/* 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 . */ /** @file Message.cpp * @author Gav Wood * @date 2014 */ #include "Message.h" using namespace std; using namespace dev; using namespace dev::p2p; using namespace dev::shh; Message::Message(Envelope const& _e, FullTopic const& _fk, Secret const& _s) { try { bytes b; if (_s) if (!decrypt(_s, &(_e.data()), b)) return; else{} else if (!openBroadcastEnvelope(_e, _fk, b)) return; if (populate(b)) if (_s) m_to = KeyPair(_s).pub(); } catch (...) // Invalid secret? TODO: replace ... with InvalidSecret { } } bool Message::openBroadcastEnvelope(Envelope const& _e, FullTopic const& _fk, bytes& o_b) { // retrieve the key using the known topic and topicIndex. unsigned topicIndex = 0; Secret topicSecret; // determine topicSecret/topicIndex from knowledge of the collapsed topics (which give the order) and our full-size filter topic. CollapsedTopic knownTopic = collapse(_fk); for (unsigned ti = 0; ti < _fk.size() && !topicSecret; ++ti) for (unsigned i = 0; i < _e.topic().size(); ++i) if (_e.topic()[i] == knownTopic[ti]) { topicSecret = _fk[ti]; topicIndex = i; break; } if (_e.data().size() < _e.topic().size() * h256::size) return false; unsigned index = topicIndex * 2; h256 encryptedKey = h256(bytesConstRef(&(_e.data())).cropped(h256::size * index, h256::size)); h256 salt = h256(bytesConstRef(&(_e.data())).cropped(h256::size * ++index, h256::size)); h256 key = generateGamma(topicSecret, salt) ^ encryptedKey; bytesConstRef cipherText = bytesConstRef(&(_e.data())).cropped(h256::size * 2 * _e.topic().size()); return decryptSym(key, cipherText, o_b); } bool Message::populate(bytes const& _data) { if (!_data.size()) return false; byte flags = _data[0]; if (!!(flags & ContainsSignature) && _data.size() >= sizeof(Signature) + 1) // has a signature { bytesConstRef payload = bytesConstRef(&_data).cropped(1, _data.size() - sizeof(Signature) - 1); h256 h = sha3(payload); Signature const& sig = *(Signature const*)&(_data[1 + payload.size()]); m_from = recover(sig, h); if (!m_from) return false; m_payload = payload.toBytes(); } else m_payload = bytesConstRef(&_data).cropped(1).toBytes(); return true; } Envelope Message::seal(Secret _from, FullTopic const& _fullTopic, unsigned _ttl, unsigned _workToProve) const { CollapsedTopic topic = collapse(_fullTopic); Envelope ret(time(0) + _ttl, _ttl, topic); bytes input(1 + m_payload.size()); input[0] = 0; memcpy(input.data() + 1, m_payload.data(), m_payload.size()); if (_from) // needs a signature { input.resize(1 + m_payload.size() + sizeof(Signature)); input[0] |= ContainsSignature; *(Signature*)&(input[1 + m_payload.size()]) = sign(_from, sha3(m_payload)); // If this fails, the something is wrong with the sign-recover round-trip. assert(recover(*(Signature*)&(input[1 + m_payload.size()]), sha3(m_payload)) == KeyPair(_from).pub()); } if (m_to) encrypt(m_to, &input, ret.m_data); else { // this message is for broadcast (could be read by anyone who knows at least one of the topics) // create the shared secret for encrypting the payload, then encrypt the shared secret with each topic Secret s = Secret::random(); for (h256 const& t : _fullTopic) { h256 salt = h256::random(); ret.m_data += (generateGamma(t, salt) ^ s).asBytes(); ret.m_data += salt.asBytes(); } bytes d; encryptSym(s, &input, d); ret.m_data += d; } ret.proveWork(_workToProve); return ret; } Envelope::Envelope(RLP const& _m) { m_expiry = _m[0].toInt(); m_ttl = _m[1].toInt(); m_topic = _m[2].toVector>(); m_data = _m[3].toBytes(); m_nonce = _m[4].toInt(); } Message Envelope::open(FullTopic const& _ft, Secret const& _s) const { return Message(*this, _ft, _s); } unsigned Envelope::workProved() const { h256 d[2]; d[0] = sha3(WithoutNonce); d[1] = m_nonce; return dev::sha3(bytesConstRef(d[0].data(), 64)).firstBitSet(); } void Envelope::proveWork(unsigned _ms) { // PoW h256 d[2]; d[0] = sha3(WithoutNonce); uint32_t& n = *(uint32_t*)&(d[1][28]); unsigned bestBitSet = 0; bytesConstRef chuck(d[0].data(), 64); chrono::high_resolution_clock::time_point then = chrono::high_resolution_clock::now() + chrono::milliseconds(_ms); for (n = 0; chrono::high_resolution_clock::now() < then; ) // do it rounds of 1024 for efficiency for (unsigned i = 0; i < 1024; ++i, ++n) { auto fbs = dev::sha3(chuck).firstBitSet(); if (fbs > bestBitSet) { bestBitSet = fbs; m_nonce = n; } } }