import esphome.codegen as cg import esphome.config_validation as cv from esphome import automation from esphome.components import binary_sensor from esphome.const import ( CONF_DATA, CONF_TRIGGER_ID, CONF_NBITS, CONF_ADDRESS, CONF_COMMAND, CONF_CODE, CONF_PULSE_LENGTH, CONF_SYNC, CONF_ZERO, CONF_ONE, CONF_INVERTED, CONF_PROTOCOL, CONF_GROUP, CONF_DEVICE, CONF_STATE, CONF_CHANNEL, CONF_FAMILY, CONF_REPEAT, CONF_WAIT_TIME, CONF_TIMES, CONF_TYPE_ID, CONF_CARRIER_FREQUENCY, CONF_RC_CODE_1, CONF_RC_CODE_2, ) from esphome.core import coroutine from esphome.jsonschema import jschema_extractor from esphome.util import Registry, SimpleRegistry AUTO_LOAD = ["binary_sensor"] CONF_RECEIVER_ID = "receiver_id" CONF_TRANSMITTER_ID = "transmitter_id" ns = remote_base_ns = cg.esphome_ns.namespace("remote_base") RemoteProtocol = ns.class_("RemoteProtocol") RemoteReceiverListener = ns.class_("RemoteReceiverListener") RemoteReceiverBinarySensorBase = ns.class_( "RemoteReceiverBinarySensorBase", binary_sensor.BinarySensor, cg.Component ) RemoteReceiverTrigger = ns.class_( "RemoteReceiverTrigger", automation.Trigger, RemoteReceiverListener ) RemoteTransmitterDumper = ns.class_("RemoteTransmitterDumper") RemoteTransmitterActionBase = ns.class_( "RemoteTransmitterActionBase", automation.Action ) RemoteReceiverBase = ns.class_("RemoteReceiverBase") RemoteTransmitterBase = ns.class_("RemoteTransmitterBase") def templatize(value): if isinstance(value, cv.Schema): value = value.schema ret = {} for key, val in value.items(): ret[key] = cv.templatable(val) return cv.Schema(ret) async def register_listener(var, config): receiver = await cg.get_variable(config[CONF_RECEIVER_ID]) cg.add(receiver.register_listener(var)) def register_binary_sensor(name, type, schema): return BINARY_SENSOR_REGISTRY.register(name, type, schema) def register_trigger(name, type, data_type): validator = automation.validate_automation( { cv.GenerateID(CONF_TRIGGER_ID): cv.declare_id(type), cv.GenerateID(CONF_RECEIVER_ID): cv.use_id(RemoteReceiverBase), } ) registerer = TRIGGER_REGISTRY.register(f"on_{name}", validator) def decorator(func): async def new_func(config): var = cg.new_Pvariable(config[CONF_TRIGGER_ID]) await register_listener(var, config) await coroutine(func)(var, config) await automation.build_automation(var, [(data_type, "x")], config) return var return registerer(new_func) return decorator def register_dumper(name, type): registerer = DUMPER_REGISTRY.register(name, type, {}) def decorator(func): async def new_func(config, dumper_id): var = cg.new_Pvariable(dumper_id) await coroutine(func)(var, config) return var return registerer(new_func) return decorator def validate_repeat(value): if isinstance(value, dict): return cv.Schema( { cv.Required(CONF_TIMES): cv.templatable(cv.positive_int), cv.Optional(CONF_WAIT_TIME, default="25ms"): cv.templatable( cv.positive_time_period_microseconds ), } )(value) return validate_repeat({CONF_TIMES: value}) BASE_REMOTE_TRANSMITTER_SCHEMA = cv.Schema( { cv.GenerateID(CONF_TRANSMITTER_ID): cv.use_id(RemoteTransmitterBase), cv.Optional(CONF_REPEAT): validate_repeat, } ) def register_action(name, type_, schema): validator = templatize(schema).extend(BASE_REMOTE_TRANSMITTER_SCHEMA) registerer = automation.register_action( f"remote_transmitter.transmit_{name}", type_, validator ) def decorator(func): async def new_func(config, action_id, template_arg, args): transmitter = await cg.get_variable(config[CONF_TRANSMITTER_ID]) var = cg.new_Pvariable(action_id, template_arg) cg.add(var.set_parent(transmitter)) if CONF_REPEAT in config: conf = config[CONF_REPEAT] template_ = await cg.templatable(conf[CONF_TIMES], args, cg.uint32) cg.add(var.set_send_times(template_)) template_ = await cg.templatable(conf[CONF_WAIT_TIME], args, cg.uint32) cg.add(var.set_send_wait(template_)) await coroutine(func)(var, config, args) return var return registerer(new_func) return decorator def declare_protocol(name): data = ns.struct(f"{name}Data") binary_sensor_ = ns.class_(f"{name}BinarySensor", RemoteReceiverBinarySensorBase) trigger = ns.class_(f"{name}Trigger", RemoteReceiverTrigger) action = ns.class_(f"{name}Action", RemoteTransmitterActionBase) dumper = ns.class_(f"{name}Dumper", RemoteTransmitterDumper) return data, binary_sensor_, trigger, action, dumper BINARY_SENSOR_REGISTRY = Registry( binary_sensor.BINARY_SENSOR_SCHEMA.extend( { cv.GenerateID(CONF_RECEIVER_ID): cv.use_id(RemoteReceiverBase), } ) ) validate_binary_sensor = cv.validate_registry_entry( "remote receiver", BINARY_SENSOR_REGISTRY ) TRIGGER_REGISTRY = SimpleRegistry() DUMPER_REGISTRY = Registry( { cv.Optional(CONF_RECEIVER_ID): cv.invalid( "This has been removed in ESPHome 1.20.0 and the dumper attaches directly to the parent receiver." ), } ) def validate_dumpers(value): if isinstance(value, str) and value.lower() == "all": return validate_dumpers(list(DUMPER_REGISTRY.keys())) return cv.validate_registry("dumper", DUMPER_REGISTRY)(value) def validate_triggers(base_schema): assert isinstance(base_schema, cv.Schema) @jschema_extractor("triggers") def validator(config): added_keys = {} for key, (_, valid) in TRIGGER_REGISTRY.items(): added_keys[cv.Optional(key)] = valid new_schema = base_schema.extend(added_keys) # pylint: disable=comparison-with-callable if config == jschema_extractor: return new_schema return new_schema(config) return validator async def build_binary_sensor(full_config): registry_entry, config = cg.extract_registry_entry_config( BINARY_SENSOR_REGISTRY, full_config ) type_id = full_config[CONF_TYPE_ID] builder = registry_entry.coroutine_fun var = cg.new_Pvariable(type_id) await cg.register_component(var, full_config) await register_listener(var, full_config) await builder(var, config) return var async def build_triggers(full_config): for key in TRIGGER_REGISTRY: for config in full_config.get(key, []): func = TRIGGER_REGISTRY[key][0] await func(config) async def build_dumpers(config): dumpers = [] for conf in config: dumper = await cg.build_registry_entry(DUMPER_REGISTRY, conf) dumpers.append(dumper) return dumpers # JVC JVCData, JVCBinarySensor, JVCTrigger, JVCAction, JVCDumper = declare_protocol("JVC") JVC_SCHEMA = cv.Schema({cv.Required(CONF_DATA): cv.hex_uint32_t}) @register_binary_sensor("jvc", JVCBinarySensor, JVC_SCHEMA) def jvc_binary_sensor(var, config): cg.add( var.set_data( cg.StructInitializer( JVCData, ("data", config[CONF_DATA]), ) ) ) @register_trigger("jvc", JVCTrigger, JVCData) def jvc_trigger(var, config): pass @register_dumper("jvc", JVCDumper) def jvc_dumper(var, config): pass @register_action("jvc", JVCAction, JVC_SCHEMA) async def jvc_action(var, config, args): template_ = await cg.templatable(config[CONF_DATA], args, cg.uint32) cg.add(var.set_data(template_)) # LG LGData, LGBinarySensor, LGTrigger, LGAction, LGDumper = declare_protocol("LG") LG_SCHEMA = cv.Schema( { cv.Required(CONF_DATA): cv.hex_uint32_t, cv.Optional(CONF_NBITS, default=28): cv.one_of(28, 32, int=True), } ) @register_binary_sensor("lg", LGBinarySensor, LG_SCHEMA) def lg_binary_sensor(var, config): cg.add( var.set_data( cg.StructInitializer( LGData, ("data", config[CONF_DATA]), ("nbits", config[CONF_NBITS]), ) ) ) @register_trigger("lg", LGTrigger, LGData) def lg_trigger(var, config): pass @register_dumper("lg", LGDumper) def lg_dumper(var, config): pass @register_action("lg", LGAction, LG_SCHEMA) async def lg_action(var, config, args): template_ = await cg.templatable(config[CONF_DATA], args, cg.uint32) cg.add(var.set_data(template_)) template_ = await cg.templatable(config[CONF_NBITS], args, cg.uint8) cg.add(var.set_nbits(template_)) # NEC NECData, NECBinarySensor, NECTrigger, NECAction, NECDumper = declare_protocol("NEC") NEC_SCHEMA = cv.Schema( { cv.Required(CONF_ADDRESS): cv.hex_uint16_t, cv.Required(CONF_COMMAND): cv.hex_uint16_t, } ) @register_binary_sensor("nec", NECBinarySensor, NEC_SCHEMA) def nec_binary_sensor(var, config): cg.add( var.set_data( cg.StructInitializer( NECData, ("address", config[CONF_ADDRESS]), ("command", config[CONF_COMMAND]), ) ) ) @register_trigger("nec", NECTrigger, NECData) def nec_trigger(var, config): pass @register_dumper("nec", NECDumper) def nec_dumper(var, config): pass @register_action("nec", NECAction, NEC_SCHEMA) async def nec_action(var, config, args): template_ = await cg.templatable(config[CONF_ADDRESS], args, cg.uint16) cg.add(var.set_address(template_)) template_ = await cg.templatable(config[CONF_COMMAND], args, cg.uint16) cg.add(var.set_command(template_)) # Pioneer ( PioneerData, PioneerBinarySensor, PioneerTrigger, PioneerAction, PioneerDumper, ) = declare_protocol("Pioneer") PIONEER_SCHEMA = cv.Schema( { cv.Required(CONF_RC_CODE_1): cv.hex_uint16_t, cv.Optional(CONF_RC_CODE_2, default=0): cv.hex_uint16_t, } ) @register_binary_sensor("pioneer", PioneerBinarySensor, PIONEER_SCHEMA) def pioneer_binary_sensor(var, config): cg.add( var.set_data( cg.StructInitializer( PioneerData, ("rc_code_1", config[CONF_RC_CODE_1]), ("rc_code_2", config[CONF_RC_CODE_2]), ) ) ) @register_trigger("pioneer", PioneerTrigger, PioneerData) def pioneer_trigger(var, config): pass @register_dumper("pioneer", PioneerDumper) def pioneer_dumper(var, config): pass @register_action("pioneer", PioneerAction, PIONEER_SCHEMA) async def pioneer_action(var, config, args): template_ = await cg.templatable(config[CONF_RC_CODE_1], args, cg.uint16) cg.add(var.set_rc_code_1(template_)) template_ = await cg.templatable(config[CONF_RC_CODE_2], args, cg.uint16) cg.add(var.set_rc_code_2(template_)) # Sony SonyData, SonyBinarySensor, SonyTrigger, SonyAction, SonyDumper = declare_protocol( "Sony" ) SONY_SCHEMA = cv.Schema( { cv.Required(CONF_DATA): cv.hex_uint32_t, cv.Optional(CONF_NBITS, default=12): cv.one_of(12, 15, 20, int=True), } ) @register_binary_sensor("sony", SonyBinarySensor, SONY_SCHEMA) def sony_binary_sensor(var, config): cg.add( var.set_data( cg.StructInitializer( SonyData, ("data", config[CONF_DATA]), ("nbits", config[CONF_NBITS]), ) ) ) @register_trigger("sony", SonyTrigger, SonyData) def sony_trigger(var, config): pass @register_dumper("sony", SonyDumper) def sony_dumper(var, config): pass @register_action("sony", SonyAction, SONY_SCHEMA) async def sony_action(var, config, args): template_ = await cg.templatable(config[CONF_DATA], args, cg.uint16) cg.add(var.set_data(template_)) template_ = await cg.templatable(config[CONF_NBITS], args, cg.uint32) cg.add(var.set_nbits(template_)) # Raw def validate_raw_alternating(value): assert isinstance(value, list) last_negative = None for i, val in enumerate(value): this_negative = val < 0 if i != 0: if this_negative == last_negative: raise cv.Invalid( "Values must alternate between being positive and negative, " "please see index {} and {}".format(i, i + 1), [i], ) last_negative = this_negative return value RawData, RawBinarySensor, RawTrigger, RawAction, RawDumper = declare_protocol("Raw") CONF_CODE_STORAGE_ID = "code_storage_id" RAW_SCHEMA = cv.Schema( { cv.Required(CONF_CODE): cv.All( [cv.Any(cv.int_, cv.time_period_microseconds)], cv.Length(min=1), validate_raw_alternating, ), cv.GenerateID(CONF_CODE_STORAGE_ID): cv.declare_id(cg.int32), } ) @register_binary_sensor("raw", RawBinarySensor, RAW_SCHEMA) def raw_binary_sensor(var, config): code_ = config[CONF_CODE] arr = cg.progmem_array(config[CONF_CODE_STORAGE_ID], code_) cg.add(var.set_data(arr)) cg.add(var.set_len(len(code_))) @register_trigger("raw", RawTrigger, cg.std_vector.template(cg.int32)) def raw_trigger(var, config): pass @register_dumper("raw", RawDumper) def raw_dumper(var, config): pass @register_action( "raw", RawAction, RAW_SCHEMA.extend( { cv.Optional(CONF_CARRIER_FREQUENCY, default="0Hz"): cv.All( cv.frequency, cv.int_ ), } ), ) async def raw_action(var, config, args): code_ = config[CONF_CODE] if cg.is_template(code_): template_ = await cg.templatable(code_, args, cg.std_vector.template(cg.int32)) cg.add(var.set_code_template(template_)) else: code_ = config[CONF_CODE] arr = cg.progmem_array(config[CONF_CODE_STORAGE_ID], code_) cg.add(var.set_code_static(arr, len(code_))) templ = await cg.templatable(config[CONF_CARRIER_FREQUENCY], args, cg.uint32) cg.add(var.set_carrier_frequency(templ)) # RC5 RC5Data, RC5BinarySensor, RC5Trigger, RC5Action, RC5Dumper = declare_protocol("RC5") RC5_SCHEMA = cv.Schema( { cv.Required(CONF_ADDRESS): cv.All(cv.hex_int, cv.Range(min=0, max=0x1F)), cv.Required(CONF_COMMAND): cv.All(cv.hex_int, cv.Range(min=0, max=0x7F)), } ) @register_binary_sensor("rc5", RC5BinarySensor, RC5_SCHEMA) def rc5_binary_sensor(var, config): cg.add( var.set_data( cg.StructInitializer( RC5Data, ("address", config[CONF_ADDRESS]), ("command", config[CONF_COMMAND]), ) ) ) @register_trigger("rc5", RC5Trigger, RC5Data) def rc5_trigger(var, config): pass @register_dumper("rc5", RC5Dumper) def rc5_dumper(var, config): pass @register_action("rc5", RC5Action, RC5_SCHEMA) async def rc5_action(var, config, args): template_ = await cg.templatable(config[CONF_ADDRESS], args, cg.uint8) cg.add(var.set_address(template_)) template_ = await cg.templatable(config[CONF_COMMAND], args, cg.uint8) cg.add(var.set_command(template_)) # RC Switch Raw RC_SWITCH_TIMING_SCHEMA = cv.All([cv.uint8_t], cv.Length(min=2, max=2)) RC_SWITCH_PROTOCOL_SCHEMA = cv.Any( cv.int_range(min=1, max=8), cv.Schema( { cv.Required(CONF_PULSE_LENGTH): cv.uint32_t, cv.Optional(CONF_SYNC, default=[1, 31]): RC_SWITCH_TIMING_SCHEMA, cv.Optional(CONF_ZERO, default=[1, 3]): RC_SWITCH_TIMING_SCHEMA, cv.Optional(CONF_ONE, default=[3, 1]): RC_SWITCH_TIMING_SCHEMA, cv.Optional(CONF_INVERTED, default=False): cv.boolean, } ), ) def validate_rc_switch_code(value): if not isinstance(value, (str, str)): raise cv.Invalid("All RCSwitch codes must be in quotes ('')") for c in value: if c not in ("0", "1"): raise cv.Invalid( "Invalid RCSwitch code character '{}'. Only '0' and '1' are allowed" "".format(c) ) if len(value) > 64: raise cv.Invalid( "Maximum length for RCSwitch codes is 64, code '{}' has length {}" "".format(value, len(value)) ) if not value: raise cv.Invalid("RCSwitch code must not be empty") return value def validate_rc_switch_raw_code(value): if not isinstance(value, (str, str)): raise cv.Invalid("All RCSwitch raw codes must be in quotes ('')") for c in value: if c not in ("0", "1", "x"): raise cv.Invalid( "Invalid RCSwitch raw code character '{}'.Only '0', '1' and 'x' are allowed".format( c ) ) if len(value) > 64: raise cv.Invalid( "Maximum length for RCSwitch raw codes is 64, code '{}' has length {}" "".format(value, len(value)) ) if not value: raise cv.Invalid("RCSwitch raw code must not be empty") return value def build_rc_switch_protocol(config): if isinstance(config, int): return rc_switch_protocols[config] pl = config[CONF_PULSE_LENGTH] return RCSwitchBase( config[CONF_SYNC][0] * pl, config[CONF_SYNC][1] * pl, config[CONF_ZERO][0] * pl, config[CONF_ZERO][1] * pl, config[CONF_ONE][0] * pl, config[CONF_ONE][1] * pl, config[CONF_INVERTED], ) RC_SWITCH_RAW_SCHEMA = cv.Schema( { cv.Required(CONF_CODE): validate_rc_switch_raw_code, cv.Optional(CONF_PROTOCOL, default=1): RC_SWITCH_PROTOCOL_SCHEMA, } ) RC_SWITCH_TYPE_A_SCHEMA = cv.Schema( { cv.Required(CONF_GROUP): cv.All( validate_rc_switch_code, cv.Length(min=5, max=5) ), cv.Required(CONF_DEVICE): cv.All( validate_rc_switch_code, cv.Length(min=5, max=5) ), cv.Required(CONF_STATE): cv.boolean, cv.Optional(CONF_PROTOCOL, default=1): RC_SWITCH_PROTOCOL_SCHEMA, } ) RC_SWITCH_TYPE_B_SCHEMA = cv.Schema( { cv.Required(CONF_ADDRESS): cv.int_range(min=1, max=4), cv.Required(CONF_CHANNEL): cv.int_range(min=1, max=4), cv.Required(CONF_STATE): cv.boolean, cv.Optional(CONF_PROTOCOL, default=1): RC_SWITCH_PROTOCOL_SCHEMA, } ) RC_SWITCH_TYPE_C_SCHEMA = cv.Schema( { cv.Required(CONF_FAMILY): cv.one_of( "a", "b", "c", "d", "e", "f", "g", "h", "i", "j", "k", "l", "m", "n", "o", "p", lower=True, ), cv.Required(CONF_GROUP): cv.int_range(min=1, max=4), cv.Required(CONF_DEVICE): cv.int_range(min=1, max=4), cv.Required(CONF_STATE): cv.boolean, cv.Optional(CONF_PROTOCOL, default=1): RC_SWITCH_PROTOCOL_SCHEMA, } ) RC_SWITCH_TYPE_D_SCHEMA = cv.Schema( { cv.Required(CONF_GROUP): cv.one_of("a", "b", "c", "d", lower=True), cv.Required(CONF_DEVICE): cv.int_range(min=1, max=3), cv.Required(CONF_STATE): cv.boolean, cv.Optional(CONF_PROTOCOL, default=1): RC_SWITCH_PROTOCOL_SCHEMA, } ) RC_SWITCH_TRANSMITTER = cv.Schema( { cv.Optional(CONF_REPEAT, default={CONF_TIMES: 5}): cv.Schema( { cv.Required(CONF_TIMES): cv.templatable(cv.positive_int), cv.Optional(CONF_WAIT_TIME, default="0us"): cv.templatable( cv.positive_time_period_microseconds ), } ), } ) rc_switch_protocols = ns.RC_SWITCH_PROTOCOLS RCSwitchData = ns.struct("RCSwitchData") RCSwitchBase = ns.class_("RCSwitchBase") RCSwitchTrigger = ns.class_("RCSwitchTrigger", RemoteReceiverTrigger) RCSwitchDumper = ns.class_("RCSwitchDumper", RemoteTransmitterDumper) RCSwitchRawAction = ns.class_("RCSwitchRawAction", RemoteTransmitterActionBase) RCSwitchTypeAAction = ns.class_("RCSwitchTypeAAction", RemoteTransmitterActionBase) RCSwitchTypeBAction = ns.class_("RCSwitchTypeBAction", RemoteTransmitterActionBase) RCSwitchTypeCAction = ns.class_("RCSwitchTypeCAction", RemoteTransmitterActionBase) RCSwitchTypeDAction = ns.class_("RCSwitchTypeDAction", RemoteTransmitterActionBase) RCSwitchRawReceiver = ns.class_("RCSwitchRawReceiver", RemoteReceiverBinarySensorBase) @register_binary_sensor("rc_switch_raw", RCSwitchRawReceiver, RC_SWITCH_RAW_SCHEMA) def rc_switch_raw_binary_sensor(var, config): cg.add(var.set_protocol(build_rc_switch_protocol(config[CONF_PROTOCOL]))) cg.add(var.set_code(config[CONF_CODE])) @register_action( "rc_switch_raw", RCSwitchRawAction, RC_SWITCH_RAW_SCHEMA.extend(RC_SWITCH_TRANSMITTER), ) async def rc_switch_raw_action(var, config, args): proto = await cg.templatable( config[CONF_PROTOCOL], args, RCSwitchBase, to_exp=build_rc_switch_protocol ) cg.add(var.set_protocol(proto)) cg.add(var.set_code((await cg.templatable(config[CONF_CODE], args, cg.std_string)))) @register_binary_sensor( "rc_switch_type_a", RCSwitchRawReceiver, RC_SWITCH_TYPE_A_SCHEMA ) def rc_switch_type_a_binary_sensor(var, config): cg.add(var.set_protocol(build_rc_switch_protocol(config[CONF_PROTOCOL]))) cg.add(var.set_type_a(config[CONF_GROUP], config[CONF_DEVICE], config[CONF_STATE])) @register_action( "rc_switch_type_a", RCSwitchTypeAAction, RC_SWITCH_TYPE_A_SCHEMA.extend(RC_SWITCH_TRANSMITTER), ) async def rc_switch_type_a_action(var, config, args): proto = await cg.templatable( config[CONF_PROTOCOL], args, RCSwitchBase, to_exp=build_rc_switch_protocol ) cg.add(var.set_protocol(proto)) cg.add( var.set_group((await cg.templatable(config[CONF_GROUP], args, cg.std_string))) ) cg.add( var.set_device((await cg.templatable(config[CONF_DEVICE], args, cg.std_string))) ) cg.add(var.set_state((await cg.templatable(config[CONF_STATE], args, bool)))) @register_binary_sensor( "rc_switch_type_b", RCSwitchRawReceiver, RC_SWITCH_TYPE_B_SCHEMA ) def rc_switch_type_b_binary_sensor(var, config): cg.add(var.set_protocol(build_rc_switch_protocol(config[CONF_PROTOCOL]))) cg.add( var.set_type_b(config[CONF_ADDRESS], config[CONF_CHANNEL], config[CONF_STATE]) ) @register_action( "rc_switch_type_b", RCSwitchTypeBAction, RC_SWITCH_TYPE_B_SCHEMA.extend(RC_SWITCH_TRANSMITTER), ) async def rc_switch_type_b_action(var, config, args): proto = await cg.templatable( config[CONF_PROTOCOL], args, RCSwitchBase, to_exp=build_rc_switch_protocol ) cg.add(var.set_protocol(proto)) cg.add( var.set_address((await cg.templatable(config[CONF_ADDRESS], args, cg.uint8))) ) cg.add( var.set_channel((await cg.templatable(config[CONF_CHANNEL], args, cg.uint8))) ) cg.add(var.set_state((await cg.templatable(config[CONF_STATE], args, bool)))) @register_binary_sensor( "rc_switch_type_c", RCSwitchRawReceiver, RC_SWITCH_TYPE_C_SCHEMA ) def rc_switch_type_c_binary_sensor(var, config): cg.add(var.set_protocol(build_rc_switch_protocol(config[CONF_PROTOCOL]))) cg.add( var.set_type_c( config[CONF_FAMILY], config[CONF_GROUP], config[CONF_DEVICE], config[CONF_STATE], ) ) @register_action( "rc_switch_type_c", RCSwitchTypeCAction, RC_SWITCH_TYPE_C_SCHEMA.extend(RC_SWITCH_TRANSMITTER), ) async def rc_switch_type_c_action(var, config, args): proto = await cg.templatable( config[CONF_PROTOCOL], args, RCSwitchBase, to_exp=build_rc_switch_protocol ) cg.add(var.set_protocol(proto)) cg.add( var.set_family((await cg.templatable(config[CONF_FAMILY], args, cg.std_string))) ) cg.add(var.set_group((await cg.templatable(config[CONF_GROUP], args, cg.uint8)))) cg.add(var.set_device((await cg.templatable(config[CONF_DEVICE], args, cg.uint8)))) cg.add(var.set_state((await cg.templatable(config[CONF_STATE], args, bool)))) @register_binary_sensor( "rc_switch_type_d", RCSwitchRawReceiver, RC_SWITCH_TYPE_D_SCHEMA.extend(RC_SWITCH_TRANSMITTER), ) def rc_switch_type_d_binary_sensor(var, config): cg.add(var.set_protocol(build_rc_switch_protocol(config[CONF_PROTOCOL]))) cg.add(var.set_type_d(config[CONF_GROUP], config[CONF_DEVICE], config[CONF_STATE])) @register_action( "rc_switch_type_d", RCSwitchTypeDAction, RC_SWITCH_TYPE_D_SCHEMA.extend(RC_SWITCH_TRANSMITTER), ) async def rc_switch_type_d_action(var, config, args): proto = await cg.templatable( config[CONF_PROTOCOL], args, RCSwitchBase, to_exp=build_rc_switch_protocol ) cg.add(var.set_protocol(proto)) cg.add( var.set_group((await cg.templatable(config[CONF_GROUP], args, cg.std_string))) ) cg.add(var.set_device((await cg.templatable(config[CONF_DEVICE], args, cg.uint8)))) cg.add(var.set_state((await cg.templatable(config[CONF_STATE], args, bool)))) @register_trigger("rc_switch", RCSwitchTrigger, RCSwitchData) def rc_switch_trigger(var, config): pass @register_dumper("rc_switch", RCSwitchDumper) def rc_switch_dumper(var, config): pass # Samsung ( SamsungData, SamsungBinarySensor, SamsungTrigger, SamsungAction, SamsungDumper, ) = declare_protocol("Samsung") SAMSUNG_SCHEMA = cv.Schema( { cv.Required(CONF_DATA): cv.hex_uint64_t, cv.Optional(CONF_NBITS, default=32): cv.int_range(32, 64), } ) @register_binary_sensor("samsung", SamsungBinarySensor, SAMSUNG_SCHEMA) def samsung_binary_sensor(var, config): cg.add( var.set_data( cg.StructInitializer( SamsungData, ("data", config[CONF_DATA]), ("nbits", config[CONF_NBITS]), ) ) ) @register_trigger("samsung", SamsungTrigger, SamsungData) def samsung_trigger(var, config): pass @register_dumper("samsung", SamsungDumper) def samsung_dumper(var, config): pass @register_action("samsung", SamsungAction, SAMSUNG_SCHEMA) async def samsung_action(var, config, args): template_ = await cg.templatable(config[CONF_DATA], args, cg.uint64) cg.add(var.set_data(template_)) template_ = await cg.templatable(config[CONF_NBITS], args, cg.uint8) cg.add(var.set_nbits(template_)) # Samsung36 ( Samsung36Data, Samsung36BinarySensor, Samsung36Trigger, Samsung36Action, Samsung36Dumper, ) = declare_protocol("Samsung36") SAMSUNG36_SCHEMA = cv.Schema( { cv.Required(CONF_ADDRESS): cv.hex_uint16_t, cv.Required(CONF_COMMAND): cv.hex_uint32_t, } ) @register_binary_sensor("samsung36", Samsung36BinarySensor, SAMSUNG36_SCHEMA) def samsung36_binary_sensor(var, config): cg.add( var.set_data( cg.StructInitializer( Samsung36Data, ("address", config[CONF_ADDRESS]), ("command", config[CONF_COMMAND]), ) ) ) @register_trigger("samsung36", Samsung36Trigger, Samsung36Data) def samsung36_trigger(var, config): pass @register_dumper("samsung36", Samsung36Dumper) def samsung36_dumper(var, config): pass @register_action("samsung36", Samsung36Action, SAMSUNG36_SCHEMA) async def samsung36_action(var, config, args): template_ = await cg.templatable(config[CONF_ADDRESS], args, cg.uint16) cg.add(var.set_address(template_)) template_ = await cg.templatable(config[CONF_COMMAND], args, cg.uint32) cg.add(var.set_command(template_)) # Toshiba AC ( ToshibaAcData, ToshibaAcBinarySensor, ToshibaAcTrigger, ToshibaAcAction, ToshibaAcDumper, ) = declare_protocol("ToshibaAc") TOSHIBAAC_SCHEMA = cv.Schema( { cv.Required(CONF_RC_CODE_1): cv.hex_uint64_t, cv.Optional(CONF_RC_CODE_2, default=0): cv.hex_uint64_t, } ) @register_binary_sensor("toshiba_ac", ToshibaAcBinarySensor, TOSHIBAAC_SCHEMA) def toshibaac_binary_sensor(var, config): cg.add( var.set_data( cg.StructInitializer( ToshibaAcData, ("rc_code_1", config[CONF_RC_CODE_1]), ("rc_code_2", config[CONF_RC_CODE_2]), ) ) ) @register_trigger("toshiba_ac", ToshibaAcTrigger, ToshibaAcData) def toshibaac_trigger(var, config): pass @register_dumper("toshiba_ac", ToshibaAcDumper) def toshibaac_dumper(var, config): pass @register_action("toshiba_ac", ToshibaAcAction, TOSHIBAAC_SCHEMA) async def toshibaac_action(var, config, args): template_ = await cg.templatable(config[CONF_RC_CODE_1], args, cg.uint64) cg.add(var.set_rc_code_1(template_)) template_ = await cg.templatable(config[CONF_RC_CODE_2], args, cg.uint64) cg.add(var.set_rc_code_2(template_)) # Panasonic ( PanasonicData, PanasonicBinarySensor, PanasonicTrigger, PanasonicAction, PanasonicDumper, ) = declare_protocol("Panasonic") PANASONIC_SCHEMA = cv.Schema( { cv.Required(CONF_ADDRESS): cv.hex_uint16_t, cv.Required(CONF_COMMAND): cv.hex_uint32_t, } ) @register_binary_sensor("panasonic", PanasonicBinarySensor, PANASONIC_SCHEMA) def panasonic_binary_sensor(var, config): cg.add( var.set_data( cg.StructInitializer( PanasonicData, ("address", config[CONF_ADDRESS]), ("command", config[CONF_COMMAND]), ) ) ) @register_trigger("panasonic", PanasonicTrigger, PanasonicData) def panasonic_trigger(var, config): pass @register_dumper("panasonic", PanasonicDumper) def panasonic_dumper(var, config): pass @register_action("panasonic", PanasonicAction, PANASONIC_SCHEMA) async def panasonic_action(var, config, args): template_ = await cg.templatable(config[CONF_ADDRESS], args, cg.uint16) cg.add(var.set_address(template_)) template_ = await cg.templatable(config[CONF_COMMAND], args, cg.uint32) cg.add(var.set_command(template_))