// Copyright (c) 2022 The Bitcoin Core developers // Distributed under the MIT software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. #include #include #include #include #include #include // The two constants below are computed using the simulation script in // contrib/devtools/headerssync-params.py. //! Store one header commitment per HEADER_COMMITMENT_PERIOD blocks. constexpr size_t HEADER_COMMITMENT_PERIOD{606}; //! Only feed headers to validation once this many headers on top have been //! received and validated against commitments. constexpr size_t REDOWNLOAD_BUFFER_SIZE{14441}; // 14441/606 = ~23.8 commitments // Our memory analysis assumes 48 bytes for a CompressedHeader (so we should // re-calculate parameters if we compress further) static_assert(sizeof(CompressedHeader) == 48); HeadersSyncState::HeadersSyncState(NodeId id, const Consensus::Params& consensus_params, const CBlockIndex* chain_start, const arith_uint256& minimum_required_work) : m_commit_offset(FastRandomContext().randrange(HEADER_COMMITMENT_PERIOD)), m_id(id), m_consensus_params(consensus_params), m_chain_start(chain_start), m_minimum_required_work(minimum_required_work), m_current_chain_work(chain_start->nChainWork), m_last_header_received(m_chain_start->GetBlockHeader()), m_current_height(chain_start->nHeight) { // Estimate the number of blocks that could possibly exist on the peer's // chain *right now* using 6 blocks/second (fastest blockrate given the MTP // rule) times the number of seconds from the last allowed block until // today. This serves as a memory bound on how many commitments we might // store from this peer, and we can safely give up syncing if the peer // exceeds this bound, because it's not possible for a consensus-valid // chain to be longer than this (at the current time -- in the future we // could try again, if necessary, to sync a longer chain). m_max_commitments = 6*(Ticks(NodeClock::now() - NodeSeconds{std::chrono::seconds{chain_start->GetMedianTimePast()}}) + MAX_FUTURE_BLOCK_TIME) / HEADER_COMMITMENT_PERIOD; LogPrint(BCLog::NET, "Initial headers sync started with peer=%d: height=%i, max_commitments=%i, min_work=%s\n", m_id, m_current_height, m_max_commitments, m_minimum_required_work.ToString()); } /** Free any memory in use, and mark this object as no longer usable. This is * required to guarantee that we won't reuse this object with the same * SaltedTxidHasher for another sync. */ void HeadersSyncState::Finalize() { Assume(m_download_state != State::FINAL); ClearShrink(m_header_commitments); m_last_header_received.SetNull(); ClearShrink(m_redownloaded_headers); m_redownload_buffer_last_hash.SetNull(); m_redownload_buffer_first_prev_hash.SetNull(); m_process_all_remaining_headers = false; m_current_height = 0; m_download_state = State::FINAL; } /** Process the next batch of headers received from our peer. * Validate and store commitments, and compare total chainwork to our target to * see if we can switch to REDOWNLOAD mode. */ HeadersSyncState::ProcessingResult HeadersSyncState::ProcessNextHeaders(const std::vector& received_headers, const bool full_headers_message) { ProcessingResult ret; Assume(!received_headers.empty()); if (received_headers.empty()) return ret; Assume(m_download_state != State::FINAL); if (m_download_state == State::FINAL) return ret; if (m_download_state == State::PRESYNC) { // During PRESYNC, we minimally validate block headers and // occasionally add commitments to them, until we reach our work // threshold (at which point m_download_state is updated to REDOWNLOAD). ret.success = ValidateAndStoreHeadersCommitments(received_headers); if (ret.success) { if (full_headers_message || m_download_state == State::REDOWNLOAD) { // A full headers message means the peer may have more to give us; // also if we just switched to REDOWNLOAD then we need to re-request // headers from the beginning. ret.request_more = true; } else { Assume(m_download_state == State::PRESYNC); // If we're in PRESYNC and we get a non-full headers // message, then the peer's chain has ended and definitely doesn't // have enough work, so we can stop our sync. LogPrint(BCLog::NET, "Initial headers sync aborted with peer=%d: incomplete headers message at height=%i (presync phase)\n", m_id, m_current_height); } } } else if (m_download_state == State::REDOWNLOAD) { // During REDOWNLOAD, we compare our stored commitments to what we // receive, and add headers to our redownload buffer. When the buffer // gets big enough (meaning that we've checked enough commitments), // we'll return a batch of headers to the caller for processing. ret.success = true; for (const auto& hdr : received_headers) { if (!ValidateAndStoreRedownloadedHeader(hdr)) { // Something went wrong -- the peer gave us an unexpected chain. // We could consider looking at the reason for failure and // punishing the peer, but for now just give up on sync. ret.success = false; break; } } if (ret.success) { // Return any headers that are ready for acceptance. ret.pow_validated_headers = PopHeadersReadyForAcceptance(); // If we hit our target blockhash, then all remaining headers will be // returned and we can clear any leftover internal state. if (m_redownloaded_headers.empty() && m_process_all_remaining_headers) { LogPrint(BCLog::NET, "Initial headers sync complete with peer=%d: releasing all at height=%i (redownload phase)\n", m_id, m_redownload_buffer_last_height); } else if (full_headers_message) { // If the headers message is full, we need to request more. ret.request_more = true; } else { // For some reason our peer gave us a high-work chain, but is now // declining to serve us that full chain again. Give up. // Note that there's no more processing to be done with these // headers, so we can still return success. LogPrint(BCLog::NET, "Initial headers sync aborted with peer=%d: incomplete headers message at height=%i (redownload phase)\n", m_id, m_redownload_buffer_last_height); } } } if (!(ret.success && ret.request_more)) Finalize(); return ret; } bool HeadersSyncState::ValidateAndStoreHeadersCommitments(const std::vector& headers) { // The caller should not give us an empty set of headers. Assume(headers.size() > 0); if (headers.size() == 0) return true; Assume(m_download_state == State::PRESYNC); if (m_download_state != State::PRESYNC) return false; if (headers[0].hashPrevBlock != m_last_header_received.GetHash()) { // Somehow our peer gave us a header that doesn't connect. // This might be benign -- perhaps our peer reorged away from the chain // they were on. Give up on this sync for now (likely we will start a // new sync with a new starting point). LogPrint(BCLog::NET, "Initial headers sync aborted with peer=%d: non-continuous headers at height=%i (presync phase)\n", m_id, m_current_height); return false; } // If it does connect, (minimally) validate and occasionally store // commitments. for (const auto& hdr : headers) { if (!ValidateAndProcessSingleHeader(hdr)) { return false; } } if (m_current_chain_work >= m_minimum_required_work) { m_redownloaded_headers.clear(); m_redownload_buffer_last_height = m_chain_start->nHeight; m_redownload_buffer_first_prev_hash = m_chain_start->GetBlockHash(); m_redownload_buffer_last_hash = m_chain_start->GetBlockHash(); m_redownload_chain_work = m_chain_start->nChainWork; m_download_state = State::REDOWNLOAD; LogPrint(BCLog::NET, "Initial headers sync transition with peer=%d: reached sufficient work at height=%i, redownloading from height=%i\n", m_id, m_current_height, m_redownload_buffer_last_height); } return true; } bool HeadersSyncState::ValidateAndProcessSingleHeader(const CBlockHeader& current) { Assume(m_download_state == State::PRESYNC); if (m_download_state != State::PRESYNC) return false; int next_height = m_current_height + 1; // Verify that the difficulty isn't growing too fast; an adversary with // limited hashing capability has a greater chance of producing a high // work chain if they compress the work into as few blocks as possible, // so don't let anyone give a chain that would violate the difficulty // adjustment maximum. if (!PermittedDifficultyTransition(m_consensus_params, next_height, m_last_header_received.nBits, current.nBits)) { LogPrint(BCLog::NET, "Initial headers sync aborted with peer=%d: invalid difficulty transition at height=%i (presync phase)\n", m_id, next_height); return false; } if (next_height % HEADER_COMMITMENT_PERIOD == m_commit_offset) { // Add a commitment. m_header_commitments.push_back(m_hasher(current.GetHash()) & 1); if (m_header_commitments.size() > m_max_commitments) { // The peer's chain is too long; give up. // It's possible the chain grew since we started the sync; so // potentially we could succeed in syncing the peer's chain if we // try again later. LogPrint(BCLog::NET, "Initial headers sync aborted with peer=%d: exceeded max commitments at height=%i (presync phase)\n", m_id, next_height); return false; } } m_current_chain_work += GetBlockProof(CBlockIndex(current)); m_last_header_received = current; m_current_height = next_height; return true; } bool HeadersSyncState::ValidateAndStoreRedownloadedHeader(const CBlockHeader& header) { Assume(m_download_state == State::REDOWNLOAD); if (m_download_state != State::REDOWNLOAD) return false; int64_t next_height = m_redownload_buffer_last_height + 1; // Ensure that we're working on a header that connects to the chain we're // downloading. if (header.hashPrevBlock != m_redownload_buffer_last_hash) { LogPrint(BCLog::NET, "Initial headers sync aborted with peer=%d: non-continuous headers at height=%i (redownload phase)\n", m_id, next_height); return false; } // Check that the difficulty adjustments are within our tolerance: uint32_t previous_nBits{0}; if (!m_redownloaded_headers.empty()) { previous_nBits = m_redownloaded_headers.back().nBits; } else { previous_nBits = m_chain_start->nBits; } if (!PermittedDifficultyTransition(m_consensus_params, next_height, previous_nBits, header.nBits)) { LogPrint(BCLog::NET, "Initial headers sync aborted with peer=%d: invalid difficulty transition at height=%i (redownload phase)\n", m_id, next_height); return false; } // Track work on the redownloaded chain m_redownload_chain_work += GetBlockProof(CBlockIndex(header)); if (m_redownload_chain_work >= m_minimum_required_work) { m_process_all_remaining_headers = true; } // If we're at a header for which we previously stored a commitment, verify // it is correct. Failure will result in aborting download. // Also, don't check commitments once we've gotten to our target blockhash; // it's possible our peer has extended its chain between our first sync and // our second, and we don't want to return failure after we've seen our // target blockhash just because we ran out of commitments. if (!m_process_all_remaining_headers && next_height % HEADER_COMMITMENT_PERIOD == m_commit_offset) { if (m_header_commitments.size() == 0) { LogPrint(BCLog::NET, "Initial headers sync aborted with peer=%d: commitment overrun at height=%i (redownload phase)\n", m_id, next_height); // Somehow our peer managed to feed us a different chain and // we've run out of commitments. return false; } bool commitment = m_hasher(header.GetHash()) & 1; bool expected_commitment = m_header_commitments.front(); m_header_commitments.pop_front(); if (commitment != expected_commitment) { LogPrint(BCLog::NET, "Initial headers sync aborted with peer=%d: commitment mismatch at height=%i (redownload phase)\n", m_id, next_height); return false; } } // Store this header for later processing. m_redownloaded_headers.emplace_back(header); m_redownload_buffer_last_height = next_height; m_redownload_buffer_last_hash = header.GetHash(); return true; } std::vector HeadersSyncState::PopHeadersReadyForAcceptance() { std::vector ret; Assume(m_download_state == State::REDOWNLOAD); if (m_download_state != State::REDOWNLOAD) return ret; while (m_redownloaded_headers.size() > REDOWNLOAD_BUFFER_SIZE || (m_redownloaded_headers.size() > 0 && m_process_all_remaining_headers)) { ret.emplace_back(m_redownloaded_headers.front().GetFullHeader(m_redownload_buffer_first_prev_hash)); m_redownloaded_headers.pop_front(); m_redownload_buffer_first_prev_hash = ret.back().GetHash(); } return ret; } CBlockLocator HeadersSyncState::NextHeadersRequestLocator() const { Assume(m_download_state != State::FINAL); if (m_download_state == State::FINAL) return {}; auto chain_start_locator = LocatorEntries(m_chain_start); std::vector locator; if (m_download_state == State::PRESYNC) { // During pre-synchronization, we continue from the last header received. locator.push_back(m_last_header_received.GetHash()); } if (m_download_state == State::REDOWNLOAD) { // During redownload, we will download from the last received header that we stored. locator.push_back(m_redownload_buffer_last_hash); } locator.insert(locator.end(), chain_start_locator.begin(), chain_start_locator.end()); return CBlockLocator{std::move(locator)}; }