Espresso Sequencer

The Espresso Sequencer offers rollups credible neutrality and enhanced interoperability, without compromising on scale. Consisting of a data availability solution and a decentralized network of nodes that sequences transactions, layer-2 rollups can leverage the Espresso Sequencer to give developers and end users fast confirmations, low (and fair) fees, and robust infrastructure.

Documentation

Running the demo

Refer to sequencer-example-l2 for instructions on how to run a dockerized Espresso Sequencer network with an example Layer 2 rollup application.

Development

• Obtain code: git clone [email protected]:EspressoSystems/espresso-sequencer.
• Make sure nix is installed.
• Activate the environment with nix-shell, or nix develop, or direnv allow if using direnv.
• For installation without nix please see ubuntu.md.

Run the tests

just pull # to pull docker images
just test

Building figures

make doc

Building and running

Docker images and the docker-compose-demo.yaml file are provided for convenience. The Docker-based demo fetches the images from the ghcr repository, where they are updated with every push to main on GitHub. For testing uncommitted changes, you can also run the binaries by manually building and running the services.

Build all executables with cargo build --release. You may then start a sequencer network. First, start an orchestrator. Choose a port $PORT to run it on and decide how many sequencer nodes $N you will use, then run target/release/orchestrator -p $PORT -n $N.

The sequencer will distribute a HotShot configuration to all the nodes which connect to it, which specifies consensus parameters like view timers. There is a default config, but you can override any parameters you want by passing additional options to the orchestrator executable. Run target/release/orchestrator --help to see a list of available options.

Next, you must launch a cdn instance, which is necessary to facilitate consensus.

just dev-cdn -- -p 1738

In this case, we run it on port 1738.

Once you have started the orchestrator and the CDN, you must connect $N sequencer nodes to them, after which the network will start up automatically. To start one node, run

target/release/sequencer \
    --orchestrator-url http://localhost:$PORT \
    --cdn-endpoint "127.0.0.1:1738"  \
    -- http --port 8083 -- query --storage-path storage -- submit

A useful Bash snippet for running $N nodes simultaneously in the background of your shell is:

for i in `seq $N`; do
    target/release/sequencer \
        --orchestrator-url http://localhost:$PORT \
        --cdn-endpoint "127.0.0.1:1738"  \
done

For running a full demo natively run just demo-native.

Contracts

Development

A foundry project for the contracts specific to HotShot can be found in the directory contracts.

To compile

forge build

To run the tests

forge test

In order to avoid constant warnings about checksum mismatches with svm-rs managed solc we set FOUNDRY_SRC to solc installed via flake.nix.

• To use the contracts from rust generate the rust contracts bindings: just gen-bindings.
• Bindings are only generated for contracts in the contracts/src folder

To generate documentation in ./docs for solidity code run

forge doc

Deployment

To deploy the contracts to a local testnet, first run a dev chain (e.g. anvil), then run

forge script DeployHotShot --broadcast --rpc-url local

To deploy to sepolia set SEPOLIA_RPC_URL and MNEMONIC env vars and run

forge script DeployHotShot --broadcast --rpc-url sepolia

To additionally verify the contact on etherscan set the ETHERSCAN_API_KEY env var and run

forge script DeployHotShot --broadcast --rpc-url sepolia --verify

Running the script will save a file with details about the deployment in contracts/broadcast/$CHAIN_ID.

Folder Structure Rationale

• code for demo purposes goes into the contracts/demo folder
• code that eventually ends up in production goes into the contracts/src folder

Benchmarking and profiling

The gas consumption for updating the state of the light client contract can be seen by running:

> just lc-contract-benchmark
cargo build --bin diff-test --release
    Finished release [optimized] target(s) in 0.41s
forge test --mt testCorrectUpdateBench | grep testCorrectUpdateBench
[PASS] testCorrectUpdateBench() (gas: 597104)

In order to profile the gas consumption of the light client contract do the following:

1. Set the environment variables SEPOLIA_RPC_URL, MNEMONIC and ETHERSCAN_API_KEY.
2. just lc-contract-profiling-sepolia
3. Create an account on sentio.xyz.
4. Use the hash of the transaction generated in step two when calling the function newFinalizedState in order to obtain the gas profile.

Misc

Authenticate with GitHub container registry

This is only necessary to fetch private images.

• Go to your github profile
• Developer Settings > Personal access tokens > Personal access tokens (classic)
• Generate a new token
  • for the scope options of the token, tick the repo box.
• Run docker login ghcr.io --username <you_github_id> --password <your_personal_access_token>

License

Copyright

(c) 2022 Espresso Systems espresso-sequencer was developed by Espresso Systems. While we plan to adopt an open source license, we have not yet selected one. As such, all rights are reserved for the time being. Please reach out to us if you have thoughts on licensing.

Disclaimer

DISCLAIMER: This software is provided "as is" and its security has not been externally audited. Use at your own risk.

DISCLAIMER: The Rust library crates provided in this repository are intended primarily for use by the binary targets in this repository. We make no guarantees of public API stability. If you are building on these crates, reach out by opening an issue to discuss the APIs you need.