/* SPDX-License-Identifier: MIT * * Copyright (C) 2017-2020 WireGuard LLC. All Rights Reserved. */ package device import ( "bufio" "errors" "fmt" "io" "net" "strconv" "strings" "sync/atomic" "time" "golang.zx2c4.com/wireguard/conn" "golang.zx2c4.com/wireguard/ipc" ) type IPCError struct { code int64 // error code err error // underlying/wrapped error } func (s IPCError) Error() string { return fmt.Sprintf("IPC error %d: %v", s.code, s.err) } func (s IPCError) Unwrap() error { return s.err } func (s IPCError) ErrorCode() int64 { return s.code } func ipcErrorf(code int64, msg string, args ...interface{}) *IPCError { return &IPCError{code: code, err: fmt.Errorf(msg, args...)} } // IpcGetOperation implements the WireGuard configuration protocol "get" operation. // See https://www.wireguard.com/xplatform/#configuration-protocol for details. func (device *Device) IpcGetOperation(w io.Writer) error { lines := make([]string, 0, 100) send := func(line string) { lines = append(lines, line) } func() { // lock required resources device.net.RLock() defer device.net.RUnlock() device.staticIdentity.RLock() defer device.staticIdentity.RUnlock() device.peers.RLock() defer device.peers.RUnlock() // serialize device related values if !device.staticIdentity.privateKey.IsZero() { send("private_key=" + device.staticIdentity.privateKey.ToHex()) } if device.net.port != 0 { send(fmt.Sprintf("listen_port=%d", device.net.port)) } if device.net.fwmark != 0 { send(fmt.Sprintf("fwmark=%d", device.net.fwmark)) } // serialize each peer state for _, peer := range device.peers.keyMap { peer.RLock() defer peer.RUnlock() send("public_key=" + peer.handshake.remoteStatic.ToHex()) send("preshared_key=" + peer.handshake.presharedKey.ToHex()) send("protocol_version=1") if peer.endpoint != nil { send("endpoint=" + peer.endpoint.DstToString()) } nano := atomic.LoadInt64(&peer.stats.lastHandshakeNano) secs := nano / time.Second.Nanoseconds() nano %= time.Second.Nanoseconds() send(fmt.Sprintf("last_handshake_time_sec=%d", secs)) send(fmt.Sprintf("last_handshake_time_nsec=%d", nano)) send(fmt.Sprintf("tx_bytes=%d", atomic.LoadUint64(&peer.stats.txBytes))) send(fmt.Sprintf("rx_bytes=%d", atomic.LoadUint64(&peer.stats.rxBytes))) send(fmt.Sprintf("persistent_keepalive_interval=%d", atomic.LoadUint32(&peer.persistentKeepaliveInterval))) for _, ip := range device.allowedips.EntriesForPeer(peer) { send("allowed_ip=" + ip.String()) } } }() // send lines (does not require resource locks) for _, line := range lines { _, err := io.WriteString(w, line+"\n") if err != nil { return ipcErrorf(ipc.IpcErrorIO, "failed to write output: %w", err) } } return nil } // IpcSetOperation implements the WireGuard configuration protocol "set" operation. // See https://www.wireguard.com/xplatform/#configuration-protocol for details. func (device *Device) IpcSetOperation(r io.Reader) (err error) { defer func() { if err != nil { device.log.Error.Println(err) } }() peer := new(ipcSetPeer) deviceConfig := true scanner := bufio.NewScanner(r) for scanner.Scan() { line := scanner.Text() if line == "" { // Blank line means terminate operation. return nil } parts := strings.Split(line, "=") if len(parts) != 2 { return ipcErrorf(ipc.IpcErrorProtocol, "failed to parse line %q, found %d =-separated parts, want 2", line, len(parts)) } key := parts[0] value := parts[1] if key == "public_key" { if deviceConfig { deviceConfig = false } // Load/create the peer we are now configuring. err := device.handlePublicKeyLine(peer, value) if err != nil { return err } continue } var err error if deviceConfig { err = device.handleDeviceLine(key, value) } else { err = device.handlePeerLine(peer, key, value) } if err != nil { return err } } if err := scanner.Err(); err != nil { return ipcErrorf(ipc.IpcErrorIO, "failed to read input: %w", err) } return nil } func (device *Device) handleDeviceLine(key, value string) error { switch key { case "private_key": var sk NoisePrivateKey err := sk.FromMaybeZeroHex(value) if err != nil { return ipcErrorf(ipc.IpcErrorInvalid, "failed to set private_key: %w", err) } device.log.Debug.Println("UAPI: Updating private key") device.SetPrivateKey(sk) case "listen_port": port, err := strconv.ParseUint(value, 10, 16) if err != nil { return ipcErrorf(ipc.IpcErrorInvalid, "failed to parse listen_port: %w", err) } // update port and rebind device.log.Debug.Println("UAPI: Updating listen port") device.net.Lock() device.net.port = uint16(port) device.net.Unlock() if err := device.BindUpdate(); err != nil { return ipcErrorf(ipc.IpcErrorPortInUse, "failed to set listen_port: %w", err) } case "fwmark": mark, err := strconv.ParseUint(value, 10, 32) if err != nil { return ipcErrorf(ipc.IpcErrorInvalid, "invalid fwmark: %w", err) } device.log.Debug.Println("UAPI: Updating fwmark") if err := device.BindSetMark(uint32(mark)); err != nil { return ipcErrorf(ipc.IpcErrorPortInUse, "failed to update fwmark: %w", err) } case "replace_peers": if value != "true" { return ipcErrorf(ipc.IpcErrorInvalid, "failed to set replace_peers, invalid value: %v", value) } device.log.Debug.Println("UAPI: Removing all peers") device.RemoveAllPeers() default: return ipcErrorf(ipc.IpcErrorInvalid, "invalid UAPI device key: %v", key) } return nil } // An ipcSetPeer is the current state of an IPC set operation on a peer. type ipcSetPeer struct { *Peer // Peer is the current peer being operated on dummy bool // dummy reports whether this peer is a temporary, placeholder peer created bool // new reports whether this is a newly created peer } func (device *Device) handlePublicKeyLine(peer *ipcSetPeer, value string) error { // Load/create the peer we are configuring. var publicKey NoisePublicKey err := publicKey.FromHex(value) if err != nil { return ipcErrorf(ipc.IpcErrorInvalid, "failed to get peer by public key: %w", err) } // Ignore peer with the same public key as this device. device.staticIdentity.RLock() peer.dummy = device.staticIdentity.publicKey.Equals(publicKey) device.staticIdentity.RUnlock() if peer.dummy { peer.Peer = &Peer{} } else { peer.Peer = device.LookupPeer(publicKey) } peer.created = peer.Peer == nil if peer.created { peer.Peer, err = device.NewPeer(publicKey) if err != nil { return ipcErrorf(ipc.IpcErrorInvalid, "failed to create new peer: %w", err) } device.log.Debug.Println(peer, "- UAPI: Created") } return nil } func (device *Device) handlePeerLine(peer *ipcSetPeer, key, value string) error { switch key { case "update_only": // allow disabling of creation if value != "true" { return ipcErrorf(ipc.IpcErrorInvalid, "failed to set update only, invalid value: %v", value) } if peer.created && !peer.dummy { device.RemovePeer(peer.handshake.remoteStatic) peer.Peer = &Peer{} peer.dummy = true } case "remove": // remove currently selected peer from device if value != "true" { return ipcErrorf(ipc.IpcErrorInvalid, "failed to set remove, invalid value: %v", value) } if !peer.dummy { device.log.Debug.Println(peer, "- UAPI: Removing") device.RemovePeer(peer.handshake.remoteStatic) } peer.Peer = &Peer{} peer.dummy = true case "preshared_key": device.log.Debug.Println(peer, "- UAPI: Updating preshared key") peer.handshake.mutex.Lock() err := peer.handshake.presharedKey.FromHex(value) peer.handshake.mutex.Unlock() if err != nil { return ipcErrorf(ipc.IpcErrorInvalid, "failed to set preshared key: %w", err) } case "endpoint": device.log.Debug.Println(peer, "- UAPI: Updating endpoint") endpoint, err := conn.CreateEndpoint(value) if err != nil { return ipcErrorf(ipc.IpcErrorInvalid, "failed to set endpoint %v: %w", value, err) } peer.Lock() defer peer.Unlock() peer.endpoint = endpoint case "persistent_keepalive_interval": device.log.Debug.Println(peer, "- UAPI: Updating persistent keepalive interval") secs, err := strconv.ParseUint(value, 10, 16) if err != nil { return ipcErrorf(ipc.IpcErrorInvalid, "failed to set persistent keepalive interval: %w", err) } old := atomic.SwapUint32(&peer.persistentKeepaliveInterval, uint32(secs)) // Send immediate keepalive if we're turning it on and before it wasn't on. if old == 0 && secs != 0 { if err != nil { return ipcErrorf(ipc.IpcErrorIO, "failed to get tun device status: %w", err) } if device.isUp.Get() && !peer.dummy { peer.SendKeepalive() } } case "replace_allowed_ips": device.log.Debug.Println(peer, "- UAPI: Removing all allowedips") if value != "true" { return ipcErrorf(ipc.IpcErrorInvalid, "failed to replace allowedips, invalid value: %v", value) } if peer.dummy { return nil } device.allowedips.RemoveByPeer(peer.Peer) case "allowed_ip": device.log.Debug.Println(peer, "- UAPI: Adding allowedip") _, network, err := net.ParseCIDR(value) if err != nil { return ipcErrorf(ipc.IpcErrorInvalid, "failed to set allowed ip: %w", err) } if peer.dummy { return nil } ones, _ := network.Mask.Size() device.allowedips.Insert(network.IP, uint(ones), peer.Peer) case "protocol_version": if value != "1" { return ipcErrorf(ipc.IpcErrorInvalid, "invalid protocol version: %v", value) } default: return ipcErrorf(ipc.IpcErrorInvalid, "invalid UAPI peer key: %v", key) } return nil } func (device *Device) IpcGet() (string, error) { buf := new(strings.Builder) if err := device.IpcGetOperation(buf); err != nil { return "", err } return buf.String(), nil } func (device *Device) IpcSet(uapiConf string) error { return device.IpcSetOperation(strings.NewReader(uapiConf)) } func (device *Device) IpcHandle(socket net.Conn) { // create buffered read/writer defer socket.Close() buffered := func(s io.ReadWriter) *bufio.ReadWriter { reader := bufio.NewReader(s) writer := bufio.NewWriter(s) return bufio.NewReadWriter(reader, writer) }(socket) defer buffered.Flush() op, err := buffered.ReadString('\n') if err != nil { return } // handle operation switch op { case "set=1\n": err = device.IpcSetOperation(buffered.Reader) case "get=1\n": err = device.IpcGetOperation(buffered.Writer) default: device.log.Error.Println("invalid UAPI operation:", op) return } // write status var status *IPCError if err != nil && !errors.As(err, &status) { // shouldn't happen status = ipcErrorf(ipc.IpcErrorUnknown, "other UAPI error: %w", err) } if status != nil { device.log.Error.Println(status) fmt.Fprintf(buffered, "errno=%d\n\n", status.ErrorCode()) } else { fmt.Fprintf(buffered, "errno=0\n\n") } }