nim-libp2p/libp2p/crypto/secp.nim

219 lines
8.0 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.
{.push raises: [Defect].}
import
secp256k1, bearssl,
stew/[byteutils, results],
nimcrypto/[hash, sha2]
export sha2, results
const
SkRawPrivateKeySize* = 256 div 8
## Size of private key in octets (bytes)
SkRawSignatureSize* = SkRawPrivateKeySize * 2 + 1
## Size of signature in octets (bytes)
SkRawPublicKeySize* = SkRawPrivateKeySize + 1
## Size of public key in octets (bytes)
# This is extremely confusing but it's to avoid.. confusion between Eth standard and Secp standard
type
SkPrivateKey* = distinct secp256k1.SkSecretKey
SkPublicKey* = distinct secp256k1.SkPublicKey
SkSignature* = distinct secp256k1.SkSignature
SkKeyPair* = distinct secp256k1.SkKeyPair
template pubkey*(v: SkKeyPair): SkPublicKey = SkPublicKey(secp256k1.SkKeyPair(v).pubkey)
template seckey*(v: SkKeyPair): SkPrivateKey = SkPrivateKey(secp256k1.SkKeyPair(v).seckey)
proc random*(t: typedesc[SkPrivateKey], rng: var BrHmacDrbgContext): SkPrivateKey =
let rngPtr = unsafeAddr rng # doesn't escape
proc callRng(data: var openArray[byte]) =
brHmacDrbgGenerate(rngPtr[], data)
SkPrivateKey(SkSecretKey.random(callRng))
proc random*(t: typedesc[SkKeyPair], rng: var BrHmacDrbgContext): SkKeyPair =
let rngPtr = unsafeAddr rng # doesn't escape
proc callRng(data: var openArray[byte]) =
brHmacDrbgGenerate(rngPtr[], data)
SkKeyPair(secp256k1.SkKeyPair.random(callRng))
template seckey*(v: SkKeyPair): SkPrivateKey =
SkPrivateKey(secp256k1.SkKeyPair(v).seckey)
template pubkey*(v: SkKeyPair): SkPublicKey =
SkPublicKey(secp256k1.SkKeyPair(v).pubkey)
proc init*(key: var SkPrivateKey, data: openarray[byte]): SkResult[void] =
## Initialize Secp256k1 `private key` ``key`` from raw binary
## representation ``data``.
key = SkPrivateKey(? secp256k1.SkSecretKey.fromRaw(data))
ok()
proc init*(key: var SkPrivateKey, data: string): SkResult[void] =
## Initialize Secp256k1 `private key` ``key`` from hexadecimal string
## representation ``data``.
key = SkPrivateKey(? secp256k1.SkSecretKey.fromHex(data))
ok()
proc init*(key: var SkPublicKey, data: openarray[byte]): SkResult[void] =
## Initialize Secp256k1 `public key` ``key`` from raw binary
## representation ``data``.
key = SkPublicKey(? secp256k1.SkPublicKey.fromRaw(data))
ok()
proc init*(key: var SkPublicKey, data: string): SkResult[void] =
## Initialize Secp256k1 `public key` ``key`` from hexadecimal string
## representation ``data``.
key = SkPublicKey(? secp256k1.SkPublicKey.fromHex(data))
ok()
proc init*(sig: var SkSignature, data: openarray[byte]): SkResult[void] =
## Initialize Secp256k1 `signature` ``sig`` from raw binary
## representation ``data``.
sig = SkSignature(? secp256k1.SkSignature.fromDer(data))
ok()
proc init*(sig: var SkSignature, data: string): SkResult[void] =
## Initialize Secp256k1 `signature` ``sig`` from hexadecimal string
## representation ``data``.
# TODO DER vs raw here is fishy
var buffer: seq[byte]
try:
buffer = hexToSeqByte(data)
except ValueError:
return err("secp: Hex to bytes failed")
init(sig, buffer)
proc init*(t: typedesc[SkPrivateKey], data: openarray[byte]): SkResult[SkPrivateKey] =
## Initialize Secp256k1 `private key` from raw binary
## representation ``data``.
##
## Procedure returns `private key` on success.
SkSecretKey.fromRaw(data).mapConvert(SkPrivateKey)
proc init*(t: typedesc[SkPrivateKey], data: string): SkResult[SkPrivateKey] =
## Initialize Secp256k1 `private key` from hexadecimal string
## representation ``data``.
##
## Procedure returns `private key` on success.
SkSecretKey.fromHex(data).mapConvert(SkPrivateKey)
proc init*(t: typedesc[SkPublicKey], data: openarray[byte]): SkResult[SkPublicKey] =
## Initialize Secp256k1 `public key` from raw binary
## representation ``data``.
##
## Procedure returns `public key` on success.
var key: SkPublicKey
key.init(data) and ok(key)
proc init*(t: typedesc[SkPublicKey], data: string): SkResult[SkPublicKey] =
## Initialize Secp256k1 `public key` from hexadecimal string
## representation ``data``.
##
## Procedure returns `public key` on success.
var key: SkPublicKey
key.init(data) and ok(key)
proc init*(t: typedesc[SkSignature], data: openarray[byte]): SkResult[SkSignature] =
## Initialize Secp256k1 `signature` from raw binary
## representation ``data``.
##
## Procedure returns `signature` on success.
var sig: SkSignature
sig.init(data) and ok(sig)
proc init*(t: typedesc[SkSignature], data: string): SkResult[SkSignature] =
## Initialize Secp256k1 `signature` from hexadecimal string
## representation ``data``.
##
## Procedure returns `signature` on success.
var sig: SkSignature
sig.init(data) and ok(sig)
proc getPublicKey*(key: SkPrivateKey): SkPublicKey =
## Calculate and return Secp256k1 `public key` from `private key` ``key``.
SkPublicKey(SkSecretKey(key).toPublicKey())
proc toBytes*(key: SkPrivateKey, data: var openarray[byte]): SkResult[int] =
## Serialize Secp256k1 `private key` ``key`` to raw binary form and store it
## to ``data``.
##
## Procedure returns number of bytes (octets) needed to store
## Secp256k1 private key.
if len(data) >= SkRawPrivateKeySize:
data[0..<SkRawPrivateKeySize] = SkSecretKey(key).toRaw()
ok(SkRawPrivateKeySize)
else:
err("secp: Not enough bytes")
proc toBytes*(key: SkPublicKey, data: var openarray[byte]): SkResult[int] =
## Serialize Secp256k1 `public key` ``key`` to raw binary form and store it
## to ``data``.
##
## Procedure returns number of bytes (octets) needed to store
## Secp256k1 public key.
if len(data) >= SkRawPublicKeySize:
data[0..<SkRawPublicKeySize] = secp256k1.SkPublicKey(key).toRawCompressed()
ok(SkRawPublicKeySize)
else:
err("secp: Not enough bytes")
proc toBytes*(sig: SkSignature, data: var openarray[byte]): int =
## Serialize Secp256k1 `signature` ``sig`` to raw binary form and store it
## to ``data``.
##
## Procedure returns number of bytes (octets) needed to store
## Secp256k1 signature.
secp256k1.SkSignature(sig).toDer(data)
proc getBytes*(key: SkPrivateKey): seq[byte] {.inline.} =
## Serialize Secp256k1 `private key` and return it.
@(SkSecretKey(key).toRaw())
proc getBytes*(key: SkPublicKey): seq[byte] {.inline.} =
## Serialize Secp256k1 `public key` and return it.
@(secp256k1.SkPublicKey(key).toRawCompressed())
proc getBytes*(sig: SkSignature): seq[byte] {.inline.} =
## Serialize Secp256k1 `signature` and return it.
result = newSeq[byte](72)
let length = toBytes(sig, result)
result.setLen(length)
proc sign*[T: byte|char](key: SkPrivateKey, msg: openarray[T]): SkSignature =
## Sign message `msg` using private key `key` and return signature object.
let h = sha256.digest(msg)
SkSignature(sign(SkSecretKey(key), SkMessage(h.data)))
proc verify*[T: byte|char](sig: SkSignature, msg: openarray[T],
key: SkPublicKey): bool =
let h = sha256.digest(msg)
verify(secp256k1.SkSignature(sig), SkMessage(h.data), secp256k1.SkPublicKey(key))
func clear*(key: var SkPrivateKey) = clear(secp256k1.SkSecretKey(key))
func `$`*(key: SkPrivateKey): string = $secp256k1.SkSecretKey(key)
func `$`*(key: SkPublicKey): string = $secp256k1.SkPublicKey(key)
func `$`*(key: SkSignature): string = $secp256k1.SkSignature(key)
func `$`*(key: SkKeyPair): string = $secp256k1.SkKeyPair(key)
func `==`*(a, b: SkPrivateKey): bool =
secp256k1.SkSecretKey(a) == secp256k1.SkSecretKey(b)
func `==`*(a, b: SkPublicKey): bool =
secp256k1.SkPublicKey(a) == secp256k1.SkPublicKey(b)
func `==`*(a, b: SkSignature): bool =
secp256k1.SkSignature(a) == secp256k1.SkSignature(b)
func `==`*(a, b: SkKeyPair): bool =
secp256k1.SkKeyPair(a) == secp256k1.SkKeyPair(b)