#!/usr/bin/env python from cereal import car, log from common.realtime import sec_since_boot from selfdrive.config import Conversions as CV from selfdrive.controls.lib.drive_helpers import EventTypes as ET, create_event from selfdrive.controls.lib.vehicle_model import VehicleModel from selfdrive.car.hyundai.carstate import CarState, get_can_parser, get_camera_parser from selfdrive.car.hyundai.values import CAMERA_MSGS, CAR, get_hud_alerts try: from selfdrive.car.hyundai.carcontroller import CarController except ImportError: CarController = None class CarInterface(object): def __init__(self, CP, sendcan=None): self.CP = CP self.VM = VehicleModel(CP) self.idx = 0 self.lanes = 0 self.lkas_request = 0 self.gas_pressed_prev = False self.brake_pressed_prev = False self.can_invalid_count = 0 self.cruise_enabled_prev = False self.low_speed_alert = False # *** init the major players *** self.CS = CarState(CP) self.cp = get_can_parser(CP) self.cp_cam = get_camera_parser(CP) # sending if read only is False if sendcan is not None: self.sendcan = sendcan self.CC = CarController(self.cp.dbc_name, CP.carFingerprint, CP.enableCamera) @staticmethod def compute_gb(accel, speed): return float(accel) / 3.0 @staticmethod def calc_accel_override(a_ego, a_target, v_ego, v_target): return 1.0 @staticmethod def get_params(candidate, fingerprint): # kg of standard extra cargo to count for drive, gas, etc... std_cargo = 136 ret = car.CarParams.new_message() ret.carName = "hyundai" ret.carFingerprint = candidate ret.radarOffCan = True ret.safetyModel = car.CarParams.SafetyModels.hyundai ret.enableCruise = True # stock acc # FIXME: hardcoding honda civic 2016 touring params so they can be used to # scale unknown params for other cars mass_civic = 2923 * CV.LB_TO_KG + std_cargo wheelbase_civic = 2.70 centerToFront_civic = wheelbase_civic * 0.4 centerToRear_civic = wheelbase_civic - centerToFront_civic rotationalInertia_civic = 2500 tireStiffnessFront_civic = 192150 tireStiffnessRear_civic = 202500 ret.steerActuatorDelay = 0.1 # Default delay tire_stiffness_factor = 1. if candidate == CAR.SANTA_FE: ret.steerKf = 0.00005 ret.steerRateCost = 0.5 ret.mass = 3982 * CV.LB_TO_KG + std_cargo ret.wheelbase = 2.766 # Values from optimizer ret.steerRatio = 16.55 # 13.8 is spec end-to-end tire_stiffness_factor = 0.82 ret.steerKiBP, ret.steerKpBP = [[0.], [0.]] ret.steerKpV, ret.steerKiV = [[0.37], [0.1]] ret.minSteerSpeed = 0. elif candidate == CAR.KIA_SORENTO: ret.steerKf = 0.00005 ret.steerRateCost = 0.5 ret.mass = 1985 + std_cargo ret.wheelbase = 2.78 ret.steerRatio = 14.4 * 1.1 # 10% higher at the center seems reasonable ret.steerKiBP, ret.steerKpBP = [[0.], [0.]] ret.steerKpV, ret.steerKiV = [[0.25], [0.05]] ret.minSteerSpeed = 0. elif candidate == CAR.ELANTRA: ret.steerKf = 0.00006 ret.steerRateCost = 0.5 ret.mass = 1275 + std_cargo ret.wheelbase = 2.7 ret.steerRatio = 13.73 #Spec tire_stiffness_factor = 0.385 ret.steerKiBP, ret.steerKpBP = [[0.], [0.]] ret.steerKpV, ret.steerKiV = [[0.25], [0.05]] ret.minSteerSpeed = 32 * CV.MPH_TO_MS elif candidate == CAR.GENESIS: ret.steerKf = 0.00005 ret.steerRateCost = 0.5 ret.mass = 2060 + std_cargo ret.wheelbase = 3.01 ret.steerRatio = 16.5 ret.steerKiBP, ret.steerKpBP = [[0.], [0.]] ret.steerKpV, ret.steerKiV = [[0.16], [0.01]] ret.minSteerSpeed = 35 * CV.MPH_TO_MS elif candidate == CAR.KIA_STINGER: ret.steerKf = 0.00005 ret.steerRateCost = 0.5 ret.mass = 1825 + std_cargo ret.wheelbase = 2.78 ret.steerRatio = 14.4 * 1.15 # 15% higher at the center seems reasonable ret.steerKiBP, ret.steerKpBP = [[0.], [0.]] ret.steerKpV, ret.steerKiV = [[0.25], [0.05]] ret.minSteerSpeed = 0. ret.minEnableSpeed = -1. # enable is done by stock ACC, so ignore this ret.longitudinalKpBP = [0.] ret.longitudinalKpV = [0.] ret.longitudinalKiBP = [0.] ret.longitudinalKiV = [0.] ret.centerToFront = ret.wheelbase * 0.4 centerToRear = ret.wheelbase - ret.centerToFront # TODO: get actual value, for now starting with reasonable value for # civic and scaling by mass and wheelbase ret.rotationalInertia = rotationalInertia_civic * \ ret.mass * ret.wheelbase**2 / (mass_civic * wheelbase_civic**2) # TODO: start from empirically derived lateral slip stiffness for the civic and scale by # mass and CG position, so all cars will have approximately similar dyn behaviors ret.tireStiffnessFront = (tireStiffnessFront_civic * tire_stiffness_factor) * \ ret.mass / mass_civic * \ (centerToRear / ret.wheelbase) / (centerToRear_civic / wheelbase_civic) ret.tireStiffnessRear = (tireStiffnessRear_civic * tire_stiffness_factor) * \ ret.mass / mass_civic * \ (ret.centerToFront / ret.wheelbase) / (centerToFront_civic / wheelbase_civic) # no rear steering, at least on the listed cars above ret.steerRatioRear = 0. ret.steerControlType = car.CarParams.SteerControlType.torque # steer, gas, brake limitations VS speed ret.steerMaxBP = [0.] ret.steerMaxV = [1.0] ret.gasMaxBP = [0.] ret.gasMaxV = [1.] ret.brakeMaxBP = [0.] ret.brakeMaxV = [1.] ret.longPidDeadzoneBP = [0.] ret.longPidDeadzoneV = [0.] ret.enableCamera = not any(x for x in CAMERA_MSGS if x in fingerprint) ret.openpilotLongitudinalControl = False ret.steerLimitAlert = False ret.stoppingControl = False ret.startAccel = 0.0 return ret # returns a car.CarState def update(self, c): # ******************* do can recv ******************* canMonoTimes = [] self.cp.update(int(sec_since_boot() * 1e9), False) self.cp_cam.update(int(sec_since_boot() * 1e9), False) self.CS.update(self.cp, self.cp_cam) # create message ret = car.CarState.new_message() # speeds ret.vEgo = self.CS.v_ego ret.vEgoRaw = self.CS.v_ego_raw ret.aEgo = self.CS.a_ego ret.yawRate = self.CS.yaw_rate ret.standstill = self.CS.standstill ret.wheelSpeeds.fl = self.CS.v_wheel_fl ret.wheelSpeeds.fr = self.CS.v_wheel_fr ret.wheelSpeeds.rl = self.CS.v_wheel_rl ret.wheelSpeeds.rr = self.CS.v_wheel_rr # gear shifter if self.CP.carFingerprint == CAR.ELANTRA: ret.gearShifter = self.CS.gear_shifter_cluster else: ret.gearShifter = self.CS.gear_shifter # gas pedal ret.gas = self.CS.car_gas ret.gasPressed = self.CS.pedal_gas > 1e-3 # tolerance to avoid false press reading # brake pedal ret.brake = self.CS.user_brake ret.brakePressed = self.CS.brake_pressed != 0 ret.brakeLights = self.CS.brake_lights # steering wheel ret.steeringAngle = self.CS.angle_steers ret.steeringRate = self.CS.angle_steers_rate # it's unsigned ret.steeringTorque = self.CS.steer_torque_driver ret.steeringPressed = self.CS.steer_override # cruise state ret.cruiseState.enabled = self.CS.pcm_acc_status != 0 if self.CS.pcm_acc_status != 0: ret.cruiseState.speed = self.CS.cruise_set_speed else: ret.cruiseState.speed = 0 ret.cruiseState.available = bool(self.CS.main_on) ret.cruiseState.standstill = False # TODO: button presses buttonEvents = [] if self.CS.left_blinker_on != self.CS.prev_left_blinker_on: be = car.CarState.ButtonEvent.new_message() be.type = 'leftBlinker' be.pressed = self.CS.left_blinker_on != 0 buttonEvents.append(be) if self.CS.right_blinker_on != self.CS.prev_right_blinker_on: be = car.CarState.ButtonEvent.new_message() be.type = 'rightBlinker' be.pressed = self.CS.right_blinker_on != 0 buttonEvents.append(be) ret.buttonEvents = buttonEvents ret.leftBlinker = bool(self.CS.left_blinker_on) ret.rightBlinker = bool(self.CS.right_blinker_on) ret.doorOpen = not self.CS.door_all_closed ret.seatbeltUnlatched = not self.CS.seatbelt # low speed steer alert hysteresis logic (only for cars with steer cut off above 10 m/s) if ret.vEgo < (self.CP.minSteerSpeed + 2.) and self.CP.minSteerSpeed > 10.: self.low_speed_alert = True if ret.vEgo > (self.CP.minSteerSpeed + 4.): self.low_speed_alert = False # events events = [] if not self.CS.can_valid: self.can_invalid_count += 1 if self.can_invalid_count >= 5: events.append(create_event('commIssue', [ET.NO_ENTRY, ET.IMMEDIATE_DISABLE])) else: self.can_invalid_count = 0 if not ret.gearShifter == 'drive': events.append(create_event('wrongGear', [ET.NO_ENTRY, ET.SOFT_DISABLE])) if ret.doorOpen: events.append(create_event('doorOpen', [ET.NO_ENTRY, ET.SOFT_DISABLE])) if ret.seatbeltUnlatched: events.append(create_event('seatbeltNotLatched', [ET.NO_ENTRY, ET.SOFT_DISABLE])) if self.CS.esp_disabled: events.append(create_event('espDisabled', [ET.NO_ENTRY, ET.SOFT_DISABLE])) if not self.CS.main_on: events.append(create_event('wrongCarMode', [ET.NO_ENTRY, ET.USER_DISABLE])) if ret.gearShifter == 'reverse': events.append(create_event('reverseGear', [ET.NO_ENTRY, ET.IMMEDIATE_DISABLE])) if self.CS.steer_error: events.append(create_event('steerTempUnavailable', [ET.NO_ENTRY, ET.WARNING])) # enable request in prius is simple, as we activate when Toyota is active (rising edge) if ret.cruiseState.enabled and not self.cruise_enabled_prev: events.append(create_event('pcmEnable', [ET.ENABLE])) elif not ret.cruiseState.enabled: events.append(create_event('pcmDisable', [ET.USER_DISABLE])) # disable on pedals rising edge or when brake is pressed and speed isn't zero if (ret.gasPressed and not self.gas_pressed_prev) or \ (ret.brakePressed and (not self.brake_pressed_prev or ret.vEgoRaw > 0.1)): events.append(create_event('pedalPressed', [ET.NO_ENTRY, ET.USER_DISABLE])) if ret.gasPressed: events.append(create_event('pedalPressed', [ET.PRE_ENABLE])) if self.low_speed_alert: events.append(create_event('belowSteerSpeed', [ET.WARNING])) ret.events = events ret.canMonoTimes = canMonoTimes self.gas_pressed_prev = ret.gasPressed self.brake_pressed_prev = ret.brakePressed self.cruise_enabled_prev = ret.cruiseState.enabled return ret.as_reader() def apply(self, c, perception_state=log.Live20Data.new_message()): hud_alert = get_hud_alerts(c.hudControl.visualAlert, c.hudControl.audibleAlert) self.CC.update(self.sendcan, c.enabled, self.CS, c.actuators, c.cruiseControl.cancel, hud_alert) return False