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mirror of https://git.zx2c4.com/wireguard-go synced 2024-11-15 01:05:15 +01:00
wireguard-go/device/sticky_linux.go
Jordan Whited 9e2f386022 conn, device, tun: implement vectorized I/O on Linux
Implement TCP offloading via TSO and GRO for the Linux tun.Device, which
is made possible by virtio extensions in the kernel's TUN driver.

Delete conn.LinuxSocketEndpoint in favor of a collapsed conn.StdNetBind.
conn.StdNetBind makes use of recvmmsg() and sendmmsg() on Linux. All
platforms now fall under conn.StdNetBind, except for Windows, which
remains in conn.WinRingBind, which still needs to be adjusted to handle
multiple packets.

Also refactor sticky sockets support to eventually be applicable on
platforms other than just Linux. However Linux remains the sole platform
that fully implements it for now.

Co-authored-by: James Tucker <james@tailscale.com>
Signed-off-by: James Tucker <james@tailscale.com>
Signed-off-by: Jordan Whited <jordan@tailscale.com>
Signed-off-by: Jason A. Donenfeld <Jason@zx2c4.com>
2023-03-10 14:52:17 +01:00

222 lines
5.4 KiB
Go

/* SPDX-License-Identifier: MIT
*
* Copyright (C) 2017-2023 WireGuard LLC. All Rights Reserved.
*
* This implements userspace semantics of "sticky sockets", modeled after
* WireGuard's kernelspace implementation. This is more or less a straight port
* of the sticky-sockets.c example code:
* https://git.zx2c4.com/WireGuard/tree/contrib/examples/sticky-sockets/sticky-sockets.c
*
* Currently there is no way to achieve this within the net package:
* See e.g. https://github.com/golang/go/issues/17930
* So this code is remains platform dependent.
*/
package device
import (
"sync"
"unsafe"
"golang.org/x/sys/unix"
"golang.zx2c4.com/wireguard/conn"
"golang.zx2c4.com/wireguard/rwcancel"
)
func (device *Device) startRouteListener(bind conn.Bind) (*rwcancel.RWCancel, error) {
if _, ok := bind.(*conn.StdNetBind); !ok {
return nil, nil
}
netlinkSock, err := createNetlinkRouteSocket()
if err != nil {
return nil, err
}
netlinkCancel, err := rwcancel.NewRWCancel(netlinkSock)
if err != nil {
unix.Close(netlinkSock)
return nil, err
}
go device.routineRouteListener(bind, netlinkSock, netlinkCancel)
return netlinkCancel, nil
}
func (device *Device) routineRouteListener(bind conn.Bind, netlinkSock int, netlinkCancel *rwcancel.RWCancel) {
type peerEndpointPtr struct {
peer *Peer
endpoint *conn.Endpoint
}
var reqPeer map[uint32]peerEndpointPtr
var reqPeerLock sync.Mutex
defer netlinkCancel.Close()
defer unix.Close(netlinkSock)
for msg := make([]byte, 1<<16); ; {
var err error
var msgn int
for {
msgn, _, _, _, err = unix.Recvmsg(netlinkSock, msg[:], nil, 0)
if err == nil || !rwcancel.RetryAfterError(err) {
break
}
if !netlinkCancel.ReadyRead() {
return
}
}
if err != nil {
return
}
for remain := msg[:msgn]; len(remain) >= unix.SizeofNlMsghdr; {
hdr := *(*unix.NlMsghdr)(unsafe.Pointer(&remain[0]))
if uint(hdr.Len) > uint(len(remain)) {
break
}
switch hdr.Type {
case unix.RTM_NEWROUTE, unix.RTM_DELROUTE:
if hdr.Seq <= MaxPeers && hdr.Seq > 0 {
if uint(len(remain)) < uint(hdr.Len) {
break
}
if hdr.Len > unix.SizeofNlMsghdr+unix.SizeofRtMsg {
attr := remain[unix.SizeofNlMsghdr+unix.SizeofRtMsg:]
for {
if uint(len(attr)) < uint(unix.SizeofRtAttr) {
break
}
attrhdr := *(*unix.RtAttr)(unsafe.Pointer(&attr[0]))
if attrhdr.Len < unix.SizeofRtAttr || uint(len(attr)) < uint(attrhdr.Len) {
break
}
if attrhdr.Type == unix.RTA_OIF && attrhdr.Len == unix.SizeofRtAttr+4 {
ifidx := *(*uint32)(unsafe.Pointer(&attr[unix.SizeofRtAttr]))
reqPeerLock.Lock()
if reqPeer == nil {
reqPeerLock.Unlock()
break
}
pePtr, ok := reqPeer[hdr.Seq]
reqPeerLock.Unlock()
if !ok {
break
}
pePtr.peer.Lock()
if &pePtr.peer.endpoint != pePtr.endpoint {
pePtr.peer.Unlock()
break
}
if uint32(pePtr.peer.endpoint.(*conn.StdNetEndpoint).SrcIfidx()) == ifidx {
pePtr.peer.Unlock()
break
}
pePtr.peer.endpoint.(*conn.StdNetEndpoint).ClearSrc()
pePtr.peer.Unlock()
}
attr = attr[attrhdr.Len:]
}
}
break
}
reqPeerLock.Lock()
reqPeer = make(map[uint32]peerEndpointPtr)
reqPeerLock.Unlock()
go func() {
device.peers.RLock()
i := uint32(1)
for _, peer := range device.peers.keyMap {
peer.RLock()
if peer.endpoint == nil {
peer.RUnlock()
continue
}
nativeEP, _ := peer.endpoint.(*conn.StdNetEndpoint)
if nativeEP == nil {
peer.RUnlock()
continue
}
if nativeEP.DstIP().Is6() || nativeEP.SrcIfidx() == 0 {
peer.RUnlock()
break
}
nlmsg := struct {
hdr unix.NlMsghdr
msg unix.RtMsg
dsthdr unix.RtAttr
dst [4]byte
srchdr unix.RtAttr
src [4]byte
markhdr unix.RtAttr
mark uint32
}{
unix.NlMsghdr{
Type: uint16(unix.RTM_GETROUTE),
Flags: unix.NLM_F_REQUEST,
Seq: i,
},
unix.RtMsg{
Family: unix.AF_INET,
Dst_len: 32,
Src_len: 32,
},
unix.RtAttr{
Len: 8,
Type: unix.RTA_DST,
},
nativeEP.DstIP().As4(),
unix.RtAttr{
Len: 8,
Type: unix.RTA_SRC,
},
nativeEP.SrcIP().As4(),
unix.RtAttr{
Len: 8,
Type: unix.RTA_MARK,
},
device.net.fwmark,
}
nlmsg.hdr.Len = uint32(unsafe.Sizeof(nlmsg))
reqPeerLock.Lock()
reqPeer[i] = peerEndpointPtr{
peer: peer,
endpoint: &peer.endpoint,
}
reqPeerLock.Unlock()
peer.RUnlock()
i++
_, err := netlinkCancel.Write((*[unsafe.Sizeof(nlmsg)]byte)(unsafe.Pointer(&nlmsg))[:])
if err != nil {
break
}
}
device.peers.RUnlock()
}()
}
remain = remain[hdr.Len:]
}
}
}
func createNetlinkRouteSocket() (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_IPV4_ROUTE,
}
err = unix.Bind(sock, saddr)
if err != nil {
unix.Close(sock)
return -1, err
}
return sock, nil
}