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rsa-aes-gen.py
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rsa-aes-gen.py
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#!/usr/bin/python3
import sys
import random
import getopt
import os
from threading import Thread, Event
from tlslite.x509 import X509
from tlslite.utils.cryptomath import divceil
from tlsfuzzer.utils.log import Log
from tlsfuzzer.utils.progress_report import progress_report
from tlslite.utils.python_aes import Python_AES
if sys.version_info < (3, 7):
print("This script is compatible with Python 3.7 and later only")
sys.exit(1)
def get_key(cert_file):
"""
Read an X.509 certificate, extract public key from it.
"""
with open(cert_file, "r") as f:
key_txt = f.read()
x509 = X509().parse(key_txt)
return x509.publicKey
class CiphertextGenerator(object):
"""
Class for generating different kinds of RSA plaintexts
"""
types = {}
def __init__(self, public_key, aes_size, tag):
self.pub_key = public_key
self.key_size = divceil(len(public_key), 8)
self.aes_size = aes_size
self.aes_key_size = 16
self.tag = tag
def encrypt_plaintext(self, plaintext):
"""
Performs raw RSA encryption on plaintext
"""
assert len(plaintext) == self.key_size, \
"Plaintext length ({0}) doesn't match key length ({1})".format(
len(plaintext), self.key_size)
msg = self.pub_key._rawPublicKeyOp(int.from_bytes(plaintext, "big"))
return int(msg).to_bytes(self.key_size, "big")
types["good_rsa_static_key_static_iv_good_pad_tag_present"] = 3
def good_rsa_static_key_static_iv_good_pad_tag_present(self, p_len, k_byte, iv_byte):
"""
Create valid RSA ciphertext with correct key, of repeated k_byte bytes.
Create valid AES ciphertext with specified padding length, iv of
repeated iv_byte bytes and tag present.
Padding length must be between 1 and 16 (inclusive) to be valid.
"""
aes_plaintext = random.randbytes(self.aes_size - len(self.tag) - p_len) +\
self.tag + bytes([p_len] * p_len)
assert len(aes_plaintext) == self.aes_size
aes_key = bytes([k_byte] * self.aes_key_size)
iv = bytes([iv_byte] * 16)
aes_ciphertext = Python_AES(aes_key, 2, iv).encrypt(aes_plaintext)
rsa_ciphertext = self.pub_key.encrypt(aes_key)
return rsa_ciphertext + iv + aes_ciphertext
types["good_rsa_static_key_static_iv_good_pad_tag_absent"] = 3
def good_rsa_static_key_static_iv_good_pad_tag_absent(self, p_len, k_byte, iv_byte):
"""
Create valid RSA ciphertext with correct key, of repeated k_byte bytes.
Create valid AES ciphertext with specified padding length, iv of
repeated iv_byte bytes and tag absent.
Padding length must be between 1 and 16 (inclusive) to be valid.
"""
aes_plaintext = random.randbytes(self.aes_size - p_len) +\
bytes([p_len] * p_len)
assert len(aes_plaintext) == self.aes_size
aes_key = bytes([k_byte] * self.aes_key_size)
iv = bytes([iv_byte] * 16)
aes_ciphertext = Python_AES(aes_key, 2, iv).encrypt(aes_plaintext)
rsa_ciphertext = self.pub_key.encrypt(aes_key)
return rsa_ciphertext + iv + aes_ciphertext
types["good_rsa_static_key_good_pad_tag_present"] = 2
def good_rsa_static_key_good_pad_tag_present(self, p_len, k_byte):
"""
Create valid RSA ciphertext with correct key, of repeated k_byte bytes.
Create valid AES ciphertext with specified padding length and tag
present.
Padding length must be between 1 and 16 (inclusive) to be valid.
"""
aes_plaintext = random.randbytes(self.aes_size - len(self.tag) - p_len) +\
self.tag + bytes([p_len] * p_len)
assert len(aes_plaintext) == self.aes_size
aes_key = bytes([k_byte] * self.aes_key_size)
iv = random.randbytes(16)
aes_ciphertext = Python_AES(aes_key, 2, iv).encrypt(aes_plaintext)
rsa_ciphertext = self.pub_key.encrypt(aes_key)
return rsa_ciphertext + iv + aes_ciphertext
types["good_rsa_static_key_good_pad_tag_absent"] = 2
def good_rsa_static_key_good_pad_tag_absent(self, p_len, k_byte):
"""
Create valid RSA ciphertext with correct key, of repeated k_byte bytes.
Create valid AES ciphertext with specified padding length and tag
absent.
Padding length must be between 1 and 16 (inclusive) to be valid.
"""
aes_plaintext = random.randbytes(self.aes_size - p_len) +\
bytes([p_len] * p_len)
assert len(aes_plaintext) == self.aes_size
aes_key = bytes([k_byte] * self.aes_key_size)
iv = random.randbytes(16)
aes_ciphertext = Python_AES(aes_key, 2, iv).encrypt(aes_plaintext)
rsa_ciphertext = self.pub_key.encrypt(aes_key)
return rsa_ciphertext + iv + aes_ciphertext
types["good_rsa_good_pad_tag_present"] = 1
def good_rsa_good_pad_tag_present(self, p_len):
"""
Create valid RSA ciphertext with correct key size.
Create valid AES ciphertext with specified padding length and
tag present.
Padding length must be between 1 and 16 (inclusive) to be valid.
"""
aes_plaintext = random.randbytes(self.aes_size - len(self.tag) - p_len) +\
self.tag + bytes([p_len] * p_len)
assert len(aes_plaintext) == self.aes_size
aes_key = random.randbytes(self.aes_key_size)
iv = random.randbytes(16)
aes_ciphertext = Python_AES(aes_key, 2, iv).encrypt(aes_plaintext)
rsa_ciphertext = self.pub_key.encrypt(aes_key)
return rsa_ciphertext + iv + aes_ciphertext
types["good_rsa_good_pad_tag_absent"] = 1
def good_rsa_good_pad_tag_absent(self, p_len):
"""
Create valid RSA ciphertext with correct key size.
Create valid AES ciphertext with specified padding length and
tag absent.
Padding length must be between 1 and 16 (inclusive) to be valid.
"""
aes_plaintext = random.randbytes(self.aes_size - p_len) +\
bytes([p_len] * p_len)
assert len(aes_plaintext) == self.aes_size
aes_key = random.randbytes(self.aes_key_size)
iv = random.randbytes(16)
aes_ciphertext = Python_AES(aes_key, 2, iv).encrypt(aes_plaintext)
rsa_ciphertext = self.pub_key.encrypt(aes_key)
return rsa_ciphertext + iv + aes_ciphertext
types["good_rsa_bad_pad_tag_present"] = 2
def good_rsa_bad_pad_tag_present(self, p_len, err_pos):
"""
Create valid RSA ciphertext with correct key size.
Create invalid AES ciphertext, with specified padding length
(p_len) and an invalid padding byte at err_pos from the end
(with last byte being identified as -1, second to last as -2, etc.).
Tag is present.
Padding length must be between 1 and 16 (inclusive) to be valid.
Error position must lie within pad.
"""
if -err_pos - 1 > p_len or err_pos >= 0:
raise ValueError("invalid error position")
pad = bytearray([p_len] * p_len)
pad[err_pos] = 0
aes_plaintext = random.randbytes(self.aes_size - len(self.tag) - p_len) \
+ self.tag + pad
assert len(aes_plaintext) == self.aes_size
aes_key = random.randbytes(self.aes_key_size)
iv = random.randbytes(16)
aes_ciphertext = Python_AES(aes_key, 2, iv).encrypt(aes_plaintext)
rsa_ciphertext = self.pub_key.encrypt(aes_key)
return rsa_ciphertext + iv + aes_ciphertext
types["good_rsa_bad_pad_tag_absent"] = 2
def good_rsa_bad_pad_tag_absent(self, p_len, err_pos):
"""
Create valid RSA ciphertext with correct key size.
Create invalid AES ciphertext, with specified padding length
(p_len) and an invalid padding byte at err_pos from the end
(with last byte being identified as -1, second to last as -2, etc.).
Tag is absent.
Padding length must be between 1 and 16 (inclusive) to be valid.
Error position must lie within pad.
"""
if -err_pos - 1 > p_len or err_pos >= 0:
raise ValueError("invalid error position")
pad = bytearray([p_len] * p_len)
pad[err_pos] = 0
aes_plaintext = random.randbytes(self.aes_size - p_len) \
+ pad
assert len(aes_plaintext) == self.aes_size
aes_key = random.randbytes(self.aes_key_size)
iv = random.randbytes(16)
aes_ciphertext = Python_AES(aes_key, 2, iv).encrypt(aes_plaintext)
rsa_ciphertext = self.pub_key.encrypt(aes_key)
return rsa_ciphertext + iv + aes_ciphertext
types["good_rsa_random_pad_tag_present"] = 0
def good_rsa_random_pad_tag_present(self):
"""
Create valid RSA ciphertext with correct key size.
Create invalid AES ciphertext, with random padding.
Tag is present (the tag is present at location specified by
last byte of padding, but padding is inconsistent).
"""
# one byte long pad can't be invalid, as then it wouldn't be
# one byte long...
pad_len = random.randint(2, 16)
pad = bytearray(random.randbytes(pad_len - 1))
pad += bytes([pad_len])
if pad[-2] == pad[-1]:
pad[-2] ^= 0xff
aes_plaintext = random.randbytes(self.aes_size - len(self.tag) - pad_len) \
+ self.tag + pad
assert len(aes_plaintext) == self.aes_size
aes_key = random.randbytes(self.aes_key_size)
iv = random.randbytes(16)
aes_ciphertext = Python_AES(aes_key, 2, iv).encrypt(aes_plaintext)
rsa_ciphertext = self.pub_key.encrypt(aes_key)
return rsa_ciphertext + iv + aes_ciphertext
types["good_rsa_random_pad_tag_absent"] = 0
def good_rsa_random_pad_tag_absent(self):
"""
Create valid RSA ciphertext with correct key size.
Create invalid AES ciphertext, with random padding.
Tag is absent.
"""
aes_plaintext = random.randbytes(self.aes_size)
assert len(aes_plaintext) == self.aes_size
aes_key = random.randbytes(self.aes_key_size)
iv = random.randbytes(16)
aes_ciphertext = Python_AES(aes_key, 2, iv).encrypt(aes_plaintext)
rsa_ciphertext = self.pub_key.encrypt(aes_key)
return rsa_ciphertext + iv + aes_ciphertext
types["wrong_size_rsa_random_aes"] = 1
def wrong_size_rsa_random_aes(self, k_size):
"""
Create valid RSA ciphertext, but with specified key size.
Create random AES ciphertext.
To be invalid the key size must be different than used AES size
(16 for AES-128, 32 for AES-256).
"""
aes_key = random.randbytes(k_size)
# since it will be processed with random, unpredictable key,
# the ciphertext will be effectively random anyway, so don't
# waste time on encrypting anything
aes_ciphertext = random.randbytes(self.aes_size + 16)
rsa_ciphertext = self.pub_key.encrypt(aes_key)
return rsa_ciphertext + aes_ciphertext
types["bad_rsa_random_aes"] = 0
def bad_rsa_random_aes(self):
"""
Create RSA ciphertext with invalid padding.
Create random AES ciphertext.
Creates a RSA plaintext that has incorrect header (doesn't start with
0x00 0x02) but has padding separator
"""
rsa_plaintext = [random.choice(range(1, 128)),
random.choice(range(3, 256))] + \
random.choices(range(1, 256),
k=self.key_size-2-1-self.aes_key_size) + \
[0] + \
random.choices(range(0, 256), k=self.aes_key_size)
rsa_ciphertext = self.encrypt_plaintext(rsa_plaintext)
aes_ciphertext = random.randbytes(self.aes_size + 16)
return rsa_ciphertext + aes_ciphertext
def help_msg():
print(
"""
{0} -c cert.pem [-o dir] ciphertext_name[="param1 param2"] [ciphertext_name]
Generate ciphertexts for testing combined RSA+AES-CBC decryption interface
against timing side-channel. Assumes use of implicit rejection through
generation of random AES key in case of PKCS#1 v1.5 padding error.
-c cert.pem Path to PEM-encoded X.509 certificate
-o dir Directory that will contain the generated ciphertexts.
"ciphertexts" by default.
-l num Length of AES ciphertext to generate (in bytes)
--tag=name Tag to place at the end of AES plaintext (utf-8 string)
--describe=name Describe the specified probe
--repeat=num Save the ciphertexts in random order in a single file
(ciphers.bin) in the specified directory together with a
file specifying the order (log.csv). Used for generating
input file for timing tests.
--force Don't abort when the output dir exists
--verbose Print status progress when generating repeated probes
--help This message
Supported probes:
{1}
""".format(sys.argv[0], "\n".join("{0}, args: {1}".format(
i, j) for i, j in CiphertextGenerator.types.items())))
def single_shot(out_dir, pub, args, aes_len, tag):
generator = CiphertextGenerator(pub, aes_len, tag)
for arg in args:
ret = arg.split('=')
if len(ret) == 1:
name = ret[0]
params = []
elif len(ret) == 2:
name, params = ret
ret = params.split(' ')
params = [int(i, 16) if i[:2] == '0x' else int(i) for i in ret]
else:
print("ERROR: Incorrect formatting of option: {0}".format(arg))
if len(params) != generator.types[name]:
print("ERROR: Incorrect number of parameters specified for probe "
"{0}, expected: {1}, got {2}".format(
name, generator.types[name], len(params)),
file=sys.stderr)
sys.exit(1)
ciphertext = getattr(generator, name)(*params)
file_name = "_".join([name] + [str(i) for i in params])
with open(os.path.join(out_dir, file_name), "wb") as out_file:
out_file.write(ciphertext)
def gen_timing_probes(out_dir, pub, args, repeat, aes_len, tag, verbose=False):
generator = CiphertextGenerator(pub, aes_len, tag)
probes = {}
probe_names = []
# parse the parameters
for arg in args:
ret = arg.split('=')
if len(ret) == 1:
name = ret[0]
params = []
elif len(ret) == 2:
name, params = ret
ret = params.split(' ')
params = [int(i, 16) if i[:2] == '0x' else int(i) for i in ret]
else:
print("ERROR: Incorrect formatting of option: {0}".format(arg))
if len(params) != generator.types[name]:
print("ERROR: Incorrect number of parameters specified for probe "
"{0}, expected: {1}, got {2}".format(
name, generator.types[name], len(params)),
file=sys.stderr)
sys.exit(1)
method = getattr(generator, name)
probe_name = "_".join([name] + [str(i) for i in params])
if probe_name in probes:
print("ERROR: duplicate probe name and/or parameters: {0}, {1}"
.format(name, params))
sys.exit(1)
probes[probe_name] = (method, params)
probe_names.append(probe_name)
# create an order in which we will write the ciphertexts in
log = Log(os.path.join(out_dir, "log.csv"))
log.start_log(probes.keys())
for _ in range(repeat):
log.shuffle_new_run()
log.write()
# reset the log position
log.read_log()
try:
# start progress reporting
status = [0, len(probe_names) * repeat, Event()]
if verbose:
kwargs = {}
kwargs['unit'] = ' ciphertext'
kwargs['delay'] = 2
progress = Thread(target=progress_report, args=(status,),
kwargs=kwargs)
progress.start()
with open(os.path.join(out_dir, "ciphers.bin"), "wb") as out:
# start the ciphertext generation
for executed, index in enumerate(log.iterate_log()):
status[0] = executed
p_name = probe_names[index]
p_method, p_params = probes[p_name]
ciphertext = p_method(*p_params)
out.write(ciphertext)
finally:
if verbose:
status[2].set()
progress.join()
print()
print("done")
if __name__ == '__main__':
cert = None
out_dir = "ciphertexts"
repeat = None
force_dir = False
verbose = False
aes_len = None
tag = None
argv = sys.argv[1:]
opts, args = getopt.getopt(argv, "c:o:l:", ["help", "describe=", "repeat=",
"force", "verbose", "tag="])
for opt, arg in opts:
if opt == "-c":
cert = arg
elif opt == "-o":
out_dir = arg
elif opt == "-l":
aes_len = int(arg)
elif opt == "--tag":
tag = bytes(arg, "utf-8")
elif opt == "--help":
help_msg()
sys.exit(0)
elif opt == "--force":
force_dir = True
elif opt == "--repeat":
repeat = int(arg)
elif opt == "--verbose":
verbose = True
elif opt == "--describe":
try:
fun = getattr(CiphertextGenerator, arg)
except Exception:
help_msg()
raise ValueError("No ciphertext named {0}".format(arg))
print("{0}:".format(arg))
print(fun.__doc__)
sys.exit(0)
else:
raise ValueError("Unrecognised option: {0}".format(opt))
if not args:
print("ERROR: No ciphertexts specified", file=sys.stderr)
sys.exit(1)
if not cert:
print("ERROR: No certificate specified", file=sys.stderr)
sys.exit(1)
if aes_len is None:
print("ERROR: no AES ciphertext length specified", file=sys.stderr)
sys.exit(1)
if tag is None:
print("ERROR: no tag to place in AES plaintext specified",
file=sys.stderr)
sys.exit(1)
if aes_len % 16:
print("WARNING: AES plaintext must by a multiple of AES block"
"size (16 bytes)", file=sys.stderr)
if repeat is not None and repeat <= 0:
print("ERROR: repeat must be a positive integer", file=sys.stder)
sys.exit(1)
pub = get_key(cert)
print("working with {0}bit key".format(len(pub)))
print("Will save ciphertexts to {0}".format(out_dir))
try:
os.mkdir(out_dir)
except FileExistsError:
if force_dir:
pass
else:
raise
if repeat is None:
single_shot(out_dir, pub, args, aes_len, tag)
else:
gen_timing_probes(out_dir, pub, args, repeat, aes_len, tag, verbose)