signature_ps

Crates.iosignature_ps
lib.rssignature_ps
version0.35.0
sourcesrc
created_at2021-04-27 23:50:26.062149
updated_at2022-05-09 17:52:20.837905
descriptionThe Ockam PS signature impementation.
homepagehttps://github.com/build-trust/ockam
repositoryhttps://github.com/build-trust/ockam/tree/develop/implementations/rust/ockam/signature_ps
max_upload_size
id390401
size70,517
Matthew Gregory (mattgreg)

documentation

README

signature_ps

crate docs license discuss

Ockam is a library for building devices that communicate securely, privately and trustfully with cloud services and other devices.

In order to support a variety of proving protocols, this crate implements the PS signature scheme which can be used to generate zero-knowledge proofs about signed attributes and the signatures themselves.

Usage

Add this to your Cargo.toml:

[dependencies]
signature_ps = "0.35.0"

Crate Features

[dependencies]
signature_ps = { version = "0.35.0" , default-features = false }

Please note that Cargo features are unioned across the entire dependency graph of a project. If any other crate you depend on has not opted out of signature_ps default features, Cargo will build signature_ps with the std feature enabled whether or not your direct dependency on signature_ps has default-features = false.

API

Generating Keys

The PS scheme allows the Signer and Holder to be two separate parties. This is often the case, particularly in the case of verifiable credentials.

To generate a new key pair for signing, call the Issuer::new_keys API. A Short Group Signature allows a set of messages to be signed with a single key. PS can sign any number of messages at the expense of a bigger public key. This implementation uses curve BLS12-381 and Blake2b-512 as a hash.

let (public_key, secret_key) = Issuer::new_keys(&mut rand::thread_rng())?;

Message Generators

Message Generators are per-message cryptographic information input into the BBS+ algorithm. They are derived from the public key, and the number of messages the key will be used to sign.

Signing

To sign messages, call the Issuer::sign API.

let (public_key, secret_key) = Issuer::new_keys(&mut rand::thread_rng())?;
let num_messages = 4;
let generators = MessageGenerators::from_public_key(public_key, num_messages);
let messages = [
    Message::hash(b"message 1"),
    Message::hash(b"message 2"),
    Message::hash(b"message 3"),
    Message::hash(b"message 4"),
];

let signature = Issuer::sign(&secret_key, &generators, &messages)?;

Blinding Signatures

To create blind signatures, we first need to establish a blind signature context. This is done with the Prover::new_blind_signature_context API. This function takes an optional slice of pre-committed messages. In this example, an empty slice is used, indicating no pre-committed messages. The generators, a random nonce, and the RNG are also used.

With the context and secret key, the blind signature is created by calling Issuer::blind_sign.

let nonce = Nonce::random(&mut rng);

let (context, blinding) =
    Prover::new_blind_signature_context(&mut [][..], &generators, nonce, &mut rng)?;
let mut messages = [
    (0, Message::hash(b"firstname")),
    (1, Message::hash(b"lastname")),
    (2, Message::hash(b"age")),
    (3, Message::hash(b"allowed")),
];

let blind_signature =
    Issuer::blind_sign(&context, &secret_key, &mut messages[..], nonce)?;

Unblinding Signatures

Unblinding the signature uses the blinding information provided by the blinding signature context. The function to_unblinded takes the blinding and returns a Signature.

let signature = blind_signature.to_unblinded(blinding);

Verification

Once the signature has been unblinded, it can be used to verify the messages, using the public key. This is done by calling the Signature::verify function. Calling Choice::unwrap_u8 on the result of verify returns 1 when verification succeeds.

let signature = blind_signature.to_unblinded(blinding);

let messages = [
    Message::hash(b"message 1"),
    Message::hash(b"message 2"),
    Message::hash(b"message 3"),
    Message::hash(b"message 4"),
];
let res = signature.verify(&public_key, &generators, messages.as_ref());
assert_eq!(res.unwrap_u8(), 1);

Full Example - Blinding, Unblinding, Verifying

use short_group_signatures_core::{error::Error, lib::*};
use signature_ps::{Issuer, MessageGenerators, Prover};

fn main() -> Result<(), Error> {
    let mut rng = rand::thread_rng();
    let (public_key, secret_key) = Issuer::new_keys(&mut rng)?;
    let num_messages = 4;
    let generators = MessageGenerators::from_secret_key(num_messages, &secret_key);
    let nonce = Nonce::random(&mut rng);

    let (context, blinding) =
        Prover::new_blind_signature_context(&mut [][..], &generators, nonce, &mut rng)?;
    let mut messages = [
        (0, Message::hash(b"firstname")),
        (1, Message::hash(b"lastname")),
        (2, Message::hash(b"age")),
        (3, Message::hash(b"allowed")),
    ];

    let blind_signature =
        Issuer::blind_sign(&context, &secret_key, &mut messages[..], nonce)?;

    let signature = blind_signature.to_unblinded(blinding);

    // Remove index
    let messages = [messages[0].1, messages[1].1, messages[2].1, messages[3].1];

    let res = signature.verify(&public_key, messages.as_ref());
    assert_eq!(res.unwrap_u8(), 1);
    Ok(())
}

License

This code is licensed under the terms of the Apache License 2.0.

Commit count: 0

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