package encryption import ( "bytes" "crypto/ecdsa" "crypto/rand" "database/sql" "fmt" "go.uber.org/zap" "github.com/golang/protobuf/proto" "github.com/pkg/errors" "github.com/status-im/status-go/eth-node/crypto" "github.com/status-im/status-go/eth-node/types" "github.com/status-im/status-go/protocol/encryption/multidevice" "github.com/status-im/status-go/protocol/encryption/publisher" "github.com/status-im/status-go/protocol/encryption/sharedsecret" ) //go:generate protoc --go_out=. ./protocol_message.proto const ( protocolVersion = 1 sharedSecretNegotiationVersion = 1 partitionedTopicMinVersion = 1 defaultMinVersion = 0 maxKeysChannelSize = 10000 ) type PartitionTopicMode int const ( PartitionTopicNoSupport PartitionTopicMode = iota PartitionTopicV1 ) type ProtocolMessageSpec struct { Message *ProtocolMessage // Installations is the targeted devices Installations []*multidevice.Installation // SharedSecret is a shared secret established among the installations SharedSecret *sharedsecret.Secret // AgreedSecret indicates whether the shared secret has been agreed AgreedSecret bool // Public means that the spec contains a public wrapped message Public bool } func (p *ProtocolMessageSpec) MinVersion() uint32 { if len(p.Installations) == 0 { return defaultMinVersion } version := p.Installations[0].Version for _, installation := range p.Installations[1:] { if installation.Version < version { version = installation.Version } } return version } func (p *ProtocolMessageSpec) PartitionedTopicMode() PartitionTopicMode { if p.MinVersion() >= partitionedTopicMinVersion { return PartitionTopicV1 } return PartitionTopicNoSupport } type Protocol struct { encryptor *encryptor secret *sharedsecret.SharedSecret multidevice *multidevice.Multidevice publisher *publisher.Publisher subscriptions *Subscriptions logger *zap.Logger } var ( // ErrNoPayload means that there was no payload found in the received protocol message. ErrNoPayload = errors.New("no payload") ErrNoRatchetKey = errors.New("no ratchet key for given keyID") ) // New creates a new ProtocolService instance func New( db *sql.DB, installationID string, logger *zap.Logger, ) *Protocol { return NewWithEncryptorConfig( db, installationID, defaultEncryptorConfig(installationID, logger), logger, ) } // DB and migrations are shared between encryption package // and its sub-packages. func NewWithEncryptorConfig( db *sql.DB, installationID string, encryptorConfig encryptorConfig, logger *zap.Logger, ) *Protocol { return &Protocol{ encryptor: newEncryptor(db, encryptorConfig), secret: sharedsecret.New(db, logger), multidevice: multidevice.New(db, &multidevice.Config{ MaxInstallations: 3, ProtocolVersion: protocolVersion, InstallationID: installationID, }), publisher: publisher.New(logger), logger: logger.With(zap.Namespace("Protocol")), } } type Subscriptions struct { SharedSecrets []*sharedsecret.Secret SendContactCode <-chan struct{} NewHashRatchetKeys chan []*HashRatchetInfo Quit chan struct{} } func (p *Protocol) Start(myIdentity *ecdsa.PrivateKey) (*Subscriptions, error) { // Propagate currently cached shared secrets. secrets, err := p.secret.All() if err != nil { return nil, errors.Wrap(err, "failed to get all secrets") } p.subscriptions = &Subscriptions{ SharedSecrets: secrets, SendContactCode: p.publisher.Start(), NewHashRatchetKeys: make(chan []*HashRatchetInfo, maxKeysChannelSize), Quit: make(chan struct{}), } return p.subscriptions, nil } func (p *Protocol) Stop() error { p.publisher.Stop() if p.subscriptions != nil { close(p.subscriptions.Quit) } return nil } func (p *Protocol) addBundle(myIdentityKey *ecdsa.PrivateKey, msg *ProtocolMessage) error { // Get a bundle installations, err := p.multidevice.GetOurActiveInstallations(&myIdentityKey.PublicKey) if err != nil { return err } bundle, err := p.encryptor.CreateBundle(myIdentityKey, installations) if err != nil { return err } msg.Bundles = []*Bundle{bundle} return nil } // BuildPublicMessage marshals a public chat message given the user identity private key and a payload func (p *Protocol) BuildPublicMessage(myIdentityKey *ecdsa.PrivateKey, payload []byte) (*ProtocolMessageSpec, error) { // Build message not encrypted message := &ProtocolMessage{ InstallationId: p.encryptor.config.InstallationID, PublicMessage: payload, } err := p.addBundle(myIdentityKey, message) if err != nil { return nil, err } return &ProtocolMessageSpec{Message: message, Public: true}, nil } // BuildEncryptedMessage returns a 1:1 chat message and optionally a negotiated topic given the user identity private key, the recipient's public key, and a payload func (p *Protocol) BuildEncryptedMessage(myIdentityKey *ecdsa.PrivateKey, publicKey *ecdsa.PublicKey, payload []byte) (*ProtocolMessageSpec, error) { // Get recipients installations. activeInstallations, err := p.multidevice.GetActiveInstallations(publicKey) if err != nil { return nil, err } // Encrypt payload encryptedMessagesByInstalls, installations, err := p.encryptor.EncryptPayload(publicKey, myIdentityKey, activeInstallations, payload) if err != nil { return nil, err } // Build message message := &ProtocolMessage{ InstallationId: p.encryptor.config.InstallationID, EncryptedMessage: encryptedMessagesByInstalls, } err = p.addBundle(myIdentityKey, message) if err != nil { return nil, err } // Check who we are sending the message to, and see if we have a shared secret // across devices var installationIDs []string for installationID := range message.GetEncryptedMessage() { if installationID != noInstallationID { installationIDs = append(installationIDs, installationID) } } sharedSecret, agreed, err := p.secret.Agreed(myIdentityKey, p.encryptor.config.InstallationID, publicKey, installationIDs) if err != nil { return nil, err } spec := &ProtocolMessageSpec{ SharedSecret: sharedSecret, AgreedSecret: agreed, Message: message, Installations: installations, } return spec, nil } func (p *Protocol) GenerateHashRatchetKey(groupID []byte) (*HashRatchetKeyCompatibility, error) { return p.encryptor.GenerateHashRatchetKey(groupID) } // Deprecated: This function is deprecated as it does not marshal groupID. Kept for backward compatibility. func (p *Protocol) GetAllHRKeysMarshaledV1(groupID []byte) ([]byte, error) { keys, err := p.GetAllHRKeys(groupID) if err != nil { return nil, err } if keys == nil { return nil, nil } return proto.Marshal(keys) } func (p *Protocol) GetAllHRKeysMarshaledV2(groupID []byte) ([]byte, error) { keys, err := p.GetAllHRKeys(groupID) if err != nil { return nil, err } if keys == nil { return nil, nil } header := &HRHeader{ SeqNo: 0, GroupId: groupID, Keys: keys, } return proto.Marshal(header) } func (p *Protocol) GetAllHRKeys(groupID []byte) (*HRKeys, error) { ratchets, err := p.encryptor.persistence.GetKeysForGroup(groupID) if err != nil { return nil, err } if len(ratchets) == 0 { return nil, nil } return p.GetHRKeys(ratchets), nil } // GetKeyIDsForGroup returns a slice of key IDs belonging to a given group ID func (p *Protocol) GetKeysForGroup(groupID []byte) ([]*HashRatchetKeyCompatibility, error) { return p.encryptor.persistence.GetKeysForGroup(groupID) } func (p *Protocol) GetHRKeys(ratchets []*HashRatchetKeyCompatibility) *HRKeys { keys := &HRKeys{} for _, ratchet := range ratchets { key := &HRKey{ DeprecatedKeyId: ratchet.DeprecatedKeyID(), Key: ratchet.Key, Timestamp: ratchet.Timestamp, } keys.Keys = append(keys.Keys, key) } return keys } // BuildHashRatchetRekeyGroup builds a public message // with the new key func (p *Protocol) BuildHashRatchetReKeyGroupMessage(myIdentityKey *ecdsa.PrivateKey, recipients []*ecdsa.PublicKey, groupID []byte, payload []byte, ratchet *HashRatchetKeyCompatibility) (*ProtocolMessageSpec, error) { var err error if ratchet == nil { ratchet, err = p.GenerateHashRatchetKey(groupID) if err != nil { return nil, err } } message, err := buildGroupRekeyMessage(myIdentityKey, groupID, ratchet.Timestamp, ratchet.Key, recipients) if err != nil { return nil, err } keys := &HRKeys{ RekeyGroup: message, } spec := &ProtocolMessageSpec{ Public: true, Message: &ProtocolMessage{ InstallationId: p.encryptor.config.InstallationID, EncryptedMessage: map[string]*EncryptedMessageProtocol{noInstallationID: &EncryptedMessageProtocol{ HRHeader: &HRHeader{ SeqNo: 0, GroupId: groupID, Keys: keys, }, Payload: payload, }, }, }, } return spec, nil } // BuildHashRatchetKeyExchangeMessage builds a 1:1 message // containing newly generated hash ratchet key func (p *Protocol) BuildHashRatchetKeyExchangeMessage(myIdentityKey *ecdsa.PrivateKey, publicKey *ecdsa.PublicKey, groupID []byte, ratchets []*HashRatchetKeyCompatibility) (*ProtocolMessageSpec, error) { keys := p.GetHRKeys(ratchets) encodedKeys, err := proto.Marshal(keys) if err != nil { return nil, err } response, err := p.BuildEncryptedMessage(myIdentityKey, publicKey, encodedKeys) if err != nil { return nil, err } // Loop through installations and assign HRHeader // SeqNo=0 has a special meaning for HandleMessage // and signifies a message with hash ratchet key payload for _, v := range response.Message.EncryptedMessage { v.HRHeader = &HRHeader{ SeqNo: 0, GroupId: groupID, Keys: keys, } } return response, err } func (p *Protocol) BuildHashRatchetKeyExchangeMessageWithPayload(myIdentityKey *ecdsa.PrivateKey, publicKey *ecdsa.PublicKey, groupID []byte, ratchets []*HashRatchetKeyCompatibility, payload []byte) (*ProtocolMessageSpec, error) { keys := p.GetHRKeys(ratchets) response, err := p.BuildEncryptedMessage(myIdentityKey, publicKey, payload) if err != nil { return nil, err } // Loop through installations and assign HRHeader // SeqNo=0 has a special meaning for HandleMessage // and signifies a message with hash ratchet key payload for _, v := range response.Message.EncryptedMessage { v.HRHeader = &HRHeader{ SeqNo: 0, GroupId: groupID, Keys: keys, } } return response, err } func (p *Protocol) GetCurrentKeyForGroup(groupID []byte) (*HashRatchetKeyCompatibility, error) { return p.encryptor.persistence.GetCurrentKeyForGroup(groupID) } // BuildHashRatchetMessage returns a hash ratchet chat message func (p *Protocol) BuildHashRatchetMessage(groupID []byte, payload []byte) (*ProtocolMessageSpec, error) { ratchet, err := p.encryptor.persistence.GetCurrentKeyForGroup(groupID) if err != nil { return nil, err } // Encrypt payload encryptedMessagesByInstalls, err := p.encryptor.EncryptHashRatchetPayload(ratchet, payload) if err != nil { return nil, err } // Build message message := &ProtocolMessage{ InstallationId: p.encryptor.config.InstallationID, EncryptedMessage: encryptedMessagesByInstalls, } spec := &ProtocolMessageSpec{ Message: message, } return spec, nil } func (p *Protocol) EncryptCommunityGrants(privateKey *ecdsa.PrivateKey, recipientGrants map[*ecdsa.PublicKey][]byte) (map[uint32][]byte, error) { grants := make(map[uint32][]byte) for recipientKey, grant := range recipientGrants { sharedKey, err := GenerateSharedKey(privateKey, recipientKey) if err != nil { return nil, err } encryptedGrant, err := encrypt(grant, sharedKey, rand.Reader) if err != nil { return nil, err } kBytes := publicKeyMostRelevantBytes(recipientKey) grants[kBytes] = encryptedGrant } return grants, nil } func (p *Protocol) DecryptCommunityGrant(myIdentityKey *ecdsa.PrivateKey, senderKey *ecdsa.PublicKey, grants map[uint32][]byte) ([]byte, error) { kBytes := publicKeyMostRelevantBytes(&myIdentityKey.PublicKey) ecryptedGrant, ok := grants[kBytes] if !ok { return nil, errors.New("can't find related grant in the map") } sharedKey, err := GenerateSharedKey(myIdentityKey, senderKey) if err != nil { return nil, err } return decrypt(ecryptedGrant, sharedKey) } func (p *Protocol) GetKeyExMessageSpecs(groupID []byte, identity *ecdsa.PrivateKey, recipients []*ecdsa.PublicKey, forceRekey bool) ([]*ProtocolMessageSpec, error) { var ratchets []*HashRatchetKeyCompatibility var err error if !forceRekey { ratchets, err = p.encryptor.persistence.GetKeysForGroup(groupID) if err != nil { return nil, err } } if len(ratchets) == 0 || forceRekey { ratchet, err := p.GenerateHashRatchetKey(groupID) if err != nil { return nil, err } ratchets = []*HashRatchetKeyCompatibility{ratchet} } specs := make([]*ProtocolMessageSpec, len(recipients)) for i, recipient := range recipients { keyExMsg, err := p.BuildHashRatchetKeyExchangeMessage(identity, recipient, groupID, ratchets) if err != nil { return nil, err } specs[i] = keyExMsg } return specs, nil } // BuildDHMessage builds a message with DH encryption so that it can be decrypted by any other device. func (p *Protocol) BuildDHMessage(myIdentityKey *ecdsa.PrivateKey, destination *ecdsa.PublicKey, payload []byte) (*ProtocolMessageSpec, error) { // Encrypt payload encryptionResponse, err := p.encryptor.EncryptPayloadWithDH(destination, payload) if err != nil { return nil, err } // Build message message := &ProtocolMessage{ InstallationId: p.encryptor.config.InstallationID, EncryptedMessage: encryptionResponse, } err = p.addBundle(myIdentityKey, message) if err != nil { return nil, err } return &ProtocolMessageSpec{Message: message}, nil } // ProcessPublicBundle processes a received X3DH bundle. func (p *Protocol) ProcessPublicBundle(myIdentityKey *ecdsa.PrivateKey, bundle *Bundle) ([]*multidevice.Installation, error) { logger := p.logger.With(zap.String("site", "ProcessPublicBundle")) if err := p.encryptor.ProcessPublicBundle(myIdentityKey, bundle); err != nil { return nil, err } installations, enabled, err := p.recoverInstallationsFromBundle(myIdentityKey, bundle) if err != nil { return nil, err } // TODO(adam): why do we add installations using identity obtained from GetIdentity() // instead of the output of crypto.CompressPubkey()? I tried the second option // and the unit tests TestTopic and TestMaxDevices fail. identityFromBundle := bundle.GetIdentity() theirIdentity, err := ExtractIdentity(bundle) if err != nil { logger.Panic("unrecoverable error extracting identity", zap.Error(err)) } compressedIdentity := crypto.CompressPubkey(theirIdentity) if !bytes.Equal(identityFromBundle, compressedIdentity) { logger.Panic("identity from bundle and compressed are not equal") } return p.multidevice.AddInstallations(bundle.GetIdentity(), bundle.GetTimestamp(), installations, enabled) } func (p *Protocol) GetMultiDevice() *multidevice.Multidevice { return p.multidevice } // recoverInstallationsFromBundle extracts installations from the bundle. // It returns extracted installations and true if the installations // are ours, i.e. the bundle was created by our identity key. func (p *Protocol) recoverInstallationsFromBundle(myIdentityKey *ecdsa.PrivateKey, bundle *Bundle) ([]*multidevice.Installation, bool, error) { var installations []*multidevice.Installation theirIdentity, err := ExtractIdentity(bundle) if err != nil { return nil, false, err } myIdentityStr := fmt.Sprintf("0x%x", crypto.FromECDSAPub(&myIdentityKey.PublicKey)) theirIdentityStr := fmt.Sprintf("0x%x", crypto.FromECDSAPub(theirIdentity)) // Any device from other peers will be considered enabled, ours needs to // be explicitly enabled. enabled := theirIdentityStr != myIdentityStr signedPreKeys := bundle.GetSignedPreKeys() for installationID, signedPreKey := range signedPreKeys { if installationID != p.multidevice.InstallationID() { installations = append(installations, &multidevice.Installation{ Identity: theirIdentityStr, ID: installationID, Version: signedPreKey.GetProtocolVersion(), }) } } return installations, enabled, nil } // GetBundle retrieves or creates a X3DH bundle, given a private identity key. func (p *Protocol) GetBundle(myIdentityKey *ecdsa.PrivateKey) (*Bundle, error) { installations, err := p.multidevice.GetOurActiveInstallations(&myIdentityKey.PublicKey) if err != nil { return nil, err } return p.encryptor.CreateBundle(myIdentityKey, installations) } // EnableInstallation enables an installation for multi-device sync. func (p *Protocol) EnableInstallation(myIdentityKey *ecdsa.PublicKey, installationID string) error { return p.multidevice.EnableInstallation(myIdentityKey, installationID) } // DisableInstallation disables an installation for multi-device sync. func (p *Protocol) DisableInstallation(myIdentityKey *ecdsa.PublicKey, installationID string) error { return p.multidevice.DisableInstallation(myIdentityKey, installationID) } // GetOurInstallations returns all the installations available given an identity func (p *Protocol) GetOurInstallations(myIdentityKey *ecdsa.PublicKey) ([]*multidevice.Installation, error) { return p.multidevice.GetOurInstallations(myIdentityKey) } // GetOurActiveInstallations returns all the active installations available given an identity func (p *Protocol) GetOurActiveInstallations(myIdentityKey *ecdsa.PublicKey) ([]*multidevice.Installation, error) { return p.multidevice.GetOurActiveInstallations(myIdentityKey) } // SetInstallationMetadata sets the metadata for our own installation func (p *Protocol) SetInstallationMetadata(myIdentityKey *ecdsa.PublicKey, installationID string, data *multidevice.InstallationMetadata) error { return p.multidevice.SetInstallationMetadata(myIdentityKey, installationID, data) } // SetInstallationName sets the metadata for our own installation func (p *Protocol) SetInstallationName(myIdentityKey *ecdsa.PublicKey, installationID string, name string) error { return p.multidevice.SetInstallationName(myIdentityKey, installationID, name) } // GetPublicBundle retrieves a public bundle given an identity func (p *Protocol) GetPublicBundle(theirIdentityKey *ecdsa.PublicKey) (*Bundle, error) { installations, err := p.multidevice.GetActiveInstallations(theirIdentityKey) if err != nil { return nil, err } return p.encryptor.GetPublicBundle(theirIdentityKey, installations) } // ConfirmMessageProcessed confirms and deletes message keys for the given messages func (p *Protocol) ConfirmMessageProcessed(messageID []byte) error { logger := p.logger.With(zap.String("site", "ConfirmMessageProcessed")) logger.Debug("confirming message", zap.String("messageID", types.EncodeHex(messageID))) return p.encryptor.ConfirmMessageProcessed(messageID) } type HashRatchetInfo struct { GroupID []byte KeyID []byte } type DecryptMessageResponse struct { DecryptedMessage []byte Installations []*multidevice.Installation SharedSecrets []*sharedsecret.Secret HashRatchetInfo []*HashRatchetInfo } func (p *Protocol) HandleHashRatchetKeysPayload(groupID, encodedKeys []byte, myIdentityKey *ecdsa.PrivateKey, theirIdentityKey *ecdsa.PublicKey) ([]*HashRatchetInfo, error) { keys := &HRKeys{} err := proto.Unmarshal(encodedKeys, keys) if err != nil { return nil, err } return p.HandleHashRatchetKeys(groupID, keys, myIdentityKey, theirIdentityKey) } func (p *Protocol) HandleHashRatchetHeadersPayload(encodedHeaders [][]byte) error { for _, encodedHeader := range encodedHeaders { header := &HRHeader{} err := proto.Unmarshal(encodedHeader, header) if err != nil { return err } _, err = p.HandleHashRatchetKeys(header.GroupId, header.Keys, nil, nil) if err != nil { return err } } return nil } func (p *Protocol) HandleHashRatchetKeys(groupID []byte, keys *HRKeys, myIdentityKey *ecdsa.PrivateKey, theirIdentityKey *ecdsa.PublicKey) ([]*HashRatchetInfo, error) { if keys == nil { return nil, nil } var info []*HashRatchetInfo for _, key := range keys.Keys { ratchet := &HashRatchetKeyCompatibility{ GroupID: groupID, Timestamp: key.Timestamp, Key: key.Key, } // If there's no timestamp, is coming from an older client if key.Timestamp == 0 { ratchet.Timestamp = uint64(key.DeprecatedKeyId) } keyID, err := ratchet.GetKeyID() if err != nil { return nil, err } p.logger.Debug("retrieved keys", zap.String("keyID", types.Bytes2Hex(keyID))) // Payload contains hash ratchet key err = p.encryptor.persistence.SaveHashRatchetKey(ratchet) if err != nil { return nil, err } info = append(info, &HashRatchetInfo{GroupID: groupID, KeyID: keyID}) } if keys.RekeyGroup != nil { if keys.RekeyGroup.Timestamp == 0 { return nil, errors.New("timestamp can't be nil") } encryptionKey, err := decryptGroupRekeyMessage(myIdentityKey, theirIdentityKey, keys.RekeyGroup) if err != nil { return nil, err } if len(encryptionKey) != 0 { ratchet := &HashRatchetKeyCompatibility{ GroupID: groupID, Timestamp: keys.RekeyGroup.Timestamp, Key: encryptionKey, } keyID, err := ratchet.GetKeyID() if err != nil { return nil, err } p.logger.Debug("retrieved group keys", zap.String("keyID", types.Bytes2Hex(keyID))) // Payload contains hash ratchet key err = p.encryptor.persistence.SaveHashRatchetKey(ratchet) if err != nil { return nil, err } info = append(info, &HashRatchetInfo{GroupID: groupID, KeyID: keyID}) } } if p.subscriptions != nil { p.subscriptions.NewHashRatchetKeys <- info } return info, nil } // HandleMessage unmarshals a message and processes it, decrypting it if it is a 1:1 message. func (p *Protocol) HandleMessage( myIdentityKey *ecdsa.PrivateKey, theirPublicKey *ecdsa.PublicKey, protocolMessage *ProtocolMessage, messageID []byte, ) (*DecryptMessageResponse, error) { logger := p.logger.With(zap.String("site", "HandleMessage")) response := &DecryptMessageResponse{} logger.Debug("received a protocol message", zap.String("sender-public-key", types.EncodeHex(crypto.FromECDSAPub(theirPublicKey))), zap.String("my-installation-id", p.encryptor.config.InstallationID), zap.String("messageID", types.EncodeHex(messageID))) if p.encryptor == nil { return nil, errors.New("encryption service not initialized") } // Process bundles for _, bundle := range protocolMessage.GetBundles() { // Should we stop processing if the bundle cannot be verified? newInstallations, err := p.ProcessPublicBundle(myIdentityKey, bundle) if err != nil { return nil, err } response.Installations = newInstallations } // Check if it's a public message if publicMessage := protocolMessage.GetPublicMessage(); publicMessage != nil { // Nothing to do, as already in cleartext response.DecryptedMessage = publicMessage return response, nil } // Decrypt message if encryptedMessage := protocolMessage.GetEncryptedMessage(); encryptedMessage != nil { message, err := p.encryptor.DecryptPayload( myIdentityKey, theirPublicKey, protocolMessage.GetInstallationId(), encryptedMessage, messageID, ) if err == ErrHashRatchetGroupIDNotFound { msg := p.encryptor.GetMessage(encryptedMessage) if msg != nil { if header := msg.GetHRHeader(); header != nil { response.HashRatchetInfo = append(response.HashRatchetInfo, &HashRatchetInfo{GroupID: header.GroupId, KeyID: header.KeyId}) } } return response, err } if err != nil { return nil, err } dmProtocol := encryptedMessage[p.encryptor.config.InstallationID] if dmProtocol == nil { dmProtocol = encryptedMessage[noInstallationID] } if dmProtocol != nil { hrHeader := dmProtocol.HRHeader if hrHeader != nil && hrHeader.SeqNo == 0 { var hashRatchetKeys []*HashRatchetInfo if hrHeader.Keys != nil { hashRatchetKeys, err = p.HandleHashRatchetKeys(hrHeader.GroupId, hrHeader.Keys, myIdentityKey, theirPublicKey) if err != nil { return nil, err } } else { // For backward compatibility hashRatchetKeys, err = p.HandleHashRatchetKeysPayload(hrHeader.GroupId, message, myIdentityKey, theirPublicKey) if err != nil { return nil, err } } response.HashRatchetInfo = hashRatchetKeys } } bundles := protocolMessage.GetBundles() version := getProtocolVersion(bundles, protocolMessage.GetInstallationId()) if version >= sharedSecretNegotiationVersion { sharedSecret, err := p.secret.Generate(myIdentityKey, theirPublicKey, protocolMessage.GetInstallationId()) if err != nil { return nil, err } response.SharedSecrets = []*sharedsecret.Secret{sharedSecret} } response.DecryptedMessage = message return response, nil } // Return error return nil, ErrNoPayload } func (p *Protocol) ShouldAdvertiseBundle(publicKey *ecdsa.PublicKey, time int64) (bool, error) { return p.publisher.ShouldAdvertiseBundle(publicKey, time) } func (p *Protocol) ConfirmBundleAdvertisement(publicKey *ecdsa.PublicKey, time int64) { p.publisher.SetLastAck(publicKey, time) } func (p *Protocol) BuildBundleAdvertiseMessage(myIdentityKey *ecdsa.PrivateKey, publicKey *ecdsa.PublicKey) (*ProtocolMessageSpec, error) { return p.BuildDHMessage(myIdentityKey, publicKey, nil) } func getProtocolVersion(bundles []*Bundle, installationID string) uint32 { if installationID == "" { return defaultMinVersion } for _, bundle := range bundles { if bundle != nil { signedPreKeys := bundle.GetSignedPreKeys() if signedPreKeys == nil { continue } signedPreKey := signedPreKeys[installationID] if signedPreKey == nil { return defaultMinVersion } return signedPreKey.GetProtocolVersion() } } return defaultMinVersion } func (p *Protocol) EncryptWithHashRatchet(groupID []byte, payload []byte) ([]byte, *HashRatchetKeyCompatibility, uint32, error) { ratchet, err := p.encryptor.persistence.GetCurrentKeyForGroup(groupID) if err != nil { return nil, nil, 0, err } encryptedPayload, newSeqNo, err := p.encryptor.EncryptWithHR(ratchet, payload) if err != nil { return nil, nil, 0, err } return encryptedPayload, ratchet, newSeqNo, nil } func (p *Protocol) DecryptWithHashRatchet(keyID []byte, seqNo uint32, payload []byte) ([]byte, error) { ratchet, err := p.encryptor.persistence.GetHashRatchetKeyByID(keyID) if err != nil { return nil, err } if ratchet == nil { return nil, ErrNoRatchetKey } return p.encryptor.DecryptWithHR(ratchet, seqNo, payload) }