// Copyright (c) 2009-2010 Satoshi Nakamoto // Copyright (c) 2009-2012 The Bitcoin developers // Distributed under the MIT/X11 software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. #ifndef BITCOIN_MAIN_H #define BITCOIN_MAIN_H #include "bignum.h" #include "sync.h" #include "net.h" #include "script.h" #include class CWallet; class CBlock; class CBlockIndex; class CKeyItem; class CReserveKey; class CAddress; class CInv; class CRequestTracker; class CNode; static const unsigned int MAX_BLOCK_SIZE = 1000000; static const unsigned int MAX_BLOCK_SIZE_GEN = MAX_BLOCK_SIZE/2; static const unsigned int MAX_BLOCK_SIGOPS = MAX_BLOCK_SIZE/50; static const unsigned int MAX_ORPHAN_TRANSACTIONS = MAX_BLOCK_SIZE/100; static const unsigned int MAX_INV_SZ = 50000; static const int64 MIN_TX_FEE = 50000; static const int64 MIN_RELAY_TX_FEE = 10000; static const int64 MAX_MONEY = 21000000 * COIN; inline bool MoneyRange(int64 nValue) { return (nValue >= 0 && nValue <= MAX_MONEY); } static const int COINBASE_MATURITY = 100; // Threshold for nLockTime: below this value it is interpreted as block number, otherwise as UNIX timestamp. static const unsigned int LOCKTIME_THRESHOLD = 500000000; // Tue Nov 5 00:53:20 1985 UTC #ifdef USE_UPNP static const int fHaveUPnP = true; #else static const int fHaveUPnP = false; #endif extern CScript COINBASE_FLAGS; extern CCriticalSection cs_main; extern std::map mapBlockIndex; extern uint256 hashGenesisBlock; extern CBlockIndex* pindexGenesisBlock; extern int nBestHeight; extern CBigNum bnBestChainWork; extern CBigNum bnBestInvalidWork; extern uint256 hashBestChain; extern CBlockIndex* pindexBest; extern unsigned int nTransactionsUpdated; extern uint64 nLastBlockTx; extern uint64 nLastBlockSize; extern const std::string strMessageMagic; extern double dHashesPerSec; extern int64 nHPSTimerStart; extern int64 nTimeBestReceived; extern CCriticalSection cs_setpwalletRegistered; extern std::set setpwalletRegistered; extern unsigned char pchMessageStart[4]; extern bool fImporting; // Settings extern int64 nTransactionFee; // Minimum disk space required - used in CheckDiskSpace() static const uint64 nMinDiskSpace = 52428800; class CReserveKey; class CTxDB; class CTxIndex; class CDiskBlockPos; void RegisterWallet(CWallet* pwalletIn); void UnregisterWallet(CWallet* pwalletIn); void SyncWithWallets(const CTransaction& tx, const CBlock* pblock = NULL, bool fUpdate = false); bool ProcessBlock(CNode* pfrom, CBlock* pblock); bool CheckDiskSpace(uint64 nAdditionalBytes=0); FILE* OpenBlockFile(const CDiskBlockPos &pos, const char* pszMode="rb"); bool LoadBlockIndex(bool fAllowNew=true); void PrintBlockTree(); CBlockIndex* FindBlockByHeight(int nHeight); bool ProcessMessages(CNode* pfrom); bool SendMessages(CNode* pto, bool fSendTrickle); void ThreadImport(void *parg); void GenerateBitcoins(bool fGenerate, CWallet* pwallet); CBlock* CreateNewBlock(CReserveKey& reservekey); void IncrementExtraNonce(CBlock* pblock, CBlockIndex* pindexPrev, unsigned int& nExtraNonce); void FormatHashBuffers(CBlock* pblock, char* pmidstate, char* pdata, char* phash1); bool CheckWork(CBlock* pblock, CWallet& wallet, CReserveKey& reservekey); bool CheckProofOfWork(uint256 hash, unsigned int nBits); unsigned int ComputeMinWork(unsigned int nBase, int64 nTime); int GetNumBlocksOfPeers(); bool IsInitialBlockDownload(); std::string GetWarnings(std::string strFor); bool GetTransaction(const uint256 &hash, CTransaction &tx, uint256 &hashBlock); bool GetWalletFile(CWallet* pwallet, std::string &strWalletFileOut); class CDiskBlockPos { public: int nHeight; int nAlternative; CDiskBlockPos() { SetNull(); } CDiskBlockPos(int nHeightIn, int nAlternativeIn = 0) { nHeight = nHeightIn; nAlternative = nAlternativeIn; } std::string GetAlternative() const { char c[9]={0,0,0,0,0,0,0,0,0}; char *cp = &c[8]; unsigned int n = nAlternative; while (n > 0 && cp>c) { n--; *(--cp) = 'a' + (n % 26); n /= 26; } return std::string(cp); } boost::filesystem::path GetDirectory(const boost::filesystem::path &base) const { assert(nHeight != -1); return base / strprintf("era%02u", nHeight / 210000) / strprintf("cycle%04u", nHeight / 2016); } boost::filesystem::path GetFileName(const boost::filesystem::path &base) const { return GetDirectory(base) / strprintf("%08u%s.blk", nHeight, GetAlternative().c_str()); } // TODO: make thread-safe (lockfile, atomic file creation, ...?) void MakeUnique(const boost::filesystem::path &base) { while (boost::filesystem::exists(GetFileName(base))) nAlternative++; } IMPLEMENT_SERIALIZE(({ CDiskBlockPos *me = const_cast(this); if (!fRead) { unsigned int nCode = (nHeight + 1) * 2 + (nAlternative > 0); READWRITE(VARINT(nCode)); if (nAlternative > 0) { unsigned int nAlt = nAlternative - 1; READWRITE(VARINT(nAlt)); } } else { unsigned int nCode = 0; READWRITE(VARINT(nCode)); me->nHeight = (nCode / 2) - 1; if (nCode & 1) { unsigned int nAlt = 0; READWRITE(VARINT(nAlt)); me->nAlternative = 1 + nAlt; } else { me->nAlternative = 0; } } });) friend bool operator==(const CDiskBlockPos &a, const CDiskBlockPos &b) { return ((a.nHeight == b.nHeight) && (a.nAlternative == b.nAlternative)); } friend bool operator!=(const CDiskBlockPos &a, const CDiskBlockPos &b) { return !(a == b); } void SetNull() { nHeight = -1; nAlternative = 0; } bool IsNull() const { return ((nHeight == -1) && (nAlternative == 0)); } void SetMemPool() { nHeight = -1; nAlternative = -1; } bool IsMemPool() const { return ((nHeight == -1) && (nAlternative == -1)); } }; /** Position on disk for a particular transaction. */ class CDiskTxPos { public: CDiskBlockPos blockPos; unsigned int nTxPos; CDiskTxPos(bool fInMemPool = false) { SetNull(); if (fInMemPool) blockPos.SetMemPool(); } CDiskTxPos(const CDiskBlockPos &block, unsigned int nTxPosIn) : blockPos(block), nTxPos(nTxPosIn) { } IMPLEMENT_SERIALIZE( READWRITE(blockPos); READWRITE(VARINT(nTxPos)); ) void SetNull() { blockPos.SetNull(); nTxPos = 0; } bool IsNull() const { return blockPos.IsNull(); } bool IsMemPool() const { return blockPos.IsMemPool(); } friend bool operator==(const CDiskTxPos& a, const CDiskTxPos& b) { return (a.blockPos == b.blockPos && a.nTxPos == b.nTxPos); } friend bool operator!=(const CDiskTxPos& a, const CDiskTxPos& b) { return !(a == b); } std::string ToString() const { if (IsNull()) return "null"; else if (blockPos.IsMemPool()) return "mempool"; else return strprintf("(%s, nTxPos=%u)", blockPos.GetFileName("").string().c_str(), nTxPos); } void print() const { printf("%s", ToString().c_str()); } }; /** An inpoint - a combination of a transaction and an index n into its vin */ class CInPoint { public: CTransaction* ptx; unsigned int n; CInPoint() { SetNull(); } CInPoint(CTransaction* ptxIn, unsigned int nIn) { ptx = ptxIn; n = nIn; } void SetNull() { ptx = NULL; n = (unsigned int) -1; } bool IsNull() const { return (ptx == NULL && n == (unsigned int) -1); } }; /** An outpoint - a combination of a transaction hash and an index n into its vout */ class COutPoint { public: uint256 hash; unsigned int n; COutPoint() { SetNull(); } COutPoint(uint256 hashIn, unsigned int nIn) { hash = hashIn; n = nIn; } IMPLEMENT_SERIALIZE( READWRITE(FLATDATA(*this)); ) void SetNull() { hash = 0; n = (unsigned int) -1; } bool IsNull() const { return (hash == 0 && n == (unsigned int) -1); } friend bool operator<(const COutPoint& a, const COutPoint& b) { return (a.hash < b.hash || (a.hash == b.hash && a.n < b.n)); } friend bool operator==(const COutPoint& a, const COutPoint& b) { return (a.hash == b.hash && a.n == b.n); } friend bool operator!=(const COutPoint& a, const COutPoint& b) { return !(a == b); } std::string ToString() const { return strprintf("COutPoint(%s, %u)", hash.ToString().substr(0,10).c_str(), n); } void print() const { printf("%s\n", ToString().c_str()); } }; /** An input of a transaction. It contains the location of the previous * transaction's output that it claims and a signature that matches the * output's public key. */ class CTxIn { public: COutPoint prevout; CScript scriptSig; unsigned int nSequence; CTxIn() { nSequence = std::numeric_limits::max(); } explicit CTxIn(COutPoint prevoutIn, CScript scriptSigIn=CScript(), unsigned int nSequenceIn=std::numeric_limits::max()) { prevout = prevoutIn; scriptSig = scriptSigIn; nSequence = nSequenceIn; } CTxIn(uint256 hashPrevTx, unsigned int nOut, CScript scriptSigIn=CScript(), unsigned int nSequenceIn=std::numeric_limits::max()) { prevout = COutPoint(hashPrevTx, nOut); scriptSig = scriptSigIn; nSequence = nSequenceIn; } IMPLEMENT_SERIALIZE ( READWRITE(prevout); READWRITE(scriptSig); READWRITE(nSequence); ) bool IsFinal() const { return (nSequence == std::numeric_limits::max()); } friend bool operator==(const CTxIn& a, const CTxIn& b) { return (a.prevout == b.prevout && a.scriptSig == b.scriptSig && a.nSequence == b.nSequence); } friend bool operator!=(const CTxIn& a, const CTxIn& b) { return !(a == b); } std::string ToString() const { std::string str; str += "CTxIn("; str += prevout.ToString(); if (prevout.IsNull()) str += strprintf(", coinbase %s", HexStr(scriptSig).c_str()); else str += strprintf(", scriptSig=%s", scriptSig.ToString().substr(0,24).c_str()); if (nSequence != std::numeric_limits::max()) str += strprintf(", nSequence=%u", nSequence); str += ")"; return str; } void print() const { printf("%s\n", ToString().c_str()); } }; /** An output of a transaction. It contains the public key that the next input * must be able to sign with to claim it. */ class CTxOut { public: int64 nValue; CScript scriptPubKey; CTxOut() { SetNull(); } CTxOut(int64 nValueIn, CScript scriptPubKeyIn) { nValue = nValueIn; scriptPubKey = scriptPubKeyIn; } IMPLEMENT_SERIALIZE ( READWRITE(nValue); READWRITE(scriptPubKey); ) void SetNull() { nValue = -1; scriptPubKey.clear(); } bool IsNull() const { return (nValue == -1); } uint256 GetHash() const { return SerializeHash(*this); } friend bool operator==(const CTxOut& a, const CTxOut& b) { return (a.nValue == b.nValue && a.scriptPubKey == b.scriptPubKey); } friend bool operator!=(const CTxOut& a, const CTxOut& b) { return !(a == b); } std::string ToString() const { if (scriptPubKey.size() < 6) return "CTxOut(error)"; return strprintf("CTxOut(nValue=%"PRI64d".%08"PRI64d", scriptPubKey=%s)", nValue / COIN, nValue % COIN, scriptPubKey.ToString().substr(0,30).c_str()); } void print() const { printf("%s\n", ToString().c_str()); } }; enum GetMinFee_mode { GMF_BLOCK, GMF_RELAY, GMF_SEND, }; typedef std::map > MapPrevTx; /** The basic transaction that is broadcasted on the network and contained in * blocks. A transaction can contain multiple inputs and outputs. */ class CTransaction { public: static const int CURRENT_VERSION=1; int nVersion; std::vector vin; std::vector vout; unsigned int nLockTime; // Denial-of-service detection: mutable int nDoS; bool DoS(int nDoSIn, bool fIn) const { nDoS += nDoSIn; return fIn; } CTransaction() { SetNull(); } IMPLEMENT_SERIALIZE ( READWRITE(this->nVersion); nVersion = this->nVersion; READWRITE(vin); READWRITE(vout); READWRITE(nLockTime); ) void SetNull() { nVersion = CTransaction::CURRENT_VERSION; vin.clear(); vout.clear(); nLockTime = 0; nDoS = 0; // Denial-of-service prevention } bool IsNull() const { return (vin.empty() && vout.empty()); } uint256 GetHash() const { return SerializeHash(*this); } bool IsFinal(int nBlockHeight=0, int64 nBlockTime=0) const { // Time based nLockTime implemented in 0.1.6 if (nLockTime == 0) return true; if (nBlockHeight == 0) nBlockHeight = nBestHeight; if (nBlockTime == 0) nBlockTime = GetAdjustedTime(); if ((int64)nLockTime < ((int64)nLockTime < LOCKTIME_THRESHOLD ? (int64)nBlockHeight : nBlockTime)) return true; BOOST_FOREACH(const CTxIn& txin, vin) if (!txin.IsFinal()) return false; return true; } bool IsNewerThan(const CTransaction& old) const { if (vin.size() != old.vin.size()) return false; for (unsigned int i = 0; i < vin.size(); i++) if (vin[i].prevout != old.vin[i].prevout) return false; bool fNewer = false; unsigned int nLowest = std::numeric_limits::max(); for (unsigned int i = 0; i < vin.size(); i++) { if (vin[i].nSequence != old.vin[i].nSequence) { if (vin[i].nSequence <= nLowest) { fNewer = false; nLowest = vin[i].nSequence; } if (old.vin[i].nSequence < nLowest) { fNewer = true; nLowest = old.vin[i].nSequence; } } } return fNewer; } bool IsCoinBase() const { return (vin.size() == 1 && vin[0].prevout.IsNull()); } /** Check for standard transaction types @return True if all outputs (scriptPubKeys) use only standard transaction forms */ bool IsStandard() const; /** Check for standard transaction types @param[in] mapInputs Map of previous transactions that have outputs we're spending @return True if all inputs (scriptSigs) use only standard transaction forms @see CTransaction::FetchInputs */ bool AreInputsStandard(const MapPrevTx& mapInputs) const; /** Count ECDSA signature operations the old-fashioned (pre-0.6) way @return number of sigops this transaction's outputs will produce when spent @see CTransaction::FetchInputs */ unsigned int GetLegacySigOpCount() const; /** Count ECDSA signature operations in pay-to-script-hash inputs. @param[in] mapInputs Map of previous transactions that have outputs we're spending @return maximum number of sigops required to validate this transaction's inputs @see CTransaction::FetchInputs */ unsigned int GetP2SHSigOpCount(const MapPrevTx& mapInputs) const; /** Amount of bitcoins spent by this transaction. @return sum of all outputs (note: does not include fees) */ int64 GetValueOut() const { int64 nValueOut = 0; BOOST_FOREACH(const CTxOut& txout, vout) { nValueOut += txout.nValue; if (!MoneyRange(txout.nValue) || !MoneyRange(nValueOut)) throw std::runtime_error("CTransaction::GetValueOut() : value out of range"); } return nValueOut; } /** Amount of bitcoins coming in to this transaction Note that lightweight clients may not know anything besides the hash of previous transactions, so may not be able to calculate this. @param[in] mapInputs Map of previous transactions that have outputs we're spending @return Sum of value of all inputs (scriptSigs) @see CTransaction::FetchInputs */ int64 GetValueIn(const MapPrevTx& mapInputs) const; static bool AllowFree(double dPriority) { // Large (in bytes) low-priority (new, small-coin) transactions // need a fee. return dPriority > COIN * 144 / 250; } int64 GetMinFee(unsigned int nBlockSize=1, bool fAllowFree=true, enum GetMinFee_mode mode=GMF_BLOCK) const; bool ReadFromDisk(CDiskTxPos pos, FILE** pfileRet=NULL) { CAutoFile filein = CAutoFile(OpenBlockFile(pos.blockPos, pfileRet ? "rb+" : "rb"), SER_DISK, CLIENT_VERSION); if (!filein) return error("CTransaction::ReadFromDisk() : OpenBlockFile failed"); // Read transaction if (fseek(filein, pos.nTxPos, SEEK_SET) != 0) return error("CTransaction::ReadFromDisk() : fseek failed"); try { filein >> *this; } catch (std::exception &e) { return error("%s() : deserialize or I/O error", __PRETTY_FUNCTION__); } // Return file pointer if (pfileRet) { if (fseek(filein, pos.nTxPos, SEEK_SET) != 0) return error("CTransaction::ReadFromDisk() : second fseek failed"); *pfileRet = filein.release(); } return true; } friend bool operator==(const CTransaction& a, const CTransaction& b) { return (a.nVersion == b.nVersion && a.vin == b.vin && a.vout == b.vout && a.nLockTime == b.nLockTime); } friend bool operator!=(const CTransaction& a, const CTransaction& b) { return !(a == b); } std::string ToString() const { std::string str; str += strprintf("CTransaction(hash=%s, ver=%d, vin.size=%"PRIszu", vout.size=%"PRIszu", nLockTime=%u)\n", GetHash().ToString().substr(0,10).c_str(), nVersion, vin.size(), vout.size(), nLockTime); for (unsigned int i = 0; i < vin.size(); i++) str += " " + vin[i].ToString() + "\n"; for (unsigned int i = 0; i < vout.size(); i++) str += " " + vout[i].ToString() + "\n"; return str; } void print() const { printf("%s", ToString().c_str()); } bool ReadFromDisk(CTxDB& txdb, COutPoint prevout, CTxIndex& txindexRet); bool ReadFromDisk(CTxDB& txdb, COutPoint prevout); bool ReadFromDisk(COutPoint prevout); bool DisconnectInputs(CTxDB& txdb); /** Fetch from memory and/or disk. inputsRet keys are transaction hashes. @param[in] txdb Transaction database @param[in] mapTestPool List of pending changes to the transaction index database @param[in] fBlock True if being called to add a new best-block to the chain @param[in] fMiner True if being called by CreateNewBlock @param[out] inputsRet Pointers to this transaction's inputs @param[out] fInvalid returns true if transaction is invalid @return Returns true if all inputs are in txdb or mapTestPool */ bool FetchInputs(CTxDB& txdb, const std::map& mapTestPool, bool fBlock, bool fMiner, MapPrevTx& inputsRet, bool& fInvalid); /** Sanity check previous transactions, then, if all checks succeed, mark them as spent by this transaction. @param[in] inputs Previous transactions (from FetchInputs) @param[out] mapTestPool Keeps track of inputs that need to be updated on disk @param[in] posThisTx Position of this transaction on disk @param[in] pindexBlock @param[in] fBlock true if called from ConnectBlock @param[in] fMiner true if called from CreateNewBlock @param[in] fStrictPayToScriptHash true if fully validating p2sh transactions @return Returns true if all checks succeed */ bool ConnectInputs(MapPrevTx inputs, std::map& mapTestPool, const CDiskTxPos& posThisTx, const CBlockIndex* pindexBlock, bool fBlock, bool fMiner, bool fStrictPayToScriptHash=true); bool ClientConnectInputs(); bool CheckTransaction() const; bool AcceptToMemoryPool(CTxDB& txdb, bool fCheckInputs=true, bool* pfMissingInputs=NULL); protected: const CTxOut& GetOutputFor(const CTxIn& input, const MapPrevTx& inputs) const; }; /** wrapper for CTxOut that provides a more compact serialization */ class CTxOutCompressor { private: CTxOut &txout; public: static uint64 CompressAmount(uint64 nAmount); static uint64 DecompressAmount(uint64 nAmount); CTxOutCompressor(CTxOut &txoutIn) : txout(txoutIn) { } IMPLEMENT_SERIALIZE(({ if (!fRead) { uint64 nVal = CompressAmount(txout.nValue); READWRITE(VARINT(nVal)); } else { uint64 nVal = 0; READWRITE(VARINT(nVal)); txout.nValue = DecompressAmount(nVal); } CScriptCompressor cscript(REF(txout.scriptPubKey)); READWRITE(cscript); });) }; /** Undo information for a CTxIn * * Contains the prevout's CTxOut being spent, and if this was the * last output of the affected transaction, its metadata as well * (coinbase or not, height, transaction version) */ class CTxInUndo { public: CTxOut txout; // the txout data before being spent bool fCoinBase; // if the outpoint was the last unspent: whether it belonged to a coinbase unsigned int nHeight; // if the outpoint was the last unspent: its height int nVersion; // if the outpoint was the last unspent: its version CTxInUndo() : txout(), fCoinBase(false), nHeight(0), nVersion(0) {} CTxInUndo(const CTxOut &txoutIn, bool fCoinBaseIn = false, unsigned int nHeightIn = 0, int nVersionIn = 0) : txout(txoutIn), fCoinBase(fCoinBaseIn), nHeight(nHeightIn), nVersion(nVersionIn) { } unsigned int GetSerializeSize(int nType, int nVersion) const { return ::GetSerializeSize(VARINT(nHeight*2+(fCoinBase ? 1 : 0)), nType, nVersion) + (nHeight > 0 ? ::GetSerializeSize(VARINT(this->nVersion), nType, nVersion) : 0) + ::GetSerializeSize(CTxOutCompressor(REF(txout)), nType, nVersion); } template void Serialize(Stream &s, int nType, int nVersion) const { ::Serialize(s, VARINT(nHeight*2+(fCoinBase ? 1 : 0)), nType, nVersion); if (nHeight > 0) ::Serialize(s, VARINT(this->nVersion), nType, nVersion); ::Serialize(s, CTxOutCompressor(REF(txout)), nType, nVersion); } template void Unserialize(Stream &s, int nType, int nVersion) { unsigned int nCode = 0; ::Unserialize(s, VARINT(nCode), nType, nVersion); nHeight = nCode / 2; fCoinBase = nCode & 1; if (nHeight > 0) ::Unserialize(s, VARINT(this->nVersion), nType, nVersion); ::Unserialize(s, REF(CTxOutCompressor(REF(txout))), nType, nVersion); } }; /** Undo information for a CTransaction */ class CTxUndo { public: std::vector vprevout; IMPLEMENT_SERIALIZE( READWRITE(vprevout); ) }; /** pruned version of CTransaction: only retains metadata and unspent transaction outputs * * Serialized format: * - VARINT(nVersion) * - VARINT(nCode) * - unspentness bitvector, for vout[2] and further; least significant byte first * - the non-spent CTxOuts (via CTxOutCompressor) * - VARINT(nHeight) * * The nCode value consists of: * - bit 1: IsCoinBase() * - bit 2: vout[0] is not spent * - bit 4: vout[1] is not spent * - The higher bits encode N, the number of non-zero bytes in the following bitvector. * - In case both bit 2 and bit 4 are unset, they encode N-1, as there must be at * least one non-spent output). * * Example: 0104835800816115944e077fe7c803cfa57f29b36bf87c1d358bb85e * <><><--------------------------------------------><----> * | \ | / * version code vout[1] height * * - version = 1 * - code = 4 (vout[1] is not spent, and 0 non-zero bytes of bitvector follow) * - unspentness bitvector: as 0 non-zero bytes follow, it has length 0 * - vout[1]: 835800816115944e077fe7c803cfa57f29b36bf87c1d35 * * 8358: compact amount representation for 60000000000 (600 BTC) * * 00: special txout type pay-to-pubkey-hash * * 816115944e077fe7c803cfa57f29b36bf87c1d35: address uint160 * - height = 203998 * * * Example: 0109044086ef97d5790061b01caab50f1b8e9c50a5057eb43c2d9563a4eebbd123008c988f1a4a4de2161e0f50aac7f17e7f9555caa486af3b * <><><--><--------------------------------------------------><----------------------------------------------><----> * / \ \ | | / * version code unspentness vout[4] vout[16] height * * - version = 1 * - code = 9 (coinbase, neither vout[0] or vout[1] are unspent, * 2 (1, +1 because both bit 2 and bit 4 are unset) non-zero bitvector bytes follow) * - unspentness bitvector: bits 2 (0x04) and 14 (0x4000) are set, so vout[2+2] and vout[14+2] are unspent * - vout[4]: 86ef97d5790061b01caab50f1b8e9c50a5057eb43c2d9563a4ee * * 86ef97d579: compact amount representation for 234925952 (2.35 BTC) * * 00: special txout type pay-to-pubkey-hash * * 61b01caab50f1b8e9c50a5057eb43c2d9563a4ee: address uint160 * - vout[16]: bbd123008c988f1a4a4de2161e0f50aac7f17e7f9555caa4 * * bbd123: compact amount representation for 110397 (0.001 BTC) * * 00: special txout type pay-to-pubkey-hash * * 8c988f1a4a4de2161e0f50aac7f17e7f9555caa4: address uint160 * - height = 120891 */ class CCoins { public: // whether transaction is a coinbase bool fCoinBase; // unspent transaction outputs; spent outputs are .IsNull(); spent outputs at the end of the array are dropped std::vector vout; // at which height this transaction was included in the active blockchain int nHeight; // version of the CTransaction; accesses to this value should probably check for nHeight as well, // as new tx version will probably only be introduced at certain heights int nVersion; // construct a CCoins from a CTransaction, at a given height CCoins(const CTransaction &tx, int nHeightIn) : fCoinBase(tx.IsCoinBase()), vout(tx.vout), nHeight(nHeightIn), nVersion(tx.nVersion) { } // empty constructor CCoins() : fCoinBase(false), vout(0), nHeight(0), nVersion(0) { } // remove spent outputs at the end of vout void Cleanup() { while (vout.size() > 0 && vout.back().IsNull()) vout.pop_back(); } // equality test friend bool operator==(const CCoins &a, const CCoins &b) { return a.fCoinBase == b.fCoinBase && a.nHeight == b.nHeight && a.nVersion == b.nVersion && a.vout == b.vout; } friend bool operator!=(const CCoins &a, const CCoins &b) { return !(a == b); } // calculate number of bytes for the bitmask, and its number of non-zero bytes // each bit in the bitmask represents the availability of one output, but the // availabilities of the first two outputs are encoded separately void CalcMaskSize(unsigned int &nBytes, unsigned int &nNonzeroBytes) const { unsigned int nLastUsedByte = 0; for (unsigned int b = 0; 2+b*8 < vout.size(); b++) { bool fZero = true; for (unsigned int i = 0; i < 8 && 2+b*8+i < vout.size(); i++) { if (!vout[2+b*8+i].IsNull()) { fZero = false; continue; } } if (!fZero) { nLastUsedByte = b + 1; nNonzeroBytes++; } } nBytes += nLastUsedByte; } bool IsCoinBase() const { return fCoinBase; } unsigned int GetSerializeSize(int nType, int nVersion) const { unsigned int nSize = 0; unsigned int nMaskSize = 0, nMaskCode = 0; CalcMaskSize(nMaskSize, nMaskCode); bool fFirst = vout.size() > 0 && !vout[0].IsNull(); bool fSecond = vout.size() > 1 && !vout[1].IsNull(); assert(fFirst || fSecond || nMaskCode); unsigned int nCode = 8*(nMaskCode - (fFirst || fSecond ? 0 : 1)) + (fCoinBase ? 1 : 0) + (fFirst ? 2 : 0) + (fSecond ? 4 : 0); // version nSize += ::GetSerializeSize(VARINT(this->nVersion), nType, nVersion); // size of header code nSize += ::GetSerializeSize(VARINT(nCode), nType, nVersion); // spentness bitmask nSize += nMaskSize; // txouts themself for (unsigned int i = 0; i < vout.size(); i++) if (!vout[i].IsNull()) nSize += ::GetSerializeSize(CTxOutCompressor(REF(vout[i])), nType, nVersion); // height nSize += ::GetSerializeSize(VARINT(nHeight), nType, nVersion); return nSize; } template void Serialize(Stream &s, int nType, int nVersion) const { unsigned int nMaskSize = 0, nMaskCode = 0; CalcMaskSize(nMaskSize, nMaskCode); bool fFirst = vout.size() > 0 && !vout[0].IsNull(); bool fSecond = vout.size() > 1 && !vout[1].IsNull(); assert(fFirst || fSecond || nMaskCode); unsigned int nCode = 8*(nMaskCode - (fFirst || fSecond ? 0 : 1)) + (fCoinBase ? 1 : 0) + (fFirst ? 2 : 0) + (fSecond ? 4 : 0); // version ::Serialize(s, VARINT(this->nVersion), nType, nVersion); // header code ::Serialize(s, VARINT(nCode), nType, nVersion); // spentness bitmask for (unsigned int b = 0; b void Unserialize(Stream &s, int nType, int nVersion) { unsigned int nCode = 0; // version ::Unserialize(s, VARINT(this->nVersion), nType, nVersion); // header code ::Unserialize(s, VARINT(nCode), nType, nVersion); fCoinBase = nCode & 1; std::vector vAvail(2, false); vAvail[0] = nCode & 2; vAvail[1] = nCode & 4; unsigned int nMaskCode = (nCode / 8) + ((nCode & 6) != 0 ? 0 : 1); // spentness bitmask while (nMaskCode > 0) { unsigned char chAvail = 0; ::Unserialize(s, chAvail, nType, nVersion); for (unsigned int p = 0; p < 8; p++) { bool f = (chAvail & (1 << p)) != 0; vAvail.push_back(f); } if (chAvail != 0) nMaskCode--; } // txouts themself vout.assign(vAvail.size(), CTxOut()); for (unsigned int i = 0; i < vAvail.size(); i++) { if (vAvail[i]) ::Unserialize(s, REF(CTxOutCompressor(vout[i])), nType, nVersion); } // coinbase height ::Unserialize(s, VARINT(nHeight), nType, nVersion); Cleanup(); } // mark an outpoint spent, and construct undo information bool Spend(const COutPoint &out, CTxInUndo &undo) { if (out.n >= vout.size()) return false; if (vout[out.n].IsNull()) return false; undo = CTxInUndo(vout[out.n]); vout[out.n].SetNull(); Cleanup(); if (vout.size() == 0) { undo.nHeight = nHeight; undo.fCoinBase = fCoinBase; undo.nVersion = this->nVersion; } return true; } // mark a vout spent bool Spend(int nPos) { CTxInUndo undo; COutPoint out(0, nPos); return Spend(out, undo); } // check whether a particular output is still available bool IsAvailable(unsigned int nPos) const { return (nPos < vout.size() && !vout[nPos].IsNull()); } // check whether the entire CCoins is spent // note that only !IsPruned() CCoins can be serialized bool IsPruned() const { BOOST_FOREACH(const CTxOut &out, vout) if (!out.IsNull()) return false; return true; } }; /** A transaction with a merkle branch linking it to the block chain. */ class CMerkleTx : public CTransaction { public: uint256 hashBlock; std::vector vMerkleBranch; int nIndex; // memory only mutable bool fMerkleVerified; CMerkleTx() { Init(); } CMerkleTx(const CTransaction& txIn) : CTransaction(txIn) { Init(); } void Init() { hashBlock = 0; nIndex = -1; fMerkleVerified = false; } IMPLEMENT_SERIALIZE ( nSerSize += SerReadWrite(s, *(CTransaction*)this, nType, nVersion, ser_action); nVersion = this->nVersion; READWRITE(hashBlock); READWRITE(vMerkleBranch); READWRITE(nIndex); ) int SetMerkleBranch(const CBlock* pblock=NULL); int GetDepthInMainChain(CBlockIndex* &pindexRet) const; int GetDepthInMainChain() const { CBlockIndex *pindexRet; return GetDepthInMainChain(pindexRet); } bool IsInMainChain() const { return GetDepthInMainChain() > 0; } int GetBlocksToMaturity() const; bool AcceptToMemoryPool(CTxDB& txdb, bool fCheckInputs=true); bool AcceptToMemoryPool(); }; /** A txdb record that contains the disk location of a transaction and the * locations of transactions that spend its outputs. vSpent is really only * used as a flag, but having the location is very helpful for debugging. */ class CTxIndex { public: CDiskTxPos pos; std::vector vSpent; CTxIndex() { SetNull(); } CTxIndex(const CDiskTxPos& posIn, unsigned int nOutputs) { pos = posIn; vSpent.resize(nOutputs); } IMPLEMENT_SERIALIZE ( if (!(nType & SER_GETHASH)) READWRITE(nVersion); READWRITE(pos); READWRITE(vSpent); ) void SetNull() { pos.SetNull(); vSpent.clear(); } bool IsNull() { return pos.IsNull(); } friend bool operator==(const CTxIndex& a, const CTxIndex& b) { return (a.pos == b.pos && a.vSpent == b.vSpent); } friend bool operator!=(const CTxIndex& a, const CTxIndex& b) { return !(a == b); } int GetDepthInMainChain() const; }; /** Nodes collect new transactions into a block, hash them into a hash tree, * and scan through nonce values to make the block's hash satisfy proof-of-work * requirements. When they solve the proof-of-work, they broadcast the block * to everyone and the block is added to the block chain. The first transaction * in the block is a special one that creates a new coin owned by the creator * of the block. * * Blocks are appended to blk0001.dat files on disk. Their location on disk * is indexed by CBlockIndex objects in memory. */ class CBlock { public: // header static const int CURRENT_VERSION=2; int nVersion; uint256 hashPrevBlock; uint256 hashMerkleRoot; unsigned int nTime; unsigned int nBits; unsigned int nNonce; // network and disk std::vector vtx; // memory only mutable std::vector vMerkleTree; // Denial-of-service detection: mutable int nDoS; bool DoS(int nDoSIn, bool fIn) const { nDoS += nDoSIn; return fIn; } CBlock() { SetNull(); } IMPLEMENT_SERIALIZE ( READWRITE(this->nVersion); nVersion = this->nVersion; READWRITE(hashPrevBlock); READWRITE(hashMerkleRoot); READWRITE(nTime); READWRITE(nBits); READWRITE(nNonce); // ConnectBlock depends on vtx being last so it can calculate offset if (!(nType & (SER_GETHASH|SER_BLOCKHEADERONLY))) READWRITE(vtx); else if (fRead) const_cast(this)->vtx.clear(); ) void SetNull() { nVersion = CBlock::CURRENT_VERSION; hashPrevBlock = 0; hashMerkleRoot = 0; nTime = 0; nBits = 0; nNonce = 0; vtx.clear(); vMerkleTree.clear(); nDoS = 0; } bool IsNull() const { return (nBits == 0); } uint256 GetHash() const { return Hash(BEGIN(nVersion), END(nNonce)); } int64 GetBlockTime() const { return (int64)nTime; } void UpdateTime(const CBlockIndex* pindexPrev); uint256 BuildMerkleTree() const { vMerkleTree.clear(); BOOST_FOREACH(const CTransaction& tx, vtx) vMerkleTree.push_back(tx.GetHash()); int j = 0; for (int nSize = vtx.size(); nSize > 1; nSize = (nSize + 1) / 2) { for (int i = 0; i < nSize; i += 2) { int i2 = std::min(i+1, nSize-1); vMerkleTree.push_back(Hash(BEGIN(vMerkleTree[j+i]), END(vMerkleTree[j+i]), BEGIN(vMerkleTree[j+i2]), END(vMerkleTree[j+i2]))); } j += nSize; } return (vMerkleTree.empty() ? 0 : vMerkleTree.back()); } std::vector GetMerkleBranch(int nIndex) const { if (vMerkleTree.empty()) BuildMerkleTree(); std::vector vMerkleBranch; int j = 0; for (int nSize = vtx.size(); nSize > 1; nSize = (nSize + 1) / 2) { int i = std::min(nIndex^1, nSize-1); vMerkleBranch.push_back(vMerkleTree[j+i]); nIndex >>= 1; j += nSize; } return vMerkleBranch; } static uint256 CheckMerkleBranch(uint256 hash, const std::vector& vMerkleBranch, int nIndex) { if (nIndex == -1) return 0; BOOST_FOREACH(const uint256& otherside, vMerkleBranch) { if (nIndex & 1) hash = Hash(BEGIN(otherside), END(otherside), BEGIN(hash), END(hash)); else hash = Hash(BEGIN(hash), END(hash), BEGIN(otherside), END(otherside)); nIndex >>= 1; } return hash; } bool WriteToDisk(CDiskBlockPos &pos) { // Open history file to append pos.MakeUnique(GetDataDir()); CAutoFile fileout = CAutoFile(OpenBlockFile(pos, "ab"), SER_DISK, CLIENT_VERSION); if (!fileout) return error("CBlock::WriteToDisk() : AppendBlockFile failed"); // Write block fileout << *this; // Flush stdio buffers and commit to disk before returning fflush(fileout); if (!IsInitialBlockDownload() || (nBestHeight+1) % 500 == 0) FileCommit(fileout); return true; } bool ReadFromDisk(const CDiskBlockPos &pos, bool fReadTransactions = true) { SetNull(); // Open history file to read CAutoFile filein = CAutoFile(OpenBlockFile(pos, "rb"), SER_DISK, CLIENT_VERSION); if (!filein) return error("CBlock::ReadFromDisk() : OpenBlockFile failed"); if (!fReadTransactions) filein.nType |= SER_BLOCKHEADERONLY; // Read block try { filein >> *this; } catch (std::exception &e) { return error("%s() : deserialize or I/O error", __PRETTY_FUNCTION__); } // Check the header if (!CheckProofOfWork(GetHash(), nBits)) return error("CBlock::ReadFromDisk() : errors in block header"); return true; } void print() const { printf("CBlock(hash=%s, ver=%d, hashPrevBlock=%s, hashMerkleRoot=%s, nTime=%u, nBits=%08x, nNonce=%u, vtx=%"PRIszu")\n", GetHash().ToString().substr(0,20).c_str(), nVersion, hashPrevBlock.ToString().substr(0,20).c_str(), hashMerkleRoot.ToString().substr(0,10).c_str(), nTime, nBits, nNonce, vtx.size()); for (unsigned int i = 0; i < vtx.size(); i++) { printf(" "); vtx[i].print(); } printf(" vMerkleTree: "); for (unsigned int i = 0; i < vMerkleTree.size(); i++) printf("%s ", vMerkleTree[i].ToString().substr(0,10).c_str()); printf("\n"); } bool DisconnectBlock(CTxDB& txdb, CBlockIndex* pindex); bool ConnectBlock(CTxDB& txdb, CBlockIndex* pindex, bool fJustCheck=false); bool ReadFromDisk(const CBlockIndex* pindex, bool fReadTransactions=true); bool SetBestChain(CTxDB& txdb, CBlockIndex* pindexNew); bool AddToBlockIndex(const CDiskBlockPos &pos); bool CheckBlock(bool fCheckPOW=true, bool fCheckMerkleRoot=true) const; bool AcceptBlock(); private: bool SetBestChainInner(CTxDB& txdb, CBlockIndex *pindexNew); }; /** The block chain is a tree shaped structure starting with the * genesis block at the root, with each block potentially having multiple * candidates to be the next block. pprev and pnext link a path through the * main/longest chain. A blockindex may have multiple pprev pointing back * to it, but pnext will only point forward to the longest branch, or will * be null if the block is not part of the longest chain. */ class CBlockIndex { public: const uint256* phashBlock; CBlockIndex* pprev; CBlockIndex* pnext; int nHeight; unsigned int nAlternative; CBigNum bnChainWork; // block header int nVersion; uint256 hashMerkleRoot; unsigned int nTime; unsigned int nBits; unsigned int nNonce; CBlockIndex() { phashBlock = NULL; pprev = NULL; pnext = NULL; nHeight = 0; bnChainWork = 0; nAlternative = 0; nVersion = 0; hashMerkleRoot = 0; nTime = 0; nBits = 0; nNonce = 0; } CBlockIndex(CBlock& block) { phashBlock = NULL; pprev = NULL; pnext = NULL; nHeight = 0; bnChainWork = 0; nAlternative = 0; nVersion = block.nVersion; hashMerkleRoot = block.hashMerkleRoot; nTime = block.nTime; nBits = block.nBits; nNonce = block.nNonce; } CDiskBlockPos GetBlockPos() const { return CDiskBlockPos(nHeight, nAlternative); } CBlock GetBlockHeader() const { CBlock block; block.nVersion = nVersion; if (pprev) block.hashPrevBlock = pprev->GetBlockHash(); block.hashMerkleRoot = hashMerkleRoot; block.nTime = nTime; block.nBits = nBits; block.nNonce = nNonce; return block; } uint256 GetBlockHash() const { return *phashBlock; } int64 GetBlockTime() const { return (int64)nTime; } CBigNum GetBlockWork() const { CBigNum bnTarget; bnTarget.SetCompact(nBits); if (bnTarget <= 0) return 0; return (CBigNum(1)<<256) / (bnTarget+1); } bool IsInMainChain() const { return (pnext || this == pindexBest); } bool CheckIndex() const { return CheckProofOfWork(GetBlockHash(), nBits); } enum { nMedianTimeSpan=11 }; int64 GetMedianTimePast() const { int64 pmedian[nMedianTimeSpan]; int64* pbegin = &pmedian[nMedianTimeSpan]; int64* pend = &pmedian[nMedianTimeSpan]; const CBlockIndex* pindex = this; for (int i = 0; i < nMedianTimeSpan && pindex; i++, pindex = pindex->pprev) *(--pbegin) = pindex->GetBlockTime(); std::sort(pbegin, pend); return pbegin[(pend - pbegin)/2]; } int64 GetMedianTime() const { const CBlockIndex* pindex = this; for (int i = 0; i < nMedianTimeSpan/2; i++) { if (!pindex->pnext) return GetBlockTime(); pindex = pindex->pnext; } return pindex->GetMedianTimePast(); } /** * Returns true if there are nRequired or more blocks of minVersion or above * in the last nToCheck blocks, starting at pstart and going backwards. */ static bool IsSuperMajority(int minVersion, const CBlockIndex* pstart, unsigned int nRequired, unsigned int nToCheck); std::string ToString() const { return strprintf("CBlockIndex(pprev=%p, pnext=%p, nHeight=%d, merkle=%s, hashBlock=%s)", pprev, pnext, nHeight, hashMerkleRoot.ToString().substr(0,10).c_str(), GetBlockHash().ToString().substr(0,20).c_str()); } void print() const { printf("%s\n", ToString().c_str()); } }; /** Used to marshal pointers into hashes for db storage. */ class CDiskBlockIndex : public CBlockIndex { public: uint256 hashPrev; uint256 hashNext; CDiskBlockIndex() { hashPrev = 0; hashNext = 0; } explicit CDiskBlockIndex(CBlockIndex* pindex) : CBlockIndex(*pindex) { hashPrev = (pprev ? pprev->GetBlockHash() : 0); hashNext = (pnext ? pnext->GetBlockHash() : 0); } IMPLEMENT_SERIALIZE ( if (!(nType & SER_GETHASH)) READWRITE(nVersion); READWRITE(hashNext); READWRITE(nHeight); READWRITE(nAlternative); // block header READWRITE(this->nVersion); READWRITE(hashPrev); READWRITE(hashMerkleRoot); READWRITE(nTime); READWRITE(nBits); READWRITE(nNonce); ) uint256 GetBlockHash() const { CBlock block; block.nVersion = nVersion; block.hashPrevBlock = hashPrev; block.hashMerkleRoot = hashMerkleRoot; block.nTime = nTime; block.nBits = nBits; block.nNonce = nNonce; return block.GetHash(); } std::string ToString() const { std::string str = "CDiskBlockIndex("; str += CBlockIndex::ToString(); str += strprintf("\n hashBlock=%s, hashPrev=%s, hashNext=%s)", GetBlockHash().ToString().c_str(), hashPrev.ToString().substr(0,20).c_str(), hashNext.ToString().substr(0,20).c_str()); return str; } void print() const { printf("%s\n", ToString().c_str()); } }; /** Describes a place in the block chain to another node such that if the * other node doesn't have the same branch, it can find a recent common trunk. * The further back it is, the further before the fork it may be. */ class CBlockLocator { protected: std::vector vHave; public: CBlockLocator() { } explicit CBlockLocator(const CBlockIndex* pindex) { Set(pindex); } explicit CBlockLocator(uint256 hashBlock) { std::map::iterator mi = mapBlockIndex.find(hashBlock); if (mi != mapBlockIndex.end()) Set((*mi).second); } CBlockLocator(const std::vector& vHaveIn) { vHave = vHaveIn; } IMPLEMENT_SERIALIZE ( if (!(nType & SER_GETHASH)) READWRITE(nVersion); READWRITE(vHave); ) void SetNull() { vHave.clear(); } bool IsNull() { return vHave.empty(); } void Set(const CBlockIndex* pindex) { vHave.clear(); int nStep = 1; while (pindex) { vHave.push_back(pindex->GetBlockHash()); // Exponentially larger steps back for (int i = 0; pindex && i < nStep; i++) pindex = pindex->pprev; if (vHave.size() > 10) nStep *= 2; } vHave.push_back(hashGenesisBlock); } int GetDistanceBack() { // Retrace how far back it was in the sender's branch int nDistance = 0; int nStep = 1; BOOST_FOREACH(const uint256& hash, vHave) { std::map::iterator mi = mapBlockIndex.find(hash); if (mi != mapBlockIndex.end()) { CBlockIndex* pindex = (*mi).second; if (pindex->IsInMainChain()) return nDistance; } nDistance += nStep; if (nDistance > 10) nStep *= 2; } return nDistance; } CBlockIndex* GetBlockIndex() { // Find the first block the caller has in the main chain BOOST_FOREACH(const uint256& hash, vHave) { std::map::iterator mi = mapBlockIndex.find(hash); if (mi != mapBlockIndex.end()) { CBlockIndex* pindex = (*mi).second; if (pindex->IsInMainChain()) return pindex; } } return pindexGenesisBlock; } uint256 GetBlockHash() { // Find the first block the caller has in the main chain BOOST_FOREACH(const uint256& hash, vHave) { std::map::iterator mi = mapBlockIndex.find(hash); if (mi != mapBlockIndex.end()) { CBlockIndex* pindex = (*mi).second; if (pindex->IsInMainChain()) return hash; } } return hashGenesisBlock; } int GetHeight() { CBlockIndex* pindex = GetBlockIndex(); if (!pindex) return 0; return pindex->nHeight; } }; class CTxMemPool { public: mutable CCriticalSection cs; std::map mapTx; std::map mapNextTx; bool accept(CTxDB& txdb, CTransaction &tx, bool fCheckInputs, bool* pfMissingInputs); bool addUnchecked(const uint256& hash, CTransaction &tx); bool remove(CTransaction &tx); void clear(); void queryHashes(std::vector& vtxid); unsigned long size() { LOCK(cs); return mapTx.size(); } bool exists(uint256 hash) { return (mapTx.count(hash) != 0); } CTransaction& lookup(uint256 hash) { return mapTx[hash]; } }; extern CTxMemPool mempool; #endif