#!/usr/bin/env python import os import zmq import numpy as np import selfdrive.messaging as messaging from cereal import car from common.numpy_fast import clip from selfdrive.config import Conversions as CV from common.services import service_list from common.realtime import sec_since_boot, set_realtime_priority, Ratekeeper from common.profiler import Profiler from selfdrive.controls.lib.drive_helpers import learn_angle_offset from selfdrive.controls.lib.longcontrol import LongControl from selfdrive.controls.lib.latcontrol import LatControl from selfdrive.controls.lib.pathplanner import PathPlanner from selfdrive.controls.lib.adaptivecruise import AdaptiveCruise from selfdrive.controls.lib.alertmanager import AlertManager car_type = os.getenv("CAR") if car_type is not None: exec('from selfdrive.car.'+car_type+'.interface import CarInterface') else: from selfdrive.car.honda.interface import CarInterface V_CRUISE_MAX = 144 V_CRUISE_MIN = 8 V_CRUISE_DELTA = 8 V_CRUISE_ENABLE_MIN = 40 def controlsd_thread(gctx, rate=100): #rate in Hz # *** log *** context = zmq.Context() live100 = messaging.pub_sock(context, service_list['live100'].port) thermal = messaging.sub_sock(context, service_list['thermal'].port) live20 = messaging.sub_sock(context, service_list['live20'].port) model = messaging.sub_sock(context, service_list['model'].port) health = messaging.sub_sock(context, service_list['health'].port) # connects to can and sendcan CI = CarInterface() VP = CI.getVehicleParams() PP = PathPlanner(model) AC = AdaptiveCruise(live20) AM = AlertManager() LoC = LongControl() LaC = LatControl() # controls enabled state enabled = False last_enable_request = 0 # learned angle offset angle_offset = 0 # rear view camera state rear_view_toggle = False v_cruise_kph = 255 # 0.0 - 1.0 awareness_status = 0.0 soft_disable_timer = None # Is cpu temp too high to enable? overtemp = False free_space = 1.0 # start the loop set_realtime_priority(2) rk = Ratekeeper(rate, print_delay_threshold=2./1000) while 1: prof = Profiler() cur_time = sec_since_boot() # read CAN CS = CI.update() prof.checkpoint("CarInterface") # did it request to enable? enable_request, enable_condition = False, False if enabled: # gives the user 6 minutes awareness_status -= 1.0/(100*60*6) if awareness_status <= 0.: AM.add("driverDistracted", enabled) # reset awareness status on steering if CS.steeringPressed: awareness_status = 1.0 # handle button presses for b in CS.buttonEvents: print b # reset awareness on any user action awareness_status = 1.0 # button presses for rear view if b.type == "leftBlinker" or b.type == "rightBlinker": if b.pressed: rear_view_toggle = True else: rear_view_toggle = False if b.type == "altButton1" and b.pressed: rear_view_toggle = not rear_view_toggle if not VP.brake_only and enabled and not b.pressed: if b.type == "accelCruise": v_cruise_kph = v_cruise_kph - (v_cruise_kph % V_CRUISE_DELTA) + V_CRUISE_DELTA elif b.type == "decelCruise": v_cruise_kph = v_cruise_kph - (v_cruise_kph % V_CRUISE_DELTA) - V_CRUISE_DELTA v_cruise_kph = clip(v_cruise_kph, V_CRUISE_MIN, V_CRUISE_MAX) if not enabled and b.type in ["accelCruise", "decelCruise"] and not b.pressed: enable_request = True # do disable on button down if b.type == "cancel" and b.pressed: AM.add("disable", enabled) prof.checkpoint("Buttons") # *** health checking logic *** hh = messaging.recv_sock(health) if hh is not None: # if the board isn't allowing controls but somehow we are enabled! if not hh.health.controlsAllowed and enabled: AM.add("controlsMismatch", enabled) # *** thermal checking logic *** # thermal data, checked every second td = messaging.recv_sock(thermal) if td is not None: # Check temperature. overtemp = any( t > 950 for t in (td.thermal.cpu0, td.thermal.cpu1, td.thermal.cpu2, td.thermal.cpu3, td.thermal.mem, td.thermal.gpu)) # under 15% of space free free_space = td.thermal.freeSpace prof.checkpoint("Health") # *** getting model logic *** PP.update(cur_time, CS.vEgo) if rk.frame % 5 == 2: # *** run this at 20hz again *** angle_offset = learn_angle_offset(enabled, CS.vEgo, angle_offset, np.asarray(PP.d_poly), LaC.y_des, CS.steeringPressed) # disable if the pedals are pressed while engaged, this is a user disable if enabled: if CS.gasPressed or CS.brakePressed: AM.add("disable", enabled) if enable_request: # check for pressed pedals if CS.gasPressed or CS.brakePressed: AM.add("pedalPressed", enabled) enable_request = False else: print "enabled pressed at", cur_time last_enable_request = cur_time # don't engage with less than 15% free if free_space < 0.15: AM.add("outOfSpace", enabled) enable_request = False if VP.brake_only: enable_condition = ((cur_time - last_enable_request) < 0.2) and CS.cruiseState.enabled else: enable_condition = enable_request if enable_request or enable_condition or enabled: # add all alerts from car for alert in CS.errors: AM.add(alert, enabled) if AC.dead: AM.add("radarCommIssue", enabled) if PP.dead: AM.add("modelCommIssue", enabled) if overtemp: AM.add("overheat", enabled) prof.checkpoint("Model") if enable_condition and not enabled and not AM.alertPresent(): print "*** enabling controls" # beep for enabling AM.add("enable", enabled) # enable both lateral and longitudinal controls enabled = True # on activation, let's always set v_cruise from where we are, even if PCM ACC is active v_cruise_kph = int(round(max(CS.vEgo * CV.MS_TO_KPH * VP.ui_speed_fudge, V_CRUISE_ENABLE_MIN))) # 6 minutes driver you're on awareness_status = 1.0 # reset the PID loops LaC.reset() # start long control at actual speed LoC.reset(v_pid = CS.vEgo) if VP.brake_only and CS.cruiseState.enabled: v_cruise_kph = CS.cruiseState.speed * CV.MS_TO_KPH # *** put the adaptive in adaptive cruise control *** AC.update(cur_time, CS.vEgo, CS.steeringAngle, LoC.v_pid, awareness_status, VP) prof.checkpoint("AdaptiveCruise") # *** gas/brake PID loop *** final_gas, final_brake = LoC.update(enabled, CS.vEgo, v_cruise_kph, AC.v_target_lead, AC.a_target, AC.jerk_factor, VP) # *** steering PID loop *** final_steer, sat_flag = LaC.update(enabled, CS.vEgo, CS.steeringAngle, CS.steeringPressed, PP.d_poly, angle_offset, VP) prof.checkpoint("PID") # ***** handle alerts **** # send a "steering required alert" if saturation count has reached the limit if sat_flag: AM.add("steerSaturated", enabled) if enabled and AM.alertShouldDisable(): print "DISABLING IMMEDIATELY ON ALERT" enabled = False if enabled and AM.alertShouldSoftDisable(): if soft_disable_timer is None: soft_disable_timer = 3 * rate elif soft_disable_timer == 0: print "SOFT DISABLING ON ALERT" enabled = False else: soft_disable_timer -= 1 else: soft_disable_timer = None # *** push the alerts to current *** alert_text_1, alert_text_2, visual_alert, audible_alert = AM.process_alerts(cur_time) # ***** control the car ***** CC = car.CarControl.new_message() CC.enabled = enabled CC.gas = float(final_gas) CC.brake = float(final_brake) CC.steeringTorque = float(final_steer) CC.cruiseControl.override = True CC.cruiseControl.cancel = bool((not VP.brake_only) or (not enabled and CS.cruiseState.enabled)) # always cancel if we have an interceptor CC.cruiseControl.speedOverride = float((LoC.v_pid - .3) if (VP.brake_only and final_brake == 0.) else 0.0) CC.cruiseControl.accelOverride = float(AC.a_pcm) CC.hudControl.setSpeed = float(v_cruise_kph * CV.KPH_TO_MS) CC.hudControl.speedVisible = enabled CC.hudControl.lanesVisible = enabled CC.hudControl.leadVisible = bool(AC.has_lead) CC.hudControl.visualAlert = visual_alert CC.hudControl.audibleAlert = audible_alert # this alert will apply next controls cycle if not CI.apply(CC): AM.add("controlsFailed", enabled) prof.checkpoint("CarControl") # ***** publish state to logger ***** # publish controls state at 100Hz dat = messaging.new_message() dat.init('live100') # show rear view camera on phone if in reverse gear or when button is pressed dat.live100.rearViewCam = ('reverseGear' in CS.errors) or rear_view_toggle dat.live100.alertText1 = alert_text_1 dat.live100.alertText2 = alert_text_2 dat.live100.awarenessStatus = max(awareness_status, 0.0) if enabled else 0.0 # what packets were used to process dat.live100.canMonoTimes = list(CS.canMonoTimes) dat.live100.mdMonoTime = PP.logMonoTime dat.live100.l20MonoTime = AC.logMonoTime # if controls is enabled dat.live100.enabled = enabled # car state dat.live100.vEgo = CS.vEgo dat.live100.angleSteers = CS.steeringAngle dat.live100.steerOverride = CS.steeringPressed # longitudinal control state dat.live100.vPid = float(LoC.v_pid) dat.live100.vCruise = float(v_cruise_kph) dat.live100.upAccelCmd = float(LoC.Up_accel_cmd) dat.live100.uiAccelCmd = float(LoC.Ui_accel_cmd) # lateral control state dat.live100.yActual = float(LaC.y_actual) dat.live100.yDes = float(LaC.y_des) dat.live100.upSteer = float(LaC.Up_steer) dat.live100.uiSteer = float(LaC.Ui_steer) # processed radar state, should add a_pcm? dat.live100.vTargetLead = float(AC.v_target_lead) dat.live100.aTargetMin = float(AC.a_target[0]) dat.live100.aTargetMax = float(AC.a_target[1]) dat.live100.jerkFactor = float(AC.jerk_factor) # lag dat.live100.cumLagMs = -rk.remaining*1000. live100.send(dat.to_bytes()) prof.checkpoint("Live100") # *** run loop at fixed rate *** if rk.keep_time(): prof.display() def main(gctx=None): controlsd_thread(gctx, 100) if __name__ == "__main__": main()