def add_keys3(dst, a, A, b, B):
dst = _ensure_dst_key(dst)
crypto.decodeint_into_noreduce(tmp_sc_1, a)
crypto.decodeint_into_noreduce(tmp_sc_2, b)
crypto.decodepoint_into(tmp_pt_1, A)
crypto.decodepoint_into(tmp_pt_2, B)
crypto.add_keys3_into(tmp_pt_3, tmp_sc_1, tmp_pt_1, tmp_sc_2, tmp_pt_2)
crypto.encodepoint_into(dst, tmp_pt_3)
return dst
def vector_exponent_custom(A, B, a, b, dst=None):
dst = _ensure_dst_key(dst)
crypto.identity_into(tmp_pt_2)
for i in range(len(a)):
crypto.decodeint_into_noreduce(tmp_sc_1, a.to(i))
crypto.decodepoint_into(tmp_pt_3, A.to(i))
crypto.decodeint_into_noreduce(tmp_sc_2, b.to(i))
crypto.decodepoint_into(tmp_pt_4, B.to(i))
crypto.add_keys3_into(tmp_pt_1, tmp_sc_1, tmp_pt_3, tmp_sc_2, tmp_pt_4)
crypto.point_add_into(tmp_pt_2, tmp_pt_2, tmp_pt_1)
gc_iter(i)
crypto.encodepoint_into(dst, tmp_pt_2)
return dst
def hadamard_fold(v, a, b, into=None, into_offset=0):
"""
Folds a curvepoint array using a two way scaled Hadamard product
ln = len(v); h = ln // 2
v[i] = a * v[i] + b * v[h + i]
"""
h = len(v) // 2
crypto.decodeint_into_noreduce(tmp_sc_1, a)
crypto.decodeint_into_noreduce(tmp_sc_2, b)
into = into if into else v
for i in range(h):
crypto.decodepoint_into(tmp_pt_1, v.to(i))
crypto.decodepoint_into(tmp_pt_2, v.to(h + i))
crypto.add_keys3_into(tmp_pt_3, tmp_sc_1, tmp_pt_1, tmp_sc_2, tmp_pt_2)
crypto.encodepoint_into(tmp_bf_0, tmp_pt_3)
into.read(i + into_offset, tmp_bf_0)
gc_iter(i)
return into
def _generate_clsag(
message: bytes,
P: List[bytes],
p: Sc25519,
C_nonzero: List[bytes],
z: Sc25519,
Cout: Ge25519,
index: int,
mg_buff: List[bytes],
) -> List[bytes]:
sI = crypto.new_point() # sig.I
sD = crypto.new_point() # sig.D
sc1 = crypto.new_scalar() # sig.c1
a = crypto.random_scalar()
H = crypto.new_point()
D = crypto.new_point()
Cout_bf = crypto.encodepoint(Cout)
tmp_sc = crypto.new_scalar()
tmp = crypto.new_point()
tmp_bf = bytearray(32)
crypto.hash_to_point_into(H, P[index])
crypto.scalarmult_into(sI, H, p) # I = p*H
crypto.scalarmult_into(D, H, z) # D = z*H
crypto.sc_mul_into(tmp_sc, z, crypto.sc_inv_eight()) # 1/8*z
crypto.scalarmult_into(sD, H, tmp_sc) # sig.D = 1/8*z*H
sD = crypto.encodepoint(sD)
hsh_P = crypto.get_keccak() # domain, I, D, P, C, C_offset
hsh_C = crypto.get_keccak() # domain, I, D, P, C, C_offset
hsh_P.update(_HASH_KEY_CLSAG_AGG_0)
hsh_C.update(_HASH_KEY_CLSAG_AGG_1)
def hsh_PC(x):
nonlocal hsh_P, hsh_C
hsh_P.update(x)
hsh_C.update(x)
for x in P:
hsh_PC(x)
for x in C_nonzero:
hsh_PC(x)
hsh_PC(crypto.encodepoint_into(tmp_bf, sI))
hsh_PC(sD)
hsh_PC(Cout_bf)
mu_P = crypto.decodeint(hsh_P.digest())
mu_C = crypto.decodeint(hsh_C.digest())
del (hsh_PC, hsh_P, hsh_C)
c_to_hash = crypto.get_keccak() # domain, P, C, C_offset, message, aG, aH
c_to_hash.update(_HASH_KEY_CLSAG_ROUND)
for i in range(len(P)):
c_to_hash.update(P[i])
for i in range(len(P)):
c_to_hash.update(C_nonzero[i])
c_to_hash.update(Cout_bf)
c_to_hash.update(message)
chasher = c_to_hash.copy()
crypto.scalarmult_base_into(tmp, a)
chasher.update(crypto.encodepoint_into(tmp_bf, tmp)) # aG
crypto.scalarmult_into(tmp, H, a)
chasher.update(crypto.encodepoint_into(tmp_bf, tmp)) # aH
c = crypto.decodeint(chasher.digest())
del (chasher, H)
L = crypto.new_point()
R = crypto.new_point()
c_p = crypto.new_scalar()
c_c = crypto.new_scalar()
i = (index + 1) % len(P)
if i == 0:
crypto.sc_copy(sc1, c)
mg_buff.append(int_serialize.dump_uvarint_b(len(P)))
for _ in range(len(P)):
mg_buff.append(bytearray(32))
while i != index:
crypto.random_scalar(tmp_sc)
crypto.encodeint_into(mg_buff[i + 1], tmp_sc)
crypto.sc_mul_into(c_p, mu_P, c)
crypto.sc_mul_into(c_c, mu_C, c)
# L = tmp_sc * G + c_P * P[i] + c_c * C[i]
crypto.add_keys2_into(L, tmp_sc, c_p,
crypto.decodepoint_into(tmp, P[i]))
crypto.decodepoint_into(tmp, C_nonzero[i]) # C = C_nonzero - Cout
crypto.point_sub_into(tmp, tmp, Cout)
crypto.scalarmult_into(tmp, tmp, c_c)
crypto.point_add_into(L, L, tmp)
# R = tmp_sc * HP + c_p * I + c_c * D
crypto.hash_to_point_into(tmp, P[i])
crypto.add_keys3_into(R, tmp_sc, tmp, c_p, sI)
crypto.point_add_into(R, R, crypto.scalarmult_into(tmp, D, c_c))
chasher = c_to_hash.copy()
chasher.update(crypto.encodepoint_into(tmp_bf, L))
chasher.update(crypto.encodepoint_into(tmp_bf, R))
crypto.decodeint_into(c, chasher.digest())
P[i] = None
C_nonzero[i] = None
i = (i + 1) % len(P)
if i == 0:
crypto.sc_copy(sc1, c)
if i & 3 == 0:
gc.collect()
# Final scalar = a - c * (mu_P * p + mu_c * Z)
crypto.sc_mul_into(tmp_sc, mu_P, p)
crypto.sc_muladd_into(tmp_sc, mu_C, z, tmp_sc)
crypto.sc_mulsub_into(tmp_sc, c, tmp_sc, a)
crypto.encodeint_into(mg_buff[index + 1], tmp_sc)
mg_buff.append(crypto.encodeint(sc1))
mg_buff.append(sD)
return mg_buff
def generate_mlsag(
message: bytes,
pk: KeyM,
xx: List[Sc25519],
index: int,
dsRows: int,
mg_buff: List[bytes],
) -> List[bytes]:
"""
Multilayered Spontaneous Anonymous Group Signatures (MLSAG signatures)
:param message: the full message to be signed (actually its hash)
:param pk: matrix of public keys and commitments
:param xx: input secret array composed of a private key and commitment mask
:param index: specifies corresponding public key to the `xx`'s private key in the `pk` array
:param dsRows: separates pubkeys from commitment
:param mg_buff: mg signature buffer
"""
rows, cols = gen_mlsag_assert(pk, xx, index, dsRows)
rows_b_size = int_serialize.uvarint_size(rows)
# Preallocation of the chunked buffer, len + cols + cc
for _ in range(1 + cols + 1):
mg_buff.append(None)
mg_buff[0] = int_serialize.dump_uvarint_b(cols)
cc = crypto.new_scalar() # rv.cc
c = crypto.new_scalar()
L = crypto.new_point()
R = crypto.new_point()
Hi = crypto.new_point()
# calculates the "first" c, key images and random scalars alpha
c_old, II, alpha = generate_first_c_and_key_images(message, pk, xx, index,
dsRows, rows, cols)
i = (index + 1) % cols
if i == 0:
crypto.sc_copy(cc, c_old)
ss = [crypto.new_scalar() for _ in range(rows)]
tmp_buff = bytearray(32)
while i != index:
hasher = _hasher_message(message)
# Serialize size of the row
mg_buff[i + 1] = bytearray(rows_b_size + 32 * rows)
int_serialize.dump_uvarint_b_into(rows, mg_buff[i + 1])
for x in ss:
crypto.random_scalar(x)
for j in range(dsRows):
# L = rv.ss[i][j] * G + c_old * pk[i][j]
crypto.add_keys2_into(L, ss[j], c_old,
crypto.decodepoint_into(Hi, pk[i][j]))
crypto.hash_to_point_into(Hi, pk[i][j])
# R = rv.ss[i][j] * H(pk[i][j]) + c_old * Ip[j]
crypto.add_keys3_into(R, ss[j], Hi, c_old, II[j])
hasher.update(pk[i][j])
_hash_point(hasher, L, tmp_buff)
_hash_point(hasher, R, tmp_buff)
for j in range(dsRows, rows):
# again, omitting R here as discussed above
crypto.add_keys2_into(L, ss[j], c_old,
crypto.decodepoint_into(Hi, pk[i][j]))
hasher.update(pk[i][j])
_hash_point(hasher, L, tmp_buff)
for si in range(rows):
crypto.encodeint_into(mg_buff[i + 1], ss[si],
rows_b_size + 32 * si)
crypto.decodeint_into(c, hasher.digest())
crypto.sc_copy(c_old, c)
pk[i] = None
i = (i + 1) % cols
if i == 0:
crypto.sc_copy(cc, c_old)
gc.collect()
del II
# Finalizing rv.ss by processing rv.ss[index]
mg_buff[index + 1] = bytearray(rows_b_size + 32 * rows)
int_serialize.dump_uvarint_b_into(rows, mg_buff[index + 1])
for j in range(rows):
crypto.sc_mulsub_into(ss[j], c, xx[j], alpha[j])
crypto.encodeint_into(mg_buff[index + 1], ss[j], rows_b_size + 32 * j)
# rv.cc
mg_buff[-1] = crypto.encodeint(cc)
return mg_buff
def verify_clsag(self, msg, ss, sc1, sI, sD, pubs, C_offset):
n = len(pubs)
c = crypto.Scalar()
D_8 = crypto.Point()
tmp_bf = bytearray(32)
C_offset_bf = crypto_helpers.encodepoint(C_offset)
crypto.sc_copy(c, sc1)
point_mul8_into(D_8, sD)
hsh_P = crypto_helpers.get_keccak() # domain, I, D, P, C, C_offset
hsh_C = crypto_helpers.get_keccak() # domain, I, D, P, C, C_offset
hsh_P.update(clsag._HASH_KEY_CLSAG_AGG_0)
hsh_C.update(clsag._HASH_KEY_CLSAG_AGG_1)
def hsh_PC(x):
hsh_P.update(x)
hsh_C.update(x)
for x in pubs:
hsh_PC(x.dest)
for x in pubs:
hsh_PC(x.commitment)
hsh_PC(crypto.encodepoint_into(tmp_bf, sI))
hsh_PC(crypto.encodepoint_into(tmp_bf, sD))
hsh_PC(C_offset_bf)
mu_P = crypto_helpers.decodeint(hsh_P.digest())
mu_C = crypto_helpers.decodeint(hsh_C.digest())
c_to_hash = crypto_helpers.get_keccak(
) # domain, P, C, C_offset, message, L, R
c_to_hash.update(clsag._HASH_KEY_CLSAG_ROUND)
for i in range(len(pubs)):
c_to_hash.update(pubs[i].dest)
for i in range(len(pubs)):
c_to_hash.update(pubs[i].commitment)
c_to_hash.update(C_offset_bf)
c_to_hash.update(msg)
c_p = crypto.Scalar()
c_c = crypto.Scalar()
L = crypto.Point()
R = crypto.Point()
tmp_pt = crypto.Point()
i = 0
while i < n:
crypto.sc_mul_into(c_p, mu_P, c)
crypto.sc_mul_into(c_c, mu_C, c)
C_P = crypto.point_sub_into(
None, crypto.decodepoint_into(tmp_pt, pubs[i].commitment),
C_offset)
crypto.add_keys2_into(
L, ss[i], c_p, crypto.decodepoint_into(tmp_pt, pubs[i].dest))
crypto.point_add_into(L, L,
crypto.scalarmult_into(tmp_pt, C_P, c_c))
HP = crypto.hash_to_point_into(None, pubs[i].dest)
crypto.add_keys3_into(R, ss[i], HP, c_p, sI)
crypto.point_add_into(R, R,
crypto.scalarmult_into(tmp_pt, D_8, c_c))
chasher = c_to_hash.copy()
chasher.update(crypto.encodepoint_into(tmp_bf, L))
chasher.update(crypto.encodepoint_into(tmp_bf, R))
crypto.decodeint_into(c, chasher.digest())
i += 1
res = crypto.sc_sub_into(None, c, sc1)
if not crypto.sc_eq(res, crypto.Scalar(0)):
raise ValueError("Signature error")
def generate_ring_signature(
prefix_hash: bytes,
image: crypto.Point,
pubs: list[crypto.Point],
sec: crypto.Scalar,
sec_idx: int,
test: bool = False,
) -> Sig:
"""
Generates ring signature with key image.
void crypto_ops::generate_ring_signature()
"""
from trezor.utils import memcpy
if test:
t = crypto.scalarmult_base_into(None, sec)
if not crypto.point_eq(t, pubs[sec_idx]):
raise ValueError("Invalid sec key")
k_i = monero.generate_key_image(
crypto_helpers.encodepoint(pubs[sec_idx]), sec)
if not crypto.point_eq(k_i, image):
raise ValueError("Key image invalid")
for k in pubs:
crypto.ge25519_check(k)
buff_off = len(prefix_hash)
buff = bytearray(buff_off + 2 * 32 * len(pubs))
memcpy(buff, 0, prefix_hash, 0, buff_off)
mvbuff = memoryview(buff)
sum = crypto.Scalar(0)
k = crypto.Scalar(0)
sig = []
for _ in range(len(pubs)):
sig.append([crypto.Scalar(0), crypto.Scalar(0)]) # c, r
for i in range(len(pubs)):
if i == sec_idx:
k = crypto.random_scalar()
tmp3 = crypto.scalarmult_base_into(None, k)
crypto.encodepoint_into(mvbuff[buff_off:buff_off + 32], tmp3)
buff_off += 32
tmp3 = crypto.hash_to_point_into(
None, crypto_helpers.encodepoint(pubs[i]))
tmp2 = crypto.scalarmult_into(None, tmp3, k)
crypto.encodepoint_into(mvbuff[buff_off:buff_off + 32], tmp2)
buff_off += 32
else:
sig[i] = [crypto.random_scalar(), crypto.random_scalar()]
tmp3 = pubs[i]
tmp2 = crypto.ge25519_double_scalarmult_vartime_into(
None, tmp3, sig[i][0], sig[i][1])
crypto.encodepoint_into(mvbuff[buff_off:buff_off + 32], tmp2)
buff_off += 32
tmp3 = crypto.hash_to_point_into(None,
crypto_helpers.encodepoint(tmp3))
tmp2 = crypto.add_keys3_into(None, sig[i][1], tmp3, sig[i][0],
image)
crypto.encodepoint_into(mvbuff[buff_off:buff_off + 32], tmp2)
buff_off += 32
crypto.sc_add_into(sum, sum, sig[i][0])
h = crypto.hash_to_scalar_into(None, buff)
sig[sec_idx][0] = crypto.sc_sub_into(None, h, sum)
sig[sec_idx][1] = crypto.sc_mulsub_into(None, sig[sec_idx][0], sec, k)
return sig
