BlueCap provides a swift wrapper around CoreBluetooth and much more.
- A futures interface replacing protocol implementations.
- Timeout for
Peripheral
connection,Service
scan, 'Serviceand
Characteristicdiscovery and
Characteristic` read/write. - A DSL for specification of GATT profiles.
- Characteristic profile types encapsulating serialization and deserialization.
- Example applications implementing CentralManager and PeripheralManager.
- A full featured extendable scanner and Peripheral simulator available in the App Store.
- Thread safe.
- Comprehensive test coverage.
- iOS 9.0+
- Xcode 8.2
CocoaPods is an Xcode dependency manager. It is installed with the following command,
gem install cocoapods
Requires CocoaPods 1.1+
Add BluCapKit
to your to your project Podfile
,
platform :ios, '9.0'
use_frameworks!
target 'Your Target Name' do
pod 'BlueCapKit', '~> 0.5'
end
To enable DBUG
output add this post_install
hook to your Podfile
Carthage is a decentralized dependency manager for Xcode projects. It can be installed using Homebrew,
brew update
brew install carthage
To add BlueCapKit
to your Cartfile
github "troystribling/BlueCap" ~> 0.5
To download and build BlueCapKit.framework
run the command,
carthage update
then add BlueCapKit.framework
to your project.
If desired use the --no-build
option,
carthage update --no-build
This will only download BlueCapKit
. Then follow the steps in Manual to add it to a project.
- Place the BlueCap somewhere in your project directory. You can either copy it or add it as a git submodule.
- Open the BlueCap project folder and drag BlueCapKit.xcodeproj into the project navigator of your applications Xcode project.
- Under your Projects Info tab set the iOS Deployment Target to 9.0 and verify that the BlueCapKit.xcodeproj iOS Deployment Target is also 9.0.
- Under the General tab for your project target add the top BlueCapKit.framework as an Embedded Binary.
- Under the Build Phases tab add BlueCapKit.framework as a Target Dependency and under Link Binary With Libraries add CoreLocation.framework and CoreBluetooth.framework.
With BlueCap it is possible to easily implement CentralManager
and PeripheralManager
applications, serialize and deserialize messages exchanged with Bluetooth devices and define reusable GATT profile definitions. The BlueCap asynchronous interface uses Futures instead of the usual block interface or the protocol-delegate pattern. Futures can be chained with the result of the previous passed as input to the next. This simplifies application implementation because the persistence of state between asynchronous calls is eliminated and code will not be distributed over multiple files, which is the case for protocol-delegate, or be deeply nested, which is the case for block interfaces. In this section a brief overview of how an application is constructed will be given. Following sections will describe supported use cases. Example applications are also available.
A simple CentralManager implementation that scans for Peripherals advertising a TiSensorTag Accelerometer Service, connects on peripheral discovery, discovers service and characteristics and subscribes to accelerometer data updates will be described.
All applications begin by calling CentralManager#whenStateChanges
which returns a Future<Void>
completed when the CBCentralManager
state is set to CBCentralManagerState.PoweredOn
.
let manager = CentralManager(options: [CBCentralManagerOptionRestoreIdentifierKey : "us.gnos.BlueCap.central-manager-documentation" as NSString])
let stateChangeFuture = manager.whenStateChanges()
To start scanning for Peripherals
advertising the TiSensorTag Accelerometer Service follow whenStateChanges()
with CentralManager#startScanning
and combine the two with the SimpleFutures FutureStream#flatMap
combinator. An application error object is also defined,
public enum AppError : Error {
case invalidState
case resetting
case poweredOff
case unknown
case unlikely
}
let serviceUUID = CBUUID(string: TISensorTag.AccelerometerService.uuid)
let scanFuture = stateChangeFuture.flatMap { [weak manager] state -> FutureStream<Peripheral> in
guard let manager = manager else {
throw AppError.unlikely
}
switch state {
case .poweredOn:
return manager.startScanning(forServiceUUIDs: [serviceUUID])
case .poweredOff:
throw AppError.poweredOff
case .unauthorized, .unsupported:
throw AppError.invalidState
case .resetting:
throw AppError.resetting
case .unknown:
throw AppError.unknown
}
}
scanFuture.onFailure { [weak manager] error in
guard let appError = error as? AppError else {
return
}
switch appError {
case .invalidState:
break
case .resetting:
manager?.reset()
case .poweredOff:
break
case .unknown:
break
}
}
Here when .poweredOn
is received the scan is started. On all other state changes the appropriate error is thrown
and handled in the error handler.
To connect discovered peripherals the scan is followed by Peripheral#connect
and combined with FutureStream#flatMap
,
var peripheral: Peripheral?
let connectionFuture = scanFuture.flatMap { [weak manager] discoveredPeripheral -> FutureStream<Void> in
manager?.stopScanning()
peripheral = discoveredPeripheral
return peripheral.connect(connectionTimeout: 10.0)
}
Here the scan is also stopped after a peripheral with the desired service UUID is discovered.
The Peripheral
Services
and Characteristics
need to be discovered and the connection errors need to be handled. Service
and Characteristic
discovery are performed by 'Peripheral#discoverServices' and Service#discoverCharacteristics
and more errors are added to AppError
.
public enum AppError : Error {
case dataCharactertisticNotFound
case enabledCharactertisticNotFound
case updateCharactertisticNotFound
case serviceNotFound
case invalidState
case resetting
case poweredOff
case unknown
case unlikely
}
let discoveryFuture = connectionFuture.flatMap { [weak peripheral] () -> Future<Void> in
guard let peripheral = peripheral else {
throw AppError.unlikely
}
return peripheral.discoverServices([serviceUUID])
}.flatMap { [weak peripheral] () -> Future<Void> in
guard let peripheral = peripheral, let service = peripheral.services(withUUID: serviceUUID)?.first else {
throw AppError.serviceNotFound
}
return service.discoverCharacteristics([dataUUID, enabledUUID, updatePeriodUUID])
}
discoveryFuture.onFailure { [weak peripheral] error in
switch error {
case PeripheralError.disconnected:
peripheral?.reconnect()
case AppError.serviceNotFound:
break
default:
break
}
}
Here a reconnect attempt is made if the Peripheral
is disconnected and the AppError.serviceNotFound
error is handled. Finally read and subscribe to the data Characteristic
and handle the dataCharactertisticNotFound
.
public enum AppError : Error {
case dataCharactertisticNotFound
case enabledCharactertisticNotFound
case updateCharactertisticNotFound
case serviceNotFound
case invalidState
case resetting
case poweredOff
case unknown
}
var accelerometerDataCharacteristic: Characteristic?
let subscriptionFuture = discoveryFuture.flatMap { [weak peripheral] () -> Future<Void> in
guard let peripheral = peripheral, let service = peripheral.services(withUUID: serviceUUID)?.first else {
throw AppError.serviceNotFound
}
guard let dataCharacteristic = service.service.characteristics(withUUID: dataUUID)?.first else {
throw AppError.dataCharactertisticNotFound
}
accelerometerDataCharacteristic = dataCharacteristic
return dataCharacteristic.read(timeout: 10.0)
}.flatMap { [weak accelerometerDataCharacteristic] () -> Future<Void> in
guard let accelerometerDataCharacteristic = accelerometerDataCharacteristic else {
throw AppError.dataCharactertisticNotFound
}
return accelerometerDataCharacteristic.startNotifying()
}.flatMap { [weak accelerometerDataCharacteristic] () -> FutureStream<Data?> in
guard let accelerometerDataCharacteristic = accelerometerDataCharacteristic else {
throw AppError.dataCharactertisticNotFound
}
return accelerometerDataCharacteristic.receiveNotificationUpdates(capacity: 10)
}
dataUpdateFuture.onFailure { [weak peripheral] error in
switch error {
case PeripheralError.disconnected:
peripheral?.reconnect()
case AppError.serviceNotFound:
break
case AppError.dataCharactertisticNotFound:
break
default:
break
}
}
These examples can be written as a single flatMap
chain as shown in the CentralManager Example.
A simple PeripheralManager
application that emulates a TiSensorTag Accelerometer Service supporting all Characteristics
will be described. It will advertise the service and respond to characteristic write requests on the writable Characteristics
.
First the Characteristics
and Service
are created and the Characteristics
are then added to Service
// create accelerometer service
let accelerometerService = MutableService(uuid: TISensorTag.AccelerometerService.uuid)
// create accelerometer data characteristic
let accelerometerDataCharacteristic = MutableCharacteristic(profile: RawArrayCharacteristicProfile<TISensorTag.AccelerometerService.Data>())
// create accelerometer enabled characteristic
let accelerometerEnabledCharacteristic = MutableCharacteristic(profile: RawCharacteristicProfile<TISensorTag.AccelerometerService.Enabled>())
// create accelerometer update period characteristic
let accelerometerUpdatePeriodCharacteristic = MutableCharacteristic(profile: RawCharacteristicProfile<TISensorTag.AccelerometerService.UpdatePeriod>())
// add characteristics to service
accelerometerService.characteristics = [accelerometerDataCharacteristic, accelerometerEnabledCharacteristic, accelerometerUpdatePeriodCharacteristic]
Next create the PeripheralManager
add the Service
and start advertising.
enum AppError: Error {
case invalidState
case resetting
case poweredOff
case unsupported
case unlikely
}
let manager = PeripheralManager(options: [CBPeripheralManagerOptionRestoreIdentifierKey : "us.gnos.BlueCap.peripheral-manager-documentation" as NSString])
let startAdvertiseFuture = manager.whenStateChanges().flatMap { [weak manager] state -> Future<Void> in
guard let manager = manager else {
throw AppError.unlikely
}
switch state {
case .poweredOn:
manager.removeAllServices()
return manager.add(self.accelerometerService)
case .poweredOff:
throw AppError.poweredOff
case .unauthorized, .unknown:
throw AppError.invalidState
case .unsupported:
throw AppError.unsupported
case .resetting:
throw AppError.resetting
}
}.flatMap { [weak manager] _ -> Future<Void> in
guard let manager = manager else {
throw AppError.unlikely
}
manager.startAdvertising(TISensorTag.AccelerometerService.name, uuids:[CBUUID(string: TISensorTag.AccelerometerService.uuid)])
}
startAdvertiseFuture.onFailure { [weak manager] error in
switch error {
case AppError.poweredOff:
manager?.reset()
case AppError.resetting:
manager?.reset()
default:
break
}
manager?.stopAdvertising()
}
Now respond to write events on accelerometerEnabledFuture
and accelerometerUpdatePeriodFuture
.
// respond to Update Period write requests
let accelerometerUpdatePeriodFuture = startAdvertiseFuture.flatMap {
accelerometerUpdatePeriodCharacteristic.startRespondingToWriteRequests()
}
accelerometerUpdatePeriodFuture.onSuccess { [weak accelerometerUpdatePeriodCharacteristic] (request, _) in
guard let accelerometerUpdatePeriodCharacteristic = accelerometerUpdatePeriodCharacteristic else {
throw AppError.unlikely
}
guard let value = request.value, value.count > 0 && value.count <= 8 else {
return
}
accelerometerUpdatePeriodCharacteristic.value = value
accelerometerUpdatePeriodCharacteristic.respondToRequest(request, withResult:CBATTError.success)
}
// respond to Enabled write requests
let accelerometerEnabledFuture = startAdvertiseFuture.flatMap {
accelerometerEnabledCharacteristic.startRespondingToWriteRequests(capacity: 2)
}
accelerometerEnabledFuture.onSuccess { [weak accelerometerUpdatePeriodCharacteristic] (request, _) in
guard let accelerometerEnabledCharacteristic = accelerometerEnabledCharacteristic else {
throw AppError.unlikely
}
guard let value = request.value, value.count == 1 else {
return
}
accelerometerEnabledCharacteristic.value = request.value
accelerometerEnabledCharacteristic.respondToRequest(request, withResult:CBATTError.success)
}
See PeripheralManager Example for details.
Test Cases are available. To run type,
pod install
and run from test tab in generated workspace
.
Examples are available that implement both CentralManager and PeripheralManager. The BluCap app is also available. The example projects are constructed using either CocoaPods or Carthage. The CocaPods projects require installing the Pod before building,
pod install
and Carthage projects require,
carthage update
BlueCap | BlueCap provides CentralManager, PeripheralManager and iBeacon Ranging with implementations of GATT profiles. In CentralManager mode a scanner for Bluetooth LE peripherals is provided. In PeripheralManager mode an emulation of any of the included GATT profiles or an iBeacon is supported. In iBeacon Ranging mode beacon regions can be configured and monitored. |
CentralManager | CentralManager implements a BLE CentralManager scanning for services advertising the TiSensorTag Accelerometer Service. When a Peripheral is discovered a connection is established, services are discovered, the accelerometer is enabled and the application subscribes to accelerometer data updates. It is also possible to change the data update period. |
CentralManagerWithProfile | A version of CentralManager that uses GATT Profile Definitions to create services. |
PeripheralManager | PeripheralManager implements a BLE PeripheralManager advertising a TiSensorTag Accelerometer Service. PeripheralManager uses the onboard accelerometer to provide data updates. |
PeripheralManagerWithProfile | A version of Peripheral that uses GATT Profile Definitions to create services. |
Beacon | Peripheral emulating an iBeacon. |
Beacons | iBeacon ranging. |
BlueCap supports many features that simplify writing Bluetooth LE applications. Use cases with example implementations are described in each of the following sections.
-
CentralManager: The BlueCap CentralManager implementation replaces CBCentralManagerDelegate and CBPeripheralDelegate protocol implementations with a Scala Futures interface using SimpleFutures.
-
PeripheralManager: The BlueCap PeripheralManager implementation replaces CBPeripheralManagerDelegate protocol implementations with a Scala Futures interface using SimpleFutures.
-
Serialization/Deserialization: Serialization and deserialization of device messages.
-
GATT Profile Definition: Define reusable GATT profiles and add profiles to the BlueCap app.