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# -*- coding: utf-8 -*-
# test_crypto.py
# Copyright (C) 2013 LEAP
#
# This program is free software: you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# This program 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 General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program. If not, see <http://www.gnu.org/licenses/>.
"""
Tests for cryptographic related stuff.
"""
import binascii
import base64
import json
import os

from io import BytesIO

import pytest

from cryptography.hazmat.primitives.ciphers import Cipher, algorithms, modes
from cryptography.hazmat.backends import default_backend
from cryptography.exceptions import InvalidTag

from leap.soledad.common.document import SoledadDocument
from test_soledad.util import BaseSoledadTest
from leap.soledad.client import _crypto

from twisted.trial import unittest
from twisted.internet import defer


snowden1 = (
    "You can't come up against "
    "the world's most powerful intelligence "
    "agencies and not accept the risk. "
    "If they want to get you, over time "
    "they will.")


class AESTest(unittest.TestCase):

    def test_chunked_encryption(self):
        key = 'A' * 32

        fd = BytesIO()
        aes = _crypto.AESWriter(key, _buffer=fd)
        iv = aes.iv

        data = snowden1
        block = 16

        for i in range(len(data) / block):
            chunk = data[i * block:(i + 1) * block]
            aes.write(chunk)
        aes.end()

        ciphertext_chunked = fd.getvalue()
        ciphertext, tag = _aes_encrypt(key, iv, data)

        assert ciphertext_chunked == ciphertext

    def test_decrypt(self):
        key = 'A' * 32
        iv = 'A' * 16

        data = snowden1
        block = 16

        ciphertext, tag = _aes_encrypt(key, iv, data)

        fd = BytesIO()
        aes = _crypto.AESWriter(key, iv, fd, tag=tag)

        for i in range(len(ciphertext) / block):
            chunk = ciphertext[i * block:(i + 1) * block]
            aes.write(chunk)
        aes.end()

        cleartext_chunked = fd.getvalue()
        assert cleartext_chunked == data


class BlobTestCase(unittest.TestCase):

    class doc_info:
        doc_id = 'D-deadbeef'
        rev = '397932e0c77f45fcb7c3732930e7e9b2:1'

    @defer.inlineCallbacks
    def test_blob_encryptor(self):

        inf = BytesIO(snowden1)

        blob = _crypto.BlobEncryptor(
            self.doc_info, inf,
            secret='A' * 96)

        encrypted = yield blob.encrypt()
        preamble, ciphertext = _crypto._split(encrypted.getvalue())
        ciphertext = ciphertext[:-16]

        assert len(preamble) == _crypto.PACMAN.size
        unpacked_data = _crypto.PACMAN.unpack(preamble)
        magic, sch, meth, ts, iv, doc_id, rev = unpacked_data
        assert magic == _crypto.BLOB_SIGNATURE_MAGIC
        assert sch == 1
        assert meth == _crypto.ENC_METHOD.aes_256_gcm
        assert iv == blob.iv
        assert doc_id == 'D-deadbeef'
        assert rev == self.doc_info.rev

        aes_key = _crypto._get_sym_key_for_doc(
            self.doc_info.doc_id, 'A' * 96)
        assert ciphertext == _aes_encrypt(aes_key, blob.iv, snowden1)[0]

        decrypted = _aes_decrypt(aes_key, blob.iv, blob.tag, ciphertext,
                                 preamble)
        assert str(decrypted) == snowden1

    @defer.inlineCallbacks
    def test_blob_decryptor(self):

        inf = BytesIO(snowden1)

        blob = _crypto.BlobEncryptor(
            self.doc_info, inf,
            secret='A' * 96)
        ciphertext = yield blob.encrypt()

        decryptor = _crypto.BlobDecryptor(
            self.doc_info, ciphertext,
            secret='A' * 96)
        decrypted = yield decryptor.decrypt()
        assert decrypted == snowden1

    @defer.inlineCallbacks
    def test_encrypt_and_decrypt(self):
        """
        Check that encrypting and decrypting gives same doc.
        """
        crypto = _crypto.SoledadCrypto('A' * 96)
        payload = {'key': 'someval'}
        doc1 = SoledadDocument('id1', '1', json.dumps(payload))

        encrypted = yield crypto.encrypt_doc(doc1)
        assert encrypted != payload
        assert 'raw' in encrypted
        doc2 = SoledadDocument('id1', '1')
        doc2.set_json(encrypted)
        assert _crypto.is_symmetrically_encrypted(encrypted)
        decrypted = yield crypto.decrypt_doc(doc2)
        assert len(decrypted) != 0
        assert json.loads(decrypted) == payload

    @defer.inlineCallbacks
    def test_decrypt_with_wrong_tag_raises(self):
        """
        Trying to decrypt a document with wrong MAC should raise.
        """
        crypto = _crypto.SoledadCrypto('A' * 96)
        payload = {'key': 'someval'}
        doc1 = SoledadDocument('id1', '1', json.dumps(payload))

        encrypted = yield crypto.encrypt_doc(doc1)
        encdict = json.loads(encrypted)
        preamble, raw = _crypto._split(str(encdict['raw']))
        # mess with tag
        messed = raw[:-16] + '0' * 16

        preamble = base64.urlsafe_b64encode(preamble)
        newraw = preamble + ' ' + base64.urlsafe_b64encode(str(messed))
        doc2 = SoledadDocument('id1', '1')
        doc2.set_json(json.dumps({"raw": str(newraw)}))

        with pytest.raises(_crypto.InvalidBlob):
            yield crypto.decrypt_doc(doc2)


class SoledadSecretsTestCase(BaseSoledadTest):

    def test_generated_secrets_have_correct_length(self):
        expected = self._soledad.secrets.lengths
        for name, length in expected.iteritems():
            secret = getattr(self._soledad.secrets, name)
            self.assertEqual(length, len(secret))


class SoledadCryptoAESTestCase(BaseSoledadTest):

    def test_encrypt_decrypt_sym(self):
        # generate 256-bit key
        key = os.urandom(32)
        iv, cyphertext = _crypto.encrypt_sym('data', key)
        self.assertTrue(cyphertext is not None)
        self.assertTrue(cyphertext != '')
        self.assertTrue(cyphertext != 'data')
        plaintext = _crypto.decrypt_sym(cyphertext, key, iv)
        self.assertEqual('data', plaintext)

    def test_decrypt_with_wrong_iv_raises(self):
        key = os.urandom(32)
        iv, cyphertext = _crypto.encrypt_sym('data', key)
        self.assertTrue(cyphertext is not None)
        self.assertTrue(cyphertext != '')
        self.assertTrue(cyphertext != 'data')
        # get a different iv by changing the first byte
        rawiv = binascii.a2b_base64(iv)
        wrongiv = rawiv
        while wrongiv == rawiv:
            wrongiv = os.urandom(1) + rawiv[1:]
        with pytest.raises(InvalidTag):
            _crypto.decrypt_sym(
                cyphertext, key, iv=binascii.b2a_base64(wrongiv))

    def test_decrypt_with_wrong_key_raises(self):
        key = os.urandom(32)
        iv, cyphertext = _crypto.encrypt_sym('data', key)
        self.assertTrue(cyphertext is not None)
        self.assertTrue(cyphertext != '')
        self.assertTrue(cyphertext != 'data')
        wrongkey = os.urandom(32)  # 256-bits key
        # ensure keys are different in case we are extremely lucky
        while wrongkey == key:
            wrongkey = os.urandom(32)
        with pytest.raises(InvalidTag):
            _crypto.decrypt_sym(cyphertext, wrongkey, iv)


def _aes_encrypt(key, iv, data):
    backend = default_backend()
    cipher = Cipher(algorithms.AES(key), modes.GCM(iv), backend=backend)
    encryptor = cipher.encryptor()
    return encryptor.update(data) + encryptor.finalize(), encryptor.tag


def _aes_decrypt(key, iv, tag, data, aead=''):
    backend = default_backend()
    cipher = Cipher(algorithms.AES(key), modes.GCM(iv, tag), backend=backend)
    decryptor = cipher.decryptor()
    if aead:
        decryptor.authenticate_additional_data(aead)
    return decryptor.update(data) + decryptor.finalize()