// Copyright 2018-2023 the Deno authors. All rights reserved. MIT license. // False positive lint for explicit drops. // https://github.com/rust-lang/rust-clippy/issues/6446 #![allow(clippy::await_holding_lock)] // https://github.com/rust-lang/rust-clippy/issues/6353 #![allow(clippy::await_holding_refcell_ref)] use deno_core::error::generic_error; use deno_core::error::type_error; use deno_core::error::AnyError; use deno_core::op; use deno_core::serde_v8; use deno_core::v8; use deno_core::v8::fast_api; use deno_core::ByteString; use deno_core::CancelFuture; use deno_core::CancelHandle; use deno_core::Extension; use deno_core::OpState; use deno_core::StringOrBuffer; use deno_core::ZeroCopyBuf; use deno_core::V8_WRAPPER_OBJECT_INDEX; use deno_tls::load_certs; use deno_tls::load_private_keys; use http::header::HeaderName; use http::header::CONNECTION; use http::header::CONTENT_LENGTH; use http::header::EXPECT; use http::header::TRANSFER_ENCODING; use http::HeaderValue; use log::trace; use mio::net::TcpListener; use mio::Events; use mio::Interest; use mio::Poll; use mio::Token; use serde::Deserialize; use serde::Serialize; use socket2::Socket; use std::cell::RefCell; use std::cell::UnsafeCell; use std::collections::HashMap; use std::ffi::c_void; use std::future::Future; use std::intrinsics::transmute; use std::io::BufReader; use std::io::Read; use std::io::Write; use std::mem::replace; use std::net::SocketAddr; use std::net::ToSocketAddrs; use std::pin::Pin; use std::rc::Rc; use std::sync::Arc; use std::sync::Mutex; use std::task::Context; use std::time::Duration; use tokio::sync::mpsc; use tokio::task::JoinHandle; mod chunked; mod request; #[cfg(unix)] mod sendfile; mod socket; use request::InnerRequest; use request::Request; use socket::InnerStream; use socket::Stream; pub struct FlashContext { next_server_id: u32, join_handles: HashMap>>, pub servers: HashMap, } pub struct ServerContext { _addr: SocketAddr, tx: mpsc::Sender, rx: mpsc::Receiver, requests: HashMap, next_token: u32, listening_rx: Option>, close_tx: mpsc::Sender<()>, cancel_handle: Rc, } #[derive(Debug, Eq, PartialEq)] pub enum ParseStatus { None, Ongoing(usize), } #[op] fn op_flash_respond( op_state: &mut OpState, server_id: u32, token: u32, response: StringOrBuffer, shutdown: bool, ) -> u32 { let flash_ctx = op_state.borrow_mut::(); let ctx = flash_ctx.servers.get_mut(&server_id).unwrap(); flash_respond(ctx, token, shutdown, &response) } #[op(fast)] fn op_try_flash_respond_chuncked( op_state: &mut OpState, server_id: u32, token: u32, response: &[u8], shutdown: bool, ) -> u32 { let flash_ctx = op_state.borrow_mut::(); let ctx = flash_ctx.servers.get_mut(&server_id).unwrap(); let tx = ctx.requests.get(&token).unwrap(); let sock = tx.socket(); // TODO(@littledivy): Use writev when `UnixIoSlice` lands. // https://github.com/denoland/deno/pull/15629 let h = format!("{:x}\r\n", response.len()); let concat = [h.as_bytes(), response, b"\r\n"].concat(); let expected = sock.try_write(&concat); if expected != concat.len() { if expected > 2 { return expected as u32; } return expected as u32; } if shutdown { // Best case: We've written everything and the stream is done too. let _ = ctx.requests.remove(&token).unwrap(); } 0 } #[op] async fn op_flash_respond_async( state: Rc>, server_id: u32, token: u32, response: StringOrBuffer, shutdown: bool, ) -> Result<(), AnyError> { trace!("op_flash_respond_async"); let mut close = false; let sock = { let mut op_state = state.borrow_mut(); let flash_ctx = op_state.borrow_mut::(); let ctx = flash_ctx.servers.get_mut(&server_id).unwrap(); match shutdown { true => { let tx = ctx.requests.remove(&token).unwrap(); close = !tx.keep_alive; tx.socket() } // In case of a websocket upgrade or streaming response. false => { let tx = ctx.requests.get(&token).unwrap(); tx.socket() } } }; sock .with_async_stream(|stream| { Box::pin(async move { Ok(tokio::io::AsyncWriteExt::write(stream, &response).await?) }) }) .await?; // server is done writing and request doesn't want to kept alive. if shutdown && close { sock.shutdown(); } Ok(()) } #[op] async fn op_flash_respond_chuncked( op_state: Rc>, server_id: u32, token: u32, response: Option, shutdown: bool, nwritten: u32, ) -> Result<(), AnyError> { let mut op_state = op_state.borrow_mut(); let flash_ctx = op_state.borrow_mut::(); let ctx = flash_ctx.servers.get_mut(&server_id).unwrap(); let sock = match shutdown { true => { let tx = ctx.requests.remove(&token).unwrap(); tx.socket() } // In case of a websocket upgrade or streaming response. false => { let tx = ctx.requests.get(&token).unwrap(); tx.socket() } }; drop(op_state); sock .with_async_stream(|stream| { Box::pin(async move { use tokio::io::AsyncWriteExt; // TODO(@littledivy): Use writev when `UnixIoSlice` lands. // https://github.com/denoland/deno/pull/15629 macro_rules! write_whats_not_written { ($e:expr) => { let e = $e; let n = nwritten as usize; if n < e.len() { stream.write_all(&e[n..]).await?; } }; } if let Some(response) = response { let h = format!("{:x}\r\n", response.len()); write_whats_not_written!(h.as_bytes()); write_whats_not_written!(&response); write_whats_not_written!(b"\r\n"); } // The last chunk if shutdown { write_whats_not_written!(b"0\r\n\r\n"); } Ok(()) }) }) .await?; Ok(()) } #[op] async fn op_flash_write_resource( op_state: Rc>, response: StringOrBuffer, server_id: u32, token: u32, resource_id: deno_core::ResourceId, auto_close: bool, ) -> Result<(), AnyError> { let (resource, sock) = { let op_state = &mut op_state.borrow_mut(); let resource = if auto_close { op_state.resource_table.take_any(resource_id)? } else { op_state.resource_table.get_any(resource_id)? }; let flash_ctx = op_state.borrow_mut::(); let ctx = flash_ctx.servers.get_mut(&server_id).unwrap(); (resource, ctx.requests.remove(&token).unwrap().socket()) }; let _ = sock.write(&response); #[cfg(unix)] { use std::os::unix::io::AsRawFd; if let InnerStream::Tcp(stream_handle) = &sock.inner { let stream_handle = stream_handle.as_raw_fd(); if let Some(fd) = resource.clone().backing_fd() { // SAFETY: all-zero byte-pattern is a valid value for libc::stat. let mut stat: libc::stat = unsafe { std::mem::zeroed() }; // SAFETY: call to libc::fstat. if unsafe { libc::fstat(fd, &mut stat) } >= 0 { let _ = sock.write( format!("Content-Length: {}\r\n\r\n", stat.st_size).as_bytes(), ); let tx = sendfile::SendFile { io: (fd, stream_handle), written: 0, }; tx.await?; return Ok(()); } } } } sock .with_async_stream(|stream| { Box::pin(async move { use tokio::io::AsyncWriteExt; stream .write_all(b"Transfer-Encoding: chunked\r\n\r\n") .await?; loop { let view = resource.clone().read(64 * 1024).await?; // 64KB if view.is_empty() { stream.write_all(b"0\r\n\r\n").await?; break; } // TODO(@littledivy): use vectored writes. stream .write_all(format!("{:x}\r\n", view.len()).as_bytes()) .await?; stream.write_all(&view).await?; stream.write_all(b"\r\n").await?; } resource.close(); Ok(()) }) }) .await?; Ok(()) } pub struct RespondFast; impl fast_api::FastFunction for RespondFast { fn function(&self) -> *const c_void { op_flash_respond_fast as *const c_void } fn args(&self) -> &'static [fast_api::Type] { &[ fast_api::Type::V8Value, fast_api::Type::Uint32, fast_api::Type::TypedArray(fast_api::CType::Uint8), fast_api::Type::Bool, ] } fn return_type(&self) -> fast_api::CType { fast_api::CType::Uint32 } } fn flash_respond( ctx: &mut ServerContext, token: u32, shutdown: bool, response: &[u8], ) -> u32 { let tx = ctx.requests.get(&token).unwrap(); let sock = tx.socket(); sock.read_tx.take(); sock.read_rx.take(); let nwritten = sock.try_write(response); if shutdown && nwritten == response.len() { if !tx.keep_alive { sock.shutdown(); } ctx.requests.remove(&token).unwrap(); } nwritten as u32 } unsafe fn op_flash_respond_fast( recv: v8::Local, token: u32, response: *const fast_api::FastApiTypedArray, shutdown: bool, ) -> u32 { let ptr = recv.get_aligned_pointer_from_internal_field(V8_WRAPPER_OBJECT_INDEX); let ctx = &mut *(ptr as *mut ServerContext); let response = &*response; if let Some(response) = response.get_storage_if_aligned() { flash_respond(ctx, token, shutdown, response) } else { todo!(); } } macro_rules! get_request { ($op_state: ident, $token: ident) => { get_request!($op_state, 0, $token) }; ($op_state: ident, $server_id: expr, $token: ident) => {{ let flash_ctx = $op_state.borrow_mut::(); let ctx = flash_ctx.servers.get_mut(&$server_id).unwrap(); ctx.requests.get_mut(&$token).unwrap() }}; } #[repr(u32)] pub enum Method { GET = 0, HEAD, CONNECT, PUT, DELETE, OPTIONS, TRACE, POST, PATCH, } #[inline] fn get_method(req: &mut Request) -> u32 { let method = match req.method() { "GET" => Method::GET, "POST" => Method::POST, "PUT" => Method::PUT, "DELETE" => Method::DELETE, "OPTIONS" => Method::OPTIONS, "HEAD" => Method::HEAD, "PATCH" => Method::PATCH, "TRACE" => Method::TRACE, "CONNECT" => Method::CONNECT, _ => Method::GET, }; method as u32 } #[op] fn op_flash_method(state: &mut OpState, server_id: u32, token: u32) -> u32 { let req = get_request!(state, server_id, token); get_method(req) } #[op] async fn op_flash_close_server(state: Rc>, server_id: u32) { let close_tx = { let mut op_state = state.borrow_mut(); let flash_ctx = op_state.borrow_mut::(); let ctx = flash_ctx.servers.get_mut(&server_id).unwrap(); ctx.cancel_handle.cancel(); ctx.close_tx.clone() }; let _ = close_tx.send(()).await; } #[op] fn op_flash_path( state: Rc>, server_id: u32, token: u32, ) -> String { let mut op_state = state.borrow_mut(); let flash_ctx = op_state.borrow_mut::(); let ctx = flash_ctx.servers.get_mut(&server_id).unwrap(); ctx .requests .get(&token) .unwrap() .inner .req .path .unwrap() .to_string() } #[inline] fn next_request_sync(ctx: &mut ServerContext) -> u32 { let offset = ctx.next_token; while let Ok(token) = ctx.rx.try_recv() { ctx.requests.insert(ctx.next_token, token); ctx.next_token += 1; } ctx.next_token - offset } pub struct NextRequestFast; impl fast_api::FastFunction for NextRequestFast { fn function(&self) -> *const c_void { op_flash_next_fast as *const c_void } fn args(&self) -> &'static [fast_api::Type] { &[fast_api::Type::V8Value] } fn return_type(&self) -> fast_api::CType { fast_api::CType::Uint32 } } unsafe fn op_flash_next_fast(recv: v8::Local) -> u32 { let ptr = recv.get_aligned_pointer_from_internal_field(V8_WRAPPER_OBJECT_INDEX); let ctx = &mut *(ptr as *mut ServerContext); next_request_sync(ctx) } pub struct GetMethodFast; impl fast_api::FastFunction for GetMethodFast { fn function(&self) -> *const c_void { op_flash_get_method_fast as *const c_void } fn args(&self) -> &'static [fast_api::Type] { &[fast_api::Type::V8Value, fast_api::Type::Uint32] } fn return_type(&self) -> fast_api::CType { fast_api::CType::Uint32 } } unsafe fn op_flash_get_method_fast( recv: v8::Local, token: u32, ) -> u32 { let ptr = recv.get_aligned_pointer_from_internal_field(V8_WRAPPER_OBJECT_INDEX); let ctx = &mut *(ptr as *mut ServerContext); let req = ctx.requests.get_mut(&token).unwrap(); get_method(req) } // Fast calls #[op(v8)] fn op_flash_make_request<'scope>( scope: &mut v8::HandleScope<'scope>, state: &mut OpState, ) -> serde_v8::Value<'scope> { let object_template = v8::ObjectTemplate::new(scope); assert!(object_template .set_internal_field_count((V8_WRAPPER_OBJECT_INDEX + 1) as usize)); let obj = object_template.new_instance(scope).unwrap(); let ctx = { let flash_ctx = state.borrow_mut::(); let ctx = flash_ctx.servers.get_mut(&0).unwrap(); ctx as *mut ServerContext }; obj.set_aligned_pointer_in_internal_field(V8_WRAPPER_OBJECT_INDEX, ctx as _); // nextRequest { let builder = v8::FunctionTemplate::builder( |_: &mut v8::HandleScope, args: v8::FunctionCallbackArguments, mut rv: v8::ReturnValue| { let external: v8::Local = args.data().try_into().unwrap(); // SAFETY: This external is guaranteed to be a pointer to a ServerContext let ctx = unsafe { &mut *(external.value() as *mut ServerContext) }; rv.set_uint32(next_request_sync(ctx)); }, ) .data(v8::External::new(scope, ctx as *mut _).into()); let func = builder.build_fast(scope, &NextRequestFast, None); let func: v8::Local = func.get_function(scope).unwrap().into(); let key = v8::String::new(scope, "nextRequest").unwrap(); obj.set(scope, key.into(), func).unwrap(); } // getMethod { let builder = v8::FunctionTemplate::builder( |scope: &mut v8::HandleScope, args: v8::FunctionCallbackArguments, mut rv: v8::ReturnValue| { let external: v8::Local = args.data().try_into().unwrap(); // SAFETY: This external is guaranteed to be a pointer to a ServerContext let ctx = unsafe { &mut *(external.value() as *mut ServerContext) }; let token = args.get(0).uint32_value(scope).unwrap(); let req = ctx.requests.get_mut(&token).unwrap(); rv.set_uint32(get_method(req)); }, ) .data(v8::External::new(scope, ctx as *mut _).into()); let func = builder.build_fast(scope, &GetMethodFast, None); let func: v8::Local = func.get_function(scope).unwrap().into(); let key = v8::String::new(scope, "getMethod").unwrap(); obj.set(scope, key.into(), func).unwrap(); } // respond { let builder = v8::FunctionTemplate::builder( |scope: &mut v8::HandleScope, args: v8::FunctionCallbackArguments, mut rv: v8::ReturnValue| { let external: v8::Local = args.data().try_into().unwrap(); // SAFETY: This external is guaranteed to be a pointer to a ServerContext let ctx = unsafe { &mut *(external.value() as *mut ServerContext) }; let token = args.get(0).uint32_value(scope).unwrap(); let response: v8::Local = args.get(1).try_into().unwrap(); let ab = response.buffer(scope).unwrap(); let store = ab.get_backing_store(); let (offset, len) = (response.byte_offset(), response.byte_length()); // SAFETY: v8::SharedRef is similar to Arc<[u8]>, // it points to a fixed continuous slice of bytes on the heap. // We assume it's initialized and thus safe to read (though may not contain meaningful data) let response = unsafe { &*(&store[offset..offset + len] as *const _ as *const [u8]) }; let shutdown = args.get(2).boolean_value(scope); rv.set_uint32(flash_respond(ctx, token, shutdown, response)); }, ) .data(v8::External::new(scope, ctx as *mut _).into()); let func = builder.build_fast(scope, &RespondFast, None); let func: v8::Local = func.get_function(scope).unwrap().into(); let key = v8::String::new(scope, "respond").unwrap(); obj.set(scope, key.into(), func).unwrap(); } let value: v8::Local = obj.into(); value.into() } #[inline] fn has_body_stream(req: &Request) -> bool { let sock = req.socket(); sock.read_rx.is_some() } #[op] fn op_flash_has_body_stream( op_state: &mut OpState, server_id: u32, token: u32, ) -> bool { let req = get_request!(op_state, server_id, token); has_body_stream(req) } #[op] fn op_flash_headers( state: Rc>, server_id: u32, token: u32, ) -> Result, AnyError> { let mut op_state = state.borrow_mut(); let flash_ctx = op_state.borrow_mut::(); let ctx = flash_ctx .servers .get_mut(&server_id) .ok_or_else(|| type_error("server closed"))?; let inner_req = &ctx .requests .get(&token) .ok_or_else(|| type_error("request closed"))? .inner .req; Ok( inner_req .headers .iter() .map(|h| (h.name.as_bytes().into(), h.value.into())) .collect(), ) } // Remember the first packet we read? It probably also has some body data. This op quickly copies it into // a buffer and sets up channels for streaming the rest. #[op] fn op_flash_first_packet( op_state: &mut OpState, server_id: u32, token: u32, ) -> Result, AnyError> { let tx = get_request!(op_state, server_id, token); let sock = tx.socket(); if !tx.te_chunked && tx.content_length.is_none() { return Ok(None); } if tx.expect_continue { let _ = sock.write(b"HTTP/1.1 100 Continue\r\n\r\n"); tx.expect_continue = false; } let buffer = &tx.inner.buffer[tx.inner.body_offset..tx.inner.body_len]; // Oh there is nothing here. if buffer.is_empty() { return Ok(Some(ZeroCopyBuf::empty())); } if tx.te_chunked { let mut buf = vec![0; 1024]; let mut offset = 0; let mut decoder = chunked::Decoder::new( std::io::Cursor::new(buffer), tx.remaining_chunk_size, ); loop { match decoder.read(&mut buf[offset..]) { Ok(n) => { tx.remaining_chunk_size = decoder.remaining_chunks_size; offset += n; if n == 0 { tx.te_chunked = false; buf.truncate(offset); return Ok(Some(buf.into())); } if offset < buf.len() && decoder.source.position() < buffer.len() as u64 { continue; } buf.truncate(offset); return Ok(Some(buf.into())); } Err(e) => { return Err(type_error(format!("{}", e))); } } } } tx.content_length .ok_or_else(|| type_error("no content-length"))?; tx.content_read += buffer.len(); Ok(Some(buffer.to_vec().into())) } #[op] async fn op_flash_read_body( state: Rc>, server_id: u32, token: u32, mut buf: ZeroCopyBuf, ) -> usize { // SAFETY: we cannot hold op_state borrow across the await point. The JS caller // is responsible for ensuring this is not called concurrently. let ctx = unsafe { { let op_state = &mut state.borrow_mut(); let flash_ctx = op_state.borrow_mut::(); flash_ctx.servers.get_mut(&server_id).unwrap() as *mut ServerContext } .as_mut() .unwrap() }; let tx = ctx.requests.get_mut(&token).unwrap(); if tx.te_chunked { let mut decoder = chunked::Decoder::new(tx.socket(), tx.remaining_chunk_size); loop { let sock = tx.socket(); let _lock = sock.read_lock.lock().unwrap(); match decoder.read(&mut buf) { Ok(n) => { tx.remaining_chunk_size = decoder.remaining_chunks_size; return n; } Err(e) if e.kind() == std::io::ErrorKind::InvalidInput => { panic!("chunked read error: {}", e); } Err(_) => { drop(_lock); sock.read_rx.as_mut().unwrap().recv().await.unwrap(); } } } } if let Some(content_length) = tx.content_length { let sock = tx.socket(); let l = sock.read_lock.clone(); loop { let _lock = l.lock().unwrap(); if tx.content_read >= content_length as usize { return 0; } match sock.read(&mut buf) { Ok(n) => { tx.content_read += n; return n; } _ => { drop(_lock); sock.read_rx.as_mut().unwrap().recv().await.unwrap(); } } } } 0 } // https://github.com/hyperium/hyper/blob/0c8ee93d7f557afc63ca2a5686d19071813ab2b7/src/headers.rs#L67 #[inline] fn from_digits(bytes: &[u8]) -> Option { // cannot use FromStr for u64, since it allows a signed prefix let mut result = 0u64; const RADIX: u64 = 10; if bytes.is_empty() { return None; } for &b in bytes { // can't use char::to_digit, since we haven't verified these bytes // are utf-8. match b { b'0'..=b'9' => { result = result.checked_mul(RADIX)?; result = result.checked_add((b - b'0') as u64)?; } _ => { return None; } } } Some(result) } #[inline] fn connection_has(value: &HeaderValue, needle: &str) -> bool { if let Ok(s) = value.to_str() { for val in s.split(',') { if val.trim().eq_ignore_ascii_case(needle) { return true; } } } false } #[derive(Serialize, Deserialize)] #[serde(rename_all = "camelCase")] pub struct ListenOpts { cert: Option, key: Option, hostname: String, port: u16, reuseport: bool, } fn run_server( tx: mpsc::Sender, listening_tx: mpsc::Sender, mut close_rx: mpsc::Receiver<()>, addr: SocketAddr, maybe_cert: Option, maybe_key: Option, reuseport: bool, ) -> Result<(), AnyError> { let domain = if addr.is_ipv4() { socket2::Domain::IPV4 } else { socket2::Domain::IPV6 }; let socket = Socket::new(domain, socket2::Type::STREAM, None)?; #[cfg(not(windows))] socket.set_reuse_address(true)?; if reuseport { #[cfg(target_os = "linux")] socket.set_reuse_port(true)?; } let socket_addr = socket2::SockAddr::from(addr); socket.bind(&socket_addr)?; socket.listen(128)?; socket.set_nonblocking(true)?; let std_listener: std::net::TcpListener = socket.into(); let mut listener = TcpListener::from_std(std_listener); let mut poll = Poll::new()?; let token = Token(0); poll .registry() .register(&mut listener, token, Interest::READABLE) .unwrap(); let tls_context: Option> = { if let Some(cert) = maybe_cert { let key = maybe_key.unwrap(); let certificate_chain: Vec = load_certs(&mut BufReader::new(cert.as_bytes()))?; let private_key = load_private_keys(key.as_bytes())?.remove(0); let config = rustls::ServerConfig::builder() .with_safe_defaults() .with_no_client_auth() .with_single_cert(certificate_chain, private_key) .expect("invalid key or certificate"); Some(Arc::new(config)) } else { None } }; listening_tx .blocking_send(listener.local_addr().unwrap().port()) .unwrap(); let mut sockets = HashMap::with_capacity(1000); let mut counter: usize = 1; let mut events = Events::with_capacity(1024); 'outer: loop { let result = close_rx.try_recv(); if result.is_ok() { break 'outer; } // FIXME(bartlomieju): how does Tokio handle it? I just put random 100ms // timeout here to handle close signal. match poll.poll(&mut events, Some(Duration::from_millis(100))) { Err(ref e) if e.kind() == std::io::ErrorKind::Interrupted => continue, Err(e) => panic!("{}", e), Ok(()) => (), } 'events: for event in &events { if close_rx.try_recv().is_ok() { break 'outer; } let token = event.token(); match token { Token(0) => loop { match listener.accept() { Ok((mut socket, _)) => { counter += 1; let token = Token(counter); poll .registry() .register(&mut socket, token, Interest::READABLE) .unwrap(); let socket = match tls_context { Some(ref tls_conf) => { let connection = rustls::ServerConnection::new(tls_conf.clone()).unwrap(); InnerStream::Tls(Box::new(rustls::StreamOwned::new( connection, socket, ))) } None => InnerStream::Tcp(socket), }; let stream = Box::pin(Stream { inner: socket, detached: false, read_rx: None, read_tx: None, read_lock: Arc::new(Mutex::new(())), parse_done: ParseStatus::None, buffer: UnsafeCell::new(vec![0_u8; 1024]), }); trace!("New connection: {}", token.0); sockets.insert(token, stream); } Err(ref e) if e.kind() == std::io::ErrorKind::WouldBlock => break, Err(_) => break, } }, token => { let socket = sockets.get_mut(&token).unwrap(); // SAFETY: guarantee that we will never move the data out of the mutable reference. let socket = unsafe { let mut_ref: Pin<&mut Stream> = Pin::as_mut(socket); Pin::get_unchecked_mut(mut_ref) }; let sock_ptr = socket as *mut _; if socket.detached { match &mut socket.inner { InnerStream::Tcp(ref mut socket) => { poll.registry().deregister(socket).unwrap(); } InnerStream::Tls(_) => { todo!("upgrade tls not implemented"); } } let boxed = sockets.remove(&token).unwrap(); std::mem::forget(boxed); trace!("Socket detached: {}", token.0); continue; } debug_assert!(event.is_readable()); trace!("Socket readable: {}", token.0); if let Some(tx) = &socket.read_tx { { let _l = socket.read_lock.lock().unwrap(); } trace!("Sending readiness notification: {}", token.0); let _ = tx.blocking_send(()); continue; } let mut headers = vec![httparse::EMPTY_HEADER; 40]; let mut req = httparse::Request::new(&mut headers); let body_offset; let body_len; loop { // SAFETY: It is safe for the read buf to be mutable here. let buffer = unsafe { &mut *socket.buffer.get() }; let offset = match socket.parse_done { ParseStatus::None => 0, ParseStatus::Ongoing(offset) => offset, }; if offset >= buffer.len() { buffer.resize(offset * 2, 0); } let nread = socket.read(&mut buffer[offset..]); match nread { Ok(0) => { trace!("Socket closed: {}", token.0); // FIXME: don't remove while JS is writing! // sockets.remove(&token); continue 'events; } Ok(read) => { match req.parse(&buffer[..offset + read]) { Ok(httparse::Status::Complete(n)) => { body_offset = n; body_len = offset + read; socket.parse_done = ParseStatus::None; // On Windows, We must keep calling socket.read() until it fails with WouldBlock. // // Mio tries to emulate edge triggered events on Windows. // AFAICT it only rearms the event on WouldBlock, but it doesn't when a partial read happens. // https://github.com/denoland/deno/issues/15549 #[cfg(target_os = "windows")] match &mut socket.inner { InnerStream::Tcp(ref mut socket) => { poll .registry() .reregister(socket, token, Interest::READABLE) .unwrap(); } InnerStream::Tls(ref mut socket) => { poll .registry() .reregister( &mut socket.sock, token, Interest::READABLE, ) .unwrap(); } }; break; } Ok(httparse::Status::Partial) => { socket.parse_done = ParseStatus::Ongoing(offset + read); continue; } Err(_) => { let _ = socket.write(b"HTTP/1.1 400 Bad Request\r\n\r\n"); continue 'events; } } } Err(ref e) if e.kind() == std::io::ErrorKind::WouldBlock => { break 'events } Err(_) => break 'events, } } debug_assert_eq!(socket.parse_done, ParseStatus::None); if let Some(method) = &req.method { if method == &"POST" || method == &"PUT" { let (tx, rx) = mpsc::channel(100); socket.read_tx = Some(tx); socket.read_rx = Some(rx); } } // SAFETY: It is safe for the read buf to be mutable here. let buffer = unsafe { &mut *socket.buffer.get() }; let inner_req = InnerRequest { // SAFETY: backing buffer is pinned and lives as long as the request. req: unsafe { transmute::, _>(req) }, // SAFETY: backing buffer is pinned and lives as long as the request. _headers: unsafe { transmute::>, _>(headers) }, buffer: Pin::new( replace(buffer, vec![0_u8; 1024]).into_boxed_slice(), ), body_offset, body_len, }; // h1 // https://github.com/tiny-http/tiny-http/blob/master/src/client.rs#L177 // https://github.com/hyperium/hyper/blob/4545c3ef191ce9b5f5d250ee27c4c96f9b71d2c6/src/proto/h1/role.rs#L127 let mut keep_alive = inner_req.req.version.unwrap() == 1; let mut expect_continue = false; let mut te = false; let mut te_chunked = false; let mut content_length = None; for header in inner_req.req.headers.iter() { match HeaderName::from_bytes(header.name.as_bytes()) { Ok(CONNECTION) => { // SAFETY: illegal bytes are validated by httparse. let value = unsafe { HeaderValue::from_maybe_shared_unchecked(header.value) }; if keep_alive { // 1.1 keep_alive = !connection_has(&value, "close"); } else { // 1.0 keep_alive = connection_has(&value, "keep-alive"); } } Ok(TRANSFER_ENCODING) => { // https://tools.ietf.org/html/rfc7230#section-3.3.3 debug_assert!(inner_req.req.version.unwrap() == 1); // Two states for Transfer-Encoding because we want to make sure Content-Length handling knows it. te = true; content_length = None; // SAFETY: illegal bytes are validated by httparse. let value = unsafe { HeaderValue::from_maybe_shared_unchecked(header.value) }; if let Ok(Some(encoding)) = value.to_str().map(|s| s.rsplit(',').next()) { // Chunked must always be the last encoding if encoding.trim().eq_ignore_ascii_case("chunked") { te_chunked = true; } } } // Transfer-Encoding overrides the Content-Length. Ok(CONTENT_LENGTH) if !te => { if let Some(len) = from_digits(header.value) { if let Some(prev) = content_length { if prev != len { let _ = socket.write(b"HTTP/1.1 400 Bad Request\r\n\r\n"); continue 'events; } continue; } content_length = Some(len); } else { let _ = socket.write(b"HTTP/1.1 400 Bad Request\r\n\r\n"); continue 'events; } } Ok(EXPECT) if inner_req.req.version.unwrap() != 0 => { expect_continue = header.value.eq_ignore_ascii_case(b"100-continue"); } _ => {} } } // There is Transfer-Encoding but its not chunked. if te && !te_chunked { let _ = socket.write(b"HTTP/1.1 400 Bad Request\r\n\r\n"); continue 'events; } tx.blocking_send(Request { socket: sock_ptr, // SAFETY: headers backing buffer outlives the mio event loop ('static) inner: inner_req, keep_alive, te_chunked, remaining_chunk_size: None, content_read: 0, content_length, expect_continue, }) .ok(); } } } } Ok(()) } fn make_addr_port_pair(hostname: &str, port: u16) -> (&str, u16) { // Default to localhost if given just the port. Example: ":80" if hostname.is_empty() { return ("0.0.0.0", port); } // If this looks like an ipv6 IP address. Example: "[2001:db8::1]" // Then we remove the brackets. let addr = hostname.trim_start_matches('[').trim_end_matches(']'); (addr, port) } /// Resolve network address *synchronously*. pub fn resolve_addr_sync( hostname: &str, port: u16, ) -> Result, AnyError> { let addr_port_pair = make_addr_port_pair(hostname, port); let result = addr_port_pair.to_socket_addrs()?; Ok(result) } fn flash_serve

( state: &mut OpState, opts: ListenOpts, ) -> Result where P: FlashPermissions + 'static, { state .borrow_mut::

() .check_net(&(&opts.hostname, Some(opts.port)), "Deno.serve()")?; let addr = resolve_addr_sync(&opts.hostname, opts.port)? .next() .ok_or_else(|| generic_error("No resolved address found"))?; let (tx, rx) = mpsc::channel(100); let (close_tx, close_rx) = mpsc::channel(1); let (listening_tx, listening_rx) = mpsc::channel(1); let ctx = ServerContext { _addr: addr, tx, rx, requests: HashMap::with_capacity(1000), next_token: 0, close_tx, listening_rx: Some(listening_rx), cancel_handle: CancelHandle::new_rc(), }; let tx = ctx.tx.clone(); let maybe_cert = opts.cert; let maybe_key = opts.key; let reuseport = opts.reuseport; let join_handle = tokio::task::spawn_blocking(move || { run_server( tx, listening_tx, close_rx, addr, maybe_cert, maybe_key, reuseport, ) }); let flash_ctx = state.borrow_mut::(); let server_id = flash_ctx.next_server_id; flash_ctx.next_server_id += 1; flash_ctx.join_handles.insert(server_id, join_handle); flash_ctx.servers.insert(server_id, ctx); Ok(server_id) } #[op] fn op_flash_serve

( state: &mut OpState, opts: ListenOpts, ) -> Result where P: FlashPermissions + 'static, { check_unstable(state, "Deno.serve"); flash_serve::

(state, opts) } #[op] fn op_node_unstable_flash_serve

( state: &mut OpState, opts: ListenOpts, ) -> Result where P: FlashPermissions + 'static, { flash_serve::

(state, opts) } #[op] fn op_flash_wait_for_listening( state: Rc>, server_id: u32, ) -> Result> + 'static, AnyError> { let mut listening_rx = { let mut state = state.borrow_mut(); let flash_ctx = state.borrow_mut::(); let server_ctx = flash_ctx .servers .get_mut(&server_id) .ok_or_else(|| type_error("server not found"))?; server_ctx.listening_rx.take().unwrap() }; Ok(async move { if let Some(port) = listening_rx.recv().await { Ok(port) } else { Err(generic_error("This error will be discarded")) } }) } #[op] fn op_flash_drive_server( state: Rc>, server_id: u32, ) -> Result> + 'static, AnyError> { let join_handle = { let mut state = state.borrow_mut(); let flash_ctx = state.borrow_mut::(); flash_ctx .join_handles .remove(&server_id) .ok_or_else(|| type_error("server not found"))? }; Ok(async move { join_handle .await .map_err(|_| type_error("server join error"))??; Ok(()) }) } // Asychronous version of op_flash_next. This can be a bottleneck under // heavy load, it should be used as a fallback if there are no buffered // requests i.e `op_flash_next() == 0`. #[op] async fn op_flash_next_async( op_state: Rc>, server_id: u32, ) -> u32 { let ctx = { let mut op_state = op_state.borrow_mut(); let flash_ctx = op_state.borrow_mut::(); let ctx = flash_ctx.servers.get_mut(&server_id).unwrap(); ctx as *mut ServerContext }; // SAFETY: we cannot hold op_state borrow across the await point. The JS caller // is responsible for ensuring this is not called concurrently. let ctx = unsafe { &mut *ctx }; let cancel_handle = &ctx.cancel_handle; if let Ok(Some(req)) = ctx.rx.recv().or_cancel(cancel_handle).await { ctx.requests.insert(ctx.next_token, req); ctx.next_token += 1; return 1; } 0 } // Synchronous version of op_flash_next_async. Under heavy load, // this can collect buffered requests from rx channel and return tokens in a single batch. // // perf: please do not add any arguments to this op. With optimizations enabled, // the ContextScope creation is optimized away and the op is as simple as: // f(info: *const v8::FunctionCallbackInfo) { let rv = ...; rv.set_uint32(op_flash_next()); } #[op] fn op_flash_next(state: &mut OpState) -> u32 { let flash_ctx = state.borrow_mut::(); let ctx = flash_ctx.servers.get_mut(&0).unwrap(); next_request_sync(ctx) } // Syncrhonous version of op_flash_next_async. Under heavy load, // this can collect buffered requests from rx channel and return tokens in a single batch. #[op] fn op_flash_next_server(state: &mut OpState, server_id: u32) -> u32 { let flash_ctx = state.borrow_mut::(); let ctx = flash_ctx.servers.get_mut(&server_id).unwrap(); next_request_sync(ctx) } // Wrapper type for tokio::net::TcpStream that implements // deno_websocket::UpgradedStream struct UpgradedStream(tokio::net::TcpStream); impl tokio::io::AsyncRead for UpgradedStream { fn poll_read( self: Pin<&mut Self>, cx: &mut Context, buf: &mut tokio::io::ReadBuf, ) -> std::task::Poll> { 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> { Pin::new(&mut self.get_mut().0).poll_write(cx, buf) } fn poll_flush( self: Pin<&mut Self>, cx: &mut Context, ) -> std::task::Poll> { Pin::new(&mut self.get_mut().0).poll_flush(cx) } fn poll_shutdown( self: Pin<&mut Self>, cx: &mut Context, ) -> std::task::Poll> { Pin::new(&mut self.get_mut().0).poll_shutdown(cx) } } impl deno_websocket::Upgraded for UpgradedStream {} #[inline] pub fn detach_socket( ctx: &mut ServerContext, token: u32, ) -> Result { // Two main 'hacks' to get this working: // * make server thread forget about the socket. `detach_ownership` prevents the socket from being // dropped on the server thread. // * conversion from mio::net::TcpStream -> tokio::net::TcpStream. There is no public API so we // use raw fds. let tx = ctx .requests .remove(&token) .ok_or_else(|| type_error("request closed"))?; let stream = tx.socket(); // prevent socket from being dropped on server thread. // TODO(@littledivy): Box-ify, since there is no overhead. stream.detach_ownership(); #[cfg(unix)] let std_stream = { use std::os::unix::prelude::AsRawFd; use std::os::unix::prelude::FromRawFd; let fd = match stream.inner { InnerStream::Tcp(ref tcp) => tcp.as_raw_fd(), _ => todo!(), }; // SAFETY: `fd` is a valid file descriptor. unsafe { std::net::TcpStream::from_raw_fd(fd) } }; #[cfg(windows)] let std_stream = { use std::os::windows::prelude::AsRawSocket; use std::os::windows::prelude::FromRawSocket; let fd = match stream.inner { InnerStream::Tcp(ref tcp) => tcp.as_raw_socket(), _ => todo!(), }; // SAFETY: `fd` is a valid file descriptor. unsafe { std::net::TcpStream::from_raw_socket(fd) } }; let stream = tokio::net::TcpStream::from_std(std_stream)?; Ok(stream) } #[op] async fn op_flash_upgrade_websocket( state: Rc>, server_id: u32, token: u32, ) -> Result { let stream = { let op_state = &mut state.borrow_mut(); let flash_ctx = op_state.borrow_mut::(); detach_socket(flash_ctx.servers.get_mut(&server_id).unwrap(), token)? }; deno_websocket::ws_create_server_stream( &state, Box::pin(UpgradedStream(stream)), ) .await } pub struct Unstable(pub bool); fn check_unstable(state: &OpState, api_name: &str) { let unstable = state.borrow::(); if !unstable.0 { eprintln!( "Unstable API '{}'. The --unstable flag must be provided.", api_name ); std::process::exit(70); } } pub trait FlashPermissions { fn check_net>( &mut self, _host: &(T, Option), _api_name: &str, ) -> Result<(), AnyError>; } pub fn init(unstable: bool) -> Extension { Extension::builder() .js(deno_core::include_js_files!( prefix "deno:ext/flash", "01_http.js", )) .ops(vec![ op_flash_serve::decl::

(), op_node_unstable_flash_serve::decl::

(), op_flash_respond::decl(), op_flash_respond_async::decl(), op_flash_respond_chuncked::decl(), op_flash_method::decl(), op_flash_path::decl(), op_flash_headers::decl(), op_flash_next::decl(), op_flash_next_server::decl(), op_flash_next_async::decl(), op_flash_read_body::decl(), op_flash_upgrade_websocket::decl(), op_flash_drive_server::decl(), op_flash_wait_for_listening::decl(), op_flash_first_packet::decl(), op_flash_has_body_stream::decl(), op_flash_close_server::decl(), op_flash_make_request::decl(), op_flash_write_resource::decl(), op_try_flash_respond_chuncked::decl(), ]) .state(move |op_state| { op_state.put(Unstable(unstable)); op_state.put(FlashContext { next_server_id: 0, join_handles: HashMap::default(), servers: HashMap::default(), }); Ok(()) }) .build() }