package vault import ( "encoding/json" "fmt" "log" "os" "path" "strings" "sync" "time" "github.com/hashicorp/vault/logical" ) const ( // expirationSubPath is the sub-path used for the expiration manager // view. This is nested under the system view. expirationSubPath = "expire/" // maxRevokeAttempts limits how many revoke attempts are made maxRevokeAttempts = 6 // revokeRetryBase is a baseline retry time revokeRetryBase = 10 * time.Second // minRevokeDelay is used to prevent an instant revoke on restore minRevokeDelay = 5 * time.Second ) // ExpirationManager is used by the Core to manage leases. Secrets // can provide a lease, meaning that they can be renewed or revoked. // If a secret is not renewed in timely manner, it may be expired, and // the ExpirationManager will handle doing automatic revocation. type ExpirationManager struct { router *Router view *BarrierView tokenStore *TokenStore logger *log.Logger pending map[string]*time.Timer pendingLock sync.Mutex } // NewExpirationManager creates a new ExpirationManager that is backed // using a given view, and uses the provided router for revocation. func NewExpirationManager(router *Router, view *BarrierView, ts *TokenStore, logger *log.Logger) *ExpirationManager { if logger == nil { logger = log.New(os.Stderr, "", log.LstdFlags) } exp := &ExpirationManager{ router: router, view: view, tokenStore: ts, logger: logger, pending: make(map[string]*time.Timer), } return exp } // setupExpiration is invoked after we've loaded the mount table to // initialize the expiration manager func (c *Core) setupExpiration() error { // Create a sub-view view := c.systemView.SubView(expirationSubPath) // Create the manager mgr := NewExpirationManager(c.router, view, c.tokenStore, c.logger) c.expiration = mgr // Restore the existing state if err := c.expiration.Restore(); err != nil { return fmt.Errorf("expiration state restore failed: %v", err) } return nil } // stopExpiration is used to stop the expiration manager before // sealing the Vault. func (c *Core) stopExpiration() error { if err := c.expiration.Stop(); err != nil { return err } c.expiration = nil return nil } // Restore is used to recover the lease states when starting. // This is used after starting the vault. func (m *ExpirationManager) Restore() error { m.pendingLock.Lock() defer m.pendingLock.Unlock() // Accumulate existing leases existing, err := CollectKeys(m.view) if err != nil { return fmt.Errorf("failed to scan for leases: %v", err) } // Restore each key for _, vaultID := range existing { // Load the entry le, err := m.loadEntry(vaultID) if err != nil { return err } // If there is no entry, nothing to restore if le == nil { continue } // If there is no expiry time, don't do anything if le.ExpireTime.IsZero() { continue } // Determine the remaining time to expiration expires := le.ExpireTime.Sub(time.Now().UTC()) if expires <= 0 { expires = minRevokeDelay } // Setup revocation timer m.pending[le.VaultID] = time.AfterFunc(expires, func() { m.expireID(le.VaultID) }) } if len(m.pending) > 0 { m.logger.Printf("[INFO] expire: restored %d leases", len(m.pending)) } return nil } // Stop is used to prevent further automatic revocations. // This must be called before sealing the view. func (m *ExpirationManager) Stop() error { // Stop all the pending expiration timers m.pendingLock.Lock() for _, timer := range m.pending { timer.Stop() } m.pending = make(map[string]*time.Timer) m.pendingLock.Unlock() return nil } // Revoke is used to revoke a secret named by the given vaultID func (m *ExpirationManager) Revoke(vaultID string) error { // Load the entry le, err := m.loadEntry(vaultID) if err != nil { return err } // If there is no entry, nothing to revoke if le == nil { return nil } // Revoke the entry if err := m.revokeEntry(le); err != nil { return err } // Delete the entry if err := m.deleteEntry(vaultID); err != nil { return err } // Clear the expiration handler m.pendingLock.Lock() if timer, ok := m.pending[vaultID]; ok { timer.Stop() delete(m.pending, vaultID) } m.pendingLock.Unlock() return nil } // RevokePrefix is used to revoke all secrets with a given prefix. // The prefix maps to that of the mount table to make this simpler // to reason about. func (m *ExpirationManager) RevokePrefix(prefix string) error { // Ensure there is a trailing slash if !strings.HasSuffix(prefix, "/") { prefix = prefix + "/" } // Accumulate existing leases sub := m.view.SubView(prefix) existing, err := CollectKeys(sub) if err != nil { return fmt.Errorf("failed to scan for leases: %v", err) } // Revoke all the keys for idx, suffix := range existing { vaultID := prefix + suffix if err := m.Revoke(vaultID); err != nil { return fmt.Errorf("failed to revoke '%s' (%d / %d): %v", vaultID, idx+1, len(existing), err) } } return nil } // Renew is used to renew a secret using the given vaultID // and a renew interval. The increment may be ignored. func (m *ExpirationManager) Renew(vaultID string, increment time.Duration) (*logical.Response, error) { // Load the entry le, err := m.loadEntry(vaultID) if err != nil { return nil, err } // If there is no entry, cannot review if le == nil { return nil, fmt.Errorf("lease not found") } // Determine if the lease is expired if le.ExpireTime.Before(time.Now().UTC()) { return nil, fmt.Errorf("lease expired") } // Attempt to renew the entry resp, err := m.renewEntry(le, increment) if err != nil { return nil, err } // Fast-path if there is no lease if resp == nil || resp.Secret == nil || resp.Secret.Lease == 0 { return resp, nil } // Validate the lease if err := resp.Secret.Validate(); err != nil { return nil, err } // Attach the VaultID resp.Secret.VaultID = vaultID // Update the lease entry var expireTime time.Time leaseTotal := resp.Secret.Lease + resp.Secret.LeaseGracePeriod if resp.Secret.Lease > 0 { expireTime = time.Now().UTC().Add(leaseTotal) } le.Data = resp.Data le.Secret = resp.Secret le.ExpireTime = expireTime if err := m.persistEntry(le); err != nil { return nil, err } // Update the expiration time m.pendingLock.Lock() if timer, ok := m.pending[vaultID]; ok { timer.Reset(leaseTotal) } m.pendingLock.Unlock() // Return the response return resp, nil } // Register is used to take a request and response with an associated // lease. The secret gets assigned a vaultId and the management of // of lease is assumed by the expiration manager. func (m *ExpirationManager) Register(req *logical.Request, resp *logical.Response) (string, error) { // Ignore if there is no leased secret if resp == nil || resp.Secret == nil { return "", nil } // Validate the secret if err := resp.Secret.Validate(); err != nil { return "", err } // Create a lease entry now := time.Now().UTC() leaseTotal := resp.Secret.Lease + resp.Secret.LeaseGracePeriod var expireTime time.Time if resp.Secret.Lease > 0 { expireTime = now.Add(leaseTotal) } le := leaseEntry{ VaultID: path.Join(req.Path, generateUUID()), Path: req.Path, Data: resp.Data, Secret: resp.Secret, IssueTime: now, ExpireTime: expireTime, } // Encode the entry if err := m.persistEntry(&le); err != nil { return "", err } // Setup revocation timer if there is a lease if !expireTime.IsZero() { m.pendingLock.Lock() m.pending[le.VaultID] = time.AfterFunc(leaseTotal, func() { m.expireID(le.VaultID) }) m.pendingLock.Unlock() } // Done return le.VaultID, nil } /* // RegisterLogin is used to take a credential request and response with // an associated lease. The secret gets assigned a vaultId and the management of // of lease is assumed by the expiration manager. This is distinct from Register // as the behavior of renew and revocation differs a bit. func (m *ExpirationManager) RegisterLogin(token string, req *credential.Request, resp *credential.Response) (string, error) { // Ignore if there is no leased secret if resp == nil || resp.Secret == nil || resp.Secret.Lease == 0 { return "", nil } // Validate the secret if err := resp.Secret.Validate(); err != nil { return "", err } // Create a lease entry now := time.Now().UTC() leaseTotal := resp.Secret.Lease + resp.Secret.LeaseGracePeriod le := leaseEntry{ VaultID: path.Join(req.Path, generateUUID()), LoginToken: token, Path: req.Path, Data: resp.Data, Secret: resp.Secret, IssueTime: now, ExpireTime: now.Add(leaseTotal), } // Encode the entry if err := m.persistEntry(&le); err != nil { return "", err } // Setup revocation timer m.pendingLock.Lock() m.pending[le.VaultID] = time.AfterFunc(leaseTotal, func() { m.expireID(le.VaultID) }) m.pendingLock.Unlock() // Done return le.VaultID, nil } */ // expireID is invoked when a given ID is expired func (m *ExpirationManager) expireID(vaultID string) { // Clear from the pending expiration m.pendingLock.Lock() delete(m.pending, vaultID) m.pendingLock.Unlock() for attempt := uint(0); attempt < maxRevokeAttempts; attempt++ { err := m.Revoke(vaultID) if err == nil { m.logger.Printf("[INFO] expire: revoked '%s'", vaultID) return } m.logger.Printf("[ERR] expire: failed to revoke '%s': %v", vaultID, err) time.Sleep((1 << attempt) * revokeRetryBase) } m.logger.Printf("[ERR] expire: maximum revoke attempts for '%s' reached", vaultID) } // revokeEntry is used to attempt revocation of an internal entry func (m *ExpirationManager) revokeEntry(le *leaseEntry) error { // Revocation of login tokens is special since we can by-pass the // backend and directly interact with the token store if le.LoginToken != "" { if err := m.tokenStore.RevokeTree(le.LoginToken); err != nil { return fmt.Errorf("failed to revoke token: %v", err) } return nil } // Handle standard revocation via backends _, err := m.router.Route(logical.RevokeRequest( le.Path, le.Secret, le.Data)) if err != nil { return fmt.Errorf("failed to revoke entry: %v", err) } return nil } // renewEntry is used to attempt renew of an internal entry func (m *ExpirationManager) renewEntry(le *leaseEntry, increment time.Duration) (*logical.Response, error) { secret := *le.Secret secret.LeaseIncrement = increment secret.VaultID = "" resp, err := m.router.Route(logical.RenewRequest( le.Path, &secret, le.Data)) if err != nil { return nil, fmt.Errorf("failed to renew entry: %v", err) } return resp, nil } // loadEntry is used to read a lease entry func (m *ExpirationManager) loadEntry(vaultID string) (*leaseEntry, error) { out, err := m.view.Get(vaultID) if err != nil { return nil, fmt.Errorf("failed to read lease entry: %v", err) } if out == nil { return nil, nil } le, err := decodeLeaseEntry(out.Value) if err != nil { return nil, fmt.Errorf("failed to decode lease entry: %v", err) } return le, nil } // persistEntry is used to persist a lease entry func (m *ExpirationManager) persistEntry(le *leaseEntry) error { // Encode the entry buf, err := le.encode() if err != nil { return fmt.Errorf("failed to encode lease entry: %v", err) } // Write out to the view ent := logical.StorageEntry{ Key: le.VaultID, Value: buf, } if err := m.view.Put(&ent); err != nil { return fmt.Errorf("failed to persist lease entry: %v", err) } return nil } // deleteEntry is used to delete a lease entry func (m *ExpirationManager) deleteEntry(vaultID string) error { if err := m.view.Delete(vaultID); err != nil { return fmt.Errorf("failed to delete lease entry: %v", err) } return nil } // leaseEntry is used to structure the values the expiration // manager stores. This is used to handle renew and revocation. type leaseEntry struct { VaultID string `json:"vault_id"` LoginToken string `json:"login_token"` Path string `json:"path"` Data map[string]interface{} `json:"data"` Secret *logical.Secret `json:"secret"` IssueTime time.Time `json:"issue_time"` ExpireTime time.Time `json:"expire_time"` } // encode is used to JSON encode the lease entry func (l *leaseEntry) encode() ([]byte, error) { return json.Marshal(l) } // decodeLeaseEntry is used to reverse encode and return a new entry func decodeLeaseEntry(buf []byte) (*leaseEntry, error) { out := new(leaseEntry) return out, json.Unmarshal(buf, out) }