# 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. # This script checks polynomial irreducibility # # Constructing Tower Extensions for the implementation of Pairing-Based Cryptography # Naomi Benger and Michael Scott, 2009 # https://eprint.iacr.org/2009/556 # Note: Some of the curves here are not pairing friendly and never used in an extension field. # We still check them to potentially add them as additional test vectors in # 𝔽p2, 𝔽p6, 𝔽p12, ... since as they are most 0xFF bytes they # trigger "carry" code-paths that are not triggered by pairing-friendly moduli. Curves = { 'P224': Integer('0xffffffffffffffffffffffffffffffff000000000000000000000001'), 'BN254_Nogami': Integer('0x2523648240000001ba344d80000000086121000000000013a700000000000013'), 'BN254_Snarks': Integer('0x30644e72e131a029b85045b68181585d97816a916871ca8d3c208c16d87cfd47'), 'Curve25519': Integer('0x7fffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffed'), 'P256': Integer('0xffffffff00000001000000000000000000000000ffffffffffffffffffffffff'), 'Secp256k1': Integer('0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFC2F'), 'BLS12_377': Integer('0x01ae3a4617c510eac63b05c06ca1493b1a22d9f300f5138f1ef3622fba094800170b5d44300000008508c00000000001'), 'BLS12_381': Integer('0x1a0111ea397fe69a4b1ba7b6434bacd764774b84f38512bf6730d2a0f6b0f6241eabfffeb153ffffb9feffffffffaaab'), 'BN446': Integer('0x2400000000000000002400000002d00000000d800000021c0000001800000000870000000b0400000057c00000015c000000132000000067'), 'FKM12_447': Integer('0x4ce300001338c00001c08180000f20cfffffe5a8bffffd08a000000f228000007e8ffffffaddfffffffdc00000009efffffffca000000007'), 'BLS12_461': Integer('0x15555545554d5a555a55d69414935fbd6f1e32d8bacca47b14848b42a8dffa5c1cc00f26aa91557f00400020000555554aaaaaac0000aaaaaaab'), 'BN462': Integer('0x240480360120023ffffffffff6ff0cf6b7d9bfca0000000000d812908f41c8020ffffffffff6ff66fc6ff687f640000000002401b00840138013') } def find_quadratic_non_residues(A, B, Field, modulus): result = false for a in A: for b in B: residue = Fp(a^2 + b^2).residue_symbol(Fp.ideal(modulus),2) if residue < 0: print(f' 𝔽p4 = 𝔽p2[v] / v² - ({a} ± {b}𝑖) is an irreducible polynomial') result = true return result def find_cubic_non_residues_pmod3eq1(A, B, modulus): assert modulus % 3 == 1 result = false for a in A: for b in B: # The following `residue_symbol` is not satisfactory for cubic root # It just returns exceptions for all values # # # residue = Fp(a^2 + b^2).residue_symbol(Fp.ideal(modulus),3) # if residue < 0: # print(f' 𝔽p2[v] / v³ - ({a} ± {b}𝑖) is an irreducible polynomial') # for p ≡ 1 (mod 3) # we have ``a`` a cubic residue iff a^((p-1)/3) ≡ 1 (mod p) residue = pow(a^2 + b^2, (modulus-1)//3, modulus) if residue != 1: print(f' 𝔽p6 = 𝔽p2[v] / v³ - ({a} ± {b}𝑖) is a possible extension') result = true return result for curve, modulus in Curves.items(): print(f'Curve {curve}:') print(f' Modulus 0x{modulus.hex()}:') pMod4 = modulus % 4 print(f' p mod 4: {pMod4}') if pMod4 == 3: # This is actually the hard case, but given that most pairing friendly curves somehow end up in that case # this is the one we will focus on. print(f' ^ suggested irreducible polynomial for 𝔽p2: u² + 1 (𝔽p2 complex)') else: print(f' ⚠️ p mod 4 != 3: to be reviewed manually. See Theorem 1 of Scott 2009 Constructing Tower Extensions for the implementation of Pairing-Based Cryptography') print(f' p mod 8: {modulus % 8}') print(f' p mod 12: {modulus % 12}') if pMod4 != 3: print(f' p mod 4 != 3 => find a square/cubic root and then successively adjoin roots of the roots to build the tower.') print(f' Skipping to next curve.') continue Fp.
= NumberField(x - 1) print('') print(' Searching for valid irreducible polynomials ...') # Constructing 𝔽p4 print(' 𝔽p4 = 𝔽p2[v] / v² - (a ± 𝑖 b))') found = find_quadratic_non_residues([0, 1, 2], [1, 2], Fp, modulus) if not found: found = find_quadratic_non_residues(range(5), range(1, 5), Fp, modulus) assert found found = false # Constructing 𝔽p6 print(' 𝔽p6 = 𝔽p2[v] / v³ - (a ± 𝑖 b))') pMod3 = modulus % 3 print(f' p mod 3: {pMod3}') if pMod3 != 1: # A remark on the computation of cube roots in finite fields # https://eprint.iacr.org/2009/457.pdf print(f' p mod 3 != 1 => to be reviewed manually') print(f' Skipping to next curve.') continue if not found: found = find_cubic_non_residues_pmod3eq1([0, 1, 2], [1, 2], modulus) if not found: found = find_cubic_non_residues_pmod3eq1(range(5), range(1, 5), modulus) if not found: found = find_cubic_non_residues_pmod3eq1(range(17), range(1, 17), modulus) assert found # ############################################################ # # Failed experiments of actually instantiating # the tower of extension fields # # ############################################################ # ############################################################ # 1st try # # Create the field of x ∈ [0, p-1] # K.
= NumberField(x - 1)
#
# # Tower Fp² with Fp[u] / (u² + 1) <=> u = 𝑖
# L. = NumberField(x - 1)
# r1 = Fp(-1).residue_symbol(Fp.ideal(modulus),2)
# print('Fp² = Fp[sqrt(-1)]: ' + str(r1))
# Fp2.