OP Stack
Rollup Overview

Rollup Protocol Overview

The big idea that makes Optimism possible is the Optimistic Rollup. We'll go through a brief explainer of how Optimistic Rollups work at a high level. Then we'll explain why Optimism is built as an Optimistic Rollup and why we believe it's the best option for a system that addresses all of our design goals. Check out the protocol specs (opens in a new tab), if you want to more detail about the rollup protocol.

Optimistic Rollups TL;DR

Optimism is an "Optimistic Rollup," which is basically just a fancy way of describing a blockchain that piggy-backs off of the security of another "parent" blockchain. Specifically, Optimistic Rollups leverage the consensus mechanism (like PoW or PoS) of their parent chain instead of providing their own. In OP Mainnet's case, this parent blockchain is Ethereum.

Ethereum and Optimism Forever Doodle.

Block Storage

In Bedrock, L2 blocks are saved to the Ethereum blockchain using a non-contract address (0xff00..0010 on Ethereum (opens in a new tab)) to minimize the L1 gas expense. As these blocks are submitted as transactions using EIP-4844 blobs, there is no way to modify or censor them after the "transaction" is included in a block that has enough attestations. This is the way that OP Mainnet inherits the availability and integrity guarantees of Ethereum.

Blocks are written to L1 in a compressed format (opens in a new tab) to reduce costs. This is important because writing to L1 is the major cost of OP Mainnet transactions.

Block Production

Optimism block production is primarily managed by a single party, called the "sequencer," which helps the network by providing the following services:

  • Providing transaction confirmations and state updates.
  • Constructing and executing L2 blocks.
  • Submitting user transactions to L1.

In Bedrock, the sequencer does have a mempool, similar to L1 Ethereum, but the mempool is private to avoid opening opportunities for MEV. In OP Mainnet, blocks are produced every two seconds, regardless of whether they are empty (no transactions), filled up to the block gas limit with transactions, or anything in between.

Transactions get to the sequencer in two ways:

  1. Transactions submitted directly to the sequencer. These transactions are a lot cheaper to submit, as they do not require the expense of a separate L1 transaction. However, they cannot be made censorship resistant since the sequencer is the only participant that knows about them.

  2. Transactions submitted on L1 (called deposits) are included in the chain in the appropriate L2 block. Every L2 block is identified by the "epoch" (the L1 block to which it corresponds, which typically has happened a few minutes before the L2 block) and its serial number within that epoch. The first block of the epoch includes all the deposits that happened in the L1 block to which it corresponds. If the sequencer attempts to ignore a legitimate L1 transaction, it ends up with a state that is inconsistent with the verifiers, same as if the sequencer tried to fake the state by other means. This provides OP Mainnet with L1 Ethereum level censorship resistance. You can read more about this mechanism in the protocol specifications (opens in a new tab).

For the moment, The Optimism Foundation (opens in a new tab) runs the only block producer on OP Mainnet. Refer to Protocol specs section for more information about how we plan to decentralize the Sequencer role in the future.

Block Execution

The execution engine (implemented as the op-geth component) receive blocks using two mechanisms:

  1. The execution engine can update itself using peer to peer network with other execution engines. This operates the same way that the L1 execution clients synchronize the state across the network. You can read more about it in the specs (opens in a new tab).

  2. The rollup node (implemented as the op-node component) derives the L2 blocks from L1. This mechanism is slower, but censorship resistant. You can read more about it in the specs (opens in a new tab).

Bridging ETH or Tokens Between Layers

Optimism is designed so that users can send arbitrary messages between smart contracts on L2 (OP Mainnet, OP Sepolia, etc.) and the underlying L1 (Ethereum mainnet, Sepolia, etc.). This makes it possible to transfer ETH or tokens, including ERC20 tokens, between the two networks. The exact mechanism by which this communication occurs differs depending on the direction in which messages are being sent.

OP Mainnet uses this functionality in the Standard bridge to allow users to deposit tokens from Ethereum to OP Mainnet and also allow withdrawals of the same tokens from OP Mainnet back to Ethereum. See the developer documentation and examples for details on the inner workings of the Standard bridge.

Moving from Ethereum to OP Mainnet

In Optimism terminology, transactions going from Ethereum (L1) to OP Mainnet (L2) are called deposits.

You use L1CrossDomainMessenger (opens in a new tab) or L1StandardBridge (opens in a new tab). Deposit transactions become part of the canonical blockchain in the first L2 block of the "epoch" corresponding to the L1 block where the deposits were made. This L2 block will usually be created a few minutes after the corresponding L1 block. You can read more about this in the specs (opens in a new tab).

Moving from OP Mainnet to Ethereum

Withdrawals (the term is used for any OP Mainnet to Ethereum message) have three stages:

  1. You initialize withdrawals with an L2 transaction.

  2. Wait for the next output root to be submitted to L1 (you can see this on the SDK (opens in a new tab)) and then submit the withdrawal proof using proveWithdrawalTransaction. This new step enables offchain monitoring of the withdrawals, which makes it easier to identify incorrect withdrawals or output roots. This protects OP Mainnet users against a whole class of potential bridge vulnerabilities.

  3. After the fault challenge period ends (a week on mainnet, less than that on the test network), finalize the withdrawal.

You can read the full withdrawal specifications here (opens in a new tab)

Fault Proofs

In an Optimistic Rollup, state commitments are published to L1 (Ethereum in the case of OP Mainnet) without any direct proof of the validity of these commitments. Instead, these commitments are considered pending for a period of time (called the "challenge window"). If a proposed state commitment goes unchallenged for the duration of the challenge window (currently set to 7 days), then it is considered final. Once a commitment is considered final, smart contracts on Ethereum can safely accept withdrawal proofs about the state of OP Mainnet based on that commitment.

When a state commitment is challenged, it can be invalidated through a "fault proof" (formerly known as a "fraud proof" (opens in a new tab)) process. If the commitment is successfully challenged, then it is removed from the StateCommitmentChain to eventually be replaced by another proposed commitment. It's important to note that a successful challenge does not roll back OP Mainnet itself, only the published commitments about the state of the chain. The ordering of transactions and the state of OP Mainnet is unchanged by a fault proof challenge.

The fault proof process is currently undergoing major redevelopment as a side-effect of the November 11th, 2021 EVM Equivalence (opens in a new tab) update.

Next Steps