private JobGraph createTestJobGraph(
String jobName, int senderParallelism, int receiverParallelism) {
// The sender and receiver invokable logic ensure that each subtask gets the expected data
final JobVertex sender = new JobVertex("Sender");
sender.setInvokableClass(RoundRobinSubtaskIndexSender.class);
sender
.getConfiguration()
.setInteger(RoundRobinSubtaskIndexSender.CONFIG_KEY, receiverParallelism);
sender.setParallelism(senderParallelism);
final JobVertex receiver = new JobVertex("Receiver");
receiver.setInvokableClass(SubtaskIndexReceiver.class);
receiver.getConfiguration().setInteger(SubtaskIndexReceiver.CONFIG_KEY, senderParallelism);
receiver.setParallelism(receiverParallelism);
receiver.connectNewDataSetAsInput(
sender, DistributionPattern.ALL_TO_ALL, ResultPartitionType.BLOCKING);
final JobGraph jobGraph = new JobGraph(jobName, sender, receiver);
// We need to allow queued scheduling, because there are not enough slots available
// to run all tasks at once. We queue tasks and then let them finish/consume the blocking
// result one after the other.
jobGraph.setAllowQueuedScheduling(true);
return jobGraph;
}
private Map<ExecutionAttemptID, Execution> setupExecution(
JobVertex v1, int dop1, JobVertex v2, int dop2) throws Exception {
final JobID jobId = new JobID();
v1.setParallelism(dop1);
v2.setParallelism(dop2);
v1.setInvokableClass(BatchTask.class);
v2.setInvokableClass(BatchTask.class);
// execution graph that executes actions synchronously
ExecutionGraph eg =
new ExecutionGraph(
TestingUtils.directExecutionContext(),
jobId,
"some job",
new Configuration(),
new SerializedValue<>(new ExecutionConfig()),
AkkaUtils.getDefaultTimeout(),
new NoRestartStrategy());
eg.setQueuedSchedulingAllowed(false);
List<JobVertex> ordered = Arrays.asList(v1, v2);
eg.attachJobGraph(ordered);
Scheduler scheduler = new Scheduler(TestingUtils.defaultExecutionContext());
for (int i = 0; i < dop1 + dop2; i++) {
scheduler.newInstanceAvailable(
ExecutionGraphTestUtils.getInstance(
new ExecutionGraphTestUtils.SimpleActorGateway(
TestingUtils.directExecutionContext())));
}
assertEquals(dop1 + dop2, scheduler.getNumberOfAvailableSlots());
// schedule, this triggers mock deployment
eg.scheduleForExecution(scheduler);
Map<ExecutionAttemptID, Execution> executions = eg.getRegisteredExecutions();
assertEquals(dop1 + dop2, executions.size());
return executions;
}
public JobGraph createBlockingJob(int parallelism) {
Tasks.BlockingOnceReceiver$.MODULE$.blocking_$eq(true);
JobVertex sender = new JobVertex("sender");
JobVertex receiver = new JobVertex("receiver");
sender.setInvokableClass(Tasks.Sender.class);
receiver.setInvokableClass(Tasks.BlockingOnceReceiver.class);
sender.setParallelism(parallelism);
receiver.setParallelism(parallelism);
receiver.connectNewDataSetAsInput(sender, DistributionPattern.POINTWISE);
SlotSharingGroup slotSharingGroup = new SlotSharingGroup();
sender.setSlotSharingGroup(slotSharingGroup);
receiver.setSlotSharingGroup(slotSharingGroup);
return new JobGraph("Blocking test job", sender, receiver);
}
@Test
public void testBuildDeploymentDescriptor() {
try {
final JobID jobId = new JobID();
final JobVertexID jid1 = new JobVertexID();
final JobVertexID jid2 = new JobVertexID();
final JobVertexID jid3 = new JobVertexID();
final JobVertexID jid4 = new JobVertexID();
JobVertex v1 = new JobVertex("v1", jid1);
JobVertex v2 = new JobVertex("v2", jid2);
JobVertex v3 = new JobVertex("v3", jid3);
JobVertex v4 = new JobVertex("v4", jid4);
v1.setParallelism(10);
v2.setParallelism(10);
v3.setParallelism(10);
v4.setParallelism(10);
v1.setInvokableClass(BatchTask.class);
v2.setInvokableClass(BatchTask.class);
v3.setInvokableClass(BatchTask.class);
v4.setInvokableClass(BatchTask.class);
v2.connectNewDataSetAsInput(v1, DistributionPattern.ALL_TO_ALL);
v3.connectNewDataSetAsInput(v2, DistributionPattern.ALL_TO_ALL);
v4.connectNewDataSetAsInput(v2, DistributionPattern.ALL_TO_ALL);
ExecutionGraph eg =
new ExecutionGraph(
TestingUtils.defaultExecutionContext(),
jobId,
"some job",
new Configuration(),
new SerializedValue<>(new ExecutionConfig()),
AkkaUtils.getDefaultTimeout(),
new NoRestartStrategy());
List<JobVertex> ordered = Arrays.asList(v1, v2, v3, v4);
eg.attachJobGraph(ordered);
ExecutionJobVertex ejv = eg.getAllVertices().get(jid2);
ExecutionVertex vertex = ejv.getTaskVertices()[3];
ExecutionGraphTestUtils.SimpleActorGateway instanceGateway =
new ExecutionGraphTestUtils.SimpleActorGateway(TestingUtils.directExecutionContext());
final Instance instance = getInstance(instanceGateway);
final SimpleSlot slot = instance.allocateSimpleSlot(jobId);
assertEquals(ExecutionState.CREATED, vertex.getExecutionState());
vertex.deployToSlot(slot);
assertEquals(ExecutionState.DEPLOYING, vertex.getExecutionState());
TaskDeploymentDescriptor descr = instanceGateway.lastTDD;
assertNotNull(descr);
assertEquals(jobId, descr.getJobID());
assertEquals(jid2, descr.getVertexID());
assertEquals(3, descr.getIndexInSubtaskGroup());
assertEquals(10, descr.getNumberOfSubtasks());
assertEquals(BatchTask.class.getName(), descr.getInvokableClassName());
assertEquals("v2", descr.getTaskName());
List<ResultPartitionDeploymentDescriptor> producedPartitions = descr.getProducedPartitions();
List<InputGateDeploymentDescriptor> consumedPartitions = descr.getInputGates();
assertEquals(2, producedPartitions.size());
assertEquals(1, consumedPartitions.size());
assertEquals(10, producedPartitions.get(0).getNumberOfSubpartitions());
assertEquals(10, producedPartitions.get(1).getNumberOfSubpartitions());
assertEquals(10, consumedPartitions.get(0).getInputChannelDeploymentDescriptors().length);
} catch (Exception e) {
e.printStackTrace();
fail(e.getMessage());
}
}
@Test
/**
* Tests that a blocking batch job fails if there are not enough resources left to schedule the
* succeeding tasks. This test case is related to [FLINK-4296] where finished producing tasks
* swallow the fail exception when scheduling a consumer task.
*/
public void testNoResourceAvailableFailure() throws Exception {
final JobID jobId = new JobID();
JobVertex v1 = new JobVertex("source");
JobVertex v2 = new JobVertex("sink");
int dop1 = 1;
int dop2 = 1;
v1.setParallelism(dop1);
v2.setParallelism(dop2);
v1.setInvokableClass(BatchTask.class);
v2.setInvokableClass(BatchTask.class);
v2.connectNewDataSetAsInput(
v1, DistributionPattern.POINTWISE, ResultPartitionType.BLOCKING, false);
// execution graph that executes actions synchronously
ExecutionGraph eg =
new ExecutionGraph(
TestingUtils.directExecutionContext(),
jobId,
"failing test job",
new Configuration(),
new SerializedValue<>(new ExecutionConfig()),
AkkaUtils.getDefaultTimeout(),
new NoRestartStrategy());
eg.setQueuedSchedulingAllowed(false);
List<JobVertex> ordered = Arrays.asList(v1, v2);
eg.attachJobGraph(ordered);
Scheduler scheduler = new Scheduler(TestingUtils.directExecutionContext());
for (int i = 0; i < dop1; i++) {
scheduler.newInstanceAvailable(
ExecutionGraphTestUtils.getInstance(
new ExecutionGraphTestUtils.SimpleActorGateway(
TestingUtils.directExecutionContext())));
}
assertEquals(dop1, scheduler.getNumberOfAvailableSlots());
// schedule, this triggers mock deployment
eg.scheduleForExecution(scheduler);
ExecutionAttemptID attemptID =
eg.getJobVertex(v1.getID())
.getTaskVertices()[0]
.getCurrentExecutionAttempt()
.getAttemptId();
eg.updateState(new TaskExecutionState(jobId, attemptID, ExecutionState.RUNNING));
eg.updateState(
new TaskExecutionState(
jobId,
attemptID,
ExecutionState.FINISHED,
null,
new AccumulatorSnapshot(
jobId,
attemptID,
new HashMap<AccumulatorRegistry.Metric, Accumulator<?, ?>>(),
new HashMap<String, Accumulator<?, ?>>())));
assertEquals(JobStatus.FAILED, eg.getState());
}
/*
* Test setup:
* - v1 is isolated, no slot sharing
* - v2 and v3 (not connected) share slots
* - v4 and v5 (connected) share slots
*/
@Test
public void testAssignSlotSharingGroup() {
try {
JobVertex v1 = new JobVertex("v1");
JobVertex v2 = new JobVertex("v2");
JobVertex v3 = new JobVertex("v3");
JobVertex v4 = new JobVertex("v4");
JobVertex v5 = new JobVertex("v5");
v1.setParallelism(4);
v2.setParallelism(5);
v3.setParallelism(7);
v4.setParallelism(1);
v5.setParallelism(11);
v2.connectNewDataSetAsInput(v1, DistributionPattern.POINTWISE);
v5.connectNewDataSetAsInput(v4, DistributionPattern.POINTWISE);
SlotSharingGroup jg1 = new SlotSharingGroup();
v2.setSlotSharingGroup(jg1);
v3.setSlotSharingGroup(jg1);
SlotSharingGroup jg2 = new SlotSharingGroup();
v4.setSlotSharingGroup(jg2);
v5.setSlotSharingGroup(jg2);
List<JobVertex> vertices = new ArrayList<JobVertex>(Arrays.asList(v1, v2, v3, v4, v5));
ExecutionGraph eg =
new ExecutionGraph(
TestingUtils.defaultExecutionContext(),
new JobID(),
"test job",
new Configuration(),
ExecutionConfigTest.getSerializedConfig(),
AkkaUtils.getDefaultTimeout(),
new NoRestartStrategy());
eg.attachJobGraph(vertices);
// verify that the vertices are all in the same slot sharing group
SlotSharingGroup group1 = null;
SlotSharingGroup group2 = null;
// verify that v1 tasks have no slot sharing group
assertNull(eg.getJobVertex(v1.getID()).getSlotSharingGroup());
// v2 and v3 are shared
group1 = eg.getJobVertex(v2.getID()).getSlotSharingGroup();
assertNotNull(group1);
assertEquals(group1, eg.getJobVertex(v3.getID()).getSlotSharingGroup());
assertEquals(2, group1.getJobVertexIds().size());
assertTrue(group1.getJobVertexIds().contains(v2.getID()));
assertTrue(group1.getJobVertexIds().contains(v3.getID()));
// v4 and v5 are shared
group2 = eg.getJobVertex(v4.getID()).getSlotSharingGroup();
assertNotNull(group2);
assertEquals(group2, eg.getJobVertex(v5.getID()).getSlotSharingGroup());
assertEquals(2, group1.getJobVertexIds().size());
assertTrue(group2.getJobVertexIds().contains(v4.getID()));
assertTrue(group2.getJobVertexIds().contains(v5.getID()));
} catch (Exception e) {
e.printStackTrace();
fail(e.getMessage());
}
}
