netbird/client/internal/routemanager/client.go

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package routemanager
import (
"context"
"fmt"
"net"
"net/netip"
"time"
log "github.com/sirupsen/logrus"
"github.com/netbirdio/netbird/client/internal/peer"
"github.com/netbirdio/netbird/iface"
"github.com/netbirdio/netbird/route"
)
const minRangeBits = 7
type routerPeerStatus struct {
connected bool
relayed bool
direct bool
latency time.Duration
}
type routesUpdate struct {
updateSerial uint64
routes []*route.Route
}
type clientNetwork struct {
ctx context.Context
stop context.CancelFunc
statusRecorder *peer.Status
wgInterface *iface.WGIface
routes map[string]*route.Route
routeUpdate chan routesUpdate
peerStateUpdate chan struct{}
routePeersNotifiers map[string]chan struct{}
chosenRoute *route.Route
network netip.Prefix
updateSerial uint64
}
func newClientNetworkWatcher(ctx context.Context, wgInterface *iface.WGIface, statusRecorder *peer.Status, network netip.Prefix) *clientNetwork {
ctx, cancel := context.WithCancel(ctx)
client := &clientNetwork{
ctx: ctx,
stop: cancel,
statusRecorder: statusRecorder,
wgInterface: wgInterface,
routes: make(map[string]*route.Route),
routePeersNotifiers: make(map[string]chan struct{}),
routeUpdate: make(chan routesUpdate),
peerStateUpdate: make(chan struct{}),
network: network,
}
return client
}
func (c *clientNetwork) getRouterPeerStatuses() map[string]routerPeerStatus {
routePeerStatuses := make(map[string]routerPeerStatus)
for _, r := range c.routes {
peerStatus, err := c.statusRecorder.GetPeer(r.Peer)
if err != nil {
log.Debugf("couldn't fetch peer state: %v", err)
continue
}
routePeerStatuses[r.ID] = routerPeerStatus{
connected: peerStatus.ConnStatus == peer.StatusConnected,
relayed: peerStatus.Relayed,
direct: peerStatus.Direct,
latency: peerStatus.Latency,
}
}
return routePeerStatuses
}
// getBestRouteFromStatuses determines the most optimal route from the available routes
// within a clientNetwork, taking into account peer connection status, route metrics, and
// preference for non-relayed and direct connections.
//
// It follows these prioritization rules:
// * Connected peers: Only routes with connected peers are considered.
// * Metric: Routes with lower metrics (better) are prioritized.
// * Non-relayed: Routes without relays are preferred.
// * Direct connections: Routes with direct peer connections are favored.
// * Stability: In case of equal scores, the currently active route (if any) is maintained.
// * Latency: Routes with lower latency are prioritized.
//
// It returns the ID of the selected optimal route.
func (c *clientNetwork) getBestRouteFromStatuses(routePeerStatuses map[string]routerPeerStatus) string {
chosen := ""
chosenScore := float64(0)
currScore := float64(0)
currID := ""
if c.chosenRoute != nil {
currID = c.chosenRoute.ID
}
for _, r := range c.routes {
tempScore := float64(0)
peerStatus, found := routePeerStatuses[r.ID]
if !found || !peerStatus.connected {
continue
}
if r.Metric < route.MaxMetric {
metricDiff := route.MaxMetric - r.Metric
tempScore = float64(metricDiff) * 10
}
// in some temporal cases, latency can be 0, so we set it to 1s to not block but try to avoid this route
latency := time.Second
if peerStatus.latency != 0 {
latency = peerStatus.latency
} else {
log.Warnf("peer %s has 0 latency", r.Peer)
}
tempScore += 1 - latency.Seconds()
if !peerStatus.relayed {
tempScore++
}
if peerStatus.direct {
tempScore++
}
if tempScore > chosenScore || (tempScore == chosenScore && chosen == "") {
chosen = r.ID
chosenScore = tempScore
}
if chosen == "" && currID == "" {
chosen = r.ID
chosenScore = tempScore
}
if r.ID == currID {
currScore = tempScore
}
}
switch {
case chosen == "":
var peers []string
for _, r := range c.routes {
peers = append(peers, r.Peer)
}
log.Warnf("the network %s has not been assigned a routing peer as no peers from the list %s are currently connected", c.network, peers)
case chosen != currID:
if currScore != 0 && currScore < chosenScore+0.1 {
return currID
} else {
log.Infof("new chosen route is %s with peer %s with score %f for network %s", chosen, c.routes[chosen].Peer, chosenScore, c.network)
}
}
return chosen
}
func (c *clientNetwork) watchPeerStatusChanges(ctx context.Context, peerKey string, peerStateUpdate chan struct{}, closer chan struct{}) {
for {
select {
case <-ctx.Done():
return
case <-closer:
return
case <-c.statusRecorder.GetPeerStateChangeNotifier(peerKey):
state, err := c.statusRecorder.GetPeer(peerKey)
if err != nil || state.ConnStatus == peer.StatusConnecting {
continue
}
peerStateUpdate <- struct{}{}
log.Debugf("triggered route state update for Peer %s, state: %s", peerKey, state.ConnStatus)
}
}
}
func (c *clientNetwork) startPeersStatusChangeWatcher() {
for _, r := range c.routes {
_, found := c.routePeersNotifiers[r.Peer]
if !found {
c.routePeersNotifiers[r.Peer] = make(chan struct{})
go c.watchPeerStatusChanges(c.ctx, r.Peer, c.peerStateUpdate, c.routePeersNotifiers[r.Peer])
}
}
}
func (c *clientNetwork) removeRouteFromWireguardPeer(peerKey string) error {
state, err := c.statusRecorder.GetPeer(peerKey)
if err != nil {
return fmt.Errorf("get peer state: %v", err)
}
state.DeleteRoute(c.network.String())
if err := c.statusRecorder.UpdatePeerState(state); err != nil {
log.Warnf("Failed to update peer state: %v", err)
}
if state.ConnStatus != peer.StatusConnected {
return nil
}
err = c.wgInterface.RemoveAllowedIP(peerKey, c.network.String())
if err != nil {
return fmt.Errorf("remove allowed IP %s removed for peer %s, err: %v",
c.network, c.chosenRoute.Peer, err)
}
return nil
}
func (c *clientNetwork) removeRouteFromPeerAndSystem() error {
if c.chosenRoute != nil {
if err := removeVPNRoute(c.network, c.getAsInterface()); err != nil {
return fmt.Errorf("remove route %s from system, err: %v", c.network, err)
}
if err := c.removeRouteFromWireguardPeer(c.chosenRoute.Peer); err != nil {
return fmt.Errorf("remove route: %v", err)
}
}
return nil
}
func (c *clientNetwork) recalculateRouteAndUpdatePeerAndSystem() error {
routerPeerStatuses := c.getRouterPeerStatuses()
chosen := c.getBestRouteFromStatuses(routerPeerStatuses)
// If no route is chosen, remove the route from the peer and system
if chosen == "" {
if err := c.removeRouteFromPeerAndSystem(); err != nil {
return fmt.Errorf("remove route from peer and system: %v", err)
}
c.chosenRoute = nil
return nil
}
// If the chosen route is the same as the current route, do nothing
if c.chosenRoute != nil && c.chosenRoute.ID == chosen {
if c.chosenRoute.IsEqual(c.routes[chosen]) {
return nil
}
}
if c.chosenRoute != nil {
// If a previous route exists, remove it from the peer
if err := c.removeRouteFromWireguardPeer(c.chosenRoute.Peer); err != nil {
return fmt.Errorf("remove route from peer: %v", err)
}
} else {
// otherwise add the route to the system
if err := addVPNRoute(c.network, c.getAsInterface()); err != nil {
return fmt.Errorf("route %s couldn't be added for peer %s, err: %v",
c.network.String(), c.wgInterface.Address().IP.String(), err)
}
}
c.chosenRoute = c.routes[chosen]
state, err := c.statusRecorder.GetPeer(c.chosenRoute.Peer)
if err != nil {
log.Errorf("Failed to get peer state: %v", err)
} else {
state.AddRoute(c.network.String())
if err := c.statusRecorder.UpdatePeerState(state); err != nil {
log.Warnf("Failed to update peer state: %v", err)
}
}
if err := c.wgInterface.AddAllowedIP(c.chosenRoute.Peer, c.network.String()); err != nil {
log.Errorf("couldn't add allowed IP %s added for peer %s, err: %v",
c.network, c.chosenRoute.Peer, err)
}
return nil
}
func (c *clientNetwork) sendUpdateToClientNetworkWatcher(update routesUpdate) {
go func() {
c.routeUpdate <- update
}()
}
func (c *clientNetwork) handleUpdate(update routesUpdate) {
updateMap := make(map[string]*route.Route)
for _, r := range update.routes {
updateMap[r.ID] = r
}
for id, r := range c.routes {
_, found := updateMap[id]
if !found {
close(c.routePeersNotifiers[r.Peer])
delete(c.routePeersNotifiers, r.Peer)
}
}
c.routes = updateMap
}
// peersStateAndUpdateWatcher is the main point of reacting on client network routing events.
// All the processing related to the client network should be done here. Thread-safe.
func (c *clientNetwork) peersStateAndUpdateWatcher() {
for {
select {
case <-c.ctx.Done():
log.Debugf("stopping watcher for network %s", c.network)
err := c.removeRouteFromPeerAndSystem()
if err != nil {
log.Errorf("Couldn't remove route from peer and system for network %s: %v", c.network, err)
}
return
case <-c.peerStateUpdate:
err := c.recalculateRouteAndUpdatePeerAndSystem()
if err != nil {
log.Errorf("Couldn't recalculate route and update peer and system: %v", err)
}
case update := <-c.routeUpdate:
if update.updateSerial < c.updateSerial {
log.Warnf("Received a routes update with smaller serial number, ignoring it")
continue
}
log.Debugf("Received a new client network route update for %s", c.network)
c.handleUpdate(update)
c.updateSerial = update.updateSerial
err := c.recalculateRouteAndUpdatePeerAndSystem()
if err != nil {
log.Errorf("Couldn't recalculate route and update peer and system for network %s: %v", c.network, err)
}
c.startPeersStatusChangeWatcher()
}
}
}
func (c *clientNetwork) getAsInterface() *net.Interface {
intf, err := net.InterfaceByName(c.wgInterface.Name())
if err != nil {
log.Warnf("Couldn't get interface by name %s: %v", c.wgInterface.Name(), err)
intf = &net.Interface{
Name: c.wgInterface.Name(),
}
}
return intf
}