Rigs

Tableland Rigs tooling and contract.

Repo Layout

This repo contains various components of the Rigs tooling and smart contracts. Some important landmarks are:

• artifacts/ - Various artifacts used as input to the Rigs building process as well as the resulting SQLite data
• cmd/ - A Go CLI implementation for building and publishing Rigs data and imagery
• pkg/ - Backing Go packages used by the CLI implementation
• viewer/ - A Nuxt.js app used by the CLI for viewing built Rigs data locally
• ethereum/ - The Rigs smart contract

Artifacts

The artifacts/ folder contains some build input and output that could be useful for those interested in inspecting or extending Rigs.

• layers/ - The raw layer folders and images of Rig parts that all Rigs data and imagery was built from
• local.db - SQLite database of built Rigs data that was used to publish the official Rigs NFT collection to Tableland using the CLI
• tableland.db - SQLite representation of the official Rigs NFT collection stored on Tableland

The Rigs CLI

Build and Install

The Rigs CLI executable can be built by running make build-rigs or go build ./cmd/rigs/. The resulting executable will end up in the root of the repo working directory. If you want to install it into your $PATH using a properly configured Go installation, use go install ./cmd/rigs.

Running the CLI

The CLI was used to build and publish the Rigs NFT collection. The CLI is used generally in two different modes, "local" and "publish". The idea is to build Rigs data and imagery locally, perform any inspection and QA on the results, and then publish the resulting data and imagery to Tableland and IPFS.

CLI commands have reasonable defaults for most parameters, but you can customize many settings by using command flags or environment variables. For example, a flag name of --my-flag could be set using the environment variable RIGS_MY_FLAG (all environment variables must be prefixed with RIGS_).

See documentation for any command by calling the command with the --help flag.

Local Mode

To build a Rigs dataset from scratch, the first step is to build the Rigs "inventory". This is the raw data derived from artifacts/layers, stored by default in local.db, that serves as the building blocks for Rigs data and imagery.

> rigs local inventory

This will create local.db and populate the parts and layers tables with data.

The next step is to build some actual Rigs data:

> rigs local build 200 --no-originals

This builds 200 random Rigs, reading from the parts and layers tables, and storing the resulting data in the rigs and rig_parts tables of local.db. Providing the --no-orginials flag means none of the original Rigs (Rigs with all parts from the same original and of matching color) will be built.

You can view some basic statistics about the built Rigs data using the stats command.

> rigs local stats

...

Fleet Distribution:
        Foils           3       1.5% (2.8%) 
        Hoppers         15      7.5% (8.3%) 
        Edge Riders     18      9.0% (13.9%) 
        Tracers         20      10.0% (11.1%) 
        Airelights      25      12.5% (5.6%) ***
        Sleds           33      16.5% (16.7%) 
        Titans          41      20.5% (22.2%) 
        Tumblers        45      22.5% (19.4%)

...

Now that our Rigs data is built, we can render the corresponding images for all the Rigs.

> rigs local render

The resulting images will be written to a folder called ./renders. Each subfolder name corresponds to a Rig ID and inside each Rig ID folder are the six images created for the Rig.

> ls ./renders/1/
image_full.png        image_full_alpha.png        image_medium.png        image_medium_alpha.png        image_thumb.png        image_thumb_alpha.png

You can launch a simple local web app to view the results.

> rigs local view

Publish Mode

Now that we've built our Rigs data and imagery locally, we're ready to publish the imagery to IPFS (via NFT.storage) and data to Tableland.

Note Pushing the Rig images to NFT.storage requires a local IPFS node to be running. The easiest way to do that is using IPFS Desktop. The default settings for the CLI will use the locally running IPFS node's default settings, but you can always customize the connection information using the --ipfs-api-url flag.

We'll first push the Rigs images to NFT.storage.

> rigs publish renders
2022/08/24 20:50:00 Adding folder to IPFS...

...

Images published with CID bafybeiffjkwh6jndds6mvkflhxgkpod3fvc7esaueabn5j6jva5wnw5zhm

Note Pushing imagery to NFT.storage requires you pass a NFT.storate API key using the --nft-storage-key flag. In this example, it has be set using the RIGS_NFT_STORAGE_KEY environment variable.

The resulting CID is tracked in local.db's cids table and used in an upcoming step to write the Rigs data to Tableland. Before we can do that, we must first create the tables that will hold our Rigs data on Tableland.

> rigs publish schema --attrs --lookups --to-tableland
created table rig_attributes_80001_1218
created table lookups_80001_1219

The --attrs and --lookups flags specify that we want to create the tables to hold the Rigs attributes and lookup information about the imagery we've stored on NFT.storage(IPFS). The names of the resulting tables are tracked in local.db's table called table_names. By default, the tables are created on Polygon Mumbai, but you can choose a different chain with the --chain flag.

Note All mutating interactions with Tableland (creating and writing to tables) must provide a private key hex string using the --private-key flag as well as an EVM backend provider API key using the --infura or --alchemy flags. In these examples, you can assume the flags were set using the corresponding environment variables RIGS_PRIVATE_KEY and RIGS_INFURA or RIGS_ALCHEMY.

Now we can write our Rigs data to those Tableland tables. The following command transforms our built Rigs data stored in local.db into the appropriate SQL statements to populate the Tableland tables, and then executes those SQL statements using Tableland's Go client.

> rigs publish data --attrs --lookups --to-tableland
processed job 1. rig attrs offset 0
processed job 2. rig attrs offset 70
processed job 3. rig attrs offset 140
processed job 4. lookups
done

Note The above commands to create and write to the Rigs tables include the --to-tableland flag. This flag directs the CLI to interact with the actual Tableland network, and if omitted, the CLI will instead execute the same SQL statements against a local SQLite database file called tableland.db. This is useful to perform a dry run of publishing the Rigs data and allows inspection of the local SQLite database.

Now that all of our imagery is stored on IPFS and Rigs data written to Tableland, we can integrate it into the Rigs smart contract.

The Rigs Smart Contract

The Rigs smart contract breaks new ground by utilizing Tableland for NFT metadata and mint allowlists.

TablelandRigs.sol is the main contract. The following is a high-level overview of the contract features. See ITablelandRigs.sol for a detailed overview.

Overview

Rigs inherits from ERC721A. Rigs is an important component of the Tableland protocol. To ensure the contract is able to evolve as Tableland matures, we chose to use the upgradable version of ERC721A. Once Rigs role in Tableland is stable, upgradability will be permanently removed.

Configuration

Configuration is managed from the Hardhat config file and deployments.ts. These files include information needed for contract-level metadata, the ERC2981 NFT Royalty Standard, royalty receivers for a payment splitter, max supply, mint price, mint revenue receiver, mint phase, allowlist files, and Tableland tables used for Rig parts, layers, attributes and lookups that were covered in the Rigs CLI section above.

The scripts folder contains a number of helpful scripts covered below. The input to these scripts comes from the Hardhat config file and deployments.ts.

Deploying

Deployments are handled on a per-network basis:

npx hardhat run scripts/deploy.ts --network ethereum

Refer to the deployments.ts for the list of current deployments.

The deploy.ts script takes care of the following:

1. Loads the owner account from environment variables. See .env.example for details.
2. Checks to ensure that a deployment doesn't already exist for the target network.
3. Generates the URI template components. See the getURITemplate method from helpers/uris.ts for more details.
4. Generated the contract metadata URI. See the getContractURI method from helpers/uris.ts for more details.
5. Deploys an OpenZeppelin PaymentSplitter.sol with the share holders specified in the Hardhat config file. The address of this contract is used with ERC2981 NFT Royalty Standard and in the contract-level metadata to ensure maximum marketplace compatibility.
6. Creates a Tableland table to store contract-level metadata and writes values specified in the Hardhat config file and from prior steps.
7. Builds the allowlist and waitlist merkle trees and checks that the allowlist size doesn't exceed the max supply and that the waitlist is the expected size (as specified in Hardhat config file).
8. Creates a Tableland table for the allowlist and waitlist and writes a row for each unique address with columns corresponding to allocations from each list.
9. Deploys an instance of TablelandRigs.sol with values from prior steps.
10. Lastly, prompts the deployer to save outputs in deployments.ts so that can be used in the bundled JS client and with other commands.

You can verify the deployed contracts by running the verify.ts script. You'll need to have Etherscan credentials for the target network (see .env.example).

Upgrades are handled by the upgrade.ts script.

Mint Phases

Rigs includes a four-phase mint process controlled by the contract owner via setMintPhase. The current mint phase is specified in the Hardhat config file. The contract owner can run the setMintPhase.ts script, which simply reads the current phase and calls the contract. This makes managing the phases of a mint very easy.

The four mint phases:

• CLOSED: This is the default phase after the contract is deployed. Minting is not allowed.
• ALLOWLIST: During this phase, addresses that are part of the allowlist (as generated during deployment from CSV files), are allowed to mint their allocation.
• WAITLIST: During this phase, addresses that are part of the waitlist (as generated during deployment from CSV files), are allowed to mint their allocation.
• PUBLIC: Anyone can mint during this phase, so long as the number of tokens doesn't exceed the max supply as specified during deployment.

If an address has allocations on the allowist and the waitlist and they minted during the ALLOWLIST phase, they will not be allowed to mint durnig the WAITLIST phase.

During contract deployment, a merkle tree is created for both the allowlist and the waitlist by reading any number of CSV files specified in the Hardhat config file. The format of these CSV files must be address,free_allowance,paid_allowance. The free_allowance column indicates their allocation of free mints, while the paid_allowance indicated their allocation of normal (paid) mints. The roots of these merkle trees are stored in the contract and used to verify client-generated proofs that must be supplied with calls to mint (unless the mint phase is PUBLIC). While not needed on their own, the scripts allowist.ts and proof.ts can be used to generate allowlist merkle trees and generate proofs. This can be helpful if you ever need to manually generate a merkle proof for minting.

See the tests to get a deeper view into the allowlist handling logic.

Tableland NFT Metadata

NFT metadata can be queried from Tableland by calling Tableland's /query endpoint with the appropriate SQL query string. For Rigs, this query is defined in ethereum/helpers/uris.ts. This query string is used by the contract function tokenURI(uint256 tokenId) to return the Tableland /query URL for the specified token ID. An example of this URL for Rig 2856 can be seen here.

That metadata URL is unique in that it requires the token ID be inserted into the middle of the URL string, something not typically supported by ERC721 implementations. Additionally, during the Rigs minting process, we chose to make visible the minted Rigs images and top-level metadata, while hiding the more detailed attribute metadata until after the mint period ended. This required being able to change the URI returned from tokenURI(uint256 tokenId) from the SQL query that hides attribute data to the one that returns it.

Both of these challenges were solved by a custom onlyOwner contract function we added called setURITemplate(string[] memory uriTemplate). This allows the caller to provide the two parts of the URL string (the "template") to be wrapped around the token ID, the resulting URL string being returned from tokenURI(uint256 tokenId). Since this function can be called repeatedly, we were able to update the URL template from the version that hides metadata attributes to the one that returns them. As mentioned above, there's a script called setURITemplate.ts that builds the URI template query from Tableland tables specified in the Hardhat config file.

Development

Building the client

You can build the contracts and Typescript client locally:

npm install
npm run build

Install the client

The Rigs client is used in the Garage.

npm install @tableland/rigs

Testing

Run the test suite:

npm test

Test with gas reporting:

REPORT_GAS=true npx hardhat test

Extacting the ABI and Bytecode

You can you grab the assets you need by compiling and then using some jq magic:

ABI

cat artifacts/contracts/TablelandRigs.sol/TablelandRigs.json | jq '.abi' > abi.json

Bytecode

cat artifacts/contracts/TablelandRigs.sol/TablelandRigs.json | jq -r '.bytecode' > bytecode.bin

Generate the Go client

You can use the above abi.json to build the Go client:

mkdir gobuild
abigen --abi ./abi.json --bin ./bytecode.bin --pkg contracts --out gobuild/TablelandRigs.go

License

The Unlicense