Awesome
🔐 secp256k1.swift
Swift package with elliptic curve public key cryptography, ECDSA, Schnorr Signatures for Bitcoin and C bindings from libsecp256k1.
Objectives
Long-term goals are:
- Lightweight ECDSA & Schnorr Signatures functionality
- Built for simple or advance usage with things like BIP340
- Exposed C bindings to take full control of the secp256k1 implementation
- Familiar API design by modeling after Swift Crypto
- Automatic updates for Swift and libsecp256k1
- Availability for Linux and Apple platform ecosystems
Getting Started
This repository primarily uses Swift package manager as its build tool, so we recommend using that as well. Xcode comes with built-in support for Swift packages. From the menu bar, goto: File > Add Packages... If you manage packages via a Package.swift file, simply add secp256k1.swift as a dependencies' clause in your Swift manifest:
.package(name: "secp256k1.swift", url: "https://github.com/GigaBitcoin/secp256k1.swift.git", exact: "0.15.0"),
Include secp256k1 as a dependency for your executable target:
.target(name: "<target>", dependencies: [
.product(name: "secp256k1", package: "secp256k1.swift")
]),
Try in a playground using the SPI Playgrounds app or 🏟 Arena
arena GigaBitcoin/secp256k1.swift
Example Usage
ECDSA
import secp256k1
// Private key
let privateBytes = try! "14E4A74438858920D8A35FB2D88677580B6A2EE9BE4E711AE34EC6B396D87B5C".bytes
let privateKey = try! secp256k1.Signing.PrivateKey(rawRepresentation: privateBytes)
// Public key
print(String(bytes: privateKey.publicKey.rawRepresentation))
// ECDSA
let messageData = "We're all Satoshi.".data(using: .utf8)!
let signature = try! privateKey.signature(for: messageData)
// DER signature
print(try! signature.derRepresentation.base64EncodedString())
Schnorr
// Strict BIP340 mode is disabled by default for Schnorr signatures with variable length messages
let privateKey = try! secp256k1.Schnorr.PrivateKey()
// Extra params for custom signing
var auxRand = try! "C87AA53824B4D7AE2EB035A2B5BBBCCC080E76CDC6D1692C4B0B62D798E6D906".bytes
var messageDigest = try! "7E2D58D8B3BCDF1ABADEC7829054F90DDA9805AAB56C77333024B9D0A508B75C".bytes
// API allows for signing variable length messages
let signature = try! privateKey.signature(message: &messageDigest, auxiliaryRand: &auxRand)
Tweak
let privateKey = try! secp256k1.Signing.PrivateKey()
// Adding a tweak to the private key and public key
let tweak = try! "5f0da318c6e02f653a789950e55756ade9f194e1ec228d7f368de1bd821322b6".bytes
let tweakedPrivateKey = try! privateKey.add(tweak)
let tweakedPublicKeyKey = try! privateKey.publicKey.add(tweak)
Elliptic Curve Diffie Hellman
let privateKey = try! secp256k1.KeyAgreement.PrivateKey()
let publicKey = try! secp256k1.KeyAgreement.PrivateKey().publicKey
// Create a compressed shared secret with a private key from only a public key
let sharedSecret = try! privateKey.sharedSecretFromKeyAgreement(with: publicKey, format: .compressed)
// By default, libsecp256k1 hashes the x-coordinate with version information.
let symmetricKey = SHA256.hash(data: sharedSecret.bytes)
Silent Payments Scheme
let privateSign1 = try! secp256k1.Signing.PrivateKey()
let privateSign2 = try! secp256k1.Signing.PrivateKey()
let privateKey1 = try! secp256k1.KeyAgreement.PrivateKey(rawRepresentation: privateSign1.rawRepresentation)
let privateKey2 = try! secp256k1.KeyAgreement.PrivateKey(rawRepresentation: privateSign2.rawRepresentation)
let sharedSecret1 = try! privateKey1.sharedSecretFromKeyAgreement(with: privateKey2.publicKey)
let sharedSecret2 = try! privateKey2.sharedSecretFromKeyAgreement(with: privateKey1.publicKey)
let sharedSecretSign1 = try! secp256k1.Signing.PrivateKey(rawRepresentation: sharedSecret1.bytes)
let sharedSecretSign2 = try! secp256k1.Signing.PrivateKey(rawRepresentation: sharedSecret2.bytes)
// Payable Silent Payment public key
let xonlyTweak2 = try! sharedSecretSign2.publicKey.xonly.add(privateSign1.publicKey.xonly.bytes)
// Spendable Silent Payment private key
let privateTweak1 = try! sharedSecretSign1.add(xonly: privateSign1.publicKey.xonly.bytes)
Recovery
let privateKey = try! secp256k1.Recovery.PrivateKey()
let messageData = "We're all Satoshi.".data(using: .utf8)!
// Create a recoverable ECDSA signature
let recoverySignature = try! privateKey.signature(for: messageData)
// Recover an ECDSA public key from a signature
let publicKey = try! secp256k1.Recovery.PublicKey(messageData, signature: recoverySignature)
// Convert a recoverable signature into a normal signature
let signature = try! recoverySignature.normalize
Combine Public Keys
let privateKey = try! secp256k1.Signing.PrivateKey()
let publicKey = try! secp256k1.Signing.PrivateKey().public
// The Combine API arguments are an array of PublicKey objects and an optional format
publicKey.combine([privateKey.publicKey], format: .uncompressed)
PEM Key Format
let privateKeyString = """
-----BEGIN EC PRIVATE KEY-----
MHQCAQEEIBXwHPDpec6b07GeLbnwetT0dvWzp0nV3MR+4pPKXIc7oAcGBSuBBAAK
oUQDQgAEt2uDn+2GqqYs/fmkBr5+rCQ3oiFSIJMAcjHIrTDS6HEELgguOatmFBOp
2wU4P2TAl/0Ihiq+nMkrAIV69m2W8g==
-----END EC PRIVATE KEY-----
"""
// Import keys generated from OpenSSL
let privateKey = try! secp256k1.Signing.PrivateKey(pemRepresentation: privateKeyString)
Danger
These APIs should not be considered stable and may change at any time.