void cmdVelReceived(const geometry_msgs::Twist::ConstPtr& cmd_vel)
{
	std::cout << "cmdVel Received: speed = " << cmd_vel->linear.x <<  " angular = " << cmd_vel->angular.z << std::endl; 
	if(bumper_warning.load()) roomba->drive(-0.2, 0);
	else if(ir_warning.load()) roomba->drive(0, cmd_vel->angular.z);
	else roomba->drive(cmd_vel->linear.x,cmd_vel->angular.z);
}
Exemple #2
0
	void thread_pool::thread_func(std::atomic_bool & stop_request)
	{
		std::unique_lock<std::mutex> lk(m_mutex, std::defer_lock);

		for (;;)
		{
			ext::intrusive_ptr<task_base> task_ptr; 
			lk.lock();

			if (stop_request.load(std::memory_order_relaxed)) return;
			if (!m_tasks.empty()) goto avail;

		again:
			m_event.wait(lk);

			if (stop_request.load(std::memory_order_relaxed)) return;
			if (m_tasks.empty()) goto again;
			
		avail:
			task_ptr.reset(&m_tasks.front(), ext::noaddref);
			m_tasks.pop_front();

			lk.unlock();

			task_ptr->execute();
		}
	}
			progressIndicatorThreadWrapper( const std::chrono::nanoseconds& updateInterval )
			{
				m_stopCondition.store( false );
				
				m_thread = std::thread( [this, &updateInterval]
										{
											FormattedPrint::On(std::cout, false).app("    ");
											
											int slashIndex = 0;

											while( ! m_stopCondition.load() )
											{
												FormattedPrint::On(std::cout, false).app("\b\b\b \b")
																					.color( Green )
																					.app('[')
																					.color( Yellow )
																					.app( slashes[ slashIndex++ ] )
																					.color( Green )
																					.app(']')
																					.color();

												slashIndex = slashIndex % 4;

												std::this_thread::sleep_for( updateInterval );
											}

											FormattedPrint::On(std::cout, false).app("\b\b\b");
										});
			}
Exemple #4
0
        /**
          * This is the actual function that the thread executes.
          * It receives a block from the scheduler, class its run() method and returns it to the scheduler.
          * The thread runs until the it is told to stop by setting the m_stop boolean flag
          */
        void operator()()
        {
            if(CPU_COUNT(&m_mask)>0)
            {
                pthread_t id = pthread_self();
               int ret = pthread_setaffinity_np(id, sizeof(m_mask), &m_mask);
                if(ret != 0)
                {
                    perror("setaffinity");
                    throw(std::runtime_error("set affinity failed"));
                }
            }
            while(!m_stop.load())
            {

                std::shared_ptr<Block>torun(m_scheduler.next_task(m_id));
                if(torun)
                {
                    torun->run();
                    m_scheduler.task_done(m_id, std::move(torun));
                }
                else
                {
                    std::this_thread::sleep_for(std::chrono::milliseconds(10));
                }
            }
            m_stop.store(false);
        }
	void thread_connect() {
		connected.store(false);

		do {
			struct sockaddr_in addr;
			int      r;
			hostent* h;

			memset((void*)&addr, 0, sizeof(addr));
			addr.sin_addr.s_addr = inet_addr(ip.c_str());
			if(INADDR_NONE == addr.sin_addr.s_addr) {
				h = gethostbyname(ip.c_str());
				if(NULL == h) {
					perror("Could not get host by name");
					break;;
				}
			} else {
				h = gethostbyaddr((const char*)&addr.sin_addr, sizeof(struct sockaddr_in), AF_INET);
				if(NULL == h) {
					perror("Could not get host by address");
					break;;
				}
			}

			sock = socket(AF_INET, SOCK_STREAM, IPPROTO_TCP);
			if(INVALID_SOCKET == sock) {
				perror("Could not create socket");
				break;
			}

			BOOL bDontLinger = TRUE;
			setsockopt( sock, SOL_SOCKET, SO_DONTLINGER, ( const char* )&bDontLinger, sizeof( BOOL ) );

			addr.sin_family = AF_INET;
			addr.sin_addr   = *((in_addr*)*h->h_addr_list);
			addr.sin_port   = htons(port);

			printf("Connecting... ");
			r = connect(sock, (sockaddr*)&addr, sizeof(struct sockaddr));
			if(SOCKET_ERROR == r) {
				printf("Cannot connect to server%d\n", get_errno());
				break;
			}
			printf("connected.\n");

			connected.store(true);
			connecting.store(false);
			sender.swap(std::thread(std::bind(&transport_t::thread_send, this)));
			recver.swap(std::thread(std::bind(&transport_t::thread_recv, this)));
			return;
		} while (0);

		connecting.store(false);
	}
Exemple #6
0
void
handleDbgBreakInterrupt()
{
   // If we are not initialised, we should ignore DbgBreaks
   if (!decaf::config::debugger::enabled) {
      return;
   }

   std::unique_lock<std::mutex> lock(sMutex);
   auto coreId = cpu::this_core::id();

   // Store our core state before we flip isPaused
   sCorePauseState[coreId] = cpu::this_core::state();

   // Check to see if we were the last core to join on the fun
   auto coreBit = 1 << coreId;
   auto isPausing = sIsPausing.fetch_or(coreBit);

   if (isPausing == 0) {
      // This is the first core to hit a breakpoint
      sPauseInitiatorCoreId = coreId;

      // Signal the rest of the cores to stop
      for (auto i = 0; i < 3; ++i) {
         cpu::interrupt(i, cpu::DBGBREAK_INTERRUPT);
      }
   }

   if ((isPausing | coreBit) == (1 | 2 | 4)) {
      // This was the last core to join.
      sIsPaused.store(true);
      sIsPausing.store(0);
      sIsResuming.store(0);
   }

   // Spin around the release condition while we are paused
   while (sIsPausing.load() || sIsPaused.load()) {
      sPauseReleaseCond.wait(lock);
   }

   // Clear any additional DbgBreaks that occured
   cpu::this_core::clearInterrupt(cpu::DBGBREAK_INTERRUPT);

   // Everyone needs to leave at once in case new breakpoints occur.
   if ((sIsResuming.fetch_or(coreBit) | coreBit) == (1 | 2 | 4)) {
      sPauseReleaseCond.notify_all();
   } else {
      while ((sIsResuming.load() | coreBit) != (1 | 2 | 4)) {
         sPauseReleaseCond.wait(lock);
      }
   }
}
	bool fiber_waiter::wait_ready(std::chrono::steady_clock::duration timeout_duration) noexcept
	{
		if (gth_thread_type == thread_type::thread)
		{
			std::unique_lock<std::mutex> lk(m_thread_mutex);
			return m_thread_var.wait_for(lk, timeout_duration, [this] { return m_ready.load(std::memory_order_relaxed); });
		}
		else
		{
			std::unique_lock<boost::fibers::mutex> lk(m_fiber_mutex);
			return m_fiber_var.wait_for(lk, timeout_duration, [this] { return m_ready.load(std::memory_order_relaxed); });
		}
	}
	void fiber_waiter::wait_ready() noexcept
	{
		if (gth_thread_type == thread_type::thread)
		{
			std::unique_lock<std::mutex> lk(m_thread_mutex);
			return m_thread_var.wait(lk, [this] { return m_ready.load(std::memory_order_relaxed); });
		}
		else
		{
			std::unique_lock<boost::fibers::mutex> lk(m_fiber_mutex);
			return m_fiber_var.wait(lk, [this] { return m_ready.load(std::memory_order_relaxed); });
		}
	}
/**
 * Start the IPC thread.
 */
void
ipcStart()
{
   std::unique_lock<std::mutex> lock { sIpcMutex };
   sIpcThreadRunning.store(true);
   sIpcThread = std::thread { ipcThreadEntry };
}
LRESULT WINAPI WndProc(HWND hWnd, UINT msg, WPARAM wParam, LPARAM lParam) {
    WindowEvent params = {};
    params.hWnd = hWnd;
    params.msg = msg;
    params.wParam = wParam;
    params.lParam = lParam;

    s_queue->Enqueue(params);

    switch (msg)
    {
    case WM_SIZE:
        if (g_renderApi && wParam != SIZE_MINIMIZED) {
            g_renderApi->Resize((int32_t) LOWORD(lParam), (int32_t) HIWORD(lParam));
            return 0;
        }
        break;
    case WM_SYSCOMMAND:
        if ((wParam & 0xfff0) == SC_KEYMENU) // Disable ALT application menu
            return 0;
        break;
    case WM_DESTROY:
        s_running.store(false);
        PostQuitMessage(0);
        return 0;
    }
    return DefWindowProcW(hWnd, msg, wParam, lParam);
}
Exemple #11
0
void gstate_update_func()
{
	POINT p;
	int mButton;

	if(GetSystemMetrics(SM_SWAPBUTTON))
		mButton = VK_RBUTTON; // if  swapped
	else
		mButton = VK_LBUTTON; // not swapped (normal)

	int screenWidth  = GetSystemMetrics( SM_CXSCREEN );
	int screenHeight = GetSystemMetrics( SM_CYSCREEN );
	// default: SM_CX/CYSCREEN gets the size of a primary screen.
	// lines uncommented below are just for a specially need on multi-display.
	//int screenWidth  = GetSystemMetrics( SM_CXVIRTUALSCREEN );
	//int screenHeight = GetSystemMetrics( SM_CYVIRTUALSCREEN );
	float r_screenWidth  = 1.f / (float)(screenWidth  -1);
	float r_screenHeight = 1.f / (float)(screenHeight -1);


	while ( inputThreadRunning.load( std::memory_order_relaxed ) ) {
		// "KeyState" is disabled for now, on Windows...
		//GetKey((long*)gstate->keys);

		GetCursorPos(&p);
		gMouseUGenGlobals.mouseX = (float)p.x * r_screenWidth;
		gMouseUGenGlobals.mouseY = 1.f - (float)p.y * r_screenHeight;
		gMouseUGenGlobals.mouseButton = (GetKeyState(mButton) < 0);
		std::this_thread::sleep_for( std::chrono::milliseconds( 17 ) );
	}
}
Exemple #12
0
static void
run(std::atomic_bool& running, int fd, felix::netio::DataSinkCallbacks* callbacks)
{
	while(running.load())
	{
	  /*		felix::netio::msgheader header;
		ssize_t count = read(fd, &header, sizeof(header));
		assert(count == sizeof(header));

		char* data = new char[header.len];

		ssize_t bytes_read = 0;
		while(bytes_read < header.len)
		{
			count = read(fd, data+bytes_read, header.len-bytes_read);
			if (count == 0)
			{
				std::vector<felix::netio::DataSinkMessage> messages;
				messages.emplace_back(data, bytes_read);
				callbacks->on_data_received_with_error(messages);
				return;
			}
			bytes_read += count;
		}

	  */

	  char* data = new char[1024];
	  ssize_t count = read(fd, data, 1024);

		std::vector<felix::netio::DataSinkMessage> messages;
		messages.emplace_back(data, count);
		callbacks->on_data_received(messages);
	}
}
Exemple #13
0
bool example1_rx(const std::string& dataaddress, unsigned short dataport, std::atomic_bool& stopFlag)
{
    SuperBlock rxBlock;
    uint8_t rawBlock[sizeof(SuperBlock)];
    int rawBlockSize;
    UDPSocket rxSocket(dataport);
    std::string senderaddress, senderaddress0;
    unsigned short senderport, senderport0 = 0;
    Example1Rx ex1(nbSamplesPerBlock, nbOriginalBlocks, nbRecoveryBlocks);

    std::cerr << "example1_rx: receiving on address: " << dataaddress << " port: " << (int) dataport << std::endl;

    while (!stopFlag.load())
    {
        rawBlockSize = 0;

        while (rawBlockSize < sizeof(SuperBlock))
        {
            rawBlockSize += rxSocket.RecvDataGram((void *) &rawBlock[rawBlockSize], (int) sizeof(SuperBlock), senderaddress, senderport);

            if ((senderaddress != senderaddress0) || (senderport != senderport0))
            {
            	std::cerr << "example1_rx: connected to: " << senderaddress << ":" << senderport << std::endl;
            	senderaddress0 = senderaddress;
            	senderport0 = senderport;
            }

            usleep(10);
        }

        rxBlock = *((SuperBlock *) rawBlock);
        ex1.processBlock(rxBlock);
    }
}
Exemple #14
0
void consume(std::atomic_bool& done, int* array, int_queue& q)
{
    while (!done.load())
    {
        int val;
        if(q.pop(val))
        {
            array[val] = val;
        }
        else
        {
            std::this_thread::yield();
        }
    }
    
    // drain
    while (!q.empty())
    {
        int val;
        if(q.pop(val))
        {
            array[val] = val;
        }
        else
        {
            std::this_thread::yield();
        }

    }
}
Exemple #15
0
bool check_events() {
    bool true_value = true;
    if (flag_needs_recreate_swapchain.compare_exchange_weak(true_value, false)) {
        graphics::render3d::resources::create_pipeline();
    }
    return true;
}
Exemple #16
0
void reader_thread()
{
    while (!data_ready.load()) {
        std::this_thread::sleep_for(std::chrono::milliseconds(1));
    }
    std::cout<<"The answer = "<<data[0]<<"\n";
}
	void try_connect() {
		bool f = false;
		if (!connecting.compare_exchange_strong(f, true))
			return;
		
		connector.swap(std::thread(std::bind(&transport_t::thread_connect, this)));
		connector.detach();
		return;
	}
void
OSLockScheduler()
{
   bool locked = false;

   while (!gSchedulerLock.compare_exchange_weak(locked, true, std::memory_order_acquire)) {
      locked = false;
   }
}
Exemple #19
0
 ~ThreadPool() {
     stoped.exchange(true);
     for (auto& cond: thread_cond) {
         cond.notify_one();
     }
     for (auto& worker : workers) {
         if (worker.joinable()) worker.join();
     }
 }
Exemple #20
0
 inline void
 lock()
 {
     while (m_spin.exchange(true)) {
         if (yield) {
             std::this_thread::yield();
         }
     }
 }
Exemple #21
0
bool init(const char* pipeline, core::c_window *window, bool validation) {
    VERIFY(graphics::render3d::resources::load_pipeline(pipeline));

    VERIFY(create_instance("appname"));
    VERIFY(create_surface(window));
    VERIFY(create_device());
    VERIFY(create_device_queue());
    VERIFY(graphics::render3d::resources::create_pipeline());

    vk_globals::is_init = true;

    flag_needs_recreate_swapchain.store(false);
    flag_needs_shutdown.store(false);

    on_window_resize_listener = window->add_event_listener(core::e_window_event::ON_RESIZE, on_window_resize);

    return true;
}
			~progressIndicatorThreadWrapper()
			{
				m_stopCondition.store( true );

				if( m_thread.joinable() )
				{
					m_thread.join();
				}
			}
Exemple #23
0
void
resumeAll()
{
   auto oldState = sIsPaused.exchange(false);
   decaf_check(oldState);
   for (auto i = 0; i < 3; ++i) {
      sCorePauseState[i] = nullptr;
   }
   sPauseReleaseCond.notify_all();
}
	void disconnect() {
		connected.store(false);
		closesocket(sock);

		sender.join();
		recver.join();

		send_queue.clear();
		recv_queue.clear();
	}
/**
 * Main thread entry point for the IPC thread.
 *
 * This thread represents the IOS side of the IPC mechanism.
 *
 * Responsible for receiving IPC requests and dispatching them to the
 * correct IOS device.
 */
void
ipcThreadEntry()
{
   std::unique_lock<std::mutex> lock { sIpcMutex };

   while (true) {
      if (!sIpcRequests.empty()) {
         auto request = sIpcRequests.front();
         sIpcRequests.pop();
         lock.unlock();
         iosDispatchIpcRequest(request);
         lock.lock();

         switch (request->cpuId) {
         case IOSCpuId::PPC0:
            sIpcResponses[0].push(request);
            cpu::interrupt(0, cpu::IPC_INTERRUPT);
            break;
         case IOSCpuId::PPC1:
            sIpcResponses[1].push(request);
            cpu::interrupt(1, cpu::IPC_INTERRUPT);
            break;
         case IOSCpuId::PPC2:
            sIpcResponses[2].push(request);
            cpu::interrupt(2, cpu::IPC_INTERRUPT);
            break;
         default:
            decaf_abort("Unexpected cpu id");
         }
      }

      if (!sIpcThreadRunning.load()) {
         break;
      }

      if (sIpcRequests.empty()) {
         sIpcCond.wait(lock);
      }
   }

   sIpcThreadRunning.store(false);
}
Exemple #26
0
static void
stepCore(uint32_t coreId, bool stepOver)
{
   decaf_check(sIsPaused.load());

   const cpu::CoreRegs *state = sCorePauseState[coreId];
   uint32_t nextInstr = calculateNextInstr(state, stepOver);
   cpu::addBreakpoint(nextInstr, cpu::SYSTEM_BPFLAG);

   resumeAll();
}
Exemple #27
0
	~WorkerThreads()
	{
		_shutdownFlag.store(true);

		_cache.setShutdownFlag();

		for (auto worker : _workers)
		{
			worker->join();
			delete worker;
		}
	}
/**
 * Stop the IPC thread.
 */
void
ipcShutdown()
{
   std::unique_lock<std::mutex> lock { sIpcMutex };

   if (sIpcThreadRunning.exchange(false)) {
      sIpcCond.notify_all();
      lock.unlock();

      sIpcThread.join();
   }
}
Exemple #29
0
	WorkerThreads(unsigned int threadsCount, RJCache& cache) :
		_nextThreadId(0),
		_cache(cache)
	{
		_shutdownFlag.store(false);

		_workers.reserve(threadsCount);

		for (unsigned int i = 0; i < threadsCount; i++)
		{
			std::thread* worker = new std::thread(&WorkerThreads::workerThreadFunc, this, _nextThreadId++, &cache);
			_workers.push_back(worker);
		}
	}
Exemple #30
0
 void swap_queues()
 {
     for(unsigned int i=0; i<m_full_slots; ++i)
     {
         m_queues[m_consumer_q].vec[i].valid.store(false,std::memory_order_release);
     }
     unsigned int newpoint=m_consumer_q<<30;
     m_consumer_q=exchange_queue(m_consumer_q);
     unsigned int old_pointer=m_pointer.exchange(newpoint,std::memory_order_release);
     m_full.store(false,std::memory_order_release);
     old_pointer&=~MASK;
     m_full_slots=std::min(old_pointer,Qlen);
     m_read=0;
 }