// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license. use crate::io::TcpStreamResource; use crate::raw::NetworkListenerResource; use crate::resolve_addr::resolve_addr; use crate::resolve_addr::resolve_addr_sync; use crate::tcp::TcpListener; use crate::NetPermissions; use deno_core::op2; use deno_core::CancelFuture; use deno_core::AsyncRefCell; use deno_core::ByteString; 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 hickory_proto::rr::rdata::caa::Value; use hickory_proto::rr::record_data::RData; use hickory_proto::rr::record_type::RecordType; use hickory_resolver::config::NameServerConfigGroup; use hickory_resolver::config::ResolverConfig; use hickory_resolver::config::ResolverOpts; use hickory_resolver::error::ResolveError; use hickory_resolver::error::ResolveErrorKind; use hickory_resolver::system_conf; use hickory_resolver::AsyncResolver; use serde::Deserialize; use serde::Serialize; use socket2::Domain; use socket2::Protocol; use socket2::Socket; use socket2::Type; use std::borrow::Cow; use std::cell::RefCell; use std::net::Ipv4Addr; use std::net::Ipv6Addr; use std::net::SocketAddr; use std::rc::Rc; use std::str::FromStr; use tokio::net::TcpStream; use tokio::net::UdpSocket; #[derive(Serialize, Clone, Debug)] #[serde(rename_all = "camelCase")] pub struct TlsHandshakeInfo { pub alpn_protocol: Option, } #[derive(Debug, Deserialize, Serialize)] pub struct IpAddr { pub hostname: String, pub port: u16, } impl From for IpAddr { fn from(addr: SocketAddr) -> Self { Self { hostname: addr.ip().to_string(), port: addr.port(), } } } #[derive(Debug, thiserror::Error)] pub enum NetError { #[error("Listener has been closed")] ListenerClosed, #[error("Listener already in use")] ListenerBusy, #[error("Socket has been closed")] SocketClosed, #[error("Socket has been closed")] SocketClosedNotConnected, #[error("Socket already in use")] SocketBusy, #[error("{0}")] Io(#[from] std::io::Error), #[error("Another accept task is ongoing")] AcceptTaskOngoing, #[error(transparent)] Permission(#[from] deno_permissions::PermissionCheckError), #[error("{0}")] Resource(deno_core::error::AnyError), #[error("No resolved address found")] NoResolvedAddress, #[error("{0}")] AddrParse(#[from] std::net::AddrParseError), #[error("{0}")] Map(crate::io::MapError), #[error("{0}")] Canceled(#[from] deno_core::Canceled), #[error("{0}")] DnsNotFound(ResolveError), #[error("{0}")] DnsNotConnected(ResolveError), #[error("{0}")] DnsTimedOut(ResolveError), #[error("{0}")] Dns(#[from] ResolveError), #[error("Provided record type is not supported")] UnsupportedRecordType, #[error("File name or path {0:?} is not valid UTF-8")] InvalidUtf8(std::ffi::OsString), #[error("unexpected key type")] UnexpectedKeyType, #[error("Invalid hostname: '{0}'")] InvalidHostname(String), // TypeError #[error("TCP stream is currently in use")] TcpStreamBusy, #[error("{0}")] Rustls(#[from] deno_tls::rustls::Error), #[error("{0}")] Tls(#[from] deno_tls::TlsError), #[error("Error creating TLS certificate: Deno.listenTls requires a key")] ListenTlsRequiresKey, // InvalidData #[error("{0}")] RootCertStore(deno_core::anyhow::Error), #[error("{0}")] Reunite(tokio::net::tcp::ReuniteError), } pub(crate) fn accept_err(e: std::io::Error) -> NetError { if let std::io::ErrorKind::Interrupted = e.kind() { NetError::ListenerClosed } else { NetError::Io(e) } } #[op2(async)] #[serde] pub async fn op_net_accept_tcp( state: Rc>, #[smi] rid: ResourceId, ) -> Result<(ResourceId, IpAddr, IpAddr), NetError> { let resource = state .borrow() .resource_table .get::>(rid) .map_err(|_| NetError::ListenerClosed)?; let listener = RcRef::map(&resource, |r| &r.listener) .try_borrow_mut() .ok_or_else(|| NetError::AcceptTaskOngoing)?; let cancel = RcRef::map(resource, |r| &r.cancel); let (tcp_stream, _socket_addr) = listener .accept() .try_or_cancel(cancel) .await .map_err(accept_err)?; let local_addr = tcp_stream.local_addr()?; let remote_addr = tcp_stream.peer_addr()?; let mut state = state.borrow_mut(); let rid = state .resource_table .add(TcpStreamResource::new(tcp_stream.into_split())); Ok((rid, IpAddr::from(local_addr), IpAddr::from(remote_addr))) } #[op2(async)] #[serde] pub async fn op_net_recv_udp( state: Rc>, #[smi] rid: ResourceId, #[buffer] mut buf: JsBuffer, ) -> Result<(usize, IpAddr), NetError> { let resource = state .borrow_mut() .resource_table .get::(rid) .map_err(|_| NetError::SocketClosed)?; let socket = RcRef::map(&resource, |r| &r.socket).borrow().await; let cancel_handle = RcRef::map(&resource, |r| &r.cancel); let (nread, remote_addr) = socket .recv_from(&mut buf) .try_or_cancel(cancel_handle) .await?; Ok((nread, IpAddr::from(remote_addr))) } #[op2(async)] #[number] pub async fn op_net_send_udp( state: Rc>, #[smi] rid: ResourceId, #[serde] addr: IpAddr, #[buffer] zero_copy: JsBuffer, ) -> Result where NP: NetPermissions + 'static, { { let mut s = state.borrow_mut(); s.borrow_mut::().check_net( &(&addr.hostname, Some(addr.port)), "Deno.DatagramConn.send()", )?; } let addr = resolve_addr(&addr.hostname, addr.port) .await? .next() .ok_or(NetError::NoResolvedAddress)?; let resource = state .borrow_mut() .resource_table .get::(rid) .map_err(|_| NetError::SocketClosed)?; let socket = RcRef::map(&resource, |r| &r.socket).borrow().await; let nwritten = socket.send_to(&zero_copy, &addr).await?; Ok(nwritten) } #[op2(async)] pub async fn op_net_join_multi_v4_udp( state: Rc>, #[smi] rid: ResourceId, #[string] address: String, #[string] multi_interface: String, ) -> Result<(), NetError> { let resource = state .borrow_mut() .resource_table .get::(rid) .map_err(|_| NetError::SocketClosed)?; let socket = RcRef::map(&resource, |r| &r.socket).borrow().await; let addr = Ipv4Addr::from_str(address.as_str())?; let interface_addr = Ipv4Addr::from_str(multi_interface.as_str())?; socket.join_multicast_v4(addr, interface_addr)?; Ok(()) } #[op2(async)] pub async fn op_net_join_multi_v6_udp( state: Rc>, #[smi] rid: ResourceId, #[string] address: String, #[smi] multi_interface: u32, ) -> Result<(), NetError> { let resource = state .borrow_mut() .resource_table .get::(rid) .map_err(|_| NetError::SocketClosed)?; let socket = RcRef::map(&resource, |r| &r.socket).borrow().await; let addr = Ipv6Addr::from_str(address.as_str())?; socket.join_multicast_v6(&addr, multi_interface)?; Ok(()) } #[op2(async)] pub async fn op_net_leave_multi_v4_udp( state: Rc>, #[smi] rid: ResourceId, #[string] address: String, #[string] multi_interface: String, ) -> Result<(), NetError> { let resource = state .borrow_mut() .resource_table .get::(rid) .map_err(|_| NetError::SocketClosed)?; let socket = RcRef::map(&resource, |r| &r.socket).borrow().await; let addr = Ipv4Addr::from_str(address.as_str())?; let interface_addr = Ipv4Addr::from_str(multi_interface.as_str())?; socket.leave_multicast_v4(addr, interface_addr)?; Ok(()) } #[op2(async)] pub async fn op_net_leave_multi_v6_udp( state: Rc>, #[smi] rid: ResourceId, #[string] address: String, #[smi] multi_interface: u32, ) -> Result<(), NetError> { let resource = state .borrow_mut() .resource_table .get::(rid) .map_err(|_| NetError::SocketClosed)?; let socket = RcRef::map(&resource, |r| &r.socket).borrow().await; let addr = Ipv6Addr::from_str(address.as_str())?; socket.leave_multicast_v6(&addr, multi_interface)?; Ok(()) } #[op2(async)] pub async fn op_net_set_multi_loopback_udp( state: Rc>, #[smi] rid: ResourceId, is_v4_membership: bool, loopback: bool, ) -> Result<(), NetError> { let resource = state .borrow_mut() .resource_table .get::(rid) .map_err(|_| NetError::SocketClosed)?; let socket = RcRef::map(&resource, |r| &r.socket).borrow().await; if is_v4_membership { socket.set_multicast_loop_v4(loopback)?; } else { socket.set_multicast_loop_v6(loopback)?; } Ok(()) } #[op2(async)] pub async fn op_net_set_multi_ttl_udp( state: Rc>, #[smi] rid: ResourceId, #[smi] ttl: u32, ) -> Result<(), NetError> { let resource = state .borrow_mut() .resource_table .get::(rid) .map_err(|_| NetError::SocketClosed)?; let socket = RcRef::map(&resource, |r| &r.socket).borrow().await; socket.set_multicast_ttl_v4(ttl)?; Ok(()) } #[op2(async)] #[serde] pub async fn op_net_connect_tcp( state: Rc>, #[serde] addr: IpAddr, ) -> Result<(ResourceId, IpAddr, IpAddr), NetError> where NP: NetPermissions + 'static, { op_net_connect_tcp_inner::(state, addr).await } #[inline] pub async fn op_net_connect_tcp_inner( state: Rc>, addr: IpAddr, ) -> Result<(ResourceId, IpAddr, IpAddr), NetError> where NP: NetPermissions + 'static, { { let mut state_ = state.borrow_mut(); state_ .borrow_mut::() .check_net(&(&addr.hostname, Some(addr.port)), "Deno.connect()")?; } let addr = resolve_addr(&addr.hostname, addr.port) .await? .next() .ok_or_else(|| NetError::NoResolvedAddress)?; let tcp_stream = TcpStream::connect(&addr).await?; let local_addr = tcp_stream.local_addr()?; let remote_addr = tcp_stream.peer_addr()?; let mut state_ = state.borrow_mut(); let rid = state_ .resource_table .add(TcpStreamResource::new(tcp_stream.into_split())); Ok((rid, IpAddr::from(local_addr), IpAddr::from(remote_addr))) } struct UdpSocketResource { socket: AsyncRefCell, cancel: CancelHandle, } impl Resource for UdpSocketResource { fn name(&self) -> Cow { "udpSocket".into() } fn close(self: Rc) { self.cancel.cancel() } } #[op2] #[serde] pub fn op_net_listen_tcp( state: &mut OpState, #[serde] addr: IpAddr, reuse_port: bool, load_balanced: bool, ) -> Result<(ResourceId, IpAddr), NetError> where NP: NetPermissions + 'static, { if reuse_port { super::check_unstable(state, "Deno.listen({ reusePort: true })"); } state .borrow_mut::() .check_net(&(&addr.hostname, Some(addr.port)), "Deno.listen()")?; let addr = resolve_addr_sync(&addr.hostname, addr.port)? .next() .ok_or_else(|| NetError::NoResolvedAddress)?; let listener = if load_balanced { TcpListener::bind_load_balanced(addr) } else { TcpListener::bind_direct(addr, reuse_port) }?; let local_addr = listener.local_addr()?; let listener_resource = NetworkListenerResource::new(listener); let rid = state.resource_table.add(listener_resource); Ok((rid, IpAddr::from(local_addr))) } fn net_listen_udp( state: &mut OpState, addr: IpAddr, reuse_address: bool, loopback: bool, ) -> Result<(ResourceId, IpAddr), NetError> where NP: NetPermissions + 'static, { state .borrow_mut::() .check_net(&(&addr.hostname, Some(addr.port)), "Deno.listenDatagram()")?; let addr = resolve_addr_sync(&addr.hostname, addr.port)? .next() .ok_or_else(|| NetError::NoResolvedAddress)?; let domain = if addr.is_ipv4() { Domain::IPV4 } else { Domain::IPV6 }; let socket_tmp = Socket::new(domain, Type::DGRAM, Some(Protocol::UDP))?; if reuse_address { // This logic is taken from libuv: // // On the BSDs, SO_REUSEPORT implies SO_REUSEADDR but with some additional // refinements for programs that use multicast. // // Linux as of 3.9 has a SO_REUSEPORT socket option but with semantics that // are different from the BSDs: it _shares_ the port rather than steal it // from the current listener. While useful, it's not something we can // emulate on other platforms so we don't enable it. #[cfg(any( target_os = "windows", target_os = "android", target_os = "linux" ))] socket_tmp.set_reuse_address(true)?; #[cfg(all(unix, not(target_os = "linux")))] socket_tmp.set_reuse_port(true)?; } let socket_addr = socket2::SockAddr::from(addr); socket_tmp.bind(&socket_addr)?; socket_tmp.set_nonblocking(true)?; // Enable messages to be sent to the broadcast address (255.255.255.255) by default socket_tmp.set_broadcast(true)?; if domain == Domain::IPV4 { socket_tmp.set_multicast_loop_v4(loopback)?; } else { socket_tmp.set_multicast_loop_v6(loopback)?; } let std_socket: std::net::UdpSocket = socket_tmp.into(); let socket = UdpSocket::from_std(std_socket)?; let local_addr = socket.local_addr()?; let socket_resource = UdpSocketResource { socket: AsyncRefCell::new(socket), cancel: Default::default(), }; let rid = state.resource_table.add(socket_resource); Ok((rid, IpAddr::from(local_addr))) } #[op2] #[serde] pub fn op_net_listen_udp( state: &mut OpState, #[serde] addr: IpAddr, reuse_address: bool, loopback: bool, ) -> Result<(ResourceId, IpAddr), NetError> where NP: NetPermissions + 'static, { super::check_unstable(state, "Deno.listenDatagram"); net_listen_udp::(state, addr, reuse_address, loopback) } #[op2] #[serde] pub fn op_node_unstable_net_listen_udp( state: &mut OpState, #[serde] addr: IpAddr, reuse_address: bool, loopback: bool, ) -> Result<(ResourceId, IpAddr), NetError> where NP: NetPermissions + 'static, { net_listen_udp::(state, addr, reuse_address, loopback) } #[derive(Serialize, Eq, PartialEq, Debug)] #[serde(untagged)] pub enum DnsReturnRecord { A(String), Aaaa(String), Aname(String), Caa { critical: bool, tag: String, value: String, }, Cname(String), Mx { preference: u16, exchange: String, }, Naptr { order: u16, preference: u16, flags: String, services: String, regexp: String, replacement: String, }, Ns(String), Ptr(String), Soa { mname: String, rname: String, serial: u32, refresh: i32, retry: i32, expire: i32, minimum: u32, }, Srv { priority: u16, weight: u16, port: u16, target: String, }, Txt(Vec), } #[derive(Deserialize)] #[serde(rename_all = "camelCase")] pub struct ResolveAddrArgs { cancel_rid: Option, query: String, record_type: RecordType, options: Option, } #[derive(Deserialize)] #[serde(rename_all = "camelCase")] pub struct ResolveDnsOption { name_server: Option, } fn default_port() -> u16 { 53 } #[derive(Deserialize)] #[serde(rename_all = "camelCase")] pub struct NameServer { ip_addr: String, #[serde(default = "default_port")] port: u16, } #[op2(async)] #[serde] pub async fn op_dns_resolve( state: Rc>, #[serde] args: ResolveAddrArgs, ) -> Result, NetError> where NP: NetPermissions + 'static, { let ResolveAddrArgs { query, record_type, options, cancel_rid, } = args; let (config, opts) = if let Some(name_server) = options.as_ref().and_then(|o| o.name_server.as_ref()) { let group = NameServerConfigGroup::from_ips_clear( &[name_server.ip_addr.parse()?], name_server.port, true, ); ( ResolverConfig::from_parts(None, vec![], group), ResolverOpts::default(), ) } else { system_conf::read_system_conf()? }; { let mut s = state.borrow_mut(); let perm = s.borrow_mut::(); // Checks permission against the name servers which will be actually queried. for ns in config.name_servers() { let socker_addr = &ns.socket_addr; let ip = socker_addr.ip().to_string(); let port = socker_addr.port(); perm.check_net(&(ip, Some(port)), "Deno.resolveDns()")?; } } let resolver = AsyncResolver::tokio(config, opts); let lookup_fut = resolver.lookup(query, record_type); let cancel_handle = cancel_rid.and_then(|rid| { state .borrow_mut() .resource_table .get::(rid) .ok() }); let lookup = if let Some(cancel_handle) = cancel_handle { let lookup_rv = lookup_fut.or_cancel(cancel_handle).await; if let Some(cancel_rid) = cancel_rid { if let Ok(res) = state.borrow_mut().resource_table.take_any(cancel_rid) { res.close(); } }; lookup_rv? } else { lookup_fut.await }; lookup .map_err(|e| match e.kind() { ResolveErrorKind::NoRecordsFound { .. } => NetError::DnsNotFound(e), ResolveErrorKind::Message("No connections available") => { NetError::DnsNotConnected(e) } ResolveErrorKind::Timeout => NetError::DnsTimedOut(e), _ => NetError::Dns(e), })? .iter() .filter_map(|rdata| rdata_to_return_record(record_type)(rdata).transpose()) .collect::, NetError>>() } #[op2(fast)] pub fn op_set_nodelay( state: &mut OpState, #[smi] rid: ResourceId, nodelay: bool, ) -> Result<(), NetError> { op_set_nodelay_inner(state, rid, nodelay) } #[inline] pub fn op_set_nodelay_inner( state: &mut OpState, rid: ResourceId, nodelay: bool, ) -> Result<(), NetError> { let resource: Rc = state .resource_table .get::(rid) .map_err(NetError::Resource)?; resource.set_nodelay(nodelay).map_err(NetError::Map) } #[op2(fast)] pub fn op_set_keepalive( state: &mut OpState, #[smi] rid: ResourceId, keepalive: bool, ) -> Result<(), NetError> { op_set_keepalive_inner(state, rid, keepalive) } #[inline] pub fn op_set_keepalive_inner( state: &mut OpState, rid: ResourceId, keepalive: bool, ) -> Result<(), NetError> { let resource: Rc = state .resource_table .get::(rid) .map_err(NetError::Resource)?; resource.set_keepalive(keepalive).map_err(NetError::Map) } fn rdata_to_return_record( ty: RecordType, ) -> impl Fn(&RData) -> Result, NetError> { use RecordType::*; move |r: &RData| -> Result, NetError> { let record = match ty { A => r.as_a().map(ToString::to_string).map(DnsReturnRecord::A), AAAA => r .as_aaaa() .map(ToString::to_string) .map(DnsReturnRecord::Aaaa), ANAME => r .as_aname() .map(ToString::to_string) .map(DnsReturnRecord::Aname), CAA => r.as_caa().map(|caa| DnsReturnRecord::Caa { critical: caa.issuer_critical(), tag: caa.tag().to_string(), value: match caa.value() { Value::Issuer(name, key_values) => { let mut s = String::new(); if let Some(name) = name { s.push_str(&name.to_string()); } else if name.is_none() && key_values.is_empty() { s.push(';'); } for key_value in key_values { s.push_str("; "); s.push_str(&key_value.to_string()); } s } Value::Url(url) => url.to_string(), Value::Unknown(data) => String::from_utf8(data.to_vec()).unwrap(), }, }), CNAME => r .as_cname() .map(ToString::to_string) .map(DnsReturnRecord::Cname), MX => r.as_mx().map(|mx| DnsReturnRecord::Mx { preference: mx.preference(), exchange: mx.exchange().to_string(), }), NAPTR => r.as_naptr().map(|naptr| DnsReturnRecord::Naptr { order: naptr.order(), preference: naptr.preference(), flags: String::from_utf8(naptr.flags().to_vec()).unwrap(), services: String::from_utf8(naptr.services().to_vec()).unwrap(), regexp: String::from_utf8(naptr.regexp().to_vec()).unwrap(), replacement: naptr.replacement().to_string(), }), NS => r.as_ns().map(ToString::to_string).map(DnsReturnRecord::Ns), PTR => r .as_ptr() .map(ToString::to_string) .map(DnsReturnRecord::Ptr), SOA => r.as_soa().map(|soa| DnsReturnRecord::Soa { mname: soa.mname().to_string(), rname: soa.rname().to_string(), serial: soa.serial(), refresh: soa.refresh(), retry: soa.retry(), expire: soa.expire(), minimum: soa.minimum(), }), SRV => r.as_srv().map(|srv| DnsReturnRecord::Srv { priority: srv.priority(), weight: srv.weight(), port: srv.port(), target: srv.target().to_string(), }), TXT => r.as_txt().map(|txt| { let texts: Vec = txt .iter() .map(|bytes| { // Tries to parse these bytes as Latin-1 bytes.iter().map(|&b| b as char).collect::() }) .collect(); DnsReturnRecord::Txt(texts) }), _ => return Err(NetError::UnsupportedRecordType), }; Ok(record) } } #[cfg(test)] mod tests { use super::*; use deno_core::futures::FutureExt; use deno_core::JsRuntime; use deno_core::RuntimeOptions; use deno_permissions::PermissionCheckError; use hickory_proto::rr::rdata::a::A; use hickory_proto::rr::rdata::aaaa::AAAA; use hickory_proto::rr::rdata::caa::KeyValue; use hickory_proto::rr::rdata::caa::CAA; use hickory_proto::rr::rdata::mx::MX; use hickory_proto::rr::rdata::name::ANAME; use hickory_proto::rr::rdata::name::CNAME; use hickory_proto::rr::rdata::name::NS; use hickory_proto::rr::rdata::name::PTR; use hickory_proto::rr::rdata::naptr::NAPTR; use hickory_proto::rr::rdata::srv::SRV; use hickory_proto::rr::rdata::txt::TXT; use hickory_proto::rr::rdata::SOA; use hickory_proto::rr::record_data::RData; use hickory_proto::rr::Name; use socket2::SockRef; use std::net::Ipv4Addr; use std::net::Ipv6Addr; use std::net::ToSocketAddrs; use std::path::Path; use std::path::PathBuf; use std::sync::Arc; use std::sync::Mutex; #[test] fn rdata_to_return_record_a() { let func = rdata_to_return_record(RecordType::A); let rdata = RData::A(A(Ipv4Addr::new(127, 0, 0, 1))); assert_eq!( func(&rdata).unwrap(), Some(DnsReturnRecord::A("127.0.0.1".to_string())) ); } #[test] fn rdata_to_return_record_aaaa() { let func = rdata_to_return_record(RecordType::AAAA); let rdata = RData::AAAA(AAAA(Ipv6Addr::new(0, 0, 0, 0, 0, 0, 0, 1))); assert_eq!( func(&rdata).unwrap(), Some(DnsReturnRecord::Aaaa("::1".to_string())) ); } #[test] fn rdata_to_return_record_aname() { let func = rdata_to_return_record(RecordType::ANAME); let rdata = RData::ANAME(ANAME(Name::new())); assert_eq!( func(&rdata).unwrap(), Some(DnsReturnRecord::Aname("".to_string())) ); } #[test] fn rdata_to_return_record_caa() { let func = rdata_to_return_record(RecordType::CAA); let rdata = RData::CAA(CAA::new_issue( false, Some(Name::parse("example.com", None).unwrap()), vec![KeyValue::new("account", "123456")], )); assert_eq!( func(&rdata).unwrap(), Some(DnsReturnRecord::Caa { critical: false, tag: "issue".to_string(), value: "example.com; account=123456".to_string(), }) ); } #[test] fn rdata_to_return_record_cname() { let func = rdata_to_return_record(RecordType::CNAME); let rdata = RData::CNAME(CNAME(Name::new())); assert_eq!( func(&rdata).unwrap(), Some(DnsReturnRecord::Cname("".to_string())) ); } #[test] fn rdata_to_return_record_mx() { let func = rdata_to_return_record(RecordType::MX); let rdata = RData::MX(MX::new(10, Name::new())); assert_eq!( func(&rdata).unwrap(), Some(DnsReturnRecord::Mx { preference: 10, exchange: "".to_string() }) ); } #[test] fn rdata_to_return_record_naptr() { let func = rdata_to_return_record(RecordType::NAPTR); let rdata = RData::NAPTR(NAPTR::new( 1, 2, >::default(), >::default(), >::default(), Name::new(), )); assert_eq!( func(&rdata).unwrap(), Some(DnsReturnRecord::Naptr { order: 1, preference: 2, flags: "".to_string(), services: "".to_string(), regexp: "".to_string(), replacement: "".to_string() }) ); } #[test] fn rdata_to_return_record_ns() { let func = rdata_to_return_record(RecordType::NS); let rdata = RData::NS(NS(Name::new())); assert_eq!( func(&rdata).unwrap(), Some(DnsReturnRecord::Ns("".to_string())) ); } #[test] fn rdata_to_return_record_ptr() { let func = rdata_to_return_record(RecordType::PTR); let rdata = RData::PTR(PTR(Name::new())); assert_eq!( func(&rdata).unwrap(), Some(DnsReturnRecord::Ptr("".to_string())) ); } #[test] fn rdata_to_return_record_soa() { let func = rdata_to_return_record(RecordType::SOA); let rdata = RData::SOA(SOA::new( Name::new(), Name::new(), 0, i32::MAX, i32::MAX, i32::MAX, 0, )); assert_eq!( func(&rdata).unwrap(), Some(DnsReturnRecord::Soa { mname: "".to_string(), rname: "".to_string(), serial: 0, refresh: i32::MAX, retry: i32::MAX, expire: i32::MAX, minimum: 0, }) ); } #[test] fn rdata_to_return_record_srv() { let func = rdata_to_return_record(RecordType::SRV); let rdata = RData::SRV(SRV::new(1, 2, 3, Name::new())); assert_eq!( func(&rdata).unwrap(), Some(DnsReturnRecord::Srv { priority: 1, weight: 2, port: 3, target: "".to_string() }) ); } #[test] fn rdata_to_return_record_txt() { let func = rdata_to_return_record(RecordType::TXT); let rdata = RData::TXT(TXT::from_bytes(vec![ "foo".as_bytes(), "bar".as_bytes(), &[0xa3], // "£" in Latin-1 &[0xe3, 0x81, 0x82], // "あ" in UTF-8 ])); assert_eq!( func(&rdata).unwrap(), Some(DnsReturnRecord::Txt(vec![ "foo".to_string(), "bar".to_string(), "£".to_string(), "ã\u{81}\u{82}".to_string(), ])) ); } struct TestPermission {} impl NetPermissions for TestPermission { fn check_net>( &mut self, _host: &(T, Option), _api_name: &str, ) -> Result<(), PermissionCheckError> { Ok(()) } fn check_read( &mut self, p: &str, _api_name: &str, ) -> Result { Ok(PathBuf::from(p)) } fn check_write( &mut self, p: &str, _api_name: &str, ) -> Result { Ok(PathBuf::from(p)) } fn check_write_path<'a>( &mut self, p: &'a Path, _api_name: &str, ) -> Result, PermissionCheckError> { Ok(Cow::Borrowed(p)) } } #[tokio::test(flavor = "multi_thread", worker_threads = 1)] async fn tcp_set_no_delay() { let set_nodelay = Box::new(|state: &mut OpState, rid| { op_set_nodelay_inner(state, rid, true).unwrap(); }); let test_fn = Box::new(|socket: SockRef| { assert!(socket.nodelay().unwrap()); assert!(!socket.keepalive().unwrap()); }); check_sockopt(String::from("127.0.0.1:4145"), set_nodelay, test_fn).await; } #[tokio::test(flavor = "multi_thread", worker_threads = 1)] async fn tcp_set_keepalive() { let set_keepalive = Box::new(|state: &mut OpState, rid| { op_set_keepalive_inner(state, rid, true).unwrap(); }); let test_fn = Box::new(|socket: SockRef| { assert!(!socket.nodelay().unwrap()); assert!(socket.keepalive().unwrap()); }); check_sockopt(String::from("127.0.0.1:4146"), set_keepalive, test_fn).await; } #[allow(clippy::type_complexity)] async fn check_sockopt( addr: String, set_sockopt_fn: Box, test_fn: Box, ) { let sockets = Arc::new(Mutex::new(vec![])); let clone_addr = addr.clone(); let addr = addr.to_socket_addrs().unwrap().next().unwrap(); let listener = TcpListener::bind_direct(addr, false).unwrap(); let accept_fut = listener.accept().boxed_local(); let store_fut = async move { let socket = accept_fut.await.unwrap(); sockets.lock().unwrap().push(socket); } .boxed_local(); deno_core::extension!( test_ext, state = |state| { state.put(TestPermission {}); } ); let mut runtime = JsRuntime::new(RuntimeOptions { extensions: vec![test_ext::init_ops()], feature_checker: Some(Arc::new(Default::default())), ..Default::default() }); let conn_state = runtime.op_state(); let server_addr: Vec<&str> = clone_addr.split(':').collect(); let ip_addr = IpAddr { hostname: String::from(server_addr[0]), port: server_addr[1].parse().unwrap(), }; let mut connect_fut = op_net_connect_tcp_inner::(conn_state, ip_addr) .boxed_local(); let mut rid = None; tokio::select! { _ = store_fut => { let result = connect_fut.await; let vals = result.unwrap(); rid = rid.or(Some(vals.0)); }, result = &mut connect_fut => { let vals = result.unwrap(); rid = rid.or(Some(vals.0)); } } let rid = rid.unwrap(); let state = runtime.op_state(); set_sockopt_fn(&mut state.borrow_mut(), rid); let resource = state .borrow_mut() .resource_table .get::(rid) .unwrap(); let wr = resource.wr_borrow_mut().await; let stream = wr.as_ref().as_ref(); let socket = socket2::SockRef::from(stream); test_fn(socket); } }