Add key interface with test vectors.

2019-03-02 21:19:41 +02:00 · 2019-03-02 21:19:41 +02:00 · b235c84bb2
parent 14686714c0
commit b235c84bb2
4 changed files with 893 additions and 4 deletions
--- a/libp2p.nimble
+++ b/libp2p.nimble
@ -22,4 +22,5 @@ task test, "Runs the test suite":
  exec "nim c -r tests/testecnist"
  exec "nim c -r tests/testrsa"
  exec "nim c -r tests/tested25519"
  exec "nim c -r tests/testcrypto"
  exec "nim c -r tests/testdaemon"
--- a/libp2p/crypto/crypto.nim
+++ b/libp2p/crypto/crypto.nim
@ -0,0 +1,487 @@
 ## Nim-Libp2p
 ## Copyright (c) 2018 Status Research & Development GmbH
 ## Licensed under either of
 ##  * Apache License, version 2.0, ([LICENSE-APACHE](LICENSE-APACHE))
 ##  * MIT license ([LICENSE-MIT](LICENSE-MIT))
 ## at your option.
 ## This file may not be copied, modified, or distributed except according to
 ## those terms.
 ## This module implements Public Key and Private Key interface for libp2p.
 import rsa, ecnist
 import ed25519/ed25519
 import ../protobuf/minprotobuf
 import nimcrypto/[rijndael, blowfish, sha, sha2, hash, hmac, utils]
 type
  PKScheme* = enum
    RSA = 0,
    Ed25519,
    Secp256k1,
    ECDSA,
    NoSupport
  CipherScheme* = enum
    Aes128 = 0,
    Aes256,
    Blowfish
  DigestSheme* = enum
    Sha1,
    Sha256,
    Sha512
  ECDHEScheme* = EcCurveKind
  PublicKey* = object
    case scheme*: PKScheme
    of RSA:
      rsakey*: RsaPublicKey
    of Ed25519:
      edkey*: EdPublicKey
    of Secp256k1:
      discard
    of ECDSA:
      eckey*: EcPublicKey
    of NoSupport:
      discard
  PrivateKey* = object
    case scheme*: PKScheme
    of RSA:
      rsakey*: RsaPrivateKey
    of Ed25519:
      edkey*: EdPrivateKey
    of Secp256k1:
      discard
    of ECDSA:
      eckey*: EcPrivateKey
    of NoSupport:
      discard
  KeyPair* = object
    seckey*: PrivateKey
    pubkey*: PublicKey
  Secret* = object
    ivsize*: int
    keysize*: int
    macsize*: int
    data*: seq[byte]
  P2pKeyError* = object of Exception
 const
  SupportedSchemes* = {RSA, Ed25519, ECDSA}
  SupportedSchemesInt* = {int8(RSA), int8(Ed25519), int8(ECDSA)}
 proc random*(t: typedesc[PrivateKey], scheme: PKScheme,
             bits = DefaultKeySize): PrivateKey =
  ## Generate random private key for scheme ``scheme``.
  ##
  ## ``bits`` is number of bits for RSA key, ``bits`` value must be in
  ## [512, 4096], default value is 2048 bits.
  assert(scheme in SupportedSchemes)
  result = PrivateKey(scheme: scheme)
  if scheme == RSA:
    result.rsakey = RsaPrivateKey.random(bits)
  elif scheme == Ed25519:
    result.edkey = EdPrivateKey.random()
  elif scheme == ECDSA:
    result.eckey = EcPrivateKey.random(Secp256r1)
 proc random*(t: typedesc[KeyPair], scheme: PKScheme,
             bits = DefaultKeySize): KeyPair =
  ## Generate random key pair for scheme ``scheme``.
  ##
  ## ``bits`` is number of bits for RSA key, ``bits`` value must be in
  ## [512, 4096], default value is 2048 bits.
  assert(scheme in SupportedSchemes)
  result.seckey = PrivateKey(scheme: scheme)
  result.pubkey = PublicKey(scheme: scheme)
  if scheme == RSA:
    var pair = RsaKeyPair.random(bits)
    result.seckey.rsakey = pair.seckey
    result.pubkey.rsakey = pair.pubkey
  elif scheme == Ed25519:
    var pair = EdKeyPair.random()
    result.seckey.edkey = pair.seckey
    result.pubkey.edkey = pair.pubkey
  elif scheme == ECDSA:
    var pair = EcKeyPair.random(Secp256r1)
    result.seckey.eckey = pair.seckey
    result.pubkey.eckey = pair.pubkey
 proc getKey*(key: PrivateKey): PublicKey =
  ## Get public key from corresponding private key ``key``.
  result = PublicKey(scheme: key.scheme)
  if key.scheme == RSA:
    result.rsakey = key.rsakey.getKey()
  elif key.scheme == Ed25519:
    result.edkey = key.edkey.getKey()
  elif key.scheme == ECDSA:
    result.eckey = key.eckey.getKey()
 proc toRawBytes*(key: PrivateKey, data: var openarray[byte]): int =
  ## Serialize private key ``key`` (using scheme's own serialization) and store
  ## it to ``data``.
  ##
  ## Returns number of bytes (octets) needed to store private key ``key``.
  if key.scheme == RSA:
    result = key.rsakey.toBytes(data)
  elif key.scheme == Ed25519:
    result = key.edkey.toBytes(data)
  elif key.scheme == ECDSA:
    result = key.eckey.toBytes(data)
 proc toRawBytes*(key: PublicKey, data: var openarray[byte]): int =
  ## Serialize public key ``key`` (using scheme's own serialization) and store
  ## it to ``data``.
  ##
  ## Returns number of bytes (octets) needed to store public key ``key``.
  if key.scheme == RSA:
    result = key.rsakey.toBytes(data)
  elif key.scheme == Ed25519:
    result = key.edkey.toBytes(data)
  elif key.scheme == ECDSA:
    result = key.eckey.toBytes(data)
 proc getRawBytes*(key: PrivateKey): seq[byte] =
  ## Return private key ``key`` in binary form (using scheme's own
  ## serialization).
  if key.scheme == RSA:
    result = key.rsakey.getBytes()
  elif key.scheme == Ed25519:
    result = key.edkey.getBytes()
  elif key.scheme == ECDSA:
    result = key.eckey.getBytes()
 proc getRawBytes*(key: PublicKey): seq[byte] =
  ## Return public key ``key`` in binary form (using scheme's own
  ## serialization).
  if key.scheme == RSA:
    result = key.rsakey.getBytes()
  elif key.scheme == Ed25519:
    result = key.edkey.getBytes()
  elif key.scheme == ECDSA:
    result = key.eckey.getBytes()
 proc toBytes*(key: PrivateKey, data: var openarray[byte]): int =
  ## Serialize private key ``key`` (using libp2p protobuf scheme) and store
  ## it to ``data``.
  ##
  ## Returns number of bytes (octets) needed to store private key ``key``.
  var msg = initProtoBuffer()
  msg.write(initProtoField(1, cast[uint64](key.scheme)))
  msg.write(initProtoField(2, key.getRawBytes()))
  msg.finish()
  result = len(msg.buffer)
  if len(data) >= result:
    copyMem(addr data[0], addr msg.buffer[0], len(msg.buffer))
 proc toBytes*(key: PublicKey, data: var openarray[byte]): int =
  ## Serialize public key ``key`` (using libp2p protobuf scheme) and store
  ## it to ``data``.
  ##
  ## Returns number of bytes (octets) needed to store public key ``key``.
  var msg = initProtoBuffer()
  msg.write(initProtoField(1, cast[uint64](key.scheme)))
  msg.write(initProtoField(2, key.getRawBytes()))
  msg.finish()
  result = len(msg.buffer)
  if len(data) >= result:
    copyMem(addr data[0], addr msg.buffer[0], len(msg.buffer))
 proc getBytes*(key: PrivateKey): seq[byte] =
  ## Return private key ``key`` in binary form (using libp2p's protobuf
  ## serialization).
  var msg = initProtoBuffer()
  msg.write(initProtoField(1, cast[uint64](key.scheme)))
  msg.write(initProtoField(2, key.getRawBytes()))
  msg.finish()
  result = msg.buffer
 proc getBytes*(key: PublicKey): seq[byte] =
  ## Return public key ``key`` in binary form (using libp2p's protobuf
  ## serialization).
  var msg = initProtoBuffer()
  msg.write(initProtoField(1, cast[uint64](key.scheme)))
  msg.write(initProtoField(2, key.getRawBytes()))
  msg.finish()
  result = msg.buffer
 proc init*(key: var PrivateKey, data: openarray[byte]): bool =
  ## Initialize private key ``key`` from libp2p's protobuf serialized raw
  ## binary form.
  ##
  ## Returns ``true`` on success.
  var id: uint64
  var buffer: seq[byte]
  if len(data) > 0:
    var pb = initProtoBuffer(@data)
    if pb.getVarintValue(1, id) != 0:
      if pb.getBytes(2, buffer) != 0:
        if cast[int8](id) in SupportedSchemesInt:
          var scheme = cast[PKScheme](cast[int8](id))
          var nkey = PrivateKey(scheme: scheme)
          if scheme == RSA:
            if init(nkey.rsakey, buffer) == Asn1Status.Success:
              key = nkey
              result = true
          elif scheme == Ed25519:
            if init(nkey.edkey, buffer):
              key = nkey
              result = true
          elif scheme == ECDSA:
            if init(nkey.eckey, buffer) == Asn1Status.Success:
              key = nkey
              result = true
 proc init*(key: var PublicKey, data: openarray[byte]): bool =
  ## Initialize public key ``key`` from libp2p's protobuf serialized raw
  ## binary form.
  ##
  ## Returns ``true`` on success.
  var id: uint64
  var buffer: seq[byte]
  if len(data) > 0:
    var pb = initProtoBuffer(@data)
    if pb.getVarintValue(1, id) != 0:
      if pb.getBytes(2, buffer) != 0:
        if cast[int8](id) in SupportedSchemesInt:
          var scheme = cast[PKScheme](cast[int8](id))
          var nkey = PublicKey(scheme: scheme)
          if scheme == RSA:
            if init(nkey.rsakey, buffer) == Asn1Status.Success:
              key = nkey
              result = true
          elif scheme == Ed25519:
            if init(nkey.edkey, buffer):
              key = nkey
              result = true
          elif scheme == ECDSA:
            if init(nkey.eckey, buffer) == Asn1Status.Success:
              key = nkey
              result = true
 proc init*(key: var PrivateKey, data: string): bool =
  ## Initialize private key ``key`` from libp2p's protobuf serialized
  ## hexadecimal string representation.
  ##
  ## Returns ``true`` on success.
  result = key.init(fromHex(data))
 proc init*(key: var PublicKey, data: string): bool =
  ## Initialize public key ``key`` from libp2p's protobuf serialized
  ## hexadecimal string representation.
  ##
  ## Returns ``true`` on success.
  result = key.init(fromHex(data))
 proc init*(t: typedesc[PrivateKey], data: openarray[byte]): PrivateKey =
  ## Create new private key from libp2p's protobuf serialized binary form.
  if not result.init(data):
    raise newException(P2pKeyError, "Incorrect binary form")
 proc init*(t: typedesc[PublicKey], data: openarray[byte]): PublicKey =
  ## Create new public key from libp2p's protobuf serialized binary form.
  if not result.init(data):
    raise newException(P2pKeyError, "Incorrect binary form")
 proc init*(t: typedesc[PrivateKey], data: string): PrivateKey =
  ## Create new private key from libp2p's protobuf serialized hexadecimal string
  ## form.
  result = t.init(fromHex(data))
 proc init*(t: typedesc[PublicKey], data: string): PublicKey =
  ## Create new public key from libp2p's protobuf serialized hexadecimal string
  ## form.
  result = t.init(fromHex(data))
 proc `==`*(key1, key2: PublicKey): bool =
  ## Return ``true`` if two public keys ``key1`` and ``key2`` of the same
  ## scheme and equal.
  if key1.scheme == key2.scheme:
    if key1.scheme == RSA:
      result = (key1.rsakey == key2.rsakey)
    elif key1.scheme == Ed25519:
      result = (key1.edkey == key2.edkey)
    elif key1.scheme == ECDSA:
      result = (key1.eckey == key2.eckey)
 proc `==`*(key1, key2: PrivateKey): bool =
  ## Return ``true`` if two private keys ``key1`` and ``key2`` of the same
  ## scheme and equal.
  if key1.scheme == key2.scheme:
    if key1.scheme == RSA:
      result = (key1.rsakey == key2.rsakey)
    elif key1.scheme == Ed25519:
      result = (key1.edkey == key2.edkey)
    elif key1.scheme == ECDSA:
      result = (key1.eckey == key2.eckey)
 proc `$`*(key: PrivateKey): string =
  ## Get string representation of private key ``key``.
  if key.scheme == RSA:
    result = $(key.rsakey)
  elif key.scheme == Ed25519:
    result = "Ed25519 key ("
    result.add($(key.edkey))
    result.add(")")
  elif key.scheme == ECDSA:
    result = "Secp256r1 key ("
    result.add($(key.eckey))
    result.add(")")
 proc `$`*(key: PublicKey): string =
  ## Get string representation of public key ``key``.
  if key.scheme == RSA:
    result = $(key.rsakey)
  elif key.scheme == Ed25519:
    result = "Ed25519 key ("
    result.add($(key.edkey))
    result.add(")")
  elif key.scheme == ECDSA:
    result = "Secp256r1 key ("
    result.add($(key.eckey))
    result.add(")")
 proc sign*(key: PrivateKey, data: openarray[byte]): seq[byte] =
  ## Sign message ``data`` using private key ``key`` and return generated
  ## signature in raw binary form.
  if key.scheme == RSA:
    var sig = key.rsakey.sign(data)
    result = sig.getBytes()
  elif key.scheme == Ed25519:
    var sig = key.edkey.sign(data)
    result = sig.getBytes()
  elif key.scheme == ECDSA:
    var sig = key.eckey.sign(data)
    result = sig.getBytes()
 proc verify*(sig: openarray[byte], message: openarray[byte],
             key: PublicKey): bool =
  ## Verify signature ``sig`` using message ``message`` and public key ``key``.
  ## Return ``true`` if message signature is valid.
  if key.scheme == RSA:
    var signature: RsaSignature
    if signature.init(sig) == Asn1Status.Success:
      result = signature.verify(message, key.rsakey)
  elif key.scheme == Ed25519:
    var signature: EdSignature
    if signature.init(sig):
      result = signature.verify(message, key.edkey)
  elif key.scheme == ECDSA:
    var signature: EcSignature
    if signature.init(sig) == Asn1Status.Success:
      result = signature.verify(message, key.eckey)
 template makeSecret(buffer, hmactype, secret, seed) =
  var ctx: hmactype
  var j = 0
  # We need to strip leading zeros, because Go bigint serialization do it.
  var offset = 0
  for i in 0..<len(secret):
    if secret[i] != 0x00'u8:
      break
    inc(offset)
  ctx.init(secret.toOpenArray(offset, len(secret) - 1))
  ctx.update(seed)
  var a = ctx.finish()
  while j < len(buffer):
    ctx.init(secret.toOpenArray(offset, len(secret) - 1))
    ctx.update(a.data)
    ctx.update(seed)
    var b = ctx.finish()
    var todo = len(b.data)
    if j + todo > len(buffer):
      todo = len(buffer) - j
    copyMem(addr buffer[j], addr b.data[0], todo)
    j += todo
    ctx.init(secret.toOpenArray(offset, len(secret) - 1))
    ctx.update(a.data)
    a = ctx.finish()
 proc stretchKeys*(cipherScheme: CipherScheme, hashScheme: DigestSheme,
                  secret: openarray[byte]): Secret =
  ## Expand shared secret to cryptographic keys.
  if cipherScheme == Aes128:
    result.ivsize = aes128.sizeBlock
    result.keysize = aes128.sizeKey
  elif cipherScheme == Aes256:
    result.ivsize = aes256.sizeBlock
    result.keysize = aes256.sizeKey
  elif cipherScheme == Blowfish:
    result.ivsize = 8
    result.keysize = 32
  var seed = "key expansion"
  result.macsize = 20
  let length = result.ivsize + result.keysize + result.macsize
  result.data = newSeq[byte](2 * length)
  if hashScheme == Sha256:
    makeSecret(result.data, HMAC[sha256], secret, seed)
  elif hashScheme == Sha512:
    makeSecret(result.data, HMAC[sha512], secret, seed)
  elif hashScheme == Sha1:
    makeSecret(result.data, HMAC[sha1], secret, seed)
 template goffset*(secret, id, o: untyped): untyped =
  id * (len(secret.data) shr 1) + o
 template ivOpenArray*(secret: Secret, id: int): untyped =
  toOpenArray(secret.data, goffset(secret, id, 0),
              goffset(secret, id, secret.ivsize - 1))
 template keyOpenArray*(secret: Secret, id: int): untyped =
  toOpenArray(secret.data, goffset(secret, id, secret.ivsize),
              goffset(secret, id, secret.ivsize + secret.keysize - 1))
 template macOpenArray*(secret: Secret, id: int): untyped =
  toOpenArray(secret.data, goffset(secret, id, secret.ivsize + secret.keysize),
       goffset(secret, id, secret.ivsize + secret.keysize + secret.macsize - 1))
 proc iv*(secret: Secret, id: int): seq[byte] {.inline.} =
  ## Get array of bytes with with initial vector.
  result = newSeq[byte](secret.ivsize)
  var offset = if id == 0: 0 else: (len(secret.data) div 2)
  copyMem(addr result[0], unsafeAddr secret.data[offset], secret.ivsize)
 proc key*(secret: Secret, id: int): seq[byte] {.inline.} =
  result = newSeq[byte](secret.keysize)
  var offset = if id == 0: 0 else: (len(secret.data) div 2)
  offset += secret.ivsize
  copyMem(addr result[0], unsafeAddr secret.data[offset], secret.keysize)
 proc mac*(secret: Secret, id: int): seq[byte] {.inline.} =
  result = newSeq[byte](secret.macsize)
  var offset = if id == 0: 0 else: (len(secret.data) div 2)
  offset += secret.ivsize + secret.keysize
  copyMem(addr result[0], unsafeAddr secret.data[offset], secret.macsize)
 proc ephemeral*(scheme: ECDHEScheme): KeyPair =
  ## Generate ephemeral keys used to perform ECDHE.
  var keypair: EcKeyPair
  if scheme == Secp256r1:
    keypair = EcKeyPair.random(Secp256r1)
  elif scheme == Secp384r1:
    keypair = EcKeyPair.random(Secp384r1)
  elif scheme == Secp521r1:
    keypair = EcKeyPair.random(Secp521r1)
  result.seckey = PrivateKey(scheme: ECDSA)
  result.pubkey = PublicKey(scheme: ECDSA)
  result.seckey.eckey = keypair.seckey
  result.pubkey.eckey = keypair.pubkey
 proc makeSecret*(remoteEPublic: PublicKey, localEPrivate: PrivateKey,
                 data: var openarray[byte]): int =
  ## Calculate shared secret using remote ephemeral public key
  ## ``remoteEPublic`` and local ephemeral private key ``localEPrivate`` and
  ## store shared secret to ``data``
  ##
  ## Returns number of bytes (octets) used to store shared secret data, or
  ## ``0`` on error.
  if remoteEPublic.scheme == ECDSA:
    if localEPrivate.scheme == remoteEPublic.scheme:
      result = toSecret(remoteEPublic.eckey, localEPrivate.eckey, data)
--- a/libp2p/crypto/ecnist.nim
+++ b/libp2p/crypto/ecnist.nim
@ -29,6 +29,9 @@ const
  Sig256Length* = 64
  Sig384Length* = 96
  Sig521Length* = 132
  Secret256Length* = SecKey256Length
  Secret384Length* = SecKey384Length
  Secret521Length* = SecKey521Length
 type
  EcPrivateKey* = ref object
@ -727,11 +730,11 @@ proc toSecret*(pubkey: EcPublicKey, seckey: EcPrivateKey,
  var length = 0
  if not isNil(mult):
    if seckey.key.curve == BR_EC_SECP256R1:
-      result = 32
+      result = Secret256Length
    elif seckey.key.curve == BR_EC_SECP384R1:
-      result = 48
+      result = Secret384Length
    elif seckey.key.curve == BR_EC_SECP521R1:
-      result = 66
+      result = Secret521Length
    if len(data) >= result:
      var qplus1 = cast[pointer](cast[uint](mult.key.q) + 1'u)
      copyMem(addr data[0], qplus1, result)
@ -742,7 +745,7 @@ proc getSecret*(pubkey: EcPublicKey, seckey: EcPrivateKey): seq[byte] =
  ## shared secret.
  ##
  ## If error happens length of result array will be ``0``.
-  var data: array[66, byte]
+  var data: array[Secret521Length, byte]
  let res = toSecret(pubkey, seckey, data)
  if res > 0:
    result = newSeq[byte](res)
--- a/tests/testcrypto.nim
+++ b/tests/testcrypto.nim
@ -0,0 +1,398 @@
 ## Nim-Libp2p
 ## Copyright (c) 2018 Status Research & Development GmbH
 ## Licensed under either of
 ##  * Apache License, version 2.0, ([LICENSE-APACHE](LICENSE-APACHE))
 ##  * MIT license ([LICENSE-MIT](LICENSE-MIT))
 ## at your option.
 ## This file may not be copied, modified, or distributed except according to
 ## those terms.
 ## Test vectors was made using Go implementation
 ## https://github.com/libp2p/go-libp2p-crypto/blob/master/key.go
 import unittest
 import nimcrypto/utils
 import ../libp2p/crypto/crypto
 const
  PrivateKeys = [
    """080012BE023082013A020100024100AD8A7D5B0EB7C852C1464E4567651F412C
       692534E1600FDC5BDA9EDBFA9927AF0FFA7C52599BE62999E085C345D21C8D43
       627CCC0E16D695C770E26D220AE709020301000102403B58BCFDC2CEBEC6EE29
       A8E2BB352DB71004F5205C62898A062F815C211AF722AADD1087C68E24015417
       E36632EEA2D2B1A20FF3D283A4C3881C724B3919FCF1022100D4BD1D7D15B328
       4EFBBB5B2C6A11CFB7BCD9000C1010D69C808F370DFA751D47022100D0D4CB1B
       BAB9F8C11376744F0D96D6E4BC2B12F4DF768AC9EEA79DAB24C8C12F02210089
       A3FA0A4E19E64083FA8A58C81FD2070CF651637C9988612584839855ADA44D02
       20137DD91B5479693B743A992E8BC1297B9E08933361EC2996217D699D00C8F0
       2702201A8D0497E8962E0AF5B15CA03085070F735B39876C54BA8908EDC87C42
       D9DADC""",
    """080012E0043082025C02010002818100B91DCD5578C2FA3EA7D1DF62F59DEEDA
       834ECE568844554163E1803CDF4C2988BE182B8F957D3405BC745A33DA1E714A
       BA13C316683767735ED72AE8B35648FD6E33A49D696FADB6499C63A09204F0BF
       77B44D3917DC746FB7B52040725746A3140E96E8682A02A4767C280DEFBE58C6
       ACB6DD1EE63F3F589F4C7941B27957F70203010001028180364CDFA66ABE06D9
       CA306DEE814DCA7A9E79C75CEAABE0B645AE2807B3188C36684C7EBAA7870A73
       844C3D0968B9F5518E33ADCE2CD3D3ACABED41D0F08A26EE705E4277AF0D5816
       491C626F6D2D5396A741B83D0730401B061A8C2DE19E18B07CE8798F387D4C79
       78C92DA6F4080A45F93D0ADE50CF7E139DB7288EBA72D341024100DE9B394C60
       6C396B65756CE4A2E3D77F66C3AFBDA0C09C3CD87EB60A35018BDA7D82FF119F
       F6EBAAEC868E8ED1AD215C9EBF4073F26A1B187CDAFC862540B1C3024100D4E2
       D92E126D92B6795EBD7991A2D8A35147FAB73CFA4BBE74644CE8D1AEDE10A2FF
       33CEDF0B4961A89B1121C58D233309589BFBDE72D374ECB6A6859B0CC9BD0241
       008B0ABB9C6831D11FB2CCC8CA7AB003BF9109B3B0A7430793BDCA4F9C4A857F
       BC665F3740E400D02CFFF5FFFF571A63D73D54CA4661E942A965FB4675E7B8E4
       0F02404A175D90DC57085DBBA60E79B6072030CF04272D08EAEFDBAC349053E3
       4E61F916518D9D6D21477BD6AB896DE08C7B78B2C3051EC6CFDDEA6ECC2EEE87
       050F5D02407BC18B68F253353D7DB89AA85A7CEC4069DAEB894828F83931ADC4
       9A3255DFD0C9AAF9D09EBFAE831588A360EB0EEB89E45C9D136DCEEC8EAEBD3E
       65FBA9EE01""",
    """080012A809308204A40201000282010100C8B014EC01E135D635F7E246BA7D42
       3E2B36F45B052F0B644DA6B1B6DD964696F279BB9BB5F5C41EE3204F74EF70C2
       28C8CDD97E4F19094274EB01C292EC25055CB3CECD1A41E8919A0C111602B1B8
       5B4E43DBB2F4898C52738465F35E3085586CF01E407BE6CB5F0C08D0AD6D6FE0
       2A43C932E124E9C8498E67BA323CC84A275ACCC20D586C04DAF54FE98018FF15
       62E80514735A3237AA3C1DD2B4281FCAD3BD94952F0397A3F15B06269107C147
       C15645DCB507C566E66BF24E2745A05E4D31F364C2C50C0F5C9A6889378051BF
       05669EA905C2370548D6EF2CF66A4A5DC23F10B7614BC43CF0BFCC8711B6FF9F
       645FC2E5713ED1CB5975392B8C8652026902030100010282010018F9B0E0DE2B
       04E42FBB35B1CFAB9EFED5A9F5270EB2181CD77D1348CAB2D4FE1C17023E129B
       0F5938B2E0B090CBDB9DEFBF8E7DA5A25C00A54449E7C919125264830C0D8263
       096A755D6312F62ADFE29D0EDCDC9C8A31A8612FECF0289CA93BA3F30E10C05A
       AC9C9B86CD5187F91050B236EBDA1119F70F1065E04A383E44DC008A143630AD
       B59064AB3D810C391B59BAEB8E7C29C38A6AD6B10EBAA456DCACFA00DB06CA61
       D630846EAF4B1A0292A695CBE5001BA8A2E419881263576358295E8B7A61E0A2
       7EFCA0EC37810873792B0F80D2DD877DCE383A704DE13BC0E8EF6D1CF4C71DE7
       306F6A0C3741DDCD81CF090746DD217925D5BEAF30B7D174B83102818100E35A
       50E392EF35CFFF9D24E0A71561E16E7CE99D13C3D9630305D74038F8F646D5CF
       440FEC38DFB145BAB25FA875C6B0B93DEF43CEDA51C52FF97BB02039913CD5BB
       36DB0D0B4DEAF0AF3A11D1DDD5991F18F6DDBEF4708B8B00DC6F99CC930E93D8
       84BF118D204E9A83C7B2163252731813A67A4043459D943549D8AFAED7EF0281
       8100E1F9A33FF755B1187302AD22B7C70FF2C6D4D5D8E765D337BECF3E417DDB
       57818588240F3A40FE2E6C73E3E0BA244FAFCC8988E010577AAD967D48203563
       4CBA45B8166269E5E64214EB23CAE8B1619F3B7910FFE343E88B4E6CDC57CE8A
       736ECD5B8B455C4B004D7222298663EDD4A59BDB718CA436A86BC2BA53BC0E7D
       B32702818100A5CFB7D0D1D7DE624D659980B2BAF8810628D9E47286D2E3D04F
       91364896E25EB50F0DEFA2F3B3C94136B162ECA4C0FD208CD8149727489DCCA8
       629A085693E34F69D3CF1C8B530F76EC0528FBEB931DB2BD6D463A3F6259934E
       54769C2FC44CCC6D0C1BA1BC5084A3525AF13A190762E37B695E1DC2326283B5
       FD9EA83A974702818100C493B88AE5AB5AD2AD0210011AA40560A9CCEE76B0DD
       687F9EF283F2CEFC67441A18535E17CC0011FC705834DF58C5256625E2B72020
       296D2673B7B1A51FCBD862DC0044FE606B0CE34BA6285682302D27BC6AA85F58
       6CCBFA9E4293F3ED86FB4593B434D353BF609FBFCE25C57A5838F4BB522D0991
       2EB40782B562EBAC37930281802E343D25B84AF8CAB1A298179FDE5F94D2EFF6
       1E51EF4784E5BBE4DC230F17B884B0074CA4603416F72C10D9137D79E28967C4
       8C0E4AEA1453952818FF9AD2FACCED7CE3A037D8545C151F57D35DED691CA53F
       8A5336590F7B080805A46701B01C9F9919E3890CA1A0373D909373638B57FD0C
       87627491C41F1BF1E9643DE7B4""",
    """080012AD12308209290201000282020100E35735127777C52E66252B014E9650
       01F3A515317B90DDAC8671F4F820AE67308DE2AA4162E99522CD6DA7EB9D7DB6
       06489FEB77341A8FA058FAC832EE6EE5E978D512FF79461FC419A23B27C39C81
       BB635228B0DA5CFAE87080AC1AAE4619BF4576771E6E24A04D98D55ADA5CBA55
       8EBE06ED14790D71438AFDC1FB9B4E2E623F221F8509A8CFE37265728EFBFAA6
       0C76E6FBC4A473511CE6EE8A72C1CE1E5D67AB9FC4FA6FE797B854DFE7064C23
       5ECB1379DB4B1E085F0042E19831D80CBE160A46C5154148A8D20E15C29F12AE
       208022EF094C5AC565153268DE8318CAFC82D2D71839EA136756FD4EBC3951F2
       60EE5DA51A63D9AC7B80B7968D769CC82DCE2494BAFE9505C124E947E0E8D3F4
       A6B207EE195B3FFBFED028DCE59DB5CD60B1C6C316B4A712DAC2E8BF46E00611
       6685BB77D56E00B2A63B74CFA5C7CAD003BD2DA9F865239DAB45FE52DAB9C792
       8A705F3A0A3DCEC0B45A73DCE0A63DA1E24417ECD9C4B51342600CD2963BBA4F
       A3DF170666B9804E1BCC9E7CF171571CB336F383B5A0FA375F7A7F72CC4F4460
       B8255F4F38556C360D712910B34A8ACE1C270175DFF5CECC7A34681835915BCE
       5FD4CA52D0F5A57685E28F5DCA1CA5A4410FDEAF516FC4F8226BCE2CFDBA9F83
       0DD9A0903A18E009BBE818D52D11AD85974021CE0CC908DEC21FD6163EC7FD55
       8150506FAE4FE6393EA3CC061EC9749DFD020301000102820200535C63E28C9A
       075C9729E3D60BDA0426630FD2709D8DA62B1FF5634D24B6AEB1D8251826F7BD
       0CE98108477D96F744AA9330C8A7A21C6733F5CCA7623D99BE8658BF50C30AD6
       12C9D6586D768C3CB4396116FC42B51F4905B85306489644B02639B351C47FC0
       C06313BA9020E7C58F9FD2C03968BB66997499DFA8A4B8F2F701218342A986BC
       36D680D90023BBF3D1B55A5822539DB58735A0DC313A19249A6FC796DFF3DB9C
       F2FFE8207F257862ACC9928F66AC69A3EE8FDF49A6ED26C1C11266848824B641
       85021A5BFDD0AA81B005CCD6826E1768655F466180A0AED3858307F985D3A550
       D6A29AFC3145C582EDEC6B1B3D722AD0E37539E297BAF19655B3FD0DCBBF06DF
       65135B59D6FD56F2587523B231C7736A39D1C73967E56EF9E1D093DE6136F74A
       CFABE1B0917F0C67724EA16FC7BD0CF57FF5AED3941AE5DA068A48B3F5726A56
       223DAF96A24F0D4D22E2CE81B189D0A75A52ECFA50AEE24149E8285E2FD0892E
       0D028EE5F39CEF0C070418C3C8CEAE1243481417F2277FC9207E8F78841653AF
       674B1C37A6E9CBF4D9EAB1DB9B43D19AA1F4E24F7A6416A4EE6DB565CDD05616
       A33EF1A61D74DF07506ACAE38DE6820F384560D39A53DD35302CEC5CDF0A6E42
       239EC3344EC5088C3E4787480F876223BBFCF70E48F39A37C4B43B33000F1D7B
       38128484865BC4E9614C3F8AB7FAB0829574ECFB30AAE5E954810282010100F9
       E86D7571EF36C6A6735EEDEE2AA87FA7A6D269B0EC79D6A4053BB7327ACBBE00
       8C5C713A056FCEF6777A5A3BC0BE7DB5B94032425394EF579F9847041765E3A0
       9E9DBD942C8C09BB8EBCB8F5E941055F75BCD2DB1337A93FE2D66B2D4F3F6741
       FAC20024402A067BD69892D830B8069D93AD3C47A46E12C78D6BA6292F3D3270
       2F72DC29DF1FDA9BCE4467D13D0A7BA4A69E65B1205F443CB015533788B62919
       EEA289BA5BAC4B943DA27B611FAAE83119CD5F877763475109ACECC97018BBC4
       973E34A83C09DD43EF6E4FBECC79BF8B5A9BDABEF78E139FFD5C549848B0B593
       377F105F5A4B2B44FCACC4745C56B54ABAD14DF31ABF738861F032D48DDE5D02
       82010100E8E1F25C4EDDF32B479E092C19C824DC02AF331570EE89A557F69936
       F40567377C1CFA0C077716EE8289D7F0467FA6CF96D483B62AFFCE075A8911EE
       47E77B56550F2874BA4FA9B6BDEB00606DFE4BE54A2257DCA1AB0B7C394973B3
       CAE48F9CB352452A6DDC1A8FA28AB85372F3E028C4CA44EE54EA61716F829FF9
       6FABDEC82EE86B1213C5355778F0262F5E1DC5F292F4BD663D3C37438A4469BB
       BDFCB3D0E0DE81C16154EBD1204F1D8AED4CFC97FFEB3066780EE143E78E2886
       0FB637A62F3B6E85428C6FD4F357017AF9647E33E16D1DDF17FF524E53FB8E4D
       3FE2B24D5DE0FEC1F9D2A6EA9CC63A3AA406584651A2CA6EB7A68AE00E8332C2
       185F842102820100367ACBF9F17793BA64A8FC05E488DA28D2149504437499EF
       07DCB832ECC746494A774EE3C42151498E0367E1E9EACFDC39D483C131226572
       73E8AFDAB372A25CA8344BF0FB2F66EBEC3E66B7EFAC04E7B5F2C5D235BE0FC1
       4ED315A951BC57F71BB41DBCC82A50BF0F1A2E32BCFC89F1AF42755E91C3AFD7
       5A3763435AF11867397BAE8F7E754CCD6C6FE00BBDDA8FC17A987429791EB485
       FCB0EA4534F311BB0E132ECDD5998C8B016B1A53C94D8D058746B7B5DEA3513A
       47D953205F9D9756BFB9B4EEE7CA06E07CA1E2AB71CDC3B0D521509EB448E569
       33D498DF3C3F847E60F49537AD81D2A74127D0461793D5B739EE5618A729AA98
       F61F5BACC917906502820101008F88DB810B56FF0E78D8ADDC91936B2C73371A
       AC276BCE48AB7BA1195EB389D787D6B04303C2E1CE6584A22444BF5EC7E9B5D7
       EC4A7A59B8EC93390AFD246E3F5AB3BA029FE683BACF396D8501A64F8EE5EF5E
       E9EC76E8E04ACABBD65FC219C5C23C7DC6D5E96831894428B1BE5313A0ED11A2
       04A72FC29950DA58D13B83DA0ED5E288439F0DD87FAE598D9F7A49AD7C8218F8
       37709C918F3E44464AE1A1440F04D9FF6D7A19063361CF816CE42FA42BE71F45
       3892DCD0F8B25A4B1DBDC7586B4407446A3C0724D2429D289B6BE50567E29407
       6A3E772E7A7A86BC415E93D1C39F8E1256EA2C6C9683C42595890D24114B35A3
       C133CE212051B1897259E55D210282010100999A507C3D551ECC5F68A63C80E5
       DC15177996E55203CDA99B69C1C6B4E2D7DE52660412BFD7CE9AC7C7427533A3
       A442DCA58CB14F7B776D3D9A681FC7D3762A789E4BFBC7D854704CFE1726154C
       DB9F1DC399AF2A687AFB2FCBD110EBD5A00AE8CA70DA5C94670AF149B909BC91
       829848B4479470D843E800D366F735F7BCE5F209775156FB57F6B77316CD54F2
       558938D43D500160A280F299906C8119BF67E6B080522EB7BF074E3E20141EA3
       4F4DAABB32A15D3693E301ED3F0E35F2F663EC3F3F93DD63063ECFB12FD29CCE
       F01A15B0BE6BA9BB352F11FF7DC08DB863BE69A77E4F3644EA12F949A3167FC8
       2E67516B0572EC62AB9F05775636808B9E3C""",
    """08031279307702010104202D19BABF4420E2F25F075A71DA9DA86E29596C6013
       B8FD50D5999F98DF636226A00A06082A8648CE3D030107A14403420004AA407C
       C163A2BFF807DAE1BB58A67A3C1A3C80CF83C31C9736607407137511F06812B6
       F497BA747F5CA6CB69E21ADA2F291A6040D2D58BD254E1ECCB13B72999""",
    """08011240B9EA7F0357B5C1247E4FCB5AD09C46818ECB07318CA84711875F4C6C
       E6B946186A4EB44E0D714B2A2D48263D75CF52D30BEF9D9AE2A9FEB7DAF1775F
       E731065A"""
  ]
  PublicKeys = [
    """0800125E305C300D06092A864886F70D0101010500034B003048024100AD8A7D
       5B0EB7C852C1464E4567651F412C692534E1600FDC5BDA9EDBFA9927AF0FFA7C
       52599BE62999E085C345D21C8D43627CCC0E16D695C770E26D220AE709020301
       0001""",
    """080012A20130819F300D06092A864886F70D010101050003818D003081890281
       8100B91DCD5578C2FA3EA7D1DF62F59DEEDA834ECE568844554163E1803CDF4C
       2988BE182B8F957D3405BC745A33DA1E714ABA13C316683767735ED72AE8B356
       48FD6E33A49D696FADB6499C63A09204F0BF77B44D3917DC746FB7B520407257
       46A3140E96E8682A02A4767C280DEFBE58C6ACB6DD1EE63F3F589F4C7941B279
       57F70203010001""",
    """080012A60230820122300D06092A864886F70D01010105000382010F00308201
       0A0282010100C8B014EC01E135D635F7E246BA7D423E2B36F45B052F0B644DA6
       B1B6DD964696F279BB9BB5F5C41EE3204F74EF70C228C8CDD97E4F19094274EB
       01C292EC25055CB3CECD1A41E8919A0C111602B1B85B4E43DBB2F4898C527384
       65F35E3085586CF01E407BE6CB5F0C08D0AD6D6FE02A43C932E124E9C8498E67
       BA323CC84A275ACCC20D586C04DAF54FE98018FF1562E80514735A3237AA3C1D
       D2B4281FCAD3BD94952F0397A3F15B06269107C147C15645DCB507C566E66BF2
       4E2745A05E4D31F364C2C50C0F5C9A6889378051BF05669EA905C2370548D6EF
       2CF66A4A5DC23F10B7614BC43CF0BFCC8711B6FF9F645FC2E5713ED1CB597539
       2B8C865202690203010001""",
    """080012A60430820222300D06092A864886F70D01010105000382020F00308202
       0A0282020100E35735127777C52E66252B014E965001F3A515317B90DDAC8671
       F4F820AE67308DE2AA4162E99522CD6DA7EB9D7DB606489FEB77341A8FA058FA
       C832EE6EE5E978D512FF79461FC419A23B27C39C81BB635228B0DA5CFAE87080
       AC1AAE4619BF4576771E6E24A04D98D55ADA5CBA558EBE06ED14790D71438AFD
       C1FB9B4E2E623F221F8509A8CFE37265728EFBFAA60C76E6FBC4A473511CE6EE
       8A72C1CE1E5D67AB9FC4FA6FE797B854DFE7064C235ECB1379DB4B1E085F0042
       E19831D80CBE160A46C5154148A8D20E15C29F12AE208022EF094C5AC5651532
       68DE8318CAFC82D2D71839EA136756FD4EBC3951F260EE5DA51A63D9AC7B80B7
       968D769CC82DCE2494BAFE9505C124E947E0E8D3F4A6B207EE195B3FFBFED028
       DCE59DB5CD60B1C6C316B4A712DAC2E8BF46E006116685BB77D56E00B2A63B74
       CFA5C7CAD003BD2DA9F865239DAB45FE52DAB9C7928A705F3A0A3DCEC0B45A73
       DCE0A63DA1E24417ECD9C4B51342600CD2963BBA4FA3DF170666B9804E1BCC9E
       7CF171571CB336F383B5A0FA375F7A7F72CC4F4460B8255F4F38556C360D7129
       10B34A8ACE1C270175DFF5CECC7A34681835915BCE5FD4CA52D0F5A57685E28F
       5DCA1CA5A4410FDEAF516FC4F8226BCE2CFDBA9F830DD9A0903A18E009BBE818
       D52D11AD85974021CE0CC908DEC21FD6163EC7FD558150506FAE4FE6393EA3CC
       061EC9749DFD0203010001""",
    """0803125B3059301306072A8648CE3D020106082A8648CE3D03010703420004AA
       407CC163A2BFF807DAE1BB58A67A3C1A3C80CF83C31C9736607407137511F068
       12B6F497BA747F5CA6CB69E21ADA2F291A6040D2D58BD254E1ECCB13B72999""",
    """080112206A4EB44E0D714B2A2D48263D75CF52D30BEF9D9AE2A9FEB7DAF1775F
       E731065A"""
  ]
  # Key expanding test vectors obtained from Go implementation
  # https://github.com/libp2p/go-libp2p-crypto/blob/master/key.go
  Secrets = [
    # AES-128 SHA-256
    "4F13360145891C202B74FDCA838A85A37CBAEBF5E0774CC344BD6DABA9C4C86A",
    """4ED31DA5EEA36277CA9E1C198F3EBB89AE4A6B18B76E48CAE8AEC23A7D0D4E8F
       700D6696AB01365278E5C45C2B4B1807""",
    """01D4FBB5104F9B8DEDA95B447C1401A35F995B6BEFE20DBEFF9F7A13B7DA2831
       FB5A7EA194C4CE1ECE340B993C4C2C53FE641227DB7428B62BF4083686F6FF8F
       BE8C""",
    # Edge case (where Go implementation returns 65 bytes of secret)
    # Nim implementation has leading `00`.
    """00691BB84462F460D603B3F5FA0031D8DE195234C65B8890CBB6F84456E9718D
       4572749FC6040D0602698EEE6CCF6FB83101A26925D1A3AB40FB45BF98EAF06A
       2693""",
    # AES-256 SHA-512
    "1F29EC3E0A07994D2ACCEA23A2F570DA9C7A7E39D5026FE6340C1E551E1ADAAF",
    """85C20386C1EA1575DD8D111111DBC8B43CA630BEE4BB9AD91658719FF307C0BE
       0065935B8B849BE80E0D08A3D39098C3""",
    """01779213E2993A77F1E1BB3B4DB77B5900B53A3A31CDE95D352C695643879824
       C8EE6501DC8679F5735869251256830A31357B34FF463B9292C02CD22CD30351
       C44F""",
    # Edge case (where Go implementation returns 65 bytes of secret)
    # Nim implementation has leading `00`.
    """001CC33294544D898781010258C2FB81F02429D2DD54D0B59B8CD2335F57498F
       D4E444BEC94DA7BE2BAF3E3796AFA8388F626AEB3178355991985EE5FFC9D1AA
       CAD9""",
    # AES-256 SHA-1
    "85076756644AAC06A47B29E25CB39B3E0C717152EE587F50C5A10281DB7F2FA5",
    """256D46C5E5449AA7B9BE985646D5F32E455BB4B7AAF3566507A023B72801A7BC
       5066647E82DE2BC37FE22AB0DE440F77""",
    """01FF82C71215CFFD7A42A5CED03BD2256D4A5B6850472A5C5CA90665D510F038
       A21F3A6EA0BB0A64113960C54DDAFC5E7A5F018E4413D7CC93C736A8D30579ED
       5A2B""",
    # Edge case (where Go implementation returns 65 bytes of secret)
    # Nim implementation has leading `00`.
    """00360D9410E58534AC6A89CA5AC17E9455F619DCA71A6C2FB6F3156AE58DDB91
       6E9A7D223D1D7DD05D5475BFC4C517C85475600AAF6F28703ED1203281369A41
       9A7C"""
  ]
  Ivs = [
    "F643627AA8B91D40BA644B894C7F148E",
    "F1D6521E4EE59248F7CCFA6D6C916A32",
    "937D77D24441858AF5040C9A81B3D178",
    "C7D6AE667F38A3E0C77F4AC96D82112F",
    "735E51C37802A6E72277EE74C829A84D",
    "617BAEA342062AE87B7A5D5D9F99371C",
    "B535FFA95043C90C5FEEF3654E846445",
    "3B2D2219A7EE18AB9164910821955C05",
    "DACC23805C4ED233A7100A488AB5D68F",
    "C5BFA3F8BF0D8436840D1AAAF091BD69",
    "54CA4A681AEB8B5793A450100244256F",
    "D1EB94C73D4C033EA4130B47669F4485",
    "1F1ADF6BBDE1DFC5F922D672D2344F3A",
    "A828F6D249F38A917CD297F7BDDE7B70",
    "54FC8070579A17F6DAD342174062D60A",
    "D33C7696183DA21C5CD40AB677BECE7C",
    "9EFF93741DC080A15B9E554080AB9869",
    "7A007E351C9A5C930D01645D97648F8C",
    "934DB2529D1D3AC37BAD56FD1E522196",
    "30D19C3C1AB9A3391A5F88E92307261D",
    "32ED1A961630D94A279F99757B3131CB",
    "003ABE572377D59B74713425854FED29",
    "3338850C0A4D7BD53C70E40FA0079AA2",
    "62787F194DC218C5B0DAFD806F0D3125"
  ]
  CipherKeys = [
    "8C2964320284FAD935AFEC1AFEC9EEF7",
    "622A9292256B012F3EBE814C0DB22095",
    "3171DCDBE794BB6CAADDDD71E1751F2C",
    "5E1519DFCABA2AF17AA4AA580CC1B76E",
    "8B7AC311FF7B7EA7B4E55E37688DA2BD",
    "6BB6E06A3A92D5C300598023330712D4",
    "D794A6B794C1E3501A24240D348B9A62",
    "45E2FFAC35B7647AD5045C8581F39BF0",
    "B2F8CDBD11B158DC68120E10A6D04C0B272DC3F698EB56B18094275076307CEB",
    "E0238BAA6B77646CD708DD00DE1FD17C6BB45F184348F512F4AE64E00CEA37B9",
    "CE009DE8D1C76C2793540A8B24774E09B0F84590B583F1A0551AC0CF1E911BF9",
    "ED5F14E36F4F2F80084571B24FD55C870B9C2AD937694B75B90E67D3591DC921",
    "1607CC9FF2B19E8F0CDA902D5996948E8EA8CFFA03F956038497684088A88B2F",
    "FC2797D1040FF162A90275EBA3FCC4330C2BDC28D23DA80B89842C2D7A6EFA06",
    "B83698789ED8E3B44E48EAAEB291B3003AD95FAF344EBA1B9071F4FB46A4E4E9",
    "5D90C579971B7B7F9ECDE55EBCE8921B807AAD45D61952228758BA80F4490E8F",
    "1C429A32A2E16168D3E3F942AEEAD708456C6566D800D5B7A6DCE8184739F16D",
    "84987E7CC9F71243408454DD0787F438CCB62C79ED56078FD920FFFD7D5C44FF",
    "971372E385E0F9FED8F67C922D0F5EB77D7D7818F63B26EF80C4D3C81D9E1B97",
    "F20AE0A5387B2D1D38B8B340466D252F894C00C5907EE3A510442E4F38966AB0",
    "B58F32D83C7A91B6B1DA731334D70502348CD82EFB8258C0AE316B983F2F1E1E",
    "5903FE75A1C328BE6C98EB4A4EFF19C67D3C52C87B3131047F3773201D44BFCE",
    "55EAD85B3124C36828ED3A43698952111EECE8C7FB156D71EE3F84E088B4F4CE",
    "E4C99C782A88B69E5D83F4DEFDD2AE61A397486E17EC9EAE6EC679A75E47BBCD"
  ]
  MacKeys = [
    "2C812CB8425299B485CEE0BC97778F540380F14F",
    "8AB685E8A66256480E794B0ADC09BCF4014883C8",
    "C68EF3F3102D0CEFC0924FEF17D51FABC23EA54C",
    "F177BD066555CF25327C32C807D2E44B7DAC3EFF",
    "57176FF3103FA0F4EB58B9E49133C48B4DE9BDE6",
    "0C9ECECB80DF43CA2720DD340DD992A80AAB56DB",
    "028BCC3F5559CF43DA1B0C1A03E263C90D04DD77",
    "02DAF3FF888999C6121CA50F1D49C10FF55F1ACF",
    "6F015DDA49E0DFABD5532E6CB08709CE43F326EC",
    "68C703B3867247723D21A8C58BA9109DDBB359EF",
    "6C91DBB5FE99B94A11D0937D0F4E50F2BCB248F3",
    "D5A856ECC5820D611111BE8CEAAD781E6E4E549D",
    "9DCEB01D9657A69D40B1885C392FA850486E32B3",
    "EE66A1579D732E99A8500F48595BF25289E722DB",
    "E692EC73B0A2E68625221E1D01BA0E6B24BCB43F",
    "8613E8F86D2DD1CF3CEDC52AD91423F2F31E0003",
    "F8A7EF47F37257B54A5028424E64F172E532E7E7",
    "4D3596723AECD3DF21A20E956755782E783C9E4A",
    "484860090D99F4B702C809294037E6C7F6E58BBA",
    "15163D55C0A32E79E0EDD8E8EDA5AC9564B5488C",
    "6116BCB44773E3342AB5671D2AC107D4C9EC0757",
    "1CA3FCA023C72B7695481CA815856FEF0C5D7E9E",
    "E34004C383C36201DC23E062DAE791C76738C28E",
    "FA5CB0689A1DFDBAE8618BC079D70E318377B0DA"
  ]
 proc cmp(a, b: openarray[byte]): bool =
  result = (@a == @b)
 proc testStretcher(s, e: int, cs: CipherScheme, ds: DigestSheme): bool =
  for i in s..<e:
    var sharedsecret = fromHex(stripSpaces(Secrets[i]))
    var secret = stretchKeys(cs, ds, sharedsecret)
    var iv1 = fromHex(stripSpaces(Ivs[i * 2]))
    var iv2 = fromHex(stripSpaces(Ivs[i * 2 + 1]))
    var ckey1 = fromHex(stripSpaces(CipherKeys[i * 2]))
    var ckey2 = fromHex(stripSpaces(CipherKeys[i * 2 + 1]))
    var mkey1 = fromHex(stripSpaces(MacKeys[i * 2]))
    var mkey2 = fromHex(stripSpaces(MacKeys[i * 2 + 1]))
    var r1 = cmp(secret.ivOpenArray(0), iv1) == true
    var r2 = cmp(secret.ivOpenArray(1), iv2) == true
    var r3 = secret.iv(0) == iv1
    var r4 = secret.iv(1) == iv2
    var r5 = cmp(secret.keyOpenArray(0), ckey1) == true
    var r6 = cmp(secret.keyOpenArray(1), ckey2) == true
    var r7 = secret.key(0) == ckey1
    var r8 = secret.key(1) == ckey2
    var r9 = cmp(secret.macOpenArray(0), mkey1) == true
    var rA = cmp(secret.macOpenArray(1), mkey2) == true
    var rB = secret.mac(0) == mkey1
    var rC = secret.mac(1) == mkey2
    result = r1 and r2 and r3 and r4 and r5 and r6 and r7 and r8 and
             r9 and rA and rB and rC
    if not result:
      break
 suite "Key interface test suite":
  test "Go test vectors":
    for i in 0..<len(PrivateKeys):
      var seckey = PrivateKey.init(fromHex(stripSpaces(PrivateKeys[i])))
      var pubkey = PublicKey.init(fromHex(stripSpaces(PublicKeys[i])))
      var calckey = seckey.getKey()
      check:
        pubkey == calckey
      var checkseckey = seckey.getBytes()
      var checkpubkey = pubkey.getBytes()
      check:
        toHex(checkseckey) == stripSpaces(PrivateKeys[i])
        toHex(checkpubkey) == stripSpaces(PublicKeys[i])
  test "Go key stretch function AES128-SHA256 test vectors":
    check testStretcher(0, 4, Aes128, Sha256) == true
  test "Go key stretch function AES256-SHA512 test vectors":
    check testStretcher(4, 8, Aes256, Sha512) == true
  test "Go key stretch function AES256-SHA1 test vectors":
    check testStretcher(8, 12, Aes256, Sha1) == true