Commitment schemes are a way for one counterparty to commit to a value such that the value committed remains private, but can be revealed at a later time when the committing party divulges a necessary parameter of the commitment process. Strong commitment schemes must be both information hiding and computationally binding.
The Pedersen commitment sheme allows a sender to create a commitment to a secret value. They may then later open the commitment and reveal the value in a verifiable manner that binds them to their commitment. A commitment shceme consists of a three stages:
Setup
Commit
Open
example :: IO Bool
example = do
-- Setup commitment parameters
(a, cp) <- setup 256
-- Commit to the message using paramaters: Com(msg, cp)
let msg = 0xCAFEBEEF
Pedersen c r <- commit msg cp
-- Open and verify commitment: Open(cp,c,r)
pure (open cp c r)
Pedersen commitment scheme has the following properties:
- Hiding: A dishonest party cannot discover the honest party's value.
- Binding: A dishonest party cannot open his or her commitment in more than one way
- Non-correlation: A dishonest party cannot commit to a value that is in some significant way correlated to the honest party's value.
Using Pedersen commitments we implement mutually independent commitments system, a secure multiparty communication protocol in which counterparties can commit to arbitrary messages or data in a binding way such that all counterparties can perform zero knowledge equality or non-equality checks of counterparts data, with the option to reveal the data at a later point; all with perfect information hiding of the underlying data or messages.
Pedersen commitments are also additionally homomorphic, such that for messages
m0
and m1
and blinding factors r0
and r1
we have:
Commit(m0; r0) * Commit(m1; r1) = Commit(m0 + m1; r0 + r1)
A more efficient implementation of the Pedersen Commitment scheme arises from Elliptic Curve Cryptography (ECC) which is based on the algebraic structure of elliptic curves over finite (prime) fields. Using ECC, the commitment scheme computations require fewer bits and as a result yields a much faster commitment phase.
Given a secure elliptic curve (e.g. secp256k1), a Pedersen commitment can be implemented using the same interface as usual but instead of prime field modular exponentiation, EC point multiplication and addition are used. The use of EC Pedersen commitments is almost exactly the same as the general prime field implementation:
example :: IO Bool
example = do
-- Setup commitment parameters
(a, cp) <- ecSetup Nothing -- SECP256k1 is used by default
-- Commit to the message using paramaters: Com(msg, cp)
let msg = 0xCAFEBEEF
ECPedersen c r <- ecCommit msg cp
-- Open and verify commitment: Open(cp,c,r)
pure (ecOpen cp c r)
Additionally, the EC Pedersen Commitment implementation is also additively homomorphic in two ways:
Commit(x, r1) + Commit(y, r2) = Commit(x + y, r1 + r2)
and given a scalar n
:
Commit(x,r) + n = Commit(x + n,r)
References:
- Pedersen, Torben Pryds. "Non-interactive and information-theoretic secure verifiable secret sharing." Annual International Cryptology Conference. Springer Berlin Heidelberg, 1991. APA
- Liskov, Moses, et al. "Mutually independent commitments." International Conference on the Theory and Application of Cryptology and Information Security. Springer Berlin Heidelberg, 2001. APA
- Blum, Manuel, and Silvio Micali. "How to generate cryptographically strong sequences of pseudorandom bits." SIAM journal on Computing 13.4 (1984): 850-864.
$ stack build
$ stack repl
> :load example/Example.hs
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