/*
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 .
*/
/** @file TestHelper.cpp
* @author Marko Simovic
* @date 2014
*/
#include "TestHelper.h"
#include
#include
#include
#include
#include
#include "Stats.h"
using namespace std;
using namespace dev::eth;
namespace dev
{
namespace eth
{
void mine(Client& c, int numBlocks)
{
auto startBlock = c.blockChain().details().number;
c.startMining();
while(c.blockChain().details().number < startBlock + numBlocks)
std::this_thread::sleep_for(std::chrono::milliseconds(100));
c.stopMining();
}
void connectClients(Client& c1, Client& c2)
{
(void)c1;
(void)c2;
// TODO: Move to WebThree. eth::Client no longer handles networking.
#if 0
short c1Port = 20000;
short c2Port = 21000;
c1.startNetwork(c1Port);
c2.startNetwork(c2Port);
c2.connect("127.0.0.1", c1Port);
#endif
}
void mine(State& s, BlockChain const& _bc)
{
s.commitToMine(_bc);
GenericFarm f;
bool completed = false;
f.onSolutionFound([&](ProofOfWork::Solution sol)
{
return completed = s.completeMine(sol);
});
f.setWork(s.info());
f.startCPU();
while (!completed)
this_thread::sleep_for(chrono::milliseconds(20));
}
void mine(BlockInfo& _bi)
{
GenericFarm f;
bool completed = false;
f.onSolutionFound([&](ProofOfWork::Solution sol)
{
_bi.proof = sol;
return completed = true;
});
f.setWork(_bi);
f.startCPU();
while (!completed)
this_thread::sleep_for(chrono::milliseconds(20));
}
}
namespace test
{
struct ValueTooLarge: virtual Exception {};
struct MissingFields : virtual Exception {};
bigint const c_max256plus1 = bigint(1) << 256;
ImportTest::ImportTest(json_spirit::mObject& _o, bool isFiller):
m_statePre(OverlayDB(), eth::BaseState::Empty, Address(_o["env"].get_obj()["currentCoinbase"].get_str())),
m_statePost(OverlayDB(), eth::BaseState::Empty, Address(_o["env"].get_obj()["currentCoinbase"].get_str())),
m_TestObject(_o)
{
importEnv(_o["env"].get_obj());
importState(_o["pre"].get_obj(), m_statePre);
importTransaction(_o["transaction"].get_obj());
if (!isFiller)
{
importState(_o["post"].get_obj(), m_statePost);
m_environment.sub.logs = importLog(_o["logs"].get_array());
}
}
json_spirit::mObject& ImportTest::makeAllFieldsHex(json_spirit::mObject& _o)
{
static const set hashes {"bloom" , "coinbase", "hash", "mixHash", "parentHash", "receiptTrie",
"stateRoot", "transactionsTrie", "uncleHash", "currentCoinbase",
"previousHash", "to", "address", "caller", "origin", "secretKey", "data"};
for (auto& i: _o)
{
std::string key = i.first;
if (hashes.count(key))
continue;
std::string str;
json_spirit::mValue value = i.second;
if (value.type() == json_spirit::int_type)
str = toString(value.get_int());
else if (value.type() == json_spirit::str_type)
str = value.get_str();
else continue;
_o[key] = (str.substr(0, 2) == "0x") ? str : toCompactHex(toInt(str), HexPrefix::Add, 1);
}
return _o;
}
void ImportTest::importEnv(json_spirit::mObject& _o)
{
assert(_o.count("previousHash") > 0);
assert(_o.count("currentGasLimit") > 0);
assert(_o.count("currentDifficulty") > 0);
assert(_o.count("currentTimestamp") > 0);
assert(_o.count("currentCoinbase") > 0);
assert(_o.count("currentNumber") > 0);
m_environment.currentBlock.parentHash = h256(_o["previousHash"].get_str());
m_environment.currentBlock.number = toInt(_o["currentNumber"]);
m_environment.currentBlock.gasLimit = toInt(_o["currentGasLimit"]);
m_environment.currentBlock.difficulty = toInt(_o["currentDifficulty"]);
m_environment.currentBlock.timestamp = toInt(_o["currentTimestamp"]);
m_environment.currentBlock.coinbaseAddress = Address(_o["currentCoinbase"].get_str());
m_statePre.m_previousBlock = m_environment.previousBlock;
m_statePre.m_currentBlock = m_environment.currentBlock;
}
// import state from not fully declared json_spirit::mObject, writing to _stateOptionsMap which fields were defined in json
void ImportTest::importState(json_spirit::mObject& _o, State& _state, stateOptionsMap& _stateOptionsMap)
{
for (auto& i: _o)
{
json_spirit::mObject o = i.second.get_obj();
ImportStateOptions stateOptions;
u256 balance = 0;
u256 nonce = 0;
if (o.count("balance") > 0)
{
stateOptions.m_bHasBalance = true;
if (bigint(o["balance"].get_str()) >= c_max256plus1)
BOOST_THROW_EXCEPTION(ValueTooLarge() << errinfo_comment("State 'balance' is equal or greater than 2**256") );
balance = toInt(o["balance"]);
}
if (o.count("nonce") > 0)
{
stateOptions.m_bHasNonce = true;
if (bigint(o["nonce"].get_str()) >= c_max256plus1)
BOOST_THROW_EXCEPTION(ValueTooLarge() << errinfo_comment("State 'nonce' is equal or greater than 2**256") );
nonce = toInt(o["nonce"]);
}
Address address = Address(i.first);
bytes code;
if (o.count("code") > 0)
{
code = importCode(o);
stateOptions.m_bHasCode = true;
}
if (!code.empty())
{
_state.m_cache[address] = Account(balance, Account::ContractConception);
_state.m_cache[address].setCode(std::move(code));
}
else
_state.m_cache[address] = Account(balance, Account::NormalCreation);
if (o.count("storage") > 0)
{
stateOptions.m_bHasStorage = true;
for (auto const& j: o["storage"].get_obj())
_state.setStorage(address, toInt(j.first), toInt(j.second));
}
for (int i = 0; i < nonce; ++i)
_state.noteSending(address);
_state.ensureCached(address, false, false);
_stateOptionsMap[address] = stateOptions;
}
}
void ImportTest::importState(json_spirit::mObject& _o, State& _state)
{
stateOptionsMap importedMap;
importState(_o, _state, importedMap);
for (auto& stateOptionMap : importedMap)
{
//check that every parameter was declared in state object
if (!stateOptionMap.second.isAllSet())
BOOST_THROW_EXCEPTION(MissingFields() << errinfo_comment("Import State: Missing state fields!"));
}
}
void ImportTest::importTransaction(json_spirit::mObject& _o)
{
if (_o.count("secretKey") > 0)
{
assert(_o.count("nonce") > 0);
assert(_o.count("gasPrice") > 0);
assert(_o.count("gasLimit") > 0);
assert(_o.count("to") > 0);
assert(_o.count("value") > 0);
assert(_o.count("data") > 0);
if (bigint(_o["nonce"].get_str()) >= c_max256plus1)
BOOST_THROW_EXCEPTION(ValueTooLarge() << errinfo_comment("Transaction 'nonce' is equal or greater than 2**256") );
if (bigint(_o["gasPrice"].get_str()) >= c_max256plus1)
BOOST_THROW_EXCEPTION(ValueTooLarge() << errinfo_comment("Transaction 'gasPrice' is equal or greater than 2**256") );
if (bigint(_o["gasLimit"].get_str()) >= c_max256plus1)
BOOST_THROW_EXCEPTION(ValueTooLarge() << errinfo_comment("Transaction 'gasLimit' is equal or greater than 2**256") );
if (bigint(_o["value"].get_str()) >= c_max256plus1)
BOOST_THROW_EXCEPTION(ValueTooLarge() << errinfo_comment("Transaction 'value' is equal or greater than 2**256") );
m_transaction = _o["to"].get_str().empty() ?
Transaction(toInt(_o["value"]), toInt(_o["gasPrice"]), toInt(_o["gasLimit"]), importData(_o), toInt(_o["nonce"]), Secret(_o["secretKey"].get_str())) :
Transaction(toInt(_o["value"]), toInt(_o["gasPrice"]), toInt(_o["gasLimit"]), Address(_o["to"].get_str()), importData(_o), toInt(_o["nonce"]), Secret(_o["secretKey"].get_str()));
}
else
{
RLPStream transactionRLPStream = createRLPStreamFromTransactionFields(_o);
RLP transactionRLP(transactionRLPStream.out());
try
{
m_transaction = Transaction(transactionRLP.data(), CheckTransaction::Everything);
}
catch (InvalidSignature)
{
// create unsigned transaction
m_transaction = _o["to"].get_str().empty() ?
Transaction(toInt(_o["value"]), toInt(_o["gasPrice"]), toInt(_o["gasLimit"]), importData(_o), toInt(_o["nonce"])) :
Transaction(toInt(_o["value"]), toInt(_o["gasPrice"]), toInt(_o["gasLimit"]), Address(_o["to"].get_str()), importData(_o), toInt(_o["nonce"]));
}
catch (Exception& _e)
{
cnote << "invalid transaction" << boost::diagnostic_information(_e);
}
}
}
void ImportTest::checkExpectedState(State const& _stateExpect, State const& _statePost, stateOptionsMap const _expectedStateOptions, WhenError _throw)
{
#define CHECK(a,b) \
{ \
if (_throw == WhenError::Throw) \
{TBOOST_CHECK_MESSAGE(a,b);}\
else \
{TBOOST_WARN_MESSAGE(a,b);} \
}
for (auto const& a: _stateExpect.addresses())
{
CHECK(_statePost.addressInUse(a.first), "Filling Test: " << a.first << " missing expected address!");
if (_statePost.addressInUse(a.first))
{
ImportStateOptions addressOptions(true);
if(_expectedStateOptions.size())
{
try
{
addressOptions = _expectedStateOptions.at(a.first);
}
catch(std::out_of_range const&)
{
TBOOST_ERROR("expectedStateOptions map does not match expectedState in checkExpectedState!");
break;
}
}
if (addressOptions.m_bHasBalance)
CHECK((_stateExpect.balance(a.first) == _statePost.balance(a.first)),
"Check State: " << a.first << ": incorrect balance " << _statePost.balance(a.first) << ", expected " << _stateExpect.balance(a.first));
if (addressOptions.m_bHasNonce)
CHECK((_stateExpect.transactionsFrom(a.first) == _statePost.transactionsFrom(a.first)),
"Check State: " << a.first << ": incorrect nonce " << _statePost.transactionsFrom(a.first) << ", expected " << _stateExpect.transactionsFrom(a.first));
if (addressOptions.m_bHasStorage)
{
unordered_map stateStorage = _statePost.storage(a.first);
for (auto const& s: _stateExpect.storage(a.first))
CHECK((stateStorage[s.first] == s.second),
"Check State: " << a.first << ": incorrect storage [" << s.first << "] = " << toHex(stateStorage[s.first]) << ", expected [" << s.first << "] = " << toHex(s.second));
//Check for unexpected storage values
stateStorage = _stateExpect.storage(a.first);
for (auto const& s: _statePost.storage(a.first))
CHECK((stateStorage[s.first] == s.second),
"Check State: " << a.first << ": incorrect storage [" << s.first << "] = " << toHex(s.second) << ", expected [" << s.first << "] = " << toHex(stateStorage[s.first]));
}
if (addressOptions.m_bHasCode)
CHECK((_stateExpect.code(a.first) == _statePost.code(a.first)),
"Check State: " << a.first << ": incorrect code '" << toHex(_statePost.code(a.first)) << "', expected '" << toHex(_stateExpect.code(a.first)) << "'");
}
}
}
void ImportTest::exportTest(bytes const& _output, State const& _statePost)
{
// export output
m_TestObject["out"] = (_output.size() > 4096 && !Options::get().fulloutput) ? "#" + toString(_output.size()) : toHex(_output, 2, HexPrefix::Add);
// compare expected output with post output
if (m_TestObject.count("expectOut") > 0)
{
std::string warning = "Check State: Error! Unexpected output: " + m_TestObject["out"].get_str() + " Expected: " + m_TestObject["expectOut"].get_str();
if (Options::get().checkState)
{TBOOST_CHECK_MESSAGE((m_TestObject["out"].get_str() == m_TestObject["expectOut"].get_str()), warning);}
else
TBOOST_WARN_MESSAGE((m_TestObject["out"].get_str() == m_TestObject["expectOut"].get_str()), warning);
m_TestObject.erase(m_TestObject.find("expectOut"));
}
// export logs
m_TestObject["logs"] = exportLog(_statePost.pending().size() ? _statePost.log(0) : LogEntries());
// compare expected state with post state
if (m_TestObject.count("expect") > 0)
{
stateOptionsMap stateMap;
State expectState(OverlayDB(), eth::BaseState::Empty);
importState(m_TestObject["expect"].get_obj(), expectState, stateMap);
checkExpectedState(expectState, _statePost, stateMap, Options::get().checkState ? WhenError::Throw : WhenError::DontThrow);
m_TestObject.erase(m_TestObject.find("expect"));
}
// export post state
m_TestObject["post"] = fillJsonWithState(_statePost);
m_TestObject["postStateRoot"] = toHex(_statePost.rootHash().asBytes());
// export pre state
m_TestObject["pre"] = fillJsonWithState(m_statePre);
m_TestObject["env"] = makeAllFieldsHex(m_TestObject["env"].get_obj());
m_TestObject["transaction"] = makeAllFieldsHex(m_TestObject["transaction"].get_obj());
}
json_spirit::mObject fillJsonWithTransaction(Transaction _txn)
{
json_spirit::mObject txObject;
txObject["nonce"] = toCompactHex(_txn.nonce(), HexPrefix::Add, 1);
txObject["data"] = toHex(_txn.data(), 2, HexPrefix::Add);
txObject["gasLimit"] = toCompactHex(_txn.gas(), HexPrefix::Add, 1);
txObject["gasPrice"] = toCompactHex(_txn.gasPrice(), HexPrefix::Add, 1);
txObject["r"] = toCompactHex(_txn.signature().r, HexPrefix::Add, 1);
txObject["s"] = toCompactHex(_txn.signature().s, HexPrefix::Add, 1);
txObject["v"] = toCompactHex(_txn.signature().v + 27, HexPrefix::Add, 1);
txObject["to"] = _txn.isCreation() ? "" : toString(_txn.receiveAddress());
txObject["value"] = toCompactHex(_txn.value(), HexPrefix::Add, 1);
return txObject;
}
json_spirit::mObject fillJsonWithState(State _state)
{
json_spirit::mObject oState;
for (auto const& a: _state.addresses())
{
json_spirit::mObject o;
o["balance"] = toCompactHex(_state.balance(a.first), HexPrefix::Add, 1);
o["nonce"] = toCompactHex(_state.transactionsFrom(a.first), HexPrefix::Add, 1);
{
json_spirit::mObject store;
for (auto const& s: _state.storage(a.first))
store[toCompactHex(s.first, HexPrefix::Add, 1)] = toCompactHex(s.second, HexPrefix::Add, 1);
o["storage"] = store;
}
o["code"] = toHex(_state.code(a.first), 2, HexPrefix::Add);
oState[toString(a.first)] = o;
}
return oState;
}
json_spirit::mArray exportLog(eth::LogEntries _logs)
{
json_spirit::mArray ret;
if (_logs.size() == 0) return ret;
for (LogEntry const& l: _logs)
{
json_spirit::mObject o;
o["address"] = toString(l.address);
json_spirit::mArray topics;
for (auto const& t: l.topics)
topics.push_back(toString(t));
o["topics"] = topics;
o["data"] = toHex(l.data, 2, HexPrefix::Add);
o["bloom"] = toString(l.bloom());
ret.push_back(o);
}
return ret;
}
u256 toInt(json_spirit::mValue const& _v)
{
switch (_v.type())
{
case json_spirit::str_type: return u256(_v.get_str());
case json_spirit::int_type: return (u256)_v.get_uint64();
case json_spirit::bool_type: return (u256)(uint64_t)_v.get_bool();
case json_spirit::real_type: return (u256)(uint64_t)_v.get_real();
default: cwarn << "Bad type for scalar: " << _v.type();
}
return 0;
}
byte toByte(json_spirit::mValue const& _v)
{
switch (_v.type())
{
case json_spirit::str_type: return (byte)stoi(_v.get_str());
case json_spirit::int_type: return (byte)_v.get_uint64();
case json_spirit::bool_type: return (byte)_v.get_bool();
case json_spirit::real_type: return (byte)_v.get_real();
default: cwarn << "Bad type for scalar: " << _v.type();
}
return 0;
}
bytes importByteArray(std::string const& _str)
{
return fromHex(_str.substr(0, 2) == "0x" ? _str.substr(2) : _str, WhenError::Throw);
}
bytes importData(json_spirit::mObject& _o)
{
bytes data;
if (_o["data"].type() == json_spirit::str_type)
data = importByteArray(_o["data"].get_str());
else
for (auto const& j: _o["data"].get_array())
data.push_back(toByte(j));
return data;
}
bytes importCode(json_spirit::mObject& _o)
{
bytes code;
if (_o["code"].type() == json_spirit::str_type)
if (_o["code"].get_str().find("0x") != 0)
code = compileLLL(_o["code"].get_str(), false);
else
code = fromHex(_o["code"].get_str().substr(2));
else if (_o["code"].type() == json_spirit::array_type)
{
code.clear();
for (auto const& j: _o["code"].get_array())
code.push_back(toByte(j));
}
return code;
}
LogEntries importLog(json_spirit::mArray& _a)
{
LogEntries logEntries;
for (auto const& l: _a)
{
json_spirit::mObject o = l.get_obj();
// cant use BOOST_REQUIRE, because this function is used outside boost test (createRandomTest)
assert(o.count("address") > 0);
assert(o.count("topics") > 0);
assert(o.count("data") > 0);
assert(o.count("bloom") > 0);
LogEntry log;
log.address = Address(o["address"].get_str());
for (auto const& t: o["topics"].get_array())
log.topics.push_back(h256(t.get_str()));
log.data = importData(o);
logEntries.push_back(log);
}
return logEntries;
}
void checkOutput(bytes const& _output, json_spirit::mObject& _o)
{
int j = 0;
if (_o["out"].get_str().find("#") == 0)
{TBOOST_CHECK(((u256)_output.size() == toInt(_o["out"].get_str().substr(1))));}
else if (_o["out"].type() == json_spirit::array_type)
for (auto const& d: _o["out"].get_array())
{
TBOOST_CHECK_MESSAGE((_output[j] == toInt(d)), "Output byte [" << j << "] different!");
++j;
}
else if (_o["out"].get_str().find("0x") == 0)
{TBOOST_CHECK((_output == fromHex(_o["out"].get_str().substr(2))));}
else
TBOOST_CHECK((_output == fromHex(_o["out"].get_str())));
}
void checkStorage(map _expectedStore, map _resultStore, Address _expectedAddr)
{
_expectedAddr = _expectedAddr; //unsed parametr when macro
for (auto&& expectedStorePair : _expectedStore)
{
auto& expectedStoreKey = expectedStorePair.first;
auto resultStoreIt = _resultStore.find(expectedStoreKey);
if (resultStoreIt == _resultStore.end())
{TBOOST_ERROR(_expectedAddr << ": missing store key " << expectedStoreKey);}
else
{
auto& expectedStoreValue = expectedStorePair.second;
auto& resultStoreValue = resultStoreIt->second;
TBOOST_CHECK_MESSAGE((expectedStoreValue == resultStoreValue), _expectedAddr << ": store[" << expectedStoreKey << "] = " << resultStoreValue << ", expected " << expectedStoreValue);
}
}
TBOOST_CHECK_EQUAL(_resultStore.size(), _expectedStore.size());
for (auto&& resultStorePair: _resultStore)
{
if (!_expectedStore.count(resultStorePair.first))
TBOOST_ERROR(_expectedAddr << ": unexpected store key " << resultStorePair.first);
}
}
void checkLog(LogEntries _resultLogs, LogEntries _expectedLogs)
{
TBOOST_REQUIRE_EQUAL(_resultLogs.size(), _expectedLogs.size());
for (size_t i = 0; i < _resultLogs.size(); ++i)
{
TBOOST_CHECK_EQUAL(_resultLogs[i].address, _expectedLogs[i].address);
TBOOST_CHECK_EQUAL(_resultLogs[i].topics, _expectedLogs[i].topics);
TBOOST_CHECK((_resultLogs[i].data == _expectedLogs[i].data));
}
}
void checkCallCreates(eth::Transactions _resultCallCreates, eth::Transactions _expectedCallCreates)
{
TBOOST_REQUIRE_EQUAL(_resultCallCreates.size(), _expectedCallCreates.size());
for (size_t i = 0; i < _resultCallCreates.size(); ++i)
{
TBOOST_CHECK((_resultCallCreates[i].data() == _expectedCallCreates[i].data()));
TBOOST_CHECK((_resultCallCreates[i].receiveAddress() == _expectedCallCreates[i].receiveAddress()));
TBOOST_CHECK((_resultCallCreates[i].gas() == _expectedCallCreates[i].gas()));
TBOOST_CHECK((_resultCallCreates[i].value() == _expectedCallCreates[i].value()));
}
}
void userDefinedTest(std::function doTests)
{
if (!Options::get().singleTest)
return;
if (Options::get().singleTestFile.empty() || Options::get().singleTestName.empty())
{
cnote << "Missing user test specification\nUsage: testeth --singletest \n";
return;
}
auto& filename = Options::get().singleTestFile;
auto& testname = Options::get().singleTestName;
VerbosityHolder sentinel(12);
try
{
cnote << "Testing user defined test: " << filename;
json_spirit::mValue v;
string s = contentsString(filename);
TBOOST_REQUIRE_MESSAGE((s.length() > 0), "Contents of " + filename + " is empty. ");
json_spirit::read_string(s, v);
json_spirit::mObject oSingleTest;
json_spirit::mObject::const_iterator pos = v.get_obj().find(testname);
if (pos == v.get_obj().end())
{
cnote << "Could not find test: " << testname << " in " << filename << "\n";
return;
}
else
oSingleTest[pos->first] = pos->second;
json_spirit::mValue v_singleTest(oSingleTest);
doTests(v_singleTest, test::Options::get().fillTests);
}
catch (Exception const& _e)
{
TBOOST_ERROR("Failed Test with Exception: " << diagnostic_information(_e));
}
catch (std::exception const& _e)
{
TBOOST_ERROR("Failed Test with Exception: " << _e.what());
}
}
void executeTests(const string& _name, const string& _testPathAppendix, const boost::filesystem::path _pathToFiller, std::function doTests)
{
string testPath = getTestPath();
testPath += _testPathAppendix;
if (Options::get().stats)
Listener::registerListener(Stats::get());
if (Options::get().fillTests)
{
try
{
cnote << "Populating tests...";
json_spirit::mValue v;
boost::filesystem::path p(__FILE__);
string s = asString(dev::contents(_pathToFiller.string() + "/" + _name + "Filler.json"));
TBOOST_REQUIRE_MESSAGE((s.length() > 0), "Contents of " + _pathToFiller.string() + "/" + _name + "Filler.json is empty.");
json_spirit::read_string(s, v);
doTests(v, true);
writeFile(testPath + "/" + _name + ".json", asBytes(json_spirit::write_string(v, true)));
}
catch (Exception const& _e)
{
TBOOST_ERROR("Failed filling test with Exception: " << diagnostic_information(_e));
}
catch (std::exception const& _e)
{
TBOOST_ERROR("Failed filling test with Exception: " << _e.what());
}
}
try
{
std::cout << "TEST " << _name << ":\n";
json_spirit::mValue v;
string s = asString(dev::contents(testPath + "/" + _name + ".json"));
TBOOST_REQUIRE_MESSAGE((s.length() > 0), "Contents of " + testPath + "/" + _name + ".json is empty. Have you cloned the 'tests' repo branch develop and set ETHEREUM_TEST_PATH to its path?");
json_spirit::read_string(s, v);
Listener::notifySuiteStarted(_name);
doTests(v, false);
}
catch (Exception const& _e)
{
TBOOST_ERROR("Failed test with Exception: " << diagnostic_information(_e));
}
catch (std::exception const& _e)
{
TBOOST_ERROR("Failed test with Exception: " << _e.what());
}
}
RLPStream createRLPStreamFromTransactionFields(json_spirit::mObject& _tObj)
{
//Construct Rlp of the given transaction
RLPStream rlpStream;
rlpStream.appendList(_tObj.size());
if (_tObj.count("nonce"))
rlpStream << bigint(_tObj["nonce"].get_str());
if (_tObj.count("gasPrice"))
rlpStream << bigint(_tObj["gasPrice"].get_str());
if (_tObj.count("gasLimit"))
rlpStream << bigint(_tObj["gasLimit"].get_str());
if (_tObj.count("to"))
{
if (_tObj["to"].get_str().empty())
rlpStream << "";
else
rlpStream << importByteArray(_tObj["to"].get_str());
}
if (_tObj.count("value"))
rlpStream << bigint(_tObj["value"].get_str());
if (_tObj.count("data"))
rlpStream << importData(_tObj);
if (_tObj.count("v"))
rlpStream << bigint(_tObj["v"].get_str());
if (_tObj.count("r"))
rlpStream << bigint(_tObj["r"].get_str());
if (_tObj.count("s"))
rlpStream << bigint(_tObj["s"].get_str());
if (_tObj.count("extrafield"))
rlpStream << bigint(_tObj["extrafield"].get_str());
return rlpStream;
}
Options::Options()
{
auto argc = boost::unit_test::framework::master_test_suite().argc;
auto argv = boost::unit_test::framework::master_test_suite().argv;
for (auto i = 0; i < argc; ++i)
{
auto arg = std::string{argv[i]};
if (arg == "--vm" && i + 1 < argc)
{
string vmKind = argv[++i];
if (vmKind == "interpreter")
VMFactory::setKind(VMKind::Interpreter);
else if (vmKind == "jit")
VMFactory::setKind(VMKind::JIT);
else if (vmKind == "smart")
VMFactory::setKind(VMKind::Smart);
else
cerr << "Unknown VM kind: " << vmKind << endl;
}
else if (arg == "--jit") // TODO: Remove deprecated option "--jit"
VMFactory::setKind(VMKind::JIT);
else if (arg == "--vmtrace")
vmtrace = true;
else if (arg == "--filltests")
fillTests = true;
else if (arg == "--stats" && i + 1 < argc)
{
stats = true;
statsOutFile = argv[i + 1];
}
else if (arg == "--performance")
performance = true;
else if (arg == "--quadratic")
quadratic = true;
else if (arg == "--memory")
memory = true;
else if (arg == "--inputlimits")
inputLimits = true;
else if (arg == "--bigdata")
bigData = true;
else if (arg == "--checkstate")
checkState = true;
else if (arg == "--wallet")
wallet = true;
else if (arg == "--nonetwork")
nonetwork = true;
else if (arg == "--network")
nonetwork = false;
else if (arg == "--nodag")
nodag = true;
else if (arg == "--all")
{
performance = true;
quadratic = true;
memory = true;
inputLimits = true;
bigData = true;
wallet = true;
}
else if (arg == "--singletest" && i + 1 < argc)
{
singleTest = true;
auto name1 = std::string{argv[i + 1]};
if (i + 1 < argc) // two params
{
auto name2 = std::string{argv[i + 2]};
if (name2[0] == '-') // not param, another option
singleTestName = std::move(name1);
else
{
singleTestFile = std::move(name1);
singleTestName = std::move(name2);
}
}
else
singleTestName = std::move(name1);
}
else if (arg == "--fulloutput")
fulloutput = true;
}
}
Options const& Options::get()
{
static Options instance;
return instance;
}
LastHashes lastHashes(u256 _currentBlockNumber)
{
LastHashes ret;
for (u256 i = 1; i <= 256 && i <= _currentBlockNumber; ++i)
ret.push_back(sha3(toString(_currentBlockNumber - i)));
return ret;
}
namespace
{
Listener* g_listener;
}
void Listener::registerListener(Listener& _listener)
{
g_listener = &_listener;
}
void Listener::notifySuiteStarted(std::string const& _name)
{
if (g_listener)
g_listener->suiteStarted(_name);
}
void Listener::notifyTestStarted(std::string const& _name)
{
if (g_listener)
g_listener->testStarted(_name);
}
void Listener::notifyTestFinished()
{
if (g_listener)
g_listener->testFinished();
}
} } // namespaces