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/*
    This file is part of cpp-ethereum.

    cpp-ethereum is free software: you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation, either version 3 of the License, or
    (at your option) any later version.

    cpp-ethereum is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.

    You should have received a copy of the GNU General Public License
    along with cpp-ethereum.  If not, see <http://www.gnu.org/licenses/>.
*/
/** @file FixedHash.h
 * @author Gav Wood <i@gavwood.com>
 * @date 2014
 *
 * The FixedHash fixed-size "hash" container type.
 */

#pragma once

#include <array>
#include <cstdint>
#include <algorithm>
#include <boost/functional/hash.hpp>
#include "CommonData.h"

namespace dev
{

/// Compile-time calculation of Log2 of constant values.
template <unsigned N> struct StaticLog2 { enum { result = 1 + StaticLog2<N/2>::result }; };
template <> struct StaticLog2<1> { enum { result = 0 }; };

/// Fixed-size raw-byte array container type, with an API optimised for storing hashes.
/// Transparently converts to/from the corresponding arithmetic type; this will
/// assume the data contained in the hash is big-endian.
template <unsigned N>
class FixedHash
{
public:
    /// The corresponding arithmetic type.
    using Arith = boost::multiprecision::number<boost::multiprecision::cpp_int_backend<N * 8, N * 8, boost::multiprecision::unsigned_magnitude, boost::multiprecision::unchecked, void>>;

    /// The size of the container.
    enum { size = N };

    /// A dummy flag to avoid accidental construction from pointer.
    enum ConstructFromPointerType { ConstructFromPointer };

    /// Method to convert from a string.
    enum ConstructFromStringType { FromHex, FromBinary };

    /// Method to convert from a string.
    enum ConstructFromHashType { AlignLeft, AlignRight, FailIfDifferent };

    /// Construct an empty hash.
    FixedHash() { m_data.fill(0); }

    /// Construct from another hash, filling with zeroes or cropping as necessary.
    template <unsigned M> explicit FixedHash(FixedHash<M> const& _h, ConstructFromHashType _t = AlignLeft) { m_data.fill(0); unsigned c = std::min(M, N); for (unsigned i = 0; i < c; ++i) m_data[_t == AlignRight ? N - 1 - i : i] = _h[_t == AlignRight ? M - 1 - i : i]; }

    /// Convert from the corresponding arithmetic type.
    FixedHash(Arith const& _arith) { toBigEndian(_arith, m_data); }

    /// Convert from unsigned
    explicit FixedHash(unsigned _u) { toBigEndian(_u, m_data); }

    /// Explicitly construct, copying from a byte array.
    explicit FixedHash(bytes const& _b, ConstructFromHashType _t = FailIfDifferent) { if (_b.size() == N) memcpy(m_data.data(), _b.data(), std::min<unsigned>(_b.size(), N)); else { m_data.fill(0); if (_t != FailIfDifferent) { auto c = std::min<unsigned>(_b.size(), N); for (unsigned i = 0; i < c; ++i) m_data[_t == AlignRight ? N - 1 - i : i] = _b[_t == AlignRight ? _b.size() - 1 - i : i]; } } }

    /// Explicitly construct, copying from a byte array.
    explicit FixedHash(bytesConstRef _b, ConstructFromHashType _t = FailIfDifferent) { if (_b.size() == N) memcpy(m_data.data(), _b.data(), std::min<unsigned>(_b.size(), N)); else { m_data.fill(0); if (_t != FailIfDifferent) { auto c = std::min<unsigned>(_b.size(), N); for (unsigned i = 0; i < c; ++i) m_data[_t == AlignRight ? N - 1 - i : i] = _b[_t == AlignRight ? _b.size() - 1 - i : i]; } } }

    /// Explicitly construct, copying from a bytes in memory with given pointer.
    explicit FixedHash(byte const* _bs, ConstructFromPointerType) { memcpy(m_data.data(), _bs, N); }

    /// Explicitly construct, copying from a  string.
    explicit FixedHash(std::string const& _s, ConstructFromStringType _t = FromHex, ConstructFromHashType _ht = FailIfDifferent): FixedHash(_t == FromHex ? fromHex(_s, WhenError::Throw) : dev::asBytes(_s), _ht) {}

    /// Convert to arithmetic type.
    operator Arith() const { return fromBigEndian<Arith>(m_data); }

    /// @returns true iff this is the empty hash.
    explicit operator bool() const { return std::any_of(m_data.begin(), m_data.end(), [](byte _b) { return _b != 0; }); }

    // The obvious comparison operators.
    bool operator==(FixedHash const& _c) const { return m_data == _c.m_data; }
    bool operator!=(FixedHash const& _c) const { return m_data != _c.m_data; }
    bool operator<(FixedHash const& _c) const { for (unsigned i = 0; i < N; ++i) if (m_data[i] < _c.m_data[i]) return true; else if (m_data[i] > _c.m_data[i]) return false; return false; }
    bool operator>=(FixedHash const& _c) const { return !operator<(_c); }
    bool operator<=(FixedHash const& _c) const { return operator==(_c) || operator<(_c); }
    bool operator>(FixedHash const& _c) const { return !operator<=(_c); }

    // The obvious binary operators.
    FixedHash& operator^=(FixedHash const& _c) { for (unsigned i = 0; i < N; ++i) m_data[i] ^= _c.m_data[i]; return *this; }
    FixedHash operator^(FixedHash const& _c) const { return FixedHash(*this) ^= _c; }
    FixedHash& operator|=(FixedHash const& _c) { for (unsigned i = 0; i < N; ++i) m_data[i] |= _c.m_data[i]; return *this; }
    FixedHash operator|(FixedHash const& _c) const { return FixedHash(*this) |= _c; }
    FixedHash& operator&=(FixedHash const& _c) { for (unsigned i = 0; i < N; ++i) m_data[i] &= _c.m_data[i]; return *this; }
    FixedHash operator&(FixedHash const& _c) const { return FixedHash(*this) &= _c; }
    FixedHash operator~() const { FixedHash ret; for (unsigned i = 0; i < N; ++i) ret[i] = ~m_data[i]; return ret; }

    // Big-endian increment.
    FixedHash& operator++() { for (unsigned i = size; i > 0 && !++m_data[--i]; ) {} return *this; }

    /// @returns true if all one-bits in @a _c are set in this object.
    bool contains(FixedHash const& _c) const { return (*this & _c) == _c; }

    /// @returns a particular byte from the hash.
    byte& operator[](unsigned _i) { return m_data[_i]; }
    /// @returns a particular byte from the hash.
    byte operator[](unsigned _i) const { return m_data[_i]; }

    /// @returns an abridged version of the hash as a user-readable hex string.
    std::string abridged() const { return toHex(ref().cropped(0, 4)) + "\342\200\246"; }

    /// @returns a version of the hash as a user-readable hex string that leaves out the middle part.
    std::string abridgedMiddle() const { return toHex(ref().cropped(0, 4)) + "\342\200\246" + toHex(ref().cropped(N - 4)); }

    /// @returns the hash as a user-readable hex string.
    std::string hex() const { return toHex(ref()); }

    /// @returns a mutable byte vector_ref to the object's data.
    bytesRef ref() { return bytesRef(m_data.data(), N); }

    /// @returns a constant byte vector_ref to the object's data.
    bytesConstRef ref() const { return bytesConstRef(m_data.data(), N); }

    /// @returns a mutable byte pointer to the object's data.
    byte* data() { return m_data.data(); }

    /// @returns a constant byte pointer to the object's data.
    byte const* data() const { return m_data.data(); }

    /// @returns a copy of the object's data as a byte vector.
    bytes asBytes() const { return bytes(data(), data() + N); }

    /// @returns a mutable reference to the object's data as an STL array.
    std::array<byte, N>& asArray() { return m_data; }

    /// @returns a constant reference to the object's data as an STL array.
    std::array<byte, N> const& asArray() const { return m_data; }

    struct hash
    {
        /// Make a hash of the object's data.
        size_t operator()(FixedHash const& _value) const { return boost::hash_range(_value.m_data.cbegin(), _value.m_data.cend()); }
    };

    template <unsigned P, unsigned M> inline FixedHash& shiftBloom(FixedHash<M> const& _h)
    {
        return (*this |= _h.template bloomPart<P, N>());
    }

    template <unsigned P, unsigned M> inline bool containsBloom(FixedHash<M> const& _h)
    {
        return contains(_h.template bloomPart<P, N>());
    }

    template <unsigned P, unsigned M> inline FixedHash<M> bloomPart() const
    {
        unsigned const c_bloomBits = M * 8;
        unsigned const c_mask = c_bloomBits - 1;
        unsigned const c_bloomBytes = (StaticLog2<c_bloomBits>::result + 7) / 8;

        static_assert((M & (M - 1)) == 0, "M must be power-of-two");
        static_assert(P * c_bloomBytes <= N, "out of range");

        FixedHash<M> ret;
        byte const* p = data();
        for (unsigned i = 0; i < P; ++i)
        {
            unsigned index = 0;
            for (unsigned j = 0; j < c_bloomBytes; ++j, ++p)
                index = (index << 8) | *p;
            index &= c_mask;
            ret[M - 1 - index / 8] |= (1 << (index % 8));
        }
        return ret;
    }

    /// Returns the index of the first bit set to one, or size() * 8 if no bits are set.
    inline unsigned firstBitSet() const
    {
        unsigned ret = 0;
        for (auto d: m_data)
            if (d)
                for (;; ++ret, d <<= 1)
                    if (d & 0x80)
                        return ret;
                    else {}
            else
                ret += 8;
        return ret;
    }

    void clear() { m_data.fill(0); }

private:
    std::array<byte, N> m_data;     ///< The binary data.
};

/// Fast equality operator for h256.
template<> inline bool FixedHash<32>::operator==(FixedHash<32> const& _other) const
{
    const uint64_t* hash1 = (const uint64_t*)data();
    const uint64_t* hash2 = (const uint64_t*)_other.data();
    return (hash1[0] == hash2[0]) && (hash1[1] == hash2[1]) && (hash1[2] == hash2[2]) && (hash1[3] == hash2[3]);
}

/// Fast std::hash compatible hash function object for h256.
template<> inline size_t FixedHash<32>::hash::operator()(FixedHash<32> const& value) const
{
    uint64_t const* data = reinterpret_cast<uint64_t const*>(value.data());
    return boost::hash_range(data, data + 4);
}

/// Stream I/O for the FixedHash class.
template <unsigned N>
inline std::ostream& operator<<(std::ostream& _out, FixedHash<N> const& _h)
{
    _out << std::noshowbase << std::hex << std::setfill('0');
    for (unsigned i = 0; i < N; ++i)
        _out << std::setw(2) << (int)_h[i];
    _out << std::dec;
    return _out;
}

// Common types of FixedHash.
using h2048 = FixedHash<256>;
using h1024 = FixedHash<128>;
using h520 = FixedHash<65>;
using h512 = FixedHash<64>;
using h256 = FixedHash<32>;
using h160 = FixedHash<20>;
using h128 = FixedHash<16>;
using h64 = FixedHash<8>;
using h512s = std::vector<h512>;
using h256s = std::vector<h256>;
using h160s = std::vector<h160>;
using h256Set = std::set<h256>;
using h160Set = std::set<h160>;
using h256Hash = std::unordered_set<h256>;
using h160Hash = std::unordered_set<h160>;

/// Convert the given value into h160 (160-bit unsigned integer) using the right 20 bytes.
inline h160 right160(h256 const& _t)
{
    h160 ret;
    memcpy(ret.data(), _t.data() + 12, 20);
    return ret;
}

/// Convert the given value into h160 (160-bit unsigned integer) using the left 20 bytes.
inline h160 left160(h256 const& _t)
{
    h160 ret;
    memcpy(&ret[0], _t.data(), 20);
    return ret;
}

inline std::string toString(h256s const& _bs)
{
    std::ostringstream out;
    out << "[ ";
    for (auto i: _bs)
        out << i.abridged() << ", ";
    out << "]";
    return out.str();
}

}

namespace std
{
    /// Forward std::hash<dev::FixedHash> to dev::FixedHash::hash.
    template<> struct hash<dev::h64>: dev::h64::hash {};
    template<> struct hash<dev::h128>: dev::h128::hash {};
    template<> struct hash<dev::h160>: dev::h160::hash {};
    template<> struct hash<dev::h256>: dev::h256::hash {};
    template<> struct hash<dev::h512>: dev::h512::hash {};
}