Deploy a contract using web3.js
In this tutorial, you'll create a simple smart contract and use the Web3 JavaScript library to compile and then deploy the smart contract.
Prerequisites
- An Ethereum project on Infura
- Node.js installed
- An Ethereum account for testing purposes
You can use MetaMask or similar to create an Ethereum account for testing purposes.
Steps
1. Fund your Ethereum account
Use the Infura faucet to load testnet ETH on your Ethereum account for the Sepolia network.
If using a network other than Sepolia, ensure you update your environment file with the network name.
2. Create a project directory
Create a new directory for your project. You can do this from the command line:
mkdir deployContract
Change into the new directory:
cd deployContract
3. Install required packages
Install the web3, solc, and dotenv packages in the project directory.
The dotenv package allows you to use a .env file to securely store private environment variables on your local machine.
Install the web3 package:
npm install web3
This example has been written for web3js v4.x. It may not work for earlier versions.
Install the solidity compiler (solc package):
npm install solc
Install the dotenv package:
npm install dotenv
4. Create the .env file
Create a .env file in your project directory to store the project and Ethereum account details.
ETHEREUM_NETWORK = "sepolia"
INFURA_API_KEY = "<Your-API-Key>"
SIGNER_PRIVATE_KEY = "<Your-Private-Key>"
Ensure you replace the following values in the .env file:
<Your-API-Key>with the API key of the Ethereum project.<Private-Key>with the private key of your Ethereum account.- If using a network other than Sepolia, ensure you update
ETHEREUM_NETWORKwith the network name.
Never disclose your private key. Anyone with your private keys can steal any assets held in your account.
5. Create a smart contract
Using an editor, create a smart contract. In this example, we'll create a basic contract called Demo.sol.
pragma solidity >=0.5.8;
contract Demo {
event Echo(string message);
function echo(string calldata message) external {
emit Echo(message);
}
}
6. Create the compile script
We need to compile the contract to ensure the code is correct.
You can compile the smart contract using the solc command line options. In this example, we'll create a compile script using JavaScript.
Create a file called compile.js with the following content:
const fs = require("fs").promises;
const solc = require("solc");
async function main() {
// Load the contract source code
const sourceCode = await fs.readFile("Demo.sol", "utf8");
// Compile the source code and retrieve the ABI and Bytecode
const { abi, bytecode } = compile(sourceCode, "Demo");
// Store the ABI and Bytecode into a JSON file
const artifact = JSON.stringify({ abi, bytecode }, null, 2);
await fs.writeFile("Demo.json", artifact);
}
function compile(sourceCode, contractName) {
// Create the Solidity Compiler Standard Input and Output JSON
const input = {
language: "Solidity",
sources: { main: { content: sourceCode } },
settings: { outputSelection: { "*": { "*": ["abi", "evm.bytecode"] } } },
};
// Parse the compiler output to retrieve the ABI and Bytecode
const output = solc.compile(JSON.stringify(input));
const artifact = JSON.parse(output).contracts.main[contractName];
return {
abi: artifact.abi,
bytecode: artifact.evm.bytecode.object,
};
}
main()
7. Run the compile script
In the compile script we'll also copy the generated Application Binary Interface (ABI) and binary to a file called Demo.json.
To compile the contract run the following command:
node compile.js
A file called Demo.json should be created in the directory.
8. Create the deployment script
Next, we'll create a deployment script called deploy.js. The script uses the Web3 methods to sign the transaction and deploy the smart contract to the network.
const { Web3 } = require("web3");
// Loading the contract ABI and Bytecode
// (the results of a previous compilation step)
const fs = require("fs");
const { abi, bytecode } = JSON.parse(fs.readFileSync("Demo.json"));
async function main() {
// Configuring the connection to an Ethereum node
const network = process.env.ETHEREUM_NETWORK;
const web3 = new Web3(
new Web3.providers.HttpProvider(
`https://${network}.infura.io/v3/${process.env.INFURA_API_KEY}`,
),
);
// Creating a signing account from a private key
const signer = web3.eth.accounts.privateKeyToAccount(
'0x' + process.env.SIGNER_PRIVATE_KEY,
);
web3.eth.accounts.wallet.add(signer);
// Using the signing account to deploy the contract
const contract = new web3.eth.Contract(abi);
contract.options.data = bytecode;
const deployTx = contract.deploy();
const deployedContract = await deployTx
.send({
from: signer.address,
gas: await deployTx.estimateGas(),
})
.once("transactionHash", (txhash) => {
console.log(`Mining deployment transaction ...`);
console.log(`https://${network}.etherscan.io/tx/${txhash}`);
});
// The contract is now deployed on chain!
console.log(`Contract deployed at ${deployedContract.options.address}`);
console.log(
`Add DEMO_CONTRACT to the.env file to store the contract address: ${deployedContract.options.address}`,
);
}
require("dotenv").config();
main();
9. Deploy the contract
Run the deployment script to deploy the contract to the blockchain:
node deploy.js
The contract deploys to the blockchain and the script displays the contract address.
To make calls to the contract in the future we'll need the contract address. Next we'll update the .env file to store the contract address.
10. Update the .env file
Update the .env file in the working directory to include the contract address. In this example, we'll add the DEMO_CONTRACT variable:
ETHEREUM_NETWORK = "sepolia"
INFURA_API_KEY = "<Your-API-Key>"
SIGNER_PRIVATE_KEY = "<Your-Private-Key>"
DEMO_CONTRACT = "<Contract_Address>"
Next steps
You can now make calls to the deployed contract. A contract call is a transaction that will consume gas on the public Ethereum network.