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Direktori : /opt/imunify360/venv/lib/python3.11/site-packages/Crypto/SelfTest/Hash/ |
Current File : //opt/imunify360/venv/lib/python3.11/site-packages/Crypto/SelfTest/Hash/common.py |
# -*- coding: utf-8 -*- # # SelfTest/Hash/common.py: Common code for Crypto.SelfTest.Hash # # Written in 2008 by Dwayne C. Litzenberger <dlitz@dlitz.net> # # =================================================================== # The contents of this file are dedicated to the public domain. To # the extent that dedication to the public domain is not available, # everyone is granted a worldwide, perpetual, royalty-free, # non-exclusive license to exercise all rights associated with the # contents of this file for any purpose whatsoever. # No rights are reserved. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, # EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF # MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND # NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS # BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN # ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN # CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE # SOFTWARE. # =================================================================== """Self-testing for PyCrypto hash modules""" import re import sys import unittest import binascii import Crypto.Hash from binascii import hexlify, unhexlify from Crypto.Util.py3compat import b, tobytes from Crypto.Util.strxor import strxor_c def t2b(hex_string): shorter = re.sub(br'\s+', b'', tobytes(hex_string)) return unhexlify(shorter) class HashDigestSizeSelfTest(unittest.TestCase): def __init__(self, hashmod, description, expected, extra_params): unittest.TestCase.__init__(self) self.hashmod = hashmod self.expected = expected self.description = description self.extra_params = extra_params def shortDescription(self): return self.description def runTest(self): if "truncate" not in self.extra_params: self.assertTrue(hasattr(self.hashmod, "digest_size")) self.assertEqual(self.hashmod.digest_size, self.expected) h = self.hashmod.new(**self.extra_params) self.assertTrue(hasattr(h, "digest_size")) self.assertEqual(h.digest_size, self.expected) class HashSelfTest(unittest.TestCase): def __init__(self, hashmod, description, expected, input, extra_params): unittest.TestCase.__init__(self) self.hashmod = hashmod self.expected = expected.lower() self.input = input self.description = description self.extra_params = extra_params def shortDescription(self): return self.description def runTest(self): h = self.hashmod.new(**self.extra_params) h.update(self.input) out1 = binascii.b2a_hex(h.digest()) out2 = h.hexdigest() h = self.hashmod.new(self.input, **self.extra_params) out3 = h.hexdigest() out4 = binascii.b2a_hex(h.digest()) # PY3K: hexdigest() should return str(), and digest() bytes self.assertEqual(self.expected, out1) # h = .new(); h.update(data); h.digest() if sys.version_info[0] == 2: self.assertEqual(self.expected, out2) # h = .new(); h.update(data); h.hexdigest() self.assertEqual(self.expected, out3) # h = .new(data); h.hexdigest() else: self.assertEqual(self.expected.decode(), out2) # h = .new(); h.update(data); h.hexdigest() self.assertEqual(self.expected.decode(), out3) # h = .new(data); h.hexdigest() self.assertEqual(self.expected, out4) # h = .new(data); h.digest() # Verify that the .new() method produces a fresh hash object, except # for MD5 and SHA1, which are hashlib objects. (But test any .new() # method that does exist.) if self.hashmod.__name__ not in ('Crypto.Hash.MD5', 'Crypto.Hash.SHA1') or hasattr(h, 'new'): h2 = h.new() h2.update(self.input) out5 = binascii.b2a_hex(h2.digest()) self.assertEqual(self.expected, out5) class HashTestOID(unittest.TestCase): def __init__(self, hashmod, oid, extra_params): unittest.TestCase.__init__(self) self.hashmod = hashmod self.oid = oid self.extra_params = extra_params def runTest(self): h = self.hashmod.new(**self.extra_params) self.assertEqual(h.oid, self.oid) class ByteArrayTest(unittest.TestCase): def __init__(self, module, extra_params): unittest.TestCase.__init__(self) self.module = module self.extra_params = extra_params def runTest(self): data = b("\x00\x01\x02") # Data can be a bytearray (during initialization) ba = bytearray(data) h1 = self.module.new(data, **self.extra_params) h2 = self.module.new(ba, **self.extra_params) ba[:1] = b'\xFF' self.assertEqual(h1.digest(), h2.digest()) # Data can be a bytearray (during operation) ba = bytearray(data) h1 = self.module.new(**self.extra_params) h2 = self.module.new(**self.extra_params) h1.update(data) h2.update(ba) ba[:1] = b'\xFF' self.assertEqual(h1.digest(), h2.digest()) class MemoryViewTest(unittest.TestCase): def __init__(self, module, extra_params): unittest.TestCase.__init__(self) self.module = module self.extra_params = extra_params def runTest(self): data = b"\x00\x01\x02" def get_mv_ro(data): return memoryview(data) def get_mv_rw(data): return memoryview(bytearray(data)) for get_mv in get_mv_ro, get_mv_rw: # Data can be a memoryview (during initialization) mv = get_mv(data) h1 = self.module.new(data, **self.extra_params) h2 = self.module.new(mv, **self.extra_params) if not mv.readonly: mv[:1] = b'\xFF' self.assertEqual(h1.digest(), h2.digest()) # Data can be a memoryview (during operation) mv = get_mv(data) h1 = self.module.new(**self.extra_params) h2 = self.module.new(**self.extra_params) h1.update(data) h2.update(mv) if not mv.readonly: mv[:1] = b'\xFF' self.assertEqual(h1.digest(), h2.digest()) class MACSelfTest(unittest.TestCase): def __init__(self, module, description, result, data, key, params): unittest.TestCase.__init__(self) self.module = module self.result = t2b(result) self.data = t2b(data) self.key = t2b(key) self.params = params self.description = description def shortDescription(self): return self.description def runTest(self): result_hex = hexlify(self.result) # Verify result h = self.module.new(self.key, **self.params) h.update(self.data) self.assertEqual(self.result, h.digest()) self.assertEqual(hexlify(self.result).decode('ascii'), h.hexdigest()) # Verify that correct MAC does not raise any exception h.verify(self.result) h.hexverify(result_hex) # Verify that incorrect MAC does raise ValueError exception wrong_mac = strxor_c(self.result, 255) self.assertRaises(ValueError, h.verify, wrong_mac) self.assertRaises(ValueError, h.hexverify, "4556") # Verify again, with data passed to new() h = self.module.new(self.key, self.data, **self.params) self.assertEqual(self.result, h.digest()) self.assertEqual(hexlify(self.result).decode('ascii'), h.hexdigest()) # Test .copy() try: h = self.module.new(self.key, self.data, **self.params) h2 = h.copy() h3 = h.copy() # Verify that changing the copy does not change the original h2.update(b"bla") self.assertEqual(h3.digest(), self.result) # Verify that both can reach the same state h.update(b"bla") self.assertEqual(h.digest(), h2.digest()) except NotImplementedError: pass # PY3K: Check that hexdigest() returns str and digest() returns bytes self.assertTrue(isinstance(h.digest(), type(b""))) self.assertTrue(isinstance(h.hexdigest(), type(""))) # PY3K: Check that .hexverify() accepts bytes or str h.hexverify(h.hexdigest()) h.hexverify(h.hexdigest().encode('ascii')) def make_hash_tests(module, module_name, test_data, digest_size, oid=None, extra_params={}): tests = [] for i in range(len(test_data)): row = test_data[i] (expected, input) = map(tobytes,row[0:2]) if len(row) < 3: description = repr(input) else: description = row[2] name = "%s #%d: %s" % (module_name, i+1, description) tests.append(HashSelfTest(module, name, expected, input, extra_params)) name = "%s #%d: digest_size" % (module_name, len(test_data) + 1) tests.append(HashDigestSizeSelfTest(module, name, digest_size, extra_params)) if oid is not None: tests.append(HashTestOID(module, oid, extra_params)) tests.append(ByteArrayTest(module, extra_params)) tests.append(MemoryViewTest(module, extra_params)) return tests def make_mac_tests(module, module_name, test_data): tests = [] for i, row in enumerate(test_data): if len(row) == 4: (key, data, results, description, params) = list(row) + [ {} ] else: (key, data, results, description, params) = row name = "%s #%d: %s" % (module_name, i+1, description) tests.append(MACSelfTest(module, name, results, data, key, params)) return tests # vim:set ts=4 sw=4 sts=4 expandtab: