// Copyright (c) 2009-2010 Satoshi Nakamoto // Copyright (c) 2009-2012 The Bitcoin developers // Distributed under the MIT/X11 software license, see the accompanying // file license.txt or http://www.opensource.org/licenses/mit-license.php. #include "headers.h" #include "db.h" #include "net.h" #include #include #include using namespace std; using namespace boost; unsigned int nWalletDBUpdated; uint64 nAccountingEntryNumber = 0; // // CDB // static CCriticalSection cs_db; static bool fDbEnvInit = false; DbEnv dbenv(0); static map mapFileUseCount; static map mapDb; static void EnvShutdown() { if (!fDbEnvInit) return; fDbEnvInit = false; try { dbenv.close(0); } catch (const DbException& e) { printf("EnvShutdown exception: %s (%d)\n", e.what(), e.get_errno()); } DbEnv(0).remove(GetDataDir().c_str(), 0); } class CDBInit { public: CDBInit() { } ~CDBInit() { EnvShutdown(); } } instance_of_cdbinit; CDB::CDB(const char* pszFile, const char* pszMode) : pdb(NULL) { int ret; if (pszFile == NULL) return; fReadOnly = (!strchr(pszMode, '+') && !strchr(pszMode, 'w')); bool fCreate = strchr(pszMode, 'c'); unsigned int nFlags = DB_THREAD; if (fCreate) nFlags |= DB_CREATE; CRITICAL_BLOCK(cs_db) { if (!fDbEnvInit) { if (fShutdown) return; string strDataDir = GetDataDir(); string strLogDir = strDataDir + "/database"; filesystem::create_directory(strLogDir.c_str()); string strErrorFile = strDataDir + "/db.log"; printf("dbenv.open strLogDir=%s strErrorFile=%s\n", strLogDir.c_str(), strErrorFile.c_str()); int nDbCache = GetArg("-dbcache", 25); dbenv.set_lg_dir(strLogDir.c_str()); dbenv.set_cachesize(nDbCache / 1024, (nDbCache % 1024)*1048576, 1); dbenv.set_lg_bsize(10485760); dbenv.set_lg_max(104857600); dbenv.set_lk_max_locks(10000); dbenv.set_lk_max_objects(10000); dbenv.set_errfile(fopen(strErrorFile.c_str(), "a")); /// debug dbenv.set_flags(DB_AUTO_COMMIT, 1); ret = dbenv.open(strDataDir.c_str(), DB_CREATE | DB_INIT_LOCK | DB_INIT_LOG | DB_INIT_MPOOL | DB_INIT_TXN | DB_THREAD | DB_RECOVER, S_IRUSR | S_IWUSR); if (ret > 0) throw runtime_error(strprintf("CDB() : error %d opening database environment", ret)); fDbEnvInit = true; } strFile = pszFile; ++mapFileUseCount[strFile]; pdb = mapDb[strFile]; if (pdb == NULL) { pdb = new Db(&dbenv, 0); ret = pdb->open(NULL, // Txn pointer pszFile, // Filename "main", // Logical db name DB_BTREE, // Database type nFlags, // Flags 0); if (ret > 0) { delete pdb; pdb = NULL; CRITICAL_BLOCK(cs_db) --mapFileUseCount[strFile]; strFile = ""; throw runtime_error(strprintf("CDB() : can't open database file %s, error %d", pszFile, ret)); } if (fCreate && !Exists(string("version"))) { bool fTmp = fReadOnly; fReadOnly = false; WriteVersion(CLIENT_VERSION); fReadOnly = fTmp; } mapDb[strFile] = pdb; } } } void CDB::Close() { if (!pdb) return; if (!vTxn.empty()) vTxn.front()->abort(); vTxn.clear(); pdb = NULL; // Flush database activity from memory pool to disk log unsigned int nMinutes = 0; if (fReadOnly) nMinutes = 1; if (strFile == "addr.dat") nMinutes = 2; if (strFile == "blkindex.dat" && IsInitialBlockDownload() && nBestHeight % 5000 != 0) nMinutes = 1; dbenv.txn_checkpoint(0, nMinutes, 0); CRITICAL_BLOCK(cs_db) --mapFileUseCount[strFile]; } void static CloseDb(const string& strFile) { CRITICAL_BLOCK(cs_db) { if (mapDb[strFile] != NULL) { // Close the database handle Db* pdb = mapDb[strFile]; pdb->close(0); delete pdb; mapDb[strFile] = NULL; } } } bool CDB::Rewrite(const string& strFile, const char* pszSkip) { while (!fShutdown) { CRITICAL_BLOCK(cs_db) { if (!mapFileUseCount.count(strFile) || mapFileUseCount[strFile] == 0) { // Flush log data to the dat file CloseDb(strFile); dbenv.txn_checkpoint(0, 0, 0); dbenv.lsn_reset(strFile.c_str(), 0); mapFileUseCount.erase(strFile); bool fSuccess = true; printf("Rewriting %s...\n", strFile.c_str()); string strFileRes = strFile + ".rewrite"; { // surround usage of db with extra {} CDB db(strFile.c_str(), "r"); Db* pdbCopy = new Db(&dbenv, 0); int ret = pdbCopy->open(NULL, // Txn pointer strFileRes.c_str(), // Filename "main", // Logical db name DB_BTREE, // Database type DB_CREATE, // Flags 0); if (ret > 0) { printf("Cannot create database file %s\n", strFileRes.c_str()); fSuccess = false; } Dbc* pcursor = db.GetCursor(); if (pcursor) while (fSuccess) { CDataStream ssKey; CDataStream ssValue; int ret = db.ReadAtCursor(pcursor, ssKey, ssValue, DB_NEXT); if (ret == DB_NOTFOUND) { pcursor->close(); break; } else if (ret != 0) { pcursor->close(); fSuccess = false; break; } if (pszSkip && strncmp(&ssKey[0], pszSkip, std::min(ssKey.size(), strlen(pszSkip))) == 0) continue; if (strncmp(&ssKey[0], "\x07version", 8) == 0) { // Update version: ssValue.clear(); ssValue << CLIENT_VERSION; } Dbt datKey(&ssKey[0], ssKey.size()); Dbt datValue(&ssValue[0], ssValue.size()); int ret2 = pdbCopy->put(NULL, &datKey, &datValue, DB_NOOVERWRITE); if (ret2 > 0) fSuccess = false; } if (fSuccess) { db.Close(); CloseDb(strFile); if (pdbCopy->close(0)) fSuccess = false; delete pdbCopy; } } if (fSuccess) { Db dbA(&dbenv, 0); if (dbA.remove(strFile.c_str(), NULL, 0)) fSuccess = false; Db dbB(&dbenv, 0); if (dbB.rename(strFileRes.c_str(), NULL, strFile.c_str(), 0)) fSuccess = false; } if (!fSuccess) printf("Rewriting of %s FAILED!\n", strFileRes.c_str()); return fSuccess; } } Sleep(100); } return false; } void DBFlush(bool fShutdown) { // Flush log data to the actual data file // on all files that are not in use printf("DBFlush(%s)%s\n", fShutdown ? "true" : "false", fDbEnvInit ? "" : " db not started"); if (!fDbEnvInit) return; CRITICAL_BLOCK(cs_db) { map::iterator mi = mapFileUseCount.begin(); while (mi != mapFileUseCount.end()) { string strFile = (*mi).first; int nRefCount = (*mi).second; printf("%s refcount=%d\n", strFile.c_str(), nRefCount); if (nRefCount == 0) { // Move log data to the dat file CloseDb(strFile); dbenv.txn_checkpoint(0, 0, 0); printf("%s flush\n", strFile.c_str()); dbenv.lsn_reset(strFile.c_str(), 0); mapFileUseCount.erase(mi++); } else mi++; } if (fShutdown) { char** listp; if (mapFileUseCount.empty()) { dbenv.log_archive(&listp, DB_ARCH_REMOVE); EnvShutdown(); } } } } // // CTxDB // bool CTxDB::ReadTxIndex(uint256 hash, CTxIndex& txindex) { assert(!fClient); txindex.SetNull(); return Read(make_pair(string("tx"), hash), txindex); } bool CTxDB::UpdateTxIndex(uint256 hash, const CTxIndex& txindex) { assert(!fClient); return Write(make_pair(string("tx"), hash), txindex); } bool CTxDB::AddTxIndex(const CTransaction& tx, const CDiskTxPos& pos, int nHeight) { assert(!fClient); // Add to tx index uint256 hash = tx.GetHash(); CTxIndex txindex(pos, tx.vout.size()); return Write(make_pair(string("tx"), hash), txindex); } bool CTxDB::EraseTxIndex(const CTransaction& tx) { assert(!fClient); uint256 hash = tx.GetHash(); return Erase(make_pair(string("tx"), hash)); } bool CTxDB::ContainsTx(uint256 hash) { assert(!fClient); return Exists(make_pair(string("tx"), hash)); } bool CTxDB::ReadOwnerTxes(uint160 hash160, int nMinHeight, vector& vtx) { assert(!fClient); vtx.clear(); // Get cursor Dbc* pcursor = GetCursor(); if (!pcursor) return false; unsigned int fFlags = DB_SET_RANGE; loop { // Read next record CDataStream ssKey; if (fFlags == DB_SET_RANGE) ssKey << string("owner") << hash160 << CDiskTxPos(0, 0, 0); CDataStream ssValue; int ret = ReadAtCursor(pcursor, ssKey, ssValue, fFlags); fFlags = DB_NEXT; if (ret == DB_NOTFOUND) break; else if (ret != 0) { pcursor->close(); return false; } // Unserialize string strType; uint160 hashItem; CDiskTxPos pos; ssKey >> strType >> hashItem >> pos; int nItemHeight; ssValue >> nItemHeight; // Read transaction if (strType != "owner" || hashItem != hash160) break; if (nItemHeight >= nMinHeight) { vtx.resize(vtx.size()+1); if (!vtx.back().ReadFromDisk(pos)) { pcursor->close(); return false; } } } pcursor->close(); return true; } bool CTxDB::ReadDiskTx(uint256 hash, CTransaction& tx, CTxIndex& txindex) { assert(!fClient); tx.SetNull(); if (!ReadTxIndex(hash, txindex)) return false; return (tx.ReadFromDisk(txindex.pos)); } bool CTxDB::ReadDiskTx(uint256 hash, CTransaction& tx) { CTxIndex txindex; return ReadDiskTx(hash, tx, txindex); } bool CTxDB::ReadDiskTx(COutPoint outpoint, CTransaction& tx, CTxIndex& txindex) { return ReadDiskTx(outpoint.hash, tx, txindex); } bool CTxDB::ReadDiskTx(COutPoint outpoint, CTransaction& tx) { CTxIndex txindex; return ReadDiskTx(outpoint.hash, tx, txindex); } bool CTxDB::WriteBlockIndex(const CDiskBlockIndex& blockindex) { return Write(make_pair(string("blockindex"), blockindex.GetBlockHash()), blockindex); } bool CTxDB::EraseBlockIndex(uint256 hash) { return Erase(make_pair(string("blockindex"), hash)); } bool CTxDB::ReadHashBestChain(uint256& hashBestChain) { return Read(string("hashBestChain"), hashBestChain); } bool CTxDB::WriteHashBestChain(uint256 hashBestChain) { return Write(string("hashBestChain"), hashBestChain); } bool CTxDB::ReadBestInvalidWork(CBigNum& bnBestInvalidWork) { return Read(string("bnBestInvalidWork"), bnBestInvalidWork); } bool CTxDB::WriteBestInvalidWork(CBigNum bnBestInvalidWork) { return Write(string("bnBestInvalidWork"), bnBestInvalidWork); } CBlockIndex static * InsertBlockIndex(uint256 hash) { if (hash == 0) return NULL; // Return existing map::iterator mi = mapBlockIndex.find(hash); if (mi != mapBlockIndex.end()) return (*mi).second; // Create new CBlockIndex* pindexNew = new CBlockIndex(); if (!pindexNew) throw runtime_error("LoadBlockIndex() : new CBlockIndex failed"); mi = mapBlockIndex.insert(make_pair(hash, pindexNew)).first; pindexNew->phashBlock = &((*mi).first); return pindexNew; } bool CTxDB::LoadBlockIndex() { // Get database cursor Dbc* pcursor = GetCursor(); if (!pcursor) return false; // Load mapBlockIndex unsigned int fFlags = DB_SET_RANGE; loop { // Read next record CDataStream ssKey; if (fFlags == DB_SET_RANGE) ssKey << make_pair(string("blockindex"), uint256(0)); CDataStream ssValue; int ret = ReadAtCursor(pcursor, ssKey, ssValue, fFlags); fFlags = DB_NEXT; if (ret == DB_NOTFOUND) break; else if (ret != 0) return false; // Unserialize string strType; ssKey >> strType; if (strType == "blockindex") { CDiskBlockIndex diskindex; ssValue >> diskindex; // Construct block index object CBlockIndex* pindexNew = InsertBlockIndex(diskindex.GetBlockHash()); pindexNew->pprev = InsertBlockIndex(diskindex.hashPrev); pindexNew->pnext = InsertBlockIndex(diskindex.hashNext); pindexNew->nFile = diskindex.nFile; pindexNew->nBlockPos = diskindex.nBlockPos; pindexNew->nHeight = diskindex.nHeight; pindexNew->nVersion = diskindex.nVersion; pindexNew->hashMerkleRoot = diskindex.hashMerkleRoot; pindexNew->nTime = diskindex.nTime; pindexNew->nBits = diskindex.nBits; pindexNew->nNonce = diskindex.nNonce; // Watch for genesis block if (pindexGenesisBlock == NULL && diskindex.GetBlockHash() == hashGenesisBlock) pindexGenesisBlock = pindexNew; if (!pindexNew->CheckIndex()) return error("LoadBlockIndex() : CheckIndex failed at %d", pindexNew->nHeight); } else { break; } } pcursor->close(); // Calculate bnChainWork vector > vSortedByHeight; vSortedByHeight.reserve(mapBlockIndex.size()); BOOST_FOREACH(const PAIRTYPE(uint256, CBlockIndex*)& item, mapBlockIndex) { CBlockIndex* pindex = item.second; vSortedByHeight.push_back(make_pair(pindex->nHeight, pindex)); } sort(vSortedByHeight.begin(), vSortedByHeight.end()); BOOST_FOREACH(const PAIRTYPE(int, CBlockIndex*)& item, vSortedByHeight) { CBlockIndex* pindex = item.second; pindex->bnChainWork = (pindex->pprev ? pindex->pprev->bnChainWork : 0) + pindex->GetBlockWork(); } // Load hashBestChain pointer to end of best chain if (!ReadHashBestChain(hashBestChain)) { if (pindexGenesisBlock == NULL) return true; return error("CTxDB::LoadBlockIndex() : hashBestChain not loaded"); } if (!mapBlockIndex.count(hashBestChain)) return error("CTxDB::LoadBlockIndex() : hashBestChain not found in the block index"); pindexBest = mapBlockIndex[hashBestChain]; nBestHeight = pindexBest->nHeight; bnBestChainWork = pindexBest->bnChainWork; printf("LoadBlockIndex(): hashBestChain=%s height=%d\n", hashBestChain.ToString().substr(0,20).c_str(), nBestHeight); // Load bnBestInvalidWork, OK if it doesn't exist ReadBestInvalidWork(bnBestInvalidWork); // Verify blocks in the best chain int nCheckLevel = GetArg("-checklevel", 1); int nCheckDepth = GetArg( "-checkblocks", 2500); if (nCheckDepth == 0) nCheckDepth = 1000000000; // suffices until the year 19000 if (nCheckDepth > nBestHeight) nCheckDepth = nBestHeight; printf("Verifying last %i blocks at level %i\n", nCheckDepth, nCheckLevel); CBlockIndex* pindexFork = NULL; map, CBlockIndex*> mapBlockPos; for (CBlockIndex* pindex = pindexBest; pindex && pindex->pprev; pindex = pindex->pprev) { if (pindex->nHeight < nBestHeight-nCheckDepth) break; CBlock block; if (!block.ReadFromDisk(pindex)) return error("LoadBlockIndex() : block.ReadFromDisk failed"); // check level 1: verify block validity if (nCheckLevel>0 && !block.CheckBlock()) { printf("LoadBlockIndex() : *** found bad block at %d, hash=%s\n", pindex->nHeight, pindex->GetBlockHash().ToString().c_str()); pindexFork = pindex->pprev; } // check level 2: verify transaction index validity if (nCheckLevel>1) { pair pos = make_pair(pindex->nFile, pindex->nBlockPos); mapBlockPos[pos] = pindex; BOOST_FOREACH(const CTransaction &tx, block.vtx) { uint256 hashTx = tx.GetHash(); CTxIndex txindex; if (ReadTxIndex(hashTx, txindex)) { // check level 3: checker transaction hashes if (nCheckLevel>2 || pindex->nFile != txindex.pos.nFile || pindex->nBlockPos != txindex.pos.nBlockPos) { // either an error or a duplicate transaction CTransaction txFound; if (!txFound.ReadFromDisk(txindex.pos)) { printf("LoadBlockIndex() : *** cannot read mislocated transaction %s\n", hashTx.ToString().c_str()); pindexFork = pindex->pprev; } else if (txFound.GetHash() != hashTx) // not a duplicate tx { printf("LoadBlockIndex(): *** invalid tx position for %s\n", hashTx.ToString().c_str()); pindexFork = pindex->pprev; } } // check level 4: check whether spent txouts were spent within the main chain int nOutput = 0; if (nCheckLevel>3) BOOST_FOREACH(const CDiskTxPos &txpos, txindex.vSpent) { if (!txpos.IsNull()) { pair posFind = make_pair(txpos.nFile, txpos.nBlockPos); if (!mapBlockPos.count(posFind)) { printf("LoadBlockIndex(): *** found bad spend at %d, hashBlock=%s, hashTx=%s\n", pindex->nHeight, pindex->GetBlockHash().ToString().c_str(), hashTx.ToString().c_str()); pindexFork = pindex->pprev; } // check level 6: check whether spent txouts were spent by a valid transaction that consume them if (nCheckLevel>5) { CTransaction txSpend; if (!txSpend.ReadFromDisk(txpos)) { printf("LoadBlockIndex(): *** cannot read spending transaction of %s:%i from disk\n", hashTx.ToString().c_str(), nOutput); pindexFork = pindex->pprev; } else if (!txSpend.CheckTransaction()) { printf("LoadBlockIndex(): *** spending transaction of %s:%i is invalid\n", hashTx.ToString().c_str(), nOutput); pindexFork = pindex->pprev; } else { bool fFound = false; BOOST_FOREACH(const CTxIn &txin, txSpend.vin) if (txin.prevout.hash == hashTx && txin.prevout.n == nOutput) fFound = true; if (!fFound) { printf("LoadBlockIndex(): *** spending transaction of %s:%i does not spend it\n", hashTx.ToString().c_str(), nOutput); pindexFork = pindex->pprev; } } } } nOutput++; } } // check level 5: check whether all prevouts are marked spent if (nCheckLevel>4) BOOST_FOREACH(const CTxIn &txin, tx.vin) { CTxIndex txindex; if (ReadTxIndex(txin.prevout.hash, txindex)) if (txindex.vSpent.size()-1 < txin.prevout.n || txindex.vSpent[txin.prevout.n].IsNull()) { printf("LoadBlockIndex(): *** found unspent prevout %s:%i in %s\n", txin.prevout.hash.ToString().c_str(), txin.prevout.n, hashTx.ToString().c_str()); pindexFork = pindex->pprev; } } } } } if (pindexFork) { // Reorg back to the fork printf("LoadBlockIndex() : *** moving best chain pointer back to block %d\n", pindexFork->nHeight); CBlock block; if (!block.ReadFromDisk(pindexFork)) return error("LoadBlockIndex() : block.ReadFromDisk failed"); CTxDB txdb; block.SetBestChain(txdb, pindexFork); } return true; } // // CAddrDB // bool CAddrDB::WriteAddrman(const CAddrMan& addrman) { return Write(string("addrman"), addrman); } bool CAddrDB::LoadAddresses() { bool fAddrMan = false; if (Read(string("addrman"), addrman)) { printf("Loaded %i addresses\n", addrman.size()); fAddrMan = true; } vector vAddr; vector > vDelete; // Get cursor Dbc* pcursor = GetCursor(); if (!pcursor) return false; loop { // Read next record CDataStream ssKey; CDataStream ssValue; int ret = ReadAtCursor(pcursor, ssKey, ssValue); if (ret == DB_NOTFOUND) break; else if (ret != 0) return false; // Unserialize string strType; ssKey >> strType; if (strType == "addr") { if (fAddrMan) { vector vchKey; ssKey >> vchKey; vDelete.push_back(vchKey); } else { CAddress addr; ssValue >> addr; vAddr.push_back(addr); } } } pcursor->close(); BOOST_FOREACH(const vector &vchKey, vDelete) Erase(make_pair(string("addr"), vchKey)); if (!fAddrMan) { addrman.Add(vAddr, CNetAddr("0.0.0.0")); printf("Loaded %i addresses\n", addrman.size()); } return true; } bool LoadAddresses() { return CAddrDB("cr+").LoadAddresses(); } // // CWalletDB // bool CWalletDB::WriteName(const string& strAddress, const string& strName) { nWalletDBUpdated++; return Write(make_pair(string("name"), strAddress), strName); } bool CWalletDB::EraseName(const string& strAddress) { // This should only be used for sending addresses, never for receiving addresses, // receiving addresses must always have an address book entry if they're not change return. nWalletDBUpdated++; return Erase(make_pair(string("name"), strAddress)); } bool CWalletDB::ReadAccount(const string& strAccount, CAccount& account) { account.SetNull(); return Read(make_pair(string("acc"), strAccount), account); } bool CWalletDB::WriteAccount(const string& strAccount, const CAccount& account) { return Write(make_pair(string("acc"), strAccount), account); } bool CWalletDB::WriteAccountingEntry(const CAccountingEntry& acentry) { return Write(boost::make_tuple(string("acentry"), acentry.strAccount, ++nAccountingEntryNumber), acentry); } int64 CWalletDB::GetAccountCreditDebit(const string& strAccount) { list entries; ListAccountCreditDebit(strAccount, entries); int64 nCreditDebit = 0; BOOST_FOREACH (const CAccountingEntry& entry, entries) nCreditDebit += entry.nCreditDebit; return nCreditDebit; } void CWalletDB::ListAccountCreditDebit(const string& strAccount, list& entries) { bool fAllAccounts = (strAccount == "*"); Dbc* pcursor = GetCursor(); if (!pcursor) throw runtime_error("CWalletDB::ListAccountCreditDebit() : cannot create DB cursor"); unsigned int fFlags = DB_SET_RANGE; loop { // Read next record CDataStream ssKey; if (fFlags == DB_SET_RANGE) ssKey << boost::make_tuple(string("acentry"), (fAllAccounts? string("") : strAccount), uint64(0)); CDataStream ssValue; int ret = ReadAtCursor(pcursor, ssKey, ssValue, fFlags); fFlags = DB_NEXT; if (ret == DB_NOTFOUND) break; else if (ret != 0) { pcursor->close(); throw runtime_error("CWalletDB::ListAccountCreditDebit() : error scanning DB"); } // Unserialize string strType; ssKey >> strType; if (strType != "acentry") break; CAccountingEntry acentry; ssKey >> acentry.strAccount; if (!fAllAccounts && acentry.strAccount != strAccount) break; ssValue >> acentry; entries.push_back(acentry); } pcursor->close(); } int CWalletDB::LoadWallet(CWallet* pwallet) { pwallet->vchDefaultKey.clear(); int nFileVersion = 0; vector vWalletUpgrade; bool fIsEncrypted = false; //// todo: shouldn't we catch exceptions and try to recover and continue? CRITICAL_BLOCK(pwallet->cs_wallet) { int nMinVersion = 0; if (Read((string)"minversion", nMinVersion)) { if (nMinVersion > CLIENT_VERSION) return DB_TOO_NEW; pwallet->LoadMinVersion(nMinVersion); } // Get cursor Dbc* pcursor = GetCursor(); if (!pcursor) { printf("Error getting wallet database cursor\n"); return DB_CORRUPT; } loop { // Read next record CDataStream ssKey; CDataStream ssValue; int ret = ReadAtCursor(pcursor, ssKey, ssValue); if (ret == DB_NOTFOUND) break; else if (ret != 0) { printf("Error reading next record from wallet database\n"); return DB_CORRUPT; } // Unserialize // Taking advantage of the fact that pair serialization // is just the two items serialized one after the other string strType; ssKey >> strType; if (strType == "name") { string strAddress; ssKey >> strAddress; ssValue >> pwallet->mapAddressBook[strAddress]; } else if (strType == "tx") { uint256 hash; ssKey >> hash; CWalletTx& wtx = pwallet->mapWallet[hash]; ssValue >> wtx; wtx.BindWallet(pwallet); if (wtx.GetHash() != hash) printf("Error in wallet.dat, hash mismatch\n"); // Undo serialize changes in 31600 if (31404 <= wtx.fTimeReceivedIsTxTime && wtx.fTimeReceivedIsTxTime <= 31703) { if (!ssValue.empty()) { char fTmp; char fUnused; ssValue >> fTmp >> fUnused >> wtx.strFromAccount; printf("LoadWallet() upgrading tx ver=%d %d '%s' %s\n", wtx.fTimeReceivedIsTxTime, fTmp, wtx.strFromAccount.c_str(), hash.ToString().c_str()); wtx.fTimeReceivedIsTxTime = fTmp; } else { printf("LoadWallet() repairing tx ver=%d %s\n", wtx.fTimeReceivedIsTxTime, hash.ToString().c_str()); wtx.fTimeReceivedIsTxTime = 0; } vWalletUpgrade.push_back(hash); } //// debug print //printf("LoadWallet %s\n", wtx.GetHash().ToString().c_str()); //printf(" %12I64d %s %s %s\n", // wtx.vout[0].nValue, // DateTimeStrFormat("%x %H:%M:%S", wtx.GetBlockTime()).c_str(), // wtx.hashBlock.ToString().substr(0,20).c_str(), // wtx.mapValue["message"].c_str()); } else if (strType == "acentry") { string strAccount; ssKey >> strAccount; uint64 nNumber; ssKey >> nNumber; if (nNumber > nAccountingEntryNumber) nAccountingEntryNumber = nNumber; } else if (strType == "key" || strType == "wkey") { vector vchPubKey; ssKey >> vchPubKey; CKey key; if (strType == "key") { CPrivKey pkey; ssValue >> pkey; key.SetPubKey(vchPubKey); key.SetPrivKey(pkey); if (key.GetPubKey() != vchPubKey) { printf("Error reading wallet database: CPrivKey pubkey inconsistency\n"); return DB_CORRUPT; } if (!key.IsValid()) { printf("Error reading wallet database: invalid CPrivKey\n"); return DB_CORRUPT; } } else { CWalletKey wkey; ssValue >> wkey; key.SetPubKey(vchPubKey); key.SetPrivKey(wkey.vchPrivKey); if (key.GetPubKey() != vchPubKey) { printf("Error reading wallet database: CWalletKey pubkey inconsistency\n"); return DB_CORRUPT; } if (!key.IsValid()) { printf("Error reading wallet database: invalid CWalletKey\n"); return DB_CORRUPT; } } if (!pwallet->LoadKey(key)) { printf("Error reading wallet database: LoadKey failed\n"); return DB_CORRUPT; } } else if (strType == "mkey") { unsigned int nID; ssKey >> nID; CMasterKey kMasterKey; ssValue >> kMasterKey; if(pwallet->mapMasterKeys.count(nID) != 0) { printf("Error reading wallet database: duplicate CMasterKey id %u\n", nID); return DB_CORRUPT; } pwallet->mapMasterKeys[nID] = kMasterKey; if (pwallet->nMasterKeyMaxID < nID) pwallet->nMasterKeyMaxID = nID; } else if (strType == "ckey") { vector vchPubKey; ssKey >> vchPubKey; vector vchPrivKey; ssValue >> vchPrivKey; if (!pwallet->LoadCryptedKey(vchPubKey, vchPrivKey)) { printf("Error reading wallet database: LoadCryptedKey failed\n"); return DB_CORRUPT; } fIsEncrypted = true; } else if (strType == "defaultkey") { ssValue >> pwallet->vchDefaultKey; } else if (strType == "pool") { int64 nIndex; ssKey >> nIndex; pwallet->setKeyPool.insert(nIndex); } else if (strType == "version") { ssValue >> nFileVersion; if (nFileVersion == 10300) nFileVersion = 300; } else if (strType == "cscript") { uint160 hash; ssKey >> hash; CScript script; ssValue >> script; if (!pwallet->LoadCScript(script)) { printf("Error reading wallet database: LoadCScript failed\n"); return DB_CORRUPT; } } } pcursor->close(); } BOOST_FOREACH(uint256 hash, vWalletUpgrade) WriteTx(hash, pwallet->mapWallet[hash]); printf("nFileVersion = %d\n", nFileVersion); // Rewrite encrypted wallets of versions 0.4.0 and 0.5.0rc: if (fIsEncrypted && (nFileVersion == 40000 || nFileVersion == 50000)) return DB_NEED_REWRITE; if (nFileVersion < CLIENT_VERSION) // Update { // Get rid of old debug.log file in current directory if (nFileVersion <= 105 && !pszSetDataDir[0]) unlink("debug.log"); WriteVersion(CLIENT_VERSION); } return DB_LOAD_OK; } void ThreadFlushWalletDB(void* parg) { const string& strFile = ((const string*)parg)[0]; static bool fOneThread; if (fOneThread) return; fOneThread = true; if (!GetBoolArg("-flushwallet", true)) return; unsigned int nLastSeen = nWalletDBUpdated; unsigned int nLastFlushed = nWalletDBUpdated; int64 nLastWalletUpdate = GetTime(); while (!fShutdown) { Sleep(500); if (nLastSeen != nWalletDBUpdated) { nLastSeen = nWalletDBUpdated; nLastWalletUpdate = GetTime(); } if (nLastFlushed != nWalletDBUpdated && GetTime() - nLastWalletUpdate >= 2) { TRY_CRITICAL_BLOCK(cs_db) { // Don't do this if any databases are in use int nRefCount = 0; map::iterator mi = mapFileUseCount.begin(); while (mi != mapFileUseCount.end()) { nRefCount += (*mi).second; mi++; } if (nRefCount == 0 && !fShutdown) { map::iterator mi = mapFileUseCount.find(strFile); if (mi != mapFileUseCount.end()) { printf("%s ", DateTimeStrFormat("%x %H:%M:%S", GetTime()).c_str()); printf("Flushing wallet.dat\n"); nLastFlushed = nWalletDBUpdated; int64 nStart = GetTimeMillis(); // Flush wallet.dat so it's self contained CloseDb(strFile); dbenv.txn_checkpoint(0, 0, 0); dbenv.lsn_reset(strFile.c_str(), 0); mapFileUseCount.erase(mi++); printf("Flushed wallet.dat %"PRI64d"ms\n", GetTimeMillis() - nStart); } } } } } } bool BackupWallet(const CWallet& wallet, const string& strDest) { if (!wallet.fFileBacked) return false; while (!fShutdown) { CRITICAL_BLOCK(cs_db) { if (!mapFileUseCount.count(wallet.strWalletFile) || mapFileUseCount[wallet.strWalletFile] == 0) { // Flush log data to the dat file CloseDb(wallet.strWalletFile); dbenv.txn_checkpoint(0, 0, 0); dbenv.lsn_reset(wallet.strWalletFile.c_str(), 0); mapFileUseCount.erase(wallet.strWalletFile); // Copy wallet.dat filesystem::path pathSrc(GetDataDir() + "/" + wallet.strWalletFile); filesystem::path pathDest(strDest); if (filesystem::is_directory(pathDest)) pathDest = pathDest / wallet.strWalletFile; try { #if BOOST_VERSION >= 104000 filesystem::copy_file(pathSrc, pathDest, filesystem::copy_option::overwrite_if_exists); #else filesystem::copy_file(pathSrc, pathDest); #endif printf("copied wallet.dat to %s\n", pathDest.string().c_str()); return true; } catch(const filesystem::filesystem_error &e) { printf("error copying wallet.dat to %s - %s\n", pathDest.string().c_str(), e.what()); return false; } } } Sleep(100); } return false; }