package netlink import ( "bytes" "encoding/binary" "fmt" "net" "os" "syscall" "unsafe" "github.com/vishvananda/netlink/nl" "github.com/vishvananda/netns" ) const ( SizeofLinkStats32 = 0x5c SizeofLinkStats64 = 0xd8 IFLA_STATS64 = 0x17 // syscall pkg does not contain this one ) const ( TUNTAP_MODE_TUN TuntapMode = syscall.IFF_TUN TUNTAP_MODE_TAP TuntapMode = syscall.IFF_TAP TUNTAP_DEFAULTS TuntapFlag = syscall.IFF_TUN_EXCL | syscall.IFF_ONE_QUEUE TUNTAP_VNET_HDR TuntapFlag = syscall.IFF_VNET_HDR TUNTAP_TUN_EXCL TuntapFlag = syscall.IFF_TUN_EXCL TUNTAP_NO_PI TuntapFlag = syscall.IFF_NO_PI TUNTAP_ONE_QUEUE TuntapFlag = syscall.IFF_ONE_QUEUE ) var lookupByDump = false var macvlanModes = [...]uint32{ 0, nl.MACVLAN_MODE_PRIVATE, nl.MACVLAN_MODE_VEPA, nl.MACVLAN_MODE_BRIDGE, nl.MACVLAN_MODE_PASSTHRU, nl.MACVLAN_MODE_SOURCE, } func ensureIndex(link *LinkAttrs) { if link != nil && link.Index == 0 { newlink, _ := LinkByName(link.Name) if newlink != nil { link.Index = newlink.Attrs().Index } } } func (h *Handle) ensureIndex(link *LinkAttrs) { if link != nil && link.Index == 0 { newlink, _ := h.LinkByName(link.Name) if newlink != nil { link.Index = newlink.Attrs().Index } } } func (h *Handle) LinkSetARPOff(link Link) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Change |= syscall.IFF_NOARP msg.Flags |= syscall.IFF_NOARP msg.Index = int32(base.Index) req.AddData(msg) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } func LinkSetARPOff(link Link) error { return pkgHandle.LinkSetARPOff(link) } func (h *Handle) LinkSetARPOn(link Link) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Change |= syscall.IFF_NOARP msg.Flags &= ^uint32(syscall.IFF_NOARP) msg.Index = int32(base.Index) req.AddData(msg) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } func LinkSetARPOn(link Link) error { return pkgHandle.LinkSetARPOn(link) } func (h *Handle) SetPromiscOn(link Link) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Change = syscall.IFF_PROMISC msg.Flags = syscall.IFF_UP msg.Index = int32(base.Index) req.AddData(msg) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } func SetPromiscOn(link Link) error { return pkgHandle.SetPromiscOn(link) } func (h *Handle) SetPromiscOff(link Link) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Change = syscall.IFF_PROMISC msg.Flags = 0 & ^syscall.IFF_UP msg.Index = int32(base.Index) req.AddData(msg) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } func SetPromiscOff(link Link) error { return pkgHandle.SetPromiscOff(link) } // LinkSetUp enables the link device. // Equivalent to: `ip link set $link up` func LinkSetUp(link Link) error { return pkgHandle.LinkSetUp(link) } // LinkSetUp enables the link device. // Equivalent to: `ip link set $link up` func (h *Handle) LinkSetUp(link Link) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_NEWLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Change = syscall.IFF_UP msg.Flags = syscall.IFF_UP msg.Index = int32(base.Index) req.AddData(msg) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } // LinkSetDown disables link device. // Equivalent to: `ip link set $link down` func LinkSetDown(link Link) error { return pkgHandle.LinkSetDown(link) } // LinkSetDown disables link device. // Equivalent to: `ip link set $link down` func (h *Handle) LinkSetDown(link Link) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_NEWLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Change = syscall.IFF_UP msg.Flags = 0 & ^syscall.IFF_UP msg.Index = int32(base.Index) req.AddData(msg) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } // LinkSetMTU sets the mtu of the link device. // Equivalent to: `ip link set $link mtu $mtu` func LinkSetMTU(link Link, mtu int) error { return pkgHandle.LinkSetMTU(link, mtu) } // LinkSetMTU sets the mtu of the link device. // Equivalent to: `ip link set $link mtu $mtu` func (h *Handle) LinkSetMTU(link Link, mtu int) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(base.Index) req.AddData(msg) b := make([]byte, 4) native.PutUint32(b, uint32(mtu)) data := nl.NewRtAttr(syscall.IFLA_MTU, b) req.AddData(data) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } // LinkSetName sets the name of the link device. // Equivalent to: `ip link set $link name $name` func LinkSetName(link Link, name string) error { return pkgHandle.LinkSetName(link, name) } // LinkSetName sets the name of the link device. // Equivalent to: `ip link set $link name $name` func (h *Handle) LinkSetName(link Link, name string) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(base.Index) req.AddData(msg) data := nl.NewRtAttr(syscall.IFLA_IFNAME, []byte(name)) req.AddData(data) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } // LinkSetAlias sets the alias of the link device. // Equivalent to: `ip link set dev $link alias $name` func LinkSetAlias(link Link, name string) error { return pkgHandle.LinkSetAlias(link, name) } // LinkSetAlias sets the alias of the link device. // Equivalent to: `ip link set dev $link alias $name` func (h *Handle) LinkSetAlias(link Link, name string) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(base.Index) req.AddData(msg) data := nl.NewRtAttr(syscall.IFLA_IFALIAS, []byte(name)) req.AddData(data) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } // LinkSetHardwareAddr sets the hardware address of the link device. // Equivalent to: `ip link set $link address $hwaddr` func LinkSetHardwareAddr(link Link, hwaddr net.HardwareAddr) error { return pkgHandle.LinkSetHardwareAddr(link, hwaddr) } // LinkSetHardwareAddr sets the hardware address of the link device. // Equivalent to: `ip link set $link address $hwaddr` func (h *Handle) LinkSetHardwareAddr(link Link, hwaddr net.HardwareAddr) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(base.Index) req.AddData(msg) data := nl.NewRtAttr(syscall.IFLA_ADDRESS, []byte(hwaddr)) req.AddData(data) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } // LinkSetVfHardwareAddr sets the hardware address of a vf for the link. // Equivalent to: `ip link set $link vf $vf mac $hwaddr` func LinkSetVfHardwareAddr(link Link, vf int, hwaddr net.HardwareAddr) error { return pkgHandle.LinkSetVfHardwareAddr(link, vf, hwaddr) } // LinkSetVfHardwareAddr sets the hardware address of a vf for the link. // Equivalent to: `ip link set $link vf $vf mac $hwaddr` func (h *Handle) LinkSetVfHardwareAddr(link Link, vf int, hwaddr net.HardwareAddr) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(base.Index) req.AddData(msg) data := nl.NewRtAttr(nl.IFLA_VFINFO_LIST, nil) info := nl.NewRtAttrChild(data, nl.IFLA_VF_INFO, nil) vfmsg := nl.VfMac{ Vf: uint32(vf), } copy(vfmsg.Mac[:], []byte(hwaddr)) nl.NewRtAttrChild(info, nl.IFLA_VF_MAC, vfmsg.Serialize()) req.AddData(data) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } // LinkSetVfVlan sets the vlan of a vf for the link. // Equivalent to: `ip link set $link vf $vf vlan $vlan` func LinkSetVfVlan(link Link, vf, vlan int) error { return pkgHandle.LinkSetVfVlan(link, vf, vlan) } // LinkSetVfVlan sets the vlan of a vf for the link. // Equivalent to: `ip link set $link vf $vf vlan $vlan` func (h *Handle) LinkSetVfVlan(link Link, vf, vlan int) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(base.Index) req.AddData(msg) data := nl.NewRtAttr(nl.IFLA_VFINFO_LIST, nil) info := nl.NewRtAttrChild(data, nl.IFLA_VF_INFO, nil) vfmsg := nl.VfVlan{ Vf: uint32(vf), Vlan: uint32(vlan), } nl.NewRtAttrChild(info, nl.IFLA_VF_VLAN, vfmsg.Serialize()) req.AddData(data) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } // LinkSetVfTxRate sets the tx rate of a vf for the link. // Equivalent to: `ip link set $link vf $vf rate $rate` func LinkSetVfTxRate(link Link, vf, rate int) error { return pkgHandle.LinkSetVfTxRate(link, vf, rate) } // LinkSetVfTxRate sets the tx rate of a vf for the link. // Equivalent to: `ip link set $link vf $vf rate $rate` func (h *Handle) LinkSetVfTxRate(link Link, vf, rate int) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(base.Index) req.AddData(msg) data := nl.NewRtAttr(nl.IFLA_VFINFO_LIST, nil) info := nl.NewRtAttrChild(data, nl.IFLA_VF_INFO, nil) vfmsg := nl.VfTxRate{ Vf: uint32(vf), Rate: uint32(rate), } nl.NewRtAttrChild(info, nl.IFLA_VF_TX_RATE, vfmsg.Serialize()) req.AddData(data) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } // LinkSetMaster sets the master of the link device. // Equivalent to: `ip link set $link master $master` func LinkSetMaster(link Link, master *Bridge) error { return pkgHandle.LinkSetMaster(link, master) } // LinkSetMaster sets the master of the link device. // Equivalent to: `ip link set $link master $master` func (h *Handle) LinkSetMaster(link Link, master *Bridge) error { index := 0 if master != nil { masterBase := master.Attrs() h.ensureIndex(masterBase) index = masterBase.Index } if index <= 0 { return fmt.Errorf("Device does not exist") } return h.LinkSetMasterByIndex(link, index) } // LinkSetNoMaster removes the master of the link device. // Equivalent to: `ip link set $link nomaster` func LinkSetNoMaster(link Link) error { return pkgHandle.LinkSetNoMaster(link) } // LinkSetNoMaster removes the master of the link device. // Equivalent to: `ip link set $link nomaster` func (h *Handle) LinkSetNoMaster(link Link) error { return h.LinkSetMasterByIndex(link, 0) } // LinkSetMasterByIndex sets the master of the link device. // Equivalent to: `ip link set $link master $master` func LinkSetMasterByIndex(link Link, masterIndex int) error { return pkgHandle.LinkSetMasterByIndex(link, masterIndex) } // LinkSetMasterByIndex sets the master of the link device. // Equivalent to: `ip link set $link master $master` func (h *Handle) LinkSetMasterByIndex(link Link, masterIndex int) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(base.Index) req.AddData(msg) b := make([]byte, 4) native.PutUint32(b, uint32(masterIndex)) data := nl.NewRtAttr(syscall.IFLA_MASTER, b) req.AddData(data) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } // LinkSetNsPid puts the device into a new network namespace. The // pid must be a pid of a running process. // Equivalent to: `ip link set $link netns $pid` func LinkSetNsPid(link Link, nspid int) error { return pkgHandle.LinkSetNsPid(link, nspid) } // LinkSetNsPid puts the device into a new network namespace. The // pid must be a pid of a running process. // Equivalent to: `ip link set $link netns $pid` func (h *Handle) LinkSetNsPid(link Link, nspid int) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(base.Index) req.AddData(msg) b := make([]byte, 4) native.PutUint32(b, uint32(nspid)) data := nl.NewRtAttr(syscall.IFLA_NET_NS_PID, b) req.AddData(data) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } // LinkSetNsFd puts the device into a new network namespace. The // fd must be an open file descriptor to a network namespace. // Similar to: `ip link set $link netns $ns` func LinkSetNsFd(link Link, fd int) error { return pkgHandle.LinkSetNsFd(link, fd) } // LinkSetNsFd puts the device into a new network namespace. The // fd must be an open file descriptor to a network namespace. // Similar to: `ip link set $link netns $ns` func (h *Handle) LinkSetNsFd(link Link, fd int) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(base.Index) req.AddData(msg) b := make([]byte, 4) native.PutUint32(b, uint32(fd)) data := nl.NewRtAttr(nl.IFLA_NET_NS_FD, b) req.AddData(data) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } // LinkSetXdpFd adds a bpf function to the driver. The fd must be a bpf // program loaded with bpf(type=BPF_PROG_TYPE_XDP) func LinkSetXdpFd(link Link, fd int) error { base := link.Attrs() ensureIndex(base) req := nl.NewNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(base.Index) req.AddData(msg) addXdpAttrs(&LinkXdp{Fd: fd}, req) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } func boolAttr(val bool) []byte { var v uint8 if val { v = 1 } return nl.Uint8Attr(v) } type vxlanPortRange struct { Lo, Hi uint16 } func addVxlanAttrs(vxlan *Vxlan, linkInfo *nl.RtAttr) { data := nl.NewRtAttrChild(linkInfo, nl.IFLA_INFO_DATA, nil) nl.NewRtAttrChild(data, nl.IFLA_VXLAN_ID, nl.Uint32Attr(uint32(vxlan.VxlanId))) if vxlan.VtepDevIndex != 0 { nl.NewRtAttrChild(data, nl.IFLA_VXLAN_LINK, nl.Uint32Attr(uint32(vxlan.VtepDevIndex))) } if vxlan.SrcAddr != nil { ip := vxlan.SrcAddr.To4() if ip != nil { nl.NewRtAttrChild(data, nl.IFLA_VXLAN_LOCAL, []byte(ip)) } else { ip = vxlan.SrcAddr.To16() if ip != nil { nl.NewRtAttrChild(data, nl.IFLA_VXLAN_LOCAL6, []byte(ip)) } } } if vxlan.Group != nil { group := vxlan.Group.To4() if group != nil { nl.NewRtAttrChild(data, nl.IFLA_VXLAN_GROUP, []byte(group)) } else { group = vxlan.Group.To16() if group != nil { nl.NewRtAttrChild(data, nl.IFLA_VXLAN_GROUP6, []byte(group)) } } } nl.NewRtAttrChild(data, nl.IFLA_VXLAN_TTL, nl.Uint8Attr(uint8(vxlan.TTL))) nl.NewRtAttrChild(data, nl.IFLA_VXLAN_TOS, nl.Uint8Attr(uint8(vxlan.TOS))) nl.NewRtAttrChild(data, nl.IFLA_VXLAN_LEARNING, boolAttr(vxlan.Learning)) nl.NewRtAttrChild(data, nl.IFLA_VXLAN_PROXY, boolAttr(vxlan.Proxy)) nl.NewRtAttrChild(data, nl.IFLA_VXLAN_RSC, boolAttr(vxlan.RSC)) nl.NewRtAttrChild(data, nl.IFLA_VXLAN_L2MISS, boolAttr(vxlan.L2miss)) nl.NewRtAttrChild(data, nl.IFLA_VXLAN_L3MISS, boolAttr(vxlan.L3miss)) if vxlan.UDPCSum { nl.NewRtAttrChild(data, nl.IFLA_VXLAN_UDP_CSUM, boolAttr(vxlan.UDPCSum)) } if vxlan.GBP { nl.NewRtAttrChild(data, nl.IFLA_VXLAN_GBP, []byte{}) } if vxlan.NoAge { nl.NewRtAttrChild(data, nl.IFLA_VXLAN_AGEING, nl.Uint32Attr(0)) } else if vxlan.Age > 0 { nl.NewRtAttrChild(data, nl.IFLA_VXLAN_AGEING, nl.Uint32Attr(uint32(vxlan.Age))) } if vxlan.Limit > 0 { nl.NewRtAttrChild(data, nl.IFLA_VXLAN_LIMIT, nl.Uint32Attr(uint32(vxlan.Limit))) } if vxlan.Port > 0 { nl.NewRtAttrChild(data, nl.IFLA_VXLAN_PORT, htons(uint16(vxlan.Port))) } if vxlan.PortLow > 0 || vxlan.PortHigh > 0 { pr := vxlanPortRange{uint16(vxlan.PortLow), uint16(vxlan.PortHigh)} buf := new(bytes.Buffer) binary.Write(buf, binary.BigEndian, &pr) nl.NewRtAttrChild(data, nl.IFLA_VXLAN_PORT_RANGE, buf.Bytes()) } } func addBondAttrs(bond *Bond, linkInfo *nl.RtAttr) { data := nl.NewRtAttrChild(linkInfo, nl.IFLA_INFO_DATA, nil) if bond.Mode >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_MODE, nl.Uint8Attr(uint8(bond.Mode))) } if bond.ActiveSlave >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_ACTIVE_SLAVE, nl.Uint32Attr(uint32(bond.ActiveSlave))) } if bond.Miimon >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_MIIMON, nl.Uint32Attr(uint32(bond.Miimon))) } if bond.UpDelay >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_UPDELAY, nl.Uint32Attr(uint32(bond.UpDelay))) } if bond.DownDelay >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_DOWNDELAY, nl.Uint32Attr(uint32(bond.DownDelay))) } if bond.UseCarrier >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_USE_CARRIER, nl.Uint8Attr(uint8(bond.UseCarrier))) } if bond.ArpInterval >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_ARP_INTERVAL, nl.Uint32Attr(uint32(bond.ArpInterval))) } if bond.ArpIpTargets != nil { msg := nl.NewRtAttrChild(data, nl.IFLA_BOND_ARP_IP_TARGET, nil) for i := range bond.ArpIpTargets { ip := bond.ArpIpTargets[i].To4() if ip != nil { nl.NewRtAttrChild(msg, i, []byte(ip)) continue } ip = bond.ArpIpTargets[i].To16() if ip != nil { nl.NewRtAttrChild(msg, i, []byte(ip)) } } } if bond.ArpValidate >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_ARP_VALIDATE, nl.Uint32Attr(uint32(bond.ArpValidate))) } if bond.ArpAllTargets >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_ARP_ALL_TARGETS, nl.Uint32Attr(uint32(bond.ArpAllTargets))) } if bond.Primary >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_PRIMARY, nl.Uint32Attr(uint32(bond.Primary))) } if bond.PrimaryReselect >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_PRIMARY_RESELECT, nl.Uint8Attr(uint8(bond.PrimaryReselect))) } if bond.FailOverMac >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_FAIL_OVER_MAC, nl.Uint8Attr(uint8(bond.FailOverMac))) } if bond.XmitHashPolicy >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_XMIT_HASH_POLICY, nl.Uint8Attr(uint8(bond.XmitHashPolicy))) } if bond.ResendIgmp >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_RESEND_IGMP, nl.Uint32Attr(uint32(bond.ResendIgmp))) } if bond.NumPeerNotif >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_NUM_PEER_NOTIF, nl.Uint8Attr(uint8(bond.NumPeerNotif))) } if bond.AllSlavesActive >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_ALL_SLAVES_ACTIVE, nl.Uint8Attr(uint8(bond.AllSlavesActive))) } if bond.MinLinks >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_MIN_LINKS, nl.Uint32Attr(uint32(bond.MinLinks))) } if bond.LpInterval >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_LP_INTERVAL, nl.Uint32Attr(uint32(bond.LpInterval))) } if bond.PackersPerSlave >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_PACKETS_PER_SLAVE, nl.Uint32Attr(uint32(bond.PackersPerSlave))) } if bond.LacpRate >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_AD_LACP_RATE, nl.Uint8Attr(uint8(bond.LacpRate))) } if bond.AdSelect >= 0 { nl.NewRtAttrChild(data, nl.IFLA_BOND_AD_SELECT, nl.Uint8Attr(uint8(bond.AdSelect))) } } // LinkAdd adds a new link device. The type and features of the device // are taken from the parameters in the link object. // Equivalent to: `ip link add $link` func LinkAdd(link Link) error { return pkgHandle.LinkAdd(link) } // LinkAdd adds a new link device. The type and features of the device // are taken fromt the parameters in the link object. // Equivalent to: `ip link add $link` func (h *Handle) LinkAdd(link Link) error { // TODO: set mtu and hardware address // TODO: support extra data for macvlan base := link.Attrs() if base.Name == "" { return fmt.Errorf("LinkAttrs.Name cannot be empty!") } if tuntap, ok := link.(*Tuntap); ok { // TODO: support user // TODO: support group // TODO: multi_queue // TODO: support non- persistent if tuntap.Mode < syscall.IFF_TUN || tuntap.Mode > syscall.IFF_TAP { return fmt.Errorf("Tuntap.Mode %v unknown!", tuntap.Mode) } file, err := os.OpenFile("/dev/net/tun", os.O_RDWR, 0) if err != nil { return err } defer file.Close() var req ifReq if tuntap.Flags == 0 { req.Flags = uint16(TUNTAP_DEFAULTS) } else { req.Flags = uint16(tuntap.Flags) } req.Flags |= uint16(tuntap.Mode) copy(req.Name[:15], base.Name) _, _, errno := syscall.Syscall(syscall.SYS_IOCTL, file.Fd(), uintptr(syscall.TUNSETIFF), uintptr(unsafe.Pointer(&req))) if errno != 0 { return fmt.Errorf("Tuntap IOCTL TUNSETIFF failed, errno %v", errno) } _, _, errno = syscall.Syscall(syscall.SYS_IOCTL, file.Fd(), uintptr(syscall.TUNSETPERSIST), 1) if errno != 0 { return fmt.Errorf("Tuntap IOCTL TUNSETPERSIST failed, errno %v", errno) } h.ensureIndex(base) // can't set master during create, so set it afterwards if base.MasterIndex != 0 { // TODO: verify MasterIndex is actually a bridge? return h.LinkSetMasterByIndex(link, base.MasterIndex) } return nil } req := h.newNetlinkRequest(syscall.RTM_NEWLINK, syscall.NLM_F_CREATE|syscall.NLM_F_EXCL|syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) // TODO: make it shorter if base.Flags&net.FlagUp != 0 { msg.Change = syscall.IFF_UP msg.Flags = syscall.IFF_UP } if base.Flags&net.FlagBroadcast != 0 { msg.Change |= syscall.IFF_BROADCAST msg.Flags |= syscall.IFF_BROADCAST } if base.Flags&net.FlagLoopback != 0 { msg.Change |= syscall.IFF_LOOPBACK msg.Flags |= syscall.IFF_LOOPBACK } if base.Flags&net.FlagPointToPoint != 0 { msg.Change |= syscall.IFF_POINTOPOINT msg.Flags |= syscall.IFF_POINTOPOINT } if base.Flags&net.FlagMulticast != 0 { msg.Change |= syscall.IFF_MULTICAST msg.Flags |= syscall.IFF_MULTICAST } req.AddData(msg) if base.ParentIndex != 0 { b := make([]byte, 4) native.PutUint32(b, uint32(base.ParentIndex)) data := nl.NewRtAttr(syscall.IFLA_LINK, b) req.AddData(data) } else if link.Type() == "ipvlan" { return fmt.Errorf("Can't create ipvlan link without ParentIndex") } nameData := nl.NewRtAttr(syscall.IFLA_IFNAME, nl.ZeroTerminated(base.Name)) req.AddData(nameData) if base.MTU > 0 { mtu := nl.NewRtAttr(syscall.IFLA_MTU, nl.Uint32Attr(uint32(base.MTU))) req.AddData(mtu) } if base.TxQLen >= 0 { qlen := nl.NewRtAttr(syscall.IFLA_TXQLEN, nl.Uint32Attr(uint32(base.TxQLen))) req.AddData(qlen) } if base.Namespace != nil { var attr *nl.RtAttr switch base.Namespace.(type) { case NsPid: val := nl.Uint32Attr(uint32(base.Namespace.(NsPid))) attr = nl.NewRtAttr(syscall.IFLA_NET_NS_PID, val) case NsFd: val := nl.Uint32Attr(uint32(base.Namespace.(NsFd))) attr = nl.NewRtAttr(nl.IFLA_NET_NS_FD, val) } req.AddData(attr) } if base.Xdp != nil { addXdpAttrs(base.Xdp, req) } linkInfo := nl.NewRtAttr(syscall.IFLA_LINKINFO, nil) nl.NewRtAttrChild(linkInfo, nl.IFLA_INFO_KIND, nl.NonZeroTerminated(link.Type())) if vlan, ok := link.(*Vlan); ok { b := make([]byte, 2) native.PutUint16(b, uint16(vlan.VlanId)) data := nl.NewRtAttrChild(linkInfo, nl.IFLA_INFO_DATA, nil) nl.NewRtAttrChild(data, nl.IFLA_VLAN_ID, b) } else if veth, ok := link.(*Veth); ok { data := nl.NewRtAttrChild(linkInfo, nl.IFLA_INFO_DATA, nil) peer := nl.NewRtAttrChild(data, nl.VETH_INFO_PEER, nil) nl.NewIfInfomsgChild(peer, syscall.AF_UNSPEC) nl.NewRtAttrChild(peer, syscall.IFLA_IFNAME, nl.ZeroTerminated(veth.PeerName)) if base.TxQLen >= 0 { nl.NewRtAttrChild(peer, syscall.IFLA_TXQLEN, nl.Uint32Attr(uint32(base.TxQLen))) } if base.MTU > 0 { nl.NewRtAttrChild(peer, syscall.IFLA_MTU, nl.Uint32Attr(uint32(base.MTU))) } } else if vxlan, ok := link.(*Vxlan); ok { addVxlanAttrs(vxlan, linkInfo) } else if bond, ok := link.(*Bond); ok { addBondAttrs(bond, linkInfo) } else if ipv, ok := link.(*IPVlan); ok { data := nl.NewRtAttrChild(linkInfo, nl.IFLA_INFO_DATA, nil) nl.NewRtAttrChild(data, nl.IFLA_IPVLAN_MODE, nl.Uint16Attr(uint16(ipv.Mode))) } else if macv, ok := link.(*Macvlan); ok { if macv.Mode != MACVLAN_MODE_DEFAULT { data := nl.NewRtAttrChild(linkInfo, nl.IFLA_INFO_DATA, nil) nl.NewRtAttrChild(data, nl.IFLA_MACVLAN_MODE, nl.Uint32Attr(macvlanModes[macv.Mode])) } } else if macv, ok := link.(*Macvtap); ok { if macv.Mode != MACVLAN_MODE_DEFAULT { data := nl.NewRtAttrChild(linkInfo, nl.IFLA_INFO_DATA, nil) nl.NewRtAttrChild(data, nl.IFLA_MACVLAN_MODE, nl.Uint32Attr(macvlanModes[macv.Mode])) } } else if gretap, ok := link.(*Gretap); ok { addGretapAttrs(gretap, linkInfo) } else if iptun, ok := link.(*Iptun); ok { addIptunAttrs(iptun, linkInfo) } else if vti, ok := link.(*Vti); ok { addVtiAttrs(vti, linkInfo) } else if vrf, ok := link.(*Vrf); ok { addVrfAttrs(vrf, linkInfo) } req.AddData(linkInfo) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) if err != nil { return err } h.ensureIndex(base) // can't set master during create, so set it afterwards if base.MasterIndex != 0 { // TODO: verify MasterIndex is actually a bridge? return h.LinkSetMasterByIndex(link, base.MasterIndex) } return nil } // LinkDel deletes link device. Either Index or Name must be set in // the link object for it to be deleted. The other values are ignored. // Equivalent to: `ip link del $link` func LinkDel(link Link) error { return pkgHandle.LinkDel(link) } // LinkDel deletes link device. Either Index or Name must be set in // the link object for it to be deleted. The other values are ignored. // Equivalent to: `ip link del $link` func (h *Handle) LinkDel(link Link) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_DELLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(base.Index) req.AddData(msg) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) return err } func (h *Handle) linkByNameDump(name string) (Link, error) { links, err := h.LinkList() if err != nil { return nil, err } for _, link := range links { if link.Attrs().Name == name { return link, nil } } return nil, fmt.Errorf("Link %s not found", name) } func (h *Handle) linkByAliasDump(alias string) (Link, error) { links, err := h.LinkList() if err != nil { return nil, err } for _, link := range links { if link.Attrs().Alias == alias { return link, nil } } return nil, fmt.Errorf("Link alias %s not found", alias) } // LinkByName finds a link by name and returns a pointer to the object. func LinkByName(name string) (Link, error) { return pkgHandle.LinkByName(name) } // LinkByName finds a link by name and returns a pointer to the object. func (h *Handle) LinkByName(name string) (Link, error) { if h.lookupByDump { return h.linkByNameDump(name) } req := h.newNetlinkRequest(syscall.RTM_GETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) req.AddData(msg) nameData := nl.NewRtAttr(syscall.IFLA_IFNAME, nl.ZeroTerminated(name)) req.AddData(nameData) link, err := execGetLink(req) if err == syscall.EINVAL { // older kernels don't support looking up via IFLA_IFNAME // so fall back to dumping all links h.lookupByDump = true return h.linkByNameDump(name) } return link, err } // LinkByAlias finds a link by its alias and returns a pointer to the object. // If there are multiple links with the alias it returns the first one func LinkByAlias(alias string) (Link, error) { return pkgHandle.LinkByAlias(alias) } // LinkByAlias finds a link by its alias and returns a pointer to the object. // If there are multiple links with the alias it returns the first one func (h *Handle) LinkByAlias(alias string) (Link, error) { if h.lookupByDump { return h.linkByAliasDump(alias) } req := h.newNetlinkRequest(syscall.RTM_GETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) req.AddData(msg) nameData := nl.NewRtAttr(syscall.IFLA_IFALIAS, nl.ZeroTerminated(alias)) req.AddData(nameData) link, err := execGetLink(req) if err == syscall.EINVAL { // older kernels don't support looking up via IFLA_IFALIAS // so fall back to dumping all links h.lookupByDump = true return h.linkByAliasDump(alias) } return link, err } // LinkByIndex finds a link by index and returns a pointer to the object. func LinkByIndex(index int) (Link, error) { return pkgHandle.LinkByIndex(index) } // LinkByIndex finds a link by index and returns a pointer to the object. func (h *Handle) LinkByIndex(index int) (Link, error) { req := h.newNetlinkRequest(syscall.RTM_GETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) msg.Index = int32(index) req.AddData(msg) return execGetLink(req) } func execGetLink(req *nl.NetlinkRequest) (Link, error) { msgs, err := req.Execute(syscall.NETLINK_ROUTE, 0) if err != nil { if errno, ok := err.(syscall.Errno); ok { if errno == syscall.ENODEV { return nil, fmt.Errorf("Link not found") } } return nil, err } switch { case len(msgs) == 0: return nil, fmt.Errorf("Link not found") case len(msgs) == 1: return LinkDeserialize(nil, msgs[0]) default: return nil, fmt.Errorf("More than one link found") } } // linkDeserialize deserializes a raw message received from netlink into // a link object. func LinkDeserialize(hdr *syscall.NlMsghdr, m []byte) (Link, error) { msg := nl.DeserializeIfInfomsg(m) attrs, err := nl.ParseRouteAttr(m[msg.Len():]) if err != nil { return nil, err } base := LinkAttrs{Index: int(msg.Index), RawFlags: msg.Flags, Flags: linkFlags(msg.Flags), EncapType: msg.EncapType()} if msg.Flags&syscall.IFF_PROMISC != 0 { base.Promisc = 1 } var ( link Link stats32 []byte stats64 []byte linkType string ) for _, attr := range attrs { switch attr.Attr.Type { case syscall.IFLA_LINKINFO: infos, err := nl.ParseRouteAttr(attr.Value) if err != nil { return nil, err } for _, info := range infos { switch info.Attr.Type { case nl.IFLA_INFO_KIND: linkType = string(info.Value[:len(info.Value)-1]) switch linkType { case "dummy": link = &Dummy{} case "ifb": link = &Ifb{} case "bridge": link = &Bridge{} case "vlan": link = &Vlan{} case "veth": link = &Veth{} case "vxlan": link = &Vxlan{} case "bond": link = &Bond{} case "ipvlan": link = &IPVlan{} case "macvlan": link = &Macvlan{} case "macvtap": link = &Macvtap{} case "gretap": link = &Gretap{} case "ipip": link = &Iptun{} case "vti": link = &Vti{} case "vrf": link = &Vrf{} default: link = &GenericLink{LinkType: linkType} } case nl.IFLA_INFO_DATA: data, err := nl.ParseRouteAttr(info.Value) if err != nil { return nil, err } switch linkType { case "vlan": parseVlanData(link, data) case "vxlan": parseVxlanData(link, data) case "bond": parseBondData(link, data) case "ipvlan": parseIPVlanData(link, data) case "macvlan": parseMacvlanData(link, data) case "macvtap": parseMacvtapData(link, data) case "gretap": parseGretapData(link, data) case "ipip": parseIptunData(link, data) case "vti": parseVtiData(link, data) case "vrf": parseVrfData(link, data) } } } case syscall.IFLA_ADDRESS: var nonzero bool for _, b := range attr.Value { if b != 0 { nonzero = true } } if nonzero { base.HardwareAddr = attr.Value[:] } case syscall.IFLA_IFNAME: base.Name = string(attr.Value[:len(attr.Value)-1]) case syscall.IFLA_MTU: base.MTU = int(native.Uint32(attr.Value[0:4])) case syscall.IFLA_LINK: base.ParentIndex = int(native.Uint32(attr.Value[0:4])) case syscall.IFLA_MASTER: base.MasterIndex = int(native.Uint32(attr.Value[0:4])) case syscall.IFLA_TXQLEN: base.TxQLen = int(native.Uint32(attr.Value[0:4])) case syscall.IFLA_IFALIAS: base.Alias = string(attr.Value[:len(attr.Value)-1]) case syscall.IFLA_STATS: stats32 = attr.Value[:] case IFLA_STATS64: stats64 = attr.Value[:] case nl.IFLA_XDP: xdp, err := parseLinkXdp(attr.Value[:]) if err != nil { return nil, err } base.Xdp = xdp case syscall.IFLA_PROTINFO | syscall.NLA_F_NESTED: if hdr != nil && hdr.Type == syscall.RTM_NEWLINK && msg.Family == syscall.AF_BRIDGE { attrs, err := nl.ParseRouteAttr(attr.Value[:]) if err != nil { return nil, err } base.Protinfo = parseProtinfo(attrs) } case syscall.IFLA_OPERSTATE: base.OperState = LinkOperState(uint8(attr.Value[0])) } } if stats64 != nil { base.Statistics = parseLinkStats64(stats64) } else if stats32 != nil { base.Statistics = parseLinkStats32(stats32) } // Links that don't have IFLA_INFO_KIND are hardware devices if link == nil { link = &Device{} } *link.Attrs() = base return link, nil } // LinkList gets a list of link devices. // Equivalent to: `ip link show` func LinkList() ([]Link, error) { return pkgHandle.LinkList() } // LinkList gets a list of link devices. // Equivalent to: `ip link show` func (h *Handle) LinkList() ([]Link, error) { // NOTE(vish): This duplicates functionality in net/iface_linux.go, but we need // to get the message ourselves to parse link type. req := h.newNetlinkRequest(syscall.RTM_GETLINK, syscall.NLM_F_DUMP) msg := nl.NewIfInfomsg(syscall.AF_UNSPEC) req.AddData(msg) msgs, err := req.Execute(syscall.NETLINK_ROUTE, syscall.RTM_NEWLINK) if err != nil { return nil, err } var res []Link for _, m := range msgs { link, err := LinkDeserialize(nil, m) if err != nil { return nil, err } res = append(res, link) } return res, nil } // LinkUpdate is used to pass information back from LinkSubscribe() type LinkUpdate struct { nl.IfInfomsg Header syscall.NlMsghdr Link } // LinkSubscribe takes a chan down which notifications will be sent // when links change. Close the 'done' chan to stop subscription. func LinkSubscribe(ch chan<- LinkUpdate, done <-chan struct{}) error { return linkSubscribe(netns.None(), netns.None(), ch, done) } // LinkSubscribeAt works like LinkSubscribe plus it allows the caller // to choose the network namespace in which to subscribe (ns). func LinkSubscribeAt(ns netns.NsHandle, ch chan<- LinkUpdate, done <-chan struct{}) error { return linkSubscribe(ns, netns.None(), ch, done) } func linkSubscribe(newNs, curNs netns.NsHandle, ch chan<- LinkUpdate, done <-chan struct{}) error { s, err := nl.SubscribeAt(newNs, curNs, syscall.NETLINK_ROUTE, syscall.RTNLGRP_LINK) if err != nil { return err } if done != nil { go func() { <-done s.Close() }() } go func() { defer close(ch) for { msgs, err := s.Receive() if err != nil { return } for _, m := range msgs { ifmsg := nl.DeserializeIfInfomsg(m.Data) link, err := LinkDeserialize(&m.Header, m.Data) if err != nil { return } ch <- LinkUpdate{IfInfomsg: *ifmsg, Header: m.Header, Link: link} } } }() return nil } func LinkSetHairpin(link Link, mode bool) error { return pkgHandle.LinkSetHairpin(link, mode) } func (h *Handle) LinkSetHairpin(link Link, mode bool) error { return h.setProtinfoAttr(link, mode, nl.IFLA_BRPORT_MODE) } func LinkSetGuard(link Link, mode bool) error { return pkgHandle.LinkSetGuard(link, mode) } func (h *Handle) LinkSetGuard(link Link, mode bool) error { return h.setProtinfoAttr(link, mode, nl.IFLA_BRPORT_GUARD) } func LinkSetFastLeave(link Link, mode bool) error { return pkgHandle.LinkSetFastLeave(link, mode) } func (h *Handle) LinkSetFastLeave(link Link, mode bool) error { return h.setProtinfoAttr(link, mode, nl.IFLA_BRPORT_FAST_LEAVE) } func LinkSetLearning(link Link, mode bool) error { return pkgHandle.LinkSetLearning(link, mode) } func (h *Handle) LinkSetLearning(link Link, mode bool) error { return h.setProtinfoAttr(link, mode, nl.IFLA_BRPORT_LEARNING) } func LinkSetRootBlock(link Link, mode bool) error { return pkgHandle.LinkSetRootBlock(link, mode) } func (h *Handle) LinkSetRootBlock(link Link, mode bool) error { return h.setProtinfoAttr(link, mode, nl.IFLA_BRPORT_PROTECT) } func LinkSetFlood(link Link, mode bool) error { return pkgHandle.LinkSetFlood(link, mode) } func (h *Handle) LinkSetFlood(link Link, mode bool) error { return h.setProtinfoAttr(link, mode, nl.IFLA_BRPORT_UNICAST_FLOOD) } func (h *Handle) setProtinfoAttr(link Link, mode bool, attr int) error { base := link.Attrs() h.ensureIndex(base) req := h.newNetlinkRequest(syscall.RTM_SETLINK, syscall.NLM_F_ACK) msg := nl.NewIfInfomsg(syscall.AF_BRIDGE) msg.Index = int32(base.Index) req.AddData(msg) br := nl.NewRtAttr(syscall.IFLA_PROTINFO|syscall.NLA_F_NESTED, nil) nl.NewRtAttrChild(br, attr, boolToByte(mode)) req.AddData(br) _, err := req.Execute(syscall.NETLINK_ROUTE, 0) if err != nil { return err } return nil } func parseVlanData(link Link, data []syscall.NetlinkRouteAttr) { vlan := link.(*Vlan) for _, datum := range data { switch datum.Attr.Type { case nl.IFLA_VLAN_ID: vlan.VlanId = int(native.Uint16(datum.Value[0:2])) } } } func parseVxlanData(link Link, data []syscall.NetlinkRouteAttr) { vxlan := link.(*Vxlan) for _, datum := range data { switch datum.Attr.Type { case nl.IFLA_VXLAN_ID: vxlan.VxlanId = int(native.Uint32(datum.Value[0:4])) case nl.IFLA_VXLAN_LINK: vxlan.VtepDevIndex = int(native.Uint32(datum.Value[0:4])) case nl.IFLA_VXLAN_LOCAL: vxlan.SrcAddr = net.IP(datum.Value[0:4]) case nl.IFLA_VXLAN_LOCAL6: vxlan.SrcAddr = net.IP(datum.Value[0:16]) case nl.IFLA_VXLAN_GROUP: vxlan.Group = net.IP(datum.Value[0:4]) case nl.IFLA_VXLAN_GROUP6: vxlan.Group = net.IP(datum.Value[0:16]) case nl.IFLA_VXLAN_TTL: vxlan.TTL = int(datum.Value[0]) case nl.IFLA_VXLAN_TOS: vxlan.TOS = int(datum.Value[0]) case nl.IFLA_VXLAN_LEARNING: vxlan.Learning = int8(datum.Value[0]) != 0 case nl.IFLA_VXLAN_PROXY: vxlan.Proxy = int8(datum.Value[0]) != 0 case nl.IFLA_VXLAN_RSC: vxlan.RSC = int8(datum.Value[0]) != 0 case nl.IFLA_VXLAN_L2MISS: vxlan.L2miss = int8(datum.Value[0]) != 0 case nl.IFLA_VXLAN_L3MISS: vxlan.L3miss = int8(datum.Value[0]) != 0 case nl.IFLA_VXLAN_UDP_CSUM: vxlan.UDPCSum = int8(datum.Value[0]) != 0 case nl.IFLA_VXLAN_GBP: vxlan.GBP = true case nl.IFLA_VXLAN_AGEING: vxlan.Age = int(native.Uint32(datum.Value[0:4])) vxlan.NoAge = vxlan.Age == 0 case nl.IFLA_VXLAN_LIMIT: vxlan.Limit = int(native.Uint32(datum.Value[0:4])) case nl.IFLA_VXLAN_PORT: vxlan.Port = int(ntohs(datum.Value[0:2])) case nl.IFLA_VXLAN_PORT_RANGE: buf := bytes.NewBuffer(datum.Value[0:4]) var pr vxlanPortRange if binary.Read(buf, binary.BigEndian, &pr) != nil { vxlan.PortLow = int(pr.Lo) vxlan.PortHigh = int(pr.Hi) } } } } func parseBondData(link Link, data []syscall.NetlinkRouteAttr) { bond := NewLinkBond(NewLinkAttrs()) for i := range data { switch data[i].Attr.Type { case nl.IFLA_BOND_MODE: bond.Mode = BondMode(data[i].Value[0]) case nl.IFLA_BOND_ACTIVE_SLAVE: bond.ActiveSlave = int(native.Uint32(data[i].Value[0:4])) case nl.IFLA_BOND_MIIMON: bond.Miimon = int(native.Uint32(data[i].Value[0:4])) case nl.IFLA_BOND_UPDELAY: bond.UpDelay = int(native.Uint32(data[i].Value[0:4])) case nl.IFLA_BOND_DOWNDELAY: bond.DownDelay = int(native.Uint32(data[i].Value[0:4])) case nl.IFLA_BOND_USE_CARRIER: bond.UseCarrier = int(data[i].Value[0]) case nl.IFLA_BOND_ARP_INTERVAL: bond.ArpInterval = int(native.Uint32(data[i].Value[0:4])) case nl.IFLA_BOND_ARP_IP_TARGET: // TODO: implement case nl.IFLA_BOND_ARP_VALIDATE: bond.ArpValidate = BondArpValidate(native.Uint32(data[i].Value[0:4])) case nl.IFLA_BOND_ARP_ALL_TARGETS: bond.ArpAllTargets = BondArpAllTargets(native.Uint32(data[i].Value[0:4])) case nl.IFLA_BOND_PRIMARY: bond.Primary = int(native.Uint32(data[i].Value[0:4])) case nl.IFLA_BOND_PRIMARY_RESELECT: bond.PrimaryReselect = BondPrimaryReselect(data[i].Value[0]) case nl.IFLA_BOND_FAIL_OVER_MAC: bond.FailOverMac = BondFailOverMac(data[i].Value[0]) case nl.IFLA_BOND_XMIT_HASH_POLICY: bond.XmitHashPolicy = BondXmitHashPolicy(data[i].Value[0]) case nl.IFLA_BOND_RESEND_IGMP: bond.ResendIgmp = int(native.Uint32(data[i].Value[0:4])) case nl.IFLA_BOND_NUM_PEER_NOTIF: bond.NumPeerNotif = int(data[i].Value[0]) case nl.IFLA_BOND_ALL_SLAVES_ACTIVE: bond.AllSlavesActive = int(data[i].Value[0]) case nl.IFLA_BOND_MIN_LINKS: bond.MinLinks = int(native.Uint32(data[i].Value[0:4])) case nl.IFLA_BOND_LP_INTERVAL: bond.LpInterval = int(native.Uint32(data[i].Value[0:4])) case nl.IFLA_BOND_PACKETS_PER_SLAVE: bond.PackersPerSlave = int(native.Uint32(data[i].Value[0:4])) case nl.IFLA_BOND_AD_LACP_RATE: bond.LacpRate = BondLacpRate(data[i].Value[0]) case nl.IFLA_BOND_AD_SELECT: bond.AdSelect = BondAdSelect(data[i].Value[0]) case nl.IFLA_BOND_AD_INFO: // TODO: implement } } } func parseIPVlanData(link Link, data []syscall.NetlinkRouteAttr) { ipv := link.(*IPVlan) for _, datum := range data { if datum.Attr.Type == nl.IFLA_IPVLAN_MODE { ipv.Mode = IPVlanMode(native.Uint32(datum.Value[0:4])) return } } } func parseMacvtapData(link Link, data []syscall.NetlinkRouteAttr) { macv := link.(*Macvtap) parseMacvlanData(&macv.Macvlan, data) } func parseMacvlanData(link Link, data []syscall.NetlinkRouteAttr) { macv := link.(*Macvlan) for _, datum := range data { if datum.Attr.Type == nl.IFLA_MACVLAN_MODE { switch native.Uint32(datum.Value[0:4]) { case nl.MACVLAN_MODE_PRIVATE: macv.Mode = MACVLAN_MODE_PRIVATE case nl.MACVLAN_MODE_VEPA: macv.Mode = MACVLAN_MODE_VEPA case nl.MACVLAN_MODE_BRIDGE: macv.Mode = MACVLAN_MODE_BRIDGE case nl.MACVLAN_MODE_PASSTHRU: macv.Mode = MACVLAN_MODE_PASSTHRU case nl.MACVLAN_MODE_SOURCE: macv.Mode = MACVLAN_MODE_SOURCE } return } } } // copied from pkg/net_linux.go func linkFlags(rawFlags uint32) net.Flags { var f net.Flags if rawFlags&syscall.IFF_UP != 0 { f |= net.FlagUp } if rawFlags&syscall.IFF_BROADCAST != 0 { f |= net.FlagBroadcast } if rawFlags&syscall.IFF_LOOPBACK != 0 { f |= net.FlagLoopback } if rawFlags&syscall.IFF_POINTOPOINT != 0 { f |= net.FlagPointToPoint } if rawFlags&syscall.IFF_MULTICAST != 0 { f |= net.FlagMulticast } return f } func addGretapAttrs(gretap *Gretap, linkInfo *nl.RtAttr) { data := nl.NewRtAttrChild(linkInfo, nl.IFLA_INFO_DATA, nil) ip := gretap.Local.To4() if ip != nil { nl.NewRtAttrChild(data, nl.IFLA_GRE_LOCAL, []byte(ip)) } ip = gretap.Remote.To4() if ip != nil { nl.NewRtAttrChild(data, nl.IFLA_GRE_REMOTE, []byte(ip)) } if gretap.IKey != 0 { nl.NewRtAttrChild(data, nl.IFLA_GRE_IKEY, htonl(gretap.IKey)) gretap.IFlags |= uint16(nl.GRE_KEY) } if gretap.OKey != 0 { nl.NewRtAttrChild(data, nl.IFLA_GRE_OKEY, htonl(gretap.OKey)) gretap.OFlags |= uint16(nl.GRE_KEY) } nl.NewRtAttrChild(data, nl.IFLA_GRE_IFLAGS, htons(gretap.IFlags)) nl.NewRtAttrChild(data, nl.IFLA_GRE_OFLAGS, htons(gretap.OFlags)) if gretap.Link != 0 { nl.NewRtAttrChild(data, nl.IFLA_GRE_LINK, nl.Uint32Attr(gretap.Link)) } nl.NewRtAttrChild(data, nl.IFLA_GRE_PMTUDISC, nl.Uint8Attr(gretap.PMtuDisc)) nl.NewRtAttrChild(data, nl.IFLA_GRE_TTL, nl.Uint8Attr(gretap.Ttl)) nl.NewRtAttrChild(data, nl.IFLA_GRE_TOS, nl.Uint8Attr(gretap.Tos)) nl.NewRtAttrChild(data, nl.IFLA_GRE_ENCAP_TYPE, nl.Uint16Attr(gretap.EncapType)) nl.NewRtAttrChild(data, nl.IFLA_GRE_ENCAP_FLAGS, nl.Uint16Attr(gretap.EncapFlags)) nl.NewRtAttrChild(data, nl.IFLA_GRE_ENCAP_SPORT, htons(gretap.EncapSport)) nl.NewRtAttrChild(data, nl.IFLA_GRE_ENCAP_DPORT, htons(gretap.EncapDport)) } func parseGretapData(link Link, data []syscall.NetlinkRouteAttr) { gre := link.(*Gretap) for _, datum := range data { switch datum.Attr.Type { case nl.IFLA_GRE_OKEY: gre.IKey = ntohl(datum.Value[0:4]) case nl.IFLA_GRE_IKEY: gre.OKey = ntohl(datum.Value[0:4]) case nl.IFLA_GRE_LOCAL: gre.Local = net.IP(datum.Value[0:4]) case nl.IFLA_GRE_REMOTE: gre.Remote = net.IP(datum.Value[0:4]) case nl.IFLA_GRE_ENCAP_SPORT: gre.EncapSport = ntohs(datum.Value[0:2]) case nl.IFLA_GRE_ENCAP_DPORT: gre.EncapDport = ntohs(datum.Value[0:2]) case nl.IFLA_GRE_IFLAGS: gre.IFlags = ntohs(datum.Value[0:2]) case nl.IFLA_GRE_OFLAGS: gre.OFlags = ntohs(datum.Value[0:2]) case nl.IFLA_GRE_TTL: gre.Ttl = uint8(datum.Value[0]) case nl.IFLA_GRE_TOS: gre.Tos = uint8(datum.Value[0]) case nl.IFLA_GRE_PMTUDISC: gre.PMtuDisc = uint8(datum.Value[0]) case nl.IFLA_GRE_ENCAP_TYPE: gre.EncapType = native.Uint16(datum.Value[0:2]) case nl.IFLA_GRE_ENCAP_FLAGS: gre.EncapFlags = native.Uint16(datum.Value[0:2]) } } } func parseLinkStats32(data []byte) *LinkStatistics { return (*LinkStatistics)((*LinkStatistics32)(unsafe.Pointer(&data[0:SizeofLinkStats32][0])).to64()) } func parseLinkStats64(data []byte) *LinkStatistics { return (*LinkStatistics)((*LinkStatistics64)(unsafe.Pointer(&data[0:SizeofLinkStats64][0]))) } func addXdpAttrs(xdp *LinkXdp, req *nl.NetlinkRequest) { attrs := nl.NewRtAttr(nl.IFLA_XDP|syscall.NLA_F_NESTED, nil) b := make([]byte, 4) native.PutUint32(b, uint32(xdp.Fd)) nl.NewRtAttrChild(attrs, nl.IFLA_XDP_FD, b) req.AddData(attrs) } func parseLinkXdp(data []byte) (*LinkXdp, error) { attrs, err := nl.ParseRouteAttr(data) if err != nil { return nil, err } xdp := &LinkXdp{} for _, attr := range attrs { switch attr.Attr.Type { case nl.IFLA_XDP_FD: xdp.Fd = int(native.Uint32(attr.Value[0:4])) case nl.IFLA_XDP_ATTACHED: xdp.Attached = attr.Value[0] != 0 } } return xdp, nil } func addIptunAttrs(iptun *Iptun, linkInfo *nl.RtAttr) { data := nl.NewRtAttrChild(linkInfo, nl.IFLA_INFO_DATA, nil) ip := iptun.Local.To4() if ip != nil { nl.NewRtAttrChild(data, nl.IFLA_IPTUN_LOCAL, []byte(ip)) } ip = iptun.Remote.To4() if ip != nil { nl.NewRtAttrChild(data, nl.IFLA_IPTUN_REMOTE, []byte(ip)) } if iptun.Link != 0 { nl.NewRtAttrChild(data, nl.IFLA_IPTUN_LINK, nl.Uint32Attr(iptun.Link)) } nl.NewRtAttrChild(data, nl.IFLA_IPTUN_PMTUDISC, nl.Uint8Attr(iptun.PMtuDisc)) nl.NewRtAttrChild(data, nl.IFLA_IPTUN_TTL, nl.Uint8Attr(iptun.Ttl)) nl.NewRtAttrChild(data, nl.IFLA_IPTUN_TOS, nl.Uint8Attr(iptun.Tos)) } func parseIptunData(link Link, data []syscall.NetlinkRouteAttr) { iptun := link.(*Iptun) for _, datum := range data { switch datum.Attr.Type { case nl.IFLA_IPTUN_LOCAL: iptun.Local = net.IP(datum.Value[0:4]) case nl.IFLA_IPTUN_REMOTE: iptun.Remote = net.IP(datum.Value[0:4]) case nl.IFLA_IPTUN_TTL: iptun.Ttl = uint8(datum.Value[0]) case nl.IFLA_IPTUN_TOS: iptun.Tos = uint8(datum.Value[0]) case nl.IFLA_IPTUN_PMTUDISC: iptun.PMtuDisc = uint8(datum.Value[0]) } } } func addVtiAttrs(vti *Vti, linkInfo *nl.RtAttr) { data := nl.NewRtAttrChild(linkInfo, nl.IFLA_INFO_DATA, nil) ip := vti.Local.To4() if ip != nil { nl.NewRtAttrChild(data, nl.IFLA_VTI_LOCAL, []byte(ip)) } ip = vti.Remote.To4() if ip != nil { nl.NewRtAttrChild(data, nl.IFLA_VTI_REMOTE, []byte(ip)) } if vti.Link != 0 { nl.NewRtAttrChild(data, nl.IFLA_VTI_LINK, nl.Uint32Attr(vti.Link)) } nl.NewRtAttrChild(data, nl.IFLA_VTI_IKEY, htonl(vti.IKey)) nl.NewRtAttrChild(data, nl.IFLA_VTI_OKEY, htonl(vti.OKey)) } func parseVtiData(link Link, data []syscall.NetlinkRouteAttr) { vti := link.(*Vti) for _, datum := range data { switch datum.Attr.Type { case nl.IFLA_VTI_LOCAL: vti.Local = net.IP(datum.Value[0:4]) case nl.IFLA_VTI_REMOTE: vti.Remote = net.IP(datum.Value[0:4]) case nl.IFLA_VTI_IKEY: vti.IKey = ntohl(datum.Value[0:4]) case nl.IFLA_VTI_OKEY: vti.OKey = ntohl(datum.Value[0:4]) } } } func addVrfAttrs(vrf *Vrf, linkInfo *nl.RtAttr) { data := nl.NewRtAttrChild(linkInfo, nl.IFLA_INFO_DATA, nil) b := make([]byte, 4) native.PutUint32(b, uint32(vrf.Table)) nl.NewRtAttrChild(data, nl.IFLA_VRF_TABLE, b) } func parseVrfData(link Link, data []syscall.NetlinkRouteAttr) { vrf := link.(*Vrf) for _, datum := range data { switch datum.Attr.Type { case nl.IFLA_VRF_TABLE: vrf.Table = native.Uint32(datum.Value[0:4]) } } }