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denoland-deno/tests/integration/jupyter_tests.rs

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// 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 chrono::DateTime;
use chrono::Utc;
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;
/// 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: DateTime<Utc>,
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: chrono::Utc::now(),
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"pong"));
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",
"nbconvert_exporter": "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(())
}