zulip/zerver/worker/queue_processors.py

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# Documented in https://zulip.readthedocs.io/en/latest/subsystems/queuing.html
import base64
import copy
import email
import email.policy
import logging
import os
import signal
import socket
import tempfile
import threading
import time
from abc import ABC, abstractmethod
from collections import defaultdict, deque
from datetime import timedelta
from email.message import EmailMessage
from functools import wraps
from types import FrameType
from typing import (
Any,
Callable,
Dict,
List,
Mapping,
MutableSequence,
Optional,
Sequence,
Set,
Tuple,
Type,
TypeVar,
)
from urllib.parse import urlsplit
import orjson
import sentry_sdk
from django.conf import settings
from django.core.mail.backends.base import BaseEmailBackend
from django.db import connection, transaction
from django.db.models import F
from django.db.utils import IntegrityError
from django.utils.timezone import now as timezone_now
from django.utils.translation import gettext as _
from django.utils.translation import override as override_language
from psycopg2.sql import SQL, Literal
from returns.curry import partial
from sentry_sdk import add_breadcrumb, configure_scope
from typing_extensions import override
from zulip_bots.lib import extract_query_without_mention
from zerver.actions.invites import do_send_confirmation_email
from zerver.actions.message_edit import do_update_embedded_data
from zerver.actions.message_flags import do_mark_stream_messages_as_read
from zerver.actions.message_send import internal_send_private_message, render_incoming_message
from zerver.actions.presence import do_update_user_presence
from zerver.actions.realm_export import notify_realm_export
from zerver.actions.user_activity import do_update_user_activity_interval
from zerver.context_processors import common_context
from zerver.lib.bot_lib import EmbeddedBotHandler, EmbeddedBotQuitError, get_bot_handler
from zerver.lib.context_managers import lockfile
from zerver.lib.db import reset_queries
from zerver.lib.digest import bulk_handle_digest_email
from zerver.lib.email_mirror import (
decode_stream_email_address,
is_missed_message_address,
rate_limit_mirror_by_realm,
)
from zerver.lib.email_mirror import process_message as mirror_email
from zerver.lib.email_notifications import MissedMessageData, handle_missedmessage_emails
from zerver.lib.exceptions import RateLimitedError
from zerver.lib.export import export_realm_wrapper
from zerver.lib.outgoing_webhook import do_rest_call, get_outgoing_webhook_service_handler
per-request caches: Add per_request_cache library. We have historically cached two types of values on a per-request basis inside of memory: * linkifiers * display recipients Both of these caches were hand-written, and they both actually cache values that are also in memcached, so the per-request cache essentially only saves us from a few memcached hits. I think the linkifier per-request cache is a necessary evil. It's an important part of message rendering, and it's not super easy to structure the code to just get a single value up front and pass it down the stack. I'm not so sure we even need the display recipient per-request cache any more, as we are generally pretty smart now about hydrating recipient data in terms of how the code is organized. But I haven't done thorough research on that hypotheseis. Fortunately, it's not rocket science to just write a glorified memoize decorator and tie it into key places in the code: * middleware * tests (e.g. asserting db counts) * queue processors That's what I did in this commit. This commit definitely reduces the amount of code to maintain. I think it also gets us closer to possibly phasing out this whole technique, but that effort is beyond the scope of this PR. We could add some instrumentation to the decorator to see how often we get a non-trivial number of saved round trips to memcached. Note that when we flush linkifiers, we just use a big hammer and flush the entire per-request cache for linkifiers, since there is only ever one realm in the cache.
2023-07-14 19:46:50 +02:00
from zerver.lib.per_request_cache import flush_per_request_caches
from zerver.lib.push_notifications import (
clear_push_device_tokens,
handle_push_notification,
handle_remove_push_notification,
initialize_push_notifications,
)
from zerver.lib.pysa import mark_sanitized
from zerver.lib.queue import SimpleQueueClient, retry_event
from zerver.lib.remote_server import (
PushNotificationBouncerRetryLaterError,
send_server_data_to_push_bouncer,
)
from zerver.lib.send_email import (
EmailNotDeliveredError,
FromAddress,
handle_send_email_format_changes,
initialize_connection,
send_email,
send_future_email,
)
from zerver.lib.soft_deactivation import reactivate_user_if_soft_deactivated
from zerver.lib.timestamp import timestamp_to_datetime
from zerver.lib.upload import handle_reupload_emojis_event
from zerver.lib.url_preview import preview as url_preview
from zerver.lib.url_preview.types import UrlEmbedData
from zerver.models import (
Message,
PreregistrationUser,
Realm,
RealmAuditLog,
ScheduledMessageNotificationEmail,
Stream,
UserMessage,
UserProfile,
)
from zerver.models.bots import get_bot_services
from zerver.models.clients import get_client
from zerver.models.prereg_users import filter_to_valid_prereg_users
from zerver.models.users import get_system_bot, get_user_profile_by_id
logger = logging.getLogger(__name__)
class WorkerTimeoutError(Exception):
def __init__(self, queue_name: str, limit: int, event_count: int) -> None:
self.queue_name = queue_name
self.limit = limit
self.event_count = event_count
@override
def __str__(self) -> str:
return f"Timed out in {self.queue_name} after {self.limit * self.event_count} seconds processing {self.event_count} events"
class InterruptConsumeError(Exception):
"""
This exception is to be thrown inside event consume function
if the intention is to simply interrupt the processing
of the current event and normally continue the work of the queue.
"""
class WorkerDeclarationError(Exception):
pass
ConcreteQueueWorker = TypeVar("ConcreteQueueWorker", bound="QueueProcessingWorker")
def assign_queue(
queue_name: str,
enabled: bool = True,
is_test_queue: bool = False,
) -> Callable[[Type[ConcreteQueueWorker]], Type[ConcreteQueueWorker]]:
def decorate(clazz: Type[ConcreteQueueWorker]) -> Type[ConcreteQueueWorker]:
clazz.queue_name = queue_name
if enabled:
register_worker(queue_name, clazz, is_test_queue)
return clazz
return decorate
python: Convert assignment type annotations to Python 3.6 style. This commit was split by tabbott; this piece covers the vast majority of files in Zulip, but excludes scripts/, tools/, and puppet/ to help ensure we at least show the right error messages for Xenial systems. We can likely further refine the remaining pieces with some testing. Generated by com2ann, with whitespace fixes and various manual fixes for runtime issues: - invoiced_through: Optional[LicenseLedger] = models.ForeignKey( + invoiced_through: Optional["LicenseLedger"] = models.ForeignKey( -_apns_client: Optional[APNsClient] = None +_apns_client: Optional["APNsClient"] = None - notifications_stream: Optional[Stream] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) - signup_notifications_stream: Optional[Stream] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) + notifications_stream: Optional["Stream"] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) + signup_notifications_stream: Optional["Stream"] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) - author: Optional[UserProfile] = models.ForeignKey('UserProfile', blank=True, null=True, on_delete=CASCADE) + author: Optional["UserProfile"] = models.ForeignKey('UserProfile', blank=True, null=True, on_delete=CASCADE) - bot_owner: Optional[UserProfile] = models.ForeignKey('self', null=True, on_delete=models.SET_NULL) + bot_owner: Optional["UserProfile"] = models.ForeignKey('self', null=True, on_delete=models.SET_NULL) - default_sending_stream: Optional[Stream] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) - default_events_register_stream: Optional[Stream] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) + default_sending_stream: Optional["Stream"] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) + default_events_register_stream: Optional["Stream"] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) -descriptors_by_handler_id: Dict[int, ClientDescriptor] = {} +descriptors_by_handler_id: Dict[int, "ClientDescriptor"] = {} -worker_classes: Dict[str, Type[QueueProcessingWorker]] = {} -queues: Dict[str, Dict[str, Type[QueueProcessingWorker]]] = {} +worker_classes: Dict[str, Type["QueueProcessingWorker"]] = {} +queues: Dict[str, Dict[str, Type["QueueProcessingWorker"]]] = {} -AUTH_LDAP_REVERSE_EMAIL_SEARCH: Optional[LDAPSearch] = None +AUTH_LDAP_REVERSE_EMAIL_SEARCH: Optional["LDAPSearch"] = None Signed-off-by: Anders Kaseorg <anders@zulipchat.com>
2020-04-22 01:09:50 +02:00
worker_classes: Dict[str, Type["QueueProcessingWorker"]] = {}
test_queues: Set[str] = set()
def register_worker(
queue_name: str, clazz: Type["QueueProcessingWorker"], is_test_queue: bool = False
) -> None:
worker_classes[queue_name] = clazz
if is_test_queue:
test_queues.add(queue_name)
def get_worker(
queue_name: str, threaded: bool = False, disable_timeout: bool = False
) -> "QueueProcessingWorker":
return worker_classes[queue_name](threaded=threaded, disable_timeout=disable_timeout)
def get_active_worker_queues(only_test_queues: bool = False) -> List[str]:
"""Returns all (either test, or real) worker queues."""
return [
queue_name
for queue_name in worker_classes
if bool(queue_name in test_queues) == only_test_queues
]
def check_and_send_restart_signal() -> None:
try:
if not connection.is_usable():
logging.warning("*** Sending self SIGUSR1 to trigger a restart.")
os.kill(os.getpid(), signal.SIGUSR1)
except Exception:
pass
# If you change the function on which this decorator is used be careful that the new
# function doesn't delete the "failed_tries" attribute of "data" which is needed for
# "retry_event" to work correctly; see EmailSendingWorker for an example with deepcopy.
def retry_send_email_failures(
func: Callable[[ConcreteQueueWorker, Dict[str, Any]], None],
) -> Callable[[ConcreteQueueWorker, Dict[str, Any]], None]:
@wraps(func)
def wrapper(worker: ConcreteQueueWorker, data: Dict[str, Any]) -> None:
try:
func(worker, data)
except (
socket.gaierror,
socket.timeout,
EmailNotDeliveredError,
) as e:
error_class_name = type(e).__name__
def on_failure(event: Dict[str, Any]) -> None:
logging.exception(
"Event %r failed due to exception %s", event, error_class_name, stack_info=True
)
retry_event(worker.queue_name, data, on_failure)
return wrapper
class QueueProcessingWorker(ABC):
queue_name: str
MAX_CONSUME_SECONDS: Optional[int] = 30
CONSUME_ITERATIONS_BEFORE_UPDATE_STATS_NUM = 50
MAX_SECONDS_BEFORE_UPDATE_STATS = 30
queue_processors: Set a bounded prefetch size on rabbitmq queues. RabbitMQ clients have a setting called prefetch[1], which controls how many un-acknowledged events the server forwards to the local queue in the client. The default is 0; this means that when clients first connect, the server must send them every message in the queue. This itself may cause unbounded memory usage in the client, but also has other detrimental effects. While the client is attempting to process the head of the queue, it may be unable to read from the TCP socket at the rate that the server is sending to it -- filling the TCP buffers, and causing the server's writes to block. If the server blocks for more than 30 seconds, it times out the send, and closes the connection with: ``` closing AMQP connection <0.30902.126> (127.0.0.1:53870 -> 127.0.0.1:5672): {writer,send_failed,{error,timeout}} ``` This is https://github.com/pika/pika/issues/753#issuecomment-318119222. Set a prefetch limit of 100 messages, or the batch size, to better handle queues which start with large numbers of outstanding events. Setting prefetch=1 causes significant performance degradation in the no-op queue worker, to 30% of the prefetch=0 performance. Setting prefetch=100 achieves 90% of the prefetch=0 performance, and higher values offer only minor gains above that. For batch workers, their performance is not notably degraded by prefetch equal to their batch size, and they cannot function on smaller prefetches than their batch size. We also set a 100-count prefetch on Tornado workers, as they are potentially susceptible to the same effect. [1] https://www.rabbitmq.com/confirms.html#channel-qos-prefetch
2021-11-09 17:41:19 +01:00
# How many un-acknowledged events the worker should have on hand,
# fetched from the rabbitmq server. Larger values may be more
# performant, but if queues are large, cause more network IO at
# startup and steady-state memory.
PREFETCH = 100
def __init__(self, threaded: bool = False, disable_timeout: bool = False) -> None:
self.q: Optional[SimpleQueueClient] = None
self.threaded = threaded
self.disable_timeout = disable_timeout
if not hasattr(self, "queue_name"):
raise WorkerDeclarationError("Queue worker declared without queue_name")
self.initialize_statistics()
def initialize_statistics(self) -> None:
self.queue_last_emptied_timestamp = time.time()
self.consumed_since_last_emptied = 0
python: Convert assignment type annotations to Python 3.6 style. This commit was split by tabbott; this piece covers the vast majority of files in Zulip, but excludes scripts/, tools/, and puppet/ to help ensure we at least show the right error messages for Xenial systems. We can likely further refine the remaining pieces with some testing. Generated by com2ann, with whitespace fixes and various manual fixes for runtime issues: - invoiced_through: Optional[LicenseLedger] = models.ForeignKey( + invoiced_through: Optional["LicenseLedger"] = models.ForeignKey( -_apns_client: Optional[APNsClient] = None +_apns_client: Optional["APNsClient"] = None - notifications_stream: Optional[Stream] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) - signup_notifications_stream: Optional[Stream] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) + notifications_stream: Optional["Stream"] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) + signup_notifications_stream: Optional["Stream"] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) - author: Optional[UserProfile] = models.ForeignKey('UserProfile', blank=True, null=True, on_delete=CASCADE) + author: Optional["UserProfile"] = models.ForeignKey('UserProfile', blank=True, null=True, on_delete=CASCADE) - bot_owner: Optional[UserProfile] = models.ForeignKey('self', null=True, on_delete=models.SET_NULL) + bot_owner: Optional["UserProfile"] = models.ForeignKey('self', null=True, on_delete=models.SET_NULL) - default_sending_stream: Optional[Stream] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) - default_events_register_stream: Optional[Stream] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) + default_sending_stream: Optional["Stream"] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) + default_events_register_stream: Optional["Stream"] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) -descriptors_by_handler_id: Dict[int, ClientDescriptor] = {} +descriptors_by_handler_id: Dict[int, "ClientDescriptor"] = {} -worker_classes: Dict[str, Type[QueueProcessingWorker]] = {} -queues: Dict[str, Dict[str, Type[QueueProcessingWorker]]] = {} +worker_classes: Dict[str, Type["QueueProcessingWorker"]] = {} +queues: Dict[str, Dict[str, Type["QueueProcessingWorker"]]] = {} -AUTH_LDAP_REVERSE_EMAIL_SEARCH: Optional[LDAPSearch] = None +AUTH_LDAP_REVERSE_EMAIL_SEARCH: Optional["LDAPSearch"] = None Signed-off-by: Anders Kaseorg <anders@zulipchat.com>
2020-04-22 01:09:50 +02:00
self.recent_consume_times: MutableSequence[Tuple[int, float]] = deque(maxlen=50)
self.consume_iteration_counter = 0
self.idle = True
self.last_statistics_update_time = 0.0
self.update_statistics()
def update_statistics(self) -> None:
total_seconds = sum(seconds for _, seconds in self.recent_consume_times)
total_events = sum(events_number for events_number, _ in self.recent_consume_times)
if total_events == 0:
recent_average_consume_time = None
else:
recent_average_consume_time = total_seconds / total_events
stats_dict = dict(
update_time=time.time(),
recent_average_consume_time=recent_average_consume_time,
queue_last_emptied_timestamp=self.queue_last_emptied_timestamp,
consumed_since_last_emptied=self.consumed_since_last_emptied,
)
os.makedirs(settings.QUEUE_STATS_DIR, exist_ok=True)
fname = f"{self.queue_name}.stats"
fn = os.path.join(settings.QUEUE_STATS_DIR, fname)
with lockfile(fn + ".lock"):
tmp_fn = fn + ".tmp"
with open(tmp_fn, "wb") as f:
f.write(
orjson.dumps(stats_dict, option=orjson.OPT_APPEND_NEWLINE | orjson.OPT_INDENT_2)
)
os.rename(tmp_fn, fn)
self.last_statistics_update_time = time.time()
queue: Rename queue_size, and update for all local queues. Despite its name, the `queue_size` method does not return the number of items in the queue; it returns the number of items that the local consumer has delivered but unprocessed. These are often, but not always, the same. RabbitMQ's queues maintain the queue of unacknowledged messages; when a consumer connects, it sends to the consumer some number of messages to handle, known as the "prefetch." This is a performance optimization, to ensure the consumer code does not need to wait for a network round-trip before having new data to consume. The default prefetch is 0, which means that RabbitMQ immediately dumps all outstanding messages to the consumer, which slowly processes and acknowledges them. If a second consumer were to connect to the same queue, they would receive no messages to process, as the first consumer has already been allocated them. If the first consumer disconnects or crashes, all prior events sent to it are then made available for other consumers on the queue. The consumer does not know the total size of the queue -- merely how many messages it has been handed. No change is made to the prefetch here; however, future changes may wish to limit the prefetch, either for memory-saving, or to allow multiple consumers to work the same queue. Rename the method to make clear that it only contains information about the local queue in the consumer, not the full RabbitMQ queue. Also include the waiting message count, which is used by the `consume()` iterator for similar purpose to the pending events list.
2020-10-09 22:12:55 +02:00
def get_remaining_local_queue_size(self) -> int:
if self.q is not None:
queue: Rename queue_size, and update for all local queues. Despite its name, the `queue_size` method does not return the number of items in the queue; it returns the number of items that the local consumer has delivered but unprocessed. These are often, but not always, the same. RabbitMQ's queues maintain the queue of unacknowledged messages; when a consumer connects, it sends to the consumer some number of messages to handle, known as the "prefetch." This is a performance optimization, to ensure the consumer code does not need to wait for a network round-trip before having new data to consume. The default prefetch is 0, which means that RabbitMQ immediately dumps all outstanding messages to the consumer, which slowly processes and acknowledges them. If a second consumer were to connect to the same queue, they would receive no messages to process, as the first consumer has already been allocated them. If the first consumer disconnects or crashes, all prior events sent to it are then made available for other consumers on the queue. The consumer does not know the total size of the queue -- merely how many messages it has been handed. No change is made to the prefetch here; however, future changes may wish to limit the prefetch, either for memory-saving, or to allow multiple consumers to work the same queue. Rename the method to make clear that it only contains information about the local queue in the consumer, not the full RabbitMQ queue. Also include the waiting message count, which is used by the `consume()` iterator for similar purpose to the pending events list.
2020-10-09 22:12:55 +02:00
return self.q.local_queue_size()
else:
# This is a special case that will happen if we're operating without
# using RabbitMQ (e.g. in tests). In that case there's no queuing to speak of
# and the only reasonable size to return is 0.
return 0
@abstractmethod
def consume(self, data: Dict[str, Any]) -> None:
pass
def do_consume(
self, consume_func: Callable[[List[Dict[str, Any]]], None], events: List[Dict[str, Any]]
) -> None:
consume_time_seconds: Optional[float] = None
with configure_scope() as scope:
scope.clear_breadcrumbs()
add_breadcrumb(
type="debug",
category="queue_processor",
message=f"Consuming {self.queue_name}",
queue: Rename queue_size, and update for all local queues. Despite its name, the `queue_size` method does not return the number of items in the queue; it returns the number of items that the local consumer has delivered but unprocessed. These are often, but not always, the same. RabbitMQ's queues maintain the queue of unacknowledged messages; when a consumer connects, it sends to the consumer some number of messages to handle, known as the "prefetch." This is a performance optimization, to ensure the consumer code does not need to wait for a network round-trip before having new data to consume. The default prefetch is 0, which means that RabbitMQ immediately dumps all outstanding messages to the consumer, which slowly processes and acknowledges them. If a second consumer were to connect to the same queue, they would receive no messages to process, as the first consumer has already been allocated them. If the first consumer disconnects or crashes, all prior events sent to it are then made available for other consumers on the queue. The consumer does not know the total size of the queue -- merely how many messages it has been handed. No change is made to the prefetch here; however, future changes may wish to limit the prefetch, either for memory-saving, or to allow multiple consumers to work the same queue. Rename the method to make clear that it only contains information about the local queue in the consumer, not the full RabbitMQ queue. Also include the waiting message count, which is used by the `consume()` iterator for similar purpose to the pending events list.
2020-10-09 22:12:55 +02:00
data={"events": events, "local_queue_size": self.get_remaining_local_queue_size()},
)
try:
if self.idle:
# We're reactivating after having gone idle due to emptying the queue.
# We should update the stats file to keep it fresh and to make it clear
# that the queue started processing, in case the event we're about to process
# makes us freeze.
self.idle = False
self.update_statistics()
time_start = time.time()
if self.MAX_CONSUME_SECONDS and not self.threaded and not self.disable_timeout:
try:
signal.signal(
signal.SIGALRM,
partial(self.timer_expired, self.MAX_CONSUME_SECONDS, events),
)
try:
signal.alarm(self.MAX_CONSUME_SECONDS * len(events))
consume_func(events)
finally:
signal.alarm(0)
finally:
signal.signal(signal.SIGALRM, signal.SIG_DFL)
else:
consume_func(events)
consume_time_seconds = time.time() - time_start
self.consumed_since_last_emptied += len(events)
except Exception as e:
self._handle_consume_exception(events, e)
finally:
flush_per_request_caches()
reset_queries()
if consume_time_seconds is not None:
self.recent_consume_times.append((len(events), consume_time_seconds))
queue: Rename queue_size, and update for all local queues. Despite its name, the `queue_size` method does not return the number of items in the queue; it returns the number of items that the local consumer has delivered but unprocessed. These are often, but not always, the same. RabbitMQ's queues maintain the queue of unacknowledged messages; when a consumer connects, it sends to the consumer some number of messages to handle, known as the "prefetch." This is a performance optimization, to ensure the consumer code does not need to wait for a network round-trip before having new data to consume. The default prefetch is 0, which means that RabbitMQ immediately dumps all outstanding messages to the consumer, which slowly processes and acknowledges them. If a second consumer were to connect to the same queue, they would receive no messages to process, as the first consumer has already been allocated them. If the first consumer disconnects or crashes, all prior events sent to it are then made available for other consumers on the queue. The consumer does not know the total size of the queue -- merely how many messages it has been handed. No change is made to the prefetch here; however, future changes may wish to limit the prefetch, either for memory-saving, or to allow multiple consumers to work the same queue. Rename the method to make clear that it only contains information about the local queue in the consumer, not the full RabbitMQ queue. Also include the waiting message count, which is used by the `consume()` iterator for similar purpose to the pending events list.
2020-10-09 22:12:55 +02:00
remaining_local_queue_size = self.get_remaining_local_queue_size()
if remaining_local_queue_size == 0:
self.queue_last_emptied_timestamp = time.time()
self.consumed_since_last_emptied = 0
# We've cleared all the events from the queue, so we don't
# need to worry about the small overhead of doing a disk write.
# We take advantage of this to update the stats file to keep it fresh,
# especially since the queue might go idle until new events come in.
self.update_statistics()
self.idle = True
else:
self.consume_iteration_counter += 1
if (
self.consume_iteration_counter
>= self.CONSUME_ITERATIONS_BEFORE_UPDATE_STATS_NUM
or time.time() - self.last_statistics_update_time
>= self.MAX_SECONDS_BEFORE_UPDATE_STATS
):
self.consume_iteration_counter = 0
self.update_statistics()
def consume_single_event(self, event: Dict[str, Any]) -> None:
consume_func = lambda events: self.consume(events[0])
self.do_consume(consume_func, [event])
def timer_expired(
self, limit: int, events: List[Dict[str, Any]], signal: int, frame: Optional[FrameType]
) -> None:
raise WorkerTimeoutError(self.queue_name, limit, len(events))
def _handle_consume_exception(self, events: List[Dict[str, Any]], exception: Exception) -> None:
if isinstance(exception, InterruptConsumeError):
# The exception signals that no further error handling
# is needed and the worker can proceed.
return
with configure_scope() as scope:
scope.set_context(
"events",
{
"data": events,
"queue_name": self.queue_name,
},
)
if isinstance(exception, WorkerTimeoutError):
with sentry_sdk.push_scope() as scope:
scope.fingerprint = ["worker-timeout", self.queue_name]
logging.exception(exception, stack_info=True)
else:
logging.exception(
"Problem handling data on queue %s", self.queue_name, stack_info=True
)
if not os.path.exists(settings.QUEUE_ERROR_DIR):
os.mkdir(settings.QUEUE_ERROR_DIR) # nocoverage
# Use 'mark_sanitized' to prevent Pysa from detecting this false positive
# flow. 'queue_name' is always a constant string.
fname = mark_sanitized(f"{self.queue_name}.errors")
fn = os.path.join(settings.QUEUE_ERROR_DIR, fname)
line = f"{time.asctime()}\t{orjson.dumps(events).decode()}\n"
lock_fn = fn + ".lock"
with lockfile(lock_fn):
with open(fn, "a") as f:
f.write(line)
check_and_send_restart_signal()
def setup(self) -> None:
queue_processors: Set a bounded prefetch size on rabbitmq queues. RabbitMQ clients have a setting called prefetch[1], which controls how many un-acknowledged events the server forwards to the local queue in the client. The default is 0; this means that when clients first connect, the server must send them every message in the queue. This itself may cause unbounded memory usage in the client, but also has other detrimental effects. While the client is attempting to process the head of the queue, it may be unable to read from the TCP socket at the rate that the server is sending to it -- filling the TCP buffers, and causing the server's writes to block. If the server blocks for more than 30 seconds, it times out the send, and closes the connection with: ``` closing AMQP connection <0.30902.126> (127.0.0.1:53870 -> 127.0.0.1:5672): {writer,send_failed,{error,timeout}} ``` This is https://github.com/pika/pika/issues/753#issuecomment-318119222. Set a prefetch limit of 100 messages, or the batch size, to better handle queues which start with large numbers of outstanding events. Setting prefetch=1 causes significant performance degradation in the no-op queue worker, to 30% of the prefetch=0 performance. Setting prefetch=100 achieves 90% of the prefetch=0 performance, and higher values offer only minor gains above that. For batch workers, their performance is not notably degraded by prefetch equal to their batch size, and they cannot function on smaller prefetches than their batch size. We also set a 100-count prefetch on Tornado workers, as they are potentially susceptible to the same effect. [1] https://www.rabbitmq.com/confirms.html#channel-qos-prefetch
2021-11-09 17:41:19 +01:00
self.q = SimpleQueueClient(prefetch=self.PREFETCH)
def start(self) -> None:
assert self.q is not None
self.initialize_statistics()
self.q.start_json_consumer(
self.queue_name,
lambda events: self.consume_single_event(events[0]),
)
def stop(self) -> None: # nocoverage
assert self.q is not None
self.q.stop_consuming()
class LoopQueueProcessingWorker(QueueProcessingWorker):
sleep_delay = 1
batch_size = 100
@override
queue_processors: Set a bounded prefetch size on rabbitmq queues. RabbitMQ clients have a setting called prefetch[1], which controls how many un-acknowledged events the server forwards to the local queue in the client. The default is 0; this means that when clients first connect, the server must send them every message in the queue. This itself may cause unbounded memory usage in the client, but also has other detrimental effects. While the client is attempting to process the head of the queue, it may be unable to read from the TCP socket at the rate that the server is sending to it -- filling the TCP buffers, and causing the server's writes to block. If the server blocks for more than 30 seconds, it times out the send, and closes the connection with: ``` closing AMQP connection <0.30902.126> (127.0.0.1:53870 -> 127.0.0.1:5672): {writer,send_failed,{error,timeout}} ``` This is https://github.com/pika/pika/issues/753#issuecomment-318119222. Set a prefetch limit of 100 messages, or the batch size, to better handle queues which start with large numbers of outstanding events. Setting prefetch=1 causes significant performance degradation in the no-op queue worker, to 30% of the prefetch=0 performance. Setting prefetch=100 achieves 90% of the prefetch=0 performance, and higher values offer only minor gains above that. For batch workers, their performance is not notably degraded by prefetch equal to their batch size, and they cannot function on smaller prefetches than their batch size. We also set a 100-count prefetch on Tornado workers, as they are potentially susceptible to the same effect. [1] https://www.rabbitmq.com/confirms.html#channel-qos-prefetch
2021-11-09 17:41:19 +01:00
def setup(self) -> None:
self.q = SimpleQueueClient(prefetch=max(self.PREFETCH, self.batch_size))
@override
def start(self) -> None: # nocoverage
assert self.q is not None
self.initialize_statistics()
self.q.start_json_consumer(
self.queue_name,
lambda events: self.do_consume(self.consume_batch, events),
batch_size=self.batch_size,
timeout=self.sleep_delay,
)
@abstractmethod
def consume_batch(self, events: List[Dict[str, Any]]) -> None:
pass
@override
def consume(self, event: Dict[str, Any]) -> None:
"""In LoopQueueProcessingWorker, consume is used just for automated tests"""
self.consume_batch([event])
@assign_queue("invites")
class ConfirmationEmailWorker(QueueProcessingWorker):
@override
def consume(self, data: Mapping[str, Any]) -> None:
if "invite_expires_in_days" in data:
invite_expires_in_minutes = data["invite_expires_in_days"] * 24 * 60
elif "invite_expires_in_minutes" in data:
invite_expires_in_minutes = data["invite_expires_in_minutes"]
invitee = filter_to_valid_prereg_users(
PreregistrationUser.objects.filter(id=data["prereg_id"]), invite_expires_in_minutes
).first()
if invitee is None:
# The invitation could have been revoked
return
referrer = get_user_profile_by_id(data["referrer_id"])
logger.info(
"Sending invitation for realm %s to %s", referrer.realm.string_id, invitee.email
)
if "email_language" in data:
email_language = data["email_language"]
else:
email_language = referrer.realm.default_language
activate_url = do_send_confirmation_email(
invitee, referrer, email_language, invite_expires_in_minutes
)
if invite_expires_in_minutes is None:
# We do not queue reminder email for never expiring
# invitations. This is probably a low importance bug; it
# would likely be more natural to send a reminder after 7
# days.
return
# queue invitation reminder
if invite_expires_in_minutes >= 4 * 24 * 60:
context = common_context(referrer)
context.update(
activate_url=activate_url,
referrer_name=referrer.full_name,
referrer_email=referrer.delivery_email,
referrer_realm_name=referrer.realm.name,
)
send_future_email(
"zerver/emails/invitation_reminder",
referrer.realm,
to_emails=[invitee.email],
from_address=FromAddress.tokenized_no_reply_placeholder,
language=email_language,
context=context,
delay=timedelta(minutes=invite_expires_in_minutes - (2 * 24 * 60)),
)
@assign_queue("user_activity")
class UserActivityWorker(LoopQueueProcessingWorker):
"""The UserActivity queue is perhaps our highest-traffic queue, and
requires some care to ensure it performs adequately.
We use a LoopQueueProcessingWorker as a performance optimization
for managing the queue. The structure of UserActivity records is
such that they are easily deduplicated before being sent to the
database; we take advantage of that to make this queue highly
effective at dealing with a backlog containing many similar
events. Such a backlog happen in a few ways:
* In abuse/DoS situations, if a client is sending huge numbers of
similar requests to the server.
* If the queue ends up with several minutes of backlog e.g. due to
downtime of the queue processor, many clients will have several
common events from doing an action multiple times.
"""
python: Convert assignment type annotations to Python 3.6 style. This commit was split by tabbott; this piece covers the vast majority of files in Zulip, but excludes scripts/, tools/, and puppet/ to help ensure we at least show the right error messages for Xenial systems. We can likely further refine the remaining pieces with some testing. Generated by com2ann, with whitespace fixes and various manual fixes for runtime issues: - invoiced_through: Optional[LicenseLedger] = models.ForeignKey( + invoiced_through: Optional["LicenseLedger"] = models.ForeignKey( -_apns_client: Optional[APNsClient] = None +_apns_client: Optional["APNsClient"] = None - notifications_stream: Optional[Stream] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) - signup_notifications_stream: Optional[Stream] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) + notifications_stream: Optional["Stream"] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) + signup_notifications_stream: Optional["Stream"] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) - author: Optional[UserProfile] = models.ForeignKey('UserProfile', blank=True, null=True, on_delete=CASCADE) + author: Optional["UserProfile"] = models.ForeignKey('UserProfile', blank=True, null=True, on_delete=CASCADE) - bot_owner: Optional[UserProfile] = models.ForeignKey('self', null=True, on_delete=models.SET_NULL) + bot_owner: Optional["UserProfile"] = models.ForeignKey('self', null=True, on_delete=models.SET_NULL) - default_sending_stream: Optional[Stream] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) - default_events_register_stream: Optional[Stream] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) + default_sending_stream: Optional["Stream"] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) + default_events_register_stream: Optional["Stream"] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) -descriptors_by_handler_id: Dict[int, ClientDescriptor] = {} +descriptors_by_handler_id: Dict[int, "ClientDescriptor"] = {} -worker_classes: Dict[str, Type[QueueProcessingWorker]] = {} -queues: Dict[str, Dict[str, Type[QueueProcessingWorker]]] = {} +worker_classes: Dict[str, Type["QueueProcessingWorker"]] = {} +queues: Dict[str, Dict[str, Type["QueueProcessingWorker"]]] = {} -AUTH_LDAP_REVERSE_EMAIL_SEARCH: Optional[LDAPSearch] = None +AUTH_LDAP_REVERSE_EMAIL_SEARCH: Optional["LDAPSearch"] = None Signed-off-by: Anders Kaseorg <anders@zulipchat.com>
2020-04-22 01:09:50 +02:00
client_id_map: Dict[str, int] = {}
@override
def start(self) -> None:
# For our unit tests to make sense, we need to clear this on startup.
self.client_id_map = {}
super().start()
@override
def consume_batch(self, user_activity_events: List[Dict[str, Any]]) -> None:
python: Convert assignment type annotations to Python 3.6 style. This commit was split by tabbott; this piece covers the vast majority of files in Zulip, but excludes scripts/, tools/, and puppet/ to help ensure we at least show the right error messages for Xenial systems. We can likely further refine the remaining pieces with some testing. Generated by com2ann, with whitespace fixes and various manual fixes for runtime issues: - invoiced_through: Optional[LicenseLedger] = models.ForeignKey( + invoiced_through: Optional["LicenseLedger"] = models.ForeignKey( -_apns_client: Optional[APNsClient] = None +_apns_client: Optional["APNsClient"] = None - notifications_stream: Optional[Stream] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) - signup_notifications_stream: Optional[Stream] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) + notifications_stream: Optional["Stream"] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) + signup_notifications_stream: Optional["Stream"] = models.ForeignKey('Stream', related_name='+', null=True, blank=True, on_delete=CASCADE) - author: Optional[UserProfile] = models.ForeignKey('UserProfile', blank=True, null=True, on_delete=CASCADE) + author: Optional["UserProfile"] = models.ForeignKey('UserProfile', blank=True, null=True, on_delete=CASCADE) - bot_owner: Optional[UserProfile] = models.ForeignKey('self', null=True, on_delete=models.SET_NULL) + bot_owner: Optional["UserProfile"] = models.ForeignKey('self', null=True, on_delete=models.SET_NULL) - default_sending_stream: Optional[Stream] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) - default_events_register_stream: Optional[Stream] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) + default_sending_stream: Optional["Stream"] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) + default_events_register_stream: Optional["Stream"] = models.ForeignKey('zerver.Stream', null=True, related_name='+', on_delete=CASCADE) -descriptors_by_handler_id: Dict[int, ClientDescriptor] = {} +descriptors_by_handler_id: Dict[int, "ClientDescriptor"] = {} -worker_classes: Dict[str, Type[QueueProcessingWorker]] = {} -queues: Dict[str, Dict[str, Type[QueueProcessingWorker]]] = {} +worker_classes: Dict[str, Type["QueueProcessingWorker"]] = {} +queues: Dict[str, Dict[str, Type["QueueProcessingWorker"]]] = {} -AUTH_LDAP_REVERSE_EMAIL_SEARCH: Optional[LDAPSearch] = None +AUTH_LDAP_REVERSE_EMAIL_SEARCH: Optional["LDAPSearch"] = None Signed-off-by: Anders Kaseorg <anders@zulipchat.com>
2020-04-22 01:09:50 +02:00
uncommitted_events: Dict[Tuple[int, int, str], Tuple[int, float]] = {}
# First, we drain the queue of all user_activity events and
# deduplicate them for insertion into the database.
for event in user_activity_events:
user_profile_id = event["user_profile_id"]
client_id = event["client_id"]
key_tuple = (user_profile_id, client_id, event["query"])
if key_tuple not in uncommitted_events:
uncommitted_events[key_tuple] = (1, event["time"])
else:
count, event_time = uncommitted_events[key_tuple]
uncommitted_events[key_tuple] = (count + 1, max(event_time, event["time"]))
rows = []
for key_tuple, value_tuple in uncommitted_events.items():
user_profile_id, client_id, query = key_tuple
count, event_time = value_tuple
rows.append(
SQL("({},{},{},{},to_timestamp({}))").format(
Literal(user_profile_id),
Literal(client_id),
Literal(query),
Literal(count),
Literal(event_time),
)
)
# Perform a single bulk UPSERT for all of the rows
sql_query = SQL(
"""
INSERT INTO zerver_useractivity(user_profile_id, client_id, query, count, last_visit)
VALUES {rows}
ON CONFLICT (user_profile_id, client_id, query) DO UPDATE SET
count = zerver_useractivity.count + excluded.count,
last_visit = greatest(zerver_useractivity.last_visit, excluded.last_visit)
"""
).format(rows=SQL(", ").join(rows))
with connection.cursor() as cursor:
cursor.execute(sql_query)
@assign_queue("user_activity_interval")
class UserActivityIntervalWorker(QueueProcessingWorker):
@override
def consume(self, event: Mapping[str, Any]) -> None:
user_profile = get_user_profile_by_id(event["user_profile_id"])
log_time = timestamp_to_datetime(event["time"])
do_update_user_activity_interval(user_profile, log_time)
@assign_queue("user_presence")
class UserPresenceWorker(QueueProcessingWorker):
@override
def consume(self, event: Mapping[str, Any]) -> None:
logging.debug("Received presence event: %s", event)
user_profile = get_user_profile_by_id(event["user_profile_id"])
client = get_client(event["client"])
log_time = timestamp_to_datetime(event["time"])
status = event["status"]
do_update_user_presence(user_profile, client, log_time, status)
@assign_queue("missedmessage_emails")
class MissedMessageWorker(QueueProcessingWorker):
# Aggregate all messages received over the last several seconds
# (configurable by each recipient) to let someone finish sending a
# batch of messages and/or editing them before they are sent out
# as emails to recipients.
#
# The batch interval is best-effort -- we poll at most every
# CHECK_FREQUENCY_SECONDS, to avoid excessive activity.
CHECK_FREQUENCY_SECONDS = 5
worker_thread: Optional[threading.Thread] = None
# This condition variable mediates the stopping and has_timeout
# pieces of state, below it.
cv = threading.Condition()
stopping = False
has_timeout = False
# The main thread, which handles the RabbitMQ connection and creates
# database rows from them.
@override
def consume(self, event: Dict[str, Any]) -> None:
logging.debug("Processing missedmessage_emails event: %s", event)
# When we consume an event, check if there are existing pending emails
# for that user, and if so use the same scheduled timestamp.
user_profile_id: int = event["user_profile_id"]
user_profile = get_user_profile_by_id(user_profile_id)
batch_duration_seconds = user_profile.email_notifications_batching_period_seconds
batch_duration = timedelta(seconds=batch_duration_seconds)
try:
pending_email = ScheduledMessageNotificationEmail.objects.filter(
user_profile_id=user_profile_id
)[0]
scheduled_timestamp = pending_email.scheduled_timestamp
except IndexError:
scheduled_timestamp = timezone_now() + batch_duration
with self.cv:
# We now hold the lock, so there are three places the
# worker thread can be:
#
# 1. In maybe_send_batched_emails, and will have to take
# the lock (and thus block insertions of new rows
# here) to decide if there are any rows and if it thus
# needs a timeout.
#
# 2. In the cv.wait_for with a timeout because there were
# rows already. There's nothing for us to do, since
# the newly-inserted row will get checked upon that
# timeout.
#
# 3. In the cv.wait_for without a timeout, because there
# weren't any rows (which we're about to change).
#
# Notifying in (1) is irrelevant, since the thread is not
# waiting. If we over-notify by doing so for both (2) and
# (3), the behaviour is correct but slightly inefficient,
# as the thread will be needlessly awoken and will just
# re-wait. However, if we fail to awake case (3), the
# worker thread will never wake up, and the
# ScheduledMessageNotificationEmail internal queue will
# back up.
#
# Use the self.has_timeout property (which is protected by
# the lock) to determine which of cases (2) or (3) we are
# in, and as such if we need to notify after making the
# row.
try:
ScheduledMessageNotificationEmail.objects.create(
user_profile_id=user_profile_id,
message_id=event["message_id"],
trigger=event["trigger"],
scheduled_timestamp=scheduled_timestamp,
mentioned_user_group_id=event.get("mentioned_user_group_id"),
)
if not self.has_timeout:
self.cv.notify()
except IntegrityError:
logging.debug(
"ScheduledMessageNotificationEmail row could not be created. The message may have been deleted. Skipping event."
)
@override
def start(self) -> None:
with self.cv:
self.stopping = False
self.worker_thread = threading.Thread(target=lambda: self.work())
self.worker_thread.start()
super().start()
queue: Use locking to avoid race conditions in missedmessage_emails. This queue had a race condition with creation of another Timer while maybe_send_batched_emails is still doing its work, which may cause two or more threads to be running maybe_send_batched_emails at the same time, mutating the shared data simultaneously. Another less likely potential race condition was that maybe_send_batched_emails after sending out its email, can call ensure_timer(). If the consume function is run simultaneously in the main thread, it will call ensure_timer() too, which, given unfortunate timings, might lead to both calls setting a new Timer. We add locking to the queue to avoid such race conditions. Tested manually, by print debugging with the following setup: 1. Making handle_missedmessage_emails sleep 2 seconds for each email, and changed BATCH_DURATION to 1s to make the queue start working right after launching. 2. Putting a bunch of events in the queue. 3. ./manage.py process_queue --queue_name missedmessage_emails 4. Once maybe_send_batched_emails is called and while it's processing the events, I pushed more events to the queue. That triggers the consume() function and ensure_timer(). Before implementing the locking mechanism, this causes two threads to run maybe_send_batched_emails at the same time, mutating each other's shared data, causing a traceback such as Exception in thread Thread-3: Traceback (most recent call last): File "/usr/lib/python3.6/threading.py", line 916, in _bootstrap_inner self.run() File "/usr/lib/python3.6/threading.py", line 1182, in run self.function(*self.args, **self.kwargs) File "/srv/zulip/zerver/worker/queue_processors.py", line 507, in maybe_send_batched_emails del self.events_by_recipient[user_profile_id] KeyError: '5' With the locking mechanism, things get handled as expected, and ensure_timer() exits if it can't obtain the lock due to maybe_send_batched_emails still working. Co-authored-by: Tim Abbott <tabbott@zulip.com>
2020-08-26 21:40:59 +02:00
def work(self) -> None:
while True:
try:
finished = self.background_loop()
if finished:
break
except Exception:
logging.exception(
"Exception in MissedMessage background worker; restarting the loop",
stack_info=True,
)
def background_loop(self) -> bool:
with self.cv:
if self.stopping:
return True
# There are three conditions which we wait for:
#
# 1. We are being explicitly asked to stop; see the
# notify() call in stop()
#
# 2. We have no ScheduledMessageNotificationEmail
# objects currently (has_timeout = False) and the
# first one was just enqueued; see the notify()
# call in consume(). We break out so that we can
# come back around the loop and re-wait with a
# timeout (see next condition).
#
# 3. One or more ScheduledMessageNotificationEmail
# exist in the database, so we need to re-check
# them regularly; this happens by hitting the
# timeout and calling maybe_send_batched_emails().
# There is no explicit notify() for this.
timeout: Optional[int] = None
if ScheduledMessageNotificationEmail.objects.exists():
timeout = self.CHECK_FREQUENCY_SECONDS
self.has_timeout = timeout is not None
def wait_condition() -> bool:
if self.stopping:
# Condition (1)
return True
if timeout is None:
# Condition (2). We went to sleep with no
# ScheduledMessageNotificationEmail existing,
# and one has just been made. We re-check
# that is still true now that we have the
# lock, and if we see it, we stop waiting.
return ScheduledMessageNotificationEmail.objects.exists()
# This should only happen at the start or end of
# the wait, when we haven't been notified, but are
# re-checking the condition.
return False
was_notified = self.cv.wait_for(wait_condition, timeout=timeout)
# Being notified means that we are in conditions (1) or
# (2), above. In neither case do we need to look at if
# there are batches to send -- (2) means that the
# ScheduledMessageNotificationEmail was _just_ created, so
# there is no need to check it now.
if not was_notified:
self.maybe_send_batched_emails()
return False
queue: Use locking to avoid race conditions in missedmessage_emails. This queue had a race condition with creation of another Timer while maybe_send_batched_emails is still doing its work, which may cause two or more threads to be running maybe_send_batched_emails at the same time, mutating the shared data simultaneously. Another less likely potential race condition was that maybe_send_batched_emails after sending out its email, can call ensure_timer(). If the consume function is run simultaneously in the main thread, it will call ensure_timer() too, which, given unfortunate timings, might lead to both calls setting a new Timer. We add locking to the queue to avoid such race conditions. Tested manually, by print debugging with the following setup: 1. Making handle_missedmessage_emails sleep 2 seconds for each email, and changed BATCH_DURATION to 1s to make the queue start working right after launching. 2. Putting a bunch of events in the queue. 3. ./manage.py process_queue --queue_name missedmessage_emails 4. Once maybe_send_batched_emails is called and while it's processing the events, I pushed more events to the queue. That triggers the consume() function and ensure_timer(). Before implementing the locking mechanism, this causes two threads to run maybe_send_batched_emails at the same time, mutating each other's shared data, causing a traceback such as Exception in thread Thread-3: Traceback (most recent call last): File "/usr/lib/python3.6/threading.py", line 916, in _bootstrap_inner self.run() File "/usr/lib/python3.6/threading.py", line 1182, in run self.function(*self.args, **self.kwargs) File "/srv/zulip/zerver/worker/queue_processors.py", line 507, in maybe_send_batched_emails del self.events_by_recipient[user_profile_id] KeyError: '5' With the locking mechanism, things get handled as expected, and ensure_timer() exits if it can't obtain the lock due to maybe_send_batched_emails still working. Co-authored-by: Tim Abbott <tabbott@zulip.com>
2020-08-26 21:40:59 +02:00
def maybe_send_batched_emails(self) -> None:
current_time = timezone_now()
with transaction.atomic():
events_to_process = ScheduledMessageNotificationEmail.objects.filter(
scheduled_timestamp__lte=current_time
).select_for_update()
# Batch the entries by user
events_by_recipient: Dict[int, Dict[int, MissedMessageData]] = defaultdict(dict)
for event in events_to_process:
events_by_recipient[event.user_profile_id][event.message_id] = MissedMessageData(
trigger=event.trigger, mentioned_user_group_id=event.mentioned_user_group_id
)
for user_profile_id in events_by_recipient:
events = events_by_recipient[user_profile_id]
logging.info(
"Batch-processing %s missedmessage_emails events for user %s",
len(events),
user_profile_id,
)
try:
# Because we process events in batches, an
# escaped exception here would lead to
# duplicate messages being sent for other
# users in the same events_to_process batch,
# and no guarantee of forward progress.
handle_missedmessage_emails(user_profile_id, events)
except Exception:
logging.exception(
"Failed to process %d missedmessage_emails for user %s",
len(events),
user_profile_id,
stack_info=True,
)
events_to_process.delete()
@override
def stop(self) -> None:
with self.cv:
self.stopping = True
self.cv.notify()
if self.worker_thread is not None:
self.worker_thread.join()
super().stop()
@assign_queue("email_senders")
class EmailSendingWorker(LoopQueueProcessingWorker):
def __init__(self, threaded: bool = False, disable_timeout: bool = False) -> None:
super().__init__(threaded, disable_timeout)
self.connection: Optional[BaseEmailBackend] = None
@retry_send_email_failures
def send_email(self, event: Dict[str, Any]) -> None:
# Copy the event, so that we don't pass the `failed_tries'
# data to send_email (which neither takes that
# argument nor needs that data).
copied_event = copy.deepcopy(event)
if "failed_tries" in copied_event:
del copied_event["failed_tries"]
handle_send_email_format_changes(copied_event)
self.connection = initialize_connection(self.connection)
send_email(**copied_event, connection=self.connection)
@override
def consume_batch(self, events: List[Dict[str, Any]]) -> None:
for event in events:
self.send_email(event)
@override
def stop(self) -> None:
try:
if self.connection is not None:
self.connection.close()
finally:
super().stop()
@assign_queue("missedmessage_mobile_notifications")
class PushNotificationsWorker(QueueProcessingWorker):
queue_processors: Disable timeouts with PushNotificationsWorker. Since 385328524174, PushNotificationsWorker uses the aioapns library to send Apple push notifications. This introduces an asyncio event loop into this worker process, which, if unlucky, can respond poorly when a SIGALRM is introduced to it: ``` [asyncio] Task exception was never retrieved future: <Task finished coro=<send_apple_push_notification.<locals>.attempt_send() done, defined at /path/to/zerver/lib/push_notifications.py:166> exception=WorkerTimeoutException(30, 1)> Traceback (most recent call last): File "/path/to/zerver/lib/push_notifications.py", line 169, in attempt_send result = await apns_context.apns.send_notification(request) File "/path/to/zulip-py3-venv/lib/python3.6/site-packages/aioapns/client.py", line 57, in send_notification response = await self.pool.send_notification(request) File "/path/to/zulip-py3-venv/lib/python3.6/site-packages/aioapns/connection.py", line 407, in send_notification response = await connection.send_notification(request) File "/path/to/zulip-py3-venv/lib/python3.6/site-packages/aioapns/connection.py", line 189, in send_notification data = json.dumps(request.message, ensure_ascii=False).encode() File "/usr/lib/python3.6/json/__init__.py", line 238, in dumps **kw).encode(obj) File "/usr/lib/python3.6/json/encoder.py", line 199, in encode chunks = self.iterencode(o, _one_shot=True) File "/usr/lib/python3.6/json/encoder.py", line 257, in iterencode return _iterencode(o, 0) File "/path/to/zerver/worker/queue_processors.py", line 353, in timer_expired raise WorkerTimeoutException(limit, len(events)) zerver.worker.queue_processors.WorkerTimeoutException: Timed out after 30 seconds processing 1 events ``` ...which subsequently leads to the worker failing to make any progress on the queue. Remove the timeout on the worker. This may result in failing to make forward progress if Apple/Google take overly long handling requests, but is likely preferable to failing to make forward progress if _one_ request takes too long and gets unlucky with when the signal comes through.
2021-10-21 02:24:16 +02:00
# The use of aioapns in the backend means that we cannot use
# SIGALRM to limit how long a consume takes, as SIGALRM does not
# play well with asyncio.
MAX_CONSUME_SECONDS = None
@override
def start(self) -> None:
# initialize_push_notifications doesn't strictly do anything
# beyond printing some logging warnings if push notifications
# are not available in the current configuration.
initialize_push_notifications()
super().start()
@override
def consume(self, event: Dict[str, Any]) -> None:
try:
if event.get("type", "add") == "remove":
message_ids = event["message_ids"]
handle_remove_push_notification(event["user_profile_id"], message_ids)
else:
handle_push_notification(event["user_profile_id"], event)
except PushNotificationBouncerRetryLaterError:
def failure_processor(event: Dict[str, Any]) -> None:
logger.warning(
"Maximum retries exceeded for trigger:%s event:push_notification",
event["user_profile_id"],
)
retry_event(self.queue_name, event, failure_processor)
@assign_queue("digest_emails")
class DigestWorker(QueueProcessingWorker): # nocoverage
# Who gets a digest is entirely determined by the enqueue_digest_emails
# management command, not here.
@override
def consume(self, event: Mapping[str, Any]) -> None:
if "user_ids" in event:
user_ids = event["user_ids"]
else:
# legacy code may have enqueued a single id
user_ids = [event["user_profile_id"]]
bulk_handle_digest_email(user_ids, event["cutoff"])
@assign_queue("email_mirror")
class MirrorWorker(QueueProcessingWorker):
@override
def consume(self, event: Mapping[str, Any]) -> None:
rcpt_to = event["rcpt_to"]
msg = email.message_from_bytes(
base64.b64decode(event["msg_base64"]),
policy=email.policy.default,
)
assert isinstance(msg, EmailMessage) # https://github.com/python/typeshed/issues/2417
if not is_missed_message_address(rcpt_to):
# Missed message addresses are one-time use, so we don't need
# to worry about emails to them resulting in message spam.
recipient_realm = decode_stream_email_address(rcpt_to)[0].realm
try:
rate_limit_mirror_by_realm(recipient_realm)
except RateLimitedError:
logger.warning(
"MirrorWorker: Rejecting an email from: %s to realm: %s - rate limited.",
msg["From"],
recipient_realm.subdomain,
)
return
mirror_email(msg, rcpt_to=rcpt_to)
@assign_queue("embed_links")
class FetchLinksEmbedData(QueueProcessingWorker):
# This is a slow queue with network requests, so a disk write is negligible.
# Update stats file after every consume call.
CONSUME_ITERATIONS_BEFORE_UPDATE_STATS_NUM = 1
@override
def consume(self, event: Mapping[str, Any]) -> None:
url_embed_data: Dict[str, Optional[UrlEmbedData]] = {}
for url in event["urls"]:
start_time = time.time()
url_embed_data[url] = url_preview.get_link_embed_data(url)
logging.info(
"Time spent on get_link_embed_data for %s: %s", url, time.time() - start_time
)
with transaction.atomic():
try:
message = Message.objects.select_for_update().get(id=event["message_id"])
except Message.DoesNotExist:
# Message may have been deleted
return
# If the message changed, we will run this task after updating the message
# in zerver.actions.message_edit.check_update_message
if message.content != event["message_content"]:
return
# Fetch the realm whose settings we're using for rendering
realm = Realm.objects.get(id=event["message_realm_id"])
# If rendering fails, the called code will raise a JsonableError.
rendering_result = render_incoming_message(
message,
message.content,
realm,
url_embed_data=url_embed_data,
)
do_update_embedded_data(message.sender, message, message.content, rendering_result)
@override
def timer_expired(
self, limit: int, events: List[Dict[str, Any]], signal: int, frame: Optional[FrameType]
) -> None:
assert len(events) == 1
event = events[0]
logging.warning(
"Timed out in %s after %s seconds while fetching URLs for message %s: %s",
self.queue_name,
limit,
event["message_id"],
event["urls"],
)
raise InterruptConsumeError
@assign_queue("outgoing_webhooks")
class OutgoingWebhookWorker(QueueProcessingWorker):
@override
def consume(self, event: Dict[str, Any]) -> None:
message = event["message"]
event["command"] = message["content"]
services = get_bot_services(event["user_profile_id"])
for service in services:
event["service_name"] = str(service.name)
service_handler = get_outgoing_webhook_service_handler(service)
do_rest_call(service.base_url, event, service_handler)
@assign_queue("embedded_bots")
class EmbeddedBotWorker(QueueProcessingWorker):
def get_bot_api_client(self, user_profile: UserProfile) -> EmbeddedBotHandler:
return EmbeddedBotHandler(user_profile)
@override
def consume(self, event: Mapping[str, Any]) -> None:
user_profile_id = event["user_profile_id"]
user_profile = get_user_profile_by_id(user_profile_id)
message: Dict[str, Any] = event["message"]
# TODO: Do we actually want to allow multiple Services per bot user?
services = get_bot_services(user_profile_id)
for service in services:
bot_handler = get_bot_handler(str(service.name))
if bot_handler is None:
logging.error(
"Error: User %s has bot with invalid embedded bot service %s",
user_profile_id,
service.name,
)
continue
try:
if hasattr(bot_handler, "initialize"):
bot_handler.initialize(self.get_bot_api_client(user_profile))
if event["trigger"] == "mention":
message["content"] = extract_query_without_mention(
message=message,
client=self.get_bot_api_client(user_profile),
)
assert message["content"] is not None
bot_handler.handle_message(
message=message,
bot_handler=self.get_bot_api_client(user_profile),
)
except EmbeddedBotQuitError as e:
logging.warning("%s", e)
@assign_queue("deferred_work")
class DeferredWorker(QueueProcessingWorker):
"""This queue processor is intended for cases where we want to trigger a
potentially expensive, not urgent, job to be run on a separate
thread from the Django worker that initiated it (E.g. so we that
can provide a low-latency HTTP response or avoid risk of request
timeouts for an operation that could in rare cases take minutes).
"""
# Because these operations have no SLO, and can take minutes,
# remove any processing timeouts
MAX_CONSUME_SECONDS = None
@override
def consume(self, event: Dict[str, Any]) -> None:
start = time.time()
if event["type"] == "mark_stream_messages_as_read":
user_profile = get_user_profile_by_id(event["user_profile_id"])
logger.info(
"Marking messages as read for user %s, stream_recipient_ids %s",
user_profile.id,
event["stream_recipient_ids"],
)
for recipient_id in event["stream_recipient_ids"]:
count = do_mark_stream_messages_as_read(user_profile, recipient_id)
logger.info(
"Marked %s messages as read for user %s, stream_recipient_id %s",
count,
user_profile.id,
recipient_id,
)
elif event["type"] == "mark_stream_messages_as_read_for_everyone":
logger.info(
"Marking messages as read for all users, stream_recipient_id %s",
event["stream_recipient_id"],
)
stream = Stream.objects.get(recipient_id=event["stream_recipient_id"])
# This event is generated by the stream deactivation code path.
batch_size = 100
offset = 0
while True:
messages = Message.objects.filter(
# Uses index: zerver_message_realm_recipient_id
realm_id=stream.realm_id,
recipient_id=event["stream_recipient_id"],
).order_by("id")[offset : offset + batch_size]
with transaction.atomic(savepoint=False):
UserMessage.select_for_update_query().filter(message__in=messages).extra(
where=[UserMessage.where_unread()]
).update(flags=F("flags").bitor(UserMessage.flags.read))
offset += len(messages)
if len(messages) < batch_size:
break
logger.info(
"Marked %s messages as read for all users, stream_recipient_id %s",
offset,
event["stream_recipient_id"],
)
elif event["type"] == "clear_push_device_tokens":
logger.info(
"Clearing push device tokens for user_profile_id %s",
event["user_profile_id"],
)
try:
clear_push_device_tokens(event["user_profile_id"])
except PushNotificationBouncerRetryLaterError:
def failure_processor(event: Dict[str, Any]) -> None:
logger.warning(
"Maximum retries exceeded for trigger:%s event:clear_push_device_tokens",
event["user_profile_id"],
)
retry_event(self.queue_name, event, failure_processor)
elif event["type"] == "realm_export":
realm = Realm.objects.get(id=event["realm_id"])
output_dir = tempfile.mkdtemp(prefix="zulip-export-")
export_event = RealmAuditLog.objects.get(id=event["id"])
user_profile = get_user_profile_by_id(event["user_profile_id"])
extra_data = export_event.extra_data
if extra_data.get("started_timestamp") is not None:
logger.error(
"Marking export for realm %s as failed due to retry -- possible OOM during export?",
realm.string_id,
)
extra_data["failed_timestamp"] = timezone_now().timestamp()
export_event.extra_data = extra_data
export_event.save(update_fields=["extra_data"])
notify_realm_export(user_profile)
return
extra_data["started_timestamp"] = timezone_now().timestamp()
export_event.extra_data = extra_data
export_event.save(update_fields=["extra_data"])
logger.info(
"Starting realm export for realm %s into %s, initiated by user_profile_id %s",
realm.string_id,
output_dir,
event["user_profile_id"],
)
try:
public_url = export_realm_wrapper(
realm=realm,
output_dir=output_dir,
threads=1 if self.threaded else 6,
upload=True,
public_only=True,
)
except Exception:
extra_data["failed_timestamp"] = timezone_now().timestamp()
export_event.extra_data = extra_data
export_event.save(update_fields=["extra_data"])
logging.exception(
"Data export for %s failed after %s",
user_profile.realm.string_id,
time.time() - start,
stack_info=True,
)
notify_realm_export(user_profile)
return
assert public_url is not None
# Update the extra_data field now that the export is complete.
extra_data["export_path"] = urlsplit(public_url).path
export_event.extra_data = extra_data
export_event.save(update_fields=["extra_data"])
# Send a direct message notification letting the user who
# triggered the export know the export finished.
with override_language(user_profile.default_language):
content = _(
"Your data export is complete. [View and download exports]({export_settings_link})."
).format(export_settings_link="/#organization/data-exports-admin")
internal_send_private_message(
sender=get_system_bot(settings.NOTIFICATION_BOT, realm.id),
recipient_user=user_profile,
content=content,
)
# For future frontend use, also notify administrator
# clients that the export happened.
notify_realm_export(user_profile)
logging.info(
"Completed data export for %s in %s",
user_profile.realm.string_id,
time.time() - start,
)
elif event["type"] == "reupload_realm_emoji":
# This is a special event queued by the migration for reuploading emojis.
# We don't want to run the necessary code in the actual migration, so it simply
# queues the necessary event, and the actual work is done here in the queue worker.
realm = Realm.objects.get(id=event["realm_id"])
logger.info("Processing reupload_realm_emoji event for realm %s", realm.id)
handle_reupload_emojis_event(realm, logger)
elif event["type"] == "soft_reactivate":
logger.info(
"Starting soft reactivation for user_profile_id %s",
event["user_profile_id"],
)
user_profile = get_user_profile_by_id(event["user_profile_id"])
reactivate_user_if_soft_deactivated(user_profile)
elif event["type"] == "push_bouncer_update_for_realm":
# In the future we may use the realm_id to send only that single realm's info.
realm_id = event["realm_id"]
logger.info("Updating push bouncer with metadata on behalf of realm %s", realm_id)
send_server_data_to_push_bouncer(consider_usage_statistics=False)
end = time.time()
logger.info(
"deferred_work processed %s event (%dms)",
event["type"],
(end - start) * 1000,
)
@assign_queue("test", is_test_queue=True)
class TestWorker(QueueProcessingWorker):
# This worker allows you to test the queue worker infrastructure without
# creating significant side effects. It can be useful in development or
# for troubleshooting prod/staging. It pulls a message off the test queue
# and appends it to a file in /var/log/zulip.
@override
def consume(self, event: Mapping[str, Any]) -> None: # nocoverage
fn = settings.ZULIP_WORKER_TEST_FILE
message = orjson.dumps(event)
logging.info("TestWorker should append this message to %s: %s", fn, message.decode())
with open(fn, "ab") as f:
f.write(message + b"\n")
@assign_queue("noop", is_test_queue=True)
class NoopWorker(QueueProcessingWorker):
"""Used to profile the queue processing framework, in zilencer's queue_rate."""
def __init__(
self,
threaded: bool = False,
disable_timeout: bool = False,
max_consume: int = 1000,
slow_queries: Sequence[int] = [],
) -> None:
super().__init__(threaded, disable_timeout)
self.consumed = 0
self.max_consume = max_consume
self.slow_queries: Set[int] = set(slow_queries)
@override
def consume(self, event: Mapping[str, Any]) -> None:
self.consumed += 1
if self.consumed in self.slow_queries:
logging.info("Slow request...")
time.sleep(60)
logging.info("Done!")
if self.consumed >= self.max_consume:
self.stop()
@assign_queue("noop_batch", is_test_queue=True)
class BatchNoopWorker(LoopQueueProcessingWorker):
"""Used to profile the queue processing framework, in zilencer's queue_rate."""
batch_size = 100
def __init__(
self,
threaded: bool = False,
disable_timeout: bool = False,
max_consume: int = 1000,
slow_queries: Sequence[int] = [],
) -> None:
super().__init__(threaded, disable_timeout)
self.consumed = 0
self.max_consume = max_consume
self.slow_queries: Set[int] = set(slow_queries)
@override
def consume_batch(self, events: List[Dict[str, Any]]) -> None:
event_numbers = set(range(self.consumed + 1, self.consumed + 1 + len(events)))
found_slow = self.slow_queries & event_numbers
if found_slow:
logging.info("%d slow requests...", len(found_slow))
time.sleep(60 * len(found_slow))
logging.info("Done!")
self.consumed += len(events)
if self.consumed >= self.max_consume:
self.stop()