Immutable X Contracts

Address goerli 0x685576c3a592088eA9CA528b342D05087a64b6E7

Installation:

npm install @imtbl/imx-contracts

or

yarn add @imtbl/imx-contracts

Immutable Contract Addresses

Environment/Network	Core (StarkEx Bridge) Contract	User Registration Contract
Sandbox (Goerli)	0x7917edb51ecd6cdb3f9854c3cc593f33de10c623	0x1c97ada273c9a52253f463042f29117090cd7d83
Production (Mainnet)	0x5fdcca53617f4d2b9134b29090c87d01058e27e9	0x72a06bf2a1CE5e39cBA06c0CAb824960B587d64c

Setup

You will need an Ethereum wallet private key to deploy contracts. This can be your own private key or you can use the scripts/generateRandomKey.ts script to generate a new random Ethereum private key and address for use with this repo with the following command:

yarn generate-random-key

Also required are API keys for Alchemy and Etherscan to deploy contracts from this repo.

1. Make a copy of the .env.example file and rename the file to .env.
2. Add private keys and API keys to the .env file.

Note: All the environment variables in .env need a value or hardhat will throw an error.

L2 Minting

Immutable X is the only NFT scaling protocol that supports minting assets on L2, and having those assets be trustlessly withdrawable to Ethereum L1. To enable this, before you can mint on L2, you need to deploy an IMX-compatible ERC721 contract as the potential L1 home for these assets. Luckily, making an ERC721 contract IMX-compatible is easy!

No Code Usage (Test Environment Only)

In the test environment, deploying an ERC721 contract which is compatible with Immutable X is extremely easy. First, update the .env file, setting:

• CONTRACT_OWNER_ADDRESS
• CONTRACT_NAME
• CONTRACT_SYMBOL
• ETHERSCAN_API_KEY
  • which can be obtained from your Etherscan account.

Then, just run yarn hardhat run deploy/asset.ts --network sandbox.

Basic Usage

If you're starting from scratch, simply deploy a new instance of Asset.sol and you'll have an L2-mintable ERC721 contract. Set the _imx parameter in the contract constructor to either the Sandbox or Production addresses as above.

If you already have an ERC721 contract written, simply add Mintable.sol as an ancestor, implement the _mintFor function with your internal mint function, and set up the constructor as above:

import "@imtbl/imx-contracts/contracts/Mintable.sol";

contract YourContract is Mintable {

    constructor(address _imx) Mintable(_imx) {}

    function _mintFor(
        address to,
        uint256 id,
        bytes calldata blueprint
    ) internal override {
        // TODO: mint the token using your existing implementation
    }

}

Advanced Usage

To enable L2 minting, your contract must implement the IMintable.sol interface with a function which mints the corresponding L1 NFT. This function is mintFor(address to, uint256 quantity, bytes mintingBlob). Note that this is a different function signature to _mintFor in the previous example. The "blueprint" is the immutable metadata set by the minting application at the time of asset creation. This blueprint can store the IPFS hash of the asset, or some of the asset's properties, or anything a minting application deems valuable. You can use a custom implementation of the mintFor function to do whatever you like with the blueprint.

Your contract also needs to have an owner() function which returns an address. You must be able to sign a message with this address, which is used to link this contract your off-chain application (so you can authorise L2 mints). A simple way to do this is using the OpenZeppelin Ownable contract (npm install @openzeppelin/contracts).

import "@imtbl/imx-contracts/contracts/Mintable.sol";
import "@openzeppelin/contracts/access/Ownable.sol";

contract YourContract is IMintable, Ownable {

    function mintFor(
        address to,
        uint256 quantity,
        bytes calldata mintingBlob
    ) external override {
        // TODO: make sure only Immutable X can call this function
        // TODO: mint the token!
    }

}

Registration.sol & IMX.sol is for reference purposes if you choose to offer these functions in your own smart contracts and is not required if you only want to deploy an ERC721.

Manually verifying registration contract

First, deploy to sandbox as described in the L2 Minting section. Change to mainnet if required.

Verification with Etherscan should happen automatically within a few minutes of contract deployment, but if it fails you can run it manually, e.g.

yarn hardhat verify --network <network> <address> <args used in deployment>

Generating Typescript Types

Run yarn compile. The output can be found in the artifacts/typechain folder.