// Copyright (c) 2009-2012 The Bitcoin developers // Copyright (c) 2011-2013 The PPCoin developers // Copyright (c) 2013 NovaCoin Developers // Distributed under the MIT/X11 software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. #include // for 'map_list_of()' #include #include "checkpoints.h" #include "db.h" #include "main.h" #include "uint256.h" namespace Checkpoints { typedef std::map MapCheckpoints; // hardened checkpoints // // What makes a good checkpoint block? // + Is surrounded by blocks with reasonable timestamps // (no blocks before with a timestamp after, none after with // timestamp before) // + Contains no strange transactions // static MapCheckpoints mapCheckpoints = boost::assign::map_list_of ( 0, hashGenesisBlockOfficial ) ( 6000, uint256("0x000000000945e3c9d8e15df834e802521eb79f9ceb4191a27bdfadad4b777f4a")) ( 8700, uint256("0x00000000014270724837789c9a69859290f6bdee38556bc4561c21f17935a178")) ( 13560, uint256("0xa1591a0fcbf11f282d671581edb9f0aadcd06fee69761081e0a3245914c13729")) ( 14189, uint256("0x00000000020f76474d2522b19c7bfafc43ba6ecbabae54293bcd9546159c8c1d")) ; bool CheckHardened(int nHeight, const uint256& hash) { if (fTestNet) return true; // Testnet has no checkpoints MapCheckpoints::const_iterator i = mapCheckpoints.find(nHeight); if (i == mapCheckpoints.end()) return true; return hash == i->second; } int GetTotalBlocksEstimate() { if (fTestNet) return 0; return mapCheckpoints.rbegin()->first; } CBlockIndex* GetLastCheckpoint(const std::map& mapBlockIndex) { if (fTestNet) { std::map::const_iterator t = mapBlockIndex.find(hashGenesisBlock); if (t != mapBlockIndex.end()) return t->second; return NULL; } BOOST_REVERSE_FOREACH(const MapCheckpoints::value_type& i, mapCheckpoints) { const uint256& hash = i.second; std::map::const_iterator t = mapBlockIndex.find(hash); if (t != mapBlockIndex.end()) return t->second; } return NULL; } // ppcoin: synchronized checkpoint (centrally broadcasted) uint256 hashSyncCheckpoint = 0; uint256 hashPendingCheckpoint = 0; CSyncCheckpoint checkpointMessage; CSyncCheckpoint checkpointMessagePending; uint256 hashInvalidCheckpoint = 0; CCriticalSection cs_hashSyncCheckpoint; // ppcoin: get last synchronized checkpoint CBlockIndex* GetLastSyncCheckpoint() { LOCK(cs_hashSyncCheckpoint); if (!mapBlockIndex.count(hashSyncCheckpoint)) error("GetSyncCheckpoint: block index missing for current sync-checkpoint %s", hashSyncCheckpoint.ToString().c_str()); else return mapBlockIndex[hashSyncCheckpoint]; return NULL; } // ppcoin: only descendant of current sync-checkpoint is allowed bool ValidateSyncCheckpoint(uint256 hashCheckpoint) { if (!mapBlockIndex.count(hashSyncCheckpoint)) return error("ValidateSyncCheckpoint: block index missing for current sync-checkpoint %s", hashSyncCheckpoint.ToString().c_str()); if (!mapBlockIndex.count(hashCheckpoint)) return error("ValidateSyncCheckpoint: block index missing for received sync-checkpoint %s", hashCheckpoint.ToString().c_str()); CBlockIndex* pindexSyncCheckpoint = mapBlockIndex[hashSyncCheckpoint]; CBlockIndex* pindexCheckpointRecv = mapBlockIndex[hashCheckpoint]; if (pindexCheckpointRecv->nHeight <= pindexSyncCheckpoint->nHeight) { // Received an older checkpoint, trace back from current checkpoint // to the same height of the received checkpoint to verify // that current checkpoint should be a descendant block CBlockIndex* pindex = pindexSyncCheckpoint; while (pindex->nHeight > pindexCheckpointRecv->nHeight) if (!(pindex = pindex->pprev)) return error("ValidateSyncCheckpoint: pprev1 null - block index structure failure"); if (pindex->GetBlockHash() != hashCheckpoint) { hashInvalidCheckpoint = hashCheckpoint; return error("ValidateSyncCheckpoint: new sync-checkpoint %s is conflicting with current sync-checkpoint %s", hashCheckpoint.ToString().c_str(), hashSyncCheckpoint.ToString().c_str()); } return false; // ignore older checkpoint } // Received checkpoint should be a descendant block of the current // checkpoint. Trace back to the same height of current checkpoint // to verify. CBlockIndex* pindex = pindexCheckpointRecv; while (pindex->nHeight > pindexSyncCheckpoint->nHeight) if (!(pindex = pindex->pprev)) return error("ValidateSyncCheckpoint: pprev2 null - block index structure failure"); if (pindex->GetBlockHash() != hashSyncCheckpoint) { hashInvalidCheckpoint = hashCheckpoint; return error("ValidateSyncCheckpoint: new sync-checkpoint %s is not a descendant of current sync-checkpoint %s", hashCheckpoint.ToString().c_str(), hashSyncCheckpoint.ToString().c_str()); } return true; } bool WriteSyncCheckpoint(const uint256& hashCheckpoint) { CTxDB txdb; txdb.TxnBegin(); if (!txdb.WriteSyncCheckpoint(hashCheckpoint)) { txdb.TxnAbort(); return error("WriteSyncCheckpoint(): failed to write to db sync checkpoint %s", hashCheckpoint.ToString().c_str()); } if (!txdb.TxnCommit()) return error("WriteSyncCheckpoint(): failed to commit to db sync checkpoint %s", hashCheckpoint.ToString().c_str()); txdb.Close(); Checkpoints::hashSyncCheckpoint = hashCheckpoint; return true; } bool AcceptPendingSyncCheckpoint() { LOCK(cs_hashSyncCheckpoint); if (hashPendingCheckpoint != 0 && mapBlockIndex.count(hashPendingCheckpoint)) { if (!ValidateSyncCheckpoint(hashPendingCheckpoint)) { hashPendingCheckpoint = 0; checkpointMessagePending.SetNull(); return false; } CTxDB txdb; CBlockIndex* pindexCheckpoint = mapBlockIndex[hashPendingCheckpoint]; if (!pindexCheckpoint->IsInMainChain()) { CBlock block; if (!block.ReadFromDisk(pindexCheckpoint)) return error("AcceptPendingSyncCheckpoint: ReadFromDisk failed for sync checkpoint %s", hashPendingCheckpoint.ToString().c_str()); if (!block.SetBestChain(txdb, pindexCheckpoint)) { hashInvalidCheckpoint = hashPendingCheckpoint; return error("AcceptPendingSyncCheckpoint: SetBestChain failed for sync checkpoint %s", hashPendingCheckpoint.ToString().c_str()); } } txdb.Close(); if (!WriteSyncCheckpoint(hashPendingCheckpoint)) return error("AcceptPendingSyncCheckpoint(): failed to write sync checkpoint %s", hashPendingCheckpoint.ToString().c_str()); hashPendingCheckpoint = 0; checkpointMessage = checkpointMessagePending; checkpointMessagePending.SetNull(); printf("AcceptPendingSyncCheckpoint : sync-checkpoint at %s\n", hashSyncCheckpoint.ToString().c_str()); // relay the checkpoint if (!checkpointMessage.IsNull()) { BOOST_FOREACH(CNode* pnode, vNodes) checkpointMessage.RelayTo(pnode); } return true; } return false; } // Automatically select a suitable sync-checkpoint uint256 AutoSelectSyncCheckpoint() { // Proof-of-work blocks are immediately checkpointed // to defend against 51% attack which rejects other miners block // Select the last proof-of-work block const CBlockIndex *pindex = GetLastBlockIndex(pindexBest, false); // Search forward for a block within max span and maturity window while (pindex->pnext && (pindex->GetBlockTime() + CHECKPOINT_MAX_SPAN <= pindexBest->GetBlockTime() || pindex->nHeight + std::min(6, nCoinbaseMaturity - 20) <= pindexBest->nHeight)) pindex = pindex->pnext; return pindex->GetBlockHash(); } // Check against synchronized checkpoint bool CheckSync(const uint256& hashBlock, const CBlockIndex* pindexPrev) { if (fTestNet) return true; // Testnet has no checkpoints int nHeight = pindexPrev->nHeight + 1; LOCK(cs_hashSyncCheckpoint); // sync-checkpoint should always be accepted block assert(mapBlockIndex.count(hashSyncCheckpoint)); const CBlockIndex* pindexSync = mapBlockIndex[hashSyncCheckpoint]; if (nHeight > pindexSync->nHeight) { // trace back to same height as sync-checkpoint const CBlockIndex* pindex = pindexPrev; while (pindex->nHeight > pindexSync->nHeight) if (!(pindex = pindex->pprev)) return error("CheckSync: pprev null - block index structure failure"); if (pindex->nHeight < pindexSync->nHeight || pindex->GetBlockHash() != hashSyncCheckpoint) return false; // only descendant of sync-checkpoint can pass check } if (nHeight == pindexSync->nHeight && hashBlock != hashSyncCheckpoint) return false; // same height with sync-checkpoint if (nHeight < pindexSync->nHeight && !mapBlockIndex.count(hashBlock)) return false; // lower height than sync-checkpoint return true; } bool WantedByPendingSyncCheckpoint(uint256 hashBlock) { LOCK(cs_hashSyncCheckpoint); if (hashPendingCheckpoint == 0) return false; if (hashBlock == hashPendingCheckpoint) return true; if (mapOrphanBlocks.count(hashPendingCheckpoint) && hashBlock == WantedByOrphan(mapOrphanBlocks[hashPendingCheckpoint])) return true; return false; } // ppcoin: reset synchronized checkpoint to last hardened checkpoint bool ResetSyncCheckpoint() { LOCK(cs_hashSyncCheckpoint); const uint256& hash = mapCheckpoints.rbegin()->second; if (mapBlockIndex.count(hash) && !mapBlockIndex[hash]->IsInMainChain()) { // checkpoint block accepted but not yet in main chain printf("ResetSyncCheckpoint: SetBestChain to hardened checkpoint %s\n", hash.ToString().c_str()); CTxDB txdb; CBlock block; if (!block.ReadFromDisk(mapBlockIndex[hash])) return error("ResetSyncCheckpoint: ReadFromDisk failed for hardened checkpoint %s", hash.ToString().c_str()); if (!block.SetBestChain(txdb, mapBlockIndex[hash])) { return error("ResetSyncCheckpoint: SetBestChain failed for hardened checkpoint %s", hash.ToString().c_str()); } txdb.Close(); } else if(!mapBlockIndex.count(hash)) { // checkpoint block not yet accepted hashPendingCheckpoint = hash; checkpointMessagePending.SetNull(); printf("ResetSyncCheckpoint: pending for sync-checkpoint %s\n", hashPendingCheckpoint.ToString().c_str()); } BOOST_REVERSE_FOREACH(const MapCheckpoints::value_type& i, mapCheckpoints) { const uint256& hash = i.second; if (mapBlockIndex.count(hash) && mapBlockIndex[hash]->IsInMainChain()) { if (!WriteSyncCheckpoint(hash)) return error("ResetSyncCheckpoint: failed to write sync checkpoint %s", hash.ToString().c_str()); printf("ResetSyncCheckpoint: sync-checkpoint reset to %s\n", hashSyncCheckpoint.ToString().c_str()); return true; } } return false; } void AskForPendingSyncCheckpoint(CNode* pfrom) { LOCK(cs_hashSyncCheckpoint); if (pfrom && hashPendingCheckpoint != 0 && (!mapBlockIndex.count(hashPendingCheckpoint)) && (!mapOrphanBlocks.count(hashPendingCheckpoint))) pfrom->AskFor(CInv(MSG_BLOCK, hashPendingCheckpoint)); } bool SetCheckpointPrivKey(std::string strPrivKey) { // Test signing a sync-checkpoint with genesis block CSyncCheckpoint checkpoint; checkpoint.hashCheckpoint = hashGenesisBlock; CDataStream sMsg(SER_NETWORK, PROTOCOL_VERSION); sMsg << (CUnsignedSyncCheckpoint)checkpoint; checkpoint.vchMsg = std::vector(sMsg.begin(), sMsg.end()); std::vector vchPrivKey = ParseHex(strPrivKey); CKey key; key.SetPrivKey(CPrivKey(vchPrivKey.begin(), vchPrivKey.end())); // if key is not correct openssl may crash if (!key.Sign(Hash(checkpoint.vchMsg.begin(), checkpoint.vchMsg.end()), checkpoint.vchSig)) return false; // Test signing successful, proceed CSyncCheckpoint::strMasterPrivKey = strPrivKey; return true; } bool SendSyncCheckpoint(uint256 hashCheckpoint) { CSyncCheckpoint checkpoint; checkpoint.hashCheckpoint = hashCheckpoint; CDataStream sMsg(SER_NETWORK, PROTOCOL_VERSION); sMsg << (CUnsignedSyncCheckpoint)checkpoint; checkpoint.vchMsg = std::vector(sMsg.begin(), sMsg.end()); if (CSyncCheckpoint::strMasterPrivKey.empty()) return error("SendSyncCheckpoint: Checkpoint master key unavailable."); std::vector vchPrivKey = ParseHex(CSyncCheckpoint::strMasterPrivKey); CKey key; key.SetPrivKey(CPrivKey(vchPrivKey.begin(), vchPrivKey.end())); // if key is not correct openssl may crash if (!key.Sign(Hash(checkpoint.vchMsg.begin(), checkpoint.vchMsg.end()), checkpoint.vchSig)) return error("SendSyncCheckpoint: Unable to sign checkpoint, check private key?"); if(!checkpoint.ProcessSyncCheckpoint(NULL)) { printf("WARNING: SendSyncCheckpoint: Failed to process checkpoint.\n"); return false; } // Relay checkpoint { LOCK(cs_vNodes); BOOST_FOREACH(CNode* pnode, vNodes) checkpoint.RelayTo(pnode); } return true; } // Is the sync-checkpoint outside maturity window? bool IsMatureSyncCheckpoint() { LOCK(cs_hashSyncCheckpoint); // sync-checkpoint should always be accepted block assert(mapBlockIndex.count(hashSyncCheckpoint)); const CBlockIndex* pindexSync = mapBlockIndex[hashSyncCheckpoint]; return (nBestHeight >= pindexSync->nHeight + nCoinbaseMaturity || pindexSync->GetBlockTime() + nStakeMinAge < GetAdjustedTime()); } // Is the sync-checkpoint too old? bool IsSyncCheckpointTooOld(unsigned int nSeconds) { LOCK(cs_hashSyncCheckpoint); // sync-checkpoint should always be accepted block assert(mapBlockIndex.count(hashSyncCheckpoint)); const CBlockIndex* pindexSync = mapBlockIndex[hashSyncCheckpoint]; return (pindexSync->GetBlockTime() + nSeconds < GetAdjustedTime()); } } // ppcoin: sync-checkpoint master key const std::string CSyncCheckpoint::strMasterPubKey = "04a51b735f816de4ec3f891d5b38bbc91e1f7245c7c08d17990760b86b4d8fc3910a850ffecf73bfa8886f01739a0c4c4322201282d07b6e48ce931cc92af94850"; std::string CSyncCheckpoint::strMasterPrivKey = ""; // ppcoin: verify signature of sync-checkpoint message bool CSyncCheckpoint::CheckSignature() { CKey key; if (!key.SetPubKey(ParseHex(CSyncCheckpoint::strMasterPubKey))) return error("CSyncCheckpoint::CheckSignature() : SetPubKey failed"); if (!key.Verify(Hash(vchMsg.begin(), vchMsg.end()), vchSig)) return error("CSyncCheckpoint::CheckSignature() : verify signature failed"); // Now unserialize the data CDataStream sMsg(vchMsg, SER_NETWORK, PROTOCOL_VERSION); sMsg >> *(CUnsignedSyncCheckpoint*)this; return true; } // ppcoin: process synchronized checkpoint bool CSyncCheckpoint::ProcessSyncCheckpoint(CNode* pfrom) { if (!CheckSignature()) return false; LOCK(Checkpoints::cs_hashSyncCheckpoint); if (!mapBlockIndex.count(hashCheckpoint)) { // We haven't received the checkpoint chain, keep the checkpoint as pending Checkpoints::hashPendingCheckpoint = hashCheckpoint; Checkpoints::checkpointMessagePending = *this; printf("ProcessSyncCheckpoint: pending for sync-checkpoint %s\n", hashCheckpoint.ToString().c_str()); // Ask this guy to fill in what we're missing if (pfrom) { pfrom->PushGetBlocks(pindexBest, hashCheckpoint); // ask directly as well in case rejected earlier by duplicate // proof-of-stake because getblocks may not get it this time pfrom->AskFor(CInv(MSG_BLOCK, mapOrphanBlocks.count(hashCheckpoint)? WantedByOrphan(mapOrphanBlocks[hashCheckpoint]) : hashCheckpoint)); } return false; } if (!Checkpoints::ValidateSyncCheckpoint(hashCheckpoint)) return false; CTxDB txdb; CBlockIndex* pindexCheckpoint = mapBlockIndex[hashCheckpoint]; if (!pindexCheckpoint->IsInMainChain()) { // checkpoint chain received but not yet main chain CBlock block; if (!block.ReadFromDisk(pindexCheckpoint)) return error("ProcessSyncCheckpoint: ReadFromDisk failed for sync checkpoint %s", hashCheckpoint.ToString().c_str()); if (!block.SetBestChain(txdb, pindexCheckpoint)) { Checkpoints::hashInvalidCheckpoint = hashCheckpoint; return error("ProcessSyncCheckpoint: SetBestChain failed for sync checkpoint %s", hashCheckpoint.ToString().c_str()); } } txdb.Close(); if (!Checkpoints::WriteSyncCheckpoint(hashCheckpoint)) return error("ProcessSyncCheckpoint(): failed to write sync checkpoint %s", hashCheckpoint.ToString().c_str()); Checkpoints::checkpointMessage = *this; Checkpoints::hashPendingCheckpoint = 0; Checkpoints::checkpointMessagePending.SetNull(); printf("ProcessSyncCheckpoint: sync-checkpoint at %s\n", hashCheckpoint.ToString().c_str()); return true; }