# Copyright 2011 Sybren A. Stüvel <sybren@stuvel.eu>
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# https://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""Tests string operations."""
import struct
import sys
import unittest
import rsa
from rsa import pkcs1
class BinaryTest(unittest.TestCase):
def setUp(self):
(self.pub, self.priv) = rsa.newkeys(256)
def test_enc_dec(self):
message = struct.pack(">IIII", 0, 0, 0, 1)
print("\n\tMessage: %r" % message)
encrypted = pkcs1.encrypt(message, self.pub)
print("\tEncrypted: %r" % encrypted)
decrypted = pkcs1.decrypt(encrypted, self.priv)
print("\tDecrypted: %r" % decrypted)
self.assertEqual(message, decrypted)
def test_decoding_failure(self):
message = struct.pack(">IIII", 0, 0, 0, 1)
encrypted = pkcs1.encrypt(message, self.pub)
# Alter the encrypted stream
a = encrypted[5]
self.assertIsInstance(a, int)
altered_a = (a + 1) % 256
encrypted = encrypted[:5] + bytes([altered_a]) + encrypted[6:]
self.assertRaises(pkcs1.DecryptionError, pkcs1.decrypt, encrypted, self.priv)
def test_randomness(self):
"""Encrypting the same message twice should result in different
cryptos.
"""
message = struct.pack(">IIII", 0, 0, 0, 1)
encrypted1 = pkcs1.encrypt(message, self.pub)
encrypted2 = pkcs1.encrypt(message, self.pub)
self.assertNotEqual(encrypted1, encrypted2)
class ExtraZeroesTest(unittest.TestCase):
def setUp(self):
# Key, cyphertext, and plaintext taken from https://github.com/sybrenstuvel/python-rsa/issues/146
self.private_key = rsa.PrivateKey.load_pkcs1(
"-----BEGIN RSA PRIVATE KEY-----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\nXVJl32HuKYPJOMIWfc7hIfxLRHnCN+coz2M6tgqMDs0E/OfjuqVZ\n-----END RSA PRIVATE KEY-----",
format="PEM",
)
self.cyphertext = bytes.fromhex(
"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"
)
self.plaintext = bytes.fromhex("54657374")
def test_unmodified(self):
message = rsa.decrypt(self.cyphertext, self.private_key)
self.assertEqual(message, self.plaintext)
def test_prepend_zeroes(self):
cyphertext = bytes.fromhex("0000") + self.cyphertext
with self.assertRaises(rsa.DecryptionError):
rsa.decrypt(cyphertext, self.private_key)
def test_append_zeroes(self):
cyphertext = self.cyphertext + bytes.fromhex("0000")
with self.assertRaises(rsa.DecryptionError):
rsa.decrypt(cyphertext, self.private_key)
class SignatureTest(unittest.TestCase):
def setUp(self):
(self.pub, self.priv) = rsa.newkeys(512)
def test_sign_verify(self):
"""Test happy flow of sign and verify"""
message = b"je moeder"
signature = pkcs1.sign(message, self.priv, "SHA-256")
self.assertEqual("SHA-256", pkcs1.verify(message, signature, self.pub))
@unittest.skipIf(sys.version_info < (3, 6), "SHA3 requires Python 3.6+")
def test_sign_verify_sha3(self):
"""Test happy flow of sign and verify with SHA3-256"""
message = b"je moeder"
signature = pkcs1.sign(message, self.priv, "SHA3-256")
self.assertEqual("SHA3-256", pkcs1.verify(message, signature, self.pub))
def test_find_signature_hash(self):
"""Test happy flow of sign and find_signature_hash"""
message = b"je moeder"
signature = pkcs1.sign(message, self.priv, "SHA-256")
self.assertEqual("SHA-256", pkcs1.find_signature_hash(signature, self.pub))
def test_alter_message(self):
"""Altering the message should let the verification fail."""
signature = pkcs1.sign(b"je moeder", self.priv, "SHA-256")
self.assertRaises(
pkcs1.VerificationError, pkcs1.verify, b"mijn moeder", signature, self.pub
)
def test_sign_different_key(self):
"""Signing with another key should let the verification fail."""
(otherpub, _) = rsa.newkeys(512)
message = b"je moeder"
signature = pkcs1.sign(message, self.priv, "SHA-256")
self.assertRaises(pkcs1.VerificationError, pkcs1.verify, message, signature, otherpub)
def test_multiple_signings(self):
"""Signing the same message twice should return the same signatures."""
message = struct.pack(">IIII", 0, 0, 0, 1)
signature1 = pkcs1.sign(message, self.priv, "SHA-1")
signature2 = pkcs1.sign(message, self.priv, "SHA-1")
self.assertEqual(signature1, signature2)
def test_split_hash_sign(self):
"""Hashing and then signing should match with directly signing the message."""
message = b"je moeder"
msg_hash = pkcs1.compute_hash(message, "SHA-256")
signature1 = pkcs1.sign_hash(msg_hash, self.priv, "SHA-256")
# Calculate the signature using the unified method
signature2 = pkcs1.sign(message, self.priv, "SHA-256")
self.assertEqual(signature1, signature2)
def test_hash_sign_verify(self):
"""Test happy flow of hash, sign, and verify"""
message = b"je moeder"
msg_hash = pkcs1.compute_hash(message, "SHA-224")
signature = pkcs1.sign_hash(msg_hash, self.priv, "SHA-224")
self.assertTrue(pkcs1.verify(message, signature, self.pub))
def test_prepend_zeroes(self):
"""Prepending the signature with zeroes should be detected."""
message = b"je moeder"
signature = pkcs1.sign(message, self.priv, "SHA-256")
signature = bytes.fromhex("0000") + signature
with self.assertRaises(rsa.VerificationError):
pkcs1.verify(message, signature, self.pub)
def test_apppend_zeroes(self):
"""Apppending the signature with zeroes should be detected."""
message = b"je moeder"
signature = pkcs1.sign(message, self.priv, "SHA-256")
signature = signature + bytes.fromhex("0000")
with self.assertRaises(rsa.VerificationError):
pkcs1.verify(message, signature, self.pub)
class PaddingSizeTest(unittest.TestCase):
def test_too_little_padding(self):
"""Padding less than 8 bytes should be rejected."""
# Construct key that will be small enough to need only 7 bytes of padding.
# This key is 168 bit long, and was generated with rsa.newkeys(nbits=168).
self.private_key = rsa.PrivateKey.load_pkcs1(
b"""
-----BEGIN RSA PRIVATE KEY-----
MHkCAQACFgCIGbbNSkIRLtprxka9NgOf5UxgxCMCAwEAAQIVQqymO0gHubdEVS68
CdCiWmOJxVfRAgwBQM+e1JJwMKmxSF0CCmya6CFxO8Evdn8CDACMM3AlVC4FhlN8
3QIKC9cjoam/swMirwIMAR7Br9tdouoH7jAE
-----END RSA PRIVATE KEY-----
"""
)
self.public_key = rsa.PublicKey(n=self.private_key.n, e=self.private_key.e)
cyphertext = self.encrypt_with_short_padding(b"op je hoofd")
with self.assertRaises(rsa.DecryptionError):
rsa.decrypt(cyphertext, self.private_key)
def encrypt_with_short_padding(self, message: bytes) -> bytes:
# This is a copy of rsa.pkcs1.encrypt() adjusted to use the wrong padding length.
keylength = rsa.common.byte_size(self.public_key.n)
# The word 'padding' has 7 letters, so is one byte short of a valid padding length.
padded = b"\x00\x02padding\x00" + message
payload = rsa.transform.bytes2int(padded)
encrypted_value = rsa.core.encrypt_int(payload, self.public_key.e, self.public_key.n)
cyphertext = rsa.transform.int2bytes(encrypted_value, keylength)
return cyphertext