void main(void) { struct device *ipm; int rc; uint32_t value32; rc = bt_enable(bt_ready); if (rc) { printk("Bluetooth init failed (err %d)\n", rc); return; } bt_conn_cb_register(&conn_callbacks); bt_conn_auth_cb_register(&auth_cb_display); ipm = device_get_binding("power_ipm"); ipm_register_callback(ipm, sensor_ipm_callback, NULL); ipm_set_enabled(ipm, 1); while (1) { if (default_conn) { value32 = sys_cpu_to_le32(consumption_value); bt_gatt_notify(default_conn, &attrs[2], &value32, sizeof(value32)); k_sleep(INTERVAL); value32 = sys_cpu_to_le32(solar_value); bt_gatt_notify(default_conn, &attrs[6], &value32, sizeof(value32)); } k_sleep(INTERVAL); } }
void service_init(struct bt_conn *conn) { if ((pwm = device_get_binding("PWM_0")) == NULL) printk("device_get_binding: failed for PWM\n"); else { pwm_write(); printk("PWM init OK\n"); } struct device *ipm; ipm = device_get_binding("temperature_ipm"); ipm_register_callback(ipm, temperature_ipm_callback, conn); ipm_set_enabled(ipm, 1); bt_gatt_register(attrs, ARRAY_SIZE(attrs)); }
void main(void) { struct device *ipm; int rc; uint16_t value16; uint32_t value32; rc = bt_enable(bt_ready); if (rc) { printk("Bluetooth init failed (err %d)\n", rc); return; } bt_conn_cb_register(&conn_callbacks); bt_conn_auth_cb_register(&auth_cb_display); ipm = device_get_binding("ess_ipm"); ipm_register_callback(ipm, sensor_ipm_callback, NULL); ipm_set_enabled(ipm, 1); while (1) { /* Notify value changes via BLE here so that the notification intervals can be controlled. */ if (default_conn) { value16 = sys_cpu_to_le16(temp_value); bt_gatt_notify(default_conn, &attrs[2], &value16, sizeof(value16)); k_sleep(INTERVAL); value16 = sys_cpu_to_le16(humidity_value); bt_gatt_notify(default_conn, &attrs[6], &value16, sizeof(value16)); k_sleep(INTERVAL); value32 = sys_cpu_to_le32(pressure_value); bt_gatt_notify(default_conn, &attrs[10], &value32, sizeof(value32)); k_sleep(INTERVAL); value16 = sys_cpu_to_le16(uv_index_value); bt_gatt_notify(default_conn, &attrs[14], &uv_index_value, sizeof(uv_index_value)); } k_sleep(INTERVAL); } }
int ipm_console_receiver_init(struct device *d) { const struct ipm_console_receiver_config_info *config_info = d->config->config_info; struct ipm_console_receiver_runtime_data *driver_data = d->driver_data; struct device *ipm; ipm = device_get_binding(config_info->bind_to); if (!ipm) { printk("unable to bind IPM console receiver to '%s'\n", config_info->bind_to); return -EINVAL; } if (ipm_max_id_val_get(ipm) < 0xFF) { printk("IPM driver %s doesn't support 8-bit id values", config_info->bind_to); return -EINVAL; } driver_data->ipm_device = ipm; driver_data->channel_disabled = 0; k_sem_init(&driver_data->sem, 0, UINT_MAX); ring_buf_init(&driver_data->rb, config_info->rb_size32, config_info->ring_buf_data); ipm_register_callback(ipm, ipm_console_receive_callback, d); k_thread_create(&driver_data->rx_thread, config_info->thread_stack, CONFIG_IPM_CONSOLE_STACK_SIZE, ipm_console_thread, d, NULL, NULL, K_PRIO_COOP(IPM_CONSOLE_PRI), 0, 0); ipm_set_enabled(ipm, 1); return 0; }