rmm2/agent-linux/ws/handler.go
cynfo3000 291d2e3c17 feat: VM/CT Start/Stop im Frontend + Agent proxmox_action Handler
- Agent: neuer 'proxmox_action' Command (start/stop/shutdown fuer VMs und LXC)
- Backend: POST /api/v1/agents/{id}/proxmox/action Endpoint
- Frontend: Start/Stop/Shutdown Buttons in VMs- und Container-Tab
  - Play (gruen) = starten (nur wenn gestoppt)
  - Power (gelb) = Graceful Shutdown (nur VMs, nur wenn running)
  - Stop (rot) = Hard Stop (wenn running)
- api/client.js: proxmoxAction() Methode
2026-03-09 20:22:45 +01:00

548 lines
15 KiB
Go

package ws
import (
"context"
"crypto/sha256"
"encoding/base64"
"encoding/hex"
"fmt"
"log"
"os"
"os/exec"
"strconv"
"strings"
"time"
)
type Handler struct {
client *Client
}
func NewHandler(client *Client) *Handler {
return &Handler{client: client}
}
func (h *Handler) HandleCommand(msg Message) {
log.Printf("Command erhalten: %s (ID: %s)", msg.Command, msg.ID)
var response Message
response.Type = "response"
response.ID = msg.ID
switch msg.Command {
case "exec":
response = h.handleExec(msg)
case "reboot":
response = h.handleReboot(msg)
case "tunnel_connect":
response = h.handleTunnelConnect(msg)
case "tunnel_disconnect":
h.handleTunnelDisconnect(msg)
return
case "agent_update":
response = h.handleAgentUpdate(msg)
case "update_check":
response = h.handleUpdateCheck(msg)
case "update":
response = h.handleUpdate(msg)
case "zpoolscrub":
response = h.handleZpoolScrub(msg)
case "proxmox_action":
response = h.handleProxmoxAction(msg)
case "pty_start":
response = h.handlePTYStart(msg)
case "pty_stop":
h.handlePTYStop(msg)
return
case "pty_resize":
h.handlePTYResize(msg)
return
default:
response.Status = "error"
response.Error = fmt.Sprintf("Unbekanntes Command: %s", msg.Command)
}
if err := h.client.SendMessage(response); err != nil {
log.Printf("Response senden fehlgeschlagen: %v", err)
}
}
// handleExec fuehrt einen beliebigen Befehl aus
func (h *Handler) handleExec(msg Message) Message {
response := Message{Type: "response", ID: msg.ID}
command, ok := msg.Params["command"].(string)
if !ok || command == "" {
response.Status = "error"
response.Error = "Parameter 'command' erforderlich"
return response
}
timeoutSec := 30
if t, ok := msg.Params["timeout"]; ok {
if ts, ok := t.(float64); ok {
timeoutSec = int(ts)
} else if ts, ok := t.(string); ok {
if parsed, err := strconv.Atoi(ts); err == nil {
timeoutSec = parsed
}
}
}
output, err := h.runCommand(command, timeoutSec)
if err != nil {
response.Status = "error"
response.Error = err.Error()
response.Data = map[string]interface{}{"output": output}
} else {
response.Status = "ok"
response.Data = map[string]interface{}{"output": output}
}
return response
}
// handleReboot fuehrt einen Reboot durch
func (h *Handler) handleReboot(msg Message) Message {
response := Message{Type: "response", ID: msg.ID}
delaySec := 5
if d, ok := msg.Params["delay"].(float64); ok && d > 0 {
delaySec = int(d)
}
log.Printf("Reboot angefordert (Verzoegerung: %ds)", delaySec)
response.Status = "ok"
response.Data = map[string]interface{}{
"message": fmt.Sprintf("Reboot in %d Sekunden", delaySec),
}
go func() {
time.Sleep(time.Duration(delaySec) * time.Second)
log.Println("Reboot wird ausgefuehrt...")
exec.Command("/sbin/shutdown", "-r", "now").Run()
}()
return response
}
// handleAgentUpdate aktualisiert den Agent
func (h *Handler) handleAgentUpdate(msg Message) Message {
response := Message{Type: "response", ID: msg.ID}
// Binary kommt als Base64 im Data-Feld
data, ok := msg.Data.(map[string]interface{})
if !ok {
response.Status = "error"
response.Error = "Ungueltige Daten"
return response
}
binaryB64, _ := data["binary"].(string)
expectedHash, _ := data["hash"].(string)
newVersion, _ := data["version"].(string)
if binaryB64 == "" || expectedHash == "" {
response.Status = "error"
response.Error = "Binary oder Hash fehlt"
return response
}
log.Printf("Agent-Update empfangen: Version %s, Hash %s", newVersion, expectedHash[:16])
// Base64 dekodieren
binary, err := base64.StdEncoding.DecodeString(binaryB64)
if err != nil {
response.Status = "error"
response.Error = fmt.Sprintf("Base64-Dekodierung fehlgeschlagen: %v", err)
return response
}
// Hash pruefen
hash := sha256.Sum256(binary)
actualHash := hex.EncodeToString(hash[:])
if actualHash != expectedHash {
response.Status = "error"
response.Error = fmt.Sprintf("Hash-Mismatch: erwartet %s, bekommen %s", expectedHash[:16], actualHash[:16])
return response
}
// Aktuelles Binary finden
binaryPath := "/usr/local/bin/rmm-agent-linux"
if _, err := os.Stat(binaryPath); os.IsNotExist(err) {
// Fallback: eigener Pfad
binaryPath, _ = os.Executable()
}
// Backup vom alten Binary
backupPath := binaryPath + ".old"
if err := os.Rename(binaryPath, backupPath); err != nil {
response.Status = "error"
response.Error = fmt.Sprintf("Backup fehlgeschlagen: %v", err)
return response
}
// Neues Binary schreiben
if err := os.WriteFile(binaryPath, binary, 0755); err != nil {
// Rollback
os.Rename(backupPath, binaryPath)
response.Status = "error"
response.Error = fmt.Sprintf("Binary schreiben fehlgeschlagen: %v", err)
return response
}
log.Printf("Neues Binary geschrieben: %s (%d bytes)", binaryPath, len(binary))
response.Status = "ok"
response.Data = map[string]interface{}{
"message": fmt.Sprintf("Update auf %s erfolgreich, Neustart...", newVersion),
"old_version": data["old_version"],
"new_version": newVersion,
}
// Response senden, dann Neustart
go func() {
time.Sleep(2 * time.Second)
log.Printf("Agent-Neustart nach Update auf %s", newVersion)
// Versuche systemd service restart, fallback zu kill + restart
if err := exec.Command("systemctl", "restart", "rmm-agent-linux").Run(); err != nil {
log.Printf("systemctl restart fehlgeschlagen, versuche manuelle Wiederbelebung: %v", err)
// Als letzter Ausweg: sich selbst ersetzen
os.Exit(0)
}
}()
return response
}
// --- PTY Handlers ---
func (h *Handler) handlePTYStart(msg Message) Message {
response := Message{Type: "response", ID: msg.ID}
sessionID, _ := msg.Params["session_id"].(string)
if sessionID == "" {
response.Status = "error"
response.Error = "session_id erforderlich"
return response
}
cols := uint16(80)
rows := uint16(24)
if c, ok := msg.Params["cols"].(float64); ok && c > 0 {
cols = uint16(c)
}
if r, ok := msg.Params["rows"].(float64); ok && r > 0 {
rows = uint16(r)
}
if err := h.client.ptyManager.StartPTY(sessionID, cols, rows); err != nil {
response.Status = "error"
response.Error = err.Error()
return response
}
response.Status = "ok"
response.Data = map[string]interface{}{"session_id": sessionID}
return response
}
func (h *Handler) handlePTYStop(msg Message) {
sessionID, _ := msg.Params["session_id"].(string)
if sessionID != "" {
h.client.ptyManager.StopPTY(sessionID)
}
}
func (h *Handler) handlePTYResize(msg Message) {
sessionID, _ := msg.Params["session_id"].(string)
cols := uint16(80)
rows := uint16(24)
if c, ok := msg.Params["cols"].(float64); ok && c > 0 {
cols = uint16(c)
}
if r, ok := msg.Params["rows"].(float64); ok && r > 0 {
rows = uint16(r)
}
if sessionID != "" {
h.client.ptyManager.ResizePTY(sessionID, cols, rows)
}
}
// --- Tunnel Handlers ---
func (h *Handler) handleTunnelConnect(msg Message) Message {
response := Message{Type: "response", ID: msg.ID}
sessionID, _ := msg.Params["session_id"].(string)
tunnelID, _ := msg.Params["tunnel_id"].(string)
targetHost, _ := msg.Params["target_host"].(string)
targetPortFloat, _ := msg.Params["target_port"].(float64)
targetPort := int(targetPortFloat)
if sessionID == "" || targetHost == "" || targetPort <= 0 {
response.Status = "error"
response.Error = "session_id, target_host und target_port erforderlich"
return response
}
if err := h.client.tunnelManager.ConnectSession(sessionID, tunnelID, targetHost, targetPort); err != nil {
response.Status = "error"
response.Error = fmt.Sprintf("Session-Connect fehlgeschlagen: %v", err)
return response
}
response.Status = "ok"
response.Data = map[string]interface{}{"session_id": sessionID}
return response
}
func (h *Handler) handleTunnelDisconnect(msg Message) {
sessionID, _ := msg.Params["session_id"].(string)
if sessionID != "" {
h.client.tunnelManager.DisconnectSession(sessionID)
}
}
// SendSessionData schickt Tunnel-Daten als Binary-Message zurueck zum Backend
func (h *Handler) SendSessionData(sessionID string, data []byte) error {
idBytes := []byte(sessionID)
if len(idBytes) > 255 {
return fmt.Errorf("session_id zu lang")
}
message := make([]byte, 1+len(idBytes)+len(data))
message[0] = byte(len(idBytes))
copy(message[1:], idBytes)
copy(message[1+len(idBytes):], data)
return h.client.SendBinaryData(message)
}
// runCommand fuehrt einen Shell-Befehl mit Timeout aus
func (h *Handler) runCommand(command string, timeoutSec int) (string, error) {
ctx, cancel := context.WithTimeout(context.Background(), time.Duration(timeoutSec)*time.Second)
defer cancel()
cmd := exec.CommandContext(ctx, "/bin/sh", "-c", command)
output, err := cmd.CombinedOutput()
return string(output), err
}
// handleUpdateCheck: apt update + Liste verfügbarer Pakete zurückgeben
func (h *Handler) handleUpdateCheck(msg Message) Message {
var response Message
response.Type = "response"
response.ID = msg.ID
log.Println("Update-Check gestartet (apt update)...")
// apt update (Paketlisten aktualisieren)
_, err := h.runCommand("DEBIAN_FRONTEND=noninteractive apt-get update -q 2>&1", 120)
if err != nil {
log.Printf("apt update Fehler: %v", err)
// Fehler ignorieren, apt update gibt oft non-zero bei Warnings zurück
}
// Verfügbare Updates abfragen
output, _ := h.runCommand("LC_ALL=C apt list --upgradable 2>/dev/null", 60)
// Security-Updates separat zählen
secOutput, _ := h.runCommand("LC_ALL=C apt list --upgradable 2>/dev/null | grep -c security || true", 30)
secCount := 0
fmt.Sscanf(strings.TrimSpace(secOutput), "%d", &secCount)
// Pakete zählen (Zeilen ohne "Listing..." und Leerzeilen)
lines := strings.Split(output, "\n")
pkgCount := 0
for _, l := range lines {
l = strings.TrimSpace(l)
if l != "" && !strings.HasPrefix(l, "Listing") && !strings.HasPrefix(l, "WARNING") {
pkgCount++
}
}
response.Status = "ok"
response.Data = map[string]interface{}{
"update_available": pkgCount > 0,
"pending_count": pkgCount,
"security_count": secCount,
"output": output,
}
return response
}
// handleUpdate: apt-get upgrade ausführen
func (h *Handler) handleUpdate(msg Message) Message {
var response Message
response.Type = "response"
response.ID = msg.ID
reboot := false
if r, ok := msg.Params["reboot"].(bool); ok {
reboot = r
}
securityOnly := false
if s, ok := msg.Params["security_only"].(bool); ok {
securityOnly = s
}
log.Printf("Update gestartet (reboot=%v, security_only=%v)", reboot, securityOnly)
// apt update
h.runCommand("DEBIAN_FRONTEND=noninteractive apt-get update -q 2>&1", 120)
// apt-get upgrade oder nur Security-Updates
var upgradeCmd string
if securityOnly {
upgradeCmd = `DEBIAN_FRONTEND=noninteractive apt-get install -y --only-upgrade \
$(LC_ALL=C apt list --upgradable 2>/dev/null | grep security | cut -d/ -f1 | tr '\n' ' ') 2>&1`
} else {
// dist-upgrade statt upgrade: löst auch neue Abhängigkeiten auf (nötig für Proxmox/PVE-Pakete)
upgradeCmd = "DEBIAN_FRONTEND=noninteractive apt-get dist-upgrade -y 2>&1"
}
output, err := h.runCommand(upgradeCmd, 900)
if err != nil {
log.Printf("apt upgrade Fehler: %v", err)
response.Status = "error"
response.Error = fmt.Sprintf("Update fehlgeschlagen: %v", err)
response.Data = map[string]interface{}{"output": output}
return response
}
log.Println("Update abgeschlossen")
response.Status = "ok"
response.Data = map[string]interface{}{
"message": "Update erfolgreich",
"output": output,
"reboot": reboot,
}
if reboot {
log.Println("Reboot nach Update in 10 Sekunden...")
go func() {
time.Sleep(10 * time.Second)
exec.Command("/sbin/shutdown", "-r", "now").Run()
}()
}
return response
}
// handleZpoolScrub: alle ZFS-Pools scrubben
func (h *Handler) handleZpoolScrub(msg Message) Message {
response := Message{Type: "response", ID: msg.ID}
log.Println("ZFS Scrub gestartet (alle Pools)...")
// Alle Pools ermitteln
poolOutput, err := h.runCommand("zpool list -H -o name 2>&1", 30)
if err != nil || strings.TrimSpace(poolOutput) == "" {
response.Status = "error"
response.Error = "Keine ZFS-Pools gefunden oder zpool nicht verfügbar"
return response
}
pools := []string{}
for _, line := range strings.Split(strings.TrimSpace(poolOutput), "\n") {
name := strings.TrimSpace(line)
if name != "" {
pools = append(pools, name)
}
}
results := map[string]string{}
scrubErrors := 0
// Jeden Pool scrubben (nicht-blockierend: scrub startet sofort und läuft im Hintergrund)
for _, pool := range pools {
log.Printf("ZFS Scrub starte: %s", pool)
out, err := h.runCommand(fmt.Sprintf("zpool scrub %s 2>&1", pool), 60)
if err != nil {
results[pool] = fmt.Sprintf("Fehler: %v — %s", err, strings.TrimSpace(out))
scrubErrors++
} else {
results[pool] = "Scrub gestartet"
}
}
if scrubErrors > 0 {
response.Status = "error"
response.Error = fmt.Sprintf("%d Pool(s) konnten nicht gestartet werden", scrubErrors)
} else {
response.Status = "ok"
}
log.Printf("ZFS Scrub: %d Pool(s) gestartet, %d Fehler", len(pools), scrubErrors)
response.Data = map[string]interface{}{
"pools": pools,
"results": results,
"message": fmt.Sprintf("Scrub auf %d Pool(s) gestartet", len(pools)-scrubErrors),
}
return response
}
// handleProxmoxAction: VM/CT starten oder stoppen via pvesh
func (h *Handler) handleProxmoxAction(msg Message) Message {
response := Message{Type: "response", ID: msg.ID}
vmType, _ := msg.Params["type"].(string) // "vm" oder "ct"
action, _ := msg.Params["action"].(string) // "start", "stop", "shutdown"
vmidFloat, ok := msg.Params["vmid"].(float64)
if !ok {
response.Status = "error"
response.Error = "Parameter 'vmid' erforderlich"
return response
}
vmid := int(vmidFloat)
if vmType != "vm" && vmType != "ct" {
response.Status = "error"
response.Error = "Parameter 'type' muss 'vm' oder 'ct' sein"
return response
}
if action != "start" && action != "stop" && action != "shutdown" {
response.Status = "error"
response.Error = "Parameter 'action' muss 'start', 'stop' oder 'shutdown' sein"
return response
}
// Node-Name ermitteln
nodeName, _ := os.Hostname()
if nodeName == "" {
nodeName = "localhost"
}
// pvesh-Pfad aufbauen
var apiPath string
if vmType == "vm" {
apiPath = fmt.Sprintf("/nodes/%s/qemu/%d/status/%s", nodeName, vmid, action)
} else {
if action == "shutdown" {
action = "stop" // LXC kennt kein "shutdown", stop reicht
}
apiPath = fmt.Sprintf("/nodes/%s/lxc/%d/status/%s", nodeName, vmid, action)
}
log.Printf("Proxmox Action: pvesh create %s", apiPath)
cmd := exec.Command("/usr/bin/pvesh", "create", apiPath, "--output-format", "json")
output, err := cmd.CombinedOutput()
if err != nil {
log.Printf("Proxmox Action Fehler: %v — %s", err, string(output))
response.Status = "error"
response.Error = fmt.Sprintf("pvesh fehlgeschlagen: %v — %s", err, strings.TrimSpace(string(output)))
return response
}
log.Printf("Proxmox Action erfolgreich: %s %s %d", action, vmType, vmid)
response.Status = "ok"
response.Data = map[string]interface{}{
"message": fmt.Sprintf("%s %d: %s ausgeführt", vmType, vmid, action),
"output": strings.TrimSpace(string(output)),
}
return response
}