__init__.py

# python library to interface with panda
import os
import sys
import time
import usb1
import struct
import hashlib
import binascii
from functools import wraps, partial
from itertools import accumulate

from .base import BaseHandle
from .constants import FW_PATH, McuType
from .dfu import PandaDFU
from .isotp import isotp_send, isotp_recv
from .spi import PandaSpiHandle, PandaSpiException, PandaProtocolMismatch
from .usb import PandaUsbHandle
from .utils import logger

__version__ = '0.0.10'

CANPACKET_HEAD_SIZE = 0x6
DLC_TO_LEN = [0, 1, 2, 3, 4, 5, 6, 7, 8, 12, 16, 20, 24, 32, 48, 64]
LEN_TO_DLC = {length: dlc for (dlc, length) in enumerate(DLC_TO_LEN)}
PANDA_BUS_CNT = 3


def calculate_checksum(data):
  res = 0
  for b in data:
    res ^= b
  return res

def pack_can_buffer(arr):
  snds = [b'']
  for address, dat, bus in arr:
    assert len(dat) in LEN_TO_DLC
    #logger.debug("  W 0x%x: 0x%s", address, dat.hex())

    extended = 1 if address >= 0x800 else 0
    data_len_code = LEN_TO_DLC[len(dat)]
    header = bytearray(CANPACKET_HEAD_SIZE)
    word_4b = address << 3 | extended << 2
    header[0] = (data_len_code << 4) | (bus << 1)
    header[1] = word_4b & 0xFF
    header[2] = (word_4b >> 8) & 0xFF
    header[3] = (word_4b >> 16) & 0xFF
    header[4] = (word_4b >> 24) & 0xFF
    header[5] = calculate_checksum(header[:5] + dat)

    snds[-1] += header + dat
    if len(snds[-1]) > 256: # Limit chunks to 256 bytes
      snds.append(b'')

  return snds

def unpack_can_buffer(dat):
  ret = []

  while len(dat) >= CANPACKET_HEAD_SIZE:
    data_len = DLC_TO_LEN[(dat[0]>>4)]

    header = dat[:CANPACKET_HEAD_SIZE]

    bus = (header[0] >> 1) & 0x7
    address = (header[4] << 24 | header[3] << 16 | header[2] << 8 | header[1]) >> 3

    if (header[1] >> 1) & 0x1:
      # returned
      bus += 128
    if header[1] & 0x1:
      # rejected
      bus += 192

    # we need more from the next transfer
    if data_len > len(dat) - CANPACKET_HEAD_SIZE:
      break

    assert calculate_checksum(dat[:(CANPACKET_HEAD_SIZE+data_len)]) == 0, "CAN packet checksum incorrect"

    data = dat[CANPACKET_HEAD_SIZE:(CANPACKET_HEAD_SIZE+data_len)]
    dat = dat[(CANPACKET_HEAD_SIZE+data_len):]

    ret.append((address, data, bus))

  return (ret, dat)


def ensure_version(desc, lib_field, panda_field, fn):
  @wraps(fn)
  def wrapper(self, *args, **kwargs):
    lib_version = getattr(self, lib_field)
    panda_version = getattr(self, panda_field)
    if lib_version != panda_version:
      raise RuntimeError(f"{desc} packet version mismatch: panda's firmware v{panda_version}, library v{lib_version}. Reflash panda.")
    return fn(self, *args, **kwargs)
  return wrapper
ensure_can_packet_version = partial(ensure_version, "CAN", "CAN_PACKET_VERSION", "can_version")
ensure_can_health_packet_version = partial(ensure_version, "CAN health", "CAN_HEALTH_PACKET_VERSION", "can_health_version")
ensure_health_packet_version = partial(ensure_version, "health", "HEALTH_PACKET_VERSION", "health_version")



class ALTERNATIVE_EXPERIENCE:
  DEFAULT = 0
  DISABLE_DISENGAGE_ON_GAS = 1
  DISABLE_STOCK_AEB = 2
  RAISE_LONGITUDINAL_LIMITS_TO_ISO_MAX = 8
  ALLOW_AEB = 16

class Panda:

  # matches cereal.car.CarParams.SafetyModel
  SAFETY_SILENT = 0
  SAFETY_HONDA_NIDEC = 1
  SAFETY_TOYOTA = 2
  SAFETY_ELM327 = 3
  SAFETY_GM = 4
  SAFETY_HONDA_BOSCH_GIRAFFE = 5
  SAFETY_FORD = 6
  SAFETY_HYUNDAI = 8
  SAFETY_CHRYSLER = 9
  SAFETY_TESLA = 10
  SAFETY_SUBARU = 11
  SAFETY_MAZDA = 13
  SAFETY_NISSAN = 14
  SAFETY_VOLKSWAGEN_MQB = 15
  SAFETY_ALLOUTPUT = 17
  SAFETY_GM_ASCM = 18
  SAFETY_NOOUTPUT = 19
  SAFETY_HONDA_BOSCH = 20
  SAFETY_VOLKSWAGEN_PQ = 21
  SAFETY_SUBARU_PREGLOBAL = 22
  SAFETY_HYUNDAI_LEGACY = 23
  SAFETY_HYUNDAI_COMMUNITY = 24
  SAFETY_STELLANTIS = 25
  SAFETY_FAW = 26
  SAFETY_BODY = 27
  SAFETY_HYUNDAI_CANFD = 28

  SERIAL_DEBUG = 0
  SERIAL_ESP = 1
  SERIAL_LIN1 = 2
  SERIAL_LIN2 = 3
  SERIAL_SOM_DEBUG = 4

  USB_PIDS = (0xddee, 0xddcc)
  REQUEST_IN = usb1.ENDPOINT_IN | usb1.TYPE_VENDOR | usb1.RECIPIENT_DEVICE
  REQUEST_OUT = usb1.ENDPOINT_OUT | usb1.TYPE_VENDOR | usb1.RECIPIENT_DEVICE

  HW_TYPE_UNKNOWN = b'\x00'
  HW_TYPE_WHITE_PANDA = b'\x01'
  HW_TYPE_GREY_PANDA = b'\x02'
  HW_TYPE_BLACK_PANDA = b'\x03'
  HW_TYPE_PEDAL = b'\x04'
  HW_TYPE_UNO = b'\x05'
  HW_TYPE_DOS = b'\x06'
  HW_TYPE_RED_PANDA = b'\x07'
  HW_TYPE_RED_PANDA_V2 = b'\x08'
  HW_TYPE_TRES = b'\x09'
  HW_TYPE_CUATRO = b'\x0a'

  CAN_PACKET_VERSION = 4
  HEALTH_PACKET_VERSION = 16
  CAN_HEALTH_PACKET_VERSION = 5
  HEALTH_STRUCT = struct.Struct("<IIIIIIIIBBBBBHBBBHfBBHBHHB")
  CAN_HEALTH_STRUCT = struct.Struct("<BIBBBBBBBBIIIIIIIHHBBBIIII")

  F4_DEVICES = [HW_TYPE_WHITE_PANDA, HW_TYPE_GREY_PANDA, HW_TYPE_BLACK_PANDA, HW_TYPE_UNO, HW_TYPE_DOS]
  H7_DEVICES = [HW_TYPE_RED_PANDA, HW_TYPE_RED_PANDA_V2, HW_TYPE_TRES, HW_TYPE_CUATRO]

  INTERNAL_DEVICES = (HW_TYPE_UNO, HW_TYPE_DOS, HW_TYPE_TRES, HW_TYPE_CUATRO)
  HAS_OBD = (HW_TYPE_BLACK_PANDA, HW_TYPE_UNO, HW_TYPE_DOS, HW_TYPE_RED_PANDA, HW_TYPE_RED_PANDA_V2, HW_TYPE_TRES, HW_TYPE_CUATRO)

  MAX_FAN_RPMs = {
    HW_TYPE_UNO: 5100,
    HW_TYPE_DOS: 6500,
    HW_TYPE_TRES: 6600,
    HW_TYPE_CUATRO: 6600,
  }

  HARNESS_STATUS_NC = 0
  HARNESS_STATUS_NORMAL = 1
  HARNESS_STATUS_FLIPPED = 2

  # first byte is for EPS scaling factor
  FLAG_TOYOTA_ALT_BRAKE = (1 << 8)
  FLAG_TOYOTA_STOCK_LONGITUDINAL = (2 << 8)
  FLAG_TOYOTA_LTA = (4 << 8)
  FLAG_TOYOTA_SECOC = (8 << 8)

  FLAG_HONDA_ALT_BRAKE = 1
  FLAG_HONDA_BOSCH_LONG = 2
  FLAG_HONDA_NIDEC_ALT = 4
  FLAG_HONDA_RADARLESS = 8

  FLAG_HYUNDAI_EV_GAS = 1
  FLAG_HYUNDAI_HYBRID_GAS = 2
  FLAG_HYUNDAI_LONG = 4
  FLAG_HYUNDAI_CAMERA_SCC = 8
  FLAG_HYUNDAI_CANFD_HDA2 = 16
  FLAG_HYUNDAI_CANFD_ALT_BUTTONS = 32
  FLAG_HYUNDAI_ALT_LIMITS = 64
  FLAG_HYUNDAI_CANFD_HDA2_ALT_STEERING = 128

  FLAG_TESLA_POWERTRAIN = 1
  FLAG_TESLA_LONG_CONTROL = 2
  FLAG_TESLA_RAVEN = 4

  FLAG_VOLKSWAGEN_LONG_CONTROL = 1

  FLAG_CHRYSLER_RAM_DT = 1
  FLAG_CHRYSLER_RAM_HD = 2

  FLAG_SUBARU_GEN2 = 1
  FLAG_SUBARU_LONG = 2

  FLAG_SUBARU_PREGLOBAL_REVERSED_DRIVER_TORQUE = 1

  FLAG_NISSAN_ALT_EPS_BUS = 1

  FLAG_GM_HW_CAM = 1
  FLAG_GM_HW_CAM_LONG = 2

  FLAG_FORD_LONG_CONTROL = 1
  FLAG_FORD_CANFD = 2

  def __init__(self, serial: str | None = None, claim: bool = True, disable_checks: bool = True, can_speed_kbps: int = 500, cli: bool = True):
    self._disable_checks = disable_checks

    self._handle: BaseHandle
    self._handle_open = False
    self.can_rx_overflow_buffer = b''
    self._can_speed_kbps = can_speed_kbps

    if cli and serial is None:
        self._connect_serial = self._cli_select_panda()
    else:
        self._connect_serial = serial

    # connect and set mcu type
    self.connect(claim)

  def _cli_select_panda(self):
    dfu_pandas = PandaDFU.list()
    if len(dfu_pandas) > 0:
      print("INFO: some attached pandas are in DFU mode.")

    pandas = self.list()
    if len(pandas) == 0:
      print("INFO: panda not available")
      return None
    if len(pandas) == 1:
      print(f"INFO: connecting to panda {pandas[0]}")
      return pandas[0]
    while True:
      print("Multiple pandas available:")
      pandas.sort()
      for idx, serial in enumerate(pandas):
        print(f"{[idx]}: {serial}")
      try:
        choice = int(input("Choose serial [0]:") or "0")
        return pandas[choice]
      except (ValueError, IndexError):
        print("Enter a valid index.")

  def __enter__(self):
    return self

  def __exit__(self, *args):
    self.close()

  def close(self):
    if self._handle_open:
      self._handle.close()
      self._handle_open = False
      if self._context is not None:
        self._context.close()

  def connect(self, claim=True, wait=False):
    self.close()

    self._handle = None
    while self._handle is None:
      # try USB first, then SPI
      self._context, self._handle, serial, self.bootstub, bcd = self.usb_connect(self._connect_serial, claim=claim, no_error=wait)
      if self._handle is None:
        self._context, self._handle, serial, self.bootstub, bcd = self.spi_connect(self._connect_serial)
      if not wait:
        break

    if self._handle is None:
      raise Exception("failed to connect to panda")

    # Some fallback logic to determine panda and MCU type for old bootstubs,
    # since we now support multiple MCUs and need to know which fw to flash.
    # Three cases to consider:
    # A) oldest bootstubs don't have any way to distinguish
    #    MCU or panda type
    # B) slightly newer (~2 weeks after first C3's built) bootstubs
    #    have the panda type set in the USB bcdDevice
    # C) latest bootstubs also implement the endpoint for panda type
    self._bcd_hw_type = None
    ret = self._handle.controlRead(Panda.REQUEST_IN, 0xc1, 0, 0, 0x40)
    missing_hw_type_endpoint = self.bootstub and ret.startswith(b'\xff\x00\xc1\x3e\xde\xad\xd0\x0d')
    if missing_hw_type_endpoint and bcd is not None:
      self._bcd_hw_type = bcd

    # For case A, we assume F4 MCU type, since all H7 pandas should be case B at worst
    self._assume_f4_mcu = (self._bcd_hw_type is None) and missing_hw_type_endpoint

    self._serial = serial
    self._connect_serial = serial
    self._handle_open = True
    self._mcu_type = self.get_mcu_type()
    self.health_version, self.can_version, self.can_health_version = self.get_packets_versions()
    logger.debug("connected")

    # disable openpilot's heartbeat checks
    if self._disable_checks:
      self.set_heartbeat_disabled()
      self.set_power_save(0)

    # reset comms
    self.can_reset_communications()

    # set CAN speed
    for bus in range(PANDA_BUS_CNT):
      self.set_can_speed_kbps(bus, self._can_speed_kbps)

  @property
  def spi(self) -> bool:
    return isinstance(self._handle, PandaSpiHandle)

  @classmethod
  def spi_connect(cls, serial, ignore_version=False):
    # get UID to confirm slave is present and up
    handle = None
    spi_serial = None
    bootstub = None
    spi_version = None
    try:
      handle = PandaSpiHandle()

      # connect by protcol version
      try:
        dat = handle.get_protocol_version()
        spi_serial = binascii.hexlify(dat[:12]).decode()
        pid = dat[13]
        if pid not in (0xcc, 0xee):
          raise PandaSpiException("invalid bootstub status")
        bootstub = pid == 0xee
        spi_version = dat[14]
      except PandaSpiException:
        # fallback, we'll raise a protocol mismatch below
        dat = handle.controlRead(Panda.REQUEST_IN, 0xc3, 0, 0, 12, timeout=100)
        spi_serial = binascii.hexlify(dat).decode()
        bootstub = Panda.flasher_present(handle)
        spi_version = 0
    except PandaSpiException:
      pass

    # no connection or wrong panda
    if None in (spi_serial, bootstub) or (serial is not None and (spi_serial != serial)):
      handle = None
      spi_serial = None
      bootstub = False

    # ensure our protocol version matches the panda
    if handle is not None and not ignore_version:
      if spi_version != handle.PROTOCOL_VERSION:
        err = f"panda protocol mismatch: expected {handle.PROTOCOL_VERSION}, got {spi_version}. reflash panda"
        raise PandaProtocolMismatch(err)

    return None, handle, spi_serial, bootstub, None

  @classmethod
  def usb_connect(cls, serial, claim=True, no_error=False):
    handle, usb_serial, bootstub, bcd = None, None, None, None
    context = usb1.USBContext()
    context.open()
    try:
      for device in context.getDeviceList(skip_on_error=True):
        if device.getVendorID() == 0xbbaa and device.getProductID() in cls.USB_PIDS:
          try:
            this_serial = device.getSerialNumber()
          except Exception:
            # Allow to ignore errors on reconnect. USB hubs need some time to initialize after panda reset
            if not no_error:
              logger.exception("failed to get serial number of panda")
            continue

          if serial is None or this_serial == serial:
            logger.debug("opening device %s %s", this_serial, hex(device.getProductID()))

            usb_serial = this_serial
            bootstub = (device.getProductID() & 0xF0) == 0xe0
            handle = device.open()
            if sys.platform not in ("win32", "cygwin", "msys", "darwin"):
              handle.setAutoDetachKernelDriver(True)
            if claim:
              handle.claimInterface(0)
              # handle.setInterfaceAltSetting(0, 0)  # Issue in USB stack

            # bcdDevice wasn't always set to the hw type, ignore if it's the old constant
            this_bcd = device.getbcdDevice()
            if this_bcd is not None and this_bcd != 0x2300:
              bcd = bytearray([this_bcd >> 8, ])

            break
    except Exception:
      logger.exception("USB connect error")

    usb_handle = None
    if handle is not None:
      usb_handle = PandaUsbHandle(handle)
    else:
      context.close()

    return context, usb_handle, usb_serial, bootstub, bcd

  def is_connected_spi(self):
    return isinstance(self._handle, PandaSpiHandle)

  def is_connected_usb(self):
    return isinstance(self._handle, PandaUsbHandle)

  @classmethod
  def list(cls):
    ret = cls.usb_list()
    ret += cls.spi_list()
    return list(set(ret))

  @classmethod
  def usb_list(cls):
    ret = []
    try:
      with usb1.USBContext() as context:
        for device in context.getDeviceList(skip_on_error=True):
          if device.getVendorID() == 0xbbaa and device.getProductID() in cls.USB_PIDS:
            try:
              serial = device.getSerialNumber()
              if len(serial) == 24:
                ret.append(serial)
              else:
                logger.warning(f"found device with panda descriptors but invalid serial: {serial}", RuntimeWarning)
            except Exception:
              logger.exception("error connecting to panda")
    except Exception:
      logger.exception("exception while listing pandas")
    return ret

  @classmethod
  def spi_list(cls):
    _, _, serial, _, _ = cls.spi_connect(None, ignore_version=True)
    if serial is not None:
      return [serial, ]
    return []

  def reset(self, enter_bootstub=False, enter_bootloader=False, reconnect=True):
    # no response is expected since it resets right away
    timeout = 5000 if isinstance(self._handle, PandaSpiHandle) else 15000
    try:
      if enter_bootloader:
        self._handle.controlWrite(Panda.REQUEST_IN, 0xd1, 0, 0, b'', timeout=timeout, expect_disconnect=True)
      else:
        if enter_bootstub:
          self._handle.controlWrite(Panda.REQUEST_IN, 0xd1, 1, 0, b'', timeout=timeout, expect_disconnect=True)
        else:
          self._handle.controlWrite(Panda.REQUEST_IN, 0xd8, 0, 0, b'', timeout=timeout, expect_disconnect=True)
    except Exception:
      pass

    self.close()
    if not enter_bootloader and reconnect:
      self.reconnect()

  @property
  def connected(self) -> bool:
    return self._handle_open

  def reconnect(self):
    if self._handle_open:
      self.close()

    success = False
    # wait up to 15 seconds
    for _ in range(15*10):
      try:
        self.connect(claim=False, wait=True)
        success = True
        break
      except Exception:
        pass
      time.sleep(0.1)
    if not success:
      raise Exception("reconnect failed")

  @staticmethod
  def flasher_present(handle: BaseHandle) -> bool:
    fr = handle.controlRead(Panda.REQUEST_IN, 0xb0, 0, 0, 0xc)
    return fr[4:8] == b"\xde\xad\xd0\x0d"

  @staticmethod
  def flash_static(handle, code, mcu_type):
    assert mcu_type is not None, "must set valid mcu_type to flash"

    # confirm flasher is present
    assert Panda.flasher_present(handle)

    # determine sectors to erase
    apps_sectors_cumsum = accumulate(mcu_type.config.sector_sizes[1:])
    last_sector = next((i + 1 for i, v in enumerate(apps_sectors_cumsum) if v > len(code)), -1)
    assert last_sector >= 1, "Binary too small? No sector to erase."
    assert last_sector < 7, "Binary too large! Risk of overwriting provisioning chunk."

    # unlock flash
    logger.info("flash: unlocking")
    handle.controlWrite(Panda.REQUEST_IN, 0xb1, 0, 0, b'')

    # erase sectors
    logger.info(f"flash: erasing sectors 1 - {last_sector}")
    for i in range(1, last_sector + 1):
      handle.controlWrite(Panda.REQUEST_IN, 0xb2, i, 0, b'')

    # flash over EP2
    STEP = 0x10
    logger.info("flash: flashing")
    for i in range(0, len(code), STEP):
      handle.bulkWrite(2, code[i:i + STEP])

    # reset
    logger.info("flash: resetting")
    try:
      handle.controlWrite(Panda.REQUEST_IN, 0xd8, 0, 0, b'', expect_disconnect=True)
    except Exception:
      pass

  def flash(self, fn=None, code=None, reconnect=True):
    if self.up_to_date(fn=fn):
      logger.info("flash: already up to date")
      return

    if not fn:
      fn = os.path.join(FW_PATH, self._mcu_type.config.app_fn)
    assert os.path.isfile(fn)
    logger.debug("flash: main version is %s", self.get_version())
    if not self.bootstub:
      self.reset(enter_bootstub=True)
    assert(self.bootstub)

    if code is None:
      with open(fn, "rb") as f:
        code = f.read()

    # get version
    logger.debug("flash: bootstub version is %s", self.get_version())

    # do flash
    Panda.flash_static(self._handle, code, mcu_type=self._mcu_type)

    # reconnect
    if reconnect:
      self.reconnect()

  def recover(self, timeout: int | None = 60, reset: bool = True) -> bool:
    dfu_serial = self.get_dfu_serial()

    if reset:
      self.reset(enter_bootstub=True)
      self.reset(enter_bootloader=True)

    if not self.wait_for_dfu(dfu_serial, timeout=timeout):
      return False

    dfu = PandaDFU(dfu_serial)
    dfu.recover()

    # reflash after recover
    self.connect(True, True)
    self.flash()
    return True

  @staticmethod
  def wait_for_dfu(dfu_serial: str | None, timeout: int | None = None) -> bool:
    t_start = time.monotonic()
    dfu_list = PandaDFU.list()
    while (dfu_serial is None and len(dfu_list) == 0) or (dfu_serial is not None and dfu_serial not in dfu_list):
      logger.debug("waiting for DFU...")
      time.sleep(0.1)
      if timeout is not None and (time.monotonic() - t_start) > timeout:
        return False
      dfu_list = PandaDFU.list()
    return True

  @staticmethod
  def wait_for_panda(serial: str | None, timeout: int) -> bool:
    t_start = time.monotonic()
    serials = Panda.list()
    while (serial is None and len(serials) == 0) or (serial is not None and serial not in serials):
      logger.debug("waiting for panda...")
      time.sleep(0.1)
      if timeout is not None and (time.monotonic() - t_start) > timeout:
        return False
      serials = Panda.list()
    return True

  def up_to_date(self, fn=None) -> bool:
    current = self.get_signature()
    if fn is None:
      fn = os.path.join(FW_PATH, self.get_mcu_type().config.app_fn)
    expected = Panda.get_signature_from_firmware(fn)
    return (current == expected)

  def call_control_api(self, msg):
    self._handle.controlWrite(Panda.REQUEST_OUT, msg, 0, 0, b'')

  # ******************* health *******************

  @ensure_health_packet_version
  def health(self):
    dat = self._handle.controlRead(Panda.REQUEST_IN, 0xd2, 0, 0, self.HEALTH_STRUCT.size)
    a = self.HEALTH_STRUCT.unpack(dat)
    return {
      "uptime": a[0],
      "voltage": a[1],
      "current": a[2],
      "safety_tx_blocked": a[3],
      "safety_rx_invalid": a[4],
      "tx_buffer_overflow": a[5],
      "rx_buffer_overflow": a[6],
      "faults": a[7],
      "ignition_line": a[8],
      "ignition_can": a[9],
      "controls_allowed": a[10],
      "car_harness_status": a[11],
      "safety_mode": a[12],
      "safety_param": a[13],
      "fault_status": a[14],
      "power_save_enabled": a[15],
      "heartbeat_lost": a[16],
      "alternative_experience": a[17],
      "interrupt_load": a[18],
      "fan_power": a[19],
      "safety_rx_checks_invalid": a[20],
      "spi_checksum_error_count": a[21],
      "fan_stall_count": a[22],
      "sbu1_voltage_mV": a[23],
      "sbu2_voltage_mV": a[24],
      "som_reset_triggered": a[25],
    }

  @ensure_can_health_packet_version
  def can_health(self, can_number):
    LEC_ERROR_CODE = {
      0: "No error",
      1: "Stuff error",
      2: "Form error",
      3: "AckError",
      4: "Bit1Error",
      5: "Bit0Error",
      6: "CRCError",
      7: "NoChange",
    }
    dat = self._handle.controlRead(Panda.REQUEST_IN, 0xc2, int(can_number), 0, self.CAN_HEALTH_STRUCT.size)
    a = self.CAN_HEALTH_STRUCT.unpack(dat)
    return {
      "bus_off": a[0],
      "bus_off_cnt": a[1],
      "error_warning": a[2],
      "error_passive": a[3],
      "last_error": LEC_ERROR_CODE[a[4]],
      "last_stored_error": LEC_ERROR_CODE[a[5]],
      "last_data_error": LEC_ERROR_CODE[a[6]],
      "last_data_stored_error": LEC_ERROR_CODE[a[7]],
      "receive_error_cnt": a[8],
      "transmit_error_cnt": a[9],
      "total_error_cnt": a[10],
      "total_tx_lost_cnt": a[11],
      "total_rx_lost_cnt": a[12],
      "total_tx_cnt": a[13],
      "total_rx_cnt": a[14],
      "total_fwd_cnt": a[15],
      "total_tx_checksum_error_cnt": a[16],
      "can_speed": a[17],
      "can_data_speed": a[18],
      "canfd_enabled": a[19],
      "brs_enabled": a[20],
      "canfd_non_iso": a[21],
      "irq0_call_rate": a[22],
      "irq1_call_rate": a[23],
      "irq2_call_rate": a[24],
      "can_core_reset_count": a[25],
    }

  # ******************* control *******************

  def get_version(self):
    return self._handle.controlRead(Panda.REQUEST_IN, 0xd6, 0, 0, 0x40).decode('utf8')

  @staticmethod
  def get_signature_from_firmware(fn) -> bytes:
    with open(fn, 'rb') as f:
      f.seek(-128, 2)  # Seek from end of file
      return f.read(128)

  def get_signature(self) -> bytes:
    part_1 = self._handle.controlRead(Panda.REQUEST_IN, 0xd3, 0, 0, 0x40)
    part_2 = self._handle.controlRead(Panda.REQUEST_IN, 0xd4, 0, 0, 0x40)
    return bytes(part_1 + part_2)

  def get_type(self):
    ret = self._handle.controlRead(Panda.REQUEST_IN, 0xc1, 0, 0, 0x40)

    # old bootstubs don't implement this endpoint, see comment in Panda.device
    if self._bcd_hw_type is not None and (ret is None or len(ret) != 1):
      ret = self._bcd_hw_type

    return ret

  # Returns tuple with health packet version and CAN packet/USB packet version
  def get_packets_versions(self):
    dat = self._handle.controlRead(Panda.REQUEST_IN, 0xdd, 0, 0, 3)
    if dat and len(dat) == 3:
      a = struct.unpack("BBB", dat)
      return (a[0], a[1], a[2])
    else:
      return (0, 0, 0)

  def get_mcu_type(self) -> McuType:
    hw_type = self.get_type()
    if hw_type in Panda.F4_DEVICES:
      return McuType.F4
    elif hw_type in Panda.H7_DEVICES:
      return McuType.H7
    else:
      # have to assume F4, see comment in Panda.connect
      if self._assume_f4_mcu:
        return McuType.F4

    raise ValueError(f"unknown HW type: {hw_type}")

  def has_obd(self):
    return self.get_type() in Panda.HAS_OBD

  def is_internal(self):
    return self.get_type() in Panda.INTERNAL_DEVICES

  def get_serial(self):
    """
      Returns the comma-issued dongle ID from our provisioning
    """
    dat = self._handle.controlRead(Panda.REQUEST_IN, 0xd0, 0, 0, 0x20)
    hashsig, calc_hash = dat[0x1c:], hashlib.sha1(dat[0:0x1c]).digest()[0:4]
    assert(hashsig == calc_hash)
    return [dat[0:0x10].decode("utf8"), dat[0x10:0x10 + 10].decode("utf8")]

  def get_usb_serial(self):
    """
      Returns the serial number reported from the USB descriptor;
      matches the MCU UID
    """
    return self._serial

  def get_dfu_serial(self):
    return PandaDFU.st_serial_to_dfu_serial(self._serial, self._mcu_type)

  def get_uid(self):
    """
      Returns the UID from the MCU
    """
    dat = self._handle.controlRead(Panda.REQUEST_IN, 0xc3, 0, 0, 12)
    return binascii.hexlify(dat).decode()

  def get_secret(self):
    return self._handle.controlRead(Panda.REQUEST_IN, 0xd0, 1, 0, 0x10)

  def get_interrupt_call_rate(self, irqnum):
    dat = self._handle.controlRead(Panda.REQUEST_IN, 0xc4, int(irqnum), 0, 4)
    return struct.unpack("I", dat)[0]

  # ******************* configuration *******************

  def set_power_save(self, power_save_enabled=0):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xe7, int(power_save_enabled), 0, b'')

  def set_safety_mode(self, mode=SAFETY_SILENT, param=0):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xdc, mode, param, b'')

  def set_obd(self, obd):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xdb, int(obd), 0, b'')

  def set_can_loopback(self, enable):
    # set can loopback mode for all buses
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xe5, int(enable), 0, b'')

  def set_can_enable(self, bus_num, enable):
    # sets the can transceiver enable pin
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xf4, int(bus_num), int(enable), b'')

  def set_can_speed_kbps(self, bus, speed):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xde, bus, int(speed * 10), b'')

  def set_can_data_speed_kbps(self, bus, speed):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xf9, bus, int(speed * 10), b'')

  def set_canfd_non_iso(self, bus, non_iso):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xfc, bus, int(non_iso), b'')

  def set_uart_baud(self, uart, rate):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xe4, uart, int(rate / 300), b'')

  def set_uart_parity(self, uart, parity):
    # parity, 0=off, 1=even, 2=odd
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xe2, uart, parity, b'')

  def set_uart_callback(self, uart, install):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xe3, uart, int(install), b'')

  # ******************* can *******************

  # The panda will NAK CAN writes when there is CAN congestion.
  # libusb will try to send it again, with a max timeout.
  # Timeout is in ms. If set to 0, the timeout is infinite.
  CAN_SEND_TIMEOUT_MS = 10

  def can_reset_communications(self):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xc0, 0, 0, b'')

  @ensure_can_packet_version
  def can_send_many(self, arr, timeout=CAN_SEND_TIMEOUT_MS):
    snds = pack_can_buffer(arr)
    for tx in snds:
      while len(tx) > 0:
        bs = self._handle.bulkWrite(3, tx, timeout=timeout)
        tx = tx[bs:]

  def can_send(self, addr, dat, bus, timeout=CAN_SEND_TIMEOUT_MS):
    self.can_send_many([[addr, dat, bus]], timeout=timeout)

  @ensure_can_packet_version
  def can_recv(self):
    dat = bytearray()
    while True:
      try:
        dat = self._handle.bulkRead(1, 16384) # Max receive batch size + 2 extra reserve frames
        break
      except (usb1.USBErrorIO, usb1.USBErrorOverflow):
        logger.error("CAN: BAD RECV, RETRYING")
        time.sleep(0.1)
    msgs, self.can_rx_overflow_buffer = unpack_can_buffer(self.can_rx_overflow_buffer + dat)
    return msgs

  def can_clear(self, bus):
    """Clears all messages from the specified internal CAN ringbuffer as
    though it were drained.

    Args:
      bus (int): can bus number to clear a tx queue, or 0xFFFF to clear the
        global can rx queue.

    """
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xf1, bus, 0, b'')

  # ******************* isotp *******************

  def isotp_send(self, addr, dat, bus, recvaddr=None, subaddr=None):
    return isotp_send(self, dat, addr, bus, recvaddr, subaddr)

  def isotp_recv(self, addr, bus=0, sendaddr=None, subaddr=None):
    return isotp_recv(self, addr, bus, sendaddr, subaddr)

  # ******************* serial *******************

  def serial_read(self, port_number):
    ret = []
    while 1:
      lret = bytes(self._handle.controlRead(Panda.REQUEST_IN, 0xe0, port_number, 0, 0x40))
      if len(lret) == 0:
        break
      ret.append(lret)
    return b''.join(ret)

  def serial_write(self, port_number, ln):
    ret = 0
    if isinstance(ln, str):
      ln = bytes(ln, 'utf-8')
    for i in range(0, len(ln), 0x20):
      ret += self._handle.bulkWrite(2, struct.pack("B", port_number) + ln[i:i + 0x20])
    return ret

  def serial_clear(self, port_number):
    """Clears all messages (tx and rx) from the specified internal uart
    ringbuffer as though it were drained.

    Args:
      port_number (int): port number of the uart to clear.

    """
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xf2, port_number, 0, b'')

  def send_heartbeat(self, engaged=True):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xf3, engaged, 0, b'')

  # disable heartbeat checks for use outside of openpilot
  # sending a heartbeat will reenable the checks
  def set_heartbeat_disabled(self):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xf8, 0, 0, b'')

  # ****************** Timer *****************
  def get_microsecond_timer(self):
    dat = self._handle.controlRead(Panda.REQUEST_IN, 0xa8, 0, 0, 4)
    return struct.unpack("I", dat)[0]

  # ******************* IR *******************
  def set_ir_power(self, percentage):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xb0, int(percentage), 0, b'')

  # ******************* Fan ******************
  def set_fan_power(self, percentage):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xb1, int(percentage), 0, b'')

  def get_fan_rpm(self):
    dat = self._handle.controlRead(Panda.REQUEST_IN, 0xb2, 0, 0, 2)
    a = struct.unpack("H", dat)
    return a[0]

  # ****************** Siren *****************
  def set_siren(self, enabled):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xf6, int(enabled), 0, b'')

  # ****************** Debug *****************
  def set_green_led(self, enabled):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xf7, int(enabled), 0, b'')

  def set_clock_source_period(self, period):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xe6, period, 0, b'')

  def force_relay_drive(self, intercept_relay_drive, ignition_relay_drive):
    self._handle.controlWrite(Panda.REQUEST_OUT, 0xc5, (int(intercept_relay_drive) | int(ignition_relay_drive) << 1), 0, b'')

  def read_som_gpio(self) -> bool:
    r = self._handle.controlRead(Panda.REQUEST_IN, 0xc6, 0, 0, 1)
    return r[0] == 1