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denoland-deno/ext/http/lib.rs

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// Copyright 2018-2022 the Deno authors. All rights reserved. MIT license.
use async_compression::tokio::write::BrotliEncoder;
use async_compression::tokio::write::GzipEncoder;
use cache_control::CacheControl;
use deno_core::error::custom_error;
use deno_core::error::AnyError;
use deno_core::futures::channel::mpsc;
use deno_core::futures::channel::oneshot;
use deno_core::futures::future::pending;
use deno_core::futures::future::select;
use deno_core::futures::future::Either;
use deno_core::futures::future::Pending;
use deno_core::futures::future::RemoteHandle;
use deno_core::futures::future::Shared;
use deno_core::futures::never::Never;
use deno_core::futures::pin_mut;
use deno_core::futures::ready;
use deno_core::futures::stream::Peekable;
use deno_core::futures::FutureExt;
use deno_core::futures::StreamExt;
use deno_core::futures::TryFutureExt;
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use deno_core::include_js_files;
use deno_core::op;
use deno_core::AsyncRefCell;
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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use deno_core::AsyncResult;
use deno_core::BufView;
use deno_core::ByteString;
use deno_core::CancelFuture;
use deno_core::CancelHandle;
use deno_core::CancelTryFuture;
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use deno_core::Extension;
use deno_core::OpState;
use deno_core::RcRef;
use deno_core::Resource;
use deno_core::ResourceId;
use deno_core::StringOrBuffer;
use deno_core::ZeroCopyBuf;
use deno_websocket::ws_create_server_stream;
use flate2::write::GzEncoder;
use flate2::Compression;
use fly_accept_encoding::Encoding;
use hyper::body::Bytes;
use hyper::body::HttpBody;
use hyper::body::SizeHint;
use hyper::header::HeaderName;
use hyper::header::HeaderValue;
use hyper::server::conn::Http;
use hyper::service::Service;
use hyper::Body;
use hyper::HeaderMap;
use hyper::Request;
use hyper::Response;
use serde::Serialize;
use std::borrow::Cow;
use std::cell::RefCell;
use std::cmp::min;
use std::error::Error;
use std::future::Future;
use std::io;
use std::io::Write;
use std::mem::replace;
use std::mem::take;
use std::pin::Pin;
use std::rc::Rc;
use std::sync::Arc;
use std::task::Context;
use std::task::Poll;
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use tokio::io::AsyncRead;
use tokio::io::AsyncWrite;
use tokio::io::AsyncWriteExt;
use tokio::task::spawn_local;
use crate::reader_stream::ExternallyAbortableReaderStream;
use crate::reader_stream::ShutdownHandle;
pub mod compressible;
mod reader_stream;
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pub fn init() -> Extension {
Extension::builder()
.js(include_js_files!(
prefix "deno:ext/http",
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"01_http.js",
))
.ops(vec![
op_http_accept::decl(),
op_http_write_headers::decl(),
op_http_headers::decl(),
op_http_write::decl(),
op_http_write_resource::decl(),
op_http_shutdown::decl(),
op_http_websocket_accept_header::decl(),
op_http_upgrade_websocket::decl(),
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])
.build()
}
pub enum HttpSocketAddr {
IpSocket(std::net::SocketAddr),
#[cfg(unix)]
UnixSocket(tokio::net::unix::SocketAddr),
}
impl From<std::net::SocketAddr> for HttpSocketAddr {
fn from(addr: std::net::SocketAddr) -> Self {
Self::IpSocket(addr)
}
}
#[cfg(unix)]
impl From<tokio::net::unix::SocketAddr> for HttpSocketAddr {
fn from(addr: tokio::net::unix::SocketAddr) -> Self {
Self::UnixSocket(addr)
}
}
struct HttpConnResource {
addr: HttpSocketAddr,
scheme: &'static str,
acceptors_tx: mpsc::UnboundedSender<HttpAcceptor>,
closed_fut: Shared<RemoteHandle<Result<(), Arc<hyper::Error>>>>,
cancel_handle: Rc<CancelHandle>, // Closes gracefully and cancels accept ops.
}
impl HttpConnResource {
fn new<S>(io: S, scheme: &'static str, addr: HttpSocketAddr) -> Self
where
S: AsyncRead + AsyncWrite + Unpin + Send + 'static,
{
let (acceptors_tx, acceptors_rx) = mpsc::unbounded::<HttpAcceptor>();
let service = HttpService::new(acceptors_rx);
let conn_fut = Http::new()
.with_executor(LocalExecutor)
.serve_connection(io, service)
.with_upgrades();
// When the cancel handle is used, the connection shuts down gracefully.
// No new HTTP streams will be accepted, but existing streams will be able
// to continue operating and eventually shut down cleanly.
let cancel_handle = CancelHandle::new_rc();
let shutdown_fut = never().or_cancel(&cancel_handle).fuse();
// A local task that polls the hyper connection future to completion.
let task_fut = async move {
pin_mut!(shutdown_fut);
pin_mut!(conn_fut);
let result = match select(conn_fut, shutdown_fut).await {
Either::Left((result, _)) => result,
Either::Right((_, mut conn_fut)) => {
conn_fut.as_mut().graceful_shutdown();
conn_fut.await
}
};
filter_enotconn(result).map_err(Arc::from)
};
let (task_fut, closed_fut) = task_fut.remote_handle();
let closed_fut = closed_fut.shared();
spawn_local(task_fut);
Self {
addr,
scheme,
acceptors_tx,
closed_fut,
cancel_handle,
}
}
// Accepts a new incoming HTTP request.
async fn accept(
self: &Rc<Self>,
) -> Result<Option<(HttpStreamResource, String, String)>, AnyError> {
let fut = async {
let (request_tx, request_rx) = oneshot::channel();
let (response_tx, response_rx) = oneshot::channel();
let acceptor = HttpAcceptor::new(request_tx, response_rx);
self.acceptors_tx.unbounded_send(acceptor).ok()?;
let request = request_rx.await.ok()?;
let accept_encoding = {
let encodings = fly_accept_encoding::encodings_iter(request.headers())
.filter(|r| {
matches!(r, Ok((Some(Encoding::Brotli | Encoding::Gzip), _)))
});
fly_accept_encoding::preferred(encodings)
.ok()
.flatten()
.unwrap_or(Encoding::Identity)
};
let method = request.method().to_string();
let url = req_url(&request, self.scheme, &self.addr);
let stream =
HttpStreamResource::new(self, request, response_tx, accept_encoding);
Some((stream, method, url))
};
async {
match fut.await {
Some(stream) => Ok(Some(stream)),
// Return the connection error, if any.
None => self.closed().map_ok(|_| None).await,
}
}
.try_or_cancel(&self.cancel_handle)
.await
}
/// A future that completes when this HTTP connection is closed or errors.
async fn closed(&self) -> Result<(), AnyError> {
self.closed_fut.clone().map_err(AnyError::from).await
}
}
impl Resource for HttpConnResource {
fn name(&self) -> Cow<str> {
"httpConn".into()
}
fn close(self: Rc<Self>) {
self.cancel_handle.cancel();
}
}
/// Creates a new HttpConn resource which uses `io` as its transport.
pub fn http_create_conn_resource<S, A>(
state: &mut OpState,
io: S,
addr: A,
scheme: &'static str,
) -> Result<ResourceId, AnyError>
where
S: AsyncRead + AsyncWrite + Unpin + Send + 'static,
A: Into<HttpSocketAddr>,
{
let conn = HttpConnResource::new(io, scheme, addr.into());
let rid = state.resource_table.add(conn);
Ok(rid)
}
/// An object that implements the `hyper::Service` trait, through which Hyper
/// delivers incoming HTTP requests.
struct HttpService {
acceptors_rx: Peekable<mpsc::UnboundedReceiver<HttpAcceptor>>,
}
impl HttpService {
fn new(acceptors_rx: mpsc::UnboundedReceiver<HttpAcceptor>) -> Self {
let acceptors_rx = acceptors_rx.peekable();
Self { acceptors_rx }
}
}
impl Service<Request<Body>> for HttpService {
type Response = Response<Body>;
type Error = oneshot::Canceled;
type Future = oneshot::Receiver<Response<Body>>;
fn poll_ready(
&mut self,
cx: &mut Context<'_>,
) -> Poll<Result<(), Self::Error>> {
let acceptors_rx = Pin::new(&mut self.acceptors_rx);
let result = ready!(acceptors_rx.poll_peek(cx))
.map(|_| ())
.ok_or(oneshot::Canceled);
Poll::Ready(result)
}
fn call(&mut self, request: Request<Body>) -> Self::Future {
let acceptor = self.acceptors_rx.next().now_or_never().flatten().unwrap();
acceptor.call(request)
}
}
/// A pair of one-shot channels which first transfer a HTTP request from the
/// Hyper service to the HttpConn resource, and then take the Response back to
/// the service.
struct HttpAcceptor {
request_tx: oneshot::Sender<Request<Body>>,
response_rx: oneshot::Receiver<Response<Body>>,
}
impl HttpAcceptor {
fn new(
request_tx: oneshot::Sender<Request<Body>>,
response_rx: oneshot::Receiver<Response<Body>>,
) -> Self {
Self {
request_tx,
response_rx,
}
}
fn call(self, request: Request<Body>) -> oneshot::Receiver<Response<Body>> {
let Self {
request_tx,
response_rx,
} = self;
request_tx
.send(request)
.map(|_| response_rx)
.unwrap_or_else(|_| oneshot::channel().1) // Make new canceled receiver.
}
}
/// A resource representing a single HTTP request/response stream.
pub struct HttpStreamResource {
conn: Rc<HttpConnResource>,
pub rd: AsyncRefCell<HttpRequestReader>,
wr: AsyncRefCell<HttpResponseWriter>,
accept_encoding: Encoding,
cancel_handle: CancelHandle,
size: SizeHint,
}
impl HttpStreamResource {
fn new(
conn: &Rc<HttpConnResource>,
request: Request<Body>,
response_tx: oneshot::Sender<Response<Body>>,
accept_encoding: Encoding,
) -> Self {
let size = request.body().size_hint();
Self {
conn: conn.clone(),
rd: HttpRequestReader::Headers(request).into(),
wr: HttpResponseWriter::Headers(response_tx).into(),
accept_encoding,
size,
cancel_handle: CancelHandle::new(),
}
}
}
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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impl Resource for HttpStreamResource {
fn name(&self) -> Cow<str> {
"httpStream".into()
}
fn read(self: Rc<Self>, limit: usize) -> AsyncResult<BufView> {
Box::pin(async move {
let mut rd = RcRef::map(&self, |r| &r.rd).borrow_mut().await;
let body = loop {
match &mut *rd {
HttpRequestReader::Headers(_) => {}
HttpRequestReader::Body(_, body) => break body,
HttpRequestReader::Closed => return Ok(BufView::empty()),
}
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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match take(&mut *rd) {
HttpRequestReader::Headers(request) => {
let (parts, body) = request.into_parts();
*rd = HttpRequestReader::Body(parts.headers, body.peekable());
}
_ => unreachable!(),
};
};
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 fut = async {
let mut body = Pin::new(body);
loop {
match body.as_mut().peek_mut().await {
Some(Ok(chunk)) if !chunk.is_empty() => {
let len = min(limit, chunk.len());
let buf = chunk.split_to(len);
let view = BufView::from(buf);
break Ok(view);
}
// This unwrap is safe because `peek_mut()` returned `Some`, and thus
// currently has a peeked value that can be synchronously returned
// from `next()`.
//
// The future returned from `next()` is always ready, so we can
// safely call `await` on it without creating a race condition.
Some(_) => match body.as_mut().next().await.unwrap() {
Ok(chunk) => assert!(chunk.is_empty()),
Err(err) => break Err(AnyError::from(err)),
},
None => break Ok(BufView::empty()),
}
}
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.
2022-10-09 10:49:25 -04:00
};
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 cancel_handle = RcRef::map(&self, |r| &r.cancel_handle);
fut.try_or_cancel(cancel_handle).await
})
}
fn close(self: Rc<Self>) {
self.cancel_handle.cancel();
}
fn size_hint(&self) -> (u64, Option<u64>) {
(self.size.lower(), self.size.upper())
}
}
/// The read half of an HTTP stream.
pub enum HttpRequestReader {
Headers(Request<Body>),
Body(HeaderMap<HeaderValue>, Peekable<Body>),
Closed,
}
impl Default for HttpRequestReader {
fn default() -> Self {
Self::Closed
}
}
/// The write half of an HTTP stream.
enum HttpResponseWriter {
Headers(oneshot::Sender<Response<Body>>),
Body {
writer: Pin<Box<dyn tokio::io::AsyncWrite>>,
shutdown_handle: ShutdownHandle,
},
BodyUncompressed(BodyUncompressedSender),
Closed,
}
impl Default for HttpResponseWriter {
fn default() -> Self {
Self::Closed
}
}
struct BodyUncompressedSender(Option<hyper::body::Sender>);
impl BodyUncompressedSender {
fn sender(&mut self) -> &mut hyper::body::Sender {
// This is safe because we only ever take the sender out of the option
// inside of the shutdown method.
self.0.as_mut().unwrap()
}
fn shutdown(mut self) {
// take the sender out of self so that when self is dropped at the end of
// this block, it doesn't get aborted
self.0.take();
}
}
impl From<hyper::body::Sender> for BodyUncompressedSender {
fn from(sender: hyper::body::Sender) -> Self {
BodyUncompressedSender(Some(sender))
}
}
impl Drop for BodyUncompressedSender {
fn drop(&mut self) {
if let Some(sender) = self.0.take() {
sender.abort();
}
}
}
// We use a tuple instead of struct to avoid serialization overhead of the keys.
#[derive(Serialize)]
#[serde(rename_all = "camelCase")]
struct NextRequestResponse(
// stream_rid:
ResourceId,
// method:
// This is a String rather than a ByteString because reqwest will only return
// the method as a str which is guaranteed to be ASCII-only.
String,
// url:
String,
);
#[op]
async fn op_http_accept(
state: Rc<RefCell<OpState>>,
rid: ResourceId,
) -> Result<Option<NextRequestResponse>, AnyError> {
let conn = state.borrow().resource_table.get::<HttpConnResource>(rid)?;
match conn.accept().await {
Ok(Some((stream, method, url))) => {
let stream_rid =
state.borrow_mut().resource_table.add_rc(Rc::new(stream));
let r = NextRequestResponse(stream_rid, method, url);
Ok(Some(r))
}
Ok(None) => Ok(None),
Err(err) => Err(err),
}
}
fn req_url(
req: &hyper::Request<hyper::Body>,
scheme: &'static str,
addr: &HttpSocketAddr,
) -> String {
let host: Cow<str> = match addr {
HttpSocketAddr::IpSocket(addr) => {
if let Some(auth) = req.uri().authority() {
match addr.port() {
443 if scheme == "https" => Cow::Borrowed(auth.host()),
80 if scheme == "http" => Cow::Borrowed(auth.host()),
_ => Cow::Borrowed(auth.as_str()), // Includes port number.
}
} else if let Some(host) = req.uri().host() {
Cow::Borrowed(host)
} else if let Some(host) = req.headers().get("HOST") {
match host.to_str() {
Ok(host) => Cow::Borrowed(host),
Err(_) => Cow::Owned(
host
.as_bytes()
.iter()
.cloned()
.map(char::from)
.collect::<String>(),
),
}
} else {
Cow::Owned(addr.to_string())
}
}
// There is no standard way for unix domain socket URLs
// nginx and nodejs request use http://unix:[socket_path]:/ but it is not a valid URL
// httpie uses http+unix://[percent_encoding_of_path]/ which we follow
#[cfg(unix)]
HttpSocketAddr::UnixSocket(addr) => Cow::Owned(
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percent_encoding::percent_encode(
addr
.as_pathname()
.and_then(|x| x.to_str())
.unwrap_or_default()
.as_bytes(),
percent_encoding::NON_ALPHANUMERIC,
)
.to_string(),
),
};
let path = req.uri().path_and_query().map_or("/", |p| p.as_str());
[scheme, "://", &host, path].concat()
}
fn req_headers(
header_map: &HeaderMap<HeaderValue>,
) -> Vec<(ByteString, ByteString)> {
// We treat cookies specially, because we don't want them to get them
// mangled by the `Headers` object in JS. What we do is take all cookie
// headers and concat them into a single cookie header, separated by
// semicolons.
let cookie_sep = "; ".as_bytes();
let mut cookies = vec![];
let mut headers = Vec::with_capacity(header_map.len());
for (name, value) in header_map.iter() {
if name == hyper::header::COOKIE {
cookies.push(value.as_bytes());
} else {
let name: &[u8] = name.as_ref();
let value = value.as_bytes();
headers.push((name.into(), value.into()));
}
}
if !cookies.is_empty() {
headers.push(("cookie".into(), cookies.join(cookie_sep).into()));
}
headers
}
#[op]
async fn op_http_write_headers(
state: Rc<RefCell<OpState>>,
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rid: u32,
status: u16,
headers: Vec<(ByteString, ByteString)>,
data: Option<StringOrBuffer>,
) -> Result<(), AnyError> {
let stream = state
.borrow_mut()
.resource_table
.get::<HttpStreamResource>(rid)?;
// Track supported encoding
let encoding = stream.accept_encoding;
let mut builder = Response::builder();
// SAFETY: can not fail, since a fresh Builder is non-errored
let hmap = unsafe { builder.headers_mut().unwrap_unchecked() };
// Add headers
hmap.reserve(headers.len() + 2);
for (k, v) in headers.into_iter() {
let v: Vec<u8> = v.into();
hmap.append(
HeaderName::try_from(k.as_slice())?,
HeaderValue::try_from(v)?,
);
}
ensure_vary_accept_encoding(hmap);
let accepts_compression =
matches!(encoding, Encoding::Brotli | Encoding::Gzip);
let compressing = accepts_compression
&& (matches!(data, Some(ref data) if data.len() > 20) || data.is_none())
&& should_compress(hmap);
if compressing {
weaken_etag(hmap);
// Drop 'content-length' header. Hyper will update it using compressed body.
hmap.remove(hyper::header::CONTENT_LENGTH);
// Content-Encoding header
hmap.insert(
hyper::header::CONTENT_ENCODING,
HeaderValue::from_static(match encoding {
Encoding::Brotli => "br",
Encoding::Gzip => "gzip",
_ => unreachable!(), // Forbidden by accepts_compression
}),
);
}
let (new_wr, body) = http_response(data, compressing, encoding)?;
let body = builder.status(status).body(body)?;
let mut old_wr = RcRef::map(&stream, |r| &r.wr).borrow_mut().await;
let response_tx = match replace(&mut *old_wr, new_wr) {
HttpResponseWriter::Headers(response_tx) => response_tx,
_ => return Err(http_error("response headers already sent")),
};
match response_tx.send(body) {
Ok(_) => Ok(()),
Err(_) => {
stream.conn.closed().await?;
Err(http_error("connection closed while sending response"))
}
}
}
#[op]
fn op_http_headers(
state: &mut OpState,
rid: u32,
) -> Result<Vec<(ByteString, ByteString)>, AnyError> {
let stream = state.resource_table.get::<HttpStreamResource>(rid)?;
let rd = RcRef::map(&stream, |r| &r.rd)
.try_borrow()
.ok_or_else(|| http_error("already in use"))?;
match &*rd {
HttpRequestReader::Headers(request) => Ok(req_headers(request.headers())),
HttpRequestReader::Body(headers, _) => Ok(req_headers(headers)),
_ => unreachable!(),
}
}
fn http_response(
data: Option<StringOrBuffer>,
compressing: bool,
encoding: Encoding,
) -> Result<(HttpResponseWriter, hyper::Body), AnyError> {
match data {
Some(data) if compressing => match encoding {
Encoding::Brotli => {
// quality level 6 is based on google's nginx default value for
// on-the-fly compression
// https://github.com/google/ngx_brotli#brotli_comp_level
// lgwin 22 is equivalent to brotli window size of (2**22)-16 bytes
// (~4MB)
let mut writer = brotli::CompressorWriter::new(Vec::new(), 4096, 6, 22);
writer.write_all(&data)?;
Ok((HttpResponseWriter::Closed, writer.into_inner().into()))
}
Encoding::Gzip => {
// Gzip, after level 1, doesn't produce significant size difference.
// Probably the reason why nginx's default gzip compression level is
// 1.
// https://nginx.org/en/docs/http/ngx_http_gzip_module.html#gzip_comp_level
let mut writer = GzEncoder::new(Vec::new(), Compression::new(1));
writer.write_all(&data)?;
Ok((HttpResponseWriter::Closed, writer.finish()?.into()))
}
_ => unreachable!(), // forbidden by accepts_compression
},
Some(data) => {
// If a buffer was passed, but isn't compressible, we use it to
// construct a response body.
Ok((HttpResponseWriter::Closed, Bytes::from(data).into()))
}
None if compressing => {
// Create a one way pipe that implements tokio's async io traits. To do
// this we create a [tokio::io::DuplexStream], but then throw away one
// of the directions to create a one way pipe.
let (a, b) = tokio::io::duplex(64 * 1024);
let (reader, _) = tokio::io::split(a);
let (_, writer) = tokio::io::split(b);
let writer: Pin<Box<dyn tokio::io::AsyncWrite>> = match encoding {
Encoding::Brotli => Box::pin(BrotliEncoder::new(writer)),
Encoding::Gzip => Box::pin(GzipEncoder::new(writer)),
_ => unreachable!(), // forbidden by accepts_compression
};
let (stream, shutdown_handle) =
ExternallyAbortableReaderStream::new(reader);
Ok((
HttpResponseWriter::Body {
writer,
shutdown_handle,
},
Body::wrap_stream(stream),
))
}
None => {
let (body_tx, body_rx) = Body::channel();
Ok((
HttpResponseWriter::BodyUncompressed(body_tx.into()),
body_rx,
))
}
}
}
// If user provided a ETag header for uncompressed data, we need to
// ensure it is a Weak Etag header ("W/").
fn weaken_etag(hmap: &mut hyper::HeaderMap) {
if let Some(etag) = hmap.get_mut(hyper::header::ETAG) {
if !etag.as_bytes().starts_with(b"W/") {
let mut v = Vec::with_capacity(etag.as_bytes().len() + 2);
v.extend(b"W/");
v.extend(etag.as_bytes());
*etag = v.try_into().unwrap();
}
}
}
// Set Vary: Accept-Encoding header for direct body response.
// Note: we set the header irrespective of whether or not we compress the data
// to make sure cache services do not serve uncompressed data to clients that
// support compression.
fn ensure_vary_accept_encoding(hmap: &mut hyper::HeaderMap) {
if let Some(v) = hmap.get_mut(hyper::header::VARY) {
if let Ok(s) = v.to_str() {
if !s.to_lowercase().contains("accept-encoding") {
*v = format!("Accept-Encoding, {}", s).try_into().unwrap()
}
return;
}
}
hmap.insert(
hyper::header::VARY,
HeaderValue::from_static("Accept-Encoding"),
);
}
fn should_compress(headers: &hyper::HeaderMap) -> bool {
// skip compression if the cache-control header value is set to "no-transform" or not utf8
fn cache_control_no_transform(headers: &hyper::HeaderMap) -> Option<bool> {
let v = headers.get(hyper::header::CACHE_CONTROL)?;
let s = match std::str::from_utf8(v.as_bytes()) {
Ok(s) => s,
Err(_) => return Some(true),
};
let c = CacheControl::from_value(s)?;
Some(c.no_transform)
}
// we skip compression if the `content-range` header value is set, as it
// indicates the contents of the body were negotiated based directly
// with the user code and we can't compress the response
let content_range = headers.contains_key(hyper::header::CONTENT_RANGE);
// assume body is already compressed if Content-Encoding header present, thus avoid recompressing
let is_precompressed = headers.contains_key(hyper::header::CONTENT_ENCODING);
!content_range
&& !is_precompressed
&& !cache_control_no_transform(headers).unwrap_or_default()
&& headers
.get(hyper::header::CONTENT_TYPE)
.map(compressible::is_content_compressible)
.unwrap_or_default()
}
#[op]
async fn op_http_write_resource(
state: Rc<RefCell<OpState>>,
rid: ResourceId,
stream: ResourceId,
) -> Result<(), AnyError> {
let http_stream = state
.borrow()
.resource_table
.get::<HttpStreamResource>(rid)?;
let mut wr = RcRef::map(&http_stream, |r| &r.wr).borrow_mut().await;
let resource = state.borrow().resource_table.get_any(stream)?;
loop {
match *wr {
HttpResponseWriter::Headers(_) => {
return Err(http_error("no response headers"))
}
HttpResponseWriter::Closed => {
return Err(http_error("response already completed"))
}
_ => {}
};
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.
2022-10-09 10:49:25 -04:00
let view = resource.clone().read(64 * 1024).await?; // 64KB
if view.is_empty() {
break;
}
match &mut *wr {
HttpResponseWriter::Body { writer, .. } => {
let mut result = writer.write_all(&view).await;
if result.is_ok() {
result = writer.flush().await;
}
if let Err(err) = result {
assert_eq!(err.kind(), std::io::ErrorKind::BrokenPipe);
// Don't return "broken pipe", that's an implementation detail.
// Pull up the failure associated with the transport connection instead.
http_stream.conn.closed().await?;
// If there was no connection error, drop body_tx.
*wr = HttpResponseWriter::Closed;
}
}
HttpResponseWriter::BodyUncompressed(body) => {
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.
2022-10-09 10:49:25 -04:00
let bytes = Bytes::from(view);
if let Err(err) = body.sender().send_data(bytes).await {
assert!(err.is_closed());
// Pull up the failure associated with the transport connection instead.
http_stream.conn.closed().await?;
// If there was no connection error, drop body_tx.
*wr = HttpResponseWriter::Closed;
}
}
_ => unreachable!(),
};
}
Ok(())
}
#[op]
async fn op_http_write(
state: Rc<RefCell<OpState>>,
rid: ResourceId,
buf: ZeroCopyBuf,
) -> Result<(), AnyError> {
let stream = state
.borrow()
.resource_table
.get::<HttpStreamResource>(rid)?;
let mut wr = RcRef::map(&stream, |r| &r.wr).borrow_mut().await;
match &mut *wr {
HttpResponseWriter::Headers(_) => Err(http_error("no response headers")),
HttpResponseWriter::Closed => Err(http_error("response already completed")),
HttpResponseWriter::Body { writer, .. } => {
let mut result = writer.write_all(&buf).await;
if result.is_ok() {
result = writer.flush().await;
}
match result {
Ok(_) => Ok(()),
Err(err) => {
assert_eq!(err.kind(), std::io::ErrorKind::BrokenPipe);
// Don't return "broken pipe", that's an implementation detail.
// Pull up the failure associated with the transport connection instead.
stream.conn.closed().await?;
// If there was no connection error, drop body_tx.
*wr = HttpResponseWriter::Closed;
Err(http_error("response already completed"))
}
}
}
HttpResponseWriter::BodyUncompressed(body) => {
let bytes = Bytes::from(buf);
match body.sender().send_data(bytes).await {
Ok(_) => Ok(()),
Err(err) => {
assert!(err.is_closed());
// Pull up the failure associated with the transport connection instead.
stream.conn.closed().await?;
// If there was no connection error, drop body_tx.
*wr = HttpResponseWriter::Closed;
Err(http_error("response already completed"))
}
}
}
}
}
/// Gracefully closes the write half of the HTTP stream. Note that this does not
/// remove the HTTP stream resource from the resource table; it still has to be
/// closed with `Deno.core.close()`.
#[op]
async fn op_http_shutdown(
state: Rc<RefCell<OpState>>,
rid: ResourceId,
) -> Result<(), AnyError> {
let stream = state
.borrow()
.resource_table
.get::<HttpStreamResource>(rid)?;
let mut wr = RcRef::map(&stream, |r| &r.wr).borrow_mut().await;
let wr = take(&mut *wr);
match wr {
HttpResponseWriter::Body {
mut writer,
shutdown_handle,
} => {
shutdown_handle.shutdown();
match writer.shutdown().await {
Ok(_) => {}
Err(err) => {
assert_eq!(err.kind(), std::io::ErrorKind::BrokenPipe);
// Don't return "broken pipe", that's an implementation detail.
// Pull up the failure associated with the transport connection instead.
stream.conn.closed().await?;
}
}
}
HttpResponseWriter::BodyUncompressed(body) => {
body.shutdown();
}
_ => {}
};
Ok(())
}
#[op]
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fn op_http_websocket_accept_header(key: String) -> Result<String, AnyError> {
let digest = ring::digest::digest(
&ring::digest::SHA1_FOR_LEGACY_USE_ONLY,
format!("{}258EAFA5-E914-47DA-95CA-C5AB0DC85B11", key).as_bytes(),
);
Ok(base64::encode(digest))
}
struct UpgradedStream(hyper::upgrade::Upgraded);
impl tokio::io::AsyncRead for UpgradedStream {
fn poll_read(
self: Pin<&mut Self>,
cx: &mut Context,
buf: &mut tokio::io::ReadBuf,
) -> std::task::Poll<std::result::Result<(), std::io::Error>> {
Pin::new(&mut self.get_mut().0).poll_read(cx, buf)
}
}
impl tokio::io::AsyncWrite for UpgradedStream {
fn poll_write(
self: Pin<&mut Self>,
cx: &mut Context,
buf: &[u8],
) -> std::task::Poll<Result<usize, std::io::Error>> {
Pin::new(&mut self.get_mut().0).poll_write(cx, buf)
}
fn poll_flush(
self: Pin<&mut Self>,
cx: &mut Context,
) -> std::task::Poll<Result<(), std::io::Error>> {
Pin::new(&mut self.get_mut().0).poll_flush(cx)
}
fn poll_shutdown(
self: Pin<&mut Self>,
cx: &mut Context,
) -> std::task::Poll<Result<(), std::io::Error>> {
Pin::new(&mut self.get_mut().0).poll_shutdown(cx)
}
}
impl deno_websocket::Upgraded for UpgradedStream {}
#[op]
async fn op_http_upgrade_websocket(
state: Rc<RefCell<OpState>>,
rid: ResourceId,
) -> Result<ResourceId, AnyError> {
let stream = state
.borrow_mut()
.resource_table
.get::<HttpStreamResource>(rid)?;
let mut rd = RcRef::map(&stream, |r| &r.rd).borrow_mut().await;
let request = match &mut *rd {
HttpRequestReader::Headers(request) => request,
_ => {
return Err(http_error("cannot upgrade because request body was used"))
}
};
let transport = hyper::upgrade::on(request).await?;
let ws_rid =
ws_create_server_stream(&state, Box::pin(UpgradedStream(transport)))
.await?;
Ok(ws_rid)
}
// Needed so hyper can use non Send futures
#[derive(Clone)]
struct LocalExecutor;
impl<Fut> hyper::rt::Executor<Fut> for LocalExecutor
where
Fut: Future + 'static,
Fut::Output: 'static,
{
fn execute(&self, fut: Fut) {
spawn_local(fut);
}
}
fn http_error(message: &'static str) -> AnyError {
custom_error("Http", message)
}
/// Filters out the ever-surprising 'shutdown ENOTCONN' errors.
fn filter_enotconn(
result: Result<(), hyper::Error>,
) -> Result<(), hyper::Error> {
if result
.as_ref()
.err()
.and_then(|err| err.source())
.and_then(|err| err.downcast_ref::<io::Error>())
.filter(|err| err.kind() == io::ErrorKind::NotConnected)
.is_some()
{
Ok(())
} else {
result
}
}
/// Create a future that is forever pending.
fn never() -> Pending<Never> {
pending()
}