package crypto import ( "bytes" "crypto/aes" "crypto/cipher" "crypto/hmac" "crypto/sha256" "fmt" "io" "github.com/ethereum/go-ethereum/crypto/ecies" "github.com/ethereum/go-ethereum/crypto" dr "github.com/status-im/doubleratchet" "golang.org/x/crypto/hkdf" ) // EthereumCrypto is an implementation of Crypto with cryptographic primitives recommended // by the Double Ratchet Algorithm specification. However, some details are different, // see function comments for details. type EthereumCrypto struct{} // See the Crypto interface. func (c EthereumCrypto) GenerateDH() (dr.DHPair, error) { keys, err := crypto.GenerateKey() if err != nil { return nil, err } var publicKey [32]byte copy(publicKey[:], crypto.CompressPubkey(&keys.PublicKey)[:32]) var privateKey [32]byte copy(privateKey[:], crypto.FromECDSA(keys)) return DHPair{ PrvKey: privateKey, PubKey: publicKey, }, nil } // See the Crypto interface. func (c EthereumCrypto) DH(dhPair dr.DHPair, dhPub dr.Key) dr.Key { tmpKey := dhPair.PrivateKey() privateKey, err := crypto.ToECDSA(tmpKey[:]) eciesPrivate := ecies.ImportECDSA(privateKey) var a [32]byte if err != nil { return a } publicKey, err := crypto.DecompressPubkey(dhPub[:]) if err != nil { return a } eciesPublic := ecies.ImportECDSAPublic(publicKey) key, err := eciesPrivate.GenerateShared( eciesPublic, 16, 16, ) if err != nil { return a } copy(a[:], key) return a } // See the Crypto interface. func (c EthereumCrypto) KdfRK(rk, dhOut dr.Key) (rootKey, chainKey, headerKey dr.Key) { var ( // We can use a non-secret constant as the last argument r = hkdf.New(sha256.New, dhOut[:], rk[:], []byte("rsZUpEuXUqqwXBvSy3EcievAh4cMj6QL")) buf = make([]byte, 96) ) // The only error here is an entropy limit which won't be reached for such a short buffer. _, _ = io.ReadFull(r, buf) copy(rootKey[:], buf[:32]) copy(chainKey[:], buf[32:64]) copy(headerKey[:], buf[64:96]) return } // See the Crypto interface. func (c EthereumCrypto) KdfCK(ck dr.Key) (chainKey dr.Key, msgKey dr.Key) { const ( ckInput = 15 mkInput = 16 ) h := hmac.New(sha256.New, ck[:]) _, _ = h.Write([]byte{ckInput}) copy(chainKey[:], h.Sum(nil)) h.Reset() _, _ = h.Write([]byte{mkInput}) copy(msgKey[:], h.Sum(nil)) return chainKey, msgKey } // Encrypt uses a slightly different approach than in the algorithm specification: // it uses AES-256-CTR instead of AES-256-CBC for security, ciphertext length and implementation // complexity considerations. func (c EthereumCrypto) Encrypt(mk dr.Key, plaintext, ad []byte) []byte { encKey, authKey, iv := c.deriveEncKeys(mk) ciphertext := make([]byte, aes.BlockSize+len(plaintext)) copy(ciphertext, iv[:]) var ( block, _ = aes.NewCipher(encKey[:]) // No error will occur here as encKey is guaranteed to be 32 bytes. stream = cipher.NewCTR(block, iv[:]) ) stream.XORKeyStream(ciphertext[aes.BlockSize:], plaintext) return append(ciphertext, c.computeSignature(authKey[:], ciphertext, ad)...) } // See the Crypto interface. func (c EthereumCrypto) Decrypt(mk dr.Key, authCiphertext, ad []byte) ([]byte, error) { var ( l = len(authCiphertext) ciphertext = authCiphertext[:l-sha256.Size] signature = authCiphertext[l-sha256.Size:] ) // Check the signature. encKey, authKey, _ := c.deriveEncKeys(mk) if s := c.computeSignature(authKey[:], ciphertext, ad); !bytes.Equal(s, signature) { return nil, fmt.Errorf("invalid signature") } // Decrypt. var ( block, _ = aes.NewCipher(encKey[:]) // No error will occur here as encKey is guaranteed to be 32 bytes. stream = cipher.NewCTR(block, ciphertext[:aes.BlockSize]) plaintext = make([]byte, len(ciphertext[aes.BlockSize:])) ) stream.XORKeyStream(plaintext, ciphertext[aes.BlockSize:]) return plaintext, nil } // deriveEncKeys derive keys for message encryption and decryption. Returns (encKey, authKey, iv, err). func (c EthereumCrypto) deriveEncKeys(mk dr.Key) (encKey dr.Key, authKey dr.Key, iv [16]byte) { // First, derive encryption and authentication key out of mk. salt := make([]byte, 32) var ( r = hkdf.New(sha256.New, mk[:], salt, []byte("pcwSByyx2CRdryCffXJwy7xgVZWtW5Sh")) buf = make([]byte, 80) ) // The only error here is an entropy limit which won't be reached for such a short buffer. _, _ = io.ReadFull(r, buf) copy(encKey[:], buf[0:32]) copy(authKey[:], buf[32:64]) copy(iv[:], buf[64:80]) return } func (c EthereumCrypto) computeSignature(authKey, ciphertext, associatedData []byte) []byte { h := hmac.New(sha256.New, authKey) _, _ = h.Write(associatedData) _, _ = h.Write(ciphertext) return h.Sum(nil) } type DHPair struct { PrvKey dr.Key PubKey dr.Key } func (p DHPair) PrivateKey() dr.Key { return p.PrvKey } func (p DHPair) PublicKey() dr.Key { return p.PubKey }