SignedPreKeyRecord::SignedPreKeyRecord(uint64_t id, uint64_t timestamp, const ECKeyPair &keyPair, const ByteArray &signature)
{
ByteArray bytePublic = keyPair.getPublicKey().serialize();
ByteArray bytePrivate = keyPair.getPrivateKey().serialize();
structure.set_id(id);
structure.set_publickey(bytePublic.c_str(), bytePublic.size());
structure.set_privatekey(bytePrivate.c_str(), bytePrivate.size());
structure.set_signature(signature.c_str(), signature.size());
structure.set_timestamp(timestamp);
}
ByteArray HKDF::expand(const ByteArray &prk, const ByteArray &info, int outputSize) const
{
int iterations = std::ceil((float)outputSize / HKDF::HASH_OUTPUT_SIZE);
ByteArray mixin;
ByteArray results;
int remainingBytes = outputSize;
for (int i = iterationStartOffset; i < (iterations + iterationStartOffset); i++) {
ByteArray message(mixin);
if (!info.empty()) {
message += info;
}
message += ByteArray(1, (char)(i % 256));
unsigned char out[32];
HMAC_SHA256((unsigned char*)message.c_str(), message.size(), (unsigned char*)prk.c_str(), prk.size(), out);
ByteArray stepResult((const char*)out, 32);
int stepSize = std::min((int)remainingBytes, (int)stepResult.size());
results += stepResult.substr(0, stepSize);
mixin = stepResult;
remainingBytes -= stepSize;
}
return results;
}
void File::Write( const ByteArray& buffer )
{
if( m_fd < 0 )
{
THROW_ERROR( "Can't write to a closed file" );
}
while(true)
{
ssize_t n = write( m_fd, buffer.c_str(), buffer.size() );
if( n < 0 )
{
if( errno == EINTR ) continue;
THROW_ERROR( "Failed to write data to the file (Error=%s)", strerror(errno) );
}
if( n != (ssize_t)buffer.size() )
{
THROW_ERROR( "Failed to write all data to the file" );
}
break;
}
}
SenderKeyState::SenderKeyState(int id, int iteration, const ByteArray &chainKey, const DjbECPublicKey &signatureKeyPublic, const DjbECPrivateKey &signatureKeyPrivate)
{
senderKeyStateStructure = textsecure::SenderKeyStateStructure();
senderKeyStateStructure.set_senderkeyid(id);
senderKeyStateStructure.mutable_senderchainkey()->set_iteration(iteration);
senderKeyStateStructure.mutable_senderchainkey()->set_seed(chainKey.c_str(),
chainKey.size());
senderKeyStateStructure.mutable_sendersigningkey()->set_public_(signatureKeyPublic.serialize().c_str(),
signatureKeyPublic.serialize().size());
senderKeyStateStructure.mutable_sendersigningkey()->set_private_(signatureKeyPrivate.serialize().c_str(),
signatureKeyPrivate.serialize().size());
/*textsecure::SenderKeyStateStructure::SenderChainKey senderChainKeyStructure;
senderChainKeyStructure.set_iteration(iteration);
senderChainKeyStructure.set_seed(chainKey.c_str());
textsecure::SenderKeyStateStructure::SenderSigningKey signingKeyStructure;
signingKeyStructure.set_public_(signatureKeyPublic.serialize().c_str());
signingKeyStructure.set_private_(signatureKeyPrivate.serialize().c_str());
senderKeyStateStructure = textsecure::SenderKeyStateStructure();
senderKeyStateStructure.set_senderkeyid(id);
senderKeyStateStructure.mutable_senderchainkey()->CopyFrom(senderChainKeyStructure);
senderKeyStateStructure.mutable_sendersigningkey()->CopyFrom(signingKeyStructure);*/
}
SignedPreKeyRecord::SignedPreKeyRecord(const ByteArray &serialized)
{
structure.ParsePartialFromArray(serialized.c_str(), serialized.size());
}
ByteArray HKDF::extract(const ByteArray &salt, const ByteArray &inputKeyMaterial) const
{
unsigned char out[32];
HMAC_SHA256((unsigned char*)inputKeyMaterial.c_str(), inputKeyMaterial.size(), (unsigned char*)salt.c_str(), salt.size(), out);
return ByteArray((const char*)out, 32);
}
ByteArray SenderChainKey::getDerivative(const ByteArray &seed, const ByteArray &key) const
{
unsigned char out[32];
HMAC_SHA256((unsigned char*)seed.c_str(), seed.size(), (unsigned char*)key.c_str(), key.size(), out);
return ByteArray((const char*)out, 32);
}
