/***********************************************************************//**
* @brief Print test suite information
*
* @param[in] chatter Chattiness (defaults to NORMAL).
* @return String containing test suite information.
***************************************************************************/
std::string GTestSuite::print(const GChatter& chatter) const
{
// Initialise result string
std::string result;
// Continue only if chatter is not silent
if (chatter != SILENT) {
// Append header
result.append("=== GTestSuite ===");
// Append information
result.append("\n"+gammalib::parformat("Name")+m_name);
result.append("\n"+gammalib::parformat("Number of functions"));
result.append(gammalib::str(m_names.size()));
result.append("\n"+gammalib::parformat("Number of executed tests"));
result.append(gammalib::str(size()));
result.append("\n"+gammalib::parformat("Number of errors"));
result.append(gammalib::str(errors()));
result.append("\n"+gammalib::parformat("Number of failures"));
result.append(gammalib::str(failures()));
} // endif: chatter was not silent
// Return result
return result;
}
/***********************************************************************//**
* @brief Print test suites information
*
* @param[in] chatter Chattiness (defaults to NORMAL).
* @return String containing test suites information.
***************************************************************************/
std::string GTestSuites::print(const GChatter& chatter) const
{
// Initialise result string
std::string result;
// Continue only if chatter is not silent
if (chatter != SILENT) {
// Append header
result.append("=== GTestSuites ===");
// Append information
result.append("\n"+gammalib::parformat("Name")+m_name);
result.append("\n"+gammalib::parformat("Number of test suites"));
result.append(gammalib::str(size()));
result.append("\n"+gammalib::parformat("Number of tests"));
result.append(gammalib::str(tests()));
result.append("\n"+gammalib::parformat("Number of errors"));
result.append(gammalib::str(errors()));
result.append("\n"+gammalib::parformat("Number of failures"));
result.append(gammalib::str(failures()));
// Append test suites
for (int i = 0; i < size(); ++i) {
result.append("\n");
result.append((*this)[i]->print(chatter));
}
} // endif: chatter was not silent
// Return result
return result;
}
void TextTestResult::printFailures(std::ostream& stream)
{
if (testFailures() != 0)
{
stream << "\n";
if (testFailures() == 1)
stream << "There was " << testFailures() << " failure: " << std::endl;
else
stream << "There were " << testFailures() << " failures: " << std::endl;
int i = 1;
for (std::vector<TestFailure*>::iterator it = failures().begin(); it != failures().end(); ++it)
{
TestFailure* failure = *it;
CppUnitException* e = failure->thrownException();
stream << std::setw(2) << i
<< ": "
<< failure->failedTest()->toString() << "\n"
<< " \"" << (e ? e->what() : "") << "\"\n"
<< " in \""
<< (e ? e->fileName() : std::string())
<< "\", line ";
if (e == 0)
{
stream << "0";
}
else
{
stream << e->lineNumber();
if (e->data2LineNumber() != CppUnitException::CPPUNIT_UNKNOWNLINENUMBER)
{
stream << " data lines "
<< e->data1LineNumber()
<< ", " << e->data2LineNumber();
}
else if (e->data1LineNumber() != CppUnitException::CPPUNIT_UNKNOWNLINENUMBER)
{
stream << " data line " << e->data1LineNumber();
}
}
stream << "\n";
i++;
}
}
}
void TextTestResult::printFailures (std::ostream &stream)
{
if ( testFailures () != 0 ) {
if (testFailures () == 1) {
stream << "There was " << testFailures () << " failure: " << std::endl;
} else {
stream << "There were " << testFailures () << " failures: " << std::endl;
}
printCauses(stream, failures());
}
}
bool file_exists(const std::string &filename) {
int readok = access(filename.c_str(), R_OK);
if (readok == 0) {
return true;
} else {
if (errno == ENOENT) {
// File does not exist
return false;
} else {
// It exists, but we can't access it
failures("Error accessing file %s", filename.c_str());
}
}
failure("Unreachable");
}
/***********************************************************************//**
* @brief Print test suites information
***************************************************************************/
std::string GTestSuites::print(void) const
{
// Initialise result string
std::string result;
// Append header
result.append("=== GTestSuites ===");
result.append("\n"+parformat("Name")+m_name);
result.append("\n"+parformat("Number of test suites")+str(size()));
result.append("\n"+parformat("Number of tests")+str(tests()));
result.append("\n"+parformat("Number of errors")+str(errors()));
result.append("\n"+parformat("Number of failures")+str(failures()));
// Append test suites
for (int i = 0; i < size(); ++i) {
result.append("\n");
result.append((*this)[i].print());
}
// Return result
return result;
}
void TestLocalSocket::runTest(uchar dataAmnt, uchar pkgAmnt, uchar fdAmnt)
{
quint64 sendCount = 0;
quint64 sendCountPackage = 0;
quint64 sendCountData = 0;
quint64 sendCountFD = 0;
quint64 sendBytes = 0;
// Runtime for peer in seconds
int runTime = 15; // In seconds
QElapsedTimer time;
// Log timer
QElapsedTimer logTimer;
const int logInterval = 200; // In msec
logTimer.start();
printf("\tRunning %d seconds\n", runTime);
time.start();
while(m_localSocket && time.elapsed() < runTime * 1000)
{
QVERIFY2(m_localSocket->isOpen(), qPrintable(QStringLiteral("LocalSocket not open! (" + m_localSocket->errorString() + ")")));
QChar command;
uchar action;
QFile * file = 0;
QString filename;
Variant data(randomData(&action, dataAmnt, pkgAmnt, fdAmnt, &file));
// data can be invalid if we only test file descriptors as they have an limit
if(dataAmnt == 0 && pkgAmnt == 0 && !data.isValid())
break;
// randomData returned invalid data -> Error already printed
QVERIFY(data.isValid());
// Handle filename
if(file != 0)
{
filename = QFileInfo(*file).absoluteFilePath();
m_openFiles[filename] = file;
}
// if(!m_peer->m_socket->isOpen() && !m_peer->m_socket->bytesAvailable())
// {
// returnLock.lockForWrite();
// failureReason = "Socket closed";
// failureReceived = true;
// returnLock.unlock();
// }
// qDebug("Open: %s", m_peer->m_socket->isOpen() ? "true" : "false");
switch(action)
{
// Send data
case 0:
{
QByteArray dataAr(data.toByteArray());
QByteArray hash(QCryptographicHash::hash(dataAr, QCryptographicHash::Md5));
command = 'd';
// qDebug("Sending data with size %d", dataAr.size());
QVERIFY2(m_peer->writeControlData(QString(command).toLatin1() + hash.toHex() + "\n"), "Could not write data to peer!");
// size
quint32 size = qToBigEndian<quint32>(dataAr.size());
// qDebug("Size written: %d", data.size());
dataAr.prepend((const char*)&size, sizeof(size));
// static quint64 totalWrittenTest = 0;
// totalWrittenTest += data.size();
// qDebug("total-written (test): %llu", totalWrittenTest);
qint64 written = 0;
QElapsedTimer timer;
timer.start();
while(m_localSocket && m_localSocket->isOpen() && written < dataAr.size() && timer.elapsed() < 30000)
{
qint64 tmp = m_localSocket->write(dataAr.constData() + written, dataAr.size() - written);
// if(tmp < 0)
// qDebug("tmp < 0! open: %s", m_localSocket->isOpen() ? "true" : "false");
QVERIFY2(tmp >= 0, qPrintable(QStringLiteral("Could not write all data to peer! (" + m_localSocket->errorString() + ")")));
written += tmp;
// QCoreApplication::processEvents();
m_localSocket->waitForBytesWritten(3000);
}
// For debugging
// printf("\t=== Data written ===\n");
// for(int i = 0; i < data.size(); i++)
// printf("\t%02X", data.constData()[i]);
// printf("\t\n====================\n");
QVERIFY2(written == dataAr.size(), "Could not write all data to peer!");
sendCountData++;
sendBytes += dataAr.size() - sizeof(size);
dataAr.clear();
// qDebug("Sent data!");
}break;
// Send package
case 1:
{
QByteArray dataAr(data.toByteArray());
QByteArray hash(QCryptographicHash::hash(dataAr, QCryptographicHash::Md5));
command = 'p';
QVERIFY2(m_peer->writeControlData(QString(command).toLatin1() + hash.toHex() + "\n"), "Could not write data to peer!");
bool result = m_localSocket->writePackage(dataAr);
while(!result && m_localSocket->isOpen())
{
m_localSocket->waitForPackageWritten(30000);
result = m_localSocket->writePackage(dataAr);
}
QVERIFY2(result, "Could not write package!");
sendCountPackage++;
sendBytes += dataAr.size();
dataAr.clear();
// qDebug("Sent package!");
}break;
// Send file descriptor
case 2:
{
QByteArray dataAr(filename.toLatin1());
command = 's';
QVERIFY2(m_peer->writeControlData(QString(command).toLatin1() + dataAr.toHex() + "\n"), "Could not write data to peer!");
QVERIFY2(m_localSocket->writeSocketDescriptor(data.toSocketDescriptor()), "Could not write socket descriptor!");
sendCountFD++;
// qDebug("Sent socket descriptor!");
}break;
}
QCoreApplication::processEvents();
// qDebug("Sent data!");
sendCount++;
if(logTimer.elapsed() >= logInterval)
{
Logger::log("Written commands (TestLocalSocket)", sendCount);
logTimer.restart();
}
QStringList failures(m_peer->failureMessages());
QVERIFY2(failures.isEmpty(), qPrintable(QStringLiteral("Received failures:\n\t- %1").arg(failures.join("\n\t- "))));
}
Logger::log("Written commands (TestLocalSocket)", sendCount, "wB", "Waiting for bytes to be written");
printf("\tSent %llu actions (%llu data portions, %llu packages, %llu file descriptors)\n", sendCount, sendCountData, sendCountPackage, sendCountFD);
quint64 sendBytesFormatted = sendBytes;
QStringList formatter;
formatter << "b" << "KB" << "MB" << "GB" << "TB" << "PB";
int idx = 0;
while(sendBytesFormatted > 1024*10)
{
sendBytesFormatted /= 1024;
idx++;
}
printf("\tSent %llu bytes (%llu %s)\n", sendBytes, sendBytesFormatted, qPrintable(formatter[idx]));
printf("\tWaiting for results (This could take a while)\n");
while(m_localSocket && m_localSocket->isOpen() && m_localSocket->bytesToWrite())
{
QCoreApplication::processEvents();
m_localSocket->waitForBytesWritten(10000);
}
// Send close command
// qDebug("Sending close command!");
Logger::log("Written commands (TestLocalSocket)", sendCount, "sC", "Sent close command");
QVERIFY2(m_peer->writeControlData(QStringLiteral("c\n").toLatin1()), "Could not write data to peer!");
QCoreApplication::processEvents();
if(!m_peer->waitForTotalSuccessCount(sendCount, 20000))
{
QStringList failures(m_peer->failureMessages());
QVERIFY2(failures.isEmpty(), qPrintable(QStringLiteral("Received failures:\n\t- %1").arg(failures.join("\n\t- "))));
if(m_peer->totalSuccessCount() != sendCount)
Logger::log("Written commands (TestLocalSocket)", sendCount, "f", "Failed to wait for all return commands");
QVERIFY2(m_peer->totalSuccessCount() == sendCount, qPrintable(QStringLiteral("Invalid return count. Expected: %1; Got: %2").arg(sendCount).arg(m_peer->totalSuccessCount())));
}
// Check signal socketDescriptorWritten()
QList<quintptr> neededFdSignals;
foreach(QFile * file, m_openFiles.values())
neededFdSignals.append((quintptr)file->handle());
QCoreApplication::processEvents();
QList<quintptr> emittedFdSignals(m_peer->fileDescriptorSignals());
for(int i = 0; i < emittedFdSignals.count(); i++)
QVERIFY2(neededFdSignals.removeOne(emittedFdSignals[i]), qPrintable(QStringLiteral("Invalid socketDescriptorWritten() signal")));
QVERIFY2(neededFdSignals.isEmpty(), qPrintable(QStringLiteral("Missing socketDescriptorWritten() signals: %1").arg(neededFdSignals.count())));
Logger::log("Written commands (TestLocalSocket)", sendCount, "d", "Done");
}
/***********************************************************************//**
* @brief Run all tests in test suite
*
* @return True if all tests were successful, false otherwise.
*
* Executes all test functions that have been appended to the test suite.
* For each test function a test case is added to the test suite.
***************************************************************************/
bool GTestSuite::run(void)
{
// Setup the test functions. This is a pure virtual function that needs
// to be implemented in the derived class. It sets the function
// pointers and function names for all test functions that should be
// executed.
set();
// Initialise success flag
bool success = true;
// Loop over all functions in suite
for (m_index = 0; m_index < m_functions.size(); ++m_index) {
// Continue only if function is valid
if (m_functions[m_index] != NULL) {
// Save the number of errors and failures before test
// execution. We use this after the test to see if
// any failures occured.
int old_errors = errors();
int old_failures = failures();
// Log the name of the test
std::cout << m_names[m_index] << ": ";
// Create a test of error type for function testing
GTestCase* test = new GTestCase(GTestCase::ERROR_TEST, m_names[m_index]);
// Add test case to test suite
m_tests.push_back(test);
// Set start time
#ifdef _OPENMP
double t_start = omp_get_wtime();
#else
clock_t t_start = clock();
#endif
// Execute test function
try {
(this->*(m_functions[m_index]))();
}
catch (std::exception& e) {
// Signal that test did not succeed
test->has_passed(false);
// Set test message to exception message
test->message(e.what());
// Set type as class name
test->type(typeid(e).name());
}
catch (...)
{
// For other exceptions
test->has_passed(false);
test->message("Non-standard C++ exception thrown");
}
// Compute elapsed time
#ifdef _OPENMP
double t_elapse = omp_get_wtime()-t_start;
#else
double t_elapse = (double)(clock() - t_start) / (double)CLOCKS_PER_SEC;
#endif
// Set test duration
test->duration(t_elapse);
// Increment number of errors if the test did not pass
if (!test->has_passed()) {
m_errors++;
}
// Log the result (".","F" or, "E")
std::cout << test->print();
// Log if there are errors or failures
if ((m_errors == old_errors && m_failures == old_failures)) {
std::cout << " ok" << std::endl;
}
else {
std::cout << " NOK" << std::endl;
success = false;
}
} // endif: test case has a function pointer
} // endfor: looped over tests on the stack
// Reset index
m_index = 0;
// Return success flag
return success;
}
