package vault import ( "context" "encoding/base64" "encoding/hex" "errors" "fmt" "net/url" "sync/atomic" wrapping "github.com/hashicorp/go-kms-wrapping" "github.com/hashicorp/vault/physical/raft" "github.com/hashicorp/vault/vault/seal" "github.com/hashicorp/errwrap" aeadwrapper "github.com/hashicorp/go-kms-wrapping/wrappers/aead" "github.com/hashicorp/vault/helper/namespace" "github.com/hashicorp/vault/helper/pgpkeys" "github.com/hashicorp/vault/shamir" ) // InitParams keeps the init function from being littered with too many // params, that's it! type InitParams struct { BarrierConfig *SealConfig RecoveryConfig *SealConfig RootTokenPGPKey string // LegacyShamirSeal should only be used in test code, we don't want to // give the user a way to create legacy shamir seals. LegacyShamirSeal bool } // InitResult is used to provide the key parts back after // they are generated as part of the initialization. type InitResult struct { SecretShares [][]byte RecoveryShares [][]byte RootToken string } var ( initPTFunc = func(c *Core) func() { return nil } initInProgress uint32 ) func (c *Core) InitializeRecovery(ctx context.Context) error { if !c.recoveryMode { return nil } raftStorage, ok := c.underlyingPhysical.(*raft.RaftBackend) if !ok { return nil } parsedClusterAddr, err := url.Parse(c.ClusterAddr()) if err != nil { return err } c.postRecoveryUnsealFuncs = append(c.postRecoveryUnsealFuncs, func() error { return raftStorage.StartRecoveryCluster(context.Background(), raft.Peer{ ID: raftStorage.NodeID(), Address: parsedClusterAddr.Host, }) }) return nil } // Initialized checks if the Vault is already initialized func (c *Core) Initialized(ctx context.Context) (bool, error) { // Check the barrier first init, err := c.barrier.Initialized(ctx) if err != nil { c.logger.Error("barrier init check failed", "error", err) return false, err } if !init { c.logger.Info("security barrier not initialized") return false, nil } // Verify the seal configuration sealConf, err := c.seal.BarrierConfig(ctx) if err != nil { return false, err } if sealConf == nil { return false, fmt.Errorf("core: barrier reports initialized but no seal configuration found") } return true, nil } func (c *Core) generateShares(sc *SealConfig) ([]byte, [][]byte, error) { // Generate a master key masterKey, err := c.barrier.GenerateKey(c.secureRandomReader) if err != nil { return nil, nil, errwrap.Wrapf("key generation failed: {{err}}", err) } // Return the master key if only a single key part is used var unsealKeys [][]byte if sc.SecretShares == 1 { unsealKeys = append(unsealKeys, masterKey) } else { // Split the master key using the Shamir algorithm shares, err := shamir.Split(masterKey, sc.SecretShares, sc.SecretThreshold) if err != nil { return nil, nil, errwrap.Wrapf("failed to generate barrier shares: {{err}}", err) } unsealKeys = shares } // If we have PGP keys, perform the encryption if len(sc.PGPKeys) > 0 { hexEncodedShares := make([][]byte, len(unsealKeys)) for i, _ := range unsealKeys { hexEncodedShares[i] = []byte(hex.EncodeToString(unsealKeys[i])) } _, encryptedShares, err := pgpkeys.EncryptShares(hexEncodedShares, sc.PGPKeys) if err != nil { return nil, nil, err } unsealKeys = encryptedShares } return masterKey, unsealKeys, nil } // Initialize is used to initialize the Vault with the given // configurations. func (c *Core) Initialize(ctx context.Context, initParams *InitParams) (*InitResult, error) { atomic.StoreUint32(&initInProgress, 1) defer atomic.StoreUint32(&initInProgress, 0) barrierConfig := initParams.BarrierConfig recoveryConfig := initParams.RecoveryConfig // N.B. Although the core is capable of handling situations where some keys // are stored and some aren't, in practice, replication + HSMs makes this // extremely hard to reason about, to the point that it will probably never // be supported. The reason is that each HSM needs to encode the master key // separately, which means the shares must be generated independently, // which means both that the shares will be different *AND* there would // need to be a way to actually allow fetching of the generated keys by // operators. if c.SealAccess().StoredKeysSupported() == seal.StoredKeysSupportedGeneric { if len(barrierConfig.PGPKeys) > 0 { return nil, fmt.Errorf("PGP keys not supported when storing shares") } barrierConfig.SecretShares = 1 barrierConfig.SecretThreshold = 1 if barrierConfig.StoredShares != 1 { c.Logger().Warn("stored keys supported on init, forcing shares/threshold to 1") } } if initParams.LegacyShamirSeal { barrierConfig.StoredShares = 0 } else { barrierConfig.StoredShares = 1 } if len(barrierConfig.PGPKeys) > 0 && len(barrierConfig.PGPKeys) != barrierConfig.SecretShares { return nil, fmt.Errorf("incorrect number of PGP keys") } if c.SealAccess().RecoveryKeySupported() { if len(recoveryConfig.PGPKeys) > 0 && len(recoveryConfig.PGPKeys) != recoveryConfig.SecretShares { return nil, fmt.Errorf("incorrect number of PGP keys for recovery") } } if c.seal.RecoveryKeySupported() { if recoveryConfig == nil { return nil, fmt.Errorf("recovery configuration must be supplied") } if recoveryConfig.SecretShares < 1 { return nil, fmt.Errorf("recovery configuration must specify a positive number of shares") } // Check if the seal configuration is valid if err := recoveryConfig.Validate(); err != nil { c.logger.Error("invalid recovery configuration", "error", err) return nil, errwrap.Wrapf("invalid recovery configuration: {{err}}", err) } } // Check if the seal configuration is valid if err := barrierConfig.Validate(); err != nil { c.logger.Error("invalid seal configuration", "error", err) return nil, errwrap.Wrapf("invalid seal configuration: {{err}}", err) } // Avoid an initialization race c.stateLock.Lock() defer c.stateLock.Unlock() // Check if we are initialized init, err := c.Initialized(ctx) if err != nil { return nil, err } if init { return nil, ErrAlreadyInit } // If we have clustered storage, set it up now if raftStorage, ok := c.underlyingPhysical.(*raft.RaftBackend); ok { parsedClusterAddr, err := url.Parse(c.ClusterAddr()) if err != nil { return nil, errwrap.Wrapf("error parsing cluster address: {{err}}", err) } if err := raftStorage.Bootstrap(ctx, []raft.Peer{ { ID: raftStorage.NodeID(), Address: parsedClusterAddr.Host, }, }); err != nil { return nil, errwrap.Wrapf("could not bootstrap clustered storage: {{err}}", err) } if err := raftStorage.SetupCluster(ctx, raft.SetupOpts{ StartAsLeader: true, }); err != nil { return nil, errwrap.Wrapf("could not start clustered storage: {{err}}", err) } defer func() { if err := raftStorage.TeardownCluster(nil); err != nil { c.logger.Error("failed to stop raft storage", "error", err) } }() } err = c.seal.Init(ctx) if err != nil { c.logger.Error("failed to initialize seal", "error", err) return nil, errwrap.Wrapf("error initializing seal: {{err}}", err) } initPTCleanup := initPTFunc(c) if initPTCleanup != nil { defer initPTCleanup() } barrierKey, barrierKeyShares, err := c.generateShares(barrierConfig) if err != nil { c.logger.Error("error generating shares", "error", err) return nil, err } var sealKey []byte var sealKeyShares [][]byte if barrierConfig.StoredShares == 1 && c.seal.BarrierType() == wrapping.Shamir { sealKey, sealKeyShares, err = c.generateShares(barrierConfig) if err != nil { c.logger.Error("error generating shares", "error", err) return nil, err } } // Initialize the barrier if err := c.barrier.Initialize(ctx, barrierKey, sealKey, c.secureRandomReader); err != nil { c.logger.Error("failed to initialize barrier", "error", err) return nil, errwrap.Wrapf("failed to initialize barrier: {{err}}", err) } if c.logger.IsInfo() { c.logger.Info("security barrier initialized", "stored", barrierConfig.StoredShares, "shares", barrierConfig.SecretShares, "threshold", barrierConfig.SecretThreshold) } // Unseal the barrier if err := c.barrier.Unseal(ctx, barrierKey); err != nil { c.logger.Error("failed to unseal barrier", "error", err) return nil, errwrap.Wrapf("failed to unseal barrier: {{err}}", err) } // Ensure the barrier is re-sealed defer func() { // Defers are LIFO so we need to run this here too to ensure the stop // happens before sealing. preSeal also stops, so we just make the // stopping safe against multiple calls. if err := c.barrier.Seal(); err != nil { c.logger.Error("failed to seal barrier", "error", err) } }() err = c.seal.SetBarrierConfig(ctx, barrierConfig) if err != nil { c.logger.Error("failed to save barrier configuration", "error", err) return nil, errwrap.Wrapf("barrier configuration saving failed: {{err}}", err) } results := &InitResult{ SecretShares: [][]byte{}, } // If we are storing shares, pop them out of the returned results and push // them through the seal switch c.seal.StoredKeysSupported() { case seal.StoredKeysSupportedShamirMaster: keysToStore := [][]byte{barrierKey} if err := c.seal.GetAccess().Wrapper.(*aeadwrapper.Wrapper).SetAESGCMKeyBytes(sealKey); err != nil { c.logger.Error("failed to set seal key", "error", err) return nil, errwrap.Wrapf("failed to set seal key: {{err}}", err) } if err := c.seal.SetStoredKeys(ctx, keysToStore); err != nil { c.logger.Error("failed to store keys", "error", err) return nil, errwrap.Wrapf("failed to store keys: {{err}}", err) } results.SecretShares = sealKeyShares case seal.StoredKeysSupportedGeneric: keysToStore := [][]byte{barrierKey} if err := c.seal.SetStoredKeys(ctx, keysToStore); err != nil { c.logger.Error("failed to store keys", "error", err) return nil, errwrap.Wrapf("failed to store keys: {{err}}", err) } default: // We don't support initializing an old-style Shamir seal anymore, so // this case is only reachable by tests. results.SecretShares = barrierKeyShares } // Perform initial setup if err := c.setupCluster(ctx); err != nil { c.logger.Error("cluster setup failed during init", "error", err) return nil, err } // Start tracking if initPTCleanup != nil { initPTCleanup() } activeCtx, ctxCancel := context.WithCancel(namespace.RootContext(nil)) if err := c.postUnseal(activeCtx, ctxCancel, standardUnsealStrategy{}); err != nil { c.logger.Error("post-unseal setup failed during init", "error", err) return nil, err } // Save the configuration regardless, but only generate a key if it's not // disabled. When using recovery keys they are stored in the barrier, so // this must happen post-unseal. if c.seal.RecoveryKeySupported() { err = c.seal.SetRecoveryConfig(ctx, recoveryConfig) if err != nil { c.logger.Error("failed to save recovery configuration", "error", err) return nil, errwrap.Wrapf("recovery configuration saving failed: {{err}}", err) } if recoveryConfig.SecretShares > 0 { recoveryKey, recoveryUnsealKeys, err := c.generateShares(recoveryConfig) if err != nil { c.logger.Error("failed to generate recovery shares", "error", err) return nil, err } err = c.seal.SetRecoveryKey(ctx, recoveryKey) if err != nil { return nil, err } results.RecoveryShares = recoveryUnsealKeys } } // Generate a new root token rootToken, err := c.tokenStore.rootToken(ctx) if err != nil { c.logger.Error("root token generation failed", "error", err) return nil, err } results.RootToken = rootToken.ID c.logger.Info("root token generated") if initParams.RootTokenPGPKey != "" { _, encryptedVals, err := pgpkeys.EncryptShares([][]byte{[]byte(results.RootToken)}, []string{initParams.RootTokenPGPKey}) if err != nil { c.logger.Error("root token encryption failed", "error", err) return nil, err } results.RootToken = base64.StdEncoding.EncodeToString(encryptedVals[0]) } if err := c.createRaftTLSKeyring(ctx); err != nil { c.logger.Error("failed to create raft TLS keyring", "error", err) return nil, err } // Prepare to re-seal if err := c.preSeal(); err != nil { c.logger.Error("pre-seal teardown failed", "error", err) return nil, err } if c.serviceRegistration != nil { if err := c.serviceRegistration.NotifyInitializedStateChange(true); err != nil { if c.logger.IsWarn() { c.logger.Warn("notification of initialization failed", "error", err) } } } return results, nil } // UnsealWithStoredKeys performs auto-unseal using stored keys. An error // return value of "nil" implies the Vault instance is unsealed. // // Callers should attempt to retry any NonFatalErrors. Callers should // not re-attempt fatal errors. func (c *Core) UnsealWithStoredKeys(ctx context.Context) error { c.unsealWithStoredKeysLock.Lock() defer c.unsealWithStoredKeysLock.Unlock() if c.seal.BarrierType() == wrapping.Shamir { return nil } // Disallow auto-unsealing when migrating if c.IsInSealMigration() { return NewNonFatalError(errors.New("cannot auto-unseal during seal migration")) } sealed := c.Sealed() if !sealed { c.Logger().Warn("attempted unseal with stored keys, but vault is already unsealed") return nil } c.Logger().Info("stored unseal keys supported, attempting fetch") keys, err := c.seal.GetStoredKeys(ctx) if err != nil { return NewNonFatalError(errwrap.Wrapf("fetching stored unseal keys failed: {{err}}", err)) } // This usually happens when auto-unseal is configured, but the servers have // not been initialized yet. if len(keys) == 0 { return NewNonFatalError(errors.New("stored unseal keys are supported, but none were found")) } unsealed := false keysUsed := 0 for _, key := range keys { unsealed, err = c.Unseal(key) if err != nil { return NewNonFatalError(errwrap.Wrapf("unseal with stored key failed: {{err}}", err)) } keysUsed++ if unsealed { break } } if !unsealed { // This most likely means that the user configured Vault to only store a // subset of the required threshold of keys. We still consider this a // "success", since trying again would yield the same result. c.Logger().Warn("vault still sealed after using stored unseal keys", "stored_keys_used", keysUsed) } else { c.Logger().Info("unsealed with stored keys", "stored_keys_used", keysUsed) } return nil }