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denoland-deno/tests/integration/jupyter_tests.rs
Nathan Whitaker 672216d65a
fix(lsp): Pass diagnostic codes to TSC as numbers (#23720)
Fixes the `Debug Failure` errors described in
https://github.com/denoland/deno/issues/23643#issuecomment-2094552765 .

The issue here was that we were passing diagnostic codes as strings but
TSC expects the codes to be numbers. This resulted in some quick fixes
not working (as illustrated by the test added here which fails before
this PR).

The first commit is the actual fix. The rest are just test related.
2024-05-06 23:54:52 +00:00

631 lines
16 KiB
Rust

// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
use std::process::Output;
use std::sync::Arc;
use std::time::Duration;
use bytes::Bytes;
use test_util::assertions::assert_json_subset;
use test_util::DenoChild;
use test_util::TestContext;
use test_util::TestContextBuilder;
use deno_core::anyhow::Result;
use deno_core::serde_json;
use deno_core::serde_json::json;
use deno_core::serde_json::Value;
use serde::Deserialize;
use serde::Serialize;
use tokio::sync::Mutex;
use tokio::time::timeout;
use uuid::Uuid;
use zeromq::SocketRecv;
use zeromq::SocketSend;
use zeromq::ZmqMessage;
// for the `utc_now` function
include!("../../cli/util/time.rs");
/// Jupyter connection file format
#[derive(Serialize)]
struct ConnectionSpec {
// key used for HMAC signature, if empty, hmac is not used
key: String,
signature_scheme: String,
transport: String,
ip: String,
hb_port: u16,
control_port: u16,
shell_port: u16,
stdin_port: u16,
iopub_port: u16,
kernel_name: String,
}
impl ConnectionSpec {
fn endpoint(&self, port: u16) -> String {
format!("{}://{}:{}", self.transport, self.ip, port)
}
}
/// Gets an unused port from the OS, and returns the port number and a
/// `TcpListener` bound to that port. You can keep the listener alive
/// to prevent another process from binding to the port.
fn pick_unused_port() -> (u16, std::net::TcpListener) {
let listener = std::net::TcpListener::bind("127.0.0.1:0").unwrap();
(listener.local_addr().unwrap().port(), listener)
}
impl ConnectionSpec {
fn new() -> (Self, Vec<std::net::TcpListener>) {
let mut listeners = Vec::new();
let (hb_port, listener) = pick_unused_port();
listeners.push(listener);
let (control_port, listener) = pick_unused_port();
listeners.push(listener);
let (shell_port, listener) = pick_unused_port();
listeners.push(listener);
let (stdin_port, listener) = pick_unused_port();
listeners.push(listener);
let (iopub_port, listener) = pick_unused_port();
listeners.push(listener);
(
Self {
key: "".into(),
signature_scheme: "hmac-sha256".into(),
transport: "tcp".into(),
ip: "127.0.0.1".into(),
hb_port,
control_port,
shell_port,
stdin_port,
iopub_port,
kernel_name: "deno".into(),
},
listeners,
)
}
}
const DELIMITER: &[u8] = b"<IDS|MSG>";
#[derive(Debug, Clone)]
struct JupyterMsg {
routing_prefix: Vec<String>,
signature: String,
header: MsgHeader,
parent_header: Value,
metadata: Value,
content: Value,
buffers: Vec<Bytes>,
}
impl Default for JupyterMsg {
fn default() -> Self {
Self {
routing_prefix: vec![Uuid::new_v4().to_string()],
signature: "".into(),
header: MsgHeader::default(),
parent_header: json!({}),
metadata: json!({}),
content: json!({}),
buffers: Vec::new(),
}
}
}
#[derive(Serialize, Clone, Debug, Deserialize)]
struct MsgHeader {
msg_id: Uuid,
session: Uuid,
date: String,
username: String,
msg_type: String,
version: String,
}
impl MsgHeader {
fn to_json(&self) -> Value {
serde_json::to_value(self).unwrap()
}
}
impl Default for MsgHeader {
fn default() -> Self {
Self {
msg_id: Uuid::new_v4(),
session: Uuid::new_v4(),
date: utc_now().to_rfc3339(),
username: "test".into(),
msg_type: "kernel_info_request".into(),
version: "5.3".into(),
}
}
}
impl JupyterMsg {
fn to_raw(&self) -> ZmqMessage {
let mut parts = Vec::new();
parts.extend(
self
.routing_prefix
.iter()
.map(|uuid| uuid.as_bytes().to_vec().into()),
);
parts.push(Bytes::from_static(DELIMITER));
parts.push(self.signature.clone().into());
parts.push(serde_json::to_vec(&self.header).unwrap().into());
parts.push(self.parent_header.to_string().into());
parts.push(self.metadata.to_string().into());
parts.push(self.content.to_string().into());
parts.extend(self.buffers.clone());
ZmqMessage::try_from(parts).unwrap()
}
fn new(session: Uuid, msg_type: impl AsRef<str>, content: Value) -> Self {
Self {
header: MsgHeader {
session,
msg_type: msg_type.as_ref().into(),
..Default::default()
},
content,
..Default::default()
}
}
fn from_raw(msg: ZmqMessage) -> Self {
let parts = msg.into_vec();
let delimiter = parts.iter().position(|part| part == DELIMITER).unwrap();
let routing_prefix = parts[..delimiter]
.iter()
.map(|part: &Bytes| String::from_utf8_lossy(part.as_ref()).to_string())
.collect();
let signature = String::from_utf8(parts[delimiter + 1].to_vec())
.expect("Failed to parse signature");
let header: MsgHeader = serde_json::from_slice(&parts[delimiter + 2])
.expect("Failed to parse header");
let parent_header: Value =
serde_json::from_slice(&parts[delimiter + 3]).unwrap();
let metadata: Value =
serde_json::from_slice(&parts[delimiter + 4]).unwrap();
let content: Value = serde_json::from_slice(&parts[delimiter + 5]).unwrap();
let buffers = parts[delimiter + 6..].to_vec();
Self {
routing_prefix,
signature,
header,
parent_header,
metadata,
content,
buffers,
}
}
}
async fn connect_socket<S: zeromq::Socket>(
spec: &ConnectionSpec,
port: u16,
) -> S {
let addr = spec.endpoint(port);
let mut socket = S::new();
match timeout(Duration::from_millis(5000), socket.connect(&addr)).await {
Ok(Ok(_)) => socket,
Ok(Err(e)) => {
panic!("Failed to connect to {addr}: {e}");
}
Err(e) => {
panic!("Timed out connecting to {addr}: {e}");
}
}
}
#[derive(Clone)]
struct JupyterClient {
recv_timeout: Duration,
session: Uuid,
heartbeat: Arc<Mutex<zeromq::ReqSocket>>,
control: Arc<Mutex<zeromq::DealerSocket>>,
shell: Arc<Mutex<zeromq::DealerSocket>>,
io_pub: Arc<Mutex<zeromq::SubSocket>>,
stdin: Arc<Mutex<zeromq::RouterSocket>>,
}
#[derive(Debug, Clone, Copy)]
enum JupyterChannel {
Control,
Shell,
#[allow(dead_code)]
Stdin,
IoPub,
}
use JupyterChannel::*;
impl JupyterClient {
async fn new(spec: &ConnectionSpec) -> Self {
Self::new_with_timeout(spec, Duration::from_secs(10)).await
}
async fn new_with_timeout(spec: &ConnectionSpec, timeout: Duration) -> Self {
let (heartbeat, control, shell, io_pub, stdin) = tokio::join!(
connect_socket::<zeromq::ReqSocket>(spec, spec.hb_port),
connect_socket::<zeromq::DealerSocket>(spec, spec.control_port),
connect_socket::<zeromq::DealerSocket>(spec, spec.shell_port),
connect_socket::<zeromq::SubSocket>(spec, spec.iopub_port),
connect_socket::<zeromq::RouterSocket>(spec, spec.stdin_port),
);
Self {
session: Uuid::new_v4(),
heartbeat: Arc::new(Mutex::new(heartbeat)),
control: Arc::new(Mutex::new(control)),
shell: Arc::new(Mutex::new(shell)),
io_pub: Arc::new(Mutex::new(io_pub)),
stdin: Arc::new(Mutex::new(stdin)),
recv_timeout: timeout,
}
}
async fn io_subscribe(&self, topic: &str) -> Result<()> {
Ok(self.io_pub.lock().await.subscribe(topic).await?)
}
async fn recv_with_timeout<S: SocketRecv>(
&self,
s: &mut S,
) -> Result<JupyterMsg> {
let msg = timeout(self.recv_timeout, s.recv()).await??;
Ok(JupyterMsg::from_raw(msg))
}
async fn send_msg(
&self,
channel: JupyterChannel,
msg: JupyterMsg,
) -> Result<JupyterMsg> {
let raw = msg.to_raw();
match channel {
Control => self.control.lock().await.send(raw).await?,
Shell => self.shell.lock().await.send(raw).await?,
Stdin => self.stdin.lock().await.send(raw).await?,
IoPub => panic!("Cannot send over IOPub"),
}
Ok(msg)
}
async fn send(
&self,
channel: JupyterChannel,
msg_type: &str,
content: Value,
) -> Result<JupyterMsg> {
let msg = JupyterMsg::new(self.session, msg_type, content);
self.send_msg(channel, msg).await
}
async fn recv(&self, channel: JupyterChannel) -> Result<JupyterMsg> {
Ok(match channel {
Control => {
self
.recv_with_timeout(&mut *self.control.lock().await)
.await?
}
Shell => {
self
.recv_with_timeout(&mut *self.shell.lock().await)
.await?
}
Stdin => {
self
.recv_with_timeout(&mut *self.stdin.lock().await)
.await?
}
IoPub => {
self
.recv_with_timeout(&mut *self.io_pub.lock().await)
.await?
}
})
}
async fn send_heartbeat(&self, bytes: impl AsRef<[u8]>) -> Result<()> {
Ok(
self
.heartbeat
.lock()
.await
.send(ZmqMessage::from(bytes.as_ref().to_vec()))
.await?,
)
}
async fn recv_heartbeat(&self) -> Result<Bytes> {
Ok(
timeout(self.recv_timeout, self.heartbeat.lock().await.recv())
.await??
.into_vec()[0]
.clone(),
)
}
}
async fn wait_or_kill(
mut process: DenoChild,
wait: Duration,
) -> Result<Output> {
let start = std::time::Instant::now();
while start.elapsed() < wait {
if process.try_wait()?.is_some() {
return Ok(process.wait_with_output()?);
}
tokio::time::sleep(Duration::from_millis(100)).await;
}
process.kill()?;
Ok(process.wait_with_output()?)
}
// Wrapper around the Jupyter server process that
// ensures the process is killed when dropped.
struct JupyterServerProcess(Option<DenoChild>);
impl JupyterServerProcess {
// Wait for the process to exit, or kill it after the given duration.
//
// Ideally we could use this at the end of each test, but the server
// doesn't seem to exit in a reasonable amount of time after getting
// a shutdown request.
#[allow(dead_code)]
async fn wait_or_kill(mut self, wait: Duration) -> Output {
wait_or_kill(self.0.take().unwrap(), wait).await.unwrap()
}
}
impl Drop for JupyterServerProcess {
fn drop(&mut self) {
let Some(mut proc) = self.0.take() else {
return;
};
if proc.try_wait().unwrap().is_some() {
// already exited
return;
}
proc.kill().unwrap();
}
}
async fn server_ready_on(addr: &str) -> bool {
matches!(
timeout(
Duration::from_millis(1000),
tokio::net::TcpStream::connect(addr.trim_start_matches("tcp://")),
)
.await,
Ok(Ok(_))
)
}
async fn server_ready(conn: &ConnectionSpec) -> bool {
let hb = conn.endpoint(conn.hb_port);
let control = conn.endpoint(conn.control_port);
let shell = conn.endpoint(conn.shell_port);
let stdin = conn.endpoint(conn.stdin_port);
let iopub = conn.endpoint(conn.iopub_port);
let (a, b, c, d, e) = tokio::join!(
server_ready_on(&hb),
server_ready_on(&control),
server_ready_on(&shell),
server_ready_on(&stdin),
server_ready_on(&iopub),
);
a && b && c && d && e
}
async fn setup_server() -> (TestContext, ConnectionSpec, JupyterServerProcess) {
let context = TestContextBuilder::new().use_temp_cwd().build();
let (mut conn, mut listeners) = ConnectionSpec::new();
let conn_file = context.temp_dir().path().join("connection.json");
conn_file.write_json(&conn);
let start_process = |conn_file: &test_util::PathRef| {
context
.new_command()
.args_vec(vec![
"jupyter",
"--kernel",
"--conn",
conn_file.to_string().as_str(),
])
.spawn()
.unwrap()
};
// drop the listeners so the server can listen on the ports
drop(listeners);
// try to start the server, retrying up to 5 times
// (this can happen due to TOCTOU errors with selecting unused TCP ports)
let mut process = start_process(&conn_file);
'outer: for i in 0..10 {
// try to see if the server is healthy
for _ in 0..10 {
// server still running?
if process.try_wait().unwrap().is_none() {
// listening on all ports?
if server_ready(&conn).await {
// server is ready to go
break 'outer;
}
} else {
// server exited, try again
break;
}
tokio::time::sleep(Duration::from_millis(500)).await;
}
// pick new ports and try again
(conn, listeners) = ConnectionSpec::new();
conn_file.write_json(&conn);
drop(listeners);
process = start_process(&conn_file);
tokio::time::sleep(Duration::from_millis((i + 1) * 250)).await;
}
if process.try_wait().unwrap().is_some() || !server_ready(&conn).await {
panic!("Failed to start Jupyter server");
}
(context, conn, JupyterServerProcess(Some(process)))
}
async fn setup() -> (TestContext, JupyterClient, JupyterServerProcess) {
let (context, conn, process) = setup_server().await;
let client = JupyterClient::new(&conn).await;
client.io_subscribe("").await.unwrap();
// make sure server is ready to receive messages
client.send_heartbeat(b"ping").await.unwrap();
let _ = client.recv_heartbeat().await.unwrap();
(context, client, process)
}
#[tokio::test]
async fn jupyter_heartbeat_echoes() -> Result<()> {
let (_ctx, client, _process) = setup().await;
client.send_heartbeat(b"ping").await?;
let msg = client.recv_heartbeat().await?;
assert_eq!(msg, Bytes::from_static(b"ping"));
Ok(())
}
#[tokio::test]
async fn jupyter_kernel_info() -> Result<()> {
let (_ctx, client, _process) = setup().await;
client
.send(Control, "kernel_info_request", json!({}))
.await?;
let msg = client.recv(Control).await?;
assert_eq!(msg.header.msg_type, "kernel_info_reply");
assert_json_subset(
msg.content,
json!({
"status": "ok",
"implementation": "Deno kernel",
"language_info": {
"name": "typescript",
"mimetype": "text/x.typescript",
"file_extension": ".ts",
"pygments_lexer": "typescript",
"nb_converter": "script"
},
}),
);
Ok(())
}
#[tokio::test]
async fn jupyter_execute_request() -> Result<()> {
let (_ctx, client, _process) = setup().await;
let request = client
.send(
Shell,
"execute_request",
json!({
"silent": false,
"store_history": true,
"user_expressions": {},
"allow_stdin": true,
"stop_on_error": false,
"code": "console.log(\"asdf\")"
}),
)
.await?;
let reply = client.recv(Shell).await?;
assert_eq!(reply.header.msg_type, "execute_reply");
assert_json_subset(
reply.content,
json!({
"status": "ok",
"execution_count": 1,
}),
);
let mut msgs = Vec::new();
for _ in 0..4 {
match client.recv(IoPub).await {
Ok(msg) => msgs.push(msg),
Err(e) => {
if e.downcast_ref::<tokio::time::error::Elapsed>().is_some() {
// may timeout if we missed some messages
eprintln!("Timed out waiting for messages");
}
panic!("Error: {:#?}", e);
}
}
}
let execution_idle = msgs
.iter()
.find(|msg| {
if let Some(state) = msg.content.get("execution_state") {
state == "idle"
} else {
false
}
})
.expect("execution_state idle not found");
assert_eq!(execution_idle.parent_header, request.header.to_json());
assert_json_subset(
execution_idle.content.clone(),
json!({
"execution_state": "idle",
}),
);
let execution_result = msgs
.iter()
.find(|msg| msg.header.msg_type == "stream")
.expect("stream not found");
assert_eq!(execution_result.header.msg_type, "stream");
assert_eq!(execution_result.parent_header, request.header.to_json());
assert_json_subset(
execution_result.content.clone(),
json!({
"name": "stdout",
"text": "asdf\n", // the trailing newline is added by console.log
}),
);
Ok(())
}
#[tokio::test]
async fn jupyter_store_history_false() -> Result<()> {
let (_ctx, client, _process) = setup().await;
client
.send(
Shell,
"execute_request",
json!({
"silent": false,
"store_history": false,
"code": "console.log(\"asdf\")"
}),
)
.await?;
let reply = client.recv(Shell).await?;
assert_eq!(reply.header.msg_type, "execute_reply");
assert_json_subset(
reply.content,
json!({
"status": "ok",
"execution_count": 0,
}),
);
Ok(())
}