package netlink import ( "encoding/binary" "fmt" "io" "math/rand" "net" "os" "sync/atomic" "syscall" "time" "unsafe" ) const ( IFNAMSIZ = 16 DEFAULT_CHANGE = 0xFFFFFFFF IFLA_INFO_KIND = 1 IFLA_INFO_DATA = 2 VETH_INFO_PEER = 1 IFLA_MACVLAN_MODE = 1 IFLA_VLAN_ID = 1 IFLA_NET_NS_FD = 28 IFLA_ADDRESS = 1 IFLA_BRPORT_MODE = 4 SIOC_BRADDBR = 0x89a0 SIOC_BRDELBR = 0x89a1 SIOC_BRADDIF = 0x89a2 SIOC_BRDELIF = 0x89a3 ) const ( MACVLAN_MODE_PRIVATE = 1 << iota MACVLAN_MODE_VEPA MACVLAN_MODE_BRIDGE MACVLAN_MODE_PASSTHRU ) var nextSeqNr uint32 type ifreqHwaddr struct { IfrnName [IFNAMSIZ]byte IfruHwaddr syscall.RawSockaddr } type ifreqIndex struct { IfrnName [IFNAMSIZ]byte IfruIndex int32 } type ifreqFlags struct { IfrnName [IFNAMSIZ]byte Ifruflags uint16 } var native binary.ByteOrder var rnd = rand.New(rand.NewSource(time.Now().UnixNano())) func init() { var x uint32 = 0x01020304 if *(*byte)(unsafe.Pointer(&x)) == 0x01 { native = binary.BigEndian } else { native = binary.LittleEndian } } func getIpFamily(ip net.IP) int { if len(ip) <= net.IPv4len { return syscall.AF_INET } if ip.To4() != nil { return syscall.AF_INET } return syscall.AF_INET6 } type NetlinkRequestData interface { Len() int ToWireFormat() []byte } type IfInfomsg struct { syscall.IfInfomsg } func newIfInfomsg(family int) *IfInfomsg { return &IfInfomsg{ IfInfomsg: syscall.IfInfomsg{ Family: uint8(family), }, } } func newIfInfomsgChild(parent *RtAttr, family int) *IfInfomsg { msg := newIfInfomsg(family) parent.children = append(parent.children, msg) return msg } func (msg *IfInfomsg) ToWireFormat() []byte { length := syscall.SizeofIfInfomsg b := make([]byte, length) b[0] = msg.Family b[1] = 0 native.PutUint16(b[2:4], msg.Type) native.PutUint32(b[4:8], uint32(msg.Index)) native.PutUint32(b[8:12], msg.Flags) native.PutUint32(b[12:16], msg.Change) return b } func (msg *IfInfomsg) Len() int { return syscall.SizeofIfInfomsg } type IfAddrmsg struct { syscall.IfAddrmsg } func newIfAddrmsg(family int) *IfAddrmsg { return &IfAddrmsg{ IfAddrmsg: syscall.IfAddrmsg{ Family: uint8(family), }, } } func (msg *IfAddrmsg) ToWireFormat() []byte { length := syscall.SizeofIfAddrmsg b := make([]byte, length) b[0] = msg.Family b[1] = msg.Prefixlen b[2] = msg.Flags b[3] = msg.Scope native.PutUint32(b[4:8], msg.Index) return b } func (msg *IfAddrmsg) Len() int { return syscall.SizeofIfAddrmsg } type RtMsg struct { syscall.RtMsg } func newRtMsg() *RtMsg { return &RtMsg{ RtMsg: syscall.RtMsg{ Table: syscall.RT_TABLE_MAIN, Scope: syscall.RT_SCOPE_UNIVERSE, Protocol: syscall.RTPROT_BOOT, Type: syscall.RTN_UNICAST, }, } } func (msg *RtMsg) ToWireFormat() []byte { length := syscall.SizeofRtMsg b := make([]byte, length) b[0] = msg.Family b[1] = msg.Dst_len b[2] = msg.Src_len b[3] = msg.Tos b[4] = msg.Table b[5] = msg.Protocol b[6] = msg.Scope b[7] = msg.Type native.PutUint32(b[8:12], msg.Flags) return b } func (msg *RtMsg) Len() int { return syscall.SizeofRtMsg } func rtaAlignOf(attrlen int) int { return (attrlen + syscall.RTA_ALIGNTO - 1) & ^(syscall.RTA_ALIGNTO - 1) } type RtAttr struct { syscall.RtAttr Data []byte children []NetlinkRequestData } func newRtAttr(attrType int, data []byte) *RtAttr { return &RtAttr{ RtAttr: syscall.RtAttr{ Type: uint16(attrType), }, children: []NetlinkRequestData{}, Data: data, } } func newRtAttrChild(parent *RtAttr, attrType int, data []byte) *RtAttr { attr := newRtAttr(attrType, data) parent.children = append(parent.children, attr) return attr } func (a *RtAttr) Len() int { if len(a.children) == 0 { return (syscall.SizeofRtAttr + len(a.Data)) } l := 0 for _, child := range a.children { l += child.Len() } l += syscall.SizeofRtAttr return rtaAlignOf(l + len(a.Data)) } func (a *RtAttr) ToWireFormat() []byte { length := a.Len() buf := make([]byte, rtaAlignOf(length)) if a.Data != nil { copy(buf[4:], a.Data) } else { next := 4 for _, child := range a.children { childBuf := child.ToWireFormat() copy(buf[next:], childBuf) next += rtaAlignOf(len(childBuf)) } } if l := uint16(length); l != 0 { native.PutUint16(buf[0:2], l) } native.PutUint16(buf[2:4], a.Type) return buf } func uint32Attr(t int, n uint32) *RtAttr { buf := make([]byte, 4) native.PutUint32(buf, n) return newRtAttr(t, buf) } type NetlinkRequest struct { syscall.NlMsghdr Data []NetlinkRequestData } func (rr *NetlinkRequest) ToWireFormat() []byte { length := rr.Len dataBytes := make([][]byte, len(rr.Data)) for i, data := range rr.Data { dataBytes[i] = data.ToWireFormat() length += uint32(len(dataBytes[i])) } b := make([]byte, length) native.PutUint32(b[0:4], length) native.PutUint16(b[4:6], rr.Type) native.PutUint16(b[6:8], rr.Flags) native.PutUint32(b[8:12], rr.Seq) native.PutUint32(b[12:16], rr.Pid) next := 16 for _, data := range dataBytes { copy(b[next:], data) next += len(data) } return b } func (rr *NetlinkRequest) AddData(data NetlinkRequestData) { if data != nil { rr.Data = append(rr.Data, data) } } func newNetlinkRequest(proto, flags int) *NetlinkRequest { return &NetlinkRequest{ NlMsghdr: syscall.NlMsghdr{ Len: uint32(syscall.NLMSG_HDRLEN), Type: uint16(proto), Flags: syscall.NLM_F_REQUEST | uint16(flags), Seq: atomic.AddUint32(&nextSeqNr, 1), }, } } type NetlinkSocket struct { fd int lsa syscall.SockaddrNetlink } func getNetlinkSocket() (*NetlinkSocket, error) { fd, err := syscall.Socket(syscall.AF_NETLINK, syscall.SOCK_RAW, syscall.NETLINK_ROUTE) if err != nil { return nil, err } s := &NetlinkSocket{ fd: fd, } s.lsa.Family = syscall.AF_NETLINK if err := syscall.Bind(fd, &s.lsa); err != nil { syscall.Close(fd) return nil, err } return s, nil } func (s *NetlinkSocket) Close() { syscall.Close(s.fd) } func (s *NetlinkSocket) Send(request *NetlinkRequest) error { if err := syscall.Sendto(s.fd, request.ToWireFormat(), 0, &s.lsa); err != nil { return err } return nil } func (s *NetlinkSocket) Receive() ([]syscall.NetlinkMessage, error) { rb := make([]byte, syscall.Getpagesize()) nr, _, err := syscall.Recvfrom(s.fd, rb, 0) if err != nil { return nil, err } if nr < syscall.NLMSG_HDRLEN { return nil, ErrShortResponse } rb = rb[:nr] return syscall.ParseNetlinkMessage(rb) } func (s *NetlinkSocket) GetPid() (uint32, error) { lsa, err := syscall.Getsockname(s.fd) if err != nil { return 0, err } switch v := lsa.(type) { case *syscall.SockaddrNetlink: return v.Pid, nil } return 0, ErrWrongSockType } func (s *NetlinkSocket) CheckMessage(m syscall.NetlinkMessage, seq, pid uint32) error { if m.Header.Seq != seq { return fmt.Errorf("netlink: invalid seq %d, expected %d", m.Header.Seq, seq) } if m.Header.Pid != pid { return fmt.Errorf("netlink: wrong pid %d, expected %d", m.Header.Pid, pid) } if m.Header.Type == syscall.NLMSG_DONE { return io.EOF } if m.Header.Type == syscall.NLMSG_ERROR { e := int32(native.Uint32(m.Data[0:4])) if e == 0 { return io.EOF } return syscall.Errno(-e) } return nil } func (s *NetlinkSocket) HandleAck(seq uint32) error { pid, err := s.GetPid() if err != nil { return err } outer: for { msgs, err := s.Receive() if err != nil { return err } for _, m := range msgs { if err := s.CheckMessage(m, seq, pid); err != nil { if err == io.EOF { break outer } return err } } } return nil } func zeroTerminated(s string) []byte { return []byte(s + "\000") } func nonZeroTerminated(s string) []byte { return []byte(s) } // Add a new network link of a specified type. // This is identical to running: ip link add $name type $linkType func NetworkLinkAdd(name string, linkType string) error { if name == "" || linkType == "" { return fmt.Errorf("Neither link name nor link type can be empty!") } s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() wb := newNetlinkRequest(syscall.RTM_NEWLINK, syscall.NLM_F_CREATE|syscall.NLM_F_EXCL|syscall.NLM_F_ACK) msg := newIfInfomsg(syscall.AF_UNSPEC) wb.AddData(msg) linkInfo := newRtAttr(syscall.IFLA_LINKINFO, nil) newRtAttrChild(linkInfo, IFLA_INFO_KIND, nonZeroTerminated(linkType)) wb.AddData(linkInfo) nameData := newRtAttr(syscall.IFLA_IFNAME, zeroTerminated(name)) wb.AddData(nameData) if err := s.Send(wb); err != nil { return err } return s.HandleAck(wb.Seq) } // Delete a network link. // This is identical to running: ip link del $name func NetworkLinkDel(name string) error { if name == "" { return fmt.Errorf("Network link name can not be empty!") } s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() iface, err := net.InterfaceByName(name) if err != nil { return err } wb := newNetlinkRequest(syscall.RTM_DELLINK, syscall.NLM_F_ACK) msg := newIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(iface.Index) wb.AddData(msg) if err := s.Send(wb); err != nil { return err } return s.HandleAck(wb.Seq) } // Bring up a particular network interface. // This is identical to running: ip link set dev $name up func NetworkLinkUp(iface *net.Interface) error { s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() wb := newNetlinkRequest(syscall.RTM_NEWLINK, syscall.NLM_F_ACK) msg := newIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(iface.Index) msg.Flags = syscall.IFF_UP msg.Change = syscall.IFF_UP wb.AddData(msg) if err := s.Send(wb); err != nil { return err } return s.HandleAck(wb.Seq) } // Bring down a particular network interface. // This is identical to running: ip link set $name down func NetworkLinkDown(iface *net.Interface) error { s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() wb := newNetlinkRequest(syscall.RTM_NEWLINK, syscall.NLM_F_ACK) msg := newIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(iface.Index) msg.Flags = 0 & ^syscall.IFF_UP msg.Change = DEFAULT_CHANGE wb.AddData(msg) if err := s.Send(wb); err != nil { return err } return s.HandleAck(wb.Seq) } // Set link layer address ie. MAC Address. // This is identical to running: ip link set dev $name address $macaddress func NetworkSetMacAddress(iface *net.Interface, macaddr string) error { s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() hwaddr, err := net.ParseMAC(macaddr) if err != nil { return err } var ( MULTICAST byte = 0x1 ) if hwaddr[0]&0x1 == MULTICAST { return fmt.Errorf("Multicast MAC Address is not supported: %s", macaddr) } wb := newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := newIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(iface.Index) msg.Change = DEFAULT_CHANGE wb.AddData(msg) macdata := make([]byte, 6) copy(macdata, hwaddr) data := newRtAttr(IFLA_ADDRESS, macdata) wb.AddData(data) if err := s.Send(wb); err != nil { return err } return s.HandleAck(wb.Seq) } // Set link Maximum Transmission Unit // This is identical to running: ip link set dev $name mtu $MTU // bridge is a bitch here https://bugs.debian.org/cgi-bin/bugreport.cgi?bug=292088 // https://bugzilla.redhat.com/show_bug.cgi?id=697021 // There is a discussion about how to deal with ifcs joining bridge with MTU > 1500 // Regular network nterfaces do seem to work though! func NetworkSetMTU(iface *net.Interface, mtu int) error { s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() wb := newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := newIfInfomsg(syscall.AF_UNSPEC) msg.Type = syscall.RTM_SETLINK msg.Flags = syscall.NLM_F_REQUEST msg.Index = int32(iface.Index) msg.Change = DEFAULT_CHANGE wb.AddData(msg) wb.AddData(uint32Attr(syscall.IFLA_MTU, uint32(mtu))) if err := s.Send(wb); err != nil { return err } return s.HandleAck(wb.Seq) } // Set link queue length // This is identical to running: ip link set dev $name txqueuelen $QLEN func NetworkSetTxQueueLen(iface *net.Interface, txQueueLen int) error { s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() wb := newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := newIfInfomsg(syscall.AF_UNSPEC) msg.Type = syscall.RTM_SETLINK msg.Flags = syscall.NLM_F_REQUEST msg.Index = int32(iface.Index) msg.Change = DEFAULT_CHANGE wb.AddData(msg) wb.AddData(uint32Attr(syscall.IFLA_TXQLEN, uint32(txQueueLen))) if err := s.Send(wb); err != nil { return err } return s.HandleAck(wb.Seq) } func networkMasterAction(iface *net.Interface, rtattr *RtAttr) error { s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() wb := newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := newIfInfomsg(syscall.AF_UNSPEC) msg.Type = syscall.RTM_SETLINK msg.Flags = syscall.NLM_F_REQUEST msg.Index = int32(iface.Index) msg.Change = DEFAULT_CHANGE wb.AddData(msg) wb.AddData(rtattr) if err := s.Send(wb); err != nil { return err } return s.HandleAck(wb.Seq) } // Add an interface to bridge. // This is identical to running: ip link set $name master $master func NetworkSetMaster(iface, master *net.Interface) error { data := uint32Attr(syscall.IFLA_MASTER, uint32(master.Index)) return networkMasterAction(iface, data) } // Remove an interface from the bridge // This is is identical to to running: ip link $name set nomaster func NetworkSetNoMaster(iface *net.Interface) error { data := uint32Attr(syscall.IFLA_MASTER, 0) return networkMasterAction(iface, data) } func networkSetNsAction(iface *net.Interface, rtattr *RtAttr) error { s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() wb := newNetlinkRequest(syscall.RTM_NEWLINK, syscall.NLM_F_ACK) msg := newIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(iface.Index) wb.AddData(msg) wb.AddData(rtattr) if err := s.Send(wb); err != nil { return err } return s.HandleAck(wb.Seq) } // Move a particular network interface to a particular network namespace // specified by PID. This is identical to running: ip link set dev $name netns $pid func NetworkSetNsPid(iface *net.Interface, nspid int) error { data := uint32Attr(syscall.IFLA_NET_NS_PID, uint32(nspid)) return networkSetNsAction(iface, data) } // Move a particular network interface to a particular mounted // network namespace specified by file descriptor. // This is idential to running: ip link set dev $name netns $fd func NetworkSetNsFd(iface *net.Interface, fd int) error { data := uint32Attr(IFLA_NET_NS_FD, uint32(fd)) return networkSetNsAction(iface, data) } // Rename a particular interface to a different name // !!! Note that you can't rename an active interface. You need to bring it down before renaming it. // This is identical to running: ip link set dev ${oldName} name ${newName} func NetworkChangeName(iface *net.Interface, newName string) error { if len(newName) >= IFNAMSIZ { return fmt.Errorf("Interface name %s too long", newName) } s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() wb := newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := newIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(iface.Index) msg.Change = DEFAULT_CHANGE wb.AddData(msg) nameData := newRtAttr(syscall.IFLA_IFNAME, zeroTerminated(newName)) wb.AddData(nameData) if err := s.Send(wb); err != nil { return err } return s.HandleAck(wb.Seq) } // Add a new VETH pair link on the host // This is identical to running: ip link add name $name type veth peer name $peername func NetworkCreateVethPair(name1, name2 string, txQueueLen int) error { s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() wb := newNetlinkRequest(syscall.RTM_NEWLINK, syscall.NLM_F_CREATE|syscall.NLM_F_EXCL|syscall.NLM_F_ACK) msg := newIfInfomsg(syscall.AF_UNSPEC) wb.AddData(msg) nameData := newRtAttr(syscall.IFLA_IFNAME, zeroTerminated(name1)) wb.AddData(nameData) txqLen := make([]byte, 4) native.PutUint32(txqLen, uint32(txQueueLen)) txqData := newRtAttr(syscall.IFLA_TXQLEN, txqLen) wb.AddData(txqData) nest1 := newRtAttr(syscall.IFLA_LINKINFO, nil) newRtAttrChild(nest1, IFLA_INFO_KIND, zeroTerminated("veth")) nest2 := newRtAttrChild(nest1, IFLA_INFO_DATA, nil) nest3 := newRtAttrChild(nest2, VETH_INFO_PEER, nil) newIfInfomsgChild(nest3, syscall.AF_UNSPEC) newRtAttrChild(nest3, syscall.IFLA_IFNAME, zeroTerminated(name2)) txqLen2 := make([]byte, 4) native.PutUint32(txqLen2, uint32(txQueueLen)) newRtAttrChild(nest3, syscall.IFLA_TXQLEN, txqLen2) wb.AddData(nest1) if err := s.Send(wb); err != nil { return err } if err := s.HandleAck(wb.Seq); err != nil { if os.IsExist(err) { return ErrInterfaceExists } return err } return nil } // Add a new VLAN interface with masterDev as its upper device // This is identical to running: // ip link add name $name link $masterdev type vlan id $id func NetworkLinkAddVlan(masterDev, vlanDev string, vlanId uint16) error { s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() wb := newNetlinkRequest(syscall.RTM_NEWLINK, syscall.NLM_F_CREATE|syscall.NLM_F_EXCL|syscall.NLM_F_ACK) masterDevIfc, err := net.InterfaceByName(masterDev) if err != nil { return err } msg := newIfInfomsg(syscall.AF_UNSPEC) wb.AddData(msg) nest1 := newRtAttr(syscall.IFLA_LINKINFO, nil) newRtAttrChild(nest1, IFLA_INFO_KIND, nonZeroTerminated("vlan")) nest2 := newRtAttrChild(nest1, IFLA_INFO_DATA, nil) vlanData := make([]byte, 2) native.PutUint16(vlanData, vlanId) newRtAttrChild(nest2, IFLA_VLAN_ID, vlanData) wb.AddData(nest1) wb.AddData(uint32Attr(syscall.IFLA_LINK, uint32(masterDevIfc.Index))) wb.AddData(newRtAttr(syscall.IFLA_IFNAME, zeroTerminated(vlanDev))) if err := s.Send(wb); err != nil { return err } return s.HandleAck(wb.Seq) } // MacVlan link has LowerDev, UpperDev and operates in Mode mode // This simplifies the code when creating MacVlan or MacVtap interface type MacVlanLink struct { MasterDev string SlaveDev string mode string } func (m MacVlanLink) Mode() uint32 { modeMap := map[string]uint32{ "private": MACVLAN_MODE_PRIVATE, "vepa": MACVLAN_MODE_VEPA, "bridge": MACVLAN_MODE_BRIDGE, "passthru": MACVLAN_MODE_PASSTHRU, } return modeMap[m.mode] } // Add MAC VLAN network interface with masterDev as its upper device // This is identical to running: // ip link add name $name link $masterdev type macvlan mode $mode func networkLinkMacVlan(dev_type string, mcvln *MacVlanLink) error { s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() wb := newNetlinkRequest(syscall.RTM_NEWLINK, syscall.NLM_F_CREATE|syscall.NLM_F_EXCL|syscall.NLM_F_ACK) masterDevIfc, err := net.InterfaceByName(mcvln.MasterDev) if err != nil { return err } msg := newIfInfomsg(syscall.AF_UNSPEC) wb.AddData(msg) nest1 := newRtAttr(syscall.IFLA_LINKINFO, nil) newRtAttrChild(nest1, IFLA_INFO_KIND, nonZeroTerminated(dev_type)) nest2 := newRtAttrChild(nest1, IFLA_INFO_DATA, nil) macVlanData := make([]byte, 4) native.PutUint32(macVlanData, mcvln.Mode()) newRtAttrChild(nest2, IFLA_MACVLAN_MODE, macVlanData) wb.AddData(nest1) wb.AddData(uint32Attr(syscall.IFLA_LINK, uint32(masterDevIfc.Index))) wb.AddData(newRtAttr(syscall.IFLA_IFNAME, zeroTerminated(mcvln.SlaveDev))) if err := s.Send(wb); err != nil { return err } return s.HandleAck(wb.Seq) } func NetworkLinkAddMacVlan(masterDev, macVlanDev string, mode string) error { return networkLinkMacVlan("macvlan", &MacVlanLink{ MasterDev: masterDev, SlaveDev: macVlanDev, mode: mode, }) } func NetworkLinkAddMacVtap(masterDev, macVlanDev string, mode string) error { return networkLinkMacVlan("macvtap", &MacVlanLink{ MasterDev: masterDev, SlaveDev: macVlanDev, mode: mode, }) } func networkLinkIpAction(action, flags int, ifa IfAddr) error { s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() family := getIpFamily(ifa.IP) wb := newNetlinkRequest(action, flags) msg := newIfAddrmsg(family) msg.Index = uint32(ifa.Iface.Index) prefixLen, _ := ifa.IPNet.Mask.Size() msg.Prefixlen = uint8(prefixLen) wb.AddData(msg) var ipData []byte if family == syscall.AF_INET { ipData = ifa.IP.To4() } else { ipData = ifa.IP.To16() } localData := newRtAttr(syscall.IFA_LOCAL, ipData) wb.AddData(localData) addrData := newRtAttr(syscall.IFA_ADDRESS, ipData) wb.AddData(addrData) if err := s.Send(wb); err != nil { return err } return s.HandleAck(wb.Seq) } // Delete an IP address from an interface. This is identical to: // ip addr del $ip/$ipNet dev $iface func NetworkLinkDelIp(iface *net.Interface, ip net.IP, ipNet *net.IPNet) error { return networkLinkIpAction( syscall.RTM_DELADDR, syscall.NLM_F_ACK, IfAddr{iface, ip, ipNet}, ) } // Add an Ip address to an interface. This is identical to: // ip addr add $ip/$ipNet dev $iface func NetworkLinkAddIp(iface *net.Interface, ip net.IP, ipNet *net.IPNet) error { return networkLinkIpAction( syscall.RTM_NEWADDR, syscall.NLM_F_CREATE|syscall.NLM_F_EXCL|syscall.NLM_F_ACK, IfAddr{iface, ip, ipNet}, ) } // Returns an array of IPNet for all the currently routed subnets on ipv4 // This is similar to the first column of "ip route" output func NetworkGetRoutes() ([]Route, error) { s, err := getNetlinkSocket() if err != nil { return nil, err } defer s.Close() wb := newNetlinkRequest(syscall.RTM_GETROUTE, syscall.NLM_F_DUMP) msg := newIfInfomsg(syscall.AF_UNSPEC) wb.AddData(msg) if err := s.Send(wb); err != nil { return nil, err } pid, err := s.GetPid() if err != nil { return nil, err } res := make([]Route, 0) outer: for { msgs, err := s.Receive() if err != nil { return nil, err } for _, m := range msgs { if err := s.CheckMessage(m, wb.Seq, pid); err != nil { if err == io.EOF { break outer } return nil, err } if m.Header.Type != syscall.RTM_NEWROUTE { continue } var r Route msg := (*RtMsg)(unsafe.Pointer(&m.Data[0:syscall.SizeofRtMsg][0])) if msg.Flags&syscall.RTM_F_CLONED != 0 { // Ignore cloned routes continue } if msg.Table != syscall.RT_TABLE_MAIN { // Ignore non-main tables continue } if msg.Family != syscall.AF_INET { // Ignore non-ipv4 routes continue } if msg.Dst_len == 0 { // Default routes r.Default = true } attrs, err := syscall.ParseNetlinkRouteAttr(&m) if err != nil { return nil, err } for _, attr := range attrs { switch attr.Attr.Type { case syscall.RTA_DST: ip := attr.Value r.IPNet = &net.IPNet{ IP: ip, Mask: net.CIDRMask(int(msg.Dst_len), 8*len(ip)), } case syscall.RTA_OIF: index := int(native.Uint32(attr.Value[0:4])) r.Iface, _ = net.InterfaceByIndex(index) } } if r.Default || r.IPNet != nil { res = append(res, r) } } } return res, nil } // Add a new route table entry. func AddRoute(destination, source, gateway, device string) error { if destination == "" && source == "" && gateway == "" { return fmt.Errorf("one of destination, source or gateway must not be blank") } s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() wb := newNetlinkRequest(syscall.RTM_NEWROUTE, syscall.NLM_F_CREATE|syscall.NLM_F_EXCL|syscall.NLM_F_ACK) msg := newRtMsg() currentFamily := -1 var rtAttrs []*RtAttr if destination != "" { destIP, destNet, err := net.ParseCIDR(destination) if err != nil { return fmt.Errorf("destination CIDR %s couldn't be parsed", destination) } destFamily := getIpFamily(destIP) currentFamily = destFamily destLen, bits := destNet.Mask.Size() if destLen == 0 && bits == 0 { return fmt.Errorf("destination CIDR %s generated a non-canonical Mask", destination) } msg.Family = uint8(destFamily) msg.Dst_len = uint8(destLen) var destData []byte if destFamily == syscall.AF_INET { destData = destIP.To4() } else { destData = destIP.To16() } rtAttrs = append(rtAttrs, newRtAttr(syscall.RTA_DST, destData)) } if source != "" { srcIP := net.ParseIP(source) if srcIP == nil { return fmt.Errorf("source IP %s couldn't be parsed", source) } srcFamily := getIpFamily(srcIP) if currentFamily != -1 && currentFamily != srcFamily { return fmt.Errorf("source and destination ip were not the same IP family") } currentFamily = srcFamily msg.Family = uint8(srcFamily) var srcData []byte if srcFamily == syscall.AF_INET { srcData = srcIP.To4() } else { srcData = srcIP.To16() } rtAttrs = append(rtAttrs, newRtAttr(syscall.RTA_PREFSRC, srcData)) } if gateway != "" { gwIP := net.ParseIP(gateway) if gwIP == nil { return fmt.Errorf("gateway IP %s couldn't be parsed", gateway) } gwFamily := getIpFamily(gwIP) if currentFamily != -1 && currentFamily != gwFamily { return fmt.Errorf("gateway, source, and destination ip were not the same IP family") } msg.Family = uint8(gwFamily) var gwData []byte if gwFamily == syscall.AF_INET { gwData = gwIP.To4() } else { gwData = gwIP.To16() } rtAttrs = append(rtAttrs, newRtAttr(syscall.RTA_GATEWAY, gwData)) } wb.AddData(msg) for _, attr := range rtAttrs { wb.AddData(attr) } iface, err := net.InterfaceByName(device) if err != nil { return err } wb.AddData(uint32Attr(syscall.RTA_OIF, uint32(iface.Index))) if err := s.Send(wb); err != nil { return err } return s.HandleAck(wb.Seq) } // Add a new default gateway. Identical to: // ip route add default via $ip func AddDefaultGw(ip, device string) error { return AddRoute("", "", ip, device) } // THIS CODE DOES NOT COMMUNICATE WITH KERNEL VIA RTNETLINK INTERFACE // IT IS HERE FOR BACKWARDS COMPATIBILITY WITH OLDER LINUX KERNELS // WHICH SHIP WITH OLDER NOT ENTIRELY FUNCTIONAL VERSION OF NETLINK func getIfSocket() (fd int, err error) { for _, socket := range []int{ syscall.AF_INET, syscall.AF_PACKET, syscall.AF_INET6, } { if fd, err = syscall.Socket(socket, syscall.SOCK_DGRAM, 0); err == nil { break } } if err == nil { return fd, nil } return -1, err } // Create the actual bridge device. This is more backward-compatible than // netlink.NetworkLinkAdd and works on RHEL 6. func CreateBridge(name string, setMacAddr bool) error { if len(name) >= IFNAMSIZ { return fmt.Errorf("Interface name %s too long", name) } s, err := getIfSocket() if err != nil { return err } defer syscall.Close(s) nameBytePtr, err := syscall.BytePtrFromString(name) if err != nil { return err } if _, _, err := syscall.Syscall(syscall.SYS_IOCTL, uintptr(s), SIOC_BRADDBR, uintptr(unsafe.Pointer(nameBytePtr))); err != 0 { return err } if setMacAddr { return SetMacAddress(name, randMacAddr()) } return nil } // Delete the actual bridge device. func DeleteBridge(name string) error { s, err := getIfSocket() if err != nil { return err } defer syscall.Close(s) nameBytePtr, err := syscall.BytePtrFromString(name) if err != nil { return err } var ifr ifreqFlags copy(ifr.IfrnName[:len(ifr.IfrnName)-1], []byte(name)) if _, _, err := syscall.Syscall(syscall.SYS_IOCTL, uintptr(s), syscall.SIOCSIFFLAGS, uintptr(unsafe.Pointer(&ifr))); err != 0 { return err } if _, _, err := syscall.Syscall(syscall.SYS_IOCTL, uintptr(s), SIOC_BRDELBR, uintptr(unsafe.Pointer(nameBytePtr))); err != 0 { return err } return nil } func ifIoctBridge(iface, master *net.Interface, op uintptr) error { if len(master.Name) >= IFNAMSIZ { return fmt.Errorf("Interface name %s too long", master.Name) } s, err := getIfSocket() if err != nil { return err } defer syscall.Close(s) ifr := ifreqIndex{} copy(ifr.IfrnName[:len(ifr.IfrnName)-1], master.Name) ifr.IfruIndex = int32(iface.Index) if _, _, err := syscall.Syscall(syscall.SYS_IOCTL, uintptr(s), op, uintptr(unsafe.Pointer(&ifr))); err != 0 { return err } return nil } // Add a slave to a bridge device. This is more backward-compatible than // netlink.NetworkSetMaster and works on RHEL 6. func AddToBridge(iface, master *net.Interface) error { return ifIoctBridge(iface, master, SIOC_BRADDIF) } // Detach a slave from a bridge device. This is more backward-compatible than // netlink.NetworkSetMaster and works on RHEL 6. func DelFromBridge(iface, master *net.Interface) error { return ifIoctBridge(iface, master, SIOC_BRDELIF) } func randMacAddr() string { hw := make(net.HardwareAddr, 6) for i := 0; i < 6; i++ { hw[i] = byte(rnd.Intn(255)) } hw[0] &^= 0x1 // clear multicast bit hw[0] |= 0x2 // set local assignment bit (IEEE802) return hw.String() } func SetMacAddress(name, addr string) error { if len(name) >= IFNAMSIZ { return fmt.Errorf("Interface name %s too long", name) } hw, err := net.ParseMAC(addr) if err != nil { return err } s, err := getIfSocket() if err != nil { return err } defer syscall.Close(s) ifr := ifreqHwaddr{} ifr.IfruHwaddr.Family = syscall.ARPHRD_ETHER copy(ifr.IfrnName[:len(ifr.IfrnName)-1], name) for i := 0; i < 6; i++ { ifr.IfruHwaddr.Data[i] = ifrDataByte(hw[i]) } if _, _, err := syscall.Syscall(syscall.SYS_IOCTL, uintptr(s), syscall.SIOCSIFHWADDR, uintptr(unsafe.Pointer(&ifr))); err != 0 { return err } return nil } func SetHairpinMode(iface *net.Interface, enabled bool) error { s, err := getNetlinkSocket() if err != nil { return err } defer s.Close() req := newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := newIfInfomsg(syscall.AF_BRIDGE) msg.Type = syscall.RTM_SETLINK msg.Flags = syscall.NLM_F_REQUEST msg.Index = int32(iface.Index) msg.Change = DEFAULT_CHANGE req.AddData(msg) mode := []byte{0} if enabled { mode[0] = byte(1) } br := newRtAttr(syscall.IFLA_PROTINFO|syscall.NLA_F_NESTED, nil) newRtAttrChild(br, IFLA_BRPORT_MODE, mode) req.AddData(br) if err := s.Send(req); err != nil { return err } return s.HandleAck(req.Seq) } func ChangeName(iface *net.Interface, newName string) error { if len(newName) >= IFNAMSIZ { return fmt.Errorf("Interface name %s too long", newName) } fd, err := getIfSocket() if err != nil { return err } defer syscall.Close(fd) data := [IFNAMSIZ * 2]byte{} // the "-1"s here are very important for ensuring we get proper null // termination of our new C strings copy(data[:IFNAMSIZ-1], iface.Name) copy(data[IFNAMSIZ:IFNAMSIZ*2-1], newName) if _, _, errno := syscall.Syscall(syscall.SYS_IOCTL, uintptr(fd), syscall.SIOCSIFNAME, uintptr(unsafe.Pointer(&data[0]))); errno != 0 { return errno } return nil }