# Copyright (C) 2005-2011 Canonical Ltd # # 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 2 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, write to the Free Software # Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA import breezy from .. import ( errors, lockdir, osutils, transport, ) from ..lockable_files import LockableFiles, TransportLock from . import ( TestCaseInTempDir, TestNotApplicable, ) from ..bzr.tests.test_smart import TestCaseWithSmartMedium from .test_transactions import DummyWeave from ..transactions import (PassThroughTransaction, ReadOnlyTransaction, WriteTransaction, ) # these tests are applied in each parameterized suite for LockableFiles # # they use an old style of parameterization, but we want to remove this class # so won't modernize them now. - mbp 20080430 class _TestLockableFiles_mixin(object): def test_transactions(self): self.assertIs(self.lockable.get_transaction().__class__, PassThroughTransaction) self.lockable.lock_read() try: self.assertIs(self.lockable.get_transaction().__class__, ReadOnlyTransaction) finally: self.lockable.unlock() self.assertIs(self.lockable.get_transaction().__class__, PassThroughTransaction) self.lockable.lock_write() self.assertIs(self.lockable.get_transaction().__class__, WriteTransaction) # check that finish is called: vf = DummyWeave('a') self.lockable.get_transaction().register_dirty(vf) self.lockable.unlock() self.assertTrue(vf.finished) def test__escape(self): self.assertEqual('%25', self.lockable._escape('%')) def test__escape_empty(self): self.assertEqual('', self.lockable._escape('')) def test_break_lock(self): # some locks are not breakable self.lockable.lock_write() try: self.assertRaises(AssertionError, self.lockable.break_lock) except NotImplementedError: # this lock cannot be broken self.lockable.unlock() raise TestNotApplicable("%r is not breakable" % (self.lockable,)) l2 = self.get_lockable() orig_factory = breezy.ui.ui_factory # silent ui - no need for stdout breezy.ui.ui_factory = breezy.ui.CannedInputUIFactory([True]) try: l2.break_lock() finally: breezy.ui.ui_factory = orig_factory try: l2.lock_write() l2.unlock() finally: self.assertRaises(errors.LockBroken, self.lockable.unlock) self.assertFalse(self.lockable.is_locked()) def test_lock_write_returns_None_refuses_token(self): token = self.lockable.lock_write() self.addCleanup(self.lockable.unlock) if token is not None: # This test does not apply, because this lockable supports # tokens. raise TestNotApplicable("%r uses tokens" % (self.lockable,)) self.assertRaises(errors.TokenLockingNotSupported, self.lockable.lock_write, token='token') def test_lock_write_returns_token_when_given_token(self): token = self.lockable.lock_write() self.addCleanup(self.lockable.unlock) if token is None: # This test does not apply, because this lockable refuses # tokens. return new_lockable = self.get_lockable() token_from_new_lockable = new_lockable.lock_write(token=token) self.addCleanup(new_lockable.unlock) self.assertEqual(token, token_from_new_lockable) def test_lock_write_raises_on_token_mismatch(self): token = self.lockable.lock_write() self.addCleanup(self.lockable.unlock) if token is None: # This test does not apply, because this lockable refuses # tokens. return different_token = token + b'xxx' # Re-using the same lockable instance with a different token will # raise TokenMismatch. self.assertRaises(errors.TokenMismatch, self.lockable.lock_write, token=different_token) # A separate instance for the same lockable will also raise # TokenMismatch. # This detects the case where a caller claims to have a lock (via # the token) for an external resource, but doesn't (the token is # different). Clients need a separate lock object to make sure the # external resource is probed, whereas the existing lock object # might cache. new_lockable = self.get_lockable() self.assertRaises(errors.TokenMismatch, new_lockable.lock_write, token=different_token) def test_lock_write_with_matching_token(self): # If the token matches, so no exception is raised by lock_write. token = self.lockable.lock_write() self.addCleanup(self.lockable.unlock) if token is None: # This test does not apply, because this lockable refuses # tokens. return # The same instance will accept a second lock_write if the specified # token matches. self.lockable.lock_write(token=token) self.lockable.unlock() # Calling lock_write on a new instance for the same lockable will # also succeed. new_lockable = self.get_lockable() new_lockable.lock_write(token=token) new_lockable.unlock() def test_unlock_after_lock_write_with_token(self): # If lock_write did not physically acquire the lock (because it was # passed a token), then unlock should not physically release it. token = self.lockable.lock_write() self.addCleanup(self.lockable.unlock) if token is None: # This test does not apply, because this lockable refuses # tokens. return new_lockable = self.get_lockable() new_lockable.lock_write(token=token) new_lockable.unlock() self.assertTrue(self.lockable.get_physical_lock_status()) def test_lock_write_with_token_fails_when_unlocked(self): # Lock and unlock to get a superficially valid token. This mimics a # likely programming error, where a caller accidentally tries to lock # with a token that is no longer valid (because the original lock was # released). token = self.lockable.lock_write() self.lockable.unlock() if token is None: # This test does not apply, because this lockable refuses # tokens. return self.assertRaises(errors.TokenMismatch, self.lockable.lock_write, token=token) def test_lock_write_reenter_with_token(self): token = self.lockable.lock_write() try: if token is None: # This test does not apply, because this lockable refuses # tokens. return # Relock with a token. token_from_reentry = self.lockable.lock_write(token=token) try: self.assertEqual(token, token_from_reentry) finally: self.lockable.unlock() finally: self.lockable.unlock() # The lock should be unlocked on disk. Verify that with a new lock # instance. new_lockable = self.get_lockable() # Calling lock_write now should work, rather than raise LockContention. new_lockable.lock_write() new_lockable.unlock() def test_second_lock_write_returns_same_token(self): first_token = self.lockable.lock_write() try: if first_token is None: # This test does not apply, because this lockable refuses # tokens. return # Relock the already locked lockable. It should return the same # token. second_token = self.lockable.lock_write() try: self.assertEqual(first_token, second_token) finally: self.lockable.unlock() finally: self.lockable.unlock() def test_leave_in_place(self): token = self.lockable.lock_write() try: if token is None: # This test does not apply, because this lockable refuses # tokens. return self.lockable.leave_in_place() finally: self.lockable.unlock() # At this point, the lock is still in place on disk self.assertRaises(errors.LockContention, self.lockable.lock_write) # But should be relockable with a token. self.lockable.lock_write(token=token) self.lockable.unlock() # Cleanup: we should still be able to get the lock, but we restore the # behavior to clearing the lock when unlocking. self.lockable.lock_write(token=token) self.lockable.dont_leave_in_place() self.lockable.unlock() def test_dont_leave_in_place(self): token = self.lockable.lock_write() try: if token is None: # This test does not apply, because this lockable refuses # tokens. return self.lockable.leave_in_place() finally: self.lockable.unlock() # At this point, the lock is still in place on disk. # Acquire the existing lock with the token, and ask that it is removed # when this object unlocks, and unlock to trigger that removal. new_lockable = self.get_lockable() new_lockable.lock_write(token=token) new_lockable.dont_leave_in_place() new_lockable.unlock() # At this point, the lock is no longer on disk, so we can lock it. third_lockable = self.get_lockable() third_lockable.lock_write() third_lockable.unlock() # This method of adapting tests to parameters is different to # the TestProviderAdapters used elsewhere, but seems simpler for this # case. class TestLockableFiles_TransportLock(TestCaseInTempDir, _TestLockableFiles_mixin): def setUp(self): super(TestLockableFiles_TransportLock, self).setUp() t = transport.get_transport_from_path('.') t.mkdir('.bzr') self.sub_transport = t.clone('.bzr') self.lockable = self.get_lockable() self.lockable.create_lock() def stop_server(self): super(TestLockableFiles_TransportLock, self).stop_server() # free the subtransport so that we do not get a 5 second # timeout due to the SFTP connection cache. try: del self.sub_transport except AttributeError: pass def get_lockable(self): return LockableFiles(self.sub_transport, 'my-lock', TransportLock) class TestLockableFiles_LockDir(TestCaseInTempDir, _TestLockableFiles_mixin): """LockableFile tests run with LockDir underneath""" def setUp(self): super(TestLockableFiles_LockDir, self).setUp() self.transport = transport.get_transport_from_path('.') self.lockable = self.get_lockable() # the lock creation here sets mode - test_permissions on branch # tests that implicitly, but it might be a good idea to factor # out the mode checking logic and have it applied to loackable files # directly. RBC 20060418 self.lockable.create_lock() def get_lockable(self): return LockableFiles(self.transport, 'my-lock', lockdir.LockDir) def test_lock_created(self): self.assertTrue(self.transport.has('my-lock')) self.lockable.lock_write() self.assertTrue(self.transport.has('my-lock/held/info')) self.lockable.unlock() self.assertFalse(self.transport.has('my-lock/held/info')) self.assertTrue(self.transport.has('my-lock')) def test__file_modes(self): self.transport.mkdir('readonly') osutils.make_readonly('readonly') lockable = LockableFiles(self.transport.clone('readonly'), 'test-lock', lockdir.LockDir) # The directory mode should be read-write-execute for the current user self.assertEqual(0o0700, lockable._dir_mode & 0o0700) # Files should be read-write for the current user self.assertEqual(0o0600, lockable._file_mode & 0o0700) class TestLockableFiles_RemoteLockDir(TestCaseWithSmartMedium, _TestLockableFiles_mixin): """LockableFile tests run with RemoteLockDir on a branch.""" def setUp(self): super(TestLockableFiles_RemoteLockDir, self).setUp() # can only get a RemoteLockDir with some RemoteObject... # use a branch as thats what we want. These mixin tests test the end # to end behaviour, so stubbing out the backend and simulating would # defeat the purpose. We test the protocol implementation separately # in test_remote and test_smart as usual. b = self.make_branch('foo') self.addCleanup(b.controldir.transport.disconnect) self.transport = transport.get_transport_from_path('.') self.lockable = self.get_lockable() def get_lockable(self): # getting a new lockable involves opening a new instance of the branch branch = breezy.branch.Branch.open(self.get_url('foo')) self.addCleanup(branch.controldir.transport.disconnect) return branch.control_files