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mirror of https://git.zx2c4.com/wireguard-go synced 2024-11-15 01:05:15 +01:00
wireguard-go/conn/bind_std.go
Jordan Whited 6a84778f2c conn, device: use UDP GSO and GRO on Linux
StdNetBind probes for UDP GSO and GRO support at runtime. UDP GSO is
dependent on checksum offload support on the egress netdev. UDP GSO
will be disabled in the event sendmmsg() returns EIO, which is a strong
signal that the egress netdev does not support checksum offload.

The iperf3 results below demonstrate the effect of this commit between
two Linux computers with i5-12400 CPUs. There is roughly ~13us of round
trip latency between them.

The first result is from commit 052af4a without UDP GSO or GRO.

Starting Test: protocol: TCP, 1 streams, 131072 byte blocks
[ ID] Interval           Transfer     Bitrate         Retr  Cwnd
[  5]   0.00-10.00  sec  9.85 GBytes  8.46 Gbits/sec  1139   3.01 MBytes
- - - - - - - - - - - - - - - - - - - - - - - - -
Test Complete. Summary Results:
[ ID] Interval           Transfer     Bitrate         Retr
[  5]   0.00-10.00  sec  9.85 GBytes  8.46 Gbits/sec  1139  sender
[  5]   0.00-10.04  sec  9.85 GBytes  8.42 Gbits/sec        receiver

The second result is with UDP GSO and GRO.

Starting Test: protocol: TCP, 1 streams, 131072 byte blocks
[ ID] Interval           Transfer     Bitrate         Retr  Cwnd
[  5]   0.00-10.00  sec  12.3 GBytes  10.6 Gbits/sec  232   3.15 MBytes
- - - - - - - - - - - - - - - - - - - - - - - - -
Test Complete. Summary Results:
[ ID] Interval           Transfer     Bitrate         Retr
[  5]   0.00-10.00  sec  12.3 GBytes  10.6 Gbits/sec  232   sender
[  5]   0.00-10.04  sec  12.3 GBytes  10.6 Gbits/sec        receiver

Reviewed-by: Adrian Dewhurst <adrian@tailscale.com>
Signed-off-by: Jordan Whited <jordan@tailscale.com>
Signed-off-by: Jason A. Donenfeld <Jason@zx2c4.com>
2023-10-10 15:07:36 +02:00

544 lines
13 KiB
Go

/* SPDX-License-Identifier: MIT
*
* Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
*/
package conn
import (
"context"
"errors"
"fmt"
"net"
"net/netip"
"runtime"
"strconv"
"sync"
"syscall"
"golang.org/x/net/ipv4"
"golang.org/x/net/ipv6"
)
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
ipv4TxOffload bool
ipv4RxOffload bool
ipv6TxOffload bool
ipv6RxOffload bool
// these two fields are not guarded by mu
udpAddrPool sync.Pool
msgsPool sync.Pool
blackhole4 bool
blackhole6 bool
}
func NewStdNetBind() Bind {
return &StdNetBind{
udpAddrPool: sync.Pool{
New: func() any {
return &net.UDPAddr{
IP: make([]byte, 16),
}
},
},
msgsPool: sync.Pool{
New: func() any {
// ipv6.Message and ipv4.Message are interchangeable as they are
// both aliases for x/net/internal/socket.Message.
msgs := make([]ipv6.Message, IdealBatchSize)
for i := range msgs {
msgs[i].Buffers = make(net.Buffers, 1)
msgs[i].OOB = make([]byte, controlSize)
}
return &msgs
},
},
}
}
type StdNetEndpoint struct {
// AddrPort is the endpoint destination.
netip.AddrPort
// src is the current sticky source address and interface index, if
// supported. Typically this is a PKTINFO structure from/for control
// messages, see unix.PKTINFO for an example.
src []byte
}
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() {
if e.src != nil {
// Truncate src, no need to reallocate.
e.src = e.src[:0]
}
}
func (e *StdNetEndpoint) DstIP() netip.Addr {
return e.AddrPort.Addr()
}
// See control_default,linux, etc for implementations of SrcIP and SrcIfidx.
func (e *StdNetEndpoint) DstToBytes() []byte {
b, _ := e.AddrPort.MarshalBinary()
return b
}
func (e *StdNetEndpoint) DstToString() string {
return e.AddrPort.String()
}
func listenNet(network string, port int) (*net.UDPConn, int, error) {
conn, err := listenConfig().ListenPacket(context.Background(), network, ":"+strconv.Itoa(port))
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) 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, v6conn *net.UDPConn
var v4pc *ipv4.PacketConn
var v6pc *ipv6.PacketConn
v4conn, port, err = listenNet("udp4", port)
if err != nil && !errors.Is(err, syscall.EAFNOSUPPORT) {
return nil, 0, err
}
// Listen on the same port as we're using for ipv4.
v6conn, port, err = listenNet("udp6", port)
if uport == 0 && errors.Is(err, syscall.EADDRINUSE) && tries < 100 {
v4conn.Close()
tries++
goto again
}
if err != nil && !errors.Is(err, syscall.EAFNOSUPPORT) {
v4conn.Close()
return nil, 0, err
}
var fns []ReceiveFunc
if v4conn != nil {
s.ipv4TxOffload, s.ipv4RxOffload = supportsUDPOffload(v4conn)
if runtime.GOOS == "linux" {
v4pc = ipv4.NewPacketConn(v4conn)
s.ipv4PC = v4pc
}
fns = append(fns, s.makeReceiveIPv4(v4pc, v4conn, s.ipv4RxOffload))
s.ipv4 = v4conn
}
if v6conn != nil {
s.ipv6TxOffload, s.ipv6RxOffload = supportsUDPOffload(v6conn)
if runtime.GOOS == "linux" {
v6pc = ipv6.NewPacketConn(v6conn)
s.ipv6PC = v6pc
}
fns = append(fns, s.makeReceiveIPv6(v6pc, v6conn, s.ipv6RxOffload))
s.ipv6 = v6conn
}
if len(fns) == 0 {
return nil, 0, syscall.EAFNOSUPPORT
}
return fns, uint16(port), nil
}
func (s *StdNetBind) putMessages(msgs *[]ipv6.Message) {
for i := range *msgs {
(*msgs)[i] = ipv6.Message{Buffers: (*msgs)[i].Buffers, OOB: (*msgs)[i].OOB}
}
s.msgsPool.Put(msgs)
}
func (s *StdNetBind) getMessages() *[]ipv6.Message {
return s.msgsPool.Get().(*[]ipv6.Message)
}
var (
// If compilation fails here these are no longer the same underlying type.
_ ipv6.Message = ipv4.Message{}
)
type batchReader interface {
ReadBatch([]ipv6.Message, int) (int, error)
}
type batchWriter interface {
WriteBatch([]ipv6.Message, int) (int, error)
}
func (s *StdNetBind) receiveIP(
br batchReader,
conn *net.UDPConn,
rxOffload bool,
bufs [][]byte,
sizes []int,
eps []Endpoint,
) (n int, err error) {
msgs := s.getMessages()
for i := range bufs {
(*msgs)[i].Buffers[0] = bufs[i]
(*msgs)[i].OOB = (*msgs)[i].OOB[:cap((*msgs)[i].OOB)]
}
defer s.putMessages(msgs)
var numMsgs int
if runtime.GOOS == "linux" {
if rxOffload {
readAt := len(*msgs) - (IdealBatchSize / udpSegmentMaxDatagrams)
numMsgs, err = br.ReadBatch((*msgs)[readAt:], 0)
if err != nil {
return 0, err
}
numMsgs, err = splitCoalescedMessages(*msgs, readAt, getGSOSize)
if err != nil {
return 0, err
}
} else {
numMsgs, err = br.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
if sizes[i] == 0 {
continue
}
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) makeReceiveIPv4(pc *ipv4.PacketConn, conn *net.UDPConn, rxOffload bool) ReceiveFunc {
return func(bufs [][]byte, sizes []int, eps []Endpoint) (n int, err error) {
return s.receiveIP(pc, conn, rxOffload, bufs, sizes, eps)
}
}
func (s *StdNetBind) makeReceiveIPv6(pc *ipv6.PacketConn, conn *net.UDPConn, rxOffload bool) ReceiveFunc {
return func(bufs [][]byte, sizes []int, eps []Endpoint) (n int, err error) {
return s.receiveIP(pc, conn, rxOffload, bufs, sizes, eps)
}
}
// 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
s.ipv4TxOffload = false
s.ipv4RxOffload = false
s.ipv6TxOffload = false
s.ipv6RxOffload = false
if err1 != nil {
return err1
}
return err2
}
type ErrUDPGSODisabled struct {
onLaddr string
RetryErr error
}
func (e ErrUDPGSODisabled) Error() string {
return fmt.Sprintf("disabled UDP GSO on %s, NIC(s) may not support checksum offload", e.onLaddr)
}
func (e ErrUDPGSODisabled) Unwrap() error {
return e.RetryErr
}
func (s *StdNetBind) Send(bufs [][]byte, endpoint Endpoint) error {
s.mu.Lock()
blackhole := s.blackhole4
conn := s.ipv4
offload := s.ipv4TxOffload
br := batchWriter(s.ipv4PC)
is6 := false
if endpoint.DstIP().Is6() {
blackhole = s.blackhole6
conn = s.ipv6
br = s.ipv6PC
is6 = true
offload = s.ipv6TxOffload
}
s.mu.Unlock()
if blackhole {
return nil
}
if conn == nil {
return syscall.EAFNOSUPPORT
}
msgs := s.getMessages()
defer s.putMessages(msgs)
ua := s.udpAddrPool.Get().(*net.UDPAddr)
defer s.udpAddrPool.Put(ua)
if is6 {
as16 := endpoint.DstIP().As16()
copy(ua.IP, as16[:])
ua.IP = ua.IP[:16]
} else {
as4 := endpoint.DstIP().As4()
copy(ua.IP, as4[:])
ua.IP = ua.IP[:4]
}
ua.Port = int(endpoint.(*StdNetEndpoint).Port())
var (
retried bool
err error
)
retry:
if offload {
n := coalesceMessages(ua, endpoint.(*StdNetEndpoint), bufs, *msgs, setGSOSize)
err = s.send(conn, br, (*msgs)[:n])
if err != nil && offload && errShouldDisableUDPGSO(err) {
offload = false
s.mu.Lock()
if is6 {
s.ipv6TxOffload = false
} else {
s.ipv4TxOffload = false
}
s.mu.Unlock()
retried = true
goto retry
}
} else {
for i := range bufs {
(*msgs)[i].Addr = ua
(*msgs)[i].Buffers[0] = bufs[i]
setSrcControl(&(*msgs)[i].OOB, endpoint.(*StdNetEndpoint))
}
err = s.send(conn, br, (*msgs)[:len(bufs)])
}
if retried {
return ErrUDPGSODisabled{onLaddr: conn.LocalAddr().String(), RetryErr: err}
}
return err
}
func (s *StdNetBind) send(conn *net.UDPConn, pc batchWriter, msgs []ipv6.Message) error {
var (
n int
err error
start int
)
if runtime.GOOS == "linux" {
for {
n, err = pc.WriteBatch(msgs[start:], 0)
if err != nil || n == len(msgs[start:]) {
break
}
start += n
}
} else {
for _, msg := range msgs {
_, _, err = conn.WriteMsgUDP(msg.Buffers[0], msg.OOB, msg.Addr.(*net.UDPAddr))
if err != nil {
break
}
}
}
return err
}
const (
// Exceeding these values results in EMSGSIZE. They account for layer3 and
// layer4 headers. IPv6 does not need to account for itself as the payload
// length field is self excluding.
maxIPv4PayloadLen = 1<<16 - 1 - 20 - 8
maxIPv6PayloadLen = 1<<16 - 1 - 8
// This is a hard limit imposed by the kernel.
udpSegmentMaxDatagrams = 64
)
type setGSOFunc func(control *[]byte, gsoSize uint16)
func coalesceMessages(addr *net.UDPAddr, ep *StdNetEndpoint, bufs [][]byte, msgs []ipv6.Message, setGSO setGSOFunc) int {
var (
base = -1 // index of msg we are currently coalescing into
gsoSize int // segmentation size of msgs[base]
dgramCnt int // number of dgrams coalesced into msgs[base]
endBatch bool // tracking flag to start a new batch on next iteration of bufs
)
maxPayloadLen := maxIPv4PayloadLen
if ep.DstIP().Is6() {
maxPayloadLen = maxIPv6PayloadLen
}
for i, buf := range bufs {
if i > 0 {
msgLen := len(buf)
baseLenBefore := len(msgs[base].Buffers[0])
freeBaseCap := cap(msgs[base].Buffers[0]) - baseLenBefore
if msgLen+baseLenBefore <= maxPayloadLen &&
msgLen <= gsoSize &&
msgLen <= freeBaseCap &&
dgramCnt < udpSegmentMaxDatagrams &&
!endBatch {
msgs[base].Buffers[0] = append(msgs[base].Buffers[0], buf...)
if i == len(bufs)-1 {
setGSO(&msgs[base].OOB, uint16(gsoSize))
}
dgramCnt++
if msgLen < gsoSize {
// A smaller than gsoSize packet on the tail is legal, but
// it must end the batch.
endBatch = true
}
continue
}
}
if dgramCnt > 1 {
setGSO(&msgs[base].OOB, uint16(gsoSize))
}
// Reset prior to incrementing base since we are preparing to start a
// new potential batch.
endBatch = false
base++
gsoSize = len(buf)
setSrcControl(&msgs[base].OOB, ep)
msgs[base].Buffers[0] = buf
msgs[base].Addr = addr
dgramCnt = 1
}
return base + 1
}
type getGSOFunc func(control []byte) (int, error)
func splitCoalescedMessages(msgs []ipv6.Message, firstMsgAt int, getGSO getGSOFunc) (n int, err error) {
for i := firstMsgAt; i < len(msgs); i++ {
msg := &msgs[i]
if msg.N == 0 {
return n, err
}
var (
gsoSize int
start int
end = msg.N
numToSplit = 1
)
gsoSize, err = getGSO(msg.OOB[:msg.NN])
if err != nil {
return n, err
}
if gsoSize > 0 {
numToSplit = (msg.N + gsoSize - 1) / gsoSize
end = gsoSize
}
for j := 0; j < numToSplit; j++ {
if n > i {
return n, errors.New("splitting coalesced packet resulted in overflow")
}
copied := copy(msgs[n].Buffers[0], msg.Buffers[0][start:end])
msgs[n].N = copied
msgs[n].Addr = msg.Addr
start = end
end += gsoSize
if end > msg.N {
end = msg.N
}
n++
}
if i != n-1 {
// It is legal for bytes to move within msg.Buffers[0] as a result
// of splitting, so we only zero the source msg len when it is not
// the destination of the last split operation above.
msg.N = 0
}
}
return n, nil
}