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/*
This file is part of cpp-ethereum.
cpp-ethereum is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
cpp-ethereum is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with cpp-ethereum. If not, see <http://www.gnu.org/licenses/>.
*/
/** @file CryptoPP.cpp
* @author Alex Leverington <nessence@gmail.com>
* @date 2014
*/
#include <libdevcore/Guards.h>
#include <libdevcore/Assertions.h>
#include "ECDHE.h"
#include "CryptoPP.h"
using namespace std;
using namespace dev;
using namespace dev::crypto;
using namespace CryptoPP;
static_assert(dev::Secret::size == 32, "Secret key must be 32 bytes.");
static_assert(dev::Public::size == 64, "Public key must be 64 bytes.");
static_assert(dev::Signature::size == 65, "Signature must be 65 bytes.");
bytes Secp256k1PP::eciesKDF(Secret const& _z, bytes _s1, unsigned kdByteLen)
{
auto reps = ((kdByteLen + 7) * 8) / (CryptoPP::SHA256::BLOCKSIZE * 8);
// SEC/ISO/Shoup specify counter size SHOULD be equivalent
// to size of hash output, however, it also notes that
// the 4 bytes is okay. NIST specifies 4 bytes.
bytes ctr({0, 0, 0, 1});
bytes k;
CryptoPP::SHA256 ctx;
for (unsigned i = 0; i <= reps; i++)
{
ctx.Update(ctr.data(), ctr.size());
ctx.Update(_z.data(), Secret::size);
ctx.Update(_s1.data(), _s1.size());
// append hash to k
bytes digest(32);
ctx.Final(digest.data());
ctx.Restart();
k.reserve(k.size() + h256::size);
move(digest.begin(), digest.end(), back_inserter(k));
if (++ctr[3] || ++ctr[2] || ++ctr[1] || ++ctr[0])
continue;
}
k.resize(kdByteLen);
return k;
}
void Secp256k1PP::encryptECIES(Public const& _k, bytes& io_cipher)
{
// interop w/go ecies implementation
auto r = KeyPair::create();
Secret z;
ecdh::agree(r.sec(), _k, z);
auto key = eciesKDF(z, bytes(), 32);
bytesConstRef eKey = bytesConstRef(&key).cropped(0, 16);
bytesRef mKeyMaterial = bytesRef(&key).cropped(16, 16);
CryptoPP::SHA256 ctx;
ctx.Update(mKeyMaterial.data(), mKeyMaterial.size());
bytes mKey(32);
ctx.Final(mKey.data());
bytes cipherText = encryptSymNoAuth(SecureFixedHash<16>(eKey), h128(), bytesConstRef(&io_cipher));
if (cipherText.empty())
return;
bytes msg(1 + Public::size + h128::size + cipherText.size() + 32);
msg[0] = 0x04;
r.pub().ref().copyTo(bytesRef(&msg).cropped(1, Public::size));
bytesRef msgCipherRef = bytesRef(&msg).cropped(1 + Public::size + h128::size, cipherText.size());
bytesConstRef(&cipherText).copyTo(msgCipherRef);
// tag message
CryptoPP::HMAC<SHA256> hmacctx(mKey.data(), mKey.size());
bytesConstRef cipherWithIV = bytesRef(&msg).cropped(1 + Public::size, h128::size + cipherText.size());
hmacctx.Update(cipherWithIV.data(), cipherWithIV.size());
hmacctx.Final(msg.data() + 1 + Public::size + cipherWithIV.size());
io_cipher.resize(msg.size());
io_cipher.swap(msg);
}
bool Secp256k1PP::decryptECIES(Secret const& _k, bytes& io_text)
{
// interop w/go ecies implementation
// io_cipher[0] must be 2, 3, or 4, else invalidpublickey
if (io_text.empty() || io_text[0] < 2 || io_text[0] > 4)
// invalid message: publickey
return false;
if (io_text.size() < (1 + Public::size + h128::size + 1 + h256::size))
// invalid message: length
return false;
Secret z;
ecdh::agree(_k, *(Public*)(io_text.data() + 1), z);
auto key = eciesKDF(z, bytes(), 64);
bytesConstRef eKey = bytesConstRef(&key).cropped(0, 16);
bytesRef mKeyMaterial = bytesRef(&key).cropped(16, 16);
bytes mKey(32);
CryptoPP::SHA256 ctx;
ctx.Update(mKeyMaterial.data(), mKeyMaterial.size());
ctx.Final(mKey.data());
bytes plain;
size_t cipherLen = io_text.size() - 1 - Public::size - h128::size - h256::size;
bytesConstRef cipherWithIV(io_text.data() + 1 + Public::size, h128::size + cipherLen);
bytesConstRef cipherIV = cipherWithIV.cropped(0, h128::size);
bytesConstRef cipherNoIV = cipherWithIV.cropped(h128::size, cipherLen);
bytesConstRef msgMac(cipherNoIV.data() + cipherLen, h256::size);
h128 iv(cipherIV.toBytes());
// verify tag
CryptoPP::HMAC<SHA256> hmacctx(mKey.data(), mKey.size());
hmacctx.Update(cipherWithIV.data(), cipherWithIV.size());
h256 mac;
hmacctx.Final(mac.data());
for (unsigned i = 0; i < h256::size; i++)
if (mac[i] != msgMac[i])
return false;
plain = decryptSymNoAuth(SecureFixedHash<16>(eKey), iv, cipherNoIV).makeInsecure();
io_text.resize(plain.size());
io_text.swap(plain);
return true;
}
void Secp256k1PP::encrypt(Public const& _k, bytes& io_cipher)
{
ECIES<ECP>::Encryptor e;
initializeDLScheme(_k, e);
size_t plen = io_cipher.size();
bytes ciphertext;
ciphertext.resize(e.CiphertextLength(plen));
{
Guard l(x_rng);
e.Encrypt(m_rng, io_cipher.data(), plen, ciphertext.data());
}
memset(io_cipher.data(), 0, io_cipher.size());
io_cipher = std::move(ciphertext);
}
void Secp256k1PP::decrypt(Secret const& _k, bytes& io_text)
{
CryptoPP::ECIES<CryptoPP::ECP>::Decryptor d;
initializeDLScheme(_k, d);
if (!io_text.size())
{
io_text.resize(1);
io_text[0] = 0;
}
size_t clen = io_text.size();
bytes plain;
plain.resize(d.MaxPlaintextLength(io_text.size()));
DecodingResult r;
{
Guard l(x_rng);
r = d.Decrypt(m_rng, io_text.data(), clen, plain.data());
}
if (!r.isValidCoding)
{
io_text.clear();
return;
}
io_text.resize(r.messageLength);
io_text = std::move(plain);
}
Signature Secp256k1PP::sign(Secret const& _k, bytesConstRef _message)
{
return sign(_k, sha3(_message));
}
Signature Secp256k1PP::sign(Secret const& _key, h256 const& _hash)
{
// assumption made by signing alogrithm
asserts(m_q == m_qs);
Signature sig;
Integer k(kdf(_key, _hash).data(), 32);
if (k == 0)
BOOST_THROW_EXCEPTION(InvalidState());
k = 1 + (k % (m_qs - 1));
ECP::Point rp;
Integer r;
{
Guard l(x_params);
rp = m_params.ExponentiateBase(k);
r = m_params.ConvertElementToInteger(rp);
}
sig[64] = 0;
// sig[64] = (r >= m_q) ? 2 : 0;
Integer kInv = k.InverseMod(m_q);
Integer z(_hash.asBytes().data(), 32);
Integer s = (kInv * (Integer(_key.data(), 32) * r + z)) % m_q;
if (r == 0 || s == 0)
BOOST_THROW_EXCEPTION(InvalidState());
// if (s > m_qs)
// {
// s = m_q - s;
// if (sig[64])
// sig[64] ^= 1;
// }
sig[64] |= rp.y.IsOdd() ? 1 : 0;
r.Encode(sig.data(), 32);
s.Encode(sig.data() + 32, 32);
return sig;
}
bool Secp256k1PP::verify(Signature const& _signature, bytesConstRef _message)
{
return !!recover(_signature, _message);
}
bool Secp256k1PP::verify(Public const& _p, Signature const& _sig, bytesConstRef _message, bool _hashed)
{
// todo: verify w/o recovery (if faster)
return _p == (_hashed ? recover(_sig, _message) : recover(_sig, sha3(_message).ref()));
}
Public Secp256k1PP::recover(Signature _signature, bytesConstRef _message)
{
Public recovered;
Integer r(_signature.data(), 32);
Integer s(_signature.data()+32, 32);
// cryptopp encodes sign of y as 0x02/0x03 instead of 0/1 or 27/28
byte encodedpoint[33];
encodedpoint[0] = _signature[64] | 2;
memcpy(&encodedpoint[1], _signature.data(), 32);
ECP::Element x;
{
m_curve.DecodePoint(x, encodedpoint, 33);
if (!m_curve.VerifyPoint(x))
return recovered;
}
// if (_signature[64] & 2)
// {
// r += m_q;
// Guard l(x_params);
// if (r >= m_params.GetMaxExponent())
// return recovered;
// }
Integer z(_message.data(), 32);
Integer rn = r.InverseMod(m_q);
Integer u1 = m_q - (rn.Times(z)).Modulo(m_q);
Integer u2 = (rn.Times(s)).Modulo(m_q);
ECP::Point p;
byte recoveredbytes[65];
{
// todo: make generator member
p = m_curve.CascadeMultiply(u2, x, u1, m_params.GetSubgroupGenerator());
if (p.identity)
return Public();
m_curve.EncodePoint(recoveredbytes, p, false);
}
memcpy(recovered.data(), &recoveredbytes[1], 64);
return recovered;
}
bool Secp256k1PP::verifySecret(Secret const& _s, Public& _p)
{
DL_PrivateKey_EC<ECP> k;
k.Initialize(m_params, secretToExponent(_s));
if (!k.Validate(m_rng, 3))
return false;
DL_PublicKey_EC<CryptoPP::ECP> pub;
k.MakePublicKey(pub);
if (!k.Validate(m_rng, 3))
return false;
exportPublicKey(pub, _p);
return true;
}
void Secp256k1PP::agree(Secret const& _s, Public const& _r, Secret& o_s)
{
// TODO: mutex ASN1::secp256k1() singleton
// Creating Domain is non-const for m_oid and m_oid is not thread-safe
ECDH<ECP>::Domain d(ASN1::secp256k1());
assert(d.AgreedValueLength() == sizeof(o_s));
byte remote[65] = {0x04};
memcpy(&remote[1], _r.data(), 64);
d.Agree(o_s.writable().data(), _s.data(), remote);
}
void Secp256k1PP::exportPublicKey(CryptoPP::DL_PublicKey_EC<CryptoPP::ECP> const& _k, Public& o_p)
{
bytes prefixedKey(_k.GetGroupParameters().GetEncodedElementSize(true));
{
Guard l(x_params);
m_params.GetCurve().EncodePoint(prefixedKey.data(), _k.GetPublicElement(), false);
assert(Public::size + 1 == _k.GetGroupParameters().GetEncodedElementSize(true));
}
memcpy(o_p.data(), &prefixedKey[1], Public::size);
}
void Secp256k1PP::exponentToPublic(Integer const& _e, Public& o_p)
{
CryptoPP::DL_PublicKey_EC<CryptoPP::ECP> pk;
{
Guard l(x_params);
pk.Initialize(m_params, m_params.ExponentiateBase(_e));
}
exportPublicKey(pk, o_p);
}