netbird/client/server/server.go

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package server
import (
"context"
"fmt"
"os"
"os/exec"
"runtime"
"strconv"
"sync"
"time"
"github.com/cenkalti/backoff/v4"
"golang.org/x/exp/maps"
"google.golang.org/protobuf/types/known/durationpb"
log "github.com/sirupsen/logrus"
"google.golang.org/grpc/codes"
"google.golang.org/grpc/metadata"
gstatus "google.golang.org/grpc/status"
"google.golang.org/protobuf/types/known/timestamppb"
"github.com/netbirdio/netbird/client/internal/auth"
"github.com/netbirdio/netbird/client/system"
"github.com/netbirdio/netbird/client/internal"
"github.com/netbirdio/netbird/client/internal/peer"
"github.com/netbirdio/netbird/client/proto"
"github.com/netbirdio/netbird/version"
)
const (
probeThreshold = time.Second * 5
retryInitialIntervalVar = "NB_CONN_RETRY_INTERVAL_TIME"
maxRetryIntervalVar = "NB_CONN_MAX_RETRY_INTERVAL_TIME"
maxRetryTimeVar = "NB_CONN_MAX_RETRY_TIME_TIME"
retryMultiplierVar = "NB_CONN_RETRY_MULTIPLIER"
defaultInitialRetryTime = 30 * time.Minute
defaultMaxRetryInterval = 60 * time.Minute
defaultMaxRetryTime = 14 * 24 * time.Hour
defaultRetryMultiplier = 1.7
errRestoreResidualState = "failed to restore residual state: %v"
)
// Server for service control.
type Server struct {
rootCtx context.Context
actCancel context.CancelFunc
latestConfigInput internal.ConfigInput
logFile string
oauthAuthFlow oauthAuthFlow
mutex sync.Mutex
config *internal.Config
proto.UnimplementedDaemonServiceServer
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connectClient *internal.ConnectClient
statusRecorder *peer.Status
sessionWatcher *internal.SessionWatcher
mgmProbe *internal.Probe
signalProbe *internal.Probe
relayProbe *internal.Probe
wgProbe *internal.Probe
lastProbe time.Time
persistNetworkMap bool
}
type oauthAuthFlow struct {
expiresAt time.Time
flow auth.OAuthFlow
info auth.AuthFlowInfo
waitCancel context.CancelFunc
}
// New server instance constructor.
func New(ctx context.Context, configPath, logFile string) *Server {
return &Server{
rootCtx: ctx,
latestConfigInput: internal.ConfigInput{
ConfigPath: configPath,
},
logFile: logFile,
mgmProbe: internal.NewProbe(),
signalProbe: internal.NewProbe(),
relayProbe: internal.NewProbe(),
wgProbe: internal.NewProbe(),
}
}
func (s *Server) Start() error {
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s.mutex.Lock()
defer s.mutex.Unlock()
state := internal.CtxGetState(s.rootCtx)
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if err := handlePanicLog(); err != nil {
log.Warnf("failed to redirect stderr: %v", err)
}
if err := restoreResidualState(s.rootCtx); err != nil {
log.Warnf(errRestoreResidualState, err)
}
// if current state contains any error, return it
// in all other cases we can continue execution only if status is idle and up command was
// not in the progress or already successfully established connection.
status, err := state.Status()
if err != nil {
return err
}
if status != internal.StatusIdle {
return nil
}
ctx, cancel := context.WithCancel(s.rootCtx)
s.actCancel = cancel
// if configuration exists, we just start connections. if is new config we skip and set status NeedsLogin
// on failure we return error to retry
config, err := internal.UpdateConfig(s.latestConfigInput)
if errorStatus, ok := gstatus.FromError(err); ok && errorStatus.Code() == codes.NotFound {
s.config, err = internal.UpdateOrCreateConfig(s.latestConfigInput)
if err != nil {
log.Warnf("unable to create configuration file: %v", err)
return err
}
state.Set(internal.StatusNeedsLogin)
return nil
} else if err != nil {
log.Warnf("unable to create configuration file: %v", err)
return err
}
// if configuration exists, we just start connections.
config, _ = internal.UpdateOldManagementURL(ctx, config, s.latestConfigInput.ConfigPath)
s.config = config
if s.statusRecorder == nil {
s.statusRecorder = peer.NewRecorder(config.ManagementURL.String())
}
s.statusRecorder.UpdateManagementAddress(config.ManagementURL.String())
s.statusRecorder.UpdateRosenpass(config.RosenpassEnabled, config.RosenpassPermissive)
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if s.sessionWatcher == nil {
s.sessionWatcher = internal.NewSessionWatcher(s.rootCtx, s.statusRecorder)
s.sessionWatcher.SetOnExpireListener(s.onSessionExpire)
}
if config.DisableAutoConnect {
return nil
}
go s.connectWithRetryRuns(ctx, config, s.statusRecorder, nil)
return nil
}
// connectWithRetryRuns runs the client connection with a backoff strategy where we retry the operation as additional
// mechanism to keep the client connected even when the connection is lost.
// we cancel retry if the client receive a stop or down command, or if disable auto connect is configured.
func (s *Server) connectWithRetryRuns(ctx context.Context, config *internal.Config, statusRecorder *peer.Status,
runningChan chan error,
) {
backOff := getConnectWithBackoff(ctx)
retryStarted := false
go func() {
t := time.NewTicker(24 * time.Hour)
for {
select {
case <-ctx.Done():
t.Stop()
return
case <-t.C:
if retryStarted {
mgmtState := statusRecorder.GetManagementState()
signalState := statusRecorder.GetSignalState()
if mgmtState.Connected && signalState.Connected {
log.Tracef("resetting status")
retryStarted = false
} else {
log.Tracef("not resetting status: mgmt: %v, signal: %v", mgmtState.Connected, signalState.Connected)
}
}
}
}
}()
runOperation := func() error {
log.Tracef("running client connection")
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s.connectClient = internal.NewConnectClient(ctx, config, statusRecorder)
s.connectClient.SetNetworkMapPersistence(s.persistNetworkMap)
probes := internal.ProbeHolder{
MgmProbe: s.mgmProbe,
SignalProbe: s.signalProbe,
RelayProbe: s.relayProbe,
WgProbe: s.wgProbe,
}
err := s.connectClient.RunWithProbes(&probes, runningChan)
if err != nil {
log.Debugf("run client connection exited with error: %v. Will retry in the background", err)
}
if config.DisableAutoConnect {
return backoff.Permanent(err)
}
if !retryStarted {
retryStarted = true
backOff.Reset()
}
log.Tracef("client connection exited")
return fmt.Errorf("client connection exited")
}
err := backoff.Retry(runOperation, backOff)
if s, ok := gstatus.FromError(err); ok && s.Code() != codes.Canceled {
log.Errorf("received an error when trying to connect: %v", err)
} else {
log.Tracef("retry canceled")
}
}
// getConnectWithBackoff returns a backoff with exponential backoff strategy for connection retries
func getConnectWithBackoff(ctx context.Context) backoff.BackOff {
initialInterval := parseEnvDuration(retryInitialIntervalVar, defaultInitialRetryTime)
maxInterval := parseEnvDuration(maxRetryIntervalVar, defaultMaxRetryInterval)
maxElapsedTime := parseEnvDuration(maxRetryTimeVar, defaultMaxRetryTime)
multiplier := defaultRetryMultiplier
if envValue := os.Getenv(retryMultiplierVar); envValue != "" {
// parse the multiplier from the environment variable string value to float64
value, err := strconv.ParseFloat(envValue, 64)
if err != nil {
log.Warnf("unable to parse environment variable %s: %s. using default: %f", retryMultiplierVar, envValue, multiplier)
} else {
multiplier = value
}
}
return backoff.WithContext(&backoff.ExponentialBackOff{
InitialInterval: initialInterval,
RandomizationFactor: 1,
Multiplier: multiplier,
MaxInterval: maxInterval,
MaxElapsedTime: maxElapsedTime, // 14 days
Stop: backoff.Stop,
Clock: backoff.SystemClock,
}, ctx)
}
// parseEnvDuration parses the environment variable and returns the duration
func parseEnvDuration(envVar string, defaultDuration time.Duration) time.Duration {
if envValue := os.Getenv(envVar); envValue != "" {
if duration, err := time.ParseDuration(envValue); err == nil {
return duration
}
log.Warnf("unable to parse environment variable %s: %s. using default: %s", envVar, envValue, defaultDuration)
}
return defaultDuration
}
// loginAttempt attempts to login using the provided information. it returns a status in case something fails
func (s *Server) loginAttempt(ctx context.Context, setupKey, jwtToken string) (internal.StatusType, error) {
var status internal.StatusType
err := internal.Login(ctx, s.config, setupKey, jwtToken)
if err != nil {
if s, ok := gstatus.FromError(err); ok && (s.Code() == codes.InvalidArgument || s.Code() == codes.PermissionDenied) {
log.Warnf("failed login: %v", err)
status = internal.StatusNeedsLogin
} else {
log.Errorf("failed login: %v", err)
status = internal.StatusLoginFailed
}
return status, err
}
return "", nil
}
// Login uses setup key to prepare configuration for the daemon.
func (s *Server) Login(callerCtx context.Context, msg *proto.LoginRequest) (*proto.LoginResponse, error) {
s.mutex.Lock()
if s.actCancel != nil {
s.actCancel()
}
ctx, cancel := context.WithCancel(s.rootCtx)
md, ok := metadata.FromIncomingContext(callerCtx)
if ok {
ctx = metadata.NewOutgoingContext(ctx, md)
}
s.actCancel = cancel
s.mutex.Unlock()
if err := restoreResidualState(ctx); err != nil {
log.Warnf(errRestoreResidualState, err)
}
state := internal.CtxGetState(ctx)
defer func() {
status, err := state.Status()
if err != nil || (status != internal.StatusNeedsLogin && status != internal.StatusLoginFailed) {
state.Set(internal.StatusIdle)
}
}()
s.mutex.Lock()
inputConfig := s.latestConfigInput
if msg.ManagementUrl != "" {
inputConfig.ManagementURL = msg.ManagementUrl
s.latestConfigInput.ManagementURL = msg.ManagementUrl
}
if msg.AdminURL != "" {
inputConfig.AdminURL = msg.AdminURL
s.latestConfigInput.AdminURL = msg.AdminURL
}
if msg.CleanNATExternalIPs {
inputConfig.NATExternalIPs = make([]string, 0)
s.latestConfigInput.NATExternalIPs = nil
} else if msg.NatExternalIPs != nil {
inputConfig.NATExternalIPs = msg.NatExternalIPs
s.latestConfigInput.NATExternalIPs = msg.NatExternalIPs
}
inputConfig.CustomDNSAddress = msg.CustomDNSAddress
s.latestConfigInput.CustomDNSAddress = msg.CustomDNSAddress
if string(msg.CustomDNSAddress) == "empty" {
inputConfig.CustomDNSAddress = []byte{}
s.latestConfigInput.CustomDNSAddress = []byte{}
}
if msg.Hostname != "" {
// nolint
ctx = context.WithValue(ctx, system.DeviceNameCtxKey, msg.Hostname)
}
if msg.RosenpassEnabled != nil {
inputConfig.RosenpassEnabled = msg.RosenpassEnabled
s.latestConfigInput.RosenpassEnabled = msg.RosenpassEnabled
}
if msg.RosenpassPermissive != nil {
inputConfig.RosenpassPermissive = msg.RosenpassPermissive
s.latestConfigInput.RosenpassPermissive = msg.RosenpassPermissive
}
if msg.ServerSSHAllowed != nil {
inputConfig.ServerSSHAllowed = msg.ServerSSHAllowed
s.latestConfigInput.ServerSSHAllowed = msg.ServerSSHAllowed
}
if msg.DisableAutoConnect != nil {
inputConfig.DisableAutoConnect = msg.DisableAutoConnect
s.latestConfigInput.DisableAutoConnect = msg.DisableAutoConnect
}
if msg.InterfaceName != nil {
inputConfig.InterfaceName = msg.InterfaceName
s.latestConfigInput.InterfaceName = msg.InterfaceName
}
if msg.WireguardPort != nil {
port := int(*msg.WireguardPort)
inputConfig.WireguardPort = &port
s.latestConfigInput.WireguardPort = &port
}
if msg.NetworkMonitor != nil {
inputConfig.NetworkMonitor = msg.NetworkMonitor
s.latestConfigInput.NetworkMonitor = msg.NetworkMonitor
}
if len(msg.ExtraIFaceBlacklist) > 0 {
inputConfig.ExtraIFaceBlackList = msg.ExtraIFaceBlacklist
s.latestConfigInput.ExtraIFaceBlackList = msg.ExtraIFaceBlacklist
}
Release 0.28.0 (#2092) * compile client under freebsd (#1620) Compile netbird client under freebsd and now support netstack and userspace modes. Refactoring linux specific code to share same code with FreeBSD, move to *_unix.go files. Not implemented yet: Kernel mode not supported DNS probably does not work yet Routing also probably does not work yet SSH support did not tested yet Lack of test environment for freebsd (dedicated VM for github runners under FreeBSD required) Lack of tests for freebsd specific code info reporting need to review and also implement, for example OS reported as GENERIC instead of FreeBSD (lack of FreeBSD icon in management interface) Lack of proper client setup under FreeBSD Lack of FreeBSD port/package * Add DNS routes (#1943) Given domains are resolved periodically and resolved IPs are replaced with the new ones. Unless the flag keep_route is set to true, then only new ones are added. This option is helpful if there are long-running connections that might still point to old IP addresses from changed DNS records. * Add process posture check (#1693) Introduces a process posture check to validate the existence and active status of specific binaries on peer systems. The check ensures that files are present at specified paths, and that corresponding processes are running. This check supports Linux, Windows, and macOS systems. Co-authored-by: Evgenii <mail@skillcoder.com> Co-authored-by: Pascal Fischer <pascal@netbird.io> Co-authored-by: Zoltan Papp <zoltan.pmail@gmail.com> Co-authored-by: Viktor Liu <17948409+lixmal@users.noreply.github.com> Co-authored-by: Bethuel Mmbaga <bethuelmbaga12@gmail.com>
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if msg.DnsRouteInterval != nil {
duration := msg.DnsRouteInterval.AsDuration()
inputConfig.DNSRouteInterval = &duration
s.latestConfigInput.DNSRouteInterval = &duration
}
s.mutex.Unlock()
if msg.OptionalPreSharedKey != nil {
inputConfig.PreSharedKey = msg.OptionalPreSharedKey
}
config, err := internal.UpdateOrCreateConfig(inputConfig)
if err != nil {
return nil, err
}
if msg.ManagementUrl == "" {
config, _ = internal.UpdateOldManagementURL(ctx, config, s.latestConfigInput.ConfigPath)
s.config = config
s.latestConfigInput.ManagementURL = config.ManagementURL.String()
}
s.mutex.Lock()
s.config = config
s.mutex.Unlock()
if _, err := s.loginAttempt(ctx, "", ""); err == nil {
state.Set(internal.StatusIdle)
return &proto.LoginResponse{}, nil
}
state.Set(internal.StatusConnecting)
if msg.SetupKey == "" {
oAuthFlow, err := auth.NewOAuthFlow(ctx, config, msg.IsLinuxDesktopClient)
if err != nil {
state.Set(internal.StatusLoginFailed)
return nil, err
}
if s.oauthAuthFlow.flow != nil && s.oauthAuthFlow.flow.GetClientID(ctx) == oAuthFlow.GetClientID(context.TODO()) {
if s.oauthAuthFlow.expiresAt.After(time.Now().Add(90 * time.Second)) {
log.Debugf("using previous oauth flow info")
return &proto.LoginResponse{
NeedsSSOLogin: true,
VerificationURI: s.oauthAuthFlow.info.VerificationURI,
VerificationURIComplete: s.oauthAuthFlow.info.VerificationURIComplete,
UserCode: s.oauthAuthFlow.info.UserCode,
}, nil
} else {
log.Warnf("canceling previous waiting execution")
if s.oauthAuthFlow.waitCancel != nil {
s.oauthAuthFlow.waitCancel()
}
}
}
authInfo, err := oAuthFlow.RequestAuthInfo(context.TODO())
if err != nil {
log.Errorf("getting a request OAuth flow failed: %v", err)
return nil, err
}
s.mutex.Lock()
s.oauthAuthFlow.flow = oAuthFlow
s.oauthAuthFlow.info = authInfo
s.oauthAuthFlow.expiresAt = time.Now().Add(time.Duration(authInfo.ExpiresIn) * time.Second)
s.mutex.Unlock()
state.Set(internal.StatusNeedsLogin)
return &proto.LoginResponse{
NeedsSSOLogin: true,
VerificationURI: authInfo.VerificationURI,
VerificationURIComplete: authInfo.VerificationURIComplete,
UserCode: authInfo.UserCode,
}, nil
}
if loginStatus, err := s.loginAttempt(ctx, msg.SetupKey, ""); err != nil {
state.Set(loginStatus)
return nil, err
}
return &proto.LoginResponse{}, nil
}
// WaitSSOLogin uses the userCode to validate the TokenInfo and
// waits for the user to continue with the login on a browser
func (s *Server) WaitSSOLogin(callerCtx context.Context, msg *proto.WaitSSOLoginRequest) (*proto.WaitSSOLoginResponse, error) {
s.mutex.Lock()
if s.actCancel != nil {
s.actCancel()
}
ctx, cancel := context.WithCancel(s.rootCtx)
md, ok := metadata.FromIncomingContext(callerCtx)
if ok {
ctx = metadata.NewOutgoingContext(ctx, md)
}
if msg.Hostname != "" {
// nolint
ctx = context.WithValue(ctx, system.DeviceNameCtxKey, msg.Hostname)
}
s.actCancel = cancel
s.mutex.Unlock()
if s.oauthAuthFlow.flow == nil {
return nil, gstatus.Errorf(codes.Internal, "oauth flow is not initialized")
}
state := internal.CtxGetState(ctx)
defer func() {
s, err := state.Status()
if err != nil || (s != internal.StatusNeedsLogin && s != internal.StatusLoginFailed) {
state.Set(internal.StatusIdle)
}
}()
state.Set(internal.StatusConnecting)
s.mutex.Lock()
flowInfo := s.oauthAuthFlow.info
s.mutex.Unlock()
if flowInfo.UserCode != msg.UserCode {
state.Set(internal.StatusLoginFailed)
return nil, gstatus.Errorf(codes.InvalidArgument, "sso user code is invalid")
}
if s.oauthAuthFlow.waitCancel != nil {
s.oauthAuthFlow.waitCancel()
}
waitTimeout := time.Until(s.oauthAuthFlow.expiresAt)
waitCTX, cancel := context.WithTimeout(ctx, waitTimeout)
defer cancel()
s.mutex.Lock()
s.oauthAuthFlow.waitCancel = cancel
s.mutex.Unlock()
tokenInfo, err := s.oauthAuthFlow.flow.WaitToken(waitCTX, flowInfo)
if err != nil {
if err == context.Canceled {
return nil, nil //nolint:nilnil
}
s.mutex.Lock()
s.oauthAuthFlow.expiresAt = time.Now()
s.mutex.Unlock()
state.Set(internal.StatusLoginFailed)
log.Errorf("waiting for browser login failed: %v", err)
return nil, err
}
s.mutex.Lock()
s.oauthAuthFlow.expiresAt = time.Now()
s.mutex.Unlock()
if loginStatus, err := s.loginAttempt(ctx, "", tokenInfo.GetTokenToUse()); err != nil {
state.Set(loginStatus)
return nil, err
}
return &proto.WaitSSOLoginResponse{}, nil
}
// Up starts engine work in the daemon.
func (s *Server) Up(callerCtx context.Context, _ *proto.UpRequest) (*proto.UpResponse, error) {
s.mutex.Lock()
defer s.mutex.Unlock()
if err := restoreResidualState(callerCtx); err != nil {
log.Warnf(errRestoreResidualState, err)
}
state := internal.CtxGetState(s.rootCtx)
// if current state contains any error, return it
// in all other cases we can continue execution only if status is idle and up command was
// not in the progress or already successfully established connection.
status, err := state.Status()
if err != nil {
return nil, err
}
if status != internal.StatusIdle {
return nil, fmt.Errorf("up already in progress: current status %s", status)
}
// it should be nil here, but .
if s.actCancel != nil {
s.actCancel()
}
ctx, cancel := context.WithCancel(s.rootCtx)
md, ok := metadata.FromIncomingContext(callerCtx)
if ok {
ctx = metadata.NewOutgoingContext(ctx, md)
}
s.actCancel = cancel
if s.config == nil {
return nil, fmt.Errorf("config is not defined, please call login command first")
}
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if s.statusRecorder == nil {
s.statusRecorder = peer.NewRecorder(s.config.ManagementURL.String())
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}
s.statusRecorder.UpdateManagementAddress(s.config.ManagementURL.String())
s.statusRecorder.UpdateRosenpass(s.config.RosenpassEnabled, s.config.RosenpassPermissive)
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runningChan := make(chan error)
go s.connectWithRetryRuns(ctx, s.config, s.statusRecorder, runningChan)
for {
select {
case err := <-runningChan:
if err != nil {
log.Debugf("waiting for engine to become ready failed: %s", err)
} else {
return &proto.UpResponse{}, nil
}
case <-callerCtx.Done():
log.Debug("context done, stopping the wait for engine to become ready")
return nil, callerCtx.Err()
}
}
}
// Down engine work in the daemon.
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func (s *Server) Down(ctx context.Context, _ *proto.DownRequest) (*proto.DownResponse, error) {
s.mutex.Lock()
defer s.mutex.Unlock()
s.oauthAuthFlow = oauthAuthFlow{}
if s.actCancel == nil {
return nil, fmt.Errorf("service is not up")
}
s.actCancel()
err := s.connectClient.Stop()
if err != nil {
log.Errorf("failed to shut down properly: %v", err)
return nil, err
}
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state := internal.CtxGetState(s.rootCtx)
state.Set(internal.StatusIdle)
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log.Infof("service is down")
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return &proto.DownResponse{}, nil
}
// Status returns the daemon status
func (s *Server) Status(
_ context.Context,
msg *proto.StatusRequest,
) (*proto.StatusResponse, error) {
s.mutex.Lock()
defer s.mutex.Unlock()
status, err := internal.CtxGetState(s.rootCtx).Status()
if err != nil {
return nil, err
}
statusResponse := proto.StatusResponse{Status: string(status), DaemonVersion: version.NetbirdVersion()}
if s.statusRecorder == nil {
s.statusRecorder = peer.NewRecorder(s.config.ManagementURL.String())
}
s.statusRecorder.UpdateManagementAddress(s.config.ManagementURL.String())
s.statusRecorder.UpdateRosenpass(s.config.RosenpassEnabled, s.config.RosenpassPermissive)
if msg.GetFullPeerStatus {
s.runProbes()
fullStatus := s.statusRecorder.GetFullStatus()
pbFullStatus := toProtoFullStatus(fullStatus)
statusResponse.FullStatus = pbFullStatus
}
return &statusResponse, nil
}
func (s *Server) runProbes() {
if time.Since(s.lastProbe) > probeThreshold {
managementHealthy := s.mgmProbe.Probe()
signalHealthy := s.signalProbe.Probe()
relayHealthy := s.relayProbe.Probe()
wgProbe := s.wgProbe.Probe()
// Update last time only if all probes were successful
if managementHealthy && signalHealthy && relayHealthy && wgProbe {
s.lastProbe = time.Now()
}
}
}
// GetConfig of the daemon.
func (s *Server) GetConfig(_ context.Context, _ *proto.GetConfigRequest) (*proto.GetConfigResponse, error) {
s.mutex.Lock()
defer s.mutex.Unlock()
managementURL := s.latestConfigInput.ManagementURL
adminURL := s.latestConfigInput.AdminURL
preSharedKey := ""
if s.config != nil {
if managementURL == "" && s.config.ManagementURL != nil {
managementURL = s.config.ManagementURL.String()
}
if s.config.AdminURL != nil {
adminURL = s.config.AdminURL.String()
}
preSharedKey = s.config.PreSharedKey
if preSharedKey != "" {
preSharedKey = "**********"
}
}
return &proto.GetConfigResponse{
ManagementUrl: managementURL,
ConfigFile: s.latestConfigInput.ConfigPath,
LogFile: s.logFile,
PreSharedKey: preSharedKey,
AdminURL: adminURL,
InterfaceName: s.config.WgIface,
WireguardPort: int64(s.config.WgPort),
DisableAutoConnect: s.config.DisableAutoConnect,
ServerSSHAllowed: *s.config.ServerSSHAllowed,
RosenpassEnabled: s.config.RosenpassEnabled,
RosenpassPermissive: s.config.RosenpassPermissive,
}, nil
}
func (s *Server) onSessionExpire() {
if runtime.GOOS != "windows" {
isUIActive := internal.CheckUIApp()
if !isUIActive {
if err := sendTerminalNotification(); err != nil {
log.Errorf("send session expire terminal notification: %v", err)
}
}
}
}
func toProtoFullStatus(fullStatus peer.FullStatus) *proto.FullStatus {
pbFullStatus := proto.FullStatus{
ManagementState: &proto.ManagementState{},
SignalState: &proto.SignalState{},
LocalPeerState: &proto.LocalPeerState{},
Peers: []*proto.PeerState{},
}
pbFullStatus.ManagementState.URL = fullStatus.ManagementState.URL
pbFullStatus.ManagementState.Connected = fullStatus.ManagementState.Connected
if err := fullStatus.ManagementState.Error; err != nil {
pbFullStatus.ManagementState.Error = err.Error()
}
pbFullStatus.SignalState.URL = fullStatus.SignalState.URL
pbFullStatus.SignalState.Connected = fullStatus.SignalState.Connected
if err := fullStatus.SignalState.Error; err != nil {
pbFullStatus.SignalState.Error = err.Error()
}
pbFullStatus.LocalPeerState.IP = fullStatus.LocalPeerState.IP
pbFullStatus.LocalPeerState.PubKey = fullStatus.LocalPeerState.PubKey
pbFullStatus.LocalPeerState.KernelInterface = fullStatus.LocalPeerState.KernelInterface
pbFullStatus.LocalPeerState.Fqdn = fullStatus.LocalPeerState.FQDN
pbFullStatus.LocalPeerState.RosenpassPermissive = fullStatus.RosenpassState.Permissive
pbFullStatus.LocalPeerState.RosenpassEnabled = fullStatus.RosenpassState.Enabled
pbFullStatus.LocalPeerState.Routes = maps.Keys(fullStatus.LocalPeerState.Routes)
for _, peerState := range fullStatus.Peers {
pbPeerState := &proto.PeerState{
IP: peerState.IP,
PubKey: peerState.PubKey,
ConnStatus: peerState.ConnStatus.String(),
ConnStatusUpdate: timestamppb.New(peerState.ConnStatusUpdate),
Relayed: peerState.Relayed,
LocalIceCandidateType: peerState.LocalIceCandidateType,
RemoteIceCandidateType: peerState.RemoteIceCandidateType,
LocalIceCandidateEndpoint: peerState.LocalIceCandidateEndpoint,
RemoteIceCandidateEndpoint: peerState.RemoteIceCandidateEndpoint,
RelayAddress: peerState.RelayServerAddress,
Fqdn: peerState.FQDN,
LastWireguardHandshake: timestamppb.New(peerState.LastWireguardHandshake),
BytesRx: peerState.BytesRx,
BytesTx: peerState.BytesTx,
RosenpassEnabled: peerState.RosenpassEnabled,
Routes: maps.Keys(peerState.GetRoutes()),
Latency: durationpb.New(peerState.Latency),
}
pbFullStatus.Peers = append(pbFullStatus.Peers, pbPeerState)
}
for _, relayState := range fullStatus.Relays {
pbRelayState := &proto.RelayState{
URI: relayState.URI,
Available: relayState.Err == nil,
}
if err := relayState.Err; err != nil {
pbRelayState.Error = err.Error()
}
pbFullStatus.Relays = append(pbFullStatus.Relays, pbRelayState)
}
for _, dnsState := range fullStatus.NSGroupStates {
var err string
if dnsState.Error != nil {
err = dnsState.Error.Error()
}
pbDnsState := &proto.NSGroupState{
Servers: dnsState.Servers,
Domains: dnsState.Domains,
Enabled: dnsState.Enabled,
Error: err,
}
pbFullStatus.DnsServers = append(pbFullStatus.DnsServers, pbDnsState)
}
return &pbFullStatus
}
// sendTerminalNotification sends a terminal notification message
// to inform the user that the NetBird connection session has expired.
func sendTerminalNotification() error {
message := "NetBird connection session expired\n\nPlease re-authenticate to connect to the network."
echoCmd := exec.Command("echo", message)
wallCmd := exec.Command("sudo", "wall")
echoCmdStdout, err := echoCmd.StdoutPipe()
if err != nil {
return err
}
wallCmd.Stdin = echoCmdStdout
if err := echoCmd.Start(); err != nil {
return err
}
if err := wallCmd.Start(); err != nil {
return err
}
if err := echoCmd.Wait(); err != nil {
return err
}
return wallCmd.Wait()
}