Nova is a high-speed recursive SNARK (a SNARK is type cryptographic proof system that enables a prover to prove a mathematical statement to a verifier with a short proof and succinct verification, and a recursive SNARK enables producing proofs that prove statements about prior proofs).
More precisely, Nova achieves incrementally verifiable computation (IVC), a powerful cryptographic primitive that allows a prover to produce a proof of correct execution of a "long running" sequential computations in an incremental fashion. For example, IVC enables the following: The prover takes as input a proof
A distinctive aspect of Nova is that it is the simplest recursive proof system in the literature, yet it provides the fastest prover. Furthermore, it achieves the smallest verifier circuit (a key metric to minimize in this context): the circuit is constant-sized and its size is about 10,000 multiplication gates. Nova is constructed from a simple primitive called a folding scheme, a cryptographic primitive that reduces the task of checking two NP statements into the task of checking a single NP statement.
This repository provides nova-snark,
a Rust library implementation of Nova on a cycle of elliptic curves. The code currently supports Pallas/Vesta (i.e., Pasta curves) and BN254/Grumpkin elliptic curve cycles. One can use Nova with other elliptic curve cycles (e.g., secp/secq) by providing an implementation of Nova's traits for those curves (e.g., see src/provider/mod.rs
).
We also implement a SNARK, based on Spartan, to compress IVC proofs produced by Nova.
To run tests (we recommend the release mode to drastically shorten run times):
cargo test --release
To run example:
cargo run --release --example minroot
The following paper, which appeared at CRYPTO 2022, provides details of the Nova proof system and a proof of security:
Nova: Recursive Zero-Knowledge Arguments from Folding Schemes
Abhiram Kothapalli, Srinath Setty, and Ioanna Tzialla
CRYPTO 2022
For efficiency, our implementation of the Nova proof system is instantiated over a cycle of elliptic curves. The following paper specifies that instantiation and provides a proof of security:
Revisiting the Nova Proof System on a Cycle of Curves
Wilson Nguyen, Dan Boneh, and Srinath Setty
IACR ePrint 2023/969
See the contributors list here
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To run early experimental work on CCS and HyperNova, use the hypernova
feature flag:
cargo test --features hypernova ccs
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