def start_objstore(node_ip_address, redis_address, object_manager_port=None, cleanup=True, redirect_output=False, objstore_memory=None): """This method starts an object store process. Args: node_ip_address (str): The IP address of the node running the object store. redis_address (str): The address of the Redis instance to connect to. object_manager_port (int): The port to use for the object manager. If this is not provided, one will be generated randomly. cleanup (bool): True if using Ray in local mode. If cleanup is true, then this process will be killed by serices.cleanup() when the Python process that imported services exits. redirect_output (bool): True if stdout and stderr should be redirected to /dev/null. Return: A tuple of the Plasma store socket name, the Plasma manager socket name, and the plasma manager port. """ if objstore_memory is None: # Compute a fraction of the system memory for the Plasma store to use. system_memory = psutil.virtual_memory().total if sys.platform == "linux" or sys.platform == "linux2": # On linux we use /dev/shm, its size is half the size of the physical # memory. To not overflow it, we set the plasma memory limit to 0.4 times # the size of the physical memory. objstore_memory = int(system_memory * 0.4) # Compare the requested memory size to the memory available in /dev/shm. shm_fd = os.open("/dev/shm", os.O_RDONLY) try: shm_fs_stats = os.fstatvfs(shm_fd) # The value shm_fs_stats.f_bsize is the block size and the value # shm_fs_stats.f_bavail is the number of available blocks. shm_avail = shm_fs_stats.f_bsize * shm_fs_stats.f_bavail if objstore_memory > shm_avail: print("Warning: Reducing object store memory because /dev/shm has only {} bytes available. You may be able to free up space by deleting files in /dev/shm. If you are inside a Docker container, you may need to pass an argument with the flag '--shm-size' to 'docker run'.".format(shm_avail)) objstore_memory = int(shm_avail * 0.8) finally: os.close(shm_fd) else: objstore_memory = int(system_memory * 0.8) # Start the Plasma store. plasma_store_name, p1 = plasma.start_plasma_store(plasma_store_memory=objstore_memory, use_profiler=RUN_PLASMA_STORE_PROFILER, redirect_output=redirect_output) # Start the plasma manager. if object_manager_port is not None: plasma_manager_name, p2, plasma_manager_port = plasma.start_plasma_manager(plasma_store_name, redis_address, plasma_manager_port=object_manager_port, node_ip_address=node_ip_address, num_retries=1, run_profiler=RUN_PLASMA_MANAGER_PROFILER, redirect_output=redirect_output) assert plasma_manager_port == object_manager_port else: plasma_manager_name, p2, plasma_manager_port = plasma.start_plasma_manager(plasma_store_name, redis_address, node_ip_address=node_ip_address, run_profiler=RUN_PLASMA_MANAGER_PROFILER, redirect_output=redirect_output) if cleanup: all_processes[PROCESS_TYPE_PLASMA_STORE].append(p1) all_processes[PROCESS_TYPE_PLASMA_MANAGER].append(p2) return ObjectStoreAddress(plasma_store_name, plasma_manager_name, plasma_manager_port)
def test_delayed_start(self): num_objects = 10 # Create some objects using one client. object_ids = [random_object_id() for _ in range(num_objects)] for i in range(10): create_object_with_id(self.client, object_ids[i], 2000, 2000) # Wait until the objects have been sealed in the store. ready, waiting = self.client.wait(object_ids, num_returns=num_objects) self.assertEqual(set(ready), set(object_ids)) self.assertEqual(waiting, []) # Start a second plasma manager attached to the same store. manager_name, self.p5, self.port2 = plasma.start_plasma_manager(self.store_name, self.redis_address, use_valgrind=USE_VALGRIND) self.processes_to_kill.append(self.p5) # Check that the second manager knows about existing objects. client2 = plasma.PlasmaClient(self.store_name, manager_name) ready, waiting = [], object_ids while True: ready, waiting = client2.wait(object_ids, num_returns=num_objects, timeout=0) if len(ready) == len(object_ids): break self.assertEqual(set(ready), set(object_ids)) self.assertEqual(waiting, [])
def start_objstore(node_ip_address, redis_address, cleanup=True): """This method starts an object store process. Args: node_ip_address (str): The ip address of the node running the object store. redis_address (str): The address of the Redis instance to connect to. cleanup (bool): True if using Ray in local mode. If cleanup is true, then this process will be killed by serices.cleanup() when the Python process that imported services exits. Return: A tuple of the Plasma store socket name, the Plasma manager socket name, and the plasma manager port. """ # Compute a fraction of the system memory for the Plasma store to use. system_memory = psutil.virtual_memory().total plasma_store_memory = int(system_memory * 0.75) # Start the Plasma store. plasma_store_name, p1 = plasma.start_plasma_store( plasma_store_memory=plasma_store_memory, use_profiler=RUN_PLASMA_STORE_PROFILER) # Start the plasma manager. plasma_manager_name, p2, plasma_manager_port = plasma.start_plasma_manager( plasma_store_name, redis_address, run_profiler=RUN_PLASMA_MANAGER_PROFILER) if cleanup: all_processes.append(p1) all_processes.append(p2) return plasma_store_name, plasma_manager_name, plasma_manager_port
def setUp(self): # Start two PlasmaStores. store_name1, self.p2 = plasma.start_plasma_store(use_valgrind=USE_VALGRIND) store_name2, self.p3 = plasma.start_plasma_store(use_valgrind=USE_VALGRIND) # Start a Redis server. redis_address = services.start_redis("127.0.0.1") # Start two PlasmaManagers. manager_name1, self.p4, self.port1 = plasma.start_plasma_manager(store_name1, redis_address, use_valgrind=USE_VALGRIND) manager_name2, self.p5, self.port2 = plasma.start_plasma_manager(store_name2, redis_address, use_valgrind=USE_VALGRIND) # Connect two PlasmaClients. self.client1 = plasma.PlasmaClient(store_name1, manager_name1) self.client2 = plasma.PlasmaClient(store_name2, manager_name2) # Store the processes that will be explicitly killed during tearDown so # that a test case can remove ones that will be killed during the test. # NOTE: If this specific order is changed, valgrind will fail. self.processes_to_kill = [self.p4, self.p5, self.p2, self.p3]
def setUp(self): # Start one Redis server and N pairs of (plasma, photon) redis_path = os.path.join( os.path.abspath(os.path.dirname(__file__)), "../../core/src/common/thirdparty/redis/src/redis-server") redis_module = os.path.join( os.path.dirname(os.path.abspath(__file__)), "../../core/src/common/redis_module/libray_redis_module.so") assert os.path.isfile(redis_path) assert os.path.isfile(redis_module) node_ip_address = "127.0.0.1" redis_port = new_port() redis_address = "{}:{}".format(node_ip_address, redis_port) self.redis_process = subprocess.Popen([ redis_path, "--port", str(redis_port), "--loglevel", "warning", "--loadmodule", redis_module ]) time.sleep(0.1) # Create a Redis client. self.redis_client = redis.StrictRedis(host=node_ip_address, port=redis_port) # Start one global scheduler. self.p1 = global_scheduler.start_global_scheduler( redis_address, use_valgrind=USE_VALGRIND) self.plasma_store_pids = [] self.plasma_manager_pids = [] self.local_scheduler_pids = [] self.plasma_clients = [] self.photon_clients = [] for i in range(NUM_CLUSTER_NODES): # Start the Plasma store. Plasma store name is randomly generated. plasma_store_name, p2 = plasma.start_plasma_store() self.plasma_store_pids.append(p2) # Start the Plasma manager. # Assumption: Plasma manager name and port are randomly generated by the plasma module. plasma_manager_name, p3, plasma_manager_port = plasma.start_plasma_manager( plasma_store_name, redis_address) self.plasma_manager_pids.append(p3) plasma_address = "{}:{}".format(node_ip_address, plasma_manager_port) plasma_client = plasma.PlasmaClient(plasma_store_name, plasma_manager_name) self.plasma_clients.append(plasma_client) # Start the local scheduler. local_scheduler_name, p4 = photon.start_local_scheduler( plasma_store_name, plasma_manager_name=plasma_manager_name, plasma_address=plasma_address, redis_address=redis_address, static_resource_list=[10, 0]) # Connect to the scheduler. photon_client = photon.PhotonClient(local_scheduler_name, NIL_ACTOR_ID) self.photon_clients.append(photon_client) self.local_scheduler_pids.append(p4)
def setUp(self): # Start two PlasmaStores. store_name1, self.p2 = plasma.start_plasma_store(use_valgrind=USE_VALGRIND) store_name2, self.p3 = plasma.start_plasma_store(use_valgrind=USE_VALGRIND) # Start a Redis server. redis_path = os.path.join(os.path.abspath(os.path.dirname(__file__)), "../../common/thirdparty/redis/src/redis-server") redis_port = 6379 with open(os.devnull, "w") as FNULL: self.redis_process = subprocess.Popen([redis_path, "--port", str(redis_port)], stdout=FNULL) time.sleep(0.1) # Start two PlasmaManagers. redis_address = "{}:{}".format("127.0.0.1", redis_port) manager_name1, self.p4, self.port1 = plasma.start_plasma_manager(store_name1, redis_address, use_valgrind=USE_VALGRIND) manager_name2, self.p5, self.port2 = plasma.start_plasma_manager(store_name2, redis_address, use_valgrind=USE_VALGRIND) # Connect two PlasmaClients. self.client1 = plasma.PlasmaClient(store_name1, manager_name1) self.client2 = plasma.PlasmaClient(store_name2, manager_name2)
def setUp(self): # Start a Plasma store. self.store_name, self.p2 = plasma.start_plasma_store(use_valgrind=USE_VALGRIND) # Start a Redis server. self.redis_address = services.start_redis("127.0.0.1") # Start a PlasmaManagers. manager_name, self.p3, self.port1 = plasma.start_plasma_manager( self.store_name, self.redis_address, use_valgrind=USE_VALGRIND) # Connect a PlasmaClient. self.client = plasma.PlasmaClient(self.store_name, manager_name) # Store the processes that will be explicitly killed during tearDown so # that a test case can remove ones that will be killed during the test. self.processes_to_kill = [self.p2, self.p3]