Background
Asymmetric algorithms have three different purposes (that I know of)
- Encryption
- RSA is the only "standard" algorithm that can do this directly.
- Signature
- RSA
- DSA
- ECDSA
- ElGamal Signature
- Key Agreement
- Diffie-Hellman (DH)
- ECDH
- ElGamal encryption (the asymmetric startup phase)
- MQV
- ECMQV
Because RSA encryption is space limited, and was hard for computers in the '90s, RSA encryption's primary use was in "Key Transfer", which is to say that the "encrypted message" was just the symmetric encryption key for DES/3DES (AES not yet having been invented) - https://www.rfc-editor.org/rfc/rfc2313#section-8.
Key agreement (or transfer) schemes always have to be combined with a protocol/scheme to result in an encryption operation. Such schemes include
- TLS (nee SSL)
- CMS or S/MIME encrypted-data
- IES (Integrated Encryption Scheme)
- ECIES (Elliptic Curve Integrated Encryption Scheme)
- ElGamal encryption (holistically)
- PGP encryption
So what you probably want is ECIES.
ECIES.Net
Currently (.NET Framework 4.7.1, .NET Core 2.0) there's no support to get an ECDiffieHellman object from a certificate in .NET.
Game over, right? Well, probably not. Unless a certificate carrying an ECDH key explicitly uses the id-ecDH algorithm identifier (vs the more standard id-ecc one) it can be opened as ECDSA. Then, you can coerce that object into being ECDH:
using (ECDsa ecdsa = cert.GetECDsaPublicKey())
{
return ECDiffieHellman.Create(ecdsa.ExportParameters(false));
}
(a similar thing can be done for a private key, if the key is exportable, otherwise complex things are required, but you shouldn't need it)
Let's go ahead and carve off the recipient public object:
ECDiffieHellmanPublicKey recipientPublic = GetECDHFromCertificate(cert).PublicKey;
ECCurve curve = recipientPublic.ExportParameters().Curve;
So now we turn to http://www.secg.org/sec1-v2.pdf section 5.1 (Elliptic Curve Integrated Encryption Scheme)
Setup
- Choose ANSI-X9.63-KDF with SHA-2-256 as the hash function.
- Choose HMAC–SHA-256–256.
- Choose AES–256 in CBC mode.
- Choose Elliptic Curve Diffie-Hellman Primitive.
- You already chose secp256r1.
- Hard-coded. Done.
- Point compression's annoying, choose not to use it.
- I'm omitting SharedInfo. That probably makes me a bad person.
- Not using XOR, N/A.
Encrypt
Make an ephemeral key on the right curve.
ECDiffieHellman ephem = ECDiffieHellman.Create(curve);
We decided no.
ECParameters ephemPublicParams = ephem.ExportParameters(false);
int pointLen = ephemPublicParams.Q.X.Length;
byte[] rBar = new byte[pointLen * 2 + 1];
rBar[0] = 0x04;
Buffer.BlockCopy(ephemPublicParams.Q.X, 0, rBar, 1, pointLen);
Buffer.BlockCopy(ephemPublicParams.Q.Y, 0, rBar, 1 + pointLen, pointLen);
Can't directly do this, moving on.
Can't directly do this, moving on.
Since we're in control here, we'll just do 3, 4, 5, and 6 as one thing.
KDF time.
// This is why we picked AES 256, HMAC-SHA-2-256(-256) and SHA-2-256,
// the KDF is dead simple.
byte[] ek = ephem.DeriveKeyFromHash(
recipientPublic,
HashAlgorithmName.SHA256,
null,
new byte[] { 0, 0, 0, 1 });
byte[] mk = ephem.DeriveKeyFromHash(
recipientPublic,
HashAlgorithmName.SHA256,
null,
new byte[] { 0, 0, 0, 2 });
Encrypt stuff.
byte[] em;
// ECIES uses AES with the all zero IV. Since the key is never reused,
// there's not risk in that.
using (Aes aes = Aes.Create())
using (ICryptoTransform encryptor = aes.CreateEncryptor(ek, new byte[16]))
{
if (!encryptor.CanTransformMultipleBlocks)
{
throw new InvalidOperationException();
}
em = encryptor.TransformFinalBlock(message, 0, message.Length);
}
MAC it
byte[] d;
using (HMAC hmac = new HMACSHA256(mk))
{
d = hmac.ComputeHash(em);
}
Finish
// Either
return Tuple.Create(rBar, em, d);
// Or
return rBar.Concat(em).Concat(d).ToArray();
Decrypt
Left as an exercise to the reader.
