feat(web): wire the SPA to the live bus via the gateway (drop mock)

Replace the mock data source with a real data layer that talks to the webgw gateway over REST + SSE. The UI components keep their look and props; only where the data comes from changed. - src/api.ts: the single repository layer. fetch wrappers (same-origin cookie) for login/logout/me and rooms list/create/join/send, plus streamRoom() which opens an EventSource and yields each decrypted message. Wire->UI mappers (roomFromWire, messageFromWire). - src/types.ts: add the gateway wire shapes (MeInfo, RoomWire, MsgWire) next to the existing UI types. - App.tsx: probe /api/me on mount to resume an existing session; otherwise show Login. Logout calls the gateway. - Login.tsx: the password field now unlocks the gateway session (operator passphrase); shows a basic error and a loading state. Wallet-per-browser is phase 2. - ChatShell.tsx: load rooms from /api/rooms with loading / empty / error states; same Flex layout. - ChatPanel.tsx: stream messages over SSE for the active room (dedup by id), composer sends through the gateway; no optimistic insert (the peer's own echo returns over SSE with the real frame id). - vite.config.ts: dev proxy /api (REST + SSE) -> the gateway on :8481. mock.ts is left untouched (no longer imported) to avoid churn with the parallel styling work on master. Co-Authored-By: Claude Opus 4.8 (1M context) <noreply@anthropic.com>
feat(webgw): web gateway peer (REST + SSE) for the chat SPA
2026-06-07 21:14:19 +02:00 · 2026-06-07 21:14:08 +02:00 · 2026-06-07 20:46:44 +02:00 · 2026-06-07 20:46:44 +02:00 · 2026-06-07 20:34:35 +02:00
13 changed files with 1374 additions and 41 deletions
@@ -0,0 +1,246 @@
 package main
 import (
 	"encoding/hex"
 	"fmt"
 	"strings"
 	"sync"
 	cs "fn-registry/functions/cybersecurity"
 	"github.com/enmanuel/unibus/pkg/busauth"
 	"github.com/enmanuel/unibus/pkg/client"
 	"github.com/enmanuel/unibus/pkg/frame"
 	"github.com/enmanuel/unibus/pkg/room"
 )
 // gateway is the live web gateway: it owns the operator's identity and a single
 // connected unibus client, and turns the bus's crypto-bearing API into the plain
 // REST/SSE surface the browser consumes. The browser never signs, never speaks
 // NATS, and never sees a private key — the gateway is the legitimate room member
 // that seals/opens payloads on the browser's behalf.
 //
 // TRUST MODEL: content stays end-to-end encrypted on the wire. The gateway can
 // read plaintext because it acts AS the operator's client — a real member of
 // each room, holding the room key K like any peer. It is the same trust a native
 // desktop client has. In the wallet phase (per-browser WebCrypto identity) the
 // decryption can move into the browser; today, for the single-operator MVP, the
 // gateway decrypts server-side and pushes cleartext over a loopback/authenticated
 // SSE channel.
 type gateway struct {
 	id         cs.Identity
 	endpoint   string
 	cli        *client.Client
 	refreshACL bool // call RefreshSession after a membership change (needed under a per-subject ACL bus)
 	mu   sync.Mutex
 	hubs map[string]*roomHub // roomID -> live fan-out of decrypted frames to SSE clients
 }
 // gatewayConfig wires a live gateway.
 type gatewayConfig struct {
 	Identity cs.Identity
 	NatsURL  string
 	CtrlURL  string
 	CtrlURLs []string
 	NatsURLs []string
 	CAPath   string // bus CA; empty => plaintext dev connection (matches a loopback membershipd)
 }
 // newGateway connects the unibus client with the operator identity following the
 // same posture seam every peer uses: a non-empty CA path means TLS + nkey, empty
 // means plaintext dev. When a CA is configured the bus is assumed to enforce a
 // per-subject ACL, so membership changes trigger a session refresh.
 func newGateway(cfg gatewayConfig) (*gateway, error) {
 	opts := client.Options{
 		CtrlURLs:    cfg.CtrlURLs,
 		NatsServers: cfg.NatsURLs,
 	}
 	if cfg.CAPath != "" {
 		tlsCfg, err := busauth.LoadCATLSConfig(cfg.CAPath)
 		if err != nil {
 			return nil, fmt.Errorf("webgw: load bus CA %q: %w", cfg.CAPath, err)
 		}
 		opts.UseNkey = true
 		opts.TLS = tlsCfg
 		opts.CtrlTLS = tlsCfg
 	}
 	cli, err := client.NewWithOptions(cfg.NatsURL, cfg.CtrlURL, cfg.Identity, opts)
 	if err != nil {
 		return nil, fmt.Errorf("webgw: connect bus client: %w", err)
 	}
 	return &gateway{
 		id:         cfg.Identity,
 		endpoint:   frame.EndpointID(cfg.Identity.SignPub),
 		cli:        cli,
 		refreshACL: cfg.CAPath != "",
 		hubs:       map[string]*roomHub{},
 	}, nil
 }
 // Close stops every hub and releases the bus client connection.
 func (g *gateway) Close() error {
 	g.mu.Lock()
 	for _, h := range g.hubs {
 		h.stop()
 	}
 	g.hubs = map[string]*roomHub{}
 	g.mu.Unlock()
 	if g.cli != nil {
 		return g.cli.Close()
 	}
 	return nil
 }
 // ---- wire types (browser-facing JSON) ------------------------------------
 // meInfo is what GET /api/me returns: the operator identity the gateway acts as.
 type meInfo struct {
 	Endpoint string `json:"endpoint"`
 	SignPub  string `json:"sign_pub"`
 }
 // roomWire is the browser view of a room. It deliberately omits messages: those
 // stream over SSE (GET /api/rooms/{id}/stream), not in the room list.
 type roomWire struct {
 	ID       string `json:"id"`
 	Subject  string `json:"subject"`
 	Name     string `json:"name"`
 	Epoch    int    `json:"epoch"`
 	Encrypt  bool   `json:"encrypt"`
 	Persist  bool   `json:"persist"`
 	SignMsgs bool   `json:"sign_msgs"`
 	Role     string `json:"role"`
 }
 // createRoomReq is the POST /api/rooms body. Encrypt/Persist/SignMsgs are
 // pointers so an omitted field falls back to the chat default rather than to the
 // Go zero value (false). The common case — the browser sending only {subject,
 // encrypted} — maps encrypted onto all three (the Matrix-like chat policy).
 type createRoomReq struct {
 	Subject   string `json:"subject"`
 	Encrypted *bool  `json:"encrypted,omitempty"`
 	Encrypt   *bool  `json:"encrypt,omitempty"`
 	Persist   *bool  `json:"persist,omitempty"`
 	SignMsgs  *bool  `json:"sign_msgs,omitempty"`
 }
 // policy resolves the requested policy. A bare {subject} defaults to the
 // Matrix-like chat room (encrypted + persisted + signed) so a created room keeps
 // durable, end-to-end-encrypted, authored history. Callers can override any leg.
 func (r createRoomReq) policy() room.Policy {
 	enc, per, sig := true, true, true
 	if r.Encrypted != nil {
 		enc, per, sig = *r.Encrypted, *r.Encrypted, *r.Encrypted
 	}
 	if r.Encrypt != nil {
 		enc = *r.Encrypt
 	}
 	if r.Persist != nil {
 		per = *r.Persist
 	}
 	if r.SignMsgs != nil {
 		sig = *r.SignMsgs
 	}
 	return room.Policy{Encrypt: enc, Persist: per, SignMsgs: sig}
 }
 // sendReq is the POST /api/rooms/{id}/send body.
 type sendReq struct {
 	Body string `json:"body"`
 }
 // msgWire is one decrypted message pushed over SSE.
 type msgWire struct {
 	ID     string `json:"id"`
 	Sender string `json:"sender"`
 	Body   string `json:"body"`
 	TS     int64  `json:"ts"` // epoch ms (decoded from the frame's ULID id)
 	Mine   bool   `json:"mine"`
 }
 // ---- operations -----------------------------------------------------------
 func (g *gateway) me() meInfo {
 	return meInfo{Endpoint: g.endpoint, SignPub: hex.EncodeToString(g.id.SignPub)}
 }
 // subjectName derives a short, human-friendly room name from its bus subject by
 // dropping the leading namespace segment (room., test., proc., agent.). It is a
 // display nicety only; the canonical identity stays the subject/room id.
 func subjectName(subject string) string {
 	for _, p := range []string{"room.", "test.", "proc.", "agent.", "rpc."} {
 		if strings.HasPrefix(subject, p) {
 			return strings.TrimPrefix(subject, p)
 		}
 	}
 	return subject
 }
 func (g *gateway) listRooms() ([]roomWire, error) {
 	rooms, err := g.cli.ListMyRooms()
 	if err != nil {
 		return nil, err
 	}
 	out := make([]roomWire, 0, len(rooms))
 	for _, rm := range rooms {
 		out = append(out, roomWire{
 			ID:       rm.RoomID,
 			Subject:  rm.Subject,
 			Name:     subjectName(rm.Subject),
 			Epoch:    rm.Epoch,
 			Encrypt:  rm.Policy.Encrypt,
 			Persist:  rm.Policy.Persist,
 			SignMsgs: rm.Policy.SignMsgs,
 			Role:     rm.Role,
 		})
 	}
 	return out, nil
 }
 func (g *gateway) createRoom(req createRoomReq) (roomWire, error) {
 	subject := strings.TrimSpace(req.Subject)
 	if subject == "" {
 		return roomWire{}, fmt.Errorf("webgw: subject required")
 	}
 	p := req.policy()
 	roomID, err := g.cli.CreateRoom(subject, p)
 	if err != nil {
 		return roomWire{}, err
 	}
 	// Under a per-subject ACL the operator's frozen NATS permissions do not yet
 	// cover the new room's subject; refresh so subsequent data-plane use works. On
 	// a plaintext/non-ACL dev bus this is unnecessary and would needlessly drop any
 	// live SSE subscriptions, so it is gated on the secured posture.
 	if g.refreshACL {
 		_ = g.cli.RefreshSession()
 	}
 	return roomWire{
 		ID:       roomID,
 		Subject:  subject,
 		Name:     subjectName(subject),
 		Epoch:    1,
 		Encrypt:  p.Encrypt,
 		Persist:  p.Persist,
 		SignMsgs: p.SignMsgs,
 		Role:     "owner",
 	}, nil
 }
 // join resolves room metadata and (for encrypted rooms) fetches the room key so
 // the gateway can later open payloads. Idempotent.
 func (g *gateway) join(roomID string) error {
 	if err := g.cli.Join(roomID); err != nil {
 		return err
 	}
 	if g.refreshACL {
 		_ = g.cli.RefreshSession()
 	}
 	return nil
 }
 // send publishes plaintext to a room. The unibus client seals it with the room
 // key (encrypted rooms) and signs it (signed rooms) before it leaves the process.
 func (g *gateway) send(roomID, body string) error {
 	return g.cli.Publish(roomID, []byte(body))
 }
@@ -0,0 +1,140 @@
 package main
 import (
 	"sync"
 	"github.com/enmanuel/unibus/pkg/client"
 	"github.com/enmanuel/unibus/pkg/frame"
 	"github.com/oklog/ulid/v2"
 )
 // roomHub multiplexes ONE unibus room subscription to MANY SSE clients. The
 // unibus client derives a per-(room, endpoint) durable consumer name, so a
 // second Subscribe for the same room from the same operator would contend for
 // the same durable (load-balanced delivery) rather than each browser receiving
 // every message. The hub holds a single subscription per room and fans each
 // decrypted frame out to every connected browser, which also means the gateway
 // opens at most one bus subscription per room regardless of how many tabs watch
 // it.
 type roomHub struct {
 	roomID     string
 	myEndpoint string
 	sub        *client.Sub
 	mu      sync.Mutex
 	clients map[chan msgWire]struct{}
 }
 // frameTS decodes the millisecond timestamp embedded in a frame's ULID id. A
 // malformed id (should not happen for bus-produced frames) yields 0, which the
 // browser renders without crashing.
 func frameTS(msgID string) int64 {
 	id, err := ulid.Parse(msgID)
 	if err != nil {
 		return 0
 	}
 	return int64(id.Time())
 }
 // newRoomHub opens the single bus subscription for roomID and starts fanning
 // decrypted frames out to registered clients. The room must already be joined
 // (so the gateway holds the room key) before this is called.
 func newRoomHub(cli *client.Client, roomID, myEndpoint string) (*roomHub, error) {
 	h := &roomHub{
 		roomID:     roomID,
 		myEndpoint: myEndpoint,
 		clients:    map[chan msgWire]struct{}{},
 	}
 	sub, err := cli.Subscribe(roomID, func(f frame.Frame, plaintext []byte) {
 		m := msgWire{
 			ID:     f.MsgID,
 			Sender: f.Sender,
 			Body:   string(plaintext),
 			TS:     frameTS(f.MsgID),
 			Mine:   f.Sender == myEndpoint,
 		}
 		h.broadcast(m)
 	})
 	if err != nil {
 		return nil, err
 	}
 	h.sub = sub
 	return h, nil
 }
 // broadcast delivers a message to every registered client without blocking the
 // NATS delivery goroutine: a client whose buffer is full (a stalled browser)
 // drops this frame rather than stalling the whole room.
 func (h *roomHub) broadcast(m msgWire) {
 	h.mu.Lock()
 	defer h.mu.Unlock()
 	for ch := range h.clients {
 		select {
 		case ch <- m:
 		default:
 		}
 	}
 }
 // add registers a new SSE client channel.
 func (h *roomHub) add(ch chan msgWire) {
 	h.mu.Lock()
 	defer h.mu.Unlock()
 	h.clients[ch] = struct{}{}
 }
 // stop unsubscribes from the bus. Local delivery ends; for a persisted room the
 // durable consumer's ack position stays on the server, so a later subscription
 // with the same operator resumes from where it left off.
 func (h *roomHub) stop() {
 	if h.sub != nil {
 		_ = h.sub.Unsubscribe()
 	}
 }
 // openStream joins the room (idempotent; fetches the room key for encrypted
 // rooms), attaches an SSE client to the room's hub (creating it on first watcher),
 // and returns the client's message channel plus a cleanup func. The cleanup
 // detaches the client and, when it was the last watcher, tears down the room's
 // single bus subscription.
 func (g *gateway) openStream(roomID string) (chan msgWire, func(), error) {
 	if err := g.join(roomID); err != nil {
 		return nil, nil, err
 	}
 	g.mu.Lock()
 	h := g.hubs[roomID]
 	if h == nil {
 		var err error
 		h, err = newRoomHub(g.cli, roomID, g.endpoint)
 		if err != nil {
 			g.mu.Unlock()
 			return nil, nil, err
 		}
 		g.hubs[roomID] = h
 	}
 	g.mu.Unlock()
 	// Buffer so a brief render hitch in the browser does not drop live frames; a
 	// sustained stall still drops (broadcast is non-blocking) rather than wedging
 	// the room.
 	ch := make(chan msgWire, 64)
 	h.add(ch)
 	// cleanup takes g.mu before h.mu (the single, consistent lock order) so a
 	// concurrent openStream that re-creates the hub cannot race the teardown.
 	cleanup := func() {
 		g.mu.Lock()
 		defer g.mu.Unlock()
 		h.mu.Lock()
 		delete(h.clients, ch)
 		empty := len(h.clients) == 0
 		h.mu.Unlock()
 		if empty {
 			if cur := g.hubs[roomID]; cur == h {
 				delete(g.hubs, roomID)
 				h.stop()
 			}
 		}
 	}
 	return ch, cleanup, nil
 }
@@ -0,0 +1,98 @@
 package main
 import (
 	"encoding/base64"
 	"encoding/json"
 	"fmt"
 	"os"
 	"os/exec"
 	cs "fn-registry/functions/cybersecurity"
 )
 // identityJSON mirrors the on-disk / pass-stored identity format shared across
 // the unibus tooling: the four keypair halves, each std-base64. It is the SAME
 // shape the bus client persists (pkg/client identity file) and the operator's
 // `pass` entry unibus/operator-identity, so the web gateway loads the operator's
 // identity without a divergent serialization. Kept in lockstep with
 // unibus_admin/internal/admin/identity.go.
 type identityJSON struct {
 	SignPub  string `json:"sign_pub"`
 	SignPriv string `json:"sign_priv"`
 	KexPub   string `json:"kex_pub"`
 	KexPriv  string `json:"kex_priv"`
 }
 // decodeIdentity turns the JSON identity bytes into a cs.Identity. The private
 // halves stay only in memory; this never writes them anywhere.
 func decodeIdentity(raw []byte) (cs.Identity, error) {
 	var f identityJSON
 	if err := json.Unmarshal(raw, &f); err != nil {
 		return cs.Identity{}, fmt.Errorf("webgw: parse identity json: %w", err)
 	}
 	dec := base64.StdEncoding.DecodeString
 	signPub, err := dec(f.SignPub)
 	if err != nil {
 		return cs.Identity{}, fmt.Errorf("webgw: decode sign_pub: %w", err)
 	}
 	signPriv, err := dec(f.SignPriv)
 	if err != nil {
 		return cs.Identity{}, fmt.Errorf("webgw: decode sign_priv: %w", err)
 	}
 	kexPub, err := dec(f.KexPub)
 	if err != nil {
 		return cs.Identity{}, fmt.Errorf("webgw: decode kex_pub: %w", err)
 	}
 	kexPriv, err := dec(f.KexPriv)
 	if err != nil {
 		return cs.Identity{}, fmt.Errorf("webgw: decode kex_priv: %w", err)
 	}
 	if len(signPub) != 32 || len(signPriv) != 64 || len(kexPub) != 32 || len(kexPriv) != 32 {
 		return cs.Identity{}, fmt.Errorf("webgw: identity has wrong key sizes (sign_pub=%d sign_priv=%d kex_pub=%d kex_priv=%d)",
 			len(signPub), len(signPriv), len(kexPub), len(kexPriv))
 	}
 	return cs.Identity{SignPub: signPub, SignPriv: signPriv, KexPub: kexPub, KexPriv: kexPriv}, nil
 }
 // loadIdentityFromFile reads a 0600 identity JSON file (the same format the bus
 // client writes) and decodes it. Used on a deploy host where `pass` is not
 // available and the operator identity is delivered as a protected file.
 func loadIdentityFromFile(path string) (cs.Identity, error) {
 	raw, err := os.ReadFile(path)
 	if err != nil {
 		return cs.Identity{}, fmt.Errorf("webgw: read identity file %q: %w", path, err)
 	}
 	return decodeIdentity(raw)
 }
 // loadIdentityFromPass shells out to `pass show <entry>` and decodes the JSON
 // identity it returns. The secret is held only in memory; this process never
 // writes it to disk or argv. Used in local operator workflows where the GNU
 // password store holds unibus/operator-identity.
 func loadIdentityFromPass(entry string) (cs.Identity, error) {
 	out, err := exec.Command("pass", "show", entry).Output()
 	if err != nil {
 		return cs.Identity{}, fmt.Errorf("webgw: pass show %q: %w", entry, err)
 	}
 	return decodeIdentity(out)
 }
 // loadPassValue returns the first line of a `pass show <entry>` for non-identity
 // secrets (e.g. the unlock passphrase). Empty entry yields an empty string and
 // no error, so callers can treat "no pass entry configured" as "not set".
 func loadPassValue(entry string) (string, error) {
 	if entry == "" {
 		return "", nil
 	}
 	out, err := exec.Command("pass", "show", entry).Output()
 	if err != nil {
 		return "", fmt.Errorf("webgw: pass show %q: %w", entry, err)
 	}
 	s := string(out)
 	for i := 0; i < len(s); i++ {
 		if s[i] == '\n' || s[i] == '\r' {
 			return s[:i], nil
 		}
 	}
 	return s, nil
 }
@@ -0,0 +1,180 @@
 // Command webgw is the web gateway for the unibus chat SPA. It is a single Go
 // binary that holds the operator's bus identity, connects to the bus as a real
 // authenticated peer (pkg/client), and exposes a small REST + SSE API the
 // browser consumes. The browser never signs, never speaks NATS, and never sees a
 // private key: it authenticates to the gateway with a passphrase and thereafter
 // holds only an opaque session cookie.
 //
 // TRUST MODEL (MVP, single operator): room content stays end-to-end encrypted on
 // the bus. The gateway can read plaintext because it acts AS the operator's
 // client — a legitimate member of each room holding the room key. Decryption
 // happens server-side in this process; cleartext then crosses an authenticated
 // (loopback or TLS-fronted) SSE channel to the browser. The wallet phase (issue:
 // per-browser WebCrypto identity) can move decryption into the browser; see the
 // report for the FASE 2 plan.
 //
 //	# local dev against a loopback membershipd (plaintext), operator from pass:
 //	webgw --identity-pass unibus/operator-identity \
 //	  --ctrl-url http://127.0.0.1:8470 --nats-url nats://127.0.0.1:4250
 //
 //	# secured cluster (TLS + nkey on both planes), identity from a 0600 file:
 //	webgw --ca ca.crt --identity-file operator.id \
 //	  --ctrl-url https://node-a:8470 --nats-url nats://node-a:4250 \
 //	  --ctrl-urls https://node-b:8470,https://node-c:8470 \
 //	  --nats-urls nats://node-b:4250,nats://node-c:4250
 package main
 import (
 	"context"
 	"flag"
 	"log"
 	"net/http"
 	"os"
 	"os/signal"
 	"path/filepath"
 	"strings"
 	"syscall"
 	"time"
 	cs "fn-registry/functions/cybersecurity"
 )
 func main() {
 	var (
 		bind         = flag.String("bind", "127.0.0.1", "interface to bind the gateway HTTP server to (loopback by default)")
 		port         = flag.String("port", "8481", "gateway HTTP port")
 		ctrlURL      = flag.String("ctrl-url", "http://127.0.0.1:8470", "primary unibus control-plane base URL")
 		ctrlURLs     = flag.String("ctrl-urls", "", "comma-separated ADDITIONAL control-plane base URLs (cluster failover)")
 		natsURL      = flag.String("nats-url", "nats://127.0.0.1:4250", "primary NATS URL")
 		natsURLs     = flag.String("nats-urls", "", "comma-separated ADDITIONAL NATS seed URLs (cluster failover)")
 		caPath       = flag.String("ca", "", "bus CA cert path; set to talk TLS+nkey to a secured bus (empty = plaintext dev)")
 		identityFile = flag.String("identity-file", "", "path to the operator identity JSON file (0600). Mutually exclusive with --identity-pass")
 		identityPass = flag.String("identity-pass", "", "pass(1) entry holding the operator identity JSON, e.g. unibus/operator-identity")
 		unlockPass   = flag.String("unlock-pass", "", "literal passphrase the browser must send to unlock a session (dev). Prefer --unlock-pass-entry")
 		unlockEntry  = flag.String("unlock-pass-entry", "unibus/admin-panel-password", "pass(1) entry holding the unlock passphrase (used when --unlock-pass is empty)")
 		webDir       = flag.String("web-dir", "", "OPTIONAL path to the built SPA (web/dist) to serve. Empty = API only (use vite dev server)")
 	)
 	flag.Parse()
 	log.SetFlags(log.LstdFlags | log.Lmsgprefix)
 	log.SetPrefix("[webgw] ")
 	id, err := loadIdentity(*identityFile, *identityPass)
 	if err != nil {
 		log.Fatalf("%v", err)
 	}
 	unlock := *unlockPass
 	if unlock == "" {
 		unlock, err = loadPassValue(*unlockEntry)
 		if err != nil {
 			log.Fatalf("resolve unlock passphrase: %v", err)
 		}
 	}
 	if unlock == "" {
 		log.Fatalf("an unlock passphrase is required: set --unlock-pass or a non-empty --unlock-pass-entry (default unibus/admin-panel-password)")
 	}
 	resolvedWebDir := resolveWebDir(*webDir)
 	gw, err := newGateway(gatewayConfig{
 		Identity: id,
 		NatsURL:  *natsURL,
 		CtrlURL:  *ctrlURL,
 		CtrlURLs: splitCSV(*ctrlURLs),
 		NatsURLs: splitCSV(*natsURLs),
 		CAPath:   *caPath,
 	})
 	if err != nil {
 		log.Fatalf("%v", err)
 	}
 	defer gw.Close()
 	log.Printf("operator endpoint: %s", gw.endpoint)
 	log.Printf("control plane: %s (+%d failover)", *ctrlURL, len(splitCSV(*ctrlURLs)))
 	tls := "OFF (plaintext dev)"
 	if *caPath != "" {
 		tls = "ON (CA " + *caPath + ")"
 	}
 	log.Printf("bus TLS+nkey: %s", tls)
 	if resolvedWebDir != "" {
 		log.Printf("serving SPA from: %s", resolvedWebDir)
 	} else {
 		log.Printf("API only (no --web-dir): use the vite dev server with a /api+stream proxy")
 	}
 	srv := newServer(gw, unlock, resolvedWebDir)
 	addr := *bind + ":" + *port
 	httpSrv := &http.Server{
 		Addr:    addr,
 		Handler: srv,
 		// No global write timeout: SSE streams are long-lived. Header timeout still
 		// bounds slowloris on the request line/headers.
 		ReadHeaderTimeout: 10 * time.Second,
 	}
 	go func() {
 		log.Printf("web gateway: http://%s", addr)
 		if err := httpSrv.ListenAndServe(); err != nil && err != http.ErrServerClosed {
 			log.Fatalf("http server: %v", err)
 		}
 	}()
 	stop := make(chan os.Signal, 1)
 	signal.Notify(stop, syscall.SIGINT, syscall.SIGTERM)
 	<-stop
 	log.Printf("shutting down...")
 	ctx, cancel := context.WithTimeout(context.Background(), 5*time.Second)
 	defer cancel()
 	_ = httpSrv.Shutdown(ctx)
 	log.Printf("bye")
 }
 // loadIdentity resolves the operator identity from exactly one of --identity-file
 // or --identity-pass.
 func loadIdentity(file, passEntry string) (cs.Identity, error) {
 	switch {
 	case file != "" && passEntry != "":
 		return cs.Identity{}, errFlag("set only one of --identity-file or --identity-pass")
 	case file != "":
 		return loadIdentityFromFile(file)
 	case passEntry != "":
 		return loadIdentityFromPass(passEntry)
 	default:
 		return cs.Identity{}, errFlag("an identity is required: pass --identity-file <path> or --identity-pass <entry>")
 	}
 }
 // resolveWebDir validates the --web-dir flag. An empty flag means API-only. A
 // non-empty dir is kept only if it actually holds an index.html, so a typo logs
 // "API only" rather than serving 404s.
 func resolveWebDir(dir string) string {
 	if dir == "" {
 		return ""
 	}
 	abs, err := filepath.Abs(dir)
 	if err != nil {
 		log.Printf("WARN --web-dir %q: %v; serving API only", dir, err)
 		return ""
 	}
 	if !statFile(filepath.Join(abs, "index.html")) {
 		log.Printf("WARN --web-dir %q has no index.html; serving API only", abs)
 		return ""
 	}
 	return abs
 }
 type flagErr string
 func (e flagErr) Error() string { return string(e) }
 func errFlag(s string) error    { return flagErr("webgw: " + s) }
 func splitCSV(s string) []string {
 	var out []string
 	for _, p := range strings.Split(s, ",") {
 		if p = strings.TrimSpace(p); p != "" {
 			out = append(out, p)
 		}
 	}
 	return out
 }
@@ -0,0 +1,301 @@
 package main
 import (
 	"crypto/rand"
 	"crypto/subtle"
 	"encoding/hex"
 	"encoding/json"
 	"net/http"
 	"os"
 	"path/filepath"
 	"strings"
 	"sync"
 	"time"
 )
 // sessionCookie is the name of the gateway's session cookie. The browser sends
 // it automatically on same-origin fetches AND on EventSource (SSE) connections —
 // EventSource cannot set custom headers, so a cookie is the only way to
 // authenticate the stream. It is HttpOnly so page JS can never read the token.
 const sessionCookie = "unibus_session"
 // server is the gateway's HTTP surface: a small REST/SSE API under /api gated by
 // a session cookie, plus an optional static file server for the built SPA. The
 // gateway's privileged operator identity never leaves the process; the browser
 // authenticates with a passphrase and thereafter holds only an opaque session
 // token.
 type server struct {
 	gw     *gateway
 	unlock string // passphrase that unlocks a session (compared in constant time)
 	webDir string // optional path to the built SPA (web/dist); empty = API only
 	mux    *http.ServeMux
 	mu       sync.Mutex
 	sessions map[string]time.Time // token -> issued-at
 }
 func newServer(gw *gateway, unlock, webDir string) *server {
 	s := &server{
 		gw:       gw,
 		unlock:   unlock,
 		webDir:   webDir,
 		mux:      http.NewServeMux(),
 		sessions: map[string]time.Time{},
 	}
 	s.routes()
 	return s
 }
 func (s *server) ServeHTTP(w http.ResponseWriter, r *http.Request) { s.mux.ServeHTTP(w, r) }
 func (s *server) routes() {
 	// Liveness, unauthenticated (systemd / deploy smoke).
 	s.mux.HandleFunc("GET /healthz", func(w http.ResponseWriter, _ *http.Request) {
 		writeJSON(w, http.StatusOK, map[string]string{"status": "ok"})
 	})
 	// Auth: login is the only /api route reachable without a session.
 	s.mux.HandleFunc("POST /api/login", s.handleLogin)
 	s.mux.HandleFunc("POST /api/logout", s.auth(s.handleLogout))
 	s.mux.HandleFunc("GET /api/me", s.auth(s.handleMe))
 	s.mux.HandleFunc("GET /api/rooms", s.auth(s.handleListRooms))
 	s.mux.HandleFunc("POST /api/rooms", s.auth(s.handleCreateRoom))
 	s.mux.HandleFunc("POST /api/rooms/{id}/join", s.auth(s.handleJoin))
 	s.mux.HandleFunc("POST /api/rooms/{id}/send", s.auth(s.handleSend))
 	s.mux.HandleFunc("GET /api/rooms/{id}/stream", s.auth(s.handleStream))
 	// Everything else is the SPA (when --web-dir is set). Registered last.
 	if s.webDir != "" {
 		s.mux.Handle("/", s.spaHandler())
 	}
 }
 // ---- auth -----------------------------------------------------------------
 // auth wraps a handler so it runs only with a valid session cookie. A missing or
 // unknown token yields 401, which the SPA treats as "show the login screen".
 func (s *server) auth(next http.HandlerFunc) http.HandlerFunc {
 	return func(w http.ResponseWriter, r *http.Request) {
 		c, err := r.Cookie(sessionCookie)
 		if err != nil || !s.validSession(c.Value) {
 			writeErr(w, http.StatusUnauthorized, "not authenticated")
 			return
 		}
 		next(w, r)
 	}
 }
 func (s *server) validSession(token string) bool {
 	if token == "" {
 		return false
 	}
 	s.mu.Lock()
 	defer s.mu.Unlock()
 	_, ok := s.sessions[token]
 	return ok
 }
 func (s *server) handleLogin(w http.ResponseWriter, r *http.Request) {
 	var req struct {
 		Passphrase string `json:"passphrase"`
 	}
 	if !decode(w, r, &req) {
 		return
 	}
 	// Constant-time compare so a wrong passphrase cannot be timed character by
 	// character. An empty configured passphrase never matches (main refuses to
 	// start without one, so this is defense in depth).
 	if s.unlock == "" || subtle.ConstantTimeCompare([]byte(req.Passphrase), []byte(s.unlock)) != 1 {
 		writeErr(w, http.StatusUnauthorized, "wrong passphrase")
 		return
 	}
 	tok := newToken()
 	s.mu.Lock()
 	s.sessions[tok] = time.Now()
 	s.mu.Unlock()
 	http.SetCookie(w, &http.Cookie{
 		Name:     sessionCookie,
 		Value:    tok,
 		Path:     "/",
 		HttpOnly: true,
 		SameSite: http.SameSiteLaxMode,
 	})
 	writeJSON(w, http.StatusOK, s.gw.me())
 }
 func (s *server) handleLogout(w http.ResponseWriter, r *http.Request) {
 	if c, err := r.Cookie(sessionCookie); err == nil {
 		s.mu.Lock()
 		delete(s.sessions, c.Value)
 		s.mu.Unlock()
 	}
 	http.SetCookie(w, &http.Cookie{Name: sessionCookie, Value: "", Path: "/", MaxAge: -1, HttpOnly: true})
 	writeJSON(w, http.StatusOK, map[string]string{"status": "logged_out"})
 }
 func (s *server) handleMe(w http.ResponseWriter, _ *http.Request) {
 	writeJSON(w, http.StatusOK, s.gw.me())
 }
 // ---- rooms ----------------------------------------------------------------
 func (s *server) handleListRooms(w http.ResponseWriter, _ *http.Request) {
 	rooms, err := s.gw.listRooms()
 	if err != nil {
 		writeErr(w, http.StatusBadGateway, err.Error())
 		return
 	}
 	writeJSON(w, http.StatusOK, rooms)
 }
 func (s *server) handleCreateRoom(w http.ResponseWriter, r *http.Request) {
 	var req createRoomReq
 	if !decode(w, r, &req) {
 		return
 	}
 	rv, err := s.gw.createRoom(req)
 	if err != nil {
 		writeErr(w, http.StatusBadGateway, err.Error())
 		return
 	}
 	writeJSON(w, http.StatusCreated, rv)
 }
 func (s *server) handleJoin(w http.ResponseWriter, r *http.Request) {
 	if err := s.gw.join(r.PathValue("id")); err != nil {
 		writeErr(w, http.StatusBadGateway, err.Error())
 		return
 	}
 	writeJSON(w, http.StatusOK, map[string]string{"status": "joined"})
 }
 func (s *server) handleSend(w http.ResponseWriter, r *http.Request) {
 	var req sendReq
 	if !decode(w, r, &req) {
 		return
 	}
 	if strings.TrimSpace(req.Body) == "" {
 		writeErr(w, http.StatusBadRequest, "body required")
 		return
 	}
 	if err := s.gw.send(r.PathValue("id"), req.Body); err != nil {
 		writeErr(w, http.StatusBadGateway, err.Error())
 		return
 	}
 	writeJSON(w, http.StatusOK, map[string]string{"status": "sent"})
 }
 // handleStream is the SSE endpoint: it joins the room, attaches to the room's
 // fan-out hub, and streams each decrypted message as a `data:` event. For a
 // persisted room the hub's underlying subscription delivers history first
 // (scrollback) and then live messages; for an ephemeral room only live messages
 // flow. The stream ends when the browser disconnects (ctx cancelled).
 func (s *server) handleStream(w http.ResponseWriter, r *http.Request) {
 	flusher, ok := w.(http.Flusher)
 	if !ok {
 		writeErr(w, http.StatusInternalServerError, "streaming unsupported")
 		return
 	}
 	ch, cleanup, err := s.gw.openStream(r.PathValue("id"))
 	if err != nil {
 		writeErr(w, http.StatusBadGateway, err.Error())
 		return
 	}
 	defer cleanup()
 	w.Header().Set("Content-Type", "text/event-stream")
 	w.Header().Set("Cache-Control", "no-cache")
 	w.Header().Set("Connection", "keep-alive")
 	w.Header().Set("X-Accel-Buffering", "no") // disable proxy buffering (nginx/caddy)
 	w.WriteHeader(http.StatusOK)
 	// An initial comment opens the stream immediately so the browser's
 	// EventSource fires `onopen` without waiting for the first message.
 	_, _ = w.Write([]byte(": connected\n\n"))
 	flusher.Flush()
 	ctx := r.Context()
 	ping := time.NewTicker(25 * time.Second)
 	defer ping.Stop()
 	for {
 		select {
 		case <-ctx.Done():
 			return
 		case <-ping.C:
 			// Comment line keeps idle proxies from closing the connection.
 			if _, err := w.Write([]byte(": ping\n\n")); err != nil {
 				return
 			}
 			flusher.Flush()
 		case m := <-ch:
 			b, err := json.Marshal(m)
 			if err != nil {
 				continue
 			}
 			if _, err := w.Write([]byte("data: " + string(b) + "\n\n")); err != nil {
 				return
 			}
 			flusher.Flush()
 		}
 	}
 }
 // ---- SPA serving (optional) -----------------------------------------------
 // spaHandler serves the built SPA from s.webDir. A request for an existing asset
 // is served directly; any other path (a client-side route) falls back to
 // index.html so the SPA router can take over. /api and /healthz are matched first.
 func (s *server) spaHandler() http.Handler {
 	root := http.Dir(s.webDir)
 	fileServer := http.FileServer(root)
 	index := filepath.Join(s.webDir, "index.html")
 	return http.HandlerFunc(func(w http.ResponseWriter, r *http.Request) {
 		p := strings.TrimPrefix(r.URL.Path, "/")
 		if p == "" {
 			http.ServeFile(w, r, index)
 			return
 		}
 		if f, err := root.Open(p); err == nil {
 			_ = f.Close()
 			fileServer.ServeHTTP(w, r)
 			return
 		}
 		http.ServeFile(w, r, index) // unknown path -> SPA client-side routing
 	})
 }
 // ---- helpers --------------------------------------------------------------
 func newToken() string {
 	b := make([]byte, 32)
 	_, _ = rand.Read(b)
 	return hex.EncodeToString(b)
 }
 func writeJSON(w http.ResponseWriter, code int, v any) {
 	w.Header().Set("Content-Type", "application/json")
 	w.WriteHeader(code)
 	_ = json.NewEncoder(w).Encode(v)
 }
 func writeErr(w http.ResponseWriter, code int, msg string) {
 	writeJSON(w, code, map[string]string{"error": msg})
 }
 // decode reads a JSON body into v, writing a 400 and returning false on failure.
 func decode(w http.ResponseWriter, r *http.Request, v any) bool {
 	defer r.Body.Close()
 	if err := json.NewDecoder(http.MaxBytesReader(w, r.Body, 1<<20)).Decode(v); err != nil {
 		writeErr(w, http.StatusBadRequest, "bad json: "+err.Error())
 		return false
 	}
 	return true
 }
 // statFile reports whether path exists and is a regular file (used to validate
 // --web-dir at startup so a typo surfaces as a clear log line, not 404s later).
 func statFile(path string) bool {
 	fi, err := os.Stat(path)
 	return err == nil && !fi.IsDir()
 }
@@ -0,0 +1,78 @@
 ---
 issue: 0007
 title: Cifrado at-rest del control plane (JetStream KV / SQLite en disco)
 status: spec
 created: 2026-06-07
 domain: security
 scope: unibus (pkg/embeddednats, cmd/membershipd, deploy/cluster) + procedimiento de migración del store existente
 ---
 # Objetivo
 Cifrar en reposo el almacenamiento del plano de control para que un nodo comprometido
 (root en el VPS) o un disco robado no exponga los metadatos de control en claro.
 Estado actual (auditado el 07/06/2026, report 0012 y siguientes):
 - **Contenido de los mensajes**: cifrado E2E por room (megolm/olm). El servidor nunca ve el
  plaintext; no vive en el plano de control. **No es el objeto de este issue.**
 - **Claves de room** (`UNIBUS_room_keys`): guardadas **selladas** (sealed box X25519, cifradas
  para cada miembro). El servidor las almacena y reparte pero no puede abrirlas. **Ya protegidas.**
 - **Metadatos de control** (`UNIBUS_rooms`, `UNIBUS_members`, `UNIBUS_rooms_by_member`,
  `UNIBUS_users`): se serializan con `json.Marshal` y se escriben **en claro** en el store. En
  cluster ese store es el directorio `local_files/jetstream/` de cada nodo; en single-node es el
  archivo SQLite `local_files/unibus.db`. Hoy **no hay cifrado at-rest**: con root en un nodo se
  pueden leer subjects de salas, la pertenencia (quién está en qué sala con qué rol), los handles
  y roles de los usuarios, y las claves públicas (signPub/kexPub). No se exponen mensajes (E2E) ni
  se pueden descifrar salas (claves selladas), pero sí toda la topología.
 Tras este issue, los buckets/archivos del control plane quedan cifrados en disco con una clave por
 nodo gestionada fuera de git. El modelo de amenaza pasa de "root del nodo ve la topología" a "root
 del nodo necesita además la clave at-rest (que puede vivir en un secreto separado / TPM / variable
 de entorno inyectada) para leer cualquier cosa".
 # Contexto técnico
 - NATS Server / JetStream soporta **encryption at-rest** nativo: se configura una cifra
  (`aes` o `chacha20`) y una clave; JetStream cifra los ficheros de los streams/KV en disco. El
  bus usa un NATS **embebido** (`pkg/embeddednats`), así que la activación es por opciones del
  servidor embebido, no por un `nats-server.conf` externo.
 - Para el backend SQLite (single-node) el equivalente sería SQLCipher o cifrado a nivel de
  archivo/FS; queda como sub-tarea de menor prioridad porque el despliegue real es cluster (KV).
 # Tareas
 1. Confirmar la API de encryption-at-rest del NATS embebido en la versión usada (opción de
   servidor para cipher + clave; cómo se pasa la clave de forma que no quede en argv ni en git).
 2. Activar el cifrado en `pkg/embeddednats` detrás de una opción de configuración. La clave se
   inyecta por archivo (`--jetstream-encryption-key-file`, 0600, junto a las claves TLS del nodo)
   o variable de entorno desde el unit systemd; nunca en argv ni commiteada.
 3. `cmd/membershipd`: flag/env para la clave + reflejar el estado en la posture publicada en
   `/healthz` (p.ej. `"at_rest":true`) para que el monitor lo verifique.
 4. `deploy/cluster`: provisionar la clave at-rest por nodo (generación + `pass`/secrets gitignored)
   y cablearla en `cluster.env` + el unit. Documentar en el runbook.
 5. **Migración del store existente** (gotcha crítico): JetStream no re-cifra retroactivamente los
   datos ya escritos en claro. Diseñar y documentar el procedimiento seguro para el cluster en
   producción (probable: backup → exportar snapshot del control plane → parar nodo → recrear el
   store con la clave activa → re-importar; o rotación nodo a nodo aprovechando la replicación R3).
   Respetar la regla de migraciones (aditivo, sin pérdida de datos).
 6. Tests: arrancar un nodo con clave at-rest, escribir un user/room, y verificar que el fichero en
   disco **no** contiene en claro un subject/handle conocido (grep negativo), y que el nodo sigue
   leyéndolos con la clave. Verificar que sin la clave el store no se abre.
 # Definition of Done
 - Cifrado at-rest activo en los 3 nodos del cluster; `/healthz` lo refleja en la posture.
 - Evidencia ejecutable: un valor conocido (subject de sala / handle de usuario) **no** aparece en
  claro al hacer `grep` sobre `local_files/jetstream/`; el nodo lo sigue sirviendo con la clave.
 - Procedimiento de migración probado sobre datos reales sin pérdida (snapshot/restore verificado).
 - La clave at-rest nunca está en git ni en argv; vive en archivo 0600 / secreto inyectado.
 - No baja ninguna otra capa de seguridad (enforce + ACL + TLS + E2E + sealed keys intactas).
 # Notas
 Aditivo y ortogonal al resto de la seguridad: TLS protege en tránsito, E2E el contenido, las claves
 de room van selladas; este issue cierra el último hueco (metadatos de control en claro en disco)
 para el modelo de amenaza "VPS comprometido / disco robado". Prioridad media: el despliegue ya es
 seguro frente a ataques de red (enforce+TLS+ACL); esto endurece frente a compromiso físico/root del
 host. Relacionado con el endurecimiento de los issues 0004/0005/0006.
@@ -1,11 +1,44 @@
-import { useState } from "react";
+import { useEffect, useState } from "react";
 import { Center, Loader } from "@mantine/core";
 import { Login } from "./Login";
 import { ChatShell } from "./ChatShell";
 import { api } from "./api";
 import type { User } from "./types";
 // shortEndpoint hace legible el endpoint id del operador para mostrarlo como
 // handle por defecto cuando no se escribió uno en el login.
 function shortEndpoint(ep: string) {
  return ep.slice(0, 8);
 }
 export function App() {
  const [user, setUser] = useState<User | null>(null);
  const [checking, setChecking] = useState(true);
-  if (!user) return <Login onLogin={setUser} />;
+  // Al montar, comprueba si ya hay una sesión viva en el gateway (cookie). Si la
-  return <ChatShell user={user} onLogout={() => setUser(null)} />;
+  // hay, entra directo; si no (401), muestra el login.
  useEffect(() => {
    api
      .me()
      .then((me) =>
        setUser({ id: me.endpoint, handle: shortEndpoint(me.endpoint) }),
      )
      .catch(() => {})
      .finally(() => setChecking(false));
  }, []);
  const logout = () => {
    void api.logout().catch(() => {});
    setUser(null);
  };
  if (checking) {
    return (
      <Center h="100vh" bg="dark.9">
        <Loader color="brand" />
      </Center>
    );
  }
  if (!user) return <Login onLogin={setUser} />;
  return <ChatShell user={user} onLogout={logout} />;
 }
@@ -19,7 +19,8 @@ import {
  IconDotsVertical,
  IconPaperclip,
 } from "@tabler/icons-react";
-import type { Message, Room, User } from "./types";
+import { api, streamRoom } from "./api";
 import type { Message, Room } from "./types";
 function initials(s: string) {
  return s.replace(/[^a-z0-9]/gi, "").slice(0, 2).toUpperCase() || "?";
@@ -54,22 +55,30 @@ function MessageRow({ msg }: { msg: Message }) {
  );
 }
-export function ChatPanel({
+export function ChatPanel({ room }: { room: Room | undefined }) {
  room,
  user,
 }: {
  room: Room | undefined;
  user: User;
 }) {
  const [draft, setDraft] = useState("");
-  const [extra, setExtra] = useState<Record<string, Message[]>>({});
+  const [messages, setMessages] = useState<Message[]>([]);
  const [sendError, setSendError] = useState<string | null>(null);
  const viewport = useRef<HTMLDivElement>(null);
-  const msgs = room ? [...room.messages, ...(extra[room.id] ?? [])] : [];
+  // Abre el stream SSE de la room activa. El gateway entrega historia (rooms
  // persistidas) y luego mensajes en vivo, ya descifrados. Dedup por id porque
  // un re-render no debe duplicar y el eco del propio envío llega por aquí.
  useEffect(() => {
    setMessages([]);
    setSendError(null);
    if (!room) return;
    const close = streamRoom(room.id, (m) => {
      setMessages((prev) =>
        prev.some((p) => p.id === m.id) ? prev : [...prev, m],
      );
    });
    return close;
  }, [room?.id]);
  useEffect(() => {
    viewport.current?.scrollTo({ top: viewport.current.scrollHeight });
-  }, [room?.id, msgs.length]);
+  }, [room?.id, messages.length]);
  if (!room) {
    return (
@@ -79,18 +88,19 @@ export function ChatPanel({
    );
  }
-  const send = () => {
+  const send = async () => {
    const body = draft.trim();
    if (!body) return;
    const msg: Message = {
      id: `local-${Date.now()}`,
      sender: user.handle,
      body,
      ts: Date.now(),
      mine: true,
    };
    setExtra((e) => ({ ...e, [room.id]: [...(e[room.id] ?? []), msg] }));
    setDraft("");
    setSendError(null);
    try {
      // No optimista: el mensaje propio vuelve por SSE con su id real (mine:true),
      // evitando duplicados.
      await api.send(room.id, body);
    } catch (e) {
      setDraft(body); // restaura el borrador si el envío falló
      setSendError(e instanceof Error ? e.message : "No se pudo enviar");
    }
  };
  return (
@@ -126,13 +136,18 @@ export function ChatPanel({
      <ScrollArea style={{ flex: 1 }} viewportRef={viewport}>
        <Stack gap="lg" p="md">
-          {msgs.map((m) => (
+          {messages.map((m) => (
            <MessageRow key={m.id} msg={m} />
          ))}
        </Stack>
      </ScrollArea>
      <Divider color="dark.4" />
      {sendError && (
        <Text c="red" size="xs" px="sm" pt={4}>
          {sendError}
        </Text>
      )}
      <Group p="sm" gap="xs" wrap="nowrap">
        <ActionIcon variant="subtle" color="gray" size="lg">
          <IconPaperclip size={18} />
@@ -143,14 +158,14 @@ export function ChatPanel({
          placeholder={`Mensaje a ${room.name}`}
          value={draft}
          onChange={(e) => setDraft(e.currentTarget.value)}
-          onKeyDown={(e) => e.key === "Enter" && send()}
+          onKeyDown={(e) => e.key === "Enter" && void send()}
        />
        <ActionIcon
          size="lg"
          radius="xl"
          variant="filled"
          color="brand"
-          onClick={send}
+          onClick={() => void send()}
          disabled={!draft.trim()}
        >
          <IconSend size={18} />
@@ -1,9 +1,9 @@
-import { useState } from "react";
+import { useCallback, useEffect, useState } from "react";
-import { Flex, Box } from "@mantine/core";
+import { Flex, Box, Center, Loader, Stack, Text, Button } from "@mantine/core";
 import { Sidebar } from "./Sidebar";
 import { ChatPanel } from "./ChatPanel";
-import { MOCK_ROOMS } from "./mock";
+import { api } from "./api";
-import type { User } from "./types";
+import type { Room, User } from "./types";
 export function ChatShell({
  user,
@@ -12,10 +12,59 @@ export function ChatShell({
  user: User;
  onLogout: () => void;
 }) {
-  const [rooms] = useState(MOCK_ROOMS);
+  const [rooms, setRooms] = useState<Room[]>([]);
-  const [activeId, setActiveId] = useState<string>(rooms[0]?.id ?? "");
+  const [activeId, setActiveId] = useState<string>("");
  const [loading, setLoading] = useState(true);
  const [error, setError] = useState<string | null>(null);
  const load = useCallback(() => {
    setLoading(true);
    api
      .listRooms()
      .then((rs) => {
        setRooms(rs);
        setActiveId((cur) => cur || rs[0]?.id || "");
        setError(null);
      })
      .catch((e) => setError(e?.message ?? "No se pudieron cargar las rooms"))
      .finally(() => setLoading(false));
  }, []);
  useEffect(() => {
    load();
  }, [load]);
  const active = rooms.find((r) => r.id === activeId);
  // El panel derecho muestra el estado de carga/error/empty sin tocar el layout.
  let panel = <ChatPanel room={active} />;
  if (loading && rooms.length === 0) {
    panel = (
      <Center h="100%">
        <Loader color="brand" />
      </Center>
    );
  } else if (error) {
    panel = (
      <Center h="100%">
        <Stack align="center" gap="sm">
          <Text c="red" size="sm">
            {error}
          </Text>
          <Button variant="light" color="brand" onClick={load}>
            Reintentar
          </Button>
        </Stack>
      </Center>
    );
  } else if (rooms.length === 0) {
    panel = (
      <Center h="100%">
        <Text c="dimmed">No perteneces a ninguna room todavía</Text>
      </Center>
    );
  }
  return (
    <Flex h="100vh" w="100vw" style={{ overflow: "hidden" }}>
      <Box
@@ -36,7 +85,7 @@ export function ChatShell({
        />
      </Box>
      <Box flex={1} h="100%" bg="dark.7" style={{ minWidth: 0 }}>
-        <ChatPanel room={active} user={user} />
+        {panel}
      </Box>
    </Flex>
  );
@@ -11,15 +11,29 @@ import {
  Title,
 } from "@mantine/core";
 import { IconShieldLock, IconKey } from "@tabler/icons-react";
 import { api, ApiError } from "./api";
 import type { User } from "./types";
 export function Login({ onLogin }: { onLogin: (u: User) => void }) {
  const [handle, setHandle] = useState("");
  const [password, setPassword] = useState("");
  const [busy, setBusy] = useState(false);
  const [error, setError] = useState<string | null>(null);
  const ready = handle.trim().length > 0 && password.length > 0;
-  const connect = () => {
+  const connect = async () => {
-    const h = handle.trim();
+    if (!ready || busy) return;
-    if (ready) onLogin({ id: h, handle: h });
+    setBusy(true);
    setError(null);
    try {
      // La contraseña desbloquea la sesión del gateway (passphrase del operador).
      // El handle es solo el nombre a mostrar en esta iteración (wallet = fase 2).
      const me = await api.login(password);
      const h = handle.trim() || me.endpoint.slice(0, 8);
      onLogin({ id: me.endpoint, handle: h });
    } catch (e) {
      setError(e instanceof ApiError ? e.message : "No se pudo conectar al gateway");
      setBusy(false);
    }
  };
  return (
@@ -52,9 +66,20 @@ export function Login({ onLogin }: { onLogin: (u: User) => void }) {
            leftSection={<IconKey size={16} />}
            value={password}
            onChange={(e) => setPassword(e.currentTarget.value)}
-            onKeyDown={(e) => e.key === "Enter" && connect()}
+            onKeyDown={(e) => e.key === "Enter" && void connect()}
          />
-          <Button w="100%" size="md" onClick={connect} disabled={!ready}>
+          {error && (
            <Text c="red" size="sm" ta="center">
              {error}
            </Text>
          )}
          <Button
            w="100%"
            size="md"
            onClick={() => void connect()}
            disabled={!ready}
            loading={busy}
          >
            Conectar
          </Button>
        </Stack>
@@ -0,0 +1,131 @@
 // La única capa por la que la SPA habla con el bus. Cada llamada va al gateway Go
 // bajo /api; el gateway mantiene la sesión `pkg/client` (peer autenticado del
 // bus), cifra/descifra por room y traduce a REST/SSE. El navegador nunca firma,
 // nunca habla NATS y nunca ve una clave privada: solo guarda una cookie de
 // sesión opaca (HttpOnly) que el gateway emite tras el login.
 import type { MeInfo, Message, MsgWire, Room, RoomWire } from "./types";
 export class ApiError extends Error {
  status: number;
  constructor(message: string, status: number) {
    super(message);
    this.status = status;
  }
 }
 async function req<T>(path: string, init?: RequestInit): Promise<T> {
  const res = await fetch(path, {
    // same-origin envía la cookie de sesión automáticamente (también detrás del
    // proxy de vite en dev).
    credentials: "same-origin",
    headers: { "Content-Type": "application/json" },
    ...init,
  });
  const text = await res.text();
  let body: unknown = null;
  if (text) {
    try {
      body = JSON.parse(text);
    } catch {
      body = text;
    }
  }
  if (!res.ok) {
    const msg =
      body && typeof body === "object" && "error" in body
        ? String((body as { error: unknown }).error)
        : `HTTP ${res.status}`;
    throw new ApiError(msg, res.status);
  }
  return body as T;
 }
 // roomFromWire mapea la fila del gateway al tipo Room que consume la UI. Los
 // mensajes NO viven aquí: llegan por stream(). lastMessage/lastTs/unread se
 // rellenan de forma neutra para no inventar datos (la cabecera de la sidebar se
 // alimentará del stream en una iteración futura).
 export function roomFromWire(r: RoomWire): Room {
  return {
    id: r.id,
    name: r.name || r.subject,
    encrypted: r.encrypt,
    lastMessage: "",
    lastTs: 0,
    unread: 0,
    messages: [],
  };
 }
 // messageFromWire mapea un frame descifrado del SSE al tipo Message de la UI.
 export function messageFromWire(m: MsgWire): Message {
  return {
    id: m.id,
    sender: m.sender,
    body: m.body,
    ts: m.ts,
    mine: m.mine,
  };
 }
 export const api = {
  // ---- sesión -------------------------------------------------------------
  // login desbloquea la sesión del gateway con la passphrase del operador. El
  // gateway responde con una cookie de sesión; me() comprueba si ya hay una.
  login: (passphrase: string) =>
    req<MeInfo>("/api/login", {
      method: "POST",
      body: JSON.stringify({ passphrase }),
    }),
  logout: () => req<{ status: string }>("/api/logout", { method: "POST" }),
  me: () => req<MeInfo>("/api/me"),
  // ---- rooms --------------------------------------------------------------
  listRooms: async (): Promise<Room[]> => {
    const wire = await req<RoomWire[]>("/api/rooms");
    return wire.map(roomFromWire);
  },
  // createRoom: {subject, encrypted} basta — el gateway deriva la policy
  // Matrix-like (cifrada + persistida + firmada) por defecto.
  createRoom: async (subject: string, encrypted = true): Promise<Room> => {
    const r = await req<RoomWire>("/api/rooms", {
      method: "POST",
      body: JSON.stringify({ subject, encrypted }),
    });
    return roomFromWire(r);
  },
  join: (roomID: string) =>
    req<{ status: string }>(
      `/api/rooms/${encodeURIComponent(roomID)}/join`,
      { method: "POST" },
    ),
  send: (roomID: string, body: string) =>
    req<{ status: string }>(
      `/api/rooms/${encodeURIComponent(roomID)}/send`,
      { method: "POST", body: JSON.stringify({ body }) },
    ),
 };
 // streamRoom abre el SSE de una room y llama onMessage por cada frame descifrado
 // (historia primero en rooms persistidas, luego en vivo). Devuelve una función
 // de cierre. EventSource manda la cookie de sesión automáticamente y reconecta
 // solo si la conexión cae; onError se invoca en cada corte para que la UI pueda
 // reflejar el estado.
 export function streamRoom(
  roomID: string,
  onMessage: (m: Message) => void,
  onError?: (e: Event) => void,
 ): () => void {
  const es = new EventSource(
    `/api/rooms/${encodeURIComponent(roomID)}/stream`,
  );
  es.onmessage = (ev) => {
    try {
      const wire = JSON.parse(ev.data) as MsgWire;
      onMessage(messageFromWire(wire));
    } catch {
      // frame malformado: se ignora, el stream sigue.
    }
  };
  if (onError) es.onerror = onError;
  return () => es.close();
 }
@@ -1,5 +1,5 @@
-// Tipos de dominio de la UI. En la iteración 1 se llenan con datos mock;
+// Tipos de dominio de la UI. Los datos vienen del gateway Go (REST/SSE), que es
-// más adelante vendrán del gateway (REST/SSE) que es un peer del bus.
+// un peer autenticado del bus. El navegador nunca firma ni habla NATS.
 export interface User {
  id: string;
@@ -8,7 +8,7 @@ export interface User {
 export interface Message {
  id: string;
-  sender: string; // handle
+  sender: string; // endpoint id del remitente (handle legible es fase 2)
  body: string;
  ts: number; // epoch ms
  mine?: boolean;
@@ -23,3 +23,33 @@ export interface Room {
  unread: number;
  messages: Message[];
 }
 // ---- formas de la API del gateway (wire) ---------------------------------
 // MeInfo es la identidad del operador que el gateway encarna (GET /api/me).
 export interface MeInfo {
  endpoint: string;
  sign_pub: string;
 }
 // RoomWire es la fila de room que devuelve el gateway (GET /api/rooms). No trae
 // mensajes: estos llegan por SSE (GET /api/rooms/{id}/stream).
 export interface RoomWire {
  id: string;
  subject: string;
  name: string;
  epoch: number;
  encrypt: boolean;
  persist: boolean;
  sign_msgs: boolean;
  role: string;
 }
 // MsgWire es un mensaje ya descifrado que el gateway empuja por SSE.
 export interface MsgWire {
  id: string;
  sender: string;
  body: string;
  ts: number;
  mine: boolean;
 }
@@ -3,5 +3,12 @@ import react from "@vitejs/plugin-react";
 export default defineConfig({
  plugins: [react()],
-  server: { host: true, port: 5181 },
+  // En dev, /api (REST + SSE) se proxea al gateway Go (cmd/webgw, puerto 8481).
  // El proxy hace streaming, así que el SSE de /api/rooms/{id}/stream funciona a
  // través de él. En producción el gateway sirve el dist embebido y no hay proxy.
  server: {
    host: true,
    port: 5181,
    proxy: { "/api": "http://127.0.0.1:8481" },
  },
 });
Author	SHA1	Message	Date
agent	5ea8fa1c20	feat(web): wire the SPA to the live bus via the gateway (drop mock) Replace the mock data source with a real data layer that talks to the webgw gateway over REST + SSE. The UI components keep their look and props; only where the data comes from changed. - src/api.ts: the single repository layer. fetch wrappers (same-origin cookie) for login/logout/me and rooms list/create/join/send, plus streamRoom() which opens an EventSource and yields each decrypted message. Wire->UI mappers (roomFromWire, messageFromWire). - src/types.ts: add the gateway wire shapes (MeInfo, RoomWire, MsgWire) next to the existing UI types. - App.tsx: probe /api/me on mount to resume an existing session; otherwise show Login. Logout calls the gateway. - Login.tsx: the password field now unlocks the gateway session (operator passphrase); shows a basic error and a loading state. Wallet-per-browser is phase 2. - ChatShell.tsx: load rooms from /api/rooms with loading / empty / error states; same Flex layout. - ChatPanel.tsx: stream messages over SSE for the active room (dedup by id), composer sends through the gateway; no optimistic insert (the peer's own echo returns over SSE with the real frame id). - vite.config.ts: dev proxy /api (REST + SSE) -> the gateway on :8481. mock.ts is left untouched (no longer imported) to avoid churn with the parallel styling work on master. Co-Authored-By: Claude Opus 4.8 (1M context) <noreply@anthropic.com>	2026-06-07 21:14:19 +02:00
agent	fb8a03cf0c	feat(webgw): web gateway peer (REST + SSE) for the chat SPA Add cmd/webgw: a single Go binary that holds the operator's bus identity, connects to the bus as a real authenticated peer (pkg/client), and exposes a small REST + SSE API the browser consumes. The browser never signs, never speaks NATS, and never sees a private key. Endpoints (all under /api, gated by a session cookie except login): POST /api/login unlock a session with the operator passphrase POST /api/logout GET /api/me operator identity the gateway acts as GET /api/rooms ListMyRooms POST /api/rooms CreateRoom (default policy: encrypted+persisted+signed) POST /api/rooms/{id}/join Join (fetch room key) POST /api/rooms/{id}/send Publish (sealed + signed by the peer) GET /api/rooms/{id}/stream SSE of decrypted frames (history then live) Design notes: - One fan-out hub per room: a single bus subscription is multiplexed to N SSE clients, avoiding the per-(room,endpoint) durable-consumer contention that multiple Subscribe calls would cause. - Posture seam mirrors unibus_admin/clientcheck: empty --ca = plaintext dev, non-empty = TLS+nkey on both planes; RefreshSession after a membership change only under the secured (ACL) posture. - Identity loaded from `pass` or a 0600 file, held only in memory. - Session auth: passphrase compared in constant time; opaque HttpOnly cookie so EventSource (which cannot set headers) can authenticate the stream. TRUST MODEL: room content stays end-to-end encrypted on the bus. The gateway reads plaintext only because it acts AS the operator's client — a legitimate member of each room holding the room key. The per-browser wallet (WebCrypto) that moves decryption into the browser is phase 2. Co-Authored-By: Claude Opus 4.8 (1M context) <noreply@anthropic.com>	2026-06-07 21:14:08 +02:00
egutierrez	b4f3118e85	Merge quick/users-http-admin: HTTP admin-only users API + client methods (report 0014)	2026-06-07 20:46:44 +02:00
egutierrez	e9053169da	Merge quick/0011-deploy-gaps: live user-add --store kv + clientcheck E2E + runbook fixes (report 0012)	2026-06-07 20:46:44 +02:00
Egutierrez	b983e43090	docs(0007): spec encryption-at-rest del control plane (JetStream/SQLite en disco)	2026-06-07 20:34:35 +02:00