Exemplo n.º 1
0
    def test_tv(self):
        """ Test using test vectors """

        for vector in self.tv:
            r = bytes.fromhex(vector["R"])
            e = bytes.fromhex(vector["E"])
            x = bytes.fromhex(vector["X"])

            p_golden = bytes.fromhex(vector["P"])

            p = schnorr.prove(r, e, x)

            self.assertEqual(p, p_golden)
Exemplo n.º 2
0
def generate_key_material_zkp(rng, key_material, ID, AD=None):
    """ Generate ZK Proofs for key material

    Generate a commitment to the ECDSA PK, a Schnorr's
    Proof for the ECDSA PK and a factoring Proof for the
    Paillier PK
    The key material dictionary must have keys:
     * paillier_sk
     * paillier_pk
     * ecdsa_sk
     * ecdsa_pk

    Args::

        rng: pointer to CSPRNG
        key_material: dictionary with the key material

    Returns::

        r:  secret value for the ECDSA PK commitment
        c:  commitment for the ECDSA PK
        sc: commitment for the Schnorr's Proof
        sp: Schnorr's Proof
        fe: Factoring Proof. First component
        fy: Factoring Proof. Second component

    """
    # Commit to ECDSA PK
    r, c = commitments.nm_commit(rng, key_material['ecdsa_pk'])

    # Generate Schnorr's proof for ECDSA PK
    sr, sc = schnorr.commit(rng)
    e = schnorr.challenge(key_material['ecdsa_pk'], sc, ID, AD=AD)
    sp = schnorr.prove(sr, e, key_material['ecdsa_sk'])

    # Generate ZKP of knowledge of factorization for
    # Paillier key pair
    psk_p, psk_q = mpc.mpc_dump_paillier_sk(key_material['paillier_sk'])

    fe, fy = factoring_zk.prove(rng, psk_p, psk_q, ID, ad=AD)

    return r, c, sc, sp, fe, fy
Exemplo n.º 3
0
x_hex = "fab4ce512dff74bd9c71c89a14de5b877af45dca0329ee3fcb72611c0784fef3"
V_hex = "032cf4b348c9d00718f01ed98923e164df53b5e8bc4c2250662ed2df784e1784f4"

ID = b"unique_user_identifier"
AD_hex = "d7d3155616778fb436a1eb2070892205"

if __name__ == "__main__":
    r = bytes.fromhex(r_hex)
    x = bytes.fromhex(x_hex)
    V = bytes.fromhex(V_hex)
    AD = bytes.fromhex(AD_hex)

    # Generate quantities for benchmark
    r, C = schnorr.commit(None, r)
    e = schnorr.challenge(V, C, ID, AD=AD)
    p = schnorr.prove(r, e, x)

    # Check consistency of the generated quantities
    assert schnorr.verify(V, C, e, p) == schnorr.OK

    # Run benchmark
    fncall = lambda: schnorr.commit(None, r)
    time_func("commit   ", fncall, unit="us")

    fncall = lambda: schnorr.challenge(V, C, ID, AD=AD)
    time_func("challenge", fncall, unit="us")

    fncall = lambda: schnorr.prove(r, e, x)
    time_func("prove    ", fncall, unit="us")

    fncall = lambda: schnorr.verify(V, C, e, p)
Exemplo n.º 4
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    alpha2 = mpc.mpc_mta_client2(key_material2['paillier_sk'], cb)

    # Partial sums
    print("[Alice] Combine partial sum sigma1 for kw")
    sigma1 = mpc.mpc_sum_mta(k1, key_material1['ecdsa_sk'], alpha1, beta1)

    print("[Bob] Combine partial sum sigma2 for kw")
    sigma2 = mpc.mpc_sum_mta(k2, key_material2['ecdsa_sk'], alpha2, beta2)

    ## Decommitment and Proofs for R component

    # Generate Schnorr's Proofs
    print("[Alice] Generate Schnorr's Proof")
    GAMMA_schnorr_r1, GAMMA_schnorr_c1 = schnorr.commit(rng)
    GAMMA_schnorr_e1 = schnorr.challenge(GAMMA1, GAMMA_schnorr_c1, alice_id, AD = alice_ad)
    GAMMA_schnorr_p1 = schnorr.prove(GAMMA_schnorr_r1, GAMMA_schnorr_e1, gamma1)

    print("[Bob] Generate Schnorr's Proof")
    GAMMA_schnorr_r2, GAMMA_schnorr_c2 = schnorr.commit(rng)
    GAMMA_schnorr_e2 = schnorr.challenge(GAMMA2, GAMMA_schnorr_c2, bob_id, AD = bob_ad)
    GAMMA_schnorr_p2 = schnorr.prove(GAMMA_schnorr_r2, GAMMA_schnorr_e2, gamma2)

    print("[Alice] Transmit decommitment and Schnorr Proof for GAMMA1")
    print("[Bob] Transmit decommitment and Schnorr Proof for GAMMA2")

    # Decommit GAMMAi and verify Schnorr Proof
    rc = commitments.nm_decommit(GAMMA2, GAMMAR2, GAMMAC2)
    assert rc == commitments.OK, f'[Alice] Error decommitting GAMMA2. rc {rc}'

    GAMMA_schnorr_e2 = schnorr.challenge(GAMMA2, GAMMA_schnorr_c2, bob_id, AD=bob_ad)
    rc = schnorr.verify(GAMMA2, GAMMA_schnorr_c2, GAMMA_schnorr_e2, GAMMA_schnorr_p2)
Exemplo n.º 5
0
    # Generate commitment C = r.G, r random in [0, ..., q]
    r, C = schnorr.commit(rng)

    print("\n[Prover] Commitment C = r.G")
    print(f"\tr = {r.hex()}")
    print(f"\tC = {C.hex()}")

    # Generate deterministic challenge e = H(G, V, C, ID, AD)
    e = schnorr.challenge(V, C, ID, AD=AD)

    print("\n[Prover] Deterministic Challenge e = H(G, V, C, ID, AD)")
    print(f"\te = {e.hex()}")

    # Generate proof p = r - ex mod q
    p = schnorr.prove(r, e, x)

    print("\n[Prover] Generate proof p = r - ex")
    print(f"\tp = {p.hex()}")

    # Verifier regenerates deterministic challenge
    e = schnorr.challenge(V, C, ID, AD=AD)
    print("\n[Verifier] Deterministic Challenge e = H(G, V, C, ID, AD)")
    print(f"\te = {e.hex()}")

    # Verify
    rc = schnorr.verify(V, C, e, p)

    print("\n[Verifier] Verify proof p")
    if rc == schnorr.OK:
        print("\tSuccess")