import logging import random import ssl import threading import time from abc import ABCMeta, abstractmethod from collections import defaultdict from typing import Any, Callable, Dict, Generic, List, Mapping, Optional, Set, Type, TypeVar, Union import orjson import pika import pika.adapters.tornado_connection import pika.connection import pika.exceptions from django.conf import settings from pika.adapters.blocking_connection import BlockingChannel from pika.channel import Channel from pika.spec import Basic from tornado import ioloop from zerver.lib.utils import assert_is_not_none MAX_REQUEST_RETRIES = 3 ChannelT = TypeVar("ChannelT", Channel, BlockingChannel) Consumer = Callable[[ChannelT, Basic.Deliver, pika.BasicProperties, bytes], None] # This simple queuing library doesn't expose much of the power of # RabbitMQ/Pika's queuing system; its purpose is to just provide an # interface for external files to put things into queues and take them # out from bots without having to import pika code all over our codebase. class QueueClient(Generic[ChannelT], metaclass=ABCMeta): def __init__( self, # Disable RabbitMQ heartbeats by default because BlockingConnection can't process them rabbitmq_heartbeat: Optional[int] = 0, prefetch: int = 0, ) -> None: self.log = logging.getLogger("zulip.queue") self.queues: Set[str] = set() self.channel: Optional[ChannelT] = None self.prefetch = prefetch self.consumers: Dict[str, Set[Consumer[ChannelT]]] = defaultdict(set) self.rabbitmq_heartbeat = rabbitmq_heartbeat self.is_consuming = False self._connect() @abstractmethod def _connect(self) -> None: raise NotImplementedError @abstractmethod def _reconnect(self) -> None: raise NotImplementedError def _get_parameters(self) -> pika.ConnectionParameters: credentials = pika.PlainCredentials( settings.RABBITMQ_USERNAME, assert_is_not_none(settings.RABBITMQ_PASSWORD) ) # With BlockingConnection, we are passed # self.rabbitmq_heartbeat=0, which asks to explicitly disable # the RabbitMQ heartbeat feature. This is correct since that # heartbeat doesn't make sense with BlockingConnection (we do # need it for TornadoConnection). # # Where we've disabled RabbitMQ's heartbeat, the only # keepalive on this connection is the TCP keepalive (defaults: # `/proc/sys/net/ipv4/tcp_keepalive_*`). On most Linux # systems, the default is to start sending keepalive packets # after TCP_KEEPIDLE (7200 seconds) of inactivity; after that # point, it send them every TCP_KEEPINTVL (typically 75s). # Some Kubernetes / Docker Swarm networks can kill "idle" TCP # connections after as little as ~15 minutes of inactivity. # To avoid this killing our RabbitMQ connections, we set # TCP_KEEPIDLE to something significantly below 15 minutes. tcp_options = None if self.rabbitmq_heartbeat == 0: tcp_options = dict(TCP_KEEPIDLE=60 * 5) ssl_options: Union[ Type[pika.ConnectionParameters._DEFAULT], pika.SSLOptions ] = pika.ConnectionParameters._DEFAULT if settings.RABBITMQ_USE_TLS: ssl_options = pika.SSLOptions(context=ssl.create_default_context()) return pika.ConnectionParameters( settings.RABBITMQ_HOST, port=settings.RABBITMQ_PORT, heartbeat=self.rabbitmq_heartbeat, tcp_options=tcp_options, ssl_options=ssl_options, credentials=credentials, ) def _generate_ctag(self, queue_name: str) -> str: return f"{queue_name}_{str(random.getrandbits(16))}" def _reconnect_consumer_callback(self, queue: str, consumer: Consumer[ChannelT]) -> None: self.log.info("Queue reconnecting saved consumer %r to queue %s", consumer, queue) self.ensure_queue( queue, lambda channel: channel.basic_consume( queue, consumer, consumer_tag=self._generate_ctag(queue), ), ) def _reconnect_consumer_callbacks(self) -> None: for queue, consumers in self.consumers.items(): for consumer in consumers: self._reconnect_consumer_callback(queue, consumer) def ready(self) -> bool: return self.channel is not None @abstractmethod def ensure_queue(self, queue_name: str, callback: Callable[[ChannelT], object]) -> None: raise NotImplementedError def publish(self, queue_name: str, body: bytes) -> None: def do_publish(channel: ChannelT) -> None: channel.basic_publish( exchange="", routing_key=queue_name, properties=pika.BasicProperties(delivery_mode=2), body=body, ) self.ensure_queue(queue_name, do_publish) def json_publish(self, queue_name: str, body: Mapping[str, Any]) -> None: data = orjson.dumps(body) try: self.publish(queue_name, data) return except pika.exceptions.AMQPConnectionError: self.log.warning("Failed to send to rabbitmq, trying to reconnect and send again") self._reconnect() self.publish(queue_name, data) class SimpleQueueClient(QueueClient[BlockingChannel]): connection: Optional[pika.BlockingConnection] def _connect(self) -> None: start = time.time() self.connection = pika.BlockingConnection(self._get_parameters()) self.channel = self.connection.channel() self.channel.basic_qos(prefetch_count=self.prefetch) self.log.info("SimpleQueueClient connected (connecting took %.3fs)", time.time() - start) def _reconnect(self) -> None: self.connection = None self.channel = None self.queues = set() self._connect() def close(self) -> None: if self.connection is not None: self.connection.close() def ensure_queue(self, queue_name: str, callback: Callable[[BlockingChannel], object]) -> None: """Ensure that a given queue has been declared, and then call the callback with no arguments.""" if self.connection is None or not self.connection.is_open: self._connect() assert self.channel is not None else: assert self.channel is not None if queue_name not in self.queues: self.channel.queue_declare(queue=queue_name, durable=True) self.queues.add(queue_name) callback(self.channel) def start_json_consumer( self, queue_name: str, callback: Callable[[List[Dict[str, Any]]], None], batch_size: int = 1, timeout: Optional[int] = None, ) -> None: if batch_size == 1: timeout = None def do_consume(channel: BlockingChannel) -> None: events: List[Dict[str, Any]] = [] last_process = time.time() max_processed: Optional[int] = None self.is_consuming = True # This iterator technique will iteratively collect up to # batch_size events from the RabbitMQ queue (if present) # before calling the callback with the batch. If not # enough events are present, it will sleep for at most # timeout seconds before calling the callback with the # batch of events it has. for method, properties, body in channel.consume(queue_name, inactivity_timeout=timeout): if body is not None: assert method is not None events.append(orjson.loads(body)) max_processed = method.delivery_tag now = time.time() if len(events) >= batch_size or (timeout and now >= last_process + timeout): if events: assert max_processed is not None try: callback(events) channel.basic_ack(max_processed, multiple=True) except BaseException: channel.basic_nack(max_processed, multiple=True) raise events = [] last_process = now if not self.is_consuming: break self.ensure_queue(queue_name, do_consume) def local_queue_size(self) -> int: assert self.channel is not None return self.channel.get_waiting_message_count() + len( self.channel._pending_events # type: ignore[attr-defined] # private member missing from stubs ) def stop_consuming(self) -> None: assert self.channel is not None assert self.is_consuming self.is_consuming = False self.channel.stop_consuming() # Patch pika.adapters.tornado_connection.TornadoConnection so that a socket error doesn't # throw an exception and disconnect the tornado process from the rabbitmq # queue. Instead, just re-connect as usual class ExceptionFreeTornadoConnection(pika.adapters.tornado_connection.TornadoConnection): def _adapter_disconnect(self) -> None: try: super()._adapter_disconnect() # type: ignore[misc] # private method missing from stubs except ( pika.exceptions.ProbableAuthenticationError, pika.exceptions.ProbableAccessDeniedError, pika.exceptions.IncompatibleProtocolError, ): logging.warning( "Caught exception in ExceptionFreeTornadoConnection when \ calling _adapter_disconnect, ignoring", exc_info=True, ) class TornadoQueueClient(QueueClient[Channel]): connection: Optional[ExceptionFreeTornadoConnection] # Based on: # https://pika.readthedocs.io/en/0.9.8/examples/asynchronous_consumer_example.html def __init__(self) -> None: super().__init__( # TornadoConnection can process heartbeats, so enable them. rabbitmq_heartbeat=None, # Only ask for 100 un-acknowledged messages at once from # the server, rather than an unbounded number. prefetch=100, ) self._on_open_cbs: List[Callable[[Channel], None]] = [] self._connection_failure_count = 0 def _connect(self) -> None: self.log.info("Beginning TornadoQueueClient connection") self.connection = ExceptionFreeTornadoConnection( self._get_parameters(), on_open_callback=self._on_open, on_open_error_callback=self._on_connection_open_error, on_close_callback=self._on_connection_closed, ) def _reconnect(self) -> None: self.connection = None self.channel = None self.queues = set() self.log.warning("TornadoQueueClient attempting to reconnect to RabbitMQ") self._connect() CONNECTION_RETRY_SECS = 2 # When the RabbitMQ server is restarted, it's normal for it to # take a few seconds to come back; we'll retry a few times and all # will be well. So for the first few failures, we report only at # "warning" level, avoiding an email to the server admin. # # A loss of an existing connection starts a retry loop just like a # failed connection attempt, so it counts as the first failure. # # On an unloaded test system, a RabbitMQ restart takes about 6s, # potentially causing 4 failures. We add some headroom above that. CONNECTION_FAILURES_BEFORE_NOTIFY = 10 def _on_connection_open_error( self, connection: pika.connection.Connection, reason: Union[str, Exception] ) -> None: self._connection_failure_count += 1 retry_secs = self.CONNECTION_RETRY_SECS self.log.log( logging.CRITICAL if self._connection_failure_count > self.CONNECTION_FAILURES_BEFORE_NOTIFY else logging.WARNING, "TornadoQueueClient couldn't connect to RabbitMQ, retrying in %d secs...", retry_secs, ) ioloop.IOLoop.current().call_later(retry_secs, self._reconnect) def _on_connection_closed( self, connection: pika.connection.Connection, reason: Exception ) -> None: if self.connection is None: return self._connection_failure_count = 1 retry_secs = self.CONNECTION_RETRY_SECS self.log.warning( "TornadoQueueClient lost connection to RabbitMQ, reconnecting in %d secs...", retry_secs, ) ioloop.IOLoop.current().call_later(retry_secs, self._reconnect) def _on_open(self, connection: pika.connection.Connection) -> None: assert self.connection is not None self._connection_failure_count = 0 try: self.connection.channel(on_open_callback=self._on_channel_open) except pika.exceptions.ConnectionClosed: # The connection didn't stay open long enough for this code to get to it. # Let _on_connection_closed deal with trying again. self.log.warning("TornadoQueueClient couldn't open channel: connection already closed") def _on_channel_open(self, channel: Channel) -> None: self.channel = channel for callback in self._on_open_cbs: callback(channel) self._reconnect_consumer_callbacks() self.log.info("TornadoQueueClient connected") def close(self) -> None: if self.connection is not None: self.connection.close() self.connection = None def ensure_queue(self, queue_name: str, callback: Callable[[Channel], object]) -> None: def set_qos(frame: Any) -> None: assert self.channel is not None self.queues.add(queue_name) self.channel.basic_qos(prefetch_count=self.prefetch, callback=finish) def finish(frame: Any) -> None: assert self.channel is not None callback(self.channel) if queue_name not in self.queues: # If we're not connected yet, send this message # once we have created the channel if not self.ready(): self._on_open_cbs.append(lambda channel: self.ensure_queue(queue_name, callback)) return assert self.channel is not None self.channel.queue_declare(queue=queue_name, durable=True, callback=set_qos) else: assert self.channel is not None callback(self.channel) def start_json_consumer( self, queue_name: str, callback: Callable[[List[Dict[str, Any]]], None], batch_size: int = 1, timeout: Optional[int] = None, ) -> None: def wrapped_consumer( ch: Channel, method: Basic.Deliver, properties: pika.BasicProperties, body: bytes, ) -> None: assert method.delivery_tag is not None callback([orjson.loads(body)]) ch.basic_ack(delivery_tag=method.delivery_tag) assert batch_size == 1 assert timeout is None self.consumers[queue_name].add(wrapped_consumer) if not self.ready(): return self.ensure_queue( queue_name, lambda channel: channel.basic_consume( queue_name, wrapped_consumer, consumer_tag=self._generate_ctag(queue_name), ), ) thread_data = threading.local() def get_queue_client() -> Union[SimpleQueueClient, TornadoQueueClient]: if not hasattr(thread_data, "queue_client"): if not settings.USING_RABBITMQ: raise RuntimeError("Cannot get a queue client without USING_RABBITMQ") thread_data.queue_client = SimpleQueueClient() return thread_data.queue_client def set_queue_client(queue_client: Union[SimpleQueueClient, TornadoQueueClient]) -> None: thread_data.queue_client = queue_client def queue_json_publish( queue_name: str, event: Dict[str, Any], processor: Optional[Callable[[Any], None]] = None, ) -> None: if settings.USING_RABBITMQ: get_queue_client().json_publish(queue_name, event) elif processor: processor(event) else: # Must be imported here: A top section import leads to circular imports from zerver.worker.queue_processors import get_worker get_worker(queue_name).consume_single_event(event) def retry_event( queue_name: str, event: Dict[str, Any], failure_processor: Callable[[Dict[str, Any]], None] ) -> None: if "failed_tries" not in event: event["failed_tries"] = 0 event["failed_tries"] += 1 if event["failed_tries"] > MAX_REQUEST_RETRIES: failure_processor(event) else: queue_json_publish(queue_name, event)