ethminer/test/fuzzTesting/fuzzHelper.cpp


								/*

									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 fuzzHelper.cpp

								 * @author Dimitry Khokhlov <winsvega@mail.ru>

								 * @date 2015

								 */


								#include "fuzzHelper.h"


								#include <chrono>

								#include <boost/random.hpp>

								#include <boost/filesystem/path.hpp>

								#include <libevmcore/Instruction.h>


								namespace dev

								{

								namespace test

								{


								boost::random::mt19937 RandomCode::gen;

								boostIntDistrib RandomCode::opCodeDist = boostIntDistrib (0, 255);

								boostIntDistrib RandomCode::opLengDist = boostIntDistrib (1, 32);

								boostIntDistrib RandomCode::uniIntDist = boostIntDistrib (0, 0x7fffffff);

								boostUint64Distrib RandomCode::uInt64Dist = boostUint64Distrib (0, std::numeric_limits<uint64_t>::max());


								boostIntGenerator RandomCode::randOpCodeGen = boostIntGenerator(gen, opCodeDist);

								boostIntGenerator RandomCode::randOpLengGen = boostIntGenerator(gen, opLengDist);

								boostIntGenerator RandomCode::randUniIntGen = boostIntGenerator(gen, uniIntDist);

								boostUInt64Generator RandomCode::randUInt64Gen = boostUInt64Generator(gen, uInt64Dist);


								std::string RandomCode::rndByteSequence(int _length, SizeStrictness _sizeType)

								{

									refreshSeed();

									std::string hash;

									_length = (_sizeType == SizeStrictness::Strict) ? std::max(1, _length) : randomUniInt() % _length;

									for (auto i = 0; i < _length; i++)

									{

										uint8_t byte = randOpCodeGen();

										hash += toCompactHex(byte, HexPrefix::DontAdd, 1);

									}

									return hash;

								}


								//generate smart random code

								std::string RandomCode::generate(int _maxOpNumber, RandomCodeOptions _options)

								{

									refreshSeed();

									std::string code;


									//random opCode amount

									boostIntDistrib sizeDist (0, _maxOpNumber);

									boostIntGenerator rndSizeGen(gen, sizeDist);

									int size = (int)rndSizeGen();


									boostWeightGenerator randOpCodeWeight (gen, _options.opCodeProbability);

									bool weightsDefined = _options.opCodeProbability.probabilities().size() == 255;


									for (auto i = 0; i < size; i++)

									{

										uint8_t opcode = weightsDefined ? randOpCodeWeight() : randOpCodeGen();

										dev::eth::InstructionInfo info = dev::eth::instructionInfo((dev::eth::Instruction) opcode);


										if (info.name.find_first_of("INVALID_INSTRUCTION") > 0)

										{

											//Byte code is yet not implemented

											if (_options.useUndefinedOpCodes == false)

											{

												i--;

												continue;

											}

										}

										else

											code += fillArguments((dev::eth::Instruction) opcode, _options);

										std::string byte = toCompactHex(opcode);

										code += (byte == "") ? "00" : byte;

									}

									return code;

								}


								std::string RandomCode::randomUniIntHex(u256 _maxVal)

								{

									if (_maxVal == 0)

										_maxVal = std::numeric_limits<uint64_t>::max();

									refreshSeed();

									int rand = randUniIntGen() % 100;

									if (rand < 50)

										return "0x" + toCompactHex((u256)randUniIntGen() % _maxVal);

									return "0x" + toCompactHex((u256)randUInt64Gen() % _maxVal);

								}


								int RandomCode::randomUniInt()

								{

									refreshSeed();

									return (int)randUniIntGen();

								}


								void RandomCode::refreshSeed()

								{

									auto now = std::chrono::steady_clock::now().time_since_epoch();

									auto timeSinceEpoch = std::chrono::duration_cast<std::chrono::nanoseconds>(now).count();

									gen.seed(static_cast<unsigned int>(timeSinceEpoch));

								}


								std::string RandomCode::getPushCode(std::string const& _hex)

								{

									int length = _hex.length() / 2;

									int pushCode = 96 + length - 1;

									return toCompactHex(pushCode) + _hex;

								}


								std::string RandomCode::getPushCode(int _value)

								{

									std::string hexString = toCompactHex(_value);

									return getPushCode(hexString);

								}


								std::string RandomCode::fillArguments(dev::eth::Instruction _opcode, RandomCodeOptions const& _options)

								{

									dev::eth::InstructionInfo info = dev::eth::instructionInfo(_opcode);


									std::string code;

									bool smart = false;

									unsigned num = info.args;

									int rand = randUniIntGen() % 100;

									if (rand < _options.smartCodeProbability)

										smart = true;


									if (smart)

									{

										switch (_opcode)

										{

										case dev::eth::Instruction::CALL:

											//(CALL gaslimit address value memstart1 memlen1 memstart2 memlen2)

											code += getPushCode(randUniIntGen() % 32);  //memlen2

											code += getPushCode(randUniIntGen() % 32);  //memstart2

											code += getPushCode(randUniIntGen() % 32);  //memlen1

											code += getPushCode(randUniIntGen() % 32);  //memlen1

											code += getPushCode(randUniIntGen());		//value

											code += getPushCode(toString(_options.getRandomAddress()));//address

											code += getPushCode(randUniIntGen());		//gaslimit

										break;

										default:

											smart = false;

										}

									}


									if (smart == false)

									for (unsigned i = 0; i < num; i++)

									{

										//generate random parameters

										int length = randOpLengGen();

										code += getPushCode(rndByteSequence(length));

									}

									return code;

								}


								//Ramdom Code Options

								RandomCodeOptions::RandomCodeOptions() : useUndefinedOpCodes(false), smartCodeProbability(50)

								{

									//each op code with same weight-probability

									for (auto i = 0; i < 255; i++)

										mapWeights.insert(std::pair<int, int>(i, 50));

									setWeights();

								}


								void RandomCodeOptions::setWeight(dev::eth::Instruction _opCode, int _weight)

								{

									mapWeights.at((int)_opCode) = _weight;

									setWeights();

								}


								void RandomCodeOptions::addAddress(dev::Address const& _address)

								{

									addressList.push_back(_address);

								}


								dev::Address RandomCodeOptions::getRandomAddress() const

								{

									if (addressList.size() > 0)

									{

										int index = RandomCode::randomUniInt() % addressList.size();

										return addressList[index];

									}

									return Address(RandomCode::rndByteSequence(20));

								}


								void RandomCodeOptions::setWeights()

								{

									std::vector<int> weights;

									for (auto const& element: mapWeights)

										weights.push_back(element.second);

									opCodeProbability = boostDescreteDistrib(weights);

								}


								BOOST_AUTO_TEST_SUITE(RandomCodeTests)


								BOOST_AUTO_TEST_CASE(rndCode)

								{

									std::string code;

									std::cerr << "Testing Random Code: ";

									try

									{

										code = dev::test::RandomCode::generate(10);

									}

									catch(...)

									{

										BOOST_ERROR("Exception thrown when generating random code!");

									}

									std::cerr << code;

								}


								BOOST_AUTO_TEST_SUITE_END()


								}

								}