# -*- coding: utf-8 -*- # Copyright (C) 2003-2009 Robey Pointer # # This file is part of paramiko. # # Paramiko is free software; you can redistribute it and/or modify it under the # terms of the GNU Lesser General Public License as published by the Free # Software Foundation; either version 2.1 of the License, or (at your option) # any later version. # # Paramiko is distributed in the hope that it will be useful, but WITHOUT ANY # WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR # A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more # details. # # You should have received a copy of the GNU Lesser General Public License # along with Paramiko; if not, write to the Free Software Foundation, Inc., # 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. """ Some unit tests for public/private key objects. """ import unittest import os import stat from binascii import hexlify from hashlib import md5 from io import StringIO from paramiko import ( RSAKey, DSSKey, ECDSAKey, Ed25519Key, Message, util, SSHException, ) from paramiko.util import b from paramiko.common import o600, byte_chr from cryptography.exceptions import UnsupportedAlgorithm from cryptography.hazmat.primitives.asymmetric.rsa import RSAPrivateNumbers from unittest.mock import patch, Mock import pytest from ._util import _support, is_low_entropy, requires_sha1_signing # from openssh's ssh-keygen PUB_RSA = "ssh-rsa AAAAB3NzaC1yc2EAAAABIwAAAIEA049W6geFpmsljTwfvI1UmKWWJPNFI74+vNKTk4dmzkQY2yAMs6FhlvhlI8ysU4oj71ZsRYMecHbBbxdN79+JRFVYTKaLqjwGENeTd+yv4q+V2PvZv3fLnzApI3l7EJCqhWwJUHJ1jAkZzqDx0tyOL4uoZpww3nmE0kb3y21tH4c=" # noqa PUB_DSS = "ssh-dss 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" # noqa PUB_ECDSA_256 = "ecdsa-sha2-nistp256 AAAAE2VjZHNhLXNoYTItbmlzdHAyNTYAAAAIbmlzdHAyNTYAAABBBJSPZm3ZWkvk/Zx8WP+fZRZ5/NBBHnGQwR6uIC6XHGPDIHuWUzIjAwA0bzqkOUffEsbLe+uQgKl5kbc/L8KA/eo=" # noqa PUB_ECDSA_384 = "ecdsa-sha2-nistp384 AAAAE2VjZHNhLXNoYTItbmlzdHAzODQAAAAIbmlzdHAzODQAAABhBBbGibQLW9AAZiGN2hEQxWYYoFaWKwN3PKSaDJSMqmIn1Z9sgRUuw8Y/w502OGvXL/wFk0i2z50l3pWZjD7gfMH7gX5TUiCzwrQkS+Hn1U2S9aF5WJp0NcIzYxXw2r4M2A==" # noqa PUB_ECDSA_521 = "ecdsa-sha2-nistp521 AAAAE2VjZHNhLXNoYTItbmlzdHA1MjEAAAAIbmlzdHA1MjEAAACFBACaOaFLZGuxa5AW16qj6VLypFbLrEWrt9AZUloCMefxO8bNLjK/O5g0rAVasar1TnyHE9qj4NwzANZASWjQNbc4MAG8vzqezFwLIn/kNyNTsXNfqEko9OgHZknlj2Z79dwTJcRAL4QLcT5aND0EHZLB2fAUDXiWIb2j4rg1mwPlBMiBXA==" # noqa PUB_RSA_2K_OPENSSH = "ssh-rsa AAAAB3NzaC1yc2EAAAADAQABAAABAQDF+Dpr54DX0WdeTDpNAMdkCWEkl3OXtNgf58qlN1gX572OLBqLf0zT4bHstUEpU3piazph/rSWcUMuBoD46tZ6jiH7H9b9Pem2eYQWaELDDkM+v9BMbEy5rMbFRLol5OtEvPFqneyEAanPOgvd8t3yyhSev9QVusakzJ8j8LGgrA8huYZ+Srnw0shEWLG70KUKCh3rG0QIvA8nfhtUOisr2Gp+F0YxMGb5gwBlQYAYE5l6u1SjZ7hNjyNosjK+wRBFgFFBYVpkZKJgWoK9w4ijFyzMZTucnZMqKOKAjIJvHfKBf2/cEfYxSq1EndqTqjYsd9T7/s2vcn1OH5a0wkER" # noqa RSA_2K_OPENSSH_P = 161773687847617758886803946572654778625119997081005961935077336594287351354258259920334554906235187683459069634729972458348855793639393524799865799559575414247668746919721196359908321800753913350455861871582087986355637886875933045224711827701526739934602161222599672381604211130651397331775901258858869418853 # noqa RSA_2K_OPENSSH_Q = 154483416325630619558401349033571772244816915504195060221073502923720741119664820208064202825686848103224453777955988437823797692957091438442833606009978046057345917301441832647551208158342812551003395417862260727795454409459089912659057393394458150862012620127030757893820711157099494238156383382454310199869 # noqa PUB_DSS_1K_OPENSSH = "ssh-dss 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" # noqa PUB_EC_384_OPENSSH = "ecdsa-sha2-nistp384 AAAAE2VjZHNhLXNoYTItbmlzdHAzODQAAAAIbmlzdHAzODQAAABhBIch5LXTq/L/TWsTGG6dIktxD8DIMh7EfvoRmWsks6CuNDTvFvbQNtY4QO1mn5OXegHbS0M5DPIS++wpKGFP3suDEH08O35vZQasLNrL0tO2jyyEnzB2ZEx3PPYci811yg==" # noqa FINGER_RSA = "1024 60:73:38:44:cb:51:86:65:7f:de:da:a2:2b:5a:57:d5" FINGER_DSS = "1024 44:78:f0:b9:a2:3c:c5:18:20:09:ff:75:5b:c1:d2:6c" FINGER_ECDSA_256 = "256 25:19:eb:55:e6:a1:47:ff:4f:38:d2:75:6f:a5:d5:60" FINGER_ECDSA_384 = "384 c1:8d:a0:59:09:47:41:8e:a8:a6:07:01:29:23:b4:65" FINGER_ECDSA_521 = "521 44:58:22:52:12:33:16:0e:ce:0e:be:2c:7c:7e:cc:1e" SIGNED_RSA = "20:d7:8a:31:21:cb:f7:92:12:f2:a4:89:37:f5:78:af:e6:16:b6:25:b9:97:3d:a2:cd:5f:ca:20:21:73:4c:ad:34:73:8f:20:77:28:e2:94:15:08:d8:91:40:7a:85:83:bf:18:37:95:dc:54:1a:9b:88:29:6c:73:ca:38:b4:04:f1:56:b9:f2:42:9d:52:1b:29:29:b4:4f:fd:c9:2d:af:47:d2:40:76:30:f3:63:45:0c:d9:1d:43:86:0f:1c:70:e2:93:12:34:f3:ac:c5:0a:2f:14:50:66:59:f1:88:ee:c1:4a:e9:d1:9c:4e:46:f0:0e:47:6f:38:74:f1:44:a8" # noqa SIGNED_RSA_256 = "cc:6:60:e0:0:2c:ac:9e:26:bc:d5:68:64:3f:9f:a7:e5:aa:41:eb:88:4a:25:5:9c:93:84:66:ef:ef:60:f4:34:fb:f4:c8:3d:55:33:6a:77:bd:b2:ee:83:f:71:27:41:7e:f5:7:5:0:a9:4c:7:80:6f:be:76:67:cb:58:35:b9:2b:f3:c2:d3:3c:ee:e1:3f:59:e0:fa:e4:5c:92:ed:ae:74:de:d:d6:27:16:8f:84:a3:86:68:c:94:90:7d:6e:cc:81:12:d8:b6:ad:aa:31:a8:13:3d:63:81:3e:bb:5:b6:38:4d:2:d:1b:5b:70:de:83:cc:3a:cb:31" # noqa SIGNED_RSA_512 = "87:46:8b:75:92:33:78:a0:22:35:32:39:23:c6:ab:e1:6:92:ad:bc:7f:6e:ab:19:32:e4:78:b2:2c:8f:1d:c:65:da:fc:a5:7:ca:b6:55:55:31:83:b1:a0:af:d1:95:c5:2e:af:56:ba:f5:41:64:f:39:9d:af:82:43:22:8f:90:52:9d:89:e7:45:97:df:f3:f2:bc:7b:3a:db:89:e:34:fd:18:62:25:1b:ef:77:aa:c6:6c:99:36:3a:84:d6:9c:2a:34:8c:7f:f4:bb:c9:a5:9a:6c:11:f2:cf:da:51:5e:1e:7f:90:27:34:de:b2:f3:15:4f:db:47:32:6b:a7" # noqa FINGER_RSA_2K_OPENSSH = "2048 68:d1:72:01:bf:c0:0c:66:97:78:df:ce:75:74:46:d6" FINGER_DSS_1K_OPENSSH = "1024 cf:1d:eb:d7:61:d3:12:94:c6:c0:c6:54:35:35:b0:82" FINGER_EC_384_OPENSSH = "384 72:14:df:c1:9a:c3:e6:0e:11:29:d6:32:18:7b:ea:9b" RSA_PRIVATE_OUT = """\ -----BEGIN RSA PRIVATE KEY----- MIICWgIBAAKBgQDTj1bqB4WmayWNPB+8jVSYpZYk80Ujvj680pOTh2bORBjbIAyz oWGW+GUjzKxTiiPvVmxFgx5wdsFvF03v34lEVVhMpouqPAYQ15N37K/ir5XY+9m/ d8ufMCkjeXsQkKqFbAlQcnWMCRnOoPHS3I4vi6hmnDDeeYTSRvfLbW0fhwIBIwKB gBIiOqZYaoqbeD9OS9z2K9KR2atlTxGxOJPXiP4ESqP3NVScWNwyZ3NXHpyrJLa0 EbVtzsQhLn6rF+TzXnOlcipFvjsem3iYzCpuChfGQ6SovTcOjHV9z+hnpXvQ/fon soVRZY65wKnF7IAoUwTmJS9opqgrN6kRgCd3DASAMd1bAkEA96SBVWFt/fJBNJ9H tYnBKZGw0VeHOYmVYbvMSstssn8un+pQpUm9vlG/bp7Oxd/m+b9KWEh2xPfv6zqU avNwHwJBANqzGZa/EpzF4J8pGti7oIAPUIDGMtfIcmqNXVMckrmzQ2vTfqtkEZsA 4rE1IERRyiJQx6EJsz21wJmGV9WJQ5kCQQDwkS0uXqVdFzgHO6S++tjmjYcxwr3g H0CoFYSgbddOT6miqRskOQF3DZVkJT3kyuBgU2zKygz52ukQZMqxCb1fAkASvuTv qfpH87Qq5kQhNKdbbwbmd2NxlNabazPijWuphGTdW0VfJdWfklyS2Kr+iqrs/5wV HhathJt636Eg7oIjAkA8ht3MQ+XSl9yIJIS8gVpbPxSw5OMfw0PjVE7tBdQruiSc nvuQES5C9BMHjF39LZiGH1iLQy7FgdHyoP+eodI7 -----END RSA PRIVATE KEY----- """ DSS_PRIVATE_OUT = """\ -----BEGIN DSA PRIVATE KEY----- MIIBuwIBAAKBgQDngaYDZ30c6/7cJgEEbtl8FgKdwhba1Z7oOrOn4MI/6C42G1bY wMuqZf4dBCglsdq39SHrcjbE8Vq54gPSOh3g4+uV9Rcg5IOoPLbwp2jQfF6f1FIb sx7hrDCIqUcQccPSxetPBKmXI9RN8rZLaFuQeTnI65BKM98Ruwvq6SI2LwIVAPDP hSeawaJI27mKqOfe5PPBSmyHAoGBAJMXxXmPD9sGaQ419DIpmZecJKBUAy9uXD8x gbgeDpwfDaFJP8owByCKREocPFfi86LjCuQkyUKOfjYMN6iHIf1oEZjB8uJAatUr FzI0ArXtUqOhwTLwTyFuUojE5own2WYsOAGByvgfyWjsGhvckYNhI4ODpNdPlxQ8 ZamaPGPsAoGARmR7CCPjodxASvRbIyzaVpZoJ/Z6x7dAumV+ysrV1BVYd0lYukmn jO1kKBWApqpH1ve9XDQYN8zgxM4b16L21kpoWQnZtXrY3GZ4/it9kUgyB7+NwacI BlXa8cMDL7Q/69o0d54U0X/NeX5QxuYR6OMJlrkQB7oiW/P/1mwjQgECFGI9QPSc h9pT9XHqn+1rZ4bK+QGA -----END DSA PRIVATE KEY----- """ ECDSA_PRIVATE_OUT_256 = """\ -----BEGIN EC PRIVATE KEY----- MHcCAQEEIKB6ty3yVyKEnfF/zprx0qwC76MsMlHY4HXCnqho2eKioAoGCCqGSM49 AwEHoUQDQgAElI9mbdlaS+T9nHxY/59lFnn80EEecZDBHq4gLpccY8Mge5ZTMiMD ADRvOqQ5R98Sxst765CAqXmRtz8vwoD96g== -----END EC PRIVATE KEY----- """ ECDSA_PRIVATE_OUT_384 = """\ -----BEGIN EC PRIVATE KEY----- MIGkAgEBBDBDdO8IXvlLJgM7+sNtPl7tI7FM5kzuEUEEPRjXIPQM7mISciwJPBt+ y43EuG8nL4mgBwYFK4EEACKhZANiAAQWxom0C1vQAGYhjdoREMVmGKBWlisDdzyk mgyUjKpiJ9WfbIEVLsPGP8OdNjhr1y/8BZNIts+dJd6VmYw+4HzB+4F+U1Igs8K0 JEvh59VNkvWheViadDXCM2MV8Nq+DNg= -----END EC PRIVATE KEY----- """ ECDSA_PRIVATE_OUT_521 = """\ -----BEGIN EC PRIVATE KEY----- MIHcAgEBBEIAprQtAS3OF6iVUkT8IowTHWicHzShGgk86EtuEXvfQnhZFKsWm6Jo iqAr1yEaiuI9LfB3Xs8cjuhgEEfbduYr/f6gBwYFK4EEACOhgYkDgYYABACaOaFL ZGuxa5AW16qj6VLypFbLrEWrt9AZUloCMefxO8bNLjK/O5g0rAVasar1TnyHE9qj 4NwzANZASWjQNbc4MAG8vzqezFwLIn/kNyNTsXNfqEko9OgHZknlj2Z79dwTJcRA L4QLcT5aND0EHZLB2fAUDXiWIb2j4rg1mwPlBMiBXA== -----END EC PRIVATE KEY----- """ x1234 = b"\x01\x02\x03\x04" TEST_KEY_BYTESTR = "\x00\x00\x00\x07ssh-rsa\x00\x00\x00\x01#\x00\x00\x00\x00ӏV\x07k%<\x1fT$E#>ғfD\x18 \x0cae#̬S#VlE\x1epvo\x17M߉DUXL<\x06\x10דw\u2bd5ٿw˟0)#y{\x10l\tPru\t\x19Π\u070e/f0yFmm\x1f" # noqa class KeyTest(unittest.TestCase): def assert_keyfile_is_encrypted(self, keyfile): """ A quick check that filename looks like an encrypted key. """ with open(keyfile, "r") as fh: self.assertEqual( fh.readline()[:-1], "-----BEGIN RSA PRIVATE KEY-----" ) self.assertEqual(fh.readline()[:-1], "Proc-Type: 4,ENCRYPTED") self.assertEqual(fh.readline()[0:10], "DEK-Info: ") def test_generate_key_bytes(self): key = util.generate_key_bytes(md5, x1234, "happy birthday", 30) exp = b"\x61\xE1\xF2\x72\xF4\xC1\xC4\x56\x15\x86\xBD\x32\x24\x98\xC0\xE9\x24\x67\x27\x80\xF4\x7B\xB3\x7D\xDA\x7D\x54\x01\x9E\x64" # noqa self.assertEqual(exp, key) def test_load_rsa(self): key = RSAKey.from_private_key_file(_support("rsa.key")) self.assertEqual("ssh-rsa", key.get_name()) exp_rsa = b(FINGER_RSA.split()[1].replace(":", "")) my_rsa = hexlify(key.get_fingerprint()) self.assertEqual(exp_rsa, my_rsa) self.assertEqual(PUB_RSA.split()[1], key.get_base64()) self.assertEqual(1024, key.get_bits()) s = StringIO() key.write_private_key(s) self.assertEqual(RSA_PRIVATE_OUT, s.getvalue()) s.seek(0) key2 = RSAKey.from_private_key(s) self.assertEqual(key, key2) def test_load_rsa_transmutes_crypto_exceptions(self): # TODO: nix unittest for pytest for exception in (TypeError("onoz"), UnsupportedAlgorithm("oops")): with patch( "paramiko.rsakey.serialization.load_der_private_key" ) as loader: loader.side_effect = exception with pytest.raises(SSHException, match=str(exception)): RSAKey.from_private_key_file(_support("rsa.key")) def test_loading_empty_keys_errors_usefully(self): # #1599 - raise SSHException instead of IndexError with pytest.raises(SSHException, match="no lines"): RSAKey.from_private_key_file(_support("blank_rsa.key")) def test_load_rsa_password(self): key = RSAKey.from_private_key_file( _support("test_rsa_password.key"), "television" ) self.assertEqual("ssh-rsa", key.get_name()) exp_rsa = b(FINGER_RSA.split()[1].replace(":", "")) my_rsa = hexlify(key.get_fingerprint()) self.assertEqual(exp_rsa, my_rsa) self.assertEqual(PUB_RSA.split()[1], key.get_base64()) self.assertEqual(1024, key.get_bits()) def test_load_dss(self): key = DSSKey.from_private_key_file(_support("dss.key")) self.assertEqual("ssh-dss", key.get_name()) exp_dss = b(FINGER_DSS.split()[1].replace(":", "")) my_dss = hexlify(key.get_fingerprint()) self.assertEqual(exp_dss, my_dss) self.assertEqual(PUB_DSS.split()[1], key.get_base64()) self.assertEqual(1024, key.get_bits()) s = StringIO() key.write_private_key(s) self.assertEqual(DSS_PRIVATE_OUT, s.getvalue()) s.seek(0) key2 = DSSKey.from_private_key(s) self.assertEqual(key, key2) def test_load_dss_password(self): key = DSSKey.from_private_key_file( _support("test_dss_password.key"), "television" ) self.assertEqual("ssh-dss", key.get_name()) exp_dss = b(FINGER_DSS.split()[1].replace(":", "")) my_dss = hexlify(key.get_fingerprint()) self.assertEqual(exp_dss, my_dss) self.assertEqual(PUB_DSS.split()[1], key.get_base64()) self.assertEqual(1024, key.get_bits()) def test_compare_rsa(self): # verify that the private & public keys compare equal key = RSAKey.from_private_key_file(_support("rsa.key")) self.assertEqual(key, key) pub = RSAKey(data=key.asbytes()) self.assertTrue(key.can_sign()) self.assertTrue(not pub.can_sign()) self.assertEqual(key, pub) def test_compare_dss(self): # verify that the private & public keys compare equal key = DSSKey.from_private_key_file(_support("dss.key")) self.assertEqual(key, key) pub = DSSKey(data=key.asbytes()) self.assertTrue(key.can_sign()) self.assertTrue(not pub.can_sign()) self.assertEqual(key, pub) def _sign_and_verify_rsa(self, algorithm, saved_sig): key = RSAKey.from_private_key_file(_support("rsa.key")) msg = key.sign_ssh_data(b"ice weasels", algorithm) assert isinstance(msg, Message) msg.rewind() assert msg.get_text() == algorithm expected = b"".join( [byte_chr(int(x, 16)) for x in saved_sig.split(":")] ) assert msg.get_binary() == expected msg.rewind() pub = RSAKey(data=key.asbytes()) self.assertTrue(pub.verify_ssh_sig(b"ice weasels", msg)) @requires_sha1_signing def test_sign_and_verify_ssh_rsa(self): self._sign_and_verify_rsa("ssh-rsa", SIGNED_RSA) def test_sign_and_verify_rsa_sha2_512(self): self._sign_and_verify_rsa("rsa-sha2-512", SIGNED_RSA_512) def test_sign_and_verify_rsa_sha2_256(self): self._sign_and_verify_rsa("rsa-sha2-256", SIGNED_RSA_256) def test_sign_dss(self): # verify that the dss private key can sign and verify key = DSSKey.from_private_key_file(_support("dss.key")) msg = key.sign_ssh_data(b"ice weasels") self.assertTrue(type(msg) is Message) msg.rewind() self.assertEqual("ssh-dss", msg.get_text()) # can't do the same test as we do for RSA, because DSS signatures # are usually different each time. but we can test verification # anyway so it's ok. self.assertEqual(40, len(msg.get_binary())) msg.rewind() pub = DSSKey(data=key.asbytes()) self.assertTrue(pub.verify_ssh_sig(b"ice weasels", msg)) @requires_sha1_signing def test_generate_rsa(self): key = RSAKey.generate(1024) msg = key.sign_ssh_data(b"jerri blank") msg.rewind() self.assertTrue(key.verify_ssh_sig(b"jerri blank", msg)) def test_generate_dss(self): key = DSSKey.generate(1024) msg = key.sign_ssh_data(b"jerri blank") msg.rewind() self.assertTrue(key.verify_ssh_sig(b"jerri blank", msg)) def test_generate_ecdsa(self): key = ECDSAKey.generate() msg = key.sign_ssh_data(b"jerri blank") msg.rewind() self.assertTrue(key.verify_ssh_sig(b"jerri blank", msg)) self.assertEqual(key.get_bits(), 256) self.assertEqual(key.get_name(), "ecdsa-sha2-nistp256") key = ECDSAKey.generate(bits=256) msg = key.sign_ssh_data(b"jerri blank") msg.rewind() self.assertTrue(key.verify_ssh_sig(b"jerri blank", msg)) self.assertEqual(key.get_bits(), 256) self.assertEqual(key.get_name(), "ecdsa-sha2-nistp256") key = ECDSAKey.generate(bits=384) msg = key.sign_ssh_data(b"jerri blank") msg.rewind() self.assertTrue(key.verify_ssh_sig(b"jerri blank", msg)) self.assertEqual(key.get_bits(), 384) self.assertEqual(key.get_name(), "ecdsa-sha2-nistp384") key = ECDSAKey.generate(bits=521) msg = key.sign_ssh_data(b"jerri blank") msg.rewind() self.assertTrue(key.verify_ssh_sig(b"jerri blank", msg)) self.assertEqual(key.get_bits(), 521) self.assertEqual(key.get_name(), "ecdsa-sha2-nistp521") def test_load_ecdsa_256(self): key = ECDSAKey.from_private_key_file(_support("ecdsa-256.key")) self.assertEqual("ecdsa-sha2-nistp256", key.get_name()) exp_ecdsa = b(FINGER_ECDSA_256.split()[1].replace(":", "")) my_ecdsa = hexlify(key.get_fingerprint()) self.assertEqual(exp_ecdsa, my_ecdsa) self.assertEqual(PUB_ECDSA_256.split()[1], key.get_base64()) self.assertEqual(256, key.get_bits()) s = StringIO() key.write_private_key(s) self.assertEqual(ECDSA_PRIVATE_OUT_256, s.getvalue()) s.seek(0) key2 = ECDSAKey.from_private_key(s) self.assertEqual(key, key2) def test_load_ecdsa_password_256(self): key = ECDSAKey.from_private_key_file( _support("test_ecdsa_password_256.key"), b"television" ) self.assertEqual("ecdsa-sha2-nistp256", key.get_name()) exp_ecdsa = b(FINGER_ECDSA_256.split()[1].replace(":", "")) my_ecdsa = hexlify(key.get_fingerprint()) self.assertEqual(exp_ecdsa, my_ecdsa) self.assertEqual(PUB_ECDSA_256.split()[1], key.get_base64()) self.assertEqual(256, key.get_bits()) def test_compare_ecdsa_256(self): # verify that the private & public keys compare equal key = ECDSAKey.from_private_key_file(_support("ecdsa-256.key")) self.assertEqual(key, key) pub = ECDSAKey(data=key.asbytes()) self.assertTrue(key.can_sign()) self.assertTrue(not pub.can_sign()) self.assertEqual(key, pub) def test_sign_ecdsa_256(self): # verify that the rsa private key can sign and verify key = ECDSAKey.from_private_key_file(_support("ecdsa-256.key")) msg = key.sign_ssh_data(b"ice weasels") self.assertTrue(type(msg) is Message) msg.rewind() self.assertEqual("ecdsa-sha2-nistp256", msg.get_text()) # ECDSA signatures, like DSS signatures, tend to be different # each time, so we can't compare against a "known correct" # signature. # Even the length of the signature can change. msg.rewind() pub = ECDSAKey(data=key.asbytes()) self.assertTrue(pub.verify_ssh_sig(b"ice weasels", msg)) def test_load_ecdsa_384(self): key = ECDSAKey.from_private_key_file(_support("test_ecdsa_384.key")) self.assertEqual("ecdsa-sha2-nistp384", key.get_name()) exp_ecdsa = b(FINGER_ECDSA_384.split()[1].replace(":", "")) my_ecdsa = hexlify(key.get_fingerprint()) self.assertEqual(exp_ecdsa, my_ecdsa) self.assertEqual(PUB_ECDSA_384.split()[1], key.get_base64()) self.assertEqual(384, key.get_bits()) s = StringIO() key.write_private_key(s) self.assertEqual(ECDSA_PRIVATE_OUT_384, s.getvalue()) s.seek(0) key2 = ECDSAKey.from_private_key(s) self.assertEqual(key, key2) def test_load_ecdsa_password_384(self): key = ECDSAKey.from_private_key_file( _support("test_ecdsa_password_384.key"), b"television" ) self.assertEqual("ecdsa-sha2-nistp384", key.get_name()) exp_ecdsa = b(FINGER_ECDSA_384.split()[1].replace(":", "")) my_ecdsa = hexlify(key.get_fingerprint()) self.assertEqual(exp_ecdsa, my_ecdsa) self.assertEqual(PUB_ECDSA_384.split()[1], key.get_base64()) self.assertEqual(384, key.get_bits()) def test_load_ecdsa_transmutes_crypto_exceptions(self): path = _support("ecdsa-256.key") # TODO: nix unittest for pytest for exception in (TypeError("onoz"), UnsupportedAlgorithm("oops")): with patch( "paramiko.ecdsakey.serialization.load_der_private_key" ) as loader: loader.side_effect = exception with pytest.raises(SSHException, match=str(exception)): ECDSAKey.from_private_key_file(path) def test_compare_ecdsa_384(self): # verify that the private & public keys compare equal key = ECDSAKey.from_private_key_file(_support("test_ecdsa_384.key")) self.assertEqual(key, key) pub = ECDSAKey(data=key.asbytes()) self.assertTrue(key.can_sign()) self.assertTrue(not pub.can_sign()) self.assertEqual(key, pub) def test_sign_ecdsa_384(self): # verify that the rsa private key can sign and verify key = ECDSAKey.from_private_key_file(_support("test_ecdsa_384.key")) msg = key.sign_ssh_data(b"ice weasels") self.assertTrue(type(msg) is Message) msg.rewind() self.assertEqual("ecdsa-sha2-nistp384", msg.get_text()) # ECDSA signatures, like DSS signatures, tend to be different # each time, so we can't compare against a "known correct" # signature. # Even the length of the signature can change. msg.rewind() pub = ECDSAKey(data=key.asbytes()) self.assertTrue(pub.verify_ssh_sig(b"ice weasels", msg)) def test_load_ecdsa_521(self): key = ECDSAKey.from_private_key_file(_support("test_ecdsa_521.key")) self.assertEqual("ecdsa-sha2-nistp521", key.get_name()) exp_ecdsa = b(FINGER_ECDSA_521.split()[1].replace(":", "")) my_ecdsa = hexlify(key.get_fingerprint()) self.assertEqual(exp_ecdsa, my_ecdsa) self.assertEqual(PUB_ECDSA_521.split()[1], key.get_base64()) self.assertEqual(521, key.get_bits()) s = StringIO() key.write_private_key(s) # Different versions of OpenSSL (SSLeay versions 0x1000100f and # 0x1000207f for instance) use different apparently valid (as far as # ssh-keygen is concerned) padding. So we can't check the actual value # of the pem encoded key. s.seek(0) key2 = ECDSAKey.from_private_key(s) self.assertEqual(key, key2) def test_load_ecdsa_password_521(self): key = ECDSAKey.from_private_key_file( _support("test_ecdsa_password_521.key"), b"television" ) self.assertEqual("ecdsa-sha2-nistp521", key.get_name()) exp_ecdsa = b(FINGER_ECDSA_521.split()[1].replace(":", "")) my_ecdsa = hexlify(key.get_fingerprint()) self.assertEqual(exp_ecdsa, my_ecdsa) self.assertEqual(PUB_ECDSA_521.split()[1], key.get_base64()) self.assertEqual(521, key.get_bits()) def test_compare_ecdsa_521(self): # verify that the private & public keys compare equal key = ECDSAKey.from_private_key_file(_support("test_ecdsa_521.key")) self.assertEqual(key, key) pub = ECDSAKey(data=key.asbytes()) self.assertTrue(key.can_sign()) self.assertTrue(not pub.can_sign()) self.assertEqual(key, pub) def test_sign_ecdsa_521(self): # verify that the rsa private key can sign and verify key = ECDSAKey.from_private_key_file(_support("test_ecdsa_521.key")) msg = key.sign_ssh_data(b"ice weasels") self.assertTrue(type(msg) is Message) msg.rewind() self.assertEqual("ecdsa-sha2-nistp521", msg.get_text()) # ECDSA signatures, like DSS signatures, tend to be different # each time, so we can't compare against a "known correct" # signature. # Even the length of the signature can change. msg.rewind() pub = ECDSAKey(data=key.asbytes()) self.assertTrue(pub.verify_ssh_sig(b"ice weasels", msg)) def test_load_openssh_format_RSA_key(self): key = RSAKey.from_private_key_file( _support("test_rsa_openssh.key"), b"television" ) self.assertEqual("ssh-rsa", key.get_name()) self.assertEqual(PUB_RSA_2K_OPENSSH.split()[1], key.get_base64()) self.assertEqual(2048, key.get_bits()) exp_rsa = b(FINGER_RSA_2K_OPENSSH.split()[1].replace(":", "")) my_rsa = hexlify(key.get_fingerprint()) self.assertEqual(exp_rsa, my_rsa) def test_loading_openssh_RSA_keys_uses_correct_p_q(self): # Re #1723 - not the most elegant test but given how deep it is... with patch( "paramiko.rsakey.rsa.RSAPrivateNumbers", wraps=RSAPrivateNumbers ) as spy: # Load key RSAKey.from_private_key_file( _support("test_rsa_openssh.key"), b"television" ) # Ensure spy saw the correct P and Q values as derived from # hardcoded test private key value kwargs = spy.call_args[1] assert kwargs["p"] == RSA_2K_OPENSSH_P assert kwargs["q"] == RSA_2K_OPENSSH_Q def test_load_openssh_format_DSS_key(self): key = DSSKey.from_private_key_file( _support("test_dss_openssh.key"), b"television" ) self.assertEqual("ssh-dss", key.get_name()) self.assertEqual(PUB_DSS_1K_OPENSSH.split()[1], key.get_base64()) self.assertEqual(1024, key.get_bits()) exp_rsa = b(FINGER_DSS_1K_OPENSSH.split()[1].replace(":", "")) my_rsa = hexlify(key.get_fingerprint()) self.assertEqual(exp_rsa, my_rsa) def test_load_openssh_format_EC_key(self): key = ECDSAKey.from_private_key_file( _support("test_ecdsa_384_openssh.key"), b"television" ) self.assertEqual("ecdsa-sha2-nistp384", key.get_name()) self.assertEqual(PUB_EC_384_OPENSSH.split()[1], key.get_base64()) self.assertEqual(384, key.get_bits()) exp_fp = b(FINGER_EC_384_OPENSSH.split()[1].replace(":", "")) my_fp = hexlify(key.get_fingerprint()) self.assertEqual(exp_fp, my_fp) def test_salt_size(self): # Read an existing encrypted private key file_ = _support("test_rsa_password.key") password = "television" newfile = file_ + ".new" newpassword = "radio" key = RSAKey(filename=file_, password=password) # Write out a newly re-encrypted copy with a new password. # When the bug under test exists, this will ValueError. try: key.write_private_key_file(newfile, password=newpassword) self.assert_keyfile_is_encrypted(newfile) # Verify the inner key data still matches (when no ValueError) key2 = RSAKey(filename=newfile, password=newpassword) self.assertEqual(key, key2) finally: os.remove(newfile) def test_load_openssh_format_RSA_nopad(self): # check just not exploding with 'Invalid key' RSAKey.from_private_key_file(_support("test_rsa_openssh_nopad.key")) def test_stringification(self): key = RSAKey.from_private_key_file(_support("rsa.key")) comparable = TEST_KEY_BYTESTR self.assertEqual(str(key), comparable) def test_ed25519(self): key1 = Ed25519Key.from_private_key_file(_support("ed25519.key")) key2 = Ed25519Key.from_private_key_file( _support("test_ed25519_password.key"), b"abc123" ) self.assertNotEqual(key1.asbytes(), key2.asbytes()) def test_ed25519_funky_padding(self): # Proves #1306 by just not exploding with 'Invalid key'. Ed25519Key.from_private_key_file( _support("test_ed25519-funky-padding.key") ) def test_ed25519_funky_padding_with_passphrase(self): # Proves #1306 by just not exploding with 'Invalid key'. Ed25519Key.from_private_key_file( _support("test_ed25519-funky-padding_password.key"), b"asdf" ) def test_ed25519_compare(self): # verify that the private & public keys compare equal key = Ed25519Key.from_private_key_file(_support("ed25519.key")) self.assertEqual(key, key) pub = Ed25519Key(data=key.asbytes()) self.assertTrue(key.can_sign()) self.assertTrue(not pub.can_sign()) self.assertEqual(key, pub) # No point testing on systems that never exhibited the bug originally @pytest.mark.skipif( not is_low_entropy(), reason="Not a low-entropy system" ) def test_ed25519_32bit_collision(self): # Re: 2021.10.19 security report email: two different private keys # which Paramiko compared as equal on low-entropy platforms. original = Ed25519Key.from_private_key_file( _support("badhash_key1.ed25519.key") ) generated = Ed25519Key.from_private_key_file( _support("badhash_key2.ed25519.key") ) assert original != generated # TODO: use keys fixture def keys(self): for key_class, filename in [ (RSAKey, "rsa.key"), (DSSKey, "dss.key"), (ECDSAKey, "ecdsa-256.key"), (Ed25519Key, "ed25519.key"), ]: key1 = key_class.from_private_key_file(_support(filename)) key2 = key_class.from_private_key_file(_support(filename)) yield key1, key2 def test_keys_are_comparable(self): for key1, key2 in self.keys(): assert key1 == key2 def test_keys_are_not_equal_to_other(self): for value in [None, True, ""]: for key1, _ in self.keys(): assert key1 != value def test_keys_are_hashable(self): # NOTE: this isn't a great test due to hashseed randomization under # Python 3 preventing use of static values, but it does still prove # that __hash__ is implemented/doesn't explode & works across instances for key1, key2 in self.keys(): assert hash(key1) == hash(key2) # TODO: use keys fixture def test_new_fingerprint(self): # Assumes the RSA, DSS, ECDSA, Ed25519 order seen in 'def keys'. fingerprints = [x.fingerprint for x, _ in self.keys()] assert fingerprints == [ "SHA256:OhNL391d/beeFnxxg18AwWVYTAHww+D4djEE7Co0Yng", "SHA256:uHwwykG099f4M4kfzvFpKCTino0/P03DRbAidpAmPm0", "SHA256:BrQG04oNKUETjKCeL4ifkARASg3yxS/pUHl3wWM26Yg", "SHA256:J6VESFdD3xSChn8y9PzWzeF+1tl892mOy2TqkMLO4ow", ] # TODO: use keys fixture def test_algorithm_property(self): # Assumes the RSA, DSS, ECDSA, Ed25519 order seen in 'def keys'. algorithms = [x.algorithm_name for x, _ in self.keys()] assert algorithms == ["RSA", "DSS", "ECDSA", "ED25519"] def test_ed25519_nonbytes_password(self): # https://github.com/paramiko/paramiko/issues/1039 Ed25519Key.from_private_key_file( _support("test_ed25519_password.key"), # NOTE: not a bytes. Amusingly, the test above for same key DOES # explicitly cast to bytes...code smell! "abc123", ) # No exception -> it's good. Meh. def test_ed25519_load_from_file_obj(self): with open(_support("ed25519.key")) as pkey_fileobj: key = Ed25519Key.from_private_key(pkey_fileobj) self.assertEqual(key, key) self.assertTrue(key.can_sign()) def test_keyfile_is_actually_encrypted(self): # Read an existing encrypted private key file_ = _support("test_rsa_password.key") password = "television" newfile = file_ + ".new" newpassword = "radio" key = RSAKey(filename=file_, password=password) # Write out a newly re-encrypted copy with a new password. # When the bug under test exists, this will ValueError. try: key.write_private_key_file(newfile, password=newpassword) self.assert_keyfile_is_encrypted(newfile) finally: os.remove(newfile) @patch("paramiko.pkey.os") def _test_keyfile_race(self, os_, exists): # Re: CVE-2022-24302 password = "television" newpassword = "radio" source = _support("test_ecdsa_384.key") new = source + ".new" # Mock setup os_.path.exists.return_value = exists # Attach os flag values to mock for attr, value in vars(os).items(): if attr.startswith("O_"): setattr(os_, attr, value) # Load fixture key key = ECDSAKey(filename=source, password=password) key._write_private_key = Mock() # Write out in new location key.write_private_key_file(new, password=newpassword) # Expected open via os module os_.open.assert_called_once_with( new, flags=os.O_WRONLY | os.O_CREAT | os.O_TRUNC, mode=o600 ) os_.fdopen.assert_called_once_with(os_.open.return_value, "w") assert ( key._write_private_key.call_args[0][0] == os_.fdopen.return_value.__enter__.return_value ) def test_new_keyfiles_avoid_file_descriptor_race_on_chmod(self): self._test_keyfile_race(exists=False) def test_existing_keyfiles_still_work_ok(self): self._test_keyfile_race(exists=True) def test_new_keyfiles_avoid_descriptor_race_integration(self): # Integration-style version of above password = "television" newpassword = "radio" source = _support("test_ecdsa_384.key") new = source + ".new" # Load fixture key key = ECDSAKey(filename=source, password=password) try: # Write out in new location key.write_private_key_file(new, password=newpassword) # Test mode assert stat.S_IMODE(os.stat(new).st_mode) == o600 # Prove can open with new password reloaded = ECDSAKey(filename=new, password=newpassword) assert reloaded == key finally: if os.path.exists(new): os.unlink(new)