#include "api_connection.h" #ifdef USE_API #include #include #include #include #include #include "esphome/components/network/util.h" #include "esphome/core/application.h" #include "esphome/core/entity_base.h" #include "esphome/core/hal.h" #include "esphome/core/log.h" #include "esphome/core/version.h" #ifdef USE_DEEP_SLEEP #include "esphome/components/deep_sleep/deep_sleep_component.h" #endif #ifdef USE_HOMEASSISTANT_TIME #include "esphome/components/homeassistant/time/homeassistant_time.h" #endif #ifdef USE_BLUETOOTH_PROXY #include "esphome/components/bluetooth_proxy/bluetooth_proxy.h" #endif #ifdef USE_VOICE_ASSISTANT #include "esphome/components/voice_assistant/voice_assistant.h" #endif namespace esphome { namespace api { // Read a maximum of 5 messages per loop iteration to prevent starving other components. // This is a balance between API responsiveness and allowing other components to run. // Since each message could contain multiple protobuf messages when using packet batching, // this limits the number of messages processed, not the number of TCP packets. static constexpr uint8_t MAX_MESSAGES_PER_LOOP = 5; static const char *const TAG = "api.connection"; static const int ESP32_CAMERA_STOP_STREAM = 5000; APIConnection::APIConnection(std::unique_ptr sock, APIServer *parent) : parent_(parent), initial_state_iterator_(this), list_entities_iterator_(this) { #if defined(USE_API_PLAINTEXT) && defined(USE_API_NOISE) auto noise_ctx = parent->get_noise_ctx(); if (noise_ctx->has_psk()) { this->helper_ = std::unique_ptr{new APINoiseFrameHelper(std::move(sock), noise_ctx)}; } else { this->helper_ = std::unique_ptr{new APIPlaintextFrameHelper(std::move(sock))}; } #elif defined(USE_API_PLAINTEXT) this->helper_ = std::unique_ptr{new APIPlaintextFrameHelper(std::move(sock))}; #elif defined(USE_API_NOISE) this->helper_ = std::unique_ptr{new APINoiseFrameHelper(std::move(sock), parent->get_noise_ctx())}; #else #error "No frame helper defined" #endif } uint32_t APIConnection::get_batch_delay_ms_() const { return this->parent_->get_batch_delay(); } void APIConnection::start() { this->last_traffic_ = App.get_loop_component_start_time(); // Set next_ping_retry_ to prevent immediate ping // This ensures the first ping happens after the keepalive period this->next_ping_retry_ = this->last_traffic_ + KEEPALIVE_TIMEOUT_MS; APIError err = this->helper_->init(); if (err != APIError::OK) { on_fatal_error(); ESP_LOGW(TAG, "%s: Helper init failed: %s errno=%d", this->get_client_combined_info().c_str(), api_error_to_str(err), errno); return; } this->client_info_ = helper_->getpeername(); this->client_peername_ = this->client_info_; this->helper_->set_log_info(this->client_info_); } APIConnection::~APIConnection() { #ifdef USE_BLUETOOTH_PROXY if (bluetooth_proxy::global_bluetooth_proxy->get_api_connection() == this) { bluetooth_proxy::global_bluetooth_proxy->unsubscribe_api_connection(this); } #endif #ifdef USE_VOICE_ASSISTANT if (voice_assistant::global_voice_assistant->get_api_connection() == this) { voice_assistant::global_voice_assistant->client_subscription(this, false); } #endif } void APIConnection::loop() { if (this->remove_) return; if (!network::is_connected()) { // when network is disconnected force disconnect immediately // don't wait for timeout this->on_fatal_error(); ESP_LOGW(TAG, "%s: Network unavailable; disconnecting", this->get_client_combined_info().c_str()); return; } if (this->next_close_) { // requested a disconnect this->helper_->close(); this->remove_ = true; return; } APIError err = this->helper_->loop(); if (err != APIError::OK) { on_fatal_error(); ESP_LOGW(TAG, "%s: Socket operation failed: %s errno=%d", this->get_client_combined_info().c_str(), api_error_to_str(err), errno); return; } const uint32_t now = App.get_loop_component_start_time(); // Check if socket has data ready before attempting to read if (this->helper_->is_socket_ready()) { // Read up to MAX_MESSAGES_PER_LOOP messages per loop to improve throughput for (uint8_t message_count = 0; message_count < MAX_MESSAGES_PER_LOOP; message_count++) { ReadPacketBuffer buffer; err = this->helper_->read_packet(&buffer); if (err == APIError::WOULD_BLOCK) { // No more data available break; } else if (err != APIError::OK) { on_fatal_error(); if (err == APIError::SOCKET_READ_FAILED && errno == ECONNRESET) { ESP_LOGW(TAG, "%s: Connection reset", this->get_client_combined_info().c_str()); } else if (err == APIError::CONNECTION_CLOSED) { ESP_LOGW(TAG, "%s: Connection closed", this->get_client_combined_info().c_str()); } else { ESP_LOGW(TAG, "%s: Reading failed: %s errno=%d", this->get_client_combined_info().c_str(), api_error_to_str(err), errno); } return; } else { this->last_traffic_ = now; // read a packet if (buffer.data_len > 0) { this->read_message(buffer.data_len, buffer.type, &buffer.container[buffer.data_offset]); } else { this->read_message(0, buffer.type, nullptr); } if (this->remove_) return; } } } // Process deferred batch if scheduled if (this->deferred_batch_.batch_scheduled && App.get_loop_component_start_time() - this->deferred_batch_.batch_start_time >= this->get_batch_delay_ms_()) { this->process_batch_(); } if (!this->list_entities_iterator_.completed()) this->list_entities_iterator_.advance(); if (!this->initial_state_iterator_.completed() && this->list_entities_iterator_.completed()) this->initial_state_iterator_.advance(); static uint8_t max_ping_retries = 60; static uint16_t ping_retry_interval = 1000; if (this->sent_ping_) { // Disconnect if not responded within 2.5*keepalive if (now - this->last_traffic_ > (KEEPALIVE_TIMEOUT_MS * 5) / 2) { on_fatal_error(); ESP_LOGW(TAG, "%s is unresponsive; disconnecting", this->get_client_combined_info().c_str()); } } else if (now - this->last_traffic_ > KEEPALIVE_TIMEOUT_MS && now > this->next_ping_retry_) { ESP_LOGVV(TAG, "Sending keepalive PING"); this->sent_ping_ = this->send_message(PingRequest()); if (!this->sent_ping_) { this->next_ping_retry_ = now + ping_retry_interval; this->ping_retries_++; std::string warn_str = str_sprintf("%s: Sending keepalive failed %u time(s);", this->get_client_combined_info().c_str(), this->ping_retries_); if (this->ping_retries_ >= max_ping_retries) { on_fatal_error(); ESP_LOGE(TAG, "%s disconnecting", warn_str.c_str()); } else if (this->ping_retries_ >= 10) { ESP_LOGW(TAG, "%s retrying in %u ms", warn_str.c_str(), ping_retry_interval); } else { ESP_LOGD(TAG, "%s retrying in %u ms", warn_str.c_str(), ping_retry_interval); } } } #ifdef USE_ESP32_CAMERA if (this->image_reader_.available() && this->helper_->can_write_without_blocking()) { uint32_t to_send = std::min((size_t) MAX_PACKET_SIZE, this->image_reader_.available()); bool done = this->image_reader_.available() == to_send; uint32_t msg_size = 0; ProtoSize::add_fixed_field<4>(msg_size, 1, true); // partial message size calculated manually since its a special case // 1 for the data field, varint for the data size, and the data itself msg_size += 1 + ProtoSize::varint(to_send) + to_send; ProtoSize::add_bool_field(msg_size, 1, done); auto buffer = this->create_buffer(msg_size); // fixed32 key = 1; buffer.encode_fixed32(1, esp32_camera::global_esp32_camera->get_object_id_hash()); // bytes data = 2; buffer.encode_bytes(2, this->image_reader_.peek_data_buffer(), to_send); // bool done = 3; buffer.encode_bool(3, done); bool success = this->send_buffer(buffer, 44); if (success) { this->image_reader_.consume_data(to_send); } if (success && done) { this->image_reader_.return_image(); } } #endif if (state_subs_at_ != -1) { const auto &subs = this->parent_->get_state_subs(); if (state_subs_at_ >= (int) subs.size()) { state_subs_at_ = -1; } else { auto &it = subs[state_subs_at_]; SubscribeHomeAssistantStateResponse resp; resp.entity_id = it.entity_id; resp.attribute = it.attribute.value(); resp.once = it.once; if (this->send_message(resp)) { state_subs_at_++; } } } } std::string get_default_unique_id(const std::string &component_type, EntityBase *entity) { return App.get_name() + component_type + entity->get_object_id(); } DisconnectResponse APIConnection::disconnect(const DisconnectRequest &msg) { // remote initiated disconnect_client // don't close yet, we still need to send the disconnect response // close will happen on next loop ESP_LOGD(TAG, "%s disconnected", this->get_client_combined_info().c_str()); this->next_close_ = true; DisconnectResponse resp; return resp; } void APIConnection::on_disconnect_response(const DisconnectResponse &value) { this->helper_->close(); this->remove_ = true; } // Encodes a message to the buffer and returns the total number of bytes used, // including header and footer overhead. Returns 0 if the message doesn't fit. uint16_t APIConnection::encode_message_to_buffer(ProtoMessage &msg, uint16_t message_type, APIConnection *conn, uint32_t remaining_size, bool is_single) { // Calculate size uint32_t calculated_size = 0; msg.calculate_size(calculated_size); // Cache frame sizes to avoid repeated virtual calls const uint8_t header_padding = conn->helper_->frame_header_padding(); const uint8_t footer_size = conn->helper_->frame_footer_size(); // Calculate total size with padding for buffer allocation size_t total_calculated_size = calculated_size + header_padding + footer_size; // Check if it fits if (total_calculated_size > remaining_size) { return 0; // Doesn't fit } // Allocate buffer space - pass payload size, allocation functions add header/footer space ProtoWriteBuffer buffer = is_single ? conn->allocate_single_message_buffer(calculated_size) : conn->allocate_batch_message_buffer(calculated_size); // Get buffer size after allocation (which includes header padding) std::vector &shared_buf = conn->parent_->get_shared_buffer_ref(); size_t size_before_encode = shared_buf.size(); // Encode directly into buffer msg.encode(buffer); // Calculate actual encoded size (not including header that was already added) size_t actual_payload_size = shared_buf.size() - size_before_encode; // Return actual total size (header + actual payload + footer) size_t actual_total_size = header_padding + actual_payload_size + footer_size; // Verify that calculate_size() returned the correct value assert(calculated_size == actual_payload_size); return static_cast(actual_total_size); } #ifdef USE_BINARY_SENSOR bool APIConnection::send_binary_sensor_state(binary_sensor::BinarySensor *binary_sensor) { return this->schedule_message_(binary_sensor, &APIConnection::try_send_binary_sensor_state, BinarySensorStateResponse::MESSAGE_TYPE); } void APIConnection::send_binary_sensor_info(binary_sensor::BinarySensor *binary_sensor) { this->schedule_message_(binary_sensor, &APIConnection::try_send_binary_sensor_info, ListEntitiesBinarySensorResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_binary_sensor_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *binary_sensor = static_cast(entity); BinarySensorStateResponse resp; resp.state = binary_sensor->state; resp.missing_state = !binary_sensor->has_state(); fill_entity_state_base(binary_sensor, resp); return encode_message_to_buffer(resp, BinarySensorStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } uint16_t APIConnection::try_send_binary_sensor_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *binary_sensor = static_cast(entity); ListEntitiesBinarySensorResponse msg; msg.device_class = binary_sensor->get_device_class(); msg.is_status_binary_sensor = binary_sensor->is_status_binary_sensor(); msg.unique_id = get_default_unique_id("binary_sensor", binary_sensor); fill_entity_info_base(binary_sensor, msg); return encode_message_to_buffer(msg, ListEntitiesBinarySensorResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } #endif #ifdef USE_COVER bool APIConnection::send_cover_state(cover::Cover *cover) { return this->schedule_message_(cover, &APIConnection::try_send_cover_state, CoverStateResponse::MESSAGE_TYPE); } void APIConnection::send_cover_info(cover::Cover *cover) { this->schedule_message_(cover, &APIConnection::try_send_cover_info, ListEntitiesCoverResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_cover_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *cover = static_cast(entity); CoverStateResponse msg; auto traits = cover->get_traits(); msg.legacy_state = (cover->position == cover::COVER_OPEN) ? enums::LEGACY_COVER_STATE_OPEN : enums::LEGACY_COVER_STATE_CLOSED; msg.position = cover->position; if (traits.get_supports_tilt()) msg.tilt = cover->tilt; msg.current_operation = static_cast(cover->current_operation); fill_entity_state_base(cover, msg); return encode_message_to_buffer(msg, CoverStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } uint16_t APIConnection::try_send_cover_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *cover = static_cast(entity); ListEntitiesCoverResponse msg; auto traits = cover->get_traits(); msg.assumed_state = traits.get_is_assumed_state(); msg.supports_position = traits.get_supports_position(); msg.supports_tilt = traits.get_supports_tilt(); msg.supports_stop = traits.get_supports_stop(); msg.device_class = cover->get_device_class(); msg.unique_id = get_default_unique_id("cover", cover); fill_entity_info_base(cover, msg); return encode_message_to_buffer(msg, ListEntitiesCoverResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::cover_command(const CoverCommandRequest &msg) { cover::Cover *cover = App.get_cover_by_key(msg.key); if (cover == nullptr) return; auto call = cover->make_call(); if (msg.has_legacy_command) { switch (msg.legacy_command) { case enums::LEGACY_COVER_COMMAND_OPEN: call.set_command_open(); break; case enums::LEGACY_COVER_COMMAND_CLOSE: call.set_command_close(); break; case enums::LEGACY_COVER_COMMAND_STOP: call.set_command_stop(); break; } } if (msg.has_position) call.set_position(msg.position); if (msg.has_tilt) call.set_tilt(msg.tilt); if (msg.stop) call.set_command_stop(); call.perform(); } #endif #ifdef USE_FAN bool APIConnection::send_fan_state(fan::Fan *fan) { return this->schedule_message_(fan, &APIConnection::try_send_fan_state, FanStateResponse::MESSAGE_TYPE); } void APIConnection::send_fan_info(fan::Fan *fan) { this->schedule_message_(fan, &APIConnection::try_send_fan_info, ListEntitiesFanResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_fan_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *fan = static_cast(entity); FanStateResponse msg; auto traits = fan->get_traits(); msg.state = fan->state; if (traits.supports_oscillation()) msg.oscillating = fan->oscillating; if (traits.supports_speed()) { msg.speed_level = fan->speed; } if (traits.supports_direction()) msg.direction = static_cast(fan->direction); if (traits.supports_preset_modes()) msg.preset_mode = fan->preset_mode; fill_entity_state_base(fan, msg); return encode_message_to_buffer(msg, FanStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } uint16_t APIConnection::try_send_fan_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *fan = static_cast(entity); ListEntitiesFanResponse msg; auto traits = fan->get_traits(); msg.supports_oscillation = traits.supports_oscillation(); msg.supports_speed = traits.supports_speed(); msg.supports_direction = traits.supports_direction(); msg.supported_speed_count = traits.supported_speed_count(); for (auto const &preset : traits.supported_preset_modes()) msg.supported_preset_modes.push_back(preset); msg.unique_id = get_default_unique_id("fan", fan); fill_entity_info_base(fan, msg); return encode_message_to_buffer(msg, ListEntitiesFanResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::fan_command(const FanCommandRequest &msg) { fan::Fan *fan = App.get_fan_by_key(msg.key); if (fan == nullptr) return; auto call = fan->make_call(); if (msg.has_state) call.set_state(msg.state); if (msg.has_oscillating) call.set_oscillating(msg.oscillating); if (msg.has_speed_level) { // Prefer level call.set_speed(msg.speed_level); } if (msg.has_direction) call.set_direction(static_cast(msg.direction)); if (msg.has_preset_mode) call.set_preset_mode(msg.preset_mode); call.perform(); } #endif #ifdef USE_LIGHT bool APIConnection::send_light_state(light::LightState *light) { return this->schedule_message_(light, &APIConnection::try_send_light_state, LightStateResponse::MESSAGE_TYPE); } void APIConnection::send_light_info(light::LightState *light) { this->schedule_message_(light, &APIConnection::try_send_light_info, ListEntitiesLightResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_light_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *light = static_cast(entity); LightStateResponse resp; auto traits = light->get_traits(); auto values = light->remote_values; auto color_mode = values.get_color_mode(); resp.state = values.is_on(); resp.color_mode = static_cast(color_mode); resp.brightness = values.get_brightness(); resp.color_brightness = values.get_color_brightness(); resp.red = values.get_red(); resp.green = values.get_green(); resp.blue = values.get_blue(); resp.white = values.get_white(); resp.color_temperature = values.get_color_temperature(); resp.cold_white = values.get_cold_white(); resp.warm_white = values.get_warm_white(); if (light->supports_effects()) resp.effect = light->get_effect_name(); fill_entity_state_base(light, resp); return encode_message_to_buffer(resp, LightStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } uint16_t APIConnection::try_send_light_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *light = static_cast(entity); ListEntitiesLightResponse msg; auto traits = light->get_traits(); for (auto mode : traits.get_supported_color_modes()) msg.supported_color_modes.push_back(static_cast(mode)); msg.legacy_supports_brightness = traits.supports_color_capability(light::ColorCapability::BRIGHTNESS); msg.legacy_supports_rgb = traits.supports_color_capability(light::ColorCapability::RGB); msg.legacy_supports_white_value = msg.legacy_supports_rgb && (traits.supports_color_capability(light::ColorCapability::WHITE) || traits.supports_color_capability(light::ColorCapability::COLD_WARM_WHITE)); msg.legacy_supports_color_temperature = traits.supports_color_capability(light::ColorCapability::COLOR_TEMPERATURE) || traits.supports_color_capability(light::ColorCapability::COLD_WARM_WHITE); if (msg.legacy_supports_color_temperature) { msg.min_mireds = traits.get_min_mireds(); msg.max_mireds = traits.get_max_mireds(); } if (light->supports_effects()) { msg.effects.emplace_back("None"); for (auto *effect : light->get_effects()) { msg.effects.push_back(effect->get_name()); } } msg.unique_id = get_default_unique_id("light", light); fill_entity_info_base(light, msg); return encode_message_to_buffer(msg, ListEntitiesLightResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::light_command(const LightCommandRequest &msg) { light::LightState *light = App.get_light_by_key(msg.key); if (light == nullptr) return; auto call = light->make_call(); if (msg.has_state) call.set_state(msg.state); if (msg.has_brightness) call.set_brightness(msg.brightness); if (msg.has_color_mode) call.set_color_mode(static_cast(msg.color_mode)); if (msg.has_color_brightness) call.set_color_brightness(msg.color_brightness); if (msg.has_rgb) { call.set_red(msg.red); call.set_green(msg.green); call.set_blue(msg.blue); } if (msg.has_white) call.set_white(msg.white); if (msg.has_color_temperature) call.set_color_temperature(msg.color_temperature); if (msg.has_cold_white) call.set_cold_white(msg.cold_white); if (msg.has_warm_white) call.set_warm_white(msg.warm_white); if (msg.has_transition_length) call.set_transition_length(msg.transition_length); if (msg.has_flash_length) call.set_flash_length(msg.flash_length); if (msg.has_effect) call.set_effect(msg.effect); call.perform(); } #endif #ifdef USE_SENSOR bool APIConnection::send_sensor_state(sensor::Sensor *sensor) { return this->schedule_message_(sensor, &APIConnection::try_send_sensor_state, SensorStateResponse::MESSAGE_TYPE); } void APIConnection::send_sensor_info(sensor::Sensor *sensor) { this->schedule_message_(sensor, &APIConnection::try_send_sensor_info, ListEntitiesSensorResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_sensor_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *sensor = static_cast(entity); SensorStateResponse resp; resp.state = sensor->state; resp.missing_state = !sensor->has_state(); fill_entity_state_base(sensor, resp); return encode_message_to_buffer(resp, SensorStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } uint16_t APIConnection::try_send_sensor_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *sensor = static_cast(entity); ListEntitiesSensorResponse msg; msg.unit_of_measurement = sensor->get_unit_of_measurement(); msg.accuracy_decimals = sensor->get_accuracy_decimals(); msg.force_update = sensor->get_force_update(); msg.device_class = sensor->get_device_class(); msg.state_class = static_cast(sensor->get_state_class()); msg.unique_id = sensor->unique_id(); if (msg.unique_id.empty()) msg.unique_id = get_default_unique_id("sensor", sensor); fill_entity_info_base(sensor, msg); return encode_message_to_buffer(msg, ListEntitiesSensorResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } #endif #ifdef USE_SWITCH bool APIConnection::send_switch_state(switch_::Switch *a_switch) { return this->schedule_message_(a_switch, &APIConnection::try_send_switch_state, SwitchStateResponse::MESSAGE_TYPE); } void APIConnection::send_switch_info(switch_::Switch *a_switch) { this->schedule_message_(a_switch, &APIConnection::try_send_switch_info, ListEntitiesSwitchResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_switch_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *a_switch = static_cast(entity); SwitchStateResponse resp; resp.state = a_switch->state; fill_entity_state_base(a_switch, resp); return encode_message_to_buffer(resp, SwitchStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } uint16_t APIConnection::try_send_switch_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *a_switch = static_cast(entity); ListEntitiesSwitchResponse msg; msg.assumed_state = a_switch->assumed_state(); msg.device_class = a_switch->get_device_class(); msg.unique_id = get_default_unique_id("switch", a_switch); fill_entity_info_base(a_switch, msg); return encode_message_to_buffer(msg, ListEntitiesSwitchResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::switch_command(const SwitchCommandRequest &msg) { switch_::Switch *a_switch = App.get_switch_by_key(msg.key); if (a_switch == nullptr) return; if (msg.state) { a_switch->turn_on(); } else { a_switch->turn_off(); } } #endif #ifdef USE_TEXT_SENSOR bool APIConnection::send_text_sensor_state(text_sensor::TextSensor *text_sensor) { return this->schedule_message_(text_sensor, &APIConnection::try_send_text_sensor_state, TextSensorStateResponse::MESSAGE_TYPE); } void APIConnection::send_text_sensor_info(text_sensor::TextSensor *text_sensor) { this->schedule_message_(text_sensor, &APIConnection::try_send_text_sensor_info, ListEntitiesTextSensorResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_text_sensor_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *text_sensor = static_cast(entity); TextSensorStateResponse resp; resp.state = text_sensor->state; resp.missing_state = !text_sensor->has_state(); fill_entity_state_base(text_sensor, resp); return encode_message_to_buffer(resp, TextSensorStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } uint16_t APIConnection::try_send_text_sensor_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *text_sensor = static_cast(entity); ListEntitiesTextSensorResponse msg; msg.device_class = text_sensor->get_device_class(); msg.unique_id = text_sensor->unique_id(); if (msg.unique_id.empty()) msg.unique_id = get_default_unique_id("text_sensor", text_sensor); fill_entity_info_base(text_sensor, msg); return encode_message_to_buffer(msg, ListEntitiesTextSensorResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } #endif #ifdef USE_CLIMATE bool APIConnection::send_climate_state(climate::Climate *climate) { return this->schedule_message_(climate, &APIConnection::try_send_climate_state, ClimateStateResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_climate_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *climate = static_cast(entity); ClimateStateResponse resp; fill_entity_state_base(climate, resp); auto traits = climate->get_traits(); resp.mode = static_cast(climate->mode); resp.action = static_cast(climate->action); if (traits.get_supports_current_temperature()) resp.current_temperature = climate->current_temperature; if (traits.get_supports_two_point_target_temperature()) { resp.target_temperature_low = climate->target_temperature_low; resp.target_temperature_high = climate->target_temperature_high; } else { resp.target_temperature = climate->target_temperature; } if (traits.get_supports_fan_modes() && climate->fan_mode.has_value()) resp.fan_mode = static_cast(climate->fan_mode.value()); if (!traits.get_supported_custom_fan_modes().empty() && climate->custom_fan_mode.has_value()) resp.custom_fan_mode = climate->custom_fan_mode.value(); if (traits.get_supports_presets() && climate->preset.has_value()) { resp.preset = static_cast(climate->preset.value()); } if (!traits.get_supported_custom_presets().empty() && climate->custom_preset.has_value()) resp.custom_preset = climate->custom_preset.value(); if (traits.get_supports_swing_modes()) resp.swing_mode = static_cast(climate->swing_mode); if (traits.get_supports_current_humidity()) resp.current_humidity = climate->current_humidity; if (traits.get_supports_target_humidity()) resp.target_humidity = climate->target_humidity; return encode_message_to_buffer(resp, ClimateStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::send_climate_info(climate::Climate *climate) { this->schedule_message_(climate, &APIConnection::try_send_climate_info, ListEntitiesClimateResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_climate_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *climate = static_cast(entity); ListEntitiesClimateResponse msg; auto traits = climate->get_traits(); msg.supports_current_temperature = traits.get_supports_current_temperature(); msg.supports_current_humidity = traits.get_supports_current_humidity(); msg.supports_two_point_target_temperature = traits.get_supports_two_point_target_temperature(); msg.supports_target_humidity = traits.get_supports_target_humidity(); for (auto mode : traits.get_supported_modes()) msg.supported_modes.push_back(static_cast(mode)); msg.visual_min_temperature = traits.get_visual_min_temperature(); msg.visual_max_temperature = traits.get_visual_max_temperature(); msg.visual_target_temperature_step = traits.get_visual_target_temperature_step(); msg.visual_current_temperature_step = traits.get_visual_current_temperature_step(); msg.visual_min_humidity = traits.get_visual_min_humidity(); msg.visual_max_humidity = traits.get_visual_max_humidity(); msg.legacy_supports_away = traits.supports_preset(climate::CLIMATE_PRESET_AWAY); msg.supports_action = traits.get_supports_action(); for (auto fan_mode : traits.get_supported_fan_modes()) msg.supported_fan_modes.push_back(static_cast(fan_mode)); for (auto const &custom_fan_mode : traits.get_supported_custom_fan_modes()) msg.supported_custom_fan_modes.push_back(custom_fan_mode); for (auto preset : traits.get_supported_presets()) msg.supported_presets.push_back(static_cast(preset)); for (auto const &custom_preset : traits.get_supported_custom_presets()) msg.supported_custom_presets.push_back(custom_preset); for (auto swing_mode : traits.get_supported_swing_modes()) msg.supported_swing_modes.push_back(static_cast(swing_mode)); msg.unique_id = get_default_unique_id("climate", climate); fill_entity_info_base(climate, msg); return encode_message_to_buffer(msg, ListEntitiesClimateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::climate_command(const ClimateCommandRequest &msg) { climate::Climate *climate = App.get_climate_by_key(msg.key); if (climate == nullptr) return; auto call = climate->make_call(); if (msg.has_mode) call.set_mode(static_cast(msg.mode)); if (msg.has_target_temperature) call.set_target_temperature(msg.target_temperature); if (msg.has_target_temperature_low) call.set_target_temperature_low(msg.target_temperature_low); if (msg.has_target_temperature_high) call.set_target_temperature_high(msg.target_temperature_high); if (msg.has_target_humidity) call.set_target_humidity(msg.target_humidity); if (msg.has_fan_mode) call.set_fan_mode(static_cast(msg.fan_mode)); if (msg.has_custom_fan_mode) call.set_fan_mode(msg.custom_fan_mode); if (msg.has_preset) call.set_preset(static_cast(msg.preset)); if (msg.has_custom_preset) call.set_preset(msg.custom_preset); if (msg.has_swing_mode) call.set_swing_mode(static_cast(msg.swing_mode)); call.perform(); } #endif #ifdef USE_NUMBER bool APIConnection::send_number_state(number::Number *number) { return this->schedule_message_(number, &APIConnection::try_send_number_state, NumberStateResponse::MESSAGE_TYPE); } void APIConnection::send_number_info(number::Number *number) { this->schedule_message_(number, &APIConnection::try_send_number_info, ListEntitiesNumberResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_number_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *number = static_cast(entity); NumberStateResponse resp; resp.state = number->state; resp.missing_state = !number->has_state(); fill_entity_state_base(number, resp); return encode_message_to_buffer(resp, NumberStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } uint16_t APIConnection::try_send_number_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *number = static_cast(entity); ListEntitiesNumberResponse msg; msg.unit_of_measurement = number->traits.get_unit_of_measurement(); msg.mode = static_cast(number->traits.get_mode()); msg.device_class = number->traits.get_device_class(); msg.min_value = number->traits.get_min_value(); msg.max_value = number->traits.get_max_value(); msg.step = number->traits.get_step(); msg.unique_id = get_default_unique_id("number", number); fill_entity_info_base(number, msg); return encode_message_to_buffer(msg, ListEntitiesNumberResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::number_command(const NumberCommandRequest &msg) { number::Number *number = App.get_number_by_key(msg.key); if (number == nullptr) return; auto call = number->make_call(); call.set_value(msg.state); call.perform(); } #endif #ifdef USE_DATETIME_DATE bool APIConnection::send_date_state(datetime::DateEntity *date) { return this->schedule_message_(date, &APIConnection::try_send_date_state, DateStateResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_date_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *date = static_cast(entity); DateStateResponse resp; resp.missing_state = !date->has_state(); resp.year = date->year; resp.month = date->month; resp.day = date->day; fill_entity_state_base(date, resp); return encode_message_to_buffer(resp, DateStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::send_date_info(datetime::DateEntity *date) { this->schedule_message_(date, &APIConnection::try_send_date_info, ListEntitiesDateResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_date_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *date = static_cast(entity); ListEntitiesDateResponse msg; msg.unique_id = get_default_unique_id("date", date); fill_entity_info_base(date, msg); return encode_message_to_buffer(msg, ListEntitiesDateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::date_command(const DateCommandRequest &msg) { datetime::DateEntity *date = App.get_date_by_key(msg.key); if (date == nullptr) return; auto call = date->make_call(); call.set_date(msg.year, msg.month, msg.day); call.perform(); } #endif #ifdef USE_DATETIME_TIME bool APIConnection::send_time_state(datetime::TimeEntity *time) { return this->schedule_message_(time, &APIConnection::try_send_time_state, TimeStateResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_time_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *time = static_cast(entity); TimeStateResponse resp; resp.missing_state = !time->has_state(); resp.hour = time->hour; resp.minute = time->minute; resp.second = time->second; fill_entity_state_base(time, resp); return encode_message_to_buffer(resp, TimeStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::send_time_info(datetime::TimeEntity *time) { this->schedule_message_(time, &APIConnection::try_send_time_info, ListEntitiesTimeResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_time_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *time = static_cast(entity); ListEntitiesTimeResponse msg; msg.unique_id = get_default_unique_id("time", time); fill_entity_info_base(time, msg); return encode_message_to_buffer(msg, ListEntitiesTimeResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::time_command(const TimeCommandRequest &msg) { datetime::TimeEntity *time = App.get_time_by_key(msg.key); if (time == nullptr) return; auto call = time->make_call(); call.set_time(msg.hour, msg.minute, msg.second); call.perform(); } #endif #ifdef USE_DATETIME_DATETIME bool APIConnection::send_datetime_state(datetime::DateTimeEntity *datetime) { return this->schedule_message_(datetime, &APIConnection::try_send_datetime_state, DateTimeStateResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_datetime_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *datetime = static_cast(entity); DateTimeStateResponse resp; resp.missing_state = !datetime->has_state(); if (datetime->has_state()) { ESPTime state = datetime->state_as_esptime(); resp.epoch_seconds = state.timestamp; } fill_entity_state_base(datetime, resp); return encode_message_to_buffer(resp, DateTimeStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::send_datetime_info(datetime::DateTimeEntity *datetime) { this->schedule_message_(datetime, &APIConnection::try_send_datetime_info, ListEntitiesDateTimeResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_datetime_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *datetime = static_cast(entity); ListEntitiesDateTimeResponse msg; msg.unique_id = get_default_unique_id("datetime", datetime); fill_entity_info_base(datetime, msg); return encode_message_to_buffer(msg, ListEntitiesDateTimeResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::datetime_command(const DateTimeCommandRequest &msg) { datetime::DateTimeEntity *datetime = App.get_datetime_by_key(msg.key); if (datetime == nullptr) return; auto call = datetime->make_call(); call.set_datetime(msg.epoch_seconds); call.perform(); } #endif #ifdef USE_TEXT bool APIConnection::send_text_state(text::Text *text) { return this->schedule_message_(text, &APIConnection::try_send_text_state, TextStateResponse::MESSAGE_TYPE); } void APIConnection::send_text_info(text::Text *text) { this->schedule_message_(text, &APIConnection::try_send_text_info, ListEntitiesTextResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_text_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *text = static_cast(entity); TextStateResponse resp; resp.state = text->state; resp.missing_state = !text->has_state(); fill_entity_state_base(text, resp); return encode_message_to_buffer(resp, TextStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } uint16_t APIConnection::try_send_text_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *text = static_cast(entity); ListEntitiesTextResponse msg; msg.mode = static_cast(text->traits.get_mode()); msg.min_length = text->traits.get_min_length(); msg.max_length = text->traits.get_max_length(); msg.pattern = text->traits.get_pattern(); msg.unique_id = get_default_unique_id("text", text); fill_entity_info_base(text, msg); return encode_message_to_buffer(msg, ListEntitiesTextResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::text_command(const TextCommandRequest &msg) { text::Text *text = App.get_text_by_key(msg.key); if (text == nullptr) return; auto call = text->make_call(); call.set_value(msg.state); call.perform(); } #endif #ifdef USE_SELECT bool APIConnection::send_select_state(select::Select *select) { return this->schedule_message_(select, &APIConnection::try_send_select_state, SelectStateResponse::MESSAGE_TYPE); } void APIConnection::send_select_info(select::Select *select) { this->schedule_message_(select, &APIConnection::try_send_select_info, ListEntitiesSelectResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_select_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *select = static_cast(entity); SelectStateResponse resp; resp.state = select->state; resp.missing_state = !select->has_state(); fill_entity_state_base(select, resp); return encode_message_to_buffer(resp, SelectStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } uint16_t APIConnection::try_send_select_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *select = static_cast(entity); ListEntitiesSelectResponse msg; for (const auto &option : select->traits.get_options()) msg.options.push_back(option); msg.unique_id = get_default_unique_id("select", select); fill_entity_info_base(select, msg); return encode_message_to_buffer(msg, ListEntitiesSelectResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::select_command(const SelectCommandRequest &msg) { select::Select *select = App.get_select_by_key(msg.key); if (select == nullptr) return; auto call = select->make_call(); call.set_option(msg.state); call.perform(); } #endif #ifdef USE_BUTTON void esphome::api::APIConnection::send_button_info(button::Button *button) { this->schedule_message_(button, &APIConnection::try_send_button_info, ListEntitiesButtonResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_button_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *button = static_cast(entity); ListEntitiesButtonResponse msg; msg.device_class = button->get_device_class(); msg.unique_id = get_default_unique_id("button", button); fill_entity_info_base(button, msg); return encode_message_to_buffer(msg, ListEntitiesButtonResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void esphome::api::APIConnection::button_command(const ButtonCommandRequest &msg) { button::Button *button = App.get_button_by_key(msg.key); if (button == nullptr) return; button->press(); } #endif #ifdef USE_LOCK bool APIConnection::send_lock_state(lock::Lock *a_lock) { return this->schedule_message_(a_lock, &APIConnection::try_send_lock_state, LockStateResponse::MESSAGE_TYPE); } void APIConnection::send_lock_info(lock::Lock *a_lock) { this->schedule_message_(a_lock, &APIConnection::try_send_lock_info, ListEntitiesLockResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_lock_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *a_lock = static_cast(entity); LockStateResponse resp; resp.state = static_cast(a_lock->state); fill_entity_state_base(a_lock, resp); return encode_message_to_buffer(resp, LockStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } uint16_t APIConnection::try_send_lock_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *a_lock = static_cast(entity); ListEntitiesLockResponse msg; msg.assumed_state = a_lock->traits.get_assumed_state(); msg.supports_open = a_lock->traits.get_supports_open(); msg.requires_code = a_lock->traits.get_requires_code(); msg.unique_id = get_default_unique_id("lock", a_lock); fill_entity_info_base(a_lock, msg); return encode_message_to_buffer(msg, ListEntitiesLockResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::lock_command(const LockCommandRequest &msg) { lock::Lock *a_lock = App.get_lock_by_key(msg.key); if (a_lock == nullptr) return; switch (msg.command) { case enums::LOCK_UNLOCK: a_lock->unlock(); break; case enums::LOCK_LOCK: a_lock->lock(); break; case enums::LOCK_OPEN: a_lock->open(); break; } } #endif #ifdef USE_VALVE bool APIConnection::send_valve_state(valve::Valve *valve) { return this->schedule_message_(valve, &APIConnection::try_send_valve_state, ValveStateResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_valve_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *valve = static_cast(entity); ValveStateResponse resp; resp.position = valve->position; resp.current_operation = static_cast(valve->current_operation); fill_entity_state_base(valve, resp); return encode_message_to_buffer(resp, ValveStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::send_valve_info(valve::Valve *valve) { this->schedule_message_(valve, &APIConnection::try_send_valve_info, ListEntitiesValveResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_valve_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *valve = static_cast(entity); ListEntitiesValveResponse msg; auto traits = valve->get_traits(); msg.device_class = valve->get_device_class(); msg.assumed_state = traits.get_is_assumed_state(); msg.supports_position = traits.get_supports_position(); msg.supports_stop = traits.get_supports_stop(); msg.unique_id = get_default_unique_id("valve", valve); fill_entity_info_base(valve, msg); return encode_message_to_buffer(msg, ListEntitiesValveResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::valve_command(const ValveCommandRequest &msg) { valve::Valve *valve = App.get_valve_by_key(msg.key); if (valve == nullptr) return; auto call = valve->make_call(); if (msg.has_position) call.set_position(msg.position); if (msg.stop) call.set_command_stop(); call.perform(); } #endif #ifdef USE_MEDIA_PLAYER bool APIConnection::send_media_player_state(media_player::MediaPlayer *media_player) { return this->schedule_message_(media_player, &APIConnection::try_send_media_player_state, MediaPlayerStateResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_media_player_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *media_player = static_cast(entity); MediaPlayerStateResponse resp; media_player::MediaPlayerState report_state = media_player->state == media_player::MEDIA_PLAYER_STATE_ANNOUNCING ? media_player::MEDIA_PLAYER_STATE_PLAYING : media_player->state; resp.state = static_cast(report_state); resp.volume = media_player->volume; resp.muted = media_player->is_muted(); fill_entity_state_base(media_player, resp); return encode_message_to_buffer(resp, MediaPlayerStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::send_media_player_info(media_player::MediaPlayer *media_player) { this->schedule_message_(media_player, &APIConnection::try_send_media_player_info, ListEntitiesMediaPlayerResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_media_player_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *media_player = static_cast(entity); ListEntitiesMediaPlayerResponse msg; auto traits = media_player->get_traits(); msg.supports_pause = traits.get_supports_pause(); for (auto &supported_format : traits.get_supported_formats()) { MediaPlayerSupportedFormat media_format; media_format.format = supported_format.format; media_format.sample_rate = supported_format.sample_rate; media_format.num_channels = supported_format.num_channels; media_format.purpose = static_cast(supported_format.purpose); media_format.sample_bytes = supported_format.sample_bytes; msg.supported_formats.push_back(media_format); } msg.unique_id = get_default_unique_id("media_player", media_player); fill_entity_info_base(media_player, msg); return encode_message_to_buffer(msg, ListEntitiesMediaPlayerResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::media_player_command(const MediaPlayerCommandRequest &msg) { media_player::MediaPlayer *media_player = App.get_media_player_by_key(msg.key); if (media_player == nullptr) return; auto call = media_player->make_call(); if (msg.has_command) { call.set_command(static_cast(msg.command)); } if (msg.has_volume) { call.set_volume(msg.volume); } if (msg.has_media_url) { call.set_media_url(msg.media_url); } if (msg.has_announcement) { call.set_announcement(msg.announcement); } call.perform(); } #endif #ifdef USE_ESP32_CAMERA void APIConnection::set_camera_state(std::shared_ptr image) { if (!this->state_subscription_) return; if (this->image_reader_.available()) return; if (image->was_requested_by(esphome::esp32_camera::API_REQUESTER) || image->was_requested_by(esphome::esp32_camera::IDLE)) this->image_reader_.set_image(std::move(image)); } void APIConnection::send_camera_info(esp32_camera::ESP32Camera *camera) { this->schedule_message_(camera, &APIConnection::try_send_camera_info, ListEntitiesCameraResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_camera_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *camera = static_cast(entity); ListEntitiesCameraResponse msg; msg.unique_id = get_default_unique_id("camera", camera); fill_entity_info_base(camera, msg); return encode_message_to_buffer(msg, ListEntitiesCameraResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::camera_image(const CameraImageRequest &msg) { if (esp32_camera::global_esp32_camera == nullptr) return; if (msg.single) esp32_camera::global_esp32_camera->request_image(esphome::esp32_camera::API_REQUESTER); if (msg.stream) { esp32_camera::global_esp32_camera->start_stream(esphome::esp32_camera::API_REQUESTER); App.scheduler.set_timeout(this->parent_, "api_esp32_camera_stop_stream", ESP32_CAMERA_STOP_STREAM, []() { esp32_camera::global_esp32_camera->stop_stream(esphome::esp32_camera::API_REQUESTER); }); } } #endif #ifdef USE_HOMEASSISTANT_TIME void APIConnection::on_get_time_response(const GetTimeResponse &value) { if (homeassistant::global_homeassistant_time != nullptr) homeassistant::global_homeassistant_time->set_epoch_time(value.epoch_seconds); } #endif #ifdef USE_BLUETOOTH_PROXY void APIConnection::subscribe_bluetooth_le_advertisements(const SubscribeBluetoothLEAdvertisementsRequest &msg) { bluetooth_proxy::global_bluetooth_proxy->subscribe_api_connection(this, msg.flags); } void APIConnection::unsubscribe_bluetooth_le_advertisements(const UnsubscribeBluetoothLEAdvertisementsRequest &msg) { bluetooth_proxy::global_bluetooth_proxy->unsubscribe_api_connection(this); } bool APIConnection::send_bluetooth_le_advertisement(const BluetoothLEAdvertisementResponse &msg) { if (this->client_api_version_major_ < 1 || this->client_api_version_minor_ < 7) { BluetoothLEAdvertisementResponse resp = msg; for (auto &service : resp.service_data) { service.legacy_data.assign(service.data.begin(), service.data.end()); service.data.clear(); } for (auto &manufacturer_data : resp.manufacturer_data) { manufacturer_data.legacy_data.assign(manufacturer_data.data.begin(), manufacturer_data.data.end()); manufacturer_data.data.clear(); } return this->send_message(resp); } return this->send_message(msg); } void APIConnection::bluetooth_device_request(const BluetoothDeviceRequest &msg) { bluetooth_proxy::global_bluetooth_proxy->bluetooth_device_request(msg); } void APIConnection::bluetooth_gatt_read(const BluetoothGATTReadRequest &msg) { bluetooth_proxy::global_bluetooth_proxy->bluetooth_gatt_read(msg); } void APIConnection::bluetooth_gatt_write(const BluetoothGATTWriteRequest &msg) { bluetooth_proxy::global_bluetooth_proxy->bluetooth_gatt_write(msg); } void APIConnection::bluetooth_gatt_read_descriptor(const BluetoothGATTReadDescriptorRequest &msg) { bluetooth_proxy::global_bluetooth_proxy->bluetooth_gatt_read_descriptor(msg); } void APIConnection::bluetooth_gatt_write_descriptor(const BluetoothGATTWriteDescriptorRequest &msg) { bluetooth_proxy::global_bluetooth_proxy->bluetooth_gatt_write_descriptor(msg); } void APIConnection::bluetooth_gatt_get_services(const BluetoothGATTGetServicesRequest &msg) { bluetooth_proxy::global_bluetooth_proxy->bluetooth_gatt_send_services(msg); } void APIConnection::bluetooth_gatt_notify(const BluetoothGATTNotifyRequest &msg) { bluetooth_proxy::global_bluetooth_proxy->bluetooth_gatt_notify(msg); } BluetoothConnectionsFreeResponse APIConnection::subscribe_bluetooth_connections_free( const SubscribeBluetoothConnectionsFreeRequest &msg) { BluetoothConnectionsFreeResponse resp; resp.free = bluetooth_proxy::global_bluetooth_proxy->get_bluetooth_connections_free(); resp.limit = bluetooth_proxy::global_bluetooth_proxy->get_bluetooth_connections_limit(); return resp; } void APIConnection::bluetooth_scanner_set_mode(const BluetoothScannerSetModeRequest &msg) { bluetooth_proxy::global_bluetooth_proxy->bluetooth_scanner_set_mode( msg.mode == enums::BluetoothScannerMode::BLUETOOTH_SCANNER_MODE_ACTIVE); } #endif #ifdef USE_VOICE_ASSISTANT void APIConnection::subscribe_voice_assistant(const SubscribeVoiceAssistantRequest &msg) { if (voice_assistant::global_voice_assistant != nullptr) { voice_assistant::global_voice_assistant->client_subscription(this, msg.subscribe); } } void APIConnection::on_voice_assistant_response(const VoiceAssistantResponse &msg) { if (voice_assistant::global_voice_assistant != nullptr) { if (voice_assistant::global_voice_assistant->get_api_connection() != this) { return; } if (msg.error) { voice_assistant::global_voice_assistant->failed_to_start(); return; } if (msg.port == 0) { // Use API Audio voice_assistant::global_voice_assistant->start_streaming(); } else { struct sockaddr_storage storage; socklen_t len = sizeof(storage); this->helper_->getpeername((struct sockaddr *) &storage, &len); voice_assistant::global_voice_assistant->start_streaming(&storage, msg.port); } } }; void APIConnection::on_voice_assistant_event_response(const VoiceAssistantEventResponse &msg) { if (voice_assistant::global_voice_assistant != nullptr) { if (voice_assistant::global_voice_assistant->get_api_connection() != this) { return; } voice_assistant::global_voice_assistant->on_event(msg); } } void APIConnection::on_voice_assistant_audio(const VoiceAssistantAudio &msg) { if (voice_assistant::global_voice_assistant != nullptr) { if (voice_assistant::global_voice_assistant->get_api_connection() != this) { return; } voice_assistant::global_voice_assistant->on_audio(msg); } }; void APIConnection::on_voice_assistant_timer_event_response(const VoiceAssistantTimerEventResponse &msg) { if (voice_assistant::global_voice_assistant != nullptr) { if (voice_assistant::global_voice_assistant->get_api_connection() != this) { return; } voice_assistant::global_voice_assistant->on_timer_event(msg); } }; void APIConnection::on_voice_assistant_announce_request(const VoiceAssistantAnnounceRequest &msg) { if (voice_assistant::global_voice_assistant != nullptr) { if (voice_assistant::global_voice_assistant->get_api_connection() != this) { return; } voice_assistant::global_voice_assistant->on_announce(msg); } } VoiceAssistantConfigurationResponse APIConnection::voice_assistant_get_configuration( const VoiceAssistantConfigurationRequest &msg) { VoiceAssistantConfigurationResponse resp; if (voice_assistant::global_voice_assistant != nullptr) { if (voice_assistant::global_voice_assistant->get_api_connection() != this) { return resp; } auto &config = voice_assistant::global_voice_assistant->get_configuration(); for (auto &wake_word : config.available_wake_words) { VoiceAssistantWakeWord resp_wake_word; resp_wake_word.id = wake_word.id; resp_wake_word.wake_word = wake_word.wake_word; for (const auto &lang : wake_word.trained_languages) { resp_wake_word.trained_languages.push_back(lang); } resp.available_wake_words.push_back(std::move(resp_wake_word)); } for (auto &wake_word_id : config.active_wake_words) { resp.active_wake_words.push_back(wake_word_id); } resp.max_active_wake_words = config.max_active_wake_words; } return resp; } void APIConnection::voice_assistant_set_configuration(const VoiceAssistantSetConfiguration &msg) { if (voice_assistant::global_voice_assistant != nullptr) { if (voice_assistant::global_voice_assistant->get_api_connection() != this) { return; } voice_assistant::global_voice_assistant->on_set_configuration(msg.active_wake_words); } } #endif #ifdef USE_ALARM_CONTROL_PANEL bool APIConnection::send_alarm_control_panel_state(alarm_control_panel::AlarmControlPanel *a_alarm_control_panel) { return this->schedule_message_(a_alarm_control_panel, &APIConnection::try_send_alarm_control_panel_state, AlarmControlPanelStateResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_alarm_control_panel_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *a_alarm_control_panel = static_cast(entity); AlarmControlPanelStateResponse resp; resp.state = static_cast(a_alarm_control_panel->get_state()); fill_entity_state_base(a_alarm_control_panel, resp); return encode_message_to_buffer(resp, AlarmControlPanelStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::send_alarm_control_panel_info(alarm_control_panel::AlarmControlPanel *a_alarm_control_panel) { this->schedule_message_(a_alarm_control_panel, &APIConnection::try_send_alarm_control_panel_info, ListEntitiesAlarmControlPanelResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_alarm_control_panel_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *a_alarm_control_panel = static_cast(entity); ListEntitiesAlarmControlPanelResponse msg; msg.supported_features = a_alarm_control_panel->get_supported_features(); msg.requires_code = a_alarm_control_panel->get_requires_code(); msg.requires_code_to_arm = a_alarm_control_panel->get_requires_code_to_arm(); msg.unique_id = get_default_unique_id("alarm_control_panel", a_alarm_control_panel); fill_entity_info_base(a_alarm_control_panel, msg); return encode_message_to_buffer(msg, ListEntitiesAlarmControlPanelResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::alarm_control_panel_command(const AlarmControlPanelCommandRequest &msg) { alarm_control_panel::AlarmControlPanel *a_alarm_control_panel = App.get_alarm_control_panel_by_key(msg.key); if (a_alarm_control_panel == nullptr) return; auto call = a_alarm_control_panel->make_call(); switch (msg.command) { case enums::ALARM_CONTROL_PANEL_DISARM: call.disarm(); break; case enums::ALARM_CONTROL_PANEL_ARM_AWAY: call.arm_away(); break; case enums::ALARM_CONTROL_PANEL_ARM_HOME: call.arm_home(); break; case enums::ALARM_CONTROL_PANEL_ARM_NIGHT: call.arm_night(); break; case enums::ALARM_CONTROL_PANEL_ARM_VACATION: call.arm_vacation(); break; case enums::ALARM_CONTROL_PANEL_ARM_CUSTOM_BYPASS: call.arm_custom_bypass(); break; case enums::ALARM_CONTROL_PANEL_TRIGGER: call.pending(); break; } call.set_code(msg.code); call.perform(); } #endif #ifdef USE_EVENT void APIConnection::send_event(event::Event *event, const std::string &event_type) { this->schedule_message_(event, MessageCreator(event_type, EventResponse::MESSAGE_TYPE), EventResponse::MESSAGE_TYPE); } void APIConnection::send_event_info(event::Event *event) { this->schedule_message_(event, &APIConnection::try_send_event_info, ListEntitiesEventResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_event_response(event::Event *event, const std::string &event_type, APIConnection *conn, uint32_t remaining_size, bool is_single) { EventResponse resp; resp.event_type = event_type; fill_entity_state_base(event, resp); return encode_message_to_buffer(resp, EventResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } uint16_t APIConnection::try_send_event_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *event = static_cast(entity); ListEntitiesEventResponse msg; msg.device_class = event->get_device_class(); for (const auto &event_type : event->get_event_types()) msg.event_types.push_back(event_type); msg.unique_id = get_default_unique_id("event", event); fill_entity_info_base(event, msg); return encode_message_to_buffer(msg, ListEntitiesEventResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } #endif #ifdef USE_UPDATE bool APIConnection::send_update_state(update::UpdateEntity *update) { return this->schedule_message_(update, &APIConnection::try_send_update_state, UpdateStateResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_update_state(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *update = static_cast(entity); UpdateStateResponse resp; resp.missing_state = !update->has_state(); if (update->has_state()) { resp.in_progress = update->state == update::UpdateState::UPDATE_STATE_INSTALLING; if (update->update_info.has_progress) { resp.has_progress = true; resp.progress = update->update_info.progress; } resp.current_version = update->update_info.current_version; resp.latest_version = update->update_info.latest_version; resp.title = update->update_info.title; resp.release_summary = update->update_info.summary; resp.release_url = update->update_info.release_url; } fill_entity_state_base(update, resp); return encode_message_to_buffer(resp, UpdateStateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::send_update_info(update::UpdateEntity *update) { this->schedule_message_(update, &APIConnection::try_send_update_info, ListEntitiesUpdateResponse::MESSAGE_TYPE); } uint16_t APIConnection::try_send_update_info(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { auto *update = static_cast(entity); ListEntitiesUpdateResponse msg; msg.device_class = update->get_device_class(); msg.unique_id = get_default_unique_id("update", update); fill_entity_info_base(update, msg); return encode_message_to_buffer(msg, ListEntitiesUpdateResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } void APIConnection::update_command(const UpdateCommandRequest &msg) { update::UpdateEntity *update = App.get_update_by_key(msg.key); if (update == nullptr) return; switch (msg.command) { case enums::UPDATE_COMMAND_UPDATE: update->perform(); break; case enums::UPDATE_COMMAND_CHECK: update->check(); break; case enums::UPDATE_COMMAND_NONE: ESP_LOGE(TAG, "UPDATE_COMMAND_NONE not handled; confirm command is correct"); break; default: ESP_LOGW(TAG, "Unknown update command: %" PRIu32, msg.command); break; } } #endif bool APIConnection::try_send_log_message(int level, const char *tag, const char *line) { if (this->log_subscription_ < level) return false; // Pre-calculate message size to avoid reallocations const size_t line_length = strlen(line); uint32_t msg_size = 0; // Add size for level field (field ID 1, varint type) // 1 byte for field tag + size of the level varint msg_size += 1 + api::ProtoSize::varint(static_cast(level)); // Add size for string field (field ID 3, string type) // 1 byte for field tag + size of length varint + string length msg_size += 1 + api::ProtoSize::varint(static_cast(line_length)) + line_length; // Create a pre-sized buffer auto buffer = this->create_buffer(msg_size); // Encode the message (SubscribeLogsResponse) buffer.encode_uint32(1, static_cast(level)); // LogLevel level = 1 buffer.encode_string(3, line, line_length); // string message = 3 // SubscribeLogsResponse - 29 return this->send_buffer(buffer, SubscribeLogsResponse::MESSAGE_TYPE); } HelloResponse APIConnection::hello(const HelloRequest &msg) { this->client_info_ = msg.client_info; this->client_peername_ = this->helper_->getpeername(); this->helper_->set_log_info(this->get_client_combined_info()); this->client_api_version_major_ = msg.api_version_major; this->client_api_version_minor_ = msg.api_version_minor; ESP_LOGV(TAG, "Hello from client: '%s' | %s | API Version %" PRIu32 ".%" PRIu32, this->client_info_.c_str(), this->client_peername_.c_str(), this->client_api_version_major_, this->client_api_version_minor_); HelloResponse resp; resp.api_version_major = 1; resp.api_version_minor = 10; resp.server_info = App.get_name() + " (esphome v" ESPHOME_VERSION ")"; resp.name = App.get_name(); this->connection_state_ = ConnectionState::CONNECTED; return resp; } ConnectResponse APIConnection::connect(const ConnectRequest &msg) { bool correct = this->parent_->check_password(msg.password); ConnectResponse resp; // bool invalid_password = 1; resp.invalid_password = !correct; if (correct) { ESP_LOGD(TAG, "%s connected", this->get_client_combined_info().c_str()); this->connection_state_ = ConnectionState::AUTHENTICATED; this->parent_->get_client_connected_trigger()->trigger(this->client_info_, this->client_peername_); #ifdef USE_HOMEASSISTANT_TIME if (homeassistant::global_homeassistant_time != nullptr) { this->send_time_request(); } #endif } return resp; } DeviceInfoResponse APIConnection::device_info(const DeviceInfoRequest &msg) { DeviceInfoResponse resp{}; resp.uses_password = this->parent_->uses_password(); resp.name = App.get_name(); resp.friendly_name = App.get_friendly_name(); resp.suggested_area = App.get_area(); resp.mac_address = get_mac_address_pretty(); resp.esphome_version = ESPHOME_VERSION; resp.compilation_time = App.get_compilation_time(); #if defined(USE_ESP8266) || defined(USE_ESP32) resp.manufacturer = "Espressif"; #elif defined(USE_RP2040) resp.manufacturer = "Raspberry Pi"; #elif defined(USE_BK72XX) resp.manufacturer = "Beken"; #elif defined(USE_RTL87XX) resp.manufacturer = "Realtek"; #elif defined(USE_HOST) resp.manufacturer = "Host"; #endif resp.model = ESPHOME_BOARD; #ifdef USE_DEEP_SLEEP resp.has_deep_sleep = deep_sleep::global_has_deep_sleep; #endif #ifdef ESPHOME_PROJECT_NAME resp.project_name = ESPHOME_PROJECT_NAME; resp.project_version = ESPHOME_PROJECT_VERSION; #endif #ifdef USE_WEBSERVER resp.webserver_port = USE_WEBSERVER_PORT; #endif #ifdef USE_BLUETOOTH_PROXY resp.legacy_bluetooth_proxy_version = bluetooth_proxy::global_bluetooth_proxy->get_legacy_version(); resp.bluetooth_proxy_feature_flags = bluetooth_proxy::global_bluetooth_proxy->get_feature_flags(); resp.bluetooth_mac_address = bluetooth_proxy::global_bluetooth_proxy->get_bluetooth_mac_address_pretty(); #endif #ifdef USE_VOICE_ASSISTANT resp.legacy_voice_assistant_version = voice_assistant::global_voice_assistant->get_legacy_version(); resp.voice_assistant_feature_flags = voice_assistant::global_voice_assistant->get_feature_flags(); #endif #ifdef USE_API_NOISE resp.api_encryption_supported = true; #endif #ifdef USE_DEVICES for (auto const &device : App.get_devices()) { DeviceInfo device_info; device_info.device_id = device->get_device_id(); device_info.name = device->get_name(); device_info.area_id = device->get_area_id(); resp.devices.push_back(device_info); } #endif #ifdef USE_AREAS for (auto const &area : App.get_areas()) { AreaInfo area_info; area_info.area_id = area->get_area_id(); area_info.name = area->get_name(); resp.areas.push_back(area_info); } #endif return resp; } void APIConnection::on_home_assistant_state_response(const HomeAssistantStateResponse &msg) { for (auto &it : this->parent_->get_state_subs()) { if (it.entity_id == msg.entity_id && it.attribute.value() == msg.attribute) { it.callback(msg.state); } } } void APIConnection::execute_service(const ExecuteServiceRequest &msg) { bool found = false; for (auto *service : this->parent_->get_user_services()) { if (service->execute_service(msg)) { found = true; } } if (!found) { ESP_LOGV(TAG, "Could not find service"); } } #ifdef USE_API_NOISE NoiseEncryptionSetKeyResponse APIConnection::noise_encryption_set_key(const NoiseEncryptionSetKeyRequest &msg) { psk_t psk{}; NoiseEncryptionSetKeyResponse resp; if (base64_decode(msg.key, psk.data(), msg.key.size()) != psk.size()) { ESP_LOGW(TAG, "Invalid encryption key length"); resp.success = false; return resp; } if (!this->parent_->save_noise_psk(psk, true)) { ESP_LOGW(TAG, "Failed to save encryption key"); resp.success = false; return resp; } resp.success = true; return resp; } #endif void APIConnection::subscribe_home_assistant_states(const SubscribeHomeAssistantStatesRequest &msg) { state_subs_at_ = 0; } bool APIConnection::try_to_clear_buffer(bool log_out_of_space) { if (this->remove_) return false; if (this->helper_->can_write_without_blocking()) return true; delay(0); APIError err = this->helper_->loop(); if (err != APIError::OK) { on_fatal_error(); ESP_LOGW(TAG, "%s: Socket operation failed: %s errno=%d", this->get_client_combined_info().c_str(), api_error_to_str(err), errno); return false; } if (this->helper_->can_write_without_blocking()) return true; if (log_out_of_space) { ESP_LOGV(TAG, "Cannot send message because of TCP buffer space"); } return false; } bool APIConnection::send_buffer(ProtoWriteBuffer buffer, uint16_t message_type) { if (!this->try_to_clear_buffer(message_type != SubscribeLogsResponse::MESSAGE_TYPE)) { // SubscribeLogsResponse return false; } APIError err = this->helper_->write_protobuf_packet(message_type, buffer); if (err == APIError::WOULD_BLOCK) return false; if (err != APIError::OK) { on_fatal_error(); if (err == APIError::SOCKET_WRITE_FAILED && errno == ECONNRESET) { ESP_LOGW(TAG, "%s: Connection reset", this->get_client_combined_info().c_str()); } else { ESP_LOGW(TAG, "%s: Packet write failed %s errno=%d", this->get_client_combined_info().c_str(), api_error_to_str(err), errno); } return false; } // Do not set last_traffic_ on send return true; } void APIConnection::on_unauthenticated_access() { this->on_fatal_error(); ESP_LOGD(TAG, "%s requested access without authentication", this->get_client_combined_info().c_str()); } void APIConnection::on_no_setup_connection() { this->on_fatal_error(); ESP_LOGD(TAG, "%s requested access without full connection", this->get_client_combined_info().c_str()); } void APIConnection::on_fatal_error() { this->helper_->close(); this->remove_ = true; } void APIConnection::DeferredBatch::add_item(EntityBase *entity, MessageCreator creator, uint16_t message_type) { // Check if we already have a message of this type for this entity // This provides deduplication per entity/message_type combination // O(n) but optimized for RAM and not performance. for (auto &item : items) { if (item.entity == entity && item.message_type == message_type) { // Update the existing item with the new creator item.creator = std::move(creator); return; } } // No existing item found, add new one items.emplace_back(entity, std::move(creator), message_type); } bool APIConnection::schedule_batch_() { if (!this->deferred_batch_.batch_scheduled) { this->deferred_batch_.batch_scheduled = true; this->deferred_batch_.batch_start_time = App.get_loop_component_start_time(); } return true; } ProtoWriteBuffer APIConnection::allocate_single_message_buffer(uint16_t size) { return this->create_buffer(size); } ProtoWriteBuffer APIConnection::allocate_batch_message_buffer(uint16_t size) { ProtoWriteBuffer result = this->prepare_message_buffer(size, this->batch_first_message_); this->batch_first_message_ = false; return result; } void APIConnection::process_batch_() { if (this->deferred_batch_.empty()) { this->deferred_batch_.batch_scheduled = false; return; } // Try to clear buffer first if (!this->try_to_clear_buffer(true)) { // Can't write now, we'll try again later return; } size_t num_items = this->deferred_batch_.items.size(); // Fast path for single message - allocate exact size needed if (num_items == 1) { const auto &item = this->deferred_batch_.items[0]; // Let the creator calculate size and encode if it fits uint16_t payload_size = item.creator(item.entity, this, std::numeric_limits::max(), true); if (payload_size > 0 && this->send_buffer(ProtoWriteBuffer{&this->parent_->get_shared_buffer_ref()}, item.message_type)) { this->deferred_batch_.clear(); } else if (payload_size == 0) { // Message too large ESP_LOGW(TAG, "Message too large to send: type=%u", item.message_type); this->deferred_batch_.clear(); } return; } // Pre-allocate storage for packet info std::vector packet_info; packet_info.reserve(num_items); // Cache these values to avoid repeated virtual calls const uint8_t header_padding = this->helper_->frame_header_padding(); const uint8_t footer_size = this->helper_->frame_footer_size(); // Initialize buffer and tracking variables this->parent_->get_shared_buffer_ref().clear(); // Pre-calculate exact buffer size needed based on message types uint32_t total_estimated_size = 0; for (const auto &item : this->deferred_batch_.items) { total_estimated_size += get_estimated_message_size(item.message_type); } // Calculate total overhead for all messages uint32_t total_overhead = (header_padding + footer_size) * num_items; // Reserve based on estimated size (much more accurate than 24-byte worst-case) this->parent_->get_shared_buffer_ref().reserve(total_estimated_size + total_overhead); this->batch_first_message_ = true; size_t items_processed = 0; uint16_t remaining_size = std::numeric_limits::max(); // Track where each message's header padding begins in the buffer // For plaintext: this is where the 6-byte header padding starts // For noise: this is where the 7-byte header padding starts // The actual message data follows after the header padding uint32_t current_offset = 0; // Process items and encode directly to buffer for (const auto &item : this->deferred_batch_.items) { // Try to encode message // The creator will calculate overhead to determine if the message fits uint16_t payload_size = item.creator(item.entity, this, remaining_size, false); if (payload_size == 0) { // Message won't fit, stop processing break; } // Message was encoded successfully // payload_size is header_padding + actual payload size + footer_size uint16_t proto_payload_size = payload_size - header_padding - footer_size; packet_info.emplace_back(item.message_type, current_offset, proto_payload_size); // Update tracking variables items_processed++; // After first message, set remaining size to MAX_PACKET_SIZE to avoid fragmentation if (items_processed == 1) { remaining_size = MAX_PACKET_SIZE; } remaining_size -= payload_size; // Calculate where the next message's header padding will start // Current buffer size + footer space (that prepare_message_buffer will add for this message) current_offset = this->parent_->get_shared_buffer_ref().size() + footer_size; } if (items_processed == 0) { this->deferred_batch_.clear(); return; } // Add footer space for the last message (for Noise protocol MAC) if (footer_size > 0) { auto &shared_buf = this->parent_->get_shared_buffer_ref(); shared_buf.resize(shared_buf.size() + footer_size); } // Send all collected packets APIError err = this->helper_->write_protobuf_packets(ProtoWriteBuffer{&this->parent_->get_shared_buffer_ref()}, packet_info); if (err != APIError::OK && err != APIError::WOULD_BLOCK) { on_fatal_error(); if (err == APIError::SOCKET_WRITE_FAILED && errno == ECONNRESET) { ESP_LOGW(TAG, "%s: Connection reset during batch write", this->get_client_combined_info().c_str()); } else { ESP_LOGW(TAG, "%s: Batch write failed %s errno=%d", this->get_client_combined_info().c_str(), api_error_to_str(err), errno); } } // Handle remaining items more efficiently if (items_processed < this->deferred_batch_.items.size()) { // Remove processed items from the beginning this->deferred_batch_.items.erase(this->deferred_batch_.items.begin(), this->deferred_batch_.items.begin() + items_processed); // Reschedule for remaining items this->schedule_batch_(); } else { // All items processed this->deferred_batch_.clear(); } } uint16_t APIConnection::MessageCreator::operator()(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) const { switch (message_type_) { case 0: // Function pointer return data_.ptr(entity, conn, remaining_size, is_single); #ifdef USE_EVENT case EventResponse::MESSAGE_TYPE: { auto *e = static_cast(entity); return APIConnection::try_send_event_response(e, *data_.string_ptr, conn, remaining_size, is_single); } #endif default: // Should not happen, return 0 to indicate no message return 0; } } uint16_t APIConnection::try_send_list_info_done(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { ListEntitiesDoneResponse resp; return encode_message_to_buffer(resp, ListEntitiesDoneResponse::MESSAGE_TYPE, conn, remaining_size, is_single); } uint16_t APIConnection::try_send_disconnect_request(EntityBase *entity, APIConnection *conn, uint32_t remaining_size, bool is_single) { DisconnectRequest req; return encode_message_to_buffer(req, DisconnectRequest::MESSAGE_TYPE, conn, remaining_size, is_single); } uint16_t APIConnection::get_estimated_message_size(uint16_t message_type) { // Use generated ESTIMATED_SIZE constants from each message type switch (message_type) { #ifdef USE_BINARY_SENSOR case BinarySensorStateResponse::MESSAGE_TYPE: return BinarySensorStateResponse::ESTIMATED_SIZE; case ListEntitiesBinarySensorResponse::MESSAGE_TYPE: return ListEntitiesBinarySensorResponse::ESTIMATED_SIZE; #endif #ifdef USE_SENSOR case SensorStateResponse::MESSAGE_TYPE: return SensorStateResponse::ESTIMATED_SIZE; case ListEntitiesSensorResponse::MESSAGE_TYPE: return ListEntitiesSensorResponse::ESTIMATED_SIZE; #endif #ifdef USE_SWITCH case SwitchStateResponse::MESSAGE_TYPE: return SwitchStateResponse::ESTIMATED_SIZE; case ListEntitiesSwitchResponse::MESSAGE_TYPE: return ListEntitiesSwitchResponse::ESTIMATED_SIZE; #endif #ifdef USE_TEXT_SENSOR case TextSensorStateResponse::MESSAGE_TYPE: return TextSensorStateResponse::ESTIMATED_SIZE; case ListEntitiesTextSensorResponse::MESSAGE_TYPE: return ListEntitiesTextSensorResponse::ESTIMATED_SIZE; #endif #ifdef USE_NUMBER case NumberStateResponse::MESSAGE_TYPE: return NumberStateResponse::ESTIMATED_SIZE; case ListEntitiesNumberResponse::MESSAGE_TYPE: return ListEntitiesNumberResponse::ESTIMATED_SIZE; #endif #ifdef USE_TEXT case TextStateResponse::MESSAGE_TYPE: return TextStateResponse::ESTIMATED_SIZE; case ListEntitiesTextResponse::MESSAGE_TYPE: return ListEntitiesTextResponse::ESTIMATED_SIZE; #endif #ifdef USE_SELECT case SelectStateResponse::MESSAGE_TYPE: return SelectStateResponse::ESTIMATED_SIZE; case ListEntitiesSelectResponse::MESSAGE_TYPE: return ListEntitiesSelectResponse::ESTIMATED_SIZE; #endif #ifdef USE_LOCK case LockStateResponse::MESSAGE_TYPE: return LockStateResponse::ESTIMATED_SIZE; case ListEntitiesLockResponse::MESSAGE_TYPE: return ListEntitiesLockResponse::ESTIMATED_SIZE; #endif #ifdef USE_EVENT case EventResponse::MESSAGE_TYPE: return EventResponse::ESTIMATED_SIZE; case ListEntitiesEventResponse::MESSAGE_TYPE: return ListEntitiesEventResponse::ESTIMATED_SIZE; #endif #ifdef USE_COVER case CoverStateResponse::MESSAGE_TYPE: return CoverStateResponse::ESTIMATED_SIZE; case ListEntitiesCoverResponse::MESSAGE_TYPE: return ListEntitiesCoverResponse::ESTIMATED_SIZE; #endif #ifdef USE_FAN case FanStateResponse::MESSAGE_TYPE: return FanStateResponse::ESTIMATED_SIZE; case ListEntitiesFanResponse::MESSAGE_TYPE: return ListEntitiesFanResponse::ESTIMATED_SIZE; #endif #ifdef USE_LIGHT case LightStateResponse::MESSAGE_TYPE: return LightStateResponse::ESTIMATED_SIZE; case ListEntitiesLightResponse::MESSAGE_TYPE: return ListEntitiesLightResponse::ESTIMATED_SIZE; #endif #ifdef USE_CLIMATE case ClimateStateResponse::MESSAGE_TYPE: return ClimateStateResponse::ESTIMATED_SIZE; case ListEntitiesClimateResponse::MESSAGE_TYPE: return ListEntitiesClimateResponse::ESTIMATED_SIZE; #endif #ifdef USE_ESP32_CAMERA case ListEntitiesCameraResponse::MESSAGE_TYPE: return ListEntitiesCameraResponse::ESTIMATED_SIZE; #endif #ifdef USE_BUTTON case ListEntitiesButtonResponse::MESSAGE_TYPE: return ListEntitiesButtonResponse::ESTIMATED_SIZE; #endif #ifdef USE_MEDIA_PLAYER case MediaPlayerStateResponse::MESSAGE_TYPE: return MediaPlayerStateResponse::ESTIMATED_SIZE; case ListEntitiesMediaPlayerResponse::MESSAGE_TYPE: return ListEntitiesMediaPlayerResponse::ESTIMATED_SIZE; #endif #ifdef USE_ALARM_CONTROL_PANEL case AlarmControlPanelStateResponse::MESSAGE_TYPE: return AlarmControlPanelStateResponse::ESTIMATED_SIZE; case ListEntitiesAlarmControlPanelResponse::MESSAGE_TYPE: return ListEntitiesAlarmControlPanelResponse::ESTIMATED_SIZE; #endif #ifdef USE_DATETIME_DATE case DateStateResponse::MESSAGE_TYPE: return DateStateResponse::ESTIMATED_SIZE; case ListEntitiesDateResponse::MESSAGE_TYPE: return ListEntitiesDateResponse::ESTIMATED_SIZE; #endif #ifdef USE_DATETIME_TIME case TimeStateResponse::MESSAGE_TYPE: return TimeStateResponse::ESTIMATED_SIZE; case ListEntitiesTimeResponse::MESSAGE_TYPE: return ListEntitiesTimeResponse::ESTIMATED_SIZE; #endif #ifdef USE_DATETIME_DATETIME case DateTimeStateResponse::MESSAGE_TYPE: return DateTimeStateResponse::ESTIMATED_SIZE; case ListEntitiesDateTimeResponse::MESSAGE_TYPE: return ListEntitiesDateTimeResponse::ESTIMATED_SIZE; #endif #ifdef USE_VALVE case ValveStateResponse::MESSAGE_TYPE: return ValveStateResponse::ESTIMATED_SIZE; case ListEntitiesValveResponse::MESSAGE_TYPE: return ListEntitiesValveResponse::ESTIMATED_SIZE; #endif #ifdef USE_UPDATE case UpdateStateResponse::MESSAGE_TYPE: return UpdateStateResponse::ESTIMATED_SIZE; case ListEntitiesUpdateResponse::MESSAGE_TYPE: return ListEntitiesUpdateResponse::ESTIMATED_SIZE; #endif case ListEntitiesServicesResponse::MESSAGE_TYPE: return ListEntitiesServicesResponse::ESTIMATED_SIZE; case ListEntitiesDoneResponse::MESSAGE_TYPE: return ListEntitiesDoneResponse::ESTIMATED_SIZE; case DisconnectRequest::MESSAGE_TYPE: return DisconnectRequest::ESTIMATED_SIZE; default: // Fallback for unknown message types return 24; } } } // namespace api } // namespace esphome #endif