OFFICIAL COMMENT: KAZ-SIGN
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D. J. Bernstein
Jul 17, 2023, 1:09:05 PM7/17/23
to pqc-co...@nist.gov, pqc-...@list.nist.gov
Running the Sage script below in the
KAZ-SIGN/Reference_Implementation/kaz458 directory rapidly forges a
signature on any desired message under essentially any desired public
key, and checks that the signature passes verification with the
reference crypto_sign_open() software.
The script uses a particular message and the first public key in *.rsp
as an example, but I've also tested it with another random public key
and with various further messages. The reason I'm saying "essentially"
is that the KAZ-SIGN integer encoding looks like it will fail for 1/256
of all possible inputs; the reference software doesn't seem to handle
this, and this Sage script also doesn't handle this.
---D. J. Bernstein
#!/usr/bin/env sage
import os
import subprocess
import ctypes
from ctypes import c_int,c_char_p,c_ulonglong,POINTER,byref,create_string_buffer
import hashlib
import random
def hash(seed): h = hashlib.sha256(); h.update(seed); return h.digest()
proof.all(False)
# ----- copied from kaz_api.h
N = 374708747338379194165632113267540799893248494638181758681727134968599684366339106336802166494168058067745412894332797884687187786349732565
PHIN = 71467427390759841729059757466289459181369050713019533645557376916391119997637068708795979336636964345506399166398464000000000000000000000
G = 372600253421538779763660224316312740003230140106999999701117618759644181266325498418931548345929963501344215735624839833056513259148603733
ORDERG = 144070022526464542998162540305862391968000
PHIORDERG = 17966317053413597259085197820821504000000
R = 64411872697932469627298024328629501373966883091743836804603337113399879222101827567038858750269057628226431053470498775743682787912336229
ORDERR = 88155085186093475727706287744104857499274763088175719465155518774692526733036565299200000000000000000000
ALPHABYTES = 18
VBYTES = 59
S1BYTES = 19
S2BYTES = 58
SALTBYTES = 4
# ----- public information copied from *.rsp
mlen = 32
msg = 'D81C4D8D734FCBFBEADE3D3F8A039FAA2A2C9957E835AD55B22E75BF57BB556A'
pk = '2020C105E4CE23ABB476713D7805654CF78802EF11CA4B6903B0407FE23897F33CD4B41A4A15AF68E7BCD6B486920E5D6E42E5C3E86ECF6FF57F49'
sm = '20019D011CE55E5F96EACC650084407061DC0520085CB9DACF314194F1F254D8EAF6D815D5D7B9D82FDD0D0AE1C63F4B9C0FA19DE06D640FFF775FA8DAB052D8576CB53AB7DEF64C26E038B6C2D81C4D8D734FCBFBEADE3D3F8A039FAA2A2C9957E835AD55B22E75BF57BB556A7C9935A0'
# ----- miscellaneous tests
assert PHIN == euler_phi(N)
assert ORDERG == Mod(G,N).multiplicative_order()
assert ORDERR == Mod(R,PHIN).multiplicative_order()
msg = bytes.fromhex(msg)
pk = bytes.fromhex(pk)
sm = bytes.fromhex(sm)
def decode(b):
b = bytearray(b)
while b[:1] == b' ': b = b[1:]
return sum(c<<(8*i) for i,c in enumerate(reversed(b)))
def encode(i,targetbytes):
result = bytearray()
while i > 0:
result = bytearray([i%256])+result
i >>= 8
while len(result) < targetbytes:
result = bytearray([32])+result
assert len(result) == targetbytes
return bytes(result)
assert decode(encode(31415,5)) == 31415
def open(sm,pk):
s1,sm = sm[:S1BYTES],sm[S1BYTES:]
s2,sm = sm[:S2BYTES],sm[S2BYTES:]
m,salt = sm[:-SALTBYTES],sm[-SALTBYTES:]
assert len(s1) == S1BYTES
assert len(s2) == S2BYTES
assert len(salt) == SALTBYTES
h = hash(m+salt+m+salt)
pk,s1,s2,h = map(decode,(pk,s1,s2,h))
assert Mod(G,N)^(Mod(s1,PHIN)^s2) == Mod(pk,N)^(Mod(R,PHIN)^h)
return m
subprocess.run('gcc -shared -o libkaz.so kaz_api.c sign.c rng.c sha256.c -fPIC -lcrypto -lgmp',shell=True)
libkaz = ctypes.CDLL(f'{os.getcwd()}/libkaz.so')
libkaz_open = libkaz.crypto_sign_open
libkaz_open.argtypes = c_char_p,POINTER(c_ulonglong),c_char_p,c_ulonglong,c_char_p
libkaz_open.restype = c_int
def reference_open(sm,pk):
smlen = c_ulonglong(len(sm))
m = create_string_buffer(len(sm))
mlen = c_ulonglong(0)
pk = create_string_buffer(pk)
assert libkaz_open(m,byref(mlen),sm,smlen,pk) == 0
return m.raw[:mlen.value]
assert open(sm,pk) == msg
assert reference_open(sm,pk) == msg
assert reference_open(sm,pk) == msg
phiphin = euler_phi(PHIN)
realRorder = Mod(R,ORDERG).multiplicative_order()
def forge(m,pk):
salt = os.urandom(SALTBYTES)
h = hash(m+salt+m+salt)
pk = decode(pk)
h = decode(h)
r = random.randrange(2**256)
while not Mod(r,ORDERG).is_unit(): r += 1
s1 = ZZ(Mod(R,ORDERG)^r)
loggV = Mod(pk,N).log(Mod(G,N))
assert Mod(G,N)^loggV == Mod(pk,N)
alpha = Mod(loggV,ORDERG).log(Mod(R,ORDERG))
alpha += realRorder*random.randrange(2**256)
assert Mod(R,ORDERG)^alpha == Mod(loggV,ORDERG)
s2 = ZZ(Mod(alpha+h,ORDERG)/r)
s2 += ORDERG*random.randrange(2**256)
s2 %= phiphin
assert Mod(G,N)^(Mod(s1,PHIN)^s2) == Mod(pk,N)^(Mod(R,PHIN)^h)
return encode(s1,S1BYTES)+encode(s2,S2BYTES)+m+salt
newmsg = b'forged message'
while True:
sm = forge(newmsg,pk)
try:
assert newmsg == open(sm,pk)
assert newmsg == reference_open(sm,pk)
break
except:
pass
assert newmsg == open(sm,pk)
assert newmsg == reference_open(sm,pk)
print(f'newmsg: {newmsg}')
print(f'sm: {sm.hex()}')
KAZ-SIGN/Reference_Implementation/kaz458 directory rapidly forges a
signature on any desired message under essentially any desired public
key, and checks that the signature passes verification with the
reference crypto_sign_open() software.
The script uses a particular message and the first public key in *.rsp
as an example, but I've also tested it with another random public key
and with various further messages. The reason I'm saying "essentially"
is that the KAZ-SIGN integer encoding looks like it will fail for 1/256
of all possible inputs; the reference software doesn't seem to handle
this, and this Sage script also doesn't handle this.
---D. J. Bernstein
#!/usr/bin/env sage
import os
import subprocess
import ctypes
from ctypes import c_int,c_char_p,c_ulonglong,POINTER,byref,create_string_buffer
import hashlib
import random
def hash(seed): h = hashlib.sha256(); h.update(seed); return h.digest()
proof.all(False)
# ----- copied from kaz_api.h
N = 374708747338379194165632113267540799893248494638181758681727134968599684366339106336802166494168058067745412894332797884687187786349732565
PHIN = 71467427390759841729059757466289459181369050713019533645557376916391119997637068708795979336636964345506399166398464000000000000000000000
G = 372600253421538779763660224316312740003230140106999999701117618759644181266325498418931548345929963501344215735624839833056513259148603733
ORDERG = 144070022526464542998162540305862391968000
PHIORDERG = 17966317053413597259085197820821504000000
R = 64411872697932469627298024328629501373966883091743836804603337113399879222101827567038858750269057628226431053470498775743682787912336229
ORDERR = 88155085186093475727706287744104857499274763088175719465155518774692526733036565299200000000000000000000
ALPHABYTES = 18
VBYTES = 59
S1BYTES = 19
S2BYTES = 58
SALTBYTES = 4
# ----- public information copied from *.rsp
mlen = 32
msg = 'D81C4D8D734FCBFBEADE3D3F8A039FAA2A2C9957E835AD55B22E75BF57BB556A'
pk = '2020C105E4CE23ABB476713D7805654CF78802EF11CA4B6903B0407FE23897F33CD4B41A4A15AF68E7BCD6B486920E5D6E42E5C3E86ECF6FF57F49'
sm = '20019D011CE55E5F96EACC650084407061DC0520085CB9DACF314194F1F254D8EAF6D815D5D7B9D82FDD0D0AE1C63F4B9C0FA19DE06D640FFF775FA8DAB052D8576CB53AB7DEF64C26E038B6C2D81C4D8D734FCBFBEADE3D3F8A039FAA2A2C9957E835AD55B22E75BF57BB556A7C9935A0'
# ----- miscellaneous tests
assert PHIN == euler_phi(N)
assert ORDERG == Mod(G,N).multiplicative_order()
assert ORDERR == Mod(R,PHIN).multiplicative_order()
msg = bytes.fromhex(msg)
pk = bytes.fromhex(pk)
sm = bytes.fromhex(sm)
def decode(b):
b = bytearray(b)
while b[:1] == b' ': b = b[1:]
return sum(c<<(8*i) for i,c in enumerate(reversed(b)))
def encode(i,targetbytes):
result = bytearray()
while i > 0:
result = bytearray([i%256])+result
i >>= 8
while len(result) < targetbytes:
result = bytearray([32])+result
assert len(result) == targetbytes
return bytes(result)
assert decode(encode(31415,5)) == 31415
def open(sm,pk):
s1,sm = sm[:S1BYTES],sm[S1BYTES:]
s2,sm = sm[:S2BYTES],sm[S2BYTES:]
m,salt = sm[:-SALTBYTES],sm[-SALTBYTES:]
assert len(s1) == S1BYTES
assert len(s2) == S2BYTES
assert len(salt) == SALTBYTES
h = hash(m+salt+m+salt)
pk,s1,s2,h = map(decode,(pk,s1,s2,h))
assert Mod(G,N)^(Mod(s1,PHIN)^s2) == Mod(pk,N)^(Mod(R,PHIN)^h)
return m
subprocess.run('gcc -shared -o libkaz.so kaz_api.c sign.c rng.c sha256.c -fPIC -lcrypto -lgmp',shell=True)
libkaz = ctypes.CDLL(f'{os.getcwd()}/libkaz.so')
libkaz_open = libkaz.crypto_sign_open
libkaz_open.argtypes = c_char_p,POINTER(c_ulonglong),c_char_p,c_ulonglong,c_char_p
libkaz_open.restype = c_int
def reference_open(sm,pk):
smlen = c_ulonglong(len(sm))
m = create_string_buffer(len(sm))
mlen = c_ulonglong(0)
pk = create_string_buffer(pk)
assert libkaz_open(m,byref(mlen),sm,smlen,pk) == 0
return m.raw[:mlen.value]
assert open(sm,pk) == msg
assert reference_open(sm,pk) == msg
assert reference_open(sm,pk) == msg
phiphin = euler_phi(PHIN)
realRorder = Mod(R,ORDERG).multiplicative_order()
def forge(m,pk):
salt = os.urandom(SALTBYTES)
h = hash(m+salt+m+salt)
pk = decode(pk)
h = decode(h)
r = random.randrange(2**256)
while not Mod(r,ORDERG).is_unit(): r += 1
s1 = ZZ(Mod(R,ORDERG)^r)
loggV = Mod(pk,N).log(Mod(G,N))
assert Mod(G,N)^loggV == Mod(pk,N)
alpha = Mod(loggV,ORDERG).log(Mod(R,ORDERG))
alpha += realRorder*random.randrange(2**256)
assert Mod(R,ORDERG)^alpha == Mod(loggV,ORDERG)
s2 = ZZ(Mod(alpha+h,ORDERG)/r)
s2 += ORDERG*random.randrange(2**256)
s2 %= phiphin
assert Mod(G,N)^(Mod(s1,PHIN)^s2) == Mod(pk,N)^(Mod(R,PHIN)^h)
return encode(s1,S1BYTES)+encode(s2,S2BYTES)+m+salt
newmsg = b'forged message'
while True:
sm = forge(newmsg,pk)
try:
assert newmsg == open(sm,pk)
assert newmsg == reference_open(sm,pk)
break
except:
pass
assert newmsg == open(sm,pk)
assert newmsg == reference_open(sm,pk)
print(f'newmsg: {newmsg}')
print(f'sm: {sm.hex()}')
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