void run() {
while (1) {
unique_lock<mutex> sqlLock(sqlMutex);
cout << this_thread::get_id() << ": waiting until sqlQueue is NOT empty " << sqlQueue.size() << endl;
sqlCond.wait(sqlLock, []{ return !sqlQueue.empty(); } );
string sql = sqlQueue.front();
sqlQueue.pop();
sqlLock.unlock();
cout << this_thread::get_id() << ": working on sql=" << sql << endl;
string res = "";
if (0 != exec(sql, res)) {
cout << this_thread::get_id() << ": failed with error=" << m_error << endl;
res = "failed with error="+m_error;
}
unique_lock<mutex> resultLock(resultMutex);
cout << this_thread::get_id() << ": setting result to resultQueue, now size=" << resultQueue.size() << endl;
resultQueue.emplace(res);
resultLock.unlock();
resultCond.notify_one();
}
}
void conn_get(tcp::iostream *&stream) {
#if USE_CONN_POOL
{
unique_lock<mutex> lock(_conn_mutex);
while (_conns.size() == 0 && _n_conn_alloc >= CONN_MAX) {
_conn_avail_cv.wait(lock);
}
if (_conns.size() > 0) {
stream = _conns.back();
_conns.pop_back();
} else if (_n_conn_alloc < CONN_MAX) {
++ _n_conn_alloc;
stream = new tcp::iostream();
lock.unlock();
stream->connect("127.0.0.1", "1481");
}
}
#else
_conn_mutex.lock();
if (_fb_conn == NULL) {
_fb_conn = new tcp::iostream();
_fb_conn->connect("127.0.0.1", "1481");
}
stream = _fb_conn;
#endif
}
int main() {
thread t1(erzeuger1);
thread t2(erzeuger2);
thread t3(verbraucher);
thread t4(watcher);
unique_lock<mutex> sperre2(m);
cout << "\n";
condivar.notify_one();
condivar.wait(sperre2);
//t1.detach(); mit detach wird der thread asugeführt ohen berücksichtigung der anderer Threads
t1.join();
t2.join(); //mit join() wird gewartet
t3.join();
t4.join();
system("PAUSE");
}
void worker( void )
{
while( true ){
int data;
{
// unique_lockではコンストラクタでロックを取得し、デストラクタでロックを解除する。
// また、明示的にロック、アンロックが可能である。
unique_lock<mutex> lk(queue_mutex);
// キューにデータがない場合はキューにデータが追加されたことが
// 通知されるまで待つ。CPUを余分に消費することがない。
while( v_queue.empty() ){
// waitを呼ぶ前にはlkがロック状態でなければならない。
// C++11でもspurious wakeupの問題があることに注意。
// ここでready_cond.notify_one()が呼ばれるまでブロックする。
// ready_cond.notify_one()が呼ばれると、再びロックを取得した状態で、この関数から抜ける。
ready_cond.wait(lk);
}
//
data = v_queue.front();
v_queue.pop();
}
lock_guard<mutex> l(print_mutex);
printf( "%p %d\n", this_thread::get_id(), data );
fflush( stdout );
}
}
void work(int serial, int &value, condition_variable &c, mutex &m, int &turn)
{
while (1) {
{
unique_lock w{m};
// ожидаем наступления события turn == serial
c.wait(w, [&turn, &serial]() { return turn == serial; });
}
if (value >= 1000) {
lock_guard w{m};
turn = (turn + 1) % 2;
c.notify_all();
break;
}
cout << serial << " " << value << endl;
++value;
{
lock_guard w{m};
turn = (turn + 1) % 2;
c.notify_all();
}
}
}
void WriteLock() {
unique_lock<mutex> lk(mtx);
writerQ.wait(lk, [this] { return !(is_writing || readers > 0); } );
is_writing = true;
lk.unlock();
}
static void filter()
{
size_t filterCount = 0;
for (;;) {
unique_lock<mutex> filterLock(sync);
step2Condition.wait(filterLock, []() {return !nums.empty() || count == NUM_COUNT; });
if (nums.empty()) {
break;
}
int front = nums.front();
if (front % 3 != 0 && front % 13 != 0) {
filteredNums.push_back(front);
filterCount++;
}
nums.erase(nums.begin(), nums.begin() + 1);
filterLock.unlock();
}
step3Condition.notify_all();
// Print trace of consumption
//lock_guard<mutex> out(print);
//cout << "Step 2 thread done -- filtered: " << filterCount << endl;
}
static void output(size_t remainderBase)
{
// Create out file
ofstream outF("output" + to_string(remainderBase) + ".txt");
size_t outputCount = 0;
for (;;) {
// Get lock for sync mutex; Wait for step 2
unique_lock<mutex> outputLock(sync);
if (filteredNums.empty()) break;
step3Condition.wait(outputLock, []() {return !filteredNums.empty(); });
if (filteredNums.empty()) break;
// Get modulus
if (!filteredNums.empty() && filteredNums[0] % FILE_FILTER_COUNT == remainderBase) {
// Write to file
outputCount++;
outF << filteredNums[0] << endl;
filteredNums.erase(filteredNums.begin(), filteredNums.begin() + 1);
}
outputLock.unlock();
}
// print stuff
lock_guard<mutex> out(print);
cout << "Group " << remainderBase << " has " << outputCount << " numbers" << endl;
}
bool EnterStepping(std::function<void()> callback) {
lock_guard guard(pauseLock);
if (coreState != CORE_RUNNING && coreState != CORE_NEXTFRAME) {
// Shutting down, don't try to step.
return false;
}
if (!gpuDebug) {
return false;
}
gpuDebug->NotifySteppingEnter();
// Just to be sure.
if (pauseAction == PAUSE_CONTINUE) {
pauseAction = PAUSE_BREAK;
}
isStepping = true;
callback();
do {
RunPauseAction();
pauseWait.wait(pauseLock);
} while (pauseAction != PAUSE_CONTINUE);
gpuDebug->NotifySteppingExit();
isStepping = false;
return true;
}
void pub_func(const po::variables_map vm) {
context_t ctxt(1);
socket_t pub(ctxt, ZMQ_PUB);
zmq_socket_monitor(pub, "inproc://monitor.pub", ZMQ_EVENT_ALL);
thread monitor_thread(monitor_func, ref(ctxt), "inproc://monitor.pub", "pub", ref(pubDoneFlag));
std::string payload(vm["size"].as<size_t>(), '.');
if (vm.count("no-linger")) {
int linger = 0;
pub.setsockopt(ZMQ_LINGER, &linger, sizeof(linger));
}
if (vm.count("sndhwm")) {
auto sndhwm = vm["sndhwm"].as<int>();
pub.setsockopt(ZMQ_SNDHWM, &sndhwm, sizeof(sndhwm));
}
pub.bind("tcp://*:4404");
{
unique_lock<mutex> lock(subReadyMutex);
while(subReadyFlag == false)
subReadyCond.wait(lock);
}
for(size_t pubCount=0; pubCount<vm["count"].as<size_t>(); ++pubCount) {
for(size_t partNo=1; partNo<vm["parts"].as<size_t>(); ++partNo)
assert(pub.send(payload.data(), payload.size(), ZMQ_SNDMORE)==payload.size());
assert(pub.send(payload.data(), payload.size())==payload.size());
}
this_thread::sleep_for(chrono::seconds(vm["recovery-time"].as<long>()));
for(size_t pubCount=0; pubCount<vm["recovery-count"].as<size_t>(); ++pubCount) {
if (vm["recovery-rate"].as<size_t>() > 0)
this_thread::sleep_for(chrono::milliseconds(1000/vm["recovery-rate"].as<size_t>()));
pub.send("bye", 3);
}
pubDoneFlag = true;
monitor_thread.join();
}
void showID(int ID)
{
unique_lock<mutex> lck(mtx);
while (!ready) cv.wait(lck);
// 3 2 1 GO!
scout<<"Thread #"<<ID<<endl;
}
//! Dequeues log record from the queue, blocks if no log records are ready to be processed
bool dequeue_ready(record_view& rec)
{
unique_lock< mutex_type > lock(m_mutex);
while (!m_interruption_requested)
{
if (!m_queue.empty())
{
const boost::log::aux::timestamp now = boost::log::aux::get_timestamp();
enqueued_record const& elem = m_queue.top();
const uint64_t difference = (now - elem.m_timestamp).milliseconds();
if (difference >= m_ordering_window)
{
// We got a new element
rec = elem.m_record;
m_queue.pop();
return true;
}
else
{
// Wait until the element becomes ready to be processed
m_cond.timed_wait(lock, posix_time::milliseconds(m_ordering_window - difference));
}
}
else
{
// Wait for an element to come
m_cond.wait(lock);
}
}
m_interruption_requested = false;
return false;
}
void pop(T &result)
{
unique_lock<mutex> u(m);
c.wait(u, [&] {return !q.empty();} );
result = move_if_noexcept(q.front());
q.pop();
}
vector<T> get_all() {
unique_lock<mutex> l(cv_m);
cv.wait(l, [this](){return count(this->v.begin(), this->v.end(), T()) == 0;});
vector<T> ret = v;
fill(v.begin(), v.end(), T());
return ret;
}
T get(size_t k) {
unique_lock<mutex> l(cv_m);
cv.wait(l, [this, k](){return this->v[k] != T();});
T t = v[k];
v[k] = (T)0;
return t;
}
void run_thread()
{
unique_lock<mutex> guard(m_lock);
DBClientBase *client = new_connection();
while(true) {
if(!client->isStillConnected()) {
m_log->error() << "A thread lost its connection, reconnecting..." << endl;
delete client;
client = new_connection();
}
if(m_operation_queue.size() > 0) {
DBOperation *op = m_operation_queue.front();
m_operation_queue.pop();
guard.unlock();
handle_operation(client, op);
guard.lock();
} else if(m_shutdown) {
break;
} else {
m_cv.wait(guard);
}
}
delete client;
}
void acquire(){
unique_lock<mutex> lck(mtx);
while(count == 0){
cv.wait(lck);
}
count--;
}
void push(int data) {
{
unique_lock<mutex> lk(m);
cv.wait(lk,[this](){ return data_queue.size()<max_size; });
data_queue.push(data);
}
cv.notify_all();
}
void thread_func2(mutex & mtx, condition_variable & cv)
{
std::cout << "thread_func2: begin" << std::endl;
mutex::scoped_lock lc(mtx);
cv.wait(lc);
std::cout << "thread_func2: get lock" << std::endl;
std::cout << "thread_func2: end" << std::endl;
}
T pop () {
lock lock (list_mutex);
while (list.empty ()) {
m_condition.wait (lock);
}
T retval = list.front ();
list.pop_front ();
return retval;
}
void pop(int& data) {
{
unique_lock<mutex> lk(m);
cv.wait(lk,[this](){ return data_queue.size()>0; });
data = data_queue.front();
data_queue.pop();
}
cv.notify_all();
}
void InputDevice::StopPolling() {
inputThreadEnabled = false;
lock_guard guard(inputMutex);
if (inputThreadStatus) {
inputEndCond.wait(inputMutex);
}
delete inputThread;
inputThread = NULL;
}
void movePeople(vector<Human> &v) {
unique_lock<mutex> lck(mtx);
while (index == v.size()) cv.wait(lck);
current_floor = v[index].current_floor;
cout << " Elevator is picking up person: " << v[index].getID() << " at floor " << current_floor << endl;
current_floor = v[index].next_floor;
cout << " Elevator has dropped off person: " << v[index].getID() << " at floor " << current_floor << endl;
index++;
cv.notify_all();
}
void signal(int id)
{
unique_lock<mutex> lk(mx);
std::cout << "signaling " << id << "\n";
signaled_id = id;
cv.notify_all();
cv.wait(lk, [&] { return signaled_id == -1; });
}
void even_thread()
{
while (ctrEven < MAX_ELEMS) {
unique_lock<mutex> lk(mut);
cond.wait(lk, [] { return ((ctrOdd - ctrEven) == 3); });
ctrEven += 2;
cout << ctrEven << endl;
cond.notify_one();
lk.unlock();
}
}
void run()
{
{
mutex::guard g( mutex_ );
++worker_count_;
if ( worker_count_ == active_workers_ )
{
manager_cv_.notify_one();
}
}
shared_ptr< runnable > task;
for ( bool active = true; active; )
{
{
mutex::guard g( mutex_ );
while ( worker_count_ <= active_workers_ && tasks_.empty() )
{
++idle_workers_;
workers_cv_.wait( g );
--idle_workers_;
}
if ( worker_count_ <= active_workers_ ||
( state_ == STOPPING && tasks_.size() ) )
{
if ( tasks_.size() )
{
task = tasks_.front();
tasks_.pop_front();
}
}
else
{
--worker_count_;
if ( worker_count_ == active_workers_ )
{
manager_cv_.notify_one();
}
return;
}
}
if ( task )
{
task->execute();
task.reset();
}
}
}
void print_number_worker(int num) {
while(counter < 50) {
unique_lock<mutex> lk(m);
cv.wait(lk, [] { return can_print; });
cout << num << endl;
counter++;
cv.notify_one();
}
}
T& pop()
{
unique_lock<mutex> uniqueLock(mtx);
/* block thread if queue is empty */
while (tsQueue.empty()) {
cv.wait(uniqueLock);
}
auto& entry = tsQueue.front();
tsQueue.pop();
return entry;
}
// Thread function: Condition waiter
void ThreadCondition2(void * aArg)
{
cout << " Wating..." << flush;
lock_guard<mutex> lock(gMutex);
while(gCount > 0)
{
cout << "." << flush;
gCond.wait(gMutex);
}
cout << "." << endl;
}
void acquire_read() const
{
mutex::guard g( mutex_ );
while ( has_writer_ || writer_waiting_ )
{
reader_cv_.wait( mutex_ );
}
++reader_count_;
}
