from common . numpy_fast import interp
from common . kalman . simple_kalman import KF1D
from selfdrive . can . parser import CANParser , CANDefine
from selfdrive . config import Conversions as CV
from selfdrive . car . honda . values import CAR , DBC , STEER_THRESHOLD , SPEED_FACTOR , HONDA_BOSCH
def parse_gear_shifter ( gear , vals ) :
val_to_capnp = { ' P ' : ' park ' , ' R ' : ' reverse ' , ' N ' : ' neutral ' ,
' D ' : ' drive ' , ' S ' : ' sport ' , ' L ' : ' low ' }
try :
return val_to_capnp [ vals [ gear ] ]
except KeyError :
return " unknown "
def calc_cruise_offset ( offset , speed ) :
# euristic formula so that speed is controlled to ~ 0.3m/s below pid_speed
# constraints to solve for _K0, _K1, _K2 are:
# - speed = 0m/s, out = -0.3
# - speed = 34m/s, offset = 20, out = -0.25
# - speed = 34m/s, offset = -2.5, out = -1.8
_K0 = - 0.3
_K1 = - 0.01879
_K2 = 0.01013
return min ( _K0 + _K1 * speed + _K2 * speed * offset , 0. )
def get_can_signals ( CP ) :
# this function generates lists for signal, messages and initial values
signals = [
( " XMISSION_SPEED " , " ENGINE_DATA " , 0 ) ,
( " WHEEL_SPEED_FL " , " WHEEL_SPEEDS " , 0 ) ,
( " WHEEL_SPEED_FR " , " WHEEL_SPEEDS " , 0 ) ,
( " WHEEL_SPEED_RL " , " WHEEL_SPEEDS " , 0 ) ,
( " WHEEL_SPEED_RR " , " WHEEL_SPEEDS " , 0 ) ,
( " STEER_ANGLE " , " STEERING_SENSORS " , 0 ) ,
( " STEER_ANGLE_RATE " , " STEERING_SENSORS " , 0 ) ,
( " STEER_TORQUE_SENSOR " , " STEER_STATUS " , 0 ) ,
( " LEFT_BLINKER " , " SCM_FEEDBACK " , 0 ) ,
( " RIGHT_BLINKER " , " SCM_FEEDBACK " , 0 ) ,
( " GEAR " , " GEARBOX " , 0 ) ,
( " SEATBELT_DRIVER_LAMP " , " SEATBELT_STATUS " , 1 ) ,
( " SEATBELT_DRIVER_LATCHED " , " SEATBELT_STATUS " , 0 ) ,
( " BRAKE_PRESSED " , " POWERTRAIN_DATA " , 0 ) ,
( " BRAKE_SWITCH " , " POWERTRAIN_DATA " , 0 ) ,
( " CRUISE_BUTTONS " , " SCM_BUTTONS " , 0 ) ,
( " ESP_DISABLED " , " VSA_STATUS " , 1 ) ,
( " HUD_LEAD " , " ACC_HUD " , 0 ) ,
( " USER_BRAKE " , " VSA_STATUS " , 0 ) ,
( " BRAKE_HOLD_ACTIVE " , " VSA_STATUS " , 0 ) ,
( " STEER_STATUS " , " STEER_STATUS " , 5 ) ,
( " GEAR_SHIFTER " , " GEARBOX " , 0 ) ,
( " PEDAL_GAS " , " POWERTRAIN_DATA " , 0 ) ,
( " CRUISE_SETTING " , " SCM_BUTTONS " , 0 ) ,
( " ACC_STATUS " , " POWERTRAIN_DATA " , 0 ) ,
]
checks = [
( " ENGINE_DATA " , 100 ) ,
( " WHEEL_SPEEDS " , 50 ) ,
( " STEERING_SENSORS " , 100 ) ,
( " SCM_FEEDBACK " , 10 ) ,
( " GEARBOX " , 100 ) ,
( " SEATBELT_STATUS " , 10 ) ,
( " CRUISE " , 10 ) ,
( " POWERTRAIN_DATA " , 100 ) ,
( " VSA_STATUS " , 50 ) ,
( " SCM_BUTTONS " , 25 ) ,
]
if CP . radarOffCan :
# Civic is only bosch to use the same brake message as other hondas.
if CP . carFingerprint not in ( CAR . ACCORDH , CAR . CIVIC_BOSCH ) :
signals + = [ ( " BRAKE_PRESSED " , " BRAKE_MODULE " , 0 ) ]
checks + = [ ( " BRAKE_MODULE " , 50 ) ]
signals + = [ ( " CAR_GAS " , " GAS_PEDAL_2 " , 0 ) ,
( " MAIN_ON " , " SCM_FEEDBACK " , 0 ) ,
( " EPB_STATE " , " EPB_STATUS " , 0 ) ,
( " CRUISE_SPEED " , " ACC_HUD " , 0 ) ]
checks + = [ ( " GAS_PEDAL_2 " , 100 ) ]
else :
# Nidec signals.
signals + = [ ( " BRAKE_ERROR_1 " , " STANDSTILL " , 1 ) ,
( " BRAKE_ERROR_2 " , " STANDSTILL " , 1 ) ,
( " CRUISE_SPEED_PCM " , " CRUISE " , 0 ) ,
( " CRUISE_SPEED_OFFSET " , " CRUISE_PARAMS " , 0 ) ]
checks + = [ ( " CRUISE_PARAMS " , 50 ) ,
( " STANDSTILL " , 50 ) ]
if CP . carFingerprint in ( CAR . ACCORD , CAR . ACCORD_15 , CAR . ACCORDH , CAR . CIVIC_BOSCH ) :
signals + = [ ( " DRIVERS_DOOR_OPEN " , " SCM_FEEDBACK " , 1 ) ]
else :
signals + = [ ( " DOOR_OPEN_FL " , " DOORS_STATUS " , 1 ) ,
( " DOOR_OPEN_FR " , " DOORS_STATUS " , 1 ) ,
( " DOOR_OPEN_RL " , " DOORS_STATUS " , 1 ) ,
( " DOOR_OPEN_RR " , " DOORS_STATUS " , 1 ) ,
( " WHEELS_MOVING " , " STANDSTILL " , 1 ) ]
checks + = [ ( " DOORS_STATUS " , 3 ) ]
if CP . carFingerprint == CAR . CIVIC :
signals + = [ ( " CAR_GAS " , " GAS_PEDAL_2 " , 0 ) ,
( " MAIN_ON " , " SCM_FEEDBACK " , 0 ) ,
( " EPB_STATE " , " EPB_STATUS " , 0 ) ]
elif CP . carFingerprint == CAR . ACURA_ILX :
signals + = [ ( " CAR_GAS " , " GAS_PEDAL_2 " , 0 ) ,
( " MAIN_ON " , " SCM_BUTTONS " , 0 ) ]
elif CP . carFingerprint in ( CAR . CRV , CAR . ACURA_RDX , CAR . PILOT_2019 , CAR . RIDGELINE ) :
signals + = [ ( " MAIN_ON " , " SCM_BUTTONS " , 0 ) ]
elif CP . carFingerprint == CAR . ODYSSEY :
signals + = [ ( " MAIN_ON " , " SCM_FEEDBACK " , 0 ) ,
( " EPB_STATE " , " EPB_STATUS " , 0 ) ]
checks + = [ ( " EPB_STATUS " , 50 ) ]
elif CP . carFingerprint == CAR . PILOT :
signals + = [ ( " MAIN_ON " , " SCM_BUTTONS " , 0 ) ,
( " CAR_GAS " , " GAS_PEDAL_2 " , 0 ) ]
# add gas interceptor reading if we are using it
if CP . enableGasInterceptor :
signals . append ( ( " INTERCEPTOR_GAS " , " GAS_SENSOR " , 0 ) )
checks . append ( ( " GAS_SENSOR " , 50 ) )
return signals , checks
def get_can_parser ( CP ) :
signals , checks = get_can_signals ( CP )
return CANParser ( DBC [ CP . carFingerprint ] [ ' pt ' ] , signals , checks , 0 )
def get_cam_can_parser ( CP ) :
signals = [ ]
# all hondas except CRV and RDX use 0xe4 for steering
checks = [ ( 0xe4 , 100 ) ]
if CP . carFingerprint in [ CAR . CRV , CAR . ACURA_RDX ] :
checks = [ ( 0x194 , 100 ) ]
cam_bus = 1 if CP . carFingerprint in HONDA_BOSCH else 2
return CANParser ( DBC [ CP . carFingerprint ] [ ' pt ' ] , signals , checks , cam_bus )
class CarState ( object ) :
def __init__ ( self , CP ) :
self . CP = CP
self . can_define = CANDefine ( DBC [ CP . carFingerprint ] [ ' pt ' ] )
self . shifter_values = self . can_define . dv [ " GEARBOX " ] [ " GEAR_SHIFTER " ]
self . user_gas , self . user_gas_pressed = 0. , 0
self . brake_switch_prev = 0
self . brake_switch_ts = 0
self . cruise_buttons = 0
self . cruise_setting = 0
self . v_cruise_pcm_prev = 0
self . blinker_on = 0
self . left_blinker_on = 0
self . right_blinker_on = 0
self . stopped = 0
# vEgo kalman filter
dt = 0.01
# Q = np.matrix([[10.0, 0.0], [0.0, 100.0]])
# R = 1e3
self . v_ego_kf = KF1D ( x0 = [ [ 0.0 ] , [ 0.0 ] ] ,
A = [ [ 1.0 , dt ] , [ 0.0 , 1.0 ] ] ,
C = [ [ 1.0 , 0.0 ] ] ,
K = [ [ 0.12287673 ] , [ 0.29666309 ] ] )
self . v_ego = 0.0
def update ( self , cp , cp_cam ) :
# copy can_valid on buses 0 and 2
self . can_valid = cp . can_valid
self . cam_can_valid = cp_cam . can_valid
# car params
v_weight_v = [ 0. , 1. ] # don't trust smooth speed at low values to avoid premature zero snapping
v_weight_bp = [ 1. , 6. ] # smooth blending, below ~0.6m/s the smooth speed snaps to zero
# update prevs, update must run once per loop
self . prev_cruise_buttons = self . cruise_buttons
self . prev_cruise_setting = self . cruise_setting
self . prev_blinker_on = self . blinker_on
self . prev_left_blinker_on = self . left_blinker_on
self . prev_right_blinker_on = self . right_blinker_on
# ******************* parse out can *******************
if self . CP . carFingerprint in ( CAR . ACCORD , CAR . ACCORD_15 , CAR . ACCORDH , CAR . CIVIC_BOSCH ) : # TODO: find wheels moving bit in dbc
self . standstill = cp . vl [ " ENGINE_DATA " ] [ ' XMISSION_SPEED ' ] < 0.1
self . door_all_closed = not cp . vl [ " SCM_FEEDBACK " ] [ ' DRIVERS_DOOR_OPEN ' ]
else :
self . standstill = not cp . vl [ " STANDSTILL " ] [ ' WHEELS_MOVING ' ]
self . door_all_closed = not any ( [ cp . vl [ " DOORS_STATUS " ] [ ' DOOR_OPEN_FL ' ] , cp . vl [ " DOORS_STATUS " ] [ ' DOOR_OPEN_FR ' ] ,
cp . vl [ " DOORS_STATUS " ] [ ' DOOR_OPEN_RL ' ] , cp . vl [ " DOORS_STATUS " ] [ ' DOOR_OPEN_RR ' ] ] )
self . seatbelt = not cp . vl [ " SEATBELT_STATUS " ] [ ' SEATBELT_DRIVER_LAMP ' ] and cp . vl [ " SEATBELT_STATUS " ] [ ' SEATBELT_DRIVER_LATCHED ' ]
# 2 = temporary; 3 = TBD; 4 = temporary, hit a bump; 5 = (permanent); 6 = temporary; 7 = (permanent)
# TODO: Use values from DBC to parse this field
self . steer_error = cp . vl [ " STEER_STATUS " ] [ ' STEER_STATUS ' ] not in [ 0 , 2 , 3 , 4 , 6 ]
self . steer_not_allowed = cp . vl [ " STEER_STATUS " ] [ ' STEER_STATUS ' ] != 0
self . steer_warning = cp . vl [ " STEER_STATUS " ] [ ' STEER_STATUS ' ] not in [ 0 , 3 ] # 3 is low speed lockout, not worth a warning
if self . CP . radarOffCan :
self . brake_error = 0
else :
self . brake_error = cp . vl [ " STANDSTILL " ] [ ' BRAKE_ERROR_1 ' ] or cp . vl [ " STANDSTILL " ] [ ' BRAKE_ERROR_2 ' ]
self . esp_disabled = cp . vl [ " VSA_STATUS " ] [ ' ESP_DISABLED ' ]
# calc best v_ego estimate, by averaging two opposite corners
speed_factor = SPEED_FACTOR [ self . CP . carFingerprint ]
self . v_wheel_fl = cp . vl [ " WHEEL_SPEEDS " ] [ ' WHEEL_SPEED_FL ' ] * CV . KPH_TO_MS * speed_factor
self . v_wheel_fr = cp . vl [ " WHEEL_SPEEDS " ] [ ' WHEEL_SPEED_FR ' ] * CV . KPH_TO_MS * speed_factor
self . v_wheel_rl = cp . vl [ " WHEEL_SPEEDS " ] [ ' WHEEL_SPEED_RL ' ] * CV . KPH_TO_MS * speed_factor
self . v_wheel_rr = cp . vl [ " WHEEL_SPEEDS " ] [ ' WHEEL_SPEED_RR ' ] * CV . KPH_TO_MS * speed_factor
v_wheel = ( self . v_wheel_fl + self . v_wheel_fr + self . v_wheel_rl + self . v_wheel_rr ) / 4.
# blend in transmission speed at low speed, since it has more low speed accuracy
self . v_weight = interp ( v_wheel , v_weight_bp , v_weight_v )
speed = ( 1. - self . v_weight ) * cp . vl [ " ENGINE_DATA " ] [ ' XMISSION_SPEED ' ] * CV . KPH_TO_MS * speed_factor + \
self . v_weight * v_wheel
if abs ( speed - self . v_ego ) > 2.0 : # Prevent large accelerations when car starts at non zero speed
self . v_ego_kf . x = [ [ speed ] , [ 0.0 ] ]
self . v_ego_raw = speed
v_ego_x = self . v_ego_kf . update ( speed )
self . v_ego = float ( v_ego_x [ 0 ] )
self . a_ego = float ( v_ego_x [ 1 ] )
# this is a hack for the interceptor. This is now only used in the simulation
# TODO: Replace tests by toyota so this can go away
if self . CP . enableGasInterceptor :
self . user_gas = cp . vl [ " GAS_SENSOR " ] [ ' INTERCEPTOR_GAS ' ]
self . user_gas_pressed = self . user_gas > 0 # this works because interceptor read < 0 when pedal position is 0. Once calibrated, this will change
self . gear = 0 if self . CP . carFingerprint == CAR . CIVIC else cp . vl [ " GEARBOX " ] [ ' GEAR ' ]
self . angle_steers = cp . vl [ " STEERING_SENSORS " ] [ ' STEER_ANGLE ' ]
self . angle_steers_rate = cp . vl [ " STEERING_SENSORS " ] [ ' STEER_ANGLE_RATE ' ]
self . cruise_setting = cp . vl [ " SCM_BUTTONS " ] [ ' CRUISE_SETTING ' ]
self . cruise_buttons = cp . vl [ " SCM_BUTTONS " ] [ ' CRUISE_BUTTONS ' ]
self . blinker_on = cp . vl [ " SCM_FEEDBACK " ] [ ' LEFT_BLINKER ' ] or cp . vl [ " SCM_FEEDBACK " ] [ ' RIGHT_BLINKER ' ]
self . left_blinker_on = cp . vl [ " SCM_FEEDBACK " ] [ ' LEFT_BLINKER ' ]
self . right_blinker_on = cp . vl [ " SCM_FEEDBACK " ] [ ' RIGHT_BLINKER ' ]
self . brake_hold = cp . vl [ " VSA_STATUS " ] [ ' BRAKE_HOLD_ACTIVE ' ]
if self . CP . carFingerprint in ( CAR . CIVIC , CAR . ODYSSEY , CAR . CRV_5G , CAR . ACCORD , CAR . ACCORD_15 , CAR . ACCORDH , CAR . CIVIC_BOSCH ) :
self . park_brake = cp . vl [ " EPB_STATUS " ] [ ' EPB_STATE ' ] != 0
self . main_on = cp . vl [ " SCM_FEEDBACK " ] [ ' MAIN_ON ' ]
else :
self . park_brake = 0 # TODO
self . main_on = cp . vl [ " SCM_BUTTONS " ] [ ' MAIN_ON ' ]
can_gear_shifter = int ( cp . vl [ " GEARBOX " ] [ ' GEAR_SHIFTER ' ] )
self . gear_shifter = parse_gear_shifter ( can_gear_shifter , self . shifter_values )
self . pedal_gas = cp . vl [ " POWERTRAIN_DATA " ] [ ' PEDAL_GAS ' ]
# crv doesn't include cruise control
if self . CP . carFingerprint in ( CAR . CRV , CAR . ODYSSEY , CAR . ACURA_RDX , CAR . RIDGELINE , CAR . PILOT_2019 ) :
self . car_gas = self . pedal_gas
else :
self . car_gas = cp . vl [ " GAS_PEDAL_2 " ] [ ' CAR_GAS ' ]
self . steer_torque_driver = cp . vl [ " STEER_STATUS " ] [ ' STEER_TORQUE_SENSOR ' ]
self . steer_override = abs ( self . steer_torque_driver ) > STEER_THRESHOLD [ self . CP . carFingerprint ]
self . brake_switch = cp . vl [ " POWERTRAIN_DATA " ] [ ' BRAKE_SWITCH ' ]
if self . CP . radarOffCan :
self . stopped = cp . vl [ " ACC_HUD " ] [ ' CRUISE_SPEED ' ] == 252.
self . cruise_speed_offset = calc_cruise_offset ( 0 , self . v_ego )
if self . CP . carFingerprint in ( CAR . CIVIC_BOSCH , CAR . ACCORDH ) :
self . brake_switch = cp . vl [ " POWERTRAIN_DATA " ] [ ' BRAKE_SWITCH ' ]
self . brake_pressed = cp . vl [ " POWERTRAIN_DATA " ] [ ' BRAKE_PRESSED ' ] or \
( self . brake_switch and self . brake_switch_prev and \
cp . ts [ " POWERTRAIN_DATA " ] [ ' BRAKE_SWITCH ' ] != self . brake_switch_ts )
self . brake_switch_prev = self . brake_switch
self . brake_switch_ts = cp . ts [ " POWERTRAIN_DATA " ] [ ' BRAKE_SWITCH ' ]
else :
self . brake_pressed = cp . vl [ " BRAKE_MODULE " ] [ ' BRAKE_PRESSED ' ]
# On set, cruise set speed pulses between 254~255 and the set speed prev is set to avoid this.
self . v_cruise_pcm = self . v_cruise_pcm_prev if cp . vl [ " ACC_HUD " ] [ ' CRUISE_SPEED ' ] > 160.0 else cp . vl [ " ACC_HUD " ] [ ' CRUISE_SPEED ' ]
self . v_cruise_pcm_prev = self . v_cruise_pcm
else :
self . brake_switch = cp . vl [ " POWERTRAIN_DATA " ] [ ' BRAKE_SWITCH ' ]
self . cruise_speed_offset = calc_cruise_offset ( cp . vl [ " CRUISE_PARAMS " ] [ ' CRUISE_SPEED_OFFSET ' ] , self . v_ego )
self . v_cruise_pcm = cp . vl [ " CRUISE " ] [ ' CRUISE_SPEED_PCM ' ]
# brake switch has shown some single time step noise, so only considered when
# switch is on for at least 2 consecutive CAN samples
self . brake_pressed = cp . vl [ " POWERTRAIN_DATA " ] [ ' BRAKE_PRESSED ' ] or \
( self . brake_switch and self . brake_switch_prev and \
cp . ts [ " POWERTRAIN_DATA " ] [ ' BRAKE_SWITCH ' ] != self . brake_switch_ts )
self . brake_switch_prev = self . brake_switch
self . brake_switch_ts = cp . ts [ " POWERTRAIN_DATA " ] [ ' BRAKE_SWITCH ' ]
self . user_brake = cp . vl [ " VSA_STATUS " ] [ ' USER_BRAKE ' ]
self . pcm_acc_status = cp . vl [ " POWERTRAIN_DATA " ] [ ' ACC_STATUS ' ]
self . hud_lead = cp . vl [ " ACC_HUD " ] [ ' HUD_LEAD ' ]
# Gets rid of Pedal Grinding noise when brake is pressed at slow speeds for some models
# TODO: this should be ok for all cars. Verify it.
if self . CP . carFingerprint in ( CAR . PILOT , CAR . PILOT_2019 , CAR . RIDGELINE ) :
if self . user_brake > 0.05 :
self . brake_pressed = 1
# carstate standalone tester
if __name__ == ' __main__ ' :
import zmq
context = zmq . Context ( )
class CarParams ( object ) :
def __init__ ( self ) :
self . carFingerprint = " HONDA CIVIC 2016 TOURING "
self . enableGasInterceptor = 0
CP = CarParams ( )
CS = CarState ( CP )
# while 1:
# CS.update()
# time.sleep(0.01)
