/walletkit

Primary LanguageCMIT LicenseMIT

WalletKit

WalletKit provides a uniform wallet interface to access numerous crypto-currencies including Bitcoin and Ethereum. WalletKit is implemented in the C progamming language and includes a number of bindings for other languages, notably Swift and Java.

WalletKit supports the following crypto-currencies: Bitcoin, Bitcoin Cash, Bitcoin SV, Ethereum, Ethereum ERC20 'tokens', Ripple, Hedera and Tezos. Other crypto-currencies are added regularly. Adding another blockchain is accomplished by satisfying a WalletKit-defined API.

WalletKit is the basis for the BRD iOS and Android mobile applications which currently have combined downloads of over 6,000,000.

badge-mit badge-languages badge-platforms

Features

Cryptocurrency Agnostic

WalletKit treats the assets held in a wallet without regard to the crytpocurrency. Thus Bitcoin, Ethereuem and other wallets have a balance and a set of transfers contributing to that balance. The wallet's balance will be in a currency defined for the cryptocurrency.

Syncing Modes

WalletKit allows one to specify how a wallet's transfers are identified. Some cryptocurrencies, notably Bitcoin and related currencies, define peer-to-peer interfaces that can be used to identify transactions for a User's wallet. (For Bitcoin, this peer-to-peer interface is known as SPV - 'Simple Payment Verification'). WalletKit implements peer-to-peer interfaces for some cyptocurrencies. In addition, WalletKit defines an interface that can be used to identify transactions based on HTTP requests made to endpoints holding cryptocurrency blocks and transactions. WalletKit provides a default implementatin of this 'client interface' using Blockset.

Event-Based

WalletKit defines

Multiple Language Bindings

WalletKit is implemented in C and uses minimal OS resources. Thus WalletKit will run on many platforms. With a basis in C, multiple other languages can invoke the C interfaces.

C

WalletKit defines a C interface, with associated C implementation, that runs on both MacOS and on Linux platforms. The C interface can be accessed through the 'foriegn function interface' offered by other languages, such as by Swift and Java.

The C interface is located in .../WalletKit/WalletKitCore/include.

Swift

WalletKit includes a Swift framework, called WalletKit layered on the C code.

Java

WalletKit includes a Java library ...

Others

WalletKit is being extended with additional language bindings for Kotlin, Python, node.js and web assembly.

Demo Mobile Applications

WalletKit includes iOS and Android demo applications. These applications illustrate basic usage of WalletKit to connect to numerous blockchains and to manage numerous wallets holding assets based on blockchain transactions.

The iOS demo application is accessed using Xcode; the Andriod demo application is accessed using Android Studio.

Concepts

WalletKit is crypto-currency agnostic; as such, WalletKit defines a number of concepts that apply across disparte blockchains but also can be extended with blockchain specific data and behaviors.

Network

A WKNetwork represents a cryptocurrency blockchain.

Currency

A WKCurrency represents an asset on a particular network that can be held by a User or transfers between Users.

Account

A WKAccount holds the User's public information for an associated BIP-39 'paperKey'. The public information includes everything needed to interact with any of WalletKit's supported blockchains.

WalletKit never holds a User's private information. An account is created initially with a BIP-39 'paperKey' and then, thereafter, the account is recreated from an account-specific serializaiton of the account's public information.

Transfer

A WKTransfer represents the exchange of an asset between two Users. A transfer abstracts over blockchain's transactions - a transaction potentially produces multiple Transfers.

Wallet

A WKWallet holds the asset represented by a currency. A wallet maintains a balance and a time-ordered list of transfers.

WalletManager

A WKWalletManager manages one or more wallets associated with a specific network. For example, the Ethereum blockchain defines ERC20 tokens, a type of asset. The Ethereum wallet manager can manage a wallet holding Ether as well as any number of ERC20-based assets.

System

A WKSystem provides the primary interface to WalletKit. A system manages one or more Networks and one or more Wallet Manaers.

A WKSystem is configured with a WKListener and a WKClient. The listener implements a defined interface with functions that receive events; the events announce WalletKit state changes - such as a blockchain height has been updated and a wallet has a new transfer. The client also implements a defined interface that WalletKit uses to gather blockchain data from and external, generally HTTP, source. A default implementation of WKClient is provided that uses Blockset for blockchain data.

A WKSystem is created with a WKAccount and thus one system exists for each User.

A WKSystem is created with a WKDatbaseClient which is used to store the User's public blockchain information - specifically transfers associated with the User's various wallets. Two types of database clients are provided for default use - one that stores no User information which thus requires re-discovering transaction each time a system is created and one that stores User information in a file-system based SQLite database.

Installation

WalletKit is delivered as a Git repository for development within Xcode and Android Studio.

Access

Git

Clone WalletKit with

git clone --recurse-submodules git@github.com:blockset-corp/walletkit.git WalletKit

If you've cloned WalletKit but without the --recursive-submodules flag then perform:

(cd .../WalletKit; git submodule update --init --recursive)

Otherwise a compilation error will arise when a secp256k1 header file is not found.

SwiftPM

...

Maven

...

Setup

WalletKit must be configured to support the demo applications and the units tests. Setup is required whether one chooses Xcode or Android Studio for development. Setup entails ensuring that a file, typically called WalletKitTestsConfig.json, exists and can be built into the applications and unit tests. That file has the following structure:

{
  "blockset": {
    "baseURL": "https://api.blockset.com",
    "token":   "<blockset access token>"
  },

  "accounts": [
    {
      "identifier": "ginger",
      "paperKey":   "ginger settle marine tissue robot crane night number ramp coast roast critic",
      "timestamp":  "2018-01-01",
      "network":    "testnet",
      "content":    "BTC, BCH, ETH"
    },

    {
      "identifier": "tape",
      "paperKey":   "tape argue fetch truck cattle quiz wide equal inform rabbit ranch educate",
      "timestamp":  "2018-04-02",
      "network":    "testnet",
      "content":    "(NO) BTC"
    },
    
    ...
    }

The structure is as follows:

  • The "blockset" dictionary detemines how the FastSync capability is accomplisted with a connection to Blockset. Use of FastSync requires a "blockset client access token", which can be obtained from Blockset Docs, Client Authentication.

  • The "accounts" array defines 'paperKeys' to use when creating an 'account' for connecting to various blockchains. You can add your own 'paperKeys', including ones for mainnet. It is a good idea to get the "timestamp" correct so that searching for transactions (aka 'syncing') has a reasonable starting time.

To specify a WalletKitTestsConfig.json file do the following:

  • Copy the file .../WalletKit/templates/WalletKitTestsConfig_example.json into a location in your file system, generally outside of the WalletKit cloned directory. For example, ${HOME}/.walletKitTestsConfig.json is a common location. If you edit the file and add your own paperKeys then you will want to ensure that those changes are kept independent of the WalletKit directory.

  • Copy the file .../WalletKit/templates/WalletKitTestsConfig.env to .../WalletKit/WalletKitTestsConfig.env and then edit that file by changing the assignment of WALLET_KIT_TESTS_CONFIG_FILE to point to your config file.

With the .env file specified, the WalletKit build process will copy the .json file into the iOS and Android mobile apps as a resource and into locations accessible by the unit tests.

Building

Swift Package Manager

The WalletKit Swift framework can be built with swift build; the unit tests can be run with swift test. This will work on MacOS and on Linux operating systems. The swift-tools-version must be 5.3 or greater (see .../WalletKit/WalletKitSwift/Package.swift)

Gradle

The WalletKit Java library can be built with ...

Xcode

WalletKit can be started in Xcode using open .../WalletKit/WalletKitSwift/WalletKitDemo/WalletKitDemo.xcworkspace. This defines a workspace that allows one to access the Swift Demo App, the WalletKit Swift code and the WalletKitCore C code.

Android Studio

WalletKit can be started in Android Studio using ...

Command Line

The cmake file 'WalletKitCore/CMakeLists.txt' can be used to build all of the C code into
libWalletKitCore.so which can then be linked into an exectuable.

A Makefile located within WalletKitCore can be used to build natively for either:

  • Darwin/Clang
  • GNU/Linux

The WalletKit shared library can be built via make libs, and shared libraries and test applications can be built via make tests. Cmake will select the toolchain appropriately, or the compiler toolchain can be selected specifically via export CC=gcc;make tests for example.

Build output goes to the build folder.

Framework Use

WalletKit is delivered as a framework and is designed to be embedded in another application. The WalletKit interfaces are implmented in each of C, Swift and Java. All the interfaces are analogous to one other with differences owing to idiomatic usage for that language.

Concepts

The following describes the C interfaces, upon which the Swift and Java interfaces are built.

WKSystem

Use of the framework starts with the instantiation of WKSystem. The top-level interfaces is:

extern WKSystem
wkSystemCreate (WKClient client,
                WKListener listener,
                WKAccount account,
                const char *path,
                WKBoolean onMainnet);

Given a system, one invokes wkSystemStart() to begin receiving events on listener and then wkSystemConnect() to begin processing blockchain transactions on client. If internet connection is lost one calls wkSystemDisconnect() and then one connects again when internet connectivity is restorted.

Beyond this, there are various WKSystem accessor functions.

The embedding applications primary interaction with a system comes from the WKListener.
As listener callbacks (aka events) occur, the application can create wallet managers of interest, update the UI with the blockchains current height, display wallet balances and transfers.

WKListener

A WKListener is created with:

extern WKListener
wkListenerCreate (WKListenerContext context,
                  WKListenerSystemCallback systemCallback,
                  WKListenerNetworkCallback networkCallback,
                  WKListenerWalletManagerCallback managerCallback,
                  WKListenerWalletCallback walletCallback,
                  WKListenerTransferCallback transferCallback);

where the context allows the application to reestablish its own state within each listener callback. The callbacks are functions; WKListenerSystemCallback is:

typedef void (*WKListenerSystemCallback) (WKListenerContext context,
                                          WKSystem system,
                                          WKSystemEvent event);

where the WKSysemEvent types are:

typedef enum {
    WK_SYSTEM_EVENT_CREATED,
    WK_SYSTEM_EVENT_CHANGED,
    WK_SYSTEM_EVENT_DELETED,

    WK_SYSTEM_EVENT_NETWORK_ADDED,
    WK_SYSTEM_EVENT_NETWORK_CHANGED,
    WK_SYSTEM_EVENT_NETWORK_DELETED,

    WK_SYSTEM_EVENT_MANAGER_ADDED,
    WK_SYSTEM_EVENT_MANAGER_CHANGED,
    WK_SYSTEM_EVENT_MANAGER_DELETED,

    WK_SYSTEM_EVENT_DISCOVERED_NETWORKS,
} WKSystemEventType;

These events detail the system changes in state. The listener takes actions appropriate for the application. Notably, on NETWORK_ADDED or DISCOVERED_NETWORKS the application can create a WKWalletManager for each network of interest. One might be interested in BTC and ETH network types, but not BCH for example.

As the networks are announced and wallet managers of interest are created, then their associated callbacks occur, including adding wallets to wallet manager and adding transfers to wallets. The WKListener instance handles each event with an update to application state, typically the UI.

WKClient

A WKClient is created as a value-type instance of:

typedef struct {
    WKClientContext context;
    WKClientGetBlockNumberCallback  funcGetBlockNumber;
    WKClientGetTransactionsCallback funcGetTransactions;
    WKClientGetTransfersCallback funcGetTransfers;
    WKClientSubmitTransactionCallback funcSubmitTransaction;
    WKClientEstimateTransactionFeeCallback funcEstimateTransactionFee;
} WKClient;

where the context allows the application to reestablish its own state within each client callback. The callbacks are functions; WKClientGetTransactionsCallback is:

typedef void
(*WKClientGetTransactionsCallback) (WKClientContext context,
                                    OwnershipGiven WKWalletManager manager,
                                    OwnershipGiven WKClientCallbackState callbackState,
                                    OwnershipKept const char **addresses,
                                    size_t addressCount,
                                    WKBlockNumber begBlockNumber,
                                    WKBlockNumber endBlockNumber);

This callback queries the manager's network for transactions in blocks [begBlockNumber, endBlockNumber) that involve any of addressCount addresses in the array addresses. Once all the transactions have been identified, the application invokes

extern void
wkClientAnnounceTransactions (OwnershipKept WKWalletManager cwm,
                              OwnershipGiven WKClientCallbackState callbackState,
                              WKBoolean success,
                              WKClientTransactionBundle *bundles,
                              size_t bundlesCount);

with one bundle created for each transaction using:

extern WKClientTransactionBundle
wkClientTransactionBundleCreate (WKTransferStateType status,
                                 OwnershipKept uint8_t *transaction,
                                 size_t transactionLength,
                                 WKTimestamp timestamp,
                                 WKBlockNumber blockHeight);

Other callbacks have similar forms: a) perform a query to get the objects of interest, b) create a specified 'bundle' for each object, c) and then 'announce' all the bundles.

A default WKClient, based on Blockset is implemented in the Swift and Java code - where convenient HTTP related functions are accessible for iOS, Android and Linux platforms.

WKAccount

A WKAccount is created in one of two ways. For the very first time, an account is created with:

extern WKAccount
wkAccountCreate (const char *paperKey, WKTimestamp timestamp, const char *uids);

where paperKey is a BIP-39 sequence of 12 words, timestamp is the Unix time at which the paperKey was initially created (or the time of the User's first transaction on any blockchain), and uids is a globally unique identifier for the account. The uids is not used internally by WalletKit.

Once an account is created and to avoid repeated use of the sensitive, private paperKey, one creates a serialization of the account with wkAccountSerialize() and then subsequently re-creates the account with:

extern WKAccount
wkAccountCreateFromSerialization (const uint8_t *bytes, size_t bytesCount, const char *uids);

The BIP-39 paperKey is thus only used in two cases: 1) to create the account initially and 2) to sign transactions.

WKDatabaseClient

TBD

Example

WalletKit is designed to be include in Swift, Java or C executables. An example is provided for each.

The high-level process is to create a System by providing: - Client - implements functions designed to query for a User's transactions. The Swift and Java implementations provide a default client that uses Blockset - Listener - implements functions, as callbacks, that announce changes to WalletKit state such as the addition of a Transfer to a Wallet. - Account - provides the public key information needed to derive a User's addresses. The private key is only needed when signing transactions for submission to a blockchain.

Given a System one then starts and connects it.

Importantly, one of the early events provided by a System, which gets announced through the Listener interface, is the WK_SYSTEM_EVENT_NETWORK_ADDED event. All networks, aka blockchains such as BTC, BCH, DOGE, ETH, XRP, etc, supported by WalletKit get announced. If your application is interested in the announced network, your application must call wkSystemCreateWalletManager(). The created wallet manager is responsible for managing the currencies on that network.

Swift

Java

C

Versions

0.10.0

Version 0.10.0 is currently the basis for the BRD iOS and Android mobile applications. Note that walletkit-0.10.x has evolved from core-9.x.x

Support

Contact Blockset