// Copyright (c) 2011-2022 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 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace kernel { static constexpr uint8_t DB_BLOCK_FILES{'f'}; static constexpr uint8_t DB_BLOCK_INDEX{'b'}; static constexpr uint8_t DB_FLAG{'F'}; static constexpr uint8_t DB_REINDEX_FLAG{'R'}; static constexpr uint8_t DB_LAST_BLOCK{'l'}; // Keys used in previous version that might still be found in the DB: // BlockTreeDB::DB_TXINDEX_BLOCK{'T'}; // BlockTreeDB::DB_TXINDEX{'t'} // BlockTreeDB::ReadFlag("txindex") bool BlockTreeDB::ReadBlockFileInfo(int nFile, CBlockFileInfo& info) { return Read(std::make_pair(DB_BLOCK_FILES, nFile), info); } bool BlockTreeDB::WriteReindexing(bool fReindexing) { if (fReindexing) { return Write(DB_REINDEX_FLAG, uint8_t{'1'}); } else { return Erase(DB_REINDEX_FLAG); } } void BlockTreeDB::ReadReindexing(bool& fReindexing) { fReindexing = Exists(DB_REINDEX_FLAG); } bool BlockTreeDB::ReadLastBlockFile(int& nFile) { return Read(DB_LAST_BLOCK, nFile); } bool BlockTreeDB::WriteBatchSync(const std::vector>& fileInfo, int nLastFile, const std::vector& blockinfo) { CDBBatch batch(*this); for (const auto& [file, info] : fileInfo) { batch.Write(std::make_pair(DB_BLOCK_FILES, file), *info); } batch.Write(DB_LAST_BLOCK, nLastFile); for (const CBlockIndex* bi : blockinfo) { batch.Write(std::make_pair(DB_BLOCK_INDEX, bi->GetBlockHash()), CDiskBlockIndex{bi}); } return WriteBatch(batch, true); } bool BlockTreeDB::WriteFlag(const std::string& name, bool fValue) { return Write(std::make_pair(DB_FLAG, name), fValue ? uint8_t{'1'} : uint8_t{'0'}); } bool BlockTreeDB::ReadFlag(const std::string& name, bool& fValue) { uint8_t ch; if (!Read(std::make_pair(DB_FLAG, name), ch)) { return false; } fValue = ch == uint8_t{'1'}; return true; } bool BlockTreeDB::LoadBlockIndexGuts(const Consensus::Params& consensusParams, std::function insertBlockIndex, const util::SignalInterrupt& interrupt) { AssertLockHeld(::cs_main); std::unique_ptr pcursor(NewIterator()); pcursor->Seek(std::make_pair(DB_BLOCK_INDEX, uint256())); // Load m_block_index while (pcursor->Valid()) { if (interrupt) return false; std::pair key; if (pcursor->GetKey(key) && key.first == DB_BLOCK_INDEX) { CDiskBlockIndex diskindex; if (pcursor->GetValue(diskindex)) { // Construct block index object CBlockIndex* pindexNew = insertBlockIndex(diskindex.ConstructBlockHash()); pindexNew->pprev = insertBlockIndex(diskindex.hashPrev); pindexNew->nHeight = diskindex.nHeight; pindexNew->nFile = diskindex.nFile; pindexNew->nDataPos = diskindex.nDataPos; pindexNew->nUndoPos = diskindex.nUndoPos; pindexNew->nVersion = diskindex.nVersion; pindexNew->hashMerkleRoot = diskindex.hashMerkleRoot; pindexNew->nTime = diskindex.nTime; pindexNew->nBits = diskindex.nBits; pindexNew->nNonce = diskindex.nNonce; pindexNew->nStatus = diskindex.nStatus; pindexNew->nTx = diskindex.nTx; if (!CheckProofOfWork(pindexNew->GetBlockHash(), pindexNew->nBits, consensusParams)) { return error("%s: CheckProofOfWork failed: %s", __func__, pindexNew->ToString()); } pcursor->Next(); } else { return error("%s: failed to read value", __func__); } } else { break; } } return true; } } // namespace kernel namespace node { std::atomic_bool fReindex(false); bool CBlockIndexWorkComparator::operator()(const CBlockIndex* pa, const CBlockIndex* pb) const { // First sort by most total work, ... if (pa->nChainWork > pb->nChainWork) return false; if (pa->nChainWork < pb->nChainWork) return true; // ... then by earliest time received, ... if (pa->nSequenceId < pb->nSequenceId) return false; if (pa->nSequenceId > pb->nSequenceId) return true; // Use pointer address as tie breaker (should only happen with blocks // loaded from disk, as those all have id 0). if (pa < pb) return false; if (pa > pb) return true; // Identical blocks. return false; } bool CBlockIndexHeightOnlyComparator::operator()(const CBlockIndex* pa, const CBlockIndex* pb) const { return pa->nHeight < pb->nHeight; } std::vector BlockManager::GetAllBlockIndices() { AssertLockHeld(cs_main); std::vector rv; rv.reserve(m_block_index.size()); for (auto& [_, block_index] : m_block_index) { rv.push_back(&block_index); } return rv; } CBlockIndex* BlockManager::LookupBlockIndex(const uint256& hash) { AssertLockHeld(cs_main); BlockMap::iterator it = m_block_index.find(hash); return it == m_block_index.end() ? nullptr : &it->second; } const CBlockIndex* BlockManager::LookupBlockIndex(const uint256& hash) const { AssertLockHeld(cs_main); BlockMap::const_iterator it = m_block_index.find(hash); return it == m_block_index.end() ? nullptr : &it->second; } CBlockIndex* BlockManager::AddToBlockIndex(const CBlockHeader& block, CBlockIndex*& best_header) { AssertLockHeld(cs_main); auto [mi, inserted] = m_block_index.try_emplace(block.GetHash(), block); if (!inserted) { return &mi->second; } CBlockIndex* pindexNew = &(*mi).second; // We assign the sequence id to blocks only when the full data is available, // to avoid miners withholding blocks but broadcasting headers, to get a // competitive advantage. pindexNew->nSequenceId = 0; pindexNew->phashBlock = &((*mi).first); BlockMap::iterator miPrev = m_block_index.find(block.hashPrevBlock); if (miPrev != m_block_index.end()) { pindexNew->pprev = &(*miPrev).second; pindexNew->nHeight = pindexNew->pprev->nHeight + 1; pindexNew->BuildSkip(); } pindexNew->nTimeMax = (pindexNew->pprev ? std::max(pindexNew->pprev->nTimeMax, pindexNew->nTime) : pindexNew->nTime); pindexNew->nChainWork = (pindexNew->pprev ? pindexNew->pprev->nChainWork : 0) + GetBlockProof(*pindexNew); pindexNew->RaiseValidity(BLOCK_VALID_TREE); if (best_header == nullptr || best_header->nChainWork < pindexNew->nChainWork) { best_header = pindexNew; } m_dirty_blockindex.insert(pindexNew); return pindexNew; } void BlockManager::PruneOneBlockFile(const int fileNumber) { AssertLockHeld(cs_main); LOCK(cs_LastBlockFile); for (auto& entry : m_block_index) { CBlockIndex* pindex = &entry.second; if (pindex->nFile == fileNumber) { pindex->nStatus &= ~BLOCK_HAVE_DATA; pindex->nStatus &= ~BLOCK_HAVE_UNDO; pindex->nFile = 0; pindex->nDataPos = 0; pindex->nUndoPos = 0; m_dirty_blockindex.insert(pindex); // Prune from m_blocks_unlinked -- any block we prune would have // to be downloaded again in order to consider its chain, at which // point it would be considered as a candidate for // m_blocks_unlinked or setBlockIndexCandidates. auto range = m_blocks_unlinked.equal_range(pindex->pprev); while (range.first != range.second) { std::multimap::iterator _it = range.first; range.first++; if (_it->second == pindex) { m_blocks_unlinked.erase(_it); } } } } m_blockfile_info[fileNumber].SetNull(); m_dirty_fileinfo.insert(fileNumber); } void BlockManager::FindFilesToPruneManual(std::set& setFilesToPrune, int nManualPruneHeight, int chain_tip_height) { assert(IsPruneMode() && nManualPruneHeight > 0); LOCK2(cs_main, cs_LastBlockFile); if (chain_tip_height < 0) { return; } // last block to prune is the lesser of (user-specified height, MIN_BLOCKS_TO_KEEP from the tip) unsigned int nLastBlockWeCanPrune = std::min((unsigned)nManualPruneHeight, chain_tip_height - MIN_BLOCKS_TO_KEEP); int count = 0; for (int fileNumber = 0; fileNumber < m_last_blockfile; fileNumber++) { if (m_blockfile_info[fileNumber].nSize == 0 || m_blockfile_info[fileNumber].nHeightLast > nLastBlockWeCanPrune) { continue; } PruneOneBlockFile(fileNumber); setFilesToPrune.insert(fileNumber); count++; } LogPrintf("Prune (Manual): prune_height=%d removed %d blk/rev pairs\n", nLastBlockWeCanPrune, count); } void BlockManager::FindFilesToPrune(std::set& setFilesToPrune, uint64_t nPruneAfterHeight, int chain_tip_height, int prune_height, bool is_ibd) { LOCK2(cs_main, cs_LastBlockFile); if (chain_tip_height < 0 || GetPruneTarget() == 0) { return; } if ((uint64_t)chain_tip_height <= nPruneAfterHeight) { return; } unsigned int nLastBlockWeCanPrune{(unsigned)std::min(prune_height, chain_tip_height - static_cast(MIN_BLOCKS_TO_KEEP))}; uint64_t nCurrentUsage = CalculateCurrentUsage(); // We don't check to prune until after we've allocated new space for files // So we should leave a buffer under our target to account for another allocation // before the next pruning. uint64_t nBuffer = BLOCKFILE_CHUNK_SIZE + UNDOFILE_CHUNK_SIZE; uint64_t nBytesToPrune; int count = 0; if (nCurrentUsage + nBuffer >= GetPruneTarget()) { // On a prune event, the chainstate DB is flushed. // To avoid excessive prune events negating the benefit of high dbcache // values, we should not prune too rapidly. // So when pruning in IBD, increase the buffer a bit to avoid a re-prune too soon. if (is_ibd) { // Since this is only relevant during IBD, we use a fixed 10% nBuffer += GetPruneTarget() / 10; } for (int fileNumber = 0; fileNumber < m_last_blockfile; fileNumber++) { nBytesToPrune = m_blockfile_info[fileNumber].nSize + m_blockfile_info[fileNumber].nUndoSize; if (m_blockfile_info[fileNumber].nSize == 0) { continue; } if (nCurrentUsage + nBuffer < GetPruneTarget()) { // are we below our target? break; } // don't prune files that could have a block within MIN_BLOCKS_TO_KEEP of the main chain's tip but keep scanning if (m_blockfile_info[fileNumber].nHeightLast > nLastBlockWeCanPrune) { continue; } PruneOneBlockFile(fileNumber); // Queue up the files for removal setFilesToPrune.insert(fileNumber); nCurrentUsage -= nBytesToPrune; count++; } } LogPrint(BCLog::PRUNE, "target=%dMiB actual=%dMiB diff=%dMiB max_prune_height=%d removed %d blk/rev pairs\n", GetPruneTarget() / 1024 / 1024, nCurrentUsage / 1024 / 1024, (int64_t(GetPruneTarget()) - int64_t(nCurrentUsage)) / 1024 / 1024, nLastBlockWeCanPrune, count); } void BlockManager::UpdatePruneLock(const std::string& name, const PruneLockInfo& lock_info) { AssertLockHeld(::cs_main); m_prune_locks[name] = lock_info; } CBlockIndex* BlockManager::InsertBlockIndex(const uint256& hash) { AssertLockHeld(cs_main); if (hash.IsNull()) { return nullptr; } const auto [mi, inserted]{m_block_index.try_emplace(hash)}; CBlockIndex* pindex = &(*mi).second; if (inserted) { pindex->phashBlock = &((*mi).first); } return pindex; } bool BlockManager::LoadBlockIndex() { if (!m_block_tree_db->LoadBlockIndexGuts( GetConsensus(), [this](const uint256& hash) EXCLUSIVE_LOCKS_REQUIRED(cs_main) { return this->InsertBlockIndex(hash); }, m_interrupt)) { return false; } // Calculate nChainWork std::vector vSortedByHeight{GetAllBlockIndices()}; std::sort(vSortedByHeight.begin(), vSortedByHeight.end(), CBlockIndexHeightOnlyComparator()); for (CBlockIndex* pindex : vSortedByHeight) { if (m_interrupt) return false; pindex->nChainWork = (pindex->pprev ? pindex->pprev->nChainWork : 0) + GetBlockProof(*pindex); pindex->nTimeMax = (pindex->pprev ? std::max(pindex->pprev->nTimeMax, pindex->nTime) : pindex->nTime); // We can link the chain of blocks for which we've received transactions at some point, or // blocks that are assumed-valid on the basis of snapshot load (see // PopulateAndValidateSnapshot()). // Pruned nodes may have deleted the block. if (pindex->nTx > 0) { if (pindex->pprev) { if (pindex->pprev->nChainTx > 0) { pindex->nChainTx = pindex->pprev->nChainTx + pindex->nTx; } else { pindex->nChainTx = 0; m_blocks_unlinked.insert(std::make_pair(pindex->pprev, pindex)); } } else { pindex->nChainTx = pindex->nTx; } } if (!(pindex->nStatus & BLOCK_FAILED_MASK) && pindex->pprev && (pindex->pprev->nStatus & BLOCK_FAILED_MASK)) { pindex->nStatus |= BLOCK_FAILED_CHILD; m_dirty_blockindex.insert(pindex); } if (pindex->pprev) { pindex->BuildSkip(); } } return true; } bool BlockManager::WriteBlockIndexDB() { AssertLockHeld(::cs_main); std::vector> vFiles; vFiles.reserve(m_dirty_fileinfo.size()); for (std::set::iterator it = m_dirty_fileinfo.begin(); it != m_dirty_fileinfo.end();) { vFiles.push_back(std::make_pair(*it, &m_blockfile_info[*it])); m_dirty_fileinfo.erase(it++); } std::vector vBlocks; vBlocks.reserve(m_dirty_blockindex.size()); for (std::set::iterator it = m_dirty_blockindex.begin(); it != m_dirty_blockindex.end();) { vBlocks.push_back(*it); m_dirty_blockindex.erase(it++); } if (!m_block_tree_db->WriteBatchSync(vFiles, m_last_blockfile, vBlocks)) { return false; } return true; } bool BlockManager::LoadBlockIndexDB() { if (!LoadBlockIndex()) { return false; } // Load block file info m_block_tree_db->ReadLastBlockFile(m_last_blockfile); m_blockfile_info.resize(m_last_blockfile + 1); LogPrintf("%s: last block file = %i\n", __func__, m_last_blockfile); for (int nFile = 0; nFile <= m_last_blockfile; nFile++) { m_block_tree_db->ReadBlockFileInfo(nFile, m_blockfile_info[nFile]); } LogPrintf("%s: last block file info: %s\n", __func__, m_blockfile_info[m_last_blockfile].ToString()); for (int nFile = m_last_blockfile + 1; true; nFile++) { CBlockFileInfo info; if (m_block_tree_db->ReadBlockFileInfo(nFile, info)) { m_blockfile_info.push_back(info); } else { break; } } // Check presence of blk files LogPrintf("Checking all blk files are present...\n"); std::set setBlkDataFiles; for (const auto& [_, block_index] : m_block_index) { if (block_index.nStatus & BLOCK_HAVE_DATA) { setBlkDataFiles.insert(block_index.nFile); } } for (std::set::iterator it = setBlkDataFiles.begin(); it != setBlkDataFiles.end(); it++) { FlatFilePos pos(*it, 0); if (AutoFile{OpenBlockFile(pos, true)}.IsNull()) { return false; } } // Check whether we have ever pruned block & undo files m_block_tree_db->ReadFlag("prunedblockfiles", m_have_pruned); if (m_have_pruned) { LogPrintf("LoadBlockIndexDB(): Block files have previously been pruned\n"); } // Check whether we need to continue reindexing bool fReindexing = false; m_block_tree_db->ReadReindexing(fReindexing); if (fReindexing) fReindex = true; return true; } void BlockManager::ScanAndUnlinkAlreadyPrunedFiles() { AssertLockHeld(::cs_main); if (!m_have_pruned) { return; } std::set block_files_to_prune; for (int file_number = 0; file_number < m_last_blockfile; file_number++) { if (m_blockfile_info[file_number].nSize == 0) { block_files_to_prune.insert(file_number); } } UnlinkPrunedFiles(block_files_to_prune); } const CBlockIndex* BlockManager::GetLastCheckpoint(const CCheckpointData& data) { const MapCheckpoints& checkpoints = data.mapCheckpoints; for (const MapCheckpoints::value_type& i : reverse_iterate(checkpoints)) { const uint256& hash = i.second; const CBlockIndex* pindex = LookupBlockIndex(hash); if (pindex) { return pindex; } } return nullptr; } bool BlockManager::IsBlockPruned(const CBlockIndex* pblockindex) { AssertLockHeld(::cs_main); return (m_have_pruned && !(pblockindex->nStatus & BLOCK_HAVE_DATA) && pblockindex->nTx > 0); } const CBlockIndex* BlockManager::GetFirstStoredBlock(const CBlockIndex& upper_block, const CBlockIndex* lower_block) { AssertLockHeld(::cs_main); const CBlockIndex* last_block = &upper_block; assert(last_block->nStatus & BLOCK_HAVE_DATA); // 'upper_block' must have data while (last_block->pprev && (last_block->pprev->nStatus & BLOCK_HAVE_DATA)) { if (lower_block) { // Return if we reached the lower_block if (last_block == lower_block) return lower_block; // if range was surpassed, means that 'lower_block' is not part of the 'upper_block' chain // and so far this is not allowed. assert(last_block->nHeight >= lower_block->nHeight); } last_block = last_block->pprev; } assert(last_block != nullptr); return last_block; } bool BlockManager::CheckBlockDataAvailability(const CBlockIndex& upper_block, const CBlockIndex& lower_block) { if (!(upper_block.nStatus & BLOCK_HAVE_DATA)) return false; return GetFirstStoredBlock(upper_block, &lower_block) == &lower_block; } // If we're using -prune with -reindex, then delete block files that will be ignored by the // reindex. Since reindexing works by starting at block file 0 and looping until a blockfile // is missing, do the same here to delete any later block files after a gap. Also delete all // rev files since they'll be rewritten by the reindex anyway. This ensures that m_blockfile_info // is in sync with what's actually on disk by the time we start downloading, so that pruning // works correctly. void BlockManager::CleanupBlockRevFiles() const { std::map mapBlockFiles; // Glob all blk?????.dat and rev?????.dat files from the blocks directory. // Remove the rev files immediately and insert the blk file paths into an // ordered map keyed by block file index. LogPrintf("Removing unusable blk?????.dat and rev?????.dat files for -reindex with -prune\n"); for (fs::directory_iterator it(m_opts.blocks_dir); it != fs::directory_iterator(); it++) { const std::string path = fs::PathToString(it->path().filename()); if (fs::is_regular_file(*it) && path.length() == 12 && path.substr(8,4) == ".dat") { if (path.substr(0, 3) == "blk") { mapBlockFiles[path.substr(3, 5)] = it->path(); } else if (path.substr(0, 3) == "rev") { remove(it->path()); } } } // Remove all block files that aren't part of a contiguous set starting at // zero by walking the ordered map (keys are block file indices) by // keeping a separate counter. Once we hit a gap (or if 0 doesn't exist) // start removing block files. int nContigCounter = 0; for (const std::pair& item : mapBlockFiles) { if (LocaleIndependentAtoi(item.first) == nContigCounter) { nContigCounter++; continue; } remove(item.second); } } CBlockFileInfo* BlockManager::GetBlockFileInfo(size_t n) { LOCK(cs_LastBlockFile); return &m_blockfile_info.at(n); } bool BlockManager::UndoWriteToDisk(const CBlockUndo& blockundo, FlatFilePos& pos, const uint256& hashBlock) const { // Open history file to append AutoFile fileout{OpenUndoFile(pos)}; if (fileout.IsNull()) { return error("%s: OpenUndoFile failed", __func__); } // Write index header unsigned int nSize = GetSerializeSize(blockundo, CLIENT_VERSION); fileout << GetParams().MessageStart() << nSize; // Write undo data long fileOutPos = ftell(fileout.Get()); if (fileOutPos < 0) { return error("%s: ftell failed", __func__); } pos.nPos = (unsigned int)fileOutPos; fileout << blockundo; // calculate & write checksum HashWriter hasher{}; hasher << hashBlock; hasher << blockundo; fileout << hasher.GetHash(); return true; } bool BlockManager::UndoReadFromDisk(CBlockUndo& blockundo, const CBlockIndex& index) const { const FlatFilePos pos{WITH_LOCK(::cs_main, return index.GetUndoPos())}; if (pos.IsNull()) { return error("%s: no undo data available", __func__); } // Open history file to read AutoFile filein{OpenUndoFile(pos, true)}; if (filein.IsNull()) { return error("%s: OpenUndoFile failed", __func__); } // Read block uint256 hashChecksum; HashVerifier verifier{filein}; // Use HashVerifier as reserializing may lose data, c.f. commit d342424301013ec47dc146a4beb49d5c9319d80a try { verifier << index.pprev->GetBlockHash(); verifier >> blockundo; filein >> hashChecksum; } catch (const std::exception& e) { return error("%s: Deserialize or I/O error - %s", __func__, e.what()); } // Verify checksum if (hashChecksum != verifier.GetHash()) { return error("%s: Checksum mismatch", __func__); } return true; } void BlockManager::FlushUndoFile(int block_file, bool finalize) { FlatFilePos undo_pos_old(block_file, m_blockfile_info[block_file].nUndoSize); if (!UndoFileSeq().Flush(undo_pos_old, finalize)) { m_opts.notifications.flushError("Flushing undo file to disk failed. This is likely the result of an I/O error."); } } void BlockManager::FlushBlockFile(bool fFinalize, bool finalize_undo) { LOCK(cs_LastBlockFile); if (m_blockfile_info.size() < 1) { // Return if we haven't loaded any blockfiles yet. This happens during // chainstate init, when we call ChainstateManager::MaybeRebalanceCaches() (which // then calls FlushStateToDisk()), resulting in a call to this function before we // have populated `m_blockfile_info` via LoadBlockIndexDB(). return; } assert(static_cast(m_blockfile_info.size()) > m_last_blockfile); FlatFilePos block_pos_old(m_last_blockfile, m_blockfile_info[m_last_blockfile].nSize); if (!BlockFileSeq().Flush(block_pos_old, fFinalize)) { m_opts.notifications.flushError("Flushing block file to disk failed. This is likely the result of an I/O error."); } // we do not always flush the undo file, as the chain tip may be lagging behind the incoming blocks, // e.g. during IBD or a sync after a node going offline if (!fFinalize || finalize_undo) FlushUndoFile(m_last_blockfile, finalize_undo); } uint64_t BlockManager::CalculateCurrentUsage() { LOCK(cs_LastBlockFile); uint64_t retval = 0; for (const CBlockFileInfo& file : m_blockfile_info) { retval += file.nSize + file.nUndoSize; } return retval; } void BlockManager::UnlinkPrunedFiles(const std::set& setFilesToPrune) const { std::error_code ec; for (std::set::iterator it = setFilesToPrune.begin(); it != setFilesToPrune.end(); ++it) { FlatFilePos pos(*it, 0); const bool removed_blockfile{fs::remove(BlockFileSeq().FileName(pos), ec)}; const bool removed_undofile{fs::remove(UndoFileSeq().FileName(pos), ec)}; if (removed_blockfile || removed_undofile) { LogPrint(BCLog::BLOCKSTORAGE, "Prune: %s deleted blk/rev (%05u)\n", __func__, *it); } } } FlatFileSeq BlockManager::BlockFileSeq() const { return FlatFileSeq(m_opts.blocks_dir, "blk", m_opts.fast_prune ? 0x4000 /* 16kb */ : BLOCKFILE_CHUNK_SIZE); } FlatFileSeq BlockManager::UndoFileSeq() const { return FlatFileSeq(m_opts.blocks_dir, "rev", UNDOFILE_CHUNK_SIZE); } FILE* BlockManager::OpenBlockFile(const FlatFilePos& pos, bool fReadOnly) const { return BlockFileSeq().Open(pos, fReadOnly); } /** Open an undo file (rev?????.dat) */ FILE* BlockManager::OpenUndoFile(const FlatFilePos& pos, bool fReadOnly) const { return UndoFileSeq().Open(pos, fReadOnly); } fs::path BlockManager::GetBlockPosFilename(const FlatFilePos& pos) const { return BlockFileSeq().FileName(pos); } bool BlockManager::FindBlockPos(FlatFilePos& pos, unsigned int nAddSize, unsigned int nHeight, uint64_t nTime, bool fKnown) { LOCK(cs_LastBlockFile); unsigned int nFile = fKnown ? pos.nFile : m_last_blockfile; if (m_blockfile_info.size() <= nFile) { m_blockfile_info.resize(nFile + 1); } bool finalize_undo = false; if (!fKnown) { unsigned int max_blockfile_size{MAX_BLOCKFILE_SIZE}; // Use smaller blockfiles in test-only -fastprune mode - but avoid // the possibility of having a block not fit into the block file. if (m_opts.fast_prune) { max_blockfile_size = 0x10000; // 64kiB if (nAddSize >= max_blockfile_size) { // dynamically adjust the blockfile size to be larger than the added size max_blockfile_size = nAddSize + 1; } } assert(nAddSize < max_blockfile_size); while (m_blockfile_info[nFile].nSize + nAddSize >= max_blockfile_size) { // when the undo file is keeping up with the block file, we want to flush it explicitly // when it is lagging behind (more blocks arrive than are being connected), we let the // undo block write case handle it finalize_undo = (m_blockfile_info[nFile].nHeightLast == m_undo_height_in_last_blockfile); nFile++; if (m_blockfile_info.size() <= nFile) { m_blockfile_info.resize(nFile + 1); } } pos.nFile = nFile; pos.nPos = m_blockfile_info[nFile].nSize; } if ((int)nFile != m_last_blockfile) { if (!fKnown) { LogPrint(BCLog::BLOCKSTORAGE, "Leaving block file %i: %s\n", m_last_blockfile, m_blockfile_info[m_last_blockfile].ToString()); } FlushBlockFile(!fKnown, finalize_undo); m_last_blockfile = nFile; m_undo_height_in_last_blockfile = 0; // No undo data yet in the new file, so reset our undo-height tracking. } m_blockfile_info[nFile].AddBlock(nHeight, nTime); if (fKnown) { m_blockfile_info[nFile].nSize = std::max(pos.nPos + nAddSize, m_blockfile_info[nFile].nSize); } else { m_blockfile_info[nFile].nSize += nAddSize; } if (!fKnown) { bool out_of_space; size_t bytes_allocated = BlockFileSeq().Allocate(pos, nAddSize, out_of_space); if (out_of_space) { m_opts.notifications.fatalError("Disk space is too low!", _("Disk space is too low!")); return false; } if (bytes_allocated != 0 && IsPruneMode()) { m_check_for_pruning = true; } } m_dirty_fileinfo.insert(nFile); return true; } bool BlockManager::FindUndoPos(BlockValidationState& state, int nFile, FlatFilePos& pos, unsigned int nAddSize) { pos.nFile = nFile; LOCK(cs_LastBlockFile); pos.nPos = m_blockfile_info[nFile].nUndoSize; m_blockfile_info[nFile].nUndoSize += nAddSize; m_dirty_fileinfo.insert(nFile); bool out_of_space; size_t bytes_allocated = UndoFileSeq().Allocate(pos, nAddSize, out_of_space); if (out_of_space) { return FatalError(m_opts.notifications, state, "Disk space is too low!", _("Disk space is too low!")); } if (bytes_allocated != 0 && IsPruneMode()) { m_check_for_pruning = true; } return true; } bool BlockManager::WriteBlockToDisk(const CBlock& block, FlatFilePos& pos) const { // Open history file to append CAutoFile fileout(OpenBlockFile(pos), SER_DISK, CLIENT_VERSION); if (fileout.IsNull()) { return error("WriteBlockToDisk: OpenBlockFile failed"); } // Write index header unsigned int nSize = GetSerializeSize(block, fileout.GetVersion()); fileout << GetParams().MessageStart() << nSize; // Write block long fileOutPos = ftell(fileout.Get()); if (fileOutPos < 0) { return error("WriteBlockToDisk: ftell failed"); } pos.nPos = (unsigned int)fileOutPos; fileout << block; return true; } bool BlockManager::WriteUndoDataForBlock(const CBlockUndo& blockundo, BlockValidationState& state, CBlockIndex& block) { AssertLockHeld(::cs_main); // Write undo information to disk if (block.GetUndoPos().IsNull()) { FlatFilePos _pos; if (!FindUndoPos(state, block.nFile, _pos, ::GetSerializeSize(blockundo, CLIENT_VERSION) + 40)) { return error("ConnectBlock(): FindUndoPos failed"); } if (!UndoWriteToDisk(blockundo, _pos, block.pprev->GetBlockHash())) { return FatalError(m_opts.notifications, state, "Failed to write undo data"); } // rev files are written in block height order, whereas blk files are written as blocks come in (often out of order) // we want to flush the rev (undo) file once we've written the last block, which is indicated by the last height // in the block file info as below; note that this does not catch the case where the undo writes are keeping up // with the block writes (usually when a synced up node is getting newly mined blocks) -- this case is caught in // the FindBlockPos function if (_pos.nFile < m_last_blockfile && static_cast(block.nHeight) == m_blockfile_info[_pos.nFile].nHeightLast) { FlushUndoFile(_pos.nFile, true); } else if (_pos.nFile == m_last_blockfile && static_cast(block.nHeight) > m_undo_height_in_last_blockfile) { m_undo_height_in_last_blockfile = block.nHeight; } // update nUndoPos in block index block.nUndoPos = _pos.nPos; block.nStatus |= BLOCK_HAVE_UNDO; m_dirty_blockindex.insert(&block); } return true; } bool BlockManager::ReadBlockFromDisk(CBlock& block, const FlatFilePos& pos) const { block.SetNull(); // Open history file to read CAutoFile filein(OpenBlockFile(pos, true), SER_DISK, CLIENT_VERSION); if (filein.IsNull()) { return error("ReadBlockFromDisk: OpenBlockFile failed for %s", pos.ToString()); } // Read block try { filein >> block; } catch (const std::exception& e) { return error("%s: Deserialize or I/O error - %s at %s", __func__, e.what(), pos.ToString()); } // Check the header if (!CheckProofOfWork(block.GetHash(), block.nBits, GetConsensus())) { return error("ReadBlockFromDisk: Errors in block header at %s", pos.ToString()); } // Signet only: check block solution if (GetConsensus().signet_blocks && !CheckSignetBlockSolution(block, GetConsensus())) { return error("ReadBlockFromDisk: Errors in block solution at %s", pos.ToString()); } return true; } bool BlockManager::ReadBlockFromDisk(CBlock& block, const CBlockIndex& index) const { const FlatFilePos block_pos{WITH_LOCK(cs_main, return index.GetBlockPos())}; if (!ReadBlockFromDisk(block, block_pos)) { return false; } if (block.GetHash() != index.GetBlockHash()) { return error("ReadBlockFromDisk(CBlock&, CBlockIndex*): GetHash() doesn't match index for %s at %s", index.ToString(), block_pos.ToString()); } return true; } bool BlockManager::ReadRawBlockFromDisk(std::vector& block, const FlatFilePos& pos) const { FlatFilePos hpos = pos; hpos.nPos -= 8; // Seek back 8 bytes for meta header AutoFile filein{OpenBlockFile(hpos, true)}; if (filein.IsNull()) { return error("%s: OpenBlockFile failed for %s", __func__, pos.ToString()); } try { CMessageHeader::MessageStartChars blk_start; unsigned int blk_size; filein >> blk_start >> blk_size; if (blk_start != GetParams().MessageStart()) { return error("%s: Block magic mismatch for %s: %s versus expected %s", __func__, pos.ToString(), HexStr(blk_start), HexStr(GetParams().MessageStart())); } if (blk_size > MAX_SIZE) { return error("%s: Block data is larger than maximum deserialization size for %s: %s versus %s", __func__, pos.ToString(), blk_size, MAX_SIZE); } block.resize(blk_size); // Zeroing of memory is intentional here filein.read(MakeWritableByteSpan(block)); } catch (const std::exception& e) { return error("%s: Read from block file failed: %s for %s", __func__, e.what(), pos.ToString()); } return true; } FlatFilePos BlockManager::SaveBlockToDisk(const CBlock& block, int nHeight, const FlatFilePos* dbp) { unsigned int nBlockSize = ::GetSerializeSize(block, CLIENT_VERSION); FlatFilePos blockPos; const auto position_known {dbp != nullptr}; if (position_known) { blockPos = *dbp; } else { // when known, blockPos.nPos points at the offset of the block data in the blk file. that already accounts for // the serialization header present in the file (the 4 magic message start bytes + the 4 length bytes = 8 bytes = BLOCK_SERIALIZATION_HEADER_SIZE). // we add BLOCK_SERIALIZATION_HEADER_SIZE only for new blocks since they will have the serialization header added when written to disk. nBlockSize += static_cast(BLOCK_SERIALIZATION_HEADER_SIZE); } if (!FindBlockPos(blockPos, nBlockSize, nHeight, block.GetBlockTime(), position_known)) { error("%s: FindBlockPos failed", __func__); return FlatFilePos(); } if (!position_known) { if (!WriteBlockToDisk(block, blockPos)) { m_opts.notifications.fatalError("Failed to write block"); return FlatFilePos(); } } return blockPos; } class ImportingNow { std::atomic& m_importing; public: ImportingNow(std::atomic& importing) : m_importing{importing} { assert(m_importing == false); m_importing = true; } ~ImportingNow() { assert(m_importing == true); m_importing = false; } }; void ImportBlocks(ChainstateManager& chainman, std::vector vImportFiles) { ScheduleBatchPriority(); { ImportingNow imp{chainman.m_blockman.m_importing}; // -reindex if (fReindex) { int nFile = 0; // Map of disk positions for blocks with unknown parent (only used for reindex); // parent hash -> child disk position, multiple children can have the same parent. std::multimap blocks_with_unknown_parent; while (true) { FlatFilePos pos(nFile, 0); if (!fs::exists(chainman.m_blockman.GetBlockPosFilename(pos))) { break; // No block files left to reindex } FILE* file = chainman.m_blockman.OpenBlockFile(pos, true); if (!file) { break; // This error is logged in OpenBlockFile } LogPrintf("Reindexing block file blk%05u.dat...\n", (unsigned int)nFile); chainman.LoadExternalBlockFile(file, &pos, &blocks_with_unknown_parent); if (chainman.m_interrupt) { LogPrintf("Interrupt requested. Exit %s\n", __func__); return; } nFile++; } WITH_LOCK(::cs_main, chainman.m_blockman.m_block_tree_db->WriteReindexing(false)); fReindex = false; LogPrintf("Reindexing finished\n"); // To avoid ending up in a situation without genesis block, re-try initializing (no-op if reindexing worked): chainman.ActiveChainstate().LoadGenesisBlock(); } // -loadblock= for (const fs::path& path : vImportFiles) { FILE* file = fsbridge::fopen(path, "rb"); if (file) { LogPrintf("Importing blocks file %s...\n", fs::PathToString(path)); chainman.LoadExternalBlockFile(file); if (chainman.m_interrupt) { LogPrintf("Interrupt requested. Exit %s\n", __func__); return; } } else { LogPrintf("Warning: Could not open blocks file %s\n", fs::PathToString(path)); } } // scan for better chains in the block chain database, that are not yet connected in the active best chain // We can't hold cs_main during ActivateBestChain even though we're accessing // the chainman unique_ptrs since ABC requires us not to be holding cs_main, so retrieve // the relevant pointers before the ABC call. for (Chainstate* chainstate : WITH_LOCK(::cs_main, return chainman.GetAll())) { BlockValidationState state; if (!chainstate->ActivateBestChain(state, nullptr)) { chainman.GetNotifications().fatalError(strprintf("Failed to connect best block (%s)", state.ToString())); return; } } } // End scope of ImportingNow } } // namespace node