constantine/sage/testgen_bn254_snarks.sage

# Constantine
# Copyright (c) 2018-2019    Status Research & Development GmbH
# Copyright (c) 2020-Present Mamy André-Ratsimbazafy
# Licensed and distributed under either of
#   * MIT license (license terms in the root directory or at http://opensource.org/licenses/MIT).
#   * Apache v2 license (license terms in the root directory or at http://www.apache.org/licenses/LICENSE-2.0).
# at your option. This file may not be copied, modified, or distributed except according to those terms.

# ############################################################
#
#                    BN254 test generator
#
# ############################################################

# Parameters
x = Integer('0x44E992B44A6909F1')
p = 36*x^4 + 36*x^3 + 24*x^2 + 6*x + 1
r = 36*x^4 + 36*x^3 + 18*x^2 + 6*x + 1
cofactor = 1

# Finite fields
Fp       = GF(p)
K2.<u>  = PolynomialRing(Fp)
Fp2.<beta>  = Fp.extension(u^2+1)
# K6.<v>  = PolynomialRing(Fp2)
# Fp6.<eta>  = Fp2.extension(v^3-Fp2([9, 1]))
# K12.<w> = PolynomialRing(F6)
# K12.<gamma> = Fp6.extension(w^2-eta)

# Curves
b = 3
SNR = Fp2([9, 1])
G1 = EllipticCurve(Fp, [0, b])
G2 = EllipticCurve(Fp2, [0, b/SNR])

# Test generator
set_random_seed(1337)

print('=========================================')
print('G1 vectors: ')
for i in range(10):
    P = G1.random_point()
    (Px, Py, Pz) = P
    print('Px: ' + Integer(Px).hex())
    print('Py: ' + Integer(Py).hex())
    # print('Pz: ' + Integer(Pz).hex())
    exponent = randrange(r) # Pick an integer below curve order
    print('scalar: ' + Integer(exponent).hex())

    Q = exponent * P
    (Qx, Qy, Qz) = Q
    print('Qx: ' + Integer(Qx).hex())
    print('Qy: ' + Integer(Qy).hex())
    # print('Qz: ' + Integer(Qz).hex())
    print('---------------------------------------')
print('=========================================')
print('G2 vectors: ')

for i in range(10):
    P = G2.random_point()
    (Px, Py, Pz) = P
    vPx = vector(Px)
    vPy = vector(Py)
    # Pz = vector(Pz)
    print('Px: ' + Integer(vPx[0]).hex() + ' + β * ' + Integer(vPx[1]).hex())
    print('Py: ' + Integer(vPy[0]).hex() + ' + β * ' + Integer(vPy[1]).hex())

    exponent = randrange(r) # Pick an integer below curve order
    print('scalar: ' + Integer(exponent).hex())

    Q = exponent * P
    (Qx, Qy, Qz) = Q
    Qx = vector(Qx)
    Qy = vector(Qy)
    print('Qx: ' + Integer(Qx[0]).hex() + ' + β * ' + Integer(Qx[1]).hex())
    print('Qy: ' + Integer(Qy[0]).hex() + ' + β * ' + Integer(Qy[1]).hex())
    print('---------------------------------------')
print('=========================================')

# CurveOrder sanity check
#
# P = G1.random_point()
# (Px, Py, Pz) = P
# print('Px: ' + Integer(Px).hex())
# print('Py: ' + Integer(Py).hex())
# print('Pz: ' + Integer(Pz).hex())
#
# print('order: ' + Integer(r).hex())
#
# Q = (r * cofactor) * P
# (Qx, Qy, Qz) = Q
# print('Qx: ' + Integer(Qx).hex())
# print('Qy: ' + Integer(Qy).hex())
# print('Qz: ' + Integer(Qz).hex())
Scalar mul tests (#28) * Add sage script for BN254 * Implement (failing) scalar multiplication tests * Add a first test against sagemath * Finish the tests against SAGE for BN254 * Add significant test coverage of scalar multiplication with reference checks for BN254_Snarks and BLS12_381 2020-06-04 18:37:29 +00:00			`# Constantine`
			`# Copyright (c) 2018-2019 Status Research & Development GmbH`
			`# Copyright (c) 2020-Present Mamy André-Ratsimbazafy`
			`# Licensed and distributed under either of`
			`# * MIT license (license terms in the root directory or at http://opensource.org/licenses/MIT).`
			`# * Apache v2 license (license terms in the root directory or at http://www.apache.org/licenses/LICENSE-2.0).`
			`# at your option. This file may not be copied, modified, or distributed except according to those terms.`

			`# ############################################################`
			`#`
			`# BN254 test generator`
			`#`
			`# ############################################################`

			`# Parameters`
Add a test vector generator for BN254 on G2 and pass the tests 2020-06-17 23:40:13 +00:00			`x = Integer('0x44E992B44A6909F1')`
			`p = 36x^4 + 36x^3 + 24x^2 + 6x + 1`
			`r = 36x^4 + 36x^3 + 18x^2 + 6x + 1`
Scalar mul tests (#28) * Add sage script for BN254 * Implement (failing) scalar multiplication tests * Add a first test against sagemath * Finish the tests against SAGE for BN254 * Add significant test coverage of scalar multiplication with reference checks for BN254_Snarks and BLS12_381 2020-06-04 18:37:29 +00:00			`cofactor = 1`

			`# Finite fields`
Add a test vector generator for BN254 on G2 and pass the tests 2020-06-17 23:40:13 +00:00			`Fp = GF(p)`
			`K2.<u> = PolynomialRing(Fp)`
			`Fp2.<beta> = Fp.extension(u^2+1)`
			`# K6.<v> = PolynomialRing(Fp2)`
			`# Fp6.<eta> = Fp2.extension(v^3-Fp2([9, 1]))`
Scalar mul tests (#28) * Add sage script for BN254 * Implement (failing) scalar multiplication tests * Add a first test against sagemath * Finish the tests against SAGE for BN254 * Add significant test coverage of scalar multiplication with reference checks for BN254_Snarks and BLS12_381 2020-06-04 18:37:29 +00:00			`# K12.<w> = PolynomialRing(F6)`
Add a test vector generator for BN254 on G2 and pass the tests 2020-06-17 23:40:13 +00:00			`# K12.<gamma> = Fp6.extension(w^2-eta)`
Scalar mul tests (#28) * Add sage script for BN254 * Implement (failing) scalar multiplication tests * Add a first test against sagemath * Finish the tests against SAGE for BN254 * Add significant test coverage of scalar multiplication with reference checks for BN254_Snarks and BLS12_381 2020-06-04 18:37:29 +00:00
			`# Curves`
			`b = 3`
Add a test vector generator for BN254 on G2 and pass the tests 2020-06-17 23:40:13 +00:00			`SNR = Fp2([9, 1])`
			`G1 = EllipticCurve(Fp, [0, b])`
			`G2 = EllipticCurve(Fp2, [0, b/SNR])`
Scalar mul tests (#28) * Add sage script for BN254 * Implement (failing) scalar multiplication tests * Add a first test against sagemath * Finish the tests against SAGE for BN254 * Add significant test coverage of scalar multiplication with reference checks for BN254_Snarks and BLS12_381 2020-06-04 18:37:29 +00:00
			`# Test generator`
			`set_random_seed(1337)`

Add a test vector generator for BN254 on G2 and pass the tests 2020-06-17 23:40:13 +00:00			`print('=========================================')`
			`print('G1 vectors: ')`
Scalar mul tests (#28) * Add sage script for BN254 * Implement (failing) scalar multiplication tests * Add a first test against sagemath * Finish the tests against SAGE for BN254 * Add significant test coverage of scalar multiplication with reference checks for BN254_Snarks and BLS12_381 2020-06-04 18:37:29 +00:00			`for i in range(10):`
			`P = G1.random_point()`
			`(Px, Py, Pz) = P`
			`print('Px: ' + Integer(Px).hex())`
			`print('Py: ' + Integer(Py).hex())`
Add a test vector generator for BN254 on G2 and pass the tests 2020-06-17 23:40:13 +00:00			`# print('Pz: ' + Integer(Pz).hex())`
Scalar mul tests (#28) * Add sage script for BN254 * Implement (failing) scalar multiplication tests * Add a first test against sagemath * Finish the tests against SAGE for BN254 * Add significant test coverage of scalar multiplication with reference checks for BN254_Snarks and BLS12_381 2020-06-04 18:37:29 +00:00			`exponent = randrange(r) # Pick an integer below curve order`
			`print('scalar: ' + Integer(exponent).hex())`

			`Q = exponent * P`
			`(Qx, Qy, Qz) = Q`
			`print('Qx: ' + Integer(Qx).hex())`
			`print('Qy: ' + Integer(Qy).hex())`
Add a test vector generator for BN254 on G2 and pass the tests 2020-06-17 23:40:13 +00:00			`# print('Qz: ' + Integer(Qz).hex())`
			`print('---------------------------------------')`
			`print('=========================================')`
			`print('G2 vectors: ')`

			`for i in range(10):`
			`P = G2.random_point()`
			`(Px, Py, Pz) = P`
			`vPx = vector(Px)`
			`vPy = vector(Py)`
			`# Pz = vector(Pz)`
			`print('Px: ' + Integer(vPx[0]).hex() + ' + β * ' + Integer(vPx[1]).hex())`
			`print('Py: ' + Integer(vPy[0]).hex() + ' + β * ' + Integer(vPy[1]).hex())`

			`exponent = randrange(r) # Pick an integer below curve order`
			`print('scalar: ' + Integer(exponent).hex())`

			`Q = exponent * P`
			`(Qx, Qy, Qz) = Q`
			`Qx = vector(Qx)`
			`Qy = vector(Qy)`
			`print('Qx: ' + Integer(Qx[0]).hex() + ' + β * ' + Integer(Qx[1]).hex())`
			`print('Qy: ' + Integer(Qy[0]).hex() + ' + β * ' + Integer(Qy[1]).hex())`
			`print('---------------------------------------')`
Endomorphism acceleration for Scalar Multiplication (#44) * Add MultiScalar recoding from "Efficient and Secure Algorithms for GLV-Based Scalar Multiplication" by Faz et al * precompute cube root of unity - Add VM precomputation of Fp - workaround upstream bug https://github.com/nim-lang/Nim/issues/14585 * Add the φ-accelerated lookup table builder * Add a dedicated bithacks file * cosmetic import consistency * Build the φ precompute table with n-1 EC additions instead of 2^(n-1) additions * remove binary * Add the GLV precomputations to the sage scripts * You can't avoid it, bigint multiplication is needed at one point * Add bigint multiplication discarding some low words * Implement the lattice decomposition in sage * Proper decomposition for BN254 * Prepare the code for a new scalar mul * We compile, and now debugging hunt * More helpers to debug GLV scalar Mul * Fix conditional negation * Endomorphism accelerated scalar mul working for BN254 curve * Implement endomorphism acceleration for BLS12-381 (needed cofactor clearing of the point) * fix nimble test script after bench rename 2020-06-14 13:39:06 +00:00			`print('=========================================')`
Scalar mul tests (#28) * Add sage script for BN254 * Implement (failing) scalar multiplication tests * Add a first test against sagemath * Finish the tests against SAGE for BN254 * Add significant test coverage of scalar multiplication with reference checks for BN254_Snarks and BLS12_381 2020-06-04 18:37:29 +00:00
			`# CurveOrder sanity check`
			`#`
			`# P = G1.random_point()`
			`# (Px, Py, Pz) = P`
			`# print('Px: ' + Integer(Px).hex())`
			`# print('Py: ' + Integer(Py).hex())`
			`# print('Pz: ' + Integer(Pz).hex())`
			`#`
			`# print('order: ' + Integer(r).hex())`
			`#`
			`# Q = (r * cofactor) * P`
			`# (Qx, Qy, Qz) = Q`
			`# print('Qx: ' + Integer(Qx).hex())`
			`# print('Qy: ' + Integer(Qy).hex())`
			`# print('Qz: ' + Integer(Qz).hex())`