diff options
| author | Jack Lloyd <[email protected]> | 2018-08-11 17:40:33 -0400 |
|---|---|---|
| committer | Jack Lloyd <[email protected]> | 2018-08-11 17:44:58 -0400 |
| commit | cb3b4483d7784a6c593e13c91fa2325b2c31208b (patch) | |
| tree | d126a349438f4836098239bd3f545c550509c67a /src/scripts | |
| parent | 7fe0cc6081c608d796cdaf0f45b195dbb42841e4 (diff) | |
Convert Python tests to actual unit tests
Diffstat (limited to 'src/scripts')
| -rw-r--r-- | src/scripts/test_python.py | 286 |
1 files changed, 120 insertions, 166 deletions
diff --git a/src/scripts/test_python.py b/src/scripts/test_python.py index e7fb76f0c..32e57bc0a 100644 --- a/src/scripts/test_python.py +++ b/src/scripts/test_python.py @@ -6,7 +6,7 @@ Botan is released under the Simplified BSD License (see license.txt) """ -import sys +import unittest import binascii import botan2 @@ -16,105 +16,108 @@ def hex_encode(buf): def hex_decode(buf): return binascii.unhexlify(buf.encode('ascii')) -def test(): - # pylint: disable=too-many-statements +class BotanPythonTests(unittest.TestCase): - def test_version(): + def test_version(self): + version_str = botan2.version_string() + self.assertTrue(version_str.startswith('Botan ')) - print("\n%s" % botan2.version_string()) - print("v%d.%d.%d\n" % (botan2.version_major(), botan2.version_minor(), botan2.version_patch())) - print("\nPython %s\n" % sys.version.replace('\n', ' ')) + self.assertEqual(botan2.version_major(), 2) + self.assertTrue(botan2.version_minor() >= 8) - def test_kdf(): - print("KDF2(SHA-1) %s" % - hex_encode(botan2.kdf('KDF2(SHA-1)', - hex_decode('701F3480DFE95F57941F804B1B2413EF'), 7, - hex_decode('55A4E9DD5F4CA2EF82'), hex_decode('')))) + def test_kdf(self): - def test_pbkdf(): - print("PBKDF2(SHA-1) %s" % - hex_encode(botan2.pbkdf('PBKDF2(SHA-1)', '', 32, 10000, hex_decode('0001020304050607'))[2])) - print("good output %s\n" % - '59B2B1143B4CB1059EC58D9722FB1C72471E0D85C6F7543BA5228526375B0127') + secret = hex_decode('6FD4C3C0F38E5C7A6F83E99CD9BD') + salt = hex_decode('DBB986') + label = hex_decode('') + expected = hex_decode('02AEB40A3D4B66FBA540F9D4B20006F2046E0F3A029DEAB201FC692B79EB27CEF7E16069046A') - (salt, iterations, psk) = botan2.pbkdf_timed('PBKDF2(SHA-256)', 'xyz', 32, 200) + produced = botan2.kdf('KDF2(SHA-1)', secret, 38, salt, label) - print("PBKDF2(SHA-256) x=timed, y=iterated; salt = %s (len=%d) #iterations = %d\n" % - (hex_encode(salt), len(salt), iterations)) + self.assertEqual(hex_encode(produced), hex_encode(expected)) - print('x %s' % hex_encode(psk)) - print('y %s\n' % (hex_encode(botan2.pbkdf('PBKDF2(SHA-256)', 'xyz', 32, iterations, salt)[2]))) + def test_pbkdf(self): - def test_scrypt(): + (salt, iterations, pbkdf) = botan2.pbkdf('PBKDF2(SHA-1)', '', 32, 10000, hex_decode('0001020304050607')) + + self.assertEqual(iterations, 10000) + self.assertEqual(hex_encode(pbkdf), + '59b2b1143b4cb1059ec58d9722fb1c72471e0d85c6f7543ba5228526375b0127') + + (salt, iterations, pbkdf) = botan2.pbkdf_timed('PBKDF2(SHA-256)', 'xyz', 32, 200) + + cmp_pbkdf = botan2.pbkdf('PBKDF2(SHA-256)', 'xyz', 32, iterations, salt)[2] + + self.assertEqual(pbkdf, cmp_pbkdf) + + def test_scrypt(self): scrypt = botan2.scrypt(10, '', '', 16, 1, 1) - print(hex_encode(scrypt)) - assert hex_encode(scrypt) == "77d6576238657b203b19" + self.assertEqual(hex_encode(scrypt), "77d6576238657b203b19") scrypt = botan2.scrypt(32, 'password', 'NaCl', 1024, 8, 16) - print(hex_encode(scrypt)) - assert hex_encode(scrypt) == "fdbabe1c9d3472007856e7190d01e9fe7c6ad7cbc8237830e77376634b373162" - + self.assertEqual(hex_encode(scrypt), "fdbabe1c9d3472007856e7190d01e9fe7c6ad7cbc8237830e77376634b373162") - def test_bcrypt(): - print("Testing Bcrypt...") + def test_bcrypt(self): r = botan2.rng() phash = botan2.bcrypt('testing', r) - print("bcrypt returned %s (%d bytes)" % (hex_encode(phash), len(phash))) - print("validating the hash produced: %r" % (botan2.check_bcrypt('testing', phash))) - print("\n") + self.assertTrue(phash.startswith("$2a$")) + + self.assertTrue(botan2.check_bcrypt('testing', phash)) + self.assertFalse(botan2.check_bcrypt('live fire', phash)) - def test_hmac(): + self.assertTrue(botan2.check_bcrypt('test', '$2a$04$wjen1fAA.UW6UxthpKK.huyOoxvCR7ATRCVC4CBIEGVDOCtr8Oj1C')) + + def test_hmac(self): hmac = botan2.message_authentication_code('HMAC(SHA-256)') hmac.set_key(hex_decode('0102030405060708090A0B0C0D0E0F101112131415161718191A1B1C1D1E1F20')) hmac.update(hex_decode('616263')) - hmac_vec = hex_decode('A21B1F5D4CF4F73A4DD939750F7A066A7F98CC131CB16A6692759021CFAB8181') - hmac_output = hmac.final() + expected = hex_decode('A21B1F5D4CF4F73A4DD939750F7A066A7F98CC131CB16A6692759021CFAB8181') + produced = hmac.final() - if hmac_output != hmac_vec: - print("Bad HMAC:\t%s" % hex_encode(hmac_output)) - print("vs good: \t%s" % hex_encode(hmac_vec)) - else: - print("HMAC output correct: %s\n" % hex_encode(hmac_output)) + self.assertEqual(hex_encode(expected), hex_encode(produced)) - def test_rng(): + def test_rng(self): user_rng = botan2.rng("user") - print("rng output:\n\t%s\n\t%s\n\t%s\n" % - (hex_encode(user_rng.get(42)), - hex_encode(user_rng.get(13)), - hex_encode(user_rng.get(9)))) - - def test_hash(): - md5 = botan2.hash_function('MD5') - assert md5.output_length() == 16 - md5.update('h') - md5.clear() - md5.update('h') - md5.update('i') - h1 = md5.final() - print("md5 hash: %s (%s)\n" % (hex_encode(h1), '49f68a5c8493ec2c0bf489821c21fc3b')) - - md5.update(hex_decode('f468025b')) - h2 = md5.final() - print("md5 hash: %s (%s)\n" % (hex_encode(h2), '47efd2be302a937775e93dea281b6751')) - - def test_cipher(): + output1 = user_rng.get(32) + output2 = user_rng.get(32) + + self.assertEqual(len(output1), 32) + self.assertEqual(len(output2), 32) + self.assertNotEqual(output1, output2) + + output3 = user_rng.get(1021) + self.assertEqual(len(output3), 1021) + + def test_hash(self): + h = botan2.hash_function('SHA-256') + assert h.output_length() == 32 + h.update('ignore this please') + h.clear() + h.update('a') + h1 = h.final() + + self.assertEqual(hex_encode(h1), "ca978112ca1bbdcafac231b39a23dc4da786eff8147c4e72b9807785afee48bb") + + h.update(hex_decode('616263')) + h2 = h.final() + self.assertEqual(hex_encode(h2), "ba7816bf8f01cfea414140de5dae2223b00361a396177a9cb410ff61f20015ad") + + def test_cipher(self): for mode in ['AES-128/CTR-BE', 'Serpent/GCM', 'ChaCha20Poly1305']: enc = botan2.cipher(mode, encrypt=True) (kmin, kmax) = enc.key_length() - print("%s: default nonce=%d update_size=%d key_min=%d key_max=%d" % - (mode, enc.default_nonce_length(), enc.update_granularity(), kmin, kmax)) + + self.assertTrue(kmin <= kmax) rng = botan2.rng() iv = rng.get(enc.default_nonce_length()) key = rng.get(kmax) pt = rng.get(21) - print(" plaintext %s (%d)" % (hex_encode(pt), len(pt))) - enc.set_key(key) enc.start(iv) @@ -122,61 +125,46 @@ def test(): assert not update_result ct = enc.finish(pt) - print(" ciphertext %s (%d)" % (hex_encode(ct), len(ct))) dec = botan2.cipher(mode, encrypt=False) dec.set_key(key) dec.start(iv) decrypted = dec.finish(ct) - print(" decrypted %s (%d)\n" % (hex_encode(decrypted), len(decrypted))) + self.assertEqual(decrypted, pt) - def test_mceliece(): - mce_priv = botan2.private_key('mce', [2960, 57], botan2.rng()) + def test_mceliece(self): + rng = botan2.rng() + mce_priv = botan2.private_key('mce', [2960, 57], rng) mce_pub = mce_priv.get_public_key() + self.assertEqual(mce_pub.estimated_strength(), 128) - mce_plaintext = 'mce plaintext' - mce_ad = 'mce AD' + mce_plaintext = rng.get(16) + mce_ad = rng.get(48) mce_ciphertext = botan2.mceies_encrypt(mce_pub, botan2.rng(), 'ChaCha20Poly1305', mce_plaintext, mce_ad) - print("mceies len(pt)=%d len(ct)=%d" % (len(mce_plaintext), len(mce_ciphertext))) - mce_decrypt = botan2.mceies_decrypt(mce_priv, 'ChaCha20Poly1305', mce_ciphertext, mce_ad) - print(" mceies plaintext \'%s\' (%d)" % (mce_plaintext, len(mce_plaintext))) - - # Since mceies_decrypt() returns bytes in Python3, the following line - # needs .decode('utf-8') to convert mce_decrypt from bytes to a - # text string (Unicode). - # You don't need to add .decode() if - # (a) your expected output is bytes rather than a text string, or - # (b) you are using Python2 rather than Python3. - print(" mceies decrypted \'%s\' (%d)" % (mce_decrypt.decode('utf-8'), len(mce_decrypt))) - - print("mce_pub %s/SHA-1 fingerprint: %s\nEstimated strength %s bits (len %d)\n" % ( - mce_pub.algo_name(), mce_pub.fingerprint("SHA-1"), - mce_pub.estimated_strength(), len(mce_pub.encoding()) - )) - - def test_rsa(): - rsapriv = botan2.private_key('rsa', 1536, botan2.rng()) + + self.assertEqual(mce_plaintext, mce_decrypt) + + def test_rsa(self): + rng = botan2.rng() + rsapriv = botan2.private_key('RSA', '1024', rng) rsapub = rsapriv.get_public_key() - print("rsapub %s SHA-1 fingerprint: %s estimated strength %d (len %d)" % ( - rsapub.algo_name(), rsapub.fingerprint("SHA-1"), - rsapub.estimated_strength(), len(rsapub.encoding()) - )) + self.assertEqual(rsapub.estimated_strength(), 80) + self.assertEqual(rsapub.algo_name(), 'RSA') + + enc = botan2.pk_op_encrypt(rsapub, "OAEP(SHA-256)") + dec = botan2.pk_op_decrypt(rsapriv, "OAEP(SHA-256)") + + symkey = rng.get(32) + ctext = enc.encrypt(symkey, rng) - dec = botan2.pk_op_decrypt(rsapriv, "EME1(SHA-256)") - enc = botan2.pk_op_encrypt(rsapub, "EME1(SHA-256)") + ptext = dec.decrypt(ctext) - sys_rng = botan2.rng() - symkey = sys_rng.get(32) - ctext = enc.encrypt(symkey, sys_rng) - print("ptext \'%s\' (%d)" % (hex_encode(symkey), len(symkey))) - print("ctext \'%s\' (%d)" % (hex_encode(ctext), len(ctext))) - print("decrypt \'%s\' (%d)\n" % (hex_encode(dec.decrypt(ctext)), - len(dec.decrypt(ctext)))) + self.assertEqual(ptext, symkey) signer = botan2.pk_op_sign(rsapriv, 'EMSA4(SHA-384)') @@ -184,29 +172,27 @@ def test(): signer.update('ge') sig = signer.finish(botan2.rng()) - print("EMSA4(SHA-384) signature: %s" % hex_encode(sig)) - verify = botan2.pk_op_verify(rsapub, 'EMSA4(SHA-384)') verify.update('mess') verify.update('age') - print("good sig accepted? %s" % verify.check_signature(sig)) + self.assertTrue(verify.check_signature(sig)) verify.update('mess of things') verify.update('age') - print("bad sig accepted? %s" % verify.check_signature(sig)) + self.assertFalse(verify.check_signature(sig)) verify.update('message') - print("good sig accepted? %s\n" % verify.check_signature(sig)) + self.assertTrue(verify.check_signature(sig)) - def test_dh(): + def test_dh(self): a_rng = botan2.rng('user') b_rng = botan2.rng('user') for dh_grp in ['secp256r1', 'curve25519']: dh_kdf = 'KDF2(SHA-384)'.encode('utf-8') - a_dh_priv = botan2.private_key('ecdh', dh_grp, botan2.rng()) - b_dh_priv = botan2.private_key('ecdh', dh_grp, botan2.rng()) + a_dh_priv = botan2.private_key('ecdh', dh_grp, a_rng) + b_dh_priv = botan2.private_key('ecdh', dh_grp, b_rng) a_dh = botan2.pk_op_key_agreement(a_dh_priv, dh_kdf) b_dh = botan2.pk_op_key_agreement(b_dh_priv, dh_kdf) @@ -214,66 +200,34 @@ def test(): a_dh_pub = a_dh.public_value() b_dh_pub = b_dh.public_value() - a_salt = a_rng.get(8) - b_salt = b_rng.get(8) - - print("ecdh %s pubs:\n %s (salt %s)\n %s (salt %s)\n" % - (dh_grp, - hex_encode(a_dh_pub), hex_encode(a_salt), - hex_encode(b_dh_pub), hex_encode(b_salt))) + salt = a_rng.get(8) + b_rng.get(8) - a_key = a_dh.agree(b_dh_pub, 32, a_salt + b_salt) - b_key = b_dh.agree(a_dh_pub, 32, a_salt + b_salt) + a_key = a_dh.agree(b_dh_pub, 32, salt) + b_key = b_dh.agree(a_dh_pub, 32, salt) - print("ecdh %s shared:\n %s\n %s\n" % - (dh_grp, hex_encode(a_key), hex_encode(b_key))) + self.assertEqual(a_key, b_key) - def test_certs(): + def test_certs(self): cert = botan2.x509_cert(filename="src/tests/data/x509/ecc/CSCA.CSCA.csca-germany.1.crt") - print("CSCA (Germany) Certificate\nDetails:") - print("SHA-1 fingerprint: %s" % cert.fingerprint("SHA-1")) - print("Expected: 32:42:1C:C3:EC:54:D7:E9:43:EC:51:F0:19:23:BD:85:1D:F2:1B:B9") + pubkey = cert.subject_public_key() - print("Not before: %s" % cert.time_starts()) - print("Not after: %s" % cert.time_expires()) + self.assertEqual(pubkey.algo_name(), 'ECDSA') + self.assertEqual(pubkey.estimated_strength(), 112) - print("Serial number: %s" % hex_encode(cert.serial_number())) - print("Authority Key ID: %s" % hex_encode(cert.authority_key_id())) - print("Subject Key ID: %s" % hex_encode(cert.subject_key_id())) - print("Public key bits:\n%s\n" % binascii.b2a_base64(cert.subject_public_key_bits())) + self.assertEqual(cert.fingerprint("SHA-1"), + "32:42:1C:C3:EC:54:D7:E9:43:EC:51:F0:19:23:BD:85:1D:F2:1B:B9") - pubkey = cert.subject_public_key() - print("Public key algo: %s" % pubkey.algo_name()) - print("Public key strength: %s" % pubkey.estimated_strength() + " bits") - - dn_fields = ("Name", "Email", "Organization", "Organizational Unit", "Country") - for field in dn_fields: - try: - print("%s: %s" % (field, cert.subject_dn(field, 0))) - except botan2.BotanException: - print("Field: %s not found in certificate" % field) - - print(cert.to_string()) - - test_version() - test_kdf() - test_pbkdf() - test_scrypt() - test_bcrypt() - test_hmac() - test_rng() - test_hash() - test_cipher() - test_mceliece() - test_rsa() - test_dh() - test_certs() - - -def main(args=None): - if args is None: - args = sys.argv - test() + self.assertEqual(hex_encode(cert.serial_number()), "01") + self.assertEqual(hex_encode(cert.authority_key_id()), + "0096452de588f966c4ccdf161dd1f3f5341b71e7") + + self.assertEqual(cert.subject_dn('Name', 0), 'csca-germany') + self.assertEqual(cert.subject_dn('Email', 0), '[email protected]') + self.assertEqual(cert.subject_dn('Organization', 0), 'bund') + self.assertEqual(cert.subject_dn('Organizational Unit', 0), 'bsi') + self.assertEqual(cert.subject_dn('Country', 0), 'DE') + + self.assertTrue(cert.to_string().startswith("Version: 3")) if __name__ == '__main__': - sys.exit(main()) + unittest.main() |