#include "zh_espnow_sensor.h" sensor_config_t sensor_main_config = {0}; void app_main(void) { sensor_config_t *sensor_config = &sensor_main_config; nvs_flash_init(); esp_netif_init(); esp_event_loop_create_default(); zh_load_config(sensor_config); zh_sensor_init(sensor_config); uint8_t power_selection_pin = zh_load_power_selection_pin(); if (power_selection_pin != ZH_NOT_USED && sensor_config->hardware_config.battery_power == true) { gpio_config_t config = {0}; config.intr_type = GPIO_INTR_DISABLE; config.mode = GPIO_MODE_INPUT; config.pin_bit_mask = (1ULL << power_selection_pin); config.pull_down_en = GPIO_PULLDOWN_DISABLE; config.pull_up_en = GPIO_PULLUP_ENABLE; gpio_config(&config); if (gpio_get_level(power_selection_pin) == 0) { sensor_config->hardware_config.battery_power = false; } } wifi_init_config_t wifi_init_config = WIFI_INIT_CONFIG_DEFAULT(); esp_wifi_init(&wifi_init_config); esp_wifi_set_mode(WIFI_MODE_STA); esp_wifi_set_protocol(WIFI_IF_STA, WIFI_PROTOCOL_11B); esp_wifi_start(); #ifdef CONFIG_NETWORK_TYPE_DIRECT zh_espnow_init_config_t espnow_init_config = ZH_ESPNOW_INIT_CONFIG_DEFAULT(); zh_espnow_init(&espnow_init_config); #else zh_network_init_config_t network_init_config = ZH_NETWORK_INIT_CONFIG_DEFAULT(); zh_network_init(&network_init_config); #endif #ifdef CONFIG_IDF_TARGET_ESP8266 esp_event_handler_register(ZH_EVENT, ESP_EVENT_ANY_ID, &zh_espnow_event_handler, sensor_config); if (sensor_config->hardware_config.battery_power == true) { zh_sensor_deep_sleep(sensor_config); } #else esp_event_handler_instance_register(ZH_EVENT, ESP_EVENT_ANY_ID, &zh_espnow_event_handler, sensor_config, NULL); if (sensor_config->hardware_config.battery_power == true) { zh_sensor_deep_sleep(sensor_config); } else { const esp_partition_t *running = esp_ota_get_running_partition(); esp_ota_img_states_t ota_state = {0}; esp_ota_get_state_partition(running, &ota_state); if (ota_state == ESP_OTA_IMG_PENDING_VERIFY) { vTaskDelay(60000 / portTICK_PERIOD_MS); esp_ota_mark_app_valid_cancel_rollback(); } } #endif } void zh_load_config(sensor_config_t *sensor_config) { nvs_handle_t nvs_handle = {0}; nvs_open("config", NVS_READWRITE, &nvs_handle); uint8_t config_is_present = {0}; if (nvs_get_u8(nvs_handle, "present", &config_is_present) == ESP_ERR_NVS_NOT_FOUND) { nvs_set_u8(nvs_handle, "present", 0xFE); nvs_close(nvs_handle); #ifdef CONFIG_SENSOR_TYPE_DS18B20 sensor_config->hardware_config.sensor_type = HAST_DS18B20; #elif CONFIG_SENSOR_TYPE_DHT sensor_config->hardware_config.sensor_type = HAST_DHT; #elif CONFIG_SENSOR_TYPE_AHT sensor_config->hardware_config.sensor_type = HAST_AHT; #elif CONFIG_SENSOR_TYPE_BH1750 sensor_config->hardware_config.sensor_type = HAST_BH1750; #else sensor_config->hardware_config.sensor_type = HAST_NONE; #endif #ifdef CONFIG_MEASUREMENT_FREQUENCY sensor_config->hardware_config.measurement_frequency = CONFIG_MEASUREMENT_FREQUENCY; #else sensor_config->hardware_config.measurement_frequency = 300; #endif #ifdef CONFIG_SENSOR_PIN_1 sensor_config->hardware_config.sensor_pin_1 = CONFIG_SENSOR_PIN_1; #else sensor_config->hardware_config.sensor_pin_1 = ZH_NOT_USED; #endif #ifdef CONFIG_SENSOR_PIN_2 sensor_config->hardware_config.sensor_pin_2 = CONFIG_SENSOR_PIN_2; #else sensor_config->hardware_config.sensor_pin_2 = ZH_NOT_USED; #endif #ifdef CONFIG_POWER_CONTROL_PIN sensor_config->hardware_config.power_pin = CONFIG_POWER_CONTROL_PIN; #else sensor_config->hardware_config.power_pin = ZH_NOT_USED; #endif #ifdef CONFIG_BATTERY_POWERED sensor_config->hardware_config.battery_power = true; #else sensor_config->hardware_config.battery_power = false; #endif zh_save_config(sensor_config); return; } nvs_get_u8(nvs_handle, "sensor_type", (uint8_t *)&sensor_config->hardware_config.sensor_type); nvs_get_u8(nvs_handle, "sensor_pin_1", &sensor_config->hardware_config.sensor_pin_1); nvs_get_u8(nvs_handle, "sensor_pin_2", &sensor_config->hardware_config.sensor_pin_2); nvs_get_u8(nvs_handle, "power_pin", &sensor_config->hardware_config.power_pin); nvs_get_u16(nvs_handle, "frequency", &sensor_config->hardware_config.measurement_frequency); nvs_get_u8(nvs_handle, "battery_power", (uint8_t *)&sensor_config->hardware_config.battery_power); nvs_close(nvs_handle); } void zh_save_config(const sensor_config_t *sensor_config) { nvs_handle_t nvs_handle = {0}; nvs_open("config", NVS_READWRITE, &nvs_handle); nvs_set_u8(nvs_handle, "sensor_type", sensor_config->hardware_config.sensor_type); nvs_set_u8(nvs_handle, "sensor_pin_1", sensor_config->hardware_config.sensor_pin_1); nvs_set_u8(nvs_handle, "sensor_pin_2", sensor_config->hardware_config.sensor_pin_2); nvs_set_u8(nvs_handle, "power_pin", sensor_config->hardware_config.power_pin); nvs_set_u16(nvs_handle, "frequency", sensor_config->hardware_config.measurement_frequency); nvs_set_u8(nvs_handle, "battery_power", sensor_config->hardware_config.battery_power); nvs_close(nvs_handle); } uint8_t zh_load_power_selection_pin(void) { uint8_t power_selection_pin = {0}; nvs_handle_t nvs_handle = {0}; nvs_open("selection_pin", NVS_READWRITE, &nvs_handle); uint8_t config_is_present = {0}; if (nvs_get_u8(nvs_handle, "present", &config_is_present) == ESP_ERR_NVS_NOT_FOUND) { nvs_set_u8(nvs_handle, "present", 0xFE); nvs_close(nvs_handle); #ifdef CONFIG_POWER_MODE_USING power_selection_pin = CONFIG_POWER_MODE_PIN; #else uint8_t power_selection_pin = ZH_NOT_USED; #endif zh_save_power_selection_pin(&power_selection_pin); return power_selection_pin; } nvs_get_u8(nvs_handle, "mode_pin", &power_selection_pin); nvs_close(nvs_handle); return power_selection_pin; } void zh_save_power_selection_pin(const uint8_t *power_selection_pin) { nvs_handle_t nvs_handle = {0}; nvs_open("selection_pin", NVS_READWRITE, &nvs_handle); nvs_set_u8(nvs_handle, "mode_pin", *power_selection_pin); nvs_close(nvs_handle); } void zh_sensor_init(sensor_config_t *sensor_config) { if (sensor_config->hardware_config.power_pin != ZH_NOT_USED) { gpio_config_t config = {0}; config.intr_type = GPIO_INTR_DISABLE; config.mode = GPIO_MODE_OUTPUT; config.pin_bit_mask = (1ULL << sensor_config->hardware_config.power_pin); config.pull_down_en = GPIO_PULLDOWN_DISABLE; config.pull_up_en = GPIO_PULLUP_DISABLE; if (gpio_config(&config) != ESP_OK) { sensor_config->hardware_config.power_pin = ZH_NOT_USED; } else { gpio_set_level(sensor_config->hardware_config.power_pin, 0); } } if (sensor_config->hardware_config.sensor_type != HAST_NONE && sensor_config->hardware_config.sensor_pin_1 != ZH_NOT_USED && sensor_config->hardware_config.sensor_pin_2 != ZH_NOT_USED) { #ifdef CONFIG_IDF_TARGET_ESP8266 i2c_config_t i2c_config = { .mode = I2C_MODE_MASTER, .sda_io_num = sensor_config->hardware_config.sensor_pin_1, .sda_pullup_en = GPIO_PULLUP_ENABLE, .scl_io_num = sensor_config->hardware_config.sensor_pin_2, .scl_pullup_en = GPIO_PULLUP_ENABLE, }; i2c_driver_install(I2C_PORT, i2c_config.mode); i2c_param_config(I2C_PORT, &i2c_config); #else i2c_master_bus_config_t i2c_bus_config = { .clk_source = I2C_CLK_SRC_DEFAULT, .i2c_port = I2C_PORT, .scl_io_num = sensor_config->hardware_config.sensor_pin_2, .sda_io_num = sensor_config->hardware_config.sensor_pin_1, .glitch_ignore_cnt = 7, .flags.enable_internal_pullup = true, }; i2c_new_master_bus(&i2c_bus_config, &sensor_config->i2c_bus_handle); #endif } if (sensor_config->hardware_config.sensor_pin_1 != ZH_NOT_USED) { switch (sensor_config->hardware_config.sensor_type) { case HAST_DS18B20: if (zh_onewire_init(sensor_config->hardware_config.sensor_pin_1) != ESP_OK) { goto ZH_SENSOR_ERROR; } break; case HAST_DHT:; zh_dht_init_config_t dht_init_config = ZH_DHT_INIT_CONFIG_DEFAULT(); if (sensor_config->hardware_config.sensor_pin_2 == ZH_NOT_USED) { dht_init_config.sensor_pin = sensor_config->hardware_config.sensor_pin_1; } else { #ifdef CONFIG_IDF_TARGET_ESP8266 dht_init_config.i2c_port = I2C_PORT; #else dht_init_config.i2c_handle = sensor_config->i2c_bus_handle; #endif } if (zh_dht_init(&dht_init_config) != ESP_OK) { goto ZH_SENSOR_ERROR; } break; case HAST_BH1750:; zh_bh1750_init_config_t bh1750_init_config = ZH_BH1750_INIT_CONFIG_DEFAULT(); bh1750_init_config.auto_adjust = true; #ifdef CONFIG_IDF_TARGET_ESP8266 bh1750_init_config.i2c_port = I2C_PORT; #else bh1750_init_config.i2c_handle = sensor_config->i2c_bus_handle; #endif if (zh_bh1750_init(&bh1750_init_config) != ESP_OK) { goto ZH_SENSOR_ERROR; } break; case HAST_BMP280: // For future development. break; case HAST_BME280: // For future development. break; case HAST_BME680: // For future development. break; case HAST_AHT:; zh_aht_init_config_t aht_init_config = ZH_AHT_INIT_CONFIG_DEFAULT(); #ifdef CONFIG_IDF_TARGET_ESP8266 aht_init_config.i2c_port = I2C_PORT; #else aht_init_config.i2c_handle = sensor_config->i2c_bus_handle; #endif if (zh_aht_init(&aht_init_config) != ESP_OK) { goto ZH_SENSOR_ERROR; } break; case HAST_SHT: // For future development. break; case HAST_HTU: // For future development. break; case HAST_HDC1080: // For future development. break; default: ZH_SENSOR_ERROR: sensor_config->hardware_config.sensor_type = HAST_NONE; sensor_config->hardware_config.sensor_pin_1 = ZH_NOT_USED; sensor_config->hardware_config.sensor_pin_2 = ZH_NOT_USED; break; } } } void zh_sensor_deep_sleep(sensor_config_t *sensor_config) { uint8_t gateway[6] = {0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF}; memcpy(sensor_config->gateway_mac, gateway, 6); #ifndef CONFIG_IDF_TARGET_ESP8266 esp_sleep_enable_timer_wakeup(sensor_config->hardware_config.measurement_frequency * 1000000); #endif uint8_t required_message_quantity = 1; zh_send_sensor_hardware_config_message(sensor_config); if (sensor_config->hardware_config.sensor_pin_1 != ZH_NOT_USED && sensor_config->hardware_config.sensor_type != HAST_NONE) { required_message_quantity += zh_send_sensor_config_message(sensor_config); zh_send_sensor_status_message_task(sensor_config); zh_send_sensor_attributes_message_task(sensor_config); } while (sensor_config->sent_message_quantity < (required_message_quantity + 2)) { vTaskDelay(10 / portTICK_PERIOD_MS); } #ifdef CONFIG_IDF_TARGET_ESP8266 esp_deep_sleep(sensor_config->hardware_config.measurement_frequency * 1000000); #else esp_deep_sleep_start(); #endif } void zh_send_sensor_hardware_config_message(const sensor_config_t *sensor_config) { zh_espnow_data_t data = {0}; data.device_type = ZHDT_SENSOR; data.payload_type = ZHPT_HARDWARE; data.payload_data.config_message.sensor_hardware_config_message.sensor_type = sensor_config->hardware_config.sensor_type; data.payload_data.config_message.sensor_hardware_config_message.sensor_pin_1 = sensor_config->hardware_config.sensor_pin_1; data.payload_data.config_message.sensor_hardware_config_message.sensor_pin_2 = sensor_config->hardware_config.sensor_pin_2; data.payload_data.config_message.sensor_hardware_config_message.power_pin = sensor_config->hardware_config.power_pin; data.payload_data.config_message.sensor_hardware_config_message.measurement_frequency = sensor_config->hardware_config.measurement_frequency; data.payload_data.config_message.sensor_hardware_config_message.battery_power = sensor_config->hardware_config.battery_power; zh_send_message(sensor_config->gateway_mac, (uint8_t *)&data, sizeof(zh_espnow_data_t)); } void zh_send_sensor_attributes_message_task(void *pvParameter) { sensor_config_t *sensor_config = pvParameter; const esp_app_desc_t *app_info = get_app_description(); zh_espnow_data_t data = {0}; data.device_type = ZHDT_SENSOR; data.payload_type = ZHPT_ATTRIBUTES; data.payload_data.attributes_message.chip_type = ZH_CHIP_TYPE; data.payload_data.attributes_message.sensor_type = sensor_config->hardware_config.sensor_type; strcpy(data.payload_data.attributes_message.flash_size, CONFIG_ESPTOOLPY_FLASHSIZE); data.payload_data.attributes_message.cpu_frequency = ZH_CPU_FREQUENCY; data.payload_data.attributes_message.reset_reason = (uint8_t)esp_reset_reason(); strcpy(data.payload_data.attributes_message.app_name, app_info->project_name); strcpy(data.payload_data.attributes_message.app_version, app_info->version); for (;;) { data.payload_data.attributes_message.heap_size = esp_get_free_heap_size(); data.payload_data.attributes_message.min_heap_size = esp_get_minimum_free_heap_size(); data.payload_data.attributes_message.uptime = esp_timer_get_time() / 1000000; zh_send_message(sensor_config->gateway_mac, (uint8_t *)&data, sizeof(zh_espnow_data_t)); if (sensor_config->hardware_config.battery_power == true) { return; } vTaskDelay(ZH_SENSOR_ATTRIBUTES_MESSAGE_FREQUENCY * 1000 / portTICK_PERIOD_MS); } vTaskDelete(NULL); } uint8_t zh_send_sensor_config_message(const sensor_config_t *sensor_config) { uint8_t messages_quantity = 0; zh_espnow_data_t data = {0}; data.device_type = ZHDT_SENSOR; data.payload_type = ZHPT_CONFIG; data.payload_data.config_message.sensor_config_message.suggested_display_precision = 1; data.payload_data.config_message.sensor_config_message.expire_after = sensor_config->hardware_config.measurement_frequency * 3; data.payload_data.config_message.sensor_config_message.enabled_by_default = true; data.payload_data.config_message.sensor_config_message.force_update = true; data.payload_data.config_message.sensor_config_message.qos = 2; data.payload_data.config_message.sensor_config_message.retain = true; char *unit_of_measurement = NULL; data.payload_data.config_message.sensor_config_message.unique_id = 1; data.payload_data.config_message.sensor_config_message.sensor_device_class = HASDC_VOLTAGE; unit_of_measurement = "V"; strcpy(data.payload_data.config_message.sensor_config_message.unit_of_measurement, unit_of_measurement); zh_send_message(sensor_config->gateway_mac, (uint8_t *)&data, sizeof(zh_espnow_data_t)); ++messages_quantity; switch (sensor_config->hardware_config.sensor_type) { case HAST_DS18B20: data.payload_data.config_message.sensor_config_message.unique_id = 2; data.payload_data.config_message.sensor_config_message.sensor_device_class = HASDC_TEMPERATURE; unit_of_measurement = "°C"; strcpy(data.payload_data.config_message.sensor_config_message.unit_of_measurement, unit_of_measurement); zh_send_message(sensor_config->gateway_mac, (uint8_t *)&data, sizeof(zh_espnow_data_t)); ++messages_quantity; break; case HAST_DHT: case HAST_AHT: case HAST_SHT: // For future development. case HAST_HTU: // For future development. case HAST_HDC1080: // For future development. data.payload_data.config_message.sensor_config_message.unique_id = 2; data.payload_data.config_message.sensor_config_message.sensor_device_class = HASDC_TEMPERATURE; unit_of_measurement = "°C"; strcpy(data.payload_data.config_message.sensor_config_message.unit_of_measurement, unit_of_measurement); zh_send_message(sensor_config->gateway_mac, (uint8_t *)&data, sizeof(zh_espnow_data_t)); ++messages_quantity; data.payload_data.config_message.sensor_config_message.unique_id = 3; data.payload_data.config_message.sensor_config_message.sensor_device_class = HASDC_HUMIDITY; unit_of_measurement = "%"; strcpy(data.payload_data.config_message.sensor_config_message.unit_of_measurement, unit_of_measurement); zh_send_message(sensor_config->gateway_mac, (uint8_t *)&data, sizeof(zh_espnow_data_t)); ++messages_quantity; break; case HAST_BH1750: data.payload_data.config_message.sensor_config_message.unique_id = 2; data.payload_data.config_message.sensor_config_message.sensor_device_class = HASDC_ILLUMINANCE; unit_of_measurement = "lx"; strcpy(data.payload_data.config_message.sensor_config_message.unit_of_measurement, unit_of_measurement); zh_send_message(sensor_config->gateway_mac, (uint8_t *)&data, sizeof(zh_espnow_data_t)); ++messages_quantity; break; case HAST_BMP280: // For future development. break; case HAST_BME280: // For future development. break; case HAST_BME680: // For future development. break; default: break; } return messages_quantity; } void zh_send_sensor_status_message_task(void *pvParameter) { sensor_config_t *sensor_config = pvParameter; float humidity = 0.0; float temperature = 0.0; float illuminance = 0.0; zh_espnow_data_t data = {0}; data.device_type = ZHDT_SENSOR; data.payload_type = ZHPT_STATE; data.payload_data.status_message.sensor_status_message.sensor_type = sensor_config->hardware_config.sensor_type; for (;;) { if (sensor_config->hardware_config.power_pin != ZH_NOT_USED && sensor_config->hardware_config.sensor_pin_1 != ZH_NOT_USED && sensor_config->hardware_config.sensor_pin_2 == ZH_NOT_USED) { gpio_set_level(sensor_config->hardware_config.power_pin, 1); switch (sensor_config->hardware_config.sensor_type) { case HAST_DS18B20: vTaskDelay(DS18B20_POWER_STABILIZATION_PERIOD / portTICK_PERIOD_MS); break; case HAST_DHT: vTaskDelay(DHT_POWER_STABILIZATION_PERIOD / portTICK_PERIOD_MS); break; default: gpio_set_level(sensor_config->hardware_config.power_pin, 0); break; } } esp_err_t err = ESP_OK; switch (sensor_config->hardware_config.sensor_type) { case HAST_DS18B20: err = zh_ds18b20_read(NULL, &temperature); if (err == ESP_OK) { data.payload_data.status_message.sensor_status_message.temperature = temperature; data.payload_data.status_message.sensor_status_message.voltage = 3.3; // For future development. } break; case HAST_DHT: err = zh_dht_read(&humidity, &temperature); if (err == ESP_OK) { data.payload_data.status_message.sensor_status_message.humidity = humidity; data.payload_data.status_message.sensor_status_message.temperature = temperature; data.payload_data.status_message.sensor_status_message.voltage = 3.3; // For future development. } break; case HAST_BH1750: err = zh_bh1750_read(&illuminance); if (err == ESP_OK) { data.payload_data.status_message.sensor_status_message.illuminance = illuminance; data.payload_data.status_message.sensor_status_message.voltage = 3.3; // For future development. } break; case HAST_BMP280: // For future development. break; case HAST_BME280: // For future development. break; case HAST_BME680: // For future development. break; case HAST_AHT: err = zh_aht_read(&humidity, &temperature); if (err == ESP_OK) { data.payload_data.status_message.sensor_status_message.humidity = humidity; data.payload_data.status_message.sensor_status_message.temperature = temperature; data.payload_data.status_message.sensor_status_message.voltage = 3.3; // For future development. } break; case HAST_SHT: // For future development. break; case HAST_HTU: // For future development. break; case HAST_HDC1080: // For future development. break; default: break; } if (err == ESP_OK) { zh_send_message(sensor_config->gateway_mac, (uint8_t *)&data, sizeof(zh_espnow_data_t)); } else { zh_send_message(sensor_config->gateway_mac, (uint8_t *)&data, sizeof(zh_espnow_data_t)); // For future development. Will be changed for sensor read error message. } if (gpio_get_level(sensor_config->hardware_config.power_pin) == 1) { gpio_set_level(sensor_config->hardware_config.power_pin, 0); } if (sensor_config->hardware_config.battery_power == true) { return; } vTaskDelay(sensor_config->hardware_config.measurement_frequency * 1000 / portTICK_PERIOD_MS); } vTaskDelete(NULL); } void zh_espnow_event_handler(void *arg, esp_event_base_t event_base, int32_t event_id, void *event_data) { sensor_config_t *sensor_config = arg; switch (event_id) { #ifdef CONFIG_NETWORK_TYPE_DIRECT case ZH_ESPNOW_ON_RECV_EVENT:; zh_espnow_event_on_recv_t *recv_data = event_data; if (recv_data->data_len != sizeof(zh_espnow_data_t) || sensor_config->hardware_config.battery_power == true) { goto ZH_ESPNOW_EVENT_HANDLER_EXIT; } #else case ZH_NETWORK_ON_RECV_EVENT:; zh_network_event_on_recv_t *recv_data = event_data; if (recv_data->data_len != sizeof(zh_espnow_data_t) || sensor_config->hardware_config.battery_power == true) { goto ZH_NETWORK_EVENT_HANDLER_EXIT; } #endif zh_espnow_data_t *data = (zh_espnow_data_t *)recv_data->data; switch (data->device_type) { case ZHDT_GATEWAY: switch (data->payload_type) { case ZHPT_KEEP_ALIVE: if (data->payload_data.keep_alive_message.online_status == ZH_ONLINE) { if (sensor_config->gateway_is_available == false) { sensor_config->gateway_is_available = true; memcpy(sensor_config->gateway_mac, recv_data->mac_addr, 6); zh_send_sensor_hardware_config_message(sensor_config); if (sensor_config->hardware_config.sensor_pin_1 != ZH_NOT_USED && sensor_config->hardware_config.sensor_type != HAST_NONE) { zh_send_sensor_config_message(sensor_config); xTaskCreatePinnedToCore(&zh_send_sensor_status_message_task, "NULL", ZH_MESSAGE_STACK_SIZE, sensor_config, ZH_MESSAGE_TASK_PRIORITY, (TaskHandle_t *)&sensor_config->status_message_task, tskNO_AFFINITY); xTaskCreatePinnedToCore(&zh_send_sensor_attributes_message_task, "NULL", ZH_MESSAGE_STACK_SIZE, sensor_config, ZH_MESSAGE_TASK_PRIORITY, (TaskHandle_t *)&sensor_config->attributes_message_task, tskNO_AFFINITY); } } } else { if (sensor_config->gateway_is_available == true) { sensor_config->gateway_is_available = false; if (sensor_config->hardware_config.sensor_pin_1 != ZH_NOT_USED && sensor_config->hardware_config.sensor_type != HAST_NONE) { vTaskDelete(sensor_config->status_message_task); vTaskDelete(sensor_config->attributes_message_task); } } } break; case ZHPT_HARDWARE: sensor_config->hardware_config.sensor_type = data->payload_data.config_message.sensor_hardware_config_message.sensor_type; sensor_config->hardware_config.sensor_pin_1 = data->payload_data.config_message.sensor_hardware_config_message.sensor_pin_1; sensor_config->hardware_config.sensor_pin_2 = data->payload_data.config_message.sensor_hardware_config_message.sensor_pin_2; sensor_config->hardware_config.power_pin = data->payload_data.config_message.sensor_hardware_config_message.power_pin; sensor_config->hardware_config.measurement_frequency = data->payload_data.config_message.sensor_hardware_config_message.measurement_frequency; sensor_config->hardware_config.battery_power = data->payload_data.config_message.sensor_hardware_config_message.battery_power; zh_save_config(sensor_config); esp_restart(); break; case ZHPT_UPDATE:; const esp_app_desc_t *app_info = get_app_description(); sensor_config->update_partition = esp_ota_get_next_update_partition(NULL); strcpy(data->payload_data.ota_message.espnow_ota_data.app_version, app_info->version); #ifdef CONFIG_IDF_TARGET_ESP8266 char *app_name = (char *)heap_caps_malloc(strlen(app_info->project_name) + 6, MALLOC_CAP_8BIT); memset(app_name, 0, strlen(app_info->project_name) + 6); sprintf(app_name, "%s.app%d", app_info->project_name, sensor_config->update_partition->subtype - ESP_PARTITION_SUBTYPE_APP_OTA_0 + 1); strcpy(data->payload_data.ota_message.espnow_ota_data.app_name, app_name); heap_caps_free(app_name); #else strcpy(data->payload_data.ota_message.espnow_ota_data.app_name, app_info->project_name); #endif data->device_type = ZHDT_SENSOR; data->payload_type = ZHPT_UPDATE; zh_send_message(sensor_config->gateway_mac, (uint8_t *)data, sizeof(zh_espnow_data_t)); break; case ZHPT_UPDATE_BEGIN: #ifdef CONFIG_IDF_TARGET_ESP8266 esp_ota_begin(sensor_config->update_partition, OTA_SIZE_UNKNOWN, &sensor_config->update_handle); #else esp_ota_begin(sensor_config->update_partition, OTA_SIZE_UNKNOWN, (esp_ota_handle_t *)&sensor_config->update_handle); #endif sensor_config->ota_message_part_number = 1; data->device_type = ZHDT_SENSOR; data->payload_type = ZHPT_UPDATE_PROGRESS; zh_send_message(sensor_config->gateway_mac, (uint8_t *)data, sizeof(zh_espnow_data_t)); break; case ZHPT_UPDATE_PROGRESS: if (sensor_config->ota_message_part_number == data->payload_data.ota_message.espnow_ota_message.part) { ++sensor_config->ota_message_part_number; esp_ota_write(sensor_config->update_handle, (const void *)data->payload_data.ota_message.espnow_ota_message.data, data->payload_data.ota_message.espnow_ota_message.data_len); } data->device_type = ZHDT_SENSOR; data->payload_type = ZHPT_UPDATE_PROGRESS; zh_send_message(sensor_config->gateway_mac, (uint8_t *)data, sizeof(zh_espnow_data_t)); break; case ZHPT_UPDATE_ERROR: esp_ota_end(sensor_config->update_handle); break; case ZHPT_UPDATE_END: if (esp_ota_end(sensor_config->update_handle) != ESP_OK) { data->device_type = ZHDT_SENSOR; data->payload_type = ZHPT_UPDATE_FAIL; zh_send_message(sensor_config->gateway_mac, (uint8_t *)data, sizeof(zh_espnow_data_t)); break; } esp_ota_set_boot_partition(sensor_config->update_partition); data->device_type = ZHDT_SENSOR; data->payload_type = ZHPT_UPDATE_SUCCESS; zh_send_message(sensor_config->gateway_mac, (uint8_t *)data, sizeof(zh_espnow_data_t)); vTaskDelay(1000 / portTICK_PERIOD_MS); esp_restart(); break; case ZHPT_RESTART: esp_restart(); break; default: break; } break; default: break; } #ifdef CONFIG_NETWORK_TYPE_DIRECT ZH_ESPNOW_EVENT_HANDLER_EXIT: heap_caps_free(recv_data->data); break; case ZH_ESPNOW_ON_SEND_EVENT:; zh_espnow_event_on_send_t *send_data = event_data; if (sensor_config->hardware_config.battery_power == false) { if (send_data->status == ZH_ESPNOW_SEND_FAIL && sensor_config->gateway_is_available == true) { sensor_config->gateway_is_available = false; if (sensor_config->hardware_config.sensor_pin_1 != ZH_NOT_USED && sensor_config->hardware_config.sensor_type != HAST_NONE) { vTaskDelete(sensor_config->status_message_task); vTaskDelete(sensor_config->attributes_message_task); } } } else { ++sensor_config->sent_message_quantity; } break; #else ZH_NETWORK_EVENT_HANDLER_EXIT: heap_caps_free(recv_data->data); break; case ZH_NETWORK_ON_SEND_EVENT:; zh_network_event_on_send_t *send_data = event_data; if (sensor_config->hardware_config.battery_power == false) { if (send_data->status == ZH_NETWORK_SEND_FAIL && sensor_config->gateway_is_available == true) { sensor_config->gateway_is_available = false; if (sensor_config->hardware_config.sensor_pin_1 != ZH_NOT_USED && sensor_config->hardware_config.sensor_type != HAST_NONE) { vTaskDelete(sensor_config->status_message_task); vTaskDelete(sensor_config->attributes_message_task); } } } else { ++sensor_config->sent_message_quantity; } break; #endif default: break; } }