class ConnectDistributedTest(Test):
"""
Simple test of Kafka Connect in distributed mode, producing data from files on one cluster and consuming it on
another, validating the total output is identical to the input.
"""
FILE_SOURCE_CONNECTOR = 'org.apache.kafka.connect.file.FileStreamSourceConnector'
FILE_SINK_CONNECTOR = 'org.apache.kafka.connect.file.FileStreamSinkConnector'
INPUT_FILE = "/mnt/connect.input"
OUTPUT_FILE = "/mnt/connect.output"
TOPIC = "test"
OFFSETS_TOPIC = "connect-offsets"
CONFIG_TOPIC = "connect-configs"
STATUS_TOPIC = "connect-status"
# Since tasks can be assigned to any node and we're testing with files, we need to make sure the content is the same
# across all nodes.
FIRST_INPUT_LIST = ["foo", "bar", "baz"]
FIRST_INPUTS = "\n".join(FIRST_INPUT_LIST) + "\n"
SECOND_INPUT_LIST = ["razz", "ma", "tazz"]
SECOND_INPUTS = "\n".join(SECOND_INPUT_LIST) + "\n"
SCHEMA = { "type": "string", "optional": False }
def __init__(self, test_context):
super(ConnectDistributedTest, self).__init__(test_context)
self.num_zk = 1
self.num_brokers = 1
self.topics = {
'test' : { 'partitions': 1, 'replication-factor': 1 }
}
self.zk = ZookeeperService(test_context, self.num_zk)
self.key_converter = "org.apache.kafka.connect.json.JsonConverter"
self.value_converter = "org.apache.kafka.connect.json.JsonConverter"
self.schemas = True
def setup_services(self, security_protocol=SecurityConfig.PLAINTEXT):
self.kafka = KafkaService(self.test_context, self.num_brokers, self.zk,
security_protocol=security_protocol, interbroker_security_protocol=security_protocol,
topics=self.topics)
self.cc = ConnectDistributedService(self.test_context, 3, self.kafka, [self.INPUT_FILE, self.OUTPUT_FILE])
self.cc.log_level = "DEBUG"
self.zk.start()
self.kafka.start()
def _start_connector(self, config_file):
connector_props = self.render(config_file)
connector_config = dict([line.strip().split('=', 1) for line in connector_props.split('\n') if line.strip() and not line.strip().startswith('#')])
self.cc.create_connector(connector_config)
def _connector_status(self, connector, node=None):
try:
return self.cc.get_connector_status(connector, node)
except ConnectRestError:
return None
def _connector_has_state(self, status, state):
return status is not None and status['connector']['state'] == state
def _task_has_state(self, task_id, status, state):
if not status:
return False
tasks = status['tasks']
if not tasks:
return False
for task in tasks:
if task['id'] == task_id:
return task['state'] == state
return False
def _all_tasks_have_state(self, status, task_count, state):
if status is None:
return False
tasks = status['tasks']
if len(tasks) != task_count:
return False
return reduce(operator.and_, [task['state'] == state for task in tasks], True)
def is_running(self, connector, node=None):
status = self._connector_status(connector.name, node)
return self._connector_has_state(status, 'RUNNING') and self._all_tasks_have_state(status, connector.tasks, 'RUNNING')
def is_paused(self, connector, node=None):
status = self._connector_status(connector.name, node)
return self._connector_has_state(status, 'PAUSED') and self._all_tasks_have_state(status, connector.tasks, 'PAUSED')
def connector_is_running(self, connector, node=None):
status = self._connector_status(connector.name, node)
return self._connector_has_state(status, 'RUNNING')
def connector_is_failed(self, connector, node=None):
status = self._connector_status(connector.name, node)
return self._connector_has_state(status, 'FAILED')
def task_is_failed(self, connector, task_id, node=None):
status = self._connector_status(connector.name, node)
return self._task_has_state(task_id, status, 'FAILED')
def task_is_running(self, connector, task_id, node=None):
status = self._connector_status(connector.name, node)
return self._task_has_state(task_id, status, 'RUNNING')
def test_restart_failed_connector(self):
self.setup_services()
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
self.sink = MockSink(self.cc, self.topics.keys(), mode='connector-failure', delay_sec=5)
self.sink.start()
wait_until(lambda: self.connector_is_failed(self.sink), timeout_sec=15,
err_msg="Failed to see connector transition to the FAILED state")
self.cc.restart_connector(self.sink.name)
wait_until(lambda: self.connector_is_running(self.sink), timeout_sec=10,
err_msg="Failed to see connector transition to the RUNNING state")
@matrix(delete_before_reconfig=[False, True])
def test_bad_connector_class(self, delete_before_reconfig):
"""
For the same connector name, first configure it with a bad connector class name such that it fails to start, verify that it enters a FAILED state.
Restart should also fail.
Then try to rectify by reconfiguring it as a MockConnector and verifying it successfully transitions to RUNNING.
"""
self.setup_services()
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
connector_name = 'bad-to-good-test'
connector = namedtuple('BadConnector', ['name', 'tasks'])(connector_name, 1)
config = {
'name': connector.name,
'tasks.max': connector.tasks,
'connector.class': 'java.util.HashMap'
}
self.cc.create_connector(config)
wait_until(lambda: self.connector_is_failed(connector), timeout_sec=10, err_msg="Failed to see connector transition to FAILED state")
try:
self.cc.restart_connector(connector_name)
except ConnectRestError:
pass
else:
raise AssertionError("Expected restart of %s to fail" % connector_name)
if delete_before_reconfig:
self.cc.delete_connector(connector_name)
config['connector.class'] = 'org.apache.kafka.connect.tools.MockSourceConnector'
self.cc.set_connector_config(connector_name, config)
wait_until(lambda: self.connector_is_running(connector), timeout_sec=10, err_msg="Failed to see connector transition to the RUNNING state")
@matrix(connector_type=["source", "sink"])
def test_restart_failed_task(self, connector_type):
self.setup_services()
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
connector = None
if connector_type == "sink":
connector = MockSink(self.cc, self.topics.keys(), mode='task-failure', delay_sec=5)
else:
connector = MockSource(self.cc, mode='task-failure', delay_sec=5)
connector.start()
task_id = 0
wait_until(lambda: self.task_is_failed(connector, task_id), timeout_sec=20,
err_msg="Failed to see task transition to the FAILED state")
self.cc.restart_task(connector.name, task_id)
wait_until(lambda: self.task_is_running(connector, task_id), timeout_sec=10,
err_msg="Failed to see task transition to the RUNNING state")
def test_pause_and_resume_source(self):
"""
Verify that source connectors stop producing records when paused and begin again after
being resumed.
"""
self.setup_services()
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
self.source = VerifiableSource(self.cc)
self.source.start()
wait_until(lambda: self.is_running(self.source), timeout_sec=30,
err_msg="Failed to see connector transition to the RUNNING state")
self.cc.pause_connector(self.source.name)
# wait until all nodes report the paused transition
for node in self.cc.nodes:
wait_until(lambda: self.is_paused(self.source, node), timeout_sec=30,
err_msg="Failed to see connector transition to the PAUSED state")
# verify that we do not produce new messages while paused
num_messages = len(self.source.sent_messages())
time.sleep(10)
assert num_messages == len(self.source.sent_messages()), "Paused source connector should not produce any messages"
self.cc.resume_connector(self.source.name)
for node in self.cc.nodes:
wait_until(lambda: self.is_running(self.source, node), timeout_sec=30,
err_msg="Failed to see connector transition to the RUNNING state")
# after resuming, we should see records produced again
wait_until(lambda: len(self.source.sent_messages()) > num_messages, timeout_sec=30,
err_msg="Failed to produce messages after resuming source connector")
def test_pause_and_resume_sink(self):
"""
Verify that sink connectors stop consuming records when paused and begin again after
being resumed.
"""
self.setup_services()
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
# use the verifiable source to produce a steady stream of messages
self.source = VerifiableSource(self.cc)
self.source.start()
wait_until(lambda: len(self.source.committed_messages()) > 0, timeout_sec=30,
err_msg="Timeout expired waiting for source task to produce a message")
self.sink = VerifiableSink(self.cc)
self.sink.start()
wait_until(lambda: self.is_running(self.sink), timeout_sec=30,
err_msg="Failed to see connector transition to the RUNNING state")
self.cc.pause_connector(self.sink.name)
# wait until all nodes report the paused transition
for node in self.cc.nodes:
wait_until(lambda: self.is_paused(self.sink, node), timeout_sec=30,
err_msg="Failed to see connector transition to the PAUSED state")
# verify that we do not consume new messages while paused
num_messages = len(self.sink.received_messages())
time.sleep(10)
assert num_messages == len(self.sink.received_messages()), "Paused sink connector should not consume any messages"
self.cc.resume_connector(self.sink.name)
for node in self.cc.nodes:
wait_until(lambda: self.is_running(self.sink, node), timeout_sec=30,
err_msg="Failed to see connector transition to the RUNNING state")
# after resuming, we should see records consumed again
wait_until(lambda: len(self.sink.received_messages()) > num_messages, timeout_sec=30,
err_msg="Failed to consume messages after resuming sink connector")
def test_pause_state_persistent(self):
"""
Verify that paused state is preserved after a cluster restart.
"""
self.setup_services()
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
self.source = VerifiableSource(self.cc)
self.source.start()
wait_until(lambda: self.is_running(self.source), timeout_sec=30,
err_msg="Failed to see connector transition to the RUNNING state")
self.cc.pause_connector(self.source.name)
self.cc.restart()
# we should still be paused after restarting
for node in self.cc.nodes:
wait_until(lambda: self.is_paused(self.source, node), timeout_sec=30,
err_msg="Failed to see connector startup in PAUSED state")
@matrix(security_protocol=[SecurityConfig.PLAINTEXT, SecurityConfig.SASL_SSL])
def test_file_source_and_sink(self, security_protocol):
"""
Tests that a basic file connector works across clean rolling bounces. This validates that the connector is
correctly created, tasks instantiated, and as nodes restart the work is rebalanced across nodes.
"""
self.setup_services(security_protocol=security_protocol)
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
self.logger.info("Creating connectors")
self._start_connector("connect-file-source.properties")
self._start_connector("connect-file-sink.properties")
# Generating data on the source node should generate new records and create new output on the sink node. Timeouts
# here need to be more generous than they are for standalone mode because a) it takes longer to write configs,
# do rebalancing of the group, etc, and b) without explicit leave group support, rebalancing takes awhile
for node in self.cc.nodes:
node.account.ssh("echo -e -n " + repr(self.FIRST_INPUTS) + " >> " + self.INPUT_FILE)
wait_until(lambda: self._validate_file_output(self.FIRST_INPUT_LIST), timeout_sec=70, err_msg="Data added to input file was not seen in the output file in a reasonable amount of time.")
# Restarting both should result in them picking up where they left off,
# only processing new data.
self.cc.restart()
for node in self.cc.nodes:
node.account.ssh("echo -e -n " + repr(self.SECOND_INPUTS) + " >> " + self.INPUT_FILE)
wait_until(lambda: self._validate_file_output(self.FIRST_INPUT_LIST + self.SECOND_INPUT_LIST), timeout_sec=70, err_msg="Sink output file never converged to the same state as the input file")
@matrix(clean=[True, False])
def test_bounce(self, clean):
"""
Validates that source and sink tasks that run continuously and produce a predictable sequence of messages
run correctly and deliver messages exactly once when Kafka Connect workers undergo clean rolling bounces.
"""
num_tasks = 3
self.setup_services()
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
self.source = VerifiableSource(self.cc, tasks=num_tasks, throughput=100)
self.source.start()
self.sink = VerifiableSink(self.cc, tasks=num_tasks)
self.sink.start()
for _ in range(3):
for node in self.cc.nodes:
started = time.time()
self.logger.info("%s bouncing Kafka Connect on %s", clean and "Clean" or "Hard", str(node.account))
self.cc.stop_node(node, clean_shutdown=clean)
with node.account.monitor_log(self.cc.LOG_FILE) as monitor:
self.cc.start_node(node)
monitor.wait_until("Starting connectors and tasks using config offset", timeout_sec=90,
err_msg="Kafka Connect worker didn't successfully join group and start work")
self.logger.info("Bounced Kafka Connect on %s and rejoined in %f seconds", node.account, time.time() - started)
# Give additional time for the consumer groups to recover. Even if it is not a hard bounce, there are
# some cases where a restart can cause a rebalance to take the full length of the session timeout
# (e.g. if the client shuts down before it has received the memberId from its initial JoinGroup).
# If we don't give enough time for the group to stabilize, the next bounce may cause consumers to
# be shut down before they have any time to process data and we can end up with zero data making it
# through the test.
time.sleep(15)
self.source.stop()
self.sink.stop()
self.cc.stop()
# Validate at least once delivery of everything that was reported as written since we should have flushed and
# cleanly exited. Currently this only tests at least once delivery because the sink task may not have consumed
# all the messages generated by the source task. This needs to be done per-task since seqnos are not unique across
# tasks.
success = True
errors = []
allow_dups = not clean
src_messages = self.source.committed_messages()
sink_messages = self.sink.flushed_messages()
for task in range(num_tasks):
# Validate source messages
src_seqnos = [msg['seqno'] for msg in src_messages if msg['task'] == task]
# Every seqno up to the largest one we ever saw should appear. Each seqno should only appear once because clean
# bouncing should commit on rebalance.
src_seqno_max = max(src_seqnos)
self.logger.debug("Max source seqno: %d", src_seqno_max)
src_seqno_counts = Counter(src_seqnos)
missing_src_seqnos = sorted(set(range(src_seqno_max)).difference(set(src_seqnos)))
duplicate_src_seqnos = sorted([seqno for seqno,count in src_seqno_counts.iteritems() if count > 1])
if missing_src_seqnos:
self.logger.error("Missing source sequence numbers for task " + str(task))
errors.append("Found missing source sequence numbers for task %d: %s" % (task, missing_src_seqnos))
success = False
if not allow_dups and duplicate_src_seqnos:
self.logger.error("Duplicate source sequence numbers for task " + str(task))
errors.append("Found duplicate source sequence numbers for task %d: %s" % (task, duplicate_src_seqnos))
success = False
# Validate sink messages
sink_seqnos = [msg['seqno'] for msg in sink_messages if msg['task'] == task]
# Every seqno up to the largest one we ever saw should appear. Each seqno should only appear once because
# clean bouncing should commit on rebalance.
sink_seqno_max = max(sink_seqnos)
self.logger.debug("Max sink seqno: %d", sink_seqno_max)
sink_seqno_counts = Counter(sink_seqnos)
missing_sink_seqnos = sorted(set(range(sink_seqno_max)).difference(set(sink_seqnos)))
duplicate_sink_seqnos = sorted([seqno for seqno,count in sink_seqno_counts.iteritems() if count > 1])
if missing_sink_seqnos:
self.logger.error("Missing sink sequence numbers for task " + str(task))
errors.append("Found missing sink sequence numbers for task %d: %s" % (task, missing_sink_seqnos))
success = False
if not allow_dups and duplicate_sink_seqnos:
self.logger.error("Duplicate sink sequence numbers for task " + str(task))
errors.append("Found duplicate sink sequence numbers for task %d: %s" % (task, duplicate_sink_seqnos))
success = False
# Validate source and sink match
if sink_seqno_max > src_seqno_max:
self.logger.error("Found sink sequence number greater than any generated sink sequence number for task %d: %d > %d", task, sink_seqno_max, src_seqno_max)
errors.append("Found sink sequence number greater than any generated sink sequence number for task %d: %d > %d" % (task, sink_seqno_max, src_seqno_max))
success = False
if src_seqno_max < 1000 or sink_seqno_max < 1000:
errors.append("Not enough messages were processed: source:%d sink:%d" % (src_seqno_max, sink_seqno_max))
success = False
if not success:
self.mark_for_collect(self.cc)
# Also collect the data in the topic to aid in debugging
consumer_validator = ConsoleConsumer(self.test_context, 1, self.kafka, self.source.topic, consumer_timeout_ms=1000, print_key=True)
consumer_validator.run()
self.mark_for_collect(consumer_validator, "consumer_stdout")
assert success, "Found validation errors:\n" + "\n ".join(errors)
def _validate_file_output(self, input):
input_set = set(input)
# Output needs to be collected from all nodes because we can't be sure where the tasks will be scheduled.
# Between the first and second rounds, we might even end up with half the data on each node.
output_set = set(itertools.chain(*[
[line.strip() for line in self._file_contents(node, self.OUTPUT_FILE)] for node in self.cc.nodes
]))
return input_set == output_set
def _file_contents(self, node, file):
try:
# Convert to a list here or the CalledProcessError may be returned during a call to the generator instead of
# immediately
return list(node.account.ssh_capture("cat " + file))
except subprocess.CalledProcessError:
return []
class ConnectDistributedTest(Test):
"""
Simple test of Kafka Connect in distributed mode, producing data from files on one cluster and consuming it on
another, validating the total output is identical to the input.
"""
FILE_SOURCE_CONNECTOR = 'org.apache.kafka.connect.file.FileStreamSourceConnector'
FILE_SINK_CONNECTOR = 'org.apache.kafka.connect.file.FileStreamSinkConnector'
INPUT_FILE = "/mnt/connect.input"
OUTPUT_FILE = "/mnt/connect.output"
TOPIC = "test"
OFFSETS_TOPIC = "connect-offsets"
OFFSETS_REPLICATION_FACTOR = "1"
OFFSETS_PARTITIONS = "1"
CONFIG_TOPIC = "connect-configs"
CONFIG_REPLICATION_FACTOR = "1"
STATUS_TOPIC = "connect-status"
STATUS_REPLICATION_FACTOR = "1"
STATUS_PARTITIONS = "1"
SCHEDULED_REBALANCE_MAX_DELAY_MS = "60000"
CONNECT_PROTOCOL = "compatible"
# Since tasks can be assigned to any node and we're testing with files, we need to make sure the content is the same
# across all nodes.
FIRST_INPUT_LIST = ["foo", "bar", "baz"]
FIRST_INPUTS = "\n".join(FIRST_INPUT_LIST) + "\n"
SECOND_INPUT_LIST = ["razz", "ma", "tazz"]
SECOND_INPUTS = "\n".join(SECOND_INPUT_LIST) + "\n"
SCHEMA = {"type": "string", "optional": False}
def __init__(self, test_context):
super(ConnectDistributedTest, self).__init__(test_context)
self.num_zk = 1
self.num_brokers = 1
self.topics = {self.TOPIC: {'partitions': 1, 'replication-factor': 1}}
self.zk = ZookeeperService(test_context, self.num_zk)
self.key_converter = "org.apache.kafka.connect.json.JsonConverter"
self.value_converter = "org.apache.kafka.connect.json.JsonConverter"
self.schemas = True
def setup_services(self,
security_protocol=SecurityConfig.PLAINTEXT,
timestamp_type=None,
broker_version=DEV_BRANCH,
auto_create_topics=False):
self.kafka = KafkaService(
self.test_context,
self.num_brokers,
self.zk,
security_protocol=security_protocol,
interbroker_security_protocol=security_protocol,
topics=self.topics,
version=broker_version,
server_prop_overides=[[
"auto.create.topics.enable",
str(auto_create_topics)
]])
if timestamp_type is not None:
for node in self.kafka.nodes:
node.config[
config_property.MESSAGE_TIMESTAMP_TYPE] = timestamp_type
self.cc = ConnectDistributedService(
self.test_context, 3, self.kafka,
[self.INPUT_FILE, self.OUTPUT_FILE])
self.cc.log_level = "DEBUG"
self.zk.start()
self.kafka.start()
def _start_connector(self, config_file):
connector_props = self.render(config_file)
connector_config = dict([
line.strip().split('=', 1) for line in connector_props.split('\n')
if line.strip() and not line.strip().startswith('#')
])
self.cc.create_connector(connector_config)
def _connector_status(self, connector, node=None):
try:
return self.cc.get_connector_status(connector, node)
except ConnectRestError:
return None
def _connector_has_state(self, status, state):
return status is not None and status['connector']['state'] == state
def _task_has_state(self, task_id, status, state):
if not status:
return False
tasks = status['tasks']
if not tasks:
return False
for task in tasks:
if task['id'] == task_id:
return task['state'] == state
return False
def _all_tasks_have_state(self, status, task_count, state):
if status is None:
return False
tasks = status['tasks']
if len(tasks) != task_count:
return False
return reduce(operator.and_,
[task['state'] == state for task in tasks], True)
def is_running(self, connector, node=None):
status = self._connector_status(connector.name, node)
return self._connector_has_state(
status, 'RUNNING') and self._all_tasks_have_state(
status, connector.tasks, 'RUNNING')
def is_paused(self, connector, node=None):
status = self._connector_status(connector.name, node)
return self._connector_has_state(
status, 'PAUSED') and self._all_tasks_have_state(
status, connector.tasks, 'PAUSED')
def connector_is_running(self, connector, node=None):
status = self._connector_status(connector.name, node)
return self._connector_has_state(status, 'RUNNING')
def connector_is_failed(self, connector, node=None):
status = self._connector_status(connector.name, node)
return self._connector_has_state(status, 'FAILED')
def task_is_failed(self, connector, task_id, node=None):
status = self._connector_status(connector.name, node)
return self._task_has_state(task_id, status, 'FAILED')
def task_is_running(self, connector, task_id, node=None):
status = self._connector_status(connector.name, node)
return self._task_has_state(task_id, status, 'RUNNING')
@cluster(num_nodes=5)
@matrix(connect_protocol=['compatible', 'eager'])
def test_restart_failed_connector(self, connect_protocol):
self.CONNECT_PROTOCOL = connect_protocol
self.setup_services()
self.cc.set_configs(lambda node: self.render(
"connect-distributed.properties", node=node))
self.cc.start()
self.sink = MockSink(self.cc,
self.topics.keys(),
mode='connector-failure',
delay_sec=5)
self.sink.start()
wait_until(
lambda: self.connector_is_failed(self.sink),
timeout_sec=15,
err_msg="Failed to see connector transition to the FAILED state")
self.cc.restart_connector(self.sink.name)
wait_until(
lambda: self.connector_is_running(self.sink),
timeout_sec=10,
err_msg="Failed to see connector transition to the RUNNING state")
@cluster(num_nodes=5)
@matrix(connector_type=['source', 'sink'],
connect_protocol=['compatible', 'eager'])
def test_restart_failed_task(self, connector_type, connect_protocol):
self.CONNECT_PROTOCOL = connect_protocol
self.setup_services()
self.cc.set_configs(lambda node: self.render(
"connect-distributed.properties", node=node))
self.cc.start()
connector = None
if connector_type == "sink":
connector = MockSink(self.cc,
self.topics.keys(),
mode='task-failure',
delay_sec=5)
else:
connector = MockSource(self.cc, mode='task-failure', delay_sec=5)
connector.start()
task_id = 0
wait_until(lambda: self.task_is_failed(connector, task_id),
timeout_sec=20,
err_msg="Failed to see task transition to the FAILED state")
self.cc.restart_task(connector.name, task_id)
wait_until(
lambda: self.task_is_running(connector, task_id),
timeout_sec=10,
err_msg="Failed to see task transition to the RUNNING state")
@cluster(num_nodes=5)
@matrix(connect_protocol=['compatible', 'eager'])
def test_pause_and_resume_source(self, connect_protocol):
"""
Verify that source connectors stop producing records when paused and begin again after
being resumed.
"""
self.CONNECT_PROTOCOL = connect_protocol
self.setup_services()
self.cc.set_configs(lambda node: self.render(
"connect-distributed.properties", node=node))
self.cc.start()
self.source = VerifiableSource(self.cc, topic=self.TOPIC)
self.source.start()
wait_until(
lambda: self.is_running(self.source),
timeout_sec=30,
err_msg="Failed to see connector transition to the RUNNING state")
self.cc.pause_connector(self.source.name)
# wait until all nodes report the paused transition
for node in self.cc.nodes:
wait_until(
lambda: self.is_paused(self.source, node),
timeout_sec=30,
err_msg="Failed to see connector transition to the PAUSED state"
)
# verify that we do not produce new messages while paused
num_messages = len(self.source.sent_messages())
time.sleep(10)
assert num_messages == len(self.source.sent_messages(
)), "Paused source connector should not produce any messages"
self.cc.resume_connector(self.source.name)
for node in self.cc.nodes:
wait_until(
lambda: self.is_running(self.source, node),
timeout_sec=30,
err_msg=
"Failed to see connector transition to the RUNNING state")
# after resuming, we should see records produced again
wait_until(
lambda: len(self.source.sent_messages()) > num_messages,
timeout_sec=30,
err_msg="Failed to produce messages after resuming source connector"
)
@cluster(num_nodes=5)
@matrix(connect_protocol=['compatible', 'eager'])
def test_pause_and_resume_sink(self, connect_protocol):
"""
Verify that sink connectors stop consuming records when paused and begin again after
being resumed.
"""
self.CONNECT_PROTOCOL = connect_protocol
self.setup_services()
self.cc.set_configs(lambda node: self.render(
"connect-distributed.properties", node=node))
self.cc.start()
# use the verifiable source to produce a steady stream of messages
self.source = VerifiableSource(self.cc, topic=self.TOPIC)
self.source.start()
wait_until(
lambda: len(self.source.committed_messages()) > 0,
timeout_sec=30,
err_msg=
"Timeout expired waiting for source task to produce a message")
self.sink = VerifiableSink(self.cc, topics=[self.TOPIC])
self.sink.start()
wait_until(
lambda: self.is_running(self.sink),
timeout_sec=30,
err_msg="Failed to see connector transition to the RUNNING state")
self.cc.pause_connector(self.sink.name)
# wait until all nodes report the paused transition
for node in self.cc.nodes:
wait_until(
lambda: self.is_paused(self.sink, node),
timeout_sec=30,
err_msg="Failed to see connector transition to the PAUSED state"
)
# verify that we do not consume new messages while paused
num_messages = len(self.sink.received_messages())
time.sleep(10)
assert num_messages == len(self.sink.received_messages(
)), "Paused sink connector should not consume any messages"
self.cc.resume_connector(self.sink.name)
for node in self.cc.nodes:
wait_until(
lambda: self.is_running(self.sink, node),
timeout_sec=30,
err_msg=
"Failed to see connector transition to the RUNNING state")
# after resuming, we should see records consumed again
wait_until(
lambda: len(self.sink.received_messages()) > num_messages,
timeout_sec=30,
err_msg="Failed to consume messages after resuming sink connector")
@cluster(num_nodes=5)
@matrix(connect_protocol=['compatible', 'eager'])
def test_pause_state_persistent(self, connect_protocol):
"""
Verify that paused state is preserved after a cluster restart.
"""
self.CONNECT_PROTOCOL = connect_protocol
self.setup_services()
self.cc.set_configs(lambda node: self.render(
"connect-distributed.properties", node=node))
self.cc.start()
self.source = VerifiableSource(self.cc, topic=self.TOPIC)
self.source.start()
wait_until(
lambda: self.is_running(self.source),
timeout_sec=30,
err_msg="Failed to see connector transition to the RUNNING state")
self.cc.pause_connector(self.source.name)
self.cc.restart()
if connect_protocol == 'compatible':
timeout_sec = 120
else:
timeout_sec = 30
# we should still be paused after restarting
for node in self.cc.nodes:
wait_until(
lambda: self.is_paused(self.source, node),
timeout_sec=timeout_sec,
err_msg="Failed to see connector startup in PAUSED state")
@cluster(num_nodes=6)
@matrix(
security_protocol=[SecurityConfig.PLAINTEXT, SecurityConfig.SASL_SSL],
connect_protocol=['compatible', 'eager'])
def test_file_source_and_sink(self, security_protocol, connect_protocol):
"""
Tests that a basic file connector works across clean rolling bounces. This validates that the connector is
correctly created, tasks instantiated, and as nodes restart the work is rebalanced across nodes.
"""
self.CONNECT_PROTOCOL = connect_protocol
self.setup_services(security_protocol=security_protocol)
self.cc.set_configs(lambda node: self.render(
"connect-distributed.properties", node=node))
self.cc.start()
self.logger.info("Creating connectors")
self._start_connector("connect-file-source.properties")
self._start_connector("connect-file-sink.properties")
# Generating data on the source node should generate new records and create new output on the sink node. Timeouts
# here need to be more generous than they are for standalone mode because a) it takes longer to write configs,
# do rebalancing of the group, etc, and b) without explicit leave group support, rebalancing takes awhile
for node in self.cc.nodes:
node.account.ssh("echo -e -n " + repr(self.FIRST_INPUTS) + " >> " +
self.INPUT_FILE)
wait_until(
lambda: self._validate_file_output(self.FIRST_INPUT_LIST),
timeout_sec=70,
err_msg=
"Data added to input file was not seen in the output file in a reasonable amount of time."
)
# Restarting both should result in them picking up where they left off,
# only processing new data.
self.cc.restart()
if connect_protocol == 'compatible':
timeout_sec = 150
else:
timeout_sec = 70
for node in self.cc.nodes:
node.account.ssh("echo -e -n " + repr(self.SECOND_INPUTS) +
" >> " + self.INPUT_FILE)
wait_until(
lambda: self._validate_file_output(self.FIRST_INPUT_LIST + self.
SECOND_INPUT_LIST),
timeout_sec=timeout_sec,
err_msg=
"Sink output file never converged to the same state as the input file"
)
@cluster(num_nodes=6)
@matrix(clean=[True, False], connect_protocol=['compatible', 'eager'])
def test_bounce(self, clean, connect_protocol):
"""
Validates that source and sink tasks that run continuously and produce a predictable sequence of messages
run correctly and deliver messages exactly once when Kafka Connect workers undergo clean rolling bounces.
"""
num_tasks = 3
self.CONNECT_PROTOCOL = connect_protocol
self.setup_services()
self.cc.set_configs(lambda node: self.render(
"connect-distributed.properties", node=node))
self.cc.start()
self.source = VerifiableSource(self.cc,
topic=self.TOPIC,
tasks=num_tasks,
throughput=100)
self.source.start()
self.sink = VerifiableSink(self.cc,
tasks=num_tasks,
topics=[self.TOPIC])
self.sink.start()
for _ in range(3):
for node in self.cc.nodes:
started = time.time()
self.logger.info("%s bouncing Kafka Connect on %s",
clean and "Clean" or "Hard",
str(node.account))
self.cc.stop_node(node, clean_shutdown=clean)
with node.account.monitor_log(self.cc.LOG_FILE) as monitor:
self.cc.start_node(node)
monitor.wait_until(
"Starting connectors and tasks using config offset",
timeout_sec=90,
err_msg=
"Kafka Connect worker didn't successfully join group and start work"
)
self.logger.info(
"Bounced Kafka Connect on %s and rejoined in %f seconds",
node.account,
time.time() - started)
# Give additional time for the consumer groups to recover. Even if it is not a hard bounce, there are
# some cases where a restart can cause a rebalance to take the full length of the session timeout
# (e.g. if the client shuts down before it has received the memberId from its initial JoinGroup).
# If we don't give enough time for the group to stabilize, the next bounce may cause consumers to
# be shut down before they have any time to process data and we can end up with zero data making it
# through the test.
time.sleep(15)
self.source.stop()
self.sink.stop()
self.cc.stop()
# Validate at least once delivery of everything that was reported as written since we should have flushed and
# cleanly exited. Currently this only tests at least once delivery because the sink task may not have consumed
# all the messages generated by the source task. This needs to be done per-task since seqnos are not unique across
# tasks.
success = True
errors = []
allow_dups = not clean
src_messages = self.source.committed_messages()
sink_messages = self.sink.flushed_messages()
for task in range(num_tasks):
# Validate source messages
src_seqnos = [
msg['seqno'] for msg in src_messages if msg['task'] == task
]
# Every seqno up to the largest one we ever saw should appear. Each seqno should only appear once because clean
# bouncing should commit on rebalance.
src_seqno_max = max(src_seqnos)
self.logger.debug("Max source seqno: %d", src_seqno_max)
src_seqno_counts = Counter(src_seqnos)
missing_src_seqnos = sorted(
set(range(src_seqno_max)).difference(set(src_seqnos)))
duplicate_src_seqnos = sorted([
seqno for seqno, count in src_seqno_counts.iteritems()
if count > 1
])
if missing_src_seqnos:
self.logger.error("Missing source sequence numbers for task " +
str(task))
errors.append(
"Found missing source sequence numbers for task %d: %s" %
(task, missing_src_seqnos))
success = False
if not allow_dups and duplicate_src_seqnos:
self.logger.error(
"Duplicate source sequence numbers for task " + str(task))
errors.append(
"Found duplicate source sequence numbers for task %d: %s" %
(task, duplicate_src_seqnos))
success = False
# Validate sink messages
sink_seqnos = [
msg['seqno'] for msg in sink_messages if msg['task'] == task
]
# Every seqno up to the largest one we ever saw should appear. Each seqno should only appear once because
# clean bouncing should commit on rebalance.
sink_seqno_max = max(sink_seqnos)
self.logger.debug("Max sink seqno: %d", sink_seqno_max)
sink_seqno_counts = Counter(sink_seqnos)
missing_sink_seqnos = sorted(
set(range(sink_seqno_max)).difference(set(sink_seqnos)))
duplicate_sink_seqnos = sorted([
seqno for seqno, count in sink_seqno_counts.iteritems()
if count > 1
])
if missing_sink_seqnos:
self.logger.error("Missing sink sequence numbers for task " +
str(task))
errors.append(
"Found missing sink sequence numbers for task %d: %s" %
(task, missing_sink_seqnos))
success = False
if not allow_dups and duplicate_sink_seqnos:
self.logger.error("Duplicate sink sequence numbers for task " +
str(task))
errors.append(
"Found duplicate sink sequence numbers for task %d: %s" %
(task, duplicate_sink_seqnos))
success = False
# Validate source and sink match
if sink_seqno_max > src_seqno_max:
self.logger.error(
"Found sink sequence number greater than any generated sink sequence number for task %d: %d > %d",
task, sink_seqno_max, src_seqno_max)
errors.append(
"Found sink sequence number greater than any generated sink sequence number for task %d: %d > %d"
% (task, sink_seqno_max, src_seqno_max))
success = False
if src_seqno_max < 1000 or sink_seqno_max < 1000:
errors.append(
"Not enough messages were processed: source:%d sink:%d" %
(src_seqno_max, sink_seqno_max))
success = False
if not success:
self.mark_for_collect(self.cc)
# Also collect the data in the topic to aid in debugging
consumer_validator = ConsoleConsumer(self.test_context,
1,
self.kafka,
self.source.topic,
consumer_timeout_ms=1000,
print_key=True)
consumer_validator.run()
self.mark_for_collect(consumer_validator, "consumer_stdout")
assert success, "Found validation errors:\n" + "\n ".join(errors)
@cluster(num_nodes=6)
@matrix(connect_protocol=['compatible', 'eager'])
def test_transformations(self, connect_protocol):
self.CONNECT_PROTOCOL = connect_protocol
self.setup_services(timestamp_type='CreateTime')
self.cc.set_configs(lambda node: self.render(
"connect-distributed.properties", node=node))
self.cc.start()
ts_fieldname = 'the_timestamp'
NamedConnector = namedtuple('Connector', ['name'])
source_connector = NamedConnector(name='file-src')
self.cc.create_connector({
'name':
source_connector.name,
'connector.class':
'org.apache.kafka.connect.file.FileStreamSourceConnector',
'tasks.max':
1,
'file':
self.INPUT_FILE,
'topic':
self.TOPIC,
'transforms':
'hoistToStruct,insertTimestampField',
'transforms.hoistToStruct.type':
'org.apache.kafka.connect.transforms.HoistField$Value',
'transforms.hoistToStruct.field':
'content',
'transforms.insertTimestampField.type':
'org.apache.kafka.connect.transforms.InsertField$Value',
'transforms.insertTimestampField.timestamp.field':
ts_fieldname,
})
wait_until(
lambda: self.connector_is_running(source_connector),
timeout_sec=30,
err_msg='Failed to see connector transition to the RUNNING state')
for node in self.cc.nodes:
node.account.ssh("echo -e -n " + repr(self.FIRST_INPUTS) + " >> " +
self.INPUT_FILE)
consumer = ConsoleConsumer(self.test_context,
1,
self.kafka,
self.TOPIC,
consumer_timeout_ms=15000,
print_timestamp=True)
consumer.run()
assert len(consumer.messages_consumed[1]) == len(self.FIRST_INPUT_LIST)
expected_schema = {
'type':
'struct',
'fields': [
{
'field': 'content',
'type': 'string',
'optional': False
},
{
'field': ts_fieldname,
'name': 'org.apache.kafka.connect.data.Timestamp',
'type': 'int64',
'version': 1,
'optional': True
},
],
'optional':
False
}
for msg in consumer.messages_consumed[1]:
(ts_info, value) = msg.split('\t')
assert ts_info.startswith('CreateTime:')
ts = int(ts_info[len('CreateTime:'):])
obj = json.loads(value)
assert obj['schema'] == expected_schema
assert obj['payload']['content'] in self.FIRST_INPUT_LIST
assert obj['payload'][ts_fieldname] == ts
@cluster(num_nodes=5)
@parametrize(broker_version=str(DEV_BRANCH),
auto_create_topics=False,
security_protocol=SecurityConfig.PLAINTEXT,
connect_protocol='compatible')
@parametrize(broker_version=str(LATEST_0_11_0),
auto_create_topics=False,
security_protocol=SecurityConfig.PLAINTEXT,
connect_protocol='compatible')
@parametrize(broker_version=str(LATEST_0_10_2),
auto_create_topics=False,
security_protocol=SecurityConfig.PLAINTEXT,
connect_protocol='compatible')
@parametrize(broker_version=str(LATEST_0_10_1),
auto_create_topics=False,
security_protocol=SecurityConfig.PLAINTEXT,
connect_protocol='compatible')
@parametrize(broker_version=str(LATEST_0_10_0),
auto_create_topics=True,
security_protocol=SecurityConfig.PLAINTEXT,
connect_protocol='compatible')
@parametrize(broker_version=str(LATEST_0_9),
auto_create_topics=True,
security_protocol=SecurityConfig.PLAINTEXT,
connect_protocol='compatible')
@parametrize(broker_version=str(DEV_BRANCH),
auto_create_topics=False,
security_protocol=SecurityConfig.PLAINTEXT,
connect_protocol='eager')
@parametrize(broker_version=str(LATEST_0_11_0),
auto_create_topics=False,
security_protocol=SecurityConfig.PLAINTEXT,
connect_protocol='eager')
@parametrize(broker_version=str(LATEST_0_10_2),
auto_create_topics=False,
security_protocol=SecurityConfig.PLAINTEXT,
connect_protocol='eager')
@parametrize(broker_version=str(LATEST_0_10_1),
auto_create_topics=False,
security_protocol=SecurityConfig.PLAINTEXT,
connect_protocol='eager')
@parametrize(broker_version=str(LATEST_0_10_0),
auto_create_topics=True,
security_protocol=SecurityConfig.PLAINTEXT,
connect_protocol='eager')
@parametrize(broker_version=str(LATEST_0_9),
auto_create_topics=True,
security_protocol=SecurityConfig.PLAINTEXT,
connect_protocol='eager')
def test_broker_compatibility(self, broker_version, auto_create_topics,
security_protocol, connect_protocol):
"""
Verify that Connect will start up with various broker versions with various configurations.
When Connect distributed starts up, it either creates internal topics (v0.10.1.0 and after)
or relies upon the broker to auto-create the topics (v0.10.0.x and before).
"""
self.CONNECT_PROTOCOL = connect_protocol
self.setup_services(broker_version=broker_version,
auto_create_topics=auto_create_topics,
security_protocol=security_protocol)
self.cc.set_configs(lambda node: self.render(
"connect-distributed.properties", node=node))
self.cc.start()
self.logger.info("Creating connectors")
self._start_connector("connect-file-source.properties")
self._start_connector("connect-file-sink.properties")
# Generating data on the source node should generate new records and create new output on the sink node. Timeouts
# here need to be more generous than they are for standalone mode because a) it takes longer to write configs,
# do rebalancing of the group, etc, and b) without explicit leave group support, rebalancing takes awhile
for node in self.cc.nodes:
node.account.ssh("echo -e -n " + repr(self.FIRST_INPUTS) + " >> " +
self.INPUT_FILE)
wait_until(
lambda: self._validate_file_output(self.FIRST_INPUT_LIST),
timeout_sec=70,
err_msg=
"Data added to input file was not seen in the output file in a reasonable amount of time."
)
def _validate_file_output(self, input):
input_set = set(input)
# Output needs to be collected from all nodes because we can't be sure where the tasks will be scheduled.
# Between the first and second rounds, we might even end up with half the data on each node.
output_set = set(
itertools.chain(*[[
line.strip()
for line in self._file_contents(node, self.OUTPUT_FILE)
] for node in self.cc.nodes]))
return input_set == output_set
def _file_contents(self, node, file):
try:
# Convert to a list here or the RemoteCommandError may be returned during a call to the generator instead of
# immediately
return list(node.account.ssh_capture("cat " + file))
except RemoteCommandError:
return []
class ConnectDistributedTest(Test):
"""
Simple test of Kafka Connect in distributed mode, producing data from files on one cluster and consuming it on
another, validating the total output is identical to the input.
"""
FILE_SOURCE_CONNECTOR = 'org.apache.kafka.connect.file.FileStreamSourceConnector'
FILE_SINK_CONNECTOR = 'org.apache.kafka.connect.file.FileStreamSinkConnector'
INPUT_FILE = "/mnt/connect.input"
OUTPUT_FILE = "/mnt/connect.output"
TOPIC = "test"
OFFSETS_TOPIC = "connect-offsets"
OFFSETS_REPLICATION_FACTOR = "1"
OFFSETS_PARTITIONS = "1"
CONFIG_TOPIC = "connect-configs"
CONFIG_REPLICATION_FACTOR = "1"
STATUS_TOPIC = "connect-status"
STATUS_REPLICATION_FACTOR = "1"
STATUS_PARTITIONS = "1"
# Since tasks can be assigned to any node and we're testing with files, we need to make sure the content is the same
# across all nodes.
FIRST_INPUT_LIST = ["foo", "bar", "baz"]
FIRST_INPUTS = "\n".join(FIRST_INPUT_LIST) + "\n"
SECOND_INPUT_LIST = ["razz", "ma", "tazz"]
SECOND_INPUTS = "\n".join(SECOND_INPUT_LIST) + "\n"
SCHEMA = { "type": "string", "optional": False }
def __init__(self, test_context):
super(ConnectDistributedTest, self).__init__(test_context)
self.num_zk = 1
self.num_brokers = 1
self.topics = {
self.TOPIC: {'partitions': 1, 'replication-factor': 1}
}
self.zk = ZookeeperService(test_context, self.num_zk)
self.key_converter = "org.apache.kafka.connect.json.JsonConverter"
self.value_converter = "org.apache.kafka.connect.json.JsonConverter"
self.schemas = True
def setup_services(self, security_protocol=SecurityConfig.PLAINTEXT, timestamp_type=None, broker_version=DEV_BRANCH, auto_create_topics=False):
self.kafka = KafkaService(self.test_context, self.num_brokers, self.zk,
security_protocol=security_protocol, interbroker_security_protocol=security_protocol,
topics=self.topics, version=broker_version,
server_prop_overides=[["auto.create.topics.enable", str(auto_create_topics)]])
if timestamp_type is not None:
for node in self.kafka.nodes:
node.config[config_property.MESSAGE_TIMESTAMP_TYPE] = timestamp_type
self.cc = ConnectDistributedService(self.test_context, 3, self.kafka, [self.INPUT_FILE, self.OUTPUT_FILE])
self.cc.log_level = "DEBUG"
self.zk.start()
self.kafka.start()
def _start_connector(self, config_file):
connector_props = self.render(config_file)
connector_config = dict([line.strip().split('=', 1) for line in connector_props.split('\n') if line.strip() and not line.strip().startswith('#')])
self.cc.create_connector(connector_config)
def _connector_status(self, connector, node=None):
try:
return self.cc.get_connector_status(connector, node)
except ConnectRestError:
return None
def _connector_has_state(self, status, state):
return status is not None and status['connector']['state'] == state
def _task_has_state(self, task_id, status, state):
if not status:
return False
tasks = status['tasks']
if not tasks:
return False
for task in tasks:
if task['id'] == task_id:
return task['state'] == state
return False
def _all_tasks_have_state(self, status, task_count, state):
if status is None:
return False
tasks = status['tasks']
if len(tasks) != task_count:
return False
return reduce(operator.and_, [task['state'] == state for task in tasks], True)
def is_running(self, connector, node=None):
status = self._connector_status(connector.name, node)
return self._connector_has_state(status, 'RUNNING') and self._all_tasks_have_state(status, connector.tasks, 'RUNNING')
def is_paused(self, connector, node=None):
status = self._connector_status(connector.name, node)
return self._connector_has_state(status, 'PAUSED') and self._all_tasks_have_state(status, connector.tasks, 'PAUSED')
def connector_is_running(self, connector, node=None):
status = self._connector_status(connector.name, node)
return self._connector_has_state(status, 'RUNNING')
def connector_is_failed(self, connector, node=None):
status = self._connector_status(connector.name, node)
return self._connector_has_state(status, 'FAILED')
def task_is_failed(self, connector, task_id, node=None):
status = self._connector_status(connector.name, node)
return self._task_has_state(task_id, status, 'FAILED')
def task_is_running(self, connector, task_id, node=None):
status = self._connector_status(connector.name, node)
return self._task_has_state(task_id, status, 'RUNNING')
@cluster(num_nodes=5)
def test_restart_failed_connector(self):
self.setup_services()
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
self.sink = MockSink(self.cc, self.topics.keys(), mode='connector-failure', delay_sec=5)
self.sink.start()
wait_until(lambda: self.connector_is_failed(self.sink), timeout_sec=15,
err_msg="Failed to see connector transition to the FAILED state")
self.cc.restart_connector(self.sink.name)
wait_until(lambda: self.connector_is_running(self.sink), timeout_sec=10,
err_msg="Failed to see connector transition to the RUNNING state")
@cluster(num_nodes=5)
@matrix(connector_type=["source", "sink"])
def test_restart_failed_task(self, connector_type):
self.setup_services()
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
connector = None
if connector_type == "sink":
connector = MockSink(self.cc, self.topics.keys(), mode='task-failure', delay_sec=5)
else:
connector = MockSource(self.cc, mode='task-failure', delay_sec=5)
connector.start()
task_id = 0
wait_until(lambda: self.task_is_failed(connector, task_id), timeout_sec=20,
err_msg="Failed to see task transition to the FAILED state")
self.cc.restart_task(connector.name, task_id)
wait_until(lambda: self.task_is_running(connector, task_id), timeout_sec=10,
err_msg="Failed to see task transition to the RUNNING state")
@cluster(num_nodes=5)
def test_pause_and_resume_source(self):
"""
Verify that source connectors stop producing records when paused and begin again after
being resumed.
"""
self.setup_services()
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
self.source = VerifiableSource(self.cc, topic=self.TOPIC)
self.source.start()
wait_until(lambda: self.is_running(self.source), timeout_sec=30,
err_msg="Failed to see connector transition to the RUNNING state")
self.cc.pause_connector(self.source.name)
# wait until all nodes report the paused transition
for node in self.cc.nodes:
wait_until(lambda: self.is_paused(self.source, node), timeout_sec=30,
err_msg="Failed to see connector transition to the PAUSED state")
# verify that we do not produce new messages while paused
num_messages = len(self.source.sent_messages())
time.sleep(10)
assert num_messages == len(self.source.sent_messages()), "Paused source connector should not produce any messages"
self.cc.resume_connector(self.source.name)
for node in self.cc.nodes:
wait_until(lambda: self.is_running(self.source, node), timeout_sec=30,
err_msg="Failed to see connector transition to the RUNNING state")
# after resuming, we should see records produced again
wait_until(lambda: len(self.source.sent_messages()) > num_messages, timeout_sec=30,
err_msg="Failed to produce messages after resuming source connector")
@cluster(num_nodes=5)
def test_pause_and_resume_sink(self):
"""
Verify that sink connectors stop consuming records when paused and begin again after
being resumed.
"""
self.setup_services()
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
# use the verifiable source to produce a steady stream of messages
self.source = VerifiableSource(self.cc, topic=self.TOPIC)
self.source.start()
wait_until(lambda: len(self.source.committed_messages()) > 0, timeout_sec=30,
err_msg="Timeout expired waiting for source task to produce a message")
self.sink = VerifiableSink(self.cc, topics=[self.TOPIC])
self.sink.start()
wait_until(lambda: self.is_running(self.sink), timeout_sec=30,
err_msg="Failed to see connector transition to the RUNNING state")
self.cc.pause_connector(self.sink.name)
# wait until all nodes report the paused transition
for node in self.cc.nodes:
wait_until(lambda: self.is_paused(self.sink, node), timeout_sec=30,
err_msg="Failed to see connector transition to the PAUSED state")
# verify that we do not consume new messages while paused
num_messages = len(self.sink.received_messages())
time.sleep(10)
assert num_messages == len(self.sink.received_messages()), "Paused sink connector should not consume any messages"
self.cc.resume_connector(self.sink.name)
for node in self.cc.nodes:
wait_until(lambda: self.is_running(self.sink, node), timeout_sec=30,
err_msg="Failed to see connector transition to the RUNNING state")
# after resuming, we should see records consumed again
wait_until(lambda: len(self.sink.received_messages()) > num_messages, timeout_sec=30,
err_msg="Failed to consume messages after resuming sink connector")
@cluster(num_nodes=5)
def test_pause_state_persistent(self):
"""
Verify that paused state is preserved after a cluster restart.
"""
self.setup_services()
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
self.source = VerifiableSource(self.cc, topic=self.TOPIC)
self.source.start()
wait_until(lambda: self.is_running(self.source), timeout_sec=30,
err_msg="Failed to see connector transition to the RUNNING state")
self.cc.pause_connector(self.source.name)
self.cc.restart()
# we should still be paused after restarting
for node in self.cc.nodes:
wait_until(lambda: self.is_paused(self.source, node), timeout_sec=30,
err_msg="Failed to see connector startup in PAUSED state")
@cluster(num_nodes=5)
@parametrize(security_protocol=SecurityConfig.PLAINTEXT)
@cluster(num_nodes=6)
@parametrize(security_protocol=SecurityConfig.SASL_SSL)
def test_file_source_and_sink(self, security_protocol):
"""
Tests that a basic file connector works across clean rolling bounces. This validates that the connector is
correctly created, tasks instantiated, and as nodes restart the work is rebalanced across nodes.
"""
self.setup_services(security_protocol=security_protocol)
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
self.logger.info("Creating connectors")
self._start_connector("connect-file-source.properties")
self._start_connector("connect-file-sink.properties")
# Generating data on the source node should generate new records and create new output on the sink node. Timeouts
# here need to be more generous than they are for standalone mode because a) it takes longer to write configs,
# do rebalancing of the group, etc, and b) without explicit leave group support, rebalancing takes awhile
for node in self.cc.nodes:
node.account.ssh("echo -e -n " + repr(self.FIRST_INPUTS) + " >> " + self.INPUT_FILE)
wait_until(lambda: self._validate_file_output(self.FIRST_INPUT_LIST), timeout_sec=70, err_msg="Data added to input file was not seen in the output file in a reasonable amount of time.")
# Restarting both should result in them picking up where they left off,
# only processing new data.
self.cc.restart()
for node in self.cc.nodes:
node.account.ssh("echo -e -n " + repr(self.SECOND_INPUTS) + " >> " + self.INPUT_FILE)
wait_until(lambda: self._validate_file_output(self.FIRST_INPUT_LIST + self.SECOND_INPUT_LIST), timeout_sec=70, err_msg="Sink output file never converged to the same state as the input file")
@cluster(num_nodes=5)
@matrix(clean=[True, False])
def test_bounce(self, clean):
"""
Validates that source and sink tasks that run continuously and produce a predictable sequence of messages
run correctly and deliver messages exactly once when Kafka Connect workers undergo clean rolling bounces.
"""
num_tasks = 3
self.setup_services()
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
self.source = VerifiableSource(self.cc, topic=self.TOPIC, tasks=num_tasks, throughput=100)
self.source.start()
self.sink = VerifiableSink(self.cc, tasks=num_tasks, topics=[self.TOPIC])
self.sink.start()
for _ in range(3):
for node in self.cc.nodes:
started = time.time()
self.logger.info("%s bouncing Kafka Connect on %s", clean and "Clean" or "Hard", str(node.account))
self.cc.stop_node(node, clean_shutdown=clean)
with node.account.monitor_log(self.cc.LOG_FILE) as monitor:
self.cc.start_node(node)
monitor.wait_until("Starting connectors and tasks using config offset", timeout_sec=90,
err_msg="Kafka Connect worker didn't successfully join group and start work")
self.logger.info("Bounced Kafka Connect on %s and rejoined in %f seconds", node.account, time.time() - started)
# Give additional time for the consumer groups to recover. Even if it is not a hard bounce, there are
# some cases where a restart can cause a rebalance to take the full length of the session timeout
# (e.g. if the client shuts down before it has received the memberId from its initial JoinGroup).
# If we don't give enough time for the group to stabilize, the next bounce may cause consumers to
# be shut down before they have any time to process data and we can end up with zero data making it
# through the test.
time.sleep(15)
self.source.stop()
self.sink.stop()
self.cc.stop()
# Validate at least once delivery of everything that was reported as written since we should have flushed and
# cleanly exited. Currently this only tests at least once delivery because the sink task may not have consumed
# all the messages generated by the source task. This needs to be done per-task since seqnos are not unique across
# tasks.
success = True
errors = []
allow_dups = not clean
src_messages = self.source.committed_messages()
sink_messages = self.sink.flushed_messages()
for task in range(num_tasks):
# Validate source messages
src_seqnos = [msg['seqno'] for msg in src_messages if msg['task'] == task]
# Every seqno up to the largest one we ever saw should appear. Each seqno should only appear once because clean
# bouncing should commit on rebalance.
src_seqno_max = max(src_seqnos)
self.logger.debug("Max source seqno: %d", src_seqno_max)
src_seqno_counts = Counter(src_seqnos)
missing_src_seqnos = sorted(set(range(src_seqno_max)).difference(set(src_seqnos)))
duplicate_src_seqnos = sorted([seqno for seqno,count in src_seqno_counts.iteritems() if count > 1])
if missing_src_seqnos:
self.logger.error("Missing source sequence numbers for task " + str(task))
errors.append("Found missing source sequence numbers for task %d: %s" % (task, missing_src_seqnos))
success = False
if not allow_dups and duplicate_src_seqnos:
self.logger.error("Duplicate source sequence numbers for task " + str(task))
errors.append("Found duplicate source sequence numbers for task %d: %s" % (task, duplicate_src_seqnos))
success = False
# Validate sink messages
sink_seqnos = [msg['seqno'] for msg in sink_messages if msg['task'] == task]
# Every seqno up to the largest one we ever saw should appear. Each seqno should only appear once because
# clean bouncing should commit on rebalance.
sink_seqno_max = max(sink_seqnos)
self.logger.debug("Max sink seqno: %d", sink_seqno_max)
sink_seqno_counts = Counter(sink_seqnos)
missing_sink_seqnos = sorted(set(range(sink_seqno_max)).difference(set(sink_seqnos)))
duplicate_sink_seqnos = sorted([seqno for seqno,count in sink_seqno_counts.iteritems() if count > 1])
if missing_sink_seqnos:
self.logger.error("Missing sink sequence numbers for task " + str(task))
errors.append("Found missing sink sequence numbers for task %d: %s" % (task, missing_sink_seqnos))
success = False
if not allow_dups and duplicate_sink_seqnos:
self.logger.error("Duplicate sink sequence numbers for task " + str(task))
errors.append("Found duplicate sink sequence numbers for task %d: %s" % (task, duplicate_sink_seqnos))
success = False
# Validate source and sink match
if sink_seqno_max > src_seqno_max:
self.logger.error("Found sink sequence number greater than any generated sink sequence number for task %d: %d > %d", task, sink_seqno_max, src_seqno_max)
errors.append("Found sink sequence number greater than any generated sink sequence number for task %d: %d > %d" % (task, sink_seqno_max, src_seqno_max))
success = False
if src_seqno_max < 1000 or sink_seqno_max < 1000:
errors.append("Not enough messages were processed: source:%d sink:%d" % (src_seqno_max, sink_seqno_max))
success = False
if not success:
self.mark_for_collect(self.cc)
# Also collect the data in the topic to aid in debugging
consumer_validator = ConsoleConsumer(self.test_context, 1, self.kafka, self.source.topic, consumer_timeout_ms=1000, print_key=True)
consumer_validator.run()
self.mark_for_collect(consumer_validator, "consumer_stdout")
assert success, "Found validation errors:\n" + "\n ".join(errors)
@cluster(num_nodes=6)
def test_transformations(self):
self.setup_services(timestamp_type='CreateTime')
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
ts_fieldname = 'the_timestamp'
NamedConnector = namedtuple('Connector', ['name'])
source_connector = NamedConnector(name='file-src')
self.cc.create_connector({
'name': source_connector.name,
'connector.class': 'org.apache.kafka.connect.file.FileStreamSourceConnector',
'tasks.max': 1,
'file': self.INPUT_FILE,
'topic': self.TOPIC,
'transforms': 'hoistToStruct,insertTimestampField',
'transforms.hoistToStruct.type': 'org.apache.kafka.connect.transforms.HoistField$Value',
'transforms.hoistToStruct.field': 'content',
'transforms.insertTimestampField.type': 'org.apache.kafka.connect.transforms.InsertField$Value',
'transforms.insertTimestampField.timestamp.field': ts_fieldname,
})
wait_until(lambda: self.connector_is_running(source_connector), timeout_sec=30, err_msg='Failed to see connector transition to the RUNNING state')
for node in self.cc.nodes:
node.account.ssh("echo -e -n " + repr(self.FIRST_INPUTS) + " >> " + self.INPUT_FILE)
consumer = ConsoleConsumer(self.test_context, 1, self.kafka, self.TOPIC, consumer_timeout_ms=15000, print_timestamp=True)
consumer.run()
assert len(consumer.messages_consumed[1]) == len(self.FIRST_INPUT_LIST)
expected_schema = {
'type': 'struct',
'fields': [
{'field': 'content', 'type': 'string', 'optional': False},
{'field': ts_fieldname, 'name': 'org.apache.kafka.connect.data.Timestamp', 'type': 'int64', 'version': 1, 'optional': True},
],
'optional': False
}
for msg in consumer.messages_consumed[1]:
(ts_info, value) = msg.split('\t')
assert ts_info.startswith('CreateTime:')
ts = int(ts_info[len('CreateTime:'):])
obj = json.loads(value)
assert obj['schema'] == expected_schema
assert obj['payload']['content'] in self.FIRST_INPUT_LIST
assert obj['payload'][ts_fieldname] == ts
@cluster(num_nodes=5)
@parametrize(broker_version=str(DEV_BRANCH), auto_create_topics=False, security_protocol=SecurityConfig.PLAINTEXT)
@parametrize(broker_version=str(LATEST_0_11_0), auto_create_topics=False, security_protocol=SecurityConfig.PLAINTEXT)
@parametrize(broker_version=str(LATEST_0_10_2), auto_create_topics=False, security_protocol=SecurityConfig.PLAINTEXT)
@parametrize(broker_version=str(LATEST_0_10_1), auto_create_topics=False, security_protocol=SecurityConfig.PLAINTEXT)
@parametrize(broker_version=str(LATEST_0_10_0), auto_create_topics=True, security_protocol=SecurityConfig.PLAINTEXT)
@parametrize(broker_version=str(LATEST_0_9), auto_create_topics=True, security_protocol=SecurityConfig.PLAINTEXT)
def test_broker_compatibility(self, broker_version, auto_create_topics, security_protocol):
"""
Verify that Connect will start up with various broker versions with various configurations.
When Connect distributed starts up, it either creates internal topics (v0.10.1.0 and after)
or relies upon the broker to auto-create the topics (v0.10.0.x and before).
"""
self.setup_services(broker_version=broker_version, auto_create_topics=auto_create_topics, security_protocol=security_protocol)
self.cc.set_configs(lambda node: self.render("connect-distributed.properties", node=node))
self.cc.start()
self.logger.info("Creating connectors")
self._start_connector("connect-file-source.properties")
self._start_connector("connect-file-sink.properties")
# Generating data on the source node should generate new records and create new output on the sink node. Timeouts
# here need to be more generous than they are for standalone mode because a) it takes longer to write configs,
# do rebalancing of the group, etc, and b) without explicit leave group support, rebalancing takes awhile
for node in self.cc.nodes:
node.account.ssh("echo -e -n " + repr(self.FIRST_INPUTS) + " >> " + self.INPUT_FILE)
wait_until(lambda: self._validate_file_output(self.FIRST_INPUT_LIST), timeout_sec=70, err_msg="Data added to input file was not seen in the output file in a reasonable amount of time.")
def _validate_file_output(self, input):
input_set = set(input)
# Output needs to be collected from all nodes because we can't be sure where the tasks will be scheduled.
# Between the first and second rounds, we might even end up with half the data on each node.
output_set = set(itertools.chain(*[
[line.strip() for line in self._file_contents(node, self.OUTPUT_FILE)] for node in self.cc.nodes
]))
return input_set == output_set
def _file_contents(self, node, file):
try:
# Convert to a list here or the RemoteCommandError may be returned during a call to the generator instead of
# immediately
return list(node.account.ssh_capture("cat " + file))
except RemoteCommandError:
return []