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denoland-deno/ext/net/ops_tls.rs

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// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
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use crate::io::TcpStreamResource;
use crate::ops::IpAddr;
use crate::ops::NetError;
use crate::ops::TlsHandshakeInfo;
use crate::raw::NetworkListenerResource;
use crate::resolve_addr::resolve_addr;
use crate::resolve_addr::resolve_addr_sync;
use crate::tcp::TcpListener;
use crate::DefaultTlsOptions;
use crate::NetPermissions;
use crate::UnsafelyIgnoreCertificateErrors;
use deno_core::futures::TryFutureExt;
use deno_core::op2;
use deno_core::v8;
use deno_core::AsyncRefCell;
use deno_core::AsyncResult;
use deno_core::CancelHandle;
use deno_core::CancelTryFuture;
use deno_core::OpState;
use deno_core::RcRef;
use deno_core::Resource;
use deno_core::ResourceId;
use deno_tls::create_client_config;
use deno_tls::load_certs;
use deno_tls::load_private_keys;
use deno_tls::new_resolver;
use deno_tls::rustls::pki_types::ServerName;
use deno_tls::rustls::ClientConnection;
use deno_tls::rustls::ServerConfig;
use deno_tls::ServerConfigProvider;
use deno_tls::SocketUse;
use deno_tls::TlsKey;
use deno_tls::TlsKeyLookup;
use deno_tls::TlsKeys;
use deno_tls::TlsKeysHolder;
use rustls_tokio_stream::TlsStreamRead;
use rustls_tokio_stream::TlsStreamWrite;
use serde::Deserialize;
use std::borrow::Cow;
use std::cell::RefCell;
use std::convert::From;
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use std::fs::File;
use std::io::BufReader;
use std::io::ErrorKind;
use std::io::Read;
use std::net::SocketAddr;
use std::num::NonZeroUsize;
use std::rc::Rc;
use std::sync::Arc;
use tokio::io::AsyncReadExt;
use tokio::io::AsyncWriteExt;
use tokio::net::TcpStream;
pub use rustls_tokio_stream::TlsStream;
pub(crate) const TLS_BUFFER_SIZE: Option<NonZeroUsize> =
NonZeroUsize::new(65536);
pub struct TlsListener {
pub(crate) tcp_listener: TcpListener,
pub(crate) tls_config: Option<Arc<ServerConfig>>,
pub(crate) server_config_provider: Option<ServerConfigProvider>,
}
impl TlsListener {
pub async fn accept(&self) -> std::io::Result<(TlsStream, SocketAddr)> {
let (tcp, addr) = self.tcp_listener.accept().await?;
let tls = if let Some(provider) = &self.server_config_provider {
TlsStream::new_server_side_acceptor(
tcp,
provider.clone(),
TLS_BUFFER_SIZE,
)
} else {
TlsStream::new_server_side(
tcp,
self.tls_config.clone().unwrap(),
TLS_BUFFER_SIZE,
)
};
Ok((tls, addr))
}
pub fn local_addr(&self) -> std::io::Result<SocketAddr> {
self.tcp_listener.local_addr()
}
}
#[derive(Debug)]
pub struct TlsStreamResource {
rd: AsyncRefCell<TlsStreamRead>,
wr: AsyncRefCell<TlsStreamWrite>,
// `None` when a TLS handshake hasn't been done.
handshake_info: RefCell<Option<TlsHandshakeInfo>>,
cancel_handle: CancelHandle, // Only read and handshake ops get canceled.
}
impl TlsStreamResource {
pub fn new((rd, wr): (TlsStreamRead, TlsStreamWrite)) -> Self {
Self {
rd: rd.into(),
wr: wr.into(),
handshake_info: RefCell::new(None),
cancel_handle: Default::default(),
}
}
pub fn into_inner(self) -> (TlsStreamRead, TlsStreamWrite) {
(self.rd.into_inner(), self.wr.into_inner())
}
pub async fn read(
self: Rc<Self>,
feat(core): improve resource read & write traits (#16115) This commit introduces two new buffer wrapper types to `deno_core`. The main benefit of these new wrappers is that they can wrap a number of different underlying buffer types. This allows for a more flexible read and write API on resources that will require less copying of data between different buffer representations. - `BufView` is a read-only view onto a buffer. It can be backed by `ZeroCopyBuf`, `Vec<u8>`, and `bytes::Bytes`. - `BufViewMut` is a read-write view onto a buffer. It can be cheaply converted into a `BufView`. It can be backed by `ZeroCopyBuf` or `Vec<u8>`. Both new buffer views have a cursor. This means that the start point of the view can be constrained to write / read from just a slice of the view. Only the start point of the slice can be adjusted. The end point is fixed. To adjust the end point, the underlying buffer needs to be truncated. Readable resources have been changed to better cater to resources that do not support BYOB reads. The basic `read` method now returns a `BufView` instead of taking a `ZeroCopyBuf` to fill. This allows the operation to return buffers that the resource has already allocated, instead of forcing the caller to allocate the buffer. BYOB reads are still very useful for resources that support them, so a new `read_byob` method has been added that takes a `BufViewMut` to fill. `op_read` attempts to use `read_byob` if the resource supports it, which falls back to `read` and performs an additional copy if it does not. For Rust->JS reads this change should have no impact, but for Rust->Rust reads, this allows the caller to avoid an additional copy in many scenarios. This combined with the support for `BufView` to be backed by `bytes::Bytes` allows us to avoid one data copy when piping from a `fetch` response into an `ext/http` response. Writable resources have been changed to take a `BufView` instead of a `ZeroCopyBuf` as an argument. This allows for less copying of data in certain scenarios, as described above. Additionally a new `Resource::write_all` method has been added that takes a `BufView` and continually attempts to write the resource until the entire buffer has been written. Certain resources like files can override this method to provide a more efficient `write_all` implementation.
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data: &mut [u8],
) -> Result<usize, std::io::Error> {
let mut rd = RcRef::map(&self, |r| &r.rd).borrow_mut().await;
let cancel_handle = RcRef::map(&self, |r| &r.cancel_handle);
rd.read(data).try_or_cancel(cancel_handle).await
}
pub async fn write(
self: Rc<Self>,
data: &[u8],
) -> Result<usize, std::io::Error> {
let mut wr = RcRef::map(self, |r| &r.wr).borrow_mut().await;
feat(core): improve resource read & write traits (#16115) This commit introduces two new buffer wrapper types to `deno_core`. The main benefit of these new wrappers is that they can wrap a number of different underlying buffer types. This allows for a more flexible read and write API on resources that will require less copying of data between different buffer representations. - `BufView` is a read-only view onto a buffer. It can be backed by `ZeroCopyBuf`, `Vec<u8>`, and `bytes::Bytes`. - `BufViewMut` is a read-write view onto a buffer. It can be cheaply converted into a `BufView`. It can be backed by `ZeroCopyBuf` or `Vec<u8>`. Both new buffer views have a cursor. This means that the start point of the view can be constrained to write / read from just a slice of the view. Only the start point of the slice can be adjusted. The end point is fixed. To adjust the end point, the underlying buffer needs to be truncated. Readable resources have been changed to better cater to resources that do not support BYOB reads. The basic `read` method now returns a `BufView` instead of taking a `ZeroCopyBuf` to fill. This allows the operation to return buffers that the resource has already allocated, instead of forcing the caller to allocate the buffer. BYOB reads are still very useful for resources that support them, so a new `read_byob` method has been added that takes a `BufViewMut` to fill. `op_read` attempts to use `read_byob` if the resource supports it, which falls back to `read` and performs an additional copy if it does not. For Rust->JS reads this change should have no impact, but for Rust->Rust reads, this allows the caller to avoid an additional copy in many scenarios. This combined with the support for `BufView` to be backed by `bytes::Bytes` allows us to avoid one data copy when piping from a `fetch` response into an `ext/http` response. Writable resources have been changed to take a `BufView` instead of a `ZeroCopyBuf` as an argument. This allows for less copying of data in certain scenarios, as described above. Additionally a new `Resource::write_all` method has been added that takes a `BufView` and continually attempts to write the resource until the entire buffer has been written. Certain resources like files can override this method to provide a more efficient `write_all` implementation.
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let nwritten = wr.write(data).await?;
wr.flush().await?;
Ok(nwritten)
}
pub async fn shutdown(self: Rc<Self>) -> Result<(), std::io::Error> {
let mut wr = RcRef::map(self, |r| &r.wr).borrow_mut().await;
wr.shutdown().await?;
Ok(())
}
pub async fn handshake(
self: &Rc<Self>,
) -> Result<TlsHandshakeInfo, std::io::Error> {
if let Some(tls_info) = &*self.handshake_info.borrow() {
return Ok(tls_info.clone());
}
let mut wr = RcRef::map(self, |r| &r.wr).borrow_mut().await;
let cancel_handle = RcRef::map(self, |r| &r.cancel_handle);
let handshake = wr.handshake().try_or_cancel(cancel_handle).await?;
let alpn_protocol = handshake.alpn.map(|alpn| alpn.into());
let tls_info = TlsHandshakeInfo { alpn_protocol };
self.handshake_info.replace(Some(tls_info.clone()));
Ok(tls_info)
}
}
impl Resource for TlsStreamResource {
feat(core): improve resource read & write traits (#16115) This commit introduces two new buffer wrapper types to `deno_core`. The main benefit of these new wrappers is that they can wrap a number of different underlying buffer types. This allows for a more flexible read and write API on resources that will require less copying of data between different buffer representations. - `BufView` is a read-only view onto a buffer. It can be backed by `ZeroCopyBuf`, `Vec<u8>`, and `bytes::Bytes`. - `BufViewMut` is a read-write view onto a buffer. It can be cheaply converted into a `BufView`. It can be backed by `ZeroCopyBuf` or `Vec<u8>`. Both new buffer views have a cursor. This means that the start point of the view can be constrained to write / read from just a slice of the view. Only the start point of the slice can be adjusted. The end point is fixed. To adjust the end point, the underlying buffer needs to be truncated. Readable resources have been changed to better cater to resources that do not support BYOB reads. The basic `read` method now returns a `BufView` instead of taking a `ZeroCopyBuf` to fill. This allows the operation to return buffers that the resource has already allocated, instead of forcing the caller to allocate the buffer. BYOB reads are still very useful for resources that support them, so a new `read_byob` method has been added that takes a `BufViewMut` to fill. `op_read` attempts to use `read_byob` if the resource supports it, which falls back to `read` and performs an additional copy if it does not. For Rust->JS reads this change should have no impact, but for Rust->Rust reads, this allows the caller to avoid an additional copy in many scenarios. This combined with the support for `BufView` to be backed by `bytes::Bytes` allows us to avoid one data copy when piping from a `fetch` response into an `ext/http` response. Writable resources have been changed to take a `BufView` instead of a `ZeroCopyBuf` as an argument. This allows for less copying of data in certain scenarios, as described above. Additionally a new `Resource::write_all` method has been added that takes a `BufView` and continually attempts to write the resource until the entire buffer has been written. Certain resources like files can override this method to provide a more efficient `write_all` implementation.
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deno_core::impl_readable_byob!();
deno_core::impl_writable!();
fn name(&self) -> Cow<str> {
"tlsStream".into()
}
fn shutdown(self: Rc<Self>) -> AsyncResult<()> {
Box::pin(self.shutdown().map_err(Into::into))
}
fn close(self: Rc<Self>) {
self.cancel_handle.cancel();
}
}
#[derive(Deserialize)]
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#[serde(rename_all = "camelCase")]
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pub struct ConnectTlsArgs {
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cert_file: Option<String>,
ca_certs: Vec<String>,
alpn_protocols: Option<Vec<String>>,
server_name: Option<String>,
}
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#[derive(Deserialize)]
#[serde(rename_all = "camelCase")]
pub struct StartTlsArgs {
rid: ResourceId,
ca_certs: Vec<String>,
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hostname: String,
alpn_protocols: Option<Vec<String>>,
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}
#[op2]
#[cppgc]
pub fn op_tls_key_null() -> TlsKeysHolder {
TlsKeysHolder::from(TlsKeys::Null)
}
#[op2]
#[cppgc]
pub fn op_tls_key_static(
#[string] cert: &str,
#[string] key: &str,
) -> Result<TlsKeysHolder, deno_tls::TlsError> {
let cert = load_certs(&mut BufReader::new(cert.as_bytes()))?;
let key = load_private_keys(key.as_bytes())?
.into_iter()
.next()
.unwrap();
Ok(TlsKeysHolder::from(TlsKeys::Static(TlsKey(cert, key))))
}
#[op2]
pub fn op_tls_cert_resolver_create<'s>(
scope: &mut v8::HandleScope<'s>,
) -> v8::Local<'s, v8::Array> {
let (resolver, lookup) = new_resolver();
let resolver = deno_core::cppgc::make_cppgc_object(
scope,
TlsKeysHolder::from(TlsKeys::Resolver(resolver)),
);
let lookup = deno_core::cppgc::make_cppgc_object(scope, lookup);
v8::Array::new_with_elements(scope, &[resolver.into(), lookup.into()])
}
#[op2(async)]
#[string]
pub async fn op_tls_cert_resolver_poll(
#[cppgc] lookup: &TlsKeyLookup,
) -> Option<String> {
lookup.poll().await
}
#[op2(fast)]
pub fn op_tls_cert_resolver_resolve(
#[cppgc] lookup: &TlsKeyLookup,
#[string] sni: String,
#[cppgc] key: &TlsKeysHolder,
) -> Result<(), NetError> {
let TlsKeys::Static(key) = key.take() else {
return Err(NetError::UnexpectedKeyType);
};
lookup.resolve(sni, Ok(key));
Ok(())
}
#[op2(fast)]
pub fn op_tls_cert_resolver_resolve_error(
#[cppgc] lookup: &TlsKeyLookup,
#[string] sni: String,
#[string] error: String,
) {
lookup.resolve(sni, Err(error))
}
#[op2(stack_trace)]
#[serde]
pub fn op_tls_start<NP>(
state: Rc<RefCell<OpState>>,
#[serde] args: StartTlsArgs,
) -> Result<(ResourceId, IpAddr, IpAddr), NetError>
where
NP: NetPermissions + 'static,
{
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let rid = args.rid;
let hostname = match &*args.hostname {
"" => "localhost".to_string(),
n => n.to_string(),
};
{
let mut s = state.borrow_mut();
let permissions = s.borrow_mut::<NP>();
permissions
.check_net(&(&hostname, Some(0)), "Deno.startTls()")
.map_err(NetError::Permission)?;
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}
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let ca_certs = args
.ca_certs
.into_iter()
.map(|s| s.into_bytes())
.collect::<Vec<_>>();
let hostname_dns = ServerName::try_from(hostname.to_string())
.map_err(|_| NetError::InvalidHostname(hostname))?;
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let unsafely_ignore_certificate_errors = state
.borrow()
.try_borrow::<UnsafelyIgnoreCertificateErrors>()
.and_then(|it| it.0.clone());
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let root_cert_store = state
.borrow()
.borrow::<DefaultTlsOptions>()
.root_cert_store()
.map_err(NetError::RootCertStore)?;
let resource_rc = state
.borrow_mut()
.resource_table
.take::<TcpStreamResource>(rid)
.map_err(NetError::Resource)?;
// This TCP connection might be used somewhere else. If it's the case, we cannot proceed with the
// process of starting a TLS connection on top of this TCP connection, so we just return a Busy error.
// See also: https://github.com/denoland/deno/pull/16242
let resource =
Rc::try_unwrap(resource_rc).map_err(|_| NetError::TcpStreamBusy)?;
let (read_half, write_half) = resource.into_inner();
let tcp_stream = read_half.reunite(write_half).map_err(NetError::Reunite)?;
let local_addr = tcp_stream.local_addr()?;
let remote_addr = tcp_stream.peer_addr()?;
let mut tls_config = create_client_config(
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root_cert_store,
ca_certs,
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unsafely_ignore_certificate_errors,
TlsKeys::Null,
SocketUse::GeneralSsl,
)?;
if let Some(alpn_protocols) = args.alpn_protocols {
tls_config.alpn_protocols =
alpn_protocols.into_iter().map(|s| s.into_bytes()).collect();
}
let tls_config = Arc::new(tls_config);
let tls_stream = TlsStream::new_client_side(
tcp_stream,
ClientConnection::new(tls_config, hostname_dns)?,
TLS_BUFFER_SIZE,
);
let rid = {
let mut state_ = state.borrow_mut();
state_
.resource_table
.add(TlsStreamResource::new(tls_stream.into_split()))
};
Ok((rid, IpAddr::from(local_addr), IpAddr::from(remote_addr)))
}
#[op2(async, stack_trace)]
#[serde]
pub async fn op_net_connect_tls<NP>(
state: Rc<RefCell<OpState>>,
#[serde] addr: IpAddr,
#[serde] args: ConnectTlsArgs,
#[cppgc] key_pair: &TlsKeysHolder,
) -> Result<(ResourceId, IpAddr, IpAddr), NetError>
where
NP: NetPermissions + 'static,
{
let cert_file = args.cert_file.as_deref();
let unsafely_ignore_certificate_errors = state
.borrow()
.try_borrow::<UnsafelyIgnoreCertificateErrors>()
.and_then(|it| it.0.clone());
let cert_file = {
let mut s = state.borrow_mut();
let permissions = s.borrow_mut::<NP>();
permissions
.check_net(&(&addr.hostname, Some(addr.port)), "Deno.connectTls()")
.map_err(NetError::Permission)?;
if let Some(path) = cert_file {
Some(
permissions
.check_read(path, "Deno.connectTls()")
.map_err(NetError::Permission)?,
)
} else {
None
}
};
let mut ca_certs = args
.ca_certs
.into_iter()
.map(|s| s.into_bytes())
.collect::<Vec<_>>();
if let Some(path) = cert_file {
let mut buf = Vec::new();
File::open(path)?.read_to_end(&mut buf)?;
ca_certs.push(buf);
};
let root_cert_store = state
.borrow()
.borrow::<DefaultTlsOptions>()
.root_cert_store()
.map_err(NetError::RootCertStore)?;
let hostname_dns = if let Some(server_name) = args.server_name {
ServerName::try_from(server_name)
} else {
ServerName::try_from(addr.hostname.clone())
}
.map_err(|_| NetError::InvalidHostname(addr.hostname.clone()))?;
let connect_addr = resolve_addr(&addr.hostname, addr.port)
.await?
.next()
.ok_or_else(|| NetError::NoResolvedAddress)?;
let tcp_stream = TcpStream::connect(connect_addr).await?;
let local_addr = tcp_stream.local_addr()?;
let remote_addr = tcp_stream.peer_addr()?;
let mut tls_config = create_client_config(
root_cert_store,
ca_certs,
unsafely_ignore_certificate_errors,
key_pair.take(),
SocketUse::GeneralSsl,
)?;
if let Some(alpn_protocols) = args.alpn_protocols {
tls_config.alpn_protocols =
alpn_protocols.into_iter().map(|s| s.into_bytes()).collect();
}
let tls_config = Arc::new(tls_config);
let tls_stream = TlsStream::new_client_side(
tcp_stream,
ClientConnection::new(tls_config, hostname_dns)?,
TLS_BUFFER_SIZE,
);
let rid = {
let mut state_ = state.borrow_mut();
state_
.resource_table
.add(TlsStreamResource::new(tls_stream.into_split()))
};
Ok((rid, IpAddr::from(local_addr), IpAddr::from(remote_addr)))
}
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#[derive(Deserialize)]
#[serde(rename_all = "camelCase")]
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pub struct ListenTlsArgs {
alpn_protocols: Option<Vec<String>>,
reuse_port: bool,
feat(serve): Opt-in parallelism for `deno serve` (#24920) Adds a `parallel` flag to `deno serve`. When present, we spawn multiple workers to parallelize serving requests. ```bash deno serve --parallel main.ts ``` Currently on linux we use `SO_REUSEPORT` and rely on the fact that the kernel will distribute connections in a round-robin manner. On mac and windows, we sort of emulate this by cloning the underlying file descriptor and passing a handle to each worker. The connections will not be guaranteed to be fairly distributed (and in practice almost certainly won't be), but the distribution is still spread enough to provide a significant performance increase. --- (Run on an Macbook Pro with an M3 Max, serving `deno.com` baseline:: ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 239.78ms 13.56ms 330.54ms 79.12% Req/Sec 258.58 35.56 360.00 70.64% Latency Distribution 50% 236.72ms 75% 248.46ms 90% 256.84ms 99% 268.23ms 15458 requests in 30.02s, 2.47GB read Requests/sec: 514.89 Transfer/sec: 84.33MB ``` this PR (`with --parallel` flag) ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 117.40ms 142.84ms 590.45ms 79.07% Req/Sec 1.33k 175.19 1.77k 69.00% Latency Distribution 50% 22.34ms 75% 223.67ms 90% 357.32ms 99% 460.50ms 79636 requests in 30.07s, 12.74GB read Requests/sec: 2647.96 Transfer/sec: 433.71MB ```
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#[serde(default)]
load_balanced: bool,
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}
#[op2(stack_trace)]
#[serde]
pub fn op_net_listen_tls<NP>(
state: &mut OpState,
#[serde] addr: IpAddr,
#[serde] args: ListenTlsArgs,
#[cppgc] keys: &TlsKeysHolder,
) -> Result<(ResourceId, IpAddr), NetError>
where
NP: NetPermissions + 'static,
{
if args.reuse_port {
super::check_unstable(state, "Deno.listenTls({ reusePort: true })");
}
{
let permissions = state.borrow_mut::<NP>();
permissions
.check_net(&(&addr.hostname, Some(addr.port)), "Deno.listenTls()")
.map_err(NetError::Permission)?;
}
let bind_addr = resolve_addr_sync(&addr.hostname, addr.port)?
.next()
.ok_or(NetError::NoResolvedAddress)?;
feat(serve): Opt-in parallelism for `deno serve` (#24920) Adds a `parallel` flag to `deno serve`. When present, we spawn multiple workers to parallelize serving requests. ```bash deno serve --parallel main.ts ``` Currently on linux we use `SO_REUSEPORT` and rely on the fact that the kernel will distribute connections in a round-robin manner. On mac and windows, we sort of emulate this by cloning the underlying file descriptor and passing a handle to each worker. The connections will not be guaranteed to be fairly distributed (and in practice almost certainly won't be), but the distribution is still spread enough to provide a significant performance increase. --- (Run on an Macbook Pro with an M3 Max, serving `deno.com` baseline:: ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 239.78ms 13.56ms 330.54ms 79.12% Req/Sec 258.58 35.56 360.00 70.64% Latency Distribution 50% 236.72ms 75% 248.46ms 90% 256.84ms 99% 268.23ms 15458 requests in 30.02s, 2.47GB read Requests/sec: 514.89 Transfer/sec: 84.33MB ``` this PR (`with --parallel` flag) ``` ❯ wrk -d 30s -c 125 --latency http://127.0.0.1:8000 Running 30s test @ http://127.0.0.1:8000 2 threads and 125 connections Thread Stats Avg Stdev Max +/- Stdev Latency 117.40ms 142.84ms 590.45ms 79.07% Req/Sec 1.33k 175.19 1.77k 69.00% Latency Distribution 50% 22.34ms 75% 223.67ms 90% 357.32ms 99% 460.50ms 79636 requests in 30.07s, 12.74GB read Requests/sec: 2647.96 Transfer/sec: 433.71MB ```
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let tcp_listener = if args.load_balanced {
TcpListener::bind_load_balanced(bind_addr)
} else {
TcpListener::bind_direct(bind_addr, args.reuse_port)
}?;
let local_addr = tcp_listener.local_addr()?;
let alpn = args
.alpn_protocols
.unwrap_or_default()
.into_iter()
.map(|s| s.into_bytes())
.collect();
let listener = match keys.take() {
TlsKeys::Null => return Err(NetError::ListenTlsRequiresKey),
TlsKeys::Static(TlsKey(cert, key)) => {
let mut tls_config = ServerConfig::builder()
.with_no_client_auth()
.with_single_cert(cert, key)?;
tls_config.alpn_protocols = alpn;
TlsListener {
tcp_listener,
tls_config: Some(tls_config.into()),
server_config_provider: None,
}
}
TlsKeys::Resolver(resolver) => TlsListener {
tcp_listener,
tls_config: None,
server_config_provider: Some(resolver.into_server_config_provider(alpn)),
},
};
let tls_listener_resource = NetworkListenerResource::new(listener);
let rid = state.resource_table.add(tls_listener_resource);
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Ok((rid, IpAddr::from(local_addr)))
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}
#[op2(async)]
#[serde]
pub async fn op_net_accept_tls(
state: Rc<RefCell<OpState>>,
#[smi] rid: ResourceId,
) -> Result<(ResourceId, IpAddr, IpAddr), NetError> {
let resource = state
.borrow()
.resource_table
.get::<NetworkListenerResource<TlsListener>>(rid)
.map_err(|_| NetError::ListenerClosed)?;
let cancel_handle = RcRef::map(&resource, |r| &r.cancel);
let listener = RcRef::map(&resource, |r| &r.listener)
.try_borrow_mut()
.ok_or_else(|| NetError::AcceptTaskOngoing)?;
let (tls_stream, remote_addr) =
match listener.accept().try_or_cancel(&cancel_handle).await {
Ok(tuple) => tuple,
Err(err) if err.kind() == ErrorKind::Interrupted => {
return Err(NetError::ListenerClosed);
}
Err(err) => return Err(err.into()),
};
let local_addr = tls_stream.local_addr()?;
let rid = {
let mut state_ = state.borrow_mut();
state_
.resource_table
.add(TlsStreamResource::new(tls_stream.into_split()))
};
Ok((rid, IpAddr::from(local_addr), IpAddr::from(remote_addr)))
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}
#[op2(async)]
#[serde]
pub async fn op_tls_handshake(
state: Rc<RefCell<OpState>>,
#[smi] rid: ResourceId,
) -> Result<TlsHandshakeInfo, NetError> {
let resource = state
.borrow()
.resource_table
.get::<TlsStreamResource>(rid)
.map_err(|_| NetError::ListenerClosed)?;
resource.handshake().await.map_err(Into::into)
}