How to Create an NFT

This tutorial is Part I of a series on NFTs that will take you step by step on how to write and deploy a Non Fungible Token (ERC721 token) smart contract using Ethereum and Inter Planetary File System (IPFS). In Part II, we will describe how to mint an NFT using our smart contract, and in Part III, we will explain how to view your freshly minted NFT on Metamask!

Even if you’ve been living under a rock, you’ll have noticed that every major news outlet has been profiling the rise of NFTs in the past few weeks.

Alchemy is extremely proud to be powering the biggest names in the NFT space, including Makersplace (recently set a record digital artwork sale at Christie’s for $69 Million), Dapper Labs (creators of NBA Top Shot & Crypto Kitties), OpenSea (the world’s largest NFT marketplace), Zora, Super Rare, NFTfi, Foundation, Enjin, Origin Protocol, Immutable, and more.

With NFTs bringing blockchain into the public eye, now is an excellent opportunity to understand the hype yourself by publishing your own NFT (ERC-721 Token) on the Ethereum blockchain!

In this tutorial, we will walk through creating and deploying an ERC-721 smart contract on the Ropsten test network using Metamask, Solidity, Hardhat, Pinata and Alchemy (don’t fret if you don’t understand what any of this means yet — we will explain it!).

In Part II of this tutorial we’ll go through how we can use our smart contract to mint an NFT, and in Part III we’ll explain how view your NFT on Metamask.

And of course, if you have questions at any point, don’t hesitate to reach out in the Alchemy Discord!

Step 1: Connect to the Ethereum network

There a bunch of ways to make requests to the Ethereum blockchain, but to make things easiest, we’ll use a free account on Alchemy, a blockchain developer platform and API that allows us to communicate with the Ethereum chain without having to run our own nodes.

In this tutorial, we’ll also take advantage of Alchemy’s developer tools for monitoring and analytics to understand what’s going on under the hood in our smart contract deployment. If you don’t already have an Alchemy account, you can sign up for free here.

Step 2: Create your app (and API key)

Once you’ve created an Alchemy account, you can generate an API key by creating an app. This will allow us to make requests to the Ropsten test network. Check out this guide if you’re curious to learn more about test networks.

1. Navigate to the “Create App” page in your Alchemy Dashboard by hovering over “Apps” in the nav bar and clicking “Create App”

Create your app

2. Name your app (we chose “My First NFT!”), offer a short description, select “Staging” for the Environment (used for your app bookkeeping), and choose “Ropsten” for your network.

Configure and publish your app

3. Click “Create app” and that’s it! Your app should appear in the table below.

Step 3: Create an Ethereum account (address)

We need an Ethereum account to send and receive transactions. For this tutorial, we’ll use Metamask, a virtual wallet in the browser used to manage your Ethereum account address. If you want to understand more about how transactions on Ethereum work, check out this page from the Ethereum foundation.

You can download and create a Metamask account for free here. When you are creating an account, or if you already have an account, make sure to switch over to the “Ropsten Test Network” in the upper right (so that we’re not dealing with real money).

Set Ropsten as your network

Step 4: Add ether from a Faucet

In order to deploy our smart contract to the test network, we’ll need some fake Eth. To get Eth you can go to the Ropsten faucet and enter your Ropsten account address, then click “Send Ropsten Eth.” You should see Eth in your Metamask account soon after!

Step 5: Check your Balance

To double check our balance is there, let’s make an eth_getBalance request using Alchemy’s composer tool. This will return the amount of Eth in our wallet. After you input your Metamask account address and click “Send Request”, you should see a response like this:

{"jsonrpc": "2.0", "id": 0, "result": "0xde0b6b3a7640000"}

NOTE: This result is in wei not eth. Wei is used as the smallest denomination of ether. The conversion from wei to eth is: 1 eth = 1⁰¹⁸ wei. So if we convert 0xde0b6b3a7640000 to decimal we get 1*1⁰¹⁸ which equals 1 eth.

Phew! Our fake money is all there🤑 .

Step 6: Initialize our project

First, we’ll need to create a folder for our project. Navigate to your command line and type:

mkdir my-nft
cd my-nft

Now that we’re inside our project folder, we’ll use npm init to initialize the project. If you don’t already have npm installed, follow these instructions (we’ll also need Node.js, so download that too!).

npm init

It doesn’t really matter how you answer the installation questions, here is how we did it for reference:

package name: (my-nft) 
version: (1.0.0) 
description: My first NFT!
entry point: (index.js) 
test command: 
git repository: 
keywords: 
author: 
license: (ISC) 
About to write to /Users/thesuperb1/Desktop/my-nft/package.json:
{
  "name": "my-nft",
  "version": "1.0.0",
  "description": "My first NFT!",
  "main": "index.js",
  "scripts": {
    "test": "echo \"Error: no test specified\" && exit 1"
  },
  "author": "",
  "license": "ISC"
}

Approve the package.json, and we’re good to go!

Step 7: Download Hardhat

Hardhat is a development environment to compile, deploy, test, and debug your Ethereum software. It helps developers when building smart contracts and dApps locally before deploying to the live chain.

Inside our my-nft project run:

npm install --save-dev hardhat

Check out this page for more details on installation instructions.

Step 8: Create Hardhat project

Inside our project folder run:

npx hardhat

You should then see a welcome message and option to select what you want to do. Select “create an empty hardhat.config.js”:

888    888                      888 888               888
888    888                      888 888               888
888    888                      888 888               888
8888888888  8888b.  888d888 .d88888 88888b.   8888b.  888888
888    888     "88b 888P"  d88" 888 888 "88b     "88b 888
888    888 .d888888 888    888  888 888  888 .d888888 888
888    888 888  888 888    Y88b 888 888  888 888  888 Y88b.
888    888 "Y888888 888     "Y88888 888  888 "Y888888  "Y888
👷 Welcome to Hardhat v2.0.11 👷‍
? What do you want to do? …
Create a sample project
❯ Create an empty hardhat.config.js
Quit

This will generate a hardhat.config.js file for us which is where we’ll specify all of the set up for our project (on step 13).

Step 9: Add project folders

To keep our project organized, we’ll create two new folders. Navigate to the root directory of your project in your command line and type:

mkdir contracts
mkdir scripts

• contracts/ is where we’ll keep our NFT smart contract code
• scripts/ is where we’ll keep scripts to deploy and interact with our smart contract

Step 10: Write our contract

Now time that our environment is set up, onto more exciting stuff: writing our smart contract code!

Open up the my-nft project in your favorite editor (we like VSCode). Smart contracts are written in a language called Solidity which is what we will use to write our MyNFT.sol smart contract.‌

1. Navigate to the “contracts” folder and create a new file called MyNFT.sol
2. Below is our NFT smart contract code, which based off of the OpenZepplin library’s ERC721 implementation. Copy and paste the contents below into your MyNFT.sol file.

//Contract based on https://docs.openzeppelin.com/contracts/3.x/erc721
// SPDX-License-Identifier: MIT
pragma solidity ^0.7.3;
import "@openzeppelin/contracts/token/ERC721/ERC721.sol";
import "@openzeppelin/contracts/utils/Counters.sol";
import "@openzeppelin/contracts/access/Ownable.sol";

contract MyNFT is ERC721, Ownable {
    using Counters for Counters.Counter;
    Counters.Counter private _tokenIds;
    constructor() public ERC721("MyNFT", "NFT") {}
    function mintNFT(address recipient, string memory tokenURI)
        public onlyOwner
        returns (uint256)
    {
        _tokenIds.increment();
        uint256 newItemId = _tokenIds.current();
        _mint(recipient, newItemId);
        _setTokenURI(newItemId, tokenURI);
        return newItemId;
    }
}

3. Because we are inheriting classes from the OpenZepplin contracts library, in your command line run npm install @openzeppelin/contracts@3.1.0-solc-0.7to install the library into our folder.

So, what does this code do exactly? Let’s break it down, line by line.

At the top of our smart contract, we import three OpenZepplin smart contract classes:

• @openzeppelin/contracts/token/ERC721/ERC721.solcontains the implementation of the ERC721 standard, which our NFT smart contract will inherit. (To be a valid NFT, your smart contract must implement all the methods of the ERC721 standard.) To learn more about the inherited ERC721 functions, check out the interface definition here.
• @openzeppelin/contracts/utils/Counters.solprovides counters that can only be incremented or decremented by one. Our smart contract uses a counter to keep track of the total number of NFTs minted and set the unique ID our new NFT. (Each NFT minted using a smart contract must be assigned a unique ID—here our unique ID is just determined by the total number of NFTs in existance. For example, the first NFT we mint with our smart contract has an ID of "1," our second NFT has an ID of "2," etc.)
• @openzeppelin/contracts/access/Ownable.sol sets up access control on our smart contract, so only the owner of the smart contract (you) can mint NFTs. (Note, including access control is entirely a preference. If you'd like anyone to be able to mint an NFT using your smart contract, remove the word Ownable on line 10 and onlyOwner on line 17.)

After our import statements, we have our custom NFT smart contract, which is surprisingly short — it only contains a counter, a constructor, and single function! This is thanks to our inherited OpenZepplin contracts, which implement most of the methods we need to create an NFT, such as ownerOf which returns the owner of the NFT, and transferFrom,which transfers ownership of the NFT from one account to another.

In our ERC721 constructor, you’ll notice we pass 2 strings, “MyNFT” and “NFT.” The first variable is the smart contract’s name, and the second is its symbol. You can name each of these variables whatever you wish!

Finally, we have our function mintNFT(address recipient, string memory tokenURI) that allows us to mint an NFT! You'll notice it this function takes in two variables:

• address recipient specifies the address that will receive your freshly minted NFT
• string memory tokenURI is a string that should resolve to a JSON document that describes the NFT's metadata. An NFT's metadata is really what brings it to life, allowing it to have configurable properties, such as a name, description, image, and other attributes. In part 2 of this tutorial, we will describe how to configure this metadata.

mintNFT calls some methods from the inherited ERC721 library, and ultimately returns a number that represents the ID of the freshly minted NFT.

Step 11: Connect Metamask & Alchemy to your project

Now that we’ve created a Metamask wallet, Alchemy account, and written our smart contract, it’s time to connect the three.

Every transaction sent from your virtual wallet requires a signature using your unique private key. To provide our program with this permission, we can safely store our private key (and Alchemy API key) in an environment file.

To learn more about sending transactions, check out this tutorial on sending transactions using web3.

First, install the dotenv package in your project directory:

npm install dotenv --save

Then, create a .env file in the root directory of our project, and add your Metamask private key and HTTP Alchemy API URL to it.

• Follow these instructions to export your private key from Metamask
• See below to get HTTP Alchemy API URL and copy it to your clipboard

Copy your Alchemy API URL

Your .env should now look like this:

API_URL = "https://eth-ropsten.alchemyapi.io/v2/your-api-key"
PRIVATE_KEY = "your-metamask-private-key"

To actually connect these to our code, we’ll reference these variables in our hardhat.config.js file on step 13.

Step 12: Install Ethers.js

Ethers.js is a library that makes it easier to interact and make requests to Ethreum by wrapping standard JSON-RPC methods with more user friendly methods.

Hardhat makes it super easy to integrate Plugins for additional tooling and extended functionality. We’ll be taking advantage of the Ethers plugin for contract deployment (Ethers.js has some super clean contract deployment methods).

In your project directory type:

npm install --save-dev @nomiclabs/hardhat-ethers 'ethers@^5.0.0'

We’ll also require ethers in our hardhat.config.js in the next step.

Step 13: Update hardhat.config.js

We’ve added several dependencies and plugins so far, now we need to update hardhat.config.js so that our project knows about all of them.

Update your hardhat.config.js to look like this:

/**
* @type import('hardhat/config').HardhatUserConfig
*/
require('dotenv').config();
require("@nomiclabs/hardhat-ethers");
const { API_URL, PRIVATE_KEY } = process.env;
module.exports = {
   solidity: "0.7.3",
   defaultNetwork: "ropsten",
   networks: {
      hardhat: {},
      ropsten: {
         url: API_URL,
         accounts: [`0x${PRIVATE_KEY}`]
      }
   },
}

Step 14: Compile our contract

To make sure everything is working so far, let’s compile our contract. The compile task is one of the built-in hardhat tasks.

From the command line run:

npx hardhat compile

You might get a warning about SPDX license identifier not provided in source file , but no need to worry about that — hopefully everything else looks good! If not, you can always message in the Alchemy discord.

Step 15: Write our deploy script

Now that our contract is written and our configuration file is good to go, it’s time to write our contract deploy script.

Navigate to the scripts/ folder and create a new file called deploy.js , adding the following contents to it:

async function main() {
   const MyNFT = await ethers.getContractFactory("MyNFT");
   
   // Start deployment, returning a promise that resolves to a contract object
   const myNFT = await MyNFT.deploy();
   console.log("Contract deployed to address:", myNFT.address);
}
main()
  .then(() => process.exit(0))
  .catch(error => {
    console.error(error);
    process.exit(1);
  });

Hardhat does an amazing job of explaining what each of these lines of code does in their Contracts tutorial, we’ve adopted their explanations here.

const MyNFT = await ethers.getContractFactory("MyNFT");

A ContractFactory in ethers.js is an abstraction used to deploy new smart contracts, so MyNFT here is a factory for instances of our NFT contract. When using the hardhat-ethers plugin ContractFactory and Contract instances are connected to the first signer by default.

const myNFT = await MyNFT.deploy();

Calling deploy() on a ContractFactory will start the deployment, and return a Promise that resolves to a Contract. This is the object that has a method for each of our smart contract functions.

Step 16: Deploy our contract

We’re finally ready to deploy our smart contract! Navigate back to the root of your project directory, and in the command line run:

npx hardhat run scripts/deploy.js --network ropsten

You should then see something like:

Contract deployed to address: 0x81c587EB0fE773404c42c1d2666b5f557C470eED

If we go to the Ropsten etherscan and search for our contract address we should able to see that it has been deployed successfully. The transaction will look something like this:

View your transaction address on Etherscan

The From address should match your Metamask account address and the To address will say “Contract Creation.” If we click into the transaction, we’ll see our contract address in the To field:

View your contract address on Etherscan

Yasssss! You just deployed your NFT smart contract to the Ethereum chain 🎉

To understand what’s going on under the hood, let’s navigate to the Explorer tab in our Alchemy dashboard . If you have multiple Alchemy apps make sure to filter by app and select “MyNFT”.

View calls made “under the hood” with Alchemy’s Explorer Dashboard

Here you’ll see a handful of JSON-RPC calls that Hardhat/Ethers made under the hood for us when we called the .deploy() function. Two important ones to call out here are eth_sendRawTransaction, which is the request to actually write our smart contract onto the Ropsten chain, and eth_getTransactionByHash which is a request to read information about our transaction given the hash (a typical pattern when sending transactions). To learn more about sending transactions, check out this tutorial on sending transactions using Web3.

That’s all for Part I of this tutorial. In Part II, we’ll actually interact with our smart contract by minting an NFT, and in Part III we’ll show you how to view your NFT in your Ethereum wallet!

Alchemy provides the leading blockchain development platform powering millions of users for 99% of countries worldwide and the biggest players in the NFT space, including OpenSea, Nifty Gateway, Makersplace, Dapper Labs, Zora, NFTfi, Super Rare, Foundation, Enjin, Origin Protocol, Immutable, and more. Our mission is to provide developers with the fundamental building blocks they need to create the future of technology, and lower the barrier to entry for developers to build blockchain applications. Alchemy currently powers 70% of the top Ethereum applications and over $15 billion in on-chain transactions, and have been featured on TechCrunch, Wired, Bloomberg and numerous other media outlets. The Alchemy team draws from decades of deep expertise in massively scalable infrastructure, AI, and blockchain from leadership roles at technology pioneers like Google, Microsoft, Facebook, Stanford, and MIT.

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