// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license. use async_compression::tokio::write::BrotliEncoder; use async_compression::tokio::write::GzipEncoder; use async_compression::Level; use base64::prelude::BASE64_STANDARD; use base64::Engine; 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::ready; use deno_core::futures::stream::Peekable; use deno_core::futures::FutureExt; use deno_core::futures::StreamExt; use deno_core::futures::TryFutureExt; use deno_core::op2; use deno_core::unsync::spawn; use deno_core::AsyncRefCell; use deno_core::AsyncResult; use deno_core::BufView; use deno_core::ByteString; use deno_core::CancelFuture; use deno_core::CancelHandle; use deno_core::CancelTryFuture; use deno_core::JsBuffer; use deno_core::OpState; use deno_core::RcRef; use deno_core::Resource; use deno_core::ResourceId; use deno_core::StringOrBuffer; use deno_net::raw::NetworkStream; use deno_websocket::ws_create_server_stream; use flate2::write::GzEncoder; use flate2::Compression; use hyper_util::rt::TokioIo; use hyper_v014::body::Bytes; use hyper_v014::body::HttpBody; use hyper_v014::body::SizeHint; use hyper_v014::header::HeaderName; use hyper_v014::header::HeaderValue; use hyper_v014::server::conn::Http; use hyper_v014::service::Service; use hyper_v014::Body; use hyper_v014::HeaderMap; use hyper_v014::Request; use hyper_v014::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::pin::Pin; use std::rc::Rc; use std::sync::Arc; use std::task::Context; use std::task::Poll; use tokio::io::AsyncRead; use tokio::io::AsyncWrite; use tokio::io::AsyncWriteExt; use crate::network_buffered_stream::NetworkBufferedStream; use crate::reader_stream::ExternallyAbortableReaderStream; use crate::reader_stream::ShutdownHandle; pub mod compressible; mod fly_accept_encoding; mod http_next; mod network_buffered_stream; mod reader_stream; mod request_body; mod request_properties; mod response_body; mod service; mod websocket_upgrade; use fly_accept_encoding::Encoding; pub use request_properties::DefaultHttpPropertyExtractor; pub use request_properties::HttpConnectionProperties; pub use request_properties::HttpListenProperties; pub use request_properties::HttpPropertyExtractor; pub use request_properties::HttpRequestProperties; deno_core::extension!( deno_http, deps = [deno_web, deno_net, deno_fetch, deno_websocket], parameters = [ HTTP: HttpPropertyExtractor ], ops = [ op_http_accept, op_http_headers, op_http_shutdown, op_http_upgrade_websocket, op_http_websocket_accept_header, op_http_write_headers, op_http_write_resource, op_http_write, http_next::op_http_close_after_finish, http_next::op_http_get_request_header, http_next::op_http_get_request_headers, http_next::op_http_get_request_method_and_url, http_next::op_http_read_request_body, http_next::op_http_serve_on, http_next::op_http_serve, http_next::op_http_set_promise_complete, http_next::op_http_set_response_body_bytes, http_next::op_http_set_response_body_resource, http_next::op_http_set_response_body_text, http_next::op_http_set_response_header, http_next::op_http_set_response_headers, http_next::op_http_set_response_trailers, http_next::op_http_upgrade_websocket_next, http_next::op_http_upgrade_raw, http_next::op_raw_write_vectored, http_next::op_can_write_vectored, http_next::op_http_try_wait, http_next::op_http_wait, http_next::op_http_close, http_next::op_http_cancel, ], esm = ["00_serve.js", "01_http.js"], ); pub enum HttpSocketAddr { IpSocket(std::net::SocketAddr), #[cfg(unix)] UnixSocket(tokio::net::unix::SocketAddr), } impl From for HttpSocketAddr { fn from(addr: std::net::SocketAddr) -> Self { Self::IpSocket(addr) } } #[cfg(unix)] impl From for HttpSocketAddr { fn from(addr: tokio::net::unix::SocketAddr) -> Self { Self::UnixSocket(addr) } } struct HttpConnResource { addr: HttpSocketAddr, scheme: &'static str, acceptors_tx: mpsc::UnboundedSender, closed_fut: Shared>>>, cancel_handle: Rc, // Closes gracefully and cancels accept ops. } impl HttpConnResource { fn new(io: S, scheme: &'static str, addr: HttpSocketAddr) -> Self where S: AsyncRead + AsyncWrite + Unpin + Send + 'static, { let (acceptors_tx, acceptors_rx) = mpsc::unbounded::(); 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 { let conn_fut = pin!(conn_fut); let shutdown_fut = pin!(shutdown_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(task_fut); Self { addr, scheme, acceptors_tx, closed_fut, cancel_handle, } } // Accepts a new incoming HTTP request. async fn accept( self: &Rc, ) -> Result, 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_http_02(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 { "httpConn".into() } fn close(self: Rc) { self.cancel_handle.cancel(); } } /// Creates a new HttpConn resource which uses `io` as its transport. pub fn http_create_conn_resource( state: &mut OpState, io: S, addr: A, scheme: &'static str, ) -> Result where S: AsyncRead + AsyncWrite + Unpin + Send + 'static, A: Into, { 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>, } impl HttpService { fn new(acceptors_rx: mpsc::UnboundedReceiver) -> Self { let acceptors_rx = acceptors_rx.peekable(); Self { acceptors_rx } } } impl Service> for HttpService { type Response = Response; type Error = oneshot::Canceled; type Future = oneshot::Receiver>; fn poll_ready( &mut self, cx: &mut Context<'_>, ) -> Poll> { 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) -> 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>, response_rx: oneshot::Receiver>, } impl HttpAcceptor { fn new( request_tx: oneshot::Sender>, response_rx: oneshot::Receiver>, ) -> Self { Self { request_tx, response_rx, } } fn call(self, request: Request) -> oneshot::Receiver> { 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, pub rd: AsyncRefCell, wr: AsyncRefCell, accept_encoding: Encoding, cancel_handle: CancelHandle, size: SizeHint, } impl HttpStreamResource { fn new( conn: &Rc, request: Request, response_tx: oneshot::Sender>, 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(), } } } impl Resource for HttpStreamResource { fn name(&self) -> Cow { "httpStream".into() } fn read(self: Rc, limit: usize) -> AsyncResult { 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()), } match take(&mut *rd) { HttpRequestReader::Headers(request) => { let (parts, body) = request.into_parts(); *rd = HttpRequestReader::Body(parts.headers, body.peekable()); } _ => unreachable!(), }; }; 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()), } } }; let cancel_handle = RcRef::map(&self, |r| &r.cancel_handle); fut.try_or_cancel(cancel_handle).await }) } fn close(self: Rc) { self.cancel_handle.cancel(); } fn size_hint(&self) -> (u64, Option) { (self.size.lower(), self.size.upper()) } } /// The read half of an HTTP stream. pub enum HttpRequestReader { Headers(Request), Body(HeaderMap, Peekable), Closed, } impl Default for HttpRequestReader { fn default() -> Self { Self::Closed } } /// The write half of an HTTP stream. enum HttpResponseWriter { Headers(oneshot::Sender>), Body { writer: Pin>, shutdown_handle: ShutdownHandle, }, BodyUncompressed(BodyUncompressedSender), Closed, } impl Default for HttpResponseWriter { fn default() -> Self { Self::Closed } } struct BodyUncompressedSender(Option); impl BodyUncompressedSender { fn sender(&mut self) -> &mut hyper_v014::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 for BodyUncompressedSender { fn from(sender: hyper_v014::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, ); #[op2(async)] #[serde] async fn op_http_accept( state: Rc>, #[smi] rid: ResourceId, ) -> Result, AnyError> { let conn = state.borrow().resource_table.get::(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_v014::Request, scheme: &'static str, addr: &HttpSocketAddr, ) -> String { let host: Cow = 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::(), ), } } 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( 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(|p| p.as_str()) .unwrap_or("/"); [scheme, "://", &host, path].concat() } fn req_headers( header_map: &HeaderMap, ) -> 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_v014::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 } #[op2(async)] async fn op_http_write_headers( state: Rc>, #[smi] rid: u32, #[smi] status: u16, #[serde] headers: Vec<(ByteString, ByteString)>, #[serde] data: Option, ) -> Result<(), AnyError> { let stream = state .borrow_mut() .resource_table .get::(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 = 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_v014::header::CONTENT_LENGTH); // Content-Encoding header hmap.insert( hyper_v014::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")) } } } #[op2] #[serde] fn op_http_headers( state: &mut OpState, #[smi] rid: u32, ) -> Result, AnyError> { let stream = state.resource_table.get::(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, compressing: bool, encoding: Encoding, ) -> Result<(HttpResponseWriter, hyper_v014::Body), AnyError> { // Gzip, after level 1, doesn't produce significant size difference. // This default matches nginx default gzip compression level (1): // https://nginx.org/en/docs/http/ngx_http_gzip_module.html#gzip_comp_level const GZIP_DEFAULT_COMPRESSION_LEVEL: u8 = 1; 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 => { let mut writer = GzEncoder::new( Vec::new(), Compression::new(GZIP_DEFAULT_COMPRESSION_LEVEL.into()), ); 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, data.to_vec().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> = match encoding { Encoding::Brotli => { Box::pin(BrotliEncoder::with_quality(writer, Level::Fastest)) } Encoding::Gzip => Box::pin(GzipEncoder::with_quality( writer, Level::Precise(GZIP_DEFAULT_COMPRESSION_LEVEL.into()), )), _ => 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_v014::HeaderMap) { if let Some(etag) = hmap.get_mut(hyper_v014::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_v014::HeaderMap) { if let Some(v) = hmap.get_mut(hyper_v014::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_v014::header::VARY, HeaderValue::from_static("Accept-Encoding"), ); } fn should_compress(headers: &hyper_v014::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_v014::HeaderMap, ) -> Option { let v = headers.get(hyper_v014::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_v014::header::CONTENT_RANGE); // assume body is already compressed if Content-Encoding header present, thus avoid recompressing let is_precompressed = headers.contains_key(hyper_v014::header::CONTENT_ENCODING); !content_range && !is_precompressed && !cache_control_no_transform(headers).unwrap_or_default() && headers .get(hyper_v014::header::CONTENT_TYPE) .map(compressible::is_content_compressible) .unwrap_or_default() } #[op2(async)] async fn op_http_write_resource( state: Rc>, #[smi] rid: ResourceId, #[smi] stream: ResourceId, ) -> Result<(), AnyError> { let http_stream = state .borrow() .resource_table .get::(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")) } _ => {} }; 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) => { let bytes = view.to_vec().into(); 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(()) } #[op2(async)] async fn op_http_write( state: Rc>, #[smi] rid: ResourceId, #[buffer] buf: JsBuffer, ) -> Result<(), AnyError> { let stream = state .borrow() .resource_table .get::(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.to_vec()); 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()`. #[op2(async)] async fn op_http_shutdown( state: Rc>, #[smi] rid: ResourceId, ) -> Result<(), AnyError> { let stream = state .borrow() .resource_table .get::(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(()) } #[op2] #[string] fn op_http_websocket_accept_header( #[string] key: String, ) -> Result { let digest = ring::digest::digest( &ring::digest::SHA1_FOR_LEGACY_USE_ONLY, format!("{key}258EAFA5-E914-47DA-95CA-C5AB0DC85B11").as_bytes(), ); Ok(BASE64_STANDARD.encode(digest)) } #[op2(async)] #[smi] async fn op_http_upgrade_websocket( state: Rc>, #[smi] rid: ResourceId, ) -> Result { let stream = state .borrow_mut() .resource_table .get::(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, bytes) = extract_network_stream(hyper_v014::upgrade::on(request).await?); let ws_rid = ws_create_server_stream(&mut state.borrow_mut(), transport, bytes)?; Ok(ws_rid) } // Needed so hyper can use non Send futures #[derive(Clone)] struct LocalExecutor; impl hyper_v014::rt::Executor for LocalExecutor where Fut: Future + 'static, Fut::Output: 'static, { fn execute(&self, fut: Fut) { deno_core::unsync::spawn(fut); } } impl hyper::rt::Executor for LocalExecutor where Fut: Future + 'static, Fut::Output: 'static, { fn execute(&self, fut: Fut) { deno_core::unsync::spawn(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_v014::Error>, ) -> Result<(), hyper_v014::Error> { if result .as_ref() .err() .and_then(|err| err.source()) .and_then(|err| err.downcast_ref::()) .filter(|err| err.kind() == io::ErrorKind::NotConnected) .is_some() { Ok(()) } else { result } } /// Create a future that is forever pending. fn never() -> Pending { pending() } trait CanDowncastUpgrade: Sized { fn downcast( self, ) -> Result<(T, Bytes), Self>; } impl CanDowncastUpgrade for hyper::upgrade::Upgraded { fn downcast( self, ) -> Result<(T, Bytes), Self> { let hyper::upgrade::Parts { io, read_buf, .. } = self.downcast::>()?; Ok((io.into_inner(), read_buf)) } } impl CanDowncastUpgrade for hyper_v014::upgrade::Upgraded { fn downcast( self, ) -> Result<(T, Bytes), Self> { let hyper_v014::upgrade::Parts { io, read_buf, .. } = self.downcast()?; Ok((io, read_buf)) } } fn maybe_extract_network_stream< T: Into + AsyncRead + AsyncWrite + Unpin + 'static, U: CanDowncastUpgrade, >( upgraded: U, ) -> Result<(NetworkStream, Bytes), U> { let upgraded = match upgraded.downcast::() { Ok((stream, bytes)) => return Ok((stream.into(), bytes)), Err(x) => x, }; match upgraded.downcast::>() { Ok((stream, upgraded_bytes)) => { // Both the upgrade and the stream might have unread bytes let (io, stream_bytes) = stream.into_inner(); let bytes = match (stream_bytes.is_empty(), upgraded_bytes.is_empty()) { (false, false) => Bytes::default(), (true, false) => upgraded_bytes, (false, true) => stream_bytes, (true, true) => { // The upgraded bytes come first as they have already been read let mut v = upgraded_bytes.to_vec(); v.append(&mut stream_bytes.to_vec()); Bytes::from(v) } }; Ok((io.into(), bytes)) } Err(x) => Err(x), } } fn extract_network_stream( upgraded: U, ) -> (NetworkStream, Bytes) { let upgraded = match maybe_extract_network_stream::(upgraded) { Ok(res) => return res, Err(x) => x, }; let upgraded = match maybe_extract_network_stream::( upgraded, ) { Ok(res) => return res, Err(x) => x, }; #[cfg(unix)] let upgraded = match maybe_extract_network_stream::(upgraded) { Ok(res) => return res, Err(x) => x, }; let upgraded = match maybe_extract_network_stream::(upgraded) { Ok(res) => return res, Err(x) => x, }; // TODO(mmastrac): HTTP/2 websockets may yield an un-downgradable type drop(upgraded); unreachable!("unexpected stream type"); }