Non-interactive zero-knowledge proof

Non-interactive zero-knowledge proofs (NIZKs) are zero-knowledge proofs that require no interaction between the prover and verifier. Blum, Feldman, and Micali[1] showed that a common reference string shared between the prover and the verifier is enough to achieve computational zero-knowledge without requiring interaction. Goldreich and Oren[2] gave impossibility results for one shot zero-knowledge protocols in the standard model. In 2003, Shafi Goldwasser and Yael Tauman Kalai published an instance of an identification scheme for which any hash function will yield an insecure digital signature scheme.[3] These results are not contradictory, as the impossibility result of Goldreich and Oren does not hold in the common reference string model or the random oracle model. Non-interactive zero-knowledge proofs however show a separation between the cryptographic tasks that can be achieved in the standard model and those that can be achieved in 'more powerful' extended models.

The model influences the properties that can be obtained from a zero-knowledge protocol. Pass[4] showed that in the common reference string model non-interactive zero-knowledge protocols do not preserve all of the properties of interactive zero-knowledge protocols; e.g., they do not preserve deniability.

Non-interactive zero-knowledge proofs can also be obtained in the random oracle model using the Fiat–Shamir heuristic. The article[5] introduced the acronym zk-SNARK for zero-knowledge succinct non-interactive argument of knowledge that are the backbone of the Zcash protocol.[6]

In 2017, Bulletproofs was released, which enable proving that a committed value is in a range using a logarithmic (in the bit length of the range) number of field and group elements.[7]

In 2018, the zk-STARK protocol was introduced, offering transparency (no trusted setup), quasi-linear proving time, and poly-logarithmic verification time.[8]

Definition

Originally,[1] non-interactive zero-knowledge was only defined as a single theorem proof system. In such a system each proof requires its own fresh common reference string. A common reference string in general is not a random string. It may, for instance, consist of randomly chosen group elements that all protocol parties use. Although the group elements are random, the reference string is not as it contains a certain structure (e.g., group elements) that is distinguishable from randomness. Subsequently, Feige, Lapidot, and Shamir[9] introduced multi-theorem zero-knowledge proofs as a more versatile notion for non-interactive zero knowledge proofs.

In this model the prover and the verifier are in possession of a reference string sampled from a distribution, D, by a trusted setup . To prove statement with witness w, the prover runs and sends the proof, , to the verifier. The verifier accepts if , and rejects otherwise. To account for the fact that may influence the statements that are being proven, the witness relation can be generalized to parameterized by .

Completeness

Verification succeeds for all and every .

More formally, for all k, all , and all :

Soundness

Soundness requires that no prover can make the verifier accept a wrong statement except with some small probability. The upper bound of this probability is referred to as the soundness error of a proof system.

More formally, for every malicious prover, , there exists a negligible function, , such that

The above definition requires the soundness error to be negligible in the security parameter, k. By increasing k the soundness error can be made arbitrary small. If the soundness error is 0 for all k, we speak of perfect soundness.

Multi-theorem zero-knowledge

A non-interactive proof system is multi-theorem zero-knowledge, if there exists a simulator, , such that for all non-uniform polynomial time adversaries, ,

Here outputs for and both oracles output failure otherwise.

Pairing-based non-interactive proofs

Pairing-based cryptography has led to several cryptographic advancements. One of these advancements is more powerful and more efficient non-interactive zero-knowledge proofs. The seminal idea was to hide the values for the evaluation of the pairing in a commitment. Using different commitment schemes, this idea was used to build zero-knowledge proof systems under the sub-group hiding[10] and under the decisional linear assumption.[11] These proof systems prove circuit satisfiability, and thus by the Cook–Levin theorem allow proving membership for every language in NP. The size of the common reference string and the proofs is relatively small; however, transforming a statement into a boolean circuit incurs considerable overhead.

Proof systems under the sub-group hiding, decisional linear assumption, and external Diffie–Hellman assumption that allow directly proving the pairing product equations that are common in pairing-based cryptography have been proposed.[12]

Under strong knowledge assumptions, it is known how to create sublinear-length computationally sound proof systems for NP-complete languages. More precisely, the proof in such proof systems consists only of a small number of bilinear group elements.[13][14]

gollark: 80 MILLION?!
gollark: They run off RF instead of coal, they can dig stuff selectively at long range, they're faster...
gollark: Digital miners are, in my opinion, way more powerful autominers.
gollark: Also, did you try comparing a turtle quarry to a digital miner or something?
gollark: What did you want them for?

References

  1. Manuel Blum, Paul Feldman, and Silvio Micali. Non-Interactive Zero-Knowledge and Its Applications. Proceedings of the twentieth annual ACM symposium on Theory of computing (STOC 1988). 103–112. 1988
  2. Oded Goldreich and Yair Oren. Definitions and Properties of Zero-Knowledge Proof Systems. Journal of Cryptology. Vol 7(1). 1–32. 1994 (PS)
  3. Shafi Goldwasser and Yael Kalai. On the (In)security of the Fiat–Shamir Paradigm. Proceedings of the 44th Annual IEEE Symposium on Foundations of Computer Science (FOCS'03). 2003
  4. Rafael Pass. On Deniability in the Common Reference String and Random Oracle Model. Advances in Cryptology – CRYPTO 2003. 316–337. 2003 (PS)
  5. Bitansky, Nir; Canetti, Ran; Chiesa, Alessandro (2012). "From extractable collision resistance to succinct non-interactive arguments of knowledge, and back again". ACM.
  6. Ben-Sasson, Eli; Chiesa, Alessandro; Garman, Christina; Green, Matthew; Miers, Ian; Tromer, Eran; Virza, Madars (18 May 2014). "Zerocash: Decentralized Anonymous Payments from Bitcoin" (PDF). IEEE. Retrieved 26 January 2016.
  7. http://web.stanford.edu/~buenz/pubs/bulletproofs.pdf
  8. https://eprint.iacr.org/2018/046.pdf
  9. Uriel Feige, Dror Lapidot, Adi Shamir: Multiple Non-Interactive Zero Knowledge Proofs Under General Assumptions. SIAM J. Comput. 29(1): 1–28 (1999)
  10. Jens Groth, Rafail Ostrovsky, Amit Sahai: Perfect Non-interactive Zero Knowledge for NP. EUROCRYPT 2006: 339–358
  11. Jens Groth, Rafail Ostrovsky, Amit Sahai: Non-interactive Zaps and New Techniques for NIZK. CRYPTO 2006: 97–111
  12. Jens Groth, Amit Sahai: Efficient Non-interactive Proof Systems for Bilinear Groups. EUROCRYPT 2008: 415–432
  13. Jens Groth. Short Pairing-Based Non-interactive Zero-Knowledge Arguments. ASIACRYPT 2010: 321–340
  14. Helger Lipmaa. Progression-Free Sets and Sublinear Pairing-Based Non-Interactive Zero-Knowledge Arguments. TCC 2012: 169–189
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