sure

reuse control on gso
reuse GRO slices
2025-11-22 16:34:25 +01:00 · 2025-11-03 17:23:57 +00:00 · 2025-11-03 11:14:52 +00:00 · 2025-11-03 11:06:07 +00:00 · 2025-11-03 10:52:09 +00:00 · 2025-11-03 10:45:30 +00:00
54 changed files with 4890 additions and 4997 deletions
--- a/batch_pipeline.go
+++ b/batch_pipeline.go
@@ -1,164 +0,0 @@
 package nebula
 import (
 	"net/netip"
 	"github.com/slackhq/nebula/overlay"
 	"github.com/slackhq/nebula/udp"
 )
 // batchPipelines tracks whether the inside device can operate on packet batches
 // and, if so, holds the shared packet pool sized for the virtio headroom and
 // payload limits advertised by the device. It also owns the fan-in/fan-out
 // queues between the TUN readers, encrypt/decrypt workers, and the UDP writers.
 type batchPipelines struct {
 	enabled    bool
 	inside     overlay.BatchCapableDevice
 	headroom   int
 	payloadCap int
 	pool       *overlay.PacketPool
 	batchSize  int
 	routines   int
 	rxQueues   []chan *overlay.Packet
 	txQueues   []chan queuedDatagram
 	tunQueues  []chan *overlay.Packet
 }
 type queuedDatagram struct {
 	packet *overlay.Packet
 	addr   netip.AddrPort
 }
 func (bp *batchPipelines) init(device overlay.Device, routines int, queueDepth int, maxSegments int) {
 	if device == nil || routines <= 0 {
 		return
 	}
 	bcap, ok := device.(overlay.BatchCapableDevice)
 	if !ok {
 		return
 	}
 	headroom := bcap.BatchHeadroom()
 	payload := bcap.BatchPayloadCap()
 	if maxSegments < 1 {
 		maxSegments = 1
 	}
 	requiredPayload := udp.MTU * maxSegments
 	if payload < requiredPayload {
 		payload = requiredPayload
 	}
 	batchSize := bcap.BatchSize()
 	if headroom <= 0 || payload <= 0 || batchSize <= 0 {
 		return
 	}
 	bp.enabled = true
 	bp.inside = bcap
 	bp.headroom = headroom
 	bp.payloadCap = payload
 	bp.batchSize = batchSize
 	bp.routines = routines
 	bp.pool = overlay.NewPacketPool(headroom, payload)
 	queueCap := batchSize * defaultBatchQueueDepthFactor
 	if queueDepth > 0 {
 		queueCap = queueDepth
 	}
 	if queueCap < batchSize {
 		queueCap = batchSize
 	}
 	bp.rxQueues = make([]chan *overlay.Packet, routines)
 	bp.txQueues = make([]chan queuedDatagram, routines)
 	bp.tunQueues = make([]chan *overlay.Packet, routines)
 	for i := 0; i < routines; i++ {
 		bp.rxQueues[i] = make(chan *overlay.Packet, queueCap)
 		bp.txQueues[i] = make(chan queuedDatagram, queueCap)
 		bp.tunQueues[i] = make(chan *overlay.Packet, queueCap)
 	}
 }
 func (bp *batchPipelines) Pool() *overlay.PacketPool {
 	if bp == nil || !bp.enabled {
 		return nil
 	}
 	return bp.pool
 }
 func (bp *batchPipelines) Enabled() bool {
 	return bp != nil && bp.enabled
 }
 func (bp *batchPipelines) batchSizeHint() int {
 	if bp == nil || bp.batchSize <= 0 {
 		return 1
 	}
 	return bp.batchSize
 }
 func (bp *batchPipelines) rxQueue(i int) chan *overlay.Packet {
 	if bp == nil || !bp.enabled || i < 0 || i >= len(bp.rxQueues) {
 		return nil
 	}
 	return bp.rxQueues[i]
 }
 func (bp *batchPipelines) txQueue(i int) chan queuedDatagram {
 	if bp == nil || !bp.enabled || i < 0 || i >= len(bp.txQueues) {
 		return nil
 	}
 	return bp.txQueues[i]
 }
 func (bp *batchPipelines) tunQueue(i int) chan *overlay.Packet {
 	if bp == nil || !bp.enabled || i < 0 || i >= len(bp.tunQueues) {
 		return nil
 	}
 	return bp.tunQueues[i]
 }
 func (bp *batchPipelines) txQueueLen(i int) int {
 	q := bp.txQueue(i)
 	if q == nil {
 		return 0
 	}
 	return len(q)
 }
 func (bp *batchPipelines) tunQueueLen(i int) int {
 	q := bp.tunQueue(i)
 	if q == nil {
 		return 0
 	}
 	return len(q)
 }
 func (bp *batchPipelines) enqueueRx(i int, pkt *overlay.Packet) bool {
 	q := bp.rxQueue(i)
 	if q == nil {
 		return false
 	}
 	q <- pkt
 	return true
 }
 func (bp *batchPipelines) enqueueTx(i int, pkt *overlay.Packet, addr netip.AddrPort) bool {
 	q := bp.txQueue(i)
 	if q == nil {
 		return false
 	}
 	q <- queuedDatagram{packet: pkt, addr: addr}
 	return true
 }
 func (bp *batchPipelines) enqueueTun(i int, pkt *overlay.Packet) bool {
 	q := bp.tunQueue(i)
 	if q == nil {
 		return false
 	}
 	q <- pkt
 	return true
 }
 func (bp *batchPipelines) newPacket() *overlay.Packet {
 	if bp == nil || !bp.enabled || bp.pool == nil {
 		return nil
 	}
 	return bp.pool.Get()
 }
--- a/cert/pem.go
+++ b/cert/pem.go
@@ -140,101 +140,6 @@ func MarshalSigningPrivateKeyToPEM(curve Curve, b []byte) []byte {
 	}
 }
 // Backward compatibility functions for older API
 func MarshalX25519PublicKey(b []byte) []byte {
 	return MarshalPublicKeyToPEM(Curve_CURVE25519, b)
 }
 func MarshalX25519PrivateKey(b []byte) []byte {
 	return MarshalPrivateKeyToPEM(Curve_CURVE25519, b)
 }
 func MarshalPublicKey(curve Curve, b []byte) []byte {
 	return MarshalPublicKeyToPEM(curve, b)
 }
 func MarshalPrivateKey(curve Curve, b []byte) []byte {
 	return MarshalPrivateKeyToPEM(curve, b)
 }
 // NebulaCertificate is a compatibility wrapper for the old API
 type NebulaCertificate struct {
 	Details   NebulaCertificateDetails
 	Signature []byte
 	cert      Certificate
 }
 // NebulaCertificateDetails is a compatibility wrapper for certificate details
 type NebulaCertificateDetails struct {
 	Name      string
 	NotBefore time.Time
 	NotAfter  time.Time
 	PublicKey []byte
 	IsCA      bool
 	Issuer    []byte
 	Curve     Curve
 }
 // UnmarshalNebulaCertificateFromPEM provides backward compatibility with the old API
 func UnmarshalNebulaCertificateFromPEM(b []byte) (*NebulaCertificate, []byte, error) {
 	c, rest, err := UnmarshalCertificateFromPEM(b)
 	if err != nil {
 		return nil, rest, err
 	}
 	issuerBytes, err := func() ([]byte, error) {
 		issuer := c.Issuer()
 		if issuer == "" {
 			return nil, nil
 		}
 		decoded, err := hex.DecodeString(issuer)
 		if err != nil {
 			return nil, fmt.Errorf("failed to decode issuer fingerprint: %w", err)
 		}
 		return decoded, nil
 	}()
 	if err != nil {
 		return nil, rest, err
 	}
 	pubKey := c.PublicKey()
 	if pubKey != nil {
 		pubKey = append([]byte(nil), pubKey...)
 	}
 	sig := c.Signature()
 	if sig != nil {
 		sig = append([]byte(nil), sig...)
 	}
 	return &NebulaCertificate{
 		Details: NebulaCertificateDetails{
 			Name:      c.Name(),
 			NotBefore: c.NotBefore(),
 			NotAfter:  c.NotAfter(),
 			PublicKey: pubKey,
 			IsCA:      c.IsCA(),
 			Issuer:    issuerBytes,
 			Curve:     c.Curve(),
 		},
 		Signature: sig,
 		cert:      c,
 	}, rest, nil
 }
 // IssuerString returns the issuer in hex format for compatibility
 func (n *NebulaCertificate) IssuerString() string {
 	if n.Details.Issuer == nil {
 		return ""
 	}
 	return hex.EncodeToString(n.Details.Issuer)
 }
 // Certificate returns the underlying certificate (read-only)
 func (n *NebulaCertificate) Certificate() Certificate {
 	return n.cert
 }
 // UnmarshalPrivateKeyFromPEM will try to unmarshal the first pem block in a byte array, returning any non
 // consumed data or an error on failure
 func UnmarshalPrivateKeyFromPEM(b []byte) ([]byte, []byte, Curve, error) {
@@ -286,3 +191,71 @@ func UnmarshalSigningPrivateKeyFromPEM(b []byte) ([]byte, []byte, Curve, error)
 	}
 	return k.Bytes, r, curve, nil
 }
 // Backward compatibility functions for older API
 func MarshalX25519PublicKey(b []byte) []byte {
 	return MarshalPublicKeyToPEM(Curve_CURVE25519, b)
 }
 func MarshalX25519PrivateKey(b []byte) []byte {
 	return MarshalPrivateKeyToPEM(Curve_CURVE25519, b)
 }
 func MarshalPublicKey(curve Curve, b []byte) []byte {
 	return MarshalPublicKeyToPEM(curve, b)
 }
 func MarshalPrivateKey(curve Curve, b []byte) []byte {
 	return MarshalPrivateKeyToPEM(curve, b)
 }
 // NebulaCertificate is a compatibility wrapper for the old API
 type NebulaCertificate struct {
 	Details   NebulaCertificateDetails
 	Signature []byte
 	cert      Certificate
 }
 // NebulaCertificateDetails is a compatibility wrapper for certificate details
 type NebulaCertificateDetails struct {
 	Name      string
 	NotBefore time.Time
 	NotAfter  time.Time
 	PublicKey []byte
 	IsCA      bool
 	Issuer    []byte
 	Curve     Curve
 }
 // UnmarshalNebulaCertificateFromPEM provides backward compatibility with the old API
 func UnmarshalNebulaCertificateFromPEM(b []byte) (*NebulaCertificate, []byte, error) {
 	c, rest, err := UnmarshalCertificateFromPEM(b)
 	if err != nil {
 		return nil, rest, err
 	}
 	// Convert to old format
 	nc := &NebulaCertificate{
 		Details: NebulaCertificateDetails{
 			Name:      c.Name(),
 			NotBefore: c.NotBefore(),
 			NotAfter:  c.NotAfter(),
 			PublicKey: c.PublicKey(),
 			IsCA:      c.IsCA(),
 			Curve:     c.Curve(),
 		},
 		Signature: c.Signature(),
 		cert:      c,
 	}
 	// Handle issuer
 	if c.Issuer() != "" {
 		issuerBytes, err := hex.DecodeString(c.Issuer())
 		if err != nil {
 			return nil, rest, fmt.Errorf("failed to decode issuer fingerprint: %w", err)
 		}
 		nc.Details.Issuer = issuerBytes
 	}
 	return nc, rest, nil
 }
--- a/cert_test/cert.go
+++ b/cert_test/cert.go
@@ -114,33 +114,6 @@ func NewTestCert(v cert.Version, curve cert.Curve, ca cert.Certificate, key []by
 	return c, pub, cert.MarshalPrivateKeyToPEM(curve, priv), pem
 }
 func NewTestCertDifferentVersion(c cert.Certificate, v cert.Version, ca cert.Certificate, key []byte) (cert.Certificate, []byte) {
 	nc := &cert.TBSCertificate{
 		Version:        v,
 		Curve:          c.Curve(),
 		Name:           c.Name(),
 		Networks:       c.Networks(),
 		UnsafeNetworks: c.UnsafeNetworks(),
 		Groups:         c.Groups(),
 		NotBefore:      time.Unix(c.NotBefore().Unix(), 0),
 		NotAfter:       time.Unix(c.NotAfter().Unix(), 0),
 		PublicKey:      c.PublicKey(),
 		IsCA:           false,
 	}
 	c, err := nc.Sign(ca, ca.Curve(), key)
 	if err != nil {
 		panic(err)
 	}
 	pem, err := c.MarshalPEM()
 	if err != nil {
 		panic(err)
 	}
 	return c, pem
 }
 func X25519Keypair() ([]byte, []byte) {
 	privkey := make([]byte, 32)
 	if _, err := io.ReadFull(rand.Reader, privkey); err != nil {
--- a/connection_manager.go
+++ b/connection_manager.go
@@ -354,6 +354,7 @@ func (cm *connectionManager) makeTrafficDecision(localIndex uint32, now time.Tim
 		if mainHostInfo {
 			decision = tryRehandshake
 		} else {
 			if cm.shouldSwapPrimary(hostinfo) {
 				decision = swapPrimary
@@ -460,10 +461,6 @@ func (cm *connectionManager) shouldSwapPrimary(current *HostInfo) bool {
 	}
 	crt := cm.intf.pki.getCertState().getCertificate(current.ConnectionState.myCert.Version())
 	if crt == nil {
 		//my cert was reloaded away. We should definitely swap from this tunnel
 		return true
 	}
 	// If this tunnel is using the latest certificate then we should swap it to primary for a bit and see if things
 	// settle down.
 	return bytes.Equal(current.ConnectionState.myCert.Signature(), crt.Signature())
@@ -478,34 +475,31 @@ func (cm *connectionManager) swapPrimary(current, primary *HostInfo) {
 	cm.hostMap.Unlock()
 }
-// isInvalidCertificate decides if we should destroy a tunnel.
+// isInvalidCertificate will check if we should destroy a tunnel if pki.disconnect_invalid is true and
-// returns true if pki.disconnect_invalid is true and the certificate is no longer valid.
+// the certificate is no longer valid. Block listed certificates will skip the pki.disconnect_invalid
-// Blocklisted certificates will skip the pki.disconnect_invalid check and return true.
+// check and return true.
 func (cm *connectionManager) isInvalidCertificate(now time.Time, hostinfo *HostInfo) bool {
 	remoteCert := hostinfo.GetCert()
 	if remoteCert == nil {
-		return false //don't tear down tunnels for handshakes in progress
+		return false
 	}
 	caPool := cm.intf.pki.GetCAPool()
 	err := caPool.VerifyCachedCertificate(now, remoteCert)
 	if err == nil {
 		return false //cert is still valid! yay!
 	} else if err == cert.ErrBlockListed { //avoiding errors.Is for speed
 		// Block listed certificates should always be disconnected
 		hostinfo.logger(cm.l).WithError(err).
 			WithField("fingerprint", remoteCert.Fingerprint).
 			Info("Remote certificate is blocked, tearing down the tunnel")
 		return true
 	} else if cm.intf.disconnectInvalid.Load() {
 		hostinfo.logger(cm.l).WithError(err).
 			WithField("fingerprint", remoteCert.Fingerprint).
 			Info("Remote certificate is no longer valid, tearing down the tunnel")
 		return true
 	} else {
 		//if we reach here, the cert is no longer valid, but we're configured to keep tunnels from now-invalid certs open
 		return false
 	}
 	if !cm.intf.disconnectInvalid.Load() && err != cert.ErrBlockListed {
 		// Block listed certificates should always be disconnected
 		return false
 	}
 	hostinfo.logger(cm.l).WithError(err).
 		WithField("fingerprint", remoteCert.Fingerprint).
 		Info("Remote certificate is no longer valid, tearing down the tunnel")
 	return true
 }
 func (cm *connectionManager) sendPunch(hostinfo *HostInfo) {
@@ -536,45 +530,15 @@ func (cm *connectionManager) sendPunch(hostinfo *HostInfo) {
 func (cm *connectionManager) tryRehandshake(hostinfo *HostInfo) {
 	cs := cm.intf.pki.getCertState()
 	curCrt := hostinfo.ConnectionState.myCert
-	curCrtVersion := curCrt.Version()
+	myCrt := cs.getCertificate(curCrt.Version())
-	myCrt := cs.getCertificate(curCrtVersion)
+	if curCrt.Version() >= cs.initiatingVersion && bytes.Equal(curCrt.Signature(), myCrt.Signature()) == true {
-	if myCrt == nil {
+		// The current tunnel is using the latest certificate and version, no need to rehandshake.
 		cm.l.WithField("vpnAddrs", hostinfo.vpnAddrs).
 			WithField("version", curCrtVersion).
 			WithField("reason", "local certificate removed").
 			Info("Re-handshaking with remote")
 		cm.intf.handshakeManager.StartHandshake(hostinfo.vpnAddrs[0], nil)
 		return
 	}
 	peerCrt := hostinfo.ConnectionState.peerCert
 	if peerCrt != nil && curCrtVersion < peerCrt.Certificate.Version() {
 		// if our certificate version is less than theirs, and we have a matching version available, rehandshake?
 		if cs.getCertificate(peerCrt.Certificate.Version()) != nil {
 			cm.l.WithField("vpnAddrs", hostinfo.vpnAddrs).
 				WithField("version", curCrtVersion).
 				WithField("peerVersion", peerCrt.Certificate.Version()).
 				WithField("reason", "local certificate version lower than peer, attempting to correct").
 				Info("Re-handshaking with remote")
 			cm.intf.handshakeManager.StartHandshake(hostinfo.vpnAddrs[0], func(hh *HandshakeHostInfo) {
 				hh.initiatingVersionOverride = peerCrt.Certificate.Version()
 			})
 			return
 		}
 	}
 	if !bytes.Equal(curCrt.Signature(), myCrt.Signature()) {
 		cm.l.WithField("vpnAddrs", hostinfo.vpnAddrs).
 			WithField("reason", "local certificate is not current").
 			Info("Re-handshaking with remote")
-		cm.intf.handshakeManager.StartHandshake(hostinfo.vpnAddrs[0], nil)
+	cm.l.WithField("vpnAddrs", hostinfo.vpnAddrs).
-		return
+		WithField("reason", "local certificate is not current").
-	}
+		Info("Re-handshaking with remote")
 	if curCrtVersion < cs.initiatingVersion {
 		cm.l.WithField("vpnAddrs", hostinfo.vpnAddrs).
 			WithField("reason", "current cert version < pki.initiatingVersion").
 			Info("Re-handshaking with remote")
-		cm.intf.handshakeManager.StartHandshake(hostinfo.vpnAddrs[0], nil)
+	cm.intf.handshakeManager.StartHandshake(hostinfo.vpnAddrs[0], nil)
 		return
 	}
 }
--- a/e2e/helpers_test.go
+++ b/e2e/helpers_test.go
@@ -129,109 +129,6 @@ func newSimpleServer(v cert.Version, caCrt cert.Certificate, caKey []byte, name
 	return control, vpnNetworks, udpAddr, c
 }
 // newServer creates a nebula instance with fewer assumptions
 func newServer(caCrt []cert.Certificate, certs []cert.Certificate, key []byte, overrides m) (*nebula.Control, []netip.Prefix, netip.AddrPort, *config.C) {
 	l := NewTestLogger()
 	vpnNetworks := certs[len(certs)-1].Networks()
 	var udpAddr netip.AddrPort
 	if vpnNetworks[0].Addr().Is4() {
 		budpIp := vpnNetworks[0].Addr().As4()
 		budpIp[1] -= 128
 		udpAddr = netip.AddrPortFrom(netip.AddrFrom4(budpIp), 4242)
 	} else {
 		budpIp := vpnNetworks[0].Addr().As16()
 		// beef for funsies
 		budpIp[2] = 190
 		budpIp[3] = 239
 		udpAddr = netip.AddrPortFrom(netip.AddrFrom16(budpIp), 4242)
 	}
 	caStr := ""
 	for _, ca := range caCrt {
 		x, err := ca.MarshalPEM()
 		if err != nil {
 			panic(err)
 		}
 		caStr += string(x)
 	}
 	certStr := ""
 	for _, c := range certs {
 		x, err := c.MarshalPEM()
 		if err != nil {
 			panic(err)
 		}
 		certStr += string(x)
 	}
 	mc := m{
 		"pki": m{
 			"ca":   caStr,
 			"cert": certStr,
 			"key":  string(key),
 		},
 		//"tun": m{"disabled": true},
 		"firewall": m{
 			"outbound": []m{{
 				"proto": "any",
 				"port":  "any",
 				"host":  "any",
 			}},
 			"inbound": []m{{
 				"proto": "any",
 				"port":  "any",
 				"host":  "any",
 			}},
 		},
 		//"handshakes": m{
 		//	"try_interval": "1s",
 		//},
 		"listen": m{
 			"host": udpAddr.Addr().String(),
 			"port": udpAddr.Port(),
 		},
 		"logging": m{
 			"timestamp_format": fmt.Sprintf("%v 15:04:05.000000", certs[0].Name()),
 			"level":            l.Level.String(),
 		},
 		"timers": m{
 			"pending_deletion_interval": 2,
 			"connection_alive_interval": 2,
 		},
 	}
 	if overrides != nil {
 		final := m{}
 		err := mergo.Merge(&final, overrides, mergo.WithAppendSlice)
 		if err != nil {
 			panic(err)
 		}
 		err = mergo.Merge(&final, mc, mergo.WithAppendSlice)
 		if err != nil {
 			panic(err)
 		}
 		mc = final
 	}
 	cb, err := yaml.Marshal(mc)
 	if err != nil {
 		panic(err)
 	}
 	c := config.NewC(l)
 	cStr := string(cb)
 	c.LoadString(cStr)
 	control, err := nebula.Main(c, false, "e2e-test", l, nil)
 	if err != nil {
 		panic(err)
 	}
 	return control, vpnNetworks, udpAddr, c
 }
 type doneCb func()
 func deadline(t *testing.T, seconds time.Duration) doneCb {
--- a/e2e/tunnels_test.go
+++ b/e2e/tunnels_test.go
@@ -4,16 +4,12 @@
 package e2e
 import (
 	"fmt"
 	"net/netip"
 	"testing"
 	"time"
 	"github.com/slackhq/nebula/cert"
 	"github.com/slackhq/nebula/cert_test"
 	"github.com/slackhq/nebula/e2e/router"
 	"github.com/stretchr/testify/assert"
 	"gopkg.in/yaml.v3"
 )
 func TestDropInactiveTunnels(t *testing.T) {
@@ -59,262 +55,3 @@ func TestDropInactiveTunnels(t *testing.T) {
 	myControl.Stop()
 	theirControl.Stop()
 }
 func TestCertUpgrade(t *testing.T) {
 	// The goal of this test is to ensure the shortest inactivity timeout will close the tunnel on both sides
 	// under ideal conditions
 	ca, _, caKey, _ := cert_test.NewTestCaCert(cert.Version1, cert.Curve_CURVE25519, time.Now(), time.Now().Add(10*time.Minute), nil, nil, []string{})
 	caB, err := ca.MarshalPEM()
 	if err != nil {
 		panic(err)
 	}
 	ca2, _, caKey2, _ := cert_test.NewTestCaCert(cert.Version2, cert.Curve_CURVE25519, time.Now(), time.Now().Add(10*time.Minute), nil, nil, []string{})
 	ca2B, err := ca2.MarshalPEM()
 	if err != nil {
 		panic(err)
 	}
 	caStr := fmt.Sprintf("%s\n%s", caB, ca2B)
 	myCert, _, myPrivKey, _ := cert_test.NewTestCert(cert.Version1, cert.Curve_CURVE25519, ca, caKey, "me", time.Now(), time.Now().Add(5*time.Minute), []netip.Prefix{netip.MustParsePrefix("10.128.0.1/24")}, nil, []string{})
 	_, myCert2Pem := cert_test.NewTestCertDifferentVersion(myCert, cert.Version2, ca2, caKey2)
 	theirCert, _, theirPrivKey, _ := cert_test.NewTestCert(cert.Version1, cert.Curve_CURVE25519, ca, caKey, "them", time.Now(), time.Now().Add(5*time.Minute), []netip.Prefix{netip.MustParsePrefix("10.128.0.2/24")}, nil, []string{})
 	theirCert2, _ := cert_test.NewTestCertDifferentVersion(theirCert, cert.Version2, ca2, caKey2)
 	myControl, myVpnIpNet, myUdpAddr, myC := newServer([]cert.Certificate{ca, ca2}, []cert.Certificate{myCert}, myPrivKey, m{})
 	theirControl, theirVpnIpNet, theirUdpAddr, _ := newServer([]cert.Certificate{ca, ca2}, []cert.Certificate{theirCert, theirCert2}, theirPrivKey, m{})
 	// Share our underlay information
 	myControl.InjectLightHouseAddr(theirVpnIpNet[0].Addr(), theirUdpAddr)
 	theirControl.InjectLightHouseAddr(myVpnIpNet[0].Addr(), myUdpAddr)
 	// Start the servers
 	myControl.Start()
 	theirControl.Start()
 	r := router.NewR(t, myControl, theirControl)
 	defer r.RenderFlow()
 	r.Log("Assert the tunnel between me and them works")
 	assertTunnel(t, myVpnIpNet[0].Addr(), theirVpnIpNet[0].Addr(), myControl, theirControl, r)
 	r.Log("yay")
 	//todo ???
 	time.Sleep(1 * time.Second)
 	r.FlushAll()
 	mc := m{
 		"pki": m{
 			"ca":   caStr,
 			"cert": string(myCert2Pem),
 			"key":  string(myPrivKey),
 		},
 		//"tun": m{"disabled": true},
 		"firewall": myC.Settings["firewall"],
 		//"handshakes": m{
 		//	"try_interval": "1s",
 		//},
 		"listen":  myC.Settings["listen"],
 		"logging": myC.Settings["logging"],
 		"timers":  myC.Settings["timers"],
 	}
 	cb, err := yaml.Marshal(mc)
 	if err != nil {
 		panic(err)
 	}
 	r.Logf("reload new v2-only config")
 	err = myC.ReloadConfigString(string(cb))
 	assert.NoError(t, err)
 	r.Log("yay, spin until their sees it")
 	waitStart := time.Now()
 	for {
 		assertTunnel(t, myVpnIpNet[0].Addr(), theirVpnIpNet[0].Addr(), myControl, theirControl, r)
 		c := theirControl.GetHostInfoByVpnAddr(myVpnIpNet[0].Addr(), false)
 		if c == nil {
 			r.Log("nil")
 		} else {
 			version := c.Cert.Version()
 			r.Logf("version %d", version)
 			if version == cert.Version2 {
 				break
 			}
 		}
 		since := time.Since(waitStart)
 		if since > time.Second*10 {
 			t.Fatal("Cert should be new by now")
 		}
 		time.Sleep(time.Second)
 	}
 	r.RenderHostmaps("Final hostmaps", myControl, theirControl)
 	myControl.Stop()
 	theirControl.Stop()
 }
 func TestCertDowngrade(t *testing.T) {
 	// The goal of this test is to ensure the shortest inactivity timeout will close the tunnel on both sides
 	// under ideal conditions
 	ca, _, caKey, _ := cert_test.NewTestCaCert(cert.Version1, cert.Curve_CURVE25519, time.Now(), time.Now().Add(10*time.Minute), nil, nil, []string{})
 	caB, err := ca.MarshalPEM()
 	if err != nil {
 		panic(err)
 	}
 	ca2, _, caKey2, _ := cert_test.NewTestCaCert(cert.Version2, cert.Curve_CURVE25519, time.Now(), time.Now().Add(10*time.Minute), nil, nil, []string{})
 	ca2B, err := ca2.MarshalPEM()
 	if err != nil {
 		panic(err)
 	}
 	caStr := fmt.Sprintf("%s\n%s", caB, ca2B)
 	myCert, _, myPrivKey, myCertPem := cert_test.NewTestCert(cert.Version1, cert.Curve_CURVE25519, ca, caKey, "me", time.Now(), time.Now().Add(5*time.Minute), []netip.Prefix{netip.MustParsePrefix("10.128.0.1/24")}, nil, []string{})
 	myCert2, _ := cert_test.NewTestCertDifferentVersion(myCert, cert.Version2, ca2, caKey2)
 	theirCert, _, theirPrivKey, _ := cert_test.NewTestCert(cert.Version1, cert.Curve_CURVE25519, ca, caKey, "them", time.Now(), time.Now().Add(5*time.Minute), []netip.Prefix{netip.MustParsePrefix("10.128.0.2/24")}, nil, []string{})
 	theirCert2, _ := cert_test.NewTestCertDifferentVersion(theirCert, cert.Version2, ca2, caKey2)
 	myControl, myVpnIpNet, myUdpAddr, myC := newServer([]cert.Certificate{ca, ca2}, []cert.Certificate{myCert2}, myPrivKey, m{})
 	theirControl, theirVpnIpNet, theirUdpAddr, _ := newServer([]cert.Certificate{ca, ca2}, []cert.Certificate{theirCert, theirCert2}, theirPrivKey, m{})
 	// Share our underlay information
 	myControl.InjectLightHouseAddr(theirVpnIpNet[0].Addr(), theirUdpAddr)
 	theirControl.InjectLightHouseAddr(myVpnIpNet[0].Addr(), myUdpAddr)
 	// Start the servers
 	myControl.Start()
 	theirControl.Start()
 	r := router.NewR(t, myControl, theirControl)
 	defer r.RenderFlow()
 	r.Log("Assert the tunnel between me and them works")
 	//assertTunnel(t, theirVpnIpNet[0].Addr(), myVpnIpNet[0].Addr(), theirControl, myControl, r)
 	//r.Log("yay")
 	assertTunnel(t, myVpnIpNet[0].Addr(), theirVpnIpNet[0].Addr(), myControl, theirControl, r)
 	r.Log("yay")
 	//todo ???
 	time.Sleep(1 * time.Second)
 	r.FlushAll()
 	mc := m{
 		"pki": m{
 			"ca":   caStr,
 			"cert": string(myCertPem),
 			"key":  string(myPrivKey),
 		},
 		"firewall": myC.Settings["firewall"],
 		"listen":   myC.Settings["listen"],
 		"logging":  myC.Settings["logging"],
 		"timers":   myC.Settings["timers"],
 	}
 	cb, err := yaml.Marshal(mc)
 	if err != nil {
 		panic(err)
 	}
 	r.Logf("reload new v1-only config")
 	err = myC.ReloadConfigString(string(cb))
 	assert.NoError(t, err)
 	r.Log("yay, spin until their sees it")
 	waitStart := time.Now()
 	for {
 		assertTunnel(t, myVpnIpNet[0].Addr(), theirVpnIpNet[0].Addr(), myControl, theirControl, r)
 		c := theirControl.GetHostInfoByVpnAddr(myVpnIpNet[0].Addr(), false)
 		c2 := myControl.GetHostInfoByVpnAddr(theirVpnIpNet[0].Addr(), false)
 		if c == nil || c2 == nil {
 			r.Log("nil")
 		} else {
 			version := c.Cert.Version()
 			theirVersion := c2.Cert.Version()
 			r.Logf("version %d,%d", version, theirVersion)
 			if version == cert.Version1 {
 				break
 			}
 		}
 		since := time.Since(waitStart)
 		if since > time.Second*5 {
 			r.Log("it is unusual that the cert is not new yet, but not a failure yet")
 		}
 		if since > time.Second*10 {
 			r.Log("wtf")
 			t.Fatal("Cert should be new by now")
 		}
 		time.Sleep(time.Second)
 	}
 	r.RenderHostmaps("Final hostmaps", myControl, theirControl)
 	myControl.Stop()
 	theirControl.Stop()
 }
 func TestCertMismatchCorrection(t *testing.T) {
 	// The goal of this test is to ensure the shortest inactivity timeout will close the tunnel on both sides
 	// under ideal conditions
 	ca, _, caKey, _ := cert_test.NewTestCaCert(cert.Version1, cert.Curve_CURVE25519, time.Now(), time.Now().Add(10*time.Minute), nil, nil, []string{})
 	ca2, _, caKey2, _ := cert_test.NewTestCaCert(cert.Version2, cert.Curve_CURVE25519, time.Now(), time.Now().Add(10*time.Minute), nil, nil, []string{})
 	myCert, _, myPrivKey, _ := cert_test.NewTestCert(cert.Version1, cert.Curve_CURVE25519, ca, caKey, "me", time.Now(), time.Now().Add(5*time.Minute), []netip.Prefix{netip.MustParsePrefix("10.128.0.1/24")}, nil, []string{})
 	myCert2, _ := cert_test.NewTestCertDifferentVersion(myCert, cert.Version2, ca2, caKey2)
 	theirCert, _, theirPrivKey, _ := cert_test.NewTestCert(cert.Version1, cert.Curve_CURVE25519, ca, caKey, "them", time.Now(), time.Now().Add(5*time.Minute), []netip.Prefix{netip.MustParsePrefix("10.128.0.2/24")}, nil, []string{})
 	theirCert2, _ := cert_test.NewTestCertDifferentVersion(theirCert, cert.Version2, ca2, caKey2)
 	myControl, myVpnIpNet, myUdpAddr, _ := newServer([]cert.Certificate{ca, ca2}, []cert.Certificate{myCert2}, myPrivKey, m{})
 	theirControl, theirVpnIpNet, theirUdpAddr, _ := newServer([]cert.Certificate{ca, ca2}, []cert.Certificate{theirCert, theirCert2}, theirPrivKey, m{})
 	// Share our underlay information
 	myControl.InjectLightHouseAddr(theirVpnIpNet[0].Addr(), theirUdpAddr)
 	theirControl.InjectLightHouseAddr(myVpnIpNet[0].Addr(), myUdpAddr)
 	// Start the servers
 	myControl.Start()
 	theirControl.Start()
 	r := router.NewR(t, myControl, theirControl)
 	defer r.RenderFlow()
 	r.Log("Assert the tunnel between me and them works")
 	//assertTunnel(t, theirVpnIpNet[0].Addr(), myVpnIpNet[0].Addr(), theirControl, myControl, r)
 	//r.Log("yay")
 	assertTunnel(t, myVpnIpNet[0].Addr(), theirVpnIpNet[0].Addr(), myControl, theirControl, r)
 	r.Log("yay")
 	//todo ???
 	time.Sleep(1 * time.Second)
 	r.FlushAll()
 	waitStart := time.Now()
 	for {
 		assertTunnel(t, myVpnIpNet[0].Addr(), theirVpnIpNet[0].Addr(), myControl, theirControl, r)
 		c := theirControl.GetHostInfoByVpnAddr(myVpnIpNet[0].Addr(), false)
 		c2 := myControl.GetHostInfoByVpnAddr(theirVpnIpNet[0].Addr(), false)
 		if c == nil || c2 == nil {
 			r.Log("nil")
 		} else {
 			version := c.Cert.Version()
 			theirVersion := c2.Cert.Version()
 			r.Logf("version %d,%d", version, theirVersion)
 			if version == theirVersion {
 				break
 			}
 		}
 		since := time.Since(waitStart)
 		if since > time.Second*5 {
 			r.Log("wtf")
 		}
 		if since > time.Second*10 {
 			r.Log("wtf")
 			t.Fatal("Cert should be new by now")
 		}
 		time.Sleep(time.Second)
 	}
 	r.RenderHostmaps("Final hostmaps", myControl, theirControl)
 	myControl.Stop()
 	theirControl.Stop()
 }
--- a/firewall.go
+++ b/firewall.go
@@ -423,7 +423,7 @@ var ErrNoMatchingRule = errors.New("no matching rule in firewall table")
 // Drop returns an error if the packet should be dropped, explaining why. It
 // returns nil if the packet should not be dropped.
-func (f *Firewall) Drop(fp firewall.Packet, incoming bool, h *HostInfo, caPool *cert.CAPool, localCache *firewall.ConntrackCache) error {
+func (f *Firewall) Drop(fp firewall.Packet, incoming bool, h *HostInfo, caPool *cert.CAPool, localCache firewall.ConntrackCache) error {
 	// Check if we spoke to this tuple, if we did then allow this packet
 	if f.inConns(fp, h, caPool, localCache) {
 		return nil
@@ -490,9 +490,11 @@ func (f *Firewall) EmitStats() {
 	metrics.GetOrRegisterGauge("firewall.rules.hash", nil).Update(int64(f.GetRuleHashFNV()))
 }
-func (f *Firewall) inConns(fp firewall.Packet, h *HostInfo, caPool *cert.CAPool, localCache *firewall.ConntrackCache) bool {
+func (f *Firewall) inConns(fp firewall.Packet, h *HostInfo, caPool *cert.CAPool, localCache firewall.ConntrackCache) bool {
-	if localCache != nil && localCache.Has(fp) {
+	if localCache != nil {
-		return true
+		if _, ok := localCache[fp]; ok {
 			return true
 		}
 	}
 	conntrack := f.Conntrack
 	conntrack.Lock()
@@ -557,7 +559,7 @@ func (f *Firewall) inConns(fp firewall.Packet, h *HostInfo, caPool *cert.CAPool,
 	conntrack.Unlock()
 	if localCache != nil {
-		localCache.Add(fp)
+		localCache[fp] = struct{}{}
 	}
 	return true
--- a/firewall/cache.go
+++ b/firewall/cache.go
@@ -1,7 +1,6 @@
 package firewall
 import (
 	"sync"
 	"sync/atomic"
 	"time"
@@ -10,58 +9,13 @@ import (
 // ConntrackCache is used as a local routine cache to know if a given flow
 // has been seen in the conntrack table.
-type ConntrackCache struct {
+type ConntrackCache map[Packet]struct{}
 	mu      sync.Mutex
 	entries map[Packet]struct{}
 }
 func newConntrackCache() *ConntrackCache {
 	return &ConntrackCache{entries: make(map[Packet]struct{})}
 }
 func (c *ConntrackCache) Has(p Packet) bool {
 	if c == nil {
 		return false
 	}
 	c.mu.Lock()
 	_, ok := c.entries[p]
 	c.mu.Unlock()
 	return ok
 }
 func (c *ConntrackCache) Add(p Packet) {
 	if c == nil {
 		return
 	}
 	c.mu.Lock()
 	c.entries[p] = struct{}{}
 	c.mu.Unlock()
 }
 func (c *ConntrackCache) Len() int {
 	if c == nil {
 		return 0
 	}
 	c.mu.Lock()
 	l := len(c.entries)
 	c.mu.Unlock()
 	return l
 }
 func (c *ConntrackCache) Reset(capHint int) {
 	if c == nil {
 		return
 	}
 	c.mu.Lock()
 	c.entries = make(map[Packet]struct{}, capHint)
 	c.mu.Unlock()
 }
 type ConntrackCacheTicker struct {
 	cacheV    uint64
 	cacheTick atomic.Uint64
-	cache *ConntrackCache
+	cache ConntrackCache
 }
 func NewConntrackCacheTicker(d time.Duration) *ConntrackCacheTicker {
@@ -69,7 +23,9 @@ func NewConntrackCacheTicker(d time.Duration) *ConntrackCacheTicker {
 		return nil
 	}
-	c := &ConntrackCacheTicker{cache: newConntrackCache()}
+	c := &ConntrackCacheTicker{
 		cache: ConntrackCache{},
 	}
 	go c.tick(d)
@@ -85,17 +41,17 @@ func (c *ConntrackCacheTicker) tick(d time.Duration) {
 // Get checks if the cache ticker has moved to the next version before returning
 // the map. If it has moved, we reset the map.
-func (c *ConntrackCacheTicker) Get(l *logrus.Logger) *ConntrackCache {
+func (c *ConntrackCacheTicker) Get(l *logrus.Logger) ConntrackCache {
 	if c == nil {
 		return nil
 	}
 	if tick := c.cacheTick.Load(); tick != c.cacheV {
 		c.cacheV = tick
-		if ll := c.cache.Len(); ll > 0 {
+		if ll := len(c.cache); ll > 0 {
 			if l.Level == logrus.DebugLevel {
 				l.WithField("len", ll).Debug("resetting conntrack cache")
 			}
-			c.cache.Reset(ll)
+			c.cache = make(ConntrackCache, ll)
 		}
 	}
--- a/handshake_ix.go
+++ b/handshake_ix.go
@@ -23,17 +23,13 @@ func ixHandshakeStage0(f *Interface, hh *HandshakeHostInfo) bool {
 		return false
 	}
 	// If we're connecting to a v6 address we must use a v2 cert
 	cs := f.pki.getCertState()
 	v := cs.initiatingVersion
-	if hh.initiatingVersionOverride != cert.VersionPre1 {
+	for _, a := range hh.hostinfo.vpnAddrs {
-		v = hh.initiatingVersionOverride
+		if a.Is6() {
-	} else if v < cert.Version2 {
+			v = cert.Version2
-		// If we're connecting to a v6 address we should encourage use of a V2 cert
+			break
 		for _, a := range hh.hostinfo.vpnAddrs {
 			if a.Is6() {
 				v = cert.Version2
 				break
 			}
 		}
 	}
@@ -52,7 +48,6 @@ func ixHandshakeStage0(f *Interface, hh *HandshakeHostInfo) bool {
 			WithField("handshake", m{"stage": 0, "style": "ix_psk0"}).
 			WithField("certVersion", v).
 			Error("Unable to handshake with host because no certificate handshake bytes is available")
 		return false
 	}
 	ci, err := NewConnectionState(f.l, cs, crt, true, noise.HandshakeIX)
@@ -108,7 +103,6 @@ func ixHandshakeStage1(f *Interface, addr netip.AddrPort, via *ViaSender, packet
 			WithField("handshake", m{"stage": 0, "style": "ix_psk0"}).
 			WithField("certVersion", cs.initiatingVersion).
 			Error("Unable to handshake with host because no certificate is available")
 		return
 	}
 	ci, err := NewConnectionState(f.l, cs, crt, false, noise.HandshakeIX)
@@ -149,8 +143,8 @@ func ixHandshakeStage1(f *Interface, addr netip.AddrPort, via *ViaSender, packet
 	remoteCert, err := f.pki.GetCAPool().VerifyCertificate(time.Now(), rc)
 	if err != nil {
-		fp, fperr := rc.Fingerprint()
+		fp, err := rc.Fingerprint()
-		if fperr != nil {
+		if err != nil {
 			fp = "<error generating certificate fingerprint>"
 		}
@@ -169,19 +163,16 @@ func ixHandshakeStage1(f *Interface, addr netip.AddrPort, via *ViaSender, packet
 	if remoteCert.Certificate.Version() != ci.myCert.Version() {
 		// We started off using the wrong certificate version, lets see if we can match the version that was sent to us
-		myCertOtherVersion := cs.getCertificate(remoteCert.Certificate.Version())
+		rc := cs.getCertificate(remoteCert.Certificate.Version())
-		if myCertOtherVersion == nil {
+		if rc == nil {
-			if f.l.Level >= logrus.DebugLevel {
+			f.l.WithError(err).WithField("udpAddr", addr).
-				f.l.WithError(err).WithFields(m{
+				WithField("handshake", m{"stage": 1, "style": "ix_psk0"}).WithField("cert", remoteCert).
-					"udpAddr":   addr,
+				Info("Unable to handshake with host due to missing certificate version")
-					"handshake": m{"stage": 1, "style": "ix_psk0"},
+			return
 					"cert":      remoteCert,
 				}).Debug("Might be unable to handshake with host due to missing certificate version")
 			}
 		} else {
 			// Record the certificate we are actually using
 			ci.myCert = myCertOtherVersion
 		}
 		// Record the certificate we are actually using
 		ci.myCert = rc
 	}
 	if len(remoteCert.Certificate.Networks()) == 0 {
--- a/handshake_manager.go
+++ b/handshake_manager.go
@@ -68,12 +68,11 @@ type HandshakeManager struct {
 type HandshakeHostInfo struct {
 	sync.Mutex
-	startTime                 time.Time        // Time that we first started trying with this handshake
+	startTime   time.Time        // Time that we first started trying with this handshake
-	ready                     bool             // Is the handshake ready
+	ready       bool             // Is the handshake ready
-	initiatingVersionOverride cert.Version     // Should we use a non-default cert version for this handshake?
+	counter     int64            // How many attempts have we made so far
-	counter                   int64            // How many attempts have we made so far
+	lastRemotes []netip.AddrPort // Remotes that we sent to during the previous attempt
-	lastRemotes               []netip.AddrPort // Remotes that we sent to during the previous attempt
+	packetStore []*cachedPacket  // A set of packets to be transmitted once the handshake completes
 	packetStore               []*cachedPacket  // A set of packets to be transmitted once the handshake completes
 	hostinfo *HostInfo
 }
--- a/inside.go
+++ b/inside.go
@@ -2,18 +2,16 @@ package nebula
 import (
 	"net/netip"
 	"unsafe"
 	"github.com/sirupsen/logrus"
 	"github.com/slackhq/nebula/firewall"
 	"github.com/slackhq/nebula/header"
 	"github.com/slackhq/nebula/iputil"
 	"github.com/slackhq/nebula/noiseutil"
 	"github.com/slackhq/nebula/overlay"
 	"github.com/slackhq/nebula/routing"
 )
-func (f *Interface) consumeInsidePacket(packet []byte, fwPacket *firewall.Packet, nb, out []byte, q int, localCache *firewall.ConntrackCache) {
+func (f *Interface) consumeInsidePacket(packet []byte, fwPacket *firewall.Packet, nb, out []byte, q int, localCache firewall.ConntrackCache) {
 	err := newPacket(packet, false, fwPacket)
 	if err != nil {
 		if f.l.Level >= logrus.DebugLevel {
@@ -337,21 +335,9 @@ func (f *Interface) sendNoMetrics(t header.MessageType, st header.MessageSubType
 	if ci.eKey == nil {
 		return
 	}
-	target := remote
+	useRelay := !remote.IsValid() && !hostinfo.remote.IsValid()
 	if !target.IsValid() {
 		target = hostinfo.remote
 	}
 	useRelay := !target.IsValid()
 	fullOut := out
 	var pkt *overlay.Packet
 	if !useRelay && f.batches.Enabled() {
 		pkt = f.batches.newPacket()
 		if pkt != nil {
 			out = pkt.Payload()[:0]
 		}
 	}
 	if useRelay {
 		if len(out) < header.Len {
 			// out always has a capacity of mtu, but not always a length greater than the header.Len.
@@ -385,85 +371,41 @@ func (f *Interface) sendNoMetrics(t header.MessageType, st header.MessageSubType
 	}
 	var err error
 	if len(p) > 0 && slicesOverlap(out, p) {
 		tmp := make([]byte, len(p))
 		copy(tmp, p)
 		p = tmp
 	}
 	out, err = ci.eKey.EncryptDanger(out, out, p, c, nb)
 	if noiseutil.EncryptLockNeeded {
 		ci.writeLock.Unlock()
 	}
 	if err != nil {
 		if pkt != nil {
 			pkt.Release()
 		}
 		hostinfo.logger(f.l).WithError(err).
-			WithField("udpAddr", target).WithField("counter", c).
+			WithField("udpAddr", remote).WithField("counter", c).
 			WithField("attemptedCounter", c).
 			Error("Failed to encrypt outgoing packet")
 		return
 	}
-	if target.IsValid() {
+	if remote.IsValid() {
-		if pkt != nil {
+		err = f.writers[q].WriteTo(out, remote)
 			pkt.Len = len(out)
 			if f.l.Level >= logrus.DebugLevel {
 				f.l.WithFields(logrus.Fields{
 					"queue":        q,
 					"dest":         target,
 					"payload_len":  pkt.Len,
 					"use_batches":  true,
 					"remote_index": hostinfo.remoteIndexId,
 				}).Debug("enqueueing packet to UDP batch queue")
 			}
 			if f.tryQueuePacket(q, pkt, target) {
 				return
 			}
 			if f.l.Level >= logrus.DebugLevel {
 				f.l.WithFields(logrus.Fields{
 					"queue": q,
 					"dest":  target,
 				}).Debug("failed to enqueue packet; falling back to immediate send")
 			}
 			f.writeImmediatePacket(q, pkt, target, hostinfo)
 			return
 		}
 		if f.tryQueueDatagram(q, out, target) {
 			return
 		}
 		f.writeImmediate(q, out, target, hostinfo)
 		return
 	}
 	// fall back to relay path
 	if pkt != nil {
 		pkt.Release()
 	}
 	// Try to send via a relay
 	for _, relayIP := range hostinfo.relayState.CopyRelayIps() {
 		relayHostInfo, relay, err := f.hostMap.QueryVpnAddrsRelayFor(hostinfo.vpnAddrs, relayIP)
 		if err != nil {
-			hostinfo.relayState.DeleteRelay(relayIP)
+			hostinfo.logger(f.l).WithError(err).
-			hostinfo.logger(f.l).WithField("relay", relayIP).WithError(err).Info("sendNoMetrics failed to find HostInfo")
+				WithField("udpAddr", remote).Error("Failed to write outgoing packet")
-			continue
+		}
 	} else if hostinfo.remote.IsValid() {
 		err = f.writers[q].WriteTo(out, hostinfo.remote)
 		if err != nil {
 			hostinfo.logger(f.l).WithError(err).
 				WithField("udpAddr", remote).Error("Failed to write outgoing packet")
 		}
 	} else {
 		// Try to send via a relay
 		for _, relayIP := range hostinfo.relayState.CopyRelayIps() {
 			relayHostInfo, relay, err := f.hostMap.QueryVpnAddrsRelayFor(hostinfo.vpnAddrs, relayIP)
 			if err != nil {
 				hostinfo.relayState.DeleteRelay(relayIP)
 				hostinfo.logger(f.l).WithField("relay", relayIP).WithError(err).Info("sendNoMetrics failed to find HostInfo")
 				continue
 			}
 			f.SendVia(relayHostInfo, relay, out, nb, fullOut[:header.Len+len(out)], true)
 			break
 		}
 		f.SendVia(relayHostInfo, relay, out, nb, fullOut[:header.Len+len(out)], true)
 		break
 	}
 }
 // slicesOverlap reports whether the two byte slices share any portion of memory.
 // cipher.AEAD.Seal requires plaintext and dst to live in disjoint regions.
 func slicesOverlap(a, b []byte) bool {
 	if len(a) == 0 || len(b) == 0 {
 		return false
 	}
 	aStart := uintptr(unsafe.Pointer(&a[0]))
 	aEnd := aStart + uintptr(len(a))
 	bStart := uintptr(unsafe.Pointer(&b[0]))
 	bEnd := bStart + uintptr(len(b))
 	return aStart < bEnd && bStart < aEnd
 }
--- a/interface.go
+++ b/interface.go
@@ -8,7 +8,6 @@ import (
 	"net/netip"
 	"os"
 	"runtime"
 	"strings"
 	"sync/atomic"
 	"time"
@@ -22,13 +21,7 @@ import (
 	"github.com/slackhq/nebula/udp"
 )
-const (
+const mtu = 9001
 	mtu                          = 9001
 	defaultGSOFlushInterval      = 150 * time.Microsecond
 	defaultBatchQueueDepthFactor = 4
 	defaultGSOMaxSegments        = 8
 	maxKernelGSOSegments         = 64
 )
 type InterfaceConfig struct {
 	HostMap            *HostMap
@@ -43,9 +36,6 @@ type InterfaceConfig struct {
 	connectionManager  *connectionManager
 	DropLocalBroadcast bool
 	DropMulticast      bool
 	EnableGSO          bool
 	EnableGRO          bool
 	GSOMaxSegments     int
 	routines           int
 	MessageMetrics     *MessageMetrics
 	version            string
@@ -57,8 +47,6 @@ type InterfaceConfig struct {
 	reQueryWait     time.Duration
 	ConntrackCacheTimeout time.Duration
 	BatchFlushInterval    time.Duration
 	BatchQueueDepth       int
 	l                     *logrus.Logger
 }
@@ -96,20 +84,9 @@ type Interface struct {
 	version     string
 	conntrackCacheTimeout time.Duration
 	batchQueueDepth       int
 	enableGSO             bool
 	enableGRO             bool
 	gsoMaxSegments        int
 	batchUDPQueueGauge    metrics.Gauge
 	batchUDPFlushCounter  metrics.Counter
 	batchTunQueueGauge    metrics.Gauge
 	batchTunFlushCounter  metrics.Counter
 	batchFlushInterval    atomic.Int64
 	sendSem               chan struct{}
 	writers []udp.Conn
 	readers []io.ReadWriteCloser
 	batches batchPipelines
 	metricHandshakes    metrics.Histogram
 	messageMetrics      *MessageMetrics
@@ -184,22 +161,6 @@ func NewInterface(ctx context.Context, c *InterfaceConfig) (*Interface, error) {
 		return nil, errors.New("no connection manager")
 	}
 	if c.GSOMaxSegments <= 0 {
 		c.GSOMaxSegments = defaultGSOMaxSegments
 	}
 	if c.GSOMaxSegments > maxKernelGSOSegments {
 		c.GSOMaxSegments = maxKernelGSOSegments
 	}
 	if c.BatchQueueDepth <= 0 {
 		c.BatchQueueDepth = c.routines * defaultBatchQueueDepthFactor
 	}
 	if c.BatchFlushInterval < 0 {
 		c.BatchFlushInterval = 0
 	}
 	if c.BatchFlushInterval == 0 && c.EnableGSO {
 		c.BatchFlushInterval = defaultGSOFlushInterval
 	}
 	cs := c.pki.getCertState()
 	ifce := &Interface{
 		pki:                   c.pki,
@@ -225,10 +186,6 @@ func NewInterface(ctx context.Context, c *InterfaceConfig) (*Interface, error) {
 		relayManager:          c.relayManager,
 		connectionManager:     c.connectionManager,
 		conntrackCacheTimeout: c.ConntrackCacheTimeout,
 		batchQueueDepth:       c.BatchQueueDepth,
 		enableGSO:             c.EnableGSO,
 		enableGRO:             c.EnableGRO,
 		gsoMaxSegments:        c.GSOMaxSegments,
 		metricHandshakes: metrics.GetOrRegisterHistogram("handshakes", nil, metrics.NewExpDecaySample(1028, 0.015)),
 		messageMetrics:   c.MessageMetrics,
@@ -241,25 +198,8 @@ func NewInterface(ctx context.Context, c *InterfaceConfig) (*Interface, error) {
 	}
 	ifce.tryPromoteEvery.Store(c.tryPromoteEvery)
 	ifce.batchUDPQueueGauge = metrics.GetOrRegisterGauge("batch.udp.queue_depth", nil)
 	ifce.batchUDPFlushCounter = metrics.GetOrRegisterCounter("batch.udp.flushes", nil)
 	ifce.batchTunQueueGauge = metrics.GetOrRegisterGauge("batch.tun.queue_depth", nil)
 	ifce.batchTunFlushCounter = metrics.GetOrRegisterCounter("batch.tun.flushes", nil)
 	ifce.batchFlushInterval.Store(int64(c.BatchFlushInterval))
 	ifce.sendSem = make(chan struct{}, c.routines)
 	ifce.batches.init(c.Inside, c.routines, c.BatchQueueDepth, c.GSOMaxSegments)
 	ifce.reQueryEvery.Store(c.reQueryEvery)
 	ifce.reQueryWait.Store(int64(c.reQueryWait))
 	if c.l.Level >= logrus.DebugLevel {
 		c.l.WithFields(logrus.Fields{
 			"enableGSO":       c.EnableGSO,
 			"enableGRO":       c.EnableGRO,
 			"gsoMaxSegments":  c.GSOMaxSegments,
 			"batchQueueDepth": c.BatchQueueDepth,
 			"batchFlush":      c.BatchFlushInterval,
 			"batching":        ifce.batches.Enabled(),
 		}).Debug("initialized batch pipelines")
 	}
 	ifce.connectionManager.intf = ifce
@@ -308,18 +248,6 @@ func (f *Interface) run() {
 		go f.listenOut(i)
 	}
 	if f.l.Level >= logrus.DebugLevel {
 		f.l.WithField("batching", f.batches.Enabled()).Debug("starting interface run loops")
 	}
 	if f.batches.Enabled() {
 		for i := 0; i < f.routines; i++ {
 			go f.runInsideBatchWorker(i)
 			go f.runTunWriteQueue(i)
 			go f.runSendQueue(i)
 		}
 	}
 	// Launch n queues to read packets from tun dev
 	for i := 0; i < f.routines; i++ {
 		go f.listenIn(f.readers[i], i)
@@ -343,7 +271,10 @@ func (f *Interface) listenOut(i int) {
 	fwPacket := &firewall.Packet{}
 	nb := make([]byte, 12, 12)
-	li.ListenOut(func(fromUdpAddr netip.AddrPort, payload []byte) {
+	li.ListenOut(func(fromUdpAddr netip.AddrPort, payload []byte, release func()) {
 		if release != nil {
 			defer release()
 		}
 		f.readOutsidePackets(fromUdpAddr, nil, plaintext[:0], payload, h, fwPacket, lhh, nb, i, ctCache.Get(f.l))
 	})
 }
@@ -351,17 +282,6 @@ func (f *Interface) listenOut(i int) {
 func (f *Interface) listenIn(reader io.ReadWriteCloser, i int) {
 	runtime.LockOSThread()
 	if f.batches.Enabled() {
 		if br, ok := reader.(overlay.BatchReader); ok {
 			f.listenInBatchLocked(reader, br, i)
 			return
 		}
 	}
 	f.listenInLegacyLocked(reader, i)
 }
 func (f *Interface) listenInLegacyLocked(reader io.ReadWriteCloser, i int) {
 	packet := make([]byte, mtu)
 	out := make([]byte, mtu)
 	fwPacket := &firewall.Packet{}
@@ -385,581 +305,6 @@ func (f *Interface) listenInLegacyLocked(reader io.ReadWriteCloser, i int) {
 	}
 }
 func (f *Interface) listenInBatchLocked(raw io.ReadWriteCloser, reader overlay.BatchReader, i int) {
 	pool := f.batches.Pool()
 	if pool == nil {
 		f.l.Warn("batch pipeline enabled without an allocated pool; falling back to single-packet reads")
 		f.listenInLegacyLocked(raw, i)
 		return
 	}
 	for {
 		packets, err := reader.ReadIntoBatch(pool)
 		if err != nil {
 			if errors.Is(err, os.ErrClosed) && f.closed.Load() {
 				return
 			}
 			if isVirtioHeadroomError(err) {
 				f.l.WithError(err).Warn("Batch reader fell back due to tun headroom issue")
 				f.listenInLegacyLocked(raw, i)
 				return
 			}
 			f.l.WithError(err).Error("Error while reading outbound packet batch")
 			os.Exit(2)
 		}
 		if len(packets) == 0 {
 			continue
 		}
 		for _, pkt := range packets {
 			if pkt == nil {
 				continue
 			}
 			if !f.batches.enqueueRx(i, pkt) {
 				pkt.Release()
 			}
 		}
 	}
 }
 func (f *Interface) runInsideBatchWorker(i int) {
 	queue := f.batches.rxQueue(i)
 	if queue == nil {
 		return
 	}
 	out := make([]byte, mtu)
 	fwPacket := &firewall.Packet{}
 	nb := make([]byte, 12, 12)
 	conntrackCache := firewall.NewConntrackCacheTicker(f.conntrackCacheTimeout)
 	for pkt := range queue {
 		if pkt == nil {
 			continue
 		}
 		f.consumeInsidePacket(pkt.Payload(), fwPacket, nb, out, i, conntrackCache.Get(f.l))
 		pkt.Release()
 	}
 }
 func (f *Interface) runSendQueue(i int) {
 	queue := f.batches.txQueue(i)
 	if queue == nil {
 		if f.l.Level >= logrus.DebugLevel {
 			f.l.WithField("queue", i).Debug("tx queue not initialized; batching disabled for writer")
 		}
 		return
 	}
 	writer := f.writerForIndex(i)
 	if writer == nil {
 		if f.l.Level >= logrus.DebugLevel {
 			f.l.WithField("queue", i).Debug("no UDP writer for batch queue")
 		}
 		return
 	}
 	if f.l.Level >= logrus.DebugLevel {
 		f.l.WithField("queue", i).Debug("send queue worker started")
 	}
 	defer func() {
 		if f.l.Level >= logrus.WarnLevel {
 			f.l.WithField("queue", i).Warn("send queue worker exited")
 		}
 	}()
 	batchCap := f.batches.batchSizeHint()
 	if batchCap <= 0 {
 		batchCap = 1
 	}
 	gsoLimit := f.effectiveGSOMaxSegments()
 	if gsoLimit > batchCap {
 		batchCap = gsoLimit
 	}
 	pending := make([]queuedDatagram, 0, batchCap)
 	var (
 		flushTimer *time.Timer
 		flushC     <-chan time.Time
 	)
 	dispatch := func(reason string, timerFired bool) {
 		if len(pending) == 0 {
 			return
 		}
 		batch := pending
 		f.flushAndReleaseBatch(i, writer, batch, reason)
 		for idx := range batch {
 			batch[idx] = queuedDatagram{}
 		}
 		pending = pending[:0]
 		if flushTimer != nil {
 			if !timerFired {
 				if !flushTimer.Stop() {
 					select {
 					case <-flushTimer.C:
 					default:
 					}
 				}
 			}
 			flushTimer = nil
 			flushC = nil
 		}
 	}
 	armTimer := func() {
 		delay := f.currentBatchFlushInterval()
 		if delay <= 0 {
 			dispatch("nogso", false)
 			return
 		}
 		if flushTimer == nil {
 			flushTimer = time.NewTimer(delay)
 			flushC = flushTimer.C
 		}
 	}
 	for {
 		select {
 		case d := <-queue:
 			if d.packet == nil {
 				continue
 			}
 			if f.l.Level >= logrus.DebugLevel {
 				f.l.WithFields(logrus.Fields{
 					"queue":       i,
 					"payload_len": d.packet.Len,
 					"dest":        d.addr,
 				}).Debug("send queue received packet")
 			}
 			pending = append(pending, d)
 			if gsoLimit > 0 && len(pending) >= gsoLimit {
 				dispatch("gso", false)
 				continue
 			}
 			if len(pending) >= cap(pending) {
 				dispatch("cap", false)
 				continue
 			}
 			armTimer()
 			f.observeUDPQueueLen(i)
 		case <-flushC:
 			dispatch("timer", true)
 		}
 	}
 }
 func (f *Interface) runTunWriteQueue(i int) {
 	queue := f.batches.tunQueue(i)
 	if queue == nil {
 		return
 	}
 	writer := f.batches.inside
 	if writer == nil {
 		return
 	}
 	requiredHeadroom := writer.BatchHeadroom()
 	batchCap := f.batches.batchSizeHint()
 	if batchCap <= 0 {
 		batchCap = 1
 	}
 	pending := make([]*overlay.Packet, 0, batchCap)
 	var (
 		flushTimer *time.Timer
 		flushC     <-chan time.Time
 	)
 	flush := func(reason string, timerFired bool) {
 		if len(pending) == 0 {
 			return
 		}
 		valid := pending[:0]
 		for idx := range pending {
 			if !f.ensurePacketHeadroom(&pending[idx], requiredHeadroom, i, reason) {
 				pending[idx] = nil
 				continue
 			}
 			if pending[idx] != nil {
 				valid = append(valid, pending[idx])
 			}
 		}
 		if len(valid) > 0 {
 			if _, err := writer.WriteBatch(valid); err != nil {
 				f.l.WithError(err).
 					WithField("queue", i).
 					WithField("reason", reason).
 					Warn("Failed to write tun batch")
 				for _, pkt := range valid {
 					if pkt != nil {
 						f.writePacketToTun(i, pkt)
 					}
 				}
 			}
 		}
 		pending = pending[:0]
 		if flushTimer != nil {
 			if !timerFired {
 				if !flushTimer.Stop() {
 					select {
 					case <-flushTimer.C:
 					default:
 					}
 				}
 			}
 			flushTimer = nil
 			flushC = nil
 		}
 	}
 	armTimer := func() {
 		delay := f.currentBatchFlushInterval()
 		if delay <= 0 {
 			return
 		}
 		if flushTimer == nil {
 			flushTimer = time.NewTimer(delay)
 			flushC = flushTimer.C
 		}
 	}
 	for {
 		select {
 		case pkt := <-queue:
 			if pkt == nil {
 				continue
 			}
 			if f.ensurePacketHeadroom(&pkt, requiredHeadroom, i, "queue") {
 				pending = append(pending, pkt)
 			}
 			if len(pending) >= cap(pending) {
 				flush("cap", false)
 				continue
 			}
 			armTimer()
 			f.observeTunQueueLen(i)
 		case <-flushC:
 			flush("timer", true)
 		}
 	}
 }
 func (f *Interface) flushAndReleaseBatch(index int, writer udp.Conn, batch []queuedDatagram, reason string) {
 	if len(batch) == 0 {
 		return
 	}
 	f.flushDatagrams(index, writer, batch, reason)
 	for idx := range batch {
 		if batch[idx].packet != nil {
 			batch[idx].packet.Release()
 			batch[idx].packet = nil
 		}
 	}
 	if f.batchUDPFlushCounter != nil {
 		f.batchUDPFlushCounter.Inc(int64(len(batch)))
 	}
 }
 func (f *Interface) flushDatagrams(index int, writer udp.Conn, batch []queuedDatagram, reason string) {
 	if len(batch) == 0 {
 		return
 	}
 	if f.l.Level >= logrus.DebugLevel {
 		f.l.WithFields(logrus.Fields{
 			"writer":  index,
 			"reason":  reason,
 			"pending": len(batch),
 		}).Debug("udp batch flush summary")
 	}
 	maxSeg := f.effectiveGSOMaxSegments()
 	if bw, ok := writer.(udp.BatchConn); ok {
 		chunkCap := maxSeg
 		if chunkCap <= 0 {
 			chunkCap = len(batch)
 		}
 		chunk := make([]udp.Datagram, 0, chunkCap)
 		var (
 			currentAddr netip.AddrPort
 			segments    int
 		)
 		flushChunk := func() {
 			if len(chunk) == 0 {
 				return
 			}
 			if f.l.Level >= logrus.DebugLevel {
 				f.l.WithFields(logrus.Fields{
 					"writer":        index,
 					"segments":      len(chunk),
 					"dest":          chunk[0].Addr,
 					"reason":        reason,
 					"pending_total": len(batch),
 				}).Debug("flushing UDP batch")
 			}
 			if err := bw.WriteBatch(chunk); err != nil {
 				f.l.WithError(err).
 					WithField("writer", index).
 					WithField("reason", reason).
 					Warn("Failed to write UDP batch")
 			}
 			chunk = chunk[:0]
 			segments = 0
 		}
 		for _, item := range batch {
 			if item.packet == nil || !item.addr.IsValid() {
 				continue
 			}
 			payload := item.packet.Payload()[:item.packet.Len]
 			if segments == 0 {
 				currentAddr = item.addr
 			}
 			if item.addr != currentAddr || (maxSeg > 0 && segments >= maxSeg) {
 				flushChunk()
 				currentAddr = item.addr
 			}
 			chunk = append(chunk, udp.Datagram{Payload: payload, Addr: item.addr})
 			segments++
 		}
 		flushChunk()
 		return
 	}
 	for _, item := range batch {
 		if item.packet == nil || !item.addr.IsValid() {
 			continue
 		}
 		if f.l.Level >= logrus.DebugLevel {
 			f.l.WithFields(logrus.Fields{
 				"writer":   index,
 				"reason":   reason,
 				"dest":     item.addr,
 				"segments": 1,
 			}).Debug("flushing UDP batch")
 		}
 		if err := writer.WriteTo(item.packet.Payload()[:item.packet.Len], item.addr); err != nil {
 			f.l.WithError(err).
 				WithField("writer", index).
 				WithField("udpAddr", item.addr).
 				WithField("reason", reason).
 				Warn("Failed to write UDP packet")
 		}
 	}
 }
 func (f *Interface) tryQueueDatagram(q int, buf []byte, addr netip.AddrPort) bool {
 	if !addr.IsValid() || !f.batches.Enabled() {
 		return false
 	}
 	pkt := f.batches.newPacket()
 	if pkt == nil {
 		return false
 	}
 	payload := pkt.Payload()
 	if len(payload) < len(buf) {
 		pkt.Release()
 		return false
 	}
 	copy(payload, buf)
 	pkt.Len = len(buf)
 	if f.batches.enqueueTx(q, pkt, addr) {
 		f.observeUDPQueueLen(q)
 		return true
 	}
 	pkt.Release()
 	return false
 }
 func (f *Interface) writerForIndex(i int) udp.Conn {
 	if i < 0 || i >= len(f.writers) {
 		return nil
 	}
 	return f.writers[i]
 }
 func (f *Interface) writeImmediate(q int, buf []byte, addr netip.AddrPort, hostinfo *HostInfo) {
 	writer := f.writerForIndex(q)
 	if writer == nil {
 		f.l.WithField("udpAddr", addr).
 			WithField("writer", q).
 			Error("Failed to write outgoing packet: no writer available")
 		return
 	}
 	if err := writer.WriteTo(buf, addr); err != nil {
 		hostinfo.logger(f.l).
 			WithError(err).
 			WithField("udpAddr", addr).
 			Error("Failed to write outgoing packet")
 	}
 }
 func (f *Interface) tryQueuePacket(q int, pkt *overlay.Packet, addr netip.AddrPort) bool {
 	if pkt == nil || !addr.IsValid() || !f.batches.Enabled() {
 		return false
 	}
 	if f.batches.enqueueTx(q, pkt, addr) {
 		f.observeUDPQueueLen(q)
 		return true
 	}
 	return false
 }
 func (f *Interface) writeImmediatePacket(q int, pkt *overlay.Packet, addr netip.AddrPort, hostinfo *HostInfo) {
 	if pkt == nil {
 		return
 	}
 	writer := f.writerForIndex(q)
 	if writer == nil {
 		f.l.WithField("udpAddr", addr).
 			WithField("writer", q).
 			Error("Failed to write outgoing packet: no writer available")
 		pkt.Release()
 		return
 	}
 	if err := writer.WriteTo(pkt.Payload()[:pkt.Len], addr); err != nil {
 		hostinfo.logger(f.l).
 			WithError(err).
 			WithField("udpAddr", addr).
 			Error("Failed to write outgoing packet")
 	}
 	pkt.Release()
 }
 func (f *Interface) writePacketToTun(q int, pkt *overlay.Packet) {
 	if pkt == nil {
 		return
 	}
 	writer := f.readers[q]
 	if writer == nil {
 		pkt.Release()
 		return
 	}
 	if bw, ok := writer.(interface {
 		WriteBatch([]*overlay.Packet) (int, error)
 	}); ok {
 		if _, err := bw.WriteBatch([]*overlay.Packet{pkt}); err != nil {
 			f.l.WithError(err).WithField("queue", q).Warn("Failed to write tun packet via batch writer")
 			pkt.Release()
 		}
 		return
 	}
 	if _, err := writer.Write(pkt.Payload()[:pkt.Len]); err != nil {
 		f.l.WithError(err).Error("Failed to write to tun")
 	}
 	pkt.Release()
 }
 func (f *Interface) clonePacketWithHeadroom(pkt *overlay.Packet, required int) *overlay.Packet {
 	if pkt == nil {
 		return nil
 	}
 	payload := pkt.Payload()[:pkt.Len]
 	if len(payload) == 0 && required <= 0 {
 		return pkt
 	}
 	pool := f.batches.Pool()
 	if pool != nil {
 		if clone := pool.Get(); clone != nil {
 			if len(clone.Payload()) >= len(payload) {
 				clone.Len = copy(clone.Payload(), payload)
 				pkt.Release()
 				return clone
 			}
 			clone.Release()
 		}
 	}
 	if required < 0 {
 		required = 0
 	}
 	buf := make([]byte, required+len(payload))
 	n := copy(buf[required:], payload)
 	pkt.Release()
 	return &overlay.Packet{
 		Buf:    buf,
 		Offset: required,
 		Len:    n,
 	}
 }
 func (f *Interface) observeUDPQueueLen(i int) {
 	if f.batchUDPQueueGauge == nil {
 		return
 	}
 	f.batchUDPQueueGauge.Update(int64(f.batches.txQueueLen(i)))
 }
 func (f *Interface) observeTunQueueLen(i int) {
 	if f.batchTunQueueGauge == nil {
 		return
 	}
 	f.batchTunQueueGauge.Update(int64(f.batches.tunQueueLen(i)))
 }
 func (f *Interface) currentBatchFlushInterval() time.Duration {
 	if v := f.batchFlushInterval.Load(); v > 0 {
 		return time.Duration(v)
 	}
 	return 0
 }
 func (f *Interface) ensurePacketHeadroom(pkt **overlay.Packet, required int, queue int, reason string) bool {
 	p := *pkt
 	if p == nil {
 		return false
 	}
 	if required <= 0 || p.Offset >= required {
 		return true
 	}
 	clone := f.clonePacketWithHeadroom(p, required)
 	if clone == nil {
 		f.l.WithFields(logrus.Fields{
 			"queue":  queue,
 			"reason": reason,
 		}).Warn("dropping packet lacking tun headroom")
 		return false
 	}
 	*pkt = clone
 	return true
 }
 func isVirtioHeadroomError(err error) bool {
 	if err == nil {
 		return false
 	}
 	msg := err.Error()
 	return strings.Contains(msg, "headroom") || strings.Contains(msg, "virtio")
 }
 func (f *Interface) effectiveGSOMaxSegments() int {
 	max := f.gsoMaxSegments
 	if max <= 0 {
 		max = defaultGSOMaxSegments
 	}
 	if max > maxKernelGSOSegments {
 		max = maxKernelGSOSegments
 	}
 	if !f.enableGSO {
 		return 1
 	}
 	return max
 }
 type udpOffloadConfigurator interface {
 	ConfigureOffload(enableGSO, enableGRO bool, maxSegments int)
 }
 func (f *Interface) applyOffloadConfig(enableGSO, enableGRO bool, maxSegments int) {
 	if maxSegments <= 0 {
 		maxSegments = defaultGSOMaxSegments
 	}
 	if maxSegments > maxKernelGSOSegments {
 		maxSegments = maxKernelGSOSegments
 	}
 	f.enableGSO = enableGSO
 	f.enableGRO = enableGRO
 	f.gsoMaxSegments = maxSegments
 	for _, writer := range f.writers {
 		if cfg, ok := writer.(udpOffloadConfigurator); ok {
 			cfg.ConfigureOffload(enableGSO, enableGRO, maxSegments)
 		}
 	}
 }
 func (f *Interface) RegisterConfigChangeCallbacks(c *config.C) {
 	c.RegisterReloadCallback(f.reloadFirewall)
 	c.RegisterReloadCallback(f.reloadSendRecvError)
@@ -1062,42 +407,6 @@ func (f *Interface) reloadMisc(c *config.C) {
 		f.reQueryWait.Store(int64(n))
 		f.l.Info("timers.requery_wait_duration has changed")
 	}
 	if c.HasChanged("listen.gso_flush_timeout") {
 		d := c.GetDuration("listen.gso_flush_timeout", defaultGSOFlushInterval)
 		if d < 0 {
 			d = 0
 		}
 		f.batchFlushInterval.Store(int64(d))
 		f.l.WithField("duration", d).Info("listen.gso_flush_timeout has changed")
 	} else if c.HasChanged("batch.flush_interval") {
 		d := c.GetDuration("batch.flush_interval", defaultGSOFlushInterval)
 		if d < 0 {
 			d = 0
 		}
 		f.batchFlushInterval.Store(int64(d))
 		f.l.WithField("duration", d).Warn("batch.flush_interval is deprecated; use listen.gso_flush_timeout")
 	}
 	if c.HasChanged("batch.queue_depth") {
 		n := c.GetInt("batch.queue_depth", f.batchQueueDepth)
 		if n != f.batchQueueDepth {
 			f.batchQueueDepth = n
 			f.l.Warn("batch.queue_depth changes require a restart to take effect")
 		}
 	}
 	if c.HasChanged("listen.enable_gso") || c.HasChanged("listen.enable_gro") || c.HasChanged("listen.gso_max_segments") {
 		enableGSO := c.GetBool("listen.enable_gso", f.enableGSO)
 		enableGRO := c.GetBool("listen.enable_gro", f.enableGRO)
 		maxSeg := c.GetInt("listen.gso_max_segments", f.gsoMaxSegments)
 		f.applyOffloadConfig(enableGSO, enableGRO, maxSeg)
 		f.l.WithFields(logrus.Fields{
 			"enableGSO":      enableGSO,
 			"enableGRO":      enableGRO,
 			"gsoMaxSegments": maxSeg,
 		}).Info("listen GSO/GRO configuration updated")
 	}
 }
 func (f *Interface) emitStats(ctx context.Context, i time.Duration) {
--- a/main.go
+++ b/main.go
@@ -5,7 +5,6 @@ import (
 	"fmt"
 	"net"
 	"net/netip"
 	"runtime"
 	"time"
 	"github.com/sirupsen/logrus"
@@ -144,20 +143,6 @@ func Main(c *config.C, configTest bool, buildVersion string, logger *logrus.Logg
 	// set up our UDP listener
 	udpConns := make([]udp.Conn, routines)
 	port := c.GetInt("listen.port", 0)
 	enableGSO := c.GetBool("listen.enable_gso", true)
 	enableGRO := c.GetBool("listen.enable_gro", true)
 	gsoMaxSegments := c.GetInt("listen.gso_max_segments", defaultGSOMaxSegments)
 	if gsoMaxSegments <= 0 {
 		gsoMaxSegments = defaultGSOMaxSegments
 	}
 	if gsoMaxSegments > maxKernelGSOSegments {
 		gsoMaxSegments = maxKernelGSOSegments
 	}
 	gsoFlushTimeout := c.GetDuration("listen.gso_flush_timeout", defaultGSOFlushInterval)
 	if gsoFlushTimeout < 0 {
 		gsoFlushTimeout = 0
 	}
 	batchQueueDepth := c.GetInt("batch.queue_depth", 0)
 	if !configTest {
 		rawListenHost := c.GetString("listen.host", "0.0.0.0")
@@ -177,27 +162,13 @@ func Main(c *config.C, configTest bool, buildVersion string, logger *logrus.Logg
 			listenHost = ips[0].Unmap()
 		}
 		useWGDefault := runtime.GOOS == "linux"
 		useWG := c.GetBool("listen.use_wireguard_stack", useWGDefault)
 		var mkListener func(*logrus.Logger, netip.Addr, int, bool, int) (udp.Conn, error)
 		if useWG {
 			mkListener = udp.NewWireguardListener
 		} else {
 			mkListener = udp.NewListener
 		}
 		for i := 0; i < routines; i++ {
 			l.Infof("listening on %v", netip.AddrPortFrom(listenHost, uint16(port)))
-			udpServer, err := mkListener(l, listenHost, port, routines > 1, c.GetInt("listen.batch", 64))
+			udpServer, err := udp.NewListener(l, listenHost, port, routines > 1, c.GetInt("listen.batch", 64))
 			if err != nil {
 				return nil, util.NewContextualError("Failed to open udp listener", m{"queue": i}, err)
 			}
 			udpServer.ReloadConfig(c)
 			if cfg, ok := udpServer.(interface {
 				ConfigureOffload(bool, bool, int)
 			}); ok {
 				cfg.ConfigureOffload(enableGSO, enableGRO, gsoMaxSegments)
 			}
 			udpConns[i] = udpServer
 			// If port is dynamic, discover it before the next pass through the for loop
@@ -265,17 +236,12 @@ func Main(c *config.C, configTest bool, buildVersion string, logger *logrus.Logg
 		reQueryWait:           c.GetDuration("timers.requery_wait_duration", defaultReQueryWait),
 		DropLocalBroadcast:    c.GetBool("tun.drop_local_broadcast", false),
 		DropMulticast:         c.GetBool("tun.drop_multicast", false),
 		EnableGSO:             enableGSO,
 		EnableGRO:             enableGRO,
 		GSOMaxSegments:        gsoMaxSegments,
 		routines:              routines,
 		MessageMetrics:        messageMetrics,
 		version:               buildVersion,
 		relayManager:          NewRelayManager(ctx, l, hostMap, c),
 		punchy:                punchy,
 		ConntrackCacheTimeout: conntrackCacheTimeout,
 		BatchFlushInterval:    gsoFlushTimeout,
 		BatchQueueDepth:       batchQueueDepth,
 		l:                     l,
 	}
@@ -287,7 +253,6 @@ func Main(c *config.C, configTest bool, buildVersion string, logger *logrus.Logg
 		}
 		ifce.writers = udpConns
 		ifce.applyOffloadConfig(enableGSO, enableGRO, gsoMaxSegments)
 		lightHouse.ifce = ifce
 		ifce.RegisterConfigChangeCallbacks(c)
--- a/outside.go
+++ b/outside.go
@@ -12,7 +12,6 @@ import (
 	"github.com/sirupsen/logrus"
 	"github.com/slackhq/nebula/firewall"
 	"github.com/slackhq/nebula/header"
 	"github.com/slackhq/nebula/overlay"
 	"golang.org/x/net/ipv4"
 )
@@ -20,7 +19,7 @@ const (
 	minFwPacketLen = 4
 )
-func (f *Interface) readOutsidePackets(ip netip.AddrPort, via *ViaSender, out []byte, packet []byte, h *header.H, fwPacket *firewall.Packet, lhf *LightHouseHandler, nb []byte, q int, localCache *firewall.ConntrackCache) {
+func (f *Interface) readOutsidePackets(ip netip.AddrPort, via *ViaSender, out []byte, packet []byte, h *header.H, fwPacket *firewall.Packet, lhf *LightHouseHandler, nb []byte, q int, localCache firewall.ConntrackCache) {
 	err := h.Parse(packet)
 	if err != nil {
 		// Hole punch packets are 0 or 1 byte big, so lets ignore printing those errors
@@ -62,7 +61,7 @@ func (f *Interface) readOutsidePackets(ip netip.AddrPort, via *ViaSender, out []
 		switch h.Subtype {
 		case header.MessageNone:
-			if !f.decryptToTun(hostinfo, h.MessageCounter, out, packet, fwPacket, nb, q, localCache, ip, h.RemoteIndex) {
+			if !f.decryptToTun(hostinfo, h.MessageCounter, out, packet, fwPacket, nb, q, localCache) {
 				return
 			}
 		case header.MessageRelay:
@@ -466,45 +465,23 @@ func (f *Interface) decrypt(hostinfo *HostInfo, mc uint64, out []byte, packet []
 	return out, nil
 }
-func (f *Interface) decryptToTun(hostinfo *HostInfo, messageCounter uint64, out []byte, packet []byte, fwPacket *firewall.Packet, nb []byte, q int, localCache *firewall.ConntrackCache, addr netip.AddrPort, recvIndex uint32) bool {
+func (f *Interface) decryptToTun(hostinfo *HostInfo, messageCounter uint64, out []byte, packet []byte, fwPacket *firewall.Packet, nb []byte, q int, localCache firewall.ConntrackCache) bool {
-	var (
+	var err error
 		err error
 		pkt *overlay.Packet
 	)
 	if f.batches.tunQueue(q) != nil {
 		pkt = f.batches.newPacket()
 		if pkt != nil {
 			out = pkt.Payload()[:0]
 		}
 	}
 	out, err = hostinfo.ConnectionState.dKey.DecryptDanger(out, packet[:header.Len], packet[header.Len:], messageCounter, nb)
 	if err != nil {
 		if pkt != nil {
 			pkt.Release()
 		}
 		hostinfo.logger(f.l).WithError(err).Error("Failed to decrypt packet")
 		if addr.IsValid() {
 			f.maybeSendRecvError(addr, recvIndex)
 		}
 		return false
 	}
 	err = newPacket(out, true, fwPacket)
 	if err != nil {
 		if pkt != nil {
 			pkt.Release()
 		}
 		hostinfo.logger(f.l).WithError(err).WithField("packet", out).
 			Warnf("Error while validating inbound packet")
 		return false
 	}
 	if !hostinfo.ConnectionState.window.Update(f.l, messageCounter) {
 		if pkt != nil {
 			pkt.Release()
 		}
 		hostinfo.logger(f.l).WithField("fwPacket", fwPacket).
 			Debugln("dropping out of window packet")
 		return false
@@ -512,9 +489,6 @@ func (f *Interface) decryptToTun(hostinfo *HostInfo, messageCounter uint64, out
 	dropReason := f.firewall.Drop(*fwPacket, true, hostinfo, f.pki.GetCAPool(), localCache)
 	if dropReason != nil {
 		if pkt != nil {
 			pkt.Release()
 		}
 		// NOTE: We give `packet` as the `out` here since we already decrypted from it and we don't need it anymore
 		// This gives us a buffer to build the reject packet in
 		f.rejectOutside(out, hostinfo.ConnectionState, hostinfo, nb, packet, q)
@@ -527,17 +501,8 @@ func (f *Interface) decryptToTun(hostinfo *HostInfo, messageCounter uint64, out
 	}
 	f.connectionManager.In(hostinfo)
-	if pkt != nil {
+	_, err = f.readers[q].Write(out)
-		pkt.Len = len(out)
+	if err != nil {
 		if f.batches.enqueueTun(q, pkt) {
 			f.observeTunQueueLen(q)
 			return true
 		}
 		f.writePacketToTun(q, pkt)
 		return true
 	}
 	if _, err = f.readers[q].Write(out); err != nil {
 		f.l.WithError(err).Error("Failed to write to tun")
 	}
 	return true
--- a/overlay/device.go
+++ b/overlay/device.go
@@ -3,7 +3,6 @@ package overlay
 import (
 	"io"
 	"net/netip"
 	"sync"
 	"github.com/slackhq/nebula/routing"
 )
@@ -16,84 +15,3 @@ type Device interface {
 	RoutesFor(netip.Addr) routing.Gateways
 	NewMultiQueueReader() (io.ReadWriteCloser, error)
 }
 // Packet represents a single packet buffer with optional headroom to carry
 // metadata (for example virtio-net headers).
 type Packet struct {
 	Buf     []byte
 	Offset  int
 	Len     int
 	release func()
 }
 func (p *Packet) Payload() []byte {
 	return p.Buf[p.Offset : p.Offset+p.Len]
 }
 func (p *Packet) Reset() {
 	p.Len = 0
 	p.Offset = 0
 	p.release = nil
 }
 func (p *Packet) Release() {
 	if p.release != nil {
 		p.release()
 		p.release = nil
 	}
 }
 func (p *Packet) Capacity() int {
 	return len(p.Buf) - p.Offset
 }
 // PacketPool manages reusable buffers with headroom.
 type PacketPool struct {
 	headroom int
 	blksz    int
 	pool     sync.Pool
 }
 func NewPacketPool(headroom, payload int) *PacketPool {
 	p := &PacketPool{headroom: headroom, blksz: headroom + payload}
 	p.pool.New = func() any {
 		buf := make([]byte, p.blksz)
 		return &Packet{Buf: buf, Offset: headroom}
 	}
 	return p
 }
 func (p *PacketPool) Get() *Packet {
 	pkt := p.pool.Get().(*Packet)
 	pkt.Offset = p.headroom
 	pkt.Len = 0
 	pkt.release = func() { p.put(pkt) }
 	return pkt
 }
 func (p *PacketPool) put(pkt *Packet) {
 	pkt.Reset()
 	p.pool.Put(pkt)
 }
 // BatchReader allows reading multiple packets into a shared pool with
 // preallocated headroom (e.g. virtio-net headers).
 type BatchReader interface {
 	ReadIntoBatch(pool *PacketPool) ([]*Packet, error)
 }
 // BatchWriter writes a slice of packets that carry their own metadata.
 type BatchWriter interface {
 	WriteBatch(packets []*Packet) (int, error)
 }
 // BatchCapableDevice describes a device that can efficiently read and write
 // batches of packets with virtio headroom.
 type BatchCapableDevice interface {
 	Device
 	BatchReader
 	BatchWriter
 	BatchHeadroom() int
 	BatchPayloadCap() int
 	BatchSize() int
 }
--- a/overlay/tun_linux.go
+++ b/overlay/tun_linux.go
@@ -9,7 +9,6 @@ import (
 	"net"
 	"net/netip"
 	"os"
 	"runtime"
 	"strings"
 	"sync/atomic"
 	"time"
@@ -20,7 +19,6 @@ import (
 	"github.com/slackhq/nebula/config"
 	"github.com/slackhq/nebula/routing"
 	"github.com/slackhq/nebula/util"
 	wgtun "github.com/slackhq/nebula/wgstack/tun"
 	"github.com/vishvananda/netlink"
 	"golang.org/x/sys/unix"
 )
@@ -35,7 +33,6 @@ type tun struct {
 	TXQueueLen  int
 	deviceIndex int
 	ioctlFd     uintptr
 	wgDevice    wgtun.Device
 	Routes                    atomic.Pointer[[]Route]
 	routeTree                 atomic.Pointer[bart.Table[routing.Gateways]]
@@ -71,9 +68,7 @@ type ifreqQLEN struct {
 func newTunFromFd(c *config.C, l *logrus.Logger, deviceFd int, vpnNetworks []netip.Prefix) (*tun, error) {
 	file := os.NewFile(uintptr(deviceFd), "/dev/net/tun")
-	useWGDefault := runtime.GOOS == "linux"
+	t, err := newTunGeneric(c, l, file, vpnNetworks)
 	useWG := c.GetBool("tun.use_wireguard_stack", c.GetBool("listen.use_wireguard_stack", useWGDefault))
 	t, err := newTunGeneric(c, l, file, vpnNetworks, useWG)
 	if err != nil {
 		return nil, err
 	}
@@ -118,9 +113,7 @@ func newTun(c *config.C, l *logrus.Logger, vpnNetworks []netip.Prefix, multiqueu
 	name := strings.Trim(string(req.Name[:]), "\x00")
 	file := os.NewFile(uintptr(fd), "/dev/net/tun")
-	useWGDefault := runtime.GOOS == "linux"
+	t, err := newTunGeneric(c, l, file, vpnNetworks)
 	useWG := c.GetBool("tun.use_wireguard_stack", c.GetBool("listen.use_wireguard_stack", useWGDefault))
 	t, err := newTunGeneric(c, l, file, vpnNetworks, useWG)
 	if err != nil {
 		return nil, err
 	}
@@ -130,45 +123,16 @@ func newTun(c *config.C, l *logrus.Logger, vpnNetworks []netip.Prefix, multiqueu
 	return t, nil
 }
-func newTunGeneric(c *config.C, l *logrus.Logger, file *os.File, vpnNetworks []netip.Prefix, useWireguard bool) (*tun, error) {
+func newTunGeneric(c *config.C, l *logrus.Logger, file *os.File, vpnNetworks []netip.Prefix) (*tun, error) {
 	var (
 		rw    io.ReadWriteCloser = file
 		fd                       = int(file.Fd())
 		wgDev wgtun.Device
 	)
 	if useWireguard {
 		dev, err := wgtun.CreateTUNFromFile(file, c.GetInt("tun.mtu", DefaultMTU))
 		if err != nil {
 			return nil, fmt.Errorf("failed to initialize wireguard tun device: %w", err)
 		}
 		wgDev = dev
 		rw = newWireguardTunIO(dev, c.GetInt("tun.mtu", DefaultMTU))
 		fd = int(dev.File().Fd())
 	}
 	t := &tun{
-		ReadWriteCloser:           rw,
+		ReadWriteCloser:           file,
-		fd:                        fd,
+		fd:                        int(file.Fd()),
 		vpnNetworks:               vpnNetworks,
 		TXQueueLen:                c.GetInt("tun.tx_queue", 500),
 		useSystemRoutes:           c.GetBool("tun.use_system_route_table", false),
 		useSystemRoutesBufferSize: c.GetInt("tun.use_system_route_table_buffer_size", 0),
 		l:                         l,
 	}
 	if wgDev != nil {
 		t.wgDevice = wgDev
 	}
 	if wgDev != nil {
 		// replace ioctl fd with device file descriptor to keep route management working
 		file = wgDev.File()
 		t.fd = int(file.Fd())
 		t.ioctlFd = file.Fd()
 	}
 	if t.ioctlFd == 0 {
 		t.ioctlFd = file.Fd()
 	}
 	err := t.reload(c, true)
 	if err != nil {
@@ -714,14 +678,6 @@ func (t *tun) Close() error {
 		_ = t.ReadWriteCloser.Close()
 	}
 	if t.wgDevice != nil {
 		_ = t.wgDevice.Close()
 		if t.ioctlFd > 0 {
 			// underlying fd already closed by the device
 			t.ioctlFd = 0
 		}
 	}
 	if t.ioctlFd > 0 {
 		_ = os.NewFile(t.ioctlFd, "ioctlFd").Close()
 	}
--- a/overlay/tun_linux_batch.go
+++ b/overlay/tun_linux_batch.go
@@ -1,56 +0,0 @@
 //go:build linux && !android && !e2e_testing
 package overlay
 import "fmt"
 func (t *tun) batchIO() (*wireguardTunIO, bool) {
 	io, ok := t.ReadWriteCloser.(*wireguardTunIO)
 	return io, ok
 }
 func (t *tun) ReadIntoBatch(pool *PacketPool) ([]*Packet, error) {
 	io, ok := t.batchIO()
 	if !ok {
 		return nil, fmt.Errorf("wireguard batch I/O not enabled")
 	}
 	return io.ReadIntoBatch(pool)
 }
 func (t *tun) WriteBatch(packets []*Packet) (int, error) {
 	io, ok := t.batchIO()
 	if ok {
 		return io.WriteBatch(packets)
 	}
 	for _, pkt := range packets {
 		if pkt == nil {
 			continue
 		}
 		if _, err := t.Write(pkt.Payload()[:pkt.Len]); err != nil {
 			return 0, err
 		}
 		pkt.Release()
 	}
 	return len(packets), nil
 }
 func (t *tun) BatchHeadroom() int {
 	if io, ok := t.batchIO(); ok {
 		return io.BatchHeadroom()
 	}
 	return 0
 }
 func (t *tun) BatchPayloadCap() int {
 	if io, ok := t.batchIO(); ok {
 		return io.BatchPayloadCap()
 	}
 	return 0
 }
 func (t *tun) BatchSize() int {
 	if io, ok := t.batchIO(); ok {
 		return io.BatchSize()
 	}
 	return 1
 }
--- a/overlay/wireguard_tun_linux.go
+++ b/overlay/wireguard_tun_linux.go
@@ -1,220 +0,0 @@
 //go:build linux && !android && !e2e_testing
 package overlay
 import (
 	"fmt"
 	"sync"
 	wgtun "github.com/slackhq/nebula/wgstack/tun"
 )
 type wireguardTunIO struct {
 	dev       wgtun.Device
 	mtu       int
 	batchSize int
 	readMu      sync.Mutex
 	readBuffers [][]byte
 	readLens    []int
 	legacyBuf   []byte
 	writeMu      sync.Mutex
 	writeBuf     []byte
 	writeWrap    [][]byte
 	writeBuffers [][]byte
 }
 func newWireguardTunIO(dev wgtun.Device, mtu int) *wireguardTunIO {
 	batch := dev.BatchSize()
 	if batch <= 0 {
 		batch = 1
 	}
 	if mtu <= 0 {
 		mtu = DefaultMTU
 	}
 	return &wireguardTunIO{
 		dev:       dev,
 		mtu:       mtu,
 		batchSize: batch,
 		readLens:  make([]int, batch),
 		legacyBuf: make([]byte, wgtun.VirtioNetHdrLen+mtu),
 		writeBuf:  make([]byte, wgtun.VirtioNetHdrLen+mtu),
 		writeWrap: make([][]byte, 1),
 	}
 }
 func (w *wireguardTunIO) Read(p []byte) (int, error) {
 	w.readMu.Lock()
 	defer w.readMu.Unlock()
 	bufs := w.readBuffers
 	if len(bufs) == 0 {
 		bufs = [][]byte{w.legacyBuf}
 		w.readBuffers = bufs
 	}
 	n, err := w.dev.Read(bufs[:1], w.readLens[:1], wgtun.VirtioNetHdrLen)
 	if err != nil {
 		return 0, err
 	}
 	if n == 0 {
 		return 0, nil
 	}
 	length := w.readLens[0]
 	copy(p, w.legacyBuf[wgtun.VirtioNetHdrLen:wgtun.VirtioNetHdrLen+length])
 	return length, nil
 }
 func (w *wireguardTunIO) Write(p []byte) (int, error) {
 	if len(p) > w.mtu {
 		return 0, fmt.Errorf("wireguard tun: payload exceeds MTU (%d > %d)", len(p), w.mtu)
 	}
 	w.writeMu.Lock()
 	defer w.writeMu.Unlock()
 	buf := w.writeBuf[:wgtun.VirtioNetHdrLen+len(p)]
 	for i := 0; i < wgtun.VirtioNetHdrLen; i++ {
 		buf[i] = 0
 	}
 	copy(buf[wgtun.VirtioNetHdrLen:], p)
 	w.writeWrap[0] = buf
 	n, err := w.dev.Write(w.writeWrap, wgtun.VirtioNetHdrLen)
 	if err != nil {
 		return n, err
 	}
 	return len(p), nil
 }
 func (w *wireguardTunIO) ReadIntoBatch(pool *PacketPool) ([]*Packet, error) {
 	if pool == nil {
 		return nil, fmt.Errorf("wireguard tun: packet pool is nil")
 	}
 	w.readMu.Lock()
 	defer w.readMu.Unlock()
 	if len(w.readBuffers) < w.batchSize {
 		w.readBuffers = make([][]byte, w.batchSize)
 	}
 	if len(w.readLens) < w.batchSize {
 		w.readLens = make([]int, w.batchSize)
 	}
 	packets := make([]*Packet, w.batchSize)
 	requiredHeadroom := w.BatchHeadroom()
 	requiredPayload := w.BatchPayloadCap()
 	headroom := 0
 	for i := 0; i < w.batchSize; i++ {
 		pkt := pool.Get()
 		if pkt == nil {
 			releasePackets(packets[:i])
 			return nil, fmt.Errorf("wireguard tun: packet pool returned nil packet")
 		}
 		if pkt.Capacity() < requiredPayload {
 			pkt.Release()
 			releasePackets(packets[:i])
 			return nil, fmt.Errorf("wireguard tun: packet capacity %d below required %d", pkt.Capacity(), requiredPayload)
 		}
 		if i == 0 {
 			headroom = pkt.Offset
 			if headroom < requiredHeadroom {
 				pkt.Release()
 				releasePackets(packets[:i])
 				return nil, fmt.Errorf("wireguard tun: packet headroom %d below virtio requirement %d", headroom, requiredHeadroom)
 			}
 		} else if pkt.Offset != headroom {
 			pkt.Release()
 			releasePackets(packets[:i])
 			return nil, fmt.Errorf("wireguard tun: inconsistent packet headroom (%d != %d)", pkt.Offset, headroom)
 		}
 		packets[i] = pkt
 		w.readBuffers[i] = pkt.Buf
 	}
 	n, err := w.dev.Read(w.readBuffers[:w.batchSize], w.readLens[:w.batchSize], headroom)
 	if err != nil {
 		releasePackets(packets)
 		return nil, err
 	}
 	if n == 0 {
 		releasePackets(packets)
 		return nil, nil
 	}
 	for i := 0; i < n; i++ {
 		packets[i].Len = w.readLens[i]
 	}
 	for i := n; i < w.batchSize; i++ {
 		packets[i].Release()
 		packets[i] = nil
 	}
 	return packets[:n], nil
 }
 func (w *wireguardTunIO) WriteBatch(packets []*Packet) (int, error) {
 	if len(packets) == 0 {
 		return 0, nil
 	}
 	requiredHeadroom := w.BatchHeadroom()
 	offset := packets[0].Offset
 	if offset < requiredHeadroom {
 		releasePackets(packets)
 		return 0, fmt.Errorf("wireguard tun: packet offset %d smaller than required headroom %d", offset, requiredHeadroom)
 	}
 	for _, pkt := range packets {
 		if pkt == nil {
 			continue
 		}
 		if pkt.Offset != offset {
 			releasePackets(packets)
 			return 0, fmt.Errorf("wireguard tun: mixed packet offsets not supported")
 		}
 		limit := pkt.Offset + pkt.Len
 		if limit > len(pkt.Buf) {
 			releasePackets(packets)
 			return 0, fmt.Errorf("wireguard tun: packet length %d exceeds buffer capacity %d", pkt.Len, len(pkt.Buf)-pkt.Offset)
 		}
 	}
 	w.writeMu.Lock()
 	defer w.writeMu.Unlock()
 	if len(w.writeBuffers) < len(packets) {
 		w.writeBuffers = make([][]byte, len(packets))
 	}
 	for i, pkt := range packets {
 		if pkt == nil {
 			w.writeBuffers[i] = nil
 			continue
 		}
 		limit := pkt.Offset + pkt.Len
 		w.writeBuffers[i] = pkt.Buf[:limit]
 	}
 	n, err := w.dev.Write(w.writeBuffers[:len(packets)], offset)
 	if err != nil {
 		return n, err
 	}
 	releasePackets(packets)
 	return n, nil
 }
 func (w *wireguardTunIO) BatchHeadroom() int {
 	return wgtun.VirtioNetHdrLen
 }
 func (w *wireguardTunIO) BatchPayloadCap() int {
 	return w.mtu
 }
 func (w *wireguardTunIO) BatchSize() int {
 	return w.batchSize
 }
 func (w *wireguardTunIO) Close() error {
 	return nil
 }
 func releasePackets(pkts []*Packet) {
 	for _, pkt := range pkts {
 		if pkt != nil {
 			pkt.Release()
 		}
 	}
 }
--- a/pki.go
+++ b/pki.go
@@ -100,62 +100,55 @@ func (p *PKI) reloadCerts(c *config.C, initial bool) *util.ContextualError {
 		currentState := p.cs.Load()
 		if newState.v1Cert != nil {
 			if currentState.v1Cert == nil {
-				//adding certs is fine, actually. Networks-in-common confirmed in newCertState().
+				return util.NewContextualError("v1 certificate was added, restart required", nil, err)
 			} else {
 				// did IP in cert change? if so, don't set
 				if !slices.Equal(currentState.v1Cert.Networks(), newState.v1Cert.Networks()) {
 					return util.NewContextualError(
 						"Networks in new cert was different from old",
 						m{"new_networks": newState.v1Cert.Networks(), "old_networks": currentState.v1Cert.Networks(), "cert_version": cert.Version1},
 						nil,
 					)
 				}
 				if currentState.v1Cert.Curve() != newState.v1Cert.Curve() {
 					return util.NewContextualError(
 						"Curve in new v1 cert was different from old",
 						m{"new_curve": newState.v1Cert.Curve(), "old_curve": currentState.v1Cert.Curve(), "cert_version": cert.Version1},
 						nil,
 					)
 				}
 			}
 			// did IP in cert change? if so, don't set
 			if !slices.Equal(currentState.v1Cert.Networks(), newState.v1Cert.Networks()) {
 				return util.NewContextualError(
 					"Networks in new cert was different from old",
 					m{"new_networks": newState.v1Cert.Networks(), "old_networks": currentState.v1Cert.Networks()},
 					nil,
 				)
 			}
 			if currentState.v1Cert.Curve() != newState.v1Cert.Curve() {
 				return util.NewContextualError(
 					"Curve in new cert was different from old",
 					m{"new_curve": newState.v1Cert.Curve(), "old_curve": currentState.v1Cert.Curve()},
 					nil,
 				)
 			}
 		} else if currentState.v1Cert != nil {
 			//TODO: CERT-V2 we should be able to tear this down
 			return util.NewContextualError("v1 certificate was removed, restart required", nil, err)
 		}
 		if newState.v2Cert != nil {
 			if currentState.v2Cert == nil {
-				//adding certs is fine, actually
+				return util.NewContextualError("v2 certificate was added, restart required", nil, err)
 			} else {
 				// did IP in cert change? if so, don't set
 				if !slices.Equal(currentState.v2Cert.Networks(), newState.v2Cert.Networks()) {
 					return util.NewContextualError(
 						"Networks in new cert was different from old",
 						m{"new_networks": newState.v2Cert.Networks(), "old_networks": currentState.v2Cert.Networks(), "cert_version": cert.Version2},
 						nil,
 					)
 				}
 				if currentState.v2Cert.Curve() != newState.v2Cert.Curve() {
 					return util.NewContextualError(
 						"Curve in new cert was different from old",
 						m{"new_curve": newState.v2Cert.Curve(), "old_curve": currentState.v2Cert.Curve(), "cert_version": cert.Version2},
 						nil,
 					)
 				}
 			}
-		} else if currentState.v2Cert != nil {
+			// did IP in cert change? if so, don't set
-			//newState.v1Cert is non-nil bc empty certstates aren't permitted
+			if !slices.Equal(currentState.v2Cert.Networks(), newState.v2Cert.Networks()) {
 			if newState.v1Cert == nil {
 				return util.NewContextualError("v1 and v2 certs are nil, this should be impossible", nil, err)
 			}
 			//if we're going to v1-only, we need to make sure we didn't orphan any v2-cert vpnaddrs
 			if !slices.Equal(currentState.v2Cert.Networks(), newState.v1Cert.Networks()) {
 				return util.NewContextualError(
-					"Removing a V2 cert is not permitted unless it has identical networks to the new V1 cert",
+					"Networks in new cert was different from old",
-					m{"new_v1_networks": newState.v1Cert.Networks(), "old_v2_networks": currentState.v2Cert.Networks()},
+					m{"new_networks": newState.v2Cert.Networks(), "old_networks": currentState.v2Cert.Networks()},
 					nil,
 				)
 			}
 			if currentState.v2Cert.Curve() != newState.v2Cert.Curve() {
 				return util.NewContextualError(
 					"Curve in new cert was different from old",
 					m{"new_curve": newState.v2Cert.Curve(), "old_curve": currentState.v2Cert.Curve()},
 					nil,
 				)
 			}
 		} else if currentState.v2Cert != nil {
 			return util.NewContextualError("v2 certificate was removed, restart required", nil, err)
 		}
 		// Cipher cant be hot swapped so just leave it at what it was before
--- a/udp/config.go
+++ b/udp/config.go
@@ -0,0 +1,16 @@
 package udp
 import "sync/atomic"
 var disableUDPCsum atomic.Bool
 // SetDisableUDPCsum controls whether IPv4 UDP sockets opt out of kernel
 // checksum calculation via SO_NO_CHECK. Only applicable on platforms that
 // support the option (Linux). IPv6 always keeps the checksum enabled.
 func SetDisableUDPCsum(disable bool) {
 	disableUDPCsum.Store(disable)
 }
 func udpChecksumDisabled() bool {
 	return disableUDPCsum.Load()
 }
--- a/udp/conn.go
+++ b/udp/conn.go
@@ -11,6 +11,7 @@ const MTU = 9001
 type EncReader func(
 	addr netip.AddrPort,
 	payload []byte,
 	release func(),
 )
 type Conn interface {
@@ -22,18 +23,6 @@ type Conn interface {
 	Close() error
 }
 // Datagram represents a UDP payload destined to a specific address.
 type Datagram struct {
 	Payload []byte
 	Addr    netip.AddrPort
 }
 // BatchConn can send multiple datagrams in one syscall.
 type BatchConn interface {
 	Conn
 	WriteBatch(pkts []Datagram) error
 }
 type NoopConn struct{}
 func (NoopConn) Rebind() error {
--- a/udp/io_uring_linux.go
+++ b/udp/io_uring_linux.go
--- a/udp/msghdr_helper_linux_32.go
+++ b/udp/msghdr_helper_linux_32.go
@@ -0,0 +1,25 @@
 //go:build linux && (386 || amd64p32 || arm || mips || mipsle) && !android && !e2e_testing
 // +build linux
 // +build 386 amd64p32 arm mips mipsle
 // +build !android
 // +build !e2e_testing
 package udp
 import "golang.org/x/sys/unix"
 func controllen(n int) uint32 {
 	return uint32(n)
 }
 func setCmsgLen(h *unix.Cmsghdr, n int) {
 	h.Len = uint32(unix.CmsgLen(n))
 }
 func setIovecLen(v *unix.Iovec, n int) {
 	v.Len = uint32(n)
 }
 func setMsghdrIovlen(m *unix.Msghdr, n int) {
 	m.Iovlen = uint32(n)
 }
--- a/udp/msghdr_helper_linux_64.go
+++ b/udp/msghdr_helper_linux_64.go
@@ -0,0 +1,25 @@
 //go:build linux && (amd64 || arm64 || ppc64 || ppc64le || mips64 || mips64le || s390x || riscv64 || loong64) && !android && !e2e_testing
 // +build linux
 // +build amd64 arm64 ppc64 ppc64le mips64 mips64le s390x riscv64 loong64
 // +build !android
 // +build !e2e_testing
 package udp
 import "golang.org/x/sys/unix"
 func controllen(n int) uint64 {
 	return uint64(n)
 }
 func setCmsgLen(h *unix.Cmsghdr, n int) {
 	h.Len = uint64(unix.CmsgLen(n))
 }
 func setIovecLen(v *unix.Iovec, n int) {
 	v.Len = uint64(n)
 }
 func setMsghdrIovlen(m *unix.Msghdr, n int) {
 	m.Iovlen = uint64(n)
 }
--- a/udp/sendmmsg_linux_32.go
+++ b/udp/sendmmsg_linux_32.go
@@ -0,0 +1,25 @@
 //go:build linux && (386 || amd64p32 || arm || mips || mipsle) && !android && !e2e_testing
 package udp
 import (
 	"unsafe"
 	"golang.org/x/sys/unix"
 )
 type linuxMmsgHdr struct {
 	Hdr unix.Msghdr
 	Len uint32
 }
 func sendmmsg(fd int, hdrs []linuxMmsgHdr, flags int) (int, error) {
 	if len(hdrs) == 0 {
 		return 0, nil
 	}
 	n, _, errno := unix.Syscall6(unix.SYS_SENDMMSG, uintptr(fd), uintptr(unsafe.Pointer(&hdrs[0])), uintptr(len(hdrs)), uintptr(flags), 0, 0)
 	if errno != 0 {
 		return int(n), errno
 	}
 	return int(n), nil
 }
--- a/udp/sendmmsg_linux_64.go
+++ b/udp/sendmmsg_linux_64.go
@@ -0,0 +1,26 @@
 //go:build linux && (amd64 || arm64 || ppc64 || ppc64le || mips64 || mips64le || s390x || riscv64 || loong64) && !android && !e2e_testing
 package udp
 import (
 	"unsafe"
 	"golang.org/x/sys/unix"
 )
 type linuxMmsgHdr struct {
 	Hdr unix.Msghdr
 	Len uint32
 	_   uint32
 }
 func sendmmsg(fd int, hdrs []linuxMmsgHdr, flags int) (int, error) {
 	if len(hdrs) == 0 {
 		return 0, nil
 	}
 	n, _, errno := unix.Syscall6(unix.SYS_SENDMMSG, uintptr(fd), uintptr(unsafe.Pointer(&hdrs[0])), uintptr(len(hdrs)), uintptr(flags), 0, 0)
 	if errno != 0 {
 		return int(n), errno
 	}
 	return int(n), nil
 }
--- a/udp/udp_darwin.go
+++ b/udp/udp_darwin.go
@@ -180,7 +180,7 @@ func (u *StdConn) ListenOut(r EncReader) {
 			u.l.WithError(err).Error("unexpected udp socket receive error")
 		}
-		r(netip.AddrPortFrom(rua.Addr().Unmap(), rua.Port()), buffer[:n])
+		r(netip.AddrPortFrom(rua.Addr().Unmap(), rua.Port()), buffer[:n], nil)
 	}
 }
--- a/udp/udp_generic.go
+++ b/udp/udp_generic.go
@@ -82,6 +82,6 @@ func (u *GenericConn) ListenOut(r EncReader) {
 			return
 		}
-		r(netip.AddrPortFrom(rua.Addr().Unmap(), rua.Port()), buffer[:n])
+		r(netip.AddrPortFrom(rua.Addr().Unmap(), rua.Port()), buffer[:n], nil)
 	}
 }
--- a/udp/udp_linux.go
+++ b/udp/udp_linux.go
--- a/udp/udp_linux_32.go
+++ b/udp/udp_linux_32.go
@@ -7,6 +7,9 @@
 package udp
 import (
 	"errors"
 	"fmt"
 	"golang.org/x/sys/unix"
 )
@@ -30,17 +33,29 @@ type rawMessage struct {
 	Len uint32
 }
-func (u *StdConn) PrepareRawMessages(n int) ([]rawMessage, [][]byte, [][]byte) {
+func (u *StdConn) PrepareRawMessages(n int) ([]rawMessage, [][]byte, [][]byte, [][]byte) {
 	controlLen := int(u.controlLen.Load())
 	msgs := make([]rawMessage, n)
 	buffers := make([][]byte, n)
 	names := make([][]byte, n)
 	var controls [][]byte
 	if controlLen > 0 {
 		controls = make([][]byte, n)
 	}
 	for i := range msgs {
-		buffers[i] = make([]byte, MTU)
+		size := int(u.groBufSize.Load())
 		if size < MTU {
 			size = MTU
 		}
 		buf := u.borrowRxBuffer(size)
 		buffers[i] = buf
 		names[i] = make([]byte, unix.SizeofSockaddrInet6)
 		vs := []iovec{
-			{Base: &buffers[i][0], Len: uint32(len(buffers[i]))},
+			{Base: &buf[0], Len: uint32(len(buf))},
 		}
 		msgs[i].Hdr.Iov = &vs[0]
@@ -48,7 +63,71 @@ func (u *StdConn) PrepareRawMessages(n int) ([]rawMessage, [][]byte, [][]byte) {
 		msgs[i].Hdr.Name = &names[i][0]
 		msgs[i].Hdr.Namelen = uint32(len(names[i]))
 		if controlLen > 0 {
 			controls[i] = make([]byte, controlLen)
 			msgs[i].Hdr.Control = &controls[i][0]
 			msgs[i].Hdr.Controllen = controllen(len(controls[i]))
 		} else {
 			msgs[i].Hdr.Control = nil
 			msgs[i].Hdr.Controllen = controllen(0)
 		}
 	}
-	return msgs, buffers, names
+	return msgs, buffers, names, controls
 }
 func setIovecBase(msg *rawMessage, buf []byte) {
 	iov := (*iovec)(msg.Hdr.Iov)
 	iov.Base = &buf[0]
 	iov.Len = uint32(len(buf))
 }
 func rawMessageToUnixMsghdr(msg *rawMessage) (unix.Msghdr, unix.Iovec, error) {
 	var hdr unix.Msghdr
 	var iov unix.Iovec
 	if msg == nil {
 		return hdr, iov, errors.New("nil rawMessage")
 	}
 	if msg.Hdr.Iov == nil || msg.Hdr.Iov.Base == nil {
 		return hdr, iov, errors.New("rawMessage missing payload buffer")
 	}
 	payloadLen := int(msg.Hdr.Iov.Len)
 	if payloadLen < 0 {
 		return hdr, iov, fmt.Errorf("invalid payload length: %d", payloadLen)
 	}
 	iov.Base = msg.Hdr.Iov.Base
 	iov.Len = uint32(payloadLen)
 	hdr.Iov = &iov
 	hdr.Iovlen = 1
 	hdr.Name = msg.Hdr.Name
 	// CRITICAL: Always set to full buffer size for receive, not what kernel wrote last time
 	if hdr.Name != nil {
 		hdr.Namelen = uint32(unix.SizeofSockaddrInet6)
 	} else {
 		hdr.Namelen = 0
 	}
 	hdr.Control = msg.Hdr.Control
 	// CRITICAL: Use the allocated size, not what was previously returned
 	if hdr.Control != nil {
 		// Control buffer size is stored in Controllen from PrepareRawMessages
 		hdr.Controllen = msg.Hdr.Controllen
 	} else {
 		hdr.Controllen = 0
 	}
 	hdr.Flags = 0 // Reset flags for new receive
 	return hdr, iov, nil
 }
 func updateRawMessageFromUnixMsghdr(msg *rawMessage, hdr *unix.Msghdr, n int) {
 	if msg == nil || hdr == nil {
 		return
 	}
 	msg.Hdr.Namelen = hdr.Namelen
 	msg.Hdr.Controllen = hdr.Controllen
 	msg.Hdr.Flags = hdr.Flags
 	if n < 0 {
 		n = 0
 	}
 	msg.Len = uint32(n)
 }
--- a/udp/udp_linux_64.go
+++ b/udp/udp_linux_64.go
@@ -7,6 +7,9 @@
 package udp
 import (
 	"errors"
 	"fmt"
 	"golang.org/x/sys/unix"
 )
@@ -33,25 +36,99 @@ type rawMessage struct {
 	Pad0 [4]byte
 }
-func (u *StdConn) PrepareRawMessages(n int) ([]rawMessage, [][]byte, [][]byte) {
+func (u *StdConn) PrepareRawMessages(n int) ([]rawMessage, [][]byte, [][]byte, [][]byte) {
 	controlLen := int(u.controlLen.Load())
 	msgs := make([]rawMessage, n)
 	buffers := make([][]byte, n)
 	names := make([][]byte, n)
 	var controls [][]byte
 	if controlLen > 0 {
 		controls = make([][]byte, n)
 	}
 	for i := range msgs {
-		buffers[i] = make([]byte, MTU)
+		size := int(u.groBufSize.Load())
 		if size < MTU {
 			size = MTU
 		}
 		buf := u.borrowRxBuffer(size)
 		buffers[i] = buf
 		names[i] = make([]byte, unix.SizeofSockaddrInet6)
-		vs := []iovec{
+		vs := []iovec{{Base: &buf[0], Len: uint64(len(buf))}}
 			{Base: &buffers[i][0], Len: uint64(len(buffers[i]))},
 		}
 		msgs[i].Hdr.Iov = &vs[0]
 		msgs[i].Hdr.Iovlen = uint64(len(vs))
 		msgs[i].Hdr.Name = &names[i][0]
 		msgs[i].Hdr.Namelen = uint32(len(names[i]))
 		if controlLen > 0 {
 			controls[i] = make([]byte, controlLen)
 			msgs[i].Hdr.Control = &controls[i][0]
 			msgs[i].Hdr.Controllen = controllen(len(controls[i]))
 		} else {
 			msgs[i].Hdr.Control = nil
 			msgs[i].Hdr.Controllen = controllen(0)
 		}
 	}
-	return msgs, buffers, names
+	return msgs, buffers, names, controls
 }
 func setIovecBase(msg *rawMessage, buf []byte) {
 	iov := (*iovec)(msg.Hdr.Iov)
 	iov.Base = &buf[0]
 	iov.Len = uint64(len(buf))
 }
 func rawMessageToUnixMsghdr(msg *rawMessage) (unix.Msghdr, unix.Iovec, error) {
 	var hdr unix.Msghdr
 	var iov unix.Iovec
 	if msg == nil {
 		return hdr, iov, errors.New("nil rawMessage")
 	}
 	if msg.Hdr.Iov == nil || msg.Hdr.Iov.Base == nil {
 		return hdr, iov, errors.New("rawMessage missing payload buffer")
 	}
 	payloadLen := int(msg.Hdr.Iov.Len)
 	if payloadLen < 0 {
 		return hdr, iov, fmt.Errorf("invalid payload length: %d", payloadLen)
 	}
 	iov.Base = msg.Hdr.Iov.Base
 	iov.Len = uint64(payloadLen)
 	hdr.Iov = &iov
 	hdr.Iovlen = 1
 	hdr.Name = msg.Hdr.Name
 	// CRITICAL: Always set to full buffer size for receive, not what kernel wrote last time
 	if hdr.Name != nil {
 		hdr.Namelen = uint32(unix.SizeofSockaddrInet6)
 	} else {
 		hdr.Namelen = 0
 	}
 	hdr.Control = msg.Hdr.Control
 	// CRITICAL: Use the allocated size, not what was previously returned
 	if hdr.Control != nil {
 		// Control buffer size is stored in Controllen from PrepareRawMessages
 		hdr.Controllen = msg.Hdr.Controllen
 	} else {
 		hdr.Controllen = 0
 	}
 	hdr.Flags = 0 // Reset flags for new receive
 	return hdr, iov, nil
 }
 func updateRawMessageFromUnixMsghdr(msg *rawMessage, hdr *unix.Msghdr, n int) {
 	if msg == nil || hdr == nil {
 		return
 	}
 	msg.Hdr.Namelen = hdr.Namelen
 	msg.Hdr.Controllen = hdr.Controllen
 	msg.Hdr.Flags = hdr.Flags
 	if n < 0 {
 		n = 0
 	}
 	msg.Len = uint32(n)
 }
--- a/udp/udp_rio_windows.go
+++ b/udp/udp_rio_windows.go
@@ -149,7 +149,7 @@ func (u *RIOConn) ListenOut(r EncReader) {
 			continue
 		}
-		r(netip.AddrPortFrom(netip.AddrFrom16(rua.Addr).Unmap(), (rua.Port>>8)|((rua.Port&0xff)<<8)), buffer[:n])
+		r(netip.AddrPortFrom(netip.AddrFrom16(rua.Addr).Unmap(), (rua.Port>>8)|((rua.Port&0xff)<<8)), buffer[:n], nil)
 	}
 }
--- a/udp/udp_tester.go
+++ b/udp/udp_tester.go
@@ -112,7 +112,7 @@ func (u *TesterConn) ListenOut(r EncReader) {
 		if !ok {
 			return
 		}
-		r(p.From, p.Data)
+		r(p.From, p.Data, func() {})
 	}
 }
--- a/udp/wireguard_conn_linux.go
+++ b/udp/wireguard_conn_linux.go
@@ -1,225 +0,0 @@
 //go:build linux && !android && !e2e_testing
 package udp
 import (
 	"errors"
 	"net"
 	"net/netip"
 	"sync"
 	"sync/atomic"
 	"github.com/sirupsen/logrus"
 	"github.com/slackhq/nebula/config"
 	wgconn "github.com/slackhq/nebula/wgstack/conn"
 )
 // WGConn adapts WireGuard's batched UDP bind implementation to Nebula's udp.Conn interface.
 type WGConn struct {
 	l         *logrus.Logger
 	bind      *wgconn.StdNetBind
 	recvers   []wgconn.ReceiveFunc
 	batch     int
 	reqBatch  int
 	localIP   netip.Addr
 	localPort uint16
 	enableGSO bool
 	enableGRO bool
 	gsoMaxSeg int
 	closed    atomic.Bool
 	closeOnce sync.Once
 }
 // NewWireguardListener creates a UDP listener backed by WireGuard's StdNetBind.
 func NewWireguardListener(l *logrus.Logger, ip netip.Addr, port int, multi bool, batch int) (Conn, error) {
 	bind := wgconn.NewStdNetBindForAddr(ip, multi)
 	recvers, actualPort, err := bind.Open(uint16(port))
 	if err != nil {
 		return nil, err
 	}
 	if batch <= 0 {
 		batch = bind.BatchSize()
 	} else if batch > bind.BatchSize() {
 		batch = bind.BatchSize()
 	}
 	return &WGConn{
 		l:         l,
 		bind:      bind,
 		recvers:   recvers,
 		batch:     batch,
 		reqBatch:  batch,
 		localIP:   ip,
 		localPort: actualPort,
 	}, nil
 }
 func (c *WGConn) Rebind() error {
 	// WireGuard's bind does not support rebinding in place.
 	return nil
 }
 func (c *WGConn) LocalAddr() (netip.AddrPort, error) {
 	if !c.localIP.IsValid() || c.localIP.IsUnspecified() {
 		// Fallback to wildcard IPv4 for display purposes.
 		return netip.AddrPortFrom(netip.IPv4Unspecified(), c.localPort), nil
 	}
 	return netip.AddrPortFrom(c.localIP, c.localPort), nil
 }
 func (c *WGConn) listen(fn wgconn.ReceiveFunc, r EncReader) {
 	batchSize := c.batch
 	packets := make([][]byte, batchSize)
 	for i := range packets {
 		packets[i] = make([]byte, MTU)
 	}
 	sizes := make([]int, batchSize)
 	endpoints := make([]wgconn.Endpoint, batchSize)
 	for {
 		if c.closed.Load() {
 			return
 		}
 		n, err := fn(packets, sizes, endpoints)
 		if err != nil {
 			if errors.Is(err, net.ErrClosed) {
 				return
 			}
 			if c.l != nil {
 				c.l.WithError(err).Debug("wireguard UDP listener receive error")
 			}
 			continue
 		}
 		for i := 0; i < n; i++ {
 			if sizes[i] == 0 {
 				continue
 			}
 			stdEp, ok := endpoints[i].(*wgconn.StdNetEndpoint)
 			if !ok {
 				if c.l != nil {
 					c.l.Warn("wireguard UDP listener received unexpected endpoint type")
 				}
 				continue
 			}
 			addr := stdEp.AddrPort
 			r(addr, packets[i][:sizes[i]])
 			endpoints[i] = nil
 		}
 	}
 }
 func (c *WGConn) ListenOut(r EncReader) {
 	for _, fn := range c.recvers {
 		go c.listen(fn, r)
 	}
 }
 func (c *WGConn) WriteTo(b []byte, addr netip.AddrPort) error {
 	if len(b) == 0 {
 		return nil
 	}
 	if c.closed.Load() {
 		return net.ErrClosed
 	}
 	ep := &wgconn.StdNetEndpoint{AddrPort: addr}
 	return c.bind.Send([][]byte{b}, ep)
 }
 func (c *WGConn) WriteBatch(datagrams []Datagram) error {
 	if len(datagrams) == 0 {
 		return nil
 	}
 	if c.closed.Load() {
 		return net.ErrClosed
 	}
 	max := c.batch
 	if max <= 0 {
 		max = len(datagrams)
 		if max == 0 {
 			max = 1
 		}
 	}
 	bufs := make([][]byte, 0, max)
 	var (
 		current  netip.AddrPort
 		endpoint *wgconn.StdNetEndpoint
 		haveAddr bool
 	)
 	flush := func() error {
 		if len(bufs) == 0 || endpoint == nil {
 			bufs = bufs[:0]
 			return nil
 		}
 		err := c.bind.Send(bufs, endpoint)
 		bufs = bufs[:0]
 		return err
 	}
 	for _, d := range datagrams {
 		if len(d.Payload) == 0 || !d.Addr.IsValid() {
 			continue
 		}
 		if !haveAddr || d.Addr != current {
 			if err := flush(); err != nil {
 				return err
 			}
 			current = d.Addr
 			endpoint = &wgconn.StdNetEndpoint{AddrPort: current}
 			haveAddr = true
 		}
 		bufs = append(bufs, d.Payload)
 		if len(bufs) >= max {
 			if err := flush(); err != nil {
 				return err
 			}
 		}
 	}
 	return flush()
 }
 func (c *WGConn) ConfigureOffload(enableGSO, enableGRO bool, maxSegments int) {
 	c.enableGSO = enableGSO
 	c.enableGRO = enableGRO
 	if maxSegments <= 0 {
 		maxSegments = 1
 	} else if maxSegments > wgconn.IdealBatchSize {
 		maxSegments = wgconn.IdealBatchSize
 	}
 	c.gsoMaxSeg = maxSegments
 	effectiveBatch := c.reqBatch
 	if enableGSO && c.bind != nil {
 		bindBatch := c.bind.BatchSize()
 		if effectiveBatch < bindBatch {
 			if c.l != nil {
 				c.l.WithFields(logrus.Fields{
 					"requested": c.reqBatch,
 					"effective": bindBatch,
 				}).Warn("listen.batch below wireguard minimum; using bind batch size for UDP GSO support")
 			}
 			effectiveBatch = bindBatch
 		}
 	}
 	c.batch = effectiveBatch
 	if c.l != nil {
 		c.l.WithFields(logrus.Fields{
 			"enableGSO":      enableGSO,
 			"enableGRO":      enableGRO,
 			"gsoMaxSegments": maxSegments,
 		}).Debug("configured wireguard UDP offload")
 	}
 }
 func (c *WGConn) ReloadConfig(*config.C) {
 	// WireGuard bind currently does not expose runtime configuration knobs.
 }
 func (c *WGConn) Close() error {
 	var err error
 	c.closeOnce.Do(func() {
 		c.closed.Store(true)
 		err = c.bind.Close()
 	})
 	return err
 }
--- a/udp/wireguard_conn_unsupported.go
+++ b/udp/wireguard_conn_unsupported.go
@@ -1,15 +0,0 @@
 //go:build !linux || android || e2e_testing
 package udp
 import (
 	"fmt"
 	"net/netip"
 	"github.com/sirupsen/logrus"
 )
 // NewWireguardListener is only available on Linux builds.
 func NewWireguardListener(*logrus.Logger, netip.Addr, int, bool, int) (Conn, error) {
 	return nil, fmt.Errorf("wireguard experimental UDP listener is only supported on Linux")
 }
--- a/wgstack/conn/bind_std.go
+++ b/wgstack/conn/bind_std.go
@@ -1,539 +0,0 @@
 // SPDX-License-Identifier: MIT
 //
 // Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 package conn
 import (
 	"context"
 	"errors"
 	"net"
 	"net/netip"
 	"runtime"
 	"strconv"
 	"sync"
 	"syscall"
 	"golang.org/x/net/ipv4"
 	"golang.org/x/net/ipv6"
 	"golang.org/x/sys/unix"
 )
 var (
 	_ Bind = (*StdNetBind)(nil)
 )
 // StdNetBind implements Bind for all platforms. While Windows has its own Bind
 // (see bind_windows.go), it may fall back to StdNetBind.
 // TODO: Remove usage of ipv{4,6}.PacketConn when net.UDPConn has comparable
 // methods for sending and receiving multiple datagrams per-syscall. See the
 // proposal in https://github.com/golang/go/issues/45886#issuecomment-1218301564.
 type StdNetBind struct {
 	mu     sync.Mutex // protects all fields except as specified
 	ipv4   *net.UDPConn
 	ipv6   *net.UDPConn
 	ipv4PC *ipv4.PacketConn // will be nil on non-Linux
 	ipv6PC *ipv6.PacketConn // will be nil on non-Linux
 	// these three fields are not guarded by mu
 	udpAddrPool  sync.Pool
 	ipv4MsgsPool sync.Pool
 	ipv6MsgsPool sync.Pool
 	blackhole4 bool
 	blackhole6 bool
 	listenAddr4 string
 	listenAddr6 string
 	bindV4      bool
 	bindV6      bool
 	reusePort   bool
 }
 func newStdNetBind() *StdNetBind {
 	return &StdNetBind{
 		udpAddrPool: sync.Pool{
 			New: func() any {
 				return &net.UDPAddr{
 					IP: make([]byte, 16),
 				}
 			},
 		},
 		ipv4MsgsPool: sync.Pool{
 			New: func() any {
 				msgs := make([]ipv4.Message, IdealBatchSize)
 				for i := range msgs {
 					msgs[i].Buffers = make(net.Buffers, 1)
 					msgs[i].OOB = make([]byte, srcControlSize)
 				}
 				return &msgs
 			},
 		},
 		ipv6MsgsPool: sync.Pool{
 			New: func() any {
 				msgs := make([]ipv6.Message, IdealBatchSize)
 				for i := range msgs {
 					msgs[i].Buffers = make(net.Buffers, 1)
 					msgs[i].OOB = make([]byte, srcControlSize)
 				}
 				return &msgs
 			},
 		},
 		bindV4:    true,
 		bindV6:    true,
 		reusePort: false,
 	}
 }
 // NewStdNetBind creates a bind that listens on all interfaces.
 func NewStdNetBind() *StdNetBind {
 	return newStdNetBind()
 }
 // NewStdNetBindForAddr creates a bind that listens on a specific address.
 // If addr is IPv4, only the IPv4 socket will be created. For IPv6, only the
 // IPv6 socket will be created.
 func NewStdNetBindForAddr(addr netip.Addr, reusePort bool) *StdNetBind {
 	b := newStdNetBind()
 	if addr.IsValid() {
 		if addr.IsUnspecified() {
 			// keep dual-stack defaults with empty listen addresses
 		} else if addr.Is4() {
 			b.listenAddr4 = addr.Unmap().String()
 			b.bindV4 = true
 			b.bindV6 = false
 		} else {
 			b.listenAddr6 = addr.Unmap().String()
 			b.bindV6 = true
 			b.bindV4 = false
 		}
 	}
 	b.reusePort = reusePort
 	return b
 }
 type StdNetEndpoint struct {
 	// AddrPort is the endpoint destination.
 	netip.AddrPort
 	// src is the current sticky source address and interface index, if supported.
 	src struct {
 		netip.Addr
 		ifidx int32
 	}
 }
 var (
 	_ Bind     = (*StdNetBind)(nil)
 	_ Endpoint = &StdNetEndpoint{}
 )
 func (*StdNetBind) ParseEndpoint(s string) (Endpoint, error) {
 	e, err := netip.ParseAddrPort(s)
 	if err != nil {
 		return nil, err
 	}
 	return &StdNetEndpoint{
 		AddrPort: e,
 	}, nil
 }
 func (e *StdNetEndpoint) ClearSrc() {
 	e.src.ifidx = 0
 	e.src.Addr = netip.Addr{}
 }
 func (e *StdNetEndpoint) DstIP() netip.Addr {
 	return e.AddrPort.Addr()
 }
 func (e *StdNetEndpoint) SrcIP() netip.Addr {
 	return e.src.Addr
 }
 func (e *StdNetEndpoint) SrcIfidx() int32 {
 	return e.src.ifidx
 }
 func (e *StdNetEndpoint) DstToBytes() []byte {
 	b, _ := e.AddrPort.MarshalBinary()
 	return b
 }
 func (e *StdNetEndpoint) DstToString() string {
 	return e.AddrPort.String()
 }
 func (e *StdNetEndpoint) SrcToString() string {
 	return e.src.Addr.String()
 }
 func (s *StdNetBind) listenNet(network string, host string, port int) (*net.UDPConn, int, error) {
 	lc := listenConfig()
 	if s.reusePort {
 		base := lc.Control
 		lc.Control = func(network, address string, c syscall.RawConn) error {
 			if base != nil {
 				if err := base(network, address, c); err != nil {
 					return err
 				}
 			}
 			return c.Control(func(fd uintptr) {
 				_ = unix.SetsockoptInt(int(fd), unix.SOL_SOCKET, unix.SO_REUSEPORT, 1)
 			})
 		}
 	}
 	addr := ":" + strconv.Itoa(port)
 	if host != "" {
 		addr = net.JoinHostPort(host, strconv.Itoa(port))
 	}
 	conn, err := lc.ListenPacket(context.Background(), network, addr)
 	if err != nil {
 		return nil, 0, err
 	}
 	// Retrieve port.
 	laddr := conn.LocalAddr()
 	uaddr, err := net.ResolveUDPAddr(
 		laddr.Network(),
 		laddr.String(),
 	)
 	if err != nil {
 		return nil, 0, err
 	}
 	return conn.(*net.UDPConn), uaddr.Port, nil
 }
 func (s *StdNetBind) openIPv4(port int) (*net.UDPConn, *ipv4.PacketConn, int, error) {
 	if !s.bindV4 {
 		return nil, nil, port, nil
 	}
 	host := s.listenAddr4
 	conn, actualPort, err := s.listenNet("udp4", host, port)
 	if err != nil {
 		if errors.Is(err, syscall.EAFNOSUPPORT) {
 			return nil, nil, port, nil
 		}
 		return nil, nil, port, err
 	}
 	if runtime.GOOS != "linux" {
 		return conn, nil, actualPort, nil
 	}
 	pc := ipv4.NewPacketConn(conn)
 	return conn, pc, actualPort, nil
 }
 func (s *StdNetBind) openIPv6(port int) (*net.UDPConn, *ipv6.PacketConn, int, error) {
 	if !s.bindV6 {
 		return nil, nil, port, nil
 	}
 	host := s.listenAddr6
 	conn, actualPort, err := s.listenNet("udp6", host, port)
 	if err != nil {
 		if errors.Is(err, syscall.EAFNOSUPPORT) {
 			return nil, nil, port, nil
 		}
 		return nil, nil, port, err
 	}
 	if runtime.GOOS != "linux" {
 		return conn, nil, actualPort, nil
 	}
 	pc := ipv6.NewPacketConn(conn)
 	return conn, pc, actualPort, nil
 }
 func (s *StdNetBind) Open(uport uint16) ([]ReceiveFunc, uint16, error) {
 	s.mu.Lock()
 	defer s.mu.Unlock()
 	var err error
 	var tries int
 	if s.ipv4 != nil || s.ipv6 != nil {
 		return nil, 0, ErrBindAlreadyOpen
 	}
 	// Attempt to open ipv4 and ipv6 listeners on the same port.
 	// If uport is 0, we can retry on failure.
 again:
 	port := int(uport)
 	var v4conn *net.UDPConn
 	var v6conn *net.UDPConn
 	var v4pc *ipv4.PacketConn
 	var v6pc *ipv6.PacketConn
 	v4conn, v4pc, port, err = s.openIPv4(port)
 	if err != nil {
 		return nil, 0, err
 	}
 	// Listen on the same port as we're using for ipv4.
 	v6conn, v6pc, port, err = s.openIPv6(port)
 	if uport == 0 && errors.Is(err, syscall.EADDRINUSE) && tries < 100 {
 		if v4conn != nil {
 			v4conn.Close()
 		}
 		tries++
 		goto again
 	}
 	if err != nil {
 		if v4conn != nil {
 			v4conn.Close()
 		}
 		return nil, 0, err
 	}
 	var fns []ReceiveFunc
 	if v4conn != nil {
 		s.ipv4 = v4conn
 		if v4pc != nil {
 			s.ipv4PC = v4pc
 		}
 		fns = append(fns, s.makeReceiveIPv4(v4pc, v4conn))
 	}
 	if v6conn != nil {
 		s.ipv6 = v6conn
 		if v6pc != nil {
 			s.ipv6PC = v6pc
 		}
 		fns = append(fns, s.makeReceiveIPv6(v6pc, v6conn))
 	}
 	if len(fns) == 0 {
 		return nil, 0, syscall.EAFNOSUPPORT
 	}
 	return fns, uint16(port), nil
 }
 func (s *StdNetBind) makeReceiveIPv4(pc *ipv4.PacketConn, conn *net.UDPConn) ReceiveFunc {
 	return func(bufs [][]byte, sizes []int, eps []Endpoint) (n int, err error) {
 		msgs := s.ipv4MsgsPool.Get().(*[]ipv4.Message)
 		defer s.ipv4MsgsPool.Put(msgs)
 		for i := range bufs {
 			(*msgs)[i].Buffers[0] = bufs[i]
 		}
 		var numMsgs int
 		if runtime.GOOS == "linux" && pc != nil {
 			numMsgs, err = pc.ReadBatch(*msgs, 0)
 			if err != nil {
 				return 0, err
 			}
 		} else {
 			msg := &(*msgs)[0]
 			msg.N, msg.NN, _, msg.Addr, err = conn.ReadMsgUDP(msg.Buffers[0], msg.OOB)
 			if err != nil {
 				return 0, err
 			}
 			numMsgs = 1
 		}
 		for i := 0; i < numMsgs; i++ {
 			msg := &(*msgs)[i]
 			sizes[i] = msg.N
 			addrPort := msg.Addr.(*net.UDPAddr).AddrPort()
 			ep := &StdNetEndpoint{AddrPort: addrPort} // TODO: remove allocation
 			getSrcFromControl(msg.OOB[:msg.NN], ep)
 			eps[i] = ep
 		}
 		return numMsgs, nil
 	}
 }
 func (s *StdNetBind) makeReceiveIPv6(pc *ipv6.PacketConn, conn *net.UDPConn) ReceiveFunc {
 	return func(bufs [][]byte, sizes []int, eps []Endpoint) (n int, err error) {
 		msgs := s.ipv6MsgsPool.Get().(*[]ipv6.Message)
 		defer s.ipv6MsgsPool.Put(msgs)
 		for i := range bufs {
 			(*msgs)[i].Buffers[0] = bufs[i]
 		}
 		var numMsgs int
 		if runtime.GOOS == "linux" && pc != nil {
 			numMsgs, err = pc.ReadBatch(*msgs, 0)
 			if err != nil {
 				return 0, err
 			}
 		} else {
 			msg := &(*msgs)[0]
 			msg.N, msg.NN, _, msg.Addr, err = conn.ReadMsgUDP(msg.Buffers[0], msg.OOB)
 			if err != nil {
 				return 0, err
 			}
 			numMsgs = 1
 		}
 		for i := 0; i < numMsgs; i++ {
 			msg := &(*msgs)[i]
 			sizes[i] = msg.N
 			addrPort := msg.Addr.(*net.UDPAddr).AddrPort()
 			ep := &StdNetEndpoint{AddrPort: addrPort} // TODO: remove allocation
 			getSrcFromControl(msg.OOB[:msg.NN], ep)
 			eps[i] = ep
 		}
 		return numMsgs, nil
 	}
 }
 // TODO: When all Binds handle IdealBatchSize, remove this dynamic function and
 // rename the IdealBatchSize constant to BatchSize.
 func (s *StdNetBind) BatchSize() int {
 	if runtime.GOOS == "linux" {
 		return IdealBatchSize
 	}
 	return 1
 }
 func (s *StdNetBind) Close() error {
 	s.mu.Lock()
 	defer s.mu.Unlock()
 	var err1, err2 error
 	if s.ipv4 != nil {
 		err1 = s.ipv4.Close()
 		s.ipv4 = nil
 		s.ipv4PC = nil
 	}
 	if s.ipv6 != nil {
 		err2 = s.ipv6.Close()
 		s.ipv6 = nil
 		s.ipv6PC = nil
 	}
 	s.blackhole4 = false
 	s.blackhole6 = false
 	if err1 != nil {
 		return err1
 	}
 	return err2
 }
 func (s *StdNetBind) Send(bufs [][]byte, endpoint Endpoint) error {
 	s.mu.Lock()
 	blackhole := s.blackhole4
 	conn := s.ipv4
 	var (
 		pc4 *ipv4.PacketConn
 		pc6 *ipv6.PacketConn
 	)
 	is6 := false
 	if endpoint.DstIP().Is6() {
 		blackhole = s.blackhole6
 		conn = s.ipv6
 		pc6 = s.ipv6PC
 		is6 = true
 	} else {
 		pc4 = s.ipv4PC
 	}
 	s.mu.Unlock()
 	if blackhole {
 		return nil
 	}
 	if conn == nil {
 		return syscall.EAFNOSUPPORT
 	}
 	if is6 {
 		return s.send6(conn, pc6, endpoint, bufs)
 	} else {
 		return s.send4(conn, pc4, endpoint, bufs)
 	}
 }
 func (s *StdNetBind) send4(conn *net.UDPConn, pc *ipv4.PacketConn, ep Endpoint, bufs [][]byte) error {
 	ua := s.udpAddrPool.Get().(*net.UDPAddr)
 	as4 := ep.DstIP().As4()
 	copy(ua.IP, as4[:])
 	ua.IP = ua.IP[:4]
 	ua.Port = int(ep.(*StdNetEndpoint).Port())
 	msgs := s.ipv4MsgsPool.Get().(*[]ipv4.Message)
 	for i, buf := range bufs {
 		(*msgs)[i].Buffers[0] = buf
 		(*msgs)[i].Addr = ua
 		setSrcControl(&(*msgs)[i].OOB, ep.(*StdNetEndpoint))
 	}
 	var (
 		n     int
 		err   error
 		start int
 	)
 	if runtime.GOOS == "linux" && pc != nil {
 		for {
 			n, err = pc.WriteBatch((*msgs)[start:len(bufs)], 0)
 			if err != nil {
 				if errors.Is(err, syscall.EAFNOSUPPORT) {
 					for j := start; j < len(bufs); j++ {
 						_, _, werr := conn.WriteMsgUDP(bufs[j], (*msgs)[j].OOB, ua)
 						if werr != nil {
 							err = werr
 							break
 						}
 					}
 				}
 				break
 			}
 			if n == len((*msgs)[start:len(bufs)]) {
 				break
 			}
 			start += n
 		}
 	} else {
 		for i, buf := range bufs {
 			_, _, err = conn.WriteMsgUDP(buf, (*msgs)[i].OOB, ua)
 			if err != nil {
 				break
 			}
 		}
 	}
 	s.udpAddrPool.Put(ua)
 	s.ipv4MsgsPool.Put(msgs)
 	return err
 }
 func (s *StdNetBind) send6(conn *net.UDPConn, pc *ipv6.PacketConn, ep Endpoint, bufs [][]byte) error {
 	ua := s.udpAddrPool.Get().(*net.UDPAddr)
 	as16 := ep.DstIP().As16()
 	copy(ua.IP, as16[:])
 	ua.IP = ua.IP[:16]
 	ua.Port = int(ep.(*StdNetEndpoint).Port())
 	msgs := s.ipv6MsgsPool.Get().(*[]ipv6.Message)
 	for i, buf := range bufs {
 		(*msgs)[i].Buffers[0] = buf
 		(*msgs)[i].Addr = ua
 		setSrcControl(&(*msgs)[i].OOB, ep.(*StdNetEndpoint))
 	}
 	var (
 		n     int
 		err   error
 		start int
 	)
 	if runtime.GOOS == "linux" && pc != nil {
 		for {
 			n, err = pc.WriteBatch((*msgs)[start:len(bufs)], 0)
 			if err != nil {
 				if errors.Is(err, syscall.EAFNOSUPPORT) {
 					for j := start; j < len(bufs); j++ {
 						_, _, werr := conn.WriteMsgUDP(bufs[j], (*msgs)[j].OOB, ua)
 						if werr != nil {
 							err = werr
 							break
 						}
 					}
 				}
 				break
 			}
 			if n == len((*msgs)[start:len(bufs)]) {
 				break
 			}
 			start += n
 		}
 	} else {
 		for i, buf := range bufs {
 			_, _, err = conn.WriteMsgUDP(buf, (*msgs)[i].OOB, ua)
 			if err != nil {
 				break
 			}
 		}
 	}
 	s.udpAddrPool.Put(ua)
 	s.ipv6MsgsPool.Put(msgs)
 	return err
 }
--- a/wgstack/conn/conn.go
+++ b/wgstack/conn/conn.go
@@ -1,131 +0,0 @@
 // SPDX-License-Identifier: MIT
 //
 // Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 package conn
 import (
 	"errors"
 	"fmt"
 	"net/netip"
 	"reflect"
 	"runtime"
 	"strings"
 )
 const (
 	IdealBatchSize = 128 // maximum number of packets handled per read and write
 )
 // A ReceiveFunc receives at least one packet from the network and writes them
 // into packets. On a successful read it returns the number of elements of
 // sizes, packets, and endpoints that should be evaluated. Some elements of
 // sizes may be zero, and callers should ignore them. Callers must pass a sizes
 // and eps slice with a length greater than or equal to the length of packets.
 // These lengths must not exceed the length of the associated Bind.BatchSize().
 type ReceiveFunc func(packets [][]byte, sizes []int, eps []Endpoint) (n int, err error)
 // A Bind listens on a port for both IPv6 and IPv4 UDP traffic.
 //
 // A Bind interface may also be a PeekLookAtSocketFd or BindSocketToInterface,
 // depending on the platform-specific implementation.
 type Bind interface {
 	// Open puts the Bind into a listening state on a given port and reports the actual
 	// port that it bound to. Passing zero results in a random selection.
 	// fns is the set of functions that will be called to receive packets.
 	Open(port uint16) (fns []ReceiveFunc, actualPort uint16, err error)
 	// Close closes the Bind listener.
 	// All fns returned by Open must return net.ErrClosed after a call to Close.
 	Close() error
 	// SetMark sets the mark for each packet sent through this Bind.
 	// This mark is passed to the kernel as the socket option SO_MARK.
 	SetMark(mark uint32) error
 	// Send writes one or more packets in bufs to address ep. The length of
 	// bufs must not exceed BatchSize().
 	Send(bufs [][]byte, ep Endpoint) error
 	// ParseEndpoint creates a new endpoint from a string.
 	ParseEndpoint(s string) (Endpoint, error)
 	// BatchSize is the number of buffers expected to be passed to
 	// the ReceiveFuncs, and the maximum expected to be passed to SendBatch.
 	BatchSize() int
 }
 // BindSocketToInterface is implemented by Bind objects that support being
 // tied to a single network interface. Used by wireguard-windows.
 type BindSocketToInterface interface {
 	BindSocketToInterface4(interfaceIndex uint32, blackhole bool) error
 	BindSocketToInterface6(interfaceIndex uint32, blackhole bool) error
 }
 // PeekLookAtSocketFd is implemented by Bind objects that support having their
 // file descriptor peeked at. Used by wireguard-android.
 type PeekLookAtSocketFd interface {
 	PeekLookAtSocketFd4() (fd int, err error)
 	PeekLookAtSocketFd6() (fd int, err error)
 }
 // An Endpoint maintains the source/destination caching for a peer.
 //
 //	dst: the remote address of a peer ("endpoint" in uapi terminology)
 //	src: the local address from which datagrams originate going to the peer
 type Endpoint interface {
 	ClearSrc()           // clears the source address
 	SrcToString() string // returns the local source address (ip:port)
 	DstToString() string // returns the destination address (ip:port)
 	DstToBytes() []byte  // used for mac2 cookie calculations
 	DstIP() netip.Addr
 	SrcIP() netip.Addr
 }
 var (
 	ErrBindAlreadyOpen   = errors.New("bind is already open")
 	ErrWrongEndpointType = errors.New("endpoint type does not correspond with bind type")
 )
 func (fn ReceiveFunc) PrettyName() string {
 	name := runtime.FuncForPC(reflect.ValueOf(fn).Pointer()).Name()
 	// 0. cheese/taco.beansIPv6.func12.func21218-fm
 	name = strings.TrimSuffix(name, "-fm")
 	// 1. cheese/taco.beansIPv6.func12.func21218
 	if idx := strings.LastIndexByte(name, '/'); idx != -1 {
 		name = name[idx+1:]
 		// 2. taco.beansIPv6.func12.func21218
 	}
 	for {
 		var idx int
 		for idx = len(name) - 1; idx >= 0; idx-- {
 			if name[idx] < '0' || name[idx] > '9' {
 				break
 			}
 		}
 		if idx == len(name)-1 {
 			break
 		}
 		const dotFunc = ".func"
 		if !strings.HasSuffix(name[:idx+1], dotFunc) {
 			break
 		}
 		name = name[:idx+1-len(dotFunc)]
 		// 3. taco.beansIPv6.func12
 		// 4. taco.beansIPv6
 	}
 	if idx := strings.LastIndexByte(name, '.'); idx != -1 {
 		name = name[idx+1:]
 		// 5. beansIPv6
 	}
 	if name == "" {
 		return fmt.Sprintf("%p", fn)
 	}
 	if strings.HasSuffix(name, "IPv4") {
 		return "v4"
 	}
 	if strings.HasSuffix(name, "IPv6") {
 		return "v6"
 	}
 	return name
 }
--- a/wgstack/conn/controlfns.go
+++ b/wgstack/conn/controlfns.go
@@ -1,42 +0,0 @@
 // SPDX-License-Identifier: MIT
 //
 // Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 package conn
 import (
 	"net"
 	"syscall"
 )
 // UDP socket read/write buffer size (7MB). The value of 7MB is chosen as it is
 // the max supported by a default configuration of macOS. Some platforms will
 // silently clamp the value to other maximums, such as linux clamping to
 // net.core.{r,w}mem_max (see _linux.go for additional implementation that works
 // around this limitation)
 const socketBufferSize = 7 << 20
 // controlFn is the callback function signature from net.ListenConfig.Control.
 // It is used to apply platform specific configuration to the socket prior to
 // bind.
 type controlFn func(network, address string, c syscall.RawConn) error
 // controlFns is a list of functions that are called from the listen config
 // that can apply socket options.
 var controlFns = []controlFn{}
 // listenConfig returns a net.ListenConfig that applies the controlFns to the
 // socket prior to bind. This is used to apply socket buffer sizing and packet
 // information OOB configuration for sticky sockets.
 func listenConfig() *net.ListenConfig {
 	return &net.ListenConfig{
 		Control: func(network, address string, c syscall.RawConn) error {
 			for _, fn := range controlFns {
 				if err := fn(network, address, c); err != nil {
 					return err
 				}
 			}
 			return nil
 		},
 	}
 }
--- a/wgstack/conn/controlfns_linux.go
+++ b/wgstack/conn/controlfns_linux.go
@@ -1,62 +0,0 @@
 //go:build linux
 // SPDX-License-Identifier: MIT
 //
 // Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 package conn
 import (
 	"fmt"
 	"runtime"
 	"syscall"
 	"golang.org/x/sys/unix"
 )
 func init() {
 	controlFns = append(controlFns,
 		// Attempt to set the socket buffer size beyond net.core.{r,w}mem_max by
 		// using SO_*BUFFORCE. This requires CAP_NET_ADMIN, and is allowed here to
 		// fail silently - the result of failure is lower performance on very fast
 		// links or high latency links.
 		func(network, address string, c syscall.RawConn) error {
 			return c.Control(func(fd uintptr) {
 				// Set up to *mem_max
 				_ = unix.SetsockoptInt(int(fd), unix.SOL_SOCKET, unix.SO_RCVBUF, socketBufferSize)
 				_ = unix.SetsockoptInt(int(fd), unix.SOL_SOCKET, unix.SO_SNDBUF, socketBufferSize)
 				// Set beyond *mem_max if CAP_NET_ADMIN
 				_ = unix.SetsockoptInt(int(fd), unix.SOL_SOCKET, unix.SO_RCVBUFFORCE, socketBufferSize)
 				_ = unix.SetsockoptInt(int(fd), unix.SOL_SOCKET, unix.SO_SNDBUFFORCE, socketBufferSize)
 			})
 		},
 		// Enable receiving of the packet information (IP_PKTINFO for IPv4,
 		// IPV6_PKTINFO for IPv6) that is used to implement sticky socket support.
 		func(network, address string, c syscall.RawConn) error {
 			var err error
 			switch network {
 			case "udp4":
 				if runtime.GOOS != "android" {
 					c.Control(func(fd uintptr) {
 						err = unix.SetsockoptInt(int(fd), unix.IPPROTO_IP, unix.IP_PKTINFO, 1)
 					})
 				}
 			case "udp6":
 				c.Control(func(fd uintptr) {
 					if runtime.GOOS != "android" {
 						err = unix.SetsockoptInt(int(fd), unix.IPPROTO_IPV6, unix.IPV6_RECVPKTINFO, 1)
 						if err != nil {
 							return
 						}
 					}
 					err = unix.SetsockoptInt(int(fd), unix.IPPROTO_IPV6, unix.IPV6_V6ONLY, 1)
 				})
 			default:
 				err = fmt.Errorf("unhandled network: %s: %w", network, unix.EINVAL)
 			}
 			return err
 		},
 	)
 }
--- a/wgstack/conn/default.go
+++ b/wgstack/conn/default.go
@@ -1,9 +0,0 @@
 //go:build !windows
 // SPDX-License-Identifier: MIT
 //
 // Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 package conn
 func NewDefaultBind() Bind { return NewStdNetBind() }
--- a/wgstack/conn/errors_default.go
+++ b/wgstack/conn/errors_default.go
@@ -1,12 +0,0 @@
 //go:build !linux
 /* SPDX-License-Identifier: MIT
 *
 * Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 */
 package conn
 func errShouldDisableUDPGSO(err error) bool {
 	return false
 }
--- a/wgstack/conn/errors_linux.go
+++ b/wgstack/conn/errors_linux.go
@@ -1,26 +0,0 @@
 /* SPDX-License-Identifier: MIT
 *
 * Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 */
 package conn
 import (
 	"errors"
 	"os"
 	"golang.org/x/sys/unix"
 )
 func errShouldDisableUDPGSO(err error) bool {
 	var serr *os.SyscallError
 	if errors.As(err, &serr) {
 		// EIO is returned by udp_send_skb() if the device driver does not have
 		// tx checksumming enabled, which is a hard requirement of UDP_SEGMENT.
 		// See:
 		// https://git.kernel.org/pub/scm/docs/man-pages/man-pages.git/tree/man7/udp.7?id=806eabd74910447f21005160e90957bde4db0183#n228
 		// https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/tree/net/ipv4/udp.c?h=v6.2&id=c9c3395d5e3dcc6daee66c6908354d47bf98cb0c#n942
 		return serr.Err == unix.EIO
 	}
 	return false
 }
--- a/wgstack/conn/features_default.go
+++ b/wgstack/conn/features_default.go
@@ -1,15 +0,0 @@
 //go:build !linux
 // +build !linux
 /* SPDX-License-Identifier: MIT
 *
 * Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 */
 package conn
 import "net"
 func supportsUDPOffload(conn *net.UDPConn) (txOffload, rxOffload bool) {
 	return
 }
--- a/wgstack/conn/features_linux.go
+++ b/wgstack/conn/features_linux.go
@@ -1,29 +0,0 @@
 /* SPDX-License-Identifier: MIT
 *
 * Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 */
 package conn
 import (
 	"net"
 	"golang.org/x/sys/unix"
 )
 func supportsUDPOffload(conn *net.UDPConn) (txOffload, rxOffload bool) {
 	rc, err := conn.SyscallConn()
 	if err != nil {
 		return
 	}
 	err = rc.Control(func(fd uintptr) {
 		_, errSyscall := unix.GetsockoptInt(int(fd), unix.IPPROTO_UDP, unix.UDP_SEGMENT)
 		txOffload = errSyscall == nil
 		opt, errSyscall := unix.GetsockoptInt(int(fd), unix.IPPROTO_UDP, unix.UDP_GRO)
 		rxOffload = errSyscall == nil && opt == 1
 	})
 	if err != nil {
 		return false, false
 	}
 	return txOffload, rxOffload
 }
--- a/wgstack/conn/gso_default.go
+++ b/wgstack/conn/gso_default.go
@@ -1,21 +0,0 @@
 //go:build !linux
 /* SPDX-License-Identifier: MIT
 *
 * Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 */
 package conn
 // getGSOSize parses control for UDP_GRO and if found returns its GSO size data.
 func getGSOSize(control []byte) (int, error) {
 	return 0, nil
 }
 // setGSOSize sets a UDP_SEGMENT in control based on gsoSize.
 func setGSOSize(control *[]byte, gsoSize uint16) {
 }
 // gsoControlSize returns the recommended buffer size for pooling sticky and UDP
 // offloading control data.
 const gsoControlSize = 0
--- a/wgstack/conn/gso_linux.go
+++ b/wgstack/conn/gso_linux.go
@@ -1,65 +0,0 @@
 //go:build linux
 /* SPDX-License-Identifier: MIT
 *
 * Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 */
 package conn
 import (
 	"fmt"
 	"unsafe"
 	"golang.org/x/sys/unix"
 )
 const (
 	sizeOfGSOData = 2
 )
 // getGSOSize parses control for UDP_GRO and if found returns its GSO size data.
 func getGSOSize(control []byte) (int, error) {
 	var (
 		hdr  unix.Cmsghdr
 		data []byte
 		rem  = control
 		err  error
 	)
 	for len(rem) > unix.SizeofCmsghdr {
 		hdr, data, rem, err = unix.ParseOneSocketControlMessage(rem)
 		if err != nil {
 			return 0, fmt.Errorf("error parsing socket control message: %w", err)
 		}
 		if hdr.Level == unix.SOL_UDP && hdr.Type == unix.UDP_GRO && len(data) >= sizeOfGSOData {
 			var gso uint16
 			copy(unsafe.Slice((*byte)(unsafe.Pointer(&gso)), sizeOfGSOData), data[:sizeOfGSOData])
 			return int(gso), nil
 		}
 	}
 	return 0, nil
 }
 // setGSOSize sets a UDP_SEGMENT in control based on gsoSize. It leaves existing
 // data in control untouched.
 func setGSOSize(control *[]byte, gsoSize uint16) {
 	existingLen := len(*control)
 	avail := cap(*control) - existingLen
 	space := unix.CmsgSpace(sizeOfGSOData)
 	if avail < space {
 		return
 	}
 	*control = (*control)[:cap(*control)]
 	gsoControl := (*control)[existingLen:]
 	hdr := (*unix.Cmsghdr)(unsafe.Pointer(&(gsoControl)[0]))
 	hdr.Level = unix.SOL_UDP
 	hdr.Type = unix.UDP_SEGMENT
 	hdr.SetLen(unix.CmsgLen(sizeOfGSOData))
 	copy((gsoControl)[unix.CmsgLen(0):], unsafe.Slice((*byte)(unsafe.Pointer(&gsoSize)), sizeOfGSOData))
 	*control = (*control)[:existingLen+space]
 }
 // gsoControlSize returns the recommended buffer size for pooling UDP
 // offloading control data.
 var gsoControlSize = unix.CmsgSpace(sizeOfGSOData)
--- a/wgstack/conn/mark_unix.go
+++ b/wgstack/conn/mark_unix.go
@@ -1,64 +0,0 @@
 //go:build linux || openbsd || freebsd
 // SPDX-License-Identifier: MIT
 //
 // Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 package conn
 import (
 	"runtime"
 	"golang.org/x/sys/unix"
 )
 var fwmarkIoctl int
 func init() {
 	switch runtime.GOOS {
 	case "linux", "android":
 		fwmarkIoctl = 36 /* unix.SO_MARK */
 	case "freebsd":
 		fwmarkIoctl = 0x1015 /* unix.SO_USER_COOKIE */
 	case "openbsd":
 		fwmarkIoctl = 0x1021 /* unix.SO_RTABLE */
 	}
 }
 func (s *StdNetBind) SetMark(mark uint32) error {
 	var operr error
 	if fwmarkIoctl == 0 {
 		return nil
 	}
 	if s.ipv4 != nil {
 		fd, err := s.ipv4.SyscallConn()
 		if err != nil {
 			return err
 		}
 		err = fd.Control(func(fd uintptr) {
 			operr = unix.SetsockoptInt(int(fd), unix.SOL_SOCKET, fwmarkIoctl, int(mark))
 		})
 		if err == nil {
 			err = operr
 		}
 		if err != nil {
 			return err
 		}
 	}
 	if s.ipv6 != nil {
 		fd, err := s.ipv6.SyscallConn()
 		if err != nil {
 			return err
 		}
 		err = fd.Control(func(fd uintptr) {
 			operr = unix.SetsockoptInt(int(fd), unix.SOL_SOCKET, fwmarkIoctl, int(mark))
 		})
 		if err == nil {
 			err = operr
 		}
 		if err != nil {
 			return err
 		}
 	}
 	return nil
 }
--- a/wgstack/conn/sticky_default.go
+++ b/wgstack/conn/sticky_default.go
@@ -1,42 +0,0 @@
 //go:build !linux || android
 /* SPDX-License-Identifier: MIT
 *
 * Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 */
 package conn
 import "net/netip"
 func (e *StdNetEndpoint) SrcIP() netip.Addr {
 	return netip.Addr{}
 }
 func (e *StdNetEndpoint) SrcIfidx() int32 {
 	return 0
 }
 func (e *StdNetEndpoint) SrcToString() string {
 	return ""
 }
 // TODO: macOS, FreeBSD and other BSDs likely do support the sticky sockets
 // {get,set}srcControl feature set, but use alternatively named flags and need
 // ports and require testing.
 // getSrcFromControl parses the control for PKTINFO and if found updates ep with
 // the source information found.
 func getSrcFromControl(control []byte, ep *StdNetEndpoint) {
 }
 // setSrcControl parses the control for PKTINFO and if found updates ep with
 // the source information found.
 func setSrcControl(control *[]byte, ep *StdNetEndpoint) {
 }
 // stickyControlSize returns the recommended buffer size for pooling sticky
 // offloading control data.
 const stickyControlSize = 0
 const StdNetSupportsStickySockets = false
--- a/wgstack/conn/sticky_linux.go
+++ b/wgstack/conn/sticky_linux.go
@@ -1,116 +0,0 @@
 //go:build linux && !android
 // SPDX-License-Identifier: MIT
 //
 // Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 package conn
 import (
 	"net/netip"
 	"unsafe"
 	"golang.org/x/sys/unix"
 )
 // getSrcFromControl parses the control for PKTINFO and if found updates ep with
 // the source information found.
 func getSrcFromControl(control []byte, ep *StdNetEndpoint) {
 	ep.ClearSrc()
 	var (
 		hdr  unix.Cmsghdr
 		data []byte
 		rem  []byte = control
 		err  error
 	)
 	for len(rem) > unix.SizeofCmsghdr {
 		hdr, data, rem, err = unix.ParseOneSocketControlMessage(rem)
 		if err != nil {
 			return
 		}
 		if hdr.Level == unix.IPPROTO_IP &&
 			hdr.Type == unix.IP_PKTINFO {
 			info := pktInfoFromBuf[unix.Inet4Pktinfo](data)
 			ep.src.Addr = netip.AddrFrom4(info.Spec_dst)
 			ep.src.ifidx = info.Ifindex
 			return
 		}
 		if hdr.Level == unix.IPPROTO_IPV6 &&
 			hdr.Type == unix.IPV6_PKTINFO {
 			info := pktInfoFromBuf[unix.Inet6Pktinfo](data)
 			ep.src.Addr = netip.AddrFrom16(info.Addr)
 			ep.src.ifidx = int32(info.Ifindex)
 			return
 		}
 	}
 }
 // pktInfoFromBuf returns type T populated from the provided buf via copy(). It
 // panics if buf is of insufficient size.
 func pktInfoFromBuf[T unix.Inet4Pktinfo | unix.Inet6Pktinfo](buf []byte) (t T) {
 	size := int(unsafe.Sizeof(t))
 	if len(buf) < size {
 		panic("pktInfoFromBuf: buffer too small")
 	}
 	copy(unsafe.Slice((*byte)(unsafe.Pointer(&t)), size), buf)
 	return t
 }
 // setSrcControl sets an IP{V6}_PKTINFO in control based on the source address
 // and source ifindex found in ep. control's len will be set to 0 in the event
 // that ep is a default value.
 func setSrcControl(control *[]byte, ep *StdNetEndpoint) {
 	*control = (*control)[:cap(*control)]
 	if len(*control) < int(unsafe.Sizeof(unix.Cmsghdr{})) {
 		*control = (*control)[:0]
 		return
 	}
 	if ep.src.ifidx == 0 && !ep.SrcIP().IsValid() {
 		*control = (*control)[:0]
 		return
 	}
 	if len(*control) < srcControlSize {
 		*control = (*control)[:0]
 		return
 	}
 	hdr := (*unix.Cmsghdr)(unsafe.Pointer(&(*control)[0]))
 	if ep.SrcIP().Is4() {
 		hdr.Level = unix.IPPROTO_IP
 		hdr.Type = unix.IP_PKTINFO
 		hdr.SetLen(unix.CmsgLen(unix.SizeofInet4Pktinfo))
 		info := (*unix.Inet4Pktinfo)(unsafe.Pointer(&(*control)[unix.SizeofCmsghdr]))
 		info.Ifindex = ep.src.ifidx
 		if ep.SrcIP().IsValid() {
 			info.Spec_dst = ep.SrcIP().As4()
 		}
 		*control = (*control)[:unix.CmsgSpace(unix.SizeofInet4Pktinfo)]
 	} else {
 		hdr.Level = unix.IPPROTO_IPV6
 		hdr.Type = unix.IPV6_PKTINFO
 		hdr.SetLen(unix.CmsgLen(unix.SizeofInet6Pktinfo))
 		info := (*unix.Inet6Pktinfo)(unsafe.Pointer(&(*control)[unix.SizeofCmsghdr]))
 		info.Ifindex = uint32(ep.src.ifidx)
 		if ep.SrcIP().IsValid() {
 			info.Addr = ep.SrcIP().As16()
 		}
 		*control = (*control)[:unix.CmsgSpace(unix.SizeofInet6Pktinfo)]
 	}
 }
 var srcControlSize = unix.CmsgSpace(unix.SizeofInet6Pktinfo)
 const StdNetSupportsStickySockets = true
--- a/wgstack/tun/checksum.go
+++ b/wgstack/tun/checksum.go
@@ -1,42 +0,0 @@
 package tun
 import "encoding/binary"
 // TODO: Explore SIMD and/or other assembly optimizations.
 func checksumNoFold(b []byte, initial uint64) uint64 {
 	ac := initial
 	i := 0
 	n := len(b)
 	for n >= 4 {
 		ac += uint64(binary.BigEndian.Uint32(b[i : i+4]))
 		n -= 4
 		i += 4
 	}
 	for n >= 2 {
 		ac += uint64(binary.BigEndian.Uint16(b[i : i+2]))
 		n -= 2
 		i += 2
 	}
 	if n == 1 {
 		ac += uint64(b[i]) << 8
 	}
 	return ac
 }
 func checksum(b []byte, initial uint64) uint16 {
 	ac := checksumNoFold(b, initial)
 	ac = (ac >> 16) + (ac & 0xffff)
 	ac = (ac >> 16) + (ac & 0xffff)
 	ac = (ac >> 16) + (ac & 0xffff)
 	ac = (ac >> 16) + (ac & 0xffff)
 	return uint16(ac)
 }
 func pseudoHeaderChecksumNoFold(protocol uint8, srcAddr, dstAddr []byte, totalLen uint16) uint64 {
 	sum := checksumNoFold(srcAddr, 0)
 	sum = checksumNoFold(dstAddr, sum)
 	sum = checksumNoFold([]byte{0, protocol}, sum)
 	tmp := make([]byte, 2)
 	binary.BigEndian.PutUint16(tmp, totalLen)
 	return checksumNoFold(tmp, sum)
 }
--- a/wgstack/tun/export.go
+++ b/wgstack/tun/export.go
@@ -1,3 +0,0 @@
 package tun
 const VirtioNetHdrLen = virtioNetHdrLen
--- a/wgstack/tun/tcp_offload_linux.go
+++ b/wgstack/tun/tcp_offload_linux.go
@@ -1,630 +0,0 @@
 //go:build linux
 // SPDX-License-Identifier: MIT
 //
 // Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 package tun
 import (
 	"bytes"
 	"encoding/binary"
 	"errors"
 	"io"
 	"unsafe"
 	wgconn "github.com/slackhq/nebula/wgstack/conn"
 	"golang.org/x/sys/unix"
 )
 var ErrTooManySegments = errors.New("tun: too many segments for TSO")
 const tcpFlagsOffset = 13
 const (
 	tcpFlagFIN uint8 = 0x01
 	tcpFlagPSH uint8 = 0x08
 	tcpFlagACK uint8 = 0x10
 )
 // virtioNetHdr is defined in the kernel in include/uapi/linux/virtio_net.h. The
 // kernel symbol is virtio_net_hdr.
 type virtioNetHdr struct {
 	flags      uint8
 	gsoType    uint8
 	hdrLen     uint16
 	gsoSize    uint16
 	csumStart  uint16
 	csumOffset uint16
 }
 func (v *virtioNetHdr) decode(b []byte) error {
 	if len(b) < virtioNetHdrLen {
 		return io.ErrShortBuffer
 	}
 	copy(unsafe.Slice((*byte)(unsafe.Pointer(v)), virtioNetHdrLen), b[:virtioNetHdrLen])
 	return nil
 }
 func (v *virtioNetHdr) encode(b []byte) error {
 	if len(b) < virtioNetHdrLen {
 		return io.ErrShortBuffer
 	}
 	copy(b[:virtioNetHdrLen], unsafe.Slice((*byte)(unsafe.Pointer(v)), virtioNetHdrLen))
 	return nil
 }
 const (
 	// virtioNetHdrLen is the length in bytes of virtioNetHdr. This matches the
 	// shape of the C ABI for its kernel counterpart -- sizeof(virtio_net_hdr).
 	virtioNetHdrLen = int(unsafe.Sizeof(virtioNetHdr{}))
 )
 // flowKey represents the key for a flow.
 type flowKey struct {
 	srcAddr, dstAddr [16]byte
 	srcPort, dstPort uint16
 	rxAck            uint32 // varying ack values should not be coalesced. Treat them as separate flows.
 }
 // tcpGROTable holds flow and coalescing information for the purposes of GRO.
 type tcpGROTable struct {
 	itemsByFlow map[flowKey][]tcpGROItem
 	itemsPool   [][]tcpGROItem
 }
 func newTCPGROTable() *tcpGROTable {
 	t := &tcpGROTable{
 		itemsByFlow: make(map[flowKey][]tcpGROItem, wgconn.IdealBatchSize),
 		itemsPool:   make([][]tcpGROItem, wgconn.IdealBatchSize),
 	}
 	for i := range t.itemsPool {
 		t.itemsPool[i] = make([]tcpGROItem, 0, wgconn.IdealBatchSize)
 	}
 	return t
 }
 func newFlowKey(pkt []byte, srcAddr, dstAddr, tcphOffset int) flowKey {
 	key := flowKey{}
 	addrSize := dstAddr - srcAddr
 	copy(key.srcAddr[:], pkt[srcAddr:dstAddr])
 	copy(key.dstAddr[:], pkt[dstAddr:dstAddr+addrSize])
 	key.srcPort = binary.BigEndian.Uint16(pkt[tcphOffset:])
 	key.dstPort = binary.BigEndian.Uint16(pkt[tcphOffset+2:])
 	key.rxAck = binary.BigEndian.Uint32(pkt[tcphOffset+8:])
 	return key
 }
 // lookupOrInsert looks up a flow for the provided packet and metadata,
 // returning the packets found for the flow, or inserting a new one if none
 // is found.
 func (t *tcpGROTable) lookupOrInsert(pkt []byte, srcAddrOffset, dstAddrOffset, tcphOffset, tcphLen, bufsIndex int) ([]tcpGROItem, bool) {
 	key := newFlowKey(pkt, srcAddrOffset, dstAddrOffset, tcphOffset)
 	items, ok := t.itemsByFlow[key]
 	if ok {
 		return items, ok
 	}
 	// TODO: insert() performs another map lookup. This could be rearranged to avoid.
 	t.insert(pkt, srcAddrOffset, dstAddrOffset, tcphOffset, tcphLen, bufsIndex)
 	return nil, false
 }
 // insert an item in the table for the provided packet and packet metadata.
 func (t *tcpGROTable) insert(pkt []byte, srcAddrOffset, dstAddrOffset, tcphOffset, tcphLen, bufsIndex int) {
 	key := newFlowKey(pkt, srcAddrOffset, dstAddrOffset, tcphOffset)
 	item := tcpGROItem{
 		key:       key,
 		bufsIndex: uint16(bufsIndex),
 		gsoSize:   uint16(len(pkt[tcphOffset+tcphLen:])),
 		iphLen:    uint8(tcphOffset),
 		tcphLen:   uint8(tcphLen),
 		sentSeq:   binary.BigEndian.Uint32(pkt[tcphOffset+4:]),
 		pshSet:    pkt[tcphOffset+tcpFlagsOffset]&tcpFlagPSH != 0,
 	}
 	items, ok := t.itemsByFlow[key]
 	if !ok {
 		items = t.newItems()
 	}
 	items = append(items, item)
 	t.itemsByFlow[key] = items
 }
 func (t *tcpGROTable) updateAt(item tcpGROItem, i int) {
 	items, _ := t.itemsByFlow[item.key]
 	items[i] = item
 }
 func (t *tcpGROTable) deleteAt(key flowKey, i int) {
 	items, _ := t.itemsByFlow[key]
 	items = append(items[:i], items[i+1:]...)
 	t.itemsByFlow[key] = items
 }
 // tcpGROItem represents bookkeeping data for a TCP packet during the lifetime
 // of a GRO evaluation across a vector of packets.
 type tcpGROItem struct {
 	key       flowKey
 	sentSeq   uint32 // the sequence number
 	bufsIndex uint16 // the index into the original bufs slice
 	numMerged uint16 // the number of packets merged into this item
 	gsoSize   uint16 // payload size
 	iphLen    uint8  // ip header len
 	tcphLen   uint8  // tcp header len
 	pshSet    bool   // psh flag is set
 }
 func (t *tcpGROTable) newItems() []tcpGROItem {
 	var items []tcpGROItem
 	items, t.itemsPool = t.itemsPool[len(t.itemsPool)-1], t.itemsPool[:len(t.itemsPool)-1]
 	return items
 }
 func (t *tcpGROTable) reset() {
 	for k, items := range t.itemsByFlow {
 		items = items[:0]
 		t.itemsPool = append(t.itemsPool, items)
 		delete(t.itemsByFlow, k)
 	}
 }
 // canCoalesce represents the outcome of checking if two TCP packets are
 // candidates for coalescing.
 type canCoalesce int
 const (
 	coalescePrepend     canCoalesce = -1
 	coalesceUnavailable canCoalesce = 0
 	coalesceAppend      canCoalesce = 1
 )
 // tcpPacketsCanCoalesce evaluates if pkt can be coalesced with the packet
 // described by item. This function makes considerations that match the kernel's
 // GRO self tests, which can be found in tools/testing/selftests/net/gro.c.
 func tcpPacketsCanCoalesce(pkt []byte, iphLen, tcphLen uint8, seq uint32, pshSet bool, gsoSize uint16, item tcpGROItem, bufs [][]byte, bufsOffset int) canCoalesce {
 	pktTarget := bufs[item.bufsIndex][bufsOffset:]
 	if tcphLen != item.tcphLen {
 		// cannot coalesce with unequal tcp options len
 		return coalesceUnavailable
 	}
 	if tcphLen > 20 {
 		if !bytes.Equal(pkt[iphLen+20:iphLen+tcphLen], pktTarget[item.iphLen+20:iphLen+tcphLen]) {
 			// cannot coalesce with unequal tcp options
 			return coalesceUnavailable
 		}
 	}
 	if pkt[0]>>4 == 6 {
 		if pkt[0] != pktTarget[0] || pkt[1]>>4 != pktTarget[1]>>4 {
 			// cannot coalesce with unequal Traffic class values
 			return coalesceUnavailable
 		}
 		if pkt[7] != pktTarget[7] {
 			// cannot coalesce with unequal Hop limit values
 			return coalesceUnavailable
 		}
 	} else {
 		if pkt[1] != pktTarget[1] {
 			// cannot coalesce with unequal ToS values
 			return coalesceUnavailable
 		}
 		if pkt[6]>>5 != pktTarget[6]>>5 {
 			// cannot coalesce with unequal DF or reserved bits. MF is checked
 			// further up the stack.
 			return coalesceUnavailable
 		}
 		if pkt[8] != pktTarget[8] {
 			// cannot coalesce with unequal TTL values
 			return coalesceUnavailable
 		}
 	}
 	// seq adjacency
 	lhsLen := item.gsoSize
 	lhsLen += item.numMerged * item.gsoSize
 	if seq == item.sentSeq+uint32(lhsLen) { // pkt aligns following item from a seq num perspective
 		if item.pshSet {
 			// We cannot append to a segment that has the PSH flag set, PSH
 			// can only be set on the final segment in a reassembled group.
 			return coalesceUnavailable
 		}
 		if len(pktTarget[iphLen+tcphLen:])%int(item.gsoSize) != 0 {
 			// A smaller than gsoSize packet has been appended previously.
 			// Nothing can come after a smaller packet on the end.
 			return coalesceUnavailable
 		}
 		if gsoSize > item.gsoSize {
 			// We cannot have a larger packet following a smaller one.
 			return coalesceUnavailable
 		}
 		return coalesceAppend
 	} else if seq+uint32(gsoSize) == item.sentSeq { // pkt aligns in front of item from a seq num perspective
 		if pshSet {
 			// We cannot prepend with a segment that has the PSH flag set, PSH
 			// can only be set on the final segment in a reassembled group.
 			return coalesceUnavailable
 		}
 		if gsoSize < item.gsoSize {
 			// We cannot have a larger packet following a smaller one.
 			return coalesceUnavailable
 		}
 		if gsoSize > item.gsoSize && item.numMerged > 0 {
 			// There's at least one previous merge, and we're larger than all
 			// previous. This would put multiple smaller packets on the end.
 			return coalesceUnavailable
 		}
 		return coalescePrepend
 	}
 	return coalesceUnavailable
 }
 func tcpChecksumValid(pkt []byte, iphLen uint8, isV6 bool) bool {
 	srcAddrAt := ipv4SrcAddrOffset
 	addrSize := 4
 	if isV6 {
 		srcAddrAt = ipv6SrcAddrOffset
 		addrSize = 16
 	}
 	tcpTotalLen := uint16(len(pkt) - int(iphLen))
 	tcpCSumNoFold := pseudoHeaderChecksumNoFold(unix.IPPROTO_TCP, pkt[srcAddrAt:srcAddrAt+addrSize], pkt[srcAddrAt+addrSize:srcAddrAt+addrSize*2], tcpTotalLen)
 	return ^checksum(pkt[iphLen:], tcpCSumNoFold) == 0
 }
 // coalesceResult represents the result of attempting to coalesce two TCP
 // packets.
 type coalesceResult int
 const (
 	coalesceInsufficientCap coalesceResult = 0
 	coalescePSHEnding       coalesceResult = 1
 	coalesceItemInvalidCSum coalesceResult = 2
 	coalescePktInvalidCSum  coalesceResult = 3
 	coalesceSuccess         coalesceResult = 4
 )
 // coalesceTCPPackets attempts to coalesce pkt with the packet described by
 // item, returning the outcome. This function may swap bufs elements in the
 // event of a prepend as item's bufs index is already being tracked for writing
 // to a Device.
 func coalesceTCPPackets(mode canCoalesce, pkt []byte, pktBuffsIndex int, gsoSize uint16, seq uint32, pshSet bool, item *tcpGROItem, bufs [][]byte, bufsOffset int, isV6 bool) coalesceResult {
 	var pktHead []byte // the packet that will end up at the front
 	headersLen := item.iphLen + item.tcphLen
 	coalescedLen := len(bufs[item.bufsIndex][bufsOffset:]) + len(pkt) - int(headersLen)
 	// Copy data
 	if mode == coalescePrepend {
 		pktHead = pkt
 		if cap(pkt)-bufsOffset < coalescedLen {
 			// We don't want to allocate a new underlying array if capacity is
 			// too small.
 			return coalesceInsufficientCap
 		}
 		if pshSet {
 			return coalescePSHEnding
 		}
 		if item.numMerged == 0 {
 			if !tcpChecksumValid(bufs[item.bufsIndex][bufsOffset:], item.iphLen, isV6) {
 				return coalesceItemInvalidCSum
 			}
 		}
 		if !tcpChecksumValid(pkt, item.iphLen, isV6) {
 			return coalescePktInvalidCSum
 		}
 		item.sentSeq = seq
 		extendBy := coalescedLen - len(pktHead)
 		bufs[pktBuffsIndex] = append(bufs[pktBuffsIndex], make([]byte, extendBy)...)
 		copy(bufs[pktBuffsIndex][bufsOffset+len(pkt):], bufs[item.bufsIndex][bufsOffset+int(headersLen):])
 		// Flip the slice headers in bufs as part of prepend. The index of item
 		// is already being tracked for writing.
 		bufs[item.bufsIndex], bufs[pktBuffsIndex] = bufs[pktBuffsIndex], bufs[item.bufsIndex]
 	} else {
 		pktHead = bufs[item.bufsIndex][bufsOffset:]
 		if cap(pktHead)-bufsOffset < coalescedLen {
 			// We don't want to allocate a new underlying array if capacity is
 			// too small.
 			return coalesceInsufficientCap
 		}
 		if item.numMerged == 0 {
 			if !tcpChecksumValid(bufs[item.bufsIndex][bufsOffset:], item.iphLen, isV6) {
 				return coalesceItemInvalidCSum
 			}
 		}
 		if !tcpChecksumValid(pkt, item.iphLen, isV6) {
 			return coalescePktInvalidCSum
 		}
 		if pshSet {
 			// We are appending a segment with PSH set.
 			item.pshSet = pshSet
 			pktHead[item.iphLen+tcpFlagsOffset] |= tcpFlagPSH
 		}
 		extendBy := len(pkt) - int(headersLen)
 		bufs[item.bufsIndex] = append(bufs[item.bufsIndex], make([]byte, extendBy)...)
 		copy(bufs[item.bufsIndex][bufsOffset+len(pktHead):], pkt[headersLen:])
 	}
 	if gsoSize > item.gsoSize {
 		item.gsoSize = gsoSize
 	}
 	hdr := virtioNetHdr{
 		flags:      unix.VIRTIO_NET_HDR_F_NEEDS_CSUM, // this turns into CHECKSUM_PARTIAL in the skb
 		hdrLen:     uint16(headersLen),
 		gsoSize:    uint16(item.gsoSize),
 		csumStart:  uint16(item.iphLen),
 		csumOffset: 16,
 	}
 	// Recalculate the total len (IPv4) or payload len (IPv6). Recalculate the
 	// (IPv4) header checksum.
 	if isV6 {
 		hdr.gsoType = unix.VIRTIO_NET_HDR_GSO_TCPV6
 		binary.BigEndian.PutUint16(pktHead[4:], uint16(coalescedLen)-uint16(item.iphLen)) // set new payload len
 	} else {
 		hdr.gsoType = unix.VIRTIO_NET_HDR_GSO_TCPV4
 		pktHead[10], pktHead[11] = 0, 0                               // clear checksum field
 		binary.BigEndian.PutUint16(pktHead[2:], uint16(coalescedLen)) // set new total length
 		iphCSum := ^checksum(pktHead[:item.iphLen], 0)                // compute checksum
 		binary.BigEndian.PutUint16(pktHead[10:], iphCSum)             // set checksum field
 	}
 	hdr.encode(bufs[item.bufsIndex][bufsOffset-virtioNetHdrLen:])
 	// Calculate the pseudo header checksum and place it at the TCP checksum
 	// offset. Downstream checksum offloading will combine this with computation
 	// of the tcp header and payload checksum.
 	addrLen := 4
 	addrOffset := ipv4SrcAddrOffset
 	if isV6 {
 		addrLen = 16
 		addrOffset = ipv6SrcAddrOffset
 	}
 	srcAddrAt := bufsOffset + addrOffset
 	srcAddr := bufs[item.bufsIndex][srcAddrAt : srcAddrAt+addrLen]
 	dstAddr := bufs[item.bufsIndex][srcAddrAt+addrLen : srcAddrAt+addrLen*2]
 	psum := pseudoHeaderChecksumNoFold(unix.IPPROTO_TCP, srcAddr, dstAddr, uint16(coalescedLen-int(item.iphLen)))
 	binary.BigEndian.PutUint16(pktHead[hdr.csumStart+hdr.csumOffset:], checksum([]byte{}, psum))
 	item.numMerged++
 	return coalesceSuccess
 }
 const (
 	ipv4FlagMoreFragments uint8 = 0x20
 )
 const (
 	ipv4SrcAddrOffset = 12
 	ipv6SrcAddrOffset = 8
 	maxUint16         = 1<<16 - 1
 )
 // tcpGRO evaluates the TCP packet at pktI in bufs for coalescing with
 // existing packets tracked in table. It will return false when pktI is not
 // coalesced, otherwise true. This indicates to the caller if bufs[pktI]
 // should be written to the Device.
 func tcpGRO(bufs [][]byte, offset int, pktI int, table *tcpGROTable, isV6 bool) (pktCoalesced bool) {
 	pkt := bufs[pktI][offset:]
 	if len(pkt) > maxUint16 {
 		// A valid IPv4 or IPv6 packet will never exceed this.
 		return false
 	}
 	iphLen := int((pkt[0] & 0x0F) * 4)
 	if isV6 {
 		iphLen = 40
 		ipv6HPayloadLen := int(binary.BigEndian.Uint16(pkt[4:]))
 		if ipv6HPayloadLen != len(pkt)-iphLen {
 			return false
 		}
 	} else {
 		totalLen := int(binary.BigEndian.Uint16(pkt[2:]))
 		if totalLen != len(pkt) {
 			return false
 		}
 	}
 	if len(pkt) < iphLen {
 		return false
 	}
 	tcphLen := int((pkt[iphLen+12] >> 4) * 4)
 	if tcphLen < 20 || tcphLen > 60 {
 		return false
 	}
 	if len(pkt) < iphLen+tcphLen {
 		return false
 	}
 	if !isV6 {
 		if pkt[6]&ipv4FlagMoreFragments != 0 || pkt[6]<<3 != 0 || pkt[7] != 0 {
 			// no GRO support for fragmented segments for now
 			return false
 		}
 	}
 	tcpFlags := pkt[iphLen+tcpFlagsOffset]
 	var pshSet bool
 	// not a candidate if any non-ACK flags (except PSH+ACK) are set
 	if tcpFlags != tcpFlagACK {
 		if pkt[iphLen+tcpFlagsOffset] != tcpFlagACK|tcpFlagPSH {
 			return false
 		}
 		pshSet = true
 	}
 	gsoSize := uint16(len(pkt) - tcphLen - iphLen)
 	// not a candidate if payload len is 0
 	if gsoSize < 1 {
 		return false
 	}
 	seq := binary.BigEndian.Uint32(pkt[iphLen+4:])
 	srcAddrOffset := ipv4SrcAddrOffset
 	addrLen := 4
 	if isV6 {
 		srcAddrOffset = ipv6SrcAddrOffset
 		addrLen = 16
 	}
 	items, existing := table.lookupOrInsert(pkt, srcAddrOffset, srcAddrOffset+addrLen, iphLen, tcphLen, pktI)
 	if !existing {
 		return false
 	}
 	for i := len(items) - 1; i >= 0; i-- {
 		// In the best case of packets arriving in order iterating in reverse is
 		// more efficient if there are multiple items for a given flow. This
 		// also enables a natural table.deleteAt() in the
 		// coalesceItemInvalidCSum case without the need for index tracking.
 		// This algorithm makes a best effort to coalesce in the event of
 		// unordered packets, where pkt may land anywhere in items from a
 		// sequence number perspective, however once an item is inserted into
 		// the table it is never compared across other items later.
 		item := items[i]
 		can := tcpPacketsCanCoalesce(pkt, uint8(iphLen), uint8(tcphLen), seq, pshSet, gsoSize, item, bufs, offset)
 		if can != coalesceUnavailable {
 			result := coalesceTCPPackets(can, pkt, pktI, gsoSize, seq, pshSet, &item, bufs, offset, isV6)
 			switch result {
 			case coalesceSuccess:
 				table.updateAt(item, i)
 				return true
 			case coalesceItemInvalidCSum:
 				// delete the item with an invalid csum
 				table.deleteAt(item.key, i)
 			case coalescePktInvalidCSum:
 				// no point in inserting an item that we can't coalesce
 				return false
 			default:
 			}
 		}
 	}
 	// failed to coalesce with any other packets; store the item in the flow
 	table.insert(pkt, srcAddrOffset, srcAddrOffset+addrLen, iphLen, tcphLen, pktI)
 	return false
 }
 func isTCP4NoIPOptions(b []byte) bool {
 	if len(b) < 40 {
 		return false
 	}
 	if b[0]>>4 != 4 {
 		return false
 	}
 	if b[0]&0x0F != 5 {
 		return false
 	}
 	if b[9] != unix.IPPROTO_TCP {
 		return false
 	}
 	return true
 }
 func isTCP6NoEH(b []byte) bool {
 	if len(b) < 60 {
 		return false
 	}
 	if b[0]>>4 != 6 {
 		return false
 	}
 	if b[6] != unix.IPPROTO_TCP {
 		return false
 	}
 	return true
 }
 // handleGRO evaluates bufs for GRO, and writes the indices of the resulting
 // packets into toWrite. toWrite, tcp4Table, and tcp6Table should initially be
 // empty (but non-nil), and are passed in to save allocs as the caller may reset
 // and recycle them across vectors of packets.
 func handleGRO(bufs [][]byte, offset int, tcp4Table, tcp6Table *tcpGROTable, toWrite *[]int) error {
 	for i := range bufs {
 		if offset < virtioNetHdrLen || offset > len(bufs[i])-1 {
 			return errors.New("invalid offset")
 		}
 		var coalesced bool
 		switch {
 		case isTCP4NoIPOptions(bufs[i][offset:]): // ipv4 packets w/IP options do not coalesce
 			coalesced = tcpGRO(bufs, offset, i, tcp4Table, false)
 		case isTCP6NoEH(bufs[i][offset:]): // ipv6 packets w/extension headers do not coalesce
 			coalesced = tcpGRO(bufs, offset, i, tcp6Table, true)
 		}
 		if !coalesced {
 			hdr := virtioNetHdr{}
 			err := hdr.encode(bufs[i][offset-virtioNetHdrLen:])
 			if err != nil {
 				return err
 			}
 			*toWrite = append(*toWrite, i)
 		}
 	}
 	return nil
 }
 // tcpTSO splits packets from in into outBuffs, writing the size of each
 // element into sizes. It returns the number of buffers populated, and/or an
 // error.
 func tcpTSO(in []byte, hdr virtioNetHdr, outBuffs [][]byte, sizes []int, outOffset int) (int, error) {
 	iphLen := int(hdr.csumStart)
 	srcAddrOffset := ipv6SrcAddrOffset
 	addrLen := 16
 	if hdr.gsoType == unix.VIRTIO_NET_HDR_GSO_TCPV4 {
 		in[10], in[11] = 0, 0 // clear ipv4 header checksum
 		srcAddrOffset = ipv4SrcAddrOffset
 		addrLen = 4
 	}
 	tcpCSumAt := int(hdr.csumStart + hdr.csumOffset)
 	in[tcpCSumAt], in[tcpCSumAt+1] = 0, 0 // clear tcp checksum
 	firstTCPSeqNum := binary.BigEndian.Uint32(in[hdr.csumStart+4:])
 	nextSegmentDataAt := int(hdr.hdrLen)
 	i := 0
 	for ; nextSegmentDataAt < len(in); i++ {
 		if i == len(outBuffs) {
 			return i - 1, ErrTooManySegments
 		}
 		nextSegmentEnd := nextSegmentDataAt + int(hdr.gsoSize)
 		if nextSegmentEnd > len(in) {
 			nextSegmentEnd = len(in)
 		}
 		segmentDataLen := nextSegmentEnd - nextSegmentDataAt
 		totalLen := int(hdr.hdrLen) + segmentDataLen
 		sizes[i] = totalLen
 		out := outBuffs[i][outOffset:]
 		copy(out, in[:iphLen])
 		if hdr.gsoType == unix.VIRTIO_NET_HDR_GSO_TCPV4 {
 			// For IPv4 we are responsible for incrementing the ID field,
 			// updating the total len field, and recalculating the header
 			// checksum.
 			if i > 0 {
 				id := binary.BigEndian.Uint16(out[4:])
 				id += uint16(i)
 				binary.BigEndian.PutUint16(out[4:], id)
 			}
 			binary.BigEndian.PutUint16(out[2:], uint16(totalLen))
 			ipv4CSum := ^checksum(out[:iphLen], 0)
 			binary.BigEndian.PutUint16(out[10:], ipv4CSum)
 		} else {
 			// For IPv6 we are responsible for updating the payload length field.
 			binary.BigEndian.PutUint16(out[4:], uint16(totalLen-iphLen))
 		}
 		// TCP header
 		copy(out[hdr.csumStart:hdr.hdrLen], in[hdr.csumStart:hdr.hdrLen])
 		tcpSeq := firstTCPSeqNum + uint32(hdr.gsoSize*uint16(i))
 		binary.BigEndian.PutUint32(out[hdr.csumStart+4:], tcpSeq)
 		if nextSegmentEnd != len(in) {
 			// FIN and PSH should only be set on last segment
 			clearFlags := tcpFlagFIN | tcpFlagPSH
 			out[hdr.csumStart+tcpFlagsOffset] &^= clearFlags
 		}
 		// payload
 		copy(out[hdr.hdrLen:], in[nextSegmentDataAt:nextSegmentEnd])
 		// TCP checksum
 		tcpHLen := int(hdr.hdrLen - hdr.csumStart)
 		tcpLenForPseudo := uint16(tcpHLen + segmentDataLen)
 		tcpCSumNoFold := pseudoHeaderChecksumNoFold(unix.IPPROTO_TCP, in[srcAddrOffset:srcAddrOffset+addrLen], in[srcAddrOffset+addrLen:srcAddrOffset+addrLen*2], tcpLenForPseudo)
 		tcpCSum := ^checksum(out[hdr.csumStart:totalLen], tcpCSumNoFold)
 		binary.BigEndian.PutUint16(out[hdr.csumStart+hdr.csumOffset:], tcpCSum)
 		nextSegmentDataAt += int(hdr.gsoSize)
 	}
 	return i, nil
 }
 func gsoNoneChecksum(in []byte, cSumStart, cSumOffset uint16) error {
 	cSumAt := cSumStart + cSumOffset
 	// The initial value at the checksum offset should be summed with the
 	// checksum we compute. This is typically the pseudo-header checksum.
 	initial := binary.BigEndian.Uint16(in[cSumAt:])
 	in[cSumAt], in[cSumAt+1] = 0, 0
 	binary.BigEndian.PutUint16(in[cSumAt:], ^checksum(in[cSumStart:], uint64(initial)))
 	return nil
 }
--- a/wgstack/tun/tun.go
+++ b/wgstack/tun/tun.go
@@ -1,52 +0,0 @@
 // SPDX-License-Identifier: MIT
 //
 // Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 package tun
 import (
 	"os"
 )
 type Event int
 const (
 	EventUp = 1 << iota
 	EventDown
 	EventMTUUpdate
 )
 type Device interface {
 	// File returns the file descriptor of the device.
 	File() *os.File
 	// Read one or more packets from the Device (without any additional headers).
 	// On a successful read it returns the number of packets read, and sets
 	// packet lengths within the sizes slice. len(sizes) must be >= len(bufs).
 	// A nonzero offset can be used to instruct the Device on where to begin
 	// reading into each element of the bufs slice.
 	Read(bufs [][]byte, sizes []int, offset int) (n int, err error)
 	// Write one or more packets to the device (without any additional headers).
 	// On a successful write it returns the number of packets written. A nonzero
 	// offset can be used to instruct the Device on where to begin writing from
 	// each packet contained within the bufs slice.
 	Write(bufs [][]byte, offset int) (int, error)
 	// MTU returns the MTU of the Device.
 	MTU() (int, error)
 	// Name returns the current name of the Device.
 	Name() (string, error)
 	// Events returns a channel of type Event, which is fed Device events.
 	Events() <-chan Event
 	// Close stops the Device and closes the Event channel.
 	Close() error
 	// BatchSize returns the preferred/max number of packets that can be read or
 	// written in a single read/write call. BatchSize must not change over the
 	// lifetime of a Device.
 	BatchSize() int
 }
--- a/wgstack/tun/tun_linux.go
+++ b/wgstack/tun/tun_linux.go
@@ -1,664 +0,0 @@
 //go:build linux
 // SPDX-License-Identifier: MIT
 //
 // Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
 package tun
 /* Implementation of the TUN device interface for linux
 */
 import (
 	"errors"
 	"fmt"
 	"os"
 	"sync"
 	"syscall"
 	"time"
 	"unsafe"
 	wgconn "github.com/slackhq/nebula/wgstack/conn"
 	"golang.org/x/sys/unix"
 	"golang.zx2c4.com/wireguard/rwcancel"
 )
 const (
 	cloneDevicePath = "/dev/net/tun"
 	ifReqSize       = unix.IFNAMSIZ + 64
 )
 type NativeTun struct {
 	tunFile                 *os.File
 	index                   int32      // if index
 	errors                  chan error // async error handling
 	events                  chan Event // device related events
 	netlinkSock             int
 	netlinkCancel           *rwcancel.RWCancel
 	hackListenerClosed      sync.Mutex
 	statusListenersShutdown chan struct{}
 	batchSize               int
 	vnetHdr                 bool
 	closeOnce sync.Once
 	nameOnce  sync.Once // guards calling initNameCache, which sets following fields
 	nameCache string    // name of interface
 	nameErr   error
 	readOpMu sync.Mutex                    // readOpMu guards readBuff
 	readBuff [virtioNetHdrLen + 65535]byte // if vnetHdr every read() is prefixed by virtioNetHdr
 	writeOpMu                  sync.Mutex // writeOpMu guards toWrite, tcp4GROTable, tcp6GROTable
 	toWrite                    []int
 	tcp4GROTable, tcp6GROTable *tcpGROTable
 }
 func (tun *NativeTun) File() *os.File {
 	return tun.tunFile
 }
 func (tun *NativeTun) routineHackListener() {
 	defer tun.hackListenerClosed.Unlock()
 	/* This is needed for the detection to work across network namespaces
 	 * If you are reading this and know a better method, please get in touch.
 	 */
 	last := 0
 	const (
 		up   = 1
 		down = 2
 	)
 	for {
 		sysconn, err := tun.tunFile.SyscallConn()
 		if err != nil {
 			return
 		}
 		err2 := sysconn.Control(func(fd uintptr) {
 			_, err = unix.Write(int(fd), nil)
 		})
 		if err2 != nil {
 			return
 		}
 		switch err {
 		case unix.EINVAL:
 			if last != up {
 				// If the tunnel is up, it reports that write() is
 				// allowed but we provided invalid data.
 				tun.events <- EventUp
 				last = up
 			}
 		case unix.EIO:
 			if last != down {
 				// If the tunnel is down, it reports that no I/O
 				// is possible, without checking our provided data.
 				tun.events <- EventDown
 				last = down
 			}
 		default:
 			return
 		}
 		select {
 		case <-time.After(time.Second):
 			// nothing
 		case <-tun.statusListenersShutdown:
 			return
 		}
 	}
 }
 func createNetlinkSocket() (int, error) {
 	sock, err := unix.Socket(unix.AF_NETLINK, unix.SOCK_RAW|unix.SOCK_CLOEXEC, unix.NETLINK_ROUTE)
 	if err != nil {
 		return -1, err
 	}
 	saddr := &unix.SockaddrNetlink{
 		Family: unix.AF_NETLINK,
 		Groups: unix.RTMGRP_LINK | unix.RTMGRP_IPV4_IFADDR | unix.RTMGRP_IPV6_IFADDR,
 	}
 	err = unix.Bind(sock, saddr)
 	if err != nil {
 		return -1, err
 	}
 	return sock, nil
 }
 func (tun *NativeTun) routineNetlinkListener() {
 	defer func() {
 		unix.Close(tun.netlinkSock)
 		tun.hackListenerClosed.Lock()
 		close(tun.events)
 		tun.netlinkCancel.Close()
 	}()
 	for msg := make([]byte, 1<<16); ; {
 		var err error
 		var msgn int
 		for {
 			msgn, _, _, _, err = unix.Recvmsg(tun.netlinkSock, msg[:], nil, 0)
 			if err == nil || !rwcancel.RetryAfterError(err) {
 				break
 			}
 			if !tun.netlinkCancel.ReadyRead() {
 				tun.errors <- fmt.Errorf("netlink socket closed: %w", err)
 				return
 			}
 		}
 		if err != nil {
 			tun.errors <- fmt.Errorf("failed to receive netlink message: %w", err)
 			return
 		}
 		select {
 		case <-tun.statusListenersShutdown:
 			return
 		default:
 		}
 		wasEverUp := false
 		for remain := msg[:msgn]; len(remain) >= unix.SizeofNlMsghdr; {
 			hdr := *(*unix.NlMsghdr)(unsafe.Pointer(&remain[0]))
 			if int(hdr.Len) > len(remain) {
 				break
 			}
 			switch hdr.Type {
 			case unix.NLMSG_DONE:
 				remain = []byte{}
 			case unix.RTM_NEWLINK:
 				info := *(*unix.IfInfomsg)(unsafe.Pointer(&remain[unix.SizeofNlMsghdr]))
 				remain = remain[hdr.Len:]
 				if info.Index != tun.index {
 					// not our interface
 					continue
 				}
 				if info.Flags&unix.IFF_RUNNING != 0 {
 					tun.events <- EventUp
 					wasEverUp = true
 				}
 				if info.Flags&unix.IFF_RUNNING == 0 {
 					// Don't emit EventDown before we've ever emitted EventUp.
 					// This avoids a startup race with HackListener, which
 					// might detect Up before we have finished reporting Down.
 					if wasEverUp {
 						tun.events <- EventDown
 					}
 				}
 				tun.events <- EventMTUUpdate
 			default:
 				remain = remain[hdr.Len:]
 			}
 		}
 	}
 }
 func getIFIndex(name string) (int32, error) {
 	fd, err := unix.Socket(
 		unix.AF_INET,
 		unix.SOCK_DGRAM|unix.SOCK_CLOEXEC,
 		0,
 	)
 	if err != nil {
 		return 0, err
 	}
 	defer unix.Close(fd)
 	var ifr [ifReqSize]byte
 	copy(ifr[:], name)
 	_, _, errno := unix.Syscall(
 		unix.SYS_IOCTL,
 		uintptr(fd),
 		uintptr(unix.SIOCGIFINDEX),
 		uintptr(unsafe.Pointer(&ifr[0])),
 	)
 	if errno != 0 {
 		return 0, errno
 	}
 	return *(*int32)(unsafe.Pointer(&ifr[unix.IFNAMSIZ])), nil
 }
 func (tun *NativeTun) setMTU(n int) error {
 	name, err := tun.Name()
 	if err != nil {
 		return err
 	}
 	// open datagram socket
 	fd, err := unix.Socket(
 		unix.AF_INET,
 		unix.SOCK_DGRAM|unix.SOCK_CLOEXEC,
 		0,
 	)
 	if err != nil {
 		return err
 	}
 	defer unix.Close(fd)
 	var ifr [ifReqSize]byte
 	copy(ifr[:], name)
 	*(*uint32)(unsafe.Pointer(&ifr[unix.IFNAMSIZ])) = uint32(n)
 	_, _, errno := unix.Syscall(
 		unix.SYS_IOCTL,
 		uintptr(fd),
 		uintptr(unix.SIOCSIFMTU),
 		uintptr(unsafe.Pointer(&ifr[0])),
 	)
 	if errno != 0 {
 		return errno
 	}
 	return nil
 }
 func (tun *NativeTun) routineNetlinkRead() {
 	defer func() {
 		unix.Close(tun.netlinkSock)
 		tun.hackListenerClosed.Lock()
 		close(tun.events)
 		tun.netlinkCancel.Close()
 	}()
 	for msg := make([]byte, 1<<16); ; {
 		var err error
 		var msgn int
 		for {
 			msgn, _, _, _, err = unix.Recvmsg(tun.netlinkSock, msg[:], nil, 0)
 			if err == nil || !rwcancel.RetryAfterError(err) {
 				break
 			}
 			if !tun.netlinkCancel.ReadyRead() {
 				tun.errors <- fmt.Errorf("netlink socket closed: %w", err)
 				return
 			}
 		}
 		if err != nil {
 			tun.errors <- fmt.Errorf("failed to receive netlink message: %w", err)
 			return
 		}
 		wasEverUp := false
 		for remain := msg[:msgn]; len(remain) >= unix.SizeofNlMsghdr; {
 			hdr := *(*unix.NlMsghdr)(unsafe.Pointer(&remain[0]))
 			if int(hdr.Len) > len(remain) {
 				break
 			}
 			switch hdr.Type {
 			case unix.NLMSG_DONE:
 				remain = []byte{}
 			case unix.RTM_NEWLINK:
 				info := *(*unix.IfInfomsg)(unsafe.Pointer(&remain[unix.SizeofNlMsghdr]))
 				remain = remain[hdr.Len:]
 				if info.Index != tun.index {
 					continue
 				}
 				if info.Flags&unix.IFF_RUNNING != 0 {
 					tun.events <- EventUp
 					wasEverUp = true
 				}
 				if info.Flags&unix.IFF_RUNNING == 0 {
 					if wasEverUp {
 						tun.events <- EventDown
 					}
 				}
 				tun.events <- EventMTUUpdate
 			default:
 				remain = remain[hdr.Len:]
 			}
 		}
 	}
 }
 func (tun *NativeTun) routineNetlink() {
 	var err error
 	tun.netlinkSock, err = createNetlinkSocket()
 	if err != nil {
 		tun.errors <- fmt.Errorf("failed to create netlink socket: %w", err)
 		return
 	}
 	tun.netlinkCancel, err = rwcancel.NewRWCancel(tun.netlinkSock)
 	if err != nil {
 		tun.errors <- fmt.Errorf("failed to create netlink cancel: %w", err)
 		return
 	}
 	go tun.routineNetlinkListener()
 }
 func (tun *NativeTun) Close() error {
 	var err1, err2 error
 	tun.closeOnce.Do(func() {
 		if tun.statusListenersShutdown != nil {
 			close(tun.statusListenersShutdown)
 			if tun.netlinkCancel != nil {
 				err1 = tun.netlinkCancel.Cancel()
 			}
 		} else if tun.events != nil {
 			close(tun.events)
 		}
 		err2 = tun.tunFile.Close()
 	})
 	if err1 != nil {
 		return err1
 	}
 	return err2
 }
 func (tun *NativeTun) BatchSize() int {
 	return tun.batchSize
 }
 const (
 	// TODO: support TSO with ECN bits
 	tunOffloads = unix.TUN_F_CSUM | unix.TUN_F_TSO4 | unix.TUN_F_TSO6
 )
 func (tun *NativeTun) initFromFlags(name string) error {
 	sc, err := tun.tunFile.SyscallConn()
 	if err != nil {
 		return err
 	}
 	if e := sc.Control(func(fd uintptr) {
 		var (
 			ifr *unix.Ifreq
 		)
 		ifr, err = unix.NewIfreq(name)
 		if err != nil {
 			return
 		}
 		err = unix.IoctlIfreq(int(fd), unix.TUNGETIFF, ifr)
 		if err != nil {
 			return
 		}
 		got := ifr.Uint16()
 		if got&unix.IFF_VNET_HDR != 0 {
 			err = unix.IoctlSetInt(int(fd), unix.TUNSETOFFLOAD, tunOffloads)
 			if err != nil {
 				return
 			}
 			tun.vnetHdr = true
 			tun.batchSize = wgconn.IdealBatchSize
 		} else {
 			tun.batchSize = 1
 		}
 	}); e != nil {
 		return e
 	}
 	return err
 }
 // CreateTUN creates a Device with the provided name and MTU.
 func CreateTUN(name string, mtu int) (Device, error) {
 	nfd, err := unix.Open(cloneDevicePath, unix.O_RDWR|unix.O_CLOEXEC, 0)
 	if err != nil {
 		return nil, fmt.Errorf("CreateTUN(%q) failed; %s does not exist", name, cloneDevicePath)
 	}
 	fd := os.NewFile(uintptr(nfd), cloneDevicePath)
 	tun, err := CreateTUNFromFile(fd, mtu)
 	if err != nil {
 		return nil, err
 	}
 	if name != "tun" {
 		if err := tun.(*NativeTun).initFromFlags(name); err != nil {
 			tun.Close()
 			return nil, fmt.Errorf("CreateTUN(%q) failed to set flags: %w", name, err)
 		}
 	}
 	return tun, nil
 }
 // CreateTUNFromFile creates a Device from an os.File with the provided MTU.
 func CreateTUNFromFile(file *os.File, mtu int) (Device, error) {
 	tun := &NativeTun{
 		tunFile: file,
 		errors:  make(chan error, 5),
 		events:  make(chan Event, 5),
 	}
 	name, err := tun.Name()
 	if err != nil {
 		return nil, fmt.Errorf("failed to determine TUN name: %w", err)
 	}
 	if err := tun.initFromFlags(name); err != nil {
 		return nil, fmt.Errorf("failed to query TUN flags: %w", err)
 	}
 	if tun.batchSize == 0 {
 		tun.batchSize = 1
 	}
 	tun.index, err = getIFIndex(name)
 	if err != nil {
 		return nil, fmt.Errorf("failed to get TUN index: %w", err)
 	}
 	if err = tun.setMTU(mtu); err != nil {
 		return nil, fmt.Errorf("failed to set MTU: %w", err)
 	}
 	tun.statusListenersShutdown = make(chan struct{})
 	go tun.routineNetlink()
 	if tun.batchSize == 0 {
 		tun.batchSize = 1
 	}
 	tun.tcp4GROTable = newTCPGROTable()
 	tun.tcp6GROTable = newTCPGROTable()
 	return tun, nil
 }
 func (tun *NativeTun) Name() (string, error) {
 	tun.nameOnce.Do(tun.initNameCache)
 	return tun.nameCache, tun.nameErr
 }
 func (tun *NativeTun) initNameCache() {
 	sysconn, err := tun.tunFile.SyscallConn()
 	if err != nil {
 		tun.nameErr = err
 		return
 	}
 	err = sysconn.Control(func(fd uintptr) {
 		var ifr [ifReqSize]byte
 		_, _, errno := unix.Syscall(
 			unix.SYS_IOCTL,
 			fd,
 			uintptr(unix.TUNGETIFF),
 			uintptr(unsafe.Pointer(&ifr[0])),
 		)
 		if errno != 0 {
 			tun.nameErr = errno
 			return
 		}
 		tun.nameCache = unix.ByteSliceToString(ifr[:])
 	})
 	if err != nil && tun.nameErr == nil {
 		tun.nameErr = err
 	}
 }
 func (tun *NativeTun) MTU() (int, error) {
 	name, err := tun.Name()
 	if err != nil {
 		return 0, err
 	}
 	// open datagram socket
 	fd, err := unix.Socket(
 		unix.AF_INET,
 		unix.SOCK_DGRAM|unix.SOCK_CLOEXEC,
 		0,
 	)
 	if err != nil {
 		return 0, err
 	}
 	defer unix.Close(fd)
 	var ifr [ifReqSize]byte
 	copy(ifr[:], name)
 	_, _, errno := unix.Syscall(
 		unix.SYS_IOCTL,
 		uintptr(fd),
 		uintptr(unix.SIOCGIFMTU),
 		uintptr(unsafe.Pointer(&ifr[0])),
 	)
 	if errno != 0 {
 		return 0, errno
 	}
 	return int(*(*uint32)(unsafe.Pointer(&ifr[unix.IFNAMSIZ]))), nil
 }
 func (tun *NativeTun) Events() <-chan Event {
 	return tun.events
 }
 func (tun *NativeTun) Write(bufs [][]byte, offset int) (int, error) {
 	tun.writeOpMu.Lock()
 	defer func() {
 		tun.tcp4GROTable.reset()
 		tun.tcp6GROTable.reset()
 		tun.writeOpMu.Unlock()
 	}()
 	var (
 		errs  error
 		total int
 	)
 	tun.toWrite = tun.toWrite[:0]
 	if tun.vnetHdr {
 		err := handleGRO(bufs, offset, tun.tcp4GROTable, tun.tcp6GROTable, &tun.toWrite)
 		if err != nil {
 			return 0, err
 		}
 		offset -= virtioNetHdrLen
 	} else {
 		for i := range bufs {
 			tun.toWrite = append(tun.toWrite, i)
 		}
 	}
 	for _, bufsI := range tun.toWrite {
 		n, err := tun.tunFile.Write(bufs[bufsI][offset:])
 		if errors.Is(err, syscall.EBADFD) {
 			return total, os.ErrClosed
 		}
 		if err != nil {
 			errs = errors.Join(errs, err)
 		} else {
 			total += n
 		}
 	}
 	return total, errs
 }
 // handleVirtioRead splits in into bufs, leaving offset bytes at the front of
 // each buffer. It mutates sizes to reflect the size of each element of bufs,
 // and returns the number of packets read.
 func handleVirtioRead(in []byte, bufs [][]byte, sizes []int, offset int) (int, error) {
 	var hdr virtioNetHdr
 	if err := hdr.decode(in); err != nil {
 		return 0, err
 	}
 	in = in[virtioNetHdrLen:]
 	if hdr.gsoType == unix.VIRTIO_NET_HDR_GSO_NONE {
 		if hdr.flags&unix.VIRTIO_NET_HDR_F_NEEDS_CSUM != 0 {
 			if err := gsoNoneChecksum(in, hdr.csumStart, hdr.csumOffset); err != nil {
 				return 0, err
 			}
 		}
 		if len(in) > len(bufs[0][offset:]) {
 			return 0, fmt.Errorf("read len %d overflows bufs element len %d", len(in), len(bufs[0][offset:]))
 		}
 		n := copy(bufs[0][offset:], in)
 		sizes[0] = n
 		return 1, nil
 	}
 	if hdr.gsoType != unix.VIRTIO_NET_HDR_GSO_TCPV4 && hdr.gsoType != unix.VIRTIO_NET_HDR_GSO_TCPV6 {
 		return 0, fmt.Errorf("unsupported virtio GSO type: %d", hdr.gsoType)
 	}
 	ipVersion := in[0] >> 4
 	switch ipVersion {
 	case 4:
 		if hdr.gsoType != unix.VIRTIO_NET_HDR_GSO_TCPV4 {
 			return 0, fmt.Errorf("ip header version: %d, GSO type: %d", ipVersion, hdr.gsoType)
 		}
 	case 6:
 		if hdr.gsoType != unix.VIRTIO_NET_HDR_GSO_TCPV6 {
 			return 0, fmt.Errorf("ip header version: %d, GSO type: %d", ipVersion, hdr.gsoType)
 		}
 	default:
 		return 0, fmt.Errorf("invalid ip header version: %d", ipVersion)
 	}
 	if len(in) <= int(hdr.csumStart+12) {
 		return 0, errors.New("packet is too short")
 	}
 	tcpHLen := uint16(in[hdr.csumStart+12] >> 4 * 4)
 	if tcpHLen < 20 || tcpHLen > 60 {
 		return 0, fmt.Errorf("tcp header len is invalid: %d", tcpHLen)
 	}
 	hdr.hdrLen = hdr.csumStart + tcpHLen
 	if len(in) < int(hdr.hdrLen) {
 		return 0, fmt.Errorf("length of packet (%d) < virtioNetHdr.hdrLen (%d)", len(in), hdr.hdrLen)
 	}
 	if hdr.hdrLen < hdr.csumStart {
 		return 0, fmt.Errorf("virtioNetHdr.hdrLen (%d) < virtioNetHdr.csumStart (%d)", hdr.hdrLen, hdr.csumStart)
 	}
 	cSumAt := int(hdr.csumStart + hdr.csumOffset)
 	if cSumAt+1 >= len(in) {
 		return 0, fmt.Errorf("end of checksum offset (%d) exceeds packet length (%d)", cSumAt+1, len(in))
 	}
 	return tcpTSO(in, hdr, bufs, sizes, offset)
 }
 func (tun *NativeTun) Read(bufs [][]byte, sizes []int, offset int) (int, error) {
 	tun.readOpMu.Lock()
 	defer tun.readOpMu.Unlock()
 	select {
 	case err := <-tun.errors:
 		return 0, err
 	default:
 		readInto := bufs[0][offset:]
 		if tun.vnetHdr {
 			readInto = tun.readBuff[:]
 		}
 		n, err := tun.tunFile.Read(readInto)
 		if errors.Is(err, syscall.EBADFD) {
 			err = os.ErrClosed
 		}
 		if err != nil {
 			return 0, err
 		}
 		if tun.vnetHdr {
 			return handleVirtioRead(readInto[:n], bufs, sizes, offset)
 		}
 		sizes[0] = n
 		return 1, nil
 	}
 }
Author	SHA1	Message	Date
Ryan Huber	a4b7f624da	sure	2025-11-03 17:23:57 +00:00
Ryan Huber	1c069a8e42	reuse control on gso	2025-11-03 11:14:52 +00:00
Ryan Huber	0d8bd11818	reuse GRO slices	2025-11-03 11:06:07 +00:00
Ryan Huber	5128e2653e	reuse packet buffer	2025-11-03 10:52:09 +00:00
Ryan Huber	c73b2dfbc7	fixed fallback for non io_uring packet send/recv	2025-11-03 10:45:30 +00:00
Ryan Huber	3dea761530	fix compile for 386	2025-11-03 10:12:02 +00:00
Ryan Huber	b394112ad9	gso and gro with uring on send/receive for udp	2025-11-03 09:59:45 +00:00
		`@@ -1,3 +0,0 @@`
			`package tun`

			`const VirtioNetHdrLen = virtioNetHdrLen`