#include #if CONFIG_HAL_BOARD == HAL_BOARD_PX4 #include "AP_HAL_PX4.h" #include "Scheduler.h" #include #include #include #include #include #include #include #include #include #include #include "UARTDriver.h" #include "AnalogIn.h" #include "Storage.h" #include "RCOutput.h" #include "RCInput.h" #include #include #if HAL_WITH_UAVCAN #include "CAN.h" #include #endif using namespace PX4; extern const AP_HAL::HAL& hal; extern bool _px4_thread_should_exit; PX4Scheduler::PX4Scheduler() : _perf_timers(perf_alloc(PC_ELAPSED, "APM_timers")), _perf_io_timers(perf_alloc(PC_ELAPSED, "APM_IO_timers")), _perf_storage_timer(perf_alloc(PC_ELAPSED, "APM_storage_timers")), _perf_delay(perf_alloc(PC_ELAPSED, "APM_delay")) {} void PX4Scheduler::init() { _main_task_pid = getpid(); // setup the timer thread - this will call tasks at 1kHz pthread_attr_t thread_attr; struct sched_param param; pthread_attr_init(&thread_attr); pthread_attr_setstacksize(&thread_attr, 2048); param.sched_priority = APM_TIMER_PRIORITY; (void)pthread_attr_setschedparam(&thread_attr, ¶m); pthread_attr_setschedpolicy(&thread_attr, SCHED_FIFO); pthread_create(&_timer_thread_ctx, &thread_attr, &PX4Scheduler::_timer_thread, this); // the UART thread runs at a medium priority pthread_attr_init(&thread_attr); pthread_attr_setstacksize(&thread_attr, 2048); param.sched_priority = APM_UART_PRIORITY; (void)pthread_attr_setschedparam(&thread_attr, ¶m); pthread_attr_setschedpolicy(&thread_attr, SCHED_FIFO); pthread_create(&_uart_thread_ctx, &thread_attr, &PX4Scheduler::_uart_thread, this); // the IO thread runs at lower priority pthread_attr_init(&thread_attr); pthread_attr_setstacksize(&thread_attr, 2048); param.sched_priority = APM_IO_PRIORITY; (void)pthread_attr_setschedparam(&thread_attr, ¶m); pthread_attr_setschedpolicy(&thread_attr, SCHED_FIFO); pthread_create(&_io_thread_ctx, &thread_attr, &PX4Scheduler::_io_thread, this); // the storage thread runs at just above IO priority pthread_attr_init(&thread_attr); pthread_attr_setstacksize(&thread_attr, 1024); param.sched_priority = APM_STORAGE_PRIORITY; (void)pthread_attr_setschedparam(&thread_attr, ¶m); pthread_attr_setschedpolicy(&thread_attr, SCHED_FIFO); pthread_create(&_storage_thread_ctx, &thread_attr, &PX4Scheduler::_storage_thread, this); } void PX4Scheduler::create_uavcan_thread() { #if HAL_WITH_UAVCAN pthread_attr_t thread_attr; struct sched_param param; //the UAVCAN thread runs at medium priority pthread_attr_init(&thread_attr); pthread_attr_setstacksize(&thread_attr, 8192); param.sched_priority = APM_CAN_PRIORITY; (void) pthread_attr_setschedparam(&thread_attr, ¶m); pthread_attr_setschedpolicy(&thread_attr, SCHED_FIFO); pthread_create(&_uavcan_thread_ctx, &thread_attr, &PX4Scheduler::_uavcan_thread, this); printf("UAVCAN thread started\n\r"); #endif } /** delay for a specified number of microseconds using a semaphore wait */ void PX4Scheduler::delay_microseconds_semaphore(uint16_t usec) { sem_t wait_semaphore; struct hrt_call wait_call; sem_init(&wait_semaphore, 0, 0); memset(&wait_call, 0, sizeof(wait_call)); hrt_call_after(&wait_call, usec, (hrt_callout)sem_post, &wait_semaphore); sem_wait(&wait_semaphore); } void PX4Scheduler::delay_microseconds(uint16_t usec) { perf_begin(_perf_delay); delay_microseconds_semaphore(usec); perf_end(_perf_delay); } /* wrapper around sem_post that boosts main thread priority */ static void sem_post_boost(sem_t *sem) { hal_px4_set_priority(APM_MAIN_PRIORITY_BOOST); sem_post(sem); } /* return the main thread to normal priority */ static void set_normal_priority(void *sem) { hal_px4_set_priority(APM_MAIN_PRIORITY); } /* a variant of delay_microseconds that boosts priority to APM_MAIN_PRIORITY_BOOST for APM_MAIN_PRIORITY_BOOST_USEC microseconds when the time completes. This significantly improves the regularity of timing of the main loop as it takes */ void PX4Scheduler::delay_microseconds_boost(uint16_t usec) { sem_t wait_semaphore; static struct hrt_call wait_call; sem_init(&wait_semaphore, 0, 0); hrt_call_after(&wait_call, usec, (hrt_callout)sem_post_boost, &wait_semaphore); sem_wait(&wait_semaphore); hrt_call_after(&wait_call, APM_MAIN_PRIORITY_BOOST_USEC, (hrt_callout)set_normal_priority, nullptr); } void PX4Scheduler::delay(uint16_t ms) { if (in_timerprocess()) { ::printf("ERROR: delay() from timer process\n"); return; } perf_begin(_perf_delay); uint64_t start = AP_HAL::micros64(); while ((AP_HAL::micros64() - start)/1000 < ms && !_px4_thread_should_exit) { delay_microseconds_semaphore(1000); if (_min_delay_cb_ms <= ms) { if (_delay_cb) { _delay_cb(); } } } perf_end(_perf_delay); if (_px4_thread_should_exit) { exit(1); } } void PX4Scheduler::register_delay_callback(AP_HAL::Proc proc, uint16_t min_time_ms) { _delay_cb = proc; _min_delay_cb_ms = min_time_ms; } void PX4Scheduler::register_timer_process(AP_HAL::MemberProc proc) { for (uint8_t i = 0; i < _num_timer_procs; i++) { if (_timer_proc[i] == proc) { return; } } if (_num_timer_procs < PX4_SCHEDULER_MAX_TIMER_PROCS) { _timer_proc[_num_timer_procs] = proc; _num_timer_procs++; } else { hal.console->printf("Out of timer processes\n"); } } void PX4Scheduler::register_io_process(AP_HAL::MemberProc proc) { for (uint8_t i = 0; i < _num_io_procs; i++) { if (_io_proc[i] == proc) { return; } } if (_num_io_procs < PX4_SCHEDULER_MAX_TIMER_PROCS) { _io_proc[_num_io_procs] = proc; _num_io_procs++; } else { hal.console->printf("Out of IO processes\n"); } } void PX4Scheduler::register_timer_failsafe(AP_HAL::Proc failsafe, uint32_t period_us) { _failsafe = failsafe; } void PX4Scheduler::suspend_timer_procs() { _timer_suspended = true; } void PX4Scheduler::resume_timer_procs() { _timer_suspended = false; if (_timer_event_missed == true) { _run_timers(false); _timer_event_missed = false; } } void PX4Scheduler::reboot(bool hold_in_bootloader) { // disarm motors to ensure they are off during a bootloader upload hal.rcout->force_safety_on(); hal.rcout->force_safety_no_wait(); // delay to ensure the async force_saftey operation completes delay(500); px4_systemreset(hold_in_bootloader); } void PX4Scheduler::_run_timers(bool called_from_timer_thread) { if (_in_timer_proc) { return; } _in_timer_proc = true; if (!_timer_suspended) { // now call the timer based drivers for (int i = 0; i < _num_timer_procs; i++) { if (_timer_proc[i]) { _timer_proc[i](); } } } else if (called_from_timer_thread) { _timer_event_missed = true; } // and the failsafe, if one is setup if (_failsafe != nullptr) { _failsafe(); } // process analog input ((PX4AnalogIn *)hal.analogin)->_timer_tick(); _in_timer_proc = false; } extern bool px4_ran_overtime; void *PX4Scheduler::_timer_thread(void *arg) { PX4Scheduler *sched = (PX4Scheduler *)arg; uint32_t last_ran_overtime = 0; pthread_setname_np(pthread_self(), "apm_timer"); while (!sched->_hal_initialized) { poll(nullptr, 0, 1); } while (!_px4_thread_should_exit) { sched->delay_microseconds_semaphore(1000); // run registered timers perf_begin(sched->_perf_timers); sched->_run_timers(true); perf_end(sched->_perf_timers); // process any pending RC output requests hal.rcout->timer_tick(); // process any pending RC input requests ((PX4RCInput *)hal.rcin)->_timer_tick(); if (px4_ran_overtime && AP_HAL::millis() - last_ran_overtime > 2000) { last_ran_overtime = AP_HAL::millis(); #if 0 printf("Overtime in task %d\n", (int)AP_Scheduler::current_task); hal.console->printf("Overtime in task %d\n", (int)AP_Scheduler::current_task); #endif } } return nullptr; } void PX4Scheduler::_run_io(void) { if (_in_io_proc) { return; } _in_io_proc = true; if (!_timer_suspended) { // now call the IO based drivers for (int i = 0; i < _num_io_procs; i++) { if (_io_proc[i]) { _io_proc[i](); } } } _in_io_proc = false; } void *PX4Scheduler::_uart_thread(void *arg) { PX4Scheduler *sched = (PX4Scheduler *)arg; pthread_setname_np(pthread_self(), "apm_uart"); while (!sched->_hal_initialized) { poll(nullptr, 0, 1); } while (!_px4_thread_should_exit) { sched->delay_microseconds_semaphore(1000); // process any pending serial bytes ((PX4UARTDriver *)hal.uartA)->_timer_tick(); ((PX4UARTDriver *)hal.uartB)->_timer_tick(); ((PX4UARTDriver *)hal.uartC)->_timer_tick(); ((PX4UARTDriver *)hal.uartD)->_timer_tick(); ((PX4UARTDriver *)hal.uartE)->_timer_tick(); ((PX4UARTDriver *)hal.uartF)->_timer_tick(); } return nullptr; } void *PX4Scheduler::_io_thread(void *arg) { PX4Scheduler *sched = (PX4Scheduler *)arg; pthread_setname_np(pthread_self(), "apm_io"); while (!sched->_hal_initialized) { poll(nullptr, 0, 1); } while (!_px4_thread_should_exit) { sched->delay_microseconds_semaphore(1000); // run registered IO processes perf_begin(sched->_perf_io_timers); sched->_run_io(); perf_end(sched->_perf_io_timers); } return nullptr; } void *PX4Scheduler::_storage_thread(void *arg) { PX4Scheduler *sched = (PX4Scheduler *)arg; pthread_setname_np(pthread_self(), "apm_storage"); while (!sched->_hal_initialized) { poll(nullptr, 0, 1); } while (!_px4_thread_should_exit) { sched->delay_microseconds_semaphore(10000); // process any pending storage writes perf_begin(sched->_perf_storage_timer); ((PX4Storage *)hal.storage)->_timer_tick(); perf_end(sched->_perf_storage_timer); } return nullptr; } #if HAL_WITH_UAVCAN void *PX4Scheduler::_uavcan_thread(void *arg) { PX4Scheduler *sched = (PX4Scheduler *) arg; pthread_setname_np(pthread_self(), "apm_uavcan"); while (!sched->_hal_initialized) { poll(nullptr, 0, 1); } while (!_px4_thread_should_exit) { if (((PX4CANManager *)hal.can_mgr)->is_initialized()) { if (((PX4CANManager *)hal.can_mgr)->get_UAVCAN() != nullptr) { (((PX4CANManager *)hal.can_mgr)->get_UAVCAN())->do_cyclic(); } else { sched->delay_microseconds_semaphore(10000); } } else { sched->delay_microseconds_semaphore(10000); } } return nullptr; } #endif bool PX4Scheduler::in_timerprocess() { return getpid() != _main_task_pid; } void PX4Scheduler::system_initialized() { if (_initialized) { AP_HAL::panic("PANIC: scheduler::system_initialized called" "more than once"); } _initialized = true; } #endif