module net import io.util import net.conv import os union AddrData { Unix Ip Ip6 } const ( addr_ip6_any = [16]u8{init: u8(0)} addr_ip_any = [4]u8{init: u8(0)} ) // new_ip6 creates a new Addr from the IP6 address family, based on the given port and addr pub fn new_ip6(port u16, addr [16]u8) Addr { n_port := $if tinyc { conv.hton16(port) } $else { u16(C.htons(port)) } a := Addr{ f: u8(AddrFamily.ip6) addr: AddrData{ Ip6: Ip6{ port: n_port } } } unsafe { vmemcpy(&a.addr.Ip6.addr[0], &addr[0], 16) } return a } // new_ip creates a new Addr from the IPv4 address family, based on the given port and addr pub fn new_ip(port u16, addr [4]u8) Addr { n_port := $if tinyc { conv.hton16(port) } $else { u16(C.htons(port)) } a := Addr{ f: u8(AddrFamily.ip) addr: AddrData{ Ip: Ip{ port: n_port } } } unsafe { vmemcpy(&a.addr.Ip.addr[0], &addr[0], 4) } return a } fn temp_unix() !Addr { // create a temp file to get a filename // close it // remove it // then reuse the filename mut file, filename := util.temp_file()! file.close() os.rm(filename)! addrs := resolve_addrs(filename, .unix, .udp)! return addrs[0] } // family returns the family/kind of the given address `a` pub fn (a Addr) family() AddrFamily { return unsafe { AddrFamily(a.f) } } const ( max_ip_len = 24 max_ip6_len = 46 ) // str returns a string representation of `a` pub fn (a Ip) str() string { buf := [net.max_ip_len]char{} res := &char(C.inet_ntop(.ip, &a.addr, &buf[0], buf.len)) if res == 0 { return '' } saddr := unsafe { cstring_to_vstring(&buf[0]) } port := $if tinyc { conv.hton16(a.port) } $else { C.ntohs(a.port) } return '${saddr}:${port}' } // str returns a string representation of `a` pub fn (a Ip6) str() string { buf := [net.max_ip6_len]char{} res := &char(C.inet_ntop(.ip6, &a.addr, &buf[0], buf.len)) if res == 0 { return '' } saddr := unsafe { cstring_to_vstring(&buf[0]) } port := $if tinyc { conv.hton16(a.port) } $else { C.ntohs(a.port) } return '[${saddr}]:${port}' } const aoffset = __offsetof(Addr, addr) // len returns the length in bytes of the address `a`, depending on its family pub fn (a Addr) len() u32 { match a.family() { .ip { return sizeof(Ip) + net.aoffset } .ip6 { return sizeof(Ip6) + net.aoffset } .unix { return sizeof(Unix) + net.aoffset } else { panic('Unknown address family') } } } // resolve_addrs converts the given `addr`, `family` and `@type` to a list of addresses pub fn resolve_addrs(addr string, family AddrFamily, @type SocketType) ![]Addr { match family { .ip, .ip6, .unspec { return resolve_ipaddrs(addr, family, @type) } .unix { resolved := Unix{} if addr.len > max_unix_path { return error('net: resolve_addrs Unix socket address is too long') } // Copy the unix path into the address struct unsafe { C.memcpy(&resolved.path, addr.str, addr.len) } return [ Addr{ f: u8(AddrFamily.unix) addr: AddrData{ Unix: resolved } }, ] } } } // resolve_addrs converts the given `addr` and `@type` to a list of addresses pub fn resolve_addrs_fuzzy(addr string, @type SocketType) ![]Addr { if addr.len == 0 { return error('none') } // Use a small heuristic to figure out what address family this is // (out of the ones that we support) if addr.contains(':') { // Colon is a reserved character in unix paths // so this must be an ip address return resolve_addrs(addr, .unspec, @type) } return resolve_addrs(addr, .unix, @type) } // resolve_ipaddrs converts the given `addr`, `family` and `typ` to a list of addresses pub fn resolve_ipaddrs(addr string, family AddrFamily, typ SocketType) ![]Addr { address, port := split_address(addr)! if addr[0] == `:` { match family { .ip6 { return [new_ip6(port, net.addr_ip6_any)] } .ip, .unspec { return [new_ip(port, net.addr_ip_any)] } else {} } } mut hints := C.addrinfo{ // ai_family: int(family) // ai_socktype: int(typ) // ai_flags: C.AI_PASSIVE } unsafe { vmemset(&hints, 0, int(sizeof(hints))) } hints.ai_family = int(family) hints.ai_socktype = int(typ) hints.ai_flags = C.AI_PASSIVE results := &C.addrinfo(unsafe { nil }) sport := '${port}' // This might look silly but is recommended by MSDN $if windows { socket_error(0 - C.getaddrinfo(&char(address.str), &char(sport.str), &hints, &results))! } $else { x := C.getaddrinfo(&char(address.str), &char(sport.str), &hints, &results) wrap_error(x)! } defer { C.freeaddrinfo(results) } // Now that we have our linked list of addresses // convert them into an array mut addresses := []Addr{} for result := unsafe { results }; !isnil(result); result = result.ai_next { match unsafe { AddrFamily(result.ai_family) } { .ip { new_addr := Addr{ addr: AddrData{ Ip: Ip{} } } unsafe { C.memcpy(&new_addr, result.ai_addr, result.ai_addrlen) } addresses << new_addr } .ip6 { new_addr := Addr{ addr: AddrData{ Ip6: Ip6{} } } unsafe { C.memcpy(&new_addr, result.ai_addr, result.ai_addrlen) } addresses << new_addr } else { panic('Unexpected address family ${result.ai_family}') } } } return addresses } // str returns a string representation of the address `a` pub fn (a Addr) str() string { match unsafe { AddrFamily(a.f) } { .ip { unsafe { return a.addr.Ip.str() } } .ip6 { unsafe { return a.addr.Ip6.str() } } .unix { unsafe { return tos_clone(a.addr.Unix.path[0..max_unix_path].data) } } .unspec { return '<.unspec>' } } } // addr_from_socket_handle returns an address, based on the given integer socket `handle` pub fn addr_from_socket_handle(handle int) Addr { mut addr := Addr{ addr: AddrData{ Ip6: Ip6{} } } mut size := sizeof(addr) C.getsockname(handle, voidptr(&addr), &size) return addr } // peer_addr_from_socket_handle retrieves the ip address and port number, given a socket handle pub fn peer_addr_from_socket_handle(handle int) !Addr { mut addr := Addr{ addr: AddrData{ Ip6: Ip6{} } } mut size := sizeof(Addr) socket_error_message(C.getpeername(handle, voidptr(&addr), &size), 'peer_addr_from_socket_handle failed')! return addr }