)
from types import SimpleNamespace
+from .protomodule import ProtoClass
+
__all__ = (
"Stream",
"class_by_prefix",
"enframe",
+ "exposed_protos",
"inline_response",
"proto_handled",
"parse_message",
"proto_name",
"DecodeError",
"Respond",
- "LK",
)
PROTO_PREFIX = "BS:"
return x
-class MetaPkt(type):
- """
- For each class corresponding to a message, automatically create
- two nested classes `In` and `Out` that also inherit from their
- "nest". Class attribute `IN_KWARGS` defined in the "nest" is
- copied to the `In` nested class under the name `KWARGS`, and
- likewise, `OUT_KWARGS` of the nest class is copied as `KWARGS`
- to the nested class `Out`. In addition, method `encode` is
- defined in both classes equal to `in_encode()` and `out_encode()`
- respectively.
- """
+def l3str(x: Union[str, List[str]]) -> List[str]:
+ if isinstance(x, str):
+ lx = x.split(",")
+ else:
+ lx = x
+ if len(lx) != 3 or not all(isinstance(el, str) for el in x):
+ raise ValueError(str(lx) + " is not a list of three strings")
+ return lx
- if TYPE_CHECKING:
- def __getattr__(self, name: str) -> Any:
- pass
+def pblist(x: Union[str, List[Tuple[str, str]]]) -> List[Tuple[str, str]]:
+ if isinstance(x, str):
- def __setattr__(self, name: str, value: Any) -> None:
- pass
+ def splitpair(s: str) -> Tuple[str, str]:
+ a, b = s.split(":")
+ return a, b
- def __new__(
- cls: Type["MetaPkt"],
- name: str,
- bases: Tuple[type, ...],
- attrs: Dict[str, Any],
- ) -> "MetaPkt":
- newcls = super().__new__(cls, name, bases, attrs)
- newcls.In = super().__new__(
- cls,
- name + ".In",
- (newcls,) + bases,
- {
- "KWARGS": newcls.IN_KWARGS,
- "decode": newcls.in_decode,
- "encode": newcls.in_encode,
- },
- )
- newcls.Out = super().__new__(
- cls,
- name + ".Out",
- (newcls,) + bases,
- {
- "KWARGS": newcls.OUT_KWARGS,
- "decode": newcls.out_decode,
- "encode": newcls.out_encode,
- },
- )
- return newcls
+ lx = [splitpair(el) for el in x.split(",")]
+ else:
+ lx = x
+ if len(lx) > 5:
+ raise ValueError(str(lx) + " has too many elements (max 5)")
+ return lx
class Respond(Enum):
EXT = 2 # Birirectional, use external responder
-class BeeSurePkt(metaclass=MetaPkt):
+class BeeSurePkt(ProtoClass):
RESPOND = Respond.NON # Do not send anything back by default
- PROTO: str
IN_KWARGS: Tuple[Tuple[str, Callable[[Any], Any], Any], ...] = ()
OUT_KWARGS: Tuple[Tuple[str, Callable[[Any], Any], Any], ...] = ()
KWARGS: Tuple[Tuple[str, Callable[[Any], Any], Any], ...] = ()
Construct the object _either_ from (length, payload),
_or_ from the values of individual fields
"""
+ self.payload: Union[List[str], bytes]
assert not args or (len(args) == 4 and not kwargs)
if args: # guaranteed to be two arguments at this point
self.vendor, self.imei, self.datalength, self.payload = args
try:
- self.decode(*self.payload)
+ if isinstance(self.payload, list):
+ self.decode(*self.payload)
+ else:
+ self.decode(self.payload)
except error as e:
raise DecodeError(e, obj=self)
else:
),
)
- def decode(self, *args: str) -> None:
+ def decode(self, *args: Any) -> None:
...
def in_decode(self, *args: str) -> None:
def out_encode(self) -> str:
# Overridden in subclasses, otherwise command verb only
- return self.PROTO
+ return ""
+
+ @property
+ def PROTO(self) -> str:
+ try:
+ proto, _ = self.__class__.__name__.split(".")
+ except ValueError:
+ proto = self.__class__.__name__
+ return proto
@property
def packed(self) -> bytes:
- buffer = self.encode().encode()
- return f"[LT*0000000000*{len(buffer):04X}*".encode() + buffer + b"]"
+ data = self.encode()
+ payload = self.PROTO + "," + data if data else self.PROTO
+ return f"[LT*0000000000*{len(payload):04X}*{payload}]".encode()
class UNKNOWN(BeeSurePkt):
- PROTO = "UNKNOWN"
-
-
-class LK(BeeSurePkt):
- PROTO = "LK"
- RESPOND = Respond.INL
-
- def in_decode(self, *args: str) -> None:
- numargs = len(args)
- if numargs > 1:
- self.step = args[1]
- if numargs > 2:
- self.tumbling_number = args[2]
- if numargs > 3:
- self.battery_percentage = args[3]
-
- def in_encode(self) -> str:
- return "LK"
-
-
-class CONFIG(BeeSurePkt):
- PROTO = "CONFIG"
-
-
-class ICCID(BeeSurePkt):
- PROTO = "ICCID"
+ pass
class _LOC_DATA(BeeSurePkt):
_id = lambda x: x
for (obj, attr, func), val in zip(
(
- (p, "verb", _id),
(p, "date", _id),
(p, "time", _id),
(self, "gps_valid", lambda x: x == "A"),
(self, "mcc", int),
(self, "mnc", int),
),
- args[:21],
+ args[:20],
):
setattr(obj, attr, func(val)) # type: ignore
- rest_args = args[21:]
+ rest_args = args[20:]
# (area_id, cell_id, strength)*
self.base_stations = [
tuple(int(el) for el in rest_args[i * 3 : 3 + i * 3])
self.latitude = p.lat * p.nors
self.longitude = p.lon * p.eorw
+ def rectified(self) -> Dict[str, Any]: # JSON-able dict
+ if self.gps_valid:
+ return {
+ "type": "location",
+ "devtime": str(self.devtime),
+ "battery_percentage": self.battery_percentage,
+ "accuracy": self.positioning_accuracy,
+ "altitude": self.altitude,
+ "speed": self.speed,
+ "direction": self.direction,
+ "latitude": self.latitude,
+ "longitude": self.longitude,
+ }
+ else:
+ return {
+ "type": "approximate_location",
+ "devtime": str(self.devtime),
+ "battery_percentage": self.battery_percentage,
+ "mcc": self.mcc,
+ "mnc": self.mnc,
+ "base_stations": self.base_stations,
+ "wifi_aps": self.wifi_aps,
+ }
+
-class UD(_LOC_DATA):
- PROTO = "UD"
+class AL(_LOC_DATA):
+ RESPOND = Respond.INL
-class UD2(_LOC_DATA):
- PROTO = "UD2"
+class CONFIG(BeeSurePkt):
+ pass
+
+
+class CR(BeeSurePkt):
+ pass
+
+
+class FLOWER(BeeSurePkt):
+ OUT_KWARGS = (("number", int, 1),)
+
+ def out_encode(self) -> str:
+ self.number: int
+ return str(self.number)
+
+
+class ICCID(BeeSurePkt):
+ pass
+
+
+class LK(BeeSurePkt):
+ RESPOND = Respond.INL
+
+ def in_decode(self, *args: str) -> None:
+ numargs = len(args)
+ if numargs > 0:
+ self.step = args[0]
+ if numargs > 1:
+ self.tumbling_number = args[1]
+ if numargs > 2:
+ self.battery_percentage = args[2]
+
+ def in_encode(self) -> str:
+ return "LK"
+
+
+class MESSAGE(BeeSurePkt):
+ OUT_KWARGS = (("message", str, ""),)
+
+ def out_encode(self) -> str:
+ return str(self.message.encode("utf_16_be").hex())
+
+
+class _PHB(BeeSurePkt):
+ OUT_KWARGS: Tuple[Tuple[str, Callable[[Any], Any], Any], ...] = (
+ ("entries", pblist, []),
+ )
+
+ def out_encode(self) -> str:
+ self.entries: List[Tuple[str, str]]
+ return ",".join(
+ [
+ ",".join((num, name.encode("utf_16_be").hex()))
+ for name, num in self.entries
+ ]
+ )
+
+
+class PHB(_PHB):
+ pass
+
+
+class PHB2(_PHB):
+ pass
+
+
+class POWEROFF(BeeSurePkt):
+ pass
+
+
+class RESET(BeeSurePkt):
+ pass
+
+
+class SOS(BeeSurePkt):
+ OUT_KWARGS = (("phonenumbers", l3str, ["", "", ""]),)
+
+ def out_encode(self) -> str:
+ self.phonenumbers: List[str]
+ return ",".join(self.phonenumbers)
+
+
+class _SET_PHONE(BeeSurePkt):
+ OUT_KWARGS = (("phonenumber", str, ""),)
+
+ def out_encode(self) -> str:
+ self.phonenumber: str
+ return self.phonenumber
+
+
+class SOS1(_SET_PHONE):
+ pass
+
+
+class SOS2(_SET_PHONE):
+ pass
+
+
+class SOS3(_SET_PHONE):
+ pass
+
+
+class TK(BeeSurePkt):
+ RESPOND = Respond.INL
+
+ def in_decode(self, *args: Any) -> None:
+ assert len(args) == 1 and isinstance(args[0], bytes)
+ self.amr_data = (
+ args[0]
+ .replace(b"}*", b"*")
+ .replace(b"},", b",")
+ .replace(b"}[", b"[")
+ .replace(b"}]", b"]")
+ .replace(b"}}", b"}")
+ )
+
+ def out_encode(self) -> str:
+ return "1" # 0 - receive failure, 1 - receive success
class TKQ(BeeSurePkt):
- PROTO = "TKQ"
RESPOND = Respond.INL
class TKQ2(BeeSurePkt):
- PROTO = "TKQ2"
RESPOND = Respond.INL
-class AL(_LOC_DATA):
- PROTO = "AL"
- RESPOND = Respond.INL
+class UD(_LOC_DATA):
+ pass
+
+
+class UD2(_LOC_DATA):
+ pass
# Build dicts protocol number -> class and class name -> protocol number
CLASSES = {}
-PROTOS = {}
if True: # just to indent the code, sorry!
for cls in [
cls
and issubclass(cls, BeeSurePkt)
and not name.startswith("_")
]:
- if hasattr(cls, "PROTO"):
- CLASSES[cls.PROTO] = cls
- PROTOS[cls.__name__] = cls.PROTO
+ CLASSES[cls.__name__] = cls
def class_by_prefix(
prefix: str,
-) -> Union[Type[BeeSurePkt], List[Tuple[str, str]]]:
- lst = [
- (name, proto)
- for name, proto in PROTOS.items()
- if name.upper().startswith(prefix.upper())
- ]
- if len(lst) != 1:
- return lst
- _, proto = lst[0]
- return CLASSES[proto]
+) -> Union[Type[BeeSurePkt], List[str]]:
+ if prefix.startswith(PROTO_PREFIX):
+ pname = prefix[len(PROTO_PREFIX) :].upper()
+ else:
+ raise KeyError(pname)
+ lst = [name for name in CLASSES.keys() if name.upper().startswith(pname)]
+ for proto in lst:
+ if len(lst) == 1: # unique prefix match
+ return CLASSES[proto]
+ if proto == pname: # exact match
+ return CLASSES[proto]
+ return lst
def proto_handled(proto: str) -> bool:
return proto.startswith(PROTO_PREFIX)
-def proto_name(obj: Union[MetaPkt, BeeSurePkt]) -> str:
+def proto_name(obj: Union[Type[BeeSurePkt], BeeSurePkt]) -> str:
return PROTO_PREFIX + (
obj.__class__.__name__ if isinstance(obj, BeeSurePkt) else obj.__name__
)
def parse_message(packet: bytes, is_incoming: bool = True) -> BeeSurePkt:
"""From a packet (without framing bytes) derive the XXX.In object"""
toskip, vendor, imei, datalength = _framestart(packet)
- payload = packet[20:-1].decode().split(",")
- proto = payload[0] if len(payload) > 0 else ""
+ try:
+ splits = packet[20:-1].decode().split(",")
+ proto = splits[0] if len(splits) > 0 else ""
+ payload: Union[List[str], bytes] = splits[1:]
+ except UnicodeDecodeError:
+ bsplits = packet[20:-1].split(b",", 1)
+ if len(bsplits) == 2:
+ proto = bsplits[0].decode("ascii")
+ payload = bsplits[1]
if proto not in CLASSES:
cause: Union[DecodeError, ValueError, IndexError] = ValueError(
f"Proto {proto} is unknown"
retobj = UNKNOWN.In(vendor, imei, datalength, payload)
else:
retobj = UNKNOWN.Out(vendor, imei, datalength, payload)
- retobj.PROTO = proto # Override class attr with object attr
+ retobj.proto = proto # Override class attr with object attr
retobj.cause = cause
return retobj
+
+
+def exposed_protos() -> List[Tuple[str, bool]]:
+ return [
+ (proto_name(cls), False)
+ for cls in CLASSES.values()
+ if hasattr(cls, "rectified")
+ ]