// Copyright (C) 2019 Storj Labs, Inc. // See LICENSE for copying information. package uplink import ( "github.com/btcsuite/btcutil/base58" "github.com/gogo/protobuf/proto" "github.com/zeebo/errs" "storj.io/common/encryption" "storj.io/common/macaroon" "storj.io/common/paths" "storj.io/common/pb" "storj.io/common/storj" ) const ( defaultCipher = storj.EncAESGCM ) // EncryptionAccess represents an encryption access context. It holds // information about how various buckets and objects should be // encrypted and decrypted. type EncryptionAccess struct { store *encryption.Store } // NewEncryptionAccess creates an encryption access context func NewEncryptionAccess() *EncryptionAccess { store := encryption.NewStore() store.SetDefaultPathCipher(defaultCipher) return &EncryptionAccess{store: store} } // NewEncryptionAccessWithDefaultKey creates an encryption access context with // a default key set. // Use (*Project).SaltedKeyFromPassphrase to generate a default key func NewEncryptionAccessWithDefaultKey(defaultKey storj.Key) *EncryptionAccess { ec := NewEncryptionAccess() ec.SetDefaultKey(defaultKey) return ec } // Store returns the underlying encryption store for the access context. func (s *EncryptionAccess) Store() *encryption.Store { return s.store } // SetDefaultKey sets the default key for the encryption access context. // Use (*Project).SaltedKeyFromPassphrase to generate a default key func (s *EncryptionAccess) SetDefaultKey(defaultKey storj.Key) { s.store.SetDefaultKey(&defaultKey) } // Import merges the other encryption access context into this one. In cases // of conflicting path decryption settings (including if both accesses have // a default key), the new settings are kept. func (s *EncryptionAccess) Import(other *EncryptionAccess) error { if key := other.store.GetDefaultKey(); key != nil { s.store.SetDefaultKey(key) } return other.store.Iterate(s.store.Add) } // EncryptionRestriction represents a scenario where some set of objects // may need to be encrypted/decrypted type EncryptionRestriction struct { Bucket string PathPrefix storj.Path } // Restrict creates a new EncryptionAccess with no default key, where the key material // in the new access is just enough to allow someone to access all of the given // restrictions but no more. func (s *EncryptionAccess) Restrict(apiKey APIKey, restrictions ...EncryptionRestriction) (APIKey, *EncryptionAccess, error) { if len(restrictions) == 0 { // Should the function signature be // func (s *EncryptionAccess) Restrict(apiKey APIKey, restriction EncryptionRestriction, restrictions ...EncryptionRestriction) (APIKey, *EncryptionAccess, error) { // so we don't have to do this test? return APIKey{}, nil, errs.New("at least one restriction required") } caveat := macaroon.Caveat{} access := NewEncryptionAccess() for _, res := range restrictions { unencPath := paths.NewUnencrypted(res.PathPrefix) cipher := storj.EncAESGCM // TODO(jeff): pick the right path cipher encPath, err := encryption.EncryptPath(res.Bucket, unencPath, cipher, s.store) if err != nil { return APIKey{}, nil, err } derivedKey, err := encryption.DerivePathKey(res.Bucket, unencPath, s.store) if err != nil { return APIKey{}, nil, err } if err := access.store.Add(res.Bucket, unencPath, encPath, *derivedKey); err != nil { return APIKey{}, nil, err } caveat.AllowedPaths = append(caveat.AllowedPaths, &macaroon.Caveat_Path{ Bucket: []byte(res.Bucket), EncryptedPathPrefix: []byte(encPath.Raw()), }) } apiKey, err := apiKey.Restrict(caveat) if err != nil { return APIKey{}, nil, err } return apiKey, access, nil } // Serialize turns an EncryptionAccess into base58 func (s *EncryptionAccess) Serialize() (string, error) { p, err := s.toProto() if err != nil { return "", err } data, err := proto.Marshal(p) if err != nil { return "", errs.New("unable to marshal encryption access: %v", err) } return base58.CheckEncode(data, 0), nil } func (s *EncryptionAccess) toProto() (*pb.EncryptionAccess, error) { var storeEntries []*pb.EncryptionAccess_StoreEntry err := s.store.Iterate(func(bucket string, unenc paths.Unencrypted, enc paths.Encrypted, key storj.Key) error { storeEntries = append(storeEntries, &pb.EncryptionAccess_StoreEntry{ Bucket: []byte(bucket), UnencryptedPath: []byte(unenc.Raw()), EncryptedPath: []byte(enc.Raw()), Key: key[:], }) return nil }) if err != nil { return nil, err } var defaultKey []byte if key := s.store.GetDefaultKey(); key != nil { defaultKey = key[:] } return &pb.EncryptionAccess{ DefaultKey: defaultKey, StoreEntries: storeEntries, }, nil } // ParseEncryptionAccess parses a base58 serialized encryption access into a working one. func ParseEncryptionAccess(serialized string) (*EncryptionAccess, error) { data, version, err := base58.CheckDecode(serialized) if err != nil || version != 0 { return nil, errs.New("invalid encryption access format") } p := new(pb.EncryptionAccess) if err := proto.Unmarshal(data, p); err != nil { return nil, errs.New("unable to unmarshal encryption access: %v", err) } return parseEncryptionAccessFromProto(p) } func parseEncryptionAccessFromProto(p *pb.EncryptionAccess) (*EncryptionAccess, error) { access := NewEncryptionAccess() if len(p.DefaultKey) > 0 { if len(p.DefaultKey) != len(storj.Key{}) { return nil, errs.New("invalid default key in encryption access") } var defaultKey storj.Key copy(defaultKey[:], p.DefaultKey) access.SetDefaultKey(defaultKey) } for _, entry := range p.StoreEntries { if len(entry.Key) != len(storj.Key{}) { return nil, errs.New("invalid key in encryption access entry") } var key storj.Key copy(key[:], entry.Key) err := access.store.Add( string(entry.Bucket), paths.NewUnencrypted(string(entry.UnencryptedPath)), paths.NewEncrypted(string(entry.EncryptedPath)), key) if err != nil { return nil, errs.New("invalid encryption access entry: %v", err) } } return access, nil }