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DEV: Allow CheckpointManagers to optimize for shared backends....
DEV: Allow CheckpointManagers to optimize for shared backends. On `create_checkpoint` and `restore_checkpoint`, pass a path and a `ContentsManager` to `CheckpointManager` instead of an already-loaded model. The `CheckpointManager` base class provides a correct implementation of these methods that's generic across any ContentsManager, but subclasses are free to specialize when the storage backend of `ContentsManager` is shared.

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test_sign.py
191 lines | 6.7 KiB | text/x-python | PythonLexer
"""Test Notebook signing"""
# Copyright (c) IPython Development Team.
# Distributed under the terms of the Modified BSD License.
import copy
import time
from .base import TestsBase
from IPython.nbformat import read, sign
from IPython.core.getipython import get_ipython
class TestNotary(TestsBase):
def setUp(self):
self.notary = sign.NotebookNotary(
db_file=':memory:',
secret=b'secret',
profile_dir=get_ipython().profile_dir,
)
with self.fopen(u'test3.ipynb', u'r') as f:
self.nb = read(f, as_version=4)
with self.fopen(u'test3.ipynb', u'r') as f:
self.nb3 = read(f, as_version=3)
def test_algorithms(self):
last_sig = ''
for algo in sign.algorithms:
self.notary.algorithm = algo
sig = self.notary.compute_signature(self.nb)
self.assertNotEqual(last_sig, sig)
last_sig = sig
def test_sign_same(self):
"""Multiple signatures of the same notebook are the same"""
sig1 = self.notary.compute_signature(self.nb)
sig2 = self.notary.compute_signature(self.nb)
self.assertEqual(sig1, sig2)
def test_change_secret(self):
"""Changing the secret changes the signature"""
sig1 = self.notary.compute_signature(self.nb)
self.notary.secret = b'different'
sig2 = self.notary.compute_signature(self.nb)
self.assertNotEqual(sig1, sig2)
def test_sign(self):
self.assertFalse(self.notary.check_signature(self.nb))
self.notary.sign(self.nb)
self.assertTrue(self.notary.check_signature(self.nb))
def test_unsign(self):
self.notary.sign(self.nb)
self.assertTrue(self.notary.check_signature(self.nb))
self.notary.unsign(self.nb)
self.assertFalse(self.notary.check_signature(self.nb))
self.notary.unsign(self.nb)
self.assertFalse(self.notary.check_signature(self.nb))
def test_cull_db(self):
# this test has various sleeps of 2ms
# to ensure low resolution timestamps compare as expected
dt = 2e-3
nbs = [
copy.deepcopy(self.nb) for i in range(10)
]
for row in self.notary.db.execute("SELECT * FROM nbsignatures"):
print(row)
self.notary.cache_size = 8
for i, nb in enumerate(nbs[:8]):
nb.metadata.dirty = i
self.notary.sign(nb)
for i, nb in enumerate(nbs[:8]):
time.sleep(dt)
self.assertTrue(self.notary.check_signature(nb), 'nb %i is trusted' % i)
# signing the 9th triggers culling of first 3
# (75% of 8 = 6, 9 - 6 = 3 culled)
self.notary.sign(nbs[8])
self.assertFalse(self.notary.check_signature(nbs[0]))
self.assertFalse(self.notary.check_signature(nbs[1]))
self.assertFalse(self.notary.check_signature(nbs[2]))
self.assertTrue(self.notary.check_signature(nbs[3]))
# checking nb3 should keep it from being culled:
self.notary.sign(nbs[0])
self.notary.sign(nbs[1])
self.notary.sign(nbs[2])
self.assertTrue(self.notary.check_signature(nbs[3]))
self.assertFalse(self.notary.check_signature(nbs[4]))
def test_check_signature(self):
nb = self.nb
md = nb.metadata
notary = self.notary
check_signature = notary.check_signature
# no signature:
md.pop('signature', None)
self.assertFalse(check_signature(nb))
# hash only, no algo
md.signature = notary.compute_signature(nb)
self.assertFalse(check_signature(nb))
# proper signature, algo mismatch
notary.algorithm = 'sha224'
notary.sign(nb)
notary.algorithm = 'sha256'
self.assertFalse(check_signature(nb))
# check correctly signed notebook
notary.sign(nb)
self.assertTrue(check_signature(nb))
def test_mark_cells_untrusted(self):
cells = self.nb.cells
self.notary.mark_cells(self.nb, False)
for cell in cells:
self.assertNotIn('trusted', cell)
if cell.cell_type == 'code':
self.assertIn('trusted', cell.metadata)
self.assertFalse(cell.metadata.trusted)
else:
self.assertNotIn('trusted', cell.metadata)
def test_mark_cells_trusted(self):
cells = self.nb.cells
self.notary.mark_cells(self.nb, True)
for cell in cells:
self.assertNotIn('trusted', cell)
if cell.cell_type == 'code':
self.assertIn('trusted', cell.metadata)
self.assertTrue(cell.metadata.trusted)
else:
self.assertNotIn('trusted', cell.metadata)
def test_check_cells(self):
nb = self.nb
self.notary.mark_cells(nb, True)
self.assertTrue(self.notary.check_cells(nb))
for cell in nb.cells:
self.assertNotIn('trusted', cell)
self.notary.mark_cells(nb, False)
self.assertFalse(self.notary.check_cells(nb))
for cell in nb.cells:
self.assertNotIn('trusted', cell)
def test_trust_no_output(self):
nb = self.nb
self.notary.mark_cells(nb, False)
for cell in nb.cells:
if cell.cell_type == 'code':
cell.outputs = []
self.assertTrue(self.notary.check_cells(nb))
def test_mark_cells_untrusted_v3(self):
nb = self.nb3
cells = nb.worksheets[0].cells
self.notary.mark_cells(nb, False)
for cell in cells:
self.assertNotIn('trusted', cell)
if cell.cell_type == 'code':
self.assertIn('trusted', cell.metadata)
self.assertFalse(cell.metadata.trusted)
else:
self.assertNotIn('trusted', cell.metadata)
def test_mark_cells_trusted_v3(self):
nb = self.nb3
cells = nb.worksheets[0].cells
self.notary.mark_cells(nb, True)
for cell in cells:
self.assertNotIn('trusted', cell)
if cell.cell_type == 'code':
self.assertIn('trusted', cell.metadata)
self.assertTrue(cell.metadata.trusted)
else:
self.assertNotIn('trusted', cell.metadata)
def test_check_cells_v3(self):
nb = self.nb3
cells = nb.worksheets[0].cells
self.notary.mark_cells(nb, True)
self.assertTrue(self.notary.check_cells(nb))
for cell in cells:
self.assertNotIn('trusted', cell)
self.notary.mark_cells(nb, False)
self.assertFalse(self.notary.check_cells(nb))
for cell in cells:
self.assertNotIn('trusted', cell)