nim-libp2p/libp2p/crypto/crypto.nim

763 lines
26 KiB
Nim

## 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, ed25519/ed25519, secp
import ../protobuf/minprotobuf, ../vbuffer, ../multihash, ../multicodec
import nimcrypto/[rijndael, blowfish, twofish, sha, sha2, hash, hmac, utils]
# This is workaround for Nim's `import` bug
export rijndael, blowfish, twofish, sha, sha2, hash, hmac, utils
from strutils import split
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:
skkey*: SkPublicKey
of ECDSA:
eckey*: EcPublicKey
of NoSupport:
discard
PrivateKey* = object
case scheme*: PKScheme
of RSA:
rsakey*: RsaPrivateKey
of Ed25519:
edkey*: EdPrivateKey
of Secp256k1:
skkey*: SkPrivateKey
of ECDSA:
eckey*: EcPrivateKey
of NoSupport:
discard
KeyPair* = object
seckey*: PrivateKey
pubkey*: PublicKey
Secret* = object
ivsize*: int
keysize*: int
macsize*: int
data*: seq[byte]
Signature* = object
data*: seq[byte]
P2pKeyError* = object of CatchableError
P2pSigError* = object of CatchableError
const
SupportedSchemes* = {RSA, Ed25519, Secp256k1, ECDSA}
SupportedSchemesInt* = {int8(RSA), int8(Ed25519), int8(Secp256k1),
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.
doAssert(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)
elif scheme == Secp256k1:
result.skkey = SkPrivateKey.random()
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.
doAssert(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
elif scheme == Secp256k1:
var pair = SkKeyPair.random()
result.seckey.skkey = pair.seckey
result.pubkey.skkey = 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()
elif key.scheme == Secp256k1:
result.skkey = key.skkey.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)
elif key.scheme == Secp256k1:
result = key.skkey.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)
elif key.scheme == Secp256k1:
result = key.skkey.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()
elif key.scheme == Secp256k1:
result = key.skkey.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()
elif key.scheme == Secp256k1:
result = key.skkey.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 toBytes*(sig: Signature, data: var openarray[byte]): int =
## Serialize signature ``sig`` and store it to ``data``.
##
## Returns number of bytes (octets) needed to store signature ``sig``.
result = len(sig.data)
if len(data) >= result:
copyMem(addr data[0], unsafeAddr sig.data[0], len(sig.data))
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 getBytes*(sig: Signature): seq[byte] =
## Return signature ``sig`` in binary form.
result = sig.data
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
elif scheme == Secp256k1:
if init(nkey.skkey, buffer):
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
elif scheme == Secp256k1:
if init(nkey.skkey, buffer):
key = nkey
result = true
proc init*(sig: var Signature, data: openarray[byte]): bool =
## Initialize signature ``sig`` from raw binary form.
##
## Returns ``true`` on success.
if len(data) > 0:
sig.data = @data
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*(sig: var Signature, data: string): bool =
## Initialize signature ``sig`` from serialized hexadecimal string
## representation.
##
## Returns ``true`` on success.
result = sig.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[Signature], data: openarray[byte]): Signature =
## Create new public key from libp2p's protobuf serialized binary form.
if not result.init(data):
raise newException(P2pSigError, "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 init*(t: typedesc[Signature], data: string): Signature =
## Create new signature from 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($(key.eckey))
result.add(")")
elif key.scheme == Secp256k1:
result = "Secp256k1 key ("
result.add($(key.skkey))
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($(key.eckey))
result.add(")")
elif key.scheme == Secp256k1:
result = "Secp256k1 key ("
result.add($(key.skkey))
result.add(")")
proc `$`*(sig: Signature): string =
## Get string representation of signature ``sig``.
result = toHex(sig.data)
proc sign*(key: PrivateKey, data: openarray[byte]): Signature =
## 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.data = sig.getBytes()
elif key.scheme == Ed25519:
var sig = key.edkey.sign(data)
result.data = sig.getBytes()
elif key.scheme == ECDSA:
var sig = key.eckey.sign(data)
result.data = sig.getBytes()
elif key.scheme == Secp256k1:
var sig = key.skkey.sign(data)
result.data = sig.getBytes()
proc verify*(sig: Signature, 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.data) == Asn1Status.Success:
result = signature.verify(message, key.rsakey)
elif key.scheme == Ed25519:
var signature: EdSignature
if signature.init(sig.data):
result = signature.verify(message, key.edkey)
elif key.scheme == ECDSA:
var signature: EcSignature
if signature.init(sig.data) == Asn1Status.Success:
result = signature.verify(message, key.eckey)
elif key.scheme == Secp256k1:
var signature: SkSignature
if signature.init(sig.data):
result = signature.verify(message, key.skkey)
template makeSecret(buffer, hmactype, secret, seed: untyped) {.dirty.}=
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*(cipherType: string, hashType: string,
sharedSecret: seq[byte]): Secret =
## Expand shared secret to cryptographic keys.
if cipherType == "AES-128":
result.ivsize = aes128.sizeBlock
result.keysize = aes128.sizeKey
elif cipherType == "AES-256":
result.ivsize = aes256.sizeBlock
result.keysize = aes256.sizeKey
elif cipherType == "TwofishCTR":
result.ivsize = twofish256.sizeBlock
result.keysize = twofish256.sizeKey
elif cipherType == "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 hashType == "SHA256":
makeSecret(result.data, HMAC[sha256], sharedSecret, seed)
elif hashType == "SHA512":
makeSecret(result.data, HMAC[sha512], sharedSecret, seed)
elif hashType == "SHA1":
makeSecret(result.data, HMAC[sha1], sharedSecret, 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 ephemeral*(scheme: string): KeyPair {.inline.} =
## Generate ephemeral keys used to perform ECDHE using string encoding.
##
## Currently supported encoding strings are P-256, P-384, P-521, if encoding
## string is not supported P-521 key will be generated.
if scheme == "P-256":
result = ephemeral(Secp256r1)
elif scheme == "P-384":
result = ephemeral(Secp384r1)
elif scheme == "P-521":
result = ephemeral(Secp521r1)
else:
result = ephemeral(Secp521r1)
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``.
##
## Note this procedure supports only ECDSA keys.
##
## 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)
proc getSecret*(remoteEPublic: PublicKey,
localEPrivate: PrivateKey): seq[byte] =
## Calculate shared secret using remote ephemeral public key
## ``remoteEPublic`` and local ephemeral private key ``localEPrivate`` and
## store shared secret to ``data``.
##
## Note this procedure supports only ECDSA keys.
##
## Returns shared secret on success.
if remoteEPublic.scheme == ECDSA:
if localEPrivate.scheme == remoteEPublic.scheme:
result = getSecret(remoteEPublic.eckey, localEPrivate.eckey)
proc getOrder*(remotePubkey, localNonce: openarray[byte],
localPubkey, remoteNonce: openarray[byte]): int =
## Compare values and calculate `order` parameter.
var ctx: sha256
ctx.init()
ctx.update(remotePubkey)
ctx.update(localNonce)
var digest1 = ctx.finish()
ctx.init()
ctx.update(localPubkey)
ctx.update(remoteNonce)
var digest2 = ctx.finish()
var mh1 = MultiHash.init(multiCodec("sha2-256"), digest1)
var mh2 = MultiHash.init(multiCodec("sha2-256"), digest2)
for i in 0 ..< len(mh1.data.buffer):
result = int(mh1.data.buffer[i]) - int(mh2.data.buffer[i])
if result != 0:
if result < 0:
result = -1
elif result > 0:
result = 1
break
proc selectBest*(order: int, p1, p2: string): string =
## Determines which algorithm to use from list `p1` and `p2`.
##
## Returns empty string if there no algorithms in common.
var f, s: seq[string]
if order < 0:
f = strutils.split(p2, ",")
s = strutils.split(p1, ",")
elif order > 0:
f = strutils.split(p1, ",")
s = strutils.split(p2, ",")
else:
var p = strutils.split(p1, ",")
result = p[0]
return
for felement in f:
for selement in s:
if felement == selement:
result = felement
return
proc createProposal*(nonce, pubkey: openarray[byte],
exchanges, ciphers, hashes: string): seq[byte] =
## Create SecIO proposal message using random ``nonce``, local public key
## ``pubkey``, comma-delimieted list of supported exchange schemes
## ``exchanges``, comma-delimeted list of supported ciphers ``ciphers`` and
## comma-delimeted list of supported hashes ``hashes``.
var msg = initProtoBuffer({WithUint32BeLength})
msg.write(initProtoField(1, nonce))
msg.write(initProtoField(2, pubkey))
msg.write(initProtoField(3, exchanges))
msg.write(initProtoField(4, ciphers))
msg.write(initProtoField(5, hashes))
msg.finish()
shallowCopy(result, msg.buffer)
proc decodeProposal*(message: seq[byte], nonce, pubkey: var seq[byte],
exchanges, ciphers, hashes: var string): bool =
## Parse incoming proposal message and decode remote random nonce ``nonce``,
## remote public key ``pubkey``, comma-delimieted list of supported exchange
## schemes ``exchanges``, comma-delimeted list of supported ciphers
## ``ciphers`` and comma-delimeted list of supported hashes ``hashes``.
##
## Procedure returns ``true`` on success and ``false`` on error.
var pb = initProtoBuffer(message)
if pb.getLengthValue(1, nonce) != -1 and
pb.getLengthValue(2, pubkey) != -1 and
pb.getLengthValue(3, exchanges) != -1 and
pb.getLengthValue(4, ciphers) != -1 and
pb.getLengthValue(5, hashes) != -1:
result = true
proc createExchange*(epubkey, signature: openarray[byte]): seq[byte] =
## Create SecIO exchange message using ephemeral public key ``epubkey`` and
## signature of proposal blocks ``signature``.
var msg = initProtoBuffer({WithUint32BeLength})
msg.write(initProtoField(1, epubkey))
msg.write(initProtoField(2, signature))
msg.finish()
shallowCopy(result, msg.buffer)
proc decodeExchange*(message: seq[byte],
pubkey, signature: var seq[byte]): bool =
## Parse incoming exchange message and decode remote ephemeral public key
## ``pubkey`` and signature ``signature``.
##
## Procedure returns ``true`` on success and ``false`` on error.
var pb = initProtoBuffer(message)
if pb.getLengthValue(1, pubkey) != -1 and
pb.getLengthValue(2, signature) != -1:
result = true
## Serialization/Deserialization helpers
proc write*(vb: var VBuffer, pubkey: PublicKey) {.inline.} =
## Write PublicKey value ``pubkey`` to buffer ``vb``.
vb.writeSeq(pubkey.getBytes())
proc write*(vb: var VBuffer, seckey: PrivateKey) {.inline.} =
## Write PrivateKey value ``seckey`` to buffer ``vb``.
vb.writeSeq(seckey.getBytes())
proc write*(vb: var VBuffer, sig: PrivateKey) {.inline.} =
## Write Signature value ``sig`` to buffer ``vb``.
vb.writeSeq(sig.getBytes())
proc initProtoField*(index: int, pubkey: PublicKey): ProtoField =
## Initialize ProtoField with PublicKey ``pubkey``.
result = initProtoField(index, pubkey.getBytes())
proc initProtoField*(index: int, seckey: PrivateKey): ProtoField =
## Initialize ProtoField with PrivateKey ``seckey``.
result = initProtoField(index, seckey.getBytes())
proc initProtoField*(index: int, sig: Signature): ProtoField =
## Initialize ProtoField with Signature ``sig``.
result = initProtoField(index, sig.getBytes())
proc getValue*(data: var ProtoBuffer, field: int, value: var PublicKey): int =
## Read ``PublicKey`` from ProtoBuf's message and validate it.
var buf: seq[byte]
var key: PublicKey
result = getLengthValue(data, field, buf)
if result > 0:
if not key.init(buf):
result = -1
else:
value = key
proc getValue*(data: var ProtoBuffer, field: int, value: var PrivateKey): int =
## Read ``PrivateKey`` from ProtoBuf's message and validate it.
var buf: seq[byte]
var key: PrivateKey
result = getLengthValue(data, field, buf)
if result > 0:
if not key.init(buf):
result = -1
else:
value = key
proc getValue*(data: var ProtoBuffer, field: int, value: var Signature): int =
## Read ``Signature`` from ProtoBuf's message and validate it.
var buf: seq[byte]
var sig: Signature
result = getLengthValue(data, field, buf)
if result > 0:
if not sig.init(buf):
result = -1
else:
value = sig