// Copyright (c) 2009-2010 Satoshi Nakamoto // Copyright (c) 2009-2016 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_UINT256_H #define BITCOIN_UINT256_H #include #include #include #include #include #include #include "crypto/common.h" /** Template base class for fixed-sized opaque blobs. */ template class base_blob { protected: enum { WIDTH=BITS/8 }; uint8_t data[WIDTH]; public: base_blob() { memset(data, 0, sizeof(data)); } explicit base_blob(const std::vector& vch); bool IsNull() const { for (int i = 0; i < WIDTH; i++) if (data[i] != 0) return false; return true; } void SetNull() { memset(data, 0, sizeof(data)); } inline int Compare(const base_blob& other) const { return memcmp(data, other.data, sizeof(data)); } friend inline bool operator==(const base_blob& a, const base_blob& b) { return a.Compare(b) == 0; } friend inline bool operator!=(const base_blob& a, const base_blob& b) { return a.Compare(b) != 0; } friend inline bool operator<(const base_blob& a, const base_blob& b) { return a.Compare(b) < 0; } std::string GetHex() const; void SetHex(const char* psz); void SetHex(const std::string& str); std::string ToString() const; unsigned char* begin() { return &data[0]; } unsigned char* end() { return &data[WIDTH]; } const unsigned char* begin() const { return &data[0]; } const unsigned char* end() const { return &data[WIDTH]; } unsigned int size() const { return sizeof(data); } uint64_t GetUint64(int pos) const { const uint8_t* ptr = data + pos * 8; return ((uint64_t)ptr[0]) | \ ((uint64_t)ptr[1]) << 8 | \ ((uint64_t)ptr[2]) << 16 | \ ((uint64_t)ptr[3]) << 24 | \ ((uint64_t)ptr[4]) << 32 | \ ((uint64_t)ptr[5]) << 40 | \ ((uint64_t)ptr[6]) << 48 | \ ((uint64_t)ptr[7]) << 56; } template void Serialize(Stream& s) const { s.write((char*)data, sizeof(data)); } template void Unserialize(Stream& s) { s.read((char*)data, sizeof(data)); } }; /** 160-bit opaque blob. * @note This type is called uint160 for historical reasons only. It is an opaque * blob of 160 bits and has no integer operations. */ class uint160 : public base_blob<160> { public: uint160() {} uint160(const base_blob<160>& b) : base_blob<160>(b) {} explicit uint160(const std::vector& vch) : base_blob<160>(vch) {} }; /** 256-bit opaque blob. * @note This type is called uint256 for historical reasons only. It is an * opaque blob of 256 bits and has no integer operations. Use arith_uint256 if * those are required. */ class uint256 : public base_blob<256> { public: uint256() {} uint256(const base_blob<256>& b) : base_blob<256>(b) {} explicit uint256(const std::vector& vch) : base_blob<256>(vch) {} /** A cheap hash function that just returns 64 bits from the result, it can be * used when the contents are considered uniformly random. It is not appropriate * when the value can easily be influenced from outside as e.g. a network adversary could * provide values to trigger worst-case behavior. */ uint64_t GetCheapHash() const { return ReadLE64(data); } }; /* uint256 from const char *. * This is a separate function because the constructor uint256(const char*) can result * in dangerously catching uint256(0). */ inline uint256 uint256S(const char *str) { uint256 rv; rv.SetHex(str); return rv; } /* uint256 from std::string. * This is a separate function because the constructor uint256(const std::string &str) can result * in dangerously catching uint256(0) via std::string(const char*). */ inline uint256 uint256S(const std::string& str) { uint256 rv; rv.SetHex(str); return rv; } #endif // BITCOIN_UINT256_H