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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 TrieHash.cpp
 * @author Gav Wood <i@gavwood.com>
 * @date 2014
 */

#include "TrieHash.h"

#include <libdevcrypto/TrieCommon.h>
#include <libdevcrypto/SHA3.h>
#include <libethcore/Common.h>
using namespace std;
using namespace dev;
using namespace dev::eth;

namespace dev
{

/*/
#define APPEND_CHILD appendData
/*/
#define APPEND_CHILD appendRaw
/**/

#define ENABLE_DEBUG_PRINT 0

#if ENABLE_DEBUG_PRINT
bool g_hashDebug = false;
#endif

void hash256aux(HexMap const& _s, HexMap::const_iterator _begin, HexMap::const_iterator _end, unsigned _preLen, RLPStream& _rlp);

void hash256rlp(HexMap const& _s, HexMap::const_iterator _begin, HexMap::const_iterator _end, unsigned _preLen, RLPStream& _rlp)
{
#if ENABLE_DEBUG_PRINT
    static std::string s_indent;
    if (_preLen)
        s_indent += "  ";
#endif

    if (_begin == _end)
        _rlp << ""; // NULL
    else if (std::next(_begin) == _end)
    {
        // only one left - terminate with the pair.
        _rlp.appendList(2) << hexPrefixEncode(_begin->first, true, _preLen) << _begin->second;
#if ENABLE_DEBUG_PRINT
        if (g_hashDebug)
            std::cerr << s_indent << toHex(bytesConstRef(_begin->first.data() + _preLen, _begin->first.size() - _preLen), 1) << ": " << _begin->second << " = " << sha3(_rlp.out()) << std::endl;
#endif
    }
    else
    {
        // find the number of common prefix nibbles shared
        // i.e. the minimum number of nibbles shared at the beginning between the first hex string and each successive.
        unsigned sharedPre = (unsigned)-1;
        unsigned c = 0;
        for (auto i = std::next(_begin); i != _end && sharedPre; ++i, ++c)
        {
            unsigned x = std::min(sharedPre, std::min((unsigned)_begin->first.size(), (unsigned)i->first.size()));
            unsigned shared = _preLen;
            for (; shared < x && _begin->first[shared] == i->first[shared]; ++shared) {}
            sharedPre = std::min(shared, sharedPre);
        }
        if (sharedPre > _preLen)
        {
            // if they all have the same next nibble, we also want a pair.
#if ENABLE_DEBUG_PRINT
            if (g_hashDebug)
                std::cerr << s_indent << toHex(bytesConstRef(_begin->first.data() + _preLen, sharedPre), 1) << ": " << std::endl;
#endif
            _rlp.appendList(2) << hexPrefixEncode(_begin->first, false, _preLen, (int)sharedPre);
            hash256aux(_s, _begin, _end, (unsigned)sharedPre, _rlp);
#if ENABLE_DEBUG_PRINT
            if (g_hashDebug)
                std::cerr << s_indent << "= " << hex << sha3(_rlp.out()) << dec << std::endl;
#endif
        }
        else
        {
            // otherwise enumerate all 16+1 entries.
            _rlp.appendList(17);
            auto b = _begin;
            if (_preLen == b->first.size())
            {
#if ENABLE_DEBUG_PRINT
                if (g_hashDebug)
                    std::cerr << s_indent << "@: " << b->second << std::endl;
#endif
                ++b;
            }
            for (auto i = 0; i < 16; ++i)
            {
                auto n = b;
                for (; n != _end && n->first[_preLen] == i; ++n) {}
                if (b == n)
                    _rlp << "";
                else
                {
#if ENABLE_DEBUG_PRINT
                    if (g_hashDebug)
                        std::cerr << s_indent << std::hex << i << ": " << std::dec << std::endl;
#endif
                    hash256aux(_s, b, n, _preLen + 1, _rlp);
                }
                b = n;
            }
            if (_preLen == _begin->first.size())
                _rlp << _begin->second;
            else
                _rlp << "";

#if ENABLE_DEBUG_PRINT
            if (g_hashDebug)
                std::cerr << s_indent << "= " << hex << sha3(_rlp.out()) << dec << std::endl;
#endif
        }
    }
#if ENABLE_DEBUG_PRINT
    if (_preLen)
        s_indent.resize(s_indent.size() - 2);
#endif
}

void hash256aux(HexMap const& _s, HexMap::const_iterator _begin, HexMap::const_iterator _end, unsigned _preLen, RLPStream& _rlp)
{
    RLPStream rlp;
    hash256rlp(_s, _begin, _end, _preLen, rlp);
    if (rlp.out().size() < 32)
    {
        // RECURSIVE RLP
#if ENABLE_DEBUG_PRINT
        cerr << "[INLINE: " << dec << rlp.out().size() << " < 32]" << endl;
#endif
        _rlp.APPEND_CHILD(rlp.out());
    }
    else
    {
#if ENABLE_DEBUG_PRINT
        cerr << "[HASH: " << dec << rlp.out().size() << " >= 32]" << endl;
#endif
        _rlp << sha3(rlp.out());
    }
}

h256 hash256(StringMap const& _s)
{
    // build patricia tree.
    if (_s.empty())
        return sha3(rlp(""));
    HexMap hexMap;
    for (auto i = _s.rbegin(); i != _s.rend(); ++i)
        hexMap[asNibbles(i->first)] = i->second;
    RLPStream s;
    hash256rlp(hexMap, hexMap.cbegin(), hexMap.cend(), 0, s);
    return sha3(s.out());
}

bytes rlp256(StringMap const& _s)
{
    // build patricia tree.
    if (_s.empty())
        return rlp("");
    HexMap hexMap;
    for (auto i = _s.rbegin(); i != _s.rend(); ++i)
        hexMap[asNibbles(i->first)] = i->second;
    RLPStream s;
    hash256aux(hexMap, hexMap.cbegin(), hexMap.cend(), 0, s);
    return s.out();
}

h256 hash256(u256Map const& _s)
{
    // build patricia tree.
    if (_s.empty())
        return sha3(rlp(""));
    HexMap hexMap;
    for (auto i = _s.rbegin(); i != _s.rend(); ++i)
        hexMap[asNibbles(toBigEndianString(i->first))] = asString(rlp(i->second));
    RLPStream s;
    hash256rlp(hexMap, hexMap.cbegin(), hexMap.cend(), 0, s);
    return sha3(s.out());
}

}