// Copyright (c) 2009-2010 Satoshi Nakamoto // Copyright (c) 2009-2015 The Bitcoin Core developers // Distributed under the MIT software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. #ifndef BITCOIN_TEST_SCRIPTNUM10_H #define BITCOIN_TEST_SCRIPTNUM10_H #include #include #include #include #include #include class scriptnum10_error : public std::runtime_error { public: explicit scriptnum10_error(const std::string& str) : std::runtime_error(str) {} }; class CScriptNum10 { /** * The ScriptNum implementation from Bitcoin Core 0.10.0, for cross-comparison. */ public: explicit CScriptNum10(const int64_t& n) { m_value = n; } static const size_t nDefaultMaxNumSize = 4; explicit CScriptNum10(const std::vector& vch, bool fRequireMinimal, const size_t nMaxNumSize = nDefaultMaxNumSize) { if (vch.size() > nMaxNumSize) { throw scriptnum10_error("script number overflow"); } if (fRequireMinimal && vch.size() > 0) { // Check that the number is encoded with the minimum possible // number of bytes. // // If the most-significant-byte - excluding the sign bit - is zero // then we're not minimal. Note how this test also rejects the // negative-zero encoding, 0x80. if ((vch.back() & 0x7f) == 0) { // One exception: if there's more than one byte and the most // significant bit of the second-most-significant-byte is set // it would conflict with the sign bit. An example of this case // is +-255, which encode to 0xff00 and 0xff80 respectively. // (big-endian). if (vch.size() <= 1 || (vch[vch.size() - 2] & 0x80) == 0) { throw scriptnum10_error("non-minimally encoded script number"); } } } m_value = set_vch(vch); } inline bool operator==(const int64_t& rhs) const { return m_value == rhs; } inline bool operator!=(const int64_t& rhs) const { return m_value != rhs; } inline bool operator<=(const int64_t& rhs) const { return m_value <= rhs; } inline bool operator< (const int64_t& rhs) const { return m_value < rhs; } inline bool operator>=(const int64_t& rhs) const { return m_value >= rhs; } inline bool operator> (const int64_t& rhs) const { return m_value > rhs; } inline bool operator==(const CScriptNum10& rhs) const { return operator==(rhs.m_value); } inline bool operator!=(const CScriptNum10& rhs) const { return operator!=(rhs.m_value); } inline bool operator<=(const CScriptNum10& rhs) const { return operator<=(rhs.m_value); } inline bool operator< (const CScriptNum10& rhs) const { return operator< (rhs.m_value); } inline bool operator>=(const CScriptNum10& rhs) const { return operator>=(rhs.m_value); } inline bool operator> (const CScriptNum10& rhs) const { return operator> (rhs.m_value); } inline CScriptNum10 operator+( const int64_t& rhs) const { return CScriptNum10(m_value + rhs);} inline CScriptNum10 operator-( const int64_t& rhs) const { return CScriptNum10(m_value - rhs);} inline CScriptNum10 operator+( const CScriptNum10& rhs) const { return operator+(rhs.m_value); } inline CScriptNum10 operator-( const CScriptNum10& rhs) const { return operator-(rhs.m_value); } inline CScriptNum10& operator+=( const CScriptNum10& rhs) { return operator+=(rhs.m_value); } inline CScriptNum10& operator-=( const CScriptNum10& rhs) { return operator-=(rhs.m_value); } inline CScriptNum10 operator-() const { assert(m_value != std::numeric_limits::min()); return CScriptNum10(-m_value); } inline CScriptNum10& operator=( const int64_t& rhs) { m_value = rhs; return *this; } inline CScriptNum10& operator+=( const int64_t& rhs) { assert(rhs == 0 || (rhs > 0 && m_value <= std::numeric_limits::max() - rhs) || (rhs < 0 && m_value >= std::numeric_limits::min() - rhs)); m_value += rhs; return *this; } inline CScriptNum10& operator-=( const int64_t& rhs) { assert(rhs == 0 || (rhs > 0 && m_value >= std::numeric_limits::min() + rhs) || (rhs < 0 && m_value <= std::numeric_limits::max() + rhs)); m_value -= rhs; return *this; } int getint() const { if (m_value > std::numeric_limits::max()) return std::numeric_limits::max(); else if (m_value < std::numeric_limits::min()) return std::numeric_limits::min(); return m_value; } std::vector getvch() const { return serialize(m_value); } static std::vector serialize(const int64_t& value) { if(value == 0) return std::vector(); std::vector result; const bool neg = value < 0; uint64_t absvalue = neg ? -value : value; while(absvalue) { result.push_back(absvalue & 0xff); absvalue >>= 8; } // - If the most significant byte is >= 0x80 and the value is positive, push a // new zero-byte to make the significant byte < 0x80 again. // - If the most significant byte is >= 0x80 and the value is negative, push a // new 0x80 byte that will be popped off when converting to an integral. // - If the most significant byte is < 0x80 and the value is negative, add // 0x80 to it, since it will be subtracted and interpreted as a negative when // converting to an integral. if (result.back() & 0x80) result.push_back(neg ? 0x80 : 0); else if (neg) result.back() |= 0x80; return result; } private: static int64_t set_vch(const std::vector& vch) { if (vch.empty()) return 0; int64_t result = 0; for (size_t i = 0; i != vch.size(); ++i) result |= static_cast(vch[i]) << 8*i; // If the input vector's most significant byte is 0x80, remove it from // the result's msb and return a negative. if (vch.back() & 0x80) return -((int64_t)(result & ~(0x80ULL << (8 * (vch.size() - 1))))); return result; } int64_t m_value; }; #endif // BITCOIN_TEST_BIGNUM_H