예제 #1
0
int test_mixer(int argc, char *argv[])
{
	warnx("testing mixer");

	char *filename = "/etc/mixers/IO_pass.mix";

	if (argc > 1)
		filename = argv[1];

	warnx("loading: %s", filename);

	char		buf[2048];

	load_mixer_file(filename, &buf[0], sizeof(buf));
	unsigned loaded = strlen(buf);

	warnx("loaded: \n\"%s\"\n (%d chars)", &buf[0], loaded);

	/* load the mixer in chunks, like
	 * in the case of a remote load,
	 * e.g. on PX4IO.
	 */

	unsigned nused = 0;

	const unsigned chunk_size = 64;

	MixerGroup mixer_group(mixer_callback, 0);

	/* load at once test */
	unsigned xx = loaded;
	mixer_group.load_from_buf(&buf[0], xx);
	warnx("complete buffer load: loaded %u mixers", mixer_group.count());
	if (mixer_group.count() != 8)
		return 1;

	unsigned empty_load = 2;
	char empty_buf[2];
	empty_buf[0] = ' ';
	empty_buf[1] = '\0';
	mixer_group.reset();
	mixer_group.load_from_buf(&empty_buf[0], empty_load);
	warnx("empty buffer load: loaded %u mixers, used: %u", mixer_group.count(), empty_load);
	if (empty_load != 0)
		return 1;

	/* FIRST mark the mixer as invalid */
	bool mixer_ok = false;
	/* THEN actually delete it */
	mixer_group.reset();
	char mixer_text[256];		/* large enough for one mixer */
	unsigned mixer_text_length = 0;

	unsigned transmitted = 0;

	warnx("transmitted: %d, loaded: %d", transmitted, loaded);

	while (transmitted < loaded) {

		unsigned	text_length = (loaded - transmitted > chunk_size) ? chunk_size : loaded - transmitted;

		/* check for overflow - this would be really fatal */
		if ((mixer_text_length + text_length + 1) > sizeof(mixer_text)) {
			bool mixer_ok = false;
			return 1;
		}

		/* append mixer text and nul-terminate */
		memcpy(&mixer_text[mixer_text_length], &buf[transmitted], text_length);
		mixer_text_length += text_length;
		mixer_text[mixer_text_length] = '\0';
		warnx("buflen %u, text:\n\"%s\"", mixer_text_length, &mixer_text[0]);

		/* process the text buffer, adding new mixers as their descriptions can be parsed */
		unsigned resid = mixer_text_length;
		mixer_group.load_from_buf(&mixer_text[0], resid);

		/* if anything was parsed */
		if (resid != mixer_text_length) {

			/* only set mixer ok if no residual is left over */
			if (resid == 0) {
				mixer_ok = true;
			} else {
				/* not yet reached the end of the mixer, set as not ok */
				mixer_ok = false;
			}

			warnx("used %u", mixer_text_length - resid);

			/* copy any leftover text to the base of the buffer for re-use */
			if (resid > 0)
				memcpy(&mixer_text[0], &mixer_text[mixer_text_length - resid], resid);

			mixer_text_length = resid;
		}

		transmitted += text_length;
	}

	warnx("chunked load: loaded %u mixers", mixer_group.count());

	if (mixer_group.count() != 8)
		return 1;

	/* execute the mixer */
	
	float	outputs[output_max];
	unsigned mixed;
	const int jmax = 5;

	pwm_limit_init(&pwm_limit);
	should_arm = true;

	/* run through arming phase */
	for (int i = 0; i < output_max; i++) {
		actuator_controls[i] = 0.1f;
		r_page_servo_disarmed[i] = PWM_LOWEST_MIN;
		r_page_servo_control_min[i] = PWM_DEFAULT_MIN;
		r_page_servo_control_max[i] = PWM_DEFAULT_MAX;
	}

	warnx("ARMING TEST: STARTING RAMP");
	unsigned sleep_quantum_us = 10000;

	hrt_abstime starttime = hrt_absolute_time();
	unsigned sleepcount = 0;

	while (hrt_elapsed_time(&starttime) < INIT_TIME_US + RAMP_TIME_US) {
		
		/* mix */
		mixed = mixer_group.mix(&outputs[0], output_max);

		pwm_limit_calc(should_arm, mixed, r_page_servo_disarmed, r_page_servo_control_min, r_page_servo_control_max, outputs, r_page_servos, &pwm_limit);

		//warnx("mixed %d outputs (max %d), values:", mixed, output_max);
		for (int i = 0; i < mixed; i++)
		{
			/* check mixed outputs to be zero during init phase */
			if (hrt_elapsed_time(&starttime) < INIT_TIME_US &&
				r_page_servos[i] != r_page_servo_disarmed[i]) {
				warnx("disarmed servo value mismatch");
				return 1;
			}

			if (hrt_elapsed_time(&starttime) >= INIT_TIME_US &&
				r_page_servos[i] + 1 <= r_page_servo_disarmed[i]) {
				warnx("ramp servo value mismatch");
				return 1;
			}

			//printf("\t %d: %8.4f limited: %8.4f, servo: %d\n", i, outputs_unlimited[i], outputs[i], (int)r_page_servos[i]);
		}
		usleep(sleep_quantum_us);
		sleepcount++;

		if (sleepcount % 10 == 0) {
			printf(".");
			fflush(stdout);
		}
	}
	printf("\n");

	warnx("ARMING TEST: NORMAL OPERATION");

	for (int j = -jmax; j <= jmax; j++) {

		for (int i = 0; i < output_max; i++) {
			actuator_controls[i] = j/10.0f + 0.1f * i;
			r_page_servo_disarmed[i] = PWM_LOWEST_MIN;
			r_page_servo_control_min[i] = PWM_DEFAULT_MIN;
			r_page_servo_control_max[i] = PWM_DEFAULT_MAX;
		}

		/* mix */
		mixed = mixer_group.mix(&outputs[0], output_max);

		pwm_limit_calc(should_arm, mixed, r_page_servo_disarmed, r_page_servo_control_min, r_page_servo_control_max, outputs, r_page_servos, &pwm_limit);

		warnx("mixed %d outputs (max %d)", mixed, output_max);
		for (int i = 0; i < mixed; i++)
		{
			servo_predicted[i] = 1500 + outputs[i] * (r_page_servo_control_max[i] - r_page_servo_control_min[i]) / 2.0f;
			if (fabsf(servo_predicted[i] - r_page_servos[i]) > 2) {
				printf("\t %d: %8.4f predicted: %d, servo: %d\n", i, outputs[i], servo_predicted[i], (int)r_page_servos[i]);
				warnx("mixer violated predicted value");
				return 1;
			}
		}
	}

	warnx("ARMING TEST: DISARMING");

	starttime = hrt_absolute_time();
	sleepcount = 0;
	should_arm = false;

	while (hrt_elapsed_time(&starttime) < 600000) {
		
		/* mix */
		mixed = mixer_group.mix(&outputs[0], output_max);

		pwm_limit_calc(should_arm, mixed, r_page_servo_disarmed, r_page_servo_control_min, r_page_servo_control_max, outputs, r_page_servos, &pwm_limit);

		//warnx("mixed %d outputs (max %d), values:", mixed, output_max);
		for (int i = 0; i < mixed; i++)
		{
			/* check mixed outputs to be zero during init phase */
			if (r_page_servos[i] != r_page_servo_disarmed[i]) {
				warnx("disarmed servo value mismatch");
				return 1;
			}

			//printf("\t %d: %8.4f limited: %8.4f, servo: %d\n", i, outputs_unlimited[i], outputs[i], (int)r_page_servos[i]);
		}
		usleep(sleep_quantum_us);
		sleepcount++;

		if (sleepcount % 10 == 0) {
			printf(".");
			fflush(stdout);
		}
	}
	printf("\n");

	warnx("ARMING TEST: REARMING: STARTING RAMP");

	starttime = hrt_absolute_time();
	sleepcount = 0;
	should_arm = true;

	while (hrt_elapsed_time(&starttime) < 600000 + RAMP_TIME_US) {
		
		/* mix */
		mixed = mixer_group.mix(&outputs[0], output_max);

		pwm_limit_calc(should_arm, mixed, r_page_servo_disarmed, r_page_servo_control_min, r_page_servo_control_max, outputs, r_page_servos, &pwm_limit);

		//warnx("mixed %d outputs (max %d), values:", mixed, output_max);
		for (int i = 0; i < mixed; i++)
		{
			/* predict value */
			servo_predicted[i] = 1500 + outputs[i] * (r_page_servo_control_max[i] - r_page_servo_control_min[i]) / 2.0f;

			/* check ramp */

			if (hrt_elapsed_time(&starttime) < RAMP_TIME_US &&
				(r_page_servos[i] + 1 <= r_page_servo_disarmed[i] ||
					r_page_servos[i] > servo_predicted[i])) {
				warnx("ramp servo value mismatch");
				return 1;
			}

			/* check post ramp phase */
			if (hrt_elapsed_time(&starttime) > RAMP_TIME_US &&
				fabsf(servo_predicted[i] - r_page_servos[i]) > 2) {
				printf("\t %d: %8.4f predicted: %d, servo: %d\n", i, outputs[i], servo_predicted[i], (int)r_page_servos[i]);
				warnx("mixer violated predicted value");
				return 1;
			}

			//printf("\t %d: %8.4f limited: %8.4f, servo: %d\n", i, outputs_unlimited[i], outputs[i], (int)r_page_servos[i]);
		}
		usleep(sleep_quantum_us);
		sleepcount++;

		if (sleepcount % 10 == 0) {
			printf(".");
			fflush(stdout);
		}
	}
	printf("\n");

	/* load multirotor at once test */
	mixer_group.reset();

	if (argc > 2)
		filename = argv[2];
	else
		filename = "/etc/mixers/FMU_quad_w.mix";

	load_mixer_file(filename, &buf[0], sizeof(buf));
	loaded = strlen(buf);

	warnx("loaded: \n\"%s\"\n (%d chars)", &buf[0], loaded);

	unsigned mc_loaded = loaded;
	mixer_group.load_from_buf(&buf[0], mc_loaded);
	warnx("complete buffer load: loaded %u mixers", mixer_group.count());
	if (mixer_group.count() != 5) {
		warnx("FAIL: Quad W mixer load failed");
		return 1;
	}

	warnx("SUCCESS: No errors in mixer test");
}
예제 #2
0
파일: px4io.c 프로젝트: PX4-Works/Firmware
int
user_start(int argc, char *argv[])
{
	/* run C++ ctors before we go any further */
	up_cxxinitialize();

	/* reset all to zero */
	memset(&system_state, 0, sizeof(system_state));

	/* configure the high-resolution time/callout interface */
	hrt_init();

	/* calculate our fw CRC so FMU can decide if we need to update */
	calculate_fw_crc();

	/*
	 * Poll at 1ms intervals for received bytes that have not triggered
	 * a DMA event.
	 */
#ifdef CONFIG_ARCH_DMA
	hrt_call_every(&serial_dma_call, 1000, 1000, (hrt_callout)stm32_serial_dma_poll, NULL);
#endif

	/* print some startup info */
	lowsyslog("\nPX4IO: starting\n");

	/* default all the LEDs to off while we start */
	LED_AMBER(false);
	LED_BLUE(false);
	LED_SAFETY(false);
#ifdef GPIO_LED4
	LED_RING(false);
#endif

	/* turn on servo power (if supported) */
#ifdef POWER_SERVO
	POWER_SERVO(true);
#endif

	/* turn off S.Bus out (if supported) */
#ifdef ENABLE_SBUS_OUT
	ENABLE_SBUS_OUT(false);
#endif

	/* start the safety switch handler */
	safety_init();

	/* configure the first 8 PWM outputs (i.e. all of them) */
	up_pwm_servo_init(0xff);

	/* initialise the control inputs */
	controls_init();

	/* set up the ADC */
	adc_init();

	/* start the FMU interface */
	interface_init();

	/* add a performance counter for mixing */
	perf_counter_t mixer_perf = perf_alloc(PC_ELAPSED, "mix");

	/* add a performance counter for controls */
	perf_counter_t controls_perf = perf_alloc(PC_ELAPSED, "controls");

	/* and one for measuring the loop rate */
	perf_counter_t loop_perf = perf_alloc(PC_INTERVAL, "loop");

	struct mallinfo minfo = mallinfo();
	lowsyslog("MEM: free %u, largest %u\n", minfo.mxordblk, minfo.fordblks);

	/* initialize PWM limit lib */
	pwm_limit_init(&pwm_limit);

	/*
	 *    P O L I C E    L I G H T S
	 *
	 * Not enough memory, lock down.
	 *
	 * We might need to allocate mixers later, and this will
	 * ensure that a developer doing a change will notice
	 * that he just burned the remaining RAM with static
	 * allocations. We don't want him to be able to
	 * get past that point. This needs to be clearly
	 * documented in the dev guide.
	 *
	 */
	if (minfo.mxordblk < 600) {

		lowsyslog("ERR: not enough MEM");
		bool phase = false;

		while (true) {

			if (phase) {
				LED_AMBER(true);
				LED_BLUE(false);

			} else {
				LED_AMBER(false);
				LED_BLUE(true);
			}

			up_udelay(250000);

			phase = !phase;
		}
	}

	/* Start the failsafe led init */
	failsafe_led_init();

	/*
	 * Run everything in a tight loop.
	 */

	uint64_t last_debug_time = 0;
	uint64_t last_heartbeat_time = 0;

	for (;;) {

		/* track the rate at which the loop is running */
		perf_count(loop_perf);

		/* kick the mixer */
		perf_begin(mixer_perf);
		mixer_tick();
		perf_end(mixer_perf);

		/* kick the control inputs */
		perf_begin(controls_perf);
		controls_tick();
		perf_end(controls_perf);

		if ((hrt_absolute_time() - last_heartbeat_time) > 250 * 1000) {
			last_heartbeat_time = hrt_absolute_time();
			heartbeat_blink();
		}

		ring_blink();

		check_reboot();

		/* check for debug activity (default: none) */
		show_debug_messages();

		/* post debug state at ~1Hz - this is via an auxiliary serial port
		 * DEFAULTS TO OFF!
		 */
		if (hrt_absolute_time() - last_debug_time > (1000 * 1000)) {

			isr_debug(1, "d:%u s=0x%x a=0x%x f=0x%x m=%u",
				  (unsigned)r_page_setup[PX4IO_P_SETUP_SET_DEBUG],
				  (unsigned)r_status_flags,
				  (unsigned)r_setup_arming,
				  (unsigned)r_setup_features,
				  (unsigned)mallinfo().mxordblk);
			last_debug_time = hrt_absolute_time();
		}
	}
}
예제 #3
0
/**
 * Main loop function
 */
void
PCA9685::i2cpwm()
{
	if (_mode == IOX_MODE_TEST_OUT) {
		setPin(0, PCA9685_PWMCENTER);
		_should_run = true;

	} else if (_mode == IOX_MODE_OFF) {
		_should_run = false;

	} else {
		if (!_mode_on_initialized) {
			// Init PWM limits
			pwm_limit_init(&_pwm_limit);

			// Get arming state
			_armed_sub = orb_subscribe(ORB_ID(actuator_armed));

			/* Subscribe to actuator groups */
			subscribe();

			/* set the uorb update interval lower than the driver pwm interval */
			for (unsigned i = 0; i < actuator_controls_s::NUM_ACTUATOR_CONTROL_GROUPS; ++i) {
				orb_set_interval(_control_subs[i], 1000.0f / PCA9685_PWMFREQ - 5);
			}

			_mode_on_initialized = true;
		}

		/* check if anything updated */
		int ret = ::poll(_poll_fds, _poll_fds_num, 0);

		if (ret < 0) {
			DEVICE_LOG("poll error %d", errno);

		} else if (ret == 0) {
	//			warnx("no PWM: failsafe");
		} else {
			/* get controls for required topics */
			unsigned poll_id = 0;

			for (unsigned i = 0; i < actuator_controls_s::NUM_ACTUATOR_CONTROL_GROUPS; i++) {
				if (_control_subs[i] > 0) {
					if (_poll_fds[poll_id].revents & POLLIN) {
						orb_copy(_control_topics[i], _control_subs[i], &_controls[i]);
					}
				}
				poll_id++;
			}

			if (_mixers != nullptr) {
				size_t num_outputs = actuator_outputs_s::NUM_ACTUATOR_OUTPUTS;

				// do mixing
				num_outputs = _mixers->mix(_outputs, num_outputs, NULL);

				// disable unused ports by setting their output to NaN
				for (size_t i = 0; i < sizeof(_outputs) / sizeof(_outputs[0]); i++) {
					if (i >= num_outputs) {
						_outputs[i] = NAN_VALUE;
					}
				}

				// Finally, write servo values to motors
				for (int i = 0; i < num_outputs; i++) {
					uint16_t new_value = PCA9685_PWMCENTER +
								 (_outputs[i] * M_PI_F * PCA9685_SCALE);
					// DEVICE_DEBUG("%d: current: %u, new %u, control %.2f", i, _current_values[i], new_value,
					//      (double)_controls[1].control[i]);

					if (isfinite(new_value) &&
						new_value >= PCA9685_PWMMIN &&
						new_value <= PCA9685_PWMMAX) {

						setPin(i, new_value);
						_rates[i] = new_value;
					}
				}
			}
		}

		bool updated;

		// Update Arming state
		orb_check(_armed_sub, &updated);
		if (updated) {
			orb_copy(ORB_ID(actuator_armed), _armed_sub, &_armed);

			bool set_armed = (_armed.armed || _armed.prearmed) && !_armed.lockdown;

			if (_servo_armed != set_armed) {
				_servo_armed = set_armed;
			}
		}

		// Update AUX controls update
		// orb_check(_actuator_controls_sub, &updated);
		// if (updated) {
		// 	size_t num_outputs = actuator_outputs_s::NUM_ACTUATOR_OUTPUTS;
		//
		// 	// Get updated actuator
		// 	// Only update actuator 1 for now
		// 	orb_copy(ORB_ID(actuator_controls_1), _actuator_controls_sub, &_controls[1]);
		//
		//
		// }

		_should_run = true;
	}

	// check if any activity remains, else stop
	if (!_should_run) {
		_running = false;
		return;
	}

	// re-queue ourselves to run again later
	_running = true;
	work_queue(LPWORK, &_work, (worker_t)&PCA9685::i2cpwm_trampoline, this, _i2cpwm_interval);
}
예제 #4
0
void
PX4FMU::task_main()
{
	/* force a reset of the update rate */
	_current_update_rate = 0;

	_armed_sub = orb_subscribe(ORB_ID(actuator_armed));
	_param_sub = orb_subscribe(ORB_ID(parameter_update));

	/* advertise the mixed control outputs */
	actuator_outputs_s outputs;
	memset(&outputs, 0, sizeof(outputs));

#ifdef HRT_PPM_CHANNEL
	// rc input, published to ORB
	struct rc_input_values rc_in;
	orb_advert_t to_input_rc = 0;

	memset(&rc_in, 0, sizeof(rc_in));
	rc_in.input_source = RC_INPUT_SOURCE_PX4FMU_PPM;
#endif

	/* initialize PWM limit lib */
	pwm_limit_init(&_pwm_limit);

	update_pwm_rev_mask();

	/* loop until killed */
	while (!_task_should_exit) {
		if (_groups_subscribed != _groups_required) {
			subscribe();
			_groups_subscribed = _groups_required;
			/* force setting update rate */
			_current_update_rate = 0;
		}

		/*
		 * Adjust actuator topic update rate to keep up with
		 * the highest servo update rate configured.
		 *
		 * We always mix at max rate; some channels may update slower.
		 */
		unsigned max_rate = (_pwm_default_rate > _pwm_alt_rate) ? _pwm_default_rate : _pwm_alt_rate;

		if (_current_update_rate != max_rate) {
			_current_update_rate = max_rate;
			int update_rate_in_ms = int(1000 / _current_update_rate);

			/* reject faster than 500 Hz updates */
			if (update_rate_in_ms < 2) {
				update_rate_in_ms = 2;
			}

			/* reject slower than 10 Hz updates */
			if (update_rate_in_ms > 100) {
				update_rate_in_ms = 100;
			}

			debug("adjusted actuator update interval to %ums", update_rate_in_ms);
			for (unsigned i = 0; i < actuator_controls_s::NUM_ACTUATOR_CONTROL_GROUPS; i++) {
				if (_control_subs[i] > 0) {
					orb_set_interval(_control_subs[i], update_rate_in_ms);
				}
			}

			// set to current max rate, even if we are actually checking slower/faster
			_current_update_rate = max_rate;
		}

		/* sleep waiting for data, stopping to check for PPM
		 * input at 50Hz */
		int ret = ::poll(_poll_fds, _poll_fds_num, CONTROL_INPUT_DROP_LIMIT_MS);

		/* this would be bad... */
		if (ret < 0) {
			log("poll error %d", errno);
			continue;

		} else if (ret == 0) {
			/* timeout: no control data, switch to failsafe values */
//			warnx("no PWM: failsafe");

		} else {

			/* get controls for required topics */
			unsigned poll_id = 0;
			for (unsigned i = 0; i < actuator_controls_s::NUM_ACTUATOR_CONTROL_GROUPS; i++) {
				if (_control_subs[i] > 0) {
					if (_poll_fds[poll_id].revents & POLLIN) {
						orb_copy(_control_topics[i], _control_subs[i], &_controls[i]);
					}
					poll_id++;
				}
			}

			/* can we mix? */
			if (_mixers != nullptr) {

				unsigned num_outputs;

				switch (_mode) {
				case MODE_2PWM:
					num_outputs = 2;
					break;

				case MODE_4PWM:
					num_outputs = 4;
					break;

				case MODE_6PWM:
					num_outputs = 6;
					break;

				case MODE_8PWM:
					num_outputs = 8;
					break;
				default:
					num_outputs = 0;
					break;
				}

				/* do mixing */
				outputs.noutputs = _mixers->mix(&outputs.output[0], num_outputs, NULL);
				outputs.timestamp = hrt_absolute_time();

				/* iterate actuators */
				for (unsigned i = 0; i < num_outputs; i++) {
					/* last resort: catch NaN and INF */
					if ((i >= outputs.noutputs) ||
						!isfinite(outputs.output[i])) {
						/*
						 * Value is NaN, INF or out of band - set to the minimum value.
						 * This will be clearly visible on the servo status and will limit the risk of accidentally
						 * spinning motors. It would be deadly in flight.
						 */
						outputs.output[i] = -1.0f;
					}
				}

				uint16_t pwm_limited[num_outputs];

				/* the PWM limit call takes care of out of band errors and constrains */
				pwm_limit_calc(_servo_armed, num_outputs, _reverse_pwm_mask, _disarmed_pwm, _min_pwm, _max_pwm, outputs.output, pwm_limited, &_pwm_limit);

				/* output to the servos */
				for (unsigned i = 0; i < num_outputs; i++) {
					up_pwm_servo_set(i, pwm_limited[i]);
				}

				/* publish mixed control outputs */
				if (_outputs_pub != nullptr) {
					_outputs_pub = orb_advertise_multi(ORB_ID(actuator_outputs), &outputs, &_actuator_output_topic_instance, ORB_PRIO_DEFAULT);
				} else {

					orb_publish(ORB_ID(actuator_outputs), _outputs_pub, &outputs);
				}
			}
		}

		/* check arming state */
		bool updated = false;
		orb_check(_armed_sub, &updated);

		if (updated) {
			orb_copy(ORB_ID(actuator_armed), _armed_sub, &_armed);

			/* update the armed status and check that we're not locked down */
			bool set_armed = _armed.armed && !_armed.lockdown;

			if (_servo_armed != set_armed)
				_servo_armed = set_armed;

			/* update PWM status if armed or if disarmed PWM values are set */
			bool pwm_on = (_armed.armed || _num_disarmed_set > 0);

			if (_pwm_on != pwm_on) {
				_pwm_on = pwm_on;
				up_pwm_servo_arm(pwm_on);
			}
		}

		orb_check(_param_sub, &updated);
		if (updated) {
			parameter_update_s pupdate;
			orb_copy(ORB_ID(parameter_update), _param_sub, &pupdate);

			update_pwm_rev_mask();
		}

#ifdef HRT_PPM_CHANNEL

		// see if we have new PPM input data
		if (ppm_last_valid_decode != rc_in.timestamp_last_signal) {
			// we have a new PPM frame. Publish it.
			rc_in.channel_count = ppm_decoded_channels;

			if (rc_in.channel_count > RC_INPUT_MAX_CHANNELS) {
				rc_in.channel_count = RC_INPUT_MAX_CHANNELS;
			}

			for (uint8_t i = 0; i < rc_in.channel_count; i++) {
				rc_in.values[i] = ppm_buffer[i];
			}

			rc_in.timestamp_publication = ppm_last_valid_decode;
			rc_in.timestamp_last_signal = ppm_last_valid_decode;

			rc_in.rc_ppm_frame_length = ppm_frame_length;
			rc_in.rssi = RC_INPUT_RSSI_MAX;
			rc_in.rc_failsafe = false;
			rc_in.rc_lost = false;
			rc_in.rc_lost_frame_count = 0;
			rc_in.rc_total_frame_count = 0;

			/* lazily advertise on first publication */
			if (to_input_rc == 0) {
				to_input_rc = orb_advertise(ORB_ID(input_rc), &rc_in);

			} else {
				orb_publish(ORB_ID(input_rc), to_input_rc, &rc_in);
			}
		}

#endif

	}

	for (unsigned i = 0; i < actuator_controls_s::NUM_ACTUATOR_CONTROL_GROUPS; i++) {
		if (_control_subs[i] > 0) {
			::close(_control_subs[i]);
			_control_subs[i] = -1;
		}
	}
	::close(_armed_sub);
	::close(_param_sub);

	/* make sure servos are off */
	up_pwm_servo_deinit();

	log("stopping");

	/* note - someone else is responsible for restoring the GPIO config */

	/* tell the dtor that we are exiting */
	_task = -1;
	_exit(0);
}
예제 #5
0
void task_main(int argc, char *argv[])
{
	_is_running = true;

	if (uart_initialize(_device) < 0) {
		PX4_ERR("Failed to initialize UART.");
		return;
	}

	// Subscribe for orb topics
	_controls_sub = orb_subscribe(ORB_ID(actuator_controls_0));
	_armed_sub = orb_subscribe(ORB_ID(actuator_armed));

	// Start disarmed
	_armed.armed = false;
	_armed.prearmed = false;

	// Set up poll topic
	px4_pollfd_struct_t fds[1];
	fds[0].fd     = _controls_sub;
	fds[0].events = POLLIN;
	/* Don't limit poll intervall for now, 250 Hz should be fine. */
	//orb_set_interval(_controls_sub, 10);

	// Set up mixer
	if (initialize_mixer(MIXER_FILENAME) < 0) {
		PX4_ERR("Mixer initialization failed.");
		return;
	}

	pwm_limit_init(&_pwm_limit);

	// TODO XXX: this is needed otherwise we crash in the callback context.
	_rc_pub = orb_advertise(ORB_ID(input_rc), &_rc);

	// Main loop
	while (!_task_should_exit) {

		int pret = px4_poll(&fds[0], (sizeof(fds) / sizeof(fds[0])), 10);

		/* Timed out, do a periodic check for _task_should_exit. */
		if (pret == 0) {
			continue;
		}

		/* This is undesirable but not much we can do. */
		if (pret < 0) {
			PX4_WARN("poll error %d, %d", pret, errno);
			/* sleep a bit before next try */
			usleep(100000);
			continue;
		}

		if (fds[0].revents & POLLIN) {
			orb_copy(ORB_ID(actuator_controls_0), _controls_sub, &_controls);

			_outputs.timestamp = _controls.timestamp;

			/* do mixing */
			_outputs.noutputs = _mixer->mix(_outputs.output, 0 /* not used */, NULL);

			/* disable unused ports by setting their output to NaN */
			for (size_t i = _outputs.noutputs; i < sizeof(_outputs.output) / sizeof(_outputs.output[0]); i++) {
				_outputs.output[i] = NAN;
			}

			const uint16_t reverse_mask = 0;
			// TODO FIXME: these should probably be params
			const uint16_t disarmed_pwm[4] = {900, 900, 900, 900};
			const uint16_t min_pwm[4] = {1230, 1230, 1230, 1230};
			const uint16_t max_pwm[4] = {1900, 1900, 1900, 1900};
			uint16_t pwm[4];

			// TODO FIXME: pre-armed seems broken
			pwm_limit_calc(_armed.armed, false/*_armed.prearmed*/, _outputs.noutputs, reverse_mask,
				       disarmed_pwm, min_pwm, max_pwm, _outputs.output, pwm, &_pwm_limit);


			send_outputs_mavlink(pwm, 4);

			if (_outputs_pub != nullptr) {
				orb_publish(ORB_ID(actuator_outputs), _outputs_pub, &_outputs);

			} else {
				_outputs_pub = orb_advertise(ORB_ID(actuator_outputs), &_outputs);
			}
		}

		bool updated;
		orb_check(_armed_sub, &updated);

		if (updated) {
			orb_copy(ORB_ID(actuator_armed), _armed_sub, &_armed);
		}
	}

	uart_deinitialize();
	orb_unsubscribe(_controls_sub);
	orb_unsubscribe(_armed_sub);

	_is_running = false;

}
예제 #6
0
파일: px4io.c 프로젝트: Aerovinci/Firmware
int
user_start(int argc, char *argv[])
{
	/* configure the first 8 PWM outputs (i.e. all of them) */
	up_pwm_servo_init(0xff);

#if defined(CONFIG_HAVE_CXX) && defined(CONFIG_HAVE_CXXINITIALIZE)

	/* run C++ ctors before we go any further */

	up_cxxinitialize();

#	if defined(CONFIG_EXAMPLES_NSH_CXXINITIALIZE)
#  		error CONFIG_EXAMPLES_NSH_CXXINITIALIZE Must not be defined! Use CONFIG_HAVE_CXX and CONFIG_HAVE_CXXINITIALIZE.
#	endif

#else
#  error platform is dependent on c++ both CONFIG_HAVE_CXX and CONFIG_HAVE_CXXINITIALIZE must be defined.
#endif

	/* reset all to zero */
	memset(&system_state, 0, sizeof(system_state));

	/* configure the high-resolution time/callout interface */
	hrt_init();

	/* calculate our fw CRC so FMU can decide if we need to update */
	calculate_fw_crc();

	/*
	 * Poll at 1ms intervals for received bytes that have not triggered
	 * a DMA event.
	 */
#ifdef CONFIG_ARCH_DMA
	hrt_call_every(&serial_dma_call, 1000, 1000, (hrt_callout)stm32_serial_dma_poll, NULL);
#endif

	/* print some startup info */
	syslog(LOG_INFO, "\nPX4IO: starting\n");

	/* default all the LEDs to off while we start */
	LED_AMBER(false);
	LED_BLUE(false);
	LED_SAFETY(false);
#ifdef GPIO_LED4
	LED_RING(false);
#endif

	/* turn on servo power (if supported) */
#ifdef POWER_SERVO
	POWER_SERVO(true);
#endif

	/* turn off S.Bus out (if supported) */
#ifdef ENABLE_SBUS_OUT
	ENABLE_SBUS_OUT(false);
#endif

	/* start the safety switch handler */
	safety_init();

	/* initialise the control inputs */
	controls_init();

	/* set up the ADC */
	adc_init();

	/* start the FMU interface */
	interface_init();

	/* add a performance counter for mixing */
	perf_counter_t mixer_perf = perf_alloc(PC_ELAPSED, "mix");

	/* add a performance counter for controls */
	perf_counter_t controls_perf = perf_alloc(PC_ELAPSED, "controls");

	/* and one for measuring the loop rate */
	perf_counter_t loop_perf = perf_alloc(PC_INTERVAL, "loop");

	struct mallinfo minfo = mallinfo();
	r_page_status[PX4IO_P_STATUS_FREEMEM] = minfo.mxordblk;
	syslog(LOG_INFO, "MEM: free %u, largest %u\n", minfo.mxordblk, minfo.fordblks);

	/* initialize PWM limit lib */
	pwm_limit_init(&pwm_limit);

	/*
	 *    P O L I C E    L I G H T S
	 *
	 * Not enough memory, lock down.
	 *
	 * We might need to allocate mixers later, and this will
	 * ensure that a developer doing a change will notice
	 * that he just burned the remaining RAM with static
	 * allocations. We don't want him to be able to
	 * get past that point. This needs to be clearly
	 * documented in the dev guide.
	 *
	 */
	if (minfo.mxordblk < 600) {

		syslog(LOG_ERR, "ERR: not enough MEM");
		bool phase = false;

		while (true) {

			if (phase) {
				LED_AMBER(true);
				LED_BLUE(false);

			} else {
				LED_AMBER(false);
				LED_BLUE(true);
			}

			up_udelay(250000);

			phase = !phase;
		}
	}

	/* Start the failsafe led init */
	failsafe_led_init();

	/*
	 * Run everything in a tight loop.
	 */

	uint64_t last_debug_time = 0;
	uint64_t last_heartbeat_time = 0;
	uint64_t last_loop_time = 0;

	for (;;) {
		dt = (hrt_absolute_time() - last_loop_time) / 1000000.0f;
		last_loop_time = hrt_absolute_time();

		if (dt < 0.0001f) {
			dt = 0.0001f;

		} else if (dt > 0.02f) {
			dt = 0.02f;
		}

		/* track the rate at which the loop is running */
		perf_count(loop_perf);

		/* kick the mixer */
		perf_begin(mixer_perf);
		mixer_tick();
		perf_end(mixer_perf);

		/* kick the control inputs */
		perf_begin(controls_perf);
		controls_tick();
		perf_end(controls_perf);

		/* some boards such as Pixhawk 2.1 made
		   the unfortunate choice to combine the blue led channel with
		   the IMU heater. We need a software hack to fix the hardware hack
		   by allowing to disable the LED / heater.
		 */
		if (r_page_setup[PX4IO_P_SETUP_THERMAL] == PX4IO_THERMAL_IGNORE) {
			/*
			  blink blue LED at 4Hz in normal operation. When in
			  override blink 4x faster so the user can clearly see
			  that override is happening. This helps when
			  pre-flight testing the override system
			 */
			uint32_t heartbeat_period_us = 250 * 1000UL;

			if (r_status_flags & PX4IO_P_STATUS_FLAGS_OVERRIDE) {
				heartbeat_period_us /= 4;
			}

			if ((hrt_absolute_time() - last_heartbeat_time) > heartbeat_period_us) {
				last_heartbeat_time = hrt_absolute_time();
				heartbeat_blink();
			}

		} else if (r_page_setup[PX4IO_P_SETUP_THERMAL] < PX4IO_THERMAL_FULL) {
			/* switch resistive heater off */
			LED_BLUE(false);

		} else {
			/* switch resistive heater hard on */
			LED_BLUE(true);
		}

		update_mem_usage();

		ring_blink();

		check_reboot();

		/* check for debug activity (default: none) */
		show_debug_messages();

		/* post debug state at ~1Hz - this is via an auxiliary serial port
		 * DEFAULTS TO OFF!
		 */
		if (hrt_absolute_time() - last_debug_time > (1000 * 1000)) {

			isr_debug(1, "d:%u s=0x%x a=0x%x f=0x%x m=%u",
				  (unsigned)r_page_setup[PX4IO_P_SETUP_SET_DEBUG],
				  (unsigned)r_status_flags,
				  (unsigned)r_setup_arming,
				  (unsigned)r_setup_features,
				  (unsigned)mallinfo().mxordblk);
			last_debug_time = hrt_absolute_time();
		}
	}
}
예제 #7
0
bool MixerTest::mixerTest()
{
	/*
	 * PWM limit structure
	 */
	pwm_limit_t pwm_limit;
	bool should_arm = false;
	uint16_t r_page_servo_disarmed[output_max];
	uint16_t r_page_servo_control_min[output_max];
	uint16_t r_page_servo_control_max[output_max];
	uint16_t r_page_servos[output_max];
	uint16_t servo_predicted[output_max];
	int16_t reverse_pwm_mask = 0;

	bool load_ok = load_mixer(MIXER_PATH(IO_pass.mix), 8);

	if (!load_ok) {
		return load_ok;
	}

	/* execute the mixer */

	float	outputs[output_max];
	unsigned mixed;
	const int jmax = 5;

	pwm_limit_init(&pwm_limit);

	/* run through arming phase */
	for (unsigned i = 0; i < output_max; i++) {
		actuator_controls[i] = 0.1f;
		r_page_servo_disarmed[i] = PWM_MOTOR_OFF;
		r_page_servo_control_min[i] = PWM_DEFAULT_MIN;
		r_page_servo_control_max[i] = PWM_DEFAULT_MAX;
	}

	//PX4_INFO("PRE-ARM TEST: DISABLING SAFETY");

	/* mix */
	should_prearm = true;
	mixed = mixer_group.mix(&outputs[0], output_max, nullptr);

	pwm_limit_calc(should_arm, should_prearm, mixed, reverse_pwm_mask, r_page_servo_disarmed, r_page_servo_control_min,
		       r_page_servo_control_max, outputs, r_page_servos, &pwm_limit);

	//warnx("mixed %d outputs (max %d), values:", mixed, output_max);
	for (unsigned i = 0; i < mixed; i++) {

		//fprintf(stderr, "pre-arm:\t %d: out: %8.4f, servo: %d \n", i, (double)outputs[i], (int)r_page_servos[i]);

		if (i != actuator_controls_s::INDEX_THROTTLE) {
			if (r_page_servos[i] < r_page_servo_control_min[i]) {
				warnx("active servo < min");
				return false;
			}

		} else {
			if (r_page_servos[i] != r_page_servo_disarmed[i]) {
				warnx("throttle output != 0 (this check assumed the IO pass mixer!)");
				return false;
			}
		}
	}

	should_arm = true;
	should_prearm = false;

	/* simulate another orb_copy() from actuator controls */
	for (unsigned i = 0; i < output_max; i++) {
		actuator_controls[i] = 0.1f;
	}

	//PX4_INFO("ARMING TEST: STARTING RAMP");
	unsigned sleep_quantum_us = 10000;

	hrt_abstime starttime = hrt_absolute_time();
	unsigned sleepcount = 0;

	while (hrt_elapsed_time(&starttime) < INIT_TIME_US + RAMP_TIME_US + 2 * sleep_quantum_us) {

		/* mix */
		mixed = mixer_group.mix(&outputs[0], output_max, nullptr);

		pwm_limit_calc(should_arm, should_prearm, mixed, reverse_pwm_mask, r_page_servo_disarmed, r_page_servo_control_min,
			       r_page_servo_control_max, outputs, r_page_servos, &pwm_limit);

		//warnx("mixed %d outputs (max %d), values:", mixed, output_max);
		for (unsigned i = 0; i < mixed; i++) {

			//fprintf(stderr, "ramp:\t %d: out: %8.4f, servo: %d \n", i, (double)outputs[i], (int)r_page_servos[i]);

			/* check mixed outputs to be zero during init phase */
			if (hrt_elapsed_time(&starttime) < INIT_TIME_US &&
			    r_page_servos[i] != r_page_servo_disarmed[i]) {
				PX4_ERR("disarmed servo value mismatch: %d vs %d", r_page_servos[i], r_page_servo_disarmed[i]);
				return false;
			}

			if (hrt_elapsed_time(&starttime) >= INIT_TIME_US &&
			    r_page_servos[i] + 1 <= r_page_servo_disarmed[i]) {
				PX4_ERR("ramp servo value mismatch");
				return false;
			}
		}

		usleep(sleep_quantum_us);
		sleepcount++;

		if (sleepcount % 10 == 0) {
			fflush(stdout);
		}
	}

	//PX4_INFO("ARMING TEST: NORMAL OPERATION");

	for (int j = -jmax; j <= jmax; j++) {

		for (unsigned i = 0; i < output_max; i++) {
			actuator_controls[i] = j / 10.0f + 0.1f * i;
			r_page_servo_disarmed[i] = PWM_LOWEST_MIN;
			r_page_servo_control_min[i] = PWM_DEFAULT_MIN;
			r_page_servo_control_max[i] = PWM_DEFAULT_MAX;
		}

		/* mix */
		mixed = mixer_group.mix(&outputs[0], output_max, nullptr);

		pwm_limit_calc(should_arm, should_prearm, mixed, reverse_pwm_mask, r_page_servo_disarmed, r_page_servo_control_min,
			       r_page_servo_control_max, outputs, r_page_servos, &pwm_limit);

		//fprintf(stderr, "mixed %d outputs (max %d)", mixed, output_max);

		for (unsigned i = 0; i < mixed; i++) {
			servo_predicted[i] = 1500 + outputs[i] * (r_page_servo_control_max[i] - r_page_servo_control_min[i]) / 2.0f;

			if (abs(servo_predicted[i] - r_page_servos[i]) > MIXER_DIFFERENCE_THRESHOLD) {
				fprintf(stderr, "\t %d: %8.4f predicted: %d, servo: %d\n", i, (double)outputs[i], servo_predicted[i],
					(int)r_page_servos[i]);
				PX4_ERR("mixer violated predicted value");
				return false;
			}
		}
	}

	//PX4_INFO("ARMING TEST: DISARMING");

	starttime = hrt_absolute_time();
	sleepcount = 0;
	should_arm = false;

	while (hrt_elapsed_time(&starttime) < 600000) {

		/* mix */
		mixed = mixer_group.mix(&outputs[0], output_max, nullptr);

		pwm_limit_calc(should_arm, should_prearm, mixed, reverse_pwm_mask, r_page_servo_disarmed, r_page_servo_control_min,
			       r_page_servo_control_max, outputs, r_page_servos, &pwm_limit);

		//warnx("mixed %d outputs (max %d), values:", mixed, output_max);
		for (unsigned i = 0; i < mixed; i++) {

			//fprintf(stderr, "disarmed:\t %d: out: %8.4f, servo: %d \n", i, (double)outputs[i], (int)r_page_servos[i]);

			/* check mixed outputs to be zero during init phase */
			if (r_page_servos[i] != r_page_servo_disarmed[i]) {
				PX4_ERR("disarmed servo value mismatch");
				return false;
			}
		}

		usleep(sleep_quantum_us);
		sleepcount++;

		if (sleepcount % 10 == 0) {
			//printf(".");
			//fflush(stdout);
		}
	}

	//printf("\n");

	//PX4_INFO("ARMING TEST: REARMING: STARTING RAMP");

	starttime = hrt_absolute_time();
	sleepcount = 0;
	should_arm = true;

	while (hrt_elapsed_time(&starttime) < 600000 + RAMP_TIME_US) {

		/* mix */
		mixed = mixer_group.mix(&outputs[0], output_max, nullptr);

		pwm_limit_calc(should_arm, should_prearm, mixed, reverse_pwm_mask, r_page_servo_disarmed, r_page_servo_control_min,
			       r_page_servo_control_max, outputs, r_page_servos, &pwm_limit);

		//warnx("mixed %d outputs (max %d), values:", mixed, output_max);
		for (unsigned i = 0; i < mixed; i++) {
			/* predict value */
			servo_predicted[i] = 1500 + outputs[i] * (r_page_servo_control_max[i] - r_page_servo_control_min[i]) / 2.0f;

			/* check ramp */

			//fprintf(stderr, "ramp:\t %d: out: %8.4f, servo: %d \n", i, (double)outputs[i], (int)r_page_servos[i]);

			if (hrt_elapsed_time(&starttime) < RAMP_TIME_US &&
			    (r_page_servos[i] + 1 <= r_page_servo_disarmed[i] ||
			     r_page_servos[i] > servo_predicted[i])) {
				PX4_ERR("ramp servo value mismatch");
				return false;
			}

			/* check post ramp phase */
			if (hrt_elapsed_time(&starttime) > RAMP_TIME_US &&
			    abs(servo_predicted[i] - r_page_servos[i]) > 2) {
				printf("\t %d: %8.4f predicted: %d, servo: %d\n", i, (double)outputs[i], servo_predicted[i], (int)r_page_servos[i]);
				PX4_ERR("mixer violated predicted value");
				return false;
			}
		}

		usleep(sleep_quantum_us);
		sleepcount++;

		if (sleepcount % 10 == 0) {
			//	printf(".");
			//	fflush(stdout);
		}
	}

	return true;
}
예제 #8
0
int test_mixer(int argc, char *argv[])
{
	/*
	 * PWM limit structure
	 */
	pwm_limit_t pwm_limit;
	bool should_arm = false;
	uint16_t r_page_servo_disarmed[output_max];
	uint16_t r_page_servo_control_min[output_max];
	uint16_t r_page_servo_control_max[output_max];
	uint16_t r_page_servos[output_max];
	uint16_t servo_predicted[output_max];
	int16_t reverse_pwm_mask = 0;

	//PX4_INFO("testing mixer");

#if !defined(CONFIG_ARCH_BOARD_SITL)
	const char *filename = "/etc/mixers/IO_pass.mix";
#else
	const char *filename = "ROMFS/px4fmu_test/mixers/IO_pass.mix";
#endif

	//PX4_INFO("loading: %s", filename);

	char		buf[2048];

	load_mixer_file(filename, &buf[0], sizeof(buf));
	unsigned loaded = strlen(buf);

	//fprintf(stderr, "loaded: \n\"%s\"\n (%d chars)", &buf[0], loaded);

	/* load the mixer in chunks, like
	 * in the case of a remote load,
	 * e.g. on PX4IO.
	 */

	const unsigned chunk_size = 64;

	MixerGroup mixer_group(mixer_callback, 0);

	/* load at once test */
	unsigned xx = loaded;
	mixer_group.load_from_buf(&buf[0], xx);
	//ASSERT_EQ(mixer_group.count(), 8);

	unsigned empty_load = 2;
	char empty_buf[2];
	empty_buf[0] = ' ';
	empty_buf[1] = '\0';
	mixer_group.reset();
	mixer_group.load_from_buf(&empty_buf[0], empty_load);
	//PX4_INFO("empty buffer load: loaded %u mixers, used: %u", mixer_group.count(), empty_load);

	//ASSERT_NE(empty_load, 0);

	if (empty_load != 0) {
		return 1;
	}

	/* FIRST mark the mixer as invalid */
	/* THEN actually delete it */
	mixer_group.reset();
	char mixer_text[256];		/* large enough for one mixer */
	unsigned mixer_text_length = 0;

	unsigned transmitted = 0;

	//PX4_INFO("transmitted: %d, loaded: %d", transmitted, loaded);

	while (transmitted < loaded) {

		unsigned text_length = (loaded - transmitted > chunk_size) ? chunk_size : loaded - transmitted;

		/* check for overflow - this would be really fatal */
		if ((mixer_text_length + text_length + 1) > sizeof(mixer_text)) {
			return 1;
		}

		/* append mixer text and nul-terminate */
		memcpy(&mixer_text[mixer_text_length], &buf[transmitted], text_length);
		mixer_text_length += text_length;
		mixer_text[mixer_text_length] = '\0';
		//fprintf(stderr, "buflen %u, text:\n\"%s\"", mixer_text_length, &mixer_text[0]);

		/* process the text buffer, adding new mixers as their descriptions can be parsed */
		unsigned resid = mixer_text_length;
		mixer_group.load_from_buf(&mixer_text[0], resid);

		/* if anything was parsed */
		if (resid != mixer_text_length) {
			//fprintf(stderr, "used %u", mixer_text_length - resid);

			/* copy any leftover text to the base of the buffer for re-use */
			if (resid > 0) {
				memcpy(&mixer_text[0], &mixer_text[mixer_text_length - resid], resid);
			}

			mixer_text_length = resid;
		}

		transmitted += text_length;
	}

	//PX4_INFO("chunked load: loaded %u mixers", mixer_group.count());

	if (mixer_group.count() != 8) {
		return 1;
	}

	/* execute the mixer */

	float	outputs[output_max];
	unsigned mixed;
	const int jmax = 5;

	pwm_limit_init(&pwm_limit);

	/* run through arming phase */
	for (unsigned i = 0; i < output_max; i++) {
		actuator_controls[i] = 0.1f;
		r_page_servo_disarmed[i] = PWM_MOTOR_OFF;
		r_page_servo_control_min[i] = PWM_DEFAULT_MIN;
		r_page_servo_control_max[i] = PWM_DEFAULT_MAX;
	}

	//PX4_INFO("PRE-ARM TEST: DISABLING SAFETY");

	/* mix */
	should_prearm = true;
	mixed = mixer_group.mix(&outputs[0], output_max, NULL);

	pwm_limit_calc(should_arm, should_prearm, mixed, reverse_pwm_mask, r_page_servo_disarmed, r_page_servo_control_min,
		       r_page_servo_control_max, outputs, r_page_servos, &pwm_limit);

	//warnx("mixed %d outputs (max %d), values:", mixed, output_max);
	for (unsigned i = 0; i < mixed; i++) {

		//fprintf(stderr, "pre-arm:\t %d: out: %8.4f, servo: %d \n", i, (double)outputs[i], (int)r_page_servos[i]);

		if (i != actuator_controls_s::INDEX_THROTTLE) {
			if (r_page_servos[i] < r_page_servo_control_min[i]) {
				warnx("active servo < min");
				return 1;
			}

		} else {
			if (r_page_servos[i] != r_page_servo_disarmed[i]) {
				warnx("throttle output != 0 (this check assumed the IO pass mixer!)");
				return 1;
			}
		}
	}

	should_arm = true;
	should_prearm = false;

	/* simulate another orb_copy() from actuator controls */
	for (unsigned i = 0; i < output_max; i++) {
		actuator_controls[i] = 0.1f;
	}

	//PX4_INFO("ARMING TEST: STARTING RAMP");
	unsigned sleep_quantum_us = 10000;

	hrt_abstime starttime = hrt_absolute_time();
	unsigned sleepcount = 0;

	while (hrt_elapsed_time(&starttime) < INIT_TIME_US + RAMP_TIME_US + 2 * sleep_quantum_us) {

		/* mix */
		mixed = mixer_group.mix(&outputs[0], output_max, NULL);

		pwm_limit_calc(should_arm, should_prearm, mixed, reverse_pwm_mask, r_page_servo_disarmed, r_page_servo_control_min,
			       r_page_servo_control_max, outputs, r_page_servos, &pwm_limit);

		//warnx("mixed %d outputs (max %d), values:", mixed, output_max);
		for (unsigned i = 0; i < mixed; i++) {

			//fprintf(stderr, "ramp:\t %d: out: %8.4f, servo: %d \n", i, (double)outputs[i], (int)r_page_servos[i]);

			/* check mixed outputs to be zero during init phase */
			if (hrt_elapsed_time(&starttime) < INIT_TIME_US &&
			    r_page_servos[i] != r_page_servo_disarmed[i]) {
				PX4_ERR("disarmed servo value mismatch: %d vs %d", r_page_servos[i], r_page_servo_disarmed[i]);
				return 1;
			}

			if (hrt_elapsed_time(&starttime) >= INIT_TIME_US &&
			    r_page_servos[i] + 1 <= r_page_servo_disarmed[i]) {
				PX4_ERR("ramp servo value mismatch");
				return 1;
			}
		}

		usleep(sleep_quantum_us);
		sleepcount++;

		if (sleepcount % 10 == 0) {
			fflush(stdout);
		}
	}

	//PX4_INFO("ARMING TEST: NORMAL OPERATION");

	for (int j = -jmax; j <= jmax; j++) {

		for (unsigned i = 0; i < output_max; i++) {
			actuator_controls[i] = j / 10.0f + 0.1f * i;
			r_page_servo_disarmed[i] = PWM_LOWEST_MIN;
			r_page_servo_control_min[i] = PWM_DEFAULT_MIN;
			r_page_servo_control_max[i] = PWM_DEFAULT_MAX;
		}

		/* mix */
		mixed = mixer_group.mix(&outputs[0], output_max, NULL);

		pwm_limit_calc(should_arm, should_prearm, mixed, reverse_pwm_mask, r_page_servo_disarmed, r_page_servo_control_min,
			       r_page_servo_control_max, outputs, r_page_servos, &pwm_limit);

		//fprintf(stderr, "mixed %d outputs (max %d)", mixed, output_max);

		for (unsigned i = 0; i < mixed; i++) {
			servo_predicted[i] = 1500 + outputs[i] * (r_page_servo_control_max[i] - r_page_servo_control_min[i]) / 2.0f;

			if (abs(servo_predicted[i] - r_page_servos[i]) > MIXER_DIFFERENCE_THRESHOLD) {
				fprintf(stderr, "\t %d: %8.4f predicted: %d, servo: %d\n", i, (double)outputs[i], servo_predicted[i],
					(int)r_page_servos[i]);
				PX4_ERR("mixer violated predicted value");
				return 1;
			}
		}
	}

	//PX4_INFO("ARMING TEST: DISARMING");

	starttime = hrt_absolute_time();
	sleepcount = 0;
	should_arm = false;

	while (hrt_elapsed_time(&starttime) < 600000) {

		/* mix */
		mixed = mixer_group.mix(&outputs[0], output_max, NULL);

		pwm_limit_calc(should_arm, should_prearm, mixed, reverse_pwm_mask, r_page_servo_disarmed, r_page_servo_control_min,
			       r_page_servo_control_max, outputs, r_page_servos, &pwm_limit);

		//warnx("mixed %d outputs (max %d), values:", mixed, output_max);
		for (unsigned i = 0; i < mixed; i++) {

			//fprintf(stderr, "disarmed:\t %d: out: %8.4f, servo: %d \n", i, (double)outputs[i], (int)r_page_servos[i]);

			/* check mixed outputs to be zero during init phase */
			if (r_page_servos[i] != r_page_servo_disarmed[i]) {
				PX4_ERR("disarmed servo value mismatch");
				return 1;
			}
		}

		usleep(sleep_quantum_us);
		sleepcount++;

		if (sleepcount % 10 == 0) {
			//printf(".");
			//fflush(stdout);
		}
	}

	//printf("\n");

	//PX4_INFO("ARMING TEST: REARMING: STARTING RAMP");

	starttime = hrt_absolute_time();
	sleepcount = 0;
	should_arm = true;

	while (hrt_elapsed_time(&starttime) < 600000 + RAMP_TIME_US) {

		/* mix */
		mixed = mixer_group.mix(&outputs[0], output_max, NULL);

		pwm_limit_calc(should_arm, should_prearm, mixed, reverse_pwm_mask, r_page_servo_disarmed, r_page_servo_control_min,
			       r_page_servo_control_max, outputs, r_page_servos, &pwm_limit);

		//warnx("mixed %d outputs (max %d), values:", mixed, output_max);
		for (unsigned i = 0; i < mixed; i++) {
			/* predict value */
			servo_predicted[i] = 1500 + outputs[i] * (r_page_servo_control_max[i] - r_page_servo_control_min[i]) / 2.0f;

			/* check ramp */

			//fprintf(stderr, "ramp:\t %d: out: %8.4f, servo: %d \n", i, (double)outputs[i], (int)r_page_servos[i]);

			if (hrt_elapsed_time(&starttime) < RAMP_TIME_US &&
			    (r_page_servos[i] + 1 <= r_page_servo_disarmed[i] ||
			     r_page_servos[i] > servo_predicted[i])) {
				PX4_ERR("ramp servo value mismatch");
				return 1;
			}

			/* check post ramp phase */
			if (hrt_elapsed_time(&starttime) > RAMP_TIME_US &&
			    abs(servo_predicted[i] - r_page_servos[i]) > 2) {
				printf("\t %d: %8.4f predicted: %d, servo: %d\n", i, (double)outputs[i], servo_predicted[i], (int)r_page_servos[i]);
				PX4_ERR("mixer violated predicted value");
				return 1;
			}
		}

		usleep(sleep_quantum_us);
		sleepcount++;

		if (sleepcount % 10 == 0) {
			//	printf(".");
			//	fflush(stdout);
		}
	}

	//printf("\n");

	/* load multirotor at once test */
	mixer_group.reset();

#if !defined(CONFIG_ARCH_BOARD_SITL)
	filename = "/etc/mixers/quad_test.mix";
#else
	filename = "ROMFS/px4fmu_test/mixers/quad_test.mix";
#endif

	load_mixer_file(filename, &buf[0], sizeof(buf));
	loaded = strlen(buf);

	//fprintf(stderr, "loaded: \n\"%s\"\n (%d chars)", &buf[0], loaded);

	unsigned mc_loaded = loaded;
	mixer_group.load_from_buf(&buf[0], mc_loaded);
	//PX4_INFO("complete buffer load: loaded %u mixers", mixer_group.count());

	if (mixer_group.count() != 5) {
		PX4_ERR("FAIL: Quad test mixer load failed");
		return 1;
	}

	//PX4_INFO("SUCCESS: No errors in mixer test");
	return 0;
}
예제 #9
0
void
PX4FMU::cycle()
{
	if (!_initialized) {

		/* force a reset of the update rate */
		_current_update_rate = 0;

		_armed_sub = orb_subscribe(ORB_ID(actuator_armed));
		//_param_sub = orb_subscribe(ORB_ID(parameter_update));

		/* initialize PWM limit lib */
		pwm_limit_init(&_pwm_limit);

		update_pwm_rev_mask();

#ifdef RC_SERIAL_PORT
		_sbus_fd = sbus_init(RC_SERIAL_PORT, true);
#endif
		_initialized = true;
	}

	if (_groups_subscribed != _groups_required) {
		subscribe();
		_groups_subscribed = _groups_required;
		/* force setting update rate */
		_current_update_rate = 0;
	}

	/*
	 * Adjust actuator topic update rate to keep up with
	 * the highest servo update rate configured.
	 *
	 * We always mix at max rate; some channels may update slower.
	 */
	unsigned max_rate = (_pwm_default_rate > _pwm_alt_rate) ? _pwm_default_rate : _pwm_alt_rate;

	if (_current_update_rate != max_rate) {
		_current_update_rate = max_rate;
		int update_rate_in_ms = int(1000 / _current_update_rate);

		/* reject faster than 500 Hz updates */
		if (update_rate_in_ms < 2) {
			update_rate_in_ms = 2;
		}

		/* reject slower than 10 Hz updates */
		if (update_rate_in_ms > 100) {
			update_rate_in_ms = 100;
		}

		//DEVICE_DEBUG("adjusted actuator update interval to %ums\n", update_rate_in_ms);

		for (unsigned i = 0; i < actuator_controls_s::NUM_ACTUATOR_CONTROL_GROUPS; i++) {
			if (_control_subs[i] > 0) {
				orb_set_interval(_control_subs[i], update_rate_in_ms);
			}
		}

		// set to current max rate, even if we are actually checking slower/faster
		_current_update_rate = max_rate;
	}

	/* check if anything updated */
    //从mkblctrl-blctrl电子模块驱动拿数据,貌似没用到,而且poll里面也在等待定时器导致定时器卡死
	int ret = 0;//::poll(_poll_fds, _poll_fds_num, 0);

	/* this would be bad... */
	if (ret < 0) {
		DEVICE_LOG("poll error %d\n", ret);

	} else if (ret == 0) {
		/* timeout: no control data, switch to failsafe values */
//			warnx("no PWM: failsafe\n");

	} else {

		/* get controls for required topics */
		unsigned poll_id = 0;

		for (unsigned i = 0; i < actuator_controls_s::NUM_ACTUATOR_CONTROL_GROUPS; i++) {
			if (_control_subs[i] > 0) {
				if (_poll_fds[poll_id].revents & POLLIN) {
					orb_copy(_control_topics[i], _control_subs[i], &_controls[i]);
				}

				poll_id++;
			}
		}

		/* can we mix? */
		if (_mixers != NULL) {

			size_t num_outputs;

			switch (_mode) {
			case MODE_2PWM:
				num_outputs = 2;
				break;

			case MODE_4PWM:
				num_outputs = 4;
				break;

			case MODE_6PWM:
				num_outputs = 6;
				break;

			case MODE_8PWM:
				num_outputs = 8;
				break;

			default:
				num_outputs = 0;
				break;
			}

			/* do mixing */
			float outputs[_max_actuators];
			num_outputs = _mixers->mix(outputs, num_outputs, NULL);

			/* disable unused ports by setting their output to NaN */
			for (size_t i = 0; i < sizeof(outputs) / sizeof(outputs[0]); i++) {
				if (i >= num_outputs) {
					outputs[i] = NAN_VALUE;
				}
			}

			uint16_t pwm_limited[_max_actuators];

			/* the PWM limit call takes care of out of band errors, NaN and constrains */
			pwm_limit_calc(_servo_armed, arm_nothrottle(), num_outputs, _reverse_pwm_mask, _disarmed_pwm, _min_pwm, _max_pwm,
				       outputs, pwm_limited, &_pwm_limit);

			/* output to the servos */
			for (size_t i = 0; i < num_outputs; i++) {
				up_pwm_servo_set(i, pwm_limited[i]);
			}

			publish_pwm_outputs(pwm_limited, num_outputs);
		}
	}

	/* check arming state */
	bool updated = false;
	orb_check(_armed_sub, &updated);

	if (updated) {
		orb_copy(ORB_ID(actuator_armed), _armed_sub, &_armed);

		/* update the armed status and check that we're not locked down */
		bool set_armed = (_armed.armed || _armed.prearmed) && !_armed.lockdown;

		if (_servo_armed != set_armed) {
			_servo_armed = set_armed;
		}

		/* update PWM status if armed or if disarmed PWM values are set */
		bool pwm_on = (set_armed || _num_disarmed_set > 0);

		if (_pwm_on != pwm_on) {
			_pwm_on = pwm_on;
			up_pwm_servo_arm(pwm_on);
		}
	}
/* TODO:F
	orb_check(_param_sub, &updated);

	if (updated) {
		parameter_update_s pupdate;
		orb_copy(ORB_ID(parameter_update), _param_sub, &pupdate);

		update_pwm_rev_mask();
	}
*/
	bool rc_updated = false;

#ifdef RC_SERIAL_PORT
	bool sbus_failsafe, sbus_frame_drop;
	uint16_t raw_rc_values[input_rc_s::RC_INPUT_MAX_CHANNELS];
	uint16_t raw_rc_count;
	bool sbus_updated = sbus_input(_sbus_fd, &raw_rc_values[0], &raw_rc_count, &sbus_failsafe, &sbus_frame_drop,
				       input_rc_s::RC_INPUT_MAX_CHANNELS);

	if (sbus_updated) {
		// we have a new PPM frame. Publish it.
		_rc_in.channel_count = raw_rc_count;

		if (_rc_in.channel_count > input_rc_s::RC_INPUT_MAX_CHANNELS) {
			_rc_in.channel_count = input_rc_s::RC_INPUT_MAX_CHANNELS;
		}

		for (uint8_t i = 0; i < _rc_in.channel_count; i++) {
			_rc_in.values[i] = raw_rc_values[i];
       //     pilot_info("value[%d]=%d\n", i, _rc_in.values[i]);
		}

		_rc_in.timestamp_publication = hrt_absolute_time();
		_rc_in.timestamp_last_signal = _rc_in.timestamp_publication;

		_rc_in.rc_ppm_frame_length = 0;
		_rc_in.rssi = (!sbus_frame_drop) ? RC_INPUT_RSSI_MAX : 0;
		_rc_in.rc_failsafe = false;
		_rc_in.rc_lost = false;
		_rc_in.rc_lost_frame_count = 0;
		_rc_in.rc_total_frame_count = 0;

		rc_updated = true;
	}
#endif

#ifdef HRT_PPM_CHANNEL

	// see if we have new PPM input data
	if ((ppm_last_valid_decode != _rc_in.timestamp_last_signal) &&
		ppm_decoded_channels > 3) {
		// we have a new PPM frame. Publish it.
		_rc_in.channel_count = ppm_decoded_channels;

		if (_rc_in.channel_count > input_rc_s::RC_INPUT_MAX_CHANNELS) {
			_rc_in.channel_count = input_rc_s::RC_INPUT_MAX_CHANNELS;
		}

		for (uint8_t i = 0; i < _rc_in.channel_count; i++) {
			_rc_in.values[i] = ppm_buffer[i];
		}

		_rc_in.timestamp_publication = ppm_last_valid_decode;
		_rc_in.timestamp_last_signal = ppm_last_valid_decode;

		_rc_in.rc_ppm_frame_length = ppm_frame_length;
		_rc_in.rssi = RC_INPUT_RSSI_MAX;
		_rc_in.rc_failsafe = false;
		_rc_in.rc_lost = false;
		_rc_in.rc_lost_frame_count = 0;
		_rc_in.rc_total_frame_count = 0;
	
		rc_updated = true;
	}

#endif

	if (rc_updated) {
		/* lazily advertise on first publication */
		if (_to_input_rc == NULL) {
			_to_input_rc = orb_advertise(ORB_ID(input_rc), &_rc_in);

		} else {
			orb_publish(ORB_ID(input_rc), _to_input_rc, &_rc_in);
		}
	}

//	xTimerStart(_work, (2/portTICK_PERIOD_MS));
}