ray/python/ray/tests/test_component_failures_2.py

import json
import os
import signal
import sys
import time

import pytest

import ray
import ray.ray_constants as ray_constants
from ray.cluster_utils import Cluster
from ray.test_utils import RayTestTimeoutException


@pytest.fixture(params=[(1, 4), (4, 4)])
def ray_start_workers_separate_multinode(request):
    num_nodes = request.param[0]
    num_initial_workers = request.param[1]
    # Start the Ray processes.
    cluster = Cluster()
    for _ in range(num_nodes):
        cluster.add_node(num_cpus=num_initial_workers)
    ray.init(address=cluster.address)

    yield num_nodes, num_initial_workers
    # The code after the yield will run as teardown code.
    ray.shutdown()
    cluster.shutdown()


def test_worker_failed(ray_start_workers_separate_multinode):
    num_nodes, num_initial_workers = (ray_start_workers_separate_multinode)

    @ray.remote
    def get_pids():
        time.sleep(0.25)
        return os.getpid()

    start_time = time.time()
    pids = set()
    while len(pids) < num_nodes * num_initial_workers:
        new_pids = ray.get([
            get_pids.remote()
            for _ in range(2 * num_nodes * num_initial_workers)
        ])
        for pid in new_pids:
            pids.add(pid)
        if time.time() - start_time > 60:
            raise RayTestTimeoutException(
                "Timed out while waiting to get worker PIDs.")

    @ray.remote
    def f(x):
        time.sleep(0.5)
        return x

    # Submit more tasks than there are workers so that all workers and
    # cores are utilized.
    object_ids = [f.remote(i) for i in range(num_initial_workers * num_nodes)]
    object_ids += [f.remote(object_id) for object_id in object_ids]
    # Allow the tasks some time to begin executing.
    time.sleep(0.1)
    # Kill the workers as the tasks execute.
    for pid in pids:
        os.kill(pid, signal.SIGKILL)
        time.sleep(0.1)
    # Make sure that we either get the object or we get an appropriate
    # exception.
    for object_id in object_ids:
        try:
            ray.get(object_id)
        except (ray.exceptions.RayTaskError, ray.exceptions.RayWorkerError):
            pass


def _test_component_failed(cluster, component_type):
    """Kill a component on all worker nodes and check workload succeeds."""
    # Submit many tasks with many dependencies.
    @ray.remote
    def f(x):
        return x

    @ray.remote
    def g(*xs):
        return 1

    # Kill the component on all nodes except the head node as the tasks
    # execute. Do this in a loop while submitting tasks between each
    # component failure.
    time.sleep(0.1)
    worker_nodes = cluster.list_all_nodes()[1:]
    assert len(worker_nodes) > 0
    for node in worker_nodes:
        process = node.all_processes[component_type][0].process
        # Submit a round of tasks with many dependencies.
        x = 1
        for _ in range(1000):
            x = f.remote(x)

        xs = [g.remote(1)]
        for _ in range(100):
            xs.append(g.remote(*xs))
            xs.append(g.remote(1))

        # Kill a component on one of the nodes.
        process.terminate()
        time.sleep(1)
        process.kill()
        process.wait()
        assert not process.poll() is None

        # Make sure that we can still get the objects after the
        # executing tasks died.
        ray.get(x)
        ray.get(xs)


def check_components_alive(cluster, component_type, check_component_alive):
    """Check that a given component type is alive on all worker nodes."""
    worker_nodes = cluster.list_all_nodes()[1:]
    assert len(worker_nodes) > 0
    for node in worker_nodes:
        process = node.all_processes[component_type][0].process
        if check_component_alive:
            assert process.poll() is None
        else:
            print("waiting for " + component_type + " with PID " +
                  str(process.pid) + "to terminate")
            process.wait()
            print("done waiting for " + component_type + " with PID " +
                  str(process.pid) + "to terminate")
            assert not process.poll() is None


@pytest.mark.parametrize(
    "ray_start_cluster", [{
        "num_cpus": 8,
        "num_nodes": 4,
        "_internal_config": json.dumps({
            "num_heartbeats_timeout": 100
        }),
    }],
    indirect=True)
def test_raylet_failed(ray_start_cluster):
    cluster = ray_start_cluster
    # Kill all raylets on worker nodes.
    _test_component_failed(cluster, ray_constants.PROCESS_TYPE_RAYLET)

    # The plasma stores should still be alive on the worker nodes.
    check_components_alive(cluster, ray_constants.PROCESS_TYPE_PLASMA_STORE,
                           True)


@pytest.mark.skipif(
    os.environ.get("RAY_USE_NEW_GCS") == "on",
    reason="Hanging with new GCS API.")
@pytest.mark.parametrize(
    "ray_start_cluster", [{
        "num_cpus": 8,
        "num_nodes": 2,
        "_internal_config": json.dumps({
            "num_heartbeats_timeout": 100
        }),
    }],
    indirect=True)
def test_plasma_store_failed(ray_start_cluster):
    cluster = ray_start_cluster
    # Kill all plasma stores on worker nodes.
    _test_component_failed(cluster, ray_constants.PROCESS_TYPE_PLASMA_STORE)

    # No processes should be left alive on the worker nodes.
    check_components_alive(cluster, ray_constants.PROCESS_TYPE_PLASMA_STORE,
                           False)
    check_components_alive(cluster, ray_constants.PROCESS_TYPE_RAYLET, False)


if __name__ == "__main__":
    import pytest
    sys.exit(pytest.main(["-v", __file__]))