def test_encrypted_signed_compressed_message(self):
""" Test Encrypted Signed Compressed Message """
# Build an As2 message to be transmitted to partner
self.partner.sign = True
self.partner.encrypt = True
self.partner.compress = True
out_message = as2.Message(self.org, self.partner)
out_message.build(self.test_data)
raw_out_message = out_message.headers_str + b"\r\n" + out_message.content
# Parse the generated AS2 message as the partner
in_message = as2.Message()
status, _, _ = in_message.parse(
raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=self.find_partner,
)
# Compare the mic contents of the input and output messages
self.assertEqual(status, "processed")
self.assertTrue(in_message.signed)
self.assertTrue(in_message.encrypted)
self.assertTrue(in_message.compressed)
self.assertEqual(out_message.mic, in_message.mic)
self.assertEqual(self.test_data.splitlines(), in_message.content.splitlines())
def test_message_checks(self):
"""Test the checks and other features of Message."""
msg = as2.Message()
assert msg.content == ""
assert msg.headers == {}
assert msg.headers_str == b""
msg.payload = message.Message()
msg.payload.set_payload(b"data")
assert msg.content == b"data"
org = as2.Organization(as2_name="AS2 Server")
partner = as2.Partner(as2_name="AS2 Partner", sign=True)
msg = as2.Message(sender=org, receiver=partner)
with self.assertRaises(ImproperlyConfigured):
msg.build(b"data")
msg.receiver.sign = False
msg.receiver.encrypt = True
with self.assertRaises(ImproperlyConfigured):
msg.build(b"data")
msg.receiver.encrypt = False
msg.receiver.mdn_mode = "ASYNC"
with self.assertRaises(ImproperlyConfigured):
msg.build(b"data")
msg.sender.mdn_url = "http://localhost/pyas2/as2receive"
msg.build(b"data")
def test_insufficient_security(self):
""" Test case where message security is not as per the configuration """
# Build an As2 message to be transmitted to partner
self.partner.mdn_mode = as2.SYNCHRONOUS_MDN
self.out_message = as2.Message(self.org, self.partner)
self.out_message.build(self.test_data)
# Parse the generated AS2 message as the partner
self.partner.encrypt = True
raw_out_message = \
self.out_message.headers_str + b'\r\n' + self.out_message.content
in_message = as2.Message()
status, (exc, _), mdn = in_message.parse(
raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=self.find_partner,
find_message_cb=lambda x, y: False
)
self.assertEqual(status, 'processed/Error')
self.assertEqual(exc.disposition_modifier, 'insufficient-message-security')
# Try again for signing check
self.partner.encrypt = False
self.partner.sign = True
in_message = as2.Message()
status, (exc, _), mdn = in_message.parse(
raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=self.find_partner,
find_message_cb=lambda x, y: False
)
self.assertEqual(status, 'processed/Error')
self.assertEqual(exc.disposition_modifier, 'insufficient-message-security')
def test_binary_message(self):
""" Test Encrypted Signed Binary Message """
# Build an As2 message to be transmitted to partner
self.partner.sign = True
self.partner.encrypt = True
self.partner.compress = True
out_message = as2.Message(self.org, self.partner)
test_message_path = os.path.join(TEST_DIR, "payload.binary")
with open(test_message_path, "rb") as bin_file:
original_message = bin_file.read()
out_message.build(
original_message,
filename="payload.binary",
content_type="application/octet-stream",
)
raw_out_message = out_message.headers_str + b"\r\n" + out_message.content
# Parse the generated AS2 message as the partner
in_message = as2.Message()
status, _, _ = in_message.parse(
raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=self.find_partner,
find_message_cb=lambda x, y: False,
)
# Compare the mic contents of the input and output messages
self.assertEqual(status, "processed")
self.assertEqual(original_message,
in_message.payload.get_payload(decode=True))
self.assertTrue(in_message.signed)
self.assertTrue(in_message.encrypted)
self.assertEqual(out_message.mic, in_message.mic)
def test_failed_decompression(self):
""" Test case where message decompression has failed """
# Build an As2 message to be transmitted to partner
self.partner.compress = True
self.partner.mdn_mode = as2.SYNCHRONOUS_MDN
self.out_message = as2.Message(self.org, self.partner)
self.out_message.build(self.test_data)
# Parse the generated AS2 message as the partner
raw_out_message = (self.out_message.headers_str + b"\r\n" +
base64.b64encode(b"xxxxx"))
in_message = as2.Message()
_, exec_info, mdn = in_message.parse(
raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=self.find_partner,
)
out_mdn = as2.Mdn()
status, detailed_status = out_mdn.parse(
mdn.headers_str + b"\r\n" + mdn.content,
find_message_cb=self.find_message)
self.assertEqual(status, "processed/Error")
self.assertEqual(detailed_status, "decompression-failed")
def test_failed_signature(self):
""" Test case where signature verification has failed """
# Build an As2 message to be transmitted to partner
self.partner.sign = True
self.partner.verify_cert = self.mecas2_public_key
self.partner.validate_certs = False
self.partner.mdn_mode = as2.SYNCHRONOUS_MDN
self.out_message = as2.Message(self.org, self.partner)
self.out_message.build(self.test_data)
# Parse the generated AS2 message as the partner
raw_out_message = (self.out_message.headers_str + b"\r\n" +
self.out_message.content)
in_message = as2.Message()
_, exec_info, mdn = in_message.parse(
raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=self.find_partner,
find_message_cb=lambda x, y: False,
)
out_mdn = as2.Mdn()
status, detailed_status = out_mdn.parse(
mdn.headers_str + b"\r\n" + mdn.content,
find_message_cb=self.find_message)
self.assertEqual(status, "processed/Error")
self.assertEqual(detailed_status, "authentication-failed")
def test_failed_decryption(self):
""" Test case where message decryption has failed """
# Build an As2 message to be transmitted to partner
self.partner.encrypt = True
self.partner.encrypt_cert = self.mecas2_public_key
self.partner.validate_certs = False
self.partner.mdn_mode = as2.SYNCHRONOUS_MDN
self.out_message = as2.Message(self.org, self.partner)
self.out_message.build(self.test_data)
# Parse the generated AS2 message as the partner
raw_out_message = \
self.out_message.headers_str + b'\r\n' + self.out_message.content
in_message = as2.Message()
_, exec_info, mdn = in_message.parse(
raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=self.find_partner,
find_message_cb=lambda x, y: False
)
out_mdn = as2.Mdn()
status, detailed_status = out_mdn.parse(
mdn.headers_str + b'\r\n' + mdn.content,
find_message_cb=self.find_message
)
self.assertEqual(status, 'processed/Error')
self.assertEqual(detailed_status, 'decryption-failed')
def test_duplicate_message(self):
""" Test case where a duplicate message is sent to the partner """
# Build an As2 message to be transmitted to partner
self.partner.sign = True
self.partner.encrypt = True
self.partner.mdn_mode = as2.SYNCHRONOUS_MDN
self.out_message = as2.Message(self.org, self.partner)
self.out_message.build(self.test_data)
# Parse the generated AS2 message as the partner
raw_out_message = (self.out_message.headers_str + b"\r\n" +
self.out_message.content)
in_message = as2.Message()
_, _, mdn = in_message.parse(
raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=self.find_partner,
find_message_cb=lambda x, y: True,
)
out_mdn = as2.Mdn()
status, detailed_status = out_mdn.parse(
mdn.headers_str + b"\r\n" + mdn.content,
find_message_cb=self.find_message)
self.assertEqual(status, "processed/Warning")
self.assertEqual(detailed_status, "duplicate-document")
def test_signed_mdn(self):
""" Test signed MDN generation and parsing """
# Build an As2 message to be transmitted to partner
self.partner.sign = True
self.partner.encrypt = True
self.partner.mdn_mode = as2.SYNCHRONOUS_MDN
self.partner.mdn_digest_alg = "sha256"
self.out_message = as2.Message(self.org, self.partner)
self.out_message.build(self.test_data)
# Parse the generated AS2 message as the partner
raw_out_message = (
self.out_message.headers_str + b"\r\n" + self.out_message.content
)
in_message = as2.Message()
_, _, mdn = in_message.parse(
raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=self.find_partner,
)
out_mdn = as2.Mdn()
status, detailed_status = out_mdn.parse(
mdn.headers_str + b"\r\n" + mdn.content, find_message_cb=self.find_message
)
self.assertEqual(status, "processed")
def test_non_matching_mic(self):
"""Test the case where a the mic in the mdn does not match the mic in the message."""
self.partner.mdn_mode = as2.SYNCHRONOUS_MDN
self.partner.sign = True
self.out_message = as2.Message(self.org, self.partner)
self.out_message.build(self.test_data)
# Parse the generated AS2 message as the partner
raw_out_message = (self.out_message.headers_str + b"\r\n" +
self.out_message.content)
in_message = as2.Message()
_, _, mdn = in_message.parse(
raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=self.find_partner,
find_message_cb=lambda x, y: False,
)
# Set the mdn sig alg and parse it
self.out_message.mic = b"dummy value"
out_mdn = as2.Mdn()
status, detailed_status = out_mdn.parse(
mdn.headers_str + b"\r\n" + mdn.content,
find_message_cb=self.find_message)
self.assertEqual(status, "processed/warning")
self.assertEqual(detailed_status, "Message Integrity check failed.")
def test_unsigned_mdn_sent_error(self):
"""Test the case where a signed mdn was expected but unsigned mdn was returned."""
self.partner.mdn_mode = as2.SYNCHRONOUS_MDN
self.out_message = as2.Message(self.org, self.partner)
self.out_message.build(self.test_data)
# Parse the generated AS2 message as the partner
raw_out_message = (self.out_message.headers_str + b"\r\n" +
self.out_message.content)
in_message = as2.Message()
_, _, mdn = in_message.parse(
raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=self.find_partner,
find_message_cb=lambda x, y: False,
)
# Set the mdn sig alg and parse it
self.partner.mdn_digest_alg = "sha256"
out_mdn = as2.Mdn()
status, detailed_status = out_mdn.parse(
mdn.headers_str + b"\r\n" + mdn.content,
find_message_cb=self.find_message)
self.assertEqual(status, "failed/Failure")
self.assertEqual(detailed_status,
"Expected signed MDN but unsigned MDN returned")
def test_failed_mdn_parse(self):
"""Test mdn parsing failures are captured."""
# Build an As2 message to be transmitted to partner
self.partner.sign = True
self.partner.encrypt = True
self.partner.mdn_mode = as2.SYNCHRONOUS_MDN
self.partner.mdn_digest_alg = 'sha256'
self.out_message = as2.Message(self.org, self.partner)
self.out_message.build(self.test_data)
# Parse the generated AS2 message as the partner
raw_out_message = \
self.out_message.headers_str + b'\r\n' + self.out_message.content
in_message = as2.Message()
_, _, mdn = in_message.parse(raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=self.find_partner)
out_mdn = as2.Mdn()
self.partner.verify_cert = self.mecas2_public_key
self.partner.validate_certs = False
status, detailed_status = out_mdn.parse(
mdn.headers_str + b'\r\n' + mdn.content,
find_message_cb=self.find_message)
self.assertEqual(status, 'failed/Failure')
self.assertEqual(
detailed_status,
'Failed to parse received MDN. Failed to verify message signature: '
'Message Digest does not match.')
def test_partner_not_found(self):
""" Test case where partner and organization is not found """
# Build an As2 message to be transmitted to partner
self.partner.sign = True
self.partner.encrypt = True
self.partner.mdn_mode = as2.SYNCHRONOUS_MDN
self.out_message = as2.Message(self.org, self.partner)
self.out_message.build(self.test_data)
# Parse the generated AS2 message as the partner
raw_out_message = \
self.out_message.headers_str + b'\r\n' + self.out_message.content
in_message = as2.Message()
_, _, mdn = in_message.parse(
raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=lambda x: None,
find_message_cb=lambda x, y: False
)
out_mdn = as2.Mdn()
status, detailed_status = out_mdn.parse(
mdn.headers_str + b'\r\n' + mdn.content,
find_message_cb=self.find_message
)
self.assertEqual(status, 'processed/Error')
self.assertEqual(detailed_status, 'unknown-trading-partner')
# Parse again but this time make without organization
in_message = as2.Message()
_, _, mdn = in_message.parse(
raw_out_message,
find_org_cb=lambda x: None,
find_partner_cb=self.find_partner,
find_message_cb=lambda x, y: False
)
out_mdn = as2.Mdn()
status, detailed_status = out_mdn.parse(
mdn.headers_str + b'\r\n' + mdn.content,
find_message_cb=self.find_message
)
self.assertEqual(status, 'processed/Error')
self.assertEqual(detailed_status, 'unknown-trading-partner')
def test_plain_message(self):
""" Test Unencrypted Unsigned Uncompressed Message """
# Build an As2 message to be transmitted to partner
out_message = as2.Message(self.org, self.partner)
out_message.build(self.test_data)
raw_out_message = \
out_message.headers_str + b'\r\n' + out_message.content
# Parse the generated AS2 message as the partner
in_message = as2.Message()
status, _, _ = in_message.parse(raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=self.find_partner)
# Compare contents of the input and output messages
self.assertEqual(status, 'processed')
self.assertEqual(self.test_data, in_message.content)
def test_process_mdn(self):
""" Test processing mdn received from Sterling Integrator"""
msg = as2.Message(sender=self.org, receiver=self.partner)
msg.message_id = '*****@*****.**'
as2mdn = as2.Mdn()
# Parse the mdn and get the message status
with open(os.path.join(TEST_DIR, 'sb2bi_signed.mdn'), 'rb') as mdn:
status, detailed_status = as2mdn.parse(mdn.read(), lambda x, y: msg)
self.assertEqual(status, 'processed')
def test_process_message(self):
""" Test processing message received from Sterling Integrator"""
with open(os.path.join(TEST_DIR, "sb2bi_signed_cmp.msg"), "rb") as msg:
as2message = as2.Message()
status, exception, as2mdn = as2message.parse(
msg.read(),
lambda x: self.org,
lambda y: self.partner,
lambda x, y: False,
)
self.assertEqual(status, "processed")
def test_encrypted_signed_message_dos(self):
""" Test Encrypted Signed Uncompressed Message with DOS line endings. """
# Build an As2 message to be transmitted to partner
self.partner.sign = True
self.partner.encrypt = True
out_message = as2.Message(self.org, self.partner)
out_message.build(self.test_data_dos)
raw_out_message = out_message.headers_str + b'\r\n' + out_message.content
# Parse the generated AS2 message as the partner
in_message = as2.Message()
status, _, _ = in_message.parse(raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=self.find_partner)
# Compare the mic contents of the input and output messages
self.assertEqual(status, 'processed')
self.assertTrue(in_message.signed)
self.assertTrue(in_message.encrypted)
self.assertEqual(out_message.mic, in_message.mic)
self.assertEqual(self.test_data_dos, in_message.content)
def test_compressed_message(self):
""" Test Compressed Message received from Mendelson AS2"""
# Parse the generated AS2 message as the partner
received_file = os.path.join(TEST_DIR, 'mecas2_compressed.as2')
with open(received_file, 'rb') as fp:
in_message = as2.Message()
in_message.parse(fp.read(),
find_org_cb=self.find_org,
find_partner_cb=self.find_partner)
# Compare the mic contents of the input and output messages
self.assertTrue(in_message.compressed)
self.assertEqual(self.test_data, in_message.content)
def test_signed_message(self):
""" Test Unencrypted Signed Uncompressed Message from Mendelson AS2"""
# Parse the generated AS2 message as the partner
received_file = os.path.join(TEST_DIR, "mecas2_signed.as2")
with open(received_file, "rb") as fp:
in_message = as2.Message()
in_message.parse(fp.read(),
find_org_cb=self.find_org,
find_partner_cb=self.find_partner)
# Compare the mic contents of the input and output messages
self.assertTrue(in_message.signed)
self.assertEqual(in_message.digest_alg, "sha1")
self.assertEqual(self.test_data, in_message.content)
def test_all_encryption_algos(self):
"""Test all the available encryption algorithms."""
algos = ['rc2_128_cbc', 'rc4_128_cbc', 'aes_128_cbc', 'aes_192_cbc', 'aes_256_cbc']
for algo in algos:
# Build an As2 message to be transmitted to partner
self.partner.encrypt = True
self.partner.enc_alg = algo
out_message = as2.Message(self.org, self.partner)
out_message.build(self.test_data)
raw_out_message = out_message.headers_str + b'\r\n' + out_message.content
# Parse the generated AS2 message as the partner
in_message = as2.Message()
status, _, _ = in_message.parse(
raw_out_message,
find_org_cb=self.find_org,
find_partner_cb=self.find_partner
)
# Compare the mic contents of the input and output messages
self.assertEqual(status, 'processed')
self.assertTrue(in_message.encrypted)
self.assertEqual(self.test_data.splitlines(), in_message.content.splitlines())
def test_mdn_not_found(self):
"""Test that the MDN parser raises MDN not found when a non MDN message is passed."""
self.partner.encrypt = True
self.partner.validate_certs = False
self.partner.mdn_mode = as2.SYNCHRONOUS_MDN
self.out_message = as2.Message(self.org, self.partner)
self.out_message.build(self.test_data)
# Parse the AS2 message as an MDN
mdn = as2.Mdn()
raw_out_message = (self.out_message.headers_str + b"\r\n" +
self.out_message.content)
status, detailed_status = mdn.parse(raw_out_message,
find_message_cb=self.find_message)
self.assertEqual(status, "failed/Failure")
self.assertEqual(detailed_status, "mdn-not-found")
def test_encrypted_signed_compressed_message(self):
""" Test Encrypted Signed Compressed Message from Mendelson AS2"""
# Parse the generated AS2 message as the partner
received_file = os.path.join(TEST_DIR,
'mecas2_compressed_signed_encrypted.as2')
with open(received_file, 'rb') as fp:
in_message = as2.Message()
in_message.parse(fp.read(),
find_org_cb=self.find_org,
find_partner_cb=self.find_partner)
# Compare the mic contents of the input and output messages
self.assertTrue(in_message.encrypted)
self.assertEqual(in_message.enc_alg, 'tripledes_192_cbc')
self.assertTrue(in_message.signed)
self.assertEqual(in_message.digest_alg, 'sha1')
self.assertEqual(self.test_data, in_message.content)
def test_encrypted_message(self):
""" Send Encrypted Unsigned Uncompressed Message to Mendelson AS2"""
self.partner.encrypt = True
self.out_message = as2.Message(self.org, self.partner)
self.out_message.build(self.test_data)
response = requests.post('http://localhost:8080/pyas2/as2receive',
headers=self.out_message.headers,
data=self.out_message.content)
raw_mdn = ''
for k, v in response.headers.items():
raw_mdn += '{}: {}\n'.format(k, v)
raw_mdn = raw_mdn + '\n' + response.text
out_mdn = as2.Mdn()
status, detailed_status = out_mdn.parse(
raw_mdn, find_message_cb=self.find_message)
self.assertEqual(status, 'processed')
def test_signed_message(self):
""" Send Unencrypted Signed Uncompressed Message to Mendelson AS2"""
self.partner.sign = True
self.out_message = as2.Message(self.org, self.partner)
self.out_message.build(self.test_data)
response = requests.post(
"http://localhost:8080/pyas2/as2receive",
data=self.out_message.content,
headers=self.out_message.headers,
)
raw_mdn = ""
for k, v in response.headers.items():
raw_mdn += "{}: {}\n".format(k, v)
raw_mdn = raw_mdn + "\n" + response.text
out_mdn = as2.Mdn()
status, detailed_status = out_mdn.parse(
raw_mdn, find_message_cb=self.find_message)
self.assertEqual(status, "processed")
def find_message(self, message_id, message_recipient):
message = as2.Message()
message.sender = self.org
message.receiver = self.partner
message.mic = b"O4bvrm5t2YunRfwvZicNdEUmPaPZ9vUslX8loVLDck0="
return message
