use core::cmp::min; use alloc::{boxed::Box, sync::Arc}; use num_traits::{FromPrimitive, ToPrimitive}; use smoltcp::wire; use system_error::SystemError; use crate::{ filesystem::vfs::{ file::{File, FileMode}, syscall::{IoVec, IoVecs}, }, libs::spinlock::SpinLockGuard, mm::{verify_area, VirtAddr}, net::socket::{AddressFamily, SOL_SOCKET}, process::ProcessManager, syscall::Syscall, }; use super::{ socket::{ PosixSocketType, RawSocket, SocketHandleItem, SocketInode, SocketOptions, TcpSocket, UdpSocket, HANDLE_MAP, }, Endpoint, Protocol, ShutdownType, Socket, }; /// Flags for socket, socketpair, accept4 const SOCK_CLOEXEC: FileMode = FileMode::O_CLOEXEC; const SOCK_NONBLOCK: FileMode = FileMode::O_NONBLOCK; impl Syscall { /// @brief sys_socket系统调用的实际执行函数 /// /// @param address_family 地址族 /// @param socket_type socket类型 /// @param protocol 传输协议 pub fn socket( address_family: usize, socket_type: usize, protocol: usize, ) -> Result { let address_family = AddressFamily::try_from(address_family as u16)?; let socket_type = PosixSocketType::try_from((socket_type & 0xf) as u8)?; // kdebug!("do_socket: address_family: {address_family:?}, socket_type: {socket_type:?}, protocol: {protocol}"); // 根据地址族和socket类型创建socket let socket: Box = match address_family { AddressFamily::Unix | AddressFamily::INet => match socket_type { PosixSocketType::Stream => Box::new(TcpSocket::new(SocketOptions::default())), PosixSocketType::Datagram => Box::new(UdpSocket::new(SocketOptions::default())), PosixSocketType::Raw => Box::new(RawSocket::new( Protocol::from(protocol as u8), SocketOptions::default(), )), _ => { // kdebug!("do_socket: EINVAL"); return Err(SystemError::EINVAL); } }, _ => { // kdebug!("do_socket: EAFNOSUPPORT"); return Err(SystemError::EAFNOSUPPORT); } }; let handle_item = SocketHandleItem::new(&socket); HANDLE_MAP .write_irqsave() .insert(socket.socket_handle(), handle_item); // kdebug!("do_socket: socket: {socket:?}"); let socketinode: Arc = SocketInode::new(socket); let f = File::new(socketinode, FileMode::O_RDWR)?; // kdebug!("do_socket: f: {f:?}"); // 把socket添加到当前进程的文件描述符表中 let binding = ProcessManager::current_pcb().fd_table(); let mut fd_table_guard = binding.write(); let fd = fd_table_guard.alloc_fd(f, None).map(|x| x as usize); drop(fd_table_guard); // kdebug!("do_socket: fd: {fd:?}"); return fd; } /// @brief sys_setsockopt系统调用的实际执行函数 /// /// @param fd 文件描述符 /// @param level 选项级别 /// @param optname 选项名称 /// @param optval 选项值 /// @param optlen optval缓冲区长度 pub fn setsockopt( fd: usize, level: usize, optname: usize, optval: &[u8], ) -> Result { let socket_inode: Arc = ProcessManager::current_pcb() .get_socket(fd as i32) .ok_or(SystemError::EBADF)?; // 获取内层的socket(真正的数据) let socket: SpinLockGuard> = socket_inode.inner(); return socket.setsockopt(level, optname, optval).map(|_| 0); } /// @brief sys_getsockopt系统调用的实际执行函数 /// /// 参考:https://man7.org/linux/man-pages/man2/setsockopt.2.html /// /// @param fd 文件描述符 /// @param level 选项级别 /// @param optname 选项名称 /// @param optval 返回的选项值 /// @param optlen 返回的optval缓冲区长度 pub fn getsockopt( fd: usize, level: usize, optname: usize, optval: *mut u8, optlen: *mut u32, ) -> Result { // 获取socket let optval = optval as *mut u32; let binding: Arc = ProcessManager::current_pcb() .get_socket(fd as i32) .ok_or(SystemError::EBADF)?; let socket = binding.inner(); if level as u8 == SOL_SOCKET { let optname = PosixSocketOption::try_from(optname as i32) .map_err(|_| SystemError::ENOPROTOOPT)?; match optname { PosixSocketOption::SO_SNDBUF => { // 返回发送缓冲区大小 unsafe { *optval = socket.metadata()?.send_buf_size as u32; *optlen = core::mem::size_of::() as u32; } return Ok(0); } PosixSocketOption::SO_RCVBUF => { let optval = optval as *mut u32; // 返回默认的接收缓冲区大小 unsafe { *optval = socket.metadata()?.recv_buf_size as u32; *optlen = core::mem::size_of::() as u32; } return Ok(0); } _ => { return Err(SystemError::ENOPROTOOPT); } } } drop(socket); // To manipulate options at any other level the // protocol number of the appropriate protocol controlling the // option is supplied. For example, to indicate that an option is // to be interpreted by the TCP protocol, level should be set to the // protocol number of TCP. let posix_protocol = PosixIpProtocol::try_from(level as u16).map_err(|_| SystemError::ENOPROTOOPT)?; if posix_protocol == PosixIpProtocol::TCP { let optname = PosixTcpSocketOptions::try_from(optname as i32) .map_err(|_| SystemError::ENOPROTOOPT)?; match optname { PosixTcpSocketOptions::Congestion => return Ok(0), _ => { return Err(SystemError::ENOPROTOOPT); } } } return Err(SystemError::ENOPROTOOPT); } /// @brief sys_connect系统调用的实际执行函数 /// /// @param fd 文件描述符 /// @param addr SockAddr /// @param addrlen 地址长度 /// /// @return 成功返回0,失败返回错误码 pub fn connect(fd: usize, addr: *const SockAddr, addrlen: usize) -> Result { let endpoint: Endpoint = SockAddr::to_endpoint(addr, addrlen)?; let socket: Arc = ProcessManager::current_pcb() .get_socket(fd as i32) .ok_or(SystemError::EBADF)?; let mut socket = unsafe { socket.inner_no_preempt() }; // kdebug!("connect to {:?}...", endpoint); socket.connect(endpoint)?; return Ok(0); } /// @brief sys_bind系统调用的实际执行函数 /// /// @param fd 文件描述符 /// @param addr SockAddr /// @param addrlen 地址长度 /// /// @return 成功返回0,失败返回错误码 pub fn bind(fd: usize, addr: *const SockAddr, addrlen: usize) -> Result { let endpoint: Endpoint = SockAddr::to_endpoint(addr, addrlen)?; let socket: Arc = ProcessManager::current_pcb() .get_socket(fd as i32) .ok_or(SystemError::EBADF)?; let mut socket = unsafe { socket.inner_no_preempt() }; socket.bind(endpoint)?; return Ok(0); } /// @brief sys_sendto系统调用的实际执行函数 /// /// @param fd 文件描述符 /// @param buf 发送缓冲区 /// @param flags 标志 /// @param addr SockAddr /// @param addrlen 地址长度 /// /// @return 成功返回发送的字节数,失败返回错误码 pub fn sendto( fd: usize, buf: &[u8], _flags: u32, addr: *const SockAddr, addrlen: usize, ) -> Result { let endpoint = if addr.is_null() { None } else { Some(SockAddr::to_endpoint(addr, addrlen)?) }; let socket: Arc = ProcessManager::current_pcb() .get_socket(fd as i32) .ok_or(SystemError::EBADF)?; let socket = unsafe { socket.inner_no_preempt() }; return socket.write(buf, endpoint); } /// @brief sys_recvfrom系统调用的实际执行函数 /// /// @param fd 文件描述符 /// @param buf 接收缓冲区 /// @param flags 标志 /// @param addr SockAddr /// @param addrlen 地址长度 /// /// @return 成功返回接收的字节数,失败返回错误码 pub fn recvfrom( fd: usize, buf: &mut [u8], _flags: u32, addr: *mut SockAddr, addrlen: *mut u32, ) -> Result { let socket: Arc = ProcessManager::current_pcb() .get_socket(fd as i32) .ok_or(SystemError::EBADF)?; let mut socket = unsafe { socket.inner_no_preempt() }; let (n, endpoint) = socket.read(buf); drop(socket); let n: usize = n?; // 如果有地址信息,将地址信息写入用户空间 if !addr.is_null() { let sockaddr_in = SockAddr::from(endpoint); unsafe { sockaddr_in.write_to_user(addr, addrlen)?; } } return Ok(n); } /// @brief sys_recvmsg系统调用的实际执行函数 /// /// @param fd 文件描述符 /// @param msg MsgHdr /// @param flags 标志,暂时未使用 /// /// @return 成功返回接收的字节数,失败返回错误码 pub fn recvmsg(fd: usize, msg: &mut MsgHdr, _flags: u32) -> Result { // 检查每个缓冲区地址是否合法,生成iovecs let mut iovs = unsafe { IoVecs::from_user(msg.msg_iov, msg.msg_iovlen, true)? }; let socket: Arc = ProcessManager::current_pcb() .get_socket(fd as i32) .ok_or(SystemError::EBADF)?; let mut socket = unsafe { socket.inner_no_preempt() }; let mut buf = iovs.new_buf(true); // 从socket中读取数据 let (n, endpoint) = socket.read(&mut buf); drop(socket); let n: usize = n?; // 将数据写入用户空间的iovecs iovs.scatter(&buf[..n]); let sockaddr_in = SockAddr::from(endpoint); unsafe { sockaddr_in.write_to_user(msg.msg_name, &mut msg.msg_namelen)?; } return Ok(n); } /// @brief sys_listen系统调用的实际执行函数 /// /// @param fd 文件描述符 /// @param backlog 队列最大连接数 /// /// @return 成功返回0,失败返回错误码 pub fn listen(fd: usize, backlog: usize) -> Result { let socket: Arc = ProcessManager::current_pcb() .get_socket(fd as i32) .ok_or(SystemError::EBADF)?; let mut socket = unsafe { socket.inner_no_preempt() }; socket.listen(backlog)?; return Ok(0); } /// @brief sys_shutdown系统调用的实际执行函数 /// /// @param fd 文件描述符 /// @param how 关闭方式 /// /// @return 成功返回0,失败返回错误码 pub fn shutdown(fd: usize, how: usize) -> Result { let socket: Arc = ProcessManager::current_pcb() .get_socket(fd as i32) .ok_or(SystemError::EBADF)?; let mut socket = unsafe { socket.inner_no_preempt() }; socket.shutdown(ShutdownType::from_bits_truncate(how as u8))?; return Ok(0); } /// @brief sys_accept系统调用的实际执行函数 /// /// @param fd 文件描述符 /// @param addr SockAddr /// @param addrlen 地址长度 /// /// @return 成功返回新的文件描述符,失败返回错误码 pub fn accept(fd: usize, addr: *mut SockAddr, addrlen: *mut u32) -> Result { return Self::do_accept(fd, addr, addrlen, 0); } /// sys_accept4 - accept a connection on a socket /// /// /// If flags is 0, then accept4() is the same as accept(). The /// following values can be bitwise ORed in flags to obtain different /// behavior: /// /// - SOCK_NONBLOCK /// Set the O_NONBLOCK file status flag on the open file /// description (see open(2)) referred to by the new file /// descriptor. Using this flag saves extra calls to fcntl(2) /// to achieve the same result. /// /// - SOCK_CLOEXEC /// Set the close-on-exec (FD_CLOEXEC) flag on the new file /// descriptor. See the description of the O_CLOEXEC flag in /// open(2) for reasons why this may be useful. pub fn accept4( fd: usize, addr: *mut SockAddr, addrlen: *mut u32, mut flags: u32, ) -> Result { // 如果flags不合法,返回错误 if (flags & (!(SOCK_CLOEXEC | SOCK_NONBLOCK)).bits()) != 0 { return Err(SystemError::EINVAL); } if SOCK_NONBLOCK != FileMode::O_NONBLOCK && ((flags & SOCK_NONBLOCK.bits()) != 0) { flags = (flags & !SOCK_NONBLOCK.bits()) | FileMode::O_NONBLOCK.bits(); } return Self::do_accept(fd, addr, addrlen, flags); } fn do_accept( fd: usize, addr: *mut SockAddr, addrlen: *mut u32, flags: u32, ) -> Result { let socket: Arc = ProcessManager::current_pcb() .get_socket(fd as i32) .ok_or(SystemError::EBADF)?; // kdebug!("accept: socket={:?}", socket); let mut socket = unsafe { socket.inner_no_preempt() }; // 从socket中接收连接 let (new_socket, remote_endpoint) = socket.accept()?; drop(socket); // kdebug!("accept: new_socket={:?}", new_socket); // Insert the new socket into the file descriptor vector let new_socket: Arc = SocketInode::new(new_socket); let mut file_mode = FileMode::O_RDWR; if flags & FileMode::O_NONBLOCK.bits() != 0 { file_mode |= FileMode::O_NONBLOCK; } if flags & FileMode::O_CLOEXEC.bits() != 0 { file_mode |= FileMode::O_CLOEXEC; } let new_fd = ProcessManager::current_pcb() .fd_table() .write() .alloc_fd(File::new(new_socket, file_mode)?, None)?; // kdebug!("accept: new_fd={}", new_fd); if !addr.is_null() { // kdebug!("accept: write remote_endpoint to user"); // 将对端地址写入用户空间 let sockaddr_in = SockAddr::from(remote_endpoint); unsafe { sockaddr_in.write_to_user(addr, addrlen)?; } } return Ok(new_fd as usize); } /// @brief sys_getsockname系统调用的实际执行函数 /// /// Returns the current address to which the socket /// sockfd is bound, in the buffer pointed to by addr. /// /// @param fd 文件描述符 /// @param addr SockAddr /// @param addrlen 地址长度 /// /// @return 成功返回0,失败返回错误码 pub fn getsockname( fd: usize, addr: *mut SockAddr, addrlen: *mut u32, ) -> Result { if addr.is_null() { return Err(SystemError::EINVAL); } let socket: Arc = ProcessManager::current_pcb() .get_socket(fd as i32) .ok_or(SystemError::EBADF)?; let socket = socket.inner(); let endpoint: Endpoint = socket.endpoint().ok_or(SystemError::EINVAL)?; drop(socket); let sockaddr_in = SockAddr::from(endpoint); unsafe { sockaddr_in.write_to_user(addr, addrlen)?; } return Ok(0); } /// @brief sys_getpeername系统调用的实际执行函数 /// /// @param fd 文件描述符 /// @param addr SockAddr /// @param addrlen 地址长度 /// /// @return 成功返回0,失败返回错误码 pub fn getpeername( fd: usize, addr: *mut SockAddr, addrlen: *mut u32, ) -> Result { if addr.is_null() { return Err(SystemError::EINVAL); } let socket: Arc = ProcessManager::current_pcb() .get_socket(fd as i32) .ok_or(SystemError::EBADF)?; let socket = socket.inner(); let endpoint: Endpoint = socket.peer_endpoint().ok_or(SystemError::EINVAL)?; drop(socket); let sockaddr_in = SockAddr::from(endpoint); unsafe { sockaddr_in.write_to_user(addr, addrlen)?; } return Ok(0); } } // 参考资料: https://pubs.opengroup.org/onlinepubs/9699919799/basedefs/netinet_in.h.html#tag_13_32 #[repr(C)] #[derive(Debug, Clone, Copy)] pub struct SockAddrIn { pub sin_family: u16, pub sin_port: u16, pub sin_addr: u32, pub sin_zero: [u8; 8], } #[repr(C)] #[derive(Debug, Clone, Copy)] pub struct SockAddrUn { pub sun_family: u16, pub sun_path: [u8; 108], } #[repr(C)] #[derive(Debug, Clone, Copy)] pub struct SockAddrLl { pub sll_family: u16, pub sll_protocol: u16, pub sll_ifindex: u32, pub sll_hatype: u16, pub sll_pkttype: u8, pub sll_halen: u8, pub sll_addr: [u8; 8], } #[repr(C)] #[derive(Debug, Clone, Copy)] pub struct SockAddrNl { nl_family: u16, nl_pad: u16, nl_pid: u32, nl_groups: u32, } #[repr(C)] #[derive(Debug, Clone, Copy)] pub struct SockAddrPlaceholder { pub family: u16, pub data: [u8; 14], } #[repr(C)] #[derive(Clone, Copy)] pub union SockAddr { pub family: u16, pub addr_in: SockAddrIn, pub addr_un: SockAddrUn, pub addr_ll: SockAddrLl, pub addr_nl: SockAddrNl, pub addr_ph: SockAddrPlaceholder, } impl SockAddr { /// @brief 把用户传入的SockAddr转换为Endpoint结构体 pub fn to_endpoint(addr: *const SockAddr, len: usize) -> Result { verify_area( VirtAddr::new(addr as usize), core::mem::size_of::(), ) .map_err(|_| SystemError::EFAULT)?; let addr = unsafe { addr.as_ref() }.ok_or(SystemError::EFAULT)?; if len < addr.len()? { return Err(SystemError::EINVAL); } unsafe { match AddressFamily::try_from(addr.family)? { AddressFamily::INet => { let addr_in: SockAddrIn = addr.addr_in; let ip: wire::IpAddress = wire::IpAddress::from(wire::Ipv4Address::from_bytes( &u32::from_be(addr_in.sin_addr).to_be_bytes()[..], )); let port = u16::from_be(addr_in.sin_port); return Ok(Endpoint::Ip(Some(wire::IpEndpoint::new(ip, port)))); } AddressFamily::Packet => { // TODO: support packet socket return Err(SystemError::EINVAL); } AddressFamily::Netlink => { // TODO: support netlink socket return Err(SystemError::EINVAL); } AddressFamily::Unix => { return Err(SystemError::EINVAL); } _ => { return Err(SystemError::EINVAL); } } } } /// @brief 获取地址长度 pub fn len(&self) -> Result { let ret = match AddressFamily::try_from(unsafe { self.family })? { AddressFamily::INet => Ok(core::mem::size_of::()), AddressFamily::Packet => Ok(core::mem::size_of::()), AddressFamily::Netlink => Ok(core::mem::size_of::()), AddressFamily::Unix => Err(SystemError::EINVAL), _ => Err(SystemError::EINVAL), }; return ret; } /// @brief 把SockAddr的数据写入用户空间 /// /// @param addr 用户空间的SockAddr的地址 /// @param len 要写入的长度 /// /// @return 成功返回写入的长度,失败返回错误码 pub unsafe fn write_to_user( &self, addr: *mut SockAddr, addr_len: *mut u32, ) -> Result { // 当用户传入的地址或者长度为空时,直接返回0 if addr.is_null() || addr_len.is_null() { return Ok(0); } // 检查用户传入的地址是否合法 verify_area( VirtAddr::new(addr as usize), core::mem::size_of::(), ) .map_err(|_| SystemError::EFAULT)?; verify_area( VirtAddr::new(addr_len as usize), core::mem::size_of::(), ) .map_err(|_| SystemError::EFAULT)?; let to_write = min(self.len()?, *addr_len as usize); if to_write > 0 { let buf = core::slice::from_raw_parts_mut(addr as *mut u8, to_write); buf.copy_from_slice(core::slice::from_raw_parts( self as *const SockAddr as *const u8, to_write, )); } *addr_len = self.len()? as u32; return Ok(to_write); } } impl From for SockAddr { fn from(value: Endpoint) -> Self { match value { Endpoint::Ip(ip_endpoint) => { // 未指定地址 if let None = ip_endpoint { return SockAddr { addr_ph: SockAddrPlaceholder { family: AddressFamily::Unspecified as u16, data: [0; 14], }, }; } // 指定了地址 let ip_endpoint = ip_endpoint.unwrap(); match ip_endpoint.addr { wire::IpAddress::Ipv4(ipv4_addr) => { let addr_in = SockAddrIn { sin_family: AddressFamily::INet as u16, sin_port: ip_endpoint.port.to_be(), sin_addr: u32::from_be_bytes(ipv4_addr.0).to_be(), sin_zero: [0; 8], }; return SockAddr { addr_in }; } _ => { unimplemented!("not support ipv6"); } } } Endpoint::LinkLayer(link_endpoint) => { let addr_ll = SockAddrLl { sll_family: AddressFamily::Packet as u16, sll_protocol: 0, sll_ifindex: link_endpoint.interface as u32, sll_hatype: 0, sll_pkttype: 0, sll_halen: 0, sll_addr: [0; 8], }; return SockAddr { addr_ll }; } // _ => { // // todo: support other endpoint, like Netlink... // unimplemented!("not support {value:?}"); // } } } } #[repr(C)] #[derive(Debug, Clone, Copy)] pub struct MsgHdr { /// 指向一个SockAddr结构体的指针 pub msg_name: *mut SockAddr, /// SockAddr结构体的大小 pub msg_namelen: u32, /// scatter/gather array pub msg_iov: *mut IoVec, /// elements in msg_iov pub msg_iovlen: usize, /// 辅助数据 pub msg_control: *mut u8, /// 辅助数据长度 pub msg_controllen: usize, /// 接收到的消息的标志 pub msg_flags: u32, } #[derive(Debug, Clone, Copy, FromPrimitive, ToPrimitive, PartialEq, Eq)] pub enum PosixIpProtocol { /// Dummy protocol for TCP. IP = 0, /// Internet Control Message Protocol. ICMP = 1, /// Internet Group Management Protocol. IGMP = 2, /// IPIP tunnels (older KA9Q tunnels use 94). IPIP = 4, /// Transmission Control Protocol. TCP = 6, /// Exterior Gateway Protocol. EGP = 8, /// PUP protocol. PUP = 12, /// User Datagram Protocol. UDP = 17, /// XNS IDP protocol. IDP = 22, /// SO Transport Protocol Class 4. TP = 29, /// Datagram Congestion Control Protocol. DCCP = 33, /// IPv6-in-IPv4 tunnelling. IPv6 = 41, /// RSVP Protocol. RSVP = 46, /// Generic Routing Encapsulation. (Cisco GRE) (rfc 1701, 1702) GRE = 47, /// Encapsulation Security Payload protocol ESP = 50, /// Authentication Header protocol AH = 51, /// Multicast Transport Protocol. MTP = 92, /// IP option pseudo header for BEET BEETPH = 94, /// Encapsulation Header. ENCAP = 98, /// Protocol Independent Multicast. PIM = 103, /// Compression Header Protocol. COMP = 108, /// Stream Control Transport Protocol SCTP = 132, /// UDP-Lite protocol (RFC 3828) UDPLITE = 136, /// MPLS in IP (RFC 4023) MPLSINIP = 137, /// Ethernet-within-IPv6 Encapsulation ETHERNET = 143, /// Raw IP packets RAW = 255, /// Multipath TCP connection MPTCP = 262, } impl TryFrom for PosixIpProtocol { type Error = SystemError; fn try_from(value: u16) -> Result { match ::from_u16(value) { Some(p) => Ok(p), None => Err(SystemError::EPROTONOSUPPORT), } } } impl Into for PosixIpProtocol { fn into(self) -> u16 { ::to_u16(&self).unwrap() } } #[allow(non_camel_case_types)] #[derive(Debug, Clone, Copy, FromPrimitive, ToPrimitive, PartialEq, Eq)] pub enum PosixSocketOption { SO_DEBUG = 1, SO_REUSEADDR = 2, SO_TYPE = 3, SO_ERROR = 4, SO_DONTROUTE = 5, SO_BROADCAST = 6, SO_SNDBUF = 7, SO_RCVBUF = 8, SO_SNDBUFFORCE = 32, SO_RCVBUFFORCE = 33, SO_KEEPALIVE = 9, SO_OOBINLINE = 10, SO_NO_CHECK = 11, SO_PRIORITY = 12, SO_LINGER = 13, SO_BSDCOMPAT = 14, SO_REUSEPORT = 15, SO_PASSCRED = 16, SO_PEERCRED = 17, SO_RCVLOWAT = 18, SO_SNDLOWAT = 19, SO_RCVTIMEO_OLD = 20, SO_SNDTIMEO_OLD = 21, SO_SECURITY_AUTHENTICATION = 22, SO_SECURITY_ENCRYPTION_TRANSPORT = 23, SO_SECURITY_ENCRYPTION_NETWORK = 24, SO_BINDTODEVICE = 25, /// 与SO_GET_FILTER相同 SO_ATTACH_FILTER = 26, SO_DETACH_FILTER = 27, SO_PEERNAME = 28, SO_ACCEPTCONN = 30, SO_PEERSEC = 31, SO_PASSSEC = 34, SO_MARK = 36, SO_PROTOCOL = 38, SO_DOMAIN = 39, SO_RXQ_OVFL = 40, /// 与SCM_WIFI_STATUS相同 SO_WIFI_STATUS = 41, SO_PEEK_OFF = 42, /* Instruct lower device to use last 4-bytes of skb data as FCS */ SO_NOFCS = 43, SO_LOCK_FILTER = 44, SO_SELECT_ERR_QUEUE = 45, SO_BUSY_POLL = 46, SO_MAX_PACING_RATE = 47, SO_BPF_EXTENSIONS = 48, SO_INCOMING_CPU = 49, SO_ATTACH_BPF = 50, // SO_DETACH_BPF = SO_DETACH_FILTER, SO_ATTACH_REUSEPORT_CBPF = 51, SO_ATTACH_REUSEPORT_EBPF = 52, SO_CNX_ADVICE = 53, SCM_TIMESTAMPING_OPT_STATS = 54, SO_MEMINFO = 55, SO_INCOMING_NAPI_ID = 56, SO_COOKIE = 57, SCM_TIMESTAMPING_PKTINFO = 58, SO_PEERGROUPS = 59, SO_ZEROCOPY = 60, /// 与SCM_TXTIME相同 SO_TXTIME = 61, SO_BINDTOIFINDEX = 62, SO_TIMESTAMP_OLD = 29, SO_TIMESTAMPNS_OLD = 35, SO_TIMESTAMPING_OLD = 37, SO_TIMESTAMP_NEW = 63, SO_TIMESTAMPNS_NEW = 64, SO_TIMESTAMPING_NEW = 65, SO_RCVTIMEO_NEW = 66, SO_SNDTIMEO_NEW = 67, SO_DETACH_REUSEPORT_BPF = 68, SO_PREFER_BUSY_POLL = 69, SO_BUSY_POLL_BUDGET = 70, SO_NETNS_COOKIE = 71, SO_BUF_LOCK = 72, SO_RESERVE_MEM = 73, SO_TXREHASH = 74, SO_RCVMARK = 75, } impl TryFrom for PosixSocketOption { type Error = SystemError; fn try_from(value: i32) -> Result { match ::from_i32(value) { Some(p) => Ok(p), None => Err(SystemError::EINVAL), } } } impl Into for PosixSocketOption { fn into(self) -> i32 { ::to_i32(&self).unwrap() } } #[derive(Debug, Clone, Copy, PartialEq, Eq, FromPrimitive, ToPrimitive)] pub enum PosixTcpSocketOptions { /// Turn off Nagle's algorithm. NoDelay = 1, /// Limit MSS. MaxSegment = 2, /// Never send partially complete segments. Cork = 3, /// Start keeplives after this period. KeepIdle = 4, /// Interval between keepalives. KeepIntvl = 5, /// Number of keepalives before death. KeepCnt = 6, /// Number of SYN retransmits. Syncnt = 7, /// Lifetime for orphaned FIN-WAIT-2 state. Linger2 = 8, /// Wake up listener only when data arrive. DeferAccept = 9, /// Bound advertised window WindowClamp = 10, /// Information about this connection. Info = 11, /// Block/reenable quick acks. QuickAck = 12, /// Congestion control algorithm. Congestion = 13, /// TCP MD5 Signature (RFC2385). Md5Sig = 14, /// Use linear timeouts for thin streams ThinLinearTimeouts = 16, /// Fast retrans. after 1 dupack. ThinDupack = 17, /// How long for loss retry before timeout. UserTimeout = 18, /// TCP sock is under repair right now. Repair = 19, RepairQueue = 20, QueueSeq = 21, RepairOptions = 22, /// Enable FastOpen on listeners FastOpen = 23, Timestamp = 24, /// Limit number of unsent bytes in write queue. NotSentLowat = 25, /// Get Congestion Control (optional) info. CCInfo = 26, /// Record SYN headers for new connections. SaveSyn = 27, /// Get SYN headers recorded for connection. SavedSyn = 28, /// Get/set window parameters. RepairWindow = 29, /// Attempt FastOpen with connect. FastOpenConnect = 30, /// Attach a ULP to a TCP connection. ULP = 31, /// TCP MD5 Signature with extensions. Md5SigExt = 32, /// Set the key for Fast Open(cookie). FastOpenKey = 33, /// Enable TFO without a TFO cookie. FastOpenNoCookie = 34, ZeroCopyReceive = 35, /// Notify bytes available to read as a cmsg on read. /// 与TCP_CM_INQ相同 INQ = 36, /// delay outgoing packets by XX usec TxDelay = 37, } impl TryFrom for PosixTcpSocketOptions { type Error = SystemError; fn try_from(value: i32) -> Result { match ::from_i32(value) { Some(p) => Ok(p), None => Err(SystemError::EINVAL), } } } impl Into for PosixTcpSocketOptions { fn into(self) -> i32 { ::to_i32(&self).unwrap() } }