from allmydata.test.common import SystemTestMixin, ShareManglingMixin from allmydata.monitor import Monitor from allmydata.interfaces import IURI, NotEnoughSharesError from allmydata.immutable import upload from allmydata.util import log from twisted.internet import defer from twisted.trial import unittest import random, struct import common_util as testutil TEST_DATA="\x02"*(upload.Uploader.URI_LIT_SIZE_THRESHOLD+1) def corrupt_field(data, offset, size, debug=False): if random.random() < 0.5: newdata = testutil.flip_one_bit(data, offset, size) if debug: log.msg("testing: corrupting offset %d, size %d flipping one bit orig: %r, newdata: %r" % (offset, size, data[offset:offset+size], newdata[offset:offset+size])) return newdata else: newval = testutil.insecurerandstr(size) if debug: log.msg("testing: corrupting offset %d, size %d randomizing field, orig: %r, newval: %r" % (offset, size, data[offset:offset+size], newval)) return data[:offset]+newval+data[offset+size:] def _corrupt_file_version_number(data): """ Scramble the file data -- the share file version number have one bit flipped or else will be changed to a random value.""" return corrupt_field(data, 0x00, 4) def _corrupt_size_of_file_data(data): """ Scramble the file data -- the field showing the size of the share data within the file will be set to one smaller. """ return corrupt_field(data, 0x04, 4) def _corrupt_sharedata_version_number(data): """ Scramble the file data -- the share data version number will have one bit flipped or else will be changed to a random value, but not 1 or 2.""" return corrupt_field(data, 0x0c, 4) sharevernum = struct.unpack(">l", data[0x0c:0x0c+4])[0] assert sharevernum in (1, 2), "This test is designed to corrupt immutable shares of v1 or v2 in specific ways." newsharevernum = sharevernum while newsharevernum in (1, 2): newsharevernum = random.randrange(0, 2**32) newsharevernumbytes = struct.pack(">l", newsharevernum) return data[:0x0c] + newsharevernumbytes + data[0x0c+4:] def _corrupt_sharedata_version_number_to_known_version(data): """ Scramble the file data -- the share data version number will be changed to 2 if it is 1 or else to 1 if it is 2.""" sharevernum = struct.unpack(">l", data[0x0c:0x0c+4])[0] assert sharevernum in (1, 2), "This test is designed to corrupt immutable shares of v1 or v2 in specific ways." if sharevernum == 1: newsharevernum = 2 else: newsharevernum = 1 newsharevernumbytes = struct.pack(">l", newsharevernum) return data[:0x0c] + newsharevernumbytes + data[0x0c+4:] def _corrupt_segment_size(data): """ Scramble the file data -- the field showing the size of the segment will have one bit flipped or else be changed to a random value. """ sharevernum = struct.unpack(">l", data[0x0c:0x0c+4])[0] assert sharevernum in (1, 2), "This test is designed to corrupt immutable shares of v1 or v2 in specific ways." if sharevernum == 1: return corrupt_field(data, 0x0c+0x04, 4, debug=True) else: return corrupt_field(data, 0x0c+0x04, 8, debug=True) def _corrupt_size_of_sharedata(data): """ Scramble the file data -- the field showing the size of the data within the share data will have one bit flipped or else will be changed to a random value. """ sharevernum = struct.unpack(">l", data[0x0c:0x0c+4])[0] assert sharevernum in (1, 2), "This test is designed to corrupt immutable shares of v1 or v2 in specific ways." if sharevernum == 1: return corrupt_field(data, 0x0c+0x08, 4) else: return corrupt_field(data, 0x0c+0x0c, 8) def _corrupt_offset_of_sharedata(data): """ Scramble the file data -- the field showing the offset of the data within the share data will have one bit flipped or else be changed to a random value. """ sharevernum = struct.unpack(">l", data[0x0c:0x0c+4])[0] assert sharevernum in (1, 2), "This test is designed to corrupt immutable shares of v1 or v2 in specific ways." if sharevernum == 1: return corrupt_field(data, 0x0c+0x0c, 4) else: return corrupt_field(data, 0x0c+0x14, 8) def _corrupt_offset_of_ciphertext_hash_tree(data): """ Scramble the file data -- the field showing the offset of the ciphertext hash tree within the share data will have one bit flipped or else be changed to a random value. """ sharevernum = struct.unpack(">l", data[0x0c:0x0c+4])[0] assert sharevernum in (1, 2), "This test is designed to corrupt immutable shares of v1 or v2 in specific ways." if sharevernum == 1: return corrupt_field(data, 0x0c+0x14, 4, debug=True) else: return corrupt_field(data, 0x0c+0x24, 8, debug=True) def _corrupt_offset_of_block_hashes(data): """ Scramble the file data -- the field showing the offset of the block hash tree within the share data will have one bit flipped or else will be changed to a random value. """ sharevernum = struct.unpack(">l", data[0x0c:0x0c+4])[0] assert sharevernum in (1, 2), "This test is designed to corrupt immutable shares of v1 or v2 in specific ways." if sharevernum == 1: return corrupt_field(data, 0x0c+0x18, 4) else: return corrupt_field(data, 0x0c+0x2c, 8) def _corrupt_offset_of_share_hashes(data): """ Scramble the file data -- the field showing the offset of the share hash tree within the share data will have one bit flipped or else will be changed to a random value. """ sharevernum = struct.unpack(">l", data[0x0c:0x0c+4])[0] assert sharevernum in (1, 2), "This test is designed to corrupt immutable shares of v1 or v2 in specific ways." if sharevernum == 1: return corrupt_field(data, 0x0c+0x1c, 4) else: return corrupt_field(data, 0x0c+0x34, 8) def _corrupt_offset_of_uri_extension(data): """ Scramble the file data -- the field showing the offset of the uri extension will have one bit flipped or else will be changed to a random value. """ sharevernum = struct.unpack(">l", data[0x0c:0x0c+4])[0] assert sharevernum in (1, 2), "This test is designed to corrupt immutable shares of v1 or v2 in specific ways." if sharevernum == 1: return corrupt_field(data, 0x0c+0x20, 4) else: return corrupt_field(data, 0x0c+0x3c, 8) def _corrupt_share_data(data): """ Scramble the file data -- the field containing the share data itself will have one bit flipped or else will be changed to a random value. """ sharevernum = struct.unpack(">l", data[0x0c:0x0c+4])[0] assert sharevernum in (1, 2), "This test is designed to corrupt immutable shares of v1 or v2 in specific ways." if sharevernum == 1: sharedatasize = struct.unpack(">L", data[0x0c+0x08:0x0c+0x08+4])[0] return corrupt_field(data, 0x0c+0x24, sharedatasize) else: sharedatasize = struct.unpack(">Q", data[0x0c+0x08:0x0c+0x0c+8])[0] return corrupt_field(data, 0x0c+0x44, sharedatasize) def _corrupt_crypttext_hash_tree(data): """ Scramble the file data -- the field containing the crypttext hash tree will have one bit flipped or else will be changed to a random value. """ sharevernum = struct.unpack(">l", data[0x0c:0x0c+4])[0] assert sharevernum in (1, 2), "This test is designed to corrupt immutable shares of v1 or v2 in specific ways." if sharevernum == 1: crypttexthashtreeoffset = struct.unpack(">L", data[0x0c+0x14:0x0c+0x14+4])[0] blockhashesoffset = struct.unpack(">L", data[0x0c+0x18:0x0c+0x18+4])[0] else: crypttexthashtreeoffset = struct.unpack(">Q", data[0x0c+0x24:0x0c+0x24+8])[0] blockhashesoffset = struct.unpack(">Q", data[0x0c+0x2c:0x0c+0x2c+8])[0] return corrupt_field(data, crypttexthashtreeoffset, blockhashesoffset-crypttexthashtreeoffset) def _corrupt_block_hashes(data): """ Scramble the file data -- the field containing the block hash tree will have one bit flipped or else will be changed to a random value. """ sharevernum = struct.unpack(">l", data[0x0c:0x0c+4])[0] assert sharevernum in (1, 2), "This test is designed to corrupt immutable shares of v1 or v2 in specific ways." if sharevernum == 1: blockhashesoffset = struct.unpack(">L", data[0x0c+0x18:0x0c+0x18+4])[0] sharehashesoffset = struct.unpack(">L", data[0x0c+0x1c:0x0c+0x1c+4])[0] else: blockhashesoffset = struct.unpack(">Q", data[0x0c+0x2c:0x0c+0x2c+8])[0] sharehashesoffset = struct.unpack(">Q", data[0x0c+0x34:0x0c+0x34+8])[0] return corrupt_field(data, blockhashesoffset, sharehashesoffset-blockhashesoffset) def _corrupt_share_hashes(data): """ Scramble the file data -- the field containing the share hash chain will have one bit flipped or else will be changed to a random value. """ sharevernum = struct.unpack(">l", data[0x0c:0x0c+4])[0] assert sharevernum in (1, 2), "This test is designed to corrupt immutable shares of v1 or v2 in specific ways." if sharevernum == 1: sharehashesoffset = struct.unpack(">L", data[0x0c+0x1c:0x0c+0x1c+4])[0] uriextoffset = struct.unpack(">L", data[0x0c+0x20:0x0c+0x20+4])[0] else: sharehashesoffset = struct.unpack(">Q", data[0x0c+0x34:0x0c+0x34+8])[0] uriextoffset = struct.unpack(">Q", data[0x0c+0x3c:0x0c+0x3c+8])[0] return corrupt_field(data, sharehashesoffset, uriextoffset-sharehashesoffset) def _corrupt_length_of_uri_extension(data): """ Scramble the file data -- the field showing the length of the uri extension will have one bit flipped or else will be changed to a random value. """ sharevernum = struct.unpack(">l", data[0x0c:0x0c+4])[0] assert sharevernum in (1, 2), "This test is designed to corrupt immutable shares of v1 or v2 in specific ways." if sharevernum == 1: uriextoffset = struct.unpack(">L", data[0x0c+0x20:0x0c+0x20+4])[0] return corrupt_field(data, uriextoffset, 4) else: uriextoffset = struct.unpack(">Q", data[0x0c+0x3c:0x0c+0x3c+8])[0] return corrupt_field(data, uriextoffset, 8) def _corrupt_uri_extension(data): """ Scramble the file data -- the field containing the uri extension will have one bit flipped or else will be changed to a random value. """ sharevernum = struct.unpack(">l", data[0x0c:0x0c+4])[0] assert sharevernum in (1, 2), "This test is designed to corrupt immutable shares of v1 or v2 in specific ways." if sharevernum == 1: uriextoffset = struct.unpack(">L", data[0x0c+0x20:0x0c+0x20+4])[0] uriextlen = struct.unpack(">L", data[0x0c+uriextoffset:0x0c+uriextoffset+4])[0] else: uriextoffset = struct.unpack(">Q", data[0x0c+0x3c:0x0c+0x3c+8])[0] uriextlen = struct.unpack(">Q", data[0x0c+uriextoffset:0x0c+uriextoffset+8])[0] return corrupt_field(data, uriextoffset, uriextlen) class Test(ShareManglingMixin, unittest.TestCase): def setUp(self): # Set self.basedir to a temp dir which has the name of the current test method in its # name. self.basedir = self.mktemp() d = defer.maybeDeferred(SystemTestMixin.setUp, self) d.addCallback(lambda x: self.set_up_nodes()) def _upload_a_file(ignored): d2 = self.clients[0].upload(upload.Data(TEST_DATA, convergence="")) def _after_upload(u): self.uri = IURI(u.uri) return self.clients[0].create_node_from_uri(self.uri) d2.addCallback(_after_upload) return d2 d.addCallback(_upload_a_file) def _stash_it(filenode): self.filenode = filenode d.addCallback(_stash_it) return d def _download_and_check_plaintext(self, unused=None): self.downloader = self.clients[1].getServiceNamed("downloader") d = self.downloader.download_to_data(self.uri) def _after_download(result): self.failUnlessEqual(result, TEST_DATA) d.addCallback(_after_download) return d def _delete_a_share(self, unused=None, sharenum=None): """ Delete one share. """ shares = self.find_shares() ks = shares.keys() if sharenum is not None: k = [ key for key in shares.keys() if key[1] == sharenum ][0] else: k = random.choice(ks) del shares[k] self.replace_shares(shares, storage_index=self.uri.storage_index) return unused def test_test_code(self): # The following process of stashing the shares, running # replace_shares, and asserting that the new set of shares equals the # old is more to test this test code than to test the Tahoe code... d = defer.succeed(None) d.addCallback(self.find_shares) stash = [None] def _stash_it(res): stash[0] = res return res d.addCallback(_stash_it) d.addCallback(self.replace_shares, storage_index=self.uri.storage_index) def _compare(res): oldshares = stash[0] self.failUnless(isinstance(oldshares, dict), oldshares) self.failUnlessEqual(oldshares, res) d.addCallback(self.find_shares) d.addCallback(_compare) d.addCallback(lambda ignore: self.replace_shares({}, storage_index=self.uri.storage_index)) d.addCallback(self.find_shares) d.addCallback(lambda x: self.failUnlessEqual(x, {})) # The following process of deleting 8 of the shares and asserting that you can't # download it is more to test this test code than to test the Tahoe code... def _then_delete_8(unused=None): self.replace_shares(stash[0], storage_index=self.uri.storage_index) for i in range(8): self._delete_a_share() d.addCallback(_then_delete_8) def _then_download(unused=None): self.downloader = self.clients[1].getServiceNamed("downloader") d = self.downloader.download_to_data(self.uri) def _after_download_callb(result): self.fail() # should have gotten an errback instead return result def _after_download_errb(failure): failure.trap(NotEnoughSharesError) return None # success! d.addCallbacks(_after_download_callb, _after_download_errb) d.addCallback(_then_download) # The following process of leaving 8 of the shares deleted and asserting that you can't # repair it is more to test this test code than to test the Tahoe code... def _then_repair(unused=None): d2 = self.filenode.check_and_repair(Monitor(), verify=False) def _after_repair(checkandrepairresults): prerepairres = checkandrepairresults.get_pre_repair_results() postrepairres = checkandrepairresults.get_post_repair_results() self.failIf(prerepairres.is_healthy()) self.failIf(postrepairres.is_healthy()) d2.addCallback(_after_repair) return d2 d.addCallback(_then_repair) return d def _count_reads(self): sum_of_read_counts = 0 for client in self.clients: counters = client.stats_provider.get_stats()['counters'] sum_of_read_counts += counters.get('storage_server.read', 0) return sum_of_read_counts def _count_allocates(self): sum_of_allocate_counts = 0 for client in self.clients: counters = client.stats_provider.get_stats()['counters'] sum_of_allocate_counts += counters.get('storage_server.allocate', 0) return sum_of_allocate_counts def _corrupt_a_random_share(self, unused, corruptor_func): """ Exactly one share on disk will be corrupted by corruptor_func. """ shares = self.find_shares() ks = shares.keys() k = random.choice(ks) shares[k] = corruptor_func(shares[k]) self.replace_shares(shares, storage_index=self.uri.storage_index) def test_check_without_verify(self): """ Check says the file is healthy when none of the shares have been touched. It says that the file is unhealthy when all of them have been removed. It doesn't use any reads. """ d = defer.succeed(self.filenode) def _check1(filenode): before_check_reads = self._count_reads() d2 = filenode.check(Monitor(), verify=False) def _after_check(checkresults): after_check_reads = self._count_reads() self.failIf(after_check_reads - before_check_reads > 0, after_check_reads - before_check_reads) self.failUnless(checkresults.is_healthy()) d2.addCallback(_after_check) return d2 d.addCallback(_check1) d.addCallback(lambda ignore: self.replace_shares({}, storage_index=self.uri.storage_index)) def _check2(ignored): before_check_reads = self._count_reads() d2 = self.filenode.check(Monitor(), verify=False) def _after_check(checkresults): after_check_reads = self._count_reads() self.failIf(after_check_reads - before_check_reads > 0, after_check_reads - before_check_reads) self.failIf(checkresults.is_healthy()) d2.addCallback(_after_check) return d2 d.addCallback(_check2) return d def test_check_with_verify(self): """ Check says the file is healthy when none of the shares have been touched. It says that the file is unhealthy if any field of any share has been corrupted. It doesn't use more than twice as many reads as it needs. """ LEEWAY = 7 # We'll allow you to pass this test even if you trigger seven times as many disk reads and blocks sends as would be optimal. DELTA_READS = 10 * LEEWAY # N = 10 d = defer.succeed(self.filenode) def _check_pristine(filenode): before_check_reads = self._count_reads() d2 = filenode.check(Monitor(), verify=True) def _after_check(checkresults): after_check_reads = self._count_reads() self.failIf(after_check_reads - before_check_reads > DELTA_READS, (after_check_reads, before_check_reads, DELTA_READS)) self.failUnless(checkresults.is_healthy()) d2.addCallback(_after_check) return d2 d.addCallback(_check_pristine) d.addCallback(self.find_shares) stash = [None] def _stash_it(res): stash[0] = res return res d.addCallback(_stash_it) def _check_after_feckless_corruption(ignored, corruptor_func): # Corruption which has no effect -- bits of the share file that are unused. before_check_reads = self._count_reads() d2 = self.filenode.check(Monitor(), verify=True) def _after_check(checkresults): after_check_reads = self._count_reads() self.failIf(after_check_reads - before_check_reads > DELTA_READS) self.failUnless(checkresults.is_healthy(), (checkresults, checkresults.is_healthy(), checkresults.get_data(), corruptor_func)) data = checkresults.get_data() self.failUnless(data['count-shares-good'] == 10, data) self.failUnless(len(data['sharemap']) == 10, data) self.failUnless(data['count-shares-needed'] == 3, data) self.failUnless(data['count-shares-expected'] == 10, data) self.failUnless(data['count-good-share-hosts'] == 5, data) self.failUnless(len(data['servers-responding']) == 5, data) self.failUnless(len(data['list-corrupt-shares']) == 0, data) d2.addCallback(_after_check) return d2 def _put_it_all_back(ignored): self.replace_shares(stash[0], storage_index=self.uri.storage_index) return ignored for corruptor_func in ( _corrupt_size_of_file_data, _corrupt_size_of_sharedata, _corrupt_segment_size, ): d.addCallback(self._corrupt_a_random_share, corruptor_func) d.addCallback(_check_after_feckless_corruption, corruptor_func=corruptor_func) d.addCallback(_put_it_all_back) def _check_after_server_visible_corruption(ignored, corruptor_func): # Corruption which is detected by the server means that the server will send you # back a Failure in response to get_bucket instead of giving you the share data. before_check_reads = self._count_reads() d2 = self.filenode.check(Monitor(), verify=True) def _after_check(checkresults): after_check_reads = self._count_reads() self.failIf(after_check_reads - before_check_reads > DELTA_READS) self.failIf(checkresults.is_healthy(), (checkresults, checkresults.is_healthy(), checkresults.get_data(), corruptor_func)) data = checkresults.get_data() # The server might fail to serve up its other share as well as the corrupted # one, so count-shares-good could be 8 or 9. self.failUnless(data['count-shares-good'] in (8, 9), data) self.failUnless(len(data['sharemap']) in (8, 9,), data) self.failUnless(data['count-shares-needed'] == 3, data) self.failUnless(data['count-shares-expected'] == 10, data) # The server may have served up the non-corrupted share, or it may not have, so # the checker could have detected either 4 or 5 good servers. self.failUnless(data['count-good-share-hosts'] in (4, 5), data) self.failUnless(len(data['servers-responding']) in (4, 5), data) # If the server served up the other share, then the checker should consider it good, else it should # not. self.failUnless((data['count-shares-good'] == 9) == (data['count-good-share-hosts'] == 5), data) self.failUnless(len(data['list-corrupt-shares']) == 0, data) d2.addCallback(_after_check) return d2 for corruptor_func in ( _corrupt_file_version_number, ): d.addCallback(self._corrupt_a_random_share, corruptor_func) d.addCallback(_check_after_server_visible_corruption, corruptor_func=corruptor_func) d.addCallback(_put_it_all_back) def _check_after_share_incompatibility(ignored, corruptor_func): # Corruption which means the share is indistinguishable from a share of an # incompatible version. before_check_reads = self._count_reads() d2 = self.filenode.check(Monitor(), verify=True) def _after_check(checkresults): after_check_reads = self._count_reads() self.failIf(after_check_reads - before_check_reads > DELTA_READS) self.failIf(checkresults.is_healthy(), (checkresults, checkresults.is_healthy(), checkresults.get_data(), corruptor_func)) data = checkresults.get_data() self.failUnless(data['count-shares-good'] == 9, data) self.failUnless(len(data['sharemap']) == 9, data) self.failUnless(data['count-shares-needed'] == 3, data) self.failUnless(data['count-shares-expected'] == 10, data) self.failUnless(data['count-good-share-hosts'] == 5, data) self.failUnless(len(data['servers-responding']) == 5, data) self.failUnless(len(data['list-corrupt-shares']) == 0, data) self.failUnless(len(data['list-corrupt-shares']) == data['count-corrupt-shares'], data) self.failUnless(len(data['list-incompatible-shares']) == data['count-incompatible-shares'], data) self.failUnless(len(data['list-incompatible-shares']) == 1, data) d2.addCallback(_after_check) return d2 for corruptor_func in ( _corrupt_sharedata_version_number, ): d.addCallback(self._corrupt_a_random_share, corruptor_func) d.addCallback(_check_after_share_incompatibility, corruptor_func=corruptor_func) d.addCallback(_put_it_all_back) def _check_after_server_invisible_corruption(ignored, corruptor_func): # Corruption which is not detected by the server means that the server will send you # back the share data, but you will detect that it is wrong. before_check_reads = self._count_reads() d2 = self.filenode.check(Monitor(), verify=True) def _after_check(checkresults): after_check_reads = self._count_reads() # print "delta was ", after_check_reads - before_check_reads self.failIf(after_check_reads - before_check_reads > DELTA_READS) self.failIf(checkresults.is_healthy(), (checkresults, checkresults.is_healthy(), checkresults.get_data(), corruptor_func)) data = checkresults.get_data() self.failUnless(data['count-shares-good'] == 9, data) self.failUnless(data['count-shares-needed'] == 3, data) self.failUnless(data['count-shares-expected'] == 10, data) self.failUnless(data['count-good-share-hosts'] == 5, data) self.failUnless(data['count-corrupt-shares'] == 1, (data, corruptor_func)) self.failUnless(len(data['list-corrupt-shares']) == 1, data) self.failUnless(len(data['list-corrupt-shares']) == data['count-corrupt-shares'], data) self.failUnless(len(data['list-incompatible-shares']) == data['count-incompatible-shares'], data) self.failUnless(len(data['list-incompatible-shares']) == 0, data) self.failUnless(len(data['servers-responding']) == 5, data) self.failUnless(len(data['sharemap']) == 9, data) d2.addCallback(_after_check) return d2 for corruptor_func in ( _corrupt_sharedata_version_number_to_known_version, _corrupt_offset_of_sharedata, _corrupt_offset_of_ciphertext_hash_tree, _corrupt_offset_of_block_hashes, _corrupt_offset_of_share_hashes, _corrupt_offset_of_uri_extension, _corrupt_share_data, _corrupt_crypttext_hash_tree, _corrupt_block_hashes, _corrupt_share_hashes, _corrupt_length_of_uri_extension, _corrupt_uri_extension, ): d.addCallback(self._corrupt_a_random_share, corruptor_func) d.addCallback(_check_after_server_invisible_corruption, corruptor_func=corruptor_func) d.addCallback(_put_it_all_back) return d test_check_with_verify.todo = "We haven't implemented a verifier this thorough yet." def test_repair(self): """ Repair replaces a share that got deleted. """ # N == 10. 7 is the "efficiency leeway" -- we'll allow you to pass this test even if # you trigger seven times as many disk reads and blocks sends as would be optimal. DELTA_READS = 10 * 7 # We'll allow you to pass this test only if you repair the missing share using only a # single allocate. DELTA_ALLOCATES = 1 d = defer.succeed(self.filenode) d.addCallback(self._delete_a_share, sharenum=2) def _repair_from_deletion_of_1(filenode): before_repair_reads = self._count_reads() before_repair_allocates = self._count_allocates() d2 = filenode.check_and_repair(Monitor(), verify=False) def _after_repair(checkandrepairresults): prerepairres = checkandrepairresults.get_pre_repair_results() postrepairres = checkandrepairresults.get_post_repair_results() after_repair_reads = self._count_reads() after_repair_allocates = self._count_allocates() # print "delta was ", after_repair_reads - before_repair_reads, after_repair_allocates - before_repair_allocates self.failIf(after_repair_reads - before_repair_reads > DELTA_READS) self.failIf(after_repair_allocates - before_repair_allocates > DELTA_ALLOCATES) self.failIf(prerepairres.is_healthy()) self.failUnless(postrepairres.is_healthy()) # Now we inspect the filesystem to make sure that it has 10 shares. shares = self.find_shares() self.failIf(len(shares) < 10) # Now we delete seven of the other shares, then try to download the file and # assert that it succeeds at downloading and has the right contents. This can't # work unless it has already repaired the previously-deleted share #2. for sharenum in range(3, 10): self._delete_a_share(sharenum=sharenum) return self._download_and_check_plaintext() d2.addCallback(_after_repair) return d2 d.addCallback(_repair_from_deletion_of_1) # Now we repair again to get all of those 7 back... def _repair_from_deletion_of_7(filenode): before_repair_reads = self._count_reads() before_repair_allocates = self._count_allocates() d2 = filenode.check_and_repair(Monitor(), verify=False) def _after_repair(checkandrepairresults): prerepairres = checkandrepairresults.get_pre_repair_results() postrepairres = checkandrepairresults.get_post_repair_results() after_repair_reads = self._count_reads() after_repair_allocates = self._count_allocates() # print "delta was ", after_repair_reads - before_repair_reads, after_repair_allocates - before_repair_allocates self.failIf(after_repair_reads - before_repair_reads > DELTA_READS) self.failIf(after_repair_allocates - before_repair_allocates > (DELTA_ALLOCATES*7)) self.failIf(prerepairres.is_healthy()) self.failUnless(postrepairres.is_healthy()) # Now we inspect the filesystem to make sure that it has 10 shares. shares = self.find_shares() self.failIf(len(shares) < 10) return self._download_and_check_plaintext() d2.addCallback(_after_repair) return d2 d.addCallback(_repair_from_deletion_of_7) def _repair_from_corruption(filenode): before_repair_reads = self._count_reads() before_repair_allocates = self._count_allocates() d2 = filenode.check_and_repair(Monitor(), verify=False) def _after_repair(checkandrepairresults): prerepairres = checkandrepairresults.get_pre_repair_results() postrepairres = checkandrepairresults.get_post_repair_results() after_repair_reads = self._count_reads() after_repair_allocates = self._count_allocates() # print "delta was ", after_repair_reads - before_repair_reads, after_repair_allocates - before_repair_allocates self.failIf(after_repair_reads - before_repair_reads > DELTA_READS) self.failIf(after_repair_allocates - before_repair_allocates > DELTA_ALLOCATES) self.failIf(prerepairres.is_healthy()) self.failUnless(postrepairres.is_healthy()) return self._download_and_check_plaintext() d2.addCallback(_after_repair) return d2 for corruptor_func in ( _corrupt_file_version_number, _corrupt_sharedata_version_number, _corrupt_sharedata_version_number_to_known_version, _corrupt_offset_of_sharedata, _corrupt_offset_of_ciphertext_hash_tree, _corrupt_offset_of_block_hashes, _corrupt_offset_of_share_hashes, _corrupt_offset_of_uri_extension, _corrupt_share_data, _corrupt_crypttext_hash_tree, _corrupt_block_hashes, _corrupt_share_hashes, _corrupt_length_of_uri_extension, _corrupt_uri_extension, ): # Now we corrupt a share... d.addCallback(self._corrupt_a_random_share, corruptor_func) # And repair... d.addCallback(_repair_from_corruption) return d test_repair.todo = "We haven't implemented a repairer yet." # XXX extend these tests to show that the checker detects which specific share on which specific server is broken -- this is necessary so that the checker results can be passed to the repairer and the repairer can go ahead and upload fixes without first doing what is effectively a check (/verify) run # XXX extend these tests to show bad behavior of various kinds from servers: raising exception from each remove_foo() method, for example # XXX test disconnect DeadReferenceError from get_buckets and get_block_whatsit