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tailscale/wgengine/netstack/link_endpoint.go

416 lines
12 KiB
Go

// Copyright (c) Tailscale Inc & AUTHORS
// SPDX-License-Identifier: BSD-3-Clause
package netstack
import (
"bytes"
"context"
"sync"
"github.com/tailscale/wireguard-go/tun"
"gvisor.dev/gvisor/pkg/buffer"
"gvisor.dev/gvisor/pkg/tcpip"
"gvisor.dev/gvisor/pkg/tcpip/header"
"gvisor.dev/gvisor/pkg/tcpip/header/parse"
"gvisor.dev/gvisor/pkg/tcpip/stack"
"gvisor.dev/gvisor/pkg/tcpip/stack/gro"
"tailscale.com/net/packet"
"tailscale.com/types/ipproto"
)
type queue struct {
// TODO(jwhited): evaluate performance with mu as Mutex and/or alternative
// non-channel buffer.
c chan *stack.PacketBuffer
mu sync.RWMutex // mu guards closed
closed bool
}
func (q *queue) Close() {
q.mu.Lock()
defer q.mu.Unlock()
if !q.closed {
close(q.c)
}
q.closed = true
}
func (q *queue) Read() *stack.PacketBuffer {
select {
case p := <-q.c:
return p
default:
return nil
}
}
func (q *queue) ReadContext(ctx context.Context) *stack.PacketBuffer {
select {
case pkt := <-q.c:
return pkt
case <-ctx.Done():
return nil
}
}
func (q *queue) Write(pkt *stack.PacketBuffer) tcpip.Error {
// q holds the PacketBuffer.
q.mu.RLock()
defer q.mu.RUnlock()
if q.closed {
return &tcpip.ErrClosedForSend{}
}
wrote := false
select {
case q.c <- pkt.IncRef():
wrote = true
default:
// TODO(jwhited): reconsider/count
pkt.DecRef()
}
if wrote {
return nil
}
return &tcpip.ErrNoBufferSpace{}
}
func (q *queue) Num() int {
return len(q.c)
}
var _ stack.LinkEndpoint = (*linkEndpoint)(nil)
var _ stack.GSOEndpoint = (*linkEndpoint)(nil)
// linkEndpoint implements stack.LinkEndpoint and stack.GSOEndpoint. Outbound
// packets written by gVisor towards Tailscale are stored in a channel.
// Inbound is fed to gVisor via injectInbound or enqueueGRO. This is loosely
// modeled after gvisor.dev/pkg/tcpip/link/channel.Endpoint.
type linkEndpoint struct {
SupportedGSOKind stack.SupportedGSO
initGRO initGRO
mu sync.RWMutex // mu guards the following fields
dispatcher stack.NetworkDispatcher
linkAddr tcpip.LinkAddress
mtu uint32
gro gro.GRO // mu only guards access to gro.Dispatcher
q *queue // outbound
}
// TODO(jwhited): move to linkEndpointOpts struct or similar.
type initGRO bool
const (
disableGRO initGRO = false
enableGRO initGRO = true
)
func newLinkEndpoint(size int, mtu uint32, linkAddr tcpip.LinkAddress, gro initGRO) *linkEndpoint {
le := &linkEndpoint{
q: &queue{
c: make(chan *stack.PacketBuffer, size),
},
mtu: mtu,
linkAddr: linkAddr,
}
le.initGRO = gro
le.gro.Init(bool(gro))
return le
}
// Close closes l. Further packet injections will return an error, and all
// pending packets are discarded. Close may be called concurrently with
// WritePackets.
func (l *linkEndpoint) Close() {
l.mu.Lock()
if l.gro.Dispatcher != nil {
l.gro.Flush()
}
l.dispatcher = nil
l.gro.Dispatcher = nil
l.mu.Unlock()
l.q.Close()
l.Drain()
}
// Read does non-blocking read one packet from the outbound packet queue.
func (l *linkEndpoint) Read() *stack.PacketBuffer {
return l.q.Read()
}
// ReadContext does blocking read for one packet from the outbound packet queue.
// It can be cancelled by ctx, and in this case, it returns nil.
func (l *linkEndpoint) ReadContext(ctx context.Context) *stack.PacketBuffer {
return l.q.ReadContext(ctx)
}
// Drain removes all outbound packets from the channel and counts them.
func (l *linkEndpoint) Drain() int {
c := 0
for pkt := l.Read(); pkt != nil; pkt = l.Read() {
pkt.DecRef()
c++
}
return c
}
// NumQueued returns the number of packets queued for outbound.
func (l *linkEndpoint) NumQueued() int {
return l.q.Num()
}
// rxChecksumOffload validates IPv4, TCP, and UDP header checksums in p,
// returning an equivalent *stack.PacketBuffer if they are valid, otherwise nil.
// The set of headers validated covers where gVisor would perform validation if
// !stack.PacketBuffer.RXChecksumValidated, i.e. it satisfies
// stack.CapabilityRXChecksumOffload. Other protocols with checksum fields,
// e.g. ICMP{v6}, are still validated by gVisor regardless of rx checksum
// offloading capabilities.
func rxChecksumOffload(p *packet.Parsed) *stack.PacketBuffer {
var (
pn tcpip.NetworkProtocolNumber
csumStart int
)
buf := p.Buffer()
switch p.IPVersion {
case 4:
if len(buf) < header.IPv4MinimumSize {
return nil
}
csumStart = int((buf[0] & 0x0F) * 4)
if csumStart < header.IPv4MinimumSize || csumStart > header.IPv4MaximumHeaderSize || len(buf) < csumStart {
return nil
}
if ^tun.Checksum(buf[:csumStart], 0) != 0 {
return nil
}
pn = header.IPv4ProtocolNumber
case 6:
if len(buf) < header.IPv6FixedHeaderSize {
return nil
}
csumStart = header.IPv6FixedHeaderSize
pn = header.IPv6ProtocolNumber
if p.IPProto != ipproto.ICMPv6 && p.IPProto != ipproto.TCP && p.IPProto != ipproto.UDP {
// buf could have extension headers before a UDP or TCP header, but
// packet.Parsed.IPProto will be set to the ext header type, so we
// have to look deeper. We are still responsible for validating the
// L4 checksum in this case. So, make use of gVisor's existing
// extension header parsing via parse.IPv6() in order to unpack the
// L4 csumStart index. This is not particularly efficient as we have
// to allocate a short-lived stack.PacketBuffer that cannot be
// re-used. parse.IPv6() "consumes" the IPv6 headers, so we can't
// inject this stack.PacketBuffer into the stack at a later point.
packetBuf := stack.NewPacketBuffer(stack.PacketBufferOptions{
Payload: buffer.MakeWithData(bytes.Clone(buf)),
})
defer packetBuf.DecRef()
// The rightmost bool returns false only if packetBuf is too short,
// which we've already accounted for above.
transportProto, _, _, _, _ := parse.IPv6(packetBuf)
if transportProto == header.TCPProtocolNumber || transportProto == header.UDPProtocolNumber {
csumLen := packetBuf.Data().Size()
if len(buf) < csumLen {
return nil
}
csumStart = len(buf) - csumLen
p.IPProto = ipproto.Proto(transportProto)
}
}
}
if p.IPProto == ipproto.TCP || p.IPProto == ipproto.UDP {
lenForPseudo := len(buf) - csumStart
csum := tun.PseudoHeaderChecksum(
uint8(p.IPProto),
p.Src.Addr().AsSlice(),
p.Dst.Addr().AsSlice(),
uint16(lenForPseudo))
csum = tun.Checksum(buf[csumStart:], csum)
if ^csum != 0 {
return nil
}
}
packetBuf := stack.NewPacketBuffer(stack.PacketBufferOptions{
Payload: buffer.MakeWithData(bytes.Clone(buf)),
})
packetBuf.NetworkProtocolNumber = pn
// Setting this is not technically required. gVisor overrides where
// stack.CapabilityRXChecksumOffload is advertised from Capabilities().
// https://github.com/google/gvisor/blob/64c016c92987cc04dfd4c7b091ddd21bdad875f8/pkg/tcpip/stack/nic.go#L763
// This is also why we offload for all packets since we cannot signal this
// per-packet.
packetBuf.RXChecksumValidated = true
return packetBuf
}
func (l *linkEndpoint) injectInbound(p *packet.Parsed) {
l.mu.RLock()
d := l.dispatcher
l.mu.RUnlock()
if d == nil {
return
}
pkt := rxChecksumOffload(p)
if pkt == nil {
return
}
d.DeliverNetworkPacket(pkt.NetworkProtocolNumber, pkt)
pkt.DecRef()
}
// enqueueGRO enqueues the provided packet for GRO. It may immediately deliver
// it to the underlying stack.NetworkDispatcher depending on its contents and if
// GRO was initialized via newLinkEndpoint. To explicitly flush previously
// enqueued packets see flushGRO. enqueueGRO is not thread-safe and must not
// be called concurrently with flushGRO.
func (l *linkEndpoint) enqueueGRO(p *packet.Parsed) {
l.mu.RLock()
defer l.mu.RUnlock()
if l.gro.Dispatcher == nil {
return
}
pkt := rxChecksumOffload(p)
if pkt == nil {
return
}
// TODO(jwhited): gro.Enqueue() duplicates a lot of p.Decode().
// We may want to push stack.PacketBuffer further up as a
// replacement for packet.Parsed, or inversely push packet.Parsed
// down into refactored GRO logic.
l.gro.Enqueue(pkt)
pkt.DecRef()
}
// flushGRO flushes previously enqueueGRO'd packets to the underlying
// stack.NetworkDispatcher. flushGRO is not thread-safe, and must not be
// called concurrently with enqueueGRO.
func (l *linkEndpoint) flushGRO() {
if !l.initGRO {
// If GRO was not initialized fast path return to avoid scanning GRO
// buckets (see l.gro.Flush()) that will always be empty.
return
}
l.mu.RLock()
defer l.mu.RUnlock()
if l.gro.Dispatcher != nil {
l.gro.Flush()
}
}
// Attach saves the stack network-layer dispatcher for use later when packets
// are injected.
func (l *linkEndpoint) Attach(dispatcher stack.NetworkDispatcher) {
l.mu.Lock()
defer l.mu.Unlock()
l.dispatcher = dispatcher
l.gro.Dispatcher = dispatcher
}
// IsAttached implements stack.LinkEndpoint.IsAttached.
func (l *linkEndpoint) IsAttached() bool {
l.mu.RLock()
defer l.mu.RUnlock()
return l.dispatcher != nil
}
// MTU implements stack.LinkEndpoint.MTU.
func (l *linkEndpoint) MTU() uint32 {
l.mu.RLock()
defer l.mu.RUnlock()
return l.mtu
}
// SetMTU implements stack.LinkEndpoint.SetMTU.
func (l *linkEndpoint) SetMTU(mtu uint32) {
l.mu.Lock()
defer l.mu.Unlock()
l.mtu = mtu
}
// Capabilities implements stack.LinkEndpoint.Capabilities.
func (l *linkEndpoint) Capabilities() stack.LinkEndpointCapabilities {
// We are required to offload RX checksum validation for the purposes of
// GRO.
return stack.CapabilityRXChecksumOffload
}
// GSOMaxSize implements stack.GSOEndpoint.
func (*linkEndpoint) GSOMaxSize() uint32 {
// This an increase from 32k returned by channel.Endpoint.GSOMaxSize() to
// 64k, which improves throughput.
return (1 << 16) - 1
}
// SupportedGSO implements stack.GSOEndpoint.
func (l *linkEndpoint) SupportedGSO() stack.SupportedGSO {
return l.SupportedGSOKind
}
// MaxHeaderLength returns the maximum size of the link layer header. Given it
// doesn't have a header, it just returns 0.
func (*linkEndpoint) MaxHeaderLength() uint16 {
return 0
}
// LinkAddress returns the link address of this endpoint.
func (l *linkEndpoint) LinkAddress() tcpip.LinkAddress {
l.mu.RLock()
defer l.mu.RUnlock()
return l.linkAddr
}
// SetLinkAddress implements stack.LinkEndpoint.SetLinkAddress.
func (l *linkEndpoint) SetLinkAddress(addr tcpip.LinkAddress) {
l.mu.Lock()
defer l.mu.Unlock()
l.linkAddr = addr
}
// WritePackets stores outbound packets into the channel.
// Multiple concurrent calls are permitted.
func (l *linkEndpoint) WritePackets(pkts stack.PacketBufferList) (int, tcpip.Error) {
n := 0
// TODO(jwhited): evaluate writing a stack.PacketBufferList instead of a
// single packet. We can split 2 x 64K GSO across
// wireguard-go/conn.IdealBatchSize (128 slots) @ 1280 MTU, and non-GSO we
// could do more. Read API would need to change to take advantage. Verify
// gVisor limits around max number of segments packed together. Since we
// control MTU (and by effect TCP MSS in gVisor) we *shouldn't* expect to
// ever overflow 128 slots (see wireguard-go/tun.ErrTooManySegments usage).
for _, pkt := range pkts.AsSlice() {
if err := l.q.Write(pkt); err != nil {
if _, ok := err.(*tcpip.ErrNoBufferSpace); !ok && n == 0 {
return 0, err
}
break
}
n++
}
return n, nil
}
// Wait implements stack.LinkEndpoint.Wait.
func (*linkEndpoint) Wait() {}
// ARPHardwareType implements stack.LinkEndpoint.ARPHardwareType.
func (*linkEndpoint) ARPHardwareType() header.ARPHardwareType {
return header.ARPHardwareNone
}
// AddHeader implements stack.LinkEndpoint.AddHeader.
func (*linkEndpoint) AddHeader(*stack.PacketBuffer) {}
// ParseHeader implements stack.LinkEndpoint.ParseHeader.
func (*linkEndpoint) ParseHeader(*stack.PacketBuffer) bool { return true }
// SetOnCloseAction implements stack.LinkEndpoint.
func (*linkEndpoint) SetOnCloseAction(func()) {}