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test.py
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test.py
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import pickle
from TESTING_verifier_DO_NOT_OPEN import TestingVerificationKey
from compiler.program import Program
from curve import G1Point
from poly import Basis, Polynomial
from setup import Setup
from prover import Prover
from verifier import VerificationKey
import json
from test.mini_poseidon import rc, mds, poseidon_hash
from utils import *
def setup_test():
print("===setup_test===")
setup = Setup.from_file("test/powersOfTau28_hez_final_11.ptau")
dummy_values = Polynomial(
list(map(Scalar, [1, 2, 3, 4, 5, 6, 7, 8])), Basis.LAGRANGE
)
program = Program(["c <== a * b"], 8)
commitment = setup.commit(dummy_values)
assert commitment == G1Point(
(
16120260411117808045030798560855586501988622612038310041007562782458075125622,
3125847109934958347271782137825877642397632921923926105820408033549219695465,
)
)
vk = setup.verification_key(program.common_preprocessed_input())
assert (
vk.w
== 19540430494807482326159819597004422086093766032135589407132600596362845576832
)
print("Successfully created dummy commitment and verification key")
def basic_test():
print("===basic_test===")
# Extract 2^28 powers of tau
setup = Setup.from_file("test/powersOfTau28_hez_final_11.ptau")
print("Extracted setup")
program = Program(["c <== a * b"], 8)
vk = setup.verification_key(program.common_preprocessed_input())
print("Generated verification key")
their_output = json.load(open("test/main.plonk.vkey.json"))
for key in ("Qm", "Ql", "Qr", "Qo", "Qc", "S1", "S2", "S3", "X_2"):
if interpret_json_point(their_output[key]) != getattr(vk, key):
raise Exception(
"Mismatch {}: ours {} theirs {}".format(
key, getattr(vk, key), their_output[key]
)
)
assert getattr(vk, "w") == int(their_output["w"])
print("Basic test success")
return setup
# Equivalent to this zkrepl code:
#
# template Example () {
# signal input a;
# signal input b;
# signal c;
# c <== a * b + a;
# }
def ab_plus_a_test(setup):
print("===ab_plus_a_test===")
program = Program(["ab === a - c", "-ab === a * b"], 8)
vk = setup.verification_key(program.common_preprocessed_input())
print("Generated verification key")
their_output = json.load(open("test/main.plonk.vkey-58.json"))
for key in ("Qm", "Ql", "Qr", "Qo", "Qc", "S1", "S2", "S3", "X_2"):
if interpret_json_point(their_output[key]) != getattr(vk, key):
raise Exception(
"Mismatch {}: ours {} theirs {}".format(
key, getattr(vk, key), their_output[key]
)
)
assert getattr(vk, "w") == int(their_output["w"])
print("ab+a test success")
def one_public_input_test(setup):
print("===one_public_input_test===")
program = Program(["c public", "c === a * b"], 8)
vk = setup.verification_key(program.common_preprocessed_input())
print("Generated verification key")
their_output = json.load(open("test/main.plonk.vkey-59.json"))
for key in ("Qm", "Ql", "Qr", "Qo", "Qc", "S1", "S2", "S3", "X_2"):
if interpret_json_point(their_output[key]) != getattr(vk, key):
raise Exception(
"Mismatch {}: ours {} theirs {}".format(
key, getattr(vk, key), their_output[key]
)
)
assert getattr(vk, "w") == int(their_output["w"])
print("One public input test success")
def prover_test_dummy_verifier(setup):
print("===prover_test_dummy_verifier===")
print("Beginning prover test with test verifier")
program = Program(["e public", "c <== a * b", "e <== c * d"], 8)
assignments = {"a": 3, "b": 4, "c": 12, "d": 5, "e": 60}
prover = Prover(setup, program)
proof = prover.prove(assignments)
print("Beginning test verification")
program = Program(["e public", "c <== a * b", "e <== c * d"], 8)
public = [60]
vk = setup.verification_key(program.common_preprocessed_input())
vk_test = TestingVerificationKey(
group_order=vk.group_order,
Qm=vk.Qm,
Ql=vk.Ql,
Qr=vk.Qr,
Qo=vk.Qo,
Qc=vk.Qc,
S1=vk.S1,
S2=vk.S2,
S3=vk.S3,
X_2=vk.X_2,
w=vk.w,
)
assert vk_test.verify_proof_unoptimized(8, proof, public)
assert vk_test.verify_proof(8, proof, public)
print("Prover test with dummy verifier success")
def prover_test(setup):
print("===prover_test===")
print("Beginning prover test")
program = Program(["e public", "c <== a * b", "e <== c * d"], 8)
assignments = {"a": 3, "b": 4, "c": 12, "d": 5, "e": 60}
prover = Prover(setup, program)
proof = prover.prove(assignments)
print("Prover test success")
return proof
def verifier_test_unoptimized(setup, proof):
print("===verifier_test_unoptimized===")
print("Beginning verifier test")
program = Program(["e public", "c <== a * b", "e <== c * d"], 8)
public = [60]
vk = setup.verification_key(program.common_preprocessed_input())
assert vk.verify_proof_unoptimized(8, proof, public)
print("Verifier test success")
def verifier_test_full(setup, proof):
print("===verifier_test_full===")
print("Beginning verifier test")
program = Program(["e public", "c <== a * b", "e <== c * d"], 8)
public = [60]
vk = setup.verification_key(program.common_preprocessed_input())
assert vk.verify_proof_unoptimized(8, proof, public)
assert vk.verify_proof(8, proof, public)
print("Verifier test success")
def factorization_test(setup):
print("===factorization_test===")
print("Beginning test: prove you know small integers that multiply to 91")
program = Program.from_str(
"""n public
pb0 === pb0 * pb0
pb1 === pb1 * pb1
pb2 === pb2 * pb2
pb3 === pb3 * pb3
qb0 === qb0 * qb0
qb1 === qb1 * qb1
qb2 === qb2 * qb2
qb3 === qb3 * qb3
pb01 <== pb0 + 2 * pb1
pb012 <== pb01 + 4 * pb2
p <== pb012 + 8 * pb3
qb01 <== qb0 + 2 * qb1
qb012 <== qb01 + 4 * qb2
q <== qb012 + 8 * qb3
n <== p * q""",
16,
)
public = [91]
vk = setup.verification_key(program.common_preprocessed_input())
print("Generated verification key")
assignments = program.fill_variable_assignments(
{
"pb3": 1,
"pb2": 1,
"pb1": 0,
"pb0": 1,
"qb3": 0,
"qb2": 1,
"qb1": 1,
"qb0": 1,
}
)
prover = Prover(setup, program)
proof = prover.prove(assignments)
print("Generated proof")
assert vk.verify_proof(16, proof, public)
print("Factorization test success!")
def output_proof_lang() -> str:
o = []
o.append("L0 public")
o.append("M0 public")
o.append("M64 public")
o.append("R0 <== 0")
for i in range(64):
for j, pos in enumerate(("L", "M", "R")):
f = {"x": i, "r": rc[i][j], "p": pos}
if i < 4 or i >= 60 or pos == "L":
o.append("{p}adj{x} <== {p}{x} + {r}".format(**f))
o.append("{p}sq{x} <== {p}adj{x} * {p}adj{x}".format(**f))
o.append("{p}qd{x} <== {p}sq{x} * {p}sq{x}".format(**f))
o.append("{p}qn{x} <== {p}qd{x} * {p}adj{x}".format(**f))
else:
o.append("{p}qn{x} <== {p}{x} + {r}".format(**f))
for j, pos in enumerate(("L", "M", "R")):
f = {"x": i, "p": pos, "m": mds[j]}
o.append("{p}suma{x} <== Lqn{x} * {m}".format(**f))
f = {"x": i, "p": pos, "m": mds[j + 1]}
o.append("{p}sumb{x} <== {p}suma{x} + Mqn{x} * {m}".format(**f))
f = {"x": i, "xp1": i + 1, "p": pos, "m": mds[j + 2]}
o.append("{p}{xp1} <== {p}sumb{x} + Rqn{x} * {m}".format(**f))
return "\n".join(o)
def poseidon_test(setup):
print("===poseidon_test===")
# PLONK-prove the correctness of a Poseidon execution. Note that this is
# a very suboptimal way to do it: an optimized implementation would use
# a custom PLONK gate to do a round in a single gate
expected_value = poseidon_hash(1, 2)
# Generate code for proof
program = Program.from_str(output_proof_lang(), 1024)
print("Generated code for Poseidon test")
assignments = program.fill_variable_assignments({"L0": 1, "M0": 2})
vk = setup.verification_key(program.common_preprocessed_input())
print("Generated verification key")
prover = Prover(setup, program)
proof = prover.prove(assignments)
print("Generated proof")
assert vk.verify_proof(1024, proof, [1, 2, expected_value])
print("Verified proof!")
if __name__ == "__main__":
# Step 1: Pass setup test
setup_test()
setup = basic_test()
# Step 2: Pass prover test using verifier we provide (DO NOT READ TEST VERIFIER CODE)
prover_test_dummy_verifier(setup)
# Step 3: Pass verifier test using your own verifier
with open("test/proof.pickle", "rb") as f:
proof = pickle.load(f)
verifier_test_unoptimized(setup, proof)
verifier_test_full(setup, proof)
# Step 4: Pass end-to-end tests for prover and verifier
ab_plus_a_test(setup)
one_public_input_test(setup)
proof = prover_test(setup)
verifier_test_full(setup, proof)
factorization_test(setup)
poseidon_test(setup)