''' Fly ArduPlane in SITL AP_FLAKE8_CLEAN ''' from __future__ import print_function import math import os import signal import sys import time from pymavlink import quaternion from pymavlink import mavextra from pymavlink import mavutil from common import AutoTest from common import AutoTestTimeoutException from common import NotAchievedException from common import PreconditionFailedException from common import WaitModeTimeout from pymavlink.rotmat import Vector3 from pysim import vehicleinfo import operator # get location of scripts testdir = os.path.dirname(os.path.realpath(__file__)) SITL_START_LOCATION = mavutil.location(-35.362938, 149.165085, 585, 354) WIND = "0,180,0.2" # speed,direction,variance class AutoTestPlane(AutoTest): @staticmethod def get_not_armable_mode_list(): return [] @staticmethod def get_not_disarmed_settable_modes_list(): return ["FOLLOW"] @staticmethod def get_no_position_not_settable_modes_list(): return [] @staticmethod def get_position_armable_modes_list(): return ["GUIDED", "AUTO"] @staticmethod def get_normal_armable_modes_list(): return ["MANUAL", "STABILIZE", "ACRO"] def log_name(self): return "ArduPlane" def default_speedup(self): return 100 def test_filepath(self): return os.path.realpath(__file__) def sitl_start_location(self): return SITL_START_LOCATION def defaults_filepath(self): return os.path.join(testdir, 'default_params/plane-jsbsim.parm') def set_current_test_name(self, name): self.current_test_name_directory = "ArduPlane_Tests/" + name + "/" def default_frame(self): return "plane-elevrev" def apply_defaultfile_parameters(self): # plane passes in a defaults_filepath in place of applying # parameters afterwards. pass def is_plane(self): return True def get_stick_arming_channel(self): return int(self.get_parameter("RCMAP_YAW")) def get_disarm_delay(self): return int(self.get_parameter("LAND_DISARMDELAY")) def set_autodisarm_delay(self, delay): self.set_parameter("LAND_DISARMDELAY", delay) def takeoff(self, alt=150, alt_max=None, relative=True): """Takeoff to altitude.""" if alt_max is None: alt_max = alt + 30 self.change_mode("FBWA") self.wait_ready_to_arm() self.arm_vehicle() # some rudder to counteract the prop torque self.set_rc(4, 1700) # some up elevator to keep the tail down self.set_rc(2, 1200) # get it moving a bit first self.set_rc(3, 1300) self.wait_groundspeed(6, 100) # a bit faster again, straighten rudder self.set_rc_from_map({ 3: 1600, 4: 1500, }) self.wait_groundspeed(12, 100) # hit the gas harder now, and give it some more elevator self.set_rc_from_map({ 2: 1100, 3: 2000, }) # gain a bit of altitude self.wait_altitude(alt, alt_max, timeout=30, relative=relative) # level off self.set_rc(2, 1500) self.progress("TAKEOFF COMPLETE") def fly_left_circuit(self): """Fly a left circuit, 200m on a side.""" self.change_mode('FBWA') self.set_rc(3, 2000) self.wait_level_flight() self.progress("Flying left circuit") # do 4 turns for i in range(0, 4): # hard left self.progress("Starting turn %u" % i) self.set_rc(1, 1000) self.wait_heading(270 - (90*i), accuracy=10) self.set_rc(1, 1500) self.progress("Starting leg %u" % i) self.wait_distance(100, accuracy=20) self.progress("Circuit complete") def fly_RTL(self): """Fly to home.""" self.progress("Flying home in RTL") self.change_mode('RTL') self.wait_location(self.homeloc, accuracy=120, target_altitude=self.homeloc.alt+100, height_accuracy=20, timeout=180) self.progress("RTL Complete") def NeedEKFToArm(self): """Ensure the EKF must be healthy for the vehicle to arm.""" self.progress("Ensuring we need EKF to be healthy to arm") self.set_parameter("SIM_GPS_DISABLE", 1) self.context_collect("STATUSTEXT") tstart = self.get_sim_time() success = False while not success: if self.get_sim_time_cached() - tstart > 60: raise NotAchievedException("Did not get correct failure reason") self.run_cmd_run_prearms() try: self.wait_statustext(".*AHRS: not using configured AHRS type.*", timeout=1, check_context=True, regex=True) success = True continue except AutoTestTimeoutException: pass self.set_parameter("SIM_GPS_DISABLE", 0) self.wait_ready_to_arm() def fly_LOITER(self, num_circles=4): """Loiter where we are.""" self.progress("Testing LOITER for %u turns" % num_circles) self.change_mode('LOITER') m = self.mav.recv_match(type='VFR_HUD', blocking=True) initial_alt = m.alt self.progress("Initial altitude %u\n" % initial_alt) while num_circles > 0: self.wait_heading(0, accuracy=10, timeout=60) self.wait_heading(180, accuracy=10, timeout=60) num_circles -= 1 self.progress("Loiter %u circles left" % num_circles) m = self.mav.recv_match(type='VFR_HUD', blocking=True) final_alt = m.alt self.progress("Final altitude %u initial %u\n" % (final_alt, initial_alt)) self.change_mode('FBWA') if abs(final_alt - initial_alt) > 20: raise NotAchievedException("Failed to maintain altitude") self.progress("Completed Loiter OK") def fly_CIRCLE(self, num_circles=1): """Circle where we are.""" self.progress("Testing CIRCLE for %u turns" % num_circles) self.change_mode('CIRCLE') m = self.mav.recv_match(type='VFR_HUD', blocking=True) initial_alt = m.alt self.progress("Initial altitude %u\n" % initial_alt) while num_circles > 0: self.wait_heading(0, accuracy=10, timeout=60) self.wait_heading(180, accuracy=10, timeout=60) num_circles -= 1 self.progress("CIRCLE %u circles left" % num_circles) m = self.mav.recv_match(type='VFR_HUD', blocking=True) final_alt = m.alt self.progress("Final altitude %u initial %u\n" % (final_alt, initial_alt)) self.change_mode('FBWA') if abs(final_alt - initial_alt) > 20: raise NotAchievedException("Failed to maintain altitude") self.progress("Completed CIRCLE OK") def wait_level_flight(self, accuracy=5, timeout=30): """Wait for level flight.""" tstart = self.get_sim_time() self.progress("Waiting for level flight") self.set_rc(1, 1500) self.set_rc(2, 1500) self.set_rc(4, 1500) while self.get_sim_time_cached() < tstart + timeout: m = self.mav.recv_match(type='ATTITUDE', blocking=True) roll = math.degrees(m.roll) pitch = math.degrees(m.pitch) self.progress("Roll=%.1f Pitch=%.1f" % (roll, pitch)) if math.fabs(roll) <= accuracy and math.fabs(pitch) <= accuracy: self.progress("Attained level flight") return raise NotAchievedException("Failed to attain level flight") def change_altitude(self, altitude, accuracy=30): """Get to a given altitude.""" self.change_mode('FBWA') alt_error = self.mav.messages['VFR_HUD'].alt - altitude if alt_error > 0: self.set_rc(2, 2000) else: self.set_rc(2, 1000) self.wait_altitude(altitude-accuracy/2, altitude+accuracy/2) self.set_rc(2, 1500) self.progress("Reached target altitude at %u" % self.mav.messages['VFR_HUD'].alt) return self.wait_level_flight() def axial_left_roll(self, count=1): """Fly a left axial roll.""" # full throttle! self.set_rc(3, 2000) self.change_altitude(self.homeloc.alt+300) # fly the roll in manual self.change_mode('MANUAL') while count > 0: self.progress("Starting roll") self.set_rc(1, 1000) try: self.wait_roll(-150, accuracy=90) self.wait_roll(150, accuracy=90) self.wait_roll(0, accuracy=90) except Exception as e: self.set_rc(1, 1500) raise e count -= 1 # back to FBWA self.set_rc(1, 1500) self.change_mode('FBWA') self.set_rc(3, 1700) return self.wait_level_flight() def inside_loop(self, count=1): """Fly a inside loop.""" # full throttle! self.set_rc(3, 2000) self.change_altitude(self.homeloc.alt+300) # fly the loop in manual self.change_mode('MANUAL') while count > 0: self.progress("Starting loop") self.set_rc(2, 1000) self.wait_pitch(-60, accuracy=20) self.wait_pitch(0, accuracy=20) count -= 1 # back to FBWA self.set_rc(2, 1500) self.change_mode('FBWA') self.set_rc(3, 1700) return self.wait_level_flight() def set_attitude_target(self, tolerance=10): """Test setting of attitude target in guided mode.""" self.change_mode("GUIDED") # self.set_parameter("STALL_PREVENTION", 0) state_roll_over = "roll-over" state_stabilize_roll = "stabilize-roll" state_hold = "hold" state_roll_back = "roll-back" state_done = "done" tstart = self.get_sim_time() try: state = state_roll_over while state != state_done: m = self.mav.recv_match(type='ATTITUDE', blocking=True, timeout=0.1) now = self.get_sim_time_cached() if now - tstart > 20: raise AutoTestTimeoutException("Manuevers not completed") if m is None: continue r = math.degrees(m.roll) if state == state_roll_over: target_roll_degrees = 60 if abs(r - target_roll_degrees) < tolerance: state = state_stabilize_roll stabilize_start = now elif state == state_stabilize_roll: # just give it a little time to sort it self out if now - stabilize_start > 2: state = state_hold hold_start = now elif state == state_hold: target_roll_degrees = 60 if now - hold_start > tolerance: state = state_roll_back if abs(r - target_roll_degrees) > tolerance: raise NotAchievedException("Failed to hold attitude") elif state == state_roll_back: target_roll_degrees = 0 if abs(r - target_roll_degrees) < tolerance: state = state_done else: raise ValueError("Unknown state %s" % str(state)) m_nav = self.mav.messages['NAV_CONTROLLER_OUTPUT'] self.progress("%s Roll: %f desired=%f set=%f" % (state, r, m_nav.nav_roll, target_roll_degrees)) time_boot_millis = 0 # FIXME target_system = 1 # FIXME target_component = 1 # FIXME type_mask = 0b10000001 ^ 0xFF # FIXME # attitude in radians: q = quaternion.Quaternion([math.radians(target_roll_degrees), 0, 0]) roll_rate_radians = 0.5 pitch_rate_radians = 0 yaw_rate_radians = 0 thrust = 1.0 self.mav.mav.set_attitude_target_send(time_boot_millis, target_system, target_component, type_mask, q, roll_rate_radians, pitch_rate_radians, yaw_rate_radians, thrust) except Exception as e: self.change_mode('FBWA') self.set_rc(3, 1700) raise e # back to FBWA self.change_mode('FBWA') self.set_rc(3, 1700) self.wait_level_flight() def test_stabilize(self, count=1): """Fly stabilize mode.""" # full throttle! self.set_rc(3, 2000) self.set_rc(2, 1300) self.change_altitude(self.homeloc.alt+300) self.set_rc(2, 1500) self.change_mode('STABILIZE') while count > 0: self.progress("Starting roll") self.set_rc(1, 2000) self.wait_roll(-150, accuracy=90) self.wait_roll(150, accuracy=90) self.wait_roll(0, accuracy=90) count -= 1 self.set_rc(1, 1500) self.wait_roll(0, accuracy=5) # back to FBWA self.change_mode('FBWA') self.set_rc(3, 1700) return self.wait_level_flight() def test_acro(self, count=1): """Fly ACRO mode.""" # full throttle! self.set_rc(3, 2000) self.set_rc(2, 1300) self.change_altitude(self.homeloc.alt+300) self.set_rc(2, 1500) self.change_mode('ACRO') while count > 0: self.progress("Starting roll") self.set_rc(1, 1000) self.wait_roll(-150, accuracy=90) self.wait_roll(150, accuracy=90) self.wait_roll(0, accuracy=90) count -= 1 self.set_rc(1, 1500) # back to FBWA self.change_mode('FBWA') self.wait_level_flight() self.change_mode('ACRO') count = 2 while count > 0: self.progress("Starting loop") self.set_rc(2, 1000) self.wait_pitch(-60, accuracy=20) self.wait_pitch(0, accuracy=20) count -= 1 self.set_rc(2, 1500) # back to FBWA self.change_mode('FBWA') self.set_rc(3, 1700) return self.wait_level_flight() def test_FBWB(self, mode='FBWB'): """Fly FBWB or CRUISE mode.""" self.change_mode(mode) self.set_rc(3, 1700) self.set_rc(2, 1500) # lock in the altitude by asking for an altitude change then releasing self.set_rc(2, 1000) self.wait_distance(50, accuracy=20) self.set_rc(2, 1500) self.wait_distance(50, accuracy=20) m = self.mav.recv_match(type='VFR_HUD', blocking=True) initial_alt = m.alt self.progress("Initial altitude %u\n" % initial_alt) self.progress("Flying right circuit") # do 4 turns for i in range(0, 4): # hard left self.progress("Starting turn %u" % i) self.set_rc(1, 1800) try: self.wait_heading(0 + (90*i), accuracy=20, timeout=60) except Exception as e: self.set_rc(1, 1500) raise e self.set_rc(1, 1500) self.progress("Starting leg %u" % i) self.wait_distance(100, accuracy=20) self.progress("Circuit complete") self.progress("Flying rudder left circuit") # do 4 turns for i in range(0, 4): # hard left self.progress("Starting turn %u" % i) self.set_rc(4, 1900) try: self.wait_heading(360 - (90*i), accuracy=20, timeout=60) except Exception as e: self.set_rc(4, 1500) raise e self.set_rc(4, 1500) self.progress("Starting leg %u" % i) self.wait_distance(100, accuracy=20) self.progress("Circuit complete") m = self.mav.recv_match(type='VFR_HUD', blocking=True) final_alt = m.alt self.progress("Final altitude %u initial %u\n" % (final_alt, initial_alt)) # back to FBWA self.change_mode('FBWA') if abs(final_alt - initial_alt) > 20: raise NotAchievedException("Failed to maintain altitude") return self.wait_level_flight() def fly_mission(self, filename, mission_timeout=60.0, strict=True, quadplane=False): """Fly a mission from a file.""" self.progress("Flying mission %s" % filename) num_wp = self.load_mission(filename, strict=strict)-1 self.fly_mission_waypoints(num_wp, mission_timeout=mission_timeout, quadplane=quadplane) def fly_mission_waypoints(self, num_wp, mission_timeout=60.0, quadplane=False): self.set_current_waypoint(0, check_afterwards=False) self.context_push() self.context_collect('STATUSTEXT') self.change_mode('AUTO') self.wait_waypoint(1, num_wp, max_dist=60, timeout=mission_timeout) self.wait_groundspeed(0, 0.5, timeout=mission_timeout) if quadplane: self.wait_statustext("Throttle disarmed", timeout=200, check_context=True) else: self.wait_statustext("Auto disarmed", timeout=60, check_context=True) self.context_pop() self.progress("Mission OK") def DO_REPOSITION(self): '''Test mavlink DO_REPOSITION command''' self.progress("Takeoff") self.takeoff(alt=50) self.set_rc(3, 1500) self.progress("Entering guided and flying somewhere constant") self.change_mode("GUIDED") loc = self.mav.location() self.location_offset_ne(loc, 500, 500) new_alt = 100 self.run_cmd_int( mavutil.mavlink.MAV_CMD_DO_REPOSITION, 0, 0, 0, 0, int(loc.lat * 1e7), int(loc.lng * 1e7), new_alt, # alt frame=mavutil.mavlink.MAV_FRAME_GLOBAL_RELATIVE_ALT_INT, ) self.wait_altitude(new_alt-10, new_alt, timeout=30, relative=True) self.fly_home_land_and_disarm() def DeepStall(self): '''Test DeepStall Landing''' # self.fly_deepstall_absolute() self.fly_deepstall_relative() def fly_deepstall_absolute(self): self.start_subtest("DeepStall Relative Absolute") deepstall_elevator_pwm = 1661 self.set_parameters({ "LAND_TYPE": 1, "LAND_DS_ELEV_PWM": deepstall_elevator_pwm, "RTL_AUTOLAND": 1, }) self.load_mission("plane-deepstall-mission.txt") self.change_mode("AUTO") self.wait_ready_to_arm() self.arm_vehicle() self.progress("Waiting for deepstall messages") # note that the following two don't necessarily happen in this # order, but at very high speedups we may miss the elevator # PWM if we first look for the text (due to the get_sim_time() # in wait_servo_channel_value) self.context_collect('STATUSTEXT') # assume elevator is on channel 2: self.wait_servo_channel_value(2, deepstall_elevator_pwm, timeout=240) self.wait_text("Deepstall: Entry: ", check_context=True) self.disarm_wait(timeout=120) self.progress("Flying home") self.set_current_waypoint(0, check_afterwards=False) self.takeoff(10) self.set_parameter("LAND_TYPE", 0) self.fly_home_land_and_disarm() def fly_deepstall_relative(self): self.start_subtest("DeepStall Relative") deepstall_elevator_pwm = 1661 self.set_parameters({ "LAND_TYPE": 1, "LAND_DS_ELEV_PWM": deepstall_elevator_pwm, "RTL_AUTOLAND": 1, }) self.load_mission("plane-deepstall-relative-mission.txt") self.change_mode("AUTO") self.wait_ready_to_arm() self.arm_vehicle() self.progress("Waiting for deepstall messages") # note that the following two don't necessarily happen in this # order, but at very high speedups we may miss the elevator # PWM if we first look for the text (due to the get_sim_time() # in wait_servo_channel_value) self.context_collect('STATUSTEXT') # assume elevator is on channel 2: self.wait_servo_channel_value(2, deepstall_elevator_pwm, timeout=240) self.wait_text("Deepstall: Entry: ", check_context=True) self.disarm_wait(timeout=120) self.set_current_waypoint(0, check_afterwards=False) self.progress("Flying home") self.set_current_waypoint(0, check_afterwards=False) self.takeoff(100) self.set_parameter("LAND_TYPE", 0) self.fly_home_land_and_disarm(timeout=240) def SmartBattery(self): '''Test smart battery logging etc''' self.set_parameters({ "BATT_MONITOR": 16, # Maxell battery monitor }) # Must reboot sitl after setting montior type for SMBus parameters to be set due to dynamic group self.reboot_sitl() self.set_parameters({ "BATT_I2C_BUS": 2, # specified in SIM_I2C.cpp "BATT_I2C_ADDR": 11, # specified in SIM_I2C.cpp }) self.reboot_sitl() self.wait_ready_to_arm() m = self.assert_receive_message('BATTERY_STATUS', timeout=10) if m.voltages_ext[0] == 65536: raise NotAchievedException("Flag value rather than voltage") if abs(m.voltages_ext[0] - 1000) > 300: raise NotAchievedException("Did not get good ext voltage (got=%f)" % (m.voltages_ext[0],)) self.arm_vehicle() self.delay_sim_time(5) self.disarm_vehicle() if not self.current_onboard_log_contains_message("BCL2"): raise NotAchievedException("Expected BCL2 message") def DO_CHANGE_SPEED(self): '''Test DO_CHANGE_SPEED command/item''' # the following lines ensure we revert these parameter values # - DO_CHANGE_AIRSPEED is a permanent vehicle change! self.set_parameters({ "TRIM_ARSPD_CM": self.get_parameter("TRIM_ARSPD_CM"), "MIN_GNDSPD_CM": self.get_parameter("MIN_GNDSPD_CM"), "RTL_AUTOLAND": 1, }) self.DO_CHANGE_SPEED_mavlink() self.DO_CHANGE_SPEED_mission() def DO_CHANGE_SPEED_mission(self): '''test DO_CHANGE_SPEED as a mission item''' self.start_subtest("DO_CHANGE_SPEED_mission") self.load_mission("mission.txt") self.set_current_waypoint(1) self.progress("Takeoff") self.set_rc(3, 1000) self.takeoff(alt=10) self.set_rc(3, 1500) self.start_subtest("Check initial speed") self.change_mode('AUTO') checks = [ (1, self.get_parameter("TRIM_ARSPD_CM") * 0.01), (3, 10), (5, 20), (7, 15), ] for (current_waypoint, want_airspeed) in checks: self.wait_current_waypoint(current_waypoint, timeout=150) self.wait_airspeed(want_airspeed-1, want_airspeed+1, minimum_duration=5, timeout=120) self.fly_home_land_and_disarm() def DO_CHANGE_SPEED_mavlink(self): '''test DO_CHANGE_SPEED as a mavlink command''' self.progress("Takeoff") self.takeoff(alt=100) self.set_rc(3, 1500) # ensure we know what the airspeed is: self.progress("Entering guided and flying somewhere constant") self.change_mode("GUIDED") self.run_cmd_int( mavutil.mavlink.MAV_CMD_DO_REPOSITION, 0, 0, 0, 0, 12345, # lat* 1e7 12345, # lon* 1e7 100 # alt ) self.delay_sim_time(10) self.progress("Ensuring initial speed is known and relatively constant") initial_speed = 22.0 timeout = 15 self.wait_airspeed(initial_speed-1, initial_speed+1, minimum_duration=5, timeout=timeout) self.progress("Setting groundspeed") new_target_groundspeed = initial_speed + 5 self.run_cmd( mavutil.mavlink.MAV_CMD_DO_CHANGE_SPEED, 1, # groundspeed new_target_groundspeed, -1, # throttle / no change 0, # absolute values 0, 0, 0) self.wait_groundspeed(new_target_groundspeed-0.5, new_target_groundspeed+0.5, timeout=40) self.progress("Adding some wind, ensuring groundspeed holds") self.set_parameter("SIM_WIND_SPD", 5) self.delay_sim_time(5) self.wait_groundspeed(new_target_groundspeed-0.5, new_target_groundspeed+0.5, timeout=40) self.set_parameter("SIM_WIND_SPD", 0) # clear target groundspeed self.run_cmd( mavutil.mavlink.MAV_CMD_DO_CHANGE_SPEED, 1, # groundspeed 0, -1, # throttle / no change 0, # absolute values 0, 0, 0) self.progress("Setting airspeed") new_target_airspeed = initial_speed + 5 self.run_cmd( mavutil.mavlink.MAV_CMD_DO_CHANGE_SPEED, 0, # airspeed new_target_airspeed, -1, # throttle / no change 0, # absolute values 0, 0, 0) self.wait_airspeed(new_target_airspeed-0.5, new_target_airspeed+0.5) self.progress("Adding some wind, hoping groundspeed increases/decreases") self.set_parameters({ "SIM_WIND_SPD": 7, "SIM_WIND_DIR": 270, }) self.delay_sim_time(5) timeout = 10 tstart = self.get_sim_time() while True: if self.get_sim_time_cached() - tstart > timeout: raise NotAchievedException("Did not achieve groundspeed delta") m = self.mav.recv_match(type='VFR_HUD', blocking=True) delta = abs(m.airspeed - m.groundspeed) want_delta = 5 self.progress("groundspeed and airspeed should be different (have=%f want=%f)" % (delta, want_delta)) if delta > want_delta: break self.fly_home_land_and_disarm(timeout=240) def fly_home_land_and_disarm(self, timeout=120): filename = "flaps.txt" self.progress("Using %s to fly home" % filename) self.load_generic_mission(filename) self.change_mode("AUTO") # don't set current waypoint to 8 unless we're distant from it # or we arrive instantly and never see it as our current # waypoint: self.wait_distance_to_waypoint(8, 100, 10000000) self.set_current_waypoint(8) # TODO: reflect on file to find this magic waypoint number? # self.wait_waypoint(7, num_wp-1, timeout=500) # we # tend to miss the final waypoint by a fair bit, and # this is probably too noisy anyway? self.wait_disarmed(timeout=timeout) def TestFlaps(self): """Test flaps functionality.""" filename = "flaps.txt" self.context_push() ex = None try: flaps_ch = 5 flaps_ch_min = 1000 flaps_ch_trim = 1500 flaps_ch_max = 2000 servo_ch = 5 servo_ch_min = 1200 servo_ch_trim = 1300 servo_ch_max = 1800 self.set_parameters({ "SERVO%u_FUNCTION" % servo_ch: 3, # flapsauto "RC%u_OPTION" % flaps_ch: 208, # Flaps RCx_OPTION "LAND_FLAP_PERCNT": 50, "LOG_DISARMED": 1, "RTL_AUTOLAND": 1, "RC%u_MIN" % flaps_ch: flaps_ch_min, "RC%u_MAX" % flaps_ch: flaps_ch_max, "RC%u_TRIM" % flaps_ch: flaps_ch_trim, "SERVO%u_MIN" % servo_ch: servo_ch_min, "SERVO%u_MAX" % servo_ch: servo_ch_max, "SERVO%u_TRIM" % servo_ch: servo_ch_trim, }) self.progress("check flaps are not deployed") self.set_rc(flaps_ch, flaps_ch_min) self.wait_servo_channel_value(servo_ch, servo_ch_min, timeout=3) self.progress("deploy the flaps") self.set_rc(flaps_ch, flaps_ch_max) tstart = self.get_sim_time() self.wait_servo_channel_value(servo_ch, servo_ch_max) tstop = self.get_sim_time_cached() delta_time = tstop - tstart delta_time_min = 0.5 delta_time_max = 1.5 if delta_time < delta_time_min or delta_time > delta_time_max: raise NotAchievedException(( "Flaps Slew not working (%f seconds)" % (delta_time,))) self.progress("undeploy flaps") self.set_rc(flaps_ch, flaps_ch_min) self.wait_servo_channel_value(servo_ch, servo_ch_min) self.progress("Flying mission %s" % filename) self.load_mission(filename) self.set_current_waypoint(1) self.change_mode('AUTO') self.wait_ready_to_arm() self.arm_vehicle() last_mission_current_msg = 0 last_seq = None while self.armed(): m = self.mav.recv_match(type='MISSION_CURRENT', blocking=True) time_delta = (self.get_sim_time_cached() - last_mission_current_msg) if (time_delta > 1 or m.seq != last_seq): dist = None x = self.mav.messages.get("NAV_CONTROLLER_OUTPUT", None) if x is not None: dist = x.wp_dist self.progress("MISSION_CURRENT.seq=%u (dist=%s)" % (m.seq, str(dist))) last_mission_current_msg = self.get_sim_time_cached() last_seq = m.seq # flaps should undeploy at the end self.wait_servo_channel_value(servo_ch, servo_ch_min, timeout=30) # do a short flight in FBWA, watching for flaps # self.mavproxy.send('switch 4\n') # self.wait_mode('FBWA') # self.delay_sim_time(10) # self.mavproxy.send('switch 6\n') # self.wait_mode('MANUAL') # self.delay_sim_time(10) self.progress("Flaps OK") except Exception as e: self.print_exception_caught(e) ex = e self.context_pop() if ex: if self.armed(): self.disarm_vehicle() raise ex def TestRCRelay(self): '''Test Relay RC Channel Option''' self.set_parameter("RC12_OPTION", 28) # Relay On/Off self.set_rc(12, 1000) self.reboot_sitl() # needed for RC12_OPTION to take effect off = self.get_parameter("SIM_PIN_MASK") if off: raise PreconditionFailedException("SIM_MASK_PIN off") # allow time for the RC library to register initial value: self.delay_sim_time(1) self.set_rc(12, 2000) self.wait_heartbeat() self.wait_heartbeat() on = self.get_parameter("SIM_PIN_MASK") if not on: raise NotAchievedException("SIM_PIN_MASK doesn't reflect ON") self.set_rc(12, 1000) self.wait_heartbeat() self.wait_heartbeat() off = self.get_parameter("SIM_PIN_MASK") if off: raise NotAchievedException("SIM_PIN_MASK doesn't reflect OFF") def TestRCCamera(self): '''Test RC Option - Camera Trigger''' self.set_parameter("RC12_OPTION", 9) # CameraTrigger self.set_parameter("CAM1_TYPE", 1) # Camera with servo trigger self.reboot_sitl() # needed for RC12_OPTION to take effect x = self.mav.messages.get("CAMERA_FEEDBACK", None) if x is not None: raise PreconditionFailedException("Receiving CAMERA_FEEDBACK?!") self.set_rc(12, 2000) tstart = self.get_sim_time() while self.get_sim_time_cached() - tstart < 10: x = self.mav.messages.get("CAMERA_FEEDBACK", None) if x is not None: break self.wait_heartbeat() self.set_rc(12, 1000) if x is None: raise NotAchievedException("No CAMERA_FEEDBACK message received") self.wait_ready_to_arm() original_alt = self.get_altitude() takeoff_alt = 30 self.takeoff(takeoff_alt) self.set_rc(12, 2000) self.delay_sim_time(1) self.set_rc(12, 1000) x = self.mav.messages.get("CAMERA_FEEDBACK", None) if abs(x.alt_rel - takeoff_alt) > 10: raise NotAchievedException("Bad relalt (want=%f vs got=%f)" % (takeoff_alt, x.alt_rel)) if abs(x.alt_msl - (original_alt+30)) > 10: raise NotAchievedException("Bad absalt (want=%f vs got=%f)" % (original_alt+30, x.alt_msl)) self.fly_home_land_and_disarm() def ThrottleFailsafe(self): '''Fly throttle failsafe''' self.change_mode('MANUAL') m = self.mav.recv_match(type='SYS_STATUS', blocking=True) receiver_bit = mavutil.mavlink.MAV_SYS_STATUS_SENSOR_RC_RECEIVER self.progress("Testing receiver enabled") if (not (m.onboard_control_sensors_enabled & receiver_bit)): raise PreconditionFailedException() self.progress("Testing receiver present") if (not (m.onboard_control_sensors_present & receiver_bit)): raise PreconditionFailedException() self.progress("Testing receiver health") if (not (m.onboard_control_sensors_health & receiver_bit)): raise PreconditionFailedException() self.progress("Ensure we know original throttle value") self.wait_rc_channel_value(3, 1000) self.set_parameter("THR_FS_VALUE", 960) self.progress("Failing receiver (throttle-to-950)") self.context_collect("HEARTBEAT") self.set_parameter("SIM_RC_FAIL", 2) # throttle-to-950 self.wait_mode('RTL') # long failsafe if (not self.get_mode_from_mode_mapping("CIRCLE") in [x.custom_mode for x in self.context_stop_collecting("HEARTBEAT")]): raise NotAchievedException("Did not go via circle mode") self.progress("Ensure we've had our throttle squashed to 950") self.wait_rc_channel_value(3, 950) self.do_timesync_roundtrip() m = self.assert_receive_message('SYS_STATUS') self.progress("Got (%s)" % str(m)) self.progress("Testing receiver enabled") if (not (m.onboard_control_sensors_enabled & receiver_bit)): raise NotAchievedException("Receiver not enabled") self.progress("Testing receiver present") if (not (m.onboard_control_sensors_present & receiver_bit)): raise NotAchievedException("Receiver not present") # skip this until RC is fixed # self.progress("Testing receiver health") # if (m.onboard_control_sensors_health & receiver_bit): # raise NotAchievedException("Sensor healthy when it shouldn't be") self.set_parameter("SIM_RC_FAIL", 0) # have to allow time for RC to be fetched from SITL self.delay_sim_time(0.5) self.do_timesync_roundtrip() m = self.assert_receive_message('SYS_STATUS') self.progress("Testing receiver enabled") if (not (m.onboard_control_sensors_enabled & receiver_bit)): raise NotAchievedException("Receiver not enabled") self.progress("Testing receiver present") if (not (m.onboard_control_sensors_present & receiver_bit)): raise NotAchievedException("Receiver not present") self.progress("Testing receiver health") if (not (m.onboard_control_sensors_health & receiver_bit)): raise NotAchievedException("Receiver not healthy2") self.change_mode('MANUAL') self.progress("Failing receiver (no-pulses)") self.context_collect("HEARTBEAT") self.set_parameter("SIM_RC_FAIL", 1) # no-pulses self.wait_mode('RTL') # long failsafe if (not self.get_mode_from_mode_mapping("CIRCLE") in [x.custom_mode for x in self.context_stop_collecting("HEARTBEAT")]): raise NotAchievedException("Did not go via circle mode") self.do_timesync_roundtrip() m = self.assert_receive_message('SYS_STATUS') self.progress("Got (%s)" % str(m)) self.progress("Testing receiver enabled") if (not (m.onboard_control_sensors_enabled & receiver_bit)): raise NotAchievedException("Receiver not enabled") self.progress("Testing receiver present") if (not (m.onboard_control_sensors_present & receiver_bit)): raise NotAchievedException("Receiver not present") self.progress("Testing receiver health") if (m.onboard_control_sensors_health & receiver_bit): raise NotAchievedException("Sensor healthy when it shouldn't be") self.progress("Making RC work again") self.set_parameter("SIM_RC_FAIL", 0) # have to allow time for RC to be fetched from SITL self.progress("Giving receiver time to recover") self.delay_sim_time(0.5) self.do_timesync_roundtrip() m = self.assert_receive_message('SYS_STATUS') self.progress("Testing receiver enabled") if (not (m.onboard_control_sensors_enabled & receiver_bit)): raise NotAchievedException("Receiver not enabled") self.progress("Testing receiver present") if (not (m.onboard_control_sensors_present & receiver_bit)): raise NotAchievedException("Receiver not present") self.progress("Testing receiver health") if (not (m.onboard_control_sensors_health & receiver_bit)): raise NotAchievedException("Receiver not healthy") self.change_mode('MANUAL') self.progress("Ensure long failsafe can trigger when short failsafe disabled") self.context_push() self.context_collect("STATUSTEXT") ex = None try: self.set_parameters({ "FS_SHORT_ACTN": 3, # 3 means disabled "SIM_RC_FAIL": 1, }) self.wait_statustext("Long failsafe on", check_context=True) self.wait_mode("RTL") # self.context_clear_collection("STATUSTEXT") self.set_parameter("SIM_RC_FAIL", 0) self.wait_text("Long Failsafe Cleared", check_context=True) self.change_mode("MANUAL") self.progress("Trying again with THR_FS_VALUE") self.set_parameters({ "THR_FS_VALUE": 960, "SIM_RC_FAIL": 2, }) self.wait_statustext("Long Failsafe on", check_context=True) self.wait_mode("RTL") except Exception as e: self.print_exception_caught(e) ex = e self.context_pop() if ex is not None: raise ex self.start_subtest("Not use RC throttle input when THR_FAILSAFE==2") self.takeoff(100) self.set_rc(3, 1800) self.set_rc(1, 2000) self.wait_attitude(desroll=45, timeout=1) self.context_push() self.set_parameters({ "THR_FAILSAFE": 2, "SIM_RC_FAIL": 1, # no pulses }) self.delay_sim_time(1) self.wait_attitude(desroll=0, timeout=5) self.assert_servo_channel_value(3, self.get_parameter("RC3_MIN")) self.set_parameters({ "SIM_RC_FAIL": 0, # fix receiver }) self.zero_throttle() self.disarm_vehicle(force=True) self.context_pop() self.reboot_sitl() def ThrottleFailsafeFence(self): '''Fly fence survives throttle failsafe''' fence_bit = mavutil.mavlink.MAV_SYS_STATUS_GEOFENCE self.progress("Checking fence is not present before being configured") m = self.mav.recv_match(type='SYS_STATUS', blocking=True) self.progress("Got (%s)" % str(m)) if (m.onboard_control_sensors_enabled & fence_bit): raise NotAchievedException("Fence enabled before being configured") self.change_mode('MANUAL') self.wait_ready_to_arm() self.load_fence("CMAC-fence.txt") self.set_parameter("RC7_OPTION", 11) # AC_Fence uses Aux switch functionality self.set_parameter("FENCE_ACTION", 4) # Fence action Brake self.set_rc_from_map({ 3: 1000, 7: 2000, }) # Turn fence on with aux function m = self.mav.recv_match(type='FENCE_STATUS', blocking=True, timeout=2) self.progress("Got (%s)" % str(m)) if m is None: raise NotAchievedException("Got FENCE_STATUS unexpectedly") self.progress("Checking fence is initially OK") self.wait_sensor_state(mavutil.mavlink.MAV_SYS_STATUS_GEOFENCE, present=True, enabled=True, healthy=True, verbose=True, timeout=30) self.set_parameter("THR_FS_VALUE", 960) self.progress("Failing receiver (throttle-to-950)") self.set_parameter("SIM_RC_FAIL", 2) # throttle-to-950 self.wait_mode("CIRCLE") self.delay_sim_time(1) # give self.do_timesync_roundtrip() self.progress("Checking fence is OK after receiver failure (bind-values)") fence_bit = mavutil.mavlink.MAV_SYS_STATUS_GEOFENCE m = self.assert_receive_message('SYS_STATUS') if (not (m.onboard_control_sensors_enabled & fence_bit)): raise NotAchievedException("Fence not enabled after RC fail") self.do_fence_disable() # Ensure the fence is disabled after test def GCSFailsafe(self): '''Ensure Long-Failsafe works on GCS loss''' self.start_subtest("Test Failsafe: RTL") self.load_sample_mission() self.set_parameter("RTL_AUTOLAND", 1) self.change_mode("AUTO") self.takeoff() self.set_parameters({ "FS_GCS_ENABL": 1, "FS_LONG_ACTN": 1, }) self.progress("Disconnecting GCS") self.set_heartbeat_rate(0) self.wait_mode("RTL", timeout=5) self.set_heartbeat_rate(self.speedup) self.end_subtest("Completed RTL Failsafe test") self.start_subtest("Test Failsafe: FBWA Glide") self.set_parameters({ "RTL_AUTOLAND": 1, "FS_LONG_ACTN": 2, }) self.change_mode("AUTO") self.takeoff() self.progress("Disconnecting GCS") self.set_heartbeat_rate(0) self.wait_mode("FBWA", timeout=5) self.set_heartbeat_rate(self.speedup) self.end_subtest("Completed FBWA Failsafe test") self.start_subtest("Test Failsafe: Deploy Parachute") self.load_mission("plane-parachute-mission.txt") self.set_current_waypoint(1) self.set_parameters({ "CHUTE_ENABLED": 1, "CHUTE_TYPE": 10, "SERVO9_FUNCTION": 27, "SIM_PARA_ENABLE": 1, "SIM_PARA_PIN": 9, "FS_LONG_ACTN": 3, }) self.change_mode("AUTO") self.progress("Disconnecting GCS") self.set_heartbeat_rate(0) self.wait_statustext("BANG", timeout=60) self.set_heartbeat_rate(self.speedup) self.disarm_vehicle(force=True) self.reboot_sitl() self.end_subtest("Completed Parachute Failsafe test") def TestGripperMission(self): '''Test Gripper mission items''' self.context_push() ex = None try: self.set_parameter("RTL_AUTOLAND", 1) self.load_mission("plane-gripper-mission.txt") self.set_current_waypoint(1) self.change_mode('AUTO') self.wait_ready_to_arm() self.arm_vehicle() self.wait_statustext("Gripper Grabbed", timeout=60) self.wait_statustext("Gripper Released", timeout=60) self.wait_statustext("Auto disarmed", timeout=60) except Exception as e: self.print_exception_caught(e) ex = e self.context_pop() if ex is not None: raise ex def assert_fence_sys_status(self, present, enabled, health): self.delay_sim_time(1) self.do_timesync_roundtrip() m = self.assert_receive_message('SYS_STATUS', timeout=1) tests = [ ("present", present, m.onboard_control_sensors_present), ("enabled", enabled, m.onboard_control_sensors_enabled), ("health", health, m.onboard_control_sensors_health), ] bit = mavutil.mavlink.MAV_SYS_STATUS_GEOFENCE for test in tests: (name, want, field) = test got = (field & bit) != 0 if want != got: raise NotAchievedException("fence status incorrect; %s want=%u got=%u" % (name, want, got)) def wait_circling_point_with_radius(self, loc, want_radius, epsilon=5.0, min_circle_time=5, timeout=120): on_radius_start_heading = None average_radius = 0.0 circle_time_start = 0 done_time = False done_angle = False tstart = self.get_sim_time() while True: if self.get_sim_time() - tstart > timeout: raise AutoTestTimeoutException("Did not get onto circle") here = self.mav.location() got_radius = self.get_distance(loc, here) average_radius = 0.95*average_radius + 0.05*got_radius on_radius = abs(got_radius - want_radius) < epsilon m = self.mav.recv_match(type='VFR_HUD', blocking=True) heading = m.heading on_string = "off" got_angle = "" if on_radius_start_heading is not None: got_angle = "%0.2f" % abs(on_radius_start_heading - heading) # FIXME on_string = "on" want_angle = 180 # we don't actually get this (angle-substraction issue. But we get enough... self.progress("wait-circling: got-r=%0.2f want-r=%f avg-r=%f %s want-a=%0.1f got-a=%s" % (got_radius, want_radius, average_radius, on_string, want_angle, got_angle)) if on_radius: if on_radius_start_heading is None: on_radius_start_heading = heading average_radius = got_radius circle_time_start = self.get_sim_time() continue if abs(on_radius_start_heading - heading) > want_angle: # FIXME done_angle = True if self.get_sim_time() - circle_time_start > min_circle_time: done_time = True if done_time and done_angle: return continue if on_radius_start_heading is not None: average_radius = 0.0 on_radius_start_heading = None circle_time_start = 0 def FenceStatic(self): '''Test Basic Fence Functionality''' ex = None try: self.progress("Checking for bizarre healthy-when-not-present-or-enabled") self.set_parameter("FENCE_TYPE", 4) # Start by only setting polygon fences, otherwise fence will report present self.assert_fence_sys_status(False, False, True) self.load_fence("CMAC-fence.txt") m = self.mav.recv_match(type='FENCE_STATUS', blocking=True, timeout=2) if m is not None: raise NotAchievedException("Got FENCE_STATUS unexpectedly") self.set_parameter("FENCE_ACTION", 0) # report only self.assert_fence_sys_status(True, False, True) self.set_parameter("FENCE_ACTION", 1) # RTL self.assert_fence_sys_status(True, False, True) self.do_fence_enable() self.assert_fence_sys_status(True, True, True) m = self.assert_receive_message('FENCE_STATUS', timeout=2) if m.breach_status: raise NotAchievedException("Breached fence unexpectedly (%u)" % (m.breach_status)) self.do_fence_disable() self.assert_fence_sys_status(True, False, True) self.set_parameter("FENCE_ACTION", 1) self.assert_fence_sys_status(True, False, True) self.set_parameter("FENCE_ACTION", 0) self.assert_fence_sys_status(True, False, True) self.clear_fence() if self.get_parameter("FENCE_TOTAL") != 0: raise NotAchievedException("Expected zero points remaining") self.assert_fence_sys_status(False, False, True) self.progress("Trying to enable fence with no points") self.do_fence_enable(want_result=mavutil.mavlink.MAV_RESULT_FAILED) # test a rather unfortunate behaviour: self.progress("Killing a live fence with fence-clear") self.load_fence("CMAC-fence.txt") self.set_parameter("FENCE_ACTION", 1) # AC_FENCE_ACTION_RTL_AND_LAND == 1. mavutil.mavlink.FENCE_ACTION_RTL == 4 self.do_fence_enable() self.assert_fence_sys_status(True, True, True) self.clear_fence() self.wait_sensor_state(mavutil.mavlink.MAV_SYS_STATUS_GEOFENCE, False, False, True) if self.get_parameter("FENCE_TOTAL") != 0: raise NotAchievedException("Expected zero points remaining") self.assert_fence_sys_status(False, False, True) self.do_fence_disable() # ensure that a fence is present if it is tin can, min alt or max alt self.progress("Test other fence types (tin-can, min alt, max alt") self.set_parameter("FENCE_TYPE", 1) # max alt self.assert_fence_sys_status(True, False, True) self.set_parameter("FENCE_TYPE", 8) # min alt self.assert_fence_sys_status(True, False, True) self.set_parameter("FENCE_TYPE", 2) # tin can self.assert_fence_sys_status(True, False, True) # Test cannot arm if outside of fence and fence is enabled self.progress("Test Arming while vehicle below FENCE_ALT_MIN") default_fence_alt_min = self.get_parameter("FENCE_ALT_MIN") self.set_parameter("FENCE_ALT_MIN", 50) self.set_parameter("FENCE_TYPE", 8) # Enables minimum altitude breaches self.do_fence_enable() self.delay_sim_time(2) # Allow breach to propagate self.assert_fence_enabled() self.try_arm(False, "vehicle outside fence") self.do_fence_disable() self.set_parameter("FENCE_ALT_MIN", default_fence_alt_min) # Test arming outside inclusion zone self.progress("Test arming while vehicle outside of inclusion zone") self.set_parameter("FENCE_TYPE", 4) # Enables polygon fence types locs = [ mavutil.location(1.000, 1.000, 0, 0), mavutil.location(1.000, 1.001, 0, 0), mavutil.location(1.001, 1.001, 0, 0), mavutil.location(1.001, 1.000, 0, 0) ] self.upload_fences_from_locations( mavutil.mavlink.MAV_CMD_NAV_FENCE_POLYGON_VERTEX_INCLUSION, [ locs ] ) self.delay_sim_time(10) # let fence check run so it loads-from-eeprom self.do_fence_enable() self.assert_fence_enabled() self.delay_sim_time(2) # Allow breach to propagate self.try_arm(False, "vehicle outside fence") self.do_fence_disable() self.clear_fence() self.progress("Test arming while vehicle inside exclusion zone") self.set_parameter("FENCE_TYPE", 4) # Enables polygon fence types home_loc = self.mav.location() locs = [ mavutil.location(home_loc.lat - 0.001, home_loc.lng - 0.001, 0, 0), mavutil.location(home_loc.lat - 0.001, home_loc.lng + 0.001, 0, 0), mavutil.location(home_loc.lat + 0.001, home_loc.lng + 0.001, 0, 0), mavutil.location(home_loc.lat + 0.001, home_loc.lng - 0.001, 0, 0), ] self.upload_fences_from_locations( mavutil.mavlink.MAV_CMD_NAV_FENCE_POLYGON_VERTEX_EXCLUSION, [ locs ] ) self.delay_sim_time(10) # let fence check run so it loads-from-eeprom self.do_fence_enable() self.assert_fence_enabled() self.delay_sim_time(2) # Allow breach to propagate self.try_arm(False, "vehicle outside fence") self.do_fence_disable() self.clear_fence() except Exception as e: self.print_exception_caught(e) ex = e self.clear_fence() if ex is not None: raise ex def test_fence_breach_circle_at(self, loc, disable_on_breach=False): ex = None try: self.load_fence("CMAC-fence.txt") want_radius = 100 # when ArduPlane is fixed, remove this fudge factor REALLY_BAD_FUDGE_FACTOR = 1.16 expected_radius = REALLY_BAD_FUDGE_FACTOR * want_radius self.set_parameters({ "RTL_RADIUS": want_radius, "NAVL1_LIM_BANK": 60, "FENCE_ACTION": 1, # AC_FENCE_ACTION_RTL_AND_LAND == 1. mavutil.mavlink.FENCE_ACTION_RTL == 4 }) self.wait_ready_to_arm() # need an origin to load fence self.do_fence_enable() self.assert_fence_sys_status(True, True, True) self.takeoff(alt=45, alt_max=300) tstart = self.get_sim_time() while True: if self.get_sim_time() - tstart > 30: raise NotAchievedException("Did not breach fence") m = self.assert_receive_message('FENCE_STATUS', timeout=2) if m.breach_status == 0: continue # we've breached; check our state; if m.breach_type != mavutil.mavlink.FENCE_BREACH_BOUNDARY: raise NotAchievedException("Unexpected breach type %u" % (m.breach_type,)) if m.breach_count == 0: raise NotAchievedException("Unexpected breach count %u" % (m.breach_count,)) self.assert_fence_sys_status(True, True, False) break if disable_on_breach: self.do_fence_disable() self.wait_circling_point_with_radius(loc, expected_radius) self.disarm_vehicle(force=True) self.reboot_sitl() except Exception as e: self.print_exception_caught(e) ex = e self.clear_fence() if ex is not None: raise ex def FenceRTL(self): '''Test Fence RTL''' self.progress("Testing FENCE_ACTION_RTL no rally point") # have to disable the fence once we've breached or we breach # it as part of the loiter-at-home! self.test_fence_breach_circle_at(self.home_position_as_mav_location(), disable_on_breach=True) def FenceRTLRally(self): '''Test Fence RTL Rally''' ex = None target_system = 1 target_component = 1 try: self.progress("Testing FENCE_ACTION_RTL with rally point") self.wait_ready_to_arm() loc = self.home_relative_loc_ne(50, -50) self.set_parameter("RALLY_TOTAL", 1) self.mav.mav.rally_point_send(target_system, target_component, 0, # sequence number 1, # total count int(loc.lat * 1e7), int(loc.lng * 1e7), 15, 0, # "break" alt?! 0, # "land dir" 0) # flags self.delay_sim_time(1) if self.mavproxy is not None: self.mavproxy.send("rally list\n") self.test_fence_breach_circle_at(loc) except Exception as e: self.print_exception_caught(e) ex = e self.clear_mission(mavutil.mavlink.MAV_MISSION_TYPE_RALLY) if ex is not None: raise ex def FenceRetRally(self): """ Tests the FENCE_RET_RALLY flag, either returning to fence return point, or rally point """ target_system = 1 target_component = 1 self.progress("Testing FENCE_ACTION_RTL with fence rally point") self.wait_ready_to_arm() self.homeloc = self.mav.location() # Grab a location for fence return point, and upload it. fence_loc = self.home_position_as_mav_location() self.location_offset_ne(fence_loc, 50, 50) fence_return_mission_items = [ self.mav.mav.mission_item_int_encode( target_system, target_component, 0, # seq mavutil.mavlink.MAV_FRAME_GLOBAL_INT, mavutil.mavlink.MAV_CMD_NAV_FENCE_RETURN_POINT, 0, # current 0, # autocontinue 0, # p1 0, # p2 0, # p3 0, # p4 int(fence_loc.lat * 1e7), # latitude int(fence_loc.lng * 1e7), # longitude 0, # altitude mavutil.mavlink.MAV_MISSION_TYPE_FENCE ) ] self.upload_using_mission_protocol(mavutil.mavlink.MAV_MISSION_TYPE_FENCE, fence_return_mission_items) self.delay_sim_time(1) # Grab a location for rally point, and upload it. rally_loc = self.home_relative_loc_ne(-50, 50) self.set_parameter("RALLY_TOTAL", 1) self.mav.mav.rally_point_send(target_system, target_component, 0, # sequence number 1, # total count int(rally_loc.lat * 1e7), int(rally_loc.lng * 1e7), 15, 0, # "break" alt?! 0, # "land dir" 0) # flags self.delay_sim_time(1) return_radius = 100 return_alt = 80 self.set_parameters({ "RTL_RADIUS": return_radius, "FENCE_ACTION": 6, # Set Fence Action to Guided "FENCE_TYPE": 8, # Only use fence floor "FENCE_RET_ALT": return_alt, }) self.do_fence_enable() self.assert_fence_enabled() self.takeoff(alt=50, alt_max=300) # Trigger fence breach, fly to rally location self.set_parameters({ "FENCE_RET_RALLY": 1, "FENCE_ALT_MIN": 60, }) self.wait_circling_point_with_radius(rally_loc, return_radius) self.set_parameter("FENCE_ALT_MIN", 0) # Clear fence breach # 10 second fence min retrigger time self.delay_sim_time(15) # Fly up before re-triggering fence breach. Fly to fence return point self.change_altitude(self.homeloc.alt+30) self.set_parameters({ "FENCE_RET_RALLY": 0, "FENCE_ALT_MIN": 60, }) self.wait_altitude(altitude_min=return_alt-3, altitude_max=return_alt+3, relative=True) self.wait_circling_point_with_radius(fence_loc, return_radius) self.do_fence_disable() # Disable fence so we can land self.fly_home_land_and_disarm() # Pack it up, we're going home. def Parachute(self): '''Test Parachute''' self.set_rc(9, 1000) self.set_parameters({ "CHUTE_ENABLED": 1, "CHUTE_TYPE": 10, "SERVO9_FUNCTION": 27, "SIM_PARA_ENABLE": 1, "SIM_PARA_PIN": 9, }) self.load_mission("plane-parachute-mission.txt") self.set_current_waypoint(1) self.change_mode('AUTO') self.wait_ready_to_arm() self.arm_vehicle() self.wait_statustext("BANG", timeout=60) self.disarm_vehicle(force=True) self.reboot_sitl() def ParachuteSinkRate(self): '''Test Parachute (SinkRate triggering)''' self.set_rc(9, 1000) self.set_parameters({ "CHUTE_ENABLED": 1, "CHUTE_TYPE": 10, "SERVO9_FUNCTION": 27, "SIM_PARA_ENABLE": 1, "SIM_PARA_PIN": 9, "CHUTE_CRT_SINK": 9, }) self.progress("Takeoff") self.takeoff(alt=300) self.progress("Diving") self.set_rc(2, 2000) self.wait_statustext("BANG", timeout=60) self.disarm_vehicle(force=True) self.reboot_sitl() def run_subtest(self, desc, func): self.start_subtest(desc) func() def check_attitudes_match(self, a, b): '''make sure ahrs2 and simstate and ATTTIUDE_QUATERNION all match''' # these are ordered to bookend the list with timestamps (which # both attitude messages have): get_names = ['ATTITUDE', 'SIMSTATE', 'AHRS2', 'ATTITUDE_QUATERNION'] msgs = self.get_messages_frame(get_names) for get_name in get_names: self.progress("%s: %s" % (get_name, msgs[get_name])) simstate = msgs['SIMSTATE'] attitude = msgs['ATTITUDE'] ahrs2 = msgs['AHRS2'] attitude_quaternion = msgs['ATTITUDE_QUATERNION'] # check ATTITUDE want = math.degrees(simstate.roll) got = math.degrees(attitude.roll) if abs(mavextra.angle_diff(want, got)) > 20: raise NotAchievedException("ATTITUDE.Roll looks bad (want=%f got=%f)" % (want, got)) want = math.degrees(simstate.pitch) got = math.degrees(attitude.pitch) if abs(mavextra.angle_diff(want, got)) > 20: raise NotAchievedException("ATTITUDE.Pitch looks bad (want=%f got=%f)" % (want, got)) # check AHRS2 want = math.degrees(simstate.roll) got = math.degrees(ahrs2.roll) if abs(mavextra.angle_diff(want, got)) > 20: raise NotAchievedException("AHRS2.Roll looks bad (want=%f got=%f)" % (want, got)) want = math.degrees(simstate.pitch) got = math.degrees(ahrs2.pitch) if abs(mavextra.angle_diff(want, got)) > 20: raise NotAchievedException("AHRS2.Pitch looks bad (want=%f got=%f)" % (want, got)) # check ATTITUDE_QUATERNION q = quaternion.Quaternion([ attitude_quaternion.q1, attitude_quaternion.q2, attitude_quaternion.q3, attitude_quaternion.q4 ]) euler = q.euler self.progress("attquat:%s q:%s euler:%s" % ( str(attitude_quaternion), q, euler)) want = math.degrees(simstate.roll) got = math.degrees(euler[0]) if mavextra.angle_diff(want, got) > 20: raise NotAchievedException("quat roll differs from attitude roll; want=%f got=%f" % (want, got)) want = math.degrees(simstate.pitch) got = math.degrees(euler[1]) if mavextra.angle_diff(want, got) > 20: raise NotAchievedException("quat pitch differs from attitude pitch; want=%f got=%f" % (want, got)) def fly_ahrs2_test(self): '''check secondary estimator is looking OK''' ahrs2 = self.mav.recv_match(type='AHRS2', blocking=True, timeout=1) if ahrs2 is None: raise NotAchievedException("Did not receive AHRS2 message") self.progress("AHRS2: %s" % str(ahrs2)) # check location gpi = self.mav.recv_match( type='GLOBAL_POSITION_INT', blocking=True, timeout=5 ) if gpi is None: raise NotAchievedException("Did not receive GLOBAL_POSITION_INT message") self.progress("GPI: %s" % str(gpi)) if self.get_distance_int(gpi, ahrs2) > 10: raise NotAchievedException("Secondary location looks bad") self.check_attitudes_match(1, 2) def MainFlight(self): '''Lots of things in one flight''' self.change_mode('MANUAL') self.progress("Asserting we do support transfer of fence via mission item protocol") self.assert_capability(mavutil.mavlink.MAV_PROTOCOL_CAPABILITY_MISSION_FENCE) # grab home position: self.mav.recv_match(type='HOME_POSITION', blocking=True) self.homeloc = self.mav.location() self.run_subtest("Takeoff", self.takeoff) self.run_subtest("Set Attitude Target", self.set_attitude_target) self.run_subtest("Fly left circuit", self.fly_left_circuit) self.run_subtest("Left roll", lambda: self.axial_left_roll(1)) self.run_subtest("Inside loop", self.inside_loop) self.run_subtest("Stablize test", self.test_stabilize) self.run_subtest("ACRO test", self.test_acro) self.run_subtest("FBWB test", self.test_FBWB) self.run_subtest("CRUISE test", lambda: self.test_FBWB(mode='CRUISE')) self.run_subtest("RTL test", self.fly_RTL) self.run_subtest("LOITER test", self.fly_LOITER) self.run_subtest("CIRCLE test", self.fly_CIRCLE) self.run_subtest("AHRS2 test", self.fly_ahrs2_test) self.run_subtest("Mission test", lambda: self.fly_mission("ap1.txt", strict=False)) def PitotBlockage(self): '''Test detection and isolation of a blocked pitot tube''' self.set_parameters({ "ARSPD_OPTIONS": 15, "ARSPD_USE": 1, "SIM_WIND_SPD": 7, "SIM_WIND_DIR": 0, "ARSPD_WIND_MAX": 15, }) self.change_mode("TAKEOFF") self.wait_ready_to_arm() self.arm_vehicle() # simulate the effect of a blocked pitot tube self.set_parameter("ARSPD_RATIO", 0.1) self.delay_sim_time(10) if (self.get_parameter("ARSPD_USE") == 0): self.progress("Faulty Sensor Disabled") else: raise NotAchievedException("Airspeed Sensor Not Disabled") self.delay_sim_time(20) # simulate the effect of blockage partially clearing self.set_parameter("ARSPD_RATIO", 1.0) self.delay_sim_time(60) if (self.get_parameter("ARSPD_USE") == 0): self.progress("Faulty Sensor Remains Disabled") else: raise NotAchievedException("Fault Sensor Re-Enabled") # simulate the effect of blockage fully clearing self.set_parameter("ARSPD_RATIO", 2.0) self.delay_sim_time(60) if (self.get_parameter("ARSPD_USE") == 1): self.progress("Sensor Re-Enabled") else: raise NotAchievedException("Airspeed Sensor Not Re-Enabled") self.disarm_vehicle(force=True) def AIRSPEED_AUTOCAL(self): '''Test AIRSPEED_AUTOCAL''' self.progress("Ensure no AIRSPEED_AUTOCAL on ground") self.set_parameters({ "ARSPD_AUTOCAL": 1, "ARSPD_PIN": 2, "ARSPD_RATIO": 0, "ARSPD2_RATIO": 4, "ARSPD2_TYPE": 3, # MS5525 "ARSPD2_BUS": 1, "ARSPD2_AUTOCAL": 1, "SIM_ARSPD2_OFS": 1900, # default is 2013 "RTL_AUTOLAND": 1, }) self.context_collect('STATUSTEXT') self.reboot_sitl() self.assert_not_receive_message('AIRSPEED_AUTOCAL', timeout=5) # these are boot-time calibration messages: self.wait_statustext('Airspeed 1 calibrated', check_context=True, timeout=30) self.wait_statustext('Airspeed 2 calibrated', check_context=True) mission_filepath = "flaps.txt" self.load_mission(mission_filepath) self.wait_ready_to_arm() self.arm_vehicle() self.change_mode("AUTO") self.progress("Ensure AIRSPEED_AUTOCAL in air") self.assert_receive_message('AIRSPEED_AUTOCAL') self.wait_statustext("Airspeed 0 ratio reset", check_context=True, timeout=70) self.wait_statustext("Airspeed 1 ratio reset", check_context=True, timeout=70) self.fly_home_land_and_disarm() def deadreckoning_main(self, disable_airspeed_sensor=False): self.wait_ready_to_arm() self.gpi = None self.simstate = None self.last_print = 0 self.max_divergence = 0 def validate_global_position_int_against_simstate(mav, m): if m.get_type() == 'GLOBAL_POSITION_INT': self.gpi = m elif m.get_type() == 'SIMSTATE': self.simstate = m if self.gpi is None: return if self.simstate is None: return divergence = self.get_distance_int(self.gpi, self.simstate) max_allowed_divergence = 200 if (time.time() - self.last_print > 1 or divergence > self.max_divergence): self.progress("position-estimate-divergence=%fm" % (divergence,)) self.last_print = time.time() if divergence > self.max_divergence: self.max_divergence = divergence if divergence > max_allowed_divergence: raise NotAchievedException( "global-position-int diverged from simstate by %fm (max=%fm" % (divergence, max_allowed_divergence,)) self.install_message_hook(validate_global_position_int_against_simstate) try: # wind is from the West: self.set_parameter("SIM_WIND_DIR", 270) # light winds: self.set_parameter("SIM_WIND_SPD", 10) if disable_airspeed_sensor: self.set_parameter("ARSPD_USE", 0) self.takeoff(50) loc = self.mav.location() self.location_offset_ne(loc, 500, 500) self.run_cmd_int( mavutil.mavlink.MAV_CMD_DO_REPOSITION, 0, mavutil.mavlink.MAV_DO_REPOSITION_FLAGS_CHANGE_MODE, 0, 0, int(loc.lat * 1e7), int(loc.lng * 1e7), 100, # alt frame=mavutil.mavlink.MAV_FRAME_GLOBAL_RELATIVE_ALT_INT, ) self.wait_location(loc, accuracy=100) self.progress("Stewing") self.delay_sim_time(20) self.set_parameter("SIM_GPS_DISABLE", 1) self.progress("Roasting") self.delay_sim_time(20) self.change_mode("RTL") self.wait_distance_to_home(100, 200, timeout=200) self.set_parameter("SIM_GPS_DISABLE", 0) self.delay_sim_time(10) self.set_rc(3, 1000) self.fly_home_land_and_disarm() self.progress("max-divergence: %fm" % (self.max_divergence,)) finally: self.remove_message_hook(validate_global_position_int_against_simstate) def Deadreckoning(self): '''Test deadreckoning support''' self.deadreckoning_main() def DeadreckoningNoAirSpeed(self): '''Test deadreckoning support with no airspeed sensor''' self.deadreckoning_main(disable_airspeed_sensor=True) def ClimbBeforeTurn(self): '''Test climb-before-turn''' self.wait_ready_to_arm() self.set_parameters({ "FLIGHT_OPTIONS": 0, "ALT_HOLD_RTL": 8000, "RTL_AUTOLAND": 1, }) takeoff_alt = 10 self.takeoff(alt=takeoff_alt) self.change_mode("CRUISE") self.wait_distance_to_home(500, 1000, timeout=60) self.change_mode("RTL") expected_alt = self.get_parameter("ALT_HOLD_RTL") / 100.0 home = self.home_position_as_mav_location() distance = self.get_distance(home, self.mav.location()) self.wait_altitude(expected_alt - 10, expected_alt + 10, relative=True, timeout=80) new_distance = self.get_distance(home, self.mav.location()) # We should be closer to home. if new_distance > distance: raise NotAchievedException( "Expected to be closer to home (was %fm, now %fm)." % (distance, new_distance) ) self.fly_home_land_and_disarm() self.set_current_waypoint(0, check_afterwards=False) self.change_mode("MANUAL") self.set_rc(3, 1000) self.wait_ready_to_arm() self.set_parameters({ "FLIGHT_OPTIONS": 16, "ALT_HOLD_RTL": 10000, }) self.takeoff(alt=takeoff_alt) self.change_mode("CRUISE") self.wait_distance_to_home(500, 1000, timeout=60) self.change_mode("RTL") home = self.home_position_as_mav_location() distance = self.get_distance(home, self.mav.location()) self.wait_altitude(expected_alt - 10, expected_alt + 10, relative=True, timeout=80) new_distance = self.get_distance(home, self.mav.location()) # We should be farther from to home. if new_distance < distance: raise NotAchievedException( "Expected to be farther from home (was %fm, now %fm)." % (distance, new_distance) ) self.fly_home_land_and_disarm(timeout=240) def RTL_CLIMB_MIN(self): '''Test RTL_CLIMB_MIN''' self.wait_ready_to_arm() rtl_climb_min = 100 self.set_parameter("RTL_CLIMB_MIN", rtl_climb_min) takeoff_alt = 50 self.takeoff(alt=takeoff_alt) self.change_mode('CRUISE') self.wait_distance_to_home(1000, 1500, timeout=60) post_cruise_alt = self.get_altitude(relative=True) self.change_mode('RTL') expected_alt = self.get_parameter("ALT_HOLD_RTL")/100.0 if expected_alt == -1: expected_alt = self.get_altitude(relative=True) # ensure we're about half-way-down at the half-way-home stage: self.wait_distance_to_nav_target( 0, 500, timeout=240, ) alt = self.get_altitude(relative=True) expected_halfway_alt = expected_alt + (post_cruise_alt + rtl_climb_min - expected_alt)/2.0 if abs(alt - expected_halfway_alt) > 30: raise NotAchievedException("Not half-way-down and half-way-home (want=%f got=%f" % (expected_halfway_alt, alt)) self.progress("Half-way-down at half-way-home (want=%f vs got=%f)" % (expected_halfway_alt, alt)) rtl_radius = self.get_parameter("RTL_RADIUS") if rtl_radius == 0: rtl_radius = self.get_parameter("WP_LOITER_RAD") self.wait_distance_to_nav_target( 0, rtl_radius, timeout=120, ) alt = self.get_altitude(relative=True) if abs(alt - expected_alt) > 10: raise NotAchievedException( "Expected to have %fm altitude at end of RTL (got %f)" % (expected_alt, alt)) self.fly_home_land_and_disarm() def sample_enable_parameter(self): return "Q_ENABLE" def RangeFinder(self): '''Test RangeFinder Basic Functionality''' self.context_push() self.progress("Making sure we don't ordinarily get RANGEFINDER") self.assert_not_receive_message('RANGEFDINDER') self.set_analog_rangefinder_parameters() self.reboot_sitl() '''ensure rangefinder gives height-above-ground''' self.load_mission("plane-gripper-mission.txt") # borrow this self.set_parameter("RTL_AUTOLAND", 1) self.set_current_waypoint(1) self.change_mode('AUTO') self.wait_ready_to_arm() self.arm_vehicle() self.wait_waypoint(5, 5, max_dist=100) rf = self.mav.recv_match(type="RANGEFINDER", timeout=1, blocking=True) if rf is None: raise NotAchievedException("Did not receive rangefinder message") gpi = self.mav.recv_match(type='GLOBAL_POSITION_INT', blocking=True, timeout=1) if gpi is None: raise NotAchievedException("Did not receive GLOBAL_POSITION_INT message") if abs(rf.distance - gpi.relative_alt/1000.0) > 3: raise NotAchievedException( "rangefinder alt (%s) disagrees with global-position-int.relative_alt (%s)" % (rf.distance, gpi.relative_alt/1000.0)) self.wait_statustext("Auto disarmed", timeout=60) self.progress("Ensure RFND messages in log") if not self.current_onboard_log_contains_message("RFND"): raise NotAchievedException("No RFND messages in log") self.context_pop() self.reboot_sitl() def rc_defaults(self): ret = super(AutoTestPlane, self).rc_defaults() ret[3] = 1000 ret[8] = 1800 return ret def initial_mode_switch_mode(self): return "MANUAL" def default_mode(self): return "MANUAL" def PIDTuning(self): '''Test PID Tuning''' self.change_mode("FBWA") # we don't update PIDs in MANUAL super(AutoTestPlane, self).PIDTuning() def AuxModeSwitch(self): '''Set modes via auxswitches''' self.set_parameter("FLTMODE1", 1) # circle self.set_rc(8, 950) self.wait_mode("CIRCLE") self.set_rc(9, 1000) self.set_rc(10, 1000) self.set_parameters({ "RC9_OPTION": 4, # RTL "RC10_OPTION": 55, # guided }) self.set_rc(9, 1900) self.wait_mode("RTL") self.set_rc(10, 1900) self.wait_mode("GUIDED") self.progress("resetting both switches - should go back to CIRCLE") self.set_rc(9, 1000) self.set_rc(10, 1000) self.wait_mode("CIRCLE") self.set_rc(9, 1900) self.wait_mode("RTL") self.set_rc(10, 1900) self.wait_mode("GUIDED") self.progress("Resetting switch should repoll mode switch") self.set_rc(10, 1000) # this re-polls the mode switch self.wait_mode("CIRCLE") self.set_rc(9, 1000) def wait_for_collision_threat_to_clear(self): '''wait to get a "clear" collision message", then slurp remaining messages''' last_collision = self.get_sim_time() while True: now = self.get_sim_time() if now - last_collision > 5: return self.progress("Waiting for collision message") m = self.mav.recv_match(type='COLLISION', blocking=True, timeout=1) self.progress("Got (%s)" % str(m)) if m is None: continue last_collision = now def SimADSB(self): '''Tests to ensure simulated ADSB sensor continues to function''' self.set_parameters({ "SIM_ADSB_COUNT": 1, "ADSB_TYPE": 1, }) self.reboot_sitl() self.assert_receive_message('ADSB_VEHICLE', timeout=30) def ADSB(self): '''Test ADSB''' self.ADSB_f_action_rtl() self.ADSB_r_action_resume_or_loiter() def ADSB_r_action_resume_or_loiter(self): '''ensure we resume auto mission or enter loiter''' self.set_parameters({ "ADSB_TYPE": 1, "AVD_ENABLE": 1, "AVD_F_ACTION": mavutil.mavlink.MAV_COLLISION_ACTION_MOVE_HORIZONTALLY, "AVD_F_RCVRY": 3, # resume auto or loiter }) self.reboot_sitl() self.takeoff(50) # fly North, create thread to east, wait for flying east self.start_subtest("Testing loiter resume") self.reach_heading_manual(0) here = self.mav.location() self.test_adsb_send_threatening_adsb_message(here, offset_ne=(0, 30)) self.wait_mode('AVOID_ADSB') # recovery has the vehicle circling a point... but we don't # know which point. So wait 'til it looks like it is # circling, then grab the point, then check we're circling # it... self.wait_heading(290) self.wait_heading(300) dest = self.position_target_loc() REALLY_BAD_FUDGE_FACTOR = 1.25 # FIXME expected_radius = REALLY_BAD_FUDGE_FACTOR * self.get_parameter('WP_LOITER_RAD') self.wait_circling_point_with_radius(dest, expected_radius) self.start_subtest("Testing mission resume") self.reach_heading_manual(270) self.load_generic_mission("CMAC-circuit.txt", strict=False) self.change_mode('AUTO') self.wait_current_waypoint(2) self.test_adsb_send_threatening_adsb_message(here, offset_ne=(0, 30)) self.wait_mode('AVOID_ADSB') self.wait_mode('AUTO') self.fly_home_land_and_disarm() def ADSB_f_action_rtl(self): self.context_push() ex = None try: # message ADSB_VEHICLE 37 -353632614 1491652305 0 584070 0 0 0 "bob" 3 1 255 17 self.set_parameter("RC12_OPTION", 38) # avoid-adsb self.set_rc(12, 2000) self.set_parameters({ "ADSB_TYPE": 1, "AVD_ENABLE": 1, "AVD_F_ACTION": mavutil.mavlink.MAV_COLLISION_ACTION_RTL, }) self.reboot_sitl() self.wait_ready_to_arm() here = self.mav.location() self.change_mode("FBWA") self.delay_sim_time(2) # TODO: work out why this is required... self.test_adsb_send_threatening_adsb_message(here) self.progress("Waiting for collision message") m = self.assert_receive_message('COLLISION', timeout=4) if m.threat_level != 2: raise NotAchievedException("Expected some threat at least") if m.action != mavutil.mavlink.MAV_COLLISION_ACTION_RTL: raise NotAchievedException("Incorrect action; want=%u got=%u" % (mavutil.mavlink.MAV_COLLISION_ACTION_RTL, m.action)) self.wait_mode("RTL") self.progress("Sending far-away ABSD_VEHICLE message") self.mav.mav.adsb_vehicle_send( 37, # ICAO address int(here.lat+1 * 1e7), int(here.lng * 1e7), mavutil.mavlink.ADSB_ALTITUDE_TYPE_PRESSURE_QNH, int(here.alt*1000 + 10000), # 10m up 0, # heading in cdeg 0, # horizontal velocity cm/s 0, # vertical velocity cm/s "bob".encode("ascii"), # callsign mavutil.mavlink.ADSB_EMITTER_TYPE_LIGHT, 1, # time since last communication 65535, # flags 17 # squawk ) self.wait_for_collision_threat_to_clear() self.change_mode("FBWA") self.progress("Disabling ADSB-avoidance with RC channel") self.set_rc(12, 1000) self.delay_sim_time(1) # let the switch get polled self.test_adsb_send_threatening_adsb_message(here) m = self.mav.recv_match(type='COLLISION', blocking=True, timeout=4) self.progress("Got (%s)" % str(m)) if m is not None: raise NotAchievedException("Got collision message when I shouldn't have") except Exception as e: self.print_exception_caught(e) ex = e self.context_pop() self.reboot_sitl() if ex is not None: raise ex def GuidedRequest(self, target_system=1, target_component=1): '''Test handling of MISSION_ITEM in guided mode''' self.progress("Takeoff") self.takeoff(alt=50) self.set_rc(3, 1500) self.start_subtest("Ensure command bounced outside guided mode") desired_relative_alt = 33 loc = self.mav.location() self.location_offset_ne(loc, 300, 300) loc.alt += desired_relative_alt self.mav.mav.mission_item_int_send( target_system, target_component, 0, # seq mavutil.mavlink.MAV_FRAME_GLOBAL, mavutil.mavlink.MAV_CMD_NAV_WAYPOINT, 2, # current - guided-mode request 0, # autocontinue 0, # p1 0, # p2 0, # p3 0, # p4 int(loc.lat * 1e7), # latitude int(loc.lng * 1e7), # longitude loc.alt, # altitude mavutil.mavlink.MAV_MISSION_TYPE_MISSION) m = self.assert_receive_message('MISSION_ACK', timeout=5) if m.type != mavutil.mavlink.MAV_MISSION_ERROR: raise NotAchievedException("Did not get appropriate error") self.start_subtest("Enter guided and flying somewhere constant") self.change_mode("GUIDED") self.mav.mav.mission_item_int_send( target_system, target_component, 0, # seq mavutil.mavlink.MAV_FRAME_GLOBAL_RELATIVE_ALT, mavutil.mavlink.MAV_CMD_NAV_WAYPOINT, 2, # current - guided-mode request 0, # autocontinue 0, # p1 0, # p2 0, # p3 0, # p4 int(loc.lat * 1e7), # latitude int(loc.lng * 1e7), # longitude desired_relative_alt, # altitude mavutil.mavlink.MAV_MISSION_TYPE_MISSION) m = self.assert_receive_message('MISSION_ACK', timeout=5) if m.type != mavutil.mavlink.MAV_MISSION_ACCEPTED: raise NotAchievedException("Did not get accepted response") self.wait_location(loc, accuracy=100) # based on loiter radius self.wait_altitude(altitude_min=desired_relative_alt-3, altitude_max=desired_relative_alt+3, relative=True, timeout=30) self.start_subtest("changing alt with mission item in guided mode") # test changing alt only - NOTE - this is still a # NAV_WAYPOINT, not a changel-alt request! desired_relative_alt = desired_relative_alt + 50 self.mav.mav.mission_item_int_send( target_system, target_component, 0, # seq mavutil.mavlink.MAV_FRAME_GLOBAL_RELATIVE_ALT, mavutil.mavlink.MAV_CMD_NAV_WAYPOINT, 3, # current - change-alt request 0, # autocontinue 0, # p1 0, # p2 0, # p3 0, # p4 0, # latitude 0, desired_relative_alt, # altitude mavutil.mavlink.MAV_MISSION_TYPE_MISSION) self.wait_altitude(altitude_min=desired_relative_alt-3, altitude_max=desired_relative_alt+3, relative=True, timeout=30) self.fly_home_land_and_disarm() def LOITER(self): '''Test Loiter mode''' # first test old loiter behavour self.set_parameter("FLIGHT_OPTIONS", 0) self.takeoff(alt=200) self.set_rc(3, 1500) self.change_mode("LOITER") self.progress("Doing a bit of loitering to start with") tstart = self.get_sim_time() while True: now = self.get_sim_time_cached() if now - tstart > 60: break m = self.mav.recv_match(type='VFR_HUD', blocking=True, timeout=5) if m is None: raise NotAchievedException("Did not get VFR_HUD") new_throttle = m.throttle alt = m.alt m = self.assert_receive_message('ATTITUDE', timeout=5) pitch = math.degrees(m.pitch) self.progress("Pitch:%f throttle:%u alt:%f" % (pitch, new_throttle, alt)) m = self.assert_receive_message('VFR_HUD', timeout=5) initial_throttle = m.throttle initial_alt = m.alt self.progress("Initial throttle: %u" % initial_throttle) # pitch down, ensure throttle decreases: rc2_max = self.get_parameter("RC2_MAX") self.set_rc(2, int(rc2_max)) tstart = self.get_sim_time() while True: now = self.get_sim_time_cached() '''stick-mixing is pushing the aircraft down. It doesn't want to go down (the target loiter altitude hasn't changed), so it tries to add energy by increasing the throttle. ''' if now - tstart > 60: raise NotAchievedException("Did not see increase in throttle") m = self.assert_receive_message('VFR_HUD', timeout=5) new_throttle = m.throttle alt = m.alt m = self.assert_receive_message('ATTITUDE', timeout=5) pitch = math.degrees(m.pitch) self.progress("Pitch:%f throttle:%u alt:%f" % (pitch, new_throttle, alt)) if new_throttle - initial_throttle > 20: self.progress("Throttle delta achieved") break self.progress("Centering elevator and ensuring we get back to loiter altitude") self.set_rc(2, 1500) self.wait_altitude(initial_alt-1, initial_alt+1) # Test new loiter behavour self.set_parameter("FLIGHT_OPTIONS", 1 << 12) # should decend at max stick self.set_rc(2, int(rc2_max)) self.wait_altitude(initial_alt - 110, initial_alt - 90, timeout=90) # should not climb back at mid stick self.set_rc(2, 1500) self.delay_sim_time(60) self.wait_altitude(initial_alt - 110, initial_alt - 90) # should climb at min stick self.set_rc(2, 1100) self.wait_altitude(initial_alt - 10, initial_alt + 10, timeout=90) # return stick to center and fly home self.set_rc(2, 1500) self.fly_home_land_and_disarm() def CPUFailsafe(self): '''In lockup Plane should copy RC inputs to RC outputs''' self.plane_CPUFailsafe() def LargeMissions(self): '''Test Manipulation of Large missions''' self.load_mission("Kingaroy-vlarge.txt", strict=False) self.load_mission("Kingaroy-vlarge2.txt", strict=False) def Soaring(self): '''Test Soaring feature''' model = "plane-soaring" self.customise_SITL_commandline( [], model=model, defaults_filepath=self.model_defaults_filepath(model), wipe=True) self.load_mission('CMAC-soar.txt', strict=False) self.set_current_waypoint(1) self.change_mode('AUTO') self.wait_ready_to_arm() self.arm_vehicle() # Enable thermalling RC rc_chan = 0 for i in range(8): rcx_option = self.get_parameter('RC{0}_OPTION'.format(i+1)) if rcx_option == 88: rc_chan = i+1 break if rc_chan == 0: raise NotAchievedException("Did not find soaring enable channel option.") self.set_rc_from_map({ rc_chan: 1900, 3: 1500, # Use trim airspeed. }) # Wait to detect thermal self.progress("Waiting for thermal") self.wait_mode('THERMAL', timeout=600) self.set_parameter("SOAR_VSPEED", 0.6) # Wait to climb to SOAR_ALT_MAX self.progress("Waiting for climb to max altitude") alt_max = self.get_parameter('SOAR_ALT_MAX') self.wait_altitude(alt_max-10, alt_max, timeout=600, relative=True) # Wait for AUTO self.progress("Waiting for AUTO mode") self.wait_mode('AUTO') # Disable thermals self.set_parameter("SIM_THML_SCENARI", 0) # Wait to descend to SOAR_ALT_MIN self.progress("Waiting for glide to min altitude") alt_min = self.get_parameter('SOAR_ALT_MIN') self.wait_altitude(alt_min-10, alt_min, timeout=600, relative=True) self.progress("Waiting for throttle up") self.wait_servo_channel_value(3, 1200, timeout=5, comparator=operator.gt) self.progress("Waiting for climb to cutoff altitude") alt_ctf = self.get_parameter('SOAR_ALT_CUTOFF') self.wait_altitude(alt_ctf-10, alt_ctf, timeout=600, relative=True) # Allow time to suppress throttle and start descent. self.delay_sim_time(20) # Now set FBWB mode self.change_mode('FBWB') self.delay_sim_time(5) # Now disable soaring (should hold altitude) self.set_parameter("SOAR_ENABLE", 0) self.delay_sim_time(10) # And reenable. This should force throttle-down self.set_parameter("SOAR_ENABLE", 1) self.delay_sim_time(10) # Now wait for descent and check throttle up self.wait_altitude(alt_min-10, alt_min, timeout=600, relative=True) self.progress("Waiting for climb") self.wait_altitude(alt_ctf-10, alt_ctf, timeout=600, relative=True) # Back to auto self.change_mode('AUTO') # Reenable thermals self.set_parameter("SIM_THML_SCENARI", 1) # Disable soaring using RC channel. self.set_rc(rc_chan, 1100) # Wait to get back to waypoint before thermal. self.progress("Waiting to get back to position") self.wait_current_waypoint(3, timeout=1200) # Enable soaring with mode changes suppressed) self.set_rc(rc_chan, 1500) # Make sure this causes throttle down. self.wait_servo_channel_value(3, 1200, timeout=3, comparator=operator.lt) self.progress("Waiting for next WP with no thermalling") self.wait_waypoint(4, 4, timeout=1200, max_dist=120) # Disarm self.disarm_vehicle_expect_fail() self.progress("Mission OK") def SpeedToFly(self): '''Test soaring speed-to-fly''' model = "plane-soaring" self.customise_SITL_commandline( [], model=model, defaults_filepath=self.model_defaults_filepath(model), wipe=True) self.load_mission('CMAC-soar.txt', strict=False) self.set_parameters({ "SIM_THML_SCENARI": 0, # Turn off environmental thermals. "SOAR_ALT_MAX": 1000, # remove source of random failure }) # Get thermalling RC channel rc_chan = 0 for i in range(8): rcx_option = self.get_parameter('RC{0}_OPTION'.format(i+1)) if rcx_option == 88: rc_chan = i+1 break if rc_chan == 0: raise NotAchievedException("Did not find soaring enable channel option.") # Disable soaring self.set_rc(rc_chan, 1100) self.set_current_waypoint(1) self.change_mode('AUTO') self.wait_ready_to_arm() self.arm_vehicle() # Wait for to 400m before starting. self.wait_altitude(390, 400, timeout=600, relative=True) # Wait 10s to stabilize. self.delay_sim_time(30) # Enable soaring (no automatic thermalling) self.set_rc(rc_chan, 1500) self.set_parameters({ "SOAR_CRSE_ARSPD": -1, # Enable speed to fly. "SOAR_VSPEED": 1, # Set appropriate McCready. "SIM_WIND_SPD": 0, }) self.progress('Waiting a few seconds before determining the "trim" airspeed.') self.delay_sim_time(20) m = self.assert_receive_message('VFR_HUD') trim_airspeed = m.airspeed self.progress("Using trim_airspeed=%f" % (trim_airspeed,)) min_airspeed = self.get_parameter("ARSPD_FBW_MIN") max_airspeed = self.get_parameter("ARSPD_FBW_MAX") if trim_airspeed > max_airspeed: raise NotAchievedException("trim airspeed > max_airspeed (%f>%f)" % (trim_airspeed, max_airspeed)) if trim_airspeed < min_airspeed: raise NotAchievedException("trim airspeed < min_airspeed (%f<%f)" % (trim_airspeed, min_airspeed)) self.progress("Adding updraft") self.set_parameters({ "SIM_WIND_SPD": 1, 'SIM_WIND_DIR_Z': 90, }) self.progress("Waiting for vehicle to move slower in updraft") self.wait_airspeed(0, trim_airspeed-0.5, minimum_duration=10, timeout=120) self.progress("Adding downdraft") self.set_parameter('SIM_WIND_DIR_Z', -90) self.progress("Waiting for vehicle to move faster in downdraft") self.wait_airspeed(trim_airspeed+0.5, trim_airspeed+100, minimum_duration=10, timeout=120) self.progress("Zeroing wind and increasing McCready") self.set_parameters({ "SIM_WIND_SPD": 0, "SOAR_VSPEED": 2, }) self.progress("Waiting for airspeed to increase with higher VSPEED") self.wait_airspeed(trim_airspeed+0.5, trim_airspeed+100, minimum_duration=10, timeout=120) # mcReady tests don't work ATM, so just return early: # takes too long to land, so just make it all go away: self.disarm_vehicle(force=True) self.reboot_sitl() return self.start_subtest('Test McReady values') # Disable soaring self.set_rc(rc_chan, 1100) # Wait for to 400m before starting. self.wait_altitude(390, 400, timeout=600, relative=True) # Enable soaring self.set_rc(rc_chan, 2000) self.progress("Find airspeed with 1m/s updraft and mcready=1") self.set_parameters({ "SOAR_VSPEED": 1, "SIM_WIND_SPD": 1, }) self.delay_sim_time(20) m = self.assert_receive_message('VFR_HUD') mcready1_speed = m.airspeed self.progress("airspeed is %f" % mcready1_speed) self.progress("Reducing McCready") self.set_parameters({ "SOAR_VSPEED": 0.5, }) self.progress("Waiting for airspeed to decrease with lower McReady") self.wait_airspeed(0, mcready1_speed-0.5, minimum_duration=10, timeout=120) self.progress("Increasing McCready") self.set_parameters({ "SOAR_VSPEED": 1.5, }) self.progress("Waiting for airspeed to decrease with lower McReady") self.wait_airspeed(mcready1_speed+0.5, mcready1_speed+100, minimum_duration=10, timeout=120) # takes too long to land, so just make it all go away: self.disarm_vehicle(force=True) self.reboot_sitl() def AirspeedDrivers(self): '''Test AirSpeed drivers''' airspeed_sensors = [ ("MS5525", 3, 1), ("DLVR", 7, 2), ("SITL", 100, 0), ] for (name, t, bus) in airspeed_sensors: self.context_push() if bus is not None: self.set_parameter("ARSPD2_BUS", bus) self.set_parameter("ARSPD2_TYPE", t) self.reboot_sitl() self.wait_ready_to_arm() self.arm_vehicle() # insert listener to compare airspeeds: airspeed = [None, None] # don't start testing until we've seen real speed from # both sensors. This gets us out of the noise area. global initial_airspeed_threshold_reached initial_airspeed_threshold_reached = False def check_airspeeds(mav, m): global initial_airspeed_threshold_reached m_type = m.get_type() if (m_type == 'NAMED_VALUE_FLOAT' and m.name == 'AS2'): airspeed[1] = m.value elif m_type == 'VFR_HUD': airspeed[0] = m.airspeed else: return if airspeed[0] is None or airspeed[1] is None: return if airspeed[0] < 2 or airspeed[1] < 2: # this mismatch can occur on takeoff, or when we # smack into the ground at the end of the mission return if not initial_airspeed_threshold_reached: if not (airspeed[0] > 10 or airspeed[1] > 10): return initial_airspeed_threshold_reached = True delta = abs(airspeed[0] - airspeed[1]) if delta > 2: raise NotAchievedException("Airspeed mismatch (as1=%f as2=%f)" % (airspeed[0], airspeed[1])) self.install_message_hook_context(check_airspeeds) self.fly_mission("ap1.txt", strict=False) if airspeed[0] is None: raise NotAchievedException("Never saw an airspeed1") if airspeed[1] is None: raise NotAchievedException("Never saw an airspeed2") self.context_pop() self.reboot_sitl() def TerrainMission(self): '''Test terrain following in mission''' self.install_terrain_handlers_context() num_wp = self.load_mission("ap-terrain.txt") self.wait_ready_to_arm() self.arm_vehicle() global max_alt max_alt = 0 def record_maxalt(mav, m): global max_alt if m.get_type() != 'GLOBAL_POSITION_INT': return if m.relative_alt/1000.0 > max_alt: max_alt = m.relative_alt/1000.0 self.install_message_hook(record_maxalt) self.fly_mission_waypoints(num_wp-1, mission_timeout=600) if max_alt < 200: raise NotAchievedException("Did not follow terrain") def Terrain(self): '''test AP_Terrain''' self.reboot_sitl() # we know the terrain height at CMAC self.install_terrain_handlers_context() self.wait_ready_to_arm() loc = self.mav.location() lng_int = int(loc.lng * 1e7) lat_int = int(loc.lat * 1e7) # FIXME: once we have a pre-populated terrain cache this # should require an instantly correct report to pass tstart = self.get_sim_time_cached() last_terrain_report_pending = -1 while True: now = self.get_sim_time_cached() if now - tstart > 60: raise NotAchievedException("Did not get correct terrain report") self.mav.mav.terrain_check_send(lat_int, lng_int) report = self.mav.recv_match(type='TERRAIN_REPORT', blocking=True, timeout=60) self.progress(self.dump_message_verbose(report)) if report.spacing != 0: break # we will keep trying to long as the number of pending # tiles is dropping: if last_terrain_report_pending == -1: last_terrain_report_pending = report.pending elif report.pending < last_terrain_report_pending: last_terrain_report_pending = report.pending tstart = now self.delay_sim_time(1) self.progress(self.dump_message_verbose(report)) expected_terrain_height = 583.5 if abs(report.terrain_height - expected_terrain_height) > 0.5: raise NotAchievedException("Expected terrain height=%f got=%f" % (expected_terrain_height, report.terrain_height)) def TerrainLoiter(self): '''Test terrain following in loiter''' self.context_push() self.set_parameters({ "TERRAIN_FOLLOW": 1, # enable terrain following in loiter "WP_LOITER_RAD": 2000, # set very large loiter rad to get some terrain changes }) alt = 200 self.takeoff(alt*0.9, alt*1.1) self.set_rc(3, 1500) self.change_mode("LOITER") self.progress("loitering at %um" % alt) tstart = self.get_sim_time() timeout = 60*15 # enough time to do one and a bit circles max_delta = 0 while True: now = self.get_sim_time_cached() if now - tstart > timeout: break gpi = self.assert_receive_message('GLOBAL_POSITION_INT') terrain = self.assert_receive_message('TERRAIN_REPORT') rel_alt = terrain.current_height self.progress("%um above terrain (%um bove home)" % (rel_alt, gpi.relative_alt/1000.0)) if rel_alt > alt*1.2 or rel_alt < alt * 0.8: raise NotAchievedException("Not terrain following") delta = abs(rel_alt - gpi.relative_alt/1000.0) if delta > max_delta: max_delta = delta want_max_delta = 30 if max_delta < want_max_delta: raise NotAchievedException( "Expected terrain and home alts to vary more than they did (max=%u want=%u)" % (max_delta, want_max_delta)) self.context_pop() self.progress("Returning home") self.fly_home_land_and_disarm(240) def fly_external_AHRS(self, sim, eahrs_type, mission): """Fly with external AHRS (VectorNav)""" self.customise_SITL_commandline(["--uartE=sim:%s" % sim]) self.set_parameters({ "EAHRS_TYPE": eahrs_type, "SERIAL4_PROTOCOL": 36, "SERIAL4_BAUD": 230400, "GPS_TYPE": 21, "AHRS_EKF_TYPE": 11, "INS_GYR_CAL": 1, }) self.reboot_sitl() self.delay_sim_time(5) self.progress("Running accelcal") self.run_cmd(mavutil.mavlink.MAV_CMD_PREFLIGHT_CALIBRATION, 0, 0, 0, 0, 4, 0, 0, timeout=5) self.wait_ready_to_arm() self.arm_vehicle() self.fly_mission(mission) def wait_and_maintain_wind_estimate( self, want_speed, want_dir, timeout=10, speed_tolerance=0.5, dir_tolerance=5, **kwargs): '''wait for wind estimate to reach speed and direction''' def validator(last, _min, _max): '''returns false of spd or direction is too-far wrong''' (spd, di) = last _min_spd, _min_dir = _min _max_spd, _max_dir = _max if spd < _min_spd or spd > _max_spd: return False # my apologies to whoever is staring at this and wondering # why we're not wrapping angles here... if di < _min_dir or di > _max_dir: return False return True def value_getter(): '''returns a tuple of (wind_speed, wind_dir), where wind_dir is 45 if wind is coming from NE''' m = self.assert_receive_message("WIND") return (m.speed, m.direction) class ValueAverager(object): def __init__(self): self.speed_average = -1 self.dir_average = -1 self.count = 0.0 def add_value(self, value): (spd, di) = value if self.speed_average == -1: self.speed_average = spd self.dir_average = di else: self.speed_average += spd self.di_average += spd self.count += 1 return (self.speed_average/self.count, self.dir_average/self.count) def reset(self): self.count = 0 self.speed_average = -1 self.dir_average = -1 self.wait_and_maintain_range( value_name="WindEstimates", minimum=(want_speed-speed_tolerance, want_dir-dir_tolerance), maximum=(want_speed+speed_tolerance, want_dir+dir_tolerance), current_value_getter=value_getter, value_averager=ValueAverager(), validator=lambda last, _min, _max: validator(last, _min, _max), timeout=timeout, **kwargs ) def WindEstimates(self): '''fly non-external AHRS, ensure wind estimate correct''' self.set_parameters({ "SIM_WIND_SPD": 5, "SIM_WIND_DIR": 45, }) self.wait_ready_to_arm() self.takeoff(70) # default wind sim wind is a sqrt function up to 60m self.change_mode('LOITER') # use default estimator to determine when to check others: self.wait_and_maintain_wind_estimate(5, 45, timeout=120) for ahrs_type in 0, 2, 3, 10: self.start_subtest("Checking AHRS_EKF_TYPE=%u" % ahrs_type) self.set_parameter("AHRS_EKF_TYPE", ahrs_type) self.wait_and_maintain_wind_estimate( 5, 45, speed_tolerance=1, timeout=20 ) self.fly_home_land_and_disarm() def VectorNavEAHRS(self): '''Test VectorNav EAHRS support''' self.fly_external_AHRS("VectorNav", 1, "ap1.txt") def LordEAHRS(self): '''Test LORD Microstrain EAHRS support''' self.fly_external_AHRS("LORD", 2, "ap1.txt") def get_accelvec(self, m): return Vector3(m.xacc, m.yacc, m.zacc) * 0.001 * 9.81 def get_gyrovec(self, m): return Vector3(m.xgyro, m.ygyro, m.zgyro) * 0.001 * math.degrees(1) def IMUTempCal(self): '''Test IMU temperature calibration''' self.progress("Setting up SITL temperature profile") self.set_parameters({ "SIM_IMUT1_ENABLE" : 1, "SIM_IMUT1_ACC1_X" : 120000.000000, "SIM_IMUT1_ACC1_Y" : -190000.000000, "SIM_IMUT1_ACC1_Z" : 1493.864746, "SIM_IMUT1_ACC2_X" : -51.624416, "SIM_IMUT1_ACC2_Y" : 10.364172, "SIM_IMUT1_ACC2_Z" : -7878.000000, "SIM_IMUT1_ACC3_X" : -0.514242, "SIM_IMUT1_ACC3_Y" : 0.862218, "SIM_IMUT1_ACC3_Z" : -234.000000, "SIM_IMUT1_GYR1_X" : -5122.513817, "SIM_IMUT1_GYR1_Y" : -3250.470428, "SIM_IMUT1_GYR1_Z" : -2136.346676, "SIM_IMUT1_GYR2_X" : 30.720505, "SIM_IMUT1_GYR2_Y" : 17.778447, "SIM_IMUT1_GYR2_Z" : 0.765997, "SIM_IMUT1_GYR3_X" : -0.003572, "SIM_IMUT1_GYR3_Y" : 0.036346, "SIM_IMUT1_GYR3_Z" : 0.015457, "SIM_IMUT1_TMAX" : 70.0, "SIM_IMUT1_TMIN" : -20.000000, "SIM_IMUT2_ENABLE" : 1, "SIM_IMUT2_ACC1_X" : -160000.000000, "SIM_IMUT2_ACC1_Y" : 198730.000000, "SIM_IMUT2_ACC1_Z" : 27812.000000, "SIM_IMUT2_ACC2_X" : 30.658159, "SIM_IMUT2_ACC2_Y" : 32.085022, "SIM_IMUT2_ACC2_Z" : 1572.000000, "SIM_IMUT2_ACC3_X" : 0.102912, "SIM_IMUT2_ACC3_Y" : 0.229734, "SIM_IMUT2_ACC3_Z" : 172.000000, "SIM_IMUT2_GYR1_X" : 3173.925644, "SIM_IMUT2_GYR1_Y" : -2368.312836, "SIM_IMUT2_GYR1_Z" : -1796.497177, "SIM_IMUT2_GYR2_X" : 13.029696, "SIM_IMUT2_GYR2_Y" : -10.349280, "SIM_IMUT2_GYR2_Z" : -15.082653, "SIM_IMUT2_GYR3_X" : 0.004831, "SIM_IMUT2_GYR3_Y" : -0.020528, "SIM_IMUT2_GYR3_Z" : 0.009469, "SIM_IMUT2_TMAX" : 70.000000, "SIM_IMUT2_TMIN" : -20.000000, "SIM_IMUT_END" : 45.000000, "SIM_IMUT_START" : 3.000000, "SIM_IMUT_TCONST" : 75.000000, "SIM_DRIFT_SPEED" : 0, "INS_GYR_CAL" : 0, }) self.set_parameter("SIM_IMUT_FIXED", 12) self.progress("Running accel cal") self.run_cmd(mavutil.mavlink.MAV_CMD_PREFLIGHT_CALIBRATION, 0, 0, 0, 0, 4, 0, 0, timeout=5) self.progress("Running gyro cal") self.run_cmd(mavutil.mavlink.MAV_CMD_PREFLIGHT_CALIBRATION, 0, 0, 0, 0, 1, 0, 0, timeout=5) self.set_parameters({ "SIM_IMUT_FIXED": 0, "INS_TCAL1_ENABLE": 2, "INS_TCAL1_TMAX": 42, "INS_TCAL2_ENABLE": 2, "INS_TCAL2_TMAX": 42, "SIM_SPEEDUP": 200, }) self.set_parameter("LOG_DISARMED", 1) self.reboot_sitl() self.progress("Waiting for IMU temperature") self.assert_reach_imu_temperature(43, timeout=600) if self.get_parameter("INS_TCAL1_ENABLE") != 1.0: raise NotAchievedException("TCAL1 did not complete") if self.get_parameter("INS_TCAL2_ENABLE") != 1.0: raise NotAchievedException("TCAL2 did not complete") self.progress("Logging with calibration enabled") self.reboot_sitl() self.assert_reach_imu_temperature(43, timeout=600) self.progress("Testing with compensation enabled") test_temperatures = range(10, 45, 5) corrected = {} uncorrected = {} for temp in test_temperatures: self.progress("Testing temperature %.1f" % temp) self.set_parameter("SIM_IMUT_FIXED", temp) self.delay_sim_time(2) for msg in ['RAW_IMU', 'SCALED_IMU2']: m = self.assert_receive_message(msg, timeout=2) temperature = m.temperature*0.01 if abs(temperature - temp) > 0.2: raise NotAchievedException("incorrect %s temperature %.1f should be %.1f" % (msg, temperature, temp)) accel = self.get_accelvec(m) gyro = self.get_gyrovec(m) accel2 = accel + Vector3(0, 0, 9.81) corrected[temperature] = (accel2, gyro) self.progress("Testing with compensation disabled") self.set_parameters({ "INS_TCAL1_ENABLE": 0, "INS_TCAL2_ENABLE": 0, }) gyro_threshold = 0.2 accel_threshold = 0.2 for temp in test_temperatures: self.progress("Testing temperature %.1f" % temp) self.set_parameter("SIM_IMUT_FIXED", temp) self.wait_heartbeat() self.wait_heartbeat() for msg in ['RAW_IMU', 'SCALED_IMU2']: m = self.assert_receive_message(msg, timeout=2) temperature = m.temperature*0.01 if abs(temperature - temp) > 0.2: raise NotAchievedException("incorrect %s temperature %.1f should be %.1f" % (msg, temperature, temp)) accel = self.get_accelvec(m) gyro = self.get_gyrovec(m) accel2 = accel + Vector3(0, 0, 9.81) uncorrected[temperature] = (accel2, gyro) for temp in test_temperatures: (accel, gyro) = corrected[temp] self.progress("Corrected gyro at %.1f %s" % (temp, gyro)) self.progress("Corrected accel at %.1f %s" % (temp, accel)) for temp in test_temperatures: (accel, gyro) = uncorrected[temp] self.progress("Uncorrected gyro at %.1f %s" % (temp, gyro)) self.progress("Uncorrected accel at %.1f %s" % (temp, accel)) bad_value = False for temp in test_temperatures: (accel, gyro) = corrected[temp] if gyro.length() > gyro_threshold: raise NotAchievedException("incorrect corrected at %.1f gyro %s" % (temp, gyro)) if accel.length() > accel_threshold: raise NotAchievedException("incorrect corrected at %.1f accel %s" % (temp, accel)) (accel, gyro) = uncorrected[temp] if gyro.length() > gyro_threshold*2: bad_value = True if accel.length() > accel_threshold*2: bad_value = True if not bad_value: raise NotAchievedException("uncompensated IMUs did not vary enough") # the above tests change the internal persistent state of the # vehicle in ways that autotest doesn't track (magically set # parameters). So wipe the vehicle's eeprom: self.reset_SITL_commandline() def EKFlaneswitch(self): '''Test EKF3 Affinity and Lane Switching''' self.context_push() ex = None # new lane swtich available only with EK3 self.set_parameters({ "EK3_ENABLE": 1, "EK2_ENABLE": 0, "AHRS_EKF_TYPE": 3, "EK3_AFFINITY": 15, # enable affinity for all sensors "EK3_IMU_MASK": 3, # use only 2 IMUs "GPS_TYPE2": 1, "SIM_GPS2_DISABLE": 0, "SIM_BARO_COUNT": 2, "SIM_BAR2_DISABLE": 0, "ARSPD2_TYPE": 2, "ARSPD2_USE": 1, "ARSPD2_PIN": 2, }) # some parameters need reboot to take effect self.reboot_sitl() self.lane_switches = [] # add an EKF lane switch hook def statustext_hook(mav, message): if message.get_type() != 'STATUSTEXT': return # example msg: EKF3 lane switch 1 if not message.text.startswith("EKF3 lane switch "): return newlane = int(message.text[-1]) self.lane_switches.append(newlane) self.install_message_hook(statustext_hook) # get flying self.takeoff(alt=50) self.change_mode('CIRCLE') try: ################################################################### self.progress("Checking EKF3 Lane Switching trigger from all sensors") ################################################################### self.start_subtest("ACCELEROMETER: Change z-axis offset") # create an accelerometer error by changing the Z-axis offset self.context_collect("STATUSTEXT") old_parameter = self.get_parameter("INS_ACCOFFS_Z") self.wait_statustext( text="EKF3 lane switch", timeout=30, the_function=self.set_parameter("INS_ACCOFFS_Z", old_parameter + 5), check_context=True) if self.lane_switches != [1]: raise NotAchievedException("Expected lane switch 1, got %s" % str(self.lane_switches[-1])) # Cleanup self.set_parameter("INS_ACCOFFS_Z", old_parameter) self.context_clear_collection("STATUSTEXT") self.wait_heading(0, accuracy=10, timeout=60) self.wait_heading(180, accuracy=10, timeout=60) ################################################################### self.start_subtest("BAROMETER: Freeze to last measured value") self.context_collect("STATUSTEXT") # create a barometer error by inhibiting any pressure change while changing altitude old_parameter = self.get_parameter("SIM_BAR2_FREEZE") self.set_parameter("SIM_BAR2_FREEZE", 1) self.wait_statustext( text="EKF3 lane switch", timeout=30, the_function=lambda: self.set_rc(2, 2000), check_context=True) if self.lane_switches != [1, 0]: raise NotAchievedException("Expected lane switch 0, got %s" % str(self.lane_switches[-1])) # Cleanup self.set_rc(2, 1500) self.set_parameter("SIM_BAR2_FREEZE", old_parameter) self.context_clear_collection("STATUSTEXT") self.wait_heading(0, accuracy=10, timeout=60) self.wait_heading(180, accuracy=10, timeout=60) ################################################################### self.start_subtest("GPS: Apply GPS Velocity Error in NED") self.context_push() self.context_collect("STATUSTEXT") # create a GPS velocity error by adding a random 2m/s # noise on each axis def sim_gps_verr(): self.set_parameters({ "SIM_GPS_VERR_X": self.get_parameter("SIM_GPS_VERR_X") + 2, "SIM_GPS_VERR_Y": self.get_parameter("SIM_GPS_VERR_Y") + 2, "SIM_GPS_VERR_Z": self.get_parameter("SIM_GPS_VERR_Z") + 2, }) self.wait_statustext(text="EKF3 lane switch", timeout=30, the_function=sim_gps_verr, check_context=True) if self.lane_switches != [1, 0, 1]: raise NotAchievedException("Expected lane switch 1, got %s" % str(self.lane_switches[-1])) # Cleanup self.context_pop() self.context_clear_collection("STATUSTEXT") self.wait_heading(0, accuracy=10, timeout=60) self.wait_heading(180, accuracy=10, timeout=60) ################################################################### self.start_subtest("MAGNETOMETER: Change X-Axis Offset") self.context_collect("STATUSTEXT") # create a magnetometer error by changing the X-axis offset old_parameter = self.get_parameter("SIM_MAG2_OFS_X") self.wait_statustext( text="EKF3 lane switch", timeout=30, the_function=self.set_parameter("SIM_MAG2_OFS_X", old_parameter + 150), check_context=True) if self.lane_switches != [1, 0, 1, 0]: raise NotAchievedException("Expected lane switch 0, got %s" % str(self.lane_switches[-1])) # Cleanup self.set_parameter("SIM_MAG2_OFS_X", old_parameter) self.context_clear_collection("STATUSTEXT") self.wait_heading(0, accuracy=10, timeout=60) self.wait_heading(180, accuracy=10, timeout=60) ################################################################### self.start_subtest("AIRSPEED: Fail to constant value") self.context_push() self.context_collect("STATUSTEXT") old_parameter = self.get_parameter("SIM_ARSPD_FAIL") def fail_speed(): self.change_mode("GUIDED") loc = self.mav.location() self.run_cmd_int( mavutil.mavlink.MAV_CMD_DO_REPOSITION, 0, 0, 0, 0, int(loc.lat * 1e7), int(loc.lng * 1e7), 50 # alt ) self.delay_sim_time(5) # create an airspeed sensor error by freezing to the # current airspeed then changing the airspeed demand # to a higher value and waiting for the TECS speed # loop to diverge m = self.mav.recv_match(type='VFR_HUD', blocking=True) self.set_parameter("SIM_ARSPD_FAIL", m.airspeed) self.run_cmd( mavutil.mavlink.MAV_CMD_DO_CHANGE_SPEED, 0, # airspeed 30, -1, # throttle / no change 0, # absolute values 0, 0, 0 ) self.wait_statustext(text="EKF3 lane switch", timeout=30, the_function=fail_speed, check_context=True) if self.lane_switches != [1, 0, 1, 0, 1]: raise NotAchievedException("Expected lane switch 1, got %s" % str(self.lane_switches[-1])) # Cleanup self.set_parameter("SIM_ARSPD_FAIL", old_parameter) self.change_mode('CIRCLE') self.context_pop() self.context_clear_collection("STATUSTEXT") self.wait_heading(0, accuracy=10, timeout=60) self.wait_heading(180, accuracy=10, timeout=60) ################################################################### self.progress("GYROSCOPE: Change Y-Axis Offset") self.context_collect("STATUSTEXT") # create a gyroscope error by changing the Y-axis offset old_parameter = self.get_parameter("INS_GYR2OFFS_Y") self.wait_statustext( text="EKF3 lane switch", timeout=30, the_function=self.set_parameter("INS_GYR2OFFS_Y", old_parameter + 1), check_context=True) if self.lane_switches != [1, 0, 1, 0, 1, 0]: raise NotAchievedException("Expected lane switch 0, got %s" % str(self.lane_switches[-1])) # Cleanup self.set_parameter("INS_GYR2OFFS_Y", old_parameter) self.context_clear_collection("STATUSTEXT") ################################################################### self.disarm_vehicle(force=True) except Exception as e: self.print_exception_caught(e) ex = e self.remove_message_hook(statustext_hook) self.context_pop() # some parameters need reboot to take effect self.reboot_sitl() if ex is not None: raise ex def FenceAltCeilFloor(self): '''Tests the fence ceiling and floor''' fence_bit = mavutil.mavlink.MAV_SYS_STATUS_GEOFENCE self.set_parameters({ "FENCE_TYPE": 9, # Set fence type to max and min alt "FENCE_ACTION": 0, # Set action to report "FENCE_ALT_MAX": 200, "FENCE_ALT_MIN": 100, }) # Grab Home Position self.mav.recv_match(type='HOME_POSITION', blocking=True) self.homeloc = self.mav.location() cruise_alt = 150 self.takeoff(cruise_alt) self.do_fence_enable() self.progress("Fly above ceiling and check for breach") self.change_altitude(self.homeloc.alt + cruise_alt + 80) m = self.mav.recv_match(type='SYS_STATUS', blocking=True) self.progress("Got (%s)" % str(m)) if ((m.onboard_control_sensors_health & fence_bit)): raise NotAchievedException("Fence Ceiling did not breach") self.progress("Return to cruise alt and check for breach clear") self.change_altitude(self.homeloc.alt + cruise_alt) m = self.mav.recv_match(type='SYS_STATUS', blocking=True) self.progress("Got (%s)" % str(m)) if (not (m.onboard_control_sensors_health & fence_bit)): raise NotAchievedException("Fence breach did not clear") self.progress("Fly below floor and check for breach") self.change_altitude(self.homeloc.alt + cruise_alt - 80) m = self.mav.recv_match(type='SYS_STATUS', blocking=True) self.progress("Got (%s)" % str(m)) if ((m.onboard_control_sensors_health & fence_bit)): raise NotAchievedException("Fence Floor did not breach") self.do_fence_disable() self.fly_home_land_and_disarm(timeout=150) def FenceBreachedChangeMode(self): '''Tests manual mode change after fence breach, as set with FENCE_OPTIONS''' """ Attempts to change mode while a fence is breached. mode should change should fail if fence option bit is set""" self.set_parameters({ "FENCE_ACTION": 1, "FENCE_TYPE": 4, }) home_loc = self.mav.location() locs = [ mavutil.location(home_loc.lat - 0.001, home_loc.lng - 0.001, 0, 0), mavutil.location(home_loc.lat - 0.001, home_loc.lng + 0.001, 0, 0), mavutil.location(home_loc.lat + 0.001, home_loc.lng + 0.001, 0, 0), mavutil.location(home_loc.lat + 0.001, home_loc.lng - 0.001, 0, 0), ] self.upload_fences_from_locations( mavutil.mavlink.MAV_CMD_NAV_FENCE_POLYGON_VERTEX_INCLUSION, [ locs ] ) self.delay_sim_time(1) self.wait_ready_to_arm() self.takeoff(alt=50) self.change_mode("CRUISE") self.wait_distance(250, accuracy=15) self.progress("Enable fence and initiate fence action") self.do_fence_enable() self.assert_fence_enabled() self.wait_mode("RTL") # We should RTL because of fence breach self.progress("User mode change to cruise should retrigger fence action") try: # mode change should time out, 'WaitModeTimeout' exception is the desired resut # cant wait too long or the vehicle will be inside fence and allow the mode change self.change_mode("CRUISE", timeout=10) raise NotAchievedException("Should not change mode in fence breach") except WaitModeTimeout: pass except Exception as e: raise e # enable mode change self.set_parameter("FENCE_OPTIONS", 0) self.progress("Check user mode change to LOITER is allowed") self.change_mode("LOITER") # Fly for 20 seconds and make sure still in LOITER mode self.delay_sim_time(20) if not self.mode_is("LOITER"): raise NotAchievedException("Fence should not re-trigger") # reset options parameter self.set_parameter("FENCE_OPTIONS", 1) self.progress("Test complete, disable fence and come home") self.do_fence_disable() self.fly_home_land_and_disarm() def FenceNoFenceReturnPoint(self): '''Tests calculated return point during fence breach when no fence return point present''' """ Attempts to change mode while a fence is breached. This should revert to the mode specified by the fence action. """ want_radius = 100 # Fence Return Radius self.set_parameters({ "FENCE_ACTION": 6, "FENCE_TYPE": 4, "RTL_RADIUS": want_radius, "NAVL1_LIM_BANK": 60, }) home_loc = self.mav.location() locs = [ mavutil.location(home_loc.lat - 0.003, home_loc.lng - 0.001, 0, 0), mavutil.location(home_loc.lat - 0.003, home_loc.lng + 0.003, 0, 0), mavutil.location(home_loc.lat + 0.001, home_loc.lng + 0.003, 0, 0), mavutil.location(home_loc.lat + 0.001, home_loc.lng - 0.001, 0, 0), ] self.upload_fences_from_locations( mavutil.mavlink.MAV_CMD_NAV_FENCE_POLYGON_VERTEX_INCLUSION, [ locs ] ) self.delay_sim_time(1) self.wait_ready_to_arm() self.takeoff(alt=50) self.change_mode("CRUISE") self.wait_distance(150, accuracy=20) self.progress("Enable fence and initiate fence action") self.do_fence_enable() self.assert_fence_enabled() self.wait_mode("GUIDED", timeout=120) # We should RTL because of fence breach self.delay_sim_time(60) items = self.download_using_mission_protocol(mavutil.mavlink.MAV_MISSION_TYPE_FENCE) if len(items) != 4: raise NotAchievedException("Unexpected fencepoint count (want=%u got=%u)" % (4, len(items))) # Check there are no fence return points specified still for fence_loc in items: if fence_loc.command == mavutil.mavlink.MAV_CMD_NAV_FENCE_RETURN_POINT: raise NotAchievedException( "Unexpected fence return point found (%u) got %u" % (fence_loc.command, mavutil.mavlink.MAV_CMD_NAV_FENCE_RETURN_POINT)) # Work out the approximate return point when no fence return point present # Logic taken from AC_PolyFence_loader.cpp min_loc = self.mav.location() max_loc = self.mav.location() for new_loc in locs: if new_loc.lat < min_loc.lat: min_loc.lat = new_loc.lat if new_loc.lng < min_loc.lng: min_loc.lng = new_loc.lng if new_loc.lat > max_loc.lat: max_loc.lat = new_loc.lat if new_loc.lng > max_loc.lng: max_loc.lng = new_loc.lng # Generate the return location based on min and max locs ret_lat = (min_loc.lat + max_loc.lat) / 2 ret_lng = (min_loc.lng + max_loc.lng) / 2 ret_loc = mavutil.location(ret_lat, ret_lng, 0, 0) self.progress("Return loc: (%s)" % str(ret_loc)) # Wait for guided return to vehicle calculated fence return location self.wait_distance_to_location(ret_loc, 90, 110) self.wait_circling_point_with_radius(ret_loc, 92) self.progress("Test complete, disable fence and come home") self.do_fence_disable() self.fly_home_land_and_disarm() def FenceNoFenceReturnPointInclusion(self): '''Tests using home as fence return point when none is present, and no inclusion fence is uploaded''' """ Test result when a breach occurs and No fence return point is present and no inclusion fence is present and exclusion fence is present """ want_radius = 100 # Fence Return Radius self.set_parameters({ "FENCE_ACTION": 6, "FENCE_TYPE": 2, "FENCE_RADIUS": 300, "RTL_RADIUS": want_radius, "NAVL1_LIM_BANK": 60, }) self.clear_fence() self.delay_sim_time(1) self.wait_ready_to_arm() home_loc = self.mav.location() self.takeoff(alt=50) self.change_mode("CRUISE") self.wait_distance(150, accuracy=20) self.progress("Enable fence and initiate fence action") self.do_fence_enable() self.assert_fence_enabled() self.wait_mode("GUIDED") # We should RTL because of fence breach self.delay_sim_time(30) items = self.download_using_mission_protocol(mavutil.mavlink.MAV_MISSION_TYPE_FENCE) if len(items) != 0: raise NotAchievedException("Unexpected fencepoint count (want=%u got=%u)" % (0, len(items))) # Check there are no fence return points specified still for fence_loc in items: if fence_loc.command == mavutil.mavlink.MAV_CMD_NAV_FENCE_RETURN_POINT: raise NotAchievedException( "Unexpected fence return point found (%u) got %u" % (fence_loc.command, mavutil.mavlink.MAV_CMD_NAV_FENCE_RETURN_POINT)) # Wait for guided return to vehicle calculated fence return location self.wait_distance_to_location(home_loc, 90, 110) self.wait_circling_point_with_radius(home_loc, 92) self.progress("Test complete, disable fence and come home") self.do_fence_disable() self.fly_home_land_and_disarm() def FenceDisableUnderAction(self): '''Tests Disabling fence while undergoing action caused by breach''' """ Fence breach will cause the vehicle to enter guided mode. Upon breach clear, check the vehicle is in the expected mode""" self.set_parameters({ "FENCE_ALT_MIN": 50, # Sets the fence floor "FENCE_TYPE": 8, # Only use fence floor for breaches }) self.wait_ready_to_arm() def attempt_fence_breached_disable(start_mode, end_mode, expected_mode, action): self.set_parameter("FENCE_ACTION", action) # Set Fence Action to Guided self.change_mode(start_mode) self.arm_vehicle() self.do_fence_enable() self.assert_fence_enabled() self.wait_mode(expected_mode) self.do_fence_disable() self.assert_fence_disabled() self.wait_mode(end_mode) self.disarm_vehicle(force=True) attempt_fence_breached_disable(start_mode="FBWA", end_mode="RTL", expected_mode="RTL", action=1) attempt_fence_breached_disable(start_mode="FBWA", end_mode="FBWA", expected_mode="GUIDED", action=6) attempt_fence_breached_disable(start_mode="FBWA", end_mode="FBWA", expected_mode="GUIDED", action=7) def MAV_DO_AUX_FUNCTION(self): '''Test triggering Auxiliary Functions via mavlink''' self.context_collect('STATUSTEXT') self.run_auxfunc(64, 2) # 64 == reverse throttle self.wait_statustext("RevThrottle: ENABLE", check_context=True) self.run_auxfunc(64, 0) self.wait_statustext("RevThrottle: DISABLE", check_context=True) self.run_auxfunc(65, 2) # 65 == GPS_DISABLE self.start_subtest("Bad auxfunc") self.run_auxfunc( 65231, 2, want_result=mavutil.mavlink.MAV_RESULT_FAILED ) self.start_subtest("Bad switchpos") self.run_auxfunc( 62, 17, want_result=mavutil.mavlink.MAV_RESULT_DENIED ) def FlyEachFrame(self): '''Fly each supported internal frame''' vinfo = vehicleinfo.VehicleInfo() vinfo_options = vinfo.options[self.vehicleinfo_key()] known_broken_frames = { "firefly": "falls out of sky after transition", "plane-tailsitter": "does not take off; immediately emits 'AP: Transition VTOL done' while on ground", "quadplane-cl84": "falls out of sky instead of transitioning", "quadplane-tilttri": "falls out of sky instead of transitioning", "quadplane-tilttrivec": "loses attitude control and crashes", "plane-ice" : "needs ICE control channel for ignition", "quadplane-ice" : "needs ICE control channel for ignition", } for frame in sorted(vinfo_options["frames"].keys()): self.start_subtest("Testing frame (%s)" % str(frame)) if frame in known_broken_frames: self.progress("Actually, no I'm not - it is known-broken (%s)" % (known_broken_frames[frame])) continue frame_bits = vinfo_options["frames"][frame] print("frame_bits: %s" % str(frame_bits)) if frame_bits.get("external", False): self.progress("Actually, no I'm not - it is an external simulation") continue model = frame_bits.get("model", frame) # the model string for Callisto has crap in it.... we # should really have another entry in the vehicleinfo data # to carry the path to the JSON. actual_model = model.split(":")[0] defaults = self.model_defaults_filepath(actual_model) if type(defaults) != list: defaults = [defaults] self.customise_SITL_commandline( ["--defaults", ','.join(defaults), ], model=model, wipe=True, ) mission_file = "basic.txt" quadplane = self.get_parameter('Q_ENABLE') if quadplane: mission_file = "basic-quadplane.txt" tailsitter = self.get_parameter('Q_TAILSIT_ENABLE') if tailsitter: # tailsitter needs extra re-boot to pick up the rotated AHRS view self.reboot_sitl() self.wait_ready_to_arm() self.arm_vehicle() self.fly_mission(mission_file, strict=False, quadplane=quadplane, mission_timeout=400.0) self.wait_disarmed() def RCDisableAirspeedUse(self): '''Test RC DisableAirspeedUse option''' self.set_parameter("RC9_OPTION", 106) self.delay_sim_time(5) self.set_rc(9, 1000) self.wait_sensor_state( mavutil.mavlink.MAV_SYS_STATUS_SENSOR_DIFFERENTIAL_PRESSURE, True, True, True) self.set_rc(9, 2000) self.wait_sensor_state( mavutil.mavlink.MAV_SYS_STATUS_SENSOR_DIFFERENTIAL_PRESSURE, True, False, True) self.set_rc(9, 1000) self.wait_sensor_state( mavutil.mavlink.MAV_SYS_STATUS_SENSOR_DIFFERENTIAL_PRESSURE, True, True, True) def WatchdogHome(self): '''Ensure home is restored after watchdog reset''' if self.gdb: # we end up signalling the wrong process. I think. # Probably need to have a "sitl_pid()" method to get the # ardupilot process's PID. self.progress("######## Skipping WatchdogHome test under GDB") return ex = None try: self.progress("Enabling watchdog") self.set_parameter("BRD_OPTIONS", 1 << 0) self.reboot_sitl() self.wait_ready_to_arm() self.progress("Explicitly setting home to a known location") orig_home = self.poll_home_position() new_home = orig_home new_home.latitude = new_home.latitude + 1000 new_home.longitude = new_home.longitude + 2000 new_home.altitude = new_home.altitude + 300000 # 300 metres self.run_cmd_int( mavutil.mavlink.MAV_CMD_DO_SET_HOME, 0, # p1, 0, # p2, 0, # p3, 0, # p4, new_home.latitude, new_home.longitude, new_home.altitude/1000.0, # mm => m ) old_bootcount = self.get_parameter('STAT_BOOTCNT') self.progress("Forcing watchdog reset") os.kill(self.sitl.pid, signal.SIGALRM) self.detect_and_handle_reboot(old_bootcount) self.wait_statustext("WDG:") self.wait_statustext("IMU1 is using GPS") # won't be come armable self.progress("Verifying home position") post_reboot_home = self.poll_home_position() delta = self.get_distance_int(new_home, post_reboot_home) max_delta = 1 if delta > max_delta: raise NotAchievedException( "New home not where it should be (dist=%f) (want=%s) (got=%s)" % (delta, str(new_home), str(post_reboot_home))) except Exception as e: self.print_exception_caught(e) ex = e self.reboot_sitl() if ex is not None: raise ex def AUTOTUNE(self): '''Test AutoTune mode''' self.takeoff(100) self.change_mode('AUTOTUNE') self.context_collect('STATUSTEXT') tstart = self.get_sim_time() axis = "Roll" rc_value = 1000 while True: timeout = 600 if self.get_sim_time() - tstart > timeout: raise NotAchievedException("Did not complete within %u seconds" % timeout) try: m = self.wait_statustext("%s: Finished" % axis, check_context=True, timeout=0.1) self.progress("Got %s" % str(m)) if axis == "Roll": axis = "Pitch" elif axis == "Pitch": break else: raise ValueError("Bug: %s" % axis) except AutoTestTimeoutException: pass self.delay_sim_time(1) if rc_value == 1000: rc_value = 2000 elif rc_value == 2000: rc_value = 1000 elif rc_value == 1000: rc_value = 2000 else: raise ValueError("Bug") if axis == "Roll": self.set_rc(1, rc_value) self.set_rc(2, 1500) elif axis == "Pitch": self.set_rc(1, 1500) self.set_rc(2, rc_value) else: raise ValueError("Bug") tdelta = self.get_sim_time() - tstart self.progress("Finished in %0.1f seconds" % (tdelta,)) self.set_rc(1, 1500) self.set_rc(2, 1500) self.change_mode('FBWA') self.fly_home_land_and_disarm(timeout=tdelta+240) def LandingDrift(self): '''Circuit with baro drift''' self.customise_SITL_commandline([], wipe=True) self.set_analog_rangefinder_parameters() self.set_parameters({ "SIM_BARO_DRIFT": -0.02, "SIM_TERRAIN": 0, "RNGFND_LANDING": 1, "LAND_SLOPE_RCALC": 2, "LAND_ABORT_DEG": 1, }) self.reboot_sitl() self.wait_ready_to_arm() self.arm_vehicle() # Load and start mission self.load_mission("ap-circuit.txt", strict=True) self.set_current_waypoint(1, check_afterwards=True) self.change_mode('AUTO') self.wait_current_waypoint(1, timeout=5) self.wait_groundspeed(0, 10, timeout=5) # Wait for landing waypoint self.wait_current_waypoint(9, timeout=1200) # Wait for landing restart self.wait_current_waypoint(5, timeout=60) # Wait for landing waypoint (second attempt) self.wait_current_waypoint(9, timeout=1200) self.wait_disarmed(timeout=180) def DCMFallback(self): '''Really annoy the EKF and force fallback''' self.reboot_sitl() self.delay_sim_time(30) self.takeoff(50) self.change_mode('CIRCLE') self.context_push() self.context_collect('STATUSTEXT') self.set_parameters({ "EK3_POS_I_GATE": 0, "SIM_GPS_HZ": 1, "SIM_GPS_LAG_MS": 1000, }) self.wait_statustext("DCM Active", check_context=True, timeout=60) self.wait_statustext("EKF3 Active", check_context=True) self.wait_statustext("DCM Active", check_context=True) self.wait_statustext("EKF3 Active", check_context=True) self.wait_statustext("DCM Active", check_context=True) self.wait_statustext("EKF3 Active", check_context=True) self.context_stop_collecting('STATUSTEXT') self.fly_home_land_and_disarm() self.context_pop() self.reboot_sitl() def ForcedDCM(self): '''Switch to DCM mid-flight''' self.wait_ready_to_arm() self.arm_vehicle() self.takeoff(50) self.context_collect('STATUSTEXT') self.set_parameter("AHRS_EKF_TYPE", 0) self.wait_statustext("DCM Active", check_context=True) self.context_stop_collecting('STATUSTEXT') self.fly_home_land_and_disarm() def MegaSquirt(self): '''Test MegaSquirt EFI''' self.assert_not_receiving_message('EFI_STATUS') self.set_parameters({ 'SIM_EFI_TYPE': 1, 'EFI_TYPE': 1, 'SERIAL5_PROTOCOL': 24, }) self.customise_SITL_commandline(["--uartF=sim:megasquirt"]) self.delay_sim_time(5) m = self.assert_receive_message('EFI_STATUS') mavutil.dump_message_verbose(sys.stdout, m) if m.throttle_out != 0: raise NotAchievedException("Expected zero throttle") if m.health != 1: raise NotAchievedException("Not healthy") if m.intake_manifold_temperature < 20: raise NotAchievedException("Bad intake manifold temperature") def GlideSlopeThresh(self): '''Test rebuild glide slope if above and climbing''' # Test that GLIDE_SLOPE_THRESHOLD correctly controls re-planning glide slope # in the scenario that aircraft is above planned slope and slope is positive (climbing). # # # Behaviour with GLIDE_SLOPE_THRESH = 0 (no slope replanning) # (2).. __(4) # | \..__/ # | __/ # (3) # # Behaviour with GLIDE_SLOPE_THRESH = 5 (slope replanning when >5m error) # (2)........__(4) # | __/ # | __/ # (3) # Solid is plan, dots are actual flightpath. self.load_mission('rapid-descent-then-climb.txt', strict=False) self.set_current_waypoint(1) self.change_mode('AUTO') self.wait_ready_to_arm() self.arm_vehicle() # # Initial run with GLIDE_SLOPE_THR = 5 (default). # self.set_parameter("GLIDE_SLOPE_THR", 5) # Wait for waypoint commanding rapid descent, followed by climb. self.wait_current_waypoint(5, timeout=1200) # Altitude should not descend significantly below the initial altitude init_altitude = self.get_altitude(relative=True, timeout=2) timeout = 600 wpnum = 7 tstart = self.get_sim_time() while True: if self.get_sim_time() - tstart > timeout: raise AutoTestTimeoutException("Did not get wanted current waypoint") if (self.get_altitude(relative=True, timeout=2) - init_altitude) < -10: raise NotAchievedException("Descended >10m before reaching desired waypoint,\ indicating slope was not replanned") seq = self.mav.waypoint_current() self.progress("Waiting for wp=%u current=%u" % (wpnum, seq)) if seq == wpnum: break self.set_current_waypoint(2) # # Second run with GLIDE_SLOPE_THR = 0 (no re-plan). # self.set_parameter("GLIDE_SLOPE_THR", 0) # Wait for waypoint commanding rapid descent, followed by climb. self.wait_current_waypoint(5, timeout=1200) # This time altitude should descend significantly below the initial altitude init_altitude = self.get_altitude(relative=True, timeout=2) timeout = 600 wpnum = 7 tstart = self.get_sim_time() while True: if self.get_sim_time() - tstart > timeout: raise AutoTestTimeoutException("Did not get wanted altitude") seq = self.mav.waypoint_current() self.progress("Waiting for wp=%u current=%u" % (wpnum, seq)) if seq == wpnum: raise NotAchievedException("Reached desired waypoint without first decending 10m,\ indicating slope was replanned unexpectedly") if (self.get_altitude(relative=True, timeout=2) - init_altitude) < -10: break # Disarm self.wait_disarmed(timeout=600) self.progress("Mission OK") def MAV_CMD_NAV_LOITER_TURNS(self, target_system=1, target_component=1): '''test MAV_CMD_NAV_LOITER_TURNS mission item''' alt = 100 seq = 0 items = [] tests = [ (self.home_relative_loc_ne(50, -50), 100), (self.home_relative_loc_ne(100, 50), 1005), ] # add a home position: items.append(self.mav.mav.mission_item_int_encode( target_system, target_component, seq, # seq mavutil.mavlink.MAV_FRAME_GLOBAL, mavutil.mavlink.MAV_CMD_NAV_WAYPOINT, 0, # current 0, # autocontinue 0, # p1 0, # p2 0, # p3 0, # p4 0, # latitude 0, # longitude 0, # altitude mavutil.mavlink.MAV_MISSION_TYPE_MISSION)) seq += 1 # add takeoff items.append(self.mav.mav.mission_item_int_encode( target_system, target_component, seq, # seq mavutil.mavlink.MAV_FRAME_GLOBAL_RELATIVE_ALT, mavutil.mavlink.MAV_CMD_NAV_TAKEOFF, 0, # current 0, # autocontinue 0, # p1 0, # p2 0, # p3 0, # p4 0, # latitude 0, # longitude alt, # altitude mavutil.mavlink.MAV_MISSION_TYPE_MISSION)) seq += 1 # add circles for (loc, radius) in tests: items.append(self.mav.mav.mission_item_int_encode( target_system, target_component, seq, # seq mavutil.mavlink.MAV_FRAME_GLOBAL_RELATIVE_ALT, mavutil.mavlink.MAV_CMD_NAV_LOITER_TURNS, 0, # current 0, # autocontinue 3, # p1 0, # p2 radius, # p3 0, # p4 int(loc.lat*1e7), # latitude int(loc.lng*1e7), # longitude alt, # altitude mavutil.mavlink.MAV_MISSION_TYPE_MISSION)) seq += 1 # add an RTL items.append(self.mav.mav.mission_item_int_encode( target_system, target_component, seq, # seq mavutil.mavlink.MAV_FRAME_GLOBAL, mavutil.mavlink.MAV_CMD_NAV_RETURN_TO_LAUNCH, 0, # current 0, # autocontinue 0, # p1 0, # p2 0, # p3 0, # p4 0, # latitude 0, # longitude 0, # altitude mavutil.mavlink.MAV_MISSION_TYPE_MISSION)) seq += 1 self.upload_using_mission_protocol(mavutil.mavlink.MAV_MISSION_TYPE_MISSION, items) downloaded_items = self.download_using_mission_protocol(mavutil.mavlink.MAV_MISSION_TYPE_MISSION) ofs = 2 self.progress("Checking downloaded mission is as expected") for (loc, radius) in tests: downloaded = downloaded_items[ofs] if radius > 255: # ArduPilot only stores % 10 radius = radius - radius % 10 if downloaded.param3 != radius: raise NotAchievedException( "Did not get expected radius for item %u; want=%f got=%f" % (ofs, radius, downloaded.param3)) ofs += 1 self.change_mode('AUTO') self.wait_ready_to_arm() self.arm_vehicle() self.set_parameter("NAVL1_LIM_BANK", 50) self.wait_current_waypoint(2) for (loc, expected_radius) in tests: self.wait_circling_point_with_radius( loc, expected_radius, epsilon=20.0, timeout=240, ) self.set_current_waypoint(self.current_waypoint()+1) self.fly_home_land_and_disarm(timeout=180) def MidAirDisarmDisallowed(self): '''Ensure mid-air disarm is not possible''' self.takeoff(50) disarmed = False try: self.disarm_vehicle() disarmed = True except ValueError as e: self.progress("Got %s" % repr(e)) if "Expected MAV_RESULT_ACCEPTED got MAV_RESULT_FAILED" not in str(e): raise e if disarmed: raise NotAchievedException("Disarmed when we shouldn't have") # should still be able to force-disarm: self.disarm_vehicle(force=True) self.reboot_sitl() def AerobaticsScripting(self): '''Fixed Wing Aerobatics''' applet_script = "Aerobatics/FixedWing/plane_aerobatics.lua" airshow = "Aerobatics/FixedWing/Schedules/AirShow.txt" trick72 = "trick72.txt" model = "plane-3d" self.customise_SITL_commandline( [], model=model, defaults_filepath="", wipe=True) self.context_push() self.install_applet_script(applet_script) self.install_applet_script(airshow, install_name=trick72) self.context_collect('STATUSTEXT') self.reboot_sitl() self.set_parameter("TRIK_ENABLE", 1) self.set_rc(7, 1000) # disable tricks self.scripting_restart() self.wait_text("Enabled 3 aerobatic tricks", check_context=True) self.set_parameters({ "TRIK1_ID": 72, "RC7_OPTION" : 300, # activation switch "RC9_OPTION" : 301, # selection switch "SIM_SPEEDUP": 5, # need to give some cycles to lua }) self.wait_ready_to_arm() self.change_mode("TAKEOFF") self.arm_vehicle() self.wait_altitude(30, 40, timeout=30, relative=True) self.change_mode("CRUISE") self.set_rc(9, 1000) # select first trick self.delay_sim_time(1) self.set_rc(7, 1500) # show selected trick self.wait_text("Trick 1 selected (SuperAirShow)", check_context=True) self.set_rc(7, 2000) # activate trick self.wait_text("Trick 1 started (SuperAirShow)", check_context=True) highest_error = 0 while True: m = self.mav.recv_match(type='NAMED_VALUE_FLOAT', blocking=True, timeout=2) if not m: break if m.name != 'PERR': continue highest_error = max(highest_error, m.value) if highest_error > 15: raise NotAchievedException("path error %.1f" % highest_error) if highest_error == 0: raise NotAchievedException("path error not reported") self.progress("Finished trick, max error=%.1fm" % highest_error) self.disarm_vehicle(force=True) self.remove_installed_script(applet_script) self.remove_installed_script(trick72) messages = self.context_collection('STATUSTEXT') self.context_pop() self.reboot_sitl() # check all messages to see if we got all tricks tricks = ["Loop", "HalfReverseCubanEight", "ScaleFigureEight", "Immelmann", "Split-S", "RollingCircle", "HumptyBump", "HalfCubanEight", "BarrelRoll", "CrossBoxTopHat", "TriangularLoop", "Finishing SuperAirShow!"] texts = [m.text for m in messages] for t in tricks: if t in texts: self.progress("Completed trick %s" % t) else: raise NotAchievedException("Missing trick %s" % t) def SDCardWPTest(self): '''test BRD_SD_MISSION support''' spiral_script = "mission_spiral.lua" self.context_push() self.install_example_script(spiral_script) self.context_collect('STATUSTEXT') self.set_parameters({ "BRD_SD_MISSION" : 64, "SCR_ENABLE" : 1, "SCR_VM_I_COUNT" : 1000000 }) self.wait_ready_to_arm() self.reboot_sitl() self.wait_text("Loaded spiral mission creator", check_context=True) self.set_parameters({ "SCR_USER2": 19, # radius "SCR_USER3": -35.36322, # lat "SCR_USER4": 149.16525, # lon "SCR_USER5": 684.13, # alt }) count = (65536 // 15) - 1 self.progress("Creating spiral mission of size %s" % count) self.set_parameter("SCR_USER1", count) self.wait_text("Created spiral of size %u" % count, check_context=True) self.progress("Checking spiral before reboot") self.set_parameter("SCR_USER6", count) self.wait_text("Compared spiral of size %u OK" % count, check_context=True) self.set_parameter("SCR_USER6", 0) self.wait_ready_to_arm() self.reboot_sitl() self.progress("Checking spiral after reboot") self.set_parameter("SCR_USER6", count) self.wait_text("Compared spiral of size %u OK" % count, check_context=True) self.remove_installed_script(spiral_script) self.context_pop() self.wait_ready_to_arm() self.reboot_sitl() def MANUAL_CONTROL(self): '''test MANUAL_CONTROL mavlink message''' self.set_parameter("SYSID_MYGCS", self.mav.source_system) self.progress("Takeoff") self.takeoff(alt=50) self.change_mode('FBWA') tstart = self.get_sim_time_cached() roll_input = -500 want_roll_degrees = -12 while True: if self.get_sim_time_cached() - tstart > 10: raise AutoTestTimeoutException("Did not reach roll") self.progress("Sending roll-left") self.mav.mav.manual_control_send( 1, # target system 32767, # x (pitch) roll_input, # y (roll) 32767, # z (thrust) 32767, # r (yaw) 0) # button mask m = self.mav.recv_match(type='ATTITUDE', blocking=True, timeout=1) print("m=%s" % str(m)) if m is None: continue p = math.degrees(m.roll) self.progress("roll=%f want<=%f" % (p, want_roll_degrees)) if p <= want_roll_degrees: break self.mav.mav.manual_control_send( 1, # target system 32767, # x (pitch) 32767, # y (roll) 32767, # z (thrust) 32767, # r (yaw) 0) # button mask self.fly_home_land_and_disarm() def mission_home_point(self, target_system=1, target_component=1): '''just an empty-ish item-int to store home''' return self.mav.mav.mission_item_int_encode( target_system, target_component, 0, # seq mavutil.mavlink.MAV_FRAME_GLOBAL, mavutil.mavlink.MAV_CMD_NAV_WAYPOINT, 0, # current 0, # autocontinue 0, # p1 0, # p2 0, # p3 0, # p4 0, # latitude 0, # longitude 0, # altitude mavutil.mavlink.MAV_MISSION_TYPE_MISSION) def mission_jump_tag(self, tag, target_system=1, target_component=1): '''create a jump tag mission item''' return self.mav.mav.mission_item_int_encode( target_system, target_component, 0, # seq mavutil.mavlink.MAV_FRAME_GLOBAL, mavutil.mavlink.MAV_CMD_JUMP_TAG, 0, # current 0, # autocontinue tag, # p1 0, # p2 0, # p3 0, # p4 0, # latitude 0, # longitude 0, # altitude mavutil.mavlink.MAV_MISSION_TYPE_MISSION) def mission_do_jump_tag(self, tag, target_system=1, target_component=1): '''create a jump tag mission item''' return self.mav.mav.mission_item_int_encode( target_system, target_component, 0, # seq mavutil.mavlink.MAV_FRAME_GLOBAL, mavutil.mavlink.MAV_CMD_DO_JUMP_TAG, 0, # current 0, # autocontinue tag, # p1 0, # p2 0, # p3 0, # p4 0, # latitude 0, # longitude 0, # altitude mavutil.mavlink.MAV_MISSION_TYPE_MISSION) def mission_anonymous_waypoint(self, target_system=1, target_component=1): '''just a boring waypoint''' return self.mav.mav.mission_item_int_encode( target_system, target_component, 0, # seq mavutil.mavlink.MAV_FRAME_GLOBAL, mavutil.mavlink.MAV_CMD_NAV_WAYPOINT, 0, # current 0, # autocontinue 0, # p1 0, # p2 0, # p3 0, # p4 1, # latitude 1, # longitude 1, # altitude mavutil.mavlink.MAV_MISSION_TYPE_MISSION) def renumber_mission_items(self, mission): count = 0 for item in mission: item.seq = count count += 1 def MissionJumpTags_missing_jump_target(self, target_system=1, target_component=1): self.start_subtest("Check missing-jump-tag behaviour") jump_target = 2 mission = [ self.mission_home_point(), self.mission_anonymous_waypoint(), self.mission_anonymous_waypoint(), self.mission_jump_tag(jump_target), self.mission_anonymous_waypoint(), self.mission_anonymous_waypoint(), ] self.renumber_mission_items(mission) self.check_mission_upload_download(mission) self.progress("Checking incorrect tag behaviour") self.run_cmd( mavutil.mavlink.MAV_CMD_DO_JUMP_TAG, jump_target + 1, # p1 0, # p2 0, # p3 0, # p4 0, # p5 0, # p6 0, # p7 want_result=mavutil.mavlink.MAV_RESULT_FAILED ) self.progress("Checking correct tag behaviour") self.run_cmd( mavutil.mavlink.MAV_CMD_DO_JUMP_TAG, jump_target, # p1 0, # p2 0, # p3 0, # p4 0, # p5 0, # p6 0, # p7 ) self.assert_current_waypoint(4) def MissionJumpTags_do_jump_to_bad_tag(self, target_system=1, target_component=1): mission = [ self.mission_home_point(), self.mission_anonymous_waypoint(), self.mission_do_jump_tag(17), self.mission_anonymous_waypoint(), ] self.renumber_mission_items(mission) self.check_mission_upload_download(mission) self.change_mode('AUTO') self.arm_vehicle() self.set_current_waypoint(2, check_afterwards=False) self.assert_mode('RTL') self.disarm_vehicle() def MissionJumpTags_jump_tag_at_end_of_mission(self, target_system=1, target_component=1): mission = [ self.mission_home_point(), self.mission_anonymous_waypoint(), self.mission_jump_tag(17), ] # Jumping to an end of a mission, either DO_JUMP or DO_JUMP_TAG will result in a failed attempt. # The failure is from mission::set_current_cmd() returning false if it can not find any NAV # commands on or after the index. Two scenarios: # 1) AUTO mission triggered: The the set_command will fail and it will cause an RTL event # (Harder to test, need vehicle to actually reach the waypoint) # 2) GCS/MAVLink: It will return MAV_RESULT_FAILED and there's on change to the mission. (Easy to test) self.renumber_mission_items(mission) self.check_mission_upload_download(mission) self.progress("Checking correct tag behaviour") self.change_mode('AUTO') self.arm_vehicle() self.run_cmd( mavutil.mavlink.MAV_CMD_DO_JUMP_TAG, 17, # p1 0, # p2 0, # p3 0, # p4 0, # p5 0, # p6 0, # p7 want_result=mavutil.mavlink.MAV_RESULT_FAILED ) self.disarm_vehicle() def MissionJumpTags(self): '''test MAV_CMD_JUMP_TAG''' self.wait_ready_to_arm() self.MissionJumpTags_missing_jump_target() self.MissionJumpTags_do_jump_to_bad_tag() self.MissionJumpTags_jump_tag_at_end_of_mission() def AltResetBadGPS(self): '''Tests the handling of poor GPS lock pre-arm alt resets''' self.set_parameters({ "SIM_GPS_GLITCH_Z": 0, "SIM_GPS_ACC": 0.3, }) self.wait_ready_to_arm() m = self.assert_receive_message('GLOBAL_POSITION_INT') relalt = m.relative_alt*0.001 if abs(relalt) > 3: raise NotAchievedException("Bad relative alt %.1f" % relalt) self.progress("Setting low accuracy, glitching GPS") self.set_parameter("SIM_GPS_ACC", 40) self.set_parameter("SIM_GPS_GLITCH_Z", -47) self.progress("Waiting 10s for height update") self.delay_sim_time(10) self.wait_ready_to_arm() self.arm_vehicle() m = self.assert_receive_message('GLOBAL_POSITION_INT') relalt = m.relative_alt*0.001 if abs(relalt) > 3: raise NotAchievedException("Bad glitching relative alt %.1f" % relalt) self.disarm_vehicle() # reboot to clear potentially bad state def trigger_airspeed_cal(self): self.run_cmd(mavutil.mavlink.MAV_CMD_PREFLIGHT_CALIBRATION, 0, 0, 1, 0, 0, 0, 0) def AirspeedCal(self): '''test Airspeed calibration''' self.start_subtest('1 airspeed sensor') self.context_push() self.context_collect('STATUSTEXT') self.trigger_airspeed_cal() self.wait_statustext('Airspeed 1 calibrated', check_context=True) self.context_pop() self.context_push() self.context_collect('STATUSTEXT') self.start_subtest('0 airspeed sensors') self.set_parameter('ARSPD_TYPE', 0) self.reboot_sitl() self.wait_statustext('No airspeed sensor present or enabled', check_context=True) self.trigger_airspeed_cal() self.delay_sim_time(5) if self.statustext_in_collections('Airspeed 1 calibrated'): raise NotAchievedException("Did not disable airspeed sensor?!") self.context_pop() self.start_subtest('2 airspeed sensors') self.set_parameter('ARSPD_TYPE', 100) self.set_parameter('ARSPD2_TYPE', 100) self.reboot_sitl() self.context_push() self.context_collect('STATUSTEXT') self.trigger_airspeed_cal() self.wait_statustext('Airspeed 1 calibrated', check_context=True) self.wait_statustext('Airspeed 2 calibrated', check_context=True) self.context_pop() self.reboot_sitl() def tests(self): '''return list of all tests''' ret = super(AutoTestPlane, self).tests() ret.extend([ self.AuxModeSwitch, self.TestRCCamera, self.TestRCRelay, self.ThrottleFailsafe, self.NeedEKFToArm, self.ThrottleFailsafeFence, self.TestFlaps, self.DO_CHANGE_SPEED, self.DO_REPOSITION, self.GuidedRequest, self.MainFlight, self.TestGripperMission, self.Parachute, self.ParachuteSinkRate, self.PitotBlockage, self.AIRSPEED_AUTOCAL, self.RangeFinder, self.FenceStatic, self.FenceRTL, self.FenceRTLRally, self.FenceRetRally, self.FenceAltCeilFloor, self.FenceBreachedChangeMode, self.FenceNoFenceReturnPoint, self.FenceNoFenceReturnPointInclusion, self.FenceDisableUnderAction, self.ADSB, self.SimADSB, self.Button, self.FRSkySPort, self.FRSkyPassThroughStatustext, self.FRSkyPassThroughSensorIDs, self.FRSkyMAVlite, self.FRSkyD, self.LTM, self.DEVO, self.AdvancedFailsafe, self.LOITER, self.MAV_CMD_NAV_LOITER_TURNS, self.DeepStall, self.WatchdogHome, self.LargeMissions, self.Soaring, self.Terrain, self.TerrainMission, self.TerrainLoiter, self.VectorNavEAHRS, self.LordEAHRS, self.Deadreckoning, self.DeadreckoningNoAirSpeed, self.EKFlaneswitch, self.AirspeedDrivers, self.RTL_CLIMB_MIN, self.ClimbBeforeTurn, self.IMUTempCal, self.MAV_DO_AUX_FUNCTION, self.SmartBattery, self.FlyEachFrame, self.RCDisableAirspeedUse, self.AHRS_ORIENTATION, self.AHRSTrim, self.LandingDrift, self.ForcedDCM, self.DCMFallback, self.MAVFTP, self.AUTOTUNE, self.MegaSquirt, self.MSP_DJI, self.SpeedToFly, self.GlideSlopeThresh, self.HIGH_LATENCY2, self.MidAirDisarmDisallowed, self.EmbeddedParamParser, self.AerobaticsScripting, self.MANUAL_CONTROL, self.WindEstimates, self.AltResetBadGPS, self.AirspeedCal, self.MissionJumpTags, self.GCSFailsafe, self.SDCardWPTest, ]) return ret def disabled_tests(self): return { "LandingDrift": "Flapping test. See https://github.com/ArduPilot/ardupilot/issues/20054", }