I think it's really important that people start running their own Optimism nodes. I've created this repository to make that process as simple as possible. You should be relatively familiar with running commands on your machine. Let's do it!

simple-optimism-node now supports the Bedrock versions of both OP Mainnet, OP Goerli, and OP Sepolia. Please note that, for the moment, this repository only supports running a Bedrock node from the pre-migrated data directory supplied by OP Labs.

Previous versions of this repository used a torrenting system for downloading configuration files and data directories. I've decided to move to Cloudflare R2 temporarily since it provides better download speeds and is relatively inexpensive. I will likely move back to a torrenting model in the future but R2 allows people to get running with Bedrock more quickly.

• docker

• 16GB+ RAM
• 2TB SSD
• 10mb/s+ download

Instructions here should work for MacOS and most Linux distributions. I probably won't include instructions for Windows because I'm lazy.

If you're planning to run Docker as a root user, you can safely skip this step. However, if you're using Docker as a non-root user, you'll need to add yourself to the docker user group:

sudo usermod -a -G docker `whoami`

You'll need to log out and log in again for this change to take effect.

git clone https://github.com/smartcontracts/simple-optimism-node.git
cd simple-optimism-node

Make a copy of .env.example named .env.

cp .env.example .env

Open .env with your editor of choice and fill out the environment variables listed inside that file. You MUST fill in all variables in the REQUIRED (LEGACY) OR REQUIRED (BEDROCK) sections. If you wish to run both a legacy node and a Bedrock node at the same time, you MUST fill in BOTH sections.

You can also modify any of the optional environment variables if you'd wish, but the defaults should work perfectly well for most people. You can get L1/L2 RPC endpoints from these node providers or by running your own nodes.

The OP_NODE__RPC_TYPE environment variable tells the op-node component of the Bedrock node what sort of RPC it is connected to. When this variable is configured properly op-node can execute more efficiently by using special RPC endpoints that some RPC providers have and others may not. The available options for this variable are alchemy, quicknode, infura, parity, nethermind, debug_geth, erigon, basic, and any. The default is basic.

Standard queries like eth_getBlockByNumber will execute properly for blocks before the Bedrock upgrade but op-geth is not able to execute the legacy state transition function. This means that op-geth cannot natively serve requests like eth_call that require executing the legacy state transition.

The OP_GETH__HISTORICAL_RPC environment variable points op-geth to a node running the legacy version of OP Mainnet. op-geth will use this to serve certain historical queries that can't be fulfilled by op-geth itself. If this variable isn't defined, it defaults to attempting to use the legacy node spun up by this tool. If you are not running a legacy node alongside op-geth and you do not supply this environment variable, your op-geth will not be able to serve these sort of legacy requests.

Please note that this is an optional step but might be useful for anyone who was confused as I was about how to make Docker point at disk other than your primary disk. If you'd like your Docker data to live on a disk other than your primary disk, create a file /etc/docker/daemon.json with the following contents:

{
    "data-root": "/mnt/<disk>/docker_data"
}

Make sure to restart docker after you do this or the changes won't apply:

sudo systemctl daemon-reload
sudo systemctl restart docker

Confirm that the changes were properly applied:

docker info | grep -i "Docker Root Dir"

simple-optimism-node now supplies two docker compose profiles for the current system and the legacy system. If you want to run BOTH of the systems in tandem, run the commands below WITHOUT the --profile current flag.

docker compose --profile current up -d

Will start the node in a detatched shell (-d), meaning the node will continue to run in the background. You will need to run this again if you ever turn your machine off.

docker compose --profile current down

Will shut down the node without wiping any volumes. You can safely run this command and then restart the node again.

docker compose --profile current down -v

Will completely wipe the node by removing the volumes that were created for each container. Note that this is a destructive action, be very careful!

You may need to do this if the op-geth data directory becomes corrupted because of an unclean shutdown. Your op-geth data directory is likely corrupted if you see the following error log from the op-node:

stage 0 failed resetting: temp: failed to find the L2 Heads to start from: failed to fetch L2 block by hash 0x0000000000000000000000000000000000000000000000000000000000000000

docker compose logs <service name>

Will display the logs for a given service. You can also follow along with the logs for a service in real time by adding the flag -f.

The available services are:

• dtl, l2geth, op-node, and op-geth
• healthcheck
• fault-detector
• prometheus, grafana, and influxdb

docker compose pull
docker compose --profile current up -d --build

Will download the latest images for any services where you haven't hard-coded a service version. Updates are regularly pushed to improve the stability of Optimism nodes or to introduce new quality-of-life features like better logging and better metrics. I recommend that you run this command every once in a while (once a week should be more than enough). If you intend to maintain an Optimism node for a long time, it's also worth tracking the Monorepo's releases to keep an eye on important changes.

Currently, an Optimism node can either sync from L1 or from other L2 nodes. Syncing from L1 is generally the safest option but takes longer. A node that syncs from L1 will also lag behind the tip of the chain depending on how long it takes for the Optimism Sequencer to publish transactions to Ethereum. Syncing from L2 is faster but (currently) requires trusting the L2 node you're syncing from.

Many people are running nodes that sync from other L2 nodes, but I'd like to incentivize more people to run nodes that sync directly from L1. As a result, I've set this repository up to sync from L1 by default. I may later add the option to sync from L2 but I need to go do other things for a while.

When you run your Optimism node using these instructions, you will also be running two services that monitor the health of your node and the health of the network. The Healthcheck service will constantly compare the state computed by your node to the state of some other reference node. This is a great way to confirm that your node is syncing correctly.

The Fault Detector service will continuously scan the transaction results published by the Optimism Sequencer and cross-check them against the transaction results that your node generated locally. If there's ever a discrepancy between these two values, please complain very loudly! This either means that the Sequencer has published an invalid transaction result or there's a bug in your node software and an Optimism developer needs to know about it. In the future, this service will trigger Cannon, the fault proving mechanism that Optimism is building as part of its Bedrock upgrade.

The Fault Detector exposes several metrics that can be used to determine whether your node has detected a discrepancy including the is_currently_diverged gauge. The Fault Detector also exposes a simple API at localhost:$PORT__FAULT_DETECTOR_METRICS/api/status which returns { ok: boolean }. You can use this API to monitor the status of the Fault Detector from another application.

Grafana is exposed at http://localhost:3000 and comes with one pre-loaded dashboard ("Simple Node Dashboard"). Simple Node Dashboard includes basic node information and will tell you if your node ever falls out of sync with the reference L2 node or if a state root fault is detected.

Use the following login details to access the dashboard:

• Username: admin
• Password: optimism

Navigate over to Dashboards > Manage > Simple Node Dashboard to see the dashboard, see the following gif if you need help: