@cogitojs/cogito-ethereum
Provides a means to interact with smart contracts on an Ethereum blockchain using the Cogito app. Uses the accounts that are stored in the Cogito app on the user's phone. Whenever a blockchain transaction is initiated, the user is prompted to sign it using the Cogito app.
This package aims to make working with cogito-web3-provider, telepath, and Ethereum contracts easier. You do not have know all the details about web3 providers, cogito-web3-provider, and telepath, in order to setup a working cogito ecosystem.
Usage
Add @cogitojs/cogito-ethereum as a dependency
$ yarn add `@cogitojs/cogito-ethereum`@cogitojs/cogito-ethereum's main abstraction is CogitoEthereum. Before we
learn how to use CogitoEthereum, we need first make sure we have a good
understanding how CogitoEthereum handles the Ethereum contracts.
Working with Contracts
Developers working with Ethereum contract often use a convenience package
truffle-contract. To get an instance of a contract you first import
truffle-contract. What you will get from importing truffle-contract is a
function that takes a contract definition as an argument and returns a proxy
object that you can use to interact with your contract. Before you can do that,
however, you still need to set the provider on the returned proxy object:
import Web3 from 'web3'
import initContract from 'truffle-contract'
import { SimpleStorage } from '@cogitojs/demo-app-contracts'
const providerUrl = 'http://localhost:9545' // example for the local development
const provider = new Web3.providers.HttpProvider(providerUrl)
const web3 = new Web3(provider)
const contractProxy = initContract(SimpleStorage())
contractProxy.setProvider(provider)
// or if you got web3 already initialized
contractProxy.setProvider(web3.currentProvider)Please, note that
@cogitojs/demo-app-contractsexports a function that returns the actual contract JSON blob. We could also directly return a function, but that would make mocking withjest.mock('@cogitojs/demo-app-contracts')not possible.jest.mockcan only mock exported functions. This is why in the snipped above we are callingSimpleStorage()instead of just usingSimpleStorage. In the following examples we will directly import JSON blobs from JSON files.
To get the actual instance of the contract, you can use one of the proxy
methods: deployed(), at(), or new(). Please refer to the documentation of
truffle-contract for more information.
Creating an instance of CogitoEthereum
CogitoEtheruem expects an array of contracts JSON blobs as the first
constructor argument:
import DataStoreJSON from 'contracts/DataStore.json'
import DataRequestJSON from 'contracts/DataRequest.json'
import DataResponseJSON from 'contracts/DataResponse.json'
import { CogitoEthereum } from '@cogitojs/cogito-ethereum'
const cogitoEthereum = new CogitoEthereum([ DataStoreJSON, DataRequestJSON, DataResponseJSON ])CogitoEtheruem takes care for setting up a new Web3 instance that uses the
CogitoProvider from @cogitojs/cogito-web3-provider as the currentProvider
(cogitoWeb3), the associated telepath channel (telepathChannel), and an
object with contract proxies corresponding to each contract JSON blob passed in
the first constructor argument (contractsProxies). cogitoWeb3,
telepathChannel, and contractsProxies together are called a context and
can be retrieved using CogitoEthereum instance method: getContext:
const {
cogitoWeb3,
telepathChannel,
contractsProxies
} = await cogitoEthereum.getContext({ appName: 'Demo App' })getContext expect an object as an argument: { channelId, channelKey, appName }. If channelId and/or channelKey are not provided, a new random value
will be created, and the resulting channelId and channelKey will be used to
create a telepath channel instance. Notice, that the appName attribute is
required.
The returned telepathChannel attribute refers to an instance of a
JsonRpcChannel that is returned by the createChannel method of the instance
of Telepath. It provides the channel id as telepathChannel.id, the channel
key as telepathChannel.key, allows to send a JSON-RPC request using
send(request), and provides a convenience method to get the telepath
connection url via telepathChannel.createConnectUrl(). This connection url
can be use to generate the QR-Code to be scanned by the Cogito app in order to
establish a secure connection with the JavaScript client. To learn more about
Telepath, connection URLs, and QR-Codes, please refer to the documentation of
the telepath-js package.
cogitoWeb3 holds a reference to a valid Web3 object that uses
CogitoProvider as the provider. It means that requests for requesting
Ethereum accounts (cogitoWeb3.eth.getAccounts(), see also eth_accounts) or
sending Ethereum transactions (cogitoWeb3.eth.sendTransaction, see also
eth_sendTransaction) will be redirect to the client via associated telepath
channel.
Finally, contractsProxies is an object with attributes referring to the
contract proxies corresponding to the provided contract JSON blobs. For
example:
const cogitoEthereum = new CogitoEthereum([ DataStore, DataRequest, DataResponse ])
const { contractsProxies } = await cogitoEthereum.getContext({ appName: 'Demo App' })
const { DataStore, DataRequest, DataResponse } = contractsProxies
const dataStoreContractInstance = await DataStore.deployed()
const dataRequestContractInstance = await DataRequest.at(await dataStoreContractInstance.getDataRequest())
const dataResponseContractInstance = await DataResponse.at(await dataStoreContractInstance.getDataResponse())The names of the attributes in the contractsProxies object correspond to the
name of the contracts as given by the contractName attribute of the
corresponding contract JSON blob.
Finally, CogitoEthereum accepts an optional second argument holding the
queuing service url to be used with telepath. The default is
https://telepath.cogito.mobi.