Files
3x-ui/internal/web/job/node_traffic_sync_job.go
T
MHSanaei 1c0b76c27a Use efficient APIs and simplify loops
Minor refactors across the codebase to improve readability and use more efficient APIs: replace fmt.Sprintf+base64 encoding with fmt.Appendf when building Shadowsocks userInfo; compute elapsed using max(now-prev.at, window) to simplify logic; use strings.SplitSeq for splitting in two places; simplify test and goroutine loops to range-based iterations and use errgroup's Go helper; and align/clean up struct field formatting and test map literals. Mostly stylistic/efficiency changes with no intended behavior changes.
2026-06-23 14:12:28 +02:00

410 lines
13 KiB
Go

package job
import (
"context"
"strings"
"sync"
"time"
"github.com/mhsanaei/3x-ui/v3/internal/database/model"
"github.com/mhsanaei/3x-ui/v3/internal/logger"
"github.com/mhsanaei/3x-ui/v3/internal/util/common"
"github.com/mhsanaei/3x-ui/v3/internal/web/runtime"
"github.com/mhsanaei/3x-ui/v3/internal/web/service"
"github.com/mhsanaei/3x-ui/v3/internal/web/websocket"
"github.com/mhsanaei/3x-ui/v3/internal/xray"
)
const (
nodeTrafficSyncConcurrency = 8
nodeTrafficSyncRequestTimeout = 4 * time.Second
nodeReconcileTimeout = 30 * time.Second
nodeClientIpSyncInterval = 10 * time.Second
nodeClientIpSyncTimeout = 6 * time.Second
nodeGlobalPushInterval = 30 * time.Second
// nodeInboundSpeedWindowMs is the poll window node-inbound speed deltas are
// normalized to; it MUST match the dashboard's TRAFFIC_POLL_INTERVAL_S (5s),
// the fixed divisor the frontend applies to turn a delta into a rate.
nodeInboundSpeedWindowMs int64 = 5000
)
// inboundSample is a node inbound's last-seen cumulative up/down and the time
// (unix millis) its counter last changed, used to derive a normalized speed.
type inboundSample struct {
up, down, at int64
}
type NodeTrafficSyncJob struct {
nodeService service.NodeService
inboundService service.InboundService
settingService service.SettingService
xrayService service.XrayService
running sync.Mutex
structural atomicBool
ipSyncMu sync.Mutex
lastIpSync int64
globalPushMu sync.Mutex
lastGlobalPush int64
// noGuidIpEndpoint tracks nodes (by id) whose client-IP attribution endpoint
// returned 404, so an old-build node is noted once instead of every cycle.
noGuidIpEndpoint sync.Map
// prevInboundTotals holds the previous poll's cumulative up/down (and the time
// the counter last changed) per node inbound tag, so the next poll can derive
// a per-inbound speed delta — node inbounds have no local Xray poll. Touched
// only from Run (serialized).
prevInboundTotals map[string]inboundSample
}
type atomicBool struct {
mu sync.Mutex
v bool
}
func (a *atomicBool) set() {
a.mu.Lock()
a.v = true
a.mu.Unlock()
}
func (a *atomicBool) takeAndReset() bool {
a.mu.Lock()
v := a.v
a.v = false
a.mu.Unlock()
return v
}
func NewNodeTrafficSyncJob() *NodeTrafficSyncJob {
return &NodeTrafficSyncJob{}
}
func (j *NodeTrafficSyncJob) Run() {
if !j.running.TryLock() {
return
}
defer j.running.Unlock()
mgr := runtime.GetManager()
if mgr == nil {
return
}
nodes, err := j.nodeService.GetAll()
if err != nil {
logger.Warning("node traffic sync: load nodes failed:", err)
return
}
if len(nodes) == 0 {
return
}
// Decide once per tick whether this run also syncs client IPs, and stamp the
// clock before the loop so two back-to-back 5s ticks can't both qualify.
doIpSync := false
j.ipSyncMu.Lock()
if now := time.Now().Unix(); now-j.lastIpSync >= int64(nodeClientIpSyncInterval/time.Second) {
doIpSync = true
j.lastIpSync = now
}
j.ipSyncMu.Unlock()
sem := make(chan struct{}, nodeTrafficSyncConcurrency)
var wg sync.WaitGroup
for _, n := range nodes {
if !n.Enable || n.Status != "online" {
continue
}
wg.Add(1)
sem <- struct{}{}
n := n
common.GoRecover("node-traffic-sync:"+n.Name, func() {
defer wg.Done()
defer func() { <-sem }()
j.syncOne(mgr, n, doIpSync)
})
}
wg.Wait()
_, clientsDisabled, err := j.inboundService.AddTraffic(nil, nil)
if err != nil {
logger.Warning("node traffic sync: depletion check failed:", err)
}
if clientsDisabled {
if restartOnDisable, settingErr := j.settingService.GetRestartXrayOnClientDisable(); settingErr == nil && restartOnDisable {
if err := j.xrayService.RestartXray(true); err != nil {
logger.Warning("node traffic sync: restart xray after disabling clients failed:", err)
j.xrayService.SetToNeedRestart()
}
} else if settingErr != nil {
logger.Warning("node traffic sync: get RestartXrayOnClientDisable failed:", settingErr)
}
j.structural.set()
}
j.maybePushGlobals(mgr, nodes)
lastOnline, err := j.inboundService.GetClientsLastOnline()
if err != nil {
logger.Warning("node traffic sync: get last-online failed:", err)
}
if lastOnline == nil {
lastOnline = map[string]int64{}
}
// Prune stale local-online entries (no local active emails or inbound tags
// to add here — only the local xray poll feeds those) so a stopped local
// xray's clients and inbounds still age out between traffic polls.
j.inboundService.RefreshLocalOnlineClients(nil, nil)
// Derive per-node-inbound speed every tick (keeps the baseline fresh even
// with no dashboard open); only broadcast it when someone is watching.
inboundSpeed := j.nodeInboundSpeed()
if !websocket.HasClients() {
return
}
online := j.inboundService.GetOnlineClients()
if online == nil {
online = []string{}
}
trafficPayload := map[string]any{
"onlineClients": online,
"onlineByGuid": j.inboundService.GetOnlineClientsByGuid(),
"activeInbounds": j.inboundService.GetActiveInboundsByGuid(),
"lastOnlineMap": lastOnline,
}
// Always send the key so the dashboard clears node inbounds that went idle
// this tick. A nil result (query error) marshals to null and is skipped
// client-side, leaving the last shown value untouched; an empty (non-nil)
// slice marshals to [] and clears stale speeds.
trafficPayload["nodeTraffics"] = inboundSpeed
websocket.BroadcastTraffic(trafficPayload)
clientStats := map[string]any{}
if stats, err := j.inboundService.GetAllClientTraffics(); err != nil {
logger.Warning("node traffic sync: get all client traffics for websocket failed:", err)
} else if len(stats) > 0 {
clientStats["clients"] = stats
}
if summary, err := j.inboundService.GetInboundsTrafficSummary(); err != nil {
logger.Warning("node traffic sync: get inbounds summary for websocket failed:", err)
} else if len(summary) > 0 {
clientStats["inbounds"] = summary
}
if len(clientStats) > 0 {
websocket.BroadcastClientStats(clientStats)
}
if j.structural.takeAndReset() {
websocket.BroadcastInvalidate(websocket.MessageTypeInbounds)
websocket.BroadcastInvalidate(websocket.MessageTypeClients)
}
}
// nodeInboundSpeed derives a per-node-inbound speed delta by diffing the current
// cumulative up/down against the previous poll's, keyed by the central tag the
// dashboard matches. The node's counter keeps climbing while the master can't
// reach it, so the first delta after a gap (node outage, skipped poll, slow
// node) spans more than one poll window; it is normalized to the fixed
// nodeInboundSpeedWindowMs using the real elapsed time so the dashboard's fixed
// divisor yields the true average rate over the gap instead of an impossible
// one-tick spike. The change timestamp only advances when the value actually
// moves, so an idle stretch is averaged correctly when traffic resumes. A reset
// rebaselines to the lower value; a first-seen tag yields no delta until the
// next poll.
func (j *NodeTrafficSyncJob) nodeInboundSpeed() []*xray.Traffic {
totals, err := j.inboundService.GetNodeInboundTrafficTotals()
if err != nil {
return nil
}
now := time.Now().UnixMilli()
deltas := make([]*xray.Traffic, 0, len(totals))
next := make(map[string]inboundSample, len(totals))
for tag, cur := range totals {
prev, ok := j.prevInboundTotals[tag]
if !ok {
next[tag] = inboundSample{up: cur[0], down: cur[1], at: now}
continue
}
dUp := cur[0] - prev.up
dDown := cur[1] - prev.down
if dUp <= 0 && dDown <= 0 {
// No movement, or a counter reset: hold the change timestamp so a
// later jump is averaged over the real elapsed window, not shown as a
// spike. Adopt the lower value on a reset.
if cur[0] < prev.up || cur[1] < prev.down {
next[tag] = inboundSample{up: cur[0], down: cur[1], at: now}
} else {
next[tag] = prev
}
continue
}
if dUp < 0 {
dUp = 0
}
if dDown < 0 {
dDown = 0
}
elapsed := max(now-prev.at, nodeInboundSpeedWindowMs)
up := dUp * nodeInboundSpeedWindowMs / elapsed
down := dDown * nodeInboundSpeedWindowMs / elapsed
if up > 0 || down > 0 {
deltas = append(deltas, &xray.Traffic{Tag: tag, IsInbound: true, Up: up, Down: down})
}
next[tag] = inboundSample{up: cur[0], down: cur[1], at: now}
}
j.prevInboundTotals = next
return deltas
}
// maybePushGlobals broadcasts this panel's aggregated per-client usage to its
// online nodes so each node can display the client's cross-panel total and
// enforce its quota locally (see InboundService.AcceptGlobalTraffic). Scoped
// per node to the clients that node actually hosts, and throttled — the
// aggregates only need to reach nodes on a human timescale, not every poll.
func (j *NodeTrafficSyncJob) maybePushGlobals(mgr *runtime.Manager, nodes []*model.Node) {
j.globalPushMu.Lock()
now := time.Now().Unix()
if now-j.lastGlobalPush < int64(nodeGlobalPushInterval/time.Second) {
j.globalPushMu.Unlock()
return
}
j.lastGlobalPush = now
j.globalPushMu.Unlock()
masterGuid, err := j.settingService.GetPanelGuid()
if err != nil || masterGuid == "" {
return
}
sem := make(chan struct{}, nodeTrafficSyncConcurrency)
var wg sync.WaitGroup
for _, n := range nodes {
if !n.Enable || n.Status != "online" {
continue
}
remote, err := mgr.RemoteFor(n)
if err != nil {
continue
}
traffics, err := j.inboundService.GetNodeClientTraffics(n.Id)
if err != nil {
logger.Warningf("node traffic sync: load globals for %s failed: %v", n.Name, err)
continue
}
if len(traffics) == 0 {
continue
}
wg.Add(1)
sem <- struct{}{}
n, remote, traffics := n, remote, traffics
common.GoRecover("node-global-push:"+n.Name, func() {
defer wg.Done()
defer func() { <-sem }()
ctx, cancel := context.WithTimeout(context.Background(), nodeTrafficSyncRequestTimeout)
defer cancel()
if err := remote.PushGlobalClientTraffics(ctx, masterGuid, traffics); err != nil {
// An old-build node without the endpoint answers 404 — not worth a
// warning every cycle.
if strings.Contains(err.Error(), "HTTP 404") {
logger.Debugf("node traffic sync: node %s has no global-traffic endpoint (old build)", n.Name)
} else {
logger.Warningf("node traffic sync: push globals to %s failed: %v", n.Name, err)
}
}
})
}
wg.Wait()
}
func (j *NodeTrafficSyncJob) syncOne(mgr *runtime.Manager, n *model.Node, doIpSync bool) {
rt, err := mgr.RemoteFor(n)
if err != nil {
logger.Warningf("node traffic sync: remote lookup failed for %s: %v", n.Name, err)
return
}
if n.ConfigDirty {
reconcileCtx, reconcileCancel := context.WithTimeout(context.Background(), nodeReconcileTimeout)
reconcileErr := j.inboundService.ReconcileNode(reconcileCtx, rt, n)
reconcileCancel()
if reconcileErr != nil {
logger.Warningf("node traffic sync: reconcile for %s failed: %v", n.Name, reconcileErr)
return
}
if clearErr := j.nodeService.ClearNodeDirty(n.Id, n.ConfigDirtyAt); clearErr != nil {
logger.Warningf("node traffic sync: clear dirty for %s failed: %v", n.Name, clearErr)
}
j.structural.set()
}
ctx, cancel := context.WithTimeout(context.Background(), nodeTrafficSyncRequestTimeout)
defer cancel()
snap, err := rt.FetchTrafficSnapshot(ctx)
if err != nil {
logger.Warningf("node traffic sync: fetch from %s failed: %v", n.Name, err)
j.inboundService.ClearNodeOnlineClients(n.Id)
return
}
service.FilterNodeSnapshot(n, snap)
_, _, dirty, _, _ := j.nodeService.NodeSyncState(n.Id)
changed, err := j.inboundService.SetRemoteTraffic(n.Id, snap, dirty)
if err != nil {
logger.Warningf("node traffic sync: merge for %s failed: %v", n.Name, err)
return
}
if changed {
j.structural.set()
}
if !doIpSync {
return
}
ipCtx, ipCancel := context.WithTimeout(context.Background(), nodeClientIpSyncTimeout)
defer ipCancel()
nodeIps, err := rt.FetchAllClientIps(ipCtx)
if err == nil && len(nodeIps) > 0 {
if err := j.inboundService.MergeInboundClientIps(nodeIps); err != nil {
logger.Warningf("node traffic sync: merge client ips from %s failed: %v", n.Name, err)
}
} else if err != nil {
logger.Warningf("node traffic sync: fetch client ips from %s failed: %v", n.Name, err)
}
masterIps, err := j.inboundService.GetAllInboundClientIps()
if err != nil {
logger.Warningf("node traffic sync: load client ips for push to %s failed: %v", n.Name, err)
return
}
if len(masterIps) > 0 {
if err := rt.PushAllClientIps(ipCtx, masterIps); err != nil {
logger.Warningf("node traffic sync: push client ips to %s failed: %v", n.Name, err)
}
}
// Per-node IP attribution: pull the node's guid-keyed subtree (its own
// observations plus any descendants) so the master can tell which node each
// IP is on. Old nodes without the endpoint return HTTP 404 every cycle — note
// it once per node (re-armed on recovery) instead of flooding the log.
if guidTrees, err := rt.FetchClientIpsByGuid(ipCtx); err != nil {
if strings.Contains(err.Error(), "HTTP 404") {
if _, seen := j.noGuidIpEndpoint.LoadOrStore(n.Id, true); !seen {
logger.Debugf("node traffic sync: node %s has no client-IP attribution endpoint (old build)", n.Name)
}
} else {
logger.Debugf("node traffic sync: fetch client ip attribution from %s failed: %v", n.Name, err)
}
} else {
j.noGuidIpEndpoint.Delete(n.Id)
if len(guidTrees) > 0 {
if err := j.inboundService.MergeClientIpsByGuid(n, guidTrees); err != nil {
logger.Warningf("node traffic sync: merge client ip attribution from %s failed: %v", n.Name, err)
}
}
}
}