Files
Commilitia-Drop/internal/httpapi/session.go
T
admin 90a3790a98 扫码登录:cdrop 自签会话原语 + 薄账户层 + 受限访客 + 2FA step-up
身份仍源自 OAuth provider(user_id = OIDC sub),cdrop 在其上自维护一薄层:
自签会话令牌 + accounts 表,并新增扫码快速登录。实施蓝本见 AUTH.md。

后端 · 自签会话原语
- web_sessions 加 kind/scope/granted_by 列(bootstrap 幂等迁移);既有 oidc
  会话行为不变,新增 self(滑动续期)/ guest(受限·不续)两类
- cdrop 自签 HS256 会话 access token,密钥派生自 SESSION_SECRET,与落盘 AES、
  shortcut HS256 三密钥域隔离;jwtauth.verifySelfToken 无状态校验、靠 typ 区分
- requireFullSession 守卫:guest 会话不得改账号 / 再批准设备 / 签长效 token
- /auth/refresh 按 kind 分流:self/guest 纯自签、不触 IdP

后端 · 扫码登录(internal/httpapi/qr.go)
- qr/start・status・request・approve・deny 五端点 + login_requests 表 + reaper
- 三密钥分离:QR 仅含批准信息,会话只投递给持私有 poll_secret 的原设备
  (偷拍 QR 者无 poll_secret 领不到会话、未登录批不了准)
- 会话在新设备侧领取(cookie 不经手机)、单次消费、短 TTL

后端 · 薄账户层与 2FA step-up
- accounts 表(键 sub,不含任何凭证):exchange/refresh upsert match_key /
  显示名 / 头像 / roles,供显示与未来管理员开启迁移标记时跨源关联
- step-up(默认关):开启后 qr/approve 要求新鲜 prompt=login 授权码,后端就地
  换 id_token、JWKS 验签 + auth_time 窗口 + sub 匹配,provider 2FA 于此往返强制

前端(web/)
- 显码页 /link/new + 批准页 /link + net/qr.ts,对齐 Theme B、复用 AuthShell
  与聚珍排版管线、零新全局样式
- step-up 再认证流:批准前跑 prompt=login PKCE,回调分叉(不消费一次性 code、
  独立 state key)后带 step_up_code/verifier 调 approve
- 三语 i18n qr.*;新增 qrcode 依赖

修复 · clipboard sweeper(早已提交的损坏)
- ClearExpiredClipboards 因 clipboard.sql 全角注释触发 sqlc 1.31 多字节偏移
  bug,生成 SQL 被截断为「UPDATE clipboard_state SET content =」,sweeper 运行
  期报「incomplete input」、过期剪贴板内容从未清除(短 TTL 暴露保护失效)
- 注释改纯 ASCII 并加 bug 警告,重生成得完整 SQL;prod 已验证 sweeper 由 ERROR
  转为正常清理(cleared count=1)

构建
- .dockerignore:排除本地 node_modules 等,避免宿主原生二进制污染镜像内 vite 构建
- Dockerfile.base:GOPROXY 改为可经 --build-arg 覆盖(默认仍官方代理,受限网络
  构建时传区域镜像即可,仓库不固化区域值)

文档
- 新增 AUTH.md(账户与登录实施蓝本);README 特性;.env.example /
  compose.snippet 增配置项(QR / 自签会话 TTL / step-up / match_claim)

测试
- 自签 token 密钥域隔离、扫码端到端(领取 / 单次 / poll_secret 校验 / deny /
  step-up 门)、extractIdentity、web_sessions 升级迁移
2026-06-21 22:43:36 +08:00

269 lines
8.2 KiB
Go

package httpapi
import (
"context"
"crypto/aes"
"crypto/cipher"
"crypto/rand"
"crypto/sha256"
"encoding/base64"
"encoding/hex"
"encoding/json"
"errors"
"io"
"log/slog"
"net/http"
"net/url"
"time"
"commilitia.net/cdrop/internal/db"
"commilitia.net/cdrop/internal/jwtauth"
)
// Browser "passwordless re-login" (web only — desktop persists its own
// refresh_token in the OS keyring and never touches these endpoints).
//
// The durable credential (Casdoor's ~15 KB refresh_token) stays server-side in
// web_sessions, encrypted at rest. The browser only ever holds an opaque cookie
// token whose SHA-256 is the row's primary key — so a leaked DB yields neither a
// usable cookie nor a decryptable token. The cookie is HttpOnly (XSS can't read
// it), Secure (HTTPS only), SameSite=Lax + Origin-checked (CSRF), and Path-scoped
// to /api/auth so it rides only these four endpoints, not every API call.
const (
sessionCookieName = "cdrop_session"
sessionCookiePath = "/api/auth"
// webSessionTTL is the sliding inactivity window: each refresh pushes
// expires_at this far forward. The effective cap is min(this, the IdP's own
// refresh_token validity) — once Casdoor retires the refresh_token, refresh
// 401s and the user re-logs in regardless.
webSessionTTL = 7 * 24 * time.Hour
// refreshLockStripes bounds the per-session refresh lock set (see Server).
refreshLockStripes = 256
)
// lockRefresh serialises refreshes of one session id, returning the unlock fn.
// Callers must re-read the session row after acquiring it: a concurrent refresh
// may have already rotated the refresh_token.
func (s *Server) lockRefresh(id string) func() {
idx := stripeIndex(id)
s.refreshLocks[idx].Lock()
return func() { s.refreshLocks[idx].Unlock() }
}
// stripeIndex folds a session id into a stripe with FNV-1a — bounded, no cleanup.
func stripeIndex(id string) int {
var h uint32 = 2166136261
for i := 0; i < len(id); i++ {
h = (h ^ uint32(id[i])) * 16777619
}
return int(h % refreshLockStripes)
}
// deriveSessionKey turns a config secret of any length into a 32-byte AES key
// (mirrors jwtauth.DeriveHS256Key). Empty secret → nil (feature disabled).
func deriveSessionKey(secret string) []byte {
if secret == "" {
return nil
}
sum := sha256.Sum256([]byte(secret))
return sum[:]
}
// deriveSiteOrigin extracts scheme://host from the configured redirect_uri to
// give the CSRF Origin check a fixed expected value. Empty (dev) disables it.
func deriveSiteOrigin(redirectURI string) string {
if redirectURI == "" {
return ""
}
u, err := url.Parse(redirectURI)
if err != nil || u.Scheme == "" || u.Host == "" {
return ""
}
return u.Scheme + "://" + u.Host
}
// newSessionToken mints a fresh opaque cookie token plus its storage id. raw
// goes in Set-Cookie; id (hex SHA-256 of raw) is the DB key, so the stored row
// never contains a usable cookie value.
func newSessionToken() (raw, id string, err error) {
b := make([]byte, 32)
if _, err := rand.Read(b); err != nil {
return "", "", err
}
raw = base64.RawURLEncoding.EncodeToString(b)
return raw, sessionID(raw), nil
}
func sessionID(raw string) string {
sum := sha256.Sum256([]byte(raw))
return hex.EncodeToString(sum[:])
}
// encryptRefresh seals a refresh_token with AES-256-GCM. Output is
// base64(nonce || ciphertext+tag); the key is s.sessionKey (env-derived).
func (s *Server) encryptRefresh(plain string) (string, error) {
if len(s.sessionKey) == 0 {
return "", errors.New("session key not configured")
}
gcm, err := newGCM(s.sessionKey)
if err != nil {
return "", err
}
nonce := make([]byte, gcm.NonceSize())
if _, err := rand.Read(nonce); err != nil {
return "", err
}
ct := gcm.Seal(nonce, nonce, []byte(plain), nil)
return base64.StdEncoding.EncodeToString(ct), nil
}
func (s *Server) decryptRefresh(enc string) (string, error) {
if len(s.sessionKey) == 0 {
return "", errors.New("session key not configured")
}
raw, err := base64.StdEncoding.DecodeString(enc)
if err != nil {
return "", err
}
gcm, err := newGCM(s.sessionKey)
if err != nil {
return "", err
}
if len(raw) < gcm.NonceSize() {
return "", errors.New("ciphertext too short")
}
nonce, ct := raw[:gcm.NonceSize()], raw[gcm.NonceSize():]
plain, err := gcm.Open(nil, nonce, ct, nil)
if err != nil {
return "", err
}
return string(plain), nil
}
func newGCM(key []byte) (cipher.AEAD, error) {
block, err := aes.NewCipher(key)
if err != nil {
return nil, err
}
return cipher.NewGCM(block)
}
func setSessionCookie(w http.ResponseWriter, raw string) {
http.SetCookie(w, &http.Cookie{
Name: sessionCookieName,
Value: raw,
Path: sessionCookiePath,
MaxAge: int(webSessionTTL / time.Second),
HttpOnly: true,
Secure: true,
SameSite: http.SameSiteLaxMode,
})
}
func clearSessionCookie(w http.ResponseWriter) {
http.SetCookie(w, &http.Cookie{
Name: sessionCookieName,
Value: "",
Path: sessionCookiePath,
MaxAge: -1,
HttpOnly: true,
Secure: true,
SameSite: http.SameSiteLaxMode,
})
}
// sameOrigin is belt-and-suspenders CSRF defence atop SameSite=Lax: when the
// browser sends an Origin header (always, on fetch POST) it must match the
// deployment's own origin. Absent Origin (non-browser clients) is allowed, as is
// an unconfigured site origin (dev).
func (s *Server) sameOrigin(r *http.Request) bool {
origin := r.Header.Get("Origin")
if origin == "" || s.siteOrigin == "" {
return true
}
return origin == s.siteOrigin
}
// handleAuthLogout destroys the server-side session and clears the cookie.
// Cookie-authenticated (no bearer): the cookie is the only thing that proves
// which session to drop.
func (s *Server) handleAuthLogout(w http.ResponseWriter, r *http.Request) {
if c, err := r.Cookie(sessionCookieName); err == nil && c.Value != "" {
if err := s.queries.DeleteWebSession(r.Context(), sessionID(c.Value)); err != nil {
slog.Warn("web session delete failed", "err", err)
}
}
clearSessionCookie(w)
w.WriteHeader(http.StatusNoContent)
}
type sessionDeviceReq struct {
DeviceName string `json:"device_name"`
}
// handleAuthDevice persists this browser's device name into its session row so
// it survives PWA storage eviction: on the next boot, /auth/refresh hands the
// name back and the client re-hydrates selfDeviceName without a trip to /setup.
func (s *Server) handleAuthDevice(w http.ResponseWriter, r *http.Request) {
if !s.sameOrigin(r) {
writeJSON(w, http.StatusForbidden, map[string]string{"error": "bad origin"})
return
}
c, err := r.Cookie(sessionCookieName)
if err != nil || c.Value == "" {
writeJSON(w, http.StatusUnauthorized, map[string]string{"error": "no session"})
return
}
var req sessionDeviceReq
if err := json.NewDecoder(io.LimitReader(r.Body, 4096)).Decode(&req); err != nil {
writeJSON(w, http.StatusBadRequest, map[string]string{"error": "invalid json"})
return
}
name := jwtauth.SanitizeDeviceName(req.DeviceName)
if name == "" {
writeJSON(w, http.StatusBadRequest, map[string]string{"error": "empty device name"})
return
}
if err := s.queries.SetWebSessionDevice(r.Context(), db.SetWebSessionDeviceParams{
DeviceName: name,
ID: sessionID(c.Value),
}); err != nil {
slog.Error("set web session device failed", "err", err)
writeJSON(w, http.StatusInternalServerError, map[string]string{"error": "persist failed"})
return
}
w.WriteHeader(http.StatusNoContent)
}
// RunWebSessionReaper periodically reclaims expired web_sessions rows. Lazy
// deletion on access covers the hot path; this sweeps sessions that simply go
// idle and are never touched again.
func RunWebSessionReaper(ctx context.Context, q *db.Queries) {
ticker := time.NewTicker(1 * time.Hour)
defer ticker.Stop()
for {
select {
case <-ctx.Done():
return
case <-ticker.C:
now := time.Now().Unix()
n, err := q.DeleteExpiredWebSessions(ctx, now)
if err != nil {
slog.Warn("web session reaper failed", "err", err)
} else if n > 0 {
slog.Info("web sessions reaped", "count", n)
}
// Scan-login requests are short-lived (default 120s); sweep the
// stragglers here too. Expired rows are already rejected at use time.
if n, err := q.DeleteExpiredLoginRequests(ctx, now); err != nil {
slog.Warn("login request reaper failed", "err", err)
} else if n > 0 {
slog.Info("login requests reaped", "count", n)
}
}
}
}