import tinyb.*; import java.util.*; import java.time.*; import java.util.concurrent.locks.*; import java.util.concurrent.TimeUnit; public class AsyncTinyB { private static final float SCALE_LSB = 0.03125f; static boolean running = true; static void printDevice(BluetoothDevice device) { System.out.print("Address = " + device.getAddress()); System.out.print(" Name = " + device.getName()); System.out.print(" Connected = " + device.getConnected()); System.out.println(); } static float convertCelsius(int raw) { return raw / 128f; } /* * This program connects to a TI SensorTag 2.0 and reads the temperature characteristic exposed by the device over * Bluetooth Low Energy. The parameter provided to the program should be the MAC address of the device. * * A wiki describing the sensor is found here: http://processors.wiki.ti.com/index.php/CC2650_SensorTag_User's_Guide * * The API used in this example is based on TinyB v0.3, which only supports polling, but v0.4 will introduce a * simplied API for discovering devices and services. */ public static void main(String[] args) throws InterruptedException { if (args.length < 1) { System.err.println("Run with argument"); System.exit(-1); } /* * To start looking of the device, we first must initialize the TinyB library. The way of interacting with the * library is through the BluetoothManager. There can be only one BluetoothManager at one time, and the * reference to it is obtained through the getBluetoothManager method. */ BluetoothManager manager = BluetoothManager.getBluetoothManager(); /* * The manager will try to initialize a BluetoothAdapter if any adapter is present in the system. To initialize * discovery we can call startDiscovery, which will put the default adapter in discovery mode. */ boolean discoveryStarted = manager.startDiscovery(); System.out.println("The discovery started: " + (discoveryStarted ? "true" : "false")); /* * After discovery is started, new devices will be detected. We can find the device we are interested in * through the manager's find method. */ BluetoothDevice sensor = manager.find(null, args[0], null, Duration.ofSeconds(10)); /* * After we find the device we can stop looking for other devices. */ try { manager.stopDiscovery(); } catch (BluetoothException e) { System.err.println("Discovery could not be stopped right now"); } if (sensor == null) { System.err.println("No sensor found with the provided address."); System.exit(-1); } System.out.print("Found device: "); printDevice(sensor); if (sensor.connect()) System.out.println("Sensor with the provided address connected"); else { System.out.println("Could not connect device."); System.exit(-1); } Lock lock = new ReentrantLock(); Condition cv = lock.newCondition(); Runtime.getRuntime().addShutdownHook(new Thread() { public void run() { running = false; lock.lock(); try { cv.signalAll(); } finally { lock.unlock(); } } }); /* * Our device should expose a temperature service, which has a UUID we can find out from the data sheet. The service * description of the SensorTag can be found here: * http://processors.wiki.ti.com/images/a/a8/BLE_SensorTag_GATT_Server.pdf. The service we are looking for has the * short UUID AA00 which we insert into the TI Base UUID: f000XXXX-0451-4000-b000-000000000000 */ BluetoothGattService tempService = sensor.find( "f000aa00-0451-4000-b000-000000000000"); if (tempService == null) { System.err.println("This device does not have the temperature service we are looking for."); sensor.disconnect(); System.exit(-1); } System.out.println("Found service " + tempService.getUUID()); BluetoothGattCharacteristic tempValue = tempService.find("f000aa01-0451-4000-b000-000000000000"); BluetoothGattCharacteristic tempConfig = tempService.find("f000aa02-0451-4000-b000-000000000000"); BluetoothGattCharacteristic tempPeriod = tempService.find("f000aa03-0451-4000-b000-000000000000"); if (tempValue == null || tempConfig == null || tempPeriod == null) { System.err.println("Could not find the correct characteristics."); sensor.disconnect(); System.exit(-1); } System.out.println("Found the temperature characteristics"); /* * Turn on the Temperature Service by writing 1 in the configuration characteristic, as mentioned in the PDF * mentioned above. We could also modify the update interval, by writing in the period characteristic, but the * default 1s is good enough for our purposes. */ byte[] config = { 0x01 }; tempConfig.writeValue(config); /* * Each second read the value characteristic and display it in a human readable format. */ while (running) { byte[] tempRaw = tempValue.readValue(); System.out.print("Temp raw = {"); for (byte b : tempRaw) { System.out.print(String.format("%02x,", b)); } System.out.print("}"); /* * The temperature service returns the data in an encoded format which can be found in the wiki. Convert the * raw temperature format to celsius and print it. Conversion for object temperature depends on ambient * according to wiki, but assume result is good enough for our purposes without conversion. */ int objectTempRaw = (tempRaw[0] & 0xff) | (tempRaw[1] << 8); int ambientTempRaw = (tempRaw[2] & 0xff) | (tempRaw[3] << 8); float objectTempCelsius = convertCelsius(objectTempRaw); float ambientTempCelsius = convertCelsius(ambientTempRaw); System.out.println( String.format(" Temp: Object = %fC, Ambient = %fC", objectTempCelsius, ambientTempCelsius)); lock.lock(); try { cv.await(1, TimeUnit.SECONDS); } finally { lock.unlock(); } } sensor.disconnect(); } }