In mobile apps (e.g. iOS and Android), you can integrate with the XRP Ledger using JavaScript libraries (example: XUMM).
DEPRECATION NOTICE: This library is no longer actively maintained.
XpringKit is the Swift client side library of the Xpring SDK.
XpringKit provides the following features:
XpringKit is available via Carthage. Simply add the following to your Cartfile
:
github "xpring-eng/XpringKit"
XpringKit is available via CocoaPods. Simply add the following to your Podfile
:
pod 'XpringKit'
Xpring SDK needs to communicate with a rippled node which has gRPC enabled. Consult the rippled documentation for details on how to build your own node.
To get developers started right away, Xpring currently provides nodes:
# Testnet
test.xrp.xpring.io:50051
# Mainnet
main.xrp.xpring.io:50051
Xpring SDK's IlpClient
needs to communicate with Xpring's ILP infrastructure through an instance of Hermes.
In order to connect to the Hermes instance that Xpring currently operates, you will need to create an ILP wallet here
Once your wallet has been created, you can use the gRPC URL specified in your wallet, as well as your access token to check your balance and send payments over ILP.
Note: Xpring SDK only works with the X-Address format. For more information about this format, see the Utilities section and http://xrpaddress.info.
A wallet is a fundamental model object in XpringKit which provides key management, address derivation, and signing functionality. Wallets can be derived from either a seed or a mnemonic and derivation path. You can also choose to generate a new random HD wallet.
XpringKit can derive a wallet from a seed or it can derive a hierarchical deterministic wallet (HDWallet) from a mnemonic and derivation path.
A hierarchical deterministic wallet is created using a mnemonic and a derivation path. Simply pass the mnemonic and derivation path to the wallet generation function. Note that you can omit the derivation path and have a default path be used instead.
import XpringKit
let mnemonic = "abandon abandon abandon abandon abandon abandon abandon abandon abandon abandon abandon about"
let hdWallet1 = Wallet.generateWalletFromMnemonic(mnemonic: mnemonic)! // Has default derivation path
let hdWallet2 = Wallet(mnemonic: mnemonic, derivationPath: Wallet.defaultDerivationPath)! // Same as hdWallet1
let hdWallet = Wallet(mnemonic: mnemonic, derivationPath: "m/44'/144'/0'/0/1"); // Wallet with custom derivation path.
You can construct a seed based wallet by passing a base58check encoded seed string.
import XpringKit
let seedWallet = Wallet(seed: "snRiAJGeKCkPVddbjB3zRwiYDBm1M")!
XpringKit can generate a new and random HD Wallet. The result of a wallet generation call is a tuple which contains the following:
import XpringKit
// Generate a random wallet.
let generationResult = Wallet.generateRandomWallet()!
let newWallet = generationResult.wallet
// Wallet can be recreated with the artifacts of the initial generation.
let copyOfNewWallet = Wallet(mnemonic: generationResult.mnemonic, derivationPath: generationResult.derivationPath)
A generated wallet can provide its public key, private key, and address on the XRP ledger.
import XpringKit
let mnemonic = "abandon abandon abandon abandon abandon abandon abandon abandon abandon abandon abandon about";
let wallet = Wallet(mnemonic: mnemonic)!
print(wallet.address) // XVMFQQBMhdouRqhPMuawgBMN1AVFTofPAdRsXG5RkPtUPNQ
print(wallet.publicKey) // 031D68BC1A142E6766B2BDFB006CCFE135EF2E0E2E94ABB5CF5C9AB6104776FBAE
print(wallet.privateKey) // 0090802A50AA84EFB6CDB225F17C27616EA94048C179142FECF03F4712A07EA7A4
A wallet can also sign and verify arbitrary hex messages. Generally, users should use the functions on XRPClient
to perform cryptographic functions rather than using these low level APIs.
import XpringKit
let mnemonic = "abandon abandon abandon abandon abandon abandon abandon abandon abandon abandon abandon about"
let message = "deadbeef";
let wallet = Wallet(mnemonic: mnemonic)!
let signature = wallet.sign(message)
wallet.verify(message, signature); // true
XRPClient
is a gateway into the XRP Ledger. XRPClient
is initialized with a single parameter, which is the URL of the remote adapter (see: ‘Server Side Component’ section above).
import XpringKit
let remoteURL = "test.xrp.xpring.io:50051"; // Testnet URL, use main.xrp.xpring.io:50051 for Mainnet
let xrpClient = XRPClient(grpcURL: remoteURL, network: XRPLNetwork.test)
An XRPClient
can check the balance of an account on the XRP Ledger.
import XpringKit
let remoteURL = "test.xrp.xpring.io:50051"; // Testnet URL, use main.xrp.xpring.io:50051 for Mainnet
let xrpClient = XRPClient(grpcURL: remoteURL, network: XRPLNetwork.test)
let address = "XVMFQQBMhdouRqhPMuawgBMN1AVFTofPAdRsXG5RkPtUPNQ"
let balance = try! xrpClient.getBalance(for: address)
print(balance) // Logs a balance in drops of XRP
An XRPClient
can check the status of a payment on the XRP Ledger.
This method can only determine the status of payment transactions which do not have the partial payment flag (tfPartialPayment) set.
XpringKit returns the following transaction states:
succeeded
: The transaction was successfully validated and applied to the XRP Ledger.failed:
The transaction was successfully validated but not applied to the XRP Ledger. Or the operation will never be validated.pending
: The transaction has not yet been validated, but may be validated in the future.unknown
: The transaction status could not be determined, the hash represented a non-payment type transaction, or the hash represented a transaction with the tfPartialPayment flag set.Note: For more information, see Reliable Transaction Submission and Transaction Results.
These states are determined by the TransactionStatus
enum.
import XpringKit
let remoteURL = "test.xrp.xpring.io:50051"; // Testnet URL, use main.xrp.xpring.io:50051 for Mainnet
let xrpClient = XRPClient(grpcURL: remoteURL, network: XRPLNetwork.test)
let transactionHash = "9FC7D277C1C8ED9CE133CC17AEA9978E71FC644CE6F5F0C8E26F1C635D97AF4A"
let transactionStatus = xrpClient.paymentStatus(for: transactionHash) // TransactionStatus.succeeded
Note: The example transactionHash
may lead to a "Transaction not found." error because the TestNet is regularly reset, or the accessed node may only maintain one month of history. Recent transaction hashes can be found in the XRP Ledger Explorer .
An XRPClient
can retrieve a specific payment transaction by hash.
import XpringKit
let remoteURL = "alpha.test.xrp.xpring.io:50051"; // TestNet URL, use alpha.xrp.xpring.io:50051 for Mainnet
let xrpClient = XRPClient(grpcURL: remoteURL, network: XRPLNetwork.test)
let transactionHash = "9FC7D277C1C8ED9CE133CC17AEA9978E71FC644CE6F5F0C8E26F1C635D97AF4A"
let payment = try! xrpClient.getPayment(for: transactionHash)
Note: The example transactionHash
may lead to a "Transaction not found." error because the TestNet is regularly reset, or the accessed node may only maintain one month of history. Recent transaction hashes can be found in the XRP Ledger Explorer .
An XRPClient
can retrieve a specific payment transaction by hash.
import xpringkit
let remoteURL = "alpha.test.xrp.xpring.io:50051"; // TestNet URL, use alpha.xrp.xpring.io:50051 for Mainnet
let xrpClient = XRPClient(grpcURL: remoteURL, useNewProtocolBuffers: true)
let transactionHash = "9FC7D277C1C8ED9CE133CC17AEA9978E71FC644CE6F5F0C8E26F1C635D97AF4A"
let payment = try! xrpClient.getPayment(for: transactionHash)
Note: The example transactionHash may lead to a "Transaction not found." error because the TestNet is regularly reset, or the accessed node may only maintain one month of history. Recent transaction hashes can be found in the XRP Ledger Explorer .
An XRPClient
can return payments to and from an account.
import XpringKit
let remoteURL = "alpha.test.xrp.xpring.io:50051"; // TestNet URL, use alpha.xrp.xpring.io:50051 for Mainnet
let xrpClient = XRPClient(grpcURL: remoteURL, network: XRPLNetwork.test)
let address = "XVMFQQBMhdouRqhPMuawgBMN1AVFTofPAdRsXG5RkPtUPNQ"
let transactions = try! xrpClient.paymentHistory(for: address)
An XRPClient
can send XRP to other accounts on the XRP Ledger.
Note: The payment operation will block the calling thread until the operation reaches a definitive and irreversible success or failure state.
import XpringKit
let remoteURL = "test.xrp.xpring.io:50051"; // TestNet URL, use main.xrp.xpring.io:50051 for Mainnet
let xrpClient = XRPClient(grpcURL: remoteURL, network: XRPLNetwork.test)
// Wallet which will send XRP
let generationResult = Wallet.generateRandomWallet()!
let senderWallet = generationResult.wallet
// Destination address.
let address = "X7u4MQVhU2YxS4P9fWzQjnNuDRUkP3GM6kiVjTjcQgUU3Jr"
// Amount of XRP to send, in drops.
let amount: UInt64 = 10
let transactionHash = try! xrpClient.send(amount, to: destinationAddress, from: senderWallet)
Note: The above example will yield an "Account not found." error because the randomly generated wallet contains no XRP.
let remoteURL = "test.xrp.xpring.io:50051" // TestNet URL, use main.xrp.xpring.io:50051 for Mainnet
let xrpClient = new XRPClient(remoteURL, XRPLNetwork.test)
// Wallet for which to enable Deposit Authorization
let seedWallet = Wallet("snRiAJGeKCkPVddbjB3zRwwoiYDBm1M")
let transactionResult: TransactionResult = xrpClient.enableDepositAuth(seedWallet)
let transactionHash: String = transactionResult.hash
let transactionStatus: TransactionStatus = transactionResult.status
let validated: Bool = transactionResult.validated
The Utils object provides an easy way to validate addresses.
import XpringKit
let rippleClassicAddress = "rnysDDrRXxz9z66DmCmfWpq4Z5s4TyUP3G"
let rippleXAddress = "X7jjQ4d6bz1qmjwxYUsw6gtxSyjYv5iWPqPEjGqqhn9Woti"
let bitcoinAddress = "1DiqLtKZZviDxccRpowkhVowsbLSNQWBE8"
Utils.isValid(address: rippleAddress); // returns true
Utils.isValid(address: bitcoinAddress); // returns false
You can also validate if an address is an X-Address or a classic address.
import XpringKit
let rippleClassicAddress = "rnysDDrRXxz9z66DmCmfWpq4Z5s4TyUP3G"
let rippleXAddress = "X7jjQ4d6bz1qmjwxYUsw6gtxSyjYv5iWPqPEjGqqhn9Woti"
let bitcoinAddress = "1DiqLtKZZviDxccRpowkhVowsbLSNQWBE8"
Utils.isValidXAddress(address: rippleClassicAddress); // returns false
Utils.isValidXAddress(address: rippleXAddress); // returns true
Utils.isValidXAddress(address: bitcoinAddress); // returns false
Utils.isValidClassicAddress(address: rippleClassicAddress); // returns true
Utils.isValidClassicAddress(address: rippleXAddress); // returns false
Utils.isValidClassicAddress(address: bitcoinAddress); // returns false
You can encode and decode X-Addresses with the SDK.
import XpringKit
let rippleClassicAddress = "rnysDDrRXxz9z66DmCmfWpq4Z5s4TyUP3G"
let tag: UInt32 = 12345;
// Encode an X-Address.
let xAddress = Utils.encode(classicAddress: address, tag: tag) // X7jjQ4d6bz1qmjwxYUsw6gtxSyjYv5xRB7JM3ht8XC4P45P
// Decode an X-Address.
let classicAddressTuple = Utils.decode(xAddress: address)!
print(classicAddressTuple.classicAddress); // rnysDDrRXxz9z66DmCmfWpq4Z5s4TyUP3G
print(classicAddressTuple.tag); // 12345
Two classes are used to work with PayID: PayIDClient
and XRPPayIDClient
.
PayIDClient
can resolve addresses on arbitrary cryptocurrency networks.
import XpringKit
// Resolve on Bitcoin Mainnet.
let network = "btc-mainnet"
let payIDClient = PayIDClient()
let payID = "georgewashington$xpring.money"
let result = payIDClient.cryptoAddress(for: payID, on: network)
switch result {
case .success(let btcAddressComponents)
print("Resolved to \(btcAddressComponents.address)")
case .failure(let error):
fatalError("Unknown error resolving address: \(error)")
}
#### Single Address Resolution
`PayIdClient` can retrieve all available addresses.
```swift
import XpringKit
let payID = "georgewashington$xpring.money"
let payIDClient = new PayIDClient()
let allAddresses = payIDClient.allAddresses(for: payID)
case .success(let addresses)
print("All addresses: \(allAddresses)")
case .failure(let error):
fatalError("Unknown error retrieving all addresses: \(error)")
}
Asynchronous APIs are also provided.
XRPPayIDClient
can resolve addresses on the XRP Ledger network. The class always coerces returned addresses into an X-Address. (See https://xrpaddress.info/)
import XpringKit
// Use XrplNetwork.main for Mainnet.
let xrpPayIDClient = XRPPayIDClient(xrplNetwork: .main)
let payID = 'georgewashington$xpring.money'
let result = xrpPayIDClient.xrpAddress(for: payID)
switch result {
case .success(let xrpAddress):
print("Resolved to \(xrpAddress)")
case .failure(let error):
fatalError("Unknown error resolving address: \(error)")
}
Asynchronous APIs are also provided.
ILPClient
is the main interface into the ILP network. ILPClient
must be initialized with the URL of a Hermes instance.
This can be found in your wallet.
All calls to ILPClient
must pass an access token, which can be generated in your wallet.
import XpringKit
let grpcUrl = "hermes-grpc-test.xpring.dev" // TestNet Hermes URL
let ilpClient = ILPClient(grpcURL: grpcUrl)
An ILPClient
can check the balance of an account on a connector.
import XpringKit
let grpcUrl = "hermes-grpc-test.xpring.dev" // TestNet Hermes URL
let ilpClient = ILPClient(grpcURL: grpcUrl)
let getBalance = try ilpClient.getBalance(for: "demo_user", withAuthorization: "2S1PZh3fEKnKg") // Just a demo user on Testnet
print("Net balance was \(getBalance.netBalance) with asset scale \(getBalance.assetScale)")
An ILPClient
can send an ILP payment to another ILP address by supplying a Payment Pointer
and a sender's account ID.
import XpringKit
let grpcUrl = "hermes-grpc-test.xpring.dev" // TestNet Hermes URL
let ilpClient = ILPClient(grpcURL: grpcUrl)
let paymentRequest = PaymentRequest(
100,
to: "$xpring.money/demo_receiver",
from: "demo_user"
)
let payment = try ilpClient.sendPayment(
paymentRequest,
withAuthorization: "2S1PZh3fEKnKg"
)
Xpring components compose PayID and XRP components to make complex interactions easy.
import XpringKit
let network = XRPLNetwork.test
// Build an XRPClient
let rippledUrl = "test.xrp.xpring.io:50051"
let xrpClient = XRPClient(rippledUrl, network)
// Build a PayIDClient
let payIDClient = XRPPayIDClient(network)
// XpringClient combines functionality from XRP and PayID
let xpringClient = XpringClient(payIdClient, xrpClient)
// A wallet with some balance on TestNet.
let wallet = Wallet(seed: "snYP7oArxKepd3GPDcrjMsJYiJeJB")!
// A PayID which will receive the payment.
let payId = "georgewashington$xpring.money"
// Send XRP to the given PayID.
let result = xpringClient.send(dropsToSend, to: payID, from: wallet)
switch result {
case .success(let hash):
print("Hash for transaction:\n\(hash)\n")
case .failure:
fatalError("Unable to send transaction.")
}
Asynchronous APIs are also provided.