PreFlightCheck.cpp 8.87 KB
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/**
 * @file PreFlightCheck.cpp
 */

#include "PreFlightCheck.hpp"

#include <drivers/drv_hrt.h>
#include <HealthFlags.h>
#include <lib/parameters/param.h>
#include <systemlib/mavlink_log.h>
#include <uORB/Subscription.hpp>

using namespace time_literals;

static constexpr unsigned max_mandatory_gyro_count = 1;
static constexpr unsigned max_optional_gyro_count = 4;
static constexpr unsigned max_mandatory_accel_count = 1;
static constexpr unsigned max_optional_accel_count = 4;
static constexpr unsigned max_mandatory_mag_count = 1;
static constexpr unsigned max_optional_mag_count = 4;
static constexpr unsigned max_mandatory_baro_count = 1;
static constexpr unsigned max_optional_baro_count = 4;

bool PreFlightCheck::preflightCheck(orb_advert_t *mavlink_log_pub, vehicle_status_s &status,
				    vehicle_status_flags_s &status_flags, bool report_failures, const bool prearm,
				    const hrt_abstime &time_since_boot)
{
	report_failures = (report_failures && status_flags.condition_system_hotplug_timeout
			   && !status_flags.condition_calibration_enabled);

	bool failed = false;

	failed = failed || !airframeCheck(mavlink_log_pub, status);
	failed = failed || !sdcardCheck(mavlink_log_pub, status_flags.sd_card_detected_once, report_failures);

	/* ---- MAG ---- */
	{
		int32_t sys_has_mag = 1;
		param_get(param_find("SYS_HAS_MAG"), &sys_has_mag);

		if (sys_has_mag == 1) {

			/* check all sensors individually, but fail only for mandatory ones */
			for (unsigned i = 0; i < max_optional_mag_count; i++) {
				const bool required = (i < max_mandatory_mag_count) && (sys_has_mag == 1);
				bool report_fail = report_failures;

				int32_t device_id = -1;

				if (!magnetometerCheck(mavlink_log_pub, status, i, !required, device_id, report_fail)) {
					if (required) {
						failed = true;
					}

					report_fail = false; // only report the first failure
				}
			}

			// TODO: highest priority mag

			/* mag consistency checks (need to be performed after the individual checks) */
			if (!magConsistencyCheck(mavlink_log_pub, status, report_failures)) {
				failed = true;
			}
		}
	}

	/* ---- ACCEL ---- */
	{
		/* check all sensors individually, but fail only for mandatory ones */
		for (unsigned i = 0; i < max_optional_accel_count; i++) {
			const bool required = (i < max_mandatory_accel_count);
			bool report_fail = report_failures;

			int32_t device_id = -1;

			if (!accelerometerCheck(mavlink_log_pub, status, i, !required, device_id, report_fail)) {
				if (required) {
					failed = true;
				}

				report_fail = false; // only report the first failure
			}
		}

		// TODO: highest priority (from params)
	}

	/* ---- GYRO ---- */
	{
		/* check all sensors individually, but fail only for mandatory ones */
		for (unsigned i = 0; i < max_optional_gyro_count; i++) {
			const bool required = (i < max_mandatory_gyro_count);
			bool report_fail = report_failures;

			int32_t device_id = -1;

			if (!gyroCheck(mavlink_log_pub, status, i, !required, device_id, report_fail)) {
				if (required) {
					failed = true;
				}

				report_fail = false; // only report the first failure
			}
		}

		// TODO: highest priority (from params)
	}

	/* ---- BARO ---- */
	{
		int32_t sys_has_baro = 1;
		param_get(param_find("SYS_HAS_BARO"), &sys_has_baro);

		bool baro_fail_reported = false;

		/* check all sensors, but fail only for mandatory ones */
		for (unsigned i = 0; i < max_optional_baro_count; i++) {
			const bool required = (i < max_mandatory_baro_count) && (sys_has_baro == 1);
			bool report_fail = (report_failures && !baro_fail_reported);

			int32_t device_id = -1;

			if (!baroCheck(mavlink_log_pub, status, i, !required, device_id, report_fail)) {
				if (required) {
					baro_fail_reported = true;
				}

				report_fail = false; // only report the first failure
			}
		}
	}

	/* ---- IMU CONSISTENCY ---- */
	// To be performed after the individual sensor checks have completed
	{
		if (!imuConsistencyCheck(mavlink_log_pub, status, report_failures)) {
			failed = true;
		}
	}

	/* ---- AIRSPEED ---- */
	/* Perform airspeed check only if circuit breaker is not engaged and it's not a rotary wing */
	if (!status_flags.circuit_breaker_engaged_airspd_check &&
	    (status.vehicle_type == vehicle_status_s::VEHICLE_TYPE_FIXED_WING || status.is_vtol)) {

		int32_t airspeed_mode = 0;
		param_get(param_find("FW_ARSP_MODE"), &airspeed_mode);
		const bool optional = (airspeed_mode == 1);

		int32_t max_airspeed_check_en = 0;
		param_get(param_find("COM_ARM_ARSP_EN"), &max_airspeed_check_en);

		float airspeed_stall = 10.0f;
		param_get(param_find("ASPD_STALL"), &airspeed_stall);

		const float arming_max_airspeed_allowed = airspeed_stall / 2.0f; // set to half of stall speed

		if (!airspeedCheck(mavlink_log_pub, status, optional, report_failures, prearm, (bool)max_airspeed_check_en,
				   arming_max_airspeed_allowed)
		    && !(bool)optional) {
			failed = true;
		}
	}

	/* ---- RC CALIBRATION ---- */
	if (status.rc_input_mode == vehicle_status_s::RC_IN_MODE_DEFAULT) {
		if (rcCalibrationCheck(mavlink_log_pub, report_failures, status.is_vtol) != OK) {
			if (report_failures) {
				mavlink_log_critical(mavlink_log_pub, "RC calibration check failed");
			}

			failed = true;

			set_health_flags(subsystem_info_s::SUBSYSTEM_TYPE_RCRECEIVER, status_flags.rc_signal_found_once, true, false, status);
			status_flags.rc_calibration_valid = false;

		} else {
			// The calibration is fine, but only set the overall health state to true if the signal is not currently lost
			status_flags.rc_calibration_valid = true;
			set_health_flags(subsystem_info_s::SUBSYSTEM_TYPE_RCRECEIVER, status_flags.rc_signal_found_once, true,
					 !status.rc_signal_lost, status);
		}
	}

	/* ---- SYSTEM POWER ---- */
	if (status_flags.condition_power_input_valid && !status_flags.circuit_breaker_engaged_power_check) {
		if (!powerCheck(mavlink_log_pub, status, report_failures, prearm)) {
			failed = true;
		}
	}

	/* ---- Navigation EKF ---- */
	// only check EKF2 data if EKF2 is selected as the estimator and GNSS checking is enabled
	int32_t estimator_type = -1;

	if (status.vehicle_type == vehicle_status_s::VEHICLE_TYPE_ROTARY_WING && !status.is_vtol) {
		param_get(param_find("SYS_MC_EST_GROUP"), &estimator_type);

	} else {
		// EKF2 is currently the only supported option for FW & VTOL
		estimator_type = 2;
	}

	if (estimator_type == 2) {

		const bool ekf_healthy = ekf2Check(mavlink_log_pub, status, false, report_failures) &&
					 ekf2CheckSensorBias(mavlink_log_pub, report_failures);

		// For the first 10 seconds the ekf2 can be unhealthy, and we just mark it
		// as not present.
		// After that or if report_failures is true, we'll set the flags as is.

		if (!ekf_healthy && time_since_boot < 10_s && !report_failures) {
			set_health_flags(subsystem_info_s::SUBSYSTEM_TYPE_AHRS, true, false, false, status);

		} else {
			set_health_flags(subsystem_info_s::SUBSYSTEM_TYPE_AHRS, true, true, ekf_healthy, status);
		}

		failed |= !ekf_healthy;
	}

	/* ---- Failure Detector ---- */
	if (!failureDetectorCheck(mavlink_log_pub, status, report_failures, prearm)) {
		failed = true;
	}

	failed = failed || !manualControlCheck(mavlink_log_pub, report_failures);
	failed = failed || !cpuResourceCheck(mavlink_log_pub, report_failures);

	/* Report status */
	return !failed;
}