"""Support for climate control.""" from typing import List from .device import device from .exceptions import check_error from .helpers import calculate_crc16 class hysen(device): """Controls a Hysen HVAC.""" TYPE = "Hysen heating controller" # Send a request # input_payload should be a bytearray, usually 6 bytes, e.g. bytearray([0x01,0x06,0x00,0x02,0x10,0x00]) # Returns decrypted payload # New behaviour: raises a ValueError if the device response indicates an error or CRC check fails # The function prepends length (2 bytes) and appends CRC def send_request(self, input_payload: bytes) -> bytes: """Send a request to the device.""" crc = calculate_crc16(input_payload) # first byte is length, +2 for CRC16 request_payload = bytearray([len(input_payload) + 2, 0x00]) request_payload.extend(input_payload) # append CRC request_payload.append(crc & 0xFF) request_payload.append((crc >> 8) & 0xFF) # send to device response = self.send_packet(0x6A, request_payload) check_error(response[0x22:0x24]) response_payload = self.decrypt(response[0x38:]) # experimental check on CRC in response (first 2 bytes are len, and trailing bytes are crc) response_payload_len = response_payload[0] if response_payload_len + 2 > len(response_payload): raise ValueError( "hysen_response_error", "first byte of response is not length" ) crc = calculate_crc16(response_payload[2:response_payload_len]) if (response_payload[response_payload_len] == crc & 0xFF) and ( response_payload[response_payload_len + 1] == (crc >> 8) & 0xFF ): return response_payload[2:response_payload_len] raise ValueError("hysen_response_error", "CRC check on response failed") def get_temp(self) -> int: """Return the room temperature in degrees celsius.""" payload = self.send_request(bytearray([0x01, 0x03, 0x00, 0x00, 0x00, 0x08])) return payload[0x05] / 2.0 def get_external_temp(self) -> int: """Return the external temperature in degrees celsius.""" payload = self.send_request(bytearray([0x01, 0x03, 0x00, 0x00, 0x00, 0x08])) return payload[18] / 2.0 def get_full_status(self) -> dict: """Return the state of the device. Timer schedule included. """ payload = self.send_request(bytearray([0x01, 0x03, 0x00, 0x00, 0x00, 0x16])) data = {} data["remote_lock"] = payload[3] & 1 data["power"] = payload[4] & 1 data["active"] = (payload[4] >> 4) & 1 data["temp_manual"] = (payload[4] >> 6) & 1 data["room_temp"] = (payload[5] & 255) / 2.0 data["thermostat_temp"] = (payload[6] & 255) / 2.0 data["auto_mode"] = payload[7] & 15 data["loop_mode"] = (payload[7] >> 4) & 15 data["sensor"] = payload[8] data["osv"] = payload[9] data["dif"] = payload[10] data["svh"] = payload[11] data["svl"] = payload[12] data["room_temp_adj"] = ((payload[13] << 8) + payload[14]) / 2.0 if data["room_temp_adj"] > 32767: data["room_temp_adj"] = 32767 - data["room_temp_adj"] data["fre"] = payload[15] data["poweron"] = payload[16] data["unknown"] = payload[17] data["external_temp"] = (payload[18] & 255) / 2.0 data["hour"] = payload[19] data["min"] = payload[20] data["sec"] = payload[21] data["dayofweek"] = payload[22] weekday = [] for i in range(0, 6): weekday.append( { "start_hour": payload[2 * i + 23], "start_minute": payload[2 * i + 24], "temp": payload[i + 39] / 2.0, } ) data["weekday"] = weekday weekend = [] for i in range(6, 8): weekend.append( { "start_hour": payload[2 * i + 23], "start_minute": payload[2 * i + 24], "temp": payload[i + 39] / 2.0, } ) data["weekend"] = weekend return data # Change controller mode # auto_mode = 1 for auto (scheduled/timed) mode, 0 for manual mode. # Manual mode will activate last used temperature. # In typical usage call set_temp to activate manual control and set temp. # loop_mode refers to index in [ "12345,67", "123456,7", "1234567" ] # E.g. loop_mode = 0 ("12345,67") means Saturday and Sunday follow the "weekend" schedule # loop_mode = 2 ("1234567") means every day (including Saturday and Sunday) follows the "weekday" schedule # The sensor command is currently experimental def set_mode(self, auto_mode: int, loop_mode: int, sensor: int = 0) -> None: """Set the mode of the device.""" mode_byte = ((loop_mode + 1) << 4) + auto_mode self.send_request(bytearray([0x01, 0x06, 0x00, 0x02, mode_byte, sensor])) # Advanced settings # Sensor mode (SEN) sensor = 0 for internal sensor, 1 for external sensor, # 2 for internal control temperature, external limit temperature. Factory default: 0. # Set temperature range for external sensor (OSV) osv = 5..99. Factory default: 42C # Deadzone for floor temprature (dIF) dif = 1..9. Factory default: 2C # Upper temperature limit for internal sensor (SVH) svh = 5..99. Factory default: 35C # Lower temperature limit for internal sensor (SVL) svl = 5..99. Factory default: 5C # Actual temperature calibration (AdJ) adj = -0.5. Prescision 0.1C # Anti-freezing function (FrE) fre = 0 for anti-freezing function shut down, # 1 for anti-freezing function open. Factory default: 0 # Power on memory (POn) poweron = 0 for power on memory off, 1 for power on memory on. Factory default: 0 def set_advanced( self, loop_mode: int, sensor: int, osv: int, dif: int, svh: int, svl: int, adj: float, fre: int, poweron: int, ) -> None: """Set advanced options.""" input_payload = bytearray( [ 0x01, 0x10, 0x00, 0x02, 0x00, 0x05, 0x0A, loop_mode, sensor, osv, dif, svh, svl, (int(adj * 2) >> 8 & 0xFF), (int(adj * 2) & 0xFF), fre, poweron, ] ) self.send_request(input_payload) # For backwards compatibility only. Prefer calling set_mode directly. # Note this function invokes loop_mode=0 and sensor=0. def switch_to_auto(self) -> None: """Switch mode to auto.""" self.set_mode(auto_mode=1, loop_mode=0) def switch_to_manual(self) -> None: """Switch mode to manual.""" self.set_mode(auto_mode=0, loop_mode=0) # Set temperature for manual mode (also activates manual mode if currently in automatic) def set_temp(self, temp: float) -> None: """Set the target temperature.""" self.send_request(bytearray([0x01, 0x06, 0x00, 0x01, 0x00, int(temp * 2)])) # Set device on(1) or off(0), does not deactivate Wifi connectivity. # Remote lock disables control by buttons on thermostat. def set_power(self, power: int = 1, remote_lock: int = 0) -> None: """Set the power state of the device.""" self.send_request(bytearray([0x01, 0x06, 0x00, 0x00, remote_lock, power])) # set time on device # n.b. day=1 is Monday, ..., day=7 is Sunday def set_time(self, hour: int, minute: int, second: int, day: int) -> None: """Set the time.""" self.send_request( bytearray( [0x01, 0x10, 0x00, 0x08, 0x00, 0x02, 0x04, hour, minute, second, day] ) ) # Set timer schedule # Format is the same as you get from get_full_status. # weekday is a list (ordered) of 6 dicts like: # {'start_hour':17, 'start_minute':30, 'temp': 22 } # Each one specifies the thermostat temp that will become effective at start_hour:start_minute # weekend is similar but only has 2 (e.g. switch on in morning and off in afternoon) def set_schedule(self, weekday: List[dict], weekend: List[dict]) -> None: """Set timer schedule.""" # Begin with some magic values ... input_payload = bytearray([0x01, 0x10, 0x00, 0x0A, 0x00, 0x0C, 0x18]) # Now simply append times/temps # weekday times for i in range(0, 6): input_payload.append(weekday[i]["start_hour"]) input_payload.append(weekday[i]["start_minute"]) # weekend times for i in range(0, 2): input_payload.append(weekend[i]["start_hour"]) input_payload.append(weekend[i]["start_minute"]) # weekday temperatures for i in range(0, 6): input_payload.append(int(weekday[i]["temp"] * 2)) # weekend temperatures for i in range(0, 2): input_payload.append(int(weekend[i]["temp"] * 2)) self.send_request(input_payload)