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Development Tools, Frameworks and Libraries

Frameworks

Frameworks can be used to ease development. By doing everything yourself you get a better understanding of how everything fits together, but it’s a lot of tedious work and it’s mostly doing the same over and over. These frameworks can automate some of these tasks and make development a breeze.

Truffle

Documentation link; https://truffleframework.com/docs

npm packages repository link; https://www.+npm+js.com/package/truffle

Installing the truffle framework

The truffle framework is made of several NodeJS packages. Before we install truffle, we need to have an up-to-date and working installation of NodeJS and the Node Package Manager (npm).

The recommended way to install NodeJS and npm, is to use the Node Version Manager, nvm. Once we install nvm, it will handle all the dependencies and updates for us. We’ll follow the instructions found at: http://nvm.sh

Once nvm is installed on your operating system, installing NodeJS is simple. We use the --lts flag to tell nvm that we want the most recent "Long Term Support (LTS)" version of NodeJS

$ nvm install --lts

Confirm you have node and npm installed:

$ node -v
v8.9.4
$ npm -v
5.6.0

Looking good. Now to install truffle:

$ npm -g install truffle

+ [email protected]
installed 1 package in 37.508s

Creating a truffle project directory

For each project where we will use truffle, we create a project directory and initialize truffle within that directory. Truffle will create the necessary directory structure inside our project directory. Customarily, we give the project directory a name that describes our project. For this example, we will use truffle to deploy our faucet contract from [simple_contract_example], and therefore we will name the project folder Faucet.

$ mkdir faucet
$ cd Faucet
Faucet $

Once inside the Faucet directory, we initialize truffle:

Faucet $ truffle init

Truffle creates a directory structure and some default files:

Faucet
├── contracts
│   └── Migrations.sol
├── migrations
│   └── 1_initial_migration.js
├── test
├── truffle-config.js
└── truffle.js

We will also use a number of JavaScript (nodeJS) support packages, in addition to truffle itself. We can install these with npm. We initialize the npm directory structure and accept the defaults suggested by npm:

$ npm init

package name: (faucet)
version: (1.0.0)
description:
entry point: (truffle-config.js)
test command:
git repository:
keywords:
author:
license: (ISC)
About to write to Faucet/package.json:

{
  "name": "faucet",
  "version": "1.0.0",
  "description": "",
  "main": "truffle-config.js",
  "directories": {
    "test": "test"
  },
  "scripts": {
    "test": "echo \"Error: no test specified\" && exit 1"
  },
  "author": "",
  "license": "ISC"
}


Is this ok? (yes)

Now, we can install the dependencies that we will use to make working with truffle easier:

$ npm install dotenv truffle-wallet-provider ethereumjs-wallet

You now have a node_modules directory with several thousand files, inside your Faucet directory.

Configuring truffle

Truffle creates some empty configuration files, truffle.js and truffle-config.js. There are two configuration files because on Windows systems, the truffle.js name may cause a conflict when you try to run truffle the command and Windows attempts to run truffle.js instead. We will delete truffle.js and use truffle-config.js, in support of Windows users who, after all, are suffering enough already.

$ rm truffle.js

Now we edit truffle-config.js and replace the contents with:

truffle-config.js - a truffle configuration to get us started
module.exports = {
	networks: {
		localnode: { // Whatever network our local node connects to
			network_id: "*", // Match any network id
			host: "localhost",
			port: 8545,
		}
	}
};

The configuration above is a good starting point. It sets up one default Ethereum network (named localnode), which assumes you are running an Ethereum client (such as parity), either as a full node, or as a light client. This configuration will instruct truffle to communicate with the local node over RPC, on port 8545. Truffle will use whatever Ethereum network the local node is connected to, such as the Ethereum main network, or a test network like Ropsten. The local node will also be providing the wallet functionality.

In following sections, we will configure additional networks for truffle to use, such as the ganache test-RPC blockchain and Infura, a hosted network provider. As we add more networks, the configuration file will get more complex, but it will also give us more options for our testing and development workflow.

Using truffle to deploy a contract

We now have a basic working directory for our Faucet project, and we have truffle and its dependencies configured. Contracts go in the contracts subdirectory of our project. The directory already contains a "helper" contract, Migrations.sol which manages contract upgrades for us. We’ll examine the use of Migrations.sol in a later section.

Let’s copy the Faucet.sol contract (from [solidity_faucet_example]) into the contracts subdirectory, so that the project directory looks like this:

Faucet
├── contracts
│   ├── Faucet.sol
│   └── Migrations.sol
...

We can now ask truffle to compile the contract for us:

$ truffle compile
Compiling ./contracts/Faucet.sol...
Compiling ./contracts/Migrations.sol...
Writing artifacts to ./build/contracts

Truffle migrations - understanding deployment scripts

Truffle offers a deployment system called a migration. If you have worked in other frameworks, you may have seen something similar: Ruby on Rails, Python Django and many other languages and frameworks have a migrate command.

In all those frameworks, the purpose of a migration is to handle changes in the data schema between different versions of the software. The purpose of migrations in Ethereum is slightly different. Because Ethereum contracts are immutable and cost gas to deploy, truffle offers a migration mechanism to keep track of which contracts (and which versions) have already been deployed. In a complex project with dozens of contracts and complex dependencies, you would not want to have to pay to redeploy contracts that haven’t changed. You would also not want to manually track which versions of which contracts have been deployed already. The truffle migration mechanism does all that by deploying the smart contract Migrations.sol, which then keeps track of all other contract deployments.

We have only one contract, Faucet.sol, which means that the migration system is overkill, to say the least. Unfortunately, we have to use it. But, by learning how to use it for one contract, we can start practicing some good habits for our development workflow. The effort will pay off as things get more complicated.

Truffle’s migrations directory is where the migration scripts are found. Right now, there’s only one script 1_initial_migration.js, which deploys the Migrations.sol contract itself:

[[1_initial_migration]] .1_initial_migration.js - the migration script for Migrations.sol

include::code/Faucet/migrations/1_initial_migration.js

We need a second migration script, to deploy Faucet.sol. Let’s call it 2_deploy_contracts.js. It is very simple, just like 1_initial_migration.js, with only a few small changes. In fact, you can copy the contents of 1_initial_migration.js and simply replace all instances of Migrations with Faucet:

[[2_deploy_contracts]] .2_deploy_contracts.js - the migration script for Faucet.sol

include::code/Faucet/migrations/2_deploy_contracts.js

The script initializes a variable Faucet, identifying the Faucet.sol Solidity source code as the artifact that defines Faucet. Then, it calls the deploy function to deploy this contract.

We’re all set. Let’s use truffle migrate to deploy the contract. We have to specify on which network to deploy the contract, using the --network argument. We only have one network specified in the configuration file, which we named localnode. Make sure your local Ethereum client is running and then type:

Faucet $ truffle migrate --network localnode

Because we are using a local node to connect to the Ethereum network and manage our wallet, we have to authorize the transaction that truffle creates. I’m running parity connected to the Ropsten test blockchain, so during the truffle migration I will see a pop-up on parity’s web console:

Parity asking for confirmation to deploy Faucet
Figure 1. Parity asking for confirmation to deploy Faucet

You will see four transactions, total. One to deploy Migrations, one to update the deployments counter to 1, one to deploy Faucet and one to update the deployments counter to 2.

Truffle will show the migrations completing, show each of the transactions and show the contract addresses:

$ truffle migrate --network localnode
Using network 'localnode'.

Running migration: 1_initial_migration.js
  Deploying Migrations...
  ... 0xfa090db179d023d2abae543b4a21a1479e70ca7d35a469a5d1a98bfc6bd80fe8
  Migrations: 0x8861c27715550bed8362c0345add158489df6db0
Saving successful migration to network...
  ... 0x985c4a32716826ddbe4eae284104bef8bc69e959899f62246a1b27c9dfcd6c03
Saving artifacts...
Running migration: 2_deploy_contracts.js
  Deploying Faucet...
  ... 0xecdbeef77f0558edc689440e34b7bba0a3ba7a45e4b680b071b47c30a930e9d6
  Faucet: 0xd01cd8e7bd29e4bff8c1693f59eee46137a9f300
Saving successful migration to network...
  ... 0x11f376bd7307edddfd40dc4a14c3f7cb84b6c921ac2465602060b67d08f9fd8a
Saving artifacts...

Using the truffle console

Truffle offers a JavaScript console that we can use to interact with the Ethereum network (via the local node), interact with deployed contracts, and interact with the wallet provider. In our current configuration (localnode), the node and wallet provider is our local parity client.

Let’s start the truffle console and try some commands:

$ truffle console --network localnode
truffle(localnode)>

Truffle presents a prompt, showing the selected network configuration (localnode). It’s important to remember and be aware of which network we are using. You wouldn’t want to accidentally deploy a test contract or make a transaction on the Ethereum main network. That could be an expensive mistake!

The truffle console offers an auto-complete function that makes it easy for us to explore the environment. If we press Tab after a partially-completed command, truffle will complete the command for us. Pressing Tab twice will show all possible completions if more than one command matches our input. In fact, if we press Tab twice on an empty prompt, truffle lists all commands:

truffle(localnode)>
Array Boolean Date Error EvalError Function Infinity JSON Math NaN Number Object RangeError ReferenceError RegExp String SyntaxError TypeError URIError decodeURI decodeURIComponent encodeURI encodeURIComponent eval isFinite isNaN parseFloat parseInt undefined

ArrayBuffer Buffer DataView Faucet Float32Array Float64Array GLOBAL Int16Array Int32Array Int8Array Intl Map Migrations Promise Proxy Reflect Set StateManager Symbol Uint16Array Uint32Array Uint8Array Uint8ClampedArray WeakMap WeakSet WebAssembly XMLHttpRequest _ assert async_hooks buffer child_process clearImmediate clearInterval clearTimeout cluster console crypto dgram dns domain escape events fs global http http2 https module net os path perf_hooks process punycode querystring readline repl require root setImmediate setInterval setTimeout stream string_decoder tls tty unescape url util v8 vm web3 zlib

__defineGetter__ __defineSetter__ __lookupGetter__ __lookupSetter__ __proto__ constructor hasOwnProperty isPrototypeOf propertyIsEnumerable toLocaleString toString valueOf

The vast majority of the wallet and node related functions are provided by the web3 object, which is an instance of the web3.js library. The web3 object abstracts the RPC interface into our parity node. You will also notice two objects with familiar names: Migrations and Faucet. Those represent the contracts we just deployed. We will use the truffle console to interact with a contract. First, let’s check our wallet via the web3 object:

truffle(localnode)> web3.eth.accounts
[ '0x9e713963a92c02317a681b9bb3065a8249de124f',
  '0xdb5dc1a13e3a55cf3b4587cd8d1e5fdeb6738145' ]

Our parity client has two wallets, with some test ether on Ropsten. The web3.eth.accounts attribute contains a list of all the accounts. We can check the balance of the first account, using the getBalance function:

truffle(localnode)> web3.eth.getBalance(web3.eth.accounts[0]).toNumber()
191198572800000000
truffle(localnode)>

The web3.js is a large JavaScript library that offers a comprehensive interface to the Ethereum system, via a provider such as a local client. We will examine web3.js in more detail in web3js. Now let’s try to interact with our contracts:

truffle(localnode)> Faucet.address
'0xd01cd8e7bd29e4bff8c1693f59eee46137a9f300'
truffle(localnode)> web3.eth.getBalance(Faucet.address).toNumber()
0
truffle(localnode)>

Next, we’ll use sendTransaction to send some test ether to fund the Faucet. Note the use of web3.toWei to convert ether units for us. Typing eighteen zeros without making a mistake is both difficult and dangerous, so it’s always better to use a unit converter for values. Here’s how we send the transaction:

truffle(localnode)> web3.eth.sendTransaction({from:web3.eth.accounts[0], to:Faucet.address, value:web3.toWei(0.5, 'ether')});
'0xf134c75b985dc0e0c27c2f0412251e0860eb530a5055e660f21e7483ab336808'

Switch to the web console on parity, where you will see a pop-up asking you to confirm this transaction. Wait a minute and once the transaction is mined, you will be able to see the balance of our Faucet contract:

truffle(localnode)> web3.eth.getBalance(Faucet.address).toNumber()
500000000000000000

Let’s call the withdraw function now, to withdraw some test ether from the Faucet:

truffle(localnode)> Faucet.deployed().then(instance => {instance.withdraw(web3.toWei(0.1, 'ether'))}).then(console.log)

Again, you will need to approve the transaction in the parity web console. The balance of the Faucet has decreased, and our test wallet has received 0.1 ether:

truffle(localnode)> web3.eth.getBalance(Faucet.address).toNumber()
400000000000000000
truffle(localnode)> Faucet.deployed().then(instance => {instance.withdraw(web3.toWei(1, 'ether'))})
StatusError: Transaction: 0xe147ae9e3610334ada8d863c9028c12bd0501be2d0cfd05865c18612b92d3f9c exited with an error (status 0).

Ganache: A personal blockchain for Ethereum development

You can use Ganache to deploy contracts, develop your applications, and run tests. It is available as a desktop application for Windows, Mac, and Linux.

Ganache CLI: Ganache as a command-line tool

This tool was previously known under the name "ethereumJS TestRPC".

$ npm install -g ganache-cli

Embark

npm packages repository link; https://www.+npm+js.com/package/embark

$ npm -g install embark

Dapple (?)

Utilities

ethereumJS helpeth: A command line utility

helpeth is a command line tool for key and transaction manipulation that makes a developer’s job a lot easier.

It is part of the ethereumjs collection of JavaScript based libraries and tools.

Usage: helpeth [command]

Commands:
  signMessage <message>                     Sign a message
  verifySig <hash> <sig>                    Verify signature
  verifySigParams <hash> <r> <s> <v>        Verify signature parameters
  createTx <nonce> <to> <value> <data>      Sign a transaction
  <gasLimit> <gasPrice>
  assembleTx <nonce> <to> <value> <data>    Assemble a transaction from its
  <gasLimit> <gasPrice> <v> <r> <s>         components
  parseTx <tx>                              Parse raw transaction
  keyGenerate [format] [icapdirect]         Generate new key
  keyConvert                                Convert a key to V3 keystore format
  keyDetails                                Print key details
  bip32Details <path>                       Print key details for a given path
  addressDetails <address>                  Print details about an address
  unitConvert <value> <from> <to>           Convert between Ethereum units

Options:
  -p, --private      Private key as a hex string                        [string]
  --password         Password for the private key                       [string]
  --password-prompt  Prompt for the private key password               [boolean]
  -k, --keyfile      Encoded key file                                   [string]
  --show-private     Show private key details                          [boolean]
  --mnemonic         Mnemonic for HD key derivation                     [string]
  --version          Show version number                               [boolean]
  --help             Show help                                         [boolean]

dapp.tools

Installing:

$ curl https://nixos.org/nix/install | sh
$ nix-channel --add https://nix.dapphub.com/pkgs/dapphub
$ nix-channel --update
$ nix-env -iA dapphub.{dapp,seth,hevm,evmdis}

Libraries

web3js

web3js is the Ethereum compatible JS API for communicating with clients via JSON RPC, developed by the Ethereum foundation.

web3.py

web3.py is a Python library for interacting with the Ethereum blockchain. It now lives in the Ethereum Foundation’s GitHub too.

Documentation link; https://web3py.readthedocs.io/

EthereumJS

a collection of libraries and utilities for Ethereum.

web3j

web3j is the Java and Android library for integrating with Ethereum clients and working with smart contracts.

Website link; https://web3j.io

Documentation link; https://docs.web3j.io

Nethereum

Nethereum is the .Net integration library for Ethereum.

Website link; http://nethereum.com/