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kilo/vendor/github.com/vishvananda/netlink/link_linux.go
Lucas Servén Marín 8cadff2b79
CNI: bump to 1.0.1 (#297) 
* CNI: bump to 1.0.1

This commit bumps the declared version of CNI in the Kilo manifests to
1.0.1. This is possible with no changes to the configuration lists
because our simple configuration is not affected by any of the
deprecations, and there was effectively no change between 0.4.0 and
1.0.0, other than the declaration of a stable API. Similarly, this
commit also bumps the version of the CNI library and the plugins
package.

Bumping to CNI 1.0.0 will help ensure that Kilo stays compatible with
container runtimes in the future.

Signed-off-by: Lucas Servén Marín <lserven@gmail.com>

* vendor: revendor

Signed-off-by: Lucas Servén Marín <lserven@gmail.com>
2022-04-18 19:00:37 +02:00

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package netlink
import (
"bytes"
"encoding/binary"
"fmt"
"io/ioutil"
"net"
"os"
"strconv"
"strings"
"syscall"
"unsafe"
"github.com/vishvananda/netlink/nl"
"github.com/vishvananda/netns"
"golang.org/x/sys/unix"
)
const (
SizeofLinkStats32 = 0x5c
SizeofLinkStats64 = 0xb8
)
const (
TUNTAP_MODE_TUN TuntapMode = unix.IFF_TUN
TUNTAP_MODE_TAP TuntapMode = unix.IFF_TAP
TUNTAP_DEFAULTS TuntapFlag = unix.IFF_TUN_EXCL | unix.IFF_ONE_QUEUE
TUNTAP_VNET_HDR TuntapFlag = unix.IFF_VNET_HDR
TUNTAP_TUN_EXCL TuntapFlag = unix.IFF_TUN_EXCL
TUNTAP_NO_PI TuntapFlag = unix.IFF_NO_PI
TUNTAP_ONE_QUEUE TuntapFlag = unix.IFF_ONE_QUEUE
TUNTAP_MULTI_QUEUE TuntapFlag = unix.IFF_MULTI_QUEUE
TUNTAP_MULTI_QUEUE_DEFAULTS TuntapFlag = TUNTAP_MULTI_QUEUE | TUNTAP_NO_PI
)
var StringToTuntapModeMap = map[string]TuntapMode{
"tun": TUNTAP_MODE_TUN,
"tap": TUNTAP_MODE_TAP,
}
func (ttm TuntapMode) String() string {
switch ttm {
case TUNTAP_MODE_TUN:
return "tun"
case TUNTAP_MODE_TAP:
return "tap"
}
return "unknown"
}
const (
VF_LINK_STATE_AUTO uint32 = 0
VF_LINK_STATE_ENABLE uint32 = 1
VF_LINK_STATE_DISABLE uint32 = 2
)
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(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Change |= unix.IFF_NOARP
msg.Flags |= unix.IFF_NOARP
msg.Index = int32(base.Index)
req.AddData(msg)
_, err := req.Execute(unix.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(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Change |= unix.IFF_NOARP
msg.Flags &= ^uint32(unix.IFF_NOARP)
msg.Index = int32(base.Index)
req.AddData(msg)
_, err := req.Execute(unix.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(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Change = unix.IFF_PROMISC
msg.Flags = unix.IFF_PROMISC
msg.Index = int32(base.Index)
req.AddData(msg)
_, err := req.Execute(unix.NETLINK_ROUTE, 0)
return err
}
// LinkSetAllmulticastOn enables the reception of all hardware multicast packets for the link device.
// Equivalent to: `ip link set $link allmulticast on`
func LinkSetAllmulticastOn(link Link) error {
return pkgHandle.LinkSetAllmulticastOn(link)
}
// LinkSetAllmulticastOn enables the reception of all hardware multicast packets for the link device.
// Equivalent to: `ip link set $link allmulticast on`
func (h *Handle) LinkSetAllmulticastOn(link Link) error {
base := link.Attrs()
h.ensureIndex(base)
req := h.newNetlinkRequest(unix.RTM_NEWLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Change = unix.IFF_ALLMULTI
msg.Flags = unix.IFF_ALLMULTI
msg.Index = int32(base.Index)
req.AddData(msg)
_, err := req.Execute(unix.NETLINK_ROUTE, 0)
return err
}
// LinkSetAllmulticastOff disables the reception of all hardware multicast packets for the link device.
// Equivalent to: `ip link set $link allmulticast off`
func LinkSetAllmulticastOff(link Link) error {
return pkgHandle.LinkSetAllmulticastOff(link)
}
// LinkSetAllmulticastOff disables the reception of all hardware multicast packets for the link device.
// Equivalent to: `ip link set $link allmulticast off`
func (h *Handle) LinkSetAllmulticastOff(link Link) error {
base := link.Attrs()
h.ensureIndex(base)
req := h.newNetlinkRequest(unix.RTM_NEWLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Change = unix.IFF_ALLMULTI
msg.Index = int32(base.Index)
req.AddData(msg)
_, err := req.Execute(unix.NETLINK_ROUTE, 0)
return err
}
func MacvlanMACAddrAdd(link Link, addr net.HardwareAddr) error {
return pkgHandle.MacvlanMACAddrAdd(link, addr)
}
func (h *Handle) MacvlanMACAddrAdd(link Link, addr net.HardwareAddr) error {
return h.macvlanMACAddrChange(link, []net.HardwareAddr{addr}, nl.MACVLAN_MACADDR_ADD)
}
func MacvlanMACAddrDel(link Link, addr net.HardwareAddr) error {
return pkgHandle.MacvlanMACAddrDel(link, addr)
}
func (h *Handle) MacvlanMACAddrDel(link Link, addr net.HardwareAddr) error {
return h.macvlanMACAddrChange(link, []net.HardwareAddr{addr}, nl.MACVLAN_MACADDR_DEL)
}
func MacvlanMACAddrFlush(link Link) error {
return pkgHandle.MacvlanMACAddrFlush(link)
}
func (h *Handle) MacvlanMACAddrFlush(link Link) error {
return h.macvlanMACAddrChange(link, nil, nl.MACVLAN_MACADDR_FLUSH)
}
func MacvlanMACAddrSet(link Link, addrs []net.HardwareAddr) error {
return pkgHandle.MacvlanMACAddrSet(link, addrs)
}
func (h *Handle) MacvlanMACAddrSet(link Link, addrs []net.HardwareAddr) error {
return h.macvlanMACAddrChange(link, addrs, nl.MACVLAN_MACADDR_SET)
}
func (h *Handle) macvlanMACAddrChange(link Link, addrs []net.HardwareAddr, mode uint32) error {
base := link.Attrs()
h.ensureIndex(base)
req := h.newNetlinkRequest(unix.RTM_NEWLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
linkInfo := nl.NewRtAttr(unix.IFLA_LINKINFO, nil)
linkInfo.AddRtAttr(nl.IFLA_INFO_KIND, nl.NonZeroTerminated(link.Type()))
inner := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
// IFLA_MACVLAN_MACADDR_MODE = mode
b := make([]byte, 4)
native.PutUint32(b, mode)
inner.AddRtAttr(nl.IFLA_MACVLAN_MACADDR_MODE, b)
// populate message with MAC addrs, if necessary
switch mode {
case nl.MACVLAN_MACADDR_ADD, nl.MACVLAN_MACADDR_DEL:
if len(addrs) == 1 {
inner.AddRtAttr(nl.IFLA_MACVLAN_MACADDR, []byte(addrs[0]))
}
case nl.MACVLAN_MACADDR_SET:
mad := inner.AddRtAttr(nl.IFLA_MACVLAN_MACADDR_DATA, nil)
for _, addr := range addrs {
mad.AddRtAttr(nl.IFLA_MACVLAN_MACADDR, []byte(addr))
}
}
req.AddData(linkInfo)
_, err := req.Execute(unix.NETLINK_ROUTE, 0)
return err
}
// LinkSetMacvlanMode sets the mode of a macvlan or macvtap link device.
// Note that passthrough mode cannot be set to and from and will fail.
// Equivalent to: `ip link set $link type (macvlan|macvtap) mode $mode
func LinkSetMacvlanMode(link Link, mode MacvlanMode) error {
return pkgHandle.LinkSetMacvlanMode(link, mode)
}
// LinkSetMacvlanMode sets the mode of the macvlan or macvtap link device.
// Note that passthrough mode cannot be set to and from and will fail.
// Equivalent to: `ip link set $link type (macvlan|macvtap) mode $mode
func (h *Handle) LinkSetMacvlanMode(link Link, mode MacvlanMode) error {
base := link.Attrs()
h.ensureIndex(base)
req := h.newNetlinkRequest(unix.RTM_NEWLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
linkInfo := nl.NewRtAttr(unix.IFLA_LINKINFO, nil)
linkInfo.AddRtAttr(nl.IFLA_INFO_KIND, nl.NonZeroTerminated(link.Type()))
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
data.AddRtAttr(nl.IFLA_MACVLAN_MODE, nl.Uint32Attr(macvlanModes[mode]))
req.AddData(linkInfo)
_, err := req.Execute(unix.NETLINK_ROUTE, 0)
return err
}
func BridgeSetMcastSnoop(link Link, on bool) error {
return pkgHandle.BridgeSetMcastSnoop(link, on)
}
func (h *Handle) BridgeSetMcastSnoop(link Link, on bool) error {
bridge := link.(*Bridge)
bridge.MulticastSnooping = &on
return h.linkModify(bridge, unix.NLM_F_ACK)
}
func BridgeSetVlanFiltering(link Link, on bool) error {
return pkgHandle.BridgeSetVlanFiltering(link, on)
}
func (h *Handle) BridgeSetVlanFiltering(link Link, on bool) error {
bridge := link.(*Bridge)
bridge.VlanFiltering = &on
return h.linkModify(bridge, unix.NLM_F_ACK)
}
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(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Change = unix.IFF_PROMISC
msg.Index = int32(base.Index)
req.AddData(msg)
_, err := req.Execute(unix.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(unix.RTM_NEWLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Change = unix.IFF_UP
msg.Flags = unix.IFF_UP
msg.Index = int32(base.Index)
req.AddData(msg)
_, err := req.Execute(unix.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(unix.RTM_NEWLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Change = unix.IFF_UP
msg.Index = int32(base.Index)
req.AddData(msg)
_, err := req.Execute(unix.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(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
b := make([]byte, 4)
native.PutUint32(b, uint32(mtu))
data := nl.NewRtAttr(unix.IFLA_MTU, b)
req.AddData(data)
_, err := req.Execute(unix.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(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
data := nl.NewRtAttr(unix.IFLA_IFNAME, []byte(name))
req.AddData(data)
_, err := req.Execute(unix.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(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
data := nl.NewRtAttr(unix.IFLA_IFALIAS, []byte(name))
req.AddData(data)
_, err := req.Execute(unix.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(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
data := nl.NewRtAttr(unix.IFLA_ADDRESS, []byte(hwaddr))
req.AddData(data)
_, err := req.Execute(unix.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(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
data := nl.NewRtAttr(unix.IFLA_VFINFO_LIST, nil)
info := data.AddRtAttr(nl.IFLA_VF_INFO, nil)
vfmsg := nl.VfMac{
Vf: uint32(vf),
}
copy(vfmsg.Mac[:], []byte(hwaddr))
info.AddRtAttr(nl.IFLA_VF_MAC, vfmsg.Serialize())
req.AddData(data)
_, err := req.Execute(unix.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(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
data := nl.NewRtAttr(unix.IFLA_VFINFO_LIST, nil)
info := data.AddRtAttr(nl.IFLA_VF_INFO, nil)
vfmsg := nl.VfVlan{
Vf: uint32(vf),
Vlan: uint32(vlan),
}
info.AddRtAttr(nl.IFLA_VF_VLAN, vfmsg.Serialize())
req.AddData(data)
_, err := req.Execute(unix.NETLINK_ROUTE, 0)
return err
}
// LinkSetVfVlanQos sets the vlan and qos priority of a vf for the link.
// Equivalent to: `ip link set $link vf $vf vlan $vlan qos $qos`
func LinkSetVfVlanQos(link Link, vf, vlan, qos int) error {
return pkgHandle.LinkSetVfVlanQos(link, vf, vlan, qos)
}
// LinkSetVfVlanQos sets the vlan and qos priority of a vf for the link.
// Equivalent to: `ip link set $link vf $vf vlan $vlan qos $qos`
func (h *Handle) LinkSetVfVlanQos(link Link, vf, vlan, qos int) error {
base := link.Attrs()
h.ensureIndex(base)
req := h.newNetlinkRequest(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
data := nl.NewRtAttr(unix.IFLA_VFINFO_LIST, nil)
info := nl.NewRtAttrChild(data, nl.IFLA_VF_INFO, nil)
vfmsg := nl.VfVlan{
Vf: uint32(vf),
Vlan: uint32(vlan),
Qos: uint32(qos),
}
nl.NewRtAttrChild(info, nl.IFLA_VF_VLAN, vfmsg.Serialize())
req.AddData(data)
_, err := req.Execute(unix.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(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
data := nl.NewRtAttr(unix.IFLA_VFINFO_LIST, nil)
info := data.AddRtAttr(nl.IFLA_VF_INFO, nil)
vfmsg := nl.VfTxRate{
Vf: uint32(vf),
Rate: uint32(rate),
}
info.AddRtAttr(nl.IFLA_VF_TX_RATE, vfmsg.Serialize())
req.AddData(data)
_, err := req.Execute(unix.NETLINK_ROUTE, 0)
return err
}
// LinkSetVfRate sets the min and max tx rate of a vf for the link.
// Equivalent to: `ip link set $link vf $vf min_tx_rate $min_rate max_tx_rate $max_rate`
func LinkSetVfRate(link Link, vf, minRate, maxRate int) error {
return pkgHandle.LinkSetVfRate(link, vf, minRate, maxRate)
}
// LinkSetVfRate sets the min and max tx rate of a vf for the link.
// Equivalent to: `ip link set $link vf $vf min_tx_rate $min_rate max_tx_rate $max_rate`
func (h *Handle) LinkSetVfRate(link Link, vf, minRate, maxRate int) error {
base := link.Attrs()
h.ensureIndex(base)
req := h.newNetlinkRequest(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
data := nl.NewRtAttr(unix.IFLA_VFINFO_LIST, nil)
info := data.AddRtAttr(nl.IFLA_VF_INFO, nil)
vfmsg := nl.VfRate{
Vf: uint32(vf),
MinTxRate: uint32(minRate),
MaxTxRate: uint32(maxRate),
}
info.AddRtAttr(nl.IFLA_VF_RATE, vfmsg.Serialize())
req.AddData(data)
_, err := req.Execute(unix.NETLINK_ROUTE, 0)
return err
}
// LinkSetVfState enables/disables virtual link state on a vf.
// Equivalent to: `ip link set $link vf $vf state $state`
func LinkSetVfState(link Link, vf int, state uint32) error {
return pkgHandle.LinkSetVfState(link, vf, state)
}
// LinkSetVfState enables/disables virtual link state on a vf.
// Equivalent to: `ip link set $link vf $vf state $state`
func (h *Handle) LinkSetVfState(link Link, vf int, state uint32) error {
base := link.Attrs()
h.ensureIndex(base)
req := h.newNetlinkRequest(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
data := nl.NewRtAttr(unix.IFLA_VFINFO_LIST, nil)
info := data.AddRtAttr(nl.IFLA_VF_INFO, nil)
vfmsg := nl.VfLinkState{
Vf: uint32(vf),
LinkState: state,
}
info.AddRtAttr(nl.IFLA_VF_LINK_STATE, vfmsg.Serialize())
req.AddData(data)
_, err := req.Execute(unix.NETLINK_ROUTE, 0)
return err
}
// LinkSetVfSpoofchk enables/disables spoof check on a vf for the link.
// Equivalent to: `ip link set $link vf $vf spoofchk $check`
func LinkSetVfSpoofchk(link Link, vf int, check bool) error {
return pkgHandle.LinkSetVfSpoofchk(link, vf, check)
}
// LinkSetVfSpoofchk enables/disables spoof check on a vf for the link.
// Equivalent to: `ip link set $link vf $vf spoofchk $check`
func (h *Handle) LinkSetVfSpoofchk(link Link, vf int, check bool) error {
var setting uint32
base := link.Attrs()
h.ensureIndex(base)
req := h.newNetlinkRequest(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
data := nl.NewRtAttr(unix.IFLA_VFINFO_LIST, nil)
info := data.AddRtAttr(nl.IFLA_VF_INFO, nil)
if check {
setting = 1
}
vfmsg := nl.VfSpoofchk{
Vf: uint32(vf),
Setting: setting,
}
info.AddRtAttr(nl.IFLA_VF_SPOOFCHK, vfmsg.Serialize())
req.AddData(data)
_, err := req.Execute(unix.NETLINK_ROUTE, 0)
return err
}
// LinkSetVfTrust enables/disables trust state on a vf for the link.
// Equivalent to: `ip link set $link vf $vf trust $state`
func LinkSetVfTrust(link Link, vf int, state bool) error {
return pkgHandle.LinkSetVfTrust(link, vf, state)
}
// LinkSetVfTrust enables/disables trust state on a vf for the link.
// Equivalent to: `ip link set $link vf $vf trust $state`
func (h *Handle) LinkSetVfTrust(link Link, vf int, state bool) error {
var setting uint32
base := link.Attrs()
h.ensureIndex(base)
req := h.newNetlinkRequest(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
data := nl.NewRtAttr(unix.IFLA_VFINFO_LIST, nil)
info := data.AddRtAttr(nl.IFLA_VF_INFO, nil)
if state {
setting = 1
}
vfmsg := nl.VfTrust{
Vf: uint32(vf),
Setting: setting,
}
info.AddRtAttr(nl.IFLA_VF_TRUST, vfmsg.Serialize())
req.AddData(data)
_, err := req.Execute(unix.NETLINK_ROUTE, 0)
return err
}
// LinkSetVfNodeGUID sets the node GUID of a vf for the link.
// Equivalent to: `ip link set dev $link vf $vf node_guid $nodeguid`
func LinkSetVfNodeGUID(link Link, vf int, nodeguid net.HardwareAddr) error {
return pkgHandle.LinkSetVfGUID(link, vf, nodeguid, nl.IFLA_VF_IB_NODE_GUID)
}
// LinkSetVfPortGUID sets the port GUID of a vf for the link.
// Equivalent to: `ip link set dev $link vf $vf port_guid $portguid`
func LinkSetVfPortGUID(link Link, vf int, portguid net.HardwareAddr) error {
return pkgHandle.LinkSetVfGUID(link, vf, portguid, nl.IFLA_VF_IB_PORT_GUID)
}
// LinkSetVfGUID sets the node or port GUID of a vf for the link.
func (h *Handle) LinkSetVfGUID(link Link, vf int, vfGuid net.HardwareAddr, guidType int) error {
var err error
var guid uint64
buf := bytes.NewBuffer(vfGuid)
err = binary.Read(buf, binary.BigEndian, &guid)
if err != nil {
return err
}
base := link.Attrs()
h.ensureIndex(base)
req := h.newNetlinkRequest(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
data := nl.NewRtAttr(unix.IFLA_VFINFO_LIST, nil)
info := data.AddRtAttr(nl.IFLA_VF_INFO, nil)
vfmsg := nl.VfGUID{
Vf: uint32(vf),
GUID: guid,
}
info.AddRtAttr(guidType, vfmsg.Serialize())
req.AddData(data)
_, err = req.Execute(unix.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 Link) 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 Link) 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(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
b := make([]byte, 4)
native.PutUint32(b, uint32(masterIndex))
data := nl.NewRtAttr(unix.IFLA_MASTER, b)
req.AddData(data)
_, err := req.Execute(unix.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(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
b := make([]byte, 4)
native.PutUint32(b, uint32(nspid))
data := nl.NewRtAttr(unix.IFLA_NET_NS_PID, b)
req.AddData(data)
_, err := req.Execute(unix.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(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
b := make([]byte, 4)
native.PutUint32(b, uint32(fd))
data := nl.NewRtAttr(unix.IFLA_NET_NS_FD, b)
req.AddData(data)
_, err := req.Execute(unix.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 {
return LinkSetXdpFdWithFlags(link, fd, 0)
}
// LinkSetXdpFdWithFlags adds a bpf function to the driver with the given
// options. The fd must be a bpf program loaded with bpf(type=BPF_PROG_TYPE_XDP)
func LinkSetXdpFdWithFlags(link Link, fd, flags int) error {
base := link.Attrs()
ensureIndex(base)
req := nl.NewNetlinkRequest(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
addXdpAttrs(&LinkXdp{Fd: fd, Flags: uint32(flags)}, req)
_, err := req.Execute(unix.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 := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
if vxlan.FlowBased {
vxlan.VxlanId = 0
}
data.AddRtAttr(nl.IFLA_VXLAN_ID, nl.Uint32Attr(uint32(vxlan.VxlanId)))
if vxlan.VtepDevIndex != 0 {
data.AddRtAttr(nl.IFLA_VXLAN_LINK, nl.Uint32Attr(uint32(vxlan.VtepDevIndex)))
}
if vxlan.SrcAddr != nil {
ip := vxlan.SrcAddr.To4()
if ip != nil {
data.AddRtAttr(nl.IFLA_VXLAN_LOCAL, []byte(ip))
} else {
ip = vxlan.SrcAddr.To16()
if ip != nil {
data.AddRtAttr(nl.IFLA_VXLAN_LOCAL6, []byte(ip))
}
}
}
if vxlan.Group != nil {
group := vxlan.Group.To4()
if group != nil {
data.AddRtAttr(nl.IFLA_VXLAN_GROUP, []byte(group))
} else {
group = vxlan.Group.To16()
if group != nil {
data.AddRtAttr(nl.IFLA_VXLAN_GROUP6, []byte(group))
}
}
}
data.AddRtAttr(nl.IFLA_VXLAN_TTL, nl.Uint8Attr(uint8(vxlan.TTL)))
data.AddRtAttr(nl.IFLA_VXLAN_TOS, nl.Uint8Attr(uint8(vxlan.TOS)))
data.AddRtAttr(nl.IFLA_VXLAN_LEARNING, boolAttr(vxlan.Learning))
data.AddRtAttr(nl.IFLA_VXLAN_PROXY, boolAttr(vxlan.Proxy))
data.AddRtAttr(nl.IFLA_VXLAN_RSC, boolAttr(vxlan.RSC))
data.AddRtAttr(nl.IFLA_VXLAN_L2MISS, boolAttr(vxlan.L2miss))
data.AddRtAttr(nl.IFLA_VXLAN_L3MISS, boolAttr(vxlan.L3miss))
data.AddRtAttr(nl.IFLA_VXLAN_UDP_ZERO_CSUM6_TX, boolAttr(vxlan.UDP6ZeroCSumTx))
data.AddRtAttr(nl.IFLA_VXLAN_UDP_ZERO_CSUM6_RX, boolAttr(vxlan.UDP6ZeroCSumRx))
if vxlan.UDPCSum {
data.AddRtAttr(nl.IFLA_VXLAN_UDP_CSUM, boolAttr(vxlan.UDPCSum))
}
if vxlan.GBP {
data.AddRtAttr(nl.IFLA_VXLAN_GBP, []byte{})
}
if vxlan.FlowBased {
data.AddRtAttr(nl.IFLA_VXLAN_FLOWBASED, boolAttr(vxlan.FlowBased))
}
if vxlan.NoAge {
data.AddRtAttr(nl.IFLA_VXLAN_AGEING, nl.Uint32Attr(0))
} else if vxlan.Age > 0 {
data.AddRtAttr(nl.IFLA_VXLAN_AGEING, nl.Uint32Attr(uint32(vxlan.Age)))
}
if vxlan.Limit > 0 {
data.AddRtAttr(nl.IFLA_VXLAN_LIMIT, nl.Uint32Attr(uint32(vxlan.Limit)))
}
if vxlan.Port > 0 {
data.AddRtAttr(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)
data.AddRtAttr(nl.IFLA_VXLAN_PORT_RANGE, buf.Bytes())
}
}
func addBondAttrs(bond *Bond, linkInfo *nl.RtAttr) {
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
if bond.Mode >= 0 {
data.AddRtAttr(nl.IFLA_BOND_MODE, nl.Uint8Attr(uint8(bond.Mode)))
}
if bond.ActiveSlave >= 0 {
data.AddRtAttr(nl.IFLA_BOND_ACTIVE_SLAVE, nl.Uint32Attr(uint32(bond.ActiveSlave)))
}
if bond.Miimon >= 0 {
data.AddRtAttr(nl.IFLA_BOND_MIIMON, nl.Uint32Attr(uint32(bond.Miimon)))
}
if bond.UpDelay >= 0 {
data.AddRtAttr(nl.IFLA_BOND_UPDELAY, nl.Uint32Attr(uint32(bond.UpDelay)))
}
if bond.DownDelay >= 0 {
data.AddRtAttr(nl.IFLA_BOND_DOWNDELAY, nl.Uint32Attr(uint32(bond.DownDelay)))
}
if bond.UseCarrier >= 0 {
data.AddRtAttr(nl.IFLA_BOND_USE_CARRIER, nl.Uint8Attr(uint8(bond.UseCarrier)))
}
if bond.ArpInterval >= 0 {
data.AddRtAttr(nl.IFLA_BOND_ARP_INTERVAL, nl.Uint32Attr(uint32(bond.ArpInterval)))
}
if bond.ArpIpTargets != nil {
msg := data.AddRtAttr(nl.IFLA_BOND_ARP_IP_TARGET, nil)
for i := range bond.ArpIpTargets {
ip := bond.ArpIpTargets[i].To4()
if ip != nil {
msg.AddRtAttr(i, []byte(ip))
continue
}
ip = bond.ArpIpTargets[i].To16()
if ip != nil {
msg.AddRtAttr(i, []byte(ip))
}
}
}
if bond.ArpValidate >= 0 {
data.AddRtAttr(nl.IFLA_BOND_ARP_VALIDATE, nl.Uint32Attr(uint32(bond.ArpValidate)))
}
if bond.ArpAllTargets >= 0 {
data.AddRtAttr(nl.IFLA_BOND_ARP_ALL_TARGETS, nl.Uint32Attr(uint32(bond.ArpAllTargets)))
}
if bond.Primary >= 0 {
data.AddRtAttr(nl.IFLA_BOND_PRIMARY, nl.Uint32Attr(uint32(bond.Primary)))
}
if bond.PrimaryReselect >= 0 {
data.AddRtAttr(nl.IFLA_BOND_PRIMARY_RESELECT, nl.Uint8Attr(uint8(bond.PrimaryReselect)))
}
if bond.FailOverMac >= 0 {
data.AddRtAttr(nl.IFLA_BOND_FAIL_OVER_MAC, nl.Uint8Attr(uint8(bond.FailOverMac)))
}
if bond.XmitHashPolicy >= 0 {
data.AddRtAttr(nl.IFLA_BOND_XMIT_HASH_POLICY, nl.Uint8Attr(uint8(bond.XmitHashPolicy)))
}
if bond.ResendIgmp >= 0 {
data.AddRtAttr(nl.IFLA_BOND_RESEND_IGMP, nl.Uint32Attr(uint32(bond.ResendIgmp)))
}
if bond.NumPeerNotif >= 0 {
data.AddRtAttr(nl.IFLA_BOND_NUM_PEER_NOTIF, nl.Uint8Attr(uint8(bond.NumPeerNotif)))
}
if bond.AllSlavesActive >= 0 {
data.AddRtAttr(nl.IFLA_BOND_ALL_SLAVES_ACTIVE, nl.Uint8Attr(uint8(bond.AllSlavesActive)))
}
if bond.MinLinks >= 0 {
data.AddRtAttr(nl.IFLA_BOND_MIN_LINKS, nl.Uint32Attr(uint32(bond.MinLinks)))
}
if bond.LpInterval >= 0 {
data.AddRtAttr(nl.IFLA_BOND_LP_INTERVAL, nl.Uint32Attr(uint32(bond.LpInterval)))
}
if bond.PacketsPerSlave >= 0 {
data.AddRtAttr(nl.IFLA_BOND_PACKETS_PER_SLAVE, nl.Uint32Attr(uint32(bond.PacketsPerSlave)))
}
if bond.LacpRate >= 0 {
data.AddRtAttr(nl.IFLA_BOND_AD_LACP_RATE, nl.Uint8Attr(uint8(bond.LacpRate)))
}
if bond.AdSelect >= 0 {
data.AddRtAttr(nl.IFLA_BOND_AD_SELECT, nl.Uint8Attr(uint8(bond.AdSelect)))
}
if bond.AdActorSysPrio >= 0 {
data.AddRtAttr(nl.IFLA_BOND_AD_ACTOR_SYS_PRIO, nl.Uint16Attr(uint16(bond.AdActorSysPrio)))
}
if bond.AdUserPortKey >= 0 {
data.AddRtAttr(nl.IFLA_BOND_AD_USER_PORT_KEY, nl.Uint16Attr(uint16(bond.AdUserPortKey)))
}
if bond.AdActorSystem != nil {
data.AddRtAttr(nl.IFLA_BOND_AD_ACTOR_SYSTEM, []byte(bond.AdActorSystem))
}
if bond.TlbDynamicLb >= 0 {
data.AddRtAttr(nl.IFLA_BOND_TLB_DYNAMIC_LB, nl.Uint8Attr(uint8(bond.TlbDynamicLb)))
}
}
func cleanupFds(fds []*os.File) {
for _, f := range fds {
f.Close()
}
}
// 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 from the parameters in the link object.
// Equivalent to: `ip link add $link`
func (h *Handle) LinkAdd(link Link) error {
return h.linkModify(link, unix.NLM_F_CREATE|unix.NLM_F_EXCL|unix.NLM_F_ACK)
}
func (h *Handle) LinkModify(link Link) error {
return h.linkModify(link, unix.NLM_F_REQUEST|unix.NLM_F_ACK)
}
func (h *Handle) linkModify(link Link, flags int) error {
// TODO: support extra data for macvlan
base := link.Attrs()
// if tuntap, then the name can be empty, OS will provide a name
tuntap, isTuntap := link.(*Tuntap)
if base.Name == "" && !isTuntap {
return fmt.Errorf("LinkAttrs.Name cannot be empty")
}
if isTuntap {
if tuntap.Mode < unix.IFF_TUN || tuntap.Mode > unix.IFF_TAP {
return fmt.Errorf("Tuntap.Mode %v unknown", tuntap.Mode)
}
queues := tuntap.Queues
var fds []*os.File
var req ifReq
copy(req.Name[:15], base.Name)
req.Flags = uint16(tuntap.Flags)
if queues == 0 { //Legacy compatibility
queues = 1
if tuntap.Flags == 0 {
req.Flags = uint16(TUNTAP_DEFAULTS)
}
} else {
// For best peformance set Flags to TUNTAP_MULTI_QUEUE_DEFAULTS | TUNTAP_VNET_HDR
// when a) KVM has support for this ABI and
// b) the value of the flag is queryable using the TUNGETIFF ioctl
if tuntap.Flags == 0 {
req.Flags = uint16(TUNTAP_MULTI_QUEUE_DEFAULTS)
}
}
req.Flags |= uint16(tuntap.Mode)
const TUN = "/dev/net/tun"
for i := 0; i < queues; i++ {
localReq := req
fd, err := unix.Open(TUN, os.O_RDWR|syscall.O_CLOEXEC, 0)
if err != nil {
cleanupFds(fds)
return err
}
_, _, errno := unix.Syscall(unix.SYS_IOCTL, uintptr(fd), uintptr(unix.TUNSETIFF), uintptr(unsafe.Pointer(&localReq)))
if errno != 0 {
// close the new fd
unix.Close(fd)
// and the already opened ones
cleanupFds(fds)
return fmt.Errorf("Tuntap IOCTL TUNSETIFF failed [%d], errno %v", i, errno)
}
_, _, errno = syscall.Syscall(syscall.SYS_IOCTL, uintptr(fd), syscall.TUNSETOWNER, uintptr(tuntap.Owner))
if errno != 0 {
cleanupFds(fds)
return fmt.Errorf("Tuntap IOCTL TUNSETOWNER failed [%d], errno %v", i, errno)
}
_, _, errno = syscall.Syscall(syscall.SYS_IOCTL, uintptr(fd), syscall.TUNSETGROUP, uintptr(tuntap.Group))
if errno != 0 {
cleanupFds(fds)
return fmt.Errorf("Tuntap IOCTL TUNSETGROUP failed [%d], errno %v", i, errno)
}
// Set the tun device to non-blocking before use. The below comment
// taken from:
//
// https://github.com/mistsys/tuntap/commit/161418c25003bbee77d085a34af64d189df62bea
//
// Note there is a complication because in go, if a device node is
// opened, go sets it to use nonblocking I/O. However a /dev/net/tun
// doesn't work with epoll until after the TUNSETIFF ioctl has been
// done. So we open the unix fd directly, do the ioctl, then put the
// fd in nonblocking mode, an then finally wrap it in a os.File,
// which will see the nonblocking mode and add the fd to the
// pollable set, so later on when we Read() from it blocked the
// calling thread in the kernel.
//
// See
// https://github.com/golang/go/issues/30426
// which got exposed in go 1.13 by the fix to
// https://github.com/golang/go/issues/30624
err = unix.SetNonblock(fd, true)
if err != nil {
cleanupFds(fds)
return fmt.Errorf("Tuntap set to non-blocking failed [%d], err %v", i, err)
}
// create the file from the file descriptor and store it
file := os.NewFile(uintptr(fd), TUN)
fds = append(fds, file)
// 1) we only care for the name of the first tap in the multi queue set
// 2) if the original name was empty, the localReq has now the actual name
//
// In addition:
// This ensures that the link name is always identical to what the kernel returns.
// Not only in case of an empty name, but also when using name templates.
// e.g. when the provided name is "tap%d", the kernel replaces %d with the next available number.
if i == 0 {
link.Attrs().Name = strings.Trim(string(localReq.Name[:]), "\x00")
}
}
// only persist interface if NonPersist is NOT set
if !tuntap.NonPersist {
_, _, errno := unix.Syscall(unix.SYS_IOCTL, fds[0].Fd(), uintptr(unix.TUNSETPERSIST), 1)
if errno != 0 {
cleanupFds(fds)
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?
err := h.LinkSetMasterByIndex(link, base.MasterIndex)
if err != nil {
// un-persist (e.g. allow the interface to be removed) the tuntap
// should not hurt if not set prior, condition might be not needed
if !tuntap.NonPersist {
_, _, _ = unix.Syscall(unix.SYS_IOCTL, fds[0].Fd(), uintptr(unix.TUNSETPERSIST), 0)
}
cleanupFds(fds)
return err
}
}
if tuntap.Queues == 0 {
cleanupFds(fds)
} else {
tuntap.Fds = fds
}
return nil
}
req := h.newNetlinkRequest(unix.RTM_NEWLINK, flags)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
// TODO: make it shorter
if base.Flags&net.FlagUp != 0 {
msg.Change = unix.IFF_UP
msg.Flags = unix.IFF_UP
}
if base.Flags&net.FlagBroadcast != 0 {
msg.Change |= unix.IFF_BROADCAST
msg.Flags |= unix.IFF_BROADCAST
}
if base.Flags&net.FlagLoopback != 0 {
msg.Change |= unix.IFF_LOOPBACK
msg.Flags |= unix.IFF_LOOPBACK
}
if base.Flags&net.FlagPointToPoint != 0 {
msg.Change |= unix.IFF_POINTOPOINT
msg.Flags |= unix.IFF_POINTOPOINT
}
if base.Flags&net.FlagMulticast != 0 {
msg.Change |= unix.IFF_MULTICAST
msg.Flags |= unix.IFF_MULTICAST
}
if base.Index != 0 {
msg.Index = int32(base.Index)
}
req.AddData(msg)
if base.ParentIndex != 0 {
b := make([]byte, 4)
native.PutUint32(b, uint32(base.ParentIndex))
data := nl.NewRtAttr(unix.IFLA_LINK, b)
req.AddData(data)
} else if link.Type() == "ipvlan" || link.Type() == "ipoib" {
return fmt.Errorf("Can't create %s link without ParentIndex", link.Type())
}
nameData := nl.NewRtAttr(unix.IFLA_IFNAME, nl.ZeroTerminated(base.Name))
req.AddData(nameData)
if base.Alias != "" {
alias := nl.NewRtAttr(unix.IFLA_IFALIAS, []byte(base.Alias))
req.AddData(alias)
}
if base.MTU > 0 {
mtu := nl.NewRtAttr(unix.IFLA_MTU, nl.Uint32Attr(uint32(base.MTU)))
req.AddData(mtu)
}
if base.TxQLen >= 0 {
qlen := nl.NewRtAttr(unix.IFLA_TXQLEN, nl.Uint32Attr(uint32(base.TxQLen)))
req.AddData(qlen)
}
if base.HardwareAddr != nil {
hwaddr := nl.NewRtAttr(unix.IFLA_ADDRESS, []byte(base.HardwareAddr))
req.AddData(hwaddr)
}
if base.NumTxQueues > 0 {
txqueues := nl.NewRtAttr(unix.IFLA_NUM_TX_QUEUES, nl.Uint32Attr(uint32(base.NumTxQueues)))
req.AddData(txqueues)
}
if base.NumRxQueues > 0 {
rxqueues := nl.NewRtAttr(unix.IFLA_NUM_RX_QUEUES, nl.Uint32Attr(uint32(base.NumRxQueues)))
req.AddData(rxqueues)
}
if base.GSOMaxSegs > 0 {
gsoAttr := nl.NewRtAttr(unix.IFLA_GSO_MAX_SEGS, nl.Uint32Attr(base.GSOMaxSegs))
req.AddData(gsoAttr)
}
if base.GSOMaxSize > 0 {
gsoAttr := nl.NewRtAttr(unix.IFLA_GSO_MAX_SIZE, nl.Uint32Attr(base.GSOMaxSize))
req.AddData(gsoAttr)
}
if base.Group > 0 {
groupAttr := nl.NewRtAttr(unix.IFLA_GROUP, nl.Uint32Attr(base.Group))
req.AddData(groupAttr)
}
if base.Namespace != nil {
var attr *nl.RtAttr
switch ns := base.Namespace.(type) {
case NsPid:
val := nl.Uint32Attr(uint32(ns))
attr = nl.NewRtAttr(unix.IFLA_NET_NS_PID, val)
case NsFd:
val := nl.Uint32Attr(uint32(ns))
attr = nl.NewRtAttr(unix.IFLA_NET_NS_FD, val)
}
req.AddData(attr)
}
if base.Xdp != nil {
addXdpAttrs(base.Xdp, req)
}
linkInfo := nl.NewRtAttr(unix.IFLA_LINKINFO, nil)
linkInfo.AddRtAttr(nl.IFLA_INFO_KIND, nl.NonZeroTerminated(link.Type()))
switch link := link.(type) {
case *Vlan:
b := make([]byte, 2)
native.PutUint16(b, uint16(link.VlanId))
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
data.AddRtAttr(nl.IFLA_VLAN_ID, b)
if link.VlanProtocol != VLAN_PROTOCOL_UNKNOWN {
data.AddRtAttr(nl.IFLA_VLAN_PROTOCOL, htons(uint16(link.VlanProtocol)))
}
case *Veth:
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
peer := data.AddRtAttr(nl.VETH_INFO_PEER, nil)
nl.NewIfInfomsgChild(peer, unix.AF_UNSPEC)
peer.AddRtAttr(unix.IFLA_IFNAME, nl.ZeroTerminated(link.PeerName))
if base.TxQLen >= 0 {
peer.AddRtAttr(unix.IFLA_TXQLEN, nl.Uint32Attr(uint32(base.TxQLen)))
}
if base.NumTxQueues > 0 {
peer.AddRtAttr(unix.IFLA_NUM_TX_QUEUES, nl.Uint32Attr(uint32(base.NumTxQueues)))
}
if base.NumRxQueues > 0 {
peer.AddRtAttr(unix.IFLA_NUM_RX_QUEUES, nl.Uint32Attr(uint32(base.NumRxQueues)))
}
if base.MTU > 0 {
peer.AddRtAttr(unix.IFLA_MTU, nl.Uint32Attr(uint32(base.MTU)))
}
if link.PeerHardwareAddr != nil {
peer.AddRtAttr(unix.IFLA_ADDRESS, []byte(link.PeerHardwareAddr))
}
if link.PeerNamespace != nil {
switch ns := link.PeerNamespace.(type) {
case NsPid:
val := nl.Uint32Attr(uint32(ns))
peer.AddRtAttr(unix.IFLA_NET_NS_PID, val)
case NsFd:
val := nl.Uint32Attr(uint32(ns))
peer.AddRtAttr(unix.IFLA_NET_NS_FD, val)
}
}
case *Vxlan:
addVxlanAttrs(link, linkInfo)
case *Bond:
addBondAttrs(link, linkInfo)
case *IPVlan:
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
data.AddRtAttr(nl.IFLA_IPVLAN_MODE, nl.Uint16Attr(uint16(link.Mode)))
data.AddRtAttr(nl.IFLA_IPVLAN_FLAG, nl.Uint16Attr(uint16(link.Flag)))
case *Macvlan:
if link.Mode != MACVLAN_MODE_DEFAULT {
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
data.AddRtAttr(nl.IFLA_MACVLAN_MODE, nl.Uint32Attr(macvlanModes[link.Mode]))
}
case *Macvtap:
if link.Mode != MACVLAN_MODE_DEFAULT {
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
data.AddRtAttr(nl.IFLA_MACVLAN_MODE, nl.Uint32Attr(macvlanModes[link.Mode]))
}
case *Geneve:
addGeneveAttrs(link, linkInfo)
case *Gretap:
addGretapAttrs(link, linkInfo)
case *Iptun:
addIptunAttrs(link, linkInfo)
case *Ip6tnl:
addIp6tnlAttrs(link, linkInfo)
case *Sittun:
addSittunAttrs(link, linkInfo)
case *Gretun:
addGretunAttrs(link, linkInfo)
case *Vti:
addVtiAttrs(link, linkInfo)
case *Vrf:
addVrfAttrs(link, linkInfo)
case *Bridge:
addBridgeAttrs(link, linkInfo)
case *GTP:
addGTPAttrs(link, linkInfo)
case *Xfrmi:
addXfrmiAttrs(link, linkInfo)
case *IPoIB:
addIPoIBAttrs(link, linkInfo)
}
req.AddData(linkInfo)
_, err := req.Execute(unix.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(unix.RTM_DELLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
_, err := req.Execute(unix.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, LinkNotFoundError{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, LinkNotFoundError{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(unix.RTM_GETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
req.AddData(msg)
attr := nl.NewRtAttr(unix.IFLA_EXT_MASK, nl.Uint32Attr(nl.RTEXT_FILTER_VF))
req.AddData(attr)
nameData := nl.NewRtAttr(unix.IFLA_IFNAME, nl.ZeroTerminated(name))
req.AddData(nameData)
link, err := execGetLink(req)
if err == unix.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(unix.RTM_GETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
req.AddData(msg)
attr := nl.NewRtAttr(unix.IFLA_EXT_MASK, nl.Uint32Attr(nl.RTEXT_FILTER_VF))
req.AddData(attr)
nameData := nl.NewRtAttr(unix.IFLA_IFALIAS, nl.ZeroTerminated(alias))
req.AddData(nameData)
link, err := execGetLink(req)
if err == unix.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(unix.RTM_GETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(index)
req.AddData(msg)
attr := nl.NewRtAttr(unix.IFLA_EXT_MASK, nl.Uint32Attr(nl.RTEXT_FILTER_VF))
req.AddData(attr)
return execGetLink(req)
}
func execGetLink(req *nl.NetlinkRequest) (Link, error) {
msgs, err := req.Execute(unix.NETLINK_ROUTE, 0)
if err != nil {
if errno, ok := err.(syscall.Errno); ok {
if errno == unix.ENODEV {
return nil, LinkNotFoundError{fmt.Errorf("Link not found")}
}
}
return nil, err
}
switch {
case len(msgs) == 0:
return nil, LinkNotFoundError{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 *unix.NlMsghdr, m []byte) (Link, error) {
msg := nl.DeserializeIfInfomsg(m)
attrs, err := nl.ParseRouteAttr(m[msg.Len():])
if err != nil {
return nil, err
}
base := NewLinkAttrs()
base.Index = int(msg.Index)
base.RawFlags = msg.Flags
base.Flags = linkFlags(msg.Flags)
base.EncapType = msg.EncapType()
if msg.Flags&unix.IFF_PROMISC != 0 {
base.Promisc = 1
}
var (
link Link
stats32 *LinkStatistics32
stats64 *LinkStatistics64
linkType string
linkSlave LinkSlave
slaveType string
)
for _, attr := range attrs {
switch attr.Attr.Type {
case unix.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 "wireguard":
link = &Wireguard{}
case "vxlan":
link = &Vxlan{}
case "bond":
link = &Bond{}
case "ipvlan":
link = &IPVlan{}
case "macvlan":
link = &Macvlan{}
case "macvtap":
link = &Macvtap{}
case "geneve":
link = &Geneve{}
case "gretap":
link = &Gretap{}
case "ip6gretap":
link = &Gretap{}
case "ipip":
link = &Iptun{}
case "ip6tnl":
link = &Ip6tnl{}
case "sit":
link = &Sittun{}
case "gre":
link = &Gretun{}
case "ip6gre":
link = &Gretun{}
case "vti", "vti6":
link = &Vti{}
case "vrf":
link = &Vrf{}
case "gtp":
link = &GTP{}
case "xfrm":
link = &Xfrmi{}
case "tun":
link = &Tuntap{}
case "ipoib":
link = &IPoIB{}
case "can":
link = &Can{}
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 "geneve":
parseGeneveData(link, data)
case "gretap":
parseGretapData(link, data)
case "ip6gretap":
parseGretapData(link, data)
case "ipip":
parseIptunData(link, data)
case "ip6tnl":
parseIp6tnlData(link, data)
case "sit":
parseSittunData(link, data)
case "gre":
parseGretunData(link, data)
case "ip6gre":
parseGretunData(link, data)
case "vti", "vti6":
parseVtiData(link, data)
case "vrf":
parseVrfData(link, data)
case "bridge":
parseBridgeData(link, data)
case "gtp":
parseGTPData(link, data)
case "xfrm":
parseXfrmiData(link, data)
case "tun":
parseTuntapData(link, data)
case "ipoib":
parseIPoIBData(link, data)
case "can":
parseCanData(link, data)
}
case nl.IFLA_INFO_SLAVE_KIND:
slaveType = string(info.Value[:len(info.Value)-1])
switch slaveType {
case "bond":
linkSlave = &BondSlave{}
}
case nl.IFLA_INFO_SLAVE_DATA:
switch slaveType {
case "bond":
data, err := nl.ParseRouteAttr(info.Value)
if err != nil {
return nil, err
}
parseBondSlaveData(linkSlave, data)
}
}
}
case unix.IFLA_ADDRESS:
var nonzero bool
for _, b := range attr.Value {
if b != 0 {
nonzero = true
}
}
if nonzero {
base.HardwareAddr = attr.Value[:]
}
case unix.IFLA_IFNAME:
base.Name = string(attr.Value[:len(attr.Value)-1])
case unix.IFLA_MTU:
base.MTU = int(native.Uint32(attr.Value[0:4]))
case unix.IFLA_LINK:
base.ParentIndex = int(native.Uint32(attr.Value[0:4]))
case unix.IFLA_MASTER:
base.MasterIndex = int(native.Uint32(attr.Value[0:4]))
case unix.IFLA_TXQLEN:
base.TxQLen = int(native.Uint32(attr.Value[0:4]))
case unix.IFLA_IFALIAS:
base.Alias = string(attr.Value[:len(attr.Value)-1])
case unix.IFLA_STATS:
stats32 = new(LinkStatistics32)
if err := binary.Read(bytes.NewBuffer(attr.Value[:]), nl.NativeEndian(), stats32); err != nil {
return nil, err
}
case unix.IFLA_STATS64:
stats64 = new(LinkStatistics64)
if err := binary.Read(bytes.NewBuffer(attr.Value[:]), nl.NativeEndian(), stats64); err != nil {
return nil, err
}
case unix.IFLA_XDP:
xdp, err := parseLinkXdp(attr.Value[:])
if err != nil {
return nil, err
}
base.Xdp = xdp
case unix.IFLA_PROTINFO | unix.NLA_F_NESTED:
if hdr != nil && hdr.Type == unix.RTM_NEWLINK &&
msg.Family == unix.AF_BRIDGE {
attrs, err := nl.ParseRouteAttr(attr.Value[:])
if err != nil {
return nil, err
}
protinfo := parseProtinfo(attrs)
base.Protinfo = &protinfo
}
case unix.IFLA_OPERSTATE:
base.OperState = LinkOperState(uint8(attr.Value[0]))
case unix.IFLA_LINK_NETNSID:
base.NetNsID = int(native.Uint32(attr.Value[0:4]))
case unix.IFLA_GSO_MAX_SIZE:
base.GSOMaxSize = native.Uint32(attr.Value[0:4])
case unix.IFLA_GSO_MAX_SEGS:
base.GSOMaxSegs = native.Uint32(attr.Value[0:4])
case unix.IFLA_VFINFO_LIST:
data, err := nl.ParseRouteAttr(attr.Value)
if err != nil {
return nil, err
}
vfs, err := parseVfInfoList(data)
if err != nil {
return nil, err
}
base.Vfs = vfs
case unix.IFLA_NUM_TX_QUEUES:
base.NumTxQueues = int(native.Uint32(attr.Value[0:4]))
case unix.IFLA_NUM_RX_QUEUES:
base.NumRxQueues = int(native.Uint32(attr.Value[0:4]))
case unix.IFLA_GROUP:
base.Group = native.Uint32(attr.Value[0:4])
}
}
if stats64 != nil {
base.Statistics = (*LinkStatistics)(stats64)
} else if stats32 != nil {
base.Statistics = (*LinkStatistics)(stats32.to64())
}
// Links that don't have IFLA_INFO_KIND are hardware devices
if link == nil {
link = &Device{}
}
*link.Attrs() = base
link.Attrs().Slave = linkSlave
// If the tuntap attributes are not updated by netlink due to
// an older driver, use sysfs
if link != nil && linkType == "tun" {
tuntap := link.(*Tuntap)
if tuntap.Mode == 0 {
ifname := tuntap.Attrs().Name
if flags, err := readSysPropAsInt64(ifname, "tun_flags"); err == nil {
if flags&unix.IFF_TUN != 0 {
tuntap.Mode = unix.IFF_TUN
} else if flags&unix.IFF_TAP != 0 {
tuntap.Mode = unix.IFF_TAP
}
tuntap.NonPersist = false
if flags&unix.IFF_PERSIST == 0 {
tuntap.NonPersist = true
}
}
// The sysfs interface for owner/group returns -1 for root user, instead of returning 0.
// So explicitly check for negative value, before assigning the owner uid/gid.
if owner, err := readSysPropAsInt64(ifname, "owner"); err == nil && owner > 0 {
tuntap.Owner = uint32(owner)
}
if group, err := readSysPropAsInt64(ifname, "group"); err == nil && group > 0 {
tuntap.Group = uint32(group)
}
}
}
return link, nil
}
func readSysPropAsInt64(ifname, prop string) (int64, error) {
fname := fmt.Sprintf("/sys/class/net/%s/%s", ifname, prop)
contents, err := ioutil.ReadFile(fname)
if err != nil {
return 0, err
}
num, err := strconv.ParseInt(strings.TrimSpace(string(contents)), 0, 64)
if err == nil {
return num, nil
}
return 0, err
}
// 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(unix.RTM_GETLINK, unix.NLM_F_DUMP)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
req.AddData(msg)
attr := nl.NewRtAttr(unix.IFLA_EXT_MASK, nl.Uint32Attr(nl.RTEXT_FILTER_VF))
req.AddData(attr)
msgs, err := req.Execute(unix.NETLINK_ROUTE, unix.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 unix.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 linkSubscribeAt(netns.None(), netns.None(), ch, done, nil, false)
}
// 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 linkSubscribeAt(ns, netns.None(), ch, done, nil, false)
}
// LinkSubscribeOptions contains a set of options to use with
// LinkSubscribeWithOptions.
type LinkSubscribeOptions struct {
Namespace *netns.NsHandle
ErrorCallback func(error)
ListExisting bool
}
// LinkSubscribeWithOptions work like LinkSubscribe but enable to
// provide additional options to modify the behavior. Currently, the
// namespace can be provided as well as an error callback.
func LinkSubscribeWithOptions(ch chan<- LinkUpdate, done <-chan struct{}, options LinkSubscribeOptions) error {
if options.Namespace == nil {
none := netns.None()
options.Namespace = &none
}
return linkSubscribeAt(*options.Namespace, netns.None(), ch, done, options.ErrorCallback, options.ListExisting)
}
func linkSubscribeAt(newNs, curNs netns.NsHandle, ch chan<- LinkUpdate, done <-chan struct{}, cberr func(error), listExisting bool) error {
s, err := nl.SubscribeAt(newNs, curNs, unix.NETLINK_ROUTE, unix.RTNLGRP_LINK)
if err != nil {
return err
}
if done != nil {
go func() {
<-done
s.Close()
}()
}
if listExisting {
req := pkgHandle.newNetlinkRequest(unix.RTM_GETLINK,
unix.NLM_F_DUMP)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
req.AddData(msg)
if err := s.Send(req); err != nil {
return err
}
}
go func() {
defer close(ch)
for {
msgs, from, err := s.Receive()
if err != nil {
if cberr != nil {
cberr(err)
}
return
}
if from.Pid != nl.PidKernel {
if cberr != nil {
cberr(fmt.Errorf("Wrong sender portid %d, expected %d", from.Pid, nl.PidKernel))
}
continue
}
for _, m := range msgs {
if m.Header.Type == unix.NLMSG_DONE {
continue
}
if m.Header.Type == unix.NLMSG_ERROR {
native := nl.NativeEndian()
error := int32(native.Uint32(m.Data[0:4]))
if error == 0 {
continue
}
if cberr != nil {
cberr(syscall.Errno(-error))
}
return
}
ifmsg := nl.DeserializeIfInfomsg(m.Data)
header := unix.NlMsghdr(m.Header)
link, err := LinkDeserialize(&header, m.Data)
if err != nil {
if cberr != nil {
cberr(err)
}
return
}
ch <- LinkUpdate{IfInfomsg: *ifmsg, Header: 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 LinkSetBrProxyArp(link Link, mode bool) error {
return pkgHandle.LinkSetBrProxyArp(link, mode)
}
func (h *Handle) LinkSetBrProxyArp(link Link, mode bool) error {
return h.setProtinfoAttr(link, mode, nl.IFLA_BRPORT_PROXYARP)
}
func LinkSetBrProxyArpWiFi(link Link, mode bool) error {
return pkgHandle.LinkSetBrProxyArpWiFi(link, mode)
}
func (h *Handle) LinkSetBrProxyArpWiFi(link Link, mode bool) error {
return h.setProtinfoAttr(link, mode, nl.IFLA_BRPORT_PROXYARP_WIFI)
}
func (h *Handle) setProtinfoAttr(link Link, mode bool, attr int) error {
base := link.Attrs()
h.ensureIndex(base)
req := h.newNetlinkRequest(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_BRIDGE)
msg.Index = int32(base.Index)
req.AddData(msg)
br := nl.NewRtAttr(unix.IFLA_PROTINFO|unix.NLA_F_NESTED, nil)
br.AddRtAttr(attr, boolToByte(mode))
req.AddData(br)
_, err := req.Execute(unix.NETLINK_ROUTE, 0)
if err != nil {
return err
}
return nil
}
// LinkSetTxQLen sets the transaction queue length for the link.
// Equivalent to: `ip link set $link txqlen $qlen`
func LinkSetTxQLen(link Link, qlen int) error {
return pkgHandle.LinkSetTxQLen(link, qlen)
}
// LinkSetTxQLen sets the transaction queue length for the link.
// Equivalent to: `ip link set $link txqlen $qlen`
func (h *Handle) LinkSetTxQLen(link Link, qlen int) error {
base := link.Attrs()
h.ensureIndex(base)
req := h.newNetlinkRequest(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
b := make([]byte, 4)
native.PutUint32(b, uint32(qlen))
data := nl.NewRtAttr(unix.IFLA_TXQLEN, b)
req.AddData(data)
_, err := req.Execute(unix.NETLINK_ROUTE, 0)
return err
}
// LinkSetGroup sets the link group id which can be used to perform mass actions
// with iproute2 as well use it as a reference in nft filters.
// Equivalent to: `ip link set $link group $id`
func LinkSetGroup(link Link, group int) error {
return pkgHandle.LinkSetGroup(link, group)
}
// LinkSetGroup sets the link group id which can be used to perform mass actions
// with iproute2 as well use it as a reference in nft filters.
// Equivalent to: `ip link set $link group $id`
func (h *Handle) LinkSetGroup(link Link, group int) error {
base := link.Attrs()
h.ensureIndex(base)
req := h.newNetlinkRequest(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
b := make([]byte, 4)
native.PutUint32(b, uint32(group))
data := nl.NewRtAttr(unix.IFLA_GROUP, b)
req.AddData(data)
_, err := req.Execute(unix.NETLINK_ROUTE, 0)
return err
}
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]))
case nl.IFLA_VLAN_PROTOCOL:
vlan.VlanProtocol = VlanProtocol(int(ntohs(datum.Value[0:2])))
}
}
}
func parseVxlanData(link Link, data []syscall.NetlinkRouteAttr) {
vxlan := link.(*Vxlan)
for _, datum := range data {
// NOTE(vish): Apparently some messages can be sent with no value.
// We special case GBP here to not change existing
// functionality. It appears that GBP sends a datum.Value
// of null.
if len(datum.Value) == 0 && datum.Attr.Type != nl.IFLA_VXLAN_GBP {
continue
}
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_UDP_ZERO_CSUM6_TX:
vxlan.UDP6ZeroCSumTx = int8(datum.Value[0]) != 0
case nl.IFLA_VXLAN_UDP_ZERO_CSUM6_RX:
vxlan.UDP6ZeroCSumRx = int8(datum.Value[0]) != 0
case nl.IFLA_VXLAN_GBP:
vxlan.GBP = true
case nl.IFLA_VXLAN_FLOWBASED:
vxlan.FlowBased = int8(datum.Value[0]) != 0
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 := link.(*Bond)
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:
bond.ArpIpTargets = parseBondArpIpTargets(data[i].Value)
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.PacketsPerSlave = 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
case nl.IFLA_BOND_AD_ACTOR_SYS_PRIO:
bond.AdActorSysPrio = int(native.Uint16(data[i].Value[0:2]))
case nl.IFLA_BOND_AD_USER_PORT_KEY:
bond.AdUserPortKey = int(native.Uint16(data[i].Value[0:2]))
case nl.IFLA_BOND_AD_ACTOR_SYSTEM:
bond.AdActorSystem = net.HardwareAddr(data[i].Value[0:6])
case nl.IFLA_BOND_TLB_DYNAMIC_LB:
bond.TlbDynamicLb = int(data[i].Value[0])
}
}
}
func parseBondArpIpTargets(value []byte) []net.IP {
data, err := nl.ParseRouteAttr(value)
if err != nil {
return nil
}
targets := []net.IP{}
for i := range data {
target := net.IP(data[i].Value)
if ip := target.To4(); ip != nil {
targets = append(targets, ip)
continue
}
if ip := target.To16(); ip != nil {
targets = append(targets, ip)
}
}
return targets
}
func addBondSlaveAttrs(bondSlave *BondSlave, linkInfo *nl.RtAttr) {
data := linkInfo.AddRtAttr(nl.IFLA_INFO_SLAVE_DATA, nil)
data.AddRtAttr(nl.IFLA_BOND_SLAVE_STATE, nl.Uint8Attr(uint8(bondSlave.State)))
data.AddRtAttr(nl.IFLA_BOND_SLAVE_MII_STATUS, nl.Uint8Attr(uint8(bondSlave.MiiStatus)))
data.AddRtAttr(nl.IFLA_BOND_SLAVE_LINK_FAILURE_COUNT, nl.Uint32Attr(bondSlave.LinkFailureCount))
data.AddRtAttr(nl.IFLA_BOND_SLAVE_QUEUE_ID, nl.Uint16Attr(bondSlave.QueueId))
data.AddRtAttr(nl.IFLA_BOND_SLAVE_AD_AGGREGATOR_ID, nl.Uint16Attr(bondSlave.AggregatorId))
data.AddRtAttr(nl.IFLA_BOND_SLAVE_AD_ACTOR_OPER_PORT_STATE, nl.Uint8Attr(bondSlave.AdActorOperPortState))
data.AddRtAttr(nl.IFLA_BOND_SLAVE_AD_PARTNER_OPER_PORT_STATE, nl.Uint16Attr(bondSlave.AdPartnerOperPortState))
if mac := bondSlave.PermHardwareAddr; mac != nil {
data.AddRtAttr(nl.IFLA_BOND_SLAVE_PERM_HWADDR, []byte(mac))
}
}
func parseBondSlaveData(slave LinkSlave, data []syscall.NetlinkRouteAttr) {
bondSlave := slave.(*BondSlave)
for i := range data {
switch data[i].Attr.Type {
case nl.IFLA_BOND_SLAVE_STATE:
bondSlave.State = BondSlaveState(data[i].Value[0])
case nl.IFLA_BOND_SLAVE_MII_STATUS:
bondSlave.MiiStatus = BondSlaveMiiStatus(data[i].Value[0])
case nl.IFLA_BOND_SLAVE_LINK_FAILURE_COUNT:
bondSlave.LinkFailureCount = native.Uint32(data[i].Value[0:4])
case nl.IFLA_BOND_SLAVE_PERM_HWADDR:
bondSlave.PermHardwareAddr = net.HardwareAddr(data[i].Value[0:6])
case nl.IFLA_BOND_SLAVE_QUEUE_ID:
bondSlave.QueueId = native.Uint16(data[i].Value[0:2])
case nl.IFLA_BOND_SLAVE_AD_AGGREGATOR_ID:
bondSlave.AggregatorId = native.Uint16(data[i].Value[0:2])
case nl.IFLA_BOND_SLAVE_AD_ACTOR_OPER_PORT_STATE:
bondSlave.AdActorOperPortState = uint8(data[i].Value[0])
case nl.IFLA_BOND_SLAVE_AD_PARTNER_OPER_PORT_STATE:
bondSlave.AdPartnerOperPortState = native.Uint16(data[i].Value[0:2])
}
}
}
func parseIPVlanData(link Link, data []syscall.NetlinkRouteAttr) {
ipv := link.(*IPVlan)
for _, datum := range data {
switch datum.Attr.Type {
case nl.IFLA_IPVLAN_MODE:
ipv.Mode = IPVlanMode(native.Uint32(datum.Value[0:4]))
case nl.IFLA_IPVLAN_FLAG:
ipv.Flag = IPVlanFlag(native.Uint32(datum.Value[0:4]))
}
}
}
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 {
switch datum.Attr.Type {
case 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
}
case nl.IFLA_MACVLAN_MACADDR_COUNT:
macv.MACAddrs = make([]net.HardwareAddr, 0, int(native.Uint32(datum.Value[0:4])))
case nl.IFLA_MACVLAN_MACADDR_DATA:
macs, err := nl.ParseRouteAttr(datum.Value[:])
if err != nil {
panic(fmt.Sprintf("failed to ParseRouteAttr for IFLA_MACVLAN_MACADDR_DATA: %v", err))
}
for _, macDatum := range macs {
macv.MACAddrs = append(macv.MACAddrs, net.HardwareAddr(macDatum.Value[0:6]))
}
}
}
}
// copied from pkg/net_linux.go
func linkFlags(rawFlags uint32) net.Flags {
var f net.Flags
if rawFlags&unix.IFF_UP != 0 {
f |= net.FlagUp
}
if rawFlags&unix.IFF_BROADCAST != 0 {
f |= net.FlagBroadcast
}
if rawFlags&unix.IFF_LOOPBACK != 0 {
f |= net.FlagLoopback
}
if rawFlags&unix.IFF_POINTOPOINT != 0 {
f |= net.FlagPointToPoint
}
if rawFlags&unix.IFF_MULTICAST != 0 {
f |= net.FlagMulticast
}
return f
}
func addGeneveAttrs(geneve *Geneve, linkInfo *nl.RtAttr) {
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
if geneve.FlowBased {
// In flow based mode, no other attributes need to be configured
linkInfo.AddRtAttr(nl.IFLA_GENEVE_COLLECT_METADATA, boolAttr(geneve.FlowBased))
return
}
if ip := geneve.Remote; ip != nil {
if ip4 := ip.To4(); ip4 != nil {
data.AddRtAttr(nl.IFLA_GENEVE_REMOTE, ip.To4())
} else {
data.AddRtAttr(nl.IFLA_GENEVE_REMOTE6, []byte(ip))
}
}
if geneve.ID != 0 {
data.AddRtAttr(nl.IFLA_GENEVE_ID, nl.Uint32Attr(geneve.ID))
}
if geneve.Dport != 0 {
data.AddRtAttr(nl.IFLA_GENEVE_PORT, htons(geneve.Dport))
}
if geneve.Ttl != 0 {
data.AddRtAttr(nl.IFLA_GENEVE_TTL, nl.Uint8Attr(geneve.Ttl))
}
if geneve.Tos != 0 {
data.AddRtAttr(nl.IFLA_GENEVE_TOS, nl.Uint8Attr(geneve.Tos))
}
}
func parseGeneveData(link Link, data []syscall.NetlinkRouteAttr) {
geneve := link.(*Geneve)
for _, datum := range data {
switch datum.Attr.Type {
case nl.IFLA_GENEVE_ID:
geneve.ID = native.Uint32(datum.Value[0:4])
case nl.IFLA_GENEVE_REMOTE, nl.IFLA_GENEVE_REMOTE6:
geneve.Remote = datum.Value
case nl.IFLA_GENEVE_PORT:
geneve.Dport = ntohs(datum.Value[0:2])
case nl.IFLA_GENEVE_TTL:
geneve.Ttl = uint8(datum.Value[0])
case nl.IFLA_GENEVE_TOS:
geneve.Tos = uint8(datum.Value[0])
}
}
}
func addGretapAttrs(gretap *Gretap, linkInfo *nl.RtAttr) {
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
if gretap.FlowBased {
// In flow based mode, no other attributes need to be configured
data.AddRtAttr(nl.IFLA_GRE_COLLECT_METADATA, boolAttr(gretap.FlowBased))
return
}
if ip := gretap.Local; ip != nil {
if ip.To4() != nil {
ip = ip.To4()
}
data.AddRtAttr(nl.IFLA_GRE_LOCAL, []byte(ip))
}
if ip := gretap.Remote; ip != nil {
if ip.To4() != nil {
ip = ip.To4()
}
data.AddRtAttr(nl.IFLA_GRE_REMOTE, []byte(ip))
}
if gretap.IKey != 0 {
data.AddRtAttr(nl.IFLA_GRE_IKEY, htonl(gretap.IKey))
gretap.IFlags |= uint16(nl.GRE_KEY)
}
if gretap.OKey != 0 {
data.AddRtAttr(nl.IFLA_GRE_OKEY, htonl(gretap.OKey))
gretap.OFlags |= uint16(nl.GRE_KEY)
}
data.AddRtAttr(nl.IFLA_GRE_IFLAGS, htons(gretap.IFlags))
data.AddRtAttr(nl.IFLA_GRE_OFLAGS, htons(gretap.OFlags))
if gretap.Link != 0 {
data.AddRtAttr(nl.IFLA_GRE_LINK, nl.Uint32Attr(gretap.Link))
}
data.AddRtAttr(nl.IFLA_GRE_PMTUDISC, nl.Uint8Attr(gretap.PMtuDisc))
data.AddRtAttr(nl.IFLA_GRE_TTL, nl.Uint8Attr(gretap.Ttl))
data.AddRtAttr(nl.IFLA_GRE_TOS, nl.Uint8Attr(gretap.Tos))
data.AddRtAttr(nl.IFLA_GRE_ENCAP_TYPE, nl.Uint16Attr(gretap.EncapType))
data.AddRtAttr(nl.IFLA_GRE_ENCAP_FLAGS, nl.Uint16Attr(gretap.EncapFlags))
data.AddRtAttr(nl.IFLA_GRE_ENCAP_SPORT, htons(gretap.EncapSport))
data.AddRtAttr(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)
case nl.IFLA_GRE_REMOTE:
gre.Remote = net.IP(datum.Value)
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])
case nl.IFLA_GRE_COLLECT_METADATA:
gre.FlowBased = true
}
}
}
func addGretunAttrs(gre *Gretun, linkInfo *nl.RtAttr) {
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
if ip := gre.Local; ip != nil {
if ip.To4() != nil {
ip = ip.To4()
}
data.AddRtAttr(nl.IFLA_GRE_LOCAL, []byte(ip))
}
if ip := gre.Remote; ip != nil {
if ip.To4() != nil {
ip = ip.To4()
}
data.AddRtAttr(nl.IFLA_GRE_REMOTE, []byte(ip))
}
if gre.IKey != 0 {
data.AddRtAttr(nl.IFLA_GRE_IKEY, htonl(gre.IKey))
gre.IFlags |= uint16(nl.GRE_KEY)
}
if gre.OKey != 0 {
data.AddRtAttr(nl.IFLA_GRE_OKEY, htonl(gre.OKey))
gre.OFlags |= uint16(nl.GRE_KEY)
}
data.AddRtAttr(nl.IFLA_GRE_IFLAGS, htons(gre.IFlags))
data.AddRtAttr(nl.IFLA_GRE_OFLAGS, htons(gre.OFlags))
if gre.Link != 0 {
data.AddRtAttr(nl.IFLA_GRE_LINK, nl.Uint32Attr(gre.Link))
}
data.AddRtAttr(nl.IFLA_GRE_PMTUDISC, nl.Uint8Attr(gre.PMtuDisc))
data.AddRtAttr(nl.IFLA_GRE_TTL, nl.Uint8Attr(gre.Ttl))
data.AddRtAttr(nl.IFLA_GRE_TOS, nl.Uint8Attr(gre.Tos))
data.AddRtAttr(nl.IFLA_GRE_ENCAP_TYPE, nl.Uint16Attr(gre.EncapType))
data.AddRtAttr(nl.IFLA_GRE_ENCAP_FLAGS, nl.Uint16Attr(gre.EncapFlags))
data.AddRtAttr(nl.IFLA_GRE_ENCAP_SPORT, htons(gre.EncapSport))
data.AddRtAttr(nl.IFLA_GRE_ENCAP_DPORT, htons(gre.EncapDport))
}
func parseGretunData(link Link, data []syscall.NetlinkRouteAttr) {
gre := link.(*Gretun)
for _, datum := range data {
switch datum.Attr.Type {
case nl.IFLA_GRE_IKEY:
gre.IKey = ntohl(datum.Value[0:4])
case nl.IFLA_GRE_OKEY:
gre.OKey = ntohl(datum.Value[0:4])
case nl.IFLA_GRE_LOCAL:
gre.Local = net.IP(datum.Value)
case nl.IFLA_GRE_REMOTE:
gre.Remote = net.IP(datum.Value)
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])
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])
}
}
}
func addXdpAttrs(xdp *LinkXdp, req *nl.NetlinkRequest) {
attrs := nl.NewRtAttr(unix.IFLA_XDP|unix.NLA_F_NESTED, nil)
b := make([]byte, 4)
native.PutUint32(b, uint32(xdp.Fd))
attrs.AddRtAttr(nl.IFLA_XDP_FD, b)
if xdp.Flags != 0 {
b := make([]byte, 4)
native.PutUint32(b, xdp.Flags)
attrs.AddRtAttr(nl.IFLA_XDP_FLAGS, 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.AttachMode = uint32(attr.Value[0])
xdp.Attached = xdp.AttachMode != 0
case nl.IFLA_XDP_FLAGS:
xdp.Flags = native.Uint32(attr.Value[0:4])
case nl.IFLA_XDP_PROG_ID:
xdp.ProgId = native.Uint32(attr.Value[0:4])
}
}
return xdp, nil
}
func addIptunAttrs(iptun *Iptun, linkInfo *nl.RtAttr) {
if iptun.FlowBased {
// In flow based mode, no other attributes need to be configured
linkInfo.AddRtAttr(nl.IFLA_IPTUN_COLLECT_METADATA, boolAttr(iptun.FlowBased))
return
}
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
ip := iptun.Local.To4()
if ip != nil {
data.AddRtAttr(nl.IFLA_IPTUN_LOCAL, []byte(ip))
}
ip = iptun.Remote.To4()
if ip != nil {
data.AddRtAttr(nl.IFLA_IPTUN_REMOTE, []byte(ip))
}
if iptun.Link != 0 {
data.AddRtAttr(nl.IFLA_IPTUN_LINK, nl.Uint32Attr(iptun.Link))
}
data.AddRtAttr(nl.IFLA_IPTUN_PMTUDISC, nl.Uint8Attr(iptun.PMtuDisc))
data.AddRtAttr(nl.IFLA_IPTUN_TTL, nl.Uint8Attr(iptun.Ttl))
data.AddRtAttr(nl.IFLA_IPTUN_TOS, nl.Uint8Attr(iptun.Tos))
data.AddRtAttr(nl.IFLA_IPTUN_ENCAP_TYPE, nl.Uint16Attr(iptun.EncapType))
data.AddRtAttr(nl.IFLA_IPTUN_ENCAP_FLAGS, nl.Uint16Attr(iptun.EncapFlags))
data.AddRtAttr(nl.IFLA_IPTUN_ENCAP_SPORT, htons(iptun.EncapSport))
data.AddRtAttr(nl.IFLA_IPTUN_ENCAP_DPORT, htons(iptun.EncapDport))
}
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])
case nl.IFLA_IPTUN_ENCAP_SPORT:
iptun.EncapSport = ntohs(datum.Value[0:2])
case nl.IFLA_IPTUN_ENCAP_DPORT:
iptun.EncapDport = ntohs(datum.Value[0:2])
case nl.IFLA_IPTUN_ENCAP_TYPE:
iptun.EncapType = native.Uint16(datum.Value[0:2])
case nl.IFLA_IPTUN_ENCAP_FLAGS:
iptun.EncapFlags = native.Uint16(datum.Value[0:2])
case nl.IFLA_IPTUN_COLLECT_METADATA:
iptun.FlowBased = true
}
}
}
func addIp6tnlAttrs(ip6tnl *Ip6tnl, linkInfo *nl.RtAttr) {
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
if ip6tnl.Link != 0 {
data.AddRtAttr(nl.IFLA_IPTUN_LINK, nl.Uint32Attr(ip6tnl.Link))
}
ip := ip6tnl.Local.To16()
if ip != nil {
data.AddRtAttr(nl.IFLA_IPTUN_LOCAL, []byte(ip))
}
ip = ip6tnl.Remote.To16()
if ip != nil {
data.AddRtAttr(nl.IFLA_IPTUN_REMOTE, []byte(ip))
}
data.AddRtAttr(nl.IFLA_IPTUN_TTL, nl.Uint8Attr(ip6tnl.Ttl))
data.AddRtAttr(nl.IFLA_IPTUN_TOS, nl.Uint8Attr(ip6tnl.Tos))
data.AddRtAttr(nl.IFLA_IPTUN_FLAGS, nl.Uint32Attr(ip6tnl.Flags))
data.AddRtAttr(nl.IFLA_IPTUN_PROTO, nl.Uint8Attr(ip6tnl.Proto))
data.AddRtAttr(nl.IFLA_IPTUN_FLOWINFO, nl.Uint32Attr(ip6tnl.FlowInfo))
data.AddRtAttr(nl.IFLA_IPTUN_ENCAP_LIMIT, nl.Uint8Attr(ip6tnl.EncapLimit))
data.AddRtAttr(nl.IFLA_IPTUN_ENCAP_TYPE, nl.Uint16Attr(ip6tnl.EncapType))
data.AddRtAttr(nl.IFLA_IPTUN_ENCAP_FLAGS, nl.Uint16Attr(ip6tnl.EncapFlags))
data.AddRtAttr(nl.IFLA_IPTUN_ENCAP_SPORT, htons(ip6tnl.EncapSport))
data.AddRtAttr(nl.IFLA_IPTUN_ENCAP_DPORT, htons(ip6tnl.EncapDport))
}
func parseIp6tnlData(link Link, data []syscall.NetlinkRouteAttr) {
ip6tnl := link.(*Ip6tnl)
for _, datum := range data {
switch datum.Attr.Type {
case nl.IFLA_IPTUN_LOCAL:
ip6tnl.Local = net.IP(datum.Value[:16])
case nl.IFLA_IPTUN_REMOTE:
ip6tnl.Remote = net.IP(datum.Value[:16])
case nl.IFLA_IPTUN_TTL:
ip6tnl.Ttl = datum.Value[0]
case nl.IFLA_IPTUN_TOS:
ip6tnl.Tos = datum.Value[0]
case nl.IFLA_IPTUN_FLAGS:
ip6tnl.Flags = native.Uint32(datum.Value[:4])
case nl.IFLA_IPTUN_PROTO:
ip6tnl.Proto = datum.Value[0]
case nl.IFLA_IPTUN_FLOWINFO:
ip6tnl.FlowInfo = native.Uint32(datum.Value[:4])
case nl.IFLA_IPTUN_ENCAP_LIMIT:
ip6tnl.EncapLimit = datum.Value[0]
case nl.IFLA_IPTUN_ENCAP_TYPE:
ip6tnl.EncapType = native.Uint16(datum.Value[0:2])
case nl.IFLA_IPTUN_ENCAP_FLAGS:
ip6tnl.EncapFlags = native.Uint16(datum.Value[0:2])
case nl.IFLA_IPTUN_ENCAP_SPORT:
ip6tnl.EncapSport = ntohs(datum.Value[0:2])
case nl.IFLA_IPTUN_ENCAP_DPORT:
ip6tnl.EncapDport = ntohs(datum.Value[0:2])
}
}
}
func addSittunAttrs(sittun *Sittun, linkInfo *nl.RtAttr) {
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
if sittun.Link != 0 {
data.AddRtAttr(nl.IFLA_IPTUN_LINK, nl.Uint32Attr(sittun.Link))
}
ip := sittun.Local.To4()
if ip != nil {
data.AddRtAttr(nl.IFLA_IPTUN_LOCAL, []byte(ip))
}
ip = sittun.Remote.To4()
if ip != nil {
data.AddRtAttr(nl.IFLA_IPTUN_REMOTE, []byte(ip))
}
if sittun.Ttl > 0 {
// Would otherwise fail on 3.10 kernel
data.AddRtAttr(nl.IFLA_IPTUN_TTL, nl.Uint8Attr(sittun.Ttl))
}
data.AddRtAttr(nl.IFLA_IPTUN_PROTO, nl.Uint8Attr(sittun.Proto))
data.AddRtAttr(nl.IFLA_IPTUN_TOS, nl.Uint8Attr(sittun.Tos))
data.AddRtAttr(nl.IFLA_IPTUN_PMTUDISC, nl.Uint8Attr(sittun.PMtuDisc))
data.AddRtAttr(nl.IFLA_IPTUN_ENCAP_LIMIT, nl.Uint8Attr(sittun.EncapLimit))
data.AddRtAttr(nl.IFLA_IPTUN_ENCAP_TYPE, nl.Uint16Attr(sittun.EncapType))
data.AddRtAttr(nl.IFLA_IPTUN_ENCAP_FLAGS, nl.Uint16Attr(sittun.EncapFlags))
data.AddRtAttr(nl.IFLA_IPTUN_ENCAP_SPORT, htons(sittun.EncapSport))
data.AddRtAttr(nl.IFLA_IPTUN_ENCAP_DPORT, htons(sittun.EncapDport))
}
func parseSittunData(link Link, data []syscall.NetlinkRouteAttr) {
sittun := link.(*Sittun)
for _, datum := range data {
switch datum.Attr.Type {
case nl.IFLA_IPTUN_LOCAL:
sittun.Local = net.IP(datum.Value[0:4])
case nl.IFLA_IPTUN_REMOTE:
sittun.Remote = net.IP(datum.Value[0:4])
case nl.IFLA_IPTUN_TTL:
sittun.Ttl = datum.Value[0]
case nl.IFLA_IPTUN_TOS:
sittun.Tos = datum.Value[0]
case nl.IFLA_IPTUN_PMTUDISC:
sittun.PMtuDisc = datum.Value[0]
case nl.IFLA_IPTUN_PROTO:
sittun.Proto = datum.Value[0]
case nl.IFLA_IPTUN_ENCAP_TYPE:
sittun.EncapType = native.Uint16(datum.Value[0:2])
case nl.IFLA_IPTUN_ENCAP_FLAGS:
sittun.EncapFlags = native.Uint16(datum.Value[0:2])
case nl.IFLA_IPTUN_ENCAP_SPORT:
sittun.EncapSport = ntohs(datum.Value[0:2])
case nl.IFLA_IPTUN_ENCAP_DPORT:
sittun.EncapDport = ntohs(datum.Value[0:2])
}
}
}
func addVtiAttrs(vti *Vti, linkInfo *nl.RtAttr) {
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
family := FAMILY_V4
if vti.Local.To4() == nil {
family = FAMILY_V6
}
var ip net.IP
if family == FAMILY_V4 {
ip = vti.Local.To4()
} else {
ip = vti.Local
}
if ip != nil {
data.AddRtAttr(nl.IFLA_VTI_LOCAL, []byte(ip))
}
if family == FAMILY_V4 {
ip = vti.Remote.To4()
} else {
ip = vti.Remote
}
if ip != nil {
data.AddRtAttr(nl.IFLA_VTI_REMOTE, []byte(ip))
}
if vti.Link != 0 {
data.AddRtAttr(nl.IFLA_VTI_LINK, nl.Uint32Attr(vti.Link))
}
data.AddRtAttr(nl.IFLA_VTI_IKEY, htonl(vti.IKey))
data.AddRtAttr(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)
case nl.IFLA_VTI_REMOTE:
vti.Remote = net.IP(datum.Value)
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 := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
b := make([]byte, 4)
native.PutUint32(b, uint32(vrf.Table))
data.AddRtAttr(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])
}
}
}
func addBridgeAttrs(bridge *Bridge, linkInfo *nl.RtAttr) {
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
if bridge.MulticastSnooping != nil {
data.AddRtAttr(nl.IFLA_BR_MCAST_SNOOPING, boolToByte(*bridge.MulticastSnooping))
}
if bridge.AgeingTime != nil {
data.AddRtAttr(nl.IFLA_BR_AGEING_TIME, nl.Uint32Attr(*bridge.AgeingTime))
}
if bridge.HelloTime != nil {
data.AddRtAttr(nl.IFLA_BR_HELLO_TIME, nl.Uint32Attr(*bridge.HelloTime))
}
if bridge.VlanFiltering != nil {
data.AddRtAttr(nl.IFLA_BR_VLAN_FILTERING, boolToByte(*bridge.VlanFiltering))
}
}
func parseBridgeData(bridge Link, data []syscall.NetlinkRouteAttr) {
br := bridge.(*Bridge)
for _, datum := range data {
switch datum.Attr.Type {
case nl.IFLA_BR_AGEING_TIME:
ageingTime := native.Uint32(datum.Value[0:4])
br.AgeingTime = &ageingTime
case nl.IFLA_BR_HELLO_TIME:
helloTime := native.Uint32(datum.Value[0:4])
br.HelloTime = &helloTime
case nl.IFLA_BR_MCAST_SNOOPING:
mcastSnooping := datum.Value[0] == 1
br.MulticastSnooping = &mcastSnooping
case nl.IFLA_BR_VLAN_FILTERING:
vlanFiltering := datum.Value[0] == 1
br.VlanFiltering = &vlanFiltering
}
}
}
func addGTPAttrs(gtp *GTP, linkInfo *nl.RtAttr) {
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
data.AddRtAttr(nl.IFLA_GTP_FD0, nl.Uint32Attr(uint32(gtp.FD0)))
data.AddRtAttr(nl.IFLA_GTP_FD1, nl.Uint32Attr(uint32(gtp.FD1)))
data.AddRtAttr(nl.IFLA_GTP_PDP_HASHSIZE, nl.Uint32Attr(131072))
if gtp.Role != nl.GTP_ROLE_GGSN {
data.AddRtAttr(nl.IFLA_GTP_ROLE, nl.Uint32Attr(uint32(gtp.Role)))
}
}
func parseGTPData(link Link, data []syscall.NetlinkRouteAttr) {
gtp := link.(*GTP)
for _, datum := range data {
switch datum.Attr.Type {
case nl.IFLA_GTP_FD0:
gtp.FD0 = int(native.Uint32(datum.Value))
case nl.IFLA_GTP_FD1:
gtp.FD1 = int(native.Uint32(datum.Value))
case nl.IFLA_GTP_PDP_HASHSIZE:
gtp.PDPHashsize = int(native.Uint32(datum.Value))
case nl.IFLA_GTP_ROLE:
gtp.Role = int(native.Uint32(datum.Value))
}
}
}
func parseVfInfoList(data []syscall.NetlinkRouteAttr) ([]VfInfo, error) {
var vfs []VfInfo
for i, element := range data {
if element.Attr.Type != nl.IFLA_VF_INFO {
return nil, fmt.Errorf("Incorrect element type in vf info list: %d", element.Attr.Type)
}
vfAttrs, err := nl.ParseRouteAttr(element.Value)
if err != nil {
return nil, err
}
vfs = append(vfs, parseVfInfo(vfAttrs, i))
}
return vfs, nil
}
func parseVfInfo(data []syscall.NetlinkRouteAttr, id int) VfInfo {
vf := VfInfo{ID: id}
for _, element := range data {
switch element.Attr.Type {
case nl.IFLA_VF_MAC:
mac := nl.DeserializeVfMac(element.Value[:])
vf.Mac = mac.Mac[:6]
case nl.IFLA_VF_VLAN:
vl := nl.DeserializeVfVlan(element.Value[:])
vf.Vlan = int(vl.Vlan)
vf.Qos = int(vl.Qos)
case nl.IFLA_VF_TX_RATE:
txr := nl.DeserializeVfTxRate(element.Value[:])
vf.TxRate = int(txr.Rate)
case nl.IFLA_VF_SPOOFCHK:
sp := nl.DeserializeVfSpoofchk(element.Value[:])
vf.Spoofchk = sp.Setting != 0
case nl.IFLA_VF_LINK_STATE:
ls := nl.DeserializeVfLinkState(element.Value[:])
vf.LinkState = ls.LinkState
case nl.IFLA_VF_RATE:
vfr := nl.DeserializeVfRate(element.Value[:])
vf.MaxTxRate = vfr.MaxTxRate
vf.MinTxRate = vfr.MinTxRate
case nl.IFLA_VF_STATS:
vfstats := nl.DeserializeVfStats(element.Value[:])
vf.RxPackets = vfstats.RxPackets
vf.TxPackets = vfstats.TxPackets
vf.RxBytes = vfstats.RxBytes
vf.TxBytes = vfstats.TxBytes
vf.Multicast = vfstats.Multicast
vf.Broadcast = vfstats.Broadcast
vf.RxDropped = vfstats.RxDropped
vf.TxDropped = vfstats.TxDropped
case nl.IFLA_VF_RSS_QUERY_EN:
result := nl.DeserializeVfRssQueryEn(element.Value)
vf.RssQuery = result.Setting
case nl.IFLA_VF_TRUST:
result := nl.DeserializeVfTrust(element.Value)
vf.Trust = result.Setting
}
}
return vf
}
func addXfrmiAttrs(xfrmi *Xfrmi, linkInfo *nl.RtAttr) {
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
data.AddRtAttr(nl.IFLA_XFRM_LINK, nl.Uint32Attr(uint32(xfrmi.ParentIndex)))
data.AddRtAttr(nl.IFLA_XFRM_IF_ID, nl.Uint32Attr(xfrmi.Ifid))
}
func parseXfrmiData(link Link, data []syscall.NetlinkRouteAttr) {
xfrmi := link.(*Xfrmi)
for _, datum := range data {
switch datum.Attr.Type {
case nl.IFLA_XFRM_LINK:
xfrmi.ParentIndex = int(native.Uint32(datum.Value))
case nl.IFLA_XFRM_IF_ID:
xfrmi.Ifid = native.Uint32(datum.Value)
}
}
}
// LinkSetBondSlave add slave to bond link via ioctl interface.
func LinkSetBondSlave(link Link, master *Bond) error {
fd, err := getSocketUDP()
if err != nil {
return err
}
defer syscall.Close(fd)
ifreq := newIocltSlaveReq(link.Attrs().Name, master.Attrs().Name)
_, _, errno := syscall.Syscall(syscall.SYS_IOCTL, uintptr(fd), unix.SIOCBONDENSLAVE, uintptr(unsafe.Pointer(ifreq)))
if errno != 0 {
return fmt.Errorf("Failed to enslave %q to %q, errno=%v", link.Attrs().Name, master.Attrs().Name, errno)
}
return nil
}
// LinkSetBondSlaveQueueId modify bond slave queue-id.
func (h *Handle) LinkSetBondSlaveQueueId(link Link, queueId uint16) error {
base := link.Attrs()
h.ensureIndex(base)
req := h.newNetlinkRequest(unix.RTM_SETLINK, unix.NLM_F_ACK)
msg := nl.NewIfInfomsg(unix.AF_UNSPEC)
msg.Index = int32(base.Index)
req.AddData(msg)
linkInfo := nl.NewRtAttr(unix.IFLA_LINKINFO, nil)
data := linkInfo.AddRtAttr(nl.IFLA_INFO_SLAVE_DATA, nil)
data.AddRtAttr(nl.IFLA_BOND_SLAVE_QUEUE_ID, nl.Uint16Attr(queueId))
req.AddData(linkInfo)
_, err := req.Execute(unix.NETLINK_ROUTE, 0)
return err
}
// LinkSetBondSlaveQueueId modify bond slave queue-id.
func LinkSetBondSlaveQueueId(link Link, queueId uint16) error {
return pkgHandle.LinkSetBondSlaveQueueId(link, queueId)
}
func vethStatsSerialize(stats ethtoolStats) ([]byte, error) {
statsSize := int(unsafe.Sizeof(stats)) + int(stats.nStats)*int(unsafe.Sizeof(uint64(0)))
b := make([]byte, 0, statsSize)
buf := bytes.NewBuffer(b)
err := binary.Write(buf, nl.NativeEndian(), stats)
return buf.Bytes()[:statsSize], err
}
type vethEthtoolStats struct {
Cmd uint32
NStats uint32
Peer uint64
// Newer kernels have XDP stats in here, but we only care
// to extract the peer ifindex here.
}
func vethStatsDeserialize(b []byte) (vethEthtoolStats, error) {
var stats = vethEthtoolStats{}
err := binary.Read(bytes.NewReader(b), nl.NativeEndian(), &stats)
return stats, err
}
// VethPeerIndex get veth peer index.
func VethPeerIndex(link *Veth) (int, error) {
fd, err := getSocketUDP()
if err != nil {
return -1, err
}
defer syscall.Close(fd)
ifreq, sSet := newIocltStringSetReq(link.Name)
_, _, errno := syscall.Syscall(syscall.SYS_IOCTL, uintptr(fd), SIOCETHTOOL, uintptr(unsafe.Pointer(ifreq)))
if errno != 0 {
return -1, fmt.Errorf("SIOCETHTOOL request for %q failed, errno=%v", link.Attrs().Name, errno)
}
stats := ethtoolStats{
cmd: ETHTOOL_GSTATS,
nStats: sSet.data[0],
}
buffer, err := vethStatsSerialize(stats)
if err != nil {
return -1, err
}
ifreq.Data = uintptr(unsafe.Pointer(&buffer[0]))
_, _, errno = syscall.Syscall(syscall.SYS_IOCTL, uintptr(fd), SIOCETHTOOL, uintptr(unsafe.Pointer(ifreq)))
if errno != 0 {
return -1, fmt.Errorf("SIOCETHTOOL request for %q failed, errno=%v", link.Attrs().Name, errno)
}
vstats, err := vethStatsDeserialize(buffer)
if err != nil {
return -1, err
}
return int(vstats.Peer), nil
}
func parseTuntapData(link Link, data []syscall.NetlinkRouteAttr) {
tuntap := link.(*Tuntap)
for _, datum := range data {
switch datum.Attr.Type {
case nl.IFLA_TUN_OWNER:
tuntap.Owner = native.Uint32(datum.Value)
case nl.IFLA_TUN_GROUP:
tuntap.Group = native.Uint32(datum.Value)
case nl.IFLA_TUN_TYPE:
tuntap.Mode = TuntapMode(uint8(datum.Value[0]))
case nl.IFLA_TUN_PERSIST:
tuntap.NonPersist = false
if uint8(datum.Value[0]) == 0 {
tuntap.NonPersist = true
}
}
}
}
func parseIPoIBData(link Link, data []syscall.NetlinkRouteAttr) {
ipoib := link.(*IPoIB)
for _, datum := range data {
switch datum.Attr.Type {
case nl.IFLA_IPOIB_PKEY:
ipoib.Pkey = uint16(native.Uint16(datum.Value))
case nl.IFLA_IPOIB_MODE:
ipoib.Mode = IPoIBMode(native.Uint16(datum.Value))
case nl.IFLA_IPOIB_UMCAST:
ipoib.Umcast = uint16(native.Uint16(datum.Value))
}
}
}
func parseCanData(link Link, data []syscall.NetlinkRouteAttr) {
can := link.(*Can)
for _, datum := range data {
switch datum.Attr.Type {
case nl.IFLA_CAN_BITTIMING:
can.BitRate = native.Uint32(datum.Value)
can.SamplePoint = native.Uint32(datum.Value[4:])
can.TimeQuanta = native.Uint32(datum.Value[8:])
can.PropagationSegment = native.Uint32(datum.Value[12:])
can.PhaseSegment1 = native.Uint32(datum.Value[16:])
can.PhaseSegment2 = native.Uint32(datum.Value[20:])
can.SyncJumpWidth = native.Uint32(datum.Value[24:])
can.BitRatePreScaler = native.Uint32(datum.Value[28:])
case nl.IFLA_CAN_BITTIMING_CONST:
can.Name = string(datum.Value[:16])
can.TimeSegment1Min = native.Uint32(datum.Value[16:])
can.TimeSegment1Max = native.Uint32(datum.Value[20:])
can.TimeSegment2Min = native.Uint32(datum.Value[24:])
can.TimeSegment2Max = native.Uint32(datum.Value[28:])
can.SyncJumpWidthMax = native.Uint32(datum.Value[32:])
can.BitRatePreScalerMin = native.Uint32(datum.Value[36:])
can.BitRatePreScalerMax = native.Uint32(datum.Value[40:])
can.BitRatePreScalerInc = native.Uint32(datum.Value[44:])
case nl.IFLA_CAN_CLOCK:
can.ClockFrequency = native.Uint32(datum.Value)
case nl.IFLA_CAN_STATE:
can.State = native.Uint32(datum.Value)
case nl.IFLA_CAN_CTRLMODE:
can.Mask = native.Uint32(datum.Value)
can.Flags = native.Uint32(datum.Value[4:])
case nl.IFLA_CAN_BERR_COUNTER:
can.TxError = native.Uint16(datum.Value)
can.RxError = native.Uint16(datum.Value[2:])
case nl.IFLA_CAN_RESTART_MS:
can.RestartMs = native.Uint32(datum.Value)
case nl.IFLA_CAN_DATA_BITTIMING_CONST:
case nl.IFLA_CAN_RESTART:
case nl.IFLA_CAN_DATA_BITTIMING:
case nl.IFLA_CAN_TERMINATION:
case nl.IFLA_CAN_TERMINATION_CONST:
case nl.IFLA_CAN_BITRATE_CONST:
case nl.IFLA_CAN_DATA_BITRATE_CONST:
case nl.IFLA_CAN_BITRATE_MAX:
}
}
}
func addIPoIBAttrs(ipoib *IPoIB, linkInfo *nl.RtAttr) {
data := linkInfo.AddRtAttr(nl.IFLA_INFO_DATA, nil)
data.AddRtAttr(nl.IFLA_IPOIB_PKEY, nl.Uint16Attr(uint16(ipoib.Pkey)))
data.AddRtAttr(nl.IFLA_IPOIB_MODE, nl.Uint16Attr(uint16(ipoib.Mode)))
data.AddRtAttr(nl.IFLA_IPOIB_UMCAST, nl.Uint16Attr(uint16(ipoib.Umcast)))
}
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