python-kasa/kasa/transports/aestransport.py

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"""Implementation of the TP-Link AES transport.
Based on the work of https://github.com/petretiandrea/plugp100
under compatible GNU GPL3 license.
"""
from __future__ import annotations
import base64
import hashlib
import logging
import time
from collections.abc import AsyncGenerator
from enum import Enum, auto
from typing import TYPE_CHECKING, Any, cast
from cryptography.hazmat.primitives import hashes, padding, serialization
from cryptography.hazmat.primitives.asymmetric import padding as asymmetric_padding
from cryptography.hazmat.primitives.asymmetric import rsa
from cryptography.hazmat.primitives.ciphers import Cipher, algorithms, modes
from yarl import URL
from kasa.credentials import DEFAULT_CREDENTIALS, Credentials, get_default_credentials
from kasa.deviceconfig import DeviceConfig
from kasa.exceptions import (
SMART_AUTHENTICATION_ERRORS,
SMART_RETRYABLE_ERRORS,
AuthenticationError,
DeviceError,
KasaException,
SmartErrorCode,
TimeoutError,
_ConnectionError,
_RetryableError,
)
from kasa.httpclient import HttpClient
from kasa.json import dumps as json_dumps
from kasa.json import loads as json_loads
from .basetransport import BaseTransport
_LOGGER = logging.getLogger(__name__)
ONE_DAY_SECONDS = 86400
SESSION_EXPIRE_BUFFER_SECONDS = 60 * 20
def _sha1(payload: bytes) -> str:
sha1_algo = hashlib.sha1() # noqa: S324
sha1_algo.update(payload)
return sha1_algo.hexdigest()
class TransportState(Enum):
"""Enum for AES state."""
HANDSHAKE_REQUIRED = auto() # Handshake needed
LOGIN_REQUIRED = auto() # Login needed
ESTABLISHED = auto() # Ready to send requests
class AesTransport(BaseTransport):
"""Implementation of the AES encryption protocol.
AES is the name used in device discovery for TP-Link's TAPO encryption
protocol, sometimes used by newer firmware versions on kasa devices.
"""
DEFAULT_PORT: int = 80
SESSION_COOKIE_NAME = "TP_SESSIONID"
TIMEOUT_COOKIE_NAME = "TIMEOUT"
COMMON_HEADERS = {
"Content-Type": "application/json",
"requestByApp": "true",
"Accept": "application/json",
}
CONTENT_LENGTH = "Content-Length"
KEY_PAIR_CONTENT_LENGTH = 314
def __init__(
self,
*,
config: DeviceConfig,
) -> None:
super().__init__(config=config)
self._login_version = config.connection_type.login_version
if (
not self._credentials or self._credentials.username is None
) and not self._credentials_hash:
self._credentials = Credentials()
if self._credentials:
self._login_params = self._get_login_params(self._credentials)
else:
self._login_params = json_loads(
base64.b64decode(self._credentials_hash.encode()).decode() # type: ignore[union-attr]
)
self._default_credentials: Credentials | None = None
self._http_client: HttpClient = HttpClient(config)
self._state = TransportState.HANDSHAKE_REQUIRED
self._encryption_session: AesEncyptionSession | None = None
self._session_expire_at: float | None = None
self._session_cookie: dict[str, str] | None = None
self._key_pair: KeyPair | None = None
if config.aes_keys:
aes_keys = config.aes_keys
self._key_pair = KeyPair.create_from_der_keys(
aes_keys["private"], aes_keys["public"]
)
self._app_url = URL(f"http://{self._host}:{self._port}/app")
self._token_url: URL | None = None
_LOGGER.debug("Created AES transport for %s", self._host)
@property
def default_port(self) -> int:
"""Default port for the transport."""
return self.DEFAULT_PORT
@property
def credentials_hash(self) -> str | None:
"""The hashed credentials used by the transport."""
if self._credentials == Credentials():
return None
return base64.b64encode(json_dumps(self._login_params).encode()).decode()
def _get_login_params(self, credentials: Credentials) -> dict[str, str]:
"""Get the login parameters based on the login_version."""
un, pw = self.hash_credentials(self._login_version == 2, credentials)
password_field_name = "password2" if self._login_version == 2 else "password"
return {password_field_name: pw, "username": un}
@staticmethod
def hash_credentials(login_v2: bool, credentials: Credentials) -> tuple[str, str]:
"""Hash the credentials."""
un = base64.b64encode(_sha1(credentials.username.encode()).encode()).decode()
if login_v2:
pw = base64.b64encode(
_sha1(credentials.password.encode()).encode()
).decode()
else:
pw = base64.b64encode(credentials.password.encode()).decode()
return un, pw
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def _handle_response_error_code(self, resp_dict: dict, msg: str) -> None:
error_code_raw = resp_dict.get("error_code")
try:
error_code = SmartErrorCode.from_int(error_code_raw)
except ValueError:
_LOGGER.warning(
"Device %s received unknown error code: %s", self._host, error_code_raw
)
error_code = SmartErrorCode.INTERNAL_UNKNOWN_ERROR
if error_code is SmartErrorCode.SUCCESS:
return
msg = f"{msg}: {self._host}: {error_code.name}({error_code.value})"
if error_code in SMART_RETRYABLE_ERRORS:
raise _RetryableError(msg, error_code=error_code)
if error_code in SMART_AUTHENTICATION_ERRORS:
self._state = TransportState.HANDSHAKE_REQUIRED
raise AuthenticationError(msg, error_code=error_code)
raise DeviceError(msg, error_code=error_code)
async def send_secure_passthrough(self, request: str) -> dict[str, Any]:
"""Send encrypted message as passthrough."""
if self._state is TransportState.ESTABLISHED and self._token_url:
url = self._token_url
else:
url = self._app_url
encrypted_payload = self._encryption_session.encrypt(request.encode()) # type: ignore
passthrough_request = {
"method": "securePassthrough",
"params": {"request": encrypted_payload.decode()},
}
status_code, resp_dict = await self._http_client.post(
url,
json=passthrough_request,
headers=self.COMMON_HEADERS,
cookies_dict=self._session_cookie,
)
# _LOGGER.debug(f"secure_passthrough response is {status_code}: {resp_dict}")
if status_code != 200:
raise KasaException(
f"{self._host} responded with an unexpected "
+ f"status code {status_code} to passthrough"
)
if TYPE_CHECKING:
resp_dict = cast(dict[str, Any], resp_dict)
assert self._encryption_session is not None
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self._handle_response_error_code(
resp_dict, "Error sending secure_passthrough message"
)
raw_response: str = resp_dict["result"]["response"]
try:
response = self._encryption_session.decrypt(raw_response.encode())
ret_val = json_loads(response)
except Exception as ex:
try:
ret_val = json_loads(raw_response)
_LOGGER.debug(
"Received unencrypted response over secure passthrough from %s",
self._host,
)
except Exception:
raise KasaException(
f"Unable to decrypt response from {self._host}, "
+ f"error: {ex}, response: {raw_response}",
ex,
) from ex
return ret_val # type: ignore[return-value]
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async def perform_login(self) -> None:
"""Login to the device."""
try:
await self.try_login(self._login_params)
_LOGGER.debug(
"%s: logged in with provided credentials",
self._host,
)
except AuthenticationError as aex:
try:
if aex.error_code is not SmartErrorCode.LOGIN_ERROR:
raise aex
_LOGGER.debug(
"%s: trying login with default TAPO credentials",
self._host,
)
if self._default_credentials is None:
self._default_credentials = get_default_credentials(
DEFAULT_CREDENTIALS["TAPO"]
)
await self.perform_handshake()
await self.try_login(self._get_login_params(self._default_credentials))
_LOGGER.debug(
"%s: logged in with default TAPO credentials",
self._host,
)
except (AuthenticationError, _ConnectionError, TimeoutError):
raise
except Exception as ex:
raise KasaException(
"Unable to login and trying default "
+ f"login raised another exception: {ex}",
ex,
) from ex
async def try_login(self, login_params: dict[str, Any]) -> None:
"""Try to login with supplied login_params."""
login_request = {
"method": "login_device",
"params": login_params,
"request_time_milis": round(time.time() * 1000),
}
request = json_dumps(login_request)
resp_dict = await self.send_secure_passthrough(request)
self._handle_response_error_code(resp_dict, "Error logging in")
login_token = resp_dict["result"]["token"]
self._token_url = self._app_url.with_query(f"token={login_token}")
self._state = TransportState.ESTABLISHED
async def _generate_key_pair_payload(self) -> AsyncGenerator:
"""Generate the request body and return an ascyn_generator.
This prevents the key pair being generated unless a connection
can be made to the device.
"""
_LOGGER.debug("Generating keypair")
if not self._key_pair:
kp = KeyPair.create_key_pair()
self._config.aes_keys = {
"private": kp.private_key_der_b64,
"public": kp.public_key_der_b64,
}
self._key_pair = kp
pub_key = (
"-----BEGIN PUBLIC KEY-----\n"
+ self._key_pair.public_key_der_b64 # type: ignore[union-attr]
+ "\n-----END PUBLIC KEY-----\n"
)
handshake_params = {"key": pub_key}
request_body = {"method": "handshake", "params": handshake_params}
_LOGGER.debug("Handshake request: %s", request_body)
yield json_dumps(request_body).encode()
async def perform_handshake(self) -> None:
"""Perform the handshake."""
_LOGGER.debug("Will perform handshaking...")
self._token_url = None
self._session_expire_at = None
self._session_cookie = None
# Device needs the content length or it will response with 500
headers = {
**self.COMMON_HEADERS,
self.CONTENT_LENGTH: str(self.KEY_PAIR_CONTENT_LENGTH),
}
http_client = self._http_client
status_code, resp_dict = await http_client.post(
self._app_url,
json=self._generate_key_pair_payload(),
headers=headers,
cookies_dict=self._session_cookie,
)
_LOGGER.debug("Device responded with: %s", resp_dict)
if status_code != 200:
raise KasaException(
f"{self._host} responded with an unexpected "
+ f"status code {status_code} to handshake"
)
if TYPE_CHECKING:
resp_dict = cast(dict[str, Any], resp_dict)
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self._handle_response_error_code(resp_dict, "Unable to complete handshake")
handshake_key = resp_dict["result"]["key"]
if (
cookie := http_client.get_cookie(self.SESSION_COOKIE_NAME) # type: ignore
) or (
cookie := http_client.get_cookie("SESSIONID") # type: ignore
):
self._session_cookie = {self.SESSION_COOKIE_NAME: cookie}
timeout = int(
http_client.get_cookie(self.TIMEOUT_COOKIE_NAME) or ONE_DAY_SECONDS
)
# There is a 24 hour timeout on the session cookie
# but the clock on the device is not always accurate
# so we set the expiry to 24 hours from now minus a buffer
self._session_expire_at = time.time() + timeout - SESSION_EXPIRE_BUFFER_SECONDS
if TYPE_CHECKING:
assert self._key_pair is not None
self._encryption_session = AesEncyptionSession.create_from_keypair(
handshake_key, self._key_pair
)
self._state = TransportState.LOGIN_REQUIRED
_LOGGER.debug("Handshake with %s complete", self._host)
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def _handshake_session_expired(self) -> bool:
"""Return true if session has expired."""
return (
self._session_expire_at is None
or self._session_expire_at - time.time() <= 0
)
async def send(self, request: str) -> dict[str, Any]:
"""Send the request."""
if (
self._state is TransportState.HANDSHAKE_REQUIRED
or self._handshake_session_expired()
):
await self.perform_handshake()
if self._state is not TransportState.ESTABLISHED:
try:
await self.perform_login()
# After a login failure handshake needs to
# be redone or a 9999 error is received.
except AuthenticationError as ex:
self._state = TransportState.HANDSHAKE_REQUIRED
raise ex
return await self.send_secure_passthrough(request)
async def close(self) -> None:
"""Close the http client and reset internal state."""
await self.reset()
await self._http_client.close()
async def reset(self) -> None:
"""Reset internal handshake and login state."""
self._state = TransportState.HANDSHAKE_REQUIRED
class AesEncyptionSession:
"""Class for an AES encryption session."""
@staticmethod
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def create_from_keypair(
handshake_key: str, keypair: KeyPair
) -> AesEncyptionSession:
"""Create the encryption session."""
handshake_key_bytes: bytes = base64.b64decode(handshake_key.encode())
key_and_iv = keypair.decrypt_handshake_key(handshake_key_bytes)
if key_and_iv is None:
raise ValueError("Decryption failed!")
return AesEncyptionSession(key_and_iv[:16], key_and_iv[16:])
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def __init__(self, key: bytes, iv: bytes) -> None:
self.cipher = Cipher(algorithms.AES(key), modes.CBC(iv))
self.padding_strategy = padding.PKCS7(algorithms.AES.block_size)
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def encrypt(self, data: bytes) -> bytes:
"""Encrypt the message."""
encryptor = self.cipher.encryptor()
padder = self.padding_strategy.padder()
padded_data = padder.update(data) + padder.finalize()
encrypted = encryptor.update(padded_data) + encryptor.finalize()
return base64.b64encode(encrypted)
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def decrypt(self, data: str | bytes) -> str:
"""Decrypt the message."""
decryptor = self.cipher.decryptor()
unpadder = self.padding_strategy.unpadder()
decrypted = decryptor.update(base64.b64decode(data)) + decryptor.finalize()
unpadded_data = unpadder.update(decrypted) + unpadder.finalize()
return unpadded_data.decode()
class KeyPair:
"""Class for generating key pairs."""
@staticmethod
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def create_key_pair(key_size: int = 1024) -> KeyPair:
"""Create a key pair."""
private_key = rsa.generate_private_key(public_exponent=65537, key_size=key_size)
public_key = private_key.public_key()
return KeyPair(private_key, public_key)
@staticmethod
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def create_from_der_keys(
private_key_der_b64: str, public_key_der_b64: str
) -> KeyPair:
"""Create a key pair."""
key_bytes = base64.b64decode(private_key_der_b64.encode())
private_key = cast(
rsa.RSAPrivateKey, serialization.load_der_private_key(key_bytes, None)
)
key_bytes = base64.b64decode(public_key_der_b64.encode())
public_key = cast(
rsa.RSAPublicKey, serialization.load_der_public_key(key_bytes, None)
)
return KeyPair(private_key, public_key)
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def __init__(
self, private_key: rsa.RSAPrivateKey, public_key: rsa.RSAPublicKey
) -> None:
self.private_key = private_key
self.public_key = public_key
self.private_key_der_bytes = self.private_key.private_bytes(
encoding=serialization.Encoding.DER,
format=serialization.PrivateFormat.PKCS8,
encryption_algorithm=serialization.NoEncryption(),
)
self.public_key_der_bytes = self.public_key.public_bytes(
encoding=serialization.Encoding.DER,
format=serialization.PublicFormat.SubjectPublicKeyInfo,
)
self.private_key_der_b64 = base64.b64encode(self.private_key_der_bytes).decode()
self.public_key_der_b64 = base64.b64encode(self.public_key_der_bytes).decode()
def get_public_pem(self) -> bytes:
"""Get public key in PEM encoding."""
return self.public_key.public_bytes(
encoding=serialization.Encoding.PEM,
format=serialization.PublicFormat.SubjectPublicKeyInfo,
)
def decrypt_handshake_key(self, encrypted_key: bytes) -> bytes:
"""Decrypt an aes handshake key."""
decrypted = self.private_key.decrypt(
encrypted_key, asymmetric_padding.PKCS1v15()
)
return decrypted
def decrypt_discovery_key(self, encrypted_key: bytes) -> bytes:
"""Decrypt an aes discovery key."""
decrypted = self.private_key.decrypt(
encrypted_key,
asymmetric_padding.OAEP(
mgf=asymmetric_padding.MGF1(algorithm=hashes.SHA1()), # noqa: S303
algorithm=hashes.SHA1(), # noqa: S303
label=None,
),
)
return decrypted