# Copyright 2013-2016 DataStax, Inc. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. try: import unittest2 as unittest except ImportError: import unittest # noqa import difflib import six import sys import time from mock import Mock, patch from cassandra import AlreadyExists, SignatureDescriptor, UserFunctionDescriptor, UserAggregateDescriptor from cassandra.cluster import Cluster from cassandra.encoder import Encoder from cassandra.metadata import (Metadata, KeyspaceMetadata, IndexMetadata, Token, MD5Token, TokenMap, murmur3, Function, Aggregate, protect_name, protect_names, get_schema_parser) from cassandra.policies import SimpleConvictionPolicy from cassandra.pool import Host from tests.integration import get_cluster, use_singledc, PROTOCOL_VERSION, get_server_versions, execute_until_pass, \ BasicSegregatedKeyspaceUnitTestCase, BasicSharedKeyspaceUnitTestCase, BasicExistingKeyspaceUnitTestCase, drop_keyspace_shutdown_cluster, CASSANDRA_VERSION, \ BasicExistingSegregatedKeyspaceUnitTestCase, dseonly, DSE_VERSION, get_supported_protocol_versions def setup_module(): use_singledc() global CASS_SERVER_VERSION CASS_SERVER_VERSION = get_server_versions()[0] class HostMetatDataTests(BasicExistingKeyspaceUnitTestCase): def test_broadcast_listen_address(self): """ Check to ensure that the broadcast and listen adresss is populated correctly @since 3.3 @jira_ticket PYTHON-332 @expected_result They are populated for C*> 2.0.16, 2.1.6, 2.2.0 @test_category metadata """ # All nodes should have the broadcast_address set for host in self.cluster.metadata.all_hosts(): self.assertIsNotNone(host.broadcast_address) con = self.cluster.control_connection.get_connections()[0] local_host = con.host # The control connection node should have the listen address set. listen_addrs = [host.listen_address for host in self.cluster.metadata.all_hosts()] self.assertTrue(local_host in listen_addrs) def test_host_release_version(self): """ Checks the hosts release version and validates that it is equal to the Cassandra version we are using in our test harness. @since 3.3 @jira_ticket PYTHON-301 @expected_result host.release version should match our specified Cassandra version. @test_category metadata """ for host in self.cluster.metadata.all_hosts(): self.assertTrue(host.release_version.startswith(CASSANDRA_VERSION)) class MetaDataRemovalTest(unittest.TestCase): def setUp(self): self.cluster = Cluster(protocol_version=PROTOCOL_VERSION, contact_points=['127.0.0.1','127.0.0.2', '127.0.0.3', '126.0.0.186']) self.cluster.connect() def tearDown(self): self.cluster.shutdown() def test_bad_contact_point(self): """ Checks to ensure that hosts that are not resolvable are excluded from the contact point list. @since 3.6 @jira_ticket PYTHON-549 @expected_result Invalid hosts on the contact list should be excluded @test_category metadata """ self.assertEqual(len(self.cluster.metadata.all_hosts()), 3) class SchemaMetadataTests(BasicSegregatedKeyspaceUnitTestCase): def test_schema_metadata_disable(self): """ Checks to ensure that schema metadata_enabled, and token_metadata_enabled flags work correctly. @since 3.3 @jira_ticket PYTHON-327 @expected_result schema metadata will not be populated when schema_metadata_enabled is fause token_metadata will be missing when token_metadata is set to false @test_category metadata """ # Validate metadata is missing where appropriate no_schema = Cluster(schema_metadata_enabled=False) no_schema_session = no_schema.connect() self.assertEqual(len(no_schema.metadata.keyspaces), 0) self.assertEqual(no_schema.metadata.export_schema_as_string(), '') no_token = Cluster(token_metadata_enabled=False) no_token_session = no_token.connect() self.assertEqual(len(no_token.metadata.token_map.token_to_host_owner), 0) # Do a simple query to ensure queries are working query = "SELECT * FROM system.local" no_schema_rs = no_schema_session.execute(query) no_token_rs = no_token_session.execute(query) self.assertIsNotNone(no_schema_rs[0]) self.assertIsNotNone(no_token_rs[0]) no_schema.shutdown() no_token.shutdown() def make_create_statement(self, partition_cols, clustering_cols=None, other_cols=None, compact=False): clustering_cols = clustering_cols or [] other_cols = other_cols or [] statement = "CREATE TABLE %s.%s (" % (self.keyspace_name, self.function_table_name) if len(partition_cols) == 1 and not clustering_cols: statement += "%s text PRIMARY KEY, " % protect_name(partition_cols[0]) else: statement += ", ".join("%s text" % protect_name(col) for col in partition_cols) statement += ", " statement += ", ".join("%s text" % protect_name(col) for col in clustering_cols + other_cols) if len(partition_cols) != 1 or clustering_cols: statement += ", PRIMARY KEY (" if len(partition_cols) > 1: statement += "(" + ", ".join(protect_names(partition_cols)) + ")" else: statement += protect_name(partition_cols[0]) if clustering_cols: statement += ", " statement += ", ".join(protect_names(clustering_cols)) statement += ")" statement += ")" if compact: statement += " WITH COMPACT STORAGE" return statement def check_create_statement(self, tablemeta, original): recreate = tablemeta.as_cql_query(formatted=False) self.assertEqual(original, recreate[:len(original)]) execute_until_pass(self.session, "DROP TABLE {0}.{1}".format(self.keyspace_name, self.function_table_name)) execute_until_pass(self.session, recreate) # create the table again, but with formatting enabled execute_until_pass(self.session, "DROP TABLE {0}.{1}".format(self.keyspace_name, self.function_table_name)) recreate = tablemeta.as_cql_query(formatted=True) execute_until_pass(self.session, recreate) def get_table_metadata(self): self.cluster.refresh_table_metadata(self.keyspace_name, self.function_table_name) return self.cluster.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name] def test_basic_table_meta_properties(self): create_statement = self.make_create_statement(["a"], [], ["b", "c"]) self.session.execute(create_statement) self.cluster.refresh_schema_metadata() meta = self.cluster.metadata self.assertNotEqual(meta.cluster_name, None) self.assertTrue(self.keyspace_name in meta.keyspaces) ksmeta = meta.keyspaces[self.keyspace_name] self.assertEqual(ksmeta.name, self.keyspace_name) self.assertTrue(ksmeta.durable_writes) self.assertEqual(ksmeta.replication_strategy.name, 'SimpleStrategy') self.assertEqual(ksmeta.replication_strategy.replication_factor, 1) self.assertTrue(self.function_table_name in ksmeta.tables) tablemeta = ksmeta.tables[self.function_table_name] self.assertEqual(tablemeta.keyspace_name, ksmeta.name) self.assertEqual(tablemeta.name, self.function_table_name) self.assertEqual(tablemeta.name, self.function_table_name) self.assertEqual([u'a'], [c.name for c in tablemeta.partition_key]) self.assertEqual([], tablemeta.clustering_key) self.assertEqual([u'a', u'b', u'c'], sorted(tablemeta.columns.keys())) cc = self.cluster.control_connection._connection parser = get_schema_parser(cc, str(CASS_SERVER_VERSION[0]), 1) for option in tablemeta.options: self.assertIn(option, parser.recognized_table_options) self.check_create_statement(tablemeta, create_statement) def test_compound_primary_keys(self): create_statement = self.make_create_statement(["a"], ["b"], ["c"]) create_statement += " WITH CLUSTERING ORDER BY (b ASC)" self.session.execute(create_statement) tablemeta = self.get_table_metadata() self.assertEqual([u'a'], [c.name for c in tablemeta.partition_key]) self.assertEqual([u'b'], [c.name for c in tablemeta.clustering_key]) self.assertEqual([u'a', u'b', u'c'], sorted(tablemeta.columns.keys())) self.check_create_statement(tablemeta, create_statement) def test_compound_primary_keys_protected(self): create_statement = self.make_create_statement(["Aa"], ["Bb"], ["Cc"]) create_statement += ' WITH CLUSTERING ORDER BY ("Bb" ASC)' self.session.execute(create_statement) tablemeta = self.get_table_metadata() self.assertEqual([u'Aa'], [c.name for c in tablemeta.partition_key]) self.assertEqual([u'Bb'], [c.name for c in tablemeta.clustering_key]) self.assertEqual([u'Aa', u'Bb', u'Cc'], sorted(tablemeta.columns.keys())) self.check_create_statement(tablemeta, create_statement) def test_compound_primary_keys_more_columns(self): create_statement = self.make_create_statement(["a"], ["b", "c"], ["d", "e", "f"]) create_statement += " WITH CLUSTERING ORDER BY (b ASC, c ASC)" self.session.execute(create_statement) tablemeta = self.get_table_metadata() self.assertEqual([u'a'], [c.name for c in tablemeta.partition_key]) self.assertEqual([u'b', u'c'], [c.name for c in tablemeta.clustering_key]) self.assertEqual( [u'a', u'b', u'c', u'd', u'e', u'f'], sorted(tablemeta.columns.keys())) self.check_create_statement(tablemeta, create_statement) def test_composite_primary_key(self): create_statement = self.make_create_statement(["a", "b"], [], ["c"]) self.session.execute(create_statement) tablemeta = self.get_table_metadata() self.assertEqual([u'a', u'b'], [c.name for c in tablemeta.partition_key]) self.assertEqual([], tablemeta.clustering_key) self.assertEqual([u'a', u'b', u'c'], sorted(tablemeta.columns.keys())) self.check_create_statement(tablemeta, create_statement) def test_composite_in_compound_primary_key(self): create_statement = self.make_create_statement(["a", "b"], ["c"], ["d", "e"]) create_statement += " WITH CLUSTERING ORDER BY (c ASC)" self.session.execute(create_statement) tablemeta = self.get_table_metadata() self.assertEqual([u'a', u'b'], [c.name for c in tablemeta.partition_key]) self.assertEqual([u'c'], [c.name for c in tablemeta.clustering_key]) self.assertEqual([u'a', u'b', u'c', u'd', u'e'], sorted(tablemeta.columns.keys())) self.check_create_statement(tablemeta, create_statement) def test_compound_primary_keys_compact(self): create_statement = self.make_create_statement(["a"], ["b"], ["c"], compact=True) create_statement += " AND CLUSTERING ORDER BY (b ASC)" self.session.execute(create_statement) tablemeta = self.get_table_metadata() self.assertEqual([u'a'], [c.name for c in tablemeta.partition_key]) self.assertEqual([u'b'], [c.name for c in tablemeta.clustering_key]) self.assertEqual([u'a', u'b', u'c'], sorted(tablemeta.columns.keys())) self.check_create_statement(tablemeta, create_statement) def test_cluster_column_ordering_reversed_metadata(self): """ Simple test to ensure that the metatdata associated with cluster ordering is surfaced is surfaced correctly. Creates a table with a few clustering keys. Then checks the clustering order associated with clustering columns and ensure it's set correctly. @since 3.0.0 @jira_ticket PYTHON-402 @expected_result is_reversed is set on DESC order, and is False on ASC @test_category metadata """ create_statement = self.make_create_statement(["a"], ["b", "c"], ["d"], compact=True) create_statement += " AND CLUSTERING ORDER BY (b ASC, c DESC)" self.session.execute(create_statement) tablemeta = self.get_table_metadata() b_column = tablemeta.columns['b'] self.assertFalse(b_column.is_reversed) c_column = tablemeta.columns['c'] self.assertTrue(c_column.is_reversed) def test_compound_primary_keys_more_columns_compact(self): create_statement = self.make_create_statement(["a"], ["b", "c"], ["d"], compact=True) create_statement += " AND CLUSTERING ORDER BY (b ASC, c ASC)" self.session.execute(create_statement) tablemeta = self.get_table_metadata() self.assertEqual([u'a'], [c.name for c in tablemeta.partition_key]) self.assertEqual([u'b', u'c'], [c.name for c in tablemeta.clustering_key]) self.assertEqual([u'a', u'b', u'c', u'd'], sorted(tablemeta.columns.keys())) self.check_create_statement(tablemeta, create_statement) def test_composite_primary_key_compact(self): create_statement = self.make_create_statement(["a", "b"], [], ["c"], compact=True) self.session.execute(create_statement) tablemeta = self.get_table_metadata() self.assertEqual([u'a', u'b'], [c.name for c in tablemeta.partition_key]) self.assertEqual([], tablemeta.clustering_key) self.assertEqual([u'a', u'b', u'c'], sorted(tablemeta.columns.keys())) self.check_create_statement(tablemeta, create_statement) def test_composite_in_compound_primary_key_compact(self): create_statement = self.make_create_statement(["a", "b"], ["c"], ["d"], compact=True) create_statement += " AND CLUSTERING ORDER BY (c ASC)" self.session.execute(create_statement) tablemeta = self.get_table_metadata() self.assertEqual([u'a', u'b'], [c.name for c in tablemeta.partition_key]) self.assertEqual([u'c'], [c.name for c in tablemeta.clustering_key]) self.assertEqual([u'a', u'b', u'c', u'd'], sorted(tablemeta.columns.keys())) self.check_create_statement(tablemeta, create_statement) def test_cql_compatibility(self): if CASS_SERVER_VERSION >= (3, 0): raise unittest.SkipTest("cql compatibility does not apply Cassandra 3.0+") # having more than one non-PK column is okay if there aren't any # clustering columns create_statement = self.make_create_statement(["a"], [], ["b", "c", "d"], compact=True) self.session.execute(create_statement) tablemeta = self.get_table_metadata() self.assertEqual([u'a'], [c.name for c in tablemeta.partition_key]) self.assertEqual([], tablemeta.clustering_key) self.assertEqual([u'a', u'b', u'c', u'd'], sorted(tablemeta.columns.keys())) self.assertTrue(tablemeta.is_cql_compatible) # ... but if there are clustering columns, it's not CQL compatible. # This is a hacky way to simulate having clustering columns. tablemeta.clustering_key = ["foo", "bar"] tablemeta.columns["foo"] = None tablemeta.columns["bar"] = None self.assertFalse(tablemeta.is_cql_compatible) def test_compound_primary_keys_ordering(self): create_statement = self.make_create_statement(["a"], ["b"], ["c"]) create_statement += " WITH CLUSTERING ORDER BY (b DESC)" self.session.execute(create_statement) tablemeta = self.get_table_metadata() self.check_create_statement(tablemeta, create_statement) def test_compound_primary_keys_more_columns_ordering(self): create_statement = self.make_create_statement(["a"], ["b", "c"], ["d", "e", "f"]) create_statement += " WITH CLUSTERING ORDER BY (b DESC, c ASC)" self.session.execute(create_statement) tablemeta = self.get_table_metadata() self.check_create_statement(tablemeta, create_statement) def test_composite_in_compound_primary_key_ordering(self): create_statement = self.make_create_statement(["a", "b"], ["c"], ["d", "e"]) create_statement += " WITH CLUSTERING ORDER BY (c DESC)" self.session.execute(create_statement) tablemeta = self.get_table_metadata() self.check_create_statement(tablemeta, create_statement) def test_indexes(self): create_statement = self.make_create_statement(["a"], ["b", "c"], ["d", "e", "f"]) create_statement += " WITH CLUSTERING ORDER BY (b ASC, c ASC)" execute_until_pass(self.session, create_statement) d_index = "CREATE INDEX d_index ON %s.%s (d)" % (self.keyspace_name, self.function_table_name) e_index = "CREATE INDEX e_index ON %s.%s (e)" % (self.keyspace_name, self.function_table_name) execute_until_pass(self.session, d_index) execute_until_pass(self.session, e_index) tablemeta = self.get_table_metadata() statements = tablemeta.export_as_string().strip() statements = [s.strip() for s in statements.split(';')] statements = list(filter(bool, statements)) self.assertEqual(3, len(statements)) self.assertIn(d_index, statements) self.assertIn(e_index, statements) # make sure indexes are included in KeyspaceMetadata.export_as_string() ksmeta = self.cluster.metadata.keyspaces[self.keyspace_name] statement = ksmeta.export_as_string() self.assertIn('CREATE INDEX d_index', statement) self.assertIn('CREATE INDEX e_index', statement) def test_collection_indexes(self): if CASS_SERVER_VERSION < (2, 1, 0): raise unittest.SkipTest("Secondary index on collections were introduced in Cassandra 2.1") self.session.execute("CREATE TABLE %s.%s (a int PRIMARY KEY, b map)" % (self.keyspace_name, self.function_table_name)) self.session.execute("CREATE INDEX index1 ON %s.%s (keys(b))" % (self.keyspace_name, self.function_table_name)) tablemeta = self.get_table_metadata() self.assertIn('(keys(b))', tablemeta.export_as_string()) self.session.execute("DROP INDEX %s.index1" % (self.keyspace_name,)) self.session.execute("CREATE INDEX index2 ON %s.%s (b)" % (self.keyspace_name, self.function_table_name)) tablemeta = self.get_table_metadata() target = ' (b)' if CASS_SERVER_VERSION < (3, 0) else 'values(b))' # explicit values in C* 3+ self.assertIn(target, tablemeta.export_as_string()) # test full indexes on frozen collections, if available if CASS_SERVER_VERSION >= (2, 1, 3): self.session.execute("DROP TABLE %s.%s" % (self.keyspace_name, self.function_table_name)) self.session.execute("CREATE TABLE %s.%s (a int PRIMARY KEY, b frozen>)" % (self.keyspace_name, self.function_table_name)) self.session.execute("CREATE INDEX index3 ON %s.%s (full(b))" % (self.keyspace_name, self.function_table_name)) tablemeta = self.get_table_metadata() self.assertIn('(full(b))', tablemeta.export_as_string()) def test_compression_disabled(self): create_statement = self.make_create_statement(["a"], ["b"], ["c"]) create_statement += " WITH compression = {}" self.session.execute(create_statement) tablemeta = self.get_table_metadata() expected = "compression = {}" if CASS_SERVER_VERSION < (3, 0) else "compression = {'enabled': 'false'}" self.assertIn(expected, tablemeta.export_as_string()) def test_non_size_tiered_compaction(self): """ test options for non-size-tiered compaction strategy Creates a table with LeveledCompactionStrategy, specifying one non-default option. Verifies that the option is present in generated CQL, and that other legacy table parameters (min_threshold, max_threshold) are not included. @since 2.6.0 @jira_ticket PYTHON-352 @expected_result the options map for LeveledCompactionStrategy does not contain min_threshold, max_threshold @test_category metadata """ create_statement = self.make_create_statement(["a"], [], ["b", "c"]) create_statement += "WITH COMPACTION = {'class': 'LeveledCompactionStrategy', 'tombstone_threshold': '0.3'}" self.session.execute(create_statement) table_meta = self.get_table_metadata() cql = table_meta.export_as_string() self.assertIn("'tombstone_threshold': '0.3'", cql) self.assertIn("LeveledCompactionStrategy", cql) self.assertNotIn("min_threshold", cql) self.assertNotIn("max_threshold", cql) def test_refresh_schema_metadata(self): """ test for synchronously refreshing all cluster metadata test_refresh_schema_metadata tests all cluster metadata is refreshed when calling refresh_schema_metadata(). It creates a second cluster object with schema_event_refresh_window=-1 such that schema refreshes are disabled for schema change push events. It then alters the cluster, creating a new keyspace, using the first cluster object, and verifies that the cluster metadata has not changed in the second cluster object. It then calls refresh_schema_metadata() and verifies that the cluster metadata is updated in the second cluster object. Similarly, it then proceeds to altering keyspace, table, UDT, UDF, and UDA metadata and subsequently verfies that these metadata is updated when refresh_schema_metadata() is called. @since 2.6.0 @jira_ticket PYTHON-291 @expected_result Cluster, keyspace, table, UDT, UDF, and UDA metadata should be refreshed when refresh_schema_metadata() is called. @test_category metadata """ cluster2 = Cluster(protocol_version=PROTOCOL_VERSION, schema_event_refresh_window=-1) cluster2.connect() self.assertNotIn("new_keyspace", cluster2.metadata.keyspaces) # Cluster metadata modification self.session.execute("CREATE KEYSPACE new_keyspace WITH replication = {'class': 'SimpleStrategy', 'replication_factor': '1'}") self.assertNotIn("new_keyspace", cluster2.metadata.keyspaces) cluster2.refresh_schema_metadata() self.assertIn("new_keyspace", cluster2.metadata.keyspaces) # Keyspace metadata modification self.session.execute("ALTER KEYSPACE {0} WITH durable_writes = false".format(self.keyspace_name)) self.assertTrue(cluster2.metadata.keyspaces[self.keyspace_name].durable_writes) cluster2.refresh_schema_metadata() self.assertFalse(cluster2.metadata.keyspaces[self.keyspace_name].durable_writes) # Table metadata modification table_name = "test" self.session.execute("CREATE TABLE {0}.{1} (a int PRIMARY KEY, b text)".format(self.keyspace_name, table_name)) cluster2.refresh_schema_metadata() self.session.execute("ALTER TABLE {0}.{1} ADD c double".format(self.keyspace_name, table_name)) self.assertNotIn("c", cluster2.metadata.keyspaces[self.keyspace_name].tables[table_name].columns) cluster2.refresh_schema_metadata() self.assertIn("c", cluster2.metadata.keyspaces[self.keyspace_name].tables[table_name].columns) if PROTOCOL_VERSION >= 3: # UDT metadata modification self.session.execute("CREATE TYPE {0}.user (age int, name text)".format(self.keyspace_name)) self.assertEqual(cluster2.metadata.keyspaces[self.keyspace_name].user_types, {}) cluster2.refresh_schema_metadata() self.assertIn("user", cluster2.metadata.keyspaces[self.keyspace_name].user_types) if PROTOCOL_VERSION >= 4: # UDF metadata modification self.session.execute("""CREATE FUNCTION {0}.sum_int(key int, val int) RETURNS NULL ON NULL INPUT RETURNS int LANGUAGE javascript AS 'key + val';""".format(self.keyspace_name)) self.assertEqual(cluster2.metadata.keyspaces[self.keyspace_name].functions, {}) cluster2.refresh_schema_metadata() self.assertIn("sum_int(int,int)", cluster2.metadata.keyspaces[self.keyspace_name].functions) # UDA metadata modification self.session.execute("""CREATE AGGREGATE {0}.sum_agg(int) SFUNC sum_int STYPE int INITCOND 0""" .format(self.keyspace_name)) self.assertEqual(cluster2.metadata.keyspaces[self.keyspace_name].aggregates, {}) cluster2.refresh_schema_metadata() self.assertIn("sum_agg(int)", cluster2.metadata.keyspaces[self.keyspace_name].aggregates) # Cluster metadata modification self.session.execute("DROP KEYSPACE new_keyspace") self.assertIn("new_keyspace", cluster2.metadata.keyspaces) cluster2.refresh_schema_metadata() self.assertNotIn("new_keyspace", cluster2.metadata.keyspaces) cluster2.shutdown() def test_refresh_keyspace_metadata(self): """ test for synchronously refreshing keyspace metadata test_refresh_keyspace_metadata tests that keyspace metadata is refreshed when calling refresh_keyspace_metadata(). It creates a second cluster object with schema_event_refresh_window=-1 such that schema refreshes are disabled for schema change push events. It then alters the keyspace, disabling durable_writes, using the first cluster object, and verifies that the keyspace metadata has not changed in the second cluster object. Finally, it calls refresh_keyspace_metadata() and verifies that the keyspace metadata is updated in the second cluster object. @since 2.6.0 @jira_ticket PYTHON-291 @expected_result Keyspace metadata should be refreshed when refresh_keyspace_metadata() is called. @test_category metadata """ cluster2 = Cluster(protocol_version=PROTOCOL_VERSION, schema_event_refresh_window=-1) cluster2.connect() self.assertTrue(cluster2.metadata.keyspaces[self.keyspace_name].durable_writes) self.session.execute("ALTER KEYSPACE {0} WITH durable_writes = false".format(self.keyspace_name)) self.assertTrue(cluster2.metadata.keyspaces[self.keyspace_name].durable_writes) cluster2.refresh_keyspace_metadata(self.keyspace_name) self.assertFalse(cluster2.metadata.keyspaces[self.keyspace_name].durable_writes) cluster2.shutdown() def test_refresh_table_metadata(self): """ test for synchronously refreshing table metadata test_refresh_table_metatadata tests that table metadata is refreshed when calling test_refresh_table_metatadata(). It creates a second cluster object with schema_event_refresh_window=-1 such that schema refreshes are disabled for schema change push events. It then alters the table, adding a new column, using the first cluster object, and verifies that the table metadata has not changed in the second cluster object. Finally, it calls test_refresh_table_metatadata() and verifies that the table metadata is updated in the second cluster object. @since 2.6.0 @jira_ticket PYTHON-291 @expected_result Table metadata should be refreshed when refresh_table_metadata() is called. @test_category metadata """ table_name = "test" self.session.execute("CREATE TABLE {0}.{1} (a int PRIMARY KEY, b text)".format(self.keyspace_name, table_name)) cluster2 = Cluster(protocol_version=PROTOCOL_VERSION, schema_event_refresh_window=-1) cluster2.connect() self.assertNotIn("c", cluster2.metadata.keyspaces[self.keyspace_name].tables[table_name].columns) self.session.execute("ALTER TABLE {0}.{1} ADD c double".format(self.keyspace_name, table_name)) self.assertNotIn("c", cluster2.metadata.keyspaces[self.keyspace_name].tables[table_name].columns) cluster2.refresh_table_metadata(self.keyspace_name, table_name) self.assertIn("c", cluster2.metadata.keyspaces[self.keyspace_name].tables[table_name].columns) cluster2.shutdown() def test_refresh_metadata_for_mv(self): """ test for synchronously refreshing materialized view metadata test_refresh_table_metadata_for_materialized_views tests that materialized view metadata is refreshed when calling test_refresh_table_metatadata() with the materialized view name as the table. It creates a second cluster object with schema_event_refresh_window=-1 such that schema refreshes are disabled for schema change push events. It then creates a new materialized view , using the first cluster object, and verifies that the materialized view metadata has not changed in the second cluster object. Finally, it calls test_refresh_table_metatadata() with the materialized view name as the table name, and verifies that the materialized view metadata is updated in the second cluster object. @since 3.0.0 @jira_ticket PYTHON-371 @expected_result Materialized view metadata should be refreshed when refresh_table_metadata() is called. @test_category metadata """ if CASS_SERVER_VERSION < (3, 0): raise unittest.SkipTest("Materialized views require Cassandra 3.0+") self.session.execute("CREATE TABLE {0}.{1} (a int PRIMARY KEY, b text)".format(self.keyspace_name, self.function_table_name)) cluster2 = Cluster(protocol_version=PROTOCOL_VERSION, schema_event_refresh_window=-1) cluster2.connect() try: self.assertNotIn("mv1", cluster2.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].views) self.session.execute("CREATE MATERIALIZED VIEW {0}.mv1 AS SELECT b FROM {0}.{1} WHERE b IS NOT NULL PRIMARY KEY (a, b)" .format(self.keyspace_name, self.function_table_name)) self.assertNotIn("mv1", cluster2.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].views) cluster2.refresh_table_metadata(self.keyspace_name, "mv1") self.assertIn("mv1", cluster2.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].views) finally: cluster2.shutdown() original_meta = self.cluster.metadata.keyspaces[self.keyspace_name].views['mv1'] self.assertIs(original_meta, self.session.cluster.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].views['mv1']) self.cluster.refresh_materialized_view_metadata(self.keyspace_name, 'mv1') current_meta = self.cluster.metadata.keyspaces[self.keyspace_name].views['mv1'] self.assertIsNot(current_meta, original_meta) self.assertIsNot(original_meta, self.session.cluster.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].views['mv1']) self.assertEqual(original_meta.as_cql_query(), current_meta.as_cql_query()) cluster3 = Cluster(protocol_version=PROTOCOL_VERSION, schema_event_refresh_window=-1) cluster3.connect() try: self.assertNotIn("mv2", cluster3.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].views) self.session.execute("CREATE MATERIALIZED VIEW {0}.mv2 AS SELECT b FROM {0}.{1} WHERE b IS NOT NULL PRIMARY KEY (a, b)" .format(self.keyspace_name, self.function_table_name)) self.assertNotIn("mv2", cluster3.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].views) cluster3.refresh_materialized_view_metadata(self.keyspace_name, 'mv2') self.assertIn("mv2", cluster3.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].views) finally: cluster3.shutdown() def test_refresh_user_type_metadata(self): """ test for synchronously refreshing UDT metadata in keyspace test_refresh_user_type_metadata tests that UDT metadata in a keyspace is refreshed when calling refresh_user_type_metadata(). It creates a second cluster object with schema_event_refresh_window=-1 such that schema refreshes are disabled for schema change push events. It then alters the keyspace, creating a new UDT, using the first cluster object, and verifies that the UDT metadata has not changed in the second cluster object. Finally, it calls refresh_user_type_metadata() and verifies that the UDT metadata in the keyspace is updated in the second cluster object. @since 2.6.0 @jira_ticket PYTHON-291 @expected_result UDT metadata in the keyspace should be refreshed when refresh_user_type_metadata() is called. @test_category metadata """ if PROTOCOL_VERSION < 3: raise unittest.SkipTest("Protocol 3+ is required for UDTs, currently testing against {0}".format(PROTOCOL_VERSION)) cluster2 = Cluster(protocol_version=PROTOCOL_VERSION, schema_event_refresh_window=-1) cluster2.connect() self.assertEqual(cluster2.metadata.keyspaces[self.keyspace_name].user_types, {}) self.session.execute("CREATE TYPE {0}.user (age int, name text)".format(self.keyspace_name)) self.assertEqual(cluster2.metadata.keyspaces[self.keyspace_name].user_types, {}) cluster2.refresh_user_type_metadata(self.keyspace_name, "user") self.assertIn("user", cluster2.metadata.keyspaces[self.keyspace_name].user_types) cluster2.shutdown() def test_refresh_user_type_metadata_proto_2(self): """ Test to insure that protocol v1/v2 surface UDT metadata changes @since 3.7.0 @jira_ticket PYTHON-106 @expected_result UDT metadata in the keyspace should be updated regardless of protocol version @test_category metadata """ supported_versions = get_supported_protocol_versions() if 2 not in supported_versions or CASSANDRA_VERSION < "2.1": # 1 and 2 were dropped in the same version raise unittest.SkipTest("Protocol versions 1 and 2 are not supported in Cassandra version ".format(CASSANDRA_VERSION)) for protocol_version in (1, 2): cluster = Cluster(protocol_version=protocol_version) session = cluster.connect() self.assertEqual(cluster.metadata.keyspaces[self.keyspace_name].user_types, {}) session.execute("CREATE TYPE {0}.user (age int, name text)".format(self.keyspace_name)) self.assertIn("user", cluster.metadata.keyspaces[self.keyspace_name].user_types) self.assertIn("age", cluster.metadata.keyspaces[self.keyspace_name].user_types["user"].field_names) self.assertIn("name", cluster.metadata.keyspaces[self.keyspace_name].user_types["user"].field_names) session.execute("ALTER TYPE {0}.user ADD flag boolean".format(self.keyspace_name)) self.assertIn("flag", cluster.metadata.keyspaces[self.keyspace_name].user_types["user"].field_names) session.execute("ALTER TYPE {0}.user RENAME flag TO something".format(self.keyspace_name)) self.assertIn("something", cluster.metadata.keyspaces[self.keyspace_name].user_types["user"].field_names) session.execute("DROP TYPE {0}.user".format(self.keyspace_name)) self.assertEqual(cluster.metadata.keyspaces[self.keyspace_name].user_types, {}) cluster.shutdown() def test_refresh_user_function_metadata(self): """ test for synchronously refreshing UDF metadata in keyspace test_refresh_user_function_metadata tests that UDF metadata in a keyspace is refreshed when calling refresh_user_function_metadata(). It creates a second cluster object with schema_event_refresh_window=-1 such that schema refreshes are disabled for schema change push events. It then alters the keyspace, creating a new UDF, using the first cluster object, and verifies that the UDF metadata has not changed in the second cluster object. Finally, it calls refresh_user_function_metadata() and verifies that the UDF metadata in the keyspace is updated in the second cluster object. @since 2.6.0 @jira_ticket PYTHON-291 @expected_result UDF metadata in the keyspace should be refreshed when refresh_user_function_metadata() is called. @test_category metadata """ if PROTOCOL_VERSION < 4: raise unittest.SkipTest("Protocol 4+ is required for UDFs, currently testing against {0}".format(PROTOCOL_VERSION)) cluster2 = Cluster(protocol_version=PROTOCOL_VERSION, schema_event_refresh_window=-1) cluster2.connect() self.assertEqual(cluster2.metadata.keyspaces[self.keyspace_name].functions, {}) self.session.execute("""CREATE FUNCTION {0}.sum_int(key int, val int) RETURNS NULL ON NULL INPUT RETURNS int LANGUAGE javascript AS 'key + val';""".format(self.keyspace_name)) self.assertEqual(cluster2.metadata.keyspaces[self.keyspace_name].functions, {}) cluster2.refresh_user_function_metadata(self.keyspace_name, UserFunctionDescriptor("sum_int", ["int", "int"])) self.assertIn("sum_int(int,int)", cluster2.metadata.keyspaces[self.keyspace_name].functions) cluster2.shutdown() def test_refresh_user_aggregate_metadata(self): """ test for synchronously refreshing UDA metadata in keyspace test_refresh_user_aggregate_metadata tests that UDA metadata in a keyspace is refreshed when calling refresh_user_aggregate_metadata(). It creates a second cluster object with schema_event_refresh_window=-1 such that schema refreshes are disabled for schema change push events. It then alters the keyspace, creating a new UDA, using the first cluster object, and verifies that the UDA metadata has not changed in the second cluster object. Finally, it calls refresh_user_aggregate_metadata() and verifies that the UDF metadata in the keyspace is updated in the second cluster object. @since 2.6.0 @jira_ticket PYTHON-291 @expected_result UDA metadata in the keyspace should be refreshed when refresh_user_aggregate_metadata() is called. @test_category metadata """ if PROTOCOL_VERSION < 4: raise unittest.SkipTest("Protocol 4+ is required for UDAs, currently testing against {0}".format(PROTOCOL_VERSION)) cluster2 = Cluster(protocol_version=PROTOCOL_VERSION, schema_event_refresh_window=-1) cluster2.connect() self.assertEqual(cluster2.metadata.keyspaces[self.keyspace_name].aggregates, {}) self.session.execute("""CREATE FUNCTION {0}.sum_int(key int, val int) RETURNS NULL ON NULL INPUT RETURNS int LANGUAGE javascript AS 'key + val';""".format(self.keyspace_name)) self.session.execute("""CREATE AGGREGATE {0}.sum_agg(int) SFUNC sum_int STYPE int INITCOND 0""" .format(self.keyspace_name)) self.assertEqual(cluster2.metadata.keyspaces[self.keyspace_name].aggregates, {}) cluster2.refresh_user_aggregate_metadata(self.keyspace_name, UserAggregateDescriptor("sum_agg", ["int"])) self.assertIn("sum_agg(int)", cluster2.metadata.keyspaces[self.keyspace_name].aggregates) cluster2.shutdown() def test_multiple_indices(self): """ test multiple indices on the same column. Creates a table and two indices. Ensures that both indices metatdata is surface appropriately. @since 3.0.0 @jira_ticket PYTHON-276 @expected_result IndexMetadata is appropriately surfaced @test_category metadata """ if CASS_SERVER_VERSION < (3, 0): raise unittest.SkipTest("Materialized views require Cassandra 3.0+") self.session.execute("CREATE TABLE {0}.{1} (a int PRIMARY KEY, b map)".format(self.keyspace_name, self.function_table_name)) self.session.execute("CREATE INDEX index_1 ON {0}.{1}(b)".format(self.keyspace_name, self.function_table_name)) self.session.execute("CREATE INDEX index_2 ON {0}.{1}(keys(b))".format(self.keyspace_name, self.function_table_name)) indices = self.cluster.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].indexes self.assertEqual(len(indices), 2) index_1 = indices["index_1"] index_2 = indices['index_2'] self.assertEqual(index_1.table_name, "test_multiple_indices") self.assertEqual(index_1.name, "index_1") self.assertEqual(index_1.kind, "COMPOSITES") self.assertEqual(index_1.index_options["target"], "values(b)") self.assertEqual(index_1.keyspace_name, "schemametadatatests") self.assertEqual(index_2.table_name, "test_multiple_indices") self.assertEqual(index_2.name, "index_2") self.assertEqual(index_2.kind, "COMPOSITES") self.assertEqual(index_2.index_options["target"], "keys(b)") self.assertEqual(index_2.keyspace_name, "schemametadatatests") class TestCodeCoverage(unittest.TestCase): def test_export_schema(self): """ Test export schema functionality """ cluster = Cluster(protocol_version=PROTOCOL_VERSION) cluster.connect() self.assertIsInstance(cluster.metadata.export_schema_as_string(), six.string_types) def test_export_keyspace_schema(self): """ Test export keyspace schema functionality """ cluster = Cluster(protocol_version=PROTOCOL_VERSION) cluster.connect() for keyspace in cluster.metadata.keyspaces: keyspace_metadata = cluster.metadata.keyspaces[keyspace] self.assertIsInstance(keyspace_metadata.export_as_string(), six.string_types) self.assertIsInstance(keyspace_metadata.as_cql_query(), six.string_types) cluster.shutdown() def assert_equal_diff(self, received, expected): if received != expected: diff_string = '\n'.join(difflib.unified_diff(expected.split('\n'), received.split('\n'), 'EXPECTED', 'RECEIVED', lineterm='')) self.fail(diff_string) def assert_startswith_diff(self, received, prefix): if not received.startswith(prefix): prefix_lines = prefix.split('\n') diff_string = '\n'.join(difflib.unified_diff(prefix_lines, received.split('\n')[:len(prefix_lines)], 'EXPECTED', 'RECEIVED', lineterm='')) self.fail(diff_string) def test_export_keyspace_schema_udts(self): """ Test udt exports """ if CASS_SERVER_VERSION < (2, 1, 0): raise unittest.SkipTest('UDTs were introduced in Cassandra 2.1') if PROTOCOL_VERSION < 3: raise unittest.SkipTest( "Protocol 3.0+ is required for UDT change events, currently testing against %r" % (PROTOCOL_VERSION,)) if sys.version_info[0:2] != (2, 7): raise unittest.SkipTest('This test compares static strings generated from dict items, which may change orders. Test with 2.7.') cluster = Cluster(protocol_version=PROTOCOL_VERSION) session = cluster.connect() session.execute(""" CREATE KEYSPACE export_udts WITH replication = {'class': 'SimpleStrategy', 'replication_factor': '1'} AND durable_writes = true; """) session.execute(""" CREATE TYPE export_udts.street ( street_number int, street_name text) """) session.execute(""" CREATE TYPE export_udts.zip ( zipcode int, zip_plus_4 int) """) session.execute(""" CREATE TYPE export_udts.address ( street_address frozen, zip_code frozen) """) session.execute(""" CREATE TABLE export_udts.users ( user text PRIMARY KEY, addresses map>) """) expected_prefix = """CREATE KEYSPACE export_udts WITH replication = {'class': 'SimpleStrategy', 'replication_factor': '1'} AND durable_writes = true; CREATE TYPE export_udts.street ( street_number int, street_name text ); CREATE TYPE export_udts.zip ( zipcode int, zip_plus_4 int ); CREATE TYPE export_udts.address ( street_address frozen, zip_code frozen ); CREATE TABLE export_udts.users ( user text PRIMARY KEY, addresses map>""" self.assert_startswith_diff(cluster.metadata.keyspaces['export_udts'].export_as_string(), expected_prefix) table_meta = cluster.metadata.keyspaces['export_udts'].tables['users'] expected_prefix = """CREATE TABLE export_udts.users ( user text PRIMARY KEY, addresses map>""" self.assert_startswith_diff(table_meta.export_as_string(), expected_prefix) cluster.shutdown() def test_case_sensitivity(self): """ Test that names that need to be escaped in CREATE statements are """ cluster = Cluster(protocol_version=PROTOCOL_VERSION) session = cluster.connect() ksname = 'AnInterestingKeyspace' cfname = 'AnInterestingTable' session.execute(""" CREATE KEYSPACE "%s" WITH replication = {'class': 'SimpleStrategy', 'replication_factor': '1'} """ % (ksname,)) session.execute(""" CREATE TABLE "%s"."%s" ( k int, "A" int, "B" int, "MyColumn" int, PRIMARY KEY (k, "A")) WITH CLUSTERING ORDER BY ("A" DESC) """ % (ksname, cfname)) session.execute(""" CREATE INDEX myindex ON "%s"."%s" ("MyColumn") """ % (ksname, cfname)) session.execute(""" CREATE INDEX "AnotherIndex" ON "%s"."%s" ("B") """ % (ksname, cfname)) ksmeta = cluster.metadata.keyspaces[ksname] schema = ksmeta.export_as_string() self.assertIn('CREATE KEYSPACE "AnInterestingKeyspace"', schema) self.assertIn('CREATE TABLE "AnInterestingKeyspace"."AnInterestingTable"', schema) self.assertIn('"A" int', schema) self.assertIn('"B" int', schema) self.assertIn('"MyColumn" int', schema) self.assertIn('PRIMARY KEY (k, "A")', schema) self.assertIn('WITH CLUSTERING ORDER BY ("A" DESC)', schema) self.assertIn('CREATE INDEX myindex ON "AnInterestingKeyspace"."AnInterestingTable" ("MyColumn")', schema) self.assertIn('CREATE INDEX "AnotherIndex" ON "AnInterestingKeyspace"."AnInterestingTable" ("B")', schema) cluster.shutdown() def test_already_exists_exceptions(self): """ Ensure AlreadyExists exception is thrown when hit """ cluster = Cluster(protocol_version=PROTOCOL_VERSION) session = cluster.connect() ksname = 'test3rf' cfname = 'test' ddl = ''' CREATE KEYSPACE %s WITH replication = {'class': 'SimpleStrategy', 'replication_factor': '3'}''' self.assertRaises(AlreadyExists, session.execute, ddl % ksname) ddl = ''' CREATE TABLE %s.%s ( k int PRIMARY KEY, v int )''' self.assertRaises(AlreadyExists, session.execute, ddl % (ksname, cfname)) cluster.shutdown() def test_replicas(self): """ Ensure cluster.metadata.get_replicas return correctly when not attached to keyspace """ if murmur3 is None: raise unittest.SkipTest('the murmur3 extension is not available') cluster = Cluster(protocol_version=PROTOCOL_VERSION) self.assertEqual(cluster.metadata.get_replicas('test3rf', 'key'), []) cluster.connect('test3rf') self.assertNotEqual(list(cluster.metadata.get_replicas('test3rf', six.b('key'))), []) host = list(cluster.metadata.get_replicas('test3rf', six.b('key')))[0] self.assertEqual(host.datacenter, 'dc1') self.assertEqual(host.rack, 'r1') cluster.shutdown() def test_token_map(self): """ Test token mappings """ cluster = Cluster(protocol_version=PROTOCOL_VERSION) cluster.connect('test3rf') ring = cluster.metadata.token_map.ring owners = list(cluster.metadata.token_map.token_to_host_owner[token] for token in ring) get_replicas = cluster.metadata.token_map.get_replicas for ksname in ('test1rf', 'test2rf', 'test3rf'): self.assertNotEqual(list(get_replicas(ksname, ring[0])), []) for i, token in enumerate(ring): self.assertEqual(set(get_replicas('test3rf', token)), set(owners)) self.assertEqual(set(get_replicas('test2rf', token)), set([owners[(i + 1) % 3], owners[(i + 2) % 3]])) self.assertEqual(set(get_replicas('test1rf', token)), set([owners[(i + 1) % 3]])) cluster.shutdown() def test_legacy_tables(self): if CASS_SERVER_VERSION < (2, 1, 0): raise unittest.SkipTest('Test schema output assumes 2.1.0+ options') if CASS_SERVER_VERSION >= (2, 2, 0): raise unittest.SkipTest('Cannot test cli script on Cassandra 2.2.0+') if sys.version_info[0:2] != (2, 7): raise unittest.SkipTest('This test compares static strings generated from dict items, which may change orders. Test with 2.7.') cli_script = """CREATE KEYSPACE legacy WITH placement_strategy = 'SimpleStrategy' AND strategy_options = {replication_factor:1}; USE legacy; CREATE COLUMN FAMILY simple_no_col WITH comparator = UTF8Type AND key_validation_class = UUIDType AND default_validation_class = UTF8Type; CREATE COLUMN FAMILY simple_with_col WITH comparator = UTF8Type and key_validation_class = UUIDType and default_validation_class = UTF8Type AND column_metadata = [ {column_name: col_with_meta, validation_class: UTF8Type} ]; CREATE COLUMN FAMILY composite_partition_no_col WITH comparator = UTF8Type AND key_validation_class = 'CompositeType(UUIDType,UTF8Type)' AND default_validation_class = UTF8Type; CREATE COLUMN FAMILY composite_partition_with_col WITH comparator = UTF8Type AND key_validation_class = 'CompositeType(UUIDType,UTF8Type)' AND default_validation_class = UTF8Type AND column_metadata = [ {column_name: col_with_meta, validation_class: UTF8Type} ]; CREATE COLUMN FAMILY nested_composite_key WITH comparator = UTF8Type and key_validation_class = 'CompositeType(CompositeType(UUIDType,UTF8Type), LongType)' and default_validation_class = UTF8Type AND column_metadata = [ {column_name: full_name, validation_class: UTF8Type} ]; create column family composite_comp_no_col with column_type = 'Standard' and comparator = 'DynamicCompositeType(t=>org.apache.cassandra.db.marshal.TimeUUIDType,s=>org.apache.cassandra.db.marshal.UTF8Type,b=>org.apache.cassandra.db.marshal.BytesType)' and default_validation_class = 'BytesType' and key_validation_class = 'BytesType' and read_repair_chance = 0.0 and dclocal_read_repair_chance = 0.1 and gc_grace = 864000 and min_compaction_threshold = 4 and max_compaction_threshold = 32 and compaction_strategy = 'org.apache.cassandra.db.compaction.SizeTieredCompactionStrategy' and caching = 'KEYS_ONLY' and cells_per_row_to_cache = '0' and default_time_to_live = 0 and speculative_retry = 'NONE' and comment = 'Stores file meta data'; create column family composite_comp_with_col with column_type = 'Standard' and comparator = 'DynamicCompositeType(t=>org.apache.cassandra.db.marshal.TimeUUIDType,s=>org.apache.cassandra.db.marshal.UTF8Type,b=>org.apache.cassandra.db.marshal.BytesType)' and default_validation_class = 'BytesType' and key_validation_class = 'BytesType' and read_repair_chance = 0.0 and dclocal_read_repair_chance = 0.1 and gc_grace = 864000 and min_compaction_threshold = 4 and max_compaction_threshold = 32 and compaction_strategy = 'org.apache.cassandra.db.compaction.SizeTieredCompactionStrategy' and caching = 'KEYS_ONLY' and cells_per_row_to_cache = '0' and default_time_to_live = 0 and speculative_retry = 'NONE' and comment = 'Stores file meta data' and column_metadata = [ {column_name : 'b@6d616d6d616a616d6d61', validation_class : BytesType, index_name : 'idx_one', index_type : 0}, {column_name : 'b@6869746d65776974686d75736963', validation_class : BytesType, index_name : 'idx_two', index_type : 0}] and compression_options = {'sstable_compression' : 'org.apache.cassandra.io.compress.LZ4Compressor'};""" # note: the inner key type for legacy.nested_composite_key # (org.apache.cassandra.db.marshal.CompositeType(org.apache.cassandra.db.marshal.UUIDType, org.apache.cassandra.db.marshal.UTF8Type)) # is a bit strange, but it replays in CQL with desired results expected_string = """CREATE KEYSPACE legacy WITH replication = {'class': 'SimpleStrategy', 'replication_factor': '1'} AND durable_writes = true; /* Warning: Table legacy.composite_comp_with_col omitted because it has constructs not compatible with CQL (was created via legacy API). Approximate structure, for reference: (this should not be used to reproduce this schema) CREATE TABLE legacy.composite_comp_with_col ( key blob, column1 'org.apache.cassandra.db.marshal.DynamicCompositeType(b=>org.apache.cassandra.db.marshal.BytesType, s=>org.apache.cassandra.db.marshal.UTF8Type, t=>org.apache.cassandra.db.marshal.TimeUUIDType)', "b@6869746d65776974686d75736963" blob, "b@6d616d6d616a616d6d61" blob, PRIMARY KEY (key, column1) ) WITH COMPACT STORAGE AND CLUSTERING ORDER BY (column1 ASC) AND caching = '{"keys":"ALL", "rows_per_partition":"NONE"}' AND comment = 'Stores file meta data' AND compaction = {'min_threshold': '4', 'class': 'org.apache.cassandra.db.compaction.SizeTieredCompactionStrategy', 'max_threshold': '32'} AND compression = {'sstable_compression': 'org.apache.cassandra.io.compress.LZ4Compressor'} AND dclocal_read_repair_chance = 0.1 AND default_time_to_live = 0 AND gc_grace_seconds = 864000 AND max_index_interval = 2048 AND memtable_flush_period_in_ms = 0 AND min_index_interval = 128 AND read_repair_chance = 0.0 AND speculative_retry = 'NONE'; CREATE INDEX idx_two ON legacy.composite_comp_with_col ("b@6869746d65776974686d75736963"); CREATE INDEX idx_one ON legacy.composite_comp_with_col ("b@6d616d6d616a616d6d61"); */ CREATE TABLE legacy.nested_composite_key ( key 'org.apache.cassandra.db.marshal.CompositeType(org.apache.cassandra.db.marshal.UUIDType, org.apache.cassandra.db.marshal.UTF8Type)', key2 bigint, full_name text, PRIMARY KEY ((key, key2)) ) WITH COMPACT STORAGE AND caching = '{"keys":"ALL", "rows_per_partition":"NONE"}' AND comment = '' AND compaction = {'class': 'org.apache.cassandra.db.compaction.SizeTieredCompactionStrategy'} AND compression = {'sstable_compression': 'org.apache.cassandra.io.compress.LZ4Compressor'} AND dclocal_read_repair_chance = 0.1 AND default_time_to_live = 0 AND gc_grace_seconds = 864000 AND max_index_interval = 2048 AND memtable_flush_period_in_ms = 0 AND min_index_interval = 128 AND read_repair_chance = 0.0 AND speculative_retry = 'NONE'; CREATE TABLE legacy.composite_partition_with_col ( key uuid, key2 text, col_with_meta text, PRIMARY KEY ((key, key2)) ) WITH COMPACT STORAGE AND caching = '{"keys":"ALL", "rows_per_partition":"NONE"}' AND comment = '' AND compaction = {'class': 'org.apache.cassandra.db.compaction.SizeTieredCompactionStrategy'} AND compression = {'sstable_compression': 'org.apache.cassandra.io.compress.LZ4Compressor'} AND dclocal_read_repair_chance = 0.1 AND default_time_to_live = 0 AND gc_grace_seconds = 864000 AND max_index_interval = 2048 AND memtable_flush_period_in_ms = 0 AND min_index_interval = 128 AND read_repair_chance = 0.0 AND speculative_retry = 'NONE'; CREATE TABLE legacy.composite_partition_no_col ( key uuid, key2 text, column1 text, value text, PRIMARY KEY ((key, key2), column1) ) WITH COMPACT STORAGE AND CLUSTERING ORDER BY (column1 ASC) AND caching = '{"keys":"ALL", "rows_per_partition":"NONE"}' AND comment = '' AND compaction = {'class': 'org.apache.cassandra.db.compaction.SizeTieredCompactionStrategy'} AND compression = {'sstable_compression': 'org.apache.cassandra.io.compress.LZ4Compressor'} AND dclocal_read_repair_chance = 0.1 AND default_time_to_live = 0 AND gc_grace_seconds = 864000 AND max_index_interval = 2048 AND memtable_flush_period_in_ms = 0 AND min_index_interval = 128 AND read_repair_chance = 0.0 AND speculative_retry = 'NONE'; CREATE TABLE legacy.simple_with_col ( key uuid PRIMARY KEY, col_with_meta text ) WITH COMPACT STORAGE AND caching = '{"keys":"ALL", "rows_per_partition":"NONE"}' AND comment = '' AND compaction = {'class': 'org.apache.cassandra.db.compaction.SizeTieredCompactionStrategy'} AND compression = {'sstable_compression': 'org.apache.cassandra.io.compress.LZ4Compressor'} AND dclocal_read_repair_chance = 0.1 AND default_time_to_live = 0 AND gc_grace_seconds = 864000 AND max_index_interval = 2048 AND memtable_flush_period_in_ms = 0 AND min_index_interval = 128 AND read_repair_chance = 0.0 AND speculative_retry = 'NONE'; CREATE TABLE legacy.simple_no_col ( key uuid, column1 text, value text, PRIMARY KEY (key, column1) ) WITH COMPACT STORAGE AND CLUSTERING ORDER BY (column1 ASC) AND caching = '{"keys":"ALL", "rows_per_partition":"NONE"}' AND comment = '' AND compaction = {'class': 'org.apache.cassandra.db.compaction.SizeTieredCompactionStrategy'} AND compression = {'sstable_compression': 'org.apache.cassandra.io.compress.LZ4Compressor'} AND dclocal_read_repair_chance = 0.1 AND default_time_to_live = 0 AND gc_grace_seconds = 864000 AND max_index_interval = 2048 AND memtable_flush_period_in_ms = 0 AND min_index_interval = 128 AND read_repair_chance = 0.0 AND speculative_retry = 'NONE'; CREATE TABLE legacy.composite_comp_no_col ( key blob, column1 'org.apache.cassandra.db.marshal.DynamicCompositeType(b=>org.apache.cassandra.db.marshal.BytesType, s=>org.apache.cassandra.db.marshal.UTF8Type, t=>org.apache.cassandra.db.marshal.TimeUUIDType)', value blob, PRIMARY KEY (key, column1) ) WITH COMPACT STORAGE AND CLUSTERING ORDER BY (column1 ASC) AND caching = '{"keys":"ALL", "rows_per_partition":"NONE"}' AND comment = 'Stores file meta data' AND compaction = {'min_threshold': '4', 'class': 'org.apache.cassandra.db.compaction.SizeTieredCompactionStrategy', 'max_threshold': '32'} AND compression = {'sstable_compression': 'org.apache.cassandra.io.compress.LZ4Compressor'} AND dclocal_read_repair_chance = 0.1 AND default_time_to_live = 0 AND gc_grace_seconds = 864000 AND max_index_interval = 2048 AND memtable_flush_period_in_ms = 0 AND min_index_interval = 128 AND read_repair_chance = 0.0 AND speculative_retry = 'NONE';""" ccm = get_cluster() livenodes = [node for node in list(ccm.nodelist()) if node.is_live()] livenodes[0].run_cli(cli_script) cluster = Cluster(protocol_version=PROTOCOL_VERSION) session = cluster.connect() legacy_meta = cluster.metadata.keyspaces['legacy'] print(legacy_meta.export_as_string()) self.assert_equal_diff(legacy_meta.export_as_string(), expected_string) session.execute('DROP KEYSPACE legacy') cluster.shutdown() class TokenMetadataTest(unittest.TestCase): """ Test of TokenMap creation and other behavior. """ def test_token(self): expected_node_count = len(get_cluster().nodes) cluster = Cluster(protocol_version=PROTOCOL_VERSION) cluster.connect() tmap = cluster.metadata.token_map self.assertTrue(issubclass(tmap.token_class, Token)) self.assertEqual(expected_node_count, len(tmap.ring)) cluster.shutdown() def test_getting_replicas(self): tokens = [MD5Token(i) for i in range(0, (2 ** 127 - 1), 2 ** 125)] hosts = [Host("ip%d" % i, SimpleConvictionPolicy) for i in range(len(tokens))] token_to_primary_replica = dict(zip(tokens, hosts)) keyspace = KeyspaceMetadata("ks", True, "SimpleStrategy", {"replication_factor": "1"}) metadata = Mock(spec=Metadata, keyspaces={'ks': keyspace}) token_map = TokenMap(MD5Token, token_to_primary_replica, tokens, metadata) # tokens match node tokens exactly for i, token in enumerate(tokens): expected_host = hosts[(i + 1) % len(hosts)] replicas = token_map.get_replicas("ks", token) self.assertEqual(set(replicas), set([expected_host])) # shift the tokens back by one for token, expected_host in zip(tokens, hosts): replicas = token_map.get_replicas("ks", MD5Token(token.value - 1)) self.assertEqual(set(replicas), set([expected_host])) # shift the tokens forward by one for i, token in enumerate(tokens): replicas = token_map.get_replicas("ks", MD5Token(token.value + 1)) expected_host = hosts[(i + 1) % len(hosts)] self.assertEqual(set(replicas), set([expected_host])) class KeyspaceAlterMetadata(unittest.TestCase): """ Test verifies that table metadata is preserved on keyspace alter """ def setUp(self): self.cluster = Cluster(protocol_version=PROTOCOL_VERSION) self.session = self.cluster.connect() name = self._testMethodName.lower() crt_ks = ''' CREATE KEYSPACE %s WITH replication = {'class': 'SimpleStrategy', 'replication_factor': 1} AND durable_writes = true''' % name self.session.execute(crt_ks) def tearDown(self): name = self._testMethodName.lower() self.session.execute('DROP KEYSPACE %s' % name) self.cluster.shutdown() def test_keyspace_alter(self): """ Table info is preserved upon keyspace alter: Create table Verify schema Alter ks Verify that table metadata is still present PYTHON-173 """ name = self._testMethodName.lower() self.session.execute('CREATE TABLE %s.d (d INT PRIMARY KEY)' % name) original_keyspace_meta = self.cluster.metadata.keyspaces[name] self.assertEqual(original_keyspace_meta.durable_writes, True) self.assertEqual(len(original_keyspace_meta.tables), 1) self.session.execute('ALTER KEYSPACE %s WITH durable_writes = false' % name) new_keyspace_meta = self.cluster.metadata.keyspaces[name] self.assertNotEqual(original_keyspace_meta, new_keyspace_meta) self.assertEqual(new_keyspace_meta.durable_writes, False) class IndexMapTests(unittest.TestCase): keyspace_name = 'index_map_tests' @property def table_name(self): return self._testMethodName.lower() @classmethod def setup_class(cls): cls.cluster = Cluster(protocol_version=PROTOCOL_VERSION) cls.session = cls.cluster.connect() try: if cls.keyspace_name in cls.cluster.metadata.keyspaces: cls.session.execute("DROP KEYSPACE %s" % cls.keyspace_name) cls.session.execute( """ CREATE KEYSPACE %s WITH replication = {'class': 'SimpleStrategy', 'replication_factor': '1'}; """ % cls.keyspace_name) cls.session.set_keyspace(cls.keyspace_name) except Exception: cls.cluster.shutdown() raise @classmethod def teardown_class(cls): try: cls.session.execute("DROP KEYSPACE %s" % cls.keyspace_name) finally: cls.cluster.shutdown() def create_basic_table(self): self.session.execute("CREATE TABLE %s (k int PRIMARY KEY, a int)" % self.table_name) def drop_basic_table(self): self.session.execute("DROP TABLE %s" % self.table_name) def test_index_updates(self): self.create_basic_table() ks_meta = self.cluster.metadata.keyspaces[self.keyspace_name] table_meta = ks_meta.tables[self.table_name] self.assertNotIn('a_idx', ks_meta.indexes) self.assertNotIn('b_idx', ks_meta.indexes) self.assertNotIn('a_idx', table_meta.indexes) self.assertNotIn('b_idx', table_meta.indexes) self.session.execute("CREATE INDEX a_idx ON %s (a)" % self.table_name) self.session.execute("ALTER TABLE %s ADD b int" % self.table_name) self.session.execute("CREATE INDEX b_idx ON %s (b)" % self.table_name) ks_meta = self.cluster.metadata.keyspaces[self.keyspace_name] table_meta = ks_meta.tables[self.table_name] self.assertIsInstance(ks_meta.indexes['a_idx'], IndexMetadata) self.assertIsInstance(ks_meta.indexes['b_idx'], IndexMetadata) self.assertIsInstance(table_meta.indexes['a_idx'], IndexMetadata) self.assertIsInstance(table_meta.indexes['b_idx'], IndexMetadata) # both indexes updated when index dropped self.session.execute("DROP INDEX a_idx") # temporarily synchronously refresh the schema metadata, until CASSANDRA-9391 is merged in self.cluster.refresh_table_metadata(self.keyspace_name, self.table_name) ks_meta = self.cluster.metadata.keyspaces[self.keyspace_name] table_meta = ks_meta.tables[self.table_name] self.assertNotIn('a_idx', ks_meta.indexes) self.assertIsInstance(ks_meta.indexes['b_idx'], IndexMetadata) self.assertNotIn('a_idx', table_meta.indexes) self.assertIsInstance(table_meta.indexes['b_idx'], IndexMetadata) # keyspace index updated when table dropped self.drop_basic_table() ks_meta = self.cluster.metadata.keyspaces[self.keyspace_name] self.assertNotIn(self.table_name, ks_meta.tables) self.assertNotIn('a_idx', ks_meta.indexes) self.assertNotIn('b_idx', ks_meta.indexes) def test_index_follows_alter(self): self.create_basic_table() idx = self.table_name + '_idx' self.session.execute("CREATE INDEX %s ON %s (a)" % (idx, self.table_name)) ks_meta = self.cluster.metadata.keyspaces[self.keyspace_name] table_meta = ks_meta.tables[self.table_name] self.assertIsInstance(ks_meta.indexes[idx], IndexMetadata) self.assertIsInstance(table_meta.indexes[idx], IndexMetadata) self.session.execute('ALTER KEYSPACE %s WITH durable_writes = false' % self.keyspace_name) old_meta = ks_meta ks_meta = self.cluster.metadata.keyspaces[self.keyspace_name] self.assertIsNot(ks_meta, old_meta) table_meta = ks_meta.tables[self.table_name] self.assertIsInstance(ks_meta.indexes[idx], IndexMetadata) self.assertIsInstance(table_meta.indexes[idx], IndexMetadata) self.drop_basic_table() class FunctionTest(unittest.TestCase): """ Base functionality for Function and Aggregate metadata test classes """ def setUp(self): """ Tests are skipped if run with native protocol version < 4 """ if PROTOCOL_VERSION < 4: raise unittest.SkipTest("Function metadata requires native protocol version 4+") @property def function_name(self): return self._testMethodName.lower() @classmethod def setup_class(cls): if PROTOCOL_VERSION >= 4: cls.cluster = Cluster(protocol_version=PROTOCOL_VERSION) cls.keyspace_name = cls.__name__.lower() cls.session = cls.cluster.connect() cls.session.execute("CREATE KEYSPACE IF NOT EXISTS %s WITH replication = {'class': 'SimpleStrategy', 'replication_factor': 1}" % cls.keyspace_name) cls.session.set_keyspace(cls.keyspace_name) cls.keyspace_function_meta = cls.cluster.metadata.keyspaces[cls.keyspace_name].functions cls.keyspace_aggregate_meta = cls.cluster.metadata.keyspaces[cls.keyspace_name].aggregates @classmethod def teardown_class(cls): if PROTOCOL_VERSION >= 4: cls.session.execute("DROP KEYSPACE IF EXISTS %s" % cls.keyspace_name) cls.cluster.shutdown() class Verified(object): def __init__(self, test_case, meta_class, element_meta, **function_kwargs): self.test_case = test_case self.function_kwargs = dict(function_kwargs) self.meta_class = meta_class self.element_meta = element_meta def __enter__(self): tc = self.test_case expected_meta = self.meta_class(**self.function_kwargs) tc.assertNotIn(expected_meta.signature, self.element_meta) tc.session.execute(expected_meta.as_cql_query()) tc.assertIn(expected_meta.signature, self.element_meta) generated_meta = self.element_meta[expected_meta.signature] self.test_case.assertEqual(generated_meta.as_cql_query(), expected_meta.as_cql_query()) return self def __exit__(self, exc_type, exc_val, exc_tb): tc = self.test_case tc.session.execute("DROP %s %s.%s" % (self.meta_class.__name__, tc.keyspace_name, self.signature)) tc.assertNotIn(self.signature, self.element_meta) @property def signature(self): return SignatureDescriptor.format_signature(self.function_kwargs['name'], self.function_kwargs['argument_types']) class VerifiedFunction(Verified): def __init__(self, test_case, **kwargs): super(FunctionTest.VerifiedFunction, self).__init__(test_case, Function, test_case.keyspace_function_meta, **kwargs) class VerifiedAggregate(Verified): def __init__(self, test_case, **kwargs): super(FunctionTest.VerifiedAggregate, self).__init__(test_case, Aggregate, test_case.keyspace_aggregate_meta, **kwargs) class FunctionMetadata(FunctionTest): def make_function_kwargs(self, called_on_null=True): return {'keyspace': self.keyspace_name, 'name': self.function_name, 'argument_types': ['double', 'int'], 'argument_names': ['d', 'i'], 'return_type': 'double', 'language': 'java', 'body': 'return new Double(0.0);', 'called_on_null_input': called_on_null} def test_functions_after_udt(self): """ Test to to ensure functions come after UDTs in in keyspace dump test_functions_after_udt creates a basic function. Then queries that function and make sure that in the results that UDT's are listed before any corresponding functions, when we dump the keyspace Ideally we would make a function that takes a udt type, but this presently fails because C* c059a56 requires udt to be frozen to create, but does not store meta indicating frozen SEE https://issues.apache.org/jira/browse/CASSANDRA-9186 Maybe update this after release kwargs = self.make_function_kwargs() kwargs['argument_types'][0] = "frozen<%s>" % udt_name expected_meta = Function(**kwargs) with self.VerifiedFunction(self, **kwargs): @since 2.6.0 @jira_ticket PYTHON-211 @expected_result UDT's should come before any functions @test_category function """ self.assertNotIn(self.function_name, self.keyspace_function_meta) udt_name = 'udtx' self.session.execute("CREATE TYPE %s (x int)" % udt_name) with self.VerifiedFunction(self, **self.make_function_kwargs()): # udts must come before functions in keyspace dump keyspace_cql = self.cluster.metadata.keyspaces[self.keyspace_name].export_as_string() type_idx = keyspace_cql.rfind("CREATE TYPE") func_idx = keyspace_cql.find("CREATE FUNCTION") self.assertNotIn(-1, (type_idx, func_idx), "TYPE or FUNCTION not found in keyspace_cql: " + keyspace_cql) self.assertGreater(func_idx, type_idx) def test_function_same_name_diff_types(self): """ Test to verify to that functions with different signatures are differentiated in metadata test_function_same_name_diff_types Creates two functions. One with the same name but a slightly different signature. Then ensures that both are surfaced separately in our metadata. @since 2.6.0 @jira_ticket PYTHON-211 @expected_result function with the same name but different signatures should be surfaced separately @test_category function """ # Create a function kwargs = self.make_function_kwargs() with self.VerifiedFunction(self, **kwargs): # another function: same name, different type sig. self.assertGreater(len(kwargs['argument_types']), 1) self.assertGreater(len(kwargs['argument_names']), 1) kwargs['argument_types'] = kwargs['argument_types'][:1] kwargs['argument_names'] = kwargs['argument_names'][:1] # Ensure they are surfaced separately with self.VerifiedFunction(self, **kwargs): functions = [f for f in self.keyspace_function_meta.values() if f.name == self.function_name] self.assertEqual(len(functions), 2) self.assertNotEqual(functions[0].argument_types, functions[1].argument_types) def test_function_no_parameters(self): """ Test to verify CQL output for functions with zero parameters Creates a function with no input parameters, verify that CQL output is correct. @since 2.7.1 @jira_ticket PYTHON-392 @expected_result function with no parameters should generate proper CQL @test_category function """ kwargs = self.make_function_kwargs() kwargs['argument_types'] = [] kwargs['argument_names'] = [] kwargs['return_type'] = 'bigint' kwargs['body'] = 'return System.currentTimeMillis() / 1000L;' with self.VerifiedFunction(self, **kwargs) as vf: fn_meta = self.keyspace_function_meta[vf.signature] self.assertRegexpMatches(fn_meta.as_cql_query(), "CREATE FUNCTION.*%s\(\) .*" % kwargs['name']) def test_functions_follow_keyspace_alter(self): """ Test to verify to that functions maintain equality after a keyspace is altered test_functions_follow_keyspace_alter creates a function then alters a the keyspace associated with that function. After the alter we validate that the function maintains the same metadata @since 2.6.0 @jira_ticket PYTHON-211 @expected_result functions are the same after parent keyspace is altered @test_category function """ # Create function with self.VerifiedFunction(self, **self.make_function_kwargs()): original_keyspace_meta = self.cluster.metadata.keyspaces[self.keyspace_name] self.session.execute('ALTER KEYSPACE %s WITH durable_writes = false' % self.keyspace_name) # After keyspace alter ensure that we maintain function equality. try: new_keyspace_meta = self.cluster.metadata.keyspaces[self.keyspace_name] self.assertNotEqual(original_keyspace_meta, new_keyspace_meta) self.assertIs(original_keyspace_meta.functions, new_keyspace_meta.functions) finally: self.session.execute('ALTER KEYSPACE %s WITH durable_writes = true' % self.keyspace_name) def test_function_cql_called_on_null(self): """ Test to verify to that that called on null argument is honored on function creation. test_functions_follow_keyspace_alter create two functions. One with the called_on_null_input set to true, the other with it set to false. We then verify that the metadata constructed from those function is correctly reflected @since 2.6.0 @jira_ticket PYTHON-211 @expected_result functions metadata correctly reflects called_on_null_input flag. @test_category function """ kwargs = self.make_function_kwargs() kwargs['called_on_null_input'] = True with self.VerifiedFunction(self, **kwargs) as vf: fn_meta = self.keyspace_function_meta[vf.signature] self.assertRegexpMatches(fn_meta.as_cql_query(), "CREATE FUNCTION.*\) CALLED ON NULL INPUT RETURNS .*") kwargs['called_on_null_input'] = False with self.VerifiedFunction(self, **kwargs) as vf: fn_meta = self.keyspace_function_meta[vf.signature] self.assertRegexpMatches(fn_meta.as_cql_query(), "CREATE FUNCTION.*\) RETURNS NULL ON NULL INPUT RETURNS .*") class AggregateMetadata(FunctionTest): @classmethod def setup_class(cls): if PROTOCOL_VERSION >= 4: super(AggregateMetadata, cls).setup_class() cls.session.execute("""CREATE OR REPLACE FUNCTION sum_int(s int, i int) RETURNS NULL ON NULL INPUT RETURNS int LANGUAGE javascript AS 's + i';""") cls.session.execute("""CREATE OR REPLACE FUNCTION sum_int_two(s int, i int, j int) RETURNS NULL ON NULL INPUT RETURNS int LANGUAGE javascript AS 's + i + j';""") cls.session.execute("""CREATE OR REPLACE FUNCTION "List_As_String"(l list) RETURNS NULL ON NULL INPUT RETURNS int LANGUAGE javascript AS ''''' + l';""") cls.session.execute("""CREATE OR REPLACE FUNCTION extend_list(s list, i int) CALLED ON NULL INPUT RETURNS list LANGUAGE java AS 'if (i != null) s.add(i.toString()); return s;';""") cls.session.execute("""CREATE OR REPLACE FUNCTION update_map(s map, i int) RETURNS NULL ON NULL INPUT RETURNS map LANGUAGE java AS 's.put(new Integer(i), new Integer(i)); return s;';""") cls.session.execute("""CREATE TABLE IF NOT EXISTS t (k int PRIMARY KEY, v int)""") for x in range(4): cls.session.execute("INSERT INTO t (k,v) VALUES (%s, %s)", (x, x)) cls.session.execute("INSERT INTO t (k) VALUES (%s)", (4,)) def make_aggregate_kwargs(self, state_func, state_type, final_func=None, init_cond=None): return {'keyspace': self.keyspace_name, 'name': self.function_name + '_aggregate', 'argument_types': ['int'], 'state_func': state_func, 'state_type': state_type, 'final_func': final_func, 'initial_condition': init_cond, 'return_type': "does not matter for creation"} def test_return_type_meta(self): """ Test to verify to that the return type of a an aggregate is honored in the metadata test_return_type_meta creates an aggregate then ensures the return type of the created aggregate is correctly surfaced in the metadata @since 2.6.0 @jira_ticket PYTHON-211 @expected_result aggregate has the correct return typ in the metadata @test_category aggregate """ with self.VerifiedAggregate(self, **self.make_aggregate_kwargs('sum_int', 'int', init_cond='1')) as va: self.assertEqual(self.keyspace_aggregate_meta[va.signature].return_type, 'int') def test_init_cond(self): """ Test to verify that various initial conditions are correctly surfaced in various aggregate functions test_init_cond creates several different types of aggregates, and given various initial conditions it verifies that they correctly impact the aggregate's execution @since 2.6.0 @jira_ticket PYTHON-211 @expected_result initial conditions are correctly evaluated as part of the aggregates @test_category aggregate """ # This is required until the java driver bundled with C* is updated to support v4 c = Cluster(protocol_version=3) s = c.connect(self.keyspace_name) encoder = Encoder() expected_values = range(4) # int32 for init_cond in (-1, 0, 1): cql_init = encoder.cql_encode_all_types(init_cond) with self.VerifiedAggregate(self, **self.make_aggregate_kwargs('sum_int', 'int', init_cond=cql_init)) as va: sum_res = s.execute("SELECT %s(v) AS sum FROM t" % va.function_kwargs['name'])[0].sum self.assertEqual(sum_res, int(init_cond) + sum(expected_values)) # list for init_cond in ([], ['1', '2']): cql_init = encoder.cql_encode_all_types(init_cond) with self.VerifiedAggregate(self, **self.make_aggregate_kwargs('extend_list', 'list', init_cond=cql_init)) as va: list_res = s.execute("SELECT %s(v) AS list_res FROM t" % va.function_kwargs['name'])[0].list_res self.assertListEqual(list_res[:len(init_cond)], init_cond) self.assertEqual(set(i for i in list_res[len(init_cond):]), set(str(i) for i in expected_values)) # map expected_map_values = dict((i, i) for i in expected_values) expected_key_set = set(expected_values) for init_cond in ({}, {1: 2, 3: 4}, {5: 5}): cql_init = encoder.cql_encode_all_types(init_cond) with self.VerifiedAggregate(self, **self.make_aggregate_kwargs('update_map', 'map', init_cond=cql_init)) as va: map_res = s.execute("SELECT %s(v) AS map_res FROM t" % va.function_kwargs['name'])[0].map_res self.assertDictContainsSubset(expected_map_values, map_res) init_not_updated = dict((k, init_cond[k]) for k in set(init_cond) - expected_key_set) self.assertDictContainsSubset(init_not_updated, map_res) c.shutdown() def test_aggregates_after_functions(self): """ Test to verify that aggregates are listed after function in metadata test_aggregates_after_functions creates an aggregate, and then verifies that they are listed after any function creations when the keypspace dump is preformed @since 2.6.0 @jira_ticket PYTHON-211 @expected_result aggregates are declared after any functions @test_category aggregate """ # functions must come before functions in keyspace dump with self.VerifiedAggregate(self, **self.make_aggregate_kwargs('extend_list', 'list')): keyspace_cql = self.cluster.metadata.keyspaces[self.keyspace_name].export_as_string() func_idx = keyspace_cql.find("CREATE FUNCTION") aggregate_idx = keyspace_cql.rfind("CREATE AGGREGATE") self.assertNotIn(-1, (aggregate_idx, func_idx), "AGGREGATE or FUNCTION not found in keyspace_cql: " + keyspace_cql) self.assertGreater(aggregate_idx, func_idx) def test_same_name_diff_types(self): """ Test to verify to that aggregates with different signatures are differentiated in metadata test_same_name_diff_types Creates two Aggregates. One with the same name but a slightly different signature. Then ensures that both are surfaced separately in our metadata. @since 2.6.0 @jira_ticket PYTHON-211 @expected_result aggregates with the same name but different signatures should be surfaced separately @test_category function """ kwargs = self.make_aggregate_kwargs('sum_int', 'int', init_cond='0') with self.VerifiedAggregate(self, **kwargs): kwargs['state_func'] = 'sum_int_two' kwargs['argument_types'] = ['int', 'int'] with self.VerifiedAggregate(self, **kwargs): aggregates = [a for a in self.keyspace_aggregate_meta.values() if a.name == kwargs['name']] self.assertEqual(len(aggregates), 2) self.assertNotEqual(aggregates[0].argument_types, aggregates[1].argument_types) def test_aggregates_follow_keyspace_alter(self): """ Test to verify to that aggregates maintain equality after a keyspace is altered test_aggregates_follow_keyspace_alter creates a function then alters a the keyspace associated with that function. After the alter we validate that the function maintains the same metadata @since 2.6.0 @jira_ticket PYTHON-211 @expected_result aggregates are the same after parent keyspace is altered @test_category function """ with self.VerifiedAggregate(self, **self.make_aggregate_kwargs('sum_int', 'int', init_cond='0')): original_keyspace_meta = self.cluster.metadata.keyspaces[self.keyspace_name] self.session.execute('ALTER KEYSPACE %s WITH durable_writes = false' % self.keyspace_name) try: new_keyspace_meta = self.cluster.metadata.keyspaces[self.keyspace_name] self.assertNotEqual(original_keyspace_meta, new_keyspace_meta) self.assertIs(original_keyspace_meta.aggregates, new_keyspace_meta.aggregates) finally: self.session.execute('ALTER KEYSPACE %s WITH durable_writes = true' % self.keyspace_name) def test_cql_optional_params(self): """ Test to verify that the initial_cond and final_func parameters are correctly honored test_cql_optional_params creates various aggregates with different combinations of initial_condition, and final_func parameters set. It then ensures they are correctly honored. @since 2.6.0 @jira_ticket PYTHON-211 @expected_result initial_condition and final_func parameters are honored correctly @test_category function """ kwargs = self.make_aggregate_kwargs('extend_list', 'list') encoder = Encoder() # no initial condition, final func self.assertIsNone(kwargs['initial_condition']) self.assertIsNone(kwargs['final_func']) with self.VerifiedAggregate(self, **kwargs) as va: meta = self.keyspace_aggregate_meta[va.signature] self.assertIsNone(meta.initial_condition) self.assertIsNone(meta.final_func) cql = meta.as_cql_query() self.assertEqual(cql.find('INITCOND'), -1) self.assertEqual(cql.find('FINALFUNC'), -1) # initial condition, no final func kwargs['initial_condition'] = encoder.cql_encode_all_types(['init', 'cond']) with self.VerifiedAggregate(self, **kwargs) as va: meta = self.keyspace_aggregate_meta[va.signature] self.assertEqual(meta.initial_condition, kwargs['initial_condition']) self.assertIsNone(meta.final_func) cql = meta.as_cql_query() search_string = "INITCOND %s" % kwargs['initial_condition'] self.assertGreater(cql.find(search_string), 0, '"%s" search string not found in cql:\n%s' % (search_string, cql)) self.assertEqual(cql.find('FINALFUNC'), -1) # no initial condition, final func kwargs['initial_condition'] = None kwargs['final_func'] = 'List_As_String' with self.VerifiedAggregate(self, **kwargs) as va: meta = self.keyspace_aggregate_meta[va.signature] self.assertIsNone(meta.initial_condition) self.assertEqual(meta.final_func, kwargs['final_func']) cql = meta.as_cql_query() self.assertEqual(cql.find('INITCOND'), -1) search_string = 'FINALFUNC "%s"' % kwargs['final_func'] self.assertGreater(cql.find(search_string), 0, '"%s" search string not found in cql:\n%s' % (search_string, cql)) # both kwargs['initial_condition'] = encoder.cql_encode_all_types(['init', 'cond']) kwargs['final_func'] = 'List_As_String' with self.VerifiedAggregate(self, **kwargs) as va: meta = self.keyspace_aggregate_meta[va.signature] self.assertEqual(meta.initial_condition, kwargs['initial_condition']) self.assertEqual(meta.final_func, kwargs['final_func']) cql = meta.as_cql_query() init_cond_idx = cql.find("INITCOND %s" % kwargs['initial_condition']) final_func_idx = cql.find('FINALFUNC "%s"' % kwargs['final_func']) self.assertNotIn(-1, (init_cond_idx, final_func_idx)) self.assertGreater(init_cond_idx, final_func_idx) class BadMetaTest(unittest.TestCase): """ Test behavior when metadata has unexpected form Verify that new cluster/session can still connect, and the CQL output indicates the exception with a warning. PYTHON-370 """ class BadMetaException(Exception): pass @property def function_name(self): return self._testMethodName.lower() @classmethod def setup_class(cls): cls.cluster = Cluster(protocol_version=PROTOCOL_VERSION) cls.keyspace_name = cls.__name__.lower() cls.session = cls.cluster.connect() cls.session.execute("CREATE KEYSPACE %s WITH replication = {'class': 'SimpleStrategy', 'replication_factor': 1}" % cls.keyspace_name) cls.session.set_keyspace(cls.keyspace_name) connection = cls.cluster.control_connection._connection cls.parser_class = get_schema_parser(connection, str(CASS_SERVER_VERSION[0]), timeout=20).__class__ @classmethod def teardown_class(cls): drop_keyspace_shutdown_cluster(cls.keyspace_name, cls.session, cls.cluster) def _skip_if_not_version(self, version): if CASS_SERVER_VERSION < version: raise unittest.SkipTest("Requires server version >= %s" % (version,)) def test_bad_keyspace(self): with patch.object(self.parser_class, '_build_keyspace_metadata_internal', side_effect=self.BadMetaException): self.cluster.refresh_keyspace_metadata(self.keyspace_name) m = self.cluster.metadata.keyspaces[self.keyspace_name] self.assertIs(m._exc_info[0], self.BadMetaException) self.assertIn("/*\nWarning:", m.export_as_string()) def test_bad_table(self): self.session.execute('CREATE TABLE %s (k int PRIMARY KEY, v int)' % self.function_name) with patch.object(self.parser_class, '_build_column_metadata', side_effect=self.BadMetaException): self.cluster.refresh_table_metadata(self.keyspace_name, self.function_name) m = self.cluster.metadata.keyspaces[self.keyspace_name].tables[self.function_name] self.assertIs(m._exc_info[0], self.BadMetaException) self.assertIn("/*\nWarning:", m.export_as_string()) def test_bad_index(self): self.session.execute('CREATE TABLE %s (k int PRIMARY KEY, v int)' % self.function_name) self.session.execute('CREATE INDEX ON %s(v)' % self.function_name) with patch.object(self.parser_class, '_build_index_metadata', side_effect=self.BadMetaException): self.cluster.refresh_table_metadata(self.keyspace_name, self.function_name) m = self.cluster.metadata.keyspaces[self.keyspace_name].tables[self.function_name] self.assertIs(m._exc_info[0], self.BadMetaException) self.assertIn("/*\nWarning:", m.export_as_string()) def test_bad_user_type(self): self._skip_if_not_version((2, 1, 0)) self.session.execute('CREATE TYPE %s (i int, d double)' % self.function_name) with patch.object(self.parser_class, '_build_user_type', side_effect=self.BadMetaException): self.cluster.refresh_schema_metadata() # presently do not capture these errors on udt direct refresh -- make sure it's contained during full refresh m = self.cluster.metadata.keyspaces[self.keyspace_name] self.assertIs(m._exc_info[0], self.BadMetaException) self.assertIn("/*\nWarning:", m.export_as_string()) def test_bad_user_function(self): self._skip_if_not_version((2, 2, 0)) self.session.execute("""CREATE FUNCTION IF NOT EXISTS %s (key int, val int) RETURNS NULL ON NULL INPUT RETURNS int LANGUAGE javascript AS 'key + val';""" % self.function_name) with patch.object(self.parser_class, '_build_function', side_effect=self.BadMetaException): self.cluster.refresh_schema_metadata() # presently do not capture these errors on udt direct refresh -- make sure it's contained during full refresh m = self.cluster.metadata.keyspaces[self.keyspace_name] self.assertIs(m._exc_info[0], self.BadMetaException) self.assertIn("/*\nWarning:", m.export_as_string()) def test_bad_user_aggregate(self): self._skip_if_not_version((2, 2, 0)) self.session.execute("""CREATE FUNCTION IF NOT EXISTS sum_int (key int, val int) RETURNS NULL ON NULL INPUT RETURNS int LANGUAGE javascript AS 'key + val';""") self.session.execute("""CREATE AGGREGATE %s(int) SFUNC sum_int STYPE int INITCOND 0""" % self.function_name) with patch.object(self.parser_class, '_build_aggregate', side_effect=self.BadMetaException): self.cluster.refresh_schema_metadata() # presently do not capture these errors on udt direct refresh -- make sure it's contained during full refresh m = self.cluster.metadata.keyspaces[self.keyspace_name] self.assertIs(m._exc_info[0], self.BadMetaException) self.assertIn("/*\nWarning:", m.export_as_string()) class DynamicCompositeTypeTest(BasicSharedKeyspaceUnitTestCase): def test_dct_alias(self): """ Tests to make sure DCT's have correct string formatting Constructs a DCT and check the format as generated. To insure it matches what is expected @since 3.6.0 @jira_ticket PYTHON-579 @expected_result DCT subtypes should always have fully qualified names @test_category metadata """ self.session.execute("CREATE TABLE {0}.{1} (" "k int PRIMARY KEY," "c1 'DynamicCompositeType(s => UTF8Type, i => Int32Type)'," "c2 Text)".format(self.ks_name, self.function_table_name)) dct_table = self.cluster.metadata.keyspaces.get(self.ks_name).tables.get(self.function_table_name) # Format can very slightly between versions, strip out whitespace for consistency sake self.assertTrue("c1'org.apache.cassandra.db.marshal.DynamicCompositeType(s=>org.apache.cassandra.db.marshal.UTF8Type,i=>org.apache.cassandra.db.marshal.Int32Type)'" in dct_table.as_cql_query().replace(" ", "")) class Materia3lizedViewMetadataTestSimple(BasicSharedKeyspaceUnitTestCase): def setUp(self): if CASS_SERVER_VERSION < (3, 0): raise unittest.SkipTest("Materialized views require Cassandra 3.0+") self.session.execute("CREATE TABLE {0}.{1} (pk int PRIMARY KEY, c int)".format(self.keyspace_name, self.function_table_name)) self.session.execute("CREATE MATERIALIZED VIEW {0}.mv1 AS SELECT c FROM {0}.{1} WHERE c IS NOT NULL PRIMARY KEY (pk, c)".format(self.keyspace_name, self.function_table_name)) def tearDown(self): self.session.execute("DROP MATERIALIZED VIEW {0}.mv1".format(self.keyspace_name)) self.session.execute("DROP TABLE {0}.{1}".format(self.keyspace_name, self.function_table_name)) def test_materialized_view_metadata_creation(self): """ test for materialized view metadata creation test_materialized_view_metadata_creation tests that materialized view metadata properly created implicitly in both keyspace and table metadata under "views". It creates a simple base table and then creates a view based on that table. It then checks that the materialized view metadata is contained in the keyspace and table metadata. Finally, it checks that the keyspace_name and the base_table_name in the view metadata is properly set. @since 3.0.0 @jira_ticket PYTHON-371 @expected_result Materialized view metadata in both the ks and table should be created with a new view is created. @test_category metadata """ self.assertIn("mv1", self.cluster.metadata.keyspaces[self.keyspace_name].views) self.assertIn("mv1", self.cluster.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].views) self.assertEqual(self.keyspace_name, self.cluster.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].views["mv1"].keyspace_name) self.assertEqual(self.function_table_name, self.cluster.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].views["mv1"].base_table_name) def test_materialized_view_metadata_alter(self): """ test for materialized view metadata alteration test_materialized_view_metadata_alter tests that materialized view metadata is properly updated implicitly in the table metadata once that view is updated. It creates a simple base table and then creates a view based on that table. It then alters that materalized view and checks that the materialized view metadata is altered in the table metadata. @since 3.0.0 @jira_ticket PYTHON-371 @expected_result Materialized view metadata should be updated with the view is altered. @test_category metadata """ self.assertIn("SizeTieredCompactionStrategy", self.cluster.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].views["mv1"].options["compaction"]["class"] ) self.session.execute("ALTER MATERIALIZED VIEW {0}.mv1 WITH compaction = {{ 'class' : 'LeveledCompactionStrategy' }}".format(self.keyspace_name)) self.assertIn("LeveledCompactionStrategy", self.cluster.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].views["mv1"].options["compaction"]["class"]) def test_materialized_view_metadata_drop(self): """ test for materialized view metadata dropping test_materialized_view_metadata_drop tests that materialized view metadata is properly removed implicitly in both keyspace and table metadata once that view is dropped. It creates a simple base table and then creates a view based on that table. It then drops that materalized view and checks that the materialized view metadata is removed from the keyspace and table metadata. @since 3.0.0 @jira_ticket PYTHON-371 @expected_result Materialized view metadata in both the ks and table should be removed with the view is dropped. @test_category metadata """ self.session.execute("DROP MATERIALIZED VIEW {0}.mv1".format(self.keyspace_name)) self.assertNotIn("mv1", self.cluster.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].views) self.assertNotIn("mv1", self.cluster.metadata.keyspaces[self.keyspace_name].views) self.assertDictEqual({}, self.cluster.metadata.keyspaces[self.keyspace_name].tables[self.function_table_name].views) self.assertDictEqual({}, self.cluster.metadata.keyspaces[self.keyspace_name].views) self.session.execute("CREATE MATERIALIZED VIEW {0}.mv1 AS SELECT c FROM {0}.{1} WHERE c IS NOT NULL PRIMARY KEY (pk, c)".format(self.keyspace_name, self.function_table_name)) class MaterializedViewMetadataTestComplex(BasicSegregatedKeyspaceUnitTestCase): def setUp(self): if CASS_SERVER_VERSION < (3, 0): raise unittest.SkipTest("Materialized views require Cassandra 3.0+") super(MaterializedViewMetadataTestComplex, self).setUp() def test_create_view_metadata(self): """ test to ensure that materialized view metadata is properly constructed test_create_view_metadata tests that materialized views metadata is properly constructed. It runs a simple query to construct a materialized view, then proceeds to inspect the metadata associated with that MV. Columns are inspected to insure that all are of the proper type, and in the proper type. @since 3.0.0 @jira_ticket PYTHON-371 @expected_result Materialized view metadata should be constructed appropriately. @test_category metadata """ create_table = """CREATE TABLE {0}.scores( user TEXT, game TEXT, year INT, month INT, day INT, score INT, PRIMARY KEY (user, game, year, month, day) )""".format(self.keyspace_name) self.session.execute(create_table) create_mv = """CREATE MATERIALIZED VIEW {0}.monthlyhigh AS SELECT game, year, month, score, user, day FROM {0}.scores WHERE game IS NOT NULL AND year IS NOT NULL AND month IS NOT NULL AND score IS NOT NULL AND user IS NOT NULL AND day IS NOT NULL PRIMARY KEY ((game, year, month), score, user, day) WITH CLUSTERING ORDER BY (score DESC, user ASC, day ASC)""".format(self.keyspace_name) self.session.execute(create_mv) score_table = self.cluster.metadata.keyspaces[self.keyspace_name].tables['scores'] mv = self.cluster.metadata.keyspaces[self.keyspace_name].views['monthlyhigh'] self.assertIsNotNone(score_table.views["monthlyhigh"]) self.assertIsNotNone(len(score_table.views), 1) # Make sure user is a partition key, and not null self.assertEqual(len(score_table.partition_key), 1) self.assertIsNotNone(score_table.columns['user']) self.assertTrue(score_table.columns['user'], score_table.partition_key[0]) # Validate clustering keys self.assertEqual(len(score_table.clustering_key), 4) self.assertIsNotNone(score_table.columns['game']) self.assertTrue(score_table.columns['game'], score_table.clustering_key[0]) self.assertIsNotNone(score_table.columns['year']) self.assertTrue(score_table.columns['year'], score_table.clustering_key[1]) self.assertIsNotNone(score_table.columns['month']) self.assertTrue(score_table.columns['month'], score_table.clustering_key[2]) self.assertIsNotNone(score_table.columns['day']) self.assertTrue(score_table.columns['day'], score_table.clustering_key[3]) self.assertIsNotNone(score_table.columns['score']) # Validate basic mv information self.assertEqual(mv.keyspace_name, self.keyspace_name) self.assertEqual(mv.name, "monthlyhigh") self.assertEqual(mv.base_table_name, "scores") self.assertFalse(mv.include_all_columns) # Validate that all columns are preset and correct mv_columns = list(mv.columns.values()) self.assertEqual(len(mv_columns), 6) game_column = mv_columns[0] self.assertIsNotNone(game_column) self.assertEqual(game_column.name, 'game') self.assertEqual(game_column, mv.partition_key[0]) year_column = mv_columns[1] self.assertIsNotNone(year_column) self.assertEqual(year_column.name, 'year') self.assertEqual(year_column, mv.partition_key[1]) month_column = mv_columns[2] self.assertIsNotNone(month_column) self.assertEqual(month_column.name, 'month') self.assertEqual(month_column, mv.partition_key[2]) def compare_columns(a, b, name): self.assertEqual(a.name, name) self.assertEqual(a.name, b.name) self.assertEqual(a.table, b.table) self.assertEqual(a.cql_type, b.cql_type) self.assertEqual(a.is_static, b.is_static) self.assertEqual(a.is_reversed, b.is_reversed) score_column = mv_columns[3] compare_columns(score_column, mv.clustering_key[0], 'score') user_column = mv_columns[4] compare_columns(user_column, mv.clustering_key[1], 'user') day_column = mv_columns[5] compare_columns(day_column, mv.clustering_key[2], 'day') def test_base_table_column_addition_mv(self): """ test to ensure that materialized view metadata is properly updated with base columns are added test_create_view_metadata tests that materialized views metadata is properly updated when columns are added to the base table. @since 3.0.0 @jira_ticket PYTHON-419 @expected_result Materialized view metadata should be updated correctly @test_category metadata """ create_table = """CREATE TABLE {0}.scores( user TEXT, game TEXT, year INT, month INT, day INT, score TEXT, PRIMARY KEY (user, game, year, month, day) )""".format(self.keyspace_name) self.session.execute(create_table) create_mv = """CREATE MATERIALIZED VIEW {0}.monthlyhigh AS SELECT game, year, month, score, user, day FROM {0}.scores WHERE game IS NOT NULL AND year IS NOT NULL AND month IS NOT NULL AND score IS NOT NULL AND user IS NOT NULL AND day IS NOT NULL PRIMARY KEY ((game, year, month), score, user, day) WITH CLUSTERING ORDER BY (score DESC, user ASC, day ASC)""".format(self.keyspace_name) create_mv_alltime = """CREATE MATERIALIZED VIEW {0}.alltimehigh AS SELECT * FROM {0}.scores WHERE game IS NOT NULL AND score IS NOT NULL AND user IS NOT NULL AND year IS NOT NULL AND month IS NOT NULL AND day IS NOT NULL PRIMARY KEY (game, score, user, year, month, day) WITH CLUSTERING ORDER BY (score DESC)""".format(self.keyspace_name) self.session.execute(create_mv) self.session.execute(create_mv_alltime) score_table = self.cluster.metadata.keyspaces[self.keyspace_name].tables['scores'] self.assertIsNotNone(score_table.views["monthlyhigh"]) self.assertIsNotNone(score_table.views["alltimehigh"]) self.assertEqual(len(self.cluster.metadata.keyspaces[self.keyspace_name].views), 2) insert_fouls = """ALTER TABLE {0}.scores ADD fouls INT""".format((self.keyspace_name)) self.session.execute(insert_fouls) self.assertEqual(len(self.cluster.metadata.keyspaces[self.keyspace_name].views), 2) score_table = self.cluster.metadata.keyspaces[self.keyspace_name].tables['scores'] self.assertIn("fouls", score_table.columns) # This is a workaround for mv notifications being separate from base table schema responses. # This maybe fixed with future protocol changes for i in range(10): mv_alltime = self.cluster.metadata.keyspaces[self.keyspace_name].views["alltimehigh"] if("fouls" in mv_alltime.columns): break time.sleep(.2) self.assertIn("fouls", mv_alltime.columns) mv_alltime_fouls_comumn = self.cluster.metadata.keyspaces[self.keyspace_name].views["alltimehigh"].columns['fouls'] self.assertEqual(mv_alltime_fouls_comumn.cql_type, 'int') def test_base_table_type_alter_mv(self): """ test to ensure that materialized view metadata is properly updated when a type in the base table is updated. test_create_view_metadata tests that materialized views metadata is properly updated when the type of base table column is changed. @since 3.0.0 @jira_ticket CASSANDRA-10424 @expected_result Materialized view metadata should be updated correctly @test_category metadata """ create_table = """CREATE TABLE {0}.scores( user TEXT, game TEXT, year INT, month INT, day INT, score TEXT, PRIMARY KEY (user, game, year, month, day) )""".format(self.keyspace_name) self.session.execute(create_table) create_mv = """CREATE MATERIALIZED VIEW {0}.monthlyhigh AS SELECT game, year, month, score, user, day FROM {0}.scores WHERE game IS NOT NULL AND year IS NOT NULL AND month IS NOT NULL AND score IS NOT NULL AND user IS NOT NULL AND day IS NOT NULL PRIMARY KEY ((game, year, month), score, user, day) WITH CLUSTERING ORDER BY (score DESC, user ASC, day ASC)""".format(self.keyspace_name) self.session.execute(create_mv) self.assertEqual(len(self.cluster.metadata.keyspaces[self.keyspace_name].views), 1) alter_scores = """ALTER TABLE {0}.scores ALTER score TYPE blob""".format((self.keyspace_name)) self.session.execute(alter_scores) self.assertEqual(len(self.cluster.metadata.keyspaces[self.keyspace_name].views), 1) score_column = self.cluster.metadata.keyspaces[self.keyspace_name].tables['scores'].columns['score'] self.assertEqual(score_column.cql_type, 'blob') # until CASSANDRA-9920+CASSANDRA-10500 MV updates are only available later with an async event for i in range(10): score_mv_column = self.cluster.metadata.keyspaces[self.keyspace_name].views["monthlyhigh"].columns['score'] if "blob" == score_mv_column.cql_type: break time.sleep(.2) self.assertEqual(score_mv_column.cql_type, 'blob') def test_metadata_with_quoted_identifiers(self): """ test to ensure that materialized view metadata is properly constructed when quoted identifiers are used test_metadata_with_quoted_identifiers tests that materialized views metadata is properly constructed. It runs a simple query to construct a materialized view, then proceeds to inspect the metadata associated with that MV. The caveat here is that the tables and the materialized view both have quoted identifiers Columns are inspected to insure that all are of the proper type, and in the proper type. @since 3.0.0 @jira_ticket PYTHON-371 @expected_result Materialized view metadata should be constructed appropriately even with quoted identifiers. @test_category metadata """ create_table = """CREATE TABLE {0}.t1 ( "theKey" int, "the;Clustering" int, "the Value" int, PRIMARY KEY ("theKey", "the;Clustering"))""".format(self.keyspace_name) self.session.execute(create_table) create_mv = """CREATE MATERIALIZED VIEW {0}.mv1 AS SELECT "theKey", "the;Clustering", "the Value" FROM {0}.t1 WHERE "theKey" IS NOT NULL AND "the;Clustering" IS NOT NULL AND "the Value" IS NOT NULL PRIMARY KEY ("theKey", "the;Clustering")""".format(self.keyspace_name) self.session.execute(create_mv) t1_table = self.cluster.metadata.keyspaces[self.keyspace_name].tables['t1'] mv = self.cluster.metadata.keyspaces[self.keyspace_name].views['mv1'] self.assertIsNotNone(t1_table.views["mv1"]) self.assertIsNotNone(len(t1_table.views), 1) # Validate partition key, and not null self.assertEqual(len(t1_table.partition_key), 1) self.assertIsNotNone(t1_table.columns['theKey']) self.assertTrue(t1_table.columns['theKey'], t1_table.partition_key[0]) # Validate clustering key column self.assertEqual(len(t1_table.clustering_key), 1) self.assertIsNotNone(t1_table.columns['the;Clustering']) self.assertTrue(t1_table.columns['the;Clustering'], t1_table.clustering_key[0]) # Validate regular column self.assertIsNotNone(t1_table.columns['the Value']) # Validate basic mv information self.assertEqual(mv.keyspace_name, self.keyspace_name) self.assertEqual(mv.name, "mv1") self.assertEqual(mv.base_table_name, "t1") self.assertFalse(mv.include_all_columns) # Validate that all columns are preset and correct mv_columns = list(mv.columns.values()) self.assertEqual(len(mv_columns), 3) theKey_column = mv_columns[0] self.assertIsNotNone(theKey_column) self.assertEqual(theKey_column.name, 'theKey') self.assertEqual(theKey_column, mv.partition_key[0]) cluster_column = mv_columns[1] self.assertIsNotNone(cluster_column) self.assertEqual(cluster_column.name, 'the;Clustering') self.assertEqual(cluster_column.name, mv.clustering_key[0].name) self.assertEqual(cluster_column.table, mv.clustering_key[0].table) self.assertEqual(cluster_column.is_static, mv.clustering_key[0].is_static) self.assertEqual(cluster_column.is_reversed, mv.clustering_key[0].is_reversed) value_column = mv_columns[2] self.assertIsNotNone(value_column) self.assertEqual(value_column.name, 'the Value') @dseonly class DSEMetadataTest(BasicExistingSegregatedKeyspaceUnitTestCase): def test_dse_specific_meta(self): """ Test to ensure DSE metadata is populated appropriately. @since 3.4 @jira_ticket PYTHON-555 @expected_result metadata for dse_version, and dse_workload should be populated on dse clusters @test_category metadata """ for host in self.cluster.metadata.all_hosts(): self.assertIsNotNone(host.dse_version, "Dse version not populated as expected") self.assertEqual(host.dse_version, DSE_VERSION) self.assertTrue("Cassandra" in host.dse_workload)