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/*
    This file is part of solidity.

    solidity 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.

    solidity 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 solidity.  If not, see <http://www.gnu.org/licenses/>.
*/
/** @file ConstantOptimiser.cpp
 * @author Christian <c@ethdev.com>
 * @date 2015
 */

#include <libevmasm/ConstantOptimiser.h>
#include <libevmasm/Assembly.h>
#include <libevmasm/GasMeter.h>
using namespace std;
using namespace dev;
using namespace dev::eth;

unsigned ConstantOptimisationMethod::optimiseConstants(
    bool _isCreation,
    size_t _runs,
    Assembly& _assembly,
    AssemblyItems& _items
)
{
    unsigned optimisations = 0;
    map<AssemblyItem, size_t> pushes;
    for (AssemblyItem const& item: _items)
        if (item.type() == Push)
            pushes[item]++;
    map<u256, AssemblyItems> pendingReplacements;
    for (auto it: pushes)
    {
        AssemblyItem const& item = it.first;
        if (item.data() < 0x100)
            continue;
        Params params;
        params.multiplicity = it.second;
        params.isCreation = _isCreation;
        params.runs = _runs;
        LiteralMethod lit(params, item.data());
        bigint literalGas = lit.gasNeeded();
        CodeCopyMethod copy(params, item.data());
        bigint copyGas = copy.gasNeeded();
        ComputeMethod compute(params, item.data());
        bigint computeGas = compute.gasNeeded();
        AssemblyItems replacement;
        if (copyGas < literalGas && copyGas < computeGas)
        {
            replacement = copy.execute(_assembly);
            optimisations++;
        }
        else if (computeGas < literalGas && computeGas <= copyGas)
        {
            replacement = compute.execute(_assembly);
            optimisations++;
        }
        if (!replacement.empty())
            pendingReplacements[item.data()] = replacement;
    }
    if (!pendingReplacements.empty())
        replaceConstants(_items, pendingReplacements);
    return optimisations;
}

bigint ConstantOptimisationMethod::simpleRunGas(AssemblyItems const& _items)
{
    bigint gas = 0;
    for (AssemblyItem const& item: _items)
        if (item.type() == Push)
            gas += GasMeter::runGas(Instruction::PUSH1);
        else if (item.type() == Operation)
            gas += GasMeter::runGas(item.instruction());
    return gas;
}

bigint ConstantOptimisationMethod::dataGas(bytes const& _data) const
{
    if (m_params.isCreation)
    {
        bigint gas;
        for (auto b: _data)
            gas += b ? GasCosts::txDataNonZeroGas : GasCosts::txDataZeroGas;
        return gas;
    }
    else
        return GasCosts::createDataGas * dataSize();
}

size_t ConstantOptimisationMethod::bytesRequired(AssemblyItems const& _items)
{
    size_t size = 0;
    for (AssemblyItem const& item: _items)
        size += item.bytesRequired(3); // assume 3 byte addresses
    return size;
}

void ConstantOptimisationMethod::replaceConstants(
    AssemblyItems& _items,
    map<u256, AssemblyItems> const& _replacements
)
{
    AssemblyItems replaced;
    for (AssemblyItem const& item: _items)
    {
        if (item.type() == Push)
        {
            auto it = _replacements.find(item.data());
            if (it != _replacements.end())
            {
                replaced += it->second;
                continue;
            }
        }
        replaced.push_back(item);
    }
    _items = std::move(replaced);
}

bigint LiteralMethod::gasNeeded()
{
    return combineGas(
        simpleRunGas({Instruction::PUSH1}),
        // PUSHX plus data
        (m_params.isCreation ? GasCosts::txDataNonZeroGas : GasCosts::createDataGas) + dataGas(),
        0
    );
}

CodeCopyMethod::CodeCopyMethod(Params const& _params, u256 const& _value):
    ConstantOptimisationMethod(_params, _value)
{
}

bigint CodeCopyMethod::gasNeeded()
{
    return combineGas(
        // Run gas: we ignore memory increase costs
        simpleRunGas(copyRoutine()) + GasCosts::copyGas,
        // Data gas for copy routines: Some bytes are zero, but we ignore them.
        bytesRequired(copyRoutine()) * (m_params.isCreation ? GasCosts::txDataNonZeroGas : GasCosts::createDataGas),
        // Data gas for data itself
        dataGas(toBigEndian(m_value))
    );
}

AssemblyItems CodeCopyMethod::execute(Assembly& _assembly)
{
    bytes data = toBigEndian(m_value);
    AssemblyItems actualCopyRoutine = copyRoutine();
    actualCopyRoutine[4] = _assembly.newData(data);
    return actualCopyRoutine;
}

AssemblyItems const& CodeCopyMethod::copyRoutine() const
{
    AssemblyItems static copyRoutine{
        u256(0),
        Instruction::DUP1,
        Instruction::MLOAD, // back up memory
        u256(32),
        AssemblyItem(PushData, u256(1) << 16), // has to be replaced
        Instruction::DUP4,
        Instruction::CODECOPY,
        Instruction::DUP2,
        Instruction::MLOAD,
        Instruction::SWAP2,
        Instruction::MSTORE
    };
    return copyRoutine;
}

AssemblyItems ComputeMethod::findRepresentation(u256 const& _value)
{
    if (_value < 0x10000)
        // Very small value, not worth computing
        return AssemblyItems{_value};
    else if (dev::bytesRequired(~_value) < dev::bytesRequired(_value))
        // Negated is shorter to represent
        return findRepresentation(~_value) + AssemblyItems{Instruction::NOT};
    else
    {
        // Decompose value into a * 2**k + b where abs(b) << 2**k
        // Is not always better, try literal and decomposition method.
        AssemblyItems routine{u256(_value)};
        bigint bestGas = gasNeeded(routine);
        for (unsigned bits = 255; bits > 8; --bits)
        {
            unsigned gapDetector = unsigned(_value >> (bits - 8)) & 0x1ff;
            if (gapDetector != 0xff && gapDetector != 0x100)
                continue;

            u256 powerOfTwo = u256(1) << bits;
            u256 upperPart = _value >> bits;
            bigint lowerPart = _value & (powerOfTwo - 1);
            if (abs(powerOfTwo - lowerPart) < lowerPart)
                lowerPart = lowerPart - powerOfTwo; // make it negative
            if (abs(lowerPart) >= (powerOfTwo >> 8))
                continue;

            AssemblyItems newRoutine;
            if (lowerPart != 0)
                newRoutine += findRepresentation(u256(abs(lowerPart)));
            newRoutine += AssemblyItems{u256(bits), u256(2), Instruction::EXP};
            if (upperPart != 1 && upperPart != 0)
                newRoutine += findRepresentation(upperPart) + AssemblyItems{Instruction::MUL};
            if (lowerPart > 0)
                newRoutine += AssemblyItems{Instruction::ADD};
            else if (lowerPart < 0)
                newRoutine.push_back(Instruction::SUB);

            bigint newGas = gasNeeded(newRoutine);
            if (newGas < bestGas)
            {
                bestGas = move(newGas);
                routine = move(newRoutine);
            }
        }
        return routine;
    }
}

bigint ComputeMethod::gasNeeded(AssemblyItems const& _routine)
{
    size_t numExps = count(_routine.begin(), _routine.end(), Instruction::EXP);
    return combineGas(
        simpleRunGas(_routine) + numExps * (GasCosts::expGas + GasCosts::expByteGas),
        // Data gas for routine: Some bytes are zero, but we ignore them.
        bytesRequired(_routine) * (m_params.isCreation ? GasCosts::txDataNonZeroGas : GasCosts::createDataGas),
        0
    );
}