int main(int argc, char** argv) {
std::string arg;
std::vector<std::string> args(argc - 1 > 1 ? argc - 1 : 1);
args[0] = "all";
for (int ix = 1; ix < argc; ix++) {
args[ix - 1] = std::string(argv[ix]);
}
if (getenv("VALGRIND") != 0) {
// lower the scale of every test
WEIGHT = 1;
}
bool runAll = args[0].compare("all") == 0;
if (runAll || args[0].compare("thread-factory") == 0) {
ThreadFactoryTests threadFactoryTests;
std::cout << "ThreadFactory tests..." << std::endl;
int reapLoops = 2 * WEIGHT;
int reapCount = 100 * WEIGHT;
size_t floodLoops = 3;
size_t floodCount = 500 * WEIGHT;
std::cout << "\t\tThreadFactory reap N threads test: N = " << reapLoops << "x" << reapCount << std::endl;
if (!threadFactoryTests.reapNThreads(reapLoops, reapCount)) {
std::cerr << "\t\ttThreadFactory reap N threads FAILED" << std::endl;
return 1;
}
std::cout << "\t\tThreadFactory flood N threads test: N = " << floodLoops << "x" << floodCount << std::endl;
if (!threadFactoryTests.floodNTest(floodLoops, floodCount)) {
std::cerr << "\t\ttThreadFactory flood N threads FAILED" << std::endl;
return 1;
}
std::cout << "\t\tThreadFactory synchronous start test" << std::endl;
if (!threadFactoryTests.synchStartTest()) {
std::cerr << "\t\ttThreadFactory synchronous start FAILED" << std::endl;
return 1;
}
std::cout << "\t\tThreadFactory monitor timeout test" << std::endl;
if (!threadFactoryTests.monitorTimeoutTest()) {
std::cerr << "\t\ttThreadFactory monitor timeout FAILED" << std::endl;
return 1;
}
}
if (runAll || args[0].compare("util") == 0) {
std::cout << "Util tests..." << std::endl;
std::cout << "\t\tUtil minimum time" << std::endl;
int64_t time00 = Util::currentTime();
int64_t time01 = Util::currentTime();
std::cout << "\t\t\tMinimum time: " << time01 - time00 << "ms" << std::endl;
time00 = Util::currentTime();
time01 = time00;
size_t count = 0;
while (time01 < time00 + 10) {
count++;
time01 = Util::currentTime();
}
std::cout << "\t\t\tscall per ms: " << count / (time01 - time00) << std::endl;
}
if (runAll || args[0].compare("timer-manager") == 0) {
std::cout << "TimerManager tests..." << std::endl;
std::cout << "\t\tTimerManager test00" << std::endl;
TimerManagerTests timerManagerTests;
if (!timerManagerTests.test00()) {
std::cerr << "\t\tTimerManager tests FAILED" << std::endl;
return 1;
}
std::cout << "\t\tTimerManager test01" << std::endl;
if (!timerManagerTests.test01()) {
std::cerr << "\t\tTimerManager tests FAILED" << std::endl;
return 1;
}
std::cout << "\t\tTimerManager test02" << std::endl;
if (!timerManagerTests.test02()) {
std::cerr << "\t\tTimerManager tests FAILED" << std::endl;
return 1;
}
}
if (runAll || args[0].compare("thread-manager") == 0) {
std::cout << "ThreadManager tests..." << std::endl;
{
size_t workerCount = 10 * WEIGHT;
size_t taskCount = 500 * WEIGHT;
int64_t delay = 10LL;
ThreadManagerTests threadManagerTests;
std::cout << "\t\tThreadManager api test:" << std::endl;
if (!threadManagerTests.apiTest()) {
std::cerr << "\t\tThreadManager apiTest FAILED" << std::endl;
return 1;
}
std::cout << "\t\tThreadManager load test: worker count: " << workerCount
<< " task count: " << taskCount << " delay: " << delay << std::endl;
if (!threadManagerTests.loadTest(taskCount, delay, workerCount)) {
std::cerr << "\t\tThreadManager loadTest FAILED" << std::endl;
return 1;
}
std::cout << "\t\tThreadManager block test: worker count: " << workerCount
<< " delay: " << delay << std::endl;
if (!threadManagerTests.blockTest(delay, workerCount)) {
std::cerr << "\t\tThreadManager blockTest FAILED" << std::endl;
return 1;
}
}
}
if (runAll || args[0].compare("thread-manager-benchmark") == 0) {
std::cout << "ThreadManager benchmark tests..." << std::endl;
{
size_t minWorkerCount = 2;
size_t maxWorkerCount = 8;
size_t tasksPerWorker = 100 * WEIGHT;
int64_t delay = 5LL;
for (size_t workerCount = minWorkerCount; workerCount <= maxWorkerCount; workerCount *= 4) {
size_t taskCount = workerCount * tasksPerWorker;
std::cout << "\t\tThreadManager load test: worker count: " << workerCount
<< " task count: " << taskCount << " delay: " << delay << std::endl;
ThreadManagerTests threadManagerTests;
if (!threadManagerTests.loadTest(taskCount, delay, workerCount))
{
std::cerr << "\t\tThreadManager loadTest FAILED" << std::endl;
return 1;
}
}
}
}
std::cout << "ALL TESTS PASSED" << std::endl;
return 0;
}
int main(int argc, char** argv) {
std::string arg;
std::vector<std::string> args(argc - 1 > 1 ? argc - 1 : 1);
args[0] = "all";
for (int ix = 1; ix < argc; ix++) {
args[ix - 1] = std::string(argv[ix]);
}
bool runAll = args[0].compare("all") == 0;
if (runAll || args[0].compare("thread-factory") == 0) {
ThreadFactoryTests threadFactoryTests;
std::cout << "ThreadFactory tests..." << std::endl;
size_t count = 1000;
size_t floodLoops = 1;
size_t floodCount = 100000;
std::cout << "\t\tThreadFactory reap N threads test: N = " << count << std::endl;
assert(threadFactoryTests.reapNThreads(count));
std::cout << "\t\tThreadFactory floodN threads test: N = " << floodCount << std::endl;
assert(threadFactoryTests.floodNTest(floodLoops, floodCount));
std::cout << "\t\tThreadFactory synchronous start test" << std::endl;
assert(threadFactoryTests.synchStartTest());
std::cout << "\t\tThreadFactory monitor timeout test" << std::endl;
assert(threadFactoryTests.monitorTimeoutTest());
}
if (runAll || args[0].compare("util") == 0) {
std::cout << "Util tests..." << std::endl;
std::cout << "\t\tUtil minimum time" << std::endl;
int64_t time00 = Util::currentTime();
int64_t time01 = Util::currentTime();
std::cout << "\t\t\tMinimum time: " << time01 - time00 << "ms" << std::endl;
time00 = Util::currentTime();
time01 = time00;
size_t count = 0;
while (time01 < time00 + 10) {
count++;
time01 = Util::currentTime();
}
std::cout << "\t\t\tscall per ms: " << count / (time01 - time00) << std::endl;
}
if (runAll || args[0].compare("timer-manager") == 0) {
std::cout << "TimerManager tests..." << std::endl;
std::cout << "\t\tTimerManager test00" << std::endl;
TimerManagerTests timerManagerTests;
assert(timerManagerTests.test00());
}
if (runAll || args[0].compare("thread-manager") == 0) {
std::cout << "ThreadManager tests..." << std::endl;
{
size_t workerCount = 100;
size_t taskCount = 100000;
int64_t delay = 10LL;
std::cout << "\t\tThreadManager load test: worker count: " << workerCount << " task count: " << taskCount << " delay: " << delay << std::endl;
ThreadManagerTests threadManagerTests;
assert(threadManagerTests.loadTest(taskCount, delay, workerCount));
std::cout << "\t\tThreadManager block test: worker count: " << workerCount << " delay: " << delay << std::endl;
assert(threadManagerTests.blockTest(delay, workerCount));
}
}
if (runAll || args[0].compare("thread-manager-benchmark") == 0) {
std::cout << "ThreadManager benchmark tests..." << std::endl;
{
size_t minWorkerCount = 2;
size_t maxWorkerCount = 512;
size_t tasksPerWorker = 1000;
int64_t delay = 10LL;
for (size_t workerCount = minWorkerCount; workerCount < maxWorkerCount; workerCount*= 2) {
size_t taskCount = workerCount * tasksPerWorker;
std::cout << "\t\tThreadManager load test: worker count: " << workerCount << " task count: " << taskCount << " delay: " << delay << std::endl;
ThreadManagerTests threadManagerTests;
threadManagerTests.loadTest(taskCount, delay, workerCount);
}
}
}
}
