dex/storage/storage.go

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2016-07-26 01:30:28 +05:30
package storage
import (
"crypto/ecdsa"
"crypto/elliptic"
"crypto/rand"
"crypto/rsa"
"encoding/base32"
"errors"
"fmt"
"io"
"strings"
"time"
jose "gopkg.in/square/go-jose.v2"
)
var (
drivers = make(map[string]Driver)
// stubbed out for testing
now = time.Now
)
// ErrNotFound is the error returned by storages if a resource cannot be found.
var ErrNotFound = errors.New("not found")
// Kubernetes only allows lower case letters for names.
//
// TODO(ericchiang): refactor ID creation onto the storage.
var encoding = base32.NewEncoding("abcdefghijklmnopqrstuvwxyz234567")
// NewNonce returns a new ID for the objects.
func NewNonce() string {
buff := make([]byte, 8) // 64 bit random ID.
if _, err := io.ReadFull(rand.Reader, buff); err != nil {
panic(err)
}
// Trim padding
return strings.TrimRight(encoding.EncodeToString(buff), "=")
}
// Driver is the interface implemented by storage drivers.
type Driver interface {
// Open returns a storage implementation. It should only validate its
// arguments and not return an error if the underlying storage is
// unavailable.
Open(config map[string]string) (Storage, error)
}
// Register makes a storage driver available by the provided name. If Register
// is called twice with the same name or if driver is nil, it panics.
func Register(name string, driver Driver) {
if driver == nil {
panic("driver cannot be nil")
}
if _, ok := drivers[name]; ok {
panic("driver " + name + " is already registered")
}
drivers[name] = driver
}
// Open returns a new storage object with a given key rotation strategy.
func Open(driverName string, config map[string]string) (Storage, error) {
driver, ok := drivers[driverName]
if !ok {
return nil, fmt.Errorf("no driver of type %s found", driverName)
}
return driver.Open(config)
}
// Storage is the storage interface used by the server. Implementations, at minimum
// require compare-and-swap atomic actions.
//
// Implementations are expected to perform their own garbage collection of
// expired objects (expect keys, which are handled by the server).
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type Storage interface {
Close() error
// TODO(ericchiang): Let the storages set the IDs of these objects.
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CreateAuthRequest(a AuthRequest) error
CreateClient(c Client) error
CreateAuthCode(c AuthCode) error
CreateRefresh(r Refresh) error
// TODO(ericchiang): return (T, bool, error) so we can indicate not found
// requests that way instead of using ErrNotFound.
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GetAuthRequest(id string) (AuthRequest, error)
GetAuthCode(id string) (AuthCode, error)
GetClient(id string) (Client, error)
GetKeys() (Keys, error)
GetRefresh(id string) (Refresh, error)
ListClients() ([]Client, error)
ListRefreshTokens() ([]Refresh, error)
// Delete methods MUST be atomic.
DeleteAuthRequest(id string) error
DeleteAuthCode(code string) error
DeleteClient(id string) error
DeleteRefresh(id string) error
// Update functions are assumed to be a performed within a single object transaction.
UpdateClient(id string, updater func(old Client) (Client, error)) error
UpdateKeys(updater func(old Keys) (Keys, error)) error
UpdateAuthRequest(id string, updater func(a AuthRequest) (AuthRequest, error)) error
}
// Client is an OAuth2 client.
//
// For further reading see:
// * Trusted peers: https://developers.google.com/identity/protocols/CrossClientAuth
// * Public clients: https://developers.google.com/api-client-library/python/auth/installed-app
type Client struct {
ID string
Secret string
RedirectURIs []string
// TrustedPeers are a list of peers which can issue tokens on this client's behalf.
// Clients inherently trust themselves.
TrustedPeers []string
// Public clients must use either use a redirectURL 127.0.0.1:X or "urn:ietf:wg:oauth:2.0:oob"
Public bool
Name string
LogoURL string
}
// Identity represents the ID Token claims supported by the server.
type Identity struct {
UserID string
Username string
Email string
EmailVerified bool
Groups []string
// ConnectorData holds data used by the connector for subsequent requests after initial
// authentication, such as access tokens for upstream provides.
//
// This data is never shared with end users, OAuth clients, or through the API.
ConnectorData []byte
}
// AuthRequest represents a OAuth2 client authorization request. It holds the state
// of a single auth flow up to the point that the user authorizes the client.
type AuthRequest struct {
ID string
ClientID string
ResponseTypes []string
Scopes []string
RedirectURI string
Nonce string
State string
// The client has indicated that the end user must be shown an approval prompt
// on all requests. The server cannot cache their initial action for subsequent
// attempts.
ForceApprovalPrompt bool
// The identity of the end user. Generally nil until the user authenticates
// with a backend.
Identity *Identity
// The connector used to login the user. Set when the user authenticates.
ConnectorID string
Expiry time.Time
}
// AuthCode represents a code which can be exchanged for an OAuth2 token response.
type AuthCode struct {
ID string
ClientID string
RedirectURI string
ConnectorID string
Nonce string
Scopes []string
Identity Identity
Expiry time.Time
}
// Refresh is an OAuth2 refresh token.
type Refresh struct {
// The actual refresh token.
RefreshToken string
// Client this refresh token is valid for.
ClientID string
ConnectorID string
// Scopes present in the initial request. Refresh requests may specify a set
// of scopes different from the initial request when refreshing a token,
// however those scopes must be encompassed by this set.
Scopes []string
Nonce string
Identity Identity
}
// VerificationKey is a rotated signing key which can still be used to verify
// signatures.
type VerificationKey struct {
PublicKey *jose.JSONWebKey `json:"publicKey"`
Expiry time.Time `json:"expiry"`
}
// Keys hold encryption and signing keys.
type Keys struct {
// Key for creating and verifying signatures. These may be nil.
SigningKey *jose.JSONWebKey
SigningKeyPub *jose.JSONWebKey
// Old signing keys which have been rotated but can still be used to validate
// existing signatures.
VerificationKeys []VerificationKey
// The next time the signing key will rotate.
//
// For caching purposes, implementations MUST NOT update keys before this time.
NextRotation time.Time
}
// Sign creates a JWT using the signing key.
func (k Keys) Sign(payload []byte) (jws string, err error) {
if k.SigningKey == nil {
return "", fmt.Errorf("no key to sign payload with")
}
signingKey := jose.SigningKey{Key: k.SigningKey}
switch key := k.SigningKey.Key.(type) {
case *rsa.PrivateKey:
// TODO(ericchiang): Allow different cryptographic hashes.
signingKey.Algorithm = jose.RS256
case *ecdsa.PrivateKey:
switch key.Params() {
case elliptic.P256().Params():
signingKey.Algorithm = jose.ES256
case elliptic.P384().Params():
signingKey.Algorithm = jose.ES384
case elliptic.P521().Params():
signingKey.Algorithm = jose.ES512
default:
return "", errors.New("unsupported ecdsa curve")
}
}
signer, err := jose.NewSigner(signingKey, &jose.SignerOptions{})
if err != nil {
return "", fmt.Errorf("new signier: %v", err)
}
signature, err := signer.Sign(payload)
if err != nil {
return "", fmt.Errorf("signing payload: %v", err)
}
return signature.CompactSerialize()
}