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poseidon2_rust_params.sage
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poseidon2_rust_params.sage
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# Remark: This script contains functionality for GF(2^n), but currently works only over GF(p)! A few small adaptations are needed for GF(2^n).
from sage.rings.polynomial.polynomial_gf2x import GF2X_BuildIrred_list
from math import *
import itertools
###########################################################################
# p = 18446744069414584321 # GoldiLocks
# p = 2013265921 # BabyBear
p = 52435875175126190479447740508185965837690552500527637822603658699938581184513 # BLS12-381
# p = 21888242871839275222246405745257275088548364400416034343698204186575808495617 # BN254/BN256
# p = 28948022309329048855892746252171976963363056481941560715954676764349967630337 # Pasta (Pallas)
# p = 28948022309329048855892746252171976963363056481941647379679742748393362948097 # Pasta (Vesta)
n = len(p.bits()) # bit
# t = 12 # GoldiLocks (t = 12 for sponge, t = 8 for compression)
# t = 16 # BabyBear (t = 24 for sponge, t = 16 for compression)
t = 3 # BN254/BN256, BLS12-381, Pallas, Vesta (t = 3 for sponge, t = 2 for compression)
FIELD = 1
SBOX = 0
FIELD_SIZE = n
NUM_CELLS = t
def get_alpha(p):
for alpha in range(3, p):
if gcd(alpha, p-1) == 1:
break
return alpha
alpha = get_alpha(p)
def get_sbox_cost(R_F, R_P, N, t):
return int(t * R_F + R_P)
def get_size_cost(R_F, R_P, N, t):
n = ceil(float(N) / t)
return int((N * R_F) + (n * R_P))
def poseidon_calc_final_numbers_fixed(p, t, alpha, M, security_margin):
# [Min. S-boxes] Find best possible for t and N
n = ceil(log(p, 2))
N = int(n * t)
cost_function = get_sbox_cost
ret_list = []
(R_F, R_P) = find_FD_round_numbers(p, t, alpha, M, cost_function, security_margin)
min_sbox_cost = cost_function(R_F, R_P, N, t)
ret_list.append(R_F)
ret_list.append(R_P)
ret_list.append(min_sbox_cost)
# [Min. Size] Find best possible for t and N
# Minimum number of S-boxes for fixed n results in minimum size also (round numbers are the same)!
min_size_cost = get_size_cost(R_F, R_P, N, t)
ret_list.append(min_size_cost)
return ret_list # [R_F, R_P, min_sbox_cost, min_size_cost]
def find_FD_round_numbers(p, t, alpha, M, cost_function, security_margin):
n = ceil(log(p, 2))
N = int(n * t)
sat_inequiv = sat_inequiv_alpha
R_P = 0
R_F = 0
min_cost = float("inf")
max_cost_rf = 0
# Brute-force approach
for R_P_t in range(1, 500):
for R_F_t in range(4, 100):
if R_F_t % 2 == 0:
if (sat_inequiv(p, t, R_F_t, R_P_t, alpha, M) == True):
if security_margin == True:
R_F_t += 2
R_P_t = int(ceil(float(R_P_t) * 1.075))
cost = cost_function(R_F_t, R_P_t, N, t)
if (cost < min_cost) or ((cost == min_cost) and (R_F_t < max_cost_rf)):
R_P = ceil(R_P_t)
R_F = ceil(R_F_t)
min_cost = cost
max_cost_rf = R_F
return (int(R_F), int(R_P))
def sat_inequiv_alpha(p, t, R_F, R_P, alpha, M):
N = int(FIELD_SIZE * NUM_CELLS)
if alpha > 0:
R_F_1 = 6 if M <= ((floor(log(p, 2) - ((alpha-1)/2.0))) * (t + 1)) else 10 # Statistical
R_F_2 = 1 + ceil(log(2, alpha) * min(M, FIELD_SIZE)) + ceil(log(t, alpha)) - R_P # Interpolation
R_F_3 = (log(2, alpha) * min(M, log(p, 2))) - R_P # Groebner 1
R_F_4 = t - 1 + log(2, alpha) * min(M / float(t + 1), log(p, 2) / float(2)) - R_P # Groebner 2
R_F_5 = (t - 2 + (M / float(2 * log(alpha, 2))) - R_P) / float(t - 1) # Groebner 3
R_F_max = max(ceil(R_F_1), ceil(R_F_2), ceil(R_F_3), ceil(R_F_4), ceil(R_F_5))
# Addition due to https://eprint.iacr.org/2023/537.pdf
r_temp = floor(t / 3.0)
over = (R_F - 1) * t + R_P + r_temp + r_temp * (R_F / 2.0) + R_P + alpha
under = r_temp * (R_F / 2.0) + R_P + alpha
binom_log = log(binomial(over, under), 2)
if binom_log == inf:
binom_log = M + 1
cost_gb4 = ceil(2 * binom_log) # Paper uses 2.3727, we are more conservative here
return ((R_F >= R_F_max) and (cost_gb4 >= M))
else:
print("Invalid value for alpha!")
exit(1)
R_F_FIXED, R_P_FIXED, _, _ = poseidon_calc_final_numbers_fixed(p, t, alpha, 128, True)
print("+++ R_F = {0}, R_P = {1} +++".format(R_F_FIXED, R_P_FIXED))
# For STARK TODO
# r_p_mod = R_P_FIXED % NUM_CELLS
# if r_p_mod != 0:
# R_P_FIXED = R_P_FIXED + NUM_CELLS - r_p_mod
###########################################################################
INIT_SEQUENCE = []
PRIME_NUMBER = p
# if FIELD == 1 and len(sys.argv) != 8:
# print("Please specify a prime number (in hex format)!")
# exit()
# elif FIELD == 1 and len(sys.argv) == 8:
# PRIME_NUMBER = int(sys.argv[7], 16) # e.g. 0xa7, 0xFFFFFFFFFFFFFEFF, 0xa1a42c3efd6dbfe08daa6041b36322ef
F = GF(PRIME_NUMBER)
def grain_sr_generator():
bit_sequence = INIT_SEQUENCE
for _ in range(0, 160):
new_bit = bit_sequence[62] ^^ bit_sequence[51] ^^ bit_sequence[38] ^^ bit_sequence[23] ^^ bit_sequence[13] ^^ bit_sequence[0]
bit_sequence.pop(0)
bit_sequence.append(new_bit)
while True:
new_bit = bit_sequence[62] ^^ bit_sequence[51] ^^ bit_sequence[38] ^^ bit_sequence[23] ^^ bit_sequence[13] ^^ bit_sequence[0]
bit_sequence.pop(0)
bit_sequence.append(new_bit)
while new_bit == 0:
new_bit = bit_sequence[62] ^^ bit_sequence[51] ^^ bit_sequence[38] ^^ bit_sequence[23] ^^ bit_sequence[13] ^^ bit_sequence[0]
bit_sequence.pop(0)
bit_sequence.append(new_bit)
new_bit = bit_sequence[62] ^^ bit_sequence[51] ^^ bit_sequence[38] ^^ bit_sequence[23] ^^ bit_sequence[13] ^^ bit_sequence[0]
bit_sequence.pop(0)
bit_sequence.append(new_bit)
new_bit = bit_sequence[62] ^^ bit_sequence[51] ^^ bit_sequence[38] ^^ bit_sequence[23] ^^ bit_sequence[13] ^^ bit_sequence[0]
bit_sequence.pop(0)
bit_sequence.append(new_bit)
yield new_bit
grain_gen = grain_sr_generator()
def grain_random_bits(num_bits):
random_bits = [next(grain_gen) for i in range(0, num_bits)]
# random_bits.reverse() ## Remove comment to start from least significant bit
random_int = int("".join(str(i) for i in random_bits), 2)
return random_int
def init_generator(field, sbox, n, t, R_F, R_P):
# Generate initial sequence based on parameters
bit_list_field = [_ for _ in (bin(FIELD)[2:].zfill(2))]
bit_list_sbox = [_ for _ in (bin(SBOX)[2:].zfill(4))]
bit_list_n = [_ for _ in (bin(FIELD_SIZE)[2:].zfill(12))]
bit_list_t = [_ for _ in (bin(NUM_CELLS)[2:].zfill(12))]
bit_list_R_F = [_ for _ in (bin(R_F)[2:].zfill(10))]
bit_list_R_P = [_ for _ in (bin(R_P)[2:].zfill(10))]
bit_list_1 = [1] * 30
global INIT_SEQUENCE
INIT_SEQUENCE = bit_list_field + bit_list_sbox + bit_list_n + bit_list_t + bit_list_R_F + bit_list_R_P + bit_list_1
INIT_SEQUENCE = [int(_) for _ in INIT_SEQUENCE]
def generate_constants(field, n, t, R_F, R_P, prime_number):
round_constants = []
# num_constants = (R_F + R_P) * t # Poseidon
num_constants = (R_F * t) + R_P # Poseidon2
if field == 0:
for i in range(0, num_constants):
random_int = grain_random_bits(n)
round_constants.append(random_int)
elif field == 1:
for i in range(0, num_constants):
random_int = grain_random_bits(n)
while random_int >= prime_number:
# print("[Info] Round constant is not in prime field! Taking next one.")
random_int = grain_random_bits(n)
round_constants.append(random_int)
# Add (t-1) zeroes for Poseidon2 if partial round
if i >= ((R_F/2) * t) and i < (((R_F/2) * t) + R_P):
round_constants.extend([0] * (t-1))
return round_constants
def print_round_constants(round_constants, n, field):
print("Number of round constants:", len(round_constants))
if field == 0:
print("Round constants for GF(2^n):")
elif field == 1:
print("Round constants for GF(p):")
hex_length = int(ceil(float(n) / 4)) + 2 # +2 for "0x"
print(["{0:#0{1}x}".format(entry, hex_length) for entry in round_constants])
def create_mds_p(n, t):
M = matrix(F, t, t)
# Sample random distinct indices and assign to xs and ys
while True:
flag = True
rand_list = [F(grain_random_bits(n)) for _ in range(0, 2*t)]
while len(rand_list) != len(set(rand_list)): # Check for duplicates
rand_list = [F(grain_random_bits(n)) for _ in range(0, 2*t)]
xs = rand_list[:t]
ys = rand_list[t:]
# xs = [F(ele) for ele in range(0, t)]
# ys = [F(ele) for ele in range(t, 2*t)]
for i in range(0, t):
for j in range(0, t):
if (flag == False) or ((xs[i] + ys[j]) == 0):
flag = False
else:
entry = (xs[i] + ys[j])^(-1)
M[i, j] = entry
if flag == False:
continue
return M
def generate_vectorspace(round_num, M, M_round, NUM_CELLS):
t = NUM_CELLS
s = 1
V = VectorSpace(F, t)
if round_num == 0:
return V
elif round_num == 1:
return V.subspace(V.basis()[s:])
else:
mat_temp = matrix(F)
for i in range(0, round_num-1):
add_rows = []
for j in range(0, s):
add_rows.append(M_round[i].rows()[j][s:])
mat_temp = matrix(mat_temp.rows() + add_rows)
r_k = mat_temp.right_kernel()
extended_basis_vectors = []
for vec in r_k.basis():
extended_basis_vectors.append(vector([0]*s + list(vec)))
S = V.subspace(extended_basis_vectors)
return S
def subspace_times_matrix(subspace, M, NUM_CELLS):
t = NUM_CELLS
V = VectorSpace(F, t)
subspace_basis = subspace.basis()
new_basis = []
for vec in subspace_basis:
new_basis.append(M * vec)
new_subspace = V.subspace(new_basis)
return new_subspace
# Returns True if the matrix is considered secure, False otherwise
def algorithm_1(M, NUM_CELLS):
t = NUM_CELLS
s = 1
r = floor((t - s) / float(s))
# Generate round matrices
M_round = []
for j in range(0, t+1):
M_round.append(M^(j+1))
for i in range(1, r+1):
mat_test = M^i
entry = mat_test[0, 0]
mat_target = matrix.circulant(vector([entry] + ([F(0)] * (t-1))))
if (mat_test - mat_target) == matrix.circulant(vector([F(0)] * (t))):
return [False, 1]
S = generate_vectorspace(i, M, M_round, t)
V = VectorSpace(F, t)
basis_vectors= []
for eigenspace in mat_test.eigenspaces_right(format='galois'):
if (eigenspace[0] not in F):
continue
vector_subspace = eigenspace[1]
intersection = S.intersection(vector_subspace)
basis_vectors += intersection.basis()
IS = V.subspace(basis_vectors)
if IS.dimension() >= 1 and IS != V:
return [False, 2]
for j in range(1, i+1):
S_mat_mul = subspace_times_matrix(S, M^j, t)
if S == S_mat_mul:
print("S.basis():\n", S.basis())
return [False, 3]
return [True, 0]
# Returns True if the matrix is considered secure, False otherwise
def algorithm_2(M, NUM_CELLS):
t = NUM_CELLS
s = 1
V = VectorSpace(F, t)
trail = [None, None]
test_next = False
I = range(0, s)
I_powerset = list(sage.misc.misc.powerset(I))[1:]
for I_s in I_powerset:
test_next = False
new_basis = []
for l in I_s:
new_basis.append(V.basis()[l])
IS = V.subspace(new_basis)
for i in range(s, t):
new_basis.append(V.basis()[i])
full_iota_space = V.subspace(new_basis)
for l in I_s:
v = V.basis()[l]
while True:
delta = IS.dimension()
v = M * v
IS = V.subspace(IS.basis() + [v])
if IS.dimension() == t or IS.intersection(full_iota_space) != IS:
test_next = True
break
if IS.dimension() <= delta:
break
if test_next == True:
break
if test_next == True:
continue
return [False, [IS, I_s]]
return [True, None]
# Returns True if the matrix is considered secure, False otherwise
def algorithm_3(M, NUM_CELLS):
t = NUM_CELLS
s = 1
V = VectorSpace(F, t)
l = 4*t
for r in range(2, l+1):
next_r = False
res_alg_2 = algorithm_2(M^r, t)
if res_alg_2[0] == False:
return [False, None]
# if res_alg_2[1] == None:
# continue
# IS = res_alg_2[1][0]
# I_s = res_alg_2[1][1]
# for j in range(1, r):
# IS = subspace_times_matrix(IS, M, t)
# I_j = []
# for i in range(0, s):
# new_basis = []
# for k in range(0, t):
# if k != i:
# new_basis.append(V.basis()[k])
# iota_space = V.subspace(new_basis)
# if IS.intersection(iota_space) != iota_space:
# single_iota_space = V.subspace([V.basis()[i]])
# if IS.intersection(single_iota_space) == single_iota_space:
# I_j.append(i)
# else:
# next_r = True
# break
# if next_r == True:
# break
# if next_r == True:
# continue
# return [False, [IS, I_j, r]]
return [True, None]
def check_minpoly_condition(M, NUM_CELLS):
max_period = 2*NUM_CELLS
all_fulfilled = True
M_temp = M
for i in range(1, max_period + 1):
if not ((M_temp.minimal_polynomial().degree() == NUM_CELLS) and (M_temp.minimal_polynomial().is_irreducible() == True)):
all_fulfilled = False
break
M_temp = M * M_temp
return all_fulfilled
def generate_matrix(FIELD, FIELD_SIZE, NUM_CELLS):
if FIELD == 0:
print("Matrix generation not implemented for GF(2^n).")
exit(1)
elif FIELD == 1:
mds_matrix = create_mds_p(FIELD_SIZE, NUM_CELLS)
result_1 = algorithm_1(mds_matrix, NUM_CELLS)
result_2 = algorithm_2(mds_matrix, NUM_CELLS)
result_3 = algorithm_3(mds_matrix, NUM_CELLS)
while result_1[0] == False or result_2[0] == False or result_3[0] == False:
mds_matrix = create_mds_p(FIELD_SIZE, NUM_CELLS)
result_1 = algorithm_1(mds_matrix, NUM_CELLS)
result_2 = algorithm_2(mds_matrix, NUM_CELLS)
result_3 = algorithm_3(mds_matrix, NUM_CELLS)
return mds_matrix
def generate_matrix_full(NUM_CELLS):
M = None
if t == 2:
M = matrix.circulant(vector([F(2), F(1)]))
elif t == 3:
M = matrix.circulant(vector([F(2), F(1), F(1)]))
elif t == 4:
M = matrix(F, [[F(5), F(7), F(1), F(3)], [F(4), F(6), F(1), F(1)], [F(1), F(3), F(5), F(7)], [F(1), F(1), F(4), F(6)]])
elif (t % 4) == 0:
M = matrix(F, t, t)
# M_small = matrix.circulant(vector([F(3), F(2), F(1), F(1)]))
M_small = matrix(F, [[F(5), F(7), F(1), F(3)], [F(4), F(6), F(1), F(1)], [F(1), F(3), F(5), F(7)], [F(1), F(1), F(4), F(6)]])
small_num = t // 4
for i in range(0, small_num):
for j in range(0, small_num):
if i == j:
M[i*4:(i+1)*4,j*4:(j+1)*4] = 2* M_small
else:
M[i*4:(i+1)*4,j*4:(j+1)*4] = M_small
else:
print("Error: No matrix for these parameters.")
exit()
return M
def generate_matrix_partial(FIELD, FIELD_SIZE, NUM_CELLS): ## TODO: Prioritize small entries
entry_max_bit_size = FIELD_SIZE
if FIELD == 0:
print("Matrix generation not implemented for GF(2^n).")
exit(1)
elif FIELD == 1:
M = None
if t == 2:
M = matrix(F, [[F(2), F(1)], [F(1), F(3)]])
elif t == 3:
M = matrix(F, [[F(2), F(1), F(1)], [F(1), F(2), F(1)], [F(1), F(1), F(3)]])
else:
M_circulant = matrix.circulant(vector([F(0)] + [F(1) for _ in range(0, NUM_CELLS - 1)]))
M_diagonal = matrix.diagonal([F(grain_random_bits(entry_max_bit_size)) for _ in range(0, NUM_CELLS)])
M = M_circulant + M_diagonal
# while algorithm_1(M, NUM_CELLS)[0] == False or algorithm_2(M, NUM_CELLS)[0] == False or algorithm_3(M, NUM_CELLS)[0] == False:
while check_minpoly_condition(M, NUM_CELLS) == False:
M_diagonal = matrix.diagonal([F(grain_random_bits(entry_max_bit_size)) for _ in range(0, NUM_CELLS)])
M = M_circulant + M_diagonal
if(algorithm_1(M, NUM_CELLS)[0] == False or algorithm_2(M, NUM_CELLS)[0] == False or algorithm_3(M, NUM_CELLS)[0] == False):
print("Error: Generated partial matrix is not secure w.r.t. subspace trails.")
exit()
return M
def generate_matrix_partial_small_entries(FIELD, FIELD_SIZE, NUM_CELLS):
if FIELD == 0:
print("Matrix generation not implemented for GF(2^n).")
exit(1)
elif FIELD == 1:
M_circulant = matrix.circulant(vector([F(0)] + [F(1) for _ in range(0, NUM_CELLS - 1)]))
combinations = list(itertools.product(range(2, 6), repeat=NUM_CELLS))
for entry in combinations:
M = M_circulant + matrix.diagonal(vector(F, list(entry)))
print(M)
# if M.is_invertible() == False or algorithm_1(M, NUM_CELLS)[0] == False or algorithm_2(M, NUM_CELLS)[0] == False or algorithm_3(M, NUM_CELLS)[0] == False:
if M.is_invertible() == False or check_minpoly_condition(M, NUM_CELLS) == False:
continue
return M
def matrix_partial_m_1(matrix_partial, NUM_CELLS):
M_circulant = matrix.identity(F, NUM_CELLS)
return matrix_partial - M_circulant
def print_linear_layer(M, n, t):
print("n:", n)
print("t:", t)
print("N:", (n * t))
print("Result Algorithm 1:\n", algorithm_1(M, NUM_CELLS))
print("Result Algorithm 2:\n", algorithm_2(M, NUM_CELLS))
print("Result Algorithm 3:\n", algorithm_3(M, NUM_CELLS))
hex_length = int(ceil(float(n) / 4)) + 2 # +2 for "0x"
print("Prime number:", "0x" + hex(PRIME_NUMBER))
matrix_string = "["
for i in range(0, t):
matrix_string += str(["{0:#0{1}x}".format(int(entry), hex_length) for entry in M[i]])
if i < (t-1):
matrix_string += ","
matrix_string += "]"
print("MDS matrix:\n", matrix_string)
def calc_equivalent_matrices(MDS_matrix_field):
# Following idea: Split M into M' * M'', where M'' is "cheap" and M' can move before the partial nonlinear layer
# The "previous" matrix layer is then M * M'. Due to the construction of M', the M[0,0] and v values will be the same for the new M' (and I also, obviously)
# Thus: Compute the matrices, store the w_hat and v_hat values
MDS_matrix_field_transpose = MDS_matrix_field.transpose()
w_hat_collection = []
v_collection = []
v = MDS_matrix_field_transpose[[0], list(range(1,t))]
M_mul = MDS_matrix_field_transpose
M_i = matrix(F, t, t)
for i in range(R_P_FIXED - 1, -1, -1):
M_hat = M_mul[list(range(1,t)), list(range(1,t))]
w = M_mul[list(range(1,t)), [0]]
v = M_mul[[0], list(range(1,t))]
v_collection.append(v.list())
w_hat = M_hat.inverse() * w
w_hat_collection.append(w_hat.list())
# Generate new M_i, and multiplication M * M_i for "previous" round
M_i = matrix.identity(t)
M_i[list(range(1,t)), list(range(1,t))] = M_hat
M_mul = MDS_matrix_field_transpose * M_i
return M_i, v_collection, w_hat_collection, MDS_matrix_field_transpose[0, 0]
def calc_equivalent_constants(constants, MDS_matrix_field):
constants_temp = [constants[index:index+t] for index in range(0, len(constants), t)]
MDS_matrix_field_transpose = MDS_matrix_field.transpose()
# Start moving round constants up
# Calculate c_i' = M^(-1) * c_(i+1)
# Split c_i': Add c_i'[0] AFTER the S-box, add the rest to c_i
# I.e.: Store c_i'[0] for each of the partial rounds, and make c_i = c_i + c_i' (where now c_i'[0] = 0)
num_rounds = R_F_FIXED + R_P_FIXED
R_f = R_F_FIXED / 2
for i in range(num_rounds - 2 - R_f, R_f - 1, -1):
inv_cip1 = list(vector(constants_temp[i+1]) * MDS_matrix_field_transpose.inverse())
constants_temp[i] = list(vector(constants_temp[i]) + vector([0] + inv_cip1[1:]))
constants_temp[i+1] = [inv_cip1[0]] + [0] * (t-1)
return constants_temp
def poseidon(input_words, matrix, round_constants):
R_f = int(R_F_FIXED / 2)
round_constants_counter = 0
state_words = list(input_words)
# First full rounds
for r in range(0, R_f):
# Round constants, nonlinear layer, matrix multiplication
for i in range(0, t):
state_words[i] = state_words[i] + round_constants[round_constants_counter]
round_constants_counter += 1
for i in range(0, t):
state_words[i] = (state_words[i])^alpha
state_words = list(matrix * vector(state_words))
# Middle partial rounds
for r in range(0, R_P_FIXED):
# Round constants, nonlinear layer, matrix multiplication
for i in range(0, t):
state_words[i] = state_words[i] + round_constants[round_constants_counter]
round_constants_counter += 1
state_words[0] = (state_words[0])^alpha
state_words = list(matrix * vector(state_words))
# Last full rounds
for r in range(0, R_f):
# Round constants, nonlinear layer, matrix multiplication
for i in range(0, t):
state_words[i] = state_words[i] + round_constants[round_constants_counter]
round_constants_counter += 1
for i in range(0, t):
state_words[i] = (state_words[i])^alpha
state_words = list(matrix * vector(state_words))
return state_words
def poseidon2(input_words, matrix_full, matrix_partial, round_constants):
R_f = int(R_F_FIXED / 2)
round_constants_counter = 0
state_words = list(input_words)
# First matrix mul
state_words = list(matrix_full * vector(state_words))
# First full rounds
for r in range(0, R_f):
# Round constants, nonlinear layer, matrix multiplication
for i in range(0, t):
state_words[i] = state_words[i] + round_constants[round_constants_counter]
round_constants_counter += 1
for i in range(0, t):
state_words[i] = (state_words[i])^alpha
state_words = list(matrix_full * vector(state_words))
# Middle partial rounds
for r in range(0, R_P_FIXED):
# Round constants, nonlinear layer, matrix multiplication
for i in range(0, t):
state_words[i] = state_words[i] + round_constants[round_constants_counter]
round_constants_counter += 1
state_words[0] = (state_words[0])^alpha
state_words = list(matrix_partial * vector(state_words))
# Last full rounds
for r in range(0, R_f):
# Round constants, nonlinear layer, matrix multiplication
for i in range(0, t):
state_words[i] = state_words[i] + round_constants[round_constants_counter]
round_constants_counter += 1
for i in range(0, t):
state_words[i] = (state_words[i])^alpha
state_words = list(matrix_full * vector(state_words))
return state_words
# Init
init_generator(FIELD, SBOX, FIELD_SIZE, NUM_CELLS, R_F_FIXED, R_P_FIXED)
# Round constants
round_constants = generate_constants(FIELD, FIELD_SIZE, NUM_CELLS, R_F_FIXED, R_P_FIXED, PRIME_NUMBER)
# print_round_constants(round_constants, FIELD_SIZE, FIELD)
# Matrix
# MDS = generate_matrix(FIELD, FIELD_SIZE, NUM_CELLS)
MATRIX_FULL = generate_matrix_full(NUM_CELLS)
MATRIX_PARTIAL = generate_matrix_partial(FIELD, FIELD_SIZE, NUM_CELLS)
MATRIX_PARTIAL_DIAGONAL_M_1 = [matrix_partial_m_1(MATRIX_PARTIAL, NUM_CELLS)[i,i] for i in range(0, NUM_CELLS)]
def to_hex(value):
l = len(hex(p - 1))
if l % 2 == 1:
l = l + 1
value = hex(int(value))[2:]
value = "0x" + value.zfill(l - 2)
print("from_hex(\"{}\"),".format(value))
print("use super::poseidon::PoseidonParams;")
print("use bellman_ce::pairing::{bls12_381::Bls12, ff::ScalarEngine, from_hex};")
print("type Scalar = <Bls12 as ScalarEngine>::Fr;")
print("use lazy_static::lazy_static;")
print("use std::sync::Arc;")
print()
print("lazy_static! {")
# # MDS
# print("pub static ref MDS{}: Vec<Vec<Scalar>> = vec![".format(t))
# for vec in MDS:
# print("vec![", end="")
# for val in vec:
# to_hex(val)
# print("],")
# print("];")
# print()
# Efficient partial matrix (diagonal - 1)
print("pub static ref MAT_DIAG{}_M_1: Vec<Scalar> = vec![".format(t))
for val in MATRIX_PARTIAL_DIAGONAL_M_1:
to_hex(val)
print("];")
print()
# Efficient partial matrix (full)
print("pub static ref MAT_INTERNAL{}: Vec<Vec<Scalar>> = vec![".format(t))
for vec in MATRIX_PARTIAL:
print("vec![", end="")
for val in vec:
to_hex(val)
print("],")
print("];")
print()
# Round constants
print("pub static ref RC{}: Vec<Vec<Scalar>> = vec![".format(t))
for (i,val) in enumerate(round_constants):
if i % t == 0:
print("vec![", end="")
to_hex(val)
if i % t == t - 1:
print("],")
print("];")
print()
print("pub static ref POSEIDON_{}_PARAMS: Arc<PoseidonParams<Scalar>> = Arc::new(PoseidonParams::new({}, {}, {}, {}, &MAT_DIAG{}_M_1, &RC{}));".format(t, t, alpha, R_F_FIXED, R_P_FIXED , t, t))
print("}")
print()
print()
state_in = vector([F(i) for i in range(t)])
# state_out = poseidon(state_in, MDS, round_constants)
state_out = poseidon2(state_in, MATRIX_FULL, MATRIX_PARTIAL, round_constants)
for (i,val) in enumerate(state_in):
if i % t == 0:
print("vec![", end="")
to_hex(val)
if i % t == t - 1:
print("],")
print("];")
for (i,val) in enumerate(state_out):
if i % t == 0:
print("vec![", end="")
to_hex(val)
if i % t == t - 1:
print("],")
print("];")