// Copyright (c) 2009-2010 Satoshi Nakamoto // Copyright (c) 2009-2014 The Bitcoin developers // Copyright (c) 2014-2015 The Darkcoin developers // Distributed under the MIT/X11 software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. #include "script.h" #include "core.h" #include "hash.h" #include "key.h" #include "keystore.h" #include "sync.h" #include "uint256.h" #include "util.h" #include #include #include using namespace std; using namespace boost; typedef vector valtype; static const valtype vchFalse(0); static const valtype vchZero(0); static const valtype vchTrue(1, 1); static const CScriptNum bnZero(0); static const CScriptNum bnOne(1); static const CScriptNum bnFalse(0); static const CScriptNum bnTrue(1); bool CheckSig(vector vchSig, const vector &vchPubKey, const CScript &scriptCode, const CTransaction& txTo, unsigned int nIn, int nHashType, int flags); bool CastToBool(const valtype& vch) { for (unsigned int i = 0; i < vch.size(); i++) { if (vch[i] != 0) { // Can be negative zero if (i == vch.size()-1 && vch[i] == 0x80) return false; return true; } } return false; } // // Script is a stack machine (like Forth) that evaluates a predicate // returning a bool indicating valid or not. There are no loops. // #define stacktop(i) (stack.at(stack.size()+(i))) #define altstacktop(i) (altstack.at(altstack.size()+(i))) static inline void popstack(vector& stack) { if (stack.empty()) throw runtime_error("popstack() : stack empty"); stack.pop_back(); } const char* GetTxnOutputType(txnouttype t) { switch (t) { case TX_NONSTANDARD: return "nonstandard"; case TX_PUBKEY: return "pubkey"; case TX_PUBKEYHASH: return "pubkeyhash"; case TX_SCRIPTHASH: return "scripthash"; case TX_MULTISIG: return "multisig"; case TX_NULL_DATA: return "nulldata"; } return NULL; } const char* GetOpName(opcodetype opcode) { switch (opcode) { // push value case OP_0 : return "0"; case OP_PUSHDATA1 : return "OP_PUSHDATA1"; case OP_PUSHDATA2 : return "OP_PUSHDATA2"; case OP_PUSHDATA4 : return "OP_PUSHDATA4"; case OP_1NEGATE : return "-1"; case OP_RESERVED : return "OP_RESERVED"; case OP_1 : return "1"; case OP_2 : return "2"; case OP_3 : return "3"; case OP_4 : return "4"; case OP_5 : return "5"; case OP_6 : return "6"; case OP_7 : return "7"; case OP_8 : return "8"; case OP_9 : return "9"; case OP_10 : return "10"; case OP_11 : return "11"; case OP_12 : return "12"; case OP_13 : return "13"; case OP_14 : return "14"; case OP_15 : return "15"; case OP_16 : return "16"; // control case OP_NOP : return "OP_NOP"; case OP_VER : return "OP_VER"; case OP_IF : return "OP_IF"; case OP_NOTIF : return "OP_NOTIF"; case OP_VERIF : return "OP_VERIF"; case OP_VERNOTIF : return "OP_VERNOTIF"; case OP_ELSE : return "OP_ELSE"; case OP_ENDIF : return "OP_ENDIF"; case OP_VERIFY : return "OP_VERIFY"; case OP_RETURN : return "OP_RETURN"; // stack ops case OP_TOALTSTACK : return "OP_TOALTSTACK"; case OP_FROMALTSTACK : return "OP_FROMALTSTACK"; case OP_2DROP : return "OP_2DROP"; case OP_2DUP : return "OP_2DUP"; case OP_3DUP : return "OP_3DUP"; case OP_2OVER : return "OP_2OVER"; case OP_2ROT : return "OP_2ROT"; case OP_2SWAP : return "OP_2SWAP"; case OP_IFDUP : return "OP_IFDUP"; case OP_DEPTH : return "OP_DEPTH"; case OP_DROP : return "OP_DROP"; case OP_DUP : return "OP_DUP"; case OP_NIP : return "OP_NIP"; case OP_OVER : return "OP_OVER"; case OP_PICK : return "OP_PICK"; case OP_ROLL : return "OP_ROLL"; case OP_ROT : return "OP_ROT"; case OP_SWAP : return "OP_SWAP"; case OP_TUCK : return "OP_TUCK"; // splice ops case OP_CAT : return "OP_CAT"; case OP_SUBSTR : return "OP_SUBSTR"; case OP_LEFT : return "OP_LEFT"; case OP_RIGHT : return "OP_RIGHT"; case OP_SIZE : return "OP_SIZE"; // bit logic case OP_INVERT : return "OP_INVERT"; case OP_AND : return "OP_AND"; case OP_OR : return "OP_OR"; case OP_XOR : return "OP_XOR"; case OP_EQUAL : return "OP_EQUAL"; case OP_EQUALVERIFY : return "OP_EQUALVERIFY"; case OP_RESERVED1 : return "OP_RESERVED1"; case OP_RESERVED2 : return "OP_RESERVED2"; // numeric case OP_1ADD : return "OP_1ADD"; case OP_1SUB : return "OP_1SUB"; case OP_2MUL : return "OP_2MUL"; case OP_2DIV : return "OP_2DIV"; case OP_NEGATE : return "OP_NEGATE"; case OP_ABS : return "OP_ABS"; case OP_NOT : return "OP_NOT"; case OP_0NOTEQUAL : return "OP_0NOTEQUAL"; case OP_ADD : return "OP_ADD"; case OP_SUB : return "OP_SUB"; case OP_MUL : return "OP_MUL"; case OP_DIV : return "OP_DIV"; case OP_MOD : return "OP_MOD"; case OP_LSHIFT : return "OP_LSHIFT"; case OP_RSHIFT : return "OP_RSHIFT"; case OP_BOOLAND : return "OP_BOOLAND"; case OP_BOOLOR : return "OP_BOOLOR"; case OP_NUMEQUAL : return "OP_NUMEQUAL"; case OP_NUMEQUALVERIFY : return "OP_NUMEQUALVERIFY"; case OP_NUMNOTEQUAL : return "OP_NUMNOTEQUAL"; case OP_LESSTHAN : return "OP_LESSTHAN"; case OP_GREATERTHAN : return "OP_GREATERTHAN"; case OP_LESSTHANOREQUAL : return "OP_LESSTHANOREQUAL"; case OP_GREATERTHANOREQUAL : return "OP_GREATERTHANOREQUAL"; case OP_MIN : return "OP_MIN"; case OP_MAX : return "OP_MAX"; case OP_WITHIN : return "OP_WITHIN"; // crypto case OP_RIPEMD160 : return "OP_RIPEMD160"; case OP_SHA1 : return "OP_SHA1"; case OP_SHA256 : return "OP_SHA256"; case OP_HASH160 : return "OP_HASH160"; case OP_HASH256 : return "OP_HASH256"; case OP_CODESEPARATOR : return "OP_CODESEPARATOR"; case OP_CHECKSIG : return "OP_CHECKSIG"; case OP_CHECKSIGVERIFY : return "OP_CHECKSIGVERIFY"; case OP_CHECKMULTISIG : return "OP_CHECKMULTISIG"; case OP_CHECKMULTISIGVERIFY : return "OP_CHECKMULTISIGVERIFY"; // expanson case OP_NOP1 : return "OP_NOP1"; case OP_NOP2 : return "OP_NOP2"; case OP_NOP3 : return "OP_NOP3"; case OP_NOP4 : return "OP_NOP4"; case OP_NOP5 : return "OP_NOP5"; case OP_NOP6 : return "OP_NOP6"; case OP_NOP7 : return "OP_NOP7"; case OP_NOP8 : return "OP_NOP8"; case OP_NOP9 : return "OP_NOP9"; case OP_NOP10 : return "OP_NOP10"; // template matching params case OP_PUBKEYHASH : return "OP_PUBKEYHASH"; case OP_PUBKEY : return "OP_PUBKEY"; case OP_SMALLDATA : return "OP_SMALLDATA"; case OP_INVALIDOPCODE : return "OP_INVALIDOPCODE"; default: return "OP_UNKNOWN"; } } bool IsCanonicalPubKey(const valtype &vchPubKey, unsigned int flags) { if (!(flags & SCRIPT_VERIFY_STRICTENC)) return true; if (vchPubKey.size() < 33) return error("Non-canonical public key: too short"); if (vchPubKey[0] == 0x04) { if (vchPubKey.size() != 65) return error("Non-canonical public key: invalid length for uncompressed key"); } else if (vchPubKey[0] == 0x02 || vchPubKey[0] == 0x03) { if (vchPubKey.size() != 33) return error("Non-canonical public key: invalid length for compressed key"); } else { return error("Non-canonical public key: compressed nor uncompressed"); } return true; } bool IsCanonicalSignature(const valtype &vchSig, unsigned int flags) { if (!(flags & SCRIPT_VERIFY_STRICTENC)) return true; // See https://bitcointalk.org/index.php?topic=8392.msg127623#msg127623 // A canonical signature exists of: <30> <02> <02> // Where R and S are not negative (their first byte has its highest bit not set), and not // excessively padded (do not start with a 0 byte, unless an otherwise negative number follows, // in which case a single 0 byte is necessary and even required). if (vchSig.size() < 9) return error("Non-canonical signature: too short"); if (vchSig.size() > 73) return error("Non-canonical signature: too long"); unsigned char nHashType = vchSig[vchSig.size() - 1] & (~(SIGHASH_ANYONECANPAY)); if (nHashType < SIGHASH_ALL || nHashType > SIGHASH_SINGLE) return error("Non-canonical signature: unknown hashtype byte"); if (vchSig[0] != 0x30) return error("Non-canonical signature: wrong type"); if (vchSig[1] != vchSig.size()-3) return error("Non-canonical signature: wrong length marker"); unsigned int nLenR = vchSig[3]; if (5 + nLenR >= vchSig.size()) return error("Non-canonical signature: S length misplaced"); unsigned int nLenS = vchSig[5+nLenR]; if ((unsigned long)(nLenR+nLenS+7) != vchSig.size()) return error("Non-canonical signature: R+S length mismatch"); const unsigned char *R = &vchSig[4]; if (R[-2] != 0x02) return error("Non-canonical signature: R value type mismatch"); if (nLenR == 0) return error("Non-canonical signature: R length is zero"); if (R[0] & 0x80) return error("Non-canonical signature: R value negative"); if (nLenR > 1 && (R[0] == 0x00) && !(R[1] & 0x80)) return error("Non-canonical signature: R value excessively padded"); const unsigned char *S = &vchSig[6+nLenR]; if (S[-2] != 0x02) return error("Non-canonical signature: S value type mismatch"); if (nLenS == 0) return error("Non-canonical signature: S length is zero"); if (S[0] & 0x80) return error("Non-canonical signature: S value negative"); if (nLenS > 1 && (S[0] == 0x00) && !(S[1] & 0x80)) return error("Non-canonical signature: S value excessively padded"); if (flags & SCRIPT_VERIFY_EVEN_S) { if (S[nLenS-1] & 1) return error("Non-canonical signature: S value odd"); } return true; } // BIP 66 defined signature encoding check. This largely overlaps with // IsCanonicalSignature above, but lacks hashtype constraints, and uses the // exact implementation code from BIP 66. bool static IsValidSignatureEncoding(const std::vector &sig) { // Format: 0x30 [total-length] 0x02 [R-length] [R] 0x02 [S-length] [S] [sighash] // * total-length: 1-byte length descriptor of everything that follows, // excluding the sighash byte. // * R-length: 1-byte length descriptor of the R value that follows. // * R: arbitrary-length big-endian encoded R value. It must use the shortest // possible encoding for a positive integers (which means no null bytes at // the start, except a single one when the next byte has its highest bit set). // * S-length: 1-byte length descriptor of the S value that follows. // * S: arbitrary-length big-endian encoded S value. The same rules apply. // * sighash: 1-byte value indicating what data is hashed (not part of the DER // signature) // Minimum and maximum size constraints. if (sig.size() < 9) return false; if (sig.size() > 73) return false; // A signature is of type 0x30 (compound). if (sig[0] != 0x30) return false; // Make sure the length covers the entire signature. if (sig[1] != sig.size() - 3) return false; // Extract the length of the R element. unsigned int lenR = sig[3]; // Make sure the length of the S element is still inside the signature. if (5 + lenR >= sig.size()) return false; // Extract the length of the S element. unsigned int lenS = sig[5 + lenR]; // Verify that the length of the signature matches the sum of the length // of the elements. if ((size_t)(lenR + lenS + 7) != sig.size()) return false; // Check whether the R element is an integer. if (sig[2] != 0x02) return false; // Zero-length integers are not allowed for R. if (lenR == 0) return false; // Negative numbers are not allowed for R. if (sig[4] & 0x80) return false; // Null bytes at the start of R are not allowed, unless R would // otherwise be interpreted as a negative number. if (lenR > 1 && (sig[4] == 0x00) && !(sig[5] & 0x80)) return false; // Check whether the S element is an integer. if (sig[lenR + 4] != 0x02) return false; // Zero-length integers are not allowed for S. if (lenS == 0) return false; // Negative numbers are not allowed for S. if (sig[lenR + 6] & 0x80) return false; // Null bytes at the start of S are not allowed, unless S would otherwise be // interpreted as a negative number. if (lenS > 1 && (sig[lenR + 6] == 0x00) && !(sig[lenR + 7] & 0x80)) return false; return true; } bool static CheckSignatureEncoding(const valtype &vchSig, unsigned int flags) { // Empty signature. Not strictly DER encoded, but allowed to provide a // compact way to provide an invalid signature for use with CHECK(MULTI)SIG if (vchSig.size() == 0) { return true; } if ((flags & SCRIPT_VERIFY_DERSIG) != 0 && !IsValidSignatureEncoding(vchSig)) { return false; } return true; } bool EvalScript(vector >& stack, const CScript& script, const CTransaction& txTo, unsigned int nIn, unsigned int flags, int nHashType) { CScript::const_iterator pc = script.begin(); CScript::const_iterator pend = script.end(); CScript::const_iterator pbegincodehash = script.begin(); opcodetype opcode; valtype vchPushValue; vector vfExec; vector altstack; if (script.size() > 10000) return false; int nOpCount = 0; try { while (pc < pend) { bool fExec = !count(vfExec.begin(), vfExec.end(), false); // // Read instruction // if (!script.GetOp(pc, opcode, vchPushValue)) return false; if (vchPushValue.size() > MAX_SCRIPT_ELEMENT_SIZE) return false; // Note how OP_RESERVED does not count towards the opcode limit. if (opcode > OP_16 && ++nOpCount > 201) return false; if (opcode == OP_CAT || opcode == OP_SUBSTR || opcode == OP_LEFT || opcode == OP_RIGHT || opcode == OP_INVERT || opcode == OP_AND || opcode == OP_OR || opcode == OP_XOR || opcode == OP_2MUL || opcode == OP_2DIV || opcode == OP_MUL || opcode == OP_DIV || opcode == OP_MOD || opcode == OP_LSHIFT || opcode == OP_RSHIFT) return false; // Disabled opcodes. if (fExec && 0 <= opcode && opcode <= OP_PUSHDATA4) stack.push_back(vchPushValue); else if (fExec || (OP_IF <= opcode && opcode <= OP_ENDIF)) switch (opcode) { // // Push value // case OP_1NEGATE: case OP_1: case OP_2: case OP_3: case OP_4: case OP_5: case OP_6: case OP_7: case OP_8: case OP_9: case OP_10: case OP_11: case OP_12: case OP_13: case OP_14: case OP_15: case OP_16: { // ( -- value) CScriptNum bn((int)opcode - (int)(OP_1 - 1)); stack.push_back(bn.getvch()); } break; // // Control // case OP_NOP: case OP_NOP1: case OP_NOP2: case OP_NOP3: case OP_NOP4: case OP_NOP5: case OP_NOP6: case OP_NOP7: case OP_NOP8: case OP_NOP9: case OP_NOP10: break; case OP_IF: case OP_NOTIF: { // if [statements] [else [statements]] endif bool fValue = false; if (fExec) { if (stack.size() < 1) return false; valtype& vch = stacktop(-1); fValue = CastToBool(vch); if (opcode == OP_NOTIF) fValue = !fValue; popstack(stack); } vfExec.push_back(fValue); } break; case OP_ELSE: { if (vfExec.empty()) return false; vfExec.back() = !vfExec.back(); } break; case OP_ENDIF: { if (vfExec.empty()) return false; vfExec.pop_back(); } break; case OP_VERIFY: { // (true -- ) or // (false -- false) and return if (stack.size() < 1) return false; bool fValue = CastToBool(stacktop(-1)); if (fValue) popstack(stack); else return false; } break; case OP_RETURN: { return false; } break; // // Stack ops // case OP_TOALTSTACK: { if (stack.size() < 1) return false; altstack.push_back(stacktop(-1)); popstack(stack); } break; case OP_FROMALTSTACK: { if (altstack.size() < 1) return false; stack.push_back(altstacktop(-1)); popstack(altstack); } break; case OP_2DROP: { // (x1 x2 -- ) if (stack.size() < 2) return false; popstack(stack); popstack(stack); } break; case OP_2DUP: { // (x1 x2 -- x1 x2 x1 x2) if (stack.size() < 2) return false; valtype vch1 = stacktop(-2); valtype vch2 = stacktop(-1); stack.push_back(vch1); stack.push_back(vch2); } break; case OP_3DUP: { // (x1 x2 x3 -- x1 x2 x3 x1 x2 x3) if (stack.size() < 3) return false; valtype vch1 = stacktop(-3); valtype vch2 = stacktop(-2); valtype vch3 = stacktop(-1); stack.push_back(vch1); stack.push_back(vch2); stack.push_back(vch3); } break; case OP_2OVER: { // (x1 x2 x3 x4 -- x1 x2 x3 x4 x1 x2) if (stack.size() < 4) return false; valtype vch1 = stacktop(-4); valtype vch2 = stacktop(-3); stack.push_back(vch1); stack.push_back(vch2); } break; case OP_2ROT: { // (x1 x2 x3 x4 x5 x6 -- x3 x4 x5 x6 x1 x2) if (stack.size() < 6) return false; valtype vch1 = stacktop(-6); valtype vch2 = stacktop(-5); stack.erase(stack.end()-6, stack.end()-4); stack.push_back(vch1); stack.push_back(vch2); } break; case OP_2SWAP: { // (x1 x2 x3 x4 -- x3 x4 x1 x2) if (stack.size() < 4) return false; swap(stacktop(-4), stacktop(-2)); swap(stacktop(-3), stacktop(-1)); } break; case OP_IFDUP: { // (x - 0 | x x) if (stack.size() < 1) return false; valtype vch = stacktop(-1); if (CastToBool(vch)) stack.push_back(vch); } break; case OP_DEPTH: { // -- stacksize CScriptNum bn(stack.size()); stack.push_back(bn.getvch()); } break; case OP_DROP: { // (x -- ) if (stack.size() < 1) return false; popstack(stack); } break; case OP_DUP: { // (x -- x x) if (stack.size() < 1) return false; valtype vch = stacktop(-1); stack.push_back(vch); } break; case OP_NIP: { // (x1 x2 -- x2) if (stack.size() < 2) return false; stack.erase(stack.end() - 2); } break; case OP_OVER: { // (x1 x2 -- x1 x2 x1) if (stack.size() < 2) return false; valtype vch = stacktop(-2); stack.push_back(vch); } break; case OP_PICK: case OP_ROLL: { // (xn ... x2 x1 x0 n - xn ... x2 x1 x0 xn) // (xn ... x2 x1 x0 n - ... x2 x1 x0 xn) if (stack.size() < 2) return false; int n = CScriptNum(stacktop(-1)).getint(); popstack(stack); if (n < 0 || n >= (int)stack.size()) return false; valtype vch = stacktop(-n-1); if (opcode == OP_ROLL) stack.erase(stack.end()-n-1); stack.push_back(vch); } break; case OP_ROT: { // (x1 x2 x3 -- x2 x3 x1) // x2 x1 x3 after first swap // x2 x3 x1 after second swap if (stack.size() < 3) return false; swap(stacktop(-3), stacktop(-2)); swap(stacktop(-2), stacktop(-1)); } break; case OP_SWAP: { // (x1 x2 -- x2 x1) if (stack.size() < 2) return false; swap(stacktop(-2), stacktop(-1)); } break; case OP_TUCK: { // (x1 x2 -- x2 x1 x2) if (stack.size() < 2) return false; valtype vch = stacktop(-1); stack.insert(stack.end()-2, vch); } break; case OP_SIZE: { // (in -- in size) if (stack.size() < 1) return false; CScriptNum bn(stacktop(-1).size()); stack.push_back(bn.getvch()); } break; // // Bitwise logic // case OP_EQUAL: case OP_EQUALVERIFY: //case OP_NOTEQUAL: // use OP_NUMNOTEQUAL { // (x1 x2 - bool) if (stack.size() < 2) return false; valtype& vch1 = stacktop(-2); valtype& vch2 = stacktop(-1); bool fEqual = (vch1 == vch2); // OP_NOTEQUAL is disabled because it would be too easy to say // something like n != 1 and have some wiseguy pass in 1 with extra // zero bytes after it (numerically, 0x01 == 0x0001 == 0x000001) //if (opcode == OP_NOTEQUAL) // fEqual = !fEqual; popstack(stack); popstack(stack); stack.push_back(fEqual ? vchTrue : vchFalse); if (opcode == OP_EQUALVERIFY) { if (fEqual) popstack(stack); else return false; } } break; // // Numeric // case OP_1ADD: case OP_1SUB: case OP_NEGATE: case OP_ABS: case OP_NOT: case OP_0NOTEQUAL: { // (in -- out) if (stack.size() < 1) return false; CScriptNum bn(stacktop(-1)); switch (opcode) { case OP_1ADD: bn += bnOne; break; case OP_1SUB: bn -= bnOne; break; case OP_NEGATE: bn = -bn; break; case OP_ABS: if (bn < bnZero) bn = -bn; break; case OP_NOT: bn = (bn == bnZero); break; case OP_0NOTEQUAL: bn = (bn != bnZero); break; default: assert(!"invalid opcode"); break; } popstack(stack); stack.push_back(bn.getvch()); } break; case OP_ADD: case OP_SUB: case OP_BOOLAND: case OP_BOOLOR: case OP_NUMEQUAL: case OP_NUMEQUALVERIFY: case OP_NUMNOTEQUAL: case OP_LESSTHAN: case OP_GREATERTHAN: case OP_LESSTHANOREQUAL: case OP_GREATERTHANOREQUAL: case OP_MIN: case OP_MAX: { // (x1 x2 -- out) if (stack.size() < 2) return false; CScriptNum bn1(stacktop(-2)); CScriptNum bn2(stacktop(-1)); CScriptNum bn(0); switch (opcode) { case OP_ADD: bn = bn1 + bn2; break; case OP_SUB: bn = bn1 - bn2; break; case OP_BOOLAND: bn = (bn1 != bnZero && bn2 != bnZero); break; case OP_BOOLOR: bn = (bn1 != bnZero || bn2 != bnZero); break; case OP_NUMEQUAL: bn = (bn1 == bn2); break; case OP_NUMEQUALVERIFY: bn = (bn1 == bn2); break; case OP_NUMNOTEQUAL: bn = (bn1 != bn2); break; case OP_LESSTHAN: bn = (bn1 < bn2); break; case OP_GREATERTHAN: bn = (bn1 > bn2); break; case OP_LESSTHANOREQUAL: bn = (bn1 <= bn2); break; case OP_GREATERTHANOREQUAL: bn = (bn1 >= bn2); break; case OP_MIN: bn = (bn1 < bn2 ? bn1 : bn2); break; case OP_MAX: bn = (bn1 > bn2 ? bn1 : bn2); break; default: assert(!"invalid opcode"); break; } popstack(stack); popstack(stack); stack.push_back(bn.getvch()); if (opcode == OP_NUMEQUALVERIFY) { if (CastToBool(stacktop(-1))) popstack(stack); else return false; } } break; case OP_WITHIN: { // (x min max -- out) if (stack.size() < 3) return false; CScriptNum bn1(stacktop(-3)); CScriptNum bn2(stacktop(-2)); CScriptNum bn3(stacktop(-1)); bool fValue = (bn2 <= bn1 && bn1 < bn3); popstack(stack); popstack(stack); popstack(stack); stack.push_back(fValue ? vchTrue : vchFalse); } break; // // Crypto // case OP_RIPEMD160: case OP_SHA1: case OP_SHA256: case OP_HASH160: case OP_HASH256: { // (in -- hash) if (stack.size() < 1) return false; valtype& vch = stacktop(-1); valtype vchHash((opcode == OP_RIPEMD160 || opcode == OP_SHA1 || opcode == OP_HASH160) ? 20 : 32); if (opcode == OP_RIPEMD160) RIPEMD160(&vch[0], vch.size(), &vchHash[0]); else if (opcode == OP_SHA1) SHA1(&vch[0], vch.size(), &vchHash[0]); else if (opcode == OP_SHA256) SHA256(&vch[0], vch.size(), &vchHash[0]); else if (opcode == OP_HASH160) { uint160 hash160 = Hash160(vch); memcpy(&vchHash[0], &hash160, sizeof(hash160)); } else if (opcode == OP_HASH256) { uint256 hash = Hash(vch.begin(), vch.end()); memcpy(&vchHash[0], &hash, sizeof(hash)); } popstack(stack); stack.push_back(vchHash); } break; case OP_CODESEPARATOR: { // Hash starts after the code separator pbegincodehash = pc; } break; case OP_CHECKSIG: case OP_CHECKSIGVERIFY: { // (sig pubkey -- bool) if (stack.size() < 2) return false; valtype& vchSig = stacktop(-2); valtype& vchPubKey = stacktop(-1); ////// debug print //PrintHex(vchSig.begin(), vchSig.end(), "sig: %s\n"); //PrintHex(vchPubKey.begin(), vchPubKey.end(), "pubkey: %s\n"); // Subset of script starting at the most recent codeseparator CScript scriptCode(pbegincodehash, pend); // Drop the signature, since there's no way for a signature to sign itself scriptCode.FindAndDelete(CScript(vchSig)); if (!CheckSignatureEncoding(vchSig, flags)) { return false; } bool fSuccess = IsCanonicalSignature(vchSig, flags) && IsCanonicalPubKey(vchPubKey, flags) && CheckSig(vchSig, vchPubKey, scriptCode, txTo, nIn, nHashType, flags); popstack(stack); popstack(stack); stack.push_back(fSuccess ? vchTrue : vchFalse); if (opcode == OP_CHECKSIGVERIFY) { if (fSuccess) popstack(stack); else return false; } } break; case OP_CHECKMULTISIG: case OP_CHECKMULTISIGVERIFY: { // ([sig ...] num_of_signatures [pubkey ...] num_of_pubkeys -- bool) int i = 1; if ((int)stack.size() < i) return false; int nKeysCount = CScriptNum(stacktop(-i)).getint(); if (nKeysCount < 0 || nKeysCount > 20) return false; nOpCount += nKeysCount; if (nOpCount > 201) return false; int ikey = ++i; i += nKeysCount; if ((int)stack.size() < i) return false; int nSigsCount = CScriptNum(stacktop(-i)).getint(); if (nSigsCount < 0 || nSigsCount > nKeysCount) return false; int isig = ++i; i += nSigsCount; if ((int)stack.size() < i) return false; // Subset of script starting at the most recent codeseparator CScript scriptCode(pbegincodehash, pend); // Drop the signatures, since there's no way for a signature to sign itself for (int k = 0; k < nSigsCount; k++) { valtype& vchSig = stacktop(-isig-k); scriptCode.FindAndDelete(CScript(vchSig)); } bool fSuccess = true; while (fSuccess && nSigsCount > 0) { valtype& vchSig = stacktop(-isig); valtype& vchPubKey = stacktop(-ikey); if (!CheckSignatureEncoding(vchSig, flags)) { return false; } // Check signature bool fOk = IsCanonicalSignature(vchSig, flags) && IsCanonicalPubKey(vchPubKey, flags) && CheckSig(vchSig, vchPubKey, scriptCode, txTo, nIn, nHashType, flags); if (fOk) { isig++; nSigsCount--; } ikey++; nKeysCount--; // If there are more signatures left than keys left, // then too many signatures have failed if (nSigsCount > nKeysCount) fSuccess = false; } while (i-- > 0) popstack(stack); stack.push_back(fSuccess ? vchTrue : vchFalse); if (opcode == OP_CHECKMULTISIGVERIFY) { if (fSuccess) popstack(stack); else return false; } } break; default: return false; } // Size limits if (stack.size() + altstack.size() > 1000) return false; } } catch (...) { return false; } if (!vfExec.empty()) return false; return true; } namespace { /** Wrapper that serializes like CTransaction, but with the modifications * required for the signature hash done in-place */ class CTransactionSignatureSerializer { private: const CTransaction &txTo; // reference to the spending transaction (the one being serialized) const CScript &scriptCode; // output script being consumed const unsigned int nIn; // input index of txTo being signed const bool fAnyoneCanPay; // whether the hashtype has the SIGHASH_ANYONECANPAY flag set const bool fHashSingle; // whether the hashtype is SIGHASH_SINGLE const bool fHashNone; // whether the hashtype is SIGHASH_NONE public: CTransactionSignatureSerializer(const CTransaction &txToIn, const CScript &scriptCodeIn, unsigned int nInIn, int nHashTypeIn) : txTo(txToIn), scriptCode(scriptCodeIn), nIn(nInIn), fAnyoneCanPay(!!(nHashTypeIn & SIGHASH_ANYONECANPAY)), fHashSingle((nHashTypeIn & 0x1f) == SIGHASH_SINGLE), fHashNone((nHashTypeIn & 0x1f) == SIGHASH_NONE) {} /** Serialize the passed scriptCode, skipping OP_CODESEPARATORs */ template void SerializeScriptCode(S &s, int nType, int nVersion) const { CScript::const_iterator it = scriptCode.begin(); CScript::const_iterator itBegin = it; opcodetype opcode; unsigned int nCodeSeparators = 0; while (scriptCode.GetOp(it, opcode)) { if (opcode == OP_CODESEPARATOR) nCodeSeparators++; } ::WriteCompactSize(s, scriptCode.size() - nCodeSeparators); it = itBegin; while (scriptCode.GetOp(it, opcode)) { if (opcode == OP_CODESEPARATOR) { s.write((char*)&itBegin[0], it-itBegin-1); itBegin = it; } } s.write((char*)&itBegin[0], it-itBegin); } /** Serialize an input of txTo */ template void SerializeInput(S &s, unsigned int nInput, int nType, int nVersion) const { // In case of SIGHASH_ANYONECANPAY, only the input being signed is serialized if (fAnyoneCanPay) nInput = nIn; // Serialize the prevout ::Serialize(s, txTo.vin[nInput].prevout, nType, nVersion); // Serialize the script if (nInput != nIn) // Blank out other inputs' signatures ::Serialize(s, CScript(), nType, nVersion); else SerializeScriptCode(s, nType, nVersion); // Serialize the nSequence if (nInput != nIn && (fHashSingle || fHashNone)) // let the others update at will ::Serialize(s, (int)0, nType, nVersion); else ::Serialize(s, txTo.vin[nInput].nSequence, nType, nVersion); } /** Serialize an output of txTo */ template void SerializeOutput(S &s, unsigned int nOutput, int nType, int nVersion) const { if (fHashSingle && nOutput != nIn) // Do not lock-in the txout payee at other indices as txin ::Serialize(s, CTxOut(), nType, nVersion); else ::Serialize(s, txTo.vout[nOutput], nType, nVersion); } /** Serialize txTo */ template void Serialize(S &s, int nType, int nVersion) const { // Serialize nVersion ::Serialize(s, txTo.nVersion, nType, nVersion); // Serialize vin unsigned int nInputs = fAnyoneCanPay ? 1 : txTo.vin.size(); ::WriteCompactSize(s, nInputs); for (unsigned int nInput = 0; nInput < nInputs; nInput++) SerializeInput(s, nInput, nType, nVersion); // Serialize vout unsigned int nOutputs = fHashNone ? 0 : (fHashSingle ? nIn+1 : txTo.vout.size()); ::WriteCompactSize(s, nOutputs); for (unsigned int nOutput = 0; nOutput < nOutputs; nOutput++) SerializeOutput(s, nOutput, nType, nVersion); // Serialie nLockTime ::Serialize(s, txTo.nLockTime, nType, nVersion); } }; } uint256 SignatureHash(const CScript &scriptCode, const CTransaction& txTo, unsigned int nIn, int nHashType) { if (nIn >= txTo.vin.size()) { LogPrintf("ERROR: SignatureHash() : nIn=%d out of range\n", nIn); return 1; } // Check for invalid use of SIGHASH_SINGLE if ((nHashType & 0x1f) == SIGHASH_SINGLE) { if (nIn >= txTo.vout.size()) { LogPrintf("ERROR: SignatureHash() : nOut=%d out of range\n", nIn); return 1; } } // Wrapper to serialize only the necessary parts of the transaction being signed CTransactionSignatureSerializer txTmp(txTo, scriptCode, nIn, nHashType); // Serialize and hash CHashWriter ss(SER_GETHASH, 0); ss << txTmp << nHashType; return ss.GetHash(); } // Valid signature cache, to avoid doing expensive ECDSA signature checking // twice for every transaction (once when accepted into memory pool, and // again when accepted into the block chain) class CSignatureCache { private: // sigdata_type is (signature hash, signature, public key): typedef boost::tuple, CPubKey> sigdata_type; std::set< sigdata_type> setValid; boost::shared_mutex cs_sigcache; public: bool Get(const uint256 &hash, const std::vector& vchSig, const CPubKey& pubKey) { boost::shared_lock lock(cs_sigcache); sigdata_type k(hash, vchSig, pubKey); std::set::iterator mi = setValid.find(k); if (mi != setValid.end()) return true; return false; } void Set(const uint256 &hash, const std::vector& vchSig, const CPubKey& pubKey) { // DoS prevention: limit cache size to less than 10MB // (~200 bytes per cache entry times 50,000 entries) // Since there are a maximum of 20,000 signature operations per block // 50,000 is a reasonable default. int64_t nMaxCacheSize = GetArg("-maxsigcachesize", 50000); if (nMaxCacheSize <= 0) return; boost::unique_lock lock(cs_sigcache); while (static_cast(setValid.size()) > nMaxCacheSize) { // Evict a random entry. Random because that helps // foil would-be DoS attackers who might try to pre-generate // and re-use a set of valid signatures just-slightly-greater // than our cache size. uint256 randomHash = GetRandHash(); std::vector unused; std::set::iterator it = setValid.lower_bound(sigdata_type(randomHash, unused, unused)); if (it == setValid.end()) it = setValid.begin(); setValid.erase(*it); } sigdata_type k(hash, vchSig, pubKey); setValid.insert(k); } }; bool CheckSig(vector vchSig, const vector &vchPubKey, const CScript &scriptCode, const CTransaction& txTo, unsigned int nIn, int nHashType, int flags) { static CSignatureCache signatureCache; CPubKey pubkey(vchPubKey); if (!pubkey.IsValid()) return false; // Hash type is one byte tacked on to the end of the signature if (vchSig.empty()) return false; if (nHashType == 0) nHashType = vchSig.back(); else if (nHashType != vchSig.back()) return false; vchSig.pop_back(); uint256 sighash = SignatureHash(scriptCode, txTo, nIn, nHashType); if (signatureCache.Get(sighash, vchSig, pubkey)) return true; if (!pubkey.Verify(sighash, vchSig)) return false; if (!(flags & SCRIPT_VERIFY_NOCACHE)) signatureCache.Set(sighash, vchSig, pubkey); return true; } // // Return public keys or hashes from scriptPubKey, for 'standard' transaction types. // bool Solver(const CScript& scriptPubKey, txnouttype& typeRet, vector >& vSolutionsRet) { // Templates static multimap mTemplates; if (mTemplates.empty()) { // Standard tx, sender provides pubkey, receiver adds signature mTemplates.insert(make_pair(TX_PUBKEY, CScript() << OP_PUBKEY << OP_CHECKSIG)); // Darkcoin address tx, sender provides hash of pubkey, receiver provides signature and pubkey mTemplates.insert(make_pair(TX_PUBKEYHASH, CScript() << OP_DUP << OP_HASH160 << OP_PUBKEYHASH << OP_EQUALVERIFY << OP_CHECKSIG)); // Sender provides N pubkeys, receivers provides M signatures mTemplates.insert(make_pair(TX_MULTISIG, CScript() << OP_SMALLINTEGER << OP_PUBKEYS << OP_SMALLINTEGER << OP_CHECKMULTISIG)); // Empty, provably prunable, data-carrying output mTemplates.insert(make_pair(TX_NULL_DATA, CScript() << OP_RETURN << OP_SMALLDATA)); mTemplates.insert(make_pair(TX_NULL_DATA, CScript() << OP_RETURN)); } // Shortcut for pay-to-script-hash, which are more constrained than the other types: // it is always OP_HASH160 20 [20 byte hash] OP_EQUAL if (scriptPubKey.IsPayToScriptHash()) { typeRet = TX_SCRIPTHASH; vector hashBytes(scriptPubKey.begin()+2, scriptPubKey.begin()+22); vSolutionsRet.push_back(hashBytes); return true; } // Scan templates const CScript& script1 = scriptPubKey; BOOST_FOREACH(const PAIRTYPE(txnouttype, CScript)& tplate, mTemplates) { const CScript& script2 = tplate.second; vSolutionsRet.clear(); opcodetype opcode1, opcode2; vector vch1, vch2; // Compare CScript::const_iterator pc1 = script1.begin(); CScript::const_iterator pc2 = script2.begin(); while (true) { if (pc1 == script1.end() && pc2 == script2.end()) { // Found a match typeRet = tplate.first; if (typeRet == TX_MULTISIG) { // Additional checks for TX_MULTISIG: unsigned char m = vSolutionsRet.front()[0]; unsigned char n = vSolutionsRet.back()[0]; if (m < 1 || n < 1 || m > n || vSolutionsRet.size()-2 != n) return false; } return true; } if (!script1.GetOp(pc1, opcode1, vch1)) break; if (!script2.GetOp(pc2, opcode2, vch2)) break; // Template matching opcodes: if (opcode2 == OP_PUBKEYS) { while (vch1.size() >= 33 && vch1.size() <= 65) { vSolutionsRet.push_back(vch1); if (!script1.GetOp(pc1, opcode1, vch1)) break; } if (!script2.GetOp(pc2, opcode2, vch2)) break; // Normal situation is to fall through // to other if/else statements } if (opcode2 == OP_PUBKEY) { if (vch1.size() < 33 || vch1.size() > 65) break; vSolutionsRet.push_back(vch1); } else if (opcode2 == OP_PUBKEYHASH) { if (vch1.size() != sizeof(uint160)) break; vSolutionsRet.push_back(vch1); } else if (opcode2 == OP_SMALLINTEGER) { // Single-byte small integer pushed onto vSolutions if (opcode1 == OP_0 || (opcode1 >= OP_1 && opcode1 <= OP_16)) { char n = (char)CScript::DecodeOP_N(opcode1); vSolutionsRet.push_back(valtype(1, n)); } else break; } else if (opcode2 == OP_SMALLDATA) { // small pushdata, <= MAX_OP_RETURN_RELAY bytes if (vch1.size() > MAX_OP_RETURN_RELAY) break; } else if (opcode1 != opcode2 || vch1 != vch2) { // Others must match exactly break; } } } vSolutionsRet.clear(); typeRet = TX_NONSTANDARD; return false; } bool Sign1(const CKeyID& address, const CKeyStore& keystore, uint256 hash, int nHashType, CScript& scriptSigRet) { CKey key; if (!keystore.GetKey(address, key)) return false; vector vchSig; if (!key.Sign(hash, vchSig)) return false; vchSig.push_back((unsigned char)nHashType); scriptSigRet << vchSig; return true; } bool SignN(const vector& multisigdata, const CKeyStore& keystore, uint256 hash, int nHashType, CScript& scriptSigRet) { int nSigned = 0; int nRequired = multisigdata.front()[0]; for (unsigned int i = 1; i < multisigdata.size()-1 && nSigned < nRequired; i++) { const valtype& pubkey = multisigdata[i]; CKeyID keyID = CPubKey(pubkey).GetID(); if (Sign1(keyID, keystore, hash, nHashType, scriptSigRet)) ++nSigned; } return nSigned==nRequired; } // // Sign scriptPubKey with private keys stored in keystore, given transaction hash and hash type. // Signatures are returned in scriptSigRet (or returns false if scriptPubKey can't be signed), // unless whichTypeRet is TX_SCRIPTHASH, in which case scriptSigRet is the redemption script. // Returns false if scriptPubKey could not be completely satisfied. // bool Solver(const CKeyStore& keystore, const CScript& scriptPubKey, uint256 hash, int nHashType, CScript& scriptSigRet, txnouttype& whichTypeRet) { scriptSigRet.clear(); vector vSolutions; if (!Solver(scriptPubKey, whichTypeRet, vSolutions)) return false; CKeyID keyID; switch (whichTypeRet) { case TX_NONSTANDARD: case TX_NULL_DATA: return false; case TX_PUBKEY: keyID = CPubKey(vSolutions[0]).GetID(); return Sign1(keyID, keystore, hash, nHashType, scriptSigRet); case TX_PUBKEYHASH: keyID = CKeyID(uint160(vSolutions[0])); if (!Sign1(keyID, keystore, hash, nHashType, scriptSigRet)) return false; else { CPubKey vch; keystore.GetPubKey(keyID, vch); scriptSigRet << vch; } return true; case TX_SCRIPTHASH: return keystore.GetCScript(uint160(vSolutions[0]), scriptSigRet); case TX_MULTISIG: scriptSigRet << OP_0; // workaround CHECKMULTISIG bug return (SignN(vSolutions, keystore, hash, nHashType, scriptSigRet)); } return false; } int ScriptSigArgsExpected(txnouttype t, const std::vector >& vSolutions) { switch (t) { case TX_NONSTANDARD: case TX_NULL_DATA: return -1; case TX_PUBKEY: return 1; case TX_PUBKEYHASH: return 2; case TX_MULTISIG: if (vSolutions.size() < 1 || vSolutions[0].size() < 1) return -1; return vSolutions[0][0] + 1; case TX_SCRIPTHASH: return 1; // doesn't include args needed by the script } return -1; } bool IsStandard(const CScript& scriptPubKey, txnouttype& whichType) { vector vSolutions; if (!Solver(scriptPubKey, whichType, vSolutions)) return false; if (whichType == TX_MULTISIG) { unsigned char m = vSolutions.front()[0]; unsigned char n = vSolutions.back()[0]; // Support up to x-of-3 multisig txns as standard if (n < 1 || n > 3) return false; if (m < 1 || m > n) return false; } return whichType != TX_NONSTANDARD; } unsigned int HaveKeys(const vector& pubkeys, const CKeyStore& keystore) { unsigned int nResult = 0; BOOST_FOREACH(const valtype& pubkey, pubkeys) { CKeyID keyID = CPubKey(pubkey).GetID(); if (keystore.HaveKey(keyID)) ++nResult; } return nResult; } class CKeyStoreIsMineVisitor : public boost::static_visitor { private: const CKeyStore *keystore; public: CKeyStoreIsMineVisitor(const CKeyStore *keystoreIn) : keystore(keystoreIn) { } bool operator()(const CNoDestination &dest) const { return false; } bool operator()(const CKeyID &keyID) const { return keystore->HaveKey(keyID); } bool operator()(const CScriptID &scriptID) const { return keystore->HaveCScript(scriptID); } }; bool IsMine(const CKeyStore &keystore, const CTxDestination &dest) { return boost::apply_visitor(CKeyStoreIsMineVisitor(&keystore), dest); } bool IsMine(const CKeyStore &keystore, const CScript& scriptPubKey) { vector vSolutions; txnouttype whichType; if (!Solver(scriptPubKey, whichType, vSolutions)) return false; CKeyID keyID; switch (whichType) { case TX_NONSTANDARD: case TX_NULL_DATA: return false; case TX_PUBKEY: keyID = CPubKey(vSolutions[0]).GetID(); return keystore.HaveKey(keyID); case TX_PUBKEYHASH: keyID = CKeyID(uint160(vSolutions[0])); return keystore.HaveKey(keyID); case TX_SCRIPTHASH: { CScript subscript; if (!keystore.GetCScript(CScriptID(uint160(vSolutions[0])), subscript)) return false; return IsMine(keystore, subscript); } case TX_MULTISIG: { // Only consider transactions "mine" if we own ALL the // keys involved. multi-signature transactions that are // partially owned (somebody else has a key that can spend // them) enable spend-out-from-under-you attacks, especially // in shared-wallet situations. vector keys(vSolutions.begin()+1, vSolutions.begin()+vSolutions.size()-1); return HaveKeys(keys, keystore) == keys.size(); } } return false; } bool ExtractDestination(const CScript& scriptPubKey, CTxDestination& addressRet) { vector vSolutions; txnouttype whichType; if (!Solver(scriptPubKey, whichType, vSolutions)) return false; if (whichType == TX_PUBKEY) { addressRet = CPubKey(vSolutions[0]).GetID(); return true; } else if (whichType == TX_PUBKEYHASH) { addressRet = CKeyID(uint160(vSolutions[0])); return true; } else if (whichType == TX_SCRIPTHASH) { addressRet = CScriptID(uint160(vSolutions[0])); return true; } // Multisig txns have more than one address... return false; } bool ExtractDestinations(const CScript& scriptPubKey, txnouttype& typeRet, vector& addressRet, int& nRequiredRet) { addressRet.clear(); typeRet = TX_NONSTANDARD; vector vSolutions; if (!Solver(scriptPubKey, typeRet, vSolutions)) return false; if (typeRet == TX_NULL_DATA){ // This is data, not addresses return false; } if (typeRet == TX_MULTISIG) { nRequiredRet = vSolutions.front()[0]; for (unsigned int i = 1; i < vSolutions.size()-1; i++) { CTxDestination address = CPubKey(vSolutions[i]).GetID(); addressRet.push_back(address); } } else { nRequiredRet = 1; CTxDestination address; if (!ExtractDestination(scriptPubKey, address)) return false; addressRet.push_back(address); } return true; } class CAffectedKeysVisitor : public boost::static_visitor { private: const CKeyStore &keystore; std::vector &vKeys; public: CAffectedKeysVisitor(const CKeyStore &keystoreIn, std::vector &vKeysIn) : keystore(keystoreIn), vKeys(vKeysIn) {} void Process(const CScript &script) { txnouttype type; std::vector vDest; int nRequired; if (ExtractDestinations(script, type, vDest, nRequired)) { BOOST_FOREACH(const CTxDestination &dest, vDest) boost::apply_visitor(*this, dest); } } void operator()(const CKeyID &keyId) { if (keystore.HaveKey(keyId)) vKeys.push_back(keyId); } void operator()(const CScriptID &scriptId) { CScript script; if (keystore.GetCScript(scriptId, script)) Process(script); } void operator()(const CNoDestination &none) {} }; void ExtractAffectedKeys(const CKeyStore &keystore, const CScript& scriptPubKey, std::vector &vKeys) { CAffectedKeysVisitor(keystore, vKeys).Process(scriptPubKey); } bool VerifyScript(const CScript& scriptSig, const CScript& scriptPubKey, const CTransaction& txTo, unsigned int nIn, unsigned int flags, int nHashType) { vector > stack, stackCopy; if (!EvalScript(stack, scriptSig, txTo, nIn, flags, nHashType)) return false; if (flags & SCRIPT_VERIFY_P2SH) stackCopy = stack; if (!EvalScript(stack, scriptPubKey, txTo, nIn, flags, nHashType)) return false; if (stack.empty()) return false; if (CastToBool(stack.back()) == false) return false; // Additional validation for spend-to-script-hash transactions: if ((flags & SCRIPT_VERIFY_P2SH) && scriptPubKey.IsPayToScriptHash()) { if (!scriptSig.IsPushOnly()) // scriptSig must be literals-only return false; // or validation fails // stackCopy cannot be empty here, because if it was the // P2SH HASH <> EQUAL scriptPubKey would be evaluated with // an empty stack and the EvalScript above would return false. assert(!stackCopy.empty()); const valtype& pubKeySerialized = stackCopy.back(); CScript pubKey2(pubKeySerialized.begin(), pubKeySerialized.end()); popstack(stackCopy); if (!EvalScript(stackCopy, pubKey2, txTo, nIn, flags, nHashType)) return false; if (stackCopy.empty()) return false; return CastToBool(stackCopy.back()); } return true; } bool SignSignature(const CKeyStore &keystore, const CScript& fromPubKey, CTransaction& txTo, unsigned int nIn, int nHashType) { assert(nIn < txTo.vin.size()); CTxIn& txin = txTo.vin[nIn]; // Leave out the signature from the hash, since a signature can't sign itself. // The checksig op will also drop the signatures from its hash. uint256 hash = SignatureHash(fromPubKey, txTo, nIn, nHashType); txnouttype whichType; if (!Solver(keystore, fromPubKey, hash, nHashType, txin.scriptSig, whichType)) return false; if (whichType == TX_SCRIPTHASH) { // Solver returns the subscript that need to be evaluated; // the final scriptSig is the signatures from that // and then the serialized subscript: CScript subscript = txin.scriptSig; // Recompute txn hash using subscript in place of scriptPubKey: uint256 hash2 = SignatureHash(subscript, txTo, nIn, nHashType); txnouttype subType; bool fSolved = Solver(keystore, subscript, hash2, nHashType, txin.scriptSig, subType) && subType != TX_SCRIPTHASH; // Append serialized subscript whether or not it is completely signed: txin.scriptSig << static_cast(subscript); if (!fSolved) return false; } // Test solution return VerifyScript(txin.scriptSig, fromPubKey, txTo, nIn, SCRIPT_VERIFY_P2SH | SCRIPT_VERIFY_STRICTENC, 0); } bool SignSignature(const CKeyStore &keystore, const CTransaction& txFrom, CTransaction& txTo, unsigned int nIn, int nHashType) { assert(nIn < txTo.vin.size()); CTxIn& txin = txTo.vin[nIn]; assert(txin.prevout.n < txFrom.vout.size()); const CTxOut& txout = txFrom.vout[txin.prevout.n]; return SignSignature(keystore, txout.scriptPubKey, txTo, nIn, nHashType); } static CScript PushAll(const vector& values) { CScript result; BOOST_FOREACH(const valtype& v, values) result << v; return result; } static CScript CombineMultisig(CScript scriptPubKey, const CTransaction& txTo, unsigned int nIn, const vector& vSolutions, vector& sigs1, vector& sigs2) { // Combine all the signatures we've got: set allsigs; BOOST_FOREACH(const valtype& v, sigs1) { if (!v.empty()) allsigs.insert(v); } BOOST_FOREACH(const valtype& v, sigs2) { if (!v.empty()) allsigs.insert(v); } // Build a map of pubkey -> signature by matching sigs to pubkeys: assert(vSolutions.size() > 1); unsigned int nSigsRequired = vSolutions.front()[0]; unsigned int nPubKeys = vSolutions.size()-2; map sigs; BOOST_FOREACH(const valtype& sig, allsigs) { for (unsigned int i = 0; i < nPubKeys; i++) { const valtype& pubkey = vSolutions[i+1]; if (sigs.count(pubkey)) continue; // Already got a sig for this pubkey if (CheckSig(sig, pubkey, scriptPubKey, txTo, nIn, 0, 0)) { sigs[pubkey] = sig; break; } } } // Now build a merged CScript: unsigned int nSigsHave = 0; CScript result; result << OP_0; // pop-one-too-many workaround for (unsigned int i = 0; i < nPubKeys && nSigsHave < nSigsRequired; i++) { if (sigs.count(vSolutions[i+1])) { result << sigs[vSolutions[i+1]]; ++nSigsHave; } } // Fill any missing with OP_0: for (unsigned int i = nSigsHave; i < nSigsRequired; i++) result << OP_0; return result; } static CScript CombineSignatures(CScript scriptPubKey, const CTransaction& txTo, unsigned int nIn, const txnouttype txType, const vector& vSolutions, vector& sigs1, vector& sigs2) { switch (txType) { case TX_NONSTANDARD: case TX_NULL_DATA: // Don't know anything about this, assume bigger one is correct: if (sigs1.size() >= sigs2.size()) return PushAll(sigs1); return PushAll(sigs2); case TX_PUBKEY: case TX_PUBKEYHASH: // Signatures are bigger than placeholders or empty scripts: if (sigs1.empty() || sigs1[0].empty()) return PushAll(sigs2); return PushAll(sigs1); case TX_SCRIPTHASH: if (sigs1.empty() || sigs1.back().empty()) return PushAll(sigs2); else if (sigs2.empty() || sigs2.back().empty()) return PushAll(sigs1); else { // Recur to combine: valtype spk = sigs1.back(); CScript pubKey2(spk.begin(), spk.end()); txnouttype txType2; vector > vSolutions2; Solver(pubKey2, txType2, vSolutions2); sigs1.pop_back(); sigs2.pop_back(); CScript result = CombineSignatures(pubKey2, txTo, nIn, txType2, vSolutions2, sigs1, sigs2); result << spk; return result; } case TX_MULTISIG: return CombineMultisig(scriptPubKey, txTo, nIn, vSolutions, sigs1, sigs2); } return CScript(); } CScript CombineSignatures(CScript scriptPubKey, const CTransaction& txTo, unsigned int nIn, const CScript& scriptSig1, const CScript& scriptSig2) { txnouttype txType; vector > vSolutions; Solver(scriptPubKey, txType, vSolutions); vector stack1; EvalScript(stack1, scriptSig1, CTransaction(), 0, SCRIPT_VERIFY_STRICTENC, 0); vector stack2; EvalScript(stack2, scriptSig2, CTransaction(), 0, SCRIPT_VERIFY_STRICTENC, 0); return CombineSignatures(scriptPubKey, txTo, nIn, txType, vSolutions, stack1, stack2); } unsigned int CScript::GetSigOpCount(bool fAccurate) const { unsigned int n = 0; const_iterator pc = begin(); opcodetype lastOpcode = OP_INVALIDOPCODE; while (pc < end()) { opcodetype opcode; if (!GetOp(pc, opcode)) break; if (opcode == OP_CHECKSIG || opcode == OP_CHECKSIGVERIFY) n++; else if (opcode == OP_CHECKMULTISIG || opcode == OP_CHECKMULTISIGVERIFY) { if (fAccurate && lastOpcode >= OP_1 && lastOpcode <= OP_16) n += DecodeOP_N(lastOpcode); else n += 20; } lastOpcode = opcode; } return n; } unsigned int CScript::GetSigOpCount(const CScript& scriptSig) const { if (!IsPayToScriptHash()) return GetSigOpCount(true); // This is a pay-to-script-hash scriptPubKey; // get the last item that the scriptSig // pushes onto the stack: const_iterator pc = scriptSig.begin(); vector data; while (pc < scriptSig.end()) { opcodetype opcode; if (!scriptSig.GetOp(pc, opcode, data)) return 0; if (opcode > OP_16) return 0; } /// ... and return its opcount: CScript subscript(data.begin(), data.end()); return subscript.GetSigOpCount(true); } bool CScript::IsPayToScriptHash() const { // Extra-fast test for pay-to-script-hash CScripts: return (this->size() == 23 && this->at(0) == OP_HASH160 && this->at(1) == 0x14 && this->at(22) == OP_EQUAL); } bool CScript::IsPushOnly() const { const_iterator pc = begin(); while (pc < end()) { opcodetype opcode; if (!GetOp(pc, opcode)) return false; // Note that IsPushOnly() *does* consider OP_RESERVED to be a // push-type opcode, however execution of OP_RESERVED fails, so // it's not relevant to P2SH as the scriptSig would fail prior to // the P2SH special validation code being executed. if (opcode > OP_16) return false; } return true; } bool CScript::HasCanonicalPushes() const { const_iterator pc = begin(); while (pc < end()) { opcodetype opcode; std::vector data; if (!GetOp(pc, opcode, data)) return false; if (opcode > OP_16) continue; if (opcode < OP_PUSHDATA1 && opcode > OP_0 && (data.size() == 1 && data[0] <= 16)) // Could have used an OP_n code, rather than a 1-byte push. return false; if (opcode == OP_PUSHDATA1 && data.size() < OP_PUSHDATA1) // Could have used a normal n-byte push, rather than OP_PUSHDATA1. return false; if (opcode == OP_PUSHDATA2 && data.size() <= 0xFF) // Could have used an OP_PUSHDATA1. return false; if (opcode == OP_PUSHDATA4 && data.size() <= 0xFFFF) // Could have used an OP_PUSHDATA2. return false; } return true; } class CScriptVisitor : public boost::static_visitor { private: CScript *script; public: CScriptVisitor(CScript *scriptin) { script = scriptin; } bool operator()(const CNoDestination &dest) const { script->clear(); return false; } bool operator()(const CKeyID &keyID) const { script->clear(); *script << OP_DUP << OP_HASH160 << keyID << OP_EQUALVERIFY << OP_CHECKSIG; return true; } bool operator()(const CScriptID &scriptID) const { script->clear(); *script << OP_HASH160 << scriptID << OP_EQUAL; return true; } }; void CScript::SetDestination(const CTxDestination& dest) { boost::apply_visitor(CScriptVisitor(this), dest); } void CScript::SetMultisig(int nRequired, const std::vector& keys) { this->clear(); *this << EncodeOP_N(nRequired); BOOST_FOREACH(const CPubKey& key, keys) *this << key; *this << EncodeOP_N(keys.size()) << OP_CHECKMULTISIG; } bool CScriptCompressor::IsToKeyID(CKeyID &hash) const { if (script.size() == 25 && script[0] == OP_DUP && script[1] == OP_HASH160 && script[2] == 20 && script[23] == OP_EQUALVERIFY && script[24] == OP_CHECKSIG) { memcpy(&hash, &script[3], 20); return true; } return false; } bool CScriptCompressor::IsToScriptID(CScriptID &hash) const { if (script.size() == 23 && script[0] == OP_HASH160 && script[1] == 20 && script[22] == OP_EQUAL) { memcpy(&hash, &script[2], 20); return true; } return false; } bool CScriptCompressor::IsToPubKey(CPubKey &pubkey) const { if (script.size() == 35 && script[0] == 33 && script[34] == OP_CHECKSIG && (script[1] == 0x02 || script[1] == 0x03)) { pubkey.Set(&script[1], &script[34]); return true; } if (script.size() == 67 && script[0] == 65 && script[66] == OP_CHECKSIG && script[1] == 0x04) { pubkey.Set(&script[1], &script[66]); return pubkey.IsFullyValid(); // if not fully valid, a case that would not be compressible } return false; } bool CScriptCompressor::Compress(std::vector &out) const { CKeyID keyID; if (IsToKeyID(keyID)) { out.resize(21); out[0] = 0x00; memcpy(&out[1], &keyID, 20); return true; } CScriptID scriptID; if (IsToScriptID(scriptID)) { out.resize(21); out[0] = 0x01; memcpy(&out[1], &scriptID, 20); return true; } CPubKey pubkey; if (IsToPubKey(pubkey)) { out.resize(33); memcpy(&out[1], &pubkey[1], 32); if (pubkey[0] == 0x02 || pubkey[0] == 0x03) { out[0] = pubkey[0]; return true; } else if (pubkey[0] == 0x04) { out[0] = 0x04 | (pubkey[64] & 0x01); return true; } } return false; } unsigned int CScriptCompressor::GetSpecialSize(unsigned int nSize) const { if (nSize == 0 || nSize == 1) return 20; if (nSize == 2 || nSize == 3 || nSize == 4 || nSize == 5) return 32; return 0; } bool CScriptCompressor::Decompress(unsigned int nSize, const std::vector &in) { switch(nSize) { case 0x00: script.resize(25); script[0] = OP_DUP; script[1] = OP_HASH160; script[2] = 20; memcpy(&script[3], &in[0], 20); script[23] = OP_EQUALVERIFY; script[24] = OP_CHECKSIG; return true; case 0x01: script.resize(23); script[0] = OP_HASH160; script[1] = 20; memcpy(&script[2], &in[0], 20); script[22] = OP_EQUAL; return true; case 0x02: case 0x03: script.resize(35); script[0] = 33; script[1] = nSize; memcpy(&script[2], &in[0], 32); script[34] = OP_CHECKSIG; return true; case 0x04: case 0x05: unsigned char vch[33] = {}; vch[0] = nSize - 2; memcpy(&vch[1], &in[0], 32); CPubKey pubkey(&vch[0], &vch[33]); if (!pubkey.Decompress()) return false; assert(pubkey.size() == 65); script.resize(67); script[0] = 65; memcpy(&script[1], pubkey.begin(), 65); script[66] = OP_CHECKSIG; return true; } return false; } bool CScript::IsNormalPaymentScript() const { if(this->size() != 25) return false; std::string str; opcodetype opcode; const_iterator pc = begin(); int i = 0; while (pc < end()) { GetOp(pc, opcode); if( i == 0 && opcode != OP_DUP) return false; else if(i == 1 && opcode != OP_HASH160) return false; else if(i == 3 && opcode != OP_EQUALVERIFY) return false; else if(i == 4 && opcode != OP_CHECKSIG) return false; else if(i == 5) return false; i++; } return true; }