constantine/sage/testgen_scalar_mul.sage

261 lines
7.0 KiB
Python
Raw Normal View History

#!/usr/bin/sage
# vim: syntax=python
# vim: set ts=2 sw=2 et:
# 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.
# ############################################################
#
# Scalar multiplication test generator
#
# ############################################################
# Imports
# ---------------------------------------------------------
import os, json
import inspect, textwrap
# Working directory
# ---------------------------------------------------------
os.chdir(os.path.dirname(__file__))
# Sage imports
# ---------------------------------------------------------
# Accelerate arithmetic by accepting probabilistic proofs
from sage.structure.proof.all import arithmetic
arithmetic(False)
load('curves.sage')
# Utilities
# ---------------------------------------------------------
def progressbar(it, prefix="", size=60, file=sys.stdout):
count = len(it)
def show(j):
x = int(size*j/count)
file.write("%s[%s%s] %i/%i\r" % (prefix, "#"*x, "."*(size-x), j, count))
file.flush()
show(0)
for i, item in enumerate(it):
yield item
show(i+1)
file.write("\n")
file.flush()
def serialize_bigint(x):
return '0x' + Integer(x).hex()
def serialize_EC_Fp(P):
(Px, Py, Pz) = P
coords = {
'x': serialize_bigint(Px),
'y': serialize_bigint(Py)
}
return coords
def serialize_EC_Fp2(P):
(Px, Py, Pz) = P
Px = vector(Px)
Py = vector(Py)
coords = {
'x': {
'c0': serialize_bigint(Px[0]),
'c1': serialize_bigint(Px[1])
},
'y': {
'c0': serialize_bigint(Py[0]),
'c1': serialize_bigint(Py[1])
}
}
return coords
# Generator
# ---------------------------------------------------------
def genScalarMulG1(curve_name, curve_config, count, seed):
p = curve_config[curve_name]['field']['modulus']
r = curve_config[curve_name]['field']['order']
form = curve_config[curve_name]['curve']['form']
a = curve_config[curve_name]['curve']['a']
b = curve_config[curve_name]['curve']['b']
Fp = GF(p)
G1 = EllipticCurve(Fp, [0, b])
cofactor = G1.order() // r
out = {
'curve': curve_name,
'group': 'G1',
'modulus': serialize_bigint(p),
'order': serialize_bigint(r),
'cofactor': serialize_bigint(cofactor),
'form': form
}
if form == 'short_weierstrass':
out['a'] = serialize_bigint(a)
out['b'] = serialize_bigint(b)
vectors = []
set_random_seed(seed)
for i in progressbar(range(count)):
v = {}
P = G1.random_point()
scalar = randrange(r)
P *= cofactor # clear cofactor
Q = scalar * P
v['id'] = i
v['P'] = serialize_EC_Fp(P)
v['scalar'] = serialize_bigint(scalar)
v['Q'] = serialize_EC_Fp(Q)
vectors.append(v)
out['vectors'] = vectors
return out
def genScalarMulG2(curve_name, curve_config, count, seed):
p = curve_config[curve_name]['field']['modulus']
r = curve_config[curve_name]['field']['order']
form = curve_config[curve_name]['curve']['form']
a = curve_config[curve_name]['curve']['a']
b = curve_config[curve_name]['curve']['b']
embedding_degree = curve_config[curve_name]['tower']['embedding_degree']
twist_degree = curve_config[curve_name]['tower']['twist_degree']
twist = curve_config[curve_name]['tower']['twist']
G2_field_degree = embedding_degree // twist_degree
G2_field = f'Fp{G2_field_degree}' if G2_field_degree > 1 else 'Fp'
if G2_field_degree == 2:
non_residue_fp = curve_config[curve_name]['tower']['QNR_Fp']
elif G2_field_degree == 1:
if twist_degree == 6:
# Only for complete serialization
non_residue_fp = curve_config[curve_name]['tower']['SNR_Fp']
else:
raise NotImplementedError()
else:
raise NotImplementedError()
Fp = GF(p)
K.<u> = PolynomialRing(Fp)
if G2_field == 'Fp2':
Fp2.<beta> = Fp.extension(u^2 - non_residue_fp)
G2F = Fp2
if twist_degree == 6:
non_residue_twist = curve_config[curve_name]['tower']['SNR_Fp2']
else:
raise NotImplementedError()
elif G2_field == 'Fp':
G2F = Fp
if twist_degree == 6:
non_residue_twist = curve_config[curve_name]['tower']['SNR_Fp']
else:
raise NotImplementedError()
else:
raise NotImplementedError()
if twist == 'D_Twist':
G2 = EllipticCurve(G2F, [0, b/G2F(non_residue_twist)])
elif twist == 'M_Twist':
G2 = EllipticCurve(G2F, [0, b*G2F(non_residue_twist)])
else:
raise ValueError('G2 must be a D_Twist or M_Twist but found ' + twist)
cofactor = G2.order() // r
out = {
'curve': curve_name,
'group': 'G2',
'modulus': serialize_bigint(p),
'order': serialize_bigint(r),
'cofactor': serialize_bigint(cofactor),
'form': form,
'twist_degree': int(twist_degree),
'twist': twist,
'non_residue_fp': int(non_residue_fp),
'G2_field': G2_field,
'non_residue_twist': [int(coord) for coord in non_residue_twist] if isinstance(non_residue_twist, list) else int(non_residue_twist)
}
if form == 'short_weierstrass':
out['a'] = serialize_bigint(a)
out['b'] = serialize_bigint(b)
vectors = []
set_random_seed(seed)
for i in progressbar(range(count)):
v = {}
P = G2.random_point()
scalar = randrange(r)
P *= cofactor # clear cofactor
Q = scalar * P
v['id'] = i
if G2_field == 'Fp2':
v['P'] = serialize_EC_Fp2(P)
v['scalar'] = serialize_bigint(scalar)
v['Q'] = serialize_EC_Fp2(Q)
elif G2_field == 'Fp':
v['P'] = serialize_EC_Fp(P)
v['scalar'] = serialize_bigint(scalar)
v['Q'] = serialize_EC_Fp(Q)
vectors.append(v)
out['vectors'] = vectors
return out
# CLI
# ---------------------------------------------------------
if __name__ == "__main__":
# Usage
# BLS12-381
# sage sage/derive_pairing.sage BLS12_381 G1
from argparse import ArgumentParser
parser = ArgumentParser()
parser.add_argument("curve",nargs="+")
args = parser.parse_args()
curve = args.curve[0]
group = args.curve[1]
if curve not in Curves:
raise ValueError(
curve +
' is not one of the available curves: ' +
str(Curves.keys())
)
elif group not in ['G1', 'G2']:
raise ValueError(
group +
' is not a valid group, expected G1 or G2 instead'
)
else:
print(f'\nGenerating test vectors tv_{curve}_scalar_mul_{group}.json')
print('----------------------------------------------------\n')
count = 40
seed = 1337
if group == 'G1':
out = genScalarMulG1(curve, Curves, count, seed)
elif group == 'G2':
out = genScalarMulG2(curve, Curves, count, seed)
with open(f'tv_{curve}_scalar_mul_{group}.json', 'w') as f:
json.dump(out, f, indent=2)