# # Chronos OS utilities # (c) Copyright 2018-Present # Status Research & Development GmbH # # Licensed under either of # Apache License, version 2.0, (LICENSE-APACHEv2) # MIT license (LICENSE-MIT) ## This module implements cross-platform network interfaces list. ## Currently supported OSes are Windows, Linux, MacOS, BSD(not tested). import algorithm from strutils import toHex import ipnet export ipnet const MaxAdapterAddressLength* = 8 type InterfaceType* = enum IfError = 0, # This is workaround element for ProoveInit warnings. IfOther = 1, IfRegular1822 = 2, IfHdh1822 = 3, IfDdnX25 = 4, IfRfc877X25 = 5, IfEthernetCsmacd = 6, IfIso88023Csmacd = 7, IfIso88024TokenBus = 8, IfIso88025TokenRing = 9, IfIso88026MAN = 10, IfStarlan = 11, IfProteon10Mbit = 12, IfProteon80Mbit = 13, IfHyperChannel = 14, IfFddi = 15, IfLapB = 16, IfSdlc = 17, IfDs1 = 18, IfE1 = 19, IfBasicIsdn = 20, IfPrimaryIsdn = 21, IfPropPoint2PointSerial = 22, IfPpp = 23, IfSoftwareLoopback = 24, IfEon = 25, IfEthernet3Mbit = 26, IfNsip = 27, IfSlip = 28, IfUltra = 29, IfDs3 = 30, IfSip = 31, IfFrameRelay = 32, IfRs232 = 33, IfPara = 34, IfArcNet = 35, IfArcNetPlus = 36, IfAtm = 37, IfMioX25 = 38, IfSonet = 39, IfX25Ple = 40, IfIso88022Llc = 41, IfLocalTalk = 42, IfSmdsDxi = 43, IfFrameRelayService = 44, IfV35 = 45, IfHssi = 46, IfHippi = 47, IfModem = 48, IfAal5 = 49, IfSonetPath = 50, IfSonetVt = 51, IfSmdsIcip = 52, IfPropVirtual = 53, IfPropMultiplexor = 54, IfIeee80212 = 55, IfFibreChannel = 56, IfHippiInterface = 57, IfFrameRelayInterconnect = 58, IfAflane8023 = 59, IfAflane8025 = 60, IfCctemul = 61, IfFastEther = 62, IfIsdn = 63, IfV11 = 64, IfV36 = 65, IfG70364K = 66, IfG7032MB = 67, IfQllc = 68, IfFastEtherFx = 69, IfChannel = 70, IfIeee80211 = 71, IfIbm370Parchan = 72, IfEscon = 73, IfDlsw = 74, IfIsdnS = 75, IfIsdnU = 76, IfLapD = 77, IfIpSwitch = 78, IfRsrb = 79, IfAtmLogical = 80, IfDs0 = 81, IfDs0Bundle = 82, IfBsc = 83, IfAsync = 84, IfCnr = 85, IfIso88025rDtr = 86, IfEplrs = 87, IfArap = 88, IfPropCnls = 89, IfHostPad = 90, IfTermPad = 91, IfFrameRelayMpi = 92, IfX213 = 93, IfAdsl = 94, IfRadsl = 95, IfSdsl = 96, IfVdsl = 97, IfIso88025Crfprint = 98, IfMyrInet = 99, IfVoiceEm = 100, IfVoiceFxo = 101, IfVoiceFxs = 102, IfVoiceEncap = 103, IfVoiceOverip = 104, IfAtmDxi = 105, IfAtmFuni = 106, IfAtmIma = 107, IfPppMultilinkBundle = 108, IfIpoverCdlc = 109, IfIpoverClaw = 110, IfStackToStack = 111, IfVirtualIpAddress = 112, IfMpc = 113, IfIpoverAtm = 114, IfIso88025Fiber = 115, IfTdlc = 116, IfGigabitEthernet = 117, IfHdlc = 118, IfLapF = 119, IfV37 = 120, IfX25Mlp = 121, IfX25HuntGroup = 122, IfTransPhdlc = 123, IfInterleave = 124, IfFast = 125, IfIp = 126, IfDocScableMaclayer = 127, IfDocScableDownstream = 128, IfDocScableUpstream = 129, IfA12MppSwitch = 130, IfTunnel = 131, IfCoffee = 132, IfCes = 133, IfAtmSubInterface = 134, IfL2Vlan = 135, IfL3IpVlan = 136, IfL3IpxVlan = 137, IfDigitalPowerline = 138, IfMediaMailOverIp = 139, IfDtm = 140, IfDcn = 141, IfIpForward = 142, IfMsdsl = 143, IfIeee1394 = 144, IfIfGsn = 145, IfDvbrccMaclayer = 146, IfDvbrccDownstream = 147, IfDvbrccUpstream = 148, IfAtmVirtual = 149, IfMplsTunnel = 150, IfSrp = 151, IfVoiceOverAtm = 152, IfVoiceOverFrameRelay = 153, IfIdsl = 154, IfCompositeLink = 155, IfSs7SigLink = 156, IfPropWirelessP2p = 157, IfFrForward = 158, IfRfc1483 = 159, IfUsb = 160, IfIeee8023AdLag = 161, IfBgpPolicyAccounting = 162, IfFrf16MfrBundle = 163, IfH323Gatekeeper = 164, IfH323Proxy = 165, IfMpls = 166, IfMfSigLink = 167, IfHdsl2 = 168, IfShdsl = 169, IfDs1Fdl = 170, IfPos = 171, IfDvbAsiIn = 172, IfDvbAsiOut = 173, IfPlc = 174, IfNfas = 175, IfTr008 = 176, IfGr303Rdt = 177, IfGr303Idt = 178, IfIsup = 179, IfPropDocsWirelessMaclayer = 180, IfPropDocsWirelessDownstream = 181, IfPropDocsWirelessUpstream = 182, IfHiperLan2 = 183, IfPropBwaP2mp = 184, IfSonetOverheadChannel = 185, IfDigitalWrapperOverheadChannel = 186, IfAal2 = 187, IfRadioMac = 188, IfAtmRadio = 189, IfImt = 190, IfMvl = 191, IfReachDsl = 192, IfFrDlciEndpt = 193, IfAtmVciEndpt = 194, IfOpticalChannel = 195, IfOpticalTransport = 196, IfIeee80216Wman = 237, IfWwanPp = 243, IfWwanPp2 = 244, IfIeee802154 = 259, IfXboxWireless = 281 InterfaceState* = enum StatusError = 0, # This is workaround element for ProoveInit warnings. StatusUp, StatusDown, StatusTesting, StatusUnknown, StatusDormant, StatusNotPresent, StatusLowerLayerDown InterfaceAddress* = object host*: TransportAddress net*: IpNet NetworkInterface* = object ifIndex*: int ifType*: InterfaceType name*: string desc*: string mtu*: int flags*: uint64 state*: InterfaceState mac*: array[MaxAdapterAddressLength, byte] maclen*: int addresses*: seq[InterfaceAddress] Route* = object ifIndex*: int dest*: TransportAddress source*: TransportAddress gateway*: TransportAddress metric*: int proc broadcast*(ifa: InterfaceAddress): TransportAddress {.inline.} = ## Return broadcast address for ``ifa``. result = ifa.net.broadcast() proc network*(ifa: InterfaceAddress): TransportAddress {.inline.} = ## Return network address for ``ifa``. result = ifa.net.network() proc netmask*(ifa: InterfaceAddress): TransportAddress {.inline.} = ## Return network mask for ``ifa``. result = ifa.net.subnetMask() proc init*(ift: typedesc[InterfaceAddress], address: TransportAddress, prefix: int): InterfaceAddress = ## Initialize ``InterfaceAddress`` using ``address`` and prefix length ## ``prefix``. result.host = address result.net = IpNet.init(address, prefix) proc `$`*(ifa: InterfaceAddress): string {.inline.} = ## Return string representation of ``ifa``. if ifa.host.family == AddressFamily.IPv4: result = $ifa.net elif ifa.host.family == AddressFamily.IPv6: result = $ifa.net proc `$`*(iface: NetworkInterface): string = ## Return string representation of network interface ``iface``. result = $iface.ifIndex if len(result) == 1: result.add(". ") else: result.add(". ") result.add(iface.name) when defined(windows): result.add(" [") result.add(iface.desc) result.add("]") result.add(": flags = ") result.add($iface.flags) result.add(" mtu ") result.add($iface.mtu) result.add(" state ") result.add($iface.state) result.add("\n ") result.add($iface.ifType) result.add(" ") if iface.maclen > 0: for i in 0..= int(sizeof(NlMsgHeader))) and (nlh.nlmsg_len >= uint32(sizeof(NlMsgHeader))) and (nlh.nlmsg_len <= uint32(length)) proc NLMSG_NEXT(nlh: ptr NlMsgHeader, length: var int): ptr NlMsgHeader {.inline.} = length = length - int(NLMSG_ALIGN(uint(nlh.nlmsg_len))) result = cast[ptr NlMsgHeader](cast[uint](nlh) + cast[uint](NLMSG_ALIGN(uint(nlh.nlmsg_len)))) proc NLMSG_DATA(nlh: ptr NlMsgHeader): ptr byte {.inline.} = result = cast[ptr byte](cast[uint](nlh) + NLMSG_LENGTH(0)) proc NLMSG_TAIL(nlh: ptr NlMsgHeader): ptr byte {.inline.} = cast[ptr byte](cast[uint](nlh) + NLMSG_ALIGN(uint(nlh.nlmsg_len))) template RTA_ALIGN*(length: uint): uint = (length + RTA_ALIGNTO - 1) and not(RTA_ALIGNTO - 1) template RTA_HDRLEN(): int = int(RTA_ALIGN(uint(sizeof(RtAttr)))) template RTA_LENGTH(length: int): uint = uint(RTA_HDRLEN()) + uint(length) template RTA_PAYLOAD*(length: uint): uint = length - RTA_LENGTH(0) proc IFLA_RTA(r: ptr byte): ptr RtAttr {.inline.} = cast[ptr RtAttr](cast[uint](r) + NLMSG_ALIGN(uint(sizeof(IfInfoMessage)))) proc IFA_RTA(r: ptr byte): ptr RtAttr {.inline.} = cast[ptr RtAttr](cast[uint](r) + NLMSG_ALIGN(uint(sizeof(IfAddrMessage)))) proc RT_RTA(r: ptr byte): ptr RtAttr {.inline.} = cast[ptr RtAttr](cast[uint](r) + NLMSG_ALIGN(uint(sizeof(RtMessage)))) proc RTA_OK(rta: ptr RtAttr, length: int): bool {.inline.} = result = length >= sizeof(RtAttr) and rta.rta_len >= cushort(sizeof(RtAttr)) and rta.rta_len <= cushort(length) proc RTA_NEXT(rta: ptr RtAttr, length: var int): ptr RtAttr {.inline.} = length = length - int(RTA_ALIGN(uint(rta.rta_len))) result = cast[ptr RtAttr](cast[uint](rta) + cast[uint](RTA_ALIGN(uint(rta.rta_len)))) proc RTA_DATA(rta: ptr RtAttr): ptr byte {.inline.} = result = cast[ptr byte](cast[uint](rta) + RTA_LENGTH(0)) proc toInterfaceState(it: cint, flags: cuint): InterfaceState {.inline.} = case it of 1: result = StatusNotPresent of 2: result = StatusDown of 3: result = StatusLowerLayerDown of 4: result = StatusTesting of 5: result = StatusDormant of 6: result = StatusUp else: result = StatusUnknown proc toInterfaceType(ft: uint32): InterfaceType {.inline.} = case ft of ARPHRD_ETHER, ARPHRD_EETHER: result = IfEthernetCsmacd of ARPHRD_LOOPBACK: result = IfSoftwareLoopback of 787..799: result = IfFibreChannel of ARPHRD_PPP: result = IfPpp of ARPHRD_SLIP, ARPHRD_CSLIP, ARPHRD_SLIP6, ARPHRD_CSLIP6: result = IfSlip of ARPHRD_IEEE1394: result = IfIeee1394 of ARPHRD_IEEE80211, ARPHRD_IEEE80211_PRISM, ARPHRD_IEEE80211_RADIOTAP: result = IfIeee80211 of ARPHRD_ATM: result = IfAtm of ARPHRD_HDLC: result = IfHdlc of ARPHRD_HIPPI: result = IfHippiInterface of ARPHRD_ARCNET: result = IfArcNet of ARPHRD_LAPB: result = IfLapB of ARPHRD_FRAD: result = IfFrameRelay else: result = IfOther proc createNetlinkSocket(pid: Pid): SocketHandle = var address: SockAddr_nl address.family = cushort(AF_NETLINK) address.groups = 0 address.pid = cast[uint32](pid) result = posix.socket(AF_NETLINK, posix.SOCK_DGRAM, NETLINK_ROUTE) if result != SocketHandle(-1): if posix.bindSocket(result, cast[ptr SockAddr](addr address), Socklen(sizeof(SockAddr_nl))) != 0: discard posix.close(result) result = SocketHandle(-1) proc sendLinkMessage(fd: SocketHandle, pid: Pid, seqno: uint32, ntype: uint16, nflags: uint16): bool = var rmsg: Tmsghdr iov: IOVec req: NLReq address: SockAddr_nl address.family = cushort(AF_NETLINK) req.hdr.nlmsg_len = NLMSG_LENGTH(sizeof(RtGenMsg)) req.hdr.nlmsg_type = ntype req.hdr.nlmsg_flags = nflags req.hdr.nlmsg_seq = seqno req.hdr.nlmsg_pid = cast[uint32](pid) req.msg.rtgen_family = byte(AF_PACKET) iov.iov_base = cast[pointer](addr req) iov.iov_len = cast[csize](req.hdr.nlmsg_len) rmsg.msg_iov = addr iov rmsg.msg_iovlen = 1 rmsg.msg_name = cast[pointer](addr address) rmsg.msg_namelen = Socklen(sizeof(SockAddr_nl)) let res = posix.sendmsg(fd, addr rmsg, 0) if res == iov.iov_len: result = true proc sendRouteMessage(fd: SocketHandle, pid: Pid, seqno: uint32, ntype: uint16, nflags: uint16, dest: TransportAddress): bool = var rmsg: Tmsghdr iov: IOVec address: SockAddr_nl buffer: array[64, byte] var req = cast[ptr NlRouteReq](addr buffer[0]) address.family = cushort(AF_NETLINK) req.hdr.nlmsg_len = NLMSG_LENGTH(sizeof(RtMessage)) req.hdr.nlmsg_type = ntype req.hdr.nlmsg_flags = nflags req.hdr.nlmsg_seq = seqno req.hdr.nlmsg_pid = cast[uint32](pid) var attr = cast[ptr RtAttr](NLMSG_TAIL(addr req.hdr)) req.msg.rtm_flags = RTM_F_LOOKUP_TABLE attr.rta_type = RTA_DST if dest.family == AddressFamily.IPv4: req.msg.rtm_family = byte(posix.AF_INET) attr.rta_len = cast[cushort](RTA_LENGTH(4)) copyMem(RTA_DATA(attr), cast[ptr byte](unsafeAddr dest.address_v4[0]), 4) req.hdr.nlmsg_len = uint32(NLMSG_ALIGN(uint(req.hdr.nlmsg_len)) + RTA_ALIGN(uint(attr.rta_len))) req.msg.rtm_dst_len = 4 * 8 elif dest.family == AddressFamily.IPv6: req.msg.rtm_family = byte(posix.AF_INET6) attr.rta_len = cast[cushort](RTA_LENGTH(16)) copyMem(RTA_DATA(attr), cast[ptr byte](unsafeAddr dest.address_v6[0]), 16) req.hdr.nlmsg_len = uint32(NLMSG_ALIGN(uint(req.hdr.nlmsg_len)) + RTA_ALIGN(uint(attr.rta_len))) req.msg.rtm_dst_len = 16 * 8 iov.iov_base = cast[pointer](addr buffer[0]) iov.iov_len = cast[csize](req.hdr.nlmsg_len) rmsg.msg_iov = addr iov rmsg.msg_iovlen = 1 rmsg.msg_name = cast[pointer](addr address) rmsg.msg_namelen = Socklen(sizeof(SockAddr_nl)) let res = posix.sendmsg(fd, addr rmsg, 0) if res == iov.iov_len: result = true proc readNetlinkMessage(fd: SocketHandle, data: var seq[byte]): bool = var rmsg: Tmsghdr iov: IOVec address: SockAddr_nl data.setLen(IFLIST_REPLY_BUFFER) iov.iov_base = cast[pointer](addr data[0]) iov.iov_len = IFLIST_REPLY_BUFFER rmsg.msg_iov = addr iov rmsg.msg_iovlen = 1 rmsg.msg_name = cast[pointer](addr address) rmsg.msg_namelen = SockLen(sizeof(SockAddr_nl)) var length = posix.recvmsg(fd, addr rmsg, 0) if length >= 0: data.setLen(length) result = true else: data.setLen(0) proc processLink(msg: ptr NlMsgHeader): NetworkInterface = var iface: ptr IfInfoMessage var attr: ptr RtAttr var length: int iface = cast[ptr IfInfoMessage](NLMSG_DATA(msg)) length = int(msg.nlmsg_len) - int(NLMSG_LENGTH(sizeof(IfInfoMessage))) attr = IFLA_RTA(cast[ptr byte](iface)) result.ifType = toInterfaceType(iface.ifi_type) result.ifIndex = iface.ifi_index result.flags = cast[uint64](iface.ifi_flags) while RTA_OK(attr, length): if attr.rta_type == IFLA_IFNAME: var p = cast[cstring](RTA_DATA(attr)) result.name = $p elif attr.rta_type == IFLA_ADDRESS: var p = cast[ptr byte](RTA_DATA(attr)) var plen = min(int(RTA_PAYLOAD(uint(attr.rta_len))), len(result.mac)) copyMem(addr result.mac[0], p, plen) result.maclen = plen elif attr.rta_type == IFLA_MTU: var p = cast[ptr uint32](RTA_DATA(attr)) result.mtu = cast[int](p[]) elif attr.rta_type == IFLA_OPERSTATE: var p = cast[ptr byte](RTA_DATA(attr)) result.state = toInterfaceState(cast[cint](p[]), iface.ifi_flags) attr = RTA_NEXT(attr, length) proc getAddress(f: int, p: pointer): TransportAddress {.inline.} = if f == posix.AF_INET: result = TransportAddress(family: AddressFamily.IPv4) copyMem(addr result.address_v4[0], p, len(result.address_v4)) elif f == posix.AF_INET6: result = TransportAddress(family: AddressFamily.IPv6) copyMem(addr result.address_v6[0], p, len(result.address_v6)) proc processAddress(msg: ptr NlMsgHeader): NetworkInterface = var iaddr: ptr IfAddrMessage var attr: ptr RtAttr var length: int iaddr = cast[ptr IfAddrMessage](NLMSG_DATA(msg)) length = int(msg.nlmsg_len) - int(NLMSG_LENGTH(sizeof(IfAddrMessage))) attr = IFA_RTA(cast[ptr byte](iaddr)) let family = cast[int](iaddr.ifa_family) result.ifIndex = cast[int](iaddr.ifa_index) var address, local: TransportAddress while RTA_OK(attr, length): if attr.rta_type == IFA_LOCAL: local = getAddress(family, cast[pointer](RTA_DATA(attr))) elif attr.rta_type == IFA_ADDRESS: address = getAddress(family, cast[pointer](RTA_DATA(attr))) attr = RTA_NEXT(attr, length) if local.family != AddressFamily.None: address = local if len(result.addresses) == 0: result.addresses = newSeq[InterfaceAddress]() let prefixLength = cast[int](iaddr.ifa_prefixlen) let ifaddr = InterfaceAddress.init(address, prefixLength) result.addresses.add(ifaddr) proc processRoute(msg: ptr NlMsgHeader): Route = var rtmsg = cast[ptr RtMessage](NLMSG_DATA(msg)) var length = int(msg.nlmsg_len) - int(NLMSG_LENGTH(sizeof(RtMessage))) var attr = RT_RTA(cast[ptr byte](rtmsg)) while RTA_OK(attr, length): if attr.rta_type == RTA_DST: result.dest = getAddress(int(rtmsg.rtm_family), cast[pointer](RTA_DATA(attr))) elif attr.rta_type == RTA_GATEWAY: result.gateway = getAddress(int(rtmsg.rtm_family), cast[pointer](RTA_DATA(attr))) elif attr.rta_type == RTA_OIF: var oid: uint32 copyMem(addr oid, RTA_DATA(attr), sizeof(uint32)) result.ifIndex = int(oid) elif attr.rta_type == RTA_PREFSRC: result.source = getAddress(int(rtmsg.rtm_family), cast[pointer](RTA_DATA(attr))) attr = RTA_NEXT(attr, length) proc getRoute(netfd: SocketHandle, pid: Pid, address: TransportAddress): Route = if not sendRouteMessage(netfd, pid, 1, RTM_GETROUTE, NLM_F_REQUEST, address): return var data = newSeq[byte]() while true: if not readNetlinkMessage(netfd, data): break var length = len(data) var msg = cast[ptr NlMsgHeader](addr data[0]) var endflag = false while NLMSG_OK(msg, length): if msg.nlmsg_type == NLMSG_ERROR: endflag = true break else: result = processRoute(msg) endflag = true break msg = NLMSG_NEXT(msg, length) if endflag: break proc getLinks(netfd: SocketHandle, pid: Pid): seq[NetworkInterface] = if not sendLinkMessage(netfd, pid, 1, RTM_GETLINK, NLM_F_REQUEST or NLM_F_DUMP): return var data = newSeq[byte]() result = newSeq[NetworkInterface]() while true: if not readNetlinkMessage(netfd, data): break var length = len(data) if length == 0: break var msg = cast[ptr NlMsgHeader](addr data[0]) var endflag = false while NLMSG_OK(msg, length): if msg.nlmsg_type == NLMSG_DONE: endflag = true break elif msg.nlmsg_type == NLMSG_ERROR: endflag = true break else: var iface = processLink(msg) result.add(iface) msg = NLMSG_NEXT(msg, length) if endflag: break proc getAddresses(netfd: SocketHandle, pid: Pid, ifaces: var seq[NetworkInterface]) = if not sendLinkMessage(netfd, pid, 2, RTM_GETADDR, NLM_F_REQUEST or NLM_F_DUMP): return var data = newSeq[byte]() while true: if not readNetlinkMessage(netfd, data): break var length = len(data) if length == 0: break var msg = cast[ptr NlMsgHeader](addr data[0]) var endflag = false while NLMSG_OK(msg, length): if msg.nlmsg_type == NLMSG_DONE: endflag = true break elif msg.nlmsg_type == NLMSG_ERROR: endflag = true break else: var iface = processAddress(msg) for i in 0..", pure, final.} = object ifa_next {.importc: "ifa_next".}: ptr IfAddrs ifa_name {.importc: "ifa_name".}: ptr cchar ifa_flags {.importc: "ifa_flags".}: cuint ifa_addr {.importc: "ifa_addr".}: ptr SockAddr ifa_netmask {.importc: "ifa_netmask".}: ptr SockAddr ifa_dstaddr {.importc: "ifa_dstaddr".}: ptr SockAddr ifa_data {.importc: "ifa_data".}: pointer PIfAddrs = ptr IfAddrs IfData {.importc: "struct if_data", header: "", pure, final.} = object ifi_type {.importc: "ifi_type".}: byte ifi_typelen {.importc: "ifi_typelen".}: byte ifi_physical {.importc: "ifi_physical".}: byte ifi_addrlen {.importc: "ifi_addrlen".}: byte ifi_hdrlen {.importc: "ifi_hdrlen".}: byte ifi_recvquota {.importc: "ifi_recvquota".}: byte ifi_xmitquota {.importc: "ifi_xmitquota".}: byte ifi_unused1 {.importc: "ifi_unused1".}: byte ifi_mtu {.importc: "ifi_mtu".}: uint32 ifi_metric {.importc: "ifi_metric".}: uint32 ifi_baudrate {.importc: "ifi_baudrate".}: uint32 ifi_ipackets {.importc: "ifi_ipackets".}: uint32 ifi_ierrors {.importc: "ifi_ierrors".}: uint32 ifi_opackets {.importc: "ifi_opackets".}: uint32 ifi_oerrors {.importc: "ifi_oerrors".}: uint32 ifi_collisions {.importc: "ifi_collisions".}: uint32 ifi_ibytes {.importc: "ifi_ibytes".}: uint32 ifi_obytes {.importc: "ifi_obytes".}: uint32 ifi_imcasts {.importc: "ifi_imcasts".}: uint32 ifi_omcasts {.importc: "ifi_omcasts".}: uint32 ifi_iqdrops {.importc: "ifi_iqdrops".}: uint32 ifi_noproto {.importc: "ifi_noproto".}: uint32 ifi_recvtiming {.importc: "ifi_recvtiming".}: uint32 ifi_xmittiming {.importc: "ifi_xmittiming".}: uint32 ifi_lastchange {.importc: "ifi_lastchange".}: Timeval ifi_unused2 {.importc: "ifi_unused2".}: uint32 ifi_hwassist {.importc: "ifi_hwassist".}: uint32 ifi_reserved1 {.importc: "ifi_reserved1".}: uint32 ifi_reserved2 {.importc: "ifi_reserved2".}: uint32 SockAddr_dl = object sdl_len: byte sdl_family: byte sdl_index: uint16 sdl_type: byte sdl_nlen: byte sdl_alen: byte sdl_slen: byte sdl_data: array[12, byte] RtMetrics = object rmx_locks: uint32 rmx_mtu: uint32 rmx_hopcount: uint32 rmx_expire: int32 rmx_recvpipe: uint32 rmx_sendpipe: uint32 rmx_ssthresh: uint32 rmx_rtt: uint32 rmx_rttvar: uint32 rmx_pksent: uint32 rmx_state: uint32 rmx_filler: array[3, uint32] RtMsgHeader = object rtm_msglen: uint16 rtm_version: byte rtm_type: byte rtm_index: uint16 rtm_flags: cint rtm_addrs: cint rtm_pid: Pid rtm_seq: cint rtm_errno: cint rtm_use: cint rtm_inits: uint32 rtm_rmx: RtMetrics RtMessage = object rtm: RtMsgHeader space: array[512, byte] BSDSockAddrHeader = object sa_len: byte sa_family: byte proc getIfAddrs(ifap: ptr PIfAddrs): cint {.importc: "getifaddrs", header: """#include #include #include """.} proc freeIfAddrs(ifap: ptr IfAddrs) {.importc: "freeifaddrs", header: """#include #include #include """.} proc toInterfaceType(f: byte): InterfaceType {.inline.} = var ft = cast[int](f) if (ft >= 1 and ft <= 196) or (ft == 237) or (ft == 243) or (ft == 244): result = cast[InterfaceType](ft) else: result = IfOther proc toInterfaceState(f: cuint): InterfaceState {.inline.} = if (f and IFF_RUNNING) != 0 and (f and IFF_UP) != 0: result = StatusUp else: result = StatusDown proc getInterfaces*(): seq[NetworkInterface] = ## Return list of available interfaces. var ifap: ptr IfAddrs let res = getIfAddrs(addr ifap) if res == 0: result = newSeq[NetworkInterface]() while not isNil(ifap): var iface: NetworkInterface var ifaddress: InterfaceAddress iface.name = $ifap.ifa_name iface.flags = cast[uint64](ifap.ifa_flags) var i = 0 while i < len(result): if result[i].name == iface.name: break inc(i) if i == len(result): result.add(iface) if not isNil(ifap.ifa_addr): let family = cast[int](ifap.ifa_addr.sa_family) if family == AF_LINK: var data = cast[ptr IfData](ifap.ifa_data) var link = cast[ptr SockAddr_dl](ifap.ifa_addr) result[i].ifIndex = cast[int](link.sdl_index) let nlen = cast[int](link.sdl_nlen) if nlen < len(link.sdl_data): let minsize = min(cast[int](link.sdl_alen), len(result[i].mac)) copyMem(addr result[i].mac[0], addr link.sdl_data[nlen], minsize) result[i].maclen = cast[int](link.sdl_alen) result[i].ifType = toInterfaceType(data.ifi_type) result[i].state = toInterfaceState(ifap.ifa_flags) result[i].mtu = cast[int](data.ifi_mtu) elif family == posix.AF_INET: fromSAddr(cast[ptr Sockaddr_storage](ifap.ifa_addr), Socklen(sizeof(SockAddr_in)), ifaddress.host) elif family == posix.AF_INET6: fromSAddr(cast[ptr Sockaddr_storage](ifap.ifa_addr), Socklen(sizeof(SockAddr_in6)), ifaddress.host) if not isNil(ifap.ifa_netmask): var na: TransportAddress var slen: Socklen var family = cast[cint](ifap.ifa_netmask.sa_family) if family == posix.AF_INET: fromSAddr(cast[ptr Sockaddr_storage](ifap.ifa_netmask), Socklen(sizeof(SockAddr_in)), na) elif family == posix.AF_INET6: fromSAddr(cast[ptr Sockaddr_storage](ifap.ifa_netmask), Socklen(sizeof(SockAddr_in6)), na) ifaddress.net = IpNet.init(ifaddress.host, na) if ifaddress.host.family != AddressFamily.None: if len(result[i].addresses) == 0: result[i].addresses = newSeq[InterfaceAddress]() result[i].addresses.add(ifaddress) ifap = ifap.ifa_next sort(result, cmp) freeIfAddrs(ifap) proc sasize(data: openarray[byte]): int = # SA_SIZE() template. Taken from FreeBSD net/route.h:1.63 if len(data) > 0: if data[0] == 0x00'u8: result = sizeof(uint32) else: result = 1 + (int(data[0] - 1) or (sizeof(uint32) - 1)) proc getBestRoute*(address: TransportAddress): Route = ## Return best applicable OS route, which will be used for connecting to ## address ``address``. var sock: cint var msg: RtMessage var pid = posix.getpid() if address.family notin {AddressFamily.IPv4, AddressFamily.IPv6}: return if address.family == AddressFamily.IPv4: sock = cint(posix.socket(PF_ROUTE, posix.SOCK_RAW, posix.AF_INET)) elif address.family == AddressFamily.IPv6: sock = cint(posix.socket(PF_ROUTE, posix.SOCK_RAW, posix.AF_INET6)) if sock != -1: var sastore: Sockaddr_storage var salen: Socklen address.toSAddr(sastore, salen) # We doing this trick because Nim's posix declaration of Sockaddr_storage # is not compatible with BSD version. First byte in BSD version is length # of Sockaddr structure, and second byte is family code. copyMem(addr msg.space[0], addr sastore, int(salen)) msg.rtm.rtm_type = RTM_GET msg.rtm.rtm_flags = RTF_UP or RTF_GATEWAY msg.rtm.rtm_version = RTM_VERSION msg.rtm.rtm_seq = 0xCAFE msg.rtm.rtm_addrs = RTA_DST msg.space[0] = cast[byte](salen) msg.rtm.rtm_msglen = uint16(sizeof(RtMessage)) var res = posix.write(sock, addr msg, sizeof(RtMessage)) if res >= 0: while true: res = posix.read(sock, addr msg, sizeof(RtMessage)) if res >= 0 and msg.rtm.rtm_pid == pid and msg.rtm.rtm_seq == 0xCAFE: break if res >= 0 and msg.rtm.rtm_version == RTM_VERSION and msg.rtm.rtm_errno == 0: result.ifIndex = int(msg.rtm.rtm_index) var so = 0 var eo = len(msg.space) - 1 for i in 0..<2: let mask = 1 shl i if (msg.rtm.rtm_addrs and mask) != 0: var saddr = cast[ptr Sockaddr_storage](addr msg.space[so]) let size = sasize(msg.space.toOpenArray(so, eo)) if mask == RTA_DST: fromSAddr(saddr, Socklen(size), result.dest) elif mask == RTA_GATEWAY: fromSAddr(saddr, Socklen(size), result.gateway) so += size if result.dest.isZero(): result.dest = address var interfaces = getInterfaces() for item in interfaces: if result.ifIndex == item.ifIndex: for a in item.addresses: if a.host.family == address.family: result.source = a.host break discard posix.close(sock) elif defined(windows): import winlean, dynlib const IfOperStatusUp = cint(1) IfOperStatusDown = cint(2) IfOperStatusTesting = cint(3) IfOperStatusUnknown = cint(4) IfOperStatusDormant = cint(5) IfOperStatusNotPresent = cint(6) IfOperStatusLowerLayerDown = cint(7) IpPrefixOriginOther = cint(0) IpPrefixOriginManual = cint(1) IpPrefixOriginWellKnown = cint(2) IpPrefixOriginDhcp = cint(3) IpPrefixOriginRouterAdvertisement = cint(4) IpPrefixOriginUnchanged = cint(1) shl 4 IpSuffixOriginOther = cint(0) IpSuffixOriginManual = cint(1) IpSuffixOriginWellKnown = cint(2) IpSuffixOriginDhcp = cint(3) IpSuffixOriginLinkLayerAddress = cint(4) IpSuffixOriginRandom = cint(5) IpSuffixOriginUnchanged = cint(1) shl 4 IpDadStateInvalid = cint(0) IpDadStateTentative = cint(1) IpDadStateDuplicate = cint(2) IpDadStateDeprecated = cint(3) IpDadStatePreferred = cint(4) WorkBufferSize = 16384'u32 MaxTries = 3 AF_UNSPEC = 0x00'u32 GAA_FLAG_INCLUDE_PREFIX = 0x0010'u32 CP_UTF8 = 65001'u32 ERROR_BUFFER_OVERFLOW* = 111'u32 ERROR_SUCCESS* = 0'u32 type WCHAR = distinct uint16 SocketAddress = object lpSockaddr: ptr SockAddr iSockaddrLength: cint IpAdapterUnicastAddressXpLh = object length: uint32 flags: uint32 next: ptr IpAdapterUnicastAddressXpLh address: SocketAddress prefixOrigin: cint suffixOrigin: cint dadState: cint validLifetime: uint32 preferredLifetime: uint32 leaseLifetime: uint32 onLinkPrefixLength: byte # This field is available only from Vista IpAdapterAnycastAddressXp = object length: uint32 flags: uint32 next: ptr IpAdapterAnycastAddressXp address: SocketAddress IpAdapterMulticastAddressXp = object length: uint32 flags: uint32 next: ptr IpAdapterMulticastAddressXp address: SocketAddress IpAdapterDnsServerAddressXp = object length: uint32 flags: uint32 next: ptr IpAdapterDnsServerAddressXp address: SocketAddress IpAdapterPrefixXp = object length: uint32 flags: uint32 next: ptr IpAdapterPrefixXp address: SocketAddress prefixLength: uint32 IpAdapterAddressesXp = object length: uint32 ifIndex: uint32 next: ptr IpAdapterAddressesXp adapterName: cstring unicastAddress: ptr IpAdapterUnicastAddressXpLh anycastAddress: ptr IpAdapterAnycastAddressXp multicastAddress: ptr IpAdapterMulticastAddressXp dnsServerAddress: ptr IpAdapterDnsServerAddressXp dnsSuffix: ptr WCHAR description: ptr WCHAR friendlyName: ptr WCHAR physicalAddress: array[MaxAdapterAddressLength, byte] physicalAddressLength: uint32 flags: uint32 mtu: uint32 ifType: uint32 operStatus: cint ipv6IfIndex: uint32 zoneIndices: array[16, uint32] firstPrefix: ptr IpAdapterPrefixXp MibIpForwardRow = object dwForwardDest: uint32 dwForwardMask: uint32 dwForwardPolicy: uint32 dwForwardNextHop: uint32 dwForwardIfIndex: uint32 dwForwardType: uint32 dwForwardProto: uint32 dwForwardAge: uint32 dwForwardNextHopAS: uint32 dwForwardMetric1: uint32 dwForwardMetric2: uint32 dwForwardMetric3: uint32 dwForwardMetric4: uint32 dwForwardMetric5: uint32 NET_LUID = object value: uint64 info: uint64 SOCKADDR_INET {.union.} = object ipv4: Sockaddr_in ipv6: Sockaddr_in6 si_family: uint16 IPADDRESS_PREFIX = object prefix: SOCKADDR_INET prefixLength: uint8 MibIpForwardRow2 = object interfaceLuid: uint64 interfaceIndex: uint32 destinationPrefix: IPADDRESS_PREFIX nextHop: SOCKADDR_INET sitePrefixLength: byte validLifetime: uint32 preferredLifetime: uint32 metric: uint32 protocol: uint32 loopback: bool autoconfigureAddress: bool publish: bool immortal: bool age: uint32 origin: uint32 GETBESTROUTE2 = proc(InterfaceLuid: ptr uint64, InterfaceIndex: uint32, SourceAddress: ptr SOCKADDR_INET, DestinationAddress: ptr SOCKADDR_INET, AddressSortOptions: uint32, BestRoute: ptr MibIpForwardRow2, BestSourceAddress: ptr SOCKADDR_INET): DWORD {. gcsafe, stdcall.} proc toInterfaceType(ft: uint32): InterfaceType {.inline.} = if (ft >= 1'u32 and ft <= 196'u32) or (ft == 237) or (ft == 243) or (ft == 244) or (ft == 259) or (ft == 281): result = cast[InterfaceType](ft) else: result = IfOther proc toInterfaceState(it: cint): InterfaceState {.inline.} = if it >= 1 and it <= 7: result = cast[InterfaceState](it) else: result = StatusUnknown proc GetAdaptersAddresses(family: uint32, flags: uint32, reserved: pointer, addresses: ptr IpAdapterAddressesXp, sizeptr: ptr uint32): uint32 {. stdcall, dynlib: "iphlpapi", importc: "GetAdaptersAddresses".} proc WideCharToMultiByte(CodePage: uint32, dwFlags: uint32, lpWideCharStr: ptr WCHAR, cchWideChar: cint, lpMultiByteStr: ptr char, cbMultiByte: cint, lpDefaultChar: ptr char, lpUsedDefaultChar: ptr uint32): cint {.stdcall, dynlib: "kernel32.dll", importc: "WideCharToMultiByte".} proc getBestRouteXp(dwDestAddr: uint32, dwSourceAddr: uint32, pBestRoute: ptr MibIpForwardRow): uint32 {. stdcall, dynlib: "iphlpapi", importc: "GetBestRoute".} proc `$`(bstr: ptr WCHAR): string = var buffer: char var count = WideCharToMultiByte(CP_UTF8, 0, bstr, -1, addr(buffer), 0, nil, nil) if count > 0: result = newString(count + 8) let res = WideCharToMultiByte(CP_UTF8, 0, bstr, -1, addr(result[0]), count, nil, nil) if res > 0: result.setLen(res - 1) else: result.setLen(0) proc isVista(): bool = var ver: OSVERSIONINFO ver.dwOSVersionInfoSize = DWORD(sizeof(ver)) let res = getVersionExW(addr(ver)) if res == 0: result = false else: result = (ver.dwMajorVersion >= 6) proc toIPv6(a: TransportAddress): TransportAddress = ## IPv4-mapped addresses are formed by: ## <80 bits of zeros> + <16 bits of ones> + <32-bit IPv4 address>. if a.family == AddressFamily.IPv4: result = TransportAddress(family: AddressFamily.IPv6) result.address_v6[10] = 0xFF'u8 result.address_v6[11] = 0xFF'u8 copyMem(addr result.address_v6[12], unsafeAddr a.address_v4[0], 4) elif a.family == AddressFamily.IPv6: result = a proc ipMatchPrefix(number, prefix: TransportAddress, nbits: int): bool = var num6, prefix6: TransportAddress if number.family == AddressFamily.IPv4: num6 = toIPv6(number) else: num6 = number if prefix.family == AddressFamily.IPv4: prefix6 = toIPv6(number) else: prefix6 = prefix var bytesCount = nbits div 8 var bitsCount = nbits mod 8 for i in 0..= 0: result.net = IpNet.init(result.host, prefixLength) else: let prefixLength = cast[int](ifunic.onLinkPrefixLength) if prefixLength >= 0: result.net = IpNet.init(result.host, prefixLength) proc getInterfaces*(): seq[NetworkInterface] = ## Return list of network interfaces. result = newSeq[NetworkInterface]() var size = WorkBufferSize var tries = 0 var buffer: seq[byte] var res: uint32 var vista = isVista() while true: buffer = newSeq[byte](size) var addresses = cast[ptr IpAdapterAddressesXp](addr buffer[0]) res = GetAdaptersAddresses(AF_UNSPEC, GAA_FLAG_INCLUDE_PREFIX, nil, addresses, addr size) if res == ERROR_SUCCESS: buffer.setLen(size) break elif res == ERROR_BUFFER_OVERFLOW: discard else: break inc(tries) if tries >= MaxTries: break if res == ERROR_SUCCESS: var slider = cast[ptr IpAdapterAddressesXp](addr buffer[0]) while not isNil(slider): var iface = NetworkInterface( ifIndex: cast[int](slider.ifIndex), ifType: toInterfaceType(slider.ifType), state: toInterfaceState(slider.operStatus), name: $slider.adapterName, desc: $slider.description, mtu: cast[int](slider.mtu), maclen: cast[int](slider.physicalAddressLength), flags: cast[uint64](slider.flags) ) copyMem(addr iface.mac[0], addr slider.physicalAddress[0], len(iface.mac)) var unicast = slider.unicastAddress while not isNil(unicast): var ifaddr = processAddress(slider, unicast, vista) iface.addresses.add(ifaddr) unicast = unicast.next result.add(iface) slider = slider.next sort(result, cmp) proc getBestRoute*(address: TransportAddress): Route = ## Return best applicable OS route, which will be used for connecting to ## address ``address``. if isVista(): let iph = loadLib("iphlpapi.dll") if iph != nil: var bestRoute: MibIpForwardRow2 var empty: TransportAddress var dest, src: Sockaddr_storage var luid: uint64 var destlen: Socklen address.toSAddr(dest, destlen) var getBestRoute2 = cast[GETBESTROUTE2](symAddr(iph, "GetBestRoute2")) var res = getBestRoute2(addr luid, 0'u32, nil, cast[ptr SOCKADDR_INET](addr dest), 0'u32, addr bestRoute, cast[ptr SOCKADDR_INET](addr src)) if res == 0: if src.ss_family == winlean.AF_INET: fromSAddr(addr src, Socklen(sizeof(Sockaddr_in)), result.source) elif src.ss_family == winlean.AF_INET6: fromSAddr(addr src, Socklen(sizeof(Sockaddr_in6)), result.source) if bestRoute.nextHop.si_family == winlean.AF_INET: fromSAddr(cast[ptr Sockaddr_storage](addr bestRoute.nextHop), Socklen(sizeof(Sockaddr_in)), result.gateway) elif bestRoute.nextHop.si_family == winlean.AF_INET6: fromSAddr(cast[ptr Sockaddr_storage](addr bestRoute.nextHop), Socklen(sizeof(Sockaddr_in6)), result.gateway) if result.gateway.isZero(): result.gateway = empty result.dest = address result.ifIndex = int(bestRoute.interfaceIndex) result.metric = int(bestRoute.metric) else: if address.family == AddressFamily.IPv4: var bestRoute: MibIpForwardRow var dest: uint32 copyMem(addr dest, unsafeAddr address.address_v4[0], 4) let res = getBestRouteXp(dest, 0'u32, addr bestRoute) if res == 0: var interfaces = getInterfaces() result.dest = address if bestRoute.dwForwardNextHop != 0'u32: result.gateway = TransportAddress(family: AddressFamily.IPv4) copyMem(addr result.gateway.address_v4[0], addr bestRoute.dwForwardNextHop, 4) result.metric = int(bestRoute.dwForwardMetric1) result.ifIndex = int(bestRoute.dwForwardIfIndex) for item in interfaces: if item.ifIndex == int(bestRoute.dwForwardIfIndex): for a in item.addresses: if a.host.family == AddressFamily.IPv4: result.source = a.host break else: {.fatal: "Sorry, your OS is currently not supported!".}