result in a //! panic. //! //! [`AsyncRead`]: tokio::io::AsyncRead //! [`AsyncWrite`]: tokio::io::AsyncWrite use tokio::io::{AsyncRead, AsyncWrite, ReadBuf}; use tokio::sync::mpsc; use tokio::time::{self, Duration, Instant, Sleep}; use futures_core::ready; use std::collections::VecDeque; use std::future::Future; use std::pin::Pin; use std::sync::Arc; use std::task::{self, Poll, Waker}; use std::{cmp, io}; /// An I/O object that follows a predefined script. /// /// This value is created by `Builder` and implements `AsyncRead` + `AsyncWrite`. It /// follows the scenario described by the builder and panics otherwise. #[derive(Debug)] pub struct Mock { inner: Inner, } /// A handle to send additional actions to the related `Mock`. #[derive(Debug)] pub struct Handle { tx: mpsc::UnboundedSender, } /// Builds `Mock` instances. #[derive(Debug, Clone, Default)] pub struct Builder { // Sequence of actions for the Mock to take actions: VecDeque, } #[derive(Debug, Clone)] enum Action { Read(Vec), Write(Vec), Wait(Duration), // Wrapped in Arc so that Builder can be cloned and Send. // Mock is not cloned as does not need to check Rc for ref counts. ReadError(Option>), WriteError(Option>), } #[derive(Debug)] struct Inner { actions: VecDeque, waiting: Option, sleep: Option, read_wait: Option, rx: mpsc::UnboundedReceiver, } impl Builder { /// Return a new, empty `Builder. pub fn new() -> Self { Self::default() } /// Sequence a `read` operation. /// /// The next operation in the mock's script will be to expect a `read` call /// and return `buf`. pub fn read(&mut self, buf: &[u8]) -> &mut Self { self.actions.push_back(Action::Read(buf.into())); self } /// Sequence a `read` operation that produces an error. /// /// The next operation in the mock's script will be to expect a `read` call /// and return `error`. pub fn read_error(&mut self, error: io::Error) -> &mut Self { let error = Some(error.into()); self.actions.push_back(Action::ReadError(error)); self } /// Sequence a `write` operation. /// /// The next operation in the mock's script will be to expect a `write` /// call. pub fn write(&mut self, buf: &[u8]) -> &mut Self { self.actions.push_back(Action::Write(buf.into())); self } /// Sequence a `write` operation that produces an error. /// /// The next operation in the mock's script will be to expect a `write` /// call that provides `error`. pub fn write_error(&mut self, error: io::Error) -> &mut Self { let error = Some(error.into()); self.actions.push_back(Action::WriteError(error)); self } /// Sequence a wait. /// /// The next operation in the mock's script will be to wait without doing so /// for `duration` amount of time. pub fn wait(&mut self, duration: Duration) -> &mut Self { let duration = cmp::max(duration, Duration::from_millis(1)); self.actions.push_back(Action::Wait(duration)); self } /// Build a `Mock` value according to the defined script. pub fn build(&mut self) -> Mock { let (mock, _) = self.build_with_handle(); mock } /// Build a `Mock` value paired with a handle pub fn build_with_handle(&mut self) -> (Mock, Handle) { let (inner, handle) = Inner::new(self.actions.clone()); let mock = Mock { inner }; (mock, handle) } } impl Handle { /// Sequence a `read` operation. /// /// The next operation in the mock's script will be to expect a `read` call /// and return `buf`. pub fn read(&mut self, buf: &[u8]) -> &mut Self { self.tx.send(Action::Read(buf.into())).unwrap(); self } /// Sequence a `read` operation error. /// /// The next operation in the mock's script will be to expect a `read` call /// and return `error`. pub fn read_error(&mut self, error: io::Error) -> &mut Self { let error = Some(error.into()); self.tx.send(Action::ReadError(error)).unwrap(); self } /// Sequence a `write` operation. /// /// The next operation in the mock's script will be to expect a `write` /// call. pub fn write(&mut self, buf: &[u8]) -> &mut Self { self.tx.send(Action::Write(buf.into())).unwrap(); self } /// Sequence a `write` operation error. /// /// The next operation in the mock's script will be to expect a `write` /// call error. pub fn write_error(&mut self, error: io::Error) -> &mut Self { let error = Some(error.into()); self.tx.send(Action::WriteError(error)).unwrap(); self } } impl Inner { fn new(actions: VecDeque) -> (Inner, Handle) { let (tx, rx) = mpsc::unbounded_channel(); let inner = Inner { actions, sleep: None, read_wait: None, rx, waiting: None, }; let handle = Handle { tx }; (inner, handle) } fn poll_action(&mut self, cx: &mut task::Context<'_>) -> Poll> { use futures_core::stream::Stream; Pin::new(&mut self.rx).poll_next(cx) } fn read(&mut self, dst: &mut ReadBuf<'_>) -> io::Result<()> { match self.action() { Some(&mut Action::Read(ref mut data)) => { // Figure out how much to copy let n = cmp::min(dst.remaining(), data.len()); // Copy the data into the `dst` slice dst.put_slice(&data[..n]); // Drain the data from the source data.drain(..n); Ok(()) } Some(&mut Action::ReadError(ref mut err)) => { // As the let err = err.take().expect("Should have been removed from actions."); let err = Arc::try_unwrap(err).expect("There are no other references."); Err(err) } Some(_) => { // Either waiting or expecting a write Err(io::ErrorKind::WouldBlock.into()) } None => Ok(()), } } fn write(&mut self, mut src: &[u8]) -> io::Result { let mut ret = 0; if self.actions.is_empty() { return Err(io::ErrorKind::BrokenPipe.into()); } if let Some(&mut Action::Wait(..)) = self.action() { return Err(io::ErrorKind::WouldBlock.into()); } if let Some(&mut Action::WriteError(ref mut err)) = self.action() { let err = err.take().expect("Should have been removed from actions."); let err = Arc::try_unwrap(err).expect("There are no other references."); return Err(err); } for i in 0..self.actions.len() { match self.actions[i] { Action::Write(ref mut expect) => { let n = cmp::min(src.len(), expect.len()); assert_eq!(&src[..n], &expect[..n]); // Drop data that was matched expect.drain(..n); src = &src[n..]; ret += n; if src.is_empty() { return Ok(ret); } } Action::Wait(..) | Action::WriteError(..) => { break; } _ => {} } // TODO: remove write } Ok(ret) } fn remaining_wait(&mut self) -> Option { match self.action() { Some(&mut Action::Wait(dur)) => Some(dur), _ => None, } } fn action(&mut self) -> Option<&mut Action> { loop { if self.actions.is_empty() { return None; } match self.actions[0] { Action::Read(ref mut data) => { if !data.is_empty() { break; } } Action::Write(ref mut data) => { if !data.is_empty() { break; } } Action::Wait(ref mut dur) => { if let Some(until) = self.waiting { let now = Instant::now(); if now < until { break; } } else { self.waiting = Some(Instant::now() + *dur); break; } } Action::ReadError(ref mut error) | Action::WriteError(ref mut error) => { if error.is_some() { break; } } } let _action = self.actions.pop_front(); } self.actions.front_mut() } } // ===== impl Inner ===== impl Mock { fn maybe_wakeup_reader(&mut self) { match self.inner.action() { Some(&mut Action::Read(_)) | Some(&mut Action::ReadError(_)) | None => { if let Some(waker) = self.inner.read_wait.take() { waker.wake(); } } _ => {} } } } impl AsyncRead for Mock { fn poll_read( mut self: Pin<&mut Self>, cx: &mut task::Context<'_>, buf: &mut ReadBuf<'_>, ) -> Poll> { loop { if let Some(ref mut sleep) = self.inner.sleep { ready!(Pin::new(sleep).poll(cx)); } // If a sleep is set, it has already fired self.inner.sleep = None; // Capture 'filled' to monitor if it changed let filled = buf.filled().len(); match self.inner.read(buf) { Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => { if let Some(rem) = self.inner.remaining_wait() { let until = Instant::now() + rem; self.inner.sleep = Some(time::sleep_until(until)); } else { self.inner.read_wait = Some(cx.waker().clone()); return Poll::Pending; } } Ok(()) => { if buf.filled().len() == filled { match ready!(self.inner.poll_action(cx)) { Some(action) => { self.inner.actions.push_back(action); continue; } None => { return Poll::Ready(Ok(())); } } } else { return Poll::Ready(Ok(())); } } Err(e) => return Poll::Ready(Err(e)), } } } } impl AsyncWrite for Mock { fn poll_write( mut self: Pin<&mut Self>, cx: &mut task::Context<'_>, buf: &[u8], ) -> Poll> { loop { if let Some(ref mut sleep) = self.inner.sleep { ready!(Pin::new(sleep).poll(cx)); } // If a sleep is set, it has already fired self.inner.sleep = None; match self.inner.write(buf) { Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => { if let Some(rem) = self.inner.remaining_wait() { let until = Instant::now() + rem; self.inner.sleep = Some(time::sleep_until(until)); } else { panic!("unexpected WouldBlock"); } } Ok(0) => { // TODO: Is this correct? if !self.inner.actions.is_empty() { return Poll::Pending; } // TODO: Extract match ready!(self.inner.poll_action(cx)) { Some(action) => { self.inner.actions.push_back(action); continue; } None => { panic!("unexpected write"); } } } ret => { self.maybe_wakeup_reader(); return Poll::Ready(ret); } } } } fn poll_flush(self: Pin<&mut Self>, _cx: &mut task::Context<'_>) -> Poll> { Poll::Ready(Ok(())) } fn poll_shutdown(self: Pin<&mut Self>, _cx: &mut task::Context<'_>) -> Poll> { Poll::Ready(Ok(())) } } /// Ensures that Mock isn't dropped with data "inside". impl Drop for Mock { fn drop(&mut self) { // Avoid double panicking, since makes debugging much harder. if std::thread::panicking() { return; } self.inner.actions.iter().for_each(|a| match a { Action::Read(data) => assert!(data.is_empty(), "There is still data left to read."), Action::Write(data) => assert!(data.is_empty(), "There is still data left to write."), _ => (), }) } } /* /// Returns `true` if called from the context of a futures-rs Task fn is_task_ctx() -> bool { use std::panic; // Save the existing panic hook let h = panic::take_hook(); // Install a new one that does nothing panic::set_hook(Box::new(|_| {})); // Attempt to call the fn let r = panic::catch_unwind(|| task::current()).is_ok(); // Re-install the old one panic::set_hook(h); // Return the result r } */