tailscale/net/tstun/wrap.go
Avery Pennarun a92b9647c5 wgengine/bench: speed test for channels, sockets, and wireguard-go.
This tries to generate traffic at a rate that will saturate the
receiver, without overdoing it, even in the event of packet loss. It's
unrealistically more aggressive than TCP (which will back off quickly
in case of packet loss) but less silly than a blind test that just
generates packets as fast as it can (which can cause all the CPU to be
absorbed by the transmitter, giving an incorrect impression of how much
capacity the total system has).

Initial indications are that a syscall about every 10 packets (TCP bulk
delivery) is roughly the same speed as sending every packet through a
channel. A syscall per packet is about 5x-10x slower than that.

The whole tailscale wireguard-go + magicsock + packet filter
combination is about 4x slower again, which is better than I thought
we'd do, but probably has room for improvement.

Note that in "full" tailscale, there is also a tundev read/write for
every packet, effectively doubling the syscall overhead per packet.

Given these numbers, it seems like read/write syscalls are only 25-40%
of the total CPU time used in tailscale proper, so we do have
significant non-syscall optimization work to do too.

Sample output:

$ GOMAXPROCS=2 go test -bench . -benchtime 5s ./cmd/tailbench
goos: linux
goarch: amd64
pkg: tailscale.com/cmd/tailbench
cpu: Intel(R) Core(TM) i7-4785T CPU @ 2.20GHz
BenchmarkTrivialNoAlloc/32-2         	56340248	        93.85 ns/op	 340.98 MB/s	         0 %lost	       0 B/op	       0 allocs/op
BenchmarkTrivialNoAlloc/124-2        	57527490	        99.27 ns/op	1249.10 MB/s	         0 %lost	       0 B/op	       0 allocs/op
BenchmarkTrivialNoAlloc/1024-2       	52537773	       111.3 ns/op	9200.39 MB/s	         0 %lost	       0 B/op	       0 allocs/op
BenchmarkTrivial/32-2                	41878063	       135.6 ns/op	 236.04 MB/s	         0 %lost	       0 B/op	       0 allocs/op
BenchmarkTrivial/124-2               	41270439	       138.4 ns/op	 896.02 MB/s	         0 %lost	       0 B/op	       0 allocs/op
BenchmarkTrivial/1024-2              	36337252	       154.3 ns/op	6635.30 MB/s	         0 %lost	       0 B/op	       0 allocs/op
BenchmarkBlockingChannel/32-2           12171654	       494.3 ns/op	  64.74 MB/s	         0 %lost	    1791 B/op	       0 allocs/op
BenchmarkBlockingChannel/124-2          12149956	       507.8 ns/op	 244.17 MB/s	         0 %lost	    1792 B/op	       1 allocs/op
BenchmarkBlockingChannel/1024-2         11034754	       528.8 ns/op	1936.42 MB/s	         0 %lost	    1792 B/op	       1 allocs/op
BenchmarkNonlockingChannel/32-2          8960622	      2195 ns/op	  14.58 MB/s	         8.825 %lost	    1792 B/op	       1 allocs/op
BenchmarkNonlockingChannel/124-2         3014614	      2224 ns/op	  55.75 MB/s	        11.18 %lost	    1792 B/op	       1 allocs/op
BenchmarkNonlockingChannel/1024-2        3234915	      1688 ns/op	 606.53 MB/s	         3.765 %lost	    1792 B/op	       1 allocs/op
BenchmarkDoubleChannel/32-2          	 8457559	       764.1 ns/op	  41.88 MB/s	         5.945 %lost	    1792 B/op	       1 allocs/op
BenchmarkDoubleChannel/124-2         	 5497726	      1030 ns/op	 120.38 MB/s	        12.14 %lost	    1792 B/op	       1 allocs/op
BenchmarkDoubleChannel/1024-2        	 7985656	      1360 ns/op	 752.86 MB/s	        13.57 %lost	    1792 B/op	       1 allocs/op
BenchmarkUDP/32-2                    	 1652134	      3695 ns/op	   8.66 MB/s	         0 %lost	     176 B/op	       3 allocs/op
BenchmarkUDP/124-2                   	 1621024	      3765 ns/op	  32.94 MB/s	         0 %lost	     176 B/op	       3 allocs/op
BenchmarkUDP/1024-2                  	 1553750	      3825 ns/op	 267.72 MB/s	         0 %lost	     176 B/op	       3 allocs/op
BenchmarkTCP/32-2                    	11056336	       503.2 ns/op	  63.60 MB/s	         0 %lost	       0 B/op	       0 allocs/op
BenchmarkTCP/124-2                   	11074869	       533.7 ns/op	 232.32 MB/s	         0 %lost	       0 B/op	       0 allocs/op
BenchmarkTCP/1024-2                  	 8934968	       671.4 ns/op	1525.20 MB/s	         0 %lost	       0 B/op	       0 allocs/op
BenchmarkWireGuardTest/32-2          	 1403702	      4547 ns/op	   7.04 MB/s	        14.37 %lost	     467 B/op	       3 allocs/op
BenchmarkWireGuardTest/124-2         	  780645	      7927 ns/op	  15.64 MB/s	         1.537 %lost	     420 B/op	       3 allocs/op
BenchmarkWireGuardTest/1024-2        	  512671	     11791 ns/op	  86.85 MB/s	         0.5206 %lost	     411 B/op	       3 allocs/op
PASS
ok  	tailscale.com/wgengine/bench	195.724s

Updates #414.

Signed-off-by: Avery Pennarun <apenwarr@tailscale.com>
2021-04-26 03:51:13 -04:00

522 lines
14 KiB
Go

// Copyright (c) 2020 Tailscale Inc & AUTHORS All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// Package tstun provides a TUN struct implementing the tun.Device interface
// with additional features as required by wgengine.
package tstun
import (
"errors"
"io"
"os"
"sync"
"sync/atomic"
"time"
"github.com/tailscale/wireguard-go/device"
"github.com/tailscale/wireguard-go/tun"
"inet.af/netaddr"
"tailscale.com/net/packet"
"tailscale.com/types/ipproto"
"tailscale.com/types/logger"
"tailscale.com/wgengine/filter"
)
const maxBufferSize = device.MaxMessageSize
// PacketStartOffset is the minimal amount of leading space that must exist
// before &packet[offset] in a packet passed to Read, Write, or InjectInboundDirect.
// This is necessary to avoid reallocation in wireguard-go internals.
const PacketStartOffset = device.MessageTransportHeaderSize
// MaxPacketSize is the maximum size (in bytes)
// of a packet that can be injected into a tstun.Wrapper.
const MaxPacketSize = device.MaxContentSize
var (
// ErrClosed is returned when attempting an operation on a closed Wrapper.
ErrClosed = errors.New("device closed")
// ErrFiltered is returned when the acted-on packet is rejected by a filter.
ErrFiltered = errors.New("packet dropped by filter")
)
var (
errPacketTooBig = errors.New("packet too big")
errOffsetTooBig = errors.New("offset larger than buffer length")
errOffsetTooSmall = errors.New("offset smaller than PacketStartOffset")
)
// parsedPacketPool holds a pool of Parsed structs for use in filtering.
// This is needed because escape analysis cannot see that parsed packets
// do not escape through {Pre,Post}Filter{In,Out}.
var parsedPacketPool = sync.Pool{New: func() interface{} { return new(packet.Parsed) }}
// FilterFunc is a packet-filtering function with access to the Wrapper device.
// It must not hold onto the packet struct, as its backing storage will be reused.
type FilterFunc func(*packet.Parsed, *Wrapper) filter.Response
// Wrapper augments a tun.Device with packet filtering and injection.
type Wrapper struct {
logf logger.Logf
// tdev is the underlying Wrapper device.
tdev tun.Device
closeOnce sync.Once
lastActivityAtomic int64 // unix seconds of last send or receive
destIPActivity atomic.Value // of map[netaddr.IP]func()
// buffer stores the oldest unconsumed packet from tdev.
// It is made a static buffer in order to avoid allocations.
buffer [maxBufferSize]byte
// bufferConsumed synchronizes access to buffer (shared by Read and poll).
bufferConsumed chan struct{}
// closed signals poll (by closing) when the device is closed.
closed chan struct{}
// errors is the error queue populated by poll.
errors chan error
// outbound is the queue by which packets leave the TUN device.
//
// The directions are relative to the network, not the device:
// inbound packets arrive via UDP and are written into the TUN device;
// outbound packets are read from the TUN device and sent out via UDP.
// This queue is needed because although inbound writes are synchronous,
// the other direction must wait on a Wireguard goroutine to poll it.
//
// Empty reads are skipped by Wireguard, so it is always legal
// to discard an empty packet instead of sending it through t.outbound.
outbound chan []byte
// filter atomically stores the currently active packet filter
filter atomic.Value // of *filter.Filter
// filterFlags control the verbosity of logging packet drops/accepts.
filterFlags filter.RunFlags
// PreFilterIn is the inbound filter function that runs before the main filter
// and therefore sees the packets that may be later dropped by it.
PreFilterIn FilterFunc
// PostFilterIn is the inbound filter function that runs after the main filter.
PostFilterIn FilterFunc
// PreFilterOut is the outbound filter function that runs before the main filter
// and therefore sees the packets that may be later dropped by it.
PreFilterOut FilterFunc
// PostFilterOut is the outbound filter function that runs after the main filter.
PostFilterOut FilterFunc
// OnTSMPPongReceived, if non-nil, is called whenever a TSMP pong arrives.
OnTSMPPongReceived func(packet.TSMPPongReply)
// PeerAPIPort, if non-nil, returns the peerapi port that's
// running for the given IP address.
PeerAPIPort func(netaddr.IP) (port uint16, ok bool)
// disableFilter disables all filtering when set. This should only be used in tests.
disableFilter bool
// disableTSMPRejected disables TSMP rejected responses. For tests.
disableTSMPRejected bool
}
func Wrap(logf logger.Logf, tdev tun.Device) *Wrapper {
tun := &Wrapper{
logf: logger.WithPrefix(logf, "tstun: "),
tdev: tdev,
// bufferConsumed is conceptually a condition variable:
// a goroutine should not block when setting it, even with no listeners.
bufferConsumed: make(chan struct{}, 1),
closed: make(chan struct{}),
errors: make(chan error),
outbound: make(chan []byte),
// TODO(dmytro): (highly rate-limited) hexdumps should happen on unknown packets.
filterFlags: filter.LogAccepts | filter.LogDrops,
}
go tun.poll()
// The buffer starts out consumed.
tun.bufferConsumed <- struct{}{}
return tun
}
// SetDestIPActivityFuncs sets a map of funcs to run per packet
// destination (the map keys).
//
// The map ownership passes to the Wrapper. It must be non-nil.
func (t *Wrapper) SetDestIPActivityFuncs(m map[netaddr.IP]func()) {
t.destIPActivity.Store(m)
}
func (t *Wrapper) Close() error {
var err error
t.closeOnce.Do(func() {
// Other channels need not be closed: poll will exit gracefully after this.
close(t.closed)
err = t.tdev.Close()
})
return err
}
func (t *Wrapper) Events() chan tun.Event {
return t.tdev.Events()
}
func (t *Wrapper) File() *os.File {
return t.tdev.File()
}
func (t *Wrapper) Flush() error {
return t.tdev.Flush()
}
func (t *Wrapper) MTU() (int, error) {
return t.tdev.MTU()
}
func (t *Wrapper) Name() (string, error) {
return t.tdev.Name()
}
// poll polls t.tdev.Read, placing the oldest unconsumed packet into t.buffer.
// This is needed because t.tdev.Read in general may block (it does on Windows),
// so packets may be stuck in t.outbound if t.Read called t.tdev.Read directly.
func (t *Wrapper) poll() {
for {
select {
case <-t.closed:
return
case <-t.bufferConsumed:
// continue
}
// Read may use memory in t.buffer before PacketStartOffset for mandatory headers.
// This is the rationale behind the tun.Wrapper.{Read,Write} interfaces
// and the reason t.buffer has size MaxMessageSize and not MaxContentSize.
n, err := t.tdev.Read(t.buffer[:], PacketStartOffset)
if err != nil {
select {
case <-t.closed:
return
case t.errors <- err:
// In principle, read errors are not fatal (but wireguard-go disagrees).
t.bufferConsumed <- struct{}{}
}
continue
}
// Wireguard will skip an empty read,
// so we might as well do it here to avoid the send through t.outbound.
if n == 0 {
t.bufferConsumed <- struct{}{}
continue
}
select {
case <-t.closed:
return
case t.outbound <- t.buffer[PacketStartOffset : PacketStartOffset+n]:
// continue
}
}
}
var magicDNSIPPort = netaddr.MustParseIPPort("100.100.100.100:0")
func (t *Wrapper) filterOut(p *packet.Parsed) filter.Response {
// Fake ICMP echo responses to MagicDNS (100.100.100.100).
if p.IsEchoRequest() && p.Dst == magicDNSIPPort {
header := p.ICMP4Header()
header.ToResponse()
outp := packet.Generate(&header, p.Payload())
t.InjectInboundCopy(outp)
return filter.DropSilently // don't pass on to OS; already handled
}
if t.PreFilterOut != nil {
if res := t.PreFilterOut(p, t); res.IsDrop() {
return res
}
}
filt, _ := t.filter.Load().(*filter.Filter)
if filt == nil {
return filter.Drop
}
if filt.RunOut(p, t.filterFlags) != filter.Accept {
return filter.Drop
}
if t.PostFilterOut != nil {
if res := t.PostFilterOut(p, t); res.IsDrop() {
return res
}
}
return filter.Accept
}
// noteActivity records that there was a read or write at the current time.
func (t *Wrapper) noteActivity() {
atomic.StoreInt64(&t.lastActivityAtomic, time.Now().Unix())
}
// IdleDuration reports how long it's been since the last read or write to this device.
//
// Its value is only accurate to roughly second granularity.
// If there's never been activity, the duration is since 1970.
func (t *Wrapper) IdleDuration() time.Duration {
sec := atomic.LoadInt64(&t.lastActivityAtomic)
return time.Since(time.Unix(sec, 0))
}
func (t *Wrapper) Read(buf []byte, offset int) (int, error) {
var n int
wasInjectedPacket := false
select {
case <-t.closed:
return 0, io.EOF
case err := <-t.errors:
return 0, err
case pkt := <-t.outbound:
n = copy(buf[offset:], pkt)
// t.buffer has a fixed location in memory,
// so this is the easiest way to tell when it has been consumed.
// &pkt[0] can be used because empty packets do not reach t.outbound.
if &pkt[0] == &t.buffer[PacketStartOffset] {
t.bufferConsumed <- struct{}{}
} else {
// If the packet is not from t.buffer, then it is an injected packet.
wasInjectedPacket = true
}
}
p := parsedPacketPool.Get().(*packet.Parsed)
defer parsedPacketPool.Put(p)
p.Decode(buf[offset : offset+n])
if m, ok := t.destIPActivity.Load().(map[netaddr.IP]func()); ok {
if fn := m[p.Dst.IP]; fn != nil {
fn()
}
}
// For injected packets, we return early to bypass filtering.
if wasInjectedPacket {
t.noteActivity()
return n, nil
}
if !t.disableFilter {
response := t.filterOut(p)
if response != filter.Accept {
// Wireguard considers read errors fatal; pretend nothing was read
return 0, nil
}
}
t.noteActivity()
return n, nil
}
func (t *Wrapper) filterIn(buf []byte) filter.Response {
p := parsedPacketPool.Get().(*packet.Parsed)
defer parsedPacketPool.Put(p)
p.Decode(buf)
if p.IPProto == ipproto.TSMP {
if pingReq, ok := p.AsTSMPPing(); ok {
t.noteActivity()
t.injectOutboundPong(p, pingReq)
return filter.DropSilently
} else if data, ok := p.AsTSMPPong(); ok {
if f := t.OnTSMPPongReceived; f != nil {
f(data)
}
}
}
if t.PreFilterIn != nil {
if res := t.PreFilterIn(p, t); res.IsDrop() {
return res
}
}
filt, _ := t.filter.Load().(*filter.Filter)
if filt == nil {
return filter.Drop
}
outcome := filt.RunIn(p, t.filterFlags)
// Let peerapi through the filter; its ACLs are handled at L7,
// not at the packet level.
if outcome != filter.Accept &&
p.IPProto == ipproto.TCP &&
p.TCPFlags&packet.TCPSyn != 0 &&
t.PeerAPIPort != nil {
if port, ok := t.PeerAPIPort(p.Dst.IP); ok && port == p.Dst.Port {
outcome = filter.Accept
}
}
if outcome != filter.Accept {
// Tell them, via TSMP, we're dropping them due to the ACL.
// Their host networking stack can translate this into ICMP
// or whatnot as required. But notably, their GUI or tailscale CLI
// can show them a rejection history with reasons.
if p.IPVersion == 4 && p.IPProto == ipproto.TCP && p.TCPFlags&packet.TCPSyn != 0 && !t.disableTSMPRejected {
rj := packet.TailscaleRejectedHeader{
IPSrc: p.Dst.IP,
IPDst: p.Src.IP,
Src: p.Src,
Dst: p.Dst,
Proto: p.IPProto,
Reason: packet.RejectedDueToACLs,
}
if filt.ShieldsUp() {
rj.Reason = packet.RejectedDueToShieldsUp
}
pkt := packet.Generate(rj, nil)
t.InjectOutbound(pkt)
// TODO(bradfitz): also send a TCP RST, after the TSMP message.
}
return filter.Drop
}
if t.PostFilterIn != nil {
if res := t.PostFilterIn(p, t); res.IsDrop() {
return res
}
}
return filter.Accept
}
// Write accepts an incoming packet. The packet begins at buf[offset:],
// like wireguard-go/tun.Device.Write.
func (t *Wrapper) Write(buf []byte, offset int) (int, error) {
if !t.disableFilter {
res := t.filterIn(buf[offset:])
if res == filter.DropSilently {
return len(buf), nil
}
if res != filter.Accept {
return 0, ErrFiltered
}
}
t.noteActivity()
return t.tdev.Write(buf, offset)
}
func (t *Wrapper) GetFilter() *filter.Filter {
filt, _ := t.filter.Load().(*filter.Filter)
return filt
}
func (t *Wrapper) SetFilter(filt *filter.Filter) {
t.filter.Store(filt)
}
// InjectInboundDirect makes the Wrapper device behave as if a packet
// with the given contents was received from the network.
// It blocks and does not take ownership of the packet.
// The injected packet will not pass through inbound filters.
//
// The packet contents are to start at &buf[offset].
// offset must be greater or equal to PacketStartOffset.
// The space before &buf[offset] will be used by Wireguard.
func (t *Wrapper) InjectInboundDirect(buf []byte, offset int) error {
if len(buf) > MaxPacketSize {
return errPacketTooBig
}
if len(buf) < offset {
return errOffsetTooBig
}
if offset < PacketStartOffset {
return errOffsetTooSmall
}
// Write to the underlying device to skip filters.
_, err := t.tdev.Write(buf, offset)
return err
}
// InjectInboundCopy takes a packet without leading space,
// reallocates it to conform to the InjectInboundDirect interface
// and calls InjectInboundDirect on it. Injecting a nil packet is a no-op.
func (t *Wrapper) InjectInboundCopy(packet []byte) error {
// We duplicate this check from InjectInboundDirect here
// to avoid wasting an allocation on an oversized packet.
if len(packet) > MaxPacketSize {
return errPacketTooBig
}
if len(packet) == 0 {
return nil
}
buf := make([]byte, PacketStartOffset+len(packet))
copy(buf[PacketStartOffset:], packet)
return t.InjectInboundDirect(buf, PacketStartOffset)
}
func (t *Wrapper) injectOutboundPong(pp *packet.Parsed, req packet.TSMPPingRequest) {
pong := packet.TSMPPongReply{
Data: req.Data,
}
if t.PeerAPIPort != nil {
pong.PeerAPIPort, _ = t.PeerAPIPort(pp.Dst.IP)
}
switch pp.IPVersion {
case 4:
h4 := pp.IP4Header()
h4.ToResponse()
pong.IPHeader = h4
case 6:
h6 := pp.IP6Header()
h6.ToResponse()
pong.IPHeader = h6
default:
return
}
t.InjectOutbound(packet.Generate(pong, nil))
}
// InjectOutbound makes the Wrapper device behave as if a packet
// with the given contents was sent to the network.
// It does not block, but takes ownership of the packet.
// The injected packet will not pass through outbound filters.
// Injecting an empty packet is a no-op.
func (t *Wrapper) InjectOutbound(packet []byte) error {
if len(packet) > MaxPacketSize {
return errPacketTooBig
}
if len(packet) == 0 {
return nil
}
select {
case <-t.closed:
return ErrClosed
case t.outbound <- packet:
return nil
}
}
// Unwrap returns the underlying tun.Device.
func (t *Wrapper) Unwrap() tun.Device {
return t.tdev
}