A cross platform Swift implementation of Elliptic Curve Digital Signature Algorithm (ECDSA) and Elliptic Curve Integrated Encryption Scheme (ECIES). This allows you to sign, verify, encrypt and decrypt using elliptic curve keys.
The latest version of BlueECC requires Swift 4.1 or later. You can download this version of the Swift binaries by following this link. Compatibility with other Swift versions is not guaranteed.
Add the BlueECC
package to the dependencies within your application’s Package.swift
file. Substitute "x.x.x"
with the latest BlueECC
release.
.package(url: "https://github.com/IBM-Swift/BlueECC.git", from: "x.x.x")
Add CryptorECC
to your target's dependencies:
.target(name: "example", dependencies: ["CryptorECC"]),
import CryptorECC
you can generate an ECPrivate key using BlueECC.
let p256PrivateKey = try ECPrivateKey.make(for: .prime256v1)
You can then view the key in it's PEM format as follows:
let privateKeyPEM = p256PrivateKey.pemString
The following curves are supported:
- prime256v1
- secp384r1
- secp521r1
Alternatively, you may generate private key using a third party provider:
- You can generate a
p-256
private key as a.p8
file for Apple services from https://developer.apple.com/account/ios/authkey. This will produce a key that should be formatted as follows:
let privateKey =
"""
-----BEGIN PRIVATE KEY-----
MIGHAgEAMBMGByqGSM49AgEGCCqGSM49AwEHBG0wawIBAQQglf7ztYnsaHX2yiHJ
meHFl5dg05y4a/hD7wwuB7hSRpmhRANCAASKRzmboLbG0NZ54B5PXxYSU7fvO8U7
PyniQCWG+Agc3bdcgKU0RKApWYuBJKrZqyqLB2tTlgdtwcWSB0AEzVI8
-----END PRIVATE KEY-----
"""
- You can use OpenSSL Command Line Elliptic Curve Operations.
The following commands generate private keys for the three supported curves as .pem
files:
// p-256
$ openssl ecparam -name prime256v1 -genkey -noout -out key.pem
// p-384
$ openssl ecparam -name secp384r1 -genkey -noout -out key.pem
// p-521
$ openssl ecparam -name secp521r1 -genkey -noout -out key.pem
These keys will be formatted as follows:
let privateKey =
"""
-----BEGIN EC PRIVATE KEY-----
MHcCAQEEIJX+87WJ7Gh19sohyZnhxZeXYNOcuGv4Q+8MLge4UkaZoAoGCCqGSM49
AwEHoUQDQgAEikc5m6C2xtDWeeAeT18WElO37zvFOz8p4kAlhvgIHN23XIClNESg
KVmLgSSq2asqiwdrU5YHbcHFkgdABM1SPA==
-----END EC PRIVATE KEY-----
"""
The key string can then be used to initialize an ECPrivateKey
instance:
let eccPrivateKey = try ECPrivateKey(key: privateKey)
You can use OpenSSL to generate an elliptic curve public key .pem
file from any of the above elliptic curve private key files:
$ openssl ec -in key.pem -pubout -out public.pem
This will produce a public key formatted as follows:
let publicKey =
"""
-----BEGIN PUBLIC KEY-----
MFkwEwYHKoZIzj0CAQYIKoZIzj0DAQcDQgAEikc5m6C2xtDWeeAeT18WElO37zvF
Oz8p4kAlhvgIHN23XIClNESgKVmLgSSq2asqiwdrU5YHbcHFkgdABM1SPA==
-----END PUBLIC KEY-----
"""
These keys can then be used to initialize an ECPrivateKey
instance:
let eccPublicKey = try ECPublicKey(key: publicKey)
Alternatively, you can extract the public key from your ECPrivateKey
:
let eccPublicKey = try eccPrivateKey.extractPublicKey()
print(eccPublicKey.pemString)
BlueECC extends String
and Data
so you can call sign directly on your plaintext using an EC private key. This creates an ECSignature
containing the r and s signature values:
let message = "hello world"
let signature = try message.sign(with: eccPrivateKey)
Use the public key to verify the signature for the plaintext:
let verified = signature.verify(plaintext: message, using: eccPublicKey)
if verified {
print("Signature is valid for provided plaintext")
}
Use the public key to encrypt your plaintext String or Data to encrypted Data or an encrypted Base64Encoded String:
let encryptedData = try "Hello World".encrypt(with: eccPublicKey)
print(encryptedData.base64EncodedString())
Use the private key to decrypt the encrypted Data or Base64Encoded String to plaintext Data or UTF8 String:
let decryptedData = try encryptedData.decrypt(with: eccPrivateKey)
print(String(data: decryptedData, encoding: .utf8))
Cross platform encryption and decryption is currently only supported with prime256v1
curves. The secp384r1
and secp521r1
curves do not support Linux encryption with Apple platform decryption and vice versa.
If you would like to interoperate with this repo, The following describes the encryption process:
- Generate an ephemeral EC key pair
- Use ECDH of your EC pair to generate a symmetric key
- Use SHA256 ANSI x9.63 Key Derivation Function with the ephemeral public key to generate a 32 byte key
- Use the first 16 bytes as an AES-GCM key
- Use the second 16 bytes as the initialization vector (IV)
- Use aes_128_gcm to encrypt the plaintext and generate a 16 byte GCM tag
- Send the ephemeral public key, encrypted data and GCM tag
This is equivalent to: kSecKeyAlgorithmECIESEncryptionStandardVariableIVX963SHA256AESGCM
when using apple security.
For more information visit our API reference.
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This library is licensed under Apache 2.0. Full license text is available in LICENSE.