// Copyright (c) 2009-2010 Satoshi Nakamoto // Copyright (c) 2009-present 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 #include #include #include /** Template base class for fixed-sized opaque blobs. */ template class base_blob { protected: static constexpr int WIDTH = BITS / 8; static_assert(BITS % 8 == 0, "base_blob currently only supports whole bytes."); std::array m_data; static_assert(WIDTH == sizeof(m_data), "Sanity check"); public: /* construct 0 value by default */ constexpr base_blob() : m_data() {} /* constructor for constants between 1 and 255 */ constexpr explicit base_blob(uint8_t v) : m_data{v} {} constexpr explicit base_blob(Span vch) { assert(vch.size() == WIDTH); std::copy(vch.begin(), vch.end(), m_data.begin()); } consteval explicit base_blob(std::string_view hex_str); constexpr bool IsNull() const { return std::all_of(m_data.begin(), m_data.end(), [](uint8_t val) { return val == 0; }); } constexpr void SetNull() { std::fill(m_data.begin(), m_data.end(), 0); } /** Lexicographic ordering * @note Does NOT match the ordering on the corresponding \ref * base_uint::CompareTo, which starts comparing from the end. */ constexpr int Compare(const base_blob& other) const { return std::memcmp(m_data.data(), other.m_data.data(), WIDTH); } friend constexpr bool operator==(const base_blob& a, const base_blob& b) { return a.Compare(b) == 0; } friend constexpr bool operator!=(const base_blob& a, const base_blob& b) { return a.Compare(b) != 0; } friend constexpr bool operator<(const base_blob& a, const base_blob& b) { return a.Compare(b) < 0; } /** @name Hex representation * * The reverse-byte hex representation is a convenient way to view the blob * as a number, because it is consistent with the way the base_uint class * converts blobs to numbers. * * @note base_uint treats the blob as an array of bytes with the numerically * least significant byte first and the most significant byte last. Because * numbers are typically written with the most significant digit first and * the least significant digit last, the reverse hex display of the blob * corresponds to the same numeric value that base_uint interprets from the * blob. * @{*/ std::string GetHex() const; /** Unlike FromHex this accepts any invalid input, thus it is fragile and deprecated! * * - Hex numbers that don't specify enough bytes to fill the internal array * will be treated as setting the beginning of it, which corresponds to * the least significant bytes when converted to base_uint. * * - Hex numbers specifying too many bytes will have the numerically most * significant bytes (the beginning of the string) narrowed away. * * - An odd count of hex digits will result in the high bits of the leftmost * byte being zero. * "0x123" => {0x23, 0x1, 0x0, ..., 0x0} */ void SetHexDeprecated(std::string_view str); std::string ToString() const; /**@}*/ constexpr const unsigned char* data() const { return m_data.data(); } constexpr unsigned char* data() { return m_data.data(); } constexpr unsigned char* begin() { return m_data.data(); } constexpr unsigned char* end() { return m_data.data() + WIDTH; } constexpr const unsigned char* begin() const { return m_data.data(); } constexpr const unsigned char* end() const { return m_data.data() + WIDTH; } static constexpr unsigned int size() { return WIDTH; } constexpr uint64_t GetUint64(int pos) const { return ReadLE64(m_data.data() + pos * 8); } template void Serialize(Stream& s) const { s << Span(m_data); } template void Unserialize(Stream& s) { s.read(MakeWritableByteSpan(m_data)); } }; template consteval base_blob::base_blob(std::string_view hex_str) { // Non-lookup table version of HexDigit(). auto from_hex = [](const char c) -> int8_t { if (c >= '0' && c <= '9') return c - '0'; if (c >= 'a' && c <= 'f') return c - 'a' + 0xA; if (c >= 'A' && c <= 'F') return c - 'A' + 0xA; assert(false); // Reached if ctor is called with an invalid hex digit. }; assert(hex_str.length() == m_data.size() * 2); // 2 hex digits per byte. auto str_it = hex_str.rbegin(); for (auto& elem : m_data) { auto lo = from_hex(*(str_it++)); elem = (from_hex(*(str_it++)) << 4) | lo; } } namespace detail { /** * Writes the hex string (in reverse byte order) into a new uintN_t object * and only returns a value iff all of the checks pass: * - Input length is uintN_t::size()*2 * - All characters are hex */ template std::optional FromHex(std::string_view str) { if (uintN_t::size() * 2 != str.size() || !IsHex(str)) return std::nullopt; uintN_t rv; rv.SetHexDeprecated(str); return rv; } } // namespace detail /** 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: static std::optional FromHex(std::string_view str) { return detail::FromHex(str); } constexpr uint160() = default; constexpr explicit uint160(Span 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: static std::optional FromHex(std::string_view str) { return detail::FromHex(str); } constexpr uint256() = default; consteval explicit uint256(std::string_view hex_str) : base_blob<256>(hex_str) {} constexpr explicit uint256(uint8_t v) : base_blob<256>(v) {} constexpr explicit uint256(Span vch) : base_blob<256>(vch) {} static const uint256 ZERO; static const uint256 ONE; }; /* uint256 from std::string_view, containing byte-reversed hex encoding. * DEPRECATED. Unlike FromHex this accepts any invalid input, thus it is fragile and deprecated! */ inline uint256 uint256S(std::string_view str) { uint256 rv; rv.SetHexDeprecated(str); return rv; } #endif // BITCOIN_UINT256_H