Due to Kevaundray Wedderburn, Alex Stokes, Tim Beiko, Mary Maller, Alexander Hicks, George Kadianakis, Dankrad Feist, and Justin Drake for suggestions and overview.
Ethereum goes all in on ZK. Ultimately we anticipate emigrate to utilizing ZK proofs in any respect ranges of the stack, from consensus layer signature aggregation to onchain privateness with shopper facet proving, and improve the protocol to be easier and extra zk-friendly. However step one can be an L1 zkEVM.
How we will ship an L1 zkEVM in lower than a yr
The quickest and most secure approach to ship an L1 zkEVM is to begin by giving validators the choice to run purchasers that, somewhat than re-executing execution payloads, statelessly confirm a number of (let’s say three) proofs generated by totally different zkVMs every proving totally different EVM implementations. As a result of proof verification is so quick and proof dimension so succinct, downloading and verifying a number of proofs could be very affordable and permits us to use the identical protection in depth as present shopper variety to zkVMs.
For this plan to initially confirm execution proofs offchain, all we want from the protocol is a few type of pipelining in Glamsterdam to permit for extra proving time.
Initially, we anticipate few validators to run ZK purchasers. Over time, their safety can be demonstrated in manufacturing. With the EF additionally placing sources into formal verification, specification writing, audits, and bug bounties; we anticipate adoption will slowly improve.
When a supermajority of stake is snug operating ZK purchasers, we will improve the gasoline restrict to a stage that may require validators operating affordable {hardware} to confirm proofs as an alternative of re-executing blocks. As soon as all validators are verifying execution proofs, the identical proofs may also be utilized by an EXECUTE precompile for native zk-rollups.
Defining realtime proving for the L1
Our best benefit in executing this plan is the power to harness all the zkVM trade in the direction of making Ethereum by far the most important ZK utility on the planet. Many zkVMs are already proving Ethereum blocks and efficiency breakthroughs are being introduced on a weekly foundation.
With the intention to preserve the safety, liveness, and censorship-resistance properties of the L1 the Ethereum Basis is proposing a standardized definition of realtime proving for zkVM groups to work in the direction of.
On the proof system facet, zkVMs concentrating on realtime proving ought to purpose for 128 bits of safety, which we contemplate the fitting long-term goal for Ethereum L1. Nonetheless, we’re keen to simply accept a minimal of 100 bits of safety within the preliminary months of deployment, to accommodate short-term engineering challenges in reaching 128 bits. Proof dimension ought to stay underneath 300KiB and should not depend on recursive wrappers that use trusted setups. We anticipate proof methods to maneuver to 128-bit safety by the point ZK purchasers are in manufacturing and to additional tighten safety necessities (e.g. relating to conjectures) as proving time decreases.
With the present slot time of 12 seconds and most time to propagate knowledge throughout the community of ~1.5 seconds, realtime means 10 seconds or much less. We anticipate zkVMs to have the ability to show a minimum of 99% of mainnet blocks on this window, with the tail finish (in addition to artificial DOS vectors) mitigated in future arduous forks.
With the intention to preserve the very best ranges of liveness and censorship resistance, our definition of realtime proving goals to allow “dwelling proving” with the concept that a number of the solo stakers who presently run validators from dwelling will opt-in to proving. Despite the fact that we anticipate to harden censorship resistance by enforced transaction inclusion earlier than verifying ZK proofs is made necessary, dwelling proving is a crucial ultimate safeguard.
Since proving within the cloud is already fairly low cost with multi-GPU spot situations, the main target for zkVM groups concentrating on realtime proving will largely be optimizing for operating provers on-prem the place the specs are way more constrained. On-prem realtime proving ought to require a most capital expenditure of 100k USD (at time of writing it requires ~$80k in stake to run a validator). We anticipate this to return down over time even because the gasoline restrict is elevated.
Greater than {hardware} price, essentially the most important constraint for dwelling proving utilizing GPUs is power utilization. Most residential houses have a minimum of 10kW coming into from the road and a few can have circuits meant for electrical home equipment or charging electrical automobiles with 10kW capability. Due to this fact, realtime proving should be potential on {hardware} operating at 10kW or much less.
This brings us to our working definition of realtime proving:
Latency: <= 10s for P99 of mainnet blocksOn-prem CAPEX: <= 100k USDOn-prem energy: <= 10kWCode: Absolutely open sourceSecurity: >= 128 bitsProof dimension: <= 300KiB with no trusted setups
The race to realtime
Between now and Devconnect Argentina, we hope to see zkVM groups proceed innovating in the direction of realtime dwelling proving, and for the main zkVMs to grow to be future core infrastructure for Ethereum.
