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Package vault

v1.1.0
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The latest major version is .

Published: Mar 18, 2019 | License: MPL-2.0 | Module: github.com/conversable/vault

Index

Constants

const (
	AESGCMVersion1 = 0x1
	AESGCMVersion2 = 0x2
)

Versions of the AESGCM storage methodology

const (
	CORSDisabled uint32 = iota
	CORSEnabled
)
const (
	DenyCapability   = "deny"
	CreateCapability = "create"
	ReadCapability   = "read"
	UpdateCapability = "update"
	DeleteCapability = "delete"
	ListCapability   = "list"
	SudoCapability   = "sudo"
	RootCapability   = "root"

	// Backwards compatibility
	OldDenyPathPolicy  = "deny"
	OldReadPathPolicy  = "read"
	OldWritePathPolicy = "write"
	OldSudoPathPolicy  = "sudo"
)
const (
	DenyCapabilityInt uint32 = 1 << iota
	CreateCapabilityInt
	ReadCapabilityInt
	UpdateCapabilityInt
	DeleteCapabilityInt
	ListCapabilityInt
	SudoCapabilityInt
)
const (

	// PerformanceReplicationALPN is the negotiated protocol used for
	// performance replication.
	PerformanceReplicationALPN = "replication_v1"

	// DRReplicationALPN is the negotiated protocol used for
	// dr replication.
	DRReplicationALPN = "replication_dr_v1"
)
const (
	RecoveryTypeUnsupported = "unsupported"
	RecoveryTypeShamir      = "shamir"
)
const (
	// CoreLockPath is the path used to acquire a coordinating lock
	// for a highly-available deploy.
	CoreLockPath = "core/lock"
)
const (

	// Internal so as not to log a trace message
	IntNoForwardingHeaderName = "X-Vault-Internal-No-Request-Forwarding"
)
const (

	// StoredBarrierKeysPath is the path used for storing HSM-encrypted unseal keys
	StoredBarrierKeysPath = "core/hsm/barrier-unseal-keys"
)

Variables

var (
	// ErrBarrierSealed is returned if an operation is performed on
	// a sealed barrier. No operation is expected to succeed before unsealing
	ErrBarrierSealed = errors.New("Vault is sealed")

	// ErrBarrierAlreadyInit is returned if the barrier is already
	// initialized. This prevents a re-initialization.
	ErrBarrierAlreadyInit = errors.New("Vault is already initialized")

	// ErrBarrierNotInit is returned if a non-initialized barrier
	// is attempted to be unsealed.
	ErrBarrierNotInit = errors.New("Vault is not initialized")

	// ErrBarrierInvalidKey is returned if the Unseal key is invalid
	ErrBarrierInvalidKey = errors.New("Unseal failed, invalid key")
)
var (
	// ErrAlreadyInit is returned if the core is already
	// initialized. This prevents a re-initialization.
	ErrAlreadyInit = errors.New("Vault is already initialized")

	// ErrNotInit is returned if a non-initialized barrier
	// is attempted to be unsealed.
	ErrNotInit = errors.New("Vault is not initialized")

	// ErrInternalError is returned when we don't want to leak
	// any information about an internal error
	ErrInternalError = errors.New("internal error")

	// ErrHANotEnabled is returned if the operation only makes sense
	// in an HA setting
	ErrHANotEnabled = errors.New("Vault is not configured for highly-available mode")

	LastWAL             = lastWALImpl
	LastRemoteWAL       = lastRemoteWALImpl
	WaitUntilWALShipped = waitUntilWALShippedImpl
)
var (
	ErrDirectoryNotConfigured = errors.New("could not set plugin, plugin directory is not configured")
	ErrPluginNotFound         = errors.New("plugin not found in the catalog")
	ErrPluginBadType          = errors.New("unable to determine plugin type")
)
var (
	TestCoreUnsealedWithConfigs = testCoreUnsealedWithConfigs
	TestSealDefConfigs          = testSealDefConfigs
)
var (
	// DefaultMaxRequestDuration is the amount of time we'll wait for a request
	// to complete, unless overridden on a per-handler basis
	DefaultMaxRequestDuration = 90 * time.Second
)
var DefaultNumCores = 3
var (
	ErrCannotForward = errors.New("cannot forward request; no connection or address not known")
)
var (
	// Making this a package var allows tests to modify
	HeartbeatInterval = 5 * time.Second
)
var (
	NamespaceByID func(context.Context, string, *Core) (*namespace.Namespace, error) = namespaceByID
)
var StdAllowedHeaders = []string{
	"Content-Type",
	"X-Requested-With",
	"X-Vault-AWS-IAM-Server-ID",
	"X-Vault-MFA",
	"X-Vault-No-Request-Forwarding",
	"X-Vault-Wrap-Format",
	"X-Vault-Wrap-TTL",
	"X-Vault-Policy-Override",
	"Authorization",
	consts.AuthHeaderName,
}
var (
	// TokenLength is the size of tokens we are currently generating, without
	// any namespace information
	TokenLength = 24
)

func AddTestCredentialBackend

func AddTestCredentialBackend(name string, factory logical.Factory) error

This adds a credential backend for the test core. This needs to be invoked before the test core is created.

func AddTestLogicalBackend

func AddTestLogicalBackend(name string, factory logical.Factory) error

This adds a logical backend for the test core. This needs to be invoked before the test core is created.

func CleanupClusters

func CleanupClusters(clusters []*TestCluster)

func CubbyholeBackendFactory

func CubbyholeBackendFactory(ctx context.Context, conf *logical.BackendConfig) (logical.Backend, error)

CubbyholeBackendFactory constructs a new cubbyhole backend

func GenerateRandBytes

func GenerateRandBytes(length int) ([]byte, error)

func IsFatalError

func IsFatalError(err error) bool

IsFatalError returns true if the given error is a non-fatal error.

func LeaseSwitchedPassthroughBackend

func LeaseSwitchedPassthroughBackend(ctx context.Context, conf *logical.BackendConfig, leases bool) (logical.Backend, error)

LeaseSwitchedPassthroughBackend returns a PassthroughBackend with leases switched on or off

func LeasedPassthroughBackendFactory

func LeasedPassthroughBackendFactory(ctx context.Context, conf *logical.BackendConfig) (logical.Backend, error)

LeasedPassthroughBackendFactory returns a PassthroughBackend with leases switched on

func NewMockBuiltinRegistry

func NewMockBuiltinRegistry() *mockBuiltinRegistry

func NewRequestForwardingHandler

func NewRequestForwardingHandler(c *Core, fws *http2.Server, perfStandbySlots chan struct{}, perfStandbyRepCluster *replication.Cluster, perfStandbyCache *cache.Cache) (*requestForwardingHandler, error)

NewRequestForwardingHandler creates a cluster handler for use with request forwarding.

func NewSealUnwrapper

func NewSealUnwrapper(underlying physical.Backend, logger log.Logger) physical.Backend

NewSealUnwrapper creates a new seal unwrapper

func PassthroughBackendFactory

func PassthroughBackendFactory(ctx context.Context, conf *logical.BackendConfig) (logical.Backend, error)

PassthroughBackendFactory returns a PassthroughBackend with leases switched off

func RegisterRequestForwardingServer

func RegisterRequestForwardingServer(s *grpc.Server, srv RequestForwardingServer)

func SetReplicationFailureMode

func SetReplicationFailureMode(core *TestClusterCore, mode uint32)

func StartSSHHostTestServer

func StartSSHHostTestServer() (string, error)

StartSSHHostTestServer starts the test server which responds to SSH authentication. Used to test the SSH secret backend.

func TestAddTestPlugin

func TestAddTestPlugin(t testing.T, c *Core, name string, pluginType consts.PluginType, testFunc string, env []string, tempDir string)

TestAddTestPlugin registers the testFunc as part of the plugin command to the plugin catalog. If provided, uses tmpDir as the plugin directory.

func TestCoreInit

func TestCoreInit(t testing.T, core *Core) ([][]byte, string)

TestCoreInit initializes the core with a single key, and returns the key that must be used to unseal the core and a root token.

func TestCoreInitClusterWrapperSetup

func TestCoreInitClusterWrapperSetup(t testing.T, core *Core, clusterAddrs []*net.TCPAddr, handler http.Handler) ([][]byte, [][]byte, string)

func TestCoreUnseal

func TestCoreUnseal(core *Core, key []byte) (bool, error)

func TestCoreUnsealWithRecoveryKeys

func TestCoreUnsealWithRecoveryKeys(core *Core, key []byte) (bool, error)

func TestDynamicSystemView

func TestDynamicSystemView(c *Core) *dynamicSystemView

func TestKeyCopy

func TestKeyCopy(key []byte) []byte

TestKeyCopy is a silly little function to just copy the key so that it can be used with Unseal easily.

func TestWaitActive

func TestWaitActive(t testing.T, core *Core)

func TestWaitActiveWithError

func TestWaitActiveWithError(core *Core) error

type ACL

type ACL struct {
	// contains filtered or unexported fields
}

ACL is used to wrap a set of policies to provide an efficient interface for access control.

func NewACL

func NewACL(ctx context.Context, policies []*Policy) (*ACL, error)

NewACL is used to construct a policy based ACL from a set of policies.

func (*ACL) AllowOperation

func (a *ACL) AllowOperation(ctx context.Context, req *logical.Request, capCheckOnly bool) (ret *ACLResults)

AllowOperation is used to check if the given operation is permitted.

func (*ACL) Capabilities

func (a *ACL) Capabilities(ctx context.Context, path string) (pathCapabilities []string)

type ACLPermissions

type ACLPermissions struct {
	CapabilitiesBitmap uint32
	MinWrappingTTL     time.Duration
	MaxWrappingTTL     time.Duration
	AllowedParameters  map[string][]interface{}
	DeniedParameters   map[string][]interface{}
	RequiredParameters []string
	MFAMethods         []string
	ControlGroup       *ControlGroup
}

func (*ACLPermissions) Clone

func (p *ACLPermissions) Clone() (*ACLPermissions, error)

type ACLResults

type ACLResults struct {
	Allowed            bool
	RootPrivs          bool
	IsRoot             bool
	MFAMethods         []string
	ControlGroup       *ControlGroup
	CapabilitiesBitmap uint32
}

type AESGCMBarrier

type AESGCMBarrier struct {
	// contains filtered or unexported fields
}

AESGCMBarrier is a SecurityBarrier implementation that uses the AES cipher core and the Galois Counter Mode block mode. It defaults to the golang NONCE default value of 12 and a key size of 256 bit. AES-GCM is high performance, and provides both confidentiality and integrity.

func NewAESGCMBarrier

func NewAESGCMBarrier(physical physical.Backend) (*AESGCMBarrier, error)

NewAESGCMBarrier is used to construct a new barrier that uses the provided physical backend for storage.

func (*AESGCMBarrier) ActiveKeyInfo

func (b *AESGCMBarrier) ActiveKeyInfo() (*KeyInfo, error)

ActiveKeyInfo is used to inform details about the active key

func (*AESGCMBarrier) CheckUpgrade

func (b *AESGCMBarrier) CheckUpgrade(ctx context.Context) (bool, uint32, error)

CheckUpgrade looks for an upgrade to the current term and installs it

func (*AESGCMBarrier) CreateUpgrade

func (b *AESGCMBarrier) CreateUpgrade(ctx context.Context, term uint32) error

CreateUpgrade creates an upgrade path key to the given term from the previous term

func (*AESGCMBarrier) Decrypt

func (b *AESGCMBarrier) Decrypt(ctx context.Context, key string, ciphertext []byte) ([]byte, error)

Decrypt is used to decrypt in-memory for the BarrierEncryptor interface

func (*AESGCMBarrier) Delete

func (b *AESGCMBarrier) Delete(ctx context.Context, key string) error

Delete is used to permanently delete an entry

func (*AESGCMBarrier) DestroyUpgrade

func (b *AESGCMBarrier) DestroyUpgrade(ctx context.Context, term uint32) error

DestroyUpgrade destroys the upgrade path key to the given term

func (*AESGCMBarrier) Encrypt

func (b *AESGCMBarrier) Encrypt(ctx context.Context, key string, plaintext []byte) ([]byte, error)

Encrypt is used to encrypt in-memory for the BarrierEncryptor interface

func (*AESGCMBarrier) GenerateKey

func (b *AESGCMBarrier) GenerateKey() ([]byte, error)

GenerateKey is used to generate a new key

func (*AESGCMBarrier) Get

func (b *AESGCMBarrier) Get(ctx context.Context, key string) (*logical.StorageEntry, error)

Get is used to fetch an entry

func (*AESGCMBarrier) Initialize

func (b *AESGCMBarrier) Initialize(ctx context.Context, key []byte) error

Initialize works only if the barrier has not been initialized and makes use of the given master key.

func (*AESGCMBarrier) Initialized

func (b *AESGCMBarrier) Initialized(ctx context.Context) (bool, error)

Initialized checks if the barrier has been initialized and has a master key set.

func (*AESGCMBarrier) KeyLength

func (b *AESGCMBarrier) KeyLength() (int, int)

KeyLength is used to sanity check a key

func (*AESGCMBarrier) Keyring

func (b *AESGCMBarrier) Keyring() (*Keyring, error)

func (*AESGCMBarrier) List

func (b *AESGCMBarrier) List(ctx context.Context, prefix string) ([]string, error)

List is used ot list all the keys under a given prefix, up to the next prefix.

func (*AESGCMBarrier) Put

func (b *AESGCMBarrier) Put(ctx context.Context, entry *logical.StorageEntry) error

Put is used to insert or update an entry

func (*AESGCMBarrier) Rekey

func (b *AESGCMBarrier) Rekey(ctx context.Context, key []byte) error

Rekey is used to change the master key used to protect the keyring

func (*AESGCMBarrier) ReloadKeyring

func (b *AESGCMBarrier) ReloadKeyring(ctx context.Context) error

ReloadKeyring is used to re-read the underlying keyring. This is used for HA deployments to ensure the latest keyring is present in the leader.

func (*AESGCMBarrier) ReloadMasterKey

func (b *AESGCMBarrier) ReloadMasterKey(ctx context.Context) error

ReloadMasterKey is used to re-read the underlying masterkey. This is used for HA deployments to ensure the latest master key is available for keyring reloading.

func (*AESGCMBarrier) Rotate

func (b *AESGCMBarrier) Rotate(ctx context.Context) (uint32, error)

Rotate is used to create a new encryption key. All future writes should use the new key, while old values should still be decryptable.

func (*AESGCMBarrier) Seal

func (b *AESGCMBarrier) Seal() error

Seal is used to re-seal the barrier. This requires the barrier to be unsealed again to perform any further operations.

func (*AESGCMBarrier) Sealed

func (b *AESGCMBarrier) Sealed() (bool, error)

Sealed checks if the barrier has been unlocked yet. The Barrier is not expected to be able to perform any CRUD until it is unsealed.

func (*AESGCMBarrier) SetMasterKey

func (b *AESGCMBarrier) SetMasterKey(key []byte) error

SetMasterKey updates the keyring's in-memory master key but does not persist anything to storage

func (*AESGCMBarrier) Unseal

func (b *AESGCMBarrier) Unseal(ctx context.Context, key []byte) error

Unseal is used to provide the master key which permits the barrier to be unsealed. If the key is not correct, the barrier remains sealed.

func (*AESGCMBarrier) VerifyMaster

func (b *AESGCMBarrier) VerifyMaster(key []byte) error

VerifyMaster is used to check if the given key matches the master key

type APIMountConfig

type APIMountConfig struct {
	DefaultLeaseTTL           string                `json:"default_lease_ttl" structs:"default_lease_ttl" mapstructure:"default_lease_ttl"`
	MaxLeaseTTL               string                `json:"max_lease_ttl" structs:"max_lease_ttl" mapstructure:"max_lease_ttl"`
	ForceNoCache              bool                  `json:"force_no_cache" structs:"force_no_cache" mapstructure:"force_no_cache"`
	AuditNonHMACRequestKeys   []string              `json:"audit_non_hmac_request_keys,omitempty" structs:"audit_non_hmac_request_keys" mapstructure:"audit_non_hmac_request_keys"`
	AuditNonHMACResponseKeys  []string              "" /* 128 byte string literal not displayed */
	ListingVisibility         ListingVisibilityType `json:"listing_visibility,omitempty" structs:"listing_visibility" mapstructure:"listing_visibility"`
	PassthroughRequestHeaders []string              `json:"passthrough_request_headers,omitempty" structs:"passthrough_request_headers" mapstructure:"passthrough_request_headers"`
	AllowedResponseHeaders    []string              `json:"allowed_response_headers,omitempty" structs:"allowed_response_headers" mapstructure:"allowed_response_headers"`
	TokenType                 string                `json:"token_type" structs:"token_type" mapstructure:"token_type"`

	PluginName string `json:"plugin_name,omitempty" structs:"plugin_name,omitempty" mapstructure:"plugin_name"`
}

APIMountConfig is an embedded struct of api.MountConfigInput

type AuditBroker

type AuditBroker struct {
	sync.RWMutex
	// contains filtered or unexported fields
}

AuditBroker is used to provide a single ingest interface to auditable events given that multiple backends may be configured.

func NewAuditBroker

func NewAuditBroker(log log.Logger) *AuditBroker

NewAuditBroker creates a new audit broker

func (*AuditBroker) Deregister

func (a *AuditBroker) Deregister(name string)

Deregister is used to remove an audit backend from the broker

func (*AuditBroker) GetHash

func (a *AuditBroker) GetHash(ctx context.Context, name string, input string) (string, error)

GetHash returns a hash using the salt of the given backend

func (*AuditBroker) Invalidate

func (a *AuditBroker) Invalidate(ctx context.Context, key string)

func (*AuditBroker) IsLocal

func (a *AuditBroker) IsLocal(name string) (bool, error)

IsLocal is used to check if a given audit backend is registered

func (*AuditBroker) IsRegistered

func (a *AuditBroker) IsRegistered(name string) bool

IsRegistered is used to check if a given audit backend is registered

func (*AuditBroker) LogRequest

func (a *AuditBroker) LogRequest(ctx context.Context, in *audit.LogInput, headersConfig *AuditedHeadersConfig) (ret error)

LogRequest is used to ensure all the audit backends have an opportunity to log the given request and that *at least one* succeeds.

func (*AuditBroker) LogResponse

func (a *AuditBroker) LogResponse(ctx context.Context, in *audit.LogInput, headersConfig *AuditedHeadersConfig) (ret error)

LogResponse is used to ensure all the audit backends have an opportunity to log the given response and that *at least one* succeeds.

func (*AuditBroker) Register

func (a *AuditBroker) Register(name string, b audit.Backend, v *BarrierView, local bool)

Register is used to add new audit backend to the broker

type AuditedHeadersConfig

type AuditedHeadersConfig struct {
	Headers map[string]*auditedHeaderSettings

	sync.RWMutex
	// contains filtered or unexported fields
}

AuditedHeadersConfig is used by the Audit Broker to write only approved headers to the audit logs. It uses a BarrierView to persist the settings.

func (*AuditedHeadersConfig) ApplyConfig

func (a *AuditedHeadersConfig) ApplyConfig(ctx context.Context, headers map[string][]string, hashFunc func(context.Context, string) (string, error)) (result map[string][]string, retErr error)

ApplyConfig returns a map of approved headers and their values, either hmac'ed or plaintext

type AuthResults

type AuthResults struct {
	ACLResults  *ACLResults
	Allowed     bool
	RootPrivs   bool
	DeniedError bool
	Error       *multierror.Error
}

type BarrierEncryptor

type BarrierEncryptor interface {
	Encrypt(ctx context.Context, key string, plaintext []byte) ([]byte, error)
	Decrypt(ctx context.Context, key string, ciphertext []byte) ([]byte, error)
}

BarrierEncryptor is the in memory only interface that does not actually use the underlying barrier. It is used for lower level modules like the Write-Ahead-Log and Merkle index to allow them to use the barrier.

type BarrierEncryptorAccess

type BarrierEncryptorAccess struct {
	// contains filtered or unexported fields
}

BarrierEncryptorAccess is a wrapper around BarrierEncryptor that allows Core to expose its barrier encrypt/decrypt operations through BarrierEncryptorAccess() while restricting the ability to modify Core.barrier itself.

func NewBarrierEncryptorAccess

func NewBarrierEncryptorAccess(barrierEncryptor BarrierEncryptor) *BarrierEncryptorAccess

func (*BarrierEncryptorAccess) Decrypt

func (b *BarrierEncryptorAccess) Decrypt(ctx context.Context, key string, ciphertext []byte) ([]byte, error)

func (*BarrierEncryptorAccess) Encrypt

func (b *BarrierEncryptorAccess) Encrypt(ctx context.Context, key string, plaintext []byte) ([]byte, error)

type BarrierStorage

type BarrierStorage interface {
	// Put is used to insert or update an entry
	Put(ctx context.Context, entry *logical.StorageEntry) error

	// Get is used to fetch an entry
	Get(ctx context.Context, key string) (*logical.StorageEntry, error)

	// Delete is used to permanently delete an entry
	Delete(ctx context.Context, key string) error

	// List is used ot list all the keys under a given
	// prefix, up to the next prefix.
	List(ctx context.Context, prefix string) ([]string, error)
}

BarrierStorage is the storage only interface required for a Barrier.

type BarrierView

type BarrierView struct {
	// contains filtered or unexported fields
}

BarrierView wraps a SecurityBarrier and ensures all access is automatically prefixed. This is used to prevent anyone with access to the view to access any data in the durable storage outside of their prefix. Conceptually this is like a "chroot" into the barrier.

BarrierView implements logical.Storage so it can be passed in as the durable storage mechanism for logical views.

func NewBarrierView

func NewBarrierView(barrier logical.Storage, prefix string) *BarrierView

NewBarrierView takes an underlying security barrier and returns a view of it that can only operate with the given prefix.

func (*BarrierView) Delete

func (v *BarrierView) Delete(ctx context.Context, key string) error

logical.Storage impl.

func (*BarrierView) Get

func (v *BarrierView) Get(ctx context.Context, key string) (*logical.StorageEntry, error)

func (*BarrierView) List

func (v *BarrierView) List(ctx context.Context, prefix string) ([]string, error)

func (*BarrierView) Prefix

func (v *BarrierView) Prefix() string

func (*BarrierView) Put

func (v *BarrierView) Put(ctx context.Context, entry *logical.StorageEntry) error

Put differs from List/Get because it checks read-only errors

func (*BarrierView) SubView

func (v *BarrierView) SubView(prefix string) *BarrierView

SubView constructs a nested sub-view using the given prefix

type BuiltinRegistry

type BuiltinRegistry interface {
	Contains(name string, pluginType consts.PluginType) bool
	Get(name string, pluginType consts.PluginType) (func() (interface{}, error), bool)
	Keys(pluginType consts.PluginType) []string
}

BuiltinRegistry is an interface that allows the "vault" package to use the registry of builtin plugins without getting an import cycle. It also allows for mocking the registry easily.

type CORSConfig

type CORSConfig struct {
	sync.RWMutex `json:"-"`

	Enabled        *uint32  `json:"enabled"`
	AllowedOrigins []string `json:"allowed_origins,omitempty"`
	AllowedHeaders []string `json:"allowed_headers,omitempty"`
	// contains filtered or unexported fields
}

CORSConfig stores the state of the CORS configuration.

func (*CORSConfig) Disable

func (c *CORSConfig) Disable(ctx context.Context) error

Disable sets CORS to disabled and clears the allowed origins & headers.

func (*CORSConfig) Enable

func (c *CORSConfig) Enable(ctx context.Context, urls []string, headers []string) error

Enable takes either a '*' or a comma-separated list of URLs that can make cross-origin requests to Vault.

func (*CORSConfig) IsEnabled

func (c *CORSConfig) IsEnabled() bool

IsEnabled returns the value of CORSConfig.isEnabled

func (*CORSConfig) IsValidOrigin

func (c *CORSConfig) IsValidOrigin(origin string) bool

IsValidOrigin determines if the origin of the request is allowed to make cross-origin requests based on the CORSConfig.

type ClientKey

type ClientKey struct {
	Type                 string   `protobuf:"bytes,1,opt,name=type,proto3" json:"type,omitempty"`
	X                    []byte   `protobuf:"bytes,2,opt,name=x,proto3" json:"x,omitempty"`
	Y                    []byte   `protobuf:"bytes,3,opt,name=y,proto3" json:"y,omitempty"`
	D                    []byte   `protobuf:"bytes,4,opt,name=d,proto3" json:"d,omitempty"`
	XXX_NoUnkeyedLiteral struct{} `json:"-"`
	XXX_unrecognized     []byte   `json:"-"`
	XXX_sizecache        int32    `json:"-"`
}

func (*ClientKey) Descriptor

func (*ClientKey) Descriptor() ([]byte, []int)

func (*ClientKey) GetD

func (m *ClientKey) GetD() []byte

func (*ClientKey) GetType

func (m *ClientKey) GetType() string

func (*ClientKey) GetX

func (m *ClientKey) GetX() []byte

func (*ClientKey) GetY

func (m *ClientKey) GetY() []byte

func (*ClientKey) ProtoMessage

func (*ClientKey) ProtoMessage()

func (*ClientKey) Reset

func (m *ClientKey) Reset()

func (*ClientKey) String

func (m *ClientKey) String() string

func (*ClientKey) XXX_DiscardUnknown

func (m *ClientKey) XXX_DiscardUnknown()

func (*ClientKey) XXX_Marshal

func (m *ClientKey) XXX_Marshal(b []byte, deterministic bool) ([]byte, error)

func (*ClientKey) XXX_Merge

func (m *ClientKey) XXX_Merge(src proto.Message)

func (*ClientKey) XXX_Size

func (m *ClientKey) XXX_Size() int

func (*ClientKey) XXX_Unmarshal

func (m *ClientKey) XXX_Unmarshal(b []byte) error

type Cluster

type Cluster struct {
	// Name of the cluster
	Name string `json:"name" structs:"name" mapstructure:"name"`

	// Identifier of the cluster
	ID string `json:"id" structs:"id" mapstructure:"id"`
}

Structure representing the storage entry that holds cluster information

type ClusterClient

type ClusterClient interface {
	ClientLookup(context.Context, *tls.CertificateRequestInfo) (*tls.Certificate, error)
}

ClusterClient is used to lookup a client certificate.

type ClusterHandler

type ClusterHandler interface {
	ServerLookup(context.Context, *tls.ClientHelloInfo) (*tls.Certificate, error)
	CALookup(context.Context) (*x509.Certificate, error)

	// Handoff is used to pass the connection lifetime off to
	// the handler
	Handoff(context.Context, *sync.WaitGroup, chan struct{}, *tls.Conn) error
	Stop() error
}

ClusterHandler exposes functions for looking up TLS configuration and handing off a connection for a cluster listener application.

type ClusterLeaderParams

type ClusterLeaderParams struct {
	LeaderUUID         string
	LeaderRedirectAddr string
	LeaderClusterAddr  string
}

type ClusterListener

type ClusterListener struct {
	// contains filtered or unexported fields
}

ClusterListener is the source of truth for cluster handlers and connection clients. It dynamically builds the cluster TLS information. It's also responsible for starting tcp listeners and accepting new cluster connections.

func (*ClusterListener) AddClient

func (cl *ClusterListener) AddClient(alpn string, client ClusterClient)

AddClient adds a new client for an ALPN name

func (*ClusterListener) AddHandler

func (cl *ClusterListener) AddHandler(alpn string, handler ClusterHandler)

AddHandler registers a new cluster handler for the provided ALPN name.

func (*ClusterListener) RemoveClient

func (cl *ClusterListener) RemoveClient(alpn string)

RemoveClient removes the client for the specified ALPN name

func (*ClusterListener) Run

func (cl *ClusterListener) Run(ctx context.Context) error

Run starts the tcp listeners and will accept connections until stop is called. This function blocks so should be called in a go routine.

func (*ClusterListener) Server

func (cl *ClusterListener) Server() *http2.Server

Server returns the http2 server that the cluster listener is using

func (*ClusterListener) Stop

func (cl *ClusterListener) Stop()

Stop stops the cluster listner

func (*ClusterListener) StopHandler

func (cl *ClusterListener) StopHandler(alpn string)

StopHandler stops the cluster handler for the provided ALPN name, it also calls stop on the handler.

func (*ClusterListener) TLSConfig

func (cl *ClusterListener) TLSConfig(ctx context.Context) (*tls.Config, error)

TLSConfig returns a tls config object that uses dynamic lookups to correctly authenticate registered handlers/clients

type ControlGroup

type ControlGroup struct {
	TTL     time.Duration
	Factors []*ControlGroupFactor
}

type ControlGroupFactor

type ControlGroupFactor struct {
	Name     string
	Identity *IdentityFactor `hcl:"identity"`
}

type ControlGroupHCL

type ControlGroupHCL struct {
	TTL     interface{}                    `hcl:"ttl"`
	Factors map[string]*ControlGroupFactor `hcl:"factor"`
}

type Core

type Core struct {
	// contains filtered or unexported fields
}

Core is used as the central manager of Vault activity. It is the primary point of interface for API handlers and is responsible for managing the logical and physical backends, router, security barrier, and audit trails.

func NewCore

func NewCore(conf *CoreConfig) (*Core, error)

NewCore is used to construct a new core

func TestCore

func TestCore(t testing.T) *Core

TestCore returns a pure in-memory, uninitialized core for testing.

func TestCoreNewSeal

func TestCoreNewSeal(t testing.T) *Core

TestCoreNewSeal returns a pure in-memory, uninitialized core with the new seal configuration.

func TestCoreRaw

func TestCoreRaw(t testing.T) *Core

TestCoreRaw returns a pure in-memory, uninitialized core for testing. The raw storage endpoints are enabled with this core.

func TestCoreUI

func TestCoreUI(t testing.T, enableUI bool) *Core

func TestCoreUnsealed

func TestCoreUnsealed(t testing.T) (*Core, [][]byte, string)

TestCoreUnsealed returns a pure in-memory core that is already initialized and unsealed.

func TestCoreUnsealedBackend

func TestCoreUnsealedBackend(t testing.T, backend physical.Backend) (*Core, [][]byte, string)

func TestCoreUnsealedRaw

func TestCoreUnsealedRaw(t testing.T) (*Core, [][]byte, string)

TestCoreUnsealedRaw returns a pure in-memory core that is already initialized, unsealed, and with raw endpoints enabled.

func TestCoreUnsealedWithConfig

func TestCoreUnsealedWithConfig(t testing.T, conf *CoreConfig) (*Core, [][]byte, string)

TestCoreUnsealedWithConfig returns a pure in-memory core that is already initialized, unsealed, with the any provided core config values overridden.

func TestCoreUnsealedWithConfigSealOpts

func TestCoreUnsealedWithConfigSealOpts(t testing.T, barrierConf, recoveryConf *SealConfig, sealOpts *TestSealOpts) (*Core, [][]byte, [][]byte, string)

func TestCoreWithConfig

func TestCoreWithConfig(t testing.T, conf *CoreConfig) *Core

TestCoreWithConfig returns a pure in-memory, uninitialized core with the specified core configurations overridden for testing.

func TestCoreWithSeal

func TestCoreWithSeal(t testing.T, testSeal Seal, enableRaw bool) *Core

TestCoreWithSeal returns a pure in-memory, uninitialized core with the specified seal for testing.

func TestCoreWithSealAndUI

func TestCoreWithSealAndUI(t testing.T, opts *CoreConfig) *Core

func (*Core) ActiveNodeReplicationState

func (c *Core) ActiveNodeReplicationState() consts.ReplicationState

func (*Core) AddLogger

func (c *Core) AddLogger(logger log.Logger)

func (*Core) AuditedHeadersConfig

func (c *Core) AuditedHeadersConfig() *AuditedHeadersConfig

func (*Core) BarrierEncryptorAccess

func (c *Core) BarrierEncryptorAccess() *BarrierEncryptorAccess

func (*Core) BarrierKeyLength

func (c *Core) BarrierKeyLength() (min, max int)

func (*Core) BarrierRekeyInit

func (c *Core) BarrierRekeyInit(config *SealConfig) logical.HTTPCodedError

BarrierRekeyInit is used to initialize the rekey settings for the barrier key

func (*Core) BarrierRekeyUpdate

func (c *Core) BarrierRekeyUpdate(ctx context.Context, key []byte, nonce string) (*RekeyResult, logical.HTTPCodedError)

BarrierRekeyUpdate is used to provide a new key part. Barrier rekey can be done with unseal keys, or recovery keys if that's supported and we are storing the barrier key.

N.B.: If recovery keys are used to rekey, the new barrier key shares are not returned.

func (*Core) CORSConfig

func (c *Core) CORSConfig() *CORSConfig

CORSConfig returns the current CORS configuration

func (*Core) Capabilities

func (c *Core) Capabilities(ctx context.Context, token, path string) ([]string, error)

Capabilities is used to fetch the capabilities of the given token on the given path

func (*Core) Cluster

func (c *Core) Cluster(ctx context.Context) (*Cluster, error)

Cluster fetches the details of the local cluster. This method errors out when Vault is sealed.

func (*Core) Features

func (c *Core) Features() license.Features

func (*Core) ForwardRequest

func (c *Core) ForwardRequest(req *http.Request) (int, http.Header, []byte, error)

ForwardRequest forwards a given request to the active node and returns the response.

func (*Core) GenerateRootCancel

func (c *Core) GenerateRootCancel() error

GenerateRootCancel is used to cancel an in-progress root generation

func (*Core) GenerateRootConfiguration

func (c *Core) GenerateRootConfiguration() (*GenerateRootConfig, error)

GenerateRootConfiguration is used to read the root generation configuration It stubbornly refuses to return the OTP if one is there.

func (*Core) GenerateRootInit

func (c *Core) GenerateRootInit(otp, pgpKey string, strategy GenerateRootStrategy) error

GenerateRootInit is used to initialize the root generation settings

func (*Core) GenerateRootProgress

func (c *Core) GenerateRootProgress() (int, error)

GenerateRootProgress is used to return the root generation progress (num shares)

func (*Core) GenerateRootUpdate

func (c *Core) GenerateRootUpdate(ctx context.Context, key []byte, nonce string, strategy GenerateRootStrategy) (*GenerateRootResult, error)

GenerateRootUpdate is used to provide a new key part

func (*Core) GetContext

func (c *Core) GetContext() (context.Context, context.CancelFunc)

func (*Core) HandleRequest

func (c *Core) HandleRequest(httpCtx context.Context, req *logical.Request) (resp *logical.Response, err error)

HandleRequest is used to handle a new incoming request

func (*Core) HasFeature

func (c *Core) HasFeature(license.Features) bool

func (*Core) IdentityStore

func (c *Core) IdentityStore() *IdentityStore

func (*Core) Initialize

func (c *Core) Initialize(ctx context.Context, initParams *InitParams) (*InitResult, error)

Initialize is used to initialize the Vault with the given configurations.

func (*Core) Initialized

func (c *Core) Initialized(ctx context.Context) (bool, error)

Initialized checks if the Vault is already initialized

func (*Core) IsBatchTokenCreationRequest

func (c *Core) IsBatchTokenCreationRequest(ctx context.Context, path string) (bool, error)

func (*Core) IsDRSecondary

func (c *Core) IsDRSecondary() bool

IsDRSecondary returns if the current cluster state is a DR secondary.

func (*Core) IsInSealMigration

func (c *Core) IsInSealMigration() bool

func (*Core) Leader

func (c *Core) Leader() (isLeader bool, leaderAddr, clusterAddr string, err error)

Leader is used to get the current active leader

func (*Core) Logger

func (c *Core) Logger() log.Logger

func (*Core) LookupToken

func (c *Core) LookupToken(ctx context.Context, token string) (*logical.TokenEntry, error)

LookupToken returns the properties of the token from the token store. This is particularly useful to fetch the accessor of the client token and get it populated in the logical request along with the client token. The accessor of the client token can get audit logged.

func (*Core) PerfStandby

func (c *Core) PerfStandby() bool

PerfStandby checks if the vault is a performance standby

func (*Core) PhysicalAccess

func (c *Core) PhysicalAccess() *physical.PhysicalAccess

func (*Core) PhysicalSealConfigs

func (c *Core) PhysicalSealConfigs(ctx context.Context) (*SealConfig, *SealConfig, error)

func (*Core) RecoveryRekeyInit

func (c *Core) RecoveryRekeyInit(config *SealConfig) logical.HTTPCodedError

RecoveryRekeyInit is used to initialize the rekey settings for the recovery key

func (*Core) RecoveryRekeyUpdate

func (c *Core) RecoveryRekeyUpdate(ctx context.Context, key []byte, nonce string) (*RekeyResult, logical.HTTPCodedError)

RecoveryRekeyUpdate is used to provide a new key part

func (*Core) RegisterAuth

func (c *Core) RegisterAuth(ctx context.Context, tokenTTL time.Duration, path string, auth *logical.Auth) error

func (*Core) RekeyCancel

func (c *Core) RekeyCancel(recovery bool) logical.HTTPCodedError

RekeyCancel is used to cancel an in-progress rekey

func (*Core) RekeyConfig

func (c *Core) RekeyConfig(recovery bool) (*SealConfig, logical.HTTPCodedError)

RekeyConfig is used to read the rekey configuration

func (*Core) RekeyDeleteBackup

func (c *Core) RekeyDeleteBackup(ctx context.Context, recovery bool) logical.HTTPCodedError

RekeyDeleteBackup is used to delete any backed-up PGP-encrypted unseal keys

func (*Core) RekeyInit

func (c *Core) RekeyInit(config *SealConfig, recovery bool) logical.HTTPCodedError

RekeyInit will either initialize the rekey of barrier or recovery key. recovery determines whether this is a rekey on the barrier or recovery key.

func (*Core) RekeyProgress

func (c *Core) RekeyProgress(recovery, verification bool) (bool, int, logical.HTTPCodedError)

RekeyProgress is used to return the rekey progress (num shares).

func (*Core) RekeyRetrieveBackup

func (c *Core) RekeyRetrieveBackup(ctx context.Context, recovery bool) (*RekeyBackup, logical.HTTPCodedError)

RekeyRetrieveBackup is used to retrieve any backed-up PGP-encrypted unseal keys

func (*Core) RekeyThreshold

func (c *Core) RekeyThreshold(ctx context.Context, recovery bool) (int, logical.HTTPCodedError)

RekeyThreshold returns the secret threshold for the current seal config. This threshold can either be the barrier key threshold or the recovery key threshold, depending on whether rekey is being performed on the recovery key, or whether the seal supports recovery keys.

func (*Core) RekeyUpdate

func (c *Core) RekeyUpdate(ctx context.Context, key []byte, nonce string, recovery bool) (*RekeyResult, logical.HTTPCodedError)

RekeyUpdate is used to provide a new key part for the barrier or recovery key.

func (*Core) RekeyVerify

func (c *Core) RekeyVerify(ctx context.Context, key []byte, nonce string, recovery bool) (ret *RekeyVerifyResult, retErr logical.HTTPCodedError)

func (*Core) RekeyVerifyRestart

func (c *Core) RekeyVerifyRestart(recovery bool) logical.HTTPCodedError

RekeyVerifyRestart is used to start the verification process over

func (*Core) ReplicationState

func (c *Core) ReplicationState() consts.ReplicationState

func (*Core) ResetUnsealProcess

func (c *Core) ResetUnsealProcess()

ResetUnsealProcess removes the current unlock parts from memory, to reset the unsealing process

func (*Core) RouterAccess

func (c *Core) RouterAccess() *RouterAccess

func (*Core) Seal

func (c *Core) Seal(token string) error

Seal takes in a token and creates a logical.Request, acquires the lock, and passes through to sealInternal

func (*Core) SealAccess

func (c *Core) SealAccess() *SealAccess

func (*Core) SealWithRequest

func (c *Core) SealWithRequest(httpCtx context.Context, req *logical.Request) error

SealWithRequest takes in a logical.Request, acquires the lock, and passes through to sealInternal

func (*Core) Sealed

func (c *Core) Sealed() bool

Sealed checks if the Vault is current sealed

func (*Core) SecretProgress

func (c *Core) SecretProgress() (int, string)

SecretProgress returns the number of keys provided so far

func (*Core) SetClusterHandler

func (c *Core) SetClusterHandler(handler http.Handler)

func (*Core) SetClusterListenerAddrs

func (c *Core) SetClusterListenerAddrs(addrs []*net.TCPAddr)

func (*Core) SetLoadCaseSensitiveIdentityStore

func (c *Core) SetLoadCaseSensitiveIdentityStore(caseSensitive bool)

func (*Core) SetLogLevel

func (c *Core) SetLogLevel(level log.Level)

func (*Core) SetNeverBecomeActive

func (c *Core) SetNeverBecomeActive(on bool)

func (*Core) SetSealsForMigration

func (c *Core) SetSealsForMigration(migrationSeal, newSeal, unwrapSeal Seal)

func (*Core) Shutdown

func (c *Core) Shutdown() error

Shutdown is invoked when the Vault instance is about to be terminated. It should not be accessible as part of an API call as it will cause an availability problem. It is only used to gracefully quit in the case of HA so that failover happens as quickly as possible.

func (*Core) Standby

func (c *Core) Standby() (bool, error)

Standby checks if the Vault is in standby mode

func (*Core) StepDown

func (c *Core) StepDown(httpCtx context.Context, req *logical.Request) (retErr error)

StepDown is used to step down from leadership

func (*Core) UIEnabled

func (c *Core) UIEnabled() bool

UIEnabled returns if the UI is enabled

func (*Core) UIHeaders

func (c *Core) UIHeaders() (http.Header, error)

UIHeaders returns configured UI headers

func (*Core) Unseal

func (c *Core) Unseal(key []byte) (bool, error)

Unseal is used to provide one of the key parts to unseal the Vault.

They key given as a parameter will automatically be zerod after this method is done with it. If you want to keep the key around, a copy should be made.

func (*Core) UnsealWithRecoveryKeys

func (c *Core) UnsealWithRecoveryKeys(key []byte) (bool, error)

func (*Core) UnsealWithStoredKeys

func (c *Core) UnsealWithStoredKeys(ctx context.Context) error

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 (*Core) ValidateWrappingToken

func (c *Core) ValidateWrappingToken(ctx context.Context, req *logical.Request) (bool, error)

ValidateWrappingToken checks whether a token is a wrapping token.

type CoreConfig

type CoreConfig struct {
	DevToken string `json:"dev_token" structs:"dev_token" mapstructure:"dev_token"`

	BuiltinRegistry BuiltinRegistry `json:"builtin_registry" structs:"builtin_registry" mapstructure:"builtin_registry"`

	LogicalBackends map[string]logical.Factory `json:"logical_backends" structs:"logical_backends" mapstructure:"logical_backends"`

	CredentialBackends map[string]logical.Factory `json:"credential_backends" structs:"credential_backends" mapstructure:"credential_backends"`

	AuditBackends map[string]audit.Factory `json:"audit_backends" structs:"audit_backends" mapstructure:"audit_backends"`

	Physical physical.Backend `json:"physical" structs:"physical" mapstructure:"physical"`

	// May be nil, which disables HA operations
	HAPhysical physical.HABackend `json:"ha_physical" structs:"ha_physical" mapstructure:"ha_physical"`

	Seal Seal `json:"seal" structs:"seal" mapstructure:"seal"`

	Logger log.Logger `json:"logger" structs:"logger" mapstructure:"logger"`

	// Disables the LRU cache on the physical backend
	DisableCache bool `json:"disable_cache" structs:"disable_cache" mapstructure:"disable_cache"`

	// Disables mlock syscall
	DisableMlock bool `json:"disable_mlock" structs:"disable_mlock" mapstructure:"disable_mlock"`

	// Custom cache size for the LRU cache on the physical backend, or zero for default
	CacheSize int `json:"cache_size" structs:"cache_size" mapstructure:"cache_size"`

	// Set as the leader address for HA
	RedirectAddr string `json:"redirect_addr" structs:"redirect_addr" mapstructure:"redirect_addr"`

	// Set as the cluster address for HA
	ClusterAddr string `json:"cluster_addr" structs:"cluster_addr" mapstructure:"cluster_addr"`

	DefaultLeaseTTL time.Duration `json:"default_lease_ttl" structs:"default_lease_ttl" mapstructure:"default_lease_ttl"`

	MaxLeaseTTL time.Duration `json:"max_lease_ttl" structs:"max_lease_ttl" mapstructure:"max_lease_ttl"`

	ClusterName string `json:"cluster_name" structs:"cluster_name" mapstructure:"cluster_name"`

	ClusterCipherSuites string `json:"cluster_cipher_suites" structs:"cluster_cipher_suites" mapstructure:"cluster_cipher_suites"`

	EnableUI bool `json:"ui" structs:"ui" mapstructure:"ui"`

	// Enable the raw endpoint
	EnableRaw bool `json:"enable_raw" structs:"enable_raw" mapstructure:"enable_raw"`

	PluginDirectory string `json:"plugin_directory" structs:"plugin_directory" mapstructure:"plugin_directory"`

	DisableSealWrap bool `json:"disable_sealwrap" structs:"disable_sealwrap" mapstructure:"disable_sealwrap"`

	ReloadFuncs     *map[string][]reload.ReloadFunc
	ReloadFuncsLock *sync.RWMutex

	// Licensing
	LicensingConfig *LicensingConfig
	// Don't set this unless in dev mode, ideally only when using inmem
	DevLicenseDuration time.Duration

	DisablePerformanceStandby bool
	DisableIndexing           bool
	DisableKeyEncodingChecks  bool

	AllLoggers []log.Logger

	// Telemetry objects
	MetricsHelper *metricsutil.MetricsHelper

	CounterSyncInterval time.Duration
}

CoreConfig is used to parameterize a core

func (*CoreConfig) Clone

func (c *CoreConfig) Clone() *CoreConfig

type CubbyholeBackend

type CubbyholeBackend struct {
	*framework.Backend
	// contains filtered or unexported fields
}

CubbyholeBackend is used for storing secrets directly into the physical backend. The secrets are encrypted in the durable storage. This differs from kv in that every token has its own private storage view. The view is removed when the token expires.

type DatedRequestCounter

type DatedRequestCounter struct {
	// StartTime is when the period starts.
	StartTime time.Time `json:"start_time"`
	// RequestCounter counts requests.
	RequestCounter
}

DatedRequestCounter holds request counters from a single period of time.

type EchoReply

type EchoReply struct {
	Message              string   `protobuf:"bytes,1,opt,name=message,proto3" json:"message,omitempty"`
	ClusterAddrs         []string `protobuf:"bytes,2,rep,name=cluster_addrs,json=clusterAddrs,proto3" json:"cluster_addrs,omitempty"`
	ReplicationState     uint32   `protobuf:"varint,3,opt,name=replication_state,json=replicationState,proto3" json:"replication_state,omitempty"`
	XXX_NoUnkeyedLiteral struct{} `json:"-"`
	XXX_unrecognized     []byte   `json:"-"`
	XXX_sizecache        int32    `json:"-"`
}

func (*EchoReply) Descriptor

func (*EchoReply) Descriptor() ([]byte, []int)

func (*EchoReply) GetClusterAddrs

func (m *EchoReply) GetClusterAddrs() []string

func (*EchoReply) GetMessage

func (m *EchoReply) GetMessage() string

func (*EchoReply) GetReplicationState

func (m *EchoReply) GetReplicationState() uint32

func (*EchoReply) ProtoMessage

func (*EchoReply) ProtoMessage()

func (*EchoReply) Reset

func (m *EchoReply) Reset()

func (*EchoReply) String

func (m *EchoReply) String() string

func (*EchoReply) XXX_DiscardUnknown

func (m *EchoReply) XXX_DiscardUnknown()

func (*EchoReply) XXX_Marshal

func (m *EchoReply) XXX_Marshal(b []byte, deterministic bool) ([]byte, error)

func (*EchoReply) XXX_Merge

func (m *EchoReply) XXX_Merge(src proto.Message)

func (*EchoReply) XXX_Size

func (m *EchoReply) XXX_Size() int

func (*EchoReply) XXX_Unmarshal

func (m *EchoReply) XXX_Unmarshal(b []byte) error

type EchoRequest

type EchoRequest struct {
	Message string `protobuf:"bytes,1,opt,name=message,proto3" json:"message,omitempty"`
	// ClusterAddr is used to send up a standby node's address to the active
	// node upon heartbeat
	ClusterAddr string `protobuf:"bytes,2,opt,name=cluster_addr,json=clusterAddr,proto3" json:"cluster_addr,omitempty"`
	// ClusterAddrs is used to send up a list of cluster addresses to a dr
	// primary from a dr secondary
	ClusterAddrs         []string `protobuf:"bytes,3,rep,name=cluster_addrs,json=clusterAddrs,proto3" json:"cluster_addrs,omitempty"`
	XXX_NoUnkeyedLiteral struct{} `json:"-"`
	XXX_unrecognized     []byte   `json:"-"`
	XXX_sizecache        int32    `json:"-"`
}

func (*EchoRequest) Descriptor

func (*EchoRequest) Descriptor() ([]byte, []int)

func (*EchoRequest) GetClusterAddr

func (m *EchoRequest) GetClusterAddr() string

func (*EchoRequest) GetClusterAddrs

func (m *EchoRequest) GetClusterAddrs() []string

func (*EchoRequest) GetMessage

func (m *EchoRequest) GetMessage() string

func (*EchoRequest) ProtoMessage

func (*EchoRequest) ProtoMessage()

func (*EchoRequest) Reset

func (m *EchoRequest) Reset()

func (*EchoRequest) String

func (m *EchoRequest) String() string

func (*EchoRequest) XXX_DiscardUnknown

func (m *EchoRequest) XXX_DiscardUnknown()

func (*EchoRequest) XXX_Marshal

func (m *EchoRequest) XXX_Marshal(b []byte, deterministic bool) ([]byte, error)

func (*EchoRequest) XXX_Merge

func (m *EchoRequest) XXX_Merge(src proto.Message)

func (*EchoRequest) XXX_Size

func (m *EchoRequest) XXX_Size() int

func (*EchoRequest) XXX_Unmarshal

func (m *EchoRequest) XXX_Unmarshal(b []byte) error

type EncodedKeyring

type EncodedKeyring struct {
	MasterKey []byte
	Keys      []*Key
}

EncodedKeyring is used for serialization of the keyring

type ErrInvalidKey

type ErrInvalidKey struct {
	Reason string
}

ErrInvalidKey is returned if there is a user-based error with a provided unseal key. This will be shown to the user, so should not contain information that is sensitive.

func (*ErrInvalidKey) Error

func (e *ErrInvalidKey) Error() string

type ExpirationManager

type ExpirationManager struct {
	// contains filtered or unexported fields
}

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.

func NewExpirationManager

func NewExpirationManager(c *Core, view *BarrierView, e ExpireLeaseStrategy, logger log.Logger) *ExpirationManager

NewExpirationManager creates a new ExpirationManager that is backed using a given view, and uses the provided router for revocation.

func (*ExpirationManager) CreateOrFetchRevocationLeaseByToken

func (m *ExpirationManager) CreateOrFetchRevocationLeaseByToken(ctx context.Context, te *logical.TokenEntry) (string, error)

CreateOrFetchRevocationLeaseByToken is used to create or fetch the matching leaseID for a particular token. The lease is set to expire immediately after it's created.

func (*ExpirationManager) FetchLeaseTimes

func (m *ExpirationManager) FetchLeaseTimes(ctx context.Context, leaseID string) (*leaseEntry, error)

FetchLeaseTimes is used to fetch the issue time, expiration time, and last renewed time of a lease entry. It returns a leaseEntry itself, but with only those values copied over.

func (*ExpirationManager) FetchLeaseTimesByToken

func (m *ExpirationManager) FetchLeaseTimesByToken(ctx context.Context, te *logical.TokenEntry) (*leaseEntry, error)

FetchLeaseTimesByToken is a helper function to use token values to compute the leaseID, rather than pushing that logic back into the token store. As a special case, for a batch token it simply returns the information encoded on it.

func (*ExpirationManager) LazyRevoke

func (m *ExpirationManager) LazyRevoke(ctx context.Context, leaseID string) error

LazyRevoke is used to queue revocation for a secret named by the given LeaseID. If the lease was not found it returns nil; if the lease was found it triggers a return of a 202.

func (*ExpirationManager) Register

func (m *ExpirationManager) Register(ctx context.Context, req *logical.Request, resp *logical.Response) (id string, retErr error)

Register is used to take a request and response with an associated lease. The secret gets assigned a LeaseID and the management of of lease is assumed by the expiration manager.

func (*ExpirationManager) RegisterAuth

func (m *ExpirationManager) RegisterAuth(ctx context.Context, te *logical.TokenEntry, auth *logical.Auth) error

RegisterAuth is used to take an Auth response with an associated lease. The token does not get a LeaseID, but the lease management is handled by the expiration manager.

func (*ExpirationManager) Renew

func (m *ExpirationManager) Renew(ctx context.Context, leaseID string, increment time.Duration) (*logical.Response, error)

Renew is used to renew a secret using the given leaseID and a renew interval. The increment may be ignored.

func (*ExpirationManager) RenewToken

func (m *ExpirationManager) RenewToken(ctx context.Context, req *logical.Request, te *logical.TokenEntry,
	increment time.Duration) (*logical.Response, error)

RenewToken is used to renew a token which does not need to invoke a logical backend.

func (*ExpirationManager) Restore

func (m *ExpirationManager) Restore(errorFunc func()) (retErr error)

Restore is used to recover the lease states when starting. This is used after starting the vault.

func (*ExpirationManager) Revoke

func (m *ExpirationManager) Revoke(ctx context.Context, leaseID string) error

Revoke is used to revoke a secret named by the given LeaseID

func (*ExpirationManager) RevokeByToken

func (m *ExpirationManager) RevokeByToken(ctx context.Context, te *logical.TokenEntry) error

RevokeByToken is used to revoke all the secrets issued with a given token. This is done by using the secondary index. It also removes the lease entry for the token itself. As a result it should *ONLY* ever be called from the token store's revokeSalted function.

func (*ExpirationManager) RevokeForce

func (m *ExpirationManager) RevokeForce(ctx context.Context, prefix string) error

RevokeForce works similarly to RevokePrefix but continues in the case of a revocation error; this is mostly meant for recovery operations

func (*ExpirationManager) RevokePrefix

func (m *ExpirationManager) RevokePrefix(ctx context.Context, prefix string, sync bool) error

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 (*ExpirationManager) Stop

func (m *ExpirationManager) Stop() error

Stop is used to prevent further automatic revocations. This must be called before sealing the view.

func (*ExpirationManager) Tidy

func (m *ExpirationManager) Tidy(ctx context.Context) error

Tidy cleans up the dangling storage entries for leases. It scans the storage view to find all the available leases, checks if the token embedded in it is either empty or invalid and in both the cases, it revokes them. It also uses a token cache to avoid multiple lookups of the same token ID. It is normally not required to use the API that invokes this. This is only intended to clean up the corrupt storage due to bugs.

type ExpireLeaseStrategy

type ExpireLeaseStrategy func(context.Context, *ExpirationManager, *leaseEntry)

type GenerateRootConfig

type GenerateRootConfig struct {
	Nonce          string
	PGPKey         string
	PGPFingerprint string
	OTP            string
	Strategy       GenerateRootStrategy
}

GenerateRootConfig holds the configuration for a root generation command.

type GenerateRootResult

type GenerateRootResult struct {
	Progress       int
	Required       int
	EncodedToken   string
	PGPFingerprint string
}

GenerateRootResult holds the result of a root generation update command

type GenerateRootStrategy

type GenerateRootStrategy interface {
	// contains filtered or unexported methods
}

GenerateRootStrategy allows us to swap out the strategy we want to use to create a token upon completion of the generate root process.

var (
	// GenerateStandardRootTokenStrategy is the strategy used to generate a
	// typical root token
	GenerateStandardRootTokenStrategy GenerateRootStrategy = generateStandardRootToken{}

	// GenerateDROperationTokenStrategy is the strategy used to generate a
	// DR operational token
	GenerateDROperationTokenStrategy GenerateRootStrategy = generateStandardRootToken{}
)

type HandlerProperties

type HandlerProperties struct {
	Core                  *Core
	MaxRequestSize        int64
	MaxRequestDuration    time.Duration
	DisablePrintableCheck bool
}

HandlerProperties is used to seed configuration into a vaulthttp.Handler. It's in this package to avoid a circular dependency

type IdentityFactor

type IdentityFactor struct {
	GroupIDs          []string `hcl:"group_ids"`
	GroupNames        []string `hcl:"group_names"`
	ApprovalsRequired int      `hcl:"approvals"`
}

type IdentityStore

type IdentityStore struct {
	// IdentityStore is a secret backend in Vault
	*framework.Backend
	// contains filtered or unexported fields
}

IdentityStore is composed of its own storage view and a MemDB which maintains active in-memory replicas of the storage contents indexed by multiple fields.

func NewIdentityStore

func NewIdentityStore(ctx context.Context, core *Core, config *logical.BackendConfig, logger log.Logger) (*IdentityStore, error)

func (*IdentityStore) CreateOrFetchEntity

func (i *IdentityStore) CreateOrFetchEntity(ctx context.Context, alias *logical.Alias) (*identity.Entity, error)

CreateOrFetchEntity creates a new entity. This is used by core to associate each login attempt by an alias to a unified entity in Vault.

func (*IdentityStore) Invalidate

func (i *IdentityStore) Invalidate(ctx context.Context, key string)

Invalidate is a callback wherein the backend is informed that the value at the given key is updated. In identity store's case, it would be the entity storage entries that get updated. The value needs to be read and MemDB needs to be updated accordingly.

func (*IdentityStore) MemDBAliasByFactors

func (i *IdentityStore) MemDBAliasByFactors(mountAccessor, aliasName string, clone bool, groupAlias bool) (*identity.Alias, error)

func (*IdentityStore) MemDBAliasByFactorsInTxn

func (i *IdentityStore) MemDBAliasByFactorsInTxn(txn *memdb.Txn, mountAccessor, aliasName string, clone bool, groupAlias bool) (*identity.Alias, error)

func (*IdentityStore) MemDBAliasByID

func (i *IdentityStore) MemDBAliasByID(aliasID string, clone bool, groupAlias bool) (*identity.Alias, error)

func (*IdentityStore) MemDBAliasByIDInTxn

func (i *IdentityStore) MemDBAliasByIDInTxn(txn *memdb.Txn, aliasID string, clone bool, groupAlias bool) (*identity.Alias, error)

func (*IdentityStore) MemDBAliases

func (i *IdentityStore) MemDBAliases(ws memdb.WatchSet, groupAlias bool) (memdb.ResultIterator, error)

func (*IdentityStore) MemDBDeleteAliasByIDInTxn

func (i *IdentityStore) MemDBDeleteAliasByIDInTxn(txn *memdb.Txn, aliasID string, groupAlias bool) error

func (*IdentityStore) MemDBDeleteEntityByID

func (i *IdentityStore) MemDBDeleteEntityByID(entityID string) error

func (*IdentityStore) MemDBDeleteEntityByIDInTxn

func (i *IdentityStore) MemDBDeleteEntityByIDInTxn(txn *memdb.Txn, entityID string) error

func (*IdentityStore) MemDBDeleteGroupByIDInTxn

func (i *IdentityStore) MemDBDeleteGroupByIDInTxn(txn *memdb.Txn, groupID string) error

func (*IdentityStore) MemDBEntitiesByBucketEntryKeyHashInTxn

func (i *IdentityStore) MemDBEntitiesByBucketEntryKeyHashInTxn(txn *memdb.Txn, hashValue string) ([]*identity.Entity, error)

func (*IdentityStore) MemDBEntityByAliasID

func (i *IdentityStore) MemDBEntityByAliasID(aliasID string, clone bool) (*identity.Entity, error)

func (*IdentityStore) MemDBEntityByAliasIDInTxn

func (i *IdentityStore) MemDBEntityByAliasIDInTxn(txn *memdb.Txn, aliasID string, clone bool) (*identity.Entity, error)

func (*IdentityStore) MemDBEntityByID

func (i *IdentityStore) MemDBEntityByID(entityID string, clone bool) (*identity.Entity, error)

func (*IdentityStore) MemDBEntityByIDInTxn

func (i *IdentityStore) MemDBEntityByIDInTxn(txn *memdb.Txn, entityID string, clone bool) (*identity.Entity, error)

func (*IdentityStore) MemDBEntityByMergedEntityID

func (i *IdentityStore) MemDBEntityByMergedEntityID(mergedEntityID string, clone bool) (*identity.Entity, error)

func (*IdentityStore) MemDBEntityByName

func (i *IdentityStore) MemDBEntityByName(ctx context.Context, entityName string, clone bool) (*identity.Entity, error)

func (*IdentityStore) MemDBEntityByNameInTxn

func (i *IdentityStore) MemDBEntityByNameInTxn(ctx context.Context, txn *memdb.Txn, entityName string, clone bool) (*identity.Entity, error)

func (*IdentityStore) MemDBGroupByAliasID

func (i *IdentityStore) MemDBGroupByAliasID(aliasID string, clone bool) (*identity.Group, error)

func (*IdentityStore) MemDBGroupByAliasIDInTxn

func (i *IdentityStore) MemDBGroupByAliasIDInTxn(txn *memdb.Txn, aliasID string, clone bool) (*identity.Group, error)

func (*IdentityStore) MemDBGroupByID

func (i *IdentityStore) MemDBGroupByID(groupID string, clone bool) (*identity.Group, error)

func (*IdentityStore) MemDBGroupByIDInTxn

func (i *IdentityStore) MemDBGroupByIDInTxn(txn *memdb.Txn, groupID string, clone bool) (*identity.Group, error)

func (*IdentityStore) MemDBGroupByName

func (i *IdentityStore) MemDBGroupByName(ctx context.Context, groupName string, clone bool) (*identity.Group, error)

func (*IdentityStore) MemDBGroupByNameInTxn

func (i *IdentityStore) MemDBGroupByNameInTxn(ctx context.Context, txn *memdb.Txn, groupName string, clone bool) (*identity.Group, error)

func (*IdentityStore) MemDBGroupsByBucketEntryKeyHashInTxn

func (i *IdentityStore) MemDBGroupsByBucketEntryKeyHashInTxn(txn *memdb.Txn, hashValue string) ([]*identity.Group, error)

func (*IdentityStore) MemDBGroupsByMemberEntityID

func (i *IdentityStore) MemDBGroupsByMemberEntityID(entityID string, clone bool, externalOnly bool) ([]*identity.Group, error)

func (*IdentityStore) MemDBGroupsByMemberEntityIDInTxn

func (i *IdentityStore) MemDBGroupsByMemberEntityIDInTxn(txn *memdb.Txn, entityID string, clone bool, externalOnly bool) ([]*identity.Group, error)

func (*IdentityStore) MemDBGroupsByParentGroupID

func (i *IdentityStore) MemDBGroupsByParentGroupID(memberGroupID string, clone bool) ([]*identity.Group, error)

func (*IdentityStore) MemDBGroupsByParentGroupIDInTxn

func (i *IdentityStore) MemDBGroupsByParentGroupIDInTxn(txn *memdb.Txn, memberGroupID string, clone bool) ([]*identity.Group, error)

func (*IdentityStore) MemDBUpsertAliasInTxn

func (i *IdentityStore) MemDBUpsertAliasInTxn(txn *memdb.Txn, alias *identity.Alias, groupAlias bool) error

func (*IdentityStore) MemDBUpsertEntityInTxn

func (i *IdentityStore) MemDBUpsertEntityInTxn(txn *memdb.Txn, entity *identity.Entity) error

func (*IdentityStore) MemDBUpsertGroupInTxn

func (i *IdentityStore) MemDBUpsertGroupInTxn(txn *memdb.Txn, group *identity.Group) error

func (*IdentityStore) UpsertGroup

func (i *IdentityStore) UpsertGroup(group *identity.Group, persist bool) error

func (*IdentityStore) UpsertGroupInTxn

func (i *IdentityStore) UpsertGroupInTxn(txn *memdb.Txn, group *identity.Group, persist bool) error

type InitParams

type InitParams struct {
	BarrierConfig   *SealConfig
	RecoveryConfig  *SealConfig
	RootTokenPGPKey string
}

InitParams keeps the init function from being littered with too many params, that's it!

type InitResult

type InitResult struct {
	SecretShares   [][]byte
	RecoveryShares [][]byte
	RootToken      string
}

InitResult is used to provide the key parts back after they are generated as part of the initialization.

type Key

type Key struct {
	Term        uint32
	Version     int
	Value       []byte
	InstallTime time.Time
}

Key represents a single term, along with the key used.

func DeserializeKey

func DeserializeKey(buf []byte) (*Key, error)

DeserializeKey is used to deserialize and return a new key

func (*Key) Serialize

func (k *Key) Serialize() ([]byte, error)

Serialize is used to create a byte encoded key

type KeyInfo

type KeyInfo struct {
	Term        int
	InstallTime time.Time
}

KeyInfo is used to convey information about the encryption key

type Keyring

type Keyring struct {
	// contains filtered or unexported fields
}

Keyring is used to manage multiple encryption keys used by the barrier. New keys can be installed and each has a sequential term. The term used to encrypt a key is prefixed to the key written out. All data is encrypted with the latest key, but storing the old keys allows for decryption of keys written previously. Along with the encryption keys, the keyring also tracks the master key. This is necessary so that when a new key is added to the keyring, we can encrypt with the master key and write out the new keyring.

func DeserializeKeyring

func DeserializeKeyring(buf []byte) (*Keyring, error)

DeserializeKeyring is used to deserialize and return a new keyring

func NewKeyring

func NewKeyring() *Keyring

NewKeyring creates a new keyring

func (*Keyring) ActiveKey

func (k *Keyring) ActiveKey() *Key

ActiveKey returns the active encryption key, or nil

func (*Keyring) ActiveTerm

func (k *Keyring) ActiveTerm() uint32

ActiveTerm returns the currently active term

func (*Keyring) AddKey

func (k *Keyring) AddKey(key *Key) (*Keyring, error)

AddKey adds a new key to the keyring

func (*Keyring) Clone

func (k *Keyring) Clone() *Keyring

Clone returns a new copy of the keyring

func (*Keyring) MasterKey

func (k *Keyring) MasterKey() []byte

MasterKey returns the master key

func (*Keyring) RemoveKey

func (k *Keyring) RemoveKey(term uint32) (*Keyring, error)

RemoveKey removes a key from the keyring

func (*Keyring) Serialize

func (k *Keyring) Serialize() ([]byte, error)

Serialize is used to create a byte encoded keyring

func (*Keyring) SetMasterKey

func (k *Keyring) SetMasterKey(val []byte) *Keyring

SetMasterKey is used to update the master key

func (*Keyring) TermKey

func (k *Keyring) TermKey(term uint32) *Key

TermKey returns the key for the given term, or nil

func (*Keyring) Zeroize

func (k *Keyring) Zeroize(keysToo bool)

N.B.: Since Go 1.5 these are not reliable; see the documentation around the memzero function. These are best-effort.

type LicensingConfig

type LicensingConfig struct{}

type ListingVisibilityType

type ListingVisibilityType string

ListingVisibilityType represents the types for listing visibility

const (
	// ListingVisibilityDefault is the default value for listing visibility
	ListingVisibilityDefault ListingVisibilityType = ""
	// ListingVisibilityHidden is the hidden type for listing visibility
	ListingVisibilityHidden ListingVisibilityType = "hidden"
	// ListingVisibilityUnauth is the unauth type for listing visibility
	ListingVisibilityUnauth ListingVisibilityType = "unauth"

	MountTableUpdateStorage   = true
	MountTableNoUpdateStorage = false
)

type MountConfig

type MountConfig struct {
	DefaultLeaseTTL           time.Duration         `json:"default_lease_ttl" structs:"default_lease_ttl" mapstructure:"default_lease_ttl"`
	MaxLeaseTTL               time.Duration         `json:"max_lease_ttl" structs:"max_lease_ttl" mapstructure:"max_lease_ttl"`
	ForceNoCache              bool                  `json:"force_no_cache" structs:"force_no_cache" mapstructure:"force_no_cache"`
	AuditNonHMACRequestKeys   []string              `json:"audit_non_hmac_request_keys,omitempty" structs:"audit_non_hmac_request_keys" mapstructure:"audit_non_hmac_request_keys"`
	AuditNonHMACResponseKeys  []string              "" /* 128 byte string literal not displayed */
	ListingVisibility         ListingVisibilityType `json:"listing_visibility,omitempty" structs:"listing_visibility" mapstructure:"listing_visibility"`
	PassthroughRequestHeaders []string              `json:"passthrough_request_headers,omitempty" structs:"passthrough_request_headers" mapstructure:"passthrough_request_headers"`
	AllowedResponseHeaders    []string              `json:"allowed_response_headers,omitempty" structs:"allowed_response_headers" mapstructure:"allowed_response_headers"`
	TokenType                 logical.TokenType     `json:"token_type" structs:"token_type" mapstructure:"token_type"`

	PluginName string `json:"plugin_name,omitempty" structs:"plugin_name,omitempty" mapstructure:"plugin_name"`
}

MountConfig is used to hold settable options

type MountEntry

type MountEntry struct {
	Table            string            `json:"table"`              // The table it belongs to
	Path             string            `json:"path"`               // Mount Path
	Type             string            `json:"type"`               // Logical backend Type
	Description      string            `json:"description"`        // User-provided description
	UUID             string            `json:"uuid"`               // Barrier view UUID
	BackendAwareUUID string            `json:"backend_aware_uuid"` // UUID that can be used by the backend as a helper when a consistent value is needed outside of storage.
	Accessor         string            `json:"accessor"`           // Unique but more human-friendly ID. Does not change, not used for any sensitive things (like as a salt, which the UUID sometimes is).
	Config           MountConfig       `json:"config"`             // Configuration related to this mount (but not backend-derived)
	Options          map[string]string `json:"options"`            // Backend options
	Local            bool              `json:"local"`              // Local mounts are not replicated or affected by replication
	SealWrap         bool              `json:"seal_wrap"`          // Whether to wrap CSPs
	Tainted          bool              `json:"tainted,omitempty"`  // Set as a Write-Ahead flag for unmount/remount
	NamespaceID      string            `json:"namespace_id"`
	// contains filtered or unexported fields
}

MountEntry is used to represent a mount table entry

func (*MountEntry) APIPath

func (e *MountEntry) APIPath() string

APIPath returns the full API Path for the given mount entry

func (*MountEntry) Clone

func (e *MountEntry) Clone() (*MountEntry, error)

Clone returns a deep copy of the mount entry

func (*MountEntry) Namespace

func (e *MountEntry) Namespace() *namespace.Namespace

Namespace returns the namespace for the mount entry

func (*MountEntry) SyncCache

func (e *MountEntry) SyncCache()

SyncCache syncs tunable configuration values to the cache. In the case of cached values, they should be retrieved via synthesizedConfigCache.Load() instead of accessing them directly through MountConfig.

func (*MountEntry) ViewPath

func (e *MountEntry) ViewPath() string

ViewPath returns storage prefix for the view

type MountTable

type MountTable struct {
	Type    string        `json:"type"`
	Entries []*MountEntry `json:"entries"`
}

MountTable is used to represent the internal mount table

type NonFatalError

type NonFatalError struct {
	Err error
}

NonFatalError is an error that can be returned during NewCore that should be displayed but not cause a program exit

func NewNonFatalError

func NewNonFatalError(err error) *NonFatalError

NewNonFatalError returns a new non-fatal error.

func (*NonFatalError) Error

func (e *NonFatalError) Error() string

func (*NonFatalError) WrappedErrors

func (e *NonFatalError) WrappedErrors() []error

type PassthroughBackend

type PassthroughBackend struct {
	*framework.Backend
	// contains filtered or unexported fields
}

PassthroughBackend is used storing secrets directly into the physical backend. The secrets are encrypted in the durable storage and custom TTL information can be specified, but otherwise this backend doesn't do anything fancy.

func (*PassthroughBackend) GeneratesLeases

func (b *PassthroughBackend) GeneratesLeases() bool

type PathRules

type PathRules struct {
	Path                string
	Policy              string
	Permissions         *ACLPermissions
	IsPrefix            bool
	HasSegmentWildcards bool
	Capabilities        []string

	// These keys are used at the top level to make the HCL nicer; we store in
	// the ACLPermissions object though
	MinWrappingTTLHCL     interface{}              `hcl:"min_wrapping_ttl"`
	MaxWrappingTTLHCL     interface{}              `hcl:"max_wrapping_ttl"`
	AllowedParametersHCL  map[string][]interface{} `hcl:"allowed_parameters"`
	DeniedParametersHCL   map[string][]interface{} `hcl:"denied_parameters"`
	RequiredParametersHCL []string                 `hcl:"required_parameters"`
	MFAMethodsHCL         []string                 `hcl:"mfa_methods"`
	ControlGroupHCL       *ControlGroupHCL         `hcl:"control_group"`
}

PathRules represents a policy for a path in the namespace.

type PerfStandbyElectionInput

type PerfStandbyElectionInput struct {
	XXX_NoUnkeyedLiteral struct{} `json:"-"`
	XXX_unrecognized     []byte   `json:"-"`
	XXX_sizecache        int32    `json:"-"`
}

func (*PerfStandbyElectionInput) Descriptor

func (*PerfStandbyElectionInput) Descriptor() ([]byte, []int)

func (*PerfStandbyElectionInput) ProtoMessage

func (*PerfStandbyElectionInput) ProtoMessage()

func (*PerfStandbyElectionInput) Reset

func (m *PerfStandbyElectionInput) Reset()

func (*PerfStandbyElectionInput) String

func (m *PerfStandbyElectionInput) String() string

func (*PerfStandbyElectionInput) XXX_DiscardUnknown

func (m *PerfStandbyElectionInput) XXX_DiscardUnknown()

func (*PerfStandbyElectionInput) XXX_Marshal

func (m *PerfStandbyElectionInput) XXX_Marshal(b []byte, deterministic bool) ([]byte, error)

func (*PerfStandbyElectionInput) XXX_Merge

func (m *PerfStandbyElectionInput) XXX_Merge(src proto.Message)

func (*PerfStandbyElectionInput) XXX_Size

func (m *PerfStandbyElectionInput) XXX_Size() int

func (*PerfStandbyElectionInput) XXX_Unmarshal

func (m *PerfStandbyElectionInput) XXX_Unmarshal(b []byte) error

type PerfStandbyElectionResponse

type PerfStandbyElectionResponse struct {
	Id                   string     `protobuf:"bytes,1,opt,name=id,proto3" json:"id,omitempty"`
	ClusterId            string     `protobuf:"bytes,2,opt,name=cluster_id,json=clusterId,proto3" json:"cluster_id,omitempty"`
	PrimaryClusterAddr   string     `protobuf:"bytes,3,opt,name=primary_cluster_addr,json=primaryClusterAddr,proto3" json:"primary_cluster_addr,omitempty"`
	CaCert               []byte     `protobuf:"bytes,4,opt,name=ca_cert,json=caCert,proto3" json:"ca_cert,omitempty"`
	ClientCert           []byte     `protobuf:"bytes,5,opt,name=client_cert,json=clientCert,proto3" json:"client_cert,omitempty"`
	ClientKey            *ClientKey `protobuf:"bytes,6,opt,name=client_key,json=clientKey,proto3" json:"client_key,omitempty"`
	XXX_NoUnkeyedLiteral struct{}   `json:"-"`
	XXX_unrecognized     []byte     `json:"-"`
	XXX_sizecache        int32      `json:"-"`
}

func (*PerfStandbyElectionResponse) Descriptor

func (*PerfStandbyElectionResponse) Descriptor() ([]byte, []int)

func (*PerfStandbyElectionResponse) GetCaCert

func (m *PerfStandbyElectionResponse) GetCaCert() []byte

func (*PerfStandbyElectionResponse) GetClientCert

func (m *PerfStandbyElectionResponse) GetClientCert() []byte

func (*PerfStandbyElectionResponse) GetClientKey

func (m *PerfStandbyElectionResponse) GetClientKey() *ClientKey

func (*PerfStandbyElectionResponse) GetClusterId

func (m *PerfStandbyElectionResponse) GetClusterId() string

func (*PerfStandbyElectionResponse) GetId

func (m *PerfStandbyElectionResponse) GetId() string

func (*PerfStandbyElectionResponse) GetPrimaryClusterAddr

func (m *PerfStandbyElectionResponse) GetPrimaryClusterAddr() string

func (*PerfStandbyElectionResponse) ProtoMessage

func (*PerfStandbyElectionResponse) ProtoMessage()

func (*PerfStandbyElectionResponse) Reset

func (m *PerfStandbyElectionResponse) Reset()

func (*PerfStandbyElectionResponse) String

func (m *PerfStandbyElectionResponse) String() string

func (*PerfStandbyElectionResponse) XXX_DiscardUnknown

func (m *PerfStandbyElectionResponse) XXX_DiscardUnknown()

func (*PerfStandbyElectionResponse) XXX_Marshal

func (m *PerfStandbyElectionResponse) XXX_Marshal(b []byte, deterministic bool) ([]byte, error)

func (*PerfStandbyElectionResponse) XXX_Merge

func (m *PerfStandbyElectionResponse) XXX_Merge(src proto.Message)

func (*PerfStandbyElectionResponse) XXX_Size

func (m *PerfStandbyElectionResponse) XXX_Size() int

func (*PerfStandbyElectionResponse) XXX_Unmarshal

func (m *PerfStandbyElectionResponse) XXX_Unmarshal(b []byte) error

type PluginCatalog

type PluginCatalog struct {
	// contains filtered or unexported fields
}

PluginCatalog keeps a record of plugins known to vault. External plugins need to be registered to the catalog before they can be used in backends. Builtin plugins are automatically detected and included in the catalog.

func (*PluginCatalog) Delete

func (c *PluginCatalog) Delete(ctx context.Context, name string, pluginType consts.PluginType) error

Delete is used to remove an external plugin from the catalog. Builtin plugins can not be deleted.

func (*PluginCatalog) Get

func (c *PluginCatalog) Get(ctx context.Context, name string, pluginType consts.PluginType) (*pluginutil.PluginRunner, error)

Get retrieves a plugin with the specified name from the catalog. It first looks for external plugins with this name and then looks for builtin plugins. It returns a PluginRunner or an error if no plugin was found.

func (*PluginCatalog) List

func (c *PluginCatalog) List(ctx context.Context, pluginType consts.PluginType) ([]string, error)

List returns a list of all the known plugin names. If an external and builtin plugin share the same name, only one instance of the name will be returned.

func (*PluginCatalog) Set

func (c *PluginCatalog) Set(ctx context.Context, name string, pluginType consts.PluginType, command string, args []string, env []string, sha256 []byte) error

Set registers a new external plugin with the catalog, or updates an existing external plugin. It takes the name, command and SHA256 of the plugin.

func (*PluginCatalog) UpgradePlugins

func (c *PluginCatalog) UpgradePlugins(ctx context.Context, logger log.Logger) error

UpdatePlugins will loop over all the plugins of unknown type and attempt to upgrade them to typed plugins

type Policy

type Policy struct {
	Name      string       `hcl:"name"`
	Paths     []*PathRules `hcl:"-"`
	Raw       string
	Type      PolicyType
	Templated bool
	// contains filtered or unexported fields
}

Policy is used to represent the policy specified by an ACL configuration.

func ParseACLPolicy

func ParseACLPolicy(ns *namespace.Namespace, rules string) (*Policy, error)

ParseACLPolicy is used to parse the specified ACL rules into an intermediary set of policies, before being compiled into the ACL

func (*Policy) ShallowClone

func (p *Policy) ShallowClone() *Policy

ShallowClone returns a shallow clone of the policy. This should not be used if any of the reference-typed fields are going to be modified

type PolicyCheckOpts

type PolicyCheckOpts struct {
	RootPrivsRequired bool
	Unauth            bool
}

type PolicyEntry

type PolicyEntry struct {
	Version   int
	Raw       string
	Templated bool
	Type      PolicyType
	// contains filtered or unexported fields
}

PolicyEntry is used to store a policy by name

type PolicyStore

type PolicyStore struct {
	// contains filtered or unexported fields
}

PolicyStore is used to provide durable storage of policy, and to manage ACLs associated with them.

func NewPolicyStore

func NewPolicyStore(ctx context.Context, core *Core, baseView *BarrierView, system logical.SystemView, logger log.Logger) (*PolicyStore, error)

NewPolicyStore creates a new PolicyStore that is backed using a given view. It used used to durable store and manage named policy.

func (*PolicyStore) ACL

func (ps *PolicyStore) ACL(ctx context.Context, entity *identity.Entity, policyNames map[string][]string) (*ACL, error)

ACL is used to return an ACL which is built using the named policies.

func (*PolicyStore) DeletePolicy

func (ps *PolicyStore) DeletePolicy(ctx context.Context, name string, policyType PolicyType) error

DeletePolicy is used to delete the named policy

func (*PolicyStore) GetPolicy

func (ps *PolicyStore) GetPolicy(ctx context.Context, name string, policyType PolicyType) (*Policy, error)

GetPolicy is used to fetch the named policy

func (*PolicyStore) ListPolicies

func (ps *PolicyStore) ListPolicies(ctx context.Context, policyType PolicyType) ([]string, error)

ListPolicies is used to list the available policies

func (*PolicyStore) SetPolicy

func (ps *PolicyStore) SetPolicy(ctx context.Context, p *Policy) error

SetPolicy is used to create or update the given policy

type PolicyType

type PolicyType uint32
const (
	PolicyTypeACL PolicyType = iota
	PolicyTypeRGP
	PolicyTypeEGP

	// Triggers a lookup in the map to figure out if ACL or RGP
	PolicyTypeToken
)

func (PolicyType) String

func (p PolicyType) String() string

type RegisterAuthFunc

type RegisterAuthFunc func(context.Context, time.Duration, string, *logical.Auth) error

type RekeyBackup

type RekeyBackup struct {
	Nonce string
	Keys  map[string][]string
}

RekeyBackup stores the backup copy of PGP-encrypted keys

type RekeyResult

type RekeyResult struct {
	SecretShares         [][]byte
	PGPFingerprints      []string
	Backup               bool
	RecoveryKey          bool
	VerificationRequired bool
	VerificationNonce    string
}

RekeyResult is used to provide the key parts back after they are generated as part of the rekey.

type RekeyVerifyResult

type RekeyVerifyResult struct {
	Complete bool
	Nonce    string
}

type ReplicationTokenInfo

type ReplicationTokenInfo struct{}

type RequestCounter

type RequestCounter struct {
	// Total is the number of requests seen during a given period.
	Total *uint64 `json:"total"`
}

RequestCounter stores the state of request counters for a single unspecified period.

type RequestForwardingClient

type RequestForwardingClient interface {
	ForwardRequest(ctx context.Context, in *forwarding.Request, opts ...grpc.CallOption) (*forwarding.Response, error)
	Echo(ctx context.Context, in *EchoRequest, opts ...grpc.CallOption) (*EchoReply, error)
	PerformanceStandbyElectionRequest(ctx context.Context, in *PerfStandbyElectionInput, opts ...grpc.CallOption) (RequestForwarding_PerformanceStandbyElectionRequestClient, error)
}

RequestForwardingClient is the client API for RequestForwarding service.

For semantics around ctx use and closing/ending streaming RPCs, please refer to https://godoc.org/google.golang.org/grpc#ClientConn.NewStream.

func NewRequestForwardingClient

func NewRequestForwardingClient(cc *grpc.ClientConn) RequestForwardingClient

type RequestForwardingServer

type RequestForwardingServer interface {
	ForwardRequest(context.Context, *forwarding.Request) (*forwarding.Response, error)
	Echo(context.Context, *EchoRequest) (*EchoReply, error)
	PerformanceStandbyElectionRequest(*PerfStandbyElectionInput, RequestForwarding_PerformanceStandbyElectionRequestServer) error
}

RequestForwardingServer is the server API for RequestForwarding service.

type RequestForwarding_PerformanceStandbyElectionRequestClient

type RequestForwarding_PerformanceStandbyElectionRequestClient interface {
	Recv() (*PerfStandbyElectionResponse, error)
	grpc.ClientStream
}

type RequestForwarding_PerformanceStandbyElectionRequestServer

type RequestForwarding_PerformanceStandbyElectionRequestServer interface {
	Send(*PerfStandbyElectionResponse) error
	grpc.ServerStream
}

type RollbackManager

type RollbackManager struct {
	// contains filtered or unexported fields
}

RollbackManager is responsible for performing rollbacks of partial secrets within logical backends.

During normal operations, it is possible for logical backends to error partially through an operation. These are called "partial secrets": they are never sent back to a user, but they do need to be cleaned up. This manager handles that by periodically (on a timer) requesting that the backends clean up.

The RollbackManager periodically initiates a logical.RollbackOperation on every mounted logical backend. It ensures that only one rollback operation is in-flight at any given time within a single seal/unseal phase.

func NewRollbackManager

func NewRollbackManager(ctx context.Context, logger log.Logger, backendsFunc func() []*MountEntry, router *Router, core *Core) *RollbackManager

NewRollbackManager is used to create a new rollback manager

func (*RollbackManager) Rollback

func (m *RollbackManager) Rollback(ctx context.Context, path string) error

Rollback is used to trigger an immediate rollback of the path, or to join an existing rollback operation if in flight. Caller should have core's statelock held (write OR read). If an already inflight rollback is happening this function will simply wait for it to complete

func (*RollbackManager) Start

func (m *RollbackManager) Start()

Start starts the rollback manager

func (*RollbackManager) Stop

func (m *RollbackManager) Stop()

Stop stops the running manager. This will wait for any in-flight rollbacks to complete.

type Router

type Router struct {
	// contains filtered or unexported fields
}

Router is used to do prefix based routing of a request to a logical backend

func NewRouter

func NewRouter() *Router

NewRouter returns a new router

func (*Router) LoginPath

func (r *Router) LoginPath(ctx context.Context, path string) bool

LoginPath checks if the given path is used for logins

func (*Router) MatchingAPIPrefixByStoragePath

func (r *Router) MatchingAPIPrefixByStoragePath(ctx context.Context, path string) (*namespace.Namespace, string, string, bool)

MatchingAPIPrefixByStoragePath the api path information for the given storage path

func (*Router) MatchingBackend

func (r *Router) MatchingBackend(ctx context.Context, path string) logical.Backend

MatchingBackend returns the backend used for a path

func (*Router) MatchingMount

func (r *Router) MatchingMount(ctx context.Context, path string) string

MatchingMount returns the mount prefix that would be used for a path

func (*Router) MatchingMountByAccessor

func (r *Router) MatchingMountByAccessor(mountAccessor string) *MountEntry

MatchingMountByAccessor returns the MountEntry by accessor lookup

func (*Router) MatchingMountByUUID

func (r *Router) MatchingMountByUUID(mountID string) *MountEntry

func (*Router) MatchingMountEntry

func (r *Router) MatchingMountEntry(ctx context.Context, path string) *MountEntry

MatchingMountEntry returns the MountEntry used for a path

func (*Router) MatchingStorageByAPIPath

func (r *Router) MatchingStorageByAPIPath(ctx context.Context, path string) logical.Storage

MatchingStorageByAPIPath/StoragePath returns the storage used for API/Storage paths respectively

func (*Router) MatchingStorageByStoragePath

func (r *Router) MatchingStorageByStoragePath(ctx context.Context, path string) logical.Storage

func (*Router) MatchingStoragePrefixByAPIPath

func (r *Router) MatchingStoragePrefixByAPIPath(ctx context.Context, path string) (string, bool)

MatchingStoragePrefixByAPIPath the storage prefix for the given api path

func (*Router) MatchingSystemView

func (r *Router) MatchingSystemView(ctx context.Context, path string) logical.SystemView

MatchingSystemView returns the SystemView used for a path

func (*Router) Mount

func (r *Router) Mount(backend logical.Backend, prefix string, mountEntry *MountEntry, storageView *BarrierView) error

Mount is used to expose a logical backend at a given prefix, using a unique salt, and the barrier view for that path.

func (*Router) MountConflict

func (r *Router) MountConflict(ctx context.Context, path string) string

MountConflict determines if there are potential path conflicts

func (*Router) Remount

func (r *Router) Remount(ctx context.Context, src, dst string) error

Remount is used to change the mount location of a logical backend

func (*Router) RootPath

func (r *Router) RootPath(ctx context.Context, path string) bool

RootPath checks if the given path requires root privileges

func (*Router) Route

func (r *Router) Route(ctx context.Context, req *logical.Request) (*logical.Response, error)

Route is used to route a given request

func (*Router) RouteExistenceCheck

func (r *Router) RouteExistenceCheck(ctx context.Context, req *logical.Request) (*logical.Response, bool, bool, error)

RouteExistenceCheck is used to route a given existence check request

func (*Router) Taint

func (r *Router) Taint(ctx context.Context, path string) error

Taint is used to mark a path as tainted. This means only RollbackOperation RevokeOperation requests are allowed to proceed

func (*Router) Unmount

func (r *Router) Unmount(ctx context.Context, prefix string) error

Unmount is used to remove a logical backend from a given prefix

func (*Router) Untaint

func (r *Router) Untaint(ctx context.Context, path string) error

Untaint is used to unmark a path as tainted.

type RouterAccess

type RouterAccess struct {
	// contains filtered or unexported fields
}

RouterAccess provides access into some things necessary for testing

func NewRouterAccess

func NewRouterAccess(c *Core) *RouterAccess

func (*RouterAccess) StoragePrefixByAPIPath

func (r *RouterAccess) StoragePrefixByAPIPath(ctx context.Context, path string) (string, bool)

type Seal

type Seal interface {
	SetCore(*Core)
	Init(context.Context) error
	Finalize(context.Context) error

	StoredKeysSupported() bool
	SetStoredKeys(context.Context, [][]byte) error
	GetStoredKeys(context.Context) ([][]byte, error)

	BarrierType() string
	BarrierConfig(context.Context) (*SealConfig, error)
	SetBarrierConfig(context.Context, *SealConfig) error
	SetCachedBarrierConfig(*SealConfig)

	RecoveryKeySupported() bool
	RecoveryType() string
	RecoveryConfig(context.Context) (*SealConfig, error)
	RecoveryKey(context.Context) ([]byte, error)
	SetRecoveryConfig(context.Context, *SealConfig) error
	SetCachedRecoveryConfig(*SealConfig)
	SetRecoveryKey(context.Context, []byte) error
	VerifyRecoveryKey(context.Context, []byte) error
}

func NewAutoSeal

func NewAutoSeal(lowLevel seal.Access) Seal

func NewDefaultSeal

func NewDefaultSeal() Seal

func NewTestSeal

func NewTestSeal(testing.T, *TestSealOpts) Seal

type SealAccess

type SealAccess struct {
	// contains filtered or unexported fields
}

SealAccess is a wrapper around Seal that exposes accessor methods through Core.SealAccess() while restricting the ability to modify Core.seal itself.

func NewSealAccess

func NewSealAccess(seal Seal) *SealAccess

func (*SealAccess) BarrierConfig

func (s *SealAccess) BarrierConfig(ctx context.Context) (*SealConfig, error)

func (*SealAccess) BarrierType

func (s *SealAccess) BarrierType() string

func (*SealAccess) ClearCaches

func (s *SealAccess) ClearCaches(ctx context.Context)

func (*SealAccess) RecoveryConfig

func (s *SealAccess) RecoveryConfig(ctx context.Context) (*SealConfig, error)

func (*SealAccess) RecoveryKeySupported

func (s *SealAccess) RecoveryKeySupported() bool

func (*SealAccess) SetTestingParams

func (s *SealAccess) SetTestingParams(params *SealAccessTestingParams) error

func (*SealAccess) StoredKeysSupported

func (s *SealAccess) StoredKeysSupported() bool

func (*SealAccess) VerifyRecoveryKey

func (s *SealAccess) VerifyRecoveryKey(ctx context.Context, key []byte) error

type SealAccessTestingParams

type SealAccessTestingParams struct {
	PretendToAllowStoredShares bool
	PretendToAllowRecoveryKeys bool
	PretendRecoveryKey         []byte
}

type SealConfig

type SealConfig struct {
	// The type, for sanity checking
	Type string `json:"type"`

	// SecretShares is the number of shares the secret is split into. This is
	// the N value of Shamir.
	SecretShares int `json:"secret_shares"`

	// SecretThreshold is the number of parts required to open the vault. This
	// is the T value of Shamir.
	SecretThreshold int `json:"secret_threshold"`

	// PGPKeys is the array of public PGP keys used, if requested, to encrypt
	// the output unseal tokens. If provided, it sets the value of
	// SecretShares. Ordering is important.
	PGPKeys []string `json:"pgp_keys"`

	// Nonce is a nonce generated by Vault used to ensure that when unseal keys
	// are submitted for a rekey operation, the rekey operation itself is the
	// one intended. This prevents hijacking of the rekey operation, since it
	// is unauthenticated.
	Nonce string `json:"nonce"`

	// Backup indicates whether or not a backup of PGP-encrypted unseal keys
	// should be stored at coreUnsealKeysBackupPath after successful rekeying.
	Backup bool `json:"backup"`

	// How many keys to store, for seals that support storage.
	StoredShares int `json:"stored_shares"`

	// Stores the progress of the rekey operation (key shares)
	RekeyProgress [][]byte `json:"-"`

	// VerificationRequired indicates that after a rekey validation must be
	// performed (via providing shares from the new key) before the new key is
	// actually installed. This is omitted from JSON as we don't persist the
	// new key, it lives only in memory.
	VerificationRequired bool `json:"-"`

	// VerificationKey is the new key that we will roll to after successful
	// validation
	VerificationKey []byte `json:"-"`

	// VerificationNonce stores the current operation nonce for verification
	VerificationNonce string `json:"-"`

	// Stores the progress of the verification operation (key shares)
	VerificationProgress [][]byte `json:"-"`
}

SealConfig is used to describe the seal configuration

func (*SealConfig) Clone

func (s *SealConfig) Clone() *SealConfig

func (*SealConfig) Validate

func (s *SealConfig) Validate() error

Validate is used to sanity check the seal configuration

type SecurityBarrier

type SecurityBarrier interface {
	// Initialized checks if the barrier has been initialized
	// and has a master key set.
	Initialized(ctx context.Context) (bool, error)

	// Initialize works only if the barrier has not been initialized
	// and makes use of the given master key.
	Initialize(context.Context, []byte) error

	// GenerateKey is used to generate a new key
	GenerateKey() ([]byte, error)

	// KeyLength is used to sanity check a key
	KeyLength() (int, int)

	// Sealed checks if the barrier has been unlocked yet. The Barrier
	// is not expected to be able to perform any CRUD until it is unsealed.
	Sealed() (bool, error)

	// Unseal is used to provide the master key which permits the barrier
	// to be unsealed. If the key is not correct, the barrier remains sealed.
	Unseal(ctx context.Context, key []byte) error

	// VerifyMaster is used to check if the given key matches the master key
	VerifyMaster(key []byte) error

	// SetMasterKey is used to directly set a new master key. This is used in
	// replicated scenarios due to the chicken and egg problem of reloading the
	// keyring from disk before we have the master key to decrypt it.
	SetMasterKey(key []byte) error

	// ReloadKeyring is used to re-read the underlying keyring.
	// This is used for HA deployments to ensure the latest keyring
	// is present in the leader.
	ReloadKeyring(ctx context.Context) error

	// ReloadMasterKey is used to re-read the underlying masterkey.
	// This is used for HA deployments to ensure the latest master key
	// is available for keyring reloading.
	ReloadMasterKey(ctx context.Context) error

	// Seal is used to re-seal the barrier. This requires the barrier to
	// be unsealed again to perform any further operations.
	Seal() error

	// Rotate is used to create a new encryption key. All future writes
	// should use the new key, while old values should still be decryptable.
	Rotate(ctx context.Context) (uint32, error)

	// CreateUpgrade creates an upgrade path key to the given term from the previous term
	CreateUpgrade(ctx context.Context, term uint32) error

	// DestroyUpgrade destroys the upgrade path key to the given term
	DestroyUpgrade(ctx context.Context, term uint32) error

	// CheckUpgrade looks for an upgrade to the current term and installs it
	CheckUpgrade(ctx context.Context) (bool, uint32, error)

	// ActiveKeyInfo is used to inform details about the active key
	ActiveKeyInfo() (*KeyInfo, error)

	// Rekey is used to change the master key used to protect the keyring
	Rekey(context.Context, []byte) error

	// For replication we must send over the keyring, so this must be available
	Keyring() (*Keyring, error)

	// SecurityBarrier must provide the storage APIs
	logical.Storage

	// SecurityBarrier must provide the encryption APIs
	BarrierEncryptor
}

SecurityBarrier is a critical component of Vault. It is used to wrap an untrusted physical backend and provide a single point of encryption, decryption and checksum verification. The goal is to ensure that any data written to the barrier is confidential and that integrity is preserved. As a real-world analogy, this is the steel and concrete wrapper around a Vault. The barrier should only be Unlockable given its key.

type SystemBackend

type SystemBackend struct {
	*framework.Backend
	Core *Core
	// contains filtered or unexported fields
}

SystemBackend implements logical.Backend and is used to interact with the core of the system. This backend is hardcoded to exist at the "sys" prefix. Conceptually it is similar to procfs on Linux.

func NewSystemBackend

func NewSystemBackend(core *Core, logger log.Logger) *SystemBackend

type TemplateError

type TemplateError struct {
	Err error
}

func (*TemplateError) Error

func (t *TemplateError) Error() string

func (*TemplateError) WrappedErrors

func (t *TemplateError) WrappedErrors() []error

type TestCluster

type TestCluster struct {
	BarrierKeys   [][]byte
	RecoveryKeys  [][]byte
	CACert        *x509.Certificate
	CACertBytes   []byte
	CACertPEM     []byte
	CACertPEMFile string
	CAKey         *ecdsa.PrivateKey
	CAKeyPEM      []byte
	Cores         []*TestClusterCore
	ID            string
	RootToken     string
	RootCAs       *x509.CertPool
	TempDir       string
}

func NewTestCluster

func NewTestCluster(t testing.T, base *CoreConfig, opts *TestClusterOptions) *TestCluster

NewTestCluster creates a new test cluster based on the provided core config and test cluster options.

N.B. Even though a single base CoreConfig is provided, NewTestCluster will instantiate a core config for each core it creates. If separate seal per core is desired, opts.SealFunc can be provided to generate a seal for each one. Otherwise, the provided base.Seal will be shared among cores. NewCore's default behavior is to generate a new DefaultSeal if the provided Seal in coreConfig (i.e. base.Seal) is nil.

func (*TestCluster) Cleanup

func (c *TestCluster) Cleanup()

func (*TestCluster) EnsureCoresSealed

func (c *TestCluster) EnsureCoresSealed(t testing.T)

func (*TestCluster) Start

func (c *TestCluster) Start()

func (*TestCluster) UnsealCores

func (c *TestCluster) UnsealCores(t testing.T)

UnsealCores uses the cluster barrier keys to unseal the test cluster cores

func (*TestCluster) UnsealCoresWithError

func (c *TestCluster) UnsealCoresWithError() error

func (*TestCluster) UnsealWithStoredKeys

func (c *TestCluster) UnsealWithStoredKeys(t testing.T) error

UnsealWithStoredKeys uses stored keys to unseal the test cluster cores

type TestClusterCore

type TestClusterCore struct {
	*Core
	CoreConfig        *CoreConfig
	Client            *api.Client
	Handler           http.Handler
	Listeners         []*TestListener
	ReloadFuncs       *map[string][]reload.ReloadFunc
	ReloadFuncsLock   *sync.RWMutex
	Server            *http.Server
	ServerCert        *x509.Certificate
	ServerCertBytes   []byte
	ServerCertPEM     []byte
	ServerKey         *ecdsa.PrivateKey
	ServerKeyPEM      []byte
	TLSConfig         *tls.Config
	UnderlyingStorage physical.Backend
	Barrier           SecurityBarrier
}

func (*TestClusterCore) Seal

func (c *TestClusterCore) Seal(t testing.T)

type TestClusterOptions

type TestClusterOptions struct {
	KeepStandbysSealed bool
	SkipInit           bool
	HandlerFunc        func(*HandlerProperties) http.Handler
	BaseListenAddress  string
	NumCores           int
	SealFunc           func() Seal
	Logger             log.Logger
	TempDir            string
	CACert             []byte
	CAKey              *ecdsa.PrivateKey
}

type TestListener

type TestListener struct {
	net.Listener
	Address *net.TCPAddr
}

type TestSealOpts

type TestSealOpts struct {
	StoredKeysDisabled   bool
	RecoveryKeysDisabled bool
	Secret               []byte
}

type TokenStore

type TokenStore struct {
	*framework.Backend
	// contains filtered or unexported fields
}

TokenStore is used to manage client tokens. Tokens are used for clients to authenticate, and each token is mapped to an applicable set of policy which is used for authorization.

func NewTokenStore

func NewTokenStore(ctx context.Context, logger log.Logger, core *Core, config *logical.BackendConfig) (*TokenStore, error)

NewTokenStore is used to construct a token store that is backed by the given barrier view.

func (*TokenStore) Invalidate

func (ts *TokenStore) Invalidate(ctx context.Context, key string)

func (*TokenStore) Lookup

func (ts *TokenStore) Lookup(ctx context.Context, id string) (*logical.TokenEntry, error)

Lookup is used to find a token given its ID. It acquires a read lock, then calls lookupInternal.

func (*TokenStore) Salt

func (ts *TokenStore) Salt(ctx context.Context) (*salt.Salt, error)

func (*TokenStore) SaltID

func (ts *TokenStore) SaltID(ctx context.Context, id string) (string, error)

SaltID is used to apply a salt and hash to an ID to make sure its not reversible

func (*TokenStore) SetExpirationManager

func (ts *TokenStore) SetExpirationManager(exp *ExpirationManager)

SetExpirationManager is used to provide the token store with an expiration manager. This is used to manage prefix based revocation of tokens and to tidy entries when removed from the token store.

func (*TokenStore) UseToken

func (ts *TokenStore) UseToken(ctx context.Context, te *logical.TokenEntry) (*logical.TokenEntry, error)

UseToken is used to manage restricted use tokens and decrement their available uses. Returns two values: a potentially updated entry or, if the token has been revoked, nil; and whether an error was encountered. The locking here isn't perfect, as other parts of the code may update an entry, but usually none after the entry is already created...so this is pretty good.

func (*TokenStore) UseTokenByID

func (ts *TokenStore) UseTokenByID(ctx context.Context, id string) (*logical.TokenEntry, error)

type UIConfig

type UIConfig struct {
	// contains filtered or unexported fields
}

UIConfig contains UI configuration. This takes both a physical view and a barrier view because it is stored in both plaintext and encrypted to allow for getting the header values before the barrier is unsealed

func NewUIConfig

func NewUIConfig(enabled bool, physicalStorage physical.Backend, barrierStorage logical.Storage) *UIConfig

NewUIConfig creates a new UI config

func (*UIConfig) DeleteHeader

func (c *UIConfig) DeleteHeader(ctx context.Context, header string) error

DeleteHeader deletes the header configuration for the given header

func (*UIConfig) Enabled

func (c *UIConfig) Enabled() bool

Enabled returns if the UI is enabled

func (*UIConfig) GetHeader

func (c *UIConfig) GetHeader(ctx context.Context, header string) (string, error)

GetHeader retrieves the configured value for the given header

func (*UIConfig) HeaderKeys

func (c *UIConfig) HeaderKeys(ctx context.Context) ([]string, error)

HeaderKeys returns the list of the configured headers

func (*UIConfig) Headers

func (c *UIConfig) Headers(ctx context.Context) (http.Header, error)

Headers returns the response headers that should be returned in the UI

func (*UIConfig) SetHeader

func (c *UIConfig) SetHeader(ctx context.Context, header, value string) error

SetHeader sets the value for the given header

type UnsealStrategy

type UnsealStrategy interface {
	// contains filtered or unexported methods
}

Package Files

Documentation was rendered with GOOS=linux and GOARCH=amd64.

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