Initial commit

.travis.yml

@@ -0,0 +1,22 @@
+sudo: false
+language: c
+os:
+  - linux
+  - osx
+dist: trusty
+before_script:
+  - git clone https://github.com/nim-lang/Nim.git
+  - cd Nim
+  - git clone --depth 1 https://github.com/nim-lang/csources
+  - cd csources && sh build.sh
+  - cd ..
+  - bin/nim c koch
+  - ./koch boot -d:release
+  - ./koch nimble
+  - export PATH=$(pwd)/bin:$PATH
+  - cd ..
+  - nimble install https://github.com/status-im/nim-rlp
+  - nimble install https://github.com/cheatfate/nimcrypto >= 0.1.0
+  - nimble install https://github.com/status-im/nim-secp256k1
+script:
+  - nimble tests

ethp2p.nim

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+#
+#                 Ethereum P2P
+#              (c) Copyright 2018
+#       Status Research & Development GmbH
+#
+#    See the file "LICENSE", included in this
+#    distribution, for details about the copyright.
+#
+
+import ethp2p/ecc, ethp2p/ecies, ethp2p/auth, ethp2p/hexdump
+export ecc, ecies, auth, hexdump

ethp2p.nimble

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+mode = ScriptMode.Verbose
+
+packageName   = "ethp2p"
+version       = "1.0.0"
+author        = "Status Research & Development GmbH"
+description   = "Ethereum P2P library"
+license       = "MIT"
+skipDirs      = @["tests", "Nim"]
+
+requires "nim > 0.18.0", "https://github.com/status-im/nim-rlp >= 1.0.1", "https://github.com/cheatfate/nimcrypto >= 0.1.0", "https://github.com/status-im/nim-secp256k1 >= 0.1.0"
+
+task tests, "Runs the test suite":
+  exec "nim c -r tests/testecc"
+  exec "nim c -r tests/testecies"
+  exec "nim c -r tests/testauth"

ethp2p/auth.nim

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+#
+#                 Ethereum P2P
+#              (c) Copyright 2018
+#       Status Research & Development GmbH
+#
+#    See the file "LICENSE", included in this
+#    distribution, for details about the copyright.
+#
+
+## This module implements Ethereum authentication
+
+import endians
+import ecc, ecies, rlp
+import nimcrypto/sysrand, nimcrypto/hash, nimcrypto/utils, nimcrypto/hmac
+import nimcrypto/rijndael, nimcrypto/keccak, nimcrypto/sha2
+import hexdump
+
+const
+  SupportedRlpxVersion* = 4
+  PlainAuthMessageLength* = 194
+  PlainAuthAckMessageLength* = 97
+  AuthMessageLength* = 307
+  AuthAckMessageLength* = 210
+
+type
+  HandshakeFlag* = enum
+    Initiator,      ## `Handshake` owner is connection initiator
+    Responder,      ## `Handshake` owner is connection responder
+    Eip8            ## Flag indicates that EIP-8 handshake is used
+
+  AuthStatus* = enum
+    Success,        ## Operation was successful
+    RandomError,    ## Could not obtain random data
+    EcdhError,      ## ECDH shared secret could not be calculated
+    SignatureError, ## Signature could not be obtained
+    EciesError,     ## ECIES encryption/decryption error
+    InvalidPubKey,  ## Invalid public key
+    InvalidAuth,    ## Invalid Authentication message
+    InvalidAck,     ## Invalid Authentication ACK message
+    RlpError,       ## Error while decoding RLP stream
+    IncompleteError ## Data incomplete error
+
+  Handshake* = object
+    version: uint8
+    flags: set[HandshakeFlag]
+    host*: KeyPair
+    ephemeral*: KeyPair
+    remoteHPubkey*: PublicKey
+    remoteEPubkey*: PublicKey
+    initiatorNonce*: Nonce
+    responderNonce*: Nonce
+
+  ConnectionSecret* = object
+    aesKey*: array[aes256.sizeKey, byte]
+    macKey*: array[KeyLength, byte]
+    egressMac*: array[keccak256.sizeDigest, byte]
+    ingressMac*: array[keccak256.sizeDigest, byte]
+
+  PlainAuthMessage* = array[PlainAuthMessageLength, byte]
+  PlainAuthAckMessage* = array[PlainAuthAckMessageLength, byte]
+  AuthMessage* = array[AuthMessageLength, byte]
+  AuthAckMessage* = array[AuthAckMessageLength, byte]
+
+  AuthException* = object of Exception
+
+proc sxor[T](a: var openarray[T], b: openarray[T]) =
+  assert(len(a) == len(b))
+  for i in 0..(len(a) - 1):
+    a[i] = a[i] xor b[i]
+
+proc empty[T](v: openarray[T]): bool =
+  var r: T
+  for item in v:
+    r = r + item
+  result = (r == T(0))
+
+proc move[T](dst: var openarray[T], src: openarray[T],
+             dstx: int = 0, dsty: int = -1, srcx: int = 0, srcy: int = -1) =
+  let sx = if srcx < 0: (len(src) + srcx) else: srcx
+  let sy = if srcy < 0: (len(src) + srcy) else: srcy
+  let dx = if dstx < 0: (len(dst) + dstx) else: dstx
+  let dy = if dsty < 0: (len(dst) + dsty) else: dsty
+  assert(sy - sx == dy - dx)
+  moveMem(addr dst[dstx], unsafeAddr src[srcx], (dy - dx + 1) * sizeof(T))
+
+proc newHandshake*(flags: set[HandshakeFlag] = {Initiator}): Handshake =
+  var p: ptr byte
+  result.flags = flags
+  result.ephemeral = newKeyPair()
+
+  if Initiator in flags:
+    p = addr result.initiatorNonce[0]
+  else:
+    p = addr result.responderNonce[0]
+
+  if randomBytes(p, KeyLength) != KeyLength:
+    raise newException(AuthException, "Could not obtain random data!")
+
+proc authMessage*(h: var Handshake,
+                  pubkey: PublicKey,
+                  output: var PlainAuthMessage): AuthStatus =
+  ## Create plain preEIP8 authentication message.
+  var secret: SharedSecret
+  var signature: Signature
+  var flag = byte(0x00)
+
+  if ecdhAgree(h.host.seckey, pubkey, secret) != EccStatus.Success:
+    return(EcdhError)
+
+  if h.initiatorNonce.empty():
+    if randomBytes(addr h.initiatorNonce[0], KeyLength) != KeyLength:
+      return(RandomError)
+
+  var xornonce = h.initiatorNonce
+  xornonce.sxor(secret)
+
+  if signMessage(h.ephemeral.seckey, xornonce, signature) != EccStatus.Success:
+    return(SignatureError)
+
+  copyMem(addr h.remoteHPubkey, unsafeAddr pubkey, sizeof(PublicKey))
+
+  move(output, signature.getRaw().data, 0, 64)
+  move(output, keccak256.digest(h.ephemeral.pubkey.getRaw().data).data, 65, 96)
+  move(output, h.host.pubkey.getRaw().data, 97, 160)
+  move(output, h.initiatorNonce, 161, 192)
+  output[193] = flag
+
+proc authAckMessage*(h: var Handshake,
+                     output: var PlainAuthAckMessage): AuthStatus =
+  if EIP8 in h.flags:
+    discard
+  else:
+    move(output, h.ephemeral.pubkey.getRaw().data, 0, 63)
+    move(output, h.responderNonce, 64, 95)
+    output[96] = byte(0x00)
+
+proc encryptAuthMessage*(input: ptr byte, inputlen: int,
+                         output: ptr byte, outputlen: int,
+                         pubkey: PublicKey, shmac: ptr byte = nil,
+                         shlen: int = 0): AuthStatus =
+  result = Success
+  if eciesEncrypt(input, output, inputlen, outputlen,
+                  pubkey, shmac, shlen) != EciesStatus.Success:
+    result = EciesError
+
+proc encryptAuthMessage*(input: PlainAuthMessage,
+                         output: var AuthMessage,
+                         pubkey: PublicKey): AuthStatus =
+  result = Success
+  result = encryptAuthMessage(unsafeAddr input[0], PlainAuthMessageLength,
+                              addr output[0], AuthMessageLength, pubkey)
+
+proc decryptAuthMessage*(input: ptr byte, inputlen: int,
+                         output: ptr byte, outputlen: int,
+                         seckey: PrivateKey, shmac: ptr byte = nil,
+                         shlen: int = 0): AuthStatus =
+  result = Success
+  if eciesDecrypt(input, output, inputlen, outputlen,
+                  seckey, shmac, shlen) != EciesStatus.Success:
+    result = EciesError
+
+proc decryptAuthMessage*(input: AuthMessage, output: var PlainAuthMessage,
+                         seckey: PrivateKey): AuthStatus =
+  result = decryptAuthMessage(unsafeAddr input[0], AuthMessageLength,
+                              addr output[0], PlainAuthMessageLength,
+                              seckey)
+
+proc encryptAuthAckMessage*(input: ptr byte, inputlen: int,
+                            output: ptr byte, outputlen: int,
+                            pubkey: PublicKey, shmac: ptr byte = nil,
+                            shlen: int = 0): AuthStatus =
+  result = Success
+  if eciesEncrypt(input, output, inputlen, outputlen,
+                  pubkey, shmac, shlen) != EciesStatus.Success:
+    result = EciesError
+
+proc encryptAuthAckMessage*(input: PlainAuthAckMessage,
+                            output: var AuthAckMessage,
+                            pubkey: PublicKey): AuthStatus =
+  result = encryptAuthAckMessage(unsafeAddr input[0], PlainAuthAckMessageLength,
+                                 addr output[0], AuthAckMessageLength,
+                                 pubkey)
+
+proc decryptAuthAckMessage*(input: ptr byte, inputlen: int,
+                            output: ptr byte, outputlen: int,
+                            seckey: PrivateKey, shmac: ptr byte = nil,
+                            shlen: int = 0): AuthStatus =
+  result = Success
+  if eciesDecrypt(input, output, inputlen, outputlen,
+                  seckey, shmac, shlen) != EciesStatus.Success:
+    result = EciesError
+
+proc decryptAuthAckMessage*(input: AuthAckMessage,
+                            output: var PlainAuthAckMessage,
+                            seckey: PrivateKey): AuthStatus =
+  result = decryptAuthAckMessage(unsafeAddr input[0], AuthAckMessageLength,
+                                 addr output[0], PlainAuthAckMessageLength,
+                                 seckey)
+
+proc decodePlainAuthMessage(h: var Handshake, m: PlainAuthMessage): AuthStatus =
+  var secret: SharedSecret
+  var nonce: array[32, byte]
+  var pubkey: PublicKey
+
+  copyMem(addr nonce[0], unsafeAddr m[161], KeyLength)
+  if recoverPublicKey(unsafeAddr m[97], sizeof(PublicKey),
+                      pubkey) != EccStatus.Success:
+    return(InvalidPubKey)
+
+  if ecdhAgree(h.host.seckey, pubkey, secret) != EccStatus.Success:
+    return(EcdhError)
+
+  var xornonce = nonce
+  xornonce.sxor(secret)
+
+  if recoverSignatureKey(unsafeAddr m[0], SignatureLength, addr xornonce[0],
+                         h.remoteEPubkey) != EccStatus.Success:
+    return(SignatureError)
+
+  h.initiatorNonce = nonce
+  h.remoteHPubkey = pubkey
+  result = Success
+
+proc decodePlainAuthAckMessage*(h: var Handshake,
+                                m: PlainAuthAckMessage): AuthStatus =
+  if recoverPublicKey(m, h.remoteEPubkey, 0, 63) != EccStatus.Success:
+    return(InvalidPubKey)
+
+  h.responderNonce[0..31] = m[64..95]
+  result = Success
+
+proc getSecrets*(h: var Handshake,
+                 msg: ptr byte, msglen: int,
+                 ack: ptr byte, acklen: int,
+                 secret: var ConnectionSecret): AuthStatus =
+
+  var
+    shsec: SharedSecret
+    ctx0: keccak256
+    ctx1: keccak256
+    digest: array[keccak256.sizeDigest, byte]
+    mac1: array[keccak256.sizeDigest, byte]
+    mac2: array[keccak256.sizeDigest, byte]
+    xornonce: Nonce
+
+  # ecdhe-secret = ecdh.agree(ephemeral-privkey, remote-ephemeral-pubk)
+  if ecdhAgree(h.ephemeral.seckey, h.remoteEPubkey, shsec) != EccStatus.Success:
+    return(EcdhError)
+
+  # shared-secret = keccak(ecdhe-secret || keccak(nonce || initiator-nonce))
+  ctx0.init()
+  ctx1.init()
+  ctx1.update(addr h.responderNonce[0], uint(len(h.responderNonce)))
+  ctx1.update(addr h.initiatorNonce[0], uint(len(h.initiatorNonce)))
+  digest = ctx1.finish().data
+
+  ctx1.init() # clean keccak256 context
+  ctx0.update(addr shsec[0], uint(sizeof(SharedSecret)))
+  ctx0.update(addr digest[0], uint(keccak256.sizeDigest))
+  digest = ctx0.finish().data
+
+  # aes-secret = keccak(ecdhe-secret || shared-secret)
+  ctx0.init()
+  ctx0.update(addr shsec[0], uint(sizeof(SharedSecret)))
+  ctx0.update(addr digest[0], uint(keccak256.sizeDigest))
+  secret.aesKey = ctx0.finish().data
+
+  # mac-secret = keccak(ecdhe-secret || aes-secret)
+  ctx0.init()
+  ctx0.update(addr shsec[0], uint(sizeof(SharedSecret)))
+  ctx0.update(addr secret.aesKey[0], uint(keccak256.sizeDigest))
+  secret.macKey = ctx0.finish().data
+
+  zeroMem(addr shsec[0], sizeof(SharedSecret)) # clean ecdhe-secret
+
+  # egress-mac = keccak256(mac-secret ^ recipient-nonce || auth-sent-init)
+  xornonce = secret.macKey
+  xornonce.sxor(h.responderNonce)
+  ctx0.init()
+  ctx0.update(addr xornonce[0], uint(sizeof(Nonce)))
+  ctx0.update(msg, uint(msglen))
+  mac1 = ctx0.finish().data
+
+  # ingress-mac = keccak256(mac-secret ^ initiator-nonce || auth-recvd-ack)
+  xornonce = secret.macKey
+  xornonce.sxor(h.initiatorNonce)
+  ctx0.init()
+  ctx0.update(addr xornonce[0], uint(sizeof(Nonce)))
+  ctx0.update(ack, uint(acklen))
+  mac2 = ctx0.finish().data
+
+  ctx0.init() # clean keccak256 context
+  zeroMem(addr xornonce[0], sizeof(Nonce)) # clean xornonce
+
+  if Initiator in h.flags:
+    secret.egressMac = mac1
+    secret.ingressMac = mac2
+  else:
+    secret.ingressMac = mac1
+    secret.egressMac = mac2
+
+  zeroMem(addr mac1[0], keccak256.sizeDigest) # clean temporary mac1
+  zeroMem(addr mac2[0], keccak256.sizeDigest) # clean temporary mac2
+
+  result = Success
+
+proc getSecrets*(h: var Handshake, msg: AuthMessage, ack: AuthAckMessage,
+                 secret: var ConnectionSecret): AuthStatus =
+  result = getSecrets(h, unsafeAddr msg[0], AuthMessageLength,
+                      unsafeAddr ack[0], AuthAckMessageLength,
+                      secret)
+
+proc decodeAuthEip8Message*(h: var Handshake, msg: ptr byte,
+                            msglen: int): AuthStatus =
+  var
+    pubkey: PublicKey
+    nonce: Nonce
+    size: uint16
+    secret: SharedSecret
+  if msglen < 2:
+    return(InvalidAuth)
+  bigEndian16(addr size, msg)
+
+  if (2 + int(size)) > msglen:
+    return(InvalidAuth)
+
+  # Maximum `size` value is 65535 bytes
+  var outlen = eciesDecryptedLength(int(size))
+  var output = newSeq[byte](outlen)
+  var input = cast[ptr UncheckedArray[byte]](msg)
+  if decryptAuthMessage(addr input[2], int(size), addr output[0],
+                        outlen, h.host.seckey,
+                        addr input[0], 2) != Success:
+    return(EciesError)
+
+  try:
+    var reader = rlpFromBytes(initBytesRange(output))
+    if not reader.isList() or reader.listLen() < 4:
+      return(InvalidAuth)
+    if reader.listElem(0).blobLen != SignatureLength:
+      return(InvalidAuth)
+    if reader.listElem(1).blobLen != PublicKeyLength:
+      return(InvalidAuth)
+    if reader.listElem(2).blobLen != KeyLength:
+      return(InvalidAuth)
+    if reader.listElem(3).blobLen != 1:
+      return(InvalidAuth)
+
+    var signatureBr = reader.listElem(0).toBytes()
+    var pubkeyBr = reader.listElem(1).toBytes()
+    var nonceBr = reader.listElem(2).toBytes()
+    var versionBr = reader.listElem(3).toBytes()
+
+    if recoverPublicKey(addr output[pubkeyBr.ibegin], PublicKeyLength,
+                        pubkey) != EccStatus.Success:
+      return(InvalidPubKey)
+    copyMem(addr nonce[0], addr output[nonceBr.ibegin], KeyLength)
+
+    if ecdhAgree(h.host.seckey, pubkey, secret) != EccStatus.Success:
+      return(EcdhError)
+
+    var xornonce = nonce
+    xornonce.sxor(secret)
+
+    if recoverSignatureKey(addr output[signatureBr.ibegin], SignatureLength,
+                           addr xornonce[0],
+                           h.remoteEPubkey) != EccStatus.Success:
+      return(SignatureError)
+
+    h.initiatorNonce = nonce
+    h.remoteHPubkey = pubkey
+    h.version = output[versionBr.ibegin]
+    result = Success
+  except:
+    return(RlpError)
+
+proc decodeAuthAckEip8Message(h: var Handshake, msg: ptr byte,
+                              msglen: int): AuthStatus =
+  var size: uint16
+  if msglen < 2:
+    return(IncompleteError)
+  bigEndian16(addr size, msg)
+
+  if (2 + int(size)) > msglen:
+    return(IncompleteError)
+
+  # Maximum `size` value is 65535 bytes
+  var outlen = eciesDecryptedLength(int(size))
+  var output = newSeq[byte](outlen)
+  var input = cast[ptr UncheckedArray[byte]](msg)
+  if decryptAuthMessage(addr input[2], int(size), addr output[0],
+                        outlen, h.host.seckey,
+                        addr input[0], 2) != Success:
+    return(EciesError)
+
+  try:
+    var reader = rlpFromBytes(initBytesRange(output))
+    if not reader.isList() or reader.listLen() < 3:
+      return(InvalidAck)
+    if reader.listElem(0).blobLen != PublicKeyLength:
+      return(InvalidAck)
+    if reader.listElem(1).blobLen != KeyLength:
+      return(InvalidAck)
+    if reader.listElem(2).blobLen != 1:
+      return(InvalidAck)
+    var pubkeyBr = reader.listElem(0).toBytes()
+    var nonceBr = reader.listElem(1).toBytes()
+    var versionBr = reader.listElem(2).toBytes()
+
+    if recoverPublicKey(addr output[pubkeyBr.ibegin], PublicKeyLength,
+                        h.remoteEPubkey) != EccStatus.Success:
+      return(InvalidPubKey)
+    copyMem(addr h.responderNonce[0], addr output[nonceBr.ibegin], KeyLength)
+    h.version = output[versionBr.ibegin]
+    result = Success
+  except:
+    return(RlpError)
+
+proc decodeAuthMessage*(h: var Handshake, msg: ptr byte,
+                        msglen: int): AuthStatus =
+  if msglen < AuthMessageLength:
+    return(IncompleteError)
+  elif msglen == AuthMessageLength:
+    # Decoding plain authentication message
+    var plain: PlainAuthMessage
+    result = decryptAuthMessage(msg, msglen, addr plain[0],
+                                sizeof(PlainAuthMessage), h.host.seckey)
+    if result == Success:
+      result = decodePlainAuthMessage(h, plain)
+  else:
+    # Decoding EIP-8 authentication message
+    result = decodeAuthEip8Message(h, msg, msglen)
+    if result == Success:
+      h.flags.incl(EIP8)
+
+proc decodeAckMessage*(h: var Handshake, msg: ptr byte,
+                       msglen: int): AuthStatus =
+  if msglen < AuthAckMessageLength:
+    return(IncompleteError)
+  elif msglen == AuthAckMessageLength:
+    # Decoding plain authentication ACK message
+    var plain: PlainAuthAckMessage
+    result = decryptAuthAckMessage(msg, msglen, addr plain[0],
+                                   PlainAuthAckMessageLength,
+                                   h.host.seckey)
+    if result == Success:
+      result = decodePlainAuthAckMessage(h, plain)
+  else:
+    # Decoding EIP-8 ACK authentication message
+    result = decodeAuthAckEip8Message(h, msg, msglen)
+
+proc decodeAuthMessage*(h: var Handshake, msg: openarray[byte]): AuthStatus =
+  result = decodeAuthMessage(h, unsafeAddr msg[0], len(msg))
+
+proc decodeAckMessage*(h: var Handshake, msg: openarray[byte]): AuthStatus =
+  result = decodeAckMessage(h, unsafeAddr msg[0], len(msg))
+
+when isMainModule:
+  # This was generated by `print` actual auth message generated by
+  # https://github.com/ethereum/py-evm/blob/master/tests/p2p/test_auth.py
+  const pyevmAuth = """
+    22034ad2e7545e2b0bf02ecb1e40db478dfbbf7aeecc834aec2523eb2b7e74ee
+    77ba40c70a83bfe9f2ab91f0131546dcf92c3ee8282d9907fee093017fd0302d
+    0034fdb5419558137e0d44cd13d319afe5629eeccb47fd9dfe55cc6089426e46
+    cc762dd8a0636e07a54b31169eba0c7a20a1ac1ef68596f1f283b5c676bae406
+    4abfcce24799d09f67e392632d3ffdc12e3d6430dcb0ea19c318343ffa7aae74
+    d4cd26fecb93657d1cd9e9eaf4f8be720b56dd1d39f190c4e1c6b7ec66f077bb
+    1100"""
+
+  # This data comes from https://gist.github.com/fjl/3a78780d17c755d22df2
+  const data = [
+    ("initiator_private_key",
+     "5e173f6ac3c669587538e7727cf19b782a4f2fda07c1eaa662c593e5e85e3051"),
+    ("receiver_private_key",
+     "c45f950382d542169ea207959ee0220ec1491755abe405cd7498d6b16adb6df8"),
+    ("initiator_ephemeral_private_key",
+     "19c2185f4f40634926ebed3af09070ca9e029f2edd5fae6253074896205f5f6c"),
+    ("receiver_ephemeral_private_key",
+     "d25688cf0ab10afa1a0e2dba7853ed5f1e5bf1c631757ed4e103b593ff3f5620"),
+    ("auth_plaintext",
+     """884c36f7ae6b406637c1f61b2f57e1d2cab813d24c6559aaf843c3f48962f32f
+        46662c066d39669b7b2e3ba14781477417600e7728399278b1b5d801a519aa57
+        0034fdb5419558137e0d44cd13d319afe5629eeccb47fd9dfe55cc6089426e46
+        cc762dd8a0636e07a54b31169eba0c7a20a1ac1ef68596f1f283b5c676bae406
+        4abfcce24799d09f67e392632d3ffdc12e3d6430dcb0ea19c318343ffa7aae74
+        d4cd26fecb93657d1cd9e9eaf4f8be720b56dd1d39f190c4e1c6b7ec66f077bb
+        1100"""),
+    ("authresp_plaintext",
+     """802b052f8b066640bba94a4fc39d63815c377fced6fcb84d27f791c9921ddf3e
+        9bf0108e298f490812847109cbd778fae393e80323fd643209841a3b7f110397
+        f37ec61d84cea03dcc5e8385db93248584e8af4b4d1c832d8c7453c0089687a7
+        00"""),
+    ("auth_ciphertext",
+     """04a0274c5951e32132e7f088c9bdfdc76c9d91f0dc6078e848f8e3361193dbdc
+        43b94351ea3d89e4ff33ddcefbc80070498824857f499656c4f79bbd97b6c51a
+        514251d69fd1785ef8764bd1d262a883f780964cce6a14ff206daf1206aa073a
+        2d35ce2697ebf3514225bef186631b2fd2316a4b7bcdefec8d75a1025ba2c540
+        4a34e7795e1dd4bc01c6113ece07b0df13b69d3ba654a36e35e69ff9d482d88d
+        2f0228e7d96fe11dccbb465a1831c7d4ad3a026924b182fc2bdfe016a6944312
+        021da5cc459713b13b86a686cf34d6fe6615020e4acf26bf0d5b7579ba813e77
+        23eb95b3cef9942f01a58bd61baee7c9bdd438956b426a4ffe238e61746a8c93
+        d5e10680617c82e48d706ac4953f5e1c4c4f7d013c87d34a06626f498f34576d
+        c017fdd3d581e83cfd26cf125b6d2bda1f1d56"""),
+    ("authresp_ciphertext",
+     """049934a7b2d7f9af8fd9db941d9da281ac9381b5740e1f64f7092f3588d4f87f
+        5ce55191a6653e5e80c1c5dd538169aa123e70dc6ffc5af1827e546c0e958e42
+        dad355bcc1fcb9cdf2cf47ff524d2ad98cbf275e661bf4cf00960e74b5956b79
+        9771334f426df007350b46049adb21a6e78ab1408d5e6ccde6fb5e69f0f4c92b
+        b9c725c02f99fa72b9cdc8dd53cff089e0e73317f61cc5abf6152513cb7d833f
+        09d2851603919bf0fbe44d79a09245c6e8338eb502083dc84b846f2fee1cc310
+        d2cc8b1b9334728f97220bb799376233e113"""),
+    ("ecdhe_shared_secret",
+     "e3f407f83fc012470c26a93fdff534100f2c6f736439ce0ca90e9914f7d1c381"),
+    ("initiator_nonce",
+     "cd26fecb93657d1cd9e9eaf4f8be720b56dd1d39f190c4e1c6b7ec66f077bb11"),
+    ("receiver_nonce",
+     "f37ec61d84cea03dcc5e8385db93248584e8af4b4d1c832d8c7453c0089687a7"),
+    ("aes_secret",
+     "c0458fa97a5230830e05f4f20b7c755c1d4e54b1ce5cf43260bb191eef4e418d"),
+    ("mac_secret",
+     "48c938884d5067a1598272fcddaa4b833cd5e7d92e8228c0ecdfabbe68aef7f1"),
+    ("token",
+     "3f9ec2592d1554852b1f54d228f042ed0a9310ea86d038dc2b401ba8cd7fdac4"),
+    ("initial_egress_MAC",
+     "09771e93b1a6109e97074cbe2d2b0cf3d3878efafe68f53c41bb60c0ec49097e"),
+    ("initial_ingress_MAC",
+     "75823d96e23136c89666ee025fb21a432be906512b3dd4a3049e898adb433847"),
+    ("initiator_hello_packet",
+     """6ef23fcf1cec7312df623f9ae701e63b550cdb8517fefd8dd398fc2acd1d935e
+        6e0434a2b96769078477637347b7b01924fff9ff1c06df2f804df3b0402bbb9f
+        87365b3c6856b45e1e2b6470986813c3816a71bff9d69dd297a5dbd935ab578f
+        6e5d7e93e4506a44f307c332d95e8a4b102585fd8ef9fc9e3e055537a5cec2e9"""),
+    ("receiver_hello_packet",
+     """6ef23fcf1cec7312df623f9ae701e63be36a1cdd1b19179146019984f3625d4a
+        6e0434a2b96769050577657247b7b02bc6c314470eca7e3ef650b98c83e9d7dd
+        4830b3f718ff562349aead2530a8d28a8484604f92e5fced2c6183f304344ab0
+        e7c301a0c05559f4c25db65e36820b4b909a226171a60ac6cb7beea09376d6d8""")
+  ]
+
+  # Thies test vectors was copied from EIP8 specfication
+  # https://github.com/ethereum/EIPs/blob/master/EIPS/eip-8.md
+  const eip8data = [
+    ("initiator_private_key",
+     "49a7b37aa6f6645917e7b807e9d1c00d4fa71f18343b0d4122a4d2df64dd6fee"),
+    ("receiver_private_key",
+     "b71c71a67e1177ad4e901695e1b4b9ee17ae16c6668d313eac2f96dbcda3f291"),
+    ("initiator_ephemeral_private_key",
+     "869d6ecf5211f1cc60418a13b9d870b22959d0c16f02bec714c960dd2298a32d"),
+    ("receiver_ephemeral_private_key",
+     "e238eb8e04fee6511ab04c6dd3c89ce097b11f25d584863ac2b6d5b35b1847e4"),
+    ("initiator_nonce",
+     "7e968bba13b6c50e2c4cd7f241cc0d64d1ac25c7f5952df231ac6a2bda8ee5d6"),
+    ("receiver_nonce",
+     "559aead08264d5795d3909718cdd05abd49572e84fe55590eef31a88a08fdffd"),
+    ("auth_ciphertext_v4",
+     """048ca79ad18e4b0659fab4853fe5bc58eb83992980f4c9cc147d2aa31532efd29
+        a3d3dc6a3d89eaf913150cfc777ce0ce4af2758bf4810235f6e6ceccfee1acc6b
+        22c005e9e3a49d6448610a58e98744ba3ac0399e82692d67c1f58849050b3024e
+        21a52c9d3b01d871ff5f210817912773e610443a9ef142e91cdba0bd77b5fdf07
+        69b05671fc35f83d83e4d3b0b000c6b2a1b1bba89e0fc51bf4e460df3105c444f
+        14be226458940d6061c296350937ffd5e3acaceeaaefd3c6f74be8e23e0f45163
+        cc7ebd76220f0128410fd05250273156d548a414444ae2f7dea4dfca2d43c057a
+        db701a715bf59f6fb66b2d1d20f2c703f851cbf5ac47396d9ca65b6260bd141ac
+        4d53e2de585a73d1750780db4c9ee4cd4d225173a4592ee77e2bd94d0be3691f3
+        b406f9bba9b591fc63facc016bfa8"""),
+    ("auth_ciphertext_eip8",
+     """01b304ab7578555167be8154d5cc456f567d5ba302662433674222360f08d5f15
+        34499d3678b513b0fca474f3a514b18e75683032eb63fccb16c156dc6eb2c0b15
+        93f0d84ac74f6e475f1b8d56116b849634a8c458705bf83a626ea0384d4d7341a
+        ae591fae42ce6bd5c850bfe0b999a694a49bbbaf3ef6cda61110601d3b4c02ab6
+        c30437257a6e0117792631a4b47c1d52fc0f8f89caadeb7d02770bf999cc147d2
+        df3b62e1ffb2c9d8c125a3984865356266bca11ce7d3a688663a51d82defaa8aa
+        d69da39ab6d5470e81ec5f2a7a47fb865ff7cca21516f9299a07b1bc63ba56c7a
+        1a892112841ca44b6e0034dee70c9adabc15d76a54f443593fafdc3b27af80597
+        03f88928e199cb122362a4b35f62386da7caad09c001edaeb5f8a06d2b26fb6cb
+        93c52a9fca51853b68193916982358fe1e5369e249875bb8d0d0ec36f917bc5e1
+        eafd5896d46bd61ff23f1a863a8a8dcd54c7b109b771c8e61ec9c8908c733c026
+        3440e2aa067241aaa433f0bb053c7b31a838504b148f570c0ad62837129e54767
+        8c5190341e4f1693956c3bf7678318e2d5b5340c9e488eefea198576344afbdf6
+        6db5f51204a6961a63ce072c8926c"""),
+    ("auth_ciphertext_eip8_3f",
+     """01b8044c6c312173685d1edd268aa95e1d495474c6959bcdd10067ba4c9013df9
+        e40ff45f5bfd6f72471f93a91b493f8e00abc4b80f682973de715d77ba3a005a2
+        42eb859f9a211d93a347fa64b597bf280a6b88e26299cf263b01b8dfdb7122784
+        64fd1c25840b995e84d367d743f66c0e54a586725b7bbf12acca27170ae3283c1
+        073adda4b6d79f27656993aefccf16e0d0409fe07db2dc398a1b7e8ee93bcd181
+        485fd332f381d6a050fba4c7641a5112ac1b0b61168d20f01b479e19adf7fdbfa
+        0905f63352bfc7e23cf3357657455119d879c78d3cf8c8c06375f3f7d4861aa02
+        a122467e069acaf513025ff196641f6d2810ce493f51bee9c966b15c504350535
+        0392b57645385a18c78f14669cc4d960446c17571b7c5d725021babbcd786957f
+        3d17089c084907bda22c2b2675b4378b114c601d858802a55345a15116bc61da4
+        193996187ed70d16730e9ae6b3bb8787ebcaea1871d850997ddc08b4f4ea668fb
+        f37407ac044b55be0908ecb94d4ed172ece66fd31bfdadf2b97a8bc690163ee11
+        f5b575a4b44e36e2bfb2f0fce91676fd64c7773bac6a003f481fddd0bae0a1f31
+        aa27504e2a533af4cef3b623f4791b2cca6d490"""),
+    ("authack_ciphertext_v4",
+     """049f8abcfa9c0dc65b982e98af921bc0ba6e4243169348a236abe9df5f93aa69d
+        99cadddaa387662b0ff2c08e9006d5a11a278b1b3331e5aaabf0a32f01281b6f4
+        ede0e09a2d5f585b26513cb794d9635a57563921c04a9090b4f14ee42be1a5461
+        049af4ea7a7f49bf4c97a352d39c8d02ee4acc416388c1c66cec761d2bc1c72da
+        6ba143477f049c9d2dde846c252c111b904f630ac98e51609b3b1f58168ddca65
+        05b7196532e5f85b259a20c45e1979491683fee108e9660edbf38f3add489ae73
+        e3dda2c71bd1497113d5c755e942d1"""),
+    ("authack_ciphertext_eip8",
+     """01ea0451958701280a56482929d3b0757da8f7fbe5286784beead59d95089c217
+        c9b917788989470b0e330cc6e4fb383c0340ed85fab836ec9fb8a49672712aeab
+        bdfd1e837c1ff4cace34311cd7f4de05d59279e3524ab26ef753a0095637ac88f
+        2b499b9914b5f64e143eae548a1066e14cd2f4bd7f814c4652f11b254f8a2d019
+        1e2f5546fae6055694aed14d906df79ad3b407d94692694e259191cde171ad542
+        fc588fa2b7333313d82a9f887332f1dfc36cea03f831cb9a23fea05b33deb999e
+        85489e645f6aab1872475d488d7bd6c7c120caf28dbfc5d6833888155ed69d34d
+        bdc39c1f299be1057810f34fbe754d021bfca14dc989753d61c413d261934e1a9
+        c67ee060a25eefb54e81a4d14baff922180c395d3f998d70f46f6b58306f96962
+        7ae364497e73fc27f6d17ae45a413d322cb8814276be6ddd13b885b201b943213
+        656cde498fa0e9ddc8e0b8f8a53824fbd82254f3e2c17e8eaea009c38b4aa0a3f
+        306e8797db43c25d68e86f262e564086f59a2fc60511c42abfb3057c247a8a8fe
+        4fb3ccbadde17514b7ac8000cdb6a912778426260c47f38919a91f25f4b5ffb45
+        5d6aaaf150f7e5529c100ce62d6d92826a71778d809bdf60232ae21ce8a437eca
+        8223f45ac37f6487452ce626f549b3b5fdee26afd2072e4bc75833c2464c80524
+        6155289f4"""),
+    ("authack_ciphertext_eip8_3f",
+     """01f004076e58aae772bb101ab1a8e64e01ee96e64857ce82b1113817c6cdd52c0
+        9d26f7b90981cd7ae835aeac72e1573b8a0225dd56d157a010846d888dac7464b
+        af53f2ad4e3d584531fa203658fab03a06c9fd5e35737e417bc28c1cbf5e5dfc6
+        66de7090f69c3b29754725f84f75382891c561040ea1ddc0d8f381ed1b9d0d4ad
+        2a0ec021421d847820d6fa0ba66eaf58175f1b235e851c7e2124069fbc202888d
+        db3ac4d56bcbd1b9b7eab59e78f2e2d400905050f4a92dec1c4bdf797b3fc9b2f
+        8e84a482f3d800386186712dae00d5c386ec9387a5e9c9a1aca5a573ca91082c7
+        d68421f388e79127a5177d4f8590237364fd348c9611fa39f78dcdceee3f390f0
+        7991b7b47e1daa3ebcb6ccc9607811cb17ce51f1c8c2c5098dbdd28fca547b3f5
+        8c01a424ac05f869f49c6a34672ea2cbbc558428aa1fe48bbfd61158b1b735a65
+        d99f21e70dbc020bfdface9f724a0d1fb5895db971cc81aa7608baa0920abb0a5
+        65c9c436e2fd13323428296c86385f2384e408a31e104670df0791d93e743a3a5
+        194ee6b076fb6323ca593011b7348c16cf58f66b9633906ba54a2ee803187344b
+        394f75dd2e663a57b956cb830dd7a908d4f39a2336a61ef9fda549180d4ccde21
+        514d117b6c6fd07a9102b5efe710a32af4eeacae2cb3b1dec035b9593b48b9d3c
+        a4c13d245d5f04169b0b1"""),
+    ("auth2ack2_aes_secret",
+     "80e8632c05fed6fc2a13b0f8d31a3cf645366239170ea067065aba8e28bac487"),
+    ("auth2ack2_mac_secret",
+     "2ea74ec5dae199227dff1af715362700e989d889d7a493cb0639691efb8e5f98"),
+    ("auth2ack2_ingress_message", "foo"),
+    ("auth2ack2_ingress_mac",
+     "0c7ec6340062cc46f5e9f1e3cf86f8c8c403c5a0964f5df0ebd34a75ddc86db5")
+  ]
+
+  proc testValue(s: string): string =
+    for item in data:
+      if item[0] == s:
+        result = item[1]
+        break
+
+  proc testE8Value(s: string): string =
+    for item in eip8data:
+      if item[0] == s:
+        result = item[1]
+        break
+
+  block:
+    var initiator: Handshake
+    var receiver: Handshake
+    var m0, dm0: PlainAuthMessage
+    var em0: AuthMessage
+
+    initiator = newHandshake({Initiator})
+    receiver = newHandshake({Responder})
+    initiator.host.seckey = getPrivateKey(testValue("initiator_private_key"))
+    initiator.host.pubkey = initiator.host.seckey.getPublicKey()
+    var epki = testValue("initiator_ephemeral_private_key")
+    initiator.ephemeral.seckey = getPrivateKey(epki)
+    initiator.ephemeral.pubkey = initiator.ephemeral.seckey.getPublicKey()
+    receiver.host.seckey = getPrivateKey(testValue("receiver_private_key"))
+    receiver.host.pubkey = receiver.host.seckey.getPublicKey()
+    var epkr = testValue("receiver_ephemeral_private_key")
+    receiver.ephemeral.seckey = getPrivateKey(epkr)
+    receiver.ephemeral.pubkey = receiver.ephemeral.seckey.getPublicKey()
+    var n0 = fromHex(stripSpaces(testValue("initiator_nonce")))
+    initiator.initiatorNonce[0..^1] = n0[0..^1]
+    var n1 = fromHex(stripSpaces(testValue("receiver_nonce")))
+    receiver.responderNonce[0..^1] = n1[0..^1]
+
+    doAssert(authMessage(initiator, receiver.host.pubkey, m0) == Success)
+    var m1 = fromHex(stripSpaces(testValue("auth_plaintext")))
+    var m2 = fromHex(stripSpaces(pyevmAuth))
+
+    doAssert(m0[65..^1] == m1[65..^1])
+    doAssert(m0[0..^1] == m2[0..^1])
+
+    # Check that encrypting and decrypting the auth_init gets us the orig msg.
+    doAssert(encryptAuthMessage(m0, em0, receiver.host.pubkey) == Success)
+    doAssert(decryptAuthMessage(em0, dm0, receiver.host.seckey) == Success)
+    doAssert(m0[0..^1] == dm0[0..^1])
+
+    # Check that the responder correctly decodes the auth msg.
+    doAssert(receiver.decodeAuthMessage(em0) == Success)
+
+    doAssert(receiver.initiatorNonce[0..^1] == n0[0..^1])
+    let remoteEPubkey0 = initiator.ephemeral.pubkey.data
+    doAssert(receiver.remoteEPubkey.data[0..^1] == remoteEPubkey0[0..^1])
+    let remoteHPubkey0 = initiator.host.pubkey.data
+    doAssert(receiver.remoteHPubkey.data[0..^1] == remoteHPubkey0[0..^1])
+
+    # Check that the auth_ack msg generated by the responder is what we expect.
+    var k0: PlainAuthAckMessage
+    var ek0: AuthAckMessage
+    doAssert(receiver.authAckMessage(k0) == Success)
+    var ac0 = fromHex(stripSpaces(testValue("authresp_plaintext")))
+    doAssert(k0[0..^1] == ac0[0..^1])
+    doAssert(receiver.initiatorNonce[0..^1] == n0[0..^1])
+    doAssert(encryptAuthAckMessage(k0, ek0, receiver.remoteHPubkey) == Success)
+
+    # Check if initiator correctly decodes the auth ack msg.
+    doAssert(initiator.decodeAckMessage(ek0) == Success)
+    let remoteEPubkey1 = receiver.ephemeral.pubkey.data
+    doAssert(initiator.remoteEPubkey.data[0..^1] == remoteEPubkey1[0..^1])
+    let remoteHPubkey1 = receiver.host.pubkey.data
+    doAssert(initiator.remoteHPubkey.data[0..^1] == remoteHPubkey1[0..^1])
+    doAssert(initiator.responderNonce[0..^1] == n1[0..^1])
+
+    # Check that the secrets derived from ephemeral key agreements match
+    # the expected values.
+    var authm = fromHex(stripSpaces(testValue("auth_ciphertext")))
+    var ackm = fromHex(stripSpaces(testValue("authresp_ciphertext")))
+    var taes = fromHex(stripSpaces(testValue("aes_secret")))
+    var tmac = fromHex(stripSpaces(testValue("mac_secret")))
+    var temac = fromHex(stripSpaces(testValue("initial_egress_MAC")))
+    var timac = fromHex(stripSpaces(testValue("initial_ingress_MAC")))
+
+    var csecInitiator: ConnectionSecret
+    var csecResponder: ConnectionSecret
+
+    doAssert(initiator.getSecrets(addr authm[0], len(authm), addr ackm[0],
+                                  len(ackm), csecInitiator) == Success)
+    doAssert(receiver.getSecrets(addr authm[0], len(authm), addr ackm[0],
+                                 len(ackm), csecResponder) == Success)
+
+    doAssert(csecInitiator.aesKey == csecResponder.aesKey)
+    doAssert(csecInitiator.macKey == csecResponder.macKey)
+    doAssert(taes[0..^1] == csecInitiator.aesKey[0..^1])
+    doAssert(tmac[0..^1] == csecInitiator.macKey[0..^1])
+
+    doAssert(csecInitiator.egressMac[0..^1] == temac[0..^1])
+    doAssert(csecInitiator.ingressMac[0..^1] == timac[0..^1])
+    doAssert(csecResponder.egressMac[0..^1] == timac[0..^1])
+    doAssert(csecResponder.ingressMac[0..^1] == temac[0..^1])
+
+  block:
+    proc newTestHandshake(flags: set[HandshakeFlag]): Handshake =
+      result = newHandshake(flags)
+      if Initiator in flags:
+        result.host.seckey = getPrivateKey(testE8Value("initiator_private_key"))
+        result.host.pubkey = result.host.seckey.getPublicKey()
+        let esec = testE8Value("initiator_ephemeral_private_key")
+        result.ephemeral.seckey = getPrivateKey(esec)
+        result.ephemeral.pubkey = result.ephemeral.seckey.getPublicKey()
+        let nonce = fromHex(stripSpaces(testE8Value("initiator_nonce")))
+        result.initiatorNonce[0..(KeyLength - 1)] = nonce[0..(KeyLength - 1)]
+      elif Responder in flags:
+        result.host.seckey = getPrivateKey(testE8Value("receiver_private_key"))
+        result.host.pubkey = result.host.seckey.getPublicKey()
+        let esec = testE8Value("receiver_ephemeral_private_key")
+        result.ephemeral.seckey = getPrivateKey(esec)
+        result.ephemeral.pubkey = result.ephemeral.seckey.getPublicKey()
+        let nonce = fromHex(stripSpaces(testE8Value("receiver_nonce")))
+        result.responderNonce[0..(KeyLength - 1)] = nonce[0..(KeyLength - 1)]
+
+    block: # auth/ack v4
+      var initiator = newTestHandshake({Initiator})
+      var receiver = newTestHandshake({Responder})
+
+      # Check that the responder correctly decodes the auth msg.
+      var m0 = fromHex(stripSpaces(testE8Value("auth_ciphertext_v4")))
+      doAssert(receiver.decodeAuthMessage(m0) == Success)
+
+      doAssert(receiver.initiatorNonce[0..^1] ==
+               initiator.initiatorNonce[0..^1])
+      let remoteEPubkey0 = initiator.ephemeral.pubkey.data
+      doAssert(receiver.remoteEPubkey.data[0..^1] == remoteEPubkey0[0..^1])
+      let remoteHPubkey0 = initiator.host.pubkey.data
+      doAssert(receiver.remoteHPubkey.data[0..^1] == remoteHPubkey0[0..^1])
+
+      # Check that the initiator correctly decodes the auth ack msg.
+      var m1 = fromHex(stripSpaces(testE8Value("authack_ciphertext_v4")))
+      doAssert(initiator.decodeAckMessage(m1) == Success)
+
+      let remoteEPubkey1 = receiver.ephemeral.pubkey.data
+      doAssert(initiator.remoteEPubkey.data[0..^1] == remoteEPubkey1[0..^1])
+      doAssert(initiator.responderNonce[0..^1] ==
+               receiver.responderNonce[0..^1])
+
+    block: # auth/ack eip8
+      var initiator = newTestHandshake({Initiator})
+      var receiver = newTestHandshake({Responder})
+
+      # Check that the responder correctly decodes the auth msg.
+      var m0 = fromHex(stripSpaces(testE8Value("auth_ciphertext_eip8")))
+      doAssert(receiver.decodeAuthMessage(m0) == Success)
+
+      doAssert(receiver.initiatorNonce[0..^1] ==
+               initiator.initiatorNonce[0..^1])
+      let remoteEPubkey0 = initiator.ephemeral.pubkey.data
+      doAssert(receiver.remoteEPubkey.data[0..^1] == remoteEPubkey0[0..^1])
+      let remoteHPubkey0 = initiator.host.pubkey.data
+      doAssert(receiver.remoteHPubkey.data[0..^1] == remoteHPubkey0[0..^1])
+
+      # Check that the initiator correctly decodes the auth ack msg.
+      var m1 = fromHex(stripSpaces(testE8Value("authack_ciphertext_eip8")))
+      doAssert(initiator.decodeAckMessage(m1) == Success)
+
+      let remoteEPubkey1 = receiver.ephemeral.pubkey.data
+      doAssert(initiator.remoteEPubkey.data[0..^1] == remoteEPubkey1[0..^1])
+      doAssert(initiator.responderNonce[0..^1] ==
+               receiver.responderNonce[0..^1])
+
+      # Check that the secrets derived from ephemeral key agreements match
+      # the expected values.
+      var taes = fromHex(stripSpaces(testE8Value("auth2ack2_aes_secret")))
+      var tmac = fromHex(stripSpaces(testE8Value("auth2ack2_mac_secret")))
+      
+      var csecInitiator: ConnectionSecret
+      var csecResponder: ConnectionSecret
+
+      doAssert(initiator.getSecrets(addr m0[0], len(m0), addr m1[0],
+                                    len(m1), csecInitiator) == Success)
+      doAssert(receiver.getSecrets(addr m0[0], len(m0), addr m1[0],
+                                   len(m1), csecResponder) == Success)
+
+      doAssert(csecInitiator.aesKey == csecResponder.aesKey)
+      doAssert(csecInitiator.macKey == csecResponder.macKey)
+      doAssert(taes[0..^1] == csecInitiator.aesKey[0..^1])
+      doAssert(tmac[0..^1] == csecInitiator.macKey[0..^1])
+
+    block: # auth/ack eip8 with 3 additional fields
+      var initiator = newTestHandshake({Initiator})
+      var receiver = newTestHandshake({Responder})
+
+      # Check that the responder correctly decodes the auth msg.
+      var m0 = fromHex(stripSpaces(testE8Value("auth_ciphertext_eip8_3f")))
+      doAssert(receiver.decodeAuthMessage(m0) == Success)
+
+      doAssert(receiver.initiatorNonce[0..^1] ==
+               initiator.initiatorNonce[0..^1])
+      let remoteEPubkey0 = initiator.ephemeral.pubkey.data
+      doAssert(receiver.remoteEPubkey.data[0..^1] == remoteEPubkey0[0..^1])
+      let remoteHPubkey0 = initiator.host.pubkey.data
+      doAssert(receiver.remoteHPubkey.data[0..^1] == remoteHPubkey0[0..^1])
+
+      # Check that the initiator correctly decodes the auth ack msg.
+      var m1 = fromHex(stripSpaces(testE8Value("authack_ciphertext_eip8_3f")))
+      doAssert(initiator.decodeAckMessage(m1) == Success)
+
+      let remoteEPubkey1 = receiver.ephemeral.pubkey.data
+      doAssert(initiator.remoteEPubkey.data[0..^1] == remoteEPubkey1[0..^1])
+      doAssert(initiator.responderNonce[0..^1] ==
+               receiver.responderNonce[0..^1])

ethp2p/ecc.nim

@@ -0,0 +1,446 @@
+#
+#                 Ethereum P2P
+#              (c) Copyright 2018
+#       Status Research & Development GmbH
+#
+#    See the file "LICENSE", included in this
+#    distribution, for details about the copyright.
+#
+
+## This module implements `libsecp256k1` ECC/ECDH functions
+
+import secp256k1, hexdump, nimcrypto/sysrand, nimcrypto/utils
+
+const
+  KeyLength* = 32
+  PublicKeyLength* = 64
+  SignatureLength* = 65
+
+
+type
+  EccContext* = ref object of RootRef
+    context*: ptr secp256k1_context
+    error*: string
+
+  EccStatus* = enum
+    Success,  ## Operation was successful
+    Error     ## Operation failed
+
+  PublicKey* = secp256k1_pubkey
+    ## Representation of public key
+
+  PrivateKey* = array[KeyLength, byte]
+    ## Representation of secret key
+
+  SharedSecret* = array[KeyLength, byte]
+    ## Representation of ECDH shared secret
+
+  Nonce* = array[KeyLength, byte]
+    ## Representation of nonce
+
+  RawPublickey* = object
+    ## Representation of serialized public key
+    header*: byte
+    data*: array[KeyLength * 2, byte]
+
+  KeyPair* = object
+    ## Representation of private/public keys pair
+    seckey*: PrivateKey
+    pubkey*: PublicKey
+
+  Signature* = secp256k1_ecdsa_recoverable_signature
+    ## Representation of signature
+
+  RawSignature* = object
+    ## Representation of serialized signature
+    data*: array[KeyLength * 2 + 1, byte]
+
+  Secp256k1Exception* = object of Exception
+    ## Exceptions generated by `libsecp256k1`
+  EccException* = object of Exception
+    ## Exception generated by this module
+
+var eccContext* {.threadvar.}: EccContext
+  ## Thread local variable which holds current context
+
+proc illegalCallback(message: cstring; data: pointer) {.cdecl.} =
+  let ctx = cast[EccContext](data)
+  ctx.error = $message
+
+proc errorCallback(message: cstring, data: pointer) {.cdecl.} =
+  let ctx = cast[EccContext](data)
+  ctx.error = $message
+
+proc newEccContext*(): EccContext =
+  ## Create new `EccContext`.
+  result = new EccContext
+  let flags = cuint(SECP256K1_CONTEXT_VERIFY or SECP256K1_CONTEXT_SIGN)
+  result.context = secp256k1_context_create(flags)
+  secp256k1_context_set_illegal_callback(result.context, illegalCallback,
+                                         cast[pointer](result))
+  secp256k1_context_set_error_callback(result.context, errorCallback,
+                                       cast[pointer](result))
+  result.error = ""
+
+proc getSecpContext*(): ptr secp256k1_context =
+  ## Get current `secp256k1_context`
+  if isNil(eccContext):
+    eccContext = newEccContext()
+  result = eccContext.context
+
+proc getEccContext*(): EccContext =
+  ## Get current `EccContext`
+  if isNil(eccContext):
+    eccContext = newEccContext()
+  result = eccContext
+
+template raiseSecp256k1Error*() =
+  ## Raises `libsecp256k1` error as exception
+  let mctx = getEccContext()
+  if len(mctx.error) > 0:
+    var msg = mctx.error
+    mctx.error.setLen(0)
+    raise newException(Secp256k1Exception, msg)
+
+proc eccErrorMsg*(): string =
+  let mctx = getEccContext()
+  result = mctx.error
+
+proc setErrorMsg*(m: string) =
+  let mctx = getEccContext()
+  mctx.error = m
+
+proc getRaw*(pubkey: PublicKey): RawPublickey =
+  ## Converts public key `pubkey` to serialized form of `secp256k1_pubkey`.
+  var length = csize(sizeof(RawPublickey))
+  let ctx = getSecpContext()
+  if secp256k1_ec_pubkey_serialize(ctx, cast[ptr cuchar](addr result),
+                                   addr length, unsafeAddr pubkey,
+                                   SECP256K1_EC_UNCOMPRESSED) != 1:
+    raiseSecp256k1Error()
+  if length != 65:
+    raise newException(EccException, "Invalid public key length!")
+  if result.header != 0x04'u8:
+    raise newException(EccException, "Invalid public key header!")
+
+proc getRaw*(s: Signature): RawSignature =
+  ## Converts signature `s` to serialized form.
+  let ctx = getSecpContext()
+  var recid = cint(0)
+  if secp256k1_ecdsa_recoverable_signature_serialize_compact(
+    ctx, cast[ptr cuchar](unsafeAddr result), addr recid, unsafeAddr s) != 1:
+    raiseSecp256k1Error()
+  result.data[64] = uint8(recid)
+
+proc signMessage*(seckey: PrivateKey, data: ptr byte, length: int,
+                  sig: var Signature): EccStatus =
+  ## Sign message pointed by `data` with size `length` and save signature to
+  ## `sig`.
+  let ctx = getSecpContext()
+  if secp256k1_ecdsa_sign_recoverable(ctx, addr sig,
+                                      cast[ptr cuchar](data),
+                                      cast[ptr cuchar](unsafeAddr seckey[0]),
+                                      nil, nil) != 1:
+    return(Error)
+  return(Success)
+
+proc signMessage*[T](seckey: PrivateKey, data: openarray[T],
+                     sig: var Signature, ostart: int = 0,
+                     ofinish: int = -1): EccStatus =
+  ## Sign message ``data``[`soffset`..`eoffset`] and store result into `sig`.
+  let so = ostart
+  let eo = if ofinish == -1: (len(data) - 1) else: ofinish
+  let length = (eo - so + 1) * sizeof(T)
+  # We don't need to check `so` because compiler will do it for `data[so]`.
+  if eo >= len(data):
+    setErrorMsg("Index is out of bounds!")
+    return(Error)
+  if len(data) < KeyLength or length < KeyLength:
+    setErrorMsg("There no reason to sign this message!")
+    return(Error)
+  result = signMessage(seckey, cast[ptr byte](unsafeAddr data[so]),
+                       length, sig)
+
+proc recoverSignatureKey*(data: ptr byte, length: int, message: ptr byte,
+                          pubkey: var PublicKey): EccStatus =
+  ## Check signature and return public key from `data` with size `length` and
+  ## `message`.
+  let ctx = getSecpContext()
+  var s: secp256k1_ecdsa_recoverable_signature
+  if length >= 65:
+    var recid = cint(cast[ptr UncheckedArray[byte]](data)[KeyLength * 2])
+    if secp256k1_ecdsa_recoverable_signature_parse_compact(ctx, addr s,
+                                                         cast[ptr cuchar](data),
+                                                           recid) != 1:
+      return(Error)
+
+    if secp256k1_ecdsa_recover(ctx, addr pubkey, addr s,
+                               cast[ptr cuchar](message)) != 1:
+      setErrorMsg("Message signature verification failed!")
+      return(Error)
+    return(Success)
+  else:
+    setErrorMsg("Incorrect signature size")
+    return(Error)
+
+proc recoverSignatureKey*[A, B](data: openarray[A],
+                                message: openarray[B],
+                                pubkey: var PublicKey,
+                                ostart: int = 0,
+                                ofinish: int = -1): EccStatus =
+  ## Check signature in ``data``[`soffset`..`eoffset`] and recover public key
+  ## from signature to ``pubkey`` using message `message`.
+  if len(message) == 0:
+    setErrorMsg("Message could not be empty!")
+    return(Error)
+  let so = ostart
+  let eo = if ofinish == -1: (len(data) - 1) else: ofinish
+  let length = (eo - so + 1) * sizeof(A)
+  # We don't need to check `so` because compiler will do it for `data[so]`.
+  if eo > len(data):
+    setErrorMsg("Index is out of bounds!")
+    return(Error)
+  if length < sizeof(RawSignature) or len(data) < sizeof(RawSignature):
+    setErrorMsg("Invalid signature size!")
+    return(Error)
+  result = recoverSignatureKey(cast[ptr byte](unsafeAddr data[so]), length,
+                               cast[ptr byte](unsafeAddr message[0]), pubkey)
+
+proc ecdhAgree*(seckey: PrivateKey, pubkey: PublicKey,
+                secret: var SharedSecret): EccStatus =
+  ## Calculate ECDH shared secret
+  var res: array[KeyLength + 1, byte]
+  let ctx = getSecpContext()
+  if secp256k1_ecdh_raw(ctx, cast[ptr cuchar](addr res),
+                        unsafeAddr pubkey,
+                        cast[ptr cuchar](unsafeAddr seckey)) != 1:
+    return(Error)
+  copyMem(addr secret[0], addr res[1], KeyLength)
+  return(Success)
+
+proc getPublicKey*(seckey: PrivateKey): PublicKey =
+  ## Return public key for private key `seckey`.
+  let ctx = getSecpContext()
+  if secp256k1_ec_pubkey_create(ctx, addr result,
+                                cast[ptr cuchar](unsafeAddr seckey[0])) != 1:
+    raiseSecp256k1Error()
+
+
+proc recoverPublicKey*(data: ptr byte, length: int,
+                       pubkey: var PublicKey): EccStatus =
+  ## Unserialize public key from `data` pointer and size `length` and'
+  ## set `pubkey`.
+  let ctx = getSecpContext()
+  if length < sizeof(PublicKey):
+    setErrorMsg("Invalid public key!")
+    return(Error)
+  var rawkey: RawPublickey
+  rawkey.header = 0x04 # mark key with COMPRESSED flag
+  copyMem(addr rawkey.data[0], data, len(rawkey.data))
+  if secp256k1_ec_pubkey_parse(ctx, addr pubkey,
+                               cast[ptr cuchar](addr rawkey),
+                               sizeof(RawPublickey)) != 1:
+    return(Error)
+  return(Success)
+
+proc recoverPublicKey*[T](data: openarray[T], pubkey: var PublicKey,
+                          ostart: int = 0, ofinish: int = -1, ): EccStatus =
+  ## Unserialize public key from openarray[T] `data`, from position `ostart` to
+  ## position `ofinish` and save it to `pubkey`.
+  let so = ostart
+  let eo = if ofinish == -1: (len(data) - 1) else: ofinish
+  let length = (eo - so + 1) * sizeof(T)
+  # We don't need to check `so` because compiler will do it for `data[so]`.
+  if eo > len(data):
+    setErrorMsg("Index is out of bounds!")
+    return(Error)
+  if length < sizeof(PublicKey) or len(data) < sizeof(PublicKey):
+    setErrorMsg("Invalid public key size!")
+    return(Error)
+  result = recoverPublicKey(cast[ptr byte](unsafeAddr data[so]), length,
+                            pubkey)
+
+proc newPrivateKey*(): PrivateKey =
+  ## Generates new secret key.
+  let ctx = getSecpContext()
+  while true:
+    if randomBytes(addr result[0], KeyLength) == KeyLength:
+      if secp256k1_ec_seckey_verify(ctx, cast[ptr cuchar](addr result[0])) == 1:
+        break
+
+proc newKeyPair*(): KeyPair =
+  ## Generates new private and public key.
+  result.seckey = newPrivateKey()
+  result.pubkey = result.seckey.getPublicKey()
+
+proc getPrivateKey*(hexstr: string): PrivateKey =
+  ## Set secret key from hexadecimal string representation.
+  let ctx = getSecpContext()
+  var o = fromHex(stripSpaces(hexstr))
+  if len(o) < KeyLength:
+    raise newException(EccException, "Invalid private key!")
+  copyMem(addr result[0], unsafeAddr o[0], KeyLength)
+  if secp256k1_ec_seckey_verify(ctx, cast[ptr cuchar](addr result[0])) != 1:
+    raise newException(EccException, "Invalid private key!")
+
+proc getPublicKey*(hexstr: string): PublicKey =
+  ## Set public key from hexadecimal string representation.
+  var o = fromHex(stripSpaces(hexstr))
+  if recoverPublicKey(o, result) != Success:
+    raise newException(EccException, "Invalid public key!")
+
+proc dump*(s: openarray[byte], c: string = ""): string =
+  ## Return hexadecimal dump of array `s`.
+  result = if len(c) > 0: c & "=>\n" else: ""
+  if len(s) > 0:
+    result &= dumpHex(unsafeAddr s[0], len(s))
+  else:
+    result &= "[]"
+
+proc dump*(s: PublicKey, c: string = ""): string =
+  ## Return hexadecimal dump of public key `s`.
+  result = if len(c) > 0: c & "=>\n" else: ""
+  result &= dumpHex(unsafeAddr s.data[0], sizeof(secp256k1_pubkey))
+
+proc dump*(s: RawSignature, c: string = ""): string =
+  ## Return hexadecimal dump of serialized signature `s`.
+  result = if len(c) > 0: c & "=>\n" else: ""
+  result &= dumpHex(unsafeAddr s.data[0], sizeof(RawSignature))
+
+proc dump*(s: RawPublickey, c: string = ""): string =
+  ## Return hexadecimal dump of serialized public key `s`.
+  result = if len(c) > 0: c & "=>\n" else: ""
+  result &= dumpHex(unsafeAddr s, sizeof(RawSignature))
+
+proc dump*(s: secp256k1_ecdsa_recoverable_signature, c: string = ""): string =
+  ## Return hexadecimal dump of signature `s`.
+  result = if len(c) > 0: c & "=>\n" else: ""
+  result &= dumpHex(unsafeAddr s.data[0],
+                    sizeof(secp256k1_ecdsa_recoverable_signature))
+
+proc dump*(p: pointer, s: int, c: string = ""): string =
+  ## Return hexadecimal dump of memory blob `p` and size `s`.
+  result = if len(c) > 0: c & "=>\n" else: ""
+  result &= dumpHex(p, s)
+
+when isMainModule:
+  import nimcrypto/hash, nimcrypto/keccak
+
+  proc compare(x: openarray[byte], y: openarray[byte]): bool =
+    result = len(x) == len(y)
+    if result:
+      for i in 0..(len(x) - 1):
+        if x[i] != y[i]:
+          result = false
+          break
+
+  block:
+    # ECDHE test vectors
+    # Copied from
+    # https://github.com/ethereum/py-evm/blob/master/tests/p2p/test_ecies.py#L19
+    const privateKeys = [
+      "332143e9629eedff7d142d741f896258f5a1bfab54dab2121d3ec5000093d74b",
+      "7ebbc6a8358bc76dd73ebc557056702c8cfc34e5cfcd90eb83af0347575fd2ad"
+    ]
+    const publicKeys = [
+      """f0d2b97981bd0d415a843b5dfe8ab77a30300daab3658c578f2340308a2da1a07
+         f0821367332598b6aa4e180a41e92f4ebbae3518da847f0b1c0bbfe20bcf4e1""",
+      """83ede0f19c3c98649265956a4193677b14c338a22de2086a08d84e4446fe37e4e
+         233478259ec90dbeef52f4f6c890f8c38660ec7b61b9d439b8a6d1c323dc025"""
+    ]
+    const sharedSecrets = [
+      "ee1418607c2fcfb57fda40380e885a707f49000a5dda056d828b7d9bd1f29a08",
+      "167ccc13ac5e8a26b131c3446030c60fbfac6aa8e31149d0869f93626a4cdf62"
+    ]
+    var secret: array[KeyLength, byte]
+    for i in 0..1:
+      var s = privateKeys[i].getPrivateKey()
+      var p = publicKeys[i].getPublicKey()
+      doAssert(ecdhAgree(s, p, secret) == Success)
+      var check = fromHex(stripSpaces(sharedSecrets[i]))
+      doAssert(compare(check, secret))
+
+  block:
+    # ECDHE test vectors
+    # Copied from https://github.com/ethereum/cpp-ethereum/blob/develop/test/unittests/libdevcrypto/crypto.cpp#L394
+    var expect = """
+      8ac7e464348b85d9fdfc0a81f2fdc0bbbb8ee5fb3840de6ed60ad9372e718977"""
+    var secret: array[KeyLength, byte]
+    var s = keccak256.digest("ecdhAgree").data
+    var p = s.getPublicKey()
+    doAssert(ecdhAgree(s, p, secret) == Success)
+    var check = fromHex(stripSpaces(expect))
+    doAssert(compare(check, secret))
+
+  block:
+    # ECDHE test vectors
+    # Copied from https://github.com/ethereum/cpp-ethereum/blob/2409d7ec7d34d5ff5770463b87eb87f758e621fe/test/unittests/libp2p/rlpx.cpp#L425
+    var s0 = """
+      332143e9629eedff7d142d741f896258f5a1bfab54dab2121d3ec5000093d74b"""
+    var p0 = """
+      f0d2b97981bd0d415a843b5dfe8ab77a30300daab3658c578f2340308a2da1a0
+      7f0821367332598b6aa4e180a41e92f4ebbae3518da847f0b1c0bbfe20bcf4e1"""
+    var e0 = """
+      ee1418607c2fcfb57fda40380e885a707f49000a5dda056d828b7d9bd1f29a08"""
+    var secret: array[KeyLength, byte]
+    var s = getPrivateKey(s0)
+    var p = getPublicKey(p0)
+    var check = fromHex(stripSpaces(e0))
+    doAssert(ecdhAgree(s, p, secret) == Success)
+    doAssert(compare(check, secret))
+
+  block:
+    # ECDSA test vectors
+    # Copied from https://github.com/ethereum/cpp-ethereum/blob/develop/test/unittests/libdevcrypto/crypto.cpp#L132
+    var signature = """
+      b826808a8c41e00b7c5d71f211f005a84a7b97949d5e765831e1da4e34c9b8295d
+      2a622eee50f25af78241c1cb7cfff11bcf2a13fe65dee1e3b86fd79a4e3ed000"""
+    var pubkey = """
+      e40930c838d6cca526795596e368d16083f0672f4ab61788277abfa23c3740e1cc
+      84453b0b24f49086feba0bd978bb4446bae8dff1e79fcc1e9cf482ec2d07c3"""
+    var check1 = fromHex(stripSpaces(signature))
+    var check2 = fromHex(stripSpaces(pubkey))
+    var sig: Signature
+    var key: PublicKey
+    var s = keccak256.digest("sec").data
+    var m = keccak256.digest("msg").data
+    doAssert(signMessage(s, m, sig) == Success)
+    var sersig = sig.getRaw().data
+    doAssert(recoverSignatureKey(sersig, m, key) == Success)
+    var serkey = key.getRaw().data
+    doAssert(compare(sersig, check1))
+    doAssert(compare(serkey, check2))
+
+  block:
+    # signature test
+    var rkey: PublicKey
+    var sig: Signature
+    for i in 1..100:
+      var m = newPrivateKey()
+      var s = newPrivateKey()
+      var key = s.getPublicKey()
+      doAssert(signMessage(s, m, sig) == Success)
+      var sersig = sig.getRaw().data
+      doAssert(recoverSignatureKey(sersig, m, rkey) == Success)
+      doAssert(key == rkey)
+
+  block:
+    # key create/recovery test
+    var rkey: PublicKey
+    for i in 1..100:
+      var s = newPrivateKey()
+      var key = s.getPublicKey()
+      doAssert(recoverPublicKey(key.getRaw().data, rkey) == Success)
+      doAssert(key == rkey)
+
+  block:
+    # ECDHE shared secret test
+    var secret1, secret2: SharedSecret
+    for i in 1..100:
+      var aliceSecret = newPrivateKey()
+      var alicePublic = aliceSecret.getPublicKey()
+      var bobSecret = newPrivateKey()
+      var bobPublic = bobSecret.getPublicKey()
+      doAssert(ecdhAgree(aliceSecret, bobPublic, secret1) == Success)
+      doAssert(ecdhAgree(bobSecret, alicePublic, secret2) == Success)
+      doAssert(secret1 == secret2)

ethp2p/ecies.nim

@@ -0,0 +1,493 @@
+#
+#                 Ethereum P2P
+#              (c) Copyright 2018
+#       Status Research & Development GmbH
+#
+#    See the file "LICENSE", included in this
+#    distribution, for details about the copyright.
+#
+
+## This module implements ECIES method encryption/decryption.
+
+import ecc, nimcrypto/sha2, nimcrypto/hash, nimcrypto/hmac
+import nimcrypto/rijndael, nimcrypto/utils, nimcrypto/sysrand
+import nimcrypto/bcmode, nimcrypto/utils
+
+type
+  EciesException* = object of Exception
+  EciesStatus* = enum
+    Success,        ## Operation was successful
+    BufferOverrun,  ## Output buffer size is too small
+    EmptyMessage,   ## Attempt to encrypt/decrypt empty message
+    RandomError,    ## Could not obtain random data
+    EcdhError,      ## ECDH shared secret could not be calculated
+    IncorrectSize,  ## ECIES data has incorrect size (size is too low)
+    WrongHeader,    ## ECIES header is incorrect
+    IncorrectKey,   ## Recovered public key is invalid
+    IncorrectTag    ## ECIES tag verification failed
+
+template eciesOverheadLength*(): int =
+  ## Return data overhead size for ECIES encrypted message
+  1 + sizeof(PublicKey) + aes128.sizeBlock + sha256.sizeDigest
+
+template eciesEncryptedLength*(size: int): int =
+  ## Return size of encrypted message for message with size `size`.
+  size + eciesOverheadLength()
+
+template eciesDecryptedLength*(size: int): int =
+  ## Return size of decrypted message for encrypted message with size `size`.
+  size - eciesOverheadLength()
+
+template eciesMacLength(size: int): int =
+  ## Return size of authenticated data
+  size + aes128.sizeBlock
+
+template eciesMacPos(size: int): int =
+  ## Return position of MAC code in encrypted block
+  size - sha256.sizeDigest
+
+template eciesIvPos(): int =
+  ## Return position of IV in encrypted block
+  sizeof(PublicKey) + 1
+
+template eciesDataPos(): int =
+  ## Return position of encrypted data in block
+  sizeof(PublicKey) + 1 + aes128.sizeBlock
+
+proc kdf*(data: openarray[byte]): array[KeyLength, byte] {.noInit.} =
+  ## NIST SP 800-56a Concatenation Key Derivation Function (see section 5.8.1)
+  var ctx: sha256
+  var counter: uint32
+  var counterLe: uint32
+  let reps = ((KeyLength + 7) * 8) div (int(ctx.sizeDigest) * 8)
+  var offset = 0
+  var storage = newSeq[byte](KeyLength * (reps + 1))
+  while counter <= uint32(reps):
+    counter = counter + 1
+    counterLe = LSWAP(counter)
+    ctx.init()
+    ctx.update(cast[ptr byte](addr counterLe), uint(sizeof(uint32)))
+    ctx.update(unsafeAddr data[0], uint(len(data)))
+    var hash = ctx.finish().data
+    copyMem(addr storage[offset], addr hash[0], ctx.sizeDigest)
+    offset = offset + int(ctx.sizeDigest)
+  ctx.init() # clean ctx
+  copyMem(addr result[0], addr storage[0], KeyLength)
+
+proc eciesEncrypt*(inp, oup: ptr byte, inl, oul: int, pubkey: PublicKey,
+                   shmac: ptr byte = nil, shlen: int = 0): EciesStatus =
+  ## Encrypt data with ECIES method to the given public key `pubkey`.
+  ##
+  ## `inp`    - [INPUT] pointer to input data
+  ## `oup`    - [INPUT] pointer to output data
+  ## `inl`    - [INPUT] input data size
+  ## `oul`    - [INPUT] output data size
+  ## `pubkey` - [INPUT] Ecc secp256k1 public key
+  ## `shmac`  - [INPUT] additional mac data
+  ## `shlen`  - [INPUT] additional mac data size
+
+  var
+    encKey: array[KeyLength div 2, byte]
+    macKey: array[KeyLength, byte]
+    cipher: CTR[aes128]
+    ctx: HMAC[sha256]
+    iv: array[aes128.sizeBlock, byte]
+    tag: array[sha256.sizeDigest, byte]
+    secret: SharedSecret
+    material: array[KeyLength, byte]
+
+  assert(not isNil(inp) and not isNil(oup))
+  assert(inl > 0 and oul > 0)
+
+  if oul < eciesEncryptedLength(inl):
+    return(BufferOverrun)
+  if randomBytes(addr iv[0], len(iv)) != len(iv):
+    return(RandomError)
+
+  var ephemeral = newKeyPair()
+  var output = cast[ptr UncheckedArray[byte]](oup)
+  var epub = ephemeral.pubkey.getRaw()
+
+  if ecdhAgree(ephemeral.seckey, pubkey, secret) != EccStatus.Success:
+    return(EcdhError)
+
+  material = kdf(secret)
+  zeroMem(addr secret[0], sizeof(SharedSecret)) # clean shared secret
+  copyMem(addr encKey[0], addr material[0], KeyLength div 2)
+  macKey = sha256.digest(material, KeyLength div 2).data
+  zeroMem(addr material[0], KeyLength) # clean material
+
+  cipher.init(addr encKey[0], addr iv[0])
+  cipher.encrypt(inp, cast[ptr byte](addr output[eciesDataPos()]), uint(inl))
+  zeroMem(addr encKey[0], KeyLength div 2) # clean encKey
+  zeroMem(addr cipher, sizeof(CTR[aes128])) # clean cipher context
+
+  output[0] = 0x04
+  copyMem(addr output[1], addr epub.data[0], sizeof(PublicKey))
+  copyMem(addr output[eciesIvPos()], addr iv[0], aes128.sizeBlock)
+
+  ctx.init(addr macKey[0], uint(len(macKey)))
+  ctx.update(addr output[eciesIvPos()], uint(eciesMacLength(inl)))
+  if not isNil(shmac) and shlen > 0:
+    ctx.update(shmac, uint(shlen))
+  tag = ctx.finish().data
+  zeroMem(addr ctx, sizeof(HMAC[sha256])) # clean hmac context
+  zeroMem(addr macKey[0], KeyLength) # clean macKey
+  copyMem(addr output[eciesDataPos() + inl], addr tag[0], sha256.sizeDigest)
+  result = Success
+
+proc eciesDecrypt*(inp, oup: ptr byte, inl, oul: int, seckey: PrivateKey,
+                   shmac: ptr byte = nil, shlen: int = 0): EciesStatus =
+  ## Decrypt data with ECIES method using the given private key `seckey`.
+  ##
+  ## `inp`    - [INPUT] pointer to input data
+  ## `oup`    - [INPUT] pointer to output data
+  ## `inl`    - [INPUT] input data size
+  ## `oul`    - [INPUT] output data size
+  ## `seckey` - [INPUT] Ecc secp256k1 private key
+  ## `shmac`  - [INPUT] additional mac data (default = nil)
+  ## `shlen`  - [INPUT] additional mac data size (default = 0)
+
+  var
+    pubkey: PublicKey
+    encKey: array[KeyLength div 2, byte]
+    macKey: array[KeyLength, byte]
+    tag: array[sha256.sizeDigest, byte]
+    cipher: CTR[aes128]
+    ctx: HMAC[sha256]
+    secret: SharedSecret
+
+  assert(not isNil(inp) and not isNil(oup))
+  assert(inl > 0 and oul > 0)
+
+  var input = cast[ptr UncheckedArray[byte]](inp)
+  if inl <= eciesOverheadLength():
+    return(IncorrectSize)
+  if inl - eciesOverheadLength() > oul:
+    return(BufferOverrun)
+  if input[0] != 0x04:
+    return(WrongHeader)
+
+  if recoverPublicKey(addr input[1], KeyLength * 2,
+                      pubkey) != EccStatus.Success:
+    return(IncorrectKey)
+  if ecdhAgree(seckey, pubkey, secret) != EccStatus.Success:
+    return(EcdhError)
+
+  var material = kdf(secret)
+  zeroMem(addr secret[0], sizeof(SharedSecret)) # clean shared secret
+  copyMem(addr encKey[0], addr material[0], KeyLength div 2)
+  macKey = sha256.digest(material, KeyLength div 2).data
+  zeroMem(addr material[0], KeyLength) # clean material
+
+  let macsize = eciesMacLength(inl - eciesOverheadLength())
+  ctx.init(addr macKey[0], uint(len(macKey)))
+
+  ctx.update(addr input[eciesIvPos()], uint(macsize))
+  if not isNil(shmac) and shlen > 0:
+    ctx.update(shmac, uint(shlen))
+  tag = ctx.finish().data
+  zeroMem(addr ctx, sizeof(HMAC[sha256])) # clean hmac context
+  zeroMem(addr macKey[0], KeyLength) # clean macKey
+
+  if not equalMem(addr tag[0], addr input[eciesMacPos(inl)], sha256.sizeDigest):
+    return(IncorrectTag)
+
+  cipher.init(addr encKey[0], addr input[eciesIvPos()])
+  cipher.decrypt(cast[ptr byte](addr input[eciesDataPos()]),
+                 cast[ptr byte](oup), uint(inl - eciesOverheadLength()))
+
+  zeroMem(addr encKey[0], KeyLength div 2) # clean encKey
+  zeroMem(addr cipher, sizeof(CTR[aes128])) # clean cipher context
+  result = Success
+
+proc eciesEncrypt*[A, B](input: openarray[A],
+                         pubkey: PublicKey,
+                         output: var openarray[B],
+                         outlen: var int,
+                         ostart: int = 0,
+                         ofinish: int = -1): EciesStatus =
+  ## Encrypt data with ECIES method to the given public key `pubkey`.
+  ##
+  ## `input`   - [INPUT] input data
+  ## `pubkey`  - [INPUT] Ecc secp256k1 public key
+  ## `output`  - [OUTPUT] output data
+  ## `outlen`  - [OUTPUT] output data size
+  ## `ostart`  - [INPUT] starting index in `data` (default = -1, start of input)
+  ## `ofinish` - [INPUT] ending index in `data` (default = -1, whole input)
+  ##
+  ## Encryption is done on `data` with inclusive range [ostart, ofinish]
+  ## Negative values of `ostart` and `ofinish` are treated as index with value
+  ## (len(data) + `ostart/ofinish`).
+
+  let so = if ostart < 0: (len(input) + ostart) else: ostart
+  let eo = if ofinish < 0: (len(input) + ofinish) else: ofinish
+  let length = (eo - so + 1) * sizeof(A)
+  # We don't need to check `so` because compiler will do it for `data[so]`.
+  if eo >= len(input):
+    return(BufferOverrun)
+  if len(input) == 0:
+    return(EmptyMessage)
+  let esize = eciesEncryptedLength(length)
+  if (len(output) * sizeof(B)) < esize:
+    return(BufferOverrun)
+  outlen = esize
+  result = eciesEncrypt(cast[ptr byte](unsafeAddr input[so]), addr output[0],
+                        length, esize, pubkey)
+
+proc eciesEncrypt*[A, B, C](input: openarray[A],
+                            pubkey: PublicKey,
+                            output: var openarray[B],
+                            outlen: var int,
+                            shmac: openarray[C],
+                            ostart: int = 0,
+                            ofinish: int = -1): EciesStatus =
+  ## Encrypt data with ECIES method to the given public key `pubkey`.
+  ##
+  ## `input`   - [INPUT] input data
+  ## `pubkey`  - [INPUT] Ecc secp256k1 public key
+  ## `output`  - [OUTPUT] output data
+  ## `outlen`  - [OUTPUT] output data size
+  ## `shmac`   - [INPUT] additional mac data
+  ## `ostart`  - [INPUT] starting index in `data` (default = -1, start of input)
+  ## `ofinish` - [INPUT] ending index in `data` (default = -1, whole input)
+  ##
+  ## Encryption is done on `data` with inclusive range [ostart, ofinish]
+  ## Negative values of `ostart` and `ofinish` are treated as index with value
+  ## (len(data) + `ostart/ofinish`).
+
+  let so = if ostart < 0: (len(input) + ostart) else: ostart
+  let eo = if ofinish < 0: (len(input) + ofinish) else: ofinish
+  let length = (eo - so + 1) * sizeof(A)
+  # We don't need to check `so` because compiler will do it for `data[so]`.
+  if eo >= len(input):
+    return(BufferOverrun)
+  if len(input) == 0:
+    return(EmptyMessage)
+  let esize = eciesEncryptedLength(length)
+  if len(output) * sizeof(B) < esize:
+    return(BufferOverrun)
+  outlen = esize
+  result = eciesEncrypt(cast[ptr byte](unsafeAddr input[so]), addr output[0],
+                        length, esize, pubkey,
+                        cast[ptr byte](unsafeAddr shmac[0]),
+                        len(shmac) * sizeof(C))
+
+proc eciesDecrypt*[A, B](input: openarray[A],
+                         seckey: PrivateKey,
+                         output: var openarray[B],
+                         outlen: var int,
+                         ostart: int = 0,
+                         ofinish: int = -1): EciesStatus =
+  ## Decrypt data with ECIES method using given private key `seckey`.
+  ##
+  ## `input`   - [INPUT] input data
+  ## `seckey`  - [INPUT] Ecc secp256k1 private key
+  ## `output`  - [OUTPUT] output data
+  ## `outlen`  - [OUTPUT] output data size
+  ## `ostart`  - [INPUT] starting index in `data` (default = -1, start of input)
+  ## `ofinish` - [INPUT] ending index in `data` (default = -1, whole input)
+  ##
+  ## Decryption is done on `data` with inclusive range [ostart, ofinish]
+
+  let so = if ostart < 0: (len(input) + ostart) else: ostart
+  let eo = if ofinish < 0: (len(input) + ofinish) else: ofinish
+  let length = (eo - so + 1) * sizeof(A)
+  # We don't need to check `so` because compiler will do it for `data[so]`.
+  if eo >= len(input):
+    return(BufferOverrun)
+  if len(input) == 0:
+    return(EmptyMessage)
+  let dsize = eciesDecryptedLength(length)
+  if len(output) * sizeof(B) < dsize:
+    return(BufferOverrun)
+  outlen = dsize
+  result = eciesDecrypt(cast[ptr byte](unsafeAddr input[so]), addr output[0],
+                        length, dsize, seckey)
+
+proc eciesDecrypt*[A, B, C](input: openarray[A],
+                            seckey: PrivateKey,
+                            output: var openarray[B],
+                            outlen: var int,
+                            shmac: openarray[C],
+                            ostart: int = 0,
+                            ofinish: int = -1): EciesStatus =
+  ## Decrypt data with ECIES method using given private key `seckey`.
+  ##
+  ## `input`   - [INPUT] input data
+  ## `seckey`  - [INPUT] Ecc secp256k1 private key
+  ## `output`  - [OUTPUT] output data
+  ## `outlen`  - [OUTPUT] output data size
+  ## `shmac`   - additional mac data
+  ## `ostart`  - starting index in `data` (default = -1, data[0])
+  ## `ofinish` - ending index in `data` (default = -1, data[len(data) - 1])
+  ##
+  ## Decryption is done on `data` with inclusive range [ostart, ofinish]
+
+  let so = if ostart < 0: (len(input) + ostart) else: ostart
+  let eo = if ofinish < 0: (len(input) + ofinish) else: ofinish
+  let length = (eo - so + 1) * sizeof(A)
+  # We don't need to check `so` because compiler will do it for `data[so]`.
+  if eo >= len(input):
+    return(BufferOverrun)
+  if len(input) == 0:
+    return(EmptyMessage)
+  let dsize = eciesDecryptedLength(length)
+  if len(output) * sizeof(B) < dsize:
+    return(BufferOverrun)
+  outlen = dsize
+  result = eciesDecrypt(cast[ptr byte](unsafeAddr input[so]), addr output[0],
+                        length, dsize, seckey,
+                        cast[ptr byte](unsafeAddr shmac[0]),
+                        len(shmac) * sizeof(C))
+
+when isMainModule:
+  proc compare[A, B](x: openarray[A], y: openarray[B], s: int = 0): bool =
+    result = true
+    assert(s >= 0)
+    var size = if s == 0: min(len(x), len(y)) else: min(s, min(len(x), len(y)))
+    for i in 0..(size - 1):
+      if x[i] != cast[A](y[i]):
+        result = false
+        break
+
+  block:
+    # KDF test
+    # Copied from https://github.com/ethereum/pydevp2p/blob/develop/devp2p/tests/test_ecies.py#L53
+    let m0 = "961c065873443014e0371f1ed656c586c6730bf927415757f389d92acf8268df"
+    let c0 = "4050c52e6d9c08755e5a818ac66fabe478b825b1836fd5efc4d44e40d04dabcc"
+    var m = fromHex(stripSpaces(m0))
+    var c = fromHex(stripSpaces(c0))
+    var k = kdf(m)
+    doAssert(compare(k, c))
+
+  block:
+    # HMAC-SHA256 test
+    # https://github.com/ethereum/py-evm/blob/master/tests/p2p/test_ecies.py#L64-L76
+    const keys = [
+      "07a4b6dfa06369a570f2dcba2f11a18f",
+      "af6623e52208c596e17c72cea6f1cb09"
+    ]
+    const datas = ["4dcb92ed4fc67fe86832", "3461282bcedace970df2"]
+    const expects = [
+      "c90b62b1a673b47df8e395e671a68bfa68070d6e2ef039598bb829398b89b9a9",
+      "b3ce623bce08d5793677ba9441b22bb34d3e8a7de964206d26589df3e8eb5183"
+    ]
+    for i in 0..1:
+      var k = fromHex(stripSpaces(keys[i]))
+      var m = fromHex(stripSpaces(datas[i]))
+      var digest = sha256.hmac(k, m).data
+      var check = fromHex(stripSpaces(expects[i]))
+      doAssert(compare(digest, check))
+
+  block:
+    # ECIES encryption
+    var m = "Hello World!"
+    var encr = newSeq[byte](eciesEncryptedLength(len(m)))
+    var decr = newSeq[byte](len(m))
+    var shmac = [0x13'u8, 0x13'u8]
+    var outlen = 0
+    var s = newPrivateKey()
+    var p = s.getPublicKey()
+    # Without additional mac data
+    doAssert(eciesEncrypt(m, p, encr, outlen) == Success)
+    doAssert(eciesDecrypt(encr, s, decr, outlen) == Success)
+    doAssert(outlen == len(m))
+    doAssert(equalMem(addr m[0], addr decr[0], outlen))
+    # With additional mac data
+    doAssert(eciesEncrypt(m, p, encr, outlen, shmac) == Success)
+    doAssert(eciesDecrypt(encr, s, decr, outlen, shmac) == Success)
+    doAssert(outlen == len(m))
+    doAssert(equalMem(addr m[0], addr decr[0], outlen))
+
+  block:
+    # ECIES
+    # https://github.com/ethereum/py-evm/blob/master/tests/p2p/test_ecies.py#L43
+    # https://github.com/ethereum/cpp-ethereum/blob/develop/test/unittests/libp2p/rlpx.cpp#L187
+    const secretKeys = [
+      "c45f950382d542169ea207959ee0220ec1491755abe405cd7498d6b16adb6df8",
+      "5e173f6ac3c669587538e7727cf19b782a4f2fda07c1eaa662c593e5e85e3051"
+    ]
+    const cipherText = [
+      """04a0274c5951e32132e7f088c9bdfdc76c9d91f0dc6078e848f8e3361193dbdc
+         43b94351ea3d89e4ff33ddcefbc80070498824857f499656c4f79bbd97b6c51a
+         514251d69fd1785ef8764bd1d262a883f780964cce6a14ff206daf1206aa073a
+         2d35ce2697ebf3514225bef186631b2fd2316a4b7bcdefec8d75a1025ba2c540
+         4a34e7795e1dd4bc01c6113ece07b0df13b69d3ba654a36e35e69ff9d482d88d
+         2f0228e7d96fe11dccbb465a1831c7d4ad3a026924b182fc2bdfe016a6944312
+         021da5cc459713b13b86a686cf34d6fe6615020e4acf26bf0d5b7579ba813e77
+         23eb95b3cef9942f01a58bd61baee7c9bdd438956b426a4ffe238e61746a8c93
+         d5e10680617c82e48d706ac4953f5e1c4c4f7d013c87d34a06626f498f34576d
+         c017fdd3d581e83cfd26cf125b6d2bda1f1d56""",
+      """049934a7b2d7f9af8fd9db941d9da281ac9381b5740e1f64f7092f3588d4f87f
+         5ce55191a6653e5e80c1c5dd538169aa123e70dc6ffc5af1827e546c0e958e42
+         dad355bcc1fcb9cdf2cf47ff524d2ad98cbf275e661bf4cf00960e74b5956b79
+         9771334f426df007350b46049adb21a6e78ab1408d5e6ccde6fb5e69f0f4c92b
+         b9c725c02f99fa72b9cdc8dd53cff089e0e73317f61cc5abf6152513cb7d833f
+         09d2851603919bf0fbe44d79a09245c6e8338eb502083dc84b846f2fee1cc310
+         d2cc8b1b9334728f97220bb799376233e113"""
+    ]
+    const expectText = [
+      """884c36f7ae6b406637c1f61b2f57e1d2cab813d24c6559aaf843c3f48962f32f
+         46662c066d39669b7b2e3ba14781477417600e7728399278b1b5d801a519aa57
+         0034fdb5419558137e0d44cd13d319afe5629eeccb47fd9dfe55cc6089426e46
+         cc762dd8a0636e07a54b31169eba0c7a20a1ac1ef68596f1f283b5c676bae406
+         4abfcce24799d09f67e392632d3ffdc12e3d6430dcb0ea19c318343ffa7aae74
+         d4cd26fecb93657d1cd9e9eaf4f8be720b56dd1d39f190c4e1c6b7ec66f077bb
+         1100""",
+      """802b052f8b066640bba94a4fc39d63815c377fced6fcb84d27f791c9921ddf3e
+         9bf0108e298f490812847109cbd778fae393e80323fd643209841a3b7f110397
+         f37ec61d84cea03dcc5e8385db93248584e8af4b4d1c832d8c7453c0089687a7
+         00"""
+    ]
+    var data: array[1024, byte]
+    var outlen = 0
+    for i in 0..1:
+      var s = secretKeys[i].getPrivateKey()
+      var cipher = fromHex(stripSpaces(cipherText[i]))
+      var check = fromHex(stripSpaces(expectText[i]))
+      var r = eciesDecrypt(cipher, s, data, outlen)
+      doAssert(r == Success, $r)
+      doAssert(outlen == len(check))
+      doAssert(compare(data, check))
+
+  block:
+    # ECIES
+    # https://github.com/ethereum/cpp-ethereum/blob/develop/test/unittests/libp2p/rlpx.cpp#L432-L459
+    const secretKeys = [
+      "57baf2c62005ddec64c357d96183ebc90bf9100583280e848aa31d683cad73cb",
+      "472413e97f1fd58d84e28a559479e6b6902d2e8a0cee672ef38a3a35d263886b",
+      "472413e97f1fd58d84e28a559479e6b6902d2e8a0cee672ef38a3a35d263886b",
+      "472413e97f1fd58d84e28a559479e6b6902d2e8a0cee672ef38a3a35d263886b"
+    ]
+    const cipherData = [
+      """04ff2c874d0a47917c84eea0b2a4141ca95233720b5c70f81a8415bae1dc7b74
+         6b61df7558811c1d6054333907333ef9bb0cc2fbf8b34abb9730d14e0140f455
+         3f4b15d705120af46cf653a1dc5b95b312cf8444714f95a4f7a0425b67fc064d
+         18f4d0a528761565ca02d97faffdac23de10""",
+      """046f647e1bd8a5cd1446d31513bac233e18bdc28ec0e59d46de453137a725995
+         33f1e97c98154343420d5f16e171e5107999a7c7f1a6e26f57bcb0d2280655d0
+         8fb148d36f1d4b28642d3bb4a136f0e33e3dd2e3cffe4b45a03fb7c5b5ea5e65
+         617250fdc89e1a315563c20504b9d3a72555""",
+      """0443c24d6ccef3ad095140760bb143078b3880557a06392f17c5e368502d7953
+         2bc18903d59ced4bbe858e870610ab0d5f8b7963dd5c9c4cf81128d10efd7c7a
+         a80091563c273e996578403694673581829e25a865191bdc9954db14285b56eb
+         0043b6288172e0d003c10f42fe413222e273d1d4340c38a2d8344d7aadcbc846
+         ee""",
+      """04c4e40c86bb5324e017e598c6d48c19362ae527af8ab21b077284a4656c8735
+         e62d73fb3d740acefbec30ca4c024739a1fcdff69ecaf03301eebf156eb5f17c
+         ca6f9d7a7e214a1f3f6e34d1ee0ec00ce0ef7d2b242fbfec0f276e17941f9f1b
+         fbe26de10a15a6fac3cda039904ddd1d7e06e7b96b4878f61860e47f0b84c8ce
+         b64f6a900ff23844f4359ae49b44154980a626d3c73226c19e"""
+    ]
+    const expectData = [
+      "a", "a", "aaaaaaaaaaaaaaaa", "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa"
+    ]
+    var data: array[1024, byte]
+    var outlen = 0
+    for i in 0..3:
+      var s = secretKeys[i].getPrivateKey()
+      var cipher = fromHex(stripSpaces(cipherData[i]))
+      doAssert(eciesDecrypt(cipher, s, data, outlen) == Success)
+      doAssert(outlen == len(expectData[i]))
+      doAssert(compare(data, expectData[i]))

ethp2p/hexdump.nim

@@ -0,0 +1,92 @@
+# 
+# Copyright (c) 2016 Eugene Kabanov <ka@hardcore.kiev.ua>
+#
+# Permission is hereby granted, free of charge, to any person obtaining a copy
+# of this software and associated documentation files (the "Software"), to deal
+# in the Software without restriction, including without limitation the rights
+# to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
+# copies of the Software, and to permit persons to whom the Software is
+# furnished to do so, subject to the following conditions:
+#
+# The above copyright notice and this permission notice shall be included in all
+# copies or substantial portions of the Software.
+
+# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
+# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
+# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
+# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
+# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
+# OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
+# SOFTWARE.
+#
+
+from strutils import toHex, repeat
+
+proc dumpHex*(pbytes: pointer, nbytes: int, items = 1, ascii = true): string =
+  ## Return hexadecimal memory dump representation pointed by ``p``.
+  ## ``nbytes`` - number of bytes to show
+  ## ``items``  - number of bytes in group (supported ``items`` count is
+  ##  1, 2, 4, 8)
+  ## ``ascii``  - if ``true`` show ASCII representation of memory dump.
+  result = ""
+  let hexSize = items * 2
+  var i = 0
+  var slider = pbytes
+  var asciiText = ""
+  while i < nbytes:
+    if i %% 16 == 0:
+      result = result & toHex(cast[BiggestInt](slider),
+                              sizeof(BiggestInt) * 2) & ":  "
+    var k = 0
+    while k < items:
+      var ch = cast[ptr char](cast[uint](slider) + k.uint)[]
+      if ord(ch) > 31 and ord(ch) < 127: asciiText &= ch else: asciiText &= "."
+      inc(k)
+    case items:
+    of 1:
+      result = result & toHex(cast[BiggestInt](cast[ptr uint8](slider)[]),
+                              hexSize)
+    of 2:
+      result = result & toHex(cast[BiggestInt](cast[ptr uint16](slider)[]),
+                              hexSize)
+    of 4:
+      result = result & toHex(cast[BiggestInt](cast[ptr uint32](slider)[]),
+                              hexSize)
+    of 8:
+      result = result & toHex(cast[BiggestInt](cast[ptr uint64](slider)[]),
+                              hexSize)
+    else:
+      raise newException(ValueError, "Wrong items size!")
+    result = result & " "
+    slider = cast[pointer](cast[uint](slider) + items.uint)
+    i = i + items
+    if i %% 16 == 0:
+      result = result & " " & asciiText
+      asciiText.setLen(0)
+      result = result & "\n"
+
+  if i %% 16 != 0:
+    var spacesCount = ((16 - (i %% 16)) div items) * (hexSize + 1) + 1
+    result = result & repeat(' ', spacesCount)
+    result = result & asciiText
+  result = result & "\n"
+
+proc dumpHex*[T](v: openarray[T], items: int = 0, ascii = true): string =
+  ## Return hexadecimal memory dump representation of openarray[T] ``v``.
+  ## ``items``  - number of bytes in group (supported ``items`` count is
+  ##  0, 1, 2, 4, 8). If ``items`` is ``0`` group size will depend on
+  ## ``sizeof(T)``.
+  ## ``ascii``  - if ``true`` show ASCII representation of memory dump.
+  var i = 0
+  if items == 0:
+    when sizeof(T) == 2:
+      i = 2
+    elif sizeof(T) == 4:
+      i = 4
+    elif sizeof(T) == 8:
+      i = 8
+    else:
+      i = 1
+  else:
+    i = items
+  result = dumpHex(unsafeAddr v[0], sizeof(T) * len(v), i, ascii)

tests/config.nims

@@ -0,0 +1 @@
+switch("path", "$projectDir/..")

tests/testauth.nim

@@ -0,0 +1,420 @@
+#
+#                 Ethereum P2P
+#              (c) Copyright 2018
+#       Status Research & Development GmbH
+#
+#    See the file "LICENSE", included in this
+#    distribution, for details about the copyright.
+#
+
+import unittest
+import ethp2p/ecc, ethp2p/auth, nimcrypto/utils
+
+# This was generated by `print` actual auth message generated by
+# https://github.com/ethereum/py-evm/blob/master/tests/p2p/test_auth.py
+const pyevmAuth = """
+  22034ad2e7545e2b0bf02ecb1e40db478dfbbf7aeecc834aec2523eb2b7e74ee
+  77ba40c70a83bfe9f2ab91f0131546dcf92c3ee8282d9907fee093017fd0302d
+  0034fdb5419558137e0d44cd13d319afe5629eeccb47fd9dfe55cc6089426e46
+  cc762dd8a0636e07a54b31169eba0c7a20a1ac1ef68596f1f283b5c676bae406
+  4abfcce24799d09f67e392632d3ffdc12e3d6430dcb0ea19c318343ffa7aae74
+  d4cd26fecb93657d1cd9e9eaf4f8be720b56dd1d39f190c4e1c6b7ec66f077bb
+  1100"""
+
+# This data comes from https://gist.github.com/fjl/3a78780d17c755d22df2
+const data = [
+  ("initiator_private_key",
+   "5e173f6ac3c669587538e7727cf19b782a4f2fda07c1eaa662c593e5e85e3051"),
+  ("receiver_private_key",
+   "c45f950382d542169ea207959ee0220ec1491755abe405cd7498d6b16adb6df8"),
+  ("initiator_ephemeral_private_key",
+   "19c2185f4f40634926ebed3af09070ca9e029f2edd5fae6253074896205f5f6c"),
+  ("receiver_ephemeral_private_key",
+   "d25688cf0ab10afa1a0e2dba7853ed5f1e5bf1c631757ed4e103b593ff3f5620"),
+  ("auth_plaintext",
+   """884c36f7ae6b406637c1f61b2f57e1d2cab813d24c6559aaf843c3f48962f32f
+      46662c066d39669b7b2e3ba14781477417600e7728399278b1b5d801a519aa57
+      0034fdb5419558137e0d44cd13d319afe5629eeccb47fd9dfe55cc6089426e46
+      cc762dd8a0636e07a54b31169eba0c7a20a1ac1ef68596f1f283b5c676bae406
+      4abfcce24799d09f67e392632d3ffdc12e3d6430dcb0ea19c318343ffa7aae74
+      d4cd26fecb93657d1cd9e9eaf4f8be720b56dd1d39f190c4e1c6b7ec66f077bb
+      1100"""),
+  ("authresp_plaintext",
+   """802b052f8b066640bba94a4fc39d63815c377fced6fcb84d27f791c9921ddf3e
+      9bf0108e298f490812847109cbd778fae393e80323fd643209841a3b7f110397
+      f37ec61d84cea03dcc5e8385db93248584e8af4b4d1c832d8c7453c0089687a7
+      00"""),
+  ("auth_ciphertext",
+   """04a0274c5951e32132e7f088c9bdfdc76c9d91f0dc6078e848f8e3361193dbdc
+      43b94351ea3d89e4ff33ddcefbc80070498824857f499656c4f79bbd97b6c51a
+      514251d69fd1785ef8764bd1d262a883f780964cce6a14ff206daf1206aa073a
+      2d35ce2697ebf3514225bef186631b2fd2316a4b7bcdefec8d75a1025ba2c540
+      4a34e7795e1dd4bc01c6113ece07b0df13b69d3ba654a36e35e69ff9d482d88d
+      2f0228e7d96fe11dccbb465a1831c7d4ad3a026924b182fc2bdfe016a6944312
+      021da5cc459713b13b86a686cf34d6fe6615020e4acf26bf0d5b7579ba813e77
+      23eb95b3cef9942f01a58bd61baee7c9bdd438956b426a4ffe238e61746a8c93
+      d5e10680617c82e48d706ac4953f5e1c4c4f7d013c87d34a06626f498f34576d
+      c017fdd3d581e83cfd26cf125b6d2bda1f1d56"""),
+  ("authresp_ciphertext",
+   """049934a7b2d7f9af8fd9db941d9da281ac9381b5740e1f64f7092f3588d4f87f
+      5ce55191a6653e5e80c1c5dd538169aa123e70dc6ffc5af1827e546c0e958e42
+      dad355bcc1fcb9cdf2cf47ff524d2ad98cbf275e661bf4cf00960e74b5956b79
+      9771334f426df007350b46049adb21a6e78ab1408d5e6ccde6fb5e69f0f4c92b
+      b9c725c02f99fa72b9cdc8dd53cff089e0e73317f61cc5abf6152513cb7d833f
+      09d2851603919bf0fbe44d79a09245c6e8338eb502083dc84b846f2fee1cc310
+      d2cc8b1b9334728f97220bb799376233e113"""),
+  ("ecdhe_shared_secret",
+   "e3f407f83fc012470c26a93fdff534100f2c6f736439ce0ca90e9914f7d1c381"),
+  ("initiator_nonce",
+   "cd26fecb93657d1cd9e9eaf4f8be720b56dd1d39f190c4e1c6b7ec66f077bb11"),
+  ("receiver_nonce",
+   "f37ec61d84cea03dcc5e8385db93248584e8af4b4d1c832d8c7453c0089687a7"),
+  ("aes_secret",
+   "c0458fa97a5230830e05f4f20b7c755c1d4e54b1ce5cf43260bb191eef4e418d"),
+  ("mac_secret",
+   "48c938884d5067a1598272fcddaa4b833cd5e7d92e8228c0ecdfabbe68aef7f1"),
+  ("token",
+   "3f9ec2592d1554852b1f54d228f042ed0a9310ea86d038dc2b401ba8cd7fdac4"),
+  ("initial_egress_MAC",
+   "09771e93b1a6109e97074cbe2d2b0cf3d3878efafe68f53c41bb60c0ec49097e"),
+  ("initial_ingress_MAC",
+   "75823d96e23136c89666ee025fb21a432be906512b3dd4a3049e898adb433847"),
+  ("initiator_hello_packet",
+   """6ef23fcf1cec7312df623f9ae701e63b550cdb8517fefd8dd398fc2acd1d935e
+      6e0434a2b96769078477637347b7b01924fff9ff1c06df2f804df3b0402bbb9f
+      87365b3c6856b45e1e2b6470986813c3816a71bff9d69dd297a5dbd935ab578f
+      6e5d7e93e4506a44f307c332d95e8a4b102585fd8ef9fc9e3e055537a5cec2e9"""),
+  ("receiver_hello_packet",
+   """6ef23fcf1cec7312df623f9ae701e63be36a1cdd1b19179146019984f3625d4a
+      6e0434a2b96769050577657247b7b02bc6c314470eca7e3ef650b98c83e9d7dd
+      4830b3f718ff562349aead2530a8d28a8484604f92e5fced2c6183f304344ab0
+      e7c301a0c05559f4c25db65e36820b4b909a226171a60ac6cb7beea09376d6d8""")
+]
+
+# Thies test vectors was copied from EIP8 specfication
+# https://github.com/ethereum/EIPs/blob/master/EIPS/eip-8.md
+const eip8data = [
+  ("initiator_private_key",
+   "49a7b37aa6f6645917e7b807e9d1c00d4fa71f18343b0d4122a4d2df64dd6fee"),
+  ("receiver_private_key",
+   "b71c71a67e1177ad4e901695e1b4b9ee17ae16c6668d313eac2f96dbcda3f291"),
+  ("initiator_ephemeral_private_key",
+   "869d6ecf5211f1cc60418a13b9d870b22959d0c16f02bec714c960dd2298a32d"),
+  ("receiver_ephemeral_private_key",
+   "e238eb8e04fee6511ab04c6dd3c89ce097b11f25d584863ac2b6d5b35b1847e4"),
+  ("initiator_nonce",
+   "7e968bba13b6c50e2c4cd7f241cc0d64d1ac25c7f5952df231ac6a2bda8ee5d6"),
+  ("receiver_nonce",
+   "559aead08264d5795d3909718cdd05abd49572e84fe55590eef31a88a08fdffd"),
+  ("auth_ciphertext_v4",
+   """048ca79ad18e4b0659fab4853fe5bc58eb83992980f4c9cc147d2aa31532efd29
+      a3d3dc6a3d89eaf913150cfc777ce0ce4af2758bf4810235f6e6ceccfee1acc6b
+      22c005e9e3a49d6448610a58e98744ba3ac0399e82692d67c1f58849050b3024e
+      21a52c9d3b01d871ff5f210817912773e610443a9ef142e91cdba0bd77b5fdf07
+      69b05671fc35f83d83e4d3b0b000c6b2a1b1bba89e0fc51bf4e460df3105c444f
+      14be226458940d6061c296350937ffd5e3acaceeaaefd3c6f74be8e23e0f45163
+      cc7ebd76220f0128410fd05250273156d548a414444ae2f7dea4dfca2d43c057a
+      db701a715bf59f6fb66b2d1d20f2c703f851cbf5ac47396d9ca65b6260bd141ac
+      4d53e2de585a73d1750780db4c9ee4cd4d225173a4592ee77e2bd94d0be3691f3
+      b406f9bba9b591fc63facc016bfa8"""),
+  ("auth_ciphertext_eip8",
+   """01b304ab7578555167be8154d5cc456f567d5ba302662433674222360f08d5f15
+      34499d3678b513b0fca474f3a514b18e75683032eb63fccb16c156dc6eb2c0b15
+      93f0d84ac74f6e475f1b8d56116b849634a8c458705bf83a626ea0384d4d7341a
+      ae591fae42ce6bd5c850bfe0b999a694a49bbbaf3ef6cda61110601d3b4c02ab6
+      c30437257a6e0117792631a4b47c1d52fc0f8f89caadeb7d02770bf999cc147d2
+      df3b62e1ffb2c9d8c125a3984865356266bca11ce7d3a688663a51d82defaa8aa
+      d69da39ab6d5470e81ec5f2a7a47fb865ff7cca21516f9299a07b1bc63ba56c7a
+      1a892112841ca44b6e0034dee70c9adabc15d76a54f443593fafdc3b27af80597
+      03f88928e199cb122362a4b35f62386da7caad09c001edaeb5f8a06d2b26fb6cb
+      93c52a9fca51853b68193916982358fe1e5369e249875bb8d0d0ec36f917bc5e1
+      eafd5896d46bd61ff23f1a863a8a8dcd54c7b109b771c8e61ec9c8908c733c026
+      3440e2aa067241aaa433f0bb053c7b31a838504b148f570c0ad62837129e54767
+      8c5190341e4f1693956c3bf7678318e2d5b5340c9e488eefea198576344afbdf6
+      6db5f51204a6961a63ce072c8926c"""),
+  ("auth_ciphertext_eip8_3f",
+   """01b8044c6c312173685d1edd268aa95e1d495474c6959bcdd10067ba4c9013df9
+      e40ff45f5bfd6f72471f93a91b493f8e00abc4b80f682973de715d77ba3a005a2
+      42eb859f9a211d93a347fa64b597bf280a6b88e26299cf263b01b8dfdb7122784
+      64fd1c25840b995e84d367d743f66c0e54a586725b7bbf12acca27170ae3283c1
+      073adda4b6d79f27656993aefccf16e0d0409fe07db2dc398a1b7e8ee93bcd181
+      485fd332f381d6a050fba4c7641a5112ac1b0b61168d20f01b479e19adf7fdbfa
+      0905f63352bfc7e23cf3357657455119d879c78d3cf8c8c06375f3f7d4861aa02
+      a122467e069acaf513025ff196641f6d2810ce493f51bee9c966b15c504350535
+      0392b57645385a18c78f14669cc4d960446c17571b7c5d725021babbcd786957f
+      3d17089c084907bda22c2b2675b4378b114c601d858802a55345a15116bc61da4
+      193996187ed70d16730e9ae6b3bb8787ebcaea1871d850997ddc08b4f4ea668fb
+      f37407ac044b55be0908ecb94d4ed172ece66fd31bfdadf2b97a8bc690163ee11
+      f5b575a4b44e36e2bfb2f0fce91676fd64c7773bac6a003f481fddd0bae0a1f31
+      aa27504e2a533af4cef3b623f4791b2cca6d490"""),
+  ("authack_ciphertext_v4",
+   """049f8abcfa9c0dc65b982e98af921bc0ba6e4243169348a236abe9df5f93aa69d
+      99cadddaa387662b0ff2c08e9006d5a11a278b1b3331e5aaabf0a32f01281b6f4
+      ede0e09a2d5f585b26513cb794d9635a57563921c04a9090b4f14ee42be1a5461
+      049af4ea7a7f49bf4c97a352d39c8d02ee4acc416388c1c66cec761d2bc1c72da
+      6ba143477f049c9d2dde846c252c111b904f630ac98e51609b3b1f58168ddca65
+      05b7196532e5f85b259a20c45e1979491683fee108e9660edbf38f3add489ae73
+      e3dda2c71bd1497113d5c755e942d1"""),
+  ("authack_ciphertext_eip8",
+   """01ea0451958701280a56482929d3b0757da8f7fbe5286784beead59d95089c217
+      c9b917788989470b0e330cc6e4fb383c0340ed85fab836ec9fb8a49672712aeab
+      bdfd1e837c1ff4cace34311cd7f4de05d59279e3524ab26ef753a0095637ac88f
+      2b499b9914b5f64e143eae548a1066e14cd2f4bd7f814c4652f11b254f8a2d019
+      1e2f5546fae6055694aed14d906df79ad3b407d94692694e259191cde171ad542
+      fc588fa2b7333313d82a9f887332f1dfc36cea03f831cb9a23fea05b33deb999e
+      85489e645f6aab1872475d488d7bd6c7c120caf28dbfc5d6833888155ed69d34d
+      bdc39c1f299be1057810f34fbe754d021bfca14dc989753d61c413d261934e1a9
+      c67ee060a25eefb54e81a4d14baff922180c395d3f998d70f46f6b58306f96962
+      7ae364497e73fc27f6d17ae45a413d322cb8814276be6ddd13b885b201b943213
+      656cde498fa0e9ddc8e0b8f8a53824fbd82254f3e2c17e8eaea009c38b4aa0a3f
+      306e8797db43c25d68e86f262e564086f59a2fc60511c42abfb3057c247a8a8fe
+      4fb3ccbadde17514b7ac8000cdb6a912778426260c47f38919a91f25f4b5ffb45
+      5d6aaaf150f7e5529c100ce62d6d92826a71778d809bdf60232ae21ce8a437eca
+      8223f45ac37f6487452ce626f549b3b5fdee26afd2072e4bc75833c2464c80524
+      6155289f4"""),
+  ("authack_ciphertext_eip8_3f",
+   """01f004076e58aae772bb101ab1a8e64e01ee96e64857ce82b1113817c6cdd52c0
+      9d26f7b90981cd7ae835aeac72e1573b8a0225dd56d157a010846d888dac7464b
+      af53f2ad4e3d584531fa203658fab03a06c9fd5e35737e417bc28c1cbf5e5dfc6
+      66de7090f69c3b29754725f84f75382891c561040ea1ddc0d8f381ed1b9d0d4ad
+      2a0ec021421d847820d6fa0ba66eaf58175f1b235e851c7e2124069fbc202888d
+      db3ac4d56bcbd1b9b7eab59e78f2e2d400905050f4a92dec1c4bdf797b3fc9b2f
+      8e84a482f3d800386186712dae00d5c386ec9387a5e9c9a1aca5a573ca91082c7
+      d68421f388e79127a5177d4f8590237364fd348c9611fa39f78dcdceee3f390f0
+      7991b7b47e1daa3ebcb6ccc9607811cb17ce51f1c8c2c5098dbdd28fca547b3f5
+      8c01a424ac05f869f49c6a34672ea2cbbc558428aa1fe48bbfd61158b1b735a65
+      d99f21e70dbc020bfdface9f724a0d1fb5895db971cc81aa7608baa0920abb0a5
+      65c9c436e2fd13323428296c86385f2384e408a31e104670df0791d93e743a3a5
+      194ee6b076fb6323ca593011b7348c16cf58f66b9633906ba54a2ee803187344b
+      394f75dd2e663a57b956cb830dd7a908d4f39a2336a61ef9fda549180d4ccde21
+      514d117b6c6fd07a9102b5efe710a32af4eeacae2cb3b1dec035b9593b48b9d3c
+      a4c13d245d5f04169b0b1"""),
+  ("auth2ack2_aes_secret",
+   "80e8632c05fed6fc2a13b0f8d31a3cf645366239170ea067065aba8e28bac487"),
+  ("auth2ack2_mac_secret",
+   "2ea74ec5dae199227dff1af715362700e989d889d7a493cb0639691efb8e5f98"),
+  ("auth2ack2_ingress_message", "foo"),
+  ("auth2ack2_ingress_mac",
+   "0c7ec6340062cc46f5e9f1e3cf86f8c8c403c5a0964f5df0ebd34a75ddc86db5")
+]
+
+proc testValue(s: string): string =
+  for item in data:
+    if item[0] == s:
+      result = item[1]
+      break
+
+proc testE8Value(s: string): string =
+  for item in eip8data:
+    if item[0] == s:
+      result = item[1]
+      break
+
+suite "Ethereum P2P handshake test suite":
+
+  block:
+    var initiator: Handshake
+    var receiver: Handshake
+    var m0, dm0: PlainAuthMessage
+    var em0: AuthMessage
+
+    initiator = newHandshake({Initiator})
+    receiver = newHandshake({Responder})
+    initiator.host.seckey = getPrivateKey(testValue("initiator_private_key"))
+    initiator.host.pubkey = initiator.host.seckey.getPublicKey()
+    var epki = testValue("initiator_ephemeral_private_key")
+    initiator.ephemeral.seckey = getPrivateKey(epki)
+    initiator.ephemeral.pubkey = initiator.ephemeral.seckey.getPublicKey()
+    receiver.host.seckey = getPrivateKey(testValue("receiver_private_key"))
+    receiver.host.pubkey = receiver.host.seckey.getPublicKey()
+    var epkr = testValue("receiver_ephemeral_private_key")
+    receiver.ephemeral.seckey = getPrivateKey(epkr)
+    receiver.ephemeral.pubkey = receiver.ephemeral.seckey.getPublicKey()
+    var n0 = fromHex(stripSpaces(testValue("initiator_nonce")))
+    initiator.initiatorNonce[0..^1] = n0[0..^1]
+    var n1 = fromHex(stripSpaces(testValue("receiver_nonce")))
+    receiver.responderNonce[0..^1] = n1[0..^1]
+
+    test "Create plain auth message":
+      check authMessage(initiator, receiver.host.pubkey,
+                        m0) == AuthStatus.Success
+      var m1 = fromHex(stripSpaces(testValue("auth_plaintext")))
+      var m2 = fromHex(stripSpaces(pyevmAuth))
+      check:
+        m0[65..^1] == m1[65..^1]
+        m0[0..^1] == m2[0..^1]
+
+    test "Auth message encrypt/decrypt":
+      # Check that encrypting and decrypting the auth_init gets us the orig msg.
+      check:
+        encryptAuthMessage(m0, em0, receiver.host.pubkey) == AuthStatus.Success
+        decryptAuthMessage(em0, dm0, receiver.host.seckey) == AuthStatus.Success
+        m0[0..^1] == dm0[0..^1]
+
+    test "Auth message decode":
+      # Check that the responder correctly decodes the auth msg.
+      check receiver.decodeAuthMessage(em0) == AuthStatus.Success
+      let remoteEPubkey0 = initiator.ephemeral.pubkey.data
+      let remoteHPubkey0 = initiator.host.pubkey.data
+      check:
+        receiver.initiatorNonce[0..^1] == n0[0..^1]
+        receiver.remoteEPubkey.data[0..^1] == remoteEPubkey0[0..^1]
+        receiver.remoteHPubkey.data[0..^1] == remoteHPubkey0[0..^1]
+
+    var k0: PlainAuthAckMessage
+    var ek0: AuthAckMessage
+    
+    test "Auth ACK expectation":
+      # Check that the auth_ack msg generated by the responder is what we
+      # expect.
+      check receiver.authAckMessage(k0) == AuthStatus.Success
+      var ac0 = fromHex(stripSpaces(testValue("authresp_plaintext")))
+      check:
+        k0[0..^1] == ac0[0..^1]
+        receiver.initiatorNonce[0..^1] == n0[0..^1]
+        encryptAuthAckMessage(k0, ek0,
+                              receiver.remoteHPubkey) == AuthStatus.Success
+
+    test "Initiator decode Auth ACK message":
+      # Check if initiator correctly decodes the auth ack msg.
+      check initiator.decodeAckMessage(ek0) == AuthStatus.Success
+      let remoteEPubkey1 = receiver.ephemeral.pubkey.data
+      let remoteHPubkey1 = receiver.host.pubkey.data
+      check:
+        initiator.remoteEPubkey.data[0..^1] == remoteEPubkey1[0..^1]
+        initiator.remoteHPubkey.data[0..^1] == remoteHPubkey1[0..^1]
+        initiator.responderNonce[0..^1] == n1[0..^1]
+
+    test "Check derived secrets":
+      # Check that the secrets derived from ephemeral key agreements match
+      # the expected values.
+      var authm = fromHex(stripSpaces(testValue("auth_ciphertext")))
+      var ackm = fromHex(stripSpaces(testValue("authresp_ciphertext")))
+      var taes = fromHex(stripSpaces(testValue("aes_secret")))
+      var tmac = fromHex(stripSpaces(testValue("mac_secret")))
+      var temac = fromHex(stripSpaces(testValue("initial_egress_MAC")))
+      var timac = fromHex(stripSpaces(testValue("initial_ingress_MAC")))
+
+      var csecInitiator: ConnectionSecret
+      var csecResponder: ConnectionSecret
+
+      check:
+        initiator.getSecrets(addr authm[0], len(authm), addr ackm[0],
+                             len(ackm), csecInitiator) == AuthStatus.Success
+        receiver.getSecrets(addr authm[0], len(authm), addr ackm[0],
+                            len(ackm), csecResponder) == AuthStatus.Success
+        csecInitiator.aesKey == csecResponder.aesKey
+        csecInitiator.macKey == csecResponder.macKey
+        taes[0..^1] == csecInitiator.aesKey[0..^1]
+        tmac[0..^1] == csecInitiator.macKey[0..^1]
+        csecInitiator.egressMac[0..^1] == temac[0..^1]
+        csecInitiator.ingressMac[0..^1] == timac[0..^1]
+        csecResponder.egressMac[0..^1] == timac[0..^1]
+        csecResponder.ingressMac[0..^1] == temac[0..^1]
+
+  block:
+    proc newTestHandshake(flags: set[HandshakeFlag]): Handshake =
+      result = newHandshake(flags)
+      if Initiator in flags:
+        result.host.seckey = getPrivateKey(testE8Value("initiator_private_key"))
+        result.host.pubkey = result.host.seckey.getPublicKey()
+        let esec = testE8Value("initiator_ephemeral_private_key")
+        result.ephemeral.seckey = getPrivateKey(esec)
+        result.ephemeral.pubkey = result.ephemeral.seckey.getPublicKey()
+        let nonce = fromHex(stripSpaces(testE8Value("initiator_nonce")))
+        result.initiatorNonce[0..(KeyLength - 1)] = nonce[0..(KeyLength - 1)]
+      elif Responder in flags:
+        result.host.seckey = getPrivateKey(testE8Value("receiver_private_key"))
+        result.host.pubkey = result.host.seckey.getPublicKey()
+        let esec = testE8Value("receiver_ephemeral_private_key")
+        result.ephemeral.seckey = getPrivateKey(esec)
+        result.ephemeral.pubkey = result.ephemeral.seckey.getPublicKey()
+        let nonce = fromHex(stripSpaces(testE8Value("receiver_nonce")))
+        result.responderNonce[0..(KeyLength - 1)] = nonce[0..(KeyLength - 1)]
+
+    test "AUTH/ACK v4 test vectors": # auth/ack v4
+      var initiator = newTestHandshake({Initiator})
+      var receiver = newTestHandshake({Responder})
+
+      # Check that the responder correctly decodes the auth msg.
+      var m0 = fromHex(stripSpaces(testE8Value("auth_ciphertext_v4")))
+      check:
+        receiver.decodeAuthMessage(m0) == AuthStatus.Success
+        receiver.initiatorNonce[0..^1] == initiator.initiatorNonce[0..^1]
+      let remoteEPubkey0 = initiator.ephemeral.pubkey.data
+      check receiver.remoteEPubkey.data[0..^1] == remoteEPubkey0[0..^1]
+      let remoteHPubkey0 = initiator.host.pubkey.data
+      check receiver.remoteHPubkey.data[0..^1] == remoteHPubkey0[0..^1]
+
+      # Check that the initiator correctly decodes the auth ack msg.
+      var m1 = fromHex(stripSpaces(testE8Value("authack_ciphertext_v4")))
+      check initiator.decodeAckMessage(m1) == AuthStatus.Success
+
+      let remoteEPubkey1 = receiver.ephemeral.pubkey.data
+      check:
+        initiator.remoteEPubkey.data[0..^1] == remoteEPubkey1[0..^1]
+        initiator.responderNonce[0..^1] == receiver.responderNonce[0..^1]
+
+    test "AUTH/ACK EIP-8 test vectors":
+      var initiator = newTestHandshake({Initiator})
+      var receiver = newTestHandshake({Responder})
+
+      # Check that the responder correctly decodes the auth msg.
+      var m0 = fromHex(stripSpaces(testE8Value("auth_ciphertext_eip8")))
+      check:
+        receiver.decodeAuthMessage(m0) == AuthStatus.Success
+        receiver.initiatorNonce[0..^1] == initiator.initiatorNonce[0..^1]
+      let remoteEPubkey0 = initiator.ephemeral.pubkey.data
+      check receiver.remoteEPubkey.data[0..^1] == remoteEPubkey0[0..^1]
+      let remoteHPubkey0 = initiator.host.pubkey.data
+      check receiver.remoteHPubkey.data[0..^1] == remoteHPubkey0[0..^1]
+
+      # Check that the initiator correctly decodes the auth ack msg.
+      var m1 = fromHex(stripSpaces(testE8Value("authack_ciphertext_eip8")))
+      check initiator.decodeAckMessage(m1) == AuthStatus.Success
+
+      let remoteEPubkey1 = receiver.ephemeral.pubkey.data
+      check:
+        initiator.remoteEPubkey.data[0..^1] == remoteEPubkey1[0..^1]
+        initiator.responderNonce[0..^1] == receiver.responderNonce[0..^1]
+
+      # Check that the secrets derived from ephemeral key agreements match
+      # the expected values.
+      var taes = fromHex(stripSpaces(testE8Value("auth2ack2_aes_secret")))
+      var tmac = fromHex(stripSpaces(testE8Value("auth2ack2_mac_secret")))
+
+      var csecInitiator: ConnectionSecret
+      var csecResponder: ConnectionSecret
+
+      check:
+        initiator.getSecrets(addr m0[0], len(m0), addr m1[0],
+                             len(m1), csecInitiator) == AuthStatus.Success
+        receiver.getSecrets(addr m0[0], len(m0), addr m1[0],
+                            len(m1), csecResponder) == AuthStatus.Success
+        csecInitiator.aesKey == csecResponder.aesKey
+        csecInitiator.macKey == csecResponder.macKey
+        taes[0..^1] == csecInitiator.aesKey[0..^1]
+        tmac[0..^1] == csecInitiator.macKey[0..^1]
+
+    test "AUTH/ACK EIP-8 with additional fields test vectors":
+      var initiator = newTestHandshake({Initiator})
+      var receiver = newTestHandshake({Responder})
+
+      # Check that the responder correctly decodes the auth msg.
+      var m0 = fromHex(stripSpaces(testE8Value("auth_ciphertext_eip8_3f")))
+      check:
+        receiver.decodeAuthMessage(m0) == AuthStatus.Success
+        receiver.initiatorNonce[0..^1] == initiator.initiatorNonce[0..^1]
+      let remoteEPubkey0 = initiator.ephemeral.pubkey.data
+      check receiver.remoteEPubkey.data[0..^1] == remoteEPubkey0[0..^1]
+      let remoteHPubkey0 = initiator.host.pubkey.data
+      check receiver.remoteHPubkey.data[0..^1] == remoteHPubkey0[0..^1]
+
+      # Check that the initiator correctly decodes the auth ack msg.
+      var m1 = fromHex(stripSpaces(testE8Value("authack_ciphertext_eip8_3f")))
+      check initiator.decodeAckMessage(m1) == AuthStatus.Success
+
+      let remoteEPubkey1 = receiver.ephemeral.pubkey.data
+      check:
+        initiator.remoteEPubkey.data[0..^1] == remoteEPubkey1[0..^1]
+        initiator.responderNonce[0..^1] == receiver.responderNonce[0..^1]

tests/testecc.nim

@@ -0,0 +1,139 @@
+#
+#                 Ethereum P2P
+#              (c) Copyright 2018
+#       Status Research & Development GmbH
+#
+#    See the file "LICENSE", included in this
+#    distribution, for details about the copyright.
+#
+
+import unittest
+import ethp2p/ecc
+import nimcrypto/hash, nimcrypto/keccak, nimcrypto/utils
+
+proc compare(x: openarray[byte], y: openarray[byte]): bool =
+  result = len(x) == len(y)
+  if result:
+    for i in 0..(len(x) - 1):
+      if x[i] != y[i]:
+        result = false
+        break
+
+suite "ECC/ECDSA/ECDHE tests suite":
+  test "ECDHE/py-evm test_ecies.py#L19":
+    # ECDHE test vectors
+    # Copied from
+    # https://github.com/ethereum/py-evm/blob/master/tests/p2p/test_ecies.py#L19
+    const privateKeys = [
+      "332143e9629eedff7d142d741f896258f5a1bfab54dab2121d3ec5000093d74b",
+      "7ebbc6a8358bc76dd73ebc557056702c8cfc34e5cfcd90eb83af0347575fd2ad"
+    ]
+    const publicKeys = [
+      """f0d2b97981bd0d415a843b5dfe8ab77a30300daab3658c578f2340308a2da1a07
+         f0821367332598b6aa4e180a41e92f4ebbae3518da847f0b1c0bbfe20bcf4e1""",
+      """83ede0f19c3c98649265956a4193677b14c338a22de2086a08d84e4446fe37e4e
+         233478259ec90dbeef52f4f6c890f8c38660ec7b61b9d439b8a6d1c323dc025"""
+    ]
+    const sharedSecrets = [
+      "ee1418607c2fcfb57fda40380e885a707f49000a5dda056d828b7d9bd1f29a08",
+      "167ccc13ac5e8a26b131c3446030c60fbfac6aa8e31149d0869f93626a4cdf62"
+    ]
+    var secret: array[KeyLength, byte]
+    for i in 0..1:
+      var s = privateKeys[i].getPrivateKey()
+      var p = publicKeys[i].getPublicKey()
+      let expect = fromHex(stripSpaces(sharedSecrets[i]))
+      check:
+        ecdhAgree(s, p, secret) == Success
+        compare(expect, secret) == true
+
+  test "ECDHE/cpp-ethereum crypto.cpp#L394":
+    # ECDHE test vectors
+    # Copied from https://github.com/ethereum/cpp-ethereum/blob/develop/test/unittests/libdevcrypto/crypto.cpp#L394
+    var expectm = """
+      8ac7e464348b85d9fdfc0a81f2fdc0bbbb8ee5fb3840de6ed60ad9372e718977"""
+    var secret: array[KeyLength, byte]
+    var s = keccak256.digest("ecdhAgree").data
+    var p = s.getPublicKey()
+    let expect = fromHex(stripSpaces(expectm))
+    check:
+      ecdhAgree(s, p, secret) == Success
+      compare(expect, secret) == true
+
+  test "ECDHE/cpp-ethereum rlpx.cpp#L425":
+    # ECDHE test vectors
+    # Copied from https://github.com/ethereum/cpp-ethereum/blob/2409d7ec7d34d5ff5770463b87eb87f758e621fe/test/unittests/libp2p/rlpx.cpp#L425
+    var s0 = """
+      332143e9629eedff7d142d741f896258f5a1bfab54dab2121d3ec5000093d74b"""
+    var p0 = """
+      f0d2b97981bd0d415a843b5dfe8ab77a30300daab3658c578f2340308a2da1a0
+      7f0821367332598b6aa4e180a41e92f4ebbae3518da847f0b1c0bbfe20bcf4e1"""
+    var e0 = """
+      ee1418607c2fcfb57fda40380e885a707f49000a5dda056d828b7d9bd1f29a08"""
+    var secret: array[KeyLength, byte]
+    var s = getPrivateKey(s0)
+    var p = getPublicKey(p0)
+    let expect = fromHex(stripSpaces(e0))
+    check:
+      ecdhAgree(s, p, secret) == Success
+      compare(expect, secret) == true
+
+  test "ECDSA/cpp-ethereum crypto.cpp#L132":
+    # ECDSA test vectors
+    # Copied from https://github.com/ethereum/cpp-ethereum/blob/develop/test/unittests/libdevcrypto/crypto.cpp#L132
+    var signature = """
+      b826808a8c41e00b7c5d71f211f005a84a7b97949d5e765831e1da4e34c9b8295d
+      2a622eee50f25af78241c1cb7cfff11bcf2a13fe65dee1e3b86fd79a4e3ed000"""
+    var pubkey = """
+      e40930c838d6cca526795596e368d16083f0672f4ab61788277abfa23c3740e1cc
+      84453b0b24f49086feba0bd978bb4446bae8dff1e79fcc1e9cf482ec2d07c3"""
+    var check1 = fromHex(stripSpaces(signature))
+    var check2 = fromHex(stripSpaces(pubkey))
+    var sig: Signature
+    var key: PublicKey
+    var s = keccak256.digest("sec").data
+    var m = keccak256.digest("msg").data
+    check signMessage(s, m, sig) == Success
+    var sersig = sig.getRaw().data
+    check recoverSignatureKey(sersig, m, key) == Success
+    var serkey = key.getRaw().data
+    check:
+      compare(sersig, check1) == true
+      compare(serkey, check2) == true
+
+  test "ECDSA/100 signatures":
+    # signature test
+    var rkey: PublicKey
+    var sig: Signature
+    for i in 1..100:
+      var m = newPrivateKey()
+      var s = newPrivateKey()
+      var key = s.getPublicKey()
+      check signMessage(s, m, sig) == Success
+      var sersig = sig.getRaw().data
+      check:
+        recoverSignatureKey(sersig, m, rkey) == Success
+        key == rkey
+
+  test "KEYS/100 create/recovery keys":
+    # key create/recovery test
+    var rkey: PublicKey
+    for i in 1..100:
+      var s = newPrivateKey()
+      var key = s.getPublicKey()
+      check:
+        recoverPublicKey(key.getRaw().data, rkey) == Success
+        key == rkey
+
+  test "ECDHE/100 shared secrets":
+    # ECDHE shared secret test
+    var secret1, secret2: SharedSecret
+    for i in 1..100:
+      var aliceSecret = newPrivateKey()
+      var alicePublic = aliceSecret.getPublicKey()
+      var bobSecret = newPrivateKey()
+      var bobPublic = bobSecret.getPublicKey()
+      check:
+        ecdhAgree(aliceSecret, bobPublic, secret1) == Success
+        ecdhAgree(bobSecret, alicePublic, secret2) == Success
+        secret1 == secret2

tests/testecies.nim

@@ -0,0 +1,165 @@
+#
+#                 Ethereum P2P
+#              (c) Copyright 2018
+#       Status Research & Development GmbH
+#
+#    See the file "LICENSE", included in this
+#    distribution, for details about the copyright.
+#
+
+import unittest
+import ethp2p/ecc, ethp2p/ecies
+import nimcrypto/utils, nimcrypto/sha2, nimcrypto/hmac
+
+proc compare[A, B](x: openarray[A], y: openarray[B], s: int = 0): bool =
+  result = true
+  assert(s >= 0)
+  var size = if s == 0: min(len(x), len(y)) else: min(s, min(len(x), len(y)))
+  for i in 0..(size - 1):
+    if x[i] != cast[A](y[i]):
+      result = false
+      break
+
+suite "ECIES test suite":
+  test "KDF test vectors":
+    # KDF test
+    # Copied from https://github.com/ethereum/pydevp2p/blob/develop/devp2p/tests/test_ecies.py#L53
+    let m0 = "961c065873443014e0371f1ed656c586c6730bf927415757f389d92acf8268df"
+    let c0 = "4050c52e6d9c08755e5a818ac66fabe478b825b1836fd5efc4d44e40d04dabcc"
+    var m = fromHex(stripSpaces(m0))
+    var c = fromHex(stripSpaces(c0))
+    var k = kdf(m)
+    check compare(k, c) == true
+
+  test "HMAC-SHA256 test vectors":
+    # HMAC-SHA256 test
+    # https://github.com/ethereum/py-evm/blob/master/tests/p2p/test_ecies.py#L64-L76
+    const keys = [
+      "07a4b6dfa06369a570f2dcba2f11a18f",
+      "af6623e52208c596e17c72cea6f1cb09"
+    ]
+    const datas = ["4dcb92ed4fc67fe86832", "3461282bcedace970df2"]
+    const expects = [
+      "c90b62b1a673b47df8e395e671a68bfa68070d6e2ef039598bb829398b89b9a9",
+      "b3ce623bce08d5793677ba9441b22bb34d3e8a7de964206d26589df3e8eb5183"
+    ]
+    for i in 0..1:
+      var k = fromHex(stripSpaces(keys[i]))
+      var m = fromHex(stripSpaces(datas[i]))
+      var digest = sha256.hmac(k, m).data
+      var expect = fromHex(stripSpaces(expects[i]))
+      check compare(digest, expect) == true
+
+  test "ECIES \"Hello World!\" encryption/decryption test":
+    # ECIES encryption
+    var m = "Hello World!"
+    var encr = newSeq[byte](eciesEncryptedLength(len(m)))
+    var decr = newSeq[byte](len(m))
+    var shmac = [0x13'u8, 0x13'u8]
+    var outlen = 0
+    var s = newPrivateKey()
+    var p = s.getPublicKey()
+    check:
+      # Without additional mac data
+      eciesEncrypt(m, p, encr, outlen) == EciesStatus.Success
+      eciesDecrypt(encr, s, decr, outlen) == EciesStatus.Success
+      outlen == len(m)
+      equalMem(addr m[0], addr decr[0], outlen) == true
+      # With additional mac data
+      eciesEncrypt(m, p, encr, outlen, shmac) == EciesStatus.Success
+      eciesDecrypt(encr, s, decr, outlen, shmac) == EciesStatus.Success
+      outlen == len(m)
+      equalMem(addr m[0], addr decr[0], outlen) == true
+
+  test "ECIES/py-evm/cpp-ethereum test_ecies.py#L43/rlpx.cpp#L187":
+    # ECIES
+    # https://github.com/ethereum/py-evm/blob/master/tests/p2p/test_ecies.py#L43
+    # https://github.com/ethereum/cpp-ethereum/blob/develop/test/unittests/libp2p/rlpx.cpp#L187
+    const secretKeys = [
+      "c45f950382d542169ea207959ee0220ec1491755abe405cd7498d6b16adb6df8",
+      "5e173f6ac3c669587538e7727cf19b782a4f2fda07c1eaa662c593e5e85e3051"
+    ]
+    const cipherText = [
+      """04a0274c5951e32132e7f088c9bdfdc76c9d91f0dc6078e848f8e3361193dbdc
+         43b94351ea3d89e4ff33ddcefbc80070498824857f499656c4f79bbd97b6c51a
+         514251d69fd1785ef8764bd1d262a883f780964cce6a14ff206daf1206aa073a
+         2d35ce2697ebf3514225bef186631b2fd2316a4b7bcdefec8d75a1025ba2c540
+         4a34e7795e1dd4bc01c6113ece07b0df13b69d3ba654a36e35e69ff9d482d88d
+         2f0228e7d96fe11dccbb465a1831c7d4ad3a026924b182fc2bdfe016a6944312
+         021da5cc459713b13b86a686cf34d6fe6615020e4acf26bf0d5b7579ba813e77
+         23eb95b3cef9942f01a58bd61baee7c9bdd438956b426a4ffe238e61746a8c93
+         d5e10680617c82e48d706ac4953f5e1c4c4f7d013c87d34a06626f498f34576d
+         c017fdd3d581e83cfd26cf125b6d2bda1f1d56""",
+      """049934a7b2d7f9af8fd9db941d9da281ac9381b5740e1f64f7092f3588d4f87f
+         5ce55191a6653e5e80c1c5dd538169aa123e70dc6ffc5af1827e546c0e958e42
+         dad355bcc1fcb9cdf2cf47ff524d2ad98cbf275e661bf4cf00960e74b5956b79
+         9771334f426df007350b46049adb21a6e78ab1408d5e6ccde6fb5e69f0f4c92b
+         b9c725c02f99fa72b9cdc8dd53cff089e0e73317f61cc5abf6152513cb7d833f
+         09d2851603919bf0fbe44d79a09245c6e8338eb502083dc84b846f2fee1cc310
+         d2cc8b1b9334728f97220bb799376233e113"""
+    ]
+    const expectText = [
+      """884c36f7ae6b406637c1f61b2f57e1d2cab813d24c6559aaf843c3f48962f32f
+         46662c066d39669b7b2e3ba14781477417600e7728399278b1b5d801a519aa57
+         0034fdb5419558137e0d44cd13d319afe5629eeccb47fd9dfe55cc6089426e46
+         cc762dd8a0636e07a54b31169eba0c7a20a1ac1ef68596f1f283b5c676bae406
+         4abfcce24799d09f67e392632d3ffdc12e3d6430dcb0ea19c318343ffa7aae74
+         d4cd26fecb93657d1cd9e9eaf4f8be720b56dd1d39f190c4e1c6b7ec66f077bb
+         1100""",
+      """802b052f8b066640bba94a4fc39d63815c377fced6fcb84d27f791c9921ddf3e
+         9bf0108e298f490812847109cbd778fae393e80323fd643209841a3b7f110397
+         f37ec61d84cea03dcc5e8385db93248584e8af4b4d1c832d8c7453c0089687a7
+         00"""
+    ]
+    var data: array[1024, byte]
+    var outlen = 0
+    for i in 0..1:
+      var s = secretKeys[i].getPrivateKey()
+      var cipher = fromHex(stripSpaces(cipherText[i]))
+      var expect = fromHex(stripSpaces(expectText[i]))
+      check:
+        eciesDecrypt(cipher, s, data, outlen) == EciesStatus.Success
+        outlen == len(expect)
+        compare(data, expect) == true
+
+  test "ECIES/cpp-ethereum rlpx.cpp#L432-L459":
+    # ECIES
+    # https://github.com/ethereum/cpp-ethereum/blob/develop/test/unittests/libp2p/rlpx.cpp#L432-L459
+    const secretKeys = [
+      "57baf2c62005ddec64c357d96183ebc90bf9100583280e848aa31d683cad73cb",
+      "472413e97f1fd58d84e28a559479e6b6902d2e8a0cee672ef38a3a35d263886b",
+      "472413e97f1fd58d84e28a559479e6b6902d2e8a0cee672ef38a3a35d263886b",
+      "472413e97f1fd58d84e28a559479e6b6902d2e8a0cee672ef38a3a35d263886b"
+    ]
+    const cipherData = [
+      """04ff2c874d0a47917c84eea0b2a4141ca95233720b5c70f81a8415bae1dc7b74
+         6b61df7558811c1d6054333907333ef9bb0cc2fbf8b34abb9730d14e0140f455
+         3f4b15d705120af46cf653a1dc5b95b312cf8444714f95a4f7a0425b67fc064d
+         18f4d0a528761565ca02d97faffdac23de10""",
+      """046f647e1bd8a5cd1446d31513bac233e18bdc28ec0e59d46de453137a725995
+         33f1e97c98154343420d5f16e171e5107999a7c7f1a6e26f57bcb0d2280655d0
+         8fb148d36f1d4b28642d3bb4a136f0e33e3dd2e3cffe4b45a03fb7c5b5ea5e65
+         617250fdc89e1a315563c20504b9d3a72555""",
+      """0443c24d6ccef3ad095140760bb143078b3880557a06392f17c5e368502d7953
+         2bc18903d59ced4bbe858e870610ab0d5f8b7963dd5c9c4cf81128d10efd7c7a
+         a80091563c273e996578403694673581829e25a865191bdc9954db14285b56eb
+         0043b6288172e0d003c10f42fe413222e273d1d4340c38a2d8344d7aadcbc846
+         ee""",
+      """04c4e40c86bb5324e017e598c6d48c19362ae527af8ab21b077284a4656c8735
+         e62d73fb3d740acefbec30ca4c024739a1fcdff69ecaf03301eebf156eb5f17c
+         ca6f9d7a7e214a1f3f6e34d1ee0ec00ce0ef7d2b242fbfec0f276e17941f9f1b
+         fbe26de10a15a6fac3cda039904ddd1d7e06e7b96b4878f61860e47f0b84c8ce
+         b64f6a900ff23844f4359ae49b44154980a626d3c73226c19e"""
+    ]
+    const expectData = [
+      "a", "a", "aaaaaaaaaaaaaaaa", "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa"
+    ]
+    var data: array[1024, byte]
+    var outlen = 0
+    for i in 0..3:
+      var s = secretKeys[i].getPrivateKey()
+      var cipher = fromHex(stripSpaces(cipherData[i]))
+      check:
+        eciesDecrypt(cipher, s, data, outlen) == EciesStatus.Success
+        outlen == len(expectData[i])
+        compare(data, expectData[i]) == true